/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef vm_BytecodeLocation_h #define vm_BytecodeLocation_h #include "frontend/NameAnalysisTypes.h" #include "js/TypeDecls.h" #include "vm/AsyncFunctionResolveKind.h" #include "vm/BuiltinObjectKind.h" #include "vm/BytecodeUtil.h" #include "vm/CheckIsObjectKind.h" // CheckIsObjectKind #include "vm/CompletionKind.h" // CompletionKind #include "vm/FunctionPrefixKind.h" // FunctionPrefixKind #include "vm/GeneratorResumeKind.h" namespace js { using RawBytecodeLocationOffset = uint32_t; class PropertyName; class RegExpObject; class BytecodeLocationOffset { RawBytecodeLocationOffset rawOffset_; public: explicit BytecodeLocationOffset(RawBytecodeLocationOffset offset) : rawOffset_(offset) {} RawBytecodeLocationOffset rawOffset() const { return rawOffset_; } }; using RawBytecode = jsbytecode*; // A immutable representation of a program location // class BytecodeLocation { RawBytecode rawBytecode_; #ifdef DEBUG const JSScript* debugOnlyScript_; #endif // Construct a new BytecodeLocation, while borrowing scriptIdentity // from some other BytecodeLocation. BytecodeLocation(const BytecodeLocation& loc, RawBytecode pc) : rawBytecode_(pc) #ifdef DEBUG , debugOnlyScript_(loc.debugOnlyScript_) #endif { MOZ_ASSERT(isValid()); } public: // Disallow the creation of an uninitialized location. BytecodeLocation() = delete; BytecodeLocation(const JSScript* script, RawBytecode pc) : rawBytecode_(pc) #ifdef DEBUG , debugOnlyScript_(script) #endif { MOZ_ASSERT(isValid()); } RawBytecode toRawBytecode() const { return rawBytecode_; } #ifdef DEBUG // Return true if this bytecode location is valid for the given script. // This includes the location 1-past the end of the bytecode. bool isValid(const JSScript* script) const; // Return true if this bytecode location is within the bounds of the // bytecode for a given script. bool isInBounds(const JSScript* script) const; const JSScript* getDebugOnlyScript() const; #endif inline uint32_t bytecodeToOffset(const JSScript* script) const; inline uint32_t tableSwitchCaseOffset(const JSScript* script, uint32_t caseIndex) const; inline uint32_t getJumpTargetOffset(const JSScript* script) const; inline uint32_t getTableSwitchDefaultOffset(const JSScript* script) const; inline BytecodeLocation getTableSwitchDefaultTarget() const; inline BytecodeLocation getTableSwitchCaseTarget(const JSScript* script, uint32_t caseIndex) const; inline uint32_t useCount() const; inline uint32_t defCount() const; int32_t jumpOffset() const { return GET_JUMP_OFFSET(rawBytecode_); } inline JSAtom* getAtom(const JSScript* script) const; inline JSString* getString(const JSScript* script) const; inline PropertyName* getPropertyName(const JSScript* script) const; inline JS::BigInt* getBigInt(const JSScript* script) const; inline JSObject* getObject(const JSScript* script) const; inline JSFunction* getFunction(const JSScript* script) const; inline js::RegExpObject* getRegExp(const JSScript* script) const; inline js::Scope* getScope(const JSScript* script) const; uint32_t getSymbolIndex() const { MOZ_ASSERT(is(JSOp::Symbol)); return GET_UINT8(rawBytecode_); } inline Scope* innermostScope(const JSScript* script) const; #ifdef DEBUG bool hasSameScript(const BytecodeLocation& other) const { return debugOnlyScript_ == other.debugOnlyScript_; } #endif // Overloaded operators bool operator==(const BytecodeLocation& other) const { MOZ_ASSERT(this->debugOnlyScript_ == other.debugOnlyScript_); return rawBytecode_ == other.rawBytecode_; } bool operator!=(const BytecodeLocation& other) const { return !(other == *this); } bool operator<(const BytecodeLocation& other) const { MOZ_ASSERT(this->debugOnlyScript_ == other.debugOnlyScript_); return rawBytecode_ < other.rawBytecode_; } // It is traditional to represent the rest of the relational operators // using operator<, so we don't need to assert for these. bool operator>(const BytecodeLocation& other) const { return other < *this; } bool operator<=(const BytecodeLocation& other) const { return !(other < *this); } bool operator>=(const BytecodeLocation& other) const { return !(*this < other); } // Return the next bytecode BytecodeLocation next() const { return BytecodeLocation(*this, rawBytecode_ + GetBytecodeLength(rawBytecode_)); } // Add an offset. BytecodeLocation operator+(const BytecodeLocationOffset& offset) { return BytecodeLocation(*this, rawBytecode_ + offset.rawOffset()); } // Identity Checks bool is(JSOp op) const { MOZ_ASSERT(isInBounds()); return getOp() == op; } // Accessors: uint32_t length() const { return GetBytecodeLength(rawBytecode_); } bool isJumpTarget() const { return BytecodeIsJumpTarget(getOp()); } bool isJump() const { return IsJumpOpcode(getOp()); } bool isBackedge() const { return IsBackedgePC(rawBytecode_); } bool isBackedgeForLoophead(BytecodeLocation loopHead) const { return IsBackedgeForLoopHead(rawBytecode_, loopHead.rawBytecode_); } bool opHasIC() const { return BytecodeOpHasIC(getOp()); } bool fallsThrough() const { return BytecodeFallsThrough(getOp()); } uint32_t icIndex() const { return GET_ICINDEX(rawBytecode_); } uint32_t local() const { return GET_LOCALNO(rawBytecode_); } uint16_t arg() const { return GET_ARGNO(rawBytecode_); } bool isEqualityOp() const { return IsEqualityOp(getOp()); } bool isStrictEqualityOp() const { return IsStrictEqualityOp(getOp()); } bool isStrictSetOp() const { return IsStrictSetPC(rawBytecode_); } bool isNameOp() const { return IsNameOp(getOp()); } bool isSpreadOp() const { return IsSpreadOp(getOp()); } bool isInvokeOp() const { return IsInvokeOp(getOp()); } bool isGetPropOp() const { return IsGetPropOp(getOp()); } bool isGetElemOp() const { return IsGetElemOp(getOp()); } bool isSetPropOp() const { return IsSetPropOp(getOp()); } bool isSetElemOp() const { return IsSetElemOp(getOp()); } AsyncFunctionResolveKind getAsyncFunctionResolveKind() { return AsyncFunctionResolveKind(GET_UINT8(rawBytecode_)); } bool resultIsPopped() const { MOZ_ASSERT(StackDefs(rawBytecode_) == 1); return BytecodeIsPopped(rawBytecode_); } // Accessors: JSOp getOp() const { return JSOp(*rawBytecode_); } BytecodeLocation getJumpTarget() const { MOZ_ASSERT(isJump()); return BytecodeLocation(*this, rawBytecode_ + GET_JUMP_OFFSET(rawBytecode_)); } // Return the 'low' parameter to the tableswitch opcode int32_t getTableSwitchLow() const { MOZ_ASSERT(is(JSOp::TableSwitch)); return GET_JUMP_OFFSET(rawBytecode_ + JUMP_OFFSET_LEN); } // Return the 'high' parameter to the tableswitch opcode int32_t getTableSwitchHigh() const { MOZ_ASSERT(is(JSOp::TableSwitch)); return GET_JUMP_OFFSET(rawBytecode_ + (2 * JUMP_OFFSET_LEN)); } uint32_t getPopCount() const { MOZ_ASSERT(is(JSOp::PopN)); return GET_UINT16(rawBytecode_); } uint32_t getDupAtIndex() const { MOZ_ASSERT(is(JSOp::DupAt)); return GET_UINT24(rawBytecode_); } uint8_t getPickDepth() const { MOZ_ASSERT(is(JSOp::Pick)); return GET_UINT8(rawBytecode_); } uint8_t getUnpickDepth() const { MOZ_ASSERT(is(JSOp::Unpick)); return GET_UINT8(rawBytecode_); } uint32_t getEnvCalleeNumHops() const { MOZ_ASSERT(is(JSOp::EnvCallee)); return GET_UINT8(rawBytecode_); } EnvironmentCoordinate getEnvironmentCoordinate() const { MOZ_ASSERT(JOF_OPTYPE(getOp()) == JOF_ENVCOORD); return EnvironmentCoordinate(rawBytecode_); } uint32_t getCallArgc() const { MOZ_ASSERT(JOF_OPTYPE(getOp()) == JOF_ARGC); return GET_ARGC(rawBytecode_); } uint32_t getInitElemArrayIndex() const { MOZ_ASSERT(is(JSOp::InitElemArray)); uint32_t index = GET_UINT32(rawBytecode_); MOZ_ASSERT(index <= INT32_MAX, "the bytecode emitter must never generate JSOp::InitElemArray " "with an index exceeding int32_t range"); return index; } FunctionPrefixKind getFunctionPrefixKind() const { MOZ_ASSERT(is(JSOp::SetFunName)); return FunctionPrefixKind(GET_UINT8(rawBytecode_)); } CheckIsObjectKind getCheckIsObjectKind() const { MOZ_ASSERT(is(JSOp::CheckIsObj)); return CheckIsObjectKind(GET_UINT8(rawBytecode_)); } BuiltinObjectKind getBuiltinObjectKind() const { MOZ_ASSERT(is(JSOp::BuiltinObject)); return BuiltinObjectKind(GET_UINT8(rawBytecode_)); } CompletionKind getCompletionKind() const { MOZ_ASSERT(is(JSOp::CloseIter)); return CompletionKind(GET_UINT8(rawBytecode_)); } uint32_t getNewArrayLength() const { MOZ_ASSERT(is(JSOp::NewArray)); return GET_UINT32(rawBytecode_); } int8_t getInt8() const { MOZ_ASSERT(is(JSOp::Int8)); return GET_INT8(rawBytecode_); } uint16_t getUint16() const { MOZ_ASSERT(is(JSOp::Uint16)); return GET_UINT16(rawBytecode_); } uint32_t getUint24() const { MOZ_ASSERT(is(JSOp::Uint24)); return GET_UINT24(rawBytecode_); } int32_t getInt32() const { MOZ_ASSERT(is(JSOp::Int32)); return GET_INT32(rawBytecode_); } uint32_t getResumeIndex() const { MOZ_ASSERT(is(JSOp::InitialYield) || is(JSOp::Yield) || is(JSOp::Await)); return GET_RESUMEINDEX(rawBytecode_); } Value getInlineValue() const { MOZ_ASSERT(is(JSOp::Double)); return GET_INLINE_VALUE(rawBytecode_); } GeneratorResumeKind resumeKind() { return ResumeKindFromPC(rawBytecode_); } ThrowMsgKind throwMsgKind() { MOZ_ASSERT(is(JSOp::ThrowMsg)); return static_cast(GET_UINT8(rawBytecode_)); } #ifdef DEBUG // To ease writing assertions bool isValid() const { return isValid(debugOnlyScript_); } bool isInBounds() const { return isInBounds(debugOnlyScript_); } #endif }; } // namespace js #endif