wasm-micro-runtime/core/iwasm/common/wasm_application.c
Wenyong Huang a23fa9f86c
Implement memory64 for classic interpreter (#3266)
Adding a new cmake flag (cache variable) `WAMR_BUILD_MEMORY64` to enable
the memory64 feature, it can only be enabled on the 64-bit platform/target and
can only use software boundary check. And when it is enabled, it can support both
i32 and i64 linear memory types. The main modifications are:

- wasm loader & mini-loader: loading and bytecode validating process 
- wasm runtime: memory instantiating process
- classic-interpreter: wasm code executing process
- Support memory64 memory in related runtime APIs
- Modify main function type check when it's memory64 wasm file
- Modify `wasm_runtime_invoke_native` and `wasm_runtime_invoke_native_raw` to
  handle registered native function pointer argument when memory64 is enabled
- memory64 classic-interpreter spec test in `test_wamr.sh` and in CI

Currently, it supports memory64 memory wasm file that uses core spec
(including bulk memory proposal) opcodes and threads opcodes.

ps.
https://github.com/bytecodealliance/wasm-micro-runtime/issues/3091
https://github.com/bytecodealliance/wasm-micro-runtime/pull/3240
https://github.com/bytecodealliance/wasm-micro-runtime/pull/3260
2024-04-02 15:22:07 +08:00

912 lines
32 KiB
C

/*
* Copyright (C) 2019 Intel Corporation. All rights reserved.
* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
*/
#include "bh_platform.h"
#if WASM_ENABLE_INTERP != 0
#include "../interpreter/wasm_runtime.h"
#endif
#if WASM_ENABLE_AOT != 0
#include "../aot/aot_runtime.h"
#endif
#if WASM_ENABLE_THREAD_MGR != 0
#include "../libraries/thread-mgr/thread_manager.h"
#endif
#if WASM_ENABLE_GC != 0
#include "gc/gc_object.h"
#if WASM_ENABLE_STRINGREF != 0
#include "string_object.h"
#endif
#if WASM_ENABLE_GC_PERF_PROFILING != 0
#include "../../shared/mem-alloc/mem_alloc.h"
#endif
#endif
static void
set_error_buf(char *error_buf, uint32 error_buf_size, const char *string)
{
if (error_buf != NULL)
snprintf(error_buf, error_buf_size, "%s", string);
}
static void *
runtime_malloc(uint64 size, WASMModuleInstanceCommon *module_inst,
char *error_buf, uint32 error_buf_size)
{
void *mem;
if (size >= UINT32_MAX || !(mem = wasm_runtime_malloc((uint32)size))) {
if (module_inst != NULL) {
wasm_runtime_set_exception(module_inst, "allocate memory failed");
}
else if (error_buf != NULL) {
set_error_buf(error_buf, error_buf_size, "allocate memory failed");
}
return NULL;
}
memset(mem, 0, (uint32)size);
return mem;
}
static union {
int a;
char b;
} __ue = { .a = 1 };
#define is_little_endian() (__ue.b == 1) /* NOLINT */
/**
* Implementation of wasm_application_execute_main()
*/
static bool
check_main_func_type(const WASMFuncType *type, bool is_memory64)
{
if (!(type->param_count == 0 || type->param_count == 2)
|| type->result_count > 1) {
LOG_ERROR(
"WASM execute application failed: invalid main function type.\n");
return false;
}
if (type->param_count == 2
&& !(type->types[0] == VALUE_TYPE_I32
&& type->types[1]
== (is_memory64 ? VALUE_TYPE_I64 : VALUE_TYPE_I32))) {
LOG_ERROR(
"WASM execute application failed: invalid main function type.\n");
return false;
}
if (type->result_count
&& type->types[type->param_count] != VALUE_TYPE_I32) {
LOG_ERROR(
"WASM execute application failed: invalid main function type.\n");
return false;
}
return true;
}
static bool
execute_main(WASMModuleInstanceCommon *module_inst, int32 argc, char *argv[])
{
WASMFunctionInstanceCommon *func;
WASMFuncType *func_type = NULL;
WASMExecEnv *exec_env = NULL;
uint32 argc1 = 0, argv1[3] = { 0 };
uint32 total_argv_size = 0;
uint64 total_size;
uint64 argv_buf_offset = 0;
int32 i;
char *argv_buf, *p, *p_end;
uint32 *argv_offsets, module_type;
bool ret, is_import_func = true, is_memory64 = false;
#if WASM_ENABLE_MEMORY64 != 0
WASMModuleInstance *wasm_module_inst = (WASMModuleInstance *)module_inst;
is_memory64 = wasm_module_inst->memories[0]->is_memory64;
#endif
exec_env = wasm_runtime_get_exec_env_singleton(module_inst);
if (!exec_env) {
wasm_runtime_set_exception(module_inst,
"create singleton exec_env failed");
return false;
}
#if WASM_ENABLE_LIBC_WASI != 0
/* In wasi mode, we should call the function named "_start"
which initializes the wasi envrionment and then calls
the actual main function. Directly calling main function
may cause exception thrown. */
if ((func = wasm_runtime_lookup_wasi_start_function(module_inst))) {
const char *wasi_proc_exit_exception = "wasi proc exit";
ret = wasm_runtime_call_wasm(exec_env, func, 0, NULL);
#if WASM_ENABLE_THREAD_MGR != 0
if (ret) {
/* On a successful return from the `_start` function,
we terminate other threads by mimicing wasi:proc_exit(0).
Note:
- A return from the `main` function is an equivalent of
exit(). (C standard)
- When exit code is 0, wasi-libc's `_start` function just
returns w/o calling `proc_exit`.
- A process termination should terminate threads in
the process. */
wasm_runtime_set_exception(module_inst, wasi_proc_exit_exception);
/* exit_code is zero-initialized */
ret = false;
}
#endif
/* report wasm proc exit as a success */
WASMModuleInstance *inst = (WASMModuleInstance *)module_inst;
if (!ret && strstr(inst->cur_exception, wasi_proc_exit_exception)) {
inst->cur_exception[0] = 0;
ret = true;
}
return ret;
}
#endif /* end of WASM_ENABLE_LIBC_WASI */
if (!(func = wasm_runtime_lookup_function(module_inst, "main"))
&& !(func =
wasm_runtime_lookup_function(module_inst, "__main_argc_argv"))
&& !(func = wasm_runtime_lookup_function(module_inst, "_main"))) {
#if WASM_ENABLE_LIBC_WASI != 0
wasm_runtime_set_exception(
module_inst, "lookup the entry point symbol (like _start, main, "
"_main, __main_argc_argv) failed");
#else
wasm_runtime_set_exception(module_inst,
"lookup the entry point symbol (like main, "
"_main, __main_argc_argv) failed");
#endif
return false;
}
#if WASM_ENABLE_INTERP != 0
if (module_inst->module_type == Wasm_Module_Bytecode) {
is_import_func = ((WASMFunctionInstance *)func)->is_import_func;
}
#endif
#if WASM_ENABLE_AOT != 0
if (module_inst->module_type == Wasm_Module_AoT) {
is_import_func = ((AOTFunctionInstance *)func)->is_import_func;
}
#endif
if (is_import_func) {
wasm_runtime_set_exception(module_inst, "lookup main function failed");
return false;
}
module_type = module_inst->module_type;
func_type = wasm_runtime_get_function_type(func, module_type);
if (!func_type) {
LOG_ERROR("invalid module instance type");
return false;
}
if (!check_main_func_type(func_type, is_memory64)) {
wasm_runtime_set_exception(module_inst,
"invalid function type of main function");
return false;
}
if (func_type->param_count) {
for (i = 0; i < argc; i++)
total_argv_size += (uint32)(strlen(argv[i]) + 1);
total_argv_size = align_uint(total_argv_size, 4);
total_size = (uint64)total_argv_size + sizeof(int32) * (uint64)argc;
if (total_size >= UINT32_MAX
|| !(argv_buf_offset = wasm_runtime_module_malloc(
module_inst, total_size, (void **)&argv_buf))) {
wasm_runtime_set_exception(module_inst, "allocate memory failed");
return false;
}
p = argv_buf;
argv_offsets = (uint32 *)(p + total_argv_size);
p_end = p + total_size;
for (i = 0; i < argc; i++) {
bh_memcpy_s(p, (uint32)(p_end - p), argv[i],
(uint32)(strlen(argv[i]) + 1));
argv_offsets[i] = (uint32)argv_buf_offset + (uint32)(p - argv_buf);
p += strlen(argv[i]) + 1;
}
argv1[0] = (uint32)argc;
#if WASM_ENABLE_MEMORY64 != 0
if (is_memory64) {
argc1 = 3;
uint64 app_addr =
wasm_runtime_addr_native_to_app(module_inst, argv_offsets);
PUT_I64_TO_ADDR(&argv[1], app_addr);
}
else
#endif
{
argc1 = 2;
argv1[1] = (uint32)wasm_runtime_addr_native_to_app(module_inst,
argv_offsets);
}
}
ret = wasm_runtime_call_wasm(exec_env, func, argc1, argv1);
if (ret && func_type->result_count > 0 && argc > 0 && argv)
/* copy the return value */
*(int *)argv = (int)argv1[0];
if (argv_buf_offset)
wasm_runtime_module_free(module_inst, argv_buf_offset);
return ret;
}
bool
wasm_application_execute_main(WASMModuleInstanceCommon *module_inst, int32 argc,
char *argv[])
{
bool ret;
#if (WASM_ENABLE_MEMORY_PROFILING != 0)
WASMExecEnv *exec_env;
#endif
ret = execute_main(module_inst, argc, argv);
#if WASM_ENABLE_MEMORY_PROFILING != 0
exec_env = wasm_runtime_get_exec_env_singleton(module_inst);
if (exec_env) {
wasm_runtime_dump_mem_consumption(exec_env);
}
#endif
#if WASM_ENABLE_GC_PERF_PROFILING != 0
void *handle = wasm_runtime_get_gc_heap_handle(module_inst);
mem_allocator_dump_perf_profiling(handle);
#endif
#if WASM_ENABLE_PERF_PROFILING != 0
wasm_runtime_dump_perf_profiling(module_inst);
#endif
if (ret)
ret = wasm_runtime_get_exception(module_inst) == NULL;
return ret;
}
/**
* Implementation of wasm_application_execute_func()
*/
union ieee754_float {
float f;
/* This is the IEEE 754 single-precision format. */
union {
struct {
unsigned int negative : 1;
unsigned int exponent : 8;
unsigned int mantissa : 23;
} ieee_big_endian;
struct {
unsigned int mantissa : 23;
unsigned int exponent : 8;
unsigned int negative : 1;
} ieee_little_endian;
} ieee;
};
union ieee754_double {
double d;
/* This is the IEEE 754 double-precision format. */
union {
struct {
unsigned int negative : 1;
unsigned int exponent : 11;
/* Together these comprise the mantissa. */
unsigned int mantissa0 : 20;
unsigned int mantissa1 : 32;
} ieee_big_endian;
struct {
/* Together these comprise the mantissa. */
unsigned int mantissa1 : 32;
unsigned int mantissa0 : 20;
unsigned int exponent : 11;
unsigned int negative : 1;
} ieee_little_endian;
} ieee;
};
static bool
execute_func(WASMModuleInstanceCommon *module_inst, const char *name,
int32 argc, char *argv[])
{
WASMFunctionInstanceCommon *target_func;
WASMFuncType *type = NULL;
WASMExecEnv *exec_env = NULL;
#if WASM_ENABLE_GC != 0
WASMRefTypeMap *ref_type_map;
WASMLocalObjectRef *local_ref;
uint32 num_local_ref_pushed = 0;
#endif
uint32 argc1, *argv1 = NULL, cell_num = 0, j, k = 0;
#if WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0
uint32 param_size_in_double_world = 0, result_size_in_double_world = 0;
#endif
int32 i, p, module_type;
uint64 total_size;
char buf[128];
bh_assert(argc >= 0);
LOG_DEBUG("call a function \"%s\" with %d arguments", name, argc);
if (!(target_func = wasm_runtime_lookup_function(module_inst, name))) {
snprintf(buf, sizeof(buf), "lookup function %s failed", name);
wasm_runtime_set_exception(module_inst, buf);
goto fail;
}
module_type = module_inst->module_type;
type = wasm_runtime_get_function_type(target_func, module_type);
if (!type) {
LOG_ERROR("invalid module instance type");
return false;
}
if (type->param_count != (uint32)argc) {
wasm_runtime_set_exception(module_inst, "invalid input argument count");
goto fail;
}
exec_env = wasm_runtime_get_exec_env_singleton(module_inst);
if (!exec_env) {
wasm_runtime_set_exception(module_inst,
"create singleton exec_env failed");
goto fail;
}
#if WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0
for (i = 0; i < type->param_count; i++) {
param_size_in_double_world +=
wasm_value_type_cell_num_outside(type->types[i]);
}
for (i = 0; i < type->result_count; i++) {
result_size_in_double_world += wasm_value_type_cell_num_outside(
type->types[type->param_count + i]);
}
argc1 = param_size_in_double_world;
cell_num = (param_size_in_double_world >= result_size_in_double_world)
? param_size_in_double_world
: result_size_in_double_world;
#else
argc1 = type->param_cell_num;
cell_num = (argc1 > type->ret_cell_num) ? argc1 : type->ret_cell_num;
#endif
total_size = sizeof(uint32) * (uint64)(cell_num > 2 ? cell_num : 2);
if ((!(argv1 = runtime_malloc((uint32)total_size, module_inst, NULL, 0)))) {
goto fail;
}
#if WASM_ENABLE_GC != 0
ref_type_map = type->ref_type_maps;
#endif
/* Parse arguments */
for (i = 0, p = 0; i < argc; i++) {
char *endptr = NULL;
bh_assert(argv[i] != NULL);
if (argv[i][0] == '\0') {
snprintf(buf, sizeof(buf), "invalid input argument %" PRId32, i);
wasm_runtime_set_exception(module_inst, buf);
goto fail;
}
switch (type->types[i]) {
case VALUE_TYPE_I32:
argv1[p++] = (uint32)strtoul(argv[i], &endptr, 0);
break;
case VALUE_TYPE_I64:
{
union {
uint64 val;
uint32 parts[2];
} u;
u.val = strtoull(argv[i], &endptr, 0);
argv1[p++] = u.parts[0];
argv1[p++] = u.parts[1];
break;
}
case VALUE_TYPE_F32:
{
float32 f32 = strtof(argv[i], &endptr);
if (isnan(f32)) {
#ifdef _MSC_VER
/*
* Spec tests require the binary representation of NaN to be
* 0x7fc00000 for float and 0x7ff8000000000000 for float;
* however, in MSVC compiler, strtof doesn't return this
* exact value, causing some of the spec test failures. We
* use the value returned by nan/nanf as it is the one
* expected by spec tests.
*
*/
f32 = nanf("");
#endif
if (argv[i][0] == '-') {
union ieee754_float u;
u.f = f32;
if (is_little_endian())
u.ieee.ieee_little_endian.negative = 1;
else
u.ieee.ieee_big_endian.negative = 1;
bh_memcpy_s(&f32, sizeof(float), &u.f, sizeof(float));
}
if (endptr[0] == ':') {
uint32 sig;
union ieee754_float u;
sig = (uint32)strtoul(endptr + 1, &endptr, 0);
u.f = f32;
if (is_little_endian())
u.ieee.ieee_little_endian.mantissa = sig;
else
u.ieee.ieee_big_endian.mantissa = sig;
bh_memcpy_s(&f32, sizeof(float), &u.f, sizeof(float));
}
}
bh_memcpy_s(&argv1[p], (uint32)total_size - p, &f32,
(uint32)sizeof(float));
p++;
break;
}
case VALUE_TYPE_F64:
{
union {
float64 val;
uint32 parts[2];
} u;
u.val = strtod(argv[i], &endptr);
if (isnan(u.val)) {
#ifdef _MSC_VER
u.val = nan("");
#endif
if (argv[i][0] == '-') {
union ieee754_double ud;
ud.d = u.val;
if (is_little_endian())
ud.ieee.ieee_little_endian.negative = 1;
else
ud.ieee.ieee_big_endian.negative = 1;
bh_memcpy_s(&u.val, sizeof(double), &ud.d,
sizeof(double));
}
if (endptr[0] == ':') {
uint64 sig;
union ieee754_double ud;
sig = strtoull(endptr + 1, &endptr, 0);
ud.d = u.val;
if (is_little_endian()) {
ud.ieee.ieee_little_endian.mantissa0 = sig >> 32;
ud.ieee.ieee_little_endian.mantissa1 = (uint32)sig;
}
else {
ud.ieee.ieee_big_endian.mantissa0 = sig >> 32;
ud.ieee.ieee_big_endian.mantissa1 = (uint32)sig;
}
bh_memcpy_s(&u.val, sizeof(double), &ud.d,
sizeof(double));
}
}
argv1[p++] = u.parts[0];
argv1[p++] = u.parts[1];
break;
}
#if WASM_ENABLE_SIMD != 0
case VALUE_TYPE_V128:
{
/* it likes 0x123\0x234 or 123\234 */
/* retrive first i64 */
*(uint64 *)(argv1 + p) = strtoull(argv[i], &endptr, 0);
/* skip \ */
endptr++;
/* retrive second i64 */
*(uint64 *)(argv1 + p + 2) = strtoull(endptr, &endptr, 0);
p += 4;
break;
}
#endif /* WASM_ENABLE_SIMD != 0 */
#if WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0
case VALUE_TYPE_FUNCREF:
#if UINTPTR_MAX == UINT32_MAX
case VALUE_TYPE_EXTERNREF:
#endif
{
if (strncasecmp(argv[i], "null", 4) == 0) {
argv1[p++] = (uint32)-1;
}
else {
argv1[p++] = (uint32)strtoul(argv[i], &endptr, 0);
}
break;
}
#if UINTPTR_MAX == UINT64_MAX
case VALUE_TYPE_EXTERNREF:
{
union {
uintptr_t val;
uint32 parts[2];
} u;
if (strncasecmp(argv[i], "null", 4) == 0) {
u.val = (uintptr_t)-1LL;
}
else {
u.val = strtoull(argv[i], &endptr, 0);
}
argv1[p++] = u.parts[0];
argv1[p++] = u.parts[1];
break;
}
#endif
#endif /* WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0 */
default:
{
#if WASM_ENABLE_GC != 0
bool is_extern_ref = false;
bool is_anyref = false;
if (wasm_is_type_reftype(type->types[i])) {
if (strncasecmp(argv[i], "null", 4) == 0) {
PUT_REF_TO_ADDR(argv1 + p, NULL_REF);
p += REF_CELL_NUM;
break;
}
else if (type->types[i] == VALUE_TYPE_EXTERNREF) {
is_extern_ref = true;
}
else if (type->types[i] == VALUE_TYPE_ANYREF) {
is_anyref = true;
}
if (wasm_is_type_multi_byte_type(
type->types[type->param_count + i])) {
WASMRefType *ref_type = ref_type_map->ref_type;
if (wasm_is_refheaptype_common(
&ref_type->ref_ht_common)) {
int32 heap_type = ref_type->ref_ht_common.heap_type;
if (heap_type == HEAP_TYPE_EXTERN) {
is_extern_ref = true;
}
else if (heap_type == HEAP_TYPE_ANY) {
is_anyref = true;
}
}
ref_type_map++;
}
if (is_extern_ref) {
WASMExternrefObjectRef gc_obj;
void *extern_obj =
(void *)(uintptr_t)strtoull(argv[i], &endptr, 0);
gc_obj = wasm_externref_obj_new(exec_env, extern_obj);
if (!gc_obj) {
wasm_runtime_set_exception(
module_inst, "create extern object failed");
goto fail;
}
if (!(local_ref =
runtime_malloc(sizeof(WASMLocalObjectRef),
module_inst, NULL, 0))) {
goto fail;
}
wasm_runtime_push_local_obj_ref(exec_env, local_ref);
local_ref->val = (WASMObjectRef)gc_obj;
num_local_ref_pushed++;
PUT_REF_TO_ADDR(argv1 + p, gc_obj);
p += REF_CELL_NUM;
}
else if (is_anyref) {
/* If a parameter type is (ref null? any) and its value
* is not null, then we treat the value as host ptr */
WASMAnyrefObjectRef gc_obj;
void *host_obj =
(void *)(uintptr_t)strtoull(argv[i], &endptr, 0);
gc_obj = wasm_anyref_obj_new(exec_env, host_obj);
if (!gc_obj) {
wasm_runtime_set_exception(
module_inst, "create anyref object failed");
goto fail;
}
if (!(local_ref =
runtime_malloc(sizeof(WASMLocalObjectRef),
module_inst, NULL, 0))) {
goto fail;
}
wasm_runtime_push_local_obj_ref(exec_env, local_ref);
local_ref->val = (WASMObjectRef)gc_obj;
num_local_ref_pushed++;
PUT_REF_TO_ADDR(argv1 + p, gc_obj);
p += REF_CELL_NUM;
}
break;
}
#endif /* end of WASM_ENABLE_GC != 0 */
bh_assert(0);
break;
}
}
if (endptr && *endptr != '\0' && *endptr != '_') {
snprintf(buf, sizeof(buf), "invalid input argument %" PRId32 ": %s",
i, argv[i]);
wasm_runtime_set_exception(module_inst, buf);
goto fail;
}
}
wasm_runtime_set_exception(module_inst, NULL);
#if WASM_ENABLE_REF_TYPES == 0 && WASM_ENABLE_GC == 0
bh_assert(p == (int32)argc1);
#endif
if (!wasm_runtime_call_wasm(exec_env, target_func, argc1, argv1)) {
goto fail;
}
#if WASM_ENABLE_GC != 0
ref_type_map = type->result_ref_type_maps;
#endif
/* print return value */
for (j = 0; j < type->result_count; j++) {
switch (type->types[type->param_count + j]) {
case VALUE_TYPE_I32:
{
os_printf("0x%" PRIx32 ":i32", argv1[k]);
k++;
break;
}
case VALUE_TYPE_I64:
{
union {
uint64 val;
uint32 parts[2];
} u;
u.parts[0] = argv1[k];
u.parts[1] = argv1[k + 1];
k += 2;
os_printf("0x%" PRIx64 ":i64", u.val);
break;
}
case VALUE_TYPE_F32:
{
os_printf("%.7g:f32", *(float32 *)(argv1 + k));
k++;
break;
}
case VALUE_TYPE_F64:
{
union {
float64 val;
uint32 parts[2];
} u;
u.parts[0] = argv1[k];
u.parts[1] = argv1[k + 1];
k += 2;
os_printf("%.7g:f64", u.val);
break;
}
#if WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0
case VALUE_TYPE_FUNCREF:
{
if (argv1[k] != NULL_REF)
os_printf("%" PRIu32 ":ref.func", argv1[k]);
else
os_printf("func:ref.null");
k++;
break;
}
case VALUE_TYPE_EXTERNREF:
{
#if UINTPTR_MAX == UINT32_MAX
if (argv1[k] != 0 && argv1[k] != (uint32)-1)
os_printf("0x%" PRIxPTR ":ref.extern", (uintptr_t)argv1[k]);
else
os_printf("extern:ref.null");
k++;
#else
union {
uintptr_t val;
uint32 parts[2];
} u;
u.parts[0] = argv1[k];
u.parts[1] = argv1[k + 1];
k += 2;
if (u.val && u.val != (uintptr_t)-1LL)
os_printf("0x%" PRIxPTR ":ref.extern", u.val);
else
os_printf("extern:ref.null");
#endif
break;
}
#endif /* end of WASM_ENABLE_GC == 0 && WASM_ENABLE_REF_TYPES != 0 */
#if WASM_ENABLE_SIMD != 0
case VALUE_TYPE_V128:
{
uint64 *v = (uint64 *)(argv1 + k);
os_printf("<0x%016" PRIx64 " 0x%016" PRIx64 ">:v128", *v,
*(v + 1));
k += 4;
break;
}
#endif /* WASM_ENABLE_SIMD != 0 */
default:
{
#if WASM_ENABLE_GC != 0
if (wasm_is_type_reftype(type->types[type->param_count + j])) {
void *gc_obj = GET_REF_FROM_ADDR(argv1 + k);
k += REF_CELL_NUM;
if (!gc_obj) {
uint8 type1 = type->types[type->param_count + j];
WASMRefType *ref_type1 = NULL;
WASMType **types = NULL;
uint32 type_count = 0;
if (wasm_is_type_multi_byte_type(
type->types[type->param_count + j]))
ref_type1 = ref_type_map->ref_type;
#if WASM_ENABLE_INTERP != 0
if (module_inst->module_type == Wasm_Module_Bytecode) {
WASMModule *module =
((WASMModuleInstance *)module_inst)->module;
types = module->types;
type_count = module->type_count;
}
#endif
#if WASM_ENABLE_AOT != 0
if (module_inst->module_type == Wasm_Module_AoT) {
AOTModule *module =
(AOTModule *)((AOTModuleInstance *)module_inst)
->module;
types = module->types;
type_count = module->type_count;
}
#endif
bh_assert(type);
if (wasm_reftype_is_subtype_of(type1, ref_type1,
REF_TYPE_ANYREF, NULL,
types, type_count))
os_printf("any:");
else if (wasm_reftype_is_subtype_of(
type1, ref_type1, REF_TYPE_FUNCREF, NULL,
types, type_count))
os_printf("func:");
if (wasm_reftype_is_subtype_of(type1, ref_type1,
REF_TYPE_EXTERNREF, NULL,
types, type_count))
os_printf("extern:");
os_printf("ref.null");
}
else if (wasm_obj_is_func_obj(gc_obj))
os_printf("ref.func");
#if WASM_ENABLE_STRINGREF != 0
else if (wasm_obj_is_stringref_obj(gc_obj)
|| wasm_obj_is_stringview_wtf8_obj(gc_obj)) {
wasm_string_dump(
(WASMString)wasm_stringref_obj_get_value(gc_obj));
}
else if (wasm_obj_is_stringview_wtf16_obj(gc_obj)) {
wasm_string_dump(
(WASMString)wasm_stringview_wtf16_obj_get_value(
gc_obj));
}
#endif
else if (wasm_obj_is_externref_obj(gc_obj)) {
#if WASM_ENABLE_SPEC_TEST != 0
WASMObjectRef obj = wasm_externref_obj_to_internal_obj(
(WASMExternrefObjectRef)gc_obj);
if (wasm_obj_is_anyref_obj(obj))
os_printf("0x%" PRIxPTR ":ref.extern",
(uintptr_t)wasm_anyref_obj_get_value(
(WASMAnyrefObjectRef)obj));
else
#endif
os_printf("ref.extern");
}
else if (wasm_obj_is_i31_obj(gc_obj))
os_printf("ref.i31");
else if (wasm_obj_is_array_obj(gc_obj))
os_printf("ref.array");
else if (wasm_obj_is_struct_obj(gc_obj))
os_printf("ref.struct");
else if (wasm_obj_is_eq_obj(gc_obj))
os_printf("ref.eq");
else if (wasm_obj_is_anyref_obj(gc_obj))
os_printf("0x%" PRIxPTR ":ref.host",
(uintptr_t)wasm_anyref_obj_get_value(
(WASMAnyrefObjectRef)gc_obj));
else if (wasm_obj_is_internal_obj(gc_obj))
os_printf("ref.any");
if (wasm_is_type_multi_byte_type(
type->types[type->param_count + j]))
ref_type_map++;
break;
}
#endif /* endof WASM_ENABLE_GC != 0 */
bh_assert(0);
break;
}
}
if (j < (uint32)(type->result_count - 1))
os_printf(",");
}
os_printf("\n");
#if WASM_ENABLE_GC != 0
for (j = 0; j < num_local_ref_pushed; j++) {
local_ref = wasm_runtime_pop_local_obj_ref(exec_env);
wasm_runtime_free(local_ref);
}
#endif
wasm_runtime_free(argv1);
return true;
fail:
if (argv1)
wasm_runtime_free(argv1);
#if WASM_ENABLE_GC != 0
for (j = 0; j < num_local_ref_pushed; j++) {
local_ref = wasm_runtime_pop_local_obj_ref(exec_env);
wasm_runtime_free(local_ref);
}
#endif
bh_assert(wasm_runtime_get_exception(module_inst));
return false;
}
bool
wasm_application_execute_func(WASMModuleInstanceCommon *module_inst,
const char *name, int32 argc, char *argv[])
{
bool ret;
#if WASM_ENABLE_MEMORY_PROFILING != 0
WASMExecEnv *exec_env;
#endif
ret = execute_func(module_inst, name, argc, argv);
#if WASM_ENABLE_MEMORY_PROFILING != 0
exec_env = wasm_runtime_get_exec_env_singleton(module_inst);
if (exec_env) {
wasm_runtime_dump_mem_consumption(exec_env);
}
#endif
#if WASM_ENABLE_GC_PERF_PROFILING != 0
void *handle = wasm_runtime_get_gc_heap_handle(module_inst);
mem_allocator_dump_perf_profiling(handle);
#endif
#if WASM_ENABLE_PERF_PROFILING != 0
wasm_runtime_dump_perf_profiling(module_inst);
#endif
return (ret && !wasm_runtime_get_exception(module_inst)) ? true : false;
}