/*
* Copyright 2023 WebAssembly Community Group participants
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef parser_context_h
#define parser_context_h
#include "common.h"
#include "ir/names.h"
#include "lexer.h"
#include "support/name.h"
#include "support/result.h"
#include "support/string.h"
#include "wasm-builder.h"
#include "wasm-ir-builder.h"
#include "wasm.h"
namespace wasm::WATParser {
using IndexMap = std::unordered_map<Name, Index>;
inline std::vector<Type> getUnnamedTypes(const std::vector<NameType>& named) {
std::vector<Type> types;
types.reserve(named.size());
for (auto& t : named) {
types.push_back(t.type);
}
return types;
}
struct Limits {
uint64_t initial;
std::optional<uint64_t> max;
};
struct MemType {
Type addressType;
Limits limits;
bool shared;
};
struct Memarg {
uint64_t offset;
uint32_t align;
};
struct TableType {
Type addressType;
Limits limits;
};
// The location, possible name, and index in the respective module index space
// of a module-level definition in the input.
struct DefPos {
Name name;
Index pos;
Index index;
std::vector<Annotation> annotations;
};
struct GlobalType {
Mutability mutability;
Type type;
};
// A signature type and parameter names (possibly empty), used for parsing
// function types.
struct TypeUse {
HeapType type;
std::vector<Name> names;
};
struct NullTypeParserCtx {
using IndexT = Ok;
using HeapTypeT = Ok;
using TupleElemListT = Ok;
using TypeT = Ok;
using ParamsT = Ok;
using ResultsT = size_t;
using BlockTypeT = Ok;
using SignatureT = Ok;
using ContinuationT = Ok;
using StorageT = Ok;
using FieldT = Ok;
using FieldsT = Ok;
using StructT = Ok;
using ArrayT = Ok;
using LimitsT = Ok;
using MemTypeT = Ok;
using GlobalTypeT = Ok;
using TypeUseT = Ok;
using LocalsT = Ok;
using ElemListT = Ok;
using DataStringT = Ok;
HeapTypeT makeFuncType(Shareability) { return Ok{}; }
HeapTypeT makeAnyType(Shareability) { return Ok{}; }
HeapTypeT makeExternType(Shareability) { return Ok{}; }
HeapTypeT makeEqType(Shareability) { return Ok{}; }
HeapTypeT makeI31Type(Shareability) { return Ok{}; }
HeapTypeT makeStructType(Shareability) { return Ok{}; }
HeapTypeT makeArrayType(Shareability) { return Ok{}; }
HeapTypeT makeExnType(Shareability) { return Ok{}; }
HeapTypeT makeStringType(Shareability) { return Ok{}; }
HeapTypeT makeContType(Shareability) { return Ok{}; }
HeapTypeT makeNoneType(Shareability) { return Ok{}; }
HeapTypeT makeNoextType(Shareability) { return Ok{}; }
HeapTypeT makeNofuncType(Shareability) { return Ok{}; }
HeapTypeT makeNoexnType(Shareability) { return Ok{}; }
HeapTypeT makeNocontType(Shareability) { return Ok{}; }
TypeT makeI32() { return Ok{}; }
TypeT makeI64() { return Ok{}; }
TypeT makeF32() { return Ok{}; }
TypeT makeF64() { return Ok{}; }
TypeT makeV128() { return Ok{}; }
TypeT makeRefType(HeapTypeT, Nullability) { return Ok{}; }
TupleElemListT makeTupleElemList() { return Ok{}; }
void appendTupleElem(TupleElemListT&, TypeT) {}
TypeT makeTupleType(TupleElemListT) { return Ok{}; }
ParamsT makeParams() { return Ok{}; }
void appendParam(ParamsT&, Name, TypeT) {}
// We have to count results because whether or not a block introduces a
// typeuse that may implicitly define a type depends on how many results it
// has.
size_t makeResults() { return 0; }
void appendResult(size_t& results, TypeT) { ++results; }
size_t getResultsSize(size_t results) { return results; }
SignatureT makeFuncType(ParamsT*, ResultsT*) { return Ok{}; }
ContinuationT makeContType(HeapTypeT) { return Ok{}; }
StorageT makeI8() { return Ok{}; }
StorageT makeI16() { return Ok{}; }
StorageT makeStorageType(TypeT) { return Ok{}; }
FieldT makeFieldType(StorageT, Mutability) { return Ok{}; }
FieldsT makeFields() { return Ok{}; }
void appendField(FieldsT&, Name, FieldT) {}
StructT makeStruct(FieldsT&) { return Ok{}; }
std::optional<ArrayT> makeArray(FieldsT&) { return Ok{}; }
GlobalTypeT makeGlobalType(Mutability, TypeT) { return Ok{}; }
LocalsT makeLocals() { return Ok{}; }
void appendLocal(LocalsT&, Name, TypeT) {}
Result<Index> getTypeIndex(Name) { return 1; }
Result<HeapTypeT> getHeapTypeFromIdx(Index) { return Ok{}; }
DataStringT makeDataString() { return Ok{}; }
void appendDataString(DataStringT&, std::string_view) {}
MemTypeT makeMemType(Type, LimitsT, bool) { return Ok{}; }
BlockTypeT getBlockTypeFromResult(size_t results) { return Ok{}; }
Result<> getBlockTypeFromTypeUse(Index, TypeUseT) { return Ok{}; }
bool skipFunctionBody() { return false; }
};
template<typename Ctx> struct TypeParserCtx {
using IndexT = Index;
using HeapTypeT = HeapType;
using TypeT = Type;
using ParamsT = std::vector<NameType>;
using ResultsT = std::vector<Type>;
using BlockTypeT = HeapType;
using SignatureT = Signature;
using ContinuationT = Continuation;
using StorageT = Field;
using FieldT = Field;
using FieldsT = std::pair<std::vector<Name>, std::vector<Field>>;
using StructT = std::pair<std::vector<Name>, Struct>;
using ArrayT = Array;
using LimitsT = Ok;
using MemTypeT = Ok;
using LocalsT = std::vector<NameType>;
using DataStringT = Ok;
// Map heap type names to their indices.
const IndexMap& typeIndices;
TypeParserCtx(const IndexMap& typeIndices) : typeIndices(typeIndices) {}
Ctx& self() { return *static_cast<Ctx*>(this); }
HeapTypeT makeFuncType(Shareability share) {
return HeapTypes::func.getBasic(share);
}
HeapTypeT makeAnyType(Shareability share) {
return HeapTypes::any.getBasic(share);
}
HeapTypeT makeExternType(Shareability share) {
return HeapTypes::ext.getBasic(share);
}
HeapTypeT makeEqType(Shareability share) {
return HeapTypes::eq.getBasic(share);
}
HeapTypeT makeI31Type(Shareability share) {
return HeapTypes::i31.getBasic(share);
}
HeapTypeT makeStructType(Shareability share) {
return HeapTypes::struct_.getBasic(share);
}
HeapTypeT makeArrayType(Shareability share) {
return HeapTypes::array.getBasic(share);
}
HeapTypeT makeExnType(Shareability share) {
return HeapTypes::exn.getBasic(share);
}
HeapTypeT makeStringType(Shareability share) {
return HeapTypes::string.getBasic(share);
}
HeapTypeT makeContType(Shareability share) {
return HeapTypes::cont.getBasic(share);
}
HeapTypeT makeNoneType(Shareability share) {
return HeapTypes::none.getBasic(share);
}
HeapTypeT makeNoextType(Shareability share) {
return HeapTypes::noext.getBasic(share);
}
HeapTypeT makeNofuncType(Shareability share) {
return HeapTypes::nofunc.getBasic(share);
}
HeapTypeT makeNoexnType(Shareability share) {
return HeapTypes::noexn.getBasic(share);
}
HeapTypeT makeNocontType(Shareability share) {
return HeapTypes::nocont.getBasic(share);
}
TypeT makeI32() { return Type::i32; }
TypeT makeI64() { return Type::i64; }
TypeT makeF32() { return Type::f32; }
TypeT makeF64() { return Type::f64; }
TypeT makeV128() { return Type::v128; }
TypeT makeRefType(HeapTypeT ht, Nullability nullability) {
return Type(ht, nullability);
}
std::vector<Type> makeTupleElemList() { return {}; }
void appendTupleElem(std::vector<Type>& elems, Type elem) {
elems.push_back(elem);
}
Result<TypeT> makeTupleType(const std::vector<Type>& types) {
return Tuple(types);
}
ParamsT makeParams() { return {}; }
void appendParam(ParamsT& params, Name id, TypeT type) {
params.push_back({id, type});
}
ResultsT makeResults() { return {}; }
void appendResult(ResultsT& results, TypeT type) { results.push_back(type); }
size_t getResultsSize(const ResultsT& results) { return results.size(); }
SignatureT makeFuncType(ParamsT* params, ResultsT* results) {
std::vector<Type> empty;
const auto& paramTypes = params ? getUnnamedTypes(*params) : empty;
const auto& resultTypes = results ? *results : empty;
return Signature(self().makeTupleType(paramTypes),
self().makeTupleType(resultTypes));
}
ContinuationT makeContType(HeapTypeT ft) { return Continuation(ft); }
StorageT makeI8() { return Field(Field::i8, Immutable); }
StorageT makeI16() { return Field(Field::i16, Immutable); }
StorageT makeStorageType(TypeT type) { return Field(type, Immutable); }
FieldT makeFieldType(FieldT field, Mutability mutability) {
if (field.packedType == Field::not_packed) {
return Field(field.type, mutability);
}
return Field(field.packedType, mutability);
}
FieldsT makeFields() { return {}; }
void appendField(FieldsT& fields, Name name, FieldT field) {
fields.first.push_back(name);
fields.second.push_back(field);
}
StructT makeStruct(FieldsT& fields) {
return {std::move(fields.first), Struct(std::move(fields.second))};
}
std::optional<ArrayT> makeArray(FieldsT& fields) {
if (fields.second.size() == 1) {
return Array(fields.second[0]);
}
return {};
}
LocalsT makeLocals() { return {}; }
void appendLocal(LocalsT& locals, Name id, TypeT type) {
locals.push_back({id, type});
}
Result<Index> getTypeIndex(Name id) {
auto it = typeIndices.find(id);
if (it == typeIndices.end()) {
return self().in.err("unknown type identifier");
}
return it->second;
}
DataStringT makeDataString() { return Ok{}; }
void appendDataString(DataStringT&, std::string_view) {}
Result<LimitsT> makeLimits(uint64_t, std::optional<uint64_t>) { return Ok{}; }
LimitsT getLimitsFromData(DataStringT) { return Ok{}; }
MemTypeT makeMemType(Type, LimitsT, bool) { return Ok{}; }
HeapType getBlockTypeFromResult(const std::vector<Type> results) {
assert(results.size() == 1);
return HeapType(Signature(Type::none, results[0]));
}
bool skipFunctionBody() { return false; }
};
struct NullInstrParserCtx {
using ExprT = Ok;
using CatchT = Ok;
using CatchListT = Ok;
using TagLabelListT = Ok;
using FieldIdxT = Ok;
using FuncIdxT = Ok;
using LocalIdxT = Ok;
using TableIdxT = Ok;
using MemoryIdxT = Ok;
using GlobalIdxT = Ok;
using ElemIdxT = Ok;
using DataIdxT = Ok;
using LabelIdxT = Ok;
using TagIdxT = Ok;
using MemargT = Ok;
Result<> makeExpr() { return Ok{}; }
template<typename HeapTypeT> FieldIdxT getFieldFromIdx(HeapTypeT, uint32_t) {
return Ok{};
}
template<typename HeapTypeT> FieldIdxT getFieldFromName(HeapTypeT, Name) {
return Ok{};
}
FuncIdxT getFuncFromIdx(uint32_t) { return Ok{}; }
FuncIdxT getFuncFromName(Name) { return Ok{}; }
LocalIdxT getLocalFromIdx(uint32_t) { return Ok{}; }
LocalIdxT getLocalFromName(Name) { return Ok{}; }
GlobalIdxT getGlobalFromIdx(uint32_t) { return Ok{}; }
GlobalIdxT getGlobalFromName(Name) { return Ok{}; }
TableIdxT getTableFromIdx(uint32_t) { return Ok{}; }
TableIdxT getTableFromName(Name) { return Ok{}; }
MemoryIdxT getMemoryFromIdx(uint32_t) { return Ok{}; }
MemoryIdxT getMemoryFromName(Name) { return Ok{}; }
ElemIdxT getElemFromIdx(uint32_t) { return Ok{}; }
ElemIdxT getElemFromName(Name) { return Ok{}; }
DataIdxT getDataFromIdx(uint32_t) { return Ok{}; }
DataIdxT getDataFromName(Name) { return Ok{}; }
LabelIdxT getLabelFromIdx(uint32_t, bool) { return Ok{}; }
LabelIdxT getLabelFromName(Name, bool) { return Ok{}; }
TagIdxT getTagFromIdx(uint32_t) { return Ok{}; }
TagIdxT getTagFromName(Name) { return Ok{}; }
MemargT getMemarg(uint64_t, uint32_t) { return Ok{}; }
template<typename BlockTypeT>
Result<> makeBlock(Index,
const std::vector<Annotation>&,
std::optional<Name>,
BlockTypeT) {
return Ok{};
}
template<typename BlockTypeT>
Result<> makeIf(Index,
const std::vector<Annotation>&,
std::optional<Name>,
BlockTypeT) {
return Ok{};
}
Result<> visitElse() { return Ok{}; }
template<typename BlockTypeT>
Result<> makeLoop(Index,
const std::vector<Annotation>&,
std::optional<Name>,
BlockTypeT) {
return Ok{};
}
template<typename BlockTypeT>
Result<> makeTry(Index,
const std::vector<Annotation>&,
std::optional<Name>,
BlockTypeT) {
return Ok{};
}
Result<> visitCatch(Index, TagIdxT) { return Ok{}; }
Result<> visitCatchAll(Index) { return Ok{}; }
Result<> visitDelegate(Index, LabelIdxT) { return Ok{}; }
Result<> visitEnd() { return Ok{}; }
CatchListT makeCatchList() { return Ok{}; }
void appendCatch(CatchListT&, CatchT) {}
CatchT makeCatch(TagIdxT, LabelIdxT) { return Ok{}; }
CatchT makeCatchRef(TagIdxT, LabelIdxT) { return Ok{}; }
CatchT makeCatchAll(LabelIdxT) { return Ok{}; }
CatchT makeCatchAllRef(LabelIdxT) { return Ok{}; }
template<typename BlockTypeT>
Result<> makeTryTable(Index,
const std::vector<Annotation>&,
std::optional<Name>,
BlockTypeT,
CatchListT) {
return Ok{};
}
TagLabelListT makeTagLabelList() { return Ok{}; }
void appendTagLabel(TagLabelListT&, TagIdxT, LabelIdxT) {}
void setSrcLoc(const std::vector<Annotation>&) {}
Result<> makeUnreachable(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeNop(Index, const std::vector<Annotation>&) { return Ok{}; }
Result<> makeBinary(Index, const std::vector<Annotation>&, BinaryOp) {
return Ok{};
}
Result<> makeUnary(Index, const std::vector<Annotation>&, UnaryOp) {
return Ok{};
}
template<typename ResultsT>
Result<> makeSelect(Index, const std::vector<Annotation>&, ResultsT*) {
return Ok{};
}
Result<> makeDrop(Index, const std::vector<Annotation>&) { return Ok{}; }
Result<> makeMemorySize(Index, const std::vector<Annotation>&, MemoryIdxT*) {
return Ok{};
}
Result<> makeMemoryGrow(Index, const std::vector<Annotation>&, MemoryIdxT*) {
return Ok{};
}
Result<> makeLocalGet(Index, const std::vector<Annotation>&, LocalIdxT) {
return Ok{};
}
Result<> makeLocalTee(Index, const std::vector<Annotation>&, LocalIdxT) {
return Ok{};
}
Result<> makeLocalSet(Index, const std::vector<Annotation>&, LocalIdxT) {
return Ok{};
}
Result<> makeGlobalGet(Index, const std::vector<Annotation>&, GlobalIdxT) {
return Ok{};
}
Result<> makeGlobalSet(Index, const std::vector<Annotation>&, GlobalIdxT) {
return Ok{};
}
Result<> makeI32Const(Index, const std::vector<Annotation>&, uint32_t) {
return Ok{};
}
Result<> makeI64Const(Index, const std::vector<Annotation>&, uint64_t) {
return Ok{};
}
Result<> makeF32Const(Index, const std::vector<Annotation>&, float) {
return Ok{};
}
Result<> makeF64Const(Index, const std::vector<Annotation>&, double) {
return Ok{};
}
Result<> makeI8x16Const(Index,
const std::vector<Annotation>&,
const std::array<uint8_t, 16>&) {
return Ok{};
}
Result<> makeI16x8Const(Index,
const std::vector<Annotation>&,
const std::array<uint16_t, 8>&) {
return Ok{};
}
Result<> makeI32x4Const(Index,
const std::vector<Annotation>&,
const std::array<uint32_t, 4>&) {
return Ok{};
}
Result<> makeI64x2Const(Index,
const std::vector<Annotation>&,
const std::array<uint64_t, 2>&) {
return Ok{};
}
Result<> makeF32x4Const(Index,
const std::vector<Annotation>&,
const std::array<float, 4>&) {
return Ok{};
}
Result<> makeF64x2Const(Index,
const std::vector<Annotation>&,
const std::array<double, 2>&) {
return Ok{};
}
Result<> makeLoad(Index,
const std::vector<Annotation>&,
Type,
bool,
int,
bool,
MemoryIdxT*,
MemargT) {
return Ok{};
}
Result<> makeStore(Index,
const std::vector<Annotation>&,
Type,
int,
bool,
MemoryIdxT*,
MemargT) {
return Ok{};
}
Result<> makeAtomicRMW(Index,
const std::vector<Annotation>&,
AtomicRMWOp,
Type,
int,
MemoryIdxT*,
MemargT) {
return Ok{};
}
Result<> makeAtomicCmpxchg(
Index, const std::vector<Annotation>&, Type, int, MemoryIdxT*, MemargT) {
return Ok{};
}
Result<> makeAtomicWait(
Index, const std::vector<Annotation>&, Type, MemoryIdxT*, MemargT) {
return Ok{};
}
Result<> makeAtomicNotify(Index,
const std::vector<Annotation>&,
MemoryIdxT*,
MemargT) {
return Ok{};
}
Result<> makeAtomicFence(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeSIMDExtract(Index,
const std::vector<Annotation>&,
SIMDExtractOp,
uint8_t) {
return Ok{};
}
Result<> makeSIMDReplace(Index,
const std::vector<Annotation>&,
SIMDReplaceOp,
uint8_t) {
return Ok{};
}
Result<> makeSIMDShuffle(Index,
const std::vector<Annotation>&,
const std::array<uint8_t, 16>&) {
return Ok{};
}
Result<>
makeSIMDTernary(Index, const std::vector<Annotation>&, SIMDTernaryOp) {
return Ok{};
}
Result<> makeSIMDShift(Index, const std::vector<Annotation>&, SIMDShiftOp) {
return Ok{};
}
Result<> makeSIMDLoad(
Index, const std::vector<Annotation>&, SIMDLoadOp, MemoryIdxT*, MemargT) {
return Ok{};
}
Result<> makeSIMDLoadStoreLane(Index,
const std::vector<Annotation>&,
SIMDLoadStoreLaneOp,
MemoryIdxT*,
MemargT,
uint8_t) {
return Ok{};
}
Result<>
makeMemoryInit(Index, const std::vector<Annotation>&, MemoryIdxT*, DataIdxT) {
return Ok{};
}
Result<> makeDataDrop(Index, const std::vector<Annotation>&, DataIdxT) {
return Ok{};
}
Result<> makeMemoryCopy(Index,
const std::vector<Annotation>&,
MemoryIdxT*,
MemoryIdxT*) {
return Ok{};
}
Result<> makeMemoryFill(Index, const std::vector<Annotation>&, MemoryIdxT*) {
return Ok{};
}
template<typename TypeT>
Result<> makePop(Index, const std::vector<Annotation>&, TypeT) {
return Ok{};
}
Result<> makeCall(Index, const std::vector<Annotation>&, FuncIdxT, bool) {
return Ok{};
}
template<typename TypeUseT>
Result<> makeCallIndirect(
Index, const std::vector<Annotation>&, TableIdxT*, TypeUseT, bool) {
return Ok{};
}
Result<> makeBreak(Index, const std::vector<Annotation>&, LabelIdxT, bool) {
return Ok{};
}
Result<> makeSwitch(Index,
const std::vector<Annotation>&,
const std::vector<LabelIdxT>&,
LabelIdxT) {
return Ok{};
}
Result<> makeReturn(Index, const std::vector<Annotation>&) { return Ok{}; }
template<typename HeapTypeT>
Result<> makeRefNull(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
Result<> makeRefIsNull(Index, const std::vector<Annotation>&) { return Ok{}; }
Result<> makeRefFunc(Index, const std::vector<Annotation>&, FuncIdxT) {
return Ok{};
}
Result<> makeRefEq(Index, const std::vector<Annotation>&) { return Ok{}; }
Result<> makeTableGet(Index, const std::vector<Annotation>&, TableIdxT*) {
return Ok{};
}
Result<> makeTableSet(Index, const std::vector<Annotation>&, TableIdxT*) {
return Ok{};
}
Result<> makeTableSize(Index, const std::vector<Annotation>&, TableIdxT*) {
return Ok{};
}
Result<> makeTableGrow(Index, const std::vector<Annotation>&, TableIdxT*) {
return Ok{};
}
Result<> makeTableFill(Index, const std::vector<Annotation>&, TableIdxT*) {
return Ok{};
}
Result<>
makeTableCopy(Index, const std::vector<Annotation>&, TableIdxT*, TableIdxT*) {
return Ok{};
}
Result<>
makeTableInit(Index, const std::vector<Annotation>&, TableIdxT*, ElemIdxT) {
return Ok{};
}
Result<> makeThrow(Index, const std::vector<Annotation>&, TagIdxT) {
return Ok{};
}
Result<> makeRethrow(Index, const std::vector<Annotation>&, LabelIdxT) {
return Ok{};
}
Result<> makeThrowRef(Index, const std::vector<Annotation>&) { return Ok{}; }
Result<> makeTupleMake(Index, const std::vector<Annotation>&, uint32_t) {
return Ok{};
}
Result<>
makeTupleExtract(Index, const std::vector<Annotation>&, uint32_t, uint32_t) {
return Ok{};
}
Result<> makeTupleDrop(Index, const std::vector<Annotation>&, uint32_t) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeCallRef(Index, const std::vector<Annotation>&, HeapTypeT, bool) {
return Ok{};
}
Result<>
makeRefI31(Index, const std::vector<Annotation>&, Shareability share) {
return Ok{};
}
Result<> makeI31Get(Index, const std::vector<Annotation>&, bool) {
return Ok{};
}
template<typename TypeT>
Result<> makeRefTest(Index, const std::vector<Annotation>&, TypeT) {
return Ok{};
}
template<typename TypeT>
Result<> makeRefCast(Index, const std::vector<Annotation>&, TypeT) {
return Ok{};
}
Result<> makeBrOn(Index, const std::vector<Annotation>&, LabelIdxT, BrOnOp) {
return Ok{};
}
template<typename TypeT>
Result<> makeBrOn(
Index, const std::vector<Annotation>&, LabelIdxT, BrOnOp, TypeT, TypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeStructNew(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeStructNewDefault(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeStructGet(
Index, const std::vector<Annotation>&, HeapTypeT, FieldIdxT, bool) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeStructSet(Index, const std::vector<Annotation>&, HeapTypeT, FieldIdxT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArrayNew(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeArrayNewDefault(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeArrayNewData(Index, const std::vector<Annotation>&, HeapTypeT, DataIdxT) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeArrayNewElem(Index, const std::vector<Annotation>&, HeapTypeT, ElemIdxT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArrayNewFixed(Index,
const std::vector<Annotation>&,
HeapTypeT,
uint32_t) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeArrayGet(Index, const std::vector<Annotation>&, HeapTypeT, bool) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArraySet(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
Result<> makeArrayLen(Index, const std::vector<Annotation>&) { return Ok{}; }
template<typename HeapTypeT>
Result<>
makeArrayCopy(Index, const std::vector<Annotation>&, HeapTypeT, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArrayFill(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArrayInitData(Index,
const std::vector<Annotation>&,
HeapTypeT,
DataIdxT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeArrayInitElem(Index,
const std::vector<Annotation>&,
HeapTypeT,
ElemIdxT) {
return Ok{};
}
Result<> makeRefAs(Index, const std::vector<Annotation>&, RefAsOp) {
return Ok{};
}
Result<> makeStringNew(Index, const std::vector<Annotation>&, StringNewOp) {
return Ok{};
}
Result<>
makeStringConst(Index, const std::vector<Annotation>&, std::string_view) {
return Ok{};
}
Result<>
makeStringMeasure(Index, const std::vector<Annotation>&, StringMeasureOp) {
return Ok{};
}
Result<>
makeStringEncode(Index, const std::vector<Annotation>&, StringEncodeOp) {
return Ok{};
}
Result<> makeStringConcat(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeStringEq(Index, const std::vector<Annotation>&, StringEqOp) {
return Ok{};
}
Result<> makeStringWTF8Advance(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeStringWTF16Get(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeStringIterNext(Index, const std::vector<Annotation>&) {
return Ok{};
}
Result<> makeStringSliceWTF(Index, const std::vector<Annotation>&) {
return Ok{};
}
template<typename HeapTypeT>
Result<>
makeContBind(Index, const std::vector<Annotation>&, HeapTypeT, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeContNew(Index, const std::vector<Annotation>&, HeapTypeT) {
return Ok{};
}
template<typename HeapTypeT>
Result<> makeResume(Index,
const std::vector<Annotation>&,
HeapTypeT,
const TagLabelListT&) {
return Ok{};
}
Result<> makeSuspend(Index, const std::vector<Annotation>&, TagIdxT) {
return Ok{};
}
};
struct NullCtx : NullTypeParserCtx, NullInstrParserCtx {
Lexer in;
NullCtx(const Lexer& in) : in(in) {}
Result<> makeTypeUse(Index, std::optional<HeapTypeT>, ParamsT*, ResultsT*) {
return Ok{};
}
};
// Phase 1: Parse definition spans for top-level module elements and determine
// their indices and names.
struct ParseDeclsCtx : NullTypeParserCtx, NullInstrParserCtx {
using ExprT = Ok;
using LimitsT = Limits;
using ElemListT = Index;
using DataStringT = std::vector<char>;
using TableTypeT = TableType;
using MemTypeT = MemType;
Lexer in;
// At this stage we only look at types to find implicit type definitions,
// which are inserted directly into the context. We cannot materialize or
// validate any types because we don't know what types exist yet.
//
// Declared module elements are inserted into the module, but their bodies are
// not filled out until later parsing phases.
Module& wasm;
// The module element definitions we are parsing in this phase.
std::vector<DefPos> recTypeDefs;
std::vector<DefPos> typeDefs;
std::vector<DefPos> funcDefs;
std::vector<DefPos> tableDefs;
std::vector<DefPos> memoryDefs;
std::vector<DefPos> globalDefs;
std::vector<DefPos> startDefs;
std::vector<DefPos> elemDefs;
std::vector<DefPos> dataDefs;
std::vector<DefPos> tagDefs;
// Positions of export definitions.
std::vector<Index> exportDefs;
// Positions of typeuses that might implicitly define new types.
std::vector<Index> implicitTypeDefs;
// Map table indices to the indices of their implicit, in-line element
// segments. We need these to find associated segments in later parsing phases
// where we can parse their types and instructions.
std::unordered_map<Index, Index> implicitElemIndices;
// Counters used for generating names for module elements.
int funcCounter = 0;
int tableCounter = 0;
int memoryCounter = 0;
int globalCounter = 0;
int elemCounter = 0;
int dataCounter = 0;
int tagCounter = 0;
// Used to verify that all imports come before all non-imports.
bool hasNonImport = false;
Result<> checkImport(Index pos, ImportNames* import) {
if (import) {
if (hasNonImport) {
return in.err(pos, "import after non-import");
}
} else {
hasNonImport = true;
}
return Ok{};
}
ParseDeclsCtx(Lexer& in, Module& wasm) : in(in), wasm(wasm) {}
void addFuncType(SignatureT) {}
void addContType(ContinuationT) {}
void addStructType(StructT) {}
void addArrayType(ArrayT) {}
void setOpen() {}
void setShared() {}
Result<> addSubtype(HeapTypeT) { return Ok{}; }
void finishTypeDef(Name name, Index pos) {
// TODO: type annotations
typeDefs.push_back({name, pos, Index(typeDefs.size()), {}});
}
size_t getRecGroupStartIndex() { return 0; }
void addRecGroup(Index, size_t) {}
void finishRectype(Index pos) {
// TODO: type annotations
recTypeDefs.push_back({{}, pos, Index(recTypeDefs.size()), {}});
}
Limits makeLimits(uint64_t n, std::optional<uint64_t> m) {
return Limits{n, m};
}
Index makeElemList(TypeT) { return 0; }
Index makeFuncElemList() { return 0; }
void appendElem(Index& elems, ExprT) { ++elems; }
void appendFuncElem(Index& elems, FuncIdxT) { ++elems; }
Limits getLimitsFromElems(Index elems) { return {elems, elems}; }
TableType makeTableType(Type addressType, Limits limits, TypeT) {
return {addressType, limits};
}
std::vector<char> makeDataString() { return {}; }
void appendDataString(std::vector<char>& data, std::string_view str) {
data.insert(data.end(), str.begin(), str.end());
}
Limits getLimitsFromData(const std::vector<char>& data) {
uint64_t size = (data.size() + Memory::kPageSize - 1) / Memory::kPageSize;
return {size, size};
}
MemType makeMemType(Type addressType, Limits limits, bool shared) {
return {addressType, limits, shared};
}
Result<TypeUseT>
makeTypeUse(Index pos, std::optional<HeapTypeT> type, ParamsT*, ResultsT*) {
if (!type) {
implicitTypeDefs.push_back(pos);
}
return Ok{};
}
Result<Function*> addFuncDecl(Index pos, Name name, ImportNames* importNames);
Result<> addFunc(Name name,
const std::vector<Name>& exports,
ImportNames* import,
TypeUseT type,
std::optional<LocalsT>,
std::vector<Annotation>&&,
Index pos);
Result<Table*> addTableDecl(Index pos,
Name name,
ImportNames* importNames,
TableType limits);
Result<>
addTable(Name, const std::vector<Name>&, ImportNames*, TableType, Index);
// TODO: Record index of implicit elem for use when parsing types and instrs.
Result<> addImplicitElems(TypeT, ElemListT&& elems);
Result<Memory*>
addMemoryDecl(Index pos, Name name, ImportNames* importNames, MemType type);
Result<> addMemory(Name name,
const std::vector<Name>& exports,
ImportNames* import,
MemType type,
Index pos);
Result<> addImplicitData(DataStringT&& data);
Result<Global*> addGlobalDecl(Index pos, Name name, ImportNames* importNames);
Result<> addGlobal(Name name,
const std::vector<Name>& exports,
ImportNames* import,
GlobalTypeT,
std::optional<ExprT>,
Index pos);
Result<> addStart(FuncIdxT, Index pos) {
if (!startDefs.empty()) {
return Err{"unexpected extra 'start' function"};
}
// TODO: start function annotations.
startDefs.push_back({{}, pos, 0, {}});
return Ok{};
}
Result<> addElem(Name, TableIdxT*, std::optional<ExprT>, ElemListT&&, Index);
Result<> addDeclareElem(Name, ElemListT&&, Index) { return Ok{}; }
Result<> addData(Name name,
MemoryIdxT*,
std::optional<ExprT>,
std::vector<char>&& data,
Index pos);
Result<Tag*> addTagDecl(Index pos, Name name, ImportNames* importNames);
Result<> addTag(Name name,
const std::vector<Name>& exports,
ImportNames* import,
TypeUseT type,
Index pos);
Result<> addExport(Index pos, Ok, Name, ExternalKind) {
exportDefs.push_back(pos);
return Ok{};
}
};
// Phase 2: Parse type definitions into a TypeBuilder.
struct ParseTypeDefsCtx : TypeParserCtx<ParseTypeDefsCtx> {
Lexer in;
// We update slots in this builder as we parse type definitions.
TypeBuilder& builder;
// Parse the names of types and fields as we go.
std::vector<TypeNames> names;
// The index of the subtype definition we are parsing.
Index index = 0;
ParseTypeDefsCtx(Lexer& in, TypeBuilder& builder, const IndexMap& typeIndices)
: TypeParserCtx<ParseTypeDefsCtx>(typeIndices), in(in), builder(builder),
names(builder.size()) {}
TypeT makeRefType(HeapTypeT ht, Nullability nullability) {
return builder.getTempRefType(ht, nullability);
}
TypeT makeTupleType(const std::vector<Type> types) {
return builder.getTempTupleType(types);
}
Result<HeapTypeT> getHeapTypeFromIdx(Index idx) {
if (idx >= builder.size()) {
return in.err("type index out of bounds");
}
return builder[idx];
}
void addFuncType(SignatureT& type) { builder[index] = type; }
void addContType(ContinuationT& type) { builder[index] = type; }
void addStructType(StructT& type) {
auto& [fieldNames, str] = type;
builder[index] = str;
for (Index i = 0; i < fieldNames.size(); ++i) {
if (auto name = fieldNames[i]; name.is()) {
names[index].fieldNames[i] = name;
}
}
}
void addArrayType(ArrayT& type) { builder[index] = type; }
void setOpen() { builder[index].setOpen(); }
void setShared() { builder[index].setShared(); }
Result<> addSubtype(HeapTypeT super) {
builder[index].subTypeOf(super);
return Ok{};
}
void finishTypeDef(Name name, Index pos) { names[index++].name = name; }
size_t getRecGroupStartIndex() { return index; }
void addRecGroup(Index start, size_t len) {
builder.createRecGroup(start, len);
}
void finishRectype(Index) {}
};
// Phase 3: Parse type uses to find implicitly defined types.
struct ParseImplicitTypeDefsCtx : TypeParserCtx<ParseImplicitTypeDefsCtx> {
using TypeUseT = Ok;
Lexer in;
// Types parsed so far.
std::vector<HeapType>& types;
// Map typeuse positions without an explicit type to the correct type.
std::unordered_map<Index, HeapType>& implicitTypes;
// Map signatures to the first defined heap type they match.
std::unordered_map<Signature, HeapType> sigTypes;
ParseImplicitTypeDefsCtx(Lexer& in,
std::vector<HeapType>& types,
std::unordered_map<Index, HeapType>& implicitTypes,
const IndexMap& typeIndices)
: TypeParserCtx<ParseImplicitTypeDefsCtx>(typeIndices), in(in),
types(types), implicitTypes(implicitTypes) {
for (auto type : types) {
if (type.isSignature() && type.getRecGroup().size() == 1 &&
!type.getDeclaredSuperType() && !type.isOpen() && !type.isShared()) {
sigTypes.insert({type.getSignature(), type});
}
}
}
Result<HeapTypeT> getHeapTypeFromIdx(Index idx) {
if (idx >= types.size()) {
return in.err("type index out of bounds");
}
return types[idx];
}
Result<TypeUseT> makeTypeUse(Index pos,
std::optional<HeapTypeT>,
ParamsT* params,
ResultsT* results) {
std::vector<Type> paramTypes;
if (params) {
paramTypes = getUnnamedTypes(*params);
}
std::vector<Type> resultTypes;
if (results) {
resultTypes = *results;
}
auto sig = Signature(Type(paramTypes), Type(resultTypes));
auto [it, inserted] = sigTypes.insert({sig, HeapType::func});
if (inserted) {
auto type = HeapType(sig);
it->second = type;
types.push_back(type);
}
implicitTypes.insert({pos, it->second});
return Ok{};
}
};
// Phase 4: Parse and set the types of module elements.
struct ParseModuleTypesCtx : TypeParserCtx<ParseModuleTypesCtx>,
NullInstrParserCtx {
// In this phase we have constructed all the types, so we can materialize and
// validate them when they are used.
using GlobalTypeT = GlobalType;
using TableTypeT = Type;
using TypeUseT = TypeUse;
using ElemListT = Type;
Lexer in;
Module& wasm;
const std::vector<HeapType>& types;
const std::unordered_map<Index, HeapType>& implicitTypes;
const std::unordered_map<Index, Index>& implicitElemIndices;
// The index of the current type.
Index index = 0;
ParseModuleTypesCtx(
Lexer& in,
Module& wasm,
const std::vector<HeapType>& types,
const std::unordered_map<Index, HeapType>& implicitTypes,
const std::unordered_map<Index, Index>& implicitElemIndices,
const IndexMap& typeIndices)
: TypeParserCtx<ParseModuleTypesCtx>(typeIndices), in(in), wasm(wasm),
types(types), implicitTypes(implicitTypes),
implicitElemIndices(implicitElemIndices) {}
bool skipFunctionBody() { return true; }
Result<HeapTypeT> getHeapTypeFromIdx(Index idx) {
if (idx >= types.size()) {
return in.err("type index out of bounds");
}
return types[idx];
}
Result<TypeUseT> makeTypeUse(Index pos,
std::optional<HeapTypeT> type,
ParamsT* params,
ResultsT* results) {
std::vector<Name> ids;
if (params) {
ids.reserve(params->size());
for (auto& p : *params) {
ids.push_back(p.name);
}
}
if (type) {
return TypeUse{*type, ids};
}
auto it = implicitTypes.find(pos);
assert(it != implicitTypes.end());
return TypeUse{it->second, ids};
}
Result<HeapType> getBlockTypeFromTypeUse(Index pos, TypeUse use) {
return use.type;
}
GlobalTypeT makeGlobalType(Mutability mutability, TypeT type) {
return {mutability, type};
}
Type makeElemList(Type type) { return type; }
Type makeFuncElemList() { return Type(HeapType::func, Nullable); }
void appendElem(ElemListT&, ExprT) {}
void appendFuncElem(ElemListT&, FuncIdxT) {}
LimitsT getLimitsFromElems(ElemListT) { return Ok{}; }
Type makeTableType(Type addressType, LimitsT, Type type) { return type; }
LimitsT getLimitsFromData(DataStringT) { return Ok{}; }
MemTypeT makeMemType(Type, LimitsT, bool) { return Ok{}; }
Result<> addFunc(Name name,
const std::vector<Name>&,
ImportNames*,
TypeUse type,
std::optional<LocalsT> locals,
std::vector<Annotation>&&,
Index pos) {
auto& f = wasm.functions[index];
if (!type.type.isSignature()) {
return in.err(pos, "expected signature type");
}
f->type = type.type;
for (Index i = 0; i < type.names.size(); ++i) {
if (type.names[i].is()) {
f->setLocalName(i, type.names[i]);
}
}
if (locals) {
for (auto& l : *locals) {
Builder::addVar(f.get(), l.name, l.type);
}
}
return Ok{};
}
Result<> addTable(
Name, const std::vector<Name>&, ImportNames*, Type ttype, Index pos) {
auto& t = wasm.tables[index];
if (!ttype.isRef()) {
return in.err(pos, "expected reference type");
}
t->type = ttype;
return Ok{};
}
Result<> addImplicitElems(Type type, ElemListT&&) {
auto& t = wasm.tables[index];
auto& e = wasm.elementSegments[implicitElemIndices.at(index)];
e->type = t->type;
return Ok{};
}
Result<>
addMemory(Name, const std::vector<Name>&, ImportNames*, MemTypeT, Index) {
return Ok{};
}
Result<> addImplicitData(DataStringT&& data) { return Ok{}; }
Result<> addGlobal(Name,
const std::vector<Name>&,
ImportNames*,
GlobalType type,
std::optional<ExprT>,
Index) {
auto& g = wasm.globals[index];
g->mutable_ = type.mutability;
g->type = type.type;
return Ok{};
}
Result<>
addElem(Name, TableIdxT*, std::optional<ExprT>, ElemListT&& type, Index) {
auto& e = wasm.elementSegments[index];
e->type = type;
return Ok{};
}
Result<> addDeclareElem(Name, ElemListT&&, Index) { return Ok{}; }
Result<>
addTag(Name, const std::vector<Name>&, ImportNames*, TypeUse use, Index pos) {
auto& t = wasm.tags[index];
if (!use.type.isSignature()) {
return in.err(pos, "tag type must be a signature");
}
t->sig = use.type.getSignature();
return Ok{};
}
};
// Phase 5: Parse module element definitions, including instructions.
struct ParseDefsCtx : TypeParserCtx<ParseDefsCtx> {
using GlobalTypeT = Ok;
using TableTypeT = Ok;
using TypeUseT = HeapType;
using FieldIdxT = Index;
using FuncIdxT = Name;
using LocalIdxT = Index;
using LabelIdxT = Index;
using GlobalIdxT = Name;
using TableIdxT = Name;
using MemoryIdxT = Name;
using ElemIdxT = Name;
using DataIdxT = Name;
using TagIdxT = Name;
using MemargT = Memarg;
using ExprT = Expression*;
using ElemListT = std::vector<Expression*>;
struct CatchInfo;
using CatchT = CatchInfo;
using CatchListT = std::vector<CatchInfo>;
using TagLabelListT = std::vector<std::pair<TagIdxT, LabelIdxT>>;
Lexer in;
Module& wasm;
Builder builder;
const std::vector<HeapType>& types;
const std::unordered_map<Index, HeapType>& implicitTypes;
const std::unordered_map<HeapType, std::unordered_map<Name, Index>>&
typeNames;
const std::unordered_map<Index, Index>& implicitElemIndices;
std::unordered_map<std::string_view, Index> debugSymbolNameIndices;
std::unordered_map<std::string_view, Index> debugFileIndices;
// The index of the current module element.
Index index = 0;
// The current function being parsed, used to create scratch locals, type
// local.get, etc.
Function* func = nullptr;
IRBuilder irBuilder;
Result<> visitFunctionStart(Function* func) {
this->func = func;
CHECK_ERR(irBuilder.visitFunctionStart(func));
return Ok{};
}
ParseDefsCtx(
Lexer& in,
Module& wasm,
const std::vector<HeapType>& types,
const std::unordered_map<Index, HeapType>& implicitTypes,
const std::unordered_map<HeapType, std::unordered_map<Name, Index>>&
typeNames,
const std::unordered_map<Index, Index>& implicitElemIndices,
const IndexMap& typeIndices)
: TypeParserCtx(typeIndices), in(in), wasm(wasm), builder(wasm),
types(types), implicitTypes(implicitTypes), typeNames(typeNames),
implicitElemIndices(implicitElemIndices), irBuilder(wasm) {}
template<typename T> Result<T> withLoc(Index pos, Result<T> res) {
if (auto err = res.getErr()) {
return in.err(pos, err->msg);
}
return res;
}
template<typename T> Result<T> withLoc(Result<T> res) {
return withLoc(in.getPos(), res);
}
HeapType getBlockTypeFromResult(const std::vector<Type> results) {
assert(results.size() == 1);
return HeapType(Signature(Type::none, results[0]));
}
Result<HeapType> getBlockTypeFromTypeUse(Index pos, HeapType type) {
assert(type.isSignature());
// TODO: Error if block parameters are named
return type;
}
GlobalTypeT makeGlobalType(Mutability, TypeT) { return Ok{}; }
std::vector<Expression*> makeElemList(TypeT) { return {}; }
std::vector<Expression*> makeFuncElemList() { return {}; }
void appendElem(std::vector<Expression*>& elems, Expression* expr) {
elems.push_back(expr);
}
void appendFuncElem(std::vector<Expression*>& elems, Name func) {
auto type = wasm.getFunction(func)->type;
elems.push_back(builder.makeRefFunc(func, type));
}
LimitsT getLimitsFromElems(std::vector<Expression*>& elems) { return Ok{}; }
TableTypeT makeTableType(Type, LimitsT, Type) { return Ok{}; }
struct CatchInfo {
Name tag;
Index label;
bool isRef;
};
std::vector<CatchInfo> makeCatchList() { return {}; }
void appendCatch(std::vector<CatchInfo>& list, CatchInfo info) {
list.push_back(info);
}
CatchInfo makeCatch(Name tag, Index label) { return {tag, label, false}; }
CatchInfo makeCatchRef(Name tag, Index label) { return {tag, label, true}; }
CatchInfo makeCatchAll(Index label) { return {{}, label, false}; }
CatchInfo makeCatchAllRef(Index label) { return {{}, label, true}; }
TagLabelListT makeTagLabelList() { return {}; }
void appendTagLabel(TagLabelListT& tagLabels, Name tag, Index label) {
tagLabels.push_back({tag, label});
}
Result<HeapTypeT> getHeapTypeFromIdx(Index idx) {
if (idx >= types.size()) {
return in.err("type index out of bounds");
}
return types[idx];
}
Result<Index> getFieldFromIdx(HeapType type, uint32_t idx) {
if (!type.isStruct()) {
return in.err("expected struct type");
}
if (idx >= type.getStruct().fields.size()) {
return in.err("struct index out of bounds");
}
return idx;
}
Result<Index> getFieldFromName(HeapType type, Name name) {
if (auto typeIt = typeNames.find(type); typeIt != typeNames.end()) {
const auto& fieldIdxs = typeIt->second;
if (auto fieldIt = fieldIdxs.find(name); fieldIt != fieldIdxs.end()) {
return fieldIt->second;
}
}
return in.err("unrecognized field name");
}
Result<Index> getLocalFromIdx(uint32_t idx) {
if (!func) {
return in.err("cannot access locals outside of a function");
}
if (idx >= func->getNumLocals()) {
return in.err("local index out of bounds");
}
return idx;
}
Result<Name> getFuncFromIdx(uint32_t idx) {
if (idx >= wasm.functions.size()) {
return in.err("function index out of bounds");
}
return wasm.functions[idx]->name;
}
Result<Name> getFuncFromName(Name name) {
if (!wasm.getFunctionOrNull(name)) {
return in.err("function $" + name.toString() + " does not exist");
}
return name;
}
Result<Index> getLocalFromName(Name name) {
if (!func) {
return in.err("cannot access locals outside of a function");
}
if (!func->hasLocalIndex(name)) {
return in.err("local $" + name.toString() + " does not exist");
}
return func->getLocalIndex(name);
}
Result<Name> getGlobalFromIdx(uint32_t idx) {
if (idx >= wasm.globals.size()) {
return in.err("global index out of bounds");
}
return wasm.globals[idx]->name;
}
Result<Name> getGlobalFromName(Name name) {
if (!wasm.getGlobalOrNull(name)) {
return in.err("global $" + name.toString() + " does not exist");
}
return name;
}
Result<Name> getTableFromIdx(uint32_t idx) {
if (idx >= wasm.tables.size()) {
return in.err("table index out of bounds");
}
return wasm.tables[idx]->name;
}
Result<Name> getTableFromName(Name name) {
if (!wasm.getTableOrNull(name)) {
return in.err("table $" + name.toString() + " does not exist");
}
return name;
}
Result<Name> getMemoryFromIdx(uint32_t idx) {
if (idx >= wasm.memories.size()) {
return in.err("memory index out of bounds");
}
return wasm.memories[idx]->name;
}
Result<Name> getMemoryFromName(Name name) {
if (!wasm.getMemoryOrNull(name)) {
return in.err("memory $" + name.toString() + " does not exist");
}
return name;
}
Result<Name> getElemFromIdx(uint32_t idx) {
if (idx >= wasm.elementSegments.size()) {
return in.err("elem index out of bounds");
}
return wasm.elementSegments[idx]->name;
}
Result<Name> getElemFromName(Name name) {
if (!wasm.getElementSegmentOrNull(name)) {
return in.err("elem $" + name.toString() + " does not exist");
}
return name;
}
Result<Name> getDataFromIdx(uint32_t idx) {
if (idx >= wasm.dataSegments.size()) {
return in.err("data index out of bounds");
}
return wasm.dataSegments[idx]->name;
}
Result<Name> getDataFromName(Name name) {
if (!wasm.getDataSegmentOrNull(name)) {
return in.err("data $" + name.toString() + " does not exist");
}
return name;
}
Result<Index> getLabelFromIdx(uint32_t idx, bool) { return idx; }
Result<Index> getLabelFromName(Name name, bool inDelegate) {
return irBuilder.getLabelIndex(name, inDelegate);
}
Result<Name> getTagFromIdx(uint32_t idx) {
if (idx >= wasm.tags.size()) {
return in.err("tag index out of bounds");
}
return wasm.tags[idx]->name;
}
Result<Name> getTagFromName(Name name) {
if (!wasm.getTagOrNull(name)) {
return in.err("tag $" + name.toString() + " does not exist");
}
return name;
}
Result<TypeUseT> makeTypeUse(Index pos,
std::optional<HeapTypeT> type,
ParamsT* params,
ResultsT* results);
Result<> addFunc(Name,
const std::vector<Name>&,
ImportNames*,
TypeUseT,
std::optional<LocalsT>,
std::vector<Annotation>&&,
Index) {
return Ok{};
}
Result<>
addTable(Name, const std::vector<Name>&, ImportNames*, TableTypeT, Index) {
return Ok{};
}
Result<>
addMemory(Name, const std::vector<Name>&, ImportNames*, TableTypeT, Index) {
return Ok{};
}
Result<> addGlobal(Name,
const std::vector<Name>&,
ImportNames*,
GlobalTypeT,
std::optional<ExprT> exp,
Index);
Result<> addStart(Name name, Index pos) {
wasm.start = name;
return Ok{};
}
Result<> addImplicitElems(Type type, std::vector<Expression*>&& elems);
Result<> addDeclareElem(Name, std::vector<Expression*>&&, Index) {
// TODO: Validate that referenced functions appear in a declarative element
// segment.
return Ok{};
}
Result<> addElem(Name,
Name* table,
std::optional<Expression*> offset,
std::vector<Expression*>&& elems,
Index pos);
Result<>
addData(Name, Name* mem, std::optional<ExprT> offset, DataStringT, Index pos);
Result<>
addTag(Name, const std::vector<Name>, ImportNames*, TypeUseT, Index) {
return Ok{};
}
Result<> addExport(Index pos, Name value, Name name, ExternalKind kind) {
if (wasm.getExportOrNull(name)) {
return in.err(pos, "duplicate export");
}
wasm.addExport(builder.makeExport(name, value, kind));
return Ok{};
}
Result<Index> addScratchLocal(Index pos, Type type) {
if (!func) {
return in.err(pos,
"scratch local required, but there is no function context");
}
Name name = Names::getValidLocalName(*func, "scratch");
return Builder::addVar(func, name, type);
}
Result<Expression*> makeExpr() { return withLoc(irBuilder.build()); }
Memarg getMemarg(uint64_t offset, uint32_t align) { return {offset, align}; }
Result<Name> getTable(Index pos, Name* table) {
if (table) {
return *table;
}
if (wasm.tables.empty()) {
return in.err(pos, "table required, but there is no table");
}
return wasm.tables[0]->name;
}
Result<Name> getMemory(Index pos, Name* mem) {
if (mem) {
return *mem;
}
if (wasm.memories.empty()) {
return in.err(pos, "memory required, but there is no memory");
}
return wasm.memories[0]->name;
}
void setSrcLoc(const std::vector<Annotation>& annotations) {
const Annotation* annotation = nullptr;
for (auto& a : annotations) {
if (a.kind == srcAnnotationKind) {
annotation = &a;
}
}
if (!annotation) {
return;
}
Lexer lexer(annotation->contents);
if (lexer.empty()) {
irBuilder.setDebugLocation(std::nullopt);
return;
}
auto contents = lexer.next();
auto fileSize = contents.find(':');
if (fileSize == 0 || fileSize == contents.npos) {
return;
}
auto file = contents.substr(0, fileSize);
contents = contents.substr(fileSize + 1);
auto lineSize = contents.find(':');
if (lineSize == contents.npos) {
return;
}
lexer = Lexer(contents.substr(0, lineSize));
auto line = lexer.takeU32();
if (!line || !lexer.empty()) {
return;
}
contents = contents.substr(lineSize + 1);
auto colSize = contents.find(':');
if (colSize == contents.npos) {
colSize = contents.size();
if (colSize == 0) {
return;
}
}
lexer = Lexer(contents.substr(0, colSize));
auto col = lexer.takeU32();
if (!col) {
return;
}
std::optional<BinaryLocation> symbolNameIndex;
if (colSize != contents.size()) {
contents = contents.substr(colSize + 1);
auto symbolName = contents;
auto [it, inserted] = debugSymbolNameIndices.insert(
{symbolName, debugSymbolNameIndices.size()});
if (inserted) {
assert(wasm.debugInfoSymbolNames.size() == it->second);
wasm.debugInfoSymbolNames.push_back(std::string(symbolName));
}
symbolNameIndex = it->second;
}
// TODO: If we ever parallelize the parse, access to
// `wasm.debugInfoFileNames` will have to be protected by a lock.
auto [it, inserted] =
debugFileIndices.insert({file, debugFileIndices.size()});
if (inserted) {
assert(wasm.debugInfoFileNames.size() == it->second);
wasm.debugInfoFileNames.push_back(std::string(file));
}
irBuilder.setDebugLocation(
Function::DebugLocation({it->second, *line, *col, symbolNameIndex}));
}
Result<> makeBlock(Index pos,
const std::vector<Annotation>& annotations,
std::optional<Name> label,
HeapType type) {
// TODO: validate labels?
// TODO: Move error on input types to here?
if (!type.isSignature()) {
return in.err(pos, "expected function type");
}
return withLoc(
pos, irBuilder.makeBlock(label ? *label : Name{}, type.getSignature()));
}
Result<> makeIf(Index pos,
const std::vector<Annotation>& annotations,
std::optional<Name> label,
HeapType type) {
// TODO: validate labels?
if (!type.isSignature()) {
return in.err(pos, "expected function type");
}
return withLoc(
pos, irBuilder.makeIf(label ? *label : Name{}, type.getSignature()));
}
Result<> visitElse() { return withLoc(irBuilder.visitElse()); }
Result<> makeLoop(Index pos,
const std::vector<Annotation>& annotations,
std::optional<Name> label,
HeapType type) {
// TODO: validate labels?
if (!type.isSignature()) {
return in.err(pos, "expected function type");
}
return withLoc(
pos, irBuilder.makeLoop(label ? *label : Name{}, type.getSignature()));
}
Result<> makeTry(Index pos,
const std::vector<Annotation>& annotations,
std::optional<Name> label,
HeapType type) {
// TODO: validate labels?
if (!type.isSignature()) {
return in.err(pos, "expected function type");
}
return withLoc(
pos, irBuilder.makeTry(label ? *label : Name{}, type.getSignature()));
}
Result<> makeTryTable(Index pos,
const std::vector<Annotation>& annotations,
std::optional<Name> label,
HeapType type,
const std::vector<CatchInfo>& info) {
std::vector<Name> tags;
std::vector<Index> labels;
std::vector<bool> isRefs;
for (auto& info : info) {
tags.push_back(info.tag);
labels.push_back(info.label);
isRefs.push_back(info.isRef);
}
return withLoc(
pos,
irBuilder.makeTryTable(
label ? *label : Name{}, type.getSignature(), tags, labels, isRefs));
}
Result<> visitCatch(Index pos, Name tag) {
return withLoc(pos, irBuilder.visitCatch(tag));
}
Result<> visitCatchAll(Index pos) {
return withLoc(pos, irBuilder.visitCatchAll());
}
Result<> visitDelegate(Index pos, Index label) {
return withLoc(pos, irBuilder.visitDelegate(label));
}
Result<> visitEnd() { return withLoc(irBuilder.visitEnd()); }
Result<> makeUnreachable(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeUnreachable());
}
Result<> makeNop(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeNop());
}
Result<> makeBinary(Index pos,
const std::vector<Annotation>& annotations,
BinaryOp op) {
return withLoc(pos, irBuilder.makeBinary(op));
}
Result<>
makeUnary(Index pos, const std::vector<Annotation>& annotations, UnaryOp op) {
return withLoc(pos, irBuilder.makeUnary(op));
}
Result<> makeSelect(Index pos,
const std::vector<Annotation>& annotations,
std::vector<Type>* res) {
if (res && res->size()) {
if (res->size() > 1) {
return in.err(pos, "select may not have more than one result type");
}
return withLoc(pos, irBuilder.makeSelect((*res)[0]));
}
return withLoc(pos, irBuilder.makeSelect());
}
Result<> makeDrop(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeDrop());
}
Result<> makeMemorySize(Index pos,
const std::vector<Annotation>& annotations,
Name* mem) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeMemorySize(*m));
}
Result<> makeMemoryGrow(Index pos,
const std::vector<Annotation>& annotations,
Name* mem) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeMemoryGrow(*m));
}
Result<> makeLocalGet(Index pos,
const std::vector<Annotation>& annotations,
Index local) {
return withLoc(pos, irBuilder.makeLocalGet(local));
}
Result<> makeLocalTee(Index pos,
const std::vector<Annotation>& annotations,
Index local) {
return withLoc(pos, irBuilder.makeLocalTee(local));
}
Result<> makeLocalSet(Index pos,
const std::vector<Annotation>& annotations,
Index local) {
return withLoc(pos, irBuilder.makeLocalSet(local));
}
Result<> makeGlobalGet(Index pos,
const std::vector<Annotation>& annotations,
Name global) {
return withLoc(pos, irBuilder.makeGlobalGet(global));
}
Result<> makeGlobalSet(Index pos,
const std::vector<Annotation>& annotations,
Name global) {
assert(wasm.getGlobalOrNull(global));
return withLoc(pos, irBuilder.makeGlobalSet(global));
}
Result<> makeI32Const(Index pos,
const std::vector<Annotation>& annotations,
uint32_t c) {
return withLoc(pos, irBuilder.makeConst(Literal(c)));
}
Result<> makeI64Const(Index pos,
const std::vector<Annotation>& annotations,
uint64_t c) {
return withLoc(pos, irBuilder.makeConst(Literal(c)));
}
Result<>
makeF32Const(Index pos, const std::vector<Annotation>& annotations, float c) {
return withLoc(pos, irBuilder.makeConst(Literal(c)));
}
Result<> makeF64Const(Index pos,
const std::vector<Annotation>& annotations,
double c) {
return withLoc(pos, irBuilder.makeConst(Literal(c)));
}
Result<> makeI8x16Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<uint8_t, 16>& vals) {
std::array<Literal, 16> lanes;
for (size_t i = 0; i < 16; ++i) {
lanes[i] = Literal(uint32_t(vals[i]));
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeI16x8Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<uint16_t, 8>& vals) {
std::array<Literal, 8> lanes;
for (size_t i = 0; i < 8; ++i) {
lanes[i] = Literal(uint32_t(vals[i]));
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeI32x4Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<uint32_t, 4>& vals) {
std::array<Literal, 4> lanes;
for (size_t i = 0; i < 4; ++i) {
lanes[i] = Literal(vals[i]);
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeI64x2Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<uint64_t, 2>& vals) {
std::array<Literal, 2> lanes;
for (size_t i = 0; i < 2; ++i) {
lanes[i] = Literal(vals[i]);
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeF32x4Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<float, 4>& vals) {
std::array<Literal, 4> lanes;
for (size_t i = 0; i < 4; ++i) {
lanes[i] = Literal(vals[i]);
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeF64x2Const(Index pos,
const std::vector<Annotation>& annotations,
const std::array<double, 2>& vals) {
std::array<Literal, 2> lanes;
for (size_t i = 0; i < 2; ++i) {
lanes[i] = Literal(vals[i]);
}
return withLoc(pos, irBuilder.makeConst(Literal(lanes)));
}
Result<> makeLoad(Index pos,
const std::vector<Annotation>& annotations,
Type type,
bool signed_,
int bytes,
bool isAtomic,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
if (isAtomic) {
return withLoc(pos,
irBuilder.makeAtomicLoad(bytes, memarg.offset, type, *m));
}
return withLoc(pos,
irBuilder.makeLoad(
bytes, signed_, memarg.offset, memarg.align, type, *m));
}
Result<> makeStore(Index pos,
const std::vector<Annotation>& annotations,
Type type,
int bytes,
bool isAtomic,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
if (isAtomic) {
return withLoc(pos,
irBuilder.makeAtomicStore(bytes, memarg.offset, type, *m));
}
return withLoc(
pos, irBuilder.makeStore(bytes, memarg.offset, memarg.align, type, *m));
}
Result<> makeAtomicRMW(Index pos,
const std::vector<Annotation>& annotations,
AtomicRMWOp op,
Type type,
int bytes,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos,
irBuilder.makeAtomicRMW(op, bytes, memarg.offset, type, *m));
}
Result<> makeAtomicCmpxchg(Index pos,
const std::vector<Annotation>& annotations,
Type type,
int bytes,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos,
irBuilder.makeAtomicCmpxchg(bytes, memarg.offset, type, *m));
}
Result<> makeAtomicWait(Index pos,
const std::vector<Annotation>& annotations,
Type type,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeAtomicWait(type, memarg.offset, *m));
}
Result<> makeAtomicNotify(Index pos,
const std::vector<Annotation>& annotations,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeAtomicNotify(memarg.offset, *m));
}
Result<> makeAtomicFence(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeAtomicFence());
}
Result<> makeSIMDExtract(Index pos,
const std::vector<Annotation>& annotations,
SIMDExtractOp op,
uint8_t lane) {
return withLoc(pos, irBuilder.makeSIMDExtract(op, lane));
}
Result<> makeSIMDReplace(Index pos,
const std::vector<Annotation>& annotations,
SIMDReplaceOp op,
uint8_t lane) {
return withLoc(pos, irBuilder.makeSIMDReplace(op, lane));
}
Result<> makeSIMDShuffle(Index pos,
const std::vector<Annotation>& annotations,
const std::array<uint8_t, 16>& lanes) {
return withLoc(pos, irBuilder.makeSIMDShuffle(lanes));
}
Result<> makeSIMDTernary(Index pos,
const std::vector<Annotation>& annotations,
SIMDTernaryOp op) {
return withLoc(pos, irBuilder.makeSIMDTernary(op));
}
Result<> makeSIMDShift(Index pos,
const std::vector<Annotation>& annotations,
SIMDShiftOp op) {
return withLoc(pos, irBuilder.makeSIMDShift(op));
}
Result<> makeSIMDLoad(Index pos,
const std::vector<Annotation>& annotations,
SIMDLoadOp op,
Name* mem,
Memarg memarg) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos,
irBuilder.makeSIMDLoad(op, memarg.offset, memarg.align, *m));
}
Result<> makeSIMDLoadStoreLane(Index pos,
const std::vector<Annotation>& annotations,
SIMDLoadStoreLaneOp op,
Name* mem,
Memarg memarg,
uint8_t lane) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos,
irBuilder.makeSIMDLoadStoreLane(
op, memarg.offset, memarg.align, lane, *m));
}
Result<> makeMemoryInit(Index pos,
const std::vector<Annotation>& annotations,
Name* mem,
Name data) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeMemoryInit(data, *m));
}
Result<> makeDataDrop(Index pos,
const std::vector<Annotation>& annotations,
Name data) {
return withLoc(pos, irBuilder.makeDataDrop(data));
}
Result<> makeMemoryCopy(Index pos,
const std::vector<Annotation>& annotations,
Name* destMem,
Name* srcMem) {
auto destMemory = getMemory(pos, destMem);
CHECK_ERR(destMemory);
auto srcMemory = getMemory(pos, srcMem);
CHECK_ERR(srcMemory);
return withLoc(pos, irBuilder.makeMemoryCopy(*destMemory, *srcMemory));
}
Result<> makeMemoryFill(Index pos,
const std::vector<Annotation>& annotations,
Name* mem) {
auto m = getMemory(pos, mem);
CHECK_ERR(m);
return withLoc(pos, irBuilder.makeMemoryFill(*m));
}
Result<>
makePop(Index pos, const std::vector<Annotation>& annotations, Type type) {
return withLoc(pos, irBuilder.makePop(type));
}
Result<> makeCall(Index pos,
const std::vector<Annotation>& annotations,
Name func,
bool isReturn) {
return withLoc(pos, irBuilder.makeCall(func, isReturn));
}
Result<> makeCallIndirect(Index pos,
const std::vector<Annotation>& annotations,
Name* table,
HeapType type,
bool isReturn) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeCallIndirect(*t, type, isReturn));
}
Result<> makeBreak(Index pos,
const std::vector<Annotation>& annotations,
Index label,
bool isConditional) {
return withLoc(pos, irBuilder.makeBreak(label, isConditional));
}
Result<> makeSwitch(Index pos,
const std::vector<Annotation>& annotations,
const std::vector<Index> labels,
Index defaultLabel) {
return withLoc(pos, irBuilder.makeSwitch(labels, defaultLabel));
}
Result<> makeReturn(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeReturn());
}
Result<> makeRefNull(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeRefNull(type));
}
Result<> makeRefIsNull(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeRefIsNull());
}
Result<> makeRefFunc(Index pos,
const std::vector<Annotation>& annotations,
Name func) {
return withLoc(pos, irBuilder.makeRefFunc(func));
}
Result<> makeRefEq(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeRefEq());
}
Result<> makeTableGet(Index pos,
const std::vector<Annotation>& annotations,
Name* table) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableGet(*t));
}
Result<> makeTableSet(Index pos,
const std::vector<Annotation>& annotations,
Name* table) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableSet(*t));
}
Result<> makeTableSize(Index pos,
const std::vector<Annotation>& annotations,
Name* table) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableSize(*t));
}
Result<> makeTableGrow(Index pos,
const std::vector<Annotation>& annotations,
Name* table) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableGrow(*t));
}
Result<> makeTableFill(Index pos,
const std::vector<Annotation>& annotations,
Name* table) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableFill(*t));
}
Result<> makeTableCopy(Index pos,
const std::vector<Annotation>& annotations,
Name* destTable,
Name* srcTable) {
auto dest = getTable(pos, destTable);
CHECK_ERR(dest);
auto src = getTable(pos, srcTable);
CHECK_ERR(src);
return withLoc(pos, irBuilder.makeTableCopy(*dest, *src));
}
Result<> makeTableInit(Index pos,
const std::vector<Annotation>& annotations,
Name* table,
Name elem) {
auto t = getTable(pos, table);
CHECK_ERR(t);
return withLoc(pos, irBuilder.makeTableInit(elem, *t));
}
Result<>
makeThrow(Index pos, const std::vector<Annotation>& annotations, Name tag) {
return withLoc(pos, irBuilder.makeThrow(tag));
}
Result<> makeRethrow(Index pos,
const std::vector<Annotation>& annotations,
Index label) {
return withLoc(pos, irBuilder.makeRethrow(label));
}
Result<> makeThrowRef(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeThrowRef());
}
Result<> makeTupleMake(Index pos,
const std::vector<Annotation>& annotations,
uint32_t arity) {
return withLoc(pos, irBuilder.makeTupleMake(arity));
}
Result<> makeTupleExtract(Index pos,
const std::vector<Annotation>& annotations,
uint32_t arity,
uint32_t index) {
return withLoc(pos, irBuilder.makeTupleExtract(arity, index));
}
Result<> makeTupleDrop(Index pos,
const std::vector<Annotation>& annotations,
uint32_t arity) {
return withLoc(pos, irBuilder.makeTupleDrop(arity));
}
Result<> makeCallRef(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
bool isReturn) {
return withLoc(pos, irBuilder.makeCallRef(type, isReturn));
}
Result<> makeRefI31(Index pos,
const std::vector<Annotation>& annotations,
Shareability share) {
return withLoc(pos, irBuilder.makeRefI31(share));
}
Result<> makeI31Get(Index pos,
const std::vector<Annotation>& annotations,
bool signed_) {
return withLoc(pos, irBuilder.makeI31Get(signed_));
}
Result<> makeRefTest(Index pos,
const std::vector<Annotation>& annotations,
Type type) {
return withLoc(pos, irBuilder.makeRefTest(type));
}
Result<> makeRefCast(Index pos,
const std::vector<Annotation>& annotations,
Type type) {
return withLoc(pos, irBuilder.makeRefCast(type));
}
Result<> makeBrOn(Index pos,
const std::vector<Annotation>& annotations,
Index label,
BrOnOp op,
Type in = Type::none,
Type out = Type::none) {
return withLoc(pos, irBuilder.makeBrOn(label, op, in, out));
}
Result<> makeStructNew(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeStructNew(type));
}
Result<> makeStructNewDefault(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeStructNewDefault(type));
}
Result<> makeStructGet(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Index field,
bool signed_) {
return withLoc(pos, irBuilder.makeStructGet(type, field, signed_));
}
Result<> makeStructSet(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Index field) {
return withLoc(pos, irBuilder.makeStructSet(type, field));
}
Result<> makeArrayNew(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeArrayNew(type));
}
Result<> makeArrayNewDefault(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeArrayNewDefault(type));
}
Result<> makeArrayNewData(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Name data) {
return withLoc(pos, irBuilder.makeArrayNewData(type, data));
}
Result<> makeArrayNewElem(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Name elem) {
return withLoc(pos, irBuilder.makeArrayNewElem(type, elem));
}
Result<> makeArrayNewFixed(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
uint32_t arity) {
return withLoc(pos, irBuilder.makeArrayNewFixed(type, arity));
}
Result<> makeArrayGet(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
bool signed_) {
return withLoc(pos, irBuilder.makeArrayGet(type, signed_));
}
Result<> makeArraySet(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeArraySet(type));
}
Result<> makeArrayLen(Index pos, const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeArrayLen());
}
Result<> makeArrayCopy(Index pos,
const std::vector<Annotation>& annotations,
HeapType destType,
HeapType srcType) {
return withLoc(pos, irBuilder.makeArrayCopy(destType, srcType));
}
Result<> makeArrayFill(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeArrayFill(type));
}
Result<> makeArrayInitData(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Name data) {
return withLoc(pos, irBuilder.makeArrayInitData(type, data));
}
Result<> makeArrayInitElem(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
Name elem) {
return withLoc(pos, irBuilder.makeArrayInitElem(type, elem));
}
Result<>
makeRefAs(Index pos, const std::vector<Annotation>& annotations, RefAsOp op) {
return withLoc(pos, irBuilder.makeRefAs(op));
}
Result<> makeStringNew(Index pos,
const std::vector<Annotation>& annotations,
StringNewOp op) {
return withLoc(pos, irBuilder.makeStringNew(op));
}
Result<> makeStringConst(Index pos,
const std::vector<Annotation>& annotations,
std::string_view str) {
// Re-encode from WTF-8 to WTF-16.
std::stringstream wtf16;
if (!String::convertWTF8ToWTF16(wtf16, str)) {
return in.err(pos, "invalid string constant");
}
// TODO: Use wtf16.view() once we have C++20.
return withLoc(pos, irBuilder.makeStringConst(wtf16.str()));
}
Result<> makeStringMeasure(Index pos,
const std::vector<Annotation>& annotations,
StringMeasureOp op) {
return withLoc(pos, irBuilder.makeStringMeasure(op));
}
Result<> makeStringEncode(Index pos,
const std::vector<Annotation>& annotations,
StringEncodeOp op) {
return withLoc(pos, irBuilder.makeStringEncode(op));
}
Result<> makeStringConcat(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeStringConcat());
}
Result<> makeStringEq(Index pos,
const std::vector<Annotation>& annotations,
StringEqOp op) {
return withLoc(pos, irBuilder.makeStringEq(op));
}
Result<> makeStringWTF16Get(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeStringWTF16Get());
}
Result<> makeStringSliceWTF(Index pos,
const std::vector<Annotation>& annotations) {
return withLoc(pos, irBuilder.makeStringSliceWTF());
}
Result<> makeContBind(Index pos,
const std::vector<Annotation>& annotations,
HeapType contTypeBefore,
HeapType contTypeAfter) {
return withLoc(pos, irBuilder.makeContBind(contTypeBefore, contTypeAfter));
}
Result<> makeContNew(Index pos,
const std::vector<Annotation>& annotations,
HeapType type) {
return withLoc(pos, irBuilder.makeContNew(type));
}
Result<> makeResume(Index pos,
const std::vector<Annotation>& annotations,
HeapType type,
const TagLabelListT& tagLabels) {
std::vector<Name> tags;
std::vector<Index> labels;
tags.reserve(tagLabels.size());
labels.reserve(tagLabels.size());
for (auto& [tag, label] : tagLabels) {
tags.push_back(tag);
labels.push_back(label);
}
return withLoc(pos, irBuilder.makeResume(type, tags, labels));
}
Result<>
makeSuspend(Index pos, const std::vector<Annotation>& annotations, Name tag) {
return withLoc(pos, irBuilder.makeSuspend(tag));
}
};
} // namespace wasm::WATParser
#endif // parser_context_h