orca/ext/wasm3/source/m3_core.c

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2023-04-12 14:21:03 +00:00
//
// m3_core.c
//
// Created by Steven Massey on 4/15/19.
// Copyright © 2019 Steven Massey. All rights reserved.
//
#define M3_IMPLEMENT_ERROR_STRINGS
#include "m3_config.h"
#include "wasm3.h"
#include "m3_core.h"
#include "m3_env.h"
void m3_Abort(const char* message) {
#ifdef DEBUG
fprintf(stderr, "Error: %s\n", message);
#endif
abort();
}
M3_WEAK
M3Result m3_Yield ()
{
return m3Err_none;
}
#if d_m3LogTimestamps
#include <time.h>
#define SEC_TO_US(sec) ((sec)*1000000)
#define NS_TO_US(ns) ((ns)/1000)
static uint64_t initial_ts = -1;
uint64_t m3_GetTimestamp()
{
if (initial_ts == -1) {
initial_ts = 0;
initial_ts = m3_GetTimestamp();
}
struct timespec ts;
timespec_get(&ts, TIME_UTC);
uint64_t us = SEC_TO_US((uint64_t)ts.tv_sec) + NS_TO_US((uint64_t)ts.tv_nsec);
return us - initial_ts;
}
#endif
#if d_m3FixedHeap
static u8 fixedHeap[d_m3FixedHeap];
static u8* fixedHeapPtr = fixedHeap;
static u8* const fixedHeapEnd = fixedHeap + d_m3FixedHeap;
static u8* fixedHeapLast = NULL;
#if d_m3FixedHeapAlign > 1
# define HEAP_ALIGN_PTR(P) P = (u8*)(((size_t)(P)+(d_m3FixedHeapAlign-1)) & ~ (d_m3FixedHeapAlign-1));
#else
# define HEAP_ALIGN_PTR(P)
#endif
void * m3_Malloc_Impl (size_t i_size)
{
u8 * ptr = fixedHeapPtr;
fixedHeapPtr += i_size;
HEAP_ALIGN_PTR(fixedHeapPtr);
if (fixedHeapPtr >= fixedHeapEnd)
{
return NULL;
}
memset (ptr, 0x0, i_size);
fixedHeapLast = ptr;
return ptr;
}
void m3_Free_Impl (void * i_ptr)
{
// Handle the last chunk
if (i_ptr && i_ptr == fixedHeapLast) {
fixedHeapPtr = fixedHeapLast;
fixedHeapLast = NULL;
} else {
//printf("== free %p [failed]\n", io_ptr);
}
}
void * m3_Realloc_Impl (void * i_ptr, size_t i_newSize, size_t i_oldSize)
{
if (M3_UNLIKELY(i_newSize == i_oldSize)) return i_ptr;
void * newPtr;
// Handle the last chunk
if (i_ptr && i_ptr == fixedHeapLast) {
fixedHeapPtr = fixedHeapLast + i_newSize;
HEAP_ALIGN_PTR(fixedHeapPtr);
if (fixedHeapPtr >= fixedHeapEnd)
{
return NULL;
}
newPtr = i_ptr;
} else {
newPtr = m3_Malloc_Impl(i_newSize);
if (!newPtr) {
return NULL;
}
if (i_ptr) {
memcpy(newPtr, i_ptr, i_oldSize);
}
}
if (i_newSize > i_oldSize) {
memset ((u8 *) newPtr + i_oldSize, 0x0, i_newSize - i_oldSize);
}
return newPtr;
}
#else
void * m3_Malloc_Impl (size_t i_size)
{
return calloc (i_size, 1);
}
void m3_Free_Impl (void * io_ptr)
{
free (io_ptr);
}
void * m3_Realloc_Impl (void * i_ptr, size_t i_newSize, size_t i_oldSize)
{
if (M3_UNLIKELY(i_newSize == i_oldSize)) return i_ptr;
void * newPtr = realloc (i_ptr, i_newSize);
if (M3_LIKELY(newPtr))
{
if (i_newSize > i_oldSize) {
memset ((u8 *) newPtr + i_oldSize, 0x0, i_newSize - i_oldSize);
}
return newPtr;
}
return NULL;
}
#endif
void * m3_CopyMem (const void * i_from, size_t i_size)
{
void * ptr = m3_Malloc("CopyMem", i_size);
if (ptr) {
memcpy (ptr, i_from, i_size);
}
return ptr;
}
//--------------------------------------------------------------------------------------------
#if d_m3LogNativeStack
static size_t stack_start;
static size_t stack_end;
void m3StackCheckInit ()
{
char stack;
stack_end = stack_start = (size_t)&stack;
}
void m3StackCheck ()
{
char stack;
size_t addr = (size_t)&stack;
size_t stackEnd = stack_end;
stack_end = M3_MIN (stack_end, addr);
// if (stackEnd != stack_end)
// printf ("maxStack: %ld\n", m3StackGetMax ());
}
int m3StackGetMax ()
{
return stack_start - stack_end;
}
#endif
//--------------------------------------------------------------------------------------------
M3Result NormalizeType (u8 * o_type, i8 i_convolutedWasmType)
{
M3Result result = m3Err_none;
u8 type = -i_convolutedWasmType;
if (type == 0x40)
type = c_m3Type_none;
else if (type < c_m3Type_i32 or type > c_m3Type_f64)
result = m3Err_invalidTypeId;
* o_type = type;
return result;
}
bool IsFpType (u8 i_m3Type)
{
return (i_m3Type == c_m3Type_f32 or i_m3Type == c_m3Type_f64);
}
bool IsIntType (u8 i_m3Type)
{
return (i_m3Type == c_m3Type_i32 or i_m3Type == c_m3Type_i64);
}
bool Is64BitType (u8 i_m3Type)
{
if (i_m3Type == c_m3Type_i64 or i_m3Type == c_m3Type_f64)
return true;
else if (i_m3Type == c_m3Type_i32 or i_m3Type == c_m3Type_f32 or i_m3Type == c_m3Type_none)
return false;
else
return (sizeof (voidptr_t) == 8); // all other cases are pointers
}
u32 SizeOfType (u8 i_m3Type)
{
if (i_m3Type == c_m3Type_i32 or i_m3Type == c_m3Type_f32)
return sizeof (i32);
return sizeof (i64);
}
//-- Binary Wasm parsing utils ------------------------------------------------------------------------------------------
M3Result Read_u64 (u64 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
ptr += sizeof (u64);
if (ptr <= i_end)
{
memcpy(o_value, * io_bytes, sizeof(u64));
M3_BSWAP_u64(*o_value);
* io_bytes = ptr;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
M3Result Read_u32 (u32 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
ptr += sizeof (u32);
if (ptr <= i_end)
{
memcpy(o_value, * io_bytes, sizeof(u32));
M3_BSWAP_u32(*o_value);
* io_bytes = ptr;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
#if d_m3ImplementFloat
M3Result Read_f64 (f64 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
ptr += sizeof (f64);
if (ptr <= i_end)
{
memcpy(o_value, * io_bytes, sizeof(f64));
M3_BSWAP_f64(*o_value);
* io_bytes = ptr;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
M3Result Read_f32 (f32 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
ptr += sizeof (f32);
if (ptr <= i_end)
{
memcpy(o_value, * io_bytes, sizeof(f32));
M3_BSWAP_f32(*o_value);
* io_bytes = ptr;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
#endif
M3Result Read_u8 (u8 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
if (ptr < i_end)
{
* o_value = * ptr;
* io_bytes = ptr + 1;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
M3Result Read_opcode (m3opcode_t * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
const u8 * ptr = * io_bytes;
if (ptr < i_end)
{
m3opcode_t opcode = * ptr++;
#if d_m3CascadedOpcodes == 0
if (M3_UNLIKELY(opcode == c_waOp_extended))
{
if (ptr < i_end)
{
opcode = (opcode << 8) | (* ptr++);
}
else return m3Err_wasmUnderrun;
}
#endif
* o_value = opcode;
* io_bytes = ptr;
return m3Err_none;
}
else return m3Err_wasmUnderrun;
}
M3Result ReadLebUnsigned (u64 * o_value, u32 i_maxNumBits, bytes_t * io_bytes, cbytes_t i_end)
{
M3Result result = m3Err_wasmUnderrun;
u64 value = 0;
u32 shift = 0;
const u8 * ptr = * io_bytes;
while (ptr < i_end)
{
u64 byte = * (ptr++);
value |= ((byte & 0x7f) << shift);
shift += 7;
if ((byte & 0x80) == 0)
{
result = m3Err_none;
break;
}
if (shift >= i_maxNumBits)
{
result = m3Err_lebOverflow;
break;
}
}
* o_value = value;
* io_bytes = ptr;
return result;
}
M3Result ReadLebSigned (i64 * o_value, u32 i_maxNumBits, bytes_t * io_bytes, cbytes_t i_end)
{
M3Result result = m3Err_wasmUnderrun;
i64 value = 0;
u32 shift = 0;
const u8 * ptr = * io_bytes;
while (ptr < i_end)
{
u64 byte = * (ptr++);
value |= ((byte & 0x7f) << shift);
shift += 7;
if ((byte & 0x80) == 0)
{
result = m3Err_none;
if ((byte & 0x40) and (shift < 64)) // do sign extension
{
u64 extend = 0;
value |= (~extend << shift);
}
break;
}
if (shift >= i_maxNumBits)
{
result = m3Err_lebOverflow;
break;
}
}
* o_value = value;
* io_bytes = ptr;
return result;
}
M3Result ReadLEB_u32 (u32 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
u64 value;
M3Result result = ReadLebUnsigned (& value, 32, io_bytes, i_end);
* o_value = (u32) value;
return result;
}
M3Result ReadLEB_u7 (u8 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
u64 value;
M3Result result = ReadLebUnsigned (& value, 7, io_bytes, i_end);
* o_value = (u8) value;
return result;
}
M3Result ReadLEB_i7 (i8 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
i64 value;
M3Result result = ReadLebSigned (& value, 7, io_bytes, i_end);
* o_value = (i8) value;
return result;
}
M3Result ReadLEB_i32 (i32 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
i64 value;
M3Result result = ReadLebSigned (& value, 32, io_bytes, i_end);
* o_value = (i32) value;
return result;
}
M3Result ReadLEB_i64 (i64 * o_value, bytes_t * io_bytes, cbytes_t i_end)
{
i64 value;
M3Result result = ReadLebSigned (& value, 64, io_bytes, i_end);
* o_value = value;
return result;
}
M3Result Read_utf8 (cstr_t * o_utf8, bytes_t * io_bytes, cbytes_t i_end)
{
*o_utf8 = NULL;
u32 utf8Length;
M3Result result = ReadLEB_u32 (& utf8Length, io_bytes, i_end);
if (not result)
{
if (utf8Length <= d_m3MaxSaneUtf8Length)
{
const u8 * ptr = * io_bytes;
const u8 * end = ptr + utf8Length;
if (end <= i_end)
{
char * utf8 = (char *)m3_Malloc ("UTF8", utf8Length + 1);
if (utf8)
{
memcpy (utf8, ptr, utf8Length);
utf8 [utf8Length] = 0;
* o_utf8 = utf8;
}
* io_bytes = end;
}
else result = m3Err_wasmUnderrun;
}
else result = m3Err_missingUTF8;
}
return result;
}
#if d_m3RecordBacktraces
u32 FindModuleOffset (IM3Runtime i_runtime, pc_t i_pc)
{
// walk the code pages
IM3CodePage curr = i_runtime->pagesOpen;
bool pageFound = false;
while (curr)
{
if (ContainsPC (curr, i_pc))
{
pageFound = true;
break;
}
curr = curr->info.next;
}
if (!pageFound)
{
curr = i_runtime->pagesFull;
while (curr)
{
if (ContainsPC (curr, i_pc))
{
pageFound = true;
break;
}
curr = curr->info.next;
}
}
if (pageFound)
{
u32 result = 0;
bool pcFound = MapPCToOffset (curr, i_pc, & result);
d_m3Assert (pcFound);
return result;
}
else return 0;
}
void PushBacktraceFrame (IM3Runtime io_runtime, pc_t i_pc)
{
// don't try to push any more frames if we've already had an alloc failure
if (M3_UNLIKELY (io_runtime->backtrace.lastFrame == M3_BACKTRACE_TRUNCATED))
return;
M3BacktraceFrame * newFrame = m3_AllocStruct(M3BacktraceFrame);
if (!newFrame)
{
io_runtime->backtrace.lastFrame = M3_BACKTRACE_TRUNCATED;
return;
}
newFrame->moduleOffset = FindModuleOffset (io_runtime, i_pc);
if (!io_runtime->backtrace.frames || !io_runtime->backtrace.lastFrame)
io_runtime->backtrace.frames = newFrame;
else
io_runtime->backtrace.lastFrame->next = newFrame;
io_runtime->backtrace.lastFrame = newFrame;
}
void FillBacktraceFunctionInfo (IM3Runtime io_runtime, IM3Function i_function)
{
// If we've had an alloc failure then the last frame doesn't refer to the
// frame we want to fill in the function info for.
if (M3_UNLIKELY (io_runtime->backtrace.lastFrame == M3_BACKTRACE_TRUNCATED))
return;
if (!io_runtime->backtrace.lastFrame)
return;
io_runtime->backtrace.lastFrame->function = i_function;
}
void ClearBacktrace (IM3Runtime io_runtime)
{
M3BacktraceFrame * currentFrame = io_runtime->backtrace.frames;
while (currentFrame)
{
M3BacktraceFrame * nextFrame = currentFrame->next;
m3_Free (currentFrame);
currentFrame = nextFrame;
}
io_runtime->backtrace.frames = NULL;
io_runtime->backtrace.lastFrame = NULL;
}
#endif // d_m3RecordBacktraces