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diff --git a/js/src/wasm/AsmJS.cpp b/js/src/wasm/AsmJS.cpp
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+/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
+ * vim: set ts=8 sts=2 et sw=2 tw=80:
+ *
+ * Copyright 2014 Mozilla Foundation
+ *
+ * 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.
+ */
+
+#include "wasm/AsmJS.h"
+
+#include "mozilla/Attributes.h"
+#include "mozilla/Compression.h"
+#include "mozilla/MathAlgorithms.h"
+#include "mozilla/Maybe.h"
+#include "mozilla/ScopeExit.h"
+#include "mozilla/Sprintf.h" // SprintfLiteral
+#include "mozilla/Utf8.h" // mozilla::Utf8Unit
+#include "mozilla/Variant.h"
+
+#include <algorithm>
+#include <new>
+
+#include "jsmath.h"
+
+#include "frontend/BytecodeCompiler.h" // CompileStandaloneFunction
+#include "frontend/FrontendContext.h" // js::FrontendContext
+#include "frontend/FunctionSyntaxKind.h" // FunctionSyntaxKind
+#include "frontend/ParseNode.h"
+#include "frontend/Parser.h"
+#include "frontend/ParserAtom.h" // ParserAtomsTable, TaggedParserAtomIndex
+#include "frontend/SharedContext.h" // TopLevelFunction
+#include "frontend/TaggedParserAtomIndexHasher.h" // TaggedParserAtomIndexHasher
+#include "gc/GC.h"
+#include "gc/Policy.h"
+#include "jit/InlinableNatives.h"
+#include "js/BuildId.h" // JS::BuildIdCharVector
+#include "js/experimental/JitInfo.h"
+#include "js/friend/ErrorMessages.h" // JSMSG_*
+#include "js/MemoryMetrics.h"
+#include "js/Printf.h"
+#include "js/ScalarType.h" // js::Scalar::Type
+#include "js/SourceText.h"
+#include "js/StableStringChars.h"
+#include "js/Wrapper.h"
+#include "util/DifferentialTesting.h"
+#include "util/StringBuffer.h"
+#include "util/Text.h"
+#include "vm/ErrorReporting.h"
+#include "vm/FunctionFlags.h" // js::FunctionFlags
+#include "vm/GeneratorAndAsyncKind.h" // js::GeneratorKind, js::FunctionAsyncKind
+#include "vm/Interpreter.h"
+#include "vm/SelfHosting.h"
+#include "vm/Time.h"
+#include "vm/TypedArrayObject.h"
+#include "vm/Warnings.h" // js::WarnNumberASCII
+#include "wasm/WasmCompile.h"
+#include "wasm/WasmGenerator.h"
+#include "wasm/WasmInstance.h"
+#include "wasm/WasmIonCompile.h"
+#include "wasm/WasmJS.h"
+#include "wasm/WasmSerialize.h"
+#include "wasm/WasmValidate.h"
+
+#include "frontend/SharedContext-inl.h"
+#include "vm/ArrayBufferObject-inl.h"
+#include "vm/JSObject-inl.h"
+#include "wasm/WasmInstance-inl.h"
+
+using namespace js;
+using namespace js::frontend;
+using namespace js::jit;
+using namespace js::wasm;
+
+using JS::AsmJSOption;
+using JS::AutoStableStringChars;
+using JS::GenericNaN;
+using JS::SourceOwnership;
+using JS::SourceText;
+using mozilla::Abs;
+using mozilla::AsVariant;
+using mozilla::CeilingLog2;
+using mozilla::HashGeneric;
+using mozilla::IsNegativeZero;
+using mozilla::IsPositiveZero;
+using mozilla::IsPowerOfTwo;
+using mozilla::Nothing;
+using mozilla::PodZero;
+using mozilla::PositiveInfinity;
+using mozilla::Some;
+using mozilla::Utf8Unit;
+using mozilla::Compression::LZ4;
+
+using FunctionVector = JS::GCVector<JSFunction*>;
+
+/*****************************************************************************/
+
+// A wasm module can either use no memory, a unshared memory (ArrayBuffer) or
+// shared memory (SharedArrayBuffer).
+
+enum class MemoryUsage { None = false, Unshared = 1, Shared = 2 };
+
+// The asm.js valid heap lengths are precisely the WASM valid heap lengths for
+// ARM greater or equal to MinHeapLength
+static const size_t MinHeapLength = PageSize;
+// An asm.js heap can in principle be up to INT32_MAX bytes but requirements
+// on the format restrict it further to the largest pseudo-ARM-immediate.
+// See IsValidAsmJSHeapLength().
+static const uint64_t MaxHeapLength = 0x7f000000;
+
+static uint64_t RoundUpToNextValidAsmJSHeapLength(uint64_t length) {
+ if (length <= MinHeapLength) {
+ return MinHeapLength;
+ }
+
+ return wasm::RoundUpToNextValidARMImmediate(length);
+}
+
+static uint64_t DivideRoundingUp(uint64_t a, uint64_t b) {
+ return (a + (b - 1)) / b;
+}
+
+/*****************************************************************************/
+// asm.js module object
+
+// The asm.js spec recognizes this set of builtin Math functions.
+enum AsmJSMathBuiltinFunction {
+ AsmJSMathBuiltin_sin,
+ AsmJSMathBuiltin_cos,
+ AsmJSMathBuiltin_tan,
+ AsmJSMathBuiltin_asin,
+ AsmJSMathBuiltin_acos,
+ AsmJSMathBuiltin_atan,
+ AsmJSMathBuiltin_ceil,
+ AsmJSMathBuiltin_floor,
+ AsmJSMathBuiltin_exp,
+ AsmJSMathBuiltin_log,
+ AsmJSMathBuiltin_pow,
+ AsmJSMathBuiltin_sqrt,
+ AsmJSMathBuiltin_abs,
+ AsmJSMathBuiltin_atan2,
+ AsmJSMathBuiltin_imul,
+ AsmJSMathBuiltin_fround,
+ AsmJSMathBuiltin_min,
+ AsmJSMathBuiltin_max,
+ AsmJSMathBuiltin_clz32
+};
+
+// LitValPOD is a restricted version of LitVal suitable for asm.js that is
+// always POD.
+
+struct LitValPOD {
+ PackedTypeCode valType_;
+ union U {
+ uint32_t u32_;
+ uint64_t u64_;
+ float f32_;
+ double f64_;
+ } u;
+
+ LitValPOD() = default;
+
+ explicit LitValPOD(uint32_t u32) : valType_(ValType(ValType::I32).packed()) {
+ u.u32_ = u32;
+ }
+ explicit LitValPOD(uint64_t u64) : valType_(ValType(ValType::I64).packed()) {
+ u.u64_ = u64;
+ }
+
+ explicit LitValPOD(float f32) : valType_(ValType(ValType::F32).packed()) {
+ u.f32_ = f32;
+ }
+ explicit LitValPOD(double f64) : valType_(ValType(ValType::F64).packed()) {
+ u.f64_ = f64;
+ }
+
+ LitVal asLitVal() const {
+ switch (valType_.typeCode()) {
+ case TypeCode::I32:
+ return LitVal(u.u32_);
+ case TypeCode::I64:
+ return LitVal(u.u64_);
+ case TypeCode::F32:
+ return LitVal(u.f32_);
+ case TypeCode::F64:
+ return LitVal(u.f64_);
+ default:
+ MOZ_CRASH("Can't happen");
+ }
+ }
+};
+
+static_assert(std::is_pod_v<LitValPOD>,
+ "must be POD to be simply serialized/deserialized");
+
+// An AsmJSGlobal represents a JS global variable in the asm.js module function.
+class AsmJSGlobal {
+ public:
+ enum Which {
+ Variable,
+ FFI,
+ ArrayView,
+ ArrayViewCtor,
+ MathBuiltinFunction,
+ Constant
+ };
+ enum VarInitKind { InitConstant, InitImport };
+ enum ConstantKind { GlobalConstant, MathConstant };
+
+ private:
+ struct CacheablePod {
+ Which which_;
+ union V {
+ struct {
+ VarInitKind initKind_;
+ union U {
+ PackedTypeCode importValType_;
+ LitValPOD val_;
+ } u;
+ } var;
+ uint32_t ffiIndex_;
+ Scalar::Type viewType_;
+ AsmJSMathBuiltinFunction mathBuiltinFunc_;
+ struct {
+ ConstantKind kind_;
+ double value_;
+ } constant;
+ } u;
+ } pod;
+ CacheableChars field_;
+
+ friend class ModuleValidatorShared;
+ template <typename Unit>
+ friend class ModuleValidator;
+
+ public:
+ AsmJSGlobal() = default;
+ AsmJSGlobal(Which which, UniqueChars field) {
+ mozilla::PodZero(&pod); // zero padding for Valgrind
+ pod.which_ = which;
+ field_ = std::move(field);
+ }
+ const char* field() const { return field_.get(); }
+ Which which() const { return pod.which_; }
+ VarInitKind varInitKind() const {
+ MOZ_ASSERT(pod.which_ == Variable);
+ return pod.u.var.initKind_;
+ }
+ LitValPOD varInitVal() const {
+ MOZ_ASSERT(pod.which_ == Variable);
+ MOZ_ASSERT(pod.u.var.initKind_ == InitConstant);
+ return pod.u.var.u.val_;
+ }
+ ValType varInitImportType() const {
+ MOZ_ASSERT(pod.which_ == Variable);
+ MOZ_ASSERT(pod.u.var.initKind_ == InitImport);
+ return ValType(pod.u.var.u.importValType_);
+ }
+ uint32_t ffiIndex() const {
+ MOZ_ASSERT(pod.which_ == FFI);
+ return pod.u.ffiIndex_;
+ }
+ // When a view is created from an imported constructor:
+ // var I32 = stdlib.Int32Array;
+ // var i32 = new I32(buffer);
+ // the second import has nothing to validate and thus has a null field.
+ Scalar::Type viewType() const {
+ MOZ_ASSERT(pod.which_ == ArrayView || pod.which_ == ArrayViewCtor);
+ return pod.u.viewType_;
+ }
+ AsmJSMathBuiltinFunction mathBuiltinFunction() const {
+ MOZ_ASSERT(pod.which_ == MathBuiltinFunction);
+ return pod.u.mathBuiltinFunc_;
+ }
+ ConstantKind constantKind() const {
+ MOZ_ASSERT(pod.which_ == Constant);
+ return pod.u.constant.kind_;
+ }
+ double constantValue() const {
+ MOZ_ASSERT(pod.which_ == Constant);
+ return pod.u.constant.value_;
+ }
+};
+
+using AsmJSGlobalVector = Vector<AsmJSGlobal, 0, SystemAllocPolicy>;
+
+// An AsmJSImport is slightly different than an asm.js FFI function: a single
+// asm.js FFI function can be called with many different signatures. When
+// compiled to wasm, each unique FFI function paired with signature generates a
+// wasm import.
+class AsmJSImport {
+ uint32_t ffiIndex_;
+
+ public:
+ AsmJSImport() = default;
+ explicit AsmJSImport(uint32_t ffiIndex) : ffiIndex_(ffiIndex) {}
+ uint32_t ffiIndex() const { return ffiIndex_; }
+};
+
+using AsmJSImportVector = Vector<AsmJSImport, 0, SystemAllocPolicy>;
+
+// An AsmJSExport logically extends Export with the extra information needed for
+// an asm.js exported function, viz., the offsets in module's source chars in
+// case the function is toString()ed.
+class AsmJSExport {
+ uint32_t funcIndex_ = 0;
+
+ // All fields are treated as cacheable POD:
+ uint32_t startOffsetInModule_ = 0; // Store module-start-relative offsets
+ uint32_t endOffsetInModule_ = 0; // so preserved by serialization.
+
+ public:
+ AsmJSExport() = default;
+ AsmJSExport(uint32_t funcIndex, uint32_t startOffsetInModule,
+ uint32_t endOffsetInModule)
+ : funcIndex_(funcIndex),
+ startOffsetInModule_(startOffsetInModule),
+ endOffsetInModule_(endOffsetInModule) {}
+ uint32_t funcIndex() const { return funcIndex_; }
+ uint32_t startOffsetInModule() const { return startOffsetInModule_; }
+ uint32_t endOffsetInModule() const { return endOffsetInModule_; }
+};
+
+using AsmJSExportVector = Vector<AsmJSExport, 0, SystemAllocPolicy>;
+
+// Holds the immutable guts of an AsmJSModule.
+//
+// AsmJSMetadata is built incrementally by ModuleValidator and then shared
+// immutably between AsmJSModules.
+
+struct AsmJSMetadataCacheablePod {
+ uint32_t numFFIs = 0;
+ uint32_t srcLength = 0;
+ uint32_t srcLengthWithRightBrace = 0;
+
+ AsmJSMetadataCacheablePod() = default;
+};
+
+struct js::AsmJSMetadata : Metadata, AsmJSMetadataCacheablePod {
+ AsmJSGlobalVector asmJSGlobals;
+ AsmJSImportVector asmJSImports;
+ AsmJSExportVector asmJSExports;
+ CacheableCharsVector asmJSFuncNames;
+ CacheableChars globalArgumentName;
+ CacheableChars importArgumentName;
+ CacheableChars bufferArgumentName;
+
+ // These values are not serialized since they are relative to the
+ // containing script which can be different between serialization and
+ // deserialization contexts. Thus, they must be set explicitly using the
+ // ambient Parser/ScriptSource after deserialization.
+ //
+ // srcStart refers to the offset in the ScriptSource to the beginning of
+ // the asm.js module function. If the function has been created with the
+ // Function constructor, this will be the first character in the function
+ // source. Otherwise, it will be the opening parenthesis of the arguments
+ // list.
+ uint32_t toStringStart;
+ uint32_t srcStart;
+ bool strict;
+ bool shouldResistFingerprinting = false;
+ RefPtr<ScriptSource> source;
+
+ uint32_t srcEndBeforeCurly() const { return srcStart + srcLength; }
+ uint32_t srcEndAfterCurly() const {
+ return srcStart + srcLengthWithRightBrace;
+ }
+
+ AsmJSMetadata()
+ : Metadata(ModuleKind::AsmJS),
+ toStringStart(0),
+ srcStart(0),
+ strict(false) {}
+ ~AsmJSMetadata() override = default;
+
+ const AsmJSExport& lookupAsmJSExport(uint32_t funcIndex) const {
+ // The AsmJSExportVector isn't stored in sorted order so do a linear
+ // search. This is for the super-cold and already-expensive toString()
+ // path and the number of exports is generally small.
+ for (const AsmJSExport& exp : asmJSExports) {
+ if (exp.funcIndex() == funcIndex) {
+ return exp;
+ }
+ }
+ MOZ_CRASH("missing asm.js func export");
+ }
+
+ bool mutedErrors() const override { return source->mutedErrors(); }
+ const char16_t* displayURL() const override {
+ return source->hasDisplayURL() ? source->displayURL() : nullptr;
+ }
+ ScriptSource* maybeScriptSource() const override { return source.get(); }
+ bool getFuncName(NameContext ctx, uint32_t funcIndex,
+ UTF8Bytes* name) const override {
+ const char* p = asmJSFuncNames[funcIndex].get();
+ if (!p) {
+ return true;
+ }
+ return name->append(p, strlen(p));
+ }
+
+ AsmJSMetadataCacheablePod& pod() { return *this; }
+ const AsmJSMetadataCacheablePod& pod() const { return *this; }
+};
+
+using MutableAsmJSMetadata = RefPtr<AsmJSMetadata>;
+
+/*****************************************************************************/
+// ParseNode utilities
+
+static inline ParseNode* NextNode(ParseNode* pn) { return pn->pn_next; }
+
+static inline ParseNode* UnaryKid(ParseNode* pn) {
+ return pn->as<UnaryNode>().kid();
+}
+
+static inline ParseNode* BinaryRight(ParseNode* pn) {
+ return pn->as<BinaryNode>().right();
+}
+
+static inline ParseNode* BinaryLeft(ParseNode* pn) {
+ return pn->as<BinaryNode>().left();
+}
+
+static inline ParseNode* ReturnExpr(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::ReturnStmt));
+ return UnaryKid(pn);
+}
+
+static inline ParseNode* TernaryKid1(ParseNode* pn) {
+ return pn->as<TernaryNode>().kid1();
+}
+
+static inline ParseNode* TernaryKid2(ParseNode* pn) {
+ return pn->as<TernaryNode>().kid2();
+}
+
+static inline ParseNode* TernaryKid3(ParseNode* pn) {
+ return pn->as<TernaryNode>().kid3();
+}
+
+static inline ParseNode* ListHead(ParseNode* pn) {
+ return pn->as<ListNode>().head();
+}
+
+static inline unsigned ListLength(ParseNode* pn) {
+ return pn->as<ListNode>().count();
+}
+
+static inline ParseNode* CallCallee(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::CallExpr));
+ return BinaryLeft(pn);
+}
+
+static inline unsigned CallArgListLength(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::CallExpr));
+ return ListLength(BinaryRight(pn));
+}
+
+static inline ParseNode* CallArgList(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::CallExpr));
+ return ListHead(BinaryRight(pn));
+}
+
+static inline ParseNode* VarListHead(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::VarStmt) ||
+ pn->isKind(ParseNodeKind::ConstDecl));
+ return ListHead(pn);
+}
+
+static inline bool IsDefaultCase(ParseNode* pn) {
+ return pn->as<CaseClause>().isDefault();
+}
+
+static inline ParseNode* CaseExpr(ParseNode* pn) {
+ return pn->as<CaseClause>().caseExpression();
+}
+
+static inline ParseNode* CaseBody(ParseNode* pn) {
+ return pn->as<CaseClause>().statementList();
+}
+
+static inline ParseNode* BinaryOpLeft(ParseNode* pn) {
+ MOZ_ASSERT(pn->isBinaryOperation());
+ MOZ_ASSERT(pn->as<ListNode>().count() == 2);
+ return ListHead(pn);
+}
+
+static inline ParseNode* BinaryOpRight(ParseNode* pn) {
+ MOZ_ASSERT(pn->isBinaryOperation());
+ MOZ_ASSERT(pn->as<ListNode>().count() == 2);
+ return NextNode(ListHead(pn));
+}
+
+static inline ParseNode* BitwiseLeft(ParseNode* pn) { return BinaryOpLeft(pn); }
+
+static inline ParseNode* BitwiseRight(ParseNode* pn) {
+ return BinaryOpRight(pn);
+}
+
+static inline ParseNode* MultiplyLeft(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::MulExpr));
+ return BinaryOpLeft(pn);
+}
+
+static inline ParseNode* MultiplyRight(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::MulExpr));
+ return BinaryOpRight(pn);
+}
+
+static inline ParseNode* AddSubLeft(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::AddExpr) ||
+ pn->isKind(ParseNodeKind::SubExpr));
+ return BinaryOpLeft(pn);
+}
+
+static inline ParseNode* AddSubRight(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::AddExpr) ||
+ pn->isKind(ParseNodeKind::SubExpr));
+ return BinaryOpRight(pn);
+}
+
+static inline ParseNode* DivOrModLeft(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::DivExpr) ||
+ pn->isKind(ParseNodeKind::ModExpr));
+ return BinaryOpLeft(pn);
+}
+
+static inline ParseNode* DivOrModRight(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::DivExpr) ||
+ pn->isKind(ParseNodeKind::ModExpr));
+ return BinaryOpRight(pn);
+}
+
+static inline ParseNode* ComparisonLeft(ParseNode* pn) {
+ return BinaryOpLeft(pn);
+}
+
+static inline ParseNode* ComparisonRight(ParseNode* pn) {
+ return BinaryOpRight(pn);
+}
+
+static inline bool IsExpressionStatement(ParseNode* pn) {
+ return pn->isKind(ParseNodeKind::ExpressionStmt);
+}
+
+static inline ParseNode* ExpressionStatementExpr(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::ExpressionStmt));
+ return UnaryKid(pn);
+}
+
+static inline TaggedParserAtomIndex LoopControlMaybeLabel(ParseNode* pn) {
+ MOZ_ASSERT(pn->isKind(ParseNodeKind::BreakStmt) ||
+ pn->isKind(ParseNodeKind::ContinueStmt));
+ return pn->as<LoopControlStatement>().label();
+}
+
+static inline TaggedParserAtomIndex LabeledStatementLabel(ParseNode* pn) {
+ return pn->as<LabeledStatement>().label();
+}
+
+static inline ParseNode* LabeledStatementStatement(ParseNode* pn) {
+ return pn->as<LabeledStatement>().statement();
+}
+
+static double NumberNodeValue(ParseNode* pn) {
+ return pn->as<NumericLiteral>().value();
+}
+
+static bool NumberNodeHasFrac(ParseNode* pn) {
+ return pn->as<NumericLiteral>().decimalPoint() == HasDecimal;
+}
+
+static ParseNode* DotBase(ParseNode* pn) {
+ return &pn->as<PropertyAccess>().expression();
+}
+
+static TaggedParserAtomIndex DotMember(ParseNode* pn) {
+ return pn->as<PropertyAccess>().name();
+}
+
+static ParseNode* ElemBase(ParseNode* pn) {
+ return &pn->as<PropertyByValue>().expression();
+}
+
+static ParseNode* ElemIndex(ParseNode* pn) {
+ return &pn->as<PropertyByValue>().key();
+}
+
+static inline TaggedParserAtomIndex FunctionName(FunctionNode* funNode) {
+ if (auto name = funNode->funbox()->explicitName()) {
+ return name;
+ }
+ return TaggedParserAtomIndex::null();
+}
+
+static inline ParseNode* FunctionFormalParametersList(FunctionNode* fn,
+ unsigned* numFormals) {
+ ParamsBodyNode* argsBody = fn->body();
+
+ // The number of formals is equal to the number of parameters (excluding the
+ // trailing lexical scope). There are no destructuring or rest parameters for
+ // asm.js functions.
+ *numFormals = argsBody->count();
+
+ // If the function has been fully parsed, the trailing function body node is a
+ // lexical scope. If we've only parsed the function parameters, the last node
+ // is the last parameter.
+ if (*numFormals > 0 && argsBody->last()->is<LexicalScopeNode>()) {
+ MOZ_ASSERT(argsBody->last()->as<LexicalScopeNode>().scopeBody()->isKind(
+ ParseNodeKind::StatementList));
+ (*numFormals)--;
+ }
+
+ return argsBody->head();
+}
+
+static inline ParseNode* FunctionStatementList(FunctionNode* funNode) {
+ LexicalScopeNode* last = funNode->body()->body();
+ MOZ_ASSERT(last->isEmptyScope());
+ ParseNode* body = last->scopeBody();
+ MOZ_ASSERT(body->isKind(ParseNodeKind::StatementList));
+ return body;
+}
+
+static inline bool IsNormalObjectField(ParseNode* pn) {
+ return pn->isKind(ParseNodeKind::PropertyDefinition) &&
+ pn->as<PropertyDefinition>().accessorType() == AccessorType::None &&
+ BinaryLeft(pn)->isKind(ParseNodeKind::ObjectPropertyName);
+}
+
+static inline TaggedParserAtomIndex ObjectNormalFieldName(ParseNode* pn) {
+ MOZ_ASSERT(IsNormalObjectField(pn));
+ MOZ_ASSERT(BinaryLeft(pn)->isKind(ParseNodeKind::ObjectPropertyName));
+ return BinaryLeft(pn)->as<NameNode>().atom();
+}
+
+static inline ParseNode* ObjectNormalFieldInitializer(ParseNode* pn) {
+ MOZ_ASSERT(IsNormalObjectField(pn));
+ return BinaryRight(pn);
+}
+
+static inline bool IsUseOfName(ParseNode* pn, TaggedParserAtomIndex name) {
+ return pn->isName(name);
+}
+
+static inline bool IsIgnoredDirectiveName(TaggedParserAtomIndex atom) {
+ return atom != TaggedParserAtomIndex::WellKnown::useStrict();
+}
+
+static inline bool IsIgnoredDirective(ParseNode* pn) {
+ return pn->isKind(ParseNodeKind::ExpressionStmt) &&
+ UnaryKid(pn)->isKind(ParseNodeKind::StringExpr) &&
+ IsIgnoredDirectiveName(UnaryKid(pn)->as<NameNode>().atom());
+}
+
+static inline bool IsEmptyStatement(ParseNode* pn) {
+ return pn->isKind(ParseNodeKind::EmptyStmt);
+}
+
+static inline ParseNode* SkipEmptyStatements(ParseNode* pn) {
+ while (pn && IsEmptyStatement(pn)) {
+ pn = pn->pn_next;
+ }
+ return pn;
+}
+
+static inline ParseNode* NextNonEmptyStatement(ParseNode* pn) {
+ return SkipEmptyStatements(pn->pn_next);
+}
+
+template <typename Unit>
+static bool GetToken(AsmJSParser<Unit>& parser, TokenKind* tkp) {
+ auto& ts = parser.tokenStream;
+ TokenKind tk;
+ while (true) {
+ if (!ts.getToken(&tk, TokenStreamShared::SlashIsRegExp)) {
+ return false;
+ }
+ if (tk != TokenKind::Semi) {
+ break;
+ }
+ }
+ *tkp = tk;
+ return true;
+}
+
+template <typename Unit>
+static bool PeekToken(AsmJSParser<Unit>& parser, TokenKind* tkp) {
+ auto& ts = parser.tokenStream;
+ TokenKind tk;
+ while (true) {
+ if (!ts.peekToken(&tk, TokenStream::SlashIsRegExp)) {
+ return false;
+ }
+ if (tk != TokenKind::Semi) {
+ break;
+ }
+ ts.consumeKnownToken(TokenKind::Semi, TokenStreamShared::SlashIsRegExp);
+ }
+ *tkp = tk;
+ return true;
+}
+
+template <typename Unit>
+static bool ParseVarOrConstStatement(AsmJSParser<Unit>& parser,
+ ParseNode** var) {
+ TokenKind tk;
+ if (!PeekToken(parser, &tk)) {
+ return false;
+ }
+ if (tk != TokenKind::Var && tk != TokenKind::Const) {
+ *var = nullptr;
+ return true;
+ }
+
+ *var = parser.statementListItem(YieldIsName);
+ if (!*var) {
+ return false;
+ }
+
+ MOZ_ASSERT((*var)->isKind(ParseNodeKind::VarStmt) ||
+ (*var)->isKind(ParseNodeKind::ConstDecl));
+ return true;
+}
+
+/*****************************************************************************/
+
+// Represents the type and value of an asm.js numeric literal.
+//
+// A literal is a double iff the literal contains a decimal point (even if the
+// fractional part is 0). Otherwise, integers may be classified:
+// fixnum: [0, 2^31)
+// negative int: [-2^31, 0)
+// big unsigned: [2^31, 2^32)
+// out of range: otherwise
+// Lastly, a literal may be a float literal which is any double or integer
+// literal coerced with Math.fround.
+class NumLit {
+ public:
+ enum Which {
+ Fixnum,
+ NegativeInt,
+ BigUnsigned,
+ Double,
+ Float,
+ OutOfRangeInt = -1
+ };
+
+ private:
+ Which which_;
+ JS::Value value_;
+
+ public:
+ NumLit() = default;
+
+ NumLit(Which w, const Value& v) : which_(w), value_(v) {}
+
+ Which which() const { return which_; }
+
+ int32_t toInt32() const {
+ MOZ_ASSERT(which_ == Fixnum || which_ == NegativeInt ||
+ which_ == BigUnsigned);
+ return value_.toInt32();
+ }
+
+ uint32_t toUint32() const { return (uint32_t)toInt32(); }
+
+ double toDouble() const {
+ MOZ_ASSERT(which_ == Double);
+ return value_.toDouble();
+ }
+
+ float toFloat() const {
+ MOZ_ASSERT(which_ == Float);
+ return float(value_.toDouble());
+ }
+
+ Value scalarValue() const {
+ MOZ_ASSERT(which_ != OutOfRangeInt);
+ return value_;
+ }
+
+ bool valid() const { return which_ != OutOfRangeInt; }
+
+ bool isZeroBits() const {
+ MOZ_ASSERT(valid());
+ switch (which()) {
+ case NumLit::Fixnum:
+ case NumLit::NegativeInt:
+ case NumLit::BigUnsigned:
+ return toInt32() == 0;
+ case NumLit::Double:
+ return IsPositiveZero(toDouble());
+ case NumLit::Float:
+ return IsPositiveZero(toFloat());
+ case NumLit::OutOfRangeInt:
+ MOZ_CRASH("can't be here because of valid() check above");
+ }
+ return false;
+ }
+
+ LitValPOD value() const {
+ switch (which_) {
+ case NumLit::Fixnum:
+ case NumLit::NegativeInt:
+ case NumLit::BigUnsigned:
+ return LitValPOD(toUint32());
+ case NumLit::Float:
+ return LitValPOD(toFloat());
+ case NumLit::Double:
+ return LitValPOD(toDouble());
+ case NumLit::OutOfRangeInt:;
+ }
+ MOZ_CRASH("bad literal");
+ }
+};
+
+// Represents the type of a general asm.js expression.
+//
+// A canonical subset of types representing the coercion targets: Int, Float,
+// Double.
+//
+// Void is also part of the canonical subset.
+
+class Type {
+ public:
+ enum Which {
+ Fixnum = NumLit::Fixnum,
+ Signed = NumLit::NegativeInt,
+ Unsigned = NumLit::BigUnsigned,
+ DoubleLit = NumLit::Double,
+ Float = NumLit::Float,
+ Double,
+ MaybeDouble,
+ MaybeFloat,
+ Floatish,
+ Int,
+ Intish,
+ Void
+ };
+
+ private:
+ Which which_;
+
+ public:
+ Type() = default;
+ MOZ_IMPLICIT Type(Which w) : which_(w) {}
+
+ // Map an already canonicalized Type to the return type of a function call.
+ static Type ret(Type t) {
+ MOZ_ASSERT(t.isCanonical());
+ // The 32-bit external type is Signed, not Int.
+ return t.isInt() ? Signed : t;
+ }
+
+ static Type lit(const NumLit& lit) {
+ MOZ_ASSERT(lit.valid());
+ Which which = Type::Which(lit.which());
+ MOZ_ASSERT(which >= Fixnum && which <= Float);
+ Type t;
+ t.which_ = which;
+ return t;
+ }
+
+ // Map |t| to one of the canonical vartype representations of a
+ // wasm::ValType.
+ static Type canonicalize(Type t) {
+ switch (t.which()) {
+ case Fixnum:
+ case Signed:
+ case Unsigned:
+ case Int:
+ return Int;
+
+ case Float:
+ return Float;
+
+ case DoubleLit:
+ case Double:
+ return Double;
+
+ case Void:
+ return Void;
+
+ case MaybeDouble:
+ case MaybeFloat:
+ case Floatish:
+ case Intish:
+ // These types need some kind of coercion, they can't be mapped
+ // to an VarType.
+ break;
+ }
+ MOZ_CRASH("Invalid vartype");
+ }
+
+ Which which() const { return which_; }
+
+ bool operator==(Type rhs) const { return which_ == rhs.which_; }
+ bool operator!=(Type rhs) const { return which_ != rhs.which_; }
+
+ bool operator<=(Type rhs) const {
+ switch (rhs.which_) {
+ case Signed:
+ return isSigned();
+ case Unsigned:
+ return isUnsigned();
+ case DoubleLit:
+ return isDoubleLit();
+ case Double:
+ return isDouble();
+ case Float:
+ return isFloat();
+ case MaybeDouble:
+ return isMaybeDouble();
+ case MaybeFloat:
+ return isMaybeFloat();
+ case Floatish:
+ return isFloatish();
+ case Int:
+ return isInt();
+ case Intish:
+ return isIntish();
+ case Fixnum:
+ return isFixnum();
+ case Void:
+ return isVoid();
+ }
+ MOZ_CRASH("unexpected rhs type");
+ }
+
+ bool isFixnum() const { return which_ == Fixnum; }
+
+ bool isSigned() const { return which_ == Signed || which_ == Fixnum; }
+
+ bool isUnsigned() const { return which_ == Unsigned || which_ == Fixnum; }
+
+ bool isInt() const { return isSigned() || isUnsigned() || which_ == Int; }
+
+ bool isIntish() const { return isInt() || which_ == Intish; }
+
+ bool isDoubleLit() const { return which_ == DoubleLit; }
+
+ bool isDouble() const { return isDoubleLit() || which_ == Double; }
+
+ bool isMaybeDouble() const { return isDouble() || which_ == MaybeDouble; }
+
+ bool isFloat() const { return which_ == Float; }
+
+ bool isMaybeFloat() const { return isFloat() || which_ == MaybeFloat; }
+
+ bool isFloatish() const { return isMaybeFloat() || which_ == Floatish; }
+
+ bool isVoid() const { return which_ == Void; }
+
+ bool isExtern() const { return isDouble() || isSigned(); }
+
+ // Check if this is one of the valid types for a function argument.
+ bool isArgType() const { return isInt() || isFloat() || isDouble(); }
+
+ // Check if this is one of the valid types for a function return value.
+ bool isReturnType() const {
+ return isSigned() || isFloat() || isDouble() || isVoid();
+ }
+
+ // Check if this is one of the valid types for a global variable.
+ bool isGlobalVarType() const { return isArgType(); }
+
+ // Check if this is one of the canonical vartype representations of a
+ // wasm::ValType, or is void. See Type::canonicalize().
+ bool isCanonical() const {
+ switch (which()) {
+ case Int:
+ case Float:
+ case Double:
+ case Void:
+ return true;
+ default:
+ return false;
+ }
+ }
+
+ // Check if this is a canonical representation of a wasm::ValType.
+ bool isCanonicalValType() const { return !isVoid() && isCanonical(); }
+
+ // Convert this canonical type to a wasm::ValType.
+ ValType canonicalToValType() const {
+ switch (which()) {
+ case Int:
+ return ValType::I32;
+ case Float:
+ return ValType::F32;
+ case Double:
+ return ValType::F64;
+ default:
+ MOZ_CRASH("Need canonical type");
+ }
+ }
+
+ Maybe<ValType> canonicalToReturnType() const {
+ return isVoid() ? Nothing() : Some(canonicalToValType());
+ }
+
+ // Convert this type to a wasm::TypeCode for use in a wasm
+ // block signature. This works for all types, including non-canonical
+ // ones. Consequently, the type isn't valid for subsequent asm.js
+ // validation; it's only valid for use in producing wasm.
+ TypeCode toWasmBlockSignatureType() const {
+ switch (which()) {
+ case Fixnum:
+ case Signed:
+ case Unsigned:
+ case Int:
+ case Intish:
+ return TypeCode::I32;
+
+ case Float:
+ case MaybeFloat:
+ case Floatish:
+ return TypeCode::F32;
+
+ case DoubleLit:
+ case Double:
+ case MaybeDouble:
+ return TypeCode::F64;
+
+ case Void:
+ return TypeCode::BlockVoid;
+ }
+ MOZ_CRASH("Invalid Type");
+ }
+
+ const char* toChars() const {
+ switch (which_) {
+ case Double:
+ return "double";
+ case DoubleLit:
+ return "doublelit";
+ case MaybeDouble:
+ return "double?";
+ case Float:
+ return "float";
+ case Floatish:
+ return "floatish";
+ case MaybeFloat:
+ return "float?";
+ case Fixnum:
+ return "fixnum";
+ case Int:
+ return "int";
+ case Signed:
+ return "signed";
+ case Unsigned:
+ return "unsigned";
+ case Intish:
+ return "intish";
+ case Void:
+ return "void";
+ }
+ MOZ_CRASH("Invalid Type");
+ }
+};
+
+static const unsigned VALIDATION_LIFO_DEFAULT_CHUNK_SIZE = 4 * 1024;
+
+class MOZ_STACK_CLASS ModuleValidatorShared {
+ public:
+ struct Memory {
+ MemoryUsage usage;
+ uint64_t minLength;
+
+ uint64_t minPages() const { return DivideRoundingUp(minLength, PageSize); }
+
+ Memory() = default;
+ };
+
+ class Func {
+ TaggedParserAtomIndex name_;
+ uint32_t sigIndex_;
+ uint32_t firstUse_;
+ uint32_t funcDefIndex_;
+
+ bool defined_;
+
+ // Available when defined:
+ uint32_t srcBegin_;
+ uint32_t srcEnd_;
+ uint32_t line_;
+ Bytes bytes_;
+ Uint32Vector callSiteLineNums_;
+
+ public:
+ Func(TaggedParserAtomIndex name, uint32_t sigIndex, uint32_t firstUse,
+ uint32_t funcDefIndex)
+ : name_(name),
+ sigIndex_(sigIndex),
+ firstUse_(firstUse),
+ funcDefIndex_(funcDefIndex),
+ defined_(false),
+ srcBegin_(0),
+ srcEnd_(0),
+ line_(0) {}
+
+ TaggedParserAtomIndex name() const { return name_; }
+ uint32_t sigIndex() const { return sigIndex_; }
+ uint32_t firstUse() const { return firstUse_; }
+ bool defined() const { return defined_; }
+ uint32_t funcDefIndex() const { return funcDefIndex_; }
+
+ void define(ParseNode* fn, uint32_t line, Bytes&& bytes,
+ Uint32Vector&& callSiteLineNums) {
+ MOZ_ASSERT(!defined_);
+ defined_ = true;
+ srcBegin_ = fn->pn_pos.begin;
+ srcEnd_ = fn->pn_pos.end;
+ line_ = line;
+ bytes_ = std::move(bytes);
+ callSiteLineNums_ = std::move(callSiteLineNums);
+ }
+
+ uint32_t srcBegin() const {
+ MOZ_ASSERT(defined_);
+ return srcBegin_;
+ }
+ uint32_t srcEnd() const {
+ MOZ_ASSERT(defined_);
+ return srcEnd_;
+ }
+ uint32_t line() const {
+ MOZ_ASSERT(defined_);
+ return line_;
+ }
+ const Bytes& bytes() const {
+ MOZ_ASSERT(defined_);
+ return bytes_;
+ }
+ Uint32Vector& callSiteLineNums() {
+ MOZ_ASSERT(defined_);
+ return callSiteLineNums_;
+ }
+ };
+
+ using ConstFuncVector = Vector<const Func*>;
+ using FuncVector = Vector<Func>;
+
+ class Table {
+ uint32_t sigIndex_;
+ TaggedParserAtomIndex name_;
+ uint32_t firstUse_;
+ uint32_t mask_;
+ bool defined_;
+
+ public:
+ Table(uint32_t sigIndex, TaggedParserAtomIndex name, uint32_t firstUse,
+ uint32_t mask)
+ : sigIndex_(sigIndex),
+ name_(name),
+ firstUse_(firstUse),
+ mask_(mask),
+ defined_(false) {}
+
+ Table(Table&& rhs) = delete;
+
+ uint32_t sigIndex() const { return sigIndex_; }
+ TaggedParserAtomIndex name() const { return name_; }
+ uint32_t firstUse() const { return firstUse_; }
+ unsigned mask() const { return mask_; }
+ bool defined() const { return defined_; }
+ void define() {
+ MOZ_ASSERT(!defined_);
+ defined_ = true;
+ }
+ };
+
+ using TableVector = Vector<Table*>;
+
+ class Global {
+ public:
+ enum Which {
+ Variable,
+ ConstantLiteral,
+ ConstantImport,
+ Function,
+ Table,
+ FFI,
+ ArrayView,
+ ArrayViewCtor,
+ MathBuiltinFunction
+ };
+
+ private:
+ Which which_;
+ union U {
+ struct VarOrConst {
+ Type::Which type_;
+ unsigned index_;
+ NumLit literalValue_;
+
+ VarOrConst(unsigned index, const NumLit& lit)
+ : type_(Type::lit(lit).which()),
+ index_(index),
+ literalValue_(lit) // copies |lit|
+ {}
+
+ VarOrConst(unsigned index, Type::Which which)
+ : type_(which), index_(index) {
+ // The |literalValue_| field remains unused and
+ // uninitialized for non-constant variables.
+ }
+
+ explicit VarOrConst(double constant)
+ : type_(Type::Double),
+ literalValue_(NumLit::Double, DoubleValue(constant)) {
+ // The index_ field is unused and uninitialized for
+ // constant doubles.
+ }
+ } varOrConst;
+ uint32_t funcDefIndex_;
+ uint32_t tableIndex_;
+ uint32_t ffiIndex_;
+ Scalar::Type viewType_;
+ AsmJSMathBuiltinFunction mathBuiltinFunc_;
+
+ // |varOrConst|, through |varOrConst.literalValue_|, has a
+ // non-trivial constructor and therefore MUST be placement-new'd
+ // into existence.
+ MOZ_PUSH_DISABLE_NONTRIVIAL_UNION_WARNINGS
+ U() : funcDefIndex_(0) {}
+ MOZ_POP_DISABLE_NONTRIVIAL_UNION_WARNINGS
+ } u;
+
+ friend class ModuleValidatorShared;
+ template <typename Unit>
+ friend class ModuleValidator;
+ friend class js::LifoAlloc;
+
+ explicit Global(Which which) : which_(which) {}
+
+ public:
+ Which which() const { return which_; }
+ Type varOrConstType() const {
+ MOZ_ASSERT(which_ == Variable || which_ == ConstantLiteral ||
+ which_ == ConstantImport);
+ return u.varOrConst.type_;
+ }
+ unsigned varOrConstIndex() const {
+ MOZ_ASSERT(which_ == Variable || which_ == ConstantImport);
+ return u.varOrConst.index_;
+ }
+ bool isConst() const {
+ return which_ == ConstantLiteral || which_ == ConstantImport;
+ }
+ NumLit constLiteralValue() const {
+ MOZ_ASSERT(which_ == ConstantLiteral);
+ return u.varOrConst.literalValue_;
+ }
+ uint32_t funcDefIndex() const {
+ MOZ_ASSERT(which_ == Function);
+ return u.funcDefIndex_;
+ }
+ uint32_t tableIndex() const {
+ MOZ_ASSERT(which_ == Table);
+ return u.tableIndex_;
+ }
+ unsigned ffiIndex() const {
+ MOZ_ASSERT(which_ == FFI);
+ return u.ffiIndex_;
+ }
+ Scalar::Type viewType() const {
+ MOZ_ASSERT(which_ == ArrayView || which_ == ArrayViewCtor);
+ return u.viewType_;
+ }
+ bool isMathFunction() const { return which_ == MathBuiltinFunction; }
+ AsmJSMathBuiltinFunction mathBuiltinFunction() const {
+ MOZ_ASSERT(which_ == MathBuiltinFunction);
+ return u.mathBuiltinFunc_;
+ }
+ };
+
+ struct MathBuiltin {
+ enum Kind { Function, Constant };
+ Kind kind;
+
+ union {
+ double cst;
+ AsmJSMathBuiltinFunction func;
+ } u;
+
+ MathBuiltin() : kind(Kind(-1)), u{} {}
+ explicit MathBuiltin(double cst) : kind(Constant) { u.cst = cst; }
+ explicit MathBuiltin(AsmJSMathBuiltinFunction func) : kind(Function) {
+ u.func = func;
+ }
+ };
+
+ struct ArrayView {
+ ArrayView(TaggedParserAtomIndex name, Scalar::Type type)
+ : name(name), type(type) {}
+
+ TaggedParserAtomIndex name;
+ Scalar::Type type;
+ };
+
+ protected:
+ class HashableSig {
+ uint32_t sigIndex_;
+ const TypeContext& types_;
+
+ public:
+ HashableSig(uint32_t sigIndex, const TypeContext& types)
+ : sigIndex_(sigIndex), types_(types) {}
+ uint32_t sigIndex() const { return sigIndex_; }
+ const FuncType& funcType() const { return types_[sigIndex_].funcType(); }
+
+ // Implement HashPolicy:
+ using Lookup = const FuncType&;
+ static HashNumber hash(Lookup l) { return l.hash(nullptr); }
+ static bool match(HashableSig lhs, Lookup rhs) {
+ return FuncType::strictlyEquals(lhs.funcType(), rhs);
+ }
+ };
+
+ class NamedSig : public HashableSig {
+ TaggedParserAtomIndex name_;
+
+ public:
+ NamedSig(TaggedParserAtomIndex name, uint32_t sigIndex,
+ const TypeContext& types)
+ : HashableSig(sigIndex, types), name_(name) {}
+ TaggedParserAtomIndex name() const { return name_; }
+
+ // Implement HashPolicy:
+ struct Lookup {
+ TaggedParserAtomIndex name;
+ const FuncType& funcType;
+ Lookup(TaggedParserAtomIndex name, const FuncType& funcType)
+ : name(name), funcType(funcType) {}
+ };
+ static HashNumber hash(Lookup l) {
+ return HashGeneric(TaggedParserAtomIndexHasher::hash(l.name),
+ l.funcType.hash(nullptr));
+ }
+ static bool match(NamedSig lhs, Lookup rhs) {
+ return lhs.name() == rhs.name &&
+ FuncType::strictlyEquals(lhs.funcType(), rhs.funcType);
+ }
+ };
+
+ using SigSet = HashSet<HashableSig, HashableSig>;
+ using FuncImportMap = HashMap<NamedSig, uint32_t, NamedSig>;
+ using GlobalMap =
+ HashMap<TaggedParserAtomIndex, Global*, TaggedParserAtomIndexHasher>;
+ using MathNameMap =
+ HashMap<TaggedParserAtomIndex, MathBuiltin, TaggedParserAtomIndexHasher>;
+ using ArrayViewVector = Vector<ArrayView>;
+
+ protected:
+ FrontendContext* fc_;
+ ParserAtomsTable& parserAtoms_;
+ FunctionNode* moduleFunctionNode_;
+ TaggedParserAtomIndex moduleFunctionName_;
+ TaggedParserAtomIndex globalArgumentName_;
+ TaggedParserAtomIndex importArgumentName_;
+ TaggedParserAtomIndex bufferArgumentName_;
+ MathNameMap standardLibraryMathNames_;
+
+ // Validation-internal state:
+ LifoAlloc validationLifo_;
+ Memory memory_;
+ FuncVector funcDefs_;
+ TableVector tables_;
+ GlobalMap globalMap_;
+ SigSet sigSet_;
+ FuncImportMap funcImportMap_;
+ ArrayViewVector arrayViews_;
+
+ // State used to build the AsmJSModule in finish():
+ CompilerEnvironment compilerEnv_;
+ ModuleEnvironment moduleEnv_;
+ MutableAsmJSMetadata asmJSMetadata_;
+
+ // Error reporting:
+ UniqueChars errorString_ = nullptr;
+ uint32_t errorOffset_ = UINT32_MAX;
+ bool errorOverRecursed_ = false;
+
+ protected:
+ ModuleValidatorShared(FrontendContext* fc, ParserAtomsTable& parserAtoms,
+ FunctionNode* moduleFunctionNode)
+ : fc_(fc),
+ parserAtoms_(parserAtoms),
+ moduleFunctionNode_(moduleFunctionNode),
+ moduleFunctionName_(FunctionName(moduleFunctionNode)),
+ standardLibraryMathNames_(fc),
+ validationLifo_(VALIDATION_LIFO_DEFAULT_CHUNK_SIZE),
+ funcDefs_(fc),
+ tables_(fc),
+ globalMap_(fc),
+ sigSet_(fc),
+ funcImportMap_(fc),
+ arrayViews_(fc),
+ compilerEnv_(CompileMode::Once, Tier::Optimized, DebugEnabled::False),
+ moduleEnv_(FeatureArgs(), ModuleKind::AsmJS) {
+ compilerEnv_.computeParameters();
+ memory_.minLength = RoundUpToNextValidAsmJSHeapLength(0);
+ }
+
+ protected:
+ [[nodiscard]] bool initModuleEnvironment() { return moduleEnv_.init(); }
+
+ [[nodiscard]] bool addStandardLibraryMathInfo() {
+ static constexpr struct {
+ const char* name;
+ AsmJSMathBuiltinFunction func;
+ } functions[] = {
+ {"sin", AsmJSMathBuiltin_sin}, {"cos", AsmJSMathBuiltin_cos},
+ {"tan", AsmJSMathBuiltin_tan}, {"asin", AsmJSMathBuiltin_asin},
+ {"acos", AsmJSMathBuiltin_acos}, {"atan", AsmJSMathBuiltin_atan},
+ {"ceil", AsmJSMathBuiltin_ceil}, {"floor", AsmJSMathBuiltin_floor},
+ {"exp", AsmJSMathBuiltin_exp}, {"log", AsmJSMathBuiltin_log},
+ {"pow", AsmJSMathBuiltin_pow}, {"sqrt", AsmJSMathBuiltin_sqrt},
+ {"abs", AsmJSMathBuiltin_abs}, {"atan2", AsmJSMathBuiltin_atan2},
+ {"imul", AsmJSMathBuiltin_imul}, {"clz32", AsmJSMathBuiltin_clz32},
+ {"fround", AsmJSMathBuiltin_fround}, {"min", AsmJSMathBuiltin_min},
+ {"max", AsmJSMathBuiltin_max},
+ };
+
+ auto AddMathFunction = [this](const char* name,
+ AsmJSMathBuiltinFunction func) {
+ auto atom = parserAtoms_.internAscii(fc_, name, strlen(name));
+ if (!atom) {
+ return false;
+ }
+ MathBuiltin builtin(func);
+ return this->standardLibraryMathNames_.putNew(atom, builtin);
+ };
+
+ for (const auto& info : functions) {
+ if (!AddMathFunction(info.name, info.func)) {
+ return false;
+ }
+ }
+
+ static constexpr struct {
+ const char* name;
+ double value;
+ } constants[] = {
+ {"E", M_E},
+ {"LN10", M_LN10},
+ {"LN2", M_LN2},
+ {"LOG2E", M_LOG2E},
+ {"LOG10E", M_LOG10E},
+ {"PI", M_PI},
+ {"SQRT1_2", M_SQRT1_2},
+ {"SQRT2", M_SQRT2},
+ };
+
+ auto AddMathConstant = [this](const char* name, double cst) {
+ auto atom = parserAtoms_.internAscii(fc_, name, strlen(name));
+ if (!atom) {
+ return false;
+ }
+ MathBuiltin builtin(cst);
+ return this->standardLibraryMathNames_.putNew(atom, builtin);
+ };
+
+ for (const auto& info : constants) {
+ if (!AddMathConstant(info.name, info.value)) {
+ return false;
+ }
+ }
+
+ return true;
+ }
+
+ public:
+ FrontendContext* fc() const { return fc_; }
+ TaggedParserAtomIndex moduleFunctionName() const {
+ return moduleFunctionName_;
+ }
+ TaggedParserAtomIndex globalArgumentName() const {
+ return globalArgumentName_;
+ }
+ TaggedParserAtomIndex importArgumentName() const {
+ return importArgumentName_;
+ }
+ TaggedParserAtomIndex bufferArgumentName() const {
+ return bufferArgumentName_;
+ }
+ const ModuleEnvironment& env() { return moduleEnv_; }
+
+ void initModuleFunctionName(TaggedParserAtomIndex name) {
+ MOZ_ASSERT(!moduleFunctionName_);
+ moduleFunctionName_ = name;
+ }
+ [[nodiscard]] bool initGlobalArgumentName(TaggedParserAtomIndex n) {
+ globalArgumentName_ = n;
+ if (n) {
+ asmJSMetadata_->globalArgumentName = parserAtoms_.toNewUTF8CharsZ(fc_, n);
+ if (!asmJSMetadata_->globalArgumentName) {
+ return false;
+ }
+ }
+ return true;
+ }
+ [[nodiscard]] bool initImportArgumentName(TaggedParserAtomIndex n) {
+ importArgumentName_ = n;
+ if (n) {
+ asmJSMetadata_->importArgumentName = parserAtoms_.toNewUTF8CharsZ(fc_, n);
+ if (!asmJSMetadata_->importArgumentName) {
+ return false;
+ }
+ }
+ return true;
+ }
+ [[nodiscard]] bool initBufferArgumentName(TaggedParserAtomIndex n) {
+ bufferArgumentName_ = n;
+ if (n) {
+ asmJSMetadata_->bufferArgumentName = parserAtoms_.toNewUTF8CharsZ(fc_, n);
+ if (!asmJSMetadata_->bufferArgumentName) {
+ return false;
+ }
+ }
+ return true;
+ }
+ bool addGlobalVarInit(TaggedParserAtomIndex var, const NumLit& lit, Type type,
+ bool isConst) {
+ MOZ_ASSERT(type.isGlobalVarType());
+ MOZ_ASSERT(type == Type::canonicalize(Type::lit(lit)));
+
+ uint32_t index = moduleEnv_.globals.length();
+ if (!moduleEnv_.globals.emplaceBack(type.canonicalToValType(), !isConst,
+ index, ModuleKind::AsmJS)) {
+ return false;
+ }
+
+ Global::Which which = isConst ? Global::ConstantLiteral : Global::Variable;
+ Global* global = validationLifo_.new_<Global>(which);
+ if (!global) {
+ return false;
+ }
+ if (isConst) {
+ new (&global->u.varOrConst) Global::U::VarOrConst(index, lit);
+ } else {
+ new (&global->u.varOrConst) Global::U::VarOrConst(index, type.which());
+ }
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::Variable, nullptr);
+ g.pod.u.var.initKind_ = AsmJSGlobal::InitConstant;
+ g.pod.u.var.u.val_ = lit.value();
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addGlobalVarImport(TaggedParserAtomIndex var,
+ TaggedParserAtomIndex field, Type type,
+ bool isConst) {
+ MOZ_ASSERT(type.isGlobalVarType());
+
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ uint32_t index = moduleEnv_.globals.length();
+ ValType valType = type.canonicalToValType();
+ if (!moduleEnv_.globals.emplaceBack(valType, !isConst, index,
+ ModuleKind::AsmJS)) {
+ return false;
+ }
+
+ Global::Which which = isConst ? Global::ConstantImport : Global::Variable;
+ Global* global = validationLifo_.new_<Global>(which);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.varOrConst) Global::U::VarOrConst(index, type.which());
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::Variable, std::move(fieldChars));
+ g.pod.u.var.initKind_ = AsmJSGlobal::InitImport;
+ g.pod.u.var.u.importValType_ = valType.packed();
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addArrayView(TaggedParserAtomIndex var, Scalar::Type vt,
+ TaggedParserAtomIndex maybeField) {
+ UniqueChars fieldChars;
+ if (maybeField) {
+ fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, maybeField);
+ if (!fieldChars) {
+ return false;
+ }
+ }
+
+ if (!arrayViews_.append(ArrayView(var, vt))) {
+ return false;
+ }
+
+ Global* global = validationLifo_.new_<Global>(Global::ArrayView);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.viewType_) Scalar::Type(vt);
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::ArrayView, std::move(fieldChars));
+ g.pod.u.viewType_ = vt;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addMathBuiltinFunction(TaggedParserAtomIndex var,
+ AsmJSMathBuiltinFunction func,
+ TaggedParserAtomIndex field) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ Global* global = validationLifo_.new_<Global>(Global::MathBuiltinFunction);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.mathBuiltinFunc_) AsmJSMathBuiltinFunction(func);
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::MathBuiltinFunction, std::move(fieldChars));
+ g.pod.u.mathBuiltinFunc_ = func;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+
+ private:
+ bool addGlobalDoubleConstant(TaggedParserAtomIndex var, double constant) {
+ Global* global = validationLifo_.new_<Global>(Global::ConstantLiteral);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.varOrConst) Global::U::VarOrConst(constant);
+ return globalMap_.putNew(var, global);
+ }
+
+ public:
+ bool addMathBuiltinConstant(TaggedParserAtomIndex var, double constant,
+ TaggedParserAtomIndex field) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ if (!addGlobalDoubleConstant(var, constant)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::Constant, std::move(fieldChars));
+ g.pod.u.constant.value_ = constant;
+ g.pod.u.constant.kind_ = AsmJSGlobal::MathConstant;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addGlobalConstant(TaggedParserAtomIndex var, double constant,
+ TaggedParserAtomIndex field) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ if (!addGlobalDoubleConstant(var, constant)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::Constant, std::move(fieldChars));
+ g.pod.u.constant.value_ = constant;
+ g.pod.u.constant.kind_ = AsmJSGlobal::GlobalConstant;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addArrayViewCtor(TaggedParserAtomIndex var, Scalar::Type vt,
+ TaggedParserAtomIndex field) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ Global* global = validationLifo_.new_<Global>(Global::ArrayViewCtor);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.viewType_) Scalar::Type(vt);
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::ArrayViewCtor, std::move(fieldChars));
+ g.pod.u.viewType_ = vt;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addFFI(TaggedParserAtomIndex var, TaggedParserAtomIndex field) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, field);
+ if (!fieldChars) {
+ return false;
+ }
+
+ if (asmJSMetadata_->numFFIs == UINT32_MAX) {
+ return false;
+ }
+ uint32_t ffiIndex = asmJSMetadata_->numFFIs++;
+
+ Global* global = validationLifo_.new_<Global>(Global::FFI);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.ffiIndex_) uint32_t(ffiIndex);
+ if (!globalMap_.putNew(var, global)) {
+ return false;
+ }
+
+ AsmJSGlobal g(AsmJSGlobal::FFI, std::move(fieldChars));
+ g.pod.u.ffiIndex_ = ffiIndex;
+ return asmJSMetadata_->asmJSGlobals.append(std::move(g));
+ }
+ bool addExportField(const Func& func, TaggedParserAtomIndex maybeField) {
+ // Record the field name of this export.
+ CacheableName fieldName;
+ if (maybeField) {
+ UniqueChars fieldChars = parserAtoms_.toNewUTF8CharsZ(fc_, maybeField);
+ if (!fieldChars) {
+ return false;
+ }
+ fieldName = CacheableName::fromUTF8Chars(std::move(fieldChars));
+ }
+
+ // Declare which function is exported which gives us an index into the
+ // module ExportVector.
+ uint32_t funcIndex = funcImportMap_.count() + func.funcDefIndex();
+ if (!moduleEnv_.exports.emplaceBack(std::move(fieldName), funcIndex,
+ DefinitionKind::Function)) {
+ return false;
+ }
+
+ // The exported function might have already been exported in which case
+ // the index will refer into the range of AsmJSExports.
+ return asmJSMetadata_->asmJSExports.emplaceBack(
+ funcIndex, func.srcBegin() - asmJSMetadata_->srcStart,
+ func.srcEnd() - asmJSMetadata_->srcStart);
+ }
+
+ bool defineFuncPtrTable(uint32_t tableIndex, Uint32Vector&& elems) {
+ Table& table = *tables_[tableIndex];
+ if (table.defined()) {
+ return false;
+ }
+
+ table.define();
+
+ for (uint32_t& index : elems) {
+ index += funcImportMap_.count();
+ }
+
+ MutableElemSegment seg = js_new<ElemSegment>();
+ if (!seg) {
+ return false;
+ }
+ seg->elemType = RefType::func();
+ seg->tableIndex = tableIndex;
+ seg->offsetIfActive = Some(InitExpr(LitVal(uint32_t(0))));
+ seg->elemFuncIndices = std::move(elems);
+ return moduleEnv_.elemSegments.append(std::move(seg));
+ }
+
+ bool tryConstantAccess(uint64_t start, uint64_t width) {
+ MOZ_ASSERT(UINT64_MAX - start > width);
+ uint64_t len = start + width;
+ if (len > uint64_t(INT32_MAX) + 1) {
+ return false;
+ }
+ len = RoundUpToNextValidAsmJSHeapLength(len);
+ if (len > memory_.minLength) {
+ memory_.minLength = len;
+ }
+ return true;
+ }
+
+ // Error handling.
+ bool hasAlreadyFailed() const { return !!errorString_; }
+
+ bool failOffset(uint32_t offset, const char* str) {
+ MOZ_ASSERT(!hasAlreadyFailed());
+ MOZ_ASSERT(errorOffset_ == UINT32_MAX);
+ MOZ_ASSERT(str);
+ errorOffset_ = offset;
+ errorString_ = DuplicateString(str);
+ return false;
+ }
+
+ bool fail(ParseNode* pn, const char* str) {
+ return failOffset(pn->pn_pos.begin, str);
+ }
+
+ bool failfVAOffset(uint32_t offset, const char* fmt, va_list ap)
+ MOZ_FORMAT_PRINTF(3, 0) {
+ MOZ_ASSERT(!hasAlreadyFailed());
+ MOZ_ASSERT(errorOffset_ == UINT32_MAX);
+ MOZ_ASSERT(fmt);
+ errorOffset_ = offset;
+ errorString_ = JS_vsmprintf(fmt, ap);
+ return false;
+ }
+
+ bool failfOffset(uint32_t offset, const char* fmt, ...)
+ MOZ_FORMAT_PRINTF(3, 4) {
+ va_list ap;
+ va_start(ap, fmt);
+ failfVAOffset(offset, fmt, ap);
+ va_end(ap);
+ return false;
+ }
+
+ bool failf(ParseNode* pn, const char* fmt, ...) MOZ_FORMAT_PRINTF(3, 4) {
+ va_list ap;
+ va_start(ap, fmt);
+ failfVAOffset(pn->pn_pos.begin, fmt, ap);
+ va_end(ap);
+ return false;
+ }
+
+ bool failNameOffset(uint32_t offset, const char* fmt,
+ TaggedParserAtomIndex name) {
+ // This function is invoked without the caller properly rooting its locals.
+ if (UniqueChars bytes = parserAtoms_.toPrintableString(name)) {
+ failfOffset(offset, fmt, bytes.get());
+ } else {
+ ReportOutOfMemory(fc_);
+ }
+ return false;
+ }
+
+ bool failName(ParseNode* pn, const char* fmt, TaggedParserAtomIndex name) {
+ return failNameOffset(pn->pn_pos.begin, fmt, name);
+ }
+
+ bool failOverRecursed() {
+ errorOverRecursed_ = true;
+ return false;
+ }
+
+ unsigned numArrayViews() const { return arrayViews_.length(); }
+ const ArrayView& arrayView(unsigned i) const { return arrayViews_[i]; }
+ unsigned numFuncDefs() const { return funcDefs_.length(); }
+ const Func& funcDef(unsigned i) const { return funcDefs_[i]; }
+ unsigned numFuncPtrTables() const { return tables_.length(); }
+ Table& table(unsigned i) const { return *tables_[i]; }
+
+ const Global* lookupGlobal(TaggedParserAtomIndex name) const {
+ if (GlobalMap::Ptr p = globalMap_.lookup(name)) {
+ return p->value();
+ }
+ return nullptr;
+ }
+
+ Func* lookupFuncDef(TaggedParserAtomIndex name) {
+ if (GlobalMap::Ptr p = globalMap_.lookup(name)) {
+ Global* value = p->value();
+ if (value->which() == Global::Function) {
+ return &funcDefs_[value->funcDefIndex()];
+ }
+ }
+ return nullptr;
+ }
+
+ bool lookupStandardLibraryMathName(TaggedParserAtomIndex name,
+ MathBuiltin* mathBuiltin) const {
+ if (MathNameMap::Ptr p = standardLibraryMathNames_.lookup(name)) {
+ *mathBuiltin = p->value();
+ return true;
+ }
+ return false;
+ }
+
+ bool startFunctionBodies() {
+ if (!arrayViews_.empty()) {
+ memory_.usage = MemoryUsage::Unshared;
+ } else {
+ memory_.usage = MemoryUsage::None;
+ }
+ return true;
+ }
+};
+
+// The ModuleValidator encapsulates the entire validation of an asm.js module.
+// Its lifetime goes from the validation of the top components of an asm.js
+// module (all the globals), the emission of bytecode for all the functions in
+// the module and the validation of function's pointer tables. It also finishes
+// the compilation of all the module's stubs.
+template <typename Unit>
+class MOZ_STACK_CLASS ModuleValidator : public ModuleValidatorShared {
+ private:
+ AsmJSParser<Unit>& parser_;
+
+ public:
+ ModuleValidator(FrontendContext* fc, ParserAtomsTable& parserAtoms,
+ AsmJSParser<Unit>& parser, FunctionNode* moduleFunctionNode)
+ : ModuleValidatorShared(fc, parserAtoms, moduleFunctionNode),
+ parser_(parser) {}
+
+ ~ModuleValidator() {
+ if (errorString_) {
+ MOZ_ASSERT(errorOffset_ != UINT32_MAX);
+ typeFailure(errorOffset_, errorString_.get());
+ }
+ if (errorOverRecursed_) {
+ ReportOverRecursed(fc_);
+ }
+ }
+
+ private:
+ // Helpers:
+ bool newSig(FuncType&& sig, uint32_t* sigIndex) {
+ if (moduleEnv_.types->length() >= MaxTypes) {
+ return failCurrentOffset("too many signatures");
+ }
+
+ *sigIndex = moduleEnv_.types->length();
+ return moduleEnv_.types->addType(std::move(sig));
+ }
+ bool declareSig(FuncType&& sig, uint32_t* sigIndex) {
+ SigSet::AddPtr p = sigSet_.lookupForAdd(sig);
+ if (p) {
+ *sigIndex = p->sigIndex();
+ MOZ_ASSERT(FuncType::strictlyEquals(
+ moduleEnv_.types->type(*sigIndex).funcType(), sig));
+ return true;
+ }
+
+ return newSig(std::move(sig), sigIndex) &&
+ sigSet_.add(p, HashableSig(*sigIndex, *moduleEnv_.types));
+ }
+
+ private:
+ void typeFailure(uint32_t offset, ...) {
+ va_list args;
+ va_start(args, offset);
+
+ auto& ts = tokenStream();
+ ErrorMetadata metadata;
+ if (ts.computeErrorMetadata(&metadata, AsVariant(offset))) {
+ if (ts.anyCharsAccess().options().throwOnAsmJSValidationFailureOption) {
+ ReportCompileErrorLatin1(fc_, std::move(metadata), nullptr,
+ JSMSG_USE_ASM_TYPE_FAIL, &args);
+ } else {
+ // asm.js type failure is indicated by calling one of the fail*
+ // functions below. These functions always return false to
+ // halt asm.js parsing. Whether normal parsing is attempted as
+ // fallback, depends whether an exception is also set.
+ //
+ // If warning succeeds, no exception is set. If warning fails,
+ // an exception is set and execution will halt. Thus it's safe
+ // and correct to ignore the return value here.
+ (void)ts.compileWarning(std::move(metadata), nullptr,
+ JSMSG_USE_ASM_TYPE_FAIL, &args);
+ }
+ }
+
+ va_end(args);
+ }
+
+ public:
+ bool init() {
+ asmJSMetadata_ = js_new<AsmJSMetadata>();
+ if (!asmJSMetadata_) {
+ ReportOutOfMemory(fc_);
+ return false;
+ }
+
+ asmJSMetadata_->toStringStart =
+ moduleFunctionNode_->funbox()->extent().toStringStart;
+ asmJSMetadata_->srcStart = moduleFunctionNode_->body()->pn_pos.begin;
+ asmJSMetadata_->strict = parser_.pc_->sc()->strict() &&
+ !parser_.pc_->sc()->hasExplicitUseStrict();
+ asmJSMetadata_->shouldResistFingerprinting =
+ parser_.options().shouldResistFingerprinting();
+ asmJSMetadata_->source = do_AddRef(parser_.ss);
+
+ if (!initModuleEnvironment()) {
+ return false;
+ }
+ return addStandardLibraryMathInfo();
+ }
+
+ AsmJSParser<Unit>& parser() const { return parser_; }
+
+ auto& tokenStream() const { return parser_.tokenStream; }
+
+ bool shouldResistFingerprinting() const {
+ return asmJSMetadata_->shouldResistFingerprinting;
+ }
+
+ public:
+ bool addFuncDef(TaggedParserAtomIndex name, uint32_t firstUse, FuncType&& sig,
+ Func** func) {
+ uint32_t sigIndex;
+ if (!declareSig(std::move(sig), &sigIndex)) {
+ return false;
+ }
+
+ uint32_t funcDefIndex = funcDefs_.length();
+ if (funcDefIndex >= MaxFuncs) {
+ return failCurrentOffset("too many functions");
+ }
+
+ Global* global = validationLifo_.new_<Global>(Global::Function);
+ if (!global) {
+ return false;
+ }
+ new (&global->u.funcDefIndex_) uint32_t(funcDefIndex);
+ if (!globalMap_.putNew(name, global)) {
+ return false;
+ }
+ if (!funcDefs_.emplaceBack(name, sigIndex, firstUse, funcDefIndex)) {
+ return false;
+ }
+ *func = &funcDefs_.back();
+ return true;
+ }
+ bool declareFuncPtrTable(FuncType&& sig, TaggedParserAtomIndex name,
+ uint32_t firstUse, uint32_t mask,
+ uint32_t* tableIndex) {
+ if (mask > MaxTableLength) {
+ return failCurrentOffset("function pointer table too big");
+ }
+
+ MOZ_ASSERT(moduleEnv_.tables.length() == tables_.length());
+ *tableIndex = moduleEnv_.tables.length();
+
+ uint32_t sigIndex;
+ if (!newSig(std::move(sig), &sigIndex)) {
+ return false;
+ }
+
+ MOZ_ASSERT(sigIndex >= moduleEnv_.asmJSSigToTableIndex.length());
+ if (!moduleEnv_.asmJSSigToTableIndex.resize(sigIndex + 1)) {
+ return false;
+ }
+
+ moduleEnv_.asmJSSigToTableIndex[sigIndex] = moduleEnv_.tables.length();
+ if (!moduleEnv_.tables.emplaceBack(RefType::func(), mask + 1, Nothing(),
+ /* initExpr */ Nothing(),
+ /*isAsmJS*/ true)) {
+ return false;
+ }
+
+ Global* global = validationLifo_.new_<Global>(Global::Table);
+ if (!global) {
+ return false;
+ }
+
+ new (&global->u.tableIndex_) uint32_t(*tableIndex);
+ if (!globalMap_.putNew(name, global)) {
+ return false;
+ }
+
+ Table* t = validationLifo_.new_<Table>(sigIndex, name, firstUse, mask);
+ return t && tables_.append(t);
+ }
+ bool declareImport(TaggedParserAtomIndex name, FuncType&& sig,
+ unsigned ffiIndex, uint32_t* importIndex) {
+ FuncImportMap::AddPtr p =
+ funcImportMap_.lookupForAdd(NamedSig::Lookup(name, sig));
+ if (p) {
+ *importIndex = p->value();
+ return true;
+ }
+
+ *importIndex = funcImportMap_.count();
+ MOZ_ASSERT(*importIndex == asmJSMetadata_->asmJSImports.length());
+
+ if (*importIndex >= MaxImports) {
+ return failCurrentOffset("too many imports");
+ }
+
+ if (!asmJSMetadata_->asmJSImports.emplaceBack(ffiIndex)) {
+ return false;
+ }
+
+ uint32_t sigIndex;
+ if (!declareSig(std::move(sig), &sigIndex)) {
+ return false;
+ }
+
+ return funcImportMap_.add(p, NamedSig(name, sigIndex, *moduleEnv_.types),
+ *importIndex);
+ }
+
+ // Error handling.
+ bool failCurrentOffset(const char* str) {
+ return failOffset(tokenStream().anyCharsAccess().currentToken().pos.begin,
+ str);
+ }
+
+ SharedModule finish() {
+ MOZ_ASSERT(!moduleEnv_.usesMemory());
+ if (memory_.usage != MemoryUsage::None) {
+ Limits limits;
+ limits.shared = memory_.usage == MemoryUsage::Shared ? Shareable::True
+ : Shareable::False;
+ limits.initial = memory_.minPages();
+ limits.maximum = Nothing();
+ limits.indexType = IndexType::I32;
+ moduleEnv_.memory = Some(MemoryDesc(limits));
+ }
+ MOZ_ASSERT(moduleEnv_.funcs.empty());
+ if (!moduleEnv_.funcs.resize(funcImportMap_.count() + funcDefs_.length())) {
+ return nullptr;
+ }
+ for (FuncImportMap::Range r = funcImportMap_.all(); !r.empty();
+ r.popFront()) {
+ uint32_t funcIndex = r.front().value();
+ uint32_t funcTypeIndex = r.front().key().sigIndex();
+ MOZ_ASSERT(!moduleEnv_.funcs[funcIndex].type);
+ moduleEnv_.funcs[funcIndex] = FuncDesc(
+ &moduleEnv_.types->type(funcTypeIndex).funcType(), funcTypeIndex);
+ }
+ for (const Func& func : funcDefs_) {
+ uint32_t funcIndex = funcImportMap_.count() + func.funcDefIndex();
+ uint32_t funcTypeIndex = func.sigIndex();
+ MOZ_ASSERT(!moduleEnv_.funcs[funcIndex].type);
+ moduleEnv_.funcs[funcIndex] = FuncDesc(
+ &moduleEnv_.types->type(funcTypeIndex).funcType(), funcTypeIndex);
+ }
+ for (const Export& exp : moduleEnv_.exports) {
+ if (exp.kind() != DefinitionKind::Function) {
+ continue;
+ }
+ uint32_t funcIndex = exp.funcIndex();
+ moduleEnv_.declareFuncExported(funcIndex, /* eager */ true,
+ /* canRefFunc */ false);
+ }
+
+ moduleEnv_.numFuncImports = funcImportMap_.count();
+
+ MOZ_ASSERT(asmJSMetadata_->asmJSFuncNames.empty());
+ if (!asmJSMetadata_->asmJSFuncNames.resize(funcImportMap_.count())) {
+ return nullptr;
+ }
+ for (const Func& func : funcDefs_) {
+ CacheableChars funcName = parserAtoms_.toNewUTF8CharsZ(fc_, func.name());
+ if (!funcName ||
+ !asmJSMetadata_->asmJSFuncNames.emplaceBack(std::move(funcName))) {
+ return nullptr;
+ }
+ }
+
+ uint32_t endBeforeCurly =
+ tokenStream().anyCharsAccess().currentToken().pos.end;
+ asmJSMetadata_->srcLength = endBeforeCurly - asmJSMetadata_->srcStart;
+
+ TokenPos pos;
+ MOZ_ALWAYS_TRUE(
+ tokenStream().peekTokenPos(&pos, TokenStreamShared::SlashIsRegExp));
+ uint32_t endAfterCurly = pos.end;
+ asmJSMetadata_->srcLengthWithRightBrace =
+ endAfterCurly - asmJSMetadata_->srcStart;
+
+ ScriptedCaller scriptedCaller;
+ if (parser_.ss->filename()) {
+ scriptedCaller.line = 0; // unused
+ scriptedCaller.filename = DuplicateString(parser_.ss->filename());
+ if (!scriptedCaller.filename) {
+ return nullptr;
+ }
+ }
+
+ // The default options are fine for asm.js
+ SharedCompileArgs args =
+ CompileArgs::buildForAsmJS(std::move(scriptedCaller));
+ if (!args) {
+ ReportOutOfMemory(fc_);
+ return nullptr;
+ }
+
+ uint32_t codeSectionSize = 0;
+ for (const Func& func : funcDefs_) {
+ codeSectionSize += func.bytes().length();
+ }
+
+ moduleEnv_.codeSection.emplace();
+ moduleEnv_.codeSection->start = 0;
+ moduleEnv_.codeSection->size = codeSectionSize;
+
+ // asm.js does not have any wasm bytecode to save; view-source is
+ // provided through the ScriptSource.
+ SharedBytes bytes = js_new<ShareableBytes>();
+ if (!bytes) {
+ ReportOutOfMemory(fc_);
+ return nullptr;
+ }
+
+ ModuleGenerator mg(*args, &moduleEnv_, &compilerEnv_, nullptr, nullptr,
+ nullptr);
+ if (!mg.init(asmJSMetadata_.get())) {
+ return nullptr;
+ }
+
+ for (Func& func : funcDefs_) {
+ if (!mg.compileFuncDef(funcImportMap_.count() + func.funcDefIndex(),
+ func.line(), func.bytes().begin(),
+ func.bytes().end(),
+ std::move(func.callSiteLineNums()))) {
+ return nullptr;
+ }
+ }
+
+ if (!mg.finishFuncDefs()) {
+ return nullptr;
+ }
+
+ return mg.finishModule(*bytes);
+ }
+};
+
+/*****************************************************************************/
+// Numeric literal utilities
+
+static bool IsNumericNonFloatLiteral(ParseNode* pn) {
+ // Note: '-' is never rolled into the number; numbers are always positive
+ // and negations must be applied manually.
+ return pn->isKind(ParseNodeKind::NumberExpr) ||
+ (pn->isKind(ParseNodeKind::NegExpr) &&
+ UnaryKid(pn)->isKind(ParseNodeKind::NumberExpr));
+}
+
+static bool IsCallToGlobal(ModuleValidatorShared& m, ParseNode* pn,
+ const ModuleValidatorShared::Global** global) {
+ if (!pn->isKind(ParseNodeKind::CallExpr)) {
+ return false;
+ }
+
+ ParseNode* callee = CallCallee(pn);
+ if (!callee->isKind(ParseNodeKind::Name)) {
+ return false;
+ }
+
+ *global = m.lookupGlobal(callee->as<NameNode>().name());
+ return !!*global;
+}
+
+static bool IsCoercionCall(ModuleValidatorShared& m, ParseNode* pn,
+ Type* coerceTo, ParseNode** coercedExpr) {
+ const ModuleValidatorShared::Global* global;
+ if (!IsCallToGlobal(m, pn, &global)) {
+ return false;
+ }
+
+ if (CallArgListLength(pn) != 1) {
+ return false;
+ }
+
+ if (coercedExpr) {
+ *coercedExpr = CallArgList(pn);
+ }
+
+ if (global->isMathFunction() &&
+ global->mathBuiltinFunction() == AsmJSMathBuiltin_fround) {
+ *coerceTo = Type::Float;
+ return true;
+ }
+
+ return false;
+}
+
+static bool IsFloatLiteral(ModuleValidatorShared& m, ParseNode* pn) {
+ ParseNode* coercedExpr;
+ Type coerceTo;
+ if (!IsCoercionCall(m, pn, &coerceTo, &coercedExpr)) {
+ return false;
+ }
+ // Don't fold into || to avoid clang/memcheck bug (bug 1077031).
+ if (!coerceTo.isFloat()) {
+ return false;
+ }
+ return IsNumericNonFloatLiteral(coercedExpr);
+}
+
+static bool IsNumericLiteral(ModuleValidatorShared& m, ParseNode* pn) {
+ return IsNumericNonFloatLiteral(pn) || IsFloatLiteral(m, pn);
+}
+
+// The JS grammar treats -42 as -(42) (i.e., with separate grammar
+// productions) for the unary - and literal 42). However, the asm.js spec
+// recognizes -42 (modulo parens, so -(42) and -((42))) as a single literal
+// so fold the two potential parse nodes into a single double value.
+static double ExtractNumericNonFloatValue(ParseNode* pn,
+ ParseNode** out = nullptr) {
+ MOZ_ASSERT(IsNumericNonFloatLiteral(pn));
+
+ if (pn->isKind(ParseNodeKind::NegExpr)) {
+ pn = UnaryKid(pn);
+ if (out) {
+ *out = pn;
+ }
+ return -NumberNodeValue(pn);
+ }
+
+ return NumberNodeValue(pn);
+}
+
+static NumLit ExtractNumericLiteral(ModuleValidatorShared& m, ParseNode* pn) {
+ MOZ_ASSERT(IsNumericLiteral(m, pn));
+
+ if (pn->isKind(ParseNodeKind::CallExpr)) {
+ // Float literals are explicitly coerced and thus the coerced literal may be
+ // any valid (non-float) numeric literal.
+ MOZ_ASSERT(CallArgListLength(pn) == 1);
+ pn = CallArgList(pn);
+ double d = ExtractNumericNonFloatValue(pn);
+ return NumLit(NumLit::Float, DoubleValue(d));
+ }
+
+ double d = ExtractNumericNonFloatValue(pn, &pn);
+
+ // The asm.js spec syntactically distinguishes any literal containing a
+ // decimal point or the literal -0 as having double type.
+ if (NumberNodeHasFrac(pn) || IsNegativeZero(d)) {
+ return NumLit(NumLit::Double, DoubleValue(d));
+ }
+
+ // The syntactic checks above rule out these double values.
+ MOZ_ASSERT(!IsNegativeZero(d));
+ MOZ_ASSERT(!std::isnan(d));
+
+ // Although doubles can only *precisely* represent 53-bit integers, they
+ // can *imprecisely* represent integers much bigger than an int64_t.
+ // Furthermore, d may be inf or -inf. In both cases, casting to an int64_t
+ // is undefined, so test against the integer bounds using doubles.
+ if (d < double(INT32_MIN) || d > double(UINT32_MAX)) {
+ return NumLit(NumLit::OutOfRangeInt, UndefinedValue());
+ }
+
+ // With the above syntactic and range limitations, d is definitely an
+ // integer in the range [INT32_MIN, UINT32_MAX] range.
+ int64_t i64 = int64_t(d);
+ if (i64 >= 0) {
+ if (i64 <= INT32_MAX) {
+ return NumLit(NumLit::Fixnum, Int32Value(i64));
+ }
+ MOZ_ASSERT(i64 <= UINT32_MAX);
+ return NumLit(NumLit::BigUnsigned, Int32Value(uint32_t(i64)));
+ }
+ MOZ_ASSERT(i64 >= INT32_MIN);
+ return NumLit(NumLit::NegativeInt, Int32Value(i64));
+}
+
+static inline bool IsLiteralInt(const NumLit& lit, uint32_t* u32) {
+ switch (lit.which()) {
+ case NumLit::Fixnum:
+ case NumLit::BigUnsigned:
+ case NumLit::NegativeInt:
+ *u32 = lit.toUint32();
+ return true;
+ case NumLit::Double:
+ case NumLit::Float:
+ case NumLit::OutOfRangeInt:
+ return false;
+ }
+ MOZ_CRASH("Bad literal type");
+}
+
+static inline bool IsLiteralInt(ModuleValidatorShared& m, ParseNode* pn,
+ uint32_t* u32) {
+ return IsNumericLiteral(m, pn) &&
+ IsLiteralInt(ExtractNumericLiteral(m, pn), u32);
+}
+
+/*****************************************************************************/
+
+namespace {
+
+using LabelVector = Vector<TaggedParserAtomIndex, 4, SystemAllocPolicy>;
+
+class MOZ_STACK_CLASS FunctionValidatorShared {
+ public:
+ struct Local {
+ Type type;
+ unsigned slot;
+ Local(Type t, unsigned slot) : type(t), slot(slot) {
+ MOZ_ASSERT(type.isCanonicalValType());
+ }
+ };
+
+ protected:
+ using LocalMap =
+ HashMap<TaggedParserAtomIndex, Local, TaggedParserAtomIndexHasher>;
+ using LabelMap =
+ HashMap<TaggedParserAtomIndex, uint32_t, TaggedParserAtomIndexHasher>;
+
+ // This is also a ModuleValidator<Unit>& after the appropriate static_cast<>.
+ ModuleValidatorShared& m_;
+
+ FunctionNode* fn_;
+ Bytes bytes_;
+ Encoder encoder_;
+ Uint32Vector callSiteLineNums_;
+ LocalMap locals_;
+
+ // Labels
+ LabelMap breakLabels_;
+ LabelMap continueLabels_;
+ Uint32Vector breakableStack_;
+ Uint32Vector continuableStack_;
+ uint32_t blockDepth_;
+
+ bool hasAlreadyReturned_;
+ Maybe<ValType> ret_;
+
+ private:
+ FunctionValidatorShared(ModuleValidatorShared& m, FunctionNode* fn,
+ FrontendContext* fc)
+ : m_(m),
+ fn_(fn),
+ encoder_(bytes_),
+ locals_(fc),
+ breakLabels_(fc),
+ continueLabels_(fc),
+ blockDepth_(0),
+ hasAlreadyReturned_(false) {}
+
+ protected:
+ template <typename Unit>
+ FunctionValidatorShared(ModuleValidator<Unit>& m, FunctionNode* fn,
+ FrontendContext* fc)
+ : FunctionValidatorShared(static_cast<ModuleValidatorShared&>(m), fn,
+ fc) {}
+
+ public:
+ ModuleValidatorShared& m() const { return m_; }
+
+ FrontendContext* fc() const { return m_.fc(); }
+ FunctionNode* fn() const { return fn_; }
+
+ void define(ModuleValidatorShared::Func* func, unsigned line) {
+ MOZ_ASSERT(!blockDepth_);
+ MOZ_ASSERT(breakableStack_.empty());
+ MOZ_ASSERT(continuableStack_.empty());
+ MOZ_ASSERT(breakLabels_.empty());
+ MOZ_ASSERT(continueLabels_.empty());
+ func->define(fn_, line, std::move(bytes_), std::move(callSiteLineNums_));
+ }
+
+ bool fail(ParseNode* pn, const char* str) { return m_.fail(pn, str); }
+
+ bool failf(ParseNode* pn, const char* fmt, ...) MOZ_FORMAT_PRINTF(3, 4) {
+ va_list ap;
+ va_start(ap, fmt);
+ m_.failfVAOffset(pn->pn_pos.begin, fmt, ap);
+ va_end(ap);
+ return false;
+ }
+
+ bool failName(ParseNode* pn, const char* fmt, TaggedParserAtomIndex name) {
+ return m_.failName(pn, fmt, name);
+ }
+
+ /***************************************************** Local scope setup */
+
+ bool addLocal(ParseNode* pn, TaggedParserAtomIndex name, Type type) {
+ LocalMap::AddPtr p = locals_.lookupForAdd(name);
+ if (p) {
+ return failName(pn, "duplicate local name '%s' not allowed", name);
+ }
+ return locals_.add(p, name, Local(type, locals_.count()));
+ }
+
+ /****************************** For consistency of returns in a function */
+
+ bool hasAlreadyReturned() const { return hasAlreadyReturned_; }
+
+ Maybe<ValType> returnedType() const { return ret_; }
+
+ void setReturnedType(const Maybe<ValType>& ret) {
+ MOZ_ASSERT(!hasAlreadyReturned_);
+ ret_ = ret;
+ hasAlreadyReturned_ = true;
+ }
+
+ /**************************************************************** Labels */
+ private:
+ bool writeBr(uint32_t absolute, Op op = Op::Br) {
+ MOZ_ASSERT(op == Op::Br || op == Op::BrIf);
+ MOZ_ASSERT(absolute < blockDepth_);
+ return encoder().writeOp(op) &&
+ encoder().writeVarU32(blockDepth_ - 1 - absolute);
+ }
+ void removeLabel(TaggedParserAtomIndex label, LabelMap* map) {
+ LabelMap::Ptr p = map->lookup(label);
+ MOZ_ASSERT(p);
+ map->remove(p);
+ }
+
+ public:
+ bool pushBreakableBlock() {
+ return encoder().writeOp(Op::Block) &&
+ encoder().writeFixedU8(uint8_t(TypeCode::BlockVoid)) &&
+ breakableStack_.append(blockDepth_++);
+ }
+ bool popBreakableBlock() {
+ MOZ_ALWAYS_TRUE(breakableStack_.popCopy() == --blockDepth_);
+ return encoder().writeOp(Op::End);
+ }
+
+ bool pushUnbreakableBlock(const LabelVector* labels = nullptr) {
+ if (labels) {
+ for (TaggedParserAtomIndex label : *labels) {
+ if (!breakLabels_.putNew(label, blockDepth_)) {
+ return false;
+ }
+ }
+ }
+ blockDepth_++;
+ return encoder().writeOp(Op::Block) &&
+ encoder().writeFixedU8(uint8_t(TypeCode::BlockVoid));
+ }
+ bool popUnbreakableBlock(const LabelVector* labels = nullptr) {
+ if (labels) {
+ for (TaggedParserAtomIndex label : *labels) {
+ removeLabel(label, &breakLabels_);
+ }
+ }
+ --blockDepth_;
+ return encoder().writeOp(Op::End);
+ }
+
+ bool pushContinuableBlock() {
+ return encoder().writeOp(Op::Block) &&
+ encoder().writeFixedU8(uint8_t(TypeCode::BlockVoid)) &&
+ continuableStack_.append(blockDepth_++);
+ }
+ bool popContinuableBlock() {
+ MOZ_ALWAYS_TRUE(continuableStack_.popCopy() == --blockDepth_);
+ return encoder().writeOp(Op::End);
+ }
+
+ bool pushLoop() {
+ return encoder().writeOp(Op::Block) &&
+ encoder().writeFixedU8(uint8_t(TypeCode::BlockVoid)) &&
+ encoder().writeOp(Op::Loop) &&
+ encoder().writeFixedU8(uint8_t(TypeCode::BlockVoid)) &&
+ breakableStack_.append(blockDepth_++) &&
+ continuableStack_.append(blockDepth_++);
+ }
+ bool popLoop() {
+ MOZ_ALWAYS_TRUE(continuableStack_.popCopy() == --blockDepth_);
+ MOZ_ALWAYS_TRUE(breakableStack_.popCopy() == --blockDepth_);
+ return encoder().writeOp(Op::End) && encoder().writeOp(Op::End);
+ }
+
+ bool pushIf(size_t* typeAt) {
+ ++blockDepth_;
+ return encoder().writeOp(Op::If) && encoder().writePatchableFixedU7(typeAt);
+ }
+ bool switchToElse() {
+ MOZ_ASSERT(blockDepth_ > 0);
+ return encoder().writeOp(Op::Else);
+ }
+ void setIfType(size_t typeAt, TypeCode type) {
+ encoder().patchFixedU7(typeAt, uint8_t(type));
+ }
+ bool popIf() {
+ MOZ_ASSERT(blockDepth_ > 0);
+ --blockDepth_;
+ return encoder().writeOp(Op::End);
+ }
+ bool popIf(size_t typeAt, TypeCode type) {
+ MOZ_ASSERT(blockDepth_ > 0);
+ --blockDepth_;
+ if (!encoder().writeOp(Op::End)) {
+ return false;
+ }
+
+ setIfType(typeAt, type);
+ return true;
+ }
+
+ bool writeBreakIf() { return writeBr(breakableStack_.back(), Op::BrIf); }
+ bool writeContinueIf() { return writeBr(continuableStack_.back(), Op::BrIf); }
+ bool writeUnlabeledBreakOrContinue(bool isBreak) {
+ return writeBr(isBreak ? breakableStack_.back() : continuableStack_.back());
+ }
+ bool writeContinue() { return writeBr(continuableStack_.back()); }
+
+ bool addLabels(const LabelVector& labels, uint32_t relativeBreakDepth,
+ uint32_t relativeContinueDepth) {
+ for (TaggedParserAtomIndex label : labels) {
+ if (!breakLabels_.putNew(label, blockDepth_ + relativeBreakDepth)) {
+ return false;
+ }
+ if (!continueLabels_.putNew(label, blockDepth_ + relativeContinueDepth)) {
+ return false;
+ }
+ }
+ return true;
+ }
+ void removeLabels(const LabelVector& labels) {
+ for (TaggedParserAtomIndex label : labels) {
+ removeLabel(label, &breakLabels_);
+ removeLabel(label, &continueLabels_);
+ }
+ }
+ bool writeLabeledBreakOrContinue(TaggedParserAtomIndex label, bool isBreak) {
+ LabelMap& map = isBreak ? breakLabels_ : continueLabels_;
+ if (LabelMap::Ptr p = map.lookup(label)) {
+ return writeBr(p->value());
+ }
+ MOZ_CRASH("nonexistent label");
+ }
+
+ /*************************************************** Read-only interface */
+
+ const Local* lookupLocal(TaggedParserAtomIndex name) const {
+ if (auto p = locals_.lookup(name)) {
+ return &p->value();
+ }
+ return nullptr;
+ }
+
+ const ModuleValidatorShared::Global* lookupGlobal(
+ TaggedParserAtomIndex name) const {
+ if (locals_.has(name)) {
+ return nullptr;
+ }
+ return m_.lookupGlobal(name);
+ }
+
+ size_t numLocals() const { return locals_.count(); }
+
+ /**************************************************** Encoding interface */
+
+ Encoder& encoder() { return encoder_; }
+
+ [[nodiscard]] bool writeInt32Lit(int32_t i32) {
+ return encoder().writeOp(Op::I32Const) && encoder().writeVarS32(i32);
+ }
+ [[nodiscard]] bool writeConstExpr(const NumLit& lit) {
+ switch (lit.which()) {
+ case NumLit::Fixnum:
+ case NumLit::NegativeInt:
+ case NumLit::BigUnsigned:
+ return writeInt32Lit(lit.toInt32());
+ case NumLit::Float:
+ return encoder().writeOp(Op::F32Const) &&
+ encoder().writeFixedF32(lit.toFloat());
+ case NumLit::Double:
+ return encoder().writeOp(Op::F64Const) &&
+ encoder().writeFixedF64(lit.toDouble());
+ case NumLit::OutOfRangeInt:
+ break;
+ }
+ MOZ_CRASH("unexpected literal type");
+ }
+};
+
+// Encapsulates the building of an asm bytecode function from an asm.js function
+// source code, packing the asm.js code into the asm bytecode form that can
+// be decoded and compiled with a FunctionCompiler.
+template <typename Unit>
+class MOZ_STACK_CLASS FunctionValidator : public FunctionValidatorShared {
+ public:
+ FunctionValidator(ModuleValidator<Unit>& m, FunctionNode* fn)
+ : FunctionValidatorShared(m, fn, m.fc()) {}
+
+ public:
+ ModuleValidator<Unit>& m() const {
+ return static_cast<ModuleValidator<Unit>&>(FunctionValidatorShared::m());
+ }
+
+ [[nodiscard]] bool writeCall(ParseNode* pn, Op op) {
+ MOZ_ASSERT(op == Op::Call);
+ if (!encoder().writeOp(op)) {
+ return false;
+ }
+
+ return appendCallSiteLineNumber(pn);
+ }
+ [[nodiscard]] bool writeCall(ParseNode* pn, MozOp op) {
+ MOZ_ASSERT(op == MozOp::OldCallDirect || op == MozOp::OldCallIndirect);
+ if (!encoder().writeOp(op)) {
+ return false;
+ }
+
+ return appendCallSiteLineNumber(pn);
+ }
+ [[nodiscard]] bool prepareCall(ParseNode* pn) {
+ return appendCallSiteLineNumber(pn);
+ }
+
+ private:
+ [[nodiscard]] bool appendCallSiteLineNumber(ParseNode* node) {
+ const TokenStreamAnyChars& anyChars = m().tokenStream().anyCharsAccess();
+ auto lineToken = anyChars.lineToken(node->pn_pos.begin);
+ uint32_t lineNumber = anyChars.lineNumber(lineToken);
+ if (lineNumber > CallSiteDesc::MAX_LINE_OR_BYTECODE_VALUE) {
+ return fail(node, "line number exceeding implementation limits");
+ }
+ return callSiteLineNums_.append(lineNumber);
+ }
+};
+
+} /* anonymous namespace */
+
+/*****************************************************************************/
+// asm.js type-checking and code-generation algorithm
+
+static bool CheckIdentifier(ModuleValidatorShared& m, ParseNode* usepn,
+ TaggedParserAtomIndex name) {
+ if (name == TaggedParserAtomIndex::WellKnown::arguments() ||
+ name == TaggedParserAtomIndex::WellKnown::eval()) {
+ return m.failName(usepn, "'%s' is not an allowed identifier", name);
+ }
+ return true;
+}
+
+static bool CheckModuleLevelName(ModuleValidatorShared& m, ParseNode* usepn,
+ TaggedParserAtomIndex name) {
+ if (!CheckIdentifier(m, usepn, name)) {
+ return false;
+ }
+
+ if (name == m.moduleFunctionName() || name == m.globalArgumentName() ||
+ name == m.importArgumentName() || name == m.bufferArgumentName() ||
+ m.lookupGlobal(name)) {
+ return m.failName(usepn, "duplicate name '%s' not allowed", name);
+ }
+
+ return true;
+}
+
+static bool CheckFunctionHead(ModuleValidatorShared& m, FunctionNode* funNode) {
+ FunctionBox* funbox = funNode->funbox();
+ MOZ_ASSERT(!funbox->hasExprBody());
+
+ if (funbox->hasRest()) {
+ return m.fail(funNode, "rest args not allowed");
+ }
+ if (funbox->hasDestructuringArgs) {
+ return m.fail(funNode, "destructuring args not allowed");
+ }
+ return true;
+}
+
+static bool CheckArgument(ModuleValidatorShared& m, ParseNode* arg,
+ TaggedParserAtomIndex* name) {
+ *name = TaggedParserAtomIndex::null();
+
+ if (!arg->isKind(ParseNodeKind::Name)) {
+ return m.fail(arg, "argument is not a plain name");
+ }
+
+ TaggedParserAtomIndex argName = arg->as<NameNode>().name();
+ if (!CheckIdentifier(m, arg, argName)) {
+ return false;
+ }
+
+ *name = argName;
+ return true;
+}
+
+static bool CheckModuleArgument(ModuleValidatorShared& m, ParseNode* arg,
+ TaggedParserAtomIndex* name) {
+ if (!CheckArgument(m, arg, name)) {
+ return false;
+ }
+
+ if (!CheckModuleLevelName(m, arg, *name)) {
+ return false;
+ }
+
+ return true;
+}
+
+static bool CheckModuleArguments(ModuleValidatorShared& m,
+ FunctionNode* funNode) {
+ unsigned numFormals;
+ ParseNode* arg1 = FunctionFormalParametersList(funNode, &numFormals);
+ ParseNode* arg2 = arg1 ? NextNode(arg1) : nullptr;
+ ParseNode* arg3 = arg2 ? NextNode(arg2) : nullptr;
+
+ if (numFormals > 3) {
+ return m.fail(funNode, "asm.js modules takes at most 3 argument");
+ }
+
+ TaggedParserAtomIndex arg1Name;
+ if (arg1 && !CheckModuleArgument(m, arg1, &arg1Name)) {
+ return false;
+ }
+ if (!m.initGlobalArgumentName(arg1Name)) {
+ return false;
+ }
+
+ TaggedParserAtomIndex arg2Name;
+ if (arg2 && !CheckModuleArgument(m, arg2, &arg2Name)) {
+ return false;
+ }
+ if (!m.initImportArgumentName(arg2Name)) {
+ return false;
+ }
+
+ TaggedParserAtomIndex arg3Name;
+ if (arg3 && !CheckModuleArgument(m, arg3, &arg3Name)) {
+ return false;
+ }
+ if (!m.initBufferArgumentName(arg3Name)) {
+ return false;
+ }
+
+ return true;
+}
+
+static bool CheckPrecedingStatements(ModuleValidatorShared& m,
+ ParseNode* stmtList) {
+ MOZ_ASSERT(stmtList->isKind(ParseNodeKind::StatementList));
+
+ ParseNode* stmt = ListHead(stmtList);
+ for (unsigned i = 0, n = ListLength(stmtList); i < n; i++) {
+ if (!IsIgnoredDirective(stmt)) {
+ return m.fail(stmt, "invalid asm.js statement");
+ }
+ }
+
+ return true;
+}
+
+static bool CheckGlobalVariableInitConstant(ModuleValidatorShared& m,
+ TaggedParserAtomIndex varName,
+ ParseNode* initNode, bool isConst) {
+ NumLit lit = ExtractNumericLiteral(m, initNode);
+ if (!lit.valid()) {
+ return m.fail(initNode,
+ "global initializer is out of representable integer range");
+ }
+
+ Type canonicalType = Type::canonicalize(Type::lit(lit));
+ if (!canonicalType.isGlobalVarType()) {
+ return m.fail(initNode, "global variable type not allowed");
+ }
+
+ return m.addGlobalVarInit(varName, lit, canonicalType, isConst);
+}
+
+static bool CheckTypeAnnotation(ModuleValidatorShared& m,
+ ParseNode* coercionNode, Type* coerceTo,
+ ParseNode** coercedExpr = nullptr) {
+ switch (coercionNode->getKind()) {
+ case ParseNodeKind::BitOrExpr: {
+ ParseNode* rhs = BitwiseRight(coercionNode);
+ uint32_t i;
+ if (!IsLiteralInt(m, rhs, &i) || i != 0) {
+ return m.fail(rhs, "must use |0 for argument/return coercion");
+ }
+ *coerceTo = Type::Int;
+ if (coercedExpr) {
+ *coercedExpr = BitwiseLeft(coercionNode);
+ }
+ return true;
+ }
+ case ParseNodeKind::PosExpr: {
+ *coerceTo = Type::Double;
+ if (coercedExpr) {
+ *coercedExpr = UnaryKid(coercionNode);
+ }
+ return true;
+ }
+ case ParseNodeKind::CallExpr: {
+ if (IsCoercionCall(m, coercionNode, coerceTo, coercedExpr)) {
+ return true;
+ }
+ break;
+ }
+ default:;
+ }
+
+ return m.fail(coercionNode, "must be of the form +x, x|0 or fround(x)");
+}
+
+static bool CheckGlobalVariableInitImport(ModuleValidatorShared& m,
+ TaggedParserAtomIndex varName,
+ ParseNode* initNode, bool isConst) {
+ Type coerceTo;
+ ParseNode* coercedExpr;
+ if (!CheckTypeAnnotation(m, initNode, &coerceTo, &coercedExpr)) {
+ return false;
+ }
+
+ if (!coercedExpr->isKind(ParseNodeKind::DotExpr)) {
+ return m.failName(coercedExpr, "invalid import expression for global '%s'",
+ varName);
+ }
+
+ if (!coerceTo.isGlobalVarType()) {
+ return m.fail(initNode, "global variable type not allowed");
+ }
+
+ ParseNode* base = DotBase(coercedExpr);
+ TaggedParserAtomIndex field = DotMember(coercedExpr);
+
+ TaggedParserAtomIndex importName = m.importArgumentName();
+ if (!importName) {
+ return m.fail(coercedExpr,
+ "cannot import without an asm.js foreign parameter");
+ }
+ if (!IsUseOfName(base, importName)) {
+ return m.failName(coercedExpr, "base of import expression must be '%s'",
+ importName);
+ }
+
+ return m.addGlobalVarImport(varName, field, coerceTo, isConst);
+}
+
+static bool IsArrayViewCtorName(ModuleValidatorShared& m,
+ TaggedParserAtomIndex name,
+ Scalar::Type* type) {
+ if (name == TaggedParserAtomIndex::WellKnown::Int8Array()) {
+ *type = Scalar::Int8;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Uint8Array()) {
+ *type = Scalar::Uint8;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Int16Array()) {
+ *type = Scalar::Int16;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Uint16Array()) {
+ *type = Scalar::Uint16;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Int32Array()) {
+ *type = Scalar::Int32;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Uint32Array()) {
+ *type = Scalar::Uint32;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Float32Array()) {
+ *type = Scalar::Float32;
+ } else if (name == TaggedParserAtomIndex::WellKnown::Float64Array()) {
+ *type = Scalar::Float64;
+ } else {
+ return false;
+ }
+ return true;
+}
+
+static bool CheckNewArrayViewArgs(ModuleValidatorShared& m, ParseNode* newExpr,
+ TaggedParserAtomIndex bufferName) {
+ ParseNode* ctorExpr = BinaryLeft(newExpr);
+ ParseNode* ctorArgs = BinaryRight(newExpr);
+ ParseNode* bufArg = ListHead(ctorArgs);
+ if (!bufArg || NextNode(bufArg) != nullptr) {
+ return m.fail(ctorExpr,
+ "array view constructor takes exactly one argument");
+ }
+
+ if (!IsUseOfName(bufArg, bufferName)) {
+ return m.failName(bufArg, "argument to array view constructor must be '%s'",
+ bufferName);
+ }
+
+ return true;
+}
+
+static bool CheckNewArrayView(ModuleValidatorShared& m,
+ TaggedParserAtomIndex varName,
+ ParseNode* newExpr) {
+ TaggedParserAtomIndex globalName = m.globalArgumentName();
+ if (!globalName) {
+ return m.fail(
+ newExpr, "cannot create array view without an asm.js global parameter");
+ }
+
+ TaggedParserAtomIndex bufferName = m.bufferArgumentName();
+ if (!bufferName) {
+ return m.fail(newExpr,
+ "cannot create array view without an asm.js heap parameter");
+ }
+
+ ParseNode* ctorExpr = BinaryLeft(newExpr);
+
+ TaggedParserAtomIndex field;
+ Scalar::Type type;
+ if (ctorExpr->isKind(ParseNodeKind::DotExpr)) {
+ ParseNode* base = DotBase(ctorExpr);
+
+ if (!IsUseOfName(base, globalName)) {
+ return m.failName(base, "expecting '%s.*Array", globalName);
+ }
+
+ field = DotMember(ctorExpr);
+ if (!IsArrayViewCtorName(m, field, &type)) {
+ return m.fail(ctorExpr, "could not match typed array name");
+ }
+ } else {
+ if (!ctorExpr->isKind(ParseNodeKind::Name)) {
+ return m.fail(ctorExpr,
+ "expecting name of imported array view constructor");
+ }
+
+ TaggedParserAtomIndex globalName = ctorExpr->as<NameNode>().name();
+ const ModuleValidatorShared::Global* global = m.lookupGlobal(globalName);
+ if (!global) {
+ return m.failName(ctorExpr, "%s not found in module global scope",
+ globalName);
+ }
+
+ if (global->which() != ModuleValidatorShared::Global::ArrayViewCtor) {
+ return m.failName(ctorExpr,
+ "%s must be an imported array view constructor",
+ globalName);
+ }
+
+ type = global->viewType();
+ }
+
+ if (!CheckNewArrayViewArgs(m, newExpr, bufferName)) {
+ return false;
+ }
+
+ return m.addArrayView(varName, type, field);
+}
+
+static bool CheckGlobalMathImport(ModuleValidatorShared& m, ParseNode* initNode,
+ TaggedParserAtomIndex varName,
+ TaggedParserAtomIndex field) {
+ // Math builtin, with the form glob.Math.[[builtin]]
+ ModuleValidatorShared::MathBuiltin mathBuiltin;
+ if (!m.lookupStandardLibraryMathName(field, &mathBuiltin)) {
+ return m.failName(initNode, "'%s' is not a standard Math builtin", field);
+ }
+
+ switch (mathBuiltin.kind) {
+ case ModuleValidatorShared::MathBuiltin::Function:
+ return m.addMathBuiltinFunction(varName, mathBuiltin.u.func, field);
+ case ModuleValidatorShared::MathBuiltin::Constant:
+ return m.addMathBuiltinConstant(varName, mathBuiltin.u.cst, field);
+ default:
+ break;
+ }
+ MOZ_CRASH("unexpected or uninitialized math builtin type");
+}
+
+static bool CheckGlobalDotImport(ModuleValidatorShared& m,
+ TaggedParserAtomIndex varName,
+ ParseNode* initNode) {
+ ParseNode* base = DotBase(initNode);
+ TaggedParserAtomIndex field = DotMember(initNode);
+
+ if (base->isKind(ParseNodeKind::DotExpr)) {
+ ParseNode* global = DotBase(base);
+ TaggedParserAtomIndex math = DotMember(base);
+
+ TaggedParserAtomIndex globalName = m.globalArgumentName();
+ if (!globalName) {
+ return m.fail(
+ base, "import statement requires the module have a stdlib parameter");
+ }
+
+ if (!IsUseOfName(global, globalName)) {
+ if (global->isKind(ParseNodeKind::DotExpr)) {
+ return m.failName(base,
+ "imports can have at most two dot accesses "
+ "(e.g. %s.Math.sin)",
+ globalName);
+ }
+ return m.failName(base, "expecting %s.*", globalName);
+ }
+
+ if (math == TaggedParserAtomIndex::WellKnown::Math()) {
+ return CheckGlobalMathImport(m, initNode, varName, field);
+ }
+ return m.failName(base, "expecting %s.Math", globalName);
+ }
+
+ if (!base->isKind(ParseNodeKind::Name)) {
+ return m.fail(base, "expected name of variable or parameter");
+ }
+
+ auto baseName = base->as<NameNode>().name();
+ if (baseName == m.globalArgumentName()) {
+ if (field == TaggedParserAtomIndex::WellKnown::NaN()) {
+ return m.addGlobalConstant(varName, GenericNaN(), field);
+ }
+ if (field == TaggedParserAtomIndex::WellKnown::Infinity()) {
+ return m.addGlobalConstant(varName, PositiveInfinity<double>(), field);
+ }
+
+ Scalar::Type type;
+ if (IsArrayViewCtorName(m, field, &type)) {
+ return m.addArrayViewCtor(varName, type, field);
+ }
+
+ return m.failName(
+ initNode, "'%s' is not a standard constant or typed array name", field);
+ }
+
+ if (baseName != m.importArgumentName()) {
+ return m.fail(base, "expected global or import name");
+ }
+
+ return m.addFFI(varName, field);
+}
+
+static bool CheckModuleGlobal(ModuleValidatorShared& m, ParseNode* decl,
+ bool isConst) {
+ if (!decl->isKind(ParseNodeKind::AssignExpr)) {
+ return m.fail(decl, "module import needs initializer");
+ }
+ AssignmentNode* assignNode = &decl->as<AssignmentNode>();
+
+ ParseNode* var = assignNode->left();
+
+ if (!var->isKind(ParseNodeKind::Name)) {
+ return m.fail(var, "import variable is not a plain name");
+ }
+
+ TaggedParserAtomIndex varName = var->as<NameNode>().name();
+ if (!CheckModuleLevelName(m, var, varName)) {
+ return false;
+ }
+
+ ParseNode* initNode = assignNode->right();
+
+ if (IsNumericLiteral(m, initNode)) {
+ return CheckGlobalVariableInitConstant(m, varName, initNode, isConst);
+ }
+
+ if (initNode->isKind(ParseNodeKind::BitOrExpr) ||
+ initNode->isKind(ParseNodeKind::PosExpr) ||
+ initNode->isKind(ParseNodeKind::CallExpr)) {
+ return CheckGlobalVariableInitImport(m, varName, initNode, isConst);
+ }
+
+ if (initNode->isKind(ParseNodeKind::NewExpr)) {
+ return CheckNewArrayView(m, varName, initNode);
+ }
+
+ if (initNode->isKind(ParseNodeKind::DotExpr)) {
+ return CheckGlobalDotImport(m, varName, initNode);
+ }
+
+ return m.fail(initNode, "unsupported import expression");
+}
+
+template <typename Unit>
+static bool CheckModuleProcessingDirectives(ModuleValidator<Unit>& m) {
+ auto& ts = m.parser().tokenStream;
+ while (true) {
+ bool matched;
+ if (!ts.matchToken(&matched, TokenKind::String,
+ TokenStreamShared::SlashIsRegExp)) {
+ return false;
+ }
+ if (!matched) {
+ return true;
+ }
+
+ if (!IsIgnoredDirectiveName(ts.anyCharsAccess().currentToken().atom())) {
+ return m.failCurrentOffset("unsupported processing directive");
+ }
+
+ TokenKind tt;
+ if (!ts.getToken(&tt)) {
+ return false;
+ }
+ if (tt != TokenKind::Semi) {
+ return m.failCurrentOffset("expected semicolon after string literal");
+ }
+ }
+}
+
+template <typename Unit>
+static bool CheckModuleGlobals(ModuleValidator<Unit>& m) {
+ while (true) {
+ ParseNode* varStmt;
+ if (!ParseVarOrConstStatement(m.parser(), &varStmt)) {
+ return false;
+ }
+ if (!varStmt) {
+ break;
+ }
+ for (ParseNode* var = VarListHead(varStmt); var; var = NextNode(var)) {
+ if (!CheckModuleGlobal(m, var,
+ varStmt->isKind(ParseNodeKind::ConstDecl))) {
+ return false;
+ }
+ }
+ }
+
+ return true;
+}
+
+static bool ArgFail(FunctionValidatorShared& f, TaggedParserAtomIndex argName,
+ ParseNode* stmt) {
+ return f.failName(stmt,
+ "expecting argument type declaration for '%s' of the "
+ "form 'arg = arg|0' or 'arg = +arg' or 'arg = fround(arg)'",
+ argName);
+}
+
+static bool CheckArgumentType(FunctionValidatorShared& f, ParseNode* stmt,
+ TaggedParserAtomIndex name, Type* type) {
+ if (!stmt || !IsExpressionStatement(stmt)) {
+ return ArgFail(f, name, stmt ? stmt : f.fn());
+ }
+
+ ParseNode* initNode = ExpressionStatementExpr(stmt);
+ if (!initNode->isKind(ParseNodeKind::AssignExpr)) {
+ return ArgFail(f, name, stmt);
+ }
+
+ ParseNode* argNode = BinaryLeft(initNode);
+ ParseNode* coercionNode = BinaryRight(initNode);
+
+ if (!IsUseOfName(argNode, name)) {
+ return ArgFail(f, name, stmt);
+ }
+
+ ParseNode* coercedExpr;
+ if (!CheckTypeAnnotation(f.m(), coercionNode, type, &coercedExpr)) {
+ return false;
+ }
+
+ if (!type->isArgType()) {
+ return f.failName(stmt, "invalid type for argument '%s'", name);
+ }
+
+ if (!IsUseOfName(coercedExpr, name)) {
+ return ArgFail(f, name, stmt);
+ }
+
+ return true;
+}
+
+static bool CheckProcessingDirectives(ModuleValidatorShared& m,
+ ParseNode** stmtIter) {
+ ParseNode* stmt = *stmtIter;
+
+ while (stmt && IsIgnoredDirective(stmt)) {
+ stmt = NextNode(stmt);
+ }
+
+ *stmtIter = stmt;
+ return true;
+}
+
+static bool CheckArguments(FunctionValidatorShared& f, ParseNode** stmtIter,
+ ValTypeVector* argTypes) {
+ ParseNode* stmt = *stmtIter;
+
+ unsigned numFormals;
+ ParseNode* argpn = FunctionFormalParametersList(f.fn(), &numFormals);
+
+ for (unsigned i = 0; i < numFormals;
+ i++, argpn = NextNode(argpn), stmt = NextNode(stmt)) {
+ TaggedParserAtomIndex name;
+ if (!CheckArgument(f.m(), argpn, &name)) {
+ return false;
+ }
+
+ Type type;
+ if (!CheckArgumentType(f, stmt, name, &type)) {
+ return false;
+ }
+
+ if (!argTypes->append(type.canonicalToValType())) {
+ return false;
+ }
+
+ if (!f.addLocal(argpn, name, type)) {
+ return false;
+ }
+ }
+
+ *stmtIter = stmt;
+ return true;
+}
+
+static bool IsLiteralOrConst(FunctionValidatorShared& f, ParseNode* pn,
+ NumLit* lit) {
+ if (pn->isKind(ParseNodeKind::Name)) {
+ const ModuleValidatorShared::Global* global =
+ f.lookupGlobal(pn->as<NameNode>().name());
+ if (!global ||
+ global->which() != ModuleValidatorShared::Global::ConstantLiteral) {
+ return false;
+ }
+
+ *lit = global->constLiteralValue();
+ return true;
+ }
+
+ if (!IsNumericLiteral(f.m(), pn)) {
+ return false;
+ }
+
+ *lit = ExtractNumericLiteral(f.m(), pn);
+ return true;
+}
+
+static bool CheckFinalReturn(FunctionValidatorShared& f,
+ ParseNode* lastNonEmptyStmt) {
+ if (!f.encoder().writeOp(Op::End)) {
+ return false;
+ }
+
+ if (!f.hasAlreadyReturned()) {
+ f.setReturnedType(Nothing());
+ return true;
+ }
+
+ if (!lastNonEmptyStmt->isKind(ParseNodeKind::ReturnStmt) &&
+ f.returnedType()) {
+ return f.fail(lastNonEmptyStmt,
+ "void incompatible with previous return type");
+ }
+
+ return true;
+}
+
+static bool CheckVariable(FunctionValidatorShared& f, ParseNode* decl,
+ ValTypeVector* types, Vector<NumLit>* inits) {
+ if (!decl->isKind(ParseNodeKind::AssignExpr)) {
+ return f.failName(
+ decl, "var '%s' needs explicit type declaration via an initial value",
+ decl->as<NameNode>().name());
+ }
+ AssignmentNode* assignNode = &decl->as<AssignmentNode>();
+
+ ParseNode* var = assignNode->left();
+
+ if (!var->isKind(ParseNodeKind::Name)) {
+ return f.fail(var, "local variable is not a plain name");
+ }
+
+ TaggedParserAtomIndex name = var->as<NameNode>().name();
+
+ if (!CheckIdentifier(f.m(), var, name)) {
+ return false;
+ }
+
+ ParseNode* initNode = assignNode->right();
+
+ NumLit lit;
+ if (!IsLiteralOrConst(f, initNode, &lit)) {
+ return f.failName(
+ var, "var '%s' initializer must be literal or const literal", name);
+ }
+
+ if (!lit.valid()) {
+ return f.failName(var, "var '%s' initializer out of range", name);
+ }
+
+ Type type = Type::canonicalize(Type::lit(lit));
+
+ return f.addLocal(var, name, type) &&
+ types->append(type.canonicalToValType()) && inits->append(lit);
+}
+
+static bool CheckVariables(FunctionValidatorShared& f, ParseNode** stmtIter) {
+ ParseNode* stmt = *stmtIter;
+
+ uint32_t firstVar = f.numLocals();
+
+ ValTypeVector types;
+ Vector<NumLit> inits(f.fc());
+
+ for (; stmt && stmt->isKind(ParseNodeKind::VarStmt);
+ stmt = NextNonEmptyStatement(stmt)) {
+ for (ParseNode* var = VarListHead(stmt); var; var = NextNode(var)) {
+ if (!CheckVariable(f, var, &types, &inits)) {
+ return false;
+ }
+ }
+ }
+
+ MOZ_ASSERT(f.encoder().empty());
+
+ if (!EncodeLocalEntries(f.encoder(), types)) {
+ return false;
+ }
+
+ for (uint32_t i = 0; i < inits.length(); i++) {
+ NumLit lit = inits[i];
+ if (lit.isZeroBits()) {
+ continue;
+ }
+ if (!f.writeConstExpr(lit)) {
+ return false;
+ }
+ if (!f.encoder().writeOp(Op::LocalSet)) {
+ return false;
+ }
+ if (!f.encoder().writeVarU32(firstVar + i)) {
+ return false;
+ }
+ }
+
+ *stmtIter = stmt;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckExpr(FunctionValidator<Unit>& f, ParseNode* expr, Type* type);
+
+template <typename Unit>
+static bool CheckNumericLiteral(FunctionValidator<Unit>& f, ParseNode* num,
+ Type* type) {
+ NumLit lit = ExtractNumericLiteral(f.m(), num);
+ if (!lit.valid()) {
+ return f.fail(num, "numeric literal out of representable integer range");
+ }
+ *type = Type::lit(lit);
+ return f.writeConstExpr(lit);
+}
+
+static bool CheckVarRef(FunctionValidatorShared& f, ParseNode* varRef,
+ Type* type) {
+ TaggedParserAtomIndex name = varRef->as<NameNode>().name();
+
+ if (const FunctionValidatorShared::Local* local = f.lookupLocal(name)) {
+ if (!f.encoder().writeOp(Op::LocalGet)) {
+ return false;
+ }
+ if (!f.encoder().writeVarU32(local->slot)) {
+ return false;
+ }
+ *type = local->type;
+ return true;
+ }
+
+ if (const ModuleValidatorShared::Global* global = f.lookupGlobal(name)) {
+ switch (global->which()) {
+ case ModuleValidatorShared::Global::ConstantLiteral:
+ *type = global->varOrConstType();
+ return f.writeConstExpr(global->constLiteralValue());
+ case ModuleValidatorShared::Global::ConstantImport:
+ case ModuleValidatorShared::Global::Variable: {
+ *type = global->varOrConstType();
+ return f.encoder().writeOp(Op::GlobalGet) &&
+ f.encoder().writeVarU32(global->varOrConstIndex());
+ }
+ case ModuleValidatorShared::Global::Function:
+ case ModuleValidatorShared::Global::FFI:
+ case ModuleValidatorShared::Global::MathBuiltinFunction:
+ case ModuleValidatorShared::Global::Table:
+ case ModuleValidatorShared::Global::ArrayView:
+ case ModuleValidatorShared::Global::ArrayViewCtor:
+ break;
+ }
+ return f.failName(varRef,
+ "'%s' may not be accessed by ordinary expressions", name);
+ }
+
+ return f.failName(varRef, "'%s' not found in local or asm.js module scope",
+ name);
+}
+
+static inline bool IsLiteralOrConstInt(FunctionValidatorShared& f,
+ ParseNode* pn, uint32_t* u32) {
+ NumLit lit;
+ if (!IsLiteralOrConst(f, pn, &lit)) {
+ return false;
+ }
+
+ return IsLiteralInt(lit, u32);
+}
+
+static const int32_t NoMask = -1;
+
+template <typename Unit>
+static bool CheckArrayAccess(FunctionValidator<Unit>& f, ParseNode* viewName,
+ ParseNode* indexExpr, Scalar::Type* viewType) {
+ if (!viewName->isKind(ParseNodeKind::Name)) {
+ return f.fail(viewName,
+ "base of array access must be a typed array view name");
+ }
+
+ const ModuleValidatorShared::Global* global =
+ f.lookupGlobal(viewName->as<NameNode>().name());
+ if (!global || global->which() != ModuleValidatorShared::Global::ArrayView) {
+ return f.fail(viewName,
+ "base of array access must be a typed array view name");
+ }
+
+ *viewType = global->viewType();
+
+ uint32_t index;
+ if (IsLiteralOrConstInt(f, indexExpr, &index)) {
+ uint64_t byteOffset = uint64_t(index) << TypedArrayShift(*viewType);
+ uint64_t width = TypedArrayElemSize(*viewType);
+ if (!f.m().tryConstantAccess(byteOffset, width)) {
+ return f.fail(indexExpr, "constant index out of range");
+ }
+
+ return f.writeInt32Lit(byteOffset);
+ }
+
+ // Mask off the low bits to account for the clearing effect of a right shift
+ // followed by the left shift implicit in the array access. E.g., H32[i>>2]
+ // loses the low two bits.
+ int32_t mask = ~(TypedArrayElemSize(*viewType) - 1);
+
+ if (indexExpr->isKind(ParseNodeKind::RshExpr)) {
+ ParseNode* shiftAmountNode = BitwiseRight(indexExpr);
+
+ uint32_t shift;
+ if (!IsLiteralInt(f.m(), shiftAmountNode, &shift)) {
+ return f.failf(shiftAmountNode, "shift amount must be constant");
+ }
+
+ unsigned requiredShift = TypedArrayShift(*viewType);
+ if (shift != requiredShift) {
+ return f.failf(shiftAmountNode, "shift amount must be %u", requiredShift);
+ }
+
+ ParseNode* pointerNode = BitwiseLeft(indexExpr);
+
+ Type pointerType;
+ if (!CheckExpr(f, pointerNode, &pointerType)) {
+ return false;
+ }
+
+ if (!pointerType.isIntish()) {
+ return f.failf(pointerNode, "%s is not a subtype of int",
+ pointerType.toChars());
+ }
+ } else {
+ // For legacy scalar access compatibility, accept Int8/Uint8 accesses
+ // with no shift.
+ if (TypedArrayShift(*viewType) != 0) {
+ return f.fail(
+ indexExpr,
+ "index expression isn't shifted; must be an Int8/Uint8 access");
+ }
+
+ MOZ_ASSERT(mask == NoMask);
+
+ ParseNode* pointerNode = indexExpr;
+
+ Type pointerType;
+ if (!CheckExpr(f, pointerNode, &pointerType)) {
+ return false;
+ }
+ if (!pointerType.isInt()) {
+ return f.failf(pointerNode, "%s is not a subtype of int",
+ pointerType.toChars());
+ }
+ }
+
+ // Don't generate the mask op if there is no need for it which could happen
+ // for a shift of zero.
+ if (mask != NoMask) {
+ return f.writeInt32Lit(mask) && f.encoder().writeOp(Op::I32And);
+ }
+
+ return true;
+}
+
+static bool WriteArrayAccessFlags(FunctionValidatorShared& f,
+ Scalar::Type viewType) {
+ // asm.js only has naturally-aligned accesses.
+ size_t align = TypedArrayElemSize(viewType);
+ MOZ_ASSERT(IsPowerOfTwo(align));
+ if (!f.encoder().writeFixedU8(CeilingLog2(align))) {
+ return false;
+ }
+
+ // asm.js doesn't have constant offsets, so just encode a 0.
+ if (!f.encoder().writeVarU32(0)) {
+ return false;
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckLoadArray(FunctionValidator<Unit>& f, ParseNode* elem,
+ Type* type) {
+ Scalar::Type viewType;
+
+ if (!CheckArrayAccess(f, ElemBase(elem), ElemIndex(elem), &viewType)) {
+ return false;
+ }
+
+ switch (viewType) {
+ case Scalar::Int8:
+ if (!f.encoder().writeOp(Op::I32Load8S)) return false;
+ break;
+ case Scalar::Uint8:
+ if (!f.encoder().writeOp(Op::I32Load8U)) return false;
+ break;
+ case Scalar::Int16:
+ if (!f.encoder().writeOp(Op::I32Load16S)) return false;
+ break;
+ case Scalar::Uint16:
+ if (!f.encoder().writeOp(Op::I32Load16U)) return false;
+ break;
+ case Scalar::Uint32:
+ case Scalar::Int32:
+ if (!f.encoder().writeOp(Op::I32Load)) return false;
+ break;
+ case Scalar::Float32:
+ if (!f.encoder().writeOp(Op::F32Load)) return false;
+ break;
+ case Scalar::Float64:
+ if (!f.encoder().writeOp(Op::F64Load)) return false;
+ break;
+ default:
+ MOZ_CRASH("unexpected scalar type");
+ }
+
+ switch (viewType) {
+ case Scalar::Int8:
+ case Scalar::Int16:
+ case Scalar::Int32:
+ case Scalar::Uint8:
+ case Scalar::Uint16:
+ case Scalar::Uint32:
+ *type = Type::Intish;
+ break;
+ case Scalar::Float32:
+ *type = Type::MaybeFloat;
+ break;
+ case Scalar::Float64:
+ *type = Type::MaybeDouble;
+ break;
+ default:
+ MOZ_CRASH("Unexpected array type");
+ }
+
+ return WriteArrayAccessFlags(f, viewType);
+}
+
+template <typename Unit>
+static bool CheckStoreArray(FunctionValidator<Unit>& f, ParseNode* lhs,
+ ParseNode* rhs, Type* type) {
+ Scalar::Type viewType;
+ if (!CheckArrayAccess(f, ElemBase(lhs), ElemIndex(lhs), &viewType)) {
+ return false;
+ }
+
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ switch (viewType) {
+ case Scalar::Int8:
+ case Scalar::Int16:
+ case Scalar::Int32:
+ case Scalar::Uint8:
+ case Scalar::Uint16:
+ case Scalar::Uint32:
+ if (!rhsType.isIntish()) {
+ return f.failf(lhs, "%s is not a subtype of intish", rhsType.toChars());
+ }
+ break;
+ case Scalar::Float32:
+ if (!rhsType.isMaybeDouble() && !rhsType.isFloatish()) {
+ return f.failf(lhs, "%s is not a subtype of double? or floatish",
+ rhsType.toChars());
+ }
+ break;
+ case Scalar::Float64:
+ if (!rhsType.isMaybeFloat() && !rhsType.isMaybeDouble()) {
+ return f.failf(lhs, "%s is not a subtype of float? or double?",
+ rhsType.toChars());
+ }
+ break;
+ default:
+ MOZ_CRASH("Unexpected view type");
+ }
+
+ switch (viewType) {
+ case Scalar::Int8:
+ case Scalar::Uint8:
+ if (!f.encoder().writeOp(MozOp::I32TeeStore8)) {
+ return false;
+ }
+ break;
+ case Scalar::Int16:
+ case Scalar::Uint16:
+ if (!f.encoder().writeOp(MozOp::I32TeeStore16)) {
+ return false;
+ }
+ break;
+ case Scalar::Int32:
+ case Scalar::Uint32:
+ if (!f.encoder().writeOp(MozOp::I32TeeStore)) {
+ return false;
+ }
+ break;
+ case Scalar::Float32:
+ if (rhsType.isFloatish()) {
+ if (!f.encoder().writeOp(MozOp::F32TeeStore)) {
+ return false;
+ }
+ } else {
+ if (!f.encoder().writeOp(MozOp::F64TeeStoreF32)) {
+ return false;
+ }
+ }
+ break;
+ case Scalar::Float64:
+ if (rhsType.isFloatish()) {
+ if (!f.encoder().writeOp(MozOp::F32TeeStoreF64)) {
+ return false;
+ }
+ } else {
+ if (!f.encoder().writeOp(MozOp::F64TeeStore)) {
+ return false;
+ }
+ }
+ break;
+ default:
+ MOZ_CRASH("unexpected scalar type");
+ }
+
+ if (!WriteArrayAccessFlags(f, viewType)) {
+ return false;
+ }
+
+ *type = rhsType;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckAssignName(FunctionValidator<Unit>& f, ParseNode* lhs,
+ ParseNode* rhs, Type* type) {
+ TaggedParserAtomIndex name = lhs->as<NameNode>().name();
+
+ if (const FunctionValidatorShared::Local* lhsVar = f.lookupLocal(name)) {
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (!f.encoder().writeOp(Op::LocalTee)) {
+ return false;
+ }
+ if (!f.encoder().writeVarU32(lhsVar->slot)) {
+ return false;
+ }
+
+ if (!(rhsType <= lhsVar->type)) {
+ return f.failf(lhs, "%s is not a subtype of %s", rhsType.toChars(),
+ lhsVar->type.toChars());
+ }
+ *type = rhsType;
+ return true;
+ }
+
+ if (const ModuleValidatorShared::Global* global = f.lookupGlobal(name)) {
+ if (global->which() != ModuleValidatorShared::Global::Variable) {
+ return f.failName(lhs, "'%s' is not a mutable variable", name);
+ }
+
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ Type globType = global->varOrConstType();
+ if (!(rhsType <= globType)) {
+ return f.failf(lhs, "%s is not a subtype of %s", rhsType.toChars(),
+ globType.toChars());
+ }
+ if (!f.encoder().writeOp(MozOp::TeeGlobal)) {
+ return false;
+ }
+ if (!f.encoder().writeVarU32(global->varOrConstIndex())) {
+ return false;
+ }
+
+ *type = rhsType;
+ return true;
+ }
+
+ return f.failName(lhs, "'%s' not found in local or asm.js module scope",
+ name);
+}
+
+template <typename Unit>
+static bool CheckAssign(FunctionValidator<Unit>& f, ParseNode* assign,
+ Type* type) {
+ MOZ_ASSERT(assign->isKind(ParseNodeKind::AssignExpr));
+
+ ParseNode* lhs = BinaryLeft(assign);
+ ParseNode* rhs = BinaryRight(assign);
+
+ if (lhs->getKind() == ParseNodeKind::ElemExpr) {
+ return CheckStoreArray(f, lhs, rhs, type);
+ }
+
+ if (lhs->getKind() == ParseNodeKind::Name) {
+ return CheckAssignName(f, lhs, rhs, type);
+ }
+
+ return f.fail(
+ assign,
+ "left-hand side of assignment must be a variable or array access");
+}
+
+template <typename Unit>
+static bool CheckMathIMul(FunctionValidator<Unit>& f, ParseNode* call,
+ Type* type) {
+ if (CallArgListLength(call) != 2) {
+ return f.fail(call, "Math.imul must be passed 2 arguments");
+ }
+
+ ParseNode* lhs = CallArgList(call);
+ ParseNode* rhs = NextNode(lhs);
+
+ Type lhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (!lhsType.isIntish()) {
+ return f.failf(lhs, "%s is not a subtype of intish", lhsType.toChars());
+ }
+ if (!rhsType.isIntish()) {
+ return f.failf(rhs, "%s is not a subtype of intish", rhsType.toChars());
+ }
+
+ *type = Type::Signed;
+ return f.encoder().writeOp(Op::I32Mul);
+}
+
+template <typename Unit>
+static bool CheckMathClz32(FunctionValidator<Unit>& f, ParseNode* call,
+ Type* type) {
+ if (CallArgListLength(call) != 1) {
+ return f.fail(call, "Math.clz32 must be passed 1 argument");
+ }
+
+ ParseNode* arg = CallArgList(call);
+
+ Type argType;
+ if (!CheckExpr(f, arg, &argType)) {
+ return false;
+ }
+
+ if (!argType.isIntish()) {
+ return f.failf(arg, "%s is not a subtype of intish", argType.toChars());
+ }
+
+ *type = Type::Fixnum;
+ return f.encoder().writeOp(Op::I32Clz);
+}
+
+template <typename Unit>
+static bool CheckMathAbs(FunctionValidator<Unit>& f, ParseNode* call,
+ Type* type) {
+ if (CallArgListLength(call) != 1) {
+ return f.fail(call, "Math.abs must be passed 1 argument");
+ }
+
+ ParseNode* arg = CallArgList(call);
+
+ Type argType;
+ if (!CheckExpr(f, arg, &argType)) {
+ return false;
+ }
+
+ if (argType.isSigned()) {
+ *type = Type::Unsigned;
+ return f.encoder().writeOp(MozOp::I32Abs);
+ }
+
+ if (argType.isMaybeDouble()) {
+ *type = Type::Double;
+ return f.encoder().writeOp(Op::F64Abs);
+ }
+
+ if (argType.isMaybeFloat()) {
+ *type = Type::Floatish;
+ return f.encoder().writeOp(Op::F32Abs);
+ }
+
+ return f.failf(call, "%s is not a subtype of signed, float? or double?",
+ argType.toChars());
+}
+
+template <typename Unit>
+static bool CheckMathSqrt(FunctionValidator<Unit>& f, ParseNode* call,
+ Type* type) {
+ if (CallArgListLength(call) != 1) {
+ return f.fail(call, "Math.sqrt must be passed 1 argument");
+ }
+
+ ParseNode* arg = CallArgList(call);
+
+ Type argType;
+ if (!CheckExpr(f, arg, &argType)) {
+ return false;
+ }
+
+ if (argType.isMaybeDouble()) {
+ *type = Type::Double;
+ return f.encoder().writeOp(Op::F64Sqrt);
+ }
+
+ if (argType.isMaybeFloat()) {
+ *type = Type::Floatish;
+ return f.encoder().writeOp(Op::F32Sqrt);
+ }
+
+ return f.failf(call, "%s is neither a subtype of double? nor float?",
+ argType.toChars());
+}
+
+template <typename Unit>
+static bool CheckMathMinMax(FunctionValidator<Unit>& f, ParseNode* callNode,
+ bool isMax, Type* type) {
+ if (CallArgListLength(callNode) < 2) {
+ return f.fail(callNode, "Math.min/max must be passed at least 2 arguments");
+ }
+
+ ParseNode* firstArg = CallArgList(callNode);
+ Type firstType;
+ if (!CheckExpr(f, firstArg, &firstType)) {
+ return false;
+ }
+
+ Op op = Op::Limit;
+ MozOp mozOp = MozOp::Limit;
+ if (firstType.isMaybeDouble()) {
+ *type = Type::Double;
+ firstType = Type::MaybeDouble;
+ op = isMax ? Op::F64Max : Op::F64Min;
+ } else if (firstType.isMaybeFloat()) {
+ *type = Type::Float;
+ firstType = Type::MaybeFloat;
+ op = isMax ? Op::F32Max : Op::F32Min;
+ } else if (firstType.isSigned()) {
+ *type = Type::Signed;
+ firstType = Type::Signed;
+ mozOp = isMax ? MozOp::I32Max : MozOp::I32Min;
+ } else {
+ return f.failf(firstArg, "%s is not a subtype of double?, float? or signed",
+ firstType.toChars());
+ }
+
+ unsigned numArgs = CallArgListLength(callNode);
+ ParseNode* nextArg = NextNode(firstArg);
+ for (unsigned i = 1; i < numArgs; i++, nextArg = NextNode(nextArg)) {
+ Type nextType;
+ if (!CheckExpr(f, nextArg, &nextType)) {
+ return false;
+ }
+ if (!(nextType <= firstType)) {
+ return f.failf(nextArg, "%s is not a subtype of %s", nextType.toChars(),
+ firstType.toChars());
+ }
+
+ if (op != Op::Limit) {
+ if (!f.encoder().writeOp(op)) {
+ return false;
+ }
+ } else {
+ if (!f.encoder().writeOp(mozOp)) {
+ return false;
+ }
+ }
+ }
+
+ return true;
+}
+
+using CheckArgType = bool (*)(FunctionValidatorShared& f, ParseNode* argNode,
+ Type type);
+
+template <CheckArgType checkArg, typename Unit>
+static bool CheckCallArgs(FunctionValidator<Unit>& f, ParseNode* callNode,
+ ValTypeVector* args) {
+ ParseNode* argNode = CallArgList(callNode);
+ for (unsigned i = 0; i < CallArgListLength(callNode);
+ i++, argNode = NextNode(argNode)) {
+ Type type;
+ if (!CheckExpr(f, argNode, &type)) {
+ return false;
+ }
+
+ if (!checkArg(f, argNode, type)) {
+ return false;
+ }
+
+ if (!args->append(Type::canonicalize(type).canonicalToValType())) {
+ return false;
+ }
+ }
+ return true;
+}
+
+static bool CheckSignatureAgainstExisting(ModuleValidatorShared& m,
+ ParseNode* usepn, const FuncType& sig,
+ const FuncType& existing) {
+ if (!FuncType::strictlyEquals(sig, existing)) {
+ return m.failf(usepn, "incompatible argument types to function");
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFunctionSignature(ModuleValidator<Unit>& m, ParseNode* usepn,
+ FuncType&& sig, TaggedParserAtomIndex name,
+ ModuleValidatorShared::Func** func) {
+ if (sig.args().length() > MaxParams) {
+ return m.failf(usepn, "too many parameters");
+ }
+
+ ModuleValidatorShared::Func* existing = m.lookupFuncDef(name);
+ if (!existing) {
+ if (!CheckModuleLevelName(m, usepn, name)) {
+ return false;
+ }
+ return m.addFuncDef(name, usepn->pn_pos.begin, std::move(sig), func);
+ }
+
+ const FuncType& existingSig =
+ m.env().types->type(existing->sigIndex()).funcType();
+
+ if (!CheckSignatureAgainstExisting(m, usepn, sig, existingSig)) {
+ return false;
+ }
+
+ *func = existing;
+ return true;
+}
+
+static bool CheckIsArgType(FunctionValidatorShared& f, ParseNode* argNode,
+ Type type) {
+ if (!type.isArgType()) {
+ return f.failf(argNode, "%s is not a subtype of int, float, or double",
+ type.toChars());
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckInternalCall(FunctionValidator<Unit>& f, ParseNode* callNode,
+ TaggedParserAtomIndex calleeName, Type ret,
+ Type* type) {
+ MOZ_ASSERT(ret.isCanonical());
+
+ ValTypeVector args;
+ if (!CheckCallArgs<CheckIsArgType>(f, callNode, &args)) {
+ return false;
+ }
+
+ ValTypeVector results;
+ Maybe<ValType> retType = ret.canonicalToReturnType();
+ if (retType && !results.append(retType.ref())) {
+ return false;
+ }
+
+ FuncType sig(std::move(args), std::move(results));
+
+ ModuleValidatorShared::Func* callee;
+ if (!CheckFunctionSignature(f.m(), callNode, std::move(sig), calleeName,
+ &callee)) {
+ return false;
+ }
+
+ if (!f.writeCall(callNode, MozOp::OldCallDirect)) {
+ return false;
+ }
+
+ if (!f.encoder().writeVarU32(callee->funcDefIndex())) {
+ return false;
+ }
+
+ *type = Type::ret(ret);
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFuncPtrTableAgainstExisting(ModuleValidator<Unit>& m,
+ ParseNode* usepn,
+ TaggedParserAtomIndex name,
+ FuncType&& sig, unsigned mask,
+ uint32_t* tableIndex) {
+ if (const ModuleValidatorShared::Global* existing = m.lookupGlobal(name)) {
+ if (existing->which() != ModuleValidatorShared::Global::Table) {
+ return m.failName(usepn, "'%s' is not a function-pointer table", name);
+ }
+
+ ModuleValidatorShared::Table& table = m.table(existing->tableIndex());
+ if (mask != table.mask()) {
+ return m.failf(usepn, "mask does not match previous value (%u)",
+ table.mask());
+ }
+
+ if (!CheckSignatureAgainstExisting(
+ m, usepn, sig, m.env().types->type(table.sigIndex()).funcType())) {
+ return false;
+ }
+
+ *tableIndex = existing->tableIndex();
+ return true;
+ }
+
+ if (!CheckModuleLevelName(m, usepn, name)) {
+ return false;
+ }
+
+ if (!m.declareFuncPtrTable(std::move(sig), name, usepn->pn_pos.begin, mask,
+ tableIndex)) {
+ return false;
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFuncPtrCall(FunctionValidator<Unit>& f, ParseNode* callNode,
+ Type ret, Type* type) {
+ MOZ_ASSERT(ret.isCanonical());
+
+ ParseNode* callee = CallCallee(callNode);
+ ParseNode* tableNode = ElemBase(callee);
+ ParseNode* indexExpr = ElemIndex(callee);
+
+ if (!tableNode->isKind(ParseNodeKind::Name)) {
+ return f.fail(tableNode, "expecting name of function-pointer array");
+ }
+
+ TaggedParserAtomIndex name = tableNode->as<NameNode>().name();
+ if (const ModuleValidatorShared::Global* existing = f.lookupGlobal(name)) {
+ if (existing->which() != ModuleValidatorShared::Global::Table) {
+ return f.failName(
+ tableNode, "'%s' is not the name of a function-pointer array", name);
+ }
+ }
+
+ if (!indexExpr->isKind(ParseNodeKind::BitAndExpr)) {
+ return f.fail(indexExpr,
+ "function-pointer table index expression needs & mask");
+ }
+
+ ParseNode* indexNode = BitwiseLeft(indexExpr);
+ ParseNode* maskNode = BitwiseRight(indexExpr);
+
+ uint32_t mask;
+ if (!IsLiteralInt(f.m(), maskNode, &mask) || mask == UINT32_MAX ||
+ !IsPowerOfTwo(mask + 1)) {
+ return f.fail(maskNode,
+ "function-pointer table index mask value must be a power of "
+ "two minus 1");
+ }
+
+ Type indexType;
+ if (!CheckExpr(f, indexNode, &indexType)) {
+ return false;
+ }
+
+ if (!indexType.isIntish()) {
+ return f.failf(indexNode, "%s is not a subtype of intish",
+ indexType.toChars());
+ }
+
+ ValTypeVector args;
+ if (!CheckCallArgs<CheckIsArgType>(f, callNode, &args)) {
+ return false;
+ }
+
+ ValTypeVector results;
+ Maybe<ValType> retType = ret.canonicalToReturnType();
+ if (retType && !results.append(retType.ref())) {
+ return false;
+ }
+
+ FuncType sig(std::move(args), std::move(results));
+
+ uint32_t tableIndex;
+ if (!CheckFuncPtrTableAgainstExisting(f.m(), tableNode, name, std::move(sig),
+ mask, &tableIndex)) {
+ return false;
+ }
+
+ if (!f.writeCall(callNode, MozOp::OldCallIndirect)) {
+ return false;
+ }
+
+ // Call signature
+ if (!f.encoder().writeVarU32(f.m().table(tableIndex).sigIndex())) {
+ return false;
+ }
+
+ *type = Type::ret(ret);
+ return true;
+}
+
+static bool CheckIsExternType(FunctionValidatorShared& f, ParseNode* argNode,
+ Type type) {
+ if (!type.isExtern()) {
+ return f.failf(argNode, "%s is not a subtype of extern", type.toChars());
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFFICall(FunctionValidator<Unit>& f, ParseNode* callNode,
+ unsigned ffiIndex, Type ret, Type* type) {
+ MOZ_ASSERT(ret.isCanonical());
+
+ TaggedParserAtomIndex calleeName =
+ CallCallee(callNode)->as<NameNode>().name();
+
+ if (ret.isFloat()) {
+ return f.fail(callNode, "FFI calls can't return float");
+ }
+
+ ValTypeVector args;
+ if (!CheckCallArgs<CheckIsExternType>(f, callNode, &args)) {
+ return false;
+ }
+
+ ValTypeVector results;
+ Maybe<ValType> retType = ret.canonicalToReturnType();
+ if (retType && !results.append(retType.ref())) {
+ return false;
+ }
+
+ FuncType sig(std::move(args), std::move(results));
+
+ uint32_t importIndex;
+ if (!f.m().declareImport(calleeName, std::move(sig), ffiIndex,
+ &importIndex)) {
+ return false;
+ }
+
+ if (!f.writeCall(callNode, Op::Call)) {
+ return false;
+ }
+
+ if (!f.encoder().writeVarU32(importIndex)) {
+ return false;
+ }
+
+ *type = Type::ret(ret);
+ return true;
+}
+
+static bool CheckFloatCoercionArg(FunctionValidatorShared& f,
+ ParseNode* inputNode, Type inputType) {
+ if (inputType.isMaybeDouble()) {
+ return f.encoder().writeOp(Op::F32DemoteF64);
+ }
+ if (inputType.isSigned()) {
+ return f.encoder().writeOp(Op::F32ConvertI32S);
+ }
+ if (inputType.isUnsigned()) {
+ return f.encoder().writeOp(Op::F32ConvertI32U);
+ }
+ if (inputType.isFloatish()) {
+ return true;
+ }
+
+ return f.failf(inputNode,
+ "%s is not a subtype of signed, unsigned, double? or floatish",
+ inputType.toChars());
+}
+
+template <typename Unit>
+static bool CheckCoercedCall(FunctionValidator<Unit>& f, ParseNode* call,
+ Type ret, Type* type);
+
+template <typename Unit>
+static bool CheckCoercionArg(FunctionValidator<Unit>& f, ParseNode* arg,
+ Type expected, Type* type) {
+ MOZ_ASSERT(expected.isCanonicalValType());
+
+ if (arg->isKind(ParseNodeKind::CallExpr)) {
+ return CheckCoercedCall(f, arg, expected, type);
+ }
+
+ Type argType;
+ if (!CheckExpr(f, arg, &argType)) {
+ return false;
+ }
+
+ if (expected.isFloat()) {
+ if (!CheckFloatCoercionArg(f, arg, argType)) {
+ return false;
+ }
+ } else {
+ MOZ_CRASH("not call coercions");
+ }
+
+ *type = Type::ret(expected);
+ return true;
+}
+
+template <typename Unit>
+static bool CheckMathFRound(FunctionValidator<Unit>& f, ParseNode* callNode,
+ Type* type) {
+ if (CallArgListLength(callNode) != 1) {
+ return f.fail(callNode, "Math.fround must be passed 1 argument");
+ }
+
+ ParseNode* argNode = CallArgList(callNode);
+ Type argType;
+ if (!CheckCoercionArg(f, argNode, Type::Float, &argType)) {
+ return false;
+ }
+
+ MOZ_ASSERT(argType == Type::Float);
+ *type = Type::Float;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckMathBuiltinCall(FunctionValidator<Unit>& f,
+ ParseNode* callNode,
+ AsmJSMathBuiltinFunction func, Type* type) {
+ unsigned arity = 0;
+ Op f32 = Op::Limit;
+ Op f64 = Op::Limit;
+ MozOp mozf64 = MozOp::Limit;
+ switch (func) {
+ case AsmJSMathBuiltin_imul:
+ return CheckMathIMul(f, callNode, type);
+ case AsmJSMathBuiltin_clz32:
+ return CheckMathClz32(f, callNode, type);
+ case AsmJSMathBuiltin_abs:
+ return CheckMathAbs(f, callNode, type);
+ case AsmJSMathBuiltin_sqrt:
+ return CheckMathSqrt(f, callNode, type);
+ case AsmJSMathBuiltin_fround:
+ return CheckMathFRound(f, callNode, type);
+ case AsmJSMathBuiltin_min:
+ return CheckMathMinMax(f, callNode, /* isMax = */ false, type);
+ case AsmJSMathBuiltin_max:
+ return CheckMathMinMax(f, callNode, /* isMax = */ true, type);
+ case AsmJSMathBuiltin_ceil:
+ arity = 1;
+ f64 = Op::F64Ceil;
+ f32 = Op::F32Ceil;
+ break;
+ case AsmJSMathBuiltin_floor:
+ arity = 1;
+ f64 = Op::F64Floor;
+ f32 = Op::F32Floor;
+ break;
+ case AsmJSMathBuiltin_sin:
+ arity = 1;
+ if (!f.m().shouldResistFingerprinting()) {
+ mozf64 = MozOp::F64SinNative;
+ } else {
+ mozf64 = MozOp::F64SinFdlibm;
+ }
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_cos:
+ arity = 1;
+ if (!f.m().shouldResistFingerprinting()) {
+ mozf64 = MozOp::F64CosNative;
+ } else {
+ mozf64 = MozOp::F64CosFdlibm;
+ }
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_tan:
+ arity = 1;
+ if (!f.m().shouldResistFingerprinting()) {
+ mozf64 = MozOp::F64TanNative;
+ } else {
+ mozf64 = MozOp::F64TanFdlibm;
+ }
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_asin:
+ arity = 1;
+ mozf64 = MozOp::F64Asin;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_acos:
+ arity = 1;
+ mozf64 = MozOp::F64Acos;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_atan:
+ arity = 1;
+ mozf64 = MozOp::F64Atan;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_exp:
+ arity = 1;
+ mozf64 = MozOp::F64Exp;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_log:
+ arity = 1;
+ mozf64 = MozOp::F64Log;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_pow:
+ arity = 2;
+ mozf64 = MozOp::F64Pow;
+ f32 = Op::Unreachable;
+ break;
+ case AsmJSMathBuiltin_atan2:
+ arity = 2;
+ mozf64 = MozOp::F64Atan2;
+ f32 = Op::Unreachable;
+ break;
+ default:
+ MOZ_CRASH("unexpected mathBuiltin function");
+ }
+
+ unsigned actualArity = CallArgListLength(callNode);
+ if (actualArity != arity) {
+ return f.failf(callNode, "call passed %u arguments, expected %u",
+ actualArity, arity);
+ }
+
+ if (!f.prepareCall(callNode)) {
+ return false;
+ }
+
+ Type firstType;
+ ParseNode* argNode = CallArgList(callNode);
+ if (!CheckExpr(f, argNode, &firstType)) {
+ return false;
+ }
+
+ if (!firstType.isMaybeFloat() && !firstType.isMaybeDouble()) {
+ return f.fail(
+ argNode,
+ "arguments to math call should be a subtype of double? or float?");
+ }
+
+ bool opIsDouble = firstType.isMaybeDouble();
+ if (!opIsDouble && f32 == Op::Unreachable) {
+ return f.fail(callNode, "math builtin cannot be used as float");
+ }
+
+ if (arity == 2) {
+ Type secondType;
+ argNode = NextNode(argNode);
+ if (!CheckExpr(f, argNode, &secondType)) {
+ return false;
+ }
+
+ if (firstType.isMaybeDouble() && !secondType.isMaybeDouble()) {
+ return f.fail(
+ argNode,
+ "both arguments to math builtin call should be the same type");
+ }
+ if (firstType.isMaybeFloat() && !secondType.isMaybeFloat()) {
+ return f.fail(
+ argNode,
+ "both arguments to math builtin call should be the same type");
+ }
+ }
+
+ if (opIsDouble) {
+ if (f64 != Op::Limit) {
+ if (!f.encoder().writeOp(f64)) {
+ return false;
+ }
+ } else {
+ if (!f.encoder().writeOp(mozf64)) {
+ return false;
+ }
+ }
+ } else {
+ if (!f.encoder().writeOp(f32)) {
+ return false;
+ }
+ }
+
+ *type = opIsDouble ? Type::Double : Type::Floatish;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckUncoercedCall(FunctionValidator<Unit>& f, ParseNode* expr,
+ Type* type) {
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::CallExpr));
+
+ const ModuleValidatorShared::Global* global;
+ if (IsCallToGlobal(f.m(), expr, &global) && global->isMathFunction()) {
+ return CheckMathBuiltinCall(f, expr, global->mathBuiltinFunction(), type);
+ }
+
+ return f.fail(
+ expr,
+ "all function calls must be calls to standard lib math functions,"
+ " ignored (via f(); or comma-expression), coerced to signed (via f()|0),"
+ " coerced to float (via fround(f())), or coerced to double (via +f())");
+}
+
+static bool CoerceResult(FunctionValidatorShared& f, ParseNode* expr,
+ Type expected, Type actual, Type* type) {
+ MOZ_ASSERT(expected.isCanonical());
+
+ // At this point, the bytecode resembles this:
+ // | the thing we wanted to coerce | current position |>
+ switch (expected.which()) {
+ case Type::Void:
+ if (!actual.isVoid()) {
+ if (!f.encoder().writeOp(Op::Drop)) {
+ return false;
+ }
+ }
+ break;
+ case Type::Int:
+ if (!actual.isIntish()) {
+ return f.failf(expr, "%s is not a subtype of intish", actual.toChars());
+ }
+ break;
+ case Type::Float:
+ if (!CheckFloatCoercionArg(f, expr, actual)) {
+ return false;
+ }
+ break;
+ case Type::Double:
+ if (actual.isMaybeDouble()) {
+ // No conversion necessary.
+ } else if (actual.isMaybeFloat()) {
+ if (!f.encoder().writeOp(Op::F64PromoteF32)) {
+ return false;
+ }
+ } else if (actual.isSigned()) {
+ if (!f.encoder().writeOp(Op::F64ConvertI32S)) {
+ return false;
+ }
+ } else if (actual.isUnsigned()) {
+ if (!f.encoder().writeOp(Op::F64ConvertI32U)) {
+ return false;
+ }
+ } else {
+ return f.failf(
+ expr, "%s is not a subtype of double?, float?, signed or unsigned",
+ actual.toChars());
+ }
+ break;
+ default:
+ MOZ_CRASH("unexpected uncoerced result type");
+ }
+
+ *type = Type::ret(expected);
+ return true;
+}
+
+template <typename Unit>
+static bool CheckCoercedMathBuiltinCall(FunctionValidator<Unit>& f,
+ ParseNode* callNode,
+ AsmJSMathBuiltinFunction func, Type ret,
+ Type* type) {
+ Type actual;
+ if (!CheckMathBuiltinCall(f, callNode, func, &actual)) {
+ return false;
+ }
+ return CoerceResult(f, callNode, ret, actual, type);
+}
+
+template <typename Unit>
+static bool CheckCoercedCall(FunctionValidator<Unit>& f, ParseNode* call,
+ Type ret, Type* type) {
+ MOZ_ASSERT(ret.isCanonical());
+
+ AutoCheckRecursionLimit recursion(f.fc());
+ if (!recursion.checkDontReport(f.fc())) {
+ return f.m().failOverRecursed();
+ }
+
+ if (IsNumericLiteral(f.m(), call)) {
+ NumLit lit = ExtractNumericLiteral(f.m(), call);
+ if (!f.writeConstExpr(lit)) {
+ return false;
+ }
+ return CoerceResult(f, call, ret, Type::lit(lit), type);
+ }
+
+ ParseNode* callee = CallCallee(call);
+
+ if (callee->isKind(ParseNodeKind::ElemExpr)) {
+ return CheckFuncPtrCall(f, call, ret, type);
+ }
+
+ if (!callee->isKind(ParseNodeKind::Name)) {
+ return f.fail(callee, "unexpected callee expression type");
+ }
+
+ TaggedParserAtomIndex calleeName = callee->as<NameNode>().name();
+
+ if (const ModuleValidatorShared::Global* global =
+ f.lookupGlobal(calleeName)) {
+ switch (global->which()) {
+ case ModuleValidatorShared::Global::FFI:
+ return CheckFFICall(f, call, global->ffiIndex(), ret, type);
+ case ModuleValidatorShared::Global::MathBuiltinFunction:
+ return CheckCoercedMathBuiltinCall(
+ f, call, global->mathBuiltinFunction(), ret, type);
+ case ModuleValidatorShared::Global::ConstantLiteral:
+ case ModuleValidatorShared::Global::ConstantImport:
+ case ModuleValidatorShared::Global::Variable:
+ case ModuleValidatorShared::Global::Table:
+ case ModuleValidatorShared::Global::ArrayView:
+ case ModuleValidatorShared::Global::ArrayViewCtor:
+ return f.failName(callee, "'%s' is not callable function", calleeName);
+ case ModuleValidatorShared::Global::Function:
+ break;
+ }
+ }
+
+ return CheckInternalCall(f, call, calleeName, ret, type);
+}
+
+template <typename Unit>
+static bool CheckPos(FunctionValidator<Unit>& f, ParseNode* pos, Type* type) {
+ MOZ_ASSERT(pos->isKind(ParseNodeKind::PosExpr));
+ ParseNode* operand = UnaryKid(pos);
+
+ if (operand->isKind(ParseNodeKind::CallExpr)) {
+ return CheckCoercedCall(f, operand, Type::Double, type);
+ }
+
+ Type actual;
+ if (!CheckExpr(f, operand, &actual)) {
+ return false;
+ }
+
+ return CoerceResult(f, operand, Type::Double, actual, type);
+}
+
+template <typename Unit>
+static bool CheckNot(FunctionValidator<Unit>& f, ParseNode* expr, Type* type) {
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::NotExpr));
+ ParseNode* operand = UnaryKid(expr);
+
+ Type operandType;
+ if (!CheckExpr(f, operand, &operandType)) {
+ return false;
+ }
+
+ if (!operandType.isInt()) {
+ return f.failf(operand, "%s is not a subtype of int",
+ operandType.toChars());
+ }
+
+ *type = Type::Int;
+ return f.encoder().writeOp(Op::I32Eqz);
+}
+
+template <typename Unit>
+static bool CheckNeg(FunctionValidator<Unit>& f, ParseNode* expr, Type* type) {
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::NegExpr));
+ ParseNode* operand = UnaryKid(expr);
+
+ Type operandType;
+ if (!CheckExpr(f, operand, &operandType)) {
+ return false;
+ }
+
+ if (operandType.isInt()) {
+ *type = Type::Intish;
+ return f.encoder().writeOp(MozOp::I32Neg);
+ }
+
+ if (operandType.isMaybeDouble()) {
+ *type = Type::Double;
+ return f.encoder().writeOp(Op::F64Neg);
+ }
+
+ if (operandType.isMaybeFloat()) {
+ *type = Type::Floatish;
+ return f.encoder().writeOp(Op::F32Neg);
+ }
+
+ return f.failf(operand, "%s is not a subtype of int, float? or double?",
+ operandType.toChars());
+}
+
+template <typename Unit>
+static bool CheckCoerceToInt(FunctionValidator<Unit>& f, ParseNode* expr,
+ Type* type) {
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::BitNotExpr));
+ ParseNode* operand = UnaryKid(expr);
+
+ Type operandType;
+ if (!CheckExpr(f, operand, &operandType)) {
+ return false;
+ }
+
+ if (operandType.isMaybeDouble() || operandType.isMaybeFloat()) {
+ *type = Type::Signed;
+ Op opcode =
+ operandType.isMaybeDouble() ? Op::I32TruncF64S : Op::I32TruncF32S;
+ return f.encoder().writeOp(opcode);
+ }
+
+ if (!operandType.isIntish()) {
+ return f.failf(operand, "%s is not a subtype of double?, float? or intish",
+ operandType.toChars());
+ }
+
+ *type = Type::Signed;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckBitNot(FunctionValidator<Unit>& f, ParseNode* neg,
+ Type* type) {
+ MOZ_ASSERT(neg->isKind(ParseNodeKind::BitNotExpr));
+ ParseNode* operand = UnaryKid(neg);
+
+ if (operand->isKind(ParseNodeKind::BitNotExpr)) {
+ return CheckCoerceToInt(f, operand, type);
+ }
+
+ Type operandType;
+ if (!CheckExpr(f, operand, &operandType)) {
+ return false;
+ }
+
+ if (!operandType.isIntish()) {
+ return f.failf(operand, "%s is not a subtype of intish",
+ operandType.toChars());
+ }
+
+ if (!f.encoder().writeOp(MozOp::I32BitNot)) {
+ return false;
+ }
+
+ *type = Type::Signed;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckAsExprStatement(FunctionValidator<Unit>& f,
+ ParseNode* exprStmt);
+
+template <typename Unit>
+static bool CheckComma(FunctionValidator<Unit>& f, ParseNode* comma,
+ Type* type) {
+ MOZ_ASSERT(comma->isKind(ParseNodeKind::CommaExpr));
+ ParseNode* operands = ListHead(comma);
+
+ // The block depth isn't taken into account here, because a comma list can't
+ // contain breaks and continues and nested control flow structures.
+ if (!f.encoder().writeOp(Op::Block)) {
+ return false;
+ }
+
+ size_t typeAt;
+ if (!f.encoder().writePatchableFixedU7(&typeAt)) {
+ return false;
+ }
+
+ ParseNode* pn = operands;
+ for (; NextNode(pn); pn = NextNode(pn)) {
+ if (!CheckAsExprStatement(f, pn)) {
+ return false;
+ }
+ }
+
+ if (!CheckExpr(f, pn, type)) {
+ return false;
+ }
+
+ f.encoder().patchFixedU7(typeAt, uint8_t(type->toWasmBlockSignatureType()));
+
+ return f.encoder().writeOp(Op::End);
+}
+
+template <typename Unit>
+static bool CheckConditional(FunctionValidator<Unit>& f, ParseNode* ternary,
+ Type* type) {
+ MOZ_ASSERT(ternary->isKind(ParseNodeKind::ConditionalExpr));
+
+ ParseNode* cond = TernaryKid1(ternary);
+ ParseNode* thenExpr = TernaryKid2(ternary);
+ ParseNode* elseExpr = TernaryKid3(ternary);
+
+ Type condType;
+ if (!CheckExpr(f, cond, &condType)) {
+ return false;
+ }
+
+ if (!condType.isInt()) {
+ return f.failf(cond, "%s is not a subtype of int", condType.toChars());
+ }
+
+ size_t typeAt;
+ if (!f.pushIf(&typeAt)) {
+ return false;
+ }
+
+ Type thenType;
+ if (!CheckExpr(f, thenExpr, &thenType)) {
+ return false;
+ }
+
+ if (!f.switchToElse()) {
+ return false;
+ }
+
+ Type elseType;
+ if (!CheckExpr(f, elseExpr, &elseType)) {
+ return false;
+ }
+
+ if (thenType.isInt() && elseType.isInt()) {
+ *type = Type::Int;
+ } else if (thenType.isDouble() && elseType.isDouble()) {
+ *type = Type::Double;
+ } else if (thenType.isFloat() && elseType.isFloat()) {
+ *type = Type::Float;
+ } else {
+ return f.failf(
+ ternary,
+ "then/else branches of conditional must both produce int, float, "
+ "double, current types are %s and %s",
+ thenType.toChars(), elseType.toChars());
+ }
+
+ if (!f.popIf(typeAt, type->toWasmBlockSignatureType())) {
+ return false;
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool IsValidIntMultiplyConstant(ModuleValidator<Unit>& m,
+ ParseNode* expr) {
+ if (!IsNumericLiteral(m, expr)) {
+ return false;
+ }
+
+ NumLit lit = ExtractNumericLiteral(m, expr);
+ switch (lit.which()) {
+ case NumLit::Fixnum:
+ case NumLit::NegativeInt:
+ if (Abs(lit.toInt32()) < (uint32_t(1) << 20)) {
+ return true;
+ }
+ return false;
+ case NumLit::BigUnsigned:
+ case NumLit::Double:
+ case NumLit::Float:
+ case NumLit::OutOfRangeInt:
+ return false;
+ }
+
+ MOZ_CRASH("Bad literal");
+}
+
+template <typename Unit>
+static bool CheckMultiply(FunctionValidator<Unit>& f, ParseNode* star,
+ Type* type) {
+ MOZ_ASSERT(star->isKind(ParseNodeKind::MulExpr));
+ ParseNode* lhs = MultiplyLeft(star);
+ ParseNode* rhs = MultiplyRight(star);
+
+ Type lhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (lhsType.isInt() && rhsType.isInt()) {
+ if (!IsValidIntMultiplyConstant(f.m(), lhs) &&
+ !IsValidIntMultiplyConstant(f.m(), rhs)) {
+ return f.fail(
+ star,
+ "one arg to int multiply must be a small (-2^20, 2^20) int literal");
+ }
+ *type = Type::Intish;
+ return f.encoder().writeOp(Op::I32Mul);
+ }
+
+ if (lhsType.isMaybeDouble() && rhsType.isMaybeDouble()) {
+ *type = Type::Double;
+ return f.encoder().writeOp(Op::F64Mul);
+ }
+
+ if (lhsType.isMaybeFloat() && rhsType.isMaybeFloat()) {
+ *type = Type::Floatish;
+ return f.encoder().writeOp(Op::F32Mul);
+ }
+
+ return f.fail(
+ star, "multiply operands must be both int, both double? or both float?");
+}
+
+template <typename Unit>
+static bool CheckAddOrSub(FunctionValidator<Unit>& f, ParseNode* expr,
+ Type* type, unsigned* numAddOrSubOut = nullptr) {
+ AutoCheckRecursionLimit recursion(f.fc());
+ if (!recursion.checkDontReport(f.fc())) {
+ return f.m().failOverRecursed();
+ }
+
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::AddExpr) ||
+ expr->isKind(ParseNodeKind::SubExpr));
+ ParseNode* lhs = AddSubLeft(expr);
+ ParseNode* rhs = AddSubRight(expr);
+
+ Type lhsType, rhsType;
+ unsigned lhsNumAddOrSub, rhsNumAddOrSub;
+
+ if (lhs->isKind(ParseNodeKind::AddExpr) ||
+ lhs->isKind(ParseNodeKind::SubExpr)) {
+ if (!CheckAddOrSub(f, lhs, &lhsType, &lhsNumAddOrSub)) {
+ return false;
+ }
+ if (lhsType == Type::Intish) {
+ lhsType = Type::Int;
+ }
+ } else {
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+ lhsNumAddOrSub = 0;
+ }
+
+ if (rhs->isKind(ParseNodeKind::AddExpr) ||
+ rhs->isKind(ParseNodeKind::SubExpr)) {
+ if (!CheckAddOrSub(f, rhs, &rhsType, &rhsNumAddOrSub)) {
+ return false;
+ }
+ if (rhsType == Type::Intish) {
+ rhsType = Type::Int;
+ }
+ } else {
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+ rhsNumAddOrSub = 0;
+ }
+
+ unsigned numAddOrSub = lhsNumAddOrSub + rhsNumAddOrSub + 1;
+ if (numAddOrSub > (1 << 20)) {
+ return f.fail(expr, "too many + or - without intervening coercion");
+ }
+
+ if (lhsType.isInt() && rhsType.isInt()) {
+ if (!f.encoder().writeOp(
+ expr->isKind(ParseNodeKind::AddExpr) ? Op::I32Add : Op::I32Sub)) {
+ return false;
+ }
+ *type = Type::Intish;
+ } else if (lhsType.isMaybeDouble() && rhsType.isMaybeDouble()) {
+ if (!f.encoder().writeOp(
+ expr->isKind(ParseNodeKind::AddExpr) ? Op::F64Add : Op::F64Sub)) {
+ return false;
+ }
+ *type = Type::Double;
+ } else if (lhsType.isMaybeFloat() && rhsType.isMaybeFloat()) {
+ if (!f.encoder().writeOp(
+ expr->isKind(ParseNodeKind::AddExpr) ? Op::F32Add : Op::F32Sub)) {
+ return false;
+ }
+ *type = Type::Floatish;
+ } else {
+ return f.failf(
+ expr,
+ "operands to + or - must both be int, float? or double?, got %s and %s",
+ lhsType.toChars(), rhsType.toChars());
+ }
+
+ if (numAddOrSubOut) {
+ *numAddOrSubOut = numAddOrSub;
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckDivOrMod(FunctionValidator<Unit>& f, ParseNode* expr,
+ Type* type) {
+ MOZ_ASSERT(expr->isKind(ParseNodeKind::DivExpr) ||
+ expr->isKind(ParseNodeKind::ModExpr));
+
+ ParseNode* lhs = DivOrModLeft(expr);
+ ParseNode* rhs = DivOrModRight(expr);
+
+ Type lhsType, rhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (lhsType.isMaybeDouble() && rhsType.isMaybeDouble()) {
+ *type = Type::Double;
+ if (expr->isKind(ParseNodeKind::DivExpr)) {
+ return f.encoder().writeOp(Op::F64Div);
+ }
+ return f.encoder().writeOp(MozOp::F64Mod);
+ }
+
+ if (lhsType.isMaybeFloat() && rhsType.isMaybeFloat()) {
+ *type = Type::Floatish;
+ if (expr->isKind(ParseNodeKind::DivExpr)) {
+ return f.encoder().writeOp(Op::F32Div);
+ }
+ return f.fail(expr, "modulo cannot receive float arguments");
+ }
+
+ if (lhsType.isSigned() && rhsType.isSigned()) {
+ *type = Type::Intish;
+ return f.encoder().writeOp(
+ expr->isKind(ParseNodeKind::DivExpr) ? Op::I32DivS : Op::I32RemS);
+ }
+
+ if (lhsType.isUnsigned() && rhsType.isUnsigned()) {
+ *type = Type::Intish;
+ return f.encoder().writeOp(
+ expr->isKind(ParseNodeKind::DivExpr) ? Op::I32DivU : Op::I32RemU);
+ }
+
+ return f.failf(
+ expr,
+ "arguments to / or %% must both be double?, float?, signed, or unsigned; "
+ "%s and %s are given",
+ lhsType.toChars(), rhsType.toChars());
+}
+
+template <typename Unit>
+static bool CheckComparison(FunctionValidator<Unit>& f, ParseNode* comp,
+ Type* type) {
+ MOZ_ASSERT(comp->isKind(ParseNodeKind::LtExpr) ||
+ comp->isKind(ParseNodeKind::LeExpr) ||
+ comp->isKind(ParseNodeKind::GtExpr) ||
+ comp->isKind(ParseNodeKind::GeExpr) ||
+ comp->isKind(ParseNodeKind::EqExpr) ||
+ comp->isKind(ParseNodeKind::NeExpr));
+
+ ParseNode* lhs = ComparisonLeft(comp);
+ ParseNode* rhs = ComparisonRight(comp);
+
+ Type lhsType, rhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (!(lhsType.isSigned() && rhsType.isSigned()) &&
+ !(lhsType.isUnsigned() && rhsType.isUnsigned()) &&
+ !(lhsType.isDouble() && rhsType.isDouble()) &&
+ !(lhsType.isFloat() && rhsType.isFloat())) {
+ return f.failf(comp,
+ "arguments to a comparison must both be signed, unsigned, "
+ "floats or doubles; "
+ "%s and %s are given",
+ lhsType.toChars(), rhsType.toChars());
+ }
+
+ Op stmt;
+ if (lhsType.isSigned() && rhsType.isSigned()) {
+ switch (comp->getKind()) {
+ case ParseNodeKind::EqExpr:
+ stmt = Op::I32Eq;
+ break;
+ case ParseNodeKind::NeExpr:
+ stmt = Op::I32Ne;
+ break;
+ case ParseNodeKind::LtExpr:
+ stmt = Op::I32LtS;
+ break;
+ case ParseNodeKind::LeExpr:
+ stmt = Op::I32LeS;
+ break;
+ case ParseNodeKind::GtExpr:
+ stmt = Op::I32GtS;
+ break;
+ case ParseNodeKind::GeExpr:
+ stmt = Op::I32GeS;
+ break;
+ default:
+ MOZ_CRASH("unexpected comparison op");
+ }
+ } else if (lhsType.isUnsigned() && rhsType.isUnsigned()) {
+ switch (comp->getKind()) {
+ case ParseNodeKind::EqExpr:
+ stmt = Op::I32Eq;
+ break;
+ case ParseNodeKind::NeExpr:
+ stmt = Op::I32Ne;
+ break;
+ case ParseNodeKind::LtExpr:
+ stmt = Op::I32LtU;
+ break;
+ case ParseNodeKind::LeExpr:
+ stmt = Op::I32LeU;
+ break;
+ case ParseNodeKind::GtExpr:
+ stmt = Op::I32GtU;
+ break;
+ case ParseNodeKind::GeExpr:
+ stmt = Op::I32GeU;
+ break;
+ default:
+ MOZ_CRASH("unexpected comparison op");
+ }
+ } else if (lhsType.isDouble()) {
+ switch (comp->getKind()) {
+ case ParseNodeKind::EqExpr:
+ stmt = Op::F64Eq;
+ break;
+ case ParseNodeKind::NeExpr:
+ stmt = Op::F64Ne;
+ break;
+ case ParseNodeKind::LtExpr:
+ stmt = Op::F64Lt;
+ break;
+ case ParseNodeKind::LeExpr:
+ stmt = Op::F64Le;
+ break;
+ case ParseNodeKind::GtExpr:
+ stmt = Op::F64Gt;
+ break;
+ case ParseNodeKind::GeExpr:
+ stmt = Op::F64Ge;
+ break;
+ default:
+ MOZ_CRASH("unexpected comparison op");
+ }
+ } else if (lhsType.isFloat()) {
+ switch (comp->getKind()) {
+ case ParseNodeKind::EqExpr:
+ stmt = Op::F32Eq;
+ break;
+ case ParseNodeKind::NeExpr:
+ stmt = Op::F32Ne;
+ break;
+ case ParseNodeKind::LtExpr:
+ stmt = Op::F32Lt;
+ break;
+ case ParseNodeKind::LeExpr:
+ stmt = Op::F32Le;
+ break;
+ case ParseNodeKind::GtExpr:
+ stmt = Op::F32Gt;
+ break;
+ case ParseNodeKind::GeExpr:
+ stmt = Op::F32Ge;
+ break;
+ default:
+ MOZ_CRASH("unexpected comparison op");
+ }
+ } else {
+ MOZ_CRASH("unexpected type");
+ }
+
+ *type = Type::Int;
+ return f.encoder().writeOp(stmt);
+}
+
+template <typename Unit>
+static bool CheckBitwise(FunctionValidator<Unit>& f, ParseNode* bitwise,
+ Type* type) {
+ ParseNode* lhs = BitwiseLeft(bitwise);
+ ParseNode* rhs = BitwiseRight(bitwise);
+
+ int32_t identityElement;
+ bool onlyOnRight;
+ switch (bitwise->getKind()) {
+ case ParseNodeKind::BitOrExpr:
+ identityElement = 0;
+ onlyOnRight = false;
+ *type = Type::Signed;
+ break;
+ case ParseNodeKind::BitAndExpr:
+ identityElement = -1;
+ onlyOnRight = false;
+ *type = Type::Signed;
+ break;
+ case ParseNodeKind::BitXorExpr:
+ identityElement = 0;
+ onlyOnRight = false;
+ *type = Type::Signed;
+ break;
+ case ParseNodeKind::LshExpr:
+ identityElement = 0;
+ onlyOnRight = true;
+ *type = Type::Signed;
+ break;
+ case ParseNodeKind::RshExpr:
+ identityElement = 0;
+ onlyOnRight = true;
+ *type = Type::Signed;
+ break;
+ case ParseNodeKind::UrshExpr:
+ identityElement = 0;
+ onlyOnRight = true;
+ *type = Type::Unsigned;
+ break;
+ default:
+ MOZ_CRASH("not a bitwise op");
+ }
+
+ uint32_t i;
+ if (!onlyOnRight && IsLiteralInt(f.m(), lhs, &i) &&
+ i == uint32_t(identityElement)) {
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+ if (!rhsType.isIntish()) {
+ return f.failf(bitwise, "%s is not a subtype of intish",
+ rhsType.toChars());
+ }
+ return true;
+ }
+
+ if (IsLiteralInt(f.m(), rhs, &i) && i == uint32_t(identityElement)) {
+ if (bitwise->isKind(ParseNodeKind::BitOrExpr) &&
+ lhs->isKind(ParseNodeKind::CallExpr)) {
+ return CheckCoercedCall(f, lhs, Type::Int, type);
+ }
+
+ Type lhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+ if (!lhsType.isIntish()) {
+ return f.failf(bitwise, "%s is not a subtype of intish",
+ lhsType.toChars());
+ }
+ return true;
+ }
+
+ Type lhsType;
+ if (!CheckExpr(f, lhs, &lhsType)) {
+ return false;
+ }
+
+ Type rhsType;
+ if (!CheckExpr(f, rhs, &rhsType)) {
+ return false;
+ }
+
+ if (!lhsType.isIntish()) {
+ return f.failf(lhs, "%s is not a subtype of intish", lhsType.toChars());
+ }
+ if (!rhsType.isIntish()) {
+ return f.failf(rhs, "%s is not a subtype of intish", rhsType.toChars());
+ }
+
+ switch (bitwise->getKind()) {
+ case ParseNodeKind::BitOrExpr:
+ if (!f.encoder().writeOp(Op::I32Or)) return false;
+ break;
+ case ParseNodeKind::BitAndExpr:
+ if (!f.encoder().writeOp(Op::I32And)) return false;
+ break;
+ case ParseNodeKind::BitXorExpr:
+ if (!f.encoder().writeOp(Op::I32Xor)) return false;
+ break;
+ case ParseNodeKind::LshExpr:
+ if (!f.encoder().writeOp(Op::I32Shl)) return false;
+ break;
+ case ParseNodeKind::RshExpr:
+ if (!f.encoder().writeOp(Op::I32ShrS)) return false;
+ break;
+ case ParseNodeKind::UrshExpr:
+ if (!f.encoder().writeOp(Op::I32ShrU)) return false;
+ break;
+ default:
+ MOZ_CRASH("not a bitwise op");
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckExpr(FunctionValidator<Unit>& f, ParseNode* expr, Type* type) {
+ AutoCheckRecursionLimit recursion(f.fc());
+ if (!recursion.checkDontReport(f.fc())) {
+ return f.m().failOverRecursed();
+ }
+
+ if (IsNumericLiteral(f.m(), expr)) {
+ return CheckNumericLiteral(f, expr, type);
+ }
+
+ switch (expr->getKind()) {
+ case ParseNodeKind::Name:
+ return CheckVarRef(f, expr, type);
+ case ParseNodeKind::ElemExpr:
+ return CheckLoadArray(f, expr, type);
+ case ParseNodeKind::AssignExpr:
+ return CheckAssign(f, expr, type);
+ case ParseNodeKind::PosExpr:
+ return CheckPos(f, expr, type);
+ case ParseNodeKind::NotExpr:
+ return CheckNot(f, expr, type);
+ case ParseNodeKind::NegExpr:
+ return CheckNeg(f, expr, type);
+ case ParseNodeKind::BitNotExpr:
+ return CheckBitNot(f, expr, type);
+ case ParseNodeKind::CommaExpr:
+ return CheckComma(f, expr, type);
+ case ParseNodeKind::ConditionalExpr:
+ return CheckConditional(f, expr, type);
+ case ParseNodeKind::MulExpr:
+ return CheckMultiply(f, expr, type);
+ case ParseNodeKind::CallExpr:
+ return CheckUncoercedCall(f, expr, type);
+
+ case ParseNodeKind::AddExpr:
+ case ParseNodeKind::SubExpr:
+ return CheckAddOrSub(f, expr, type);
+
+ case ParseNodeKind::DivExpr:
+ case ParseNodeKind::ModExpr:
+ return CheckDivOrMod(f, expr, type);
+
+ case ParseNodeKind::LtExpr:
+ case ParseNodeKind::LeExpr:
+ case ParseNodeKind::GtExpr:
+ case ParseNodeKind::GeExpr:
+ case ParseNodeKind::EqExpr:
+ case ParseNodeKind::NeExpr:
+ return CheckComparison(f, expr, type);
+
+ case ParseNodeKind::BitOrExpr:
+ case ParseNodeKind::BitAndExpr:
+ case ParseNodeKind::BitXorExpr:
+ case ParseNodeKind::LshExpr:
+ case ParseNodeKind::RshExpr:
+ case ParseNodeKind::UrshExpr:
+ return CheckBitwise(f, expr, type);
+
+ default:;
+ }
+
+ return f.fail(expr, "unsupported expression");
+}
+
+template <typename Unit>
+static bool CheckStatement(FunctionValidator<Unit>& f, ParseNode* stmt);
+
+template <typename Unit>
+static bool CheckAsExprStatement(FunctionValidator<Unit>& f, ParseNode* expr) {
+ if (expr->isKind(ParseNodeKind::CallExpr)) {
+ Type ignored;
+ return CheckCoercedCall(f, expr, Type::Void, &ignored);
+ }
+
+ Type resultType;
+ if (!CheckExpr(f, expr, &resultType)) {
+ return false;
+ }
+
+ if (!resultType.isVoid()) {
+ if (!f.encoder().writeOp(Op::Drop)) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckExprStatement(FunctionValidator<Unit>& f,
+ ParseNode* exprStmt) {
+ MOZ_ASSERT(exprStmt->isKind(ParseNodeKind::ExpressionStmt));
+ return CheckAsExprStatement(f, UnaryKid(exprStmt));
+}
+
+template <typename Unit>
+static bool CheckLoopConditionOnEntry(FunctionValidator<Unit>& f,
+ ParseNode* cond) {
+ uint32_t maybeLit;
+ if (IsLiteralInt(f.m(), cond, &maybeLit) && maybeLit) {
+ return true;
+ }
+
+ Type condType;
+ if (!CheckExpr(f, cond, &condType)) {
+ return false;
+ }
+ if (!condType.isInt()) {
+ return f.failf(cond, "%s is not a subtype of int", condType.toChars());
+ }
+
+ if (!f.encoder().writeOp(Op::I32Eqz)) {
+ return false;
+ }
+
+ // brIf (i32.eqz $f) $out
+ if (!f.writeBreakIf()) {
+ return false;
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckWhile(FunctionValidator<Unit>& f, ParseNode* whileStmt,
+ const LabelVector* labels = nullptr) {
+ MOZ_ASSERT(whileStmt->isKind(ParseNodeKind::WhileStmt));
+ ParseNode* cond = BinaryLeft(whileStmt);
+ ParseNode* body = BinaryRight(whileStmt);
+
+ // A while loop `while(#cond) #body` is equivalent to:
+ // (block $after_loop
+ // (loop $top
+ // (brIf $after_loop (i32.eq 0 #cond))
+ // #body
+ // (br $top)
+ // )
+ // )
+ if (labels && !f.addLabels(*labels, 0, 1)) {
+ return false;
+ }
+
+ if (!f.pushLoop()) {
+ return false;
+ }
+
+ if (!CheckLoopConditionOnEntry(f, cond)) {
+ return false;
+ }
+ if (!CheckStatement(f, body)) {
+ return false;
+ }
+ if (!f.writeContinue()) {
+ return false;
+ }
+
+ if (!f.popLoop()) {
+ return false;
+ }
+ if (labels) {
+ f.removeLabels(*labels);
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFor(FunctionValidator<Unit>& f, ParseNode* forStmt,
+ const LabelVector* labels = nullptr) {
+ MOZ_ASSERT(forStmt->isKind(ParseNodeKind::ForStmt));
+ ParseNode* forHead = BinaryLeft(forStmt);
+ ParseNode* body = BinaryRight(forStmt);
+
+ if (!forHead->isKind(ParseNodeKind::ForHead)) {
+ return f.fail(forHead, "unsupported for-loop statement");
+ }
+
+ ParseNode* maybeInit = TernaryKid1(forHead);
+ ParseNode* maybeCond = TernaryKid2(forHead);
+ ParseNode* maybeInc = TernaryKid3(forHead);
+
+ // A for-loop `for (#init; #cond; #inc) #body` is equivalent to:
+ // (block // depth X
+ // (#init)
+ // (block $after_loop // depth X+1 (block)
+ // (loop $loop_top // depth X+2 (loop)
+ // (brIf $after (eq 0 #cond))
+ // (block $after_body #body) // depth X+3
+ // #inc
+ // (br $loop_top)
+ // )
+ // )
+ // )
+ // A break in the body should break out to $after_loop, i.e. depth + 1.
+ // A continue in the body should break out to $after_body, i.e. depth + 3.
+ if (labels && !f.addLabels(*labels, 1, 3)) {
+ return false;
+ }
+
+ if (!f.pushUnbreakableBlock()) {
+ return false;
+ }
+
+ if (maybeInit && !CheckAsExprStatement(f, maybeInit)) {
+ return false;
+ }
+
+ {
+ if (!f.pushLoop()) {
+ return false;
+ }
+
+ if (maybeCond && !CheckLoopConditionOnEntry(f, maybeCond)) {
+ return false;
+ }
+
+ {
+ // Continuing in the body should just break out to the increment.
+ if (!f.pushContinuableBlock()) {
+ return false;
+ }
+ if (!CheckStatement(f, body)) {
+ return false;
+ }
+ if (!f.popContinuableBlock()) {
+ return false;
+ }
+ }
+
+ if (maybeInc && !CheckAsExprStatement(f, maybeInc)) {
+ return false;
+ }
+
+ if (!f.writeContinue()) {
+ return false;
+ }
+ if (!f.popLoop()) {
+ return false;
+ }
+ }
+
+ if (!f.popUnbreakableBlock()) {
+ return false;
+ }
+
+ if (labels) {
+ f.removeLabels(*labels);
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckDoWhile(FunctionValidator<Unit>& f, ParseNode* whileStmt,
+ const LabelVector* labels = nullptr) {
+ MOZ_ASSERT(whileStmt->isKind(ParseNodeKind::DoWhileStmt));
+ ParseNode* body = BinaryLeft(whileStmt);
+ ParseNode* cond = BinaryRight(whileStmt);
+
+ // A do-while loop `do { #body } while (#cond)` is equivalent to:
+ // (block $after_loop // depth X
+ // (loop $top // depth X+1
+ // (block #body) // depth X+2
+ // (brIf #cond $top)
+ // )
+ // )
+ // A break should break out of the entire loop, i.e. at depth 0.
+ // A continue should break out to the condition, i.e. at depth 2.
+ if (labels && !f.addLabels(*labels, 0, 2)) {
+ return false;
+ }
+
+ if (!f.pushLoop()) {
+ return false;
+ }
+
+ {
+ // An unlabeled continue in the body should break out to the condition.
+ if (!f.pushContinuableBlock()) {
+ return false;
+ }
+ if (!CheckStatement(f, body)) {
+ return false;
+ }
+ if (!f.popContinuableBlock()) {
+ return false;
+ }
+ }
+
+ Type condType;
+ if (!CheckExpr(f, cond, &condType)) {
+ return false;
+ }
+ if (!condType.isInt()) {
+ return f.failf(cond, "%s is not a subtype of int", condType.toChars());
+ }
+
+ if (!f.writeContinueIf()) {
+ return false;
+ }
+
+ if (!f.popLoop()) {
+ return false;
+ }
+ if (labels) {
+ f.removeLabels(*labels);
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckStatementList(FunctionValidator<Unit>& f, ParseNode*,
+ const LabelVector* = nullptr);
+
+template <typename Unit>
+static bool CheckLabel(FunctionValidator<Unit>& f, ParseNode* labeledStmt) {
+ MOZ_ASSERT(labeledStmt->isKind(ParseNodeKind::LabelStmt));
+
+ LabelVector labels;
+ ParseNode* innermost = labeledStmt;
+ do {
+ if (!labels.append(LabeledStatementLabel(innermost))) {
+ return false;
+ }
+ innermost = LabeledStatementStatement(innermost);
+ } while (innermost->getKind() == ParseNodeKind::LabelStmt);
+
+ switch (innermost->getKind()) {
+ case ParseNodeKind::ForStmt:
+ return CheckFor(f, innermost, &labels);
+ case ParseNodeKind::DoWhileStmt:
+ return CheckDoWhile(f, innermost, &labels);
+ case ParseNodeKind::WhileStmt:
+ return CheckWhile(f, innermost, &labels);
+ case ParseNodeKind::StatementList:
+ return CheckStatementList(f, innermost, &labels);
+ default:
+ break;
+ }
+
+ if (!f.pushUnbreakableBlock(&labels)) {
+ return false;
+ }
+
+ if (!CheckStatement(f, innermost)) {
+ return false;
+ }
+
+ if (!f.popUnbreakableBlock(&labels)) {
+ return false;
+ }
+ return true;
+}
+
+template <typename Unit>
+static bool CheckIf(FunctionValidator<Unit>& f, ParseNode* ifStmt) {
+ uint32_t numIfEnd = 1;
+
+recurse:
+ MOZ_ASSERT(ifStmt->isKind(ParseNodeKind::IfStmt));
+ ParseNode* cond = TernaryKid1(ifStmt);
+ ParseNode* thenStmt = TernaryKid2(ifStmt);
+ ParseNode* elseStmt = TernaryKid3(ifStmt);
+
+ Type condType;
+ if (!CheckExpr(f, cond, &condType)) {
+ return false;
+ }
+ if (!condType.isInt()) {
+ return f.failf(cond, "%s is not a subtype of int", condType.toChars());
+ }
+
+ size_t typeAt;
+ if (!f.pushIf(&typeAt)) {
+ return false;
+ }
+
+ f.setIfType(typeAt, TypeCode::BlockVoid);
+
+ if (!CheckStatement(f, thenStmt)) {
+ return false;
+ }
+
+ if (elseStmt) {
+ if (!f.switchToElse()) {
+ return false;
+ }
+
+ if (elseStmt->isKind(ParseNodeKind::IfStmt)) {
+ ifStmt = elseStmt;
+ if (numIfEnd++ == UINT32_MAX) {
+ return false;
+ }
+ goto recurse;
+ }
+
+ if (!CheckStatement(f, elseStmt)) {
+ return false;
+ }
+ }
+
+ for (uint32_t i = 0; i != numIfEnd; ++i) {
+ if (!f.popIf()) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+static bool CheckCaseExpr(FunctionValidatorShared& f, ParseNode* caseExpr,
+ int32_t* value) {
+ if (!IsNumericLiteral(f.m(), caseExpr)) {
+ return f.fail(caseExpr,
+ "switch case expression must be an integer literal");
+ }
+
+ NumLit lit = ExtractNumericLiteral(f.m(), caseExpr);
+ switch (lit.which()) {
+ case NumLit::Fixnum:
+ case NumLit::NegativeInt:
+ *value = lit.toInt32();
+ break;
+ case NumLit::OutOfRangeInt:
+ case NumLit::BigUnsigned:
+ return f.fail(caseExpr, "switch case expression out of integer range");
+ case NumLit::Double:
+ case NumLit::Float:
+ return f.fail(caseExpr,
+ "switch case expression must be an integer literal");
+ }
+
+ return true;
+}
+
+static bool CheckDefaultAtEnd(FunctionValidatorShared& f, ParseNode* stmt) {
+ for (; stmt; stmt = NextNode(stmt)) {
+ if (IsDefaultCase(stmt) && NextNode(stmt) != nullptr) {
+ return f.fail(stmt, "default label must be at the end");
+ }
+ }
+
+ return true;
+}
+
+static bool CheckSwitchRange(FunctionValidatorShared& f, ParseNode* stmt,
+ int32_t* low, int32_t* high,
+ uint32_t* tableLength) {
+ if (IsDefaultCase(stmt)) {
+ *low = 0;
+ *high = -1;
+ *tableLength = 0;
+ return true;
+ }
+
+ int32_t i = 0;
+ if (!CheckCaseExpr(f, CaseExpr(stmt), &i)) {
+ return false;
+ }
+
+ *low = *high = i;
+
+ ParseNode* initialStmt = stmt;
+ for (stmt = NextNode(stmt); stmt && !IsDefaultCase(stmt);
+ stmt = NextNode(stmt)) {
+ int32_t i = 0;
+ if (!CheckCaseExpr(f, CaseExpr(stmt), &i)) {
+ return false;
+ }
+
+ *low = std::min(*low, i);
+ *high = std::max(*high, i);
+ }
+
+ int64_t i64 = (int64_t(*high) - int64_t(*low)) + 1;
+ if (i64 > MaxBrTableElems) {
+ return f.fail(
+ initialStmt,
+ "all switch statements generate tables; this table would be too big");
+ }
+
+ *tableLength = uint32_t(i64);
+ return true;
+}
+
+template <typename Unit>
+static bool CheckSwitchExpr(FunctionValidator<Unit>& f, ParseNode* switchExpr) {
+ Type exprType;
+ if (!CheckExpr(f, switchExpr, &exprType)) {
+ return false;
+ }
+ if (!exprType.isSigned()) {
+ return f.failf(switchExpr, "%s is not a subtype of signed",
+ exprType.toChars());
+ }
+ return true;
+}
+
+// A switch will be constructed as:
+// - the default block wrapping all the other blocks, to be able to break
+// out of the switch with an unlabeled break statement. It has two statements
+// (an inner block and the default expr). asm.js rules require default to be at
+// the end, so the default block always encloses all the cases blocks.
+// - one block per case between low and high; undefined cases just jump to the
+// default case. Each of these blocks contain two statements: the next case's
+// block and the possibly empty statement list comprising the case body. The
+// last block pushed is the first case so the (relative) branch target therefore
+// matches the sequential order of cases.
+// - one block for the br_table, so that the first break goes to the first
+// case's block.
+template <typename Unit>
+static bool CheckSwitch(FunctionValidator<Unit>& f, ParseNode* switchStmt) {
+ MOZ_ASSERT(switchStmt->isKind(ParseNodeKind::SwitchStmt));
+
+ ParseNode* switchExpr = BinaryLeft(switchStmt);
+ ParseNode* switchBody = BinaryRight(switchStmt);
+
+ if (switchBody->is<LexicalScopeNode>()) {
+ LexicalScopeNode* scope = &switchBody->as<LexicalScopeNode>();
+ if (!scope->isEmptyScope()) {
+ return f.fail(scope, "switch body may not contain lexical declarations");
+ }
+ switchBody = scope->scopeBody();
+ }
+
+ ParseNode* stmt = ListHead(switchBody);
+ if (!stmt) {
+ if (!CheckSwitchExpr(f, switchExpr)) {
+ return false;
+ }
+ if (!f.encoder().writeOp(Op::Drop)) {
+ return false;
+ }
+ return true;
+ }
+
+ if (!CheckDefaultAtEnd(f, stmt)) {
+ return false;
+ }
+
+ int32_t low = 0, high = 0;
+ uint32_t tableLength = 0;
+ if (!CheckSwitchRange(f, stmt, &low, &high, &tableLength)) {
+ return false;
+ }
+
+ static const uint32_t CASE_NOT_DEFINED = UINT32_MAX;
+
+ Uint32Vector caseDepths;
+ if (!caseDepths.appendN(CASE_NOT_DEFINED, tableLength)) {
+ return false;
+ }
+
+ uint32_t numCases = 0;
+ for (ParseNode* s = stmt; s && !IsDefaultCase(s); s = NextNode(s)) {
+ int32_t caseValue = ExtractNumericLiteral(f.m(), CaseExpr(s)).toInt32();
+
+ MOZ_ASSERT(caseValue >= low);
+ unsigned i = caseValue - low;
+ if (caseDepths[i] != CASE_NOT_DEFINED) {
+ return f.fail(s, "no duplicate case labels");
+ }
+
+ MOZ_ASSERT(numCases != CASE_NOT_DEFINED);
+ caseDepths[i] = numCases++;
+ }
+
+ // Open the wrapping breakable default block.
+ if (!f.pushBreakableBlock()) {
+ return false;
+ }
+
+ // Open all the case blocks.
+ for (uint32_t i = 0; i < numCases; i++) {
+ if (!f.pushUnbreakableBlock()) {
+ return false;
+ }
+ }
+
+ // Open the br_table block.
+ if (!f.pushUnbreakableBlock()) {
+ return false;
+ }
+
+ // The default block is the last one.
+ uint32_t defaultDepth = numCases;
+
+ // Subtract lowest case value, so that all the cases start from 0.
+ if (low) {
+ if (!CheckSwitchExpr(f, switchExpr)) {
+ return false;
+ }
+ if (!f.writeInt32Lit(low)) {
+ return false;
+ }
+ if (!f.encoder().writeOp(Op::I32Sub)) {
+ return false;
+ }
+ } else {
+ if (!CheckSwitchExpr(f, switchExpr)) {
+ return false;
+ }
+ }
+
+ // Start the br_table block.
+ if (!f.encoder().writeOp(Op::BrTable)) {
+ return false;
+ }
+
+ // Write the number of cases (tableLength - 1 + 1 (default)).
+ // Write the number of cases (tableLength - 1 + 1 (default)).
+ if (!f.encoder().writeVarU32(tableLength)) {
+ return false;
+ }
+
+ // Each case value describes the relative depth to the actual block. When
+ // a case is not explicitly defined, it goes to the default.
+ for (size_t i = 0; i < tableLength; i++) {
+ uint32_t target =
+ caseDepths[i] == CASE_NOT_DEFINED ? defaultDepth : caseDepths[i];
+ if (!f.encoder().writeVarU32(target)) {
+ return false;
+ }
+ }
+
+ // Write the default depth.
+ if (!f.encoder().writeVarU32(defaultDepth)) {
+ return false;
+ }
+
+ // Our br_table is done. Close its block, write the cases down in order.
+ if (!f.popUnbreakableBlock()) {
+ return false;
+ }
+
+ for (; stmt && !IsDefaultCase(stmt); stmt = NextNode(stmt)) {
+ if (!CheckStatement(f, CaseBody(stmt))) {
+ return false;
+ }
+ if (!f.popUnbreakableBlock()) {
+ return false;
+ }
+ }
+
+ // Write the default block.
+ if (stmt && IsDefaultCase(stmt)) {
+ if (!CheckStatement(f, CaseBody(stmt))) {
+ return false;
+ }
+ }
+
+ // Close the wrapping block.
+ return f.popBreakableBlock();
+}
+
+static bool CheckReturnType(FunctionValidatorShared& f, ParseNode* usepn,
+ Type ret) {
+ Maybe<ValType> type = ret.canonicalToReturnType();
+
+ if (!f.hasAlreadyReturned()) {
+ f.setReturnedType(type);
+ return true;
+ }
+
+ if (f.returnedType() != type) {
+ return f.failf(usepn, "%s incompatible with previous return of type %s",
+ ToString(type, nullptr).get(),
+ ToString(f.returnedType(), nullptr).get());
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckReturn(FunctionValidator<Unit>& f, ParseNode* returnStmt) {
+ ParseNode* expr = ReturnExpr(returnStmt);
+
+ if (!expr) {
+ if (!CheckReturnType(f, returnStmt, Type::Void)) {
+ return false;
+ }
+ } else {
+ Type type;
+ if (!CheckExpr(f, expr, &type)) {
+ return false;
+ }
+
+ if (!type.isReturnType()) {
+ return f.failf(expr, "%s is not a valid return type", type.toChars());
+ }
+
+ if (!CheckReturnType(f, expr, Type::canonicalize(type))) {
+ return false;
+ }
+ }
+
+ return f.encoder().writeOp(Op::Return);
+}
+
+template <typename Unit>
+static bool CheckStatementList(FunctionValidator<Unit>& f, ParseNode* stmtList,
+ const LabelVector* labels /*= nullptr */) {
+ MOZ_ASSERT(stmtList->isKind(ParseNodeKind::StatementList));
+
+ if (!f.pushUnbreakableBlock(labels)) {
+ return false;
+ }
+
+ for (ParseNode* stmt = ListHead(stmtList); stmt; stmt = NextNode(stmt)) {
+ if (!CheckStatement(f, stmt)) {
+ return false;
+ }
+ }
+
+ return f.popUnbreakableBlock(labels);
+}
+
+template <typename Unit>
+static bool CheckLexicalScope(FunctionValidator<Unit>& f, ParseNode* node) {
+ LexicalScopeNode* lexicalScope = &node->as<LexicalScopeNode>();
+ if (!lexicalScope->isEmptyScope()) {
+ return f.fail(lexicalScope, "cannot have 'let' or 'const' declarations");
+ }
+
+ return CheckStatement(f, lexicalScope->scopeBody());
+}
+
+static bool CheckBreakOrContinue(FunctionValidatorShared& f, bool isBreak,
+ ParseNode* stmt) {
+ if (TaggedParserAtomIndex maybeLabel = LoopControlMaybeLabel(stmt)) {
+ return f.writeLabeledBreakOrContinue(maybeLabel, isBreak);
+ }
+ return f.writeUnlabeledBreakOrContinue(isBreak);
+}
+
+template <typename Unit>
+static bool CheckStatement(FunctionValidator<Unit>& f, ParseNode* stmt) {
+ AutoCheckRecursionLimit recursion(f.fc());
+ if (!recursion.checkDontReport(f.fc())) {
+ return f.m().failOverRecursed();
+ }
+
+ switch (stmt->getKind()) {
+ case ParseNodeKind::EmptyStmt:
+ return true;
+ case ParseNodeKind::ExpressionStmt:
+ return CheckExprStatement(f, stmt);
+ case ParseNodeKind::WhileStmt:
+ return CheckWhile(f, stmt);
+ case ParseNodeKind::ForStmt:
+ return CheckFor(f, stmt);
+ case ParseNodeKind::DoWhileStmt:
+ return CheckDoWhile(f, stmt);
+ case ParseNodeKind::LabelStmt:
+ return CheckLabel(f, stmt);
+ case ParseNodeKind::IfStmt:
+ return CheckIf(f, stmt);
+ case ParseNodeKind::SwitchStmt:
+ return CheckSwitch(f, stmt);
+ case ParseNodeKind::ReturnStmt:
+ return CheckReturn(f, stmt);
+ case ParseNodeKind::StatementList:
+ return CheckStatementList(f, stmt);
+ case ParseNodeKind::BreakStmt:
+ return CheckBreakOrContinue(f, true, stmt);
+ case ParseNodeKind::ContinueStmt:
+ return CheckBreakOrContinue(f, false, stmt);
+ case ParseNodeKind::LexicalScope:
+ return CheckLexicalScope(f, stmt);
+ default:;
+ }
+
+ return f.fail(stmt, "unexpected statement kind");
+}
+
+template <typename Unit>
+static bool ParseFunction(ModuleValidator<Unit>& m, FunctionNode** funNodeOut,
+ unsigned* line) {
+ auto& tokenStream = m.tokenStream();
+
+ tokenStream.consumeKnownToken(TokenKind::Function,
+ TokenStreamShared::SlashIsRegExp);
+
+ auto& anyChars = tokenStream.anyCharsAccess();
+ uint32_t toStringStart = anyChars.currentToken().pos.begin;
+ *line = anyChars.lineNumber(anyChars.lineToken(toStringStart));
+
+ TokenKind tk;
+ if (!tokenStream.getToken(&tk, TokenStreamShared::SlashIsRegExp)) {
+ return false;
+ }
+ if (tk == TokenKind::Mul) {
+ return m.failCurrentOffset("unexpected generator function");
+ }
+ if (!TokenKindIsPossibleIdentifier(tk)) {
+ return false; // The regular parser will throw a SyntaxError, no need to
+ // m.fail.
+ }
+
+ TaggedParserAtomIndex name = m.parser().bindingIdentifier(YieldIsName);
+ if (!name) {
+ return false;
+ }
+
+ FunctionNode* funNode = m.parser().handler_.newFunction(
+ FunctionSyntaxKind::Statement, m.parser().pos());
+ if (!funNode) {
+ return false;
+ }
+
+ ParseContext* outerpc = m.parser().pc_;
+ Directives directives(outerpc);
+ FunctionFlags flags(FunctionFlags::INTERPRETED_NORMAL);
+ FunctionBox* funbox = m.parser().newFunctionBox(
+ funNode, name, flags, toStringStart, directives,
+ GeneratorKind::NotGenerator, FunctionAsyncKind::SyncFunction);
+ if (!funbox) {
+ return false;
+ }
+ funbox->initWithEnclosingParseContext(outerpc, FunctionSyntaxKind::Statement);
+
+ Directives newDirectives = directives;
+ SourceParseContext funpc(&m.parser(), funbox, &newDirectives);
+ if (!funpc.init()) {
+ return false;
+ }
+
+ if (!m.parser().functionFormalParametersAndBody(
+ InAllowed, YieldIsName, &funNode, FunctionSyntaxKind::Statement)) {
+ if (anyChars.hadError() || directives == newDirectives) {
+ return false;
+ }
+
+ return m.fail(funNode, "encountered new directive in function");
+ }
+
+ MOZ_ASSERT(!anyChars.hadError());
+ MOZ_ASSERT(directives == newDirectives);
+
+ *funNodeOut = funNode;
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFunction(ModuleValidator<Unit>& m) {
+ // asm.js modules can be quite large when represented as parse trees so pop
+ // the backing LifoAlloc after parsing/compiling each function. Release the
+ // parser's lifo memory after the last use of a parse node.
+ frontend::ParserBase::Mark mark = m.parser().mark();
+ auto releaseMark =
+ mozilla::MakeScopeExit([&m, &mark] { m.parser().release(mark); });
+
+ FunctionNode* funNode = nullptr;
+ unsigned line = 0;
+ if (!ParseFunction(m, &funNode, &line)) {
+ return false;
+ }
+
+ if (!CheckFunctionHead(m, funNode)) {
+ return false;
+ }
+
+ FunctionValidator<Unit> f(m, funNode);
+
+ ParseNode* stmtIter = ListHead(FunctionStatementList(funNode));
+
+ if (!CheckProcessingDirectives(m, &stmtIter)) {
+ return false;
+ }
+
+ ValTypeVector args;
+ if (!CheckArguments(f, &stmtIter, &args)) {
+ return false;
+ }
+
+ if (!CheckVariables(f, &stmtIter)) {
+ return false;
+ }
+
+ ParseNode* lastNonEmptyStmt = nullptr;
+ for (; stmtIter; stmtIter = NextNonEmptyStatement(stmtIter)) {
+ lastNonEmptyStmt = stmtIter;
+ if (!CheckStatement(f, stmtIter)) {
+ return false;
+ }
+ }
+
+ if (!CheckFinalReturn(f, lastNonEmptyStmt)) {
+ return false;
+ }
+
+ ValTypeVector results;
+ if (f.returnedType()) {
+ if (!results.append(f.returnedType().ref())) {
+ return false;
+ }
+ }
+
+ FuncType sig(std::move(args), std::move(results));
+
+ ModuleValidatorShared::Func* func = nullptr;
+ if (!CheckFunctionSignature(m, funNode, std::move(sig), FunctionName(funNode),
+ &func)) {
+ return false;
+ }
+
+ if (func->defined()) {
+ return m.failName(funNode, "function '%s' already defined",
+ FunctionName(funNode));
+ }
+
+ f.define(func, line);
+
+ return true;
+}
+
+static bool CheckAllFunctionsDefined(ModuleValidatorShared& m) {
+ for (unsigned i = 0; i < m.numFuncDefs(); i++) {
+ const ModuleValidatorShared::Func& f = m.funcDef(i);
+ if (!f.defined()) {
+ return m.failNameOffset(f.firstUse(), "missing definition of function %s",
+ f.name());
+ }
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFunctions(ModuleValidator<Unit>& m) {
+ while (true) {
+ TokenKind tk;
+ if (!PeekToken(m.parser(), &tk)) {
+ return false;
+ }
+
+ if (tk != TokenKind::Function) {
+ break;
+ }
+
+ if (!CheckFunction(m)) {
+ return false;
+ }
+ }
+
+ return CheckAllFunctionsDefined(m);
+}
+
+template <typename Unit>
+static bool CheckFuncPtrTable(ModuleValidator<Unit>& m, ParseNode* decl) {
+ if (!decl->isKind(ParseNodeKind::AssignExpr)) {
+ return m.fail(decl, "function-pointer table must have initializer");
+ }
+ AssignmentNode* assignNode = &decl->as<AssignmentNode>();
+
+ ParseNode* var = assignNode->left();
+
+ if (!var->isKind(ParseNodeKind::Name)) {
+ return m.fail(var, "function-pointer table name is not a plain name");
+ }
+
+ ParseNode* arrayLiteral = assignNode->right();
+
+ if (!arrayLiteral->isKind(ParseNodeKind::ArrayExpr)) {
+ return m.fail(
+ var, "function-pointer table's initializer must be an array literal");
+ }
+
+ unsigned length = ListLength(arrayLiteral);
+
+ if (!IsPowerOfTwo(length)) {
+ return m.failf(arrayLiteral,
+ "function-pointer table length must be a power of 2 (is %u)",
+ length);
+ }
+
+ unsigned mask = length - 1;
+
+ Uint32Vector elemFuncDefIndices;
+ const FuncType* sig = nullptr;
+ for (ParseNode* elem = ListHead(arrayLiteral); elem; elem = NextNode(elem)) {
+ if (!elem->isKind(ParseNodeKind::Name)) {
+ return m.fail(
+ elem, "function-pointer table's elements must be names of functions");
+ }
+
+ TaggedParserAtomIndex funcName = elem->as<NameNode>().name();
+ const ModuleValidatorShared::Func* func = m.lookupFuncDef(funcName);
+ if (!func) {
+ return m.fail(
+ elem, "function-pointer table's elements must be names of functions");
+ }
+
+ const FuncType& funcSig = m.env().types->type(func->sigIndex()).funcType();
+ if (sig) {
+ if (!FuncType::strictlyEquals(*sig, funcSig)) {
+ return m.fail(elem, "all functions in table must have same signature");
+ }
+ } else {
+ sig = &funcSig;
+ }
+
+ if (!elemFuncDefIndices.append(func->funcDefIndex())) {
+ return false;
+ }
+ }
+
+ FuncType copy;
+ if (!copy.clone(*sig)) {
+ return false;
+ }
+
+ uint32_t tableIndex;
+ if (!CheckFuncPtrTableAgainstExisting(m, var, var->as<NameNode>().name(),
+ std::move(copy), mask, &tableIndex)) {
+ return false;
+ }
+
+ if (!m.defineFuncPtrTable(tableIndex, std::move(elemFuncDefIndices))) {
+ return m.fail(var, "duplicate function-pointer definition");
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckFuncPtrTables(ModuleValidator<Unit>& m) {
+ while (true) {
+ ParseNode* varStmt;
+ if (!ParseVarOrConstStatement(m.parser(), &varStmt)) {
+ return false;
+ }
+ if (!varStmt) {
+ break;
+ }
+ for (ParseNode* var = VarListHead(varStmt); var; var = NextNode(var)) {
+ if (!CheckFuncPtrTable(m, var)) {
+ return false;
+ }
+ }
+ }
+
+ for (unsigned i = 0; i < m.numFuncPtrTables(); i++) {
+ ModuleValidatorShared::Table& table = m.table(i);
+ if (!table.defined()) {
+ return m.failNameOffset(table.firstUse(),
+ "function-pointer table %s wasn't defined",
+ table.name());
+ }
+ }
+
+ return true;
+}
+
+static bool CheckModuleExportFunction(
+ ModuleValidatorShared& m, ParseNode* pn,
+ TaggedParserAtomIndex maybeFieldName = TaggedParserAtomIndex::null()) {
+ if (!pn->isKind(ParseNodeKind::Name)) {
+ return m.fail(pn, "expected name of exported function");
+ }
+
+ TaggedParserAtomIndex funcName = pn->as<NameNode>().name();
+ const ModuleValidatorShared::Func* func = m.lookupFuncDef(funcName);
+ if (!func) {
+ return m.failName(pn, "function '%s' not found", funcName);
+ }
+
+ return m.addExportField(*func, maybeFieldName);
+}
+
+static bool CheckModuleExportObject(ModuleValidatorShared& m,
+ ParseNode* object) {
+ MOZ_ASSERT(object->isKind(ParseNodeKind::ObjectExpr));
+
+ for (ParseNode* pn = ListHead(object); pn; pn = NextNode(pn)) {
+ if (!IsNormalObjectField(pn)) {
+ return m.fail(pn,
+ "only normal object properties may be used in the export "
+ "object literal");
+ }
+
+ TaggedParserAtomIndex fieldName = ObjectNormalFieldName(pn);
+
+ ParseNode* initNode = ObjectNormalFieldInitializer(pn);
+ if (!initNode->isKind(ParseNodeKind::Name)) {
+ return m.fail(
+ initNode,
+ "initializer of exported object literal must be name of function");
+ }
+
+ if (!CheckModuleExportFunction(m, initNode, fieldName)) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckModuleReturn(ModuleValidator<Unit>& m) {
+ TokenKind tk;
+ if (!GetToken(m.parser(), &tk)) {
+ return false;
+ }
+ auto& ts = m.parser().tokenStream;
+ if (tk != TokenKind::Return) {
+ return m.failCurrentOffset(
+ (tk == TokenKind::RightCurly || tk == TokenKind::Eof)
+ ? "expecting return statement"
+ : "invalid asm.js. statement");
+ }
+ ts.anyCharsAccess().ungetToken();
+
+ ParseNode* returnStmt = m.parser().statementListItem(YieldIsName);
+ if (!returnStmt) {
+ return false;
+ }
+
+ ParseNode* returnExpr = ReturnExpr(returnStmt);
+ if (!returnExpr) {
+ return m.fail(returnStmt, "export statement must return something");
+ }
+
+ if (returnExpr->isKind(ParseNodeKind::ObjectExpr)) {
+ if (!CheckModuleExportObject(m, returnExpr)) {
+ return false;
+ }
+ } else {
+ if (!CheckModuleExportFunction(m, returnExpr)) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool CheckModuleEnd(ModuleValidator<Unit>& m) {
+ TokenKind tk;
+ if (!GetToken(m.parser(), &tk)) {
+ return false;
+ }
+
+ if (tk != TokenKind::Eof && tk != TokenKind::RightCurly) {
+ return m.failCurrentOffset(
+ "top-level export (return) must be the last statement");
+ }
+
+ m.parser().tokenStream.anyCharsAccess().ungetToken();
+ return true;
+}
+
+template <typename Unit>
+static SharedModule CheckModule(FrontendContext* fc,
+ ParserAtomsTable& parserAtoms,
+ AsmJSParser<Unit>& parser, ParseNode* stmtList,
+ unsigned* time) {
+ int64_t before = PRMJ_Now();
+
+ FunctionNode* moduleFunctionNode = parser.pc_->functionBox()->functionNode;
+
+ ModuleValidator<Unit> m(fc, parserAtoms, parser, moduleFunctionNode);
+ if (!m.init()) {
+ return nullptr;
+ }
+
+ if (!CheckFunctionHead(m, moduleFunctionNode)) {
+ return nullptr;
+ }
+
+ if (!CheckModuleArguments(m, moduleFunctionNode)) {
+ return nullptr;
+ }
+
+ if (!CheckPrecedingStatements(m, stmtList)) {
+ return nullptr;
+ }
+
+ if (!CheckModuleProcessingDirectives(m)) {
+ return nullptr;
+ }
+
+ if (!CheckModuleGlobals(m)) {
+ return nullptr;
+ }
+
+ if (!m.startFunctionBodies()) {
+ return nullptr;
+ }
+
+ if (!CheckFunctions(m)) {
+ return nullptr;
+ }
+
+ if (!CheckFuncPtrTables(m)) {
+ return nullptr;
+ }
+
+ if (!CheckModuleReturn(m)) {
+ return nullptr;
+ }
+
+ if (!CheckModuleEnd(m)) {
+ return nullptr;
+ }
+
+ SharedModule module = m.finish();
+ if (!module) {
+ return nullptr;
+ }
+
+ *time = (PRMJ_Now() - before) / PRMJ_USEC_PER_MSEC;
+ return module;
+}
+
+/*****************************************************************************/
+// Link-time validation
+
+static bool LinkFail(JSContext* cx, const char* str) {
+ WarnNumberASCII(cx, JSMSG_USE_ASM_LINK_FAIL, str);
+ return false;
+}
+
+static bool IsMaybeWrappedScriptedProxy(JSObject* obj) {
+ JSObject* unwrapped = UncheckedUnwrap(obj);
+ return unwrapped && IsScriptedProxy(unwrapped);
+}
+
+static bool GetDataProperty(JSContext* cx, HandleValue objVal,
+ Handle<JSAtom*> field, MutableHandleValue v) {
+ if (!objVal.isObject()) {
+ return LinkFail(cx, "accessing property of non-object");
+ }
+
+ RootedObject obj(cx, &objVal.toObject());
+ if (IsMaybeWrappedScriptedProxy(obj)) {
+ return LinkFail(cx, "accessing property of a Proxy");
+ }
+
+ RootedId id(cx, AtomToId(field));
+ Rooted<mozilla::Maybe<PropertyDescriptor>> desc(cx);
+ RootedObject holder(cx);
+ if (!GetPropertyDescriptor(cx, obj, id, &desc, &holder)) {
+ return false;
+ }
+
+ if (!desc.isSome()) {
+ return LinkFail(cx, "property not present on object");
+ }
+
+ if (!desc->isDataDescriptor()) {
+ return LinkFail(cx, "property is not a data property");
+ }
+
+ v.set(desc->value());
+ return true;
+}
+
+static bool GetDataProperty(JSContext* cx, HandleValue objVal,
+ const char* fieldChars, MutableHandleValue v) {
+ Rooted<JSAtom*> field(cx,
+ AtomizeUTF8Chars(cx, fieldChars, strlen(fieldChars)));
+ if (!field) {
+ return false;
+ }
+
+ return GetDataProperty(cx, objVal, field, v);
+}
+
+static bool GetDataProperty(JSContext* cx, HandleValue objVal,
+ const ImmutableTenuredPtr<PropertyName*>& field,
+ MutableHandleValue v) {
+ Handle<PropertyName*> fieldHandle = field;
+ return GetDataProperty(cx, objVal, fieldHandle, v);
+}
+
+static bool HasObjectValueOfMethodPure(JSObject* obj, JSContext* cx) {
+ Value v;
+ if (!GetPropertyPure(cx, obj, NameToId(cx->names().valueOf), &v)) {
+ return false;
+ }
+
+ JSFunction* fun;
+ if (!IsFunctionObject(v, &fun)) {
+ return false;
+ }
+
+ return IsSelfHostedFunctionWithName(fun, cx->names().Object_valueOf);
+}
+
+static bool HasPureCoercion(JSContext* cx, HandleValue v) {
+ // Ideally, we'd reject all non-primitives, but Emscripten has a bug that
+ // generates code that passes functions for some imports. To avoid breaking
+ // all the code that contains this bug, we make an exception for functions
+ // that don't have user-defined valueOf or toString, for their coercions
+ // are not observable and coercion via ToNumber/ToInt32 definitely produces
+ // NaN/0. We should remove this special case later once most apps have been
+ // built with newer Emscripten.
+ return v.toObject().is<JSFunction>() &&
+ HasNoToPrimitiveMethodPure(&v.toObject(), cx) &&
+ HasObjectValueOfMethodPure(&v.toObject(), cx) &&
+ HasNativeMethodPure(&v.toObject(), cx->names().toString, fun_toString,
+ cx);
+}
+
+static bool ValidateGlobalVariable(JSContext* cx, const AsmJSGlobal& global,
+ HandleValue importVal,
+ Maybe<LitValPOD>* val) {
+ switch (global.varInitKind()) {
+ case AsmJSGlobal::InitConstant:
+ val->emplace(global.varInitVal());
+ return true;
+
+ case AsmJSGlobal::InitImport: {
+ RootedValue v(cx);
+ if (!GetDataProperty(cx, importVal, global.field(), &v)) {
+ return false;
+ }
+
+ if (!v.isPrimitive() && !HasPureCoercion(cx, v)) {
+ return LinkFail(cx, "Imported values must be primitives");
+ }
+
+ switch (global.varInitImportType().kind()) {
+ case ValType::I32: {
+ int32_t i32;
+ if (!ToInt32(cx, v, &i32)) {
+ return false;
+ }
+ val->emplace(uint32_t(i32));
+ return true;
+ }
+ case ValType::I64:
+ MOZ_CRASH("int64");
+ case ValType::V128:
+ MOZ_CRASH("v128");
+ case ValType::F32: {
+ float f;
+ if (!RoundFloat32(cx, v, &f)) {
+ return false;
+ }
+ val->emplace(f);
+ return true;
+ }
+ case ValType::F64: {
+ double d;
+ if (!ToNumber(cx, v, &d)) {
+ return false;
+ }
+ val->emplace(d);
+ return true;
+ }
+ case ValType::Ref: {
+ MOZ_CRASH("not available in asm.js");
+ }
+ }
+ }
+ }
+
+ MOZ_CRASH("unreachable");
+}
+
+static bool ValidateFFI(JSContext* cx, const AsmJSGlobal& global,
+ HandleValue importVal,
+ MutableHandle<FunctionVector> ffis) {
+ RootedValue v(cx);
+ if (!GetDataProperty(cx, importVal, global.field(), &v)) {
+ return false;
+ }
+
+ if (!IsFunctionObject(v)) {
+ return LinkFail(cx, "FFI imports must be functions");
+ }
+
+ ffis[global.ffiIndex()].set(&v.toObject().as<JSFunction>());
+ return true;
+}
+
+static bool ValidateArrayView(JSContext* cx, const AsmJSGlobal& global,
+ HandleValue globalVal) {
+ if (!global.field()) {
+ return true;
+ }
+
+ if (Scalar::isBigIntType(global.viewType())) {
+ return LinkFail(cx, "bad typed array constructor");
+ }
+
+ RootedValue v(cx);
+ if (!GetDataProperty(cx, globalVal, global.field(), &v)) {
+ return false;
+ }
+
+ bool tac = IsTypedArrayConstructor(v, global.viewType());
+ if (!tac) {
+ return LinkFail(cx, "bad typed array constructor");
+ }
+
+ return true;
+}
+
+static InlinableNative ToInlinableNative(AsmJSMathBuiltinFunction func) {
+ switch (func) {
+ case AsmJSMathBuiltin_sin:
+ return InlinableNative::MathSin;
+ case AsmJSMathBuiltin_cos:
+ return InlinableNative::MathCos;
+ case AsmJSMathBuiltin_tan:
+ return InlinableNative::MathTan;
+ case AsmJSMathBuiltin_asin:
+ return InlinableNative::MathASin;
+ case AsmJSMathBuiltin_acos:
+ return InlinableNative::MathACos;
+ case AsmJSMathBuiltin_atan:
+ return InlinableNative::MathATan;
+ case AsmJSMathBuiltin_ceil:
+ return InlinableNative::MathCeil;
+ case AsmJSMathBuiltin_floor:
+ return InlinableNative::MathFloor;
+ case AsmJSMathBuiltin_exp:
+ return InlinableNative::MathExp;
+ case AsmJSMathBuiltin_log:
+ return InlinableNative::MathLog;
+ case AsmJSMathBuiltin_pow:
+ return InlinableNative::MathPow;
+ case AsmJSMathBuiltin_sqrt:
+ return InlinableNative::MathSqrt;
+ case AsmJSMathBuiltin_abs:
+ return InlinableNative::MathAbs;
+ case AsmJSMathBuiltin_atan2:
+ return InlinableNative::MathATan2;
+ case AsmJSMathBuiltin_imul:
+ return InlinableNative::MathImul;
+ case AsmJSMathBuiltin_fround:
+ return InlinableNative::MathFRound;
+ case AsmJSMathBuiltin_min:
+ return InlinableNative::MathMin;
+ case AsmJSMathBuiltin_max:
+ return InlinableNative::MathMax;
+ case AsmJSMathBuiltin_clz32:
+ return InlinableNative::MathClz32;
+ }
+ MOZ_CRASH("Invalid asm.js math builtin function");
+}
+
+static bool ValidateMathBuiltinFunction(JSContext* cx,
+ const AsmJSMetadata& metadata,
+ const AsmJSGlobal& global,
+ HandleValue globalVal) {
+ RootedValue v(cx);
+ if (!GetDataProperty(cx, globalVal, cx->names().Math, &v)) {
+ return false;
+ }
+
+ if (!GetDataProperty(cx, v, global.field(), &v)) {
+ return false;
+ }
+
+ InlinableNative native = ToInlinableNative(global.mathBuiltinFunction());
+
+ JSFunction* fun;
+ if (!IsFunctionObject(v, &fun) || !fun->hasJitInfo() ||
+ fun->jitInfo()->type() != JSJitInfo::InlinableNative ||
+ fun->jitInfo()->inlinableNative != native) {
+ return LinkFail(cx, "bad Math.* builtin function");
+ }
+ if (fun->realm()->behaviors().shouldResistFingerprinting() !=
+ metadata.shouldResistFingerprinting) {
+ return LinkFail(cx,
+ "Math.* builtin function and asm.js module have a "
+ "different resist fingerprinting mode");
+ }
+
+ return true;
+}
+
+static bool ValidateConstant(JSContext* cx, const AsmJSGlobal& global,
+ HandleValue globalVal) {
+ RootedValue v(cx, globalVal);
+
+ if (global.constantKind() == AsmJSGlobal::MathConstant) {
+ if (!GetDataProperty(cx, v, cx->names().Math, &v)) {
+ return false;
+ }
+ }
+
+ if (!GetDataProperty(cx, v, global.field(), &v)) {
+ return false;
+ }
+
+ if (!v.isNumber()) {
+ return LinkFail(cx, "math / global constant value needs to be a number");
+ }
+
+ // NaN != NaN
+ if (std::isnan(global.constantValue())) {
+ if (!std::isnan(v.toNumber())) {
+ return LinkFail(cx, "global constant value needs to be NaN");
+ }
+ } else {
+ if (v.toNumber() != global.constantValue()) {
+ return LinkFail(cx, "global constant value mismatch");
+ }
+ }
+
+ return true;
+}
+
+static bool CheckBuffer(JSContext* cx, const AsmJSMetadata& metadata,
+ HandleValue bufferVal,
+ MutableHandle<ArrayBufferObject*> buffer) {
+ if (!bufferVal.isObject()) {
+ return LinkFail(cx, "buffer must be an object");
+ }
+ JSObject* bufferObj = &bufferVal.toObject();
+
+ if (metadata.usesSharedMemory()) {
+ if (!bufferObj->is<SharedArrayBufferObject>()) {
+ return LinkFail(
+ cx, "shared views can only be constructed onto SharedArrayBuffer");
+ }
+ return LinkFail(cx, "Unable to prepare SharedArrayBuffer for asm.js use");
+ }
+
+ if (!bufferObj->is<ArrayBufferObject>()) {
+ return LinkFail(cx,
+ "unshared views can only be constructed onto ArrayBuffer");
+ }
+
+ buffer.set(&bufferObj->as<ArrayBufferObject>());
+
+ size_t memoryLength = buffer->byteLength();
+
+ if (!IsValidAsmJSHeapLength(memoryLength)) {
+ UniqueChars msg;
+ if (memoryLength > MaxHeapLength) {
+ msg = JS_smprintf("ArrayBuffer byteLength 0x%" PRIx64
+ " is not a valid heap length - it is too long."
+ " The longest valid length is 0x%" PRIx64,
+ uint64_t(memoryLength), MaxHeapLength);
+ } else {
+ msg = JS_smprintf("ArrayBuffer byteLength 0x%" PRIx64
+ " is not a valid heap length. The next "
+ "valid length is 0x%" PRIx64,
+ uint64_t(memoryLength),
+ RoundUpToNextValidAsmJSHeapLength(memoryLength));
+ }
+ if (!msg) {
+ return false;
+ }
+ return LinkFail(cx, msg.get());
+ }
+
+ // This check is sufficient without considering the size of the loaded datum
+ // because heap loads and stores start on an aligned boundary and the heap
+ // byteLength has larger alignment.
+ uint64_t minMemoryLength =
+ metadata.usesMemory() ? metadata.memory->initialLength32() : 0;
+ MOZ_ASSERT((minMemoryLength - 1) <= INT32_MAX);
+ if (memoryLength < minMemoryLength) {
+ UniqueChars msg(JS_smprintf("ArrayBuffer byteLength of 0x%" PRIx64
+ " is less than 0x%" PRIx64 " (the "
+ "size implied "
+ "by const heap accesses).",
+ uint64_t(memoryLength), minMemoryLength));
+ if (!msg) {
+ return false;
+ }
+ return LinkFail(cx, msg.get());
+ }
+
+ // ArrayBuffer lengths in SpiderMonkey used to be restricted to <= INT32_MAX,
+ // but that has since been relaxed for the benefit of wasm. We keep the old
+ // limit for asm.js so as to avoid having to worry about whether the asm.js
+ // implementation is safe for larger heaps.
+ if (memoryLength >= INT32_MAX) {
+ UniqueChars msg(
+ JS_smprintf("ArrayBuffer byteLength 0x%" PRIx64
+ " is too large for asm.js (implementation limit).",
+ uint64_t(memoryLength)));
+ if (!msg) {
+ return false;
+ }
+ return LinkFail(cx, msg.get());
+ }
+
+ if (!buffer->prepareForAsmJS()) {
+ return LinkFail(cx, "Unable to prepare ArrayBuffer for asm.js use");
+ }
+
+ MOZ_ASSERT(buffer->isPreparedForAsmJS());
+ return true;
+}
+
+static bool GetImports(JSContext* cx, const AsmJSMetadata& metadata,
+ HandleValue globalVal, HandleValue importVal,
+ ImportValues* imports) {
+ Rooted<FunctionVector> ffis(cx, FunctionVector(cx));
+ if (!ffis.resize(metadata.numFFIs)) {
+ return false;
+ }
+
+ for (const AsmJSGlobal& global : metadata.asmJSGlobals) {
+ switch (global.which()) {
+ case AsmJSGlobal::Variable: {
+ Maybe<LitValPOD> litVal;
+ if (!ValidateGlobalVariable(cx, global, importVal, &litVal)) {
+ return false;
+ }
+ if (!imports->globalValues.append(Val(litVal->asLitVal()))) {
+ return false;
+ }
+ break;
+ }
+ case AsmJSGlobal::FFI:
+ if (!ValidateFFI(cx, global, importVal, &ffis)) {
+ return false;
+ }
+ break;
+ case AsmJSGlobal::ArrayView:
+ case AsmJSGlobal::ArrayViewCtor:
+ if (!ValidateArrayView(cx, global, globalVal)) {
+ return false;
+ }
+ break;
+ case AsmJSGlobal::MathBuiltinFunction:
+ if (!ValidateMathBuiltinFunction(cx, metadata, global, globalVal)) {
+ return false;
+ }
+ break;
+ case AsmJSGlobal::Constant:
+ if (!ValidateConstant(cx, global, globalVal)) {
+ return false;
+ }
+ break;
+ }
+ }
+
+ for (const AsmJSImport& import : metadata.asmJSImports) {
+ if (!imports->funcs.append(ffis[import.ffiIndex()])) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+static bool TryInstantiate(JSContext* cx, CallArgs args, const Module& module,
+ const AsmJSMetadata& metadata,
+ MutableHandle<WasmInstanceObject*> instanceObj,
+ MutableHandleObject exportObj) {
+ HandleValue globalVal = args.get(0);
+ HandleValue importVal = args.get(1);
+ HandleValue bufferVal = args.get(2);
+
+ // Re-check HasPlatformSupport(cx) since this varies per-thread and
+ // 'module' may have been produced on a parser thread.
+ if (!HasPlatformSupport(cx)) {
+ return LinkFail(cx, "no platform support");
+ }
+
+ Rooted<ImportValues> imports(cx);
+
+ if (module.metadata().usesMemory()) {
+ RootedArrayBufferObject buffer(cx);
+ if (!CheckBuffer(cx, metadata, bufferVal, &buffer)) {
+ return false;
+ }
+
+ imports.get().memory =
+ WasmMemoryObject::create(cx, buffer, /* isHuge= */ false, nullptr);
+ if (!imports.get().memory) {
+ return false;
+ }
+ }
+
+ if (!GetImports(cx, metadata, globalVal, importVal, imports.address())) {
+ return false;
+ }
+
+ if (!module.instantiate(cx, imports.get(), nullptr, instanceObj)) {
+ return false;
+ }
+
+ exportObj.set(&instanceObj->exportsObj());
+ return true;
+}
+
+static bool HandleInstantiationFailure(JSContext* cx, CallArgs args,
+ const AsmJSMetadata& metadata) {
+ using js::frontend::FunctionSyntaxKind;
+
+ Rooted<JSAtom*> name(cx, args.callee().as<JSFunction>().explicitName());
+
+ if (cx->isExceptionPending()) {
+ return false;
+ }
+
+ ScriptSource* source = metadata.maybeScriptSource();
+
+ // Source discarding is allowed to affect JS semantics because it is never
+ // enabled for normal JS content.
+ bool haveSource;
+ if (!ScriptSource::loadSource(cx, source, &haveSource)) {
+ return false;
+ }
+ if (!haveSource) {
+ JS_ReportErrorASCII(cx,
+ "asm.js link failure with source discarding enabled");
+ return false;
+ }
+
+ uint32_t begin = metadata.toStringStart;
+ uint32_t end = metadata.srcEndAfterCurly();
+ Rooted<JSLinearString*> src(cx, source->substringDontDeflate(cx, begin, end));
+ if (!src) {
+ return false;
+ }
+
+ JS::CompileOptions options(cx);
+ options.setMutedErrors(source->mutedErrors())
+ .setFile(source->filename())
+ .setNoScriptRval(false);
+ options.asmJSOption = AsmJSOption::DisabledByLinker;
+
+ // The exported function inherits an implicit strict context if the module
+ // also inherited it somehow.
+ if (metadata.strict) {
+ options.setForceStrictMode();
+ }
+
+ AutoStableStringChars linearChars(cx);
+ if (!linearChars.initTwoByte(cx, src)) {
+ return false;
+ }
+
+ SourceText<char16_t> srcBuf;
+ if (!srcBuf.initMaybeBorrowed(cx, linearChars)) {
+ return false;
+ }
+
+ FunctionSyntaxKind syntaxKind = FunctionSyntaxKind::Statement;
+
+ RootedFunction fun(cx, frontend::CompileStandaloneFunction(
+ cx, options, srcBuf, Nothing(), syntaxKind));
+ if (!fun) {
+ return false;
+ }
+
+ fun->initEnvironment(&cx->global()->lexicalEnvironment());
+
+ // Call the function we just recompiled.
+ args.setCallee(ObjectValue(*fun));
+ return InternalCallOrConstruct(
+ cx, args, args.isConstructing() ? CONSTRUCT : NO_CONSTRUCT);
+}
+
+static const Module& AsmJSModuleFunctionToModule(JSFunction* fun) {
+ MOZ_ASSERT(IsAsmJSModule(fun));
+ const Value& v = fun->getExtendedSlot(FunctionExtended::ASMJS_MODULE_SLOT);
+ return v.toObject().as<WasmModuleObject>().module();
+}
+
+// Implements the semantics of an asm.js module function that has been
+// successfully validated.
+bool js::InstantiateAsmJS(JSContext* cx, unsigned argc, JS::Value* vp) {
+ CallArgs args = CallArgsFromVp(argc, vp);
+
+ JSFunction* callee = &args.callee().as<JSFunction>();
+ const Module& module = AsmJSModuleFunctionToModule(callee);
+ const AsmJSMetadata& metadata = module.metadata().asAsmJS();
+
+ Rooted<WasmInstanceObject*> instanceObj(cx);
+ RootedObject exportObj(cx);
+ if (!TryInstantiate(cx, args, module, metadata, &instanceObj, &exportObj)) {
+ // Link-time validation checks failed, so reparse the entire asm.js
+ // module from scratch to get normal interpreted bytecode which we can
+ // simply Invoke. Very slow.
+ return HandleInstantiationFailure(cx, args, metadata);
+ }
+
+ args.rval().set(ObjectValue(*exportObj));
+ return true;
+}
+
+/*****************************************************************************/
+// Top-level js::CompileAsmJS
+
+static bool NoExceptionPending(FrontendContext* fc) { return !fc->hadErrors(); }
+
+static bool SuccessfulValidation(frontend::ParserBase& parser,
+ unsigned compilationTime) {
+ unsigned errNum = js::SupportDifferentialTesting()
+ ? JSMSG_USE_ASM_TYPE_OK_NO_TIME
+ : JSMSG_USE_ASM_TYPE_OK;
+
+ char timeChars[20];
+ SprintfLiteral(timeChars, "%u", compilationTime);
+
+ return parser.warningNoOffset(errNum, timeChars);
+}
+
+static bool TypeFailureWarning(frontend::ParserBase& parser, const char* str) {
+ if (parser.options().throwOnAsmJSValidationFailureOption) {
+ parser.errorNoOffset(JSMSG_USE_ASM_TYPE_FAIL, str ? str : "");
+ return false;
+ }
+
+ // Per the asm.js standard convention, whether failure sets a pending
+ // exception determines whether to attempt non-asm.js reparsing, so ignore
+ // the return value below.
+ (void)parser.warningNoOffset(JSMSG_USE_ASM_TYPE_FAIL, str ? str : "");
+ return false;
+}
+
+// asm.js requires Ion to be available on the current hardware/OS and to be
+// enabled for wasm, since asm.js compilation goes via wasm.
+static bool IsAsmJSCompilerAvailable(JSContext* cx) {
+ return HasPlatformSupport(cx) && WasmCompilerForAsmJSAvailable(cx);
+}
+
+static bool EstablishPreconditions(frontend::ParserBase& parser) {
+ switch (parser.options().asmJSOption) {
+ case AsmJSOption::DisabledByAsmJSPref:
+ return TypeFailureWarning(
+ parser, "Asm.js optimizer disabled by 'asmjs' runtime option");
+ case AsmJSOption::DisabledByLinker:
+ return TypeFailureWarning(
+ parser,
+ "Asm.js optimizer disabled by linker (instantiation failure)");
+ case AsmJSOption::DisabledByNoWasmCompiler:
+ return TypeFailureWarning(parser,
+ "Asm.js optimizer disabled because no suitable "
+ "wasm compiler is available");
+ case AsmJSOption::DisabledByDebugger:
+ return TypeFailureWarning(
+ parser, "Asm.js optimizer disabled because debugger is active");
+ case AsmJSOption::Enabled:
+ break;
+ }
+
+ if (parser.pc_->isGenerator()) {
+ return TypeFailureWarning(parser,
+ "Asm.js optimizer disabled in generator context");
+ }
+
+ if (parser.pc_->isAsync()) {
+ return TypeFailureWarning(parser,
+ "Asm.js optimizer disabled in async context");
+ }
+
+ if (parser.pc_->isArrowFunction()) {
+ return TypeFailureWarning(
+ parser, "Asm.js optimizer disabled in arrow function context");
+ }
+
+ // Class constructors are also methods
+ if (parser.pc_->isMethod() || parser.pc_->isGetterOrSetter()) {
+ return TypeFailureWarning(
+ parser,
+ "Asm.js optimizer disabled in class constructor or method context");
+ }
+
+ return true;
+}
+
+template <typename Unit>
+static bool DoCompileAsmJS(FrontendContext* fc, ParserAtomsTable& parserAtoms,
+ AsmJSParser<Unit>& parser, ParseNode* stmtList,
+ bool* validated) {
+ *validated = false;
+
+ // Various conditions disable asm.js optimizations.
+ if (!EstablishPreconditions(parser)) {
+ return NoExceptionPending(fc);
+ }
+
+ // "Checking" parses, validates and compiles, producing a fully compiled
+ // WasmModuleObject as result.
+ unsigned time;
+ SharedModule module = CheckModule(fc, parserAtoms, parser, stmtList, &time);
+ if (!module) {
+ return NoExceptionPending(fc);
+ }
+
+ // Finished! Save the ref-counted module on the FunctionBox. When JSFunctions
+ // are eventually allocated we will create an asm.js constructor for it.
+ FunctionBox* funbox = parser.pc_->functionBox();
+ MOZ_ASSERT(funbox->isInterpreted());
+ if (!funbox->setAsmJSModule(module)) {
+ return NoExceptionPending(fc);
+ }
+
+ // Success! Write to the console with a "warning" message indicating
+ // total compilation time.
+ *validated = true;
+ SuccessfulValidation(parser, time);
+ return NoExceptionPending(fc);
+}
+
+bool js::CompileAsmJS(FrontendContext* fc, ParserAtomsTable& parserAtoms,
+ AsmJSParser<char16_t>& parser, ParseNode* stmtList,
+ bool* validated) {
+ return DoCompileAsmJS(fc, parserAtoms, parser, stmtList, validated);
+}
+
+bool js::CompileAsmJS(FrontendContext* fc, ParserAtomsTable& parserAtoms,
+ AsmJSParser<Utf8Unit>& parser, ParseNode* stmtList,
+ bool* validated) {
+ return DoCompileAsmJS(fc, parserAtoms, parser, stmtList, validated);
+}
+
+/*****************************************************************************/
+// asm.js testing functions
+
+bool js::IsAsmJSModuleNative(Native native) {
+ return native == InstantiateAsmJS;
+}
+
+bool js::IsAsmJSModule(JSFunction* fun) {
+ return fun->maybeNative() == InstantiateAsmJS;
+}
+
+bool js::IsAsmJSFunction(JSFunction* fun) {
+ return fun->kind() == FunctionFlags::AsmJS;
+}
+
+bool js::IsAsmJSStrictModeModuleOrFunction(JSFunction* fun) {
+ if (IsAsmJSModule(fun)) {
+ return AsmJSModuleFunctionToModule(fun).metadata().asAsmJS().strict;
+ }
+
+ if (IsAsmJSFunction(fun)) {
+ return ExportedFunctionToInstance(fun).metadata().asAsmJS().strict;
+ }
+
+ return false;
+}
+
+bool js::IsAsmJSCompilationAvailable(JSContext* cx) {
+ return cx->options().asmJS() && IsAsmJSCompilerAvailable(cx);
+}
+
+bool js::IsAsmJSCompilationAvailable(JSContext* cx, unsigned argc, Value* vp) {
+ CallArgs args = CallArgsFromVp(argc, vp);
+ bool available = IsAsmJSCompilationAvailable(cx);
+ args.rval().set(BooleanValue(available));
+ return true;
+}
+
+static JSFunction* MaybeWrappedNativeFunction(const Value& v) {
+ if (!v.isObject()) {
+ return nullptr;
+ }
+
+ return v.toObject().maybeUnwrapIf<JSFunction>();
+}
+
+bool js::IsAsmJSModule(JSContext* cx, unsigned argc, Value* vp) {
+ CallArgs args = CallArgsFromVp(argc, vp);
+
+ bool rval = false;
+ if (JSFunction* fun = MaybeWrappedNativeFunction(args.get(0))) {
+ rval = IsAsmJSModule(fun);
+ }
+
+ args.rval().set(BooleanValue(rval));
+ return true;
+}
+
+bool js::IsAsmJSFunction(JSContext* cx, unsigned argc, Value* vp) {
+ CallArgs args = CallArgsFromVp(argc, vp);
+
+ bool rval = false;
+ if (JSFunction* fun = MaybeWrappedNativeFunction(args.get(0))) {
+ rval = IsAsmJSFunction(fun);
+ }
+
+ args.rval().set(BooleanValue(rval));
+ return true;
+}
+
+/*****************************************************************************/
+// asm.js toString/toSource support
+
+JSString* js::AsmJSModuleToString(JSContext* cx, HandleFunction fun,
+ bool isToSource) {
+ MOZ_ASSERT(IsAsmJSModule(fun));
+
+ const AsmJSMetadata& metadata =
+ AsmJSModuleFunctionToModule(fun).metadata().asAsmJS();
+ uint32_t begin = metadata.toStringStart;
+ uint32_t end = metadata.srcEndAfterCurly();
+ ScriptSource* source = metadata.maybeScriptSource();
+
+ JSStringBuilder out(cx);
+
+ if (isToSource && fun->isLambda() && !out.append("(")) {
+ return nullptr;
+ }
+
+ bool haveSource;
+ if (!ScriptSource::loadSource(cx, source, &haveSource)) {
+ return nullptr;
+ }
+
+ if (!haveSource) {
+ if (!out.append("function ")) {
+ return nullptr;
+ }
+ if (fun->explicitName() && !out.append(fun->explicitName())) {
+ return nullptr;
+ }
+ if (!out.append("() {\n [native code]\n}")) {
+ return nullptr;
+ }
+ } else {
+ Rooted<JSLinearString*> src(cx, source->substring(cx, begin, end));
+ if (!src) {
+ return nullptr;
+ }
+
+ if (!out.append(src)) {
+ return nullptr;
+ }
+ }
+
+ if (isToSource && fun->isLambda() && !out.append(")")) {
+ return nullptr;
+ }
+
+ return out.finishString();
+}
+
+JSString* js::AsmJSFunctionToString(JSContext* cx, HandleFunction fun) {
+ MOZ_ASSERT(IsAsmJSFunction(fun));
+
+ const AsmJSMetadata& metadata =
+ ExportedFunctionToInstance(fun).metadata().asAsmJS();
+ const AsmJSExport& f =
+ metadata.lookupAsmJSExport(ExportedFunctionToFuncIndex(fun));
+
+ uint32_t begin = metadata.srcStart + f.startOffsetInModule();
+ uint32_t end = metadata.srcStart + f.endOffsetInModule();
+
+ ScriptSource* source = metadata.maybeScriptSource();
+ JSStringBuilder out(cx);
+
+ if (!out.append("function ")) {
+ return nullptr;
+ }
+
+ bool haveSource;
+ if (!ScriptSource::loadSource(cx, source, &haveSource)) {
+ return nullptr;
+ }
+
+ if (!haveSource) {
+ // asm.js functions can't be anonymous
+ MOZ_ASSERT(fun->explicitName());
+ if (!out.append(fun->explicitName())) {
+ return nullptr;
+ }
+ if (!out.append("() {\n [native code]\n}")) {
+ return nullptr;
+ }
+ } else {
+ Rooted<JSLinearString*> src(cx, source->substring(cx, begin, end));
+ if (!src) {
+ return nullptr;
+ }
+ if (!out.append(src)) {
+ return nullptr;
+ }
+ }
+
+ return out.finishString();
+}
+
+bool js::IsValidAsmJSHeapLength(size_t length) {
+ if (length < MinHeapLength) {
+ return false;
+ }
+
+ // The heap length is limited by what a wasm memory32 can handle.
+ if (length > MaxMemoryBytes(IndexType::I32)) {
+ return false;
+ }
+
+ return wasm::IsValidARMImmediate(length);
+}