/* Analysis Utilities for Loop Vectorization. Copyright (C) 2003,2004,2005,2006 Free Software Foundation, Inc. Contributed by Dorit Naishlos This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING. If not, write to the Free Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "ggc.h" #include "tree.h" #include "basic-block.h" #include "diagnostic.h" #include "tree-flow.h" #include "tree-dump.h" #include "timevar.h" #include "cfgloop.h" #include "expr.h" #include "optabs.h" #include "params.h" #include "tree-chrec.h" #include "tree-data-ref.h" #include "tree-scalar-evolution.h" #include "tree-vectorizer.h" #include "toplev.h" /* Main analysis functions. */ static loop_vec_info vect_analyze_loop_form (struct loop *); static bool vect_analyze_data_refs (loop_vec_info); static bool vect_mark_stmts_to_be_vectorized (loop_vec_info); static void vect_analyze_scalar_cycles (loop_vec_info); static bool vect_analyze_data_ref_accesses (loop_vec_info); static bool vect_analyze_data_ref_dependences (loop_vec_info); static bool vect_analyze_data_refs_alignment (loop_vec_info); static bool vect_compute_data_refs_alignment (loop_vec_info); static bool vect_enhance_data_refs_alignment (loop_vec_info); static bool vect_analyze_operations (loop_vec_info); static bool vect_determine_vectorization_factor (loop_vec_info); /* Utility functions for the analyses. */ static bool exist_non_indexing_operands_for_use_p (tree, tree); static tree vect_get_loop_niters (struct loop *, tree *); static bool vect_analyze_data_ref_dependence (struct data_dependence_relation *, loop_vec_info, bool); static bool vect_compute_data_ref_alignment (struct data_reference *); static bool vect_analyze_data_ref_access (struct data_reference *); static bool vect_can_advance_ivs_p (loop_vec_info); static void vect_update_misalignment_for_peel (struct data_reference *, struct data_reference *, int npeel); /* Function vect_determine_vectorization_factor Determine the vectorization factor (VF). VF is the number of data elements that are operated upon in parallel in a single iteration of the vectorized loop. For example, when vectorizing a loop that operates on 4byte elements, on a target with vector size (VS) 16byte, the VF is set to 4, since 4 elements can fit in a single vector register. We currently support vectorization of loops in which all types operated upon are of the same size. Therefore this function currently sets VF according to the size of the types operated upon, and fails if there are multiple sizes in the loop. VF is also the factor by which the loop iterations are strip-mined, e.g.: original loop: for (i=0; inum_nodes; block_stmt_iterator si; unsigned int vectorization_factor = 0; int i; tree scalar_type; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_determine_vectorization_factor ==="); for (i = 0; i < nbbs; i++) { basic_block bb = bbs[i]; for (si = bsi_start (bb); !bsi_end_p (si); bsi_next (&si)) { tree stmt = bsi_stmt (si); unsigned int nunits; stmt_vec_info stmt_info = vinfo_for_stmt (stmt); tree vectype; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "==> examining statement: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } if (TREE_CODE (stmt) != GIMPLE_MODIFY_STMT) continue; gcc_assert (stmt_info); /* skip stmts which do not need to be vectorized. */ if (!STMT_VINFO_RELEVANT_P (stmt_info) && !STMT_VINFO_LIVE_P (stmt_info)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "skip."); continue; } if (!GIMPLE_STMT_P (stmt) && VECTOR_MODE_P (TYPE_MODE (TREE_TYPE (stmt)))) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: vector stmt in loop:"); print_generic_expr (vect_dump, stmt, TDF_SLIM); } return false; } if (STMT_VINFO_VECTYPE (stmt_info)) { /* The only case when a vectype had been already set is for stmts that contain a dataref, or for "pattern-stmts" (stmts generated by the vectorizer to represent/replace a certain idiom). */ gcc_assert (STMT_VINFO_DATA_REF (stmt_info) || is_pattern_stmt_p (stmt_info)); vectype = STMT_VINFO_VECTYPE (stmt_info); } else { gcc_assert (! STMT_VINFO_DATA_REF (stmt_info) && !is_pattern_stmt_p (stmt_info)); /* We set the vectype according to the type of the result (lhs). For stmts whose result-type is different than the type of the arguments (e.g. demotion, promotion), vectype will be reset appropriately (later). Note that we have to visit the smallest datatype in this function, because that determines the VF. If the samallest datatype in the loop is present only as the rhs of a promotion operation - we'd miss it here. However, in such a case, that a variable of this datatype does not appear in the lhs anywhere in the loop, it shouldn't affect the vectorization factor. */ scalar_type = TREE_TYPE (GIMPLE_STMT_OPERAND (stmt, 0)); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "get vectype for scalar type: "); print_generic_expr (vect_dump, scalar_type, TDF_SLIM); } vectype = get_vectype_for_scalar_type (scalar_type); if (!vectype) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: unsupported data-type "); print_generic_expr (vect_dump, scalar_type, TDF_SLIM); } return false; } STMT_VINFO_VECTYPE (stmt_info) = vectype; } if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "vectype: "); print_generic_expr (vect_dump, vectype, TDF_SLIM); } nunits = TYPE_VECTOR_SUBPARTS (vectype); if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "nunits = %d", nunits); if (!vectorization_factor || (nunits > vectorization_factor)) vectorization_factor = nunits; } } /* TODO: Analyze cost. Decide if worth while to vectorize. */ if (vectorization_factor <= 1) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: unsupported data-type"); return false; } LOOP_VINFO_VECT_FACTOR (loop_vinfo) = vectorization_factor; return true; } /* Function vect_analyze_operations. Scan the loop stmts and make sure they are all vectorizable. */ static bool vect_analyze_operations (loop_vec_info loop_vinfo) { struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); basic_block *bbs = LOOP_VINFO_BBS (loop_vinfo); int nbbs = loop->num_nodes; block_stmt_iterator si; unsigned int vectorization_factor = 0; int i; bool ok; tree phi; stmt_vec_info stmt_info; bool need_to_vectorize = false; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_operations ==="); gcc_assert (LOOP_VINFO_VECT_FACTOR (loop_vinfo)); vectorization_factor = LOOP_VINFO_VECT_FACTOR (loop_vinfo); for (i = 0; i < nbbs; i++) { basic_block bb = bbs[i]; for (phi = phi_nodes (bb); phi; phi = PHI_CHAIN (phi)) { stmt_info = vinfo_for_stmt (phi); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "examining phi: "); print_generic_expr (vect_dump, phi, TDF_SLIM); } gcc_assert (stmt_info); if (STMT_VINFO_LIVE_P (stmt_info)) { /* FORNOW: not yet supported. */ if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: value used after loop."); return false; } if (STMT_VINFO_RELEVANT_P (stmt_info)) { /* Most likely a reduction-like computation that is used in the loop. */ if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: unsupported pattern."); return false; } } for (si = bsi_start (bb); !bsi_end_p (si); bsi_next (&si)) { tree stmt = bsi_stmt (si); stmt_vec_info stmt_info = vinfo_for_stmt (stmt); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "==> examining statement: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } gcc_assert (stmt_info); /* skip stmts which do not need to be vectorized. this is expected to include: - the COND_EXPR which is the loop exit condition - any LABEL_EXPRs in the loop - computations that are used only for array indexing or loop control */ if (!STMT_VINFO_RELEVANT_P (stmt_info) && !STMT_VINFO_LIVE_P (stmt_info)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "irrelevant."); continue; } if (STMT_VINFO_RELEVANT_P (stmt_info)) { gcc_assert (GIMPLE_STMT_P (stmt) || !VECTOR_MODE_P (TYPE_MODE (TREE_TYPE (stmt)))); gcc_assert (STMT_VINFO_VECTYPE (stmt_info)); ok = (vectorizable_type_promotion (stmt, NULL, NULL) || vectorizable_type_demotion (stmt, NULL, NULL) || vectorizable_operation (stmt, NULL, NULL) || vectorizable_assignment (stmt, NULL, NULL) || vectorizable_load (stmt, NULL, NULL) || vectorizable_call (stmt, NULL, NULL) || vectorizable_store (stmt, NULL, NULL) || vectorizable_condition (stmt, NULL, NULL)); if (!ok) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: relevant stmt not supported: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } return false; } need_to_vectorize = true; } if (STMT_VINFO_LIVE_P (stmt_info)) { ok = vectorizable_reduction (stmt, NULL, NULL); if (ok) need_to_vectorize = true; else ok = vectorizable_live_operation (stmt, NULL, NULL); if (!ok) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: live stmt not supported: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } return false; } } } /* stmts in bb */ } /* bbs */ /* TODO: Analyze cost. Decide if worth while to vectorize. */ /* All operations in the loop are either irrelevant (deal with loop control, or dead), or only used outside the loop and can be moved out of the loop (e.g. invariants, inductions). The loop can be optimized away by scalar optimizations. We're better off not touching this loop. */ if (!need_to_vectorize) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "All the computation can be taken out of the loop."); if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: redundant loop. no profit to vectorize."); return false; } if (LOOP_VINFO_NITERS_KNOWN_P (loop_vinfo) && vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "vectorization_factor = %d, niters = " HOST_WIDE_INT_PRINT_DEC, vectorization_factor, LOOP_VINFO_INT_NITERS (loop_vinfo)); if (LOOP_VINFO_NITERS_KNOWN_P (loop_vinfo) && ((LOOP_VINFO_INT_NITERS (loop_vinfo) < vectorization_factor) || (LOOP_VINFO_INT_NITERS (loop_vinfo) <= ((unsigned) (PARAM_VALUE (PARAM_MIN_VECT_LOOP_BOUND)) * vectorization_factor)))) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: iteration count too small."); return false; } if (!LOOP_VINFO_NITERS_KNOWN_P (loop_vinfo) || LOOP_VINFO_INT_NITERS (loop_vinfo) % vectorization_factor != 0 || LOOP_PEELING_FOR_ALIGNMENT (loop_vinfo)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "epilog loop required."); if (!vect_can_advance_ivs_p (loop_vinfo)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: can't create epilog loop 1."); return false; } if (!slpeel_can_duplicate_loop_p (loop, single_exit (loop))) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: can't create epilog loop 2."); return false; } } return true; } /* Function exist_non_indexing_operands_for_use_p USE is one of the uses attached to STMT. Check if USE is used in STMT for anything other than indexing an array. */ static bool exist_non_indexing_operands_for_use_p (tree use, tree stmt) { tree operand; stmt_vec_info stmt_info = vinfo_for_stmt (stmt); /* USE corresponds to some operand in STMT. If there is no data reference in STMT, then any operand that corresponds to USE is not indexing an array. */ if (!STMT_VINFO_DATA_REF (stmt_info)) return true; /* STMT has a data_ref. FORNOW this means that its of one of the following forms: -1- ARRAY_REF = var -2- var = ARRAY_REF (This should have been verified in analyze_data_refs). 'var' in the second case corresponds to a def, not a use, so USE cannot correspond to any operands that are not used for array indexing. Therefore, all we need to check is if STMT falls into the first case, and whether var corresponds to USE. */ if (TREE_CODE (GIMPLE_STMT_OPERAND (stmt, 0)) == SSA_NAME) return false; operand = GIMPLE_STMT_OPERAND (stmt, 1); if (TREE_CODE (operand) != SSA_NAME) return false; if (operand == use) return true; return false; } /* Function vect_analyze_scalar_cycles. Examine the cross iteration def-use cycles of scalar variables, by analyzing the loop (scalar) PHIs; Classify each cycle as one of the following: invariant, induction, reduction, unknown. Some forms of scalar cycles are not yet supported. Example1: reduction: (unsupported yet) loop1: for (i=0; iheader; tree dummy; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_scalar_cycles ==="); for (phi = phi_nodes (bb); phi; phi = PHI_CHAIN (phi)) { tree access_fn = NULL; tree def = PHI_RESULT (phi); stmt_vec_info stmt_vinfo = vinfo_for_stmt (phi); tree reduc_stmt; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Analyze phi: "); print_generic_expr (vect_dump, phi, TDF_SLIM); } /* Skip virtual phi's. The data dependences that are associated with virtual defs/uses (i.e., memory accesses) are analyzed elsewhere. */ if (!is_gimple_reg (SSA_NAME_VAR (def))) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "virtual phi. skip."); continue; } STMT_VINFO_DEF_TYPE (stmt_vinfo) = vect_unknown_def_type; /* Analyze the evolution function. */ access_fn = analyze_scalar_evolution (loop, def); if (!access_fn) continue; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Access function of PHI: "); print_generic_expr (vect_dump, access_fn, TDF_SLIM); } if (vect_is_simple_iv_evolution (loop->num, access_fn, &dummy, &dummy)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "Detected induction."); STMT_VINFO_DEF_TYPE (stmt_vinfo) = vect_induction_def; continue; } /* TODO: handle invariant phis */ reduc_stmt = vect_is_simple_reduction (loop, phi); if (reduc_stmt) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "Detected reduction."); STMT_VINFO_DEF_TYPE (stmt_vinfo) = vect_reduction_def; STMT_VINFO_DEF_TYPE (vinfo_for_stmt (reduc_stmt)) = vect_reduction_def; } else if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "Unknown def-use cycle pattern."); } return; } /* Function vect_insert_into_interleaving_chain. Insert DRA into the interleaving chain of DRB according to DRA's INIT. */ static void vect_insert_into_interleaving_chain (struct data_reference *dra, struct data_reference *drb) { tree prev, next, next_init; stmt_vec_info stmtinfo_a = vinfo_for_stmt (DR_STMT (dra)); stmt_vec_info stmtinfo_b = vinfo_for_stmt (DR_STMT (drb)); prev = DR_GROUP_FIRST_DR (stmtinfo_b); next = DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)); while (next) { next_init = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt (next))); if (tree_int_cst_compare (next_init, DR_INIT (dra)) > 0) { /* Insert here. */ DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)) = DR_STMT (dra); DR_GROUP_NEXT_DR (stmtinfo_a) = next; return; } prev = next; next = DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)); } /* We got to the end of the list. Insert here. */ DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)) = DR_STMT (dra); DR_GROUP_NEXT_DR (stmtinfo_a) = NULL_TREE; } /* Function vect_update_interleaving_chain. For two data-refs DRA and DRB that are a part of a chain interleaved data accesses, update the interleaving chain. DRB's INIT is smaller than DRA's. There are four possible cases: 1. New stmts - both DRA and DRB are not a part of any chain: FIRST_DR = DRB NEXT_DR (DRB) = DRA 2. DRB is a part of a chain and DRA is not: no need to update FIRST_DR no need to insert DRB insert DRA according to init 3. DRA is a part of a chain and DRB is not: if (init of FIRST_DR > init of DRB) FIRST_DR = DRB NEXT(FIRST_DR) = previous FIRST_DR else insert DRB according to its init 4. both DRA and DRB are in some interleaving chains: choose the chain with the smallest init of FIRST_DR insert the nodes of the second chain into the first one. */ static void vect_update_interleaving_chain (struct data_reference *drb, struct data_reference *dra) { stmt_vec_info stmtinfo_a = vinfo_for_stmt (DR_STMT (dra)); stmt_vec_info stmtinfo_b = vinfo_for_stmt (DR_STMT (drb)); tree next_init, init_dra_chain, init_drb_chain, first_a, first_b; tree node, prev, next, node_init, first_stmt; /* 1. New stmts - both DRA and DRB are not a part of any chain. */ if (!DR_GROUP_FIRST_DR (stmtinfo_a) && !DR_GROUP_FIRST_DR (stmtinfo_b)) { DR_GROUP_FIRST_DR (stmtinfo_a) = DR_STMT (drb); DR_GROUP_FIRST_DR (stmtinfo_b) = DR_STMT (drb); DR_GROUP_NEXT_DR (stmtinfo_b) = DR_STMT (dra); return; } /* 2. DRB is a part of a chain and DRA is not. */ if (!DR_GROUP_FIRST_DR (stmtinfo_a) && DR_GROUP_FIRST_DR (stmtinfo_b)) { DR_GROUP_FIRST_DR (stmtinfo_a) = DR_GROUP_FIRST_DR (stmtinfo_b); /* Insert DRA into the chain of DRB. */ vect_insert_into_interleaving_chain (dra, drb); return; } /* 3. DRA is a part of a chain and DRB is not. */ if (DR_GROUP_FIRST_DR (stmtinfo_a) && !DR_GROUP_FIRST_DR (stmtinfo_b)) { tree old_first_stmt = DR_GROUP_FIRST_DR (stmtinfo_a); tree init_old = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt ( old_first_stmt))); tree tmp; if (tree_int_cst_compare (init_old, DR_INIT (drb)) > 0) { /* DRB's init is smaller than the init of the stmt previously marked as the first stmt of the interleaving chain of DRA. Therefore, we update FIRST_STMT and put DRB in the head of the list. */ DR_GROUP_FIRST_DR (stmtinfo_b) = DR_STMT (drb); DR_GROUP_NEXT_DR (stmtinfo_b) = old_first_stmt; /* Update all the stmts in the list to point to the new FIRST_STMT. */ tmp = old_first_stmt; while (tmp) { DR_GROUP_FIRST_DR (vinfo_for_stmt (tmp)) = DR_STMT (drb); tmp = DR_GROUP_NEXT_DR (vinfo_for_stmt (tmp)); } } else { /* Insert DRB in the list of DRA. */ vect_insert_into_interleaving_chain (drb, dra); DR_GROUP_FIRST_DR (stmtinfo_b) = DR_GROUP_FIRST_DR (stmtinfo_a); } return; } /* 4. both DRA and DRB are in some interleaving chains. */ first_a = DR_GROUP_FIRST_DR (stmtinfo_a); first_b = DR_GROUP_FIRST_DR (stmtinfo_b); if (first_a == first_b) return; init_dra_chain = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt (first_a))); init_drb_chain = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt (first_b))); if (tree_int_cst_compare (init_dra_chain, init_drb_chain) > 0) { /* Insert the nodes of DRA chain into the DRB chain. After inserting a node, continue from this node of the DRB chain (don't start from the beginning. */ node = DR_GROUP_FIRST_DR (stmtinfo_a); prev = DR_GROUP_FIRST_DR (stmtinfo_b); first_stmt = first_b; } else { /* Insert the nodes of DRB chain into the DRA chain. After inserting a node, continue from this node of the DRA chain (don't start from the beginning. */ node = DR_GROUP_FIRST_DR (stmtinfo_b); prev = DR_GROUP_FIRST_DR (stmtinfo_a); first_stmt = first_a; } while (node) { node_init = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt (node))); next = DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)); while (next) { next_init = DR_INIT (STMT_VINFO_DATA_REF (vinfo_for_stmt (next))); if (tree_int_cst_compare (next_init, node_init) > 0) { /* Insert here. */ DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)) = node; DR_GROUP_NEXT_DR (vinfo_for_stmt (node)) = next; prev = node; break; } prev = next; next = DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)); } if (!next) { /* We got to the end of the list. Insert here. */ DR_GROUP_NEXT_DR (vinfo_for_stmt (prev)) = node; DR_GROUP_NEXT_DR (vinfo_for_stmt (node)) = NULL_TREE; prev = node; } DR_GROUP_FIRST_DR (vinfo_for_stmt (node)) = first_stmt; node = DR_GROUP_NEXT_DR (vinfo_for_stmt (node)); } } /* Function vect_equal_offsets. Check if OFFSET1 and OFFSET2 are identical expressions. */ static bool vect_equal_offsets (tree offset1, tree offset2) { bool res0, res1; STRIP_NOPS (offset1); STRIP_NOPS (offset2); if (offset1 == offset2) return true; if (TREE_CODE (offset1) != TREE_CODE (offset2) || !BINARY_CLASS_P (offset1) || !BINARY_CLASS_P (offset2)) return false; res0 = vect_equal_offsets (TREE_OPERAND (offset1, 0), TREE_OPERAND (offset2, 0)); res1 = vect_equal_offsets (TREE_OPERAND (offset1, 1), TREE_OPERAND (offset2, 1)); return (res0 && res1); } /* Function vect_check_interleaving. Check if DRA and DRB are a part of interleaving. In case they are, insert DRA and DRB in an interleaving chain. */ static void vect_check_interleaving (struct data_reference *dra, struct data_reference *drb) { HOST_WIDE_INT type_size_a, type_size_b, diff_mod_size, step, init_a, init_b; /* Check that the data-refs have same first location (except init) and they are both either store or load (not load and store). */ if ((DR_BASE_ADDRESS (dra) != DR_BASE_ADDRESS (drb) && (TREE_CODE (DR_BASE_ADDRESS (dra)) != ADDR_EXPR || TREE_CODE (DR_BASE_ADDRESS (drb)) != ADDR_EXPR || TREE_OPERAND (DR_BASE_ADDRESS (dra), 0) != TREE_OPERAND (DR_BASE_ADDRESS (drb),0))) || !vect_equal_offsets (DR_OFFSET (dra), DR_OFFSET (drb)) || !tree_int_cst_compare (DR_INIT (dra), DR_INIT (drb)) || DR_IS_READ (dra) != DR_IS_READ (drb)) return; /* Check: 1. data-refs are of the same type 2. their steps are equal 3. the step is greater than the difference between data-refs' inits */ type_size_a = TREE_INT_CST_LOW (TYPE_SIZE_UNIT (TREE_TYPE (DR_REF (dra)))); type_size_b = TREE_INT_CST_LOW (TYPE_SIZE_UNIT (TREE_TYPE (DR_REF (drb)))); if (type_size_a != type_size_b || tree_int_cst_compare (DR_STEP (dra), DR_STEP (drb))) return; init_a = TREE_INT_CST_LOW (DR_INIT (dra)); init_b = TREE_INT_CST_LOW (DR_INIT (drb)); step = TREE_INT_CST_LOW (DR_STEP (dra)); if (init_a > init_b) { /* If init_a == init_b + the size of the type * k, we have an interleaving, and DRB is accessed before DRA. */ diff_mod_size = (init_a - init_b) % type_size_a; if ((init_a - init_b) > step) return; if (diff_mod_size == 0) { vect_update_interleaving_chain (drb, dra); if (vect_print_dump_info (REPORT_DR_DETAILS)) { fprintf (vect_dump, "Detected interleaving "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return; } } else { /* If init_b == init_a + the size of the type * k, we have an interleaving, and DRA is accessed before DRB. */ diff_mod_size = (init_b - init_a) % type_size_a; if ((init_b - init_a) > step) return; if (diff_mod_size == 0) { vect_update_interleaving_chain (dra, drb); if (vect_print_dump_info (REPORT_DR_DETAILS)) { fprintf (vect_dump, "Detected interleaving "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return; } } } /* Function vect_analyze_data_ref_dependence. Return TRUE if there (might) exist a dependence between a memory-reference DRA and a memory-reference DRB. */ static bool vect_analyze_data_ref_dependence (struct data_dependence_relation *ddr, loop_vec_info loop_vinfo, bool check_interleaving) { unsigned int i; struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); int vectorization_factor = LOOP_VINFO_VECT_FACTOR (loop_vinfo); struct data_reference *dra = DDR_A (ddr); struct data_reference *drb = DDR_B (ddr); stmt_vec_info stmtinfo_a = vinfo_for_stmt (DR_STMT (dra)); stmt_vec_info stmtinfo_b = vinfo_for_stmt (DR_STMT (drb)); int dra_size = GET_MODE_SIZE (TYPE_MODE (TREE_TYPE (DR_REF (dra)))); int drb_size = GET_MODE_SIZE (TYPE_MODE (TREE_TYPE (DR_REF (drb)))); lambda_vector dist_v; unsigned int loop_depth; if (DDR_ARE_DEPENDENT (ddr) == chrec_known) { /* Independent data accesses. */ if (check_interleaving) vect_check_interleaving (dra, drb); return false; } if ((DR_IS_READ (dra) && DR_IS_READ (drb)) || dra == drb) return false; if (DDR_ARE_DEPENDENT (ddr) == chrec_dont_know) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: can't determine dependence between "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return true; } if (DDR_NUM_DIST_VECTS (ddr) == 0) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: bad dist vector for "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return true; } loop_depth = index_in_loop_nest (loop->num, DDR_LOOP_NEST (ddr)); for (i = 0; VEC_iterate (lambda_vector, DDR_DIST_VECTS (ddr), i, dist_v); i++) { int dist = dist_v[loop_depth]; if (vect_print_dump_info (REPORT_DR_DETAILS)) fprintf (vect_dump, "dependence distance = %d.", dist); /* Same loop iteration. */ if (dist % vectorization_factor == 0 && dra_size == drb_size) { /* Two references with distance zero have the same alignment. */ VEC_safe_push (dr_p, heap, STMT_VINFO_SAME_ALIGN_REFS (stmtinfo_a), drb); VEC_safe_push (dr_p, heap, STMT_VINFO_SAME_ALIGN_REFS (stmtinfo_b), dra); if (vect_print_dump_info (REPORT_ALIGNMENT)) fprintf (vect_dump, "accesses have the same alignment."); if (vect_print_dump_info (REPORT_DR_DETAILS)) { fprintf (vect_dump, "dependence distance modulo vf == 0 between "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } continue; } if (abs (dist) >= vectorization_factor) { /* Dependence distance does not create dependence, as far as vectorization is concerned, in this case. */ if (vect_print_dump_info (REPORT_DR_DETAILS)) fprintf (vect_dump, "dependence distance >= VF."); continue; } if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: possible dependence between data-refs "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return true; } return false; } /* Function vect_check_dependences. Return TRUE if there is a store-store or load-store dependence between data-refs in DDR, otherwise return FALSE. */ static bool vect_check_dependences (struct data_dependence_relation *ddr) { struct data_reference *dra = DDR_A (ddr); struct data_reference *drb = DDR_B (ddr); if (DDR_ARE_DEPENDENT (ddr) == chrec_known || dra == drb) /* Independent or same data accesses. */ return false; if (DR_IS_READ (dra) == DR_IS_READ (drb) && DR_IS_READ (dra)) /* Two loads. */ return false; if (vect_print_dump_info (REPORT_DR_DETAILS)) { fprintf (vect_dump, "possible store or store/load dependence between "); print_generic_expr (vect_dump, DR_REF (dra), TDF_SLIM); fprintf (vect_dump, " and "); print_generic_expr (vect_dump, DR_REF (drb), TDF_SLIM); } return true; } /* Function vect_analyze_data_ref_dependences. Examine all the data references in the loop, and make sure there do not exist any data dependences between them. */ static bool vect_analyze_data_ref_dependences (loop_vec_info loop_vinfo) { unsigned int i; VEC (ddr_p, heap) *ddrs = LOOP_VINFO_DDRS (loop_vinfo); struct data_dependence_relation *ddr; bool check_interleaving = true; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_dependences ==="); /* We allow interleaving only if there are no store-store and load-store dependencies in the loop. */ for (i = 0; VEC_iterate (ddr_p, ddrs, i, ddr); i++) { if (vect_check_dependences (ddr)) { check_interleaving = false; break; } } for (i = 0; VEC_iterate (ddr_p, ddrs, i, ddr); i++) if (vect_analyze_data_ref_dependence (ddr, loop_vinfo, check_interleaving)) return false; return true; } /* Function vect_compute_data_ref_alignment Compute the misalignment of the data reference DR. Output: 1. If during the misalignment computation it is found that the data reference cannot be vectorized then false is returned. 2. DR_MISALIGNMENT (DR) is defined. FOR NOW: No analysis is actually performed. Misalignment is calculated only for trivial cases. TODO. */ static bool vect_compute_data_ref_alignment (struct data_reference *dr) { tree stmt = DR_STMT (dr); stmt_vec_info stmt_info = vinfo_for_stmt (stmt); tree ref = DR_REF (dr); tree vectype; tree base, base_addr; bool base_aligned; tree misalign; tree aligned_to, alignment; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "vect_compute_data_ref_alignment:"); /* Initialize misalignment to unknown. */ DR_MISALIGNMENT (dr) = -1; misalign = DR_OFFSET_MISALIGNMENT (dr); aligned_to = DR_ALIGNED_TO (dr); base_addr = DR_BASE_ADDRESS (dr); base = build_fold_indirect_ref (base_addr); vectype = STMT_VINFO_VECTYPE (stmt_info); alignment = ssize_int (TYPE_ALIGN (vectype)/BITS_PER_UNIT); if ((aligned_to && tree_int_cst_compare (aligned_to, alignment) < 0) || !misalign) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Unknown alignment for access: "); print_generic_expr (vect_dump, base, TDF_SLIM); } return true; } if ((DECL_P (base) && tree_int_cst_compare (ssize_int (DECL_ALIGN_UNIT (base)), alignment) >= 0) || (TREE_CODE (base_addr) == SSA_NAME && tree_int_cst_compare (ssize_int (TYPE_ALIGN_UNIT (TREE_TYPE ( TREE_TYPE (base_addr)))), alignment) >= 0)) base_aligned = true; else base_aligned = false; if (!base_aligned) { /* Do not change the alignment of global variables if flag_section_anchors is enabled. */ if (!vect_can_force_dr_alignment_p (base, TYPE_ALIGN (vectype)) || (TREE_STATIC (base) && flag_section_anchors)) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "can't force alignment of ref: "); print_generic_expr (vect_dump, ref, TDF_SLIM); } return true; } /* Force the alignment of the decl. NOTE: This is the only change to the code we make during the analysis phase, before deciding to vectorize the loop. */ if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "force alignment"); DECL_ALIGN (base) = TYPE_ALIGN (vectype); DECL_USER_ALIGN (base) = 1; } /* At this point we assume that the base is aligned. */ gcc_assert (base_aligned || (TREE_CODE (base) == VAR_DECL && DECL_ALIGN (base) >= TYPE_ALIGN (vectype))); /* Modulo alignment. */ misalign = size_binop (TRUNC_MOD_EXPR, misalign, alignment); if (!host_integerp (misalign, 1)) { /* Negative or overflowed misalignment value. */ if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "unexpected misalign value"); return false; } DR_MISALIGNMENT (dr) = TREE_INT_CST_LOW (misalign); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "misalign = %d bytes of ref ", DR_MISALIGNMENT (dr)); print_generic_expr (vect_dump, ref, TDF_SLIM); } return true; } /* Function vect_compute_data_refs_alignment Compute the misalignment of data references in the loop. Return FALSE if a data reference is found that cannot be vectorized. */ static bool vect_compute_data_refs_alignment (loop_vec_info loop_vinfo) { VEC (data_reference_p, heap) *datarefs = LOOP_VINFO_DATAREFS (loop_vinfo); struct data_reference *dr; unsigned int i; for (i = 0; VEC_iterate (data_reference_p, datarefs, i, dr); i++) if (!vect_compute_data_ref_alignment (dr)) return false; return true; } /* Function vect_update_misalignment_for_peel DR - the data reference whose misalignment is to be adjusted. DR_PEEL - the data reference whose misalignment is being made zero in the vector loop by the peel. NPEEL - the number of iterations in the peel loop if the misalignment of DR_PEEL is known at compile time. */ static void vect_update_misalignment_for_peel (struct data_reference *dr, struct data_reference *dr_peel, int npeel) { unsigned int i; VEC(dr_p,heap) *same_align_drs; struct data_reference *current_dr; int dr_size = GET_MODE_SIZE (TYPE_MODE (TREE_TYPE (DR_REF (dr)))); int dr_peel_size = GET_MODE_SIZE (TYPE_MODE (TREE_TYPE (DR_REF (dr_peel)))); stmt_vec_info stmt_info = vinfo_for_stmt (DR_STMT (dr)); stmt_vec_info peel_stmt_info = vinfo_for_stmt (DR_STMT (dr_peel)); /* For interleaved data accesses the step in the loop must be multiplied by the size of the interleaving group. */ if (DR_GROUP_FIRST_DR (stmt_info)) dr_size *= DR_GROUP_SIZE (vinfo_for_stmt (DR_GROUP_FIRST_DR (stmt_info))); if (DR_GROUP_FIRST_DR (peel_stmt_info)) dr_peel_size *= DR_GROUP_SIZE (peel_stmt_info); if (known_alignment_for_access_p (dr) && known_alignment_for_access_p (dr_peel) && (DR_MISALIGNMENT (dr) / dr_size == DR_MISALIGNMENT (dr_peel) / dr_peel_size)) { DR_MISALIGNMENT (dr) = 0; return; } /* It can be assumed that the data refs with the same alignment as dr_peel are aligned in the vector loop. */ same_align_drs = STMT_VINFO_SAME_ALIGN_REFS (vinfo_for_stmt (DR_STMT (dr_peel))); for (i = 0; VEC_iterate (dr_p, same_align_drs, i, current_dr); i++) { if (current_dr != dr) continue; gcc_assert (DR_MISALIGNMENT (dr) / dr_size == DR_MISALIGNMENT (dr_peel) / dr_peel_size); DR_MISALIGNMENT (dr) = 0; return; } if (known_alignment_for_access_p (dr) && known_alignment_for_access_p (dr_peel)) { DR_MISALIGNMENT (dr) += npeel * dr_size; DR_MISALIGNMENT (dr) %= UNITS_PER_SIMD_WORD; return; } if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "Setting misalignment to -1."); DR_MISALIGNMENT (dr) = -1; } /* Function vect_verify_datarefs_alignment Return TRUE if all data references in the loop can be handled with respect to alignment. */ static bool vect_verify_datarefs_alignment (loop_vec_info loop_vinfo) { VEC (data_reference_p, heap) *datarefs = LOOP_VINFO_DATAREFS (loop_vinfo); struct data_reference *dr; enum dr_alignment_support supportable_dr_alignment; unsigned int i; for (i = 0; VEC_iterate (data_reference_p, datarefs, i, dr); i++) { tree stmt = DR_STMT (dr); stmt_vec_info stmt_info = vinfo_for_stmt (stmt); /* For interleaving, only the alignment of the first access matters. */ if (DR_GROUP_FIRST_DR (stmt_info) && DR_GROUP_FIRST_DR (stmt_info) != stmt) continue; supportable_dr_alignment = vect_supportable_dr_alignment (dr); if (!supportable_dr_alignment) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { if (DR_IS_READ (dr)) fprintf (vect_dump, "not vectorized: unsupported unaligned load."); else fprintf (vect_dump, "not vectorized: unsupported unaligned store."); } return false; } if (supportable_dr_alignment != dr_aligned && vect_print_dump_info (REPORT_ALIGNMENT)) fprintf (vect_dump, "Vectorizing an unaligned access."); } return true; } /* Function vect_enhance_data_refs_alignment This pass will use loop versioning and loop peeling in order to enhance the alignment of data references in the loop. FOR NOW: we assume that whatever versioning/peeling takes place, only the original loop is to be vectorized; Any other loops that are created by the transformations performed in this pass - are not supposed to be vectorized. This restriction will be relaxed. This pass will require a cost model to guide it whether to apply peeling or versioning or a combination of the two. For example, the scheme that intel uses when given a loop with several memory accesses, is as follows: choose one memory access ('p') which alignment you want to force by doing peeling. Then, either (1) generate a loop in which 'p' is aligned and all other accesses are not necessarily aligned, or (2) use loop versioning to generate one loop in which all accesses are aligned, and another loop in which only 'p' is necessarily aligned. ("Automatic Intra-Register Vectorization for the Intel Architecture", Aart J.C. Bik, Milind Girkar, Paul M. Grey and Ximmin Tian, International Journal of Parallel Programming, Vol. 30, No. 2, April 2002.) Devising a cost model is the most critical aspect of this work. It will guide us on which access to peel for, whether to use loop versioning, how many versions to create, etc. The cost model will probably consist of generic considerations as well as target specific considerations (on powerpc for example, misaligned stores are more painful than misaligned loads). Here are the general steps involved in alignment enhancements: -- original loop, before alignment analysis: for (i=0; i= (unsigned) PARAM_VALUE (PARAM_VECT_MAX_VERSION_CHECKS)) { do_versioning = false; break; } stmt = DR_STMT (dr); vectype = STMT_VINFO_VECTYPE (vinfo_for_stmt (stmt)); gcc_assert (vectype); /* The rightmost bits of an aligned address must be zeros. Construct the mask needed for this test. For example, GET_MODE_SIZE for the vector mode V4SI is 16 bytes so the mask must be 15 = 0xf. */ mask = GET_MODE_SIZE (TYPE_MODE (vectype)) - 1; /* FORNOW: use the same mask to test all potentially unaligned references in the loop. The vectorizer currently supports a single vector size, see the reference to GET_MODE_NUNITS (TYPE_MODE (vectype)) where the vectorization factor is computed. */ gcc_assert (!LOOP_VINFO_PTR_MASK (loop_vinfo) || LOOP_VINFO_PTR_MASK (loop_vinfo) == mask); LOOP_VINFO_PTR_MASK (loop_vinfo) = mask; VEC_safe_push (tree, heap, LOOP_VINFO_MAY_MISALIGN_STMTS (loop_vinfo), DR_STMT (dr)); } } /* Versioning requires at least one misaligned data reference. */ if (VEC_length (tree, LOOP_VINFO_MAY_MISALIGN_STMTS (loop_vinfo)) == 0) do_versioning = false; else if (!do_versioning) VEC_truncate (tree, LOOP_VINFO_MAY_MISALIGN_STMTS (loop_vinfo), 0); } if (do_versioning) { VEC(tree,heap) *may_misalign_stmts = LOOP_VINFO_MAY_MISALIGN_STMTS (loop_vinfo); tree stmt; /* It can now be assumed that the data references in the statements in LOOP_VINFO_MAY_MISALIGN_STMTS will be aligned in the version of the loop being vectorized. */ for (i = 0; VEC_iterate (tree, may_misalign_stmts, i, stmt); i++) { stmt_vec_info stmt_info = vinfo_for_stmt (stmt); dr = STMT_VINFO_DATA_REF (stmt_info); DR_MISALIGNMENT (dr) = 0; if (vect_print_dump_info (REPORT_ALIGNMENT)) fprintf (vect_dump, "Alignment of access forced using versioning."); } if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "Versioning for alignment will be applied."); /* Peeling and versioning can't be done together at this time. */ gcc_assert (! (do_peeling && do_versioning)); stat = vect_verify_datarefs_alignment (loop_vinfo); gcc_assert (stat); return stat; } /* This point is reached if neither peeling nor versioning is being done. */ gcc_assert (! (do_peeling || do_versioning)); stat = vect_verify_datarefs_alignment (loop_vinfo); return stat; } /* Function vect_analyze_data_refs_alignment Analyze the alignment of the data-references in the loop. Return FALSE if a data reference is found that cannot be vectorized. */ static bool vect_analyze_data_refs_alignment (loop_vec_info loop_vinfo) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_data_refs_alignment ==="); if (!vect_compute_data_refs_alignment (loop_vinfo)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: can't calculate alignment for data ref."); return false; } return true; } /* Function vect_analyze_data_ref_access. Analyze the access pattern of the data-reference DR. For now, a data access has to be consecutive to be considered vectorizable. */ static bool vect_analyze_data_ref_access (struct data_reference *dr) { tree step = DR_STEP (dr); HOST_WIDE_INT dr_step = TREE_INT_CST_LOW (step); tree scalar_type = TREE_TYPE (DR_REF (dr)); HOST_WIDE_INT type_size = TREE_INT_CST_LOW (TYPE_SIZE_UNIT (scalar_type)); tree stmt = DR_STMT (dr); /* For interleaving, STRIDE is STEP counted in elements, i.e., the size of the interleaving group (including gaps). */ HOST_WIDE_INT stride = dr_step / type_size; if (!step) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data-ref access"); return false; } /* Consecutive? */ if (!tree_int_cst_compare (step, TYPE_SIZE_UNIT (scalar_type))) { /* Mark that it is not interleaving. */ DR_GROUP_FIRST_DR (vinfo_for_stmt (stmt)) = NULL_TREE; return true; } /* Not consecutive access is possible only if it is a part of interleaving. */ if (!DR_GROUP_FIRST_DR (vinfo_for_stmt (stmt))) { /* Check if it this DR is a part of interleaving, and is a single element of the group that is accessed in the loop. */ /* Gaps are supported only for loads. STEP must be a multiple of the type size. The size of the group must be a power of 2. */ if (DR_IS_READ (dr) && (dr_step % type_size) == 0 && stride > 0 && exact_log2 (stride) != -1) { DR_GROUP_FIRST_DR (vinfo_for_stmt (stmt)) = stmt; DR_GROUP_SIZE (vinfo_for_stmt (stmt)) = stride; if (vect_print_dump_info (REPORT_DR_DETAILS)) { fprintf (vect_dump, "Detected single element interleaving %d ", DR_GROUP_SIZE (vinfo_for_stmt (stmt))); print_generic_expr (vect_dump, DR_REF (dr), TDF_SLIM); fprintf (vect_dump, " step "); print_generic_expr (vect_dump, step, TDF_SLIM); } return true; } if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "not consecutive access"); return false; } if (DR_GROUP_FIRST_DR (vinfo_for_stmt (stmt)) == stmt) { /* First stmt in the interleaving chain. Check the chain. */ tree next = DR_GROUP_NEXT_DR (vinfo_for_stmt (stmt)); struct data_reference *data_ref = dr; unsigned int count = 1; tree next_step; tree prev_init = DR_INIT (data_ref); tree prev = stmt; HOST_WIDE_INT diff, count_in_bytes; while (next) { /* Skip same data-refs. In case that two or more stmts share data-ref (supported only for loads), we vectorize only the first stmt, and the rest get their vectorized loads from the the first one. */ if (!tree_int_cst_compare (DR_INIT (data_ref), DR_INIT (STMT_VINFO_DATA_REF ( vinfo_for_stmt (next))))) { /* For load use the same data-ref load. (We check in vect_check_dependences() that there are no two stores to the same location). */ DR_GROUP_SAME_DR_STMT (vinfo_for_stmt (next)) = prev; prev = next; next = DR_GROUP_NEXT_DR (vinfo_for_stmt (next)); continue; } prev = next; /* Check that all the accesses have the same STEP. */ next_step = DR_STEP (STMT_VINFO_DATA_REF (vinfo_for_stmt (next))); if (tree_int_cst_compare (step, next_step)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "not consecutive access in interleaving"); return false; } data_ref = STMT_VINFO_DATA_REF (vinfo_for_stmt (next)); /* Check that the distance between two accesses is equal to the type size. Otherwise, we have gaps. */ diff = (TREE_INT_CST_LOW (DR_INIT (data_ref)) - TREE_INT_CST_LOW (prev_init)) / type_size; if (!DR_IS_READ (data_ref) && diff != 1) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "interleaved store with gaps"); return false; } /* Store the gap from the previous member of the group. If there is no gap in the access, DR_GROUP_GAP is always 1. */ DR_GROUP_GAP (vinfo_for_stmt (next)) = diff; prev_init = DR_INIT (data_ref); next = DR_GROUP_NEXT_DR (vinfo_for_stmt (next)); /* Count the number of data-refs in the chain. */ count++; } /* COUNT is the number of accesses found, we multiply it by the size of the type to get COUNT_IN_BYTES. */ count_in_bytes = type_size * count; /* Check that the size of the interleaving is not greater than STEP. */ if (dr_step < count_in_bytes) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "interleaving size is greater than step for "); print_generic_expr (vect_dump, DR_REF (dr), TDF_SLIM); } return false; } /* Check that the size of the interleaving is equal to STEP for stores, i.e., that there are no gaps. */ if (!DR_IS_READ (dr) && dr_step != count_in_bytes) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "interleaved store with gaps"); return false; } /* Check that STEP is a multiple of type size. */ if ((dr_step % type_size) != 0) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "step is not a multiple of type size: step "); print_generic_expr (vect_dump, step, TDF_SLIM); fprintf (vect_dump, " size "); print_generic_expr (vect_dump, TYPE_SIZE_UNIT (scalar_type), TDF_SLIM); } return false; } /* FORNOW: we handle only interleaving that is a power of 2. */ if (exact_log2 (stride) == -1) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "interleaving is not a power of 2"); return false; } DR_GROUP_SIZE (vinfo_for_stmt (stmt)) = stride; } return true; } /* Function vect_analyze_data_ref_accesses. Analyze the access pattern of all the data references in the loop. FORNOW: the only access pattern that is considered vectorizable is a simple step 1 (consecutive) access. FORNOW: handle only arrays and pointer accesses. */ static bool vect_analyze_data_ref_accesses (loop_vec_info loop_vinfo) { unsigned int i; VEC (data_reference_p, heap) *datarefs = LOOP_VINFO_DATAREFS (loop_vinfo); struct data_reference *dr; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_data_ref_accesses ==="); for (i = 0; VEC_iterate (data_reference_p, datarefs, i, dr); i++) if (!vect_analyze_data_ref_access (dr)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: complicated access pattern."); return false; } return true; } /* Function vect_analyze_data_refs. Find all the data references in the loop. The general structure of the analysis of data refs in the vectorizer is as follows: 1- vect_analyze_data_refs(loop): call compute_data_dependences_for_loop to find and analyze all data-refs in the loop and their dependences. 2- vect_analyze_dependences(): apply dependence testing using ddrs. 3- vect_analyze_drs_alignment(): check that ref_stmt.alignment is ok. 4- vect_analyze_drs_access(): check that ref_stmt.step is ok. */ static bool vect_analyze_data_refs (loop_vec_info loop_vinfo) { struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); unsigned int i; VEC (data_reference_p, heap) *datarefs; struct data_reference *dr; tree scalar_type; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_data_refs ==="); compute_data_dependences_for_loop (loop, true, &LOOP_VINFO_DATAREFS (loop_vinfo), &LOOP_VINFO_DDRS (loop_vinfo)); /* Go through the data-refs, check that the analysis succeeded. Update pointer from stmt_vec_info struct to DR and vectype. */ datarefs = LOOP_VINFO_DATAREFS (loop_vinfo); for (i = 0; VEC_iterate (data_reference_p, datarefs, i, dr); i++) { tree stmt; stmt_vec_info stmt_info; if (!dr || !DR_REF (dr)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: unhandled data-ref "); return false; } /* Update DR field in stmt_vec_info struct. */ stmt = DR_STMT (dr); stmt_info = vinfo_for_stmt (stmt); if (STMT_VINFO_DATA_REF (stmt_info)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: more than one data ref in stmt: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } return false; } STMT_VINFO_DATA_REF (stmt_info) = dr; /* Check that analysis of the data-ref succeeded. */ if (!DR_BASE_ADDRESS (dr) || !DR_OFFSET (dr) || !DR_INIT (dr) || !DR_STEP (dr)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: data ref analysis failed "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } return false; } if (!DR_MEMTAG (dr)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: no memory tag for "); print_generic_expr (vect_dump, DR_REF (dr), TDF_SLIM); } return false; } /* Set vectype for STMT. */ scalar_type = TREE_TYPE (DR_REF (dr)); STMT_VINFO_VECTYPE (stmt_info) = get_vectype_for_scalar_type (scalar_type); if (!STMT_VINFO_VECTYPE (stmt_info)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) { fprintf (vect_dump, "not vectorized: no vectype for stmt: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); fprintf (vect_dump, " scalar_type: "); print_generic_expr (vect_dump, scalar_type, TDF_DETAILS); } return false; } } return true; } /* Utility functions used by vect_mark_stmts_to_be_vectorized. */ /* Function vect_mark_relevant. Mark STMT as "relevant for vectorization" and add it to WORKLIST. */ static void vect_mark_relevant (VEC(tree,heap) **worklist, tree stmt, enum vect_relevant relevant, bool live_p) { stmt_vec_info stmt_info = vinfo_for_stmt (stmt); enum vect_relevant save_relevant = STMT_VINFO_RELEVANT (stmt_info); bool save_live_p = STMT_VINFO_LIVE_P (stmt_info); if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "mark relevant %d, live %d.", relevant, live_p); if (STMT_VINFO_IN_PATTERN_P (stmt_info)) { tree pattern_stmt; /* This is the last stmt in a sequence that was detected as a pattern that can potentially be vectorized. Don't mark the stmt as relevant/live because it's not going to vectorized. Instead mark the pattern-stmt that replaces it. */ if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "last stmt in pattern. don't mark relevant/live."); pattern_stmt = STMT_VINFO_RELATED_STMT (stmt_info); stmt_info = vinfo_for_stmt (pattern_stmt); gcc_assert (STMT_VINFO_RELATED_STMT (stmt_info) == stmt); save_relevant = STMT_VINFO_RELEVANT (stmt_info); save_live_p = STMT_VINFO_LIVE_P (stmt_info); stmt = pattern_stmt; } STMT_VINFO_LIVE_P (stmt_info) |= live_p; if (relevant > STMT_VINFO_RELEVANT (stmt_info)) STMT_VINFO_RELEVANT (stmt_info) = relevant; if (TREE_CODE (stmt) == PHI_NODE) /* Don't put phi-nodes in the worklist. Phis that are marked relevant or live will fail vectorization later on. */ return; if (STMT_VINFO_RELEVANT (stmt_info) == save_relevant && STMT_VINFO_LIVE_P (stmt_info) == save_live_p) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "already marked relevant/live."); return; } VEC_safe_push (tree, heap, *worklist, stmt); } /* Function vect_stmt_relevant_p. Return true if STMT in loop that is represented by LOOP_VINFO is "relevant for vectorization". A stmt is considered "relevant for vectorization" if: - it has uses outside the loop. - it has vdefs (it alters memory). - control stmts in the loop (except for the exit condition). CHECKME: what other side effects would the vectorizer allow? */ static bool vect_stmt_relevant_p (tree stmt, loop_vec_info loop_vinfo, enum vect_relevant *relevant, bool *live_p) { struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); ssa_op_iter op_iter; imm_use_iterator imm_iter; use_operand_p use_p; def_operand_p def_p; *relevant = vect_unused_in_loop; *live_p = false; /* cond stmt other than loop exit cond. */ if (is_ctrl_stmt (stmt) && (stmt != LOOP_VINFO_EXIT_COND (loop_vinfo))) *relevant = vect_used_in_loop; /* changing memory. */ if (TREE_CODE (stmt) != PHI_NODE) if (!ZERO_SSA_OPERANDS (stmt, SSA_OP_VIRTUAL_DEFS)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "vec_stmt_relevant_p: stmt has vdefs."); *relevant = vect_used_in_loop; } /* uses outside the loop. */ FOR_EACH_PHI_OR_STMT_DEF (def_p, stmt, op_iter, SSA_OP_DEF) { FOR_EACH_IMM_USE_FAST (use_p, imm_iter, DEF_FROM_PTR (def_p)) { basic_block bb = bb_for_stmt (USE_STMT (use_p)); if (!flow_bb_inside_loop_p (loop, bb)) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "vec_stmt_relevant_p: used out of loop."); /* We expect all such uses to be in the loop exit phis (because of loop closed form) */ gcc_assert (TREE_CODE (USE_STMT (use_p)) == PHI_NODE); gcc_assert (bb == single_exit (loop)->dest); *live_p = true; } } } return (*live_p || *relevant); } /* Function vect_mark_stmts_to_be_vectorized. Not all stmts in the loop need to be vectorized. For example: for i... for j... 1. T0 = i + j 2. T1 = a[T0] 3. j = j + 1 Stmt 1 and 3 do not need to be vectorized, because loop control and addressing of vectorized data-refs are handled differently. This pass detects such stmts. */ static bool vect_mark_stmts_to_be_vectorized (loop_vec_info loop_vinfo) { VEC(tree,heap) *worklist; struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); basic_block *bbs = LOOP_VINFO_BBS (loop_vinfo); unsigned int nbbs = loop->num_nodes; block_stmt_iterator si; tree stmt, use; stmt_ann_t ann; ssa_op_iter iter; unsigned int i; stmt_vec_info stmt_vinfo; basic_block bb; tree phi; bool live_p; enum vect_relevant relevant; tree def, def_stmt; enum vect_def_type dt; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_mark_stmts_to_be_vectorized ==="); worklist = VEC_alloc (tree, heap, 64); /* 1. Init worklist. */ bb = loop->header; for (phi = phi_nodes (bb); phi; phi = PHI_CHAIN (phi)) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "init: phi relevant? "); print_generic_expr (vect_dump, phi, TDF_SLIM); } if (vect_stmt_relevant_p (phi, loop_vinfo, &relevant, &live_p)) vect_mark_relevant (&worklist, phi, relevant, live_p); } for (i = 0; i < nbbs; i++) { bb = bbs[i]; for (si = bsi_start (bb); !bsi_end_p (si); bsi_next (&si)) { stmt = bsi_stmt (si); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "init: stmt relevant? "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } if (vect_stmt_relevant_p (stmt, loop_vinfo, &relevant, &live_p)) vect_mark_relevant (&worklist, stmt, relevant, live_p); } } /* 2. Process_worklist */ while (VEC_length (tree, worklist) > 0) { stmt = VEC_pop (tree, worklist); if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "worklist: examine stmt: "); print_generic_expr (vect_dump, stmt, TDF_SLIM); } /* Examine the USEs of STMT. For each ssa-name USE that is defined in the loop, mark the stmt that defines it (DEF_STMT) as relevant/irrelevant and live/dead according to the liveness and relevance properties of STMT. */ gcc_assert (TREE_CODE (stmt) != PHI_NODE); ann = stmt_ann (stmt); stmt_vinfo = vinfo_for_stmt (stmt); relevant = STMT_VINFO_RELEVANT (stmt_vinfo); live_p = STMT_VINFO_LIVE_P (stmt_vinfo); /* Generally, the liveness and relevance properties of STMT are propagated to the DEF_STMTs of its USEs: STMT_VINFO_LIVE_P (DEF_STMT_info) <-- live_p STMT_VINFO_RELEVANT (DEF_STMT_info) <-- relevant Exceptions: (case 1) If USE is used only for address computations (e.g. array indexing), which does not need to be directly vectorized, then the liveness/relevance of the respective DEF_STMT is left unchanged. (case 2) If STMT has been identified as defining a reduction variable, then we have two cases: (case 2.1) The last use of STMT is the reduction-variable, which is defined by a loop-header-phi. We don't want to mark the phi as live or relevant (because it does not need to be vectorized, it is handled as part of the vectorization of the reduction), so in this case we skip the call to vect_mark_relevant. (case 2.2) The rest of the uses of STMT are defined in the loop body. For the def_stmt of these uses we want to set liveness/relevance as follows: STMT_VINFO_LIVE_P (DEF_STMT_info) <-- false STMT_VINFO_RELEVANT (DEF_STMT_info) <-- vect_used_by_reduction because even though STMT is classified as live (since it defines a value that is used across loop iterations) and irrelevant (since it is not used inside the loop), it will be vectorized, and therefore the corresponding DEF_STMTs need to marked as relevant. We distinguish between two kinds of relevant stmts - those that are used by a reduction computation, and those that are (also) used by a regular computation. This allows us later on to identify stmts that are used solely by a reduction, and therefore the order of the results that they produce does not have to be kept. */ /* case 2.2: */ if (STMT_VINFO_DEF_TYPE (stmt_vinfo) == vect_reduction_def) { gcc_assert (relevant == vect_unused_in_loop && live_p); relevant = vect_used_by_reduction; live_p = false; } FOR_EACH_SSA_TREE_OPERAND (use, stmt, iter, SSA_OP_USE) { /* case 1: we are only interested in uses that need to be vectorized. Uses that are used for address computation are not considered relevant. */ if (!exist_non_indexing_operands_for_use_p (use, stmt)) continue; if (!vect_is_simple_use (use, loop_vinfo, &def_stmt, &def, &dt)) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: unsupported use in stmt."); VEC_free (tree, heap, worklist); return false; } if (!def_stmt || IS_EMPTY_STMT (def_stmt)) continue; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "worklist: examine use %d: ", i); print_generic_expr (vect_dump, use, TDF_SLIM); } bb = bb_for_stmt (def_stmt); if (!flow_bb_inside_loop_p (loop, bb)) continue; /* case 2.1: the reduction-use does not mark the defining-phi as relevant. */ if (STMT_VINFO_DEF_TYPE (stmt_vinfo) == vect_reduction_def && TREE_CODE (def_stmt) == PHI_NODE) continue; vect_mark_relevant (&worklist, def_stmt, relevant, live_p); } } /* while worklist */ VEC_free (tree, heap, worklist); return true; } /* Function vect_can_advance_ivs_p In case the number of iterations that LOOP iterates is unknown at compile time, an epilog loop will be generated, and the loop induction variables (IVs) will be "advanced" to the value they are supposed to take just before the epilog loop. Here we check that the access function of the loop IVs and the expression that represents the loop bound are simple enough. These restrictions will be relaxed in the future. */ static bool vect_can_advance_ivs_p (loop_vec_info loop_vinfo) { struct loop *loop = LOOP_VINFO_LOOP (loop_vinfo); basic_block bb = loop->header; tree phi; /* Analyze phi functions of the loop header. */ if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "vect_can_advance_ivs_p:"); for (phi = phi_nodes (bb); phi; phi = PHI_CHAIN (phi)) { tree access_fn = NULL; tree evolution_part; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Analyze phi: "); print_generic_expr (vect_dump, phi, TDF_SLIM); } /* Skip virtual phi's. The data dependences that are associated with virtual defs/uses (i.e., memory accesses) are analyzed elsewhere. */ if (!is_gimple_reg (SSA_NAME_VAR (PHI_RESULT (phi)))) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "virtual phi. skip."); continue; } /* Skip reduction phis. */ if (STMT_VINFO_DEF_TYPE (vinfo_for_stmt (phi)) == vect_reduction_def) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "reduc phi. skip."); continue; } /* Analyze the evolution function. */ access_fn = instantiate_parameters (loop, analyze_scalar_evolution (loop, PHI_RESULT (phi))); if (!access_fn) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "No Access function."); return false; } if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Access function of PHI: "); print_generic_expr (vect_dump, access_fn, TDF_SLIM); } evolution_part = evolution_part_in_loop_num (access_fn, loop->num); if (evolution_part == NULL_TREE) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "No evolution."); return false; } /* FORNOW: We do not transform initial conditions of IVs which evolution functions are a polynomial of degree >= 2. */ if (tree_is_chrec (evolution_part)) return false; } return true; } /* Function vect_get_loop_niters. Determine how many iterations the loop is executed. If an expression that represents the number of iterations can be constructed, place it in NUMBER_OF_ITERATIONS. Return the loop exit condition. */ static tree vect_get_loop_niters (struct loop *loop, tree *number_of_iterations) { tree niters; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== get_loop_niters ==="); niters = number_of_exit_cond_executions (loop); if (niters != NULL_TREE && niters != chrec_dont_know) { *number_of_iterations = niters; if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "==> get_loop_niters:" ); print_generic_expr (vect_dump, *number_of_iterations, TDF_SLIM); } } return get_loop_exit_condition (loop); } /* Function vect_analyze_loop_form. Verify the following restrictions (some may be relaxed in the future): - it's an inner-most loop - number of BBs = 2 (which are the loop header and the latch) - the loop has a pre-header - the loop has a single entry and exit - the loop exit condition is simple enough, and the number of iterations can be analyzed (a countable loop). */ static loop_vec_info vect_analyze_loop_form (struct loop *loop) { loop_vec_info loop_vinfo; tree loop_cond; tree number_of_iterations = NULL; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "=== vect_analyze_loop_form ==="); if (loop->inner) { if (vect_print_dump_info (REPORT_OUTER_LOOPS)) fprintf (vect_dump, "not vectorized: nested loop."); return NULL; } if (!single_exit (loop) || loop->num_nodes != 2 || EDGE_COUNT (loop->header->preds) != 2) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) { if (!single_exit (loop)) fprintf (vect_dump, "not vectorized: multiple exits."); else if (loop->num_nodes != 2) fprintf (vect_dump, "not vectorized: too many BBs in loop."); else if (EDGE_COUNT (loop->header->preds) != 2) fprintf (vect_dump, "not vectorized: too many incoming edges."); } return NULL; } /* We assume that the loop exit condition is at the end of the loop. i.e, that the loop is represented as a do-while (with a proper if-guard before the loop if needed), where the loop header contains all the executable statements, and the latch is empty. */ if (!empty_block_p (loop->latch) || phi_nodes (loop->latch)) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "not vectorized: unexpected loop form."); return NULL; } /* Make sure there exists a single-predecessor exit bb: */ if (!single_pred_p (single_exit (loop)->dest)) { edge e = single_exit (loop); if (!(e->flags & EDGE_ABNORMAL)) { split_loop_exit_edge (e); if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "split exit edge."); } else { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "not vectorized: abnormal loop exit edge."); return NULL; } } if (empty_block_p (loop->header)) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "not vectorized: empty loop."); return NULL; } loop_cond = vect_get_loop_niters (loop, &number_of_iterations); if (!loop_cond) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "not vectorized: complicated exit condition."); return NULL; } if (!number_of_iterations) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "not vectorized: number of iterations cannot be computed."); return NULL; } if (chrec_contains_undetermined (number_of_iterations)) { if (vect_print_dump_info (REPORT_BAD_FORM_LOOPS)) fprintf (vect_dump, "Infinite number of iterations."); return false; } loop_vinfo = new_loop_vec_info (loop); LOOP_VINFO_NITERS (loop_vinfo) = number_of_iterations; if (!LOOP_VINFO_NITERS_KNOWN_P (loop_vinfo)) { if (vect_print_dump_info (REPORT_DETAILS)) { fprintf (vect_dump, "Symbolic number of iterations is "); print_generic_expr (vect_dump, number_of_iterations, TDF_DETAILS); } } else if (LOOP_VINFO_INT_NITERS (loop_vinfo) == 0) { if (vect_print_dump_info (REPORT_UNVECTORIZED_LOOPS)) fprintf (vect_dump, "not vectorized: number of iterations = 0."); return NULL; } LOOP_VINFO_EXIT_COND (loop_vinfo) = loop_cond; return loop_vinfo; } /* Function vect_analyze_loop. Apply a set of analyses on LOOP, and create a loop_vec_info struct for it. The different analyses will record information in the loop_vec_info struct. */ loop_vec_info vect_analyze_loop (struct loop *loop) { bool ok; loop_vec_info loop_vinfo; if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "===== analyze_loop_nest ====="); /* Check the CFG characteristics of the loop (nesting, entry/exit, etc. */ loop_vinfo = vect_analyze_loop_form (loop); if (!loop_vinfo) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad loop form."); return NULL; } /* Find all data references in the loop (which correspond to vdefs/vuses) and analyze their evolution in the loop. FORNOW: Handle only simple, array references, which alignment can be forced, and aligned pointer-references. */ ok = vect_analyze_data_refs (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data references."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* Classify all cross-iteration scalar data-flow cycles. Cross-iteration cycles caused by virtual phis are analyzed separately. */ vect_analyze_scalar_cycles (loop_vinfo); vect_pattern_recog (loop_vinfo); /* Data-flow analysis to detect stmts that do not need to be vectorized. */ ok = vect_mark_stmts_to_be_vectorized (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "unexpected pattern."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* Analyze the alignment of the data-refs in the loop. Fail if a data reference is found that cannot be vectorized. */ ok = vect_analyze_data_refs_alignment (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data alignment."); destroy_loop_vec_info (loop_vinfo); return NULL; } ok = vect_determine_vectorization_factor (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "can't determine vectorization factor."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* Analyze data dependences between the data-refs in the loop. FORNOW: fail at the first data dependence that we encounter. */ ok = vect_analyze_data_ref_dependences (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data dependence."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* Analyze the access patterns of the data-refs in the loop (consecutive, complex, etc.). FORNOW: Only handle consecutive access pattern. */ ok = vect_analyze_data_ref_accesses (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data access."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* This pass will decide on using loop versioning and/or loop peeling in order to enhance the alignment of data references in the loop. */ ok = vect_enhance_data_refs_alignment (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad data alignment."); destroy_loop_vec_info (loop_vinfo); return NULL; } /* Scan all the operations in the loop and make sure they are vectorizable. */ ok = vect_analyze_operations (loop_vinfo); if (!ok) { if (vect_print_dump_info (REPORT_DETAILS)) fprintf (vect_dump, "bad operation or unsupported loop bound."); destroy_loop_vec_info (loop_vinfo); return NULL; } LOOP_VINFO_VECTORIZABLE_P (loop_vinfo) = 1; return loop_vinfo; }