WasmFunctionParser.h [plain text]
#pragma once
#if ENABLE(WEBASSEMBLY)
#include "WasmParser.h"
#include "WasmSignatureInlines.h"
#include <wtf/DataLog.h>
namespace JSC { namespace Wasm {
enum class BlockType {
If,
Block,
Loop,
TopLevel
};
template<typename Context>
class FunctionParser : public Parser<void> {
public:
typedef typename Context::ExpressionType ExpressionType;
typedef typename Context::ControlType ControlType;
typedef typename Context::ExpressionList ExpressionList;
FunctionParser(Context&, const uint8_t* functionStart, size_t functionLength, const Signature&, const ModuleInformation&);
Result WARN_UNUSED_RETURN parse();
struct ControlEntry {
ExpressionList enclosedExpressionStack;
ControlType controlData;
};
OpType currentOpcode() const { return m_currentOpcode; }
size_t currentOpcodeStartingOffset() const { return m_currentOpcodeStartingOffset; }
private:
static const bool verbose = false;
PartialResult WARN_UNUSED_RETURN parseBody();
PartialResult WARN_UNUSED_RETURN parseExpression();
PartialResult WARN_UNUSED_RETURN parseUnreachableExpression();
PartialResult WARN_UNUSED_RETURN unifyControl(Vector<ExpressionType>&, unsigned level);
#define WASM_TRY_POP_EXPRESSION_STACK_INTO(result, what) do { \
WASM_PARSER_FAIL_IF(m_expressionStack.isEmpty(), "can't pop empty stack in " what); \
result = m_expressionStack.takeLast(); \
} while (0)
template<OpType>
PartialResult WARN_UNUSED_RETURN unaryCase();
template<OpType>
PartialResult WARN_UNUSED_RETURN binaryCase();
#define WASM_TRY_ADD_TO_CONTEXT(add_expression) WASM_FAIL_IF_HELPER_FAILS(m_context.add_expression)
Context& m_context;
ExpressionList m_expressionStack;
Vector<ControlEntry> m_controlStack;
const Signature& m_signature;
const ModuleInformation& m_info;
OpType m_currentOpcode;
size_t m_currentOpcodeStartingOffset { 0 };
unsigned m_unreachableBlocks { 0 };
};
template<typename Context>
FunctionParser<Context>::FunctionParser(Context& context, const uint8_t* functionStart, size_t functionLength, const Signature& signature, const ModuleInformation& info)
: Parser(functionStart, functionLength)
, m_context(context)
, m_signature(signature)
, m_info(info)
{
if (verbose)
dataLogLn("Parsing function starting at: ", (uintptr_t)functionStart, " of length: ", functionLength);
m_context.setParser(this);
}
template<typename Context>
auto FunctionParser<Context>::parse() -> Result
{
uint32_t localCount;
WASM_PARSER_FAIL_IF(!m_context.addArguments(m_signature), "can't add ", m_signature.argumentCount(), " arguments to Function");
WASM_PARSER_FAIL_IF(!parseVarUInt32(localCount), "can't get local count");
WASM_PARSER_FAIL_IF(localCount > maxFunctionLocals, "Function section's local count is too big ", localCount, " maximum ", maxFunctionLocals);
for (uint32_t i = 0; i < localCount; ++i) {
uint32_t numberOfLocals;
Type typeOfLocal;
WASM_PARSER_FAIL_IF(!parseVarUInt32(numberOfLocals), "can't get Function's number of locals in group ", i);
WASM_PARSER_FAIL_IF(numberOfLocals > maxFunctionLocals, "Function section's ", i, "th local group count is too big ", numberOfLocals, " maximum ", maxFunctionLocals);
WASM_PARSER_FAIL_IF(!parseValueType(typeOfLocal), "can't get Function local's type in group ", i);
WASM_TRY_ADD_TO_CONTEXT(addLocal(typeOfLocal, numberOfLocals));
}
WASM_FAIL_IF_HELPER_FAILS(parseBody());
return { };
}
template<typename Context>
auto FunctionParser<Context>::parseBody() -> PartialResult
{
m_controlStack.append({ ExpressionList(), m_context.addTopLevel(m_signature.returnType()) });
uint8_t op;
while (m_controlStack.size()) {
m_currentOpcodeStartingOffset = m_offset;
WASM_PARSER_FAIL_IF(!parseUInt8(op), "can't decode opcode");
WASM_PARSER_FAIL_IF(!isValidOpType(op), "invalid opcode ", op);
m_currentOpcode = static_cast<OpType>(op);
if (verbose) {
dataLogLn("processing op (", m_unreachableBlocks, "): ", RawPointer(reinterpret_cast<void*>(op)), ", ", makeString(static_cast<OpType>(op)), " at offset: ", RawPointer(reinterpret_cast<void*>(m_offset)));
m_context.dump(m_controlStack, &m_expressionStack);
}
if (m_unreachableBlocks)
WASM_FAIL_IF_HELPER_FAILS(parseUnreachableExpression());
else
WASM_FAIL_IF_HELPER_FAILS(parseExpression());
}
ASSERT(op == OpType::End);
return { };
}
template<typename Context>
template<OpType op>
auto FunctionParser<Context>::binaryCase() -> PartialResult
{
ExpressionType right;
ExpressionType left;
ExpressionType result;
WASM_TRY_POP_EXPRESSION_STACK_INTO(right, "binary right");
WASM_TRY_POP_EXPRESSION_STACK_INTO(left, "binary left");
WASM_TRY_ADD_TO_CONTEXT(template addOp<op>(left, right, result));
m_expressionStack.append(result);
return { };
}
template<typename Context>
template<OpType op>
auto FunctionParser<Context>::unaryCase() -> PartialResult
{
ExpressionType value;
ExpressionType result;
WASM_TRY_POP_EXPRESSION_STACK_INTO(value, "unary");
WASM_TRY_ADD_TO_CONTEXT(template addOp<op>(value, result));
m_expressionStack.append(result);
return { };
}
template<typename Context>
auto FunctionParser<Context>::parseExpression() -> PartialResult
{
switch (m_currentOpcode) {
#define CREATE_CASE(name, id, b3op, inc) case OpType::name: return binaryCase<OpType::name>();
FOR_EACH_WASM_BINARY_OP(CREATE_CASE)
#undef CREATE_CASE
#define CREATE_CASE(name, id, b3op, inc) case OpType::name: return unaryCase<OpType::name>();
FOR_EACH_WASM_UNARY_OP(CREATE_CASE)
#undef CREATE_CASE
case Select: {
ExpressionType condition;
ExpressionType zero;
ExpressionType nonZero;
WASM_TRY_POP_EXPRESSION_STACK_INTO(condition, "select condition");
WASM_TRY_POP_EXPRESSION_STACK_INTO(zero, "select zero");
WASM_TRY_POP_EXPRESSION_STACK_INTO(nonZero, "select non-zero");
ExpressionType result;
WASM_TRY_ADD_TO_CONTEXT(addSelect(condition, nonZero, zero, result));
m_expressionStack.append(result);
return { };
}
#define CREATE_CASE(name, id, b3op, inc) case OpType::name:
FOR_EACH_WASM_MEMORY_LOAD_OP(CREATE_CASE) {
uint32_t alignment;
uint32_t offset;
ExpressionType pointer;
ExpressionType result;
WASM_PARSER_FAIL_IF(!parseVarUInt32(alignment), "can't get load alignment");
WASM_PARSER_FAIL_IF(alignment > memoryLog2Alignment(m_currentOpcode), "byte alignment ", 1ull << alignment, " exceeds load's natural alignment ", 1ull << memoryLog2Alignment(m_currentOpcode));
WASM_PARSER_FAIL_IF(!parseVarUInt32(offset), "can't get load offset");
WASM_TRY_POP_EXPRESSION_STACK_INTO(pointer, "load pointer");
WASM_TRY_ADD_TO_CONTEXT(load(static_cast<LoadOpType>(m_currentOpcode), pointer, result, offset));
m_expressionStack.append(result);
return { };
}
FOR_EACH_WASM_MEMORY_STORE_OP(CREATE_CASE) {
uint32_t alignment;
uint32_t offset;
ExpressionType value;
ExpressionType pointer;
WASM_PARSER_FAIL_IF(!parseVarUInt32(alignment), "can't get store alignment");
WASM_PARSER_FAIL_IF(alignment > memoryLog2Alignment(m_currentOpcode), "byte alignment ", 1ull << alignment, " exceeds store's natural alignment ", 1ull << memoryLog2Alignment(m_currentOpcode));
WASM_PARSER_FAIL_IF(!parseVarUInt32(offset), "can't get store offset");
WASM_TRY_POP_EXPRESSION_STACK_INTO(value, "store value");
WASM_TRY_POP_EXPRESSION_STACK_INTO(pointer, "store pointer");
WASM_TRY_ADD_TO_CONTEXT(store(static_cast<StoreOpType>(m_currentOpcode), pointer, value, offset));
return { };
}
#undef CREATE_CASE
case F32Const: {
uint32_t constant;
WASM_PARSER_FAIL_IF(!parseUInt32(constant), "can't parse 32-bit floating-point constant");
m_expressionStack.append(m_context.addConstant(F32, constant));
return { };
}
case I32Const: {
int32_t constant;
WASM_PARSER_FAIL_IF(!parseVarInt32(constant), "can't parse 32-bit constant");
m_expressionStack.append(m_context.addConstant(I32, constant));
return { };
}
case F64Const: {
uint64_t constant;
WASM_PARSER_FAIL_IF(!parseUInt64(constant), "can't parse 64-bit floating-point constant");
m_expressionStack.append(m_context.addConstant(F64, constant));
return { };
}
case I64Const: {
int64_t constant;
WASM_PARSER_FAIL_IF(!parseVarInt64(constant), "can't parse 64-bit constant");
m_expressionStack.append(m_context.addConstant(I64, constant));
return { };
}
case GetLocal: {
uint32_t index;
ExpressionType result;
WASM_PARSER_FAIL_IF(!parseVarUInt32(index), "can't get index for get_local");
WASM_TRY_ADD_TO_CONTEXT(getLocal(index, result));
m_expressionStack.append(result);
return { };
}
case SetLocal: {
uint32_t index;
ExpressionType value;
WASM_PARSER_FAIL_IF(!parseVarUInt32(index), "can't get index for set_local");
WASM_TRY_POP_EXPRESSION_STACK_INTO(value, "set_local");
WASM_TRY_ADD_TO_CONTEXT(setLocal(index, value));
return { };
}
case TeeLocal: {
uint32_t index;
WASM_PARSER_FAIL_IF(!parseVarUInt32(index), "can't get index for tee_local");
WASM_PARSER_FAIL_IF(m_expressionStack.isEmpty(), "can't tee_local on empty expression stack");
WASM_TRY_ADD_TO_CONTEXT(setLocal(index, m_expressionStack.last()));
return { };
}
case GetGlobal: {
uint32_t index;
ExpressionType result;
WASM_PARSER_FAIL_IF(!parseVarUInt32(index), "can't get get_global's index");
WASM_TRY_ADD_TO_CONTEXT(getGlobal(index, result));
m_expressionStack.append(result);
return { };
}
case SetGlobal: {
uint32_t index;
ExpressionType value;
WASM_PARSER_FAIL_IF(!parseVarUInt32(index), "can't get set_global's index");
WASM_TRY_POP_EXPRESSION_STACK_INTO(value, "set_global value");
WASM_TRY_ADD_TO_CONTEXT(setGlobal(index, value));
return { };
}
case Call: {
uint32_t functionIndex;
WASM_PARSER_FAIL_IF(!parseVarUInt32(functionIndex), "can't parse call's function index");
WASM_PARSER_FAIL_IF(functionIndex >= m_info.functionIndexSpaceSize(), "call function index ", functionIndex, " exceeds function index space ", m_info.functionIndexSpaceSize());
SignatureIndex calleeSignatureIndex = m_info.signatureIndexFromFunctionIndexSpace(functionIndex);
const Signature& calleeSignature = SignatureInformation::get(calleeSignatureIndex);
WASM_PARSER_FAIL_IF(calleeSignature.argumentCount() > m_expressionStack.size(), "call function index ", functionIndex, " has ", calleeSignature.argumentCount(), " arguments, but the expression stack currently holds ", m_expressionStack.size(), " values");
size_t firstArgumentIndex = m_expressionStack.size() - calleeSignature.argumentCount();
Vector<ExpressionType> args;
WASM_PARSER_FAIL_IF(!args.tryReserveCapacity(calleeSignature.argumentCount()), "can't allocate enough memory for call's ", calleeSignature.argumentCount(), " arguments");
for (size_t i = firstArgumentIndex; i < m_expressionStack.size(); ++i)
args.uncheckedAppend(m_expressionStack[i]);
m_expressionStack.shrink(firstArgumentIndex);
ExpressionType result = Context::emptyExpression;
WASM_TRY_ADD_TO_CONTEXT(addCall(functionIndex, calleeSignature, args, result));
if (result != Context::emptyExpression)
m_expressionStack.append(result);
return { };
}
case CallIndirect: {
uint32_t signatureIndex;
uint8_t reserved;
WASM_PARSER_FAIL_IF(!m_info.tableInformation, "call_indirect is only valid when a table is defined or imported");
WASM_PARSER_FAIL_IF(!parseVarUInt32(signatureIndex), "can't get call_indirect's signature index");
WASM_PARSER_FAIL_IF(!parseVarUInt1(reserved), "can't get call_indirect's reserved byte");
WASM_PARSER_FAIL_IF(reserved, "call_indirect's 'reserved' varuint1 must be 0x0");
WASM_PARSER_FAIL_IF(m_info.usedSignatures.size() <= signatureIndex, "call_indirect's signature index ", signatureIndex, " exceeds known signatures ", m_info.usedSignatures.size());
const Signature& calleeSignature = m_info.usedSignatures[signatureIndex].get();
size_t argumentCount = calleeSignature.argumentCount() + 1; WASM_PARSER_FAIL_IF(argumentCount > m_expressionStack.size(), "call_indirect expects ", argumentCount, " arguments, but the expression stack currently holds ", m_expressionStack.size(), " values");
Vector<ExpressionType> args;
WASM_PARSER_FAIL_IF(!args.tryReserveCapacity(argumentCount), "can't allocate enough memory for ", argumentCount, " call_indirect arguments");
size_t firstArgumentIndex = m_expressionStack.size() - argumentCount;
for (size_t i = firstArgumentIndex; i < m_expressionStack.size(); ++i)
args.uncheckedAppend(m_expressionStack[i]);
m_expressionStack.shrink(firstArgumentIndex);
ExpressionType result = Context::emptyExpression;
WASM_TRY_ADD_TO_CONTEXT(addCallIndirect(calleeSignature, args, result));
if (result != Context::emptyExpression)
m_expressionStack.append(result);
return { };
}
case Block: {
Type inlineSignature;
WASM_PARSER_FAIL_IF(!parseResultType(inlineSignature), "can't get block's inline signature");
m_controlStack.append({ WTFMove(m_expressionStack), m_context.addBlock(inlineSignature) });
m_expressionStack = ExpressionList();
return { };
}
case Loop: {
Type inlineSignature;
WASM_PARSER_FAIL_IF(!parseResultType(inlineSignature), "can't get loop's inline signature");
m_controlStack.append({ WTFMove(m_expressionStack), m_context.addLoop(inlineSignature) });
m_expressionStack = ExpressionList();
return { };
}
case If: {
Type inlineSignature;
ExpressionType condition;
ControlType control;
WASM_PARSER_FAIL_IF(!parseResultType(inlineSignature), "can't get if's inline signature");
WASM_TRY_POP_EXPRESSION_STACK_INTO(condition, "if condition");
WASM_TRY_ADD_TO_CONTEXT(addIf(condition, inlineSignature, control));
m_controlStack.append({ WTFMove(m_expressionStack), control });
m_expressionStack = ExpressionList();
return { };
}
case Else: {
WASM_PARSER_FAIL_IF(m_controlStack.size() == 1, "can't use else block at the top-level of a function");
WASM_TRY_ADD_TO_CONTEXT(addElse(m_controlStack.last().controlData, m_expressionStack));
m_expressionStack.shrink(0);
return { };
}
case Br:
case BrIf: {
uint32_t target;
ExpressionType condition = Context::emptyExpression;
WASM_PARSER_FAIL_IF(!parseVarUInt32(target), "can't get br / br_if's target");
WASM_PARSER_FAIL_IF(target >= m_controlStack.size(), "br / br_if's target ", target, " exceeds control stack size ", m_controlStack.size());
if (m_currentOpcode == BrIf)
WASM_TRY_POP_EXPRESSION_STACK_INTO(condition, "br / br_if condition");
else
m_unreachableBlocks = 1;
ControlType& data = m_controlStack[m_controlStack.size() - 1 - target].controlData;
WASM_TRY_ADD_TO_CONTEXT(addBranch(data, condition, m_expressionStack));
return { };
}
case BrTable: {
uint32_t numberOfTargets;
uint32_t defaultTarget;
ExpressionType condition;
Vector<ControlType*> targets;
WASM_PARSER_FAIL_IF(!parseVarUInt32(numberOfTargets), "can't get the number of targets for br_table");
WASM_PARSER_FAIL_IF(numberOfTargets == std::numeric_limits<uint32_t>::max(), "br_table's number of targets is too big ", numberOfTargets);
WASM_PARSER_FAIL_IF(!targets.tryReserveCapacity(numberOfTargets), "can't allocate memory for ", numberOfTargets, " br_table targets");
for (uint32_t i = 0; i < numberOfTargets; ++i) {
uint32_t target;
WASM_PARSER_FAIL_IF(!parseVarUInt32(target), "can't get ", i, "th target for br_table");
WASM_PARSER_FAIL_IF(target >= m_controlStack.size(), "br_table's ", i, "th target ", target, " exceeds control stack size ", m_controlStack.size());
targets.uncheckedAppend(&m_controlStack[m_controlStack.size() - 1 - target].controlData);
}
WASM_PARSER_FAIL_IF(!parseVarUInt32(defaultTarget), "can't get default target for br_table");
WASM_PARSER_FAIL_IF(defaultTarget >= m_controlStack.size(), "br_table's default target ", defaultTarget, " exceeds control stack size ", m_controlStack.size());
WASM_TRY_POP_EXPRESSION_STACK_INTO(condition, "br_table condition");
WASM_TRY_ADD_TO_CONTEXT(addSwitch(condition, targets, m_controlStack[m_controlStack.size() - 1 - defaultTarget].controlData, m_expressionStack));
m_unreachableBlocks = 1;
return { };
}
case Return: {
ExpressionList returnValues;
if (m_signature.returnType() != Void) {
ExpressionType returnValue;
WASM_TRY_POP_EXPRESSION_STACK_INTO(returnValue, "return");
returnValues.append(returnValue);
}
WASM_TRY_ADD_TO_CONTEXT(addReturn(m_controlStack[0].controlData, returnValues));
m_unreachableBlocks = 1;
return { };
}
case End: {
ControlEntry data = m_controlStack.takeLast();
WASM_TRY_ADD_TO_CONTEXT(endBlock(data, m_expressionStack));
m_expressionStack.swap(data.enclosedExpressionStack);
return { };
}
case Unreachable: {
WASM_TRY_ADD_TO_CONTEXT(addUnreachable());
m_unreachableBlocks = 1;
return { };
}
case Drop: {
WASM_PARSER_FAIL_IF(!m_expressionStack.size(), "can't drop on empty stack");
m_expressionStack.takeLast();
return { };
}
case Nop: {
return { };
}
case GrowMemory: {
WASM_PARSER_FAIL_IF(!m_info.memory, "grow_memory is only valid if a memory is defined or imported");
uint8_t reserved;
WASM_PARSER_FAIL_IF(!parseVarUInt1(reserved), "can't parse reserved varUint1 for grow_memory");
WASM_PARSER_FAIL_IF(reserved != 0, "reserved varUint1 for grow_memory must be zero");
ExpressionType delta;
WASM_TRY_POP_EXPRESSION_STACK_INTO(delta, "expect an i32 argument to grow_memory on the stack");
ExpressionType result;
WASM_TRY_ADD_TO_CONTEXT(addGrowMemory(delta, result));
m_expressionStack.append(result);
return { };
}
case CurrentMemory: {
WASM_PARSER_FAIL_IF(!m_info.memory, "current_memory is only valid if a memory is defined or imported");
uint8_t reserved;
WASM_PARSER_FAIL_IF(!parseVarUInt1(reserved), "can't parse reserved varUint1 for current_memory");
WASM_PARSER_FAIL_IF(reserved != 0, "reserved varUint1 for current_memory must be zero");
ExpressionType result;
WASM_TRY_ADD_TO_CONTEXT(addCurrentMemory(result));
m_expressionStack.append(result);
return { };
}
}
ASSERT_NOT_REACHED();
return { };
}
template<typename Context>
auto FunctionParser<Context>::parseUnreachableExpression() -> PartialResult
{
ASSERT(m_unreachableBlocks);
#define CREATE_CASE(name, id, b3op, inc) case OpType::name:
switch (m_currentOpcode) {
case Else: {
if (m_unreachableBlocks > 1)
return { };
ControlEntry& data = m_controlStack.last();
m_unreachableBlocks = 0;
WASM_TRY_ADD_TO_CONTEXT(addElseToUnreachable(data.controlData));
m_expressionStack.shrink(0);
return { };
}
case End: {
if (m_unreachableBlocks == 1) {
ControlEntry data = m_controlStack.takeLast();
WASM_TRY_ADD_TO_CONTEXT(addEndToUnreachable(data));
m_expressionStack.swap(data.enclosedExpressionStack);
}
m_unreachableBlocks--;
return { };
}
case Loop:
case If:
case Block: {
m_unreachableBlocks++;
Type unused;
WASM_PARSER_FAIL_IF(!parseResultType(unused), "can't get inline type for ", m_currentOpcode, " in unreachable context");
return { };
}
case BrTable: {
uint32_t numberOfTargets;
uint32_t unused;
WASM_PARSER_FAIL_IF(!parseVarUInt32(numberOfTargets), "can't get the number of targets for br_table in unreachable context");
WASM_PARSER_FAIL_IF(numberOfTargets == std::numeric_limits<uint32_t>::max(), "br_table's number of targets is too big ", numberOfTargets);
for (uint32_t i = 0; i < numberOfTargets; ++i)
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get ", i, "th target for br_table in unreachable context");
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get default target for br_table in unreachable context");
return { };
}
case CallIndirect: {
uint32_t unused;
uint8_t unused2;
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get call_indirect's signature index in unreachable context");
WASM_PARSER_FAIL_IF(!parseVarUInt1(unused2), "can't get call_indirect's reserved byte in unreachable context");
return { };
}
case F32Const: {
uint32_t unused;
WASM_PARSER_FAIL_IF(!parseUInt32(unused), "can't parse 32-bit floating-point constant");
return { };
}
case F64Const: {
uint64_t constant;
WASM_PARSER_FAIL_IF(!parseUInt64(constant), "can't parse 64-bit floating-point constant");
return { };
}
FOR_EACH_WASM_MEMORY_LOAD_OP(CREATE_CASE)
FOR_EACH_WASM_MEMORY_STORE_OP(CREATE_CASE) {
uint32_t unused;
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get first immediate for ", m_currentOpcode, " in unreachable context");
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get second immediate for ", m_currentOpcode, " in unreachable context");
return { };
}
case SetLocal:
case GetLocal:
case TeeLocal:
case GetGlobal:
case SetGlobal:
case Br:
case BrIf:
case Call: {
uint32_t unused;
WASM_PARSER_FAIL_IF(!parseVarUInt32(unused), "can't get immediate for ", m_currentOpcode, " in unreachable context");
return { };
}
case I32Const: {
int32_t unused;
WASM_PARSER_FAIL_IF(!parseVarInt32(unused), "can't get immediate for ", m_currentOpcode, " in unreachable context");
return { };
}
case I64Const: {
int64_t unused;
WASM_PARSER_FAIL_IF(!parseVarInt64(unused), "can't get immediate for ", m_currentOpcode, " in unreachable context");
return { };
}
case GrowMemory:
case CurrentMemory: {
uint8_t reserved;
WASM_PARSER_FAIL_IF(!parseVarUInt1(reserved), "can't parse reserved varUint1 for grow_memory/current_memory");
return { };
}
FOR_EACH_WASM_BINARY_OP(CREATE_CASE)
FOR_EACH_WASM_UNARY_OP(CREATE_CASE)
case Unreachable:
case Nop:
case Return:
case Select:
case Drop: {
return { };
}
}
#undef CREATE_CASE
RELEASE_ASSERT_NOT_REACHED();
}
} }
#endif // ENABLE(WEBASSEMBLY)