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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:
* 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 jit_JSJitFrameIter_h
#define jit_JSJitFrameIter_h
#include "mozilla/Maybe.h"
#include "jstypes.h"
#include "jit/JitCode.h"
#include "jit/MachineState.h"
#include "jit/Snapshots.h"
#include "js/ProfilingFrameIterator.h"
#include "vm/JSFunction.h"
#include "vm/JSScript.h"
namespace js {
class ArgumentsObject;
namespace jit {
enum class FrameType {
// A JS frame is analogous to a js::InterpreterFrame, representing one
// scripted function activation. IonJS frames are used by the optimizing
// compiler.
IonJS,
// JS frame used by the Baseline Interpreter and Baseline JIT.
BaselineJS,
// Frame pushed by Baseline stubs that make non-tail calls, so that the
// return address -> ICEntry mapping works.
BaselineStub,
// The entry frame is the initial prologue block transitioning from the VM
// into the Ion world.
CppToJSJit,
// A rectifier frame sits in between two JS frames, adapting argc != nargs
// mismatches in calls.
Rectifier,
// Ion IC calling a scripted getter/setter or a VMFunction.
IonICCall,
// An exit frame is necessary for transitioning from a JS frame into C++.
// From within C++, an exit frame is always the last frame in any
// JitActivation.
Exit,
// A bailout frame is a special IonJS jit frame after a bailout, and before
// the reconstruction of the BaselineJS frame. From within C++, a bailout
// frame is always the last frame in a JitActivation iff the bailout frame
// information is recorded on the JitActivation.
Bailout,
// A wasm to JS frame is constructed during fast calls from wasm to the JS
// jits, used as a marker to interleave JS jit and wasm frames. From the
// point of view of JS JITs, this is just another kind of entry frame.
WasmToJSJit,
// A JS to wasm frame is constructed during fast calls from any JS jits to
// wasm, and is a special kind of exit frame that doesn't have the exit
// footer. From the point of view of the jit, it can be skipped as an exit.
JSJitToWasm,
};
enum ReadFrameArgsBehavior {
// Only read formals (i.e. [0 ... callee()->nargs]
ReadFrame_Formals,
// Only read overflown args (i.e. [callee()->nargs ... numActuals()]
ReadFrame_Overflown,
// Read all args (i.e. [0 ... numActuals()])
ReadFrame_Actuals
};
class CommonFrameLayout;
class JitFrameLayout;
class ExitFrameLayout;
class BaselineFrame;
class JitActivation;
class SafepointIndex;
class OsiIndex;
// Iterate over the JIT stack to assert that all invariants are respected.
// - Check that all entry frames are aligned on JitStackAlignment.
// - Check that all rectifier frames keep the JitStackAlignment.
void AssertJitStackInvariants(JSContext* cx);
// A JSJitFrameIter can iterate over a linear frame group of JS jit frames
// only. It will stop at the first frame that is not of the same kind, or at
// the end of an activation.
//
// If you want to handle every kind of frames (including wasm frames), use
// JitFrameIter. If you want to skip interleaved frames of other kinds, use
// OnlyJSJitFrameIter.
class JSJitFrameIter {
protected:
uint8_t* current_;
FrameType type_;
uint8_t* resumePCinCurrentFrame_;
// Size of the current Baseline frame. Equivalent to
// BaselineFrame::debugFrameSize_ in debug builds.
mozilla::Maybe<uint32_t> baselineFrameSize_;
private:
mutable const SafepointIndex* cachedSafepointIndex_;
const JitActivation* activation_;
void dumpBaseline() const;
public:
// See comment above the class.
explicit JSJitFrameIter(const JitActivation* activation);
// A constructor specialized for jit->wasm frames, which starts at a
// specific FP.
JSJitFrameIter(const JitActivation* activation, FrameType frameType,
uint8_t* fp);
void setResumePCInCurrentFrame(uint8_t* newAddr) {
resumePCinCurrentFrame_ = newAddr;
}
// Current frame information.
FrameType type() const { return type_; }
uint8_t* fp() const { return current_; }
const JitActivation* activation() const { return activation_; }
CommonFrameLayout* current() const { return (CommonFrameLayout*)current_; }
inline uint8_t* returnAddress() const;
// Return the pointer of the JitFrame, the iterator is assumed to be settled
// on a scripted frame.
JitFrameLayout* jsFrame() const;
inline ExitFrameLayout* exitFrame() const;
// Returns whether the JS frame has been invalidated and, if so,
// places the invalidated Ion script in |ionScript|.
bool checkInvalidation(IonScript** ionScript) const;
bool checkInvalidation() const;
bool isExitFrame() const { return type_ == FrameType::Exit; }
bool isScripted() const {
return type_ == FrameType::BaselineJS || type_ == FrameType::IonJS ||
type_ == FrameType::Bailout;
}
bool isBaselineJS() const { return type_ == FrameType::BaselineJS; }
bool isIonScripted() const {
return type_ == FrameType::IonJS || type_ == FrameType::Bailout;
}
bool isIonJS() const { return type_ == FrameType::IonJS; }
bool isIonICCall() const { return type_ == FrameType::IonICCall; }
bool isBailoutJS() const { return type_ == FrameType::Bailout; }
bool isBaselineStub() const { return type_ == FrameType::BaselineStub; }
bool isRectifier() const { return type_ == FrameType::Rectifier; }
bool isBareExit() const;
bool isUnwoundJitExit() const;
template <typename T>
bool isExitFrameLayout() const;
static bool isEntry(FrameType type) {
return type == FrameType::CppToJSJit || type == FrameType::WasmToJSJit;
}
bool isEntry() const { return isEntry(type_); }
bool isFunctionFrame() const;
bool isConstructing() const;
void* calleeToken() const;
JSFunction* callee() const;
JSFunction* maybeCallee() const;
unsigned numActualArgs() const;
JSScript* script() const;
JSScript* maybeForwardedScript() const;
void baselineScriptAndPc(JSScript** scriptRes, jsbytecode** pcRes) const;
Value* actualArgs() const;
// Returns the address of the next instruction that will execute in this
// frame, once control returns to this frame.
uint8_t* resumePCinCurrentFrame() const { return resumePCinCurrentFrame_; }
// Previous frame information extracted from the current frame.
inline FrameType prevType() const;
uint8_t* prevFp() const;
// Functions used to iterate on frames. When prevType is an entry,
// the current frame is the last JS Jit frame.
bool done() const { return isEntry(); }
void operator++();
// Returns the IonScript associated with this JS frame.
IonScript* ionScript() const;
// Returns the IonScript associated with this JS frame; the frame must
// not be invalidated.
IonScript* ionScriptFromCalleeToken() const;
// Returns the Safepoint associated with this JS frame. Incurs a lookup
// overhead.
const SafepointIndex* safepoint() const;
// Returns the OSI index associated with this JS frame. Incurs a lookup
// overhead.
const OsiIndex* osiIndex() const;
// Returns the Snapshot offset associated with this JS frame. Incurs a
// lookup overhead.
SnapshotOffset snapshotOffset() const;
uintptr_t* spillBase() const;
MachineState machineState() const;
template <class Op>
void unaliasedForEachActual(Op op, ReadFrameArgsBehavior behavior) const {
MOZ_ASSERT(isBaselineJS());
unsigned nactual = numActualArgs();
unsigned start, end;
switch (behavior) {
case ReadFrame_Formals:
start = 0;
end = callee()->nargs();
break;
case ReadFrame_Overflown:
start = callee()->nargs();
end = nactual;
break;
case ReadFrame_Actuals:
start = 0;
end = nactual;
}
Value* argv = actualArgs();
for (unsigned i = start; i < end; i++) {
op(argv[i]);
}
}
void dump() const;
inline BaselineFrame* baselineFrame() const;
// Returns the number of local and expression stack Values for the current
// Baseline frame.
inline uint32_t baselineFrameNumValueSlots() const;
// This function isn't used, but we keep it here (debug-only) because it is
// helpful when chasing issues with the jitcode map.
#ifdef DEBUG
bool verifyReturnAddressUsingNativeToBytecodeMap();
#else
bool verifyReturnAddressUsingNativeToBytecodeMap() { return true; }
#endif
};
class JitcodeGlobalTable;
class JSJitProfilingFrameIterator {
uint8_t* fp_;
// See JS::ProfilingFrameIterator::endStackAddress_ comment.
void* endStackAddress_ = nullptr;
FrameType type_;
void* resumePCinCurrentFrame_;
inline JSScript* frameScript() const;
[[nodiscard]] bool tryInitWithPC(void* pc);
[[nodiscard]] bool tryInitWithTable(JitcodeGlobalTable* table, void* pc,
bool forLastCallSite);
void moveToNextFrame(CommonFrameLayout* frame);
public:
JSJitProfilingFrameIterator(JSContext* cx, void* pc, void* sp);
explicit JSJitProfilingFrameIterator(CommonFrameLayout* exitFP);
void operator++();
bool done() const { return fp_ == nullptr; }
const char* baselineInterpreterLabel() const;
void baselineInterpreterScriptPC(JSScript** script, jsbytecode** pc,
uint64_t* realmID) const;
void* fp() const {
MOZ_ASSERT(!done());
return fp_;
}
inline JitFrameLayout* framePtr() const;
void* stackAddress() const { return fp(); }
FrameType frameType() const {
MOZ_ASSERT(!done());
return type_;
}
void* resumePCinCurrentFrame() const {
MOZ_ASSERT(!done());
return resumePCinCurrentFrame_;
}
void* endStackAddress() const { return endStackAddress_; }
};
class RInstructionResults {
// Vector of results of recover instructions.
typedef mozilla::Vector<HeapPtr<Value>, 1, SystemAllocPolicy> Values;
UniquePtr<Values> results_;
// The frame pointer is used as a key to check if the current frame already
// bailed out.
JitFrameLayout* fp_;
// Record if we tried and succeed at allocating and filling the vector of
// recover instruction results, if needed. This flag is needed in order to
// avoid evaluating the recover instruction twice.
bool initialized_;
public:
explicit RInstructionResults(JitFrameLayout* fp);
RInstructionResults(RInstructionResults&& src);
RInstructionResults& operator=(RInstructionResults&& rhs);
~RInstructionResults();
[[nodiscard]] bool init(JSContext* cx, uint32_t numResults);
bool isInitialized() const;
size_t length() const;
JitFrameLayout* frame() const;
HeapPtr<Value>& operator[](size_t index);
void trace(JSTracer* trc);
};
struct MaybeReadFallback {
enum FallbackConsequence { Fallback_Invalidate, Fallback_DoNothing };
JSContext* maybeCx = nullptr;
JitActivation* activation = nullptr;
const JSJitFrameIter* frame = nullptr;
const FallbackConsequence consequence = Fallback_Invalidate;
MaybeReadFallback() = default;
MaybeReadFallback(JSContext* cx, JitActivation* activation,
const JSJitFrameIter* frame,
FallbackConsequence consequence = Fallback_Invalidate)
: maybeCx(cx),
activation(activation),
frame(frame),
consequence(consequence) {}
bool canRecoverResults() { return maybeCx; }
};
class RResumePoint;
// Reads frame information in snapshot-encoding order (that is, outermost frame
// to innermost frame).
class SnapshotIterator {
protected:
SnapshotReader snapshot_;
RecoverReader recover_;
JitFrameLayout* fp_;
const MachineState* machine_;
IonScript* ionScript_;
RInstructionResults* instructionResults_;
enum class ReadMethod : bool {
// Read the normal value.
Normal,
// Read the default value, or the normal value if there is no default.
AlwaysDefault,
};
private:
// Read a spilled register from the machine state.
bool hasRegister(Register reg) const { return machine_->has(reg); }
uintptr_t fromRegister(Register reg) const { return machine_->read(reg); }
bool hasRegister(FloatRegister reg) const { return machine_->has(reg); }
template <typename T>
T fromRegister(FloatRegister reg) const {
return machine_->read<T>(reg);
}
// Read an uintptr_t from the stack.
bool hasStack(int32_t offset) const { return true; }
uintptr_t fromStack(int32_t offset) const;
bool hasInstructionResult(uint32_t index) const {
return instructionResults_;
}
bool hasInstructionResults() const { return instructionResults_; }
Value fromInstructionResult(uint32_t index) const;
Value allocationValue(const RValueAllocation& a,
ReadMethod rm = ReadMethod::Normal);
[[nodiscard]] bool allocationReadable(const RValueAllocation& a,
ReadMethod rm = ReadMethod::Normal);
void writeAllocationValuePayload(const RValueAllocation& a, const Value& v);
void warnUnreadableAllocation();
public:
// Handle iterating over RValueAllocations of the snapshots.
inline RValueAllocation readAllocation() {
MOZ_ASSERT(moreAllocations());
return snapshot_.readAllocation();
}
void skip() { snapshot_.skipAllocation(); }
const RResumePoint* resumePoint() const;
const RInstruction* instruction() const { return recover_.instruction(); }
uint32_t numAllocations() const;
inline bool moreAllocations() const {
return snapshot_.numAllocationsRead() < numAllocations();
}
JitFrameLayout* frame() { return fp_; };
// Used by recover instruction to store the value back into the instruction
// results array.
void storeInstructionResult(const Value& v);
public:
// Exhibits frame properties contained in the snapshot.
uint32_t pcOffset() const;
ResumeMode resumeMode() const;
bool resumeAfter() const {
// Calls in outer frames are never considered resume-after.
MOZ_ASSERT_IF(moreFrames(), !IsResumeAfter(resumeMode()));
return IsResumeAfter(resumeMode());
}
inline BailoutKind bailoutKind() const { return snapshot_.bailoutKind(); }
public:
// Read the next instruction available and get ready to either skip it or
// evaluate it.
inline void nextInstruction() {
MOZ_ASSERT(snapshot_.numAllocationsRead() == numAllocations());
recover_.nextInstruction();
snapshot_.resetNumAllocationsRead();
}
// Skip an Instruction by walking to the next instruction and by skipping
// all the allocations corresponding to this instruction.
void skipInstruction();
inline bool moreInstructions() const { return recover_.moreInstructions(); }
// Register a vector used for storing the results of the evaluation of
// recover instructions. This vector should be registered before the
// beginning of the iteration. This function is in charge of allocating
// enough space for all instructions results, and return false iff it fails.
[[nodiscard]] bool initInstructionResults(MaybeReadFallback& fallback);
protected:
// This function is used internally for computing the result of the recover
// instructions.
[[nodiscard]] bool computeInstructionResults(
JSContext* cx, RInstructionResults* results) const;
public:
// Handle iterating over frames of the snapshots.
void nextFrame();
void settleOnFrame();
inline bool moreFrames() const {
// The last instruction is recovering the innermost frame, so as long as
// there is more instruction there is necesseray more frames.
return moreInstructions();
}
public:
// Connect all informations about the current script in order to recover the
// content of baseline frames.
SnapshotIterator(const JSJitFrameIter& iter,
const MachineState* machineState);
SnapshotIterator();
Value read() { return allocationValue(readAllocation()); }
// Read the |Normal| value unless it is not available and that the snapshot
// provides a |Default| value. This is useful to avoid invalidations of the
// frame while we are only interested in a few properties which are provided
// by the |Default| value.
Value readWithDefault(RValueAllocation* alloc) {
*alloc = RValueAllocation();
RValueAllocation a = readAllocation();
if (allocationReadable(a)) {
return allocationValue(a);
}
*alloc = a;
return allocationValue(a, ReadMethod::AlwaysDefault);
}
Value maybeRead(const RValueAllocation& a, MaybeReadFallback& fallback);
Value maybeRead(MaybeReadFallback& fallback) {
RValueAllocation a = readAllocation();
return maybeRead(a, fallback);
}
bool tryRead(Value* result);
void traceAllocation(JSTracer* trc);
template <class Op>
void readFunctionFrameArgs(Op& op, ArgumentsObject** argsObj, Value* thisv,
unsigned start, unsigned end, JSScript* script,
MaybeReadFallback& fallback) {
// Assumes that the common frame arguments have already been read.
if (script->needsArgsObj()) {
if (argsObj) {
Value v = maybeRead(fallback);
if (v.isObject()) {
*argsObj = &v.toObject().as<ArgumentsObject>();
}
} else {
skip();
}
}
if (thisv) {
*thisv = maybeRead(fallback);
} else {
skip();
}
unsigned i = 0;
if (end < start) {
i = start;
}
for (; i < start; i++) {
skip();
}
for (; i < end; i++) {
// We are not always able to read values from the snapshots, some values
// such as non-gc things may still be live in registers and cause an
// error while reading the machine state.
Value v = maybeRead(fallback);
op(v);
}
}
// Iterate over all the allocations and return only the value of the
// allocation located at one index.
Value maybeReadAllocByIndex(size_t index);
#ifdef TRACK_SNAPSHOTS
void spewBailingFrom() const { snapshot_.spewBailingFrom(); }
#endif
};
// Reads frame information in callstack order (that is, innermost frame to
// outermost frame).
class InlineFrameIterator {
const JSJitFrameIter* frame_;
SnapshotIterator start_;
SnapshotIterator si_;
uint32_t framesRead_;
// When the inline-frame-iterator is created, this variable is defined to
// UINT32_MAX. Then the first iteration of findNextFrame, which settle on
// the innermost frame, is used to update this counter to the number of
// frames contained in the recover buffer.
uint32_t frameCount_;
// The |calleeTemplate_| fields contains either the JSFunction or the
// template from which it is supposed to be cloned. The |calleeRVA_| is an
// Invalid value allocation, if the |calleeTemplate_| field is the effective
// JSFunction, and not its template. On the other hand, any other value
// allocation implies that the |calleeTemplate_| is the template JSFunction
// from which the effective one would be derived and cached by the Recover
// instruction result.
RootedFunction calleeTemplate_;
RValueAllocation calleeRVA_;
RootedScript script_;
jsbytecode* pc_;
uint32_t numActualArgs_;
// Register state, used by all snapshot iterators.
MachineState machine_;
struct Nop {
void operator()(const Value& v) {}
};
private:
void findNextFrame();
JSObject* computeEnvironmentChain(const Value& envChainValue,
MaybeReadFallback& fallback,
bool* hasInitialEnv = nullptr) const;
public:
InlineFrameIterator(JSContext* cx, const JSJitFrameIter* iter);
InlineFrameIterator(JSContext* cx, const InlineFrameIterator* iter);
bool more() const { return frame_ && framesRead_ < frameCount_; }
// Due to optimizations, we are not always capable of reading the callee of
// inlined frames without invalidating the IonCode. This function might
// return either the effective callee of the JSFunction which might be used
// to create it.
//
// As such, the |calleeTemplate()| can be used to read most of the metadata
// which are conserved across clones.
JSFunction* calleeTemplate() const {
MOZ_ASSERT(isFunctionFrame());
return calleeTemplate_;
}
JSFunction* maybeCalleeTemplate() const { return calleeTemplate_; }
JSFunction* callee(MaybeReadFallback& fallback) const;
unsigned numActualArgs() const {
// The number of actual arguments for inline frames is determined by this
// iterator based on the caller's bytecode instruction (Call, FunCall,
// GetProp/SetProp, etc). For the outer function it's stored in the stack
// frame.
if (more()) {
return numActualArgs_;
}
return frame_->numActualArgs();
}
template <class ArgOp, class LocalOp>
void readFrameArgsAndLocals(JSContext* cx, ArgOp& argOp, LocalOp& localOp,
JSObject** envChain, bool* hasInitialEnv,
Value* rval, ArgumentsObject** argsObj,
Value* thisv, ReadFrameArgsBehavior behavior,
MaybeReadFallback& fallback) const {
SnapshotIterator s(si_);
// Read the env chain.
if (envChain) {
Value envChainValue = s.maybeRead(fallback);
*envChain =
computeEnvironmentChain(envChainValue, fallback, hasInitialEnv);
} else {
s.skip();
}
// Read return value.
if (rval) {
*rval = s.maybeRead(fallback);
} else {
s.skip();
}
// Read arguments, which only function frames have.
if (isFunctionFrame()) {
unsigned nactual = numActualArgs();
unsigned nformal = calleeTemplate()->nargs();
// Get the non overflown arguments, which are taken from the inlined
// frame, because it will have the updated value when JSOp::SetArg is
// done.
if (behavior != ReadFrame_Overflown) {
s.readFunctionFrameArgs(argOp, argsObj, thisv, 0, nformal, script(),
fallback);
}
if (behavior != ReadFrame_Formals) {
if (more()) {
// There is still a parent frame of this inlined frame. All
// arguments (also the overflown) are the last pushed values
// in the parent frame. To get the overflown arguments, we
// need to take them from there.
// The overflown arguments are not available in current frame.
// They are the last pushed arguments in the parent frame of
// this inlined frame.
InlineFrameIterator it(cx, this);
++it;
unsigned argsObjAdj = it.script()->needsArgsObj() ? 1 : 0;
bool hasNewTarget = isConstructing();
SnapshotIterator parent_s(it.snapshotIterator());
// Skip over all slots until we get to the last slots
// (= arguments slots of callee) the +3 is for [this], [returnvalue],
// [envchain], and maybe +1 for [argsObj]
MOZ_ASSERT(parent_s.numAllocations() >=
nactual + 3 + argsObjAdj + hasNewTarget);
unsigned skip = parent_s.numAllocations() - nactual - 3 - argsObjAdj -
hasNewTarget;
for (unsigned j = 0; j < skip; j++) {
parent_s.skip();
}
// Get the overflown arguments
parent_s.skip(); // env chain
parent_s.skip(); // return value
parent_s.readFunctionFrameArgs(argOp, nullptr, nullptr, nformal,
nactual, it.script(), fallback);
} else {
// There is no parent frame to this inlined frame, we can read
// from the frame's Value vector directly.
Value* argv = frame_->actualArgs();
for (unsigned i = nformal; i < nactual; i++) {
argOp(argv[i]);
}
}
}
}
// At this point we've read all the formals in s, and can read the
// locals.
for (unsigned i = 0; i < script()->nfixed(); i++) {
localOp(s.maybeRead(fallback));
}
}
template <class Op>
void unaliasedForEachActual(JSContext* cx, Op op,
ReadFrameArgsBehavior behavior,
MaybeReadFallback& fallback) const {
Nop nop;
readFrameArgsAndLocals(cx, op, nop, nullptr, nullptr, nullptr, nullptr,
nullptr, behavior, fallback);
}
JSScript* script() const { return script_; }
jsbytecode* pc() const { return pc_; }
SnapshotIterator snapshotIterator() const { return si_; }
bool isFunctionFrame() const;
bool isModuleFrame() const;
bool isConstructing() const;
JSObject* environmentChain(MaybeReadFallback& fallback,
bool* hasInitialEnvironment = nullptr) const {
SnapshotIterator s(si_);
// envChain
Value v = s.maybeRead(fallback);
return computeEnvironmentChain(v, fallback, hasInitialEnvironment);
}
Value thisArgument(MaybeReadFallback& fallback) const {
SnapshotIterator s(si_);
// envChain
s.skip();
// return value
s.skip();
// Arguments object.
if (script()->needsArgsObj()) {
s.skip();
}
return s.maybeRead(fallback);
}
InlineFrameIterator& operator++() {
findNextFrame();
return *this;
}
void dump() const;
void resetOn(const JSJitFrameIter* iter);
const JSJitFrameIter& frame() const { return *frame_; }
// Inline frame number, 0 for the outermost (non-inlined) frame.
size_t frameNo() const { return frameCount() - framesRead_; }
size_t frameCount() const {
MOZ_ASSERT(frameCount_ != UINT32_MAX);
return frameCount_;
}
private:
InlineFrameIterator() = delete;
InlineFrameIterator(const InlineFrameIterator& iter) = delete;
};
} // namespace jit
} // namespace js
#endif /* jit_JSJitFrameIter_h */
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