Source code

Revision control

Copy as Markdown

Other Tools

/*
* Copyright 2016 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
*
*
* 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 WABT_IR_H_
#define WABT_IR_H_
#include <cassert>
#include <cstddef>
#include <cstdint>
#include <memory>
#include <string>
#include <string_view>
#include <type_traits>
#include <vector>
#include "wabt/binding-hash.h"
#include "wabt/common.h"
#include "wabt/intrusive-list.h"
#include "wabt/opcode.h"
namespace wabt {
struct Module;
enum class VarType {
Index,
Name,
};
struct Var {
explicit Var();
explicit Var(Index index, const Location& loc);
explicit Var(std::string_view name, const Location& loc);
Var(Var&&);
Var(const Var&);
Var& operator=(const Var&);
Var& operator=(Var&&);
~Var();
VarType type() const { return type_; }
bool is_index() const { return type_ == VarType::Index; }
bool is_name() const { return type_ == VarType::Name; }
Index index() const {
assert(is_index());
return index_;
}
const std::string& name() const {
assert(is_name());
return name_;
}
void set_index(Index);
void set_name(std::string&&);
void set_name(std::string_view);
Location loc;
private:
void Destroy();
VarType type_;
union {
Index index_;
std::string name_;
};
};
using VarVector = std::vector<Var>;
struct Const {
static constexpr uintptr_t kRefNullBits = ~uintptr_t(0);
Const() : Const(Type::I32, uint32_t(0)) {}
static Const I32(uint32_t val = 0, const Location& loc = Location()) {
return Const(Type::I32, val, loc);
}
static Const I64(uint64_t val = 0, const Location& loc = Location()) {
return Const(Type::I64, val, loc);
}
static Const F32(uint32_t val = 0, const Location& loc = Location()) {
return Const(Type::F32, val, loc);
}
static Const F64(uint64_t val = 0, const Location& loc = Location()) {
return Const(Type::F64, val, loc);
}
static Const V128(v128 val, const Location& loc = Location()) {
return Const(Type::V128, val, loc);
}
Type type() const { return type_; }
Type lane_type() const {
assert(type_ == Type::V128);
return lane_type_;
}
int lane_count() const {
switch (lane_type()) {
case Type::I8: return 16;
case Type::I16: return 8;
case Type::I32: return 4;
case Type::I64: return 2;
case Type::F32: return 4;
case Type::F64: return 2;
default: WABT_UNREACHABLE;
}
}
uint32_t u32() const { return data_.u32(0); }
uint64_t u64() const { return data_.u64(0); }
uint32_t f32_bits() const { return data_.f32_bits(0); }
uint64_t f64_bits() const { return data_.f64_bits(0); }
uintptr_t ref_bits() const { return data_.To<uintptr_t>(0); }
v128 vec128() const { return data_; }
template <typename T>
T v128_lane(int lane) const {
return data_.To<T>(lane);
}
void set_u32(uint32_t x) { From(Type::I32, x); }
void set_u64(uint64_t x) { From(Type::I64, x); }
void set_f32(uint32_t x) { From(Type::F32, x); }
void set_f64(uint64_t x) { From(Type::F64, x); }
void set_v128_u8(int lane, uint8_t x) { set_v128_lane(lane, Type::I8, x); }
void set_v128_u16(int lane, uint16_t x) { set_v128_lane(lane, Type::I16, x); }
void set_v128_u32(int lane, uint32_t x) { set_v128_lane(lane, Type::I32, x); }
void set_v128_u64(int lane, uint64_t x) { set_v128_lane(lane, Type::I64, x); }
void set_v128_f32(int lane, uint32_t x) { set_v128_lane(lane, Type::F32, x); }
void set_v128_f64(int lane, uint64_t x) { set_v128_lane(lane, Type::F64, x); }
// Only used for expectations. (e.g. wast assertions)
void set_f32(ExpectedNan nan) {
set_f32(0);
set_expected_nan(0, nan);
}
void set_f64(ExpectedNan nan) {
set_f64(0);
set_expected_nan(0, nan);
}
void set_funcref() { From<uintptr_t>(Type::FuncRef, 0); }
void set_externref(uintptr_t x) { From(Type::ExternRef, x); }
void set_null(Type type) { From<uintptr_t>(type, kRefNullBits); }
bool is_expected_nan(int lane = 0) const {
return expected_nan(lane) != ExpectedNan::None;
}
ExpectedNan expected_nan(int lane = 0) const {
return lane < 4 ? nan_[lane] : ExpectedNan::None;
}
void set_expected_nan(int lane, ExpectedNan nan) {
if (lane < 4) {
nan_[lane] = nan;
}
}
// v128 support
Location loc;
private:
template <typename T>
void set_v128_lane(int lane, Type lane_type, T x) {
lane_type_ = lane_type;
From(Type::V128, x, lane);
set_expected_nan(lane, ExpectedNan::None);
}
template <typename T>
Const(Type type, T data, const Location& loc = Location()) : loc(loc) {
From<T>(type, data);
}
template <typename T>
void From(Type type, T data, int lane = 0) {
static_assert(sizeof(T) <= sizeof(data_), "Invalid cast!");
assert((lane + 1) * sizeof(T) <= sizeof(data_));
type_ = type;
data_.From<T>(lane, data);
set_expected_nan(lane, ExpectedNan::None);
}
Type type_;
Type lane_type_; // Only valid if type_ == Type::V128.
v128 data_;
ExpectedNan nan_[4];
};
using ConstVector = std::vector<Const>;
enum class ExpectationType {
Values,
Either,
};
class Expectation {
public:
Expectation() = delete;
virtual ~Expectation() = default;
ExpectationType type() const { return type_; }
Location loc;
ConstVector expected;
protected:
explicit Expectation(ExpectationType type, const Location& loc = Location())
: loc(loc), type_(type) {}
private:
ExpectationType type_;
};
template <ExpectationType TypeEnum>
class ExpectationMixin : public Expectation {
public:
static bool classof(const Expectation* expectation) {
return expectation->type() == TypeEnum;
}
explicit ExpectationMixin(const Location& loc = Location())
: Expectation(TypeEnum, loc) {}
};
class ValueExpectation : public ExpectationMixin<ExpectationType::Values> {
public:
explicit ValueExpectation(const Location& loc = Location())
: ExpectationMixin<ExpectationType::Values>(loc) {}
};
struct EitherExpectation : public ExpectationMixin<ExpectationType::Either> {
public:
explicit EitherExpectation(const Location& loc = Location())
: ExpectationMixin<ExpectationType::Either>(loc) {}
};
typedef std::unique_ptr<Expectation> ExpectationPtr;
struct FuncSignature {
TypeVector param_types;
TypeVector result_types;
// Some types can have names, for example (ref $foo) has type $foo.
// So to use this type we need to translate its name into
// a proper index from the module type section.
// This is the mapping from parameter/result index to its name.
std::unordered_map<uint32_t, std::string> param_type_names;
std::unordered_map<uint32_t, std::string> result_type_names;
Index GetNumParams() const { return param_types.size(); }
Index GetNumResults() const { return result_types.size(); }
Type GetParamType(Index index) const { return param_types[index]; }
Type GetResultType(Index index) const { return result_types[index]; }
bool operator==(const FuncSignature&) const;
};
enum class TypeEntryKind {
Func,
Struct,
Array,
};
class TypeEntry {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(TypeEntry);
virtual ~TypeEntry() = default;
TypeEntryKind kind() const { return kind_; }
Location loc;
std::string name;
protected:
explicit TypeEntry(TypeEntryKind kind,
std::string_view name = std::string_view(),
const Location& loc = Location())
: loc(loc), name(name), kind_(kind) {}
TypeEntryKind kind_;
};
class FuncType : public TypeEntry {
public:
static bool classof(const TypeEntry* entry) {
return entry->kind() == TypeEntryKind::Func;
}
explicit FuncType(std::string_view name = std::string_view())
: TypeEntry(TypeEntryKind::Func, name) {}
Index GetNumParams() const { return sig.GetNumParams(); }
Index GetNumResults() const { return sig.GetNumResults(); }
Type GetParamType(Index index) const { return sig.GetParamType(index); }
Type GetResultType(Index index) const { return sig.GetResultType(index); }
FuncSignature sig;
};
struct Field {
std::string name;
Type type = Type::Void;
bool mutable_ = false;
};
class StructType : public TypeEntry {
public:
static bool classof(const TypeEntry* entry) {
return entry->kind() == TypeEntryKind::Struct;
}
explicit StructType(std::string_view name = std::string_view())
: TypeEntry(TypeEntryKind::Struct) {}
std::vector<Field> fields;
};
class ArrayType : public TypeEntry {
public:
static bool classof(const TypeEntry* entry) {
return entry->kind() == TypeEntryKind::Array;
}
explicit ArrayType(std::string_view name = std::string_view())
: TypeEntry(TypeEntryKind::Array) {}
Field field;
};
struct FuncDeclaration {
Index GetNumParams() const { return sig.GetNumParams(); }
Index GetNumResults() const { return sig.GetNumResults(); }
Type GetParamType(Index index) const { return sig.GetParamType(index); }
Type GetResultType(Index index) const { return sig.GetResultType(index); }
bool has_func_type = false;
Var type_var;
FuncSignature sig;
};
enum class ExprType {
AtomicLoad,
AtomicRmw,
AtomicRmwCmpxchg,
AtomicStore,
AtomicNotify,
AtomicFence,
AtomicWait,
Binary,
Block,
Br,
BrIf,
BrTable,
Call,
CallIndirect,
CallRef,
CodeMetadata,
Compare,
Const,
Convert,
Drop,
GlobalGet,
GlobalSet,
If,
Load,
LocalGet,
LocalSet,
LocalTee,
Loop,
MemoryCopy,
DataDrop,
MemoryFill,
MemoryGrow,
MemoryInit,
MemorySize,
Nop,
RefIsNull,
RefFunc,
RefNull,
Rethrow,
Return,
ReturnCall,
ReturnCallIndirect,
Select,
SimdLaneOp,
SimdLoadLane,
SimdStoreLane,
SimdShuffleOp,
LoadSplat,
LoadZero,
Store,
TableCopy,
ElemDrop,
TableInit,
TableGet,
TableGrow,
TableSize,
TableSet,
TableFill,
Ternary,
Throw,
Try,
Unary,
Unreachable,
First = AtomicLoad,
Last = Unreachable
};
const char* GetExprTypeName(ExprType type);
class Expr;
using ExprList = intrusive_list<Expr>;
using BlockDeclaration = FuncDeclaration;
struct Block {
Block() = default;
explicit Block(ExprList exprs) : exprs(std::move(exprs)) {}
std::string label;
BlockDeclaration decl;
ExprList exprs;
Location end_loc;
};
struct Catch {
explicit Catch(const Location& loc = Location()) : loc(loc) {}
explicit Catch(const Var& var, const Location& loc = Location())
: loc(loc), var(var) {}
Location loc;
Var var;
ExprList exprs;
bool IsCatchAll() const {
return var.is_index() && var.index() == kInvalidIndex;
}
};
using CatchVector = std::vector<Catch>;
enum class TryKind { Plain, Catch, Delegate };
class Expr : public intrusive_list_base<Expr> {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(Expr);
Expr() = delete;
virtual ~Expr() = default;
ExprType type() const { return type_; }
Location loc;
protected:
explicit Expr(ExprType type, const Location& loc = Location())
: loc(loc), type_(type) {}
ExprType type_;
};
const char* GetExprTypeName(const Expr& expr);
template <ExprType TypeEnum>
class ExprMixin : public Expr {
public:
static bool classof(const Expr* expr) { return expr->type() == TypeEnum; }
explicit ExprMixin(const Location& loc = Location()) : Expr(TypeEnum, loc) {}
};
template <ExprType TypeEnum>
class MemoryExpr : public ExprMixin<TypeEnum> {
public:
MemoryExpr(Var memidx, const Location& loc = Location())
: ExprMixin<TypeEnum>(loc), memidx(memidx) {}
Var memidx;
};
template <ExprType TypeEnum>
class MemoryBinaryExpr : public ExprMixin<TypeEnum> {
public:
MemoryBinaryExpr(Var srcmemidx,
Var destmemidx,
const Location& loc = Location())
: ExprMixin<TypeEnum>(loc),
srcmemidx(srcmemidx),
destmemidx(destmemidx) {}
Var srcmemidx;
Var destmemidx;
};
using DropExpr = ExprMixin<ExprType::Drop>;
using NopExpr = ExprMixin<ExprType::Nop>;
using ReturnExpr = ExprMixin<ExprType::Return>;
using UnreachableExpr = ExprMixin<ExprType::Unreachable>;
using MemoryGrowExpr = MemoryExpr<ExprType::MemoryGrow>;
using MemorySizeExpr = MemoryExpr<ExprType::MemorySize>;
using MemoryFillExpr = MemoryExpr<ExprType::MemoryFill>;
using MemoryCopyExpr = MemoryBinaryExpr<ExprType::MemoryCopy>;
template <ExprType TypeEnum>
class RefTypeExpr : public ExprMixin<TypeEnum> {
public:
RefTypeExpr(Type type, const Location& loc = Location())
: ExprMixin<TypeEnum>(loc), type(type) {}
Type type;
};
using RefNullExpr = RefTypeExpr<ExprType::RefNull>;
using RefIsNullExpr = ExprMixin<ExprType::RefIsNull>;
template <ExprType TypeEnum>
class OpcodeExpr : public ExprMixin<TypeEnum> {
public:
OpcodeExpr(Opcode opcode, const Location& loc = Location())
: ExprMixin<TypeEnum>(loc), opcode(opcode) {}
Opcode opcode;
};
using BinaryExpr = OpcodeExpr<ExprType::Binary>;
using CompareExpr = OpcodeExpr<ExprType::Compare>;
using ConvertExpr = OpcodeExpr<ExprType::Convert>;
using UnaryExpr = OpcodeExpr<ExprType::Unary>;
using TernaryExpr = OpcodeExpr<ExprType::Ternary>;
class SimdLaneOpExpr : public ExprMixin<ExprType::SimdLaneOp> {
public:
SimdLaneOpExpr(Opcode opcode, uint64_t val, const Location& loc = Location())
: ExprMixin<ExprType::SimdLaneOp>(loc), opcode(opcode), val(val) {}
Opcode opcode;
uint64_t val;
};
class SimdLoadLaneExpr : public MemoryExpr<ExprType::SimdLoadLane> {
public:
SimdLoadLaneExpr(Opcode opcode,
Var memidx,
Address align,
Address offset,
uint64_t val,
const Location& loc = Location())
: MemoryExpr<ExprType::SimdLoadLane>(memidx, loc),
opcode(opcode),
align(align),
offset(offset),
val(val) {}
Opcode opcode;
Address align;
Address offset;
uint64_t val;
};
class SimdStoreLaneExpr : public MemoryExpr<ExprType::SimdStoreLane> {
public:
SimdStoreLaneExpr(Opcode opcode,
Var memidx,
Address align,
Address offset,
uint64_t val,
const Location& loc = Location())
: MemoryExpr<ExprType::SimdStoreLane>(memidx, loc),
opcode(opcode),
align(align),
offset(offset),
val(val) {}
Opcode opcode;
Address align;
Address offset;
uint64_t val;
};
class SimdShuffleOpExpr : public ExprMixin<ExprType::SimdShuffleOp> {
public:
SimdShuffleOpExpr(Opcode opcode, v128 val, const Location& loc = Location())
: ExprMixin<ExprType::SimdShuffleOp>(loc), opcode(opcode), val(val) {}
Opcode opcode;
v128 val;
};
template <ExprType TypeEnum>
class VarExpr : public ExprMixin<TypeEnum> {
public:
VarExpr(const Var& var, const Location& loc = Location())
: ExprMixin<TypeEnum>(loc), var(var) {}
Var var;
};
template <ExprType TypeEnum>
class MemoryVarExpr : public MemoryExpr<TypeEnum> {
public:
MemoryVarExpr(const Var& var, Var memidx, const Location& loc = Location())
: MemoryExpr<TypeEnum>(memidx, loc), var(var) {}
Var var;
};
using BrExpr = VarExpr<ExprType::Br>;
using BrIfExpr = VarExpr<ExprType::BrIf>;
using CallExpr = VarExpr<ExprType::Call>;
using RefFuncExpr = VarExpr<ExprType::RefFunc>;
using GlobalGetExpr = VarExpr<ExprType::GlobalGet>;
using GlobalSetExpr = VarExpr<ExprType::GlobalSet>;
using LocalGetExpr = VarExpr<ExprType::LocalGet>;
using LocalSetExpr = VarExpr<ExprType::LocalSet>;
using LocalTeeExpr = VarExpr<ExprType::LocalTee>;
using ReturnCallExpr = VarExpr<ExprType::ReturnCall>;
using ThrowExpr = VarExpr<ExprType::Throw>;
using RethrowExpr = VarExpr<ExprType::Rethrow>;
using DataDropExpr = VarExpr<ExprType::DataDrop>;
using ElemDropExpr = VarExpr<ExprType::ElemDrop>;
using TableGetExpr = VarExpr<ExprType::TableGet>;
using TableSetExpr = VarExpr<ExprType::TableSet>;
using TableGrowExpr = VarExpr<ExprType::TableGrow>;
using TableSizeExpr = VarExpr<ExprType::TableSize>;
using TableFillExpr = VarExpr<ExprType::TableFill>;
using MemoryInitExpr = MemoryVarExpr<ExprType::MemoryInit>;
class SelectExpr : public ExprMixin<ExprType::Select> {
public:
SelectExpr(TypeVector type, const Location& loc = Location())
: ExprMixin<ExprType::Select>(loc), result_type(type) {}
TypeVector result_type;
};
class TableInitExpr : public ExprMixin<ExprType::TableInit> {
public:
TableInitExpr(const Var& segment_index,
const Var& table_index,
const Location& loc = Location())
: ExprMixin<ExprType::TableInit>(loc),
segment_index(segment_index),
table_index(table_index) {}
Var segment_index;
Var table_index;
};
class TableCopyExpr : public ExprMixin<ExprType::TableCopy> {
public:
TableCopyExpr(const Var& dst,
const Var& src,
const Location& loc = Location())
: ExprMixin<ExprType::TableCopy>(loc), dst_table(dst), src_table(src) {}
Var dst_table;
Var src_table;
};
class CallIndirectExpr : public ExprMixin<ExprType::CallIndirect> {
public:
explicit CallIndirectExpr(const Location& loc = Location())
: ExprMixin<ExprType::CallIndirect>(loc) {}
FuncDeclaration decl;
Var table;
};
class CodeMetadataExpr : public ExprMixin<ExprType::CodeMetadata> {
public:
explicit CodeMetadataExpr(std::string_view name,
std::vector<uint8_t> data,
const Location& loc = Location())
: ExprMixin<ExprType::CodeMetadata>(loc),
name(std::move(name)),
data(std::move(data)) {}
std::string_view name;
std::vector<uint8_t> data;
};
class ReturnCallIndirectExpr : public ExprMixin<ExprType::ReturnCallIndirect> {
public:
explicit ReturnCallIndirectExpr(const Location& loc = Location())
: ExprMixin<ExprType::ReturnCallIndirect>(loc) {}
FuncDeclaration decl;
Var table;
};
class CallRefExpr : public ExprMixin<ExprType::CallRef> {
public:
explicit CallRefExpr(const Location& loc = Location())
: ExprMixin<ExprType::CallRef>(loc) {}
// This field is setup only during Validate phase,
// so keep that in mind when you use it.
Var function_type_index;
};
template <ExprType TypeEnum>
class BlockExprBase : public ExprMixin<TypeEnum> {
public:
explicit BlockExprBase(const Location& loc = Location())
: ExprMixin<TypeEnum>(loc) {}
Block block;
};
using BlockExpr = BlockExprBase<ExprType::Block>;
using LoopExpr = BlockExprBase<ExprType::Loop>;
class IfExpr : public ExprMixin<ExprType::If> {
public:
explicit IfExpr(const Location& loc = Location())
: ExprMixin<ExprType::If>(loc) {}
Block true_;
ExprList false_;
Location false_end_loc;
};
class TryExpr : public ExprMixin<ExprType::Try> {
public:
explicit TryExpr(const Location& loc = Location())
: ExprMixin<ExprType::Try>(loc), kind(TryKind::Plain) {}
TryKind kind;
Block block;
CatchVector catches;
Var delegate_target;
};
class BrTableExpr : public ExprMixin<ExprType::BrTable> {
public:
BrTableExpr(const Location& loc = Location())
: ExprMixin<ExprType::BrTable>(loc) {}
VarVector targets;
Var default_target;
};
class ConstExpr : public ExprMixin<ExprType::Const> {
public:
ConstExpr(const Const& c, const Location& loc = Location())
: ExprMixin<ExprType::Const>(loc), const_(c) {}
Const const_;
};
// TODO(binji): Rename this, it is used for more than loads/stores now.
template <ExprType TypeEnum>
class LoadStoreExpr : public MemoryExpr<TypeEnum> {
public:
LoadStoreExpr(Opcode opcode,
Var memidx,
Address align,
Address offset,
const Location& loc = Location())
: MemoryExpr<TypeEnum>(memidx, loc),
opcode(opcode),
align(align),
offset(offset) {}
Opcode opcode;
Address align;
Address offset;
};
using LoadExpr = LoadStoreExpr<ExprType::Load>;
using StoreExpr = LoadStoreExpr<ExprType::Store>;
using AtomicLoadExpr = LoadStoreExpr<ExprType::AtomicLoad>;
using AtomicStoreExpr = LoadStoreExpr<ExprType::AtomicStore>;
using AtomicRmwExpr = LoadStoreExpr<ExprType::AtomicRmw>;
using AtomicRmwCmpxchgExpr = LoadStoreExpr<ExprType::AtomicRmwCmpxchg>;
using AtomicWaitExpr = LoadStoreExpr<ExprType::AtomicWait>;
using AtomicNotifyExpr = LoadStoreExpr<ExprType::AtomicNotify>;
using LoadSplatExpr = LoadStoreExpr<ExprType::LoadSplat>;
using LoadZeroExpr = LoadStoreExpr<ExprType::LoadZero>;
class AtomicFenceExpr : public ExprMixin<ExprType::AtomicFence> {
public:
explicit AtomicFenceExpr(uint32_t consistency_model,
const Location& loc = Location())
: ExprMixin<ExprType::AtomicFence>(loc),
consistency_model(consistency_model) {}
uint32_t consistency_model;
};
struct Tag {
explicit Tag(std::string_view name) : name(name) {}
std::string name;
FuncDeclaration decl;
};
class LocalTypes {
public:
using Decl = std::pair<Type, Index>;
using Decls = std::vector<Decl>;
struct const_iterator {
const_iterator(Decls::const_iterator decl, Index index)
: decl(decl), index(index) {}
Type operator*() const { return decl->first; }
const_iterator& operator++();
const_iterator operator++(int);
Decls::const_iterator decl;
Index index;
};
void Set(const TypeVector&);
const Decls& decls() const { return decls_; }
void AppendDecl(Type type, Index count) {
if (count != 0) {
decls_.emplace_back(type, count);
}
}
Index size() const;
Type operator[](Index) const;
const_iterator begin() const { return {decls_.begin(), 0}; }
const_iterator end() const { return {decls_.end(), 0}; }
private:
Decls decls_;
};
inline LocalTypes::const_iterator& LocalTypes::const_iterator::operator++() {
++index;
if (index >= decl->second) {
++decl;
index = 0;
}
return *this;
}
inline LocalTypes::const_iterator LocalTypes::const_iterator::operator++(int) {
const_iterator result = *this;
operator++();
return result;
}
inline bool operator==(const LocalTypes::const_iterator& lhs,
const LocalTypes::const_iterator& rhs) {
return lhs.decl == rhs.decl && lhs.index == rhs.index;
}
inline bool operator!=(const LocalTypes::const_iterator& lhs,
const LocalTypes::const_iterator& rhs) {
return !operator==(lhs, rhs);
}
struct Func {
explicit Func(std::string_view name) : name(name) {}
Type GetParamType(Index index) const { return decl.GetParamType(index); }
Type GetResultType(Index index) const { return decl.GetResultType(index); }
Type GetLocalType(Index index) const;
Type GetLocalType(const Var& var) const;
Index GetNumParams() const { return decl.GetNumParams(); }
Index GetNumLocals() const { return local_types.size(); }
Index GetNumParamsAndLocals() const {
return GetNumParams() + GetNumLocals();
}
Index GetNumResults() const { return decl.GetNumResults(); }
Index GetLocalIndex(const Var&) const;
std::string name;
FuncDeclaration decl;
LocalTypes local_types;
BindingHash bindings;
ExprList exprs;
Location loc;
};
struct Global {
explicit Global(std::string_view name) : name(name) {}
std::string name;
Type type = Type::Void;
bool mutable_ = false;
ExprList init_expr;
};
struct Table {
explicit Table(std::string_view name)
: name(name), elem_type(Type::FuncRef) {}
std::string name;
Limits elem_limits;
Type elem_type;
};
using ExprListVector = std::vector<ExprList>;
struct ElemSegment {
explicit ElemSegment(std::string_view name) : name(name) {}
uint8_t GetFlags(const Module*) const;
SegmentKind kind = SegmentKind::Active;
std::string name;
Var table_var;
Type elem_type;
ExprList offset;
ExprListVector elem_exprs;
};
struct Memory {
explicit Memory(std::string_view name) : name(name) {}
std::string name;
Limits page_limits;
};
struct DataSegment {
explicit DataSegment(std::string_view name) : name(name) {}
uint8_t GetFlags(const Module*) const;
SegmentKind kind = SegmentKind::Active;
std::string name;
Var memory_var;
ExprList offset;
std::vector<uint8_t> data;
};
class Import {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(Import);
Import() = delete;
virtual ~Import() = default;
ExternalKind kind() const { return kind_; }
std::string module_name;
std::string field_name;
protected:
Import(ExternalKind kind) : kind_(kind) {}
ExternalKind kind_;
};
template <ExternalKind TypeEnum>
class ImportMixin : public Import {
public:
static bool classof(const Import* import) {
return import->kind() == TypeEnum;
}
ImportMixin() : Import(TypeEnum) {}
};
class FuncImport : public ImportMixin<ExternalKind::Func> {
public:
explicit FuncImport(std::string_view name = std::string_view())
: ImportMixin<ExternalKind::Func>(), func(name) {}
Func func;
};
class TableImport : public ImportMixin<ExternalKind::Table> {
public:
explicit TableImport(std::string_view name = std::string_view())
: ImportMixin<ExternalKind::Table>(), table(name) {}
Table table;
};
class MemoryImport : public ImportMixin<ExternalKind::Memory> {
public:
explicit MemoryImport(std::string_view name = std::string_view())
: ImportMixin<ExternalKind::Memory>(), memory(name) {}
Memory memory;
};
class GlobalImport : public ImportMixin<ExternalKind::Global> {
public:
explicit GlobalImport(std::string_view name = std::string_view())
: ImportMixin<ExternalKind::Global>(), global(name) {}
Global global;
};
class TagImport : public ImportMixin<ExternalKind::Tag> {
public:
explicit TagImport(std::string_view name = std::string_view())
: ImportMixin<ExternalKind::Tag>(), tag(name) {}
Tag tag;
};
struct Export {
std::string name;
ExternalKind kind;
Var var;
};
enum class ModuleFieldType {
Func,
Global,
Import,
Export,
Type,
Table,
ElemSegment,
Memory,
DataSegment,
Start,
Tag
};
class ModuleField : public intrusive_list_base<ModuleField> {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(ModuleField);
ModuleField() = delete;
virtual ~ModuleField() = default;
ModuleFieldType type() const { return type_; }
Location loc;
protected:
ModuleField(ModuleFieldType type, const Location& loc)
: loc(loc), type_(type) {}
ModuleFieldType type_;
};
using ModuleFieldList = intrusive_list<ModuleField>;
template <ModuleFieldType TypeEnum>
class ModuleFieldMixin : public ModuleField {
public:
static bool classof(const ModuleField* field) {
return field->type() == TypeEnum;
}
explicit ModuleFieldMixin(const Location& loc) : ModuleField(TypeEnum, loc) {}
};
class FuncModuleField : public ModuleFieldMixin<ModuleFieldType::Func> {
public:
explicit FuncModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::Func>(loc), func(name) {}
Func func;
};
class GlobalModuleField : public ModuleFieldMixin<ModuleFieldType::Global> {
public:
explicit GlobalModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::Global>(loc), global(name) {}
Global global;
};
class ImportModuleField : public ModuleFieldMixin<ModuleFieldType::Import> {
public:
explicit ImportModuleField(const Location& loc = Location())
: ModuleFieldMixin<ModuleFieldType::Import>(loc) {}
explicit ImportModuleField(std::unique_ptr<Import> import,
const Location& loc = Location())
: ModuleFieldMixin<ModuleFieldType::Import>(loc),
import(std::move(import)) {}
std::unique_ptr<Import> import;
};
class ExportModuleField : public ModuleFieldMixin<ModuleFieldType::Export> {
public:
explicit ExportModuleField(const Location& loc = Location())
: ModuleFieldMixin<ModuleFieldType::Export>(loc) {}
Export export_;
};
class TypeModuleField : public ModuleFieldMixin<ModuleFieldType::Type> {
public:
explicit TypeModuleField(const Location& loc = Location())
: ModuleFieldMixin<ModuleFieldType::Type>(loc) {}
std::unique_ptr<TypeEntry> type;
};
class TableModuleField : public ModuleFieldMixin<ModuleFieldType::Table> {
public:
explicit TableModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::Table>(loc), table(name) {}
Table table;
};
class ElemSegmentModuleField
: public ModuleFieldMixin<ModuleFieldType::ElemSegment> {
public:
explicit ElemSegmentModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::ElemSegment>(loc),
elem_segment(name) {}
ElemSegment elem_segment;
};
class MemoryModuleField : public ModuleFieldMixin<ModuleFieldType::Memory> {
public:
explicit MemoryModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::Memory>(loc), memory(name) {}
Memory memory;
};
class DataSegmentModuleField
: public ModuleFieldMixin<ModuleFieldType::DataSegment> {
public:
explicit DataSegmentModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::DataSegment>(loc),
data_segment(name) {}
DataSegment data_segment;
};
class TagModuleField : public ModuleFieldMixin<ModuleFieldType::Tag> {
public:
explicit TagModuleField(const Location& loc = Location(),
std::string_view name = std::string_view())
: ModuleFieldMixin<ModuleFieldType::Tag>(loc), tag(name) {}
Tag tag;
};
class StartModuleField : public ModuleFieldMixin<ModuleFieldType::Start> {
public:
explicit StartModuleField(Var start = Var(), const Location& loc = Location())
: ModuleFieldMixin<ModuleFieldType::Start>(loc), start(start) {}
Var start;
};
struct Module {
Index GetFuncTypeIndex(const Var&) const;
Index GetFuncTypeIndex(const FuncDeclaration&) const;
Index GetFuncTypeIndex(const FuncSignature&) const;
const FuncType* GetFuncType(const Var&) const;
FuncType* GetFuncType(const Var&);
Index GetFuncIndex(const Var&) const;
const Func* GetFunc(const Var&) const;
Func* GetFunc(const Var&);
Index GetTableIndex(const Var&) const;
const Table* GetTable(const Var&) const;
Table* GetTable(const Var&);
Index GetMemoryIndex(const Var&) const;
const Memory* GetMemory(const Var&) const;
Memory* GetMemory(const Var&);
Index GetGlobalIndex(const Var&) const;
const Global* GetGlobal(const Var&) const;
Global* GetGlobal(const Var&);
const Export* GetExport(std::string_view) const;
Tag* GetTag(const Var&) const;
Index GetTagIndex(const Var&) const;
const DataSegment* GetDataSegment(const Var&) const;
DataSegment* GetDataSegment(const Var&);
Index GetDataSegmentIndex(const Var&) const;
const ElemSegment* GetElemSegment(const Var&) const;
ElemSegment* GetElemSegment(const Var&);
Index GetElemSegmentIndex(const Var&) const;
bool IsImport(ExternalKind kind, const Var&) const;
bool IsImport(const Export& export_) const {
return IsImport(export_.kind, export_.var);
}
// TODO(binji): move this into a builder class?
void AppendField(std::unique_ptr<DataSegmentModuleField>);
void AppendField(std::unique_ptr<ElemSegmentModuleField>);
void AppendField(std::unique_ptr<TagModuleField>);
void AppendField(std::unique_ptr<ExportModuleField>);
void AppendField(std::unique_ptr<FuncModuleField>);
void AppendField(std::unique_ptr<TypeModuleField>);
void AppendField(std::unique_ptr<GlobalModuleField>);
void AppendField(std::unique_ptr<ImportModuleField>);
void AppendField(std::unique_ptr<MemoryModuleField>);
void AppendField(std::unique_ptr<StartModuleField>);
void AppendField(std::unique_ptr<TableModuleField>);
void AppendField(std::unique_ptr<ModuleField>);
void AppendFields(ModuleFieldList*);
Location loc;
std::string name;
ModuleFieldList fields;
Index num_tag_imports = 0;
Index num_func_imports = 0;
Index num_table_imports = 0;
Index num_memory_imports = 0;
Index num_global_imports = 0;
// Cached for convenience; the pointers are shared with values that are
// stored in either ModuleField or Import.
std::vector<Tag*> tags;
std::vector<Func*> funcs;
std::vector<Global*> globals;
std::vector<Import*> imports;
std::vector<Export*> exports;
std::vector<TypeEntry*> types;
std::vector<Table*> tables;
std::vector<ElemSegment*> elem_segments;
std::vector<Memory*> memories;
std::vector<DataSegment*> data_segments;
std::vector<Var*> starts;
BindingHash tag_bindings;
BindingHash func_bindings;
BindingHash global_bindings;
BindingHash export_bindings;
BindingHash type_bindings;
BindingHash table_bindings;
BindingHash memory_bindings;
BindingHash data_segment_bindings;
BindingHash elem_segment_bindings;
// For a subset of features, the BinaryReaderIR tracks whether they are
// actually used by the module. wasm2c (CWriter) uses this information to
// limit its output in some cases.
struct {
bool simd = false;
bool exceptions = false;
} features_used;
};
enum class ScriptModuleType {
Text,
Binary,
Quoted,
};
// A ScriptModule is a module that may not yet be decoded. This allows for text
// and binary parsing errors to be deferred until validation time.
class ScriptModule {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(ScriptModule);
ScriptModule() = delete;
virtual ~ScriptModule() = default;
ScriptModuleType type() const { return type_; }
virtual const Location& location() const = 0;
protected:
explicit ScriptModule(ScriptModuleType type) : type_(type) {}
ScriptModuleType type_;
};
template <ScriptModuleType TypeEnum>
class ScriptModuleMixin : public ScriptModule {
public:
static bool classof(const ScriptModule* script_module) {
return script_module->type() == TypeEnum;
}
ScriptModuleMixin() : ScriptModule(TypeEnum) {}
};
class TextScriptModule : public ScriptModuleMixin<ScriptModuleType::Text> {
public:
const Location& location() const override { return module.loc; }
Module module;
};
template <ScriptModuleType TypeEnum>
class DataScriptModule : public ScriptModuleMixin<TypeEnum> {
public:
const Location& location() const override { return loc; }
Location loc;
std::string name;
std::vector<uint8_t> data;
};
using BinaryScriptModule = DataScriptModule<ScriptModuleType::Binary>;
using QuotedScriptModule = DataScriptModule<ScriptModuleType::Quoted>;
enum class ActionType {
Invoke,
Get,
};
class Action {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(Action);
Action() = delete;
virtual ~Action() = default;
ActionType type() const { return type_; }
Location loc;
Var module_var;
std::string name;
protected:
explicit Action(ActionType type, const Location& loc = Location())
: loc(loc), type_(type) {}
ActionType type_;
};
using ActionPtr = std::unique_ptr<Action>;
template <ActionType TypeEnum>
class ActionMixin : public Action {
public:
static bool classof(const Action* action) {
return action->type() == TypeEnum;
}
explicit ActionMixin(const Location& loc = Location())
: Action(TypeEnum, loc) {}
};
class GetAction : public ActionMixin<ActionType::Get> {
public:
explicit GetAction(const Location& loc = Location())
: ActionMixin<ActionType::Get>(loc) {}
};
class InvokeAction : public ActionMixin<ActionType::Invoke> {
public:
explicit InvokeAction(const Location& loc = Location())
: ActionMixin<ActionType::Invoke>(loc) {}
ConstVector args;
};
enum class CommandType {
Module,
ScriptModule,
Action,
Register,
AssertMalformed,
AssertInvalid,
AssertUnlinkable,
AssertUninstantiable,
AssertReturn,
AssertTrap,
AssertExhaustion,
AssertException,
First = Module,
Last = AssertException,
};
constexpr int kCommandTypeCount = WABT_ENUM_COUNT(CommandType);
class Command {
public:
WABT_DISALLOW_COPY_AND_ASSIGN(Command);
Command() = delete;
virtual ~Command() = default;
CommandType type;
protected:
explicit Command(CommandType type) : type(type) {}
};
template <CommandType TypeEnum>
class CommandMixin : public Command {
public:
static bool classof(const Command* cmd) { return cmd->type == TypeEnum; }
CommandMixin() : Command(TypeEnum) {}
};
class ModuleCommand : public CommandMixin<CommandType::Module> {
public:
Module module;
};
class ScriptModuleCommand : public CommandMixin<CommandType::ScriptModule> {
public:
// Both the module and the script_module need to be stored since the module
// has the parsed information about the module, but the script_module has the
// original contents (binary or quoted).
Module module;
std::unique_ptr<ScriptModule> script_module;
};
template <CommandType TypeEnum>
class ActionCommandBase : public CommandMixin<TypeEnum> {
public:
ActionPtr action;
};
using ActionCommand = ActionCommandBase<CommandType::Action>;
class RegisterCommand : public CommandMixin<CommandType::Register> {
public:
RegisterCommand(std::string_view module_name, const Var& var)
: module_name(module_name), var(var) {}
std::string module_name;
Var var;
};
class AssertReturnCommand : public CommandMixin<CommandType::AssertReturn> {
public:
ActionPtr action;
ExpectationPtr expected;
};
template <CommandType TypeEnum>
class AssertTrapCommandBase : public CommandMixin<TypeEnum> {
public:
ActionPtr action;
std::string text;
};
using AssertTrapCommand = AssertTrapCommandBase<CommandType::AssertTrap>;
using AssertExhaustionCommand =
AssertTrapCommandBase<CommandType::AssertExhaustion>;
template <CommandType TypeEnum>
class AssertModuleCommand : public CommandMixin<TypeEnum> {
public:
std::unique_ptr<ScriptModule> module;
std::string text;
};
using AssertMalformedCommand =
AssertModuleCommand<CommandType::AssertMalformed>;
using AssertInvalidCommand = AssertModuleCommand<CommandType::AssertInvalid>;
using AssertUnlinkableCommand =
AssertModuleCommand<CommandType::AssertUnlinkable>;
using AssertUninstantiableCommand =
AssertModuleCommand<CommandType::AssertUninstantiable>;
class AssertExceptionCommand
: public CommandMixin<CommandType::AssertException> {
public:
ActionPtr action;
};
using CommandPtr = std::unique_ptr<Command>;
using CommandPtrVector = std::vector<CommandPtr>;
struct Script {
WABT_DISALLOW_COPY_AND_ASSIGN(Script);
Script() = default;
const Module* GetFirstModule() const;
Module* GetFirstModule();
const Module* GetModule(const Var&) const;
CommandPtrVector commands;
BindingHash module_bindings;
};
void MakeTypeBindingReverseMapping(
size_t num_types,
const BindingHash& bindings,
std::vector<std::string>* out_reverse_mapping);
} // namespace wabt
#endif /* WABT_IR_H_ */