LCOV - code coverage report
Current view: top level - gcc - tree-vect-slp.cc (source / functions) Coverage Total Hit
Test: gcc.info Lines: 92.4 % 5945 5493
Test Date: 2026-07-11 15:47:05 Functions: 95.1 % 182 173
Legend: Lines:     hit not hit

            Line data    Source code
       1              : /* SLP - Basic Block Vectorization
       2              :    Copyright (C) 2007-2026 Free Software Foundation, Inc.
       3              :    Contributed by Dorit Naishlos <dorit@il.ibm.com>
       4              :    and Ira Rosen <irar@il.ibm.com>
       5              : 
       6              : This file is part of GCC.
       7              : 
       8              : GCC is free software; you can redistribute it and/or modify it under
       9              : the terms of the GNU General Public License as published by the Free
      10              : Software Foundation; either version 3, or (at your option) any later
      11              : version.
      12              : 
      13              : GCC is distributed in the hope that it will be useful, but WITHOUT ANY
      14              : WARRANTY; without even the implied warranty of MERCHANTABILITY or
      15              : FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
      16              : for more details.
      17              : 
      18              : You should have received a copy of the GNU General Public License
      19              : along with GCC; see the file COPYING3.  If not see
      20              : <http://www.gnu.org/licenses/>.  */
      21              : 
      22              : #include "config.h"
      23              : #define INCLUDE_ALGORITHM
      24              : #include "system.h"
      25              : #include "coretypes.h"
      26              : #include "backend.h"
      27              : #include "target.h"
      28              : #include "rtl.h"
      29              : #include "tree.h"
      30              : #include "gimple.h"
      31              : #include "tree-pass.h"
      32              : #include "ssa.h"
      33              : #include "optabs-tree.h"
      34              : #include "insn-config.h"
      35              : #include "recog.h"            /* FIXME: for insn_data */
      36              : #include "fold-const.h"
      37              : #include "stor-layout.h"
      38              : #include "gimple-iterator.h"
      39              : #include "cfgloop.h"
      40              : #include "tree-vectorizer.h"
      41              : #include "langhooks.h"
      42              : #include "gimple-walk.h"
      43              : #include "dbgcnt.h"
      44              : #include "tree-vector-builder.h"
      45              : #include "vec-perm-indices.h"
      46              : #include "gimple-fold.h"
      47              : #include "internal-fn.h"
      48              : #include "dump-context.h"
      49              : #include "cfganal.h"
      50              : #include "tree-eh.h"
      51              : #include "tree-cfg.h"
      52              : #include "alloc-pool.h"
      53              : #include "sreal.h"
      54              : #include "predict.h"
      55              : 
      56              : #define REDUC_GROUP_FIRST_ELEMENT(S) \
      57              :   (gcc_checking_assert (!(S)->dr_aux.dr), (S)->first_element)
      58              : 
      59              : static bool vect_transform_slp_perm_load_1 (vec_info *, slp_tree,
      60              :                                             load_permutation_t &,
      61              :                                             const vec<tree> &,
      62              :                                             gimple_stmt_iterator *,
      63              :                                             poly_uint64, bool, bool,
      64              :                                             unsigned *,
      65              :                                             unsigned * = nullptr,
      66              :                                             bool = false);
      67              : static int vectorizable_slp_permutation_1 (vec_info *, gimple_stmt_iterator *,
      68              :                                            slp_tree, lane_permutation_t &,
      69              :                                            vec<slp_tree> &, bool);
      70              : static void vect_print_slp_tree (dump_flags_t, dump_location_t, slp_tree);
      71              : static bool vect_slp_can_convert_to_external (const vec<stmt_vec_info> &);
      72              : 
      73              : static object_allocator<_slp_tree> *slp_tree_pool;
      74              : static slp_tree slp_first_node;
      75              : 
      76              : void
      77      1131492 : vect_slp_init (void)
      78              : {
      79      1131492 :   slp_tree_pool = new object_allocator<_slp_tree> ("SLP nodes");
      80      1131492 : }
      81              : 
      82              : void
      83      1131492 : vect_slp_fini (void)
      84              : {
      85      1793008 :   while (slp_first_node)
      86       661516 :     delete slp_first_node;
      87      2262984 :   delete slp_tree_pool;
      88      1131492 :   slp_tree_pool = NULL;
      89      1131492 : }
      90              : 
      91              : void *
      92      7885793 : _slp_tree::operator new (size_t n)
      93              : {
      94      7885793 :   gcc_assert (n == sizeof (_slp_tree));
      95      7885793 :   return slp_tree_pool->allocate_raw ();
      96              : }
      97              : 
      98              : void
      99      7885793 : _slp_tree::operator delete (void *node, size_t n)
     100              : {
     101      7885793 :   gcc_assert (n == sizeof (_slp_tree));
     102      7885793 :   slp_tree_pool->remove_raw (node);
     103      7885793 : }
     104              : 
     105              : 
     106              : /* Initialize a SLP node.  */
     107              : 
     108      7885793 : _slp_tree::_slp_tree ()
     109              : {
     110      7885793 :   this->prev_node = NULL;
     111      7885793 :   if (slp_first_node)
     112      6895983 :     slp_first_node->prev_node = this;
     113      7885793 :   this->next_node = slp_first_node;
     114      7885793 :   slp_first_node = this;
     115      7885793 :   SLP_TREE_SCALAR_STMTS (this) = vNULL;
     116      7885793 :   SLP_TREE_SCALAR_OPS (this) = vNULL;
     117      7885793 :   SLP_TREE_LIVE_LANES (this) = vNULL;
     118      7885793 :   SLP_TREE_VEC_DEFS (this) = vNULL;
     119      7885793 :   SLP_TREE_CHILDREN (this) = vNULL;
     120      7885793 :   SLP_TREE_LOAD_PERMUTATION (this) = vNULL;
     121      7885793 :   SLP_TREE_LANE_PERMUTATION (this) = vNULL;
     122      7885793 :   SLP_TREE_DEF_TYPE (this) = vect_uninitialized_def;
     123      7885793 :   SLP_TREE_CODE (this) = ERROR_MARK;
     124      7885793 :   SLP_TREE_GS_SCALE (this) = 0;
     125      7885793 :   SLP_TREE_GS_BASE (this) = NULL_TREE;
     126      7885793 :   this->ldst_lanes = false;
     127      7885793 :   this->avoid_stlf_fail = false;
     128      7885793 :   SLP_TREE_VECTYPE (this) = NULL_TREE;
     129      7885793 :   SLP_TREE_REPRESENTATIVE (this) = NULL;
     130      7885793 :   this->cycle_info.id = -1;
     131      7885793 :   this->cycle_info.reduc_idx = -1;
     132      7885793 :   SLP_TREE_REF_COUNT (this) = 1;
     133      7885793 :   this->failed = NULL;
     134      7885793 :   this->max_nunits = 1;
     135      7885793 :   this->lanes = 0;
     136      7885793 :   SLP_TREE_TYPE (this) = undef_vec_info_type;
     137      7885793 :   this->data = NULL;
     138      7885793 : }
     139              : 
     140              : /* Tear down a SLP node.  */
     141              : 
     142      7885793 : _slp_tree::~_slp_tree ()
     143              : {
     144      7885793 :   if (this->prev_node)
     145      4781649 :     this->prev_node->next_node = this->next_node;
     146              :   else
     147      3104144 :     slp_first_node = this->next_node;
     148      7885793 :   if (this->next_node)
     149      5938701 :     this->next_node->prev_node = this->prev_node;
     150      7885793 :   SLP_TREE_CHILDREN (this).release ();
     151      7885793 :   SLP_TREE_SCALAR_STMTS (this).release ();
     152      7885793 :   SLP_TREE_SCALAR_OPS (this).release ();
     153      7885793 :   SLP_TREE_LIVE_LANES (this).release ();
     154      7885793 :   SLP_TREE_VEC_DEFS (this).release ();
     155      7885793 :   SLP_TREE_LOAD_PERMUTATION (this).release ();
     156      7885793 :   SLP_TREE_LANE_PERMUTATION (this).release ();
     157      7885793 :   if (this->failed)
     158      2098446 :     free (failed);
     159      7885793 :   if (this->data)
     160      1259151 :     delete this->data;
     161      7885793 : }
     162              : 
     163              : /* Push the single SSA definition in DEF to the vector of vector defs.  */
     164              : 
     165              : void
     166       530864 : _slp_tree::push_vec_def (gimple *def)
     167              : {
     168       530864 :   if (gphi *phi = dyn_cast <gphi *> (def))
     169        59176 :     vec_defs.quick_push (gimple_phi_result (phi));
     170              :   else
     171              :     {
     172       471688 :       def_operand_p defop = single_ssa_def_operand (def, SSA_OP_ALL_DEFS);
     173       471688 :       vec_defs.quick_push (get_def_from_ptr (defop));
     174              :     }
     175       530864 : }
     176              : 
     177              : /* Recursively free the memory allocated for the SLP tree rooted at NODE.  */
     178              : 
     179              : void
     180     14920559 : vect_free_slp_tree (slp_tree node)
     181              : {
     182     14920559 :   int i;
     183     14920559 :   slp_tree child;
     184              : 
     185     14920559 :   if (--SLP_TREE_REF_COUNT (node) != 0)
     186     14920559 :     return;
     187              : 
     188     11182598 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
     189      3958321 :     if (child)
     190      3594517 :       vect_free_slp_tree (child);
     191              : 
     192      7224277 :   delete node;
     193              : }
     194              : 
     195              : /* Return a location suitable for dumpings related to the SLP instance.  */
     196              : 
     197              : dump_user_location_t
     198      3461550 : _slp_instance::location () const
     199              : {
     200      3461550 :   if (!root_stmts.is_empty ())
     201       338386 :     return root_stmts[0]->stmt;
     202              :   else
     203      3123164 :     return SLP_TREE_SCALAR_STMTS (root)[0]->stmt;
     204              : }
     205              : 
     206              : 
     207              : /* Free the memory allocated for the SLP instance.  */
     208              : 
     209              : void
     210      1587959 : vect_free_slp_instance (slp_instance instance)
     211              : {
     212      1587959 :   vect_free_slp_tree (SLP_INSTANCE_TREE (instance));
     213      1587959 :   SLP_INSTANCE_LOADS (instance).release ();
     214      1587959 :   SLP_INSTANCE_ROOT_STMTS (instance).release ();
     215      1587959 :   SLP_INSTANCE_REMAIN_DEFS (instance).release ();
     216      1587959 :   instance->subgraph_entries.release ();
     217      1587959 :   instance->cost_vec.release ();
     218      1587959 :   free (instance);
     219      1587959 : }
     220              : 
     221              : 
     222              : /* Create a SLP node with NOPS children with CODE, either VEC_PERM_EXPR
     223              :    for a permute node or else ERROR_MARK.  */
     224              : 
     225              : slp_tree
     226        96137 : vect_create_new_slp_node (unsigned nops, tree_code code)
     227              : {
     228        96137 :   gcc_assert (code == ERROR_MARK || code == VEC_PERM_EXPR);
     229        96137 :   slp_tree node = new _slp_tree;
     230        96137 :   SLP_TREE_SCALAR_STMTS (node) = vNULL;
     231        96137 :   SLP_TREE_CHILDREN (node).create (nops);
     232        96137 :   SLP_TREE_DEF_TYPE (node) = vect_internal_def;
     233        96137 :   SLP_TREE_CODE (node) = code;
     234        96137 :   return node;
     235              : }
     236              : 
     237              : /* Create a SLP node inplace at NODE for SCALAR_STMTS and NOPS children.  */
     238              : 
     239              : static slp_tree
     240      3811784 : vect_create_new_slp_node (slp_tree node,
     241              :                           vec<stmt_vec_info> scalar_stmts, unsigned nops)
     242              : {
     243      3811784 :   SLP_TREE_SCALAR_STMTS (node) = scalar_stmts;
     244      3811784 :   SLP_TREE_CHILDREN (node).create (nops);
     245      3811784 :   SLP_TREE_DEF_TYPE (node) = vect_internal_def;
     246      3811784 :   SLP_TREE_REPRESENTATIVE (node) = scalar_stmts[0];
     247      3811784 :   SLP_TREE_LANES (node) = scalar_stmts.length ();
     248      3811784 :   return node;
     249              : }
     250              : 
     251              : /* Create an SLP node for SCALAR_STMTS and NOPS children.  */
     252              : 
     253              : static slp_tree
     254         8179 : vect_create_new_slp_node (vec<stmt_vec_info> scalar_stmts, unsigned nops)
     255              : {
     256         8179 :   return vect_create_new_slp_node (new _slp_tree, scalar_stmts, nops);
     257              : }
     258              : 
     259              : /* Create a vect_external_def SLP node inplace at NODE for scalar
     260              :    operands OPS.  */
     261              : 
     262              : static slp_tree
     263      1869034 : vect_create_new_slp_node (slp_tree node, vec<tree> ops)
     264              : {
     265      1869034 :   SLP_TREE_SCALAR_OPS (node) = ops;
     266      1869034 :   SLP_TREE_DEF_TYPE (node) = vect_external_def;
     267            0 :   SLP_TREE_LANES (node) = ops.length ();
     268      1869034 :   return node;
     269              : }
     270              : 
     271              : /* Create a vect_external_def SLP node for scalar operands OPS.  */
     272              : 
     273              : static slp_tree
     274      1869034 : vect_create_new_slp_node (vec<tree> ops)
     275              : {
     276      1869034 :   return vect_create_new_slp_node (new _slp_tree, ops);
     277              : }
     278              : 
     279              : 
     280              : /* This structure is used in creation of an SLP tree.  Each instance
     281              :    corresponds to the same operand in a group of scalar stmts in an SLP
     282              :    node.  */
     283              : typedef struct _slp_oprnd_info
     284              : {
     285              :   /* Def-stmts for the operands.  */
     286              :   vec<stmt_vec_info> def_stmts;
     287              :   /* Operands.  */
     288              :   vec<tree> ops;
     289              :   /* Information about the first statement, its vector def-type, type, the
     290              :      operand itself in case it's constant, and an indication if it's a pattern
     291              :      stmt and gather/scatter info.  */
     292              :   tree first_op_type;
     293              :   enum vect_def_type first_dt;
     294              :   bool any_pattern;
     295              :   bool first_gs_p;
     296              :   gather_scatter_info first_gs_info;
     297              : } *slp_oprnd_info;
     298              : 
     299              : 
     300              : /* Allocate operands info for NOPS operands, and GROUP_SIZE def-stmts for each
     301              :    operand.  */
     302              : static vec<slp_oprnd_info>
     303      3393756 : vect_create_oprnd_info (int nops, int group_size)
     304              : {
     305      3393756 :   int i;
     306      3393756 :   slp_oprnd_info oprnd_info;
     307      3393756 :   vec<slp_oprnd_info> oprnds_info;
     308              : 
     309      3393756 :   oprnds_info.create (nops);
     310     12184628 :   for (i = 0; i < nops; i++)
     311              :     {
     312      5397116 :       oprnd_info = XNEW (struct _slp_oprnd_info);
     313      5397116 :       oprnd_info->def_stmts.create (group_size);
     314      5397116 :       oprnd_info->ops.create (group_size);
     315      5397116 :       oprnd_info->first_dt = vect_uninitialized_def;
     316      5397116 :       oprnd_info->first_op_type = NULL_TREE;
     317      5397116 :       oprnd_info->any_pattern = false;
     318      5397116 :       oprnd_info->first_gs_p = false;
     319      5397116 :       oprnds_info.quick_push (oprnd_info);
     320              :     }
     321              : 
     322      3393756 :   return oprnds_info;
     323              : }
     324              : 
     325              : 
     326              : /* Free operands info.  */
     327              : 
     328              : static void
     329      3393756 : vect_free_oprnd_info (vec<slp_oprnd_info> &oprnds_info)
     330              : {
     331      3393756 :   int i;
     332      3393756 :   slp_oprnd_info oprnd_info;
     333              : 
     334      8790872 :   FOR_EACH_VEC_ELT (oprnds_info, i, oprnd_info)
     335              :     {
     336      5397116 :       oprnd_info->def_stmts.release ();
     337      5397116 :       oprnd_info->ops.release ();
     338      5397116 :       XDELETE (oprnd_info);
     339              :     }
     340              : 
     341      3393756 :   oprnds_info.release ();
     342      3393756 : }
     343              : 
     344              : /* Return the execution frequency of NODE (so that a higher value indicates
     345              :    a "more important" node when optimizing for speed).  */
     346              : 
     347              : static sreal
     348      3531577 : vect_slp_node_weight (slp_tree node)
     349              : {
     350      3531577 :   stmt_vec_info stmt_info = vect_orig_stmt (SLP_TREE_REPRESENTATIVE (node));
     351      3531577 :   basic_block bb = gimple_bb (stmt_info->stmt);
     352      3531577 :   return bb->count.to_sreal_scale (ENTRY_BLOCK_PTR_FOR_FN (cfun)->count);
     353              : }
     354              : 
     355              : /* Return true if STMTS contains a pattern statement.  */
     356              : 
     357              : static bool
     358        22406 : vect_contains_pattern_stmt_p (vec<stmt_vec_info> stmts)
     359              : {
     360        22406 :   stmt_vec_info stmt_info;
     361        22406 :   unsigned int i;
     362        73396 :   FOR_EACH_VEC_ELT (stmts, i, stmt_info)
     363        53041 :     if (stmt_info && is_pattern_stmt_p (stmt_info))
     364              :       return true;
     365              :   return false;
     366              : }
     367              : 
     368              : /* Return true when all lanes in the external or constant NODE have
     369              :    the same value.  */
     370              : 
     371              : static bool
     372       603436 : vect_slp_tree_uniform_p (slp_tree node)
     373              : {
     374       603436 :   gcc_assert (SLP_TREE_DEF_TYPE (node) == vect_constant_def
     375              :               || SLP_TREE_DEF_TYPE (node) == vect_external_def);
     376              : 
     377              :   /* Pre-existing vectors.  */
     378      1059477 :   if (SLP_TREE_SCALAR_OPS (node).is_empty ())
     379              :     return false;
     380              : 
     381              :   unsigned i;
     382              :   tree op, first = NULL_TREE;
     383      1384221 :   FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_OPS (node), i, op)
     384      1236826 :     if (!first)
     385              :       first = op;
     386       633390 :     else if (!operand_equal_p (first, op, 0))
     387              :       return false;
     388              : 
     389              :   return true;
     390              : }
     391              : 
     392              : /* Find the place of the data-ref in STMT_INFO in the interleaving chain
     393              :    that starts from FIRST_STMT_INFO.  Return -1 if the data-ref is not a part
     394              :    of the chain.  */
     395              : 
     396              : int
     397       712331 : vect_get_place_in_interleaving_chain (stmt_vec_info stmt_info,
     398              :                                       stmt_vec_info first_stmt_info)
     399              : {
     400       712331 :   stmt_vec_info next_stmt_info = first_stmt_info;
     401       712331 :   int result = 0;
     402              : 
     403       712331 :   if (first_stmt_info != DR_GROUP_FIRST_ELEMENT (stmt_info))
     404              :     return -1;
     405              : 
     406      1782083 :   do
     407              :     {
     408      1782083 :       if (next_stmt_info == stmt_info)
     409              :         return result;
     410      1069752 :       next_stmt_info = DR_GROUP_NEXT_ELEMENT (next_stmt_info);
     411      1069752 :       if (next_stmt_info)
     412      1069752 :         result += DR_GROUP_GAP (next_stmt_info);
     413              :     }
     414      1069752 :   while (next_stmt_info);
     415              : 
     416              :   return -1;
     417              : }
     418              : 
     419              : /* Check whether it is possible to load COUNT elements of type ELT_TYPE
     420              :    using the method implemented by duplicate_and_interleave.  Return true
     421              :    if so, returning the number of intermediate vectors in *NVECTORS_OUT
     422              :    (if nonnull) and the type of each intermediate vector in *VECTOR_TYPE_OUT
     423              :    (if nonnull).  */
     424              : 
     425              : bool
     426            0 : can_duplicate_and_interleave_p (vec_info *vinfo, unsigned int count,
     427              :                                 tree elt_type, unsigned int *nvectors_out,
     428              :                                 tree *vector_type_out,
     429              :                                 tree *permutes)
     430              : {
     431            0 :   tree base_vector_type = get_vectype_for_scalar_type (vinfo, elt_type, count);
     432            0 :   if (!base_vector_type || !VECTOR_MODE_P (TYPE_MODE (base_vector_type)))
     433            0 :     return false;
     434              : 
     435            0 :   machine_mode base_vector_mode = TYPE_MODE (base_vector_type);
     436            0 :   poly_int64 elt_bytes = count * GET_MODE_UNIT_SIZE (base_vector_mode);
     437            0 :   unsigned int nvectors = 1;
     438            0 :   for (;;)
     439              :     {
     440            0 :       scalar_int_mode int_mode;
     441            0 :       poly_int64 elt_bits = elt_bytes * BITS_PER_UNIT;
     442            0 :       if (int_mode_for_size (elt_bits, 1).exists (&int_mode))
     443              :         {
     444              :           /* Get the natural vector type for this SLP group size.  */
     445            0 :           tree int_type = build_nonstandard_integer_type
     446            0 :             (GET_MODE_BITSIZE (int_mode), 1);
     447            0 :           tree vector_type
     448            0 :             = get_vectype_for_scalar_type (vinfo, int_type, count);
     449            0 :           poly_int64 half_nelts;
     450            0 :           if (vector_type
     451            0 :               && VECTOR_MODE_P (TYPE_MODE (vector_type))
     452            0 :               && known_eq (GET_MODE_SIZE (TYPE_MODE (vector_type)),
     453              :                            GET_MODE_SIZE (base_vector_mode))
     454            0 :               && multiple_p (GET_MODE_NUNITS (TYPE_MODE (vector_type)),
     455              :                              2, &half_nelts))
     456              :             {
     457              :               /* Try fusing consecutive sequences of COUNT / NVECTORS elements
     458              :                  together into elements of type INT_TYPE and using the result
     459              :                  to build NVECTORS vectors.  */
     460            0 :               poly_uint64 nelts = GET_MODE_NUNITS (TYPE_MODE (vector_type));
     461            0 :               vec_perm_builder sel1 (nelts, 2, 3);
     462            0 :               vec_perm_builder sel2 (nelts, 2, 3);
     463              : 
     464            0 :               for (unsigned int i = 0; i < 3; ++i)
     465              :                 {
     466            0 :                   sel1.quick_push (i);
     467            0 :                   sel1.quick_push (i + nelts);
     468            0 :                   sel2.quick_push (half_nelts + i);
     469            0 :                   sel2.quick_push (half_nelts + i + nelts);
     470              :                 }
     471            0 :               vec_perm_indices indices1 (sel1, 2, nelts);
     472            0 :               vec_perm_indices indices2 (sel2, 2, nelts);
     473            0 :               machine_mode vmode = TYPE_MODE (vector_type);
     474            0 :               if (can_vec_perm_const_p (vmode, vmode, indices1)
     475            0 :                   && can_vec_perm_const_p (vmode, vmode, indices2))
     476              :                 {
     477            0 :                   if (nvectors_out)
     478            0 :                     *nvectors_out = nvectors;
     479            0 :                   if (vector_type_out)
     480            0 :                     *vector_type_out = vector_type;
     481            0 :                   if (permutes)
     482              :                     {
     483            0 :                       permutes[0] = vect_gen_perm_mask_checked (vector_type,
     484              :                                                                 indices1);
     485            0 :                       permutes[1] = vect_gen_perm_mask_checked (vector_type,
     486              :                                                                 indices2);
     487              :                     }
     488            0 :                   return true;
     489              :                 }
     490            0 :             }
     491              :         }
     492            0 :       if (!multiple_p (elt_bytes, 2, &elt_bytes))
     493              :         return false;
     494            0 :       nvectors *= 2;
     495              :       /* We need to be able to fuse COUNT / NVECTORS elements together.  */
     496            0 :       if (!multiple_p (count, nvectors))
     497              :         return false;
     498              :     }
     499              : }
     500              : 
     501              : /* Return true if DTA and DTB match.  */
     502              : 
     503              : static bool
     504     17052206 : vect_def_types_match (enum vect_def_type dta, enum vect_def_type dtb)
     505              : {
     506     17052206 :   return (dta == dtb
     507       357982 :           || ((dta == vect_external_def || dta == vect_constant_def)
     508       222165 :               && (dtb == vect_external_def || dtb == vect_constant_def)));
     509              : }
     510              : 
     511              : #define GATHER_SCATTER_OFFSET (-3)
     512              : 
     513              : /* For most SLP statements, there is a one-to-one mapping between
     514              :    gimple arguments and child nodes.  If that is not true for STMT,
     515              :    return an array that contains:
     516              : 
     517              :    - the number of child nodes, followed by
     518              :    - for each child node, the index of the argument associated with that node.
     519              :      The special index -1 is the first operand of an embedded comparison and
     520              :      the special index -2 is the second operand of an embedded comparison.
     521              :      The special index -3 is the offset of a gather as analyzed by
     522              :      vect_check_gather_scatter.
     523              : 
     524              :    SWAP is as for vect_get_and_check_slp_defs.  */
     525              : 
     526              : static const int *
     527     24586313 : vect_get_operand_map (const gimple *stmt, bool gather_scatter_p,
     528              :                       unsigned char swap)
     529              : {
     530     24586313 :   static const int no_arg_map[] = { 0 };
     531     24586313 :   static const int arg0_map[] = { 1, 0 };
     532     24586313 :   static const int arg2_map[] = { 1, 2 };
     533     24586313 :   static const int arg2_arg3_map[] = { 2, 2, 3 };
     534     24586313 :   static const int arg2_arg4_map[] = { 2, 2, 4 };
     535     24586313 :   static const int arg2_arg5_arg6_map[] = { 3, 2, 5, 6 };
     536     24586313 :   static const int arg2_arg4_arg5_map[] = { 3, 2, 4, 5 };
     537     24586313 :   static const int arg3_arg2_map[] = { 2, 3, 2 };
     538     24586313 :   static const int op00_map[] = { 1, -1 };
     539     24586313 :   static const int op1_op0_map[] = { 2, 1, 0 };
     540     24586313 :   static const int off_map[] = { 1, GATHER_SCATTER_OFFSET };
     541     24586313 :   static const int off_op0_map[] = { 2, GATHER_SCATTER_OFFSET, 0 };
     542     24586313 :   static const int off_arg2_arg3_map[] = { 3, GATHER_SCATTER_OFFSET, 2, 3 };
     543     24586313 :   static const int off_arg3_arg2_map[] = { 3, GATHER_SCATTER_OFFSET, 3, 2 };
     544     24586313 :   static const int mask_call_maps[6][7] = {
     545              :         { 1, 1, },
     546              :         { 2, 1, 2, },
     547              :         { 3, 1, 2, 3, },
     548              :         { 4, 1, 2, 3, 4, },
     549              :         { 5, 1, 2, 3, 4, 5, },
     550              :         { 6, 1, 2, 3, 4, 5, 6 },
     551              :   };
     552              : 
     553     24586313 :   gcc_checking_assert (!swap
     554              :                        || !is_gimple_assign (stmt)
     555              :                        || TREE_CODE_CLASS
     556              :                             (gimple_assign_rhs_code (stmt)) == tcc_comparison
     557              :                        || commutative_tree_code
     558              :                             (gimple_assign_rhs_code (stmt)));
     559              : 
     560     24586313 :   if (auto assign = dyn_cast<const gassign *> (stmt))
     561              :     {
     562     23121222 :       tree_code code = gimple_assign_rhs_code (assign);
     563     23121222 :       if (code == COND_EXPR
     564     23121222 :           && COMPARISON_CLASS_P (gimple_assign_rhs1 (assign)))
     565            0 :         gcc_unreachable ();
     566     23121222 :       else if ((TREE_CODE_CLASS (code) == tcc_comparison
     567     21669934 :                 || commutative_tree_code (code))
     568     32079947 :                && swap)
     569              :         return op1_op0_map;
     570     23078902 :       else if (code == VIEW_CONVERT_EXPR)
     571              :         return op00_map;
     572     23070297 :       else if (gather_scatter_p)
     573        43601 :         return (TREE_CODE (gimple_assign_lhs (assign)) != SSA_NAME
     574        43601 :                 ? off_op0_map : off_map);
     575              :     }
     576      1465091 :   else if (auto call = dyn_cast<const gcall *> (stmt))
     577              :     {
     578       162153 :       if (gimple_call_internal_p (call))
     579        92078 :         switch (gimple_call_internal_fn (call))
     580              :           {
     581        15905 :           case IFN_MASK_LOAD:
     582        27090 :             return gather_scatter_p ? off_arg2_arg3_map : arg2_arg3_map;
     583              : 
     584              :           case IFN_GATHER_LOAD:
     585              :             return arg2_map;
     586              : 
     587            0 :           case IFN_MASK_GATHER_LOAD:
     588            0 :           case IFN_MASK_LEN_GATHER_LOAD:
     589            0 :             return arg2_arg5_arg6_map;
     590              : 
     591            0 :           case IFN_SCATTER_STORE:
     592            0 :             return arg2_arg4_map;
     593              : 
     594            0 :           case IFN_MASK_SCATTER_STORE:
     595            0 :           case IFN_MASK_LEN_SCATTER_STORE:
     596            0 :             return arg2_arg4_arg5_map;
     597              : 
     598         9311 :           case IFN_MASK_STORE:
     599        17200 :             return gather_scatter_p ? off_arg3_arg2_map : arg3_arg2_map;
     600              : 
     601          988 :           case IFN_MASK_CALL:
     602          988 :             {
     603          988 :               unsigned nargs = gimple_call_num_args (call);
     604          988 :               if (nargs >= 2 && nargs <= 7)
     605          988 :                 return mask_call_maps[nargs-2];
     606              :               else
     607              :                 return nullptr;
     608              :             }
     609              : 
     610          278 :           case IFN_CLZ:
     611          278 :           case IFN_CTZ:
     612          278 :             return arg0_map;
     613              : 
     614         6294 :           case IFN_GOMP_SIMD_LANE:
     615         6294 :             return no_arg_map;
     616              : 
     617              :           default:
     618              :             break;
     619              :           }
     620              :     }
     621              :   return nullptr;
     622              : }
     623              : 
     624              : static const int *
     625     24569584 : vect_get_operand_map (const stmt_vec_info stmt, unsigned char swap = 0)
     626              : {
     627            0 :   return vect_get_operand_map (stmt->stmt, STMT_VINFO_GATHER_SCATTER_P (stmt),
     628            0 :                                swap);
     629              : }
     630              : 
     631              : /* Return the SLP node child index for operand OP of STMT.  */
     632              : 
     633              : int
     634      1390022 : vect_slp_child_index_for_operand (const stmt_vec_info stmt, int op)
     635              : {
     636      1390022 :   const int *opmap = vect_get_operand_map (stmt);
     637      1390022 :   if (!opmap)
     638              :     return op;
     639        21870 :   for (int i = 1; i < 1 + opmap[0]; ++i)
     640        21870 :     if (opmap[i] == op)
     641        12222 :       return i - 1;
     642            0 :   gcc_unreachable ();
     643              : }
     644              : 
     645              : /* Helper class for mapping of GIMPLE operands to SLP children.  */
     646              : /* ???  Add vect_slp_child_index_for_operand here and amend opmaps
     647              :    with the full reverse mapping and indicating the position of the
     648              :    first commutative operand index, eliding the swap_p argument from
     649              :    vect_get_operand_map.  Adjust all consumers.  */
     650              : 
     651              : struct slp_oprnds {
     652              :   slp_oprnds (stmt_vec_info);
     653              :   tree get_op_for_slp_child (stmt_vec_info, unsigned);
     654              :   const int *opmap;
     655              :   const unsigned int num_slp_children;
     656              : };
     657              : 
     658      4460111 : slp_oprnds::slp_oprnds (stmt_vec_info stmt_info)
     659      4460111 :   : opmap (vect_get_operand_map (stmt_info)),
     660      4460111 :     num_slp_children (opmap ? opmap[0] : gimple_num_args (stmt_info->stmt))
     661              : {
     662      4460111 : }
     663              : 
     664              : /* For SLP child number N get the corresponding tree operand from GIMPLE
     665              :    statement described by STMT_INFO.  */
     666              : 
     667              : tree
     668      4907576 : slp_oprnds::get_op_for_slp_child (stmt_vec_info stmt_info, unsigned n)
     669              : {
     670      4907576 :   gcc_assert (n < num_slp_children);
     671      4907576 :   int opno = opmap ? opmap[n + 1] : (int) n;
     672      4907576 :   if (opno == GATHER_SCATTER_OFFSET)
     673            0 :     gcc_unreachable (); // TODO
     674      4907576 :   else if (opno < 0)
     675         2106 :     return TREE_OPERAND (gimple_arg (stmt_info->stmt, 0), -1 - opno);
     676              :   else
     677      4905470 :     return gimple_arg (stmt_info->stmt, opno);
     678              : }
     679              : 
     680              : /* Get the defs for the rhs of STMT (collect them in OPRNDS_INFO), check that
     681              :    they are of a valid type and that they match the defs of the first stmt of
     682              :    the SLP group (stored in OPRNDS_INFO).  This function tries to match stmts
     683              :    by swapping operands of STMTS[STMT_NUM] when possible.  Non-zero SWAP
     684              :    indicates swap is required for cond_expr stmts.  Specifically, SWAP
     685              :    is 1 if STMT is cond and operands of comparison need to be swapped;
     686              :    SWAP is 2 if STMT is cond and code of comparison needs to be inverted.
     687              : 
     688              :    If there was a fatal error return -1; if the error could be corrected by
     689              :    swapping operands of father node of this one, return 1; if everything is
     690              :    ok return 0.  */
     691              : static int
     692     12820856 : vect_get_and_check_slp_defs (vec_info *vinfo, tree vectype, unsigned char swap,
     693              :                              bool *skip_args,
     694              :                              vec<stmt_vec_info> stmts, unsigned stmt_num,
     695              :                              vec<slp_oprnd_info> *oprnds_info)
     696              : {
     697     12820856 :   stmt_vec_info stmt_info = stmts[stmt_num];
     698     12820856 :   tree oprnd;
     699     12820856 :   unsigned int i, number_of_oprnds;
     700     12820856 :   enum vect_def_type dt = vect_uninitialized_def;
     701     12820856 :   slp_oprnd_info oprnd_info;
     702     12820856 :   gather_scatter_info gs_info;
     703     12820856 :   unsigned int gs_op = -1u;
     704     12820856 :   unsigned int commutative_op = -1U;
     705     12820856 :   bool first = stmt_num == 0;
     706              : 
     707     12820856 :   if (!stmt_info)
     708              :     {
     709            0 :       for (auto oi : *oprnds_info)
     710              :         {
     711            0 :           oi->def_stmts.quick_push (NULL);
     712            0 :           oi->ops.quick_push (NULL_TREE);
     713              :         }
     714              :       return 0;
     715              :     }
     716              : 
     717     12820856 :   if (!is_a<gcall *> (stmt_info->stmt)
     718              :       && !is_a<gassign *> (stmt_info->stmt)
     719              :       && !is_a<gphi *> (stmt_info->stmt))
     720              :     return -1;
     721              : 
     722     12820856 :   number_of_oprnds = gimple_num_args (stmt_info->stmt);
     723     12820856 :   const int *map = vect_get_operand_map (stmt_info, swap);
     724     12820856 :   if (map)
     725        77738 :     number_of_oprnds = *map++;
     726     12820856 :   if (gcall *stmt = dyn_cast <gcall *> (stmt_info->stmt))
     727              :     {
     728        50765 :       if (gimple_call_internal_p (stmt))
     729              :         {
     730        32563 :           internal_fn ifn = gimple_call_internal_fn (stmt);
     731        32563 :           commutative_op = first_commutative_argument (ifn);
     732        32563 :           if (internal_gather_scatter_fn_p (ifn))
     733              :             {
     734            0 :               vect_describe_gather_scatter_call
     735            0 :                 (stmt_info,
     736            0 :                  first ? &(*oprnds_info)[0]->first_gs_info : &gs_info);
     737            0 :               if (first)
     738            0 :                 (*oprnds_info)[0]->first_gs_p = true;
     739              :               gs_op = 0;
     740              :             }
     741              :         }
     742              :     }
     743     12770091 :   else if (gassign *stmt = dyn_cast <gassign *> (stmt_info->stmt))
     744              :     {
     745     14919398 :       if (commutative_tree_code (gimple_assign_rhs_code (stmt)))
     746      8432730 :         commutative_op = 0;
     747              :     }
     748              : 
     749     12820856 :   bool swapped = (swap != 0);
     750     12820856 :   bool backedge = false;
     751     12820856 :   enum vect_def_type *dts = XALLOCAVEC (enum vect_def_type, number_of_oprnds);
     752     35455394 :   for (i = 0; i < number_of_oprnds; i++)
     753              :     {
     754     22635744 :       oprnd_info = (*oprnds_info)[i];
     755     22635744 :       int opno = map ? map[i] : int (i);
     756     22635744 :       if (opno == GATHER_SCATTER_OFFSET)
     757              :         {
     758        22866 :           gcc_assert (STMT_VINFO_GATHER_SCATTER_P (stmt_info));
     759        22866 :           if (!is_a <loop_vec_info> (vinfo)
     760        22866 :               || !vect_check_gather_scatter (stmt_info, vectype,
     761              :                                              as_a <loop_vec_info> (vinfo),
     762              :                                              first ? &oprnd_info->first_gs_info
     763              :                                              : &gs_info))
     764         1206 :             return -1;
     765              : 
     766        22866 :           if (first)
     767              :             {
     768        22609 :               oprnd_info->first_gs_p = true;
     769        22609 :               oprnd = oprnd_info->first_gs_info.offset;
     770              :             }
     771              :           else
     772              :             {
     773          257 :               gs_op = i;
     774          257 :               oprnd = gs_info.offset;
     775              :             }
     776              :         }
     777     22612878 :       else if (opno < 0)
     778         3050 :         oprnd = TREE_OPERAND (gimple_arg (stmt_info->stmt, 0), -1 - opno);
     779              :       else
     780              :         {
     781     22609828 :           oprnd = gimple_arg (stmt_info->stmt, opno);
     782     22609828 :           if (gphi *stmt = dyn_cast <gphi *> (stmt_info->stmt))
     783              :             {
     784      1224446 :               edge e = gimple_phi_arg_edge (stmt, opno);
     785      2448892 :               backedge = (is_a <bb_vec_info> (vinfo)
     786      1893123 :                           ? e->flags & EDGE_DFS_BACK
     787       668677 :                           : dominated_by_p (CDI_DOMINATORS, e->src,
     788       668677 :                                             gimple_bb (stmt_info->stmt)));
     789              :             }
     790              :         }
     791              : 
     792     22635744 :       stmt_vec_info def_stmt_info;
     793     22635744 :       if (!vect_is_simple_use (oprnd, vinfo, &dts[i], &def_stmt_info))
     794              :         {
     795          982 :           if (dump_enabled_p ())
     796            0 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     797              :                              "Build SLP failed: can't analyze def for %T\n",
     798              :                              oprnd);
     799              : 
     800          982 :           return -1;
     801              :         }
     802              : 
     803     22634762 :       if (skip_args[i])
     804              :         {
     805       534170 :           oprnd_info->def_stmts.quick_push (NULL);
     806       534170 :           oprnd_info->ops.quick_push (NULL_TREE);
     807       534170 :           oprnd_info->first_dt = vect_uninitialized_def;
     808       534170 :           continue;
     809              :         }
     810              : 
     811     22100592 :       oprnd_info->def_stmts.quick_push (def_stmt_info);
     812     22100592 :       oprnd_info->ops.quick_push (oprnd);
     813              : 
     814     22100592 :       if (def_stmt_info
     815     22100592 :           && is_pattern_stmt_p (def_stmt_info))
     816              :         {
     817       393387 :           if (STMT_VINFO_RELATED_STMT (vect_orig_stmt (def_stmt_info))
     818              :               != def_stmt_info)
     819       276541 :             oprnd_info->any_pattern = true;
     820              :           else
     821              :             /* If we promote this to external use the original stmt def.  */
     822       116846 :             oprnd_info->ops.last ()
     823       233692 :               = gimple_get_lhs (vect_orig_stmt (def_stmt_info)->stmt);
     824              :         }
     825              : 
     826              :       /* If there's a extern def on a backedge make sure we can
     827              :          code-generate at the region start.
     828              :          ???  This is another case that could be fixed by adjusting
     829              :          how we split the function but at the moment we'd have conflicting
     830              :          goals there.  */
     831     22100592 :       if (backedge
     832       168566 :           && dts[i] == vect_external_def
     833          245 :           && is_a <bb_vec_info> (vinfo)
     834          245 :           && TREE_CODE (oprnd) == SSA_NAME
     835          224 :           && !SSA_NAME_IS_DEFAULT_DEF (oprnd)
     836     22100816 :           && !dominated_by_p (CDI_DOMINATORS, vinfo->bbs[0],
     837          224 :                               gimple_bb (SSA_NAME_DEF_STMT (oprnd))))
     838              :         {
     839          224 :           if (dump_enabled_p ())
     840            0 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     841              :                              "Build SLP failed: extern def %T only defined "
     842              :                              "on backedge\n", oprnd);
     843          224 :           return -1;
     844              :         }
     845              : 
     846     22100368 :       if (first)
     847              :         {
     848      4901672 :           tree type = TREE_TYPE (oprnd);
     849      4901672 :           dt = dts[i];
     850              : 
     851              :           /* For the swapping logic below force vect_reduction_def
     852              :              for the reduction op in a SLP reduction group.  */
     853      4901672 :           if (!STMT_VINFO_DATA_REF (stmt_info)
     854      3716891 :               && REDUC_GROUP_FIRST_ELEMENT (stmt_info)
     855         5224 :               && (int)i == STMT_VINFO_REDUC_IDX (stmt_info)
     856      4904244 :               && def_stmt_info)
     857         2572 :             dts[i] = dt = vect_reduction_def;
     858              : 
     859              :           /* Check the types of the definition.  */
     860      4901672 :           switch (dt)
     861              :             {
     862      4901672 :             case vect_external_def:
     863      4901672 :             case vect_constant_def:
     864      4901672 :             case vect_internal_def:
     865      4901672 :             case vect_reduction_def:
     866      4901672 :             case vect_double_reduction_def:
     867      4901672 :             case vect_induction_def:
     868      4901672 :             case vect_nested_cycle:
     869      4901672 :             case vect_first_order_recurrence:
     870      4901672 :               break;
     871              : 
     872            0 :             default:
     873              :               /* FORNOW: Not supported.  */
     874            0 :               if (dump_enabled_p ())
     875            0 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     876              :                                  "Build SLP failed: illegal type of def %T\n",
     877              :                                  oprnd);
     878            0 :               return -1;
     879              :             }
     880              : 
     881      4901672 :           oprnd_info->first_dt = dt;
     882      4901672 :           oprnd_info->first_op_type = type;
     883              :         }
     884              :     }
     885     12819650 :   if (first)
     886              :     return 0;
     887              : 
     888              :   /* Now match the operand definition types to that of the first stmt.  */
     889     26334122 :   for (i = 0; i < number_of_oprnds;)
     890              :     {
     891     17195073 :       if (skip_args[i])
     892              :         {
     893        44124 :           ++i;
     894        44124 :           continue;
     895              :         }
     896              : 
     897     17150949 :       oprnd_info = (*oprnds_info)[i];
     898     17150949 :       dt = dts[i];
     899     17150949 :       stmt_vec_info def_stmt_info = oprnd_info->def_stmts[stmt_num];
     900     17150949 :       oprnd = oprnd_info->ops[stmt_num];
     901     17150949 :       tree type = TREE_TYPE (oprnd);
     902              : 
     903     17150949 :       if (!types_compatible_p (oprnd_info->first_op_type, type))
     904              :         {
     905       104866 :           if (dump_enabled_p ())
     906           91 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     907              :                              "Build SLP failed: different operand types\n");
     908       104866 :           return 1;
     909              :         }
     910              : 
     911     17046083 :       if ((gs_op == i) != oprnd_info->first_gs_p)
     912              :         {
     913            0 :           if (dump_enabled_p ())
     914            0 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     915              :                              "Build SLP failed: mixed gather and non-gather\n");
     916            0 :           return 1;
     917              :         }
     918     17046083 :       else if (gs_op == i)
     919              :         {
     920          227 :           if (!operand_equal_p (oprnd_info->first_gs_info.base,
     921          227 :                                 gs_info.base))
     922              :             {
     923           16 :               if (dump_enabled_p ())
     924            6 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     925              :                                  "Build SLP failed: different gather base\n");
     926           16 :               return 1;
     927              :             }
     928          211 :           if (oprnd_info->first_gs_info.scale != gs_info.scale)
     929              :             {
     930            8 :               if (dump_enabled_p ())
     931            2 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     932              :                                  "Build SLP failed: different gather scale\n");
     933            8 :               return 1;
     934              :             }
     935              :         }
     936              : 
     937              :       /* Not first stmt of the group, check that the def-stmt/s match
     938              :          the def-stmt/s of the first stmt.  Allow different definition
     939              :          types for reduction chains: the first stmt must be a
     940              :          vect_reduction_def (a phi node), and the rest
     941              :          end in the reduction chain.  */
     942     17046059 :       if ((!vect_def_types_match (oprnd_info->first_dt, dt)
     943       299269 :            && !(oprnd_info->first_dt == vect_reduction_def
     944         4797 :                 && !STMT_VINFO_DATA_REF (stmt_info)
     945         4797 :                 && REDUC_GROUP_FIRST_ELEMENT (stmt_info)
     946         4771 :                 && def_stmt_info
     947         4769 :                 && !STMT_VINFO_DATA_REF (def_stmt_info)
     948         4769 :                 && (REDUC_GROUP_FIRST_ELEMENT (def_stmt_info)
     949              :                     == REDUC_GROUP_FIRST_ELEMENT (stmt_info))))
     950     16751559 :           || (!STMT_VINFO_DATA_REF (stmt_info)
     951     15424698 :               && REDUC_GROUP_FIRST_ELEMENT (stmt_info)
     952         9943 :               && ((!def_stmt_info
     953         9747 :                    || STMT_VINFO_DATA_REF (def_stmt_info)
     954        17960 :                    || (REDUC_GROUP_FIRST_ELEMENT (def_stmt_info)
     955              :                        != REDUC_GROUP_FIRST_ELEMENT (stmt_info)))
     956         9943 :                   != (oprnd_info->first_dt != vect_reduction_def))))
     957              :         {
     958              :           /* Try swapping operands if we got a mismatch.  For BB
     959              :              vectorization only in case it will clearly improve things.  */
     960       296958 :           if (i == commutative_op && !swapped
     961       294500 :               && (!is_a <bb_vec_info> (vinfo)
     962         4838 :                   || (!vect_def_types_match ((*oprnds_info)[i+1]->first_dt,
     963         4838 :                                              dts[i+1])
     964         1153 :                       && (vect_def_types_match (oprnd_info->first_dt, dts[i+1])
     965              :                           || vect_def_types_match
     966          156 :                                ((*oprnds_info)[i+1]->first_dt, dts[i])))))
     967              :             {
     968         2458 :               if (dump_enabled_p ())
     969          153 :                 dump_printf_loc (MSG_NOTE, vect_location,
     970              :                                  "trying swapped operands\n");
     971         2458 :               std::swap (dts[i], dts[i+1]);
     972         2458 :               std::swap ((*oprnds_info)[i]->def_stmts[stmt_num],
     973         2458 :                          (*oprnds_info)[i+1]->def_stmts[stmt_num]);
     974         2458 :               std::swap ((*oprnds_info)[i]->ops[stmt_num],
     975         2458 :                          (*oprnds_info)[i+1]->ops[stmt_num]);
     976              :               /* After swapping some operands we lost track whether an
     977              :                  operand has any pattern defs so be conservative here.  */
     978         2458 :               if ((*oprnds_info)[i]->any_pattern
     979         2458 :                   || (*oprnds_info)[i+1]->any_pattern)
     980           36 :                 (*oprnds_info)[i]->any_pattern
     981           18 :                   = (*oprnds_info)[i+1]->any_pattern = true;
     982         2458 :               swapped = true;
     983         2458 :               continue;
     984              :             }
     985              : 
     986       292042 :           if (is_a <bb_vec_info> (vinfo)
     987       276512 :               && !oprnd_info->any_pattern
     988       568318 :               && number_of_oprnds > 1)
     989              :             {
     990              :               /* Now for commutative ops we should see whether we can
     991              :                  make the other operand matching.  */
     992       105070 :               if (dump_enabled_p ())
     993          203 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
     994              :                                  "treating operand as external\n");
     995       105070 :               oprnd_info->first_dt = dt = vect_external_def;
     996              :             }
     997              :           else
     998              :             {
     999       186972 :               if (dump_enabled_p ())
    1000          411 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1001              :                                  "Build SLP failed: different types\n");
    1002       186972 :               return 1;
    1003              :             }
    1004              :         }
    1005              : 
    1006              :       /* Make sure to demote the overall operand to external.  */
    1007     16856629 :       if (dt == vect_external_def)
    1008       341166 :         oprnd_info->first_dt = vect_external_def;
    1009              :       /* For a SLP reduction chain we want to duplicate the reduction to
    1010              :          each of the chain members.  That gets us a sane SLP graph (still
    1011              :          the stmts are not 100% correct wrt the initial values).  */
    1012     16515463 :       else if ((dt == vect_internal_def
    1013     16515463 :                 || dt == vect_reduction_def)
    1014     15573795 :                && oprnd_info->first_dt == vect_reduction_def
    1015       101224 :                && !STMT_VINFO_DATA_REF (stmt_info)
    1016       101224 :                && REDUC_GROUP_FIRST_ELEMENT (stmt_info)
    1017         4769 :                && !STMT_VINFO_DATA_REF (def_stmt_info)
    1018     16520232 :                && (REDUC_GROUP_FIRST_ELEMENT (def_stmt_info)
    1019              :                    == REDUC_GROUP_FIRST_ELEMENT (stmt_info)))
    1020              :         {
    1021         4769 :           oprnd_info->def_stmts[stmt_num] = oprnd_info->def_stmts[0];
    1022         4769 :           oprnd_info->ops[stmt_num] = oprnd_info->ops[0];
    1023              :         }
    1024              : 
    1025     16856629 :       ++i;
    1026              :     }
    1027              : 
    1028              :   /* Swap operands.  */
    1029      9139049 :   if (swapped)
    1030              :     {
    1031        42312 :       if (dump_enabled_p ())
    1032          457 :         dump_printf_loc (MSG_NOTE, vect_location,
    1033              :                          "swapped operands to match def types in %G",
    1034              :                          stmt_info->stmt);
    1035              :     }
    1036              : 
    1037              :   return 0;
    1038              : }
    1039              : 
    1040              : /* Return true if call statements CALL1 and CALL2 are similar enough
    1041              :    to be combined into the same SLP group.  */
    1042              : 
    1043              : bool
    1044        21985 : compatible_calls_p (gcall *call1, gcall *call2, bool allow_two_operators)
    1045              : {
    1046        21985 :   unsigned int nargs = gimple_call_num_args (call1);
    1047        21985 :   if (nargs != gimple_call_num_args (call2))
    1048              :     return false;
    1049              : 
    1050        20034 :   auto cfn1 = gimple_call_combined_fn (call1);
    1051        20034 :   auto cfn2 = gimple_call_combined_fn (call2);
    1052        20034 :   if (cfn1 != cfn2
    1053            2 :       && (!allow_two_operators
    1054            2 :           || !((cfn1 == CFN_FMA || cfn1 == CFN_FMS)
    1055            2 :                && (cfn2 == CFN_FMA || cfn2 == CFN_FMS))))
    1056              :     return false;
    1057              : 
    1058        20034 :   if (gimple_call_internal_p (call1))
    1059              :     {
    1060         7033 :       if (!types_compatible_p (TREE_TYPE (gimple_call_lhs (call1)),
    1061         7033 :                                TREE_TYPE (gimple_call_lhs (call2))))
    1062              :         return false;
    1063        14480 :       for (unsigned int i = 0; i < nargs; ++i)
    1064         7447 :         if (!types_compatible_p (TREE_TYPE (gimple_call_arg (call1, i)),
    1065         7447 :                                  TREE_TYPE (gimple_call_arg (call2, i))))
    1066              :           return false;
    1067              :     }
    1068              :   else
    1069              :     {
    1070        13001 :       if (!operand_equal_p (gimple_call_fn (call1),
    1071        13001 :                             gimple_call_fn (call2), 0))
    1072              :         return false;
    1073              : 
    1074        29088 :       if (gimple_call_fntype (call1) != gimple_call_fntype (call2))
    1075              :         return false;
    1076              :     }
    1077              : 
    1078              :   /* Check that any unvectorized arguments are equal.  */
    1079        16729 :   if (const int *map = vect_get_operand_map (call1, false, false))
    1080              :     {
    1081           15 :       unsigned int nkept = *map++;
    1082           15 :       unsigned int mapi = 0;
    1083           57 :       for (unsigned int i = 0; i < nargs; ++i)
    1084           42 :         if (mapi < nkept && map[mapi] == int (i))
    1085           27 :           mapi += 1;
    1086           15 :         else if (!operand_equal_p (gimple_call_arg (call1, i),
    1087           15 :                                    gimple_call_arg (call2, i)))
    1088              :           return false;
    1089              :     }
    1090              : 
    1091              :   return true;
    1092              : }
    1093              : 
    1094              : /* A subroutine of vect_build_slp_tree for checking VECTYPE, which is the
    1095              :    caller's attempt to find the vector type in STMT_INFO with the narrowest
    1096              :    element type.  Return true if VECTYPE is nonnull and if it is valid
    1097              :    for STMT_INFO.  When returning true, update MAX_NUNITS to reflect the
    1098              :    number of units in VECTYPE.  GROUP_SIZE and MAX_NUNITS are as for
    1099              :    vect_build_slp_tree.  */
    1100              : 
    1101              : static bool
    1102      5620401 : vect_record_max_nunits (vec_info *vinfo, stmt_vec_info stmt_info,
    1103              :                         unsigned int group_size,
    1104              :                         tree vectype, poly_uint64 *max_nunits)
    1105              : {
    1106      5620401 :   if (!vectype)
    1107              :     {
    1108         4057 :       if (dump_enabled_p ())
    1109            7 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1110              :                          "Build SLP failed: unsupported data-type in %G\n",
    1111              :                          stmt_info->stmt);
    1112              :       /* Fatal mismatch.  */
    1113         4057 :       return false;
    1114              :     }
    1115              : 
    1116              :   /* If populating the vector type requires unrolling then fail
    1117              :      before adjusting *max_nunits for basic-block vectorization.  */
    1118      5616344 :   if (is_a <bb_vec_info> (vinfo)
    1119      5616344 :       && !multiple_p (group_size, TYPE_VECTOR_SUBPARTS (vectype)))
    1120              :     {
    1121       146140 :       if (dump_enabled_p ())
    1122           36 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1123              :                          "Build SLP failed: unrolling required "
    1124              :                          "in basic block SLP\n");
    1125              :       /* Fatal mismatch.  */
    1126       146140 :       return false;
    1127              :     }
    1128              : 
    1129              :   /* In case of multiple types we need to detect the smallest type.  */
    1130      5470204 :   vect_update_max_nunits (max_nunits, vectype);
    1131      5470204 :   return true;
    1132              : }
    1133              : 
    1134              : /* Verify if the scalar stmts STMTS are isomorphic, require data
    1135              :    permutation or are of unsupported types of operation.  Return
    1136              :    true if they are, otherwise return false and indicate in *MATCHES
    1137              :    which stmts are not isomorphic to the first one.  If MATCHES[0]
    1138              :    is false then this indicates the comparison could not be
    1139              :    carried out or the stmts will never be vectorized by SLP.
    1140              : 
    1141              :    Note COND_EXPR is possibly isomorphic to another one after swapping its
    1142              :    operands.  Set SWAP[i] to 1 if stmt I is COND_EXPR and isomorphic to
    1143              :    the first stmt by swapping the two operands of comparison; set SWAP[i]
    1144              :    to 2 if stmt I is isormorphic to the first stmt by inverting the code
    1145              :    of comparison.  Take A1 >= B1 ? X1 : Y1 as an example, it can be swapped
    1146              :    to (B1 <= A1 ? X1 : Y1); or be inverted to (A1 < B1) ? Y1 : X1.  */
    1147              : 
    1148              : static bool
    1149      5894532 : vect_build_slp_tree_1 (vec_info *vinfo, unsigned char *swap,
    1150              :                        vec<stmt_vec_info> stmts,
    1151              :                        poly_uint64 *max_nunits, bool *matches,
    1152              :                        bool *two_operators, tree *node_vectype)
    1153              : {
    1154      5894532 :   unsigned int group_size = stmts.length ();
    1155      5894532 :   unsigned int i;
    1156      5894532 :   stmt_vec_info first_stmt_info = stmts[0];
    1157      5894532 :   code_helper first_stmt_code = ERROR_MARK;
    1158      5894532 :   code_helper alt_stmt_code = ERROR_MARK;
    1159      5894532 :   code_helper first_cond_code = ERROR_MARK;
    1160      5894532 :   bool need_same_oprnds = false;
    1161      5894532 :   tree first_lhs = NULL_TREE;
    1162      5894532 :   tree first_op1 = NULL_TREE;
    1163      5894532 :   stmt_vec_info first_load = NULL, prev_first_load = NULL;
    1164      5894532 :   bool first_stmt_ldst_p = false, first_stmt_ldst_masklen_p = false;
    1165      5894532 :   bool first_stmt_phi_p = false;
    1166      5894532 :   int first_reduc_idx = -1;
    1167      5894532 :   bool maybe_soft_fail = false;
    1168      5894532 :   tree soft_fail_nunits_vectype = NULL_TREE;
    1169              : 
    1170      5894532 :   tree vectype, nunits_vectype;
    1171      5894532 :   if (!vect_get_vector_types_for_stmt (vinfo, first_stmt_info, &vectype,
    1172              :                                        &nunits_vectype, group_size))
    1173              :     {
    1174              :       /* Fatal mismatch.  */
    1175       210989 :       matches[0] = false;
    1176       210989 :       return false;
    1177              :     }
    1178      5683543 :   if (is_a <bb_vec_info> (vinfo)
    1179      5683543 :       && known_le (TYPE_VECTOR_SUBPARTS (vectype), 1U))
    1180              :     {
    1181       366826 :       if (dump_enabled_p ())
    1182          298 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1183              :                          "Build SLP failed: not using single lane "
    1184              :                          "vector type %T\n", vectype);
    1185       366826 :       matches[0] = false;
    1186       366826 :       return false;
    1187              :     }
    1188              :   /* Record nunits required but continue analysis, producing matches[]
    1189              :      as if nunits was not an issue.  This allows splitting of groups
    1190              :      to happen.  */
    1191      5316717 :   if (nunits_vectype
    1192      5316717 :       && !vect_record_max_nunits (vinfo, first_stmt_info, group_size,
    1193              :                                   nunits_vectype, max_nunits))
    1194              :     {
    1195       146140 :       gcc_assert (is_a <bb_vec_info> (vinfo));
    1196       146140 :       maybe_soft_fail = true;
    1197       146140 :       soft_fail_nunits_vectype = nunits_vectype;
    1198              :     }
    1199              : 
    1200      5316717 :   gcc_assert (vectype || !gimple_get_lhs (first_stmt_info->stmt));
    1201      5316717 :   *node_vectype = vectype;
    1202              : 
    1203              :   /* For every stmt in NODE find its def stmt/s.  */
    1204      5316717 :   stmt_vec_info stmt_info;
    1205     22524050 :   FOR_EACH_VEC_ELT (stmts, i, stmt_info)
    1206              :     {
    1207     17374183 :       bool ldst_p = false;
    1208     17374183 :       bool ldst_masklen_p = false;
    1209     17374183 :       bool phi_p = false;
    1210     17374183 :       code_helper rhs_code = ERROR_MARK;
    1211              : 
    1212     17374183 :       swap[i] = 0;
    1213     17374183 :       matches[i] = false;
    1214     17374183 :       if (!stmt_info)
    1215              :         {
    1216        40709 :           matches[i] = true;
    1217     17248042 :           continue;
    1218              :         }
    1219              : 
    1220     17333474 :       gimple *stmt = stmt_info->stmt;
    1221     17333474 :       if (dump_enabled_p ())
    1222       220090 :         dump_printf_loc (MSG_NOTE, vect_location, "Build SLP for %G", stmt);
    1223              : 
    1224              :       /* Fail to vectorize statements marked as unvectorizable, throw
    1225              :          or are volatile.  */
    1226     17333474 :       if (!STMT_VINFO_VECTORIZABLE (stmt_info)
    1227     17139799 :           || stmt_can_throw_internal (cfun, stmt)
    1228     33676091 :           || gimple_has_volatile_ops (stmt))
    1229              :         {
    1230       199182 :           if (dump_enabled_p ())
    1231          203 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1232              :                              "Build SLP failed: unvectorizable statement %G",
    1233              :                              stmt);
    1234              :           /* ???  For BB vectorization we want to commutate operands in a way
    1235              :              to shuffle all unvectorizable defs into one operand and have
    1236              :              the other still vectorized.  The following doesn't reliably
    1237              :              work for this though but it's the easiest we can do here.  */
    1238       199182 :           if (is_a <bb_vec_info> (vinfo) && i != 0)
    1239        65923 :             continue;
    1240              :           /* Fatal mismatch.  */
    1241       133259 :           matches[0] = false;
    1242       133259 :           return false;
    1243              :         }
    1244              : 
    1245     17134292 :       gcall *call_stmt = dyn_cast <gcall *> (stmt);
    1246     17134292 :       tree lhs = gimple_get_lhs (stmt);
    1247     17134292 :       if (lhs == NULL_TREE && !call_stmt)
    1248              :         {
    1249           36 :           if (dump_enabled_p ())
    1250            0 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1251              :                              "Build SLP failed: not GIMPLE_ASSIGN nor "
    1252              :                              "GIMPLE_CALL %G", stmt);
    1253           36 :           if (is_a <bb_vec_info> (vinfo) && i != 0)
    1254           36 :             continue;
    1255              :           /* Fatal mismatch.  */
    1256            0 :           matches[0] = false;
    1257            0 :           return false;
    1258              :         }
    1259              : 
    1260     17134256 :       if (call_stmt)
    1261              :         {
    1262       102453 :           combined_fn cfn = gimple_call_combined_fn (call_stmt);
    1263       102453 :           if (cfn != CFN_LAST && cfn != CFN_MASK_CALL)
    1264        56996 :             rhs_code = cfn;
    1265              :           else
    1266              :             rhs_code = CALL_EXPR;
    1267              : 
    1268       102453 :           if (cfn == CFN_GATHER_LOAD
    1269       102453 :               || cfn == CFN_SCATTER_STORE)
    1270              :             ldst_p = true;
    1271              :           else if (cfn == CFN_MASK_LOAD
    1272              :                    || cfn == CFN_MASK_GATHER_LOAD
    1273              :                    || cfn == CFN_MASK_LEN_GATHER_LOAD
    1274              :                    || cfn == CFN_MASK_SCATTER_STORE
    1275              :                    || cfn == CFN_MASK_LEN_SCATTER_STORE)
    1276              :             {
    1277              :               ldst_p = true;
    1278              :               ldst_masklen_p = true;
    1279              :             }
    1280              :           else if (cfn == CFN_MASK_STORE)
    1281              :             {
    1282              :               ldst_p = true;
    1283              :               ldst_masklen_p = true;
    1284              :               rhs_code = CFN_MASK_STORE;
    1285              :             }
    1286              :           else if (cfn == CFN_GOMP_SIMD_LANE)
    1287              :             ;
    1288        91125 :           else if ((cfn != CFN_LAST
    1289              :                     && cfn != CFN_MASK_CALL
    1290        45668 :                     && internal_fn_p (cfn)
    1291        37092 :                     && !vectorizable_internal_fn_p (as_internal_fn (cfn)))
    1292        91050 :                    || gimple_call_tail_p (call_stmt)
    1293        91050 :                    || gimple_call_noreturn_p (call_stmt)
    1294       182175 :                    || gimple_call_chain (call_stmt))
    1295              :             {
    1296          424 :               if (dump_enabled_p ())
    1297           13 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1298              :                                  "Build SLP failed: unsupported call type %G",
    1299              :                                  (gimple *) call_stmt);
    1300          424 :               if (is_a <bb_vec_info> (vinfo) && i != 0)
    1301           64 :                 continue;
    1302              :               /* Fatal mismatch.  */
    1303          360 :               matches[0] = false;
    1304          360 :               return false;
    1305              :             }
    1306              :         }
    1307     17031803 :       else if (gimple_code (stmt) == GIMPLE_PHI)
    1308              :         {
    1309              :           rhs_code = ERROR_MARK;
    1310              :           phi_p = true;
    1311              :         }
    1312              :       else
    1313              :         {
    1314     16234621 :           rhs_code = gimple_assign_rhs_code (stmt);
    1315     16234621 :           ldst_p = STMT_VINFO_DATA_REF (stmt_info) != nullptr;
    1316              :         }
    1317              : 
    1318              :       /* Check the operation.  */
    1319     17133832 :       if (i == 0)
    1320              :         {
    1321      5183098 :           first_lhs = lhs;
    1322      5183098 :           first_stmt_code = rhs_code;
    1323      5183098 :           first_stmt_ldst_p = ldst_p;
    1324      5183098 :           first_stmt_ldst_masklen_p = ldst_masklen_p;
    1325      5183098 :           first_stmt_phi_p = phi_p;
    1326      5183098 :           first_reduc_idx = STMT_VINFO_REDUC_IDX (stmt_info);
    1327              : 
    1328              :           /* Shift arguments should be equal in all the packed stmts for a
    1329              :              vector shift with scalar shift operand.  */
    1330      5183098 :           if (rhs_code == LSHIFT_EXPR || rhs_code == RSHIFT_EXPR
    1331      5048242 :               || rhs_code == LROTATE_EXPR
    1332     10231268 :               || rhs_code == RROTATE_EXPR)
    1333              :             {
    1334              :               /* First see if we have a vector/vector shift.  */
    1335       135311 :               if (!directly_supported_p (rhs_code, vectype, optab_vector))
    1336              :                 {
    1337              :                   /* No vector/vector shift, try for a vector/scalar shift.  */
    1338       123296 :                   if (!directly_supported_p (rhs_code, vectype, optab_scalar))
    1339              :                     {
    1340        11915 :                       if (dump_enabled_p ())
    1341          386 :                         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1342              :                                          "Build SLP failed: "
    1343              :                                          "op not supported by target.\n");
    1344        11915 :                       if (is_a <bb_vec_info> (vinfo) && i != 0)
    1345              :                         continue;
    1346              :                       /* Fatal mismatch.  */
    1347        11915 :                       matches[0] = false;
    1348        11915 :                       return false;
    1349              :                     }
    1350       111381 :                   need_same_oprnds = true;
    1351       111381 :                   first_op1 = gimple_assign_rhs2 (stmt);
    1352              :                 }
    1353              :             }
    1354      5047787 :           else if (rhs_code == WIDEN_LSHIFT_EXPR)
    1355              :             {
    1356            0 :               need_same_oprnds = true;
    1357            0 :               first_op1 = gimple_assign_rhs2 (stmt);
    1358              :             }
    1359      5047787 :           else if (!ldst_p
    1360      5047787 :                    && rhs_code == BIT_FIELD_REF)
    1361              :             {
    1362         5590 :               tree vec = TREE_OPERAND (gimple_assign_rhs1 (stmt), 0);
    1363         5590 :               if (!is_a <bb_vec_info> (vinfo)
    1364         5464 :                   || TREE_CODE (vec) != SSA_NAME
    1365              :                   /* When the element types are not compatible we pun the
    1366              :                      source to the target vectype which requires equal size.  */
    1367        11042 :                   || ((!VECTOR_TYPE_P (TREE_TYPE (vec))
    1368         4741 :                        || !types_compatible_p (TREE_TYPE (vectype),
    1369         4741 :                                                TREE_TYPE (TREE_TYPE (vec))))
    1370         1006 :                       && !operand_equal_p (TYPE_SIZE (vectype),
    1371         1006 :                                            TYPE_SIZE (TREE_TYPE (vec)))))
    1372              :                 {
    1373          757 :                   if (dump_enabled_p ())
    1374            0 :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1375              :                                      "Build SLP failed: "
    1376              :                                      "BIT_FIELD_REF not supported\n");
    1377              :                   /* Fatal mismatch.  */
    1378          757 :                   matches[0] = false;
    1379          757 :                   return false;
    1380              :                 }
    1381              :             }
    1382      5042197 :           else if (rhs_code == CFN_DIV_POW2)
    1383              :             {
    1384            0 :               need_same_oprnds = true;
    1385            0 :               first_op1 = gimple_call_arg (call_stmt, 1);
    1386              :             }
    1387      5042197 :           else if (rhs_code == CFN_GOMP_SIMD_LANE)
    1388              :             {
    1389         3147 :               need_same_oprnds = true;
    1390         3147 :               first_op1 = gimple_call_arg (call_stmt, 1);
    1391              :             }
    1392              :         }
    1393              :       else
    1394              :         {
    1395     11950734 :           int comm_arg;
    1396     11951112 :           if (first_reduc_idx != STMT_VINFO_REDUC_IDX (stmt_info)
    1397              :               /* For SLP reduction groups the index isn't necessarily
    1398              :                  uniform but only that of the first stmt matters.  */
    1399         2334 :               && !(first_reduc_idx != -1
    1400         2334 :                    && STMT_VINFO_REDUC_IDX (stmt_info) != -1
    1401         2334 :                    && REDUC_GROUP_FIRST_ELEMENT (stmt_info))
    1402     11950734 :               && !(first_reduc_idx != -1
    1403         1049 :                    && STMT_VINFO_REDUC_IDX (stmt_info) != -1
    1404         1049 :                    && (comm_arg = first_commutative_argument
    1405         1049 :                                     (rhs_code, TREE_TYPE (lhs))) >= 0
    1406              :                    && (first_reduc_idx
    1407          815 :                        == 2 * comm_arg + 1 - STMT_VINFO_REDUC_IDX (stmt_info))))
    1408              :             {
    1409          378 :               if (dump_enabled_p ())
    1410              :                 {
    1411           12 :                   dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1412              :                                    "Build SLP failed: different reduc_idx "
    1413              :                                    "%d instead of %d in %G",
    1414              :                                    STMT_VINFO_REDUC_IDX (stmt_info),
    1415              :                                    first_reduc_idx, stmt);
    1416              :                 }
    1417              :               /* Mismatch.  */
    1418          378 :               continue;
    1419              :             }
    1420     11950356 :           if (!ldst_p
    1421      9358902 :               && first_stmt_code != rhs_code
    1422     13388747 :               && alt_stmt_code == ERROR_MARK)
    1423              :             alt_stmt_code = rhs_code;
    1424     13363848 :           if ((!ldst_p
    1425      9358902 :                && first_stmt_code != rhs_code
    1426      1438391 :                && (first_stmt_code != IMAGPART_EXPR
    1427          128 :                    || rhs_code != REALPART_EXPR)
    1428      1438371 :                && (first_stmt_code != REALPART_EXPR
    1429          532 :                    || rhs_code != IMAGPART_EXPR)
    1430              :                /* Handle mismatches in plus/minus by computing both
    1431              :                   and merging the results.  */
    1432      1438360 :                && !((((first_stmt_code == PLUS_EXPR
    1433      1324830 :                        || first_stmt_code == MINUS_EXPR)
    1434       140667 :                       && (alt_stmt_code == PLUS_EXPR
    1435       132090 :                           || alt_stmt_code == MINUS_EXPR))
    1436      1409341 :                      || ((first_stmt_code == CFN_FMA
    1437      1409339 :                           || first_stmt_code == CFN_FMS)
    1438            2 :                          && (alt_stmt_code == CFN_FMA
    1439            2 :                              || alt_stmt_code == CFN_FMS)))
    1440        29021 :                     && rhs_code == alt_stmt_code)
    1441      1451014 :                && !(first_stmt_code.is_tree_code ()
    1442      1334654 :                     && rhs_code.is_tree_code ()
    1443      1239131 :                     && (TREE_CODE_CLASS (tree_code (first_stmt_code))
    1444              :                         == tcc_comparison)
    1445       135764 :                     && (swap_tree_comparison (tree_code (first_stmt_code))
    1446       135764 :                         == tree_code (rhs_code))
    1447              :                     && (first_reduc_idx == -1
    1448            0 :                         || REDUC_GROUP_FIRST_ELEMENT (stmt_info))))
    1449              :               || (ldst_p
    1450      5182908 :                   && (STMT_VINFO_GROUPED_ACCESS (stmt_info)
    1451      2591454 :                       != STMT_VINFO_GROUPED_ACCESS (first_stmt_info)))
    1452              :               || (ldst_p
    1453      2546142 :                   && (STMT_VINFO_GATHER_SCATTER_P (stmt_info)
    1454      2546142 :                       != STMT_VINFO_GATHER_SCATTER_P (first_stmt_info)))
    1455     10537015 :               || first_stmt_ldst_p != ldst_p
    1456     10536872 :               || (ldst_p && first_stmt_ldst_masklen_p != ldst_masklen_p)
    1457     22487220 :               || first_stmt_phi_p != phi_p)
    1458              :             {
    1459      1413492 :               if (dump_enabled_p ())
    1460              :                 {
    1461         3133 :                   dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1462              :                                    "Build SLP failed: different operation "
    1463              :                                    "in stmt %G", stmt);
    1464         3133 :                   dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1465              :                                    "original stmt %G", first_stmt_info->stmt);
    1466              :                 }
    1467              :               /* Mismatch.  */
    1468      1413492 :               continue;
    1469              :             }
    1470              : 
    1471     10538899 :           if (!ldst_p
    1472      7990857 :               && first_stmt_code == BIT_FIELD_REF
    1473     10542081 :               && (TREE_OPERAND (gimple_assign_rhs1 (first_stmt_info->stmt), 0)
    1474         5217 :                   != TREE_OPERAND (gimple_assign_rhs1 (stmt_info->stmt), 0)))
    1475              :             {
    1476         2035 :               if (dump_enabled_p ())
    1477           40 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1478              :                                  "Build SLP failed: different BIT_FIELD_REF "
    1479              :                                  "arguments in %G", stmt);
    1480              :               /* Mismatch.  */
    1481         2035 :               continue;
    1482              :             }
    1483              : 
    1484     10534829 :           if (call_stmt
    1485        22698 :               && first_stmt_code != CFN_MASK_LOAD
    1486     10557125 :               && first_stmt_code != CFN_MASK_STORE)
    1487              :             {
    1488        21985 :               if (!is_a <gcall *> (stmts[0]->stmt)
    1489        21985 :                   || !compatible_calls_p (as_a <gcall *> (stmts[0]->stmt),
    1490              :                                           call_stmt, true))
    1491              :                 {
    1492         5256 :                   if (dump_enabled_p ())
    1493            0 :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1494              :                                      "Build SLP failed: different calls in %G",
    1495              :                                      stmt);
    1496              :                   /* Mismatch.  */
    1497         5256 :                   continue;
    1498              :                 }
    1499              :             }
    1500              : 
    1501     10343083 :           if ((phi_p || gimple_could_trap_p (stmt_info->stmt))
    1502     11338176 :               && (gimple_bb (first_stmt_info->stmt)
    1503       995093 :                   != gimple_bb (stmt_info->stmt)))
    1504              :             {
    1505        28425 :               if (dump_enabled_p ())
    1506            8 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1507              :                                  "Build SLP failed: different BB for PHI "
    1508              :                                  "or possibly trapping operation in %G", stmt);
    1509              :               /* Mismatch.  */
    1510        28425 :               continue;
    1511              :             }
    1512              : 
    1513     10501148 :           if (need_same_oprnds)
    1514              :             {
    1515        55114 :               tree other_op1 = gimple_arg (stmt, 1);
    1516        55114 :               if (!operand_equal_p (first_op1, other_op1, 0))
    1517              :                 {
    1518         6329 :                   if (dump_enabled_p ())
    1519          123 :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1520              :                                      "Build SLP failed: different shift "
    1521              :                                      "arguments in %G", stmt);
    1522              :                   /* Mismatch.  */
    1523         6329 :                   continue;
    1524              :                 }
    1525              :             }
    1526              : 
    1527     10495556 :           if (first_lhs
    1528     10494819 :               && lhs
    1529     10494819 :               && !types_compatible_p (TREE_TYPE (lhs), TREE_TYPE (first_lhs)))
    1530              :             {
    1531          737 :               if (dump_enabled_p ())
    1532            6 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1533              :                                  "Build SLP failed: different vector type "
    1534              :                                  "in %G", stmt);
    1535              :               /* Mismatch.  */
    1536          737 :               continue;
    1537              :             }
    1538              :         }
    1539              : 
    1540              :       /* Grouped store or load.  */
    1541     15664508 :       if (STMT_VINFO_GROUPED_ACCESS (stmt_info))
    1542              :         {
    1543      3932609 :           gcc_assert (ldst_p);
    1544      3932609 :           if (DR_IS_WRITE (STMT_VINFO_DATA_REF (stmt_info)))
    1545              :             {
    1546              :               /* Store.  */
    1547      3083134 :               gcc_assert (rhs_code == CFN_MASK_STORE
    1548              :                           || REFERENCE_CLASS_P (lhs)
    1549              :                           || DECL_P (lhs));
    1550              :             }
    1551              :           else
    1552              :             {
    1553              :               /* Load.  */
    1554       849475 :               first_load = DR_GROUP_FIRST_ELEMENT (stmt_info);
    1555       849475 :               if (prev_first_load)
    1556              :                 {
    1557              :                   /* Check that there are no loads from different interleaving
    1558              :                      chains in the same node.  */
    1559       387529 :                   if (prev_first_load != first_load)
    1560              :                     {
    1561        55091 :                       if (dump_enabled_p ())
    1562         1998 :                         dump_printf_loc (MSG_MISSED_OPTIMIZATION,
    1563              :                                          vect_location,
    1564              :                                          "Build SLP failed: different "
    1565              :                                          "interleaving chains in one node %G",
    1566              :                                          stmt);
    1567              :                       /* Mismatch.  */
    1568        55091 :                       continue;
    1569              :                     }
    1570              :                 }
    1571              :               else
    1572              :                 prev_first_load = first_load;
    1573              :            }
    1574              :         }
    1575              :       /* Non-grouped store or load.  */
    1576     11731899 :       else if (ldst_p)
    1577              :         {
    1578       904521 :           if (DR_IS_READ (STMT_VINFO_DATA_REF (stmt_info))
    1579       631472 :               && rhs_code != CFN_GATHER_LOAD
    1580              :               && rhs_code != CFN_MASK_GATHER_LOAD
    1581              :               && rhs_code != CFN_MASK_LEN_GATHER_LOAD
    1582              :               && rhs_code != CFN_SCATTER_STORE
    1583              :               && rhs_code != CFN_MASK_SCATTER_STORE
    1584              :               && rhs_code != CFN_MASK_LEN_SCATTER_STORE
    1585       631472 :               && !STMT_VINFO_GATHER_SCATTER_P (stmt_info)
    1586              :               /* Not grouped loads are handled as externals for BB
    1587              :                  vectorization.  For loop vectorization we can handle
    1588              :                  splats the same we handle single element interleaving.
    1589              :                  Likewise we can handle a collection of invariant refs.  */
    1590      1517036 :               && (is_a <bb_vec_info> (vinfo)
    1591       612515 :                   || (stmt_info != first_stmt_info
    1592        68088 :                   && !(integer_zerop (DR_STEP (STMT_VINFO_DATA_REF (stmt_info)))
    1593          241 :                       && integer_zerop (DR_STEP (STMT_VINFO_DATA_REF
    1594              :                                                          (first_stmt_info)))))))
    1595              :             {
    1596              :               /* Not grouped load.  */
    1597        67606 :               if (dump_enabled_p ())
    1598          145 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1599              :                                  "Build SLP failed: not grouped load %G", stmt);
    1600              : 
    1601        67606 :               if (i != 0)
    1602        67606 :                 continue;
    1603              :               /* Fatal mismatch.  */
    1604            0 :               matches[0] = false;
    1605            0 :               return false;
    1606              :             }
    1607              :         }
    1608              :       /* Not memory operation.  */
    1609              :       else
    1610              :         {
    1611     10827378 :           if (!phi_p
    1612     10155438 :               && rhs_code.is_tree_code ()
    1613     10108289 :               && TREE_CODE_CLASS (tree_code (rhs_code)) != tcc_binary
    1614      1608886 :               && TREE_CODE_CLASS (tree_code (rhs_code)) != tcc_unary
    1615      1022017 :               && TREE_CODE_CLASS (tree_code (rhs_code)) != tcc_expression
    1616       960145 :               && TREE_CODE_CLASS (tree_code (rhs_code)) != tcc_comparison
    1617        68300 :               && rhs_code != VIEW_CONVERT_EXPR
    1618              :               && rhs_code != CALL_EXPR
    1619              :               && rhs_code != BIT_FIELD_REF
    1620     10827378 :               && rhs_code != SSA_NAME)
    1621              :             {
    1622        20559 :               if (dump_enabled_p ())
    1623            7 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1624              :                                  "Build SLP failed: operation unsupported %G",
    1625              :                                  stmt);
    1626        20559 :               if (is_a <bb_vec_info> (vinfo) && i != 0)
    1627            0 :                 continue;
    1628              :               /* Fatal mismatch.  */
    1629        20559 :               matches[0] = false;
    1630        20559 :               return false;
    1631              :             }
    1632              : 
    1633     10806819 :           if (rhs_code == COND_EXPR)
    1634              :             {
    1635        59022 :               tree cond_expr = gimple_assign_rhs1 (stmt);
    1636        59022 :               enum tree_code cond_code = TREE_CODE (cond_expr);
    1637        59022 :               enum tree_code swap_code = ERROR_MARK;
    1638        59022 :               enum tree_code invert_code = ERROR_MARK;
    1639              : 
    1640        59022 :               if (i == 0)
    1641        49834 :                 first_cond_code = TREE_CODE (cond_expr);
    1642         9188 :               else if (TREE_CODE_CLASS (cond_code) == tcc_comparison)
    1643              :                 {
    1644            0 :                   bool honor_nans = HONOR_NANS (TREE_OPERAND (cond_expr, 0));
    1645            0 :                   swap_code = swap_tree_comparison (cond_code);
    1646            0 :                   invert_code = invert_tree_comparison (cond_code, honor_nans);
    1647              :                 }
    1648              : 
    1649        59022 :               if (first_cond_code == cond_code)
    1650              :                 ;
    1651              :               /* Isomorphic can be achieved by swapping.  */
    1652            0 :               else if (first_cond_code == swap_code)
    1653            0 :                 swap[i] = 1;
    1654              :               /* Isomorphic can be achieved by inverting.  */
    1655            0 :               else if (first_cond_code == invert_code)
    1656            0 :                 swap[i] = 2;
    1657              :               else
    1658              :                 {
    1659            0 :                   if (dump_enabled_p ())
    1660            0 :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    1661              :                                      "Build SLP failed: different"
    1662              :                                      " operation %G", stmt);
    1663              :                   /* Mismatch.  */
    1664            0 :                   continue;
    1665              :                 }
    1666              :             }
    1667              : 
    1668     10806819 :           if (i != 0
    1669      7950125 :               && first_stmt_code != rhs_code
    1670        70350 :               && first_stmt_code.is_tree_code ()
    1671        70348 :               && rhs_code.is_tree_code ()
    1672        70348 :               && TREE_CODE_CLASS ((tree_code)first_stmt_code) == tcc_comparison
    1673     10848321 :               && (swap_tree_comparison ((tree_code)first_stmt_code)
    1674        41502 :                   == (tree_code)rhs_code))
    1675        41502 :             swap[i] = 1;
    1676              : 
    1677     10806819 :           if (i != 0
    1678      7950125 :               && first_reduc_idx != STMT_VINFO_REDUC_IDX (stmt_info)
    1679         1686 :               && first_reduc_idx != -1
    1680         1686 :               && STMT_VINFO_REDUC_IDX (stmt_info) != -1
    1681         1686 :               && rhs_code.is_tree_code ()
    1682         1678 :               && commutative_tree_code (tree_code (rhs_code))
    1683     10808495 :               && first_reduc_idx == 1 - STMT_VINFO_REDUC_IDX (stmt_info))
    1684         1676 :             swap[i] = 1;
    1685              :         }
    1686              : 
    1687     15521252 :       matches[i] = true;
    1688              :     }
    1689              : 
    1690     20678919 :   for (i = 0; i < group_size; ++i)
    1691     16242297 :     if (!matches[i])
    1692              :       return false;
    1693              : 
    1694              :   /* If we allowed a two-operation SLP node verify the target can cope
    1695              :      with the permute we are going to use.  */
    1696      4436622 :   if (alt_stmt_code != ERROR_MARK
    1697      4436622 :       && (!alt_stmt_code.is_tree_code ()
    1698        54430 :           || (TREE_CODE_CLASS (tree_code (alt_stmt_code)) != tcc_reference
    1699        54430 :               && TREE_CODE_CLASS (tree_code (alt_stmt_code)) != tcc_comparison)))
    1700              :     {
    1701        14501 :       *two_operators = true;
    1702              :     }
    1703              : 
    1704      4436622 :   if (maybe_soft_fail)
    1705              :     {
    1706       145703 :       unsigned HOST_WIDE_INT const_nunits;
    1707       145703 :       if (!TYPE_VECTOR_SUBPARTS
    1708       145703 :             (soft_fail_nunits_vectype).is_constant (&const_nunits)
    1709       145703 :           || const_nunits > group_size)
    1710            0 :         matches[0] = false;
    1711              :       else
    1712              :         {
    1713              :           /* With constant vector elements simulate a mismatch at the
    1714              :              point we need to split.  */
    1715       145703 :           unsigned tail = group_size & (const_nunits - 1);
    1716       145703 :           memset (&matches[group_size - tail], 0, sizeof (bool) * tail);
    1717              :         }
    1718       145703 :       return false;
    1719              :     }
    1720              : 
    1721              :   return true;
    1722              : }
    1723              : 
    1724              : /* Traits for the hash_set to record failed SLP builds for a stmt set.
    1725              :    Note we never remove apart from at destruction time so we do not
    1726              :    need a special value for deleted that differs from empty.  */
    1727              : struct bst_traits
    1728              : {
    1729              :   typedef vec <stmt_vec_info> value_type;
    1730              :   typedef vec <stmt_vec_info> compare_type;
    1731              :   static inline hashval_t hash (value_type);
    1732              :   static inline bool equal (value_type existing, value_type candidate);
    1733    488140062 :   static inline bool is_empty (value_type x) { return !x.exists (); }
    1734    109127264 :   static inline bool is_deleted (value_type x) { return !x.exists (); }
    1735              :   static const bool empty_zero_p = true;
    1736            0 :   static inline void mark_empty (value_type &x) { x.release (); }
    1737              :   static inline void mark_deleted (value_type &x) { x.release (); }
    1738      9405119 :   static inline void remove (value_type &x) { x.release (); }
    1739              : };
    1740              : inline hashval_t
    1741     95022915 : bst_traits::hash (value_type x)
    1742              : {
    1743     95022915 :   inchash::hash h;
    1744    428240820 :   for (unsigned i = 0; i < x.length (); ++i)
    1745    333217905 :     h.add_int (x[i] ? gimple_uid (x[i]->stmt) : -1);
    1746     95022915 :   return h.end ();
    1747              : }
    1748              : inline bool
    1749     83113409 : bst_traits::equal (value_type existing, value_type candidate)
    1750              : {
    1751    249340227 :   if (existing.length () != candidate.length ())
    1752              :     return false;
    1753     84415806 :   for (unsigned i = 0; i < existing.length (); ++i)
    1754     80024426 :     if (existing[i] != candidate[i])
    1755              :       return false;
    1756              :   return true;
    1757              : }
    1758              : 
    1759              : typedef hash_map <vec <stmt_vec_info>, slp_tree,
    1760              :                   simple_hashmap_traits <bst_traits, slp_tree> >
    1761              :   scalar_stmts_to_slp_tree_map_t;
    1762              : 
    1763              : /* Release BST_MAP.  */
    1764              : 
    1765              : static void
    1766      1838178 : release_scalar_stmts_to_slp_tree_map (scalar_stmts_to_slp_tree_map_t *bst_map)
    1767              : {
    1768              :   /* The map keeps a reference on SLP nodes built, release that.  */
    1769     11243297 :   for (scalar_stmts_to_slp_tree_map_t::iterator it = bst_map->begin ();
    1770     20648416 :        it != bst_map->end (); ++it)
    1771      9405119 :     if ((*it).second)
    1772      9405119 :       vect_free_slp_tree ((*it).second);
    1773      1838178 :   delete bst_map;
    1774      1838178 : }
    1775              : 
    1776              : /* ???  This was std::pair<std::pair<tree_code, vect_def_type>, tree>
    1777              :    but then vec::insert does memmove and that's not compatible with
    1778              :    std::pair.  */
    1779              : struct chain_op_t
    1780              : {
    1781      3832239 :   chain_op_t (tree_code code_, vect_def_type dt_, tree op_)
    1782      3832239 :       : code (code_), dt (dt_), op (op_) {}
    1783              :   tree_code code;
    1784              :   vect_def_type dt;
    1785              :   tree op;
    1786              : };
    1787              : 
    1788              : /* Comparator for sorting associatable chains.  */
    1789              : 
    1790              : static int
    1791      8512455 : dt_sort_cmp (const void *op1_, const void *op2_, void *)
    1792              : {
    1793      8512455 :   auto *op1 = (const chain_op_t *) op1_;
    1794      8512455 :   auto *op2 = (const chain_op_t *) op2_;
    1795      8512455 :   if (op1->dt != op2->dt)
    1796       955424 :     return (int)op1->dt - (int)op2->dt;
    1797      7557031 :   return (int)op1->code - (int)op2->code;
    1798              : }
    1799              : 
    1800              : /* Linearize the associatable expression chain at START with the
    1801              :    associatable operation CODE (where PLUS_EXPR also allows MINUS_EXPR),
    1802              :    filling CHAIN with the result and using WORKLIST as intermediate storage.
    1803              :    CODE_STMT and ALT_CODE_STMT are filled with the first stmt using CODE
    1804              :    or MINUS_EXPR.  *CHAIN_STMTS if not NULL is filled with all computation
    1805              :    stmts, starting with START.  When ALLOW_ALT_CODE is false, do not
    1806              :    follow into MINUS_EXPR when building a PLUS chain (treat MINUS as leaf).  */
    1807              : 
    1808              : static void
    1809      1736450 : vect_slp_linearize_chain (vec_info *vinfo,
    1810              :                           vec<std::pair<tree_code, gimple *> > &worklist,
    1811              :                           vec<chain_op_t> &chain,
    1812              :                           enum tree_code code, gimple *start,
    1813              :                           gimple *&code_stmt, gimple *&alt_code_stmt,
    1814              :                           vec<gimple *> *chain_stmts,
    1815              :                           bool allow_alt_code = true)
    1816              : {
    1817              :   /* For each lane linearize the addition/subtraction (or other
    1818              :      uniform associatable operation) expression tree.  */
    1819      1736450 :   worklist.safe_push (std::make_pair (code, start));
    1820      3832239 :   while (!worklist.is_empty ())
    1821              :     {
    1822      2095789 :       auto entry = worklist.pop ();
    1823      2095789 :       gassign *stmt = as_a <gassign *> (entry.second);
    1824      2095789 :       enum tree_code in_code = entry.first;
    1825      4191578 :       enum tree_code this_code = gimple_assign_rhs_code (stmt);
    1826              :       /* Pick some stmts suitable for SLP_TREE_REPRESENTATIVE.  */
    1827      2095789 :       if (!code_stmt
    1828      2095789 :           && gimple_assign_rhs_code (stmt) == code)
    1829      1477654 :         code_stmt = stmt;
    1830       618135 :       else if (!alt_code_stmt
    1831       618135 :                && gimple_assign_rhs_code (stmt) == MINUS_EXPR)
    1832       311579 :         alt_code_stmt = stmt;
    1833      2095789 :       if (chain_stmts)
    1834      2015008 :         chain_stmts->safe_push (stmt);
    1835      6287367 :       for (unsigned opnum = 1; opnum <= 2; ++opnum)
    1836              :         {
    1837      4191578 :           tree op = gimple_op (stmt, opnum);
    1838      4191578 :           vect_def_type dt;
    1839      4191578 :           stmt_vec_info def_stmt_info;
    1840      4191578 :           bool res = vect_is_simple_use (op, vinfo, &dt, &def_stmt_info);
    1841      4191578 :           gcc_assert (res);
    1842      4191578 :           if (dt == vect_internal_def
    1843      4191578 :               && is_pattern_stmt_p (def_stmt_info))
    1844         9019 :             op = gimple_get_lhs (def_stmt_info->stmt);
    1845      4191578 :           gimple *use_stmt;
    1846      4191578 :           use_operand_p use_p;
    1847      4191578 :           if (dt == vect_internal_def
    1848      3896056 :               && single_imm_use (op, &use_p, &use_stmt)
    1849      2449886 :               && is_gimple_assign (def_stmt_info->stmt)
    1850      6460382 :               && (gimple_assign_rhs_code (def_stmt_info->stmt) == code
    1851      1909780 :                   || (allow_alt_code
    1852        57047 :                       && code == PLUS_EXPR
    1853        36181 :                       && (gimple_assign_rhs_code (def_stmt_info->stmt)
    1854              :                           == MINUS_EXPR))))
    1855              :             {
    1856       359339 :               tree_code op_def_code = this_code;
    1857       359339 :               if (op_def_code == MINUS_EXPR && opnum == 1)
    1858        51070 :                 op_def_code = PLUS_EXPR;
    1859       359339 :               if (in_code == MINUS_EXPR)
    1860          135 :                 op_def_code = op_def_code == PLUS_EXPR ? MINUS_EXPR : PLUS_EXPR;
    1861       359339 :               worklist.safe_push (std::make_pair (op_def_code,
    1862       359339 :                                                   def_stmt_info->stmt));
    1863              :             }
    1864              :           else
    1865              :             {
    1866      3832239 :               tree_code op_def_code = this_code;
    1867      3832239 :               if (op_def_code == MINUS_EXPR && opnum == 1)
    1868       260626 :                 op_def_code = PLUS_EXPR;
    1869      3832239 :               if (in_code == MINUS_EXPR)
    1870         4017 :                 op_def_code = op_def_code == PLUS_EXPR ? MINUS_EXPR : PLUS_EXPR;
    1871      3832239 :               chain.safe_push (chain_op_t (op_def_code, dt, op));
    1872              :             }
    1873              :         }
    1874              :     }
    1875      1736450 : }
    1876              : 
    1877              : /* Distance from the node currently being discovered to the closest upthread
    1878              :    commutative operation whose operand-zero discovery may still be fixed by
    1879              :    retrying with swapped operands, or -1U if there is none.  */
    1880              : 
    1881              : static unsigned least_upthread_swappable_op_distance = -1U;
    1882              : 
    1883              : static slp_tree
    1884              : vect_build_slp_tree_2 (vec_info *vinfo, slp_tree node,
    1885              :                        vec<stmt_vec_info> stmts,
    1886              :                        poly_uint64 *max_nunits,
    1887              :                        bool *matches, unsigned *limit, unsigned *tree_size,
    1888              :                        scalar_stmts_to_slp_tree_map_t *bst_map);
    1889              : 
    1890              : static slp_tree
    1891      6380307 : vect_build_slp_tree (vec_info *vinfo,
    1892              :                      vec<stmt_vec_info> stmts,
    1893              :                      poly_uint64 *max_nunits,
    1894              :                      bool *matches, unsigned *limit, unsigned *tree_size,
    1895              :                      scalar_stmts_to_slp_tree_map_t *bst_map)
    1896              : {
    1897      6380307 :   unsigned int group_size = stmts.length ();
    1898      6380307 :   if (slp_tree *leader = bst_map->get (stmts))
    1899              :     {
    1900       480388 :       if (dump_enabled_p ())
    1901        17111 :         dump_printf_loc (MSG_NOTE, vect_location, "re-using %sSLP tree %p\n",
    1902        17111 :                          !(*leader)->failed ? "" : "failed ",
    1903              :                          (void *) *leader);
    1904       480388 :       if (!(*leader)->failed)
    1905              :         {
    1906       432649 :           SLP_TREE_REF_COUNT (*leader)++;
    1907       432649 :           vect_update_max_nunits (max_nunits, (*leader)->max_nunits);
    1908       432649 :           stmts.release ();
    1909       432649 :           return *leader;
    1910              :         }
    1911        47739 :       memcpy (matches, (*leader)->failed, sizeof (bool) * group_size);
    1912        47739 :       return NULL;
    1913              :     }
    1914              : 
    1915              :   /* Single-lane SLP doesn't have the chance of run-away, do not account
    1916              :      it to the limit.  */
    1917      5899919 :   if (stmts.length () > 1)
    1918              :     {
    1919      3275877 :       if (*limit == 0)
    1920              :         {
    1921         1238 :           if (dump_enabled_p ())
    1922           15 :             dump_printf_loc (MSG_NOTE, vect_location,
    1923              :                              "SLP discovery limit exceeded\n");
    1924         1238 :           memset (matches, 0, sizeof (bool) * group_size);
    1925         1238 :           return NULL;
    1926              :         }
    1927      3274639 :       --*limit;
    1928              :     }
    1929              : 
    1930              :   /* Seed the bst_map with a stub node to be filled by vect_build_slp_tree_2
    1931              :      so we can pick up backedge destinations during discovery.  */
    1932      5898681 :   slp_tree res = new _slp_tree;
    1933      5898681 :   SLP_TREE_DEF_TYPE (res) = vect_internal_def;
    1934      5898681 :   SLP_TREE_SCALAR_STMTS (res) = stmts;
    1935      5898681 :   bst_map->put (stmts.copy (), res);
    1936              : 
    1937      5898681 :   if (dump_enabled_p ())
    1938       146613 :     dump_printf_loc (MSG_NOTE, vect_location,
    1939              :                      "starting SLP discovery for node %p\n", (void *) res);
    1940              : 
    1941      5898681 :   poly_uint64 this_max_nunits = 1;
    1942      5898681 :   slp_tree res_ = vect_build_slp_tree_2 (vinfo, res, stmts,
    1943              :                                         &this_max_nunits,
    1944              :                                         matches, limit, tree_size, bst_map);
    1945      5898681 :   if (!res_)
    1946              :     {
    1947      2098446 :       if (dump_enabled_p ())
    1948         8494 :         dump_printf_loc (MSG_NOTE, vect_location,
    1949              :                          "SLP discovery for node %p failed\n", (void *) res);
    1950              :       /* Mark the node invalid so we can detect those when still in use
    1951              :          as backedge destinations.  */
    1952      2098446 :       SLP_TREE_SCALAR_STMTS (res) = vNULL;
    1953      2098446 :       SLP_TREE_DEF_TYPE (res) = vect_uninitialized_def;
    1954      2098446 :       res->failed = XNEWVEC (bool, group_size);
    1955      2098446 :       if (flag_checking)
    1956              :         {
    1957              :           unsigned i;
    1958      3737422 :           for (i = 0; i < group_size; ++i)
    1959      3737422 :             if (!matches[i])
    1960              :               break;
    1961      2098446 :           gcc_assert (i < group_size);
    1962              :         }
    1963      2098446 :       memcpy (res->failed, matches, sizeof (bool) * group_size);
    1964              :     }
    1965              :   else
    1966              :     {
    1967      3800235 :       if (dump_enabled_p ())
    1968       138119 :         dump_printf_loc (MSG_NOTE, vect_location,
    1969              :                          "SLP discovery for node %p succeeded\n",
    1970              :                          (void *) res);
    1971      3800235 :       gcc_assert (res_ == res);
    1972      3800235 :       res->max_nunits = this_max_nunits;
    1973      3800235 :       vect_update_max_nunits (max_nunits, this_max_nunits);
    1974              :       /* Keep a reference for the bst_map use.  */
    1975      3800235 :       SLP_TREE_REF_COUNT (res)++;
    1976              :     }
    1977              :   return res_;
    1978              : }
    1979              : 
    1980              : /* Helper for building an associated SLP node chain.  */
    1981              : 
    1982              : static void
    1983          158 : vect_slp_build_two_operator_nodes (slp_tree perm, tree vectype,
    1984              :                                    slp_tree op0, slp_tree op1,
    1985              :                                    stmt_vec_info oper1, stmt_vec_info oper2,
    1986              :                                    vec<std::pair<unsigned, unsigned> > lperm)
    1987              : {
    1988          158 :   unsigned group_size = SLP_TREE_LANES (op1);
    1989              : 
    1990          158 :   slp_tree child1 = new _slp_tree;
    1991          158 :   SLP_TREE_DEF_TYPE (child1) = vect_internal_def;
    1992          158 :   SLP_TREE_VECTYPE (child1) = vectype;
    1993          158 :   SLP_TREE_LANES (child1) = group_size;
    1994          158 :   SLP_TREE_CHILDREN (child1).create (2);
    1995          158 :   SLP_TREE_CHILDREN (child1).quick_push (op0);
    1996          158 :   SLP_TREE_CHILDREN (child1).quick_push (op1);
    1997          158 :   SLP_TREE_REPRESENTATIVE (child1) = oper1;
    1998              : 
    1999          158 :   slp_tree child2 = new _slp_tree;
    2000          158 :   SLP_TREE_DEF_TYPE (child2) = vect_internal_def;
    2001          158 :   SLP_TREE_VECTYPE (child2) = vectype;
    2002          158 :   SLP_TREE_LANES (child2) = group_size;
    2003          158 :   SLP_TREE_CHILDREN (child2).create (2);
    2004          158 :   SLP_TREE_CHILDREN (child2).quick_push (op0);
    2005          158 :   SLP_TREE_REF_COUNT (op0)++;
    2006          158 :   SLP_TREE_CHILDREN (child2).quick_push (op1);
    2007          158 :   SLP_TREE_REF_COUNT (op1)++;
    2008          158 :   SLP_TREE_REPRESENTATIVE (child2) = oper2;
    2009              : 
    2010          158 :   SLP_TREE_DEF_TYPE (perm) = vect_internal_def;
    2011          158 :   SLP_TREE_CODE (perm) = VEC_PERM_EXPR;
    2012          158 :   SLP_TREE_VECTYPE (perm) = vectype;
    2013          158 :   SLP_TREE_LANES (perm) = group_size;
    2014              :   /* ???  We should set this NULL but that's not expected.  */
    2015          158 :   SLP_TREE_REPRESENTATIVE (perm) = oper1;
    2016          158 :   SLP_TREE_LANE_PERMUTATION (perm) = lperm;
    2017          158 :   SLP_TREE_CHILDREN (perm).quick_push (child1);
    2018          158 :   SLP_TREE_CHILDREN (perm).quick_push (child2);
    2019          158 : }
    2020              : 
    2021              : /* Recursively build an SLP tree starting from NODE.
    2022              :    Fail (and return a value not equal to zero) if def-stmts are not
    2023              :    isomorphic, require data permutation or are of unsupported types of
    2024              :    operation.  Otherwise, return 0.
    2025              :    The value returned is the depth in the SLP tree where a mismatch
    2026              :    was found.  */
    2027              : 
    2028              : static slp_tree
    2029      5898681 : vect_build_slp_tree_2 (vec_info *vinfo, slp_tree node,
    2030              :                        vec<stmt_vec_info> stmts,
    2031              :                        poly_uint64 *max_nunits,
    2032              :                        bool *matches, unsigned *limit, unsigned *tree_size,
    2033              :                        scalar_stmts_to_slp_tree_map_t *bst_map)
    2034              : {
    2035      5898681 :   unsigned int group_size = stmts.length ();
    2036      5898681 :   unsigned nops, i, this_tree_size = 0;
    2037      5898681 :   poly_uint64 this_max_nunits = *max_nunits;
    2038              : 
    2039      5898681 :   matches[0] = false;
    2040              : 
    2041      5898681 :   stmt_vec_info stmt_info = stmts[0];
    2042      5898681 :   if (!is_a<gcall *> (stmt_info->stmt)
    2043              :       && !is_a<gassign *> (stmt_info->stmt)
    2044              :       && !is_a<gphi *> (stmt_info->stmt))
    2045              :     return NULL;
    2046              : 
    2047      5898595 :   nops = gimple_num_args (stmt_info->stmt);
    2048      5898595 :   if (const int *map = vect_get_operand_map (stmt_info))
    2049        35205 :     nops = map[0];
    2050              : 
    2051              :   /* If the SLP node is a PHI (induction or reduction), terminate
    2052              :      the recursion.  */
    2053      5898595 :   bool *skip_args = XALLOCAVEC (bool, nops);
    2054      5898595 :   memset (skip_args, 0, sizeof (bool) * nops);
    2055      5898595 :   if (loop_vec_info loop_vinfo = dyn_cast <loop_vec_info> (vinfo))
    2056      2821181 :     if (gphi *stmt = dyn_cast <gphi *> (stmt_info->stmt))
    2057              :       {
    2058       303704 :         tree scalar_type = TREE_TYPE (PHI_RESULT (stmt));
    2059       303704 :         tree vectype = get_vectype_for_scalar_type (vinfo, scalar_type,
    2060              :                                                     group_size);
    2061       303704 :         if (!vect_record_max_nunits (vinfo, stmt_info, group_size, vectype,
    2062              :                                      max_nunits))
    2063              :           return NULL;
    2064              : 
    2065       299647 :         vect_def_type def_type = STMT_VINFO_DEF_TYPE (stmt_info);
    2066       299647 :         if (def_type == vect_induction_def)
    2067              :           {
    2068              :             /* Induction PHIs are not cycles but walk the initial
    2069              :                value.  Only for inner loops through, for outer loops
    2070              :                we need to pick up the value from the actual PHIs
    2071              :                to more easily support peeling and epilogue vectorization.  */
    2072       193348 :             class loop *loop = LOOP_VINFO_LOOP (loop_vinfo);
    2073       193348 :             if (!nested_in_vect_loop_p (loop, stmt_info))
    2074       192524 :               skip_args[loop_preheader_edge (loop)->dest_idx] = true;
    2075              :             else
    2076              :               loop = loop->inner;
    2077       193348 :             skip_args[loop_latch_edge (loop)->dest_idx] = true;
    2078              :           }
    2079       106299 :         else if (def_type == vect_reduction_def
    2080              :                  || def_type == vect_double_reduction_def
    2081              :                  || def_type == vect_nested_cycle
    2082       106299 :                  || def_type == vect_first_order_recurrence)
    2083              :           {
    2084              :             /* Else def types have to match.  */
    2085              :             stmt_vec_info other_info;
    2086              :             bool all_same = true;
    2087       240806 :             FOR_EACH_VEC_ELT (stmts, i, other_info)
    2088              :               {
    2089       135821 :                 if (STMT_VINFO_DEF_TYPE (other_info) != def_type)
    2090      1840077 :                   return NULL;
    2091       135815 :                 if (other_info != stmt_info)
    2092        26231 :                   all_same = false;
    2093              :               }
    2094       104985 :             class loop *loop = LOOP_VINFO_LOOP (loop_vinfo);
    2095              :             /* Reduction initial values are not explicitly represented.  */
    2096       104985 :             if (def_type != vect_first_order_recurrence
    2097       104985 :                 && gimple_bb (stmt_info->stmt) == loop->header)
    2098       101820 :               skip_args[loop_preheader_edge (loop)->dest_idx] = true;
    2099              :             /* Reduction chain backedge defs are filled manually.
    2100              :                ???  Need a better way to identify a SLP reduction chain PHI.
    2101              :                Or a better overall way to SLP match those.  */
    2102       104985 :             if (stmts.length () > 1
    2103       104985 :                 && all_same && def_type == vect_reduction_def)
    2104         2354 :               skip_args[loop_latch_edge (loop)->dest_idx] = true;
    2105              :           }
    2106         1308 :         else if (def_type != vect_internal_def)
    2107              :           return NULL;
    2108              :       }
    2109              : 
    2110              : 
    2111      5894532 :   bool two_operators = false;
    2112      5894532 :   unsigned char *swap = XALLOCAVEC (unsigned char, group_size);
    2113      5894532 :   tree vectype = NULL_TREE;
    2114      5894532 :   if (!vect_build_slp_tree_1 (vinfo, swap, stmts,
    2115              :                               &this_max_nunits, matches, &two_operators,
    2116              :                               &vectype))
    2117              :     return NULL;
    2118              : 
    2119              :   /* If the SLP node is a load, terminate the recursion unless masked.  */
    2120      4290919 :   if (STMT_VINFO_DATA_REF (stmt_info)
    2121      2070563 :       && DR_IS_READ (STMT_VINFO_DATA_REF (stmt_info)))
    2122              :     {
    2123       920360 :       if (STMT_VINFO_GATHER_SCATTER_P (stmt_info))
    2124              :         gcc_assert (DR_IS_READ (STMT_VINFO_DATA_REF (stmt_info)));
    2125              :       else
    2126              :         {
    2127       901660 :           *max_nunits = this_max_nunits;
    2128       901660 :           (*tree_size)++;
    2129       901660 :           node = vect_create_new_slp_node (node, stmts, 0);
    2130       901660 :           SLP_TREE_VECTYPE (node) = vectype;
    2131              :           /* And compute the load permutation.  Whether it is actually
    2132              :              a permutation depends on the unrolling factor which is
    2133              :              decided later.  */
    2134       901660 :           vec<unsigned> load_permutation;
    2135       901660 :           int j;
    2136       901660 :           stmt_vec_info load_info;
    2137       901660 :           load_permutation.create (group_size);
    2138       901660 :           stmt_vec_info first_stmt_info
    2139       901660 :             = STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2140       901660 :               ? DR_GROUP_FIRST_ELEMENT (stmt_info) : stmt_info;
    2141       901660 :           bool any_permute = false;
    2142      2171241 :           FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), j, load_info)
    2143              :             {
    2144      1269581 :               int load_place;
    2145      1269581 :               if (! load_info)
    2146              :                 {
    2147        40469 :                   if (STMT_VINFO_GROUPED_ACCESS (stmt_info))
    2148              :                     load_place = j;
    2149              :                   else
    2150              :                     load_place = 0;
    2151              :                 }
    2152      1229112 :               else if (STMT_VINFO_GROUPED_ACCESS (stmt_info))
    2153       712331 :                 load_place = vect_get_place_in_interleaving_chain
    2154       712331 :                     (load_info, first_stmt_info);
    2155              :               else
    2156              :                 /* Recognize the splat case as { 0, 0, ... } but make
    2157              :                    sure to use the appropriate refs for collections
    2158              :                    of invariant refs.  */
    2159       516781 :                 load_place = (load_info == stmt_info) ? 0 : j;
    2160       753041 :               gcc_assert (load_place != -1);
    2161      1269581 :               any_permute |= load_place != j;
    2162      1269581 :               load_permutation.quick_push (load_place);
    2163              :             }
    2164              : 
    2165       901660 :           if (gcall *stmt = dyn_cast <gcall *> (stmt_info->stmt))
    2166              :             {
    2167         3386 :               gcc_assert (gimple_call_internal_p (stmt, IFN_MASK_LOAD));
    2168         3386 :               bool has_gaps = false;
    2169         3386 :               if (STMT_VINFO_GROUPED_ACCESS (stmt_info))
    2170          189 :                 for (stmt_vec_info si = DR_GROUP_NEXT_ELEMENT (first_stmt_info);
    2171          846 :                      si; si = DR_GROUP_NEXT_ELEMENT (si))
    2172          657 :                   if (DR_GROUP_GAP (si) != 1)
    2173           80 :                     has_gaps = true;
    2174              :               /* We cannot handle permuted masked loads directly, see
    2175              :                  PR114375.  We cannot handle strided masked loads or masked
    2176              :                  loads with gaps unless the mask is uniform.  */
    2177         3386 :               if ((STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2178          189 :                    && (DR_GROUP_GAP (first_stmt_info) != 0
    2179          129 :                        || (has_gaps
    2180           35 :                            && STMT_VINFO_SLP_VECT_ONLY (first_stmt_info))))
    2181         6692 :                   || STMT_VINFO_STRIDED_P (stmt_info))
    2182              :                 {
    2183           93 :                   load_permutation.release ();
    2184           93 :                   matches[0] = false;
    2185       898406 :                   return NULL;
    2186              :                 }
    2187              : 
    2188              :               /* For permuted masked loads do an unpermuted masked load of
    2189              :                  the whole group followed by a SLP permute node.  */
    2190         3293 :               if (any_permute
    2191         3293 :                   || (STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2192           83 :                       && DR_GROUP_SIZE (first_stmt_info) != group_size))
    2193              :                 {
    2194              :                   /* Discover the whole unpermuted load.  */
    2195           39 :                   vec<stmt_vec_info> stmts2;
    2196           39 :                   unsigned dr_group_size = STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2197           68 :                       ? DR_GROUP_SIZE (first_stmt_info) : 1;
    2198           39 :                   stmts2.create (dr_group_size);
    2199           39 :                   stmts2.quick_grow_cleared (dr_group_size);
    2200           39 :                   unsigned i = 0;
    2201           39 :                   for (stmt_vec_info si = first_stmt_info;
    2202          464 :                        si; si = DR_GROUP_NEXT_ELEMENT (si))
    2203              :                     {
    2204          425 :                       if (si != first_stmt_info)
    2205         1586 :                         for (unsigned k = 1; k < DR_GROUP_GAP (si); ++k)
    2206         1200 :                           stmts2[i++] = NULL;
    2207          425 :                       stmts2[i++] = si;
    2208              :                     }
    2209           39 :                   bool *matches2 = XALLOCAVEC (bool, dr_group_size);
    2210           39 :                   slp_tree unperm_load
    2211           39 :                     = vect_build_slp_tree (vinfo, stmts2,
    2212              :                                            &this_max_nunits, matches2, limit,
    2213           39 :                                            &this_tree_size, bst_map);
    2214              :                   /* When we are able to do the full masked load emit that
    2215              :                      followed by 'node' being the desired final permutation.  */
    2216           39 :                   if (unperm_load)
    2217              :                     {
    2218           16 :                       gcc_assert
    2219              :                         (!SLP_TREE_LOAD_PERMUTATION (unperm_load).exists ());
    2220           16 :                       lane_permutation_t lperm;
    2221           16 :                       lperm.create (group_size);
    2222           56 :                       for (unsigned j = 0; j < load_permutation.length (); ++j)
    2223           40 :                         lperm.quick_push
    2224           40 :                           (std::make_pair (0, load_permutation[j]));
    2225           16 :                       SLP_TREE_CODE (node) = VEC_PERM_EXPR;
    2226           16 :                       SLP_TREE_CHILDREN (node).safe_push (unperm_load);
    2227           16 :                       SLP_TREE_LANE_PERMUTATION (node) = lperm;
    2228           16 :                       load_permutation.release ();
    2229           16 :                       return node;
    2230              :                     }
    2231           23 :                   stmts2.release ();
    2232           23 :                   load_permutation.release ();
    2233           23 :                   matches[0] = false;
    2234           23 :                   return NULL;
    2235              :                 }
    2236         3254 :               load_permutation.release ();
    2237              :             }
    2238              :           else
    2239              :             {
    2240       898274 :               if (!any_permute
    2241       783256 :                   && STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2242      1190673 :                   && group_size == DR_GROUP_SIZE (first_stmt_info))
    2243       128135 :                 load_permutation.release ();
    2244       898274 :               SLP_TREE_LOAD_PERMUTATION (node) = load_permutation;
    2245       898274 :               return node;
    2246              :             }
    2247              :         }
    2248              :     }
    2249      3370559 :   else if (gimple_assign_single_p (stmt_info->stmt)
    2250      2304792 :            && !gimple_vuse (stmt_info->stmt)
    2251      3378265 :            && gimple_assign_rhs_code (stmt_info->stmt) == BIT_FIELD_REF)
    2252              :     {
    2253              :       /* vect_build_slp_tree_2 determined all BIT_FIELD_REFs reference
    2254              :          the same SSA name vector of a compatible type to vectype.  */
    2255         2245 :       vec<std::pair<unsigned, unsigned> > lperm = vNULL;
    2256         2245 :       tree vec = TREE_OPERAND (gimple_assign_rhs1 (stmt_info->stmt), 0);
    2257         2245 :       stmt_vec_info estmt_info;
    2258         7077 :       FOR_EACH_VEC_ELT (stmts, i, estmt_info)
    2259              :         {
    2260         4979 :           gassign *estmt = as_a <gassign *> (estmt_info->stmt);
    2261         4979 :           tree bfref = gimple_assign_rhs1 (estmt);
    2262         4979 :           HOST_WIDE_INT lane;
    2263         4979 :           if (!known_eq (bit_field_size (bfref),
    2264              :                          tree_to_poly_uint64 (TYPE_SIZE (TREE_TYPE (vectype))))
    2265         9811 :               || !constant_multiple_p (bit_field_offset (bfref),
    2266         4832 :                                        bit_field_size (bfref), &lane))
    2267              :             {
    2268          147 :               lperm.release ();
    2269          147 :               matches[0] = false;
    2270          147 :               return NULL;
    2271              :             }
    2272         4832 :           lperm.safe_push (std::make_pair (0, (unsigned)lane));
    2273              :         }
    2274         2098 :       slp_tree vnode = vect_create_new_slp_node (vNULL);
    2275         2098 :       if (operand_equal_p (TYPE_SIZE (vectype), TYPE_SIZE (TREE_TYPE (vec))))
    2276              :         /* ???  We record vectype here but we hide eventually necessary
    2277              :            punning and instead rely on code generation to materialize
    2278              :            VIEW_CONVERT_EXPRs as necessary.  We instead should make
    2279              :            this explicit somehow.  */
    2280          628 :         SLP_TREE_VECTYPE (vnode) = vectype;
    2281              :       else
    2282              :         {
    2283              :           /* For different size but compatible elements we can still
    2284              :              use VEC_PERM_EXPR without punning.  */
    2285         1470 :           gcc_assert (VECTOR_TYPE_P (TREE_TYPE (vec))
    2286              :                       && types_compatible_p (TREE_TYPE (vectype),
    2287              :                                              TREE_TYPE (TREE_TYPE (vec))));
    2288         1470 :           SLP_TREE_VECTYPE (vnode) = TREE_TYPE (vec);
    2289              :         }
    2290         2098 :       auto nunits = TYPE_VECTOR_SUBPARTS (SLP_TREE_VECTYPE (vnode));
    2291         2098 :       unsigned HOST_WIDE_INT const_nunits;
    2292         2098 :       if (nunits.is_constant (&const_nunits))
    2293         2098 :         SLP_TREE_LANES (vnode) = const_nunits;
    2294         2098 :       SLP_TREE_VEC_DEFS (vnode).safe_push (vec);
    2295              :       /* We are always building a permutation node even if it is an identity
    2296              :          permute to shield the rest of the vectorizer from the odd node
    2297              :          representing an actual vector without any scalar ops.
    2298              :          ???  We could hide it completely with making the permute node
    2299              :          external?  */
    2300         2098 :       node = vect_create_new_slp_node (node, stmts, 1);
    2301         2098 :       SLP_TREE_CODE (node) = VEC_PERM_EXPR;
    2302         2098 :       SLP_TREE_LANE_PERMUTATION (node) = lperm;
    2303         2098 :       SLP_TREE_VECTYPE (node) = vectype;
    2304         2098 :       SLP_TREE_CHILDREN (node).quick_push (vnode);
    2305         2098 :       return node;
    2306              :     }
    2307              :   /* When discovery reaches an associatable operation see whether we can
    2308              :      improve that to match up lanes in a way superior to the operand
    2309              :      swapping code which at most looks at two defs.
    2310              :      ???  For BB vectorization we cannot do the brute-force search
    2311              :      for matching as we can succeed by means of builds from scalars
    2312              :      and have no good way to "cost" one build against another.  */
    2313      3368314 :   else if (is_a <loop_vec_info> (vinfo)
    2314              :            /* Do not bother for single-lane SLP.  */
    2315      1988383 :            && group_size > 1
    2316              :            /* ???  We don't handle !vect_internal_def defs below.  */
    2317       112640 :            && STMT_VINFO_DEF_TYPE (stmt_info) == vect_internal_def
    2318              :            /* ???  Do not associate a reduction, this will wreck REDUC_IDX
    2319              :               mapping as long as that exists on the stmt_info level.  */
    2320        87124 :            && STMT_VINFO_REDUC_IDX (stmt_info) == -1
    2321        78584 :            && is_gimple_assign (stmt_info->stmt)
    2322        78268 :            && (associative_tree_code (gimple_assign_rhs_code (stmt_info->stmt))
    2323        51625 :                || gimple_assign_rhs_code (stmt_info->stmt) == MINUS_EXPR)
    2324      3396842 :            && ((FLOAT_TYPE_P (vectype) && flag_associative_math)
    2325        16273 :                || (INTEGRAL_TYPE_P (TREE_TYPE (vectype))
    2326        13742 :                    && TYPE_OVERFLOW_WRAPS (TREE_TYPE (vectype)))))
    2327              :     {
    2328              :       /* See if we have a chain of (mixed) adds or subtracts or other
    2329              :          associatable ops.  */
    2330        21555 :       enum tree_code code = gimple_assign_rhs_code (stmt_info->stmt);
    2331        21555 :       if (code == MINUS_EXPR)
    2332          799 :         code = PLUS_EXPR;
    2333        21555 :       stmt_vec_info other_op_stmt_info = NULL;
    2334        21555 :       stmt_vec_info op_stmt_info = NULL;
    2335        21555 :       unsigned chain_len = 0;
    2336        21555 :       auto_vec<chain_op_t> chain;
    2337        21555 :       auto_vec<std::pair<tree_code, gimple *> > worklist;
    2338        21555 :       auto_vec<vec<chain_op_t> > chains (group_size);
    2339        21555 :       auto_vec<slp_tree, 4> children;
    2340        21555 :       bool hard_fail = true;
    2341        22582 :       for (unsigned lane = 0; lane < group_size; ++lane)
    2342              :         {
    2343        22246 :           if (!stmts[lane])
    2344              :             {
    2345              :               /* ???  Below we require lane zero is present.  */
    2346            0 :               if (lane == 0)
    2347              :                 {
    2348              :                   hard_fail = false;
    2349        21219 :                   break;
    2350              :                 }
    2351            0 :               chains.quick_push (vNULL);
    2352            0 :               continue;
    2353              :             }
    2354              :           /* For each lane linearize the addition/subtraction (or other
    2355              :              uniform associatable operation) expression tree.  */
    2356        22246 :           gimple *op_stmt = NULL, *other_op_stmt = NULL;
    2357        22246 :           vect_slp_linearize_chain (vinfo, worklist, chain, code,
    2358        22246 :                                     stmts[lane]->stmt, op_stmt, other_op_stmt,
    2359              :                                     NULL);
    2360        22246 :           if (!op_stmt_info && op_stmt)
    2361        20953 :             op_stmt_info = vinfo->lookup_stmt (op_stmt);
    2362        22246 :           if (!other_op_stmt_info && other_op_stmt)
    2363          835 :             other_op_stmt_info = vinfo->lookup_stmt (other_op_stmt);
    2364        22246 :           if (chain.length () == 2)
    2365              :             {
    2366              :               /* In a chain of just two elements resort to the regular
    2367              :                  operand swapping scheme.  Likewise if we run into a
    2368              :                  length mismatch process regularly as well as we did not
    2369              :                  process the other lanes we cannot report a good hint what
    2370              :                  lanes to try swapping in the parent.  */
    2371              :               hard_fail = false;
    2372              :               break;
    2373              :             }
    2374         1030 :           else if (chain_len == 0)
    2375          376 :             chain_len = chain.length ();
    2376         1308 :           else if (chain.length () != chain_len)
    2377              :             {
    2378              :               /* ???  Here we could slip in magic to compensate with
    2379              :                  neutral operands.  */
    2380            3 :               matches[lane] = false;
    2381            3 :               if (lane != group_size - 1)
    2382            3 :                 matches[0] = false;
    2383              :               break;
    2384              :             }
    2385         1027 :           chains.quick_push (chain.copy ());
    2386         1027 :           chain.truncate (0);
    2387              :         }
    2388        43110 :       if (chains.length () == group_size)
    2389              :         {
    2390              :           /* We cannot yet use SLP_TREE_CODE to communicate the operation.  */
    2391          336 :           if (!op_stmt_info)
    2392              :             {
    2393            3 :               hard_fail = false;
    2394            3 :               goto out;
    2395              :             }
    2396              :           /* Now we have a set of chains with the same length.  */
    2397              :           /* 1. pre-sort according to def_type and operation.  */
    2398         1248 :           for (unsigned lane = 0; lane < group_size; ++lane)
    2399         1830 :             chains[lane].stablesort (dt_sort_cmp, vinfo);
    2400          333 :           if (dump_enabled_p ())
    2401              :             {
    2402          157 :               dump_printf_loc (MSG_NOTE, vect_location,
    2403              :                                "pre-sorted chains of %s\n",
    2404              :                                get_tree_code_name (code));
    2405          685 :               for (unsigned lane = 0; lane < group_size; ++lane)
    2406              :                 {
    2407          528 :                   if (!stmts[lane])
    2408            0 :                     dump_printf (MSG_NOTE, "--");
    2409              :                   else
    2410         2422 :                     for (unsigned opnum = 0; opnum < chain_len; ++opnum)
    2411         3788 :                       dump_printf (MSG_NOTE, "%s %T ",
    2412         1894 :                                    get_tree_code_name (chains[lane][opnum].code),
    2413         1894 :                                    chains[lane][opnum].op);
    2414          528 :                   dump_printf (MSG_NOTE, "\n");
    2415              :                 }
    2416              :             }
    2417              :           /* 2. try to build children nodes, associating as necessary.  */
    2418              :           /* 2a. prepare and perform early checks to avoid eating into
    2419              :              discovery limit unnecessarily.  */
    2420          333 :           vect_def_type *dts = XALLOCAVEC (vect_def_type, chain_len);
    2421         1407 :           for (unsigned n = 0; n < chain_len; ++n)
    2422              :             {
    2423         1074 :               vect_def_type dt = chains[0][n].dt;
    2424         1074 :               unsigned lane;
    2425         4177 :               for (lane = 0; lane < group_size; ++lane)
    2426         6206 :                 if (stmts[lane] && chains[lane][n].dt != dt)
    2427              :                   {
    2428            0 :                     if (dt == vect_constant_def
    2429            0 :                         && chains[lane][n].dt == vect_external_def)
    2430              :                       dt = vect_external_def;
    2431            0 :                     else if (dt == vect_external_def
    2432            0 :                              && chains[lane][n].dt == vect_constant_def)
    2433              :                       ;
    2434              :                     else
    2435              :                       break;
    2436              :                   }
    2437         1074 :               if (lane != group_size)
    2438              :                 {
    2439            0 :                   if (dump_enabled_p ())
    2440            0 :                     dump_printf_loc (MSG_NOTE, vect_location,
    2441              :                                      "giving up on chain due to mismatched "
    2442              :                                      "def types\n");
    2443            0 :                   matches[lane] = false;
    2444            0 :                   if (lane != group_size - 1)
    2445            0 :                     matches[0] = false;
    2446            0 :                   goto out;
    2447              :                 }
    2448         1074 :               dts[n] = dt;
    2449         1074 :               if (dt == vect_constant_def
    2450         1074 :                   || dt == vect_external_def)
    2451              :                 {
    2452              :                   /* Check whether we can build the invariant.  If we can't
    2453              :                      we never will be able to.  */
    2454           93 :                   tree type = TREE_TYPE (chains[0][n].op);
    2455         1074 :                   if (!GET_MODE_SIZE (vinfo->vector_mode).is_constant ()
    2456              :                       && (TREE_CODE (type) == BOOLEAN_TYPE
    2457              :                           || !can_duplicate_and_interleave_p (vinfo, group_size,
    2458              :                                                               type)))
    2459              :                     {
    2460              :                       matches[0] = false;
    2461              :                       goto out;
    2462              :                     }
    2463              :                 }
    2464          981 :               else if (dt != vect_internal_def)
    2465              :                 {
    2466              :                   /* Not sure, we might need sth special.
    2467              :                      gcc.dg/vect/pr96854.c,
    2468              :                      gfortran.dg/vect/fast-math-pr37021.f90
    2469              :                      and gfortran.dg/vect/pr61171.f trigger.  */
    2470              :                   /* Soft-fail for now.  */
    2471            0 :                   hard_fail = false;
    2472            0 :                   goto out;
    2473              :                 }
    2474              :             }
    2475              :           /* 2b. do the actual build.  */
    2476         1349 :           for (unsigned n = 0; n < chain_len; ++n)
    2477              :             {
    2478         1036 :               vect_def_type dt = dts[n];
    2479         1036 :               unsigned lane;
    2480         1036 :               if (dt == vect_constant_def
    2481         1036 :                   || dt == vect_external_def)
    2482              :                 {
    2483           93 :                   vec<tree> ops;
    2484           93 :                   ops.create (group_size);
    2485          461 :                   for (lane = 0; lane < group_size; ++lane)
    2486          275 :                     if (stmts[lane])
    2487          275 :                       ops.quick_push (chains[lane][n].op);
    2488              :                     else
    2489            0 :                       ops.quick_push (NULL_TREE);
    2490           93 :                   slp_tree child = vect_create_new_slp_node (ops);
    2491           93 :                   SLP_TREE_DEF_TYPE (child) = dt;
    2492           93 :                   children.safe_push (child);
    2493              :                 }
    2494              :               else
    2495              :                 {
    2496          943 :                   vec<stmt_vec_info> op_stmts;
    2497          943 :                   op_stmts.create (group_size);
    2498          943 :                   slp_tree child = NULL;
    2499              :                   /* Brute-force our way.  We have to consider a lane
    2500              :                      failing after fixing an earlier fail up in the
    2501              :                      SLP discovery recursion.  So track the current
    2502              :                      permute per lane.  */
    2503          943 :                   unsigned *perms = XALLOCAVEC (unsigned, group_size);
    2504          943 :                   memset (perms, 0, sizeof (unsigned) * group_size);
    2505         1037 :                   do
    2506              :                     {
    2507         1037 :                       op_stmts.truncate (0);
    2508         5080 :                       for (lane = 0; lane < group_size; ++lane)
    2509         3006 :                         if (stmts[lane])
    2510         3006 :                           op_stmts.quick_push
    2511         3006 :                             (vinfo->lookup_def (chains[lane][n].op));
    2512              :                         else
    2513            0 :                           op_stmts.quick_push (NULL);
    2514         1037 :                       child = vect_build_slp_tree (vinfo, op_stmts,
    2515              :                                                    &this_max_nunits,
    2516              :                                                    matches, limit,
    2517              :                                                    &this_tree_size, bst_map);
    2518              :                       /* ???  We're likely getting too many fatal mismatches
    2519              :                          here so maybe we want to ignore them (but then we
    2520              :                          have no idea which lanes fatally mismatched).  */
    2521         1037 :                       if (child || !matches[0])
    2522              :                         break;
    2523              :                       /* Swap another lane we have not yet matched up into
    2524              :                          lanes that did not match.  If we run out of
    2525              :                          permute possibilities for a lane terminate the
    2526              :                          search.  */
    2527          287 :                       bool term = false;
    2528          287 :                       for (lane = 1; lane < group_size; ++lane)
    2529          193 :                         if (!matches[lane])
    2530              :                           {
    2531          165 :                             if (n + perms[lane] + 1 == chain_len)
    2532              :                               {
    2533              :                                 term = true;
    2534              :                                 break;
    2535              :                               }
    2536          146 :                             if (dump_enabled_p ())
    2537          113 :                               dump_printf_loc (MSG_NOTE, vect_location,
    2538              :                                                "swapping operand %d and %d "
    2539              :                                                "of lane %d\n",
    2540              :                                                n, n + perms[lane] + 1, lane);
    2541          292 :                             std::swap (chains[lane][n],
    2542          146 :                                        chains[lane][n + perms[lane] + 1]);
    2543          146 :                             perms[lane]++;
    2544              :                           }
    2545          113 :                       if (term)
    2546              :                         break;
    2547              :                     }
    2548              :                   while (1);
    2549          943 :                   if (!child)
    2550              :                     {
    2551           20 :                       if (dump_enabled_p ())
    2552           18 :                         dump_printf_loc (MSG_NOTE, vect_location,
    2553              :                                          "failed to match up op %d\n", n);
    2554           20 :                       op_stmts.release ();
    2555           20 :                       if (lane != group_size - 1)
    2556           10 :                         matches[0] = false;
    2557              :                       else
    2558           10 :                         matches[lane] = false;
    2559           20 :                       goto out;
    2560              :                     }
    2561          923 :                   if (dump_enabled_p ())
    2562              :                     {
    2563          421 :                       dump_printf_loc (MSG_NOTE, vect_location,
    2564              :                                        "matched up op %d to\n", n);
    2565          421 :                       vect_print_slp_tree (MSG_NOTE, vect_location, child);
    2566              :                     }
    2567          923 :                   children.safe_push (child);
    2568              :                 }
    2569              :             }
    2570              :           /* 3. build SLP nodes to combine the chain.  */
    2571         1153 :           for (unsigned lane = 0; lane < group_size; ++lane)
    2572         1692 :             if (stmts[lane] && chains[lane][0].code != code)
    2573              :               {
    2574              :                 /* See if there's any alternate all-PLUS entry.  */
    2575              :                 unsigned n;
    2576            6 :                 for (n = 1; n < chain_len; ++n)
    2577              :                   {
    2578           30 :                     for (lane = 0; lane < group_size; ++lane)
    2579           48 :                       if (stmts[lane] && chains[lane][n].code != code)
    2580              :                         break;
    2581            6 :                     if (lane == group_size)
    2582              :                       break;
    2583              :                   }
    2584            6 :                 if (n != chain_len)
    2585              :                   {
    2586              :                     /* Swap that in at first position.  */
    2587            6 :                     std::swap (children[0], children[n]);
    2588           30 :                     for (lane = 0; lane < group_size; ++lane)
    2589           24 :                       if (stmts[lane])
    2590           24 :                         std::swap (chains[lane][0], chains[lane][n]);
    2591              :                   }
    2592              :                 else
    2593              :                   {
    2594              :                     /* ???  When this triggers and we end up with two
    2595              :                        vect_constant/external_def up-front things break (ICE)
    2596              :                        spectacularly finding an insertion place for the
    2597              :                        all-constant op.  We should have a fully
    2598              :                        vect_internal_def operand though(?) so we can swap
    2599              :                        that into first place and then prepend the all-zero
    2600              :                        constant.  */
    2601            0 :                     if (dump_enabled_p ())
    2602            0 :                       dump_printf_loc (MSG_NOTE, vect_location,
    2603              :                                        "inserting constant zero to compensate "
    2604              :                                        "for (partially) negated first "
    2605              :                                        "operand\n");
    2606            0 :                     chain_len++;
    2607            0 :                     for (lane = 0; lane < group_size; ++lane)
    2608            0 :                       if (stmts[lane])
    2609            0 :                         chains[lane].safe_insert
    2610            0 :                           (0, chain_op_t (code, vect_constant_def, NULL_TREE));
    2611            0 :                     vec<tree> zero_ops;
    2612            0 :                     zero_ops.create (group_size);
    2613            0 :                     zero_ops.quick_push (build_zero_cst (TREE_TYPE (vectype)));
    2614            0 :                     for (lane = 1; lane < group_size; ++lane)
    2615            0 :                       if (stmts[lane])
    2616            0 :                         zero_ops.quick_push (zero_ops[0]);
    2617              :                       else
    2618            0 :                         zero_ops.quick_push (NULL_TREE);
    2619            0 :                     slp_tree zero = vect_create_new_slp_node (zero_ops);
    2620            0 :                     SLP_TREE_DEF_TYPE (zero) = vect_constant_def;
    2621            0 :                     children.safe_insert (0, zero);
    2622              :                   }
    2623              :                 break;
    2624              :               }
    2625         1011 :           for (unsigned i = 1; i < children.length (); ++i)
    2626              :             {
    2627          698 :               slp_tree op0 = children[i - 1];
    2628          698 :               slp_tree op1 = children[i];
    2629          698 :               bool this_two_op = false;
    2630         2560 :               for (unsigned lane = 0; lane < group_size; ++lane)
    2631         4040 :                 if (stmts[lane] && chains[lane][i].code != chains[0][i].code)
    2632              :                   {
    2633              :                     this_two_op = true;
    2634              :                     break;
    2635              :                   }
    2636          698 :               slp_tree child;
    2637          698 :               if (i == children.length () - 1)
    2638          313 :                 child = vect_create_new_slp_node (node, stmts, 2);
    2639              :               else
    2640          385 :                 child = vect_create_new_slp_node (2, ERROR_MARK);
    2641          698 :               if (this_two_op)
    2642              :                 {
    2643          158 :                   vec<std::pair<unsigned, unsigned> > lperm;
    2644          158 :                   lperm.create (group_size);
    2645          570 :                   for (unsigned lane = 0; lane < group_size; ++lane)
    2646          824 :                     lperm.quick_push (std::make_pair
    2647          412 :                       (chains[lane][i].code != chains[0][i].code, lane));
    2648          316 :                   vect_slp_build_two_operator_nodes (child, vectype, op0, op1,
    2649          158 :                                                      (chains[0][i].code == code
    2650              :                                                       ? op_stmt_info
    2651              :                                                       : other_op_stmt_info),
    2652          158 :                                                      (chains[0][i].code == code
    2653              :                                                       ? other_op_stmt_info
    2654              :                                                       : op_stmt_info),
    2655              :                                                      lperm);
    2656              :                 }
    2657              :               else
    2658              :                 {
    2659          540 :                   SLP_TREE_DEF_TYPE (child) = vect_internal_def;
    2660          540 :                   SLP_TREE_VECTYPE (child) = vectype;
    2661          540 :                   SLP_TREE_LANES (child) = group_size;
    2662          540 :                   SLP_TREE_CHILDREN (child).quick_push (op0);
    2663          540 :                   SLP_TREE_CHILDREN (child).quick_push (op1);
    2664          540 :                   SLP_TREE_REPRESENTATIVE (child)
    2665         1080 :                     = (chains[0][i].code == code
    2666          540 :                        ? op_stmt_info : other_op_stmt_info);
    2667              :                 }
    2668          698 :               children[i] = child;
    2669              :             }
    2670          313 :           *tree_size += this_tree_size + 1;
    2671          313 :           *max_nunits = this_max_nunits;
    2672         1513 :           while (!chains.is_empty ())
    2673          864 :             chains.pop ().release ();
    2674              :           return node;
    2675              :         }
    2676        21219 : out:
    2677        21242 :       if (dump_enabled_p ())
    2678         2817 :         dump_printf_loc (MSG_NOTE, vect_location,
    2679              :                          "failed to line up SLP graph by re-associating "
    2680              :                          "operations in lanes%s\n",
    2681              :                          !hard_fail ? " trying regular discovery" : "");
    2682        21247 :       while (!children.is_empty ())
    2683            5 :         vect_free_slp_tree (children.pop ());
    2684        21405 :       while (!chains.is_empty ())
    2685          163 :         chains.pop ().release ();
    2686              :       /* Hard-fail, otherwise we might run into quadratic processing of the
    2687              :          chains starting one stmt into the chain again.  */
    2688        21242 :       if (hard_fail)
    2689              :         return NULL;
    2690              :       /* Fall thru to normal processing.  */
    2691        21555 :     }
    2692              : 
    2693              :   /* Get at the operands, verifying they are compatible.  */
    2694      3389932 :   vec<slp_oprnd_info> oprnds_info = vect_create_oprnd_info (nops, group_size);
    2695      3389932 :   slp_oprnd_info oprnd_info;
    2696     16209582 :   FOR_EACH_VEC_ELT (stmts, i, stmt_info)
    2697              :     {
    2698     25641712 :       int res = vect_get_and_check_slp_defs (vinfo, vectype,
    2699     12820856 :                                              swap[i], skip_args,
    2700              :                                              stmts, i, &oprnds_info);
    2701     12820856 :       if (res != 0)
    2702       584930 :         matches[(res == -1) ? 0 : i] = false;
    2703     12820856 :       if (!matches[0])
    2704              :         break;
    2705              :     }
    2706     15877181 :   for (i = 0; i < group_size; ++i)
    2707     12719564 :     if (!matches[i])
    2708              :       {
    2709       232315 :         vect_free_oprnd_info (oprnds_info);
    2710       232315 :         return NULL;
    2711              :       }
    2712      9472851 :   swap = NULL;
    2713              : 
    2714      9472851 :   bool has_two_operators_perm = false;
    2715     18945702 :   auto_vec<unsigned> two_op_perm_indices[2];
    2716      3157617 :   vec<stmt_vec_info> two_op_scalar_stmts[2] = {vNULL, vNULL};
    2717              : 
    2718      3171910 :   if (two_operators && oprnds_info.length () == 2 && group_size > 2)
    2719              :     {
    2720         3824 :       unsigned idx = 0;
    2721         3824 :       hash_map<gimple *, unsigned> seen;
    2722         3824 :       vec<slp_oprnd_info> new_oprnds_info
    2723         3824 :         = vect_create_oprnd_info (1, group_size);
    2724         3824 :       bool success = true;
    2725              : 
    2726         3824 :       enum tree_code code = ERROR_MARK;
    2727         3824 :       if (oprnds_info[0]->def_stmts[0]
    2728         3824 :           && is_a<gassign *> (oprnds_info[0]->def_stmts[0]->stmt))
    2729         3766 :         code = gimple_assign_rhs_code (oprnds_info[0]->def_stmts[0]->stmt);
    2730         3824 :       basic_block bb = nullptr;
    2731              : 
    2732         7426 :       for (unsigned j = 0; j < group_size; ++j)
    2733              :         {
    2734        17402 :           FOR_EACH_VEC_ELT (oprnds_info, i, oprnd_info)
    2735              :             {
    2736        13800 :               stmt_vec_info stmt_info = oprnd_info->def_stmts[j];
    2737        13800 :               if (!stmt_info
    2738        13639 :                   || !is_a<gassign *> (stmt_info->stmt)
    2739        13636 :                   || gimple_assign_rhs_code (stmt_info->stmt) != code
    2740        24239 :                   || skip_args[i])
    2741              :                 {
    2742              :                   success = false;
    2743         3365 :                   break;
    2744              :                 }
    2745              :               /* Avoid mixing lanes with defs in different basic-blocks.  */
    2746        10439 :               if (!bb)
    2747         3944 :                 bb = gimple_bb (vect_orig_stmt (stmt_info)->stmt);
    2748         8261 :               else if (gimple_bb (vect_orig_stmt (stmt_info)->stmt) != bb)
    2749              :                 {
    2750              :                   success = false;
    2751              :                   break;
    2752              :                 }
    2753              : 
    2754        10435 :               bool exists;
    2755        10435 :               unsigned &stmt_idx
    2756        10435 :                 = seen.get_or_insert (stmt_info->stmt, &exists);
    2757              : 
    2758        10435 :               if (!exists)
    2759              :                 {
    2760         9094 :                   new_oprnds_info[0]->def_stmts.safe_push (stmt_info);
    2761         9094 :                   new_oprnds_info[0]->ops.safe_push (oprnd_info->ops[j]);
    2762         9094 :                   stmt_idx = idx;
    2763         9094 :                   idx++;
    2764              :                 }
    2765              : 
    2766        10435 :               two_op_perm_indices[i].safe_push (stmt_idx);
    2767              :             }
    2768              : 
    2769         6967 :           if (!success)
    2770              :             break;
    2771              :         }
    2772              : 
    2773         3824 :       if (success && idx == group_size)
    2774              :         {
    2775           94 :           if (dump_enabled_p ())
    2776              :             {
    2777            0 :               dump_printf_loc (MSG_NOTE, vect_location,
    2778              :                                "Replace two_operators operands:\n");
    2779              : 
    2780            0 :               FOR_EACH_VEC_ELT (oprnds_info, i, oprnd_info)
    2781              :                 {
    2782            0 :                   dump_printf_loc (MSG_NOTE, vect_location,
    2783              :                                    "Operand %u:\n", i);
    2784            0 :                   for (unsigned j = 0; j < group_size; j++)
    2785            0 :                     dump_printf_loc (MSG_NOTE, vect_location, "\tstmt %u %G",
    2786            0 :                                      j, oprnd_info->def_stmts[j]->stmt);
    2787              :                 }
    2788              : 
    2789            0 :               dump_printf_loc (MSG_NOTE, vect_location,
    2790              :                                "With a single operand:\n");
    2791            0 :               for (unsigned j = 0; j < group_size; j++)
    2792            0 :                 dump_printf_loc (MSG_NOTE, vect_location, "\tstmt %u %G",
    2793            0 :                                  j, new_oprnds_info[0]->def_stmts[j]->stmt);
    2794              :             }
    2795              : 
    2796           94 :           two_op_scalar_stmts[0].safe_splice (oprnds_info[0]->def_stmts);
    2797           94 :           two_op_scalar_stmts[1].safe_splice (oprnds_info[1]->def_stmts);
    2798              : 
    2799           94 :           new_oprnds_info[0]->first_op_type = oprnds_info[0]->first_op_type;
    2800           94 :           new_oprnds_info[0]->first_dt = oprnds_info[0]->first_dt;
    2801           94 :           new_oprnds_info[0]->any_pattern = oprnds_info[0]->any_pattern;
    2802           94 :           new_oprnds_info[0]->first_gs_p = oprnds_info[0]->first_gs_p;
    2803           94 :           new_oprnds_info[0]->first_gs_info = oprnds_info[0]->first_gs_info;
    2804              : 
    2805           94 :           vect_free_oprnd_info (oprnds_info);
    2806           94 :           oprnds_info = new_oprnds_info;
    2807           94 :           nops = 1;
    2808           94 :           has_two_operators_perm = true;
    2809              :         }
    2810              :       else
    2811         3730 :         vect_free_oprnd_info (new_oprnds_info);
    2812         3824 :     }
    2813              : 
    2814      6315234 :   auto_vec<slp_tree, 4> children;
    2815              : 
    2816      3157617 :   stmt_info = stmts[0];
    2817              : 
    2818      3157617 :   int reduc_idx = -1;
    2819      3157617 :   int gs_scale = 0;
    2820      3157617 :   tree gs_base = NULL_TREE;
    2821              : 
    2822              :   /* Create SLP_TREE nodes for the definition node/s.  */
    2823      8065527 :   FOR_EACH_VEC_ELT (oprnds_info, i, oprnd_info)
    2824              :     {
    2825      5036041 :       slp_tree child = nullptr;
    2826      5036041 :       unsigned int j;
    2827      5036041 :       unsigned old_swap_distance;
    2828      5036041 :       bool can_swap;
    2829      5036041 :       bool can_swap_nonmatching;
    2830      5036041 :       bool *stmt_can_swap;
    2831              : 
    2832              :       /* We're skipping certain operands from processing, for example
    2833              :          outer loop reduction initial defs.  */
    2834      5036041 :       if (skip_args[i])
    2835              :         {
    2836       490046 :           children.safe_push (NULL);
    2837      5397956 :           continue;
    2838              :         }
    2839              : 
    2840      4545995 :       if (oprnd_info->first_dt == vect_uninitialized_def)
    2841              :         {
    2842              :           /* COND_EXPR have one too many eventually if the condition
    2843              :              is a SSA name.  */
    2844            0 :           gcc_assert (i == 3 && nops == 4);
    2845            0 :           continue;
    2846              :         }
    2847              : 
    2848      4545995 :       if (oprnd_info->first_gs_p)
    2849              :         {
    2850        22561 :           gs_scale = oprnd_info->first_gs_info.scale;
    2851        22561 :           gs_base = oprnd_info->first_gs_info.base;
    2852              :         }
    2853              : 
    2854      4545995 :       if (is_a <bb_vec_info> (vinfo)
    2855      1596775 :           && oprnd_info->first_dt == vect_internal_def
    2856      5372365 :           && !oprnd_info->any_pattern)
    2857              :         {
    2858              :           /* For BB vectorization, if all defs are the same do not
    2859              :              bother to continue the build along the single-lane
    2860              :              graph but use a splat of the scalar value.  */
    2861       782979 :           stmt_vec_info first_def = oprnd_info->def_stmts[0];
    2862       842092 :           for (j = 1; j < group_size; ++j)
    2863       798633 :             if (oprnd_info->def_stmts[j] != first_def)
    2864              :               break;
    2865       782979 :           if (j == group_size
    2866              :               /* But avoid doing this for loads where we may be
    2867              :                  able to CSE things, unless the stmt is not
    2868              :                  vectorizable.  */
    2869       782979 :               && (!STMT_VINFO_VECTORIZABLE (first_def)
    2870        50792 :                   || !gimple_vuse (first_def->stmt)))
    2871              :             {
    2872        34488 :               if (dump_enabled_p ())
    2873          107 :                 dump_printf_loc (MSG_NOTE, vect_location,
    2874              :                                  "Using a splat of the uniform operand %G",
    2875              :                                  first_def->stmt);
    2876        34488 :               oprnd_info->first_dt = vect_external_def;
    2877              :             }
    2878              :         }
    2879              : 
    2880      4545995 :       if (oprnd_info->first_dt == vect_external_def
    2881      4545995 :           || oprnd_info->first_dt == vect_constant_def)
    2882              :         {
    2883      1500090 :           if (!GET_MODE_SIZE (vinfo->vector_mode).is_constant ())
    2884              :             {
    2885              :               tree op0;
    2886              :               tree uniform_val = op0 = oprnd_info->ops[0];
    2887              :               for (j = 1; j < oprnd_info->ops.length (); ++j)
    2888              :                 if (oprnd_info->ops[j]
    2889              :                     && !operand_equal_p (uniform_val, oprnd_info->ops[j]))
    2890              :                   {
    2891              :                     uniform_val = NULL_TREE;
    2892              :                     break;
    2893              :                   }
    2894              :               if (!uniform_val
    2895              :                   && !can_duplicate_and_interleave_p (vinfo,
    2896              :                                                       oprnd_info->ops.length (),
    2897              :                                                       TREE_TYPE (op0)))
    2898              :                 {
    2899              :                   matches[j] = false;
    2900              :                   if (dump_enabled_p ())
    2901              :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    2902              :                                      "Build SLP failed: invalid type of def "
    2903              :                                      "for variable-length SLP %T\n", op0);
    2904              :                   goto fail;
    2905              :                 }
    2906              :             }
    2907      1500090 :           slp_tree invnode = vect_create_new_slp_node (oprnd_info->ops);
    2908      1500090 :           SLP_TREE_DEF_TYPE (invnode) = oprnd_info->first_dt;
    2909      1500090 :           oprnd_info->ops = vNULL;
    2910      1500090 :           children.safe_push (invnode);
    2911      1500090 :           continue;
    2912      1500090 :         }
    2913              : 
    2914              :       /* See which SLP operand a reduction chain continues on.  We want
    2915              :          to chain even PHIs but not backedges.  */
    2916      3045905 :       if (STMT_VINFO_REDUC_DEF (oprnd_info->def_stmts[0])
    2917      3045905 :           || STMT_VINFO_REDUC_IDX (oprnd_info->def_stmts[0]) != -1)
    2918              :         {
    2919       233784 :           if (STMT_VINFO_DEF_TYPE (stmt_info) == vect_nested_cycle)
    2920              :             {
    2921          776 :               if (oprnd_info->first_dt == vect_double_reduction_def)
    2922          388 :                 reduc_idx = i;
    2923              :             }
    2924       233008 :           else if (is_a <gphi *> (stmt_info->stmt)
    2925       233008 :                    && gimple_phi_num_args
    2926        99859 :                         (as_a <gphi *> (stmt_info->stmt)) != 1)
    2927              :             ;
    2928       133542 :           else if (STMT_VINFO_REDUC_IDX (stmt_info) == -1
    2929          393 :                    && STMT_VINFO_DEF_TYPE (stmt_info) != vect_double_reduction_def)
    2930              :             ;
    2931       133542 :           else if (reduc_idx == -1)
    2932       125133 :             reduc_idx = i;
    2933              :           else
    2934              :             /* For .COND_* reduction operations the else value can be the
    2935              :                same as one of the operation operands.  The other def
    2936              :                stmts have been moved, so we can't check easily.  Check
    2937              :                it's a call at least.  */
    2938         8409 :             gcc_assert (is_a <gcall *> (stmt_info->stmt));
    2939              :         }
    2940              : 
    2941              :       /* When we have a masked load with uniform mask discover this
    2942              :          as a single-lane mask with a splat permute.  This way we can
    2943              :          recognize this as a masked load-lane by stripping the splat.  */
    2944      3045905 :       if (is_a <gcall *> (STMT_VINFO_STMT (stmt_info))
    2945        57492 :           && gimple_call_internal_p (STMT_VINFO_STMT (stmt_info),
    2946              :                                      IFN_MASK_LOAD)
    2947         6071 :           && STMT_VINFO_GROUPED_ACCESS (stmt_info)
    2948      3045982 :           && ! STMT_VINFO_SLP_VECT_ONLY (DR_GROUP_FIRST_ELEMENT (stmt_info)))
    2949              :         {
    2950           35 :           vec<stmt_vec_info> def_stmts2;
    2951           35 :           def_stmts2.create (1);
    2952           35 :           def_stmts2.quick_push (oprnd_info->def_stmts[0]);
    2953           35 :           child = vect_build_slp_tree (vinfo, def_stmts2,
    2954              :                                        &this_max_nunits,
    2955              :                                        matches, limit,
    2956              :                                        &this_tree_size, bst_map);
    2957           35 :           if (child)
    2958              :             {
    2959           35 :               slp_tree pnode = vect_create_new_slp_node (1, VEC_PERM_EXPR);
    2960           35 :               SLP_TREE_VECTYPE (pnode) = SLP_TREE_VECTYPE (child);
    2961           35 :               SLP_TREE_LANES (pnode) = group_size;
    2962           35 :               SLP_TREE_SCALAR_STMTS (pnode).create (group_size);
    2963           35 :               SLP_TREE_LANE_PERMUTATION (pnode).create (group_size);
    2964          210 :               for (unsigned k = 0; k < group_size; ++k)
    2965              :                 {
    2966          175 :                   SLP_TREE_SCALAR_STMTS (pnode)
    2967          175 :                     .quick_push (oprnd_info->def_stmts[0]);
    2968          175 :                   SLP_TREE_LANE_PERMUTATION (pnode)
    2969          175 :                     .quick_push (std::make_pair (0u, 0u));
    2970              :                 }
    2971           35 :               SLP_TREE_CHILDREN (pnode).quick_push (child);
    2972           35 :               pnode->max_nunits = child->max_nunits;
    2973           35 :               children.safe_push (pnode);
    2974           35 :               oprnd_info->def_stmts = vNULL;
    2975           35 :               continue;
    2976           35 :             }
    2977              :           else
    2978            0 :             def_stmts2.release ();
    2979              :         }
    2980              : 
    2981      6091740 :       can_swap = (i == 0
    2982      2260169 :                   && (nops == 2 || nops == 3)
    2983      1455776 :                   && oprnds_info.length () > 1
    2984      1455776 :                   && oprnds_info[1]->first_dt == vect_internal_def
    2985       593208 :                   && (is_gimple_assign (stmt_info->stmt)
    2986        49489 :                       || is_gimple_call (stmt_info->stmt))
    2987              :                   /* Swapping operands for reductions breaks assumptions
    2988              :                      later on.  */
    2989      3594778 :                   && STMT_VINFO_REDUC_IDX (stmt_info) == -1);
    2990      3045870 :       can_swap_nonmatching = can_swap;
    2991      3045870 :       stmt_can_swap = NULL;
    2992      3045870 :       if (can_swap)
    2993              :         {
    2994       493398 :           stmt_can_swap = XALLOCAVEC (bool, group_size);
    2995      8125958 :           for (j = 0; j < group_size; ++j)
    2996              :             {
    2997      7632560 :               stmt_can_swap[j] = false;
    2998      7632560 :               if (!stmts[j])
    2999              :                 /* NULL lanes are gaps and have no stmt to swap.  */
    3000            0 :                 stmt_can_swap[j] = true;
    3001      7632560 :               else if (gassign *stmt = dyn_cast <gassign *> (stmts[j]->stmt))
    3002              :                 {
    3003      7626950 :                   tree_code code = gimple_assign_rhs_code (stmt);
    3004     15253900 :                   stmt_can_swap[j] = (commutative_tree_code (code)
    3005      7626950 :                                       || commutative_ternary_tree_code (code));
    3006              :                 }
    3007         5610 :               else if (gcall *call = dyn_cast <gcall *> (stmts[j]->stmt))
    3008              :                 {
    3009         5610 :                   internal_fn fn = (gimple_call_internal_p (call)
    3010         5610 :                                     ? gimple_call_internal_fn (call) : IFN_LAST);
    3011        11220 :                   stmt_can_swap[j] = ((commutative_binary_fn_p (fn)
    3012         5294 :                                        || commutative_ternary_fn_p (fn))
    3013         5646 :                                       && first_commutative_argument (fn) == 0);
    3014              :                 }
    3015              : 
    3016      7632560 :               if (j != 0 && !stmt_can_swap[j])
    3017      7632560 :                 can_swap_nonmatching = false;
    3018              :             }
    3019              :         }
    3020              : 
    3021      3045870 :       old_swap_distance = least_upthread_swappable_op_distance;
    3022      3045870 :       if (can_swap_nonmatching)
    3023       459418 :         least_upthread_swappable_op_distance = 1;
    3024      2586452 :       else if (least_upthread_swappable_op_distance != -1U)
    3025       304495 :         least_upthread_swappable_op_distance++;
    3026      3045870 :       child = vect_build_slp_tree (vinfo, oprnd_info->def_stmts,
    3027              :                                    &this_max_nunits,
    3028              :                                    matches, limit,
    3029              :                                    &this_tree_size, bst_map);
    3030      3045870 :       least_upthread_swappable_op_distance = old_swap_distance;
    3031      3045870 :       if (child != NULL)
    3032              :         {
    3033      2546719 :           oprnd_info->def_stmts = vNULL;
    3034      2546719 :           children.safe_push (child);
    3035      2546719 :           continue;
    3036              :         }
    3037              : 
    3038              :       /* If the SLP build for operand zero failed and operand zero
    3039              :          and one can be commuted try that for the scalar stmts
    3040              :          that failed the match.  */
    3041       499151 :       if (/* A first scalar stmt mismatch signals a fatal mismatch.  */
    3042       499151 :           matches[0]
    3043       263553 :           && can_swap)
    3044              :         {
    3045              :           /* See whether we can swap the matching or the non-matching
    3046              :              stmt operands.  */
    3047              :           bool swap_not_matching = true;
    3048        66799 :           do
    3049              :             {
    3050      7108693 :               for (j = 0; j < group_size; ++j)
    3051              :                 {
    3052      7056967 :                   if (matches[j] != !swap_not_matching)
    3053        88237 :                     continue;
    3054              :                   /* Verify if we can swap operands of this stmt.  */
    3055      6968730 :                   if (!stmt_can_swap[j])
    3056              :                     {
    3057        15073 :                       if (!swap_not_matching)
    3058         7027 :                         goto fail;
    3059              :                       swap_not_matching = false;
    3060              :                       break;
    3061              :                     }
    3062              :                 }
    3063              :             }
    3064        59772 :           while (j != group_size);
    3065              : 
    3066              :           /* Swap mismatched definition stmts.  */
    3067        51726 :           if (dump_enabled_p ())
    3068          389 :             dump_printf_loc (MSG_NOTE, vect_location,
    3069              :                              "Re-trying with swapped operands of stmts ");
    3070      7084649 :           for (j = 0; j < group_size; ++j)
    3071      7032923 :             if (matches[j] == !swap_not_matching)
    3072              :               {
    3073     13906914 :                 std::swap (oprnds_info[0]->def_stmts[j],
    3074      6953457 :                            oprnds_info[1]->def_stmts[j]);
    3075     13906914 :                 std::swap (oprnds_info[0]->ops[j],
    3076      6953457 :                            oprnds_info[1]->ops[j]);
    3077      6953457 :                 if (dump_enabled_p ())
    3078         1076 :                   dump_printf (MSG_NOTE, "%d ", j);
    3079              :               }
    3080        51726 :           if (dump_enabled_p ())
    3081          389 :             dump_printf (MSG_NOTE, "\n");
    3082              :           /* After swapping some operands we lost track whether an
    3083              :              operand has any pattern defs so be conservative here.  */
    3084       100863 :           if (oprnds_info[0]->any_pattern || oprnds_info[1]->any_pattern)
    3085         3049 :             oprnds_info[0]->any_pattern = oprnds_info[1]->any_pattern = true;
    3086              :           /* And try again with scratch 'matches' ... */
    3087        51726 :           bool *tem = XALLOCAVEC (bool, group_size);
    3088        51726 :           if ((child = vect_build_slp_tree (vinfo, oprnd_info->def_stmts,
    3089              :                                             &this_max_nunits,
    3090              :                                             tem, limit,
    3091              :                                             &this_tree_size, bst_map)) != NULL)
    3092              :             {
    3093         6533 :               oprnd_info->def_stmts = vNULL;
    3094         6533 :               children.safe_push (child);
    3095         6533 :               continue;
    3096              :             }
    3097              :         }
    3098       440398 : fail:
    3099              : 
    3100              :       /* If the SLP build failed and we analyze a basic-block
    3101              :          simply treat nodes we fail to build as externally defined
    3102              :          (and thus build vectors from the scalar defs).
    3103              :          The cost model will reject outright expensive cases.
    3104              :          ???  This doesn't treat cases where permutation ultimatively
    3105              :          fails (or we don't try permutation below).  Ideally we'd
    3106              :          even compute a permutation that will end up with the maximum
    3107              :          SLP tree size...  */
    3108       492618 :       if (is_a <bb_vec_info> (vinfo)
    3109              :           /* ???  Rejecting patterns this way doesn't work.  We'd have to
    3110              :              do extra work to cancel the pattern so the uses see the
    3111              :              scalar version.  */
    3112              :           /* Skip building vector operands from scalars while operand
    3113              :              discovery may still be fixed by retrying with swapped operands.  */
    3114       411665 :           && (least_upthread_swappable_op_distance != 1
    3115              :               /* A first scalar stmt mismatch signals a fatal mismatch
    3116              :                  that the parent commutative retry cannot recover.  */
    3117        26480 :               || !matches[0])
    3118       393648 :           && !is_pattern_stmt_p (stmt_info)
    3119       863611 :           && !oprnd_info->any_pattern)
    3120              :         {
    3121              :           /* But if there's a leading vector sized set of matching stmts
    3122              :              fail here so we can split the group.  This matches the condition
    3123              :              vect_analyze_slp_instance uses.  */
    3124              :           /* ???  We might want to split here and combine the results to support
    3125              :              multiple vector sizes better.  */
    3126       574175 :           for (j = 0; j < group_size; ++j)
    3127       574175 :             if (!matches[j])
    3128              :               break;
    3129       370755 :           if (!known_ge (j, TYPE_VECTOR_SUBPARTS (vectype))
    3130       370724 :               && vect_slp_can_convert_to_external (oprnd_info->def_stmts))
    3131              :             {
    3132       364487 :               if (dump_enabled_p ())
    3133          622 :                 dump_printf_loc (MSG_NOTE, vect_location,
    3134              :                                  "Building vector operands from scalars\n");
    3135       364487 :               this_tree_size++;
    3136       364487 :               child = vect_create_new_slp_node (oprnd_info->ops);
    3137       364487 :               children.safe_push (child);
    3138       364487 :               oprnd_info->ops = vNULL;
    3139       364487 :               continue;
    3140              :             }
    3141              :         }
    3142              : 
    3143       128131 :       gcc_assert (child == NULL);
    3144       146850 :       FOR_EACH_VEC_ELT (children, j, child)
    3145        18719 :         if (child)
    3146        18719 :           vect_free_slp_tree (child);
    3147       128131 :       vect_free_oprnd_info (oprnds_info);
    3148       128131 :       return NULL;
    3149              :     }
    3150              : 
    3151      3029486 :   vect_free_oprnd_info (oprnds_info);
    3152              : 
    3153              :   /* If we have all children of a child built up from uniform scalars
    3154              :      or does more than one possibly expensive vector construction then
    3155              :      just throw that away, causing it built up from scalars.
    3156              :      The exception is the SLP node for the vector store.  */
    3157      3029486 :   if (is_a <bb_vec_info> (vinfo)
    3158      1106246 :       && !STMT_VINFO_GROUPED_ACCESS (stmt_info)
    3159              :       /* ???  Rejecting patterns this way doesn't work.  We'd have to
    3160              :          do extra work to cancel the pattern so the uses see the
    3161              :          scalar version.  */
    3162      3464077 :       && !is_pattern_stmt_p (stmt_info))
    3163              :     {
    3164              :       slp_tree child;
    3165              :       unsigned j;
    3166              :       bool all_uniform_p = true;
    3167              :       unsigned n_vector_builds = 0;
    3168      1233733 :       FOR_EACH_VEC_ELT (children, j, child)
    3169              :         {
    3170       824979 :           if (!child)
    3171              :             ;
    3172       824979 :           else if (SLP_TREE_DEF_TYPE (child) == vect_internal_def)
    3173              :             all_uniform_p = false;
    3174       600220 :           else if (!vect_slp_tree_uniform_p (child))
    3175              :             {
    3176       453775 :               all_uniform_p = false;
    3177       453775 :               if (SLP_TREE_DEF_TYPE (child) == vect_external_def)
    3178       416324 :                 n_vector_builds++;
    3179              :             }
    3180              :         }
    3181       408754 :       if (all_uniform_p
    3182       408754 :           || n_vector_builds > 1
    3183       692466 :           || (n_vector_builds == children.length ()
    3184        30873 :               && is_a <gphi *> (stmt_info->stmt)))
    3185              :         {
    3186              :           /* Roll back.  */
    3187       129952 :           matches[0] = false;
    3188       412428 :           FOR_EACH_VEC_ELT (children, j, child)
    3189       282476 :             if (child)
    3190       282476 :               vect_free_slp_tree (child);
    3191              : 
    3192       129952 :           if (dump_enabled_p ())
    3193          205 :             dump_printf_loc (MSG_NOTE, vect_location,
    3194              :                              "Building parent vector operands from "
    3195              :                              "scalars instead\n");
    3196       129952 :           return NULL;
    3197              :         }
    3198              :     }
    3199              : 
    3200      2899534 :   *tree_size += this_tree_size + 1;
    3201      2899534 :   *max_nunits = this_max_nunits;
    3202              : 
    3203      2899534 :   if (two_operators)
    3204              :     {
    3205              :       /* ???  We'd likely want to either cache in bst_map sth like
    3206              :          { a+b, NULL, a+b, NULL } and { NULL, a-b, NULL, a-b } or
    3207              :          the true { a+b, a+b, a+b, a+b } ... but there we don't have
    3208              :          explicit stmts to put in so the keying on 'stmts' doesn't
    3209              :          work (but we have the same issue with nodes that use 'ops').  */
    3210              : 
    3211         6723 :       if (has_two_operators_perm)
    3212              :         {
    3213           40 :           slp_tree child = children[0];
    3214           40 :           children.truncate (0);
    3215          120 :           for (i = 0; i < 2; i++)
    3216              :             {
    3217           80 :               slp_tree pnode
    3218           80 :                 = vect_create_new_slp_node (two_op_scalar_stmts[i], 2);
    3219           80 :               SLP_TREE_CODE (pnode) = VEC_PERM_EXPR;
    3220           80 :               SLP_TREE_VECTYPE (pnode) = vectype;
    3221           80 :               SLP_TREE_CHILDREN (pnode).quick_push (child);
    3222           80 :               SLP_TREE_CHILDREN (pnode).quick_push (child);
    3223           80 :               lane_permutation_t& perm = SLP_TREE_LANE_PERMUTATION (pnode);
    3224           80 :               children.safe_push (pnode);
    3225              : 
    3226          656 :               for (unsigned j = 0; j < stmts.length (); j++)
    3227          576 :                 perm.safe_push (std::make_pair (0, two_op_perm_indices[i][j]));
    3228              :             }
    3229              : 
    3230           40 :           SLP_TREE_REF_COUNT (child) += 4;
    3231              :         }
    3232              : 
    3233         6723 :       slp_tree one = new _slp_tree;
    3234         6723 :       slp_tree two = new _slp_tree;
    3235         6723 :       SLP_TREE_DEF_TYPE (one) = vect_internal_def;
    3236         6723 :       SLP_TREE_DEF_TYPE (two) = vect_internal_def;
    3237         6723 :       SLP_TREE_VECTYPE (one) = vectype;
    3238         6723 :       SLP_TREE_VECTYPE (two) = vectype;
    3239         6723 :       SLP_TREE_CHILDREN (one).safe_splice (children);
    3240         6723 :       SLP_TREE_CHILDREN (two).safe_splice (children);
    3241         6723 :       slp_tree child;
    3242        26894 :       FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (two), i, child)
    3243        13448 :         SLP_TREE_REF_COUNT (child)++;
    3244              : 
    3245              :       /* Here we record the original defs since this
    3246              :          node represents the final lane configuration.  */
    3247         6723 :       node = vect_create_new_slp_node (node, stmts, 2);
    3248         6723 :       SLP_TREE_VECTYPE (node) = vectype;
    3249         6723 :       SLP_TREE_CODE (node) = VEC_PERM_EXPR;
    3250         6723 :       SLP_TREE_CHILDREN (node).quick_push (one);
    3251         6723 :       SLP_TREE_CHILDREN (node).quick_push (two);
    3252         6723 :       enum tree_code code0 = ERROR_MARK;
    3253         6723 :       enum tree_code ocode = ERROR_MARK;
    3254         6723 :       if (gassign *stmt = dyn_cast <gassign *> (stmts[0]->stmt))
    3255         6721 :         code0 = gimple_assign_rhs_code (stmt);
    3256         6723 :       stmt_vec_info ostmt_info;
    3257         6723 :       unsigned j = 0;
    3258        24542 :       FOR_EACH_VEC_ELT (stmts, i, ostmt_info)
    3259              :         {
    3260        17819 :           int op = 0;
    3261        17819 :           if (gassign *ostmt = dyn_cast <gassign *> (ostmt_info->stmt))
    3262              :             {
    3263        17815 :               if (gimple_assign_rhs_code (ostmt) != code0)
    3264              :                 {
    3265         8928 :                   ocode = gimple_assign_rhs_code (ostmt);
    3266              :                   op = 1;
    3267              :                   j = i;
    3268              :                 }
    3269              :             }
    3270              :           else
    3271              :             {
    3272            8 :               if (gimple_call_combined_fn (stmts[0]->stmt)
    3273            4 :                   != gimple_call_combined_fn (ostmt_info->stmt))
    3274              :                 {
    3275            2 :                   op = 1;
    3276            2 :                   j = i;
    3277              :                 }
    3278              :             }
    3279        17819 :           SLP_TREE_LANE_PERMUTATION (node).safe_push (std::make_pair (op, i));
    3280              :         }
    3281         6723 :       SLP_TREE_CODE (one) = code0;
    3282         6723 :       SLP_TREE_CODE (two) = ocode;
    3283         6723 :       SLP_TREE_LANES (one) = stmts.length ();
    3284         6723 :       SLP_TREE_LANES (two) = stmts.length ();
    3285         6723 :       SLP_TREE_REPRESENTATIVE (one) = stmts[0];
    3286         6723 :       SLP_TREE_REPRESENTATIVE (two) = stmts[j];
    3287              : 
    3288         6723 :       return node;
    3289              :     }
    3290              : 
    3291      2892811 :   node = vect_create_new_slp_node (node, stmts, nops);
    3292      2892811 :   SLP_TREE_VECTYPE (node) = vectype;
    3293      2892811 :   SLP_TREE_CHILDREN (node).splice (children);
    3294      2892811 :   SLP_TREE_GS_SCALE (node) = gs_scale;
    3295      2892811 :   SLP_TREE_GS_BASE (node) = gs_base;
    3296      2892811 :   if (reduc_idx != -1)
    3297              :     {
    3298       116738 :       gcc_assert (STMT_VINFO_REDUC_IDX (stmt_info) != -1
    3299              :                   || STMT_VINFO_DEF_TYPE (stmt_info) == vect_nested_cycle
    3300              :                   || STMT_VINFO_DEF_TYPE (stmt_info) == vect_double_reduction_def);
    3301       116738 :       SLP_TREE_REDUC_IDX (node) = reduc_idx;
    3302       116738 :       node->cycle_info.id = SLP_TREE_CHILDREN (node)[reduc_idx]->cycle_info.id;
    3303              :     }
    3304              :   /* When reaching the reduction PHI, create a vect_reduc_info.  */
    3305      2776073 :   else if ((STMT_VINFO_DEF_TYPE (stmt_info) == vect_reduction_def
    3306      2776073 :             || STMT_VINFO_DEF_TYPE (stmt_info) == vect_double_reduction_def)
    3307      2776073 :            && is_a <gphi *> (STMT_VINFO_STMT (stmt_info)))
    3308              :     {
    3309       101820 :       loop_vec_info loop_vinfo = as_a <loop_vec_info> (vinfo);
    3310       101820 :       gcc_assert (STMT_VINFO_REDUC_IDX (stmt_info) == -1);
    3311       101820 :       node->cycle_info.id = loop_vinfo->reduc_infos.length ();
    3312       101820 :       vect_reduc_info reduc_info = new vect_reduc_info_s ();
    3313       101820 :       loop_vinfo->reduc_infos.safe_push (reduc_info);
    3314       101820 :       stmt_vec_info reduc_phi = stmt_info;
    3315              :       /* ???  For double reductions vect_is_simple_reduction stores the
    3316              :          reduction type and code on the inner loop header PHI.  */
    3317       101820 :       if (STMT_VINFO_DEF_TYPE (stmt_info) == vect_double_reduction_def)
    3318              :         {
    3319          388 :           use_operand_p use_p;
    3320          388 :           gimple *use_stmt;
    3321          388 :           bool res = single_imm_use (gimple_phi_result (stmt_info->stmt),
    3322              :                                      &use_p, &use_stmt);
    3323          388 :           gcc_assert (res);
    3324          388 :           reduc_phi = loop_vinfo->lookup_stmt (use_stmt);
    3325              :         }
    3326       101820 :       VECT_REDUC_INFO_DEF_TYPE (reduc_info) = STMT_VINFO_DEF_TYPE (stmt_info);
    3327       101820 :       VECT_REDUC_INFO_TYPE (reduc_info) = STMT_VINFO_REDUC_TYPE (reduc_phi);
    3328       101820 :       VECT_REDUC_INFO_CODE (reduc_info) = STMT_VINFO_REDUC_CODE (reduc_phi);
    3329       101820 :       VECT_REDUC_INFO_FN (reduc_info) = IFN_LAST;
    3330              :     }
    3331              :   return node;
    3332      9472851 : }
    3333              : 
    3334              : /* Dump a single SLP tree NODE.  */
    3335              : 
    3336              : static void
    3337       445934 : vect_print_slp_tree (dump_flags_t dump_kind, dump_location_t loc,
    3338              :                      slp_tree node)
    3339              : {
    3340       445934 :   unsigned i, j;
    3341       445934 :   slp_tree child;
    3342       445934 :   stmt_vec_info stmt_info;
    3343       445934 :   tree op;
    3344              : 
    3345       445934 :   dump_metadata_t metadata (dump_kind, loc.get_impl_location ());
    3346       445934 :   dump_user_location_t user_loc = loc.get_user_location ();
    3347       445934 :   dump_printf_loc (metadata, user_loc,
    3348              :                    "node%s %p (max_nunits=" HOST_WIDE_INT_PRINT_UNSIGNED
    3349              :                    ", refcnt=%u)",
    3350       445934 :                    SLP_TREE_DEF_TYPE (node) == vect_external_def
    3351              :                    ? " (external)"
    3352              :                    : (SLP_TREE_DEF_TYPE (node) == vect_constant_def
    3353       430157 :                       ? " (constant)"
    3354              :                       : ""), (void *) node,
    3355       445934 :                    estimated_poly_value (node->max_nunits),
    3356              :                                          SLP_TREE_REF_COUNT (node));
    3357       445934 :   if (SLP_TREE_VECTYPE (node))
    3358       378102 :     dump_printf (metadata, " %T", SLP_TREE_VECTYPE (node));
    3359       445934 :   dump_printf (metadata, "%s",
    3360       445934 :                node->avoid_stlf_fail ? " (avoid-stlf-fail)" : "");
    3361       445934 :   if (node->cycle_info.id != -1 || node->cycle_info.reduc_idx != -1)
    3362        23994 :     dump_printf (metadata, " cycle %d, link %d", node->cycle_info.id,
    3363              :                  node->cycle_info.reduc_idx);
    3364       445934 :   dump_printf (metadata, "\n");
    3365       445934 :   if (SLP_TREE_DEF_TYPE (node) == vect_internal_def)
    3366              :     {
    3367       363031 :       if (SLP_TREE_PERMUTE_P (node))
    3368        13825 :         dump_printf_loc (metadata, user_loc, "op: VEC_PERM_EXPR\n");
    3369              :       else
    3370       349206 :         dump_printf_loc (metadata, user_loc, "op template: %G",
    3371       349206 :                          SLP_TREE_REPRESENTATIVE (node)->stmt);
    3372              :     }
    3373       445934 :   if (SLP_TREE_SCALAR_STMTS (node).exists ())
    3374       869146 :     FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, stmt_info)
    3375       514300 :       if (stmt_info)
    3376       508935 :         dump_printf_loc (metadata, user_loc, "\t%sstmt %u %G",
    3377       508935 :                          SLP_TREE_LIVE_LANES (node).contains (i)
    3378       505262 :                          ? "[l*]" : (STMT_VINFO_LIVE_P (stmt_info)
    3379       505262 :                                      ? "[l] " : ""),
    3380              :                          i, stmt_info->stmt);
    3381              :       else
    3382         5365 :         dump_printf_loc (metadata, user_loc, "\tstmt %u ---\n", i);
    3383              :   else
    3384              :     {
    3385        91088 :       dump_printf_loc (metadata, user_loc, "\t{ ");
    3386       200131 :       FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_OPS (node), i, op)
    3387       109043 :         dump_printf (metadata, "%T%s ", op,
    3388       109043 :                      i < SLP_TREE_SCALAR_OPS (node).length () - 1 ? "," : "");
    3389        91088 :       dump_printf (metadata, "}\n");
    3390              :     }
    3391       445934 :   if (SLP_TREE_LOAD_PERMUTATION (node).exists ())
    3392              :     {
    3393        65022 :       dump_printf_loc (metadata, user_loc, "\tload permutation {");
    3394       148519 :       FOR_EACH_VEC_ELT (SLP_TREE_LOAD_PERMUTATION (node), i, j)
    3395        83497 :         dump_printf (dump_kind, " %u", j);
    3396        65022 :       dump_printf (dump_kind, " }\n");
    3397              :     }
    3398       445934 :   if (SLP_TREE_LANE_PERMUTATION (node).exists ())
    3399              :     {
    3400        13833 :       dump_printf_loc (metadata, user_loc, "\tlane permutation {");
    3401        51967 :       for (i = 0; i < SLP_TREE_LANE_PERMUTATION (node).length (); ++i)
    3402        38134 :         dump_printf (dump_kind, " %u[%u]",
    3403        38134 :                      SLP_TREE_LANE_PERMUTATION (node)[i].first,
    3404        38134 :                      SLP_TREE_LANE_PERMUTATION (node)[i].second);
    3405        13833 :       dump_printf (dump_kind, " }%s\n",
    3406        13833 :                    node->ldst_lanes ? " (load-lanes)" : "");
    3407              :     }
    3408       445934 :   if (SLP_TREE_CHILDREN (node).is_empty ())
    3409       170192 :     return;
    3410       275742 :   dump_printf_loc (metadata, user_loc, "\tchildren");
    3411       727722 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    3412       451980 :     dump_printf (dump_kind, " %p", (void *)child);
    3413       275742 :   dump_printf (dump_kind, "%s\n",
    3414       275742 :                node->ldst_lanes && !SLP_TREE_LANE_PERMUTATION (node).exists ()
    3415              :                ? " (store-lanes)" : "");
    3416              : }
    3417              : 
    3418              : DEBUG_FUNCTION void
    3419            0 : debug (slp_tree node)
    3420              : {
    3421            0 :   debug_dump_context ctx;
    3422            0 :   vect_print_slp_tree (MSG_NOTE,
    3423            0 :                        dump_location_t::from_location_t (UNKNOWN_LOCATION),
    3424              :                        node);
    3425            0 : }
    3426              : 
    3427              : /* Recursive helper for the dot producer below.  */
    3428              : 
    3429              : static void
    3430            0 : dot_slp_tree (FILE *f, slp_tree node, hash_set<slp_tree> &visited)
    3431              : {
    3432            0 :   if (visited.add (node))
    3433              :     return;
    3434              : 
    3435            0 :   fprintf (f, "\"%p\" [label=\"", (void *)node);
    3436            0 :   vect_print_slp_tree (MSG_NOTE,
    3437            0 :                        dump_location_t::from_location_t (UNKNOWN_LOCATION),
    3438              :                        node);
    3439            0 :   fprintf (f, "\"];\n");
    3440              : 
    3441              : 
    3442            0 :   for (slp_tree child : SLP_TREE_CHILDREN (node))
    3443            0 :     fprintf (f, "\"%p\" -> \"%p\";", (void *)node, (void *)child);
    3444              : 
    3445            0 :   for (slp_tree child : SLP_TREE_CHILDREN (node))
    3446            0 :     if (child)
    3447            0 :       dot_slp_tree (f, child, visited);
    3448              : }
    3449              : 
    3450              : DEBUG_FUNCTION void
    3451            0 : dot_slp_tree (const char *fname, slp_tree node)
    3452              : {
    3453            0 :   FILE *f = fopen (fname, "w");
    3454            0 :   fprintf (f, "digraph {\n");
    3455            0 :   fflush (f);
    3456            0 :     {
    3457            0 :       debug_dump_context ctx (f);
    3458            0 :       hash_set<slp_tree> visited;
    3459            0 :       dot_slp_tree (f, node, visited);
    3460            0 :     }
    3461            0 :   fflush (f);
    3462            0 :   fprintf (f, "}\n");
    3463            0 :   fclose (f);
    3464            0 : }
    3465              : 
    3466              : DEBUG_FUNCTION void
    3467            0 : dot_slp_tree (const char *fname, const vec<slp_instance> &slp_instances)
    3468              : {
    3469            0 :   FILE *f = fopen (fname, "w");
    3470            0 :   fprintf (f, "digraph {\n");
    3471            0 :   fflush (f);
    3472            0 :     {
    3473            0 :       debug_dump_context ctx (f);
    3474            0 :       hash_set<slp_tree> visited;
    3475            0 :       for (auto inst : slp_instances)
    3476            0 :         dot_slp_tree (f, SLP_INSTANCE_TREE (inst), visited);
    3477            0 :     }
    3478            0 :   fflush (f);
    3479            0 :   fprintf (f, "}\n");
    3480            0 :   fclose (f);
    3481            0 : }
    3482              : 
    3483              : /* Dump a slp tree NODE using flags specified in DUMP_KIND.  */
    3484              : 
    3485              : static void
    3486       484820 : vect_print_slp_graph (dump_flags_t dump_kind, dump_location_t loc,
    3487              :                       slp_tree node, hash_set<slp_tree> &visited)
    3488              : {
    3489       484820 :   unsigned i;
    3490       484820 :   slp_tree child;
    3491              : 
    3492       484820 :   if (visited.add (node))
    3493       484820 :     return;
    3494              : 
    3495       445461 :   vect_print_slp_tree (dump_kind, loc, node);
    3496              : 
    3497      1342389 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    3498       451467 :     if (child)
    3499       408789 :       vect_print_slp_graph (dump_kind, loc, child, visited);
    3500              : }
    3501              : 
    3502              : static void
    3503        46701 : vect_print_slp_graph (dump_flags_t dump_kind, dump_location_t loc,
    3504              :                       slp_tree entry)
    3505              : {
    3506        46701 :   hash_set<slp_tree> visited;
    3507        46701 :   vect_print_slp_graph (dump_kind, loc, entry, visited);
    3508        46701 : }
    3509              : 
    3510              : DEBUG_FUNCTION void
    3511            0 : debug (slp_instance instance)
    3512              : {
    3513            0 :   debug_dump_context ctx;
    3514            0 :   vect_print_slp_graph (MSG_NOTE,
    3515            0 :                         dump_location_t::from_location_t (UNKNOWN_LOCATION),
    3516              :                         SLP_INSTANCE_TREE (instance));
    3517            0 : }
    3518              : 
    3519              : 
    3520              : /* Compute the set of scalar stmts participating in external nodes.  */
    3521              : 
    3522              : static void
    3523      1581434 : vect_slp_gather_extern_scalar_stmts (vec_info *vinfo, slp_tree node,
    3524              :                                      hash_set<slp_tree> &visited,
    3525              :                                      hash_set<stmt_vec_info> &estmts)
    3526              : {
    3527      1581434 :   if (visited.add (node))
    3528              :     return;
    3529              : 
    3530      1536888 :   if (SLP_TREE_DEF_TYPE (node) == vect_internal_def)
    3531              :     {
    3532              :       slp_tree child;
    3533              :       int i;
    3534      1770409 :       FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    3535       888517 :         if (child)
    3536       888517 :           vect_slp_gather_extern_scalar_stmts (vinfo, child, visited, estmts);
    3537              :     }
    3538              :   else
    3539      3688210 :     for (tree def : SLP_TREE_SCALAR_OPS (node))
    3540              :       {
    3541      1724546 :         stmt_vec_info def_stmt = vinfo->lookup_def (def);
    3542      1724546 :         if (def_stmt)
    3543       340906 :           estmts.add (def_stmt);
    3544              :       }
    3545              : }
    3546              : 
    3547              : /* Mark the original scalar stmt coverage of the vector SLP graph of VINFO
    3548              :    with STMT_SLP_TYPE == pure_slp.  */
    3549              : 
    3550              : static void
    3551       239088 : vect_bb_slp_mark_stmts_vectorized (bb_vec_info vinfo)
    3552              : {
    3553              :   /* Gather the scalar stmt leafs of the SLP graph to stop the below DFS
    3554              :      walk on.  */
    3555       239088 :   hash_set<stmt_vec_info> scalar_stmts_in_externs;
    3556       239088 :   hash_set<slp_tree> visited;
    3557      1410181 :   for (auto instance : BB_VINFO_SLP_INSTANCES (vinfo))
    3558       692917 :     vect_slp_gather_extern_scalar_stmts (vinfo, SLP_INSTANCE_TREE (instance),
    3559              :                                          visited, scalar_stmts_in_externs);
    3560              : 
    3561              :   /* DFS walk scalar stmts to compute the vectorized coverage indicated
    3562              :      by STMT_SLP_TYPE (stmt) == pure_slp on the original scalar (non-pattern)
    3563              :      stmts.  */
    3564      1410181 :   for (auto instance : BB_VINFO_SLP_INSTANCES (vinfo))
    3565              :     {
    3566       808059 :       for (auto stmt : SLP_INSTANCE_ROOT_STMTS (instance))
    3567        53956 :         if (!scalar_stmts_in_externs.contains (stmt))
    3568        53299 :           STMT_SLP_TYPE (stmt) = pure_slp;
    3569       692917 :       auto_vec<stmt_vec_info> worklist;
    3570      3915183 :       for (auto stmt : SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (instance)))
    3571              :         {
    3572      1836432 :           stmt = vect_orig_stmt (stmt);
    3573      1836432 :           if (!scalar_stmts_in_externs.contains (stmt)
    3574      1836432 :               && STMT_SLP_TYPE (stmt) != pure_slp)
    3575              :             {
    3576      1825813 :               STMT_SLP_TYPE (stmt) = pure_slp;
    3577      1825813 :               worklist.safe_push (stmt);
    3578              :             }
    3579              :         }
    3580      3650040 :       while (!worklist.is_empty ())
    3581              :         {
    3582      2267160 :           stmt_vec_info stmt = worklist.pop ();
    3583              : 
    3584              :           /* Now walk relevant parts of the SSA use-def graph.  */
    3585      2267160 :           slp_oprnds child_ops (stmt);
    3586      4771849 :           for (unsigned i = 0; i < child_ops.num_slp_children; ++i)
    3587              :             {
    3588      2504689 :               tree op = child_ops.get_op_for_slp_child (stmt, i);
    3589      2504689 :               stmt_vec_info def = vinfo->lookup_def (op);
    3590      2504689 :               if (def
    3591       866013 :                   && !scalar_stmts_in_externs.contains (def)
    3592      3031609 :                   && STMT_SLP_TYPE (def) != pure_slp)
    3593              :                 {
    3594       441347 :                   STMT_SLP_TYPE (def) = pure_slp;
    3595       441347 :                   worklist.safe_push (def);
    3596              :                 }
    3597              :             }
    3598              :         }
    3599       692917 :     }
    3600       239088 : }
    3601              : 
    3602              : /* Mark the statements of the tree rooted at NODE as relevant (vect_used).  */
    3603              : 
    3604              : static void
    3605      2463991 : vect_mark_slp_stmts_relevant (slp_tree node, hash_set<slp_tree> &visited)
    3606              : {
    3607      2463991 :   if (SLP_TREE_DEF_TYPE (node) != vect_internal_def)
    3608              :     return;
    3609              : 
    3610      1464877 :   if (visited.add (node))
    3611              :     return;
    3612              : 
    3613      6887159 :   for (auto stmt_info : SLP_TREE_SCALAR_STMTS (node))
    3614      3080442 :     if (stmt_info)
    3615              :       {
    3616      3080442 :         gcc_assert (!STMT_VINFO_RELEVANT (stmt_info)
    3617              :                     || STMT_VINFO_RELEVANT (stmt_info) == vect_used_in_scope);
    3618      3080442 :         STMT_VINFO_RELEVANT (stmt_info) = vect_used_in_scope;
    3619              :       }
    3620              : 
    3621      5331375 :   for (auto child: SLP_TREE_CHILDREN (node))
    3622      1663770 :     if (child)
    3623      1663770 :       vect_mark_slp_stmts_relevant (child, visited);
    3624              : }
    3625              : 
    3626              : static void
    3627       800221 : vect_mark_slp_stmts_relevant (slp_tree node)
    3628              : {
    3629       800221 :   hash_set<slp_tree> visited;
    3630       800221 :   vect_mark_slp_stmts_relevant (node, visited);
    3631       800221 : }
    3632              : 
    3633              : 
    3634              : /* Gather loads in the SLP graph NODE and populate the INST loads array.  */
    3635              : 
    3636              : static void
    3637     10678868 : vect_gather_slp_loads (vec<slp_tree> &loads, slp_tree node,
    3638              :                        hash_set<slp_tree> &visited)
    3639              : {
    3640     10678868 :   if (!node || visited.add (node))
    3641      1750275 :     return;
    3642              : 
    3643      8928593 :   if (SLP_TREE_DEF_TYPE (node) != vect_internal_def)
    3644              :     return;
    3645              : 
    3646      6615767 :   if (!SLP_TREE_PERMUTE_P (node))
    3647              :     {
    3648      6409433 :       stmt_vec_info stmt_info = SLP_TREE_REPRESENTATIVE (node);
    3649      6409433 :       if (STMT_VINFO_DATA_REF (stmt_info)
    3650      2803755 :           && DR_IS_READ (STMT_VINFO_DATA_REF (stmt_info)))
    3651      1587553 :         loads.safe_push (node);
    3652              :     }
    3653              : 
    3654              :   unsigned i;
    3655              :   slp_tree child;
    3656     15021582 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    3657      8405815 :     vect_gather_slp_loads (loads, child, visited);
    3658              : }
    3659              : 
    3660              : 
    3661              : /* Find the last store in SLP INSTANCE.  */
    3662              : 
    3663              : stmt_vec_info
    3664      2770282 : vect_find_last_scalar_stmt_in_slp (slp_tree node)
    3665              : {
    3666      2770282 :   stmt_vec_info last = NULL;
    3667     15632767 :   for (auto stmt_vinfo : SLP_TREE_SCALAR_STMTS (node))
    3668      7329683 :     if (stmt_vinfo)
    3669              :       {
    3670      7329683 :         stmt_vinfo = vect_orig_stmt (stmt_vinfo);
    3671      7329683 :         last = last ? get_later_stmt (stmt_vinfo, last) : stmt_vinfo;
    3672              :       }
    3673              : 
    3674      2770282 :   return last;
    3675              : }
    3676              : 
    3677              : /* Find the first stmt in NODE.  */
    3678              : 
    3679              : stmt_vec_info
    3680       540014 : vect_find_first_scalar_stmt_in_slp (slp_tree node)
    3681              : {
    3682       540014 :   stmt_vec_info first = NULL;
    3683              : 
    3684      2911515 :   for (auto stmt_vinfo : SLP_TREE_SCALAR_STMTS (node))
    3685      1291473 :     if (stmt_vinfo)
    3686              :       {
    3687      1288777 :         stmt_vinfo = vect_orig_stmt (stmt_vinfo);
    3688      1288777 :         if (!first
    3689      1288777 :             || get_later_stmt (stmt_vinfo, first) == first)
    3690              :           first = stmt_vinfo;
    3691              :       }
    3692              : 
    3693       540014 :   return first;
    3694              : }
    3695              : 
    3696              : /* Splits a group of stores, currently beginning at FIRST_VINFO, into
    3697              :    two groups: one (still beginning at FIRST_VINFO) of size GROUP1_SIZE
    3698              :    (also containing the first GROUP1_SIZE stmts, since stores are
    3699              :    consecutive), the second containing the remainder.
    3700              :    Return the first stmt in the second group.  */
    3701              : 
    3702              : static stmt_vec_info
    3703       161969 : vect_split_slp_store_group (stmt_vec_info first_vinfo, unsigned group1_size)
    3704              : {
    3705       161969 :   gcc_assert (DR_GROUP_FIRST_ELEMENT (first_vinfo) == first_vinfo);
    3706       161969 :   gcc_assert (group1_size > 0);
    3707       161969 :   int group2_size = DR_GROUP_SIZE (first_vinfo) - group1_size;
    3708       161969 :   gcc_assert (group2_size > 0);
    3709       161969 :   DR_GROUP_SIZE (first_vinfo) = group1_size;
    3710              : 
    3711       161969 :   stmt_vec_info stmt_info = first_vinfo;
    3712       541148 :   for (unsigned i = group1_size; i > 1; i--)
    3713              :     {
    3714       379179 :       stmt_info = DR_GROUP_NEXT_ELEMENT (stmt_info);
    3715       379179 :       gcc_assert (DR_GROUP_GAP (stmt_info) == 1);
    3716              :     }
    3717              :   /* STMT is now the last element of the first group.  */
    3718       161969 :   stmt_vec_info group2 = DR_GROUP_NEXT_ELEMENT (stmt_info);
    3719       161969 :   DR_GROUP_NEXT_ELEMENT (stmt_info) = 0;
    3720              : 
    3721       161969 :   DR_GROUP_SIZE (group2) = group2_size;
    3722       451369 :   for (stmt_info = group2; stmt_info;
    3723       289400 :        stmt_info = DR_GROUP_NEXT_ELEMENT (stmt_info))
    3724              :     {
    3725       289400 :       DR_GROUP_FIRST_ELEMENT (stmt_info) = group2;
    3726       289400 :       gcc_assert (DR_GROUP_GAP (stmt_info) == 1);
    3727              :     }
    3728              : 
    3729              :   /* For the second group, the DR_GROUP_GAP is that before the original group,
    3730              :      plus skipping over the first vector.  */
    3731       161969 :   DR_GROUP_GAP (group2) = DR_GROUP_GAP (first_vinfo) + group1_size;
    3732              : 
    3733              :   /* DR_GROUP_GAP of the first group now has to skip over the second group too.  */
    3734       161969 :   DR_GROUP_GAP (first_vinfo) += group2_size;
    3735              : 
    3736       161969 :   if (dump_enabled_p ())
    3737           70 :     dump_printf_loc (MSG_NOTE, vect_location, "Split group into %d and %d\n",
    3738              :                      group1_size, group2_size);
    3739              : 
    3740       161969 :   return group2;
    3741              : }
    3742              : 
    3743              : /* Calculate the unrolling factor for an SLP instance with GROUP_SIZE
    3744              :    statements and a vector of NUNITS elements.  */
    3745              : 
    3746              : static poly_uint64
    3747      4230687 : calculate_unrolling_factor (poly_uint64 nunits, unsigned int group_size)
    3748              : {
    3749      4230687 :   return exact_div (common_multiple (nunits, group_size), group_size);
    3750              : }
    3751              : 
    3752              : /* Helper that checks to see if a node is a load node.  */
    3753              : 
    3754              : static inline bool
    3755          102 : vect_is_slp_load_node  (slp_tree root)
    3756              : {
    3757          102 :   return (!SLP_TREE_PERMUTE_P (root)
    3758          102 :           && SLP_TREE_DEF_TYPE (root) == vect_internal_def
    3759           96 :           && STMT_VINFO_GROUPED_ACCESS (SLP_TREE_REPRESENTATIVE (root))
    3760          166 :           && DR_IS_READ (STMT_VINFO_DATA_REF (SLP_TREE_REPRESENTATIVE (root))));
    3761              : }
    3762              : 
    3763              : 
    3764              : /* Helper function of optimize_load_redistribution that performs the operation
    3765              :    recursively.  */
    3766              : 
    3767              : static slp_tree
    3768        19448 : optimize_load_redistribution_1 (scalar_stmts_to_slp_tree_map_t *bst_map,
    3769              :                                 vec_info *vinfo, unsigned int group_size,
    3770              :                                 hash_map<slp_tree, slp_tree> *load_map,
    3771              :                                 slp_tree root)
    3772              : {
    3773        19448 :   if (slp_tree *leader = load_map->get (root))
    3774         3535 :     return *leader;
    3775              : 
    3776        15913 :   slp_tree node;
    3777        15913 :   unsigned i;
    3778              : 
    3779              :   /* For now, we don't know anything about externals so do not do anything.  */
    3780        15913 :   if (!root || SLP_TREE_DEF_TYPE (root) != vect_internal_def)
    3781              :     return NULL;
    3782        11416 :   else if (SLP_TREE_PERMUTE_P (root))
    3783              :     {
    3784              :       /* First convert this node into a load node and add it to the leaves
    3785              :          list and flatten the permute from a lane to a load one.  If it's
    3786              :          unneeded it will be elided later.  */
    3787           70 :       vec<stmt_vec_info> stmts;
    3788           70 :       stmts.create (SLP_TREE_LANES (root));
    3789           70 :       lane_permutation_t lane_perm = SLP_TREE_LANE_PERMUTATION (root);
    3790          134 :       for (unsigned j = 0; j < lane_perm.length (); j++)
    3791              :         {
    3792          102 :           std::pair<unsigned, unsigned> perm = lane_perm[j];
    3793          102 :           node = SLP_TREE_CHILDREN (root)[perm.first];
    3794              : 
    3795          102 :           if (!vect_is_slp_load_node (node)
    3796          102 :               || SLP_TREE_CHILDREN (node).exists ())
    3797              :             {
    3798           38 :               stmts.release ();
    3799           38 :               goto next;
    3800              :             }
    3801              : 
    3802           64 :           stmts.quick_push (SLP_TREE_SCALAR_STMTS (node)[perm.second]);
    3803              :         }
    3804              : 
    3805           32 :       if (dump_enabled_p ())
    3806            0 :         dump_printf_loc (MSG_NOTE, vect_location,
    3807              :                          "converting stmts on permute node %p\n",
    3808              :                          (void *) root);
    3809              : 
    3810           32 :       bool *matches = XALLOCAVEC (bool, group_size);
    3811           32 :       poly_uint64 max_nunits = 1;
    3812           32 :       unsigned tree_size = 0, limit = 1;
    3813           32 :       node = vect_build_slp_tree (vinfo, stmts, &max_nunits,
    3814              :                                   matches, &limit, &tree_size, bst_map);
    3815           32 :       if (!node)
    3816            0 :         stmts.release ();
    3817              : 
    3818           32 :       load_map->put (root, node);
    3819           32 :       return node;
    3820              :     }
    3821              : 
    3822        11346 : next:
    3823        11384 :   load_map->put (root, NULL);
    3824              : 
    3825        26565 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (root), i , node)
    3826              :     {
    3827        15181 :       slp_tree value
    3828        15181 :         = optimize_load_redistribution_1 (bst_map, vinfo, group_size, load_map,
    3829              :                                           node);
    3830        15181 :       if (value)
    3831              :         {
    3832           32 :           SLP_TREE_REF_COUNT (value)++;
    3833           32 :           SLP_TREE_CHILDREN (root)[i] = value;
    3834              :           /* ???  We know the original leafs of the replaced nodes will
    3835              :              be referenced by bst_map, only the permutes created by
    3836              :              pattern matching are not.  */
    3837           32 :           if (SLP_TREE_REF_COUNT (node) == 1)
    3838           32 :             load_map->remove (node);
    3839           32 :           vect_free_slp_tree (node);
    3840              :         }
    3841              :     }
    3842              : 
    3843              :   return NULL;
    3844              : }
    3845              : 
    3846              : /* Temporary workaround for loads not being CSEd during SLP build.  This
    3847              :    function will traverse the SLP tree rooted in ROOT for INSTANCE and find
    3848              :    VEC_PERM nodes that blend vectors from multiple nodes that all read from the
    3849              :    same DR such that the final operation is equal to a permuted load.  Such
    3850              :    NODES are then directly converted into LOADS themselves.  The nodes are
    3851              :    CSEd using BST_MAP.  */
    3852              : 
    3853              : static void
    3854         3121 : optimize_load_redistribution (scalar_stmts_to_slp_tree_map_t *bst_map,
    3855              :                               vec_info *vinfo, unsigned int group_size,
    3856              :                               hash_map<slp_tree, slp_tree> *load_map,
    3857              :                               slp_tree root)
    3858              : {
    3859         3121 :   slp_tree node;
    3860         3121 :   unsigned i;
    3861              : 
    3862         7388 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (root), i , node)
    3863              :     {
    3864         4267 :       slp_tree value
    3865         4267 :         = optimize_load_redistribution_1 (bst_map, vinfo, group_size, load_map,
    3866              :                                           node);
    3867         4267 :       if (value)
    3868              :         {
    3869            0 :           SLP_TREE_REF_COUNT (value)++;
    3870            0 :           SLP_TREE_CHILDREN (root)[i] = value;
    3871              :           /* ???  We know the original leafs of the replaced nodes will
    3872              :              be referenced by bst_map, only the permutes created by
    3873              :              pattern matching are not.  */
    3874            0 :           if (SLP_TREE_REF_COUNT (node) == 1)
    3875            0 :             load_map->remove (node);
    3876            0 :           vect_free_slp_tree (node);
    3877              :         }
    3878              :     }
    3879         3121 : }
    3880              : 
    3881              : /* Helper function of vect_match_slp_patterns.
    3882              : 
    3883              :    Attempts to match patterns against the slp tree rooted in REF_NODE using
    3884              :    VINFO.  Patterns are matched in post-order traversal.
    3885              : 
    3886              :    If matching is successful the value in REF_NODE is updated and returned, if
    3887              :    not then it is returned unchanged.  */
    3888              : 
    3889              : static bool
    3890      6193994 : vect_match_slp_patterns_2 (slp_tree *ref_node, vec_info *vinfo,
    3891              :                            slp_tree_to_load_perm_map_t *perm_cache,
    3892              :                            slp_compat_nodes_map_t *compat_cache,
    3893              :                            hash_set<slp_tree> *visited)
    3894              : {
    3895      6193994 :   unsigned i;
    3896      6193994 :   slp_tree node = *ref_node;
    3897      6193994 :   bool found_p = false;
    3898      6193994 :   if (!node || visited->add (node))
    3899       879078 :     return false;
    3900              : 
    3901              :   slp_tree child;
    3902      9923945 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    3903      4609029 :     found_p |= vect_match_slp_patterns_2 (&SLP_TREE_CHILDREN (node)[i],
    3904              :                                           vinfo, perm_cache, compat_cache,
    3905              :                                           visited);
    3906              : 
    3907     15944748 :   for (unsigned x = 0; x < num__slp_patterns; x++)
    3908              :     {
    3909     10629832 :       vect_pattern *pattern
    3910     10629832 :         = slp_patterns[x] (perm_cache, compat_cache, ref_node);
    3911     10629832 :       if (pattern)
    3912              :         {
    3913         1107 :           pattern->build (vinfo);
    3914         1107 :           delete pattern;
    3915         1107 :           found_p = true;
    3916              :         }
    3917              :     }
    3918              : 
    3919              :   return found_p;
    3920              : }
    3921              : 
    3922              : /* Applies pattern matching to the given SLP tree rooted in REF_NODE using
    3923              :    vec_info VINFO.
    3924              : 
    3925              :    The modified tree is returned.  Patterns are tried in order and multiple
    3926              :    patterns may match.  */
    3927              : 
    3928              : static bool
    3929      1584965 : vect_match_slp_patterns (slp_instance instance, vec_info *vinfo,
    3930              :                          hash_set<slp_tree> *visited,
    3931              :                          slp_tree_to_load_perm_map_t *perm_cache,
    3932              :                          slp_compat_nodes_map_t *compat_cache)
    3933              : {
    3934      1584965 :   DUMP_VECT_SCOPE ("vect_match_slp_patterns");
    3935      1584965 :   slp_tree *ref_node = &SLP_INSTANCE_TREE (instance);
    3936              : 
    3937      1584965 :   if (dump_enabled_p ())
    3938        30533 :     dump_printf_loc (MSG_NOTE, vect_location,
    3939              :                      "Analyzing SLP tree %p for patterns\n",
    3940        30533 :                      (void *) SLP_INSTANCE_TREE (instance));
    3941              : 
    3942      1584965 :   return vect_match_slp_patterns_2 (ref_node, vinfo, perm_cache, compat_cache,
    3943      1584965 :                                     visited);
    3944              : }
    3945              : 
    3946              : /* STMT_INFO is a store group of size GROUP_SIZE that we are considering
    3947              :    vectorizing with VECTYPE that might be NULL.  MASKED_P indicates whether
    3948              :    the stores are masked.
    3949              :    Return true if we could use IFN_STORE_LANES instead and if that appears
    3950              :    to be the better approach.  */
    3951              : 
    3952              : static bool
    3953         6126 : vect_slp_prefer_store_lanes_p (vec_info *vinfo, stmt_vec_info stmt_info,
    3954              :                                tree vectype, bool masked_p,
    3955              :                                unsigned int group_size,
    3956              :                                unsigned int new_group_size)
    3957              : {
    3958         6126 :   if (!vectype)
    3959              :     {
    3960         6126 :       tree scalar_type = TREE_TYPE (DR_REF (STMT_VINFO_DATA_REF (stmt_info)));
    3961         6126 :       vectype = get_vectype_for_scalar_type (vinfo, scalar_type);
    3962              :     }
    3963         6126 :   if (!vectype)
    3964              :     return false;
    3965              :   /* Allow the split if one of the two new groups would operate on full
    3966              :      vectors *within* rather than across one scalar loop iteration.
    3967              :      This is purely a heuristic, but it should work well for group
    3968              :      sizes of 3 and 4, where the possible splits are:
    3969              : 
    3970              :        3->2+1:  OK if the vector has exactly two elements
    3971              :        4->2+2:  Likewise
    3972              :        4->3+1:  Less clear-cut.  */
    3973         6126 :   if (multiple_p (group_size - new_group_size, TYPE_VECTOR_SUBPARTS (vectype))
    3974         3456 :       || multiple_p (new_group_size, TYPE_VECTOR_SUBPARTS (vectype)))
    3975         2693 :     return false;
    3976         3433 :   return vect_store_lanes_supported (vectype, group_size, masked_p) != IFN_LAST;
    3977              : }
    3978              : 
    3979              : /* Analyze an SLP instance starting from a group of grouped stores.  Call
    3980              :    vect_build_slp_tree to build a tree of packed stmts if possible.
    3981              :    Return FALSE if it's impossible to SLP any stmt in the loop.  */
    3982              : 
    3983              : static bool
    3984              : vect_analyze_slp_instance (vec_info *vinfo,
    3985              :                            scalar_stmts_to_slp_tree_map_t *bst_map,
    3986              :                            stmt_vec_info stmt_info, slp_instance_kind kind,
    3987              :                            unsigned max_tree_size, unsigned *limit,
    3988              :                            bool force_single_lane);
    3989              : 
    3990              : /* Build an interleaving scheme for the store sources RHS_NODES from
    3991              :    SCALAR_STMTS.  */
    3992              : 
    3993              : static slp_tree
    3994         8056 : vect_build_slp_store_interleaving (vec<slp_tree> &rhs_nodes,
    3995              :                                    vec<stmt_vec_info> &scalar_stmts,
    3996              :                                    poly_uint64 max_nunits)
    3997              : {
    3998         8056 :   unsigned int group_size = scalar_stmts.length ();
    3999        16112 :   slp_tree node = vect_create_new_slp_node (scalar_stmts,
    4000         8056 :                                             SLP_TREE_CHILDREN
    4001              :                                               (rhs_nodes[0]).length ());
    4002         8056 :   SLP_TREE_VECTYPE (node) = SLP_TREE_VECTYPE (rhs_nodes[0]);
    4003         8056 :   node->max_nunits = max_nunits;
    4004         8056 :   for (unsigned l = 0;
    4005        16139 :        l < SLP_TREE_CHILDREN (rhs_nodes[0]).length (); ++l)
    4006              :     {
    4007              :       /* And a permute merging all RHS SLP trees.  */
    4008         8083 :       slp_tree perm = vect_create_new_slp_node (rhs_nodes.length (),
    4009         8083 :                                                 VEC_PERM_EXPR);
    4010         8083 :       SLP_TREE_CHILDREN (node).quick_push (perm);
    4011         8083 :       SLP_TREE_LANE_PERMUTATION (perm).create (group_size);
    4012         8083 :       SLP_TREE_VECTYPE (perm) = SLP_TREE_VECTYPE (node);
    4013         8083 :       perm->max_nunits = max_nunits;
    4014         8083 :       SLP_TREE_LANES (perm) = group_size;
    4015              :       /* ???  We should set this NULL but that's not expected.  */
    4016         8083 :       SLP_TREE_REPRESENTATIVE (perm)
    4017         8083 :         = SLP_TREE_REPRESENTATIVE (SLP_TREE_CHILDREN (rhs_nodes[0])[l]);
    4018        31449 :       for (unsigned j = 0; j < rhs_nodes.length (); ++j)
    4019              :         {
    4020        23366 :           SLP_TREE_CHILDREN (perm)
    4021        23366 :             .quick_push (SLP_TREE_CHILDREN (rhs_nodes[j])[l]);
    4022        23366 :           SLP_TREE_CHILDREN (rhs_nodes[j])[l]->refcnt++;
    4023        23366 :           for (unsigned k = 0;
    4024        49048 :                k < SLP_TREE_LANES (rhs_nodes[j]); ++k)
    4025              :             {
    4026              :               /* ???  We should populate SLP_TREE_SCALAR_STMTS
    4027              :                  or SLP_TREE_SCALAR_OPS but then we might have
    4028              :                  a mix of both in our children.  */
    4029        25682 :               SLP_TREE_LANE_PERMUTATION (perm)
    4030        25682 :                 .quick_push (std::make_pair (j, k));
    4031              :             }
    4032              :         }
    4033              : 
    4034              :       /* Now we have a single permute node but we cannot code-generate
    4035              :          the case with more than two inputs.
    4036              :          Perform pairwise reduction, reducing the two inputs
    4037              :          with the least number of lanes to one and then repeat until
    4038              :          we end up with two inputs.  That scheme makes sure we end
    4039              :          up with permutes satisfying the restriction of requiring at
    4040              :          most two vector inputs to produce a single vector output
    4041              :          when the number of lanes is even.  */
    4042        15283 :       while (SLP_TREE_CHILDREN (perm).length () > 2)
    4043              :         {
    4044              :           /* When we have three equal sized groups left the pairwise
    4045              :              reduction does not result in a scheme that avoids using
    4046              :              three vectors.  Instead merge the first two groups
    4047              :              to the final size with do-not-care elements (chosen
    4048              :              from the first group) and then merge with the third.
    4049              :                   { A0, B0,  x, A1, B1,  x, ... }
    4050              :                -> { A0, B0, C0, A1, B1, C1, ... }
    4051              :              This handles group size of three (and at least
    4052              :              power-of-two multiples of that).  */
    4053         7200 :           if (SLP_TREE_CHILDREN (perm).length () == 3
    4054         3290 :               && (SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[0])
    4055         3290 :                   == SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[1]))
    4056         7200 :               && (SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[0])
    4057         2458 :                   == SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[2])))
    4058              :             {
    4059         2152 :               int ai = 0;
    4060         2152 :               int bi = 1;
    4061         2152 :               slp_tree a = SLP_TREE_CHILDREN (perm)[ai];
    4062         2152 :               slp_tree b = SLP_TREE_CHILDREN (perm)[bi];
    4063         2152 :               unsigned n = SLP_TREE_LANES (perm);
    4064              : 
    4065         2152 :               slp_tree permab = vect_create_new_slp_node (2, VEC_PERM_EXPR);
    4066         2152 :               SLP_TREE_LANES (permab) = n;
    4067         2152 :               SLP_TREE_LANE_PERMUTATION (permab).create (n);
    4068         2152 :               SLP_TREE_VECTYPE (permab) = SLP_TREE_VECTYPE (perm);
    4069         2152 :               permab->max_nunits = max_nunits;
    4070              :               /* ???  Should be NULL but that's not expected.  */
    4071         2152 :               SLP_TREE_REPRESENTATIVE (permab) = SLP_TREE_REPRESENTATIVE (perm);
    4072         2152 :               SLP_TREE_CHILDREN (permab).quick_push (a);
    4073         4318 :               for (unsigned k = 0; k < SLP_TREE_LANES (a); ++k)
    4074         2166 :                 SLP_TREE_LANE_PERMUTATION (permab)
    4075         2166 :                   .quick_push (std::make_pair (0, k));
    4076         2152 :               SLP_TREE_CHILDREN (permab).quick_push (b);
    4077         4318 :               for (unsigned k = 0; k < SLP_TREE_LANES (b); ++k)
    4078         2166 :                 SLP_TREE_LANE_PERMUTATION (permab)
    4079         2166 :                   .quick_push (std::make_pair (1, k));
    4080              :               /* Push the do-not-care lanes.  */
    4081         4318 :               for (unsigned k = 0; k < SLP_TREE_LANES (a); ++k)
    4082         2166 :                 SLP_TREE_LANE_PERMUTATION (permab)
    4083         2166 :                   .quick_push (std::make_pair (0, k));
    4084              : 
    4085              :               /* Put the merged node into 'perm', in place of a.  */
    4086         2152 :               SLP_TREE_CHILDREN (perm)[ai] = permab;
    4087              :               /* Adjust the references to b in the permutation
    4088              :                  of perm and to the later children which we'll
    4089              :                  remove.  */
    4090         8650 :               for (unsigned k = 0; k < SLP_TREE_LANES (perm); ++k)
    4091              :                 {
    4092         6498 :                   std::pair<unsigned, unsigned> &p
    4093         6498 :                     = SLP_TREE_LANE_PERMUTATION (perm)[k];
    4094         6498 :                   if (p.first == (unsigned) bi)
    4095              :                     {
    4096         2166 :                       p.first = ai;
    4097         2166 :                       p.second += SLP_TREE_LANES (a);
    4098              :                     }
    4099         4332 :                   else if (p.first > (unsigned) bi)
    4100         2166 :                     p.first--;
    4101              :                 }
    4102         2152 :               SLP_TREE_CHILDREN (perm).ordered_remove (bi);
    4103         2152 :               break;
    4104              :             }
    4105              : 
    4106              :           /* Pick the two nodes with the least number of lanes,
    4107              :              prefer the earliest candidate and maintain ai < bi.  */
    4108              :           int ai = -1;
    4109              :           int bi = -1;
    4110        45840 :           for (unsigned ci = 0; ci < SLP_TREE_CHILDREN (perm).length (); ++ci)
    4111              :             {
    4112        40792 :               if (ai == -1)
    4113         5048 :                 ai = ci;
    4114        35744 :               else if (bi == -1)
    4115         5048 :                 bi = ci;
    4116        30696 :               else if ((SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[ci])
    4117        30696 :                         < SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[ai]))
    4118        30696 :                        || (SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[ci])
    4119        25256 :                            < SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[bi])))
    4120              :                 {
    4121        11768 :                   if (SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[ai])
    4122         5884 :                       <= SLP_TREE_LANES (SLP_TREE_CHILDREN (perm)[bi]))
    4123         2727 :                     bi = ci;
    4124              :                   else
    4125              :                     {
    4126         3157 :                       ai = bi;
    4127         3157 :                       bi = ci;
    4128              :                     }
    4129              :                 }
    4130              :             }
    4131              : 
    4132              :           /* Produce a merge of nodes ai and bi.  */
    4133         5048 :           slp_tree a = SLP_TREE_CHILDREN (perm)[ai];
    4134         5048 :           slp_tree b = SLP_TREE_CHILDREN (perm)[bi];
    4135         5048 :           unsigned n = SLP_TREE_LANES (a) + SLP_TREE_LANES (b);
    4136         5048 :           slp_tree permab = vect_create_new_slp_node (2, VEC_PERM_EXPR);
    4137         5048 :           SLP_TREE_LANES (permab) = n;
    4138         5048 :           SLP_TREE_LANE_PERMUTATION (permab).create (n);
    4139         5048 :           SLP_TREE_VECTYPE (permab) = SLP_TREE_VECTYPE (perm);
    4140         5048 :           permab->max_nunits = max_nunits;
    4141              :           /* ???  Should be NULL but that's not expected.  */
    4142         5048 :           SLP_TREE_REPRESENTATIVE (permab) = SLP_TREE_REPRESENTATIVE (perm);
    4143         5048 :           SLP_TREE_CHILDREN (permab).quick_push (a);
    4144        13340 :           for (unsigned k = 0; k < SLP_TREE_LANES (a); ++k)
    4145         8292 :             SLP_TREE_LANE_PERMUTATION (permab)
    4146         8292 :               .quick_push (std::make_pair (0, k));
    4147         5048 :           SLP_TREE_CHILDREN (permab).quick_push (b);
    4148        12664 :           for (unsigned k = 0; k < SLP_TREE_LANES (b); ++k)
    4149         7616 :             SLP_TREE_LANE_PERMUTATION (permab)
    4150         7616 :               .quick_push (std::make_pair (1, k));
    4151              : 
    4152              :           /* Put the merged node into 'perm', in place of a.  */
    4153         5048 :           SLP_TREE_CHILDREN (perm)[ai] = permab;
    4154              :           /* Adjust the references to b in the permutation
    4155              :              of perm and to the later children which we'll
    4156              :              remove.  */
    4157        73221 :           for (unsigned k = 0; k < SLP_TREE_LANES (perm); ++k)
    4158              :             {
    4159        68173 :               std::pair<unsigned, unsigned> &p
    4160        68173 :                 = SLP_TREE_LANE_PERMUTATION (perm)[k];
    4161        68173 :               if (p.first == (unsigned) bi)
    4162              :                 {
    4163         7616 :                   p.first = ai;
    4164         7616 :                   p.second += SLP_TREE_LANES (a);
    4165              :                 }
    4166        60557 :               else if (p.first > (unsigned) bi)
    4167        25450 :                 p.first--;
    4168              :             }
    4169         5048 :           SLP_TREE_CHILDREN (perm).ordered_remove (bi);
    4170              :         }
    4171              :     }
    4172              : 
    4173         8056 :   return node;
    4174              : }
    4175              : 
    4176              : /* Analyze an SLP instance starting from SCALAR_STMTS which are a group
    4177              :    of KIND.  Return true if successful.  SCALAR_STMTS is owned by this
    4178              :    function, REMAIN and ROOT_STMT_INFOS ownership is transferred back to
    4179              :    the caller upon failure.  */
    4180              : 
    4181              : static bool
    4182      1965274 : vect_build_slp_instance (vec_info *vinfo,
    4183              :                          slp_instance_kind kind,
    4184              :                          vec<stmt_vec_info> &scalar_stmts,
    4185              :                          vec<stmt_vec_info> &root_stmt_infos,
    4186              :                          vec<tree> &remain,
    4187              :                          unsigned max_tree_size, unsigned *limit,
    4188              :                          scalar_stmts_to_slp_tree_map_t *bst_map,
    4189              :                          bool force_single_lane)
    4190              : {
    4191              :   /* If there's no budget left bail out early.  */
    4192      1965274 :   if (*limit == 0)
    4193              :     {
    4194        22248 :       scalar_stmts.release ();
    4195        22248 :       return false;
    4196              :     }
    4197              : 
    4198      1943026 :   if (kind == slp_inst_kind_ctor)
    4199              :     {
    4200        14399 :       if (dump_enabled_p ())
    4201           86 :         dump_printf_loc (MSG_NOTE, vect_location,
    4202              :                          "Analyzing vectorizable constructor: %G\n",
    4203           43 :                          root_stmt_infos[0]->stmt);
    4204              :     }
    4205      1928627 :   else if (kind == slp_inst_kind_gcond)
    4206              :     {
    4207       287986 :       if (dump_enabled_p ())
    4208         5730 :         dump_printf_loc (MSG_NOTE, vect_location,
    4209              :                          "Analyzing vectorizable control flow: %G",
    4210         2865 :                          root_stmt_infos[0]->stmt);
    4211              :     }
    4212      1640641 :   else if (kind == slp_inst_kind_bb_reduc)
    4213              :     {
    4214      1257681 :       if (dump_enabled_p ())
    4215         6142 :         dump_printf_loc (MSG_NOTE, vect_location,
    4216              :                          "Analyzing vectorizable BB reduction: %G",
    4217         3071 :                          root_stmt_infos[0]->stmt);
    4218              :     }
    4219              : 
    4220      1943026 :   if (dump_enabled_p ())
    4221              :     {
    4222        25565 :       dump_printf_loc (MSG_NOTE, vect_location,
    4223              :                        "Starting SLP discovery for\n");
    4224        54578 :       for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4225        58026 :         dump_printf_loc (MSG_NOTE, vect_location,
    4226        29013 :                          "  %G", scalar_stmts[i]->stmt);
    4227              :     }
    4228              : 
    4229              :   /* Build the tree for the SLP instance.  */
    4230      1943026 :   unsigned int group_size = scalar_stmts.length ();
    4231      1943026 :   bool *matches = XALLOCAVEC (bool, group_size);
    4232      1943026 :   poly_uint64 max_nunits = 1;
    4233      1943026 :   unsigned tree_size = 0;
    4234              : 
    4235      1943026 :   slp_tree node = NULL;
    4236      1943026 :   if (group_size > 1 && force_single_lane)
    4237              :     {
    4238            0 :       matches[0] = true;
    4239            0 :       matches[1] = false;
    4240              :     }
    4241              :   else
    4242      1943026 :     node = vect_build_slp_tree (vinfo, scalar_stmts,
    4243              :                                 &max_nunits, matches, limit,
    4244              :                                 &tree_size, bst_map);
    4245      1943026 :   if (node != NULL)
    4246              :     {
    4247              :       /* Calculate the unrolling factor based on the smallest type.  */
    4248       787608 :       poly_uint64 unrolling_factor
    4249       787608 :         = calculate_unrolling_factor (max_nunits, group_size);
    4250              : 
    4251       787608 :       if (maybe_ne (unrolling_factor, 1U)
    4252       787608 :           && is_a <bb_vec_info> (vinfo))
    4253              :         {
    4254            0 :           unsigned HOST_WIDE_INT const_max_nunits;
    4255            0 :           if (!max_nunits.is_constant (&const_max_nunits)
    4256            0 :               || const_max_nunits > group_size)
    4257              :             {
    4258            0 :               if (dump_enabled_p ())
    4259            0 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    4260              :                                  "Build SLP failed: store group "
    4261              :                                  "size not a multiple of the vector size "
    4262              :                                  "in basic block SLP\n");
    4263            0 :               vect_free_slp_tree (node);
    4264            0 :               return false;
    4265              :             }
    4266              :           /* Fatal mismatch.  */
    4267            0 :           if (dump_enabled_p ())
    4268            0 :             dump_printf_loc (MSG_NOTE, vect_location,
    4269              :                              "SLP discovery succeeded but node needs "
    4270              :                              "splitting\n");
    4271            0 :           memset (matches, true, group_size);
    4272            0 :           matches[group_size / const_max_nunits * const_max_nunits] = false;
    4273            0 :           vect_free_slp_tree (node);
    4274              :         }
    4275              :       else
    4276              :         {
    4277              :           /* Create a new SLP instance.  */
    4278       787608 :           slp_instance new_instance = XNEW (class _slp_instance);
    4279       787608 :           SLP_INSTANCE_TREE (new_instance) = node;
    4280       787608 :           SLP_INSTANCE_LOADS (new_instance) = vNULL;
    4281       787608 :           SLP_INSTANCE_ROOT_STMTS (new_instance) = root_stmt_infos;
    4282       787608 :           SLP_INSTANCE_REMAIN_DEFS (new_instance) = remain;
    4283       787608 :           SLP_INSTANCE_KIND (new_instance) = kind;
    4284       787608 :           new_instance->reduc_phis = NULL;
    4285       787608 :           new_instance->cost_vec = vNULL;
    4286       787608 :           new_instance->subgraph_entries = vNULL;
    4287              : 
    4288       787608 :           if (dump_enabled_p ())
    4289        22527 :             dump_printf_loc (MSG_NOTE, vect_location,
    4290              :                              "SLP size %u vs. limit %u.\n",
    4291              :                              tree_size, max_tree_size);
    4292              : 
    4293       787608 :           vinfo->slp_instances.safe_push (new_instance);
    4294              : 
    4295              :           /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    4296              :              the number of scalar stmts in the root in a few places.
    4297              :              Verify that assumption holds.  */
    4298      1575216 :           gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    4299              :                         .length () == group_size);
    4300              : 
    4301       787608 :           if (dump_enabled_p ())
    4302              :             {
    4303        22527 :               if (kind == slp_inst_kind_reduc_group)
    4304         1460 :                 dump_printf_loc (MSG_NOTE, vect_location,
    4305              :                                  "SLP discovery of size %d reduction group "
    4306              :                                  "succeeded\n", group_size);
    4307        22527 :               dump_printf_loc (MSG_NOTE, vect_location,
    4308              :                                "Final SLP tree for instance %p:\n",
    4309              :                                (void *) new_instance);
    4310        22527 :               vect_print_slp_graph (MSG_NOTE, vect_location,
    4311              :                                     SLP_INSTANCE_TREE (new_instance));
    4312              :             }
    4313              : 
    4314       787608 :           return true;
    4315              :         }
    4316              :     }
    4317              :   /* Failed to SLP.  */
    4318              : 
    4319              :   /* While we arrive here even with slp_inst_kind_store we should only
    4320              :      for group_size == 1.  The code to split store groups is only in
    4321              :      vect_analyze_slp_instance now.  */
    4322      1155418 :   gcc_assert (kind != slp_inst_kind_store || group_size == 1);
    4323              : 
    4324              :   /* Free the allocated memory.  */
    4325      1155418 :   scalar_stmts.release ();
    4326              : 
    4327              :   /* Failed to SLP.  */
    4328      1155418 :   if (dump_enabled_p ())
    4329         3038 :     dump_printf_loc (MSG_NOTE, vect_location, "SLP discovery failed\n");
    4330              :   return false;
    4331              : }
    4332              : 
    4333              : /* Analyze an SLP instance starting from a the start of a reduction chain.
    4334              :    Call vect_build_slp_tree to build a tree of packed stmts if possible.
    4335              :    Return FALSE if SLP build fails.  */
    4336              : 
    4337              : static bool
    4338        73102 : vect_analyze_slp_reduc_chain (loop_vec_info vinfo,
    4339              :                               scalar_stmts_to_slp_tree_map_t *bst_map,
    4340              :                               stmt_vec_info scalar_stmt,
    4341              :                               unsigned max_tree_size, unsigned *limit)
    4342              : {
    4343        73102 :   vec<stmt_vec_info> scalar_stmts = vNULL;
    4344              : 
    4345        73102 :   bool fail = false;
    4346              :   /* ???  We could leave operation code checking to SLP discovery.  */
    4347        73102 :   code_helper code = STMT_VINFO_REDUC_CODE (STMT_VINFO_REDUC_DEF
    4348              :                                               (vect_orig_stmt (scalar_stmt)));
    4349        73102 :   bool first = true;
    4350        73102 :   stmt_vec_info next_stmt = scalar_stmt;
    4351        83067 :   do
    4352              :     {
    4353        83067 :       stmt_vec_info stmt = next_stmt;
    4354        83067 :       gimple_match_op op;
    4355        83067 :       if (!gimple_extract_op (STMT_VINFO_STMT (stmt), &op))
    4356            0 :         gcc_unreachable ();
    4357       166134 :       tree reduc_def = gimple_arg (STMT_VINFO_STMT (stmt),
    4358        83067 :                                    STMT_VINFO_REDUC_IDX (stmt));
    4359        83067 :       next_stmt = vect_stmt_to_vectorize (vinfo->lookup_def (reduc_def));
    4360        83067 :       gcc_assert (is_a <gphi *> (STMT_VINFO_STMT (next_stmt))
    4361              :                   || STMT_VINFO_REDUC_IDX (next_stmt) != -1);
    4362        88976 :       if (!gimple_extract_op (STMT_VINFO_STMT (vect_orig_stmt (stmt)), &op))
    4363            0 :         gcc_unreachable ();
    4364        83067 :       if (CONVERT_EXPR_CODE_P (op.code)
    4365         4973 :           && tree_nop_conversion_p (op.type, TREE_TYPE (op.ops[0]))
    4366        88028 :           && (first
    4367         2496 :               || is_a <gphi *> (STMT_VINFO_STMT (next_stmt))))
    4368              :         ;
    4369        78166 :       else if (code != op.code)
    4370              :         {
    4371         2666 :           fail = true;
    4372         2666 :           break;
    4373              :         }
    4374              :       else
    4375        75500 :         scalar_stmts.safe_push (stmt);
    4376        80401 :       first = false;
    4377              :     }
    4378        80401 :   while (!is_a <gphi *> (STMT_VINFO_STMT (next_stmt)));
    4379        73102 :   if (fail)
    4380         2666 :     return false;
    4381              : 
    4382              :   /* Remember a stmt with the actual reduction operation.  */
    4383        70436 :   stmt_vec_info reduc_scalar_stmt = scalar_stmts[0];
    4384              : 
    4385              :   /* When the SSA def chain through reduc-idx does not form a natural
    4386              :      reduction chain try to linearize an associative operation manually.  */
    4387        70436 :   if (scalar_stmts.length () == 1
    4388        67822 :       && code.is_tree_code ()
    4389        61750 :       && associative_tree_code ((tree_code)code)
    4390              :       /* We may not associate if a fold-left reduction is required.  */
    4391       130768 :       && !needs_fold_left_reduction_p (TREE_TYPE (gimple_get_lhs
    4392              :                                                     (reduc_scalar_stmt->stmt)),
    4393              :                                        code))
    4394              :     {
    4395        57079 :       auto_vec<chain_op_t> chain;
    4396        57079 :       auto_vec<std::pair<tree_code, gimple *> > worklist;
    4397        57079 :       gimple *op_stmt = NULL, *other_op_stmt = NULL;
    4398        57079 :       if (is_a <gassign *> (scalar_stmts[0]->stmt)
    4399              :           /* We cannot linearize an operation that vect_slp_linearize_chain
    4400              :              would not put on its worklist.  */
    4401        57079 :           && gimple_assign_rhs_code (scalar_stmts[0]->stmt) == (tree_code)code)
    4402              :         {
    4403        56426 :           vect_slp_linearize_chain (vinfo, worklist, chain, (tree_code)code,
    4404        56426 :                                     scalar_stmts[0]->stmt, op_stmt,
    4405              :                                     other_op_stmt,
    4406              :                                     NULL);
    4407              : 
    4408        56426 :           scalar_stmts.truncate (0);
    4409        56426 :           stmt_vec_info tail = NULL;
    4410       282315 :           for (auto el : chain)
    4411              :             {
    4412       113400 :               if (el.dt == vect_external_def
    4413       113400 :                   || el.dt == vect_constant_def
    4414       113400 :                   || el.code != (tree_code) code)
    4415              :                 {
    4416          363 :                   scalar_stmts.release ();
    4417          363 :                   return false;
    4418              :                 }
    4419       113037 :               stmt_vec_info stmt = vinfo->lookup_def (el.op);
    4420       113037 :               if (STMT_VINFO_REDUC_IDX (stmt) != -1
    4421       110753 :                   || STMT_VINFO_REDUC_DEF (stmt))
    4422              :                 {
    4423        56296 :                   gcc_assert (tail == NULL);
    4424        56296 :                   tail = stmt;
    4425        56296 :                   continue;
    4426              :                 }
    4427        56741 :               scalar_stmts.safe_push (stmt);
    4428              :             }
    4429        56063 :           gcc_assert (tail);
    4430              :         }
    4431              : 
    4432              :       /* When this linearization didn't produce a chain see if stripping
    4433              :          a wrapping sign conversion produces one.  */
    4434        56716 :       if (scalar_stmts.length () == 1
    4435        56716 :           && (code == PLUS_EXPR || code == MULT_EXPR || code == BIT_IOR_EXPR
    4436              :               || code == BIT_AND_EXPR || code == BIT_XOR_EXPR))
    4437              :         {
    4438        54929 :           gimple *stmt = scalar_stmts[0]->stmt;
    4439        54929 :           if (!is_gimple_assign (stmt)
    4440        53763 :               || !CONVERT_EXPR_CODE_P (gimple_assign_rhs_code (stmt))
    4441         4578 :               || TREE_CODE (gimple_assign_rhs1 (stmt)) != SSA_NAME
    4442        59507 :               || !tree_nop_conversion_p (TREE_TYPE (gimple_assign_lhs (stmt)),
    4443         4578 :                                          TREE_TYPE (gimple_assign_rhs1 (stmt))))
    4444              :             {
    4445        53174 :               scalar_stmts.release ();
    4446        53174 :               return false;
    4447              :             }
    4448         1755 :           stmt = SSA_NAME_DEF_STMT (gimple_assign_rhs1 (stmt));
    4449         1755 :           if (!is_gimple_assign (stmt)
    4450         1755 :               || gimple_assign_rhs_code (stmt) != (tree_code)code)
    4451              :             {
    4452         1736 :               scalar_stmts.release ();
    4453         1736 :               return false;
    4454              :             }
    4455           19 :           chain.truncate (0);
    4456           19 :           vect_slp_linearize_chain (vinfo, worklist, chain, (tree_code)code,
    4457              :                                     stmt, op_stmt, other_op_stmt, NULL);
    4458              : 
    4459           19 :           scalar_stmts.truncate (0);
    4460           19 :           stmt_vec_info tail = NULL;
    4461           93 :           for (auto el : chain)
    4462              :             {
    4463           44 :               if (el.dt == vect_external_def
    4464           44 :                   || el.dt == vect_constant_def
    4465           44 :                   || el.code != (tree_code) code)
    4466              :                 {
    4467            8 :                   scalar_stmts.release ();
    4468            8 :                   return false;
    4469              :                 }
    4470           36 :               stmt_vec_info stmt = vinfo->lookup_def (el.op);
    4471           36 :               if (STMT_VINFO_REDUC_IDX (stmt) != -1
    4472           36 :                   || STMT_VINFO_REDUC_DEF (stmt))
    4473              :                 {
    4474            0 :                   gcc_assert (tail == NULL);
    4475            0 :                   tail = stmt;
    4476            0 :                   continue;
    4477              :                 }
    4478           36 :               scalar_stmts.safe_push (stmt);
    4479              :             }
    4480              :           /* Unlike the above this does not include the reduction SSA
    4481              :              cycle.  */
    4482           11 :           gcc_assert (!tail);
    4483              :         }
    4484              : 
    4485         1798 :       if (scalar_stmts.length () < 2)
    4486              :         {
    4487         1673 :           scalar_stmts.release ();
    4488         1673 :           return false;
    4489              :         }
    4490              : 
    4491          125 :       if (dump_enabled_p ())
    4492              :         {
    4493           34 :           dump_printf_loc (MSG_NOTE, vect_location,
    4494              :                            "Starting SLP discovery of reduction chain for\n");
    4495          140 :           for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4496          212 :             dump_printf_loc (MSG_NOTE, vect_location,
    4497          106 :                              "  %G", scalar_stmts[i]->stmt);
    4498              :         }
    4499              : 
    4500          125 :       unsigned int group_size = scalar_stmts.length ();
    4501          125 :       bool *matches = XALLOCAVEC (bool, group_size);
    4502          125 :       poly_uint64 max_nunits = 1;
    4503          125 :       unsigned tree_size = 0;
    4504          125 :       slp_tree node = vect_build_slp_tree (vinfo, scalar_stmts,
    4505              :                                            &max_nunits, matches, limit,
    4506          125 :                                            &tree_size, bst_map);
    4507          125 :       if (!node)
    4508              :         {
    4509           47 :           scalar_stmts.release ();
    4510           47 :           return false;
    4511              :         }
    4512              : 
    4513           78 :       unsigned cycle_id = vinfo->reduc_infos.length ();
    4514           78 :       vect_reduc_info reduc_info = new vect_reduc_info_s ();
    4515           78 :       vinfo->reduc_infos.safe_push (reduc_info);
    4516           78 :       VECT_REDUC_INFO_DEF_TYPE (reduc_info) = STMT_VINFO_DEF_TYPE (next_stmt);
    4517           78 :       VECT_REDUC_INFO_TYPE (reduc_info) = STMT_VINFO_REDUC_TYPE (next_stmt);
    4518           78 :       VECT_REDUC_INFO_CODE (reduc_info) = STMT_VINFO_REDUC_CODE (next_stmt);
    4519           78 :       VECT_REDUC_INFO_FN (reduc_info) = IFN_LAST;
    4520           78 :       reduc_info->is_reduc_chain = true;
    4521              : 
    4522              :       /* Build the node for the PHI and possibly the conversions.  */
    4523           78 :       slp_tree phis = vect_create_new_slp_node (2, ERROR_MARK);
    4524           78 :       SLP_TREE_REPRESENTATIVE (phis) = next_stmt;
    4525           78 :       phis->cycle_info.id = cycle_id;
    4526           78 :       SLP_TREE_LANES (phis) = group_size;
    4527           78 :       if (reduc_scalar_stmt == scalar_stmt)
    4528           74 :         SLP_TREE_VECTYPE (phis) = SLP_TREE_VECTYPE (node);
    4529              :       else
    4530            4 :         SLP_TREE_VECTYPE (phis)
    4531            4 :           = signed_or_unsigned_type_for (TYPE_UNSIGNED
    4532              :                                            (TREE_TYPE (gimple_get_lhs
    4533              :                                                          (scalar_stmt->stmt))),
    4534              :                                          SLP_TREE_VECTYPE (node));
    4535              :       /* ???  vect_cse_slp_nodes cannot cope with cycles without any
    4536              :          SLP_TREE_SCALAR_STMTS.  */
    4537           78 :       SLP_TREE_SCALAR_STMTS (phis).create (group_size);
    4538          393 :       for (unsigned i = 0; i < group_size; ++i)
    4539          315 :         SLP_TREE_SCALAR_STMTS (phis).quick_push (next_stmt);
    4540              : 
    4541           78 :       slp_tree op_input = phis;
    4542           78 :       if (reduc_scalar_stmt != scalar_stmt)
    4543              :         {
    4544            4 :           slp_tree conv = vect_create_new_slp_node (1, ERROR_MARK);
    4545            4 :           SLP_TREE_REPRESENTATIVE (conv)
    4546            4 :             = vinfo->lookup_def (gimple_arg (reduc_scalar_stmt->stmt,
    4547            4 :                                              STMT_VINFO_REDUC_IDX
    4548              :                                                (reduc_scalar_stmt)));
    4549            4 :           SLP_TREE_CHILDREN (conv).quick_push (phis);
    4550            4 :           conv->cycle_info.id = cycle_id;
    4551            4 :           SLP_TREE_REDUC_IDX (conv) = 0;
    4552            4 :           SLP_TREE_LANES (conv) = group_size;
    4553            4 :           SLP_TREE_VECTYPE (conv) = SLP_TREE_VECTYPE (node);
    4554            4 :           SLP_TREE_SCALAR_STMTS (conv) = vNULL;
    4555            4 :           op_input = conv;
    4556              :         }
    4557              : 
    4558           78 :       slp_tree reduc = vect_create_new_slp_node (2, ERROR_MARK);
    4559           78 :       SLP_TREE_REPRESENTATIVE (reduc) = reduc_scalar_stmt;
    4560           78 :       SLP_TREE_CHILDREN (reduc).quick_push (op_input);
    4561           78 :       SLP_TREE_CHILDREN (reduc).quick_push (node);
    4562           78 :       reduc->cycle_info.id = cycle_id;
    4563           78 :       SLP_TREE_REDUC_IDX (reduc) = 0;
    4564           78 :       SLP_TREE_LANES (reduc) = group_size;
    4565           78 :       SLP_TREE_VECTYPE (reduc) = SLP_TREE_VECTYPE (node);
    4566              :       /* ???  For the reduction epilogue we need a live lane.  */
    4567           78 :       SLP_TREE_SCALAR_STMTS (reduc).create (group_size);
    4568           78 :       SLP_TREE_SCALAR_STMTS (reduc).quick_push (reduc_scalar_stmt);
    4569          315 :       for (unsigned i = 1; i < group_size; ++i)
    4570          237 :         SLP_TREE_SCALAR_STMTS (reduc).quick_push (NULL);
    4571              : 
    4572           78 :       if (reduc_scalar_stmt != scalar_stmt)
    4573              :         {
    4574            4 :           slp_tree conv = vect_create_new_slp_node (1, ERROR_MARK);
    4575            4 :           SLP_TREE_REPRESENTATIVE (conv) = scalar_stmt;
    4576            4 :           SLP_TREE_CHILDREN (conv).quick_push (reduc);
    4577            4 :           conv->cycle_info.id = cycle_id;
    4578            4 :           SLP_TREE_REDUC_IDX (conv) = 0;
    4579            4 :           SLP_TREE_LANES (conv) = group_size;
    4580            4 :           SLP_TREE_VECTYPE (conv) = SLP_TREE_VECTYPE (phis);
    4581              :           /* ???  For the reduction epilogue we need a live lane.  */
    4582            4 :           SLP_TREE_SCALAR_STMTS (conv).create (group_size);
    4583            4 :           SLP_TREE_SCALAR_STMTS (conv).quick_push (scalar_stmt);
    4584            8 :           for (unsigned i = 1; i < group_size; ++i)
    4585            4 :             SLP_TREE_SCALAR_STMTS (conv).quick_push (NULL);
    4586            4 :           reduc = conv;
    4587              :         }
    4588              : 
    4589           78 :       edge le = loop_latch_edge (LOOP_VINFO_LOOP (vinfo));
    4590           78 :       SLP_TREE_CHILDREN (phis).quick_push (NULL);
    4591           78 :       SLP_TREE_CHILDREN (phis).quick_push (NULL);
    4592           78 :       SLP_TREE_CHILDREN (phis)[le->dest_idx] = reduc;
    4593           78 :       SLP_TREE_REF_COUNT (reduc)++;
    4594              : 
    4595              :       /* Create a new SLP instance.  */
    4596           78 :       slp_instance new_instance = XNEW (class _slp_instance);
    4597           78 :       SLP_INSTANCE_TREE (new_instance) = reduc;
    4598           78 :       SLP_INSTANCE_LOADS (new_instance) = vNULL;
    4599           78 :       SLP_INSTANCE_ROOT_STMTS (new_instance) = vNULL;
    4600           78 :       SLP_INSTANCE_REMAIN_DEFS (new_instance) = vNULL;
    4601           78 :       SLP_INSTANCE_KIND (new_instance) = slp_inst_kind_reduc_chain;
    4602           78 :       new_instance->reduc_phis = NULL;
    4603           78 :       new_instance->cost_vec = vNULL;
    4604           78 :       new_instance->subgraph_entries = vNULL;
    4605              : 
    4606           78 :       vinfo->slp_instances.safe_push (new_instance);
    4607              : 
    4608           78 :       if (dump_enabled_p ())
    4609              :         {
    4610           24 :           dump_printf_loc (MSG_NOTE, vect_location,
    4611              :                            "Final SLP tree for instance %p:\n",
    4612              :                            (void *) new_instance);
    4613           24 :           vect_print_slp_graph (MSG_NOTE, vect_location,
    4614              :                                 SLP_INSTANCE_TREE (new_instance));
    4615              :         }
    4616              : 
    4617           78 :       return true;
    4618        57079 :     }
    4619              : 
    4620        13357 :   if (scalar_stmts.length () <= 1)
    4621              :     {
    4622        10743 :       scalar_stmts.release ();
    4623        10743 :       return false;
    4624              :     }
    4625              : 
    4626         2614 :   scalar_stmts.reverse ();
    4627         2614 :   stmt_vec_info reduc_phi_info = next_stmt;
    4628              : 
    4629              :   /* Build the tree for the SLP instance.  */
    4630         2614 :   vec<stmt_vec_info> root_stmt_infos = vNULL;
    4631         2614 :   vec<tree> remain = vNULL;
    4632              : 
    4633         2614 :   if (dump_enabled_p ())
    4634              :     {
    4635          193 :       dump_printf_loc (MSG_NOTE, vect_location,
    4636              :                        "Starting SLP discovery of reduction chain for\n");
    4637         1029 :       for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4638         1672 :         dump_printf_loc (MSG_NOTE, vect_location,
    4639          836 :                          "  %G", scalar_stmts[i]->stmt);
    4640              :     }
    4641              : 
    4642              :   /* Build the tree for the SLP instance.  */
    4643         2614 :   unsigned int group_size = scalar_stmts.length ();
    4644         2614 :   bool *matches = XALLOCAVEC (bool, group_size);
    4645         2614 :   poly_uint64 max_nunits = 1;
    4646         2614 :   unsigned tree_size = 0;
    4647              : 
    4648              :   /* ???  We need this only for SLP discovery.  */
    4649        10210 :   for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4650         7596 :     REDUC_GROUP_FIRST_ELEMENT (scalar_stmts[i]) = scalar_stmts[0];
    4651              : 
    4652         2614 :   slp_tree node = vect_build_slp_tree (vinfo, scalar_stmts,
    4653              :                                        &max_nunits, matches, limit,
    4654         2614 :                                        &tree_size, bst_map);
    4655              : 
    4656        10210 :   for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4657         7596 :     REDUC_GROUP_FIRST_ELEMENT (scalar_stmts[i]) = NULL;
    4658              : 
    4659         2614 :   if (node != NULL)
    4660              :     {
    4661              :       /* Create a new SLP instance.  */
    4662         2329 :       slp_instance new_instance = XNEW (class _slp_instance);
    4663         2329 :       SLP_INSTANCE_TREE (new_instance) = node;
    4664         2329 :       SLP_INSTANCE_LOADS (new_instance) = vNULL;
    4665         2329 :       SLP_INSTANCE_ROOT_STMTS (new_instance) = root_stmt_infos;
    4666         2329 :       SLP_INSTANCE_REMAIN_DEFS (new_instance) = remain;
    4667         2329 :       SLP_INSTANCE_KIND (new_instance) = slp_inst_kind_reduc_chain;
    4668         2329 :       new_instance->reduc_phis = NULL;
    4669         2329 :       new_instance->cost_vec = vNULL;
    4670         2329 :       new_instance->subgraph_entries = vNULL;
    4671              : 
    4672         2329 :       vect_reduc_info reduc_info = info_for_reduction (vinfo, node);
    4673         2329 :       reduc_info->is_reduc_chain = true;
    4674              : 
    4675         2329 :       if (dump_enabled_p ())
    4676          144 :         dump_printf_loc (MSG_NOTE, vect_location,
    4677              :                          "SLP size %u vs. limit %u.\n",
    4678              :                          tree_size, max_tree_size);
    4679              : 
    4680              :       /* Fixup SLP reduction chains.  If this is a reduction chain with
    4681              :          a conversion in front amend the SLP tree with a node for that.  */
    4682         2329 :       gimple *scalar_def = STMT_VINFO_REDUC_DEF (reduc_phi_info)->stmt;
    4683         2329 :       if (is_gimple_assign (scalar_def)
    4684         2329 :           && CONVERT_EXPR_CODE_P (gimple_assign_rhs_code (scalar_def)))
    4685              :         {
    4686           43 :           stmt_vec_info conv_info = vect_stmt_to_vectorize
    4687           43 :                                         (STMT_VINFO_REDUC_DEF (reduc_phi_info));
    4688           43 :           scalar_stmts = vNULL;
    4689           43 :           scalar_stmts.create (group_size);
    4690          135 :           for (unsigned i = 0; i < group_size; ++i)
    4691           92 :             scalar_stmts.quick_push (conv_info);
    4692           43 :           slp_tree conv = vect_create_new_slp_node (scalar_stmts, 1);
    4693           43 :           SLP_TREE_VECTYPE (conv)
    4694           43 :             = get_vectype_for_scalar_type (vinfo,
    4695           43 :                                            TREE_TYPE
    4696              :                                              (gimple_assign_lhs (scalar_def)),
    4697              :                                            group_size);
    4698           43 :           SLP_TREE_REDUC_IDX (conv) = 0;
    4699           43 :           conv->cycle_info.id = node->cycle_info.id;
    4700           43 :           SLP_TREE_CHILDREN (conv).quick_push (node);
    4701           43 :           SLP_INSTANCE_TREE (new_instance) = conv;
    4702              :         }
    4703              :       /* Fill the backedge child of the PHI SLP node.  The
    4704              :          general matching code cannot find it because the
    4705              :          scalar code does not reflect how we vectorize the
    4706              :          reduction.  */
    4707         2329 :       use_operand_p use_p;
    4708         2329 :       imm_use_iterator imm_iter;
    4709         2329 :       class loop *loop = LOOP_VINFO_LOOP (vinfo);
    4710        11195 :       FOR_EACH_IMM_USE_FAST (use_p, imm_iter,
    4711              :                              gimple_get_lhs (scalar_def))
    4712              :         /* There are exactly two non-debug uses, the reduction
    4713              :            PHI and the loop-closed PHI node.  */
    4714         6537 :         if (!is_gimple_debug (USE_STMT (use_p))
    4715         6537 :             && gimple_bb (USE_STMT (use_p)) == loop->header)
    4716              :           {
    4717         2329 :             auto_vec<stmt_vec_info, 64> phis (group_size);
    4718         2329 :             stmt_vec_info phi_info = vinfo->lookup_stmt (USE_STMT (use_p));
    4719         9180 :             for (unsigned i = 0; i < group_size; ++i)
    4720         6851 :               phis.quick_push (phi_info);
    4721         2329 :             slp_tree *phi_node = bst_map->get (phis);
    4722         2329 :             unsigned dest_idx = loop_latch_edge (loop)->dest_idx;
    4723         4658 :             SLP_TREE_CHILDREN (*phi_node)[dest_idx]
    4724         2329 :               = SLP_INSTANCE_TREE (new_instance);
    4725         2329 :             SLP_INSTANCE_TREE (new_instance)->refcnt++;
    4726         2329 :           }
    4727              : 
    4728         2329 :       vinfo->slp_instances.safe_push (new_instance);
    4729              : 
    4730              :       /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    4731              :          the number of scalar stmts in the root in a few places.
    4732              :          Verify that assumption holds.  */
    4733         4658 :       gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    4734              :                   .length () == group_size);
    4735              : 
    4736         2329 :       if (dump_enabled_p ())
    4737              :         {
    4738          144 :           dump_printf_loc (MSG_NOTE, vect_location,
    4739              :                            "Final SLP tree for instance %p:\n",
    4740              :                            (void *) new_instance);
    4741          144 :           vect_print_slp_graph (MSG_NOTE, vect_location,
    4742              :                                 SLP_INSTANCE_TREE (new_instance));
    4743              :         }
    4744              : 
    4745         2329 :       return true;
    4746              :     }
    4747              : 
    4748              :   /* Failed to SLP.  */
    4749          285 :   scalar_stmts.release ();
    4750          285 :   if (dump_enabled_p ())
    4751           49 :     dump_printf_loc (MSG_NOTE, vect_location,
    4752              :                      "SLP discovery of reduction chain failed\n");
    4753              :   return false;
    4754              : }
    4755              : 
    4756              : /* Analyze an SLP instance starting from SCALAR_STMTS which are a group
    4757              :    of KIND.  Return true if successful.  */
    4758              : 
    4759              : static bool
    4760        99183 : vect_analyze_slp_reduction (loop_vec_info vinfo,
    4761              :                             stmt_vec_info scalar_stmt,
    4762              :                             unsigned max_tree_size, unsigned *limit,
    4763              :                             scalar_stmts_to_slp_tree_map_t *bst_map,
    4764              :                             bool force_single_lane)
    4765              : {
    4766        99183 :   slp_instance_kind kind = slp_inst_kind_reduc_group;
    4767              : 
    4768              :   /* Try to gather a reduction chain.  Only attempt if there's budget left
    4769              :      since chain analysis may build multi-lane trees that consume limit.  */
    4770        99183 :   if (! force_single_lane
    4771        73387 :       && *limit != 0
    4772        73387 :       && STMT_VINFO_DEF_TYPE (scalar_stmt) == vect_reduction_def
    4773       172285 :       && vect_analyze_slp_reduc_chain (vinfo, bst_map, scalar_stmt,
    4774              :                                        max_tree_size, limit))
    4775              :     return true;
    4776              : 
    4777        96776 :   vec<stmt_vec_info> scalar_stmts;
    4778        96776 :   scalar_stmts.create (1);
    4779        96776 :   scalar_stmts.quick_push (scalar_stmt);
    4780              : 
    4781        96776 :   if (dump_enabled_p ())
    4782              :     {
    4783         3864 :       dump_printf_loc (MSG_NOTE, vect_location,
    4784              :                        "Starting SLP discovery for\n");
    4785         7728 :       for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    4786         7728 :         dump_printf_loc (MSG_NOTE, vect_location,
    4787         3864 :                          "  %G", scalar_stmts[i]->stmt);
    4788              :     }
    4789              : 
    4790              :   /* Build the tree for the SLP instance.  */
    4791        96776 :   unsigned int group_size = scalar_stmts.length ();
    4792        96776 :   bool *matches = XALLOCAVEC (bool, group_size);
    4793        96776 :   poly_uint64 max_nunits = 1;
    4794        96776 :   unsigned tree_size = 0;
    4795              : 
    4796        96776 :   slp_tree node = vect_build_slp_tree (vinfo, scalar_stmts,
    4797              :                                        &max_nunits, matches, limit,
    4798              :                                        &tree_size, bst_map);
    4799        96776 :   if (node != NULL)
    4800              :     {
    4801              :       /* Create a new SLP instance.  */
    4802        93769 :       slp_instance new_instance = XNEW (class _slp_instance);
    4803        93769 :       SLP_INSTANCE_TREE (new_instance) = node;
    4804        93769 :       SLP_INSTANCE_LOADS (new_instance) = vNULL;
    4805        93769 :       SLP_INSTANCE_ROOT_STMTS (new_instance) = vNULL;
    4806        93769 :       SLP_INSTANCE_REMAIN_DEFS (new_instance) = vNULL;
    4807        93769 :       SLP_INSTANCE_KIND (new_instance) = kind;
    4808        93769 :       new_instance->reduc_phis = NULL;
    4809        93769 :       new_instance->cost_vec = vNULL;
    4810        93769 :       new_instance->subgraph_entries = vNULL;
    4811              : 
    4812        93769 :       if (dump_enabled_p ())
    4813         3744 :         dump_printf_loc (MSG_NOTE, vect_location,
    4814              :                          "SLP size %u vs. limit %u.\n",
    4815              :                          tree_size, max_tree_size);
    4816              : 
    4817        93769 :       vinfo->slp_instances.safe_push (new_instance);
    4818              : 
    4819              :       /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    4820              :          the number of scalar stmts in the root in a few places.
    4821              :          Verify that assumption holds.  */
    4822       187538 :       gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    4823              :                   .length () == group_size);
    4824              : 
    4825        93769 :       if (dump_enabled_p ())
    4826              :         {
    4827         3744 :           dump_printf_loc (MSG_NOTE, vect_location,
    4828              :                            "Final SLP tree for instance %p:\n",
    4829              :                            (void *) new_instance);
    4830         3744 :           vect_print_slp_graph (MSG_NOTE, vect_location,
    4831              :                                 SLP_INSTANCE_TREE (new_instance));
    4832              :         }
    4833              : 
    4834        93769 :       return true;
    4835              :     }
    4836              :   /* Failed to SLP.  */
    4837              : 
    4838              :   /* Free the allocated memory.  */
    4839         3007 :   scalar_stmts.release ();
    4840              : 
    4841              :   /* Failed to SLP.  */
    4842         3007 :   if (dump_enabled_p ())
    4843          120 :     dump_printf_loc (MSG_NOTE, vect_location, "SLP discovery failed\n");
    4844              :   return false;
    4845              : }
    4846              : 
    4847              : /* Analyze a single SLP reduction group.  If successful add a SLP instance
    4848              :    for it and return true, otherwise return false and have *MATCHES
    4849              :    populated.  */
    4850              : 
    4851              : static bool
    4852        24148 : vect_analyze_slp_reduction_group (loop_vec_info loop_vinfo,
    4853              :                                   vec<stmt_vec_info> scalar_stmts,
    4854              :                                   scalar_stmts_to_slp_tree_map_t *bst_map,
    4855              :                                   unsigned max_tree_size, unsigned *limit,
    4856              :                                   bool *matches)
    4857              : {
    4858              :   /* Try to form a reduction group.  Size-1 groups are not suitable
    4859              :      for SLP reduction and should fall back to single-lane reduction.  */
    4860        45533 :   unsigned int group_size = scalar_stmts.length ();
    4861        24148 :   if (group_size <= 1)
    4862              :     return false;
    4863        17471 :   if (!matches)
    4864         4550 :     matches = XALLOCAVEC (bool, group_size);
    4865        17471 :   poly_uint64 max_nunits = 1;
    4866        17471 :   unsigned tree_size = 0;
    4867        17471 :   slp_tree node = vect_build_slp_tree (loop_vinfo, scalar_stmts,
    4868              :                                        &max_nunits, matches, limit,
    4869              :                                        &tree_size, bst_map);
    4870        17471 :   if (!node)
    4871              :     return false;
    4872              : 
    4873              :   /* Create a new SLP instance.  */
    4874         2763 :   slp_instance new_instance = XNEW (class _slp_instance);
    4875         2763 :   SLP_INSTANCE_TREE (new_instance) = node;
    4876         2763 :   SLP_INSTANCE_LOADS (new_instance) = vNULL;
    4877         2763 :   SLP_INSTANCE_ROOT_STMTS (new_instance) = vNULL;
    4878         2763 :   SLP_INSTANCE_REMAIN_DEFS (new_instance) = vNULL;
    4879         2763 :   SLP_INSTANCE_KIND (new_instance) = slp_inst_kind_reduc_group;
    4880         2763 :   new_instance->reduc_phis = NULL;
    4881         2763 :   new_instance->cost_vec = vNULL;
    4882         2763 :   new_instance->subgraph_entries = vNULL;
    4883              : 
    4884         2763 :   if (dump_enabled_p ())
    4885          213 :     dump_printf_loc (MSG_NOTE, vect_location,
    4886              :                      "SLP size %u vs. limit %u.\n",
    4887              :                      tree_size, max_tree_size);
    4888              : 
    4889         2763 :   loop_vinfo->slp_instances.safe_push (new_instance);
    4890              : 
    4891              :   /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    4892              :      the number of scalar stmts in the root in a few places.
    4893              :      Verify that assumption holds.  */
    4894         5526 :   gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    4895              :               .length () == group_size);
    4896              : 
    4897         2763 :   if (dump_enabled_p ())
    4898              :     {
    4899          213 :       dump_printf_loc (MSG_NOTE, vect_location,
    4900              :                        "SLP discovery of size %d reduction group "
    4901              :                        "succeeded\n", group_size);
    4902          213 :       dump_printf_loc (MSG_NOTE, vect_location,
    4903              :                        "Final SLP tree for instance %p:\n",
    4904              :                        (void *) new_instance);
    4905          213 :       vect_print_slp_graph (MSG_NOTE, vect_location,
    4906              :                             SLP_INSTANCE_TREE (new_instance));
    4907              :     }
    4908              : 
    4909              :   return true;
    4910              : }
    4911              : 
    4912              : /* Analyze reductions in LOOP_VINFO and populate SLP instances
    4913              :    accordingly.  Returns false if something fails.  */
    4914              : 
    4915              : static bool
    4916       503996 : vect_analyze_slp_reductions (loop_vec_info loop_vinfo,
    4917              :                              unsigned max_tree_size, unsigned *limit,
    4918              :                              scalar_stmts_to_slp_tree_map_t *bst_map,
    4919              :                              bool force_single_lane)
    4920              : {
    4921       572840 :   if (loop_vinfo->reductions.is_empty ())
    4922              :     return true;
    4923              : 
    4924              :   /* Collect reduction statements we can combine into
    4925              :      a SLP reduction.  */
    4926        73407 :   vec<stmt_vec_info> scalar_stmts;
    4927        73407 :   scalar_stmts.create (loop_vinfo->reductions.length ());
    4928       325802 :   for (auto next_info : loop_vinfo->reductions)
    4929              :     {
    4930       105581 :       next_info = vect_stmt_to_vectorize (next_info);
    4931       105581 :       if ((STMT_VINFO_RELEVANT_P (next_info)
    4932           14 :            || STMT_VINFO_LIVE_P (next_info))
    4933              :           /* ???  Make sure we didn't skip a conversion around a
    4934              :              reduction path.  In that case we'd have to reverse
    4935              :              engineer that conversion stmt following the chain using
    4936              :              reduc_idx and from the PHI using reduc_def.  */
    4937       105567 :           && (STMT_VINFO_DEF_TYPE (next_info) == vect_reduction_def
    4938       105567 :               || (STMT_VINFO_DEF_TYPE (next_info)
    4939              :                   == vect_double_reduction_def)))
    4940              :         {
    4941              :           /* Do not discover SLP reductions combining lane-reducing
    4942              :              ops, that will fail later.  */
    4943       105567 :           if (!force_single_lane
    4944       105567 :               && !lane_reducing_stmt_p (STMT_VINFO_STMT (next_info)))
    4945        79074 :             scalar_stmts.quick_push (next_info);
    4946              :           /* Do SLP discovery for single-lane reductions.  */
    4947        26493 :           else if (! vect_analyze_slp_reduction (loop_vinfo, next_info,
    4948              :                                                  max_tree_size, limit,
    4949              :                                                  bst_map,
    4950              :                                                  force_single_lane))
    4951              :             {
    4952            0 :               scalar_stmts.release ();
    4953            0 :               return false;
    4954              :             }
    4955              :         }
    4956              :     }
    4957              : 
    4958        73407 :   if (scalar_stmts.length () > 1)
    4959              :     {
    4960              :       /* Try to form a reduction group.  */
    4961         4644 :       unsigned int group_size = scalar_stmts.length ();
    4962         4644 :       bool *matches = XALLOCAVEC (bool, group_size);
    4963         4644 :       if (vect_analyze_slp_reduction_group (loop_vinfo, scalar_stmts, bst_map,
    4964              :                                             max_tree_size, limit, matches))
    4965         1581 :         return true;
    4966              : 
    4967              :       /* When analysis as a single SLP reduction group failed try to
    4968              :          form sub-groups by collecting matching lanes.  Do not recurse
    4969              :          that on failure (to limit compile-time costs), but recurse
    4970              :          for the initial non-matching parts.  Everything not covered
    4971              :          by a sub-group gets single-reduction treatment.  */
    4972         3518 :       vec<stmt_vec_info> cands = vNULL;
    4973        11365 :       while (matches[0])
    4974              :         {
    4975        11227 :           cands.truncate (0);
    4976        11227 :           cands.reserve (group_size, true);
    4977        88333 :           for (unsigned i = 0; i < group_size; ++i)
    4978        77106 :             if (matches[i])
    4979        19560 :               cands.quick_push (scalar_stmts[i]);
    4980              : 
    4981              :           /* Try to form a reduction group.  */
    4982        11227 :           if (vect_analyze_slp_reduction_group (loop_vinfo, cands, bst_map,
    4983              :                                                 max_tree_size, limit, NULL))
    4984         1207 :             cands = vNULL;
    4985              :           else
    4986              :             {
    4987              :               /* Do SLP discovery for single-lane reductions.  */
    4988        47153 :               for (auto stmt_info : cands)
    4989        17118 :                 if (! vect_analyze_slp_reduction (loop_vinfo,
    4990              :                                                   vect_stmt_to_vectorize
    4991              :                                                     (stmt_info),
    4992              :                                                   max_tree_size, limit,
    4993              :                                                   bst_map, force_single_lane))
    4994              :                   {
    4995           25 :                     scalar_stmts.release ();
    4996           25 :                     cands.release ();
    4997           25 :                     return false;
    4998              :                   }
    4999              :             }
    5000              :           /* Remove the handled stmts from scalar_stmts and try again,
    5001              :              possibly repeating the above with updated matches[].  */
    5002              :           unsigned j = 0;
    5003        88238 :           for (unsigned i = 0; i < group_size; ++i)
    5004        77036 :             if (!matches[i])
    5005              :               {
    5006        57516 :                 scalar_stmts[j] = scalar_stmts[i];
    5007        57516 :                 ++j;
    5008              :               }
    5009        11202 :           scalar_stmts.truncate (j);
    5010        11202 :           group_size = scalar_stmts.length ();
    5011        11202 :           if (group_size <= 1)
    5012              :             break;
    5013         8277 :           if (vect_analyze_slp_reduction_group (loop_vinfo, scalar_stmts,
    5014              :                                                 bst_map, max_tree_size, limit,
    5015              :                                                 matches))
    5016              :             return true;
    5017              :         }
    5018              :     }
    5019              :   /* Do SLP discovery for single-lane reductions.  */
    5020       268068 :   for (auto stmt_info : scalar_stmts)
    5021        55572 :     if (! vect_analyze_slp_reduction (loop_vinfo,
    5022              :                                       vect_stmt_to_vectorize (stmt_info),
    5023              :                                       max_tree_size, limit,
    5024              :                                       bst_map, force_single_lane))
    5025              :       {
    5026         2982 :         scalar_stmts.release ();
    5027         2982 :         return false;
    5028              :       }
    5029              : 
    5030        68844 :   scalar_stmts.release ();
    5031        68844 :   return true;
    5032              : }
    5033              : 
    5034              : /* Analyze an SLP instance starting from a group of grouped stores.  Call
    5035              :    vect_build_slp_tree to build a tree of packed stmts if possible.
    5036              :    Return FALSE if it's impossible to SLP any stmt in the group.  */
    5037              : 
    5038              : static bool
    5039      1118724 : vect_analyze_slp_instance (vec_info *vinfo,
    5040              :                            scalar_stmts_to_slp_tree_map_t *bst_map,
    5041              :                            stmt_vec_info stmt_info,
    5042              :                            slp_instance_kind kind,
    5043              :                            unsigned max_tree_size, unsigned *limit,
    5044              :                            bool force_single_lane)
    5045              : {
    5046      1118724 :   vec<stmt_vec_info> scalar_stmts;
    5047              : 
    5048      1118724 :   if (is_a <bb_vec_info> (vinfo))
    5049      1088693 :     vect_location = stmt_info->stmt;
    5050              : 
    5051      1118724 :   gcc_assert (kind == slp_inst_kind_store);
    5052              : 
    5053              :   /* Collect the stores and store them in scalar_stmts.  */
    5054      1118724 :   scalar_stmts.create (DR_GROUP_SIZE (stmt_info));
    5055      1118724 :   stmt_vec_info next_info = stmt_info;
    5056      5560791 :   while (next_info)
    5057              :     {
    5058      3323343 :       scalar_stmts.quick_push (vect_stmt_to_vectorize (next_info));
    5059      3323343 :       next_info = DR_GROUP_NEXT_ELEMENT (next_info);
    5060              :     }
    5061              : 
    5062      1118724 :   vec<stmt_vec_info> root_stmt_infos = vNULL;
    5063      1118724 :   vec<tree> remain = vNULL;
    5064              : 
    5065              :   /* Build the tree for the SLP instance.  */
    5066              : 
    5067              :   /* If there's no budget left bail out early.  */
    5068      1118724 :   if (*limit == 0)
    5069              :     return false;
    5070              : 
    5071      1118704 :   if (dump_enabled_p ())
    5072              :     {
    5073         4127 :       dump_printf_loc (MSG_NOTE, vect_location,
    5074              :                        "Starting SLP discovery for\n");
    5075        24101 :       for (unsigned i = 0; i < scalar_stmts.length (); ++i)
    5076        39948 :         dump_printf_loc (MSG_NOTE, vect_location,
    5077        19974 :                          "  %G", scalar_stmts[i]->stmt);
    5078              :     }
    5079              : 
    5080              :   /* Build the tree for the SLP instance.  */
    5081      1118704 :   unsigned int group_size = scalar_stmts.length ();
    5082      1118704 :   bool *matches = XALLOCAVEC (bool, group_size);
    5083      1118704 :   poly_uint64 max_nunits = 1;
    5084      1118704 :   unsigned tree_size = 0;
    5085      1118704 :   unsigned i;
    5086              : 
    5087      1118704 :   slp_tree node = NULL;
    5088      1118704 :   if (group_size > 1 && force_single_lane)
    5089              :     {
    5090         1733 :       matches[0] = true;
    5091         1733 :       matches[1] = false;
    5092              :     }
    5093              :   else
    5094      1116971 :     node = vect_build_slp_tree (vinfo, scalar_stmts,
    5095              :                                 &max_nunits, matches, limit,
    5096              :                                 &tree_size, bst_map);
    5097      1118704 :   if (node != NULL)
    5098              :     {
    5099              :       /* Calculate the unrolling factor based on the smallest type.  */
    5100       693356 :       poly_uint64 unrolling_factor
    5101       693356 :         = calculate_unrolling_factor (max_nunits, group_size);
    5102              : 
    5103       693356 :       if (maybe_ne (unrolling_factor, 1U)
    5104       693356 :           && is_a <bb_vec_info> (vinfo))
    5105              :         {
    5106            0 :           unsigned HOST_WIDE_INT const_max_nunits;
    5107            0 :           if (!max_nunits.is_constant (&const_max_nunits)
    5108            0 :               || const_max_nunits > group_size)
    5109              :             {
    5110            0 :               if (dump_enabled_p ())
    5111            0 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    5112              :                                  "Build SLP failed: store group "
    5113              :                                  "size not a multiple of the vector size "
    5114              :                                  "in basic block SLP\n");
    5115            0 :               vect_free_slp_tree (node);
    5116            0 :               return false;
    5117              :             }
    5118              :           /* Fatal mismatch.  */
    5119            0 :           if (dump_enabled_p ())
    5120            0 :             dump_printf_loc (MSG_NOTE, vect_location,
    5121              :                              "SLP discovery succeeded but node needs "
    5122              :                              "splitting\n");
    5123            0 :           memset (matches, true, group_size);
    5124            0 :           matches[group_size / const_max_nunits * const_max_nunits] = false;
    5125            0 :           vect_free_slp_tree (node);
    5126              :         }
    5127              :       else
    5128              :         {
    5129              :           /* Create a new SLP instance.  */
    5130       693356 :           slp_instance new_instance = XNEW (class _slp_instance);
    5131       693356 :           SLP_INSTANCE_TREE (new_instance) = node;
    5132       693356 :           SLP_INSTANCE_LOADS (new_instance) = vNULL;
    5133       693356 :           SLP_INSTANCE_ROOT_STMTS (new_instance) = root_stmt_infos;
    5134       693356 :           SLP_INSTANCE_REMAIN_DEFS (new_instance) = remain;
    5135       693356 :           SLP_INSTANCE_KIND (new_instance) = kind;
    5136       693356 :           new_instance->reduc_phis = NULL;
    5137       693356 :           new_instance->cost_vec = vNULL;
    5138       693356 :           new_instance->subgraph_entries = vNULL;
    5139              : 
    5140       693356 :           if (dump_enabled_p ())
    5141         3122 :             dump_printf_loc (MSG_NOTE, vect_location,
    5142              :                              "SLP size %u vs. limit %u.\n",
    5143              :                              tree_size, max_tree_size);
    5144              : 
    5145       693356 :           vinfo->slp_instances.safe_push (new_instance);
    5146              : 
    5147              :           /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    5148              :              the number of scalar stmts in the root in a few places.
    5149              :              Verify that assumption holds.  */
    5150      1386712 :           gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    5151              :                         .length () == group_size);
    5152              : 
    5153       693356 :           if (dump_enabled_p ())
    5154              :             {
    5155         3122 :               dump_printf_loc (MSG_NOTE, vect_location,
    5156              :                                "Final SLP tree for instance %p:\n",
    5157              :                                (void *) new_instance);
    5158         3122 :               vect_print_slp_graph (MSG_NOTE, vect_location,
    5159              :                                     SLP_INSTANCE_TREE (new_instance));
    5160              :             }
    5161              : 
    5162       693356 :           return true;
    5163              :         }
    5164              :     }
    5165              :   /* Failed to SLP.  */
    5166              : 
    5167              :   /* Try to break the group up into pieces.  */
    5168       425348 :   if (*limit > 0 && kind == slp_inst_kind_store)
    5169              :     {
    5170              :       /* ???  We could delay all the actual splitting of store-groups
    5171              :          until after SLP discovery of the original group completed.
    5172              :          Then we can recurse to vect_build_slp_instance directly.  */
    5173      1112158 :       for (i = 0; i < group_size; i++)
    5174      1112158 :         if (!matches[i])
    5175              :           break;
    5176              : 
    5177              :       /* For basic block SLP, try to break the group up into multiples of
    5178              :          a vector size.  */
    5179       425347 :       if (is_a <bb_vec_info> (vinfo)
    5180       425347 :           && (i > 1 && i < group_size))
    5181              :         {
    5182              :           /* Free the allocated memory.  */
    5183       159338 :           scalar_stmts.release ();
    5184              : 
    5185       159338 :           tree scalar_type
    5186       159338 :             = TREE_TYPE (DR_REF (STMT_VINFO_DATA_REF (stmt_info)));
    5187       318676 :           tree vectype = get_vectype_for_scalar_type (vinfo, scalar_type,
    5188       159338 :                                                       1 << floor_log2 (i));
    5189       159338 :           unsigned HOST_WIDE_INT const_nunits;
    5190       159338 :           if (vectype
    5191       159338 :               && TYPE_VECTOR_SUBPARTS (vectype).is_constant (&const_nunits))
    5192              :             {
    5193              :               /* Split into two groups at the first vector boundary.  */
    5194       159338 :               gcc_assert ((const_nunits & (const_nunits - 1)) == 0);
    5195       159338 :               unsigned group1_size = i & ~(const_nunits - 1);
    5196              : 
    5197       159338 :               if (dump_enabled_p ())
    5198           66 :                 dump_printf_loc (MSG_NOTE, vect_location,
    5199              :                                  "Splitting SLP group at stmt %u\n", i);
    5200       159338 :               stmt_vec_info rest = vect_split_slp_store_group (stmt_info,
    5201              :                                                                group1_size);
    5202       159338 :               bool res = vect_analyze_slp_instance (vinfo, bst_map, stmt_info,
    5203              :                                                     kind, max_tree_size,
    5204              :                                                     limit, false);
    5205              :               /* Split the rest at the failure point and possibly
    5206              :                  re-analyze the remaining matching part if it has
    5207              :                  at least two lanes.  */
    5208       159338 :               if (group1_size < i
    5209         5667 :                   && (i + 1 < group_size
    5210         3064 :                       || i - group1_size > 1))
    5211              :                 {
    5212         2631 :                   stmt_vec_info rest2 = rest;
    5213         2631 :                   rest = vect_split_slp_store_group (rest, i - group1_size);
    5214         2631 :                   if (i - group1_size > 1)
    5215           57 :                     res |= vect_analyze_slp_instance (vinfo, bst_map, rest2,
    5216              :                                                       kind, max_tree_size,
    5217              :                                                       limit, false);
    5218              :                 }
    5219              :               /* Re-analyze the non-matching tail if it has at least
    5220              :                  two lanes.  */
    5221       159338 :               if (i + 1 < group_size)
    5222        22519 :                 res |= vect_analyze_slp_instance (vinfo, bst_map,
    5223              :                                                   rest, kind, max_tree_size,
    5224              :                                                   limit, false);
    5225       159338 :               return res;
    5226              :             }
    5227              :         }
    5228              : 
    5229              :       /* For loop vectorization split the RHS into arbitrary pieces of
    5230              :          size >= 1.  */
    5231       266009 :       else if (is_a <loop_vec_info> (vinfo)
    5232       266009 :                && (group_size != 1 && i < group_size))
    5233              :         {
    5234         8319 :           gcall *call = dyn_cast <gcall *> (stmt_info->stmt);
    5235           28 :           bool masked_p = call
    5236           28 :               && gimple_call_internal_p (call)
    5237           28 :               && internal_fn_mask_index (gimple_call_internal_fn (call)) != -1;
    5238              :           /* There are targets that cannot do even/odd interleaving schemes
    5239              :              so they absolutely need to use load/store-lanes.  For now
    5240              :              force single-lane SLP for them - they would be happy with
    5241              :              uniform power-of-two lanes (but depending on element size),
    5242              :              but even if we can use 'i' as indicator we would need to
    5243              :              backtrack when later lanes fail to discover with the same
    5244              :              granularity.  We cannot turn any of strided or scatter store
    5245              :              into store-lanes.  */
    5246              :           /* ???  If this is not in sync with what get_load_store_type
    5247              :              later decides the SLP representation is not good for other
    5248              :              store vectorization methods.  */
    5249         8319 :           bool want_store_lanes
    5250         8319 :             = (! STMT_VINFO_GATHER_SCATTER_P (stmt_info)
    5251         8319 :                && ! STMT_VINFO_STRIDED_P (stmt_info)
    5252         6219 :                && ! STMT_VINFO_SLP_VECT_ONLY (stmt_info)
    5253         6215 :                && compare_step_with_zero (vinfo, stmt_info) > 0
    5254        14445 :                && vect_slp_prefer_store_lanes_p (vinfo, stmt_info, NULL_TREE,
    5255        16638 :                                                  masked_p, group_size, i));
    5256         8319 :           if (want_store_lanes || force_single_lane)
    5257              :             i = 1;
    5258              : 
    5259              :           /* A fatal discovery fail doesn't always mean single-lane SLP
    5260              :              isn't a possibility, so try.  */
    5261         6586 :           if (i == 0)
    5262              :             i = 1;
    5263              : 
    5264         8319 :           if (dump_enabled_p ())
    5265          897 :             dump_printf_loc (MSG_NOTE, vect_location,
    5266              :                              "Splitting SLP group at stmt %u\n", i);
    5267              : 
    5268              :           /* Analyze the stored values and pinch them together with
    5269              :              a permute node so we can preserve the whole store group.  */
    5270         8319 :           auto_vec<slp_tree> rhs_nodes;
    5271         8319 :           poly_uint64 max_nunits = 1;
    5272              : 
    5273         8319 :           unsigned int rhs_common_nlanes = 0;
    5274         8319 :           unsigned int start = 0, end = i;
    5275        37229 :           while (start < group_size)
    5276              :             {
    5277        29173 :               gcc_assert (end - start >= 1);
    5278        29173 :               vec<stmt_vec_info> substmts;
    5279        29173 :               substmts.create (end - start);
    5280        90715 :               for (unsigned j = start; j < end; ++j)
    5281        61542 :                 substmts.quick_push (scalar_stmts[j]);
    5282        29173 :               max_nunits = 1;
    5283        29173 :               node = vect_build_slp_tree (vinfo, substmts,
    5284              :                                           &max_nunits,
    5285              :                                           matches, limit, &tree_size, bst_map);
    5286        29173 :               if (node)
    5287              :                 {
    5288        23311 :                   rhs_nodes.safe_push (node);
    5289        23311 :                   vect_update_max_nunits (&max_nunits, node->max_nunits);
    5290        23311 :                   if (start == 0)
    5291         8062 :                     rhs_common_nlanes = SLP_TREE_LANES (node);
    5292        15249 :                   else if (rhs_common_nlanes != SLP_TREE_LANES (node))
    5293         1375 :                     rhs_common_nlanes = 0;
    5294        23311 :                   start = end;
    5295        23311 :                   if (want_store_lanes || force_single_lane)
    5296         5207 :                     end = start + 1;
    5297              :                   else
    5298              :                     end = group_size;
    5299              :                 }
    5300              :               else
    5301              :                 {
    5302         5862 :                   substmts.release ();
    5303         5862 :                   if (end - start == 1)
    5304              :                     {
    5305              :                       /* Single-lane discovery failed.  Free resources.  */
    5306          283 :                       for (auto node : rhs_nodes)
    5307            8 :                         vect_free_slp_tree (node);
    5308          263 :                       scalar_stmts.release ();
    5309          263 :                       if (dump_enabled_p ())
    5310           39 :                         dump_printf_loc (MSG_NOTE, vect_location,
    5311              :                                          "SLP discovery failed\n");
    5312          263 :                       return false;
    5313              :                     }
    5314              : 
    5315              :                   /* ???  It really happens that we soft-fail SLP
    5316              :                      build at a mismatch but the matching part hard-fails
    5317              :                      later.  As we know we arrived here with a group
    5318              :                      larger than one try a group of size one!  */
    5319         5599 :                   if (!matches[0])
    5320           44 :                     end = start + 1;
    5321              :                   else
    5322        12209 :                     for (unsigned j = start; j < end; j++)
    5323        12209 :                       if (!matches[j - start])
    5324              :                         {
    5325              :                           end = j;
    5326              :                           break;
    5327              :                         }
    5328              :                 }
    5329              :             }
    5330              : 
    5331              :           /* Now re-assess whether we want store lanes in case the
    5332              :              discovery ended up producing all single-lane RHSs.  */
    5333         8056 :           if (! want_store_lanes
    5334         8056 :               && rhs_common_nlanes == 1
    5335         7007 :               && ! STMT_VINFO_GATHER_SCATTER_P (stmt_info)
    5336         7007 :               && ! STMT_VINFO_STRIDED_P (stmt_info)
    5337         5272 :               && ! STMT_VINFO_SLP_VECT_ONLY (stmt_info)
    5338         5269 :               && compare_step_with_zero (vinfo, stmt_info) > 0
    5339        13264 :               && (vect_store_lanes_supported (SLP_TREE_VECTYPE (rhs_nodes[0]),
    5340              :                                               group_size, masked_p)
    5341              :                   != IFN_LAST))
    5342              :             want_store_lanes = true;
    5343              : 
    5344              :           /* Now we assume we can build the root SLP node from all stores.  */
    5345         8056 :           if (want_store_lanes)
    5346              :             {
    5347              :               /* For store-lanes feed the store node with all RHS nodes
    5348              :                  in order.  */
    5349            0 :               node = vect_create_new_slp_node (scalar_stmts,
    5350            0 :                                                SLP_TREE_CHILDREN
    5351              :                                                  (rhs_nodes[0]).length ());
    5352            0 :               SLP_TREE_VECTYPE (node) = SLP_TREE_VECTYPE (rhs_nodes[0]);
    5353            0 :               node->max_nunits = max_nunits;
    5354            0 :               node->ldst_lanes = true;
    5355            0 :               SLP_TREE_CHILDREN (node)
    5356            0 :                 .reserve_exact (SLP_TREE_CHILDREN (rhs_nodes[0]).length ()
    5357            0 :                                 + rhs_nodes.length () - 1);
    5358              :               /* First store value and possibly mask.  */
    5359            0 :               SLP_TREE_CHILDREN (node)
    5360            0 :                 .splice (SLP_TREE_CHILDREN (rhs_nodes[0]));
    5361              :               /* Rest of the store values.  All mask nodes are the same,
    5362              :                  this should be guaranteed by dataref group discovery.  */
    5363            0 :               for (unsigned j = 1; j < rhs_nodes.length (); ++j)
    5364            0 :                 SLP_TREE_CHILDREN (node)
    5365            0 :                   .quick_push (SLP_TREE_CHILDREN (rhs_nodes[j])[0]);
    5366            0 :               for (slp_tree child : SLP_TREE_CHILDREN (node))
    5367            0 :                 child->refcnt++;
    5368              :             }
    5369              :           else
    5370         8056 :             node = vect_build_slp_store_interleaving (rhs_nodes, scalar_stmts,
    5371              :                                                       max_nunits);
    5372              : 
    5373        31359 :           while (!rhs_nodes.is_empty ())
    5374        23303 :             vect_free_slp_tree (rhs_nodes.pop ());
    5375              : 
    5376              :           /* Create a new SLP instance.  */
    5377         8056 :           slp_instance new_instance = XNEW (class _slp_instance);
    5378         8056 :           SLP_INSTANCE_TREE (new_instance) = node;
    5379         8056 :           SLP_INSTANCE_LOADS (new_instance) = vNULL;
    5380         8056 :           SLP_INSTANCE_ROOT_STMTS (new_instance) = root_stmt_infos;
    5381         8056 :           SLP_INSTANCE_REMAIN_DEFS (new_instance) = remain;
    5382         8056 :           SLP_INSTANCE_KIND (new_instance) = kind;
    5383         8056 :           new_instance->reduc_phis = NULL;
    5384         8056 :           new_instance->cost_vec = vNULL;
    5385         8056 :           new_instance->subgraph_entries = vNULL;
    5386              : 
    5387         8056 :           if (dump_enabled_p ())
    5388          858 :             dump_printf_loc (MSG_NOTE, vect_location,
    5389              :                              "SLP size %u vs. limit %u.\n",
    5390              :                              tree_size, max_tree_size);
    5391              : 
    5392         8056 :           vinfo->slp_instances.safe_push (new_instance);
    5393              : 
    5394              :           /* ???  We've replaced the old SLP_INSTANCE_GROUP_SIZE with
    5395              :              the number of scalar stmts in the root in a few places.
    5396              :              Verify that assumption holds.  */
    5397        16112 :           gcc_assert (SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (new_instance))
    5398              :                         .length () == group_size);
    5399              : 
    5400         8056 :           if (dump_enabled_p ())
    5401              :             {
    5402          858 :               dump_printf_loc (MSG_NOTE, vect_location,
    5403              :                                "Final SLP tree for instance %p:\n",
    5404              :                                (void *) new_instance);
    5405          858 :               vect_print_slp_graph (MSG_NOTE, vect_location,
    5406              :                                     SLP_INSTANCE_TREE (new_instance));
    5407              :             }
    5408         8056 :           return true;
    5409         8319 :         }
    5410              :       else
    5411              :         /* Free the allocated memory.  */
    5412       257690 :         scalar_stmts.release ();
    5413              : 
    5414              :       /* Even though the first vector did not all match, we might be able to SLP
    5415              :          (some) of the remainder.  FORNOW ignore this possibility.  */
    5416              :     }
    5417              :   else
    5418              :     /* Free the allocated memory.  */
    5419            1 :     scalar_stmts.release ();
    5420              : 
    5421              :   /* Failed to SLP.  */
    5422       257691 :   if (dump_enabled_p ())
    5423           42 :     dump_printf_loc (MSG_NOTE, vect_location, "SLP discovery failed\n");
    5424              :   return false;
    5425              : }
    5426              : 
    5427              : /* qsort comparator ordering SLP load nodes.  */
    5428              : 
    5429              : static int
    5430      2664531 : vllp_cmp (const void *a_, const void *b_)
    5431              : {
    5432      2664531 :   const slp_tree a = *(const slp_tree *)a_;
    5433      2664531 :   const slp_tree b = *(const slp_tree *)b_;
    5434      2664531 :   stmt_vec_info a0 = SLP_TREE_SCALAR_STMTS (a)[0];
    5435      2664531 :   stmt_vec_info b0 = SLP_TREE_SCALAR_STMTS (b)[0];
    5436      2664531 :   if (STMT_VINFO_GROUPED_ACCESS (a0)
    5437      1542763 :       && STMT_VINFO_GROUPED_ACCESS (b0)
    5438      4145954 :       && DR_GROUP_FIRST_ELEMENT (a0) == DR_GROUP_FIRST_ELEMENT (b0))
    5439              :     {
    5440              :       /* Same group, order after lanes used.  */
    5441       345656 :       if (SLP_TREE_LANES (a) < SLP_TREE_LANES (b))
    5442              :         return 1;
    5443       336865 :       else if (SLP_TREE_LANES (a) > SLP_TREE_LANES (b))
    5444              :         return -1;
    5445              :       else
    5446              :         {
    5447              :           /* Try to order loads using the same lanes together, breaking
    5448              :              the tie with the lane number that first differs.  */
    5449       327325 :           if (!SLP_TREE_LOAD_PERMUTATION (a).exists ()
    5450       327325 :               && !SLP_TREE_LOAD_PERMUTATION (b).exists ())
    5451              :             return 0;
    5452       327325 :           else if (SLP_TREE_LOAD_PERMUTATION (a).exists ()
    5453       327325 :                    && !SLP_TREE_LOAD_PERMUTATION (b).exists ())
    5454              :             return 1;
    5455       323270 :           else if (!SLP_TREE_LOAD_PERMUTATION (a).exists ()
    5456       323270 :                    && SLP_TREE_LOAD_PERMUTATION (b).exists ())
    5457              :             return -1;
    5458              :           else
    5459              :             {
    5460       315792 :               for (unsigned i = 0; i < SLP_TREE_LANES (a); ++i)
    5461       315792 :                 if (SLP_TREE_LOAD_PERMUTATION (a)[i]
    5462       315792 :                     != SLP_TREE_LOAD_PERMUTATION (b)[i])
    5463              :                   {
    5464              :                     /* In-order lane first, that's what the above case for
    5465              :                        no permutation does.  */
    5466       314480 :                     if (SLP_TREE_LOAD_PERMUTATION (a)[i] == i)
    5467              :                       return -1;
    5468       192586 :                     else if (SLP_TREE_LOAD_PERMUTATION (b)[i] == i)
    5469              :                       return 1;
    5470       101058 :                     else if (SLP_TREE_LOAD_PERMUTATION (a)[i]
    5471       101058 :                              < SLP_TREE_LOAD_PERMUTATION (b)[i])
    5472              :                       return -1;
    5473              :                     else
    5474              :                       return 1;
    5475              :                   }
    5476              :               return 0;
    5477              :             }
    5478              :         }
    5479              :     }
    5480              :   else /* Different groups or non-groups.  */
    5481              :     {
    5482              :       /* Order groups as their first element to keep them together.  */
    5483      2318875 :       if (STMT_VINFO_GROUPED_ACCESS (a0))
    5484      2318875 :         a0 = DR_GROUP_FIRST_ELEMENT (a0);
    5485      2318875 :       if (STMT_VINFO_GROUPED_ACCESS (b0))
    5486      2318875 :         b0 = DR_GROUP_FIRST_ELEMENT (b0);
    5487      2318875 :       if (a0 == b0)
    5488              :         return 0;
    5489              :       /* Tie using UID.  */
    5490      2318755 :       else if (gimple_uid (STMT_VINFO_STMT (a0))
    5491      2318755 :                < gimple_uid (STMT_VINFO_STMT (b0)))
    5492              :         return -1;
    5493              :       else
    5494              :         {
    5495      1030512 :           gcc_assert (gimple_uid (STMT_VINFO_STMT (a0))
    5496              :                       != gimple_uid (STMT_VINFO_STMT (b0)));
    5497              :           return 1;
    5498              :         }
    5499              :     }
    5500              : }
    5501              : 
    5502              : /* Return whether if the load permutation of NODE is consecutive starting
    5503              :    with value START_VAL in the first element.  If START_VAL is not given
    5504              :    the first element's value is used.  */
    5505              : 
    5506              : bool
    5507       637002 : vect_load_perm_consecutive_p (slp_tree node, unsigned start_val)
    5508              : {
    5509       637002 :   load_permutation_t perm = SLP_TREE_LOAD_PERMUTATION (node);
    5510              : 
    5511       637002 :   if (!perm.exists () || !perm.length ())
    5512              :     return false;
    5513              : 
    5514       637002 :   if (start_val == UINT_MAX)
    5515        79425 :     start_val = perm[0];
    5516              : 
    5517      1257884 :   for (unsigned int i = 0; i < perm.length (); i++)
    5518       644293 :     if (perm[i] != start_val + (unsigned int) i)
    5519              :       return false;
    5520              : 
    5521              :   return true;
    5522              : }
    5523              : 
    5524              : /* Process the set of LOADS that are all from the same dataref group.  */
    5525              : 
    5526              : static void
    5527       161498 : vect_lower_load_permutations (loop_vec_info loop_vinfo,
    5528              :                               scalar_stmts_to_slp_tree_map_t *bst_map,
    5529              :                               const array_slice<slp_tree> &loads,
    5530              :                               bool force_single_lane)
    5531              : {
    5532              :   /* We at this point want to lower without a fixed VF or vector
    5533              :      size in mind which means we cannot actually compute whether we
    5534              :      need three or more vectors for a load permutation yet.  So always
    5535              :      lower.  */
    5536       161498 :   stmt_vec_info first
    5537       161498 :     = DR_GROUP_FIRST_ELEMENT (SLP_TREE_SCALAR_STMTS (loads[0])[0]);
    5538       161498 :   unsigned group_lanes = DR_GROUP_SIZE (first);
    5539              : 
    5540              :   /* Verify if all load permutations can be implemented with a suitably
    5541              :      large element load-lanes operation.  */
    5542       161498 :   unsigned ld_lanes_lanes = SLP_TREE_LANES (loads[0]);
    5543       161498 :   if (STMT_VINFO_STRIDED_P (first)
    5544       159051 :       || compare_step_with_zero (loop_vinfo, first) <= 0
    5545       156387 :       || exact_log2 (ld_lanes_lanes) == -1
    5546              :       /* ???  For now only support the single-lane case as there is
    5547              :          missing support on the store-lane side and code generation
    5548              :          isn't up to the task yet.  */
    5549       153600 :       || ld_lanes_lanes != 1
    5550       304128 :       || vect_load_lanes_supported (SLP_TREE_VECTYPE (loads[0]),
    5551              :                                     group_lanes / ld_lanes_lanes,
    5552              :                                     false) == IFN_LAST)
    5553              :     ld_lanes_lanes = 0;
    5554              :   else
    5555              :     /* Verify the loads access the same number of lanes aligned to
    5556              :        ld_lanes_lanes.  */
    5557            0 :     for (slp_tree load : loads)
    5558              :       {
    5559            0 :         if (SLP_TREE_LANES (load) != ld_lanes_lanes)
    5560              :           {
    5561              :             ld_lanes_lanes = 0;
    5562              :             break;
    5563              :           }
    5564            0 :         unsigned first = SLP_TREE_LOAD_PERMUTATION (load)[0];
    5565            0 :         if (first % ld_lanes_lanes != 0)
    5566              :           {
    5567              :             ld_lanes_lanes = 0;
    5568              :             break;
    5569              :           }
    5570            0 :         if (!vect_load_perm_consecutive_p (load))
    5571              :           {
    5572              :             ld_lanes_lanes = 0;
    5573              :             break;
    5574              :           }
    5575              :       }
    5576              : 
    5577              :   /* Only a power-of-two number of lanes matches interleaving with N levels.
    5578              :      ???  An even number of lanes could be reduced to 1<<ceil_log2(N)-1 lanes
    5579              :      at each step.  */
    5580       262025 :   if (ld_lanes_lanes == 0 && exact_log2 (group_lanes) == -1 && group_lanes != 3)
    5581              :     return;
    5582              : 
    5583       265495 :   for (slp_tree load : loads)
    5584              :     {
    5585              :       /* Leave masked or gather loads alone for now.  */
    5586       187391 :       if (!SLP_TREE_CHILDREN (load).is_empty ())
    5587        60685 :         continue;
    5588              : 
    5589              :       /* For single-element interleaving spanning multiple vectors avoid
    5590              :          lowering, we want to use VMAT_ELEMENTWISE later.  */
    5591       187385 :       if (ld_lanes_lanes == 0
    5592       187385 :           && SLP_TREE_LANES (load) == 1
    5593       168019 :           && !DR_GROUP_NEXT_ELEMENT (first)
    5594       267033 :           && maybe_gt (group_lanes,
    5595              :                        TYPE_VECTOR_SUBPARTS (SLP_TREE_VECTYPE (load))))
    5596        51294 :         return;
    5597              : 
    5598              :       /* We want to pattern-match special cases here and keep those
    5599              :          alone.  Candidates are splats and load-lane.  */
    5600              : 
    5601              :       /* We need to lower only loads of less than half of the groups
    5602              :          lanes, including duplicate lanes.  Note this leaves nodes
    5603              :          with a non-1:1 load permutation around instead of canonicalizing
    5604              :          those into a load and a permute node.  Removing this early
    5605              :          check would do such canonicalization.  */
    5606       136091 :       if (SLP_TREE_LANES (load) >= (group_lanes + 1) / 2
    5607        57099 :           && ld_lanes_lanes == 0)
    5608        57099 :         continue;
    5609              : 
    5610              :       /* Build the permute to get the original load permutation order.  */
    5611        78992 :       bool contiguous = vect_load_perm_consecutive_p (load);
    5612        78992 :       lane_permutation_t final_perm;
    5613        78992 :       final_perm.create (SLP_TREE_LANES (load));
    5614       158898 :       for (unsigned i = 0; i < SLP_TREE_LANES (load); ++i)
    5615       159812 :         final_perm.quick_push (
    5616        79906 :           std::make_pair (0, SLP_TREE_LOAD_PERMUTATION (load)[i]));
    5617              : 
    5618              :       /* When the load permutation accesses a contiguous unpermuted,
    5619              :          power-of-two aligned and sized chunk leave the load alone.
    5620              :          We can likely (re-)load it more efficiently rather than
    5621              :          extracting it from the larger load.
    5622              :          ???  Long-term some of the lowering should move to where
    5623              :          the vector types involved are fixed.  */
    5624        82572 :       if (!force_single_lane
    5625        78992 :           && ld_lanes_lanes == 0
    5626        53168 :           && contiguous
    5627        52925 :           && (SLP_TREE_LANES (load) > 1 || loads.size () == 1)
    5628         6576 :           && pow2p_hwi (SLP_TREE_LANES (load))
    5629         6540 :           && pow2p_hwi (group_lanes)
    5630         3580 :           && SLP_TREE_LOAD_PERMUTATION (load)[0] % SLP_TREE_LANES (load) == 0
    5631        82572 :           && group_lanes % SLP_TREE_LANES (load) == 0)
    5632              :         {
    5633         3580 :           final_perm.release ();
    5634         3580 :           continue;
    5635              :         }
    5636              : 
    5637              :       /* First build (and possibly re-use) a load node for the
    5638              :          unpermuted group.  Gaps in the middle and on the end are
    5639              :          represented with NULL stmts.  */
    5640        75412 :       vec<stmt_vec_info> stmts;
    5641        75412 :       stmts.create (group_lanes);
    5642       268639 :       for (stmt_vec_info s = first; s; s = DR_GROUP_NEXT_ELEMENT (s))
    5643              :         {
    5644       193227 :           if (s != first)
    5645       122668 :             for (unsigned i = 1; i < DR_GROUP_GAP (s); ++i)
    5646         4853 :               stmts.quick_push (NULL);
    5647       193227 :           stmts.quick_push (s);
    5648              :         }
    5649       138987 :       for (unsigned i = 0; i < DR_GROUP_GAP (first); ++i)
    5650        63575 :         stmts.quick_push (NULL);
    5651        75412 :       poly_uint64 max_nunits = 1;
    5652        75412 :       bool *matches = XALLOCAVEC (bool, group_lanes);
    5653        75412 :       unsigned limit = 1;
    5654        75412 :       unsigned tree_size = 0;
    5655        75412 :       slp_tree l0 = vect_build_slp_tree (loop_vinfo, stmts,
    5656              :                                          &max_nunits, matches, &limit,
    5657        75412 :                                          &tree_size, bst_map);
    5658        75412 :       gcc_assert (!SLP_TREE_LOAD_PERMUTATION (l0).exists ());
    5659              : 
    5660        75412 :       if (ld_lanes_lanes != 0)
    5661              :         {
    5662              :           /* ???  If this is not in sync with what get_load_store_type
    5663              :              later decides the SLP representation is not good for other
    5664              :              store vectorization methods.  */
    5665            0 :           l0->ldst_lanes = true;
    5666            0 :           load->ldst_lanes = true;
    5667              :         }
    5668              : 
    5669       234746 :       while (1)
    5670              :         {
    5671       155079 :           unsigned group_lanes = SLP_TREE_LANES (l0);
    5672       155079 :           if (ld_lanes_lanes != 0
    5673       155079 :               || SLP_TREE_LANES (load) >= (group_lanes + 1) / 2)
    5674              :             break;
    5675              : 
    5676              :           /* Try to lower by reducing the group to half its size using an
    5677              :              interleaving scheme.  For this try to compute whether all
    5678              :              elements needed for this load are in even or odd elements of
    5679              :              an even/odd decomposition with N consecutive elements.
    5680              :              Thus { e, e, o, o, e, e, o, o } would be an even/odd decomposition
    5681              :              with N == 2.  */
    5682              :           /* ???  Only an even number of lanes can be handed this way, but the
    5683              :              fallback below could work for any number.  We have to make sure
    5684              :              to round up in that case.  */
    5685        79667 :           gcc_assert ((group_lanes & 1) == 0 || group_lanes == 3);
    5686        11858 :           unsigned even = 0, odd = 0;
    5687        11858 :           if ((group_lanes & 1) == 0)
    5688              :             {
    5689        11858 :               even = (1 << ceil_log2 (group_lanes)) - 1;
    5690        11858 :               odd = even;
    5691        48109 :               for (auto l : final_perm)
    5692              :                 {
    5693        12535 :                   even &= ~l.second;
    5694        12535 :                   odd &= l.second;
    5695              :                 }
    5696              :             }
    5697              : 
    5698              :           /* Now build an even or odd extraction from the unpermuted load.  */
    5699        79667 :           lane_permutation_t perm;
    5700        79667 :           perm.create ((group_lanes + 1) / 2);
    5701        79667 :           unsigned even_level = even ? 1 << ctz_hwi (even) : 0;
    5702        79667 :           unsigned odd_level = odd ? 1 << ctz_hwi (odd) : 0;
    5703        79667 :           if (even_level
    5704        10935 :               && group_lanes % (2 * even_level) == 0
    5705              :               /* ???  When code generating permutes we do not try to pun
    5706              :                  to larger component modes so level != 1 isn't a natural
    5707              :                  even/odd extract.  Prefer one if possible.  */
    5708        10935 :               && (even_level == 1 || !odd_level || odd_level != 1))
    5709              :             {
    5710              :               /* { 0, 1, ... 4, 5 ..., } */
    5711        38623 :               for (unsigned i = 0; i < group_lanes / 2 / even_level; ++i)
    5712        60858 :                 for (unsigned j = 0; j < even_level; ++j)
    5713        30602 :                   perm.quick_push (std::make_pair (0, 2 * i * even_level + j));
    5714              :             }
    5715        68732 :           else if (odd_level)
    5716              :             {
    5717              :               /* { ..., 2, 3, ... 6, 7 } */
    5718         3461 :               gcc_assert (group_lanes % (2 * odd_level) == 0);
    5719        15029 :               for (unsigned i = 0; i < group_lanes / 2 / odd_level; ++i)
    5720        23190 :                 for (unsigned j = 0; j < odd_level; ++j)
    5721        11622 :                   perm.quick_push
    5722        11622 :                     (std::make_pair (0, (2 * i + 1) * odd_level + j));
    5723              :             }
    5724              :           else
    5725              :             {
    5726              :               /* As fallback extract all used lanes and fill to half the
    5727              :                  group size by repeating the last element.
    5728              :                  ???  This is quite a bad strathegy for re-use - we could
    5729              :                  brute force our way to find more optimal filling lanes to
    5730              :                  maximize re-use when looking at all loads from the group.  */
    5731        67839 :               auto_bitmap l;
    5732       271412 :               for (auto p : final_perm)
    5733        67895 :                 bitmap_set_bit (l, p.second);
    5734        67839 :               unsigned i = 0;
    5735        67839 :               bitmap_iterator bi;
    5736       135734 :               EXECUTE_IF_SET_IN_BITMAP (l, 0, i, bi)
    5737        67895 :                   perm.quick_push (std::make_pair (0, i));
    5738       271508 :               while (perm.length () < (group_lanes + 1) / 2)
    5739        67915 :                 perm.quick_push (perm.last ());
    5740        67839 :             }
    5741              : 
    5742              :           /* Update final_perm with the intermediate permute.  */
    5743       160011 :           for (unsigned i = 0; i < final_perm.length (); ++i)
    5744              :             {
    5745        80344 :               unsigned l = final_perm[i].second;
    5746        80344 :               unsigned j;
    5747        89074 :               for (j = 0; j < perm.length (); ++j)
    5748        89074 :                 if (perm[j].second == l)
    5749              :                   {
    5750        80344 :                     final_perm[i].second = j;
    5751        80344 :                     break;
    5752              :                   }
    5753        80344 :               gcc_assert (j < perm.length ());
    5754              :             }
    5755              : 
    5756              :           /* And create scalar stmts.  */
    5757        79667 :           vec<stmt_vec_info> perm_stmts;
    5758        79667 :           perm_stmts.create (perm.length ());
    5759       257701 :           for (unsigned i = 0; i < perm.length (); ++i)
    5760       178034 :             perm_stmts.quick_push (SLP_TREE_SCALAR_STMTS (l0)[perm[i].second]);
    5761              : 
    5762        79667 :           slp_tree p = vect_create_new_slp_node (1, VEC_PERM_EXPR);
    5763        79667 :           SLP_TREE_CHILDREN (p).quick_push (l0);
    5764        79667 :           SLP_TREE_LANE_PERMUTATION (p) = perm;
    5765        79667 :           SLP_TREE_VECTYPE (p) = SLP_TREE_VECTYPE (load);
    5766        79667 :           SLP_TREE_LANES (p) = perm.length ();
    5767        79667 :           SLP_TREE_REPRESENTATIVE (p) = SLP_TREE_REPRESENTATIVE (load);
    5768              :           /* ???  As we have scalar stmts for this intermediate permute we
    5769              :              could CSE it via bst_map but we do not want to pick up
    5770              :              another SLP node with a load permutation.  We instead should
    5771              :              have a "local" CSE map here.  */
    5772        79667 :           SLP_TREE_SCALAR_STMTS (p) = perm_stmts;
    5773              : 
    5774              :           /* We now have a node for (group_lanes + 1) / 2 lanes.  */
    5775        79667 :           l0 = p;
    5776        79667 :         }
    5777              : 
    5778              :       /* And finally from the ordered reduction node create the
    5779              :          permute to shuffle the lanes into the original load-permutation
    5780              :          order.  We replace the original load node with this.  */
    5781        75412 :       SLP_TREE_CODE (load) = VEC_PERM_EXPR;
    5782        75412 :       SLP_TREE_LOAD_PERMUTATION (load).release ();
    5783        75412 :       SLP_TREE_LANE_PERMUTATION (load) = final_perm;
    5784        75412 :       SLP_TREE_CHILDREN (load).create (1);
    5785        75412 :       SLP_TREE_CHILDREN (load).quick_push (l0);
    5786              :     }
    5787              : }
    5788              : 
    5789              : /* Transform SLP loads in the SLP graph created by SLP discovery to
    5790              :    group loads from the same group and lower load permutations that
    5791              :    are unlikely to be supported into a series of permutes.
    5792              :    In the degenerate case of having only single-lane SLP instances
    5793              :    this should result in a series of permute nodes emulating an
    5794              :    interleaving scheme.  */
    5795              : 
    5796              : static void
    5797       485653 : vect_lower_load_permutations (loop_vec_info loop_vinfo,
    5798              :                               scalar_stmts_to_slp_tree_map_t *bst_map,
    5799              :                               bool force_single_lane)
    5800              : {
    5801              :   /* Gather and sort loads across all instances.  */
    5802       485653 :   hash_set<slp_tree> visited;
    5803       485653 :   auto_vec<slp_tree> loads;
    5804      2231028 :   for (auto inst : loop_vinfo->slp_instances)
    5805       776011 :     vect_gather_slp_loads (loads, SLP_INSTANCE_TREE (inst), visited);
    5806       485653 :   if (loads.is_empty ())
    5807        91163 :     return;
    5808       394490 :   loads.qsort (vllp_cmp);
    5809              : 
    5810              :   /* Now process each dataref group separately.  */
    5811       394490 :   unsigned firsti = 0;
    5812       734289 :   for (unsigned i = 1; i < loads.length (); ++i)
    5813              :     {
    5814       339799 :       slp_tree first = loads[firsti];
    5815       339799 :       slp_tree next = loads[i];
    5816       339799 :       stmt_vec_info a0 = SLP_TREE_SCALAR_STMTS (first)[0];
    5817       339799 :       stmt_vec_info b0 = SLP_TREE_SCALAR_STMTS (next)[0];
    5818       339799 :       if (STMT_VINFO_GROUPED_ACCESS (a0)
    5819       158243 :           && STMT_VINFO_GROUPED_ACCESS (b0)
    5820       484975 :           && DR_GROUP_FIRST_ELEMENT (a0) == DR_GROUP_FIRST_ELEMENT (b0))
    5821        63064 :         continue;
    5822              :       /* Now we have one or multiple SLP loads of the same group from
    5823              :          firsti to i - 1.  */
    5824       276735 :       if (STMT_VINFO_GROUPED_ACCESS (a0))
    5825        95179 :         vect_lower_load_permutations (loop_vinfo, bst_map,
    5826        95179 :                                       make_array_slice (&loads[firsti],
    5827              :                                                         i - firsti),
    5828              :                                       force_single_lane);
    5829              :       firsti = i;
    5830              :     }
    5831       788980 :   if (firsti < loads.length ()
    5832       788980 :       && STMT_VINFO_GROUPED_ACCESS (SLP_TREE_SCALAR_STMTS (loads[firsti])[0]))
    5833        66319 :     vect_lower_load_permutations (loop_vinfo, bst_map,
    5834        66319 :                                   make_array_slice (&loads[firsti],
    5835        66319 :                                                     loads.length () - firsti),
    5836              :                                   force_single_lane);
    5837       485653 : }
    5838              : 
    5839              : /* Check if there are stmts in the loop can be vectorized using SLP.  Build SLP
    5840              :    trees of packed scalar stmts if SLP is possible.  */
    5841              : 
    5842              : opt_result
    5843      1140723 : vect_analyze_slp (vec_info *vinfo, unsigned max_tree_size,
    5844              :                   bool force_single_lane)
    5845              : {
    5846      1140723 :   loop_vec_info loop_vinfo = dyn_cast <loop_vec_info> (vinfo);
    5847      1140723 :   unsigned int i;
    5848      1140723 :   stmt_vec_info first_element;
    5849      1140723 :   slp_instance instance;
    5850              : 
    5851      1140723 :   DUMP_VECT_SCOPE ("vect_analyze_slp");
    5852              : 
    5853      1140723 :   unsigned limit = max_tree_size;
    5854              : 
    5855      1140723 :   scalar_stmts_to_slp_tree_map_t *bst_map
    5856      1140723 :     = new scalar_stmts_to_slp_tree_map_t ();
    5857              : 
    5858              :   /* Find SLP sequences starting from groups of grouped stores.  */
    5859      3217985 :   FOR_EACH_VEC_ELT (vinfo->grouped_stores, i, first_element)
    5860       936810 :     if (! vect_analyze_slp_instance (vinfo, bst_map, first_element,
    5861              :                                      slp_inst_kind_store, max_tree_size, &limit,
    5862              :                                      force_single_lane)
    5863       936810 :         && loop_vinfo)
    5864              :       {
    5865          271 :         release_scalar_stmts_to_slp_tree_map (bst_map);
    5866          271 :         return opt_result::failure_at (vect_location, "SLP build failed.\n");
    5867              :       }
    5868              : 
    5869              :   /* For loops also start SLP discovery from non-grouped stores.  */
    5870      1140452 :   if (loop_vinfo)
    5871              :     {
    5872              :       data_reference_p dr;
    5873      1662348 :       FOR_EACH_VEC_ELT (vinfo->shared->datarefs, i, dr)
    5874      1158352 :         if (DR_IS_WRITE (dr))
    5875              :           {
    5876       374664 :             stmt_vec_info stmt_info = vinfo->lookup_dr (dr)->stmt;
    5877              :             /* Grouped stores are already handled above.  */
    5878       374664 :             if (STMT_VINFO_GROUPED_ACCESS (stmt_info))
    5879       101615 :               continue;
    5880       273049 :             vec<stmt_vec_info> stmts;
    5881       273049 :             vec<stmt_vec_info> roots = vNULL;
    5882       273049 :             vec<tree> remain = vNULL;
    5883       273049 :             stmts.create (1);
    5884       273049 :             stmts.quick_push (stmt_info);
    5885       273049 :             if (! vect_build_slp_instance (vinfo, slp_inst_kind_store,
    5886              :                                            stmts, roots, remain, max_tree_size,
    5887              :                                            &limit, bst_map, force_single_lane))
    5888              :               {
    5889         7006 :                 release_scalar_stmts_to_slp_tree_map (bst_map);
    5890         7006 :                 return opt_result::failure_at (vect_location,
    5891              :                                                "SLP build failed.\n");
    5892              :               }
    5893              :           }
    5894              : 
    5895              :       stmt_vec_info stmt_info;
    5896       504036 :       FOR_EACH_VEC_ELT (LOOP_VINFO_ALTERNATE_DEFS (loop_vinfo), i, stmt_info)
    5897              :         {
    5898           20 :           vec<stmt_vec_info> stmts;
    5899           20 :           vec<stmt_vec_info> roots = vNULL;
    5900           20 :           vec<tree> remain = vNULL;
    5901           20 :           stmts.create (1);
    5902           20 :           stmts.quick_push (stmt_info);
    5903           20 :           if (! vect_build_slp_instance (vinfo, slp_inst_kind_store,
    5904              :                                          stmts, roots, remain, max_tree_size,
    5905              :                                          &limit, bst_map, force_single_lane))
    5906              :             {
    5907            0 :               release_scalar_stmts_to_slp_tree_map (bst_map);
    5908            0 :               return opt_result::failure_at (vect_location,
    5909              :                                              "SLP build failed.\n");
    5910              :             }
    5911              :         }
    5912              :     }
    5913              : 
    5914      1133446 :   if (bb_vec_info bb_vinfo = dyn_cast <bb_vec_info> (vinfo))
    5915              :     {
    5916      1923778 :       for (unsigned i = 0; i < bb_vinfo->roots.length (); ++i)
    5917              :         {
    5918      1294328 :           vect_location = bb_vinfo->roots[i].roots[0]->stmt;
    5919              :           /* Apply patterns.  */
    5920      4042258 :           for (unsigned j = 0; j < bb_vinfo->roots[i].stmts.length (); ++j)
    5921      5495860 :             bb_vinfo->roots[i].stmts[j]
    5922      2835865 :               = vect_stmt_to_vectorize (bb_vinfo->roots[i].stmts[j]);
    5923      1294328 :           if (vect_build_slp_instance (bb_vinfo, bb_vinfo->roots[i].kind,
    5924      1294328 :                                        bb_vinfo->roots[i].stmts,
    5925      1294328 :                                        bb_vinfo->roots[i].roots,
    5926      1294328 :                                        bb_vinfo->roots[i].remain,
    5927              :                                        max_tree_size, &limit, bst_map, false))
    5928              :             {
    5929       137302 :               bb_vinfo->roots[i].roots = vNULL;
    5930       137302 :               bb_vinfo->roots[i].remain = vNULL;
    5931              :             }
    5932      1294328 :           bb_vinfo->roots[i].stmts = vNULL;
    5933              :         }
    5934              :     }
    5935              : 
    5936      1133446 :   if (loop_vec_info loop_vinfo = dyn_cast <loop_vec_info> (vinfo))
    5937              :     {
    5938              :       /* Find SLP sequences starting from groups of reductions.  */
    5939       503996 :       if (!vect_analyze_slp_reductions (loop_vinfo, max_tree_size, &limit,
    5940              :                                         bst_map, force_single_lane))
    5941              :         {
    5942         3007 :           release_scalar_stmts_to_slp_tree_map (bst_map);
    5943         3007 :           return opt_result::failure_at (vect_location, "SLP build failed.\n");
    5944              :         }
    5945              : 
    5946              :       /* Make sure to vectorize only-live stmts, usually inductions.  */
    5947      2259753 :       for (edge e : get_loop_exit_edges (LOOP_VINFO_LOOP (loop_vinfo)))
    5948      1461787 :         for (auto gsi = gsi_start_phis (e->dest); !gsi_end_p (gsi);
    5949       695149 :              gsi_next (&gsi))
    5950              :           {
    5951       705001 :             gphi *lc_phi = *gsi;
    5952       705001 :             tree def = gimple_phi_arg_def_from_edge (lc_phi, e);
    5953       705001 :             stmt_vec_info stmt_info;
    5954       705001 :             if (TREE_CODE (def) == SSA_NAME
    5955       590267 :                 && !virtual_operand_p (def)
    5956       303559 :                 && (stmt_info = loop_vinfo->lookup_def (def))
    5957       272046 :                 && ((stmt_info = vect_stmt_to_vectorize (stmt_info)), true)
    5958       272046 :                 && STMT_VINFO_RELEVANT (stmt_info) == vect_used_only_live
    5959       211883 :                 && STMT_VINFO_LIVE_P (stmt_info)
    5960       211883 :                 && !VECTORIZABLE_CYCLE_DEF (STMT_VINFO_DEF_TYPE (stmt_info))
    5961       814979 :                 && STMT_VINFO_REDUC_IDX (stmt_info) == -1)
    5962              :               {
    5963       109891 :                 vec<stmt_vec_info> stmts;
    5964       109891 :                 vec<stmt_vec_info> roots = vNULL;
    5965       109891 :                 vec<tree> remain = vNULL;
    5966       109891 :                 stmts.create (1);
    5967       109891 :                 stmts.quick_push (vect_stmt_to_vectorize (stmt_info));
    5968       109891 :                 if (! vect_build_slp_instance (vinfo,
    5969              :                                                slp_inst_kind_reduc_group,
    5970              :                                                stmts, roots, remain,
    5971              :                                                max_tree_size, &limit,
    5972              :                                                bst_map, force_single_lane))
    5973              :                   {
    5974         9852 :                     release_scalar_stmts_to_slp_tree_map (bst_map);
    5975         9852 :                     return opt_result::failure_at (vect_location,
    5976              :                                                    "SLP build failed.\n");
    5977              :                   }
    5978              :               }
    5979         9852 :           }
    5980              : 
    5981              :       /* Find SLP sequences starting from gconds.  */
    5982      1232771 :       for (auto cond : LOOP_VINFO_LOOP_CONDS (loop_vinfo))
    5983              :         {
    5984       289688 :           auto cond_info = loop_vinfo->lookup_stmt (cond);
    5985              : 
    5986       289688 :           cond_info = vect_stmt_to_vectorize (cond_info);
    5987       289688 :           vec<stmt_vec_info> roots = vNULL;
    5988       289688 :           roots.safe_push (cond_info);
    5989       289688 :           gimple *stmt = STMT_VINFO_STMT (cond_info);
    5990       289688 :           tree args0 = gimple_cond_lhs (stmt);
    5991       289688 :           tree args1 = gimple_cond_rhs (stmt);
    5992              : 
    5993              :           /* These should be enforced by cond lowering, but if it failed
    5994              :              bail.  */
    5995       289688 :           if (gimple_cond_code (stmt) != NE_EXPR
    5996       288561 :               || TREE_TYPE (args0) != boolean_type_node
    5997       577674 :               || !integer_zerop (args1))
    5998              :             {
    5999         1702 :               roots.release ();
    6000         1702 :               release_scalar_stmts_to_slp_tree_map (bst_map);
    6001         1702 :               return opt_result::failure_at (vect_location,
    6002              :                                              "SLP build failed.\n");
    6003              :             }
    6004              : 
    6005              :           /* An argument without a loop def will be codegened from vectorizing the
    6006              :              root gcond itself.  As such we don't need to try to build an SLP tree
    6007              :              from them.  It's highly likely that the resulting SLP tree here if both
    6008              :              arguments have a def will be incompatible, but we rely on it being split
    6009              :              later on.  */
    6010       287986 :           auto varg = loop_vinfo->lookup_def (args0);
    6011       287986 :           vec<stmt_vec_info> stmts;
    6012       287986 :           vec<tree> remain = vNULL;
    6013       287986 :           stmts.create (1);
    6014       287986 :           stmts.quick_push (vect_stmt_to_vectorize (varg));
    6015              : 
    6016       287986 :           if (! vect_build_slp_instance (vinfo, slp_inst_kind_gcond,
    6017              :                                          stmts, roots, remain,
    6018              :                                          max_tree_size, &limit,
    6019              :                                          bst_map, force_single_lane))
    6020              :             {
    6021         3782 :               roots.release ();
    6022         3782 :               release_scalar_stmts_to_slp_tree_map (bst_map);
    6023         3782 :               return opt_result::failure_at (vect_location,
    6024              :                                              "SLP build failed.\n");
    6025              :             }
    6026              :         }
    6027              :     }
    6028              : 
    6029      1115103 :   hash_set<slp_tree> visited_patterns;
    6030      1115103 :   slp_tree_to_load_perm_map_t perm_cache;
    6031      1115103 :   slp_compat_nodes_map_t compat_cache;
    6032              : 
    6033              :   /* See if any patterns can be found in the SLP tree.  */
    6034      1115103 :   bool pattern_found = false;
    6035      3815171 :   FOR_EACH_VEC_ELT (LOOP_VINFO_SLP_INSTANCES (vinfo), i, instance)
    6036      1584965 :     pattern_found |= vect_match_slp_patterns (instance, vinfo,
    6037              :                                               &visited_patterns, &perm_cache,
    6038              :                                               &compat_cache);
    6039              : 
    6040              :   /* If any were found optimize permutations of loads.  */
    6041      1115103 :   if (pattern_found)
    6042              :     {
    6043          264 :       hash_map<slp_tree, slp_tree> load_map;
    6044         3649 :       FOR_EACH_VEC_ELT (LOOP_VINFO_SLP_INSTANCES (vinfo), i, instance)
    6045              :         {
    6046         3121 :           slp_tree root = SLP_INSTANCE_TREE (instance);
    6047         3121 :           optimize_load_redistribution (bst_map, vinfo, SLP_TREE_LANES (root),
    6048              :                                         &load_map, root);
    6049              :         }
    6050          264 :     }
    6051              : 
    6052              :   /* Check whether we should force some SLP instances to use load/store-lanes
    6053              :      and do so by forcing SLP re-discovery with single lanes.  We used
    6054              :      to cancel SLP when this applied to all instances in a loop but now
    6055              :      we decide this per SLP instance.  It's important to do this only
    6056              :      after SLP pattern recognition.  */
    6057      1115103 :   if (is_a <loop_vec_info> (vinfo))
    6058      1261664 :     FOR_EACH_VEC_ELT (LOOP_VINFO_SLP_INSTANCES (vinfo), i, instance)
    6059       776011 :       if (SLP_INSTANCE_KIND (instance) == slp_inst_kind_store
    6060       293935 :           && !SLP_INSTANCE_TREE (instance)->ldst_lanes)
    6061              :         {
    6062       293935 :           slp_tree slp_root = SLP_INSTANCE_TREE (instance);
    6063       293935 :           unsigned int group_size = SLP_TREE_LANES (slp_root);
    6064       293935 :           tree vectype = SLP_TREE_VECTYPE (slp_root);
    6065              : 
    6066       293935 :           stmt_vec_info rep_info = SLP_TREE_REPRESENTATIVE (slp_root);
    6067       293935 :           gimple *rep = STMT_VINFO_STMT (rep_info);
    6068       293935 :           bool masked = (is_gimple_call (rep)
    6069         2508 :                          && gimple_call_internal_p (rep)
    6070       296423 :                          && internal_fn_mask_index
    6071         2488 :                               (gimple_call_internal_fn (rep)) != -1);
    6072       293915 :           if (!STMT_VINFO_GROUPED_ACCESS (rep_info)
    6073        29725 :               || slp_root->ldst_lanes
    6074       323660 :               || (vect_store_lanes_supported (vectype, group_size, masked)
    6075              :                   == IFN_LAST))
    6076       293935 :             continue;
    6077              : 
    6078            0 :           auto_vec<slp_tree> loads;
    6079            0 :           hash_set<slp_tree> visited;
    6080            0 :           vect_gather_slp_loads (loads, slp_root, visited);
    6081              : 
    6082              :           /* Check whether any load in the SLP instance is possibly
    6083              :              permuted.  */
    6084            0 :           bool loads_permuted = false;
    6085            0 :           slp_tree load_node;
    6086            0 :           unsigned j;
    6087            0 :           FOR_EACH_VEC_ELT (loads, j, load_node)
    6088              :             {
    6089            0 :               if (!SLP_TREE_LOAD_PERMUTATION (load_node).exists ())
    6090            0 :                 continue;
    6091            0 :               for (unsigned k = 0; k < SLP_TREE_LANES (load_node); k++)
    6092            0 :                 if (SLP_TREE_LOAD_PERMUTATION (load_node)[k] != k)
    6093              :                   {
    6094              :                     loads_permuted = true;
    6095              :                     break;
    6096              :                   }
    6097              :             }
    6098              : 
    6099              :           /* If the loads and stores can use load/store-lanes force re-discovery
    6100              :              with single lanes.  */
    6101            0 :           if (loads_permuted)
    6102              :             {
    6103            0 :               bool can_use_lanes = true;
    6104              :               bool prefer_load_lanes = false;
    6105            0 :               FOR_EACH_VEC_ELT (loads, j, load_node)
    6106            0 :                 if (STMT_VINFO_GROUPED_ACCESS
    6107              :                       (SLP_TREE_REPRESENTATIVE (load_node)))
    6108              :                   {
    6109            0 :                     stmt_vec_info stmt_vinfo = DR_GROUP_FIRST_ELEMENT
    6110              :                         (SLP_TREE_REPRESENTATIVE (load_node));
    6111            0 :                     rep = STMT_VINFO_STMT (stmt_vinfo);
    6112            0 :                     masked = (is_gimple_call (rep)
    6113            0 :                               && gimple_call_internal_p (rep)
    6114            0 :                               && internal_fn_mask_index
    6115            0 :                                    (gimple_call_internal_fn (rep)));
    6116              :                     /* Use SLP for strided accesses (or if we can't
    6117              :                        load-lanes).  */
    6118            0 :                     if (STMT_VINFO_STRIDED_P (stmt_vinfo)
    6119            0 :                         || compare_step_with_zero (vinfo, stmt_vinfo) <= 0
    6120            0 :                         || vect_load_lanes_supported
    6121            0 :                              (SLP_TREE_VECTYPE (load_node),
    6122            0 :                               DR_GROUP_SIZE (stmt_vinfo), masked) == IFN_LAST
    6123              :                         /* ???  During SLP re-discovery with a single lane
    6124              :                            a masked grouped load will appear permuted and
    6125              :                            discovery will fail.  We have to rework this
    6126              :                            on the discovery side - for now avoid ICEing.  */
    6127            0 :                         || masked)
    6128              :                       {
    6129              :                         can_use_lanes = false;
    6130              :                         break;
    6131              :                       }
    6132              :                     /* Make sure that the target would prefer store-lanes
    6133              :                        for at least one of the loads.
    6134              : 
    6135              :                        ??? Perhaps we should instead require this for
    6136              :                        all loads?  */
    6137            0 :                     prefer_load_lanes
    6138              :                       = (prefer_load_lanes
    6139            0 :                          || SLP_TREE_LANES (load_node) == group_size
    6140            0 :                          || (vect_slp_prefer_store_lanes_p
    6141            0 :                              (vinfo, stmt_vinfo,
    6142              :                               SLP_TREE_VECTYPE (load_node), masked,
    6143              :                               group_size, SLP_TREE_LANES (load_node))));
    6144              :                   }
    6145              : 
    6146            0 :               if (can_use_lanes && prefer_load_lanes)
    6147              :                 {
    6148            0 :                   if (dump_enabled_p ())
    6149            0 :                     dump_printf_loc (MSG_NOTE, vect_location,
    6150              :                                      "SLP instance %p can use load/store-lanes,"
    6151              :                                      " re-discovering with single-lanes\n",
    6152              :                                      (void *) instance);
    6153              : 
    6154            0 :                   stmt_vec_info stmt_info = SLP_TREE_REPRESENTATIVE (slp_root);
    6155              : 
    6156            0 :                   vect_free_slp_instance (instance);
    6157            0 :                   limit = max_tree_size;
    6158            0 :                   bool res = vect_analyze_slp_instance (vinfo, bst_map,
    6159              :                                                         stmt_info,
    6160              :                                                         slp_inst_kind_store,
    6161              :                                                         max_tree_size, &limit,
    6162              :                                                         true);
    6163            0 :                   gcc_assert (res);
    6164            0 :                   auto new_inst = LOOP_VINFO_SLP_INSTANCES (vinfo).pop ();
    6165            0 :                   LOOP_VINFO_SLP_INSTANCES (vinfo)[i] = new_inst;
    6166              :                 }
    6167              :             }
    6168            0 :         }
    6169              : 
    6170              :   /* When we end up with load permutations that we cannot possibly handle,
    6171              :      like those requiring three vector inputs, lower them using interleaving
    6172              :      like schemes.  */
    6173      1115103 :   if (loop_vec_info loop_vinfo = dyn_cast <loop_vec_info> (vinfo))
    6174              :     {
    6175       485653 :       vect_lower_load_permutations (loop_vinfo, bst_map, force_single_lane);
    6176       485653 :       if (dump_enabled_p ())
    6177              :         {
    6178        20040 :           dump_printf_loc (MSG_NOTE, vect_location,
    6179              :                            "SLP graph after lowering permutations:\n");
    6180        20040 :           hash_set<slp_tree> visited;
    6181        89280 :           FOR_EACH_VEC_ELT (LOOP_VINFO_SLP_INSTANCES (vinfo), i, instance)
    6182        29185 :             vect_print_slp_graph (MSG_NOTE, vect_location,
    6183              :                                   SLP_INSTANCE_TREE (instance), visited);
    6184        20040 :         }
    6185              :     }
    6186              : 
    6187      1115103 :   release_scalar_stmts_to_slp_tree_map (bst_map);
    6188              : 
    6189      1115103 :   if (pattern_found && dump_enabled_p ())
    6190              :     {
    6191           18 :       dump_printf_loc (MSG_NOTE, vect_location,
    6192              :                        "Pattern matched SLP tree\n");
    6193           18 :       hash_set<slp_tree> visited;
    6194           90 :       FOR_EACH_VEC_ELT (LOOP_VINFO_SLP_INSTANCES (vinfo), i, instance)
    6195           36 :         vect_print_slp_graph (MSG_NOTE, vect_location,
    6196              :                               SLP_INSTANCE_TREE (instance), visited);
    6197           18 :     }
    6198              : 
    6199      1115103 :   return opt_result::success ();
    6200      1115103 : }
    6201              : 
    6202              : /* Estimates the cost of inserting layout changes into the SLP graph.
    6203              :    It can also say that the insertion is impossible.  */
    6204              : 
    6205              : struct slpg_layout_cost
    6206              : {
    6207     10733369 :   slpg_layout_cost () = default;
    6208              :   slpg_layout_cost (sreal, bool);
    6209              : 
    6210       471016 :   static slpg_layout_cost impossible () { return { sreal::max (), 0 }; }
    6211      5050125 :   bool is_possible () const { return depth != sreal::max (); }
    6212              : 
    6213              :   bool operator== (const slpg_layout_cost &) const;
    6214              :   bool operator!= (const slpg_layout_cost &) const;
    6215              : 
    6216              :   bool is_better_than (const slpg_layout_cost &, bool) const;
    6217              : 
    6218              :   void add_parallel_cost (const slpg_layout_cost &);
    6219              :   void add_serial_cost (const slpg_layout_cost &);
    6220              :   void split (unsigned int);
    6221              : 
    6222              :   /* The longest sequence of layout changes needed during any traversal
    6223              :      of the partition dag, weighted by execution frequency.
    6224              : 
    6225              :      This is the most important metric when optimizing for speed, since
    6226              :      it helps to ensure that we keep the number of operations on
    6227              :      critical paths to a minimum.  */
    6228              :   sreal depth = 0;
    6229              : 
    6230              :   /* An estimate of the total number of operations needed.  It is weighted by
    6231              :      execution frequency when optimizing for speed but not when optimizing for
    6232              :      size.  In order to avoid double-counting, a node with a fanout of N will
    6233              :      distribute 1/N of its total cost to each successor.
    6234              : 
    6235              :      This is the most important metric when optimizing for size, since
    6236              :      it helps to keep the total number of operations to a minimum,  */
    6237              :   sreal total = 0;
    6238              : };
    6239              : 
    6240              : /* Construct costs for a node with weight WEIGHT.  A higher weight
    6241              :    indicates more frequent execution.  IS_FOR_SIZE is true if we are
    6242              :    optimizing for size rather than speed.  */
    6243              : 
    6244      1191260 : slpg_layout_cost::slpg_layout_cost (sreal weight, bool is_for_size)
    6245      1192222 :   : depth (weight), total (is_for_size && weight > 0 ? 1 : weight)
    6246              : {
    6247      1191260 : }
    6248              : 
    6249              : bool
    6250            0 : slpg_layout_cost::operator== (const slpg_layout_cost &other) const
    6251              : {
    6252            0 :   return depth == other.depth && total == other.total;
    6253              : }
    6254              : 
    6255              : bool
    6256            0 : slpg_layout_cost::operator!= (const slpg_layout_cost &other) const
    6257              : {
    6258            0 :   return !operator== (other);
    6259              : }
    6260              : 
    6261              : /* Return true if these costs are better than OTHER.  IS_FOR_SIZE is
    6262              :    true if we are optimizing for size rather than speed.  */
    6263              : 
    6264              : bool
    6265       287988 : slpg_layout_cost::is_better_than (const slpg_layout_cost &other,
    6266              :                                   bool is_for_size) const
    6267              : {
    6268       287988 :   if (is_for_size)
    6269              :     {
    6270          429 :       if (total != other.total)
    6271          181 :         return total < other.total;
    6272          248 :       return depth < other.depth;
    6273              :     }
    6274              :   else
    6275              :     {
    6276       287559 :       if (depth != other.depth)
    6277       119630 :         return depth < other.depth;
    6278       167929 :       return total < other.total;
    6279              :     }
    6280              : }
    6281              : 
    6282              : /* Increase the costs to account for something with cost INPUT_COST
    6283              :    happening in parallel with the current costs.  */
    6284              : 
    6285              : void
    6286       346543 : slpg_layout_cost::add_parallel_cost (const slpg_layout_cost &input_cost)
    6287              : {
    6288       346543 :   depth = std::max (depth, input_cost.depth);
    6289       346543 :   total += input_cost.total;
    6290       346543 : }
    6291              : 
    6292              : /* Increase the costs to account for something with cost INPUT_COST
    6293              :    happening in series with the current costs.  */
    6294              : 
    6295              : void
    6296      1420411 : slpg_layout_cost::add_serial_cost (const slpg_layout_cost &other)
    6297              : {
    6298      1420411 :   depth += other.depth;
    6299      1420411 :   total += other.total;
    6300      1420411 : }
    6301              : 
    6302              : /* Split the total cost among TIMES successors or predecessors.  */
    6303              : 
    6304              : void
    6305      1156242 : slpg_layout_cost::split (unsigned int times)
    6306              : {
    6307      1156242 :   if (times > 1)
    6308       529889 :     total /= times;
    6309      1156242 : }
    6310              : 
    6311              : /* Information about one node in the SLP graph, for use during
    6312              :    vect_optimize_slp_pass.  */
    6313              : 
    6314              : struct slpg_vertex
    6315              : {
    6316     10080725 :   slpg_vertex (slp_tree node_) : node (node_) {}
    6317              : 
    6318              :   /* The node itself.  */
    6319              :   slp_tree node;
    6320              : 
    6321              :   /* Which partition the node belongs to, or -1 if none.  Nodes outside of
    6322              :      partitions are flexible; they can have whichever layout consumers
    6323              :      want them to have.  */
    6324              :   int partition = -1;
    6325              : 
    6326              :   /* The number of nodes that directly use the result of this one
    6327              :      (i.e. the number of nodes that count this one as a child).  */
    6328              :   unsigned int out_degree = 0;
    6329              : 
    6330              :   /* The execution frequency of the node.  */
    6331              :   sreal weight = 0;
    6332              : 
    6333              :   /* The total execution frequency of all nodes that directly use the
    6334              :      result of this one.  */
    6335              :   sreal out_weight = 0;
    6336              : };
    6337              : 
    6338              : /* Information about one partition of the SLP graph, for use during
    6339              :    vect_optimize_slp_pass.  */
    6340              : 
    6341              : struct slpg_partition_info
    6342              : {
    6343              :   /* The nodes in the partition occupy indices [NODE_BEGIN, NODE_END)
    6344              :      of m_partitioned_nodes.  */
    6345              :   unsigned int node_begin = 0;
    6346              :   unsigned int node_end = 0;
    6347              : 
    6348              :   /* Which layout we've chosen to use for this partition, or -1 if
    6349              :      we haven't picked one yet.  */
    6350              :   int layout = -1;
    6351              : 
    6352              :   /* The number of predecessors and successors in the partition dag.
    6353              :      The predecessors always have lower partition numbers and the
    6354              :      successors always have higher partition numbers.
    6355              : 
    6356              :      Note that the directions of these edges are not necessarily the
    6357              :      same as in the data flow graph.  For example, if an SCC has separate
    6358              :      partitions for an inner loop and an outer loop, the inner loop's
    6359              :      partition will have at least two incoming edges from the outer loop's
    6360              :      partition: one for a live-in value and one for a live-out value.
    6361              :      In data flow terms, one of these edges would also be from the outer loop
    6362              :      to the inner loop, but the other would be in the opposite direction.  */
    6363              :   unsigned int in_degree = 0;
    6364              :   unsigned int out_degree = 0;
    6365              : };
    6366              : 
    6367              : /* Information about the costs of using a particular layout for a
    6368              :    particular partition.  It can also say that the combination is
    6369              :    impossible.  */
    6370              : 
    6371              : struct slpg_partition_layout_costs
    6372              : {
    6373      1469578 :   bool is_possible () const { return internal_cost.is_possible (); }
    6374        57514 :   void mark_impossible () { internal_cost = slpg_layout_cost::impossible (); }
    6375              : 
    6376              :   /* The costs inherited from predecessor partitions.  */
    6377              :   slpg_layout_cost in_cost;
    6378              : 
    6379              :   /* The inherent cost of the layout within the node itself.  For example,
    6380              :      this is nonzero for a load if choosing a particular layout would require
    6381              :      the load to permute the loaded elements.  It is nonzero for a
    6382              :      VEC_PERM_EXPR if the permutation cannot be eliminated or converted
    6383              :      to full-vector moves.  */
    6384              :   slpg_layout_cost internal_cost;
    6385              : 
    6386              :   /* The costs inherited from successor partitions.  */
    6387              :   slpg_layout_cost out_cost;
    6388              : };
    6389              : 
    6390              : /* This class tries to optimize the layout of vectors in order to avoid
    6391              :    unnecessary shuffling.  At the moment, the set of possible layouts are
    6392              :    restricted to bijective permutations.
    6393              : 
    6394              :    The goal of the pass depends on whether we're optimizing for size or
    6395              :    for speed.  When optimizing for size, the goal is to reduce the overall
    6396              :    number of layout changes (including layout changes implied by things
    6397              :    like load permutations).  When optimizing for speed, the goal is to
    6398              :    reduce the maximum latency attributable to layout changes on any
    6399              :    non-cyclical path through the data flow graph.
    6400              : 
    6401              :    For example, when optimizing a loop nest for speed, we will prefer
    6402              :    to make layout changes outside of a loop rather than inside of a loop,
    6403              :    and will prefer to make layout changes in parallel rather than serially,
    6404              :    even if that increases the overall number of layout changes.
    6405              : 
    6406              :    The high-level procedure is:
    6407              : 
    6408              :    (1) Build a graph in which edges go from uses (parents) to definitions
    6409              :        (children).
    6410              : 
    6411              :    (2) Divide the graph into a dag of strongly-connected components (SCCs).
    6412              : 
    6413              :    (3) When optimizing for speed, partition the nodes in each SCC based
    6414              :        on their containing cfg loop.  When optimizing for size, treat
    6415              :        each SCC as a single partition.
    6416              : 
    6417              :        This gives us a dag of partitions.  The goal is now to assign a
    6418              :        layout to each partition.
    6419              : 
    6420              :    (4) Construct a set of vector layouts that are worth considering.
    6421              :        Record which nodes must keep their current layout.
    6422              : 
    6423              :    (5) Perform a forward walk over the partition dag (from loads to stores)
    6424              :        accumulating the "forward" cost of using each layout.  When visiting
    6425              :        each partition, assign a tentative choice of layout to the partition
    6426              :        and use that choice when calculating the cost of using a different
    6427              :        layout in successor partitions.
    6428              : 
    6429              :    (6) Perform a backward walk over the partition dag (from stores to loads),
    6430              :        accumulating the "backward" cost of using each layout.  When visiting
    6431              :        each partition, make a final choice of layout for that partition based
    6432              :        on the accumulated forward costs (from (5)) and backward costs
    6433              :        (from (6)).
    6434              : 
    6435              :    (7) Apply the chosen layouts to the SLP graph.
    6436              : 
    6437              :    For example, consider the SLP statements:
    6438              : 
    6439              :    S1:      a_1 = load
    6440              :        loop:
    6441              :    S2:      a_2 = PHI<a_1, a_3>
    6442              :    S3:      b_1 = load
    6443              :    S4:      a_3 = a_2 + b_1
    6444              :        exit:
    6445              :    S5:      a_4 = PHI<a_3>
    6446              :    S6:      store a_4
    6447              : 
    6448              :    S2 and S4 form an SCC and are part of the same loop.  Every other
    6449              :    statement is in a singleton SCC.  In this example there is a one-to-one
    6450              :    mapping between SCCs and partitions and the partition dag looks like this;
    6451              : 
    6452              :         S1     S3
    6453              :          \     /
    6454              :           S2+S4
    6455              :             |
    6456              :            S5
    6457              :             |
    6458              :            S6
    6459              : 
    6460              :    S2, S3 and S4 will have a higher execution frequency than the other
    6461              :    statements, so when optimizing for speed, the goal is to avoid any
    6462              :    layout changes:
    6463              : 
    6464              :    - within S3
    6465              :    - within S2+S4
    6466              :    - on the S3->S2+S4 edge
    6467              : 
    6468              :    For example, if S3 was originally a reversing load, the goal of the
    6469              :    pass is to make it an unreversed load and change the layout on the
    6470              :    S1->S2+S4 and S2+S4->S5 edges to compensate.  (Changing the layout
    6471              :    on S1->S2+S4 and S5->S6 would also be acceptable.)
    6472              : 
    6473              :    The difference between SCCs and partitions becomes important if we
    6474              :    add an outer loop:
    6475              : 
    6476              :    S1:      a_1 = ...
    6477              :        loop1:
    6478              :    S2:      a_2 = PHI<a_1, a_6>
    6479              :    S3:      b_1 = load
    6480              :    S4:      a_3 = a_2 + b_1
    6481              :        loop2:
    6482              :    S5:      a_4 = PHI<a_3, a_5>
    6483              :    S6:      c_1 = load
    6484              :    S7:      a_5 = a_4 + c_1
    6485              :        exit2:
    6486              :    S8:      a_6 = PHI<a_5>
    6487              :    S9:      store a_6
    6488              :        exit1:
    6489              : 
    6490              :    Here, S2, S4, S5, S7 and S8 form a single SCC.  However, when optimizing
    6491              :    for speed, we usually do not want restrictions in the outer loop to "infect"
    6492              :    the decision for the inner loop.  For example, if an outer-loop node
    6493              :    in the SCC contains a statement with a fixed layout, that should not
    6494              :    prevent the inner loop from using a different layout.  Conversely,
    6495              :    the inner loop should not dictate a layout to the outer loop: if the
    6496              :    outer loop does a lot of computation, then it may not be efficient to
    6497              :    do all of that computation in the inner loop's preferred layout.
    6498              : 
    6499              :    So when optimizing for speed, we partition the SCC into S2+S4+S8 (outer)
    6500              :    and S5+S7 (inner).  We also try to arrange partitions so that:
    6501              : 
    6502              :    - the partition for an outer loop comes before the partition for
    6503              :      an inner loop
    6504              : 
    6505              :    - if a sibling loop A dominates a sibling loop B, A's partition
    6506              :      comes before B's
    6507              : 
    6508              :    This gives the following partition dag for the example above:
    6509              : 
    6510              :         S1        S3
    6511              :          \        /
    6512              :           S2+S4+S8   S6
    6513              :            |   \\    /
    6514              :            |    S5+S7
    6515              :            |
    6516              :           S9
    6517              : 
    6518              :    There are two edges from S2+S4+S8 to S5+S7: one for the edge S4->S5 and
    6519              :    one for a reversal of the edge S7->S8.
    6520              : 
    6521              :    The backward walk picks a layout for S5+S7 before S2+S4+S8.  The choice
    6522              :    for S2+S4+S8 therefore has to balance the cost of using the outer loop's
    6523              :    preferred layout against the cost of changing the layout on entry to the
    6524              :    inner loop (S4->S5) and on exit from the inner loop (S7->S8 reversed).
    6525              : 
    6526              :    Although this works well when optimizing for speed, it has the downside
    6527              :    when optimizing for size that the choice of layout for S5+S7 is completely
    6528              :    independent of S9, which lessens the chance of reducing the overall number
    6529              :    of permutations.  We therefore do not partition SCCs when optimizing
    6530              :    for size.
    6531              : 
    6532              :    To give a concrete example of the difference between optimizing
    6533              :    for size and speed, consider:
    6534              : 
    6535              :    a[0] = (b[1] << c[3]) - d[1];
    6536              :    a[1] = (b[0] << c[2]) - d[0];
    6537              :    a[2] = (b[3] << c[1]) - d[3];
    6538              :    a[3] = (b[2] << c[0]) - d[2];
    6539              : 
    6540              :    There are three different layouts here: one for a, one for b and d,
    6541              :    and one for c.  When optimizing for speed it is better to permute each
    6542              :    of b, c and d into the order required by a, since those permutations
    6543              :    happen in parallel.  But when optimizing for size, it is better to:
    6544              : 
    6545              :    - permute c into the same order as b
    6546              :    - do the arithmetic
    6547              :    - permute the result into the order required by a
    6548              : 
    6549              :    This gives 2 permutations rather than 3.  */
    6550              : 
    6551              : class vect_optimize_slp_pass
    6552              : {
    6553              : public:
    6554       697455 :   vect_optimize_slp_pass (vec_info *vinfo) : m_vinfo (vinfo) {}
    6555              :   void run ();
    6556              : 
    6557              : private:
    6558              :   /* Graph building.  */
    6559              :   struct loop *containing_loop (slp_tree);
    6560              :   bool is_cfg_latch_edge (graph_edge *);
    6561              :   void build_vertices (hash_set<slp_tree> &, slp_tree);
    6562              :   void build_vertices ();
    6563              :   void build_graph ();
    6564              : 
    6565              :   /* Partitioning.  */
    6566              :   void create_partitions ();
    6567              :   template<typename T> void for_each_partition_edge (unsigned int, T);
    6568              : 
    6569              :   /* Layout selection.  */
    6570              :   bool is_compatible_layout (slp_tree, unsigned int);
    6571              :   bool is_compatible_layout (const slpg_partition_info &, unsigned int);
    6572              :   int change_layout_cost (slp_tree, unsigned int, unsigned int);
    6573              :   slpg_partition_layout_costs &partition_layout_costs (unsigned int,
    6574              :                                                        unsigned int);
    6575              :   void change_vec_perm_layout (slp_tree, lane_permutation_t &,
    6576              :                                int, unsigned int);
    6577              :   int internal_node_cost (slp_tree, int, unsigned int);
    6578              :   void start_choosing_layouts ();
    6579              :   bool legitimize ();
    6580              : 
    6581              :   /* Cost propagation.  */
    6582              :   slpg_layout_cost edge_layout_cost (graph_edge *, unsigned int,
    6583              :                                      unsigned int, unsigned int);
    6584              :   slpg_layout_cost total_in_cost (unsigned int);
    6585              :   slpg_layout_cost forward_cost (graph_edge *, unsigned int, unsigned int);
    6586              :   slpg_layout_cost backward_cost (graph_edge *, unsigned int, unsigned int);
    6587              :   void forward_pass ();
    6588              :   void backward_pass ();
    6589              : 
    6590              :   /* Rematerialization.  */
    6591              :   slp_tree get_result_with_layout (slp_tree, unsigned int);
    6592              :   void materialize ();
    6593              : 
    6594              :   /* Clean-up.  */
    6595              :   void remove_redundant_permutations ();
    6596              : 
    6597              :   /* Masked load lanes discovery.  */
    6598              :   void decide_masked_load_lanes ();
    6599              : 
    6600              :   void dump ();
    6601              : 
    6602              :   vec_info *m_vinfo;
    6603              : 
    6604              :   /* True if we should optimize the graph for size, false if we should
    6605              :      optimize it for speed.  (It wouldn't be easy to make this decision
    6606              :      more locally.)  */
    6607              :   bool m_optimize_size;
    6608              : 
    6609              :   /* A graph of all SLP nodes, with edges leading from uses to definitions.
    6610              :      In other words, a node's predecessors are its slp_tree parents and
    6611              :      a node's successors are its slp_tree children.  */
    6612              :   graph *m_slpg = nullptr;
    6613              : 
    6614              :   /* The vertices of M_SLPG, indexed by slp_tree::vertex.  */
    6615              :   auto_vec<slpg_vertex> m_vertices;
    6616              : 
    6617              :   /* The list of all leaves of M_SLPG. such as external definitions, constants,
    6618              :      and loads.  */
    6619              :   auto_vec<int> m_leafs;
    6620              : 
    6621              :   /* This array has one entry for every vector layout that we're considering.
    6622              :      Element 0 is null and indicates "no change".  Other entries describe
    6623              :      permutations that are inherent in the current graph and that we would
    6624              :      like to reverse if possible.
    6625              : 
    6626              :      For example, a permutation { 1, 2, 3, 0 } means that something has
    6627              :      effectively been permuted in that way, such as a load group
    6628              :      { a[1], a[2], a[3], a[0] } (viewed as a permutation of a[0:3]).
    6629              :      We'd then like to apply the reverse permutation { 3, 0, 1, 2 }
    6630              :      in order to put things "back" in order.  */
    6631              :   auto_vec<vec<unsigned> > m_perms;
    6632              : 
    6633              :   /* A partitioning of the nodes for which a layout must be chosen.
    6634              :      Each partition represents an <SCC, cfg loop> pair; that is,
    6635              :      nodes in different SCCs belong to different partitions, and nodes
    6636              :      within an SCC can be further partitioned according to a containing
    6637              :      cfg loop.  Partition <SCC1, L1> comes before <SCC2, L2> if:
    6638              : 
    6639              :      - SCC1 != SCC2 and SCC1 is a predecessor of SCC2 in a forward walk
    6640              :        from leaves (such as loads) to roots (such as stores).
    6641              : 
    6642              :      - SCC1 == SCC2 and L1's header strictly dominates L2's header.  */
    6643              :   auto_vec<slpg_partition_info> m_partitions;
    6644              : 
    6645              :   /* The list of all nodes for which a layout must be chosen.  Nodes for
    6646              :      partition P come before the nodes for partition P+1.  Nodes within a
    6647              :      partition are in reverse postorder.  */
    6648              :   auto_vec<unsigned int> m_partitioned_nodes;
    6649              : 
    6650              :   /* Index P * num-layouts + L contains the cost of using layout L
    6651              :      for partition P.  */
    6652              :   auto_vec<slpg_partition_layout_costs> m_partition_layout_costs;
    6653              : 
    6654              :   /* Index N * num-layouts + L, if nonnull, is a node that provides the
    6655              :      original output of node N adjusted to have layout L.  */
    6656              :   auto_vec<slp_tree> m_node_layouts;
    6657              : };
    6658              : 
    6659              : /* Fill the vertices and leafs vector with all nodes in the SLP graph.
    6660              :    Also record whether we should optimize anything for speed rather
    6661              :    than size.  */
    6662              : 
    6663              : void
    6664     10887145 : vect_optimize_slp_pass::build_vertices (hash_set<slp_tree> &visited,
    6665              :                                         slp_tree node)
    6666              : {
    6667     10887145 :   unsigned i;
    6668     10887145 :   slp_tree child;
    6669              : 
    6670     10887145 :   if (visited.add (node))
    6671     10887145 :     return;
    6672              : 
    6673     10080725 :   if (stmt_vec_info rep = SLP_TREE_REPRESENTATIVE (node))
    6674              :     {
    6675      7937112 :       basic_block bb = gimple_bb (vect_orig_stmt (rep)->stmt);
    6676      7063722 :       if (optimize_bb_for_speed_p (bb))
    6677      6936070 :         m_optimize_size = false;
    6678              :     }
    6679              : 
    6680     10080725 :   node->vertex = m_vertices.length ();
    6681     10080725 :   m_vertices.safe_push (slpg_vertex (node));
    6682              : 
    6683     10080725 :   bool leaf = true;
    6684     10080725 :   bool force_leaf = false;
    6685     18849872 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    6686      8769147 :     if (child)
    6687              :       {
    6688      7893061 :         leaf = false;
    6689      7893061 :         build_vertices (visited, child);
    6690              :       }
    6691              :     else
    6692              :       force_leaf = true;
    6693              :   /* Since SLP discovery works along use-def edges all cycles have an
    6694              :      entry - but there's the exception of cycles where we do not handle
    6695              :      the entry explicitly (but with a NULL SLP node), like some reductions
    6696              :      and inductions.  Force those SLP PHIs to act as leafs to make them
    6697              :      backwards reachable.  */
    6698     10080725 :   if (leaf || force_leaf)
    6699      5000060 :     m_leafs.safe_push (node->vertex);
    6700              : }
    6701              : 
    6702              : /* Fill the vertices and leafs vector with all nodes in the SLP graph.  */
    6703              : 
    6704              : void
    6705      1394910 : vect_optimize_slp_pass::build_vertices ()
    6706              : {
    6707      1394910 :   hash_set<slp_tree> visited;
    6708      1394910 :   unsigned i;
    6709      1394910 :   slp_instance instance;
    6710      1394910 :   m_vertices.truncate (0);
    6711      1394910 :   m_leafs.truncate (0);
    6712      7178814 :   FOR_EACH_VEC_ELT (m_vinfo->slp_instances, i, instance)
    6713      2994084 :     build_vertices (visited, SLP_INSTANCE_TREE (instance));
    6714      1394910 : }
    6715              : 
    6716              : /* Apply (reverse) bijectite PERM to VEC.  */
    6717              : 
    6718              : template <class T>
    6719              : static void
    6720       187716 : vect_slp_permute (vec<unsigned> perm,
    6721              :                   vec<T> &vec, bool reverse)
    6722              : {
    6723       187716 :   auto_vec<T, 64> saved;
    6724       187716 :   saved.create (vec.length ());
    6725       615304 :   for (unsigned i = 0; i < vec.length (); ++i)
    6726       427588 :     saved.quick_push (vec[i]);
    6727              : 
    6728       187716 :   if (reverse)
    6729              :     {
    6730      1219937 :       for (unsigned i = 0; i < vec.length (); ++i)
    6731       426256 :         vec[perm[i]] = saved[i];
    6732       613374 :       for (unsigned i = 0; i < vec.length (); ++i)
    6733       743883 :         gcc_assert (vec[perm[i]] == saved[i]);
    6734              :     }
    6735              :   else
    6736              :     {
    6737         3860 :       for (unsigned i = 0; i < vec.length (); ++i)
    6738         1332 :         vec[i] = saved[perm[i]];
    6739       189048 :       for (unsigned i = 0; i < vec.length (); ++i)
    6740         1998 :         gcc_assert (vec[i] == saved[perm[i]]);
    6741              :     }
    6742       187716 : }
    6743              : 
    6744              : /* Return the cfg loop that contains NODE.  */
    6745              : 
    6746              : struct loop *
    6747      3933860 : vect_optimize_slp_pass::containing_loop (slp_tree node)
    6748              : {
    6749      3933860 :   stmt_vec_info rep = SLP_TREE_REPRESENTATIVE (node);
    6750      3933860 :   if (!rep)
    6751         5168 :     return ENTRY_BLOCK_PTR_FOR_FN (cfun)->loop_father;
    6752      4378572 :   return gimple_bb (vect_orig_stmt (rep)->stmt)->loop_father;
    6753              : }
    6754              : 
    6755              : /* Return true if UD (an edge from a use to a definition) is associated
    6756              :    with a loop latch edge in the cfg.  */
    6757              : 
    6758              : bool
    6759      7893061 : vect_optimize_slp_pass::is_cfg_latch_edge (graph_edge *ud)
    6760              : {
    6761      7893061 :   slp_tree use = m_vertices[ud->src].node;
    6762      7893061 :   slp_tree def = m_vertices[ud->dest].node;
    6763      7893061 :   if ((SLP_TREE_DEF_TYPE (use) != vect_internal_def
    6764      7893061 :        || SLP_TREE_PERMUTE_P (use))
    6765      7580582 :       || SLP_TREE_DEF_TYPE (def) != vect_internal_def)
    6766              :     return false;
    6767              : 
    6768      4576774 :   stmt_vec_info use_rep = vect_orig_stmt (SLP_TREE_REPRESENTATIVE (use));
    6769      4576774 :   return (is_a<gphi *> (use_rep->stmt)
    6770       376552 :           && bb_loop_header_p (gimple_bb (use_rep->stmt))
    6771      4788702 :           && containing_loop (def) == containing_loop (use));
    6772              : }
    6773              : 
    6774              : /* Build the graph.  Mark edges that correspond to cfg loop latch edges with
    6775              :    a nonnull data field.  */
    6776              : 
    6777              : void
    6778      1394910 : vect_optimize_slp_pass::build_graph ()
    6779              : {
    6780      1394910 :   m_optimize_size = true;
    6781      1394910 :   build_vertices ();
    6782              : 
    6783      2789820 :   m_slpg = new_graph (m_vertices.length ());
    6784     14265455 :   for (slpg_vertex &v : m_vertices)
    6785     30068594 :     for (slp_tree child : SLP_TREE_CHILDREN (v.node))
    6786      8769147 :       if (child)
    6787              :         {
    6788      7893061 :           graph_edge *ud = add_edge (m_slpg, v.node->vertex, child->vertex);
    6789      7893061 :           if (is_cfg_latch_edge (ud))
    6790       203056 :             ud->data = this;
    6791              :         }
    6792      1394910 : }
    6793              : 
    6794              : /* Return true if E corresponds to a loop latch edge in the cfg.  */
    6795              : 
    6796              : static bool
    6797      4047772 : skip_cfg_latch_edges (graph_edge *e)
    6798              : {
    6799      4047772 :   return e->data;
    6800              : }
    6801              : 
    6802              : /* Create the node partitions.  */
    6803              : 
    6804              : void
    6805       697455 : vect_optimize_slp_pass::create_partitions ()
    6806              : {
    6807              :   /* Calculate a postorder of the graph, ignoring edges that correspond
    6808              :      to natural latch edges in the cfg.  Reading the vector from the end
    6809              :      to the beginning gives the reverse postorder.  */
    6810       697455 :   auto_vec<int> initial_rpo;
    6811      1394910 :   graphds_dfs (m_slpg, &m_leafs[0], m_leafs.length (), &initial_rpo,
    6812              :                false, NULL, skip_cfg_latch_edges);
    6813      2092365 :   gcc_assert (initial_rpo.length () == m_vertices.length ());
    6814              : 
    6815              :   /* Calculate the strongly connected components of the graph.  */
    6816       697455 :   auto_vec<int> scc_grouping;
    6817       697455 :   unsigned int num_sccs = graphds_scc (m_slpg, NULL, NULL, &scc_grouping);
    6818              : 
    6819              :   /* Create a new index order in which all nodes from the same SCC are
    6820              :      consecutive.  Use scc_pos to record the index of the first node in
    6821              :      each SCC.  */
    6822       697455 :   auto_vec<unsigned int> scc_pos (num_sccs);
    6823       697455 :   int last_component = -1;
    6824       697455 :   unsigned int node_count = 0;
    6825      7132443 :   for (unsigned int node_i : scc_grouping)
    6826              :     {
    6827      5040078 :       if (last_component != m_slpg->vertices[node_i].component)
    6828              :         {
    6829      4912712 :           last_component = m_slpg->vertices[node_i].component;
    6830      9825424 :           gcc_assert (last_component == int (scc_pos.length ()));
    6831      4912712 :           scc_pos.quick_push (node_count);
    6832              :         }
    6833      5040078 :       node_count += 1;
    6834              :     }
    6835      1394910 :   gcc_assert (node_count == initial_rpo.length ()
    6836              :               && last_component + 1 == int (num_sccs));
    6837              : 
    6838              :   /* Use m_partitioned_nodes to group nodes into SCC order, with the nodes
    6839              :      inside each SCC following the RPO we calculated above.  The fact that
    6840              :      we ignored natural latch edges when calculating the RPO should ensure
    6841              :      that, for natural loop nests:
    6842              : 
    6843              :      - the first node that we encounter in a cfg loop is the loop header phi
    6844              :      - the loop header phis are in dominance order
    6845              : 
    6846              :      Arranging for this is an optimization (see below) rather than a
    6847              :      correctness issue.  Unnatural loops with a tangled mess of backedges
    6848              :      will still work correctly, but might give poorer results.
    6849              : 
    6850              :      Also update scc_pos so that it gives 1 + the index of the last node
    6851              :      in the SCC.  */
    6852       697455 :   m_partitioned_nodes.safe_grow (node_count);
    6853      6434988 :   for (unsigned int old_i = initial_rpo.length (); old_i-- > 0;)
    6854              :     {
    6855      5040078 :       unsigned int node_i = initial_rpo[old_i];
    6856      5040078 :       unsigned int new_i = scc_pos[m_slpg->vertices[node_i].component]++;
    6857      5040078 :       m_partitioned_nodes[new_i] = node_i;
    6858              :     }
    6859              : 
    6860              :   /* When optimizing for speed, partition each SCC based on the containing
    6861              :      cfg loop. The order we constructed above should ensure that, for natural
    6862              :      cfg loops, we'll create sub-SCC partitions for outer loops before
    6863              :      the corresponding sub-SCC partitions for inner loops.  Similarly,
    6864              :      when one sibling loop A dominates another sibling loop B, we should
    6865              :      create a sub-SCC partition for A before a sub-SCC partition for B.
    6866              : 
    6867              :      As above, nothing depends for correctness on whether this achieves
    6868              :      a natural nesting, but we should get better results when it does.  */
    6869      1394910 :   m_partitions.reserve (m_vertices.length ());
    6870       697455 :   unsigned int next_partition_i = 0;
    6871       697455 :   hash_map<struct loop *, int> loop_partitions;
    6872       697455 :   unsigned int rpo_begin = 0;
    6873       697455 :   unsigned int num_partitioned_nodes = 0;
    6874      7005077 :   for (unsigned int rpo_end : scc_pos)
    6875              :     {
    6876      4912712 :       loop_partitions.empty ();
    6877              :       unsigned int partition_i = next_partition_i;
    6878      9952790 :       for (unsigned int rpo_i = rpo_begin; rpo_i < rpo_end; ++rpo_i)
    6879              :         {
    6880              :           /* Handle externals and constants optimistically throughout.
    6881              :              But treat existing vectors as fixed since we do not handle
    6882              :              permuting them.  */
    6883      5040078 :           unsigned int node_i = m_partitioned_nodes[rpo_i];
    6884      5040078 :           auto &vertex = m_vertices[node_i];
    6885      5040078 :           if ((SLP_TREE_DEF_TYPE (vertex.node) == vect_external_def
    6886       511379 :                && !SLP_TREE_VEC_DEFS (vertex.node).exists ())
    6887      5042148 :               || SLP_TREE_DEF_TYPE (vertex.node) == vect_constant_def)
    6888      1503333 :             vertex.partition = -1;
    6889              :           else
    6890              :             {
    6891      3536745 :               bool existed;
    6892      3536745 :               if (m_optimize_size)
    6893        26741 :                 existed = next_partition_i > partition_i;
    6894              :               else
    6895              :                 {
    6896      3510004 :                   struct loop *loop = containing_loop (vertex.node);
    6897      3510004 :                   auto &entry = loop_partitions.get_or_insert (loop, &existed);
    6898      3510004 :                   if (!existed)
    6899      3383629 :                     entry = next_partition_i;
    6900      3510004 :                   partition_i = entry;
    6901              :                 }
    6902      3536745 :               if (!existed)
    6903              :                 {
    6904      3410280 :                   m_partitions.quick_push (slpg_partition_info ());
    6905      3410280 :                   next_partition_i += 1;
    6906              :                 }
    6907      3536745 :               vertex.partition = partition_i;
    6908      3536745 :               num_partitioned_nodes += 1;
    6909      3536745 :               m_partitions[partition_i].node_end += 1;
    6910              :             }
    6911              :         }
    6912      4912712 :       rpo_begin = rpo_end;
    6913              :     }
    6914              : 
    6915              :   /* Assign ranges of consecutive node indices to each partition,
    6916              :      in partition order.  Start with node_end being the same as
    6917              :      node_begin so that the next loop can use it as a counter.  */
    6918       697455 :   unsigned int node_begin = 0;
    6919      5502645 :   for (auto &partition : m_partitions)
    6920              :     {
    6921      3410280 :       partition.node_begin = node_begin;
    6922      3410280 :       node_begin += partition.node_end;
    6923      3410280 :       partition.node_end = partition.node_begin;
    6924              :     }
    6925       697455 :   gcc_assert (node_begin == num_partitioned_nodes);
    6926              : 
    6927              :   /* Finally build the list of nodes in partition order.  */
    6928       697455 :   m_partitioned_nodes.truncate (num_partitioned_nodes);
    6929      5737533 :   for (unsigned int node_i = 0; node_i < m_vertices.length (); ++node_i)
    6930              :     {
    6931      5040078 :       int partition_i = m_vertices[node_i].partition;
    6932      5040078 :       if (partition_i >= 0)
    6933              :         {
    6934      3536745 :           unsigned int order_i = m_partitions[partition_i].node_end++;
    6935      3536745 :           m_partitioned_nodes[order_i] = node_i;
    6936              :         }
    6937              :     }
    6938       697455 : }
    6939              : 
    6940              : /* Look for edges from earlier partitions into node NODE_I and edges from
    6941              :    node NODE_I into later partitions.  Call:
    6942              : 
    6943              :       FN (ud, other_node_i)
    6944              : 
    6945              :    for each such use-to-def edge ud, where other_node_i is the node at the
    6946              :    other end of the edge.  */
    6947              : 
    6948              : template<typename T>
    6949              : void
    6950      3955318 : vect_optimize_slp_pass::for_each_partition_edge (unsigned int node_i, T fn)
    6951              : {
    6952      3955318 :   int partition_i = m_vertices[node_i].partition;
    6953      3955318 :   for (graph_edge *pred = m_slpg->vertices[node_i].pred;
    6954      6820312 :        pred; pred = pred->pred_next)
    6955              :     {
    6956      2864994 :       int src_partition_i = m_vertices[pred->src].partition;
    6957      2864994 :       if (src_partition_i >= 0 && src_partition_i != partition_i)
    6958      2540767 :         fn (pred, pred->src);
    6959              :     }
    6960      3955318 :   for (graph_edge *succ = m_slpg->vertices[node_i].succ;
    6961      8474447 :        succ; succ = succ->succ_next)
    6962              :     {
    6963      4519129 :       int dest_partition_i = m_vertices[succ->dest].partition;
    6964      4519129 :       if (dest_partition_i >= 0 && dest_partition_i != partition_i)
    6965      2569663 :         fn (succ, succ->dest);
    6966              :     }
    6967      3955318 : }
    6968              : 
    6969              : /* Return true if layout LAYOUT_I is compatible with the number of SLP lanes
    6970              :    that NODE would operate on.  This test is independent of NODE's actual
    6971              :    operation.  */
    6972              : 
    6973              : bool
    6974      1605258 : vect_optimize_slp_pass::is_compatible_layout (slp_tree node,
    6975              :                                               unsigned int layout_i)
    6976              : {
    6977      1605258 :   if (layout_i == 0)
    6978              :     return true;
    6979              : 
    6980       918558 :   if (SLP_TREE_LANES (node) != m_perms[layout_i].length ())
    6981        15826 :     return false;
    6982              : 
    6983              :   return true;
    6984              : }
    6985              : 
    6986              : /* Return true if layout LAYOUT_I is compatible with the number of SLP lanes
    6987              :    that NODE would operate on for each NODE in PARTITION.
    6988              :    This test is independent of NODE's actual operations.  */
    6989              : 
    6990              : bool
    6991        18979 : vect_optimize_slp_pass::is_compatible_layout (const slpg_partition_info
    6992              :                                                 &partition,
    6993              :                                               unsigned int layout_i)
    6994              : {
    6995        38389 :   for (unsigned int order_i = partition.node_begin;
    6996        38389 :        order_i < partition.node_end; ++order_i)
    6997              :     {
    6998        19502 :       unsigned int node_i = m_partitioned_nodes[order_i];
    6999        19502 :       auto &vertex = m_vertices[node_i];
    7000              : 
    7001              :       /* The layout is incompatible if it is individually incompatible
    7002              :          with any node in the partition.  */
    7003        19502 :       if (!is_compatible_layout (vertex.node, layout_i))
    7004              :         return false;
    7005              :     }
    7006              :   return true;
    7007              : }
    7008              : 
    7009              : /* Return the cost (in arbitrary units) of going from layout FROM_LAYOUT_I
    7010              :    to layout TO_LAYOUT_I for a node like NODE.  Return -1 if either of the
    7011              :    layouts is incompatible with NODE or if the change is not possible for
    7012              :    some other reason.
    7013              : 
    7014              :    The properties taken from NODE include the number of lanes and the
    7015              :    vector type.  The actual operation doesn't matter.  */
    7016              : 
    7017              : int
    7018       679541 : vect_optimize_slp_pass::change_layout_cost (slp_tree node,
    7019              :                                             unsigned int from_layout_i,
    7020              :                                             unsigned int to_layout_i)
    7021              : {
    7022       679541 :   if (!is_compatible_layout (node, from_layout_i)
    7023       679541 :       || !is_compatible_layout (node, to_layout_i))
    7024          577 :     return -1;
    7025              : 
    7026       678964 :   if (from_layout_i == to_layout_i)
    7027              :     return 0;
    7028              : 
    7029       279310 :   auto_vec<slp_tree, 1> children (1);
    7030       279310 :   children.quick_push (node);
    7031       279310 :   auto_lane_permutation_t perm (SLP_TREE_LANES (node));
    7032       279310 :   if (from_layout_i > 0)
    7033       797160 :     for (unsigned int i : m_perms[from_layout_i])
    7034       353199 :       perm.quick_push ({ 0, i });
    7035              :   else
    7036       427332 :     for (unsigned int i = 0; i < SLP_TREE_LANES (node); ++i)
    7037       296009 :       perm.quick_push ({ 0, i });
    7038       279310 :   if (to_layout_i > 0)
    7039       131864 :     vect_slp_permute (m_perms[to_layout_i], perm, true);
    7040       279310 :   auto count = vectorizable_slp_permutation_1 (m_vinfo, nullptr, node, perm,
    7041              :                                                children, false);
    7042       279310 :   if (count >= 0)
    7043       274381 :     return MAX (count, 1);
    7044              : 
    7045              :   /* ??? In principle we could try changing via layout 0, giving two
    7046              :      layout changes rather than 1.  Doing that would require
    7047              :      corresponding support in get_result_with_layout.  */
    7048              :   return -1;
    7049       279310 : }
    7050              : 
    7051              : /* Return the costs of assigning layout LAYOUT_I to partition PARTITION_I.  */
    7052              : 
    7053              : inline slpg_partition_layout_costs &
    7054      1002809 : vect_optimize_slp_pass::partition_layout_costs (unsigned int partition_i,
    7055              :                                                 unsigned int layout_i)
    7056              : {
    7057      2005618 :   return m_partition_layout_costs[partition_i * m_perms.length () + layout_i];
    7058              : }
    7059              : 
    7060              : /* Change PERM in one of two ways:
    7061              : 
    7062              :    - if IN_LAYOUT_I < 0, accept input operand I in the layout that has been
    7063              :      chosen for child I of NODE.
    7064              : 
    7065              :    - if IN_LAYOUT >= 0, accept all inputs operands with that layout.
    7066              : 
    7067              :    In both cases, arrange for the output to have layout OUT_LAYOUT_I  */
    7068              : 
    7069              : void
    7070        30651 : vect_optimize_slp_pass::
    7071              : change_vec_perm_layout (slp_tree node, lane_permutation_t &perm,
    7072              :                         int in_layout_i, unsigned int out_layout_i)
    7073              : {
    7074       178071 :   for (auto &entry : perm)
    7075              :     {
    7076        86118 :       int this_in_layout_i = in_layout_i;
    7077        86118 :       if (this_in_layout_i < 0)
    7078              :         {
    7079        59823 :           slp_tree in_node = SLP_TREE_CHILDREN (node)[entry.first];
    7080        59823 :           unsigned int in_partition_i = m_vertices[in_node->vertex].partition;
    7081        59823 :           if (in_partition_i == -1u)
    7082          329 :             continue;
    7083        59494 :           this_in_layout_i = m_partitions[in_partition_i].layout;
    7084              :         }
    7085        85789 :       if (this_in_layout_i > 0)
    7086        19335 :         entry.second = m_perms[this_in_layout_i][entry.second];
    7087              :     }
    7088        30651 :   if (out_layout_i > 0)
    7089         7099 :     vect_slp_permute (m_perms[out_layout_i], perm, true);
    7090        30651 : }
    7091              : 
    7092              : /* Check whether the target allows NODE to be rearranged so that the node's
    7093              :    output has layout OUT_LAYOUT_I.  Return the cost of the change if so,
    7094              :    in the same arbitrary units as for change_layout_cost.  Return -1 otherwise.
    7095              : 
    7096              :    If NODE is a VEC_PERM_EXPR and IN_LAYOUT_I < 0, also check whether
    7097              :    NODE can adapt to the layout changes that have (perhaps provisionally)
    7098              :    been chosen for NODE's children, so that no extra permutations are
    7099              :    needed on either the input or the output of NODE.
    7100              : 
    7101              :    If NODE is a VEC_PERM_EXPR and IN_LAYOUT_I >= 0, instead assume
    7102              :    that all inputs will be forced into layout IN_LAYOUT_I beforehand.
    7103              : 
    7104              :    IN_LAYOUT_I has no meaning for other types of node.
    7105              : 
    7106              :    Keeping the node as-is is always valid.  If the target doesn't appear
    7107              :    to support the node as-is, but might realistically support other layouts,
    7108              :    then layout 0 instead has the cost of a worst-case permutation.  On the
    7109              :    one hand, this ensures that every node has at least one valid layout,
    7110              :    avoiding what would otherwise be an awkward special case.  On the other,
    7111              :    it still encourages the pass to change an invalid pre-existing layout
    7112              :    choice into a valid one.  */
    7113              : 
    7114              : int
    7115       221955 : vect_optimize_slp_pass::internal_node_cost (slp_tree node, int in_layout_i,
    7116              :                                             unsigned int out_layout_i)
    7117              : {
    7118       221955 :   const int fallback_cost = 1;
    7119              : 
    7120       221955 :   if (SLP_TREE_PERMUTE_P (node))
    7121              :     {
    7122        25494 :       auto_lane_permutation_t tmp_perm;
    7123        25494 :       tmp_perm.safe_splice (SLP_TREE_LANE_PERMUTATION (node));
    7124              : 
    7125              :       /* Check that the child nodes support the chosen layout.  Checking
    7126              :          the first child is enough, since any second child would have the
    7127              :          same shape.  */
    7128        25494 :       auto first_child = SLP_TREE_CHILDREN (node)[0];
    7129        25494 :       if (in_layout_i > 0
    7130        25494 :           && !is_compatible_layout (first_child, in_layout_i))
    7131              :         return -1;
    7132              : 
    7133        24922 :       change_vec_perm_layout (node, tmp_perm, in_layout_i, out_layout_i);
    7134        49844 :       int count = vectorizable_slp_permutation_1 (m_vinfo, nullptr,
    7135              :                                                   node, tmp_perm,
    7136        24922 :                                                   SLP_TREE_CHILDREN (node),
    7137              :                                                   false);
    7138        24922 :       if (count < 0)
    7139              :         {
    7140         1546 :           if (in_layout_i == 0 && out_layout_i == 0)
    7141              :             {
    7142              :               /* Use the fallback cost if the node could in principle support
    7143              :                  some nonzero layout for both the inputs and the outputs.
    7144              :                  Otherwise assume that the node will be rejected later
    7145              :                  and rebuilt from scalars.  */
    7146          379 :               if (SLP_TREE_LANES (node) == SLP_TREE_LANES (first_child))
    7147              :                 return fallback_cost;
    7148          309 :               return 0;
    7149              :             }
    7150              :           return -1;
    7151              :         }
    7152              : 
    7153              :       /* We currently have no way of telling whether the new layout is cheaper
    7154              :          or more expensive than the old one.  But at least in principle,
    7155              :          it should be worth making zero permutations (whole-vector shuffles)
    7156              :          cheaper than real permutations, in case the pass is able to remove
    7157              :          the latter.  */
    7158        23376 :       return count == 0 ? 0 : 1;
    7159        25494 :     }
    7160              : 
    7161       196461 :   stmt_vec_info rep = SLP_TREE_REPRESENTATIVE (node);
    7162       196461 :   if (rep
    7163       195600 :       && STMT_VINFO_DATA_REF (rep)
    7164        64321 :       && DR_IS_READ (STMT_VINFO_DATA_REF (rep))
    7165       239857 :       && SLP_TREE_LOAD_PERMUTATION (node).exists ())
    7166              :     {
    7167        35664 :       auto_load_permutation_t tmp_perm;
    7168        35664 :       tmp_perm.safe_splice (SLP_TREE_LOAD_PERMUTATION (node));
    7169        35664 :       if (out_layout_i > 0)
    7170        13543 :         vect_slp_permute (m_perms[out_layout_i], tmp_perm, true);
    7171              : 
    7172        35664 :       poly_uint64 vf = 1;
    7173        35664 :       if (auto loop_vinfo = dyn_cast<loop_vec_info> (m_vinfo))
    7174        12152 :         vf = LOOP_VINFO_VECT_FACTOR (loop_vinfo);
    7175        35664 :       unsigned int n_perms;
    7176        35664 :       if (!vect_transform_slp_perm_load_1 (m_vinfo, node, tmp_perm, vNULL,
    7177              :                                            nullptr, vf, true, false, &n_perms))
    7178              :         {
    7179         1698 :           auto rep = SLP_TREE_REPRESENTATIVE (node);
    7180         1698 :           if (out_layout_i == 0)
    7181              :             {
    7182              :               /* Use the fallback cost if the load is an N-to-N permutation.
    7183              :                  Otherwise assume that the node will be rejected later
    7184              :                  and rebuilt from scalars.  */
    7185         1259 :               if (STMT_VINFO_GROUPED_ACCESS (rep)
    7186         2518 :                   && (DR_GROUP_SIZE (DR_GROUP_FIRST_ELEMENT (rep))
    7187         1259 :                       == SLP_TREE_LANES (node)))
    7188          654 :                 return fallback_cost;
    7189              :               return 0;
    7190              :             }
    7191              :           return -1;
    7192              :         }
    7193              : 
    7194              :       /* See the comment above the corresponding VEC_PERM_EXPR handling.  */
    7195        33966 :       return n_perms == 0 ? 0 : 1;
    7196        35664 :     }
    7197              : 
    7198              :   return 0;
    7199              : }
    7200              : 
    7201              : /* Decide which element layouts we should consider using.  Calculate the
    7202              :    weights associated with inserting layout changes on partition edges.
    7203              :    Also mark partitions that cannot change layout, by setting their
    7204              :    layout to zero.  */
    7205              : 
    7206              : void
    7207       697455 : vect_optimize_slp_pass::start_choosing_layouts ()
    7208              : {
    7209              :   /* Used to assign unique permutation indices.  */
    7210       697455 :   using perm_hash = unbounded_hashmap_traits<
    7211              :     vec_free_hash_base<int_hash_base<unsigned>>,
    7212              :     int_hash<int, -1, -2>
    7213              :   >;
    7214       697455 :   hash_map<vec<unsigned>, int, perm_hash> layout_ids;
    7215              : 
    7216              :   /* Layout 0 is "no change".  */
    7217       697455 :   m_perms.safe_push (vNULL);
    7218              : 
    7219              :   /* Create layouts from existing permutations.  */
    7220       697455 :   auto_load_permutation_t tmp_perm;
    7221      5629110 :   for (unsigned int node_i : m_partitioned_nodes)
    7222              :     {
    7223              :       /* Leafs also double as entries to the reverse graph.  Allow the
    7224              :          layout of those to be changed.  */
    7225      3536745 :       auto &vertex = m_vertices[node_i];
    7226      3536745 :       auto &partition = m_partitions[vertex.partition];
    7227      3536745 :       if (!m_slpg->vertices[node_i].succ)
    7228       906044 :         partition.layout = 0;
    7229              : 
    7230              :       /* Loads and VEC_PERM_EXPRs are the only things generating permutes.  */
    7231      3536745 :       slp_tree node = vertex.node;
    7232      3536745 :       stmt_vec_info dr_stmt = SLP_TREE_REPRESENTATIVE (node);
    7233      3536745 :       slp_tree child;
    7234      3536745 :       unsigned HOST_WIDE_INT imin, imax = 0;
    7235      3536745 :       bool any_permute = false;
    7236      3536745 :       tmp_perm.truncate (0);
    7237      3536745 :       if (SLP_TREE_LOAD_PERMUTATION (node).exists ())
    7238              :         {
    7239              :           /* If splitting out a SLP_TREE_LANE_PERMUTATION can make the node
    7240              :              unpermuted, record a layout that reverses this permutation.
    7241              : 
    7242              :              We would need more work to cope with loads that are internally
    7243              :              permuted and also have inputs (such as masks for
    7244              :              IFN_MASK_LOADs).  */
    7245       611338 :           gcc_assert (partition.layout == 0 && !m_slpg->vertices[node_i].succ);
    7246       611338 :           if (!STMT_VINFO_GROUPED_ACCESS (dr_stmt))
    7247              :             {
    7248       436382 :               partition.layout = -1;
    7249      3519388 :               continue;
    7250              :             }
    7251       174956 :           dr_stmt = DR_GROUP_FIRST_ELEMENT (dr_stmt);
    7252       174956 :           imin = DR_GROUP_SIZE (dr_stmt) + 1;
    7253       174956 :           tmp_perm.safe_splice (SLP_TREE_LOAD_PERMUTATION (node));
    7254              :         }
    7255      5731987 :       else if (SLP_TREE_PERMUTE_P (node)
    7256       137390 :                && SLP_TREE_CHILDREN (node).length () == 1
    7257       118827 :                && (child = SLP_TREE_CHILDREN (node)[0])
    7258      3044234 :                && (TYPE_VECTOR_SUBPARTS (SLP_TREE_VECTYPE (child))
    7259       118827 :                    .is_constant (&imin)))
    7260              :         {
    7261              :           /* If the child has the same vector size as this node,
    7262              :              reversing the permutation can make the permutation a no-op.
    7263              :              In other cases it can change a true permutation into a
    7264              :              full-vector extract.  */
    7265       118827 :           tmp_perm.reserve (SLP_TREE_LANES (node));
    7266       319562 :           for (unsigned j = 0; j < SLP_TREE_LANES (node); ++j)
    7267       200735 :             tmp_perm.quick_push (SLP_TREE_LANE_PERMUTATION (node)[j].second);
    7268              :         }
    7269              :       else
    7270      2806580 :         continue;
    7271              : 
    7272       777016 :       for (unsigned j = 0; j < SLP_TREE_LANES (node); ++j)
    7273              :         {
    7274       483233 :           unsigned idx = tmp_perm[j];
    7275       483233 :           imin = MIN (imin, idx);
    7276       483233 :           imax = MAX (imax, idx);
    7277       483233 :           if (idx - tmp_perm[0] != j)
    7278       142334 :             any_permute = true;
    7279              :         }
    7280              :       /* If the span doesn't match we'd disrupt VF computation, avoid
    7281              :          that for now.  */
    7282       293783 :       if (imax - imin + 1 != SLP_TREE_LANES (node))
    7283        84202 :         continue;
    7284              :       /* If there's no permute no need to split one out.  In this case
    7285              :          we can consider turning a load into a permuted load, if that
    7286              :          turns out to be cheaper than alternatives.  */
    7287       209581 :       if (!any_permute)
    7288              :         {
    7289       192073 :           partition.layout = -1;
    7290       192073 :           continue;
    7291              :         }
    7292              : 
    7293              :       /* For now only handle true permutes, like
    7294              :          vect_attempt_slp_rearrange_stmts did.  This allows us to be lazy
    7295              :          when permuting constants and invariants keeping the permute
    7296              :          bijective.  */
    7297        17508 :       auto_sbitmap load_index (SLP_TREE_LANES (node));
    7298        17508 :       bitmap_clear (load_index);
    7299        67192 :       for (unsigned j = 0; j < SLP_TREE_LANES (node); ++j)
    7300        49684 :         bitmap_set_bit (load_index, tmp_perm[j] - imin);
    7301              :       unsigned j;
    7302        66357 :       for (j = 0; j < SLP_TREE_LANES (node); ++j)
    7303        49000 :         if (!bitmap_bit_p (load_index, j))
    7304              :           break;
    7305        17508 :       if (j != SLP_TREE_LANES (node))
    7306          151 :         continue;
    7307              : 
    7308        17357 :       vec<unsigned> perm = vNULL;
    7309        17357 :       perm.safe_grow (SLP_TREE_LANES (node), true);
    7310        66082 :       for (unsigned j = 0; j < SLP_TREE_LANES (node); ++j)
    7311        48725 :         perm[j] = tmp_perm[j] - imin;
    7312              : 
    7313        34714 :       if (int (m_perms.length ()) >= param_vect_max_layout_candidates)
    7314              :         {
    7315              :           /* Continue to use existing layouts, but don't add any more.  */
    7316            0 :           int *entry = layout_ids.get (perm);
    7317            0 :           partition.layout = entry ? *entry : 0;
    7318            0 :           perm.release ();
    7319              :         }
    7320              :       else
    7321              :         {
    7322        17357 :           bool existed;
    7323        17357 :           int &layout_i = layout_ids.get_or_insert (perm, &existed);
    7324        17357 :           if (existed)
    7325         6280 :             perm.release ();
    7326              :           else
    7327              :             {
    7328        11077 :               layout_i = m_perms.length ();
    7329        11077 :               m_perms.safe_push (perm);
    7330              :             }
    7331        17357 :           partition.layout = layout_i;
    7332              :         }
    7333        17508 :     }
    7334              : 
    7335              :   /* Initially assume that every layout is possible and has zero cost
    7336              :      in every partition.  */
    7337       697455 :   m_partition_layout_costs.safe_grow_cleared (m_partitions.length ()
    7338      1394910 :                                               * m_perms.length ());
    7339              : 
    7340              :   /* We have to mark outgoing permutations facing non-associating-reduction
    7341              :      graph entries that are not represented as to be materialized.
    7342              :      slp_inst_kind_bb_reduc currently only covers associatable reductions.  */
    7343      3589407 :   for (slp_instance instance : m_vinfo->slp_instances)
    7344      1497042 :     if (SLP_INSTANCE_KIND (instance) == slp_inst_kind_ctor)
    7345              :       {
    7346         6918 :         unsigned int node_i = SLP_INSTANCE_TREE (instance)->vertex;
    7347         6918 :         m_partitions[m_vertices[node_i].partition].layout = 0;
    7348              :       }
    7349      1490124 :     else if (SLP_INSTANCE_KIND (instance) == slp_inst_kind_reduc_chain)
    7350              :       {
    7351         2300 :         stmt_vec_info stmt_info
    7352         2300 :           = SLP_TREE_REPRESENTATIVE (SLP_INSTANCE_TREE (instance));
    7353         2300 :         vect_reduc_info reduc_info
    7354         2300 :           = info_for_reduction (as_a <loop_vec_info> (m_vinfo),
    7355              :                                 SLP_INSTANCE_TREE (instance));
    7356         2300 :         if (needs_fold_left_reduction_p (TREE_TYPE
    7357              :                                            (gimple_get_lhs (stmt_info->stmt)),
    7358              :                                          VECT_REDUC_INFO_CODE (reduc_info)))
    7359              :           {
    7360           97 :             unsigned int node_i = SLP_INSTANCE_TREE (instance)->vertex;
    7361           97 :             m_partitions[m_vertices[node_i].partition].layout = 0;
    7362              :           }
    7363              :       }
    7364              : 
    7365              :   /* Check which layouts each node and partition can handle.  Calculate the
    7366              :      weights associated with inserting layout changes on edges.  */
    7367      5629110 :   for (unsigned int node_i : m_partitioned_nodes)
    7368              :     {
    7369      3536745 :       auto &vertex = m_vertices[node_i];
    7370      3536745 :       auto &partition = m_partitions[vertex.partition];
    7371      3536745 :       slp_tree node = vertex.node;
    7372              : 
    7373      3536745 :       if (stmt_vec_info rep = SLP_TREE_REPRESENTATIVE (node))
    7374              :         {
    7375      3531577 :           vertex.weight = vect_slp_node_weight (node);
    7376              : 
    7377              :           /* We do not handle stores with a permutation, so all
    7378              :              incoming permutations must have been materialized.
    7379              : 
    7380              :              We also don't handle masked grouped loads, which lack a
    7381              :              permutation vector.  In this case the memory locations
    7382              :              form an implicit second input to the loads, on top of the
    7383              :              explicit mask input, and the memory input's layout cannot
    7384              :              be changed.
    7385              : 
    7386              :              On the other hand, we do support permuting gather loads and
    7387              :              masked gather loads, where each scalar load is independent
    7388              :              of the others.  This can be useful if the address/index input
    7389              :              benefits from permutation.  */
    7390      3531577 :           if (STMT_VINFO_DATA_REF (rep)
    7391      1789408 :               && STMT_VINFO_GROUPED_ACCESS (rep)
    7392      4638712 :               && !SLP_TREE_LOAD_PERMUTATION (node).exists ())
    7393       932179 :             partition.layout = 0;
    7394              : 
    7395              :           /* We cannot change the layout of an operation that is
    7396              :              not independent on lanes.  Note this is an explicit
    7397              :              negative list since that's much shorter than the respective
    7398              :              positive one but it's critical to keep maintaining it.  */
    7399      3531577 :           if (is_gimple_call (STMT_VINFO_STMT (rep)))
    7400        32204 :             switch (gimple_call_combined_fn (STMT_VINFO_STMT (rep)))
    7401              :               {
    7402         1091 :               case CFN_COMPLEX_ADD_ROT90:
    7403         1091 :               case CFN_COMPLEX_ADD_ROT270:
    7404         1091 :               case CFN_COMPLEX_MUL:
    7405         1091 :               case CFN_COMPLEX_MUL_CONJ:
    7406         1091 :               case CFN_VEC_ADDSUB:
    7407         1091 :               case CFN_VEC_FMADDSUB:
    7408         1091 :               case CFN_VEC_FMSUBADD:
    7409         1091 :                 partition.layout = 0;
    7410              :               default:;
    7411              :               }
    7412              :         }
    7413              : 
    7414      7939857 :       auto process_edge = [&](graph_edge *ud, unsigned int other_node_i)
    7415              :         {
    7416      4403112 :           auto &other_vertex = m_vertices[other_node_i];
    7417              : 
    7418              :           /* Count the number of edges from earlier partitions and the number
    7419              :              of edges to later partitions.  */
    7420      4403112 :           if (other_vertex.partition < vertex.partition)
    7421      2201556 :             partition.in_degree += 1;
    7422              :           else
    7423      2201556 :             partition.out_degree += 1;
    7424              : 
    7425              :           /* If the current node uses the result of OTHER_NODE_I, accumulate
    7426              :              the effects of that.  */
    7427      4403112 :           if (ud->src == int (node_i))
    7428              :             {
    7429      2201556 :               other_vertex.out_weight += vertex.weight;
    7430      2201556 :               other_vertex.out_degree += 1;
    7431              :             }
    7432      7939857 :         };
    7433      3536745 :       for_each_partition_edge (node_i, process_edge);
    7434              :     }
    7435       697455 : }
    7436              : 
    7437              : /* Return the incoming costs for node NODE_I, assuming that each input keeps
    7438              :    its current (provisional) choice of layout.  The inputs do not necessarily
    7439              :    have the same layout as each other.  */
    7440              : 
    7441              : slpg_layout_cost
    7442         3143 : vect_optimize_slp_pass::total_in_cost (unsigned int node_i)
    7443              : {
    7444         3143 :   auto &vertex = m_vertices[node_i];
    7445         3143 :   slpg_layout_cost cost;
    7446        11488 :   auto add_cost = [&](graph_edge *, unsigned int other_node_i)
    7447              :     {
    7448         8345 :       auto &other_vertex = m_vertices[other_node_i];
    7449         8345 :       if (other_vertex.partition < vertex.partition)
    7450              :         {
    7451         5348 :           auto &other_partition = m_partitions[other_vertex.partition];
    7452        10696 :           auto &other_costs = partition_layout_costs (other_vertex.partition,
    7453         5348 :                                                       other_partition.layout);
    7454         5348 :           slpg_layout_cost this_cost = other_costs.in_cost;
    7455         5348 :           this_cost.add_serial_cost (other_costs.internal_cost);
    7456         5348 :           this_cost.split (other_partition.out_degree);
    7457         5348 :           cost.add_parallel_cost (this_cost);
    7458              :         }
    7459        11488 :     };
    7460         3143 :   for_each_partition_edge (node_i, add_cost);
    7461         3143 :   return cost;
    7462              : }
    7463              : 
    7464              : /* Return the cost of switching between layout LAYOUT1_I (at node NODE1_I)
    7465              :    and layout LAYOUT2_I on cross-partition use-to-def edge UD.  Return
    7466              :    slpg_layout_cost::impossible () if the change isn't possible.  */
    7467              : 
    7468              : slpg_layout_cost
    7469       679541 : vect_optimize_slp_pass::
    7470              : edge_layout_cost (graph_edge *ud, unsigned int node1_i, unsigned int layout1_i,
    7471              :                   unsigned int layout2_i)
    7472              : {
    7473       679541 :   auto &def_vertex = m_vertices[ud->dest];
    7474       679541 :   auto &use_vertex = m_vertices[ud->src];
    7475       679541 :   auto def_layout_i = ud->dest == int (node1_i) ? layout1_i : layout2_i;
    7476       679541 :   auto use_layout_i = ud->dest == int (node1_i) ? layout2_i : layout1_i;
    7477       679541 :   auto factor = change_layout_cost (def_vertex.node, def_layout_i,
    7478              :                                     use_layout_i);
    7479       679541 :   if (factor < 0)
    7480         5506 :     return slpg_layout_cost::impossible ();
    7481              : 
    7482              :   /* We have a choice of putting the layout change at the site of the
    7483              :      definition or at the site of the use.  Prefer the former when
    7484              :      optimizing for size or when the execution frequency of the
    7485              :      definition is no greater than the combined execution frequencies of
    7486              :      the uses.  When putting the layout change at the site of the definition,
    7487              :      divvy up the cost among all consumers.  */
    7488       674035 :   if (m_optimize_size || def_vertex.weight <= def_vertex.out_weight)
    7489              :     {
    7490       652653 :       slpg_layout_cost cost = { def_vertex.weight * factor, m_optimize_size };
    7491       652653 :       cost.split (def_vertex.out_degree);
    7492       652653 :       return cost;
    7493              :     }
    7494        21382 :   return { use_vertex.weight * factor, m_optimize_size };
    7495              : }
    7496              : 
    7497              : /* UD represents a use-def link between FROM_NODE_I and a node in a later
    7498              :    partition; FROM_NODE_I could be the definition node or the use node.
    7499              :    The node at the other end of the link wants to use layout TO_LAYOUT_I.
    7500              :    Return the cost of any necessary fix-ups on edge UD, or return
    7501              :    slpg_layout_cost::impossible () if the change isn't possible.
    7502              : 
    7503              :    At this point, FROM_NODE_I's partition has chosen the cheapest
    7504              :    layout based on the information available so far, but this choice
    7505              :    is only provisional.  */
    7506              : 
    7507              : slpg_layout_cost
    7508       180284 : vect_optimize_slp_pass::forward_cost (graph_edge *ud, unsigned int from_node_i,
    7509              :                                       unsigned int to_layout_i)
    7510              : {
    7511       180284 :   auto &from_vertex = m_vertices[from_node_i];
    7512       180284 :   unsigned int from_partition_i = from_vertex.partition;
    7513       180284 :   slpg_partition_info &from_partition = m_partitions[from_partition_i];
    7514       180284 :   gcc_assert (from_partition.layout >= 0);
    7515              : 
    7516              :   /* First calculate the cost on the assumption that FROM_PARTITION sticks
    7517              :      with its current layout preference.  */
    7518       180284 :   slpg_layout_cost cost = slpg_layout_cost::impossible ();
    7519       180284 :   auto edge_cost = edge_layout_cost (ud, from_node_i,
    7520       180284 :                                      from_partition.layout, to_layout_i);
    7521       180284 :   if (edge_cost.is_possible ())
    7522              :     {
    7523       354822 :       auto &from_costs = partition_layout_costs (from_partition_i,
    7524       177411 :                                                  from_partition.layout);
    7525       177411 :       cost = from_costs.in_cost;
    7526       177411 :       cost.add_serial_cost (from_costs.internal_cost);
    7527       177411 :       cost.split (from_partition.out_degree);
    7528       177411 :       cost.add_serial_cost (edge_cost);
    7529              :     }
    7530         2873 :   else if (from_partition.layout == 0)
    7531              :     /* We must allow the source partition to have layout 0 as a fallback,
    7532              :        in case all other options turn out to be impossible.  */
    7533         2873 :     return cost;
    7534              : 
    7535              :   /* Take the minimum of that cost and the cost that applies if
    7536              :      FROM_PARTITION instead switches to TO_LAYOUT_I.  */
    7537       177411 :   auto &direct_layout_costs = partition_layout_costs (from_partition_i,
    7538              :                                                       to_layout_i);
    7539       177411 :   if (direct_layout_costs.is_possible ())
    7540              :     {
    7541       157046 :       slpg_layout_cost direct_cost = direct_layout_costs.in_cost;
    7542       157046 :       direct_cost.add_serial_cost (direct_layout_costs.internal_cost);
    7543       157046 :       direct_cost.split (from_partition.out_degree);
    7544       157046 :       if (!cost.is_possible ()
    7545       157046 :           || direct_cost.is_better_than (cost, m_optimize_size))
    7546        34807 :         cost = direct_cost;
    7547              :     }
    7548              : 
    7549       177411 :   return cost;
    7550              : }
    7551              : 
    7552              : /* UD represents a use-def link between TO_NODE_I and a node in an earlier
    7553              :    partition; TO_NODE_I could be the definition node or the use node.
    7554              :    The node at the other end of the link wants to use layout FROM_LAYOUT_I;
    7555              :    return the cost of any necessary fix-ups on edge UD, or
    7556              :    slpg_layout_cost::impossible () if the choice cannot be made.
    7557              : 
    7558              :    At this point, TO_NODE_I's partition has a fixed choice of layout.  */
    7559              : 
    7560              : slpg_layout_cost
    7561       163784 : vect_optimize_slp_pass::backward_cost (graph_edge *ud, unsigned int to_node_i,
    7562              :                                        unsigned int from_layout_i)
    7563              : {
    7564       163784 :   auto &to_vertex = m_vertices[to_node_i];
    7565       163784 :   unsigned int to_partition_i = to_vertex.partition;
    7566       163784 :   slpg_partition_info &to_partition = m_partitions[to_partition_i];
    7567       163784 :   gcc_assert (to_partition.layout >= 0);
    7568              : 
    7569              :   /* If TO_NODE_I is a VEC_PERM_EXPR consumer, see whether it can be
    7570              :      adjusted for this input having layout FROM_LAYOUT_I.  Assume that
    7571              :      any other inputs keep their current choice of layout.  */
    7572       163784 :   auto &to_costs = partition_layout_costs (to_partition_i,
    7573              :                                            to_partition.layout);
    7574       163784 :   if (ud->src == int (to_node_i)
    7575       163582 :       && SLP_TREE_PERMUTE_P (to_vertex.node))
    7576              :     {
    7577         9564 :       auto &from_partition = m_partitions[m_vertices[ud->dest].partition];
    7578         9564 :       auto old_layout = from_partition.layout;
    7579         9564 :       from_partition.layout = from_layout_i;
    7580        19128 :       int factor = internal_node_cost (to_vertex.node, -1,
    7581         9564 :                                        to_partition.layout);
    7582         9564 :       from_partition.layout = old_layout;
    7583         9564 :       if (factor >= 0)
    7584              :         {
    7585         8922 :           slpg_layout_cost cost = to_costs.out_cost;
    7586        17844 :           cost.add_serial_cost ({ to_vertex.weight * factor,
    7587         8922 :                                   m_optimize_size });
    7588         8922 :           cost.split (to_partition.in_degree);
    7589         8922 :           return cost;
    7590              :         }
    7591              :     }
    7592              : 
    7593              :   /* Compute the cost if we insert any necessary layout change on edge UD.  */
    7594       154862 :   auto edge_cost = edge_layout_cost (ud, to_node_i,
    7595       154862 :                                      to_partition.layout, from_layout_i);
    7596       154862 :   if (edge_cost.is_possible ())
    7597              :     {
    7598       154862 :       slpg_layout_cost cost = to_costs.out_cost;
    7599       154862 :       cost.add_serial_cost (to_costs.internal_cost);
    7600       154862 :       cost.split (to_partition.in_degree);
    7601       154862 :       cost.add_serial_cost (edge_cost);
    7602       154862 :       return cost;
    7603              :     }
    7604              : 
    7605            0 :   return slpg_layout_cost::impossible ();
    7606              : }
    7607              : 
    7608              : /* Make a forward pass through the partitions, accumulating input costs.
    7609              :    Make a tentative (provisional) choice of layout for each partition,
    7610              :    ensuring that this choice still allows later partitions to keep
    7611              :    their original layout.  */
    7612              : 
    7613              : void
    7614         5631 : vect_optimize_slp_pass::forward_pass ()
    7615              : {
    7616       119487 :   for (unsigned int partition_i = 0; partition_i < m_partitions.length ();
    7617              :        ++partition_i)
    7618              :     {
    7619       113856 :       auto &partition = m_partitions[partition_i];
    7620              : 
    7621              :       /* If the partition consists of a single VEC_PERM_EXPR, precompute
    7622              :          the incoming cost that would apply if every predecessor partition
    7623              :          keeps its current layout.  This is used within the loop below.  */
    7624       113856 :       slpg_layout_cost in_cost;
    7625       113856 :       slp_tree single_node = nullptr;
    7626       113856 :       if (partition.node_end == partition.node_begin + 1)
    7627              :         {
    7628       107516 :           unsigned int node_i = m_partitioned_nodes[partition.node_begin];
    7629       107516 :           single_node = m_vertices[node_i].node;
    7630       107516 :           if (SLP_TREE_PERMUTE_P (single_node))
    7631         3143 :             in_cost = total_in_cost (node_i);
    7632              :         }
    7633              : 
    7634              :       /* Go through the possible layouts.  Decide which ones are valid
    7635              :          for this partition and record which of the valid layouts has
    7636              :          the lowest cost.  */
    7637       113856 :       unsigned int min_layout_i = 0;
    7638       113856 :       slpg_layout_cost min_layout_cost = slpg_layout_cost::impossible ();
    7639       348204 :       for (unsigned int layout_i = 0; layout_i < m_perms.length (); ++layout_i)
    7640              :         {
    7641       234348 :           auto &layout_costs = partition_layout_costs (partition_i, layout_i);
    7642       234348 :           if (!layout_costs.is_possible ())
    7643        57514 :             continue;
    7644              : 
    7645              :           /* If the recorded layout is already 0 then the layout cannot
    7646              :              change.  */
    7647       234348 :           if (partition.layout == 0 && layout_i != 0)
    7648              :             {
    7649        39280 :               layout_costs.mark_impossible ();
    7650        39280 :               continue;
    7651              :             }
    7652              : 
    7653       195068 :           bool is_possible = true;
    7654       400937 :           for (unsigned int order_i = partition.node_begin;
    7655       400937 :                order_i < partition.node_end; ++order_i)
    7656              :             {
    7657       221535 :               unsigned int node_i = m_partitioned_nodes[order_i];
    7658       221535 :               auto &vertex = m_vertices[node_i];
    7659              : 
    7660              :               /* Reject the layout if it is individually incompatible
    7661              :                  with any node in the partition.  */
    7662       221535 :               if (!is_compatible_layout (vertex.node, layout_i))
    7663              :                 {
    7664        14585 :                   is_possible = false;
    7665        15666 :                   break;
    7666              :                 }
    7667              : 
    7668       554409 :               auto add_cost = [&](graph_edge *ud, unsigned int other_node_i)
    7669              :                 {
    7670       347459 :                   auto &other_vertex = m_vertices[other_node_i];
    7671       347459 :                   if (other_vertex.partition < vertex.partition)
    7672              :                     {
    7673              :                       /* Accumulate the incoming costs from earlier
    7674              :                          partitions, plus the cost of any layout changes
    7675              :                          on UD itself.  */
    7676       180284 :                       auto cost = forward_cost (ud, other_node_i, layout_i);
    7677       180284 :                       if (!cost.is_possible ())
    7678         2873 :                         is_possible = false;
    7679              :                       else
    7680       177411 :                         layout_costs.in_cost.add_parallel_cost (cost);
    7681              :                     }
    7682              :                   else
    7683              :                     /* Reject the layout if it would make layout 0 impossible
    7684              :                        for later partitions.  This amounts to testing that the
    7685              :                        target supports reversing the layout change on edges
    7686              :                        to later partitions.
    7687              : 
    7688              :                        In principle, it might be possible to push a layout
    7689              :                        change all the way down a graph, so that it never
    7690              :                        needs to be reversed and so that the target doesn't
    7691              :                        need to support the reverse operation.  But it would
    7692              :                        be awkward to bail out if we hit a partition that
    7693              :                        does not support the new layout, especially since
    7694              :                        we are not dealing with a lattice.  */
    7695       167175 :                     is_possible &= edge_layout_cost (ud, other_node_i, 0,
    7696       167175 :                                                      layout_i).is_possible ();
    7697       554409 :                 };
    7698       206950 :               for_each_partition_edge (node_i, add_cost);
    7699              : 
    7700              :               /* Accumulate the cost of using LAYOUT_I within NODE,
    7701              :                  both for the inputs and the outputs.  */
    7702       206950 :               int factor = internal_node_cost (vertex.node, layout_i,
    7703              :                                                layout_i);
    7704       206950 :               if (factor < 0)
    7705              :                 {
    7706         1081 :                   is_possible = false;
    7707         1081 :                   break;
    7708              :                 }
    7709       205869 :               else if (factor)
    7710        32301 :                 layout_costs.internal_cost.add_serial_cost
    7711        32301 :                   ({ vertex.weight * factor, m_optimize_size });
    7712              :             }
    7713       195068 :           if (!is_possible)
    7714              :             {
    7715        18234 :               layout_costs.mark_impossible ();
    7716        18234 :               continue;
    7717              :             }
    7718              : 
    7719              :           /* Combine the incoming and partition-internal costs.  */
    7720       176834 :           slpg_layout_cost combined_cost = layout_costs.in_cost;
    7721       176834 :           combined_cost.add_serial_cost (layout_costs.internal_cost);
    7722              : 
    7723              :           /* If this partition consists of a single VEC_PERM_EXPR, see
    7724              :              if the VEC_PERM_EXPR can be changed to support output layout
    7725              :              LAYOUT_I while keeping all the provisional choices of input
    7726              :              layout.  */
    7727       176834 :           if (single_node && SLP_TREE_PERMUTE_P (single_node))
    7728              :             {
    7729         5441 :               int factor = internal_node_cost (single_node, -1, layout_i);
    7730         5441 :               if (factor >= 0)
    7731              :                 {
    7732         4986 :                   auto weight = m_vertices[single_node->vertex].weight;
    7733         4986 :                   slpg_layout_cost internal_cost
    7734         4986 :                     = { weight * factor, m_optimize_size };
    7735              : 
    7736         4986 :                   slpg_layout_cost alt_cost = in_cost;
    7737         4986 :                   alt_cost.add_serial_cost (internal_cost);
    7738         4986 :                   if (alt_cost.is_better_than (combined_cost, m_optimize_size))
    7739              :                     {
    7740         1563 :                       combined_cost = alt_cost;
    7741         1563 :                       layout_costs.in_cost = in_cost;
    7742         1563 :                       layout_costs.internal_cost = internal_cost;
    7743              :                     }
    7744              :                 }
    7745              :             }
    7746              : 
    7747              :           /* Record the layout with the lowest cost.  Prefer layout 0 in
    7748              :              the event of a tie between it and another layout.  */
    7749       176834 :           if (!min_layout_cost.is_possible ()
    7750        62978 :               || combined_cost.is_better_than (min_layout_cost,
    7751        62978 :                                                m_optimize_size))
    7752              :             {
    7753       128124 :               min_layout_i = layout_i;
    7754       128124 :               min_layout_cost = combined_cost;
    7755              :             }
    7756              :         }
    7757              : 
    7758              :       /* This loop's handling of earlier partitions should ensure that
    7759              :          choosing the original layout for the current partition is no
    7760              :          less valid than it was in the original graph, even with the
    7761              :          provisional layout choices for those earlier partitions.  */
    7762       113856 :       gcc_assert (min_layout_cost.is_possible ());
    7763       113856 :       partition.layout = min_layout_i;
    7764              :     }
    7765         5631 : }
    7766              : 
    7767              : /* Make a backward pass through the partitions, accumulating output costs.
    7768              :    Make a final choice of layout for each partition.  */
    7769              : 
    7770              : void
    7771         5631 : vect_optimize_slp_pass::backward_pass ()
    7772              : {
    7773       125118 :   for (unsigned int partition_i = m_partitions.length (); partition_i-- > 0;)
    7774              :     {
    7775       113856 :       auto &partition = m_partitions[partition_i];
    7776              : 
    7777       113856 :       unsigned int min_layout_i = 0;
    7778       113856 :       slpg_layout_cost min_layout_cost = slpg_layout_cost::impossible ();
    7779       348204 :       for (unsigned int layout_i = 0; layout_i < m_perms.length (); ++layout_i)
    7780              :         {
    7781       234348 :           auto &layout_costs = partition_layout_costs (partition_i, layout_i);
    7782       234348 :           if (!layout_costs.is_possible ())
    7783        57514 :             continue;
    7784              : 
    7785              :           /* Accumulate the costs from successor partitions.  */
    7786       176834 :           bool is_possible = true;
    7787       380098 :           for (unsigned int order_i = partition.node_begin;
    7788       380098 :                order_i < partition.node_end; ++order_i)
    7789              :             {
    7790       203264 :               unsigned int node_i = m_partitioned_nodes[order_i];
    7791       203264 :               auto &vertex = m_vertices[node_i];
    7792       544268 :               auto add_cost = [&](graph_edge *ud, unsigned int other_node_i)
    7793              :                 {
    7794       341004 :                   auto &other_vertex = m_vertices[other_node_i];
    7795       341004 :                   auto &other_partition = m_partitions[other_vertex.partition];
    7796       341004 :                   if (other_vertex.partition > vertex.partition)
    7797              :                     {
    7798              :                       /* Accumulate the incoming costs from later
    7799              :                          partitions, plus the cost of any layout changes
    7800              :                          on UD itself.  */
    7801       163784 :                       auto cost = backward_cost (ud, other_node_i, layout_i);
    7802       163784 :                       if (!cost.is_possible ())
    7803            0 :                         is_possible = false;
    7804              :                       else
    7805       163784 :                         layout_costs.out_cost.add_parallel_cost (cost);
    7806              :                     }
    7807              :                   else
    7808              :                     /* Make sure that earlier partitions can (if necessary
    7809              :                        or beneficial) keep the layout that they chose in
    7810              :                        the forward pass.  This ensures that there is at
    7811              :                        least one valid choice of layout.  */
    7812       177220 :                     is_possible &= edge_layout_cost (ud, other_node_i,
    7813       177220 :                                                      other_partition.layout,
    7814       177220 :                                                      layout_i).is_possible ();
    7815       544268 :                 };
    7816       203264 :               for_each_partition_edge (node_i, add_cost);
    7817              :             }
    7818       176834 :           if (!is_possible)
    7819              :             {
    7820            0 :               layout_costs.mark_impossible ();
    7821            0 :               continue;
    7822              :             }
    7823              : 
    7824              :           /* Locally combine the costs from the forward and backward passes.
    7825              :              (This combined cost is not passed on, since that would lead
    7826              :              to double counting.)  */
    7827       176834 :           slpg_layout_cost combined_cost = layout_costs.in_cost;
    7828       176834 :           combined_cost.add_serial_cost (layout_costs.internal_cost);
    7829       176834 :           combined_cost.add_serial_cost (layout_costs.out_cost);
    7830              : 
    7831              :           /* Record the layout with the lowest cost.  Prefer layout 0 in
    7832              :              the event of a tie between it and another layout.  */
    7833       176834 :           if (!min_layout_cost.is_possible ()
    7834        62978 :               || combined_cost.is_better_than (min_layout_cost,
    7835        62978 :                                                m_optimize_size))
    7836              :             {
    7837       121258 :               min_layout_i = layout_i;
    7838       121258 :               min_layout_cost = combined_cost;
    7839              :             }
    7840              :         }
    7841              : 
    7842       113856 :       gcc_assert (min_layout_cost.is_possible ());
    7843       113856 :       partition.layout = min_layout_i;
    7844              :     }
    7845         5631 : }
    7846              : 
    7847              : /* Return a node that applies layout TO_LAYOUT_I to the original form of NODE.
    7848              :    NODE already has the layout that was selected for its partition.  */
    7849              : 
    7850              : slp_tree
    7851       158912 : vect_optimize_slp_pass::get_result_with_layout (slp_tree node,
    7852              :                                                 unsigned int to_layout_i)
    7853              : {
    7854       158912 :   unsigned int result_i = node->vertex * m_perms.length () + to_layout_i;
    7855       158912 :   slp_tree result = m_node_layouts[result_i];
    7856       158912 :   if (result)
    7857              :     return result;
    7858              : 
    7859       158369 :   if (SLP_TREE_DEF_TYPE (node) == vect_constant_def
    7860       158369 :       || (SLP_TREE_DEF_TYPE (node) == vect_external_def
    7861              :           /* We can't permute vector defs in place.  */
    7862        18546 :           && SLP_TREE_VEC_DEFS (node).is_empty ()))
    7863              :     {
    7864              :       /* If the vector is uniform or unchanged, there's nothing to do.  */
    7865        38585 :       if (to_layout_i == 0 || vect_slp_tree_uniform_p (node))
    7866              :         result = node;
    7867              :       else
    7868              :         {
    7869         2266 :           auto scalar_ops = SLP_TREE_SCALAR_OPS (node).copy ();
    7870         2266 :           result = vect_create_new_slp_node (scalar_ops);
    7871         2266 :           vect_slp_permute (m_perms[to_layout_i], scalar_ops, true);
    7872              :         }
    7873              :     }
    7874              :   else
    7875              :     {
    7876       119784 :       unsigned int partition_i = m_vertices[node->vertex].partition;
    7877       119784 :       unsigned int from_layout_i = m_partitions[partition_i].layout;
    7878       119784 :       if (from_layout_i == to_layout_i)
    7879       119213 :         return node;
    7880              : 
    7881              :       /* If NODE is itself a VEC_PERM_EXPR, try to create a parallel
    7882              :          permutation instead of a serial one.  Leave the new permutation
    7883              :          in TMP_PERM on success.  */
    7884          571 :       auto_lane_permutation_t tmp_perm;
    7885          571 :       unsigned int num_inputs = 1;
    7886          571 :       if (SLP_TREE_PERMUTE_P (node))
    7887              :         {
    7888            7 :           tmp_perm.safe_splice (SLP_TREE_LANE_PERMUTATION (node));
    7889            7 :           if (from_layout_i != 0)
    7890            7 :             vect_slp_permute (m_perms[from_layout_i], tmp_perm, false);
    7891            7 :           if (to_layout_i != 0)
    7892            4 :             vect_slp_permute (m_perms[to_layout_i], tmp_perm, true);
    7893            7 :           if (vectorizable_slp_permutation_1 (m_vinfo, nullptr, node,
    7894              :                                               tmp_perm,
    7895            7 :                                               SLP_TREE_CHILDREN (node),
    7896              :                                               false) >= 0)
    7897            7 :             num_inputs = SLP_TREE_CHILDREN (node).length ();
    7898              :           else
    7899            0 :             tmp_perm.truncate (0);
    7900              :         }
    7901              : 
    7902          571 :       if (dump_enabled_p ())
    7903              :         {
    7904           70 :           if (tmp_perm.length () > 0)
    7905            6 :             dump_printf_loc (MSG_NOTE, vect_location,
    7906              :                              "duplicating permutation node %p with"
    7907              :                              " layout %d\n",
    7908              :                              (void *) node, to_layout_i);
    7909              :           else
    7910           64 :             dump_printf_loc (MSG_NOTE, vect_location,
    7911              :                              "inserting permutation node in place of %p\n",
    7912              :                              (void *) node);
    7913              :         }
    7914              : 
    7915          571 :       unsigned int num_lanes = SLP_TREE_LANES (node);
    7916          571 :       result = vect_create_new_slp_node (num_inputs, VEC_PERM_EXPR);
    7917          571 :       if (SLP_TREE_SCALAR_STMTS (node).length ())
    7918              :         {
    7919          570 :           auto &stmts = SLP_TREE_SCALAR_STMTS (result);
    7920          570 :           stmts.safe_splice (SLP_TREE_SCALAR_STMTS (node));
    7921          570 :           if (from_layout_i != 0)
    7922          299 :             vect_slp_permute (m_perms[from_layout_i], stmts, false);
    7923          570 :           if (to_layout_i != 0)
    7924          275 :             vect_slp_permute (m_perms[to_layout_i], stmts, true);
    7925              :         }
    7926          571 :       SLP_TREE_REPRESENTATIVE (result) = SLP_TREE_REPRESENTATIVE (node);
    7927          571 :       SLP_TREE_LANES (result) = num_lanes;
    7928          571 :       SLP_TREE_VECTYPE (result) = SLP_TREE_VECTYPE (node);
    7929          571 :       result->vertex = -1;
    7930              : 
    7931          571 :       auto &lane_perm = SLP_TREE_LANE_PERMUTATION (result);
    7932          571 :       if (tmp_perm.length ())
    7933              :         {
    7934            7 :           lane_perm.safe_splice (tmp_perm);
    7935            7 :           SLP_TREE_CHILDREN (result).safe_splice (SLP_TREE_CHILDREN (node));
    7936              :         }
    7937              :       else
    7938              :         {
    7939          564 :           lane_perm.create (num_lanes);
    7940         1756 :           for (unsigned j = 0; j < num_lanes; ++j)
    7941         1192 :             lane_perm.quick_push ({ 0, j });
    7942          564 :           if (from_layout_i != 0)
    7943          292 :             vect_slp_permute (m_perms[from_layout_i], lane_perm, false);
    7944          564 :           if (to_layout_i != 0)
    7945          272 :             vect_slp_permute (m_perms[to_layout_i], lane_perm, true);
    7946          564 :           SLP_TREE_CHILDREN (result).safe_push (node);
    7947              :         }
    7948         2288 :       for (slp_tree child : SLP_TREE_CHILDREN (result))
    7949          575 :         child->refcnt++;
    7950          571 :     }
    7951        39156 :   m_node_layouts[result_i] = result;
    7952        39156 :   return result;
    7953              : }
    7954              : 
    7955              : /* Apply the chosen vector layouts to the SLP graph.  */
    7956              : 
    7957              : void
    7958        10655 : vect_optimize_slp_pass::materialize ()
    7959              : {
    7960              :   /* We no longer need the costs, so avoid having two O(N * P) arrays
    7961              :      live at the same time.  */
    7962        10655 :   m_partition_layout_costs.release ();
    7963        31965 :   m_node_layouts.safe_grow_cleared (m_vertices.length () * m_perms.length ());
    7964              : 
    7965        21310 :   auto_sbitmap fully_folded (m_vertices.length ());
    7966        10655 :   bitmap_clear (fully_folded);
    7967       169276 :   for (unsigned int node_i : m_partitioned_nodes)
    7968              :     {
    7969       137311 :       auto &vertex = m_vertices[node_i];
    7970       137311 :       slp_tree node = vertex.node;
    7971       137311 :       int layout_i = m_partitions[vertex.partition].layout;
    7972       137311 :       gcc_assert (layout_i >= 0);
    7973              : 
    7974              :       /* Rearrange the scalar statements to match the chosen layout.  */
    7975       137311 :       if (layout_i > 0)
    7976        15947 :         vect_slp_permute (m_perms[layout_i],
    7977        15947 :                           SLP_TREE_SCALAR_STMTS (node), true);
    7978              : 
    7979              :       /* Update load and lane permutations.  */
    7980       137311 :       if (SLP_TREE_PERMUTE_P (node))
    7981              :         {
    7982              :           /* First try to absorb the input vector layouts.  If that fails,
    7983              :              force the inputs to have layout LAYOUT_I too.  We checked that
    7984              :              that was possible before deciding to use nonzero output layouts.
    7985              :              (Note that at this stage we don't really have any guarantee that
    7986              :              the target supports the original VEC_PERM_EXPR.)  */
    7987         5350 :           auto &perm = SLP_TREE_LANE_PERMUTATION (node);
    7988         5350 :           auto_lane_permutation_t tmp_perm;
    7989         5350 :           tmp_perm.safe_splice (perm);
    7990         5350 :           change_vec_perm_layout (node, tmp_perm, -1, layout_i);
    7991         5350 :           if (vectorizable_slp_permutation_1 (m_vinfo, nullptr, node,
    7992              :                                               tmp_perm,
    7993         5350 :                                               SLP_TREE_CHILDREN (node),
    7994              :                                               false) >= 0)
    7995              :             {
    7996         4971 :               if (dump_enabled_p ()
    7997         5891 :                   && !std::equal (tmp_perm.begin (), tmp_perm.end (),
    7998              :                                   perm.begin ()))
    7999           58 :                 dump_printf_loc (MSG_NOTE, vect_location,
    8000              :                                  "absorbing input layouts into %p\n",
    8001              :                                  (void *) node);
    8002        27994 :               std::copy (tmp_perm.begin (), tmp_perm.end (), perm.begin ());
    8003         4971 :               bitmap_set_bit (fully_folded, node_i);
    8004              :             }
    8005              :           else
    8006              :             {
    8007              :               /* Not MSG_MISSED because it would make no sense to users.  */
    8008          379 :               if (dump_enabled_p ())
    8009           46 :                 dump_printf_loc (MSG_NOTE, vect_location,
    8010              :                                  "failed to absorb input layouts into %p\n",
    8011              :                                  (void *) node);
    8012          379 :               change_vec_perm_layout (nullptr, perm, layout_i, layout_i);
    8013              :             }
    8014         5350 :         }
    8015              :       else
    8016              :         {
    8017       131961 :           gcc_assert (!SLP_TREE_LANE_PERMUTATION (node).exists ());
    8018       131961 :           auto &load_perm = SLP_TREE_LOAD_PERMUTATION (node);
    8019       131961 :           if (layout_i > 0)
    8020              :             /* ???  When we handle non-bijective permutes the idea
    8021              :                is that we can force the load-permutation to be
    8022              :                { min, min + 1, min + 2, ... max }.  But then the
    8023              :                scalar defs might no longer match the lane content
    8024              :                which means wrong-code with live lane vectorization.
    8025              :                So we possibly have to have NULL entries for those.  */
    8026        15848 :             vect_slp_permute (m_perms[layout_i], load_perm, true);
    8027              :         }
    8028              :     }
    8029              : 
    8030              :   /* Do this before any nodes disappear, since it involves a walk
    8031              :      over the leaves.  */
    8032        10655 :   remove_redundant_permutations ();
    8033              : 
    8034              :   /* Replace each child with a correctly laid-out version.  */
    8035       169276 :   for (unsigned int node_i : m_partitioned_nodes)
    8036              :     {
    8037              :       /* Skip nodes that have already been handled above.  */
    8038       137311 :       if (bitmap_bit_p (fully_folded, node_i))
    8039         4971 :         continue;
    8040              : 
    8041       132340 :       auto &vertex = m_vertices[node_i];
    8042       132340 :       int in_layout_i = m_partitions[vertex.partition].layout;
    8043       132340 :       gcc_assert (in_layout_i >= 0);
    8044              : 
    8045              :       unsigned j;
    8046              :       slp_tree child;
    8047       398356 :       FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (vertex.node), j, child)
    8048              :         {
    8049       164928 :           if (!child)
    8050         6016 :             continue;
    8051              : 
    8052       158912 :           slp_tree new_child = get_result_with_layout (child, in_layout_i);
    8053       158912 :           if (new_child != child)
    8054              :             {
    8055         3080 :               vect_free_slp_tree (child);
    8056         3080 :               SLP_TREE_CHILDREN (vertex.node)[j] = new_child;
    8057         3080 :               new_child->refcnt += 1;
    8058              :             }
    8059              :         }
    8060              :     }
    8061        10655 : }
    8062              : 
    8063              : /* Elide load permutations that are not necessary.  Such permutations might
    8064              :    be pre-existing, rather than created by the layout optimizations.  */
    8065              : 
    8066              : void
    8067       697455 : vect_optimize_slp_pass::remove_redundant_permutations ()
    8068              : {
    8069      4592395 :   for (unsigned int node_i : m_leafs)
    8070              :     {
    8071      2500030 :       slp_tree node = m_vertices[node_i].node;
    8072      2500030 :       if (!SLP_TREE_LOAD_PERMUTATION (node).exists ())
    8073      1888692 :         continue;
    8074              : 
    8075              :       /* In basic block vectorization we allow any subchain of an interleaving
    8076              :          chain.
    8077              :          FORNOW: not in loop SLP because of realignment complications.  */
    8078       611338 :       if (is_a <bb_vec_info> (m_vinfo))
    8079              :         {
    8080       162607 :           bool subchain_p = true;
    8081              :           stmt_vec_info next_load_info = NULL;
    8082              :           stmt_vec_info load_info;
    8083              :           unsigned j;
    8084       162607 :           FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), j, load_info)
    8085              :             {
    8086       132439 :               if (j != 0
    8087       132439 :                   && (next_load_info != load_info
    8088        62467 :                       || ! load_info
    8089        62467 :                       || DR_GROUP_GAP (load_info) != 1))
    8090              :                 {
    8091              :                   subchain_p = false;
    8092              :                   break;
    8093              :                 }
    8094       108846 :               next_load_info = DR_GROUP_NEXT_ELEMENT (load_info);
    8095              :             }
    8096        53761 :           if (subchain_p)
    8097              :             {
    8098        30168 :               SLP_TREE_LOAD_PERMUTATION (node).release ();
    8099        30168 :               continue;
    8100              :             }
    8101              :         }
    8102              :       else
    8103              :         {
    8104       557577 :           loop_vec_info loop_vinfo = as_a<loop_vec_info> (m_vinfo);
    8105       557577 :           bool this_load_permuted = !vect_load_perm_consecutive_p (node, 0);
    8106              :           /* When this isn't a grouped access we know it's single element
    8107              :              and contiguous.  */
    8108       557577 :           if (!STMT_VINFO_GROUPED_ACCESS (SLP_TREE_SCALAR_STMTS (node)[0]))
    8109              :             {
    8110       436382 :               if (!this_load_permuted
    8111       436382 :                   && (known_eq (LOOP_VINFO_VECT_FACTOR (loop_vinfo), 1U)
    8112       435627 :                       || SLP_TREE_LANES (node) == 1))
    8113       435629 :                 SLP_TREE_LOAD_PERMUTATION (node).release ();
    8114       436382 :               continue;
    8115              :             }
    8116       121195 :           stmt_vec_info first_stmt_info
    8117       121195 :             = DR_GROUP_FIRST_ELEMENT (SLP_TREE_SCALAR_STMTS (node)[0]);
    8118       121700 :           if (!this_load_permuted
    8119              :               /* The load requires permutation when unrolling exposes
    8120              :                  a gap either because the group is larger than the SLP
    8121              :                  group-size or because there is a gap between the groups.  */
    8122       121195 :               && (known_eq (LOOP_VINFO_VECT_FACTOR (loop_vinfo), 1U)
    8123        98753 :                   || ((SLP_TREE_LANES (node) == DR_GROUP_SIZE (first_stmt_info))
    8124          140 :                       && DR_GROUP_GAP (first_stmt_info) == 0)))
    8125              :             {
    8126          505 :               SLP_TREE_LOAD_PERMUTATION (node).release ();
    8127          505 :               continue;
    8128              :             }
    8129              :         }
    8130              :     }
    8131       697455 : }
    8132              : 
    8133              : /* Print the partition graph and layout information to the dump file.  */
    8134              : 
    8135              : void
    8136          679 : vect_optimize_slp_pass::dump ()
    8137              : {
    8138          679 :   dump_printf_loc (MSG_NOTE, vect_location,
    8139              :                    "SLP optimize permutations:\n");
    8140         1371 :   for (unsigned int layout_i = 1; layout_i < m_perms.length (); ++layout_i)
    8141              :     {
    8142          692 :       dump_printf_loc (MSG_NOTE, vect_location, "  %d: { ", layout_i);
    8143          692 :       const char *sep = "";
    8144         5909 :       for (unsigned int idx : m_perms[layout_i])
    8145              :         {
    8146         3833 :           dump_printf (MSG_NOTE, "%s%d", sep, idx);
    8147         3833 :           sep = ", ";
    8148              :         }
    8149          692 :       dump_printf (MSG_NOTE, " }\n");
    8150              :     }
    8151          679 :   dump_printf_loc (MSG_NOTE, vect_location,
    8152              :                    "SLP optimize partitions:\n");
    8153         5659 :   for (unsigned int partition_i = 0; partition_i < m_partitions.length ();
    8154              :        ++partition_i)
    8155              :     {
    8156         4980 :       auto &partition = m_partitions[partition_i];
    8157         4980 :       dump_printf_loc (MSG_NOTE, vect_location,  "  -------------\n");
    8158         4980 :       dump_printf_loc (MSG_NOTE, vect_location,
    8159              :                        "  partition %d (layout %d):\n",
    8160              :                        partition_i, partition.layout);
    8161         4980 :       dump_printf_loc (MSG_NOTE, vect_location, "    nodes:\n");
    8162        10196 :       for (unsigned int order_i = partition.node_begin;
    8163        10196 :            order_i < partition.node_end; ++order_i)
    8164              :         {
    8165         5216 :           auto &vertex = m_vertices[m_partitioned_nodes[order_i]];
    8166        10432 :           dump_printf_loc (MSG_NOTE, vect_location, "      - %p:\n",
    8167         5216 :                            (void *) vertex.node);
    8168         5216 :           dump_printf_loc (MSG_NOTE, vect_location,
    8169              :                            "          weight: %f\n",
    8170              :                            vertex.weight.to_double ());
    8171         5216 :           if (vertex.out_degree)
    8172         4083 :             dump_printf_loc (MSG_NOTE, vect_location,
    8173              :                              "          out weight: %f (degree %d)\n",
    8174              :                              vertex.out_weight.to_double (),
    8175              :                              vertex.out_degree);
    8176         5216 :           if (SLP_TREE_PERMUTE_P (vertex.node))
    8177          506 :             dump_printf_loc (MSG_NOTE, vect_location,
    8178              :                              "          op: VEC_PERM_EXPR\n");
    8179         4710 :           else if (auto rep = SLP_TREE_REPRESENTATIVE (vertex.node))
    8180         4692 :             dump_printf_loc (MSG_NOTE, vect_location,
    8181              :                              "          op template: %G", rep->stmt);
    8182              :         }
    8183         4980 :       dump_printf_loc (MSG_NOTE, vect_location, "    edges:\n");
    8184        10196 :       for (unsigned int order_i = partition.node_begin;
    8185        10196 :            order_i < partition.node_end; ++order_i)
    8186              :         {
    8187         5216 :           unsigned int node_i = m_partitioned_nodes[order_i];
    8188         5216 :           auto &vertex = m_vertices[node_i];
    8189        15726 :           auto print_edge = [&](graph_edge *, unsigned int other_node_i)
    8190              :             {
    8191        10510 :               auto &other_vertex = m_vertices[other_node_i];
    8192        10510 :               if (other_vertex.partition < vertex.partition)
    8193         5255 :                 dump_printf_loc (MSG_NOTE, vect_location,
    8194              :                                  "      - %p [%d] --> %p\n",
    8195         5255 :                                  (void *) other_vertex.node,
    8196              :                                  other_vertex.partition,
    8197         5255 :                                  (void *) vertex.node);
    8198              :               else
    8199         5255 :                 dump_printf_loc (MSG_NOTE, vect_location,
    8200              :                                  "      - %p --> [%d] %p\n",
    8201         5255 :                                  (void *) vertex.node,
    8202              :                                  other_vertex.partition,
    8203         5255 :                                  (void *) other_vertex.node);
    8204        15726 :             };
    8205         5216 :           for_each_partition_edge (node_i, print_edge);
    8206              :         }
    8207              : 
    8208        15139 :       for (unsigned int layout_i = 0; layout_i < m_perms.length (); ++layout_i)
    8209              :         {
    8210        10159 :           auto &layout_costs = partition_layout_costs (partition_i, layout_i);
    8211        10159 :           if (layout_costs.is_possible ())
    8212              :             {
    8213         8380 :               dump_printf_loc (MSG_NOTE, vect_location,
    8214              :                                "    layout %d:%s\n", layout_i,
    8215         8380 :                                partition.layout == int (layout_i)
    8216              :                                ? " (*)" : "");
    8217         8380 :               slpg_layout_cost combined_cost = layout_costs.in_cost;
    8218         8380 :               combined_cost.add_serial_cost (layout_costs.internal_cost);
    8219         8380 :               combined_cost.add_serial_cost (layout_costs.out_cost);
    8220              : #define TEMPLATE "{depth: %f, total: %f}"
    8221         8380 :               dump_printf_loc (MSG_NOTE, vect_location,
    8222              :                                "        " TEMPLATE "\n",
    8223              :                                layout_costs.in_cost.depth.to_double (),
    8224              :                                layout_costs.in_cost.total.to_double ());
    8225         8380 :               dump_printf_loc (MSG_NOTE, vect_location,
    8226              :                                "      + " TEMPLATE "\n",
    8227              :                                layout_costs.internal_cost.depth.to_double (),
    8228              :                                layout_costs.internal_cost.total.to_double ());
    8229         8380 :               dump_printf_loc (MSG_NOTE, vect_location,
    8230              :                                "      + " TEMPLATE "\n",
    8231              :                                layout_costs.out_cost.depth.to_double (),
    8232              :                                layout_costs.out_cost.total.to_double ());
    8233         8380 :               dump_printf_loc (MSG_NOTE, vect_location,
    8234              :                                "      = " TEMPLATE "\n",
    8235              :                                combined_cost.depth.to_double (),
    8236              :                                combined_cost.total.to_double ());
    8237              : #undef TEMPLATE
    8238              :             }
    8239              :           else
    8240         1779 :             dump_printf_loc (MSG_NOTE, vect_location,
    8241              :                              "    layout %d: rejected\n", layout_i);
    8242              :         }
    8243              :     }
    8244          679 : }
    8245              : 
    8246              : /* Masked load lanes discovery.  */
    8247              : 
    8248              : void
    8249       697455 : vect_optimize_slp_pass::decide_masked_load_lanes ()
    8250              : {
    8251      7133012 :   for (auto v : m_vertices)
    8252              :     {
    8253      5040647 :       slp_tree node = v.node;
    8254      5040647 :       if (SLP_TREE_DEF_TYPE (node) != vect_internal_def
    8255      3535239 :           || SLP_TREE_PERMUTE_P (node))
    8256      1643367 :         continue;
    8257      3397280 :       stmt_vec_info stmt_info = SLP_TREE_REPRESENTATIVE (node);
    8258      1669362 :       if (! STMT_VINFO_GROUPED_ACCESS (stmt_info)
    8259              :           /* The mask has to be uniform.  */
    8260       987686 :           || STMT_VINFO_SLP_VECT_ONLY (stmt_info)
    8261       987608 :           || ! is_a <gcall *> (STMT_VINFO_STMT (stmt_info))
    8262      3397365 :           || ! gimple_call_internal_p (STMT_VINFO_STMT (stmt_info),
    8263              :                                        IFN_MASK_LOAD))
    8264      3397247 :         continue;
    8265           33 :       stmt_info = DR_GROUP_FIRST_ELEMENT (stmt_info);
    8266           66 :       if (STMT_VINFO_STRIDED_P (stmt_info)
    8267           33 :           || compare_step_with_zero (m_vinfo, stmt_info) <= 0
    8268           63 :           || vect_load_lanes_supported (SLP_TREE_VECTYPE (node),
    8269           30 :                                         DR_GROUP_SIZE (stmt_info),
    8270              :                                         true) == IFN_LAST)
    8271           33 :         continue;
    8272              : 
    8273              :       /* Uniform masks need to be suitably represented.  */
    8274            0 :       slp_tree mask = SLP_TREE_CHILDREN (node)[0];
    8275            0 :       if (!SLP_TREE_PERMUTE_P (mask)
    8276            0 :           || SLP_TREE_CHILDREN (mask).length () != 1)
    8277            0 :         continue;
    8278            0 :       bool match = true;
    8279            0 :       for (auto perm : SLP_TREE_LANE_PERMUTATION (mask))
    8280            0 :         if (perm.first != 0 || perm.second != 0)
    8281              :           {
    8282              :             match = false;
    8283              :             break;
    8284              :           }
    8285            0 :       if (!match)
    8286            0 :         continue;
    8287              : 
    8288              :       /* Now see if the consumer side matches.  */
    8289            0 :       for (graph_edge *pred = m_slpg->vertices[node->vertex].pred;
    8290            0 :            pred; pred = pred->pred_next)
    8291              :         {
    8292            0 :           slp_tree pred_node = m_vertices[pred->src].node;
    8293              :           /* All consumers should be a permute with a single outgoing lane.  */
    8294            0 :           if (!SLP_TREE_PERMUTE_P (pred_node)
    8295            0 :               || SLP_TREE_LANES (pred_node) != 1)
    8296              :             {
    8297              :               match = false;
    8298              :               break;
    8299              :             }
    8300            0 :           gcc_assert (SLP_TREE_CHILDREN (pred_node).length () == 1);
    8301              :         }
    8302            0 :       if (!match)
    8303            0 :         continue;
    8304              :       /* Now we can mark the nodes as to use load lanes.  */
    8305            0 :       node->ldst_lanes = true;
    8306            0 :       for (graph_edge *pred = m_slpg->vertices[node->vertex].pred;
    8307            0 :            pred; pred = pred->pred_next)
    8308            0 :         m_vertices[pred->src].node->ldst_lanes = true;
    8309              :       /* The catch is we have to massage the mask.  We have arranged
    8310              :          analyzed uniform masks to be represented by a splat VEC_PERM
    8311              :          which we can now simply elide as we cannot easily re-do SLP
    8312              :          discovery here.  */
    8313            0 :       slp_tree new_mask = SLP_TREE_CHILDREN (mask)[0];
    8314            0 :       SLP_TREE_REF_COUNT (new_mask)++;
    8315            0 :       SLP_TREE_CHILDREN (node)[0] = new_mask;
    8316            0 :       vect_free_slp_tree (mask);
    8317              :     }
    8318       697455 : }
    8319              : 
    8320              : /* Perform legitimizing attempts.  This is intended to improve the
    8321              :    situation when layout 0 is not valid which is a situation the cost
    8322              :    based propagation does not handle well.
    8323              :    Return true if further layout optimization is possible, false if
    8324              :    the layout configuration should be considered final.  */
    8325              : 
    8326              : bool
    8327        10655 : vect_optimize_slp_pass::legitimize ()
    8328              : {
    8329              :   /* Perform a very simple legitimizing attempt by attempting to choose
    8330              :      a single layout for all partitions that will make all permutations
    8331              :      a noop.  That should also be the optimal layout choice in case
    8332              :      layout zero is legitimate.
    8333              :      ???  Disconnected components of the SLP graph could have distinct
    8334              :      single layouts.  */
    8335        10655 :   int single_layout_i = -1;
    8336        10655 :   unsigned deferred_up_to = -1U;
    8337        33380 :   for (unsigned partition_i = 0; partition_i < m_partitions.length ();
    8338              :        ++partition_i)
    8339              :     {
    8340        28347 :       auto &partition = m_partitions[partition_i];
    8341        28347 :       if (single_layout_i == -1)
    8342              :         {
    8343        14571 :           single_layout_i = partition.layout;
    8344        14571 :           deferred_up_to = partition_i;
    8345              :         }
    8346        13776 :       else if (partition.layout == single_layout_i || partition.layout == -1)
    8347              :         ;
    8348              :       else
    8349              :         single_layout_i = 0;
    8350        25244 :       if (single_layout_i == 0)
    8351              :         return true;
    8352              : 
    8353        22808 :       if (single_layout_i != -1
    8354        22808 :           && !is_compatible_layout (partition, single_layout_i))
    8355              :         return true;
    8356              :     }
    8357              : 
    8358         5033 :   if (single_layout_i <= 0)
    8359              :     return true;
    8360              : 
    8361         5111 :   for (unsigned partition_i = 0; partition_i < deferred_up_to; ++partition_i)
    8362           87 :     if (!is_compatible_layout (m_partitions[partition_i],
    8363              :                                single_layout_i))
    8364              :       return true;
    8365              : 
    8366        13042 :   for (unsigned partition_i = 0; partition_i < m_partitions.length ();
    8367              :        ++partition_i)
    8368              :     {
    8369         8018 :       auto &partition = m_partitions[partition_i];
    8370         8018 :       partition.layout = single_layout_i;
    8371              :     }
    8372              : 
    8373              :   return false;
    8374              : }
    8375              : 
    8376              : /* Main entry point for the SLP graph optimization pass.  */
    8377              : 
    8378              : void
    8379       697455 : vect_optimize_slp_pass::run ()
    8380              : {
    8381       697455 :   build_graph ();
    8382       697455 :   create_partitions ();
    8383       697455 :   start_choosing_layouts ();
    8384       697455 :   if (m_perms.length () > 1)
    8385              :     {
    8386        10655 :       if (legitimize ())
    8387              :         {
    8388         5631 :           forward_pass ();
    8389         5631 :           backward_pass ();
    8390              :         }
    8391        10655 :       if (dump_enabled_p ())
    8392          679 :         dump ();
    8393        10655 :       materialize ();
    8394        43042 :       while (!m_perms.is_empty ())
    8395        21732 :         m_perms.pop ().release ();
    8396              :     }
    8397              :   else
    8398       686800 :     remove_redundant_permutations ();
    8399       697455 :   free_graph (m_slpg);
    8400       697455 :   build_graph ();
    8401       697455 :   decide_masked_load_lanes ();
    8402       697455 :   free_graph (m_slpg);
    8403       697455 : }
    8404              : 
    8405              : /* Apply CSE to NODE and its children using BST_MAP.  */
    8406              : 
    8407              : static void
    8408      5439948 : vect_cse_slp_nodes (scalar_stmts_to_slp_tree_map_t *bst_map, slp_tree& node)
    8409              : {
    8410      5439948 :   bool put_p = false;
    8411      5439948 :   if (SLP_TREE_DEF_TYPE (node) == vect_internal_def
    8412              :       /* Besides some VEC_PERM_EXPR, two-operator nodes also
    8413              :          lack scalar stmts and thus CSE doesn't work via bst_map.  Ideally
    8414              :          we'd have sth that works for all internal and external nodes.  */
    8415      5439948 :       && !SLP_TREE_SCALAR_STMTS (node).is_empty ())
    8416              :     {
    8417      3908663 :       slp_tree *leader = bst_map->get (SLP_TREE_SCALAR_STMTS (node));
    8418      3908663 :       if (leader)
    8419              :         {
    8420              :           /* We've visited this node already.  */
    8421       402225 :           if (!*leader || *leader == node)
    8422              :             return;
    8423              : 
    8424         3127 :           if (dump_enabled_p ())
    8425          912 :             dump_printf_loc (MSG_NOTE, vect_location,
    8426              :                              "re-using SLP tree %p for %p\n",
    8427              :                              (void *)*leader, (void *)node);
    8428         3127 :           vect_free_slp_tree (node);
    8429         3127 :           (*leader)->refcnt += 1;
    8430         3127 :           node = *leader;
    8431         3127 :           return;
    8432              :         }
    8433              : 
    8434              :       /* Avoid creating a cycle by populating the map only after recursion.  */
    8435      3506438 :       bst_map->put (SLP_TREE_SCALAR_STMTS (node).copy (), nullptr);
    8436      3506438 :       node->refcnt += 1;
    8437      3506438 :       put_p = true;
    8438              :       /* And recurse.  */
    8439              :     }
    8440              : 
    8441     15020996 :   for (slp_tree &child : SLP_TREE_CHILDREN (node))
    8442      4380943 :     if (child)
    8443      3942906 :       vect_cse_slp_nodes (bst_map, child);
    8444              : 
    8445              :   /* Now record the node for CSE in other siblings.  */
    8446      5037723 :   if (put_p)
    8447      3506438 :     *bst_map->get (SLP_TREE_SCALAR_STMTS (node)) = node;
    8448              : }
    8449              : 
    8450              : /* Optimize the SLP graph of VINFO.  */
    8451              : 
    8452              : void
    8453      1053074 : vect_optimize_slp (vec_info *vinfo)
    8454              : {
    8455      1053074 :   if (vinfo->slp_instances.is_empty ())
    8456              :     return;
    8457       697455 :   vect_optimize_slp_pass (vinfo).run ();
    8458              : 
    8459              :   /* Apply CSE again to nodes after permute optimization.  */
    8460       697455 :   scalar_stmts_to_slp_tree_map_t *bst_map
    8461       697455 :     = new scalar_stmts_to_slp_tree_map_t ();
    8462              : 
    8463      3589407 :   for (auto inst : vinfo->slp_instances)
    8464      1497042 :     vect_cse_slp_nodes (bst_map, SLP_INSTANCE_TREE (inst));
    8465              : 
    8466       697455 :   release_scalar_stmts_to_slp_tree_map (bst_map);
    8467              : }
    8468              : 
    8469              : /* Gather loads reachable from the individual SLP graph entries.  */
    8470              : 
    8471              : void
    8472      1053074 : vect_gather_slp_loads (vec_info *vinfo)
    8473              : {
    8474      1053074 :   unsigned i;
    8475      1053074 :   slp_instance instance;
    8476      2550116 :   FOR_EACH_VEC_ELT (vinfo->slp_instances, i, instance)
    8477              :     {
    8478      1497042 :       hash_set<slp_tree> visited;
    8479      1497042 :       vect_gather_slp_loads (SLP_INSTANCE_LOADS (instance),
    8480              :                              SLP_INSTANCE_TREE (instance), visited);
    8481      1497042 :     }
    8482      1053074 : }
    8483              : 
    8484              : /* For NODE update VF based on the number of lanes and the vector types
    8485              :    used.  */
    8486              : 
    8487              : static void
    8488      4285081 : vect_update_slp_vf_for_node (slp_tree node, poly_uint64 &vf,
    8489              :                              hash_set<slp_tree> &visited)
    8490              : {
    8491      4285081 :   if (!node || SLP_TREE_DEF_TYPE (node) != vect_internal_def)
    8492      1538943 :     return;
    8493      3110796 :   if (visited.add (node))
    8494              :     return;
    8495              : 
    8496     10395618 :   for (slp_tree child : SLP_TREE_CHILDREN (node))
    8497      3509070 :     vect_update_slp_vf_for_node (child, vf, visited);
    8498              : 
    8499              :   /* We do not visit SLP nodes for constants or externals - those neither
    8500              :      have a vector type set yet (vectorizable_* does this) nor do they
    8501              :      have max_nunits set.  Instead we rely on internal nodes max_nunit
    8502              :      to cover constant/external operands.
    8503              :      Note that when we stop using fixed size vectors externs and constants
    8504              :      shouldn't influence the (minimum) vectorization factor, instead
    8505              :      vectorizable_* should honor the vectorization factor when trying to
    8506              :      assign vector types to constants and externals and cause iteration
    8507              :      to a higher vectorization factor when required.  */
    8508      2746138 :   poly_uint64 node_vf
    8509      2746138 :     = calculate_unrolling_factor (node->max_nunits, SLP_TREE_LANES (node));
    8510      2746138 :   vf = force_common_multiple (vf, node_vf);
    8511              : 
    8512              :   /* For permute nodes that are fed from externs or constants we have to
    8513              :      consider their number of lanes as well.  Likewise for store-lanes.  */
    8514      2746138 :   if (SLP_TREE_PERMUTE_P (node) || node->ldst_lanes)
    8515       711200 :     for (slp_tree child : SLP_TREE_CHILDREN (node))
    8516       191402 :       if (SLP_TREE_DEF_TYPE (child) != vect_internal_def)
    8517              :         {
    8518         3585 :           poly_uint64 child_vf
    8519         3585 :             = calculate_unrolling_factor (node->max_nunits,
    8520              :                                           SLP_TREE_LANES (child));
    8521         3585 :           vf = force_common_multiple (vf, child_vf);
    8522              :         }
    8523              : }
    8524              : 
    8525              : /* For each possible SLP instance decide whether to SLP it and calculate overall
    8526              :    unrolling factor needed to SLP the loop.  Return TRUE if decided to SLP at
    8527              :    least one instance.  */
    8528              : 
    8529              : bool
    8530       485653 : vect_make_slp_decision (loop_vec_info loop_vinfo)
    8531              : {
    8532       485653 :   unsigned int i;
    8533       485653 :   poly_uint64 unrolling_factor = 1;
    8534       485653 :   const vec<slp_instance> &slp_instances
    8535              :     = LOOP_VINFO_SLP_INSTANCES (loop_vinfo);
    8536       485653 :   slp_instance instance;
    8537       485653 :   int decided_to_slp = 0;
    8538              : 
    8539       485653 :   DUMP_VECT_SCOPE ("vect_make_slp_decision");
    8540              : 
    8541       485653 :   hash_set<slp_tree> visited;
    8542      1261664 :   FOR_EACH_VEC_ELT (slp_instances, i, instance)
    8543              :     {
    8544       776011 :       slp_tree root = SLP_INSTANCE_TREE (instance);
    8545              : 
    8546              :       /* All unroll factors have the form:
    8547              : 
    8548              :            GET_MODE_SIZE (vinfo->vector_mode) * X
    8549              : 
    8550              :          for some rational X, so they must have a common multiple.  */
    8551       776011 :       vect_update_slp_vf_for_node (root, unrolling_factor, visited);
    8552              : 
    8553              :       /* If all instances ended up with vector(1) T roots make sure to
    8554              :          not vectorize.  RVV for example relies on loop vectorization
    8555              :          when some instances are essentially kept scalar.  See PR121048.  */
    8556       776011 :       if (SLP_TREE_VECTYPE (root)
    8557       776011 :           && known_gt (TYPE_VECTOR_SUBPARTS (SLP_TREE_VECTYPE (root)), 1U))
    8558       635153 :         decided_to_slp++;
    8559              :     }
    8560              : 
    8561       485653 :   LOOP_VINFO_VECT_FACTOR (loop_vinfo) = unrolling_factor;
    8562              : 
    8563       485653 :   if (decided_to_slp && dump_enabled_p ())
    8564              :     {
    8565        19135 :       dump_printf_loc (MSG_NOTE, vect_location,
    8566              :                        "Decided to SLP %d instances. Unrolling factor ",
    8567              :                        decided_to_slp);
    8568        19135 :       dump_dec (MSG_NOTE, unrolling_factor);
    8569        19135 :       dump_printf (MSG_NOTE, "\n");
    8570              :     }
    8571              : 
    8572       485653 :   return (decided_to_slp > 0);
    8573       485653 : }
    8574              : 
    8575              : /* Initialize a bb_vec_info struct for the statements in BBS basic blocks.  */
    8576              : 
    8577      2254092 : _bb_vec_info::_bb_vec_info (vec<basic_block> _bbs, vec_info_shared *shared)
    8578              :   : vec_info (vec_info::bb, shared),
    8579      2254092 :     roots (vNULL)
    8580              : {
    8581              :   /* The region we are operating on.  bbs[0] is the entry, excluding
    8582              :      its PHI nodes.  In the future we might want to track an explicit
    8583              :      entry edge to cover bbs[0] PHI nodes and have a region entry
    8584              :      insert location.  */
    8585      2254092 :   bbs = _bbs.address ();
    8586      2254092 :   nbbs = _bbs.length ();
    8587              : 
    8588     18136958 :   for (unsigned i = 0; i < nbbs; ++i)
    8589              :     {
    8590     15882866 :       if (i != 0)
    8591     20638364 :         for (gphi_iterator si = gsi_start_phis (bbs[i]); !gsi_end_p (si);
    8592      7009590 :              gsi_next (&si))
    8593              :           {
    8594      7009590 :             gphi *phi = si.phi ();
    8595      7009590 :             gimple_set_uid (phi, 0);
    8596      7009590 :             add_stmt (phi);
    8597              :           }
    8598     31765732 :       for (gimple_stmt_iterator gsi = gsi_start_bb (bbs[i]);
    8599    144474276 :            !gsi_end_p (gsi); gsi_next (&gsi))
    8600              :         {
    8601    128591410 :           gimple *stmt = gsi_stmt (gsi);
    8602    128591410 :           gimple_set_uid (stmt, 0);
    8603    128591410 :           if (is_gimple_debug (stmt))
    8604     81761302 :             continue;
    8605     46830108 :           add_stmt (stmt);
    8606              :         }
    8607              :     }
    8608      2254092 : }
    8609              : 
    8610              : 
    8611              : /* Free BB_VINFO struct, as well as all the stmt_vec_info structs of all the
    8612              :    stmts in the basic block.  */
    8613              : 
    8614      2254092 : _bb_vec_info::~_bb_vec_info ()
    8615              : {
    8616              :   /* Reset region marker.  */
    8617     18136958 :   for (unsigned i = 0; i < nbbs; ++i)
    8618              :     {
    8619     15882866 :       if (i != 0)
    8620     20654316 :         for (gphi_iterator si = gsi_start_phis (bbs[i]); !gsi_end_p (si);
    8621      7025542 :              gsi_next (&si))
    8622              :           {
    8623      7025542 :             gphi *phi = si.phi ();
    8624      7025542 :             gimple_set_uid (phi, -1);
    8625              :           }
    8626     31765732 :       for (gimple_stmt_iterator gsi = gsi_start_bb (bbs[i]);
    8627    144417903 :            !gsi_end_p (gsi); gsi_next (&gsi))
    8628              :         {
    8629    128535037 :           gimple *stmt = gsi_stmt (gsi);
    8630    128535037 :           gimple_set_uid (stmt, -1);
    8631              :         }
    8632              :     }
    8633              : 
    8634      3548420 :   for (unsigned i = 0; i < roots.length (); ++i)
    8635              :     {
    8636      1294328 :       roots[i].stmts.release ();
    8637      1294328 :       roots[i].roots.release ();
    8638      1294328 :       roots[i].remain.release ();
    8639              :     }
    8640      2254092 :   roots.release ();
    8641      2254092 : }
    8642              : 
    8643              : /* Subroutine of vect_slp_analyze_node_operations.  Handle the root of NODE,
    8644              :    given then that child nodes have already been processed, and that
    8645              :    their def types currently match their SLP node's def type.  */
    8646              : 
    8647              : static bool
    8648      2835684 : vect_slp_analyze_node_operations_1 (vec_info *vinfo, slp_tree node,
    8649              :                                     slp_instance node_instance,
    8650              :                                     stmt_vector_for_cost *cost_vec)
    8651              : {
    8652              :   /* Handle purely internal nodes.  */
    8653      2835684 :   if (SLP_TREE_PERMUTE_P (node))
    8654              :     {
    8655       121122 :       if (!vectorizable_slp_permutation (vinfo, NULL, node, cost_vec))
    8656              :         return false;
    8657              : 
    8658              :       stmt_vec_info slp_stmt_info;
    8659              :       unsigned int i;
    8660       319091 :       FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, slp_stmt_info)
    8661              :         {
    8662       199268 :           if (slp_stmt_info
    8663       193597 :               && STMT_VINFO_LIVE_P (slp_stmt_info)
    8664       199268 :               && !vectorizable_live_operation (vinfo, slp_stmt_info, node,
    8665              :                                                node_instance, i,
    8666              :                                                false, cost_vec))
    8667              :             return false;
    8668              :         }
    8669       119823 :       SLP_TREE_TYPE (node) = permute_info_type;
    8670       119823 :       return true;
    8671              :     }
    8672              : 
    8673      2714562 :   return vect_analyze_stmt (vinfo, node, node_instance, cost_vec);
    8674              : }
    8675              : 
    8676              : static int
    8677      1746214 : sort_ints (const void *a_, const void *b_)
    8678              : {
    8679      1746214 :   int a = *(const int *)a_;
    8680      1746214 :   int b = *(const int *)b_;
    8681      1746214 :   return a - b;
    8682              : }
    8683              : 
    8684              : /* Verify if we can externalize a set of internal defs.  */
    8685              : 
    8686              : static bool
    8687       384733 : vect_slp_can_convert_to_external (const vec<stmt_vec_info> &stmts)
    8688              : {
    8689              :   /* Constant generation uses get_later_stmt which can only handle
    8690              :      defs from the same BB or a set of defs that can be ordered
    8691              :      with a dominance query.  */
    8692       384733 :   basic_block bb = NULL;
    8693       384733 :   bool all_same = true;
    8694       384733 :   auto_vec<int> bbs;
    8695       769466 :   bbs.reserve_exact (stmts.length ());
    8696      2066869 :   for (stmt_vec_info stmt : stmts)
    8697              :     {
    8698       912670 :       if (!stmt)
    8699              :         return false;
    8700       912670 :       else if (!bb)
    8701       384733 :         bb = gimple_bb (stmt->stmt);
    8702       527937 :       else if (gimple_bb (stmt->stmt) != bb)
    8703       174145 :         all_same = false;
    8704       912670 :       bbs.quick_push (gimple_bb (stmt->stmt)->index);
    8705              :     }
    8706       384733 :   if (all_same)
    8707              :     return true;
    8708              : 
    8709              :   /* Produce a vector of unique BB indexes for the defs.  */
    8710       133244 :   bbs.qsort (sort_ints);
    8711              :   unsigned i, j;
    8712       318704 :   for (i = 1, j = 1; i < bbs.length (); ++i)
    8713       185460 :     if (bbs[i] != bbs[j-1])
    8714       141406 :       bbs[j++] = bbs[i];
    8715       133244 :   gcc_assert (j >= 2);
    8716       133244 :   bbs.truncate (j);
    8717              : 
    8718       266488 :   if (bbs.length () == 2)
    8719       130167 :     return (dominated_by_p (CDI_DOMINATORS,
    8720       130167 :                             BASIC_BLOCK_FOR_FN (cfun, bbs[0]),
    8721       130167 :                             BASIC_BLOCK_FOR_FN (cfun, bbs[1]))
    8722       254348 :             || dominated_by_p (CDI_DOMINATORS,
    8723       124181 :                                BASIC_BLOCK_FOR_FN (cfun, bbs[1]),
    8724       124181 :                                BASIC_BLOCK_FOR_FN (cfun, bbs[0])));
    8725              : 
    8726              :   /* ???  For more than two BBs we can sort the vector and verify the
    8727              :      result is a total order.  But we can't use vec::qsort with a
    8728              :      compare function using a dominance query since there's no way to
    8729              :      signal failure and any fallback for an unordered pair would
    8730              :      fail qsort_chk later.
    8731              :      For now simply hope that ordering after BB index provides the
    8732              :      best candidate total order.  If required we can implement our
    8733              :      own mergesort or export an entry without checking.  */
    8734       398994 :   for (unsigned i = 1; i < bbs.length (); ++i)
    8735        11215 :     if (!dominated_by_p (CDI_DOMINATORS,
    8736        11215 :                          BASIC_BLOCK_FOR_FN (cfun, bbs[i]),
    8737        11215 :                          BASIC_BLOCK_FOR_FN (cfun, bbs[i-1])))
    8738              :       return false;
    8739              : 
    8740              :   return true;
    8741       384733 : }
    8742              : 
    8743              : /* Try to build NODE from scalars, returning true on success.
    8744              :    NODE_INSTANCE is the SLP instance that contains NODE.  */
    8745              : 
    8746              : static bool
    8747       577937 : vect_slp_convert_to_external (vec_info *vinfo, slp_tree node,
    8748              :                               slp_instance node_instance)
    8749              : {
    8750       577937 :   stmt_vec_info stmt_info;
    8751       577937 :   unsigned int i;
    8752              : 
    8753       577937 :   if (!is_a <bb_vec_info> (vinfo)
    8754        74657 :       || node == SLP_INSTANCE_TREE (node_instance)
    8755        22447 :       || !SLP_TREE_SCALAR_STMTS (node).exists ()
    8756        22406 :       || vect_contains_pattern_stmt_p (SLP_TREE_SCALAR_STMTS (node))
    8757              :       /* Force the mask use to be built from scalars instead.  */
    8758        20355 :       || VECTOR_BOOLEAN_TYPE_P (SLP_TREE_VECTYPE (node))
    8759       598152 :       || !vect_slp_can_convert_to_external (SLP_TREE_SCALAR_STMTS (node)))
    8760       557722 :     return false;
    8761              : 
    8762        20215 :   if (dump_enabled_p ())
    8763           74 :     dump_printf_loc (MSG_NOTE, vect_location,
    8764              :                      "Building vector operands of %p from scalars instead\n",
    8765              :                      (void *) node);
    8766              : 
    8767              :   /* Don't remove and free the child nodes here, since they could be
    8768              :      referenced by other structures.  The analysis and scheduling phases
    8769              :      (need to) ignore child nodes of anything that isn't vect_internal_def.  */
    8770        20215 :   unsigned int group_size = SLP_TREE_LANES (node);
    8771        20215 :   SLP_TREE_DEF_TYPE (node) = vect_external_def;
    8772              :   /* Invariants get their vector type from the uses.  */
    8773        20215 :   SLP_TREE_VECTYPE (node) = NULL_TREE;
    8774        20215 :   SLP_TREE_SCALAR_OPS (node).safe_grow (group_size, true);
    8775        20215 :   SLP_TREE_LOAD_PERMUTATION (node).release ();
    8776        70683 :   FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, stmt_info)
    8777              :     {
    8778        50468 :       tree lhs = gimple_get_lhs (vect_orig_stmt (stmt_info)->stmt);
    8779        50468 :       SLP_TREE_SCALAR_OPS (node)[i] = lhs;
    8780              :     }
    8781              :   return true;
    8782              : }
    8783              : 
    8784              : /* Return true if all elements of the slice are the same.  */
    8785              : bool
    8786       485016 : vect_scalar_ops_slice::all_same_p () const
    8787              : {
    8788       534108 :   for (unsigned int i = 1; i < length; ++i)
    8789       450126 :     if (!operand_equal_p (op (0), op (i)))
    8790              :       return false;
    8791              :   return true;
    8792              : }
    8793              : 
    8794              : hashval_t
    8795       408341 : vect_scalar_ops_slice_hash::hash (const value_type &s)
    8796              : {
    8797       408341 :   hashval_t hash = 0;
    8798      1567935 :   for (unsigned i = 0; i < s.length; ++i)
    8799      1159594 :     hash = iterative_hash_expr (s.op (i), hash);
    8800       408341 :   return hash;
    8801              : }
    8802              : 
    8803              : bool
    8804       220245 : vect_scalar_ops_slice_hash::equal (const value_type &s1,
    8805              :                                    const compare_type &s2)
    8806              : {
    8807       220245 :   if (s1.length != s2.length)
    8808              :     return false;
    8809       385891 :   for (unsigned i = 0; i < s1.length; ++i)
    8810       335571 :     if (!operand_equal_p (s1.op (i), s2.op (i)))
    8811              :       return false;
    8812              :   return true;
    8813              : }
    8814              : 
    8815              : /* Compute the prologue cost for invariant or constant operands represented
    8816              :    by NODE.  */
    8817              : 
    8818              : static void
    8819      1123347 : vect_prologue_cost_for_slp (vec_info *vinfo, slp_tree node,
    8820              :                             stmt_vector_for_cost *cost_vec)
    8821              : {
    8822              :   /* There's a special case of an existing vector, that costs nothing.  */
    8823      1123347 :   if (SLP_TREE_SCALAR_OPS (node).length () == 0
    8824      1123347 :       && !SLP_TREE_VEC_DEFS (node).is_empty ())
    8825         1448 :     return;
    8826              :   /* Without looking at the actual initializer a vector of
    8827              :      constants can be implemented as load from the constant pool.
    8828              :      When all elements are the same we can use a splat.  */
    8829      1121899 :   tree vectype = SLP_TREE_VECTYPE (node);
    8830      1121899 :   unsigned group_size = SLP_TREE_SCALAR_OPS (node).length ();
    8831      1121899 :   unsigned HOST_WIDE_INT const_nunits;
    8832      1121899 :   unsigned nelt_limit;
    8833      1121899 :   unsigned nvectors = vect_get_num_copies (vinfo, node);
    8834      1121899 :   auto ops = &SLP_TREE_SCALAR_OPS (node);
    8835      1121899 :   auto_vec<unsigned int> starts (nvectors);
    8836      1121899 :   if (TYPE_VECTOR_SUBPARTS (vectype).is_constant (&const_nunits)
    8837      1121899 :       && ! multiple_p (const_nunits, group_size))
    8838              :     {
    8839        65460 :       nelt_limit = const_nunits;
    8840        65460 :       hash_set<vect_scalar_ops_slice_hash> vector_ops;
    8841       271321 :       for (unsigned int i = 0; i < nvectors; ++i)
    8842       205861 :         if (!vector_ops.add ({ ops, i * nelt_limit, nelt_limit }))
    8843       155541 :           starts.quick_push (i * nelt_limit);
    8844        65460 :     }
    8845              :   else
    8846              :     {
    8847              :       /* If either the vector has variable length or the vectors
    8848              :          are composed of repeated whole groups we only need to
    8849              :          cost construction once.  All vectors will be the same.  */
    8850      1056439 :       nelt_limit = group_size;
    8851      1056439 :       starts.quick_push (0);
    8852              :     }
    8853              :   /* ???  We're just tracking whether vectors in a single node are the same.
    8854              :      Ideally we'd do something more global.  */
    8855      1121899 :   bool passed = false;
    8856      4577677 :   for (unsigned int start : starts)
    8857              :     {
    8858      1211980 :       vect_cost_for_stmt kind;
    8859      1211980 :       if (SLP_TREE_DEF_TYPE (node) == vect_constant_def)
    8860              :         kind = vector_load;
    8861       485016 :       else if (vect_scalar_ops_slice { ops, start, nelt_limit }.all_same_p ())
    8862              :         kind = scalar_to_vec;
    8863              :       else
    8864       401034 :         kind = vec_construct;
    8865              :       /* The target cost hook has no idea which part of the SLP node
    8866              :          we are costing so avoid passing it down more than once.  Pass
    8867              :          it to the first vec_construct or scalar_to_vec part since for those
    8868              :          the x86 backend tries to account for GPR to XMM register moves.  */
    8869      1211980 :       record_stmt_cost (cost_vec, 1, kind, nullptr,
    8870      1211980 :                         (kind != vector_load && !passed) ? node : nullptr,
    8871              :                         vectype, 0, vect_prologue);
    8872      1211980 :       if (kind != vector_load)
    8873       485016 :         passed = true;
    8874              :     }
    8875      1121899 : }
    8876              : 
    8877              : /* Analyze statements contained in SLP tree NODE after recursively analyzing
    8878              :    the subtree.  NODE_INSTANCE contains NODE and VINFO contains INSTANCE.
    8879              : 
    8880              :    Return true if the operations are supported.  */
    8881              : 
    8882              : static bool
    8883      5246578 : vect_slp_analyze_node_operations (vec_info *vinfo, slp_tree node,
    8884              :                                   slp_instance node_instance,
    8885              :                                   hash_set<slp_tree> &visited_set,
    8886              :                                   vec<slp_tree> &visited_vec,
    8887              :                                   stmt_vector_for_cost *cost_vec)
    8888              : {
    8889      5246578 :   int i, j;
    8890      5246578 :   slp_tree child;
    8891              : 
    8892              :   /* Assume we can code-generate all invariants.  */
    8893      5246578 :   if (!node
    8894      4866177 :       || SLP_TREE_DEF_TYPE (node) == vect_constant_def
    8895      4082964 :       || SLP_TREE_DEF_TYPE (node) == vect_external_def)
    8896              :     return true;
    8897              : 
    8898      3524994 :   if (SLP_TREE_DEF_TYPE (node) == vect_uninitialized_def)
    8899              :     {
    8900            5 :       if (dump_enabled_p ())
    8901            0 :         dump_printf_loc (MSG_NOTE, vect_location,
    8902              :                          "Failed cyclic SLP reference in %p\n", (void *) node);
    8903            5 :       return false;
    8904              :     }
    8905      3524989 :   gcc_assert (SLP_TREE_DEF_TYPE (node) == vect_internal_def);
    8906              : 
    8907              :   /* If we already analyzed the exact same set of scalar stmts we're done.
    8908              :      We share the generated vector stmts for those.  */
    8909      3524989 :   if (visited_set.add (node))
    8910              :     return true;
    8911      3154056 :   visited_vec.safe_push (node);
    8912              : 
    8913      3154056 :   bool res = true;
    8914      3154056 :   unsigned visited_rec_start = visited_vec.length ();
    8915      3154056 :   unsigned cost_vec_rec_start = cost_vec->length ();
    8916      3154056 :   bool seen_non_constant_child = false;
    8917      6748288 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    8918              :     {
    8919      3912390 :       res = vect_slp_analyze_node_operations (vinfo, child, node_instance,
    8920              :                                               visited_set, visited_vec,
    8921              :                                               cost_vec);
    8922      3912390 :       if (!res)
    8923              :         break;
    8924      3594232 :       if (child && SLP_TREE_DEF_TYPE (child) != vect_constant_def)
    8925      3594232 :         seen_non_constant_child = true;
    8926              :     }
    8927              :   /* We're having difficulties scheduling nodes with just constant
    8928              :      operands and no scalar stmts since we then cannot compute a stmt
    8929              :      insertion place.  */
    8930      3154056 :   if (res
    8931      3154056 :       && !seen_non_constant_child
    8932      3154056 :       && SLP_TREE_SCALAR_STMTS (node).is_empty ())
    8933              :     {
    8934          214 :       if (dump_enabled_p ())
    8935            6 :         dump_printf_loc (MSG_NOTE, vect_location,
    8936              :                          "Cannot vectorize all-constant op node %p\n",
    8937              :                          (void *) node);
    8938              :       res = false;
    8939              :     }
    8940              : 
    8941      3153842 :   if (res)
    8942      2835684 :     res = vect_slp_analyze_node_operations_1 (vinfo, node, node_instance,
    8943              :                                               cost_vec);
    8944              :   /* If analysis failed we have to pop all recursive visited nodes
    8945              :      plus ourselves.  */
    8946      3154056 :   if (!res)
    8947              :     {
    8948      2879468 :       while (visited_vec.length () >= visited_rec_start)
    8949       861797 :         visited_set.remove (visited_vec.pop ());
    8950       577937 :       cost_vec->truncate (cost_vec_rec_start);
    8951              :     }
    8952              : 
    8953              :   /* When the node can be vectorized cost invariant nodes it references.
    8954              :      This is not done in DFS order to allow the referring node
    8955              :      vectorizable_* calls to nail down the invariant nodes vector type
    8956              :      and possibly unshare it if it needs a different vector type than
    8957              :      other referrers.  */
    8958      3154056 :   if (res)
    8959      5843519 :     FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), j, child)
    8960      3267400 :       if (child
    8961      2956002 :           && (SLP_TREE_DEF_TYPE (child) == vect_constant_def
    8962      2956002 :               || SLP_TREE_DEF_TYPE (child) == vect_external_def)
    8963              :           /* Perform usual caching, note code-generation still
    8964              :              code-gens these nodes multiple times but we expect
    8965              :              to CSE them later.  */
    8966      4477684 :           && !visited_set.add (child))
    8967              :         {
    8968      1166808 :           visited_vec.safe_push (child);
    8969              :           /* ???  After auditing more code paths make a "default"
    8970              :              and push the vector type from NODE to all children
    8971              :              if it is not already set.  */
    8972              :           /* Compute the number of vectors to be generated.  */
    8973      1166808 :           tree vector_type = SLP_TREE_VECTYPE (child);
    8974      1166808 :           if (!vector_type)
    8975              :             {
    8976              :               /* Masked loads can have an undefined (default SSA definition)
    8977              :                  else operand.  We do not need to cost it.  */
    8978        43461 :               vec<tree> ops = SLP_TREE_SCALAR_OPS (child);
    8979        44892 :               if (SLP_TREE_TYPE (node) == load_vec_info_type
    8980        44892 :                   && ((ops.length ()
    8981         1431 :                        && TREE_CODE (ops[0]) == SSA_NAME
    8982            0 :                        && SSA_NAME_IS_DEFAULT_DEF (ops[0])
    8983            0 :                        && VAR_P (SSA_NAME_VAR (ops[0])))
    8984         1431 :                       || SLP_TREE_DEF_TYPE (child) == vect_constant_def))
    8985         1431 :                 continue;
    8986              : 
    8987              :               /* For shifts with a scalar argument we don't need
    8988              :                  to cost or code-generate anything.
    8989              :                  ???  Represent this more explicitly.  */
    8990        42030 :               gcc_assert (SLP_TREE_TYPE (node) == shift_vec_info_type
    8991              :                           && j == 1);
    8992        42030 :               continue;
    8993        42030 :             }
    8994              : 
    8995              :           /* And cost them.  */
    8996      1123347 :           vect_prologue_cost_for_slp (vinfo, child, cost_vec);
    8997              :         }
    8998              : 
    8999              :   /* If this node or any of its children can't be vectorized, try pruning
    9000              :      the tree here rather than felling the whole thing.  */
    9001       577937 :   if (!res && vect_slp_convert_to_external (vinfo, node, node_instance))
    9002              :     {
    9003              :       /* We'll need to revisit this for invariant costing and number
    9004              :          of vectorized stmt setting.   */
    9005              :       res = true;
    9006              :     }
    9007              : 
    9008              :   return res;
    9009              : }
    9010              : 
    9011              : /* Mark lanes of NODE that are live outside of the basic-block vectorized
    9012              :    region and that can be vectorized using vectorizable_live_operation
    9013              :    with STMT_VINFO_LIVE_P.  Not handled live operations will cause the
    9014              :    scalar code computing it to be retained.  */
    9015              : 
    9016              : static void
    9017       924982 : vect_bb_slp_mark_live_stmts (bb_vec_info bb_vinfo, slp_tree node,
    9018              :                              slp_instance instance,
    9019              :                              stmt_vector_for_cost *cost_vec,
    9020              :                              hash_set<stmt_vec_info> &svisited,
    9021              :                              hash_set<slp_tree> &visited)
    9022              : {
    9023       924982 :   if (visited.add (node))
    9024        43073 :     return;
    9025              : 
    9026       881909 :   unsigned i;
    9027       881909 :   stmt_vec_info stmt_info;
    9028       881909 :   stmt_vec_info last_stmt = vect_find_last_scalar_stmt_in_slp (node);
    9029      3197221 :   FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, stmt_info)
    9030              :     {
    9031      2315312 :       if (!stmt_info || svisited.contains (stmt_info))
    9032        50988 :         continue;
    9033      2289741 :       stmt_vec_info orig_stmt_info = vect_orig_stmt (stmt_info);
    9034      2289741 :       if (STMT_VINFO_IN_PATTERN_P (orig_stmt_info)
    9035        12983 :           && STMT_VINFO_RELATED_STMT (orig_stmt_info) != stmt_info)
    9036              :         /* Only the pattern root stmt computes the original scalar value.  */
    9037         9541 :         continue;
    9038      2280200 :       if (!PURE_SLP_STMT (orig_stmt_info))
    9039              :         /* Iff the stmt is not part of the vector coverage because it or
    9040              :            uses of it are used by SLP graph leafs as extern input there is
    9041              :            no point in trying to live code-generate from a vector stmt as
    9042              :            the scalar stmt will survive anyway.  */
    9043        15876 :         continue;
    9044      2264324 :       bool mark_visited = true;
    9045      2264324 :       gimple *orig_stmt = orig_stmt_info->stmt;
    9046      2264324 :       ssa_op_iter op_iter;
    9047      2264324 :       def_operand_p def_p;
    9048      5028604 :       FOR_EACH_PHI_OR_STMT_DEF (def_p, orig_stmt, op_iter, SSA_OP_DEF)
    9049              :         {
    9050              :           /* We have to verify whether we can insert the lane extract
    9051              :              before all uses.  The following is a conservative approximation.
    9052              :              We cannot put this into vectorizable_live_operation because
    9053              :              iterating over all use stmts from inside a FOR_EACH_IMM_USE_STMT
    9054              :              doesn't work.
    9055              :              Note that while the fact that we emit code for loads at the
    9056              :              first load should make this a non-problem leafs we construct
    9057              :              from scalars are vectorized after the last scalar def.
    9058              :              ???  If we'd actually compute the insert location during
    9059              :              analysis we could use sth less conservative than the last
    9060              :              scalar stmt in the node for the dominance check.  */
    9061              :           /* ???  What remains is "live" uses in vector CTORs in the same
    9062              :              SLP graph which is where those uses can end up code-generated
    9063              :              right after their definition instead of close to their original
    9064              :              use.  But that would restrict us to code-generate lane-extracts
    9065              :              from the latest stmt in a node.  So we compensate for this
    9066              :              during code-generation, simply not replacing uses for those
    9067              :              hopefully rare cases.  */
    9068       499956 :           imm_use_iterator use_iter;
    9069       499956 :           gimple *use_stmt;
    9070       499956 :           stmt_vec_info use_stmt_info;
    9071              : 
    9072       499956 :           bool live_p = false;
    9073       499956 :           bool can_insert = true;
    9074      1936292 :           FOR_EACH_IMM_USE_STMT (use_stmt, use_iter, DEF_FROM_PTR (def_p))
    9075       952588 :             if (!is_gimple_debug (use_stmt)
    9076       952588 :                 && (!(use_stmt_info = bb_vinfo->lookup_stmt (use_stmt))
    9077       708344 :                     || !PURE_SLP_STMT (use_stmt_info)))
    9078              :               {
    9079       150442 :                 live_p = true;
    9080       150442 :                 if (!vect_stmt_dominates_stmt_p (last_stmt->stmt, use_stmt))
    9081              :                   {
    9082        16208 :                     if (dump_enabled_p ())
    9083           34 :                       dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    9084              :                                        "Cannot determine insertion place for "
    9085              :                                        "lane extract\n");
    9086              :                     can_insert = false;
    9087              :                     break;
    9088              :                   }
    9089       499956 :               }
    9090       499956 :           if (live_p && can_insert)
    9091              :             {
    9092              :               /* Only record a live stmt when we can replace all uses.  We
    9093              :                  record from which SLP tree we vectorize the uses, so we'll
    9094              :                  cost once and can deal with the case that not all SLP nodes
    9095              :                  may be suitable for code-generation of all live uses.
    9096              :                  ???  But we never split up the work between multiple SLP
    9097              :                  nodes.  */
    9098        67146 :               STMT_VINFO_LIVE_P (stmt_info) = true;
    9099        67146 :               if (!vectorizable_live_operation (bb_vinfo, stmt_info, node,
    9100              :                                                 instance, i, false, cost_vec))
    9101              :                 {
    9102            0 :                   STMT_VINFO_LIVE_P (stmt_info) = false;
    9103            0 :                   mark_visited = false;
    9104              :                 }
    9105              :             }
    9106              :         }
    9107      2264324 :       if (mark_visited)
    9108      2264324 :         svisited.add (stmt_info);
    9109              :     }
    9110              : 
    9111              :   slp_tree child;
    9112      2544607 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
    9113       888541 :     if (child && SLP_TREE_DEF_TYPE (child) == vect_internal_def)
    9114       232065 :       vect_bb_slp_mark_live_stmts (bb_vinfo, child, instance, cost_vec,
    9115              :                                    svisited, visited);
    9116              : }
    9117              : 
    9118              : /* Traverse all slp instances of BB_VINFO, and mark lanes of every node that
    9119              :    are live outside of the basic-block vectorized region and that can be
    9120              :    vectorized using vectorizable_live_operation with STMT_VINFO_LIVE_P.  */
    9121              : 
    9122              : static void
    9123       239088 : vect_bb_slp_mark_live_stmts (bb_vec_info bb_vinfo)
    9124              : {
    9125       239088 :   if (bb_vinfo->slp_instances.is_empty ())
    9126            0 :     return;
    9127              : 
    9128       239088 :   hash_set<slp_tree> visited;
    9129       239088 :   hash_set<stmt_vec_info> svisited;
    9130      1410181 :   for (slp_instance instance : bb_vinfo->slp_instances)
    9131              :     {
    9132       692917 :       if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ())
    9133        30593 :         STMT_VINFO_LIVE_P (SLP_INSTANCE_ROOT_STMTS (instance)[0]) = true;
    9134       692917 :       vect_location = instance->location ();
    9135       692917 :       vect_bb_slp_mark_live_stmts (bb_vinfo, SLP_INSTANCE_TREE (instance),
    9136              :                                    instance, &instance->cost_vec,
    9137              :                                    svisited, visited);
    9138              :     }
    9139       239088 : }
    9140              : 
    9141              : /* Determine whether we can vectorize the reduction epilogue for INSTANCE.  */
    9142              : 
    9143              : static bool
    9144        79546 : vectorizable_bb_reduc_epilogue (slp_instance instance,
    9145              :                                 stmt_vector_for_cost *cost_vec)
    9146              : {
    9147        79546 :   gassign *stmt = as_a <gassign *> (instance->root_stmts[0]->stmt);
    9148        79546 :   enum tree_code reduc_code = gimple_assign_rhs_code (stmt);
    9149        79546 :   if (reduc_code == MINUS_EXPR)
    9150            0 :     reduc_code = PLUS_EXPR;
    9151        79546 :   internal_fn reduc_fn;
    9152        79546 :   tree vectype = SLP_TREE_VECTYPE (SLP_INSTANCE_TREE (instance));
    9153        79546 :   if (!vectype
    9154        79534 :       || !reduction_fn_for_scalar_code (reduc_code, &reduc_fn)
    9155        79534 :       || reduc_fn == IFN_LAST
    9156        79534 :       || !direct_internal_fn_supported_p (reduc_fn, vectype, OPTIMIZE_FOR_BOTH)
    9157       117290 :       || !useless_type_conversion_p (TREE_TYPE (gimple_assign_lhs (stmt)),
    9158        37744 :                                      TREE_TYPE (vectype)))
    9159              :     {
    9160        54223 :       if (dump_enabled_p ())
    9161          313 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
    9162              :                          "not vectorized: basic block reduction epilogue "
    9163              :                          "operation unsupported.\n");
    9164        54223 :       return false;
    9165              :     }
    9166              : 
    9167              :   /* There's no way to cost a horizontal vector reduction via REDUC_FN so
    9168              :      cost log2 vector operations plus shuffles and one extraction.  */
    9169        25323 :   unsigned steps = floor_log2 (vect_nunits_for_cost (vectype));
    9170        25323 :   record_stmt_cost (cost_vec, steps, vector_stmt, instance->root_stmts[0],
    9171              :                     vectype, 0, vect_body);
    9172        25323 :   record_stmt_cost (cost_vec, steps, vec_perm, instance->root_stmts[0],
    9173              :                     vectype, 0, vect_body);
    9174        25323 :   record_stmt_cost (cost_vec, 1, vec_to_scalar, instance->root_stmts[0],
    9175              :                     vectype, 0, vect_body);
    9176              : 
    9177              :   /* Since we replace all stmts of a possibly longer scalar reduction
    9178              :      chain account for the extra scalar stmts for that.  */
    9179        25323 :   if (!instance->remain_defs.is_empty ())
    9180        19462 :     record_stmt_cost (cost_vec, instance->remain_defs.length (), scalar_stmt,
    9181         9731 :                       instance->root_stmts[0], 0, vect_body);
    9182              :   return true;
    9183              : }
    9184              : 
    9185              : /* Prune from ROOTS all stmts that are computed as part of lanes of NODE
    9186              :    and recurse to children.  */
    9187              : 
    9188              : static void
    9189       174157 : vect_slp_prune_covered_roots (slp_tree node, hash_set<stmt_vec_info> &roots,
    9190              :                               hash_set<slp_tree> &visited)
    9191              : {
    9192       174157 :   if (SLP_TREE_DEF_TYPE (node) != vect_internal_def
    9193       174157 :       || visited.add (node))
    9194        76654 :     return;
    9195              : 
    9196       530531 :   for (auto stmt : SLP_TREE_SCALAR_STMTS (node))
    9197       240388 :     if (stmt)
    9198       246782 :       roots.remove (vect_orig_stmt (stmt));
    9199              : 
    9200       358009 :   for (auto child : SLP_TREE_CHILDREN (node))
    9201       111424 :     if (child)
    9202       110012 :       vect_slp_prune_covered_roots (child, roots, visited);
    9203              : }
    9204              : 
    9205              : /* Hand over COST_VEC to the target COSTS grouped by SLP node.  */
    9206              : 
    9207              : static void
    9208       959197 : add_slp_costs (vector_costs *costs, stmt_vector_for_cost& cost_vec)
    9209              : {
    9210      3629789 :   for (unsigned start = 0; start < cost_vec.length ();)
    9211              :     {
    9212      2670592 :       unsigned end = start + 1;
    9213      3262571 :       while (end < cost_vec.length ()
    9214      5574541 :              && cost_vec[start].node == cost_vec[end].node)
    9215       591979 :         end++;
    9216      2670592 :       costs->add_slp_cost (cost_vec[start].node,
    9217      2670592 :                            array_slice<stmt_info_for_cost>
    9218      2670592 :                              (cost_vec.begin () + start, end - start));
    9219      2670592 :       start = end;
    9220              :     }
    9221       959197 : }
    9222              : 
    9223              : /* Analyze statements in SLP instances of VINFO.  Return true if the
    9224              :    operations are supported. */
    9225              : 
    9226              : bool
    9227       677800 : vect_slp_analyze_operations (vec_info *vinfo)
    9228              : {
    9229       677800 :   slp_instance instance;
    9230       677800 :   int i;
    9231              : 
    9232       677800 :   DUMP_VECT_SCOPE ("vect_slp_analyze_operations");
    9233              : 
    9234       677800 :   hash_set<slp_tree> visited;
    9235      1761928 :   for (i = 0; vinfo->slp_instances.iterate (i, &instance); )
    9236              :     {
    9237      1334188 :       auto_vec<slp_tree> visited_vec;
    9238      1334188 :       stmt_vector_for_cost cost_vec;
    9239      1334188 :       cost_vec.create (2);
    9240      1334188 :       if (is_a <bb_vec_info> (vinfo))
    9241       800221 :         vect_location = instance->location ();
    9242      1334188 :       if (!vect_slp_analyze_node_operations (vinfo,
    9243              :                                              SLP_INSTANCE_TREE (instance),
    9244              :                                              instance, visited, visited_vec,
    9245              :                                              &cost_vec)
    9246              :           /* CTOR instances require vectorized defs for the SLP tree root.  */
    9247      1094619 :           || (SLP_INSTANCE_KIND (instance) == slp_inst_kind_ctor
    9248         6141 :               && (SLP_TREE_DEF_TYPE (SLP_INSTANCE_TREE (instance))
    9249              :                   != vect_internal_def
    9250              :                   /* Make sure we vectorized with the expected type.  */
    9251         6141 :                   || !useless_type_conversion_p
    9252         6141 :                         (TREE_TYPE (TREE_TYPE (gimple_assign_rhs1
    9253              :                                               (instance->root_stmts[0]->stmt))),
    9254         6141 :                          TREE_TYPE (SLP_TREE_VECTYPE
    9255              :                                             (SLP_INSTANCE_TREE (instance))))))
    9256              :           /* Check we can vectorize the reduction.  */
    9257      1094604 :           || (SLP_INSTANCE_KIND (instance) == slp_inst_kind_bb_reduc
    9258        79546 :               && !vectorizable_bb_reduc_epilogue (instance, &cost_vec))
    9259              :           /* Check we can vectorize the gcond.  */
    9260      2374569 :           || (SLP_INSTANCE_KIND (instance) == slp_inst_kind_gcond
    9261        65330 :               && !vectorizable_early_exit (as_a <loop_vec_info> (vinfo),
    9262        65330 :                                            SLP_INSTANCE_ROOT_STMTS (instance)[0],
    9263              :                                            NULL,
    9264              :                                            SLP_INSTANCE_TREE (instance),
    9265              :                                            &cost_vec)))
    9266              :         {
    9267       356508 :           cost_vec.release ();
    9268       356508 :           slp_tree node = SLP_INSTANCE_TREE (instance);
    9269       356508 :           stmt_vec_info stmt_info;
    9270       356508 :           if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ())
    9271       272328 :             stmt_info = SLP_INSTANCE_ROOT_STMTS (instance)[0];
    9272        84180 :           else if (!SLP_TREE_SCALAR_STMTS (node).is_empty ()
    9273        84180 :                    && SLP_TREE_SCALAR_STMTS (node)[0])
    9274              :             stmt_info = SLP_TREE_SCALAR_STMTS (node)[0];
    9275              :           else
    9276            0 :             stmt_info = SLP_TREE_REPRESENTATIVE (node);
    9277       356508 :           if (is_a <loop_vec_info> (vinfo))
    9278              :             {
    9279       250060 :               if (dump_enabled_p ())
    9280         6492 :                 dump_printf_loc (MSG_NOTE, vect_location,
    9281              :                                  "unsupported SLP instance starting from: %G",
    9282              :                                  stmt_info->stmt);
    9283       250060 :               return false;
    9284              :             }
    9285       106448 :           if (dump_enabled_p ())
    9286          369 :             dump_printf_loc (MSG_NOTE, vect_location,
    9287              :                              "removing SLP instance operations starting from: %G",
    9288              :                              stmt_info->stmt);
    9289       545117 :           while (!visited_vec.is_empty ())
    9290              :             {
    9291       438669 :               slp_tree node = visited_vec.pop ();
    9292       438669 :               SLP_TREE_TYPE (node) = undef_vec_info_type;
    9293       438669 :               if (node->data)
    9294              :                 {
    9295        12065 :                   delete node->data;
    9296        12065 :                   node->data = nullptr;
    9297              :                 }
    9298       438669 :               visited.remove (node);
    9299              :             }
    9300       106448 :           vect_free_slp_instance (instance);
    9301       106448 :           vinfo->slp_instances.ordered_remove (i);
    9302              :         }
    9303              :       else
    9304              :         {
    9305       977680 :           i++;
    9306       977680 :           if (loop_vec_info loop_vinfo = dyn_cast<loop_vec_info> (vinfo))
    9307              :             {
    9308       283907 :               add_slp_costs (loop_vinfo->vector_costs, cost_vec);
    9309       283907 :               cost_vec.release ();
    9310              :             }
    9311              :           else
    9312              :             /* For BB vectorization remember the SLP graph entry
    9313              :                cost for later.  */
    9314       693773 :             instance->cost_vec = cost_vec;
    9315              :         }
    9316      1334188 :     }
    9317              : 
    9318              :   /* Now look for SLP instances with a root that are covered by other
    9319              :      instances and remove them.  */
    9320       427740 :   hash_set<stmt_vec_info> roots;
    9321      1763172 :   for (i = 0; vinfo->slp_instances.iterate (i, &instance); ++i)
    9322       941758 :     if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ())
    9323        34066 :       roots.add (SLP_INSTANCE_ROOT_STMTS (instance)[0]);
    9324       427740 :   if (!roots.is_empty ())
    9325              :     {
    9326        13301 :       visited.empty ();
    9327        77446 :       for (i = 0; vinfo->slp_instances.iterate (i, &instance); ++i)
    9328        64145 :         vect_slp_prune_covered_roots (SLP_INSTANCE_TREE (instance), roots,
    9329              :                                       visited);
    9330        77446 :       for (i = 0; vinfo->slp_instances.iterate (i, &instance); )
    9331        64145 :         if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ()
    9332        34066 :             && !roots.contains (SLP_INSTANCE_ROOT_STMTS (instance)[0]))
    9333              :           {
    9334          856 :             stmt_vec_info root = SLP_INSTANCE_ROOT_STMTS (instance)[0];
    9335          856 :             if (dump_enabled_p ())
    9336           17 :               dump_printf_loc (MSG_NOTE, vect_location,
    9337              :                                "removing SLP instance operations starting "
    9338              :                                "from: %G", root->stmt);
    9339          856 :             vect_free_slp_instance (instance);
    9340          856 :             vinfo->slp_instances.ordered_remove (i);
    9341              :           }
    9342              :         else
    9343        63289 :           ++i;
    9344              :     }
    9345              : 
    9346       855480 :   return !vinfo->slp_instances.is_empty ();
    9347      1105540 : }
    9348              : 
    9349              : /* Get the SLP instance leader from INSTANCE_LEADER thereby transitively
    9350              :    closing the eventual chain.  */
    9351              : 
    9352              : static slp_instance
    9353       765428 : get_ultimate_leader (slp_instance instance,
    9354              :                      hash_map<slp_instance, slp_instance> &instance_leader)
    9355              : {
    9356       765428 :   auto_vec<slp_instance *, 8> chain;
    9357       765428 :   slp_instance *tem;
    9358       853113 :   while (*(tem = instance_leader.get (instance)) != instance)
    9359              :     {
    9360        87685 :       chain.safe_push (tem);
    9361        87685 :       instance = *tem;
    9362              :     }
    9363       853113 :   while (!chain.is_empty ())
    9364        87685 :     *chain.pop () = instance;
    9365       765428 :   return instance;
    9366       765428 : }
    9367              : 
    9368              : namespace {
    9369              : /* Subroutine of vect_bb_partition_graph_r.  Map KEY to INSTANCE in
    9370              :    KEY_TO_INSTANCE, making INSTANCE the leader of any previous mapping
    9371              :    for KEY.  Return true if KEY was already in KEY_TO_INSTANCE.
    9372              : 
    9373              :    INSTANCE_LEADER is as for get_ultimate_leader.  */
    9374              : 
    9375              : template<typename T>
    9376              : bool
    9377      3345868 : vect_map_to_instance (slp_instance instance, T key,
    9378              :                       hash_map<T, slp_instance> &key_to_instance,
    9379              :                       hash_map<slp_instance, slp_instance> &instance_leader)
    9380              : {
    9381              :   bool existed_p;
    9382      3345868 :   slp_instance &key_instance = key_to_instance.get_or_insert (key, &existed_p);
    9383      3345868 :   if (!existed_p)
    9384              :     ;
    9385       177547 :   else if (key_instance != instance)
    9386              :     {
    9387              :       /* If we're running into a previously marked key make us the
    9388              :          leader of the current ultimate leader.  This keeps the
    9389              :          leader chain acyclic and works even when the current instance
    9390              :          connects two previously independent graph parts.  */
    9391        72511 :       slp_instance key_leader
    9392        72511 :         = get_ultimate_leader (key_instance, instance_leader);
    9393        72511 :       if (key_leader != instance)
    9394        22112 :         instance_leader.put (key_leader, instance);
    9395              :     }
    9396      3345868 :   key_instance = instance;
    9397      3345868 :   return existed_p;
    9398              : }
    9399              : }
    9400              : 
    9401              : /* Worker of vect_bb_partition_graph, recurse on NODE.  */
    9402              : 
    9403              : static void
    9404       924982 : vect_bb_partition_graph_r (bb_vec_info bb_vinfo,
    9405              :                            slp_instance instance, slp_tree node,
    9406              :                            hash_map<stmt_vec_info, slp_instance> &stmt_to_instance,
    9407              :                            hash_map<slp_tree, slp_instance> &node_to_instance,
    9408              :                            hash_map<slp_instance, slp_instance> &instance_leader)
    9409              : {
    9410      5188054 :   for (auto stmt_info : SLP_TREE_SCALAR_STMTS (node))
    9411      2420886 :     if (stmt_info)
    9412      2420886 :       vect_map_to_instance (instance, stmt_info, stmt_to_instance,
    9413              :                             instance_leader);
    9414              : 
    9415       924982 :   if (vect_map_to_instance (instance, node, node_to_instance,
    9416              :                             instance_leader))
    9417              :     return;
    9418              : 
    9419      3318764 :   for (auto child : SLP_TREE_CHILDREN (node))
    9420       888541 :     if (child && SLP_TREE_DEF_TYPE (child) == vect_internal_def)
    9421       232065 :       vect_bb_partition_graph_r (bb_vinfo, instance, child, stmt_to_instance,
    9422              :                                  node_to_instance, instance_leader);
    9423              : }
    9424              : 
    9425              : /* Partition the SLP graph into pieces that can be costed independently.  */
    9426              : 
    9427              : static void
    9428       239088 : vect_bb_partition_graph (bb_vec_info bb_vinfo)
    9429              : {
    9430       239088 :   DUMP_VECT_SCOPE ("vect_bb_partition_graph");
    9431              : 
    9432              :   /* First walk the SLP graph assigning each involved scalar stmt a
    9433              :      corresponding SLP graph entry and upon visiting a previously
    9434              :      marked stmt, make the stmts leader the current SLP graph entry.  */
    9435       239088 :   hash_map<stmt_vec_info, slp_instance> stmt_to_instance;
    9436       239088 :   hash_map<slp_tree, slp_instance> node_to_instance;
    9437       239088 :   hash_map<slp_instance, slp_instance> instance_leader;
    9438       239088 :   slp_instance instance;
    9439       932005 :   for (unsigned i = 0; bb_vinfo->slp_instances.iterate (i, &instance); ++i)
    9440              :     {
    9441       692917 :       instance_leader.put (instance, instance);
    9442       692917 :       vect_bb_partition_graph_r (bb_vinfo,
    9443              :                                  instance, SLP_INSTANCE_TREE (instance),
    9444              :                                  stmt_to_instance, node_to_instance,
    9445              :                                  instance_leader);
    9446              :     }
    9447              : 
    9448              :   /* Then collect entries to each independent subgraph.  */
    9449      1171093 :   for (unsigned i = 0; bb_vinfo->slp_instances.iterate (i, &instance); ++i)
    9450              :     {
    9451       692917 :       slp_instance leader = get_ultimate_leader (instance, instance_leader);
    9452       692917 :       leader->subgraph_entries.safe_push (instance);
    9453       692917 :       if (dump_enabled_p ()
    9454       692917 :           && leader != instance)
    9455           71 :         dump_printf_loc (MSG_NOTE, vect_location,
    9456              :                          "instance %p is leader of %p\n",
    9457              :                          (void *) leader, (void *) instance);
    9458              :     }
    9459       239088 : }
    9460              : 
    9461              : /* Compute the scalar cost of the SLP node NODE and its children
    9462              :    and return it.  Do not account defs that are marked in LIFE and
    9463              :    update LIFE according to uses of NODE.  */
    9464              : 
    9465              : static void
    9466       689411 : vect_bb_slp_scalar_cost (bb_vec_info vinfo,
    9467              :                          vec<stmt_vec_info> &worklist,
    9468              :                          stmt_vector_for_cost *cost_vec,
    9469              :                          hash_set<stmt_vec_info> &visited)
    9470              : {
    9471      3189014 :   while (!worklist.is_empty ())
    9472              :     {
    9473      2499603 :       stmt_vec_info stmt = worklist.pop ();
    9474      2790339 :       if (!PURE_SLP_STMT (stmt))
    9475       306652 :         continue;
    9476              : 
    9477              :       /* When the stmt is live but not actually vectorized we have
    9478              :          to keep the feeding scalar defs.  */
    9479      2212270 :       if (!STMT_VINFO_LIVE_P (vect_stmt_to_vectorize (stmt)))
    9480              :         {
    9481      2143509 :           bool live_p = false;
    9482      2143509 :           ssa_op_iter op_iter;
    9483      2143509 :           def_operand_p def_p;
    9484      4688977 :           FOR_EACH_PHI_OR_STMT_DEF (def_p, stmt->stmt, op_iter, SSA_OP_DEF)
    9485              :             {
    9486       401959 :               imm_use_iterator use_iter;
    9487       401959 :               gimple *use_stmt;
    9488      1453074 :               FOR_EACH_IMM_USE_STMT (use_stmt, use_iter, DEF_FROM_PTR (def_p))
    9489       649156 :                 if (!is_gimple_debug (use_stmt))
    9490              :                   {
    9491       480242 :                     stmt_vec_info use_stmt_info = vinfo->lookup_stmt (use_stmt);
    9492       480242 :                     if (!use_stmt_info || !PURE_SLP_STMT (use_stmt_info))
    9493              :                       {
    9494        24629 :                         if (dump_enabled_p ())
    9495              :                           {
    9496           67 :                             dump_printf_loc (MSG_NOTE, vect_location,
    9497              :                                              "stmt considered live: %G",
    9498              :                                              stmt->stmt);
    9499           67 :                             dump_printf_loc (MSG_NOTE, vect_location,
    9500              :                                              "because of use in: %G",
    9501              :                                              use_stmt);
    9502              :                           }
    9503              :                         live_p = true;
    9504              :                       }
    9505       401959 :                   }
    9506              :             }
    9507      2143509 :           if (live_p)
    9508        15916 :             continue;
    9509              :         }
    9510              : 
    9511              :       /* The following assert verifies that vect_bb_partition_graph
    9512              :          partitions the SLP graph in a way that each scalar stmt of
    9513              :          the coverage of the SLP graph belongs to exactly one subgraph.
    9514              :          ???  This is currently not guaranteed since the function
    9515              :          works purely on SLP_TREE_SCALAR_STMTS, resulting in the assert
    9516              :          tripping or scalar stmts costed multiple times, making vectorization
    9517              :          more profitable than it really is.  */
    9518              :       /* gcc_checking_assert (!gimple_visited_p (stmt->stmt)); */
    9519              : 
    9520      2192951 :       if (vect_nop_conversion_p (stmt))
    9521              :         ;
    9522              :       /* For single-argument PHIs assume coalescing which means zero
    9523              :          cost for the scalar and the vector PHIs.  This avoids
    9524              :          artificially favoring the vector path (but may pessimize it
    9525              :          in some cases).  */
    9526      2170227 :       else if (is_a <gphi *> (stmt->stmt)
    9527      2170227 :                && gimple_phi_num_args (as_a <gphi *> (stmt->stmt)) == 1)
    9528              :         ;
    9529              :       else
    9530              :         {
    9531      2161408 :           vect_cost_for_stmt kind;
    9532      2161408 :           if (STMT_VINFO_DATA_REF (stmt))
    9533              :             {
    9534      1986913 :               data_reference_p dr = STMT_VINFO_DATA_REF (stmt);
    9535      1986913 :               tree base = get_base_address (DR_REF (dr));
    9536              :               /* When the scalar access is to a non-global not
    9537              :                  address-taken decl that is not BLKmode assume we can
    9538              :                  access it with a single non-load/store instruction.  */
    9539      1986913 :               if (DECL_P (base)
    9540      1532840 :                   && !is_global_var (base)
    9541      1456781 :                   && !TREE_ADDRESSABLE (base)
    9542      2538192 :                   && DECL_MODE (base) != BLKmode)
    9543              :                 kind = scalar_stmt;
    9544      1842968 :               else if (DR_IS_READ (STMT_VINFO_DATA_REF (stmt)))
    9545              :                 kind = scalar_load;
    9546              :               else
    9547      1614014 :                 kind = scalar_store;
    9548              :             }
    9549              :           else
    9550              :             kind = scalar_stmt;
    9551              :           /* Cost each scalar stmt only once.  */
    9552      2161408 :           gimple_set_visited (stmt->stmt, true);
    9553      2161408 :           record_stmt_cost (cost_vec, 1, kind, stmt, NULL_TREE, 0, vect_body);
    9554              :         }
    9555              : 
    9556              :       /* Now walk relevant parts of the SSA use-def graph.  */
    9557      2192951 :       slp_oprnds child_ops (stmt);
    9558      4595838 :       for (unsigned i = 0; i < child_ops.num_slp_children; ++i)
    9559              :         {
    9560      2402887 :           tree op = child_ops.get_op_for_slp_child (stmt, i);
    9561      2402887 :           stmt_vec_info def = vinfo->lookup_def (op);
    9562      2402887 :           if (def && !visited.add (def))
    9563       696709 :             worklist.safe_push (def);
    9564              :         }
    9565              :     }
    9566       689411 : }
    9567              : 
    9568              : 
    9569              : /* Comparator for the loop-index sorted cost vectors.  */
    9570              : 
    9571              : static int
    9572     17165490 : li_cost_vec_cmp (const void *a_, const void *b_, void *)
    9573              : {
    9574     17165490 :   auto *a = (const std::pair<unsigned, stmt_info_for_cost *> *)a_;
    9575     17165490 :   auto *b = (const std::pair<unsigned, stmt_info_for_cost *> *)b_;
    9576     17165490 :   if (a->first < b->first)
    9577              :     return -1;
    9578     16346256 :   else if (a->first == b->first)
    9579     15662879 :     return 0;
    9580              :   return 1;
    9581              : }
    9582              : 
    9583              : /* Check if vectorization of the basic block is profitable for the
    9584              :    subgraph denoted by SLP_INSTANCES.  */
    9585              : 
    9586              : static bool
    9587       667451 : vect_bb_vectorization_profitable_p (bb_vec_info bb_vinfo,
    9588              :                                     vec<slp_instance> slp_instances,
    9589              :                                     loop_p orig_loop)
    9590              : {
    9591       667451 :   slp_instance instance;
    9592       667451 :   int i;
    9593       667451 :   unsigned int vec_inside_cost = 0, vec_outside_cost = 0, scalar_cost = 0;
    9594       667451 :   unsigned int vec_prologue_cost = 0, vec_epilogue_cost = 0;
    9595              : 
    9596       667451 :   if (dump_enabled_p ())
    9597              :     {
    9598          104 :       dump_printf_loc (MSG_NOTE, vect_location, "Costing subgraph: \n");
    9599          104 :       hash_set<slp_tree> visited;
    9600          421 :       FOR_EACH_VEC_ELT (slp_instances, i, instance)
    9601          109 :         vect_print_slp_graph (MSG_NOTE, vect_location,
    9602              :                               SLP_INSTANCE_TREE (instance), visited);
    9603          104 :     }
    9604              : 
    9605              :   /* Then DFS walk scalar stmts, performing costing and handling
    9606              :      still live scalar stmts via the previously computed vector coverage.  */
    9607       667451 :   stmt_vector_for_cost scalar_costs = vNULL;
    9608       667451 :   stmt_vector_for_cost vector_costs = vNULL;
    9609       667451 :   hash_set<slp_tree> visited;
    9610       667451 :   hash_set<stmt_vec_info> svisited;
    9611      1356862 :   FOR_EACH_VEC_ELT (slp_instances, i, instance)
    9612              :     {
    9613       689411 :       auto_vec<stmt_vec_info> worklist;
    9614       689411 :       if (SLP_INSTANCE_ROOT_STMTS (instance).exists ())
    9615        60616 :         record_stmt_cost (&scalar_costs,
    9616        30308 :                           SLP_INSTANCE_ROOT_STMTS (instance).length (),
    9617              :                           scalar_stmt,
    9618        30308 :                           SLP_INSTANCE_ROOT_STMTS (instance)[0], 0, vect_body);
    9619      3880771 :       for (auto stmt : SLP_TREE_SCALAR_STMTS (SLP_INSTANCE_TREE (instance)))
    9620              :         {
    9621      1812538 :           stmt = vect_orig_stmt (stmt);
    9622      1812538 :           if (!svisited.add (stmt))
    9623      1802894 :             worklist.safe_push (stmt);
    9624              :         }
    9625       689411 :       vect_bb_slp_scalar_cost (bb_vinfo, worklist, &scalar_costs, svisited);
    9626       689411 :       vector_costs.safe_splice (instance->cost_vec);
    9627       689411 :       instance->cost_vec.release ();
    9628       689411 :     }
    9629              : 
    9630       667451 :   if (dump_enabled_p ())
    9631          104 :     dump_printf_loc (MSG_NOTE, vect_location, "Cost model analysis: \n");
    9632              : 
    9633              :   /* When costing non-loop vectorization we need to consider each covered
    9634              :      loop independently and make sure vectorization is profitable.  For
    9635              :      now we assume a loop may be not entered or executed an arbitrary
    9636              :      number of iterations (???  static information can provide more
    9637              :      precise info here) which means we can simply cost each containing
    9638              :      loops stmts separately.  */
    9639              : 
    9640              :   /* First produce cost vectors sorted by loop index.  */
    9641       667451 :   auto_vec<std::pair<unsigned, stmt_info_for_cost *> >
    9642       667451 :     li_scalar_costs (scalar_costs.length ());
    9643       667451 :   auto_vec<std::pair<unsigned, stmt_info_for_cost *> >
    9644       667451 :     li_vector_costs (vector_costs.length ());
    9645       667451 :   stmt_info_for_cost *cost;
    9646      2859167 :   FOR_EACH_VEC_ELT (scalar_costs, i, cost)
    9647              :     {
    9648      2191716 :       unsigned l = gimple_bb (cost->stmt_info->stmt)->loop_father->num;
    9649      2191716 :       li_scalar_costs.quick_push (std::make_pair (l, cost));
    9650              :     }
    9651              :   /* Use a random used loop as fallback in case the first vector_costs
    9652              :      entry does not have a stmt_info associated with it.  */
    9653       667451 :   unsigned l = li_scalar_costs[0].first;
    9654      2435866 :   FOR_EACH_VEC_ELT (vector_costs, i, cost)
    9655              :     {
    9656              :       /* We inherit from the previous COST, invariants, externals and
    9657              :          extracts immediately follow the cost for the related stmt.  */
    9658      1768415 :       if (cost->stmt_info)
    9659      1038567 :         l = gimple_bb (cost->stmt_info->stmt)->loop_father->num;
    9660      1768415 :       li_vector_costs.quick_push (std::make_pair (l, cost));
    9661              :     }
    9662       667451 :   li_scalar_costs.stablesort (li_cost_vec_cmp, NULL);
    9663       667451 :   li_vector_costs.stablesort (li_cost_vec_cmp, NULL);
    9664              : 
    9665              :   /* Now cost the portions individually.  */
    9666              :   unsigned vi = 0;
    9667              :   unsigned si = 0;
    9668              :   bool profitable = true;
    9669      1343856 :   while (si < li_scalar_costs.length ()
    9670      2020303 :          && vi < li_vector_costs.length ())
    9671              :     {
    9672       676405 :       unsigned sl = li_scalar_costs[si].first;
    9673       676405 :       unsigned vl = li_vector_costs[vi].first;
    9674       676405 :       if (sl != vl)
    9675              :         {
    9676         1115 :           if (dump_enabled_p ())
    9677            0 :             dump_printf_loc (MSG_NOTE, vect_location,
    9678              :                              "Scalar %d and vector %d loop part do not "
    9679              :                              "match up, skipping scalar part\n", sl, vl);
    9680              :           /* Skip the scalar part, assuming zero cost on the vector side.  */
    9681         1821 :           do
    9682              :             {
    9683         1821 :               si++;
    9684              :             }
    9685         1821 :           while (si < li_scalar_costs.length ()
    9686         3807 :                  && li_scalar_costs[si].first == sl);
    9687         1115 :           continue;
    9688              :         }
    9689              : 
    9690       675290 :       if (dump_enabled_p ())
    9691          111 :         dump_printf_loc (MSG_NOTE, vect_location,
    9692              :                          "Scalar cost for part in loop %d\n", sl);
    9693       675290 :       class vector_costs *scalar_target_cost_data = init_cost (bb_vinfo, true);
    9694      2189762 :       do
    9695              :         {
    9696      2189762 :           add_stmt_cost (scalar_target_cost_data, li_scalar_costs[si].second);
    9697      2189762 :           si++;
    9698              :         }
    9699      2189762 :       while (si < li_scalar_costs.length ()
    9700      4387662 :              && li_scalar_costs[si].first == sl);
    9701       675290 :       scalar_target_cost_data->finish_cost (nullptr);
    9702       675290 :       scalar_cost = scalar_target_cost_data->body_cost ();
    9703              : 
    9704              :       /* Complete the target-specific vector cost calculation.  */
    9705       675290 :       if (dump_enabled_p ())
    9706          111 :         dump_printf_loc (MSG_NOTE, vect_location,
    9707              :                          "Vector cost for part in loop %d\n", vl);
    9708       675290 :       class vector_costs *vect_target_cost_data = init_cost (bb_vinfo, false);
    9709       675290 :       auto_vec<stmt_info_for_cost> tem;
    9710      1762008 :       do
    9711              :         {
    9712      1762008 :           tem.safe_push (*li_vector_costs[vi].second);
    9713      1762008 :           vi++;
    9714              :         }
    9715      1762008 :       while (vi < li_vector_costs.length ()
    9716      3533285 :              && li_vector_costs[vi].first == vl);
    9717       675290 :       add_slp_costs (vect_target_cost_data, tem);
    9718       675290 :       vect_target_cost_data->finish_cost (scalar_target_cost_data);
    9719       675290 :       vec_prologue_cost = vect_target_cost_data->prologue_cost ();
    9720       675290 :       vec_inside_cost = vect_target_cost_data->body_cost ();
    9721       675290 :       vec_epilogue_cost = vect_target_cost_data->epilogue_cost ();
    9722       675290 :       delete scalar_target_cost_data;
    9723       675290 :       delete vect_target_cost_data;
    9724              : 
    9725       675290 :       vec_outside_cost = vec_prologue_cost + vec_epilogue_cost;
    9726              : 
    9727       675290 :       if (dump_enabled_p ())
    9728              :         {
    9729          111 :           dump_printf_loc (MSG_NOTE, vect_location,
    9730              :                            "Cost model analysis for part in loop %d:\n", sl);
    9731          111 :           dump_printf (MSG_NOTE, "  Vector cost: %d\n",
    9732              :                        vec_inside_cost + vec_outside_cost);
    9733          111 :           dump_printf (MSG_NOTE, "  Scalar cost: %d\n", scalar_cost);
    9734              :         }
    9735              : 
    9736              :       /* Vectorization is profitable if its cost is more than the cost of scalar
    9737              :          version.  Note that we err on the vector side for equal cost because
    9738              :          the cost estimate is otherwise quite pessimistic (constant uses are
    9739              :          free on the scalar side but cost a load on the vector side for
    9740              :          example).  */
    9741       675290 :       if (vec_outside_cost + vec_inside_cost > scalar_cost)
    9742       184523 :         profitable = false;
    9743       675290 :     }
    9744      1152923 :   if (profitable && vi < li_vector_costs.length ())
    9745              :     {
    9746         1064 :       if (dump_enabled_p ())
    9747            0 :         dump_printf_loc (MSG_NOTE, vect_location,
    9748              :                          "Excess vector cost for part in loop %d:\n",
    9749            0 :                          li_vector_costs[vi].first);
    9750              :       profitable = false;
    9751              :     }
    9752              : 
    9753              :   /* Unset visited flag.  This is delayed when the subgraph is profitable
    9754              :      and we process the loop for remaining unvectorized if-converted code.  */
    9755       667451 :   if (!orig_loop || !profitable)
    9756      2857748 :     FOR_EACH_VEC_ELT (scalar_costs, i, cost)
    9757      2190400 :       gimple_set_visited  (cost->stmt_info->stmt, false);
    9758              : 
    9759       667451 :   scalar_costs.release ();
    9760       667451 :   vector_costs.release ();
    9761              : 
    9762       667451 :   return profitable;
    9763       667451 : }
    9764              : 
    9765              : /* qsort comparator for lane defs.  */
    9766              : 
    9767              : static int
    9768          120 : vld_cmp (const void *a_, const void *b_)
    9769              : {
    9770          120 :   auto *a = (const std::pair<unsigned, tree> *)a_;
    9771          120 :   auto *b = (const std::pair<unsigned, tree> *)b_;
    9772          120 :   return a->first - b->first;
    9773              : }
    9774              : 
    9775              : /* Return true if USE_STMT is a vector lane insert into VEC and set
    9776              :    *THIS_LANE to the lane number that is set.  */
    9777              : 
    9778              : static bool
    9779          262 : vect_slp_is_lane_insert (gimple *use_stmt, tree vec, unsigned *this_lane)
    9780              : {
    9781          262 :   gassign *use_ass = dyn_cast <gassign *> (use_stmt);
    9782          104 :   if (!use_ass
    9783          104 :       || gimple_assign_rhs_code (use_ass) != BIT_INSERT_EXPR
    9784           35 :       || (vec
    9785           35 :           ? gimple_assign_rhs1 (use_ass) != vec
    9786           24 :           : ((vec = gimple_assign_rhs1 (use_ass)), false))
    9787           59 :       || !useless_type_conversion_p (TREE_TYPE (TREE_TYPE (vec)),
    9788           59 :                                      TREE_TYPE (gimple_assign_rhs2 (use_ass)))
    9789           59 :       || !constant_multiple_p
    9790           59 :             (tree_to_poly_uint64 (gimple_assign_rhs3 (use_ass)),
    9791          118 :              tree_to_poly_uint64 (TYPE_SIZE (TREE_TYPE (TREE_TYPE (vec)))),
    9792              :              this_lane))
    9793          203 :     return false;
    9794              :   return true;
    9795              : }
    9796              : 
    9797              : /* Find any vectorizable constructors and add them to the grouped_store
    9798              :    array.  */
    9799              : 
    9800              : static void
    9801      2254092 : vect_slp_check_for_roots (bb_vec_info bb_vinfo)
    9802              : {
    9803     18136958 :   for (unsigned i = 0; i < bb_vinfo->nbbs; ++i)
    9804     31765732 :     for (gimple_stmt_iterator gsi = gsi_start_bb (bb_vinfo->bbs[i]);
    9805    144474276 :          !gsi_end_p (gsi); gsi_next (&gsi))
    9806              :     {
    9807    128591410 :       gassign *assign = dyn_cast<gassign *> (gsi_stmt (gsi));
    9808              :       /* This can be used to start SLP discovery for early breaks for BB early breaks
    9809              :          when we get that far.  */
    9810    128591410 :       if (!assign)
    9811    195067499 :         continue;
    9812              : 
    9813     32057645 :       tree rhs = gimple_assign_rhs1 (assign);
    9814     32057645 :       enum tree_code code = gimple_assign_rhs_code (assign);
    9815     32057645 :       use_operand_p use_p;
    9816     32057645 :       gimple *use_stmt;
    9817     32057645 :       if (code == CONSTRUCTOR)
    9818              :         {
    9819      1709165 :           if (!VECTOR_TYPE_P (TREE_TYPE (rhs))
    9820        68028 :               || maybe_ne (TYPE_VECTOR_SUBPARTS (TREE_TYPE (rhs)),
    9821        98111 :                            CONSTRUCTOR_NELTS (rhs))
    9822        45061 :               || VECTOR_TYPE_P (TREE_TYPE (CONSTRUCTOR_ELT (rhs, 0)->value))
    9823      1754206 :               || uniform_vector_p (rhs))
    9824      1694772 :             continue;
    9825              : 
    9826              :           unsigned j;
    9827              :           tree val;
    9828        70896 :           FOR_EACH_CONSTRUCTOR_VALUE (CONSTRUCTOR_ELTS (rhs), j, val)
    9829        56503 :             if (TREE_CODE (val) != SSA_NAME
    9830        56503 :                 || !bb_vinfo->lookup_def (val))
    9831              :               break;
    9832        35140 :           if (j != CONSTRUCTOR_NELTS (rhs))
    9833         3177 :             continue;
    9834              : 
    9835        14393 :           vec<stmt_vec_info> roots = vNULL;
    9836        14393 :           roots.safe_push (bb_vinfo->lookup_stmt (assign));
    9837        14393 :           vec<stmt_vec_info> stmts;
    9838        14393 :           stmts.create (CONSTRUCTOR_NELTS (rhs));
    9839        80322 :           FOR_EACH_CONSTRUCTOR_VALUE (CONSTRUCTOR_ELTS (rhs), j, val)
    9840        51536 :             stmts.quick_push
    9841        51536 :               (vect_stmt_to_vectorize (bb_vinfo->lookup_def (val)));
    9842        14393 :           bb_vinfo->roots.safe_push (slp_root (slp_inst_kind_ctor,
    9843        14393 :                                                stmts, roots));
    9844              :         }
    9845     30348480 :       else if (code == BIT_INSERT_EXPR
    9846          958 :                && VECTOR_TYPE_P (TREE_TYPE (rhs))
    9847          632 :                && TYPE_VECTOR_SUBPARTS (TREE_TYPE (rhs)).is_constant ()
    9848          632 :                && TYPE_VECTOR_SUBPARTS (TREE_TYPE (rhs)).to_constant () > 1
    9849          629 :                && integer_zerop (gimple_assign_rhs3 (assign))
    9850          341 :                && useless_type_conversion_p
    9851          341 :                     (TREE_TYPE (TREE_TYPE (rhs)),
    9852          341 :                      TREE_TYPE (gimple_assign_rhs2 (assign)))
    9853     30349102 :                && bb_vinfo->lookup_def (gimple_assign_rhs2 (assign)))
    9854              :         {
    9855              :           /* We start to match on insert to lane zero but since the
    9856              :              inserts need not be ordered we'd have to search both
    9857              :              the def and the use chains.  */
    9858          220 :           tree vectype = TREE_TYPE (rhs);
    9859          220 :           unsigned nlanes = TYPE_VECTOR_SUBPARTS (vectype).to_constant ();
    9860          220 :           auto_vec<std::pair<unsigned, tree> > lane_defs (nlanes);
    9861          220 :           auto_sbitmap lanes (nlanes);
    9862          220 :           bitmap_clear (lanes);
    9863          220 :           bitmap_set_bit (lanes, 0);
    9864          220 :           tree def = gimple_assign_lhs (assign);
    9865          220 :           lane_defs.quick_push
    9866          220 :                       (std::make_pair (0, gimple_assign_rhs2 (assign)));
    9867          220 :           unsigned lanes_found = 1;
    9868              :           /* Start with the use chains, the last stmt will be the root.  */
    9869          220 :           stmt_vec_info last = bb_vinfo->lookup_stmt (assign);
    9870          220 :           vec<stmt_vec_info> roots = vNULL;
    9871          220 :           roots.safe_push (last);
    9872          231 :           do
    9873              :             {
    9874          231 :               use_operand_p use_p;
    9875          231 :               gimple *use_stmt;
    9876          231 :               if (!single_imm_use (def, &use_p, &use_stmt))
    9877              :                 break;
    9878          225 :               unsigned this_lane;
    9879          225 :               if (!bb_vinfo->lookup_stmt (use_stmt)
    9880          225 :                   || !vect_slp_is_lane_insert (use_stmt, def, &this_lane)
    9881          260 :                   || !bb_vinfo->lookup_def (gimple_assign_rhs2 (use_stmt)))
    9882              :                 break;
    9883           35 :               if (bitmap_bit_p (lanes, this_lane))
    9884              :                 break;
    9885           15 :               lanes_found++;
    9886           15 :               bitmap_set_bit (lanes, this_lane);
    9887           15 :               gassign *use_ass = as_a <gassign *> (use_stmt);
    9888           15 :               lane_defs.quick_push (std::make_pair
    9889           15 :                                      (this_lane, gimple_assign_rhs2 (use_ass)));
    9890           15 :               last = bb_vinfo->lookup_stmt (use_ass);
    9891           15 :               roots.safe_push (last);
    9892           15 :               def = gimple_assign_lhs (use_ass);
    9893              :             }
    9894           15 :           while (lanes_found < nlanes);
    9895          220 :           if (roots.length () > 1)
    9896            7 :             std::swap(roots[0], roots[roots.length () - 1]);
    9897          220 :           if (lanes_found < nlanes)
    9898              :             {
    9899              :               /* Now search the def chain.  */
    9900          216 :               def = gimple_assign_rhs1 (assign);
    9901          218 :               do
    9902              :                 {
    9903          218 :                   if (TREE_CODE (def) != SSA_NAME
    9904          218 :                       || !has_single_use (def))
    9905              :                     break;
    9906           57 :                   gimple *def_stmt = SSA_NAME_DEF_STMT (def);
    9907           57 :                   unsigned this_lane;
    9908           57 :                   if (!bb_vinfo->lookup_stmt (def_stmt)
    9909           37 :                       || !vect_slp_is_lane_insert (def_stmt,
    9910              :                                                    NULL_TREE, &this_lane)
    9911           81 :                       || !bb_vinfo->lookup_def (gimple_assign_rhs2 (def_stmt)))
    9912              :                     break;
    9913           24 :                   if (bitmap_bit_p (lanes, this_lane))
    9914              :                     break;
    9915            4 :                   lanes_found++;
    9916            4 :                   bitmap_set_bit (lanes, this_lane);
    9917            8 :                   lane_defs.quick_push (std::make_pair
    9918            4 :                                           (this_lane,
    9919            4 :                                            gimple_assign_rhs2 (def_stmt)));
    9920            4 :                   roots.safe_push (bb_vinfo->lookup_stmt (def_stmt));
    9921            4 :                   def = gimple_assign_rhs1 (def_stmt);
    9922              :                 }
    9923            4 :               while (lanes_found < nlanes);
    9924              :             }
    9925          220 :           if (lanes_found == nlanes)
    9926              :             {
    9927              :               /* Sort lane_defs after the lane index and register the root.  */
    9928            6 :               lane_defs.qsort (vld_cmp);
    9929            6 :               vec<stmt_vec_info> stmts;
    9930            6 :               stmts.create (nlanes);
    9931           30 :               for (unsigned i = 0; i < nlanes; ++i)
    9932           24 :                 stmts.quick_push (bb_vinfo->lookup_def (lane_defs[i].second));
    9933            6 :               bb_vinfo->roots.safe_push (slp_root (slp_inst_kind_ctor,
    9934            6 :                                                    stmts, roots));
    9935              :             }
    9936              :           else
    9937          214 :             roots.release ();
    9938          220 :         }
    9939     30348260 :       else if (!VECTOR_TYPE_P (TREE_TYPE (rhs))
    9940     29333190 :                && (associative_tree_code (code) || code == MINUS_EXPR)
    9941              :                /* ???  This pessimizes a two-element reduction.  PR54400.
    9942              :                   ???  In-order reduction could be handled if we only
    9943              :                   traverse one operand chain in vect_slp_linearize_chain.  */
    9944     34402375 :                && !needs_fold_left_reduction_p (TREE_TYPE (rhs), code)
    9945              :                /* Ops with constants at the tail can be stripped here.  */
    9946      6017071 :                && TREE_CODE (rhs) == SSA_NAME
    9947      5948706 :                && TREE_CODE (gimple_assign_rhs2 (assign)) == SSA_NAME
    9948              :                /* Should be the chain end.  */
    9949     32739293 :                && (!single_imm_use (gimple_assign_lhs (assign),
    9950              :                                     &use_p, &use_stmt)
    9951      1839517 :                    || !is_gimple_assign (use_stmt)
    9952      1249835 :                    || (gimple_assign_rhs_code (use_stmt) != code
    9953       933804 :                        && ((code != PLUS_EXPR && code != MINUS_EXPR)
    9954       518325 :                            || (gimple_assign_rhs_code (use_stmt)
    9955       518325 :                                != (code == PLUS_EXPR ? MINUS_EXPR : PLUS_EXPR))))))
    9956              :         {
    9957              :           /* We start the match at the end of a possible association
    9958              :              chain.  */
    9959      1962956 :           auto_vec<chain_op_t> chain;
    9960      1962956 :           auto_vec<std::pair<tree_code, gimple *> > worklist;
    9961      1962956 :           auto_vec<gimple *> chain_stmts;
    9962      1962956 :           gimple *code_stmt = NULL, *alt_code_stmt = NULL;
    9963      1962956 :           if (code == MINUS_EXPR)
    9964       310445 :             code = PLUS_EXPR;
    9965      1962956 :           internal_fn reduc_fn;
    9966      2268153 :           if (!reduction_fn_for_scalar_code (code, &reduc_fn)
    9967      1962956 :               || reduc_fn == IFN_LAST)
    9968       305197 :             continue;
    9969      1657759 :           vect_slp_linearize_chain (bb_vinfo, worklist, chain, code, assign,
    9970              :                                     /* ??? */
    9971              :                                     code_stmt, alt_code_stmt, &chain_stmts,
    9972              :                                     false);
    9973      3315518 :           if (chain.length () > 1)
    9974              :             {
    9975              :               /* Sort the chain according to def_type and operation.  */
    9976      1657759 :               chain.sort (dt_sort_cmp, bb_vinfo);
    9977              :               /* ???  Now we'd want to strip externals and constants
    9978              :                  but record those to be handled in the epilogue.  */
    9979              :               /* ???  For now do not allow mixing ops or externs/constants.  */
    9980      1657759 :               bool invalid = false;
    9981      1657759 :               unsigned remain_cnt = 0;
    9982      1657759 :               unsigned last_idx = 0;
    9983      5007931 :               for (unsigned i = 0; i < chain.length (); ++i)
    9984              :                 {
    9985      3660617 :                   if (chain[i].code != code)
    9986              :                     {
    9987              :                       invalid = true;
    9988              :                       break;
    9989              :                     }
    9990      3350172 :                   if (chain[i].dt != vect_internal_def
    9991              :                       /* Avoid stmts where the def is not the LHS, like
    9992              :                          ASMs.  */
    9993      6483522 :                       || (gimple_get_lhs (bb_vinfo->lookup_def
    9994      3133350 :                                                       (chain[i].op)->stmt)
    9995      3133350 :                           != chain[i].op))
    9996       219766 :                     remain_cnt++;
    9997              :                   else
    9998              :                     last_idx = i;
    9999              :                 }
   10000              :               /* Make sure to have an even number of lanes as we later do
   10001              :                  all-or-nothing discovery, not trying to split further.  */
   10002      1657759 :               if ((chain.length () - remain_cnt) & 1)
   10003       178489 :                 remain_cnt++;
   10004      1657759 :               if (!invalid && chain.length () - remain_cnt > 1)
   10005              :                 {
   10006      1279929 :                   vec<stmt_vec_info> stmts;
   10007      1279929 :                   vec<tree> remain = vNULL;
   10008      1279929 :                   stmts.create (chain.length ());
   10009      1279929 :                   if (remain_cnt > 0)
   10010       122244 :                     remain.create (remain_cnt);
   10011      4109933 :                   for (unsigned i = 0; i < chain.length (); ++i)
   10012              :                     {
   10013      2830004 :                       stmt_vec_info stmt_info;
   10014      2830004 :                       if (chain[i].dt == vect_internal_def
   10015      2789715 :                           && ((stmt_info = bb_vinfo->lookup_def (chain[i].op)),
   10016      2789715 :                               gimple_get_lhs (stmt_info->stmt) == chain[i].op)
   10017      5619635 :                           && (i != last_idx
   10018      1279929 :                               || (stmts.length () & 1)))
   10019      2696370 :                         stmts.quick_push (stmt_info);
   10020              :                       else
   10021       133634 :                         remain.quick_push (chain[i].op);
   10022              :                     }
   10023      1279929 :                   vec<stmt_vec_info> roots;
   10024      1279929 :                   roots.create (chain_stmts.length ());
   10025      2830004 :                   for (unsigned i = 0; i < chain_stmts.length (); ++i)
   10026      1550075 :                     roots.quick_push (bb_vinfo->lookup_stmt (chain_stmts[i]));
   10027      1279929 :                   bb_vinfo->roots.safe_push (slp_root (slp_inst_kind_bb_reduc,
   10028      1279929 :                                                        stmts, roots, remain));
   10029              :                 }
   10030              :             }
   10031      1962956 :         }
   10032              :     }
   10033      2254092 : }
   10034              : 
   10035              : /* Walk the grouped store chains and replace entries with their
   10036              :    pattern variant if any.  */
   10037              : 
   10038              : static void
   10039       629450 : vect_fixup_store_groups_with_patterns (vec_info *vinfo)
   10040              : {
   10041       629450 :   stmt_vec_info first_element;
   10042       629450 :   unsigned i;
   10043              : 
   10044      1536229 :   FOR_EACH_VEC_ELT (vinfo->grouped_stores, i, first_element)
   10045              :     {
   10046              :       /* We also have CTORs in this array.  */
   10047       906779 :       if (!STMT_VINFO_GROUPED_ACCESS (first_element))
   10048            0 :         continue;
   10049       906779 :       if (STMT_VINFO_IN_PATTERN_P (first_element))
   10050              :         {
   10051          252 :           stmt_vec_info orig = first_element;
   10052          252 :           first_element = STMT_VINFO_RELATED_STMT (first_element);
   10053          252 :           DR_GROUP_FIRST_ELEMENT (first_element) = first_element;
   10054          252 :           DR_GROUP_SIZE (first_element) = DR_GROUP_SIZE (orig);
   10055          252 :           DR_GROUP_GAP (first_element) = DR_GROUP_GAP (orig);
   10056          252 :           DR_GROUP_NEXT_ELEMENT (first_element) = DR_GROUP_NEXT_ELEMENT (orig);
   10057          252 :           vinfo->grouped_stores[i] = first_element;
   10058              :         }
   10059       906779 :       stmt_vec_info prev = first_element;
   10060      2549177 :       while (DR_GROUP_NEXT_ELEMENT (prev))
   10061              :         {
   10062      1642398 :           stmt_vec_info elt = DR_GROUP_NEXT_ELEMENT (prev);
   10063      1642398 :           if (STMT_VINFO_IN_PATTERN_P (elt))
   10064              :             {
   10065          849 :               stmt_vec_info orig = elt;
   10066          849 :               elt = STMT_VINFO_RELATED_STMT (elt);
   10067          849 :               DR_GROUP_NEXT_ELEMENT (prev) = elt;
   10068          849 :               DR_GROUP_GAP (elt) = DR_GROUP_GAP (orig);
   10069          849 :               DR_GROUP_NEXT_ELEMENT (elt) = DR_GROUP_NEXT_ELEMENT (orig);
   10070              :             }
   10071      1642398 :           DR_GROUP_FIRST_ELEMENT (elt) = first_element;
   10072      1642398 :           prev = elt;
   10073              :         }
   10074              :     }
   10075       629450 : }
   10076              : 
   10077              : /* Check if the region described by BB_VINFO can be vectorized, returning
   10078              :    true if so.  When returning false, set FATAL to true if the same failure
   10079              :    would prevent vectorization at other vector sizes, false if it is still
   10080              :    worth trying other sizes.  N_STMTS is the number of statements in the
   10081              :    region.  */
   10082              : 
   10083              : static bool
   10084      2254092 : vect_slp_analyze_bb_1 (bb_vec_info bb_vinfo, int n_stmts, bool &fatal,
   10085              :                        vec<int> *dataref_groups)
   10086              : {
   10087      2254092 :   DUMP_VECT_SCOPE ("vect_slp_analyze_bb");
   10088              : 
   10089      2254092 :   slp_instance instance;
   10090      2254092 :   int i;
   10091              : 
   10092              :   /* The first group of checks is independent of the vector size.  */
   10093      2254092 :   fatal = true;
   10094              : 
   10095              :   /* Analyze the data references.  */
   10096              : 
   10097      2254092 :   if (!vect_analyze_data_refs (bb_vinfo, NULL))
   10098              :     {
   10099            0 :       if (dump_enabled_p ())
   10100            0 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10101              :                          "not vectorized: unhandled data-ref in basic "
   10102              :                          "block.\n");
   10103            0 :       return false;
   10104              :     }
   10105              : 
   10106      2254092 :   if (!vect_analyze_data_ref_accesses (bb_vinfo, dataref_groups))
   10107              :     {
   10108            0 :      if (dump_enabled_p ())
   10109            0 :        dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10110              :                         "not vectorized: unhandled data access in "
   10111              :                         "basic block.\n");
   10112            0 :       return false;
   10113              :     }
   10114              : 
   10115      2254092 :   vect_slp_check_for_roots (bb_vinfo);
   10116              : 
   10117              :   /* If there are no grouped stores and no constructors in the region
   10118              :      there is no need to continue with pattern recog as vect_analyze_slp
   10119              :      will fail anyway.  */
   10120      2254092 :   if (bb_vinfo->grouped_stores.is_empty ()
   10121      1904817 :       && bb_vinfo->roots.is_empty ())
   10122              :     {
   10123      1624642 :       if (dump_enabled_p ())
   10124         1026 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10125              :                          "not vectorized: no grouped stores in "
   10126              :                          "basic block.\n");
   10127      1624642 :       return false;
   10128              :     }
   10129              : 
   10130              :   /* While the rest of the analysis below depends on it in some way.  */
   10131       629450 :   fatal = false;
   10132              : 
   10133       629450 :   vect_pattern_recog (bb_vinfo);
   10134              : 
   10135              :   /* Update store groups from pattern processing.  */
   10136       629450 :   vect_fixup_store_groups_with_patterns (bb_vinfo);
   10137              : 
   10138              :   /* Check the SLP opportunities in the basic block, analyze and build SLP
   10139              :      trees.  */
   10140       629450 :   if (!vect_analyze_slp (bb_vinfo, n_stmts, false))
   10141              :     {
   10142            0 :       if (dump_enabled_p ())
   10143              :         {
   10144            0 :           dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10145              :                            "Failed to SLP the basic block.\n");
   10146            0 :           dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10147              :                            "not vectorized: failed to find SLP opportunities "
   10148              :                            "in basic block.\n");
   10149              :         }
   10150            0 :       return false;
   10151              :     }
   10152              : 
   10153              :   /* Optimize permutations.  */
   10154       629450 :   vect_optimize_slp (bb_vinfo);
   10155              : 
   10156              :   /* Gather the loads reachable from the SLP graph entries.  */
   10157       629450 :   vect_gather_slp_loads (bb_vinfo);
   10158              : 
   10159       629450 :   vect_record_base_alignments (bb_vinfo);
   10160              : 
   10161              :   /* Analyze and verify the alignment of data references and the
   10162              :      dependence in the SLP instances.  */
   10163      1438404 :   for (i = 0; BB_VINFO_SLP_INSTANCES (bb_vinfo).iterate (i, &instance); )
   10164              :     {
   10165       808954 :       vect_location = instance->location ();
   10166       808954 :       if (! vect_slp_analyze_instance_alignment (bb_vinfo, instance)
   10167       808954 :           || ! vect_slp_analyze_instance_dependence (bb_vinfo, instance))
   10168              :         {
   10169         8733 :           slp_tree node = SLP_INSTANCE_TREE (instance);
   10170         8733 :           stmt_vec_info stmt_info = SLP_TREE_SCALAR_STMTS (node)[0];
   10171         8733 :           if (dump_enabled_p ())
   10172            4 :             dump_printf_loc (MSG_NOTE, vect_location,
   10173              :                              "removing SLP instance operations starting from: %G",
   10174              :                              stmt_info->stmt);
   10175         8733 :           vect_free_slp_instance (instance);
   10176         8733 :           BB_VINFO_SLP_INSTANCES (bb_vinfo).ordered_remove (i);
   10177         8733 :           continue;
   10178         8733 :         }
   10179              : 
   10180              :       /* Mark all the statements that we want to vectorize as relevant.  */
   10181       800221 :       vect_mark_slp_stmts_relevant (SLP_INSTANCE_TREE (instance));
   10182              : 
   10183       800221 :       i++;
   10184              :     }
   10185      2286857 :   if (! BB_VINFO_SLP_INSTANCES (bb_vinfo).length ())
   10186              :     return false;
   10187              : 
   10188       271853 :   if (!vect_slp_analyze_operations (bb_vinfo))
   10189              :     {
   10190        32765 :       if (dump_enabled_p ())
   10191           93 :         dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10192              :                          "not vectorized: bad operation in basic block.\n");
   10193        32765 :       return false;
   10194              :     }
   10195              : 
   10196              :   /* Mark all the statements that we vectorize.  */
   10197       239088 :   vect_bb_slp_mark_stmts_vectorized (bb_vinfo);
   10198              : 
   10199              :   /* Compute vectorizable live stmts.  */
   10200       239088 :   vect_bb_slp_mark_live_stmts (bb_vinfo);
   10201              : 
   10202       239088 :   vect_bb_partition_graph (bb_vinfo);
   10203              : 
   10204       239088 :   return true;
   10205              : }
   10206              : 
   10207              : /* Subroutine of vect_slp_bb.  Try to vectorize the statements for all
   10208              :    basic blocks in BBS, returning true on success.
   10209              :    The region has N_STMTS statements and has the datarefs given by DATAREFS.  */
   10210              : 
   10211              : static bool
   10212      1922664 : vect_slp_region (vec<basic_block> bbs, vec<data_reference_p> datarefs,
   10213              :                  vec<int> *dataref_groups, unsigned int n_stmts,
   10214              :                  loop_p orig_loop)
   10215              : {
   10216      1922664 :   bb_vec_info bb_vinfo;
   10217      1922664 :   auto_vector_modes vector_modes;
   10218              : 
   10219              :   /* Autodetect first vector size we try.  */
   10220      1922664 :   machine_mode next_vector_mode = VOIDmode;
   10221      1922664 :   targetm.vectorize.autovectorize_vector_modes (&vector_modes, false);
   10222      1922664 :   unsigned int mode_i = 0;
   10223              : 
   10224      1922664 :   vec_info_shared shared;
   10225              : 
   10226      1922664 :   machine_mode autodetected_vector_mode = VOIDmode;
   10227      2585520 :   while (1)
   10228              :     {
   10229      2254092 :       bool vectorized = false;
   10230      2254092 :       bool fatal = false;
   10231      2254092 :       bb_vinfo = new _bb_vec_info (bbs, &shared);
   10232              : 
   10233      2254092 :       bool first_time_p = shared.datarefs.is_empty ();
   10234      2254092 :       BB_VINFO_DATAREFS (bb_vinfo) = datarefs;
   10235      2254092 :       if (first_time_p)
   10236      1946284 :         bb_vinfo->shared->save_datarefs ();
   10237              :       else
   10238       307808 :         bb_vinfo->shared->check_datarefs ();
   10239      2254092 :       bb_vinfo->vector_mode = next_vector_mode;
   10240              : 
   10241      2254092 :       if (vect_slp_analyze_bb_1 (bb_vinfo, n_stmts, fatal, dataref_groups))
   10242              :         {
   10243       239088 :           if (dump_enabled_p ())
   10244              :             {
   10245         1520 :               dump_printf_loc (MSG_NOTE, vect_location,
   10246              :                                "***** Analysis succeeded with vector mode"
   10247          760 :                                " %s\n", GET_MODE_NAME (bb_vinfo->vector_mode));
   10248          760 :               dump_printf_loc (MSG_NOTE, vect_location, "SLPing BB part\n");
   10249              :             }
   10250              : 
   10251       239088 :           bb_vinfo->shared->check_datarefs ();
   10252              : 
   10253       239088 :           bool force_clear = false;
   10254       239088 :           auto_vec<slp_instance> profitable_subgraphs;
   10255      1410181 :           for (slp_instance instance : BB_VINFO_SLP_INSTANCES (bb_vinfo))
   10256              :             {
   10257       692917 :               if (instance->subgraph_entries.is_empty ())
   10258       227254 :                 continue;
   10259              : 
   10260       670805 :               dump_user_location_t saved_vect_location = vect_location;
   10261       670805 :               vect_location = instance->location ();
   10262       670805 :               if (!unlimited_cost_model (NULL)
   10263       667456 :                   && !param_vect_allow_possibly_not_worthwhile_vectorizations
   10264      1338256 :                   && !vect_bb_vectorization_profitable_p
   10265       667451 :                         (bb_vinfo, instance->subgraph_entries, orig_loop))
   10266              :                 {
   10267       183030 :                   if (dump_enabled_p ())
   10268           32 :                     dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10269              :                                      "not vectorized: vectorization is not "
   10270              :                                      "profitable.\n");
   10271       183030 :                   vect_location = saved_vect_location;
   10272       183030 :                   continue;
   10273              :                 }
   10274              : 
   10275       487775 :               vect_location = saved_vect_location;
   10276       487775 :               if (!dbg_cnt (vect_slp))
   10277              :                 {
   10278            0 :                   force_clear = true;
   10279            0 :                   continue;
   10280              :                 }
   10281              : 
   10282       487775 :               profitable_subgraphs.safe_push (instance);
   10283              :             }
   10284              : 
   10285              :           /* When we're vectorizing an if-converted loop body make sure
   10286              :              we vectorized all if-converted code.  */
   10287       400151 :           if ((!profitable_subgraphs.is_empty () || force_clear) && orig_loop)
   10288              :             {
   10289          106 :               gcc_assert (bb_vinfo->nbbs == 1);
   10290          212 :               for (gimple_stmt_iterator gsi = gsi_start_bb (bb_vinfo->bbs[0]);
   10291         4390 :                    !gsi_end_p (gsi); gsi_next (&gsi))
   10292              :                 {
   10293              :                   /* The costing above left us with DCEable vectorized scalar
   10294              :                      stmts having the visited flag set on profitable
   10295              :                      subgraphs.  Do the delayed clearing of the flag here.  */
   10296         4284 :                   if (gimple_visited_p (gsi_stmt (gsi)))
   10297              :                     {
   10298         1260 :                       gimple_set_visited (gsi_stmt (gsi), false);
   10299         1260 :                       continue;
   10300              :                     }
   10301         3024 :                   if (flag_vect_cost_model == VECT_COST_MODEL_UNLIMITED)
   10302          813 :                     continue;
   10303              : 
   10304         6338 :                   if (gassign *ass = dyn_cast <gassign *> (gsi_stmt (gsi)))
   10305         2670 :                     if (gimple_assign_rhs_code (ass) == COND_EXPR)
   10306              :                       {
   10307           69 :                         if (!profitable_subgraphs.is_empty ()
   10308           31 :                             && dump_enabled_p ())
   10309            0 :                           dump_printf_loc (MSG_NOTE, vect_location,
   10310              :                                            "not profitable because of "
   10311              :                                            "unprofitable if-converted scalar "
   10312              :                                            "code\n");
   10313           38 :                         profitable_subgraphs.truncate (0);
   10314              :                       }
   10315              :                 }
   10316              :             }
   10317              : 
   10318              :           /* Finally schedule the profitable subgraphs.  */
   10319      1048943 :           for (slp_instance instance : profitable_subgraphs)
   10320              :             {
   10321       487729 :               if (!vectorized && dump_enabled_p ())
   10322          734 :                 dump_printf_loc (MSG_NOTE, vect_location,
   10323              :                                  "Basic block will be vectorized "
   10324              :                                  "using SLP\n");
   10325       487729 :               vectorized = true;
   10326              : 
   10327              :               /* Dump before scheduling as store vectorization will remove
   10328              :                  the original stores and mess with the instance tree
   10329              :                  so querying its location will eventually ICE.  */
   10330       487729 :               if (flag_checking)
   10331      1962413 :                 for (slp_instance sub : instance->subgraph_entries)
   10332       499226 :                   gcc_assert (SLP_TREE_VECTYPE (SLP_INSTANCE_TREE (sub)));
   10333       487729 :               unsigned HOST_WIDE_INT bytes;
   10334       487729 :               if (dump_enabled_p ())
   10335         3489 :                 for (slp_instance sub : instance->subgraph_entries)
   10336              :                   {
   10337          924 :                     tree vtype = SLP_TREE_VECTYPE (SLP_INSTANCE_TREE (sub));
   10338         1848 :                     if (GET_MODE_SIZE (TYPE_MODE (vtype)).is_constant (&bytes))
   10339          924 :                       dump_printf_loc (MSG_OPTIMIZED_LOCATIONS,
   10340          924 :                                        sub->location (),
   10341              :                                        "basic block part vectorized using %wu "
   10342              :                                        "byte vectors\n", bytes);
   10343              :                     else
   10344              :                       dump_printf_loc (MSG_OPTIMIZED_LOCATIONS,
   10345              :                                        sub->location (),
   10346              :                                        "basic block part vectorized using "
   10347              :                                        "variable length vectors\n");
   10348              :                   }
   10349              : 
   10350       487729 :               dump_user_location_t saved_vect_location = vect_location;
   10351       487729 :               vect_location = instance->location ();
   10352              : 
   10353       487729 :               vect_schedule_slp (bb_vinfo, instance->subgraph_entries);
   10354              : 
   10355       487729 :               vect_location = saved_vect_location;
   10356              :             }
   10357              : 
   10358              : 
   10359              :           /* Generate the invariant statements.  */
   10360       239088 :           if (!gimple_seq_empty_p (bb_vinfo->inv_pattern_def_seq))
   10361              :             {
   10362           23 :               if (dump_enabled_p ())
   10363            0 :                 dump_printf_loc (MSG_NOTE, vect_location,
   10364              :                          "------>generating invariant statements\n");
   10365              : 
   10366           23 :               bb_vinfo->insert_seq_on_entry (NULL,
   10367              :                                              bb_vinfo->inv_pattern_def_seq);
   10368              :             }
   10369       239088 :         }
   10370              :       else
   10371              :         {
   10372      2015004 :           if (dump_enabled_p ())
   10373         1312 :             dump_printf_loc (MSG_NOTE, vect_location,
   10374              :                              "***** Analysis failed with vector mode %s\n",
   10375         1312 :                              GET_MODE_NAME (bb_vinfo->vector_mode));
   10376              :         }
   10377              : 
   10378      2254092 :       if (mode_i == 0)
   10379      1922664 :         autodetected_vector_mode = bb_vinfo->vector_mode;
   10380              : 
   10381      2254092 :       if (!fatal)
   10382      3225291 :         while (mode_i < vector_modes.length ()
   10383      1805363 :                && vect_chooses_same_modes_p (bb_vinfo, vector_modes[mode_i]))
   10384              :           {
   10385       341749 :             if (dump_enabled_p ())
   10386         1666 :               dump_printf_loc (MSG_NOTE, vect_location,
   10387              :                                "***** The result for vector mode %s would"
   10388              :                                " be the same\n",
   10389          833 :                                GET_MODE_NAME (vector_modes[mode_i]));
   10390       341749 :             mode_i += 1;
   10391              :           }
   10392              : 
   10393      2254092 :       delete bb_vinfo;
   10394              : 
   10395      2254092 :       if (mode_i < vector_modes.length ()
   10396      2071276 :           && VECTOR_MODE_P (autodetected_vector_mode)
   10397      2052786 :           && (related_vector_mode (vector_modes[mode_i],
   10398              :                                    GET_MODE_INNER (autodetected_vector_mode))
   10399      1026393 :               == autodetected_vector_mode)
   10400      4325368 :           && (related_vector_mode (autodetected_vector_mode,
   10401       533503 :                                    GET_MODE_INNER (vector_modes[mode_i]))
   10402      1067006 :               == vector_modes[mode_i]))
   10403              :         {
   10404       533503 :           if (dump_enabled_p ())
   10405          207 :             dump_printf_loc (MSG_NOTE, vect_location,
   10406              :                              "***** Skipping vector mode %s, which would"
   10407              :                              " repeat the analysis for %s\n",
   10408          207 :                              GET_MODE_NAME (vector_modes[mode_i]),
   10409          207 :                              GET_MODE_NAME (autodetected_vector_mode));
   10410       533503 :           mode_i += 1;
   10411              :         }
   10412              : 
   10413      2254092 :       if (vectorized
   10414      2093060 :           || mode_i == vector_modes.length ()
   10415      1910289 :           || autodetected_vector_mode == VOIDmode
   10416              :           /* If vect_slp_analyze_bb_1 signaled that analysis for all
   10417              :              vector sizes will fail do not bother iterating.  */
   10418      3119498 :           || fatal)
   10419      3845328 :         return vectorized;
   10420              : 
   10421              :       /* Try the next biggest vector size.  */
   10422       331428 :       next_vector_mode = vector_modes[mode_i++];
   10423       331428 :       if (dump_enabled_p ())
   10424          215 :         dump_printf_loc (MSG_NOTE, vect_location,
   10425              :                          "***** Re-trying analysis with vector mode %s\n",
   10426          215 :                          GET_MODE_NAME (next_vector_mode));
   10427       331428 :     }
   10428      1922664 : }
   10429              : 
   10430              : 
   10431              : /* Main entry for the BB vectorizer.  Analyze and transform BBS, returns
   10432              :    true if anything in the basic-block was vectorized.  */
   10433              : 
   10434              : static bool
   10435      1922664 : vect_slp_bbs (const vec<basic_block> &bbs, loop_p orig_loop)
   10436              : {
   10437      1922664 :   vec<data_reference_p> datarefs = vNULL;
   10438      1922664 :   auto_vec<int> dataref_groups;
   10439      1922664 :   int insns = 0;
   10440      1922664 :   int current_group = 0;
   10441              : 
   10442     12747958 :   for (unsigned i = 0; i < bbs.length (); i++)
   10443              :     {
   10444     10825294 :       basic_block bb = bbs[i];
   10445     93582285 :       for (gimple_stmt_iterator gsi = gsi_after_labels (bb); !gsi_end_p (gsi);
   10446     82756991 :            gsi_next (&gsi))
   10447              :         {
   10448     82756991 :           gimple *stmt = gsi_stmt (gsi);
   10449     82756991 :           if (is_gimple_debug (stmt))
   10450     52202939 :             continue;
   10451              : 
   10452     30554052 :           insns++;
   10453              : 
   10454     30554052 :           if (gimple_location (stmt) != UNKNOWN_LOCATION)
   10455     27425903 :             vect_location = stmt;
   10456              : 
   10457     30554052 :           if (!vect_find_stmt_data_reference (NULL, stmt, &datarefs,
   10458              :                                               &dataref_groups, current_group))
   10459      5222996 :             ++current_group;
   10460              :         }
   10461              :       /* New BBs always start a new DR group.  */
   10462     10825294 :       ++current_group;
   10463              :     }
   10464              : 
   10465      1922664 :   return vect_slp_region (bbs, datarefs, &dataref_groups, insns, orig_loop);
   10466      1922664 : }
   10467              : 
   10468              : /* Special entry for the BB vectorizer.  Analyze and transform a single
   10469              :    if-converted BB with ORIG_LOOPs body being the not if-converted
   10470              :    representation.  Returns true if anything in the basic-block was
   10471              :    vectorized.  */
   10472              : 
   10473              : bool
   10474        19425 : vect_slp_if_converted_bb (basic_block bb, loop_p orig_loop)
   10475              : {
   10476        19425 :   auto_vec<basic_block> bbs;
   10477        19425 :   bbs.safe_push (bb);
   10478        19425 :   return vect_slp_bbs (bbs, orig_loop);
   10479        19425 : }
   10480              : 
   10481              : /* Main entry for the BB vectorizer.  Analyze and transform BB, returns
   10482              :    true if anything in the basic-block was vectorized.  */
   10483              : 
   10484              : bool
   10485       921021 : vect_slp_function (function *fun)
   10486              : {
   10487       921021 :   bool r = false;
   10488       921021 :   int *rpo = XNEWVEC (int, n_basic_blocks_for_fn (fun));
   10489       921021 :   auto_bitmap exit_bbs;
   10490       921021 :   bitmap_set_bit (exit_bbs, EXIT_BLOCK);
   10491       921021 :   edge entry = single_succ_edge (ENTRY_BLOCK_PTR_FOR_FN (fun));
   10492       921021 :   unsigned n = rev_post_order_and_mark_dfs_back_seme (fun, entry, exit_bbs,
   10493       921021 :                                                       true, rpo, NULL);
   10494              : 
   10495              :   /* For the moment split the function into pieces to avoid making
   10496              :      the iteration on the vector mode moot.  Split at points we know
   10497              :      to not handle well which is CFG merges (SLP discovery doesn't
   10498              :      handle non-loop-header PHIs) and loop exits.  Since pattern
   10499              :      recog requires reverse iteration to visit uses before defs
   10500              :      simply chop RPO into pieces.  */
   10501       921021 :   auto_vec<basic_block> bbs;
   10502     11757804 :   for (unsigned i = 0; i < n; i++)
   10503              :     {
   10504     10836783 :       basic_block bb = BASIC_BLOCK_FOR_FN (fun, rpo[i]);
   10505     10836783 :       bool split = false;
   10506              : 
   10507              :       /* Split when a BB is not dominated by the first block.  */
   10508     20440427 :       if (!bbs.is_empty ()
   10509      9603644 :           && !dominated_by_p (CDI_DOMINATORS, bb, bbs[0]))
   10510              :         {
   10511       689889 :           if (dump_enabled_p ())
   10512          146 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10513              :                              "splitting region at dominance boundary bb%d\n",
   10514              :                              bb->index);
   10515              :           split = true;
   10516              :         }
   10517              :       /* Split when the loop determined by the first block
   10518              :          is exited.  This is because we eventually insert
   10519              :          invariants at region begin.  */
   10520     19060649 :       else if (!bbs.is_empty ()
   10521      8913755 :                && bbs[0]->loop_father != bb->loop_father
   10522      2313890 :                && !flow_loop_nested_p (bbs[0]->loop_father, bb->loop_father))
   10523              :         {
   10524         3834 :           if (dump_enabled_p ())
   10525            6 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10526              :                              "splitting region at loop %d exit at bb%d\n",
   10527            3 :                              bbs[0]->loop_father->num, bb->index);
   10528              :           split = true;
   10529              :         }
   10530     10143060 :       else if (!bbs.is_empty ()
   10531      8909921 :                && bb->loop_father->header == bb
   10532       474781 :                && bb->loop_father->dont_vectorize)
   10533              :         {
   10534         7291 :           if (dump_enabled_p ())
   10535           72 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10536              :                              "splitting region at dont-vectorize loop %d "
   10537              :                              "entry at bb%d\n",
   10538              :                              bb->loop_father->num, bb->index);
   10539              :           split = true;
   10540              :         }
   10541              : 
   10542     11537797 :       if (split && !bbs.is_empty ())
   10543              :         {
   10544       701014 :           r |= vect_slp_bbs (bbs, NULL);
   10545       701014 :           bbs.truncate (0);
   10546              :         }
   10547              : 
   10548     10836783 :       if (bbs.is_empty ())
   10549              :         {
   10550              :           /* We need to be able to insert at the head of the region which
   10551              :              we cannot for region starting with a returns-twice call.  */
   10552      1934153 :           if (gcall *first = safe_dyn_cast <gcall *> (first_stmt (bb)))
   10553       409129 :             if (gimple_call_flags (first) & ECF_RETURNS_TWICE)
   10554              :               {
   10555          306 :                 if (dump_enabled_p ())
   10556            2 :                   dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10557              :                                    "skipping bb%d as start of region as it "
   10558              :                                    "starts with returns-twice call\n",
   10559              :                                    bb->index);
   10560        30914 :                 continue;
   10561              :               }
   10562              :           /* If the loop this BB belongs to is marked as not to be vectorized
   10563              :              honor that also for BB vectorization.  */
   10564      1933847 :           if (bb->loop_father->dont_vectorize)
   10565        30608 :             continue;
   10566              :         }
   10567              : 
   10568     10805869 :       bbs.safe_push (bb);
   10569              : 
   10570              :       /* When we have a stmt ending this block and defining a
   10571              :          value we have to insert on edges when inserting after it for
   10572              :          a vector containing its definition.  Avoid this for now.  */
   10573     21611738 :       if (gimple *last = *gsi_last_bb (bb))
   10574      8787110 :         if (gimple_get_lhs (last)
   10575      8787110 :             && is_ctrl_altering_stmt (last))
   10576              :           {
   10577       281211 :             if (dump_enabled_p ())
   10578            2 :               dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   10579              :                                "splitting region at control altering "
   10580              :                                "definition %G", last);
   10581       281211 :             r |= vect_slp_bbs (bbs, NULL);
   10582       281211 :             bbs.truncate (0);
   10583              :           }
   10584              :     }
   10585              : 
   10586       921021 :   if (!bbs.is_empty ())
   10587       921014 :     r |= vect_slp_bbs (bbs, NULL);
   10588              : 
   10589       921021 :   free (rpo);
   10590              : 
   10591       921021 :   return r;
   10592       921021 : }
   10593              : 
   10594              : /* Build a variable-length vector in which the elements in ELTS are repeated
   10595              :    to a fill NRESULTS vectors of type VECTOR_TYPE.  Store the vectors in
   10596              :    RESULTS and add any new instructions to SEQ.
   10597              : 
   10598              :    The approach we use is:
   10599              : 
   10600              :    (1) Find a vector mode VM with integer elements of mode IM.
   10601              : 
   10602              :    (2) Replace ELTS[0:NELTS] with ELTS'[0:NELTS'], where each element of
   10603              :        ELTS' has mode IM.  This involves creating NELTS' VIEW_CONVERT_EXPRs
   10604              :        from small vectors to IM.
   10605              : 
   10606              :    (3) Duplicate each ELTS'[I] into a vector of mode VM.
   10607              : 
   10608              :    (4) Use a tree of interleaving VEC_PERM_EXPRs to create VMs with the
   10609              :        correct byte contents.
   10610              : 
   10611              :    (5) Use VIEW_CONVERT_EXPR to cast the final VMs to the required type.
   10612              : 
   10613              :    We try to find the largest IM for which this sequence works, in order
   10614              :    to cut down on the number of interleaves.  */
   10615              : 
   10616              : void
   10617            0 : duplicate_and_interleave (vec_info *vinfo, gimple_seq *seq, tree vector_type,
   10618              :                           const vec<tree> &elts, unsigned int nresults,
   10619              :                           vec<tree> &results)
   10620              : {
   10621            0 :   unsigned int nelts = elts.length ();
   10622            0 :   tree element_type = TREE_TYPE (vector_type);
   10623              : 
   10624              :   /* (1) Find a vector mode VM with integer elements of mode IM.  */
   10625            0 :   unsigned int nvectors = 1;
   10626            0 :   tree new_vector_type;
   10627            0 :   tree permutes[2];
   10628            0 :   if (!can_duplicate_and_interleave_p (vinfo, nelts, element_type,
   10629              :                                        &nvectors, &new_vector_type,
   10630              :                                        permutes))
   10631            0 :     gcc_unreachable ();
   10632              : 
   10633              :   /* Get a vector type that holds ELTS[0:NELTS/NELTS'].  */
   10634            0 :   unsigned int partial_nelts = nelts / nvectors;
   10635            0 :   tree partial_vector_type = build_vector_type (element_type, partial_nelts);
   10636              : 
   10637            0 :   tree_vector_builder partial_elts;
   10638            0 :   auto_vec<tree, 32> pieces (nvectors * 2);
   10639            0 :   pieces.quick_grow_cleared (nvectors * 2);
   10640            0 :   for (unsigned int i = 0; i < nvectors; ++i)
   10641              :     {
   10642              :       /* (2) Replace ELTS[0:NELTS] with ELTS'[0:NELTS'], where each element of
   10643              :              ELTS' has mode IM.  */
   10644            0 :       partial_elts.new_vector (partial_vector_type, partial_nelts, 1);
   10645            0 :       for (unsigned int j = 0; j < partial_nelts; ++j)
   10646            0 :         partial_elts.quick_push (elts[i * partial_nelts + j]);
   10647            0 :       tree t = gimple_build_vector (seq, &partial_elts);
   10648            0 :       t = gimple_build (seq, VIEW_CONVERT_EXPR,
   10649            0 :                         TREE_TYPE (new_vector_type), t);
   10650              : 
   10651              :       /* (3) Duplicate each ELTS'[I] into a vector of mode VM.  */
   10652            0 :       pieces[i] = gimple_build_vector_from_val (seq, new_vector_type, t);
   10653              :     }
   10654              : 
   10655              :   /* (4) Use a tree of VEC_PERM_EXPRs to create a single VM with the
   10656              :          correct byte contents.
   10657              : 
   10658              :      Conceptually, we need to repeat the following operation log2(nvectors)
   10659              :      times, where hi_start = nvectors / 2:
   10660              : 
   10661              :         out[i * 2] = VEC_PERM_EXPR (in[i], in[i + hi_start], lo_permute);
   10662              :         out[i * 2 + 1] = VEC_PERM_EXPR (in[i], in[i + hi_start], hi_permute);
   10663              : 
   10664              :      However, if each input repeats every N elements and the VF is
   10665              :      a multiple of N * 2, the HI result is the same as the LO result.
   10666              :      This will be true for the first N1 iterations of the outer loop,
   10667              :      followed by N2 iterations for which both the LO and HI results
   10668              :      are needed.  I.e.:
   10669              : 
   10670              :         N1 + N2 = log2(nvectors)
   10671              : 
   10672              :      Each "N1 iteration" doubles the number of redundant vectors and the
   10673              :      effect of the process as a whole is to have a sequence of nvectors/2**N1
   10674              :      vectors that repeats 2**N1 times.  Rather than generate these redundant
   10675              :      vectors, we halve the number of vectors for each N1 iteration.  */
   10676              :   unsigned int in_start = 0;
   10677              :   unsigned int out_start = nvectors;
   10678              :   unsigned int new_nvectors = nvectors;
   10679            0 :   for (unsigned int in_repeat = 1; in_repeat < nvectors; in_repeat *= 2)
   10680              :     {
   10681            0 :       unsigned int hi_start = new_nvectors / 2;
   10682            0 :       unsigned int out_i = 0;
   10683            0 :       for (unsigned int in_i = 0; in_i < new_nvectors; ++in_i)
   10684              :         {
   10685            0 :           if ((in_i & 1) != 0
   10686            0 :               && multiple_p (TYPE_VECTOR_SUBPARTS (new_vector_type),
   10687              :                              2 * in_repeat))
   10688            0 :             continue;
   10689              : 
   10690            0 :           tree output = make_ssa_name (new_vector_type);
   10691            0 :           tree input1 = pieces[in_start + (in_i / 2)];
   10692            0 :           tree input2 = pieces[in_start + (in_i / 2) + hi_start];
   10693            0 :           gassign *stmt = gimple_build_assign (output, VEC_PERM_EXPR,
   10694              :                                                input1, input2,
   10695              :                                                permutes[in_i & 1]);
   10696            0 :           gimple_seq_add_stmt (seq, stmt);
   10697            0 :           pieces[out_start + out_i] = output;
   10698            0 :           out_i += 1;
   10699              :         }
   10700            0 :       std::swap (in_start, out_start);
   10701            0 :       new_nvectors = out_i;
   10702              :     }
   10703              : 
   10704              :   /* (5) Use VIEW_CONVERT_EXPR to cast the final VM to the required type.  */
   10705            0 :   results.reserve (nresults);
   10706            0 :   for (unsigned int i = 0; i < nresults; ++i)
   10707            0 :     if (i < new_nvectors)
   10708            0 :       results.quick_push (gimple_build (seq, VIEW_CONVERT_EXPR, vector_type,
   10709            0 :                                         pieces[in_start + i]));
   10710              :     else
   10711            0 :       results.quick_push (results[i - new_nvectors]);
   10712            0 : }
   10713              : 
   10714              : 
   10715              : /* For constant and loop invariant defs in OP_NODE this function creates
   10716              :    vector defs that will be used in the vectorized stmts and stores them
   10717              :    to SLP_TREE_VEC_DEFS of OP_NODE.  */
   10718              : 
   10719              : static void
   10720       496541 : vect_create_constant_vectors (vec_info *vinfo, slp_tree op_node)
   10721              : {
   10722       496541 :   unsigned HOST_WIDE_INT nunits;
   10723       496541 :   tree vec_cst;
   10724       496541 :   unsigned j, number_of_places_left_in_vector;
   10725       496541 :   tree vector_type;
   10726       496541 :   tree vop;
   10727       496541 :   int group_size = op_node->ops.length ();
   10728       496541 :   unsigned int vec_num, i;
   10729       496541 :   unsigned number_of_copies = 1;
   10730       496541 :   bool constant_p;
   10731       496541 :   gimple_seq ctor_seq = NULL;
   10732       496541 :   auto_vec<tree, 16> permute_results;
   10733              : 
   10734              :   /* We always want SLP_TREE_VECTYPE (op_node) here correctly set.  */
   10735       496541 :   vector_type = SLP_TREE_VECTYPE (op_node);
   10736              : 
   10737       496541 :   unsigned int number_of_vectors = vect_get_num_copies (vinfo, op_node);
   10738       496541 :   SLP_TREE_VEC_DEFS (op_node).create (number_of_vectors);
   10739       496541 :   auto_vec<tree> voprnds (number_of_vectors);
   10740              : 
   10741              :   /* NUMBER_OF_COPIES is the number of times we need to use the same values in
   10742              :      created vectors. It is greater than 1 if unrolling is performed.
   10743              : 
   10744              :      For example, we have two scalar operands, s1 and s2 (e.g., group of
   10745              :      strided accesses of size two), while NUNITS is four (i.e., four scalars
   10746              :      of this type can be packed in a vector).  The output vector will contain
   10747              :      two copies of each scalar operand: {s1, s2, s1, s2}.  (NUMBER_OF_COPIES
   10748              :      will be 2).
   10749              : 
   10750              :      If GROUP_SIZE > NUNITS, the scalars will be split into several vectors
   10751              :      containing the operands.
   10752              : 
   10753              :      For example, NUNITS is four as before, and the group size is 8
   10754              :      (s1, s2, ..., s8).  We will create two vectors {s1, s2, s3, s4} and
   10755              :      {s5, s6, s7, s8}.  */
   10756              : 
   10757              :   /* When using duplicate_and_interleave, we just need one element for
   10758              :      each scalar statement.  */
   10759       496541 :   if (!TYPE_VECTOR_SUBPARTS (vector_type).is_constant (&nunits))
   10760              :     nunits = group_size;
   10761              : 
   10762       496541 :   number_of_copies = nunits * number_of_vectors / group_size;
   10763              : 
   10764       496541 :   number_of_places_left_in_vector = nunits;
   10765       496541 :   constant_p = true;
   10766       496541 :   tree uniform_elt = NULL_TREE;
   10767       496541 :   tree_vector_builder elts (vector_type, nunits, 1);
   10768       496541 :   elts.quick_grow (nunits);
   10769       496541 :   stmt_vec_info insert_after = NULL;
   10770      1477121 :   for (j = 0; j < number_of_copies; j++)
   10771              :     {
   10772       980580 :       tree op;
   10773      3764106 :       for (i = group_size - 1; op_node->ops.iterate (i, &op); i--)
   10774              :         {
   10775              :           /* Create 'vect_ = {op0,op1,...,opn}'.  */
   10776      1802946 :           tree orig_op = op;
   10777      1802946 :           if (number_of_places_left_in_vector == nunits)
   10778              :             uniform_elt = op;
   10779      1175237 :           else if (uniform_elt && operand_equal_p (uniform_elt, op))
   10780       745598 :             op = elts[number_of_places_left_in_vector];
   10781              :           else
   10782              :             uniform_elt = NULL_TREE;
   10783      1802946 :           number_of_places_left_in_vector--;
   10784      1802946 :           if (!types_compatible_p (TREE_TYPE (vector_type), TREE_TYPE (op)))
   10785              :             {
   10786       281149 :               if (CONSTANT_CLASS_P (op))
   10787              :                 {
   10788       103183 :                   if (VECTOR_BOOLEAN_TYPE_P (vector_type))
   10789              :                     {
   10790              :                       /* Can't use VIEW_CONVERT_EXPR for booleans because
   10791              :                          of possibly different sizes of scalar value and
   10792              :                          vector element.  */
   10793           65 :                       if (integer_zerop (op))
   10794           65 :                         op = build_int_cst (TREE_TYPE (vector_type), 0);
   10795            0 :                       else if (integer_onep (op))
   10796            0 :                         op = build_all_ones_cst (TREE_TYPE (vector_type));
   10797              :                       else
   10798            0 :                         gcc_unreachable ();
   10799              :                     }
   10800              :                   else
   10801       103118 :                     op = fold_unary (VIEW_CONVERT_EXPR,
   10802              :                                      TREE_TYPE (vector_type), op);
   10803       103183 :                   gcc_assert (op && CONSTANT_CLASS_P (op));
   10804              :                 }
   10805              :               else
   10806              :                 {
   10807       177966 :                   tree new_temp = make_ssa_name (TREE_TYPE (vector_type));
   10808       177966 :                   gimple *init_stmt;
   10809       177966 :                   if (VECTOR_BOOLEAN_TYPE_P (vector_type))
   10810              :                     {
   10811          427 :                       tree true_val
   10812          427 :                         = build_all_ones_cst (TREE_TYPE (vector_type));
   10813          427 :                       tree false_val
   10814          427 :                         = build_zero_cst (TREE_TYPE (vector_type));
   10815          427 :                       gcc_assert (INTEGRAL_TYPE_P (TREE_TYPE (op)));
   10816          427 :                       init_stmt = gimple_build_assign (new_temp, COND_EXPR,
   10817              :                                                        op, true_val,
   10818              :                                                        false_val);
   10819              :                     }
   10820              :                   else
   10821              :                     {
   10822       177539 :                       op = build1 (VIEW_CONVERT_EXPR, TREE_TYPE (vector_type),
   10823              :                                    op);
   10824       177539 :                       init_stmt
   10825       177539 :                         = gimple_build_assign (new_temp, VIEW_CONVERT_EXPR,
   10826              :                                                op);
   10827              :                     }
   10828       177966 :                   gimple_seq_add_stmt (&ctor_seq, init_stmt);
   10829       177966 :                   op = new_temp;
   10830              :                 }
   10831              :             }
   10832      1802946 :           elts[number_of_places_left_in_vector] = op;
   10833      1802946 :           if (!CONSTANT_CLASS_P (op))
   10834       319095 :             constant_p = false;
   10835              :           /* For BB vectorization we have to compute an insert location
   10836              :              when a def is inside the analyzed region since we cannot
   10837              :              simply insert at the BB start in this case.  */
   10838      1802946 :           stmt_vec_info opdef;
   10839      1802946 :           if (TREE_CODE (orig_op) == SSA_NAME
   10840       182058 :               && !SSA_NAME_IS_DEFAULT_DEF (orig_op)
   10841       162012 :               && is_a <bb_vec_info> (vinfo)
   10842      1907281 :               && (opdef = vinfo->lookup_def (orig_op)))
   10843              :             {
   10844        84581 :               if (!insert_after)
   10845              :                 insert_after = opdef;
   10846              :               else
   10847        46570 :                 insert_after = get_later_stmt (insert_after, opdef);
   10848              :             }
   10849              : 
   10850      1802946 :           if (number_of_places_left_in_vector == 0)
   10851              :             {
   10852       627709 :               auto type_nunits = TYPE_VECTOR_SUBPARTS (vector_type);
   10853       627709 :               if (uniform_elt)
   10854       653070 :                 vec_cst = gimple_build_vector_from_val (&ctor_seq, vector_type,
   10855       326535 :                                                         elts[0]);
   10856       602348 :               else if (constant_p
   10857       602348 :                        ? multiple_p (type_nunits, nunits)
   10858       110618 :                        : known_eq (type_nunits, nunits))
   10859       301174 :                 vec_cst = gimple_build_vector (&ctor_seq, &elts);
   10860              :               else
   10861              :                 {
   10862            0 :                   if (permute_results.is_empty ())
   10863            0 :                     duplicate_and_interleave (vinfo, &ctor_seq, vector_type,
   10864              :                                               elts, number_of_vectors,
   10865              :                                               permute_results);
   10866            0 :                   vec_cst = permute_results[number_of_vectors - j - 1];
   10867              :                 }
   10868       627709 :               if (!gimple_seq_empty_p (ctor_seq))
   10869              :                 {
   10870       138097 :                   if (insert_after)
   10871              :                     {
   10872        38011 :                       gimple_stmt_iterator gsi;
   10873        38011 :                       if (gimple_code (insert_after->stmt) == GIMPLE_PHI)
   10874              :                         {
   10875          679 :                           gsi = gsi_after_labels (gimple_bb (insert_after->stmt));
   10876          679 :                           gsi_insert_seq_before (&gsi, ctor_seq,
   10877              :                                                  GSI_CONTINUE_LINKING);
   10878              :                         }
   10879        37332 :                       else if (!stmt_ends_bb_p (insert_after->stmt))
   10880              :                         {
   10881        37332 :                           gsi = gsi_for_stmt (insert_after->stmt);
   10882        37332 :                           gsi_insert_seq_after (&gsi, ctor_seq,
   10883              :                                                 GSI_CONTINUE_LINKING);
   10884              :                         }
   10885              :                       else
   10886              :                         {
   10887              :                           /* When we want to insert after a def where the
   10888              :                              defining stmt throws then insert on the fallthru
   10889              :                              edge.  */
   10890            0 :                           edge e = find_fallthru_edge
   10891            0 :                                      (gimple_bb (insert_after->stmt)->succs);
   10892            0 :                           basic_block new_bb
   10893            0 :                             = gsi_insert_seq_on_edge_immediate (e, ctor_seq);
   10894            0 :                           gcc_assert (!new_bb);
   10895              :                         }
   10896              :                     }
   10897              :                   else
   10898       100086 :                     vinfo->insert_seq_on_entry (NULL, ctor_seq);
   10899       138097 :                   ctor_seq = NULL;
   10900              :                 }
   10901       627709 :               voprnds.quick_push (vec_cst);
   10902       627709 :               insert_after = NULL;
   10903       627709 :               number_of_places_left_in_vector = nunits;
   10904       627709 :               constant_p = true;
   10905       627709 :               elts.new_vector (vector_type, nunits, 1);
   10906       627709 :               elts.quick_grow (nunits);
   10907              :             }
   10908              :         }
   10909              :     }
   10910              : 
   10911              :   /* Since the vectors are created in the reverse order, we should invert
   10912              :      them.  */
   10913       496541 :   vec_num = voprnds.length ();
   10914      1124250 :   for (j = vec_num; j != 0; j--)
   10915              :     {
   10916       627709 :       vop = voprnds[j - 1];
   10917       627709 :       SLP_TREE_VEC_DEFS (op_node).quick_push (vop);
   10918              :     }
   10919              : 
   10920              :   /* In case that VF is greater than the unrolling factor needed for the SLP
   10921              :      group of stmts, NUMBER_OF_VECTORS to be created is greater than
   10922              :      NUMBER_OF_SCALARS/NUNITS or NUNITS/NUMBER_OF_SCALARS, and hence we have
   10923              :      to replicate the vectors.  */
   10924       496541 :   while (number_of_vectors > SLP_TREE_VEC_DEFS (op_node).length ())
   10925       496541 :     for (i = 0; SLP_TREE_VEC_DEFS (op_node).iterate (i, &vop) && i < vec_num;
   10926              :          i++)
   10927            0 :       SLP_TREE_VEC_DEFS (op_node).quick_push (vop);
   10928       496541 : }
   10929              : 
   10930              : /* Get the scalar definition of the Nth lane from SLP_NODE or NULL_TREE
   10931              :    if there is no definition for it in the scalar IL or it is not known.  */
   10932              : 
   10933              : tree
   10934         2629 : vect_get_slp_scalar_def (slp_tree slp_node, unsigned n)
   10935              : {
   10936         2629 :   if (SLP_TREE_DEF_TYPE (slp_node) == vect_internal_def)
   10937              :     {
   10938         2617 :       if (!SLP_TREE_SCALAR_STMTS (slp_node).exists ())
   10939              :         return NULL_TREE;
   10940         2617 :       stmt_vec_info def = SLP_TREE_SCALAR_STMTS (slp_node)[n];
   10941         2617 :       if (!def)
   10942              :         return NULL_TREE;
   10943         2617 :       return gimple_get_lhs (STMT_VINFO_STMT (def));
   10944              :     }
   10945              :   else
   10946           12 :     return SLP_TREE_SCALAR_OPS (slp_node)[n];
   10947              : }
   10948              : 
   10949              : /* Get the Ith vectorized definition from SLP_NODE.  */
   10950              : 
   10951              : tree
   10952       146411 : vect_get_slp_vect_def (slp_tree slp_node, unsigned i)
   10953              : {
   10954       146411 :   return SLP_TREE_VEC_DEFS (slp_node)[i];
   10955              : }
   10956              : 
   10957              : /* Get the vectorized definitions of SLP_NODE in *VEC_DEFS.  */
   10958              : 
   10959              : void
   10960       940121 : vect_get_slp_defs (slp_tree slp_node, vec<tree> *vec_defs)
   10961              : {
   10962      1880242 :   vec_defs->create (SLP_TREE_VEC_DEFS (slp_node).length ());
   10963       940121 :   vec_defs->splice (SLP_TREE_VEC_DEFS (slp_node));
   10964       940121 : }
   10965              : 
   10966              : /* Get N vectorized definitions for SLP_NODE.  */
   10967              : 
   10968              : void
   10969         2939 : vect_get_slp_defs (vec_info *,
   10970              :                    slp_tree slp_node, vec<vec<tree> > *vec_oprnds, unsigned n)
   10971              : {
   10972         2939 :   if (n == -1U)
   10973         2939 :     n = SLP_TREE_CHILDREN (slp_node).length ();
   10974              : 
   10975        10611 :   for (unsigned i = 0; i < n; ++i)
   10976              :     {
   10977         7672 :       slp_tree child = SLP_TREE_CHILDREN (slp_node)[i];
   10978         7672 :       vec<tree> vec_defs = vNULL;
   10979         7672 :       vect_get_slp_defs (child, &vec_defs);
   10980         7672 :       vec_oprnds->quick_push (vec_defs);
   10981              :     }
   10982         2939 : }
   10983              : 
   10984              : /* A subroutine of vect_transform_slp_perm_load with two extra arguments:
   10985              :    - PERM gives the permutation that the caller wants to use for NODE,
   10986              :      which might be different from SLP_LOAD_PERMUTATION.
   10987              :    - DUMP_P controls whether the function dumps information.  */
   10988              : 
   10989              : static bool
   10990       126673 : vect_transform_slp_perm_load_1 (vec_info *vinfo, slp_tree node,
   10991              :                                 load_permutation_t &perm,
   10992              :                                 const vec<tree> &dr_chain,
   10993              :                                 gimple_stmt_iterator *gsi, poly_uint64 vf,
   10994              :                                 bool analyze_only, bool dump_p,
   10995              :                                 unsigned *n_perms, unsigned int *n_loads,
   10996              :                                 bool dce_chain)
   10997              : {
   10998       126673 :   stmt_vec_info stmt_info = SLP_TREE_SCALAR_STMTS (node)[0];
   10999       126673 :   int vec_index = 0;
   11000       126673 :   tree vectype = SLP_TREE_VECTYPE (node);
   11001       126673 :   unsigned int group_size = SLP_TREE_SCALAR_STMTS (node).length ();
   11002       126673 :   unsigned int mask_element;
   11003       126673 :   unsigned dr_group_size;
   11004       126673 :   machine_mode mode;
   11005              : 
   11006       126673 :   if (!STMT_VINFO_GROUPED_ACCESS (stmt_info))
   11007              :     {
   11008              :       /* We have both splats of the same non-grouped load and groups
   11009              :          of distinct invariant loads entering here.  */
   11010         1485 :       unsigned max_idx = 0;
   11011         8231 :       for (auto idx : perm)
   11012         3776 :         max_idx = idx > max_idx ? idx : max_idx;
   11013         1485 :       dr_group_size = max_idx + 1;
   11014              :     }
   11015              :   else
   11016              :     {
   11017       125188 :       stmt_info = DR_GROUP_FIRST_ELEMENT (stmt_info);
   11018       125188 :       dr_group_size = DR_GROUP_SIZE (stmt_info);
   11019              :     }
   11020              : 
   11021       126673 :   mode = TYPE_MODE (vectype);
   11022       126673 :   poly_uint64 nunits = TYPE_VECTOR_SUBPARTS (vectype);
   11023       126673 :   unsigned int nstmts = vect_get_num_copies (vinfo, node);
   11024              : 
   11025              :   /* Initialize the vect stmts of NODE to properly insert the generated
   11026              :      stmts later.  */
   11027       126673 :   if (! analyze_only)
   11028        58430 :     for (unsigned i = SLP_TREE_VEC_DEFS (node).length (); i < nstmts; i++)
   11029        22488 :       SLP_TREE_VEC_DEFS (node).quick_push (NULL_TREE);
   11030              : 
   11031              :   /* Generate permutation masks for every NODE. Number of masks for each NODE
   11032              :      is equal to GROUP_SIZE.
   11033              :      E.g., we have a group of three nodes with three loads from the same
   11034              :      location in each node, and the vector size is 4. I.e., we have a
   11035              :      a0b0c0a1b1c1... sequence and we need to create the following vectors:
   11036              :      for a's: a0a0a0a1 a1a1a2a2 a2a3a3a3
   11037              :      for b's: b0b0b0b1 b1b1b2b2 b2b3b3b3
   11038              :      ...
   11039              : 
   11040              :      The masks for a's should be: {0,0,0,3} {3,3,6,6} {6,9,9,9}.
   11041              :      The last mask is illegal since we assume two operands for permute
   11042              :      operation, and the mask element values can't be outside that range.
   11043              :      Hence, the last mask must be converted into {2,5,5,5}.
   11044              :      For the first two permutations we need the first and the second input
   11045              :      vectors: {a0,b0,c0,a1} and {b1,c1,a2,b2}, and for the last permutation
   11046              :      we need the second and the third vectors: {b1,c1,a2,b2} and
   11047              :      {c2,a3,b3,c3}.  */
   11048              : 
   11049       126673 :   int vect_stmts_counter = 0;
   11050       126673 :   unsigned int index = 0;
   11051       126673 :   int first_vec_index = -1;
   11052       126673 :   int second_vec_index = -1;
   11053       126673 :   bool noop_p = true;
   11054       126673 :   *n_perms = 0;
   11055              : 
   11056       126673 :   vec_perm_builder mask;
   11057       126673 :   unsigned int nelts_to_build;
   11058       126673 :   unsigned int nvectors_per_build;
   11059       126673 :   unsigned int in_nlanes;
   11060       126673 :   bool repeating_p = (group_size == dr_group_size
   11061       160602 :                       && multiple_p (nunits, group_size));
   11062       126673 :   if (repeating_p)
   11063              :     {
   11064              :       /* A single vector contains a whole number of copies of the node, so:
   11065              :          (a) all permutes can use the same mask; and
   11066              :          (b) the permutes only need a single vector input.  */
   11067        31627 :       mask.new_vector (nunits, group_size, 3);
   11068        31627 :       nelts_to_build = mask.encoded_nelts ();
   11069              :       /* It's possible to obtain zero nstmts during analyze_only, so make
   11070              :          it at least one to ensure the later computation for n_perms
   11071              :          proceed.  */
   11072        31627 :       nvectors_per_build = nstmts > 0 ? nstmts : 1;
   11073        31627 :       in_nlanes = dr_group_size * 3;
   11074              :     }
   11075              :   else
   11076              :     {
   11077              :       /* We need to construct a separate mask for each vector statement.  */
   11078        95046 :       unsigned HOST_WIDE_INT const_nunits, const_vf;
   11079        95046 :       if (!nunits.is_constant (&const_nunits)
   11080        95046 :           || !vf.is_constant (&const_vf))
   11081              :         return false;
   11082        95046 :       mask.new_vector (const_nunits, const_nunits, 1);
   11083        95046 :       nelts_to_build = const_vf * group_size;
   11084        95046 :       nvectors_per_build = 1;
   11085        95046 :       in_nlanes = const_vf * dr_group_size;
   11086              :     }
   11087       126673 :   auto_sbitmap used_in_lanes (in_nlanes);
   11088       126673 :   bitmap_clear (used_in_lanes);
   11089       126673 :   auto_bitmap used_defs;
   11090              : 
   11091       126673 :   unsigned int count = mask.encoded_nelts ();
   11092       126673 :   mask.quick_grow (count);
   11093       126673 :   vec_perm_indices indices;
   11094              : 
   11095       680567 :   for (unsigned int j = 0; j < nelts_to_build; j++)
   11096              :     {
   11097       563901 :       unsigned int iter_num = j / group_size;
   11098       563901 :       unsigned int stmt_num = j % group_size;
   11099       563901 :       unsigned int i = (iter_num * dr_group_size + perm[stmt_num]);
   11100       563901 :       bitmap_set_bit (used_in_lanes, i);
   11101       563901 :       if (repeating_p)
   11102              :         {
   11103              :           first_vec_index = 0;
   11104              :           mask_element = i;
   11105              :         }
   11106              :       else
   11107              :         {
   11108              :           /* Enforced before the loop when !repeating_p.  */
   11109       357711 :           unsigned int const_nunits = nunits.to_constant ();
   11110       357711 :           vec_index = i / const_nunits;
   11111       357711 :           mask_element = i % const_nunits;
   11112       357711 :           if (vec_index == first_vec_index
   11113       357711 :               || first_vec_index == -1)
   11114              :             {
   11115              :               first_vec_index = vec_index;
   11116              :             }
   11117       142522 :           else if (vec_index == second_vec_index
   11118       142522 :                    || second_vec_index == -1)
   11119              :             {
   11120       136423 :               second_vec_index = vec_index;
   11121       136423 :               mask_element += const_nunits;
   11122              :             }
   11123              :           else
   11124              :             {
   11125         6099 :               if (dump_p)
   11126          280 :                 dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11127              :                                  "permutation requires at "
   11128              :                                  "least three vectors %G",
   11129              :                                  stmt_info->stmt);
   11130         6099 :               gcc_assert (analyze_only);
   11131              :               return false;
   11132              :             }
   11133              : 
   11134       351612 :           gcc_assert (mask_element < 2 * const_nunits);
   11135              :         }
   11136              : 
   11137       557802 :       if (mask_element != index)
   11138       360733 :         noop_p = false;
   11139       557802 :       mask[index++] = mask_element;
   11140              : 
   11141       557802 :       if (index == count)
   11142              :         {
   11143       150698 :           if (!noop_p)
   11144              :             {
   11145       121938 :               indices.new_vector (mask, second_vec_index == -1 ? 1 : 2, nunits);
   11146       121938 :               if (!can_vec_perm_const_p (mode, mode, indices))
   11147              :                 {
   11148         3908 :                   if (dump_p)
   11149              :                     {
   11150           79 :                       dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11151              :                                        "unsupported vect permute { ");
   11152          669 :                       for (i = 0; i < count; ++i)
   11153              :                         {
   11154          590 :                           dump_dec (MSG_MISSED_OPTIMIZATION, mask[i]);
   11155          590 :                           dump_printf (MSG_MISSED_OPTIMIZATION, " ");
   11156              :                         }
   11157           79 :                       dump_printf (MSG_MISSED_OPTIMIZATION, "}\n");
   11158              :                     }
   11159         3908 :                   gcc_assert (analyze_only);
   11160              :                   return false;
   11161              :                 }
   11162              : 
   11163       118030 :               tree mask_vec = NULL_TREE;
   11164       118030 :               if (!analyze_only)
   11165        20782 :                 mask_vec = vect_gen_perm_mask_checked (vectype, indices);
   11166              : 
   11167       118030 :               if (second_vec_index == -1)
   11168        35591 :                 second_vec_index = first_vec_index;
   11169              : 
   11170       238934 :               for (unsigned int ri = 0; ri < nvectors_per_build; ++ri)
   11171              :                 {
   11172       120904 :                   ++*n_perms;
   11173       120904 :                   if (analyze_only)
   11174        99839 :                     continue;
   11175              :                   /* Generate the permute statement if necessary.  */
   11176        21065 :                   tree first_vec = dr_chain[first_vec_index + ri];
   11177        21065 :                   tree second_vec = dr_chain[second_vec_index + ri];
   11178        21065 :                   gassign *stmt = as_a<gassign *> (stmt_info->stmt);
   11179        21065 :                   tree perm_dest
   11180        21065 :                     = vect_create_destination_var (gimple_assign_lhs (stmt),
   11181              :                                                    vectype);
   11182        21065 :                   perm_dest = make_ssa_name (perm_dest);
   11183        21065 :                   gimple *perm_stmt
   11184        21065 :                     = gimple_build_assign (perm_dest, VEC_PERM_EXPR, first_vec,
   11185              :                                            second_vec, mask_vec);
   11186        21065 :                   vect_finish_stmt_generation (vinfo, stmt_info, perm_stmt,
   11187              :                                                gsi);
   11188        21065 :                   if (dce_chain)
   11189              :                     {
   11190        20142 :                       bitmap_set_bit (used_defs, first_vec_index + ri);
   11191        20142 :                       bitmap_set_bit (used_defs, second_vec_index + ri);
   11192              :                     }
   11193              : 
   11194              :                   /* Store the vector statement in NODE.  */
   11195        21065 :                   SLP_TREE_VEC_DEFS (node)[vect_stmts_counter++] = perm_dest;
   11196              :                 }
   11197              :             }
   11198        28760 :           else if (!analyze_only)
   11199              :             {
   11200         2846 :               for (unsigned int ri = 0; ri < nvectors_per_build; ++ri)
   11201              :                 {
   11202         1423 :                   tree first_vec = dr_chain[first_vec_index + ri];
   11203              :                   /* If mask was NULL_TREE generate the requested
   11204              :                      identity transform.  */
   11205         1423 :                   if (dce_chain)
   11206         1416 :                     bitmap_set_bit (used_defs, first_vec_index + ri);
   11207              : 
   11208              :                   /* Store the vector statement in NODE.  */
   11209         1423 :                   SLP_TREE_VEC_DEFS (node)[vect_stmts_counter++] = first_vec;
   11210              :                 }
   11211              :             }
   11212              : 
   11213              :           index = 0;
   11214              :           first_vec_index = -1;
   11215              :           second_vec_index = -1;
   11216              :           noop_p = true;
   11217              :         }
   11218              :     }
   11219              : 
   11220       116666 :   if (n_loads)
   11221              :     {
   11222        81907 :       if (repeating_p)
   11223        10562 :         *n_loads = nstmts;
   11224              :       else
   11225              :         {
   11226              :           /* Enforced above when !repeating_p.  */
   11227        71345 :           unsigned int const_nunits = nunits.to_constant ();
   11228        71345 :           *n_loads = 0;
   11229        71345 :           bool load_seen = false;
   11230       990931 :           for (unsigned i = 0; i < in_nlanes; ++i)
   11231              :             {
   11232       919586 :               if (i % const_nunits == 0)
   11233              :                 {
   11234       389146 :                   if (load_seen)
   11235       112369 :                     *n_loads += 1;
   11236              :                   load_seen = false;
   11237              :                 }
   11238       919586 :               if (bitmap_bit_p (used_in_lanes, i))
   11239       256096 :                 load_seen = true;
   11240              :             }
   11241        71345 :           if (load_seen)
   11242        49311 :             *n_loads += 1;
   11243              :         }
   11244              :     }
   11245              : 
   11246       116666 :   if (dce_chain)
   11247       217523 :     for (unsigned i = 0; i < dr_chain.length (); ++i)
   11248        73672 :       if (!bitmap_bit_p (used_defs, i))
   11249              :         {
   11250        40647 :           tree def = dr_chain[i];
   11251        41038 :           do
   11252              :             {
   11253        41038 :               gimple *stmt = SSA_NAME_DEF_STMT (def);
   11254        41038 :               if (is_gimple_assign (stmt)
   11255        41038 :                   && (gimple_assign_rhs_code (stmt) == VIEW_CONVERT_EXPR
   11256        41038 :                       || gimple_assign_rhs_code (stmt) == CONSTRUCTOR))
   11257         4960 :                 def = single_ssa_tree_operand (stmt, SSA_OP_USE);
   11258              :               else
   11259              :                 def = NULL;
   11260        41038 :               gimple_stmt_iterator rgsi = gsi_for_stmt (stmt);
   11261        41038 :               gsi_remove (&rgsi, true);
   11262        41038 :               release_defs (stmt);
   11263              :             }
   11264        41038 :           while (def);
   11265              :         }
   11266              : 
   11267              :   return true;
   11268       126673 : }
   11269              : 
   11270              : /* Generate vector permute statements from a list of loads in DR_CHAIN.
   11271              :    If ANALYZE_ONLY is TRUE, only check that it is possible to create valid
   11272              :    permute statements for the SLP node NODE.  Store the number of vector
   11273              :    permute instructions in *N_PERMS and the number of vector load
   11274              :    instructions in *N_LOADS.  If DCE_CHAIN is true, remove all definitions
   11275              :    that were not needed.  */
   11276              : 
   11277              : bool
   11278        91009 : vect_transform_slp_perm_load (vec_info *vinfo,
   11279              :                               slp_tree node, const vec<tree> &dr_chain,
   11280              :                               gimple_stmt_iterator *gsi, poly_uint64 vf,
   11281              :                               bool analyze_only, unsigned *n_perms,
   11282              :                               unsigned int *n_loads, bool dce_chain)
   11283              : {
   11284        91009 :   return vect_transform_slp_perm_load_1 (vinfo, node,
   11285        91009 :                                          SLP_TREE_LOAD_PERMUTATION (node),
   11286              :                                          dr_chain, gsi, vf, analyze_only,
   11287              :                                          dump_enabled_p (), n_perms, n_loads,
   11288        91009 :                                          dce_chain);
   11289              : }
   11290              : 
   11291              : /* Produce the next vector result for SLP permutation NODE by adding a vector
   11292              :    statement at GSI.  If MASK_VEC is nonnull, add:
   11293              : 
   11294              :       <new SSA name> = VEC_PERM_EXPR <FIRST_DEF, SECOND_DEF, MASK_VEC>
   11295              : 
   11296              :    otherwise add:
   11297              : 
   11298              :       <new SSA name> = VEC_PERM_EXPR <FIRST_DEF, SECOND_DEF,
   11299              :                                       { N, N+1, N+2, ... }>
   11300              : 
   11301              :    where N == IDENTITY_OFFSET which is either zero or equal to the
   11302              :    number of elements of the result.  */
   11303              : 
   11304              : static void
   11305        31246 : vect_add_slp_permutation (vec_info *vinfo, gimple_stmt_iterator *gsi,
   11306              :                           slp_tree node, tree first_def, tree second_def,
   11307              :                           tree mask_vec, poly_uint64 identity_offset)
   11308              : {
   11309        31246 :   tree vectype = SLP_TREE_VECTYPE (node);
   11310              : 
   11311              :   /* ???  We SLP match existing vector element extracts but
   11312              :      allow punning which we need to re-instantiate at uses
   11313              :      but have no good way of explicitly representing.  */
   11314        31246 :   if (operand_equal_p (TYPE_SIZE (TREE_TYPE (first_def)), TYPE_SIZE (vectype))
   11315        31246 :       && !types_compatible_p (TREE_TYPE (first_def), vectype))
   11316              :     {
   11317           18 :       gassign *conv_stmt
   11318           18 :         = gimple_build_assign (make_ssa_name (vectype),
   11319              :                                build1 (VIEW_CONVERT_EXPR, vectype, first_def));
   11320           18 :       vect_finish_stmt_generation (vinfo, NULL, conv_stmt, gsi);
   11321           18 :       first_def = gimple_assign_lhs (conv_stmt);
   11322              :     }
   11323        31246 :   gassign *perm_stmt;
   11324        31246 :   tree perm_dest = make_ssa_name (vectype);
   11325        31246 :   if (mask_vec)
   11326              :     {
   11327        28003 :       if (operand_equal_p (TYPE_SIZE (TREE_TYPE (first_def)),
   11328        28003 :                            TYPE_SIZE (vectype))
   11329        28003 :           && !types_compatible_p (TREE_TYPE (second_def), vectype))
   11330              :         {
   11331            8 :           gassign *conv_stmt
   11332            8 :             = gimple_build_assign (make_ssa_name (vectype),
   11333              :                                    build1 (VIEW_CONVERT_EXPR,
   11334              :                                            vectype, second_def));
   11335            8 :           vect_finish_stmt_generation (vinfo, NULL, conv_stmt, gsi);
   11336            8 :           second_def = gimple_assign_lhs (conv_stmt);
   11337              :         }
   11338        28003 :       perm_stmt = gimple_build_assign (perm_dest, VEC_PERM_EXPR,
   11339              :                                        first_def, second_def,
   11340              :                                        mask_vec);
   11341              :     }
   11342              :   else
   11343              :     {
   11344         3243 :       auto def_nunits = TYPE_VECTOR_SUBPARTS (TREE_TYPE (first_def));
   11345         3243 :       unsigned HOST_WIDE_INT vecno;
   11346         3243 :       poly_uint64 eltno;
   11347         3243 :       if (!can_div_trunc_p (poly_uint64 (identity_offset), def_nunits,
   11348              :                             &vecno, &eltno))
   11349              :         gcc_unreachable ();
   11350         3243 :       tree def = vecno & 1 ? second_def : first_def;
   11351         3243 :       if (!types_compatible_p (TREE_TYPE (def), vectype))
   11352              :         {
   11353              :           /* For identity permutes we still need to handle the case
   11354              :              of offsetted extracts or concats.  */
   11355          239 :           unsigned HOST_WIDE_INT c;
   11356          239 :           if (known_le (TYPE_VECTOR_SUBPARTS (vectype), def_nunits))
   11357              :             {
   11358          235 :               unsigned HOST_WIDE_INT elsz
   11359          235 :                 = tree_to_uhwi (TYPE_SIZE (TREE_TYPE (TREE_TYPE (def))));
   11360          470 :               tree lowpart = build3 (BIT_FIELD_REF, vectype, def,
   11361          235 :                                      TYPE_SIZE (vectype),
   11362          235 :                                      bitsize_int (eltno * elsz));
   11363          235 :               perm_stmt = gimple_build_assign (perm_dest, lowpart);
   11364              :             }
   11365            4 :           else if (constant_multiple_p (TYPE_VECTOR_SUBPARTS (vectype),
   11366            4 :                                         def_nunits, &c) && c == 2)
   11367              :             {
   11368            4 :               gcc_assert (known_eq (identity_offset, 0U));
   11369            4 :               tree ctor = build_constructor_va (vectype, 2,
   11370              :                                                 NULL_TREE, first_def,
   11371              :                                                 NULL_TREE, second_def);
   11372            4 :               perm_stmt = gimple_build_assign (perm_dest, ctor);
   11373              :             }
   11374              :           else
   11375            0 :             gcc_unreachable ();
   11376              :         }
   11377              :       else
   11378              :         {
   11379              :           /* We need a copy here in case the def was external.  */
   11380         3004 :           gcc_assert (known_eq (eltno, 0U));
   11381         3004 :           perm_stmt = gimple_build_assign (perm_dest, def);
   11382              :         }
   11383              :     }
   11384        31246 :   vect_finish_stmt_generation (vinfo, NULL, perm_stmt, gsi);
   11385              :   /* Store the vector statement in NODE.  */
   11386        31246 :   node->push_vec_def (perm_stmt);
   11387        31246 : }
   11388              : 
   11389              : /* Subroutine of vectorizable_slp_permutation.  Check whether the target
   11390              :    can perform permutation PERM on the (1 or 2) input nodes in CHILDREN.
   11391              :    If GSI is nonnull, emit the permutation there.
   11392              : 
   11393              :    When GSI is null, the only purpose of NODE is to give properties
   11394              :    of the result, such as the vector type and number of SLP lanes.
   11395              :    The node does not need to be a VEC_PERM_EXPR.
   11396              : 
   11397              :    If the target supports the operation, return the number of individual
   11398              :    VEC_PERM_EXPRs needed, otherwise return -1.  Print information to the
   11399              :    dump file if DUMP_P is true.  */
   11400              : 
   11401              : static int
   11402       447096 : vectorizable_slp_permutation_1 (vec_info *vinfo, gimple_stmt_iterator *gsi,
   11403              :                                 slp_tree node, lane_permutation_t &perm,
   11404              :                                 vec<slp_tree> &children, bool dump_p)
   11405              : {
   11406       447096 :   tree vectype = SLP_TREE_VECTYPE (node);
   11407              : 
   11408              :   /* ???  We currently only support all same vector input types
   11409              :      while the SLP IL should really do a concat + select and thus accept
   11410              :      arbitrary mismatches.  */
   11411       447096 :   slp_tree child;
   11412       447096 :   unsigned i;
   11413       447096 :   poly_uint64 nunits = TYPE_VECTOR_SUBPARTS (vectype);
   11414       447096 :   bool repeating_p = multiple_p (nunits, SLP_TREE_LANES (node));
   11415              :   /* True if we're permuting a single input of 2N vectors down
   11416              :      to N vectors.  This case doesn't generalize beyond 2 since
   11417              :      VEC_PERM_EXPR only takes 2 inputs.  */
   11418       447096 :   bool pack_p = false;
   11419              :   /* If we're permuting inputs of N vectors each into X*N outputs,
   11420              :      this is the value of X, otherwise it is 1.  */
   11421       447096 :   unsigned int unpack_factor = 1;
   11422       447096 :   tree op_vectype = NULL_TREE;
   11423       448654 :   FOR_EACH_VEC_ELT (children, i, child)
   11424       448582 :     if (SLP_TREE_VECTYPE (child))
   11425              :       {
   11426              :         op_vectype = SLP_TREE_VECTYPE (child);
   11427              :         break;
   11428              :       }
   11429       447096 :   if (!op_vectype)
   11430           72 :     op_vectype = vectype;
   11431       977418 :   FOR_EACH_VEC_ELT (children, i, child)
   11432              :     {
   11433       530322 :       if ((SLP_TREE_DEF_TYPE (child) != vect_internal_def
   11434         9580 :            && !vect_maybe_update_slp_op_vectype (child, op_vectype))
   11435       530322 :           || !types_compatible_p (SLP_TREE_VECTYPE (child), op_vectype)
   11436      1060644 :           || !types_compatible_p (TREE_TYPE (vectype), TREE_TYPE (op_vectype)))
   11437              :         {
   11438            0 :           if (dump_p)
   11439            0 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11440              :                              "Unsupported vector types in lane permutation\n");
   11441            0 :           return -1;
   11442              :         }
   11443       530322 :       auto op_nunits = TYPE_VECTOR_SUBPARTS (op_vectype);
   11444       530322 :       unsigned int this_unpack_factor;
   11445              :       /* Detect permutations of external, pre-existing vectors.  The external
   11446              :          node's SLP_TREE_LANES stores the total number of units in the vector,
   11447              :          or zero if the vector has variable length.
   11448              : 
   11449              :          We are expected to keep the original VEC_PERM_EXPR for such cases.
   11450              :          There is no repetition to model.  */
   11451       530322 :       if (SLP_TREE_DEF_TYPE (child) == vect_external_def
   11452       530322 :           && SLP_TREE_SCALAR_OPS (child).is_empty ())
   11453              :         repeating_p = false;
   11454              :       /* Check whether the input has twice as many lanes per vector.  */
   11455       523290 :       else if (children.length () == 1
   11456       523290 :                && known_eq (SLP_TREE_LANES (child) * nunits,
   11457              :                             SLP_TREE_LANES (node) * op_nunits * 2))
   11458              :         pack_p = true;
   11459              :       /* Check whether the output has N times as many lanes per vector.  */
   11460       530322 :       else if (constant_multiple_p (SLP_TREE_LANES (node) * op_nunits,
   11461       479459 :                                     SLP_TREE_LANES (child) * nunits,
   11462              :                                     &this_unpack_factor)
   11463       444621 :                && (i == 0 || unpack_factor == this_unpack_factor))
   11464              :         unpack_factor = this_unpack_factor;
   11465              :       else
   11466              :         repeating_p = false;
   11467              :     }
   11468              : 
   11469       894192 :   gcc_assert (perm.length () == SLP_TREE_LANES (node));
   11470              : 
   11471              :   /* Load-lanes permute.  This permute only acts as a forwarder to
   11472              :      select the correct vector def of the load-lanes load which
   11473              :      has the permuted vectors in its vector defs like
   11474              :      { v0, w0, r0, v1, w1, r1 ... } for a ld3.  All costs are
   11475              :      accounted for in the costing for the actual load so we
   11476              :      return zero here.  */
   11477       447096 :   if (node->ldst_lanes)
   11478              :     {
   11479            0 :       gcc_assert (children.length () == 1);
   11480            0 :       if (!gsi)
   11481              :         /* This is a trivial op always supported.  */
   11482              :         return 0;
   11483            0 :       slp_tree child = children[0];
   11484            0 :       unsigned vec_idx = (SLP_TREE_LANE_PERMUTATION (node)[0].second
   11485            0 :                           / SLP_TREE_LANES (node));
   11486            0 :       unsigned vec_num = SLP_TREE_LANES (child) / SLP_TREE_LANES (node);
   11487            0 :       unsigned nvectors = vect_get_num_copies (vinfo, node);
   11488            0 :       for (unsigned i = 0; i < nvectors; ++i)
   11489              :         {
   11490            0 :           tree def = SLP_TREE_VEC_DEFS (child)[i * vec_num  + vec_idx];
   11491            0 :           node->push_vec_def (def);
   11492              :         }
   11493              :       return 0;
   11494              :     }
   11495              : 
   11496              :   /* Set REPEATING_P to true if the permutations are cyclical wrt UNPACK_FACTOR
   11497              :      and if we can generate the vectors in a vector-length agnostic way.
   11498              :      This requires UNPACK_STEP == NUNITS / UNPACK_FACTOR to be known at
   11499              :      compile time.
   11500              : 
   11501              :      The significance of UNPACK_STEP is that, when PACK_P is false,
   11502              :      output vector I operates on a window of UNPACK_STEP elements from each
   11503              :      input, starting at lane UNPACK_STEP * (I % UNPACK_FACTOR).  For example,
   11504              :      when UNPACK_FACTOR is 2, the first output vector operates on lanes
   11505              :      [0, NUNITS / 2 - 1] of each input vector and the second output vector
   11506              :      operates on lanes [NUNITS / 2, NUNITS - 1] of each input vector.
   11507              : 
   11508              :      When REPEATING_P is true, NOUTPUTS holds the total number of outputs
   11509              :      that we actually need to generate.  */
   11510       447096 :   uint64_t noutputs = 0;
   11511       447096 :   poly_uint64 unpack_step = 0;
   11512       447096 :   loop_vec_info linfo = dyn_cast <loop_vec_info> (vinfo);
   11513       182933 :   if (!linfo
   11514       486127 :       || !multiple_p (nunits, unpack_factor, &unpack_step)
   11515       181993 :       || !constant_multiple_p (LOOP_VINFO_VECT_FACTOR (linfo)
   11516       181993 :                                * SLP_TREE_LANES (node), nunits, &noutputs))
   11517              :     repeating_p = false;
   11518              : 
   11519              :   /* We can handle the conditions described for REPEATING_P above for
   11520              :      both variable- and constant-length vectors.  The fallback requires
   11521              :      us to generate every element of every permute vector explicitly,
   11522              :      which is only possible for constant-length permute vectors.
   11523              : 
   11524              :      Set:
   11525              : 
   11526              :      - NPATTERNS and NELTS_PER_PATTERN to the encoding of the permute
   11527              :        mask vectors that we want to build.
   11528              : 
   11529              :      - NCOPIES to the number of copies of PERM that we need in order
   11530              :        to build the necessary permute mask vectors.  */
   11531       181993 :   uint64_t npatterns;
   11532       181993 :   unsigned nelts_per_pattern;
   11533       181993 :   uint64_t ncopies;
   11534       181993 :   if (repeating_p)
   11535              :     {
   11536              :       /* We need permute mask vectors that have the form:
   11537              : 
   11538              :            { X1, ..., Xn, X1 + n, ..., Xn + n, X1 + 2n, ..., Xn + 2n, ... }
   11539              : 
   11540              :          In other words, the original n-element permute in PERM is
   11541              :          "unrolled" to fill a full vector.  The stepped vector encoding
   11542              :          that we use for permutes requires 3n elements.  */
   11543       142962 :       npatterns = SLP_TREE_LANES (node);
   11544       142962 :       nelts_per_pattern = ncopies = 3;
   11545              :     }
   11546              :   else
   11547              :     {
   11548              :       /* Calculate every element of every permute mask vector explicitly,
   11549              :          instead of relying on the pattern described above.  */
   11550       304134 :       if (!nunits.is_constant (&npatterns)
   11551       304134 :           || !TYPE_VECTOR_SUBPARTS (op_vectype).is_constant ())
   11552              :         {
   11553              :           if (dump_p)
   11554              :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11555              :                              "unsupported permutation %p on variable-length"
   11556              :                              " vectors\n", (void *) node);
   11557              :           return -1;
   11558              :         }
   11559       304134 :       nelts_per_pattern = ncopies = 1;
   11560       304134 :       if (linfo && !LOOP_VINFO_VECT_FACTOR (linfo).is_constant (&ncopies))
   11561              :         {
   11562              :           if (dump_p)
   11563              :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11564              :                              "unsupported permutation %p for variable VF\n",
   11565              :                              (void *) node);
   11566              :           return -1;
   11567              :         }
   11568              :       pack_p = false;
   11569              :       unpack_factor = 1;
   11570              :     }
   11571       447096 :   unsigned olanes = unpack_factor * ncopies * SLP_TREE_LANES (node);
   11572       447096 :   gcc_assert (repeating_p || multiple_p (olanes, nunits));
   11573              : 
   11574              :   /* Compute the { { SLP operand, vector index}, lane } permutation sequence
   11575              :      from the { SLP operand, scalar lane } permutation as recorded in the
   11576              :      SLP node as intermediate step.  This part should already work
   11577              :      with SLP children with arbitrary number of lanes.  */
   11578       447096 :   auto_vec<std::pair<std::pair<unsigned, unsigned>, poly_uint64>> vperm;
   11579       447096 :   auto_vec<poly_uint64> active_lane;
   11580       447096 :   vperm.create (olanes);
   11581       447096 :   active_lane.safe_grow_cleared (children.length (), true);
   11582       902462 :   for (unsigned int ui = 0; ui < unpack_factor; ++ui)
   11583              :     {
   11584      2004408 :       for (unsigned j = 0; j < children.length (); ++j)
   11585       546838 :         active_lane[j] = ui * unpack_step;
   11586      1311102 :       for (unsigned i = 0; i < ncopies; ++i)
   11587              :         {
   11588      5343730 :           for (unsigned pi = 0; pi < perm.length (); ++pi)
   11589              :             {
   11590      1816129 :               std::pair<unsigned, unsigned> p = perm[pi];
   11591      1816129 :               tree vtype = SLP_TREE_VECTYPE (children[p.first]);
   11592      1816129 :               if (repeating_p)
   11593       834009 :                 vperm.quick_push ({{p.first, 0},
   11594       834009 :                                    p.second + active_lane[p.first]});
   11595              :               else
   11596              :                 {
   11597              :                   /* We checked above that the vectors are constant-length.  */
   11598       982120 :                   unsigned vnunits = TYPE_VECTOR_SUBPARTS (vtype)
   11599       982120 :                     .to_constant ();
   11600       982120 :                   unsigned lane = active_lane[p.first].to_constant ();
   11601       982120 :                   unsigned vi = (lane + p.second) / vnunits;
   11602       982120 :                   unsigned vl = (lane + p.second) % vnunits;
   11603       982120 :                   vperm.quick_push ({{p.first, vi}, vl});
   11604              :                 }
   11605              :             }
   11606              :           /* Advance to the next group.  */
   11607      1867336 :           for (unsigned j = 0; j < children.length (); ++j)
   11608      1011600 :             active_lane[j] += SLP_TREE_LANES (children[j]);
   11609              :         }
   11610              :     }
   11611              : 
   11612       447096 :   if (dump_p)
   11613              :     {
   11614         8985 :       dump_printf_loc (MSG_NOTE, vect_location,
   11615              :                        "vectorizing permutation %p", (void *)node);
   11616        32518 :       for (unsigned i = 0; i < perm.length (); ++i)
   11617        23533 :         dump_printf (MSG_NOTE, " op%u[%u]", perm[i].first, perm[i].second);
   11618         8985 :       if (repeating_p)
   11619         7586 :         dump_printf (MSG_NOTE, " (repeat %d)", SLP_TREE_LANES (node));
   11620         8985 :       dump_printf (MSG_NOTE, "\n");
   11621         8985 :       dump_printf_loc (MSG_NOTE, vect_location, "as");
   11622        90546 :       for (unsigned i = 0; i < vperm.length (); ++i)
   11623              :         {
   11624        81561 :           if (i != 0
   11625        81561 :               && (repeating_p
   11626        55369 :                   ? multiple_p (i, npatterns)
   11627        60659 :                   : multiple_p (i, TYPE_VECTOR_SUBPARTS (vectype))))
   11628        24399 :             dump_printf (MSG_NOTE, ",");
   11629        81561 :           dump_printf (MSG_NOTE, " vops%u[%u][",
   11630        81561 :                        vperm[i].first.first, vperm[i].first.second);
   11631        81561 :           dump_dec (MSG_NOTE, vperm[i].second);
   11632        81561 :           dump_printf (MSG_NOTE, "]");
   11633              :         }
   11634         8985 :       dump_printf (MSG_NOTE, "\n");
   11635              :     }
   11636              : 
   11637              :   /* We can only handle two-vector permutes, everything else should
   11638              :      be lowered on the SLP level.  The following is closely inspired
   11639              :      by vect_transform_slp_perm_load and is supposed to eventually
   11640              :      replace it.
   11641              :      ???   As intermediate step do code-gen in the SLP tree representation
   11642              :      somehow?  */
   11643       447096 :   std::pair<unsigned, unsigned> first_vec = std::make_pair (-1U, -1U);
   11644       447096 :   std::pair<unsigned, unsigned> second_vec = std::make_pair (-1U, -1U);
   11645       447096 :   unsigned int index = 0;
   11646       447096 :   poly_uint64 mask_element;
   11647       447096 :   vec_perm_builder mask;
   11648       447096 :   mask.new_vector (nunits, npatterns, nelts_per_pattern);
   11649       447096 :   unsigned int count = mask.encoded_nelts ();
   11650       447096 :   mask.quick_grow (count);
   11651       447096 :   vec_perm_indices indices;
   11652       447096 :   unsigned nperms = 0;
   11653              :   /* When REPEATING_P is true, we only have UNPACK_FACTOR unique permute
   11654              :      vectors to check during analysis, but we need to generate NOUTPUTS
   11655              :      vectors during transformation.  */
   11656       447096 :   unsigned total_nelts = olanes;
   11657       447096 :   unsigned process_nelts = olanes;
   11658       447096 :   if (repeating_p)
   11659              :     {
   11660       142962 :       total_nelts = (total_nelts / unpack_factor) * noutputs;
   11661       142962 :       if (gsi)
   11662         9815 :         process_nelts = total_nelts;
   11663              :     }
   11664       447096 :   unsigned last_ei = (total_nelts - 1) % process_nelts;
   11665      2271786 :   for (unsigned i = 0; i < process_nelts; ++i)
   11666              :     {
   11667              :       /* VI is the input vector index when generating code for REPEATING_P.  */
   11668      1832843 :       unsigned vi = i / olanes * (pack_p ? 2 : 1);
   11669      1832843 :       unsigned ei = i % olanes;
   11670      1832843 :       mask_element = vperm[ei].second;
   11671      1832843 :       if (pack_p)
   11672              :         {
   11673              :           /* In this case, we have N outputs and the single child provides 2N
   11674              :              inputs.  Output X permutes inputs 2X and 2X+1.
   11675              : 
   11676              :              The mask indices are taken directly from the SLP permutation node.
   11677              :              Index X selects from the first vector if (X / NUNITS) % 2 == 0;
   11678              :              X selects from the second vector otherwise.  These conditions
   11679              :              are only known at compile time for constant-length vectors.  */
   11680              :           first_vec = std::make_pair (0, 0);
   11681              :           second_vec = std::make_pair (0, 1);
   11682              :         }
   11683      1663415 :       else if (first_vec.first == -1U
   11684      1663415 :                || first_vec == vperm[ei].first)
   11685      1431265 :         first_vec = vperm[ei].first;
   11686       232150 :       else if (second_vec.first == -1U
   11687       232150 :                || second_vec == vperm[ei].first)
   11688              :         {
   11689       231763 :           second_vec = vperm[ei].first;
   11690       231763 :           mask_element += nunits;
   11691              :         }
   11692              :       else
   11693              :         {
   11694          387 :           if (dump_p)
   11695            7 :             dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
   11696              :                              "permutation requires at "
   11697              :                              "least three vectors\n");
   11698          387 :           gcc_assert (!gsi);
   11699              :           return -1;
   11700              :         }
   11701              : 
   11702      1832456 :       mask[index++] = mask_element;
   11703              : 
   11704      1832456 :       if (index == count)
   11705              :         {
   11706       588238 :           indices.new_vector (mask, second_vec.first == -1U ? 1 : 2,
   11707              :                               TYPE_VECTOR_SUBPARTS (op_vectype));
   11708       588238 :           bool identity_p = (indices.series_p (0, 1, mask[0], 1)
   11709       882709 :                              && constant_multiple_p (mask[0], nunits));
   11710       588238 :           machine_mode vmode = TYPE_MODE (vectype);
   11711       588238 :           machine_mode op_vmode = TYPE_MODE (op_vectype);
   11712       588238 :           unsigned HOST_WIDE_INT c;
   11713       588238 :           if ((!identity_p
   11714       544416 :                && !can_vec_perm_const_p (vmode, op_vmode, indices))
   11715       588238 :               || (identity_p
   11716        43822 :                   && !known_le (nunits,
   11717              :                                 TYPE_VECTOR_SUBPARTS (op_vectype))
   11718         7774 :                   && (!constant_multiple_p (nunits,
   11719            8 :                                             TYPE_VECTOR_SUBPARTS (op_vectype),
   11720            8 :                                             &c) || c != 2)))
   11721              :             {
   11722         7766 :               if (dump_p)
   11723              :                 {
   11724          152 :                   dump_printf_loc (MSG_MISSED_OPTIMIZATION,
   11725              :                                    vect_location,
   11726              :                                    "unsupported vect permute { ");
   11727         1586 :                   for (i = 0; i < count; ++i)
   11728              :                     {
   11729         1434 :                       dump_dec (MSG_MISSED_OPTIMIZATION, mask[i]);
   11730         1434 :                       dump_printf (MSG_MISSED_OPTIMIZATION, " ");
   11731              :                     }
   11732          152 :                   dump_printf (MSG_MISSED_OPTIMIZATION, "}\n");
   11733              :                 }
   11734         7766 :               gcc_assert (!gsi);
   11735         8153 :               return -1;
   11736              :             }
   11737              : 
   11738       580472 :           if (!identity_p)
   11739       536650 :             nperms += CEIL (total_nelts, process_nelts) - (ei > last_ei);
   11740       580472 :           if (gsi)
   11741              :             {
   11742        31246 :               if (second_vec.first == -1U)
   11743         6998 :                 second_vec = first_vec;
   11744              : 
   11745        31246 :               slp_tree
   11746        31246 :                 first_node = children[first_vec.first],
   11747        31246 :                 second_node = children[second_vec.first];
   11748              : 
   11749        31246 :               tree mask_vec = NULL_TREE;
   11750        31246 :               if (!identity_p)
   11751        28003 :                 mask_vec = vect_gen_perm_mask_checked (vectype, indices);
   11752              : 
   11753        31246 :               tree first_def
   11754        31246 :                 = vect_get_slp_vect_def (first_node, first_vec.second + vi);
   11755        31246 :               tree second_def
   11756        31246 :                 = vect_get_slp_vect_def (second_node, second_vec.second + vi);
   11757        31246 :               vect_add_slp_permutation (vinfo, gsi, node, first_def,
   11758        31246 :                                         second_def, mask_vec, mask[0]);
   11759              :             }
   11760              : 
   11761              :           index = 0;
   11762              :           first_vec = std::make_pair (-1U, -1U);
   11763              :           second_vec = std::make_pair (-1U, -1U);
   11764              :         }
   11765              :     }
   11766              : 
   11767       438943 :   return nperms;
   11768       447096 : }
   11769              : 
   11770              : /* Vectorize the SLP permutations in NODE as specified
   11771              :    in SLP_TREE_LANE_PERMUTATION which is a vector of pairs of SLP
   11772              :    child number and lane number.
   11773              :    Interleaving of two two-lane two-child SLP subtrees (not supported):
   11774              :      [ { 0, 0 }, { 1, 0 }, { 0, 1 }, { 1, 1 } ]
   11775              :    A blend of two four-lane two-child SLP subtrees:
   11776              :      [ { 0, 0 }, { 1, 1 }, { 0, 2 }, { 1, 3 } ]
   11777              :    Highpart of a four-lane one-child SLP subtree (not supported):
   11778              :      [ { 0, 2 }, { 0, 3 } ]
   11779              :    Where currently only a subset is supported by code generating below.  */
   11780              : 
   11781              : bool
   11782       137507 : vectorizable_slp_permutation (vec_info *vinfo, gimple_stmt_iterator *gsi,
   11783              :                               slp_tree node, stmt_vector_for_cost *cost_vec)
   11784              : {
   11785       137507 :   tree vectype = SLP_TREE_VECTYPE (node);
   11786       137507 :   lane_permutation_t &perm = SLP_TREE_LANE_PERMUTATION (node);
   11787       137507 :   int nperms = vectorizable_slp_permutation_1 (vinfo, gsi, node, perm,
   11788       137507 :                                                SLP_TREE_CHILDREN (node),
   11789              :                                                dump_enabled_p ());
   11790       137507 :   if (nperms < 0)
   11791              :     return false;
   11792              : 
   11793       136208 :   if (!gsi && nperms != 0)
   11794       114317 :     record_stmt_cost (cost_vec, nperms, vec_perm, node, vectype, 0, vect_body);
   11795              : 
   11796              :   return true;
   11797              : }
   11798              : 
   11799              : /* Vectorize SLP NODE.  */
   11800              : 
   11801              : static void
   11802      1487738 : vect_schedule_slp_node (vec_info *vinfo,
   11803              :                         slp_tree node, slp_instance instance)
   11804              : {
   11805      1487738 :   gimple_stmt_iterator si;
   11806      1487738 :   int i;
   11807      1487738 :   slp_tree child;
   11808              : 
   11809              :   /* Vectorize externals and constants.  */
   11810      1487738 :   if (SLP_TREE_DEF_TYPE (node) == vect_constant_def
   11811      1487738 :       || SLP_TREE_DEF_TYPE (node) == vect_external_def)
   11812              :     {
   11813              :       /* ???  vectorizable_shift can end up using a scalar operand which is
   11814              :          currently denoted as !SLP_TREE_VECTYPE.  No need to vectorize the
   11815              :          node in this case.  */
   11816       504425 :       if (!SLP_TREE_VECTYPE (node))
   11817       504425 :         return;
   11818              : 
   11819              :       /* There are two reasons vector defs might already exist.  The first
   11820              :          is that we are vectorizing an existing vector def.  The second is
   11821              :          when performing BB vectorization shared constant/external nodes
   11822              :          are not split apart during partitioning so during the code-gen
   11823              :          DFS walk we can end up visiting them twice.  */
   11824       497282 :       if (! SLP_TREE_VEC_DEFS (node).exists ())
   11825       496541 :         vect_create_constant_vectors (vinfo, node);
   11826       497282 :       return;
   11827              :     }
   11828              : 
   11829       983313 :   stmt_vec_info stmt_info = SLP_TREE_REPRESENTATIVE (node);
   11830              : 
   11831       983313 :   gcc_assert (SLP_TREE_VEC_DEFS (node).is_empty ());
   11832       983313 :   if (SLP_TREE_VECTYPE (node))
   11833       983307 :     SLP_TREE_VEC_DEFS (node).create (vect_get_num_copies (vinfo, node));
   11834              : 
   11835       983313 :   if (!SLP_TREE_PERMUTE_P (node) && STMT_VINFO_DATA_REF (stmt_info))
   11836              :     {
   11837              :       /* Vectorized loads go before the first scalar load to make it
   11838              :          ready early, vectorized stores go before the last scalar
   11839              :          stmt which is where all uses are ready.  */
   11840       720848 :       stmt_vec_info last_stmt_info = NULL;
   11841       720848 :       if (DR_IS_READ (STMT_VINFO_DATA_REF (stmt_info)))
   11842       168028 :         last_stmt_info = vect_find_first_scalar_stmt_in_slp (node);
   11843              :       else /* DR_IS_WRITE */
   11844       552820 :         last_stmt_info = vect_find_last_scalar_stmt_in_slp (node);
   11845       720848 :       si = gsi_for_stmt (last_stmt_info->stmt);
   11846       720848 :     }
   11847       262465 :   else if (!SLP_TREE_PERMUTE_P (node)
   11848       246080 :            && (SLP_TREE_TYPE (node) == cycle_phi_info_type
   11849              :                || SLP_TREE_TYPE (node) == induc_vec_info_type
   11850              :                || SLP_TREE_TYPE (node) == phi_info_type))
   11851              :     {
   11852              :       /* For PHI node vectorization we do not use the insertion iterator.  */
   11853        54396 :       si = gsi_none ();
   11854              :     }
   11855              :   else
   11856              :     {
   11857              :       /* Emit other stmts after the children vectorized defs which is
   11858              :          earliest possible.  */
   11859              :       gimple *last_stmt = NULL;
   11860              :       bool seen_vector_def = false;
   11861       578758 :       FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
   11862       370689 :         if (SLP_TREE_DEF_TYPE (child) == vect_internal_def)
   11863              :           {
   11864              :             /* For fold-left reductions we are retaining the scalar
   11865              :                reduction PHI but we still have SLP_TREE_NUM_VEC_STMTS
   11866              :                set so the representation isn't perfect.  Resort to the
   11867              :                last scalar def here.  */
   11868       297217 :             if (SLP_TREE_VEC_DEFS (child).is_empty ())
   11869              :               {
   11870          946 :                 gcc_assert (SLP_TREE_TYPE (child) == cycle_phi_info_type);
   11871          946 :                 gphi *phi = as_a <gphi *>
   11872          946 :                               (vect_find_last_scalar_stmt_in_slp (child)->stmt);
   11873          946 :                 if (!last_stmt)
   11874              :                   last_stmt = phi;
   11875          727 :                 else if (vect_stmt_dominates_stmt_p (last_stmt, phi))
   11876              :                   last_stmt = phi;
   11877          716 :                 else if (vect_stmt_dominates_stmt_p (phi, last_stmt))
   11878              :                   ;
   11879              :                 else
   11880            0 :                   gcc_unreachable ();
   11881              :               }
   11882              :             /* We are emitting all vectorized stmts in the same place and
   11883              :                the last one is the last.
   11884              :                ???  Unless we have a load permutation applied and that
   11885              :                figures to re-use an earlier generated load.  */
   11886              :             unsigned j;
   11887              :             tree vdef;
   11888       702613 :             FOR_EACH_VEC_ELT (SLP_TREE_VEC_DEFS (child), j, vdef)
   11889              :               {
   11890       405396 :                 gimple *vstmt = SSA_NAME_DEF_STMT (vdef);
   11891       405396 :                 if (!last_stmt)
   11892              :                   last_stmt = vstmt;
   11893       208007 :                 else if (vect_stmt_dominates_stmt_p (last_stmt, vstmt))
   11894              :                   last_stmt = vstmt;
   11895        45754 :                 else if (vect_stmt_dominates_stmt_p (vstmt, last_stmt))
   11896              :                   ;
   11897              :                 else
   11898            0 :                   gcc_unreachable ();
   11899              :               }
   11900              :           }
   11901        73472 :         else if (!SLP_TREE_VECTYPE (child))
   11902              :           {
   11903              :             /* For externals we use unvectorized at all scalar defs.  */
   11904              :             unsigned j;
   11905              :             tree def;
   11906        15553 :             FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_OPS (child), j, def)
   11907         9039 :               if (TREE_CODE (def) == SSA_NAME
   11908         9039 :                   && !SSA_NAME_IS_DEFAULT_DEF (def))
   11909              :                 {
   11910          407 :                   gimple *stmt = SSA_NAME_DEF_STMT (def);
   11911          407 :                   if (gimple_uid (stmt) == -1u)
   11912              :                     /* If the stmt is not inside the region do not
   11913              :                        use it as possible insertion point.  */
   11914              :                     ;
   11915          397 :                   else if (!last_stmt)
   11916              :                     last_stmt = stmt;
   11917          363 :                   else if (vect_stmt_dominates_stmt_p (last_stmt, stmt))
   11918              :                     last_stmt = stmt;
   11919          159 :                   else if (vect_stmt_dominates_stmt_p (stmt, last_stmt))
   11920              :                     ;
   11921              :                   else
   11922            0 :                     gcc_unreachable ();
   11923              :                 }
   11924              :           }
   11925              :         else
   11926              :           {
   11927              :             /* For externals we have to look at all defs since their
   11928              :                insertion place is decided per vector.  But beware
   11929              :                of pre-existing vectors where we need to make sure
   11930              :                we do not insert before the region boundary.  */
   11931        66958 :             if (SLP_TREE_SCALAR_OPS (child).is_empty ()
   11932          539 :                 && !vinfo->lookup_def (SLP_TREE_VEC_DEFS (child)[0]))
   11933              :               seen_vector_def = true;
   11934              :             else
   11935              :               {
   11936              :                 unsigned j;
   11937              :                 tree vdef;
   11938       532364 :                 FOR_EACH_VEC_ELT (SLP_TREE_VEC_DEFS (child), j, vdef)
   11939        94834 :                   if (TREE_CODE (vdef) == SSA_NAME
   11940        94834 :                       && !SSA_NAME_IS_DEFAULT_DEF (vdef))
   11941              :                     {
   11942        19614 :                       gimple *vstmt = SSA_NAME_DEF_STMT (vdef);
   11943        19614 :                       if (!last_stmt)
   11944              :                         last_stmt = vstmt;
   11945        10906 :                       else if (vect_stmt_dominates_stmt_p (last_stmt, vstmt))
   11946              :                         last_stmt = vstmt;
   11947         8765 :                       else if (vect_stmt_dominates_stmt_p (vstmt, last_stmt))
   11948              :                         ;
   11949              :                       else
   11950            0 :                         gcc_unreachable ();
   11951              :                     }
   11952              :               }
   11953              :           }
   11954              :       /* This can happen when all children are pre-existing vectors or
   11955              :          constants.  */
   11956       208069 :       if (!last_stmt)
   11957         1719 :         last_stmt = vect_find_first_scalar_stmt_in_slp (node)->stmt;
   11958         1719 :       if (!last_stmt)
   11959              :         {
   11960            0 :           gcc_assert (seen_vector_def);
   11961            0 :           si = gsi_after_labels (vinfo->bbs[0]);
   11962              :         }
   11963       208069 :       else if (is_ctrl_altering_stmt (last_stmt))
   11964              :         {
   11965              :           /* We split regions to vectorize at control altering stmts
   11966              :              with a definition so this must be an external which
   11967              :              we can insert at the start of the region.  */
   11968            0 :           si = gsi_after_labels (vinfo->bbs[0]);
   11969              :         }
   11970       208069 :       else if (is_a <bb_vec_info> (vinfo)
   11971        18183 :                && !SLP_TREE_PERMUTE_P (node)
   11972        16799 :                && gimple_bb (last_stmt) != gimple_bb (stmt_info->stmt)
   11973       209598 :                && gimple_could_trap_p (stmt_info->stmt))
   11974              :         {
   11975              :           /* We've constrained possibly trapping operations to all come
   11976              :              from the same basic-block, if vectorized defs would allow earlier
   11977              :              scheduling still force vectorized stmts to the original block.
   11978              :              This is only necessary for BB vectorization since for loop vect
   11979              :              all operations are in a single BB and scalar stmt based
   11980              :              placement doesn't play well with epilogue vectorization.  */
   11981           86 :           gcc_assert (dominated_by_p (CDI_DOMINATORS,
   11982              :                                       gimple_bb (stmt_info->stmt),
   11983              :                                       gimple_bb (last_stmt)));
   11984           86 :           si = gsi_after_labels (gimple_bb (stmt_info->stmt));
   11985              :         }
   11986       207983 :       else if (is_a <gphi *> (last_stmt))
   11987        14509 :         si = gsi_after_labels (gimple_bb (last_stmt));
   11988              :       else
   11989              :         {
   11990       193474 :           si = gsi_for_stmt (last_stmt);
   11991       193474 :           gsi_next (&si);
   11992              : 
   11993       193474 :           if (auto loop_vinfo = dyn_cast <loop_vec_info> (vinfo))
   11994              :             {
   11995              :               /* Avoid scheduling stmts to random places in the CFG, any
   11996              :                  stmt dominance check we performed is possibly wrong as UIDs
   11997              :                  are not initialized for all of the function for loop
   11998              :                  vectorization.  Instead append to the loop preheader.  */
   11999       175611 :               if ((LOOP_VINFO_LOOP (loop_vinfo)->header
   12000       175611 :                    != gimple_bb (last_stmt))
   12001       178806 :                   && dominated_by_p (CDI_DOMINATORS,
   12002              :                                      LOOP_VINFO_LOOP (loop_vinfo)->header,
   12003         3195 :                                      gimple_bb (last_stmt)))
   12004         1362 :                 si = gsi_end_bb (loop_preheader_edge
   12005          681 :                                    (LOOP_VINFO_LOOP (loop_vinfo))->src);
   12006              :               /* Avoid scheduling internal defs outside of the loop when
   12007              :                  we might have only implicitly tracked loop mask/len defs.  */
   12008           74 :               if (LOOP_VINFO_FULLY_MASKED_P (loop_vinfo)
   12009       175611 :                   || LOOP_VINFO_FULLY_WITH_LENGTH_P (loop_vinfo))
   12010              :                 {
   12011           74 :                   gimple_stmt_iterator si2
   12012           74 :                     = gsi_after_labels (LOOP_VINFO_LOOP (loop_vinfo)->header);
   12013           74 :                   if ((gsi_end_p (si2)
   12014            0 :                        && (LOOP_VINFO_LOOP (loop_vinfo)->header
   12015            0 :                            != gimple_bb (last_stmt))
   12016            0 :                        && dominated_by_p (CDI_DOMINATORS,
   12017              :                                           LOOP_VINFO_LOOP (loop_vinfo)->header,
   12018            0 :                                           gimple_bb (last_stmt)))
   12019           74 :                       || (!gsi_end_p (si2)
   12020           74 :                           && last_stmt != *si2
   12021           72 :                           && vect_stmt_dominates_stmt_p (last_stmt, *si2)))
   12022            3 :                     si = si2;
   12023              :                 }
   12024              :             }
   12025              :         }
   12026              :     }
   12027              : 
   12028       983313 :   if (dump_enabled_p ())
   12029              :     {
   12030        71754 :       if (stmt_info)
   12031        71702 :         dump_printf_loc (MSG_NOTE, vect_location,
   12032              :                          "------>vectorizing SLP node starting from: %G",
   12033              :                          stmt_info->stmt);
   12034              :       else
   12035              :         {
   12036           52 :           dump_printf_loc (MSG_NOTE, vect_location,
   12037              :                            "------>vectorizing SLP node:\n");
   12038           52 :           vect_print_slp_tree (MSG_NOTE, vect_location, node);
   12039              :         }
   12040              :     }
   12041       983313 :   vect_transform_stmt (vinfo, stmt_info, &si, node, instance);
   12042              : }
   12043              : 
   12044              : /* Replace scalar calls from SLP node NODE with setting of their lhs to zero.
   12045              :    For loop vectorization this is done in vectorizable_call, but for SLP
   12046              :    it needs to be deferred until end of vect_schedule_slp, because multiple
   12047              :    SLP instances may refer to the same scalar stmt.  */
   12048              : 
   12049              : static void
   12050       603369 : vect_remove_slp_scalar_calls (vec_info *vinfo,
   12051              :                               slp_tree node, hash_set<slp_tree> &visited)
   12052              : {
   12053       603369 :   gimple *new_stmt;
   12054       603369 :   gimple_stmt_iterator gsi;
   12055       603369 :   tree lhs;
   12056              : 
   12057       603369 :   if (!node || SLP_TREE_DEF_TYPE (node) != vect_internal_def)
   12058       188881 :     return;
   12059              : 
   12060       458155 :   if (visited.add (node))
   12061              :     return;
   12062              : 
   12063      1544912 :   for (auto child : SLP_TREE_CHILDREN (node))
   12064       513106 :     vect_remove_slp_scalar_calls (vinfo, child, visited);
   12065              : 
   12066      1722211 :   for (auto stmt_info : SLP_TREE_SCALAR_STMTS (node))
   12067              :     {
   12068       487025 :       if (!stmt_info)
   12069         3978 :         continue;
   12070       483047 :       stmt_info = vect_orig_stmt (stmt_info);
   12071       483047 :       gcall *stmt = dyn_cast <gcall *> (stmt_info->stmt);
   12072         5157 :       if (!stmt || gimple_bb (stmt) == NULL)
   12073       477934 :         continue;
   12074         5113 :       lhs = gimple_call_lhs (stmt);
   12075         5113 :       if (lhs)
   12076         4530 :         new_stmt = gimple_build_assign (lhs, build_zero_cst (TREE_TYPE (lhs)));
   12077              :       else
   12078          583 :         new_stmt = gimple_build_nop ();
   12079         5113 :       unlink_stmt_vdef (stmt_info->stmt);
   12080         5113 :       gsi = gsi_for_stmt (stmt);
   12081         5113 :       vinfo->replace_stmt (&gsi, stmt_info, new_stmt);
   12082         5113 :       if (lhs)
   12083         4530 :         SSA_NAME_DEF_STMT (lhs) = new_stmt;
   12084              :     }
   12085              : }
   12086              : 
   12087              : static void
   12088        90263 : vect_remove_slp_scalar_calls (vec_info *vinfo, slp_tree node)
   12089              : {
   12090        90263 :   hash_set<slp_tree> visited;
   12091        90263 :   vect_remove_slp_scalar_calls (vinfo, node, visited);
   12092        90263 : }
   12093              : 
   12094              : /* Vectorize the instance root.  */
   12095              : 
   12096              : void
   12097        11215 : vectorize_slp_instance_root_stmt (vec_info *vinfo, slp_tree node, slp_instance instance)
   12098              : {
   12099        11215 :   gassign *rstmt = NULL;
   12100              : 
   12101        11215 :   if (instance->kind == slp_inst_kind_ctor)
   12102              :     {
   12103         5467 :       if (SLP_TREE_VEC_DEFS (node).length () == 1)
   12104              :         {
   12105         5422 :           tree vect_lhs = SLP_TREE_VEC_DEFS (node)[0];
   12106         5422 :           tree root_lhs = gimple_get_lhs (instance->root_stmts[0]->stmt);
   12107         5422 :           if (!useless_type_conversion_p (TREE_TYPE (root_lhs),
   12108         5422 :                                           TREE_TYPE (vect_lhs)))
   12109            0 :             vect_lhs = build1 (VIEW_CONVERT_EXPR, TREE_TYPE (root_lhs),
   12110              :                                vect_lhs);
   12111         5422 :           rstmt = gimple_build_assign (root_lhs, vect_lhs);
   12112              :         }
   12113              :       else
   12114              :         {
   12115           45 :           gcc_assert (SLP_TREE_VEC_DEFS (node).length () > 1);
   12116           45 :           tree child_def;
   12117           45 :           int j;
   12118           45 :           vec<constructor_elt, va_gc> *v;
   12119           45 :           vec_alloc (v, SLP_TREE_VEC_DEFS (node).length ());
   12120              : 
   12121              :           /* A CTOR can handle V16HI composition from VNx8HI so we
   12122              :              do not need to convert vector elements if the types
   12123              :              do not match.  */
   12124          135 :           FOR_EACH_VEC_ELT (SLP_TREE_VEC_DEFS (node), j, child_def)
   12125           90 :             CONSTRUCTOR_APPEND_ELT (v, NULL_TREE, child_def);
   12126           45 :           tree lhs = gimple_get_lhs (instance->root_stmts[0]->stmt);
   12127           45 :           tree rtype
   12128           45 :             = TREE_TYPE (gimple_assign_rhs1 (instance->root_stmts[0]->stmt));
   12129           45 :           tree r_constructor = build_constructor (rtype, v);
   12130           45 :           rstmt = gimple_build_assign (lhs, r_constructor);
   12131              :         }
   12132              :     }
   12133         5748 :   else if (instance->kind == slp_inst_kind_bb_reduc)
   12134              :     {
   12135              :       /* Largely inspired by reduction chain epilogue handling in
   12136              :          vect_create_epilog_for_reduction.  */
   12137         4159 :       vec<tree> vec_defs = vNULL;
   12138         4159 :       vect_get_slp_defs (node, &vec_defs);
   12139         4159 :       enum tree_code reduc_code
   12140         4159 :         = gimple_assign_rhs_code (instance->root_stmts[0]->stmt);
   12141              :       /* ???  We actually have to reflect signs somewhere.  */
   12142         4159 :       if (reduc_code == MINUS_EXPR)
   12143            0 :         reduc_code = PLUS_EXPR;
   12144         4159 :       gimple_seq epilogue = NULL;
   12145              :       /* We may end up with more than one vector result, reduce them
   12146              :          to one vector.  */
   12147         4159 :       tree vec_def = vec_defs[0];
   12148         4159 :       tree vectype = TREE_TYPE (vec_def);
   12149         4159 :       tree compute_vectype = vectype;
   12150         4159 :       bool pun_for_overflow_p = (ANY_INTEGRAL_TYPE_P (vectype)
   12151         3964 :                                  && TYPE_OVERFLOW_UNDEFINED (vectype)
   12152         6936 :                                  && operation_can_overflow (reduc_code));
   12153         2630 :       if (pun_for_overflow_p)
   12154              :         {
   12155         2630 :           compute_vectype = unsigned_type_for (vectype);
   12156         2630 :           vec_def = gimple_build (&epilogue, VIEW_CONVERT_EXPR,
   12157              :                                   compute_vectype, vec_def);
   12158              :         }
   12159         6537 :       for (unsigned i = 1; i < vec_defs.length (); ++i)
   12160              :         {
   12161         2378 :           tree def = vec_defs[i];
   12162         2378 :           if (pun_for_overflow_p)
   12163         2275 :             def = gimple_build (&epilogue, VIEW_CONVERT_EXPR,
   12164              :                                 compute_vectype, def);
   12165         2378 :           vec_def = gimple_build (&epilogue, reduc_code, compute_vectype,
   12166              :                                   vec_def, def);
   12167              :         }
   12168         4159 :       vec_defs.release ();
   12169              :       /* ???  Support other schemes than direct internal fn.  */
   12170         4159 :       internal_fn reduc_fn;
   12171         4159 :       if (!reduction_fn_for_scalar_code (reduc_code, &reduc_fn)
   12172         4159 :           || reduc_fn == IFN_LAST)
   12173            0 :         gcc_unreachable ();
   12174         4159 :       tree scalar_def = gimple_build (&epilogue, as_combined_fn (reduc_fn),
   12175         4159 :                                       TREE_TYPE (compute_vectype), vec_def);
   12176         4159 :       if (!SLP_INSTANCE_REMAIN_DEFS (instance).is_empty ())
   12177              :         {
   12178         2557 :           tree rem_def = NULL_TREE;
   12179        11891 :           for (auto def : SLP_INSTANCE_REMAIN_DEFS (instance))
   12180              :             {
   12181         9334 :               def = gimple_convert (&epilogue, TREE_TYPE (scalar_def), def);
   12182         9334 :               if (!rem_def)
   12183              :                 rem_def = def;
   12184              :               else
   12185         6777 :                 rem_def = gimple_build (&epilogue, reduc_code,
   12186         6777 :                                         TREE_TYPE (scalar_def),
   12187              :                                         rem_def, def);
   12188              :             }
   12189         2557 :           scalar_def = gimple_build (&epilogue, reduc_code,
   12190         2557 :                                      TREE_TYPE (scalar_def),
   12191              :                                      scalar_def, rem_def);
   12192              :         }
   12193         4159 :       scalar_def = gimple_convert (&epilogue,
   12194         4159 :                                    TREE_TYPE (vectype), scalar_def);
   12195         4159 :       gimple_stmt_iterator rgsi = gsi_for_stmt (instance->root_stmts[0]->stmt);
   12196         4159 :       gsi_insert_seq_before (&rgsi, epilogue, GSI_SAME_STMT);
   12197         4159 :       gimple_assign_set_rhs_from_tree (&rgsi, scalar_def);
   12198         4159 :       update_stmt (gsi_stmt (rgsi));
   12199         4159 :       return;
   12200              :     }
   12201         1589 :   else if (instance->kind == slp_inst_kind_gcond)
   12202              :     {
   12203              :       /* Only support a single root for now as we can't codegen CFG yet and so we
   12204              :          can't support lane > 1 at this time.  */
   12205         1589 :       gcc_assert (instance->root_stmts.length () == 1);
   12206         1589 :       auto root_stmt_info = instance->root_stmts[0];
   12207         1589 :       auto last_stmt = STMT_VINFO_STMT (vect_orig_stmt (root_stmt_info));
   12208         1589 :       gimple_stmt_iterator rgsi = gsi_for_stmt (last_stmt);
   12209         1589 :       gcc_assert (!SLP_TREE_VEC_DEFS (node).is_empty ());
   12210         1589 :       bool res = vectorizable_early_exit (as_a <loop_vec_info> (vinfo),
   12211              :                                           root_stmt_info, &rgsi, node, NULL);
   12212         1589 :       gcc_assert (res);
   12213         1589 :       return;
   12214              :     }
   12215              :   else
   12216            0 :     gcc_unreachable ();
   12217              : 
   12218         5467 :   gcc_assert (rstmt);
   12219              : 
   12220         5467 :   gimple_stmt_iterator rgsi = gsi_for_stmt (instance->root_stmts[0]->stmt);
   12221         5467 :   gsi_replace (&rgsi, rstmt, true);
   12222              : }
   12223              : 
   12224              : struct slp_scc_info
   12225              : {
   12226              :   bool on_stack;
   12227              :   int dfs;
   12228              :   int lowlink;
   12229              : };
   12230              : 
   12231              : /* Schedule the SLP INSTANCE doing a DFS walk and collecting SCCs.  */
   12232              : 
   12233              : static void
   12234      1487738 : vect_schedule_scc (vec_info *vinfo, slp_tree node, slp_instance instance,
   12235              :                    hash_map<slp_tree, slp_scc_info> &scc_info,
   12236              :                    int &maxdfs, vec<slp_tree> &stack)
   12237              : {
   12238      1487738 :   bool existed_p;
   12239      1487738 :   slp_scc_info *info = &scc_info.get_or_insert (node, &existed_p);
   12240      1487738 :   gcc_assert (!existed_p);
   12241      1487738 :   info->dfs = maxdfs;
   12242      1487738 :   info->lowlink = maxdfs;
   12243      1487738 :   maxdfs++;
   12244              : 
   12245              :   /* Leaf.  */
   12246      1487738 :   if (SLP_TREE_DEF_TYPE (node) != vect_internal_def)
   12247              :     {
   12248       504425 :       info->on_stack = false;
   12249       504425 :       vect_schedule_slp_node (vinfo, node, instance);
   12250      1040677 :       return;
   12251              :     }
   12252              : 
   12253       983313 :   info->on_stack = true;
   12254       983313 :   stack.safe_push (node);
   12255              : 
   12256       983313 :   unsigned i;
   12257       983313 :   slp_tree child;
   12258              :   /* DFS recurse.  */
   12259      2027848 :   FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
   12260              :     {
   12261      1044535 :       if (!child)
   12262        55439 :         continue;
   12263       989096 :       slp_scc_info *child_info = scc_info.get (child);
   12264       989096 :       if (!child_info)
   12265              :         {
   12266       898366 :           vect_schedule_scc (vinfo, child, instance, scc_info, maxdfs, stack);
   12267              :           /* Recursion might have re-allocated the node.  */
   12268       898366 :           info = scc_info.get (node);
   12269       898366 :           child_info = scc_info.get (child);
   12270       898366 :           info->lowlink = MIN (info->lowlink, child_info->lowlink);
   12271              :         }
   12272        90730 :       else if (child_info->on_stack)
   12273        25569 :         info->lowlink = MIN (info->lowlink, child_info->dfs);
   12274              :     }
   12275       983313 :   if (info->lowlink != info->dfs)
   12276              :     return;
   12277              : 
   12278       951486 :   auto_vec<slp_tree, 4> phis_to_fixup;
   12279              : 
   12280              :   /* Singleton.  */
   12281       951486 :   if (stack.last () == node)
   12282              :     {
   12283       927591 :       stack.pop ();
   12284       927591 :       info->on_stack = false;
   12285       927591 :       vect_schedule_slp_node (vinfo, node, instance);
   12286       927591 :       if (!SLP_TREE_PERMUTE_P (node)
   12287       927591 :           && is_a <gphi *> (SLP_TREE_REPRESENTATIVE (node)->stmt))
   12288        30630 :         phis_to_fixup.quick_push (node);
   12289              :     }
   12290              :   else
   12291              :     {
   12292              :       /* SCC.  */
   12293        23895 :       int last_idx = stack.length () - 1;
   12294        55722 :       while (stack[last_idx] != node)
   12295        31827 :         last_idx--;
   12296              :       /* We can break the cycle at PHIs who have at least one child
   12297              :          code generated.  Then we could re-start the DFS walk until
   12298              :          all nodes in the SCC are covered (we might have new entries
   12299              :          for only back-reachable nodes).  But it's simpler to just
   12300              :          iterate and schedule those that are ready.  */
   12301        23895 :       unsigned todo = stack.length () - last_idx;
   12302        24234 :       do
   12303              :         {
   12304       105974 :           for (int idx = stack.length () - 1; idx >= last_idx; --idx)
   12305              :             {
   12306        57506 :               slp_tree entry = stack[idx];
   12307        57506 :               if (!entry)
   12308          956 :                 continue;
   12309        56550 :               bool phi = (!SLP_TREE_PERMUTE_P (entry)
   12310        56550 :                           && is_a <gphi *> (SLP_TREE_REPRESENTATIVE (entry)->stmt));
   12311        56550 :               bool ready = !phi;
   12312       143117 :               FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (entry), i, child)
   12313       111706 :                   if (!child)
   12314              :                     {
   12315        23019 :                       gcc_assert (phi);
   12316              :                       ready = true;
   12317              :                       break;
   12318              :                     }
   12319        88687 :                   else if (scc_info.get (child)->on_stack)
   12320              :                     {
   12321        24089 :                       if (!phi)
   12322              :                         {
   12323              :                           ready = false;
   12324              :                           break;
   12325              :                         }
   12326              :                     }
   12327              :                   else
   12328              :                     {
   12329        64598 :                       if (phi)
   12330              :                         {
   12331              :                           ready = true;
   12332              :                           break;
   12333              :                         }
   12334              :                     }
   12335        33531 :               if (ready)
   12336              :                 {
   12337        55722 :                   vect_schedule_slp_node (vinfo, entry, instance);
   12338        55722 :                   scc_info.get (entry)->on_stack = false;
   12339        55722 :                   stack[idx] = NULL;
   12340        55722 :                   todo--;
   12341        55722 :                   if (phi)
   12342        24341 :                     phis_to_fixup.safe_push (entry);
   12343              :                 }
   12344              :             }
   12345              :         }
   12346        24234 :       while (todo != 0);
   12347              : 
   12348              :       /* Pop the SCC.  */
   12349        23895 :       stack.truncate (last_idx);
   12350              :     }
   12351              : 
   12352              :   /* Now fixup the backedge def of the vectorized PHIs in this SCC.  */
   12353              :   slp_tree phi_node;
   12354      1957943 :   FOR_EACH_VEC_ELT (phis_to_fixup, i, phi_node)
   12355              :     {
   12356        54971 :       gphi *phi = as_a <gphi *> (SLP_TREE_REPRESENTATIVE (phi_node)->stmt);
   12357        54971 :       edge_iterator ei;
   12358        54971 :       edge e;
   12359       173585 :       FOR_EACH_EDGE (e, ei, gimple_bb (phi)->preds)
   12360              :         {
   12361       118614 :           unsigned dest_idx = e->dest_idx;
   12362       118614 :           child = SLP_TREE_CHILDREN (phi_node)[dest_idx];
   12363       118614 :           if (!child || SLP_TREE_DEF_TYPE (child) != vect_internal_def)
   12364        66658 :             continue;
   12365        51956 :           unsigned n = SLP_TREE_VEC_DEFS (phi_node).length ();
   12366              :           /* Simply fill all args.  */
   12367        51956 :           if (STMT_VINFO_DEF_TYPE (SLP_TREE_REPRESENTATIVE (phi_node))
   12368              :               != vect_first_order_recurrence)
   12369       111660 :             for (unsigned i = 0; i < n; ++i)
   12370              :               {
   12371        59749 :                 tree phidef = SLP_TREE_VEC_DEFS (phi_node)[i];
   12372        59749 :                 gphi *phi = as_a <gphi *> (SSA_NAME_DEF_STMT (phidef));
   12373        59749 :                 add_phi_arg (phi, vect_get_slp_vect_def (child, i),
   12374              :                              e, gimple_phi_arg_location (phi, dest_idx));
   12375              :               }
   12376              :           else
   12377              :             {
   12378              :               /* Unless it is a first order recurrence which needs
   12379              :                  args filled in for both the PHI node and the permutes.  */
   12380           45 :               gimple *perm
   12381           45 :                 = SSA_NAME_DEF_STMT (SLP_TREE_VEC_DEFS (phi_node)[0]);
   12382           45 :               gimple *rphi = SSA_NAME_DEF_STMT (gimple_assign_rhs1 (perm));
   12383           45 :               add_phi_arg (as_a <gphi *> (rphi),
   12384              :                            vect_get_slp_vect_def (child, n - 1),
   12385              :                            e, gimple_phi_arg_location (phi, dest_idx));
   12386          127 :               for (unsigned i = 0; i < n; ++i)
   12387              :                 {
   12388           82 :                   gimple *perm
   12389           82 :                     = SSA_NAME_DEF_STMT (SLP_TREE_VEC_DEFS (phi_node)[i]);
   12390           82 :                   if (i > 0)
   12391           37 :                     gimple_assign_set_rhs1 (perm,
   12392              :                                             vect_get_slp_vect_def (child, i - 1));
   12393           82 :                   gimple_assign_set_rhs2 (perm,
   12394              :                                           vect_get_slp_vect_def (child, i));
   12395           82 :                   update_stmt (perm);
   12396              :                 }
   12397              :             }
   12398              :         }
   12399              :     }
   12400       951486 : }
   12401              : 
   12402              : /* Generate vector code for SLP_INSTANCES in the loop/basic block.  */
   12403              : 
   12404              : void
   12405       549708 : vect_schedule_slp (vec_info *vinfo, const vec<slp_instance> &slp_instances)
   12406              : {
   12407       549708 :   slp_instance instance;
   12408       549708 :   unsigned int i;
   12409              : 
   12410       549708 :   hash_map<slp_tree, slp_scc_info> scc_info;
   12411       549708 :   int maxdfs = 0;
   12412      1139197 :   FOR_EACH_VEC_ELT (slp_instances, i, instance)
   12413              :     {
   12414       589489 :       slp_tree node = SLP_INSTANCE_TREE (instance);
   12415       589489 :       if (dump_enabled_p ())
   12416              :         {
   12417        16069 :           dump_printf_loc (MSG_NOTE, vect_location,
   12418              :                            "Vectorizing SLP tree:\n");
   12419              :           /* ???  Dump all?  */
   12420        16069 :           if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ())
   12421          468 :             dump_printf_loc (MSG_NOTE, vect_location, "Root stmt: %G",
   12422          468 :                          SLP_INSTANCE_ROOT_STMTS (instance)[0]->stmt);
   12423        16069 :           vect_print_slp_graph (MSG_NOTE, vect_location,
   12424              :                                 SLP_INSTANCE_TREE (instance));
   12425              :         }
   12426              :       /* Schedule the tree of INSTANCE, scheduling SCCs in a way to
   12427              :          have a PHI be the node breaking the cycle.  */
   12428       589489 :       auto_vec<slp_tree> stack;
   12429       589489 :       if (!scc_info.get (node))
   12430       589372 :         vect_schedule_scc (vinfo, node, instance, scc_info, maxdfs, stack);
   12431              : 
   12432       589489 :       if (!SLP_INSTANCE_ROOT_STMTS (instance).is_empty ())
   12433        11215 :         vectorize_slp_instance_root_stmt (vinfo, node, instance);
   12434              : 
   12435       589489 :       if (dump_enabled_p ())
   12436        16069 :         dump_printf_loc (MSG_NOTE, vect_location,
   12437              :                          "vectorizing stmts using SLP.\n");
   12438       589489 :     }
   12439              : 
   12440      1688905 :   FOR_EACH_VEC_ELT (slp_instances, i, instance)
   12441              :     {
   12442       589489 :       slp_tree root = SLP_INSTANCE_TREE (instance);
   12443       589489 :       stmt_vec_info store_info;
   12444       589489 :       unsigned int j;
   12445              : 
   12446              :       /* Remove scalar call stmts.  Do not do this for basic-block
   12447              :          vectorization as not all uses may be vectorized.
   12448              :          ???  Why should this be necessary?  DCE should be able to
   12449              :          remove the stmts itself.
   12450              :          ???  For BB vectorization we can as well remove scalar
   12451              :          stmts starting from the SLP tree root if they have no
   12452              :          uses.  */
   12453       589489 :       if (is_a <loop_vec_info> (vinfo))
   12454        90263 :         vect_remove_slp_scalar_calls (vinfo, root);
   12455              : 
   12456              :       /* Remove vectorized stores original scalar stmts.  */
   12457      2631974 :       for (j = 0; SLP_TREE_SCALAR_STMTS (root).iterate (j, &store_info); j++)
   12458              :         {
   12459      1489665 :           if (!store_info
   12460      1489651 :               || !STMT_VINFO_DATA_REF (store_info)
   12461      1461707 :               || !DR_IS_WRITE (STMT_VINFO_DATA_REF (store_info)))
   12462              :             break;
   12463              : 
   12464      1452996 :           store_info = vect_orig_stmt (store_info);
   12465              :           /* Free the attached stmt_vec_info and remove the stmt.  */
   12466      1452996 :           vinfo->remove_stmt (store_info);
   12467              : 
   12468              :           /* Invalidate SLP_TREE_REPRESENTATIVE in case we released it
   12469              :              to not crash in vect_free_slp_tree later.  */
   12470      1452996 :           if (SLP_TREE_REPRESENTATIVE (root) == store_info)
   12471       552489 :             SLP_TREE_REPRESENTATIVE (root) = NULL;
   12472              :         }
   12473              :     }
   12474       549708 : }
        

Generated by: LCOV version 2.4-beta

LCOV profile is generated on x86_64 machine using following configure options: configure --disable-bootstrap --enable-coverage=opt --enable-languages=c,c++,fortran,go,jit,lto,rust,m2 --enable-host-shared. GCC test suite is run with the built compiler.