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wasm-micro-runtime/core/iwasm/interpreter/wasm_interp_fast.c

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/*
* Copyright (C) 2019 Intel Corporation. All rights reserved.
* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
*/
#include "wasm_interp.h"
#include "bh_log.h"
#include "wasm_runtime.h"
#include "wasm_opcode.h"
#include "wasm_loader.h"
#include "../common/wasm_exec_env.h"
#if WASM_ENABLE_SHARED_MEMORY != 0
#include "../common/wasm_shared_memory.h"
#endif
typedef int32 CellType_I32;
typedef int64 CellType_I64;
typedef float32 CellType_F32;
typedef float64 CellType_F64;
#define BR_TABLE_TMP_BUF_LEN 32
/* 64-bit Memory accessors. */
#if WASM_CPU_SUPPORTS_UNALIGNED_64BIT_ACCESS != 0
#define PUT_I64_TO_ADDR(addr, value) do { \
*(int64*)(addr) = (int64)(value); \
} while (0)
#define PUT_F64_TO_ADDR(addr, value) do { \
*(float64*)(addr) = (float64)(value); \
} while (0)
#define GET_I64_FROM_ADDR(addr) (*(int64*)(addr))
#define GET_F64_FROM_ADDR(addr) (*(float64*)(addr))
/* For STORE opcodes */
#define STORE_I64 PUT_I64_TO_ADDR
#define STORE_U32(addr, value) do { \
*(uint32*)(addr) = (uint32)(value); \
} while (0)
#define STORE_U16(addr, value) do { \
*(uint16*)(addr) = (uint16)(value); \
} while (0)
/* For LOAD opcodes */
#define LOAD_I64(addr) (*(int64*)(addr))
#define LOAD_F64(addr) (*(float64*)(addr))
#define LOAD_F32(addr) (*(float32*)(addr))
#define LOAD_I32(addr) (*(int32*)(addr))
#define LOAD_U32(addr) (*(uint32*)(addr))
#define LOAD_I16(addr) (*(int16*)(addr))
#define LOAD_U16(addr) (*(uint16*)(addr))
#else /* WASM_CPU_SUPPORTS_UNALIGNED_64BIT_ACCESS != 0 */
#define PUT_I64_TO_ADDR(addr, value) do { \
union { int64 val; uint32 parts[2]; } u; \
u.val = (int64)(value); \
(addr)[0] = u.parts[0]; \
(addr)[1] = u.parts[1]; \
} while (0)
#define PUT_F64_TO_ADDR(addr, value) do { \
union { float64 val; uint32 parts[2]; } u; \
u.val = (value); \
(addr)[0] = u.parts[0]; \
(addr)[1] = u.parts[1]; \
} while (0)
static inline int64
GET_I64_FROM_ADDR(uint32 *addr)
{
union { int64 val; uint32 parts[2]; } u;
u.parts[0] = addr[0];
u.parts[1] = addr[1];
return u.val;
}
static inline float64
GET_F64_FROM_ADDR (uint32 *addr)
{
union { float64 val; uint32 parts[2]; } u;
u.parts[0] = addr[0];
u.parts[1] = addr[1];
return u.val;
}
/* For STORE opcodes */
#define STORE_I64(addr, value) do { \
uintptr_t addr1 = (uintptr_t)(addr); \
union { int64 val; uint32 u32[2]; \
uint16 u16[4]; uint8 u8[8]; } u; \
if ((addr1 & (uintptr_t)7) == 0) \
*(int64*)(addr) = (int64)(value); \
else { \
u.val = (int64)(value); \
if ((addr1 & (uintptr_t)3) == 0) { \
((uint32*)(addr))[0] = u.u32[0]; \
((uint32*)(addr))[1] = u.u32[1]; \
} \
else if ((addr1 & (uintptr_t)1) == 0) { \
((uint16*)(addr))[0] = u.u16[0]; \
((uint16*)(addr))[1] = u.u16[1]; \
((uint16*)(addr))[2] = u.u16[2]; \
((uint16*)(addr))[3] = u.u16[3]; \
} \
else { \
int32 t; \
for (t = 0; t < 8; t++) \
((uint8*)(addr))[t] = u.u8[t]; \
} \
} \
} while (0)
#define STORE_U32(addr, value) do { \
uintptr_t addr1 = (uintptr_t)(addr); \
union { uint32 val; \
uint16 u16[2]; uint8 u8[4]; } u; \
if ((addr1 & (uintptr_t)3) == 0) \
*(uint32*)(addr) = (uint32)(value); \
else { \
u.val = (uint32)(value); \
if ((addr1 & (uintptr_t)1) == 0) { \
((uint16*)(addr))[0] = u.u16[0]; \
((uint16*)(addr))[1] = u.u16[1]; \
} \
else { \
((uint8*)(addr))[0] = u.u8[0]; \
((uint8*)(addr))[1] = u.u8[1]; \
((uint8*)(addr))[2] = u.u8[2]; \
((uint8*)(addr))[3] = u.u8[3]; \
} \
} \
} while (0)
#define STORE_U16(addr, value) do { \
union { uint16 val; uint8 u8[2]; } u; \
u.val = (uint16)(value); \
((uint8*)(addr))[0] = u.u8[0]; \
((uint8*)(addr))[1] = u.u8[1]; \
} while (0)
/* For LOAD opcodes */
static inline int64
LOAD_I64(void *addr)
{
uintptr_t addr1 = (uintptr_t)addr;
union { int64 val; uint32 u32[2];
uint16 u16[4]; uint8 u8[8]; } u;
if ((addr1 & (uintptr_t)7) == 0)
return *(int64*)addr;
if ((addr1 & (uintptr_t)3) == 0) {
u.u32[0] = ((uint32*)addr)[0];
u.u32[1] = ((uint32*)addr)[1];
}
else if ((addr1 & (uintptr_t)1) == 0) {
u.u16[0] = ((uint16*)addr)[0];
u.u16[1] = ((uint16*)addr)[1];
u.u16[2] = ((uint16*)addr)[2];
u.u16[3] = ((uint16*)addr)[3];
}
else {
int32 t;
for (t = 0; t < 8; t++)
u.u8[t] = ((uint8*)addr)[t];
}
return u.val;
}
static inline float64
LOAD_F64(void *addr)
{
uintptr_t addr1 = (uintptr_t)addr;
union { float64 val; uint32 u32[2];
uint16 u16[4]; uint8 u8[8]; } u;
if ((addr1 & (uintptr_t)7) == 0)
return *(float64*)addr;
if ((addr1 & (uintptr_t)3) == 0) {
u.u32[0] = ((uint32*)addr)[0];
u.u32[1] = ((uint32*)addr)[1];
}
else if ((addr1 & (uintptr_t)1) == 0) {
u.u16[0] = ((uint16*)addr)[0];
u.u16[1] = ((uint16*)addr)[1];
u.u16[2] = ((uint16*)addr)[2];
u.u16[3] = ((uint16*)addr)[3];
}
else {
int32 t;
for (t = 0; t < 8; t++)
u.u8[t] = ((uint8*)addr)[t];
}
return u.val;
}
static inline int32
LOAD_I32(void *addr)
{
uintptr_t addr1 = (uintptr_t)addr;
union { int32 val; uint16 u16[2]; uint8 u8[4]; } u;
if ((addr1 & (uintptr_t)3) == 0)
return *(int32*)addr;
if ((addr1 & (uintptr_t)1) == 0) {
u.u16[0] = ((uint16*)addr)[0];
u.u16[1] = ((uint16*)addr)[1];
}
else {
u.u8[0] = ((uint8*)addr)[0];
u.u8[1] = ((uint8*)addr)[1];
u.u8[2] = ((uint8*)addr)[2];
u.u8[3] = ((uint8*)addr)[3];
}
return u.val;
}
static inline int16
LOAD_I16(void *addr)
{
union { int16 val; uint8 u8[2]; } u;
u.u8[0] = ((uint8*)addr)[0];
u.u8[1] = ((uint8*)addr)[1];
return u.val;
}
#define LOAD_U32(addr) ((uint32)LOAD_I32(addr))
#define LOAD_U16(addr) ((uint16)LOAD_I16(addr))
#define LOAD_F32(addr) ((float32)LOAD_I32(addr))
#endif /* WASM_CPU_SUPPORTS_UNALIGNED_64BIT_ACCESS != 0 */
#define CHECK_MEMORY_OVERFLOW(bytes) do { \
uint64 offset1 = (uint64)offset + (uint64)addr; \
if (offset1 + bytes <= (uint64)linear_mem_size) \
/* If offset1 is in valid range, maddr must also be in valid range,\
no need to check it again. */ \
maddr = memory->memory_data + offset1; \
else \
goto out_of_bounds; \
} while (0)
#define CHECK_BULK_MEMORY_OVERFLOW(start, bytes, maddr) do { \
uint64 offset1 = (uint32)(start); \
if (offset1 + bytes <= linear_mem_size) \
/* App heap space is not valid space for bulk memory operation */ \
maddr = memory->memory_data + offset1; \
else \
goto out_of_bounds; \
} while (0)
#define CHECK_ATOMIC_MEMORY_ACCESS(align) do { \
if (((uintptr_t)maddr & (align - 1)) != 0) \
goto unaligned_atomic; \
} while (0)
static inline uint32
rotl32(uint32 n, uint32 c)
{
const uint32 mask = (31);
c = c % 32;
c &= mask;
return (n<<c) | (n>>( (-c)&mask ));
}
static inline uint32
rotr32(uint32 n, uint32 c)
{
const uint32 mask = (31);
c = c % 32;
c &= mask;
return (n>>c) | (n<<( (-c)&mask ));
}
static inline uint64
rotl64(uint64 n, uint64 c)
{
const uint64 mask = (63);
c = c % 64;
c &= mask;
return (n<<c) | (n>>( (-c)&mask ));
}
static inline uint64
rotr64(uint64 n, uint64 c)
{
const uint64 mask = (63);
c = c % 64;
c &= mask;
return (n>>c) | (n<<( (-c)&mask ));
}
static inline double
wa_fmax(double a, double b)
{
double c = fmax(a, b);
if (c==0 && a==b)
return signbit(a) ? b : a;
return c;
}
static inline double
wa_fmin(double a, double b)
{
double c = fmin(a, b);
if (c==0 && a==b)
return signbit(a) ? a : b;
return c;
}
static inline uint32
clz32(uint32 type)
{
uint32 num = 0;
if (type == 0)
return 32;
while (!(type & 0x80000000)) {
num++;
type <<= 1;
}
return num;
}
static inline uint32
clz64(uint64 type)
{
uint32 num = 0;
if (type == 0)
return 64;
while (!(type & 0x8000000000000000LL)) {
num++;
type <<= 1;
}
return num;
}
static inline uint32
ctz32(uint32 type)
{
uint32 num = 0;
if (type == 0)
return 32;
while (!(type & 1)) {
num++;
type >>= 1;
}
return num;
}
static inline uint32
ctz64(uint64 type)
{
uint32 num = 0;
if (type == 0)
return 64;
while (!(type & 1)) {
num++;
type >>= 1;
}
return num;
}
static inline uint32
popcount32(uint32 u)
{
uint32 ret = 0;
while (u) {
u = (u & (u - 1));
ret++;
}
return ret;
}
static inline uint32
popcount64(uint64 u)
{
uint32 ret = 0;
while (u) {
u = (u & (u - 1));
ret++;
}
return ret;
}
static uint64
read_leb(const uint8 *buf, uint32 *p_offset, uint32 maxbits, bool sign)
{
uint64 result = 0;
uint32 shift = 0;
uint32 bcnt = 0;
uint64 byte;
while (true) {
byte = buf[*p_offset];
*p_offset += 1;
result |= ((byte & 0x7f) << shift);
shift += 7;
if ((byte & 0x80) == 0) {
break;
}
bcnt += 1;
}
if (sign && (shift < maxbits) && (byte & 0x40)) {
/* Sign extend */
result |= - ((uint64)1 << shift);
}
return result;
}
#define read_leb_uint32(p, p_end, res) do { \
uint8 _val = *p; \
if (!(_val & 0x80)) { \
res = _val; \
p++; \
break; \
} \
uint32 _off = 0; \
res = (uint32)read_leb(p, &_off, 32, false); \
p += _off; \
} while (0)
#define read_uint32(p) (p += sizeof(uint32), *(uint32 *)(p - sizeof(uint32)))
#define GET_LOCAL_INDEX_TYPE_AND_OFFSET() do { \
uint32 param_count = cur_func->param_count; \
read_leb_uint32(frame_ip, frame_ip_end, local_idx); \
bh_assert(local_idx < param_count + cur_func->local_count); \
local_offset = cur_func->local_offsets[local_idx]; \
if (local_idx < param_count) \
local_type = cur_func->param_types[local_idx]; \
else \
local_type = cur_func->local_types[local_idx - param_count]; \
} while (0)
#define GET_OFFSET() (frame_ip += 2, *(int16 *)(frame_ip - 2))
#define SET_OPERAND(type, off, value) \
(*(type*)(frame_lp + *(int16*)(frame_ip + off))) = value
#define GET_OPERAND(type, off) (*(type*)(frame_lp + *(int16*)(frame_ip + off)))
#define PUSH_I32(value) do { \
*(int32*)(frame_lp + GET_OFFSET()) = value; \
} while (0)
#define PUSH_F32(value) do { \
*(float32*)(frame_lp + GET_OFFSET()) = value; \
} while (0)
#define PUSH_I64(value) do { \
*(int64*)(frame_lp + GET_OFFSET()) = value; \
} while (0)
#define PUSH_F64(value) do { \
*(float64*)(frame_lp + GET_OFFSET()) = value; \
} while (0)
#define POP_I32() (*(int32*)(frame_lp + GET_OFFSET()))
#define POP_F32() (*(float32*)(frame_lp + GET_OFFSET()))
#define POP_I64() (*(int64*)(frame_lp + GET_OFFSET()))
#define POP_F64() (*(float64*)(frame_lp + GET_OFFSET()))
#define SYNC_ALL_TO_FRAME() do { \
frame->ip = frame_ip; \
} while (0)
#define UPDATE_ALL_FROM_FRAME() do { \
frame_ip = frame->ip; \
} while (0)
#define RECOVER_CONTEXT(new_frame) do { \
frame = (new_frame); \
cur_func = frame->function; \
prev_frame = frame->prev_frame; \
frame_ip = frame->ip; \
frame_lp = frame->lp; \
} while (0)
#if WASM_ENABLE_LABELS_AS_VALUES != 0
#define GET_OPCODE() opcode = *(frame_ip++);
#else
#define GET_OPCODE() (void)0
#endif
#define DEF_OP_EQZ(ctype, src_op_type) do { \
SET_OPERAND(int32, 2, (GET_OPERAND(ctype, 0) == 0)); \
frame_ip += 4; \
} while (0)
#define DEF_OP_CMP(src_type, src_op_type, cond) do { \
SET_OPERAND(uint32, 4, GET_OPERAND(src_type, 2) cond \
GET_OPERAND(src_type, 0)); \
frame_ip += 6; \
} while (0)
#define DEF_OP_BIT_COUNT(src_type, src_op_type, operation) do { \
SET_OPERAND(src_type, 2, \
(src_type)operation(GET_OPERAND(src_type, 0))); \
frame_ip += 4; \
} while (0)
#define DEF_OP_NUMERIC(src_type1, src_type2, src_op_type, operation) do { \
SET_OPERAND(src_type1, 4, (GET_OPERAND(src_type1, 2) \
operation GET_OPERAND(src_type2, 0))); \
frame_ip += 6; \
} while (0)
#if defined(BUILD_TARGET_X86_32)
#define DEF_OP_REINTERPRET(src_type) do { \
void *src = frame_lp + GET_OFFSET(); \
void *dst = frame_lp + GET_OFFSET(); \
bh_memcpy_s(dst, sizeof(src_type), src, sizeof(src_type)); \
} while (0)
#else
#define DEF_OP_REINTERPRET(src_type) do { \
SET_OPERAND(src_type, 2, GET_OPERAND(src_type, 0)); \
frame_ip += 4; \
} while (0)
#endif
#if WASM_CPU_SUPPORTS_UNALIGNED_64BIT_ACCESS != 0
#define DEF_OP_NUMERIC_64 DEF_OP_NUMERIC
#else
#define DEF_OP_NUMERIC_64(src_type1, src_type2, src_op_type, operation) do { \
src_type1 val1; \
src_type2 val2; \
val1 = \
(src_type1)GET_##src_op_type##_FROM_ADDR(frame_lp + (*(int16*)(frame_ip + 2))); \
val2 = \
(src_type2)GET_##src_op_type##_FROM_ADDR(frame_lp + (*(int16*)(frame_ip))); \
val1 operation##= val2; \
PUT_##src_op_type##_TO_ADDR(frame_lp + (*(int16*)(frame_ip + 4)), val1); \
frame_ip += 6; \
} while (0)
#endif
#define DEF_OP_NUMERIC2(src_type1, src_type2, src_op_type, operation) do { \
SET_OPERAND(src_type1, 4, (GET_OPERAND(src_type1, 2) \
operation (GET_OPERAND(src_type2, 0) % 32))); \
frame_ip += 6; \
} while (0)
#define DEF_OP_NUMERIC2_64(src_type1, src_type2, src_op_type, operation) do { \
SET_OPERAND(src_type1, 4, (GET_OPERAND(src_type1, 2) \
operation (GET_OPERAND(src_type2, 0) % 64))); \
frame_ip += 6; \
} while (0)
#define DEF_ATOMIC_RMW_OPCODE(OP_NAME, op) \
case WASM_OP_ATOMIC_RMW_I32_##OP_NAME: \
case WASM_OP_ATOMIC_RMW_I32_##OP_NAME##8_U: \
case WASM_OP_ATOMIC_RMW_I32_##OP_NAME##16_U: \
{ \
uint32 readv, sval; \
\
sval = POP_I32(); \
addr = POP_I32(); \
\
if (opcode == WASM_OP_ATOMIC_RMW_I32_##OP_NAME##8_U) { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(1); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint32)(*(uint8*)maddr); \
*(uint8*)maddr = (uint8)(readv op sval); \
os_mutex_unlock(&memory->mem_lock); \
} \
else if (opcode == WASM_OP_ATOMIC_RMW_I32_##OP_NAME##16_U) { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(2); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint32)LOAD_U16(maddr); \
STORE_U16(maddr, (uint16)(readv op sval)); \
os_mutex_unlock(&memory->mem_lock); \
} \
else { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(4); \
\
os_mutex_lock(&memory->mem_lock); \
readv = LOAD_I32(maddr); \
STORE_U32(maddr, readv op sval); \
os_mutex_unlock(&memory->mem_lock); \
} \
PUSH_I32(readv); \
break; \
} \
case WASM_OP_ATOMIC_RMW_I64_##OP_NAME: \
case WASM_OP_ATOMIC_RMW_I64_##OP_NAME##8_U: \
case WASM_OP_ATOMIC_RMW_I64_##OP_NAME##16_U: \
case WASM_OP_ATOMIC_RMW_I64_##OP_NAME##32_U: \
{ \
uint64 readv, sval; \
\
sval = (uint64)POP_I64(); \
addr = POP_I32(); \
\
if (opcode == WASM_OP_ATOMIC_RMW_I64_##OP_NAME##8_U) { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(1); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint64)(*(uint8*)maddr); \
*(uint8*)maddr = (uint8)(readv op sval); \
os_mutex_unlock(&memory->mem_lock); \
} \
else if (opcode == WASM_OP_ATOMIC_RMW_I64_##OP_NAME##16_U) { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(2); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint64)LOAD_U16(maddr); \
STORE_U16(maddr, (uint16)(readv op sval)); \
os_mutex_unlock(&memory->mem_lock); \
} \
else if (opcode == WASM_OP_ATOMIC_RMW_I64_##OP_NAME##32_U) { \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(4); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint64)LOAD_U32(maddr); \
STORE_U32(maddr, (uint32)(readv op sval)); \
os_mutex_unlock(&memory->mem_lock); \
} \
else { \
uint64 op_result; \
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 8, maddr); \
CHECK_ATOMIC_MEMORY_ACCESS(8); \
\
os_mutex_lock(&memory->mem_lock); \
readv = (uint64)LOAD_I64(maddr); \
op_result = readv op sval; \
STORE_I64(maddr, op_result); \
os_mutex_unlock(&memory->mem_lock); \
} \
PUSH_I64(readv); \
break; \
}
#define DEF_OP_MATH(src_type, src_op_type, method) do { \
SET_OPERAND(src_type, 2, method(GET_OPERAND(src_type, 0))); \
frame_ip += 4; \
} while (0)
#define TRUNC_FUNCTION(func_name, src_type, dst_type, signed_type) \
static dst_type \
func_name(src_type src_value, src_type src_min, src_type src_max, \
dst_type dst_min, dst_type dst_max, bool is_sign) \
{ \
dst_type dst_value = 0; \
if (!isnan(src_value)) { \
if (src_value <= src_min) \
dst_value = dst_min; \
else if (src_value >= src_max) \
dst_value = dst_max; \
else { \
if (is_sign) \
dst_value = (dst_type)(signed_type)src_value; \
else \
dst_value = (dst_type)src_value; \
} \
} \
return dst_value; \
}
TRUNC_FUNCTION(trunc_f32_to_i32, float32, uint32, int32)
TRUNC_FUNCTION(trunc_f32_to_i64, float32, uint64, int64)
TRUNC_FUNCTION(trunc_f64_to_i32, float64, uint32, int32)
TRUNC_FUNCTION(trunc_f64_to_i64, float64, uint64, int64)
static bool
trunc_f32_to_int(WASMModuleInstance *module,
uint8 *frame_ip, uint32 *frame_lp,
float32 src_min, float32 src_max,
bool saturating, bool is_i32, bool is_sign)
{
float32 src_value = GET_OPERAND(float32, 0);
uint64 dst_value_i64;
uint32 dst_value_i32;
if (!saturating) {
if (isnan(src_value)) {
wasm_set_exception(module, "invalid conversion to integer");
return true;
}
else if (src_value <= src_min || src_value >= src_max) {
wasm_set_exception(module, "integer overflow");
return true;
}
}
if (is_i32) {
uint32 dst_min = is_sign ? INT32_MIN : 0;
uint32 dst_max = is_sign ? INT32_MAX : UINT32_MAX;
dst_value_i32 = trunc_f32_to_i32(src_value, src_min, src_max,
dst_min, dst_max, is_sign);
SET_OPERAND(uint32, 2, dst_value_i32);
}
else {
uint64 dst_min = is_sign ? INT64_MIN : 0;
uint64 dst_max = is_sign ? INT64_MAX : UINT64_MAX;
dst_value_i64 = trunc_f32_to_i64(src_value, src_min, src_max,
dst_min, dst_max, is_sign);
SET_OPERAND(uint64, 2, dst_value_i64);
}
return false;
}
static bool
trunc_f64_to_int(WASMModuleInstance *module,
uint8 *frame_ip, uint32 *frame_lp,
float64 src_min, float64 src_max,
bool saturating, bool is_i32, bool is_sign)
{
float64 src_value = GET_OPERAND(float64, 0);
uint64 dst_value_i64;
uint32 dst_value_i32;
if (!saturating) {
if (isnan(src_value)) {
wasm_set_exception(module, "invalid conversion to integer");
return true;
}
else if (src_value <= src_min || src_value >= src_max) {
wasm_set_exception(module, "integer overflow");
return true;
}
}
if (is_i32) {
uint32 dst_min = is_sign ? INT32_MIN : 0;
uint32 dst_max = is_sign ? INT32_MAX : UINT32_MAX;
dst_value_i32 = trunc_f64_to_i32(src_value, src_min, src_max,
dst_min, dst_max, is_sign);
SET_OPERAND(uint32, 2, dst_value_i32);
}
else {
uint64 dst_min = is_sign ? INT64_MIN : 0;
uint64 dst_max = is_sign ? INT64_MAX : UINT64_MAX;
dst_value_i64 = trunc_f64_to_i64(src_value, src_min, src_max,
dst_min, dst_max, is_sign);
SET_OPERAND(uint64, 2, dst_value_i64);
}
return false;
}
#define DEF_OP_TRUNC_F32(min, max, is_i32, is_sign) do { \
if (trunc_f32_to_int(module, frame_ip, frame_lp, min, max, \
false, is_i32, is_sign)) \
goto got_exception; \
frame_ip += 4; \
} while (0)
#define DEF_OP_TRUNC_F64(min, max, is_i32, is_sign) do { \
if (trunc_f64_to_int(module, frame_ip, frame_lp, min, max, \
false, is_i32, is_sign)) \
goto got_exception; \
frame_ip += 4; \
} while (0)
#define DEF_OP_TRUNC_SAT_F32(min, max, is_i32, is_sign) do { \
(void)trunc_f32_to_int(module, frame_ip, frame_lp, min, max, \
true, is_i32, is_sign); \
frame_ip += 4; \
} while (0)
#define DEF_OP_TRUNC_SAT_F64(min, max, is_i32, is_sign) do { \
(void)trunc_f64_to_int(module, frame_ip, frame_lp, min, max, \
true, is_i32, is_sign); \
frame_ip += 4; \
} while (0)
#define DEF_OP_CONVERT(dst_type, dst_op_type, \
src_type, src_op_type) do { \
dst_type value = (dst_type)(src_type)POP_##src_op_type(); \
PUSH_##dst_op_type(value); \
} while (0)
static bool
copy_stack_values(WASMModuleInstance *module,
uint32 *frame_lp,
uint32 arity,
uint32 total_cell_num,
const uint8 *cells,
const int16 *src_offsets,
const uint16 *dst_offsets)
{
/* To avoid the overlap issue between src offsets and dst offset,
* we use 2 steps to do the copy. First step, copy the src values
* to a tmp buf. Second step, copy the values from tmp buf to dst.
*/
uint32 buf[16] = {0}, i;
uint32 *tmp_buf = buf;
uint8 cell;
int16 src, buf_index = 0;
uint16 dst;
/* Allocate memory if the buf is not large enough */
if (total_cell_num > sizeof(buf)/sizeof(uint32)) {
uint64 total_size = sizeof(uint32) * (uint64)total_cell_num;
if (total_size >= UINT32_MAX
|| !(tmp_buf = wasm_runtime_malloc((uint32)total_size))) {
wasm_set_exception(module, "allocate memory failed");
return false;
}
}
/* 1) Copy values from src to tmp buf */
for (i = 0; i < arity; i++) {
cell = cells[i];
src = src_offsets[i];
if (cell == 1)
tmp_buf[buf_index] = frame_lp[src];
else
*(uint64*)(tmp_buf + buf_index) = *(uint64*)(frame_lp + src);
buf_index += cell;
}
/* 2) Copy values from tmp buf to dest */
buf_index = 0;
for (i = 0; i < arity; i++) {
cell = cells[i];
dst = dst_offsets[i];
if (cell == 1)
frame_lp[dst] = tmp_buf[buf_index];
else
*(uint64*)(frame_lp + dst) = *(uint64*)(tmp_buf + buf_index);
buf_index += cell;
}
if (tmp_buf != buf) {
wasm_runtime_free(tmp_buf);
}
return true;
}
#define RECOVER_BR_INFO() do { \
uint32 arity; \
/* read arity */ \
arity = *(uint32*)frame_ip; \
frame_ip += sizeof(arity); \
if (arity) { \
uint32 total_cell; \
uint16 *dst_offsets = NULL; \
uint8 *cells; \
int16 *src_offsets = NULL; \
/* read total cell num */ \
total_cell = *(uint32*)frame_ip; \
frame_ip += sizeof(total_cell); \
/* cells */ \
cells = (uint8 *)frame_ip; \
frame_ip += arity * sizeof(uint8); \
/* src offsets */ \
src_offsets = (int16 *)frame_ip; \
frame_ip += arity * sizeof(int16); \
/* dst offsets */ \
dst_offsets = (uint16*)frame_ip; \
frame_ip += arity * sizeof(uint16); \
if (arity == 1) { \
if (cells[0] == 1) \
frame_lp[dst_offsets[0]] = \
frame_lp[src_offsets[0]]; \
else if (cells[0] == 2) { \
*(int64*)(frame_lp + dst_offsets[0]) = \
*(int64*)(frame_lp + src_offsets[0]); \
} \
} \
else { \
if (!copy_stack_values(module, frame_lp, \
arity, total_cell, \
cells, src_offsets, \
dst_offsets)) \
goto got_exception; \
} \
} \
frame_ip = *(uint8**)frame_ip; \
} while (0)
#define SKIP_BR_INFO() do { \
uint32 arity; \
/* read and skip arity */ \
arity = *(uint32*)frame_ip; \
frame_ip += sizeof(arity); \
if (arity) { \
/* skip total cell num */ \
frame_ip += sizeof(uint32); \
/* skip cells, src offsets and dst offsets */ \
frame_ip += (sizeof(uint8) + sizeof(int16) + sizeof(uint16)) * arity; \
} \
/* skip target address */ \
frame_ip += sizeof(uint8*); \
} while (0)
static inline int32
sign_ext_8_32(int8 val)
{
if (val & 0x80)
return (int32)val | (int32)0xffffff00;
return val;
}
static inline int32
sign_ext_16_32(int16 val)
{
if (val & 0x8000)
return (int32)val | (int32)0xffff0000;
return val;
}
static inline int64
sign_ext_8_64(int8 val)
{
if (val & 0x80)
return (int64)val | (int64)0xffffffffffffff00;
return val;
}
static inline int64
sign_ext_16_64(int16 val)
{
if (val & 0x8000)
return (int64)val | (int64)0xffffffffffff0000;
return val;
}
static inline int64
sign_ext_32_64(int32 val)
{
if (val & (int32)0x80000000)
return (int64)val | (int64)0xffffffff00000000;
return val;
}
static inline void
word_copy(uint32 *dest, uint32 *src, unsigned num)
{
for (; num > 0; num--)
*dest++ = *src++;
}
static inline WASMInterpFrame*
ALLOC_FRAME(WASMExecEnv *exec_env, uint32 size, WASMInterpFrame *prev_frame)
{
WASMInterpFrame *frame = wasm_exec_env_alloc_wasm_frame(exec_env, size);
if (frame)
frame->prev_frame = prev_frame;
else {
wasm_set_exception((WASMModuleInstance*)exec_env->module_inst,
"stack overflow");
}
return frame;
}
static inline void
FREE_FRAME(WASMExecEnv *exec_env, WASMInterpFrame *frame)
{
wasm_exec_env_free_wasm_frame(exec_env, frame);
}
static void
wasm_interp_call_func_native(WASMModuleInstance *module_inst,
WASMExecEnv *exec_env,
WASMFunctionInstance *cur_func,
WASMInterpFrame *prev_frame)
{
WASMFunctionImport *func_import = cur_func->u.func_import;
unsigned local_cell_num = 2;
WASMInterpFrame *frame;
uint32 argv_ret[2];
bool ret;
if (!(frame = ALLOC_FRAME(exec_env,
wasm_interp_interp_frame_size(local_cell_num),
prev_frame)))
return;
frame->function = cur_func;
frame->ip = NULL;
frame->lp = frame->operand;
wasm_exec_env_set_cur_frame(exec_env, frame);
if (!func_import->func_ptr_linked) {
char buf[128];
snprintf(buf,
sizeof(buf), "fail to call unlinked import function (%s, %s)",
func_import->module_name, func_import->field_name);
wasm_set_exception((WASMModuleInstance*)module_inst, buf);
return;
}
if (!func_import->call_conv_raw) {
ret = wasm_runtime_invoke_native(exec_env, func_import->func_ptr_linked,
func_import->func_type, func_import->signature,
func_import->attachment,
frame->lp, cur_func->param_cell_num, argv_ret);
}
else {
ret = wasm_runtime_invoke_native_raw(exec_env, func_import->func_ptr_linked,
func_import->func_type, func_import->signature,
func_import->attachment,
frame->lp, cur_func->param_cell_num, argv_ret);
}
if (!ret)
return;
if (cur_func->ret_cell_num == 1) {
prev_frame->lp[prev_frame->ret_offset] = argv_ret[0];
}
else if (cur_func->ret_cell_num == 2) {
prev_frame->lp[prev_frame->ret_offset] = argv_ret[0];
prev_frame->lp[prev_frame->ret_offset + 1] = argv_ret[1];
}
FREE_FRAME(exec_env, frame);
wasm_exec_env_set_cur_frame(exec_env, prev_frame);
}
#if WASM_ENABLE_MULTI_MODULE != 0
static void
wasm_interp_call_func_bytecode(WASMModuleInstance *module,
WASMExecEnv *exec_env,
WASMFunctionInstance *cur_func,
WASMInterpFrame *prev_frame);
static void
wasm_interp_call_func_import(WASMModuleInstance *module_inst,
WASMExecEnv *exec_env,
WASMFunctionInstance *cur_func,
WASMInterpFrame *prev_frame)
{
WASMModuleInstance *sub_module_inst = cur_func->import_module_inst;
WASMFunctionInstance *sub_func_inst = cur_func->import_func_inst;
WASMFunctionImport *func_import = cur_func->u.func_import;
uint8 *ip = prev_frame->ip;
char buf[128];
if (!sub_func_inst) {
snprintf(buf, sizeof(buf),
"fail to call unlinked import function (%s, %s)",
func_import->module_name, func_import->field_name);
wasm_set_exception(module_inst, buf);
return;
}
/* set ip NULL to make call_func_bytecode return after executing
this function */
prev_frame->ip = NULL;
/* replace exec_env's module_inst with sub_module_inst so we can
call it */
exec_env->module_inst = (WASMModuleInstanceCommon *)sub_module_inst;
/* call function of sub-module*/
wasm_interp_call_func_bytecode(sub_module_inst, exec_env,
sub_func_inst, prev_frame);
/* restore ip and module_inst */
prev_frame->ip = ip;
exec_env->module_inst = (WASMModuleInstanceCommon *)module_inst;
/* transfer exception if it is thrown */
if (wasm_get_exception(sub_module_inst)) {
bh_memcpy_s(module_inst->cur_exception,
sizeof(module_inst->cur_exception),
sub_module_inst->cur_exception,
sizeof(sub_module_inst->cur_exception));
}
}
#endif
#if WASM_ENABLE_THREAD_MGR != 0
#define CHECK_SUSPEND_FLAGS() do { \
if (exec_env->suspend_flags.flags != 0) { \
if (exec_env->suspend_flags.flags & 0x01) { \
/* terminate current thread */ \
return; \
} \
/* TODO: support suspend and breakpoint */ \
} \
} while (0)
#endif
#if WASM_ENABLE_OPCODE_COUNTER != 0
typedef struct OpcodeInfo {
char *name;
uint64 count;
} OpcodeInfo;
#define HANDLE_OPCODE(op) { #op, 0 }
DEFINE_GOTO_TABLE (OpcodeInfo, opcode_table);
#undef HANDLE_OPCODE
static void
wasm_interp_dump_op_count()
{
uint32 i;
uint64 total_count = 0;
for (i = 0; i < WASM_OP_IMPDEP; i++)
total_count += opcode_table[i].count;
printf("total opcode count: %ld\n", total_count);
for (i = 0; i < WASM_OP_IMPDEP; i++)
if (opcode_table[i].count > 0)
printf("\t\t%s count:\t\t%ld,\t\t%.2f%%\n",
opcode_table[i].name, opcode_table[i].count,
opcode_table[i].count * 100.0f / total_count);
}
#endif
#if WASM_ENABLE_LABELS_AS_VALUES != 0
//#define HANDLE_OP(opcode) HANDLE_##opcode:printf(#opcode"\n");h_##opcode
#if WASM_ENABLE_OPCODE_COUNTER != 0
#define HANDLE_OP(opcode) HANDLE_##opcode:opcode_table[opcode].count++;h_##opcode
#else
#define HANDLE_OP(opcode) HANDLE_##opcode
#endif
#if WASM_ENABLE_FAST_INTERP == 0
#define FETCH_OPCODE_AND_DISPATCH() goto *handle_table[*frame_ip++]
#else
#if WASM_ENABLE_ABS_LABEL_ADDR != 0
#define FETCH_OPCODE_AND_DISPATCH() do { \
const void *p_label_addr = *(void**)frame_ip; \
frame_ip += sizeof(void*); \
goto *p_label_addr; \
} while (0)
#else
#define FETCH_OPCODE_AND_DISPATCH() do { \
const void *p_label_addr = label_base \
+ *(int16*)frame_ip; \
frame_ip += sizeof(int16); \
goto *p_label_addr; \
} while (0)
#endif
#endif
#define HANDLE_OP_END() FETCH_OPCODE_AND_DISPATCH()
#else /* else of WASM_ENABLE_LABELS_AS_VALUES */
#define HANDLE_OP(opcode) case opcode
#define HANDLE_OP_END() continue
#endif /* end of WASM_ENABLE_LABELS_AS_VALUES */
#if WASM_ENABLE_FAST_INTERP != 0
static void **global_handle_table;
#endif
static void
wasm_interp_call_func_bytecode(WASMModuleInstance *module,
WASMExecEnv *exec_env,
WASMFunctionInstance *cur_func,
WASMInterpFrame *prev_frame)
{
WASMMemoryInstance *memory = module->default_memory;
uint32 num_bytes_per_page = memory ? memory->num_bytes_per_page : 0;
uint8 *global_data = module->global_data;
uint32 linear_mem_size = memory ? num_bytes_per_page * memory->cur_page_count : 0;
WASMTableInstance *table = module->default_table;
WASMGlobalInstance *globals = module->globals, *global;
uint8 opcode_IMPDEP = WASM_OP_IMPDEP;
WASMInterpFrame *frame = NULL;
/* Points to this special opcode so as to jump to the call_method_from_entry. */
register uint8 *frame_ip = &opcode_IMPDEP; /* cache of frame->ip */
register uint32 *frame_lp = NULL; /* cache of frame->lp */
#if WASM_ENABLE_ABS_LABEL_ADDR == 0
register uint8 *label_base = &&HANDLE_WASM_OP_UNREACHABLE; /* cache of label base addr */
#endif
uint8 *frame_ip_end;
uint32 cond, count, fidx, tidx, frame_size = 0;
uint64 all_cell_num = 0;
int16 addr1, addr2, addr_ret = 0;
int32 didx, val;
uint8 *maddr = NULL;
uint32 local_idx, local_offset, global_idx;
uint8 opcode, local_type, *global_addr;
#if WASM_ENABLE_LABELS_AS_VALUES != 0
#define HANDLE_OPCODE(op) &&HANDLE_##op
DEFINE_GOTO_TABLE (const void*, handle_table);
#undef HANDLE_OPCODE
#if WASM_ENABLE_FAST_INTERP != 0
if (exec_env == NULL) {
global_handle_table = (void **)handle_table;
return;
}
#endif
#endif
#if WASM_ENABLE_LABELS_AS_VALUES == 0
while (frame_ip < frame_ip_end) {
opcode = *frame_ip++;
switch (opcode) {
#else
goto *handle_table[WASM_OP_IMPDEP];
#endif
/* control instructions */
HANDLE_OP (WASM_OP_UNREACHABLE):
wasm_set_exception(module, "unreachable");
goto got_exception;
HANDLE_OP (WASM_OP_IF):
cond = (uint32)POP_I32();
if (cond == 0) {
if (*(uint8**)frame_ip == NULL) {
frame_ip = *(uint8**)(frame_ip + sizeof(uint8*));
}
else {
frame_ip = *(uint8**)(frame_ip);
}
}
else {
frame_ip += sizeof(uint8*) * 2;
}
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_ELSE):
frame_ip = *(uint8**)(frame_ip);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_BR):
#if WASM_ENABLE_THREAD_MGR != 0
CHECK_SUSPEND_FLAGS();
#endif
recover_br_info:
RECOVER_BR_INFO();
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_BR_IF):
#if WASM_ENABLE_THREAD_MGR != 0
CHECK_SUSPEND_FLAGS();
#endif
cond = frame_lp[GET_OFFSET()];
if (cond)
goto recover_br_info;
else
SKIP_BR_INFO();
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_BR_TABLE):
#if WASM_ENABLE_THREAD_MGR != 0
CHECK_SUSPEND_FLAGS();
#endif
count = read_uint32(frame_ip);
didx = GET_OPERAND(uint32, 0);
frame_ip += 2;
if (!(didx >= 0 && (uint32)didx < count))
didx = count;
while (didx--)
SKIP_BR_INFO();
goto recover_br_info;
HANDLE_OP (WASM_OP_RETURN):
{
uint32 ret_idx;
WASMType *func_type;
uint32 off, ret_offset;
uint8 *ret_types;
if (cur_func->is_import_func
#if WASM_ENABLE_MULTI_MODULE != 0
&& !cur_func->import_func_inst
#endif
)
func_type = cur_func->u.func_import->func_type;
else
func_type = cur_func->u.func->func_type;
/* types of each return value */
ret_types = func_type->types + func_type->param_count;
ret_offset = prev_frame->ret_offset;
for (ret_idx = 0, off = sizeof(int16) * (func_type->result_count - 1);
ret_idx < func_type->result_count;
ret_idx++, off -= sizeof(int16)) {
if (ret_types[ret_idx] == VALUE_TYPE_I64
|| ret_types[ret_idx] == VALUE_TYPE_F64) {
*((uint64 *)(prev_frame->lp + ret_offset)) =
GET_OPERAND(uint64, off);
ret_offset += 2;
}
else {
prev_frame->lp[ret_offset] = GET_OPERAND(int32, off);
ret_offset++;
}
}
}
goto return_func;
HANDLE_OP (WASM_OP_CALL_INDIRECT):
{
WASMType *cur_type, *cur_func_type;
WASMTableInstance *cur_table_inst;
#if WASM_ENABLE_THREAD_MGR != 0
CHECK_SUSPEND_FLAGS();
#endif
tidx = read_uint32(frame_ip);
val = GET_OPERAND(int32, 0);
frame_ip += 2;
if (tidx >= module->module->type_count) {
wasm_set_exception(module, "type index is overflow");
goto got_exception;
}
cur_type = module->module->types[tidx];
/* careful, it might be a table in another module */
cur_table_inst = table;
#if WASM_ENABLE_MULTI_MODULE != 0
if (table->table_inst_linked) {
cur_table_inst = table->table_inst_linked;
}
#endif
if (val < 0 || val >= (int32)cur_table_inst->cur_size) {
wasm_set_exception(module, "undefined element");
goto got_exception;
}
fidx = ((uint32*)cur_table_inst->base_addr)[val];
if (fidx == (uint32)-1) {
wasm_set_exception(module, "uninitialized element");
goto got_exception;
}
#if WASM_ENABLE_MULTI_MODULE != 0
if (fidx >= module->function_count) {
wasm_set_exception(module, "unknown function");
goto got_exception;
}
#endif
/* always call module own functions */
cur_func = module->functions + fidx;
if (cur_func->is_import_func
#if WASM_ENABLE_MULTI_MODULE != 0
&& !cur_func->import_func_inst
#endif
)
cur_func_type = cur_func->u.func_import->func_type;
else
cur_func_type = cur_func->u.func->func_type;
if (!wasm_type_equal(cur_type, cur_func_type)) {
wasm_set_exception(module, "indirect call type mismatch");
goto got_exception;
}
goto call_func_from_interp;
}
/* parametric instructions */
HANDLE_OP (WASM_OP_SELECT):
{
cond = frame_lp[GET_OFFSET()];
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
addr_ret = GET_OFFSET();
if (!cond) {
#if defined(BUILD_TARGET_X86_32)
if (addr_ret != addr1)
bh_memcpy_s(frame_lp + addr_ret, sizeof(int32),
frame_lp + addr1, sizeof(int32));
#else
frame_lp[addr_ret] = frame_lp[addr1];
#endif
}
else {
#if defined(BUILD_TARGET_X86_32)
if (addr_ret != addr2)
bh_memcpy_s(frame_lp + addr_ret, sizeof(int32),
frame_lp + addr2, sizeof(int32));
#else
frame_lp[addr_ret] = frame_lp[addr2];
#endif
}
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_SELECT_64):
{
cond = frame_lp[GET_OFFSET()];
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
addr_ret = GET_OFFSET();
if (!cond) {
#if defined(BUILD_TARGET_X86_32)
if (addr_ret != addr1)
bh_memcpy_s(frame_lp + addr_ret, sizeof(int64),
frame_lp + addr1, sizeof(int64));
#else
*(int64*)(frame_lp + addr_ret) = *(int64*)(frame_lp + addr1);
#endif
}
else {
#if defined(BUILD_TARGET_X86_32)
if (addr_ret != addr2)
bh_memcpy_s(frame_lp + addr_ret, sizeof(int64),
frame_lp + addr2, sizeof(int64));
#else
*(int64*)(frame_lp + addr_ret) = *(int64*)(frame_lp + addr2);
#endif
}
HANDLE_OP_END ();
}
/* variable instructions */
HANDLE_OP (EXT_OP_SET_LOCAL_FAST):
HANDLE_OP (EXT_OP_TEE_LOCAL_FAST):
{
local_offset = *frame_ip++;
*(int32*)(frame_lp + local_offset) = GET_OPERAND(uint32, 0);
frame_ip += 2;
HANDLE_OP_END ();
}
HANDLE_OP (EXT_OP_SET_LOCAL_FAST_I64):
HANDLE_OP (EXT_OP_TEE_LOCAL_FAST_I64):
{
local_offset = *frame_ip++;
PUT_I64_TO_ADDR((uint32*)(frame_lp + local_offset), GET_OPERAND(uint64, 0));
frame_ip += 2;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_GET_GLOBAL):
{
global_idx = read_uint32(frame_ip);
bh_assert(global_idx < module->global_count);
global = globals + global_idx;
#if WASM_ENABLE_MULTI_MODULE == 0
global_addr = global_data + global->data_offset;
#else
global_addr = global->import_global_inst
? global->import_module_inst->global_data
+ global->import_global_inst->data_offset
: global_data + global->data_offset;
#endif
addr_ret = GET_OFFSET();
frame_lp[addr_ret] = *(uint32*)global_addr;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_GET_GLOBAL_64):
{
global_idx = read_uint32(frame_ip);
bh_assert(global_idx < module->global_count);
global = globals + global_idx;
#if WASM_ENABLE_MULTI_MODULE == 0
global_addr = global_data + global->data_offset;
#else
global_addr = global->import_global_inst
? global->import_module_inst->global_data
+ global->import_global_inst->data_offset
: global_data + global->data_offset;
#endif
addr_ret = GET_OFFSET();
*(uint64 *)(frame_lp + addr_ret) = GET_I64_FROM_ADDR((uint32*)global_addr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_SET_GLOBAL):
{
global_idx = read_uint32(frame_ip);
bh_assert(global_idx < module->global_count);
global = globals + global_idx;
#if WASM_ENABLE_MULTI_MODULE == 0
global_addr = global_data + global->data_offset;
#else
global_addr = global->import_global_inst
? global->import_module_inst->global_data
+ global->import_global_inst->data_offset
: global_data + global->data_offset;
#endif
addr1 = GET_OFFSET();
*(int32*)global_addr = frame_lp[addr1];
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_SET_GLOBAL_AUX_STACK):
{
global_idx = read_uint32(frame_ip);
bh_assert(global_idx < module->global_count);
global = globals + global_idx;
#if WASM_ENABLE_MULTI_MODULE == 0
global_addr = global_data + global->data_offset;
#else
global_addr = global->import_global_inst
? global->import_module_inst->global_data
+ global->import_global_inst->data_offset
: global_data + global->data_offset;
#endif
addr1 = GET_OFFSET();
if (frame_lp[addr1] < exec_env->aux_stack_boundary)
goto out_of_bounds;
*(int32*)global_addr = frame_lp[addr1];
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_SET_GLOBAL_64):
{
global_idx = read_uint32(frame_ip);
bh_assert(global_idx < module->global_count);
global = globals + global_idx;
#if WASM_ENABLE_MULTI_MODULE == 0
global_addr = global_data + global->data_offset;
#else
global_addr = global->import_global_inst
? global->import_module_inst->global_data
+ global->import_global_inst->data_offset
: global_data + global->data_offset;
#endif
addr1 = GET_OFFSET();
PUT_I64_TO_ADDR((uint32*)global_addr, *(int64 *)(frame_lp + addr1));
HANDLE_OP_END ();
}
/* memory load instructions */
HANDLE_OP (WASM_OP_I32_LOAD):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(4);
frame_lp[addr_ret] = LOAD_I32(maddr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(8);
PUT_I64_TO_ADDR(frame_lp + addr_ret, LOAD_I64(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_LOAD8_S):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(1);
frame_lp[addr_ret] = sign_ext_8_32(*(int8*)maddr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_LOAD8_U):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(1);
frame_lp[addr_ret] = (uint32)(*(uint8*)maddr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_LOAD16_S):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(2);
frame_lp[addr_ret] = sign_ext_16_32(LOAD_I16(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_LOAD16_U):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(2);
frame_lp[addr_ret] = (uint32)(LOAD_U16(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD8_S):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(1);
*(int64 *)(frame_lp + addr_ret) = sign_ext_8_64(*(int8*)maddr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD8_U):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(1);
*(int64 *)(frame_lp + addr_ret) = (uint64)(*(uint8*)maddr);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD16_S):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(2);
*(int64 *)(frame_lp + addr_ret) = sign_ext_16_64(LOAD_I16(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD16_U):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(2);
*(int64 *)(frame_lp + addr_ret) = (uint64)(LOAD_U16(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD32_S):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(4);
*(int64 *)(frame_lp + addr_ret) = sign_ext_32_64(LOAD_I32(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_LOAD32_U):
{
uint32 offset, addr;
offset = read_uint32(frame_ip);
addr = GET_OPERAND(uint32, 0);
frame_ip += 2;
addr_ret = GET_OFFSET();
CHECK_MEMORY_OVERFLOW(4);
*(int64 *)(frame_lp + addr_ret) = (uint64)(LOAD_U32(maddr));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_STORE):
{
uint32 offset, addr;
uint32 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint32, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(4);
STORE_U32(maddr, sval);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_STORE8):
{
uint32 offset, addr;
uint32 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint32, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(1);
*(uint8*)maddr = (uint8)sval;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_STORE16):
{
uint32 offset, addr;
uint32 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint32, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(2);
STORE_U16(maddr, (uint16)sval);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_STORE):
{
uint32 offset, addr;
uint64 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint64, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(8);
STORE_I64(maddr, sval);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_STORE8):
{
uint32 offset, addr;
uint64 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint64, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(1);
*(uint8*)maddr = (uint8)sval;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_STORE16):
{
uint32 offset, addr;
uint64 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint64, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(2);
STORE_U16(maddr, (uint16)sval);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_STORE32):
{
uint32 offset, addr;
uint64 sval;
offset = read_uint32(frame_ip);
sval = GET_OPERAND(uint64, 0);
addr = GET_OPERAND(uint32, 2);
frame_ip += 4;
CHECK_MEMORY_OVERFLOW(4);
STORE_U32(maddr, (uint32)sval);
HANDLE_OP_END ();
}
/* memory size and memory grow instructions */
HANDLE_OP (WASM_OP_MEMORY_SIZE):
{
uint32 reserved;
addr_ret = GET_OFFSET();
frame_lp[addr_ret] = memory->cur_page_count;
(void)reserved;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_MEMORY_GROW):
{
uint32 reserved, delta, prev_page_count = memory->cur_page_count;
addr1 = GET_OFFSET();
addr_ret = GET_OFFSET();
delta = (uint32)frame_lp[addr1];
if (!wasm_enlarge_memory(module, delta)) {
/* fail to memory.grow, return -1 */
frame_lp[addr_ret] = -1;
}
else {
/* success, return previous page count */
frame_lp[addr_ret] = prev_page_count;
/* update the memory instance ptr */
memory = module->default_memory;
linear_mem_size = num_bytes_per_page * memory->cur_page_count;
}
(void)reserved;
HANDLE_OP_END ();
}
/* comparison instructions of i32 */
HANDLE_OP (WASM_OP_I32_EQZ):
DEF_OP_EQZ(int32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_EQ):
DEF_OP_CMP(uint32, I32, ==);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_NE):
DEF_OP_CMP(uint32, I32, !=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_LT_S):
DEF_OP_CMP(int32, I32, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_LT_U):
DEF_OP_CMP(uint32, I32, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_GT_S):
DEF_OP_CMP(int32, I32, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_GT_U):
DEF_OP_CMP(uint32, I32, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_LE_S):
DEF_OP_CMP(int32, I32, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_LE_U):
DEF_OP_CMP(uint32, I32, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_GE_S):
DEF_OP_CMP(int32, I32, >=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_GE_U):
DEF_OP_CMP(uint32, I32, >=);
HANDLE_OP_END ();
/* comparison instructions of i64 */
HANDLE_OP (WASM_OP_I64_EQZ):
DEF_OP_EQZ(int64, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_EQ):
DEF_OP_CMP(uint64, I64, ==);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_NE):
DEF_OP_CMP(uint64, I64, !=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_LT_S):
DEF_OP_CMP(int64, I64, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_LT_U):
DEF_OP_CMP(uint64, I64, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_GT_S):
DEF_OP_CMP(int64, I64, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_GT_U):
DEF_OP_CMP(uint64, I64, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_LE_S):
DEF_OP_CMP(int64, I64, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_LE_U):
DEF_OP_CMP(uint64, I64, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_GE_S):
DEF_OP_CMP(int64, I64, >=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_GE_U):
DEF_OP_CMP(uint64, I64, >=);
HANDLE_OP_END ();
/* comparison instructions of f32 */
HANDLE_OP (WASM_OP_F32_EQ):
DEF_OP_CMP(float32, F32, ==);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_NE):
DEF_OP_CMP(float32, F32, !=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_LT):
DEF_OP_CMP(float32, F32, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_GT):
DEF_OP_CMP(float32, F32, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_LE):
DEF_OP_CMP(float32, F32, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_GE):
DEF_OP_CMP(float32, F32, >=);
HANDLE_OP_END ();
/* comparison instructions of f64 */
HANDLE_OP (WASM_OP_F64_EQ):
DEF_OP_CMP(float64, F64, ==);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_NE):
DEF_OP_CMP(float64, F64, !=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_LT):
DEF_OP_CMP(float64, F64, <);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_GT):
DEF_OP_CMP(float64, F64, >);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_LE):
DEF_OP_CMP(float64, F64, <=);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_GE):
DEF_OP_CMP(float64, F64, >=);
HANDLE_OP_END ();
/* numberic instructions of i32 */
HANDLE_OP (WASM_OP_I32_CLZ):
DEF_OP_BIT_COUNT(uint32, I32, clz32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_CTZ):
DEF_OP_BIT_COUNT(uint32, I32, ctz32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_POPCNT):
DEF_OP_BIT_COUNT(uint32, I32, popcount32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_ADD):
DEF_OP_NUMERIC(uint32, uint32, I32, +);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_SUB):
DEF_OP_NUMERIC(uint32, uint32, I32, -);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_MUL):
DEF_OP_NUMERIC(uint32, uint32, I32, *);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_DIV_S):
{
int32 a, b;
b = frame_lp[GET_OFFSET()];
a = frame_lp[GET_OFFSET()];
addr_ret = GET_OFFSET();
if (a == (int32)0x80000000 && b == -1) {
wasm_set_exception(module, "integer overflow");
goto got_exception;
}
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
frame_lp[addr_ret] = (a / b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_DIV_U):
{
uint32 a, b;
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
addr_ret = GET_OFFSET();
b = (uint32)frame_lp[addr1];
a = (uint32)frame_lp[addr2];
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
frame_lp[addr_ret] = (a / b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_REM_S):
{
int32 a, b;
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
addr_ret = GET_OFFSET();
b = frame_lp[addr1];
a = frame_lp[addr2];
if (a == (int32)0x80000000 && b == -1) {
frame_lp[addr_ret] = 0;
HANDLE_OP_END ();
}
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
frame_lp[addr_ret] = (a % b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_REM_U):
{
uint32 a, b;
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
addr_ret = GET_OFFSET();
b = (uint32)frame_lp[addr1];
a = (uint32)frame_lp[addr2];
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
frame_lp[addr_ret] = (a % b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_AND):
DEF_OP_NUMERIC(uint32, uint32, I32, &);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_OR):
DEF_OP_NUMERIC(uint32, uint32, I32, |);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_XOR):
DEF_OP_NUMERIC(uint32, uint32, I32, ^);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_SHL):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC(uint32, uint32, I32, <<);
#else
DEF_OP_NUMERIC2(uint32, uint32, I32, <<);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_SHR_S):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC(int32, uint32, I32, >>);
#else
DEF_OP_NUMERIC2(int32, uint32, I32, >>);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_SHR_U):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC(uint32, uint32, I32, >>);
#else
DEF_OP_NUMERIC2(uint32, uint32, I32, >>);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_ROTL):
{
uint32 a, b;
b = (uint32)frame_lp[GET_OFFSET()];
a = (uint32)frame_lp[GET_OFFSET()];
frame_lp[GET_OFFSET()] = rotl32(a, b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_ROTR):
{
uint32 a, b;
b = (uint32)frame_lp[GET_OFFSET()];
a = (uint32)frame_lp[GET_OFFSET()];
frame_lp[GET_OFFSET()] = rotr32(a, b);
HANDLE_OP_END ();
}
/* numberic instructions of i64 */
HANDLE_OP (WASM_OP_I64_CLZ):
DEF_OP_BIT_COUNT(uint64, I64, clz64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_CTZ):
DEF_OP_BIT_COUNT(uint64, I64, ctz64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_POPCNT):
DEF_OP_BIT_COUNT(uint64, I64, popcount64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_ADD):
DEF_OP_NUMERIC_64(uint64, uint64, I64, +);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_SUB):
DEF_OP_NUMERIC_64(uint64, uint64, I64, -);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_MUL):
DEF_OP_NUMERIC_64(uint64, uint64, I64, *);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_DIV_S):
{
int64 a, b;
b = *(int64*)(frame_lp + GET_OFFSET());
a = *(int64*)(frame_lp + GET_OFFSET());
if (a == (int64)0x8000000000000000LL && b == -1) {
wasm_set_exception(module, "integer overflow");
goto got_exception;
}
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
*(int64*)(frame_lp + GET_OFFSET()) = (a / b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_DIV_U):
{
uint64 a, b;
b = *(uint64*)(frame_lp + GET_OFFSET());
a = *(uint64*)(frame_lp + GET_OFFSET());
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
*(uint64*)(frame_lp + GET_OFFSET()) = (a / b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_REM_S):
{
int64 a, b;
b = *(int64*)(frame_lp + GET_OFFSET());
a = *(int64*)(frame_lp + GET_OFFSET());
if (a == (int64)0x8000000000000000LL && b == -1) {
*(int64*)(frame_lp + GET_OFFSET()) = 0;
HANDLE_OP_END ();
}
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
*(int64*)(frame_lp + GET_OFFSET()) = (a % b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_REM_U):
{
uint64 a, b;
b = *(uint64*)(frame_lp + GET_OFFSET());
a = *(uint64*)(frame_lp + GET_OFFSET());
if (b == 0) {
wasm_set_exception(module, "integer divide by zero");
goto got_exception;
}
*(uint64*)(frame_lp + GET_OFFSET()) = (a % b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_AND):
DEF_OP_NUMERIC_64(uint64, uint64, I64, &);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_OR):
DEF_OP_NUMERIC_64(uint64, uint64, I64, |);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_XOR):
DEF_OP_NUMERIC_64(uint64, uint64, I64, ^);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_SHL):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC_64(uint64, uint64, I64, <<);
#else
DEF_OP_NUMERIC2_64(uint64, uint64, I64, <<);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_SHR_S):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC_64(int64, uint64, I64, >>);
#else
DEF_OP_NUMERIC2_64(int64, uint64, I64, >>);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_SHR_U):
{
#if defined(BUILD_TARGET_X86_64) || defined(BUILD_TARGET_X86_32)
DEF_OP_NUMERIC_64(uint64, uint64, I64, >>);
#else
DEF_OP_NUMERIC2_64(uint64, uint64, I64, >>);
#endif
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_ROTL):
{
uint64 a, b;
b = *(int64*)(frame_lp + GET_OFFSET());
a = *(int64*)(frame_lp + GET_OFFSET());
*(int64*)(frame_lp + GET_OFFSET()) = rotl64(a, b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I64_ROTR):
{
uint64 a, b;
b = *(uint64*)(frame_lp + GET_OFFSET());
a = *(uint64*)(frame_lp + GET_OFFSET());
*(uint64*)(frame_lp + GET_OFFSET()) = rotr64(a, b);
HANDLE_OP_END ();
}
/* numberic instructions of f32 */
HANDLE_OP (WASM_OP_F32_ABS):
DEF_OP_MATH(float32, F32, fabs);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_NEG):
{
int32 i32 = (int32)frame_lp[GET_OFFSET()];
addr_ret = GET_OFFSET();
int32 sign_bit = i32 & (1 << 31);
if (sign_bit)
frame_lp[addr_ret] = i32 & ~(1 << 31);
else
frame_lp[addr_ret] = (uint32)(i32 | (1 << 31));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F32_CEIL):
DEF_OP_MATH(float32, F32, ceil);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_FLOOR):
DEF_OP_MATH(float32, F32, floor);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_TRUNC):
DEF_OP_MATH(float32, F32, trunc);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_NEAREST):
DEF_OP_MATH(float32, F32, rint);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_SQRT):
DEF_OP_MATH(float32, F32, sqrt);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_ADD):
DEF_OP_NUMERIC(float32, float32, F32, +);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_SUB):
DEF_OP_NUMERIC(float32, float32, F32, -);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_MUL):
DEF_OP_NUMERIC(float32, float32, F32, *);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_DIV):
DEF_OP_NUMERIC(float32, float32, F32, /);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_MIN):
{
float32 a, b;
b = *(float32*)(frame_lp + GET_OFFSET());
a = *(float32*)(frame_lp + GET_OFFSET());
if (isnan(a))
*(float32*)(frame_lp + GET_OFFSET()) = a;
else if (isnan(b))
*(float32*)(frame_lp + GET_OFFSET()) = b;
else
*(float32*)(frame_lp + GET_OFFSET()) = wa_fmin(a, b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F32_MAX):
{
float32 a, b;
b = *(float32*)(frame_lp + GET_OFFSET());
a = *(float32*)(frame_lp + GET_OFFSET());
if (isnan(a))
*(float32*)(frame_lp + GET_OFFSET()) = a;
else if (isnan(b))
*(float32*)(frame_lp + GET_OFFSET()) = b;
else
*(float32*)(frame_lp + GET_OFFSET()) = wa_fmax(a, b);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F32_COPYSIGN):
{
float32 a, b;
b = *(float32*)(frame_lp + GET_OFFSET());
a = *(float32*)(frame_lp + GET_OFFSET());
*(float32*)(frame_lp + GET_OFFSET()) = (signbit(b) ? -fabs(a) : fabs(a));
HANDLE_OP_END ();
}
/* numberic instructions of f64 */
HANDLE_OP (WASM_OP_F64_ABS):
DEF_OP_MATH(float64, F64, fabs);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_NEG):
{
int64 i64 = *(int64*)(frame_lp + GET_OFFSET());
int64 sign_bit = i64 & (((int64)1) << 63);
if (sign_bit)
*(int64*)(frame_lp + GET_OFFSET()) = (uint64)i64 & ~(((uint64)1) << 63);
else
*(int64*)(frame_lp + GET_OFFSET()) = (uint64)i64 | (((uint64)1) << 63);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F64_CEIL):
DEF_OP_MATH(float64, F64, ceil);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_FLOOR):
DEF_OP_MATH(float64, F64, floor);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_TRUNC):
DEF_OP_MATH(float64, F64, trunc);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_NEAREST):
DEF_OP_MATH(float64, F64, rint);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_SQRT):
DEF_OP_MATH(float64, F64, sqrt);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_ADD):
DEF_OP_NUMERIC_64(float64, float64, F64, +);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_SUB):
DEF_OP_NUMERIC_64(float64, float64, F64, -);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_MUL):
DEF_OP_NUMERIC_64(float64, float64, F64, *);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_DIV):
DEF_OP_NUMERIC_64(float64, float64, F64, /);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_MIN):
{
float64 a, b;
b = POP_F64();
a = POP_F64();
if (isnan(a))
PUSH_F64(a);
else if (isnan(b))
PUSH_F64(b);
else
PUSH_F64(wa_fmin(a, b));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F64_MAX):
{
float64 a, b;
b = POP_F64();
a = POP_F64();
if (isnan(a))
PUSH_F64(a);
else if (isnan(b))
PUSH_F64(b);
else
PUSH_F64(wa_fmax(a, b));
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_F64_COPYSIGN):
{
float64 a, b;
b = POP_F64();
a = POP_F64();
PUSH_F64(signbit(b) ? -fabs(a) : fabs(a));
HANDLE_OP_END ();
}
/* conversions of i32 */
HANDLE_OP (WASM_OP_I32_WRAP_I64):
{
int32 value = (int32)(POP_I64() & 0xFFFFFFFFLL);
PUSH_I32(value);
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_TRUNC_S_F32):
/* We don't use INT32_MIN/INT32_MAX/UINT32_MIN/UINT32_MAX,
since float/double values of ieee754 cannot precisely represent
all int32/uint32/int64/uint64 values, e.g.:
UINT32_MAX is 4294967295, but (float32)4294967295 is 4294967296.0f,
but not 4294967295.0f. */
DEF_OP_TRUNC_F32(-2147483904.0f, 2147483648.0f, true, true);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_TRUNC_U_F32):
DEF_OP_TRUNC_F32(-1.0f, 4294967296.0f, true, false);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_TRUNC_S_F64):
DEF_OP_TRUNC_F64(-2147483649.0, 2147483648.0, true, true);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_TRUNC_U_F64):
DEF_OP_TRUNC_F64(-1.0, 4294967296.0, true, false);
HANDLE_OP_END ();
/* conversions of i64 */
HANDLE_OP (WASM_OP_I64_EXTEND_S_I32):
DEF_OP_CONVERT(int64, I64, int32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_EXTEND_U_I32):
DEF_OP_CONVERT(int64, I64, uint32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_TRUNC_S_F32):
DEF_OP_TRUNC_F32(-9223373136366403584.0f,
9223372036854775808.0f, false, true);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_TRUNC_U_F32):
DEF_OP_TRUNC_F32(-1.0f, 18446744073709551616.0f,
false, false);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_TRUNC_S_F64):
DEF_OP_TRUNC_F64(-9223372036854777856.0,
9223372036854775808.0, false, true);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_TRUNC_U_F64):
DEF_OP_TRUNC_F64(-1.0, 18446744073709551616.0,
false, false);
HANDLE_OP_END ();
/* conversions of f32 */
HANDLE_OP (WASM_OP_F32_CONVERT_S_I32):
DEF_OP_CONVERT(float32, F32, int32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_CONVERT_U_I32):
DEF_OP_CONVERT(float32, F32, uint32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_CONVERT_S_I64):
DEF_OP_CONVERT(float32, F32, int64, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_CONVERT_U_I64):
DEF_OP_CONVERT(float32, F32, uint64, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_DEMOTE_F64):
DEF_OP_CONVERT(float32, F32, float64, F64);
HANDLE_OP_END ();
/* conversions of f64 */
HANDLE_OP (WASM_OP_F64_CONVERT_S_I32):
DEF_OP_CONVERT(float64, F64, int32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_CONVERT_U_I32):
DEF_OP_CONVERT(float64, F64, uint32, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_CONVERT_S_I64):
DEF_OP_CONVERT(float64, F64, int64, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_CONVERT_U_I64):
DEF_OP_CONVERT(float64, F64, uint64, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_PROMOTE_F32):
DEF_OP_CONVERT(float64, F64, float32, F32);
HANDLE_OP_END ();
/* reinterpretations */
HANDLE_OP (WASM_OP_I32_REINTERPRET_F32):
DEF_OP_REINTERPRET(float32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_REINTERPRET_F64):
DEF_OP_REINTERPRET(float64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F32_REINTERPRET_I32):
DEF_OP_REINTERPRET(int32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_F64_REINTERPRET_I64):
DEF_OP_REINTERPRET(int64);
HANDLE_OP_END ();
HANDLE_OP (EXT_OP_COPY_STACK_TOP):
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
frame_lp[addr2] = frame_lp[addr1];
HANDLE_OP_END ();
HANDLE_OP (EXT_OP_COPY_STACK_TOP_I64):
addr1 = GET_OFFSET();
addr2 = GET_OFFSET();
*(uint64*)(frame_lp + addr2) = *(uint64*)(frame_lp + addr1);
HANDLE_OP_END ();
HANDLE_OP (EXT_OP_COPY_STACK_VALUES):
{
uint32 values_count, total_cell;
uint8 *cells;
int16 *src_offsets = NULL;
uint16 *dst_offsets = NULL;
/* read values_count */
values_count = *(uint32*)frame_ip;
frame_ip += sizeof(values_count);
/* read total cell num */
total_cell = *(uint32*)frame_ip;
frame_ip += sizeof(total_cell);
/* cells */
cells = (uint8 *)frame_ip;
frame_ip += values_count * sizeof(uint8);
/* src offsets */
src_offsets = (int16 *)frame_ip;
frame_ip += values_count * sizeof(int16);
/* dst offsets */
dst_offsets = (uint16*)frame_ip;
frame_ip += values_count * sizeof(uint16);
if (!copy_stack_values(module, frame_lp,
values_count, total_cell,
cells, src_offsets,
dst_offsets))
goto got_exception;
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_SET_LOCAL):
HANDLE_OP (WASM_OP_TEE_LOCAL):
{
GET_LOCAL_INDEX_TYPE_AND_OFFSET();
addr1 = GET_OFFSET();
if (local_type == VALUE_TYPE_I32
|| local_type == VALUE_TYPE_F32) {
*(int32*)(frame_lp + local_offset) = frame_lp[addr1];
}
else if (local_type == VALUE_TYPE_I64
|| local_type == VALUE_TYPE_F64) {
PUT_I64_TO_ADDR((uint32*)(frame_lp + local_offset),
GET_I64_FROM_ADDR(frame_lp + addr1));
}
else {
wasm_set_exception(module, "invalid local type");
goto got_exception;
}
HANDLE_OP_END ();
}
HANDLE_OP (WASM_OP_I32_EXTEND8_S):
DEF_OP_CONVERT(int32, I32, int8, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I32_EXTEND16_S):
DEF_OP_CONVERT(int32, I32, int16, I32);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_EXTEND8_S):
DEF_OP_CONVERT(int64, I64, int8, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_EXTEND16_S):
DEF_OP_CONVERT(int64, I64, int16, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_I64_EXTEND32_S):
DEF_OP_CONVERT(int64, I64, int32, I64);
HANDLE_OP_END ();
HANDLE_OP (WASM_OP_MISC_PREFIX):
{
GET_OPCODE();
switch (opcode)
{
case WASM_OP_I32_TRUNC_SAT_S_F32:
DEF_OP_TRUNC_SAT_F32(-2147483904.0f, 2147483648.0f,
true, true);
break;
case WASM_OP_I32_TRUNC_SAT_U_F32:
DEF_OP_TRUNC_SAT_F32(-1.0f, 4294967296.0f,
true, false);
break;
case WASM_OP_I32_TRUNC_SAT_S_F64:
DEF_OP_TRUNC_SAT_F64(-2147483649.0, 2147483648.0,
true, true);
break;
case WASM_OP_I32_TRUNC_SAT_U_F64:
DEF_OP_TRUNC_SAT_F64(-1.0, 4294967296.0,
true, false);
break;
case WASM_OP_I64_TRUNC_SAT_S_F32:
DEF_OP_TRUNC_SAT_F32(-9223373136366403584.0f, 9223372036854775808.0f,
false, true);
break;
case WASM_OP_I64_TRUNC_SAT_U_F32:
DEF_OP_TRUNC_SAT_F32(-1.0f, 18446744073709551616.0f,
false, false);
break;
case WASM_OP_I64_TRUNC_SAT_S_F64:
DEF_OP_TRUNC_SAT_F64(-9223372036854777856.0, 9223372036854775808.0,
false, true);
break;
case WASM_OP_I64_TRUNC_SAT_U_F64:
DEF_OP_TRUNC_SAT_F64(-1.0, 18446744073709551616.0,
false, false);
break;
#if WASM_ENABLE_BULK_MEMORY != 0
case WASM_OP_MEMORY_INIT:
{
uint32 addr, segment;
uint64 bytes, offset, seg_len;
uint8* data;
segment = read_uint32(frame_ip);
bytes = (uint64)POP_I32();
offset = (uint64)POP_I32();
addr = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(addr, bytes, maddr);
seg_len = (uint64)module->module->data_segments[segment]->data_length;
data = module->module->data_segments[segment]->data;
if (offset + bytes > seg_len)
goto out_of_bounds;
bh_memcpy_s(maddr, linear_mem_size - addr,
data + offset, bytes);
break;
}
case WASM_OP_DATA_DROP:
{
uint32 segment;
segment = read_uint32(frame_ip);
module->module->data_segments[segment]->data_length = 0;
break;
}
case WASM_OP_MEMORY_COPY:
{
uint32 dst, src, len;
uint8 *mdst, *msrc;
len = POP_I32();
src = POP_I32();
dst = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(src, len, msrc);
CHECK_BULK_MEMORY_OVERFLOW(dst, len, mdst);
/* allowing the destination and source to overlap */
bh_memmove_s(mdst, linear_mem_size - dst,
msrc, len);
break;
}
case WASM_OP_MEMORY_FILL:
{
uint32 dst, len;
uint8 val, *mdst;
len = POP_I32();
val = POP_I32();
dst = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(dst, len, mdst);
memset(mdst, val, len);
break;
}
#endif /* WASM_ENABLE_BULK_MEMORY */
default:
wasm_set_exception(module, "unsupported opcode");
goto got_exception;
break;
}
HANDLE_OP_END ();
}
#if WASM_ENABLE_SHARED_MEMORY != 0
HANDLE_OP (WASM_OP_ATOMIC_PREFIX):
{
uint32 offset, addr;
GET_OPCODE();
offset = read_uint32(frame_ip);
switch (opcode) {
case WASM_OP_ATOMIC_NOTIFY:
{
uint32 count, ret;
count = POP_I32();
addr = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
ret = wasm_runtime_atomic_notify((WASMModuleInstanceCommon*)module,
maddr, count);
bh_assert((int32)ret >= 0);
PUSH_I32(ret);
break;
}
case WASM_OP_ATOMIC_WAIT32:
{
uint64 timeout;
uint32 expect, addr, ret;
timeout = POP_I64();
expect = POP_I32();
addr = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
ret = wasm_runtime_atomic_wait((WASMModuleInstanceCommon*)module, maddr,
(uint64)expect, timeout, false);
if (ret == (uint32)-1)
goto got_exception;
PUSH_I32(ret);
break;
}
case WASM_OP_ATOMIC_WAIT64:
{
uint64 timeout, expect;
uint32 ret;
timeout = POP_I64();
expect = POP_I64();
addr = POP_I32();
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 8, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(8);
ret = wasm_runtime_atomic_wait((WASMModuleInstanceCommon*)module,
maddr, expect, timeout, true);
if (ret == (uint32)-1)
goto got_exception;
PUSH_I32(ret);
break;
}
case WASM_OP_ATOMIC_I32_LOAD:
case WASM_OP_ATOMIC_I32_LOAD8_U:
case WASM_OP_ATOMIC_I32_LOAD16_U:
{
uint32 readv;
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_I32_LOAD8_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
readv = (uint32)(*(uint8*)maddr);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_I32_LOAD16_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
readv = (uint32)LOAD_U16(maddr);
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
readv = LOAD_I32(maddr);
os_mutex_unlock(&memory->mem_lock);
}
PUSH_I32(readv);
break;
}
case WASM_OP_ATOMIC_I64_LOAD:
case WASM_OP_ATOMIC_I64_LOAD8_U:
case WASM_OP_ATOMIC_I64_LOAD16_U:
case WASM_OP_ATOMIC_I64_LOAD32_U:
{
uint64 readv;
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_I64_LOAD8_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)(*(uint8*)maddr);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_I64_LOAD16_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)LOAD_U16(maddr);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_I64_LOAD32_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)LOAD_U32(maddr);
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 8, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(8);
os_mutex_lock(&memory->mem_lock);
readv = LOAD_I64(maddr);
os_mutex_unlock(&memory->mem_lock);
}
PUSH_I64(readv);
break;
}
case WASM_OP_ATOMIC_I32_STORE:
case WASM_OP_ATOMIC_I32_STORE8:
case WASM_OP_ATOMIC_I32_STORE16:
{
uint32 sval;
sval = (uint32)POP_I32();
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_I32_STORE8) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
*(uint8*)maddr = (uint8)sval;
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_I32_STORE16) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
STORE_U16(maddr, (uint16)sval);
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
STORE_U32(maddr, sval);
os_mutex_unlock(&memory->mem_lock);
}
break;
}
case WASM_OP_ATOMIC_I64_STORE:
case WASM_OP_ATOMIC_I64_STORE8:
case WASM_OP_ATOMIC_I64_STORE16:
case WASM_OP_ATOMIC_I64_STORE32:
{
uint64 sval;
sval = (uint64)POP_I64();
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_I64_STORE8) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
*(uint8*)maddr = (uint8)sval;
os_mutex_unlock(&memory->mem_lock);
}
else if(opcode == WASM_OP_ATOMIC_I64_STORE16) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
STORE_U16(maddr, (uint16)sval);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_I64_STORE32) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
STORE_U32(maddr, (uint32)sval);
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 8, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(8);
os_mutex_lock(&memory->mem_lock);
STORE_I64(maddr, sval);
os_mutex_unlock(&memory->mem_lock);
}
break;
}
case WASM_OP_ATOMIC_RMW_I32_CMPXCHG:
case WASM_OP_ATOMIC_RMW_I32_CMPXCHG8_U:
case WASM_OP_ATOMIC_RMW_I32_CMPXCHG16_U:
{
uint32 readv, sval, expect;
sval = POP_I32();
expect = POP_I32();
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_RMW_I32_CMPXCHG8_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
readv = (uint32)(*(uint8*)maddr);
if (readv == expect)
*(uint8*)maddr = (uint8)(sval);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_RMW_I32_CMPXCHG16_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
readv = (uint32)LOAD_U16(maddr);
if (readv == expect)
STORE_U16(maddr, (uint16)(sval));
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
readv = LOAD_I32(maddr);
if (readv == expect)
STORE_U32(maddr, sval);
os_mutex_unlock(&memory->mem_lock);
}
PUSH_I32(readv);
break;
}
case WASM_OP_ATOMIC_RMW_I64_CMPXCHG:
case WASM_OP_ATOMIC_RMW_I64_CMPXCHG8_U:
case WASM_OP_ATOMIC_RMW_I64_CMPXCHG16_U:
case WASM_OP_ATOMIC_RMW_I64_CMPXCHG32_U:
{
uint64 readv, sval, expect;
sval = (uint64)POP_I64();
expect = (uint64)POP_I64();
addr = POP_I32();
if (opcode == WASM_OP_ATOMIC_RMW_I64_CMPXCHG8_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 1, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(1);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)(*(uint8*)maddr);
if (readv == expect)
*(uint8*)maddr = (uint8)(sval);
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_RMW_I64_CMPXCHG16_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 2, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(2);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)LOAD_U16(maddr);
if (readv == expect)
STORE_U16(maddr, (uint16)(sval));
os_mutex_unlock(&memory->mem_lock);
}
else if (opcode == WASM_OP_ATOMIC_RMW_I64_CMPXCHG32_U) {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 4, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(4);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)LOAD_U32(maddr);
if (readv == expect)
STORE_U32(maddr, (uint32)(sval));
os_mutex_unlock(&memory->mem_lock);
}
else {
CHECK_BULK_MEMORY_OVERFLOW(addr + offset, 8, maddr);
CHECK_ATOMIC_MEMORY_ACCESS(8);
os_mutex_lock(&memory->mem_lock);
readv = (uint64)LOAD_I64(maddr);
if (readv == expect) {
STORE_I64(maddr, sval);
}
os_mutex_unlock(&memory->mem_lock);
}
PUSH_I64(readv);
break;
}
DEF_ATOMIC_RMW_OPCODE(ADD, +);
DEF_ATOMIC_RMW_OPCODE(SUB, -);
DEF_ATOMIC_RMW_OPCODE(AND, &);
DEF_ATOMIC_RMW_OPCODE(OR, |);
DEF_ATOMIC_RMW_OPCODE(XOR, ^);
/* xchg, ignore the read value, and store the given value:
readv * 0 + sval */
DEF_ATOMIC_RMW_OPCODE(XCHG, *0 +);
}
HANDLE_OP_END ();
}
#endif
HANDLE_OP (WASM_OP_IMPDEP):
frame = prev_frame;
frame_ip = frame->ip;
goto call_func_from_entry;
HANDLE_OP (WASM_OP_CALL):
#if WASM_ENABLE_THREAD_MGR != 0
CHECK_SUSPEND_FLAGS();
#endif
fidx = read_uint32(frame_ip);
#if WASM_ENABLE_MULTI_MODULE != 0
if (fidx >= module->function_count) {
wasm_set_exception(module, "unknown function");
goto got_exception;
}
#endif
cur_func = module->functions + fidx;
goto call_func_from_interp;
#if WASM_ENABLE_LABELS_AS_VALUES == 0
default:
wasm_set_exception(module, "unsupported opcode");
goto got_exception;
}
#endif
#if WASM_ENABLE_LABELS_AS_VALUES != 0
HANDLE_OP (WASM_OP_UNUSED_0x06):
HANDLE_OP (WASM_OP_UNUSED_0x07):
HANDLE_OP (WASM_OP_UNUSED_0x08):
HANDLE_OP (WASM_OP_UNUSED_0x09):
HANDLE_OP (WASM_OP_UNUSED_0x0a):
HANDLE_OP (WASM_OP_UNUSED_0x12):
HANDLE_OP (WASM_OP_UNUSED_0x13):
HANDLE_OP (WASM_OP_UNUSED_0x14):
HANDLE_OP (WASM_OP_UNUSED_0x15):
HANDLE_OP (WASM_OP_UNUSED_0x16):
HANDLE_OP (WASM_OP_UNUSED_0x17):
HANDLE_OP (WASM_OP_UNUSED_0x18):
HANDLE_OP (WASM_OP_UNUSED_0x19):
HANDLE_OP (WASM_OP_UNUSED_0x1c):
HANDLE_OP (WASM_OP_UNUSED_0x1d):
HANDLE_OP (WASM_OP_UNUSED_0x1e):
HANDLE_OP (WASM_OP_UNUSED_0x1f):
/* optimized op code */
HANDLE_OP (WASM_OP_F32_STORE):
HANDLE_OP (WASM_OP_F64_STORE):
HANDLE_OP (WASM_OP_F32_LOAD):
HANDLE_OP (WASM_OP_F64_LOAD):
HANDLE_OP (EXT_OP_GET_LOCAL_FAST):
HANDLE_OP (WASM_OP_GET_LOCAL):
HANDLE_OP (WASM_OP_F64_CONST):
HANDLE_OP (WASM_OP_I64_CONST):
HANDLE_OP (WASM_OP_F32_CONST):
HANDLE_OP (WASM_OP_I32_CONST):
HANDLE_OP (WASM_OP_DROP):
HANDLE_OP (WASM_OP_DROP_64):
HANDLE_OP (WASM_OP_BLOCK):
HANDLE_OP (WASM_OP_LOOP):
HANDLE_OP (WASM_OP_END):
HANDLE_OP (WASM_OP_NOP):
HANDLE_OP (EXT_OP_BLOCK):
HANDLE_OP (EXT_OP_LOOP):
HANDLE_OP (EXT_OP_IF):
{
wasm_set_exception(module, "unsupported opcode");
goto got_exception;
}
#endif
#if WASM_ENABLE_LABELS_AS_VALUES == 0
continue;
#else
FETCH_OPCODE_AND_DISPATCH ();
#endif
call_func_from_interp:
/* Only do the copy when it's called from interpreter. */
{
WASMInterpFrame *outs_area = wasm_exec_env_wasm_stack_top(exec_env);
outs_area->lp = outs_area->operand + cur_func->const_cell_num;
for (int i = 0; i < cur_func->param_count; i++) {
if (cur_func->param_types[i] == VALUE_TYPE_I64
|| cur_func->param_types[i] == VALUE_TYPE_F64) {
*(int64*)(outs_area->lp) =
GET_OPERAND(int64, (2 * (cur_func->param_count - i - 1)));
outs_area->lp += 2;
} else {
*(outs_area->lp) = GET_OPERAND(int32, (2 * (cur_func->param_count - i - 1)));
outs_area->lp ++;
}
}
frame_ip += cur_func->param_count * sizeof(int16);
if (cur_func->ret_cell_num != 0) {
/* Get the first return value's offset. Since loader emit all return
* values' offset so we must skip remain return values' offsets.
*/
WASMType *func_type;
if (cur_func->is_import_func
#if WASM_ENABLE_MULTI_MODULE != 0
&& !cur_func->import_func_inst
#endif
)
func_type = cur_func->u.func_import->func_type;
else
func_type = cur_func->u.func->func_type;
frame->ret_offset = GET_OFFSET();
frame_ip += 2 * (func_type->result_count - 1);
}
SYNC_ALL_TO_FRAME();
prev_frame = frame;
}
call_func_from_entry:
{
if (cur_func->is_import_func) {
#if WASM_ENABLE_MULTI_MODULE != 0
if (cur_func->import_func_inst) {
wasm_interp_call_func_import(module, exec_env, cur_func,
prev_frame);
}
else
#endif
{
wasm_interp_call_func_native(module, exec_env, cur_func,
prev_frame);
}
prev_frame = frame->prev_frame;
cur_func = frame->function;
UPDATE_ALL_FROM_FRAME();
memory = module->default_memory;
if (wasm_get_exception(module))
goto got_exception;
}
else {
WASMFunction *cur_wasm_func = cur_func->u.func;
all_cell_num = (uint64)cur_func->param_cell_num
+ (uint64)cur_func->local_cell_num
+ (uint64)cur_func->const_cell_num
+ (uint64)cur_wasm_func->max_stack_cell_num;
if (all_cell_num >= UINT32_MAX) {
wasm_set_exception(module, "stack overflow");
goto got_exception;
}
frame_size = wasm_interp_interp_frame_size((uint32)all_cell_num);
if (!(frame = ALLOC_FRAME(exec_env, frame_size, prev_frame))) {
frame = prev_frame;
goto got_exception;
}
/* Initialize the interpreter context. */
frame->function = cur_func;
frame_ip = wasm_get_func_code(cur_func);
frame_ip_end = wasm_get_func_code_end(cur_func);
frame_lp = frame->lp = frame->operand + cur_wasm_func->const_cell_num;
/* Initialize the consts */
bh_memcpy_s(frame->operand, all_cell_num * 4,
cur_wasm_func->consts, cur_wasm_func->const_cell_num * 4);
/* Initialize the local varialbes */
memset(frame_lp + cur_func->param_cell_num, 0,
(uint32)(cur_func->local_cell_num * 4));
wasm_exec_env_set_cur_frame(exec_env, (WASMRuntimeFrame*)frame);
}
HANDLE_OP_END ();
}
return_func:
{
FREE_FRAME(exec_env, frame);
wasm_exec_env_set_cur_frame(exec_env, (WASMRuntimeFrame*)prev_frame);
if (!prev_frame->ip)
/* Called from native. */
return;
RECOVER_CONTEXT(prev_frame);
HANDLE_OP_END ();
}
(void)frame_ip_end;
#if WASM_ENABLE_SHARED_MEMORY != 0
unaligned_atomic:
wasm_set_exception(module, "unaligned atomic");
goto got_exception;
#endif
out_of_bounds:
wasm_set_exception(module, "out of bounds memory access");
got_exception:
return;
#if WASM_ENABLE_LABELS_AS_VALUES == 0
}
#else
FETCH_OPCODE_AND_DISPATCH ();
#endif
}
#if WASM_ENABLE_FAST_INTERP != 0
void **
wasm_interp_get_handle_table()
{
WASMModuleInstance module;
memset(&module, 0, sizeof(WASMModuleInstance));
wasm_interp_call_func_bytecode(&module, NULL, NULL, NULL);
return global_handle_table;
}
#endif
void
wasm_interp_call_wasm(WASMModuleInstance *module_inst,
WASMExecEnv *exec_env,
WASMFunctionInstance *function,
uint32 argc, uint32 argv[])
{
WASMRuntimeFrame *prev_frame = wasm_exec_env_get_cur_frame(exec_env);
WASMInterpFrame *frame, *outs_area;
/* Allocate sufficient cells for all kinds of return values. */
unsigned all_cell_num = function->ret_cell_num > 2 ?
function->ret_cell_num : 2, i;
/* This frame won't be used by JITed code, so only allocate interp
frame here. */
unsigned frame_size = wasm_interp_interp_frame_size(all_cell_num);
if (argc != function->param_cell_num) {
char buf[128];
snprintf(buf, sizeof(buf),
"invalid argument count %d, expected %d",
argc, function->param_cell_num);
wasm_set_exception(module_inst, buf);
return;
}
if ((uint8*)&prev_frame < exec_env->native_stack_boundary) {
wasm_set_exception((WASMModuleInstance*)exec_env->module_inst,
"native stack overflow");
return;
}
if (!(frame = ALLOC_FRAME(exec_env, frame_size, (WASMInterpFrame*)prev_frame)))
return;
outs_area = wasm_exec_env_wasm_stack_top(exec_env);
frame->function = NULL;
frame->ip = NULL;
/* There is no local variable. */
frame->lp = frame->operand + 0;
frame->ret_offset = 0;
if (argc > 0)
word_copy(outs_area->operand + function->const_cell_num, argv, argc);
wasm_exec_env_set_cur_frame(exec_env, frame);
if (function->is_import_func) {
#if WASM_ENABLE_MULTI_MODULE != 0
if (function->import_module_inst) {
LOG_DEBUG("it is a function of a sub module");
wasm_interp_call_func_import(module_inst, exec_env,
function, frame);
}
else
#endif
{
LOG_DEBUG("it is an native function");
wasm_interp_call_func_native(module_inst, exec_env,
function, frame);
}
}
else {
wasm_interp_call_func_bytecode(module_inst, exec_env, function, frame);
}
/* Output the return value to the caller */
if (!wasm_get_exception(module_inst)) {
for (i = 0; i < function->ret_cell_num; i++)
argv[i] = *(frame->lp + i);
}
wasm_exec_env_set_cur_frame(exec_env, prev_frame);
FREE_FRAME(exec_env, frame);
#if WASM_ENABLE_OPCODE_COUNTER != 0
wasm_interp_dump_op_count();
#endif
}
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