/* Interprocedural constant propagation Copyright (C) 2005, 2006, 2007, 2008, 2009, 2010 Free Software Foundation, Inc. Contributed by Razya Ladelsky 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 3, 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 COPYING3. If not see . */ /* Interprocedural constant propagation. The aim of interprocedural constant propagation (IPCP) is to find which function's argument has the same constant value in each invocation throughout the whole program. For example, consider the following program: int g (int y) { printf ("value is %d",y); } int f (int x) { g (x); } int h (int y) { g (y); } void main (void) { f (3); h (3); } The IPCP algorithm will find that g's formal argument y is always called with the value 3. The algorithm used is based on "Interprocedural Constant Propagation", by Challahan David, Keith D Cooper, Ken Kennedy, Linda Torczon, Comp86, pg 152-161 The optimization is divided into three stages: First stage - intraprocedural analysis ======================================= This phase computes jump_function and modification flags. A jump function for a callsite represents the values passed as an actual arguments of a given callsite. There are three types of values: Pass through - the caller's formal parameter is passed as an actual argument. Constant - a constant is passed as an actual argument. Unknown - neither of the above. The jump function info, ipa_jump_func, is stored in ipa_edge_args structure (defined in ipa_prop.h and pointed to by cgraph_node->aux) modified_flags are defined in ipa_node_params structure (defined in ipa_prop.h and pointed to by cgraph_edge->aux). -ipcp_generate_summary() is the first stage driver. Second stage - interprocedural analysis ======================================== This phase does the interprocedural constant propagation. It computes lattices for all formal parameters in the program and their value that may be: TOP - unknown. BOTTOM - non constant. CONSTANT - constant value. Lattice describing a formal parameter p will have a constant value if all callsites invoking this function have the same constant value passed to p. The lattices are stored in ipcp_lattice which is itself in ipa_node_params structure (defined in ipa_prop.h and pointed to by cgraph_edge->aux). -ipcp_iterate_stage() is the second stage driver. Third phase - transformation of function code ============================================ Propagates the constant-valued formals into the function. For each function whose parameters are constants, we create its clone. Then we process the clone in two ways: 1. We insert an assignment statement 'parameter = const' at the beginning of the cloned function. 2. For read-only parameters that do not live in memory, we replace all their uses with the constant. We also need to modify some callsites to call the cloned functions instead of the original ones. For a callsite passing an argument found to be a constant by IPCP, there are two different cases to handle: 1. A constant is passed as an argument. In this case the callsite in the should be redirected to call the cloned callee. 2. A parameter (of the caller) passed as an argument (pass through argument). In such cases both the caller and the callee have clones and only the callsite in the cloned caller is redirected to call to the cloned callee. This update is done in two steps: First all cloned functions are created during a traversal of the call graph, during which all callsites are redirected to call the cloned function. Then the callsites are traversed and many calls redirected back to fit the description above. -ipcp_insert_stage() is the third phase driver. This pass also performs devirtualization - turns virtual calls into direct ones if it can prove that all invocations of the function call the same callee. This is achieved by building a list of all base types (actually, their BINFOs) that individual parameters can have in an iterative matter just like propagating scalar constants and then examining whether virtual calls which take a parameter as their object fold to the same target for all these types. If we cannot enumerate all types or there is a type which does not have any BINFO associated with it, cannot_devirtualize of the associated parameter descriptor is set which is an equivalent of BOTTOM lattice value in standard IPA constant propagation. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tree.h" #include "target.h" #include "gimple.h" #include "cgraph.h" #include "ipa-prop.h" #include "tree-flow.h" #include "tree-pass.h" #include "flags.h" #include "timevar.h" #include "diagnostic.h" #include "tree-pretty-print.h" #include "tree-dump.h" #include "tree-inline.h" #include "fibheap.h" #include "params.h" /* Number of functions identified as candidates for cloning. When not cloning we can simplify iterate stage not forcing it to go through the decision on what is profitable and what not. */ static int n_cloning_candidates; /* Maximal count found in program. */ static gcov_type max_count; /* Cgraph nodes that has been completely replaced by cloning during iterate * stage and will be removed after ipcp is finished. */ static bitmap dead_nodes; static void ipcp_print_profile_data (FILE *); static void ipcp_function_scale_print (FILE *); /* Get the original node field of ipa_node_params associated with node NODE. */ static inline struct cgraph_node * ipcp_get_orig_node (struct cgraph_node *node) { return IPA_NODE_REF (node)->ipcp_orig_node; } /* Return true if NODE describes a cloned/versioned function. */ static inline bool ipcp_node_is_clone (struct cgraph_node *node) { return (ipcp_get_orig_node (node) != NULL); } /* Create ipa_node_params and its data structures for NEW_NODE. Set ORIG_NODE as the ipcp_orig_node field in ipa_node_params. */ static void ipcp_init_cloned_node (struct cgraph_node *orig_node, struct cgraph_node *new_node) { gcc_checking_assert (ipa_node_params_vector && (VEC_length (ipa_node_params_t, ipa_node_params_vector) > (unsigned) cgraph_max_uid)); gcc_checking_assert (IPA_NODE_REF (new_node)->params); IPA_NODE_REF (new_node)->ipcp_orig_node = orig_node; } /* Return scale for NODE. */ static inline gcov_type ipcp_get_node_scale (struct cgraph_node *node) { return IPA_NODE_REF (node)->count_scale; } /* Set COUNT as scale for NODE. */ static inline void ipcp_set_node_scale (struct cgraph_node *node, gcov_type count) { IPA_NODE_REF (node)->count_scale = count; } /* Return whether LAT is a constant lattice. */ static inline bool ipcp_lat_is_const (struct ipcp_lattice *lat) { if (lat->type == IPA_CONST_VALUE) return true; else return false; } /* Return whether LAT is a constant lattice that ipa-cp can actually insert into the code (i.e. constants excluding member pointers and pointers). */ static inline bool ipcp_lat_is_insertable (struct ipcp_lattice *lat) { return lat->type == IPA_CONST_VALUE; } /* Return true if LAT1 and LAT2 are equal. */ static inline bool ipcp_lats_are_equal (struct ipcp_lattice *lat1, struct ipcp_lattice *lat2) { gcc_assert (ipcp_lat_is_const (lat1) && ipcp_lat_is_const (lat2)); if (lat1->type != lat2->type) return false; if (TREE_CODE (lat1->constant) == ADDR_EXPR && TREE_CODE (lat2->constant) == ADDR_EXPR && TREE_CODE (TREE_OPERAND (lat1->constant, 0)) == CONST_DECL && TREE_CODE (TREE_OPERAND (lat2->constant, 0)) == CONST_DECL) return operand_equal_p (DECL_INITIAL (TREE_OPERAND (lat1->constant, 0)), DECL_INITIAL (TREE_OPERAND (lat2->constant, 0)), 0); else return operand_equal_p (lat1->constant, lat2->constant, 0); } /* Compute Meet arithmetics: Meet (IPA_BOTTOM, x) = IPA_BOTTOM Meet (IPA_TOP,x) = x Meet (const_a,const_b) = IPA_BOTTOM, if const_a != const_b. MEET (const_a,const_b) = const_a, if const_a == const_b.*/ static void ipa_lattice_meet (struct ipcp_lattice *res, struct ipcp_lattice *lat1, struct ipcp_lattice *lat2) { if (lat1->type == IPA_BOTTOM || lat2->type == IPA_BOTTOM) { res->type = IPA_BOTTOM; return; } if (lat1->type == IPA_TOP) { res->type = lat2->type; res->constant = lat2->constant; return; } if (lat2->type == IPA_TOP) { res->type = lat1->type; res->constant = lat1->constant; return; } if (!ipcp_lats_are_equal (lat1, lat2)) { res->type = IPA_BOTTOM; return; } res->type = lat1->type; res->constant = lat1->constant; } /* Return the lattice corresponding to the Ith formal parameter of the function described by INFO. */ static inline struct ipcp_lattice * ipcp_get_lattice (struct ipa_node_params *info, int i) { return &(info->params[i].ipcp_lattice); } /* Given the jump function JFUNC, compute the lattice LAT that describes the value coming down the callsite. INFO describes the caller node so that pass-through jump functions can be evaluated. */ static void ipcp_lattice_from_jfunc (struct ipa_node_params *info, struct ipcp_lattice *lat, struct ipa_jump_func *jfunc) { if (jfunc->type == IPA_JF_CONST) { lat->type = IPA_CONST_VALUE; lat->constant = jfunc->value.constant; } else if (jfunc->type == IPA_JF_PASS_THROUGH) { struct ipcp_lattice *caller_lat; tree cst; caller_lat = ipcp_get_lattice (info, jfunc->value.pass_through.formal_id); lat->type = caller_lat->type; if (caller_lat->type != IPA_CONST_VALUE) return; cst = caller_lat->constant; if (jfunc->value.pass_through.operation != NOP_EXPR) { tree restype; if (TREE_CODE_CLASS (jfunc->value.pass_through.operation) == tcc_comparison) restype = boolean_type_node; else restype = TREE_TYPE (cst); cst = fold_binary (jfunc->value.pass_through.operation, restype, cst, jfunc->value.pass_through.operand); } if (!cst || !is_gimple_ip_invariant (cst)) lat->type = IPA_BOTTOM; lat->constant = cst; } else if (jfunc->type == IPA_JF_ANCESTOR) { struct ipcp_lattice *caller_lat; tree t; caller_lat = ipcp_get_lattice (info, jfunc->value.ancestor.formal_id); lat->type = caller_lat->type; if (caller_lat->type != IPA_CONST_VALUE) return; if (TREE_CODE (caller_lat->constant) != ADDR_EXPR) { /* This can happen when the constant is a NULL pointer. */ lat->type = IPA_BOTTOM; return; } t = TREE_OPERAND (caller_lat->constant, 0); t = build_ref_for_offset (EXPR_LOCATION (t), t, jfunc->value.ancestor.offset, jfunc->value.ancestor.type, NULL, false); lat->constant = build_fold_addr_expr (t); } else lat->type = IPA_BOTTOM; } /* True when OLD_LAT and NEW_LAT values are not the same. */ static bool ipcp_lattice_changed (struct ipcp_lattice *old_lat, struct ipcp_lattice *new_lat) { if (old_lat->type == new_lat->type) { if (!ipcp_lat_is_const (old_lat)) return false; if (ipcp_lats_are_equal (old_lat, new_lat)) return false; } return true; } /* Print all ipcp_lattices of all functions to F. */ static void ipcp_print_all_lattices (FILE * f) { struct cgraph_node *node; int i, count; fprintf (f, "\nLattice:\n"); for (node = cgraph_nodes; node; node = node->next) { struct ipa_node_params *info; if (!node->analyzed) continue; info = IPA_NODE_REF (node); fprintf (f, " Node: %s:\n", cgraph_node_name (node)); count = ipa_get_param_count (info); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); fprintf (f, " param [%d]: ", i); if (lat->type == IPA_CONST_VALUE) { tree cst = lat->constant; fprintf (f, "type is CONST "); print_generic_expr (f, cst, 0); if (TREE_CODE (cst) == ADDR_EXPR && TREE_CODE (TREE_OPERAND (cst, 0)) == CONST_DECL) { fprintf (f, " -> "); print_generic_expr (f, DECL_INITIAL (TREE_OPERAND (cst, 0)), 0); } } else if (lat->type == IPA_TOP) fprintf (f, "type is TOP"); else fprintf (f, "type is BOTTOM"); if (ipa_param_cannot_devirtualize_p (info, i)) fprintf (f, " - cannot_devirtualize set\n"); else if (ipa_param_types_vec_empty (info, i)) fprintf (f, " - type list empty\n"); else fprintf (f, "\n"); } } } /* Return true if ipcp algorithms would allow cloning NODE. */ static bool ipcp_versionable_function_p (struct cgraph_node *node) { struct cgraph_edge *edge; /* There are a number of generic reasons functions cannot be versioned. We also cannot remove parameters if there are type attributes such as fnspec present. */ if (!node->local.versionable || TYPE_ATTRIBUTES (TREE_TYPE (node->decl))) return false; /* Removing arguments doesn't work if the function takes varargs or use __builtin_apply_args. */ for (edge = node->callees; edge; edge = edge->next_callee) { tree t = edge->callee->decl; if (DECL_BUILT_IN_CLASS (t) == BUILT_IN_NORMAL && (DECL_FUNCTION_CODE (t) == BUILT_IN_APPLY_ARGS || DECL_FUNCTION_CODE (t) == BUILT_IN_VA_START)) return false; } return true; } /* Return true if this NODE is viable candidate for cloning. */ static bool ipcp_cloning_candidate_p (struct cgraph_node *node) { int n_calls = 0; int n_hot_calls = 0; gcov_type direct_call_sum = 0; struct cgraph_edge *e; /* We never clone functions that are not visible from outside. FIXME: in future we should clone such functions when they are called with different constants, but current ipcp implementation is not good on this. */ if (cgraph_only_called_directly_p (node) || !node->analyzed) return false; /* When function address is taken, we are pretty sure it will be called in hidden way. */ if (node->address_taken) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; address is taken.\n", cgraph_node_name (node)); return false; } if (cgraph_function_body_availability (node) <= AVAIL_OVERWRITABLE) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; body is overwrittable.\n", cgraph_node_name (node)); return false; } if (!ipcp_versionable_function_p (node)) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; body is not versionable.\n", cgraph_node_name (node)); return false; } for (e = node->callers; e; e = e->next_caller) { direct_call_sum += e->count; n_calls ++; if (cgraph_maybe_hot_edge_p (e)) n_hot_calls ++; } if (!n_calls) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; no direct calls.\n", cgraph_node_name (node)); return false; } if (node->local.inline_summary.self_size < n_calls) { if (dump_file) fprintf (dump_file, "Considering %s for cloning; code would shrink.\n", cgraph_node_name (node)); return true; } if (!flag_ipa_cp_clone) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; -fipa-cp-clone disabled.\n", cgraph_node_name (node)); return false; } if (!optimize_function_for_speed_p (DECL_STRUCT_FUNCTION (node->decl))) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; optimizing it for size.\n", cgraph_node_name (node)); return false; } /* When profile is available and function is hot, propagate into it even if calls seems cold; constant propagation can improve function's speed significandly. */ if (max_count) { if (direct_call_sum > node->count * 90 / 100) { if (dump_file) fprintf (dump_file, "Considering %s for cloning; usually called directly.\n", cgraph_node_name (node)); return true; } } if (!n_hot_calls) { if (dump_file) fprintf (dump_file, "Not considering %s for cloning; no hot calls.\n", cgraph_node_name (node)); return false; } if (dump_file) fprintf (dump_file, "Considering %s for cloning.\n", cgraph_node_name (node)); return true; } /* Mark parameter with index I of function described by INFO as unsuitable for devirtualization. Return true if it has already been marked so. */ static bool ipa_set_param_cannot_devirtualize (struct ipa_node_params *info, int i) { bool ret = info->params[i].cannot_devirtualize; info->params[i].cannot_devirtualize = true; if (info->params[i].types) VEC_free (tree, heap, info->params[i].types); return ret; } /* Initialize ipcp_lattices array. The lattices corresponding to supported types (integers, real types and Fortran constants defined as const_decls) are initialized to IPA_TOP, the rest of them to IPA_BOTTOM. */ static void ipcp_initialize_node_lattices (struct cgraph_node *node) { int i; struct ipa_node_params *info = IPA_NODE_REF (node); enum ipa_lattice_type type; if (ipa_is_called_with_var_arguments (info)) type = IPA_BOTTOM; else if (node->local.local) type = IPA_TOP; /* When cloning is allowed, we can assume that externally visible functions are not called. We will compensate this by cloning later. */ else if (ipcp_cloning_candidate_p (node)) type = IPA_TOP, n_cloning_candidates ++; else type = IPA_BOTTOM; for (i = 0; i < ipa_get_param_count (info) ; i++) { ipcp_get_lattice (info, i)->type = type; if (type == IPA_BOTTOM) ipa_set_param_cannot_devirtualize (info, i); } } /* build INTEGER_CST tree with type TREE_TYPE and value according to LAT. Return the tree. */ static tree build_const_val (struct ipcp_lattice *lat, tree tree_type) { tree val; gcc_assert (ipcp_lat_is_const (lat)); val = lat->constant; if (!useless_type_conversion_p (tree_type, TREE_TYPE (val))) { if (fold_convertible_p (tree_type, val)) return fold_build1 (NOP_EXPR, tree_type, val); else return fold_build1 (VIEW_CONVERT_EXPR, tree_type, val); } return val; } /* Compute the proper scale for NODE. It is the ratio between the number of direct calls (represented on the incoming cgraph_edges) and sum of all invocations of NODE (represented as count in cgraph_node). FIXME: This code is wrong. Since the callers can be also clones and the clones are not scaled yet, the sums gets unrealistically high. To properly compute the counts, we would need to do propagation across callgraph (as external call to A might imply call to non-clonned B if A's clone calls clonned B). */ static void ipcp_compute_node_scale (struct cgraph_node *node) { gcov_type sum; struct cgraph_edge *cs; sum = 0; /* Compute sum of all counts of callers. */ for (cs = node->callers; cs != NULL; cs = cs->next_caller) sum += cs->count; /* Work around the unrealistically high sum problem. We just don't want the non-cloned body to have negative or very low frequency. Since majority of execution time will be spent in clones anyway, this should give good enough profile. */ if (sum > node->count * 9 / 10) sum = node->count * 9 / 10; if (node->count == 0) ipcp_set_node_scale (node, 0); else ipcp_set_node_scale (node, sum * REG_BR_PROB_BASE / node->count); } /* Return true if there are some formal parameters whose value is IPA_TOP (in the whole compilation unit). Change their values to IPA_BOTTOM, since they most probably get their values from outside of this compilation unit. */ static bool ipcp_change_tops_to_bottom (void) { int i, count; struct cgraph_node *node; bool prop_again; prop_again = false; for (node = cgraph_nodes; node; node = node->next) { struct ipa_node_params *info = IPA_NODE_REF (node); count = ipa_get_param_count (info); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); if (lat->type == IPA_TOP) { prop_again = true; if (dump_file) { fprintf (dump_file, "Forcing param "); print_generic_expr (dump_file, ipa_get_param (info, i), 0); fprintf (dump_file, " of node %s to bottom.\n", cgraph_node_name (node)); } lat->type = IPA_BOTTOM; } if (!ipa_param_cannot_devirtualize_p (info, i) && ipa_param_types_vec_empty (info, i)) { prop_again = true; ipa_set_param_cannot_devirtualize (info, i); if (dump_file) { fprintf (dump_file, "Marking param "); print_generic_expr (dump_file, ipa_get_param (info, i), 0); fprintf (dump_file, " of node %s as unusable for " "devirtualization.\n", cgraph_node_name (node)); } } } } return prop_again; } /* Insert BINFO to the list of known types of parameter number I of the function described by CALLEE_INFO. Return true iff the type information associated with the callee parameter changed in any way. */ static bool ipcp_add_param_type (struct ipa_node_params *callee_info, int i, tree binfo) { int j, count; if (ipa_param_cannot_devirtualize_p (callee_info, i)) return false; if (callee_info->params[i].types) { count = VEC_length (tree, callee_info->params[i].types); for (j = 0; j < count; j++) if (VEC_index (tree, callee_info->params[i].types, j) == binfo) return false; } if (VEC_length (tree, callee_info->params[i].types) == (unsigned) PARAM_VALUE (PARAM_DEVIRT_TYPE_LIST_SIZE)) return !ipa_set_param_cannot_devirtualize (callee_info, i); VEC_safe_push (tree, heap, callee_info->params[i].types, binfo); return true; } /* Copy known types information for parameter number CALLEE_IDX of CALLEE_INFO from a parameter of CALLER_INFO as described by JF. Return true iff the type information changed in any way. JF must be a pass-through or an ancestor jump function. */ static bool ipcp_copy_types (struct ipa_node_params *caller_info, struct ipa_node_params *callee_info, int callee_idx, struct ipa_jump_func *jf) { int caller_idx, j, count; bool res; if (ipa_param_cannot_devirtualize_p (callee_info, callee_idx)) return false; if (jf->type == IPA_JF_PASS_THROUGH) { if (jf->value.pass_through.operation != NOP_EXPR) { ipa_set_param_cannot_devirtualize (callee_info, callee_idx); return true; } caller_idx = jf->value.pass_through.formal_id; } else caller_idx = jf->value.ancestor.formal_id; if (ipa_param_cannot_devirtualize_p (caller_info, caller_idx)) { ipa_set_param_cannot_devirtualize (callee_info, callee_idx); return true; } if (!caller_info->params[caller_idx].types) return false; res = false; count = VEC_length (tree, caller_info->params[caller_idx].types); for (j = 0; j < count; j++) { tree binfo = VEC_index (tree, caller_info->params[caller_idx].types, j); if (jf->type == IPA_JF_ANCESTOR) { binfo = get_binfo_at_offset (binfo, jf->value.ancestor.offset, jf->value.ancestor.type); if (!binfo) { ipa_set_param_cannot_devirtualize (callee_info, callee_idx); return true; } } res |= ipcp_add_param_type (callee_info, callee_idx, binfo); } return res; } /* Propagate type information for parameter of CALLEE_INFO number I as described by JF. CALLER_INFO describes the caller. Return true iff the type information changed in any way. */ static bool ipcp_propagate_types (struct ipa_node_params *caller_info, struct ipa_node_params *callee_info, struct ipa_jump_func *jf, int i) { tree cst, binfo; switch (jf->type) { case IPA_JF_UNKNOWN: case IPA_JF_CONST_MEMBER_PTR: break; case IPA_JF_KNOWN_TYPE: return ipcp_add_param_type (callee_info, i, jf->value.base_binfo); case IPA_JF_CONST: cst = jf->value.constant; if (TREE_CODE (cst) != ADDR_EXPR) break; binfo = gimple_get_relevant_ref_binfo (TREE_OPERAND (cst, 0), NULL_TREE); if (!binfo) break; return ipcp_add_param_type (callee_info, i, binfo); case IPA_JF_PASS_THROUGH: case IPA_JF_ANCESTOR: return ipcp_copy_types (caller_info, callee_info, i, jf); } /* If we reach this we cannot use this parameter for devirtualization. */ return !ipa_set_param_cannot_devirtualize (callee_info, i); } /* Interprocedural analysis. The algorithm propagates constants from the caller's parameters to the callee's arguments. */ static void ipcp_propagate_stage (void) { int i; struct ipcp_lattice inc_lat = { IPA_BOTTOM, NULL }; struct ipcp_lattice new_lat = { IPA_BOTTOM, NULL }; struct ipcp_lattice *dest_lat; struct cgraph_edge *cs; struct ipa_jump_func *jump_func; struct ipa_func_list *wl; int count; ipa_check_create_node_params (); ipa_check_create_edge_args (); /* Initialize worklist to contain all functions. */ wl = ipa_init_func_list (); while (wl) { struct cgraph_node *node = ipa_pop_func_from_list (&wl); struct ipa_node_params *info = IPA_NODE_REF (node); for (cs = node->callees; cs; cs = cs->next_callee) { struct ipa_node_params *callee_info = IPA_NODE_REF (cs->callee); struct ipa_edge_args *args = IPA_EDGE_REF (cs); if (ipa_is_called_with_var_arguments (callee_info) || !cs->callee->analyzed || ipa_is_called_with_var_arguments (callee_info)) continue; count = ipa_get_cs_argument_count (args); for (i = 0; i < count; i++) { jump_func = ipa_get_ith_jump_func (args, i); ipcp_lattice_from_jfunc (info, &inc_lat, jump_func); dest_lat = ipcp_get_lattice (callee_info, i); ipa_lattice_meet (&new_lat, &inc_lat, dest_lat); if (ipcp_lattice_changed (&new_lat, dest_lat)) { dest_lat->type = new_lat.type; dest_lat->constant = new_lat.constant; ipa_push_func_to_list (&wl, cs->callee); } if (ipcp_propagate_types (info, callee_info, jump_func, i)) ipa_push_func_to_list (&wl, cs->callee); } } } } /* Call the constant propagation algorithm and re-call it if necessary (if there are undetermined values left). */ static void ipcp_iterate_stage (void) { struct cgraph_node *node; n_cloning_candidates = 0; if (dump_file) fprintf (dump_file, "\nIPA iterate stage:\n\n"); if (in_lto_p) ipa_update_after_lto_read (); for (node = cgraph_nodes; node; node = node->next) { ipcp_initialize_node_lattices (node); ipcp_compute_node_scale (node); } if (dump_file && (dump_flags & TDF_DETAILS)) { ipcp_print_all_lattices (dump_file); ipcp_function_scale_print (dump_file); } ipcp_propagate_stage (); if (ipcp_change_tops_to_bottom ()) /* Some lattices have changed from IPA_TOP to IPA_BOTTOM. This change should be propagated. */ { gcc_assert (n_cloning_candidates); ipcp_propagate_stage (); } if (dump_file) { fprintf (dump_file, "\nIPA lattices after propagation:\n"); ipcp_print_all_lattices (dump_file); if (dump_flags & TDF_DETAILS) ipcp_print_profile_data (dump_file); } } /* Check conditions to forbid constant insertion to function described by NODE. */ static inline bool ipcp_node_modifiable_p (struct cgraph_node *node) { /* Once we will be able to do in-place replacement, we can be more lax here. */ return ipcp_versionable_function_p (node); } /* Print count scale data structures. */ static void ipcp_function_scale_print (FILE * f) { struct cgraph_node *node; for (node = cgraph_nodes; node; node = node->next) { if (!node->analyzed) continue; fprintf (f, "printing scale for %s: ", cgraph_node_name (node)); fprintf (f, "value is " HOST_WIDE_INT_PRINT_DEC " \n", (HOST_WIDE_INT) ipcp_get_node_scale (node)); } } /* Print counts of all cgraph nodes. */ static void ipcp_print_func_profile_counts (FILE * f) { struct cgraph_node *node; for (node = cgraph_nodes; node; node = node->next) { fprintf (f, "function %s: ", cgraph_node_name (node)); fprintf (f, "count is " HOST_WIDE_INT_PRINT_DEC " \n", (HOST_WIDE_INT) node->count); } } /* Print counts of all cgraph edges. */ static void ipcp_print_call_profile_counts (FILE * f) { struct cgraph_node *node; struct cgraph_edge *cs; for (node = cgraph_nodes; node; node = node->next) { for (cs = node->callees; cs; cs = cs->next_callee) { fprintf (f, "%s -> %s ", cgraph_node_name (cs->caller), cgraph_node_name (cs->callee)); fprintf (f, "count is " HOST_WIDE_INT_PRINT_DEC " \n", (HOST_WIDE_INT) cs->count); } } } /* Print profile info for all functions. */ static void ipcp_print_profile_data (FILE * f) { fprintf (f, "\nNODE COUNTS :\n"); ipcp_print_func_profile_counts (f); fprintf (f, "\nCS COUNTS stage:\n"); ipcp_print_call_profile_counts (f); } /* Build and initialize ipa_replace_map struct according to LAT. This struct is processed by versioning, which operates according to the flags set. PARM_TREE is the formal parameter found to be constant. LAT represents the constant. */ static struct ipa_replace_map * ipcp_create_replace_map (tree parm_tree, struct ipcp_lattice *lat) { struct ipa_replace_map *replace_map; tree const_val; replace_map = ggc_alloc_ipa_replace_map (); const_val = build_const_val (lat, TREE_TYPE (parm_tree)); if (dump_file) { fprintf (dump_file, " replacing param "); print_generic_expr (dump_file, parm_tree, 0); fprintf (dump_file, " with const "); print_generic_expr (dump_file, const_val, 0); fprintf (dump_file, "\n"); } replace_map->old_tree = parm_tree; replace_map->new_tree = const_val; replace_map->replace_p = true; replace_map->ref_p = false; return replace_map; } /* Return true if this callsite should be redirected to the original callee (instead of the cloned one). */ static bool ipcp_need_redirect_p (struct cgraph_edge *cs) { struct ipa_node_params *orig_callee_info; int i, count; struct cgraph_node *node = cs->callee, *orig; if (!n_cloning_candidates) return false; if ((orig = ipcp_get_orig_node (node)) != NULL) node = orig; if (ipcp_get_orig_node (cs->caller)) return false; orig_callee_info = IPA_NODE_REF (node); count = ipa_get_param_count (orig_callee_info); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (orig_callee_info, i); struct ipa_jump_func *jump_func; jump_func = ipa_get_ith_jump_func (IPA_EDGE_REF (cs), i); if ((ipcp_lat_is_const (lat) && jump_func->type != IPA_JF_CONST) || (!ipa_param_cannot_devirtualize_p (orig_callee_info, i) && !ipa_param_types_vec_empty (orig_callee_info, i) && jump_func->type != IPA_JF_CONST && jump_func->type != IPA_JF_KNOWN_TYPE)) return true; } return false; } /* Fix the callsites and the call graph after function cloning was done. */ static void ipcp_update_callgraph (void) { struct cgraph_node *node; for (node = cgraph_nodes; node; node = node->next) if (node->analyzed && ipcp_node_is_clone (node)) { bitmap args_to_skip = BITMAP_ALLOC (NULL); struct cgraph_node *orig_node = ipcp_get_orig_node (node); struct ipa_node_params *info = IPA_NODE_REF (orig_node); int i, count = ipa_get_param_count (info); struct cgraph_edge *cs, *next; for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); /* We can proactively remove obviously unused arguments. */ if (!ipa_is_param_used (info, i)) { bitmap_set_bit (args_to_skip, i); continue; } if (lat->type == IPA_CONST_VALUE) bitmap_set_bit (args_to_skip, i); } for (cs = node->callers; cs; cs = next) { next = cs->next_caller; if (!ipcp_node_is_clone (cs->caller) && ipcp_need_redirect_p (cs)) { if (dump_file) fprintf (dump_file, "Redirecting edge %s/%i -> %s/%i " "back to %s/%i.", cgraph_node_name (cs->caller), cs->caller->uid, cgraph_node_name (cs->callee), cs->callee->uid, cgraph_node_name (orig_node), orig_node->uid); cgraph_redirect_edge_callee (cs, orig_node); } } } } /* Update profiling info for versioned functions and the functions they were versioned from. */ static void ipcp_update_profiling (void) { struct cgraph_node *node, *orig_node; gcov_type scale, scale_complement; struct cgraph_edge *cs; for (node = cgraph_nodes; node; node = node->next) { if (ipcp_node_is_clone (node)) { orig_node = ipcp_get_orig_node (node); scale = ipcp_get_node_scale (orig_node); node->count = orig_node->count * scale / REG_BR_PROB_BASE; scale_complement = REG_BR_PROB_BASE - scale; orig_node->count = orig_node->count * scale_complement / REG_BR_PROB_BASE; for (cs = node->callees; cs; cs = cs->next_callee) cs->count = cs->count * scale / REG_BR_PROB_BASE; for (cs = orig_node->callees; cs; cs = cs->next_callee) cs->count = cs->count * scale_complement / REG_BR_PROB_BASE; } } } /* If NODE was cloned, how much would program grow? */ static long ipcp_estimate_growth (struct cgraph_node *node) { struct cgraph_edge *cs; int redirectable_node_callers = 0; int removable_args = 0; bool need_original = !cgraph_will_be_removed_from_program_if_no_direct_calls (node); struct ipa_node_params *info; int i, count; int growth; for (cs = node->callers; cs != NULL; cs = cs->next_caller) if (cs->caller == node || !ipcp_need_redirect_p (cs)) redirectable_node_callers++; else need_original = true; /* If we will be able to fully replace orignal node, we never increase program size. */ if (!need_original) return 0; info = IPA_NODE_REF (node); count = ipa_get_param_count (info); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); /* We can proactively remove obviously unused arguments. */ if (!ipa_is_param_used (info, i)) removable_args++; if (lat->type == IPA_CONST_VALUE) removable_args++; } /* We make just very simple estimate of savings for removal of operand from call site. Precise cost is dificult to get, as our size metric counts constants and moves as free. Generally we are looking for cases that small function is called very many times. */ growth = node->local.inline_summary.self_size - removable_args * redirectable_node_callers; if (growth < 0) return 0; return growth; } /* Estimate cost of cloning NODE. */ static long ipcp_estimate_cloning_cost (struct cgraph_node *node) { int freq_sum = 1; gcov_type count_sum = 1; struct cgraph_edge *e; int cost; cost = ipcp_estimate_growth (node) * 1000; if (!cost) { if (dump_file) fprintf (dump_file, "Versioning of %s will save code size\n", cgraph_node_name (node)); return 0; } for (e = node->callers; e; e = e->next_caller) if (!bitmap_bit_p (dead_nodes, e->caller->uid) && !ipcp_need_redirect_p (e)) { count_sum += e->count; freq_sum += e->frequency + 1; } if (max_count) cost /= count_sum * 1000 / max_count + 1; else cost /= freq_sum * 1000 / REG_BR_PROB_BASE + 1; if (dump_file) fprintf (dump_file, "Cost of versioning %s is %i, (size: %i, freq: %i)\n", cgraph_node_name (node), cost, node->local.inline_summary.self_size, freq_sum); return cost + 1; } /* Walk indirect calls of NODE and if any polymorphic can be turned into a direct one now, do so. */ static void ipcp_process_devirtualization_opportunities (struct cgraph_node *node) { struct ipa_node_params *info = IPA_NODE_REF (node); struct cgraph_edge *ie, *next_ie; for (ie = node->indirect_calls; ie; ie = next_ie) { int param_index, types_count, j; HOST_WIDE_INT token; tree target; next_ie = ie->next_callee; if (!ie->indirect_info->polymorphic) continue; param_index = ie->indirect_info->param_index; if (param_index == -1 || ipa_param_cannot_devirtualize_p (info, param_index) || ipa_param_types_vec_empty (info, param_index)) continue; token = ie->indirect_info->otr_token; target = NULL_TREE; types_count = VEC_length (tree, info->params[param_index].types); for (j = 0; j < types_count; j++) { tree binfo = VEC_index (tree, info->params[param_index].types, j); tree t = gimple_fold_obj_type_ref_known_binfo (token, binfo); if (!t) { target = NULL_TREE; break; } else if (!target) target = t; else if (target != t) { target = NULL_TREE; break; } } if (target) ipa_make_edge_direct_to_target (ie, target); } } /* Return number of live constant parameters. */ static int ipcp_const_param_count (struct cgraph_node *node) { int const_param = 0; struct ipa_node_params *info = IPA_NODE_REF (node); int count = ipa_get_param_count (info); int i; for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); if ((ipcp_lat_is_insertable (lat) /* Do not count obviously unused arguments. */ && ipa_is_param_used (info, i)) || (!ipa_param_cannot_devirtualize_p (info, i) && !ipa_param_types_vec_empty (info, i))) const_param++; } return const_param; } /* Given that a formal parameter of NODE given by INDEX is known to be constant CST, try to find any indirect edges that can be made direct and make them so. Note that INDEX is the number the parameter at the time of analyzing parameter uses and parameter removals should not be considered for it. (In fact, the parameter itself has just been removed.) */ static void ipcp_discover_new_direct_edges (struct cgraph_node *node, int index, tree cst) { struct cgraph_edge *ie, *next_ie; for (ie = node->indirect_calls; ie; ie = next_ie) { struct cgraph_indirect_call_info *ici = ie->indirect_info; next_ie = ie->next_callee; if (ici->param_index != index) continue; if (ici->polymorphic) { tree binfo; HOST_WIDE_INT token; if (TREE_CODE (cst) != ADDR_EXPR) continue; binfo = gimple_get_relevant_ref_binfo (TREE_OPERAND (cst, 0), NULL_TREE); if (!binfo) continue; gcc_assert (ie->indirect_info->anc_offset == 0); token = ie->indirect_info->otr_token; cst = gimple_fold_obj_type_ref_known_binfo (token, binfo); if (!cst) continue; } ipa_make_edge_direct_to_target (ie, cst); } } /* Propagate the constant parameters found by ipcp_iterate_stage() to the function's code. */ static void ipcp_insert_stage (void) { struct cgraph_node *node, *node1 = NULL; int i; VEC (cgraph_edge_p, heap) * redirect_callers; VEC (ipa_replace_map_p,gc)* replace_trees; int node_callers, count; tree parm_tree; struct ipa_replace_map *replace_param; fibheap_t heap; long overall_size = 0, new_size = 0; long max_new_size; ipa_check_create_node_params (); ipa_check_create_edge_args (); if (dump_file) fprintf (dump_file, "\nIPA insert stage:\n\n"); dead_nodes = BITMAP_ALLOC (NULL); for (node = cgraph_nodes; node; node = node->next) if (node->analyzed) { if (node->count > max_count) max_count = node->count; overall_size += node->local.inline_summary.self_size; } max_new_size = overall_size; if (max_new_size < PARAM_VALUE (PARAM_LARGE_UNIT_INSNS)) max_new_size = PARAM_VALUE (PARAM_LARGE_UNIT_INSNS); max_new_size = max_new_size * PARAM_VALUE (PARAM_IPCP_UNIT_GROWTH) / 100 + 1; /* First collect all functions we proved to have constant arguments to heap. */ heap = fibheap_new (); for (node = cgraph_nodes; node; node = node->next) { struct ipa_node_params *info; /* Propagation of the constant is forbidden in certain conditions. */ if (!node->analyzed || !ipcp_node_modifiable_p (node)) continue; info = IPA_NODE_REF (node); if (ipa_is_called_with_var_arguments (info)) continue; if (ipcp_const_param_count (node)) node->aux = fibheap_insert (heap, ipcp_estimate_cloning_cost (node), node); } /* Now clone in priority order until code size growth limits are met or heap is emptied. */ while (!fibheap_empty (heap)) { struct ipa_node_params *info; int growth = 0; bitmap args_to_skip; struct cgraph_edge *cs; node = (struct cgraph_node *)fibheap_extract_min (heap); node->aux = NULL; if (dump_file) fprintf (dump_file, "considering function %s\n", cgraph_node_name (node)); growth = ipcp_estimate_growth (node); if (new_size + growth > max_new_size) break; if (growth && optimize_function_for_size_p (DECL_STRUCT_FUNCTION (node->decl))) { if (dump_file) fprintf (dump_file, "Not versioning, cold code would grow"); continue; } new_size += growth; /* Look if original function becomes dead after clonning. */ for (cs = node->callers; cs != NULL; cs = cs->next_caller) if (cs->caller == node || ipcp_need_redirect_p (cs)) break; if (!cs && cgraph_will_be_removed_from_program_if_no_direct_calls (node)) bitmap_set_bit (dead_nodes, node->uid); info = IPA_NODE_REF (node); count = ipa_get_param_count (info); replace_trees = VEC_alloc (ipa_replace_map_p, gc, 1); args_to_skip = BITMAP_GGC_ALLOC (); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); parm_tree = ipa_get_param (info, i); /* We can proactively remove obviously unused arguments. */ if (!ipa_is_param_used (info, i)) { bitmap_set_bit (args_to_skip, i); continue; } if (lat->type == IPA_CONST_VALUE) { replace_param = ipcp_create_replace_map (parm_tree, lat); VEC_safe_push (ipa_replace_map_p, gc, replace_trees, replace_param); bitmap_set_bit (args_to_skip, i); } } /* Compute how many callers node has. */ node_callers = 0; for (cs = node->callers; cs != NULL; cs = cs->next_caller) node_callers++; redirect_callers = VEC_alloc (cgraph_edge_p, heap, node_callers); for (cs = node->callers; cs != NULL; cs = cs->next_caller) if (!cs->indirect_inlining_edge) VEC_quick_push (cgraph_edge_p, redirect_callers, cs); /* Redirecting all the callers of the node to the new versioned node. */ node1 = cgraph_create_virtual_clone (node, redirect_callers, replace_trees, args_to_skip, "constprop"); args_to_skip = NULL; VEC_free (cgraph_edge_p, heap, redirect_callers); replace_trees = NULL; if (node1 == NULL) continue; ipcp_process_devirtualization_opportunities (node1); if (dump_file) fprintf (dump_file, "versioned function %s with growth %i, overall %i\n", cgraph_node_name (node), (int)growth, (int)new_size); ipcp_init_cloned_node (node, node1); info = IPA_NODE_REF (node); for (i = 0; i < count; i++) { struct ipcp_lattice *lat = ipcp_get_lattice (info, i); if (lat->type == IPA_CONST_VALUE) ipcp_discover_new_direct_edges (node1, i, lat->constant); } if (dump_file) dump_function_to_file (node1->decl, dump_file, dump_flags); for (cs = node->callees; cs; cs = cs->next_callee) if (cs->callee->aux) { fibheap_delete_node (heap, (fibnode_t) cs->callee->aux); cs->callee->aux = fibheap_insert (heap, ipcp_estimate_cloning_cost (cs->callee), cs->callee); } } while (!fibheap_empty (heap)) { if (dump_file) fprintf (dump_file, "skipping function %s\n", cgraph_node_name (node)); node = (struct cgraph_node *) fibheap_extract_min (heap); node->aux = NULL; } fibheap_delete (heap); BITMAP_FREE (dead_nodes); ipcp_update_callgraph (); ipcp_update_profiling (); } /* The IPCP driver. */ static unsigned int ipcp_driver (void) { cgraph_remove_unreachable_nodes (true,dump_file); if (dump_file) { fprintf (dump_file, "\nIPA structures before propagation:\n"); if (dump_flags & TDF_DETAILS) ipa_print_all_params (dump_file); ipa_print_all_jump_functions (dump_file); } /* 2. Do the interprocedural propagation. */ ipcp_iterate_stage (); /* 3. Insert the constants found to the functions. */ ipcp_insert_stage (); if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "\nProfiling info after insert stage:\n"); ipcp_print_profile_data (dump_file); } /* Free all IPCP structures. */ ipa_free_all_structures_after_ipa_cp (); if (dump_file) fprintf (dump_file, "\nIPA constant propagation end\n"); return 0; } /* Initialization and computation of IPCP data structures. This is the initial intraprocedural analysis of functions, which gathers information to be propagated later on. */ static void ipcp_generate_summary (void) { struct cgraph_node *node; if (dump_file) fprintf (dump_file, "\nIPA constant propagation start:\n"); ipa_check_create_node_params (); ipa_check_create_edge_args (); ipa_register_cgraph_hooks (); for (node = cgraph_nodes; node; node = node->next) if (node->analyzed) { /* Unreachable nodes should have been eliminated before ipcp. */ gcc_assert (node->needed || node->reachable); node->local.versionable = tree_versionable_function_p (node->decl); ipa_analyze_node (node); } } /* Write ipcp summary for nodes in SET. */ static void ipcp_write_summary (cgraph_node_set set, varpool_node_set vset ATTRIBUTE_UNUSED) { ipa_prop_write_jump_functions (set); } /* Read ipcp summary. */ static void ipcp_read_summary (void) { ipa_prop_read_jump_functions (); } /* Gate for IPCP optimization. */ static bool cgraph_gate_cp (void) { /* FIXME: We should remove the optimize check after we ensure we never run IPA passes when not optimizng. */ return flag_ipa_cp && optimize; } struct ipa_opt_pass_d pass_ipa_cp = { { IPA_PASS, "cp", /* name */ cgraph_gate_cp, /* gate */ ipcp_driver, /* execute */ NULL, /* sub */ NULL, /* next */ 0, /* static_pass_number */ TV_IPA_CONSTANT_PROP, /* tv_id */ 0, /* properties_required */ 0, /* properties_provided */ 0, /* properties_destroyed */ 0, /* todo_flags_start */ TODO_dump_cgraph | TODO_dump_func | TODO_remove_functions | TODO_ggc_collect /* todo_flags_finish */ }, ipcp_generate_summary, /* generate_summary */ ipcp_write_summary, /* write_summary */ ipcp_read_summary, /* read_summary */ NULL, /* write_optimization_summary */ NULL, /* read_optimization_summary */ NULL, /* stmt_fixup */ 0, /* TODOs */ NULL, /* function_transform */ NULL, /* variable_transform */ };