/* Basic IPA optimizations and utilities. Copyright (C) 2003-2014 Free Software Foundation, Inc. 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 . */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "tree.h" #include "calls.h" #include "stringpool.h" #include "predict.h" #include "basic-block.h" #include "cgraph.h" #include "tree-pass.h" #include "hash-map.h" #include "hash-set.h" #include "gimple-expr.h" #include "gimplify.h" #include "flags.h" #include "target.h" #include "tree-iterator.h" #include "ipa-utils.h" #include "ipa-inline.h" #include "tree-inline.h" #include "profile.h" #include "params.h" #include "internal-fn.h" #include "tree-ssa-alias.h" #include "gimple.h" #include "dbgcnt.h" /* Return true when NODE has ADDR reference. */ static bool has_addr_references_p (struct cgraph_node *node, void *data ATTRIBUTE_UNUSED) { int i; struct ipa_ref *ref = NULL; for (i = 0; node->iterate_referring (i, ref); i++) if (ref->use == IPA_REF_ADDR) return true; return false; } /* Look for all functions inlined to NODE and update their inlined_to pointers to INLINED_TO. */ static void update_inlined_to_pointer (struct cgraph_node *node, struct cgraph_node *inlined_to) { struct cgraph_edge *e; for (e = node->callees; e; e = e->next_callee) if (e->callee->global.inlined_to) { e->callee->global.inlined_to = inlined_to; update_inlined_to_pointer (e->callee, inlined_to); } } /* Add symtab NODE to queue starting at FIRST. The queue is linked via AUX pointers and terminated by pointer to 1. We enqueue nodes at two occasions: when we find them reachable or when we find their bodies needed for further clonning. In the second case we mark them by pointer to 2 after processing so they are re-queue when they become reachable. */ static void enqueue_node (symtab_node *node, symtab_node **first, hash_set *reachable) { /* Node is still in queue; do nothing. */ if (node->aux && node->aux != (void *) 2) return; /* Node was already processed as unreachable, re-enqueue only if it became reachable now. */ if (node->aux == (void *)2 && !reachable->contains (node)) return; node->aux = *first; *first = node; } /* Process references. */ static void process_references (symtab_node *snode, symtab_node **first, bool before_inlining_p, hash_set *reachable) { int i; struct ipa_ref *ref = NULL; for (i = 0; snode->iterate_reference (i, ref); i++) { symtab_node *node = ref->referred; if (node->definition && !node->in_other_partition && ((!DECL_EXTERNAL (node->decl) || node->alias) || (((before_inlining_p && (symtab->state < IPA_SSA || !lookup_attribute ("always_inline", DECL_ATTRIBUTES (node->decl))))) /* We use variable constructors during late complation for constant folding. Keep references alive so partitioning knows about potential references. */ || (TREE_CODE (node->decl) == VAR_DECL && flag_wpa && ctor_for_folding (node->decl) != error_mark_node)))) reachable->add (node); enqueue_node (node, first, reachable); } } /* EDGE is an polymorphic call. If BEFORE_INLINING_P is set, mark all its potential targets as reachable to permit later inlining if devirtualization happens. After inlining still keep their declarations around, so we can devirtualize to a direct call. Also try to make trivial devirutalization when no or only one target is possible. */ static void walk_polymorphic_call_targets (hash_set *reachable_call_targets, struct cgraph_edge *edge, symtab_node **first, hash_set *reachable, bool before_inlining_p) { unsigned int i; void *cache_token; bool final; vec targets = possible_polymorphic_call_targets (edge, &final, &cache_token); if (!reachable_call_targets->add (cache_token)) { for (i = 0; i < targets.length (); i++) { struct cgraph_node *n = targets[i]; /* Do not bother to mark virtual methods in anonymous namespace; either we will find use of virtual table defining it, or it is unused. */ if (TREE_CODE (TREE_TYPE (n->decl)) == METHOD_TYPE && type_in_anonymous_namespace_p (method_class_type (TREE_TYPE (n->decl)))) continue; /* Prior inlining, keep alive bodies of possible targets for devirtualization. */ if (n->definition && (before_inlining_p && (symtab->state < IPA_SSA || !lookup_attribute ("always_inline", DECL_ATTRIBUTES (n->decl))))) reachable->add (n); /* Even after inlining we want to keep the possible targets in the boundary, so late passes can still produce direct call even if the chance for inlining is lost. */ enqueue_node (n, first, reachable); } } /* Very trivial devirtualization; when the type is final or anonymous (so we know all its derivation) and there is only one possible virtual call target, make the edge direct. */ if (final) { if (targets.length () <= 1 && dbg_cnt (devirt)) { cgraph_node *target, *node = edge->caller; if (targets.length () == 1) target = targets[0]; else target = cgraph_node::get_create (builtin_decl_implicit (BUILT_IN_UNREACHABLE)); if (dump_enabled_p ()) { location_t locus; if (edge->call_stmt) locus = gimple_location (edge->call_stmt); else locus = UNKNOWN_LOCATION; dump_printf_loc (MSG_OPTIMIZED_LOCATIONS, locus, "devirtualizing call in %s/%i to %s/%i\n", edge->caller->name (), edge->caller->order, target->name (), target->order); } edge = edge->make_direct (target); if (inline_summary_vec) inline_update_overall_summary (node); else if (edge->call_stmt) edge->redirect_call_stmt_to_callee (); } } } /* Perform reachability analysis and reclaim all unreachable nodes. The algorithm is basically mark&sweep but with some extra refinements: - reachable extern inline functions needs special handling; the bodies needs to stay in memory until inlining in hope that they will be inlined. After inlining we release their bodies and turn them into unanalyzed nodes even when they are reachable. BEFORE_INLINING_P specify whether we are before or after inlining. - virtual functions are kept in callgraph even if they seem unreachable in hope calls to them will be devirtualized. Again we remove them after inlining. In late optimization some devirtualization may happen, but it is not important since we won't inline the call. In theory early opts and IPA should work out all important cases. - virtual clones needs bodies of their origins for later materialization; this means that we want to keep the body even if the origin is unreachable otherwise. To avoid origin from sitting in the callgraph and being walked by IPA passes, we turn them into unanalyzed nodes with body defined. We maintain set of function declaration where body needs to stay in body_needed_for_clonning Inline clones represent special case: their declaration match the declaration of origin and cgraph_remove_node already knows how to reshape callgraph and preserve body when offline copy of function or inline clone is being removed. - C++ virtual tables keyed to other unit are represented as DECL_EXTERNAL variables with DECL_INITIAL set. We finalize these and keep reachable ones around for constant folding purposes. After inlining we however stop walking their references to let everything static referneced by them to be removed when it is otherwise unreachable. We maintain queue of both reachable symbols (i.e. defined symbols that needs to stay) and symbols that are in boundary (i.e. external symbols referenced by reachable symbols or origins of clones). The queue is represented as linked list by AUX pointer terminated by 1. At the end we keep all reachable symbols. For symbols in boundary we always turn definition into a declaration, but we may keep function body around based on body_needed_for_clonning All symbols that enter the queue have AUX pointer non-zero and are in the boundary. Pointer set REACHABLE is used to track reachable symbols. Every symbol can be visited twice - once as part of boundary and once as real reachable symbol. enqueue_node needs to decide whether the node needs to be re-queued for second processing. For this purpose we set AUX pointer of processed symbols in the boundary to constant 2. */ bool symbol_table::remove_unreachable_nodes (bool before_inlining_p, FILE *file) { symtab_node *first = (symtab_node *) (void *) 1; struct cgraph_node *node, *next; varpool_node *vnode, *vnext; bool changed = false; hash_set reachable; hash_set body_needed_for_clonning; hash_set reachable_call_targets; timevar_push (TV_IPA_UNREACHABLE); if (optimize && flag_devirtualize) build_type_inheritance_graph (); if (file) fprintf (file, "\nReclaiming functions:"); #ifdef ENABLE_CHECKING FOR_EACH_FUNCTION (node) gcc_assert (!node->aux); FOR_EACH_VARIABLE (vnode) gcc_assert (!vnode->aux); #endif /* Mark functions whose bodies are obviously needed. This is mostly when they can be referenced externally. Inline clones are special since their declarations are shared with master clone and thus cgraph_can_remove_if_no_direct_calls_and_refs_p should not be called on them. */ FOR_EACH_FUNCTION (node) { node->used_as_abstract_origin = false; if (node->definition && !node->global.inlined_to && !node->in_other_partition && !node->can_remove_if_no_direct_calls_and_refs_p ()) { gcc_assert (!node->global.inlined_to); reachable.add (node); enqueue_node (node, &first, &reachable); } else gcc_assert (!node->aux); } /* Mark variables that are obviously needed. */ FOR_EACH_DEFINED_VARIABLE (vnode) if (!vnode->can_remove_if_no_refs_p() && !vnode->in_other_partition) { reachable.add (vnode); enqueue_node (vnode, &first, &reachable); } /* Perform reachability analysis. */ while (first != (symtab_node *) (void *) 1) { bool in_boundary_p = !reachable.contains (first); symtab_node *node = first; first = (symtab_node *)first->aux; /* If we are processing symbol in boundary, mark its AUX pointer for possible later re-processing in enqueue_node. */ if (in_boundary_p) node->aux = (void *)2; else { if (TREE_CODE (node->decl) == FUNCTION_DECL && DECL_ABSTRACT_ORIGIN (node->decl)) { struct cgraph_node *origin_node = cgraph_node::get_create (DECL_ABSTRACT_ORIGIN (node->decl)); origin_node->used_as_abstract_origin = true; enqueue_node (origin_node, &first, &reachable); } /* If any symbol in a comdat group is reachable, force all externally visible symbols in the same comdat group to be reachable as well. Comdat-local symbols can be discarded if all uses were inlined. */ if (node->same_comdat_group) { symtab_node *next; for (next = node->same_comdat_group; next != node; next = next->same_comdat_group) if (!next->comdat_local_p () && !reachable.add (next)) enqueue_node (next, &first, &reachable); } /* Mark references as reachable. */ process_references (node, &first, before_inlining_p, &reachable); } if (cgraph_node *cnode = dyn_cast (node)) { /* Mark the callees reachable unless they are direct calls to extern inline functions we decided to not inline. */ if (!in_boundary_p) { struct cgraph_edge *e; /* Keep alive possible targets for devirtualization. */ if (optimize && flag_devirtualize) { struct cgraph_edge *next; for (e = cnode->indirect_calls; e; e = next) { next = e->next_callee; if (e->indirect_info->polymorphic) walk_polymorphic_call_targets (&reachable_call_targets, e, &first, &reachable, before_inlining_p); } } for (e = cnode->callees; e; e = e->next_callee) { if (e->callee->definition && !e->callee->in_other_partition && (!e->inline_failed || !DECL_EXTERNAL (e->callee->decl) || e->callee->alias || before_inlining_p)) { /* Be sure that we will not optimize out alias target body. */ if (DECL_EXTERNAL (e->callee->decl) && e->callee->alias && before_inlining_p) reachable.add (e->callee->function_symbol ()); reachable.add (e->callee); } enqueue_node (e->callee, &first, &reachable); } /* When inline clone exists, mark body to be preserved so when removing offline copy of the function we don't kill it. */ if (cnode->global.inlined_to) body_needed_for_clonning.add (cnode->decl); /* For non-inline clones, force their origins to the boundary and ensure that body is not removed. */ while (cnode->clone_of) { bool noninline = cnode->clone_of->decl != cnode->decl; cnode = cnode->clone_of; if (noninline) { body_needed_for_clonning.add (cnode->decl); enqueue_node (cnode, &first, &reachable); } } } /* If any reachable function has simd clones, mark them as reachable as well. */ if (cnode->simd_clones) { cgraph_node *next; for (next = cnode->simd_clones; next; next = next->simdclone->next_clone) if (in_boundary_p || !reachable.add (next)) enqueue_node (next, &first, &reachable); } } /* When we see constructor of external variable, keep referred nodes in the boundary. This will also hold initializers of the external vars NODE refers to. */ varpool_node *vnode = dyn_cast (node); if (vnode && DECL_EXTERNAL (node->decl) && !vnode->alias && in_boundary_p) { struct ipa_ref *ref = NULL; for (int i = 0; node->iterate_reference (i, ref); i++) enqueue_node (ref->referred, &first, &reachable); } } /* Remove unreachable functions. */ for (node = first_function (); node; node = next) { next = next_function (node); /* If node is not needed at all, remove it. */ if (!node->aux) { if (file) fprintf (file, " %s/%i", node->name (), node->order); node->remove (); changed = true; } /* If node is unreachable, remove its body. */ else if (!reachable.contains (node)) { if (!body_needed_for_clonning.contains (node->decl)) node->release_body (); else if (!node->clone_of) gcc_assert (in_lto_p || DECL_RESULT (node->decl)); if (node->definition) { if (file) fprintf (file, " %s/%i", node->name (), node->order); node->body_removed = true; node->analyzed = false; node->definition = false; node->cpp_implicit_alias = false; node->alias = false; node->thunk.thunk_p = false; node->weakref = false; /* After early inlining we drop always_inline attributes on bodies of functions that are still referenced (have their address taken). */ DECL_ATTRIBUTES (node->decl) = remove_attribute ("always_inline", DECL_ATTRIBUTES (node->decl)); if (!node->in_other_partition) node->local.local = false; node->remove_callees (); node->remove_from_same_comdat_group (); node->remove_all_references (); changed = true; } } else gcc_assert (node->clone_of || !node->has_gimple_body_p () || in_lto_p || DECL_RESULT (node->decl)); } /* Inline clones might be kept around so their materializing allows further cloning. If the function the clone is inlined into is removed, we need to turn it into normal cone. */ FOR_EACH_FUNCTION (node) { if (node->global.inlined_to && !node->callers) { gcc_assert (node->clones); node->global.inlined_to = NULL; update_inlined_to_pointer (node, node); } node->aux = NULL; } /* Remove unreachable variables. */ if (file) fprintf (file, "\nReclaiming variables:"); for (vnode = first_variable (); vnode; vnode = vnext) { vnext = next_variable (vnode); if (!vnode->aux /* For can_refer_decl_in_current_unit_p we want to track for all external variables if they are defined in other partition or not. */ && (!flag_ltrans || !DECL_EXTERNAL (vnode->decl))) { if (file) fprintf (file, " %s/%i", vnode->name (), vnode->order); vnode->remove (); changed = true; } else if (!reachable.contains (vnode)) { tree init; if (vnode->definition) { if (file) fprintf (file, " %s", vnode->name ()); changed = true; } /* Keep body if it may be useful for constant folding. */ if ((init = ctor_for_folding (vnode->decl)) == error_mark_node) vnode->remove_initializer (); else DECL_INITIAL (vnode->decl) = init; vnode->body_removed = true; vnode->definition = false; vnode->analyzed = false; vnode->aux = NULL; vnode->remove_from_same_comdat_group (); vnode->remove_all_references (); } else vnode->aux = NULL; } /* Now update address_taken flags and try to promote functions to be local. */ if (file) fprintf (file, "\nClearing address taken flags:"); FOR_EACH_DEFINED_FUNCTION (node) if (node->address_taken && !node->used_from_other_partition) { if (!node->call_for_symbol_thunks_and_aliases (has_addr_references_p, NULL, true)) { if (file) fprintf (file, " %s", node->name ()); node->address_taken = false; changed = true; if (node->local_p ()) { node->local.local = true; if (file) fprintf (file, " (local)"); } } } if (file) fprintf (file, "\n"); #ifdef ENABLE_CHECKING symtab_node::verify_symtab_nodes (); #endif /* If we removed something, perhaps profile could be improved. */ if (changed && optimize && inline_edge_summary_vec.exists ()) FOR_EACH_DEFINED_FUNCTION (node) ipa_propagate_frequency (node); timevar_pop (TV_IPA_UNREACHABLE); return changed; } /* Process references to VNODE and set flags WRITTEN, ADDRESS_TAKEN, READ as needed, also clear EXPLICIT_REFS if the references to given variable do not need to be explicit. */ void process_references (varpool_node *vnode, bool *written, bool *address_taken, bool *read, bool *explicit_refs) { int i; struct ipa_ref *ref; if (!vnode->all_refs_explicit_p () || TREE_THIS_VOLATILE (vnode->decl)) *explicit_refs = false; for (i = 0; vnode->iterate_referring (i, ref) && *explicit_refs && (!*written || !*address_taken || !*read); i++) switch (ref->use) { case IPA_REF_ADDR: *address_taken = true; break; case IPA_REF_LOAD: *read = true; break; case IPA_REF_STORE: *written = true; break; case IPA_REF_ALIAS: process_references (dyn_cast (ref->referring), written, address_taken, read, explicit_refs); break; } } /* Set TREE_READONLY bit. */ bool set_readonly_bit (varpool_node *vnode, void *data ATTRIBUTE_UNUSED) { TREE_READONLY (vnode->decl) = true; return false; } /* Set writeonly bit and clear the initalizer, since it will not be needed. */ bool set_writeonly_bit (varpool_node *vnode, void *data ATTRIBUTE_UNUSED) { vnode->writeonly = true; if (optimize) { DECL_INITIAL (vnode->decl) = NULL; if (!vnode->alias) vnode->remove_all_references (); } return false; } /* Clear addressale bit of VNODE. */ bool clear_addressable_bit (varpool_node *vnode, void *data ATTRIBUTE_UNUSED) { vnode->address_taken = false; TREE_ADDRESSABLE (vnode->decl) = 0; return false; } /* Discover variables that have no longer address taken or that are read only and update their flags. FIXME: This can not be done in between gimplify and omp_expand since readonly flag plays role on what is shared and what is not. Currently we do this transformation as part of whole program visibility and re-do at ipa-reference pass (to take into account clonning), but it would make sense to do it before early optimizations. */ void ipa_discover_readonly_nonaddressable_vars (void) { varpool_node *vnode; if (dump_file) fprintf (dump_file, "Clearing variable flags:"); FOR_EACH_VARIABLE (vnode) if (!vnode->alias && (TREE_ADDRESSABLE (vnode->decl) || !vnode->writeonly || !TREE_READONLY (vnode->decl))) { bool written = false; bool address_taken = false; bool read = false; bool explicit_refs = true; process_references (vnode, &written, &address_taken, &read, &explicit_refs); if (!explicit_refs) continue; if (!address_taken) { if (TREE_ADDRESSABLE (vnode->decl) && dump_file) fprintf (dump_file, " %s (non-addressable)", vnode->name ()); vnode->call_for_node_and_aliases (clear_addressable_bit, NULL, true); } if (!address_taken && !written /* Making variable in explicit section readonly can cause section type conflict. See e.g. gcc.c-torture/compile/pr23237.c */ && vnode->get_section () == NULL) { if (!TREE_READONLY (vnode->decl) && dump_file) fprintf (dump_file, " %s (read-only)", vnode->name ()); vnode->call_for_node_and_aliases (set_readonly_bit, NULL, true); } if (!vnode->writeonly && !read && !address_taken && written) { if (dump_file) fprintf (dump_file, " %s (write-only)", vnode->name ()); vnode->call_for_node_and_aliases (set_writeonly_bit, NULL, true); } } if (dump_file) fprintf (dump_file, "\n"); } /* Free inline summary. */ namespace { const pass_data pass_data_ipa_free_inline_summary = { SIMPLE_IPA_PASS, /* type */ "free-inline-summary", /* name */ OPTGROUP_NONE, /* optinfo_flags */ TV_IPA_FREE_INLINE_SUMMARY, /* tv_id */ 0, /* properties_required */ 0, /* properties_provided */ 0, /* properties_destroyed */ 0, /* todo_flags_start */ /* Early optimizations may make function unreachable. We can not remove unreachable functions as part of the ealry opts pass because TODOs are run before subpasses. Do it here. */ ( TODO_remove_functions | TODO_dump_symtab ), /* todo_flags_finish */ }; class pass_ipa_free_inline_summary : public simple_ipa_opt_pass { public: pass_ipa_free_inline_summary (gcc::context *ctxt) : simple_ipa_opt_pass (pass_data_ipa_free_inline_summary, ctxt) {} /* opt_pass methods: */ virtual unsigned int execute (function *) { inline_free_summary (); return 0; } }; // class pass_ipa_free_inline_summary } // anon namespace simple_ipa_opt_pass * make_pass_ipa_free_inline_summary (gcc::context *ctxt) { return new pass_ipa_free_inline_summary (ctxt); } /* Generate and emit a static constructor or destructor. WHICH must be one of 'I' (for a constructor) or 'D' (for a destructor). BODY is a STATEMENT_LIST containing GENERIC statements. PRIORITY is the initialization priority for this constructor or destructor. FINAL specify whether the externally visible name for collect2 should be produced. */ static void cgraph_build_static_cdtor_1 (char which, tree body, int priority, bool final) { static int counter = 0; char which_buf[16]; tree decl, name, resdecl; /* The priority is encoded in the constructor or destructor name. collect2 will sort the names and arrange that they are called at program startup. */ if (final) sprintf (which_buf, "%c_%.5d_%d", which, priority, counter++); else /* Proudce sane name but one not recognizable by collect2, just for the case we fail to inline the function. */ sprintf (which_buf, "sub_%c_%.5d_%d", which, priority, counter++); name = get_file_function_name (which_buf); decl = build_decl (input_location, FUNCTION_DECL, name, build_function_type_list (void_type_node, NULL_TREE)); current_function_decl = decl; resdecl = build_decl (input_location, RESULT_DECL, NULL_TREE, void_type_node); DECL_ARTIFICIAL (resdecl) = 1; DECL_RESULT (decl) = resdecl; DECL_CONTEXT (resdecl) = decl; allocate_struct_function (decl, false); TREE_STATIC (decl) = 1; TREE_USED (decl) = 1; DECL_ARTIFICIAL (decl) = 1; DECL_NO_INSTRUMENT_FUNCTION_ENTRY_EXIT (decl) = 1; DECL_SAVED_TREE (decl) = body; if (!targetm.have_ctors_dtors && final) { TREE_PUBLIC (decl) = 1; DECL_PRESERVE_P (decl) = 1; } DECL_UNINLINABLE (decl) = 1; DECL_INITIAL (decl) = make_node (BLOCK); TREE_USED (DECL_INITIAL (decl)) = 1; DECL_SOURCE_LOCATION (decl) = input_location; cfun->function_end_locus = input_location; switch (which) { case 'I': DECL_STATIC_CONSTRUCTOR (decl) = 1; decl_init_priority_insert (decl, priority); break; case 'D': DECL_STATIC_DESTRUCTOR (decl) = 1; decl_fini_priority_insert (decl, priority); break; default: gcc_unreachable (); } gimplify_function_tree (decl); cgraph_node::add_new_function (decl, false); set_cfun (NULL); current_function_decl = NULL; } /* Generate and emit a static constructor or destructor. WHICH must be one of 'I' (for a constructor) or 'D' (for a destructor). BODY is a STATEMENT_LIST containing GENERIC statements. PRIORITY is the initialization priority for this constructor or destructor. */ void cgraph_build_static_cdtor (char which, tree body, int priority) { cgraph_build_static_cdtor_1 (which, body, priority, false); } /* A vector of FUNCTION_DECLs declared as static constructors. */ static vec static_ctors; /* A vector of FUNCTION_DECLs declared as static destructors. */ static vec static_dtors; /* When target does not have ctors and dtors, we call all constructor and destructor by special initialization/destruction function recognized by collect2. When we are going to build this function, collect all constructors and destructors and turn them into normal functions. */ static void record_cdtor_fn (struct cgraph_node *node) { if (DECL_STATIC_CONSTRUCTOR (node->decl)) static_ctors.safe_push (node->decl); if (DECL_STATIC_DESTRUCTOR (node->decl)) static_dtors.safe_push (node->decl); node = cgraph_node::get (node->decl); DECL_DISREGARD_INLINE_LIMITS (node->decl) = 1; } /* Define global constructors/destructor functions for the CDTORS, of which they are LEN. The CDTORS are sorted by initialization priority. If CTOR_P is true, these are constructors; otherwise, they are destructors. */ static void build_cdtor (bool ctor_p, vec cdtors) { size_t i,j; size_t len = cdtors.length (); i = 0; while (i < len) { tree body; tree fn; priority_type priority; priority = 0; body = NULL_TREE; j = i; do { priority_type p; fn = cdtors[j]; p = ctor_p ? DECL_INIT_PRIORITY (fn) : DECL_FINI_PRIORITY (fn); if (j == i) priority = p; else if (p != priority) break; j++; } while (j < len); /* When there is only one cdtor and target supports them, do nothing. */ if (j == i + 1 && targetm.have_ctors_dtors) { i++; continue; } /* Find the next batch of constructors/destructors with the same initialization priority. */ for (;i < j; i++) { tree call; fn = cdtors[i]; call = build_call_expr (fn, 0); if (ctor_p) DECL_STATIC_CONSTRUCTOR (fn) = 0; else DECL_STATIC_DESTRUCTOR (fn) = 0; /* We do not want to optimize away pure/const calls here. When optimizing, these should be already removed, when not optimizing, we want user to be able to breakpoint in them. */ TREE_SIDE_EFFECTS (call) = 1; append_to_statement_list (call, &body); } gcc_assert (body != NULL_TREE); /* Generate a function to call all the function of like priority. */ cgraph_build_static_cdtor_1 (ctor_p ? 'I' : 'D', body, priority, true); } } /* Comparison function for qsort. P1 and P2 are actually of type "tree *" and point to static constructors. DECL_INIT_PRIORITY is used to determine the sort order. */ static int compare_ctor (const void *p1, const void *p2) { tree f1; tree f2; int priority1; int priority2; f1 = *(const tree *)p1; f2 = *(const tree *)p2; priority1 = DECL_INIT_PRIORITY (f1); priority2 = DECL_INIT_PRIORITY (f2); if (priority1 < priority2) return -1; else if (priority1 > priority2) return 1; else /* Ensure a stable sort. Constructors are executed in backwarding order to make LTO initialize braries first. */ return DECL_UID (f2) - DECL_UID (f1); } /* Comparison function for qsort. P1 and P2 are actually of type "tree *" and point to static destructors. DECL_FINI_PRIORITY is used to determine the sort order. */ static int compare_dtor (const void *p1, const void *p2) { tree f1; tree f2; int priority1; int priority2; f1 = *(const tree *)p1; f2 = *(const tree *)p2; priority1 = DECL_FINI_PRIORITY (f1); priority2 = DECL_FINI_PRIORITY (f2); if (priority1 < priority2) return -1; else if (priority1 > priority2) return 1; else /* Ensure a stable sort. */ return DECL_UID (f1) - DECL_UID (f2); } /* Generate functions to call static constructors and destructors for targets that do not support .ctors/.dtors sections. These functions have magic names which are detected by collect2. */ static void build_cdtor_fns (void) { if (!static_ctors.is_empty ()) { gcc_assert (!targetm.have_ctors_dtors || in_lto_p); static_ctors.qsort (compare_ctor); build_cdtor (/*ctor_p=*/true, static_ctors); } if (!static_dtors.is_empty ()) { gcc_assert (!targetm.have_ctors_dtors || in_lto_p); static_dtors.qsort (compare_dtor); build_cdtor (/*ctor_p=*/false, static_dtors); } } /* Look for constructors and destructors and produce function calling them. This is needed for targets not supporting ctors or dtors, but we perform the transformation also at linktime to merge possibly numerous constructors/destructors into single function to improve code locality and reduce size. */ static unsigned int ipa_cdtor_merge (void) { struct cgraph_node *node; FOR_EACH_DEFINED_FUNCTION (node) if (DECL_STATIC_CONSTRUCTOR (node->decl) || DECL_STATIC_DESTRUCTOR (node->decl)) record_cdtor_fn (node); build_cdtor_fns (); static_ctors.release (); static_dtors.release (); return 0; } namespace { const pass_data pass_data_ipa_cdtor_merge = { IPA_PASS, /* type */ "cdtor", /* name */ OPTGROUP_NONE, /* optinfo_flags */ TV_CGRAPHOPT, /* tv_id */ 0, /* properties_required */ 0, /* properties_provided */ 0, /* properties_destroyed */ 0, /* todo_flags_start */ 0, /* todo_flags_finish */ }; class pass_ipa_cdtor_merge : public ipa_opt_pass_d { public: pass_ipa_cdtor_merge (gcc::context *ctxt) : ipa_opt_pass_d (pass_data_ipa_cdtor_merge, ctxt, NULL, /* generate_summary */ NULL, /* write_summary */ NULL, /* read_summary */ NULL, /* write_optimization_summary */ NULL, /* read_optimization_summary */ NULL, /* stmt_fixup */ 0, /* function_transform_todo_flags_start */ NULL, /* function_transform */ NULL) /* variable_transform */ {} /* opt_pass methods: */ virtual bool gate (function *); virtual unsigned int execute (function *) { return ipa_cdtor_merge (); } }; // class pass_ipa_cdtor_merge bool pass_ipa_cdtor_merge::gate (function *) { /* Perform the pass when we have no ctors/dtors support or at LTO time to merge multiple constructors into single function. */ return !targetm.have_ctors_dtors || (optimize && in_lto_p); } } // anon namespace ipa_opt_pass_d * make_pass_ipa_cdtor_merge (gcc::context *ctxt) { return new pass_ipa_cdtor_merge (ctxt); } /* Invalid pointer representing BOTTOM for single user dataflow. */ #define BOTTOM ((cgraph_node *)(size_t) 2) /* Meet operation for single user dataflow. Here we want to associate variables with sigle function that may access it. FUNCTION is current single user of a variable, VAR is variable that uses it. Latttice is stored in SINGLE_USER_MAP. We represent: - TOP by no entry in SIGNLE_USER_MAP - BOTTOM by BOTTOM in AUX pointer (to save lookups) - known single user by cgraph pointer in SINGLE_USER_MAP. */ cgraph_node * meet (cgraph_node *function, varpool_node *var, hash_map &single_user_map) { struct cgraph_node *user, **f; if (var->aux == BOTTOM) return BOTTOM; f = single_user_map.get (var); if (!f) return function; user = *f; if (!function) return user; else if (function != user) return BOTTOM; else return function; } /* Propagation step of single-use dataflow. Check all uses of VNODE and see if they are used by single function FUNCTION. SINGLE_USER_MAP represents the dataflow lattice. */ cgraph_node * propagate_single_user (varpool_node *vnode, cgraph_node *function, hash_map &single_user_map) { int i; struct ipa_ref *ref; gcc_assert (!vnode->externally_visible); /* If node is an alias, first meet with its target. */ if (vnode->alias) function = meet (function, vnode->get_alias_target (), single_user_map); /* Check all users and see if they correspond to a single function. */ for (i = 0; vnode->iterate_referring (i, ref) && function != BOTTOM; i++) { struct cgraph_node *cnode = dyn_cast (ref->referring); if (cnode) { if (cnode->global.inlined_to) cnode = cnode->global.inlined_to; if (!function) function = cnode; else if (function != cnode) function = BOTTOM; } else function = meet (function, dyn_cast (ref->referring), single_user_map); } return function; } /* Pass setting used_by_single_function flag. This flag is set on variable when there is only one function that may possibly referr to it. */ static unsigned int ipa_single_use (void) { varpool_node *first = (varpool_node *) (void *) 1; varpool_node *var; hash_map single_user_map; FOR_EACH_DEFINED_VARIABLE (var) if (!var->all_refs_explicit_p ()) var->aux = BOTTOM; else { /* Enqueue symbol for dataflow. */ var->aux = first; first = var; } /* The actual dataflow. */ while (first != (void *) 1) { cgraph_node *user, *orig_user, **f; var = first; first = (varpool_node *)first->aux; f = single_user_map.get (var); if (f) orig_user = *f; else orig_user = NULL; user = propagate_single_user (var, orig_user, single_user_map); gcc_checking_assert (var->aux != BOTTOM); /* If user differs, enqueue all references. */ if (user != orig_user) { unsigned int i; ipa_ref *ref; single_user_map.put (var, user); /* Enqueue all aliases for re-processing. */ for (i = 0; var->iterate_referring (i, ref); i++) if (ref->use == IPA_REF_ALIAS && !ref->referring->aux) { ref->referring->aux = first; first = dyn_cast (ref->referring); } /* Enqueue all users for re-processing. */ for (i = 0; var->iterate_reference (i, ref); i++) if (!ref->referred->aux && ref->referred->definition && is_a (ref->referred)) { ref->referred->aux = first; first = dyn_cast (ref->referred); } /* If user is BOTTOM, just punt on this var. */ if (user == BOTTOM) var->aux = BOTTOM; else var->aux = NULL; } else var->aux = NULL; } FOR_EACH_DEFINED_VARIABLE (var) { if (var->aux != BOTTOM) { #ifdef ENABLE_CHECKING if (!single_user_map.get (var)) gcc_assert (single_user_map.get (var)); #endif if (dump_file) { fprintf (dump_file, "Variable %s/%i is used by single function\n", var->name (), var->order); } var->used_by_single_function = true; } var->aux = NULL; } return 0; } namespace { const pass_data pass_data_ipa_single_use = { IPA_PASS, /* type */ "single-use", /* name */ OPTGROUP_NONE, /* optinfo_flags */ TV_CGRAPHOPT, /* tv_id */ 0, /* properties_required */ 0, /* properties_provided */ 0, /* properties_destroyed */ 0, /* todo_flags_start */ 0, /* todo_flags_finish */ }; class pass_ipa_single_use : public ipa_opt_pass_d { public: pass_ipa_single_use (gcc::context *ctxt) : ipa_opt_pass_d (pass_data_ipa_single_use, ctxt, NULL, /* generate_summary */ NULL, /* write_summary */ NULL, /* read_summary */ NULL, /* write_optimization_summary */ NULL, /* read_optimization_summary */ NULL, /* stmt_fixup */ 0, /* function_transform_todo_flags_start */ NULL, /* function_transform */ NULL) /* variable_transform */ {} /* opt_pass methods: */ virtual bool gate (function *); virtual unsigned int execute (function *) { return ipa_single_use (); } }; // class pass_ipa_single_use bool pass_ipa_single_use::gate (function *) { return optimize; } } // anon namespace ipa_opt_pass_d * make_pass_ipa_single_use (gcc::context *ctxt) { return new pass_ipa_single_use (ctxt); }