qemu/tcg/tcg.c

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/*
* Tiny Code Generator for QEMU
*
* Copyright (c) 2008 Fabrice Bellard
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
/* define it to use liveness analysis (better code) */
#define USE_LIVENESS_ANALYSIS
#define USE_TCG_OPTIMIZATIONS
#include "qemu/osdep.h"
/* Define to jump the ELF file used to communicate with GDB. */
#undef DEBUG_JIT
#if !defined(CONFIG_DEBUG_TCG) && !defined(NDEBUG)
/* define it to suppress various consistency checks (faster) */
#define NDEBUG
#endif
#include "qemu-common.h"
#include "qemu/host-utils.h"
#include "qemu/timer.h"
/* Note: the long term plan is to reduce the dependencies on the QEMU
CPU definitions. Currently they are used for qemu_ld/st
instructions */
#define NO_CPU_IO_DEFS
#include "cpu.h"
#include "tcg-op.h"
#if UINTPTR_MAX == UINT32_MAX
# define ELF_CLASS ELFCLASS32
#else
# define ELF_CLASS ELFCLASS64
#endif
#ifdef HOST_WORDS_BIGENDIAN
# define ELF_DATA ELFDATA2MSB
#else
# define ELF_DATA ELFDATA2LSB
#endif
#include "elf.h"
#include "exec/log.h"
/* Forward declarations for functions declared in tcg-target.c and used here. */
static void tcg_target_init(TCGContext *s);
static void tcg_target_qemu_prologue(TCGContext *s);
static void patch_reloc(tcg_insn_unit *code_ptr, int type,
intptr_t value, intptr_t addend);
/* The CIE and FDE header definitions will be common to all hosts. */
typedef struct {
uint32_t len __attribute__((aligned((sizeof(void *)))));
uint32_t id;
uint8_t version;
char augmentation[1];
uint8_t code_align;
uint8_t data_align;
uint8_t return_column;
} DebugFrameCIE;
typedef struct QEMU_PACKED {
uint32_t len __attribute__((aligned((sizeof(void *)))));
uint32_t cie_offset;
uintptr_t func_start;
uintptr_t func_len;
} DebugFrameFDEHeader;
typedef struct QEMU_PACKED {
DebugFrameCIE cie;
DebugFrameFDEHeader fde;
} DebugFrameHeader;
static void tcg_register_jit_int(void *buf, size_t size,
const void *debug_frame,
size_t debug_frame_size)
__attribute__((unused));
/* Forward declarations for functions declared and used in tcg-target.c. */
static int target_parse_constraint(TCGArgConstraint *ct, const char **pct_str);
static void tcg_out_ld(TCGContext *s, TCGType type, TCGReg ret, TCGReg arg1,
intptr_t arg2);
static void tcg_out_mov(TCGContext *s, TCGType type, TCGReg ret, TCGReg arg);
static void tcg_out_movi(TCGContext *s, TCGType type,
TCGReg ret, tcg_target_long arg);
static void tcg_out_op(TCGContext *s, TCGOpcode opc, const TCGArg *args,
const int *const_args);
static void tcg_out_st(TCGContext *s, TCGType type, TCGReg arg, TCGReg arg1,
intptr_t arg2);
static void tcg_out_call(TCGContext *s, tcg_insn_unit *target);
static int tcg_target_const_match(tcg_target_long val, TCGType type,
const TCGArgConstraint *arg_ct);
static void tcg_out_tb_init(TCGContext *s);
static bool tcg_out_tb_finalize(TCGContext *s);
static TCGRegSet tcg_target_available_regs[2];
static TCGRegSet tcg_target_call_clobber_regs;
#if TCG_TARGET_INSN_UNIT_SIZE == 1
static __attribute__((unused)) inline void tcg_out8(TCGContext *s, uint8_t v)
{
*s->code_ptr++ = v;
}
static __attribute__((unused)) inline void tcg_patch8(tcg_insn_unit *p,
uint8_t v)
{
*p = v;
}
#endif
#if TCG_TARGET_INSN_UNIT_SIZE <= 2
static __attribute__((unused)) inline void tcg_out16(TCGContext *s, uint16_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 2) {
*s->code_ptr++ = v;
} else {
tcg_insn_unit *p = s->code_ptr;
memcpy(p, &v, sizeof(v));
s->code_ptr = p + (2 / TCG_TARGET_INSN_UNIT_SIZE);
}
}
static __attribute__((unused)) inline void tcg_patch16(tcg_insn_unit *p,
uint16_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 2) {
*p = v;
} else {
memcpy(p, &v, sizeof(v));
}
}
#endif
#if TCG_TARGET_INSN_UNIT_SIZE <= 4
static __attribute__((unused)) inline void tcg_out32(TCGContext *s, uint32_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 4) {
*s->code_ptr++ = v;
} else {
tcg_insn_unit *p = s->code_ptr;
memcpy(p, &v, sizeof(v));
s->code_ptr = p + (4 / TCG_TARGET_INSN_UNIT_SIZE);
}
}
static __attribute__((unused)) inline void tcg_patch32(tcg_insn_unit *p,
uint32_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 4) {
*p = v;
} else {
memcpy(p, &v, sizeof(v));
}
}
#endif
#if TCG_TARGET_INSN_UNIT_SIZE <= 8
static __attribute__((unused)) inline void tcg_out64(TCGContext *s, uint64_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 8) {
*s->code_ptr++ = v;
} else {
tcg_insn_unit *p = s->code_ptr;
memcpy(p, &v, sizeof(v));
s->code_ptr = p + (8 / TCG_TARGET_INSN_UNIT_SIZE);
}
}
static __attribute__((unused)) inline void tcg_patch64(tcg_insn_unit *p,
uint64_t v)
{
if (TCG_TARGET_INSN_UNIT_SIZE == 8) {
*p = v;
} else {
memcpy(p, &v, sizeof(v));
}
}
#endif
/* label relocation processing */
static void tcg_out_reloc(TCGContext *s, tcg_insn_unit *code_ptr, int type,
TCGLabel *l, intptr_t addend)
{
TCGRelocation *r;
if (l->has_value) {
/* FIXME: This may break relocations on RISC targets that
modify instruction fields in place. The caller may not have
written the initial value. */
patch_reloc(code_ptr, type, l->u.value, addend);
} else {
/* add a new relocation entry */
r = tcg_malloc(sizeof(TCGRelocation));
r->type = type;
r->ptr = code_ptr;
r->addend = addend;
r->next = l->u.first_reloc;
l->u.first_reloc = r;
}
}
static void tcg_out_label(TCGContext *s, TCGLabel *l, tcg_insn_unit *ptr)
{
intptr_t value = (intptr_t)ptr;
TCGRelocation *r;
assert(!l->has_value);
for (r = l->u.first_reloc; r != NULL; r = r->next) {
patch_reloc(r->ptr, r->type, value, r->addend);
}
l->has_value = 1;
l->u.value_ptr = ptr;
}
TCGLabel *gen_new_label(void)
{
TCGContext *s = &tcg_ctx;
TCGLabel *l = tcg_malloc(sizeof(TCGLabel));
*l = (TCGLabel){
.id = s->nb_labels++
};
return l;
}
#include "tcg-target.c"
/* pool based memory allocation */
void *tcg_malloc_internal(TCGContext *s, int size)
{
TCGPool *p;
int pool_size;
if (size > TCG_POOL_CHUNK_SIZE) {
/* big malloc: insert a new pool (XXX: could optimize) */
p = g_malloc(sizeof(TCGPool) + size);
p->size = size;
p->next = s->pool_first_large;
s->pool_first_large = p;
return p->data;
} else {
p = s->pool_current;
if (!p) {
p = s->pool_first;
if (!p)
goto new_pool;
} else {
if (!p->next) {
new_pool:
pool_size = TCG_POOL_CHUNK_SIZE;
p = g_malloc(sizeof(TCGPool) + pool_size);
p->size = pool_size;
p->next = NULL;
if (s->pool_current)
s->pool_current->next = p;
else
s->pool_first = p;
} else {
p = p->next;
}
}
}
s->pool_current = p;
s->pool_cur = p->data + size;
s->pool_end = p->data + p->size;
return p->data;
}
void tcg_pool_reset(TCGContext *s)
{
TCGPool *p, *t;
for (p = s->pool_first_large; p; p = t) {
t = p->next;
g_free(p);
}
s->pool_first_large = NULL;
s->pool_cur = s->pool_end = NULL;
s->pool_current = NULL;
}
typedef struct TCGHelperInfo {
void *func;
const char *name;
unsigned flags;
unsigned sizemask;
} TCGHelperInfo;
#include "exec/helper-proto.h"
static const TCGHelperInfo all_helpers[] = {
#include "exec/helper-tcg.h"
};
void tcg_context_init(TCGContext *s)
{
int op, total_args, n, i;
TCGOpDef *def;
TCGArgConstraint *args_ct;
int *sorted_args;
GHashTable *helper_table;
memset(s, 0, sizeof(*s));
s->nb_globals = 0;
/* Count total number of arguments and allocate the corresponding
space */
total_args = 0;
for(op = 0; op < NB_OPS; op++) {
def = &tcg_op_defs[op];
n = def->nb_iargs + def->nb_oargs;
total_args += n;
}
args_ct = g_malloc(sizeof(TCGArgConstraint) * total_args);
sorted_args = g_malloc(sizeof(int) * total_args);
for(op = 0; op < NB_OPS; op++) {
def = &tcg_op_defs[op];
def->args_ct = args_ct;
def->sorted_args = sorted_args;
n = def->nb_iargs + def->nb_oargs;
sorted_args += n;
args_ct += n;
}
/* Register helpers. */
/* Use g_direct_hash/equal for direct pointer comparisons on func. */
s->helpers = helper_table = g_hash_table_new(NULL, NULL);
for (i = 0; i < ARRAY_SIZE(all_helpers); ++i) {
g_hash_table_insert(helper_table, (gpointer)all_helpers[i].func,
(gpointer)&all_helpers[i]);
}
tcg_target_init(s);
}
void tcg_prologue_init(TCGContext *s)
{
size_t prologue_size, total_size;
void *buf0, *buf1;
/* Put the prologue at the beginning of code_gen_buffer. */
buf0 = s->code_gen_buffer;
s->code_ptr = buf0;
s->code_buf = buf0;
s->code_gen_prologue = buf0;
/* Generate the prologue. */
tcg_target_qemu_prologue(s);
buf1 = s->code_ptr;
flush_icache_range((uintptr_t)buf0, (uintptr_t)buf1);
/* Deduct the prologue from the buffer. */
prologue_size = tcg_current_code_size(s);
s->code_gen_ptr = buf1;
s->code_gen_buffer = buf1;
s->code_buf = buf1;
total_size = s->code_gen_buffer_size - prologue_size;
s->code_gen_buffer_size = total_size;
/* Compute a high-water mark, at which we voluntarily flush the buffer
and start over. The size here is arbitrary, significantly larger
than we expect the code generation for any one opcode to require. */
s->code_gen_highwater = s->code_gen_buffer + (total_size - 1024);
tcg_register_jit(s->code_gen_buffer, total_size);
#ifdef DEBUG_DISAS
if (qemu_loglevel_mask(CPU_LOG_TB_OUT_ASM)) {
qemu_log("PROLOGUE: [size=%zu]\n", prologue_size);
log_disas(buf0, prologue_size);
qemu_log("\n");
qemu_log_flush();
}
#endif
}
void tcg_func_start(TCGContext *s)
{
tcg_pool_reset(s);
s->nb_temps = s->nb_globals;
/* No temps have been previously allocated for size or locality. */
memset(s->free_temps, 0, sizeof(s->free_temps));
s->nb_labels = 0;
s->current_frame_offset = s->frame_start;
#ifdef CONFIG_DEBUG_TCG
s->goto_tb_issue_mask = 0;
#endif
s->gen_first_op_idx = 0;
s->gen_last_op_idx = -1;
s->gen_next_op_idx = 0;
s->gen_next_parm_idx = 0;
s->be = tcg_malloc(sizeof(TCGBackendData));
}
static inline int temp_idx(TCGContext *s, TCGTemp *ts)
{
ptrdiff_t n = ts - s->temps;
tcg_debug_assert(n >= 0 && n < s->nb_temps);
return n;
}
static inline TCGTemp *tcg_temp_alloc(TCGContext *s)
{
int n = s->nb_temps++;
tcg_debug_assert(n < TCG_MAX_TEMPS);
return memset(&s->temps[n], 0, sizeof(TCGTemp));
}
static inline TCGTemp *tcg_global_alloc(TCGContext *s)
{
tcg_debug_assert(s->nb_globals == s->nb_temps);
s->nb_globals++;
return tcg_temp_alloc(s);
}
static int tcg_global_reg_new_internal(TCGContext *s, TCGType type,
TCGReg reg, const char *name)
{
TCGTemp *ts;
if (TCG_TARGET_REG_BITS == 32 && type != TCG_TYPE_I32) {
tcg_abort();
}
ts = tcg_global_alloc(s);
ts->base_type = type;
ts->type = type;
ts->fixed_reg = 1;
ts->reg = reg;
ts->name = name;
tcg_regset_set_reg(s->reserved_regs, reg);
return temp_idx(s, ts);
}
void tcg_set_frame(TCGContext *s, TCGReg reg, intptr_t start, intptr_t size)
{
int idx;
s->frame_start = start;
s->frame_end = start + size;
idx = tcg_global_reg_new_internal(s, TCG_TYPE_PTR, reg, "_frame");
s->frame_temp = &s->temps[idx];
}
TCGv_i32 tcg_global_reg_new_i32(TCGReg reg, const char *name)
{
TCGContext *s = &tcg_ctx;
int idx;
if (tcg_regset_test_reg(s->reserved_regs, reg)) {
tcg_abort();
}
idx = tcg_global_reg_new_internal(s, TCG_TYPE_I32, reg, name);
return MAKE_TCGV_I32(idx);
}
TCGv_i64 tcg_global_reg_new_i64(TCGReg reg, const char *name)
{
TCGContext *s = &tcg_ctx;
int idx;
if (tcg_regset_test_reg(s->reserved_regs, reg)) {
tcg_abort();
}
idx = tcg_global_reg_new_internal(s, TCG_TYPE_I64, reg, name);
return MAKE_TCGV_I64(idx);
}
int tcg_global_mem_new_internal(TCGType type, TCGv_ptr base,
intptr_t offset, const char *name)
{
TCGContext *s = &tcg_ctx;
TCGTemp *base_ts = &s->temps[GET_TCGV_PTR(base)];
TCGTemp *ts = tcg_global_alloc(s);
int bigendian = 0;
#ifdef HOST_WORDS_BIGENDIAN
bigendian = 1;
#endif
if (TCG_TARGET_REG_BITS == 32 && type == TCG_TYPE_I64) {
TCGTemp *ts2 = tcg_global_alloc(s);
char buf[64];
ts->base_type = TCG_TYPE_I64;
ts->type = TCG_TYPE_I32;
ts->mem_allocated = 1;
ts->mem_base = base_ts;
ts->mem_offset = offset + bigendian * 4;
pstrcpy(buf, sizeof(buf), name);
pstrcat(buf, sizeof(buf), "_0");
ts->name = strdup(buf);
tcg_debug_assert(ts2 == ts + 1);
ts2->base_type = TCG_TYPE_I64;
ts2->type = TCG_TYPE_I32;
ts2->mem_allocated = 1;
ts2->mem_base = base_ts;
ts2->mem_offset = offset + (1 - bigendian) * 4;
pstrcpy(buf, sizeof(buf), name);
pstrcat(buf, sizeof(buf), "_1");
ts->name = strdup(buf);
} else {
ts->base_type = type;
ts->type = type;
ts->mem_allocated = 1;
ts->mem_base = base_ts;
ts->mem_offset = offset;
ts->name = name;
}
return temp_idx(s, ts);
}
static int tcg_temp_new_internal(TCGType type, int temp_local)
{
TCGContext *s = &tcg_ctx;
TCGTemp *ts;
int idx, k;
k = type + (temp_local ? TCG_TYPE_COUNT : 0);
idx = find_first_bit(s->free_temps[k].l, TCG_MAX_TEMPS);
if (idx < TCG_MAX_TEMPS) {
/* There is already an available temp with the right type. */
clear_bit(idx, s->free_temps[k].l);
ts = &s->temps[idx];
ts->temp_allocated = 1;
tcg_debug_assert(ts->base_type == type);
tcg_debug_assert(ts->temp_local == temp_local);
} else {
ts = tcg_temp_alloc(s);
if (TCG_TARGET_REG_BITS == 32 && type == TCG_TYPE_I64) {
TCGTemp *ts2 = tcg_temp_alloc(s);
ts->base_type = type;
ts->type = TCG_TYPE_I32;
ts->temp_allocated = 1;
ts->temp_local = temp_local;
tcg_debug_assert(ts2 == ts + 1);
ts2->base_type = TCG_TYPE_I64;
ts2->type = TCG_TYPE_I32;
ts2->temp_allocated = 1;
ts2->temp_local = temp_local;
} else {
ts->base_type = type;
ts->type = type;
ts->temp_allocated = 1;
ts->temp_local = temp_local;
}
idx = temp_idx(s, ts);
}
#if defined(CONFIG_DEBUG_TCG)
s->temps_in_use++;
#endif
return idx;
}
TCGv_i32 tcg_temp_new_internal_i32(int temp_local)
{
int idx;
idx = tcg_temp_new_internal(TCG_TYPE_I32, temp_local);
return MAKE_TCGV_I32(idx);
}
TCGv_i64 tcg_temp_new_internal_i64(int temp_local)
{
int idx;
idx = tcg_temp_new_internal(TCG_TYPE_I64, temp_local);
return MAKE_TCGV_I64(idx);
}
static void tcg_temp_free_internal(int idx)
{
TCGContext *s = &tcg_ctx;
TCGTemp *ts;
int k;
#if defined(CONFIG_DEBUG_TCG)
s->temps_in_use--;
if (s->temps_in_use < 0) {
fprintf(stderr, "More temporaries freed than allocated!\n");
}
#endif
assert(idx >= s->nb_globals && idx < s->nb_temps);
ts = &s->temps[idx];
assert(ts->temp_allocated != 0);
ts->temp_allocated = 0;
k = ts->base_type + (ts->temp_local ? TCG_TYPE_COUNT : 0);
set_bit(idx, s->free_temps[k].l);
}
void tcg_temp_free_i32(TCGv_i32 arg)
{
tcg_temp_free_internal(GET_TCGV_I32(arg));
}
void tcg_temp_free_i64(TCGv_i64 arg)
{
tcg_temp_free_internal(GET_TCGV_I64(arg));
}
TCGv_i32 tcg_const_i32(int32_t val)
{
TCGv_i32 t0;
t0 = tcg_temp_new_i32();
tcg_gen_movi_i32(t0, val);
return t0;
}
TCGv_i64 tcg_const_i64(int64_t val)
{
TCGv_i64 t0;
t0 = tcg_temp_new_i64();
tcg_gen_movi_i64(t0, val);
return t0;
}
TCGv_i32 tcg_const_local_i32(int32_t val)
{
TCGv_i32 t0;
t0 = tcg_temp_local_new_i32();
tcg_gen_movi_i32(t0, val);
return t0;
}
TCGv_i64 tcg_const_local_i64(int64_t val)
{
TCGv_i64 t0;
t0 = tcg_temp_local_new_i64();
tcg_gen_movi_i64(t0, val);
return t0;
}
#if defined(CONFIG_DEBUG_TCG)
void tcg_clear_temp_count(void)
{
TCGContext *s = &tcg_ctx;
s->temps_in_use = 0;
}
int tcg_check_temp_count(void)
{
TCGContext *s = &tcg_ctx;
if (s->temps_in_use) {
/* Clear the count so that we don't give another
* warning immediately next time around.
*/
s->temps_in_use = 0;
return 1;
}
return 0;
}
#endif
/* Note: we convert the 64 bit args to 32 bit and do some alignment
and endian swap. Maybe it would be better to do the alignment
and endian swap in tcg_reg_alloc_call(). */
void tcg_gen_callN(TCGContext *s, void *func, TCGArg ret,
int nargs, TCGArg *args)
{
int i, real_args, nb_rets, pi, pi_first;
unsigned sizemask, flags;
TCGHelperInfo *info;
info = g_hash_table_lookup(s->helpers, (gpointer)func);
flags = info->flags;
sizemask = info->sizemask;
#if defined(__sparc__) && !defined(__arch64__) \
&& !defined(CONFIG_TCG_INTERPRETER)
/* We have 64-bit values in one register, but need to pass as two
separate parameters. Split them. */
int orig_sizemask = sizemask;
int orig_nargs = nargs;
TCGv_i64 retl, reth;
TCGV_UNUSED_I64(retl);
TCGV_UNUSED_I64(reth);
if (sizemask != 0) {
TCGArg *split_args = __builtin_alloca(sizeof(TCGArg) * nargs * 2);
for (i = real_args = 0; i < nargs; ++i) {
int is_64bit = sizemask & (1 << (i+1)*2);
if (is_64bit) {
TCGv_i64 orig = MAKE_TCGV_I64(args[i]);
TCGv_i32 h = tcg_temp_new_i32();
TCGv_i32 l = tcg_temp_new_i32();
tcg_gen_extr_i64_i32(l, h, orig);
split_args[real_args++] = GET_TCGV_I32(h);
split_args[real_args++] = GET_TCGV_I32(l);
} else {
split_args[real_args++] = args[i];
}
}
nargs = real_args;
args = split_args;
sizemask = 0;
}
#elif defined(TCG_TARGET_EXTEND_ARGS) && TCG_TARGET_REG_BITS == 64
for (i = 0; i < nargs; ++i) {
int is_64bit = sizemask & (1 << (i+1)*2);
int is_signed = sizemask & (2 << (i+1)*2);
if (!is_64bit) {
TCGv_i64 temp = tcg_temp_new_i64();
TCGv_i64 orig = MAKE_TCGV_I64(args[i]);
if (is_signed) {
tcg_gen_ext32s_i64(temp, orig);
} else {
tcg_gen_ext32u_i64(temp, orig);
}
args[i] = GET_TCGV_I64(temp);
}
}
#endif /* TCG_TARGET_EXTEND_ARGS */
pi_first = pi = s->gen_next_parm_idx;
if (ret != TCG_CALL_DUMMY_ARG) {
#if defined(__sparc__) && !defined(__arch64__) \
&& !defined(CONFIG_TCG_INTERPRETER)
if (orig_sizemask & 1) {
/* The 32-bit ABI is going to return the 64-bit value in
the %o0/%o1 register pair. Prepare for this by using
two return temporaries, and reassemble below. */
retl = tcg_temp_new_i64();
reth = tcg_temp_new_i64();
s->gen_opparam_buf[pi++] = GET_TCGV_I64(reth);
s->gen_opparam_buf[pi++] = GET_TCGV_I64(retl);
nb_rets = 2;
} else {
s->gen_opparam_buf[pi++] = ret;
nb_rets = 1;
}
#else
if (TCG_TARGET_REG_BITS < 64 && (sizemask & 1)) {
#ifdef HOST_WORDS_BIGENDIAN
s->gen_opparam_buf[pi++] = ret + 1;
s->gen_opparam_buf[pi++] = ret;
#else
s->gen_opparam_buf[pi++] = ret;
s->gen_opparam_buf[pi++] = ret + 1;
#endif
nb_rets = 2;
} else {
s->gen_opparam_buf[pi++] = ret;
nb_rets = 1;
}
#endif
} else {
nb_rets = 0;
}
real_args = 0;
for (i = 0; i < nargs; i++) {
int is_64bit = sizemask & (1 << (i+1)*2);
if (TCG_TARGET_REG_BITS < 64 && is_64bit) {
#ifdef TCG_TARGET_CALL_ALIGN_ARGS
/* some targets want aligned 64 bit args */
if (real_args & 1) {
s->gen_opparam_buf[pi++] = TCG_CALL_DUMMY_ARG;
real_args++;
}
#endif
/* If stack grows up, then we will be placing successive
arguments at lower addresses, which means we need to
reverse the order compared to how we would normally
treat either big or little-endian. For those arguments
that will wind up in registers, this still works for
HPPA (the only current STACK_GROWSUP target) since the
argument registers are *also* allocated in decreasing
order. If another such target is added, this logic may
have to get more complicated to differentiate between
stack arguments and register arguments. */
#if defined(HOST_WORDS_BIGENDIAN) != defined(TCG_TARGET_STACK_GROWSUP)
s->gen_opparam_buf[pi++] = args[i] + 1;
s->gen_opparam_buf[pi++] = args[i];
#else
s->gen_opparam_buf[pi++] = args[i];
s->gen_opparam_buf[pi++] = args[i] + 1;
#endif
real_args += 2;
continue;
}
s->gen_opparam_buf[pi++] = args[i];
real_args++;
}
s->gen_opparam_buf[pi++] = (uintptr_t)func;
s->gen_opparam_buf[pi++] = flags;
i = s->gen_next_op_idx;
tcg_debug_assert(i < OPC_BUF_SIZE);
tcg_debug_assert(pi <= OPPARAM_BUF_SIZE);
/* Set links for sequential allocation during translation. */
s->gen_op_buf[i] = (TCGOp){
.opc = INDEX_op_call,
.callo = nb_rets,
.calli = real_args,
.args = pi_first,
.prev = i - 1,
.next = i + 1
};
/* Make sure the calli field didn't overflow. */
tcg_debug_assert(s->gen_op_buf[i].calli == real_args);
s->gen_last_op_idx = i;
s->gen_next_op_idx = i + 1;
s->gen_next_parm_idx = pi;
#if defined(__sparc__) && !defined(__arch64__) \
&& !defined(CONFIG_TCG_INTERPRETER)
/* Free all of the parts we allocated above. */
for (i = real_args = 0; i < orig_nargs; ++i) {
int is_64bit = orig_sizemask & (1 << (i+1)*2);
if (is_64bit) {
TCGv_i32 h = MAKE_TCGV_I32(args[real_args++]);
TCGv_i32 l = MAKE_TCGV_I32(args[real_args++]);
tcg_temp_free_i32(h);
tcg_temp_free_i32(l);
} else {
real_args++;
}
}
if (orig_sizemask & 1) {
/* The 32-bit ABI returned two 32-bit pieces. Re-assemble them.
Note that describing these as TCGv_i64 eliminates an unnecessary
zero-extension that tcg_gen_concat_i32_i64 would create. */
tcg_gen_concat32_i64(MAKE_TCGV_I64(ret), retl, reth);
tcg_temp_free_i64(retl);
tcg_temp_free_i64(reth);
}
#elif defined(TCG_TARGET_EXTEND_ARGS) && TCG_TARGET_REG_BITS == 64
for (i = 0; i < nargs; ++i) {
int is_64bit = sizemask & (1 << (i+1)*2);
if (!is_64bit) {
TCGv_i64 temp = MAKE_TCGV_I64(args[i]);
tcg_temp_free_i64(temp);
}
}
#endif /* TCG_TARGET_EXTEND_ARGS */
}
static void tcg_reg_alloc_start(TCGContext *s)
{
int i;
TCGTemp *ts;
for(i = 0; i < s->nb_globals; i++) {
ts = &s->temps[i];
if (ts->fixed_reg) {
ts->val_type = TEMP_VAL_REG;
} else {
ts->val_type = TEMP_VAL_MEM;
}
}
for(i = s->nb_globals; i < s->nb_temps; i++) {
ts = &s->temps[i];
if (ts->temp_local) {
ts->val_type = TEMP_VAL_MEM;
} else {
ts->val_type = TEMP_VAL_DEAD;
}
ts->mem_allocated = 0;
ts->fixed_reg = 0;
}
for(i = 0; i < TCG_TARGET_NB_REGS; i++) {
s->reg_to_temp[i] = -1;
}
}
static char *tcg_get_arg_str_idx(TCGContext *s, char *buf, int buf_size,
int idx)
{
TCGTemp *ts;
assert(idx >= 0 && idx < s->nb_temps);
ts = &s->temps[idx];
if (idx < s->nb_globals) {
pstrcpy(buf, buf_size, ts->name);
} else {
if (ts->temp_local)
snprintf(buf, buf_size, "loc%d", idx - s->nb_globals);
else
snprintf(buf, buf_size, "tmp%d", idx - s->nb_globals);
}
return buf;
}
/* Find helper name. */
static inline const char *tcg_find_helper(TCGContext *s, uintptr_t val)
{
const char *ret = NULL;
if (s->helpers) {
TCGHelperInfo *info = g_hash_table_lookup(s->helpers, (gpointer)val);
if (info) {
ret = info->name;
}
}
return ret;
}
static const char * const cond_name[] =
{
[TCG_COND_NEVER] = "never",
[TCG_COND_ALWAYS] = "always",
[TCG_COND_EQ] = "eq",
[TCG_COND_NE] = "ne",
[TCG_COND_LT] = "lt",
[TCG_COND_GE] = "ge",
[TCG_COND_LE] = "le",
[TCG_COND_GT] = "gt",
[TCG_COND_LTU] = "ltu",
[TCG_COND_GEU] = "geu",
[TCG_COND_LEU] = "leu",
[TCG_COND_GTU] = "gtu"
};
static const char * const ldst_name[] =
{
[MO_UB] = "ub",
[MO_SB] = "sb",
[MO_LEUW] = "leuw",
[MO_LESW] = "lesw",
[MO_LEUL] = "leul",
[MO_LESL] = "lesl",
[MO_LEQ] = "leq",
[MO_BEUW] = "beuw",
[MO_BESW] = "besw",
[MO_BEUL] = "beul",
[MO_BESL] = "besl",
[MO_BEQ] = "beq",
};
void tcg_dump_ops(TCGContext *s)
{
char buf[128];
TCGOp *op;
int oi;
for (oi = s->gen_first_op_idx; oi >= 0; oi = op->next) {
int i, k, nb_oargs, nb_iargs, nb_cargs;
const TCGOpDef *def;
const TCGArg *args;
TCGOpcode c;
op = &s->gen_op_buf[oi];
c = op->opc;
def = &tcg_op_defs[c];
args = &s->gen_opparam_buf[op->args];
if (c == INDEX_op_insn_start) {
qemu_log("%s ----", oi != s->gen_first_op_idx ? "\n" : "");
for (i = 0; i < TARGET_INSN_START_WORDS; ++i) {
target_ulong a;
#if TARGET_LONG_BITS > TCG_TARGET_REG_BITS
a = ((target_ulong)args[i * 2 + 1] << 32) | args[i * 2];
#else
a = args[i];
#endif
qemu_log(" " TARGET_FMT_lx, a);
}
} else if (c == INDEX_op_call) {
/* variable number of arguments */
nb_oargs = op->callo;
nb_iargs = op->calli;
nb_cargs = def->nb_cargs;
/* function name, flags, out args */
qemu_log(" %s %s,$0x%" TCG_PRIlx ",$%d", def->name,
tcg_find_helper(s, args[nb_oargs + nb_iargs]),
args[nb_oargs + nb_iargs + 1], nb_oargs);
for (i = 0; i < nb_oargs; i++) {
qemu_log(",%s", tcg_get_arg_str_idx(s, buf, sizeof(buf),
args[i]));
}
for (i = 0; i < nb_iargs; i++) {
TCGArg arg = args[nb_oargs + i];
const char *t = "<dummy>";
if (arg != TCG_CALL_DUMMY_ARG) {
t = tcg_get_arg_str_idx(s, buf, sizeof(buf), arg);
}
qemu_log(",%s", t);
}
} else {
qemu_log(" %s ", def->name);
nb_oargs = def->nb_oargs;
nb_iargs = def->nb_iargs;
nb_cargs = def->nb_cargs;
k = 0;
for (i = 0; i < nb_oargs; i++) {
if (k != 0) {
qemu_log(",");
}
qemu_log("%s", tcg_get_arg_str_idx(s, buf, sizeof(buf),
args[k++]));
}
for (i = 0; i < nb_iargs; i++) {
if (k != 0) {
qemu_log(",");
}
qemu_log("%s", tcg_get_arg_str_idx(s, buf, sizeof(buf),
args[k++]));
}
switch (c) {
case INDEX_op_brcond_i32:
case INDEX_op_setcond_i32:
case INDEX_op_movcond_i32:
case INDEX_op_brcond2_i32:
case INDEX_op_setcond2_i32:
case INDEX_op_brcond_i64:
case INDEX_op_setcond_i64:
case INDEX_op_movcond_i64:
if (args[k] < ARRAY_SIZE(cond_name) && cond_name[args[k]]) {
qemu_log(",%s", cond_name[args[k++]]);
} else {
qemu_log(",$0x%" TCG_PRIlx, args[k++]);
}
i = 1;
break;
case INDEX_op_qemu_ld_i32:
case INDEX_op_qemu_st_i32:
case INDEX_op_qemu_ld_i64:
case INDEX_op_qemu_st_i64:
{
TCGMemOpIdx oi = args[k++];
TCGMemOp op = get_memop(oi);
unsigned ix = get_mmuidx(oi);
if (op & ~(MO_AMASK | MO_BSWAP | MO_SSIZE)) {
qemu_log(",$0x%x,%u", op, ix);
} else {
const char *s_al = "", *s_op;
if (op & MO_AMASK) {
if ((op & MO_AMASK) == MO_ALIGN) {
s_al = "al+";
} else {
s_al = "un+";
}
}
s_op = ldst_name[op & (MO_BSWAP | MO_SSIZE)];
qemu_log(",%s%s,%u", s_al, s_op, ix);
}
i = 1;
}
break;
default:
i = 0;
break;
}
switch (c) {
case INDEX_op_set_label:
case INDEX_op_br:
case INDEX_op_brcond_i32:
case INDEX_op_brcond_i64:
case INDEX_op_brcond2_i32:
qemu_log("%s$L%d", k ? "," : "", arg_label(args[k])->id);
i++, k++;
break;
default:
break;
}
for (; i < nb_cargs; i++, k++) {
qemu_log("%s$0x%" TCG_PRIlx, k ? "," : "", args[k]);
}
}
qemu_log("\n");
}
}
/* we give more priority to constraints with less registers */
static int get_constraint_priority(const TCGOpDef *def, int k)
{
const TCGArgConstraint *arg_ct;
int i, n;
arg_ct = &def->args_ct[k];
if (arg_ct->ct & TCG_CT_ALIAS) {
/* an alias is equivalent to a single register */
n = 1;
} else {
if (!(arg_ct->ct & TCG_CT_REG))
return 0;
n = 0;
for(i = 0; i < TCG_TARGET_NB_REGS; i++) {
if (tcg_regset_test_reg(arg_ct->u.regs, i))
n++;
}
}
return TCG_TARGET_NB_REGS - n + 1;
}
/* sort from highest priority to lowest */
static void sort_constraints(TCGOpDef *def, int start, int n)
{
int i, j, p1, p2, tmp;
for(i = 0; i < n; i++)
def->sorted_args[start + i] = start + i;
if (n <= 1)
return;
for(i = 0; i < n - 1; i++) {
for(j = i + 1; j < n; j++) {
p1 = get_constraint_priority(def, def->sorted_args[start + i]);
p2 = get_constraint_priority(def, def->sorted_args[start + j]);
if (p1 < p2) {
tmp = def->sorted_args[start + i];
def->sorted_args[start + i] = def->sorted_args[start + j];
def->sorted_args[start + j] = tmp;
}
}
}
}
void tcg_add_target_add_op_defs(const TCGTargetOpDef *tdefs)
{
TCGOpcode op;
TCGOpDef *def;
const char *ct_str;
int i, nb_args;
for(;;) {
if (tdefs->op == (TCGOpcode)-1)
break;
op = tdefs->op;
assert((unsigned)op < NB_OPS);
def = &tcg_op_defs[op];
#if defined(CONFIG_DEBUG_TCG)
/* Duplicate entry in op definitions? */
assert(!def->used);
def->used = 1;
#endif
nb_args = def->nb_iargs + def->nb_oargs;
for(i = 0; i < nb_args; i++) {
ct_str = tdefs->args_ct_str[i];
/* Incomplete TCGTargetOpDef entry? */
assert(ct_str != NULL);
tcg_regset_clear(def->args_ct[i].u.regs);
def->args_ct[i].ct = 0;
if (ct_str[0] >= '0' && ct_str[0] <= '9') {
int oarg;
oarg = ct_str[0] - '0';
assert(oarg < def->nb_oargs);
assert(def->args_ct[oarg].ct & TCG_CT_REG);
/* TCG_CT_ALIAS is for the output arguments. The input
argument is tagged with TCG_CT_IALIAS. */
def->args_ct[i] = def->args_ct[oarg];
def->args_ct[oarg].ct = TCG_CT_ALIAS;
def->args_ct[oarg].alias_index = i;
def->args_ct[i].ct |= TCG_CT_IALIAS;
def->args_ct[i].alias_index = oarg;
} else {
for(;;) {
if (*ct_str == '\0')
break;
switch(*ct_str) {
case 'i':
def->args_ct[i].ct |= TCG_CT_CONST;
ct_str++;
break;
default:
if (target_parse_constraint(&def->args_ct[i], &ct_str) < 0) {
fprintf(stderr, "Invalid constraint '%s' for arg %d of operation '%s'\n",
ct_str, i, def->name);
exit(1);
}
}
}
}
}
/* TCGTargetOpDef entry with too much information? */
assert(i == TCG_MAX_OP_ARGS || tdefs->args_ct_str[i] == NULL);
/* sort the constraints (XXX: this is just an heuristic) */
sort_constraints(def, 0, def->nb_oargs);
sort_constraints(def, def->nb_oargs, def->nb_iargs);
#if 0
{
int i;
printf("%s: sorted=", def->name);
for(i = 0; i < def->nb_oargs + def->nb_iargs; i++)
printf(" %d", def->sorted_args[i]);
printf("\n");
}
#endif
tdefs++;
}
#if defined(CONFIG_DEBUG_TCG)
i = 0;
for (op = 0; op < tcg_op_defs_max; op++) {
const TCGOpDef *def = &tcg_op_defs[op];
if (def->flags & TCG_OPF_NOT_PRESENT) {
/* Wrong entry in op definitions? */
if (def->used) {
fprintf(stderr, "Invalid op definition for %s\n", def->name);
i = 1;
}
} else {
/* Missing entry in op definitions? */
if (!def->used) {
fprintf(stderr, "Missing op definition for %s\n", def->name);
i = 1;
}
}
}
if (i == 1) {
tcg_abort();
}
#endif
}
void tcg_op_remove(TCGContext *s, TCGOp *op)
{
int next = op->next;
int prev = op->prev;
if (next >= 0) {
s->gen_op_buf[next].prev = prev;
} else {
s->gen_last_op_idx = prev;
}
if (prev >= 0) {
s->gen_op_buf[prev].next = next;
} else {
s->gen_first_op_idx = next;
}
memset(op, -1, sizeof(*op));
#ifdef CONFIG_PROFILER
s->del_op_count++;
#endif
}
#ifdef USE_LIVENESS_ANALYSIS
/* liveness analysis: end of function: all temps are dead, and globals
should be in memory. */
static inline void tcg_la_func_end(TCGContext *s, uint8_t *dead_temps,
uint8_t *mem_temps)
{
memset(dead_temps, 1, s->nb_temps);
memset(mem_temps, 1, s->nb_globals);
memset(mem_temps + s->nb_globals, 0, s->nb_temps - s->nb_globals);
}
/* liveness analysis: end of basic block: all temps are dead, globals
and local temps should be in memory. */
static inline void tcg_la_bb_end(TCGContext *s, uint8_t *dead_temps,
uint8_t *mem_temps)
{
int i;
memset(dead_temps, 1, s->nb_temps);
memset(mem_temps, 1, s->nb_globals);
for(i = s->nb_globals; i < s->nb_temps; i++) {
mem_temps[i] = s->temps[i].temp_local;
}
}
/* Liveness analysis : update the opc_dead_args array to tell if a
given input arguments is dead. Instructions updating dead
temporaries are removed. */
static void tcg_liveness_analysis(TCGContext *s)
{
uint8_t *dead_temps, *mem_temps;
int oi, oi_prev, nb_ops;
nb_ops = s->gen_next_op_idx;
s->op_dead_args = tcg_malloc(nb_ops * sizeof(uint16_t));
s->op_sync_args = tcg_malloc(nb_ops * sizeof(uint8_t));
dead_temps = tcg_malloc(s->nb_temps);
mem_temps = tcg_malloc(s->nb_temps);
tcg_la_func_end(s, dead_temps, mem_temps);
for (oi = s->gen_last_op_idx; oi >= 0; oi = oi_prev) {
int i, nb_iargs, nb_oargs;
TCGOpcode opc_new, opc_new2;
bool have_opc_new2;
uint16_t dead_args;
uint8_t sync_args;
TCGArg arg;
TCGOp * const op = &s->gen_op_buf[oi];
TCGArg * const args = &s->gen_opparam_buf[op->args];
TCGOpcode opc = op->opc;
const TCGOpDef *def = &tcg_op_defs[opc];
oi_prev = op->prev;
switch (opc) {
case INDEX_op_call:
{
int call_flags;
nb_oargs = op->callo;
nb_iargs = op->calli;
call_flags = args[nb_oargs + nb_iargs + 1];
/* pure functions can be removed if their result is unused */
if (call_flags & TCG_CALL_NO_SIDE_EFFECTS) {
for (i = 0; i < nb_oargs; i++) {
arg = args[i];
if (!dead_temps[arg] || mem_temps[arg]) {
goto do_not_remove_call;
}
}
goto do_remove;
} else {
do_not_remove_call:
/* output args are dead */
dead_args = 0;
sync_args = 0;
for (i = 0; i < nb_oargs; i++) {
arg = args[i];
if (dead_temps[arg]) {
dead_args |= (1 << i);
}
if (mem_temps[arg]) {
sync_args |= (1 << i);
}
dead_temps[arg] = 1;
mem_temps[arg] = 0;
}
if (!(call_flags & TCG_CALL_NO_READ_GLOBALS)) {
/* globals should be synced to memory */
memset(mem_temps, 1, s->nb_globals);
}
if (!(call_flags & (TCG_CALL_NO_WRITE_GLOBALS |
TCG_CALL_NO_READ_GLOBALS))) {
/* globals should go back to memory */
memset(dead_temps, 1, s->nb_globals);
}
/* record arguments that die in this helper */
for (i = nb_oargs; i < nb_iargs + nb_oargs; i++) {
arg = args[i];
if (arg != TCG_CALL_DUMMY_ARG) {
if (dead_temps[arg]) {
dead_args |= (1 << i);
}
}
}
/* input arguments are live for preceding opcodes */
for (i = nb_oargs; i < nb_oargs + nb_iargs; i++) {
arg = args[i];
dead_temps[arg] = 0;
}
s->op_dead_args[oi] = dead_args;
s->op_sync_args[oi] = sync_args;
}
}
break;
case INDEX_op_insn_start:
break;
case INDEX_op_discard:
/* mark the temporary as dead */
dead_temps[args[0]] = 1;
mem_temps[args[0]] = 0;
break;
case INDEX_op_add2_i32:
opc_new = INDEX_op_add_i32;
goto do_addsub2;
case INDEX_op_sub2_i32:
opc_new = INDEX_op_sub_i32;
goto do_addsub2;
case INDEX_op_add2_i64:
opc_new = INDEX_op_add_i64;
goto do_addsub2;
case INDEX_op_sub2_i64:
opc_new = INDEX_op_sub_i64;
do_addsub2:
nb_iargs = 4;
nb_oargs = 2;
/* Test if the high part of the operation is dead, but not
the low part. The result can be optimized to a simple
add or sub. This happens often for x86_64 guest when the
cpu mode is set to 32 bit. */
if (dead_temps[args[1]] && !mem_temps[args[1]]) {
if (dead_temps[args[0]] && !mem_temps[args[0]]) {
goto do_remove;
}
/* Replace the opcode and adjust the args in place,
leaving 3 unused args at the end. */
op->opc = opc = opc_new;
args[1] = args[2];
args[2] = args[4];
/* Fall through and mark the single-word operation live. */
nb_iargs = 2;
nb_oargs = 1;
}
goto do_not_remove;
case INDEX_op_mulu2_i32:
opc_new = INDEX_op_mul_i32;
opc_new2 = INDEX_op_muluh_i32;
have_opc_new2 = TCG_TARGET_HAS_muluh_i32;
goto do_mul2;
case INDEX_op_muls2_i32:
opc_new = INDEX_op_mul_i32;
opc_new2 = INDEX_op_mulsh_i32;
have_opc_new2 = TCG_TARGET_HAS_mulsh_i32;
goto do_mul2;
case INDEX_op_mulu2_i64:
opc_new = INDEX_op_mul_i64;
opc_new2 = INDEX_op_muluh_i64;
have_opc_new2 = TCG_TARGET_HAS_muluh_i64;
goto do_mul2;
case INDEX_op_muls2_i64:
opc_new = INDEX_op_mul_i64;
opc_new2 = INDEX_op_mulsh_i64;
have_opc_new2 = TCG_TARGET_HAS_mulsh_i64;
goto do_mul2;
do_mul2:
nb_iargs = 2;
nb_oargs = 2;
if (dead_temps[args[1]] && !mem_temps[args[1]]) {
if (dead_temps[args[0]] && !mem_temps[args[0]]) {
/* Both parts of the operation are dead. */
goto do_remove;
}
/* The high part of the operation is dead; generate the low. */
op->opc = opc = opc_new;
args[1] = args[2];
args[2] = args[3];
} else if (have_opc_new2 && dead_temps[args[0]]
&& !mem_temps[args[0]]) {
/* The low part of the operation is dead; generate the high. */
op->opc = opc = opc_new2;
args[0] = args[1];
args[1] = args[2];
args[2] = args[3];
} else {
goto do_not_remove;
}
/* Mark the single-word operation live. */
nb_oargs = 1;
goto do_not_remove;
default:
/* XXX: optimize by hardcoding common cases (e.g. triadic ops) */
nb_iargs = def->nb_iargs;
nb_oargs = def->nb_oargs;
/* Test if the operation can be removed because all
its outputs are dead. We assume that nb_oargs == 0
implies side effects */
if (!(def->flags & TCG_OPF_SIDE_EFFECTS) && nb_oargs != 0) {
for (i = 0; i < nb_oargs; i++) {
arg = args[i];
if (!dead_temps[arg] || mem_temps[arg]) {
goto do_not_remove;
}
}
do_remove:
tcg_op_remove(s, op);
} else {
do_not_remove:
/* output args are dead */
dead_args = 0;
sync_args = 0;
for (i = 0; i < nb_oargs; i++) {
arg = args[i];
if (dead_temps[arg]) {
dead_args |= (1 << i);
}
if (mem_temps[arg]) {
sync_args |= (1 << i);
}
dead_temps[arg] = 1;
mem_temps[arg] = 0;
}
/* if end of basic block, update */
if (def->flags & TCG_OPF_BB_END) {
tcg_la_bb_end(s, dead_temps, mem_temps);
} else if (def->flags & TCG_OPF_SIDE_EFFECTS) {
/* globals should be synced to memory */
memset(mem_temps, 1, s->nb_globals);
}
/* record arguments that die in this opcode */
for (i = nb_oargs; i < nb_oargs + nb_iargs; i++) {
arg = args[i];
if (dead_temps[arg]) {
dead_args |= (1 << i);
}
}
/* input arguments are live for preceding opcodes */
for (i = nb_oargs; i < nb_oargs + nb_iargs; i++) {
arg = args[i];
dead_temps[arg] = 0;
}
s->op_dead_args[oi] = dead_args;
s->op_sync_args[oi] = sync_args;
}
break;
}
}
}
#else
/* dummy liveness analysis */
static void tcg_liveness_analysis(TCGContext *s)
{
int nb_ops = s->gen_next_op_idx;
s->op_dead_args = tcg_malloc(nb_ops * sizeof(uint16_t));
memset(s->op_dead_args, 0, nb_ops * sizeof(uint16_t));
s->op_sync_args = tcg_malloc(nb_ops * sizeof(uint8_t));
memset(s->op_sync_args, 0, nb_ops * sizeof(uint8_t));
}
#endif
#ifndef NDEBUG
static void dump_regs(TCGContext *s)
{
TCGTemp *ts;
int i;
char buf[64];
for(i = 0; i < s->nb_temps; i++) {
ts = &s->temps[i];
printf(" %10s: ", tcg_get_arg_str_idx(s, buf, sizeof(buf), i));
switch(ts->val_type) {
case TEMP_VAL_REG:
printf("%s", tcg_target_reg_names[ts->reg]);
break;
case TEMP_VAL_MEM:
printf("%d(%s)", (int)ts->mem_offset,
tcg_target_reg_names[ts->mem_base->reg]);
break;
case TEMP_VAL_CONST:
printf("$0x%" TCG_PRIlx, ts->val);
break;
case TEMP_VAL_DEAD:
printf("D");
break;
default:
printf("???");
break;
}
printf("\n");
}
for(i = 0; i < TCG_TARGET_NB_REGS; i++) {
if (s->reg_to_temp[i] >= 0) {
printf("%s: %s\n",
tcg_target_reg_names[i],
tcg_get_arg_str_idx(s, buf, sizeof(buf), s->reg_to_temp[i]));
}
}
}
static void check_regs(TCGContext *s)
{
TCGReg reg;
int k;
TCGTemp *ts;
char buf[64];
for(reg = 0; reg < TCG_TARGET_NB_REGS; reg++) {
k = s->reg_to_temp[reg];
if (k >= 0) {
ts = &s->temps[k];
if (ts->val_type != TEMP_VAL_REG ||
ts->reg != reg) {
printf("Inconsistency for register %s:\n",
tcg_target_reg_names[reg]);
goto fail;
}
}
}
for(k = 0; k < s->nb_temps; k++) {
ts = &s->temps[k];
if (ts->val_type == TEMP_VAL_REG &&
!ts->fixed_reg &&
s->reg_to_temp[ts->reg] != k) {
printf("Inconsistency for temp %s:\n",
tcg_get_arg_str_idx(s, buf, sizeof(buf), k));
fail:
printf("reg state:\n");
dump_regs(s);
tcg_abort();
}
}
}
#endif
static void temp_allocate_frame(TCGContext *s, int temp)
{
TCGTemp *ts;
ts = &s->temps[temp];
#if !(defined(__sparc__) && TCG_TARGET_REG_BITS == 64)
/* Sparc64 stack is accessed with offset of 2047 */
s->current_frame_offset = (s->current_frame_offset +
(tcg_target_long)sizeof(tcg_target_long) - 1) &
~(sizeof(tcg_target_long) - 1);
#endif
if (s->current_frame_offset + (tcg_target_long)sizeof(tcg_target_long) >
s->frame_end) {
tcg_abort();
}
ts->mem_offset = s->current_frame_offset;
ts->mem_base = s->frame_temp;
ts->mem_allocated = 1;
s->current_frame_offset += sizeof(tcg_target_long);
}
/* sync register 'reg' by saving it to the corresponding temporary */
static inline void tcg_reg_sync(TCGContext *s, TCGReg reg)
{
TCGTemp *ts;
int temp;
temp = s->reg_to_temp[reg];
ts = &s->temps[temp];
assert(ts->val_type == TEMP_VAL_REG);
if (!ts->mem_coherent && !ts->fixed_reg) {
if (!ts->mem_allocated) {
temp_allocate_frame(s, temp);
}
tcg_out_st(s, ts->type, reg, ts->mem_base->reg, ts->mem_offset);
}
ts->mem_coherent = 1;
}
/* free register 'reg' by spilling the corresponding temporary if necessary */
static void tcg_reg_free(TCGContext *s, TCGReg reg)
{
int temp;
temp = s->reg_to_temp[reg];
if (temp != -1) {
tcg_reg_sync(s, reg);
s->temps[temp].val_type = TEMP_VAL_MEM;
s->reg_to_temp[reg] = -1;
}
}
/* Allocate a register belonging to reg1 & ~reg2 */
static TCGReg tcg_reg_alloc(TCGContext *s, TCGRegSet reg1, TCGRegSet reg2)
{
int i;
TCGReg reg;
TCGRegSet reg_ct;
tcg_regset_andnot(reg_ct, reg1, reg2);
/* first try free registers */
for(i = 0; i < ARRAY_SIZE(tcg_target_reg_alloc_order); i++) {
reg = tcg_target_reg_alloc_order[i];
if (tcg_regset_test_reg(reg_ct, reg) && s->reg_to_temp[reg] == -1)
return reg;
}
/* XXX: do better spill choice */
for(i = 0; i < ARRAY_SIZE(tcg_target_reg_alloc_order); i++) {
reg = tcg_target_reg_alloc_order[i];
if (tcg_regset_test_reg(reg_ct, reg)) {
tcg_reg_free(s, reg);
return reg;
}
}
tcg_abort();
}
/* mark a temporary as dead. */
static inline void temp_dead(TCGContext *s, int temp)
{
TCGTemp *ts;
ts = &s->temps[temp];
if (!ts->fixed_reg) {
if (ts->val_type == TEMP_VAL_REG) {
s->reg_to_temp[ts->reg] = -1;
}
if (temp < s->nb_globals || ts->temp_local) {
ts->val_type = TEMP_VAL_MEM;
} else {
ts->val_type = TEMP_VAL_DEAD;
}
}
}
/* sync a temporary to memory. 'allocated_regs' is used in case a
temporary registers needs to be allocated to store a constant. */
static inline void temp_sync(TCGContext *s, int temp, TCGRegSet allocated_regs)
{
TCGTemp *ts;
ts = &s->temps[temp];
if (!ts->fixed_reg) {
switch(ts->val_type) {
case TEMP_VAL_CONST:
ts->reg = tcg_reg_alloc(s, tcg_target_available_regs[ts->type],
allocated_regs);
ts->val_type = TEMP_VAL_REG;
s->reg_to_temp[ts->reg] = temp;
ts->mem_coherent = 0;
tcg_out_movi(s, ts->type, ts->reg, ts->val);
/* fallthrough*/
case TEMP_VAL_REG:
tcg_reg_sync(s, ts->reg);
break;
case TEMP_VAL_DEAD:
case TEMP_VAL_MEM:
break;
default:
tcg_abort();
}
}
}
/* save a temporary to memory. 'allocated_regs' is used in case a
temporary registers needs to be allocated to store a constant. */
static inline void temp_save(TCGContext *s, int temp, TCGRegSet allocated_regs)
{
#ifdef USE_LIVENESS_ANALYSIS
/* The liveness analysis already ensures that globals are back
in memory. Keep an assert for safety. */
assert(s->temps[temp].val_type == TEMP_VAL_MEM || s->temps[temp].fixed_reg);
#else
temp_sync(s, temp, allocated_regs);
temp_dead(s, temp);
#endif
}
/* save globals to their canonical location and assume they can be
modified be the following code. 'allocated_regs' is used in case a
temporary registers needs to be allocated to store a constant. */
static void save_globals(TCGContext *s, TCGRegSet allocated_regs)
{
int i;
for(i = 0; i < s->nb_globals; i++) {
temp_save(s, i, allocated_regs);
}
}
/* sync globals to their canonical location and assume they can be
read by the following code. 'allocated_regs' is used in case a
temporary registers needs to be allocated to store a constant. */
static void sync_globals(TCGContext *s, TCGRegSet allocated_regs)
{
int i;
for (i = 0; i < s->nb_globals; i++) {
#ifdef USE_LIVENESS_ANALYSIS
assert(s->temps[i].val_type != TEMP_VAL_REG || s->temps[i].fixed_reg ||
s->temps[i].mem_coherent);
#else
temp_sync(s, i, allocated_regs);
#endif
}
}
/* at the end of a basic block, we assume all temporaries are dead and
all globals are stored at their canonical location. */
static void tcg_reg_alloc_bb_end(TCGContext *s, TCGRegSet allocated_regs)
{
TCGTemp *ts;
int i;
for(i = s->nb_globals; i < s->nb_temps; i++) {
ts = &s->temps[i];
if (ts->temp_local) {
temp_save(s, i, allocated_regs);
} else {
#ifdef USE_LIVENESS_ANALYSIS
/* The liveness analysis already ensures that temps are dead.
Keep an assert for safety. */
assert(ts->val_type == TEMP_VAL_DEAD);
#else
temp_dead(s, i);
#endif
}
}
save_globals(s, allocated_regs);
}
#define IS_DEAD_ARG(n) ((dead_args >> (n)) & 1)
#define NEED_SYNC_ARG(n) ((sync_args >> (n)) & 1)
static void tcg_reg_alloc_movi(TCGContext *s, const TCGArg *args,
uint16_t dead_args, uint8_t sync_args)
{
TCGTemp *ots;
tcg_target_ulong val;
ots = &s->temps[args[0]];
val = args[1];
if (ots->fixed_reg) {
/* for fixed registers, we do not do any constant
propagation */
tcg_out_movi(s, ots->type, ots->reg, val);
} else {
/* The movi is not explicitly generated here */
if (ots->val_type == TEMP_VAL_REG)
s->reg_to_temp[ots->reg] = -1;
ots->val_type = TEMP_VAL_CONST;
ots->val = val;
}
if (NEED_SYNC_ARG(0)) {
temp_sync(s, args[0], s->reserved_regs);
}
if (IS_DEAD_ARG(0)) {
temp_dead(s, args[0]);
}
}
static void tcg_reg_alloc_mov(TCGContext *s, const TCGOpDef *def,
const TCGArg *args, uint16_t dead_args,
uint8_t sync_args)
{
TCGRegSet allocated_regs;
TCGTemp *ts, *ots;
TCGType otype, itype;
tcg_regset_set(allocated_regs, s->reserved_regs);
ots = &s->temps[args[0]];
ts = &s->temps[args[1]];
/* Note that otype != itype for no-op truncation. */
otype = ots->type;
itype = ts->type;
/* If the source value is not in a register, and we're going to be
forced to have it in a register in order to perform the copy,
then copy the SOURCE value into its own register first. That way
we don't have to reload SOURCE the next time it is used. */
if (((NEED_SYNC_ARG(0) || ots->fixed_reg) && ts->val_type != TEMP_VAL_REG)
|| ts->val_type == TEMP_VAL_MEM) {
ts->reg = tcg_reg_alloc(s, tcg_target_available_regs[itype],
allocated_regs);
if (ts->val_type == TEMP_VAL_MEM) {
tcg_out_ld(s, itype, ts->reg, ts->mem_base->reg, ts->mem_offset);
ts->mem_coherent = 1;
} else if (ts->val_type == TEMP_VAL_CONST) {
tcg_out_movi(s, itype, ts->reg, ts->val);
ts->mem_coherent = 0;
}
s->reg_to_temp[ts->reg] = args[1];
ts->val_type = TEMP_VAL_REG;
}
if (IS_DEAD_ARG(0) && !ots->fixed_reg) {
/* mov to a non-saved dead register makes no sense (even with
liveness analysis disabled). */
assert(NEED_SYNC_ARG(0));
/* The code above should have moved the temp to a register. */
assert(ts->val_type == TEMP_VAL_REG);
if (!ots->mem_allocated) {
temp_allocate_frame(s, args[0]);
}
tcg_out_st(s, otype, ts->reg, ots->mem_base->reg, ots->mem_offset);
if (IS_DEAD_ARG(1)) {
temp_dead(s, args[1]);
}
temp_dead(s, args[0]);
} else if (ts->val_type == TEMP_VAL_CONST) {
/* propagate constant */
if (ots->val_type == TEMP_VAL_REG) {
s->reg_to_temp[ots->reg] = -1;
}
ots->val_type = TEMP_VAL_CONST;
ots->val = ts->val;
if (IS_DEAD_ARG(1)) {
temp_dead(s, args[1]);
}
} else {
/* The code in the first if block should have moved the
temp to a register. */
assert(ts->val_type == TEMP_VAL_REG);
if (IS_DEAD_ARG(1) && !ts->fixed_reg && !ots->fixed_reg) {
/* the mov can be suppressed */
if (ots->val_type == TEMP_VAL_REG) {
s->reg_to_temp[ots->reg] = -1;
}
ots->reg = ts->reg;
temp_dead(s, args[1]);
} else {
if (ots->val_type != TEMP_VAL_REG) {
/* When allocating a new register, make sure to not spill the
input one. */
tcg_regset_set_reg(allocated_regs, ts->reg);
ots->reg = tcg_reg_alloc(s, tcg_target_available_regs[otype],
allocated_regs);
}
tcg_out_mov(s, otype, ots->reg, ts->reg);
}
ots->val_type = TEMP_VAL_REG;
ots->mem_coherent = 0;
s->reg_to_temp[ots->reg] = args[0];
if (NEED_SYNC_ARG(0)) {
tcg_reg_sync(s, ots->reg);
}
}
}
static void tcg_reg_alloc_op(TCGContext *s,
const TCGOpDef *def, TCGOpcode opc,
const TCGArg *args, uint16_t dead_args,
uint8_t sync_args)
{
TCGRegSet allocated_regs;
int i, k, nb_iargs, nb_oargs;
TCGReg reg;
TCGArg arg;
const TCGArgConstraint *arg_ct;
TCGTemp *ts;
TCGArg new_args[TCG_MAX_OP_ARGS];
int const_args[TCG_MAX_OP_ARGS];
nb_oargs = def->nb_oargs;
nb_iargs = def->nb_iargs;
/* copy constants */
memcpy(new_args + nb_oargs + nb_iargs,
args + nb_oargs + nb_iargs,
sizeof(TCGArg) * def->nb_cargs);
/* satisfy input constraints */
tcg_regset_set(allocated_regs, s->reserved_regs);
for(k = 0; k < nb_iargs; k++) {
i = def->sorted_args[nb_oargs + k];
arg = args[i];
arg_ct = &def->args_ct[i];
ts = &s->temps[arg];
if (ts->val_type == TEMP_VAL_MEM) {
reg = tcg_reg_alloc(s, arg_ct->u.regs, allocated_regs);
tcg_out_ld(s, ts->type, reg, ts->mem_base->reg, ts->mem_offset);
ts->val_type = TEMP_VAL_REG;
ts->reg = reg;
ts->mem_coherent = 1;
s->reg_to_temp[reg] = arg;
} else if (ts->val_type == TEMP_VAL_CONST) {
if (tcg_target_const_match(ts->val, ts->type, arg_ct)) {
/* constant is OK for instruction */
const_args[i] = 1;
new_args[i] = ts->val;
goto iarg_end;
} else {
/* need to move to a register */
reg = tcg_reg_alloc(s, arg_ct->u.regs, allocated_regs);
tcg_out_movi(s, ts->type, reg, ts->val);
ts->val_type = TEMP_VAL_REG;
ts->reg = reg;
ts->mem_coherent = 0;
s->reg_to_temp[reg] = arg;
}
}
assert(ts->val_type == TEMP_VAL_REG);
if (arg_ct->ct & TCG_CT_IALIAS) {
if (ts->fixed_reg) {
/* if fixed register, we must allocate a new register
if the alias is not the same register */
if (arg != args[arg_ct->alias_index])
goto allocate_in_reg;
} else {
/* if the input is aliased to an output and if it is
not dead after the instruction, we must allocate
a new register and move it */
if (!IS_DEAD_ARG(i)) {
goto allocate_in_reg;
}
/* check if the current register has already been allocated
for another input aliased to an output */
int k2, i2;
for (k2 = 0 ; k2 < k ; k2++) {
i2 = def->sorted_args[nb_oargs + k2];
if ((def->args_ct[i2].ct & TCG_CT_IALIAS) &&
(new_args[i2] == ts->reg)) {
goto allocate_in_reg;
}
}
}
}
reg = ts->reg;
if (tcg_regset_test_reg(arg_ct->u.regs, reg)) {
/* nothing to do : the constraint is satisfied */
} else {
allocate_in_reg:
/* allocate a new register matching the constraint
and move the temporary register into it */
reg = tcg_reg_alloc(s, arg_ct->u.regs, allocated_regs);
tcg_out_mov(s, ts->type, reg, ts->reg);
}
new_args[i] = reg;
const_args[i] = 0;
tcg_regset_set_reg(allocated_regs, reg);
iarg_end: ;
}
/* mark dead temporaries and free the associated registers */
for (i = nb_oargs; i < nb_oargs + nb_iargs; i++) {
if (IS_DEAD_ARG(i)) {
temp_dead(s, args[i]);
}
}
if (def->flags & TCG_OPF_BB_END) {
tcg_reg_alloc_bb_end(s, allocated_regs);
} else {
if (def->flags & TCG_OPF_CALL_CLOBBER) {
/* XXX: permit generic clobber register list ? */
for (i = 0; i < TCG_TARGET_NB_REGS; i++) {
if (tcg_regset_test_reg(tcg_target_call_clobber_regs, i)) {
tcg_reg_free(s, i);
}
}
}
if (def->flags & TCG_OPF_SIDE_EFFECTS) {
/* sync globals if the op has side effects and might trigger
an exception. */
sync_globals(s, allocated_regs);
}
/* satisfy the output constraints */
tcg_regset_set(allocated_regs, s->reserved_regs);
for(k = 0; k < nb_oargs; k++) {
i = def->sorted_args[k];
arg = args[i];
arg_ct = &def->args_ct[i];
ts = &s->temps[arg];
if (arg_ct->ct & TCG_CT_ALIAS) {
reg = new_args[arg_ct->alias_index];
} else {
/* if fixed register, we try to use it */
reg = ts->reg;
if (ts->fixed_reg &&
tcg_regset_test_reg(arg_ct->u.regs, reg)) {
goto oarg_end;
}
reg = tcg_reg_alloc(s, arg_ct->u.regs, allocated_regs);
}
tcg_regset_set_reg(allocated_regs, reg);
/* if a fixed register is used, then a move will be done afterwards */
if (!ts->fixed_reg) {
if (ts->val_type == TEMP_VAL_REG) {
s->reg_to_temp[ts->reg] = -1;
}
ts->val_type = TEMP_VAL_REG;
ts->reg = reg;
/* temp value is modified, so the value kept in memory is
potentially not the same */
ts->mem_coherent = 0;
s->reg_to_temp[reg] = arg;
}
oarg_end:
new_args[i] = reg;
}
}
/* emit instruction */
tcg_out_op(s, opc, new_args, const_args);
/* move the outputs in the correct register if needed */
for(i = 0; i < nb_oargs; i++) {
ts = &s->temps[args[i]];
reg = new_args[i];
if (ts->fixed_reg && ts->reg != reg) {
tcg_out_mov(s, ts->type, ts->reg, reg);
}
if (NEED_SYNC_ARG(i)) {
tcg_reg_sync(s, reg);
}
if (IS_DEAD_ARG(i)) {
temp_dead(s, args[i]);
}
}
}
#ifdef TCG_TARGET_STACK_GROWSUP
#define STACK_DIR(x) (-(x))
#else
#define STACK_DIR(x) (x)
#endif
static void tcg_reg_alloc_call(TCGContext *s, int nb_oargs, int nb_iargs,
const TCGArg * const args, uint16_t dead_args,
uint8_t sync_args)
{
int flags, nb_regs, i;
TCGReg reg;
TCGArg arg;
TCGTemp *ts;
intptr_t stack_offset;
size_t call_stack_size;
tcg_insn_unit *func_addr;
int allocate_args;
TCGRegSet allocated_regs;
func_addr = (tcg_insn_unit *)(intptr_t)args[nb_oargs + nb_iargs];
flags = args[nb_oargs + nb_iargs + 1];
nb_regs = ARRAY_SIZE(tcg_target_call_iarg_regs);
if (nb_regs > nb_iargs) {
nb_regs = nb_iargs;
}
/* assign stack slots first */
call_stack_size = (nb_iargs - nb_regs) * sizeof(tcg_target_long);
call_stack_size = (call_stack_size + TCG_TARGET_STACK_ALIGN - 1) &
~(TCG_TARGET_STACK_ALIGN - 1);
allocate_args = (call_stack_size > TCG_STATIC_CALL_ARGS_SIZE);
if (allocate_args) {
/* XXX: if more than TCG_STATIC_CALL_ARGS_SIZE is needed,
preallocate call stack */
tcg_abort();
}
stack_offset = TCG_TARGET_CALL_STACK_OFFSET;
for(i = nb_regs; i < nb_iargs; i++) {
arg = args[nb_oargs + i];
#ifdef TCG_TARGET_STACK_GROWSUP
stack_offset -= sizeof(tcg_target_long);
#endif
if (arg != TCG_CALL_DUMMY_ARG) {
ts = &s->temps[arg];
if (ts->val_type == TEMP_VAL_REG) {
tcg_out_st(s, ts->type, ts->reg, TCG_REG_CALL_STACK, stack_offset);
} else if (ts->val_type == TEMP_VAL_MEM) {
reg = tcg_reg_alloc(s, tcg_target_available_regs[ts->type],
s->reserved_regs);
/* XXX: not correct if reading values from the stack */
tcg_out_ld(s, ts->type, reg, ts->mem_base->reg, ts->mem_offset);
tcg_out_st(s, ts->type, reg, TCG_REG_CALL_STACK, stack_offset);
} else if (ts->val_type == TEMP_VAL_CONST) {
reg = tcg_reg_alloc(s, tcg_target_available_regs[ts->type],
s->reserved_regs);
/* XXX: sign extend may be needed on some targets */
tcg_out_movi(s, ts->type, reg, ts->val);
tcg_out_st(s, ts->type, reg, TCG_REG_CALL_STACK, stack_offset);
} else {
tcg_abort();
}
}
#ifndef TCG_TARGET_STACK_GROWSUP
stack_offset += sizeof(tcg_target_long);
#endif
}
/* assign input registers */
tcg_regset_set(allocated_regs, s->reserved_regs);
for(i = 0; i < nb_regs; i++) {
arg = args[nb_oargs + i];
if (arg != TCG_CALL_DUMMY_ARG) {
ts = &s->temps[arg];
reg = tcg_target_call_iarg_regs[i];
tcg_reg_free(s, reg);
if (ts->val_type == TEMP_VAL_REG) {
if (ts->reg != reg) {
tcg_out_mov(s, ts->type, reg, ts->reg);
}
} else if (ts->val_type == TEMP_VAL_MEM) {
tcg_out_ld(s, ts->type, reg, ts->mem_base->reg, ts->mem_offset);
} else if (ts->val_type == TEMP_VAL_CONST) {
/* XXX: sign extend ? */
tcg_out_movi(s, ts->type, reg, ts->val);
} else {
tcg_abort();
}
tcg_regset_set_reg(allocated_regs, reg);
}
}
/* mark dead temporaries and free the associated registers */
for(i = nb_oargs; i < nb_iargs + nb_oargs; i++) {
if (IS_DEAD_ARG(i)) {
temp_dead(s, args[i]);
}
}
/* clobber call registers */
for (i = 0; i < TCG_TARGET_NB_REGS; i++) {
if (tcg_regset_test_reg(tcg_target_call_clobber_regs, i)) {
tcg_reg_free(s, i);
}
}
/* Save globals if they might be written by the helper, sync them if
they might be read. */
if (flags & TCG_CALL_NO_READ_GLOBALS) {
/* Nothing to do */
} else if (flags & TCG_CALL_NO_WRITE_GLOBALS) {
sync_globals(s, allocated_regs);
} else {
save_globals(s, allocated_regs);
}
tcg_out_call(s, func_addr);
/* assign output registers and emit moves if needed */
for(i = 0; i < nb_oargs; i++) {
arg = args[i];
ts = &s->temps[arg];
reg = tcg_target_call_oarg_regs[i];
assert(s->reg_to_temp[reg] == -1);
if (ts->fixed_reg) {
if (ts->reg != reg) {
tcg_out_mov(s, ts->type, ts->reg, reg);
}
} else {
if (ts->val_type == TEMP_VAL_REG) {
s->reg_to_temp[ts->reg] = -1;
}
ts->val_type = TEMP_VAL_REG;
ts->reg = reg;
ts->mem_coherent = 0;
s->reg_to_temp[reg] = arg;
if (NEED_SYNC_ARG(i)) {
tcg_reg_sync(s, reg);
}
if (IS_DEAD_ARG(i)) {
temp_dead(s, args[i]);
}
}
}
}
#ifdef CONFIG_PROFILER
static int64_t tcg_table_op_count[NB_OPS];
void tcg_dump_op_count(FILE *f, fprintf_function cpu_fprintf)
{
int i;
for (i = 0; i < NB_OPS; i++) {
cpu_fprintf(f, "%s %" PRId64 "\n", tcg_op_defs[i].name,
tcg_table_op_count[i]);
}
}
#else
void tcg_dump_op_count(FILE *f, fprintf_function cpu_fprintf)
{
cpu_fprintf(f, "[TCG profiler not compiled]\n");
}
#endif
int tcg_gen_code(TCGContext *s, tcg_insn_unit *gen_code_buf)
{
int i, oi, oi_next, num_insns;
#ifdef CONFIG_PROFILER
{
int n;
n = s->gen_last_op_idx + 1;
s->op_count += n;
if (n > s->op_count_max) {
s->op_count_max = n;
}
n = s->nb_temps;
s->temp_count += n;
if (n > s->temp_count_max) {
s->temp_count_max = n;
}
}
#endif
#ifdef DEBUG_DISAS
if (unlikely(qemu_loglevel_mask(CPU_LOG_TB_OP))) {
qemu_log("OP:\n");
tcg_dump_ops(s);
qemu_log("\n");
}
#endif
#ifdef CONFIG_PROFILER
s->opt_time -= profile_getclock();
#endif
#ifdef USE_TCG_OPTIMIZATIONS
tcg_optimize(s);
#endif
#ifdef CONFIG_PROFILER
s->opt_time += profile_getclock();
s->la_time -= profile_getclock();
#endif
tcg_liveness_analysis(s);
#ifdef CONFIG_PROFILER
s->la_time += profile_getclock();
#endif
#ifdef DEBUG_DISAS
if (unlikely(qemu_loglevel_mask(CPU_LOG_TB_OP_OPT))) {
qemu_log("OP after optimization and liveness analysis:\n");
tcg_dump_ops(s);
qemu_log("\n");
}
#endif
tcg_reg_alloc_start(s);
s->code_buf = gen_code_buf;
s->code_ptr = gen_code_buf;
tcg_out_tb_init(s);
num_insns = -1;
for (oi = s->gen_first_op_idx; oi >= 0; oi = oi_next) {
TCGOp * const op = &s->gen_op_buf[oi];
TCGArg * const args = &s->gen_opparam_buf[op->args];
TCGOpcode opc = op->opc;
const TCGOpDef *def = &tcg_op_defs[opc];
uint16_t dead_args = s->op_dead_args[oi];
uint8_t sync_args = s->op_sync_args[oi];
oi_next = op->next;
#ifdef CONFIG_PROFILER
tcg_table_op_count[opc]++;
#endif
switch (opc) {
case INDEX_op_mov_i32:
case INDEX_op_mov_i64:
tcg_reg_alloc_mov(s, def, args, dead_args, sync_args);
break;
case INDEX_op_movi_i32:
case INDEX_op_movi_i64:
tcg_reg_alloc_movi(s, args, dead_args, sync_args);
break;
case INDEX_op_insn_start:
if (num_insns >= 0) {
s->gen_insn_end_off[num_insns] = tcg_current_code_size(s);
}
num_insns++;
for (i = 0; i < TARGET_INSN_START_WORDS; ++i) {
target_ulong a;
#if TARGET_LONG_BITS > TCG_TARGET_REG_BITS
a = ((target_ulong)args[i * 2 + 1] << 32) | args[i * 2];
#else
a = args[i];
#endif
s->gen_insn_data[num_insns][i] = a;
}
break;
case INDEX_op_discard:
temp_dead(s, args[0]);
break;
case INDEX_op_set_label:
tcg_reg_alloc_bb_end(s, s->reserved_regs);
tcg_out_label(s, arg_label(args[0]), s->code_ptr);
break;
case INDEX_op_call:
tcg_reg_alloc_call(s, op->callo, op->calli, args,
dead_args, sync_args);
break;
default:
/* Sanity check that we've not introduced any unhandled opcodes. */
if (def->flags & TCG_OPF_NOT_PRESENT) {
tcg_abort();
}
/* Note: in order to speed up the code, it would be much
faster to have specialized register allocator functions for
some common argument patterns */
tcg_reg_alloc_op(s, def, opc, args, dead_args, sync_args);
break;
}
#ifndef NDEBUG
check_regs(s);
#endif
/* Test for (pending) buffer overflow. The assumption is that any
one operation beginning below the high water mark cannot overrun
the buffer completely. Thus we can test for overflow after
generating code without having to check during generation. */
if (unlikely((void *)s->code_ptr > s->code_gen_highwater)) {
return -1;
}
}
tcg_debug_assert(num_insns >= 0);
s->gen_insn_end_off[num_insns] = tcg_current_code_size(s);
/* Generate TB finalization at the end of block */
if (!tcg_out_tb_finalize(s)) {
return -1;
}
/* flush instruction cache */
flush_icache_range((uintptr_t)s->code_buf, (uintptr_t)s->code_ptr);
return tcg_current_code_size(s);
}
#ifdef CONFIG_PROFILER
void tcg_dump_info(FILE *f, fprintf_function cpu_fprintf)
{
TCGContext *s = &tcg_ctx;
int64_t tb_count = s->tb_count;
int64_t tb_div_count = tb_count ? tb_count : 1;
int64_t tot = s->interm_time + s->code_time;
cpu_fprintf(f, "JIT cycles %" PRId64 " (%0.3f s at 2.4 GHz)\n",
tot, tot / 2.4e9);
cpu_fprintf(f, "translated TBs %" PRId64 " (aborted=%" PRId64 " %0.1f%%)\n",
tb_count, s->tb_count1 - tb_count,
(double)(s->tb_count1 - s->tb_count)
/ (s->tb_count1 ? s->tb_count1 : 1) * 100.0);
cpu_fprintf(f, "avg ops/TB %0.1f max=%d\n",
(double)s->op_count / tb_div_count, s->op_count_max);
cpu_fprintf(f, "deleted ops/TB %0.2f\n",
(double)s->del_op_count / tb_div_count);
cpu_fprintf(f, "avg temps/TB %0.2f max=%d\n",
(double)s->temp_count / tb_div_count, s->temp_count_max);
cpu_fprintf(f, "avg host code/TB %0.1f\n",
(double)s->code_out_len / tb_div_count);
cpu_fprintf(f, "avg search data/TB %0.1f\n",
(double)s->search_out_len / tb_div_count);
cpu_fprintf(f, "cycles/op %0.1f\n",
s->op_count ? (double)tot / s->op_count : 0);
cpu_fprintf(f, "cycles/in byte %0.1f\n",
s->code_in_len ? (double)tot / s->code_in_len : 0);
cpu_fprintf(f, "cycles/out byte %0.1f\n",
s->code_out_len ? (double)tot / s->code_out_len : 0);
cpu_fprintf(f, "cycles/search byte %0.1f\n",
s->search_out_len ? (double)tot / s->search_out_len : 0);
if (tot == 0) {
tot = 1;
}
cpu_fprintf(f, " gen_interm time %0.1f%%\n",
(double)s->interm_time / tot * 100.0);
cpu_fprintf(f, " gen_code time %0.1f%%\n",
(double)s->code_time / tot * 100.0);
cpu_fprintf(f, "optim./code time %0.1f%%\n",
(double)s->opt_time / (s->code_time ? s->code_time : 1)
* 100.0);
cpu_fprintf(f, "liveness/code time %0.1f%%\n",
(double)s->la_time / (s->code_time ? s->code_time : 1) * 100.0);
cpu_fprintf(f, "cpu_restore count %" PRId64 "\n",
s->restore_count);
cpu_fprintf(f, " avg cycles %0.1f\n",
s->restore_count ? (double)s->restore_time / s->restore_count : 0);
}
#else
void tcg_dump_info(FILE *f, fprintf_function cpu_fprintf)
{
cpu_fprintf(f, "[TCG profiler not compiled]\n");
}
#endif
#ifdef ELF_HOST_MACHINE
/* In order to use this feature, the backend needs to do three things:
(1) Define ELF_HOST_MACHINE to indicate both what value to
put into the ELF image and to indicate support for the feature.
(2) Define tcg_register_jit. This should create a buffer containing
the contents of a .debug_frame section that describes the post-
prologue unwind info for the tcg machine.
(3) Call tcg_register_jit_int, with the constructed .debug_frame.
*/
/* Begin GDB interface. THE FOLLOWING MUST MATCH GDB DOCS. */
typedef enum {
JIT_NOACTION = 0,
JIT_REGISTER_FN,
JIT_UNREGISTER_FN
} jit_actions_t;
struct jit_code_entry {
struct jit_code_entry *next_entry;
struct jit_code_entry *prev_entry;
const void *symfile_addr;
uint64_t symfile_size;
};
struct jit_descriptor {
uint32_t version;
uint32_t action_flag;
struct jit_code_entry *relevant_entry;
struct jit_code_entry *first_entry;
};
void __jit_debug_register_code(void) __attribute__((noinline));
void __jit_debug_register_code(void)
{
asm("");
}
/* Must statically initialize the version, because GDB may check
the version before we can set it. */
struct jit_descriptor __jit_debug_descriptor = { 1, 0, 0, 0 };
/* End GDB interface. */
static int find_string(const char *strtab, const char *str)
{
const char *p = strtab + 1;
while (1) {
if (strcmp(p, str) == 0) {
return p - strtab;
}
p += strlen(p) + 1;
}
}
static void tcg_register_jit_int(void *buf_ptr, size_t buf_size,
const void *debug_frame,
size_t debug_frame_size)
{
struct __attribute__((packed)) DebugInfo {
uint32_t len;
uint16_t version;
uint32_t abbrev;
uint8_t ptr_size;
uint8_t cu_die;
uint16_t cu_lang;
uintptr_t cu_low_pc;
uintptr_t cu_high_pc;
uint8_t fn_die;
char fn_name[16];
uintptr_t fn_low_pc;
uintptr_t fn_high_pc;
uint8_t cu_eoc;
};
struct ElfImage {
ElfW(Ehdr) ehdr;
ElfW(Phdr) phdr;
ElfW(Shdr) shdr[7];
ElfW(Sym) sym[2];
struct DebugInfo di;
uint8_t da[24];
char str[80];
};
struct ElfImage *img;
static const struct ElfImage img_template = {
.ehdr = {
.e_ident[EI_MAG0] = ELFMAG0,
.e_ident[EI_MAG1] = ELFMAG1,
.e_ident[EI_MAG2] = ELFMAG2,
.e_ident[EI_MAG3] = ELFMAG3,
.e_ident[EI_CLASS] = ELF_CLASS,
.e_ident[EI_DATA] = ELF_DATA,
.e_ident[EI_VERSION] = EV_CURRENT,
.e_type = ET_EXEC,
.e_machine = ELF_HOST_MACHINE,
.e_version = EV_CURRENT,
.e_phoff = offsetof(struct ElfImage, phdr),
.e_shoff = offsetof(struct ElfImage, shdr),
.e_ehsize = sizeof(ElfW(Shdr)),
.e_phentsize = sizeof(ElfW(Phdr)),
.e_phnum = 1,
.e_shentsize = sizeof(ElfW(Shdr)),
.e_shnum = ARRAY_SIZE(img->shdr),
.e_shstrndx = ARRAY_SIZE(img->shdr) - 1,
#ifdef ELF_HOST_FLAGS
.e_flags = ELF_HOST_FLAGS,
#endif
#ifdef ELF_OSABI
.e_ident[EI_OSABI] = ELF_OSABI,
#endif
},
.phdr = {
.p_type = PT_LOAD,
.p_flags = PF_X,
},
.shdr = {
[0] = { .sh_type = SHT_NULL },
/* Trick: The contents of code_gen_buffer are not present in
this fake ELF file; that got allocated elsewhere. Therefore
we mark .text as SHT_NOBITS (similar to .bss) so that readers
will not look for contents. We can record any address. */
[1] = { /* .text */
.sh_type = SHT_NOBITS,
.sh_flags = SHF_EXECINSTR | SHF_ALLOC,
},
[2] = { /* .debug_info */
.sh_type = SHT_PROGBITS,
.sh_offset = offsetof(struct ElfImage, di),
.sh_size = sizeof(struct DebugInfo),
},
[3] = { /* .debug_abbrev */
.sh_type = SHT_PROGBITS,
.sh_offset = offsetof(struct ElfImage, da),
.sh_size = sizeof(img->da),
},
[4] = { /* .debug_frame */
.sh_type = SHT_PROGBITS,
.sh_offset = sizeof(struct ElfImage),
},
[5] = { /* .symtab */
.sh_type = SHT_SYMTAB,
.sh_offset = offsetof(struct ElfImage, sym),
.sh_size = sizeof(img->sym),
.sh_info = 1,
.sh_link = ARRAY_SIZE(img->shdr) - 1,
.sh_entsize = sizeof(ElfW(Sym)),
},
[6] = { /* .strtab */
.sh_type = SHT_STRTAB,
.sh_offset = offsetof(struct ElfImage, str),
.sh_size = sizeof(img->str),
}
},
.sym = {
[1] = { /* code_gen_buffer */
.st_info = ELF_ST_INFO(STB_GLOBAL, STT_FUNC),
.st_shndx = 1,
}
},
.di = {
.len = sizeof(struct DebugInfo) - 4,
.version = 2,
.ptr_size = sizeof(void *),
.cu_die = 1,
.cu_lang = 0x8001, /* DW_LANG_Mips_Assembler */
.fn_die = 2,
.fn_name = "code_gen_buffer"
},
.da = {
1, /* abbrev number (the cu) */
0x11, 1, /* DW_TAG_compile_unit, has children */
0x13, 0x5, /* DW_AT_language, DW_FORM_data2 */
0x11, 0x1, /* DW_AT_low_pc, DW_FORM_addr */
0x12, 0x1, /* DW_AT_high_pc, DW_FORM_addr */
0, 0, /* end of abbrev */
2, /* abbrev number (the fn) */
0x2e, 0, /* DW_TAG_subprogram, no children */
0x3, 0x8, /* DW_AT_name, DW_FORM_string */
0x11, 0x1, /* DW_AT_low_pc, DW_FORM_addr */
0x12, 0x1, /* DW_AT_high_pc, DW_FORM_addr */
0, 0, /* end of abbrev */
0 /* no more abbrev */
},
.str = "\0" ".text\0" ".debug_info\0" ".debug_abbrev\0"
".debug_frame\0" ".symtab\0" ".strtab\0" "code_gen_buffer",
};
/* We only need a single jit entry; statically allocate it. */
static struct jit_code_entry one_entry;
uintptr_t buf = (uintptr_t)buf_ptr;
size_t img_size = sizeof(struct ElfImage) + debug_frame_size;
DebugFrameHeader *dfh;
img = g_malloc(img_size);
*img = img_template;
img->phdr.p_vaddr = buf;
img->phdr.p_paddr = buf;
img->phdr.p_memsz = buf_size;
img->shdr[1].sh_name = find_string(img->str, ".text");
img->shdr[1].sh_addr = buf;
img->shdr[1].sh_size = buf_size;
img->shdr[2].sh_name = find_string(img->str, ".debug_info");
img->shdr[3].sh_name = find_string(img->str, ".debug_abbrev");
img->shdr[4].sh_name = find_string(img->str, ".debug_frame");
img->shdr[4].sh_size = debug_frame_size;
img->shdr[5].sh_name = find_string(img->str, ".symtab");
img->shdr[6].sh_name = find_string(img->str, ".strtab");
img->sym[1].st_name = find_string(img->str, "code_gen_buffer");
img->sym[1].st_value = buf;
img->sym[1].st_size = buf_size;
img->di.cu_low_pc = buf;
img->di.cu_high_pc = buf + buf_size;
img->di.fn_low_pc = buf;
img->di.fn_high_pc = buf + buf_size;
dfh = (DebugFrameHeader *)(img + 1);
memcpy(dfh, debug_frame, debug_frame_size);
dfh->fde.func_start = buf;
dfh->fde.func_len = buf_size;
#ifdef DEBUG_JIT
/* Enable this block to be able to debug the ELF image file creation.
One can use readelf, objdump, or other inspection utilities. */
{
FILE *f = fopen("/tmp/qemu.jit", "w+b");
if (f) {
if (fwrite(img, img_size, 1, f) != img_size) {
/* Avoid stupid unused return value warning for fwrite. */
}
fclose(f);
}
}
#endif
one_entry.symfile_addr = img;
one_entry.symfile_size = img_size;
__jit_debug_descriptor.action_flag = JIT_REGISTER_FN;
__jit_debug_descriptor.relevant_entry = &one_entry;
__jit_debug_descriptor.first_entry = &one_entry;
__jit_debug_register_code();
}
#else
/* No support for the feature. Provide the entry point expected by exec.c,
and implement the internal function we declared earlier. */
static void tcg_register_jit_int(void *buf, size_t size,
const void *debug_frame,
size_t debug_frame_size)
{
}
void tcg_register_jit(void *buf, size_t buf_size)
{
}
#endif /* ELF_HOST_MACHINE */