/* Expands front end tree to back end RTL for GCC.
Copyright (C) 1987-2013 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
. */
/* This file handles the generation of rtl code from tree structure
at the level of the function as a whole.
It creates the rtl expressions for parameters and auto variables
and has full responsibility for allocating stack slots.
`expand_function_start' is called at the beginning of a function,
before the function body is parsed, and `expand_function_end' is
called after parsing the body.
Call `assign_stack_local' to allocate a stack slot for a local variable.
This is usually done during the RTL generation for the function body,
but it can also be done in the reload pass when a pseudo-register does
not get a hard register. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "rtl-error.h"
#include "tree.h"
#include "flags.h"
#include "except.h"
#include "function.h"
#include "expr.h"
#include "optabs.h"
#include "libfuncs.h"
#include "regs.h"
#include "hard-reg-set.h"
#include "insn-config.h"
#include "recog.h"
#include "output.h"
#include "basic-block.h"
#include "hashtab.h"
#include "ggc.h"
#include "tm_p.h"
#include "langhooks.h"
#include "target.h"
#include "common/common-target.h"
#include "gimplify.h"
#include "tree-pass.h"
#include "predict.h"
#include "df.h"
#include "params.h"
#include "bb-reorder.h"
/* So we can assign to cfun in this file. */
#undef cfun
#ifndef STACK_ALIGNMENT_NEEDED
#define STACK_ALIGNMENT_NEEDED 1
#endif
#define STACK_BYTES (STACK_BOUNDARY / BITS_PER_UNIT)
/* Round a value to the lowest integer less than it that is a multiple of
the required alignment. Avoid using division in case the value is
negative. Assume the alignment is a power of two. */
#define FLOOR_ROUND(VALUE,ALIGN) ((VALUE) & ~((ALIGN) - 1))
/* Similar, but round to the next highest integer that meets the
alignment. */
#define CEIL_ROUND(VALUE,ALIGN) (((VALUE) + (ALIGN) - 1) & ~((ALIGN)- 1))
/* Nonzero once virtual register instantiation has been done.
assign_stack_local uses frame_pointer_rtx when this is nonzero.
calls.c:emit_library_call_value_1 uses it to set up
post-instantiation libcalls. */
int virtuals_instantiated;
/* Assign unique numbers to labels generated for profiling, debugging, etc. */
static GTY(()) int funcdef_no;
/* These variables hold pointers to functions to create and destroy
target specific, per-function data structures. */
struct machine_function * (*init_machine_status) (void);
/* The currently compiled function. */
struct function *cfun = 0;
/* These hashes record the prologue and epilogue insns. */
static GTY((if_marked ("ggc_marked_p"), param_is (struct rtx_def)))
htab_t prologue_insn_hash;
static GTY((if_marked ("ggc_marked_p"), param_is (struct rtx_def)))
htab_t epilogue_insn_hash;
htab_t types_used_by_vars_hash = NULL;
vec *types_used_by_cur_var_decl;
/* Forward declarations. */
static struct temp_slot *find_temp_slot_from_address (rtx);
static void pad_to_arg_alignment (struct args_size *, int, struct args_size *);
static void pad_below (struct args_size *, enum machine_mode, tree);
static void reorder_blocks_1 (rtx, tree, vec *);
static int all_blocks (tree, tree *);
static tree *get_block_vector (tree, int *);
extern tree debug_find_var_in_block_tree (tree, tree);
/* We always define `record_insns' even if it's not used so that we
can always export `prologue_epilogue_contains'. */
static void record_insns (rtx, rtx, htab_t *) ATTRIBUTE_UNUSED;
static bool contains (const_rtx, htab_t);
static void prepare_function_start (void);
static void do_clobber_return_reg (rtx, void *);
static void do_use_return_reg (rtx, void *);
/* Stack of nested functions. */
/* Keep track of the cfun stack. */
typedef struct function *function_p;
static vec function_context_stack;
/* Save the current context for compilation of a nested function.
This is called from language-specific code. */
void
push_function_context (void)
{
if (cfun == 0)
allocate_struct_function (NULL, false);
function_context_stack.safe_push (cfun);
set_cfun (NULL);
}
/* Restore the last saved context, at the end of a nested function.
This function is called from language-specific code. */
void
pop_function_context (void)
{
struct function *p = function_context_stack.pop ();
set_cfun (p);
current_function_decl = p->decl;
/* Reset variables that have known state during rtx generation. */
virtuals_instantiated = 0;
generating_concat_p = 1;
}
/* Clear out all parts of the state in F that can safely be discarded
after the function has been parsed, but not compiled, to let
garbage collection reclaim the memory. */
void
free_after_parsing (struct function *f)
{
f->language = 0;
}
/* Clear out all parts of the state in F that can safely be discarded
after the function has been compiled, to let garbage collection
reclaim the memory. */
void
free_after_compilation (struct function *f)
{
prologue_insn_hash = NULL;
epilogue_insn_hash = NULL;
free (crtl->emit.regno_pointer_align);
memset (crtl, 0, sizeof (struct rtl_data));
f->eh = NULL;
f->machine = NULL;
f->cfg = NULL;
regno_reg_rtx = NULL;
}
/* Return size needed for stack frame based on slots so far allocated.
This size counts from zero. It is not rounded to PREFERRED_STACK_BOUNDARY;
the caller may have to do that. */
HOST_WIDE_INT
get_frame_size (void)
{
if (FRAME_GROWS_DOWNWARD)
return -frame_offset;
else
return frame_offset;
}
/* Issue an error message and return TRUE if frame OFFSET overflows in
the signed target pointer arithmetics for function FUNC. Otherwise
return FALSE. */
bool
frame_offset_overflow (HOST_WIDE_INT offset, tree func)
{
unsigned HOST_WIDE_INT size = FRAME_GROWS_DOWNWARD ? -offset : offset;
if (size > ((unsigned HOST_WIDE_INT) 1 << (GET_MODE_BITSIZE (Pmode) - 1))
/* Leave room for the fixed part of the frame. */
- 64 * UNITS_PER_WORD)
{
error_at (DECL_SOURCE_LOCATION (func),
"total size of local objects too large");
return TRUE;
}
return FALSE;
}
/* Return stack slot alignment in bits for TYPE and MODE. */
static unsigned int
get_stack_local_alignment (tree type, enum machine_mode mode)
{
unsigned int alignment;
if (mode == BLKmode)
alignment = BIGGEST_ALIGNMENT;
else
alignment = GET_MODE_ALIGNMENT (mode);
/* Allow the frond-end to (possibly) increase the alignment of this
stack slot. */
if (! type)
type = lang_hooks.types.type_for_mode (mode, 0);
return STACK_SLOT_ALIGNMENT (type, mode, alignment);
}
/* Determine whether it is possible to fit a stack slot of size SIZE and
alignment ALIGNMENT into an area in the stack frame that starts at
frame offset START and has a length of LENGTH. If so, store the frame
offset to be used for the stack slot in *POFFSET and return true;
return false otherwise. This function will extend the frame size when
given a start/length pair that lies at the end of the frame. */
static bool
try_fit_stack_local (HOST_WIDE_INT start, HOST_WIDE_INT length,
HOST_WIDE_INT size, unsigned int alignment,
HOST_WIDE_INT *poffset)
{
HOST_WIDE_INT this_frame_offset;
int frame_off, frame_alignment, frame_phase;
/* Calculate how many bytes the start of local variables is off from
stack alignment. */
frame_alignment = PREFERRED_STACK_BOUNDARY / BITS_PER_UNIT;
frame_off = STARTING_FRAME_OFFSET % frame_alignment;
frame_phase = frame_off ? frame_alignment - frame_off : 0;
/* Round the frame offset to the specified alignment. */
/* We must be careful here, since FRAME_OFFSET might be negative and
division with a negative dividend isn't as well defined as we might
like. So we instead assume that ALIGNMENT is a power of two and
use logical operations which are unambiguous. */
if (FRAME_GROWS_DOWNWARD)
this_frame_offset
= (FLOOR_ROUND (start + length - size - frame_phase,
(unsigned HOST_WIDE_INT) alignment)
+ frame_phase);
else
this_frame_offset
= (CEIL_ROUND (start - frame_phase,
(unsigned HOST_WIDE_INT) alignment)
+ frame_phase);
/* See if it fits. If this space is at the edge of the frame,
consider extending the frame to make it fit. Our caller relies on
this when allocating a new slot. */
if (frame_offset == start && this_frame_offset < frame_offset)
frame_offset = this_frame_offset;
else if (this_frame_offset < start)
return false;
else if (start + length == frame_offset
&& this_frame_offset + size > start + length)
frame_offset = this_frame_offset + size;
else if (this_frame_offset + size > start + length)
return false;
*poffset = this_frame_offset;
return true;
}
/* Create a new frame_space structure describing free space in the stack
frame beginning at START and ending at END, and chain it into the
function's frame_space_list. */
static void
add_frame_space (HOST_WIDE_INT start, HOST_WIDE_INT end)
{
struct frame_space *space = ggc_alloc_frame_space ();
space->next = crtl->frame_space_list;
crtl->frame_space_list = space;
space->start = start;
space->length = end - start;
}
/* Allocate a stack slot of SIZE bytes and return a MEM rtx for it
with machine mode MODE.
ALIGN controls the amount of alignment for the address of the slot:
0 means according to MODE,
-1 means use BIGGEST_ALIGNMENT and round size to multiple of that,
-2 means use BITS_PER_UNIT,
positive specifies alignment boundary in bits.
KIND has ASLK_REDUCE_ALIGN bit set if it is OK to reduce
alignment and ASLK_RECORD_PAD bit set if we should remember
extra space we allocated for alignment purposes. When we are
called from assign_stack_temp_for_type, it is not set so we don't
track the same stack slot in two independent lists.
We do not round to stack_boundary here. */
rtx
assign_stack_local_1 (enum machine_mode mode, HOST_WIDE_INT size,
int align, int kind)
{
rtx x, addr;
int bigend_correction = 0;
HOST_WIDE_INT slot_offset = 0, old_frame_offset;
unsigned int alignment, alignment_in_bits;
if (align == 0)
{
alignment = get_stack_local_alignment (NULL, mode);
alignment /= BITS_PER_UNIT;
}
else if (align == -1)
{
alignment = BIGGEST_ALIGNMENT / BITS_PER_UNIT;
size = CEIL_ROUND (size, alignment);
}
else if (align == -2)
alignment = 1; /* BITS_PER_UNIT / BITS_PER_UNIT */
else
alignment = align / BITS_PER_UNIT;
alignment_in_bits = alignment * BITS_PER_UNIT;
/* Ignore alignment if it exceeds MAX_SUPPORTED_STACK_ALIGNMENT. */
if (alignment_in_bits > MAX_SUPPORTED_STACK_ALIGNMENT)
{
alignment_in_bits = MAX_SUPPORTED_STACK_ALIGNMENT;
alignment = alignment_in_bits / BITS_PER_UNIT;
}
if (SUPPORTS_STACK_ALIGNMENT)
{
if (crtl->stack_alignment_estimated < alignment_in_bits)
{
if (!crtl->stack_realign_processed)
crtl->stack_alignment_estimated = alignment_in_bits;
else
{
/* If stack is realigned and stack alignment value
hasn't been finalized, it is OK not to increase
stack_alignment_estimated. The bigger alignment
requirement is recorded in stack_alignment_needed
below. */
gcc_assert (!crtl->stack_realign_finalized);
if (!crtl->stack_realign_needed)
{
/* It is OK to reduce the alignment as long as the
requested size is 0 or the estimated stack
alignment >= mode alignment. */
gcc_assert ((kind & ASLK_REDUCE_ALIGN)
|| size == 0
|| (crtl->stack_alignment_estimated
>= GET_MODE_ALIGNMENT (mode)));
alignment_in_bits = crtl->stack_alignment_estimated;
alignment = alignment_in_bits / BITS_PER_UNIT;
}
}
}
}
if (crtl->stack_alignment_needed < alignment_in_bits)
crtl->stack_alignment_needed = alignment_in_bits;
if (crtl->max_used_stack_slot_alignment < alignment_in_bits)
crtl->max_used_stack_slot_alignment = alignment_in_bits;
if (mode != BLKmode || size != 0)
{
if (kind & ASLK_RECORD_PAD)
{
struct frame_space **psp;
for (psp = &crtl->frame_space_list; *psp; psp = &(*psp)->next)
{
struct frame_space *space = *psp;
if (!try_fit_stack_local (space->start, space->length, size,
alignment, &slot_offset))
continue;
*psp = space->next;
if (slot_offset > space->start)
add_frame_space (space->start, slot_offset);
if (slot_offset + size < space->start + space->length)
add_frame_space (slot_offset + size,
space->start + space->length);
goto found_space;
}
}
}
else if (!STACK_ALIGNMENT_NEEDED)
{
slot_offset = frame_offset;
goto found_space;
}
old_frame_offset = frame_offset;
if (FRAME_GROWS_DOWNWARD)
{
frame_offset -= size;
try_fit_stack_local (frame_offset, size, size, alignment, &slot_offset);
if (kind & ASLK_RECORD_PAD)
{
if (slot_offset > frame_offset)
add_frame_space (frame_offset, slot_offset);
if (slot_offset + size < old_frame_offset)
add_frame_space (slot_offset + size, old_frame_offset);
}
}
else
{
frame_offset += size;
try_fit_stack_local (old_frame_offset, size, size, alignment, &slot_offset);
if (kind & ASLK_RECORD_PAD)
{
if (slot_offset > old_frame_offset)
add_frame_space (old_frame_offset, slot_offset);
if (slot_offset + size < frame_offset)
add_frame_space (slot_offset + size, frame_offset);
}
}
found_space:
/* On a big-endian machine, if we are allocating more space than we will use,
use the least significant bytes of those that are allocated. */
if (BYTES_BIG_ENDIAN && mode != BLKmode && GET_MODE_SIZE (mode) < size)
bigend_correction = size - GET_MODE_SIZE (mode);
/* If we have already instantiated virtual registers, return the actual
address relative to the frame pointer. */
if (virtuals_instantiated)
addr = plus_constant (Pmode, frame_pointer_rtx,
trunc_int_for_mode
(slot_offset + bigend_correction
+ STARTING_FRAME_OFFSET, Pmode));
else
addr = plus_constant (Pmode, virtual_stack_vars_rtx,
trunc_int_for_mode
(slot_offset + bigend_correction,
Pmode));
x = gen_rtx_MEM (mode, addr);
set_mem_align (x, alignment_in_bits);
MEM_NOTRAP_P (x) = 1;
stack_slot_list
= gen_rtx_EXPR_LIST (VOIDmode, x, stack_slot_list);
if (frame_offset_overflow (frame_offset, current_function_decl))
frame_offset = 0;
return x;
}
/* Wrap up assign_stack_local_1 with last parameter as false. */
rtx
assign_stack_local (enum machine_mode mode, HOST_WIDE_INT size, int align)
{
return assign_stack_local_1 (mode, size, align, ASLK_RECORD_PAD);
}
/* In order to evaluate some expressions, such as function calls returning
structures in memory, we need to temporarily allocate stack locations.
We record each allocated temporary in the following structure.
Associated with each temporary slot is a nesting level. When we pop up
one level, all temporaries associated with the previous level are freed.
Normally, all temporaries are freed after the execution of the statement
in which they were created. However, if we are inside a ({...}) grouping,
the result may be in a temporary and hence must be preserved. If the
result could be in a temporary, we preserve it if we can determine which
one it is in. If we cannot determine which temporary may contain the
result, all temporaries are preserved. A temporary is preserved by
pretending it was allocated at the previous nesting level. */
struct GTY(()) temp_slot {
/* Points to next temporary slot. */
struct temp_slot *next;
/* Points to previous temporary slot. */
struct temp_slot *prev;
/* The rtx to used to reference the slot. */
rtx slot;
/* The size, in units, of the slot. */
HOST_WIDE_INT size;
/* The type of the object in the slot, or zero if it doesn't correspond
to a type. We use this to determine whether a slot can be reused.
It can be reused if objects of the type of the new slot will always
conflict with objects of the type of the old slot. */
tree type;
/* The alignment (in bits) of the slot. */
unsigned int align;
/* Nonzero if this temporary is currently in use. */
char in_use;
/* Nesting level at which this slot is being used. */
int level;
/* The offset of the slot from the frame_pointer, including extra space
for alignment. This info is for combine_temp_slots. */
HOST_WIDE_INT base_offset;
/* The size of the slot, including extra space for alignment. This
info is for combine_temp_slots. */
HOST_WIDE_INT full_size;
};
/* A table of addresses that represent a stack slot. The table is a mapping
from address RTXen to a temp slot. */
static GTY((param_is(struct temp_slot_address_entry))) htab_t temp_slot_address_table;
static size_t n_temp_slots_in_use;
/* Entry for the above hash table. */
struct GTY(()) temp_slot_address_entry {
hashval_t hash;
rtx address;
struct temp_slot *temp_slot;
};
/* Removes temporary slot TEMP from LIST. */
static void
cut_slot_from_list (struct temp_slot *temp, struct temp_slot **list)
{
if (temp->next)
temp->next->prev = temp->prev;
if (temp->prev)
temp->prev->next = temp->next;
else
*list = temp->next;
temp->prev = temp->next = NULL;
}
/* Inserts temporary slot TEMP to LIST. */
static void
insert_slot_to_list (struct temp_slot *temp, struct temp_slot **list)
{
temp->next = *list;
if (*list)
(*list)->prev = temp;
temp->prev = NULL;
*list = temp;
}
/* Returns the list of used temp slots at LEVEL. */
static struct temp_slot **
temp_slots_at_level (int level)
{
if (level >= (int) vec_safe_length (used_temp_slots))
vec_safe_grow_cleared (used_temp_slots, level + 1);
return &(*used_temp_slots)[level];
}
/* Returns the maximal temporary slot level. */
static int
max_slot_level (void)
{
if (!used_temp_slots)
return -1;
return used_temp_slots->length () - 1;
}
/* Moves temporary slot TEMP to LEVEL. */
static void
move_slot_to_level (struct temp_slot *temp, int level)
{
cut_slot_from_list (temp, temp_slots_at_level (temp->level));
insert_slot_to_list (temp, temp_slots_at_level (level));
temp->level = level;
}
/* Make temporary slot TEMP available. */
static void
make_slot_available (struct temp_slot *temp)
{
cut_slot_from_list (temp, temp_slots_at_level (temp->level));
insert_slot_to_list (temp, &avail_temp_slots);
temp->in_use = 0;
temp->level = -1;
n_temp_slots_in_use--;
}
/* Compute the hash value for an address -> temp slot mapping.
The value is cached on the mapping entry. */
static hashval_t
temp_slot_address_compute_hash (struct temp_slot_address_entry *t)
{
int do_not_record = 0;
return hash_rtx (t->address, GET_MODE (t->address),
&do_not_record, NULL, false);
}
/* Return the hash value for an address -> temp slot mapping. */
static hashval_t
temp_slot_address_hash (const void *p)
{
const struct temp_slot_address_entry *t;
t = (const struct temp_slot_address_entry *) p;
return t->hash;
}
/* Compare two address -> temp slot mapping entries. */
static int
temp_slot_address_eq (const void *p1, const void *p2)
{
const struct temp_slot_address_entry *t1, *t2;
t1 = (const struct temp_slot_address_entry *) p1;
t2 = (const struct temp_slot_address_entry *) p2;
return exp_equiv_p (t1->address, t2->address, 0, true);
}
/* Add ADDRESS as an alias of TEMP_SLOT to the addess -> temp slot mapping. */
static void
insert_temp_slot_address (rtx address, struct temp_slot *temp_slot)
{
void **slot;
struct temp_slot_address_entry *t = ggc_alloc_temp_slot_address_entry ();
t->address = address;
t->temp_slot = temp_slot;
t->hash = temp_slot_address_compute_hash (t);
slot = htab_find_slot_with_hash (temp_slot_address_table, t, t->hash, INSERT);
*slot = t;
}
/* Remove an address -> temp slot mapping entry if the temp slot is
not in use anymore. Callback for remove_unused_temp_slot_addresses. */
static int
remove_unused_temp_slot_addresses_1 (void **slot, void *data ATTRIBUTE_UNUSED)
{
const struct temp_slot_address_entry *t;
t = (const struct temp_slot_address_entry *) *slot;
if (! t->temp_slot->in_use)
htab_clear_slot (temp_slot_address_table, slot);
return 1;
}
/* Remove all mappings of addresses to unused temp slots. */
static void
remove_unused_temp_slot_addresses (void)
{
/* Use quicker clearing if there aren't any active temp slots. */
if (n_temp_slots_in_use)
htab_traverse (temp_slot_address_table,
remove_unused_temp_slot_addresses_1,
NULL);
else
htab_empty (temp_slot_address_table);
}
/* Find the temp slot corresponding to the object at address X. */
static struct temp_slot *
find_temp_slot_from_address (rtx x)
{
struct temp_slot *p;
struct temp_slot_address_entry tmp, *t;
/* First try the easy way:
See if X exists in the address -> temp slot mapping. */
tmp.address = x;
tmp.temp_slot = NULL;
tmp.hash = temp_slot_address_compute_hash (&tmp);
t = (struct temp_slot_address_entry *)
htab_find_with_hash (temp_slot_address_table, &tmp, tmp.hash);
if (t)
return t->temp_slot;
/* If we have a sum involving a register, see if it points to a temp
slot. */
if (GET_CODE (x) == PLUS && REG_P (XEXP (x, 0))
&& (p = find_temp_slot_from_address (XEXP (x, 0))) != 0)
return p;
else if (GET_CODE (x) == PLUS && REG_P (XEXP (x, 1))
&& (p = find_temp_slot_from_address (XEXP (x, 1))) != 0)
return p;
/* Last resort: Address is a virtual stack var address. */
if (GET_CODE (x) == PLUS
&& XEXP (x, 0) == virtual_stack_vars_rtx
&& CONST_INT_P (XEXP (x, 1)))
{
int i;
for (i = max_slot_level (); i >= 0; i--)
for (p = *temp_slots_at_level (i); p; p = p->next)
{
if (INTVAL (XEXP (x, 1)) >= p->base_offset
&& INTVAL (XEXP (x, 1)) < p->base_offset + p->full_size)
return p;
}
}
return NULL;
}
/* Allocate a temporary stack slot and record it for possible later
reuse.
MODE is the machine mode to be given to the returned rtx.
SIZE is the size in units of the space required. We do no rounding here
since assign_stack_local will do any required rounding.
TYPE is the type that will be used for the stack slot. */
rtx
assign_stack_temp_for_type (enum machine_mode mode, HOST_WIDE_INT size,
tree type)
{
unsigned int align;
struct temp_slot *p, *best_p = 0, *selected = NULL, **pp;
rtx slot;
/* If SIZE is -1 it means that somebody tried to allocate a temporary
of a variable size. */
gcc_assert (size != -1);
align = get_stack_local_alignment (type, mode);
/* Try to find an available, already-allocated temporary of the proper
mode which meets the size and alignment requirements. Choose the
smallest one with the closest alignment.
If assign_stack_temp is called outside of the tree->rtl expansion,
we cannot reuse the stack slots (that may still refer to
VIRTUAL_STACK_VARS_REGNUM). */
if (!virtuals_instantiated)
{
for (p = avail_temp_slots; p; p = p->next)
{
if (p->align >= align && p->size >= size
&& GET_MODE (p->slot) == mode
&& objects_must_conflict_p (p->type, type)
&& (best_p == 0 || best_p->size > p->size
|| (best_p->size == p->size && best_p->align > p->align)))
{
if (p->align == align && p->size == size)
{
selected = p;
cut_slot_from_list (selected, &avail_temp_slots);
best_p = 0;
break;
}
best_p = p;
}
}
}
/* Make our best, if any, the one to use. */
if (best_p)
{
selected = best_p;
cut_slot_from_list (selected, &avail_temp_slots);
/* If there are enough aligned bytes left over, make them into a new
temp_slot so that the extra bytes don't get wasted. Do this only
for BLKmode slots, so that we can be sure of the alignment. */
if (GET_MODE (best_p->slot) == BLKmode)
{
int alignment = best_p->align / BITS_PER_UNIT;
HOST_WIDE_INT rounded_size = CEIL_ROUND (size, alignment);
if (best_p->size - rounded_size >= alignment)
{
p = ggc_alloc_temp_slot ();
p->in_use = 0;
p->size = best_p->size - rounded_size;
p->base_offset = best_p->base_offset + rounded_size;
p->full_size = best_p->full_size - rounded_size;
p->slot = adjust_address_nv (best_p->slot, BLKmode, rounded_size);
p->align = best_p->align;
p->type = best_p->type;
insert_slot_to_list (p, &avail_temp_slots);
stack_slot_list = gen_rtx_EXPR_LIST (VOIDmode, p->slot,
stack_slot_list);
best_p->size = rounded_size;
best_p->full_size = rounded_size;
}
}
}
/* If we still didn't find one, make a new temporary. */
if (selected == 0)
{
HOST_WIDE_INT frame_offset_old = frame_offset;
p = ggc_alloc_temp_slot ();
/* We are passing an explicit alignment request to assign_stack_local.
One side effect of that is assign_stack_local will not round SIZE
to ensure the frame offset remains suitably aligned.
So for requests which depended on the rounding of SIZE, we go ahead
and round it now. We also make sure ALIGNMENT is at least
BIGGEST_ALIGNMENT. */
gcc_assert (mode != BLKmode || align == BIGGEST_ALIGNMENT);
p->slot = assign_stack_local_1 (mode,
(mode == BLKmode
? CEIL_ROUND (size,
(int) align
/ BITS_PER_UNIT)
: size),
align, 0);
p->align = align;
/* The following slot size computation is necessary because we don't
know the actual size of the temporary slot until assign_stack_local
has performed all the frame alignment and size rounding for the
requested temporary. Note that extra space added for alignment
can be either above or below this stack slot depending on which
way the frame grows. We include the extra space if and only if it
is above this slot. */
if (FRAME_GROWS_DOWNWARD)
p->size = frame_offset_old - frame_offset;
else
p->size = size;
/* Now define the fields used by combine_temp_slots. */
if (FRAME_GROWS_DOWNWARD)
{
p->base_offset = frame_offset;
p->full_size = frame_offset_old - frame_offset;
}
else
{
p->base_offset = frame_offset_old;
p->full_size = frame_offset - frame_offset_old;
}
selected = p;
}
p = selected;
p->in_use = 1;
p->type = type;
p->level = temp_slot_level;
n_temp_slots_in_use++;
pp = temp_slots_at_level (p->level);
insert_slot_to_list (p, pp);
insert_temp_slot_address (XEXP (p->slot, 0), p);
/* Create a new MEM rtx to avoid clobbering MEM flags of old slots. */
slot = gen_rtx_MEM (mode, XEXP (p->slot, 0));
stack_slot_list = gen_rtx_EXPR_LIST (VOIDmode, slot, stack_slot_list);
/* If we know the alias set for the memory that will be used, use
it. If there's no TYPE, then we don't know anything about the
alias set for the memory. */
set_mem_alias_set (slot, type ? get_alias_set (type) : 0);
set_mem_align (slot, align);
/* If a type is specified, set the relevant flags. */
if (type != 0)
MEM_VOLATILE_P (slot) = TYPE_VOLATILE (type);
MEM_NOTRAP_P (slot) = 1;
return slot;
}
/* Allocate a temporary stack slot and record it for possible later
reuse. First two arguments are same as in preceding function. */
rtx
assign_stack_temp (enum machine_mode mode, HOST_WIDE_INT size)
{
return assign_stack_temp_for_type (mode, size, NULL_TREE);
}
/* Assign a temporary.
If TYPE_OR_DECL is a decl, then we are doing it on behalf of the decl
and so that should be used in error messages. In either case, we
allocate of the given type.
MEMORY_REQUIRED is 1 if the result must be addressable stack memory;
it is 0 if a register is OK.
DONT_PROMOTE is 1 if we should not promote values in register
to wider modes. */
rtx
assign_temp (tree type_or_decl, int memory_required,
int dont_promote ATTRIBUTE_UNUSED)
{
tree type, decl;
enum machine_mode mode;
#ifdef PROMOTE_MODE
int unsignedp;
#endif
if (DECL_P (type_or_decl))
decl = type_or_decl, type = TREE_TYPE (decl);
else
decl = NULL, type = type_or_decl;
mode = TYPE_MODE (type);
#ifdef PROMOTE_MODE
unsignedp = TYPE_UNSIGNED (type);
#endif
if (mode == BLKmode || memory_required)
{
HOST_WIDE_INT size = int_size_in_bytes (type);
rtx tmp;
/* Zero sized arrays are GNU C extension. Set size to 1 to avoid
problems with allocating the stack space. */
if (size == 0)
size = 1;
/* Unfortunately, we don't yet know how to allocate variable-sized
temporaries. However, sometimes we can find a fixed upper limit on
the size, so try that instead. */
else if (size == -1)
size = max_int_size_in_bytes (type);
/* The size of the temporary may be too large to fit into an integer. */
/* ??? Not sure this should happen except for user silliness, so limit
this to things that aren't compiler-generated temporaries. The
rest of the time we'll die in assign_stack_temp_for_type. */
if (decl && size == -1
&& TREE_CODE (TYPE_SIZE_UNIT (type)) == INTEGER_CST)
{
error ("size of variable %q+D is too large", decl);
size = 1;
}
tmp = assign_stack_temp_for_type (mode, size, type);
return tmp;
}
#ifdef PROMOTE_MODE
if (! dont_promote)
mode = promote_mode (type, mode, &unsignedp);
#endif
return gen_reg_rtx (mode);
}
/* Combine temporary stack slots which are adjacent on the stack.
This allows for better use of already allocated stack space. This is only
done for BLKmode slots because we can be sure that we won't have alignment
problems in this case. */
static void
combine_temp_slots (void)
{
struct temp_slot *p, *q, *next, *next_q;
int num_slots;
/* We can't combine slots, because the information about which slot
is in which alias set will be lost. */
if (flag_strict_aliasing)
return;
/* If there are a lot of temp slots, don't do anything unless
high levels of optimization. */
if (! flag_expensive_optimizations)
for (p = avail_temp_slots, num_slots = 0; p; p = p->next, num_slots++)
if (num_slots > 100 || (num_slots > 10 && optimize == 0))
return;
for (p = avail_temp_slots; p; p = next)
{
int delete_p = 0;
next = p->next;
if (GET_MODE (p->slot) != BLKmode)
continue;
for (q = p->next; q; q = next_q)
{
int delete_q = 0;
next_q = q->next;
if (GET_MODE (q->slot) != BLKmode)
continue;
if (p->base_offset + p->full_size == q->base_offset)
{
/* Q comes after P; combine Q into P. */
p->size += q->size;
p->full_size += q->full_size;
delete_q = 1;
}
else if (q->base_offset + q->full_size == p->base_offset)
{
/* P comes after Q; combine P into Q. */
q->size += p->size;
q->full_size += p->full_size;
delete_p = 1;
break;
}
if (delete_q)
cut_slot_from_list (q, &avail_temp_slots);
}
/* Either delete P or advance past it. */
if (delete_p)
cut_slot_from_list (p, &avail_temp_slots);
}
}
/* Indicate that NEW_RTX is an alternate way of referring to the temp
slot that previously was known by OLD_RTX. */
void
update_temp_slot_address (rtx old_rtx, rtx new_rtx)
{
struct temp_slot *p;
if (rtx_equal_p (old_rtx, new_rtx))
return;
p = find_temp_slot_from_address (old_rtx);
/* If we didn't find one, see if both OLD_RTX is a PLUS. If so, and
NEW_RTX is a register, see if one operand of the PLUS is a
temporary location. If so, NEW_RTX points into it. Otherwise,
if both OLD_RTX and NEW_RTX are a PLUS and if there is a register
in common between them. If so, try a recursive call on those
values. */
if (p == 0)
{
if (GET_CODE (old_rtx) != PLUS)
return;
if (REG_P (new_rtx))
{
update_temp_slot_address (XEXP (old_rtx, 0), new_rtx);
update_temp_slot_address (XEXP (old_rtx, 1), new_rtx);
return;
}
else if (GET_CODE (new_rtx) != PLUS)
return;
if (rtx_equal_p (XEXP (old_rtx, 0), XEXP (new_rtx, 0)))
update_temp_slot_address (XEXP (old_rtx, 1), XEXP (new_rtx, 1));
else if (rtx_equal_p (XEXP (old_rtx, 1), XEXP (new_rtx, 0)))
update_temp_slot_address (XEXP (old_rtx, 0), XEXP (new_rtx, 1));
else if (rtx_equal_p (XEXP (old_rtx, 0), XEXP (new_rtx, 1)))
update_temp_slot_address (XEXP (old_rtx, 1), XEXP (new_rtx, 0));
else if (rtx_equal_p (XEXP (old_rtx, 1), XEXP (new_rtx, 1)))
update_temp_slot_address (XEXP (old_rtx, 0), XEXP (new_rtx, 0));
return;
}
/* Otherwise add an alias for the temp's address. */
insert_temp_slot_address (new_rtx, p);
}
/* If X could be a reference to a temporary slot, mark that slot as
belonging to the to one level higher than the current level. If X
matched one of our slots, just mark that one. Otherwise, we can't
easily predict which it is, so upgrade all of them.
This is called when an ({...}) construct occurs and a statement
returns a value in memory. */
void
preserve_temp_slots (rtx x)
{
struct temp_slot *p = 0, *next;
if (x == 0)
return;
/* If X is a register that is being used as a pointer, see if we have
a temporary slot we know it points to. */
if (REG_P (x) && REG_POINTER (x))
p = find_temp_slot_from_address (x);
/* If X is not in memory or is at a constant address, it cannot be in
a temporary slot. */
if (p == 0 && (!MEM_P (x) || CONSTANT_P (XEXP (x, 0))))
return;
/* First see if we can find a match. */
if (p == 0)
p = find_temp_slot_from_address (XEXP (x, 0));
if (p != 0)
{
if (p->level == temp_slot_level)
move_slot_to_level (p, temp_slot_level - 1);
return;
}
/* Otherwise, preserve all non-kept slots at this level. */
for (p = *temp_slots_at_level (temp_slot_level); p; p = next)
{
next = p->next;
move_slot_to_level (p, temp_slot_level - 1);
}
}
/* Free all temporaries used so far. This is normally called at the
end of generating code for a statement. */
void
free_temp_slots (void)
{
struct temp_slot *p, *next;
bool some_available = false;
for (p = *temp_slots_at_level (temp_slot_level); p; p = next)
{
next = p->next;
make_slot_available (p);
some_available = true;
}
if (some_available)
{
remove_unused_temp_slot_addresses ();
combine_temp_slots ();
}
}
/* Push deeper into the nesting level for stack temporaries. */
void
push_temp_slots (void)
{
temp_slot_level++;
}
/* Pop a temporary nesting level. All slots in use in the current level
are freed. */
void
pop_temp_slots (void)
{
free_temp_slots ();
temp_slot_level--;
}
/* Initialize temporary slots. */
void
init_temp_slots (void)
{
/* We have not allocated any temporaries yet. */
avail_temp_slots = 0;
vec_alloc (used_temp_slots, 0);
temp_slot_level = 0;
n_temp_slots_in_use = 0;
/* Set up the table to map addresses to temp slots. */
if (! temp_slot_address_table)
temp_slot_address_table = htab_create_ggc (32,
temp_slot_address_hash,
temp_slot_address_eq,
NULL);
else
htab_empty (temp_slot_address_table);
}
/* Functions and data structures to keep track of the values hard regs
had at the start of the function. */
/* Private type used by get_hard_reg_initial_reg, get_hard_reg_initial_val,
and has_hard_reg_initial_val.. */
typedef struct GTY(()) initial_value_pair {
rtx hard_reg;
rtx pseudo;
} initial_value_pair;
/* ??? This could be a VEC but there is currently no way to define an
opaque VEC type. This could be worked around by defining struct
initial_value_pair in function.h. */
typedef struct GTY(()) initial_value_struct {
int num_entries;
int max_entries;
initial_value_pair * GTY ((length ("%h.num_entries"))) entries;
} initial_value_struct;
/* If a pseudo represents an initial hard reg (or expression), return
it, else return NULL_RTX. */
rtx
get_hard_reg_initial_reg (rtx reg)
{
struct initial_value_struct *ivs = crtl->hard_reg_initial_vals;
int i;
if (ivs == 0)
return NULL_RTX;
for (i = 0; i < ivs->num_entries; i++)
if (rtx_equal_p (ivs->entries[i].pseudo, reg))
return ivs->entries[i].hard_reg;
return NULL_RTX;
}
/* Make sure that there's a pseudo register of mode MODE that stores the
initial value of hard register REGNO. Return an rtx for such a pseudo. */
rtx
get_hard_reg_initial_val (enum machine_mode mode, unsigned int regno)
{
struct initial_value_struct *ivs;
rtx rv;
rv = has_hard_reg_initial_val (mode, regno);
if (rv)
return rv;
ivs = crtl->hard_reg_initial_vals;
if (ivs == 0)
{
ivs = ggc_alloc_initial_value_struct ();
ivs->num_entries = 0;
ivs->max_entries = 5;
ivs->entries = ggc_alloc_vec_initial_value_pair (5);
crtl->hard_reg_initial_vals = ivs;
}
if (ivs->num_entries >= ivs->max_entries)
{
ivs->max_entries += 5;
ivs->entries = GGC_RESIZEVEC (initial_value_pair, ivs->entries,
ivs->max_entries);
}
ivs->entries[ivs->num_entries].hard_reg = gen_rtx_REG (mode, regno);
ivs->entries[ivs->num_entries].pseudo = gen_reg_rtx (mode);
return ivs->entries[ivs->num_entries++].pseudo;
}
/* See if get_hard_reg_initial_val has been used to create a pseudo
for the initial value of hard register REGNO in mode MODE. Return
the associated pseudo if so, otherwise return NULL. */
rtx
has_hard_reg_initial_val (enum machine_mode mode, unsigned int regno)
{
struct initial_value_struct *ivs;
int i;
ivs = crtl->hard_reg_initial_vals;
if (ivs != 0)
for (i = 0; i < ivs->num_entries; i++)
if (GET_MODE (ivs->entries[i].hard_reg) == mode
&& REGNO (ivs->entries[i].hard_reg) == regno)
return ivs->entries[i].pseudo;
return NULL_RTX;
}
unsigned int
emit_initial_value_sets (void)
{
struct initial_value_struct *ivs = crtl->hard_reg_initial_vals;
int i;
rtx seq;
if (ivs == 0)
return 0;
start_sequence ();
for (i = 0; i < ivs->num_entries; i++)
emit_move_insn (ivs->entries[i].pseudo, ivs->entries[i].hard_reg);
seq = get_insns ();
end_sequence ();
emit_insn_at_entry (seq);
return 0;
}
/* Return the hardreg-pseudoreg initial values pair entry I and
TRUE if I is a valid entry, or FALSE if I is not a valid entry. */
bool
initial_value_entry (int i, rtx *hreg, rtx *preg)
{
struct initial_value_struct *ivs = crtl->hard_reg_initial_vals;
if (!ivs || i >= ivs->num_entries)
return false;
*hreg = ivs->entries[i].hard_reg;
*preg = ivs->entries[i].pseudo;
return true;
}
/* These routines are responsible for converting virtual register references
to the actual hard register references once RTL generation is complete.
The following four variables are used for communication between the
routines. They contain the offsets of the virtual registers from their
respective hard registers. */
static int in_arg_offset;
static int var_offset;
static int dynamic_offset;
static int out_arg_offset;
static int cfa_offset;
/* In most machines, the stack pointer register is equivalent to the bottom
of the stack. */
#ifndef STACK_POINTER_OFFSET
#define STACK_POINTER_OFFSET 0
#endif
/* If not defined, pick an appropriate default for the offset of dynamically
allocated memory depending on the value of ACCUMULATE_OUTGOING_ARGS,
REG_PARM_STACK_SPACE, and OUTGOING_REG_PARM_STACK_SPACE. */
#ifndef STACK_DYNAMIC_OFFSET
/* The bottom of the stack points to the actual arguments. If
REG_PARM_STACK_SPACE is defined, this includes the space for the register
parameters. However, if OUTGOING_REG_PARM_STACK space is not defined,
stack space for register parameters is not pushed by the caller, but
rather part of the fixed stack areas and hence not included in
`crtl->outgoing_args_size'. Nevertheless, we must allow
for it when allocating stack dynamic objects. */
#if defined(REG_PARM_STACK_SPACE)
#define STACK_DYNAMIC_OFFSET(FNDECL) \
((ACCUMULATE_OUTGOING_ARGS \
? (crtl->outgoing_args_size \
+ (OUTGOING_REG_PARM_STACK_SPACE ((!(FNDECL) ? NULL_TREE : TREE_TYPE (FNDECL))) ? 0 \
: REG_PARM_STACK_SPACE (FNDECL))) \
: 0) + (STACK_POINTER_OFFSET))
#else
#define STACK_DYNAMIC_OFFSET(FNDECL) \
((ACCUMULATE_OUTGOING_ARGS ? crtl->outgoing_args_size : 0) \
+ (STACK_POINTER_OFFSET))
#endif
#endif
/* Given a piece of RTX and a pointer to a HOST_WIDE_INT, if the RTX
is a virtual register, return the equivalent hard register and set the
offset indirectly through the pointer. Otherwise, return 0. */
static rtx
instantiate_new_reg (rtx x, HOST_WIDE_INT *poffset)
{
rtx new_rtx;
HOST_WIDE_INT offset;
if (x == virtual_incoming_args_rtx)
{
if (stack_realign_drap)
{
/* Replace virtual_incoming_args_rtx with internal arg
pointer if DRAP is used to realign stack. */
new_rtx = crtl->args.internal_arg_pointer;
offset = 0;
}
else
new_rtx = arg_pointer_rtx, offset = in_arg_offset;
}
else if (x == virtual_stack_vars_rtx)
new_rtx = frame_pointer_rtx, offset = var_offset;
else if (x == virtual_stack_dynamic_rtx)
new_rtx = stack_pointer_rtx, offset = dynamic_offset;
else if (x == virtual_outgoing_args_rtx)
new_rtx = stack_pointer_rtx, offset = out_arg_offset;
else if (x == virtual_cfa_rtx)
{
#ifdef FRAME_POINTER_CFA_OFFSET
new_rtx = frame_pointer_rtx;
#else
new_rtx = arg_pointer_rtx;
#endif
offset = cfa_offset;
}
else if (x == virtual_preferred_stack_boundary_rtx)
{
new_rtx = GEN_INT (crtl->preferred_stack_boundary / BITS_PER_UNIT);
offset = 0;
}
else
return NULL_RTX;
*poffset = offset;
return new_rtx;
}
/* A subroutine of instantiate_virtual_regs, called via for_each_rtx.
Instantiate any virtual registers present inside of *LOC. The expression
is simplified, as much as possible, but is not to be considered "valid"
in any sense implied by the target. If any change is made, set CHANGED
to true. */
static int
instantiate_virtual_regs_in_rtx (rtx *loc, void *data)
{
HOST_WIDE_INT offset;
bool *changed = (bool *) data;
rtx x, new_rtx;
x = *loc;
if (x == 0)
return 0;
switch (GET_CODE (x))
{
case REG:
new_rtx = instantiate_new_reg (x, &offset);
if (new_rtx)
{
*loc = plus_constant (GET_MODE (x), new_rtx, offset);
if (changed)
*changed = true;
}
return -1;
case PLUS:
new_rtx = instantiate_new_reg (XEXP (x, 0), &offset);
if (new_rtx)
{
new_rtx = plus_constant (GET_MODE (x), new_rtx, offset);
*loc = simplify_gen_binary (PLUS, GET_MODE (x), new_rtx, XEXP (x, 1));
if (changed)
*changed = true;
return -1;
}
/* FIXME -- from old code */
/* If we have (plus (subreg (virtual-reg)) (const_int)), we know
we can commute the PLUS and SUBREG because pointers into the
frame are well-behaved. */
break;
default:
break;
}
return 0;
}
/* A subroutine of instantiate_virtual_regs_in_insn. Return true if X
matches the predicate for insn CODE operand OPERAND. */
static int
safe_insn_predicate (int code, int operand, rtx x)
{
return code < 0 || insn_operand_matches ((enum insn_code) code, operand, x);
}
/* A subroutine of instantiate_virtual_regs. Instantiate any virtual
registers present inside of insn. The result will be a valid insn. */
static void
instantiate_virtual_regs_in_insn (rtx insn)
{
HOST_WIDE_INT offset;
int insn_code, i;
bool any_change = false;
rtx set, new_rtx, x, seq;
/* There are some special cases to be handled first. */
set = single_set (insn);
if (set)
{
/* We're allowed to assign to a virtual register. This is interpreted
to mean that the underlying register gets assigned the inverse
transformation. This is used, for example, in the handling of
non-local gotos. */
new_rtx = instantiate_new_reg (SET_DEST (set), &offset);
if (new_rtx)
{
start_sequence ();
for_each_rtx (&SET_SRC (set), instantiate_virtual_regs_in_rtx, NULL);
x = simplify_gen_binary (PLUS, GET_MODE (new_rtx), SET_SRC (set),
gen_int_mode (-offset, GET_MODE (new_rtx)));
x = force_operand (x, new_rtx);
if (x != new_rtx)
emit_move_insn (new_rtx, x);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, insn);
delete_insn (insn);
return;
}
/* Handle a straight copy from a virtual register by generating a
new add insn. The difference between this and falling through
to the generic case is avoiding a new pseudo and eliminating a
move insn in the initial rtl stream. */
new_rtx = instantiate_new_reg (SET_SRC (set), &offset);
if (new_rtx && offset != 0
&& REG_P (SET_DEST (set))
&& REGNO (SET_DEST (set)) > LAST_VIRTUAL_REGISTER)
{
start_sequence ();
x = expand_simple_binop (GET_MODE (SET_DEST (set)), PLUS, new_rtx,
gen_int_mode (offset,
GET_MODE (SET_DEST (set))),
SET_DEST (set), 1, OPTAB_LIB_WIDEN);
if (x != SET_DEST (set))
emit_move_insn (SET_DEST (set), x);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, insn);
delete_insn (insn);
return;
}
extract_insn (insn);
insn_code = INSN_CODE (insn);
/* Handle a plus involving a virtual register by determining if the
operands remain valid if they're modified in place. */
if (GET_CODE (SET_SRC (set)) == PLUS
&& recog_data.n_operands >= 3
&& recog_data.operand_loc[1] == &XEXP (SET_SRC (set), 0)
&& recog_data.operand_loc[2] == &XEXP (SET_SRC (set), 1)
&& CONST_INT_P (recog_data.operand[2])
&& (new_rtx = instantiate_new_reg (recog_data.operand[1], &offset)))
{
offset += INTVAL (recog_data.operand[2]);
/* If the sum is zero, then replace with a plain move. */
if (offset == 0
&& REG_P (SET_DEST (set))
&& REGNO (SET_DEST (set)) > LAST_VIRTUAL_REGISTER)
{
start_sequence ();
emit_move_insn (SET_DEST (set), new_rtx);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, insn);
delete_insn (insn);
return;
}
x = gen_int_mode (offset, recog_data.operand_mode[2]);
/* Using validate_change and apply_change_group here leaves
recog_data in an invalid state. Since we know exactly what
we want to check, do those two by hand. */
if (safe_insn_predicate (insn_code, 1, new_rtx)
&& safe_insn_predicate (insn_code, 2, x))
{
*recog_data.operand_loc[1] = recog_data.operand[1] = new_rtx;
*recog_data.operand_loc[2] = recog_data.operand[2] = x;
any_change = true;
/* Fall through into the regular operand fixup loop in
order to take care of operands other than 1 and 2. */
}
}
}
else
{
extract_insn (insn);
insn_code = INSN_CODE (insn);
}
/* In the general case, we expect virtual registers to appear only in
operands, and then only as either bare registers or inside memories. */
for (i = 0; i < recog_data.n_operands; ++i)
{
x = recog_data.operand[i];
switch (GET_CODE (x))
{
case MEM:
{
rtx addr = XEXP (x, 0);
bool changed = false;
for_each_rtx (&addr, instantiate_virtual_regs_in_rtx, &changed);
if (!changed)
continue;
start_sequence ();
x = replace_equiv_address (x, addr);
/* It may happen that the address with the virtual reg
was valid (e.g. based on the virtual stack reg, which might
be acceptable to the predicates with all offsets), whereas
the address now isn't anymore, for instance when the address
is still offsetted, but the base reg isn't virtual-stack-reg
anymore. Below we would do a force_reg on the whole operand,
but this insn might actually only accept memory. Hence,
before doing that last resort, try to reload the address into
a register, so this operand stays a MEM. */
if (!safe_insn_predicate (insn_code, i, x))
{
addr = force_reg (GET_MODE (addr), addr);
x = replace_equiv_address (x, addr);
}
seq = get_insns ();
end_sequence ();
if (seq)
emit_insn_before (seq, insn);
}
break;
case REG:
new_rtx = instantiate_new_reg (x, &offset);
if (new_rtx == NULL)
continue;
if (offset == 0)
x = new_rtx;
else
{
start_sequence ();
/* Careful, special mode predicates may have stuff in
insn_data[insn_code].operand[i].mode that isn't useful
to us for computing a new value. */
/* ??? Recognize address_operand and/or "p" constraints
to see if (plus new offset) is a valid before we put
this through expand_simple_binop. */
x = expand_simple_binop (GET_MODE (x), PLUS, new_rtx,
gen_int_mode (offset, GET_MODE (x)),
NULL_RTX, 1, OPTAB_LIB_WIDEN);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, insn);
}
break;
case SUBREG:
new_rtx = instantiate_new_reg (SUBREG_REG (x), &offset);
if (new_rtx == NULL)
continue;
if (offset != 0)
{
start_sequence ();
new_rtx = expand_simple_binop
(GET_MODE (new_rtx), PLUS, new_rtx,
gen_int_mode (offset, GET_MODE (new_rtx)),
NULL_RTX, 1, OPTAB_LIB_WIDEN);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, insn);
}
x = simplify_gen_subreg (recog_data.operand_mode[i], new_rtx,
GET_MODE (new_rtx), SUBREG_BYTE (x));
gcc_assert (x);
break;
default:
continue;
}
/* At this point, X contains the new value for the operand.
Validate the new value vs the insn predicate. Note that
asm insns will have insn_code -1 here. */
if (!safe_insn_predicate (insn_code, i, x))
{
start_sequence ();
if (REG_P (x))
{
gcc_assert (REGNO (x) <= LAST_VIRTUAL_REGISTER);
x = copy_to_reg (x);
}
else
x = force_reg (insn_data[insn_code].operand[i].mode, x);
seq = get_insns ();
end_sequence ();
if (seq)
emit_insn_before (seq, insn);
}
*recog_data.operand_loc[i] = recog_data.operand[i] = x;
any_change = true;
}
if (any_change)
{
/* Propagate operand changes into the duplicates. */
for (i = 0; i < recog_data.n_dups; ++i)
*recog_data.dup_loc[i]
= copy_rtx (recog_data.operand[(unsigned)recog_data.dup_num[i]]);
/* Force re-recognition of the instruction for validation. */
INSN_CODE (insn) = -1;
}
if (asm_noperands (PATTERN (insn)) >= 0)
{
if (!check_asm_operands (PATTERN (insn)))
{
error_for_asm (insn, "impossible constraint in %");
/* For asm goto, instead of fixing up all the edges
just clear the template and clear input operands
(asm goto doesn't have any output operands). */
if (JUMP_P (insn))
{
rtx asm_op = extract_asm_operands (PATTERN (insn));
ASM_OPERANDS_TEMPLATE (asm_op) = ggc_strdup ("");
ASM_OPERANDS_INPUT_VEC (asm_op) = rtvec_alloc (0);
ASM_OPERANDS_INPUT_CONSTRAINT_VEC (asm_op) = rtvec_alloc (0);
}
else
delete_insn (insn);
}
}
else
{
if (recog_memoized (insn) < 0)
fatal_insn_not_found (insn);
}
}
/* Subroutine of instantiate_decls. Given RTL representing a decl,
do any instantiation required. */
void
instantiate_decl_rtl (rtx x)
{
rtx addr;
if (x == 0)
return;
/* If this is a CONCAT, recurse for the pieces. */
if (GET_CODE (x) == CONCAT)
{
instantiate_decl_rtl (XEXP (x, 0));
instantiate_decl_rtl (XEXP (x, 1));
return;
}
/* If this is not a MEM, no need to do anything. Similarly if the
address is a constant or a register that is not a virtual register. */
if (!MEM_P (x))
return;
addr = XEXP (x, 0);
if (CONSTANT_P (addr)
|| (REG_P (addr)
&& (REGNO (addr) < FIRST_VIRTUAL_REGISTER
|| REGNO (addr) > LAST_VIRTUAL_REGISTER)))
return;
for_each_rtx (&XEXP (x, 0), instantiate_virtual_regs_in_rtx, NULL);
}
/* Helper for instantiate_decls called via walk_tree: Process all decls
in the given DECL_VALUE_EXPR. */
static tree
instantiate_expr (tree *tp, int *walk_subtrees, void *data ATTRIBUTE_UNUSED)
{
tree t = *tp;
if (! EXPR_P (t))
{
*walk_subtrees = 0;
if (DECL_P (t))
{
if (DECL_RTL_SET_P (t))
instantiate_decl_rtl (DECL_RTL (t));
if (TREE_CODE (t) == PARM_DECL && DECL_NAMELESS (t)
&& DECL_INCOMING_RTL (t))
instantiate_decl_rtl (DECL_INCOMING_RTL (t));
if ((TREE_CODE (t) == VAR_DECL
|| TREE_CODE (t) == RESULT_DECL)
&& DECL_HAS_VALUE_EXPR_P (t))
{
tree v = DECL_VALUE_EXPR (t);
walk_tree (&v, instantiate_expr, NULL, NULL);
}
}
}
return NULL;
}
/* Subroutine of instantiate_decls: Process all decls in the given
BLOCK node and all its subblocks. */
static void
instantiate_decls_1 (tree let)
{
tree t;
for (t = BLOCK_VARS (let); t; t = DECL_CHAIN (t))
{
if (DECL_RTL_SET_P (t))
instantiate_decl_rtl (DECL_RTL (t));
if (TREE_CODE (t) == VAR_DECL && DECL_HAS_VALUE_EXPR_P (t))
{
tree v = DECL_VALUE_EXPR (t);
walk_tree (&v, instantiate_expr, NULL, NULL);
}
}
/* Process all subblocks. */
for (t = BLOCK_SUBBLOCKS (let); t; t = BLOCK_CHAIN (t))
instantiate_decls_1 (t);
}
/* Scan all decls in FNDECL (both variables and parameters) and instantiate
all virtual registers in their DECL_RTL's. */
static void
instantiate_decls (tree fndecl)
{
tree decl;
unsigned ix;
/* Process all parameters of the function. */
for (decl = DECL_ARGUMENTS (fndecl); decl; decl = DECL_CHAIN (decl))
{
instantiate_decl_rtl (DECL_RTL (decl));
instantiate_decl_rtl (DECL_INCOMING_RTL (decl));
if (DECL_HAS_VALUE_EXPR_P (decl))
{
tree v = DECL_VALUE_EXPR (decl);
walk_tree (&v, instantiate_expr, NULL, NULL);
}
}
if ((decl = DECL_RESULT (fndecl))
&& TREE_CODE (decl) == RESULT_DECL)
{
if (DECL_RTL_SET_P (decl))
instantiate_decl_rtl (DECL_RTL (decl));
if (DECL_HAS_VALUE_EXPR_P (decl))
{
tree v = DECL_VALUE_EXPR (decl);
walk_tree (&v, instantiate_expr, NULL, NULL);
}
}
/* Now process all variables defined in the function or its subblocks. */
instantiate_decls_1 (DECL_INITIAL (fndecl));
FOR_EACH_LOCAL_DECL (cfun, ix, decl)
if (DECL_RTL_SET_P (decl))
instantiate_decl_rtl (DECL_RTL (decl));
vec_free (cfun->local_decls);
}
/* Pass through the INSNS of function FNDECL and convert virtual register
references to hard register references. */
static unsigned int
instantiate_virtual_regs (void)
{
rtx insn;
/* Compute the offsets to use for this function. */
in_arg_offset = FIRST_PARM_OFFSET (current_function_decl);
var_offset = STARTING_FRAME_OFFSET;
dynamic_offset = STACK_DYNAMIC_OFFSET (current_function_decl);
out_arg_offset = STACK_POINTER_OFFSET;
#ifdef FRAME_POINTER_CFA_OFFSET
cfa_offset = FRAME_POINTER_CFA_OFFSET (current_function_decl);
#else
cfa_offset = ARG_POINTER_CFA_OFFSET (current_function_decl);
#endif
/* Initialize recognition, indicating that volatile is OK. */
init_recog ();
/* Scan through all the insns, instantiating every virtual register still
present. */
for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
if (INSN_P (insn))
{
/* These patterns in the instruction stream can never be recognized.
Fortunately, they shouldn't contain virtual registers either. */
if (GET_CODE (PATTERN (insn)) == USE
|| GET_CODE (PATTERN (insn)) == CLOBBER
|| GET_CODE (PATTERN (insn)) == ASM_INPUT)
continue;
else if (DEBUG_INSN_P (insn))
for_each_rtx (&INSN_VAR_LOCATION (insn),
instantiate_virtual_regs_in_rtx, NULL);
else
instantiate_virtual_regs_in_insn (insn);
if (INSN_DELETED_P (insn))
continue;
for_each_rtx (®_NOTES (insn), instantiate_virtual_regs_in_rtx, NULL);
/* Instantiate any virtual registers in CALL_INSN_FUNCTION_USAGE. */
if (CALL_P (insn))
for_each_rtx (&CALL_INSN_FUNCTION_USAGE (insn),
instantiate_virtual_regs_in_rtx, NULL);
}
/* Instantiate the virtual registers in the DECLs for debugging purposes. */
instantiate_decls (current_function_decl);
targetm.instantiate_decls ();
/* Indicate that, from now on, assign_stack_local should use
frame_pointer_rtx. */
virtuals_instantiated = 1;
return 0;
}
namespace {
const pass_data pass_data_instantiate_virtual_regs =
{
RTL_PASS, /* type */
"vregs", /* name */
OPTGROUP_NONE, /* optinfo_flags */
false, /* has_gate */
true, /* has_execute */
TV_NONE, /* tv_id */
0, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
0, /* todo_flags_start */
0, /* todo_flags_finish */
};
class pass_instantiate_virtual_regs : public rtl_opt_pass
{
public:
pass_instantiate_virtual_regs (gcc::context *ctxt)
: rtl_opt_pass (pass_data_instantiate_virtual_regs, ctxt)
{}
/* opt_pass methods: */
unsigned int execute () { return instantiate_virtual_regs (); }
}; // class pass_instantiate_virtual_regs
} // anon namespace
rtl_opt_pass *
make_pass_instantiate_virtual_regs (gcc::context *ctxt)
{
return new pass_instantiate_virtual_regs (ctxt);
}
/* Return 1 if EXP is an aggregate type (or a value with aggregate type).
This means a type for which function calls must pass an address to the
function or get an address back from the function.
EXP may be a type node or an expression (whose type is tested). */
int
aggregate_value_p (const_tree exp, const_tree fntype)
{
const_tree type = (TYPE_P (exp)) ? exp : TREE_TYPE (exp);
int i, regno, nregs;
rtx reg;
if (fntype)
switch (TREE_CODE (fntype))
{
case CALL_EXPR:
{
tree fndecl = get_callee_fndecl (fntype);
fntype = (fndecl
? TREE_TYPE (fndecl)
: TREE_TYPE (TREE_TYPE (CALL_EXPR_FN (fntype))));
}
break;
case FUNCTION_DECL:
fntype = TREE_TYPE (fntype);
break;
case FUNCTION_TYPE:
case METHOD_TYPE:
break;
case IDENTIFIER_NODE:
fntype = NULL_TREE;
break;
default:
/* We don't expect other tree types here. */
gcc_unreachable ();
}
if (VOID_TYPE_P (type))
return 0;
/* If a record should be passed the same as its first (and only) member
don't pass it as an aggregate. */
if (TREE_CODE (type) == RECORD_TYPE && TYPE_TRANSPARENT_AGGR (type))
return aggregate_value_p (first_field (type), fntype);
/* If the front end has decided that this needs to be passed by
reference, do so. */
if ((TREE_CODE (exp) == PARM_DECL || TREE_CODE (exp) == RESULT_DECL)
&& DECL_BY_REFERENCE (exp))
return 1;
/* Function types that are TREE_ADDRESSABLE force return in memory. */
if (fntype && TREE_ADDRESSABLE (fntype))
return 1;
/* Types that are TREE_ADDRESSABLE must be constructed in memory,
and thus can't be returned in registers. */
if (TREE_ADDRESSABLE (type))
return 1;
if (flag_pcc_struct_return && AGGREGATE_TYPE_P (type))
return 1;
if (targetm.calls.return_in_memory (type, fntype))
return 1;
/* Make sure we have suitable call-clobbered regs to return
the value in; if not, we must return it in memory. */
reg = hard_function_value (type, 0, fntype, 0);
/* If we have something other than a REG (e.g. a PARALLEL), then assume
it is OK. */
if (!REG_P (reg))
return 0;
regno = REGNO (reg);
nregs = hard_regno_nregs[regno][TYPE_MODE (type)];
for (i = 0; i < nregs; i++)
if (! call_used_regs[regno + i])
return 1;
return 0;
}
/* Return true if we should assign DECL a pseudo register; false if it
should live on the local stack. */
bool
use_register_for_decl (const_tree decl)
{
if (!targetm.calls.allocate_stack_slots_for_args ())
return true;
/* Honor volatile. */
if (TREE_SIDE_EFFECTS (decl))
return false;
/* Honor addressability. */
if (TREE_ADDRESSABLE (decl))
return false;
/* Only register-like things go in registers. */
if (DECL_MODE (decl) == BLKmode)
return false;
/* If -ffloat-store specified, don't put explicit float variables
into registers. */
/* ??? This should be checked after DECL_ARTIFICIAL, but tree-ssa
propagates values across these stores, and it probably shouldn't. */
if (flag_float_store && FLOAT_TYPE_P (TREE_TYPE (decl)))
return false;
/* If we're not interested in tracking debugging information for
this decl, then we can certainly put it in a register. */
if (DECL_IGNORED_P (decl))
return true;
if (optimize)
return true;
if (!DECL_REGISTER (decl))
return false;
switch (TREE_CODE (TREE_TYPE (decl)))
{
case RECORD_TYPE:
case UNION_TYPE:
case QUAL_UNION_TYPE:
/* When not optimizing, disregard register keyword for variables with
types containing methods, otherwise the methods won't be callable
from the debugger. */
if (TYPE_METHODS (TREE_TYPE (decl)))
return false;
break;
default:
break;
}
return true;
}
/* Return true if TYPE should be passed by invisible reference. */
bool
pass_by_reference (CUMULATIVE_ARGS *ca, enum machine_mode mode,
tree type, bool named_arg)
{
if (type)
{
/* If this type contains non-trivial constructors, then it is
forbidden for the middle-end to create any new copies. */
if (TREE_ADDRESSABLE (type))
return true;
/* GCC post 3.4 passes *all* variable sized types by reference. */
if (!TYPE_SIZE (type) || TREE_CODE (TYPE_SIZE (type)) != INTEGER_CST)
return true;
/* If a record type should be passed the same as its first (and only)
member, use the type and mode of that member. */
if (TREE_CODE (type) == RECORD_TYPE && TYPE_TRANSPARENT_AGGR (type))
{
type = TREE_TYPE (first_field (type));
mode = TYPE_MODE (type);
}
}
return targetm.calls.pass_by_reference (pack_cumulative_args (ca), mode,
type, named_arg);
}
/* Return true if TYPE, which is passed by reference, should be callee
copied instead of caller copied. */
bool
reference_callee_copied (CUMULATIVE_ARGS *ca, enum machine_mode mode,
tree type, bool named_arg)
{
if (type && TREE_ADDRESSABLE (type))
return false;
return targetm.calls.callee_copies (pack_cumulative_args (ca), mode, type,
named_arg);
}
/* Structures to communicate between the subroutines of assign_parms.
The first holds data persistent across all parameters, the second
is cleared out for each parameter. */
struct assign_parm_data_all
{
/* When INIT_CUMULATIVE_ARGS gets revamped, allocating CUMULATIVE_ARGS
should become a job of the target or otherwise encapsulated. */
CUMULATIVE_ARGS args_so_far_v;
cumulative_args_t args_so_far;
struct args_size stack_args_size;
tree function_result_decl;
tree orig_fnargs;
rtx first_conversion_insn;
rtx last_conversion_insn;
HOST_WIDE_INT pretend_args_size;
HOST_WIDE_INT extra_pretend_bytes;
int reg_parm_stack_space;
};
struct assign_parm_data_one
{
tree nominal_type;
tree passed_type;
rtx entry_parm;
rtx stack_parm;
enum machine_mode nominal_mode;
enum machine_mode passed_mode;
enum machine_mode promoted_mode;
struct locate_and_pad_arg_data locate;
int partial;
BOOL_BITFIELD named_arg : 1;
BOOL_BITFIELD passed_pointer : 1;
BOOL_BITFIELD on_stack : 1;
BOOL_BITFIELD loaded_in_reg : 1;
};
/* A subroutine of assign_parms. Initialize ALL. */
static void
assign_parms_initialize_all (struct assign_parm_data_all *all)
{
tree fntype ATTRIBUTE_UNUSED;
memset (all, 0, sizeof (*all));
fntype = TREE_TYPE (current_function_decl);
#ifdef INIT_CUMULATIVE_INCOMING_ARGS
INIT_CUMULATIVE_INCOMING_ARGS (all->args_so_far_v, fntype, NULL_RTX);
#else
INIT_CUMULATIVE_ARGS (all->args_so_far_v, fntype, NULL_RTX,
current_function_decl, -1);
#endif
all->args_so_far = pack_cumulative_args (&all->args_so_far_v);
#ifdef REG_PARM_STACK_SPACE
all->reg_parm_stack_space = REG_PARM_STACK_SPACE (current_function_decl);
#endif
}
/* If ARGS contains entries with complex types, split the entry into two
entries of the component type. Return a new list of substitutions are
needed, else the old list. */
static void
split_complex_args (vec *args)
{
unsigned i;
tree p;
FOR_EACH_VEC_ELT (*args, i, p)
{
tree type = TREE_TYPE (p);
if (TREE_CODE (type) == COMPLEX_TYPE
&& targetm.calls.split_complex_arg (type))
{
tree decl;
tree subtype = TREE_TYPE (type);
bool addressable = TREE_ADDRESSABLE (p);
/* Rewrite the PARM_DECL's type with its component. */
p = copy_node (p);
TREE_TYPE (p) = subtype;
DECL_ARG_TYPE (p) = TREE_TYPE (DECL_ARG_TYPE (p));
DECL_MODE (p) = VOIDmode;
DECL_SIZE (p) = NULL;
DECL_SIZE_UNIT (p) = NULL;
/* If this arg must go in memory, put it in a pseudo here.
We can't allow it to go in memory as per normal parms,
because the usual place might not have the imag part
adjacent to the real part. */
DECL_ARTIFICIAL (p) = addressable;
DECL_IGNORED_P (p) = addressable;
TREE_ADDRESSABLE (p) = 0;
layout_decl (p, 0);
(*args)[i] = p;
/* Build a second synthetic decl. */
decl = build_decl (EXPR_LOCATION (p),
PARM_DECL, NULL_TREE, subtype);
DECL_ARG_TYPE (decl) = DECL_ARG_TYPE (p);
DECL_ARTIFICIAL (decl) = addressable;
DECL_IGNORED_P (decl) = addressable;
layout_decl (decl, 0);
args->safe_insert (++i, decl);
}
}
}
/* A subroutine of assign_parms. Adjust the parameter list to incorporate
the hidden struct return argument, and (abi willing) complex args.
Return the new parameter list. */
static vec
assign_parms_augmented_arg_list (struct assign_parm_data_all *all)
{
tree fndecl = current_function_decl;
tree fntype = TREE_TYPE (fndecl);
vec fnargs = vNULL;
tree arg;
for (arg = DECL_ARGUMENTS (fndecl); arg; arg = DECL_CHAIN (arg))
fnargs.safe_push (arg);
all->orig_fnargs = DECL_ARGUMENTS (fndecl);
/* If struct value address is treated as the first argument, make it so. */
if (aggregate_value_p (DECL_RESULT (fndecl), fndecl)
&& ! cfun->returns_pcc_struct
&& targetm.calls.struct_value_rtx (TREE_TYPE (fndecl), 1) == 0)
{
tree type = build_pointer_type (TREE_TYPE (fntype));
tree decl;
decl = build_decl (DECL_SOURCE_LOCATION (fndecl),
PARM_DECL, get_identifier (".result_ptr"), type);
DECL_ARG_TYPE (decl) = type;
DECL_ARTIFICIAL (decl) = 1;
DECL_NAMELESS (decl) = 1;
TREE_CONSTANT (decl) = 1;
DECL_CHAIN (decl) = all->orig_fnargs;
all->orig_fnargs = decl;
fnargs.safe_insert (0, decl);
all->function_result_decl = decl;
}
/* If the target wants to split complex arguments into scalars, do so. */
if (targetm.calls.split_complex_arg)
split_complex_args (&fnargs);
return fnargs;
}
/* A subroutine of assign_parms. Examine PARM and pull out type and mode
data for the parameter. Incorporate ABI specifics such as pass-by-
reference and type promotion. */
static void
assign_parm_find_data_types (struct assign_parm_data_all *all, tree parm,
struct assign_parm_data_one *data)
{
tree nominal_type, passed_type;
enum machine_mode nominal_mode, passed_mode, promoted_mode;
int unsignedp;
memset (data, 0, sizeof (*data));
/* NAMED_ARG is a misnomer. We really mean 'non-variadic'. */
if (!cfun->stdarg)
data->named_arg = 1; /* No variadic parms. */
else if (DECL_CHAIN (parm))
data->named_arg = 1; /* Not the last non-variadic parm. */
else if (targetm.calls.strict_argument_naming (all->args_so_far))
data->named_arg = 1; /* Only variadic ones are unnamed. */
else
data->named_arg = 0; /* Treat as variadic. */
nominal_type = TREE_TYPE (parm);
passed_type = DECL_ARG_TYPE (parm);
/* Look out for errors propagating this far. Also, if the parameter's
type is void then its value doesn't matter. */
if (TREE_TYPE (parm) == error_mark_node
/* This can happen after weird syntax errors
or if an enum type is defined among the parms. */
|| TREE_CODE (parm) != PARM_DECL
|| passed_type == NULL
|| VOID_TYPE_P (nominal_type))
{
nominal_type = passed_type = void_type_node;
nominal_mode = passed_mode = promoted_mode = VOIDmode;
goto egress;
}
/* Find mode of arg as it is passed, and mode of arg as it should be
during execution of this function. */
passed_mode = TYPE_MODE (passed_type);
nominal_mode = TYPE_MODE (nominal_type);
/* If the parm is to be passed as a transparent union or record, use the
type of the first field for the tests below. We have already verified
that the modes are the same. */
if ((TREE_CODE (passed_type) == UNION_TYPE
|| TREE_CODE (passed_type) == RECORD_TYPE)
&& TYPE_TRANSPARENT_AGGR (passed_type))
passed_type = TREE_TYPE (first_field (passed_type));
/* See if this arg was passed by invisible reference. */
if (pass_by_reference (&all->args_so_far_v, passed_mode,
passed_type, data->named_arg))
{
passed_type = nominal_type = build_pointer_type (passed_type);
data->passed_pointer = true;
passed_mode = nominal_mode = TYPE_MODE (nominal_type);
}
/* Find mode as it is passed by the ABI. */
unsignedp = TYPE_UNSIGNED (passed_type);
promoted_mode = promote_function_mode (passed_type, passed_mode, &unsignedp,
TREE_TYPE (current_function_decl), 0);
egress:
data->nominal_type = nominal_type;
data->passed_type = passed_type;
data->nominal_mode = nominal_mode;
data->passed_mode = passed_mode;
data->promoted_mode = promoted_mode;
}
/* A subroutine of assign_parms. Invoke setup_incoming_varargs. */
static void
assign_parms_setup_varargs (struct assign_parm_data_all *all,
struct assign_parm_data_one *data, bool no_rtl)
{
int varargs_pretend_bytes = 0;
targetm.calls.setup_incoming_varargs (all->args_so_far,
data->promoted_mode,
data->passed_type,
&varargs_pretend_bytes, no_rtl);
/* If the back-end has requested extra stack space, record how much is
needed. Do not change pretend_args_size otherwise since it may be
nonzero from an earlier partial argument. */
if (varargs_pretend_bytes > 0)
all->pretend_args_size = varargs_pretend_bytes;
}
/* A subroutine of assign_parms. Set DATA->ENTRY_PARM corresponding to
the incoming location of the current parameter. */
static void
assign_parm_find_entry_rtl (struct assign_parm_data_all *all,
struct assign_parm_data_one *data)
{
HOST_WIDE_INT pretend_bytes = 0;
rtx entry_parm;
bool in_regs;
if (data->promoted_mode == VOIDmode)
{
data->entry_parm = data->stack_parm = const0_rtx;
return;
}
entry_parm = targetm.calls.function_incoming_arg (all->args_so_far,
data->promoted_mode,
data->passed_type,
data->named_arg);
if (entry_parm == 0)
data->promoted_mode = data->passed_mode;
/* Determine parm's home in the stack, in case it arrives in the stack
or we should pretend it did. Compute the stack position and rtx where
the argument arrives and its size.
There is one complexity here: If this was a parameter that would
have been passed in registers, but wasn't only because it is
__builtin_va_alist, we want locate_and_pad_parm to treat it as if
it came in a register so that REG_PARM_STACK_SPACE isn't skipped.
In this case, we call FUNCTION_ARG with NAMED set to 1 instead of 0
as it was the previous time. */
in_regs = entry_parm != 0;
#ifdef STACK_PARMS_IN_REG_PARM_AREA
in_regs = true;
#endif
if (!in_regs && !data->named_arg)
{
if (targetm.calls.pretend_outgoing_varargs_named (all->args_so_far))
{
rtx tem;
tem = targetm.calls.function_incoming_arg (all->args_so_far,
data->promoted_mode,
data->passed_type, true);
in_regs = tem != NULL;
}
}
/* If this parameter was passed both in registers and in the stack, use
the copy on the stack. */
if (targetm.calls.must_pass_in_stack (data->promoted_mode,
data->passed_type))
entry_parm = 0;
if (entry_parm)
{
int partial;
partial = targetm.calls.arg_partial_bytes (all->args_so_far,
data->promoted_mode,
data->passed_type,
data->named_arg);
data->partial = partial;
/* The caller might already have allocated stack space for the
register parameters. */
if (partial != 0 && all->reg_parm_stack_space == 0)
{
/* Part of this argument is passed in registers and part
is passed on the stack. Ask the prologue code to extend
the stack part so that we can recreate the full value.
PRETEND_BYTES is the size of the registers we need to store.
CURRENT_FUNCTION_PRETEND_ARGS_SIZE is the amount of extra
stack space that the prologue should allocate.
Internally, gcc assumes that the argument pointer is aligned
to STACK_BOUNDARY bits. This is used both for alignment
optimizations (see init_emit) and to locate arguments that are
aligned to more than PARM_BOUNDARY bits. We must preserve this
invariant by rounding CURRENT_FUNCTION_PRETEND_ARGS_SIZE up to
a stack boundary. */
/* We assume at most one partial arg, and it must be the first
argument on the stack. */
gcc_assert (!all->extra_pretend_bytes && !all->pretend_args_size);
pretend_bytes = partial;
all->pretend_args_size = CEIL_ROUND (pretend_bytes, STACK_BYTES);
/* We want to align relative to the actual stack pointer, so
don't include this in the stack size until later. */
all->extra_pretend_bytes = all->pretend_args_size;
}
}
locate_and_pad_parm (data->promoted_mode, data->passed_type, in_regs,
all->reg_parm_stack_space,
entry_parm ? data->partial : 0, current_function_decl,
&all->stack_args_size, &data->locate);
/* Update parm_stack_boundary if this parameter is passed in the
stack. */
if (!in_regs && crtl->parm_stack_boundary < data->locate.boundary)
crtl->parm_stack_boundary = data->locate.boundary;
/* Adjust offsets to include the pretend args. */
pretend_bytes = all->extra_pretend_bytes - pretend_bytes;
data->locate.slot_offset.constant += pretend_bytes;
data->locate.offset.constant += pretend_bytes;
data->entry_parm = entry_parm;
}
/* A subroutine of assign_parms. If there is actually space on the stack
for this parm, count it in stack_args_size and return true. */
static bool
assign_parm_is_stack_parm (struct assign_parm_data_all *all,
struct assign_parm_data_one *data)
{
/* Trivially true if we've no incoming register. */
if (data->entry_parm == NULL)
;
/* Also true if we're partially in registers and partially not,
since we've arranged to drop the entire argument on the stack. */
else if (data->partial != 0)
;
/* Also true if the target says that it's passed in both registers
and on the stack. */
else if (GET_CODE (data->entry_parm) == PARALLEL
&& XEXP (XVECEXP (data->entry_parm, 0, 0), 0) == NULL_RTX)
;
/* Also true if the target says that there's stack allocated for
all register parameters. */
else if (all->reg_parm_stack_space > 0)
;
/* Otherwise, no, this parameter has no ABI defined stack slot. */
else
return false;
all->stack_args_size.constant += data->locate.size.constant;
if (data->locate.size.var)
ADD_PARM_SIZE (all->stack_args_size, data->locate.size.var);
return true;
}
/* A subroutine of assign_parms. Given that this parameter is allocated
stack space by the ABI, find it. */
static void
assign_parm_find_stack_rtl (tree parm, struct assign_parm_data_one *data)
{
rtx offset_rtx, stack_parm;
unsigned int align, boundary;
/* If we're passing this arg using a reg, make its stack home the
aligned stack slot. */
if (data->entry_parm)
offset_rtx = ARGS_SIZE_RTX (data->locate.slot_offset);
else
offset_rtx = ARGS_SIZE_RTX (data->locate.offset);
stack_parm = crtl->args.internal_arg_pointer;
if (offset_rtx != const0_rtx)
stack_parm = gen_rtx_PLUS (Pmode, stack_parm, offset_rtx);
stack_parm = gen_rtx_MEM (data->promoted_mode, stack_parm);
if (!data->passed_pointer)
{
set_mem_attributes (stack_parm, parm, 1);
/* set_mem_attributes could set MEM_SIZE to the passed mode's size,
while promoted mode's size is needed. */
if (data->promoted_mode != BLKmode
&& data->promoted_mode != DECL_MODE (parm))
{
set_mem_size (stack_parm, GET_MODE_SIZE (data->promoted_mode));
if (MEM_EXPR (stack_parm) && MEM_OFFSET_KNOWN_P (stack_parm))
{
int offset = subreg_lowpart_offset (DECL_MODE (parm),
data->promoted_mode);
if (offset)
set_mem_offset (stack_parm, MEM_OFFSET (stack_parm) - offset);
}
}
}
boundary = data->locate.boundary;
align = BITS_PER_UNIT;
/* If we're padding upward, we know that the alignment of the slot
is TARGET_FUNCTION_ARG_BOUNDARY. If we're using slot_offset, we're
intentionally forcing upward padding. Otherwise we have to come
up with a guess at the alignment based on OFFSET_RTX. */
if (data->locate.where_pad != downward || data->entry_parm)
align = boundary;
else if (CONST_INT_P (offset_rtx))
{
align = INTVAL (offset_rtx) * BITS_PER_UNIT | boundary;
align = align & -align;
}
set_mem_align (stack_parm, align);
if (data->entry_parm)
set_reg_attrs_for_parm (data->entry_parm, stack_parm);
data->stack_parm = stack_parm;
}
/* A subroutine of assign_parms. Adjust DATA->ENTRY_RTL such that it's
always valid and contiguous. */
static void
assign_parm_adjust_entry_rtl (struct assign_parm_data_one *data)
{
rtx entry_parm = data->entry_parm;
rtx stack_parm = data->stack_parm;
/* If this parm was passed part in regs and part in memory, pretend it
arrived entirely in memory by pushing the register-part onto the stack.
In the special case of a DImode or DFmode that is split, we could put
it together in a pseudoreg directly, but for now that's not worth
bothering with. */
if (data->partial != 0)
{
/* Handle calls that pass values in multiple non-contiguous
locations. The Irix 6 ABI has examples of this. */
if (GET_CODE (entry_parm) == PARALLEL)
emit_group_store (validize_mem (stack_parm), entry_parm,
data->passed_type,
int_size_in_bytes (data->passed_type));
else
{
gcc_assert (data->partial % UNITS_PER_WORD == 0);
move_block_from_reg (REGNO (entry_parm), validize_mem (stack_parm),
data->partial / UNITS_PER_WORD);
}
entry_parm = stack_parm;
}
/* If we didn't decide this parm came in a register, by default it came
on the stack. */
else if (entry_parm == NULL)
entry_parm = stack_parm;
/* When an argument is passed in multiple locations, we can't make use
of this information, but we can save some copying if the whole argument
is passed in a single register. */
else if (GET_CODE (entry_parm) == PARALLEL
&& data->nominal_mode != BLKmode
&& data->passed_mode != BLKmode)
{
size_t i, len = XVECLEN (entry_parm, 0);
for (i = 0; i < len; i++)
if (XEXP (XVECEXP (entry_parm, 0, i), 0) != NULL_RTX
&& REG_P (XEXP (XVECEXP (entry_parm, 0, i), 0))
&& (GET_MODE (XEXP (XVECEXP (entry_parm, 0, i), 0))
== data->passed_mode)
&& INTVAL (XEXP (XVECEXP (entry_parm, 0, i), 1)) == 0)
{
entry_parm = XEXP (XVECEXP (entry_parm, 0, i), 0);
break;
}
}
data->entry_parm = entry_parm;
}
/* A subroutine of assign_parms. Reconstitute any values which were
passed in multiple registers and would fit in a single register. */
static void
assign_parm_remove_parallels (struct assign_parm_data_one *data)
{
rtx entry_parm = data->entry_parm;
/* Convert the PARALLEL to a REG of the same mode as the parallel.
This can be done with register operations rather than on the
stack, even if we will store the reconstituted parameter on the
stack later. */
if (GET_CODE (entry_parm) == PARALLEL && GET_MODE (entry_parm) != BLKmode)
{
rtx parmreg = gen_reg_rtx (GET_MODE (entry_parm));
emit_group_store (parmreg, entry_parm, data->passed_type,
GET_MODE_SIZE (GET_MODE (entry_parm)));
entry_parm = parmreg;
}
data->entry_parm = entry_parm;
}
/* A subroutine of assign_parms. Adjust DATA->STACK_RTL such that it's
always valid and properly aligned. */
static void
assign_parm_adjust_stack_rtl (struct assign_parm_data_one *data)
{
rtx stack_parm = data->stack_parm;
/* If we can't trust the parm stack slot to be aligned enough for its
ultimate type, don't use that slot after entry. We'll make another
stack slot, if we need one. */
if (stack_parm
&& ((STRICT_ALIGNMENT
&& GET_MODE_ALIGNMENT (data->nominal_mode) > MEM_ALIGN (stack_parm))
|| (data->nominal_type
&& TYPE_ALIGN (data->nominal_type) > MEM_ALIGN (stack_parm)
&& MEM_ALIGN (stack_parm) < PREFERRED_STACK_BOUNDARY)))
stack_parm = NULL;
/* If parm was passed in memory, and we need to convert it on entry,
don't store it back in that same slot. */
else if (data->entry_parm == stack_parm
&& data->nominal_mode != BLKmode
&& data->nominal_mode != data->passed_mode)
stack_parm = NULL;
/* If stack protection is in effect for this function, don't leave any
pointers in their passed stack slots. */
else if (crtl->stack_protect_guard
&& (flag_stack_protect == 2
|| data->passed_pointer
|| POINTER_TYPE_P (data->nominal_type)))
stack_parm = NULL;
data->stack_parm = stack_parm;
}
/* A subroutine of assign_parms. Return true if the current parameter
should be stored as a BLKmode in the current frame. */
static bool
assign_parm_setup_block_p (struct assign_parm_data_one *data)
{
if (data->nominal_mode == BLKmode)
return true;
if (GET_MODE (data->entry_parm) == BLKmode)
return true;
#ifdef BLOCK_REG_PADDING
/* Only assign_parm_setup_block knows how to deal with register arguments
that are padded at the least significant end. */
if (REG_P (data->entry_parm)
&& GET_MODE_SIZE (data->promoted_mode) < UNITS_PER_WORD
&& (BLOCK_REG_PADDING (data->passed_mode, data->passed_type, 1)
== (BYTES_BIG_ENDIAN ? upward : downward)))
return true;
#endif
return false;
}
/* A subroutine of assign_parms. Arrange for the parameter to be
present and valid in DATA->STACK_RTL. */
static void
assign_parm_setup_block (struct assign_parm_data_all *all,
tree parm, struct assign_parm_data_one *data)
{
rtx entry_parm = data->entry_parm;
rtx stack_parm = data->stack_parm;
HOST_WIDE_INT size;
HOST_WIDE_INT size_stored;
if (GET_CODE (entry_parm) == PARALLEL)
entry_parm = emit_group_move_into_temps (entry_parm);
size = int_size_in_bytes (data->passed_type);
size_stored = CEIL_ROUND (size, UNITS_PER_WORD);
if (stack_parm == 0)
{
DECL_ALIGN (parm) = MAX (DECL_ALIGN (parm), BITS_PER_WORD);
stack_parm = assign_stack_local (BLKmode, size_stored,
DECL_ALIGN (parm));
if (GET_MODE_SIZE (GET_MODE (entry_parm)) == size)
PUT_MODE (stack_parm, GET_MODE (entry_parm));
set_mem_attributes (stack_parm, parm, 1);
}
/* If a BLKmode arrives in registers, copy it to a stack slot. Handle
calls that pass values in multiple non-contiguous locations. */
if (REG_P (entry_parm) || GET_CODE (entry_parm) == PARALLEL)
{
rtx mem;
/* Note that we will be storing an integral number of words.
So we have to be careful to ensure that we allocate an
integral number of words. We do this above when we call
assign_stack_local if space was not allocated in the argument
list. If it was, this will not work if PARM_BOUNDARY is not
a multiple of BITS_PER_WORD. It isn't clear how to fix this
if it becomes a problem. Exception is when BLKmode arrives
with arguments not conforming to word_mode. */
if (data->stack_parm == 0)
;
else if (GET_CODE (entry_parm) == PARALLEL)
;
else
gcc_assert (!size || !(PARM_BOUNDARY % BITS_PER_WORD));
mem = validize_mem (stack_parm);
/* Handle values in multiple non-contiguous locations. */
if (GET_CODE (entry_parm) == PARALLEL)
{
push_to_sequence2 (all->first_conversion_insn,
all->last_conversion_insn);
emit_group_store (mem, entry_parm, data->passed_type, size);
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
}
else if (size == 0)
;
/* If SIZE is that of a mode no bigger than a word, just use
that mode's store operation. */
else if (size <= UNITS_PER_WORD)
{
enum machine_mode mode
= mode_for_size (size * BITS_PER_UNIT, MODE_INT, 0);
if (mode != BLKmode
#ifdef BLOCK_REG_PADDING
&& (size == UNITS_PER_WORD
|| (BLOCK_REG_PADDING (mode, data->passed_type, 1)
!= (BYTES_BIG_ENDIAN ? upward : downward)))
#endif
)
{
rtx reg;
/* We are really truncating a word_mode value containing
SIZE bytes into a value of mode MODE. If such an
operation requires no actual instructions, we can refer
to the value directly in mode MODE, otherwise we must
start with the register in word_mode and explicitly
convert it. */
if (TRULY_NOOP_TRUNCATION (size * BITS_PER_UNIT, BITS_PER_WORD))
reg = gen_rtx_REG (mode, REGNO (entry_parm));
else
{
reg = gen_rtx_REG (word_mode, REGNO (entry_parm));
reg = convert_to_mode (mode, copy_to_reg (reg), 1);
}
emit_move_insn (change_address (mem, mode, 0), reg);
}
/* Blocks smaller than a word on a BYTES_BIG_ENDIAN
machine must be aligned to the left before storing
to memory. Note that the previous test doesn't
handle all cases (e.g. SIZE == 3). */
else if (size != UNITS_PER_WORD
#ifdef BLOCK_REG_PADDING
&& (BLOCK_REG_PADDING (mode, data->passed_type, 1)
== downward)
#else
&& BYTES_BIG_ENDIAN
#endif
)
{
rtx tem, x;
int by = (UNITS_PER_WORD - size) * BITS_PER_UNIT;
rtx reg = gen_rtx_REG (word_mode, REGNO (entry_parm));
x = expand_shift (LSHIFT_EXPR, word_mode, reg, by, NULL_RTX, 1);
tem = change_address (mem, word_mode, 0);
emit_move_insn (tem, x);
}
else
move_block_from_reg (REGNO (entry_parm), mem,
size_stored / UNITS_PER_WORD);
}
else
move_block_from_reg (REGNO (entry_parm), mem,
size_stored / UNITS_PER_WORD);
}
else if (data->stack_parm == 0)
{
push_to_sequence2 (all->first_conversion_insn, all->last_conversion_insn);
emit_block_move (stack_parm, data->entry_parm, GEN_INT (size),
BLOCK_OP_NORMAL);
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
}
data->stack_parm = stack_parm;
SET_DECL_RTL (parm, stack_parm);
}
/* A subroutine of assign_parms. Allocate a pseudo to hold the current
parameter. Get it there. Perform all ABI specified conversions. */
static void
assign_parm_setup_reg (struct assign_parm_data_all *all, tree parm,
struct assign_parm_data_one *data)
{
rtx parmreg, validated_mem;
rtx equiv_stack_parm;
enum machine_mode promoted_nominal_mode;
int unsignedp = TYPE_UNSIGNED (TREE_TYPE (parm));
bool did_conversion = false;
bool need_conversion, moved;
/* Store the parm in a pseudoregister during the function, but we may
need to do it in a wider mode. Using 2 here makes the result
consistent with promote_decl_mode and thus expand_expr_real_1. */
promoted_nominal_mode
= promote_function_mode (data->nominal_type, data->nominal_mode, &unsignedp,
TREE_TYPE (current_function_decl), 2);
parmreg = gen_reg_rtx (promoted_nominal_mode);
if (!DECL_ARTIFICIAL (parm))
mark_user_reg (parmreg);
/* If this was an item that we received a pointer to,
set DECL_RTL appropriately. */
if (data->passed_pointer)
{
rtx x = gen_rtx_MEM (TYPE_MODE (TREE_TYPE (data->passed_type)), parmreg);
set_mem_attributes (x, parm, 1);
SET_DECL_RTL (parm, x);
}
else
SET_DECL_RTL (parm, parmreg);
assign_parm_remove_parallels (data);
/* Copy the value into the register, thus bridging between
assign_parm_find_data_types and expand_expr_real_1. */
equiv_stack_parm = data->stack_parm;
validated_mem = validize_mem (data->entry_parm);
need_conversion = (data->nominal_mode != data->passed_mode
|| promoted_nominal_mode != data->promoted_mode);
moved = false;
if (need_conversion
&& GET_MODE_CLASS (data->nominal_mode) == MODE_INT
&& data->nominal_mode == data->passed_mode
&& data->nominal_mode == GET_MODE (data->entry_parm))
{
/* ENTRY_PARM has been converted to PROMOTED_MODE, its
mode, by the caller. We now have to convert it to
NOMINAL_MODE, if different. However, PARMREG may be in
a different mode than NOMINAL_MODE if it is being stored
promoted.
If ENTRY_PARM is a hard register, it might be in a register
not valid for operating in its mode (e.g., an odd-numbered
register for a DFmode). In that case, moves are the only
thing valid, so we can't do a convert from there. This
occurs when the calling sequence allow such misaligned
usages.
In addition, the conversion may involve a call, which could
clobber parameters which haven't been copied to pseudo
registers yet.
First, we try to emit an insn which performs the necessary
conversion. We verify that this insn does not clobber any
hard registers. */
enum insn_code icode;
rtx op0, op1;
icode = can_extend_p (promoted_nominal_mode, data->passed_mode,
unsignedp);
op0 = parmreg;
op1 = validated_mem;
if (icode != CODE_FOR_nothing
&& insn_operand_matches (icode, 0, op0)
&& insn_operand_matches (icode, 1, op1))
{
enum rtx_code code = unsignedp ? ZERO_EXTEND : SIGN_EXTEND;
rtx insn, insns, t = op1;
HARD_REG_SET hardregs;
start_sequence ();
/* If op1 is a hard register that is likely spilled, first
force it into a pseudo, otherwise combiner might extend
its lifetime too much. */
if (GET_CODE (t) == SUBREG)
t = SUBREG_REG (t);
if (REG_P (t)
&& HARD_REGISTER_P (t)
&& ! TEST_HARD_REG_BIT (fixed_reg_set, REGNO (t))
&& targetm.class_likely_spilled_p (REGNO_REG_CLASS (REGNO (t))))
{
t = gen_reg_rtx (GET_MODE (op1));
emit_move_insn (t, op1);
}
else
t = op1;
insn = gen_extend_insn (op0, t, promoted_nominal_mode,
data->passed_mode, unsignedp);
emit_insn (insn);
insns = get_insns ();
moved = true;
CLEAR_HARD_REG_SET (hardregs);
for (insn = insns; insn && moved; insn = NEXT_INSN (insn))
{
if (INSN_P (insn))
note_stores (PATTERN (insn), record_hard_reg_sets,
&hardregs);
if (!hard_reg_set_empty_p (hardregs))
moved = false;
}
end_sequence ();
if (moved)
{
emit_insn (insns);
if (equiv_stack_parm != NULL_RTX)
equiv_stack_parm = gen_rtx_fmt_e (code, GET_MODE (parmreg),
equiv_stack_parm);
}
}
}
if (moved)
/* Nothing to do. */
;
else if (need_conversion)
{
/* We did not have an insn to convert directly, or the sequence
generated appeared unsafe. We must first copy the parm to a
pseudo reg, and save the conversion until after all
parameters have been moved. */
int save_tree_used;
rtx tempreg = gen_reg_rtx (GET_MODE (data->entry_parm));
emit_move_insn (tempreg, validated_mem);
push_to_sequence2 (all->first_conversion_insn, all->last_conversion_insn);
tempreg = convert_to_mode (data->nominal_mode, tempreg, unsignedp);
if (GET_CODE (tempreg) == SUBREG
&& GET_MODE (tempreg) == data->nominal_mode
&& REG_P (SUBREG_REG (tempreg))
&& data->nominal_mode == data->passed_mode
&& GET_MODE (SUBREG_REG (tempreg)) == GET_MODE (data->entry_parm)
&& GET_MODE_SIZE (GET_MODE (tempreg))
< GET_MODE_SIZE (GET_MODE (data->entry_parm)))
{
/* The argument is already sign/zero extended, so note it
into the subreg. */
SUBREG_PROMOTED_VAR_P (tempreg) = 1;
SUBREG_PROMOTED_UNSIGNED_SET (tempreg, unsignedp);
}
/* TREE_USED gets set erroneously during expand_assignment. */
save_tree_used = TREE_USED (parm);
expand_assignment (parm, make_tree (data->nominal_type, tempreg), false);
TREE_USED (parm) = save_tree_used;
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
did_conversion = true;
}
else
emit_move_insn (parmreg, validated_mem);
/* If we were passed a pointer but the actual value can safely live
in a register, retrieve it and use it directly. */
if (data->passed_pointer && TYPE_MODE (TREE_TYPE (parm)) != BLKmode)
{
/* We can't use nominal_mode, because it will have been set to
Pmode above. We must use the actual mode of the parm. */
if (use_register_for_decl (parm))
{
parmreg = gen_reg_rtx (TYPE_MODE (TREE_TYPE (parm)));
mark_user_reg (parmreg);
}
else
{
int align = STACK_SLOT_ALIGNMENT (TREE_TYPE (parm),
TYPE_MODE (TREE_TYPE (parm)),
TYPE_ALIGN (TREE_TYPE (parm)));
parmreg
= assign_stack_local (TYPE_MODE (TREE_TYPE (parm)),
GET_MODE_SIZE (TYPE_MODE (TREE_TYPE (parm))),
align);
set_mem_attributes (parmreg, parm, 1);
}
if (GET_MODE (parmreg) != GET_MODE (DECL_RTL (parm)))
{
rtx tempreg = gen_reg_rtx (GET_MODE (DECL_RTL (parm)));
int unsigned_p = TYPE_UNSIGNED (TREE_TYPE (parm));
push_to_sequence2 (all->first_conversion_insn,
all->last_conversion_insn);
emit_move_insn (tempreg, DECL_RTL (parm));
tempreg = convert_to_mode (GET_MODE (parmreg), tempreg, unsigned_p);
emit_move_insn (parmreg, tempreg);
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
did_conversion = true;
}
else
emit_move_insn (parmreg, DECL_RTL (parm));
SET_DECL_RTL (parm, parmreg);
/* STACK_PARM is the pointer, not the parm, and PARMREG is
now the parm. */
data->stack_parm = NULL;
}
/* Mark the register as eliminable if we did no conversion and it was
copied from memory at a fixed offset, and the arg pointer was not
copied to a pseudo-reg. If the arg pointer is a pseudo reg or the
offset formed an invalid address, such memory-equivalences as we
make here would screw up life analysis for it. */
if (data->nominal_mode == data->passed_mode
&& !did_conversion
&& data->stack_parm != 0
&& MEM_P (data->stack_parm)
&& data->locate.offset.var == 0
&& reg_mentioned_p (virtual_incoming_args_rtx,
XEXP (data->stack_parm, 0)))
{
rtx linsn = get_last_insn ();
rtx sinsn, set;
/* Mark complex types separately. */
if (GET_CODE (parmreg) == CONCAT)
{
enum machine_mode submode
= GET_MODE_INNER (GET_MODE (parmreg));
int regnor = REGNO (XEXP (parmreg, 0));
int regnoi = REGNO (XEXP (parmreg, 1));
rtx stackr = adjust_address_nv (data->stack_parm, submode, 0);
rtx stacki = adjust_address_nv (data->stack_parm, submode,
GET_MODE_SIZE (submode));
/* Scan backwards for the set of the real and
imaginary parts. */
for (sinsn = linsn; sinsn != 0;
sinsn = prev_nonnote_insn (sinsn))
{
set = single_set (sinsn);
if (set == 0)
continue;
if (SET_DEST (set) == regno_reg_rtx [regnoi])
set_unique_reg_note (sinsn, REG_EQUIV, stacki);
else if (SET_DEST (set) == regno_reg_rtx [regnor])
set_unique_reg_note (sinsn, REG_EQUIV, stackr);
}
}
else
set_dst_reg_note (linsn, REG_EQUIV, equiv_stack_parm, parmreg);
}
/* For pointer data type, suggest pointer register. */
if (POINTER_TYPE_P (TREE_TYPE (parm)))
mark_reg_pointer (parmreg,
TYPE_ALIGN (TREE_TYPE (TREE_TYPE (parm))));
}
/* A subroutine of assign_parms. Allocate stack space to hold the current
parameter. Get it there. Perform all ABI specified conversions. */
static void
assign_parm_setup_stack (struct assign_parm_data_all *all, tree parm,
struct assign_parm_data_one *data)
{
/* Value must be stored in the stack slot STACK_PARM during function
execution. */
bool to_conversion = false;
assign_parm_remove_parallels (data);
if (data->promoted_mode != data->nominal_mode)
{
/* Conversion is required. */
rtx tempreg = gen_reg_rtx (GET_MODE (data->entry_parm));
emit_move_insn (tempreg, validize_mem (data->entry_parm));
push_to_sequence2 (all->first_conversion_insn, all->last_conversion_insn);
to_conversion = true;
data->entry_parm = convert_to_mode (data->nominal_mode, tempreg,
TYPE_UNSIGNED (TREE_TYPE (parm)));
if (data->stack_parm)
{
int offset = subreg_lowpart_offset (data->nominal_mode,
GET_MODE (data->stack_parm));
/* ??? This may need a big-endian conversion on sparc64. */
data->stack_parm
= adjust_address (data->stack_parm, data->nominal_mode, 0);
if (offset && MEM_OFFSET_KNOWN_P (data->stack_parm))
set_mem_offset (data->stack_parm,
MEM_OFFSET (data->stack_parm) + offset);
}
}
if (data->entry_parm != data->stack_parm)
{
rtx src, dest;
if (data->stack_parm == 0)
{
int align = STACK_SLOT_ALIGNMENT (data->passed_type,
GET_MODE (data->entry_parm),
TYPE_ALIGN (data->passed_type));
data->stack_parm
= assign_stack_local (GET_MODE (data->entry_parm),
GET_MODE_SIZE (GET_MODE (data->entry_parm)),
align);
set_mem_attributes (data->stack_parm, parm, 1);
}
dest = validize_mem (data->stack_parm);
src = validize_mem (data->entry_parm);
if (MEM_P (src))
{
/* Use a block move to handle potentially misaligned entry_parm. */
if (!to_conversion)
push_to_sequence2 (all->first_conversion_insn,
all->last_conversion_insn);
to_conversion = true;
emit_block_move (dest, src,
GEN_INT (int_size_in_bytes (data->passed_type)),
BLOCK_OP_NORMAL);
}
else
emit_move_insn (dest, src);
}
if (to_conversion)
{
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
}
SET_DECL_RTL (parm, data->stack_parm);
}
/* A subroutine of assign_parms. If the ABI splits complex arguments, then
undo the frobbing that we did in assign_parms_augmented_arg_list. */
static void
assign_parms_unsplit_complex (struct assign_parm_data_all *all,
vec fnargs)
{
tree parm;
tree orig_fnargs = all->orig_fnargs;
unsigned i = 0;
for (parm = orig_fnargs; parm; parm = TREE_CHAIN (parm), ++i)
{
if (TREE_CODE (TREE_TYPE (parm)) == COMPLEX_TYPE
&& targetm.calls.split_complex_arg (TREE_TYPE (parm)))
{
rtx tmp, real, imag;
enum machine_mode inner = GET_MODE_INNER (DECL_MODE (parm));
real = DECL_RTL (fnargs[i]);
imag = DECL_RTL (fnargs[i + 1]);
if (inner != GET_MODE (real))
{
real = gen_lowpart_SUBREG (inner, real);
imag = gen_lowpart_SUBREG (inner, imag);
}
if (TREE_ADDRESSABLE (parm))
{
rtx rmem, imem;
HOST_WIDE_INT size = int_size_in_bytes (TREE_TYPE (parm));
int align = STACK_SLOT_ALIGNMENT (TREE_TYPE (parm),
DECL_MODE (parm),
TYPE_ALIGN (TREE_TYPE (parm)));
/* split_complex_arg put the real and imag parts in
pseudos. Move them to memory. */
tmp = assign_stack_local (DECL_MODE (parm), size, align);
set_mem_attributes (tmp, parm, 1);
rmem = adjust_address_nv (tmp, inner, 0);
imem = adjust_address_nv (tmp, inner, GET_MODE_SIZE (inner));
push_to_sequence2 (all->first_conversion_insn,
all->last_conversion_insn);
emit_move_insn (rmem, real);
emit_move_insn (imem, imag);
all->first_conversion_insn = get_insns ();
all->last_conversion_insn = get_last_insn ();
end_sequence ();
}
else
tmp = gen_rtx_CONCAT (DECL_MODE (parm), real, imag);
SET_DECL_RTL (parm, tmp);
real = DECL_INCOMING_RTL (fnargs[i]);
imag = DECL_INCOMING_RTL (fnargs[i + 1]);
if (inner != GET_MODE (real))
{
real = gen_lowpart_SUBREG (inner, real);
imag = gen_lowpart_SUBREG (inner, imag);
}
tmp = gen_rtx_CONCAT (DECL_MODE (parm), real, imag);
set_decl_incoming_rtl (parm, tmp, false);
i++;
}
}
}
/* Assign RTL expressions to the function's parameters. This may involve
copying them into registers and using those registers as the DECL_RTL. */
static void
assign_parms (tree fndecl)
{
struct assign_parm_data_all all;
tree parm;
vec fnargs;
unsigned i;
crtl->args.internal_arg_pointer
= targetm.calls.internal_arg_pointer ();
assign_parms_initialize_all (&all);
fnargs = assign_parms_augmented_arg_list (&all);
FOR_EACH_VEC_ELT (fnargs, i, parm)
{
struct assign_parm_data_one data;
/* Extract the type of PARM; adjust it according to ABI. */
assign_parm_find_data_types (&all, parm, &data);
/* Early out for errors and void parameters. */
if (data.passed_mode == VOIDmode)
{
SET_DECL_RTL (parm, const0_rtx);
DECL_INCOMING_RTL (parm) = DECL_RTL (parm);
continue;
}
/* Estimate stack alignment from parameter alignment. */
if (SUPPORTS_STACK_ALIGNMENT)
{
unsigned int align
= targetm.calls.function_arg_boundary (data.promoted_mode,
data.passed_type);
align = MINIMUM_ALIGNMENT (data.passed_type, data.promoted_mode,
align);
if (TYPE_ALIGN (data.nominal_type) > align)
align = MINIMUM_ALIGNMENT (data.nominal_type,
TYPE_MODE (data.nominal_type),
TYPE_ALIGN (data.nominal_type));
if (crtl->stack_alignment_estimated < align)
{
gcc_assert (!crtl->stack_realign_processed);
crtl->stack_alignment_estimated = align;
}
}
if (cfun->stdarg && !DECL_CHAIN (parm))
assign_parms_setup_varargs (&all, &data, false);
/* Find out where the parameter arrives in this function. */
assign_parm_find_entry_rtl (&all, &data);
/* Find out where stack space for this parameter might be. */
if (assign_parm_is_stack_parm (&all, &data))
{
assign_parm_find_stack_rtl (parm, &data);
assign_parm_adjust_entry_rtl (&data);
}
/* Record permanently how this parm was passed. */
if (data.passed_pointer)
{
rtx incoming_rtl
= gen_rtx_MEM (TYPE_MODE (TREE_TYPE (data.passed_type)),
data.entry_parm);
set_decl_incoming_rtl (parm, incoming_rtl, true);
}
else
set_decl_incoming_rtl (parm, data.entry_parm, false);
/* Update info on where next arg arrives in registers. */
targetm.calls.function_arg_advance (all.args_so_far, data.promoted_mode,
data.passed_type, data.named_arg);
assign_parm_adjust_stack_rtl (&data);
if (assign_parm_setup_block_p (&data))
assign_parm_setup_block (&all, parm, &data);
else if (data.passed_pointer || use_register_for_decl (parm))
assign_parm_setup_reg (&all, parm, &data);
else
assign_parm_setup_stack (&all, parm, &data);
}
if (targetm.calls.split_complex_arg)
assign_parms_unsplit_complex (&all, fnargs);
fnargs.release ();
/* Output all parameter conversion instructions (possibly including calls)
now that all parameters have been copied out of hard registers. */
emit_insn (all.first_conversion_insn);
/* Estimate reload stack alignment from scalar return mode. */
if (SUPPORTS_STACK_ALIGNMENT)
{
if (DECL_RESULT (fndecl))
{
tree type = TREE_TYPE (DECL_RESULT (fndecl));
enum machine_mode mode = TYPE_MODE (type);
if (mode != BLKmode
&& mode != VOIDmode
&& !AGGREGATE_TYPE_P (type))
{
unsigned int align = GET_MODE_ALIGNMENT (mode);
if (crtl->stack_alignment_estimated < align)
{
gcc_assert (!crtl->stack_realign_processed);
crtl->stack_alignment_estimated = align;
}
}
}
}
/* If we are receiving a struct value address as the first argument, set up
the RTL for the function result. As this might require code to convert
the transmitted address to Pmode, we do this here to ensure that possible
preliminary conversions of the address have been emitted already. */
if (all.function_result_decl)
{
tree result = DECL_RESULT (current_function_decl);
rtx addr = DECL_RTL (all.function_result_decl);
rtx x;
if (DECL_BY_REFERENCE (result))
{
SET_DECL_VALUE_EXPR (result, all.function_result_decl);
x = addr;
}
else
{
SET_DECL_VALUE_EXPR (result,
build1 (INDIRECT_REF, TREE_TYPE (result),
all.function_result_decl));
addr = convert_memory_address (Pmode, addr);
x = gen_rtx_MEM (DECL_MODE (result), addr);
set_mem_attributes (x, result, 1);
}
DECL_HAS_VALUE_EXPR_P (result) = 1;
SET_DECL_RTL (result, x);
}
/* We have aligned all the args, so add space for the pretend args. */
crtl->args.pretend_args_size = all.pretend_args_size;
all.stack_args_size.constant += all.extra_pretend_bytes;
crtl->args.size = all.stack_args_size.constant;
/* Adjust function incoming argument size for alignment and
minimum length. */
crtl->args.size = MAX (crtl->args.size, all.reg_parm_stack_space);
crtl->args.size = CEIL_ROUND (crtl->args.size,
PARM_BOUNDARY / BITS_PER_UNIT);
#ifdef ARGS_GROW_DOWNWARD
crtl->args.arg_offset_rtx
= (all.stack_args_size.var == 0 ? GEN_INT (-all.stack_args_size.constant)
: expand_expr (size_diffop (all.stack_args_size.var,
size_int (-all.stack_args_size.constant)),
NULL_RTX, VOIDmode, EXPAND_NORMAL));
#else
crtl->args.arg_offset_rtx = ARGS_SIZE_RTX (all.stack_args_size);
#endif
/* See how many bytes, if any, of its args a function should try to pop
on return. */
crtl->args.pops_args = targetm.calls.return_pops_args (fndecl,
TREE_TYPE (fndecl),
crtl->args.size);
/* For stdarg.h function, save info about
regs and stack space used by the named args. */
crtl->args.info = all.args_so_far_v;
/* Set the rtx used for the function return value. Put this in its
own variable so any optimizers that need this information don't have
to include tree.h. Do this here so it gets done when an inlined
function gets output. */
crtl->return_rtx
= (DECL_RTL_SET_P (DECL_RESULT (fndecl))
? DECL_RTL (DECL_RESULT (fndecl)) : NULL_RTX);
/* If scalar return value was computed in a pseudo-reg, or was a named
return value that got dumped to the stack, copy that to the hard
return register. */
if (DECL_RTL_SET_P (DECL_RESULT (fndecl)))
{
tree decl_result = DECL_RESULT (fndecl);
rtx decl_rtl = DECL_RTL (decl_result);
if (REG_P (decl_rtl)
? REGNO (decl_rtl) >= FIRST_PSEUDO_REGISTER
: DECL_REGISTER (decl_result))
{
rtx real_decl_rtl;
real_decl_rtl = targetm.calls.function_value (TREE_TYPE (decl_result),
fndecl, true);
REG_FUNCTION_VALUE_P (real_decl_rtl) = 1;
/* The delay slot scheduler assumes that crtl->return_rtx
holds the hard register containing the return value, not a
temporary pseudo. */
crtl->return_rtx = real_decl_rtl;
}
}
}
/* A subroutine of gimplify_parameters, invoked via walk_tree.
For all seen types, gimplify their sizes. */
static tree
gimplify_parm_type (tree *tp, int *walk_subtrees, void *data)
{
tree t = *tp;
*walk_subtrees = 0;
if (TYPE_P (t))
{
if (POINTER_TYPE_P (t))
*walk_subtrees = 1;
else if (TYPE_SIZE (t) && !TREE_CONSTANT (TYPE_SIZE (t))
&& !TYPE_SIZES_GIMPLIFIED (t))
{
gimplify_type_sizes (t, (gimple_seq *) data);
*walk_subtrees = 1;
}
}
return NULL;
}
/* Gimplify the parameter list for current_function_decl. This involves
evaluating SAVE_EXPRs of variable sized parameters and generating code
to implement callee-copies reference parameters. Returns a sequence of
statements to add to the beginning of the function. */
gimple_seq
gimplify_parameters (void)
{
struct assign_parm_data_all all;
tree parm;
gimple_seq stmts = NULL;
vec fnargs;
unsigned i;
assign_parms_initialize_all (&all);
fnargs = assign_parms_augmented_arg_list (&all);
FOR_EACH_VEC_ELT (fnargs, i, parm)
{
struct assign_parm_data_one data;
/* Extract the type of PARM; adjust it according to ABI. */
assign_parm_find_data_types (&all, parm, &data);
/* Early out for errors and void parameters. */
if (data.passed_mode == VOIDmode || DECL_SIZE (parm) == NULL)
continue;
/* Update info on where next arg arrives in registers. */
targetm.calls.function_arg_advance (all.args_so_far, data.promoted_mode,
data.passed_type, data.named_arg);
/* ??? Once upon a time variable_size stuffed parameter list
SAVE_EXPRs (amongst others) onto a pending sizes list. This
turned out to be less than manageable in the gimple world.
Now we have to hunt them down ourselves. */
walk_tree_without_duplicates (&data.passed_type,
gimplify_parm_type, &stmts);
if (TREE_CODE (DECL_SIZE_UNIT (parm)) != INTEGER_CST)
{
gimplify_one_sizepos (&DECL_SIZE (parm), &stmts);
gimplify_one_sizepos (&DECL_SIZE_UNIT (parm), &stmts);
}
if (data.passed_pointer)
{
tree type = TREE_TYPE (data.passed_type);
if (reference_callee_copied (&all.args_so_far_v, TYPE_MODE (type),
type, data.named_arg))
{
tree local, t;
/* For constant-sized objects, this is trivial; for
variable-sized objects, we have to play games. */
if (TREE_CODE (DECL_SIZE_UNIT (parm)) == INTEGER_CST
&& !(flag_stack_check == GENERIC_STACK_CHECK
&& compare_tree_int (DECL_SIZE_UNIT (parm),
STACK_CHECK_MAX_VAR_SIZE) > 0))
{
local = create_tmp_var (type, get_name (parm));
DECL_IGNORED_P (local) = 0;
/* If PARM was addressable, move that flag over
to the local copy, as its address will be taken,
not the PARMs. Keep the parms address taken
as we'll query that flag during gimplification. */
if (TREE_ADDRESSABLE (parm))
TREE_ADDRESSABLE (local) = 1;
else if (TREE_CODE (type) == COMPLEX_TYPE
|| TREE_CODE (type) == VECTOR_TYPE)
DECL_GIMPLE_REG_P (local) = 1;
}
else
{
tree ptr_type, addr;
ptr_type = build_pointer_type (type);
addr = create_tmp_reg (ptr_type, get_name (parm));
DECL_IGNORED_P (addr) = 0;
local = build_fold_indirect_ref (addr);
t = builtin_decl_explicit (BUILT_IN_ALLOCA_WITH_ALIGN);
t = build_call_expr (t, 2, DECL_SIZE_UNIT (parm),
size_int (DECL_ALIGN (parm)));
/* The call has been built for a variable-sized object. */
CALL_ALLOCA_FOR_VAR_P (t) = 1;
t = fold_convert (ptr_type, t);
t = build2 (MODIFY_EXPR, TREE_TYPE (addr), addr, t);
gimplify_and_add (t, &stmts);
}
gimplify_assign (local, parm, &stmts);
SET_DECL_VALUE_EXPR (parm, local);
DECL_HAS_VALUE_EXPR_P (parm) = 1;
}
}
}
fnargs.release ();
return stmts;
}
/* Compute the size and offset from the start of the stacked arguments for a
parm passed in mode PASSED_MODE and with type TYPE.
INITIAL_OFFSET_PTR points to the current offset into the stacked
arguments.
The starting offset and size for this parm are returned in
LOCATE->OFFSET and LOCATE->SIZE, respectively. When IN_REGS is
nonzero, the offset is that of stack slot, which is returned in
LOCATE->SLOT_OFFSET. LOCATE->ALIGNMENT_PAD is the amount of
padding required from the initial offset ptr to the stack slot.
IN_REGS is nonzero if the argument will be passed in registers. It will
never be set if REG_PARM_STACK_SPACE is not defined.
REG_PARM_STACK_SPACE is the number of bytes of stack space reserved
for arguments which are passed in registers.
FNDECL is the function in which the argument was defined.
There are two types of rounding that are done. The first, controlled by
TARGET_FUNCTION_ARG_BOUNDARY, forces the offset from the start of the
argument list to be aligned to the specific boundary (in bits). This
rounding affects the initial and starting offsets, but not the argument
size.
The second, controlled by FUNCTION_ARG_PADDING and PARM_BOUNDARY,
optionally rounds the size of the parm to PARM_BOUNDARY. The
initial offset is not affected by this rounding, while the size always
is and the starting offset may be. */
/* LOCATE->OFFSET will be negative for ARGS_GROW_DOWNWARD case;
INITIAL_OFFSET_PTR is positive because locate_and_pad_parm's
callers pass in the total size of args so far as
INITIAL_OFFSET_PTR. LOCATE->SIZE is always positive. */
void
locate_and_pad_parm (enum machine_mode passed_mode, tree type, int in_regs,
int reg_parm_stack_space, int partial,
tree fndecl ATTRIBUTE_UNUSED,
struct args_size *initial_offset_ptr,
struct locate_and_pad_arg_data *locate)
{
tree sizetree;
enum direction where_pad;
unsigned int boundary, round_boundary;
int part_size_in_regs;
/* If we have found a stack parm before we reach the end of the
area reserved for registers, skip that area. */
if (! in_regs)
{
if (reg_parm_stack_space > 0)
{
if (initial_offset_ptr->var)
{
initial_offset_ptr->var
= size_binop (MAX_EXPR, ARGS_SIZE_TREE (*initial_offset_ptr),
ssize_int (reg_parm_stack_space));
initial_offset_ptr->constant = 0;
}
else if (initial_offset_ptr->constant < reg_parm_stack_space)
initial_offset_ptr->constant = reg_parm_stack_space;
}
}
part_size_in_regs = (reg_parm_stack_space == 0 ? partial : 0);
sizetree
= type ? size_in_bytes (type) : size_int (GET_MODE_SIZE (passed_mode));
where_pad = FUNCTION_ARG_PADDING (passed_mode, type);
boundary = targetm.calls.function_arg_boundary (passed_mode, type);
round_boundary = targetm.calls.function_arg_round_boundary (passed_mode,
type);
locate->where_pad = where_pad;
/* Alignment can't exceed MAX_SUPPORTED_STACK_ALIGNMENT. */
if (boundary > MAX_SUPPORTED_STACK_ALIGNMENT)
boundary = MAX_SUPPORTED_STACK_ALIGNMENT;
locate->boundary = boundary;
if (SUPPORTS_STACK_ALIGNMENT)
{
/* stack_alignment_estimated can't change after stack has been
realigned. */
if (crtl->stack_alignment_estimated < boundary)
{
if (!crtl->stack_realign_processed)
crtl->stack_alignment_estimated = boundary;
else
{
/* If stack is realigned and stack alignment value
hasn't been finalized, it is OK not to increase
stack_alignment_estimated. The bigger alignment
requirement is recorded in stack_alignment_needed
below. */
gcc_assert (!crtl->stack_realign_finalized
&& crtl->stack_realign_needed);
}
}
}
/* Remember if the outgoing parameter requires extra alignment on the
calling function side. */
if (crtl->stack_alignment_needed < boundary)
crtl->stack_alignment_needed = boundary;
if (crtl->preferred_stack_boundary < boundary)
crtl->preferred_stack_boundary = boundary;
#ifdef ARGS_GROW_DOWNWARD
locate->slot_offset.constant = -initial_offset_ptr->constant;
if (initial_offset_ptr->var)
locate->slot_offset.var = size_binop (MINUS_EXPR, ssize_int (0),
initial_offset_ptr->var);
{
tree s2 = sizetree;
if (where_pad != none
&& (!host_integerp (sizetree, 1)
|| (tree_low_cst (sizetree, 1) * BITS_PER_UNIT) % round_boundary))
s2 = round_up (s2, round_boundary / BITS_PER_UNIT);
SUB_PARM_SIZE (locate->slot_offset, s2);
}
locate->slot_offset.constant += part_size_in_regs;
if (!in_regs || reg_parm_stack_space > 0)
pad_to_arg_alignment (&locate->slot_offset, boundary,
&locate->alignment_pad);
locate->size.constant = (-initial_offset_ptr->constant
- locate->slot_offset.constant);
if (initial_offset_ptr->var)
locate->size.var = size_binop (MINUS_EXPR,
size_binop (MINUS_EXPR,
ssize_int (0),
initial_offset_ptr->var),
locate->slot_offset.var);
/* Pad_below needs the pre-rounded size to know how much to pad
below. */
locate->offset = locate->slot_offset;
if (where_pad == downward)
pad_below (&locate->offset, passed_mode, sizetree);
#else /* !ARGS_GROW_DOWNWARD */
if (!in_regs || reg_parm_stack_space > 0)
pad_to_arg_alignment (initial_offset_ptr, boundary,
&locate->alignment_pad);
locate->slot_offset = *initial_offset_ptr;
#ifdef PUSH_ROUNDING
if (passed_mode != BLKmode)
sizetree = size_int (PUSH_ROUNDING (TREE_INT_CST_LOW (sizetree)));
#endif
/* Pad_below needs the pre-rounded size to know how much to pad below
so this must be done before rounding up. */
locate->offset = locate->slot_offset;
if (where_pad == downward)
pad_below (&locate->offset, passed_mode, sizetree);
if (where_pad != none
&& (!host_integerp (sizetree, 1)
|| (tree_low_cst (sizetree, 1) * BITS_PER_UNIT) % round_boundary))
sizetree = round_up (sizetree, round_boundary / BITS_PER_UNIT);
ADD_PARM_SIZE (locate->size, sizetree);
locate->size.constant -= part_size_in_regs;
#endif /* ARGS_GROW_DOWNWARD */
#ifdef FUNCTION_ARG_OFFSET
locate->offset.constant += FUNCTION_ARG_OFFSET (passed_mode, type);
#endif
}
/* Round the stack offset in *OFFSET_PTR up to a multiple of BOUNDARY.
BOUNDARY is measured in bits, but must be a multiple of a storage unit. */
static void
pad_to_arg_alignment (struct args_size *offset_ptr, int boundary,
struct args_size *alignment_pad)
{
tree save_var = NULL_TREE;
HOST_WIDE_INT save_constant = 0;
int boundary_in_bytes = boundary / BITS_PER_UNIT;
HOST_WIDE_INT sp_offset = STACK_POINTER_OFFSET;
#ifdef SPARC_STACK_BOUNDARY_HACK
/* ??? The SPARC port may claim a STACK_BOUNDARY higher than
the real alignment of %sp. However, when it does this, the
alignment of %sp+STACK_POINTER_OFFSET is STACK_BOUNDARY. */
if (SPARC_STACK_BOUNDARY_HACK)
sp_offset = 0;
#endif
if (boundary > PARM_BOUNDARY)
{
save_var = offset_ptr->var;
save_constant = offset_ptr->constant;
}
alignment_pad->var = NULL_TREE;
alignment_pad->constant = 0;
if (boundary > BITS_PER_UNIT)
{
if (offset_ptr->var)
{
tree sp_offset_tree = ssize_int (sp_offset);
tree offset = size_binop (PLUS_EXPR,
ARGS_SIZE_TREE (*offset_ptr),
sp_offset_tree);
#ifdef ARGS_GROW_DOWNWARD
tree rounded = round_down (offset, boundary / BITS_PER_UNIT);
#else
tree rounded = round_up (offset, boundary / BITS_PER_UNIT);
#endif
offset_ptr->var = size_binop (MINUS_EXPR, rounded, sp_offset_tree);
/* ARGS_SIZE_TREE includes constant term. */
offset_ptr->constant = 0;
if (boundary > PARM_BOUNDARY)
alignment_pad->var = size_binop (MINUS_EXPR, offset_ptr->var,
save_var);
}
else
{
offset_ptr->constant = -sp_offset +
#ifdef ARGS_GROW_DOWNWARD
FLOOR_ROUND (offset_ptr->constant + sp_offset, boundary_in_bytes);
#else
CEIL_ROUND (offset_ptr->constant + sp_offset, boundary_in_bytes);
#endif
if (boundary > PARM_BOUNDARY)
alignment_pad->constant = offset_ptr->constant - save_constant;
}
}
}
static void
pad_below (struct args_size *offset_ptr, enum machine_mode passed_mode, tree sizetree)
{
if (passed_mode != BLKmode)
{
if (GET_MODE_BITSIZE (passed_mode) % PARM_BOUNDARY)
offset_ptr->constant
+= (((GET_MODE_BITSIZE (passed_mode) + PARM_BOUNDARY - 1)
/ PARM_BOUNDARY * PARM_BOUNDARY / BITS_PER_UNIT)
- GET_MODE_SIZE (passed_mode));
}
else
{
if (TREE_CODE (sizetree) != INTEGER_CST
|| (TREE_INT_CST_LOW (sizetree) * BITS_PER_UNIT) % PARM_BOUNDARY)
{
/* Round the size up to multiple of PARM_BOUNDARY bits. */
tree s2 = round_up (sizetree, PARM_BOUNDARY / BITS_PER_UNIT);
/* Add it in. */
ADD_PARM_SIZE (*offset_ptr, s2);
SUB_PARM_SIZE (*offset_ptr, sizetree);
}
}
}
/* True if register REGNO was alive at a place where `setjmp' was
called and was set more than once or is an argument. Such regs may
be clobbered by `longjmp'. */
static bool
regno_clobbered_at_setjmp (bitmap setjmp_crosses, int regno)
{
/* There appear to be cases where some local vars never reach the
backend but have bogus regnos. */
if (regno >= max_reg_num ())
return false;
return ((REG_N_SETS (regno) > 1
|| REGNO_REG_SET_P (df_get_live_out (ENTRY_BLOCK_PTR), regno))
&& REGNO_REG_SET_P (setjmp_crosses, regno));
}
/* Walk the tree of blocks describing the binding levels within a
function and warn about variables the might be killed by setjmp or
vfork. This is done after calling flow_analysis before register
allocation since that will clobber the pseudo-regs to hard
regs. */
static void
setjmp_vars_warning (bitmap setjmp_crosses, tree block)
{
tree decl, sub;
for (decl = BLOCK_VARS (block); decl; decl = DECL_CHAIN (decl))
{
if (TREE_CODE (decl) == VAR_DECL
&& DECL_RTL_SET_P (decl)
&& REG_P (DECL_RTL (decl))
&& regno_clobbered_at_setjmp (setjmp_crosses, REGNO (DECL_RTL (decl))))
warning (OPT_Wclobbered, "variable %q+D might be clobbered by"
" % or %", decl);
}
for (sub = BLOCK_SUBBLOCKS (block); sub; sub = BLOCK_CHAIN (sub))
setjmp_vars_warning (setjmp_crosses, sub);
}
/* Do the appropriate part of setjmp_vars_warning
but for arguments instead of local variables. */
static void
setjmp_args_warning (bitmap setjmp_crosses)
{
tree decl;
for (decl = DECL_ARGUMENTS (current_function_decl);
decl; decl = DECL_CHAIN (decl))
if (DECL_RTL (decl) != 0
&& REG_P (DECL_RTL (decl))
&& regno_clobbered_at_setjmp (setjmp_crosses, REGNO (DECL_RTL (decl))))
warning (OPT_Wclobbered,
"argument %q+D might be clobbered by % or %",
decl);
}
/* Generate warning messages for variables live across setjmp. */
void
generate_setjmp_warnings (void)
{
bitmap setjmp_crosses = regstat_get_setjmp_crosses ();
if (n_basic_blocks == NUM_FIXED_BLOCKS
|| bitmap_empty_p (setjmp_crosses))
return;
setjmp_vars_warning (setjmp_crosses, DECL_INITIAL (current_function_decl));
setjmp_args_warning (setjmp_crosses);
}
/* Reverse the order of elements in the fragment chain T of blocks,
and return the new head of the chain (old last element).
In addition to that clear BLOCK_SAME_RANGE flags when needed
and adjust BLOCK_SUPERCONTEXT from the super fragment to
its super fragment origin. */
static tree
block_fragments_nreverse (tree t)
{
tree prev = 0, block, next, prev_super = 0;
tree super = BLOCK_SUPERCONTEXT (t);
if (BLOCK_FRAGMENT_ORIGIN (super))
super = BLOCK_FRAGMENT_ORIGIN (super);
for (block = t; block; block = next)
{
next = BLOCK_FRAGMENT_CHAIN (block);
BLOCK_FRAGMENT_CHAIN (block) = prev;
if ((prev && !BLOCK_SAME_RANGE (prev))
|| (BLOCK_FRAGMENT_CHAIN (BLOCK_SUPERCONTEXT (block))
!= prev_super))
BLOCK_SAME_RANGE (block) = 0;
prev_super = BLOCK_SUPERCONTEXT (block);
BLOCK_SUPERCONTEXT (block) = super;
prev = block;
}
t = BLOCK_FRAGMENT_ORIGIN (t);
if (BLOCK_FRAGMENT_CHAIN (BLOCK_SUPERCONTEXT (t))
!= prev_super)
BLOCK_SAME_RANGE (t) = 0;
BLOCK_SUPERCONTEXT (t) = super;
return prev;
}
/* Reverse the order of elements in the chain T of blocks,
and return the new head of the chain (old last element).
Also do the same on subblocks and reverse the order of elements
in BLOCK_FRAGMENT_CHAIN as well. */
static tree
blocks_nreverse_all (tree t)
{
tree prev = 0, block, next;
for (block = t; block; block = next)
{
next = BLOCK_CHAIN (block);
BLOCK_CHAIN (block) = prev;
if (BLOCK_FRAGMENT_CHAIN (block)
&& BLOCK_FRAGMENT_ORIGIN (block) == NULL_TREE)
{
BLOCK_FRAGMENT_CHAIN (block)
= block_fragments_nreverse (BLOCK_FRAGMENT_CHAIN (block));
if (!BLOCK_SAME_RANGE (BLOCK_FRAGMENT_CHAIN (block)))
BLOCK_SAME_RANGE (block) = 0;
}
BLOCK_SUBBLOCKS (block) = blocks_nreverse_all (BLOCK_SUBBLOCKS (block));
prev = block;
}
return prev;
}
/* Identify BLOCKs referenced by more than one NOTE_INSN_BLOCK_{BEG,END},
and create duplicate blocks. */
/* ??? Need an option to either create block fragments or to create
abstract origin duplicates of a source block. It really depends
on what optimization has been performed. */
void
reorder_blocks (void)
{
tree block = DECL_INITIAL (current_function_decl);
if (block == NULL_TREE)
return;
stack_vec block_stack;
/* Reset the TREE_ASM_WRITTEN bit for all blocks. */
clear_block_marks (block);
/* Prune the old trees away, so that they don't get in the way. */
BLOCK_SUBBLOCKS (block) = NULL_TREE;
BLOCK_CHAIN (block) = NULL_TREE;
/* Recreate the block tree from the note nesting. */
reorder_blocks_1 (get_insns (), block, &block_stack);
BLOCK_SUBBLOCKS (block) = blocks_nreverse_all (BLOCK_SUBBLOCKS (block));
}
/* Helper function for reorder_blocks. Reset TREE_ASM_WRITTEN. */
void
clear_block_marks (tree block)
{
while (block)
{
TREE_ASM_WRITTEN (block) = 0;
clear_block_marks (BLOCK_SUBBLOCKS (block));
block = BLOCK_CHAIN (block);
}
}
static void
reorder_blocks_1 (rtx insns, tree current_block, vec *p_block_stack)
{
rtx insn;
tree prev_beg = NULL_TREE, prev_end = NULL_TREE;
for (insn = insns; insn; insn = NEXT_INSN (insn))
{
if (NOTE_P (insn))
{
if (NOTE_KIND (insn) == NOTE_INSN_BLOCK_BEG)
{
tree block = NOTE_BLOCK (insn);
tree origin;
gcc_assert (BLOCK_FRAGMENT_ORIGIN (block) == NULL_TREE);
origin = block;
if (prev_end)
BLOCK_SAME_RANGE (prev_end) = 0;
prev_end = NULL_TREE;
/* If we have seen this block before, that means it now
spans multiple address regions. Create a new fragment. */
if (TREE_ASM_WRITTEN (block))
{
tree new_block = copy_node (block);
BLOCK_SAME_RANGE (new_block) = 0;
BLOCK_FRAGMENT_ORIGIN (new_block) = origin;
BLOCK_FRAGMENT_CHAIN (new_block)
= BLOCK_FRAGMENT_CHAIN (origin);
BLOCK_FRAGMENT_CHAIN (origin) = new_block;
NOTE_BLOCK (insn) = new_block;
block = new_block;
}
if (prev_beg == current_block && prev_beg)
BLOCK_SAME_RANGE (block) = 1;
prev_beg = origin;
BLOCK_SUBBLOCKS (block) = 0;
TREE_ASM_WRITTEN (block) = 1;
/* When there's only one block for the entire function,
current_block == block and we mustn't do this, it
will cause infinite recursion. */
if (block != current_block)
{
tree super;
if (block != origin)
gcc_assert (BLOCK_SUPERCONTEXT (origin) == current_block
|| BLOCK_FRAGMENT_ORIGIN (BLOCK_SUPERCONTEXT
(origin))
== current_block);
if (p_block_stack->is_empty ())
super = current_block;
else
{
super = p_block_stack->last ();
gcc_assert (super == current_block
|| BLOCK_FRAGMENT_ORIGIN (super)
== current_block);
}
BLOCK_SUPERCONTEXT (block) = super;
BLOCK_CHAIN (block) = BLOCK_SUBBLOCKS (current_block);
BLOCK_SUBBLOCKS (current_block) = block;
current_block = origin;
}
p_block_stack->safe_push (block);
}
else if (NOTE_KIND (insn) == NOTE_INSN_BLOCK_END)
{
NOTE_BLOCK (insn) = p_block_stack->pop ();
current_block = BLOCK_SUPERCONTEXT (current_block);
if (BLOCK_FRAGMENT_ORIGIN (current_block))
current_block = BLOCK_FRAGMENT_ORIGIN (current_block);
prev_beg = NULL_TREE;
prev_end = BLOCK_SAME_RANGE (NOTE_BLOCK (insn))
? NOTE_BLOCK (insn) : NULL_TREE;
}
}
else
{
prev_beg = NULL_TREE;
if (prev_end)
BLOCK_SAME_RANGE (prev_end) = 0;
prev_end = NULL_TREE;
}
}
}
/* Reverse the order of elements in the chain T of blocks,
and return the new head of the chain (old last element). */
tree
blocks_nreverse (tree t)
{
tree prev = 0, block, next;
for (block = t; block; block = next)
{
next = BLOCK_CHAIN (block);
BLOCK_CHAIN (block) = prev;
prev = block;
}
return prev;
}
/* Concatenate two chains of blocks (chained through BLOCK_CHAIN)
by modifying the last node in chain 1 to point to chain 2. */
tree
block_chainon (tree op1, tree op2)
{
tree t1;
if (!op1)
return op2;
if (!op2)
return op1;
for (t1 = op1; BLOCK_CHAIN (t1); t1 = BLOCK_CHAIN (t1))
continue;
BLOCK_CHAIN (t1) = op2;
#ifdef ENABLE_TREE_CHECKING
{
tree t2;
for (t2 = op2; t2; t2 = BLOCK_CHAIN (t2))
gcc_assert (t2 != t1);
}
#endif
return op1;
}
/* Count the subblocks of the list starting with BLOCK. If VECTOR is
non-NULL, list them all into VECTOR, in a depth-first preorder
traversal of the block tree. Also clear TREE_ASM_WRITTEN in all
blocks. */
static int
all_blocks (tree block, tree *vector)
{
int n_blocks = 0;
while (block)
{
TREE_ASM_WRITTEN (block) = 0;
/* Record this block. */
if (vector)
vector[n_blocks] = block;
++n_blocks;
/* Record the subblocks, and their subblocks... */
n_blocks += all_blocks (BLOCK_SUBBLOCKS (block),
vector ? vector + n_blocks : 0);
block = BLOCK_CHAIN (block);
}
return n_blocks;
}
/* Return a vector containing all the blocks rooted at BLOCK. The
number of elements in the vector is stored in N_BLOCKS_P. The
vector is dynamically allocated; it is the caller's responsibility
to call `free' on the pointer returned. */
static tree *
get_block_vector (tree block, int *n_blocks_p)
{
tree *block_vector;
*n_blocks_p = all_blocks (block, NULL);
block_vector = XNEWVEC (tree, *n_blocks_p);
all_blocks (block, block_vector);
return block_vector;
}
static GTY(()) int next_block_index = 2;
/* Set BLOCK_NUMBER for all the blocks in FN. */
void
number_blocks (tree fn)
{
int i;
int n_blocks;
tree *block_vector;
/* For SDB and XCOFF debugging output, we start numbering the blocks
from 1 within each function, rather than keeping a running
count. */
#if defined (SDB_DEBUGGING_INFO) || defined (XCOFF_DEBUGGING_INFO)
if (write_symbols == SDB_DEBUG || write_symbols == XCOFF_DEBUG)
next_block_index = 1;
#endif
block_vector = get_block_vector (DECL_INITIAL (fn), &n_blocks);
/* The top-level BLOCK isn't numbered at all. */
for (i = 1; i < n_blocks; ++i)
/* We number the blocks from two. */
BLOCK_NUMBER (block_vector[i]) = next_block_index++;
free (block_vector);
return;
}
/* If VAR is present in a subblock of BLOCK, return the subblock. */
DEBUG_FUNCTION tree
debug_find_var_in_block_tree (tree var, tree block)
{
tree t;
for (t = BLOCK_VARS (block); t; t = TREE_CHAIN (t))
if (t == var)
return block;
for (t = BLOCK_SUBBLOCKS (block); t; t = TREE_CHAIN (t))
{
tree ret = debug_find_var_in_block_tree (var, t);
if (ret)
return ret;
}
return NULL_TREE;
}
/* Keep track of whether we're in a dummy function context. If we are,
we don't want to invoke the set_current_function hook, because we'll
get into trouble if the hook calls target_reinit () recursively or
when the initial initialization is not yet complete. */
static bool in_dummy_function;
/* Invoke the target hook when setting cfun. Update the optimization options
if the function uses different options than the default. */
static void
invoke_set_current_function_hook (tree fndecl)
{
if (!in_dummy_function)
{
tree opts = ((fndecl)
? DECL_FUNCTION_SPECIFIC_OPTIMIZATION (fndecl)
: optimization_default_node);
if (!opts)
opts = optimization_default_node;
/* Change optimization options if needed. */
if (optimization_current_node != opts)
{
optimization_current_node = opts;
cl_optimization_restore (&global_options, TREE_OPTIMIZATION (opts));
}
targetm.set_current_function (fndecl);
this_fn_optabs = this_target_optabs;
if (opts != optimization_default_node)
{
init_tree_optimization_optabs (opts);
if (TREE_OPTIMIZATION_OPTABS (opts))
this_fn_optabs = (struct target_optabs *)
TREE_OPTIMIZATION_OPTABS (opts);
}
}
}
/* cfun should never be set directly; use this function. */
void
set_cfun (struct function *new_cfun)
{
if (cfun != new_cfun)
{
cfun = new_cfun;
invoke_set_current_function_hook (new_cfun ? new_cfun->decl : NULL_TREE);
}
}
/* Initialized with NOGC, making this poisonous to the garbage collector. */
static vec cfun_stack;
/* Push the current cfun onto the stack, and set cfun to new_cfun. Also set
current_function_decl accordingly. */
void
push_cfun (struct function *new_cfun)
{
gcc_assert ((!cfun && !current_function_decl)
|| (cfun && current_function_decl == cfun->decl));
cfun_stack.safe_push (cfun);
current_function_decl = new_cfun ? new_cfun->decl : NULL_TREE;
set_cfun (new_cfun);
}
/* Pop cfun from the stack. Also set current_function_decl accordingly. */
void
pop_cfun (void)
{
struct function *new_cfun = cfun_stack.pop ();
/* When in_dummy_function, we do have a cfun but current_function_decl is
NULL. We also allow pushing NULL cfun and subsequently changing
current_function_decl to something else and have both restored by
pop_cfun. */
gcc_checking_assert (in_dummy_function
|| !cfun
|| current_function_decl == cfun->decl);
set_cfun (new_cfun);
current_function_decl = new_cfun ? new_cfun->decl : NULL_TREE;
}
/* Return value of funcdef and increase it. */
int
get_next_funcdef_no (void)
{
return funcdef_no++;
}
/* Return value of funcdef. */
int
get_last_funcdef_no (void)
{
return funcdef_no;
}
/* Allocate a function structure for FNDECL and set its contents
to the defaults. Set cfun to the newly-allocated object.
Some of the helper functions invoked during initialization assume
that cfun has already been set. Therefore, assign the new object
directly into cfun and invoke the back end hook explicitly at the
very end, rather than initializing a temporary and calling set_cfun
on it.
ABSTRACT_P is true if this is a function that will never be seen by
the middle-end. Such functions are front-end concepts (like C++
function templates) that do not correspond directly to functions
placed in object files. */
void
allocate_struct_function (tree fndecl, bool abstract_p)
{
tree fntype = fndecl ? TREE_TYPE (fndecl) : NULL_TREE;
cfun = ggc_alloc_cleared_function ();
init_eh_for_function ();
if (init_machine_status)
cfun->machine = (*init_machine_status) ();
#ifdef OVERRIDE_ABI_FORMAT
OVERRIDE_ABI_FORMAT (fndecl);
#endif
if (fndecl != NULL_TREE)
{
DECL_STRUCT_FUNCTION (fndecl) = cfun;
cfun->decl = fndecl;
current_function_funcdef_no = get_next_funcdef_no ();
}
invoke_set_current_function_hook (fndecl);
if (fndecl != NULL_TREE)
{
tree result = DECL_RESULT (fndecl);
if (!abstract_p && aggregate_value_p (result, fndecl))
{
#ifdef PCC_STATIC_STRUCT_RETURN
cfun->returns_pcc_struct = 1;
#endif
cfun->returns_struct = 1;
}
cfun->stdarg = stdarg_p (fntype);
/* Assume all registers in stdarg functions need to be saved. */
cfun->va_list_gpr_size = VA_LIST_MAX_GPR_SIZE;
cfun->va_list_fpr_size = VA_LIST_MAX_FPR_SIZE;
/* ??? This could be set on a per-function basis by the front-end
but is this worth the hassle? */
cfun->can_throw_non_call_exceptions = flag_non_call_exceptions;
}
}
/* This is like allocate_struct_function, but pushes a new cfun for FNDECL
instead of just setting it. */
void
push_struct_function (tree fndecl)
{
/* When in_dummy_function we might be in the middle of a pop_cfun and
current_function_decl and cfun may not match. */
gcc_assert (in_dummy_function
|| (!cfun && !current_function_decl)
|| (cfun && current_function_decl == cfun->decl));
cfun_stack.safe_push (cfun);
current_function_decl = fndecl;
allocate_struct_function (fndecl, false);
}
/* Reset crtl and other non-struct-function variables to defaults as
appropriate for emitting rtl at the start of a function. */
static void
prepare_function_start (void)
{
gcc_assert (!crtl->emit.x_last_insn);
init_temp_slots ();
init_emit ();
init_varasm_status ();
init_expr ();
default_rtl_profile ();
if (flag_stack_usage_info)
{
cfun->su = ggc_alloc_cleared_stack_usage ();
cfun->su->static_stack_size = -1;
}
cse_not_expected = ! optimize;
/* Caller save not needed yet. */
caller_save_needed = 0;
/* We haven't done register allocation yet. */
reg_renumber = 0;
/* Indicate that we have not instantiated virtual registers yet. */
virtuals_instantiated = 0;
/* Indicate that we want CONCATs now. */
generating_concat_p = 1;
/* Indicate we have no need of a frame pointer yet. */
frame_pointer_needed = 0;
}
/* Initialize the rtl expansion mechanism so that we can do simple things
like generate sequences. This is used to provide a context during global
initialization of some passes. You must call expand_dummy_function_end
to exit this context. */
void
init_dummy_function_start (void)
{
gcc_assert (!in_dummy_function);
in_dummy_function = true;
push_struct_function (NULL_TREE);
prepare_function_start ();
}
/* Generate RTL for the start of the function SUBR (a FUNCTION_DECL tree node)
and initialize static variables for generating RTL for the statements
of the function. */
void
init_function_start (tree subr)
{
if (subr && DECL_STRUCT_FUNCTION (subr))
set_cfun (DECL_STRUCT_FUNCTION (subr));
else
allocate_struct_function (subr, false);
prepare_function_start ();
decide_function_section (subr);
/* Warn if this value is an aggregate type,
regardless of which calling convention we are using for it. */
if (AGGREGATE_TYPE_P (TREE_TYPE (DECL_RESULT (subr))))
warning (OPT_Waggregate_return, "function returns an aggregate");
}
/* Expand code to verify the stack_protect_guard. This is invoked at
the end of a function to be protected. */
#ifndef HAVE_stack_protect_test
# define HAVE_stack_protect_test 0
# define gen_stack_protect_test(x, y, z) (gcc_unreachable (), NULL_RTX)
#endif
void
stack_protect_epilogue (void)
{
tree guard_decl = targetm.stack_protect_guard ();
rtx label = gen_label_rtx ();
rtx x, y, tmp;
x = expand_normal (crtl->stack_protect_guard);
y = expand_normal (guard_decl);
/* Allow the target to compare Y with X without leaking either into
a register. */
switch (HAVE_stack_protect_test != 0)
{
case 1:
tmp = gen_stack_protect_test (x, y, label);
if (tmp)
{
emit_insn (tmp);
break;
}
/* FALLTHRU */
default:
emit_cmp_and_jump_insns (x, y, EQ, NULL_RTX, ptr_mode, 1, label);
break;
}
/* The noreturn predictor has been moved to the tree level. The rtl-level
predictors estimate this branch about 20%, which isn't enough to get
things moved out of line. Since this is the only extant case of adding
a noreturn function at the rtl level, it doesn't seem worth doing ought
except adding the prediction by hand. */
tmp = get_last_insn ();
if (JUMP_P (tmp))
predict_insn_def (tmp, PRED_NORETURN, TAKEN);
expand_call (targetm.stack_protect_fail (), NULL_RTX, /*ignore=*/true);
free_temp_slots ();
emit_label (label);
}
/* Start the RTL for a new function, and set variables used for
emitting RTL.
SUBR is the FUNCTION_DECL node.
PARMS_HAVE_CLEANUPS is nonzero if there are cleanups associated with
the function's parameters, which must be run at any return statement. */
void
expand_function_start (tree subr)
{
/* Make sure volatile mem refs aren't considered
valid operands of arithmetic insns. */
init_recog_no_volatile ();
crtl->profile
= (profile_flag
&& ! DECL_NO_INSTRUMENT_FUNCTION_ENTRY_EXIT (subr));
crtl->limit_stack
= (stack_limit_rtx != NULL_RTX && ! DECL_NO_LIMIT_STACK (subr));
/* Make the label for return statements to jump to. Do not special
case machines with special return instructions -- they will be
handled later during jump, ifcvt, or epilogue creation. */
return_label = gen_label_rtx ();
/* Initialize rtx used to return the value. */
/* Do this before assign_parms so that we copy the struct value address
before any library calls that assign parms might generate. */
/* Decide whether to return the value in memory or in a register. */
if (aggregate_value_p (DECL_RESULT (subr), subr))
{
/* Returning something that won't go in a register. */
rtx value_address = 0;
#ifdef PCC_STATIC_STRUCT_RETURN
if (cfun->returns_pcc_struct)
{
int size = int_size_in_bytes (TREE_TYPE (DECL_RESULT (subr)));
value_address = assemble_static_space (size);
}
else
#endif
{
rtx sv = targetm.calls.struct_value_rtx (TREE_TYPE (subr), 2);
/* Expect to be passed the address of a place to store the value.
If it is passed as an argument, assign_parms will take care of
it. */
if (sv)
{
value_address = gen_reg_rtx (Pmode);
emit_move_insn (value_address, sv);
}
}
if (value_address)
{
rtx x = value_address;
if (!DECL_BY_REFERENCE (DECL_RESULT (subr)))
{
x = gen_rtx_MEM (DECL_MODE (DECL_RESULT (subr)), x);
set_mem_attributes (x, DECL_RESULT (subr), 1);
}
SET_DECL_RTL (DECL_RESULT (subr), x);
}
}
else if (DECL_MODE (DECL_RESULT (subr)) == VOIDmode)
/* If return mode is void, this decl rtl should not be used. */
SET_DECL_RTL (DECL_RESULT (subr), NULL_RTX);
else
{
/* Compute the return values into a pseudo reg, which we will copy
into the true return register after the cleanups are done. */
tree return_type = TREE_TYPE (DECL_RESULT (subr));
if (TYPE_MODE (return_type) != BLKmode
&& targetm.calls.return_in_msb (return_type))
/* expand_function_end will insert the appropriate padding in
this case. Use the return value's natural (unpadded) mode
within the function proper. */
SET_DECL_RTL (DECL_RESULT (subr),
gen_reg_rtx (TYPE_MODE (return_type)));
else
{
/* In order to figure out what mode to use for the pseudo, we
figure out what the mode of the eventual return register will
actually be, and use that. */
rtx hard_reg = hard_function_value (return_type, subr, 0, 1);
/* Structures that are returned in registers are not
aggregate_value_p, so we may see a PARALLEL or a REG. */
if (REG_P (hard_reg))
SET_DECL_RTL (DECL_RESULT (subr),
gen_reg_rtx (GET_MODE (hard_reg)));
else
{
gcc_assert (GET_CODE (hard_reg) == PARALLEL);
SET_DECL_RTL (DECL_RESULT (subr), gen_group_rtx (hard_reg));
}
}
/* Set DECL_REGISTER flag so that expand_function_end will copy the
result to the real return register(s). */
DECL_REGISTER (DECL_RESULT (subr)) = 1;
}
/* Initialize rtx for parameters and local variables.
In some cases this requires emitting insns. */
assign_parms (subr);
/* If function gets a static chain arg, store it. */
if (cfun->static_chain_decl)
{
tree parm = cfun->static_chain_decl;
rtx local, chain, insn;
local = gen_reg_rtx (Pmode);
chain = targetm.calls.static_chain (current_function_decl, true);
set_decl_incoming_rtl (parm, chain, false);
SET_DECL_RTL (parm, local);
mark_reg_pointer (local, TYPE_ALIGN (TREE_TYPE (TREE_TYPE (parm))));
insn = emit_move_insn (local, chain);
/* Mark the register as eliminable, similar to parameters. */
if (MEM_P (chain)
&& reg_mentioned_p (arg_pointer_rtx, XEXP (chain, 0)))
set_dst_reg_note (insn, REG_EQUIV, chain, local);
}
/* If the function receives a non-local goto, then store the
bits we need to restore the frame pointer. */
if (cfun->nonlocal_goto_save_area)
{
tree t_save;
rtx r_save;
tree var = TREE_OPERAND (cfun->nonlocal_goto_save_area, 0);
gcc_assert (DECL_RTL_SET_P (var));
t_save = build4 (ARRAY_REF,
TREE_TYPE (TREE_TYPE (cfun->nonlocal_goto_save_area)),
cfun->nonlocal_goto_save_area,
integer_zero_node, NULL_TREE, NULL_TREE);
r_save = expand_expr (t_save, NULL_RTX, VOIDmode, EXPAND_WRITE);
gcc_assert (GET_MODE (r_save) == Pmode);
emit_move_insn (r_save, targetm.builtin_setjmp_frame_value ());
update_nonlocal_goto_save_area ();
}
/* The following was moved from init_function_start.
The move is supposed to make sdb output more accurate. */
/* Indicate the beginning of the function body,
as opposed to parm setup. */
emit_note (NOTE_INSN_FUNCTION_BEG);
gcc_assert (NOTE_P (get_last_insn ()));
parm_birth_insn = get_last_insn ();
if (crtl->profile)
{
#ifdef PROFILE_HOOK
PROFILE_HOOK (current_function_funcdef_no);
#endif
}
/* If we are doing generic stack checking, the probe should go here. */
if (flag_stack_check == GENERIC_STACK_CHECK)
stack_check_probe_note = emit_note (NOTE_INSN_DELETED);
}
/* Undo the effects of init_dummy_function_start. */
void
expand_dummy_function_end (void)
{
gcc_assert (in_dummy_function);
/* End any sequences that failed to be closed due to syntax errors. */
while (in_sequence_p ())
end_sequence ();
/* Outside function body, can't compute type's actual size
until next function's body starts. */
free_after_parsing (cfun);
free_after_compilation (cfun);
pop_cfun ();
in_dummy_function = false;
}
/* Call DOIT for each hard register used as a return value from
the current function. */
void
diddle_return_value (void (*doit) (rtx, void *), void *arg)
{
rtx outgoing = crtl->return_rtx;
if (! outgoing)
return;
if (REG_P (outgoing))
(*doit) (outgoing, arg);
else if (GET_CODE (outgoing) == PARALLEL)
{
int i;
for (i = 0; i < XVECLEN (outgoing, 0); i++)
{
rtx x = XEXP (XVECEXP (outgoing, 0, i), 0);
if (REG_P (x) && REGNO (x) < FIRST_PSEUDO_REGISTER)
(*doit) (x, arg);
}
}
}
static void
do_clobber_return_reg (rtx reg, void *arg ATTRIBUTE_UNUSED)
{
emit_clobber (reg);
}
void
clobber_return_register (void)
{
diddle_return_value (do_clobber_return_reg, NULL);
/* In case we do use pseudo to return value, clobber it too. */
if (DECL_RTL_SET_P (DECL_RESULT (current_function_decl)))
{
tree decl_result = DECL_RESULT (current_function_decl);
rtx decl_rtl = DECL_RTL (decl_result);
if (REG_P (decl_rtl) && REGNO (decl_rtl) >= FIRST_PSEUDO_REGISTER)
{
do_clobber_return_reg (decl_rtl, NULL);
}
}
}
static void
do_use_return_reg (rtx reg, void *arg ATTRIBUTE_UNUSED)
{
emit_use (reg);
}
static void
use_return_register (void)
{
diddle_return_value (do_use_return_reg, NULL);
}
/* Possibly warn about unused parameters. */
void
do_warn_unused_parameter (tree fn)
{
tree decl;
for (decl = DECL_ARGUMENTS (fn);
decl; decl = DECL_CHAIN (decl))
if (!TREE_USED (decl) && TREE_CODE (decl) == PARM_DECL
&& DECL_NAME (decl) && !DECL_ARTIFICIAL (decl)
&& !TREE_NO_WARNING (decl))
warning (OPT_Wunused_parameter, "unused parameter %q+D", decl);
}
/* Set the location of the insn chain starting at INSN to LOC. */
static void
set_insn_locations (rtx insn, int loc)
{
while (insn != NULL_RTX)
{
if (INSN_P (insn))
INSN_LOCATION (insn) = loc;
insn = NEXT_INSN (insn);
}
}
/* Generate RTL for the end of the current function. */
void
expand_function_end (void)
{
rtx clobber_after;
/* If arg_pointer_save_area was referenced only from a nested
function, we will not have initialized it yet. Do that now. */
if (arg_pointer_save_area && ! crtl->arg_pointer_save_area_init)
get_arg_pointer_save_area ();
/* If we are doing generic stack checking and this function makes calls,
do a stack probe at the start of the function to ensure we have enough
space for another stack frame. */
if (flag_stack_check == GENERIC_STACK_CHECK)
{
rtx insn, seq;
for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
if (CALL_P (insn))
{
rtx max_frame_size = GEN_INT (STACK_CHECK_MAX_FRAME_SIZE);
start_sequence ();
if (STACK_CHECK_MOVING_SP)
anti_adjust_stack_and_probe (max_frame_size, true);
else
probe_stack_range (STACK_OLD_CHECK_PROTECT, max_frame_size);
seq = get_insns ();
end_sequence ();
set_insn_locations (seq, prologue_location);
emit_insn_before (seq, stack_check_probe_note);
break;
}
}
/* End any sequences that failed to be closed due to syntax errors. */
while (in_sequence_p ())
end_sequence ();
clear_pending_stack_adjust ();
do_pending_stack_adjust ();
/* Output a linenumber for the end of the function.
SDB depends on this. */
set_curr_insn_location (input_location);
/* Before the return label (if any), clobber the return
registers so that they are not propagated live to the rest of
the function. This can only happen with functions that drop
through; if there had been a return statement, there would
have either been a return rtx, or a jump to the return label.
We delay actual code generation after the current_function_value_rtx
is computed. */
clobber_after = get_last_insn ();
/* Output the label for the actual return from the function. */
emit_label (return_label);
if (targetm_common.except_unwind_info (&global_options) == UI_SJLJ)
{
/* Let except.c know where it should emit the call to unregister
the function context for sjlj exceptions. */
if (flag_exceptions)
sjlj_emit_function_exit_after (get_last_insn ());
}
else
{
/* We want to ensure that instructions that may trap are not
moved into the epilogue by scheduling, because we don't
always emit unwind information for the epilogue. */
if (cfun->can_throw_non_call_exceptions)
emit_insn (gen_blockage ());
}
/* If this is an implementation of throw, do what's necessary to
communicate between __builtin_eh_return and the epilogue. */
expand_eh_return ();
/* If scalar return value was computed in a pseudo-reg, or was a named
return value that got dumped to the stack, copy that to the hard
return register. */
if (DECL_RTL_SET_P (DECL_RESULT (current_function_decl)))
{
tree decl_result = DECL_RESULT (current_function_decl);
rtx decl_rtl = DECL_RTL (decl_result);
if (REG_P (decl_rtl)
? REGNO (decl_rtl) >= FIRST_PSEUDO_REGISTER
: DECL_REGISTER (decl_result))
{
rtx real_decl_rtl = crtl->return_rtx;
/* This should be set in assign_parms. */
gcc_assert (REG_FUNCTION_VALUE_P (real_decl_rtl));
/* If this is a BLKmode structure being returned in registers,
then use the mode computed in expand_return. Note that if
decl_rtl is memory, then its mode may have been changed,
but that crtl->return_rtx has not. */
if (GET_MODE (real_decl_rtl) == BLKmode)
PUT_MODE (real_decl_rtl, GET_MODE (decl_rtl));
/* If a non-BLKmode return value should be padded at the least
significant end of the register, shift it left by the appropriate
amount. BLKmode results are handled using the group load/store
machinery. */
if (TYPE_MODE (TREE_TYPE (decl_result)) != BLKmode
&& REG_P (real_decl_rtl)
&& targetm.calls.return_in_msb (TREE_TYPE (decl_result)))
{
emit_move_insn (gen_rtx_REG (GET_MODE (decl_rtl),
REGNO (real_decl_rtl)),
decl_rtl);
shift_return_value (GET_MODE (decl_rtl), true, real_decl_rtl);
}
/* If a named return value dumped decl_return to memory, then
we may need to re-do the PROMOTE_MODE signed/unsigned
extension. */
else if (GET_MODE (real_decl_rtl) != GET_MODE (decl_rtl))
{
int unsignedp = TYPE_UNSIGNED (TREE_TYPE (decl_result));
promote_function_mode (TREE_TYPE (decl_result),
GET_MODE (decl_rtl), &unsignedp,
TREE_TYPE (current_function_decl), 1);
convert_move (real_decl_rtl, decl_rtl, unsignedp);
}
else if (GET_CODE (real_decl_rtl) == PARALLEL)
{
/* If expand_function_start has created a PARALLEL for decl_rtl,
move the result to the real return registers. Otherwise, do
a group load from decl_rtl for a named return. */
if (GET_CODE (decl_rtl) == PARALLEL)
emit_group_move (real_decl_rtl, decl_rtl);
else
emit_group_load (real_decl_rtl, decl_rtl,
TREE_TYPE (decl_result),
int_size_in_bytes (TREE_TYPE (decl_result)));
}
/* In the case of complex integer modes smaller than a word, we'll
need to generate some non-trivial bitfield insertions. Do that
on a pseudo and not the hard register. */
else if (GET_CODE (decl_rtl) == CONCAT
&& GET_MODE_CLASS (GET_MODE (decl_rtl)) == MODE_COMPLEX_INT
&& GET_MODE_BITSIZE (GET_MODE (decl_rtl)) <= BITS_PER_WORD)
{
int old_generating_concat_p;
rtx tmp;
old_generating_concat_p = generating_concat_p;
generating_concat_p = 0;
tmp = gen_reg_rtx (GET_MODE (decl_rtl));
generating_concat_p = old_generating_concat_p;
emit_move_insn (tmp, decl_rtl);
emit_move_insn (real_decl_rtl, tmp);
}
else
emit_move_insn (real_decl_rtl, decl_rtl);
}
}
/* If returning a structure, arrange to return the address of the value
in a place where debuggers expect to find it.
If returning a structure PCC style,
the caller also depends on this value.
And cfun->returns_pcc_struct is not necessarily set. */
if (cfun->returns_struct
|| cfun->returns_pcc_struct)
{
rtx value_address = DECL_RTL (DECL_RESULT (current_function_decl));
tree type = TREE_TYPE (DECL_RESULT (current_function_decl));
rtx outgoing;
if (DECL_BY_REFERENCE (DECL_RESULT (current_function_decl)))
type = TREE_TYPE (type);
else
value_address = XEXP (value_address, 0);
outgoing = targetm.calls.function_value (build_pointer_type (type),
current_function_decl, true);
/* Mark this as a function return value so integrate will delete the
assignment and USE below when inlining this function. */
REG_FUNCTION_VALUE_P (outgoing) = 1;
/* The address may be ptr_mode and OUTGOING may be Pmode. */
value_address = convert_memory_address (GET_MODE (outgoing),
value_address);
emit_move_insn (outgoing, value_address);
/* Show return register used to hold result (in this case the address
of the result. */
crtl->return_rtx = outgoing;
}
/* Emit the actual code to clobber return register. */
{
rtx seq;
start_sequence ();
clobber_return_register ();
seq = get_insns ();
end_sequence ();
emit_insn_after (seq, clobber_after);
}
/* Output the label for the naked return from the function. */
if (naked_return_label)
emit_label (naked_return_label);
/* @@@ This is a kludge. We want to ensure that instructions that
may trap are not moved into the epilogue by scheduling, because
we don't always emit unwind information for the epilogue. */
if (cfun->can_throw_non_call_exceptions
&& targetm_common.except_unwind_info (&global_options) != UI_SJLJ)
emit_insn (gen_blockage ());
/* If stack protection is enabled for this function, check the guard. */
if (crtl->stack_protect_guard)
stack_protect_epilogue ();
/* If we had calls to alloca, and this machine needs
an accurate stack pointer to exit the function,
insert some code to save and restore the stack pointer. */
if (! EXIT_IGNORE_STACK
&& cfun->calls_alloca)
{
rtx tem = 0, seq;
start_sequence ();
emit_stack_save (SAVE_FUNCTION, &tem);
seq = get_insns ();
end_sequence ();
emit_insn_before (seq, parm_birth_insn);
emit_stack_restore (SAVE_FUNCTION, tem);
}
/* ??? This should no longer be necessary since stupid is no longer with
us, but there are some parts of the compiler (eg reload_combine, and
sh mach_dep_reorg) that still try and compute their own lifetime info
instead of using the general framework. */
use_return_register ();
}
rtx
get_arg_pointer_save_area (void)
{
rtx ret = arg_pointer_save_area;
if (! ret)
{
ret = assign_stack_local (Pmode, GET_MODE_SIZE (Pmode), 0);
arg_pointer_save_area = ret;
}
if (! crtl->arg_pointer_save_area_init)
{
rtx seq;
/* Save the arg pointer at the beginning of the function. The
generated stack slot may not be a valid memory address, so we
have to check it and fix it if necessary. */
start_sequence ();
emit_move_insn (validize_mem (ret),
crtl->args.internal_arg_pointer);
seq = get_insns ();
end_sequence ();
push_topmost_sequence ();
emit_insn_after (seq, entry_of_function ());
pop_topmost_sequence ();
crtl->arg_pointer_save_area_init = true;
}
return ret;
}
/* Add a list of INSNS to the hash HASHP, possibly allocating HASHP
for the first time. */
static void
record_insns (rtx insns, rtx end, htab_t *hashp)
{
rtx tmp;
htab_t hash = *hashp;
if (hash == NULL)
*hashp = hash
= htab_create_ggc (17, htab_hash_pointer, htab_eq_pointer, NULL);
for (tmp = insns; tmp != end; tmp = NEXT_INSN (tmp))
{
void **slot = htab_find_slot (hash, tmp, INSERT);
gcc_assert (*slot == NULL);
*slot = tmp;
}
}
/* INSN has been duplicated or replaced by as COPY, perhaps by duplicating a
basic block, splitting or peepholes. If INSN is a prologue or epilogue
insn, then record COPY as well. */
void
maybe_copy_prologue_epilogue_insn (rtx insn, rtx copy)
{
htab_t hash;
void **slot;
hash = epilogue_insn_hash;
if (!hash || !htab_find (hash, insn))
{
hash = prologue_insn_hash;
if (!hash || !htab_find (hash, insn))
return;
}
slot = htab_find_slot (hash, copy, INSERT);
gcc_assert (*slot == NULL);
*slot = copy;
}
/* Determine if any INSNs in HASH are, or are part of, INSN. Because
we can be running after reorg, SEQUENCE rtl is possible. */
static bool
contains (const_rtx insn, htab_t hash)
{
if (hash == NULL)
return false;
if (NONJUMP_INSN_P (insn) && GET_CODE (PATTERN (insn)) == SEQUENCE)
{
int i;
for (i = XVECLEN (PATTERN (insn), 0) - 1; i >= 0; i--)
if (htab_find (hash, XVECEXP (PATTERN (insn), 0, i)))
return true;
return false;
}
return htab_find (hash, insn) != NULL;
}
int
prologue_epilogue_contains (const_rtx insn)
{
if (contains (insn, prologue_insn_hash))
return 1;
if (contains (insn, epilogue_insn_hash))
return 1;
return 0;
}
#ifdef HAVE_simple_return
/* Return true if INSN requires the stack frame to be set up.
PROLOGUE_USED contains the hard registers used in the function
prologue. SET_UP_BY_PROLOGUE is the set of registers we expect the
prologue to set up for the function. */
bool
requires_stack_frame_p (rtx insn, HARD_REG_SET prologue_used,
HARD_REG_SET set_up_by_prologue)
{
df_ref *df_rec;
HARD_REG_SET hardregs;
unsigned regno;
if (CALL_P (insn))
return !SIBLING_CALL_P (insn);
/* We need a frame to get the unique CFA expected by the unwinder. */
if (cfun->can_throw_non_call_exceptions && can_throw_internal (insn))
return true;
CLEAR_HARD_REG_SET (hardregs);
for (df_rec = DF_INSN_DEFS (insn); *df_rec; df_rec++)
{
rtx dreg = DF_REF_REG (*df_rec);
if (!REG_P (dreg))
continue;
add_to_hard_reg_set (&hardregs, GET_MODE (dreg),
REGNO (dreg));
}
if (hard_reg_set_intersect_p (hardregs, prologue_used))
return true;
AND_COMPL_HARD_REG_SET (hardregs, call_used_reg_set);
for (regno = 0; regno < FIRST_PSEUDO_REGISTER; regno++)
if (TEST_HARD_REG_BIT (hardregs, regno)
&& df_regs_ever_live_p (regno))
return true;
for (df_rec = DF_INSN_USES (insn); *df_rec; df_rec++)
{
rtx reg = DF_REF_REG (*df_rec);
if (!REG_P (reg))
continue;
add_to_hard_reg_set (&hardregs, GET_MODE (reg),
REGNO (reg));
}
if (hard_reg_set_intersect_p (hardregs, set_up_by_prologue))
return true;
return false;
}
/* See whether BB has a single successor that uses [REGNO, END_REGNO),
and if BB is its only predecessor. Return that block if so,
otherwise return null. */
static basic_block
next_block_for_reg (basic_block bb, int regno, int end_regno)
{
edge e, live_edge;
edge_iterator ei;
bitmap live;
int i;
live_edge = NULL;
FOR_EACH_EDGE (e, ei, bb->succs)
{
live = df_get_live_in (e->dest);
for (i = regno; i < end_regno; i++)
if (REGNO_REG_SET_P (live, i))
{
if (live_edge && live_edge != e)
return NULL;
live_edge = e;
}
}
/* We can sometimes encounter dead code. Don't try to move it
into the exit block. */
if (!live_edge || live_edge->dest == EXIT_BLOCK_PTR)
return NULL;
/* Reject targets of abnormal edges. This is needed for correctness
on ports like Alpha and MIPS, whose pic_offset_table_rtx can die on
exception edges even though it is generally treated as call-saved
for the majority of the compilation. Moving across abnormal edges
isn't going to be interesting for shrink-wrap usage anyway. */
if (live_edge->flags & EDGE_ABNORMAL)
return NULL;
if (EDGE_COUNT (live_edge->dest->preds) > 1)
return NULL;
return live_edge->dest;
}
/* Try to move INSN from BB to a successor. Return true on success.
USES and DEFS are the set of registers that are used and defined
after INSN in BB. */
static bool
move_insn_for_shrink_wrap (basic_block bb, rtx insn,
const HARD_REG_SET uses,
const HARD_REG_SET defs)
{
rtx set, src, dest;
bitmap live_out, live_in, bb_uses, bb_defs;
unsigned int i, dregno, end_dregno, sregno, end_sregno;
basic_block next_block;
/* Look for a simple register copy. */
set = single_set (insn);
if (!set)
return false;
src = SET_SRC (set);
dest = SET_DEST (set);
if (!REG_P (dest) || !REG_P (src))
return false;
/* Make sure that the source register isn't defined later in BB. */
sregno = REGNO (src);
end_sregno = END_REGNO (src);
if (overlaps_hard_reg_set_p (defs, GET_MODE (src), sregno))
return false;
/* Make sure that the destination register isn't referenced later in BB. */
dregno = REGNO (dest);
end_dregno = END_REGNO (dest);
if (overlaps_hard_reg_set_p (uses, GET_MODE (dest), dregno)
|| overlaps_hard_reg_set_p (defs, GET_MODE (dest), dregno))
return false;
/* See whether there is a successor block to which we could move INSN. */
next_block = next_block_for_reg (bb, dregno, end_dregno);
if (!next_block)
return false;
/* At this point we are committed to moving INSN, but let's try to
move it as far as we can. */
do
{
live_out = df_get_live_out (bb);
live_in = df_get_live_in (next_block);
bb = next_block;
/* Check whether BB uses DEST or clobbers DEST. We need to add
INSN to BB if so. Either way, DEST is no longer live on entry,
except for any part that overlaps SRC (next loop). */
bb_uses = &DF_LR_BB_INFO (bb)->use;
bb_defs = &DF_LR_BB_INFO (bb)->def;
if (df_live)
{
for (i = dregno; i < end_dregno; i++)
{
if (REGNO_REG_SET_P (bb_uses, i) || REGNO_REG_SET_P (bb_defs, i)
|| REGNO_REG_SET_P (&DF_LIVE_BB_INFO (bb)->gen, i))
next_block = NULL;
CLEAR_REGNO_REG_SET (live_out, i);
CLEAR_REGNO_REG_SET (live_in, i);
}
/* Check whether BB clobbers SRC. We need to add INSN to BB if so.
Either way, SRC is now live on entry. */
for (i = sregno; i < end_sregno; i++)
{
if (REGNO_REG_SET_P (bb_defs, i)
|| REGNO_REG_SET_P (&DF_LIVE_BB_INFO (bb)->gen, i))
next_block = NULL;
SET_REGNO_REG_SET (live_out, i);
SET_REGNO_REG_SET (live_in, i);
}
}
else
{
/* DF_LR_BB_INFO (bb)->def does not comprise the DF_REF_PARTIAL and
DF_REF_CONDITIONAL defs. So if DF_LIVE doesn't exist, i.e.
at -O1, just give up searching NEXT_BLOCK. */
next_block = NULL;
for (i = dregno; i < end_dregno; i++)
{
CLEAR_REGNO_REG_SET (live_out, i);
CLEAR_REGNO_REG_SET (live_in, i);
}
for (i = sregno; i < end_sregno; i++)
{
SET_REGNO_REG_SET (live_out, i);
SET_REGNO_REG_SET (live_in, i);
}
}
/* If we don't need to add the move to BB, look for a single
successor block. */
if (next_block)
next_block = next_block_for_reg (next_block, dregno, end_dregno);
}
while (next_block);
/* BB now defines DEST. It only uses the parts of DEST that overlap SRC
(next loop). */
for (i = dregno; i < end_dregno; i++)
{
CLEAR_REGNO_REG_SET (bb_uses, i);
SET_REGNO_REG_SET (bb_defs, i);
}
/* BB now uses SRC. */
for (i = sregno; i < end_sregno; i++)
SET_REGNO_REG_SET (bb_uses, i);
emit_insn_after (PATTERN (insn), bb_note (bb));
delete_insn (insn);
return true;
}
/* Look for register copies in the first block of the function, and move
them down into successor blocks if the register is used only on one
path. This exposes more opportunities for shrink-wrapping. These
kinds of sets often occur when incoming argument registers are moved
to call-saved registers because their values are live across one or
more calls during the function. */
static void
prepare_shrink_wrap (basic_block entry_block)
{
rtx insn, curr, x;
HARD_REG_SET uses, defs;
df_ref *ref;
CLEAR_HARD_REG_SET (uses);
CLEAR_HARD_REG_SET (defs);
FOR_BB_INSNS_REVERSE_SAFE (entry_block, insn, curr)
if (NONDEBUG_INSN_P (insn)
&& !move_insn_for_shrink_wrap (entry_block, insn, uses, defs))
{
/* Add all defined registers to DEFs. */
for (ref = DF_INSN_DEFS (insn); *ref; ref++)
{
x = DF_REF_REG (*ref);
if (REG_P (x) && HARD_REGISTER_P (x))
SET_HARD_REG_BIT (defs, REGNO (x));
}
/* Add all used registers to USESs. */
for (ref = DF_INSN_USES (insn); *ref; ref++)
{
x = DF_REF_REG (*ref);
if (REG_P (x) && HARD_REGISTER_P (x))
SET_HARD_REG_BIT (uses, REGNO (x));
}
}
}
#endif
#ifdef HAVE_return
/* Insert use of return register before the end of BB. */
static void
emit_use_return_register_into_block (basic_block bb)
{
rtx seq, insn;
start_sequence ();
use_return_register ();
seq = get_insns ();
end_sequence ();
insn = BB_END (bb);
#ifdef HAVE_cc0
if (reg_mentioned_p (cc0_rtx, PATTERN (insn)))
insn = prev_cc0_setter (insn);
#endif
emit_insn_before (seq, insn);
}
/* Create a return pattern, either simple_return or return, depending on
simple_p. */
static rtx
gen_return_pattern (bool simple_p)
{
#ifdef HAVE_simple_return
return simple_p ? gen_simple_return () : gen_return ();
#else
gcc_assert (!simple_p);
return gen_return ();
#endif
}
/* Insert an appropriate return pattern at the end of block BB. This
also means updating block_for_insn appropriately. SIMPLE_P is
the same as in gen_return_pattern and passed to it. */
static void
emit_return_into_block (bool simple_p, basic_block bb)
{
rtx jump, pat;
jump = emit_jump_insn_after (gen_return_pattern (simple_p), BB_END (bb));
pat = PATTERN (jump);
if (GET_CODE (pat) == PARALLEL)
pat = XVECEXP (pat, 0, 0);
gcc_assert (ANY_RETURN_P (pat));
JUMP_LABEL (jump) = pat;
}
#endif
/* Set JUMP_LABEL for a return insn. */
void
set_return_jump_label (rtx returnjump)
{
rtx pat = PATTERN (returnjump);
if (GET_CODE (pat) == PARALLEL)
pat = XVECEXP (pat, 0, 0);
if (ANY_RETURN_P (pat))
JUMP_LABEL (returnjump) = pat;
else
JUMP_LABEL (returnjump) = ret_rtx;
}
#ifdef HAVE_simple_return
/* Create a copy of BB instructions and insert at BEFORE. Redirect
preds of BB to COPY_BB if they don't appear in NEED_PROLOGUE. */
static void
dup_block_and_redirect (basic_block bb, basic_block copy_bb, rtx before,
bitmap_head *need_prologue)
{
edge_iterator ei;
edge e;
rtx insn = BB_END (bb);
/* We know BB has a single successor, so there is no need to copy a
simple jump at the end of BB. */
if (simplejump_p (insn))
insn = PREV_INSN (insn);
start_sequence ();
duplicate_insn_chain (BB_HEAD (bb), insn);
if (dump_file)
{
unsigned count = 0;
for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
if (active_insn_p (insn))
++count;
fprintf (dump_file, "Duplicating bb %d to bb %d, %u active insns.\n",
bb->index, copy_bb->index, count);
}
insn = get_insns ();
end_sequence ();
emit_insn_before (insn, before);
/* Redirect all the paths that need no prologue into copy_bb. */
for (ei = ei_start (bb->preds); (e = ei_safe_edge (ei)); )
if (!bitmap_bit_p (need_prologue, e->src->index))
{
int freq = EDGE_FREQUENCY (e);
copy_bb->count += e->count;
copy_bb->frequency += EDGE_FREQUENCY (e);
e->dest->count -= e->count;
if (e->dest->count < 0)
e->dest->count = 0;
e->dest->frequency -= freq;
if (e->dest->frequency < 0)
e->dest->frequency = 0;
redirect_edge_and_branch_force (e, copy_bb);
continue;
}
else
ei_next (&ei);
}
#endif
#if defined (HAVE_return) || defined (HAVE_simple_return)
/* Return true if there are any active insns between HEAD and TAIL. */
static bool
active_insn_between (rtx head, rtx tail)
{
while (tail)
{
if (active_insn_p (tail))
return true;
if (tail == head)
return false;
tail = PREV_INSN (tail);
}
return false;
}
/* LAST_BB is a block that exits, and empty of active instructions.
Examine its predecessors for jumps that can be converted to
(conditional) returns. */
static vec
convert_jumps_to_returns (basic_block last_bb, bool simple_p,
vec unconverted ATTRIBUTE_UNUSED)
{
int i;
basic_block bb;
rtx label;
edge_iterator ei;
edge e;
vec src_bbs;
src_bbs.create (EDGE_COUNT (last_bb->preds));
FOR_EACH_EDGE (e, ei, last_bb->preds)
if (e->src != ENTRY_BLOCK_PTR)
src_bbs.quick_push (e->src);
label = BB_HEAD (last_bb);
FOR_EACH_VEC_ELT (src_bbs, i, bb)
{
rtx jump = BB_END (bb);
if (!JUMP_P (jump) || JUMP_LABEL (jump) != label)
continue;
e = find_edge (bb, last_bb);
/* If we have an unconditional jump, we can replace that
with a simple return instruction. */
if (simplejump_p (jump))
{
/* The use of the return register might be present in the exit
fallthru block. Either:
- removing the use is safe, and we should remove the use in
the exit fallthru block, or
- removing the use is not safe, and we should add it here.
For now, we conservatively choose the latter. Either of the
2 helps in crossjumping. */
emit_use_return_register_into_block (bb);
emit_return_into_block (simple_p, bb);
delete_insn (jump);
}
/* If we have a conditional jump branching to the last
block, we can try to replace that with a conditional
return instruction. */
else if (condjump_p (jump))
{
rtx dest;
if (simple_p)
dest = simple_return_rtx;
else
dest = ret_rtx;
if (!redirect_jump (jump, dest, 0))
{
#ifdef HAVE_simple_return
if (simple_p)
{
if (dump_file)
fprintf (dump_file,
"Failed to redirect bb %d branch.\n", bb->index);
unconverted.safe_push (e);
}
#endif
continue;
}
/* See comment in simplejump_p case above. */
emit_use_return_register_into_block (bb);
/* If this block has only one successor, it both jumps
and falls through to the fallthru block, so we can't
delete the edge. */
if (single_succ_p (bb))
continue;
}
else
{
#ifdef HAVE_simple_return
if (simple_p)
{
if (dump_file)
fprintf (dump_file,
"Failed to redirect bb %d branch.\n", bb->index);
unconverted.safe_push (e);
}
#endif
continue;
}
/* Fix up the CFG for the successful change we just made. */
redirect_edge_succ (e, EXIT_BLOCK_PTR);
e->flags &= ~EDGE_CROSSING;
}
src_bbs.release ();
return unconverted;
}
/* Emit a return insn for the exit fallthru block. */
static basic_block
emit_return_for_exit (edge exit_fallthru_edge, bool simple_p)
{
basic_block last_bb = exit_fallthru_edge->src;
if (JUMP_P (BB_END (last_bb)))
{
last_bb = split_edge (exit_fallthru_edge);
exit_fallthru_edge = single_succ_edge (last_bb);
}
emit_barrier_after (BB_END (last_bb));
emit_return_into_block (simple_p, last_bb);
exit_fallthru_edge->flags &= ~EDGE_FALLTHRU;
return last_bb;
}
#endif
/* Generate the prologue and epilogue RTL if the machine supports it. Thread
this into place with notes indicating where the prologue ends and where
the epilogue begins. Update the basic block information when possible.
Notes on epilogue placement:
There are several kinds of edges to the exit block:
* a single fallthru edge from LAST_BB
* possibly, edges from blocks containing sibcalls
* possibly, fake edges from infinite loops
The epilogue is always emitted on the fallthru edge from the last basic
block in the function, LAST_BB, into the exit block.
If LAST_BB is empty except for a label, it is the target of every
other basic block in the function that ends in a return. If a
target has a return or simple_return pattern (possibly with
conditional variants), these basic blocks can be changed so that a
return insn is emitted into them, and their target is adjusted to
the real exit block.
Notes on shrink wrapping: We implement a fairly conservative
version of shrink-wrapping rather than the textbook one. We only
generate a single prologue and a single epilogue. This is
sufficient to catch a number of interesting cases involving early
exits.
First, we identify the blocks that require the prologue to occur before
them. These are the ones that modify a call-saved register, or reference
any of the stack or frame pointer registers. To simplify things, we then
mark everything reachable from these blocks as also requiring a prologue.
This takes care of loops automatically, and avoids the need to examine
whether MEMs reference the frame, since it is sufficient to check for
occurrences of the stack or frame pointer.
We then compute the set of blocks for which the need for a prologue
is anticipatable (borrowing terminology from the shrink-wrapping
description in Muchnick's book). These are the blocks which either
require a prologue themselves, or those that have only successors
where the prologue is anticipatable. The prologue needs to be
inserted on all edges from BB1->BB2 where BB2 is in ANTIC and BB1
is not. For the moment, we ensure that only one such edge exists.
The epilogue is placed as described above, but we make a
distinction between inserting return and simple_return patterns
when modifying other blocks that end in a return. Blocks that end
in a sibcall omit the sibcall_epilogue if the block is not in
ANTIC. */
static void
thread_prologue_and_epilogue_insns (void)
{
bool inserted;
#ifdef HAVE_simple_return
vec unconverted_simple_returns = vNULL;
bool nonempty_prologue;
bitmap_head bb_flags;
unsigned max_grow_size;
#endif
rtx returnjump;
rtx seq ATTRIBUTE_UNUSED, epilogue_end ATTRIBUTE_UNUSED;
rtx prologue_seq ATTRIBUTE_UNUSED, split_prologue_seq ATTRIBUTE_UNUSED;
edge e, entry_edge, orig_entry_edge, exit_fallthru_edge;
edge_iterator ei;
df_analyze ();
rtl_profile_for_bb (ENTRY_BLOCK_PTR);
inserted = false;
seq = NULL_RTX;
epilogue_end = NULL_RTX;
returnjump = NULL_RTX;
/* Can't deal with multiple successors of the entry block at the
moment. Function should always have at least one entry
point. */
gcc_assert (single_succ_p (ENTRY_BLOCK_PTR));
entry_edge = single_succ_edge (ENTRY_BLOCK_PTR);
orig_entry_edge = entry_edge;
split_prologue_seq = NULL_RTX;
if (flag_split_stack
&& (lookup_attribute ("no_split_stack", DECL_ATTRIBUTES (cfun->decl))
== NULL))
{
#ifndef HAVE_split_stack_prologue
gcc_unreachable ();
#else
gcc_assert (HAVE_split_stack_prologue);
start_sequence ();
emit_insn (gen_split_stack_prologue ());
split_prologue_seq = get_insns ();
end_sequence ();
record_insns (split_prologue_seq, NULL, &prologue_insn_hash);
set_insn_locations (split_prologue_seq, prologue_location);
#endif
}
prologue_seq = NULL_RTX;
#ifdef HAVE_prologue
if (HAVE_prologue)
{
start_sequence ();
seq = gen_prologue ();
emit_insn (seq);
/* Insert an explicit USE for the frame pointer
if the profiling is on and the frame pointer is required. */
if (crtl->profile && frame_pointer_needed)
emit_use (hard_frame_pointer_rtx);
/* Retain a map of the prologue insns. */
record_insns (seq, NULL, &prologue_insn_hash);
emit_note (NOTE_INSN_PROLOGUE_END);
/* Ensure that instructions are not moved into the prologue when
profiling is on. The call to the profiling routine can be
emitted within the live range of a call-clobbered register. */
if (!targetm.profile_before_prologue () && crtl->profile)
emit_insn (gen_blockage ());
prologue_seq = get_insns ();
end_sequence ();
set_insn_locations (prologue_seq, prologue_location);
}
#endif
#ifdef HAVE_simple_return
bitmap_initialize (&bb_flags, &bitmap_default_obstack);
/* Try to perform a kind of shrink-wrapping, making sure the
prologue/epilogue is emitted only around those parts of the
function that require it. */
nonempty_prologue = false;
for (seq = prologue_seq; seq; seq = NEXT_INSN (seq))
if (!NOTE_P (seq) || NOTE_KIND (seq) != NOTE_INSN_PROLOGUE_END)
{
nonempty_prologue = true;
break;
}
if (flag_shrink_wrap && HAVE_simple_return
&& (targetm.profile_before_prologue () || !crtl->profile)
&& nonempty_prologue && !crtl->calls_eh_return)
{
HARD_REG_SET prologue_clobbered, prologue_used, live_on_edge;
struct hard_reg_set_container set_up_by_prologue;
rtx p_insn;
vec vec;
basic_block bb;
bitmap_head bb_antic_flags;
bitmap_head bb_on_list;
bitmap_head bb_tail;
if (dump_file)
fprintf (dump_file, "Attempting shrink-wrapping optimization.\n");
/* Compute the registers set and used in the prologue. */
CLEAR_HARD_REG_SET (prologue_clobbered);
CLEAR_HARD_REG_SET (prologue_used);
for (p_insn = prologue_seq; p_insn; p_insn = NEXT_INSN (p_insn))
{
HARD_REG_SET this_used;
if (!NONDEBUG_INSN_P (p_insn))
continue;
CLEAR_HARD_REG_SET (this_used);
note_uses (&PATTERN (p_insn), record_hard_reg_uses,
&this_used);
AND_COMPL_HARD_REG_SET (this_used, prologue_clobbered);
IOR_HARD_REG_SET (prologue_used, this_used);
note_stores (PATTERN (p_insn), record_hard_reg_sets,
&prologue_clobbered);
}
prepare_shrink_wrap (entry_edge->dest);
bitmap_initialize (&bb_antic_flags, &bitmap_default_obstack);
bitmap_initialize (&bb_on_list, &bitmap_default_obstack);
bitmap_initialize (&bb_tail, &bitmap_default_obstack);
/* Find the set of basic blocks that require a stack frame,
and blocks that are too big to be duplicated. */
vec.create (n_basic_blocks);
CLEAR_HARD_REG_SET (set_up_by_prologue.set);
add_to_hard_reg_set (&set_up_by_prologue.set, Pmode,
STACK_POINTER_REGNUM);
add_to_hard_reg_set (&set_up_by_prologue.set, Pmode, ARG_POINTER_REGNUM);
if (frame_pointer_needed)
add_to_hard_reg_set (&set_up_by_prologue.set, Pmode,
HARD_FRAME_POINTER_REGNUM);
if (pic_offset_table_rtx)
add_to_hard_reg_set (&set_up_by_prologue.set, Pmode,
PIC_OFFSET_TABLE_REGNUM);
if (crtl->drap_reg)
add_to_hard_reg_set (&set_up_by_prologue.set,
GET_MODE (crtl->drap_reg),
REGNO (crtl->drap_reg));
if (targetm.set_up_by_prologue)
targetm.set_up_by_prologue (&set_up_by_prologue);
/* We don't use a different max size depending on
optimize_bb_for_speed_p because increasing shrink-wrapping
opportunities by duplicating tail blocks can actually result
in an overall decrease in code size. */
max_grow_size = get_uncond_jump_length ();
max_grow_size *= PARAM_VALUE (PARAM_MAX_GROW_COPY_BB_INSNS);
FOR_EACH_BB (bb)
{
rtx insn;
unsigned size = 0;
FOR_BB_INSNS (bb, insn)
if (NONDEBUG_INSN_P (insn))
{
if (requires_stack_frame_p (insn, prologue_used,
set_up_by_prologue.set))
{
if (bb == entry_edge->dest)
goto fail_shrinkwrap;
bitmap_set_bit (&bb_flags, bb->index);
vec.quick_push (bb);
break;
}
else if (size <= max_grow_size)
{
size += get_attr_min_length (insn);
if (size > max_grow_size)
bitmap_set_bit (&bb_on_list, bb->index);
}
}
}
/* Blocks that really need a prologue, or are too big for tails. */
bitmap_ior_into (&bb_on_list, &bb_flags);
/* For every basic block that needs a prologue, mark all blocks
reachable from it, so as to ensure they are also seen as
requiring a prologue. */
while (!vec.is_empty ())
{
basic_block tmp_bb = vec.pop ();
FOR_EACH_EDGE (e, ei, tmp_bb->succs)
if (e->dest != EXIT_BLOCK_PTR
&& bitmap_set_bit (&bb_flags, e->dest->index))
vec.quick_push (e->dest);
}
/* Find the set of basic blocks that need no prologue, have a
single successor, can be duplicated, meet a max size
requirement, and go to the exit via like blocks. */
vec.quick_push (EXIT_BLOCK_PTR);
while (!vec.is_empty ())
{
basic_block tmp_bb = vec.pop ();
FOR_EACH_EDGE (e, ei, tmp_bb->preds)
if (single_succ_p (e->src)
&& !bitmap_bit_p (&bb_on_list, e->src->index)
&& can_duplicate_block_p (e->src))
{
edge pe;
edge_iterator pei;
/* If there is predecessor of e->src which doesn't
need prologue and the edge is complex,
we might not be able to redirect the branch
to a copy of e->src. */
FOR_EACH_EDGE (pe, pei, e->src->preds)
if ((pe->flags & EDGE_COMPLEX) != 0
&& !bitmap_bit_p (&bb_flags, pe->src->index))
break;
if (pe == NULL && bitmap_set_bit (&bb_tail, e->src->index))
vec.quick_push (e->src);
}
}
/* Now walk backwards from every block that is marked as needing
a prologue to compute the bb_antic_flags bitmap. Exclude
tail blocks; They can be duplicated to be used on paths not
needing a prologue. */
bitmap_clear (&bb_on_list);
bitmap_and_compl (&bb_antic_flags, &bb_flags, &bb_tail);
FOR_EACH_BB (bb)
{
if (!bitmap_bit_p (&bb_antic_flags, bb->index))
continue;
FOR_EACH_EDGE (e, ei, bb->preds)
if (!bitmap_bit_p (&bb_antic_flags, e->src->index)
&& bitmap_set_bit (&bb_on_list, e->src->index))
vec.quick_push (e->src);
}
while (!vec.is_empty ())
{
basic_block tmp_bb = vec.pop ();
bool all_set = true;
bitmap_clear_bit (&bb_on_list, tmp_bb->index);
FOR_EACH_EDGE (e, ei, tmp_bb->succs)
if (!bitmap_bit_p (&bb_antic_flags, e->dest->index))
{
all_set = false;
break;
}
if (all_set)
{
bitmap_set_bit (&bb_antic_flags, tmp_bb->index);
FOR_EACH_EDGE (e, ei, tmp_bb->preds)
if (!bitmap_bit_p (&bb_antic_flags, e->src->index)
&& bitmap_set_bit (&bb_on_list, e->src->index))
vec.quick_push (e->src);
}
}
/* Find exactly one edge that leads to a block in ANTIC from
a block that isn't. */
if (!bitmap_bit_p (&bb_antic_flags, entry_edge->dest->index))
FOR_EACH_BB (bb)
{
if (!bitmap_bit_p (&bb_antic_flags, bb->index))
continue;
FOR_EACH_EDGE (e, ei, bb->preds)
if (!bitmap_bit_p (&bb_antic_flags, e->src->index))
{
if (entry_edge != orig_entry_edge)
{
entry_edge = orig_entry_edge;
if (dump_file)
fprintf (dump_file, "More than one candidate edge.\n");
goto fail_shrinkwrap;
}
if (dump_file)
fprintf (dump_file, "Found candidate edge for "
"shrink-wrapping, %d->%d.\n", e->src->index,
e->dest->index);
entry_edge = e;
}
}
if (entry_edge != orig_entry_edge)
{
/* Test whether the prologue is known to clobber any register
(other than FP or SP) which are live on the edge. */
CLEAR_HARD_REG_BIT (prologue_clobbered, STACK_POINTER_REGNUM);
if (frame_pointer_needed)
CLEAR_HARD_REG_BIT (prologue_clobbered, HARD_FRAME_POINTER_REGNUM);
REG_SET_TO_HARD_REG_SET (live_on_edge,
df_get_live_in (entry_edge->dest));
if (hard_reg_set_intersect_p (live_on_edge, prologue_clobbered))
{
entry_edge = orig_entry_edge;
if (dump_file)
fprintf (dump_file,
"Shrink-wrapping aborted due to clobber.\n");
}
}
if (entry_edge != orig_entry_edge)
{
crtl->shrink_wrapped = true;
if (dump_file)
fprintf (dump_file, "Performing shrink-wrapping.\n");
/* Find tail blocks reachable from both blocks needing a
prologue and blocks not needing a prologue. */
if (!bitmap_empty_p (&bb_tail))
FOR_EACH_BB (bb)
{
bool some_pro, some_no_pro;
if (!bitmap_bit_p (&bb_tail, bb->index))
continue;
some_pro = some_no_pro = false;
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (bitmap_bit_p (&bb_flags, e->src->index))
some_pro = true;
else
some_no_pro = true;
}
if (some_pro && some_no_pro)
vec.quick_push (bb);
else
bitmap_clear_bit (&bb_tail, bb->index);
}
/* Find the head of each tail. */
while (!vec.is_empty ())
{
basic_block tbb = vec.pop ();
if (!bitmap_bit_p (&bb_tail, tbb->index))
continue;
while (single_succ_p (tbb))
{
tbb = single_succ (tbb);
bitmap_clear_bit (&bb_tail, tbb->index);
}
}
/* Now duplicate the tails. */
if (!bitmap_empty_p (&bb_tail))
FOR_EACH_BB_REVERSE (bb)
{
basic_block copy_bb, tbb;
rtx insert_point;
int eflags;
if (!bitmap_clear_bit (&bb_tail, bb->index))
continue;
/* Create a copy of BB, instructions and all, for
use on paths that don't need a prologue.
Ideal placement of the copy is on a fall-thru edge
or after a block that would jump to the copy. */
FOR_EACH_EDGE (e, ei, bb->preds)
if (!bitmap_bit_p (&bb_flags, e->src->index)
&& single_succ_p (e->src))
break;
if (e)
{
/* Make sure we insert after any barriers. */
rtx end = get_last_bb_insn (e->src);
copy_bb = create_basic_block (NEXT_INSN (end),
NULL_RTX, e->src);
BB_COPY_PARTITION (copy_bb, e->src);
}
else
{
/* Otherwise put the copy at the end of the function. */
copy_bb = create_basic_block (NULL_RTX, NULL_RTX,
EXIT_BLOCK_PTR->prev_bb);
BB_COPY_PARTITION (copy_bb, bb);
}
insert_point = emit_note_after (NOTE_INSN_DELETED,
BB_END (copy_bb));
emit_barrier_after (BB_END (copy_bb));
tbb = bb;
while (1)
{
dup_block_and_redirect (tbb, copy_bb, insert_point,
&bb_flags);
tbb = single_succ (tbb);
if (tbb == EXIT_BLOCK_PTR)
break;
e = split_block (copy_bb, PREV_INSN (insert_point));
copy_bb = e->dest;
}
/* Quiet verify_flow_info by (ab)using EDGE_FAKE.
We have yet to add a simple_return to the tails,
as we'd like to first convert_jumps_to_returns in
case the block is no longer used after that. */
eflags = EDGE_FAKE;
if (CALL_P (PREV_INSN (insert_point))
&& SIBLING_CALL_P (PREV_INSN (insert_point)))
eflags = EDGE_SIBCALL | EDGE_ABNORMAL;
make_single_succ_edge (copy_bb, EXIT_BLOCK_PTR, eflags);
/* verify_flow_info doesn't like a note after a
sibling call. */
delete_insn (insert_point);
if (bitmap_empty_p (&bb_tail))
break;
}
}
fail_shrinkwrap:
bitmap_clear (&bb_tail);
bitmap_clear (&bb_antic_flags);
bitmap_clear (&bb_on_list);
vec.release ();
}
#endif
if (split_prologue_seq != NULL_RTX)
{
insert_insn_on_edge (split_prologue_seq, orig_entry_edge);
inserted = true;
}
if (prologue_seq != NULL_RTX)
{
insert_insn_on_edge (prologue_seq, entry_edge);
inserted = true;
}
/* If the exit block has no non-fake predecessors, we don't need
an epilogue. */
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
if ((e->flags & EDGE_FAKE) == 0)
break;
if (e == NULL)
goto epilogue_done;
rtl_profile_for_bb (EXIT_BLOCK_PTR);
exit_fallthru_edge = find_fallthru_edge (EXIT_BLOCK_PTR->preds);
/* If we're allowed to generate a simple return instruction, then by
definition we don't need a full epilogue. If the last basic
block before the exit block does not contain active instructions,
examine its predecessors and try to emit (conditional) return
instructions. */
#ifdef HAVE_simple_return
if (entry_edge != orig_entry_edge)
{
if (optimize)
{
unsigned i, last;
/* convert_jumps_to_returns may add to EXIT_BLOCK_PTR->preds
(but won't remove). Stop at end of current preds. */
last = EDGE_COUNT (EXIT_BLOCK_PTR->preds);
for (i = 0; i < last; i++)
{
e = EDGE_I (EXIT_BLOCK_PTR->preds, i);
if (LABEL_P (BB_HEAD (e->src))
&& !bitmap_bit_p (&bb_flags, e->src->index)
&& !active_insn_between (BB_HEAD (e->src), BB_END (e->src)))
unconverted_simple_returns
= convert_jumps_to_returns (e->src, true,
unconverted_simple_returns);
}
}
if (exit_fallthru_edge != NULL
&& EDGE_COUNT (exit_fallthru_edge->src->preds) != 0
&& !bitmap_bit_p (&bb_flags, exit_fallthru_edge->src->index))
{
basic_block last_bb;
last_bb = emit_return_for_exit (exit_fallthru_edge, true);
returnjump = BB_END (last_bb);
exit_fallthru_edge = NULL;
}
}
#endif
#ifdef HAVE_return
if (HAVE_return)
{
if (exit_fallthru_edge == NULL)
goto epilogue_done;
if (optimize)
{
basic_block last_bb = exit_fallthru_edge->src;
if (LABEL_P (BB_HEAD (last_bb))
&& !active_insn_between (BB_HEAD (last_bb), BB_END (last_bb)))
convert_jumps_to_returns (last_bb, false, vNULL);
if (EDGE_COUNT (last_bb->preds) != 0
&& single_succ_p (last_bb))
{
last_bb = emit_return_for_exit (exit_fallthru_edge, false);
epilogue_end = returnjump = BB_END (last_bb);
#ifdef HAVE_simple_return
/* Emitting the return may add a basic block.
Fix bb_flags for the added block. */
if (last_bb != exit_fallthru_edge->src)
bitmap_set_bit (&bb_flags, last_bb->index);
#endif
goto epilogue_done;
}
}
}
#endif
/* A small fib -- epilogue is not yet completed, but we wish to re-use
this marker for the splits of EH_RETURN patterns, and nothing else
uses the flag in the meantime. */
epilogue_completed = 1;
#ifdef HAVE_eh_return
/* Find non-fallthru edges that end with EH_RETURN instructions. On
some targets, these get split to a special version of the epilogue
code. In order to be able to properly annotate these with unwind
info, try to split them now. If we get a valid split, drop an
EPILOGUE_BEG note and mark the insns as epilogue insns. */
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
{
rtx prev, last, trial;
if (e->flags & EDGE_FALLTHRU)
continue;
last = BB_END (e->src);
if (!eh_returnjump_p (last))
continue;
prev = PREV_INSN (last);
trial = try_split (PATTERN (last), last, 1);
if (trial == last)
continue;
record_insns (NEXT_INSN (prev), NEXT_INSN (trial), &epilogue_insn_hash);
emit_note_after (NOTE_INSN_EPILOGUE_BEG, prev);
}
#endif
/* If nothing falls through into the exit block, we don't need an
epilogue. */
if (exit_fallthru_edge == NULL)
goto epilogue_done;
#ifdef HAVE_epilogue
if (HAVE_epilogue)
{
start_sequence ();
epilogue_end = emit_note (NOTE_INSN_EPILOGUE_BEG);
seq = gen_epilogue ();
if (seq)
emit_jump_insn (seq);
/* Retain a map of the epilogue insns. */
record_insns (seq, NULL, &epilogue_insn_hash);
set_insn_locations (seq, epilogue_location);
seq = get_insns ();
returnjump = get_last_insn ();
end_sequence ();
insert_insn_on_edge (seq, exit_fallthru_edge);
inserted = true;
if (JUMP_P (returnjump))
set_return_jump_label (returnjump);
}
else
#endif
{
basic_block cur_bb;
if (! next_active_insn (BB_END (exit_fallthru_edge->src)))
goto epilogue_done;
/* We have a fall-through edge to the exit block, the source is not
at the end of the function, and there will be an assembler epilogue
at the end of the function.
We can't use force_nonfallthru here, because that would try to
use return. Inserting a jump 'by hand' is extremely messy, so
we take advantage of cfg_layout_finalize using
fixup_fallthru_exit_predecessor. */
cfg_layout_initialize (0);
FOR_EACH_BB (cur_bb)
if (cur_bb->index >= NUM_FIXED_BLOCKS
&& cur_bb->next_bb->index >= NUM_FIXED_BLOCKS)
cur_bb->aux = cur_bb->next_bb;
cfg_layout_finalize ();
}
epilogue_done:
default_rtl_profile ();
if (inserted)
{
sbitmap blocks;
commit_edge_insertions ();
/* Look for basic blocks within the prologue insns. */
blocks = sbitmap_alloc (last_basic_block);
bitmap_clear (blocks);
bitmap_set_bit (blocks, entry_edge->dest->index);
bitmap_set_bit (blocks, orig_entry_edge->dest->index);
find_many_sub_basic_blocks (blocks);
sbitmap_free (blocks);
/* The epilogue insns we inserted may cause the exit edge to no longer
be fallthru. */
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
{
if (((e->flags & EDGE_FALLTHRU) != 0)
&& returnjump_p (BB_END (e->src)))
e->flags &= ~EDGE_FALLTHRU;
}
}
#ifdef HAVE_simple_return
/* If there were branches to an empty LAST_BB which we tried to
convert to conditional simple_returns, but couldn't for some
reason, create a block to hold a simple_return insn and redirect
those remaining edges. */
if (!unconverted_simple_returns.is_empty ())
{
basic_block simple_return_block_hot = NULL;
basic_block simple_return_block_cold = NULL;
edge pending_edge_hot = NULL;
edge pending_edge_cold = NULL;
basic_block exit_pred;
int i;
gcc_assert (entry_edge != orig_entry_edge);
/* See if we can reuse the last insn that was emitted for the
epilogue. */
if (returnjump != NULL_RTX
&& JUMP_LABEL (returnjump) == simple_return_rtx)
{
e = split_block (BLOCK_FOR_INSN (returnjump), PREV_INSN (returnjump));
if (BB_PARTITION (e->src) == BB_HOT_PARTITION)
simple_return_block_hot = e->dest;
else
simple_return_block_cold = e->dest;
}
/* Also check returns we might need to add to tail blocks. */
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
if (EDGE_COUNT (e->src->preds) != 0
&& (e->flags & EDGE_FAKE) != 0
&& !bitmap_bit_p (&bb_flags, e->src->index))
{
if (BB_PARTITION (e->src) == BB_HOT_PARTITION)
pending_edge_hot = e;
else
pending_edge_cold = e;
}
/* Save a pointer to the exit's predecessor BB for use in
inserting new BBs at the end of the function. Do this
after the call to split_block above which may split
the original exit pred. */
exit_pred = EXIT_BLOCK_PTR->prev_bb;
FOR_EACH_VEC_ELT (unconverted_simple_returns, i, e)
{
basic_block *pdest_bb;
edge pending;
if (BB_PARTITION (e->src) == BB_HOT_PARTITION)
{
pdest_bb = &simple_return_block_hot;
pending = pending_edge_hot;
}
else
{
pdest_bb = &simple_return_block_cold;
pending = pending_edge_cold;
}
if (*pdest_bb == NULL && pending != NULL)
{
emit_return_into_block (true, pending->src);
pending->flags &= ~(EDGE_FALLTHRU | EDGE_FAKE);
*pdest_bb = pending->src;
}
else if (*pdest_bb == NULL)
{
basic_block bb;
rtx start;
bb = create_basic_block (NULL, NULL, exit_pred);
BB_COPY_PARTITION (bb, e->src);
start = emit_jump_insn_after (gen_simple_return (),
BB_END (bb));
JUMP_LABEL (start) = simple_return_rtx;
emit_barrier_after (start);
*pdest_bb = bb;
make_edge (bb, EXIT_BLOCK_PTR, 0);
}
redirect_edge_and_branch_force (e, *pdest_bb);
}
unconverted_simple_returns.release ();
}
if (entry_edge != orig_entry_edge)
{
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
if (EDGE_COUNT (e->src->preds) != 0
&& (e->flags & EDGE_FAKE) != 0
&& !bitmap_bit_p (&bb_flags, e->src->index))
{
emit_return_into_block (true, e->src);
e->flags &= ~(EDGE_FALLTHRU | EDGE_FAKE);
}
}
#endif
#ifdef HAVE_sibcall_epilogue
/* Emit sibling epilogues before any sibling call sites. */
for (ei = ei_start (EXIT_BLOCK_PTR->preds); (e = ei_safe_edge (ei)); )
{
basic_block bb = e->src;
rtx insn = BB_END (bb);
rtx ep_seq;
if (!CALL_P (insn)
|| ! SIBLING_CALL_P (insn)
#ifdef HAVE_simple_return
|| (entry_edge != orig_entry_edge
&& !bitmap_bit_p (&bb_flags, bb->index))
#endif
)
{
ei_next (&ei);
continue;
}
ep_seq = gen_sibcall_epilogue ();
if (ep_seq)
{
start_sequence ();
emit_note (NOTE_INSN_EPILOGUE_BEG);
emit_insn (ep_seq);
seq = get_insns ();
end_sequence ();
/* Retain a map of the epilogue insns. Used in life analysis to
avoid getting rid of sibcall epilogue insns. Do this before we
actually emit the sequence. */
record_insns (seq, NULL, &epilogue_insn_hash);
set_insn_locations (seq, epilogue_location);
emit_insn_before (seq, insn);
}
ei_next (&ei);
}
#endif
#ifdef HAVE_epilogue
if (epilogue_end)
{
rtx insn, next;
/* Similarly, move any line notes that appear after the epilogue.
There is no need, however, to be quite so anal about the existence
of such a note. Also possibly move
NOTE_INSN_FUNCTION_BEG notes, as those can be relevant for debug
info generation. */
for (insn = epilogue_end; insn; insn = next)
{
next = NEXT_INSN (insn);
if (NOTE_P (insn)
&& (NOTE_KIND (insn) == NOTE_INSN_FUNCTION_BEG))
reorder_insns (insn, insn, PREV_INSN (epilogue_end));
}
}
#endif
#ifdef HAVE_simple_return
bitmap_clear (&bb_flags);
#endif
/* Threading the prologue and epilogue changes the artificial refs
in the entry and exit blocks. */
epilogue_completed = 1;
df_update_entry_exit_and_calls ();
}
/* Reposition the prologue-end and epilogue-begin notes after
instruction scheduling. */
void
reposition_prologue_and_epilogue_notes (void)
{
#if defined (HAVE_prologue) || defined (HAVE_epilogue) \
|| defined (HAVE_sibcall_epilogue)
/* Since the hash table is created on demand, the fact that it is
non-null is a signal that it is non-empty. */
if (prologue_insn_hash != NULL)
{
size_t len = htab_elements (prologue_insn_hash);
rtx insn, last = NULL, note = NULL;
/* Scan from the beginning until we reach the last prologue insn. */
/* ??? While we do have the CFG intact, there are two problems:
(1) The prologue can contain loops (typically probing the stack),
which means that the end of the prologue isn't in the first bb.
(2) Sometimes the PROLOGUE_END note gets pushed into the next bb. */
for (insn = get_insns (); insn; insn = NEXT_INSN (insn))
{
if (NOTE_P (insn))
{
if (NOTE_KIND (insn) == NOTE_INSN_PROLOGUE_END)
note = insn;
}
else if (contains (insn, prologue_insn_hash))
{
last = insn;
if (--len == 0)
break;
}
}
if (last)
{
if (note == NULL)
{
/* Scan forward looking for the PROLOGUE_END note. It should
be right at the beginning of the block, possibly with other
insn notes that got moved there. */
for (note = NEXT_INSN (last); ; note = NEXT_INSN (note))
{
if (NOTE_P (note)
&& NOTE_KIND (note) == NOTE_INSN_PROLOGUE_END)
break;
}
}
/* Avoid placing note between CODE_LABEL and BASIC_BLOCK note. */
if (LABEL_P (last))
last = NEXT_INSN (last);
reorder_insns (note, note, last);
}
}
if (epilogue_insn_hash != NULL)
{
edge_iterator ei;
edge e;
FOR_EACH_EDGE (e, ei, EXIT_BLOCK_PTR->preds)
{
rtx insn, first = NULL, note = NULL;
basic_block bb = e->src;
/* Scan from the beginning until we reach the first epilogue insn. */
FOR_BB_INSNS (bb, insn)
{
if (NOTE_P (insn))
{
if (NOTE_KIND (insn) == NOTE_INSN_EPILOGUE_BEG)
{
note = insn;
if (first != NULL)
break;
}
}
else if (first == NULL && contains (insn, epilogue_insn_hash))
{
first = insn;
if (note != NULL)
break;
}
}
if (note)
{
/* If the function has a single basic block, and no real
epilogue insns (e.g. sibcall with no cleanup), the
epilogue note can get scheduled before the prologue
note. If we have frame related prologue insns, having
them scanned during the epilogue will result in a crash.
In this case re-order the epilogue note to just before
the last insn in the block. */
if (first == NULL)
first = BB_END (bb);
if (PREV_INSN (first) != note)
reorder_insns (note, note, PREV_INSN (first));
}
}
}
#endif /* HAVE_prologue or HAVE_epilogue */
}
/* Returns the name of function declared by FNDECL. */
const char *
fndecl_name (tree fndecl)
{
if (fndecl == NULL)
return "(nofn)";
return lang_hooks.decl_printable_name (fndecl, 2);
}
/* Returns the name of function FN. */
const char *
function_name (struct function *fn)
{
tree fndecl = (fn == NULL) ? NULL : fn->decl;
return fndecl_name (fndecl);
}
/* Returns the name of the current function. */
const char *
current_function_name (void)
{
return function_name (cfun);
}
static unsigned int
rest_of_handle_check_leaf_regs (void)
{
#ifdef LEAF_REGISTERS
crtl->uses_only_leaf_regs
= optimize > 0 && only_leaf_regs_used () && leaf_function_p ();
#endif
return 0;
}
/* Insert a TYPE into the used types hash table of CFUN. */
static void
used_types_insert_helper (tree type, struct function *func)
{
if (type != NULL && func != NULL)
{
void **slot;
if (func->used_types_hash == NULL)
func->used_types_hash = htab_create_ggc (37, htab_hash_pointer,
htab_eq_pointer, NULL);
slot = htab_find_slot (func->used_types_hash, type, INSERT);
if (*slot == NULL)
*slot = type;
}
}
/* Given a type, insert it into the used hash table in cfun. */
void
used_types_insert (tree t)
{
while (POINTER_TYPE_P (t) || TREE_CODE (t) == ARRAY_TYPE)
if (TYPE_NAME (t))
break;
else
t = TREE_TYPE (t);
if (TREE_CODE (t) == ERROR_MARK)
return;
if (TYPE_NAME (t) == NULL_TREE
|| TYPE_NAME (t) == TYPE_NAME (TYPE_MAIN_VARIANT (t)))
t = TYPE_MAIN_VARIANT (t);
if (debug_info_level > DINFO_LEVEL_NONE)
{
if (cfun)
used_types_insert_helper (t, cfun);
else
{
/* So this might be a type referenced by a global variable.
Record that type so that we can later decide to emit its
debug information. */
vec_safe_push (types_used_by_cur_var_decl, t);
}
}
}
/* Helper to Hash a struct types_used_by_vars_entry. */
static hashval_t
hash_types_used_by_vars_entry (const struct types_used_by_vars_entry *entry)
{
gcc_assert (entry && entry->var_decl && entry->type);
return iterative_hash_object (entry->type,
iterative_hash_object (entry->var_decl, 0));
}
/* Hash function of the types_used_by_vars_entry hash table. */
hashval_t
types_used_by_vars_do_hash (const void *x)
{
const struct types_used_by_vars_entry *entry =
(const struct types_used_by_vars_entry *) x;
return hash_types_used_by_vars_entry (entry);
}
/*Equality function of the types_used_by_vars_entry hash table. */
int
types_used_by_vars_eq (const void *x1, const void *x2)
{
const struct types_used_by_vars_entry *e1 =
(const struct types_used_by_vars_entry *) x1;
const struct types_used_by_vars_entry *e2 =
(const struct types_used_by_vars_entry *)x2;
return (e1->var_decl == e2->var_decl && e1->type == e2->type);
}
/* Inserts an entry into the types_used_by_vars_hash hash table. */
void
types_used_by_var_decl_insert (tree type, tree var_decl)
{
if (type != NULL && var_decl != NULL)
{
void **slot;
struct types_used_by_vars_entry e;
e.var_decl = var_decl;
e.type = type;
if (types_used_by_vars_hash == NULL)
types_used_by_vars_hash =
htab_create_ggc (37, types_used_by_vars_do_hash,
types_used_by_vars_eq, NULL);
slot = htab_find_slot_with_hash (types_used_by_vars_hash, &e,
hash_types_used_by_vars_entry (&e), INSERT);
if (*slot == NULL)
{
struct types_used_by_vars_entry *entry;
entry = ggc_alloc_types_used_by_vars_entry ();
entry->type = type;
entry->var_decl = var_decl;
*slot = entry;
}
}
}
namespace {
const pass_data pass_data_leaf_regs =
{
RTL_PASS, /* type */
"*leaf_regs", /* name */
OPTGROUP_NONE, /* optinfo_flags */
false, /* has_gate */
true, /* has_execute */
TV_NONE, /* tv_id */
0, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
0, /* todo_flags_start */
0, /* todo_flags_finish */
};
class pass_leaf_regs : public rtl_opt_pass
{
public:
pass_leaf_regs (gcc::context *ctxt)
: rtl_opt_pass (pass_data_leaf_regs, ctxt)
{}
/* opt_pass methods: */
unsigned int execute () { return rest_of_handle_check_leaf_regs (); }
}; // class pass_leaf_regs
} // anon namespace
rtl_opt_pass *
make_pass_leaf_regs (gcc::context *ctxt)
{
return new pass_leaf_regs (ctxt);
}
static unsigned int
rest_of_handle_thread_prologue_and_epilogue (void)
{
if (optimize)
cleanup_cfg (CLEANUP_EXPENSIVE);
/* On some machines, the prologue and epilogue code, or parts thereof,
can be represented as RTL. Doing so lets us schedule insns between
it and the rest of the code and also allows delayed branch
scheduling to operate in the epilogue. */
thread_prologue_and_epilogue_insns ();
/* The stack usage info is finalized during prologue expansion. */
if (flag_stack_usage_info)
output_stack_usage ();
return 0;
}
namespace {
const pass_data pass_data_thread_prologue_and_epilogue =
{
RTL_PASS, /* type */
"pro_and_epilogue", /* name */
OPTGROUP_NONE, /* optinfo_flags */
false, /* has_gate */
true, /* has_execute */
TV_THREAD_PROLOGUE_AND_EPILOGUE, /* tv_id */
0, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
TODO_verify_flow, /* todo_flags_start */
( TODO_df_verify | TODO_df_finish
| TODO_verify_rtl_sharing ), /* todo_flags_finish */
};
class pass_thread_prologue_and_epilogue : public rtl_opt_pass
{
public:
pass_thread_prologue_and_epilogue (gcc::context *ctxt)
: rtl_opt_pass (pass_data_thread_prologue_and_epilogue, ctxt)
{}
/* opt_pass methods: */
unsigned int execute () {
return rest_of_handle_thread_prologue_and_epilogue ();
}
}; // class pass_thread_prologue_and_epilogue
} // anon namespace
rtl_opt_pass *
make_pass_thread_prologue_and_epilogue (gcc::context *ctxt)
{
return new pass_thread_prologue_and_epilogue (ctxt);
}
/* This mini-pass fixes fall-out from SSA in asm statements that have
in-out constraints. Say you start with
orig = inout;
asm ("": "+mr" (inout));
use (orig);
which is transformed very early to use explicit output and match operands:
orig = inout;
asm ("": "=mr" (inout) : "0" (inout));
use (orig);
Or, after SSA and copyprop,
asm ("": "=mr" (inout_2) : "0" (inout_1));
use (inout_1);
Clearly inout_2 and inout_1 can't be coalesced easily anymore, as
they represent two separate values, so they will get different pseudo
registers during expansion. Then, since the two operands need to match
per the constraints, but use different pseudo registers, reload can
only register a reload for these operands. But reloads can only be
satisfied by hardregs, not by memory, so we need a register for this
reload, just because we are presented with non-matching operands.
So, even though we allow memory for this operand, no memory can be
used for it, just because the two operands don't match. This can
cause reload failures on register-starved targets.
So it's a symptom of reload not being able to use memory for reloads
or, alternatively it's also a symptom of both operands not coming into
reload as matching (in which case the pseudo could go to memory just
fine, as the alternative allows it, and no reload would be necessary).
We fix the latter problem here, by transforming
asm ("": "=mr" (inout_2) : "0" (inout_1));
back to
inout_2 = inout_1;
asm ("": "=mr" (inout_2) : "0" (inout_2)); */
static void
match_asm_constraints_1 (rtx insn, rtx *p_sets, int noutputs)
{
int i;
bool changed = false;
rtx op = SET_SRC (p_sets[0]);
int ninputs = ASM_OPERANDS_INPUT_LENGTH (op);
rtvec inputs = ASM_OPERANDS_INPUT_VEC (op);
bool *output_matched = XALLOCAVEC (bool, noutputs);
memset (output_matched, 0, noutputs * sizeof (bool));
for (i = 0; i < ninputs; i++)
{
rtx input, output, insns;
const char *constraint = ASM_OPERANDS_INPUT_CONSTRAINT (op, i);
char *end;
int match, j;
if (*constraint == '%')
constraint++;
match = strtoul (constraint, &end, 10);
if (end == constraint)
continue;
gcc_assert (match < noutputs);
output = SET_DEST (p_sets[match]);
input = RTVEC_ELT (inputs, i);
/* Only do the transformation for pseudos. */
if (! REG_P (output)
|| rtx_equal_p (output, input)
|| (GET_MODE (input) != VOIDmode
&& GET_MODE (input) != GET_MODE (output)))
continue;
/* We can't do anything if the output is also used as input,
as we're going to overwrite it. */
for (j = 0; j < ninputs; j++)
if (reg_overlap_mentioned_p (output, RTVEC_ELT (inputs, j)))
break;
if (j != ninputs)
continue;
/* Avoid changing the same input several times. For
asm ("" : "=mr" (out1), "=mr" (out2) : "0" (in), "1" (in));
only change in once (to out1), rather than changing it
first to out1 and afterwards to out2. */
if (i > 0)
{
for (j = 0; j < noutputs; j++)
if (output_matched[j] && input == SET_DEST (p_sets[j]))
break;
if (j != noutputs)
continue;
}
output_matched[match] = true;
start_sequence ();
emit_move_insn (output, input);
insns = get_insns ();
end_sequence ();
emit_insn_before (insns, insn);
/* Now replace all mentions of the input with output. We can't
just replace the occurrence in inputs[i], as the register might
also be used in some other input (or even in an address of an
output), which would mean possibly increasing the number of
inputs by one (namely 'output' in addition), which might pose
a too complicated problem for reload to solve. E.g. this situation:
asm ("" : "=r" (output), "=m" (input) : "0" (input))
Here 'input' is used in two occurrences as input (once for the
input operand, once for the address in the second output operand).
If we would replace only the occurrence of the input operand (to
make the matching) we would be left with this:
output = input
asm ("" : "=r" (output), "=m" (input) : "0" (output))
Now we suddenly have two different input values (containing the same
value, but different pseudos) where we formerly had only one.
With more complicated asms this might lead to reload failures
which wouldn't have happen without this pass. So, iterate over
all operands and replace all occurrences of the register used. */
for (j = 0; j < noutputs; j++)
if (!rtx_equal_p (SET_DEST (p_sets[j]), input)
&& reg_overlap_mentioned_p (input, SET_DEST (p_sets[j])))
SET_DEST (p_sets[j]) = replace_rtx (SET_DEST (p_sets[j]),
input, output);
for (j = 0; j < ninputs; j++)
if (reg_overlap_mentioned_p (input, RTVEC_ELT (inputs, j)))
RTVEC_ELT (inputs, j) = replace_rtx (RTVEC_ELT (inputs, j),
input, output);
changed = true;
}
if (changed)
df_insn_rescan (insn);
}
static unsigned
rest_of_match_asm_constraints (void)
{
basic_block bb;
rtx insn, pat, *p_sets;
int noutputs;
if (!crtl->has_asm_statement)
return 0;
df_set_flags (DF_DEFER_INSN_RESCAN);
FOR_EACH_BB (bb)
{
FOR_BB_INSNS (bb, insn)
{
if (!INSN_P (insn))
continue;
pat = PATTERN (insn);
if (GET_CODE (pat) == PARALLEL)
p_sets = &XVECEXP (pat, 0, 0), noutputs = XVECLEN (pat, 0);
else if (GET_CODE (pat) == SET)
p_sets = &PATTERN (insn), noutputs = 1;
else
continue;
if (GET_CODE (*p_sets) == SET
&& GET_CODE (SET_SRC (*p_sets)) == ASM_OPERANDS)
match_asm_constraints_1 (insn, p_sets, noutputs);
}
}
return TODO_df_finish;
}
namespace {
const pass_data pass_data_match_asm_constraints =
{
RTL_PASS, /* type */
"asmcons", /* name */
OPTGROUP_NONE, /* optinfo_flags */
false, /* has_gate */
true, /* has_execute */
TV_NONE, /* tv_id */
0, /* properties_required */
0, /* properties_provided */
0, /* properties_destroyed */
0, /* todo_flags_start */
0, /* todo_flags_finish */
};
class pass_match_asm_constraints : public rtl_opt_pass
{
public:
pass_match_asm_constraints (gcc::context *ctxt)
: rtl_opt_pass (pass_data_match_asm_constraints, ctxt)
{}
/* opt_pass methods: */
unsigned int execute () { return rest_of_match_asm_constraints (); }
}; // class pass_match_asm_constraints
} // anon namespace
rtl_opt_pass *
make_pass_match_asm_constraints (gcc::context *ctxt)
{
return new pass_match_asm_constraints (ctxt);
}
#include "gt-function.h"