/* Data references and dependences detectors. Copyright (C) 2003, 2004, 2005 Free Software Foundation, Inc. Contributed by Sebastian Pop 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. */ /* This pass walks a given loop structure searching for array references. The information about the array accesses is recorded in DATA_REFERENCE structures. The basic test for determining the dependences is: given two access functions chrec1 and chrec2 to a same array, and x and y two vectors from the iteration domain, the same element of the array is accessed twice at iterations x and y if and only if: | chrec1 (x) == chrec2 (y). The goals of this analysis are: - to determine the independence: the relation between two independent accesses is qualified with the chrec_known (this information allows a loop parallelization), - when two data references access the same data, to qualify the dependence relation with classic dependence representations: - distance vectors - direction vectors - loop carried level dependence - polyhedron dependence or with the chains of recurrences based representation, - to define a knowledge base for storing the data dependence information, - to define an interface to access this data. Definitions: - subscript: given two array accesses a subscript is the tuple composed of the access functions for a given dimension. Example: Given A[f1][f2][f3] and B[g1][g2][g3], there are three subscripts: (f1, g1), (f2, g2), (f3, g3). - Diophantine equation: an equation whose coefficients and solutions are integer constants, for example the equation | 3*x + 2*y = 1 has an integer solution x = 1 and y = -1. References: - "Advanced Compilation for High Performance Computing" by Randy Allen and Ken Kennedy. http://citeseer.ist.psu.edu/goff91practical.html - "Loop Transformations for Restructuring Compilers - The Foundations" by Utpal Banerjee. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "ggc.h" #include "tree.h" /* These RTL headers are needed for basic-block.h. */ #include "rtl.h" #include "basic-block.h" #include "diagnostic.h" #include "tree-flow.h" #include "tree-dump.h" #include "timevar.h" #include "cfgloop.h" #include "tree-chrec.h" #include "tree-data-ref.h" #include "tree-scalar-evolution.h" #include "tree-pass.h" static tree object_analysis (tree, tree, bool, struct data_reference **, tree *, tree *, tree *, tree *, tree *, struct ptr_info_def **, subvar_t *); static struct data_reference * init_data_ref (tree, tree, tree, tree, bool, tree, tree, tree, tree, tree, struct ptr_info_def *, enum data_ref_type); /* Determine if PTR and DECL may alias, the result is put in ALIASED. Return FALSE if there is no type memory tag for PTR. */ static bool ptr_decl_may_alias_p (tree ptr, tree decl, struct data_reference *ptr_dr, bool *aliased) { tree tag; gcc_assert (TREE_CODE (ptr) == SSA_NAME && DECL_P (decl)); tag = get_var_ann (SSA_NAME_VAR (ptr))->type_mem_tag; if (!tag) tag = DR_MEMTAG (ptr_dr); if (!tag) return false; *aliased = is_aliased_with (tag, decl); return true; } /* Determine if two pointers may alias, the result is put in ALIASED. Return FALSE if there is no type memory tag for one of the pointers. */ static bool ptr_ptr_may_alias_p (tree ptr_a, tree ptr_b, struct data_reference *dra, struct data_reference *drb, bool *aliased) { tree tag_a, tag_b; tag_a = get_var_ann (SSA_NAME_VAR (ptr_a))->type_mem_tag; if (!tag_a) tag_a = DR_MEMTAG (dra); if (!tag_a) return false; tag_b = get_var_ann (SSA_NAME_VAR (ptr_b))->type_mem_tag; if (!tag_b) tag_b = DR_MEMTAG (drb); if (!tag_b) return false; *aliased = (tag_a == tag_b); return true; } /* Determine if BASE_A and BASE_B may alias, the result is put in ALIASED. Return FALSE if there is no type memory tag for one of the symbols. */ static bool may_alias_p (tree base_a, tree base_b, struct data_reference *dra, struct data_reference *drb, bool *aliased) { if (TREE_CODE (base_a) == ADDR_EXPR || TREE_CODE (base_b) == ADDR_EXPR) { if (TREE_CODE (base_a) == ADDR_EXPR && TREE_CODE (base_b) == ADDR_EXPR) { *aliased = (TREE_OPERAND (base_a, 0) == TREE_OPERAND (base_b, 0)); return true; } if (TREE_CODE (base_a) == ADDR_EXPR) return ptr_decl_may_alias_p (base_b, TREE_OPERAND (base_a, 0), drb, aliased); else return ptr_decl_may_alias_p (base_a, TREE_OPERAND (base_b, 0), dra, aliased); } return ptr_ptr_may_alias_p (base_a, base_b, dra, drb, aliased); } /* Determine if a pointer (BASE_A) and a record/union access (BASE_B) are not aliased. Return TRUE if they differ. */ static bool record_ptr_differ_p (struct data_reference *dra, struct data_reference *drb) { bool aliased; tree base_a = DR_BASE_OBJECT (dra); tree base_b = DR_BASE_OBJECT (drb); if (TREE_CODE (base_b) != COMPONENT_REF) return false; /* Peel COMPONENT_REFs to get to the base. Do not peel INDIRECT_REFs. For a.b.c.d[i] we will get a, and for a.b->c.d[i] we will get a.b. Probably will be unnecessary with struct alias analysis. */ while (TREE_CODE (base_b) == COMPONENT_REF) base_b = TREE_OPERAND (base_b, 0); /* Compare a record/union access (b.c[i] or p->c[i]) and a pointer ((*q)[i]). */ if (TREE_CODE (base_a) == INDIRECT_REF && ((TREE_CODE (base_b) == VAR_DECL && (ptr_decl_may_alias_p (TREE_OPERAND (base_a, 0), base_b, dra, &aliased) && !aliased)) || (TREE_CODE (base_b) == INDIRECT_REF && (ptr_ptr_may_alias_p (TREE_OPERAND (base_a, 0), TREE_OPERAND (base_b, 0), dra, drb, &aliased) && !aliased)))) return true; else return false; } /* Determine if an array access (BASE_A) and a record/union access (BASE_B) are not aliased. Return TRUE if they differ. */ static bool record_array_differ_p (struct data_reference *dra, struct data_reference *drb) { bool aliased; tree base_a = DR_BASE_OBJECT (dra); tree base_b = DR_BASE_OBJECT (drb); if (TREE_CODE (base_b) != COMPONENT_REF) return false; /* Peel COMPONENT_REFs to get to the base. Do not peel INDIRECT_REFs. For a.b.c.d[i] we will get a, and for a.b->c.d[i] we will get a.b. Probably will be unnecessary with struct alias analysis. */ while (TREE_CODE (base_b) == COMPONENT_REF) base_b = TREE_OPERAND (base_b, 0); /* Compare a record/union access (b.c[i] or p->c[i]) and an array access (a[i]). In case of p->c[i] use alias analysis to verify that p is not pointing to a. */ if (TREE_CODE (base_a) == VAR_DECL && (TREE_CODE (base_b) == VAR_DECL || (TREE_CODE (base_b) == INDIRECT_REF && (ptr_decl_may_alias_p (TREE_OPERAND (base_b, 0), base_a, drb, &aliased) && !aliased)))) return true; else return false; } /* Determine if an array access (BASE_A) and a pointer (BASE_B) are not aliased. Return TRUE if they differ. */ static bool array_ptr_differ_p (tree base_a, tree base_b, struct data_reference *drb) { bool aliased; /* In case one of the bases is a pointer (a[i] and (*p)[i]), we check with the help of alias analysis that p is not pointing to a. */ if (TREE_CODE (base_a) == VAR_DECL && TREE_CODE (base_b) == INDIRECT_REF && (ptr_decl_may_alias_p (TREE_OPERAND (base_b, 0), base_a, drb, &aliased) && !aliased)) return true; else return false; } /* This is the simplest data dependence test: determines whether the data references A and B access the same array/region. Returns false when the property is not computable at compile time. Otherwise return true, and DIFFER_P will record the result. This utility will not be necessary when alias_sets_conflict_p will be less conservative. */ static bool base_object_differ_p (struct data_reference *a, struct data_reference *b, bool *differ_p) { tree base_a = DR_BASE_OBJECT (a); tree base_b = DR_BASE_OBJECT (b); bool aliased; if (!base_a || !base_b) return false; /* Determine if same base. Example: for the array accesses a[i], b[i] or pointer accesses *a, *b, bases are a, b. */ if (base_a == base_b) { *differ_p = false; return true; } /* For pointer based accesses, (*p)[i], (*q)[j], the bases are (*p) and (*q) */ if (TREE_CODE (base_a) == INDIRECT_REF && TREE_CODE (base_b) == INDIRECT_REF && TREE_OPERAND (base_a, 0) == TREE_OPERAND (base_b, 0)) { *differ_p = false; return true; } /* Record/union based accesses - s.a[i], t.b[j]. bases are s.a,t.b. */ if (TREE_CODE (base_a) == COMPONENT_REF && TREE_CODE (base_b) == COMPONENT_REF && TREE_OPERAND (base_a, 0) == TREE_OPERAND (base_b, 0) && TREE_OPERAND (base_a, 1) == TREE_OPERAND (base_b, 1)) { *differ_p = false; return true; } /* Determine if different bases. */ /* At this point we know that base_a != base_b. However, pointer accesses of the form x=(*p) and y=(*q), whose bases are p and q, may still be pointing to the same base. In SSAed GIMPLE p and q will be SSA_NAMES in this case. Therefore, here we check if they are really two different declarations. */ if (TREE_CODE (base_a) == VAR_DECL && TREE_CODE (base_b) == VAR_DECL) { *differ_p = true; return true; } /* In case one of the bases is a pointer (a[i] and (*p)[i]), we check with the help of alias analysis that p is not pointing to a. */ if (array_ptr_differ_p (base_a, base_b, b) || array_ptr_differ_p (base_b, base_a, a)) { *differ_p = true; return true; } /* If the bases are pointers ((*q)[i] and (*p)[i]), we check with the help of alias analysis they don't point to the same bases. */ if (TREE_CODE (base_a) == INDIRECT_REF && TREE_CODE (base_b) == INDIRECT_REF && (may_alias_p (TREE_OPERAND (base_a, 0), TREE_OPERAND (base_b, 0), a, b, &aliased) && !aliased)) { *differ_p = true; return true; } /* Compare two record/union bases s.a and t.b: s != t or (a != b and s and t are not unions). */ if (TREE_CODE (base_a) == COMPONENT_REF && TREE_CODE (base_b) == COMPONENT_REF && ((TREE_CODE (TREE_OPERAND (base_a, 0)) == VAR_DECL && TREE_CODE (TREE_OPERAND (base_b, 0)) == VAR_DECL && TREE_OPERAND (base_a, 0) != TREE_OPERAND (base_b, 0)) || (TREE_CODE (TREE_TYPE (TREE_OPERAND (base_a, 0))) == RECORD_TYPE && TREE_CODE (TREE_TYPE (TREE_OPERAND (base_b, 0))) == RECORD_TYPE && TREE_OPERAND (base_a, 1) != TREE_OPERAND (base_b, 1)))) { *differ_p = true; return true; } /* Compare a record/union access (b.c[i] or p->c[i]) and a pointer ((*q)[i]). */ if (record_ptr_differ_p (a, b) || record_ptr_differ_p (b, a)) { *differ_p = true; return true; } /* Compare a record/union access (b.c[i] or p->c[i]) and an array access (a[i]). In case of p->c[i] use alias analysis to verify that p is not pointing to a. */ if (record_array_differ_p (a, b) || record_array_differ_p (b, a)) { *differ_p = true; return true; } return false; } /* Function base_addr_differ_p. This is the simplest data dependence test: determines whether the data references DRA and DRB access the same array/region. Returns false when the property is not computable at compile time. Otherwise return true, and DIFFER_P will record the result. The algorithm: 1. if (both DRA and DRB are represented as arrays) compare DRA.BASE_OBJECT and DRB.BASE_OBJECT 2. else if (both DRA and DRB are represented as pointers) try to prove that DRA.FIRST_LOCATION == DRB.FIRST_LOCATION 3. else if (DRA and DRB are represented differently or 2. fails) only try to prove that the bases are surely different */ static bool base_addr_differ_p (struct data_reference *dra, struct data_reference *drb, bool *differ_p) { tree addr_a = DR_BASE_ADDRESS (dra); tree addr_b = DR_BASE_ADDRESS (drb); tree type_a, type_b; bool aliased; if (!addr_a || !addr_b) return false; type_a = TREE_TYPE (addr_a); type_b = TREE_TYPE (addr_b); gcc_assert (POINTER_TYPE_P (type_a) && POINTER_TYPE_P (type_b)); /* 1. if (both DRA and DRB are represented as arrays) compare DRA.BASE_OBJECT and DRB.BASE_OBJECT. */ if (DR_TYPE (dra) == ARRAY_REF_TYPE && DR_TYPE (drb) == ARRAY_REF_TYPE) return base_object_differ_p (dra, drb, differ_p); /* 2. else if (both DRA and DRB are represented as pointers) try to prove that DRA.FIRST_LOCATION == DRB.FIRST_LOCATION. */ /* If base addresses are the same, we check the offsets, since the access of the data-ref is described by {base addr + offset} and its access function, i.e., in order to decide whether the bases of data-refs are the same we compare both base addresses and offsets. */ if (DR_TYPE (dra) == POINTER_REF_TYPE && DR_TYPE (drb) == POINTER_REF_TYPE && (addr_a == addr_b || (TREE_CODE (addr_a) == ADDR_EXPR && TREE_CODE (addr_b) == ADDR_EXPR && TREE_OPERAND (addr_a, 0) == TREE_OPERAND (addr_b, 0)))) { /* Compare offsets. */ tree offset_a = DR_OFFSET (dra); tree offset_b = DR_OFFSET (drb); STRIP_NOPS (offset_a); STRIP_NOPS (offset_b); /* FORNOW: we only compare offsets that are MULT_EXPR, i.e., we don't handle PLUS_EXPR. */ if ((offset_a == offset_b) || (TREE_CODE (offset_a) == MULT_EXPR && TREE_CODE (offset_b) == MULT_EXPR && TREE_OPERAND (offset_a, 0) == TREE_OPERAND (offset_b, 0) && TREE_OPERAND (offset_a, 1) == TREE_OPERAND (offset_b, 1))) { *differ_p = false; return true; } } /* 3. else if (DRA and DRB are represented differently or 2. fails) only try to prove that the bases are surely different. */ /* Apply alias analysis. */ if (may_alias_p (addr_a, addr_b, dra, drb, &aliased) && !aliased) { *differ_p = true; return true; } /* An instruction writing through a restricted pointer is "independent" of any instruction reading or writing through a different pointer, in the same block/scope. */ else if ((TYPE_RESTRICT (type_a) && !DR_IS_READ (dra)) || (TYPE_RESTRICT (type_b) && !DR_IS_READ (drb))) { *differ_p = true; return true; } return false; } /* Returns true iff A divides B. */ static inline bool tree_fold_divides_p (tree a, tree b) { /* Determines whether (A == gcd (A, B)). */ return tree_int_cst_equal (a, tree_fold_gcd (a, b)); } /* Compute the greatest common denominator of two numbers using Euclid's algorithm. */ static int gcd (int a, int b) { int x, y, z; x = abs (a); y = abs (b); while (x>0) { z = y % x; y = x; x = z; } return (y); } /* Returns true iff A divides B. */ static inline bool int_divides_p (int a, int b) { return ((b % a) == 0); } /* Dump into FILE all the data references from DATAREFS. */ void dump_data_references (FILE *file, varray_type datarefs) { unsigned int i; for (i = 0; i < VARRAY_ACTIVE_SIZE (datarefs); i++) dump_data_reference (file, VARRAY_GENERIC_PTR (datarefs, i)); } /* Dump into FILE all the dependence relations from DDR. */ void dump_data_dependence_relations (FILE *file, varray_type ddr) { unsigned int i; for (i = 0; i < VARRAY_ACTIVE_SIZE (ddr); i++) dump_data_dependence_relation (file, VARRAY_GENERIC_PTR (ddr, i)); } /* Dump function for a DATA_REFERENCE structure. */ void dump_data_reference (FILE *outf, struct data_reference *dr) { unsigned int i; fprintf (outf, "(Data Ref: \n stmt: "); print_generic_stmt (outf, DR_STMT (dr), 0); fprintf (outf, " ref: "); print_generic_stmt (outf, DR_REF (dr), 0); fprintf (outf, " base_name: "); print_generic_stmt (outf, DR_BASE_OBJECT (dr), 0); for (i = 0; i < DR_NUM_DIMENSIONS (dr); i++) { fprintf (outf, " Access function %d: ", i); print_generic_stmt (outf, DR_ACCESS_FN (dr, i), 0); } fprintf (outf, ")\n"); } /* Dump function for a SUBSCRIPT structure. */ void dump_subscript (FILE *outf, struct subscript *subscript) { tree chrec = SUB_CONFLICTS_IN_A (subscript); fprintf (outf, "\n (subscript \n"); fprintf (outf, " iterations_that_access_an_element_twice_in_A: "); print_generic_stmt (outf, chrec, 0); if (chrec == chrec_known) fprintf (outf, " (no dependence)\n"); else if (chrec_contains_undetermined (chrec)) fprintf (outf, " (don't know)\n"); else { tree last_iteration = SUB_LAST_CONFLICT (subscript); fprintf (outf, " last_conflict: "); print_generic_stmt (outf, last_iteration, 0); } chrec = SUB_CONFLICTS_IN_B (subscript); fprintf (outf, " iterations_that_access_an_element_twice_in_B: "); print_generic_stmt (outf, chrec, 0); if (chrec == chrec_known) fprintf (outf, " (no dependence)\n"); else if (chrec_contains_undetermined (chrec)) fprintf (outf, " (don't know)\n"); else { tree last_iteration = SUB_LAST_CONFLICT (subscript); fprintf (outf, " last_conflict: "); print_generic_stmt (outf, last_iteration, 0); } fprintf (outf, " (Subscript distance: "); print_generic_stmt (outf, SUB_DISTANCE (subscript), 0); fprintf (outf, " )\n"); fprintf (outf, " )\n"); } /* Dump function for a DATA_DEPENDENCE_RELATION structure. */ void dump_data_dependence_relation (FILE *outf, struct data_dependence_relation *ddr) { struct data_reference *dra, *drb; dra = DDR_A (ddr); drb = DDR_B (ddr); fprintf (outf, "(Data Dep: \n"); if (DDR_ARE_DEPENDENT (ddr) == chrec_dont_know) fprintf (outf, " (don't know)\n"); else if (DDR_ARE_DEPENDENT (ddr) == chrec_known) fprintf (outf, " (no dependence)\n"); else if (DDR_ARE_DEPENDENT (ddr) == NULL_TREE) { unsigned int i; for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { fprintf (outf, " access_fn_A: "); print_generic_stmt (outf, DR_ACCESS_FN (dra, i), 0); fprintf (outf, " access_fn_B: "); print_generic_stmt (outf, DR_ACCESS_FN (drb, i), 0); dump_subscript (outf, DDR_SUBSCRIPT (ddr, i)); } for (i = 0; i < DDR_NUM_DIST_VECTS (ddr); i++) { fprintf (outf, " distance_vector: "); print_lambda_vector (outf, DDR_DIST_VECT (ddr, i), DDR_SIZE_VECT (ddr)); } for (i = 0; i < DDR_NUM_DIR_VECTS (ddr); i++) { fprintf (outf, " direction_vector: "); print_lambda_vector (outf, DDR_DIR_VECT (ddr, i), DDR_SIZE_VECT (ddr)); } } fprintf (outf, ")\n"); } /* Dump function for a DATA_DEPENDENCE_DIRECTION structure. */ void dump_data_dependence_direction (FILE *file, enum data_dependence_direction dir) { switch (dir) { case dir_positive: fprintf (file, "+"); break; case dir_negative: fprintf (file, "-"); break; case dir_equal: fprintf (file, "="); break; case dir_positive_or_negative: fprintf (file, "+-"); break; case dir_positive_or_equal: fprintf (file, "+="); break; case dir_negative_or_equal: fprintf (file, "-="); break; case dir_star: fprintf (file, "*"); break; default: break; } } /* Dumps the distance and direction vectors in FILE. DDRS contains the dependence relations, and VECT_SIZE is the size of the dependence vectors, or in other words the number of loops in the considered nest. */ void dump_dist_dir_vectors (FILE *file, varray_type ddrs) { unsigned int i, j; for (i = 0; i < VARRAY_ACTIVE_SIZE (ddrs); i++) { struct data_dependence_relation *ddr = (struct data_dependence_relation *) VARRAY_GENERIC_PTR (ddrs, i); if (DDR_ARE_DEPENDENT (ddr) == NULL_TREE && DDR_AFFINE_P (ddr)) { for (j = 0; j < DDR_NUM_DIST_VECTS (ddr); j++) { fprintf (file, "DISTANCE_V ("); print_lambda_vector (file, DDR_DIST_VECT (ddr, j), DDR_SIZE_VECT (ddr)); fprintf (file, ")\n"); } for (j = 0; j < DDR_NUM_DIR_VECTS (ddr); j++) { fprintf (file, "DIRECTION_V ("); print_lambda_vector (file, DDR_DIR_VECT (ddr, j), DDR_SIZE_VECT (ddr)); fprintf (file, ")\n"); } } } fprintf (file, "\n\n"); } /* Dumps the data dependence relations DDRS in FILE. */ void dump_ddrs (FILE *file, varray_type ddrs) { unsigned int i; for (i = 0; i < VARRAY_ACTIVE_SIZE (ddrs); i++) { struct data_dependence_relation *ddr = (struct data_dependence_relation *) VARRAY_GENERIC_PTR (ddrs, i); dump_data_dependence_relation (file, ddr); } fprintf (file, "\n\n"); } /* Estimate the number of iterations from the size of the data and the access functions. */ static void estimate_niter_from_size_of_data (struct loop *loop, tree opnd0, tree access_fn, tree stmt) { tree estimation = NULL_TREE; tree array_size, data_size, element_size; tree init, step; init = initial_condition (access_fn); step = evolution_part_in_loop_num (access_fn, loop->num); array_size = TYPE_SIZE (TREE_TYPE (opnd0)); element_size = TYPE_SIZE (TREE_TYPE (TREE_TYPE (opnd0))); if (array_size == NULL_TREE || TREE_CODE (array_size) != INTEGER_CST || TREE_CODE (element_size) != INTEGER_CST) return; data_size = fold_build2 (EXACT_DIV_EXPR, integer_type_node, array_size, element_size); if (init != NULL_TREE && step != NULL_TREE && TREE_CODE (init) == INTEGER_CST && TREE_CODE (step) == INTEGER_CST) { tree i_plus_s = fold_build2 (PLUS_EXPR, integer_type_node, init, step); tree sign = fold_build2 (GT_EXPR, boolean_type_node, i_plus_s, init); if (sign == boolean_true_node) estimation = fold_build2 (CEIL_DIV_EXPR, integer_type_node, fold_build2 (MINUS_EXPR, integer_type_node, data_size, init), step); /* When the step is negative, as in PR23386: (init = 3, step = 0ffffffff, data_size = 100), we have to compute the estimation as ceil_div (init, 0 - step) + 1. */ else if (sign == boolean_false_node) estimation = fold_build2 (PLUS_EXPR, integer_type_node, fold_build2 (CEIL_DIV_EXPR, integer_type_node, init, fold_build2 (MINUS_EXPR, unsigned_type_node, integer_zero_node, step)), integer_one_node); if (estimation) record_estimate (loop, estimation, boolean_true_node, stmt); } } /* Given an ARRAY_REF node REF, records its access functions. Example: given A[i][3], record in ACCESS_FNS the opnd1 function, i.e. the constant "3", then recursively call the function on opnd0, i.e. the ARRAY_REF "A[i]". If ESTIMATE_ONLY is true, we just set the estimated number of loop iterations, we don't store the access function. The function returns the base name: "A". */ static tree analyze_array_indexes (struct loop *loop, VEC(tree,heap) **access_fns, tree ref, tree stmt, bool estimate_only) { tree opnd0, opnd1; tree access_fn; opnd0 = TREE_OPERAND (ref, 0); opnd1 = TREE_OPERAND (ref, 1); /* The detection of the evolution function for this data access is postponed until the dependence test. This lazy strategy avoids the computation of access functions that are of no interest for the optimizers. */ access_fn = instantiate_parameters (loop, analyze_scalar_evolution (loop, opnd1)); if (estimate_only && chrec_contains_undetermined (loop->estimated_nb_iterations)) estimate_niter_from_size_of_data (loop, opnd0, access_fn, stmt); if (!estimate_only) VEC_safe_push (tree, heap, *access_fns, access_fn); /* Recursively record other array access functions. */ if (TREE_CODE (opnd0) == ARRAY_REF) return analyze_array_indexes (loop, access_fns, opnd0, stmt, estimate_only); /* Return the base name of the data access. */ else return opnd0; } /* For an array reference REF contained in STMT, attempt to bound the number of iterations in the loop containing STMT */ void estimate_iters_using_array (tree stmt, tree ref) { analyze_array_indexes (loop_containing_stmt (stmt), NULL, ref, stmt, true); } /* For a data reference REF contained in the statement STMT, initialize a DATA_REFERENCE structure, and return it. IS_READ flag has to be set to true when REF is in the right hand side of an assignment. */ struct data_reference * analyze_array (tree stmt, tree ref, bool is_read) { struct data_reference *res; VEC(tree,heap) *acc_fns; if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(analyze_array \n"); fprintf (dump_file, " (ref = "); print_generic_stmt (dump_file, ref, 0); fprintf (dump_file, ")\n"); } res = xmalloc (sizeof (struct data_reference)); DR_STMT (res) = stmt; DR_REF (res) = ref; acc_fns = VEC_alloc (tree, heap, 3); DR_BASE_OBJECT (res) = analyze_array_indexes (loop_containing_stmt (stmt), &acc_fns, ref, stmt, false); DR_TYPE (res) = ARRAY_REF_TYPE; DR_SET_ACCESS_FNS (res, acc_fns); DR_IS_READ (res) = is_read; DR_BASE_ADDRESS (res) = NULL_TREE; DR_OFFSET (res) = NULL_TREE; DR_INIT (res) = NULL_TREE; DR_STEP (res) = NULL_TREE; DR_OFFSET_MISALIGNMENT (res) = NULL_TREE; DR_MEMTAG (res) = NULL_TREE; DR_PTR_INFO (res) = NULL; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); return res; } /* Analyze an indirect memory reference, REF, that comes from STMT. IS_READ is true if this is an indirect load, and false if it is an indirect store. Return a new data reference structure representing the indirect_ref, or NULL if we cannot describe the access function. */ static struct data_reference * analyze_indirect_ref (tree stmt, tree ref, bool is_read) { struct loop *loop = loop_containing_stmt (stmt); tree ptr_ref = TREE_OPERAND (ref, 0); tree access_fn = analyze_scalar_evolution (loop, ptr_ref); tree init = initial_condition_in_loop_num (access_fn, loop->num); tree base_address = NULL_TREE, evolution, step = NULL_TREE; struct ptr_info_def *ptr_info = NULL; if (TREE_CODE (ptr_ref) == SSA_NAME) ptr_info = SSA_NAME_PTR_INFO (ptr_ref); STRIP_NOPS (init); if (access_fn == chrec_dont_know || !init || init == chrec_dont_know) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nBad access function of ptr: "); print_generic_expr (dump_file, ref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL; } if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nAccess function of ptr: "); print_generic_expr (dump_file, access_fn, TDF_SLIM); fprintf (dump_file, "\n"); } if (!expr_invariant_in_loop_p (loop, init)) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\ninitial condition is not loop invariant.\n"); } else { base_address = init; evolution = evolution_part_in_loop_num (access_fn, loop->num); if (evolution != chrec_dont_know) { if (!evolution) step = ssize_int (0); else { if (TREE_CODE (evolution) == INTEGER_CST) step = fold_convert (ssizetype, evolution); else if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\nnon constant step for ptr access.\n"); } } else if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\nunknown evolution of ptr.\n"); } return init_data_ref (stmt, ref, NULL_TREE, access_fn, is_read, base_address, NULL_TREE, step, NULL_TREE, NULL_TREE, ptr_info, POINTER_REF_TYPE); } /* For a data reference REF contained in the statement STMT, initialize a DATA_REFERENCE structure, and return it. */ struct data_reference * init_data_ref (tree stmt, tree ref, tree base, tree access_fn, bool is_read, tree base_address, tree init_offset, tree step, tree misalign, tree memtag, struct ptr_info_def *ptr_info, enum data_ref_type type) { struct data_reference *res; VEC(tree,heap) *acc_fns; if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(init_data_ref \n"); fprintf (dump_file, " (ref = "); print_generic_stmt (dump_file, ref, 0); fprintf (dump_file, ")\n"); } res = xmalloc (sizeof (struct data_reference)); DR_STMT (res) = stmt; DR_REF (res) = ref; DR_BASE_OBJECT (res) = base; DR_TYPE (res) = type; acc_fns = VEC_alloc (tree, heap, 3); DR_SET_ACCESS_FNS (res, acc_fns); VEC_quick_push (tree, DR_ACCESS_FNS (res), access_fn); DR_IS_READ (res) = is_read; DR_BASE_ADDRESS (res) = base_address; DR_OFFSET (res) = init_offset; DR_INIT (res) = NULL_TREE; DR_STEP (res) = step; DR_OFFSET_MISALIGNMENT (res) = misalign; DR_MEMTAG (res) = memtag; DR_PTR_INFO (res) = ptr_info; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); return res; } /* Function strip_conversions Strip conversions that don't narrow the mode. */ static tree strip_conversion (tree expr) { tree to, ti, oprnd0; while (TREE_CODE (expr) == NOP_EXPR || TREE_CODE (expr) == CONVERT_EXPR) { to = TREE_TYPE (expr); oprnd0 = TREE_OPERAND (expr, 0); ti = TREE_TYPE (oprnd0); if (!INTEGRAL_TYPE_P (to) || !INTEGRAL_TYPE_P (ti)) return NULL_TREE; if (GET_MODE_SIZE (TYPE_MODE (to)) < GET_MODE_SIZE (TYPE_MODE (ti))) return NULL_TREE; expr = oprnd0; } return expr; } /* Function analyze_offset_expr Given an offset expression EXPR received from get_inner_reference, analyze it and create an expression for INITIAL_OFFSET by substituting the variables of EXPR with initial_condition of the corresponding access_fn in the loop. E.g., for i for (j = 3; j < N; j++) a[j].b[i][j] = 0; For a[j].b[i][j], EXPR will be 'i * C_i + j * C_j + C'. 'i' cannot be substituted, since its access_fn in the inner loop is i. 'j' will be substituted with 3. An INITIAL_OFFSET will be 'i * C_i + C`', where C` = 3 * C_j + C. Compute MISALIGN (the misalignment of the data reference initial access from its base). Misalignment can be calculated only if all the variables can be substituted with constants, otherwise, we record maximum possible alignment in ALIGNED_TO. In the above example, since 'i' cannot be substituted, MISALIGN will be NULL_TREE, and the biggest divider of C_i (a power of 2) will be recorded in ALIGNED_TO. STEP is an evolution of the data reference in this loop in bytes. In the above example, STEP is C_j. Return FALSE, if the analysis fails, e.g., there is no access_fn for a variable. In this case, all the outputs (INITIAL_OFFSET, MISALIGN, ALIGNED_TO and STEP) are NULL_TREEs. Otherwise, return TRUE. */ static bool analyze_offset_expr (tree expr, struct loop *loop, tree *initial_offset, tree *misalign, tree *aligned_to, tree *step) { tree oprnd0; tree oprnd1; tree left_offset = ssize_int (0); tree right_offset = ssize_int (0); tree left_misalign = ssize_int (0); tree right_misalign = ssize_int (0); tree left_step = ssize_int (0); tree right_step = ssize_int (0); enum tree_code code; tree init, evolution; tree left_aligned_to = NULL_TREE, right_aligned_to = NULL_TREE; *step = NULL_TREE; *misalign = NULL_TREE; *aligned_to = NULL_TREE; *initial_offset = NULL_TREE; /* Strip conversions that don't narrow the mode. */ expr = strip_conversion (expr); if (!expr) return false; /* Stop conditions: 1. Constant. */ if (TREE_CODE (expr) == INTEGER_CST) { *initial_offset = fold_convert (ssizetype, expr); *misalign = fold_convert (ssizetype, expr); *step = ssize_int (0); return true; } /* 2. Variable. Try to substitute with initial_condition of the corresponding access_fn in the current loop. */ if (SSA_VAR_P (expr)) { tree access_fn = analyze_scalar_evolution (loop, expr); if (access_fn == chrec_dont_know) /* No access_fn. */ return false; init = initial_condition_in_loop_num (access_fn, loop->num); if (!expr_invariant_in_loop_p (loop, init)) /* Not enough information: may be not loop invariant. E.g., for a[b[i]], we get a[D], where D=b[i]. EXPR is D, its initial_condition is D, but it depends on i - loop's induction variable. */ return false; evolution = evolution_part_in_loop_num (access_fn, loop->num); if (evolution && TREE_CODE (evolution) != INTEGER_CST) /* Evolution is not constant. */ return false; if (TREE_CODE (init) == INTEGER_CST) *misalign = fold_convert (ssizetype, init); else /* Not constant, misalignment cannot be calculated. */ *misalign = NULL_TREE; *initial_offset = fold_convert (ssizetype, init); *step = evolution ? fold_convert (ssizetype, evolution) : ssize_int (0); return true; } /* Recursive computation. */ if (!BINARY_CLASS_P (expr)) { /* We expect to get binary expressions (PLUS/MINUS and MULT). */ if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nNot binary expression "); print_generic_expr (dump_file, expr, TDF_SLIM); fprintf (dump_file, "\n"); } return false; } oprnd0 = TREE_OPERAND (expr, 0); oprnd1 = TREE_OPERAND (expr, 1); if (!analyze_offset_expr (oprnd0, loop, &left_offset, &left_misalign, &left_aligned_to, &left_step) || !analyze_offset_expr (oprnd1, loop, &right_offset, &right_misalign, &right_aligned_to, &right_step)) return false; /* The type of the operation: plus, minus or mult. */ code = TREE_CODE (expr); switch (code) { case MULT_EXPR: if (TREE_CODE (right_offset) != INTEGER_CST) /* RIGHT_OFFSET can be not constant. For example, for arrays of variable sized types. FORNOW: We don't support such cases. */ return false; /* Strip conversions that don't narrow the mode. */ left_offset = strip_conversion (left_offset); if (!left_offset) return false; /* Misalignment computation. */ if (SSA_VAR_P (left_offset)) { /* If the left side contains variables that can't be substituted with constants, the misalignment is unknown. However, if the right side is a multiple of some alignment, we know that the expression is aligned to it. Therefore, we record such maximum possible value. */ *misalign = NULL_TREE; *aligned_to = ssize_int (highest_pow2_factor (right_offset)); } else { /* The left operand was successfully substituted with constant. */ if (left_misalign) { /* In case of EXPR '(i * C1 + j) * C2', LEFT_MISALIGN is NULL_TREE. */ *misalign = size_binop (code, left_misalign, right_misalign); if (left_aligned_to && right_aligned_to) *aligned_to = size_binop (MIN_EXPR, left_aligned_to, right_aligned_to); else *aligned_to = left_aligned_to ? left_aligned_to : right_aligned_to; } else *misalign = NULL_TREE; } /* Step calculation. */ /* Multiply the step by the right operand. */ *step = size_binop (MULT_EXPR, left_step, right_offset); break; case PLUS_EXPR: case MINUS_EXPR: /* Combine the recursive calculations for step and misalignment. */ *step = size_binop (code, left_step, right_step); /* Unknown alignment. */ if ((!left_misalign && !left_aligned_to) || (!right_misalign && !right_aligned_to)) { *misalign = NULL_TREE; *aligned_to = NULL_TREE; break; } if (left_misalign && right_misalign) *misalign = size_binop (code, left_misalign, right_misalign); else *misalign = left_misalign ? left_misalign : right_misalign; if (left_aligned_to && right_aligned_to) *aligned_to = size_binop (MIN_EXPR, left_aligned_to, right_aligned_to); else *aligned_to = left_aligned_to ? left_aligned_to : right_aligned_to; break; default: gcc_unreachable (); } /* Compute offset. */ *initial_offset = fold_convert (ssizetype, fold_build2 (code, TREE_TYPE (left_offset), left_offset, right_offset)); return true; } /* Function address_analysis Return the BASE of the address expression EXPR. Also compute the OFFSET from BASE, MISALIGN and STEP. Input: EXPR - the address expression that is being analyzed STMT - the statement that contains EXPR or its original memory reference IS_READ - TRUE if STMT reads from EXPR, FALSE if writes to EXPR DR - data_reference struct for the original memory reference Output: BASE (returned value) - the base of the data reference EXPR. INITIAL_OFFSET - initial offset of EXPR from BASE (an expression) MISALIGN - offset of EXPR from BASE in bytes (a constant) or NULL_TREE if the computation is impossible ALIGNED_TO - maximum alignment of EXPR or NULL_TREE if MISALIGN can be calculated (doesn't depend on variables) STEP - evolution of EXPR in the loop If something unexpected is encountered (an unsupported form of data-ref), then NULL_TREE is returned. */ static tree address_analysis (tree expr, tree stmt, bool is_read, struct data_reference *dr, tree *offset, tree *misalign, tree *aligned_to, tree *step) { tree oprnd0, oprnd1, base_address, offset_expr, base_addr0, base_addr1; tree address_offset = ssize_int (0), address_misalign = ssize_int (0); tree dummy, address_aligned_to = NULL_TREE; struct ptr_info_def *dummy1; subvar_t dummy2; switch (TREE_CODE (expr)) { case PLUS_EXPR: case MINUS_EXPR: /* EXPR is of form {base +/- offset} (or {offset +/- base}). */ oprnd0 = TREE_OPERAND (expr, 0); oprnd1 = TREE_OPERAND (expr, 1); STRIP_NOPS (oprnd0); STRIP_NOPS (oprnd1); /* Recursively try to find the base of the address contained in EXPR. For offset, the returned base will be NULL. */ base_addr0 = address_analysis (oprnd0, stmt, is_read, dr, &address_offset, &address_misalign, &address_aligned_to, step); base_addr1 = address_analysis (oprnd1, stmt, is_read, dr, &address_offset, &address_misalign, &address_aligned_to, step); /* We support cases where only one of the operands contains an address. */ if ((base_addr0 && base_addr1) || (!base_addr0 && !base_addr1)) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\neither more than one address or no addresses in expr "); print_generic_expr (dump_file, expr, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* To revert STRIP_NOPS. */ oprnd0 = TREE_OPERAND (expr, 0); oprnd1 = TREE_OPERAND (expr, 1); offset_expr = base_addr0 ? fold_convert (ssizetype, oprnd1) : fold_convert (ssizetype, oprnd0); /* EXPR is of form {base +/- offset} (or {offset +/- base}). If offset is a number, we can add it to the misalignment value calculated for base, otherwise, misalignment is NULL. */ if (TREE_CODE (offset_expr) == INTEGER_CST && address_misalign) { *misalign = size_binop (TREE_CODE (expr), address_misalign, offset_expr); *aligned_to = address_aligned_to; } else { *misalign = NULL_TREE; *aligned_to = NULL_TREE; } /* Combine offset (from EXPR {base + offset}) with the offset calculated for base. */ *offset = size_binop (TREE_CODE (expr), address_offset, offset_expr); return base_addr0 ? base_addr0 : base_addr1; case ADDR_EXPR: base_address = object_analysis (TREE_OPERAND (expr, 0), stmt, is_read, &dr, offset, misalign, aligned_to, step, &dummy, &dummy1, &dummy2); return base_address; case SSA_NAME: if (!POINTER_TYPE_P (TREE_TYPE (expr))) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nnot pointer SSA_NAME "); print_generic_expr (dump_file, expr, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } *aligned_to = ssize_int (TYPE_ALIGN_UNIT (TREE_TYPE (TREE_TYPE (expr)))); *misalign = ssize_int (0); *offset = ssize_int (0); *step = ssize_int (0); return expr; default: return NULL_TREE; } } /* Function object_analysis Create a data-reference structure DR for MEMREF. Return the BASE of the data reference MEMREF if the analysis is possible. Also compute the INITIAL_OFFSET from BASE, MISALIGN and STEP. E.g., for EXPR a.b[i] + 4B, BASE is a, and OFFSET is the overall offset 'a.b[i] + 4B' from a (can be an expression), MISALIGN is an OFFSET instantiated with initial_conditions of access_functions of variables, and STEP is the evolution of the DR_REF in this loop. Function get_inner_reference is used for the above in case of ARRAY_REF and COMPONENT_REF. The structure of the function is as follows: Part 1: Case 1. For handled_component_p refs 1.1 build data-reference structure for MEMREF 1.2 call get_inner_reference 1.2.1 analyze offset expr received from get_inner_reference (fall through with BASE) Case 2. For declarations 2.1 set MEMTAG Case 3. For INDIRECT_REFs 3.1 build data-reference structure for MEMREF 3.2 analyze evolution and initial condition of MEMREF 3.3 set data-reference structure for MEMREF 3.4 call address_analysis to analyze INIT of the access function 3.5 extract memory tag Part 2: Combine the results of object and address analysis to calculate INITIAL_OFFSET, STEP and misalignment info. Input: MEMREF - the memory reference that is being analyzed STMT - the statement that contains MEMREF IS_READ - TRUE if STMT reads from MEMREF, FALSE if writes to MEMREF Output: BASE_ADDRESS (returned value) - the base address of the data reference MEMREF E.g, if MEMREF is a.b[k].c[i][j] the returned base is &a. DR - data_reference struct for MEMREF INITIAL_OFFSET - initial offset of MEMREF from BASE (an expression) MISALIGN - offset of MEMREF from BASE in bytes (a constant) modulo alignment of ALIGNMENT or NULL_TREE if the computation is impossible ALIGNED_TO - maximum alignment of EXPR or NULL_TREE if MISALIGN can be calculated (doesn't depend on variables) STEP - evolution of the DR_REF in the loop MEMTAG - memory tag for aliasing purposes PTR_INFO - NULL or points-to aliasing info from a pointer SSA_NAME SUBVARS - Sub-variables of the variable If the analysis of MEMREF evolution in the loop fails, NULL_TREE is returned, but DR can be created anyway. */ static tree object_analysis (tree memref, tree stmt, bool is_read, struct data_reference **dr, tree *offset, tree *misalign, tree *aligned_to, tree *step, tree *memtag, struct ptr_info_def **ptr_info, subvar_t *subvars) { tree base = NULL_TREE, base_address = NULL_TREE; tree object_offset = ssize_int (0), object_misalign = ssize_int (0); tree object_step = ssize_int (0), address_step = ssize_int (0); tree address_offset = ssize_int (0), address_misalign = ssize_int (0); HOST_WIDE_INT pbitsize, pbitpos; tree poffset, bit_pos_in_bytes; enum machine_mode pmode; int punsignedp, pvolatilep; tree ptr_step = ssize_int (0), ptr_init = NULL_TREE; struct loop *loop = loop_containing_stmt (stmt); struct data_reference *ptr_dr = NULL; tree object_aligned_to = NULL_TREE, address_aligned_to = NULL_TREE; *ptr_info = NULL; /* Part 1: */ /* Case 1. handled_component_p refs. */ if (handled_component_p (memref)) { /* 1.1 build data-reference structure for MEMREF. */ /* TODO: handle COMPONENT_REFs. */ if (!(*dr)) { if (TREE_CODE (memref) == ARRAY_REF) *dr = analyze_array (stmt, memref, is_read); else { /* FORNOW. */ if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\ndata-ref of unsupported type "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } } /* 1.2 call get_inner_reference. */ /* Find the base and the offset from it. */ base = get_inner_reference (memref, &pbitsize, &pbitpos, &poffset, &pmode, &punsignedp, &pvolatilep, false); if (!base) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nfailed to get inner ref for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* 1.2.1 analyze offset expr received from get_inner_reference. */ if (poffset && !analyze_offset_expr (poffset, loop, &object_offset, &object_misalign, &object_aligned_to, &object_step)) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nfailed to compute offset or step for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* Add bit position to OFFSET and MISALIGN. */ bit_pos_in_bytes = ssize_int (pbitpos/BITS_PER_UNIT); /* Check that there is no remainder in bits. */ if (pbitpos%BITS_PER_UNIT) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\nbit offset alignment.\n"); return NULL_TREE; } object_offset = size_binop (PLUS_EXPR, bit_pos_in_bytes, object_offset); if (object_misalign) object_misalign = size_binop (PLUS_EXPR, object_misalign, bit_pos_in_bytes); memref = base; /* To continue analysis of BASE. */ /* fall through */ } /* Part 1: Case 2. Declarations. */ if (DECL_P (memref)) { /* We expect to get a decl only if we already have a DR. */ if (!(*dr)) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nunhandled decl "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* TODO: if during the analysis of INDIRECT_REF we get to an object, put the object in BASE_OBJECT field if we can prove that this is O.K., i.e., the data-ref access is bounded by the bounds of the BASE_OBJECT. (e.g., if the object is an array base 'a', where 'a[N]', we must prove that every access with 'p' (the original INDIRECT_REF based on '&a') in the loop is within the array boundaries - from a[0] to a[N-1]). Otherwise, our alias analysis can be incorrect. Even if an access function based on BASE_OBJECT can't be build, update BASE_OBJECT field to enable us to prove that two data-refs are different (without access function, distance analysis is impossible). */ if (SSA_VAR_P (memref) && var_can_have_subvars (memref)) *subvars = get_subvars_for_var (memref); base_address = build_fold_addr_expr (memref); /* 2.1 set MEMTAG. */ *memtag = memref; } /* Part 1: Case 3. INDIRECT_REFs. */ else if (TREE_CODE (memref) == INDIRECT_REF) { tree ptr_ref = TREE_OPERAND (memref, 0); if (TREE_CODE (ptr_ref) == SSA_NAME) *ptr_info = SSA_NAME_PTR_INFO (ptr_ref); /* 3.1 build data-reference structure for MEMREF. */ ptr_dr = analyze_indirect_ref (stmt, memref, is_read); if (!ptr_dr) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nfailed to create dr for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* 3.2 analyze evolution and initial condition of MEMREF. */ ptr_step = DR_STEP (ptr_dr); ptr_init = DR_BASE_ADDRESS (ptr_dr); if (!ptr_init || !ptr_step || !POINTER_TYPE_P (TREE_TYPE (ptr_init))) { *dr = (*dr) ? *dr : ptr_dr; if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nbad pointer access "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } if (integer_zerop (ptr_step) && !(*dr)) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\nptr is loop invariant.\n"); *dr = ptr_dr; return NULL_TREE; /* If there exists DR for MEMREF, we are analyzing the base of handled component (PTR_INIT), which not necessary has evolution in the loop. */ } object_step = size_binop (PLUS_EXPR, object_step, ptr_step); /* 3.3 set data-reference structure for MEMREF. */ if (!*dr) *dr = ptr_dr; /* 3.4 call address_analysis to analyze INIT of the access function. */ base_address = address_analysis (ptr_init, stmt, is_read, *dr, &address_offset, &address_misalign, &address_aligned_to, &address_step); if (!base_address) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nfailed to analyze address "); print_generic_expr (dump_file, ptr_init, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } /* 3.5 extract memory tag. */ switch (TREE_CODE (base_address)) { case SSA_NAME: *memtag = get_var_ann (SSA_NAME_VAR (base_address))->type_mem_tag; if (!(*memtag) && TREE_CODE (TREE_OPERAND (memref, 0)) == SSA_NAME) *memtag = get_var_ann ( SSA_NAME_VAR (TREE_OPERAND (memref, 0)))->type_mem_tag; break; case ADDR_EXPR: *memtag = TREE_OPERAND (base_address, 0); break; default: if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nno memtag for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } *memtag = NULL_TREE; break; } } if (!base_address) { /* MEMREF cannot be analyzed. */ if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\ndata-ref of unsupported type "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL_TREE; } if (SSA_VAR_P (*memtag) && var_can_have_subvars (*memtag)) *subvars = get_subvars_for_var (*memtag); /* Part 2: Combine the results of object and address analysis to calculate INITIAL_OFFSET, STEP and misalignment info. */ *offset = size_binop (PLUS_EXPR, object_offset, address_offset); if ((!object_misalign && !object_aligned_to) || (!address_misalign && !address_aligned_to)) { *misalign = NULL_TREE; *aligned_to = NULL_TREE; } else { if (object_misalign && address_misalign) *misalign = size_binop (PLUS_EXPR, object_misalign, address_misalign); else *misalign = object_misalign ? object_misalign : address_misalign; if (object_aligned_to && address_aligned_to) *aligned_to = size_binop (MIN_EXPR, object_aligned_to, address_aligned_to); else *aligned_to = object_aligned_to ? object_aligned_to : address_aligned_to; } *step = size_binop (PLUS_EXPR, object_step, address_step); return base_address; } /* Function analyze_offset. Extract INVARIANT and CONSTANT parts from OFFSET. */ static void analyze_offset (tree offset, tree *invariant, tree *constant) { tree op0, op1, constant_0, constant_1, invariant_0, invariant_1; enum tree_code code = TREE_CODE (offset); *invariant = NULL_TREE; *constant = NULL_TREE; /* Not PLUS/MINUS expression - recursion stop condition. */ if (code != PLUS_EXPR && code != MINUS_EXPR) { if (TREE_CODE (offset) == INTEGER_CST) *constant = offset; else *invariant = offset; return; } op0 = TREE_OPERAND (offset, 0); op1 = TREE_OPERAND (offset, 1); /* Recursive call with the operands. */ analyze_offset (op0, &invariant_0, &constant_0); analyze_offset (op1, &invariant_1, &constant_1); /* Combine the results. */ *constant = constant_0 ? constant_0 : constant_1; if (invariant_0 && invariant_1) *invariant = fold_build2 (code, TREE_TYPE (invariant_0), invariant_0, invariant_1); else *invariant = invariant_0 ? invariant_0 : invariant_1; } /* Function create_data_ref. Create a data-reference structure for MEMREF. Set its DR_BASE_ADDRESS, DR_OFFSET, DR_INIT, DR_STEP, DR_OFFSET_MISALIGNMENT, DR_ALIGNED_TO, DR_MEMTAG, and DR_POINTSTO_INFO fields. Input: MEMREF - the memory reference that is being analyzed STMT - the statement that contains MEMREF IS_READ - TRUE if STMT reads from MEMREF, FALSE if writes to MEMREF Output: DR (returned value) - data_reference struct for MEMREF */ static struct data_reference * create_data_ref (tree memref, tree stmt, bool is_read) { struct data_reference *dr = NULL; tree base_address, offset, step, misalign, memtag; struct loop *loop = loop_containing_stmt (stmt); tree invariant = NULL_TREE, constant = NULL_TREE; tree type_size, init_cond; struct ptr_info_def *ptr_info; subvar_t subvars = NULL; tree aligned_to; if (!memref) return NULL; base_address = object_analysis (memref, stmt, is_read, &dr, &offset, &misalign, &aligned_to, &step, &memtag, &ptr_info, &subvars); if (!dr || !base_address) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\ncreate_data_ref: failed to create a dr for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n"); } return NULL; } DR_BASE_ADDRESS (dr) = base_address; DR_OFFSET (dr) = offset; DR_INIT (dr) = ssize_int (0); DR_STEP (dr) = step; DR_OFFSET_MISALIGNMENT (dr) = misalign; DR_ALIGNED_TO (dr) = aligned_to; DR_MEMTAG (dr) = memtag; DR_PTR_INFO (dr) = ptr_info; DR_SUBVARS (dr) = subvars; type_size = fold_convert (ssizetype, TYPE_SIZE_UNIT (TREE_TYPE (DR_REF (dr)))); /* Change the access function for INIDIRECT_REFs, according to DR_BASE_ADDRESS. Analyze OFFSET calculated in object_analysis. OFFSET is an expression that can contain loop invariant expressions and constants. We put the constant part in the initial condition of the access function (for data dependence tests), and in DR_INIT of the data-ref. The loop invariant part is put in DR_OFFSET. The evolution part of the access function is STEP calculated in object_analysis divided by the size of data type. */ if (!DR_BASE_OBJECT (dr)) { tree access_fn; tree new_step; /* Extract CONSTANT and INVARIANT from OFFSET, and put them in DR_INIT and DR_OFFSET fields of DR. */ analyze_offset (offset, &invariant, &constant); if (constant) { DR_INIT (dr) = fold_convert (ssizetype, constant); init_cond = fold_build2 (TRUNC_DIV_EXPR, TREE_TYPE (constant), constant, type_size); } else DR_INIT (dr) = init_cond = ssize_int (0);; if (invariant) DR_OFFSET (dr) = invariant; else DR_OFFSET (dr) = ssize_int (0); /* Update access function. */ access_fn = DR_ACCESS_FN (dr, 0); new_step = size_binop (TRUNC_DIV_EXPR, fold_convert (ssizetype, step), type_size); access_fn = chrec_replace_initial_condition (access_fn, init_cond); access_fn = reset_evolution_in_loop (loop->num, access_fn, new_step); VEC_replace (tree, DR_ACCESS_FNS (dr), 0, access_fn); } if (dump_file && (dump_flags & TDF_DETAILS)) { struct ptr_info_def *pi = DR_PTR_INFO (dr); fprintf (dump_file, "\nCreated dr for "); print_generic_expr (dump_file, memref, TDF_SLIM); fprintf (dump_file, "\n\tbase_address: "); print_generic_expr (dump_file, DR_BASE_ADDRESS (dr), TDF_SLIM); fprintf (dump_file, "\n\toffset from base address: "); print_generic_expr (dump_file, DR_OFFSET (dr), TDF_SLIM); fprintf (dump_file, "\n\tconstant offset from base address: "); print_generic_expr (dump_file, DR_INIT (dr), TDF_SLIM); fprintf (dump_file, "\n\tbase_object: "); print_generic_expr (dump_file, DR_BASE_OBJECT (dr), TDF_SLIM); fprintf (dump_file, "\n\tstep: "); print_generic_expr (dump_file, DR_STEP (dr), TDF_SLIM); fprintf (dump_file, "B\n\tmisalignment from base: "); print_generic_expr (dump_file, DR_OFFSET_MISALIGNMENT (dr), TDF_SLIM); if (DR_OFFSET_MISALIGNMENT (dr)) fprintf (dump_file, "B"); if (DR_ALIGNED_TO (dr)) { fprintf (dump_file, "\n\taligned to: "); print_generic_expr (dump_file, DR_ALIGNED_TO (dr), TDF_SLIM); } fprintf (dump_file, "\n\tmemtag: "); print_generic_expr (dump_file, DR_MEMTAG (dr), TDF_SLIM); fprintf (dump_file, "\n"); if (pi && pi->name_mem_tag) { fprintf (dump_file, "\n\tnametag: "); print_generic_expr (dump_file, pi->name_mem_tag, TDF_SLIM); fprintf (dump_file, "\n"); } } return dr; } /* Returns true when all the functions of a tree_vec CHREC are the same. */ static bool all_chrecs_equal_p (tree chrec) { int j; for (j = 0; j < TREE_VEC_LENGTH (chrec) - 1; j++) { tree chrec_j = TREE_VEC_ELT (chrec, j); tree chrec_j_1 = TREE_VEC_ELT (chrec, j + 1); if (!integer_zerop (chrec_fold_minus (integer_type_node, chrec_j, chrec_j_1))) return false; } return true; } /* Determine for each subscript in the data dependence relation DDR the distance. */ void compute_subscript_distance (struct data_dependence_relation *ddr) { if (DDR_ARE_DEPENDENT (ddr) == NULL_TREE) { unsigned int i; for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { tree conflicts_a, conflicts_b, difference; struct subscript *subscript; subscript = DDR_SUBSCRIPT (ddr, i); conflicts_a = SUB_CONFLICTS_IN_A (subscript); conflicts_b = SUB_CONFLICTS_IN_B (subscript); if (TREE_CODE (conflicts_a) == TREE_VEC) { if (!all_chrecs_equal_p (conflicts_a)) { SUB_DISTANCE (subscript) = chrec_dont_know; return; } else conflicts_a = TREE_VEC_ELT (conflicts_a, 0); } if (TREE_CODE (conflicts_b) == TREE_VEC) { if (!all_chrecs_equal_p (conflicts_b)) { SUB_DISTANCE (subscript) = chrec_dont_know; return; } else conflicts_b = TREE_VEC_ELT (conflicts_b, 0); } difference = chrec_fold_minus (integer_type_node, conflicts_b, conflicts_a); if (evolution_function_is_constant_p (difference)) SUB_DISTANCE (subscript) = difference; else SUB_DISTANCE (subscript) = chrec_dont_know; } } } /* Initialize a ddr. */ struct data_dependence_relation * initialize_data_dependence_relation (struct data_reference *a, struct data_reference *b) { struct data_dependence_relation *res; bool differ_p; unsigned int i; res = xmalloc (sizeof (struct data_dependence_relation)); DDR_A (res) = a; DDR_B (res) = b; if (a == NULL || b == NULL) { DDR_ARE_DEPENDENT (res) = chrec_dont_know; return res; } /* When A and B are arrays and their dimensions differ, we directly initialize the relation to "there is no dependence": chrec_known. */ if (DR_BASE_OBJECT (a) && DR_BASE_OBJECT (b) && DR_NUM_DIMENSIONS (a) != DR_NUM_DIMENSIONS (b)) { DDR_ARE_DEPENDENT (res) = chrec_known; return res; } /* Compare the bases of the data-refs. */ if (!base_addr_differ_p (a, b, &differ_p)) { /* Can't determine whether the data-refs access the same memory region. */ DDR_ARE_DEPENDENT (res) = chrec_dont_know; return res; } if (differ_p) { DDR_ARE_DEPENDENT (res) = chrec_known; return res; } DDR_AFFINE_P (res) = true; DDR_ARE_DEPENDENT (res) = NULL_TREE; DDR_SUBSCRIPTS_VECTOR_INIT (res, DR_NUM_DIMENSIONS (a)); DDR_SIZE_VECT (res) = 0; DDR_DIR_VECTS (res) = NULL; DDR_DIST_VECTS (res) = NULL; for (i = 0; i < DR_NUM_DIMENSIONS (a); i++) { struct subscript *subscript; subscript = xmalloc (sizeof (struct subscript)); SUB_CONFLICTS_IN_A (subscript) = chrec_dont_know; SUB_CONFLICTS_IN_B (subscript) = chrec_dont_know; SUB_LAST_CONFLICT (subscript) = chrec_dont_know; SUB_DISTANCE (subscript) = chrec_dont_know; VARRAY_PUSH_GENERIC_PTR (DDR_SUBSCRIPTS (res), subscript); } return res; } /* Set DDR_ARE_DEPENDENT to CHREC and finalize the subscript overlap description. */ static inline void finalize_ddr_dependent (struct data_dependence_relation *ddr, tree chrec) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(dependence classified: "); print_generic_expr (dump_file, chrec, 0); fprintf (dump_file, ")\n"); } DDR_ARE_DEPENDENT (ddr) = chrec; varray_clear (DDR_SUBSCRIPTS (ddr)); } /* The dependence relation DDR cannot be represented by a distance vector. */ static inline void non_affine_dependence_relation (struct data_dependence_relation *ddr) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(Dependence relation cannot be represented by distance vector.) \n"); DDR_AFFINE_P (ddr) = false; } /* This section contains the classic Banerjee tests. */ /* Returns true iff CHREC_A and CHREC_B are not dependent on any index variables, i.e., if the ZIV (Zero Index Variable) test is true. */ static inline bool ziv_subscript_p (tree chrec_a, tree chrec_b) { return (evolution_function_is_constant_p (chrec_a) && evolution_function_is_constant_p (chrec_b)); } /* Returns true iff CHREC_A and CHREC_B are dependent on an index variable, i.e., if the SIV (Single Index Variable) test is true. */ static bool siv_subscript_p (tree chrec_a, tree chrec_b) { if ((evolution_function_is_constant_p (chrec_a) && evolution_function_is_univariate_p (chrec_b)) || (evolution_function_is_constant_p (chrec_b) && evolution_function_is_univariate_p (chrec_a))) return true; if (evolution_function_is_univariate_p (chrec_a) && evolution_function_is_univariate_p (chrec_b)) { switch (TREE_CODE (chrec_a)) { case POLYNOMIAL_CHREC: switch (TREE_CODE (chrec_b)) { case POLYNOMIAL_CHREC: if (CHREC_VARIABLE (chrec_a) != CHREC_VARIABLE (chrec_b)) return false; default: return true; } default: return true; } } return false; } /* Analyze a ZIV (Zero Index Variable) subscript. *OVERLAPS_A and *OVERLAPS_B are initialized to the functions that describe the relation between the elements accessed twice by CHREC_A and CHREC_B. For k >= 0, the following property is verified: CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */ static void analyze_ziv_subscript (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { tree difference; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(analyze_ziv_subscript \n"); difference = chrec_fold_minus (integer_type_node, chrec_a, chrec_b); switch (TREE_CODE (difference)) { case INTEGER_CST: if (integer_zerop (difference)) { /* The difference is equal to zero: the accessed index overlaps for each iteration in the loop. */ *overlaps_a = integer_zero_node; *overlaps_b = integer_zero_node; *last_conflicts = chrec_dont_know; } else { /* The accesses do not overlap. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; } break; default: /* We're not sure whether the indexes overlap. For the moment, conservatively answer "don't know". */ *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; break; } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* Get the real or estimated number of iterations for LOOPNUM, whichever is available. Return the number of iterations as a tree, or NULL_TREE if we don't know. */ static tree get_number_of_iters_for_loop (int loopnum) { tree numiter = number_of_iterations_in_loop (current_loops->parray[loopnum]); if (TREE_CODE (numiter) != INTEGER_CST) numiter = current_loops->parray[loopnum]->estimated_nb_iterations; if (chrec_contains_undetermined (numiter)) return NULL_TREE; return numiter; } /* Analyze a SIV (Single Index Variable) subscript where CHREC_A is a constant, and CHREC_B is an affine function. *OVERLAPS_A and *OVERLAPS_B are initialized to the functions that describe the relation between the elements accessed twice by CHREC_A and CHREC_B. For k >= 0, the following property is verified: CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */ static void analyze_siv_subscript_cst_affine (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { bool value0, value1, value2; tree difference = chrec_fold_minus (integer_type_node, CHREC_LEFT (chrec_b), chrec_a); if (!chrec_is_positive (initial_condition (difference), &value0)) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } else { if (value0 == false) { if (!chrec_is_positive (CHREC_RIGHT (chrec_b), &value1)) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } else { if (value1 == true) { /* Example: chrec_a = 12 chrec_b = {10, +, 1} */ if (tree_fold_divides_p (CHREC_RIGHT (chrec_b), difference)) { tree numiter; int loopnum = CHREC_VARIABLE (chrec_b); *overlaps_a = integer_zero_node; *overlaps_b = fold_build2 (EXACT_DIV_EXPR, integer_type_node, fold_build1 (ABS_EXPR, integer_type_node, difference), CHREC_RIGHT (chrec_b)); *last_conflicts = integer_one_node; /* Perform weak-zero siv test to see if overlap is outside the loop bounds. */ numiter = get_number_of_iters_for_loop (loopnum); if (numiter != NULL_TREE && TREE_CODE (*overlaps_b) == INTEGER_CST && tree_int_cst_lt (numiter, *overlaps_b)) { *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } return; } /* When the step does not divide the difference, there are no overlaps. */ else { *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } } else { /* Example: chrec_a = 12 chrec_b = {10, +, -1} In this case, chrec_a will not overlap with chrec_b. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } } } else { if (!chrec_is_positive (CHREC_RIGHT (chrec_b), &value2)) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } else { if (value2 == false) { /* Example: chrec_a = 3 chrec_b = {10, +, -1} */ if (tree_fold_divides_p (CHREC_RIGHT (chrec_b), difference)) { tree numiter; int loopnum = CHREC_VARIABLE (chrec_b); *overlaps_a = integer_zero_node; *overlaps_b = fold_build2 (EXACT_DIV_EXPR, integer_type_node, difference, CHREC_RIGHT (chrec_b)); *last_conflicts = integer_one_node; /* Perform weak-zero siv test to see if overlap is outside the loop bounds. */ numiter = get_number_of_iters_for_loop (loopnum); if (numiter != NULL_TREE && TREE_CODE (*overlaps_b) == INTEGER_CST && tree_int_cst_lt (numiter, *overlaps_b)) { *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } return; } /* When the step does not divide the difference, there are no overlaps. */ else { *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } } else { /* Example: chrec_a = 3 chrec_b = {4, +, 1} In this case, chrec_a will not overlap with chrec_b. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; return; } } } } } /* Helper recursive function for initializing the matrix A. Returns the initial value of CHREC. */ static int initialize_matrix_A (lambda_matrix A, tree chrec, unsigned index, int mult) { gcc_assert (chrec); if (TREE_CODE (chrec) != POLYNOMIAL_CHREC) return int_cst_value (chrec); A[index][0] = mult * int_cst_value (CHREC_RIGHT (chrec)); return initialize_matrix_A (A, CHREC_LEFT (chrec), index + 1, mult); } #define FLOOR_DIV(x,y) ((x) / (y)) /* Solves the special case of the Diophantine equation: | {0, +, STEP_A}_x (OVERLAPS_A) = {0, +, STEP_B}_y (OVERLAPS_B) Computes the descriptions OVERLAPS_A and OVERLAPS_B. NITER is the number of iterations that loops X and Y run. The overlaps will be constructed as evolutions in dimension DIM. */ static void compute_overlap_steps_for_affine_univar (int niter, int step_a, int step_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts, int dim) { if (((step_a > 0 && step_b > 0) || (step_a < 0 && step_b < 0))) { int step_overlaps_a, step_overlaps_b; int gcd_steps_a_b, last_conflict, tau2; gcd_steps_a_b = gcd (step_a, step_b); step_overlaps_a = step_b / gcd_steps_a_b; step_overlaps_b = step_a / gcd_steps_a_b; tau2 = FLOOR_DIV (niter, step_overlaps_a); tau2 = MIN (tau2, FLOOR_DIV (niter, step_overlaps_b)); last_conflict = tau2; *overlaps_a = build_polynomial_chrec (dim, integer_zero_node, build_int_cst (NULL_TREE, step_overlaps_a)); *overlaps_b = build_polynomial_chrec (dim, integer_zero_node, build_int_cst (NULL_TREE, step_overlaps_b)); *last_conflicts = build_int_cst (NULL_TREE, last_conflict); } else { *overlaps_a = integer_zero_node; *overlaps_b = integer_zero_node; *last_conflicts = integer_zero_node; } } /* Solves the special case of a Diophantine equation where CHREC_A is an affine bivariate function, and CHREC_B is an affine univariate function. For example, | {{0, +, 1}_x, +, 1335}_y = {0, +, 1336}_z has the following overlapping functions: | x (t, u, v) = {{0, +, 1336}_t, +, 1}_v | y (t, u, v) = {{0, +, 1336}_u, +, 1}_v | z (t, u, v) = {{{0, +, 1}_t, +, 1335}_u, +, 1}_v FORNOW: This is a specialized implementation for a case occurring in a common benchmark. Implement the general algorithm. */ static void compute_overlap_steps_for_affine_1_2 (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { bool xz_p, yz_p, xyz_p; int step_x, step_y, step_z; int niter_x, niter_y, niter_z, niter; tree numiter_x, numiter_y, numiter_z; tree overlaps_a_xz, overlaps_b_xz, last_conflicts_xz; tree overlaps_a_yz, overlaps_b_yz, last_conflicts_yz; tree overlaps_a_xyz, overlaps_b_xyz, last_conflicts_xyz; step_x = int_cst_value (CHREC_RIGHT (CHREC_LEFT (chrec_a))); step_y = int_cst_value (CHREC_RIGHT (chrec_a)); step_z = int_cst_value (CHREC_RIGHT (chrec_b)); numiter_x = get_number_of_iters_for_loop (CHREC_VARIABLE (CHREC_LEFT (chrec_a))); numiter_y = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_a)); numiter_z = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_b)); if (numiter_x == NULL_TREE || numiter_y == NULL_TREE || numiter_z == NULL_TREE) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } niter_x = int_cst_value (numiter_x); niter_y = int_cst_value (numiter_y); niter_z = int_cst_value (numiter_z); niter = MIN (niter_x, niter_z); compute_overlap_steps_for_affine_univar (niter, step_x, step_z, &overlaps_a_xz, &overlaps_b_xz, &last_conflicts_xz, 1); niter = MIN (niter_y, niter_z); compute_overlap_steps_for_affine_univar (niter, step_y, step_z, &overlaps_a_yz, &overlaps_b_yz, &last_conflicts_yz, 2); niter = MIN (niter_x, niter_z); niter = MIN (niter_y, niter); compute_overlap_steps_for_affine_univar (niter, step_x + step_y, step_z, &overlaps_a_xyz, &overlaps_b_xyz, &last_conflicts_xyz, 3); xz_p = !integer_zerop (last_conflicts_xz); yz_p = !integer_zerop (last_conflicts_yz); xyz_p = !integer_zerop (last_conflicts_xyz); if (xz_p || yz_p || xyz_p) { *overlaps_a = make_tree_vec (2); TREE_VEC_ELT (*overlaps_a, 0) = integer_zero_node; TREE_VEC_ELT (*overlaps_a, 1) = integer_zero_node; *overlaps_b = integer_zero_node; if (xz_p) { TREE_VEC_ELT (*overlaps_a, 0) = chrec_fold_plus (integer_type_node, TREE_VEC_ELT (*overlaps_a, 0), overlaps_a_xz); *overlaps_b = chrec_fold_plus (integer_type_node, *overlaps_b, overlaps_b_xz); *last_conflicts = last_conflicts_xz; } if (yz_p) { TREE_VEC_ELT (*overlaps_a, 1) = chrec_fold_plus (integer_type_node, TREE_VEC_ELT (*overlaps_a, 1), overlaps_a_yz); *overlaps_b = chrec_fold_plus (integer_type_node, *overlaps_b, overlaps_b_yz); *last_conflicts = last_conflicts_yz; } if (xyz_p) { TREE_VEC_ELT (*overlaps_a, 0) = chrec_fold_plus (integer_type_node, TREE_VEC_ELT (*overlaps_a, 0), overlaps_a_xyz); TREE_VEC_ELT (*overlaps_a, 1) = chrec_fold_plus (integer_type_node, TREE_VEC_ELT (*overlaps_a, 1), overlaps_a_xyz); *overlaps_b = chrec_fold_plus (integer_type_node, *overlaps_b, overlaps_b_xyz); *last_conflicts = last_conflicts_xyz; } } else { *overlaps_a = integer_zero_node; *overlaps_b = integer_zero_node; *last_conflicts = integer_zero_node; } } /* Determines the overlapping elements due to accesses CHREC_A and CHREC_B, that are affine functions. This is a part of the subscript analyzer. */ static void analyze_subscript_affine_affine (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { unsigned nb_vars_a, nb_vars_b, dim; int init_a, init_b, gamma, gcd_alpha_beta; int tau1, tau2; lambda_matrix A, U, S; tree difference = chrec_fold_minus (integer_type_node, chrec_a, chrec_b); if (integer_zerop (difference)) { /* The difference is equal to zero: the accessed index overlaps for each iteration in the loop. */ *overlaps_a = integer_zero_node; *overlaps_b = integer_zero_node; *last_conflicts = chrec_dont_know; return; } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(analyze_subscript_affine_affine \n"); /* For determining the initial intersection, we have to solve a Diophantine equation. This is the most time consuming part. For answering to the question: "Is there a dependence?" we have to prove that there exists a solution to the Diophantine equation, and that the solution is in the iteration domain, i.e. the solution is positive or zero, and that the solution happens before the upper bound loop.nb_iterations. Otherwise there is no dependence. This function outputs a description of the iterations that hold the intersections. */ nb_vars_a = nb_vars_in_chrec (chrec_a); nb_vars_b = nb_vars_in_chrec (chrec_b); dim = nb_vars_a + nb_vars_b; U = lambda_matrix_new (dim, dim); A = lambda_matrix_new (dim, 1); S = lambda_matrix_new (dim, 1); init_a = initialize_matrix_A (A, chrec_a, 0, 1); init_b = initialize_matrix_A (A, chrec_b, nb_vars_a, -1); gamma = init_b - init_a; /* Don't do all the hard work of solving the Diophantine equation when we already know the solution: for example, | {3, +, 1}_1 | {3, +, 4}_2 | gamma = 3 - 3 = 0. Then the first overlap occurs during the first iterations: | {3, +, 1}_1 ({0, +, 4}_x) = {3, +, 4}_2 ({0, +, 1}_x) */ if (gamma == 0) { if (nb_vars_a == 1 && nb_vars_b == 1) { int step_a, step_b; int niter, niter_a, niter_b; tree numiter_a, numiter_b; numiter_a = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_a)); numiter_b = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_b)); if (numiter_a == NULL_TREE || numiter_b == NULL_TREE) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } niter_a = int_cst_value (numiter_a); niter_b = int_cst_value (numiter_b); niter = MIN (niter_a, niter_b); step_a = int_cst_value (CHREC_RIGHT (chrec_a)); step_b = int_cst_value (CHREC_RIGHT (chrec_b)); compute_overlap_steps_for_affine_univar (niter, step_a, step_b, overlaps_a, overlaps_b, last_conflicts, 1); } else if (nb_vars_a == 2 && nb_vars_b == 1) compute_overlap_steps_for_affine_1_2 (chrec_a, chrec_b, overlaps_a, overlaps_b, last_conflicts); else if (nb_vars_a == 1 && nb_vars_b == 2) compute_overlap_steps_for_affine_1_2 (chrec_b, chrec_a, overlaps_b, overlaps_a, last_conflicts); else { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } return; } /* U.A = S */ lambda_matrix_right_hermite (A, dim, 1, S, U); if (S[0][0] < 0) { S[0][0] *= -1; lambda_matrix_row_negate (U, dim, 0); } gcd_alpha_beta = S[0][0]; /* The classic "gcd-test". */ if (!int_divides_p (gcd_alpha_beta, gamma)) { /* The "gcd-test" has determined that there is no integer solution, i.e. there is no dependence. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; } /* Both access functions are univariate. This includes SIV and MIV cases. */ else if (nb_vars_a == 1 && nb_vars_b == 1) { /* Both functions should have the same evolution sign. */ if (((A[0][0] > 0 && -A[1][0] > 0) || (A[0][0] < 0 && -A[1][0] < 0))) { /* The solutions are given by: | | [GAMMA/GCD_ALPHA_BETA t].[u11 u12] = [x0] | [u21 u22] [y0] For a given integer t. Using the following variables, | i0 = u11 * gamma / gcd_alpha_beta | j0 = u12 * gamma / gcd_alpha_beta | i1 = u21 | j1 = u22 the solutions are: | x0 = i0 + i1 * t, | y0 = j0 + j1 * t. */ int i0, j0, i1, j1; /* X0 and Y0 are the first iterations for which there is a dependence. X0, Y0 are two solutions of the Diophantine equation: chrec_a (X0) = chrec_b (Y0). */ int x0, y0; int niter, niter_a, niter_b; tree numiter_a, numiter_b; numiter_a = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_a)); numiter_b = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_b)); if (numiter_a == NULL_TREE || numiter_b == NULL_TREE) { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; return; } niter_a = int_cst_value (numiter_a); niter_b = int_cst_value (numiter_b); niter = MIN (niter_a, niter_b); i0 = U[0][0] * gamma / gcd_alpha_beta; j0 = U[0][1] * gamma / gcd_alpha_beta; i1 = U[1][0]; j1 = U[1][1]; if ((i1 == 0 && i0 < 0) || (j1 == 0 && j0 < 0)) { /* There is no solution. FIXME: The case "i0 > nb_iterations, j0 > nb_iterations" falls in here, but for the moment we don't look at the upper bound of the iteration domain. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; } else { if (i1 > 0) { tau1 = CEIL (-i0, i1); tau2 = FLOOR_DIV (niter - i0, i1); if (j1 > 0) { int last_conflict, min_multiple; tau1 = MAX (tau1, CEIL (-j0, j1)); tau2 = MIN (tau2, FLOOR_DIV (niter - j0, j1)); x0 = i1 * tau1 + i0; y0 = j1 * tau1 + j0; /* At this point (x0, y0) is one of the solutions to the Diophantine equation. The next step has to compute the smallest positive solution: the first conflicts. */ min_multiple = MIN (x0 / i1, y0 / j1); x0 -= i1 * min_multiple; y0 -= j1 * min_multiple; tau1 = (x0 - i0)/i1; last_conflict = tau2 - tau1; /* If the overlap occurs outside of the bounds of the loop, there is no dependence. */ if (x0 > niter || y0 > niter) { *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; } else { *overlaps_a = build_polynomial_chrec (1, build_int_cst (NULL_TREE, x0), build_int_cst (NULL_TREE, i1)); *overlaps_b = build_polynomial_chrec (1, build_int_cst (NULL_TREE, y0), build_int_cst (NULL_TREE, j1)); *last_conflicts = build_int_cst (NULL_TREE, last_conflict); } } else { /* FIXME: For the moment, the upper bound of the iteration domain for j is not checked. */ *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } } else { /* FIXME: For the moment, the upper bound of the iteration domain for i is not checked. */ *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } } } else { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } } else { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, " (overlaps_a = "); print_generic_expr (dump_file, *overlaps_a, 0); fprintf (dump_file, ")\n (overlaps_b = "); print_generic_expr (dump_file, *overlaps_b, 0); fprintf (dump_file, ")\n"); } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* Analyze a SIV (Single Index Variable) subscript. *OVERLAPS_A and *OVERLAPS_B are initialized to the functions that describe the relation between the elements accessed twice by CHREC_A and CHREC_B. For k >= 0, the following property is verified: CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */ static void analyze_siv_subscript (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(analyze_siv_subscript \n"); if (evolution_function_is_constant_p (chrec_a) && evolution_function_is_affine_p (chrec_b)) analyze_siv_subscript_cst_affine (chrec_a, chrec_b, overlaps_a, overlaps_b, last_conflicts); else if (evolution_function_is_affine_p (chrec_a) && evolution_function_is_constant_p (chrec_b)) analyze_siv_subscript_cst_affine (chrec_b, chrec_a, overlaps_b, overlaps_a, last_conflicts); else if (evolution_function_is_affine_p (chrec_a) && evolution_function_is_affine_p (chrec_b)) analyze_subscript_affine_affine (chrec_a, chrec_b, overlaps_a, overlaps_b, last_conflicts); else { *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* Return true when the evolution steps of an affine CHREC divide the constant CST. */ static bool chrec_steps_divide_constant_p (tree chrec, tree cst) { switch (TREE_CODE (chrec)) { case POLYNOMIAL_CHREC: return (tree_fold_divides_p (CHREC_RIGHT (chrec), cst) && chrec_steps_divide_constant_p (CHREC_LEFT (chrec), cst)); default: /* On the initial condition, return true. */ return true; } } /* Analyze a MIV (Multiple Index Variable) subscript. *OVERLAPS_A and *OVERLAPS_B are initialized to the functions that describe the relation between the elements accessed twice by CHREC_A and CHREC_B. For k >= 0, the following property is verified: CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */ static void analyze_miv_subscript (tree chrec_a, tree chrec_b, tree *overlaps_a, tree *overlaps_b, tree *last_conflicts) { /* FIXME: This is a MIV subscript, not yet handled. Example: (A[{1, +, 1}_1] vs. A[{1, +, 1}_2]) that comes from (A[i] vs. A[j]). In the SIV test we had to solve a Diophantine equation with two variables. In the MIV case we have to solve a Diophantine equation with 2*n variables (if the subscript uses n IVs). */ tree difference; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(analyze_miv_subscript \n"); difference = chrec_fold_minus (integer_type_node, chrec_a, chrec_b); if (chrec_zerop (difference)) { /* Access functions are the same: all the elements are accessed in the same order. */ *overlaps_a = integer_zero_node; *overlaps_b = integer_zero_node; *last_conflicts = get_number_of_iters_for_loop (CHREC_VARIABLE (chrec_a)); } else if (evolution_function_is_constant_p (difference) /* For the moment, the following is verified: evolution_function_is_affine_multivariate_p (chrec_a) */ && !chrec_steps_divide_constant_p (chrec_a, difference)) { /* testsuite/.../ssa-chrec-33.c {{21, +, 2}_1, +, -2}_2 vs. {{20, +, 2}_1, +, -2}_2 The difference is 1, and the evolution steps are equal to 2, consequently there are no overlapping elements. */ *overlaps_a = chrec_known; *overlaps_b = chrec_known; *last_conflicts = integer_zero_node; } else if (evolution_function_is_affine_multivariate_p (chrec_a) && evolution_function_is_affine_multivariate_p (chrec_b)) { /* testsuite/.../ssa-chrec-35.c {0, +, 1}_2 vs. {0, +, 1}_3 the overlapping elements are respectively located at iterations: {0, +, 1}_x and {0, +, 1}_x, in other words, we have the equality: {0, +, 1}_2 ({0, +, 1}_x) = {0, +, 1}_3 ({0, +, 1}_x) Other examples: {{0, +, 1}_1, +, 2}_2 ({0, +, 1}_x, {0, +, 1}_y) = {0, +, 1}_1 ({{0, +, 1}_x, +, 2}_y) {{0, +, 2}_1, +, 3}_2 ({0, +, 1}_y, {0, +, 1}_x) = {{0, +, 3}_1, +, 2}_2 ({0, +, 1}_x, {0, +, 1}_y) */ analyze_subscript_affine_affine (chrec_a, chrec_b, overlaps_a, overlaps_b, last_conflicts); } else { /* When the analysis is too difficult, answer "don't know". */ *overlaps_a = chrec_dont_know; *overlaps_b = chrec_dont_know; *last_conflicts = chrec_dont_know; } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* Determines the iterations for which CHREC_A is equal to CHREC_B. OVERLAP_ITERATIONS_A and OVERLAP_ITERATIONS_B are initialized with two functions that describe the iterations that contain conflicting elements. Remark: For an integer k >= 0, the following equality is true: CHREC_A (OVERLAP_ITERATIONS_A (k)) == CHREC_B (OVERLAP_ITERATIONS_B (k)). */ static void analyze_overlapping_iterations (tree chrec_a, tree chrec_b, tree *overlap_iterations_a, tree *overlap_iterations_b, tree *last_conflicts) { if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(analyze_overlapping_iterations \n"); fprintf (dump_file, " (chrec_a = "); print_generic_expr (dump_file, chrec_a, 0); fprintf (dump_file, ")\n chrec_b = "); print_generic_expr (dump_file, chrec_b, 0); fprintf (dump_file, ")\n"); } if (chrec_a == NULL_TREE || chrec_b == NULL_TREE || chrec_contains_undetermined (chrec_a) || chrec_contains_undetermined (chrec_b) || chrec_contains_symbols (chrec_a) || chrec_contains_symbols (chrec_b)) { *overlap_iterations_a = chrec_dont_know; *overlap_iterations_b = chrec_dont_know; } else if (ziv_subscript_p (chrec_a, chrec_b)) analyze_ziv_subscript (chrec_a, chrec_b, overlap_iterations_a, overlap_iterations_b, last_conflicts); else if (siv_subscript_p (chrec_a, chrec_b)) analyze_siv_subscript (chrec_a, chrec_b, overlap_iterations_a, overlap_iterations_b, last_conflicts); else analyze_miv_subscript (chrec_a, chrec_b, overlap_iterations_a, overlap_iterations_b, last_conflicts); if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, " (overlap_iterations_a = "); print_generic_expr (dump_file, *overlap_iterations_a, 0); fprintf (dump_file, ")\n (overlap_iterations_b = "); print_generic_expr (dump_file, *overlap_iterations_b, 0); fprintf (dump_file, ")\n"); } } /* This section contains the affine functions dependences detector. */ /* Computes the conflicting iterations, and initialize DDR. */ static void subscript_dependence_tester (struct data_dependence_relation *ddr) { unsigned int i; struct data_reference *dra = DDR_A (ddr); struct data_reference *drb = DDR_B (ddr); tree last_conflicts; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "(subscript_dependence_tester \n"); for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { tree overlaps_a, overlaps_b; struct subscript *subscript = DDR_SUBSCRIPT (ddr, i); analyze_overlapping_iterations (DR_ACCESS_FN (dra, i), DR_ACCESS_FN (drb, i), &overlaps_a, &overlaps_b, &last_conflicts); if (chrec_contains_undetermined (overlaps_a) || chrec_contains_undetermined (overlaps_b)) { finalize_ddr_dependent (ddr, chrec_dont_know); break; } else if (overlaps_a == chrec_known || overlaps_b == chrec_known) { finalize_ddr_dependent (ddr, chrec_known); break; } else { SUB_CONFLICTS_IN_A (subscript) = overlaps_a; SUB_CONFLICTS_IN_B (subscript) = overlaps_b; SUB_LAST_CONFLICT (subscript) = last_conflicts; } } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* Compute the classic per loop distance vector. DDR is the data dependence relation to build a vector from. NB_LOOPS is the total number of loops we are considering. FIRST_LOOP_DEPTH is the loop->depth of the first loop in the analyzed loop nest. Return FALSE when fail to represent the data dependence as a distance vector. Return TRUE otherwise. */ static bool build_classic_dist_vector (struct data_dependence_relation *ddr, int nb_loops, int first_loop_depth) { unsigned i; lambda_vector dist_v, init_v; bool init_b = false; DDR_SIZE_VECT (ddr) = nb_loops; dist_v = lambda_vector_new (nb_loops); init_v = lambda_vector_new (nb_loops); lambda_vector_clear (dist_v, nb_loops); lambda_vector_clear (init_v, nb_loops); if (DDR_ARE_DEPENDENT (ddr) != NULL_TREE) return true; for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { tree access_fn_a, access_fn_b; struct subscript *subscript = DDR_SUBSCRIPT (ddr, i); if (chrec_contains_undetermined (SUB_DISTANCE (subscript))) { non_affine_dependence_relation (ddr); return true; } access_fn_a = DR_ACCESS_FN (DDR_A (ddr), i); access_fn_b = DR_ACCESS_FN (DDR_B (ddr), i); if (TREE_CODE (access_fn_a) == POLYNOMIAL_CHREC && TREE_CODE (access_fn_b) == POLYNOMIAL_CHREC) { int dist, loop_nb, loop_depth; int loop_nb_a = CHREC_VARIABLE (access_fn_a); int loop_nb_b = CHREC_VARIABLE (access_fn_b); struct loop *loop_a = current_loops->parray[loop_nb_a]; struct loop *loop_b = current_loops->parray[loop_nb_b]; /* If the loop for either variable is at a lower depth than the first_loop's depth, then we can't possibly have a dependency at this level of the loop. */ if (loop_a->depth < first_loop_depth || loop_b->depth < first_loop_depth) return false; if (loop_nb_a != loop_nb_b && !flow_loop_nested_p (loop_a, loop_b) && !flow_loop_nested_p (loop_b, loop_a)) { /* Example: when there are two consecutive loops, | loop_1 | A[{0, +, 1}_1] | endloop_1 | loop_2 | A[{0, +, 1}_2] | endloop_2 the dependence relation cannot be captured by the distance abstraction. */ non_affine_dependence_relation (ddr); return true; } /* The dependence is carried by the outermost loop. Example: | loop_1 | A[{4, +, 1}_1] | loop_2 | A[{5, +, 1}_2] | endloop_2 | endloop_1 In this case, the dependence is carried by loop_1. */ loop_nb = loop_nb_a < loop_nb_b ? loop_nb_a : loop_nb_b; loop_depth = current_loops->parray[loop_nb]->depth - first_loop_depth; /* If the loop number is still greater than the number of loops we've been asked to analyze, or negative, something is borked. */ gcc_assert (loop_depth >= 0); gcc_assert (loop_depth < nb_loops); if (chrec_contains_undetermined (SUB_DISTANCE (subscript))) { non_affine_dependence_relation (ddr); return true; } dist = int_cst_value (SUB_DISTANCE (subscript)); /* This is the subscript coupling test. | loop i = 0, N, 1 | T[i+1][i] = ... | ... = T[i][i] | endloop There is no dependence. */ if (init_v[loop_depth] != 0 && dist_v[loop_depth] != dist) { finalize_ddr_dependent (ddr, chrec_known); return true; } dist_v[loop_depth] = dist; init_v[loop_depth] = 1; init_b = true; } } /* Save the distance vector if we initialized one. */ if (init_b) { lambda_vector save_v; /* Verify a basic constraint: classic distance vectors should always be lexicographically positive. */ if (!lambda_vector_lexico_pos (dist_v, DDR_SIZE_VECT (ddr))) { if (DDR_SIZE_VECT (ddr) == 1) /* This one is simple to fix, and can be fixed. Multidimensional arrays cannot be fixed that simply. */ lambda_vector_negate (dist_v, dist_v, DDR_SIZE_VECT (ddr)); else /* This is not valid: we need the delta test for properly fixing all this. */ return false; } save_v = lambda_vector_new (DDR_SIZE_VECT (ddr)); lambda_vector_copy (dist_v, save_v, DDR_SIZE_VECT (ddr)); VEC_safe_push (lambda_vector, heap, DDR_DIST_VECTS (ddr), save_v); /* There is nothing more to do when there are no outer loops. */ if (DDR_SIZE_VECT (ddr) == 1) goto classic_dist_done; } /* There is a distance of 1 on all the outer loops: Example: there is a dependence of distance 1 on loop_1 for the array A. | loop_1 | A[5] = ... | endloop */ { struct loop *lca, *loop_a, *loop_b; struct data_reference *a = DDR_A (ddr); struct data_reference *b = DDR_B (ddr); int lca_depth; loop_a = loop_containing_stmt (DR_STMT (a)); loop_b = loop_containing_stmt (DR_STMT (b)); /* Get the common ancestor loop. */ lca = find_common_loop (loop_a, loop_b); lca_depth = lca->depth - first_loop_depth; gcc_assert (lca_depth >= 0); gcc_assert (lca_depth < nb_loops); /* For each outer loop where init_v is not set, the accesses are in dependence of distance 1 in the loop. */ while (lca->depth != 0) { /* If we're considering just a sub-nest, then don't record any information on the outer loops. */ if (lca_depth < 0) break; gcc_assert (lca_depth < nb_loops); /* If we haven't yet determined a distance for this outer loop, push a new distance vector composed of the previous distance, and a distance of 1 for this outer loop. Example: | loop_1 | loop_2 | A[10] | endloop_2 | endloop_1 Saved vectors are of the form (dist_in_1, dist_in_2). First, we save (0, 1), then we have to save (1, 0). */ if (init_v[lca_depth] == 0) { lambda_vector save_v = lambda_vector_new (DDR_SIZE_VECT (ddr)); lambda_vector_copy (dist_v, save_v, DDR_SIZE_VECT (ddr)); save_v[lca_depth] = 1; VEC_safe_push (lambda_vector, heap, DDR_DIST_VECTS (ddr), save_v); } lca = lca->outer; lca_depth = lca->depth - first_loop_depth; } } classic_dist_done:; if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(build_classic_dist_vector\n"); for (i = 0; i < DDR_NUM_DIST_VECTS (ddr); i++) { fprintf (dump_file, " dist_vector = ("); print_lambda_vector (dump_file, DDR_DIST_VECT (ddr, i), DDR_SIZE_VECT (ddr)); fprintf (dump_file, " )\n"); } fprintf (dump_file, ")\n"); } return true; } /* Compute the classic per loop direction vector. DDR is the data dependence relation to build a vector from. NB_LOOPS is the total number of loops we are considering. FIRST_LOOP_DEPTH is the loop->depth of the first loop in the analyzed loop nest. Return FALSE if the dependence relation is outside of the loop nest at FIRST_LOOP_DEPTH. Return TRUE otherwise. */ static bool build_classic_dir_vector (struct data_dependence_relation *ddr, int nb_loops, int first_loop_depth) { unsigned i; lambda_vector dir_v, init_v; bool init_b = false; dir_v = lambda_vector_new (nb_loops); init_v = lambda_vector_new (nb_loops); lambda_vector_clear (dir_v, nb_loops); lambda_vector_clear (init_v, nb_loops); DDR_SIZE_VECT (ddr) = nb_loops; if (DDR_ARE_DEPENDENT (ddr) != NULL_TREE) return true; for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { tree access_fn_a, access_fn_b; struct subscript *subscript = DDR_SUBSCRIPT (ddr, i); if (chrec_contains_undetermined (SUB_DISTANCE (subscript))) { non_affine_dependence_relation (ddr); return true; } access_fn_a = DR_ACCESS_FN (DDR_A (ddr), i); access_fn_b = DR_ACCESS_FN (DDR_B (ddr), i); if (TREE_CODE (access_fn_a) == POLYNOMIAL_CHREC && TREE_CODE (access_fn_b) == POLYNOMIAL_CHREC) { int dist, loop_nb, loop_depth; enum data_dependence_direction dir = dir_star; int loop_nb_a = CHREC_VARIABLE (access_fn_a); int loop_nb_b = CHREC_VARIABLE (access_fn_b); struct loop *loop_a = current_loops->parray[loop_nb_a]; struct loop *loop_b = current_loops->parray[loop_nb_b]; /* If the loop for either variable is at a lower depth than the first_loop's depth, then we can't possibly have a dependency at this level of the loop. */ if (loop_a->depth < first_loop_depth || loop_b->depth < first_loop_depth) return false; if (loop_nb_a != loop_nb_b && !flow_loop_nested_p (loop_a, loop_b) && !flow_loop_nested_p (loop_b, loop_a)) { /* Example: when there are two consecutive loops, | loop_1 | A[{0, +, 1}_1] | endloop_1 | loop_2 | A[{0, +, 1}_2] | endloop_2 the dependence relation cannot be captured by the distance abstraction. */ non_affine_dependence_relation (ddr); return true; } /* The dependence is carried by the outermost loop. Example: | loop_1 | A[{4, +, 1}_1] | loop_2 | A[{5, +, 1}_2] | endloop_2 | endloop_1 In this case, the dependence is carried by loop_1. */ loop_nb = loop_nb_a < loop_nb_b ? loop_nb_a : loop_nb_b; loop_depth = current_loops->parray[loop_nb]->depth - first_loop_depth; /* If the loop number is still greater than the number of loops we've been asked to analyze, or negative, something is borked. */ gcc_assert (loop_depth >= 0); gcc_assert (loop_depth < nb_loops); if (chrec_contains_undetermined (SUB_DISTANCE (subscript))) { non_affine_dependence_relation (ddr); return true; } dist = int_cst_value (SUB_DISTANCE (subscript)); if (dist == 0) dir = dir_equal; else if (dist > 0) dir = dir_positive; else if (dist < 0) dir = dir_negative; /* This is the subscript coupling test. | loop i = 0, N, 1 | T[i+1][i] = ... | ... = T[i][i] | endloop There is no dependence. */ if (init_v[loop_depth] != 0 && dir != dir_star && (enum data_dependence_direction) dir_v[loop_depth] != dir && (enum data_dependence_direction) dir_v[loop_depth] != dir_star) { finalize_ddr_dependent (ddr, chrec_known); return true; } dir_v[loop_depth] = dir; init_v[loop_depth] = 1; init_b = true; } } /* Save the direction vector if we initialized one. */ if (init_b) { lambda_vector save_v = lambda_vector_new (DDR_SIZE_VECT (ddr)); lambda_vector_copy (dir_v, save_v, DDR_SIZE_VECT (ddr)); VEC_safe_push (lambda_vector, heap, DDR_DIR_VECTS (ddr), save_v); } /* There is a distance of 1 on all the outer loops: Example: there is a dependence of distance 1 on loop_1 for the array A. | loop_1 | A[5] = ... | endloop */ { struct loop *lca, *loop_a, *loop_b; struct data_reference *a = DDR_A (ddr); struct data_reference *b = DDR_B (ddr); int lca_depth; loop_a = loop_containing_stmt (DR_STMT (a)); loop_b = loop_containing_stmt (DR_STMT (b)); /* Get the common ancestor loop. */ lca = find_common_loop (loop_a, loop_b); lca_depth = lca->depth - first_loop_depth; gcc_assert (lca_depth >= 0); gcc_assert (lca_depth < nb_loops); while (lca->depth != 0) { /* If we're considering just a sub-nest, then don't record any information on the outer loops. */ if (lca_depth < 0) break; gcc_assert (lca_depth < nb_loops); if (init_v[lca_depth] == 0) { lambda_vector save_v = lambda_vector_new (DDR_SIZE_VECT (ddr)); lambda_vector_copy (dir_v, save_v, DDR_SIZE_VECT (ddr)); save_v[lca_depth] = dir_positive; VEC_safe_push (lambda_vector, heap, DDR_DIR_VECTS (ddr), save_v); } lca = lca->outer; lca_depth = lca->depth - first_loop_depth; } } return true; } /* Returns true when all the access functions of A are affine or constant. */ static bool access_functions_are_affine_or_constant_p (struct data_reference *a) { unsigned int i; VEC(tree,heap) **fns = DR_ACCESS_FNS_ADDR (a); tree t; for (i = 0; VEC_iterate (tree, *fns, i, t); i++) if (!evolution_function_is_constant_p (t) && !evolution_function_is_affine_multivariate_p (t)) return false; return true; } /* This computes the affine dependence relation between A and B. CHREC_KNOWN is used for representing the independence between two accesses, while CHREC_DONT_KNOW is used for representing the unknown relation. Note that it is possible to stop the computation of the dependence relation the first time we detect a CHREC_KNOWN element for a given subscript. */ void compute_affine_dependence (struct data_dependence_relation *ddr) { struct data_reference *dra = DDR_A (ddr); struct data_reference *drb = DDR_B (ddr); if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "(compute_affine_dependence\n"); fprintf (dump_file, " (stmt_a = \n"); print_generic_expr (dump_file, DR_STMT (dra), 0); fprintf (dump_file, ")\n (stmt_b = \n"); print_generic_expr (dump_file, DR_STMT (drb), 0); fprintf (dump_file, ")\n"); } /* Analyze only when the dependence relation is not yet known. */ if (DDR_ARE_DEPENDENT (ddr) == NULL_TREE) { if (access_functions_are_affine_or_constant_p (dra) && access_functions_are_affine_or_constant_p (drb)) subscript_dependence_tester (ddr); /* As a last case, if the dependence cannot be determined, or if the dependence is considered too difficult to determine, answer "don't know". */ else finalize_ddr_dependent (ddr, chrec_dont_know); } if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, ")\n"); } /* This computes the dependence relation for the same data reference into DDR. */ static void compute_self_dependence (struct data_dependence_relation *ddr) { unsigned int i; for (i = 0; i < DDR_NUM_SUBSCRIPTS (ddr); i++) { struct subscript *subscript = DDR_SUBSCRIPT (ddr, i); /* The accessed index overlaps for each iteration. */ SUB_CONFLICTS_IN_A (subscript) = integer_zero_node; SUB_CONFLICTS_IN_B (subscript) = integer_zero_node; SUB_LAST_CONFLICT (subscript) = chrec_dont_know; } } typedef struct data_dependence_relation *ddr_p; DEF_VEC_P(ddr_p); DEF_VEC_ALLOC_P(ddr_p,heap); /* Compute a subset of the data dependence relation graph. Don't compute read-read and self relations if COMPUTE_SELF_AND_READ_READ_DEPENDENCES is FALSE, and avoid the computation of the opposite relation, i.e. when AB has been computed, don't compute BA. DATAREFS contains a list of data references, and the result is set in DEPENDENCE_RELATIONS. */ static void compute_all_dependences (varray_type datarefs, bool compute_self_and_read_read_dependences, VEC(ddr_p,heap) **dependence_relations) { unsigned int i, j, N; N = VARRAY_ACTIVE_SIZE (datarefs); /* Note that we specifically skip i == j because it's a self dependence, and use compute_self_dependence below. */ for (i = 0; i < N; i++) for (j = i + 1; j < N; j++) { struct data_reference *a, *b; struct data_dependence_relation *ddr; a = VARRAY_GENERIC_PTR (datarefs, i); b = VARRAY_GENERIC_PTR (datarefs, j); if (DR_IS_READ (a) && DR_IS_READ (b) && !compute_self_and_read_read_dependences) continue; ddr = initialize_data_dependence_relation (a, b); VEC_safe_push (ddr_p, heap, *dependence_relations, ddr); compute_affine_dependence (ddr); compute_subscript_distance (ddr); } if (!compute_self_and_read_read_dependences) return; /* Compute self dependence relation of each dataref to itself. */ for (i = 0; i < N; i++) { struct data_reference *a, *b; struct data_dependence_relation *ddr; a = VARRAY_GENERIC_PTR (datarefs, i); b = VARRAY_GENERIC_PTR (datarefs, i); ddr = initialize_data_dependence_relation (a, b); VEC_safe_push (ddr_p, heap, *dependence_relations, ddr); compute_self_dependence (ddr); compute_subscript_distance (ddr); } } /* Search the data references in LOOP, and record the information into DATAREFS. Returns chrec_dont_know when failing to analyze a difficult case, returns NULL_TREE otherwise. TODO: This function should be made smarter so that it can handle address arithmetic as if they were array accesses, etc. */ tree find_data_references_in_loop (struct loop *loop, varray_type *datarefs) { basic_block bb, *bbs; unsigned int i; block_stmt_iterator bsi; struct data_reference *dr; bbs = get_loop_body (loop); for (i = 0; i < loop->num_nodes; i++) { bb = bbs[i]; for (bsi = bsi_start (bb); !bsi_end_p (bsi); bsi_next (&bsi)) { tree stmt = bsi_stmt (bsi); /* ASM_EXPR and CALL_EXPR may embed arbitrary side effects. Calls have side-effects, except those to const or pure functions. */ if ((TREE_CODE (stmt) == CALL_EXPR && !(call_expr_flags (stmt) & (ECF_CONST | ECF_PURE))) || (TREE_CODE (stmt) == ASM_EXPR && ASM_VOLATILE_P (stmt))) goto insert_dont_know_node; if (ZERO_SSA_OPERANDS (stmt, SSA_OP_ALL_VIRTUALS)) continue; switch (TREE_CODE (stmt)) { case MODIFY_EXPR: { bool one_inserted = false; tree opnd0 = TREE_OPERAND (stmt, 0); tree opnd1 = TREE_OPERAND (stmt, 1); if (TREE_CODE (opnd0) == ARRAY_REF || TREE_CODE (opnd0) == INDIRECT_REF) { dr = create_data_ref (opnd0, stmt, false); if (dr) { VARRAY_PUSH_GENERIC_PTR (*datarefs, dr); one_inserted = true; } } if (TREE_CODE (opnd1) == ARRAY_REF || TREE_CODE (opnd1) == INDIRECT_REF) { dr = create_data_ref (opnd1, stmt, true); if (dr) { VARRAY_PUSH_GENERIC_PTR (*datarefs, dr); one_inserted = true; } } if (!one_inserted) goto insert_dont_know_node; break; } case CALL_EXPR: { tree args; bool one_inserted = false; for (args = TREE_OPERAND (stmt, 1); args; args = TREE_CHAIN (args)) if (TREE_CODE (TREE_VALUE (args)) == ARRAY_REF || TREE_CODE (TREE_VALUE (args)) == INDIRECT_REF) { dr = create_data_ref (TREE_VALUE (args), stmt, true); if (dr) { VARRAY_PUSH_GENERIC_PTR (*datarefs, dr); one_inserted = true; } } if (!one_inserted) goto insert_dont_know_node; break; } default: { struct data_reference *res; insert_dont_know_node:; res = xmalloc (sizeof (struct data_reference)); DR_STMT (res) = NULL_TREE; DR_REF (res) = NULL_TREE; DR_BASE_OBJECT (res) = NULL; DR_TYPE (res) = ARRAY_REF_TYPE; DR_SET_ACCESS_FNS (res, NULL); DR_BASE_OBJECT (res) = NULL; DR_IS_READ (res) = false; DR_BASE_ADDRESS (res) = NULL_TREE; DR_OFFSET (res) = NULL_TREE; DR_INIT (res) = NULL_TREE; DR_STEP (res) = NULL_TREE; DR_OFFSET_MISALIGNMENT (res) = NULL_TREE; DR_MEMTAG (res) = NULL_TREE; DR_PTR_INFO (res) = NULL; VARRAY_PUSH_GENERIC_PTR (*datarefs, res); free (bbs); return chrec_dont_know; } } /* When there are no defs in the loop, the loop is parallel. */ if (!ZERO_SSA_OPERANDS (stmt, SSA_OP_VIRTUAL_DEFS)) loop->parallel_p = false; } } free (bbs); return NULL_TREE; } /* This section contains all the entry points. */ /* Given a loop nest LOOP, the following vectors are returned: *DATAREFS is initialized to all the array elements contained in this loop, *DEPENDENCE_RELATIONS contains the relations between the data references. Compute read-read and self relations if COMPUTE_SELF_AND_READ_READ_DEPENDENCES is TRUE. */ void compute_data_dependences_for_loop (struct loop *loop, bool compute_self_and_read_read_dependences, varray_type *datarefs, varray_type *dependence_relations) { unsigned int i, nb_loops; VEC(ddr_p,heap) *allrelations; struct data_dependence_relation *ddr; struct loop *loop_nest = loop; while (loop_nest && loop_nest->outer && loop_nest->outer->outer) loop_nest = loop_nest->outer; nb_loops = loop_nest->level; /* If one of the data references is not computable, give up without spending time to compute other dependences. */ if (find_data_references_in_loop (loop, datarefs) == chrec_dont_know) { struct data_dependence_relation *ddr; /* Insert a single relation into dependence_relations: chrec_dont_know. */ ddr = initialize_data_dependence_relation (NULL, NULL); VARRAY_PUSH_GENERIC_PTR (*dependence_relations, ddr); build_classic_dist_vector (ddr, nb_loops, loop->depth); build_classic_dir_vector (ddr, nb_loops, loop->depth); return; } allrelations = NULL; compute_all_dependences (*datarefs, compute_self_and_read_read_dependences, &allrelations); for (i = 0; VEC_iterate (ddr_p, allrelations, i, ddr); i++) { if (build_classic_dist_vector (ddr, nb_loops, loop_nest->depth)) { VARRAY_PUSH_GENERIC_PTR (*dependence_relations, ddr); build_classic_dir_vector (ddr, nb_loops, loop_nest->depth); } } } /* Entry point (for testing only). Analyze all the data references and the dependence relations. The data references are computed first. A relation on these nodes is represented by a complete graph. Some of the relations could be of no interest, thus the relations can be computed on demand. In the following function we compute all the relations. This is just a first implementation that is here for: - for showing how to ask for the dependence relations, - for the debugging the whole dependence graph, - for the dejagnu testcases and maintenance. It is possible to ask only for a part of the graph, avoiding to compute the whole dependence graph. The computed dependences are stored in a knowledge base (KB) such that later queries don't recompute the same information. The implementation of this KB is transparent to the optimizer, and thus the KB can be changed with a more efficient implementation, or the KB could be disabled. */ void analyze_all_data_dependences (struct loops *loops) { unsigned int i; varray_type datarefs; varray_type dependence_relations; int nb_data_refs = 10; VARRAY_GENERIC_PTR_INIT (datarefs, nb_data_refs, "datarefs"); VARRAY_GENERIC_PTR_INIT (dependence_relations, nb_data_refs * nb_data_refs, "dependence_relations"); /* Compute DDs on the whole function. */ compute_data_dependences_for_loop (loops->parray[0], false, &datarefs, &dependence_relations); if (dump_file) { dump_data_dependence_relations (dump_file, dependence_relations); fprintf (dump_file, "\n\n"); if (dump_flags & TDF_DETAILS) dump_dist_dir_vectors (dump_file, dependence_relations); if (dump_flags & TDF_STATS) { unsigned nb_top_relations = 0; unsigned nb_bot_relations = 0; unsigned nb_basename_differ = 0; unsigned nb_chrec_relations = 0; for (i = 0; i < VARRAY_ACTIVE_SIZE (dependence_relations); i++) { struct data_dependence_relation *ddr; ddr = VARRAY_GENERIC_PTR (dependence_relations, i); if (chrec_contains_undetermined (DDR_ARE_DEPENDENT (ddr))) nb_top_relations++; else if (DDR_ARE_DEPENDENT (ddr) == chrec_known) { struct data_reference *a = DDR_A (ddr); struct data_reference *b = DDR_B (ddr); bool differ_p; if ((DR_BASE_OBJECT (a) && DR_BASE_OBJECT (b) && DR_NUM_DIMENSIONS (a) != DR_NUM_DIMENSIONS (b)) || (base_object_differ_p (a, b, &differ_p) && differ_p)) nb_basename_differ++; else nb_bot_relations++; } else nb_chrec_relations++; } gather_stats_on_scev_database (); } } free_dependence_relations (dependence_relations); free_data_refs (datarefs); } /* Free the memory used by a data dependence relation DDR. */ void free_dependence_relation (struct data_dependence_relation *ddr) { if (ddr == NULL) return; if (DDR_ARE_DEPENDENT (ddr) == NULL_TREE && DDR_SUBSCRIPTS (ddr)) varray_clear (DDR_SUBSCRIPTS (ddr)); free (ddr); } /* Free the memory used by the data dependence relations from DEPENDENCE_RELATIONS. */ void free_dependence_relations (varray_type dependence_relations) { unsigned int i; if (dependence_relations == NULL) return; for (i = 0; i < VARRAY_ACTIVE_SIZE (dependence_relations); i++) free_dependence_relation (VARRAY_GENERIC_PTR (dependence_relations, i)); varray_clear (dependence_relations); } /* Free the memory used by the data references from DATAREFS. */ void free_data_refs (varray_type datarefs) { unsigned int i; if (datarefs == NULL) return; for (i = 0; i < VARRAY_ACTIVE_SIZE (datarefs); i++) { struct data_reference *dr = (struct data_reference *) VARRAY_GENERIC_PTR (datarefs, i); if (dr) { DR_FREE_ACCESS_FNS (dr); free (dr); } } varray_clear (datarefs); }