Mercurial > hg > CbC > CbC_gcc
view gcc/lto/lto.c @ 63:b7f97abdc517 gcc-4.6-20100522
update gcc from gcc-4.5.0 to gcc-4.6
| author | ryoma <e075725@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 24 May 2010 12:47:05 +0900 |
| parents | 77e2b8dfacca |
| children | f6334be47118 |
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/* Top-level LTO routines. Copyright 2009, 2010 Free Software Foundation, Inc. Contributed by CodeSourcery, 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 <http://www.gnu.org/licenses/>. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "opts.h" #include "toplev.h" #include "tree.h" #include "diagnostic.h" #include "tm.h" #include "libiberty.h" #include "cgraph.h" #include "ggc.h" #include "tree-ssa-operands.h" #include "tree-pass.h" #include "langhooks.h" #include "vec.h" #include "bitmap.h" #include "pointer-set.h" #include "ipa-prop.h" #include "common.h" #include "timevar.h" #include "gimple.h" #include "lto.h" #include "lto-tree.h" #include "lto-streamer.h" /* This needs to be included after config.h. Otherwise, _GNU_SOURCE will not be defined in time to set __USE_GNU in the system headers, and strsignal will not be declared. */ #if HAVE_MMAP_FILE #include <sys/mman.h> #endif /* Handle opening elf files on hosts, such as Windows, that may use text file handling that will break binary access. */ #ifndef O_BINARY # define O_BINARY 0 #endif DEF_VEC_P(bitmap); DEF_VEC_ALLOC_P(bitmap,heap); /* Read the constructors and inits. */ static void lto_materialize_constructors_and_inits (struct lto_file_decl_data * file_data) { size_t len; const char *data = lto_get_section_data (file_data, LTO_section_static_initializer, NULL, &len); lto_input_constructors_and_inits (file_data, data); lto_free_section_data (file_data, LTO_section_static_initializer, NULL, data, len); } /* Read the function body for the function associated with NODE if possible. */ static void lto_materialize_function (struct cgraph_node *node) { tree decl; struct lto_file_decl_data *file_data; const char *data, *name; size_t len; /* Ignore clone nodes. Read the body only from the original one. We may find clone nodes during LTRANS after WPA has made inlining decisions. */ if (node->clone_of) return; decl = node->decl; file_data = node->local.lto_file_data; name = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl)); /* We may have renamed the declaration, e.g., a static function. */ name = lto_get_decl_name_mapping (file_data, name); data = lto_get_section_data (file_data, LTO_section_function_body, name, &len); if (data) { gcc_assert (!DECL_IS_BUILTIN (decl)); /* This function has a definition. */ TREE_STATIC (decl) = 1; gcc_assert (DECL_STRUCT_FUNCTION (decl) == NULL); /* Load the function body only if not operating in WPA mode. In WPA mode, the body of the function is not needed. */ if (!flag_wpa) { allocate_struct_function (decl, false); announce_function (node->decl); lto_input_function_body (file_data, decl, data); lto_stats.num_function_bodies++; } lto_free_section_data (file_data, LTO_section_function_body, name, data, len); if (!flag_wpa) ggc_collect (); } else DECL_EXTERNAL (decl) = 1; /* Let the middle end know about the function. */ rest_of_decl_compilation (decl, 1, 0); } /* Decode the content of memory pointed to by DATA in the the in decl state object STATE. DATA_IN points to a data_in structure for decoding. Return the address after the decoded object in the input. */ static const uint32_t * lto_read_in_decl_state (struct data_in *data_in, const uint32_t *data, struct lto_in_decl_state *state) { uint32_t ix; tree decl; uint32_t i, j; ix = *data++; decl = lto_streamer_cache_get (data_in->reader_cache, (int) ix); if (TREE_CODE (decl) != FUNCTION_DECL) { gcc_assert (decl == void_type_node); decl = NULL_TREE; } state->fn_decl = decl; for (i = 0; i < LTO_N_DECL_STREAMS; i++) { uint32_t size = *data++; tree *decls = GGC_NEWVEC (tree, size); for (j = 0; j < size; j++) { decls[j] = lto_streamer_cache_get (data_in->reader_cache, data[j]); /* Register every type in the global type table. If the type existed already, use the existing type. */ if (TYPE_P (decls[j])) decls[j] = gimple_register_type (decls[j]); } state->streams[i].size = size; state->streams[i].trees = decls; data += size; } return data; } /* Read all the symbols from buffer DATA, using descriptors in DECL_DATA. RESOLUTIONS is the set of symbols picked by the linker (read from the resolution file when the linker plugin is being used). */ static void lto_read_decls (struct lto_file_decl_data *decl_data, const void *data, VEC(ld_plugin_symbol_resolution_t,heap) *resolutions) { const struct lto_decl_header *header = (const struct lto_decl_header *) data; const int32_t decl_offset = sizeof (struct lto_decl_header); const int32_t main_offset = decl_offset + header->decl_state_size; const int32_t string_offset = main_offset + header->main_size; struct lto_input_block ib_main; struct data_in *data_in; unsigned int i; const uint32_t *data_ptr, *data_end; uint32_t num_decl_states; LTO_INIT_INPUT_BLOCK (ib_main, (const char *) data + main_offset, 0, header->main_size); data_in = lto_data_in_create (decl_data, (const char *) data + string_offset, header->string_size, resolutions); /* Read the global declarations and types. */ while (ib_main.p < ib_main.len) { tree t = lto_input_tree (&ib_main, data_in); gcc_assert (t && ib_main.p <= ib_main.len); } /* Read in lto_in_decl_state objects. */ data_ptr = (const uint32_t *) ((const char*) data + decl_offset); data_end = (const uint32_t *) ((const char*) data_ptr + header->decl_state_size); num_decl_states = *data_ptr++; gcc_assert (num_decl_states > 0); decl_data->global_decl_state = lto_new_in_decl_state (); data_ptr = lto_read_in_decl_state (data_in, data_ptr, decl_data->global_decl_state); /* Read in per-function decl states and enter them in hash table. */ decl_data->function_decl_states = htab_create_ggc (37, lto_hash_in_decl_state, lto_eq_in_decl_state, NULL); for (i = 1; i < num_decl_states; i++) { struct lto_in_decl_state *state = lto_new_in_decl_state (); void **slot; data_ptr = lto_read_in_decl_state (data_in, data_ptr, state); slot = htab_find_slot (decl_data->function_decl_states, state, INSERT); gcc_assert (*slot == NULL); *slot = state; } if (data_ptr != data_end) internal_error ("bytecode stream: garbage at the end of symbols section"); /* Set the current decl state to be the global state. */ decl_data->current_decl_state = decl_data->global_decl_state; lto_data_in_delete (data_in); } /* strtoll is not portable. */ int64_t lto_parse_hex (const char *p) { uint64_t ret = 0; for (; *p != '\0'; ++p) { char c = *p; unsigned char part; ret <<= 4; if (c >= '0' && c <= '9') part = c - '0'; else if (c >= 'a' && c <= 'f') part = c - 'a' + 10; else if (c >= 'A' && c <= 'F') part = c - 'A' + 10; else internal_error ("could not parse hex number"); ret |= part; } return ret; } /* Read resolution for file named FILE_NAME. The resolution is read from RESOLUTION. An array with the symbol resolution is returned. The array size is written to SIZE. */ static VEC(ld_plugin_symbol_resolution_t,heap) * lto_resolution_read (FILE *resolution, lto_file *file) { /* We require that objects in the resolution file are in the same order as the lto1 command line. */ unsigned int name_len; char *obj_name; unsigned int num_symbols; unsigned int i; VEC(ld_plugin_symbol_resolution_t,heap) *ret = NULL; unsigned max_index = 0; if (!resolution) return NULL; name_len = strlen (file->filename); obj_name = XNEWVEC (char, name_len + 1); fscanf (resolution, " "); /* Read white space. */ fread (obj_name, sizeof (char), name_len, resolution); obj_name[name_len] = '\0'; if (strcmp (obj_name, file->filename) != 0) internal_error ("unexpected file name %s in linker resolution file. " "Expected %s", obj_name, file->filename); if (file->offset != 0) { int t; char offset_p[17]; int64_t offset; t = fscanf (resolution, "@0x%16s", offset_p); if (t != 1) internal_error ("could not parse file offset"); offset = lto_parse_hex (offset_p); if (offset != file->offset) internal_error ("unexpected offset"); } free (obj_name); fscanf (resolution, "%u", &num_symbols); for (i = 0; i < num_symbols; i++) { int t; unsigned index; char r_str[27]; enum ld_plugin_symbol_resolution r; unsigned int j; unsigned int lto_resolution_str_len = sizeof (lto_resolution_str) / sizeof (char *); t = fscanf (resolution, "%u %26s %*[^\n]\n", &index, r_str); if (t != 2) internal_error ("Invalid line in the resolution file."); if (index > max_index) max_index = index; for (j = 0; j < lto_resolution_str_len; j++) { if (strcmp (lto_resolution_str[j], r_str) == 0) { r = (enum ld_plugin_symbol_resolution) j; break; } } if (j == lto_resolution_str_len) internal_error ("Invalid resolution in the resolution file."); VEC_safe_grow_cleared (ld_plugin_symbol_resolution_t, heap, ret, max_index + 1); VEC_replace (ld_plugin_symbol_resolution_t, ret, index, r); } return ret; } /* Generate a TREE representation for all types and external decls entities in FILE. Read all of the globals out of the file. Then read the cgraph and process the .o index into the cgraph nodes so that it can open the .o file to load the functions and ipa information. */ static struct lto_file_decl_data * lto_file_read (lto_file *file, FILE *resolution_file) { struct lto_file_decl_data *file_data; const char *data; size_t len; VEC(ld_plugin_symbol_resolution_t,heap) *resolutions; resolutions = lto_resolution_read (resolution_file, file); file_data = GGC_NEW (struct lto_file_decl_data); file_data->file_name = file->filename; file_data->section_hash_table = lto_obj_build_section_table (file); file_data->renaming_hash_table = lto_create_renaming_table (); data = lto_get_section_data (file_data, LTO_section_decls, NULL, &len); lto_read_decls (file_data, data, resolutions); lto_free_section_data (file_data, LTO_section_decls, NULL, data, len); return file_data; } #if HAVE_MMAP_FILE && HAVE_SYSCONF && defined _SC_PAGE_SIZE #define LTO_MMAP_IO 1 #endif #if LTO_MMAP_IO /* Page size of machine is used for mmap and munmap calls. */ static size_t page_mask; #endif /* Get the section data of length LEN from FILENAME starting at OFFSET. The data segment must be freed by the caller when the caller is finished. Returns NULL if all was not well. */ static char * lto_read_section_data (struct lto_file_decl_data *file_data, intptr_t offset, size_t len) { char *result; static int fd = -1; static char *fd_name; #if LTO_MMAP_IO intptr_t computed_len; intptr_t computed_offset; intptr_t diff; #endif /* Keep a single-entry file-descriptor cache. The last file we touched will get closed at exit. ??? Eventually we want to add a more sophisticated larger cache or rather fix function body streaming to not stream them in practically random order. */ if (fd != -1 && strcmp (fd_name, file_data->file_name) != 0) { free (fd_name); close (fd); fd = -1; } if (fd == -1) { fd_name = xstrdup (file_data->file_name); fd = open (file_data->file_name, O_RDONLY|O_BINARY); if (fd == -1) return NULL; } #if LTO_MMAP_IO if (!page_mask) { size_t page_size = sysconf (_SC_PAGE_SIZE); page_mask = ~(page_size - 1); } computed_offset = offset & page_mask; diff = offset - computed_offset; computed_len = len + diff; result = (char *) mmap (NULL, computed_len, PROT_READ, MAP_PRIVATE, fd, computed_offset); if (result == MAP_FAILED) return NULL; return result + diff; #else result = (char *) xmalloc (len); if (lseek (fd, offset, SEEK_SET) != offset || read (fd, result, len) != (ssize_t) len) { free (result); return NULL; } return result; #endif } /* Get the section data from FILE_DATA of SECTION_TYPE with NAME. NAME will be NULL unless the section type is for a function body. */ static const char * get_section_data (struct lto_file_decl_data *file_data, enum lto_section_type section_type, const char *name, size_t *len) { htab_t section_hash_table = file_data->section_hash_table; struct lto_section_slot *f_slot; struct lto_section_slot s_slot; const char *section_name = lto_get_section_name (section_type, name); char *data = NULL; *len = 0; s_slot.name = section_name; f_slot = (struct lto_section_slot *) htab_find (section_hash_table, &s_slot); if (f_slot) { data = lto_read_section_data (file_data, f_slot->start, f_slot->len); *len = f_slot->len; } free (CONST_CAST (char *, section_name)); return data; } /* Free the section data from FILE_DATA of SECTION_TYPE with NAME that starts at OFFSET and has LEN bytes. */ static void free_section_data (struct lto_file_decl_data *file_data ATTRIBUTE_UNUSED, enum lto_section_type section_type ATTRIBUTE_UNUSED, const char *name ATTRIBUTE_UNUSED, const char *offset, size_t len ATTRIBUTE_UNUSED) { #if LTO_MMAP_IO intptr_t computed_len; intptr_t computed_offset; intptr_t diff; #endif #if LTO_MMAP_IO computed_offset = ((intptr_t) offset) & page_mask; diff = (intptr_t) offset - computed_offset; computed_len = len + diff; munmap ((caddr_t) computed_offset, computed_len); #else free (CONST_CAST(char *, offset)); #endif } /* Vector of all cgraph node sets. */ static GTY (()) VEC(cgraph_node_set, gc) *lto_cgraph_node_sets; static GTY (()) VEC(varpool_node_set, gc) *lto_varpool_node_sets; /* Group cgrah nodes by input files. This is used mainly for testing right now. */ static void lto_1_to_1_map (void) { struct cgraph_node *node; struct varpool_node *vnode; struct lto_file_decl_data *file_data; struct pointer_map_t *pmap; struct pointer_map_t *vpmap; cgraph_node_set set; varpool_node_set vset; void **slot; timevar_push (TV_WHOPR_WPA); lto_cgraph_node_sets = VEC_alloc (cgraph_node_set, gc, 1); lto_varpool_node_sets = VEC_alloc (varpool_node_set, gc, 1); pmap = pointer_map_create (); vpmap = pointer_map_create (); for (node = cgraph_nodes; node; node = node->next) { /* We will get proper partition based on function they are inlined to. */ if (node->global.inlined_to) continue; /* Nodes without a body do not need partitioning. */ if (!node->analyzed) continue; file_data = node->local.lto_file_data; gcc_assert (!node->same_body_alias && file_data); slot = pointer_map_contains (pmap, file_data); if (slot) set = (cgraph_node_set) *slot; else { set = cgraph_node_set_new (); slot = pointer_map_insert (pmap, file_data); *slot = set; VEC_safe_push (cgraph_node_set, gc, lto_cgraph_node_sets, set); vset = varpool_node_set_new (); slot = pointer_map_insert (vpmap, file_data); *slot = vset; VEC_safe_push (varpool_node_set, gc, lto_varpool_node_sets, vset); } cgraph_node_set_add (set, node); } for (vnode = varpool_nodes; vnode; vnode = vnode->next) { if (vnode->alias || !vnode->needed) continue; slot = pointer_map_contains (vpmap, file_data); if (slot) vset = (varpool_node_set) *slot; else { set = cgraph_node_set_new (); slot = pointer_map_insert (pmap, file_data); *slot = set; VEC_safe_push (cgraph_node_set, gc, lto_cgraph_node_sets, set); vset = varpool_node_set_new (); slot = pointer_map_insert (vpmap, file_data); *slot = vset; VEC_safe_push (varpool_node_set, gc, lto_varpool_node_sets, vset); } varpool_node_set_add (vset, vnode); } /* If the cgraph is empty, create one cgraph node set so that there is still an output file for any variables that need to be exported in a DSO. */ if (!lto_cgraph_node_sets) { set = cgraph_node_set_new (); VEC_safe_push (cgraph_node_set, gc, lto_cgraph_node_sets, set); vset = varpool_node_set_new (); VEC_safe_push (varpool_node_set, gc, lto_varpool_node_sets, vset); } pointer_map_destroy (pmap); pointer_map_destroy (vpmap); timevar_pop (TV_WHOPR_WPA); lto_stats.num_cgraph_partitions += VEC_length (cgraph_node_set, lto_cgraph_node_sets); } /* Add inlined clone NODE and its master clone to SET, if NODE itself has inlined callees, recursively add the callees. */ static void lto_add_inline_clones (cgraph_node_set set, struct cgraph_node *node, bitmap original_decls) { struct cgraph_node *callee; struct cgraph_edge *edge; cgraph_node_set_add (set, node); /* Check to see if NODE has any inlined callee. */ for (edge = node->callees; edge != NULL; edge = edge->next_callee) { callee = edge->callee; if (callee->global.inlined_to != NULL) lto_add_inline_clones (set, callee, original_decls); } } /* Compute the transitive closure of inlining of SET based on the information in the callgraph. Returns a bitmap of decls that have been inlined into SET indexed by UID. */ static void lto_add_all_inlinees (cgraph_node_set set) { cgraph_node_set_iterator csi; struct cgraph_node *node; bitmap original_nodes = lto_bitmap_alloc (); bitmap original_decls = lto_bitmap_alloc (); bool changed; /* We are going to iterate SET while adding to it, mark all original nodes so that we only add node inlined to original nodes. */ for (csi = csi_start (set); !csi_end_p (csi); csi_next (&csi)) { bitmap_set_bit (original_nodes, csi_node (csi)->uid); bitmap_set_bit (original_decls, DECL_UID (csi_node (csi)->decl)); } /* Some of the original nodes might not be needed anymore. Remove them. */ do { changed = false; for (csi = csi_start (set); !csi_end_p (csi); csi_next (&csi)) { struct cgraph_node *inlined_to; node = csi_node (csi); /* NODE was not inlined. We still need it. */ if (!node->global.inlined_to) continue; inlined_to = node->global.inlined_to; /* NODE should have only one caller. */ gcc_assert (!node->callers->next_caller); if (!bitmap_bit_p (original_nodes, inlined_to->uid)) { bitmap_clear_bit (original_nodes, node->uid); cgraph_node_set_remove (set, node); changed = true; } } } while (changed); /* Transitively add to SET all the inline clones for every node that has been inlined. */ for (csi = csi_start (set); !csi_end_p (csi); csi_next (&csi)) { node = csi_node (csi); if (bitmap_bit_p (original_nodes, node->uid)) lto_add_inline_clones (set, node, original_decls); } lto_bitmap_free (original_nodes); lto_bitmap_free (original_decls); } /* Promote variable VNODE to be static. */ static bool promote_var (struct varpool_node *vnode) { if (TREE_PUBLIC (vnode->decl) || DECL_EXTERNAL (vnode->decl)) return false; gcc_assert (flag_wpa); TREE_PUBLIC (vnode->decl) = 1; DECL_VISIBILITY (vnode->decl) = VISIBILITY_HIDDEN; return true; } /* Promote function NODE to be static. */ static bool promote_fn (struct cgraph_node *node) { gcc_assert (flag_wpa); if (TREE_PUBLIC (node->decl) || DECL_EXTERNAL (node->decl)) return false; TREE_PUBLIC (node->decl) = 1; DECL_VISIBILITY (node->decl) = VISIBILITY_HIDDEN; if (node->same_body) { struct cgraph_node *alias; for (alias = node->same_body; alias; alias = alias->next) { TREE_PUBLIC (alias->decl) = 1; DECL_VISIBILITY (alias->decl) = VISIBILITY_HIDDEN; } } return true; } /* Find out all static decls that need to be promoted to global because of cross file sharing. This function must be run in the WPA mode after all inlinees are added. */ static void lto_promote_cross_file_statics (void) { struct varpool_node *vnode; unsigned i, n_sets; cgraph_node_set set; varpool_node_set vset; cgraph_node_set_iterator csi; varpool_node_set_iterator vsi; VEC(varpool_node_ptr, heap) *promoted_initializers = NULL; struct pointer_set_t *inserted = pointer_set_create (); gcc_assert (flag_wpa); n_sets = VEC_length (cgraph_node_set, lto_cgraph_node_sets); for (i = 0; i < n_sets; i++) { set = VEC_index (cgraph_node_set, lto_cgraph_node_sets, i); vset = VEC_index (varpool_node_set, lto_varpool_node_sets, i); /* If node has either address taken (and we have no clue from where) or it is called from other partition, it needs to be globalized. */ for (csi = csi_start (set); !csi_end_p (csi); csi_next (&csi)) { struct cgraph_node *node = csi_node (csi); if (node->local.externally_visible) continue; if (node->global.inlined_to) continue; if (!DECL_EXTERNAL (node->decl) && (referenced_from_other_partition_p (&node->ref_list, set, vset) || reachable_from_other_partition_p (node, set))) promote_fn (node); } for (vsi = vsi_start (vset); !vsi_end_p (vsi); vsi_next (&vsi)) { vnode = vsi_node (vsi); /* Constant pool references use internal labels and thus can not be made global. It is sensible to keep those ltrans local to allow better optimization. */ if (!DECL_IN_CONSTANT_POOL (vnode->decl) && !vnode->externally_visible && vnode->analyzed && referenced_from_other_partition_p (&vnode->ref_list, set, vset)) promote_var (vnode); } /* We export initializers of read-only var into each partition referencing it. Folding might take declarations from the initializers and use it; so everything referenced from the initializers needs can be accessed from this partition after folding. This means that we need to promote all variables and functions referenced from all initializers from readonly vars referenced from this partition that are not in this partition. This needs to be done recursively. */ for (vnode = varpool_nodes; vnode; vnode = vnode->next) if ((TREE_READONLY (vnode->decl) || DECL_IN_CONSTANT_POOL (vnode->decl)) && DECL_INITIAL (vnode->decl) && !varpool_node_in_set_p (vnode, vset) && referenced_from_this_partition_p (&vnode->ref_list, set, vset) && !pointer_set_insert (inserted, vnode)) VEC_safe_push (varpool_node_ptr, heap, promoted_initializers, vnode); while (!VEC_empty (varpool_node_ptr, promoted_initializers)) { int i; struct ipa_ref *ref; vnode = VEC_pop (varpool_node_ptr, promoted_initializers); for (i = 0; ipa_ref_list_reference_iterate (&vnode->ref_list, i, ref); i++) { if (ref->refered_type == IPA_REF_CGRAPH) { struct cgraph_node *n = ipa_ref_node (ref); gcc_assert (!n->global.inlined_to); if (!n->local.externally_visible && !cgraph_node_in_set_p (n, set)) promote_fn (n); } else { struct varpool_node *v = ipa_ref_varpool_node (ref); if (varpool_node_in_set_p (v, vset)) continue; /* Constant pool references use internal labels and thus can not be made global. It is sensible to keep those ltrans local to allow better optimization. */ if (DECL_IN_CONSTANT_POOL (v->decl)) { if (!pointer_set_insert (inserted, vnode)) VEC_safe_push (varpool_node_ptr, heap, promoted_initializers, v); } else if (!DECL_IN_CONSTANT_POOL (v->decl) && !v->externally_visible && v->analyzed) { if (promote_var (v) && DECL_INITIAL (v->decl) && TREE_READONLY (v->decl) && !pointer_set_insert (inserted, vnode)) VEC_safe_push (varpool_node_ptr, heap, promoted_initializers, v); } } } } } pointer_set_destroy (inserted); } /* Given a file name FNAME, return a string with FNAME prefixed with '*'. */ static char * prefix_name_with_star (const char *fname) { char *star_fname; size_t len; len = strlen (fname) + 1 + 1; star_fname = XNEWVEC (char, len); snprintf (star_fname, len, "*%s", fname); return star_fname; } /* Return a copy of FNAME without the .o extension. */ static char * strip_extension (const char *fname) { char *s = XNEWVEC (char, strlen (fname) - 2 + 1); gcc_assert (strstr (fname, ".o")); snprintf (s, strlen (fname) - 2 + 1, "%s", fname); return s; } /* Return a file name associated with cgraph node set SET. This may be a new temporary file name if SET needs to be processed by LTRANS, or the original file name if all the nodes in SET belong to the same input file. */ static char * get_filename_for_set (cgraph_node_set set) { char *fname = NULL; static const size_t max_fname_len = 100; /* Create a new temporary file to store SET. To facilitate debugging, use file names from SET as part of the new temporary file name. */ cgraph_node_set_iterator si; struct pointer_set_t *pset = pointer_set_create (); for (si = csi_start (set); !csi_end_p (si); csi_next (&si)) { struct cgraph_node *n = csi_node (si); const char *node_fname; char *f; /* Don't use the same file name more than once. */ if (pointer_set_insert (pset, n->local.lto_file_data)) continue; /* The first file name found in SET determines the output directory. For the remaining files, we use their base names. */ node_fname = n->local.lto_file_data->file_name; if (fname == NULL) { fname = strip_extension (node_fname); continue; } f = strip_extension (lbasename (node_fname)); /* If the new name causes an excessively long file name, make the last component "___" to indicate overflow. */ if (strlen (fname) + strlen (f) > max_fname_len - 3) { fname = reconcat (fname, fname, "___", NULL); break; } else { fname = reconcat (fname, fname, "_", f, NULL); free (f); } } pointer_set_destroy (pset); if (!fname) { /* Since SET does not need to be processed by LTRANS, use the original file name and mark it with a '*' prefix so that lto_execute_ltrans knows not to process it. */ cgraph_node_set_iterator si = csi_start (set); struct cgraph_node *first = csi_node (si); fname = prefix_name_with_star (first->local.lto_file_data->file_name); } else { /* Add the extension .wpa.o to indicate that this file has been produced by WPA. */ fname = reconcat (fname, fname, ".wpa.o", NULL); gcc_assert (fname); } return fname; } static lto_file *current_lto_file; /* Write all output files in WPA mode. Returns a NULL-terminated array of output file names. */ static char ** lto_wpa_write_files (void) { char **output_files; unsigned i, n_sets, last_out_file_ix, num_out_files; lto_file *file; cgraph_node_set set; varpool_node_set vset; timevar_push (TV_WHOPR_WPA); /* Include all inlined functions and determine what sets need to be compiled by LTRANS. After this loop, only those sets that contain callgraph nodes from more than one file will need to be compiled by LTRANS. */ for (i = 0; VEC_iterate (cgraph_node_set, lto_cgraph_node_sets, i, set); i++) { lto_add_all_inlinees (set); lto_stats.num_output_cgraph_nodes += VEC_length (cgraph_node_ptr, set->nodes); } /* After adding all inlinees, find out statics that need to be promoted to globals because of cross-file inlining. */ lto_promote_cross_file_statics (); timevar_pop (TV_WHOPR_WPA); timevar_push (TV_WHOPR_WPA_IO); /* The number of output files depends on the number of input files and how many callgraph node sets we create. Reserve enough space for the maximum of these two. */ num_out_files = MAX (VEC_length (cgraph_node_set, lto_cgraph_node_sets), num_in_fnames); output_files = XNEWVEC (char *, num_out_files + 1); n_sets = VEC_length (cgraph_node_set, lto_cgraph_node_sets); for (i = 0; i < n_sets; i++) { char *temp_filename; set = VEC_index (cgraph_node_set, lto_cgraph_node_sets, i); vset = VEC_index (varpool_node_set, lto_varpool_node_sets, i); temp_filename = get_filename_for_set (set); output_files[i] = temp_filename; if (cgraph_node_set_nonempty_p (set) || varpool_node_set_nonempty_p (vset)) { /* Write all the nodes in SET to TEMP_FILENAME. */ file = lto_obj_file_open (temp_filename, true); if (!file) fatal_error ("lto_obj_file_open() failed"); if (!quiet_flag) fprintf (stderr, " %s", temp_filename); lto_set_current_out_file (file); ipa_write_optimization_summaries (set, vset); lto_set_current_out_file (NULL); lto_obj_file_close (file); } } last_out_file_ix = n_sets; lto_stats.num_output_files += n_sets; output_files[last_out_file_ix] = NULL; timevar_pop (TV_WHOPR_WPA_IO); return output_files; } /* Perform local transformations (LTRANS) on the files in the NULL-terminated FILES array. These should have been written previously by lto_wpa_write_files (). Transformations are performed via executing COLLECT_GCC for reach file. */ static void lto_write_ltrans_list (char *const *files) { FILE *ltrans_output_list_stream = NULL; unsigned i; /* Open the LTRANS output list. */ if (!ltrans_output_list) error ("no LTRANS output filename provided"); ltrans_output_list_stream = fopen (ltrans_output_list, "w"); if (ltrans_output_list_stream == NULL) error ("opening LTRANS output list %s: %m", ltrans_output_list); for (i = 0; files[i]; ++i) { size_t len; len = strlen (files[i]); if (fwrite (files[i], 1, len, ltrans_output_list_stream) < len || fwrite ("\n", 1, 1, ltrans_output_list_stream) < 1) error ("writing to LTRANS output list %s: %m", ltrans_output_list); } /* Close the LTRANS output list. */ if (fclose (ltrans_output_list_stream)) error ("closing LTRANS output list %s: %m", ltrans_output_list); } typedef struct { struct pointer_set_t *seen; } lto_fixup_data_t; #define LTO_FIXUP_SUBTREE(t) \ do \ walk_tree (&(t), lto_fixup_tree, data, NULL); \ while (0) #define LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE(t) \ do \ { \ if (t) \ (t) = gimple_register_type (t); \ walk_tree (&(t), lto_fixup_tree, data, NULL); \ } \ while (0) static tree lto_fixup_tree (tree *, int *, void *); /* Return true if T does not need to be fixed up recursively. */ static inline bool no_fixup_p (tree t) { return (t == NULL || CONSTANT_CLASS_P (t) || TREE_CODE (t) == IDENTIFIER_NODE); } /* Fix up fields of a tree_common T. DATA points to fix-up states. */ static void lto_fixup_common (tree t, void *data) { /* The following re-creates the TYPE_REFERENCE_TO and TYPE_POINTER_TO lists. We do not stream TYPE_REFERENCE_TO, TYPE_POINTER_TO or TYPE_NEXT_PTR_TO and TYPE_NEXT_REF_TO. First remove us from any pointer list we are on. */ if (TREE_CODE (t) == POINTER_TYPE) { if (TYPE_POINTER_TO (TREE_TYPE (t)) == t) TYPE_POINTER_TO (TREE_TYPE (t)) = TYPE_NEXT_PTR_TO (t); else { tree tem = TYPE_POINTER_TO (TREE_TYPE (t)); while (tem && TYPE_NEXT_PTR_TO (tem) != t) tem = TYPE_NEXT_PTR_TO (tem); if (tem) TYPE_NEXT_PTR_TO (tem) = TYPE_NEXT_PTR_TO (t); } TYPE_NEXT_PTR_TO (t) = NULL_TREE; } else if (TREE_CODE (t) == REFERENCE_TYPE) { if (TYPE_REFERENCE_TO (TREE_TYPE (t)) == t) TYPE_REFERENCE_TO (TREE_TYPE (t)) = TYPE_NEXT_REF_TO (t); else { tree tem = TYPE_REFERENCE_TO (TREE_TYPE (t)); while (tem && TYPE_NEXT_REF_TO (tem) != t) tem = TYPE_NEXT_REF_TO (tem); if (tem) TYPE_NEXT_REF_TO (tem) = TYPE_NEXT_REF_TO (t); } TYPE_NEXT_REF_TO (t) = NULL_TREE; } /* Fixup our type. */ LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE (TREE_TYPE (t)); /* Second put us on the list of pointers of the new pointed-to type if we are a main variant. This is done in lto_fixup_type after fixing up our main variant. */ /* This is not very efficient because we cannot do tail-recursion with a long chain of trees. */ LTO_FIXUP_SUBTREE (TREE_CHAIN (t)); } /* Fix up fields of a decl_minimal T. DATA points to fix-up states. */ static void lto_fixup_decl_minimal (tree t, void *data) { lto_fixup_common (t, data); LTO_FIXUP_SUBTREE (DECL_NAME (t)); LTO_FIXUP_SUBTREE (DECL_CONTEXT (t)); } /* Fix up fields of a decl_common T. DATA points to fix-up states. */ static void lto_fixup_decl_common (tree t, void *data) { lto_fixup_decl_minimal (t, data); LTO_FIXUP_SUBTREE (DECL_SIZE (t)); LTO_FIXUP_SUBTREE (DECL_SIZE_UNIT (t)); LTO_FIXUP_SUBTREE (DECL_INITIAL (t)); LTO_FIXUP_SUBTREE (DECL_ATTRIBUTES (t)); LTO_FIXUP_SUBTREE (DECL_ABSTRACT_ORIGIN (t)); } /* Fix up fields of a decl_with_vis T. DATA points to fix-up states. */ static void lto_fixup_decl_with_vis (tree t, void *data) { lto_fixup_decl_common (t, data); /* Accessor macro has side-effects, use field-name here. */ LTO_FIXUP_SUBTREE (t->decl_with_vis.assembler_name); gcc_assert (no_fixup_p (DECL_SECTION_NAME (t))); } /* Fix up fields of a decl_non_common T. DATA points to fix-up states. */ static void lto_fixup_decl_non_common (tree t, void *data) { lto_fixup_decl_with_vis (t, data); LTO_FIXUP_SUBTREE (DECL_ARGUMENT_FLD (t)); LTO_FIXUP_SUBTREE (DECL_RESULT_FLD (t)); LTO_FIXUP_SUBTREE (DECL_VINDEX (t)); /* SAVED_TREE should not cleared by now. Also no accessor for base type. */ gcc_assert (no_fixup_p (t->decl_non_common.saved_tree)); } /* Fix up fields of a decl_non_common T. DATA points to fix-up states. */ static void lto_fixup_function (tree t, void *data) { lto_fixup_decl_non_common (t, data); LTO_FIXUP_SUBTREE (DECL_FUNCTION_PERSONALITY (t)); } /* Fix up fields of a field_decl T. DATA points to fix-up states. */ static void lto_fixup_field_decl (tree t, void *data) { lto_fixup_decl_common (t, data); LTO_FIXUP_SUBTREE (DECL_FIELD_OFFSET (t)); LTO_FIXUP_SUBTREE (DECL_BIT_FIELD_TYPE (t)); LTO_FIXUP_SUBTREE (DECL_QUALIFIER (t)); gcc_assert (no_fixup_p (DECL_FIELD_BIT_OFFSET (t))); LTO_FIXUP_SUBTREE (DECL_FCONTEXT (t)); } /* Fix up fields of a type T. DATA points to fix-up states. */ static void lto_fixup_type (tree t, void *data) { tree tem, mv; lto_fixup_common (t, data); LTO_FIXUP_SUBTREE (TYPE_CACHED_VALUES (t)); LTO_FIXUP_SUBTREE (TYPE_SIZE (t)); LTO_FIXUP_SUBTREE (TYPE_SIZE_UNIT (t)); LTO_FIXUP_SUBTREE (TYPE_ATTRIBUTES (t)); LTO_FIXUP_SUBTREE (TYPE_NAME (t)); /* Accessors are for derived node types only. */ if (!POINTER_TYPE_P (t)) LTO_FIXUP_SUBTREE (t->type.minval); LTO_FIXUP_SUBTREE (t->type.maxval); /* Accessor is for derived node types only. */ LTO_FIXUP_SUBTREE (t->type.binfo); if (TYPE_CONTEXT (t)) { if (TYPE_P (TYPE_CONTEXT (t))) LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE (TYPE_CONTEXT (t)); else LTO_FIXUP_SUBTREE (TYPE_CONTEXT (t)); } LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE (TYPE_CANONICAL (t)); /* The following re-creates proper variant lists while fixing up the variant leaders. We do not stream TYPE_NEXT_VARIANT so the variant list state before fixup is broken. */ /* Remove us from our main variant list if we are not the variant leader. */ if (TYPE_MAIN_VARIANT (t) != t) { tem = TYPE_MAIN_VARIANT (t); while (tem && TYPE_NEXT_VARIANT (tem) != t) tem = TYPE_NEXT_VARIANT (tem); if (tem) TYPE_NEXT_VARIANT (tem) = TYPE_NEXT_VARIANT (t); TYPE_NEXT_VARIANT (t) = NULL_TREE; } /* Query our new main variant. */ mv = gimple_register_type (TYPE_MAIN_VARIANT (t)); /* If we were the variant leader and we get replaced ourselves drop all variants from our list. */ if (TYPE_MAIN_VARIANT (t) == t && mv != t) { tem = t; while (tem) { tree tem2 = TYPE_NEXT_VARIANT (tem); TYPE_NEXT_VARIANT (tem) = NULL_TREE; tem = tem2; } } /* If we are not our own variant leader link us into our new leaders variant list. */ if (mv != t) { TYPE_NEXT_VARIANT (t) = TYPE_NEXT_VARIANT (mv); TYPE_NEXT_VARIANT (mv) = t; } /* Finally adjust our main variant and fix it up. */ TYPE_MAIN_VARIANT (t) = mv; LTO_FIXUP_SUBTREE (TYPE_MAIN_VARIANT (t)); /* As the second step of reconstructing the pointer chains put us on the list of pointers of the new pointed-to type if we are a main variant. See lto_fixup_common for the first step. */ if (TREE_CODE (t) == POINTER_TYPE && TYPE_MAIN_VARIANT (t) == t) { TYPE_NEXT_PTR_TO (t) = TYPE_POINTER_TO (TREE_TYPE (t)); TYPE_POINTER_TO (TREE_TYPE (t)) = t; } else if (TREE_CODE (t) == REFERENCE_TYPE && TYPE_MAIN_VARIANT (t) == t) { TYPE_NEXT_REF_TO (t) = TYPE_REFERENCE_TO (TREE_TYPE (t)); TYPE_REFERENCE_TO (TREE_TYPE (t)) = t; } } /* Fix up fields of a BINFO T. DATA points to fix-up states. */ static void lto_fixup_binfo (tree t, void *data) { unsigned HOST_WIDE_INT i, n; tree base, saved_base; lto_fixup_common (t, data); gcc_assert (no_fixup_p (BINFO_OFFSET (t))); LTO_FIXUP_SUBTREE (BINFO_VTABLE (t)); LTO_FIXUP_SUBTREE (BINFO_VIRTUALS (t)); LTO_FIXUP_SUBTREE (BINFO_VPTR_FIELD (t)); n = VEC_length (tree, BINFO_BASE_ACCESSES (t)); for (i = 0; i < n; i++) { saved_base = base = BINFO_BASE_ACCESS (t, i); LTO_FIXUP_SUBTREE (base); if (base != saved_base) VEC_replace (tree, BINFO_BASE_ACCESSES (t), i, base); } LTO_FIXUP_SUBTREE (BINFO_INHERITANCE_CHAIN (t)); LTO_FIXUP_SUBTREE (BINFO_SUBVTT_INDEX (t)); LTO_FIXUP_SUBTREE (BINFO_VPTR_INDEX (t)); n = BINFO_N_BASE_BINFOS (t); for (i = 0; i < n; i++) { saved_base = base = BINFO_BASE_BINFO (t, i); LTO_FIXUP_SUBTREE (base); if (base != saved_base) VEC_replace (tree, BINFO_BASE_BINFOS (t), i, base); } } /* Fix up fields of a CONSTRUCTOR T. DATA points to fix-up states. */ static void lto_fixup_constructor (tree t, void *data) { unsigned HOST_WIDE_INT idx; constructor_elt *ce; LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE (TREE_TYPE (t)); for (idx = 0; VEC_iterate(constructor_elt, CONSTRUCTOR_ELTS (t), idx, ce); idx++) { LTO_FIXUP_SUBTREE (ce->index); LTO_FIXUP_SUBTREE (ce->value); } } /* A walk_tree callback used by lto_fixup_state. TP is the pointer to the current tree. WALK_SUBTREES indicates if the subtrees will be walked. DATA is a pointer set to record visited nodes. */ static tree lto_fixup_tree (tree *tp, int *walk_subtrees, void *data) { tree t; lto_fixup_data_t *fixup_data = (lto_fixup_data_t *) data; tree prevailing; t = *tp; *walk_subtrees = 0; if (!t || pointer_set_contains (fixup_data->seen, t)) return NULL; if (TREE_CODE (t) == VAR_DECL || TREE_CODE (t) == FUNCTION_DECL) { prevailing = lto_symtab_prevailing_decl (t); if (t != prevailing) { /* Also replace t with prevailing defintion. We don't want to insert the other defintion in the seen set as we want to replace all instances of it. */ *tp = prevailing; t = prevailing; } } else if (TYPE_P (t)) { /* Replace t with the prevailing type. We don't want to insert the other type in the seen set as we want to replace all instances of it. */ t = gimple_register_type (t); *tp = t; } if (pointer_set_insert (fixup_data->seen, t)) return NULL; /* walk_tree does not visit all reachable nodes that need to be fixed up. Hence we do special processing here for those kind of nodes. */ switch (TREE_CODE (t)) { case FIELD_DECL: lto_fixup_field_decl (t, data); break; case LABEL_DECL: case CONST_DECL: case PARM_DECL: case RESULT_DECL: case IMPORTED_DECL: lto_fixup_decl_common (t, data); break; case VAR_DECL: lto_fixup_decl_with_vis (t, data); break; case TYPE_DECL: lto_fixup_decl_non_common (t, data); break; case FUNCTION_DECL: lto_fixup_function (t, data); break; case TREE_BINFO: lto_fixup_binfo (t, data); break; default: if (TYPE_P (t)) lto_fixup_type (t, data); else if (TREE_CODE (t) == CONSTRUCTOR) lto_fixup_constructor (t, data); else if (CONSTANT_CLASS_P (t)) LTO_REGISTER_TYPE_AND_FIXUP_SUBTREE (TREE_TYPE (t)); else if (EXPR_P (t)) { /* walk_tree only handles TREE_OPERANDs. Do the rest here. */ lto_fixup_common (t, data); LTO_FIXUP_SUBTREE (t->exp.block); *walk_subtrees = 1; } else { /* Let walk_tree handle sub-trees. */ *walk_subtrees = 1; } } return NULL; } /* Helper function of lto_fixup_decls. Walks the var and fn streams in STATE, replaces var and function decls with the corresponding prevailing def and records the old decl in the free-list in DATA. We also record visted nodes in the seen-set in DATA to avoid multiple visit for nodes that need not to be replaced. */ static void lto_fixup_state (struct lto_in_decl_state *state, lto_fixup_data_t *data) { unsigned i, si; struct lto_tree_ref_table *table; /* Although we only want to replace FUNCTION_DECLs and VAR_DECLs, we still need to walk from all DECLs to find the reachable FUNCTION_DECLs and VAR_DECLs. */ for (si = 0; si < LTO_N_DECL_STREAMS; si++) { table = &state->streams[si]; for (i = 0; i < table->size; i++) walk_tree (table->trees + i, lto_fixup_tree, data, NULL); } } /* A callback of htab_traverse. Just extract a state from SLOT and the lto_fixup_data_t object from AUX and calls lto_fixup_state. */ static int lto_fixup_state_aux (void **slot, void *aux) { struct lto_in_decl_state *state = (struct lto_in_decl_state *) *slot; lto_fixup_state (state, (lto_fixup_data_t *) aux); return 1; } /* Fix the decls from all FILES. Replaces each decl with the corresponding prevailing one. */ static void lto_fixup_decls (struct lto_file_decl_data **files) { unsigned int i; tree decl; struct pointer_set_t *seen = pointer_set_create (); lto_fixup_data_t data; data.seen = seen; for (i = 0; files[i]; i++) { struct lto_file_decl_data *file = files[i]; struct lto_in_decl_state *state = file->global_decl_state; lto_fixup_state (state, &data); htab_traverse (file->function_decl_states, lto_fixup_state_aux, &data); } for (i = 0; VEC_iterate (tree, lto_global_var_decls, i, decl); i++) { tree saved_decl = decl; walk_tree (&decl, lto_fixup_tree, &data, NULL); if (decl != saved_decl) VEC_replace (tree, lto_global_var_decls, i, decl); } pointer_set_destroy (seen); } /* Read the options saved from each file in the command line. Called from lang_hooks.post_options which is called by process_options right before all the options are used to initialize the compiler. This assumes that decode_options has already run, so the num_in_fnames and in_fnames are properly set. Note that this assumes that all the files had been compiled with the same options, which is not a good assumption. In general, options ought to be read from all the files in the set and merged. However, it is still unclear what the merge rules should be. */ void lto_read_all_file_options (void) { size_t i; /* Clear any file options currently saved. */ lto_clear_file_options (); /* Set the hooks to read ELF sections. */ lto_set_in_hooks (NULL, get_section_data, free_section_data); for (i = 0; i < num_in_fnames; i++) { struct lto_file_decl_data *file_data; lto_file *file = lto_obj_file_open (in_fnames[i], false); if (!file) break; file_data = XCNEW (struct lto_file_decl_data); file_data->file_name = file->filename; file_data->section_hash_table = lto_obj_build_section_table (file); lto_read_file_options (file_data); lto_obj_file_close (file); htab_delete (file_data->section_hash_table); free (file_data); } /* Apply globally the options read from all the files. */ lto_reissue_options (); } static GTY((length ("lto_stats.num_input_files + 1"))) struct lto_file_decl_data **all_file_decl_data; /* Read all the symbols from the input files FNAMES. NFILES is the number of files requested in the command line. Instantiate a global call graph by aggregating all the sub-graphs found in each file. */ static void read_cgraph_and_symbols (unsigned nfiles, const char **fnames) { unsigned int i, last_file_ix; FILE *resolution; struct cgraph_node *node; lto_stats.num_input_files = nfiles; timevar_push (TV_IPA_LTO_DECL_IO); /* Set the hooks so that all of the ipa passes can read in their data. */ all_file_decl_data = GGC_CNEWVEC (struct lto_file_decl_data *, nfiles + 1); lto_set_in_hooks (all_file_decl_data, get_section_data, free_section_data); /* Read the resolution file. */ resolution = NULL; if (resolution_file_name) { int t; unsigned num_objects; resolution = fopen (resolution_file_name, "r"); if (resolution == NULL) fatal_error ("could not open symbol resolution file: %s", xstrerror (errno)); t = fscanf (resolution, "%u", &num_objects); gcc_assert (t == 1); /* True, since the plugin splits the archives. */ gcc_assert (num_objects == nfiles); } if (!quiet_flag) fprintf (stderr, "Reading object files:"); /* Read all of the object files specified on the command line. */ for (i = 0, last_file_ix = 0; i < nfiles; ++i) { struct lto_file_decl_data *file_data = NULL; if (!quiet_flag) { fprintf (stderr, " %s", fnames[i]); fflush (stderr); } current_lto_file = lto_obj_file_open (fnames[i], false); if (!current_lto_file) break; file_data = lto_file_read (current_lto_file, resolution); if (!file_data) break; all_file_decl_data[last_file_ix++] = file_data; lto_obj_file_close (current_lto_file); current_lto_file = NULL; /* ??? We'd want but can't ggc_collect () here as the type merging code in gimple.c uses hashtables that are not ggc aware. */ } if (resolution_file_name) fclose (resolution); all_file_decl_data[last_file_ix] = NULL; /* Set the hooks so that all of the ipa passes can read in their data. */ lto_set_in_hooks (all_file_decl_data, get_section_data, free_section_data); timevar_pop (TV_IPA_LTO_DECL_IO); if (!quiet_flag) fprintf (stderr, "\nReading the callgraph\n"); timevar_push (TV_IPA_LTO_CGRAPH_IO); /* Read the callgraph. */ input_cgraph (); timevar_pop (TV_IPA_LTO_CGRAPH_IO); if (!quiet_flag) fprintf (stderr, "Merging declarations\n"); timevar_push (TV_IPA_LTO_DECL_MERGE); /* Merge global decls. */ lto_symtab_merge_decls (); /* Fixup all decls and types and free the type hash tables. */ lto_fixup_decls (all_file_decl_data); free_gimple_type_tables (); ggc_collect (); timevar_pop (TV_IPA_LTO_DECL_MERGE); /* Each pass will set the appropriate timer. */ if (!quiet_flag) fprintf (stderr, "Reading summaries\n"); /* Read the IPA summary data. */ if (flag_ltrans) ipa_read_optimization_summaries (); else ipa_read_summaries (); /* Finally merge the cgraph according to the decl merging decisions. */ timevar_push (TV_IPA_LTO_CGRAPH_MERGE); lto_symtab_merge_cgraph_nodes (); ggc_collect (); if (flag_ltrans) for (node = cgraph_nodes; node; node = node->next) { /* FIXME: ipa_transforms_to_apply holds list of passes that have optimization summaries computed and needs to apply changes. At the moment WHOPR only supports inlining, so we can push it here by hand. In future we need to stream this field into ltrans compilation. */ if (node->analyzed) VEC_safe_push (ipa_opt_pass, heap, node->ipa_transforms_to_apply, (ipa_opt_pass)&pass_ipa_inline); } lto_symtab_free (); timevar_pop (TV_IPA_LTO_CGRAPH_MERGE); timevar_push (TV_IPA_LTO_DECL_INIT_IO); /* FIXME lto. This loop needs to be changed to use the pass manager to call the ipa passes directly. */ if (!errorcount) for (i = 0; i < last_file_ix; i++) { struct lto_file_decl_data *file_data = all_file_decl_data [i]; lto_materialize_constructors_and_inits (file_data); } /* Indicate that the cgraph is built and ready. */ cgraph_function_flags_ready = true; timevar_pop (TV_IPA_LTO_DECL_INIT_IO); ggc_free (all_file_decl_data); all_file_decl_data = NULL; } /* Materialize all the bodies for all the nodes in the callgraph. */ static void materialize_cgraph (void) { tree decl; struct cgraph_node *node; unsigned i; timevar_id_t lto_timer; if (!quiet_flag) fprintf (stderr, flag_wpa ? "Materializing decls:" : "Reading function bodies:"); /* Now that we have input the cgraph, we need to clear all of the aux nodes and read the functions if we are not running in WPA mode. */ timevar_push (TV_IPA_LTO_GIMPLE_IO); for (node = cgraph_nodes; node; node = node->next) { /* Some cgraph nodes get created on the fly, and they don't need to be materialized. For instance, nodes for nested functions where the parent function was not streamed out or builtin functions. Additionally, builtin functions should not be materialized and may, in fact, cause confusion because there may be a regular function in the file whose assembler name matches that of the function. See gcc.c-torture/execute/20030125-1.c and gcc.c-torture/execute/921215-1.c. */ if (node->local.lto_file_data && !DECL_IS_BUILTIN (node->decl)) { lto_materialize_function (node); lto_stats.num_input_cgraph_nodes++; } } timevar_pop (TV_IPA_LTO_GIMPLE_IO); /* Start the appropriate timer depending on the mode that we are operating in. */ lto_timer = (flag_wpa) ? TV_WHOPR_WPA : (flag_ltrans) ? TV_WHOPR_LTRANS : TV_LTO; timevar_push (lto_timer); current_function_decl = NULL; set_cfun (NULL); /* Inform the middle end about the global variables we have seen. */ for (i = 0; VEC_iterate (tree, lto_global_var_decls, i, decl); i++) rest_of_decl_compilation (decl, 1, 0); if (!quiet_flag) fprintf (stderr, "\n"); timevar_pop (lto_timer); } /* Perform whole program analysis (WPA) on the callgraph and write out the optimization plan. */ static void do_whole_program_analysis (void) { char **output_files; /* Note that since we are in WPA mode, materialize_cgraph will not actually read in all the function bodies. It only materializes the decls and cgraph nodes so that analysis can be performed. */ materialize_cgraph (); /* Reading in the cgraph uses different timers, start timing WPA now. */ timevar_push (TV_WHOPR_WPA); if (pre_ipa_mem_report) { fprintf (stderr, "Memory consumption before IPA\n"); dump_memory_report (false); } cgraph_function_flags_ready = true; bitmap_obstack_initialize (NULL); ipa_register_cgraph_hooks (); cgraph_state = CGRAPH_STATE_IPA_SSA; execute_ipa_pass_list (all_regular_ipa_passes); verify_cgraph (); bitmap_obstack_release (NULL); /* We are about to launch the final LTRANS phase, stop the WPA timer. */ timevar_pop (TV_WHOPR_WPA); lto_1_to_1_map (); if (!quiet_flag) { fprintf (stderr, "\nStreaming out"); fflush (stderr); } output_files = lto_wpa_write_files (); ggc_collect (); if (!quiet_flag) fprintf (stderr, "\n"); if (post_ipa_mem_report) { fprintf (stderr, "Memory consumption after IPA\n"); dump_memory_report (false); } /* Show the LTO report before launching LTRANS. */ if (flag_lto_report) print_lto_report (); lto_write_ltrans_list (output_files); XDELETEVEC (output_files); } /* Main entry point for the GIMPLE front end. This front end has three main personalities: - LTO (-flto). All the object files on the command line are loaded in memory and processed as a single translation unit. This is the traditional link-time optimization behavior. - WPA (-fwpa). Only the callgraph and summary information for files in the command file are loaded. A single callgraph (without function bodies) is instantiated for the whole set of files. IPA passes are only allowed to analyze the call graph and make transformation decisions. The callgraph is partitioned, each partition is written to a new object file together with the transformation decisions. - LTRANS (-fltrans). Similar to -flto but it prevents the IPA summary files from running again. Since WPA computed summary information and decided what transformations to apply, LTRANS simply applies them. */ void lto_main (int debug_p ATTRIBUTE_UNUSED) { lto_init_reader (); /* Read all the symbols and call graph from all the files in the command line. */ read_cgraph_and_symbols (num_in_fnames, in_fnames); if (!errorcount) { /* If WPA is enabled analyze the whole call graph and create an optimization plan. Otherwise, read in all the function bodies and continue with optimization. */ if (flag_wpa) do_whole_program_analysis (); else { materialize_cgraph (); /* Let the middle end know that we have read and merged all of the input files. */ cgraph_optimize (); /* FIXME lto, if the processes spawned by WPA fail, we miss the chance to print WPA's report, so WPA will call print_lto_report before launching LTRANS. If LTRANS was launched directly by the driver we would not need to do this. */ if (flag_lto_report) print_lto_report (); } } } #include "gt-lto-lto.h"