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|
/*
* Example of how to write a compiler with sparse
*/
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <assert.h>
#include "symbol.h"
#include "expression.h"
#include "linearize.h"
#include "flow.h"
#include "storage.h"
#include "target.h"
static const char *opcodes[] = {
[OP_BADOP] = "bad_op",
/* Fn entrypoint */
[OP_ENTRY] = "<entry-point>",
/* Terminator */
[OP_RET] = "ret",
[OP_BR] = "br",
[OP_SWITCH] = "switch",
[OP_INVOKE] = "invoke",
[OP_COMPUTEDGOTO] = "jmp *",
[OP_UNWIND] = "unwind",
/* Binary */
[OP_ADD] = "add",
[OP_SUB] = "sub",
[OP_MULU] = "mulu",
[OP_MULS] = "muls",
[OP_DIVU] = "divu",
[OP_DIVS] = "divs",
[OP_MODU] = "modu",
[OP_MODS] = "mods",
[OP_SHL] = "shl",
[OP_LSR] = "lsr",
[OP_ASR] = "asr",
/* Logical */
[OP_AND] = "and",
[OP_OR] = "or",
[OP_XOR] = "xor",
[OP_AND_BOOL] = "and-bool",
[OP_OR_BOOL] = "or-bool",
/* Binary comparison */
[OP_SET_EQ] = "seteq",
[OP_SET_NE] = "setne",
[OP_SET_LE] = "setle",
[OP_SET_GE] = "setge",
[OP_SET_LT] = "setlt",
[OP_SET_GT] = "setgt",
[OP_SET_B] = "setb",
[OP_SET_A] = "seta",
[OP_SET_BE] = "setbe",
[OP_SET_AE] = "setae",
/* Uni */
[OP_NOT] = "not",
[OP_NEG] = "neg",
/* Special three-input */
[OP_SEL] = "select",
/* Memory */
[OP_MALLOC] = "malloc",
[OP_FREE] = "free",
[OP_ALLOCA] = "alloca",
[OP_LOAD] = "load",
[OP_STORE] = "store",
[OP_SETVAL] = "set",
[OP_GET_ELEMENT_PTR] = "getelem",
/* Other */
[OP_PHI] = "phi",
[OP_PHISOURCE] = "phisrc",
[OP_COPY] = "copy",
[OP_CAST] = "cast",
[OP_SCAST] = "scast",
[OP_FPCAST] = "fpcast",
[OP_PTRCAST] = "ptrcast",
[OP_CALL] = "call",
[OP_VANEXT] = "va_next",
[OP_VAARG] = "va_arg",
[OP_SLICE] = "slice",
[OP_SNOP] = "snop",
[OP_LNOP] = "lnop",
[OP_NOP] = "nop",
[OP_DEATHNOTE] = "dead",
[OP_ASM] = "asm",
/* Sparse tagging (line numbers, context, whatever) */
[OP_CONTEXT] = "context",
};
static int last_reg, stack_offset;
struct hardreg {
const char *name;
struct pseudo_list *contains;
unsigned busy:16,
dead:8,
used:1;
};
#define TAG_DEAD 1
#define TAG_DIRTY 2
/* Our "switch" generation is very very stupid. */
#define SWITCH_REG (1)
static void output_bb(struct basic_block *bb, unsigned long generation);
/*
* We only know about the caller-clobbered registers
* right now.
*/
static struct hardreg hardregs[] = {
{ .name = "%eax" },
{ .name = "%edx" },
{ .name = "%ecx" },
{ .name = "%ebx" },
{ .name = "%esi" },
{ .name = "%edi" },
{ .name = "%ebp" },
{ .name = "%esp" },
};
#define REGNO 6
#define REG_EBP 6
#define REG_ESP 7
struct bb_state {
struct position pos;
struct storage_hash_list *inputs;
struct storage_hash_list *outputs;
struct storage_hash_list *internal;
/* CC cache.. */
int cc_opcode, cc_dead;
pseudo_t cc_target;
};
enum optype {
OP_UNDEF,
OP_REG,
OP_VAL,
OP_MEM,
OP_ADDR,
};
struct operand {
enum optype type;
int size;
union {
struct hardreg *reg;
long long value;
struct /* OP_MEM and OP_ADDR */ {
unsigned int offset;
unsigned int scale;
struct symbol *sym;
struct hardreg *base;
struct hardreg *index;
};
};
};
static const char *show_op(struct bb_state *state, struct operand *op)
{
static char buf[256][4];
static int bufnr;
char *p, *ret;
int nr;
nr = (bufnr + 1) & 3;
bufnr = nr;
ret = p = buf[nr];
switch (op->type) {
case OP_UNDEF:
return "undef";
case OP_REG:
return op->reg->name;
case OP_VAL:
sprintf(p, "$%lld", op->value);
break;
case OP_MEM:
case OP_ADDR:
if (op->offset)
p += sprintf(p, "%d", op->offset);
if (op->sym)
p += sprintf(p, "%s%s",
op->offset ? "+" : "",
show_ident(op->sym->ident));
if (op->base || op->index) {
p += sprintf(p, "(%s%s%s",
op->base ? op->base->name : "",
(op->base && op->index) ? "," : "",
op->index ? op->index->name : "");
if (op->scale > 1)
p += sprintf(p, ",%d", op->scale);
*p++ = ')';
*p = '\0';
}
break;
}
return ret;
}
static struct storage_hash *find_storage_hash(pseudo_t pseudo, struct storage_hash_list *list)
{
struct storage_hash *entry;
FOR_EACH_PTR(list, entry) {
if (entry->pseudo == pseudo)
return entry;
} END_FOR_EACH_PTR(entry);
return NULL;
}
static struct storage_hash *find_or_create_hash(pseudo_t pseudo, struct storage_hash_list **listp)
{
struct storage_hash *entry;
entry = find_storage_hash(pseudo, *listp);
if (!entry) {
entry = alloc_storage_hash(alloc_storage());
entry->pseudo = pseudo;
add_ptr_list(listp, entry);
}
return entry;
}
/* Eventually we should just build it up in memory */
static void FORMAT_ATTR(2) output_line(struct bb_state *state, const char *fmt, ...)
{
va_list args;
va_start(args, fmt);
vprintf(fmt, args);
va_end(args);
}
static void FORMAT_ATTR(2) output_label(struct bb_state *state, const char *fmt, ...)
{
static char buffer[512];
va_list args;
va_start(args, fmt);
vsnprintf(buffer, sizeof(buffer), fmt, args);
va_end(args);
output_line(state, "%s:\n", buffer);
}
static void FORMAT_ATTR(2) output_insn(struct bb_state *state, const char *fmt, ...)
{
static char buffer[512];
va_list args;
va_start(args, fmt);
vsnprintf(buffer, sizeof(buffer), fmt, args);
va_end(args);
output_line(state, "\t%s\n", buffer);
}
#define output_insn(state, fmt, arg...) \
output_insn(state, fmt "\t\t# %s" , ## arg , __FUNCTION__)
static void FORMAT_ATTR(2) output_comment(struct bb_state *state, const char *fmt, ...)
{
static char buffer[512];
va_list args;
if (!verbose)
return;
va_start(args, fmt);
vsnprintf(buffer, sizeof(buffer), fmt, args);
va_end(args);
output_line(state, "\t# %s\n", buffer);
}
static const char *show_memop(struct storage *storage)
{
static char buffer[1000];
if (!storage)
return "undef";
switch (storage->type) {
case REG_FRAME:
sprintf(buffer, "%d(FP)", storage->offset);
break;
case REG_STACK:
sprintf(buffer, "%d(SP)", storage->offset);
break;
case REG_REG:
return hardregs[storage->regno].name;
default:
return show_storage(storage);
}
return buffer;
}
static int alloc_stack_offset(int size)
{
int ret = stack_offset;
stack_offset = ret + size;
return ret;
}
static void alloc_stack(struct bb_state *state, struct storage *storage)
{
storage->type = REG_STACK;
storage->offset = alloc_stack_offset(4);
}
/*
* Can we re-generate the pseudo, so that we don't need to
* flush it to memory? We can regenerate:
* - immediates and symbol addresses
* - pseudos we got as input in non-registers
* - pseudos we've already saved off earlier..
*/
static int can_regenerate(struct bb_state *state, pseudo_t pseudo)
{
struct storage_hash *in;
switch (pseudo->type) {
case PSEUDO_VAL:
case PSEUDO_SYM:
return 1;
default:
in = find_storage_hash(pseudo, state->inputs);
if (in && in->storage->type != REG_REG)
return 1;
in = find_storage_hash(pseudo, state->internal);
if (in)
return 1;
}
return 0;
}
static void flush_one_pseudo(struct bb_state *state, struct hardreg *hardreg, pseudo_t pseudo)
{
struct storage_hash *out;
struct storage *storage;
if (can_regenerate(state, pseudo))
return;
output_comment(state, "flushing %s from %s", show_pseudo(pseudo), hardreg->name);
out = find_storage_hash(pseudo, state->internal);
if (!out) {
out = find_storage_hash(pseudo, state->outputs);
if (!out)
out = find_or_create_hash(pseudo, &state->internal);
}
storage = out->storage;
switch (storage->type) {
default:
/*
* Aieee - the next user wants it in a register, but we
* need to flush it to memory in between. Which means that
* we need to allocate an internal one, dammit..
*/
out = find_or_create_hash(pseudo, &state->internal);
storage = out->storage;
/* Fall through */
case REG_UDEF:
alloc_stack(state, storage);
/* Fall through */
case REG_STACK:
output_insn(state, "movl %s,%s", hardreg->name, show_memop(storage));
break;
}
}
/* Flush a hardreg out to the storage it has.. */
static void flush_reg(struct bb_state *state, struct hardreg *reg)
{
pseudo_t pseudo;
if (reg->busy)
output_comment(state, "reg %s flushed while busy is %d!", reg->name, reg->busy);
if (!reg->contains)
return;
reg->dead = 0;
reg->used = 1;
FOR_EACH_PTR(reg->contains, pseudo) {
if (CURRENT_TAG(pseudo) & TAG_DEAD)
continue;
if (!(CURRENT_TAG(pseudo) & TAG_DIRTY))
continue;
flush_one_pseudo(state, reg, pseudo);
} END_FOR_EACH_PTR(pseudo);
free_ptr_list(®->contains);
}
static struct storage_hash *find_pseudo_storage(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
struct storage_hash *src;
src = find_storage_hash(pseudo, state->internal);
if (!src) {
src = find_storage_hash(pseudo, state->inputs);
if (!src) {
src = find_storage_hash(pseudo, state->outputs);
/* Undefined? Screw it! */
if (!src)
return NULL;
/*
* If we found output storage, it had better be local stack
* that we flushed to earlier..
*/
if (src->storage->type != REG_STACK)
return NULL;
}
}
/*
* Incoming pseudo with out any pre-set storage allocation?
* We can make up our own, and obviously prefer to get it
* in the register we already selected (if it hasn't been
* used yet).
*/
if (src->storage->type == REG_UDEF) {
if (reg && !reg->used) {
src->storage->type = REG_REG;
src->storage->regno = reg - hardregs;
return NULL;
}
alloc_stack(state, src->storage);
}
return src;
}
static void mark_reg_dead(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
pseudo_t p;
FOR_EACH_PTR(reg->contains, p) {
if (p != pseudo)
continue;
if (CURRENT_TAG(p) & TAG_DEAD)
continue;
output_comment(state, "marking pseudo %s in reg %s dead", show_pseudo(pseudo), reg->name);
TAG_CURRENT(p, TAG_DEAD);
reg->dead++;
} END_FOR_EACH_PTR(p);
}
static void add_pseudo_reg(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
output_comment(state, "added pseudo %s to reg %s", show_pseudo(pseudo), reg->name);
add_ptr_list_tag(®->contains, pseudo, TAG_DIRTY);
}
static struct hardreg *preferred_reg(struct bb_state *state, pseudo_t target)
{
struct storage_hash *dst;
dst = find_storage_hash(target, state->outputs);
if (dst) {
struct storage *storage = dst->storage;
if (storage->type == REG_REG)
return hardregs + storage->regno;
}
return NULL;
}
static struct hardreg *empty_reg(struct bb_state *state)
{
int i;
struct hardreg *reg = hardregs;
for (i = 0; i < REGNO; i++, reg++) {
if (!reg->contains)
return reg;
}
return NULL;
}
static struct hardreg *target_reg(struct bb_state *state, pseudo_t pseudo, pseudo_t target)
{
int i;
int unable_to_find_reg = 0;
struct hardreg *reg;
/* First, see if we have a preferred target register.. */
reg = preferred_reg(state, target);
if (reg && !reg->contains)
goto found;
reg = empty_reg(state);
if (reg)
goto found;
i = last_reg;
do {
i++;
if (i >= REGNO)
i = 0;
reg = hardregs + i;
if (!reg->busy) {
flush_reg(state, reg);
last_reg = i;
goto found;
}
} while (i != last_reg);
assert(unable_to_find_reg);
found:
add_pseudo_reg(state, pseudo, reg);
return reg;
}
static struct hardreg *find_in_reg(struct bb_state *state, pseudo_t pseudo)
{
int i;
struct hardreg *reg;
for (i = 0; i < REGNO; i++) {
pseudo_t p;
reg = hardregs + i;
FOR_EACH_PTR(reg->contains, p) {
if (p == pseudo) {
last_reg = i;
output_comment(state, "found pseudo %s in reg %s (busy=%d)", show_pseudo(pseudo), reg->name, reg->busy);
return reg;
}
} END_FOR_EACH_PTR(p);
}
return NULL;
}
static void flush_pseudo(struct bb_state *state, pseudo_t pseudo, struct storage *storage)
{
struct hardreg *reg = find_in_reg(state, pseudo);
if (reg)
flush_reg(state, reg);
}
static void flush_cc_cache_to_reg(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
int opcode = state->cc_opcode;
state->cc_opcode = 0;
state->cc_target = NULL;
output_insn(state, "%s %s", opcodes[opcode], reg->name);
}
static void flush_cc_cache(struct bb_state *state)
{
pseudo_t pseudo = state->cc_target;
if (pseudo) {
struct hardreg *dst;
state->cc_target = NULL;
if (!state->cc_dead) {
dst = target_reg(state, pseudo, pseudo);
flush_cc_cache_to_reg(state, pseudo, dst);
}
}
}
static void add_cc_cache(struct bb_state *state, int opcode, pseudo_t pseudo)
{
assert(!state->cc_target);
state->cc_target = pseudo;
state->cc_opcode = opcode;
state->cc_dead = 0;
output_comment(state, "caching %s", opcodes[opcode]);
}
/* Fill a hardreg with the pseudo it has */
static struct hardreg *fill_reg(struct bb_state *state, struct hardreg *hardreg, pseudo_t pseudo)
{
struct storage_hash *src;
struct instruction *def;
if (state->cc_target == pseudo) {
flush_cc_cache_to_reg(state, pseudo, hardreg);
return hardreg;
}
switch (pseudo->type) {
case PSEUDO_VAL:
output_insn(state, "movl $%lld,%s", pseudo->value, hardreg->name);
break;
case PSEUDO_SYM:
src = find_pseudo_storage(state, pseudo, NULL);
/* Static thing? */
if (!src) {
output_insn(state, "movl $<%s>,%s", show_pseudo(pseudo), hardreg->name);
break;
}
switch (src->storage->type) {
case REG_REG:
/* Aiaiaiaiaii! Need to flush it to temporary memory */
src = find_or_create_hash(pseudo, &state->internal);
/* Fall through */
default:
alloc_stack(state, src->storage);
/* Fall through */
case REG_STACK:
case REG_FRAME:
flush_pseudo(state, pseudo, src->storage);
output_insn(state, "leal %s,%s", show_memop(src->storage), hardreg->name);
break;
}
break;
case PSEUDO_ARG:
case PSEUDO_REG:
def = pseudo->def;
if (def && def->opcode == OP_SETVAL) {
output_insn(state, "movl $<%s>,%s", show_pseudo(def->target), hardreg->name);
break;
}
src = find_pseudo_storage(state, pseudo, hardreg);
if (!src)
break;
if (src->flags & TAG_DEAD)
mark_reg_dead(state, pseudo, hardreg);
output_insn(state, "mov.%d %s,%s", 32, show_memop(src->storage), hardreg->name);
break;
default:
output_insn(state, "reload %s from %s", hardreg->name, show_pseudo(pseudo));
break;
}
return hardreg;
}
static struct hardreg *getreg(struct bb_state *state, pseudo_t pseudo, pseudo_t target)
{
struct hardreg *reg;
reg = find_in_reg(state, pseudo);
if (reg)
return reg;
reg = target_reg(state, pseudo, target);
return fill_reg(state, reg, pseudo);
}
static void move_reg(struct bb_state *state, struct hardreg *src, struct hardreg *dst)
{
output_insn(state, "movl %s,%s", src->name, dst->name);
}
static struct hardreg *copy_reg(struct bb_state *state, struct hardreg *src, pseudo_t target)
{
int i;
struct hardreg *reg;
/* If the container has been killed off, just re-use it */
if (!src->contains)
return src;
/* If "src" only has one user, and the contents are dead, we can re-use it */
if (src->busy == 1 && src->dead == 1)
return src;
reg = preferred_reg(state, target);
if (reg && !reg->contains) {
output_comment(state, "copying %s to preferred target %s", show_pseudo(target), reg->name);
move_reg(state, src, reg);
return reg;
}
for (i = 0; i < REGNO; i++) {
reg = hardregs + i;
if (!reg->contains) {
output_comment(state, "copying %s to %s", show_pseudo(target), reg->name);
output_insn(state, "movl %s,%s", src->name, reg->name);
return reg;
}
}
flush_reg(state, src);
return src;
}
static void put_operand(struct bb_state *state, struct operand *op)
{
switch (op->type) {
case OP_REG:
op->reg->busy--;
break;
case OP_ADDR:
case OP_MEM:
if (op->base)
op->base->busy--;
if (op->index)
op->index->busy--;
break;
default:
break;
}
}
static struct operand *alloc_op(void)
{
struct operand *op = malloc(sizeof(*op));
memset(op, 0, sizeof(*op));
return op;
}
static struct operand *get_register_operand(struct bb_state *state, pseudo_t pseudo, pseudo_t target)
{
struct operand *op = alloc_op();
op->type = OP_REG;
op->reg = getreg(state, pseudo, target);
op->reg->busy++;
return op;
}
static int get_sym_frame_offset(struct bb_state *state, pseudo_t pseudo)
{
int offset = pseudo->nr;
if (offset < 0) {
offset = alloc_stack_offset(4);
pseudo->nr = offset;
}
return offset;
}
static struct operand *get_generic_operand(struct bb_state *state, pseudo_t pseudo)
{
struct hardreg *reg;
struct storage *src;
struct storage_hash *hash;
struct operand *op = malloc(sizeof(*op));
memset(op, 0, sizeof(*op));
switch (pseudo->type) {
case PSEUDO_VAL:
op->type = OP_VAL;
op->value = pseudo->value;
break;
case PSEUDO_SYM: {
struct symbol *sym = pseudo->sym;
op->type = OP_ADDR;
if (sym->ctype.modifiers & MOD_NONLOCAL) {
op->sym = sym;
break;
}
op->base = hardregs + REG_EBP;
op->offset = get_sym_frame_offset(state, pseudo);
break;
}
default:
reg = find_in_reg(state, pseudo);
if (reg) {
op->type = OP_REG;
op->reg = reg;
reg->busy++;
break;
}
hash = find_pseudo_storage(state, pseudo, NULL);
if (!hash)
break;
src = hash->storage;
switch (src->type) {
case REG_REG:
op->type = OP_REG;
op->reg = hardregs + src->regno;
op->reg->busy++;
break;
case REG_FRAME:
op->type = OP_MEM;
op->offset = src->offset;
op->base = hardregs + REG_EBP;
break;
case REG_STACK:
op->type = OP_MEM;
op->offset = src->offset;
op->base = hardregs + REG_ESP;
break;
default:
break;
}
}
return op;
}
/* Callers should be made to use the proper "operand" formats */
static const char *generic(struct bb_state *state, pseudo_t pseudo)
{
struct hardreg *reg;
struct operand *op = get_generic_operand(state, pseudo);
static char buf[100];
const char *str;
switch (op->type) {
case OP_ADDR:
if (!op->offset && op->base && !op->sym)
return op->base->name;
if (op->sym && !op->base) {
int len = sprintf(buf, "$ %s", show_op(state, op));
if (op->offset)
sprintf(buf + len, " + %d", op->offset);
return buf;
}
str = show_op(state, op);
put_operand(state, op);
reg = target_reg(state, pseudo, NULL);
output_insn(state, "lea %s,%s", show_op(state, op), reg->name);
return reg->name;
default:
str = show_op(state, op);
}
put_operand(state, op);
return str;
}
static struct operand *get_address_operand(struct bb_state *state, struct instruction *memop)
{
struct hardreg *base;
struct operand *op = get_generic_operand(state, memop->src);
switch (op->type) {
case OP_ADDR:
op->offset += memop->offset;
break;
default:
put_operand(state, op);
base = getreg(state, memop->src, NULL);
op->type = OP_ADDR;
op->base = base;
base->busy++;
op->offset = memop->offset;
op->sym = NULL;
}
return op;
}
static const char *address(struct bb_state *state, struct instruction *memop)
{
struct operand *op = get_address_operand(state, memop);
const char *str = show_op(state, op);
put_operand(state, op);
return str;
}
static const char *reg_or_imm(struct bb_state *state, pseudo_t pseudo)
{
switch(pseudo->type) {
case PSEUDO_VAL:
return show_pseudo(pseudo);
default:
return getreg(state, pseudo, NULL)->name;
}
}
static void kill_dead_reg(struct hardreg *reg)
{
if (reg->dead) {
pseudo_t p;
FOR_EACH_PTR(reg->contains, p) {
if (CURRENT_TAG(p) & TAG_DEAD) {
DELETE_CURRENT_PTR(p);
reg->dead--;
}
} END_FOR_EACH_PTR(p);
PACK_PTR_LIST(®->contains);
assert(!reg->dead);
}
}
static struct hardreg *target_copy_reg(struct bb_state *state, struct hardreg *src, pseudo_t target)
{
kill_dead_reg(src);
return copy_reg(state, src, target);
}
static void do_binop(struct bb_state *state, struct instruction *insn, pseudo_t val1, pseudo_t val2)
{
const char *op = opcodes[insn->opcode];
struct operand *src = get_register_operand(state, val1, insn->target);
struct operand *src2 = get_generic_operand(state, val2);
struct hardreg *dst;
dst = target_copy_reg(state, src->reg, insn->target);
output_insn(state, "%s.%d %s,%s", op, insn->size, show_op(state, src2), dst->name);
put_operand(state, src);
put_operand(state, src2);
add_pseudo_reg(state, insn->target, dst);
}
static void generate_binop(struct bb_state *state, struct instruction *insn)
{
flush_cc_cache(state);
do_binop(state, insn, insn->src1, insn->src2);
}
static int is_dead_reg(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
pseudo_t p;
FOR_EACH_PTR(reg->contains, p) {
if (p == pseudo)
return CURRENT_TAG(p) & TAG_DEAD;
} END_FOR_EACH_PTR(p);
return 0;
}
/*
* Commutative binops are much more flexible, since we can switch the
* sources around to satisfy the target register, or to avoid having
* to load one of them into a register..
*/
static void generate_commutative_binop(struct bb_state *state, struct instruction *insn)
{
pseudo_t src1, src2;
struct hardreg *reg1, *reg2;
flush_cc_cache(state);
src1 = insn->src1;
src2 = insn->src2;
reg2 = find_in_reg(state, src2);
if (!reg2)
goto dont_switch;
reg1 = find_in_reg(state, src1);
if (!reg1)
goto do_switch;
if (!is_dead_reg(state, src2, reg2))
goto dont_switch;
if (!is_dead_reg(state, src1, reg1))
goto do_switch;
/* Both are dead. Is one preferable? */
if (reg2 != preferred_reg(state, insn->target))
goto dont_switch;
do_switch:
src1 = src2;
src2 = insn->src1;
dont_switch:
do_binop(state, insn, src1, src2);
}
/*
* This marks a pseudo dead. It still stays on the hardreg list (the hardreg
* still has its value), but it's scheduled to be killed after the next
* "sequence point" when we call "kill_read_pseudos()"
*/
static void mark_pseudo_dead(struct bb_state *state, pseudo_t pseudo)
{
int i;
struct storage_hash *src;
if (state->cc_target == pseudo)
state->cc_dead = 1;
src = find_pseudo_storage(state, pseudo, NULL);
if (src)
src->flags |= TAG_DEAD;
for (i = 0; i < REGNO; i++)
mark_reg_dead(state, pseudo, hardregs + i);
}
static void kill_dead_pseudos(struct bb_state *state)
{
int i;
for (i = 0; i < REGNO; i++) {
kill_dead_reg(hardregs + i);
}
}
static void generate_store(struct instruction *insn, struct bb_state *state)
{
output_insn(state, "mov.%d %s,%s", insn->size, reg_or_imm(state, insn->target), address(state, insn));
}
static void generate_load(struct instruction *insn, struct bb_state *state)
{
const char *input = address(state, insn);
struct hardreg *dst;
kill_dead_pseudos(state);
dst = target_reg(state, insn->target, NULL);
output_insn(state, "mov.%d %s,%s", insn->size, input, dst->name);
}
static void kill_pseudo(struct bb_state *state, pseudo_t pseudo)
{
int i;
struct hardreg *reg;
output_comment(state, "killing pseudo %s", show_pseudo(pseudo));
for (i = 0; i < REGNO; i++) {
pseudo_t p;
reg = hardregs + i;
FOR_EACH_PTR(reg->contains, p) {
if (p != pseudo)
continue;
if (CURRENT_TAG(p) & TAG_DEAD)
reg->dead--;
output_comment(state, "removing pseudo %s from reg %s",
show_pseudo(pseudo), reg->name);
DELETE_CURRENT_PTR(p);
} END_FOR_EACH_PTR(p);
PACK_PTR_LIST(®->contains);
}
}
static void generate_copy(struct bb_state *state, struct instruction *insn)
{
struct hardreg *src = getreg(state, insn->src, insn->target);
kill_pseudo(state, insn->target);
add_pseudo_reg(state, insn->target, src);
}
static void generate_cast(struct bb_state *state, struct instruction *insn)
{
struct hardreg *src = getreg(state, insn->src, insn->target);
struct hardreg *dst;
unsigned int old = insn->orig_type ? insn->orig_type->bit_size : 0;
unsigned int new = insn->size;
/*
* Cast to smaller type? Ignore the high bits, we
* just keep both pseudos in the same register.
*/
if (old >= new) {
add_pseudo_reg(state, insn->target, src);
return;
}
dst = target_copy_reg(state, src, insn->target);
if (insn->orig_type && (insn->orig_type->ctype.modifiers & MOD_SIGNED)) {
output_insn(state, "sext.%d.%d %s", old, new, dst->name);
} else {
unsigned long long mask;
mask = ~(~0ULL << old);
mask &= ~(~0ULL << new);
output_insn(state, "andl.%d $%#llx,%s", insn->size, mask, dst->name);
}
add_pseudo_reg(state, insn->target, dst);
}
static void generate_output_storage(struct bb_state *state);
static const char *conditional[] = {
[OP_SET_EQ] = "e",
[OP_SET_NE] = "ne",
[OP_SET_LE] = "le",
[OP_SET_GE] = "ge",
[OP_SET_LT] = "lt",
[OP_SET_GT] = "gt",
[OP_SET_B] = "b",
[OP_SET_A] = "a",
[OP_SET_BE] = "be",
[OP_SET_AE] = "ae"
};
static void generate_branch(struct bb_state *state, struct instruction *br)
{
const char *cond = "XXX";
struct basic_block *target;
if (br->cond) {
if (state->cc_target == br->cond) {
cond = conditional[state->cc_opcode];
} else {
struct hardreg *reg = getreg(state, br->cond, NULL);
output_insn(state, "testl %s,%s", reg->name, reg->name);
cond = "ne";
}
}
generate_output_storage(state);
target = br->bb_true;
if (br->cond) {
output_insn(state, "j%s .L%p", cond, target);
target = br->bb_false;
}
output_insn(state, "jmp .L%p", target);
}
/* We've made sure that there is a dummy reg live for the output */
static void generate_switch(struct bb_state *state, struct instruction *insn)
{
struct hardreg *reg = hardregs + SWITCH_REG;
generate_output_storage(state);
output_insn(state, "switch on %s", reg->name);
output_insn(state, "unimplemented: %s", show_instruction(insn));
}
static void generate_ret(struct bb_state *state, struct instruction *ret)
{
if (ret->src && ret->src != VOID) {
struct hardreg *wants = hardregs+0;
struct hardreg *reg = getreg(state, ret->src, NULL);
if (reg != wants)
output_insn(state, "movl %s,%s", reg->name, wants->name);
}
output_insn(state, "ret");
}
/*
* Fake "call" linearization just as a taster..
*/
static void generate_call(struct bb_state *state, struct instruction *insn)
{
int offset = 0;
pseudo_t arg;
FOR_EACH_PTR(insn->arguments, arg) {
output_insn(state, "pushl %s", generic(state, arg));
offset += 4;
} END_FOR_EACH_PTR(arg);
flush_reg(state, hardregs+0);
flush_reg(state, hardregs+1);
flush_reg(state, hardregs+2);
output_insn(state, "call %s", show_pseudo(insn->func));
if (offset)
output_insn(state, "addl $%d,%%esp", offset);
if (insn->target && insn->target != VOID)
add_pseudo_reg(state, insn->target, hardregs+0);
}
static void generate_select(struct bb_state *state, struct instruction *insn)
{
const char *cond;
struct hardreg *src1, *src2, *dst;
src1 = getreg(state, insn->src2, NULL);
dst = copy_reg(state, src1, insn->target);
add_pseudo_reg(state, insn->target, dst);
src2 = getreg(state, insn->src3, insn->target);
if (state->cc_target == insn->src1) {
cond = conditional[state->cc_opcode];
} else {
struct hardreg *reg = getreg(state, insn->src1, NULL);
output_insn(state, "testl %s,%s", reg->name, reg->name);
cond = "ne";
}
output_insn(state, "sel%s %s,%s", cond, src2->name, dst->name);
}
struct asm_arg {
const struct ident *name;
const char *value;
pseudo_t pseudo;
struct hardreg *reg;
};
static void replace_asm_arg(char **dst_p, struct asm_arg *arg)
{
char *dst = *dst_p;
int len = strlen(arg->value);
memcpy(dst, arg->value, len);
*dst_p = dst + len;
}
static void replace_asm_percent(const char **src_p, char **dst_p, struct asm_arg *args, int nr)
{
const char *src = *src_p;
char c;
int index;
c = *src++;
switch (c) {
case '0' ... '9':
index = c - '0';
if (index < nr)
replace_asm_arg(dst_p, args+index);
break;
}
*src_p = src;
return;
}
static void replace_asm_named(const char **src_p, char **dst_p, struct asm_arg *args, int nr)
{
const char *src = *src_p;
const char *end = src;
for(;;) {
char c = *end++;
if (!c)
return;
if (c == ']') {
int i;
*src_p = end;
for (i = 0; i < nr; i++) {
const struct ident *ident = args[i].name;
int len;
if (!ident)
continue;
len = ident->len;
if (memcmp(src, ident->name, len))
continue;
replace_asm_arg(dst_p, args+i);
return;
}
}
}
}
static const char *replace_asm_args(const char *str, struct asm_arg *args, int nr)
{
static char buffer[1000];
char *p = buffer;
for (;;) {
char c = *str;
*p = c;
if (!c)
return buffer;
str++;
switch (c) {
case '%':
if (*str == '%') {
str++;
p++;
continue;
}
replace_asm_percent(&str, &p, args, nr);
continue;
case '[':
replace_asm_named(&str, &p, args, nr);
continue;
default:
break;
}
p++;
}
}
#define MAX_ASM_ARG (50)
static struct asm_arg asm_arguments[MAX_ASM_ARG];
static struct asm_arg *generate_asm_inputs(struct bb_state *state, struct asm_constraint_list *list, struct asm_arg *arg)
{
struct asm_constraint *entry;
FOR_EACH_PTR(list, entry) {
const char *constraint = entry->constraint;
pseudo_t pseudo = entry->pseudo;
struct hardreg *reg, *orig;
const char *string;
int index;
string = "undef";
switch (*constraint) {
case 'r':
string = getreg(state, pseudo, NULL)->name;
break;
case '0' ... '9':
index = *constraint - '0';
reg = asm_arguments[index].reg;
orig = find_in_reg(state, pseudo);
if (orig)
move_reg(state, orig, reg);
else
fill_reg(state, reg, pseudo);
string = reg->name;
break;
default:
string = generic(state, pseudo);
break;
}
output_insn(state, "# asm input \"%s\": %s : %s", constraint, show_pseudo(pseudo), string);
arg->name = entry->ident;
arg->value = string;
arg->pseudo = NULL;
arg->reg = NULL;
arg++;
} END_FOR_EACH_PTR(entry);
return arg;
}
static struct asm_arg *generate_asm_outputs(struct bb_state *state, struct asm_constraint_list *list, struct asm_arg *arg)
{
struct asm_constraint *entry;
FOR_EACH_PTR(list, entry) {
const char *constraint = entry->constraint;
pseudo_t pseudo = entry->pseudo;
struct hardreg *reg;
const char *string;
while (*constraint == '=' || *constraint == '+')
constraint++;
string = "undef";
switch (*constraint) {
case 'r':
default:
reg = target_reg(state, pseudo, NULL);
arg->pseudo = pseudo;
arg->reg = reg;
string = reg->name;
break;
}
output_insn(state, "# asm output \"%s\": %s : %s", constraint, show_pseudo(pseudo), string);
arg->name = entry->ident;
arg->value = string;
arg++;
} END_FOR_EACH_PTR(entry);
return arg;
}
static void generate_asm(struct bb_state *state, struct instruction *insn)
{
const char *str = insn->string;
if (insn->asm_rules->outputs || insn->asm_rules->inputs) {
struct asm_arg *arg;
arg = generate_asm_outputs(state, insn->asm_rules->outputs, asm_arguments);
arg = generate_asm_inputs(state, insn->asm_rules->inputs, arg);
str = replace_asm_args(str, asm_arguments, arg - asm_arguments);
}
output_insn(state, "%s", str);
}
static void generate_compare(struct bb_state *state, struct instruction *insn)
{
struct hardreg *src;
const char *src2;
int opcode;
flush_cc_cache(state);
opcode = insn->opcode;
/*
* We should try to switch these around if necessary,
* and update the opcode to match..
*/
src = getreg(state, insn->src1, insn->target);
src2 = generic(state, insn->src2);
output_insn(state, "cmp.%d %s,%s", insn->size, src2, src->name);
add_cc_cache(state, opcode, insn->target);
}
static void generate_one_insn(struct instruction *insn, struct bb_state *state)
{
if (verbose)
output_comment(state, "%s", show_instruction(insn));
switch (insn->opcode) {
case OP_ENTRY: {
struct symbol *sym = insn->bb->ep->name;
const char *name = show_ident(sym->ident);
if (sym->ctype.modifiers & MOD_STATIC)
printf("\n\n%s:\n", name);
else
printf("\n\n.globl %s\n%s:\n", name, name);
break;
}
/*
* OP_SETVAL likewise doesn't actually generate any
* code. On use, the "def" of the pseudo will be
* looked up.
*/
case OP_SETVAL:
break;
case OP_STORE:
generate_store(insn, state);
break;
case OP_LOAD:
generate_load(insn, state);
break;
case OP_DEATHNOTE:
mark_pseudo_dead(state, insn->target);
return;
case OP_COPY:
generate_copy(state, insn);
break;
case OP_ADD: case OP_MULU: case OP_MULS:
case OP_AND: case OP_OR: case OP_XOR:
case OP_AND_BOOL: case OP_OR_BOOL:
generate_commutative_binop(state, insn);
break;
case OP_SUB: case OP_DIVU: case OP_DIVS:
case OP_MODU: case OP_MODS:
case OP_SHL: case OP_LSR: case OP_ASR:
generate_binop(state, insn);
break;
case OP_BINCMP ... OP_BINCMP_END:
generate_compare(state, insn);
break;
case OP_CAST: case OP_SCAST: case OP_FPCAST: case OP_PTRCAST:
generate_cast(state, insn);
break;
case OP_SEL:
generate_select(state, insn);
break;
case OP_BR:
generate_branch(state, insn);
break;
case OP_SWITCH:
generate_switch(state, insn);
break;
case OP_CALL:
generate_call(state, insn);
break;
case OP_RET:
generate_ret(state, insn);
break;
case OP_ASM:
generate_asm(state, insn);
break;
case OP_PHI:
case OP_PHISOURCE:
default:
output_insn(state, "unimplemented: %s", show_instruction(insn));
break;
}
kill_dead_pseudos(state);
}
#define VERY_BUSY 1000
#define REG_FIXED 2000
static void write_reg_to_storage(struct bb_state *state, struct hardreg *reg, pseudo_t pseudo, struct storage *storage)
{
int i;
struct hardreg *out;
switch (storage->type) {
case REG_REG:
out = hardregs + storage->regno;
if (reg == out)
return;
output_insn(state, "movl %s,%s", reg->name, out->name);
return;
case REG_UDEF:
if (reg->busy < VERY_BUSY) {
storage->type = REG_REG;
storage->regno = reg - hardregs;
reg->busy = REG_FIXED;
return;
}
/* Try to find a non-busy register.. */
for (i = 0; i < REGNO; i++) {
out = hardregs + i;
if (out->contains)
continue;
output_insn(state, "movl %s,%s", reg->name, out->name);
storage->type = REG_REG;
storage->regno = i;
out->busy = REG_FIXED;
return;
}
/* Fall back on stack allocation ... */
alloc_stack(state, storage);
/* Fall through */
default:
output_insn(state, "movl %s,%s", reg->name, show_memop(storage));
return;
}
}
static void write_val_to_storage(struct bb_state *state, pseudo_t src, struct storage *storage)
{
struct hardreg *out;
switch (storage->type) {
case REG_UDEF:
alloc_stack(state, storage);
default:
output_insn(state, "movl %s,%s", show_pseudo(src), show_memop(storage));
break;
case REG_REG:
out = hardregs + storage->regno;
output_insn(state, "movl %s,%s", show_pseudo(src), out->name);
}
}
static void fill_output(struct bb_state *state, pseudo_t pseudo, struct storage *out)
{
int i;
struct storage_hash *in;
struct instruction *def;
/* Is that pseudo a constant value? */
switch (pseudo->type) {
case PSEUDO_VAL:
write_val_to_storage(state, pseudo, out);
return;
case PSEUDO_REG:
def = pseudo->def;
if (def && def->opcode == OP_SETVAL) {
write_val_to_storage(state, pseudo, out);
return;
}
default:
break;
}
/* See if we have that pseudo in a register.. */
for (i = 0; i < REGNO; i++) {
struct hardreg *reg = hardregs + i;
pseudo_t p;
FOR_EACH_PTR(reg->contains, p) {
if (p == pseudo) {
write_reg_to_storage(state, reg, pseudo, out);
return;
}
} END_FOR_EACH_PTR(p);
}
/* Do we have it in another storage? */
in = find_storage_hash(pseudo, state->internal);
if (!in) {
in = find_storage_hash(pseudo, state->inputs);
/* Undefined? */
if (!in)
return;
}
switch (out->type) {
case REG_UDEF:
*out = *in->storage;
break;
case REG_REG:
output_insn(state, "movl %s,%s", show_memop(in->storage), hardregs[out->regno].name);
break;
default:
if (out == in->storage)
break;
if ((out->type == in->storage->type) && (out->regno == in->storage->regno))
break;
output_insn(state, "movl %s,%s", show_memop(in->storage), show_memop(out));
break;
}
return;
}
static int final_pseudo_flush(struct bb_state *state, pseudo_t pseudo, struct hardreg *reg)
{
struct storage_hash *hash;
struct storage *out;
struct hardreg *dst;
/*
* Since this pseudo is live at exit, we'd better have output
* storage for it..
*/
hash = find_storage_hash(pseudo, state->outputs);
if (!hash)
return 1;
out = hash->storage;
/* If the output is in a register, try to get it there.. */
if (out->type == REG_REG) {
dst = hardregs + out->regno;
/*
* Two good cases: nobody is using the right register,
* or we've already set it aside for output..
*/
if (!dst->contains || dst->busy > VERY_BUSY)
goto copy_to_dst;
/* Aiee. Try to keep it in a register.. */
dst = empty_reg(state);
if (dst)
goto copy_to_dst;
return 0;
}
/* If the output is undefined, let's see if we can put it in a register.. */
if (out->type == REG_UDEF) {
dst = empty_reg(state);
if (dst) {
out->type = REG_REG;
out->regno = dst - hardregs;
goto copy_to_dst;
}
/* Uhhuh. Not so good. No empty registers right now */
return 0;
}
/* If we know we need to flush it, just do so already .. */
output_insn(state, "movl %s,%s", reg->name, show_memop(out));
return 1;
copy_to_dst:
if (reg == dst)
return 1;
output_insn(state, "movl %s,%s", reg->name, dst->name);
add_pseudo_reg(state, pseudo, dst);
return 1;
}
/*
* This tries to make sure that we put all the pseudos that are
* live on exit into the proper storage
*/
static void generate_output_storage(struct bb_state *state)
{
struct storage_hash *entry;
/* Go through the fixed outputs, making sure we have those regs free */
FOR_EACH_PTR(state->outputs, entry) {
struct storage *out = entry->storage;
if (out->type == REG_REG) {
struct hardreg *reg = hardregs + out->regno;
pseudo_t p;
int flushme = 0;
reg->busy = REG_FIXED;
FOR_EACH_PTR(reg->contains, p) {
if (p == entry->pseudo) {
flushme = -100;
continue;
}
if (CURRENT_TAG(p) & TAG_DEAD)
continue;
/* Try to write back the pseudo to where it should go ... */
if (final_pseudo_flush(state, p, reg)) {
DELETE_CURRENT_PTR(p);
continue;
}
flushme++;
} END_FOR_EACH_PTR(p);
PACK_PTR_LIST(®->contains);
if (flushme > 0)
flush_reg(state, reg);
}
} END_FOR_EACH_PTR(entry);
FOR_EACH_PTR(state->outputs, entry) {
fill_output(state, entry->pseudo, entry->storage);
} END_FOR_EACH_PTR(entry);
}
static void generate(struct basic_block *bb, struct bb_state *state)
{
int i;
struct storage_hash *entry;
struct instruction *insn;
for (i = 0; i < REGNO; i++) {
free_ptr_list(&hardregs[i].contains);
hardregs[i].busy = 0;
hardregs[i].dead = 0;
hardregs[i].used = 0;
}
FOR_EACH_PTR(state->inputs, entry) {
struct storage *storage = entry->storage;
const char *name = show_storage(storage);
output_comment(state, "incoming %s in %s", show_pseudo(entry->pseudo), name);
if (storage->type == REG_REG) {
int regno = storage->regno;
add_pseudo_reg(state, entry->pseudo, hardregs + regno);
name = hardregs[regno].name;
}
} END_FOR_EACH_PTR(entry);
output_label(state, ".L%p", bb);
FOR_EACH_PTR(bb->insns, insn) {
if (!insn->bb)
continue;
generate_one_insn(insn, state);
} END_FOR_EACH_PTR(insn);
if (verbose) {
output_comment(state, "--- in ---");
FOR_EACH_PTR(state->inputs, entry) {
output_comment(state, "%s <- %s", show_pseudo(entry->pseudo), show_storage(entry->storage));
} END_FOR_EACH_PTR(entry);
output_comment(state, "--- spill ---");
FOR_EACH_PTR(state->internal, entry) {
output_comment(state, "%s <-> %s", show_pseudo(entry->pseudo), show_storage(entry->storage));
} END_FOR_EACH_PTR(entry);
output_comment(state, "--- out ---");
FOR_EACH_PTR(state->outputs, entry) {
output_comment(state, "%s -> %s", show_pseudo(entry->pseudo), show_storage(entry->storage));
} END_FOR_EACH_PTR(entry);
}
printf("\n");
}
static void generate_list(struct basic_block_list *list, unsigned long generation)
{
struct basic_block *bb;
FOR_EACH_PTR(list, bb) {
if (bb->generation == generation)
continue;
output_bb(bb, generation);
} END_FOR_EACH_PTR(bb);
}
/*
* Mark all the output registers of all the parents
* as being "used" - this does not mean that we cannot
* re-use them, but it means that we cannot ask the
* parents to pass in another pseudo in one of those
* registers that it already uses for another child.
*/
static void mark_used_registers(struct basic_block *bb, struct bb_state *state)
{
struct basic_block *parent;
FOR_EACH_PTR(bb->parents, parent) {
struct storage_hash_list *outputs = gather_storage(parent, STOR_OUT);
struct storage_hash *entry;
FOR_EACH_PTR(outputs, entry) {
struct storage *s = entry->storage;
if (s->type == REG_REG) {
struct hardreg *reg = hardregs + s->regno;
reg->used = 1;
}
} END_FOR_EACH_PTR(entry);
} END_FOR_EACH_PTR(parent);
}
static void output_bb(struct basic_block *bb, unsigned long generation)
{
struct bb_state state;
bb->generation = generation;
/* Make sure all parents have been generated first */
generate_list(bb->parents, generation);
state.pos = bb->pos;
state.inputs = gather_storage(bb, STOR_IN);
state.outputs = gather_storage(bb, STOR_OUT);
state.internal = NULL;
state.cc_opcode = 0;
state.cc_target = NULL;
/* Mark incoming registers used */
mark_used_registers(bb, &state);
generate(bb, &state);
free_ptr_list(&state.inputs);
free_ptr_list(&state.outputs);
/* Generate all children... */
generate_list(bb->children, generation);
}
/*
* We should set up argument sources here..
*
* Things like "first three arguments in registers" etc
* are all for this place.
*
* On x86, we default to stack, unless it's a static
* function that doesn't have its address taken.
*
* I should implement the -mregparm=X cmd line option.
*/
static void set_up_arch_entry(struct entrypoint *ep, struct instruction *entry)
{
pseudo_t arg;
struct symbol *sym, *argtype;
int i, offset, regparm;
sym = ep->name;
regparm = 0;
if (!(sym->ctype.modifiers & MOD_ADDRESSABLE))
regparm = 3;
sym = sym->ctype.base_type;
i = 0;
offset = 0;
PREPARE_PTR_LIST(sym->arguments, argtype);
FOR_EACH_PTR(entry->arg_list, arg) {
struct storage *in = lookup_storage(entry->bb, arg, STOR_IN);
if (!in) {
in = alloc_storage();
add_storage(in, entry->bb, arg, STOR_IN);
}
if (i < regparm) {
in->type = REG_REG;
in->regno = i;
} else {
int bits = argtype ? argtype->bit_size : 0;
if (bits < bits_in_int)
bits = bits_in_int;
in->type = REG_FRAME;
in->offset = offset;
offset += bits_to_bytes(bits);
}
i++;
NEXT_PTR_LIST(argtype);
} END_FOR_EACH_PTR(arg);
FINISH_PTR_LIST(argtype);
}
/*
* Set up storage information for "return"
*
* Not strictly necessary, since the code generator will
* certainly move the return value to the right register,
* but it can help register allocation if the allocator
* sees that the target register is going to return in %eax.
*/
static void set_up_arch_exit(struct basic_block *bb, struct instruction *ret)
{
pseudo_t pseudo = ret->src;
if (pseudo && pseudo != VOID) {
struct storage *out = lookup_storage(bb, pseudo, STOR_OUT);
if (!out) {
out = alloc_storage();
add_storage(out, bb, pseudo, STOR_OUT);
}
out->type = REG_REG;
out->regno = 0;
}
}
/*
* Set up dummy/silly output storage information for a switch
* instruction. We need to make sure that a register is available
* when we generate code for switch, so force that by creating
* a dummy output rule.
*/
static void set_up_arch_switch(struct basic_block *bb, struct instruction *insn)
{
pseudo_t pseudo = insn->cond;
struct storage *out = lookup_storage(bb, pseudo, STOR_OUT);
if (!out) {
out = alloc_storage();
add_storage(out, bb, pseudo, STOR_OUT);
}
out->type = REG_REG;
out->regno = SWITCH_REG;
}
static void arch_set_up_storage(struct entrypoint *ep)
{
struct basic_block *bb;
/* Argument storage etc.. */
set_up_arch_entry(ep, ep->entry);
FOR_EACH_PTR(ep->bbs, bb) {
struct instruction *insn = last_instruction(bb->insns);
if (!insn)
continue;
switch (insn->opcode) {
case OP_RET:
set_up_arch_exit(bb, insn);
break;
case OP_SWITCH:
set_up_arch_switch(bb, insn);
break;
default:
/* nothing */;
}
} END_FOR_EACH_PTR(bb);
}
static void output(struct entrypoint *ep)
{
unsigned long generation = ++bb_generation;
last_reg = -1;
stack_offset = 0;
/* Get rid of SSA form (phinodes etc) */
unssa(ep);
/* Set up initial inter-bb storage links */
set_up_storage(ep);
/* Architecture-specific storage rules.. */
arch_set_up_storage(ep);
/* Show the results ... */
output_bb(ep->entry->bb, generation);
/* Clear the storage hashes for the next function.. */
free_storage();
}
static int compile(struct symbol_list *list)
{
struct symbol *sym;
FOR_EACH_PTR(list, sym) {
struct entrypoint *ep;
expand_symbol(sym);
ep = linearize_symbol(sym);
if (ep)
output(ep);
} END_FOR_EACH_PTR(sym);
return 0;
}
int main(int argc, char **argv)
{
struct string_list *filelist = NULL;
char *file;
compile(sparse_initialize(argc, argv, &filelist));
dbg_dead = 1;
FOR_EACH_PTR_NOTAG(filelist, file) {
compile(sparse(file));
} END_FOR_EACH_PTR_NOTAG(file);
return 0;
}
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