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chromium / v8 / v8 / 2c90935772e30c936574343be914875fe51ff7a7 / . / src / wasm / function-body-decoder-impl.h
blob: 05c0f933b26aaf4ae4a8fd8027db73a0c0a0e3a7 [file] [log] [blame]
// Copyright 2017 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_WASM_FUNCTION_BODY_DECODER_IMPL_H_
#define V8_WASM_FUNCTION_BODY_DECODER_IMPL_H_
// Do only include this header for implementing new Interface of the
// WasmFullDecoder.
#include "src/base/platform/elapsed-timer.h"
#include "src/bit-vector.h"
#include "src/wasm/decoder.h"
#include "src/wasm/function-body-decoder.h"
#include "src/wasm/wasm-features.h"
#include "src/wasm/wasm-limits.h"
#include "src/wasm/wasm-module.h"
#include "src/wasm/wasm-opcodes.h"
namespace v8 {
namespace internal {
namespace wasm {
struct WasmGlobal;
struct WasmException;
#define TRACE(...) \
do { \
if (FLAG_trace_wasm_decoder) PrintF(__VA_ARGS__); \
} while (false)
#define TRACE_INST_FORMAT " @%-8d #%-20s|"
// Return the evaluation of `condition` if validate==true, DCHECK that it's
// true and always return true otherwise.
#define VALIDATE(condition) \
(validate ? (condition) : [&] { \
DCHECK(condition); \
return true; \
}())
#define RET_ON_PROTOTYPE_OPCODE(feat) \
DCHECK(!this->module_ || this->module_->origin == kWasmOrigin); \
if (!this->enabled_.feat) { \
this->error("Invalid opcode (enable with --experimental-wasm-" #feat ")"); \
} else { \
this->detected_->feat = true; \
}
#define CHECK_PROTOTYPE_OPCODE(feat) \
DCHECK(!this->module_ || this->module_->origin == kWasmOrigin); \
if (!this->enabled_.feat) { \
this->error("Invalid opcode (enable with --experimental-wasm-" #feat ")"); \
break; \
} else { \
this->detected_->feat = true; \
}
#define OPCODE_ERROR(opcode, message) \
(this->errorf(this->pc_, "%s: %s", WasmOpcodes::OpcodeName(opcode), \
(message)))
#define ATOMIC_OP_LIST(V) \
V(AtomicWake, Uint32) \
V(I32AtomicWait, Uint32) \
V(I64AtomicWait, Uint32) \
V(I32AtomicLoad, Uint32) \
V(I64AtomicLoad, Uint64) \
V(I32AtomicLoad8U, Uint8) \
V(I32AtomicLoad16U, Uint16) \
V(I64AtomicLoad8U, Uint8) \
V(I64AtomicLoad16U, Uint16) \
V(I64AtomicLoad32U, Uint32) \
V(I32AtomicAdd, Uint32) \
V(I32AtomicAdd8U, Uint8) \
V(I32AtomicAdd16U, Uint16) \
V(I64AtomicAdd, Uint64) \
V(I64AtomicAdd8U, Uint8) \
V(I64AtomicAdd16U, Uint16) \
V(I64AtomicAdd32U, Uint32) \
V(I32AtomicSub, Uint32) \
V(I64AtomicSub, Uint64) \
V(I32AtomicSub8U, Uint8) \
V(I32AtomicSub16U, Uint16) \
V(I64AtomicSub8U, Uint8) \
V(I64AtomicSub16U, Uint16) \
V(I64AtomicSub32U, Uint32) \
V(I32AtomicAnd, Uint32) \
V(I64AtomicAnd, Uint64) \
V(I32AtomicAnd8U, Uint8) \
V(I32AtomicAnd16U, Uint16) \
V(I64AtomicAnd8U, Uint8) \
V(I64AtomicAnd16U, Uint16) \
V(I64AtomicAnd32U, Uint32) \
V(I32AtomicOr, Uint32) \
V(I64AtomicOr, Uint64) \
V(I32AtomicOr8U, Uint8) \
V(I32AtomicOr16U, Uint16) \
V(I64AtomicOr8U, Uint8) \
V(I64AtomicOr16U, Uint16) \
V(I64AtomicOr32U, Uint32) \
V(I32AtomicXor, Uint32) \
V(I64AtomicXor, Uint64) \
V(I32AtomicXor8U, Uint8) \
V(I32AtomicXor16U, Uint16) \
V(I64AtomicXor8U, Uint8) \
V(I64AtomicXor16U, Uint16) \
V(I64AtomicXor32U, Uint32) \
V(I32AtomicExchange, Uint32) \
V(I64AtomicExchange, Uint64) \
V(I32AtomicExchange8U, Uint8) \
V(I32AtomicExchange16U, Uint16) \
V(I64AtomicExchange8U, Uint8) \
V(I64AtomicExchange16U, Uint16) \
V(I64AtomicExchange32U, Uint32) \
V(I32AtomicCompareExchange, Uint32) \
V(I64AtomicCompareExchange, Uint64) \
V(I32AtomicCompareExchange8U, Uint8) \
V(I32AtomicCompareExchange16U, Uint16) \
V(I64AtomicCompareExchange8U, Uint8) \
V(I64AtomicCompareExchange16U, Uint16) \
V(I64AtomicCompareExchange32U, Uint32)
#define ATOMIC_STORE_OP_LIST(V) \
V(I32AtomicStore, Uint32) \
V(I64AtomicStore, Uint64) \
V(I32AtomicStore8U, Uint8) \
V(I32AtomicStore16U, Uint16) \
V(I64AtomicStore8U, Uint8) \
V(I64AtomicStore16U, Uint16) \
V(I64AtomicStore32U, Uint32)
// Helpers for decoding different kinds of immediates which follow bytecodes.
template <Decoder::ValidateFlag validate>
struct LocalIndexImmediate {
uint32_t index;
ValueType type = kWasmStmt;
uint32_t length;
inline LocalIndexImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u32v<validate>(pc + 1, &length, "local index");
}
};
template <Decoder::ValidateFlag validate>
struct ExceptionIndexImmediate {
uint32_t index;
const WasmException* exception = nullptr;
uint32_t length;
inline ExceptionIndexImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u32v<validate>(pc + 1, &length, "exception index");
}
};
template <Decoder::ValidateFlag validate>
struct ImmI32Immediate {
int32_t value;
uint32_t length;
inline ImmI32Immediate(Decoder* decoder, const byte* pc) {
value = decoder->read_i32v<validate>(pc + 1, &length, "immi32");
}
};
template <Decoder::ValidateFlag validate>
struct ImmI64Immediate {
int64_t value;
uint32_t length;
inline ImmI64Immediate(Decoder* decoder, const byte* pc) {
value = decoder->read_i64v<validate>(pc + 1, &length, "immi64");
}
};
template <Decoder::ValidateFlag validate>
struct ImmF32Immediate {
float value;
uint32_t length = 4;
inline ImmF32Immediate(Decoder* decoder, const byte* pc) {
// Avoid bit_cast because it might not preserve the signalling bit of a NaN.
uint32_t tmp = decoder->read_u32<validate>(pc + 1, "immf32");
memcpy(&value, &tmp, sizeof(value));
}
};
template <Decoder::ValidateFlag validate>
struct ImmF64Immediate {
double value;
uint32_t length = 8;
inline ImmF64Immediate(Decoder* decoder, const byte* pc) {
// Avoid bit_cast because it might not preserve the signalling bit of a NaN.
uint64_t tmp = decoder->read_u64<validate>(pc + 1, "immf64");
memcpy(&value, &tmp, sizeof(value));
}
};
template <Decoder::ValidateFlag validate>
struct GlobalIndexImmediate {
uint32_t index;
ValueType type = kWasmStmt;
const WasmGlobal* global = nullptr;
uint32_t length;
inline GlobalIndexImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u32v<validate>(pc + 1, &length, "global index");
}
};
template <Decoder::ValidateFlag validate>
struct BlockTypeImmediate {
uint32_t length = 1;
ValueType type = kWasmStmt;
uint32_t sig_index = 0;
FunctionSig* sig = nullptr;
inline BlockTypeImmediate(const WasmFeatures& enabled, Decoder* decoder,
const byte* pc) {
uint8_t val = decoder->read_u8<validate>(pc + 1, "block type");
if (!decode_local_type(val, &type)) {
// Handle multi-value blocks.
if (!VALIDATE(enabled.mv)) {
decoder->error(pc + 1, "invalid block type");
return;
}
if (!VALIDATE(decoder->ok())) return;
int32_t index =
decoder->read_i32v<validate>(pc + 1, &length, "block arity");
if (!VALIDATE(length > 0 && index >= 0)) {
decoder->error(pc + 1, "invalid block type index");
return;
}
sig_index = static_cast<uint32_t>(index);
}
}
// Decode a byte representing a local type. Return {false} if the encoded
// byte was invalid or the start of a type index.
inline bool decode_local_type(uint8_t val, ValueType* result) {
switch (static_cast<ValueTypeCode>(val)) {
case kLocalVoid:
*result = kWasmStmt;
return true;
case kLocalI32:
*result = kWasmI32;
return true;
case kLocalI64:
*result = kWasmI64;
return true;
case kLocalF32:
*result = kWasmF32;
return true;
case kLocalF64:
*result = kWasmF64;
return true;
case kLocalS128:
*result = kWasmS128;
return true;
case kLocalAnyFunc:
*result = kWasmAnyFunc;
return true;
case kLocalAnyRef:
*result = kWasmAnyRef;
return true;
default:
*result = kWasmVar;
return false;
}
}
uint32_t in_arity() const {
if (type != kWasmVar) return 0;
return static_cast<uint32_t>(sig->parameter_count());
}
uint32_t out_arity() const {
if (type == kWasmStmt) return 0;
if (type != kWasmVar) return 1;
return static_cast<uint32_t>(sig->return_count());
}
ValueType in_type(uint32_t index) {
DCHECK_EQ(kWasmVar, type);
return sig->GetParam(index);
}
ValueType out_type(uint32_t index) {
if (type == kWasmVar) return sig->GetReturn(index);
DCHECK_NE(kWasmStmt, type);
DCHECK_EQ(0, index);
return type;
}
};
template <Decoder::ValidateFlag validate>
struct BreakDepthImmediate {
uint32_t depth;
uint32_t length;
inline BreakDepthImmediate(Decoder* decoder, const byte* pc) {
depth = decoder->read_u32v<validate>(pc + 1, &length, "break depth");
}
};
template <Decoder::ValidateFlag validate>
struct CallIndirectImmediate {
uint32_t table_index;
uint32_t sig_index;
FunctionSig* sig = nullptr;
uint32_t length = 0;
inline CallIndirectImmediate(Decoder* decoder, const byte* pc) {
uint32_t len = 0;
sig_index = decoder->read_u32v<validate>(pc + 1, &len, "signature index");
if (!VALIDATE(decoder->ok())) return;
table_index = decoder->read_u8<validate>(pc + 1 + len, "table index");
if (!VALIDATE(table_index == 0)) {
decoder->errorf(pc + 1 + len, "expected table index 0, found %u",
table_index);
}
length = 1 + len;
}
};
template <Decoder::ValidateFlag validate>
struct CallFunctionImmediate {
uint32_t index;
FunctionSig* sig = nullptr;
uint32_t length;
inline CallFunctionImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u32v<validate>(pc + 1, &length, "function index");
}
};
template <Decoder::ValidateFlag validate>
struct MemoryIndexImmediate {
uint32_t index;
uint32_t length = 1;
inline MemoryIndexImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u8<validate>(pc + 1, "memory index");
if (!VALIDATE(index == 0)) {
decoder->errorf(pc + 1, "expected memory index 0, found %u", index);
}
}
};
template <Decoder::ValidateFlag validate>
struct TableIndexImmediate {
uint32_t index;
unsigned length = 1;
inline TableIndexImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_u8<validate>(pc + 1, "table index");
if (!VALIDATE(index == 0)) {
decoder->errorf(pc + 1, "expected table index 0, found %u", index);
}
}
};
template <Decoder::ValidateFlag validate>
struct BranchTableImmediate {
uint32_t table_count;
const byte* start;
const byte* table;
inline BranchTableImmediate(Decoder* decoder, const byte* pc) {
DCHECK_EQ(kExprBrTable, decoder->read_u8<validate>(pc, "opcode"));
start = pc + 1;
uint32_t len = 0;
table_count = decoder->read_u32v<validate>(pc + 1, &len, "table count");
table = pc + 1 + len;
}
};
// A helper to iterate over a branch table.
template <Decoder::ValidateFlag validate>
class BranchTableIterator {
public:
uint32_t cur_index() { return index_; }
bool has_next() { return VALIDATE(decoder_->ok()) && index_ <= table_count_; }
uint32_t next() {
DCHECK(has_next());
index_++;
uint32_t length;
uint32_t result =
decoder_->read_u32v<validate>(pc_, &length, "branch table entry");
pc_ += length;
return result;
}
// length, including the length of the {BranchTableImmediate}, but not the
// opcode.
uint32_t length() {
while (has_next()) next();
return static_cast<uint32_t>(pc_ - start_);
}
const byte* pc() { return pc_; }
BranchTableIterator(Decoder* decoder,
const BranchTableImmediate<validate>& imm)
: decoder_(decoder),
start_(imm.start),
pc_(imm.table),
table_count_(imm.table_count) {}
private:
Decoder* decoder_;
const byte* start_;
const byte* pc_;
uint32_t index_ = 0; // the current index.
uint32_t table_count_; // the count of entries, not including default.
};
template <Decoder::ValidateFlag validate>
struct MemoryAccessImmediate {
uint32_t alignment;
uint32_t offset;
uint32_t length = 0;
inline MemoryAccessImmediate(Decoder* decoder, const byte* pc,
uint32_t max_alignment) {
uint32_t alignment_length;
alignment =
decoder->read_u32v<validate>(pc + 1, &alignment_length, "alignment");
if (!VALIDATE(alignment <= max_alignment)) {
decoder->errorf(pc + 1,
"invalid alignment; expected maximum alignment is %u, "
"actual alignment is %u",
max_alignment, alignment);
}
if (!VALIDATE(decoder->ok())) return;
uint32_t offset_length;
offset = decoder->read_u32v<validate>(pc + 1 + alignment_length,
&offset_length, "offset");
length = alignment_length + offset_length;
}
};
// Immediate for SIMD lane operations.
template <Decoder::ValidateFlag validate>
struct SimdLaneImmediate {
uint8_t lane;
uint32_t length = 1;
inline SimdLaneImmediate(Decoder* decoder, const byte* pc) {
lane = decoder->read_u8<validate>(pc + 2, "lane");
}
};
// Immediate for SIMD shift operations.
template <Decoder::ValidateFlag validate>
struct SimdShiftImmediate {
uint8_t shift;
uint32_t length = 1;
inline SimdShiftImmediate(Decoder* decoder, const byte* pc) {
shift = decoder->read_u8<validate>(pc + 2, "shift");
}
};
// Immediate for SIMD S8x16 shuffle operations.
template <Decoder::ValidateFlag validate>
struct Simd8x16ShuffleImmediate {
uint8_t shuffle[kSimd128Size] = {0};
inline Simd8x16ShuffleImmediate(Decoder* decoder, const byte* pc) {
for (uint32_t i = 0; i < kSimd128Size; ++i) {
shuffle[i] = decoder->read_u8<validate>(pc + 2 + i, "shuffle");
if (!VALIDATE(decoder->ok())) return;
}
}
};
template <Decoder::ValidateFlag validate>
struct MemoryInitImmediate {
MemoryIndexImmediate<validate> memory;
uint32_t data_segment_index = 0;
unsigned length = 0;
inline MemoryInitImmediate(Decoder* decoder, const byte* pc)
: memory(decoder, pc + 1) {
if (!VALIDATE(decoder->ok())) return;
uint32_t len = 0;
data_segment_index = decoder->read_i32v<validate>(
pc + 2 + memory.length, &len, "data segment index");
length = memory.length + len;
}
};
template <Decoder::ValidateFlag validate>
struct MemoryDropImmediate {
uint32_t index;
unsigned length;
inline MemoryDropImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_i32v<validate>(pc + 2, &length, "data segment index");
}
};
template <Decoder::ValidateFlag validate>
struct TableInitImmediate {
TableIndexImmediate<validate> table;
uint32_t elem_segment_index = 0;
unsigned length = 0;
inline TableInitImmediate(Decoder* decoder, const byte* pc)
: table(decoder, pc + 1) {
if (!VALIDATE(decoder->ok())) return;
uint32_t len = 0;
elem_segment_index = decoder->read_i32v<validate>(
pc + 2 + table.length, &len, "elem segment index");
length = table.length + len;
}
};
template <Decoder::ValidateFlag validate>
struct TableDropImmediate {
uint32_t index;
unsigned length;
inline TableDropImmediate(Decoder* decoder, const byte* pc) {
index = decoder->read_i32v<validate>(pc + 2, &length, "elem segment index");
}
};
// An entry on the value stack.
struct ValueBase {
const byte* pc;
ValueType type;
// Named constructors.
static ValueBase Unreachable(const byte* pc) { return {pc, kWasmVar}; }
static ValueBase New(const byte* pc, ValueType type) { return {pc, type}; }
};
template <typename Value>
struct Merge {
uint32_t arity;
union {
Value* array;
Value first;
} vals; // Either multiple values or a single value.
// Tracks whether this merge was ever reached. Uses precise reachability, like
// Reachability::kReachable.
bool reached;
Merge(bool reached = false) : reached(reached) {}
Value& operator[](uint32_t i) {
DCHECK_GT(arity, i);
return arity == 1 ? vals.first : vals.array[i];
}
};
enum ControlKind : uint8_t {
kControlIf,
kControlIfElse,
kControlBlock,
kControlLoop,
kControlTry,
kControlTryCatch,
kControlTryCatchAll
};
enum Reachability : uint8_t {
// reachable code.
kReachable,
// reachable code in unreachable block (implies normal validation).
kSpecOnlyReachable,
// code unreachable in its own block (implies polymorphic validation).
kUnreachable
};
// An entry on the control stack (i.e. if, block, loop, or try).
template <typename Value>
struct ControlBase {
ControlKind kind;
uint32_t stack_depth; // stack height at the beginning of the construct.
const byte* pc;
Reachability reachability = kReachable;
// Values merged into the start or end of this control construct.
Merge<Value> start_merge;
Merge<Value> end_merge;
ControlBase() = default;
ControlBase(ControlKind kind, uint32_t stack_depth, const byte* pc)
: kind(kind), stack_depth(stack_depth), pc(pc) {}
// Check whether the current block is reachable.
bool reachable() const { return reachability == kReachable; }
// Check whether the rest of the block is unreachable.
// Note that this is different from {!reachable()}, as there is also the
// "indirect unreachable state", for which both {reachable()} and
// {unreachable()} return false.
bool unreachable() const { return reachability == kUnreachable; }
// Return the reachability of new control structs started in this block.
Reachability innerReachability() const {
return reachability == kReachable ? kReachable : kSpecOnlyReachable;
}
bool is_if() const { return is_onearmed_if() || is_if_else(); }
bool is_onearmed_if() const { return kind == kControlIf; }
bool is_if_else() const { return kind == kControlIfElse; }
bool is_block() const { return kind == kControlBlock; }
bool is_loop() const { return kind == kControlLoop; }
bool is_incomplete_try() const { return kind == kControlTry; }
bool is_try_catch() const { return kind == kControlTryCatch; }
bool is_try_catchall() const { return kind == kControlTryCatchAll; }
bool is_try() const {
return is_incomplete_try() || is_try_catch() || is_try_catchall();
}
inline Merge<Value>* br_merge() {
return is_loop() ? &this->start_merge : &this->end_merge;
}
// Named constructors.
static ControlBase Block(const byte* pc, uint32_t stack_depth) {
return {kControlBlock, stack_depth, pc};
}
static ControlBase If(const byte* pc, uint32_t stack_depth) {
return {kControlIf, stack_depth, pc};
}
static ControlBase Loop(const byte* pc, uint32_t stack_depth) {
return {kControlLoop, stack_depth, pc};
}
static ControlBase Try(const byte* pc, uint32_t stack_depth) {
return {kControlTry, stack_depth, pc};
}
};
#define CONCRETE_NAMED_CONSTRUCTOR(concrete_type, abstract_type, name) \
template <typename... Args> \
static concrete_type name(Args&&... args) { \
concrete_type val; \
static_cast<abstract_type&>(val) = \
abstract_type::name(std::forward<Args>(args)...); \
return val; \
}
// Provide the default named constructors, which default-initialize the
// ConcreteType and the initialize the fields of ValueBase correctly.
// Use like this:
// struct Value : public ValueWithNamedConstructors<Value> { int new_field; };
template <typename ConcreteType>
struct ValueWithNamedConstructors : public ValueBase {
// Named constructors.
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ValueBase, Unreachable)
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ValueBase, New)
};
// Provide the default named constructors, which default-initialize the
// ConcreteType and the initialize the fields of ControlBase correctly.
// Use like this:
// struct Control : public ControlWithNamedConstructors<Control, Value> {
// int my_uninitialized_field;
// char* other_field = nullptr;
// };
template <typename ConcreteType, typename Value>
struct ControlWithNamedConstructors : public ControlBase<Value> {
// Named constructors.
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ControlBase<Value>, Block)
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ControlBase<Value>, If)
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ControlBase<Value>, Loop)
CONCRETE_NAMED_CONSTRUCTOR(ConcreteType, ControlBase<Value>, Try)
};
// This is the list of callback functions that an interface for the
// WasmFullDecoder should implement.
// F(Name, args...)
#define INTERFACE_FUNCTIONS(F) \
/* General: */ \
F(StartFunction) \
F(StartFunctionBody, Control* block) \
F(FinishFunction) \
F(OnFirstError) \
F(NextInstruction, WasmOpcode) \
/* Control: */ \
F(Block, Control* block) \
F(Loop, Control* block) \
F(Try, Control* block) \
F(If, const Value& cond, Control* if_block) \
F(FallThruTo, Control* c) \
F(PopControl, Control* block) \
F(EndControl, Control* block) \
/* Instructions: */ \
F(UnOp, WasmOpcode opcode, FunctionSig*, const Value& value, Value* result) \
F(BinOp, WasmOpcode opcode, FunctionSig*, const Value& lhs, \
const Value& rhs, Value* result) \
F(I32Const, Value* result, int32_t value) \
F(I64Const, Value* result, int64_t value) \
F(F32Const, Value* result, float value) \
F(F64Const, Value* result, double value) \
F(RefNull, Value* result) \
F(Drop, const Value& value) \
F(DoReturn, Vector<Value> values, bool implicit) \
F(GetLocal, Value* result, const LocalIndexImmediate<validate>& imm) \
F(SetLocal, const Value& value, const LocalIndexImmediate<validate>& imm) \
F(TeeLocal, const Value& value, Value* result, \
const LocalIndexImmediate<validate>& imm) \
F(GetGlobal, Value* result, const GlobalIndexImmediate<validate>& imm) \
F(SetGlobal, const Value& value, const GlobalIndexImmediate<validate>& imm) \
F(Unreachable) \
F(Select, const Value& cond, const Value& fval, const Value& tval, \
Value* result) \
F(Br, Control* target) \
F(BrIf, const Value& cond, Control* target) \
F(BrTable, const BranchTableImmediate<validate>& imm, const Value& key) \
F(Else, Control* if_block) \
F(LoadMem, LoadType type, const MemoryAccessImmediate<validate>& imm, \
const Value& index, Value* result) \
F(StoreMem, StoreType type, const MemoryAccessImmediate<validate>& imm, \
const Value& index, const Value& value) \
F(CurrentMemoryPages, Value* result) \
F(MemoryGrow, const Value& value, Value* result) \
F(CallDirect, const CallFunctionImmediate<validate>& imm, \
const Value args[], Value returns[]) \
F(CallIndirect, const Value& index, \
const CallIndirectImmediate<validate>& imm, const Value args[], \
Value returns[]) \
F(SimdOp, WasmOpcode opcode, Vector<Value> args, Value* result) \
F(SimdLaneOp, WasmOpcode opcode, const SimdLaneImmediate<validate>& imm, \
const Vector<Value> inputs, Value* result) \
F(SimdShiftOp, WasmOpcode opcode, const SimdShiftImmediate<validate>& imm, \
const Value& input, Value* result) \
F(Simd8x16ShuffleOp, const Simd8x16ShuffleImmediate<validate>& imm, \
const Value& input0, const Value& input1, Value* result) \
F(Throw, const ExceptionIndexImmediate<validate>& imm, \
const Vector<Value>& args) \
F(Rethrow, Control* block) \
F(CatchException, const ExceptionIndexImmediate<validate>& imm, \
Control* block, Vector<Value> caught_values) \
F(CatchAll, Control* block) \
F(AtomicOp, WasmOpcode opcode, Vector<Value> args, \
const MemoryAccessImmediate<validate>& imm, Value* result) \
F(MemoryInit, const MemoryInitImmediate<validate>& imm, Vector<Value> args) \
F(MemoryDrop, const MemoryDropImmediate<validate>& imm) \
F(MemoryCopy, const MemoryIndexImmediate<validate>& imm, Vector<Value> args) \
F(MemoryFill, const MemoryIndexImmediate<validate>& imm, Vector<Value> args) \
F(TableInit, const TableInitImmediate<validate>& imm, Vector<Value> args) \
F(TableDrop, const TableDropImmediate<validate>& imm) \
F(TableCopy, const TableIndexImmediate<validate>& imm, Vector<Value> args)
// Generic Wasm bytecode decoder with utilities for decoding immediates,
// lengths, etc.
template <Decoder::ValidateFlag validate>
class WasmDecoder : public Decoder {
public:
WasmDecoder(const WasmModule* module, const WasmFeatures& enabled,
WasmFeatures* detected, FunctionSig* sig, const byte* start,
const byte* end, uint32_t buffer_offset = 0)
: Decoder(start, end, buffer_offset),
module_(module),
enabled_(enabled),
detected_(detected),
sig_(sig),
local_types_(nullptr) {}
const WasmModule* module_;
const WasmFeatures enabled_;
WasmFeatures* detected_;
FunctionSig* sig_;
ZoneVector<ValueType>* local_types_;
uint32_t total_locals() const {
return local_types_ == nullptr
? 0
: static_cast<uint32_t>(local_types_->size());
}
static bool DecodeLocals(const WasmFeatures& enabled, Decoder* decoder,
const FunctionSig* sig,
ZoneVector<ValueType>* type_list) {
DCHECK_NOT_NULL(type_list);
DCHECK_EQ(0, type_list->size());
// Initialize from signature.
if (sig != nullptr) {
type_list->assign(sig->parameters().begin(), sig->parameters().end());
}
// Decode local declarations, if any.
uint32_t entries = decoder->consume_u32v("local decls count");
if (decoder->failed()) return false;
TRACE("local decls count: %u\n", entries);
while (entries-- > 0 && VALIDATE(decoder->ok()) && decoder->more()) {
uint32_t count = decoder->consume_u32v("local count");
if (decoder->failed()) return false;
DCHECK_LE(type_list->size(), kV8MaxWasmFunctionLocals);
if (count > kV8MaxWasmFunctionLocals - type_list->size()) {
decoder->error(decoder->pc() - 1, "local count too large");
return false;
}
byte code = decoder->consume_u8("local type");
if (decoder->failed()) return false;
ValueType type;
switch (code) {
case kLocalI32:
type = kWasmI32;
break;
case kLocalI64:
type = kWasmI64;
break;
case kLocalF32:
type = kWasmF32;
break;
case kLocalF64:
type = kWasmF64;
break;
case kLocalAnyRef:
if (enabled.anyref) {
type = kWasmAnyRef;
break;
}
decoder->error(decoder->pc() - 1, "invalid local type");
return false;
case kLocalExceptRef:
if (enabled.eh) {
type = kWasmExceptRef;
break;
}
decoder->error(decoder->pc() - 1, "invalid local type");
return false;
case kLocalS128:
if (enabled.simd) {
type = kWasmS128;
break;
}
V8_FALLTHROUGH;
default:
decoder->error(decoder->pc() - 1, "invalid local type");
return false;
}
type_list->insert(type_list->end(), count, type);
}
DCHECK(decoder->ok());
return true;
}
static BitVector* AnalyzeLoopAssignment(Decoder* decoder, const byte* pc,
uint32_t locals_count, Zone* zone) {
if (pc >= decoder->end()) return nullptr;
if (*pc != kExprLoop) return nullptr;
// The number of locals_count is augmented by 2 so that 'locals_count - 2'
// can be used to track mem_size, and 'locals_count - 1' to track mem_start.
BitVector* assigned = new (zone) BitVector(locals_count, zone);
int depth = 0;
// Iteratively process all AST nodes nested inside the loop.
while (pc < decoder->end() && VALIDATE(decoder->ok())) {
WasmOpcode opcode = static_cast<WasmOpcode>(*pc);
uint32_t length = 1;
switch (opcode) {
case kExprLoop:
case kExprIf:
case kExprBlock:
case kExprTry:
length = OpcodeLength(decoder, pc);
depth++;
break;
case kExprSetLocal: // fallthru
case kExprTeeLocal: {
LocalIndexImmediate<validate> imm(decoder, pc);
if (assigned->length() > 0 &&
imm.index < static_cast<uint32_t>(assigned->length())) {
// Unverified code might have an out-of-bounds index.
assigned->Add(imm.index);
}
length = 1 + imm.length;
break;
}
case kExprMemoryGrow:
case kExprCallFunction:
case kExprCallIndirect:
// Add instance cache nodes to the assigned set.
// TODO(titzer): make this more clear.
assigned->Add(locals_count - 1);
length = OpcodeLength(decoder, pc);
break;
case kExprEnd:
depth--;
break;
default:
length = OpcodeLength(decoder, pc);
break;
}
if (depth <= 0) break;
pc += length;
}
return VALIDATE(decoder->ok()) ? assigned : nullptr;
}
inline bool Validate(const byte* pc, LocalIndexImmediate<validate>& imm) {
if (!VALIDATE(imm.index < total_locals())) {
errorf(pc + 1, "invalid local index: %u", imm.index);
return false;
}
imm.type = local_types_ ? local_types_->at(imm.index) : kWasmStmt;
return true;
}
inline bool Validate(const byte* pc, ExceptionIndexImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr &&
imm.index < module_->exceptions.size())) {
errorf(pc + 1, "Invalid exception index: %u", imm.index);
return false;
}
imm.exception = &module_->exceptions[imm.index];
return true;
}
inline bool Validate(const byte* pc, GlobalIndexImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr && imm.index < module_->globals.size())) {
errorf(pc + 1, "invalid global index: %u", imm.index);
return false;
}
imm.global = &module_->globals[imm.index];
imm.type = imm.global->type;
return true;
}
inline bool Complete(const byte* pc, CallFunctionImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr &&
imm.index < module_->functions.size())) {
return false;
}
imm.sig = module_->functions[imm.index].sig;
return true;
}
inline bool Validate(const byte* pc, CallFunctionImmediate<validate>& imm) {
if (Complete(pc, imm)) {
return true;
}
errorf(pc + 1, "invalid function index: %u", imm.index);
return false;
}
inline bool Complete(const byte* pc, CallIndirectImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr &&
imm.sig_index < module_->signatures.size())) {
return false;
}
imm.sig = module_->signatures[imm.sig_index];
return true;
}
inline bool Validate(const byte* pc, CallIndirectImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr && !module_->tables.empty())) {
error("function table has to exist to execute call_indirect");
return false;
}
if (!Complete(pc, imm)) {
errorf(pc + 1, "invalid signature index: #%u", imm.sig_index);
return false;
}
return true;
}
inline bool Validate(const byte* pc, BreakDepthImmediate<validate>& imm,
size_t control_depth) {
if (!VALIDATE(imm.depth < control_depth)) {
errorf(pc + 1, "invalid break depth: %u", imm.depth);
return false;
}
return true;
}
bool Validate(const byte* pc, BranchTableImmediate<validate>& imm,
size_t block_depth) {
if (!VALIDATE(imm.table_count < kV8MaxWasmFunctionSize)) {
errorf(pc + 1, "invalid table count (> max function size): %u",
imm.table_count);
return false;
}
return checkAvailable(imm.table_count);
}
inline bool Validate(const byte* pc, WasmOpcode opcode,
SimdLaneImmediate<validate>& imm) {
uint8_t num_lanes = 0;
switch (opcode) {
case kExprF32x4ExtractLane:
case kExprF32x4ReplaceLane:
case kExprI32x4ExtractLane:
case kExprI32x4ReplaceLane:
num_lanes = 4;
break;
case kExprI16x8ExtractLane:
case kExprI16x8ReplaceLane:
num_lanes = 8;
break;
case kExprI8x16ExtractLane:
case kExprI8x16ReplaceLane:
num_lanes = 16;
break;
default:
UNREACHABLE();
break;
}
if (!VALIDATE(imm.lane >= 0 && imm.lane < num_lanes)) {
error(pc_ + 2, "invalid lane index");
return false;
} else {
return true;
}
}
inline bool Validate(const byte* pc, WasmOpcode opcode,
SimdShiftImmediate<validate>& imm) {
uint8_t max_shift = 0;
switch (opcode) {
case kExprI32x4Shl:
case kExprI32x4ShrS:
case kExprI32x4ShrU:
max_shift = 32;
break;
case kExprI16x8Shl:
case kExprI16x8ShrS:
case kExprI16x8ShrU:
max_shift = 16;
break;
case kExprI8x16Shl:
case kExprI8x16ShrS:
case kExprI8x16ShrU:
max_shift = 8;
break;
default:
UNREACHABLE();
break;
}
if (!VALIDATE(imm.shift >= 0 && imm.shift < max_shift)) {
error(pc_ + 2, "invalid shift amount");
return false;
} else {
return true;
}
}
inline bool Validate(const byte* pc,
Simd8x16ShuffleImmediate<validate>& imm) {
uint8_t max_lane = 0;
for (uint32_t i = 0; i < kSimd128Size; ++i) {
max_lane = std::max(max_lane, imm.shuffle[i]);
}
// Shuffle indices must be in [0..31] for a 16 lane shuffle.
if (!VALIDATE(max_lane <= 2 * kSimd128Size)) {
error(pc_ + 2, "invalid shuffle mask");
return false;
}
return true;
}
inline bool Complete(BlockTypeImmediate<validate>& imm) {
if (imm.type != kWasmVar) return true;
if (!VALIDATE((module_ && imm.sig_index < module_->signatures.size()))) {
return false;
}
imm.sig = module_->signatures[imm.sig_index];
return true;
}
inline bool Validate(BlockTypeImmediate<validate>& imm) {
if (!Complete(imm)) {
errorf(pc_, "block type index %u out of bounds (%zu signatures)",
imm.sig_index, module_ ? module_->signatures.size() : 0);
return false;
}
return true;
}
inline bool Validate(MemoryIndexImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr && module_->has_memory)) {
errorf(pc_ + 1, "memory instruction with no memory");
return false;
}
return true;
}
inline bool Validate(MemoryInitImmediate<validate>& imm) {
if (!Validate(imm.memory)) return false;
if (!VALIDATE(module_ != nullptr &&
imm.data_segment_index <
module_->num_declared_data_segments)) {
errorf(pc_ + 2, "invalid data segment index: %u", imm.data_segment_index);
return false;
}
return true;
}
inline bool Validate(MemoryDropImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr &&
imm.index < module_->num_declared_data_segments)) {
errorf(pc_ + 2, "invalid data segment index: %u", imm.index);
return false;
}
return true;
}
inline bool Validate(const byte* pc, TableIndexImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr && imm.index < module_->tables.size())) {
errorf(pc_ + 1, "invalid table index: %u", imm.index);
return false;
}
return true;
}
inline bool Validate(TableInitImmediate<validate>& imm) {
if (!Validate(pc_ + 1, imm.table)) return false;
if (!VALIDATE(module_ != nullptr &&
imm.elem_segment_index < module_->table_inits.size())) {
errorf(pc_ + 2, "invalid element segment index: %u",
imm.elem_segment_index);
return false;
}
return true;
}
inline bool Validate(TableDropImmediate<validate>& imm) {
if (!VALIDATE(module_ != nullptr &&
imm.index < module_->table_inits.size())) {
errorf(pc_ + 2, "invalid element segment index: %u", imm.index);
return false;
}
return true;
}
static uint32_t OpcodeLength(Decoder* decoder, const byte* pc) {
WasmOpcode opcode = static_cast<WasmOpcode>(*pc);
switch (opcode) {
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
FOREACH_LOAD_MEM_OPCODE(DECLARE_OPCODE_CASE)
FOREACH_STORE_MEM_OPCODE(DECLARE_OPCODE_CASE)
#undef DECLARE_OPCODE_CASE
{
MemoryAccessImmediate<validate> imm(decoder, pc, UINT32_MAX);
return 1 + imm.length;
}
case kExprRethrow:
case kExprBr:
case kExprBrIf: {
BreakDepthImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprSetGlobal:
case kExprGetGlobal: {
GlobalIndexImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprCallFunction: {
CallFunctionImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprCallIndirect: {
CallIndirectImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprTry:
case kExprIf: // fall through
case kExprLoop:
case kExprBlock: {
BlockTypeImmediate<validate> imm(kAllWasmFeatures, decoder, pc);
return 1 + imm.length;
}
case kExprThrow:
case kExprCatch: {
ExceptionIndexImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprSetLocal:
case kExprTeeLocal:
case kExprGetLocal: {
LocalIndexImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprBrTable: {
BranchTableImmediate<validate> imm(decoder, pc);
BranchTableIterator<validate> iterator(decoder, imm);
return 1 + iterator.length();
}
case kExprI32Const: {
ImmI32Immediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprI64Const: {
ImmI64Immediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprRefNull: {
return 1;
}
case kExprMemoryGrow:
case kExprMemorySize: {
MemoryIndexImmediate<validate> imm(decoder, pc);
return 1 + imm.length;
}
case kExprF32Const:
return 5;
case kExprF64Const:
return 9;
case kNumericPrefix: {
byte numeric_index =
decoder->read_u8<validate>(pc + 1, "numeric_index");
WasmOpcode opcode =
static_cast<WasmOpcode>(kNumericPrefix << 8 | numeric_index);
switch (opcode) {
case kExprI32SConvertSatF32:
case kExprI32UConvertSatF32:
case kExprI32SConvertSatF64:
case kExprI32UConvertSatF64:
case kExprI64SConvertSatF32:
case kExprI64UConvertSatF32:
case kExprI64SConvertSatF64:
case kExprI64UConvertSatF64:
return 2;
case kExprMemoryInit: {
MemoryInitImmediate<validate> imm(decoder, pc);
return 2 + imm.length;
}
case kExprMemoryDrop: {
MemoryDropImmediate<validate> imm(decoder, pc);
return 2 + imm.length;
}
case kExprMemoryCopy:
case kExprMemoryFill: {
MemoryIndexImmediate<validate> imm(decoder, pc + 1);
return 2 + imm.length;
}
case kExprTableInit: {
TableInitImmediate<validate> imm(decoder, pc);
return 2 + imm.length;
}
case kExprTableDrop: {
TableDropImmediate<validate> imm(decoder, pc);
return 2 + imm.length;
}
case kExprTableCopy: {
TableIndexImmediate<validate> imm(decoder, pc + 1);
return 2 + imm.length;
}
default:
decoder->error(pc, "invalid numeric opcode");
return 2;
}
}
case kSimdPrefix: {
byte simd_index = decoder->read_u8<validate>(pc + 1, "simd_index");
WasmOpcode opcode =
static_cast<WasmOpcode>(kSimdPrefix << 8 | simd_index);
switch (opcode) {
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
FOREACH_SIMD_0_OPERAND_OPCODE(DECLARE_OPCODE_CASE)
#undef DECLARE_OPCODE_CASE
return 2;
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
FOREACH_SIMD_1_OPERAND_OPCODE(DECLARE_OPCODE_CASE)
#undef DECLARE_OPCODE_CASE
return 3;
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
FOREACH_SIMD_MEM_OPCODE(DECLARE_OPCODE_CASE)
#undef DECLARE_OPCODE_CASE
{
MemoryAccessImmediate<validate> imm(decoder, pc + 1, UINT32_MAX);
return 2 + imm.length;
}
// Shuffles require a byte per lane, or 16 immediate bytes.
case kExprS8x16Shuffle:
return 2 + kSimd128Size;
default:
decoder->error(pc, "invalid SIMD opcode");
return 2;
}
}
case kAtomicPrefix: {
byte atomic_index = decoder->read_u8<validate>(pc + 1, "atomic_index");
WasmOpcode opcode =
static_cast<WasmOpcode>(kAtomicPrefix << 8 | atomic_index);
switch (opcode) {
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
FOREACH_ATOMIC_OPCODE(DECLARE_OPCODE_CASE)
#undef DECLARE_OPCODE_CASE
{
MemoryAccessImmediate<validate> imm(decoder, pc + 1, UINT32_MAX);
return 2 + imm.length;
}
default:
decoder->error(pc, "invalid Atomics opcode");
return 2;
}
}
default:
return 1;
}
}
std::pair<uint32_t, uint32_t> StackEffect(const byte* pc) {
WasmOpcode opcode = static_cast<WasmOpcode>(*pc);
// Handle "simple" opcodes with a fixed signature first.
FunctionSig* sig = WasmOpcodes::Signature(opcode);
if (!sig) sig = WasmOpcodes::AsmjsSignature(opcode);
if (sig) return {sig->parameter_count(), sig->return_count()};
#define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name:
// clang-format off
switch (opcode) {
case kExprSelect:
return {3, 1};
FOREACH_STORE_MEM_OPCODE(DECLARE_OPCODE_CASE)
return {2, 0};
FOREACH_LOAD_MEM_OPCODE(DECLARE_OPCODE_CASE)
case kExprTeeLocal:
case kExprMemoryGrow:
return {1, 1};
case kExprSetLocal:
case kExprSetGlobal:
case kExprDrop:
case kExprBrIf:
case kExprBrTable:
case kExprIf:
return {1, 0};
case kExprGetLocal:
case kExprGetGlobal:
case kExprI32Const:
case kExprI64Const:
case kExprF32Const:
case kExprF64Const:
case kExprRefNull:
case kExprMemorySize:
return {0, 1};
case kExprCallFunction: {
CallFunctionImmediate<validate> imm(this, pc);
CHECK(Complete(pc, imm));
return {imm.sig->parameter_count(), imm.sig->return_count()};
}
case kExprCallIndirect: {
CallIndirectImmediate<validate> imm(this, pc);
CHECK(Complete(pc, imm));
// Indirect calls pop an additional argument for the table index.
return {imm.sig->parameter_count() + 1,
imm.sig->return_count()};
}
case kExprBr:
case kExprBlock:
case kExprLoop:
case kExprEnd:
case kExprElse:
case kExprNop:
case kExprReturn:
case kExprUnreachable:
return {0, 0};
case kNumericPrefix:
case kAtomicPrefix:
case kSimdPrefix: {
opcode = static_cast<WasmOpcode>(opcode << 8 | *(pc + 1));
switch (opcode) {
FOREACH_SIMD_1_OPERAND_1_PARAM_OPCODE(DECLARE_OPCODE_CASE)
return {1, 1};
FOREACH_SIMD_1_OPERAND_2_PARAM_OPCODE(DECLARE_OPCODE_CASE)
FOREACH_SIMD_MASK_OPERAND_OPCODE(DECLARE_OPCODE_CASE)
return {2, 1};
default: {
sig = WasmOpcodes::Signature(opcode);
if (sig) {
return {sig->parameter_count(), sig->return_count()};
}
}
}
V8_FALLTHROUGH;
}
default:
V8_Fatal(__FILE__, __LINE__, "unimplemented opcode: %x (%s)", opcode,
WasmOpcodes::OpcodeName(opcode));
return {0, 0};
}
#undef DECLARE_OPCODE_CASE
// clang-format on
}
};
#define CALL_INTERFACE(name, ...) interface_.name(this, ##__VA_ARGS__)
#define CALL_INTERFACE_IF_REACHABLE(name, ...) \
do { \
DCHECK(!control_.empty()); \
if (VALIDATE(this->ok()) && control_.back().reachable()) { \
interface_.name(this, ##__VA_ARGS__); \
} \
} while (false)
#define CALL_INTERFACE_IF_PARENT_REACHABLE(name, ...) \
do { \
DCHECK(!control_.empty()); \
if (VALIDATE(this->ok()) && \
(control_.size() == 1 || control_at(1)->reachable())) { \
interface_.name(this, ##__VA_ARGS__); \
} \
} while (false)
template <Decoder::ValidateFlag validate, typename Interface>
class WasmFullDecoder : public WasmDecoder<validate> {
using Value = typename Interface::Value;
using Control = typename Interface::Control;
using MergeValues = Merge<Value>;
// All Value types should be trivially copyable for performance. We push, pop,
// and store them in local variables.
ASSERT_TRIVIALLY_COPYABLE(Value);
public:
template <typename... InterfaceArgs>
WasmFullDecoder(Zone* zone, const WasmModule* module,
const WasmFeatures& enabled, WasmFeatures* detected,
const FunctionBody& body, InterfaceArgs&&... interface_args)
: WasmDecoder<validate>(module, enabled, detected, body.sig, body.start,
body.end, body.offset),
zone_(zone),
interface_(std::forward<InterfaceArgs>(interface_args)...),
local_type_vec_(zone),
stack_(zone),
control_(zone),
args_(zone),
last_end_found_(false) {
this->local_types_ = &local_type_vec_;
}
Interface& interface() { return interface_; }
bool Decode() {
DCHECK(stack_.empty());
DCHECK(control_.empty());
base::ElapsedTimer decode_timer;
if (FLAG_trace_wasm_decode_time) {
decode_timer.Start();
}
if (this->end_ < this->pc_) {
this->error("function body end < start");
return false;
}
DCHECK_EQ(0, this->local_types_->size());
WasmDecoder<validate>::DecodeLocals(this->enabled_, this, this->sig_,
this->local_types_);
CALL_INTERFACE(StartFunction);
DecodeFunctionBody();
if (!this->failed()) CALL_INTERFACE(FinishFunction);
if (this->failed()) return this->TraceFailed();
if (!control_.empty()) {
// Generate a better error message whether the unterminated control
// structure is the function body block or an innner structure.
if (control_.size() > 1) {
this->error(control_.back().pc, "unterminated control structure");
} else {
this->error("function body must end with \"end\" opcode");
}
return TraceFailed();
}
if (!last_end_found_) {
this->error("function body must end with \"end\" opcode");
return false;
}
if (FLAG_trace_wasm_decode_time) {
double ms = decode_timer.Elapsed().InMillisecondsF();
PrintF("wasm-decode %s (%0.3f ms)\n\n",
VALIDATE(this->ok()) ? "ok" : "failed", ms);
} else {
TRACE("wasm-decode %s\n\n", VALIDATE(this->ok()) ? "ok" : "failed");
}
return true;
}
bool TraceFailed() {
TRACE("wasm-error module+%-6d func+%d: %s\n\n", this->error_offset_,
this->GetBufferRelativeOffset(this->error_offset_),
this->error_msg_.c_str());
return false;
}
const char* SafeOpcodeNameAt(const byte* pc) {
if (pc >= this->end_) return "<end>";
return WasmOpcodes::OpcodeName(static_cast<WasmOpcode>(*pc));
}
inline Zone* zone() const { return zone_; }
inline uint32_t NumLocals() {
return static_cast<uint32_t>(local_type_vec_.size());
}
inline ValueType GetLocalType(uint32_t index) {
return local_type_vec_[index];
}
inline WasmCodePosition position() {
int offset = static_cast<int>(this->pc_ - this->start_);
DCHECK_EQ(this->pc_ - this->start_, offset); // overflows cannot happen
return offset;
}
inline uint32_t control_depth() const {
return static_cast<uint32_t>(control_.size());
}
inline Control* control_at(uint32_t depth) {
DCHECK_GT(control_.size(), depth);
return &control_.back() - depth;
}
inline uint32_t stack_size() const {
DCHECK_GE(kMaxUInt32, stack_.size());
return static_cast<uint32_t>(stack_.size());
}
inline Value* stack_value(uint32_t depth) {
DCHECK_LT(0, depth);
DCHECK_GE(stack_.size(), depth);
return &*(stack_.end() - depth);
}
private:
Zone* zone_;
Interface interface_;
ZoneVector<ValueType> local_type_vec_; // types of local variables.
ZoneVector<Value> stack_; // stack of values.
ZoneVector<Control> control_; // stack of blocks, loops, and ifs.
ZoneVector<Value> args_; // parameters of current block or call
bool last_end_found_;
bool CheckHasMemory() {
if (!VALIDATE(this->module_->has_memory)) {
this->error(this->pc_ - 1, "memory instruction with no memory");
return false;
}
return true;
}
bool CheckHasSharedMemory() {
if (!VALIDATE(this->module_->has_shared_memory)) {
this->error(this->pc_ - 1, "Atomic opcodes used without shared memory");
return false;
}
return true;
}
class TraceLine {
public:
static constexpr int kMaxLen = 512;
~TraceLine() {
if (!FLAG_trace_wasm_decoder) return;
PrintF("%.*s\n", len_, buffer_);
}
// Appends a formatted string.
PRINTF_FORMAT(2, 3)
void Append(const char* format, ...) {
if (!FLAG_trace_wasm_decoder) return;
va_list va_args;
va_start(va_args, format);
size_t remaining_len = kMaxLen - len_;
Vector<char> remaining_msg_space(buffer_ + len_, remaining_len);
int len = VSNPrintF(remaining_msg_space, format, va_args);
va_end(va_args);
len_ += len < 0 ? remaining_len : len;
}
private:
char buffer_[kMaxLen];
int len_ = 0;
};
// Decodes the body of a function.
void DecodeFunctionBody() {
TRACE("wasm-decode %p...%p (module+%u, %d bytes)\n",
reinterpret_cast<const void*>(this->start()),
reinterpret_cast<const void*>(this->end()), this->pc_offset(),
static_cast<int>(this->end() - this->start()));
// Set up initial function block.
{
auto* c = PushBlock();
InitMerge(&c->start_merge, 0, [](uint32_t) -> Value { UNREACHABLE(); });
InitMerge(&c->end_merge,
static_cast<uint32_t>(this->sig_->return_count()),
[&] (uint32_t i) {
return Value::New(this->pc_, this->sig_->GetReturn(i)); });
CALL_INTERFACE(StartFunctionBody, c);
}
while (this->pc_ < this->end_) { // decoding loop.
uint32_t len = 1;
WasmOpcode opcode = static_cast<WasmOpcode>(*this->pc_);
CALL_INTERFACE_IF_REACHABLE(NextInstruction, opcode);
#if DEBUG
TraceLine trace_msg;
#define TRACE_PART(...) trace_msg.Append(__VA_ARGS__)
if (!WasmOpcodes::IsPrefixOpcode(opcode)) {
TRACE_PART(TRACE_INST_FORMAT, startrel(this->pc_),
WasmOpcodes::OpcodeName(opcode));
}
#else
#define TRACE_PART(...)
#endif
FunctionSig* sig = const_cast<FunctionSig*>(kSimpleOpcodeSigs[opcode]);
if (sig) {
BuildSimpleOperator(opcode, sig);
} else {
// Complex bytecode.
switch (opcode) {
case kExprNop:
break;
case kExprBlock: {
BlockTypeImmediate<validate> imm(this->enabled_, this, this->pc_);
if (!this->Validate(imm)) break;
PopArgs(imm.sig);
auto* block = PushBlock();
SetBlockType(block, imm);
CALL_INTERFACE_IF_REACHABLE(Block, block);
PushMergeValues(block, &block->start_merge);
len = 1 + imm.length;
break;
}
case kExprRethrow: {
CHECK_PROTOTYPE_OPCODE(eh);
BreakDepthImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm, control_.size())) break;
Control* c = control_at(imm.depth);
if (!VALIDATE(c->is_try_catchall() || c->is_try_catch())) {
this->error("rethrow not targeting catch or catch-all");
break;
}
CALL_INTERFACE_IF_REACHABLE(Rethrow, c);
len = 1 + imm.length;
EndControl();
break;
}
case kExprThrow: {
CHECK_PROTOTYPE_OPCODE(eh);
ExceptionIndexImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
if (!this->Validate(this->pc_, imm)) break;
PopArgs(imm.exception->ToFunctionSig());
CALL_INTERFACE_IF_REACHABLE(Throw, imm, VectorOf(args_));
EndControl();
break;
}
case kExprTry: {
CHECK_PROTOTYPE_OPCODE(eh);
BlockTypeImmediate<validate> imm(this->enabled_, this, this->pc_);
if (!this->Validate(imm)) break;
PopArgs(imm.sig);
auto* try_block = PushTry();
SetBlockType(try_block, imm);
len = 1 + imm.length;
CALL_INTERFACE_IF_REACHABLE(Try, try_block);
PushMergeValues(try_block, &try_block->start_merge);
break;
}
case kExprCatch: {
CHECK_PROTOTYPE_OPCODE(eh);
ExceptionIndexImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm)) break;
len = 1 + imm.length;
if (!VALIDATE(!control_.empty())) {
this->error("catch does not match any try");
break;
}
Control* c = &control_.back();
if (!VALIDATE(c->is_try())) {
this->error("catch does not match any try");
break;
}
if (!VALIDATE(!c->is_try_catchall())) {
this->error("catch after catch-all for try");
break;
}
c->kind = kControlTryCatch;
FallThruTo(c);
stack_.resize(c->stack_depth);
const WasmExceptionSig* sig = imm.exception->sig;
for (size_t i = 0, e = sig->parameter_count(); i < e; ++i) {
Push(sig->GetParam(i));
}
Vector<Value> values(stack_.data() + c->stack_depth,
sig->parameter_count());
c->reachability = control_at(1)->innerReachability();
CALL_INTERFACE_IF_PARENT_REACHABLE(CatchException, imm, c, values);
break;
}
case kExprCatchAll: {
CHECK_PROTOTYPE_OPCODE(eh);
if (!VALIDATE(!control_.empty())) {
this->error("catch-all does not match any try");
break;
}
Control* c = &control_.back();
if (!VALIDATE(c->is_try())) {
this->error("catch-all does not match any try");
break;
}
if (!VALIDATE(!c->is_try_catchall())) {
this->error("catch-all already present for try");
break;
}
c->kind = kControlTryCatchAll;
FallThruTo(c);
stack_.resize(c->stack_depth);
c->reachability = control_at(1)->innerReachability();
CALL_INTERFACE_IF_PARENT_REACHABLE(CatchAll, c);
break;
}
case kExprLoop: {
BlockTypeImmediate<validate> imm(this->enabled_, this, this->pc_);
if (!this->Validate(imm)) break;
PopArgs(imm.sig);
auto* block = PushLoop();
SetBlockType(&control_.back(), imm);
len = 1 + imm.length;
CALL_INTERFACE_IF_REACHABLE(Loop, block);
PushMergeValues(block, &block->start_merge);
break;
}
case kExprIf: {
BlockTypeImmediate<validate> imm(this->enabled_, this, this->pc_);
if (!this->Validate(imm)) break;
auto cond = Pop(0, kWasmI32);
PopArgs(imm.sig);
if (!VALIDATE(this->ok())) break;
auto* if_block = PushIf();
SetBlockType(if_block, imm);
CALL_INTERFACE_IF_REACHABLE(If, cond, if_block);
len = 1 + imm.length;
PushMergeValues(if_block, &if_block->start_merge);
break;
}
case kExprElse: {
if (!VALIDATE(!control_.empty())) {
this->error("else does not match any if");
break;
}
Control* c = &control_.back();
if (!VALIDATE(c->is_if())) {
this->error(this->pc_, "else does not match an if");
break;
}
if (c->is_if_else()) {
this->error(this->pc_, "else already present for if");
break;
}
if (!TypeCheckFallThru(c)) break;
c->kind = kControlIfElse;
CALL_INTERFACE_IF_PARENT_REACHABLE(Else, c);
if (c->reachable()) c->end_merge.reached = true;
PushMergeValues(c, &c->start_merge);
c->reachability = control_at(1)->innerReachability();
break;
}
case kExprEnd: {
if (!VALIDATE(!control_.empty())) {
this->error("end does not match any if, try, or block");
break;
}
Control* c = &control_.back();
if (!VALIDATE(!c->is_incomplete_try())) {
this->error(this->pc_, "missing catch or catch-all in try");
break;
}
if (c->is_onearmed_if()) {
if (!VALIDATE(c->end_merge.arity == c->start_merge.arity)) {
this->error(
c->pc,
"start-arity and end-arity of one-armed if must match");
break;
}
}
if (c->is_try_catch()) {
// Emulate catch-all + re-throw.
FallThruTo(c);
c->reachability = control_at(1)->innerReachability();
CALL_INTERFACE_IF_PARENT_REACHABLE(CatchAll, c);
CALL_INTERFACE_IF_REACHABLE(Rethrow, c);
EndControl();
}
FallThruTo(c);
// A loop just leaves the values on the stack.
if (!c->is_loop()) PushMergeValues(c, &c->end_merge);
if (control_.size() == 1) {
// If at the last (implicit) control, check we are at end.
if (!VALIDATE(this->pc_ + 1 == this->end_)) {
this->error(this->pc_ + 1, "trailing code after function end");
break;
}
last_end_found_ = true;
// The result of the block is the return value.
TRACE_PART("\n" TRACE_INST_FORMAT, startrel(this->pc_),
"(implicit) return");
DoReturn(c, true);
}
PopControl(c);
break;
}
case kExprSelect: {
auto cond = Pop(2, kWasmI32);
auto fval = Pop();
auto tval = Pop(0, fval.type);
auto* result = Push(tval.type == kWasmVar ? fval.type : tval.type);
CALL_INTERFACE_IF_REACHABLE(Select, cond, fval, tval, result);
break;
}
case kExprBr: {
BreakDepthImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm, control_.size())) break;
Control* c = control_at(imm.depth);
if (imm.depth == control_.size() - 1) {
DoReturn(c, false);
} else {
if (!TypeCheckBreak(c)) break;
if (control_.back().reachable()) {
CALL_INTERFACE(Br, c);
c->br_merge()->reached = true;
}
}
len = 1 + imm.length;
EndControl();
break;
}
case kExprBrIf: {
BreakDepthImmediate<validate> imm(this, this->pc_);
auto cond = Pop(0, kWasmI32);
if (this->failed()) break;
if (!this->Validate(this->pc_, imm, control_.size())) break;
Control* c = control_at(imm.depth);
if (!TypeCheckBreak(c)) break;
if (control_.back().reachable()) {
CALL_INTERFACE(BrIf, cond, c);
c->br_merge()->reached = true;
}
len = 1 + imm.length;
break;
}
case kExprBrTable: {
BranchTableImmediate<validate> imm(this, this->pc_);
BranchTableIterator<validate> iterator(this, imm);
auto key = Pop(0, kWasmI32);
if (this->failed()) break;
if (!this->Validate(this->pc_, imm, control_.size())) break;
uint32_t br_arity = 0;
std::vector<bool> br_targets(control_.size());
while (iterator.has_next()) {
const uint32_t i = iterator.cur_index();
const byte* pos = iterator.pc();
uint32_t target = iterator.next();
if (!VALIDATE(target < control_.size())) {
this->errorf(pos,
"improper branch in br_table target %u (depth %u)",
i, target);
break;
}
// Avoid redundant break target checks.
if (br_targets[target]) continue;
br_targets[target] = true;
// Check that label types match up.
Control* c = control_at(target);
uint32_t arity = c->br_merge()->arity;
if (i == 0) {
br_arity = arity;
} else if (!VALIDATE(br_arity == arity)) {
this->errorf(pos,
"inconsistent arity in br_table target %u"
" (previous was %u, this one %u)",
i, br_arity, arity);
}
if (!TypeCheckBreak(c)) break;
}
if (this->failed()) break;
if (control_.back().reachable()) {
CALL_INTERFACE(BrTable, imm, key);
for (uint32_t depth = control_depth(); depth-- > 0;) {
if (!br_targets[depth]) continue;
control_at(depth)->br_merge()->reached = true;
}
}
len = 1 + iterator.length();
EndControl();
break;
}
case kExprReturn: {
DoReturn(&control_.back(), false);
break;
}
case kExprUnreachable: {
CALL_INTERFACE_IF_REACHABLE(Unreachable);
EndControl();
break;
}
case kExprI32Const: {
ImmI32Immediate<validate> imm(this, this->pc_);
auto* value = Push(kWasmI32);
CALL_INTERFACE_IF_REACHABLE(I32Const, value, imm.value);
len = 1 + imm.length;
break;
}
case kExprI64Const: {
ImmI64Immediate<validate> imm(this, this->pc_);
auto* value = Push(kWasmI64);
CALL_INTERFACE_IF_REACHABLE(I64Const, value, imm.value);
len = 1 + imm.length;
break;
}
case kExprF32Const: {
ImmF32Immediate<validate> imm(this, this->pc_);
auto* value = Push(kWasmF32);
CALL_INTERFACE_IF_REACHABLE(F32Const, value, imm.value);
len = 1 + imm.length;
break;
}
case kExprF64Const: {
ImmF64Immediate<validate> imm(this, this->pc_);
auto* value = Push(kWasmF64);
CALL_INTERFACE_IF_REACHABLE(F64Const, value, imm.value);
len = 1 + imm.length;
break;
}
case kExprRefNull: {
CHECK_PROTOTYPE_OPCODE(anyref);
auto* value = Push(kWasmAnyRef);
CALL_INTERFACE_IF_REACHABLE(RefNull, value);
len = 1;
break;
}
case kExprGetLocal: {
LocalIndexImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm)) break;
auto* value = Push(imm.type);
CALL_INTERFACE_IF_REACHABLE(GetLocal, value, imm);
len = 1 + imm.length;
break;
}
case kExprSetLocal: {
LocalIndexImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm)) break;
auto value = Pop(0, local_type_vec_[imm.index]);
CALL_INTERFACE_IF_REACHABLE(SetLocal, value, imm);
len = 1 + imm.length;
break;
}
case kExprTeeLocal: {
LocalIndexImmediate<validate> imm(this, this->pc_);
if (!this->Validate(this->pc_, imm)) break;
auto value = Pop(0, local_type_vec_[imm.index]);
auto* result = Push(value.type);
CALL_INTERFACE_IF_REACHABLE(TeeLocal, value, result, imm);
len = 1 + imm.length;
break;
}
case kExprDrop: {
auto value = Pop();
CALL_INTERFACE_IF_REACHABLE(Drop, value);
break;
}
case kExprGetGlobal: {
GlobalIndexImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
if (!this->Validate(this->pc_, imm)) break;
auto* result = Push(imm.type);
CALL_INTERFACE_IF_REACHABLE(GetGlobal, result, imm);
break;
}
case kExprSetGlobal: {
GlobalIndexImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
if (!this->Validate(this->pc_, imm)) break;
if (!VALIDATE(imm.global->mutability)) {
this->errorf(this->pc_, "immutable global #%u cannot be assigned",
imm.index);
break;
}
auto value = Pop(0, imm.type);
CALL_INTERFACE_IF_REACHABLE(SetGlobal, value, imm);
break;
}
case kExprI32LoadMem8S:
len = 1 + DecodeLoadMem(LoadType::kI32Load8S);
break;
case kExprI32LoadMem8U:
len = 1 + DecodeLoadMem(LoadType::kI32Load8U);
break;
case kExprI32LoadMem16S:
len = 1 + DecodeLoadMem(LoadType::kI32Load16S);
break;
case kExprI32LoadMem16U:
len = 1 + DecodeLoadMem(LoadType::kI32Load16U);
break;
case kExprI32LoadMem:
len = 1 + DecodeLoadMem(LoadType::kI32Load);
break;
case kExprI64LoadMem8S:
len = 1 + DecodeLoadMem(LoadType::kI64Load8S);
break;
case kExprI64LoadMem8U:
len = 1 + DecodeLoadMem(LoadType::kI64Load8U);
break;
case kExprI64LoadMem16S:
len = 1 + DecodeLoadMem(LoadType::kI64Load16S);
break;
case kExprI64LoadMem16U:
len = 1 + DecodeLoadMem(LoadType::kI64Load16U);
break;
case kExprI64LoadMem32S:
len = 1 + DecodeLoadMem(LoadType::kI64Load32S);
break;
case kExprI64LoadMem32U:
len = 1 + DecodeLoadMem(LoadType::kI64Load32U);
break;
case kExprI64LoadMem:
len = 1 + DecodeLoadMem(LoadType::kI64Load);
break;
case kExprF32LoadMem:
len = 1 + DecodeLoadMem(LoadType::kF32Load);
break;
case kExprF64LoadMem:
len = 1 + DecodeLoadMem(LoadType::kF64Load);
break;
case kExprI32StoreMem8:
len = 1 + DecodeStoreMem(StoreType::kI32Store8);
break;
case kExprI32StoreMem16:
len = 1 + DecodeStoreMem(StoreType::kI32Store16);
break;
case kExprI32StoreMem:
len = 1 + DecodeStoreMem(StoreType::kI32Store);
break;
case kExprI64StoreMem8:
len = 1 + DecodeStoreMem(StoreType::kI64Store8);
break;
case kExprI64StoreMem16:
len = 1 + DecodeStoreMem(StoreType::kI64Store16);
break;
case kExprI64StoreMem32:
len = 1 + DecodeStoreMem(StoreType::kI64Store32);
break;
case kExprI64StoreMem:
len = 1 + DecodeStoreMem(StoreType::kI64Store);
break;
case kExprF32StoreMem:
len = 1 + DecodeStoreMem(StoreType::kF32Store);
break;
case kExprF64StoreMem:
len = 1 + DecodeStoreMem(StoreType::kF64Store);
break;
case kExprMemoryGrow: {
if (!CheckHasMemory()) break;
MemoryIndexImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
DCHECK_NOT_NULL(this->module_);
if (!VALIDATE(this->module_->origin == kWasmOrigin)) {
this->error("grow_memory is not supported for asmjs modules");
break;
}
auto value = Pop(0, kWasmI32);
auto* result = Push(kWasmI32);
CALL_INTERFACE_IF_REACHABLE(MemoryGrow, value, result);
break;
}
case kExprMemorySize: {
if (!CheckHasMemory()) break;
MemoryIndexImmediate<validate> imm(this, this->pc_);
auto* result = Push(kWasmI32);
len = 1 + imm.length;
CALL_INTERFACE_IF_REACHABLE(CurrentMemoryPages, result);
break;
}
case kExprCallFunction: {
CallFunctionImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
if (!this->Validate(this->pc_, imm)) break;
// TODO(clemensh): Better memory management.
PopArgs(imm.sig);
auto* returns = PushReturns(imm.sig);
CALL_INTERFACE_IF_REACHABLE(CallDirect, imm, args_.data(), returns);
break;
}
case kExprCallIndirect: {
CallIndirectImmediate<validate> imm(this, this->pc_);
len = 1 + imm.length;
if (!this->Validate(this->pc_, imm)) break;
auto index = Pop(0, kWasmI32);
PopArgs(imm.sig);
auto* returns = PushReturns(imm.sig);
CALL_INTERFACE_IF_REACHABLE(CallIndirect, index, imm, args_.data(),
returns);
break;
}
case kNumericPrefix: {
++len;
byte numeric_index = this->template read_u8<validate>(
this->pc_ + 1, "numeric index");
opcode = static_cast<WasmOpcode>(opcode << 8 | numeric_index);
if (opcode < kExprMemoryInit) {
CHECK_PROTOTYPE_OPCODE(sat_f2i_conversions);
} else {
CHECK_PROTOTYPE_OPCODE(bulk_memory);
}
TRACE_PART(TRACE_INST_FORMAT, startrel(this->pc_),
WasmOpcodes::OpcodeName(opcode));
len += DecodeNumericOpcode(opcode);
break;
}
case kSimdPrefix: {
CHECK_PROTOTYPE_OPCODE(simd);
len++;
byte simd_index =
this->template read_u8<validate>(this->pc_ + 1, "simd index");
opcode = static_cast<WasmOpcode>(opcode << 8 | simd_index);
TRACE_PART(TRACE_INST_FORMAT, startrel(this->pc_),
WasmOpcodes::OpcodeName(opcode));
len += DecodeSimdOpcode(opcode);
break;
}
case kAtomicPrefix: {
CHECK_PROTOTYPE_OPCODE(threads);
if (!CheckHasSharedMemory()) break;
len++;
byte atomic_index =
this->template read_u8<validate>(this->pc_ + 1, "atomic index");
opcode = static_cast<WasmOpcode>(opcode << 8 | atomic_index);
TRACE_PART(TRACE_INST_FORMAT, startrel(this->pc_),
WasmOpcodes::OpcodeName(opcode));
len += DecodeAtomicOpcode(opcode);
break;
}
// Note that prototype opcodes are not handled in the fastpath
// above this switch, to avoid checking a feature flag.
#define SIMPLE_PROTOTYPE_CASE(name, opc, sig) \
case kExpr##name: /* fallthrough */
FOREACH_SIMPLE_PROTOTYPE_OPCODE(SIMPLE_PROTOTYPE_CASE)
#undef SIMPLE_PROTOTYPE_CASE
BuildSimplePrototypeOperator(opcode);
break;
default: {
// Deal with special asmjs opcodes.
if (this->module_ != nullptr &&
this->module_->origin == kAsmJsOrigin) {
sig = WasmOpcodes::AsmjsSignature(opcode);
if (sig) {
BuildSimpleOperator(opcode, sig);
}
} else {
this->error("Invalid opcode");
return;
}
}
}
}
#if DEBUG
if (FLAG_trace_wasm_decoder) {
TRACE_PART(" ");
for (Control& c : control_) {
switch (c.kind) {
case kControlIf:
TRACE_PART("I");
break;
case kControlBlock:
TRACE_PART("B");
break;
case kControlLoop:
TRACE_PART("L");
break;
case kControlTry:
TRACE_PART("T");
break;
default:
break;
}
if (c.start_merge.arity) TRACE_PART("%u-", c.start_merge.arity);
TRACE_PART("%u", c.end_merge.arity);
if (!c.reachable()) TRACE_PART("%c", c.unreachable() ? '*' : '#');
}
TRACE_PART(" | ");
for (size_t i = 0; i < stack_.size(); ++i) {
auto& val = stack_[i];
WasmOpcode opcode = static_cast<WasmOpcode>(*val.pc);
if (WasmOpcodes::IsPrefixOpcode(opcode)) {
opcode = static_cast<WasmOpcode>(opcode << 8 | *(val.pc + 1));
}
TRACE_PART(" %c@%d:%s", ValueTypes::ShortNameOf(val.type),
static_cast<int>(val.pc - this->start_),
WasmOpcodes::OpcodeName(opcode));
// If the decoder failed, don't try to decode the immediates, as this
// can trigger a DCHECK failure.
if (this->failed()) continue;
switch (opcode) {
case kExprI32Const: {
ImmI32Immediate<Decoder::kNoValidate> imm(this, val.pc);
TRACE_PART("[%d]", imm.value);
break;
}
case kExprGetLocal:
case kExprSetLocal:
case kExprTeeLocal: {
LocalIndexImmediate<Decoder::kNoValidate> imm(this, val.pc);
TRACE_PART("[%u]", imm.index);
break;
}
case kExprGetGlobal:
case kExprSetGlobal: {
GlobalIndexImmediate<Decoder::kNoValidate> imm(this, val.pc);
TRACE_PART("[%u]", imm.index);
break;
}
default:
break;
}
}
}
#endif
this->pc_ += len;
} // end decode loop
if (!VALIDATE(this->pc_ == this->end_) && this->ok()) {
this->error("Beyond end of code");
}
}
void EndControl() {
DCHECK(!control_.empty());
auto* current = &control_.back();
stack_.resize(current->stack_depth);
CALL_INTERFACE_IF_REACHABLE(EndControl, current);
current->reachability = kUnreachable;
}
template<typename func>
void InitMerge(Merge<Value>* merge, uint32_t arity, func get_val) {
merge->arity = arity;
if (arity == 1) {
merge->vals.first = get_val(0);
} else if (arity > 1) {
merge->vals.array = zone_->NewArray<Value>(arity);
for (uint32_t i = 0; i < arity; i++) {
merge->vals.array[i] = get_val(i);
}
}
}
void SetBlockType(Control* c, BlockTypeImmediate<validate>& imm) {
DCHECK_EQ(imm.in_arity(), this->args_.size());
const byte* pc = this->pc_;
Value* args = this->args_.data();
InitMerge(&c->end_merge, imm.out_arity(), [pc, &imm](uint32_t i) {
return Value::New(pc, imm.out_type(i));
});
InitMerge(&c->start_merge, imm.in_arity(),
[args](uint32_t i) { return args[i]; });
}
// Pops arguments as required by signature into {args_}.
V8_INLINE void PopArgs(FunctionSig* sig) {
int count = sig ? static_cast<int>(sig->parameter_count()) : 0;
args_.resize(count);
for (int i = count - 1; i >= 0; --i) {
args_[i] = Pop(i, sig->GetParam(i));
}
}
ValueType GetReturnType(FunctionSig* sig) {
DCHECK_GE(1, sig->return_count());
return sig->return_count() == 0 ? kWasmStmt : sig->GetReturn();
}
Control* PushControl(Control&& new_control) {
Reachability reachability =
control_.empty() ? kReachable : control_.back().innerReachability();
control_.emplace_back(std::move(new_control));
Control* c = &control_.back();
c->reachability = reachability;
c->start_merge.reached = c->reachable();
return c;
}
Control* PushBlock() {
return PushControl(Control::Block(this->pc_, stack_size()));
}
Control* PushLoop() {
return PushControl(Control::Loop(this->pc_, stack_size()));
}
Control* PushIf() {
return PushControl(Control::If(this->pc_, stack_size()));
}
Control* PushTry() {
// current_catch_ = static_cast<int32_t>(control_.size() - 1);
return PushControl(Control::Try(this->pc_, stack_size()));
}
void PopControl(Control* c) {
DCHECK_EQ(c, &control_.back());
CALL_INTERFACE_IF_PARENT_REACHABLE(PopControl, c);
bool reached = c->end_merge.reached || c->is_onearmed_if();
control_.pop_back();
// If the parent block was reachable before, but the popped control does not
// return to here, this block becomes indirectly unreachable.
if (!control_.empty() && !reached && control_.back().reachable()) {
control_.back().reachability = kSpecOnlyReachable;
}
}
int DecodeLoadMem(LoadType type, int prefix_len = 0) {
if (!CheckHasMemory()) return 0;
MemoryAccessImmediate<validate> imm(this, this->pc_ + prefix_len,
type.size_log_2());
auto index = Pop(0, kWasmI32);
auto* result = Push(type.value_type());
CALL_INTERFACE_IF_REACHABLE(LoadMem, type, imm, index, result);
return imm.length;
}
int DecodeStoreMem(StoreType store, int prefix_len = 0) {
if (!CheckHasMemory()) return 0;
MemoryAccessImmediate<validate> imm(this, this->pc_ + prefix_len,
store.size_log_2());
auto value = Pop(1, store.value_type());
auto index = Pop(0, kWasmI32);
CALL_INTERFACE_IF_REACHABLE(StoreMem, store, imm, index, value);
return imm.length;
}
uint32_t SimdExtractLane(WasmOpcode opcode, ValueType type) {
SimdLaneImmediate<validate> imm(this, this->pc_);
if (this->Validate(this->pc_, opcode, imm)) {
Value inputs[] = {Pop(0, kWasmS128)};
auto* result = Push(type);
CALL_INTERFACE_IF_REACHABLE(SimdLaneOp, opcode, imm, ArrayVector(inputs),
result);
}
return imm.length;
}
uint32_t SimdReplaceLane(WasmOpcode opcode, ValueType type) {
SimdLaneImmediate<validate> imm(this, this->pc_);
if (this->Validate(this->pc_, opcode, imm)) {
Value inputs[2];
inputs[1] = Pop(1, type);
inputs[0] = Pop(0, kWasmS128);
auto* result = Push(kWasmS128);
CALL_INTERFACE_IF_REACHABLE(SimdLaneOp, opcode, imm, ArrayVector(inputs),
result);
}
return imm.length;
}
uint32_t SimdShiftOp(WasmOpcode opcode) {
SimdShiftImmediate<validate> imm(this, this->pc_);
if (this->Validate(this->pc_, opcode, imm)) {
auto input = Pop(0, kWasmS128);
auto* result = Push(kWasmS128);
CALL_INTERFACE_IF_REACHABLE(SimdShiftOp, opcode, imm, input, result);
}
return imm.length;
}
uint32_t Simd8x16ShuffleOp() {
Simd8x16ShuffleImmediate<validate> imm(this, this->pc_);
if (this->Validate(this->pc_, imm)) {
auto input1 = Pop(1, kWasmS128);
auto input0 = Pop(0, kWasmS128);
auto* result = Push(kWasmS128);
CALL_INTERFACE_IF_REACHABLE(Simd8x16ShuffleOp, imm, input0, input1,
result);
}
return 16;
}
uint32_t DecodeSimdOpcode(WasmOpcode opcode) {
uint32_t len = 0;
switch (opcode) {
case kExprF32x4ExtractLane: {
len = SimdExtractLane(opcode, kWasmF32);
break;
}
case kExprI32x4ExtractLane:
case kExprI16x8ExtractLane:
case kExprI8x16ExtractLane: {
len = SimdExtractLane(opcode, kWasmI32);
break;
}
case kExprF32x4ReplaceLane: {
len = SimdReplaceLane(opcode, kWasmF32);
break;
}
case kExprI32x4ReplaceLane:
case kExprI16x8ReplaceLane:
case kExprI8x16ReplaceLane: {
len = SimdReplaceLane(opcode, kWasmI32);
break;
}
case kExprI32x4Shl:
case kExprI32x4ShrS:
case kExprI32x4ShrU:
case kExprI16x8Shl:
case kExprI16x8ShrS:
case kExprI16x8ShrU:
case kExprI8x16Shl:
case kExprI8x16ShrS:
case kExprI8x16ShrU: {
len = SimdShiftOp(opcode);
break;
}
case kExprS8x16Shuffle: {
len = Simd8x16ShuffleOp();
break;
}
case kExprS128LoadMem:
len = DecodeLoadMem(LoadType::kS128Load, 1);
break;
case kExprS128StoreMem:
len = DecodeStoreMem(StoreType::kS128Store, 1);
break;
default: {
FunctionSig* sig = WasmOpcodes::Signature(opcode);
if (!VALIDATE(sig != nullptr)) {
this->error("invalid simd opcode");
break;
}
PopArgs(sig);
auto* results =
sig->return_count() == 0 ? nullptr : Push(GetReturnType(sig));
CALL_INTERFACE_IF_REACHABLE(SimdOp, opcode, VectorOf(args_), results);
}
}
return len;
}
uint32_t DecodeAtomicOpcode(WasmOpcode opcode) {
uint32_t len = 0;
ValueType ret_type;
FunctionSig* sig = WasmOpcodes::Signature(opcode);
if (sig != nullptr) {
MachineType memtype;
switch (opcode) {
#define CASE_ATOMIC_STORE_OP(Name, Type) \
case kExpr##Name: { \
memtype = MachineType::Type(); \
ret_type = kWasmStmt; \
break; \
}
ATOMIC_STORE_OP_LIST(CASE_ATOMIC_STORE_OP)
#undef CASE_ATOMIC_OP
#define CASE_ATOMIC_OP(Name, Type) \
case kExpr##Name: { \
memtype = MachineType::Type(); \
ret_type = GetReturnType(sig); \
break; \
}
ATOMIC_OP_LIST(CASE_ATOMIC_OP)
#undef CASE_ATOMIC_OP
default:
this->error("invalid atomic opcode");
return 0;
}
MemoryAccessImmediate<validate> imm(
this, this->pc_ + 1, ElementSizeLog2Of(memtype.representation()));
len += imm.length;
PopArgs(sig);
auto result = ret_type == kWasmStmt ? nullptr : Push(GetReturnType(sig));
CALL_INTERFACE_IF_REACHABLE(AtomicOp, opcode, VectorOf(args_), imm,
result);
} else {
this->error("invalid atomic opcode");
}
return len;
}
unsigned DecodeNumericOpcode(WasmOpcode opcode) {
unsigned len = 0;
FunctionSig* sig = WasmOpcodes::Signature(opcode);
if (sig != nullptr) {
switch (opcode) {
case kExprI32SConvertSatF32:
case kExprI32UConvertSatF32:
case kExprI32SConvertSatF64:
case kExprI32UConvertSatF64:
case kExprI64SConvertSatF32:
case kExprI64UConvertSatF32:
case kExprI64SConvertSatF64:
case kExprI64UConvertSatF64:
BuildSimpleOperator(opcode, sig);
break;
case kExprMemoryInit: {
MemoryInitImmediate<validate> imm(this, this->pc_);
if (!this->Validate(imm)) break;
len += imm.length;
PopArgs(sig);
CALL_INTERFACE_IF_REACHABLE(MemoryInit, imm, VectorOf(args_));
break;
}
case kExprMemoryDrop: {
MemoryDropImmediate<validate> imm(this, this->pc_);
if (!this->Validate(imm)) break;
len += imm.length;
CALL_INTERFACE_IF_REACHABLE(MemoryDrop, imm);
break;
}
case kExprMemoryCopy: {
MemoryIndexImmediate<validate> imm(this, this->pc_ + 1);
if (!this->Validate(imm)) break;
len += imm.length;
PopArgs(sig);
CALL_INTERFACE_IF_REACHABLE(MemoryCopy, imm, VectorOf(args_));
break;
}
case kExprMemoryFill: {
MemoryIndexImmediate<validate> imm(this, this->pc_ + 1);
if (!this->Validate(imm)) break;
len += imm.length;
PopArgs(sig);
CALL_INTERFACE_IF_REACHABLE(MemoryFill, imm, VectorOf(args_));
break;
}
case kExprTableInit: {
TableInitImmediate<validate> imm(this, this->pc_);
if (!this->Validate(imm)) break;
len += imm.length;
PopArgs(sig);
CALL_INTERFACE_IF_REACHABLE(TableInit, imm, VectorOf(args_));
break;
}
case kExprTableDrop: {
TableDropImmediate<validate> imm(this, this->pc_);
if (!this->Validate(imm)) break;
len += imm.length;
CALL_INTERFACE_IF_REACHABLE(TableDrop, imm);
break;
}
case kExprTableCopy: {
TableIndexImmediate<validate> imm(this, this->pc_ + 1);
if (!this->Validate(this->pc_ + 1, imm)) break;
len += imm.length;
PopArgs(sig);
CALL_INTERFACE_IF_REACHABLE(TableCopy, imm, VectorOf(args_));
break;
}
default:
this->error("invalid numeric opcode");
break;
}
} else {
this->error("invalid numeric opcode");
}
return len;
}
void DoReturn(Control* c, bool implicit) {
if (!TypeCheckReturn()) return;
size_t return_count = this->sig_->return_count();
Vector<Value> return_values =
return_count == 0
? Vector<Value>{}
: Vector<Value>{&*(stack_.end() - return_count), return_count};
// Simulate that an implicit return morally comes after the current block.
bool reached = c->reachable() || (implicit && c->end_merge.reached);
if (reached) CALL_INTERFACE(DoReturn, return_values, implicit);
EndControl();
}
inline Value* Push(ValueType type) {
DCHECK_NE(kWasmStmt, type);
stack_.push_back(Value::New(this->pc_, type));
return &stack_.back();
}
void PushMergeValues(Control* c, Merge<Value>* merge) {
DCHECK_EQ(c, &control_.back());
DCHECK(merge == &c->start_merge || merge == &c->end_merge);
stack_.resize(c->stack_depth);
if (merge->arity == 1) {
stack_.push_back(merge->vals.first);
} else {
for (uint32_t i = 0; i < merge->arity; i++) {
stack_.push_back(merge->vals.array[i]);
}
}
DCHECK_EQ(c->stack_depth + merge->arity, stack_.size());
}
Value* PushReturns(FunctionSig* sig) {
size_t return_count = sig->return_count();
if (return_count == 0) return nullptr;
size_t old_size = stack_.size();
for (size_t i = 0; i < return_count; ++i) {
Push(sig->GetReturn(i));
}
return stack_.data() + old_size;
}
Value Pop(int index, ValueType expected) {
auto val = Pop();
if (!VALIDATE(val.type == expected || val.type == kWasmVar ||
expected == kWasmVar)) {
this->errorf(val.pc, "%s[%d] expected type %s, found %s of type %s",
SafeOpcodeNameAt(this->pc_), index,
ValueTypes::TypeName(expected), SafeOpcodeNameAt(val.pc),
ValueTypes::TypeName(val.type));
}
return val;
}
Value Pop() {
DCHECK(!control_.empty());
uint32_t limit = control_.back().stack_depth;
if (stack_.size() <= limit) {
// Popping past the current control start in reachable code.
if (!VALIDATE(control_.back().unreachable())) {
this->errorf(this->pc_, "%s found empty stack",
SafeOpcodeNameAt(this->pc_));
}
return Value::Unreachable(this->pc_);
}
auto val = stack_.back();
stack_.pop_back();
return val;
}
int startrel(const byte* ptr) { return static_cast<int>(ptr - this->start_); }
void FallThruTo(Control* c) {
DCHECK_EQ(c, &control_.back());
if (!TypeCheckFallThru(c)) return;
if (!c->reachable()) return;
if (!c->is_loop()) CALL_INTERFACE(FallThruTo, c);
c->end_merge.reached = true;
}
bool TypeCheckMergeValues(Control* c, Merge<Value>* merge) {
DCHECK(merge == &c->start_merge || merge == &c->end_merge);
DCHECK_GE(stack_.size(), c->stack_depth + merge->arity);
// The computation of {stack_values} is only valid if {merge->arity} is >0.
DCHECK_LT(0, merge->arity);
Value* stack_values = &*(stack_.end() - merge->arity);
// Typecheck the topmost {merge->arity} values on the stack.
for (uint32_t i = 0; i < merge->arity; ++i) {
Value& val = stack_values[i];
Value& old = (*merge)[i];
if (val.type == old.type) continue;
// If {val.type} is polymorphic, which results from unreachable, make
// it more specific by using the merge value's expected type.
// If it is not polymorphic, this is a type error.
if (!VALIDATE(val.type == kWasmVar)) {
this->errorf(this->pc_, "type error in merge[%u] (expected %s, got %s)",
i, ValueTypes::TypeName(old.type),
ValueTypes::TypeName(val.type));
return false;
}
val.type = old.type;
}
return true;
}
bool TypeCheckFallThru(Control* c) {
DCHECK_EQ(c, &control_.back());
if (!validate) return true;
uint32_t expected = c->end_merge.arity;
DCHECK_GE(stack_.size(), c->stack_depth);
uint32_t actual = static_cast<uint32_t>(stack_.size()) - c->stack_depth;
// Fallthrus must match the arity of the control exactly.
if (!InsertUnreachablesIfNecessary(expected, actual) || actual > expected) {
this->errorf(
this->pc_,
"expected %u elements on the stack for fallthru to @%d, found %u",
expected, startrel(c->pc), actual);
return false;
}
if (expected == 0) return true; // Fast path.
return TypeCheckMergeValues(c, &c->end_merge);
}
bool TypeCheckBreak(Control* c) {
// Breaks must have at least the number of values expected; can have more.
uint32_t expected = c->br_merge()->arity;
if (expected == 0) return true; // Fast path.
DCHECK_GE(stack_.size(), control_.back().stack_depth);
uint32_t actual =
static_cast<uint32_t>(stack_.size()) - control_.back().stack_depth;
if (!InsertUnreachablesIfNecessary(expected, actual)) {
this->errorf(this->pc_,
"expected %u elements on the stack for br to @%d, found %u",
expected, startrel(c->pc), actual);
return false;
}
return TypeCheckMergeValues(c, c->br_merge());
}
bool TypeCheckReturn() {
// Returns must have at least the number of values expected; can have more.
uint32_t num_returns = static_cast<uint32_t>(this->sig_->return_count());
DCHECK_GE(stack_.size(), control_.back().stack_depth);
uint32_t actual =
static_cast<uint32_t>(stack_.size()) - control_.back().stack_depth;
if (!InsertUnreachablesIfNecessary(num_returns, actual)) {
this->errorf(this->pc_,
"expected %u elements on the stack for return, found %u",
num_returns, actual);
return false;
}
// Typecheck the topmost {num_returns} values on the stack.
Value* stack_values = &*(stack_.end() - num_returns);
for (uint32_t i = 0; i < num_returns; ++i) {
auto& val = stack_values[i];
ValueType expected_type = this->sig_->GetReturn(i);
if (val.type == expected_type) continue;
// If {val.type} is polymorphic, which results from unreachable,
// make it more specific by using the return's expected type.
// If it is not polymorphic, this is a type error.
if (!VALIDATE(val.type == kWasmVar)) {
this->errorf(this->pc_,
"type error in return[%u] (expected %s, got %s)", i,
ValueTypes::TypeName(expected_type),
ValueTypes::TypeName(val.type));
return false;
}
val.type = expected_type;
}
return true;
}
inline bool InsertUnreachablesIfNecessary(uint32_t expected,
uint32_t actual) {
if (V8_LIKELY(actual >= expected)) {
return true; // enough actual values are there.
}
if (!VALIDATE(control_.back().unreachable())) {
// There aren't enough values on the stack.
return false;
}
// A slow path. When the actual number of values on the stack is less
// than the expected number of values and the current control is
// unreachable, insert unreachable values below the actual values.
// This simplifies {TypeCheckMergeValues}.
auto pos = stack_.begin() + (stack_.size() - actual);
stack_.insert(pos, (expected - actual), Value::Unreachable(this->pc_));
return true;
}
void onFirstError() override {
this->end_ = this->pc_; // Terminate decoding loop.
TRACE(" !%s\n", this->error_msg_.c_str());
CALL_INTERFACE(OnFirstError);
}
void BuildSimplePrototypeOperator(WasmOpcode opcode) {
if (WasmOpcodes::IsSignExtensionOpcode(opcode)) {
RET_ON_PROTOTYPE_OPCODE(se);
}
if (WasmOpcodes::IsAnyRefOpcode(opcode)) {
RET_ON_PROTOTYPE_OPCODE(anyref);
}
FunctionSig* sig = WasmOpcodes::Signature(opcode);
BuildSimpleOperator(opcode, sig);
}
inline void BuildSimpleOperator(WasmOpcode opcode, FunctionSig* sig) {
switch (sig->parameter_count()) {
case 1: {
auto val = Pop(0, sig->GetParam(0));
auto* ret =
sig->return_count() == 0 ? nullptr : Push(sig->GetReturn(0));
CALL_INTERFACE_IF_REACHABLE(UnOp, opcode, sig, val, ret);
break;
}
case 2: {
auto rval = Pop(1, sig->GetParam(1));
auto lval = Pop(0, sig->GetParam(0));
auto* ret =
sig->return_count() == 0 ? nullptr : Push(sig->GetReturn(0));
CALL_INTERFACE_IF_REACHABLE(BinOp, opcode, sig, lval, rval, ret);
break;
}
default:
UNREACHABLE();
}
}
};
#undef CALL_INTERFACE
#undef CALL_INTERFACE_IF_REACHABLE
#undef CALL_INTERFACE_IF_PARENT_REACHABLE
class EmptyInterface {
public:
static constexpr Decoder::ValidateFlag validate = Decoder::kValidate;
using Value = ValueBase;
using Control = ControlBase<Value>;
using FullDecoder = WasmFullDecoder<validate, EmptyInterface>;
#define DEFINE_EMPTY_CALLBACK(name, ...) \
void name(FullDecoder* decoder, ##__VA_ARGS__) {}
INTERFACE_FUNCTIONS(DEFINE_EMPTY_CALLBACK)
#undef DEFINE_EMPTY_CALLBACK
};
#undef TRACE
#undef TRACE_INST_FORMAT
#undef VALIDATE
#undef CHECK_PROTOTYPE_OPCODE
#undef OPCODE_ERROR
} // namespace wasm
} // namespace internal
} // namespace v8
#endif // V8_WASM_FUNCTION_BODY_DECODER_IMPL_H_