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android / toolchain / gcc / 3f73d6ef904 / . / gcc-4.6 / gcc / passes.c
blob: 41867336cee48aeb594f33bb78ea18ad24a7d54c [file] [log] [blame]
/* Top level of GCC compilers (cc1, cc1plus, etc.)
Copyright (C) 1987, 1988, 1989, 1992, 1993, 1994, 1995, 1996, 1997, 1998,
1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010
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
<http://www.gnu.org/licenses/>. */
/* This is the top level of cc1/c++.
It parses command args, opens files, invokes the various passes
in the proper order, and counts the time used by each.
Error messages and low-level interface to malloc also handled here. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "line-map.h"
#include "input.h"
#include "tree.h"
#include "rtl.h"
#include "tm_p.h"
#include "flags.h"
#include "insn-attr.h"
#include "insn-config.h"
#include "insn-flags.h"
#include "hard-reg-set.h"
#include "recog.h"
#include "output.h"
#include "except.h"
#include "function.h"
#include "toplev.h"
#include "expr.h"
#include "basic-block.h"
#include "intl.h"
#include "ggc.h"
#include "graph.h"
#include "regs.h"
#include "timevar.h"
#include "diagnostic-core.h"
#include "params.h"
#include "reload.h"
#include "dwarf2asm.h"
#include "integrate.h"
#include "debug.h"
#include "target.h"
#include "langhooks.h"
#include "cfglayout.h"
#include "cfgloop.h"
#include "hosthooks.h"
#include "cgraph.h"
#include "opts.h"
#include "coverage.h"
#include "value-prof.h"
#include "tree-inline.h"
#include "tree-flow.h"
#include "tree-pass.h"
#include "tree-dump.h"
#include "df.h"
#include "predict.h"
#include "lto-streamer.h"
#include "plugin.h"
#include "l-ipo.h"
#include "tree-pretty-print.h"
#if defined (DWARF2_UNWIND_INFO) || defined (DWARF2_DEBUGGING_INFO)
#include "dwarf2out.h"
#endif
#if defined (DBX_DEBUGGING_INFO) || defined (XCOFF_DEBUGGING_INFO)
#include "dbxout.h"
#endif
#ifdef SDB_DEBUGGING_INFO
#include "sdbout.h"
#endif
#ifdef XCOFF_DEBUGGING_INFO
#include "xcoffout.h" /* Needed for external data
declarations for e.g. AIX 4.x. */
#endif
/* This is used for debugging. It allows the current pass to printed
from anywhere in compilation.
The variable current_pass is also used for statistics and plugins. */
struct opt_pass *current_pass;
static void register_pass_name (struct opt_pass *, const char *);
/* Call from anywhere to find out what pass this is. Useful for
printing out debugging information deep inside an service
routine. */
void
print_current_pass (FILE *file)
{
if (current_pass)
fprintf (file, "current pass = %s (%d)\n",
current_pass->name, current_pass->static_pass_number);
else
fprintf (file, "no current pass.\n");
}
/* Call from the debugger to get the current pass name. */
DEBUG_FUNCTION void
debug_pass (void)
{
print_current_pass (stderr);
}
/* Global variables used to communicate with passes. */
int dump_flags;
bool in_gimple_form;
bool first_pass_instance;
/* This is called from various places for FUNCTION_DECL, VAR_DECL,
and TYPE_DECL nodes.
This does nothing for local (non-static) variables, unless the
variable is a register variable with DECL_ASSEMBLER_NAME set. In
that case, or if the variable is not an automatic, it sets up the
RTL and outputs any assembler code (label definition, storage
allocation and initialization).
DECL is the declaration. TOP_LEVEL is nonzero
if this declaration is not within a function. */
void
rest_of_decl_compilation (tree decl,
int top_level,
int at_end)
{
/* We deferred calling assemble_alias so that we could collect
other attributes such as visibility. Emit the alias now. */
if (!in_lto_p)
{
tree alias;
alias = lookup_attribute ("alias", DECL_ATTRIBUTES (decl));
if (alias)
{
alias = TREE_VALUE (TREE_VALUE (alias));
alias = get_identifier (TREE_STRING_POINTER (alias));
assemble_alias (decl, alias);
}
}
/* Can't defer this, because it needs to happen before any
later function definitions are processed. */
if (DECL_ASSEMBLER_NAME_SET_P (decl) && DECL_REGISTER (decl))
make_decl_rtl (decl);
/* Forward declarations for nested functions are not "external",
but we need to treat them as if they were. */
if (TREE_STATIC (decl) || DECL_EXTERNAL (decl)
|| TREE_CODE (decl) == FUNCTION_DECL)
{
timevar_push (TV_VARCONST);
/* Don't output anything when a tentative file-scope definition
is seen. But at end of compilation, do output code for them.
We do output all variables and rely on
callgraph code to defer them except for forward declarations
(see gcc.c-torture/compile/920624-1.c) */
if ((at_end
|| !DECL_DEFER_OUTPUT (decl)
|| DECL_INITIAL (decl))
&& !DECL_EXTERNAL (decl))
{
/* When reading LTO unit, we also read varpool, so do not
rebuild it. */
if (in_lto_p && !at_end)
;
else if (TREE_CODE (decl) != FUNCTION_DECL)
varpool_finalize_decl (decl);
}
#ifdef ASM_FINISH_DECLARE_OBJECT
if (decl == last_assemble_variable_decl)
{
ASM_FINISH_DECLARE_OBJECT (asm_out_file, decl,
top_level, at_end);
}
#endif
if (L_IPO_COMP_MODE)
{
/* Create the node early during parsing so
that module id can be captured. */
if (TREE_CODE (decl) == VAR_DECL)
varpool_node (decl);
}
timevar_pop (TV_VARCONST);
}
else if (TREE_CODE (decl) == TYPE_DECL
/* Like in rest_of_type_compilation, avoid confusing the debug
information machinery when there are errors. */
&& !seen_error ())
{
timevar_push (TV_SYMOUT);
debug_hooks->type_decl (decl, !top_level);
timevar_pop (TV_SYMOUT);
}
/* Let cgraph know about the existence of variables. */
if (in_lto_p && !at_end)
;
else if (TREE_CODE (decl) == VAR_DECL && !DECL_EXTERNAL (decl)
&& TREE_STATIC (decl))
varpool_node (decl);
}
/* Called after finishing a record, union or enumeral type. */
void
rest_of_type_compilation (tree type, int toplev)
{
/* Avoid confusing the debug information machinery when there are
errors. */
if (seen_error ())
return;
timevar_push (TV_SYMOUT);
debug_hooks->type_decl (TYPE_STUB_DECL (type), !toplev);
timevar_pop (TV_SYMOUT);
}
void
finish_optimization_passes (void)
{
int i;
struct dump_file_info *dfi;
char *name;
timevar_push (TV_DUMP);
if (profile_arc_flag || flag_test_coverage || flag_branch_probabilities)
{
dump_file = dump_begin (pass_profile.pass.static_pass_number, NULL);
end_branch_prob ();
if (dump_file)
dump_end (pass_profile.pass.static_pass_number, dump_file);
}
if (optimize > 0)
{
dump_file = dump_begin (pass_combine.pass.static_pass_number, NULL);
if (dump_file)
{
dump_combine_total_stats (dump_file);
dump_end (pass_combine.pass.static_pass_number, dump_file);
}
}
/* Do whatever is necessary to finish printing the graphs. */
if (graph_dump_format != no_graph)
for (i = TDI_end; (dfi = get_dump_file_info (i)) != NULL; ++i)
if (dump_initialized_p (i)
&& (dfi->flags & TDF_GRAPH) != 0
&& (name = get_dump_file_name (i)) != NULL)
{
finish_graph_dump_file (name);
free (name);
}
timevar_pop (TV_DUMP);
}
static bool
gate_rest_of_compilation (void)
{
/* Early return if there were errors. We can run afoul of our
consistency checks, and there's not really much point in fixing them. */
return !(rtl_dump_and_exit || flag_syntax_only || seen_error ());
}
struct gimple_opt_pass pass_rest_of_compilation =
{
{
GIMPLE_PASS,
"*rest_of_compilation", /* name */
gate_rest_of_compilation, /* gate */
NULL, /* execute */
NULL, /* sub */
NULL, /* next */
0, /* static_pass_number */
TV_REST_OF_COMPILATION, /* tv_id */
PROP_rtl, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
0, /* todo_flags_start */
TODO_ggc_collect /* todo_flags_finish */
}
};
static bool
gate_postreload (void)
{
return reload_completed;
}
struct rtl_opt_pass pass_postreload =
{
{
RTL_PASS,
"*all-postreload", /* name */
gate_postreload, /* gate */
NULL, /* execute */
NULL, /* sub */
NULL, /* next */
0, /* static_pass_number */
TV_POSTRELOAD, /* tv_id */
PROP_rtl, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
0, /* todo_flags_start */
TODO_ggc_collect | TODO_verify_rtl_sharing /* todo_flags_finish */
}
};
/* The root of the compilation pass tree, once constructed. */
struct opt_pass *all_passes, *all_small_ipa_passes, *all_lowering_passes,
*all_regular_ipa_passes, *all_lto_gen_passes;
/* This is used by plugins, and should also be used in register_pass. */
#define DEF_PASS_LIST(LIST) &LIST,
struct opt_pass **gcc_pass_lists[] = { GCC_PASS_LISTS NULL };
#undef DEF_PASS_LIST
/* A map from static pass id to optimization pass. */
struct opt_pass **passes_by_id;
int passes_by_id_size;
/* Set the static pass number of pass PASS to ID and record that
in the mapping from static pass number to pass. */
static void
set_pass_for_id (int id, struct opt_pass *pass)
{
pass->static_pass_number = id;
if (passes_by_id_size <= id)
{
passes_by_id = XRESIZEVEC (struct opt_pass *, passes_by_id, id + 1);
memset (passes_by_id + passes_by_id_size, 0,
(id + 1 - passes_by_id_size) * sizeof (void *));
passes_by_id_size = id + 1;
}
passes_by_id[id] = pass;
}
/* Return the pass with the static pass number ID. */
struct opt_pass *
get_pass_for_id (int id)
{
if (id >= passes_by_id_size)
return NULL;
return passes_by_id[id];
}
/* Iterate over the pass tree allocating dump file numbers. We want
to do this depth first, and independent of whether the pass is
enabled or not. */
void
register_one_dump_file (struct opt_pass *pass)
{
char *dot_name, *flag_name, *glob_name;
const char *name, *full_name, *prefix;
char num[10];
int flags, id;
/* See below in next_pass_1. */
num[0] = '\0';
if (pass->static_pass_number != -1)
sprintf (num, "%d", ((int) pass->static_pass_number < 0
? 1 : pass->static_pass_number));
/* The name is both used to identify the pass for the purposes of plugins,
and to specify dump file name and option.
The latter two might want something short which is not quite unique; for
that reason, we may have a disambiguating prefix, followed by a space
to mark the start of the following dump file name / option string. */
name = strchr (pass->name, ' ');
name = name ? name + 1 : pass->name;
dot_name = concat (".", name, num, NULL);
if (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS)
prefix = "ipa-", flags = TDF_IPA;
else if (pass->type == GIMPLE_PASS)
prefix = "tree-", flags = TDF_TREE;
else
prefix = "rtl-", flags = TDF_RTL;
flag_name = concat (prefix, name, num, NULL);
glob_name = concat (prefix, name, NULL);
id = dump_register (dot_name, flag_name, glob_name, flags);
set_pass_for_id (id, pass);
full_name = concat (prefix, pass->name, num, NULL);
register_pass_name (pass, full_name);
}
/* Recursive worker function for register_dump_files. */
static int
register_dump_files_1 (struct opt_pass *pass, int properties)
{
do
{
int new_properties = (properties | pass->properties_provided)
& ~pass->properties_destroyed;
if (pass->name && pass->name[0] != '*')
register_one_dump_file (pass);
if (pass->sub)
new_properties = register_dump_files_1 (pass->sub, new_properties);
/* If we have a gate, combine the properties that we could have with
and without the pass being examined. */
if (pass->gate)
properties &= new_properties;
else
properties = new_properties;
pass = pass->next;
}
while (pass);
return properties;
}
/* Register the dump files for the pipeline starting at PASS.
PROPERTIES reflects the properties that are guaranteed to be available at
the beginning of the pipeline. */
static void
register_dump_files (struct opt_pass *pass,int properties)
{
pass->properties_required |= properties;
register_dump_files_1 (pass, properties);
}
struct pass_registry
{
const char* unique_name;
struct opt_pass *pass;
};
/* Pass registry hash function. */
static hashval_t
passr_hash (const void *p)
{
const struct pass_registry *const s = (const struct pass_registry *const) p;
return htab_hash_string (s->unique_name);
}
/* Hash equal function */
static int
passr_eq (const void *p1, const void *p2)
{
const struct pass_registry *const s1 = (const struct pass_registry *const) p1;
const struct pass_registry *const s2 = (const struct pass_registry *const) p2;
return !strcmp (s1->unique_name, s2->unique_name);
}
static htab_t name_to_pass_map = NULL;
/* Register PASS with NAME. */
static void
register_pass_name (struct opt_pass *pass, const char *name)
{
struct pass_registry **slot;
struct pass_registry pr;
if (!name_to_pass_map)
name_to_pass_map = htab_create (256, passr_hash, passr_eq, NULL);
pr.unique_name = name;
slot = (struct pass_registry **) htab_find_slot (name_to_pass_map, &pr, INSERT);
if (!*slot)
{
struct pass_registry *new_pr;
new_pr = XCNEW (struct pass_registry);
new_pr->unique_name = xstrdup (name);
new_pr->pass = pass;
*slot = new_pr;
}
else
return; /* Ignore plugin passes. */
}
/* Map from pass id to canonicalized pass name. */
typedef const char *char_ptr;
DEF_VEC_P(char_ptr);
DEF_VEC_ALLOC_P(char_ptr, heap);
static VEC(char_ptr, heap) *pass_tab = NULL;
/* Callback function for traversing NAME_TO_PASS_MAP. */
static int
pass_traverse (void **slot, void *data ATTRIBUTE_UNUSED)
{
struct pass_registry **p = (struct pass_registry **)slot;
struct opt_pass *pass = (*p)->pass;
gcc_assert (pass->static_pass_number > 0);
gcc_assert (pass_tab);
VEC_replace (char_ptr, pass_tab, pass->static_pass_number,
(*p)->unique_name);
return 1;
}
/* The function traverses NAME_TO_PASS_MAP and creates a pass info
table for dumping purpose. */
static void
create_pass_tab (void)
{
if (!flag_dump_passes)
return;
VEC_safe_grow_cleared (char_ptr, heap,
pass_tab, passes_by_id_size + 1);
htab_traverse (name_to_pass_map, pass_traverse, NULL);
}
static bool override_gate_status (struct opt_pass *, tree, bool);
/* Dump the instantiated name for PASS. IS_ON indicates if PASS
is turned on or not. */
static void
dump_one_pass (struct opt_pass *pass, int pass_indent)
{
int indent = 3 * pass_indent;
const char *pn;
bool is_on, is_really_on;
is_on = (pass->gate == NULL) ? true : pass->gate();
is_really_on = override_gate_status (pass, current_function_decl, is_on);
if (pass->static_pass_number <= 0)
pn = pass->name;
else
pn = VEC_index (char_ptr, pass_tab, pass->static_pass_number);
fprintf (stderr, "%*s%-40s%*s:%s%s\n", indent, " ", pn,
(15 - indent < 0 ? 0 : 15 - indent), " ",
is_on ? " ON" : " OFF",
((!is_on) == (!is_really_on) ? ""
: (is_really_on ? " (FORCED_ON)" : " (FORCED_OFF)")));
}
/* Dump pass list PASS with indentation INDENT. */
static void
dump_pass_list (struct opt_pass *pass, int indent)
{
do
{
dump_one_pass (pass, indent);
if (pass->sub)
dump_pass_list (pass->sub, indent + 1);
pass = pass->next;
}
while (pass);
}
/* Dump all optimization passes. */
void
dump_passes (void)
{
struct cgraph_node *n, *node = NULL;
tree save_fndecl = current_function_decl;
create_pass_tab();
n = cgraph_nodes;
while (n)
{
if (DECL_STRUCT_FUNCTION (n->decl))
{
node = n;
break;
}
n = n->next;
}
if (!node)
return;
push_cfun (DECL_STRUCT_FUNCTION (node->decl));
current_function_decl = node->decl;
dump_pass_list (all_lowering_passes, 1);
dump_pass_list (all_small_ipa_passes, 1);
dump_pass_list (all_regular_ipa_passes, 1);
dump_pass_list (all_lto_gen_passes, 1);
dump_pass_list (all_passes, 1);
pop_cfun ();
current_function_decl = save_fndecl;
}
/* Returns the pass with NAME. */
static struct opt_pass *
get_pass_by_name (const char *name)
{
struct pass_registry **slot, pr;
pr.unique_name = name;
slot = (struct pass_registry **) htab_find_slot (name_to_pass_map,
&pr, NO_INSERT);
if (!slot || !*slot)
return NULL;
return (*slot)->pass;
}
/* Range [start, last]. */
struct uid_range
{
unsigned int start;
unsigned int last;
const char *assem_name;
struct uid_range *next;
};
typedef struct uid_range *uid_range_p;
DEF_VEC_P(uid_range_p);
DEF_VEC_ALLOC_P(uid_range_p, heap);
static VEC(uid_range_p, heap) *enabled_pass_uid_range_tab = NULL;
static VEC(uid_range_p, heap) *disabled_pass_uid_range_tab = NULL;
/* Parse option string for -fdisable- and -fenable-
The syntax of the options:
-fenable-<pass_name>
-fdisable-<pass_name>
-fenable-<pass_name>=s1:e1,s2:e2,...
-fdisable-<pass_name>=s1:e1,s2:e2,...
*/
static void
enable_disable_pass (const char *arg, bool is_enable)
{
struct opt_pass *pass;
char *range_str, *phase_name;
char *argstr = xstrdup (arg);
VEC(uid_range_p, heap) **tab = 0;
range_str = strchr (argstr,'=');
if (range_str)
{
*range_str = '\0';
range_str++;
}
phase_name = argstr;
if (!*phase_name)
{
if (is_enable)
error ("unrecognized option -fenable");
else
error ("unrecognized option -fdisable");
free (argstr);
return;
}
pass = get_pass_by_name (phase_name);
if (!pass || pass->static_pass_number == -1)
{
if (is_enable)
error ("unknown pass %s specified in -fenable", phase_name);
else
error ("unknown pass %s specified in -fdisble", phase_name);
free (argstr);
return;
}
if (is_enable)
tab = &enabled_pass_uid_range_tab;
else
tab = &disabled_pass_uid_range_tab;
if ((unsigned) pass->static_pass_number >= VEC_length (uid_range_p, *tab))
VEC_safe_grow_cleared (uid_range_p, heap,
*tab, pass->static_pass_number + 1);
if (!range_str)
{
uid_range_p slot;
uid_range_p new_range = XCNEW (struct uid_range);
new_range->start = 0;
new_range->last = (unsigned)-1;
slot = VEC_index (uid_range_p, *tab, pass->static_pass_number);
new_range->next = slot;
VEC_replace (uid_range_p, *tab, pass->static_pass_number,
new_range);
if (is_enable)
inform (UNKNOWN_LOCATION, "enable pass %s for functions in the range "
"of [%u, %u]", phase_name, new_range->start, new_range->last);
else
inform (UNKNOWN_LOCATION, "disable pass %s for functions in the range "
"of [%u, %u]", phase_name, new_range->start, new_range->last);
}
else
{
char *next_range = NULL;
char *one_range = range_str;
char *end_val = NULL;
do
{
uid_range_p slot;
uid_range_p new_range;
char *invalid = NULL;
long start;
char *func_name = NULL;
next_range = strchr (one_range, ',');
if (next_range)
{
*next_range = '\0';
next_range++;
}
end_val = strchr (one_range, ':');
if (end_val)
{
*end_val = '\0';
end_val++;
}
start = strtol (one_range, &invalid, 10);
if (*invalid || start < 0)
{
if (end_val || (one_range[0] >= '0'
&& one_range[0] <= '9'))
{
error ("Invalid range %s in option %s",
one_range,
is_enable ? "-fenable" : "-fdisable");
free (argstr);
return;
}
func_name = one_range;
}
if (!end_val)
{
new_range = XCNEW (struct uid_range);
if (!func_name)
{
new_range->start = (unsigned) start;
new_range->last = (unsigned) start;
}
else
{
new_range->start = (unsigned) -1;
new_range->last = (unsigned) -1;
new_range->assem_name = xstrdup (func_name);
}
}
else
{
long last = strtol (end_val, &invalid, 10);
if (*invalid || last < start)
{
error ("Invalid range %s in option %s",
end_val,
is_enable ? "-fenable" : "-fdisable");
free (argstr);
return;
}
new_range = XCNEW (struct uid_range);
new_range->start = (unsigned) start;
new_range->last = (unsigned) last;
}
slot = VEC_index (uid_range_p, *tab, pass->static_pass_number);
new_range->next = slot;
VEC_replace (uid_range_p, *tab, pass->static_pass_number,
new_range);
if (is_enable)
{
if (new_range->assem_name)
inform (UNKNOWN_LOCATION,
"enable pass %s for function %s",
phase_name, new_range->assem_name);
else
inform (UNKNOWN_LOCATION,
"enable pass %s for functions in the range of [%u, %u]",
phase_name, new_range->start, new_range->last);
}
else
{
if (new_range->assem_name)
inform (UNKNOWN_LOCATION,
"disable pass %s for function %s",
phase_name, new_range->assem_name);
else
inform (UNKNOWN_LOCATION,
"disable pass %s for functions in the range of [%u, %u]",
phase_name, new_range->start, new_range->last);
}
one_range = next_range;
} while (next_range);
}
free (argstr);
}
/* Enable pass specified by ARG. */
void
enable_pass (const char *arg)
{
enable_disable_pass (arg, true);
}
/* Disable pass specified by ARG. */
void
disable_pass (const char *arg)
{
enable_disable_pass (arg, false);
}
/* Returns true if PASS is explicitly enabled/disabled for FUNC. */
static bool
is_pass_explicitly_enabled_or_disabled (struct opt_pass *pass,
tree func,
VEC(uid_range_p, heap) *tab)
{
uid_range_p slot, range;
int cgraph_uid;
const char *aname = NULL;
if (!tab
|| (unsigned) pass->static_pass_number >= VEC_length (uid_range_p, tab)
|| pass->static_pass_number == -1)
return false;
slot = VEC_index (uid_range_p, tab, pass->static_pass_number);
if (!slot)
return false;
cgraph_uid = func ? cgraph_get_node (func)->uid : 0;
if (func && DECL_ASSEMBLER_NAME_SET_P (func))
aname = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (func));
range = slot;
while (range)
{
if ((unsigned) cgraph_uid >= range->start
&& (unsigned) cgraph_uid <= range->last)
return true;
if (range->assem_name && aname
&& !strcmp (range->assem_name, aname))
return true;
range = range->next;
}
return false;
}
/* Look at the static_pass_number and duplicate the pass
if it is already added to a list. */
static struct opt_pass *
make_pass_instance (struct opt_pass *pass, bool track_duplicates)
{
/* A nonzero static_pass_number indicates that the
pass is already in the list. */
if (pass->static_pass_number)
{
struct opt_pass *new_pass;
if (pass->type == GIMPLE_PASS
|| pass->type == RTL_PASS
|| pass->type == SIMPLE_IPA_PASS)
{
new_pass = XNEW (struct opt_pass);
memcpy (new_pass, pass, sizeof (struct opt_pass));
}
else if (pass->type == IPA_PASS)
{
new_pass = (struct opt_pass *)XNEW (struct ipa_opt_pass_d);
memcpy (new_pass, pass, sizeof (struct ipa_opt_pass_d));
}
else
gcc_unreachable ();
new_pass->next = NULL;
new_pass->todo_flags_start &= ~TODO_mark_first_instance;
/* Indicate to register_dump_files that this pass has duplicates,
and so it should rename the dump file. The first instance will
be -1, and be number of duplicates = -static_pass_number - 1.
Subsequent instances will be > 0 and just the duplicate number. */
if ((pass->name && pass->name[0] != '*') || track_duplicates)
{
pass->static_pass_number -= 1;
new_pass->static_pass_number = -pass->static_pass_number;
}
return new_pass;
}
else
{
pass->todo_flags_start |= TODO_mark_first_instance;
pass->static_pass_number = -1;
invoke_plugin_callbacks (PLUGIN_NEW_PASS, pass);
}
return pass;
}
/* Add a pass to the pass list. Duplicate the pass if it's already
in the list. */
static struct opt_pass **
next_pass_1 (struct opt_pass **list, struct opt_pass *pass)
{
/* Every pass should have a name so that plugins can refer to them. */
gcc_assert (pass->name != NULL);
*list = make_pass_instance (pass, false);
return &(*list)->next;
}
/* List node for an inserted pass instance. We need to keep track of all
the newly-added pass instances (with 'added_pass_nodes' defined below)
so that we can register their dump files after pass-positioning is finished.
Registering dumping files needs to be post-processed or the
static_pass_number of the opt_pass object would be modified and mess up
the dump file names of future pass instances to be added. */
struct pass_list_node
{
struct opt_pass *pass;
struct pass_list_node *next;
};
static struct pass_list_node *added_pass_nodes = NULL;
static struct pass_list_node *prev_added_pass_node;
/* Insert the pass at the proper position. Return true if the pass
is successfully added.
NEW_PASS_INFO - new pass to be inserted
PASS_LIST - root of the pass list to insert the new pass to */
static bool
position_pass (struct register_pass_info *new_pass_info,
struct opt_pass **pass_list)
{
struct opt_pass *pass = *pass_list, *prev_pass = NULL;
bool success = false;
for ( ; pass; prev_pass = pass, pass = pass->next)
{
/* Check if the current pass is of the same type as the new pass and
matches the name and the instance number of the reference pass. */
if (pass->type == new_pass_info->pass->type
&& pass->name
&& !strcmp (pass->name, new_pass_info->reference_pass_name)
&& ((new_pass_info->ref_pass_instance_number == 0)
|| (new_pass_info->ref_pass_instance_number ==
pass->static_pass_number)
|| (new_pass_info->ref_pass_instance_number == 1
&& pass->todo_flags_start & TODO_mark_first_instance)))
{
struct opt_pass *new_pass;
struct pass_list_node *new_pass_node;
new_pass = make_pass_instance (new_pass_info->pass, true);
/* Insert the new pass instance based on the positioning op. */
switch (new_pass_info->pos_op)
{
case PASS_POS_INSERT_AFTER:
new_pass->next = pass->next;
pass->next = new_pass;
/* Skip newly inserted pass to avoid repeated
insertions in the case where the new pass and the
existing one have the same name. */
pass = new_pass;
break;
case PASS_POS_INSERT_BEFORE:
new_pass->next = pass;
if (prev_pass)
prev_pass->next = new_pass;
else
*pass_list = new_pass;
break;
case PASS_POS_REPLACE:
new_pass->next = pass->next;
if (prev_pass)
prev_pass->next = new_pass;
else
*pass_list = new_pass;
new_pass->sub = pass->sub;
new_pass->tv_id = pass->tv_id;
pass = new_pass;
break;
default:
error ("invalid pass positioning operation");
return false;
}
/* Save the newly added pass (instance) in the added_pass_nodes
list so that we can register its dump file later. Note that
we cannot register the dump file now because doing so will modify
the static_pass_number of the opt_pass object and therefore
mess up the dump file name of future instances. */
new_pass_node = XCNEW (struct pass_list_node);
new_pass_node->pass = new_pass;
if (!added_pass_nodes)
added_pass_nodes = new_pass_node;
else
prev_added_pass_node->next = new_pass_node;
prev_added_pass_node = new_pass_node;
success = true;
}
if (pass->sub && position_pass (new_pass_info, &pass->sub))
success = true;
}
return success;
}
/* Hooks a new pass into the pass lists.
PASS_INFO - pass information that specifies the opt_pass object,
reference pass, instance number, and how to position
the pass */
void
register_pass (struct register_pass_info *pass_info)
{
bool all_instances, success;
/* The checks below could fail in buggy plugins. Existing GCC
passes should never fail these checks, so we mention plugin in
the messages. */
if (!pass_info->pass)
fatal_error ("plugin cannot register a missing pass");
if (!pass_info->pass->name)
fatal_error ("plugin cannot register an unnamed pass");
if (!pass_info->reference_pass_name)
fatal_error
("plugin cannot register pass %qs without reference pass name",
pass_info->pass->name);
/* Try to insert the new pass to the pass lists. We need to check
all five lists as the reference pass could be in one (or all) of
them. */
all_instances = pass_info->ref_pass_instance_number == 0;
success = position_pass (pass_info, &all_lowering_passes);
if (!success || all_instances)
success |= position_pass (pass_info, &all_small_ipa_passes);
if (!success || all_instances)
success |= position_pass (pass_info, &all_regular_ipa_passes);
if (!success || all_instances)
success |= position_pass (pass_info, &all_lto_gen_passes);
if (!success || all_instances)
success |= position_pass (pass_info, &all_passes);
if (!success)
fatal_error
("pass %qs not found but is referenced by new pass %qs",
pass_info->reference_pass_name, pass_info->pass->name);
/* OK, we have successfully inserted the new pass. We need to register
the dump files for the newly added pass and its duplicates (if any).
Because the registration of plugin/backend passes happens after the
command-line options are parsed, the options that specify single
pass dumping (e.g. -fdump-tree-PASSNAME) cannot be used for new
passes. Therefore we currently can only enable dumping of
new passes when the 'dump-all' flags (e.g. -fdump-tree-all)
are specified. While doing so, we also delete the pass_list_node
objects created during pass positioning. */
while (added_pass_nodes)
{
struct pass_list_node *next_node = added_pass_nodes->next;
enum tree_dump_index tdi;
register_one_dump_file (added_pass_nodes->pass);
if (added_pass_nodes->pass->type == SIMPLE_IPA_PASS
|| added_pass_nodes->pass->type == IPA_PASS)
tdi = TDI_ipa_all;
else if (added_pass_nodes->pass->type == GIMPLE_PASS)
tdi = TDI_tree_all;
else
tdi = TDI_rtl_all;
/* Check if dump-all flag is specified. */
if (get_dump_file_info (tdi)->state)
get_dump_file_info (added_pass_nodes->pass->static_pass_number)
->state = get_dump_file_info (tdi)->state;
XDELETE (added_pass_nodes);
added_pass_nodes = next_node;
}
}
/* Construct the pass tree. The sequencing of passes is driven by
the cgraph routines:
cgraph_finalize_compilation_unit ()
for each node N in the cgraph
cgraph_analyze_function (N)
cgraph_lower_function (N) -> all_lowering_passes
If we are optimizing, cgraph_optimize is then invoked:
cgraph_optimize ()
ipa_passes () -> all_small_ipa_passes
cgraph_expand_all_functions ()
for each node N in the cgraph
cgraph_expand_function (N)
tree_rest_of_compilation (DECL (N)) -> all_passes
*/
void
init_optimization_passes (void)
{
struct opt_pass **p;
#define NEXT_PASS(PASS) (p = next_pass_1 (p, &((PASS).pass)))
/* All passes needed to lower the function into shape optimizers can
operate on. These passes are always run first on the function, but
backend might produce already lowered functions that are not processed
by these passes. */
p = &all_lowering_passes;
NEXT_PASS (pass_warn_unused_result);
NEXT_PASS (pass_diagnose_omp_blocks);
NEXT_PASS (pass_mudflap_1);
NEXT_PASS (pass_lower_omp);
NEXT_PASS (pass_lower_cf);
NEXT_PASS (pass_refactor_eh);
NEXT_PASS (pass_lower_eh);
NEXT_PASS (pass_build_cfg);
NEXT_PASS (pass_warn_function_return);
NEXT_PASS (pass_build_cgraph_edges);
*p = NULL;
/* Interprocedural optimization passes. */
p = &all_small_ipa_passes;
NEXT_PASS (pass_ipa_free_lang_data);
NEXT_PASS (pass_ipa_function_and_variable_visibility);
NEXT_PASS (pass_early_local_passes);
{
struct opt_pass **p = &pass_early_local_passes.pass.sub;
NEXT_PASS (pass_fixup_cfg);
NEXT_PASS (pass_init_datastructures);
NEXT_PASS (pass_expand_omp);
NEXT_PASS (pass_referenced_vars);
NEXT_PASS (pass_build_ssa);
NEXT_PASS (pass_lower_vector);
NEXT_PASS (pass_early_warn_uninitialized);
NEXT_PASS (pass_rebuild_cgraph_edges);
NEXT_PASS (pass_threadsafe_analyze);
NEXT_PASS (pass_inline_parameters);
NEXT_PASS (pass_early_inline);
NEXT_PASS (pass_all_early_optimizations);
{
struct opt_pass **p = &pass_all_early_optimizations.pass.sub;
NEXT_PASS (pass_remove_cgraph_callee_edges);
NEXT_PASS (pass_rename_ssa_copies);
NEXT_PASS (pass_ccp);
NEXT_PASS (pass_forwprop);
/* pass_build_ealias is a dummy pass that ensures that we
execute TODO_rebuild_alias at this point. Re-building
alias information also rewrites no longer addressed
locals into SSA form if possible. */
NEXT_PASS (pass_build_ealias);
NEXT_PASS (pass_sra_early);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_merge_phi);
NEXT_PASS (pass_cd_dce);
NEXT_PASS (pass_early_ipa_sra);
NEXT_PASS (pass_tail_recursion);
NEXT_PASS (pass_convert_switch);
NEXT_PASS (pass_cleanup_eh);
NEXT_PASS (pass_profile);
NEXT_PASS (pass_local_pure_const);
/* Split functions creates parts that are not run through
early optimizations again. It is thus good idea to do this
late. */
NEXT_PASS (pass_split_functions);
}
NEXT_PASS (pass_release_ssa_names);
NEXT_PASS (pass_rebuild_cgraph_edges);
NEXT_PASS (pass_inline_parameters);
}
NEXT_PASS (pass_ipa_tree_profile);
{
struct opt_pass **p = &pass_ipa_tree_profile.pass.sub;
NEXT_PASS (pass_feedback_split_functions);
}
NEXT_PASS (pass_ipa_increase_alignment);
NEXT_PASS (pass_ipa_matrix_reorg);
NEXT_PASS (pass_ipa_multiversion_dispatch);
{
struct opt_pass **p = &pass_ipa_multiversion_dispatch.pass.sub;
NEXT_PASS (pass_tree_convert_builtin_dispatch);
/* Rebuilding cgraph edges is necessary as the above passes change
the call graph. Otherwise, future optimizations use the old
call graph and make wrong decisions sometimes.*/
NEXT_PASS (pass_rebuild_cgraph_edges);
}
NEXT_PASS (pass_ipa_lower_emutls);
*p = NULL;
p = &all_regular_ipa_passes;
NEXT_PASS (pass_ipa_whole_program_visibility);
NEXT_PASS (pass_ipa_profile);
NEXT_PASS (pass_ipa_cp);
NEXT_PASS (pass_ipa_cdtor_merge);
NEXT_PASS (pass_ipa_inline);
NEXT_PASS (pass_ipa_pure_const);
NEXT_PASS (pass_ipa_reference);
NEXT_PASS (pass_ipa_type_escape);
NEXT_PASS (pass_ipa_pta);
NEXT_PASS (pass_ipa_struct_reorg);
*p = NULL;
p = &all_lto_gen_passes;
NEXT_PASS (pass_ipa_lto_gimple_out);
NEXT_PASS (pass_ipa_lto_finish_out); /* This must be the last LTO pass. */
*p = NULL;
/* These passes are run after IPA passes on every function that is being
output to the assembler file. */
p = &all_passes;
NEXT_PASS (pass_auto_clone);
NEXT_PASS (pass_direct_call_profile);
NEXT_PASS (pass_lower_eh_dispatch);
NEXT_PASS (pass_all_optimizations);
{
struct opt_pass **p = &pass_all_optimizations.pass.sub;
NEXT_PASS (pass_remove_cgraph_callee_edges);
/* Initial scalar cleanups before alias computation.
They ensure memory accesses are not indirect wherever possible. */
NEXT_PASS (pass_strip_predict_hints);
NEXT_PASS (pass_rename_ssa_copies);
NEXT_PASS (pass_complete_unrolli);
NEXT_PASS (pass_ccp);
NEXT_PASS (pass_forwprop);
NEXT_PASS (pass_call_cdce);
/* pass_build_alias is a dummy pass that ensures that we
execute TODO_rebuild_alias at this point. Re-building
alias information also rewrites no longer addressed
locals into SSA form if possible. */
NEXT_PASS (pass_build_alias);
NEXT_PASS (pass_return_slot);
NEXT_PASS (pass_phiprop);
NEXT_PASS (pass_fre);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_merge_phi);
NEXT_PASS (pass_vrp);
NEXT_PASS (pass_dce);
NEXT_PASS (pass_cselim);
NEXT_PASS (pass_tree_ifcombine);
NEXT_PASS (pass_phiopt);
NEXT_PASS (pass_tail_recursion);
NEXT_PASS (pass_ch);
NEXT_PASS (pass_stdarg);
NEXT_PASS (pass_lower_complex);
NEXT_PASS (pass_sra);
NEXT_PASS (pass_rename_ssa_copies);
/* The dom pass will also resolve all __builtin_constant_p calls
that are still there to 0. This has to be done after some
propagations have already run, but before some more dead code
is removed, and this place fits nicely. Remember this when
trying to move or duplicate pass_dominator somewhere earlier. */
NEXT_PASS (pass_dominator);
/* The only const/copy propagation opportunities left after
DOM should be due to degenerate PHI nodes. So rather than
run the full propagators, run a specialized pass which
only examines PHIs to discover const/copy propagation
opportunities. */
NEXT_PASS (pass_phi_only_cprop);
NEXT_PASS (pass_dse);
NEXT_PASS (pass_reassoc);
NEXT_PASS (pass_dce);
NEXT_PASS (pass_forwprop);
NEXT_PASS (pass_phiopt);
NEXT_PASS (pass_object_sizes);
NEXT_PASS (pass_ccp);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_cse_sincos);
NEXT_PASS (pass_optimize_bswap);
NEXT_PASS (pass_split_crit_edges);
NEXT_PASS (pass_pre);
NEXT_PASS (pass_sink_code);
NEXT_PASS (pass_tree_loop);
{
struct opt_pass **p = &pass_tree_loop.pass.sub;
NEXT_PASS (pass_tree_loop_init);
NEXT_PASS (pass_lim);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_dce_loop);
NEXT_PASS (pass_tree_unswitch);
NEXT_PASS (pass_scev_cprop);
NEXT_PASS (pass_record_bounds);
NEXT_PASS (pass_check_data_deps);
NEXT_PASS (pass_loop_distribution);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_graphite);
{
struct opt_pass **p = &pass_graphite.pass.sub;
NEXT_PASS (pass_graphite_transforms);
NEXT_PASS (pass_lim);
NEXT_PASS (pass_copy_prop);
NEXT_PASS (pass_dce_loop);
}
NEXT_PASS (pass_iv_canon);
NEXT_PASS (pass_if_conversion);
NEXT_PASS (pass_vectorize);
{
struct opt_pass **p = &pass_vectorize.pass.sub;
NEXT_PASS (pass_lower_vector_ssa);
NEXT_PASS (pass_dce_loop);
}
NEXT_PASS (pass_predcom);
NEXT_PASS (pass_complete_unroll);
NEXT_PASS (pass_slp_vectorize);
NEXT_PASS (pass_parallelize_loops);
NEXT_PASS (pass_loop_prefetch);
NEXT_PASS (pass_iv_optimize);
NEXT_PASS (pass_tree_loop_done);
}
NEXT_PASS (pass_cse_reciprocals);
NEXT_PASS (pass_reassoc);
NEXT_PASS (pass_vrp);
NEXT_PASS (pass_dominator);
/* The only const/copy propagation opportunities left after
DOM should be due to degenerate PHI nodes. So rather than
run the full propagators, run a specialized pass which
only examines PHIs to discover const/copy propagation
opportunities. */
NEXT_PASS (pass_phi_only_cprop);
NEXT_PASS (pass_cd_dce);
NEXT_PASS (pass_tracer);
/* FIXME: If DCE is not run before checking for uninitialized uses,
we may get false warnings (e.g., testsuite/gcc.dg/uninit-5.c).
However, this also causes us to misdiagnose cases that should be
real warnings (e.g., testsuite/gcc.dg/pr18501.c).
To fix the false positives in uninit-5.c, we would have to
account for the predicates protecting the set and the use of each
variable. Using a representation like Gated Single Assignment
may help. */
NEXT_PASS (pass_late_warn_uninitialized);
NEXT_PASS (pass_dse);
NEXT_PASS (pass_forwprop);
NEXT_PASS (pass_phiopt);
NEXT_PASS (pass_fold_builtins);
NEXT_PASS (pass_optimize_widening_mul);
NEXT_PASS (pass_tail_calls);
NEXT_PASS (pass_rename_ssa_copies);
NEXT_PASS (pass_uncprop);
NEXT_PASS (pass_local_pure_const);
}
NEXT_PASS (pass_lower_complex_O0);
NEXT_PASS (pass_cleanup_eh);
NEXT_PASS (pass_lower_resx);
NEXT_PASS (pass_nrv);
NEXT_PASS (pass_mudflap_2);
NEXT_PASS (pass_cleanup_cfg_post_optimizing);
NEXT_PASS (pass_warn_function_noreturn);
NEXT_PASS (pass_expand);
NEXT_PASS (pass_rest_of_compilation);
{
struct opt_pass **p = &pass_rest_of_compilation.pass.sub;
NEXT_PASS (pass_init_function);
NEXT_PASS (pass_jump);
NEXT_PASS (pass_rtl_eh);
NEXT_PASS (pass_initial_value_sets);
NEXT_PASS (pass_unshare_all_rtl);
NEXT_PASS (pass_instantiate_virtual_regs);
NEXT_PASS (pass_into_cfg_layout_mode);
NEXT_PASS (pass_jump2);
NEXT_PASS (pass_lower_subreg);
NEXT_PASS (pass_df_initialize_opt);
NEXT_PASS (pass_cse);
NEXT_PASS (pass_rtl_fwprop);
NEXT_PASS (pass_rtl_cprop);
NEXT_PASS (pass_rtl_pre);
NEXT_PASS (pass_rtl_hoist);
NEXT_PASS (pass_rtl_cprop);
NEXT_PASS (pass_rtl_store_motion);
NEXT_PASS (pass_cse_after_global_opts);
NEXT_PASS (pass_rtl_ifcvt);
NEXT_PASS (pass_reginfo_init);
/* Perform loop optimizations. It might be better to do them a bit
sooner, but we want the profile feedback to work more
efficiently. */
NEXT_PASS (pass_loop2);
{
struct opt_pass **p = &pass_loop2.pass.sub;
NEXT_PASS (pass_rtl_loop_init);
NEXT_PASS (pass_rtl_move_loop_invariants);
NEXT_PASS (pass_rtl_unswitch);
NEXT_PASS (pass_rtl_unroll_and_peel_loops);
NEXT_PASS (pass_rtl_doloop);
NEXT_PASS (pass_rtl_loop_done);
*p = NULL;
}
NEXT_PASS (pass_simplify_got);
NEXT_PASS (pass_web);
NEXT_PASS (pass_rtl_cprop);
NEXT_PASS (pass_cse2);
NEXT_PASS (pass_rtl_dse1);
NEXT_PASS (pass_rtl_fwprop_addr);
NEXT_PASS (pass_inc_dec);
NEXT_PASS (pass_initialize_regs);
NEXT_PASS (pass_ud_rtl_dce);
NEXT_PASS (pass_combine);
NEXT_PASS (pass_if_after_combine);
NEXT_PASS (pass_partition_blocks);
NEXT_PASS (pass_regmove);
NEXT_PASS (pass_outof_cfg_layout_mode);
NEXT_PASS (pass_split_all_insns);
NEXT_PASS (pass_lower_subreg2);
NEXT_PASS (pass_df_initialize_no_opt);
NEXT_PASS (pass_stack_ptr_mod);
NEXT_PASS (pass_mode_switching);
NEXT_PASS (pass_match_asm_constraints);
NEXT_PASS (pass_sms);
NEXT_PASS (pass_sched);
NEXT_PASS (pass_ira);
NEXT_PASS (pass_postreload);
{
struct opt_pass **p = &pass_postreload.pass.sub;
NEXT_PASS (pass_postreload_cse);
NEXT_PASS (pass_gcse2);
NEXT_PASS (pass_split_after_reload);
NEXT_PASS (pass_implicit_zee);
NEXT_PASS (pass_compare_elim_after_reload);
NEXT_PASS (pass_branch_target_load_optimize1);
NEXT_PASS (pass_thread_prologue_and_epilogue);
NEXT_PASS (pass_rtl_dse2);
NEXT_PASS (pass_stack_adjustments);
NEXT_PASS (pass_peephole2);
NEXT_PASS (pass_if_after_reload);
NEXT_PASS (pass_regrename);
NEXT_PASS (pass_cprop_hardreg);
NEXT_PASS (pass_fast_rtl_dce);
NEXT_PASS (pass_reorder_blocks);
NEXT_PASS (pass_branch_target_load_optimize2);
NEXT_PASS (pass_leaf_regs);
NEXT_PASS (pass_split_before_sched2);
NEXT_PASS (pass_sched2);
NEXT_PASS (pass_stack_regs);
{
struct opt_pass **p = &pass_stack_regs.pass.sub;
NEXT_PASS (pass_split_before_regstack);
NEXT_PASS (pass_stack_regs_run);
}
NEXT_PASS (pass_compute_alignments);
NEXT_PASS (pass_duplicate_computed_gotos);
NEXT_PASS (pass_variable_tracking);
NEXT_PASS (pass_free_cfg);
NEXT_PASS (pass_machine_reorg);
NEXT_PASS (pass_cleanup_barriers);
NEXT_PASS (pass_delay_slots);
NEXT_PASS (pass_split_for_shorten_branches);
NEXT_PASS (pass_convert_to_eh_region_ranges);
NEXT_PASS (pass_shorten_branches);
NEXT_PASS (pass_set_nothrow_function_flags);
NEXT_PASS (pass_final);
}
NEXT_PASS (pass_df_finish);
}
NEXT_PASS (pass_clean_state);
*p = NULL;
#undef NEXT_PASS
/* Register the passes with the tree dump code. */
register_dump_files (all_lowering_passes, PROP_gimple_any);
register_dump_files (all_small_ipa_passes,
PROP_gimple_any | PROP_gimple_lcf | PROP_gimple_leh
| PROP_cfg);
register_dump_files (all_regular_ipa_passes,
PROP_gimple_any | PROP_gimple_lcf | PROP_gimple_leh
| PROP_cfg);
register_dump_files (all_lto_gen_passes,
PROP_gimple_any | PROP_gimple_lcf | PROP_gimple_leh
| PROP_cfg);
register_dump_files (all_passes,
PROP_gimple_any | PROP_gimple_lcf | PROP_gimple_leh
| PROP_cfg);
}
/* If we are in IPA mode (i.e., current_function_decl is NULL), call
function CALLBACK for every function in the call graph. Otherwise,
call CALLBACK on the current function. */
static void
do_per_function (void (*callback) (void *data), void *data)
{
if (current_function_decl)
callback (data);
else
{
struct cgraph_node *node;
for (node = cgraph_nodes; node; node = node->next)
if (node->analyzed && gimple_has_body_p (node->decl)
&& (!node->clone_of || node->decl != node->clone_of->decl))
{
push_cfun (DECL_STRUCT_FUNCTION (node->decl));
current_function_decl = node->decl;
callback (data);
if (!flag_wpa)
{
free_dominance_info (CDI_DOMINATORS);
free_dominance_info (CDI_POST_DOMINATORS);
}
current_function_decl = NULL;
pop_cfun ();
ggc_collect ();
}
}
}
/* Because inlining might remove no-longer reachable nodes, we need to
keep the array visible to garbage collector to avoid reading collected
out nodes. */
static int nnodes;
static GTY ((length ("nnodes"))) cgraph_node_ptr *order;
/* If we are in IPA mode (i.e., current_function_decl is NULL), call
function CALLBACK for every function in the call graph. Otherwise,
call CALLBACK on the current function.
This function is global so that plugins can use it. */
void
do_per_function_toporder (void (*callback) (void *data), void *data)
{
int i;
if (current_function_decl)
callback (data);
else
{
gcc_assert (!order);
order = ggc_alloc_vec_cgraph_node_ptr (cgraph_n_nodes);
nnodes = cgraph_postorder (order);
for (i = nnodes - 1; i >= 0; i--)
order[i]->process = 1;
for (i = nnodes - 1; i >= 0; i--)
{
struct cgraph_node *node = order[i];
/* Allow possibly removed nodes to be garbage collected. */
order[i] = NULL;
node->process = 0;
if (node->analyzed)
{
push_cfun (DECL_STRUCT_FUNCTION (node->decl));
current_function_decl = node->decl;
callback (data);
free_dominance_info (CDI_DOMINATORS);
free_dominance_info (CDI_POST_DOMINATORS);
current_function_decl = NULL;
pop_cfun ();
ggc_collect ();
}
}
}
ggc_free (order);
order = NULL;
nnodes = 0;
}
/* Perform all TODO actions that ought to be done on each function. */
static void
execute_function_todo (void *data)
{
unsigned int flags = (size_t)data;
flags &= ~cfun->last_verified;
if (!flags)
return;
/* Always cleanup the CFG before trying to update SSA. */
if (flags & TODO_cleanup_cfg)
{
bool cleanup = cleanup_tree_cfg ();
if (cleanup && (cfun->curr_properties & PROP_ssa))
flags |= TODO_remove_unused_locals;
/* When cleanup_tree_cfg merges consecutive blocks, it may
perform some simplistic propagation when removing single
valued PHI nodes. This propagation may, in turn, cause the
SSA form to become out-of-date (see PR 22037). So, even
if the parent pass had not scheduled an SSA update, we may
still need to do one. */
if (!(flags & TODO_update_ssa_any) && need_ssa_update_p (cfun))
flags |= TODO_update_ssa;
}
if (flags & TODO_update_ssa_any)
{
unsigned update_flags = flags & TODO_update_ssa_any;
update_ssa (update_flags);
cfun->last_verified &= ~TODO_verify_ssa;
}
if (flags & TODO_rebuild_alias)
{
execute_update_addresses_taken ();
compute_may_aliases ();
}
else if (optimize && (flags & TODO_update_address_taken))
execute_update_addresses_taken ();
if (flags & TODO_remove_unused_locals)
remove_unused_locals ();
if ((flags & TODO_dump_func) && dump_file && current_function_decl)
{
if (cfun->curr_properties & PROP_trees)
dump_function_to_file (current_function_decl, dump_file, dump_flags);
else
{
if (dump_flags & TDF_SLIM)
print_rtl_slim_with_bb (dump_file, get_insns (), dump_flags);
else if ((cfun->curr_properties & PROP_cfg)
&& (dump_flags & TDF_BLOCKS))
print_rtl_with_bb (dump_file, get_insns ());
else
print_rtl (dump_file, get_insns ());
if ((cfun->curr_properties & PROP_cfg)
&& graph_dump_format != no_graph
&& (dump_flags & TDF_GRAPH))
print_rtl_graph_with_bb (dump_file_name, get_insns ());
}
/* Flush the file. If verification fails, we won't be able to
close the file before aborting. */
fflush (dump_file);
}
if (flags & TODO_rebuild_frequencies)
rebuild_frequencies ();
if (flags & TODO_rebuild_cgraph_edges)
rebuild_cgraph_edges ();
/* If we've seen errors do not bother running any verifiers. */
if (seen_error ())
return;
#if defined ENABLE_CHECKING
if (flags & TODO_verify_ssa
|| (current_loops && loops_state_satisfies_p (LOOP_CLOSED_SSA)))
verify_ssa (true);
if (flags & TODO_verify_flow)
verify_flow_info ();
if (flags & TODO_verify_stmts)
verify_stmts ();
if (current_loops && loops_state_satisfies_p (LOOP_CLOSED_SSA))
verify_loop_closed_ssa (false);
if (flags & TODO_verify_rtl_sharing)
verify_rtl_sharing ();
#endif
cfun->last_verified = flags & TODO_verify_all;
}
/* Perform all TODO actions. */
static void
execute_todo (unsigned int flags)
{
#if defined ENABLE_CHECKING
if (cfun
&& need_ssa_update_p (cfun))
gcc_assert (flags & TODO_update_ssa_any);
#endif
timevar_push (TV_TODO);
/* Inform the pass whether it is the first time it is run. */
first_pass_instance = (flags & TODO_mark_first_instance) != 0;
statistics_fini_pass ();
do_per_function (execute_function_todo, (void *)(size_t) flags);
/* Always remove functions just as before inlining: IPA passes might be
interested to see bodies of extern inline functions that are not inlined
to analyze side effects. The full removal is done just at the end
of IPA pass queue. */
if (flags & TODO_remove_functions)
{
gcc_assert (!cfun);
cgraph_remove_unreachable_nodes (true, dump_file);
}
if ((flags & TODO_dump_cgraph) && dump_file && !current_function_decl)
{
gcc_assert (!cfun);
dump_cgraph (dump_file);
/* Flush the file. If verification fails, we won't be able to
close the file before aborting. */
fflush (dump_file);
}
if (flags & TODO_ggc_collect)
ggc_collect ();
/* Now that the dumping has been done, we can get rid of the optional
df problems. */
if (flags & TODO_df_finish)
df_finish_pass ((flags & TODO_df_verify) != 0);
timevar_pop (TV_TODO);
}
/* Verify invariants that should hold between passes. This is a place
to put simple sanity checks. */
static void
verify_interpass_invariants (void)
{
gcc_checking_assert (!fold_deferring_overflow_warnings_p ());
}
/* Clear the last verified flag. */
static void
clear_last_verified (void *data ATTRIBUTE_UNUSED)
{
cfun->last_verified = 0;
}
/* Helper function. Verify that the properties has been turn into the
properties expected by the pass. */
#ifdef ENABLE_CHECKING
static void
verify_curr_properties (void *data)
{
unsigned int props = (size_t)data;
gcc_assert ((cfun->curr_properties & props) == props);
}
#endif
/* Initialize pass dump file. */
/* This is non-static so that the plugins can use it. */
bool
pass_init_dump_file (struct opt_pass *pass)
{
/* If a dump file name is present, open it if enabled. */
if (pass->static_pass_number != -1)
{
bool initializing_dump = !dump_initialized_p (pass->static_pass_number);
dump_file_name = get_dump_file_name (pass->static_pass_number);
dump_file = dump_begin (pass->static_pass_number, &dump_flags);
if (dump_file && current_function_decl)
dump_function_header (dump_file, current_function_decl, dump_flags);
return initializing_dump;
}
else
return false;
}
/* Flush PASS dump file. */
/* This is non-static so that plugins can use it. */
void
pass_fini_dump_file (struct opt_pass *pass)
{
/* Flush and close dump file. */
if (dump_file_name)
{
free (CONST_CAST (char *, dump_file_name));
dump_file_name = NULL;
}
if (dump_file)
{
dump_end (pass->static_pass_number, dump_file);
dump_file = NULL;
}
}
/* After executing the pass, apply expected changes to the function
properties. */
static void
update_properties_after_pass (void *data)
{
struct opt_pass *pass = (struct opt_pass *) data;
cfun->curr_properties = (cfun->curr_properties | pass->properties_provided)
& ~pass->properties_destroyed;
}
/* Execute summary generation for all of the passes in IPA_PASS. */
void
execute_ipa_summary_passes (struct ipa_opt_pass_d *ipa_pass)
{
while (ipa_pass)
{
struct opt_pass *pass = &ipa_pass->pass;
/* Execute all of the IPA_PASSes in the list. */
if (ipa_pass->pass.type == IPA_PASS
&& (!pass->gate || pass->gate ())
&& ipa_pass->generate_summary)
{
pass_init_dump_file (pass);
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
ipa_pass->generate_summary ();
/* Stop timevar. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
pass_fini_dump_file (pass);
}
ipa_pass = (struct ipa_opt_pass_d *)ipa_pass->pass.next;
}
}
/* Execute IPA_PASS function transform on NODE. */
static void
execute_one_ipa_transform_pass (struct cgraph_node *node,
struct ipa_opt_pass_d *ipa_pass)
{
struct opt_pass *pass = &ipa_pass->pass;
unsigned int todo_after = 0;
current_pass = pass;
if (!ipa_pass->function_transform)
return;
/* Note that the folders should only create gimple expressions.
This is a hack until the new folder is ready. */
in_gimple_form = (cfun && (cfun->curr_properties & PROP_trees)) != 0;
pass_init_dump_file (pass);
/* Run pre-pass verification. */
execute_todo (ipa_pass->function_transform_todo_flags_start);
/* If a timevar is present, start it. */
if (pass->tv_id != TV_NONE)
timevar_push (pass->tv_id);
/* Do it! */
todo_after = ipa_pass->function_transform (node);
/* Stop timevar. */
if (pass->tv_id != TV_NONE)
timevar_pop (pass->tv_id);
/* Run post-pass cleanup and verification. */
execute_todo (todo_after);
verify_interpass_invariants ();
pass_fini_dump_file (pass);
current_pass = NULL;
}
/* For the current function, execute all ipa transforms. */
void
execute_all_ipa_transforms (void)
{
struct cgraph_node *node;
if (!cfun)
return;
node = cgraph_node (current_function_decl);
if (node->ipa_transforms_to_apply)
{
unsigned int i;
for (i = 0; i < VEC_length (ipa_opt_pass, node->ipa_transforms_to_apply);
i++)
execute_one_ipa_transform_pass (node,
VEC_index (ipa_opt_pass,
node->ipa_transforms_to_apply,
i));
VEC_free (ipa_opt_pass, heap, node->ipa_transforms_to_apply);
node->ipa_transforms_to_apply = NULL;
}
}
/* Check if PASS is explicitly disabled or enabled and return
the gate status. FUNC is the function to be processed, and
GATE_STATUS is the gate status determined by pass manager by
default. */
static bool
override_gate_status (struct opt_pass *pass, tree func, bool gate_status)
{
bool explicitly_enabled = false;
bool explicitly_disabled = false;
explicitly_enabled
= is_pass_explicitly_enabled_or_disabled (pass, func,
enabled_pass_uid_range_tab);
explicitly_disabled
= is_pass_explicitly_enabled_or_disabled (pass, func,
disabled_pass_uid_range_tab);
gate_status = !explicitly_disabled && (gate_status || explicitly_enabled);
return gate_status;
}
/* Execute PASS. */
bool
execute_one_pass (struct opt_pass *pass)
{
bool initializing_dump;
unsigned int todo_after = 0;
bool gate_status;
/* IPA passes are executed on whole program, so cfun should be NULL.
Other passes need function context set. */
if (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS)
gcc_assert (!cfun && !current_function_decl);
else
gcc_assert (cfun && current_function_decl);
current_pass = pass;
/* Check whether gate check should be avoided.
User controls the value of the gate through the parameter "gate_status". */
gate_status = (pass->gate == NULL) ? true : pass->gate();
gate_status = override_gate_status (pass, current_function_decl, gate_status);
/* Override gate with plugin. */
invoke_plugin_callbacks (PLUGIN_OVERRIDE_GATE, &gate_status);
if (!gate_status)
{
current_pass = NULL;
return false;
}
/* Pass execution event trigger: useful to identify passes being
executed. */
invoke_plugin_callbacks (PLUGIN_PASS_EXECUTION, pass);
if (!quiet_flag && !cfun)
fprintf (stderr, " <%s>", pass->name ? pass->name : "");
/* Note that the folders should only create gimple expressions.
This is a hack until the new folder is ready. */
in_gimple_form = (cfun && (cfun->curr_properties & PROP_trees)) != 0;
initializing_dump = pass_init_dump_file (pass);
/* Run pre-pass verification. */
execute_todo (pass->todo_flags_start);
#ifdef ENABLE_CHECKING
do_per_function (verify_curr_properties,
(void *)(size_t)pass->properties_required);
#endif
/* If a timevar is present, start it. */
if (pass->tv_id != TV_NONE)
timevar_push (pass->tv_id);
/* Do it! */
if (pass->execute)
{
todo_after = pass->execute ();
do_per_function (clear_last_verified, NULL);
}
/* Stop timevar. */
if (pass->tv_id != TV_NONE)
timevar_pop (pass->tv_id);
do_per_function (update_properties_after_pass, pass);
if (initializing_dump
&& dump_file
&& graph_dump_format != no_graph
&& cfun
&& (cfun->curr_properties & (PROP_cfg | PROP_rtl))
== (PROP_cfg | PROP_rtl))
{
get_dump_file_info (pass->static_pass_number)->flags |= TDF_GRAPH;
dump_flags |= TDF_GRAPH;
clean_graph_dump_file (dump_file_name);
}
/* Run post-pass cleanup and verification. */
execute_todo (todo_after | pass->todo_flags_finish);
verify_interpass_invariants ();
if (pass->type == IPA_PASS)
{
struct cgraph_node *node;
for (node = cgraph_nodes; node; node = node->next)
if (node->analyzed)
VEC_safe_push (ipa_opt_pass, heap, node->ipa_transforms_to_apply,
(struct ipa_opt_pass_d *)pass);
}
if (!current_function_decl)
cgraph_process_new_functions ();
pass_fini_dump_file (pass);
if (pass->type != SIMPLE_IPA_PASS && pass->type != IPA_PASS)
gcc_assert (!(cfun->curr_properties & PROP_trees)
|| pass->type != RTL_PASS);
current_pass = NULL;
return true;
}
void
execute_pass_list (struct opt_pass *pass)
{
do
{
gcc_assert (pass->type == GIMPLE_PASS
|| pass->type == RTL_PASS);
if (execute_one_pass (pass) && pass->sub)
execute_pass_list (pass->sub);
pass = pass->next;
}
while (pass);
}
/* Same as execute_pass_list but assume that subpasses of IPA passes
are local passes. If SET is not NULL, write out summaries of only
those node in SET. */
static void
ipa_write_summaries_2 (struct opt_pass *pass, cgraph_node_set set,
varpool_node_set vset,
struct lto_out_decl_state *state)
{
while (pass)
{
struct ipa_opt_pass_d *ipa_pass = (struct ipa_opt_pass_d *)pass;
gcc_assert (!current_function_decl);
gcc_assert (!cfun);
gcc_assert (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS);
if (pass->type == IPA_PASS
&& ipa_pass->write_summary
&& (!pass->gate || pass->gate ()))
{
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
pass_init_dump_file (pass);
ipa_pass->write_summary (set,vset);
pass_fini_dump_file (pass);
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
}
if (pass->sub && pass->sub->type != GIMPLE_PASS)
ipa_write_summaries_2 (pass->sub, set, vset, state);
pass = pass->next;
}
}
/* Helper function of ipa_write_summaries. Creates and destroys the
decl state and calls ipa_write_summaries_2 for all passes that have
summaries. SET is the set of nodes to be written. */
static void
ipa_write_summaries_1 (cgraph_node_set set, varpool_node_set vset)
{
struct lto_out_decl_state *state = lto_new_out_decl_state ();
compute_ltrans_boundary (state, set, vset);
lto_push_out_decl_state (state);
gcc_assert (!flag_wpa);
ipa_write_summaries_2 (all_regular_ipa_passes, set, vset, state);
ipa_write_summaries_2 (all_lto_gen_passes, set, vset, state);
gcc_assert (lto_get_out_decl_state () == state);
lto_pop_out_decl_state ();
lto_delete_out_decl_state (state);
}
/* Write out summaries for all the nodes in the callgraph. */
void
ipa_write_summaries (void)
{
cgraph_node_set set;
varpool_node_set vset;
struct cgraph_node **order;
struct varpool_node *vnode;
int i, order_pos;
if (!flag_generate_lto || seen_error ())
return;
set = cgraph_node_set_new ();
/* Create the callgraph set in the same order used in
cgraph_expand_all_functions. This mostly facilitates debugging,
since it causes the gimple file to be processed in the same order
as the source code. */
order = XCNEWVEC (struct cgraph_node *, cgraph_n_nodes);
order_pos = cgraph_postorder (order);
gcc_assert (order_pos == cgraph_n_nodes);
for (i = order_pos - 1; i >= 0; i--)
{
struct cgraph_node *node = order[i];
if (node->analyzed)
{
/* When streaming out references to statements as part of some IPA
pass summary, the statements need to have uids assigned and the
following does that for all the IPA passes here. Naturally, this
ordering then matches the one IPA-passes get in their stmt_fixup
hooks. */
push_cfun (DECL_STRUCT_FUNCTION (node->decl));
renumber_gimple_stmt_uids ();
pop_cfun ();
}
if (node->analyzed)
cgraph_node_set_add (set, node);
}
vset = varpool_node_set_new ();
for (vnode = varpool_nodes; vnode; vnode = vnode->next)
if (vnode->needed && !vnode->alias)
varpool_node_set_add (vset, vnode);
ipa_write_summaries_1 (set, vset);
free (order);
ggc_free (set);
ggc_free (vset);
}
/* Same as execute_pass_list but assume that subpasses of IPA passes
are local passes. If SET is not NULL, write out optimization summaries of
only those node in SET. */
static void
ipa_write_optimization_summaries_1 (struct opt_pass *pass, cgraph_node_set set,
varpool_node_set vset,
struct lto_out_decl_state *state)
{
while (pass)
{
struct ipa_opt_pass_d *ipa_pass = (struct ipa_opt_pass_d *)pass;
gcc_assert (!current_function_decl);
gcc_assert (!cfun);
gcc_assert (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS);
if (pass->type == IPA_PASS
&& ipa_pass->write_optimization_summary
&& (!pass->gate || pass->gate ()))
{
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
pass_init_dump_file (pass);
ipa_pass->write_optimization_summary (set, vset);
pass_fini_dump_file (pass);
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
}
if (pass->sub && pass->sub->type != GIMPLE_PASS)
ipa_write_optimization_summaries_1 (pass->sub, set, vset, state);
pass = pass->next;
}
}
/* Write all the optimization summaries for the cgraph nodes in SET. If SET is
NULL, write out all summaries of all nodes. */
void
ipa_write_optimization_summaries (cgraph_node_set set, varpool_node_set vset)
{
struct lto_out_decl_state *state = lto_new_out_decl_state ();
cgraph_node_set_iterator csi;
compute_ltrans_boundary (state, set, vset);
lto_push_out_decl_state (state);
for (csi = csi_start (set); !csi_end_p (csi); csi_next (&csi))
{
struct cgraph_node *node = csi_node (csi);
/* When streaming out references to statements as part of some IPA
pass summary, the statements need to have uids assigned.
For functions newly born at WPA stage we need to initialize
the uids here. */
if (node->analyzed
&& gimple_has_body_p (node->decl))
{
push_cfun (DECL_STRUCT_FUNCTION (node->decl));
renumber_gimple_stmt_uids ();
pop_cfun ();
}
}
gcc_assert (flag_wpa);
ipa_write_optimization_summaries_1 (all_regular_ipa_passes, set, vset, state);
ipa_write_optimization_summaries_1 (all_lto_gen_passes, set, vset, state);
gcc_assert (lto_get_out_decl_state () == state);
lto_pop_out_decl_state ();
lto_delete_out_decl_state (state);
}
/* Same as execute_pass_list but assume that subpasses of IPA passes
are local passes. */
static void
ipa_read_summaries_1 (struct opt_pass *pass)
{
while (pass)
{
struct ipa_opt_pass_d *ipa_pass = (struct ipa_opt_pass_d *) pass;
gcc_assert (!current_function_decl);
gcc_assert (!cfun);
gcc_assert (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS);
if (pass->gate == NULL || pass->gate ())
{
if (pass->type == IPA_PASS && ipa_pass->read_summary)
{
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
pass_init_dump_file (pass);
ipa_pass->read_summary ();
pass_fini_dump_file (pass);
/* Stop timevar. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
}
if (pass->sub && pass->sub->type != GIMPLE_PASS)
ipa_read_summaries_1 (pass->sub);
}
pass = pass->next;
}
}
/* Read all the summaries for all_regular_ipa_passes and all_lto_gen_passes. */
void
ipa_read_summaries (void)
{
ipa_read_summaries_1 (all_regular_ipa_passes);
ipa_read_summaries_1 (all_lto_gen_passes);
}
/* Same as execute_pass_list but assume that subpasses of IPA passes
are local passes. */
static void
ipa_read_optimization_summaries_1 (struct opt_pass *pass)
{
while (pass)
{
struct ipa_opt_pass_d *ipa_pass = (struct ipa_opt_pass_d *) pass;
gcc_assert (!current_function_decl);
gcc_assert (!cfun);
gcc_assert (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS);
if (pass->gate == NULL || pass->gate ())
{
if (pass->type == IPA_PASS && ipa_pass->read_optimization_summary)
{
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
pass_init_dump_file (pass);
ipa_pass->read_optimization_summary ();
pass_fini_dump_file (pass);
/* Stop timevar. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
}
if (pass->sub && pass->sub->type != GIMPLE_PASS)
ipa_read_optimization_summaries_1 (pass->sub);
}
pass = pass->next;
}
}
/* Read all the summaries for all_regular_ipa_passes and all_lto_gen_passes. */
void
ipa_read_optimization_summaries (void)
{
ipa_read_optimization_summaries_1 (all_regular_ipa_passes);
ipa_read_optimization_summaries_1 (all_lto_gen_passes);
}
/* Same as execute_pass_list but assume that subpasses of IPA passes
are local passes. */
void
execute_ipa_pass_list (struct opt_pass *pass)
{
do
{
gcc_assert (!current_function_decl);
gcc_assert (!cfun);
gcc_assert (pass->type == SIMPLE_IPA_PASS || pass->type == IPA_PASS);
if (execute_one_pass (pass) && pass->sub)
{
if (pass->sub->type == GIMPLE_PASS)
{
invoke_plugin_callbacks (PLUGIN_EARLY_GIMPLE_PASSES_START, NULL);
do_per_function_toporder ((void (*)(void *))execute_pass_list,
pass->sub);
invoke_plugin_callbacks (PLUGIN_EARLY_GIMPLE_PASSES_END, NULL);
}
else if (pass->sub->type == SIMPLE_IPA_PASS
|| pass->sub->type == IPA_PASS)
execute_ipa_pass_list (pass->sub);
else
gcc_unreachable ();
}
gcc_assert (!current_function_decl);
cgraph_process_new_functions ();
pass = pass->next;
}
while (pass);
}
/* Execute stmt fixup hooks of all passes in PASS for NODE and STMTS. */
static void
execute_ipa_stmt_fixups (struct opt_pass *pass,
struct cgraph_node *node, gimple *stmts)
{
while (pass)
{
/* Execute all of the IPA_PASSes in the list. */
if (pass->type == IPA_PASS
&& (!pass->gate || pass->gate ()))
{
struct ipa_opt_pass_d *ipa_pass = (struct ipa_opt_pass_d *) pass;
if (ipa_pass->stmt_fixup)
{
pass_init_dump_file (pass);
/* If a timevar is present, start it. */
if (pass->tv_id)
timevar_push (pass->tv_id);
ipa_pass->stmt_fixup (node, stmts);
/* Stop timevar. */
if (pass->tv_id)
timevar_pop (pass->tv_id);
pass_fini_dump_file (pass);
}
if (pass->sub)
execute_ipa_stmt_fixups (pass->sub, node, stmts);
}
pass = pass->next;
}
}
/* Execute stmt fixup hooks of all IPA passes for NODE and STMTS. */
void
execute_all_ipa_stmt_fixups (struct cgraph_node *node, gimple *stmts)
{
execute_ipa_stmt_fixups (all_regular_ipa_passes, node, stmts);
}
extern void debug_properties (unsigned int);
extern void dump_properties (FILE *, unsigned int);
DEBUG_FUNCTION void
dump_properties (FILE *dump, unsigned int props)
{
fprintf (dump, "Properties:\n");
if (props & PROP_gimple_any)
fprintf (dump, "PROP_gimple_any\n");
if (props & PROP_gimple_lcf)
fprintf (dump, "PROP_gimple_lcf\n");
if (props & PROP_gimple_leh)
fprintf (dump, "PROP_gimple_leh\n");
if (props & PROP_cfg)
fprintf (dump, "PROP_cfg\n");
if (props & PROP_referenced_vars)
fprintf (dump, "PROP_referenced_vars\n");
if (props & PROP_ssa)
fprintf (dump, "PROP_ssa\n");
if (props & PROP_no_crit_edges)
fprintf (dump, "PROP_no_crit_edges\n");
if (props & PROP_rtl)
fprintf (dump, "PROP_rtl\n");
if (props & PROP_gimple_lomp)
fprintf (dump, "PROP_gimple_lomp\n");
if (props & PROP_gimple_lcx)
fprintf (dump, "PROP_gimple_lcx\n");
if (props & PROP_cfglayout)
fprintf (dump, "PROP_cfglayout\n");
}
DEBUG_FUNCTION void
debug_properties (unsigned int props)
{
dump_properties (stderr, props);
}
/* Called by local passes to see if function is called by already processed nodes.
Because we process nodes in topological order, this means that function is
in recursive cycle or we introduced new direct calls. */
bool
function_called_by_processed_nodes_p (void)
{
struct cgraph_edge *e;
for (e = cgraph_node (current_function_decl)->callers; e; e = e->next_caller)
{
if (e->caller->decl == current_function_decl)
continue;
if (!e->caller->analyzed)
continue;
if (TREE_ASM_WRITTEN (e->caller->decl))
continue;
if (!e->caller->process && !e->caller->global.inlined_to)
break;
}
if (dump_file && e)
{
fprintf (dump_file, "Already processed call to:\n");
dump_cgraph_node (dump_file, e->caller);
}
return e != NULL;
}
#include "gt-passes.h"