/* -*- 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/. */ #include "jit/BaselineJIT.h" #include "mozilla/BinarySearch.h" #include "mozilla/CheckedInt.h" #include "mozilla/DebugOnly.h" #include "mozilla/MemoryReporting.h" #include #include "debugger/DebugAPI.h" #include "gc/GCContext.h" #include "gc/PublicIterators.h" #include "jit/AutoWritableJitCode.h" #include "jit/BaselineCodeGen.h" #include "jit/BaselineIC.h" #include "jit/CalleeToken.h" #include "jit/JitCommon.h" #include "jit/JitRuntime.h" #include "jit/JitSpewer.h" #include "jit/MacroAssembler.h" #include "js/friend/StackLimits.h" // js::AutoCheckRecursionLimit #include "vm/Interpreter.h" #include "debugger/DebugAPI-inl.h" #include "gc/GC-inl.h" #include "jit/JitScript-inl.h" #include "vm/GeckoProfiler-inl.h" #include "vm/JSScript-inl.h" #include "vm/Stack-inl.h" using mozilla::BinarySearchIf; using mozilla::CheckedInt; using mozilla::DebugOnly; using namespace js; using namespace js::jit; void ICStubSpace::freeAllAfterMinorGC(Zone* zone) { if (zone->isAtomsZone()) { MOZ_ASSERT(allocator_.isEmpty()); } else { JSRuntime* rt = zone->runtimeFromMainThread(); rt->gc.queueAllLifoBlocksForFreeAfterMinorGC(&allocator_); } } static bool CheckFrame(InterpreterFrame* fp) { if (fp->isDebuggerEvalFrame()) { // Debugger eval-in-frame. These are likely short-running scripts so // don't bother compiling them for now. JitSpew(JitSpew_BaselineAbort, "debugger frame"); return false; } if (fp->isFunctionFrame() && fp->numActualArgs() > BASELINE_MAX_ARGS_LENGTH) { // Fall back to the interpreter to avoid running out of stack space. JitSpew(JitSpew_BaselineAbort, "Too many arguments (%u)", fp->numActualArgs()); return false; } return true; } struct EnterJitData { explicit EnterJitData(JSContext* cx) : jitcode(nullptr), osrFrame(nullptr), calleeToken(nullptr), maxArgv(nullptr), maxArgc(0), numActualArgs(0), osrNumStackValues(0), envChain(cx), result(cx), constructing(false) {} uint8_t* jitcode; InterpreterFrame* osrFrame; void* calleeToken; Value* maxArgv; unsigned maxArgc; unsigned numActualArgs; unsigned osrNumStackValues; RootedObject envChain; RootedValue result; bool constructing; }; static JitExecStatus EnterBaseline(JSContext* cx, EnterJitData& data) { MOZ_ASSERT(data.osrFrame); // Check for potential stack overflow before OSR-ing. uint32_t extra = BaselineFrame::Size() + (data.osrNumStackValues * sizeof(Value)); AutoCheckRecursionLimit recursion(cx); if (!recursion.checkWithExtra(cx, extra)) { return JitExec_Aborted; } #ifdef DEBUG // Assert we don't GC before entering JIT code. A GC could discard JIT code // or move the function stored in the CalleeToken (it won't be traced at // this point). We use Maybe<> here so we can call reset() to call the // AutoAssertNoGC destructor before we enter JIT code. mozilla::Maybe nogc; nogc.emplace(cx); #endif MOZ_ASSERT(IsBaselineInterpreterEnabled()); MOZ_ASSERT(CheckFrame(data.osrFrame)); EnterJitCode enter = cx->runtime()->jitRuntime()->enterJit(); // Caller must construct |this| before invoking the function. MOZ_ASSERT_IF(data.constructing, data.maxArgv[0].isObject() || data.maxArgv[0].isMagic(JS_UNINITIALIZED_LEXICAL)); data.result.setInt32(data.numActualArgs); { AssertRealmUnchanged aru(cx); ActivationEntryMonitor entryMonitor(cx, data.calleeToken); JitActivation activation(cx); data.osrFrame->setRunningInJit(); #ifdef DEBUG nogc.reset(); #endif // Single transition point from Interpreter to Baseline. CALL_GENERATED_CODE(enter, data.jitcode, data.maxArgc, data.maxArgv, data.osrFrame, data.calleeToken, data.envChain.get(), data.osrNumStackValues, data.result.address()); data.osrFrame->clearRunningInJit(); } // Jit callers wrap primitive constructor return, except for derived // class constructors, which are forced to do it themselves. if (!data.result.isMagic() && data.constructing && data.result.isPrimitive()) { MOZ_ASSERT(data.maxArgv[0].isObject()); data.result = data.maxArgv[0]; } // Release temporary buffer used for OSR into Ion. cx->runtime()->jitRuntime()->freeIonOsrTempData(); MOZ_ASSERT_IF(data.result.isMagic(), data.result.isMagic(JS_ION_ERROR)); return data.result.isMagic() ? JitExec_Error : JitExec_Ok; } JitExecStatus jit::EnterBaselineInterpreterAtBranch(JSContext* cx, InterpreterFrame* fp, jsbytecode* pc) { MOZ_ASSERT(JSOp(*pc) == JSOp::LoopHead); EnterJitData data(cx); // Use the entry point that skips the debug trap because the C++ interpreter // already handled this for the current op. const BaselineInterpreter& interp = cx->runtime()->jitRuntime()->baselineInterpreter(); data.jitcode = interp.interpretOpNoDebugTrapAddr().value; data.osrFrame = fp; data.osrNumStackValues = fp->script()->nfixed() + cx->interpreterRegs().stackDepth(); if (fp->isFunctionFrame()) { data.constructing = fp->isConstructing(); data.numActualArgs = fp->numActualArgs(); data.maxArgc = std::max(fp->numActualArgs(), fp->numFormalArgs()) + 1; // +1 = include |this| data.maxArgv = fp->argv() - 1; // -1 = include |this| data.envChain = nullptr; data.calleeToken = CalleeToToken(&fp->callee(), data.constructing); } else { data.constructing = false; data.numActualArgs = 0; data.maxArgc = 0; data.maxArgv = nullptr; data.envChain = fp->environmentChain(); data.calleeToken = CalleeToToken(fp->script()); } JitExecStatus status = EnterBaseline(cx, data); if (status != JitExec_Ok) { return status; } fp->setReturnValue(data.result); return JitExec_Ok; } MethodStatus jit::BaselineCompile(JSContext* cx, JSScript* script, bool forceDebugInstrumentation) { cx->check(script); MOZ_ASSERT(!script->hasBaselineScript()); MOZ_ASSERT(script->canBaselineCompile()); MOZ_ASSERT(IsBaselineJitEnabled(cx)); AutoGeckoProfilerEntry pseudoFrame( cx, "Baseline script compilation", JS::ProfilingCategoryPair::JS_BaselineCompilation); TempAllocator temp(&cx->tempLifoAlloc()); JitContext jctx(cx); BaselineCompiler compiler(cx, temp, script); if (!compiler.init()) { ReportOutOfMemory(cx); return Method_Error; } if (forceDebugInstrumentation) { compiler.setCompileDebugInstrumentation(); } MethodStatus status = compiler.compile(); MOZ_ASSERT_IF(status == Method_Compiled, script->hasBaselineScript()); MOZ_ASSERT_IF(status != Method_Compiled, !script->hasBaselineScript()); if (status == Method_CantCompile) { script->disableBaselineCompile(); } return status; } static MethodStatus CanEnterBaselineJIT(JSContext* cx, HandleScript script, AbstractFramePtr osrSourceFrame) { // Skip if the script has been disabled. if (!script->canBaselineCompile()) { return Method_Skipped; } if (!IsBaselineJitEnabled(cx)) { script->disableBaselineCompile(); return Method_CantCompile; } // This check is needed in the following corner case. Consider a function h, // // function h(x) { // if (!x) // return; // h(false); // for (var i = 0; i < N; i++) // /* do stuff */ // } // // Suppose h is not yet compiled in baseline and is executing in the // interpreter. Let this interpreter frame be f_older. The debugger marks // f_older as isDebuggee. At the point of the recursive call h(false), h is // compiled in baseline without debug instrumentation, pushing a baseline // frame f_newer. The debugger never flags f_newer as isDebuggee, and never // recompiles h. When the recursive call returns and execution proceeds to // the loop, the interpreter attempts to OSR into baseline. Since h is // already compiled in baseline, execution jumps directly into baseline // code. This is incorrect as h's baseline script does not have debug // instrumentation. if (osrSourceFrame && osrSourceFrame.isDebuggee() && !DebugAPI::ensureExecutionObservabilityOfOsrFrame(cx, osrSourceFrame)) { return Method_Error; } if (script->length() > BaselineMaxScriptLength) { script->disableBaselineCompile(); return Method_CantCompile; } if (script->nslots() > BaselineMaxScriptSlots) { script->disableBaselineCompile(); return Method_CantCompile; } if (script->hasBaselineScript()) { return Method_Compiled; } // Check script warm-up counter. if (script->getWarmUpCount() <= JitOptions.baselineJitWarmUpThreshold) { return Method_Skipped; } // Check this before calling ensureJitRealmExists, so we're less // likely to report OOM in JSRuntime::createJitRuntime. if (!CanLikelyAllocateMoreExecutableMemory()) { return Method_Skipped; } if (!cx->realm()->ensureJitRealmExists(cx)) { return Method_Error; } if (script->hasForceInterpreterOp()) { script->disableBaselineCompile(); return Method_CantCompile; } // Frames can be marked as debuggee frames independently of its underlying // script being a debuggee script, e.g., when performing // Debugger.Frame.prototype.eval. bool forceDebugInstrumentation = osrSourceFrame && osrSourceFrame.isDebuggee(); return BaselineCompile(cx, script, forceDebugInstrumentation); } bool jit::CanBaselineInterpretScript(JSScript* script) { MOZ_ASSERT(IsBaselineInterpreterEnabled()); if (script->hasForceInterpreterOp()) { return false; } if (script->nslots() > BaselineMaxScriptSlots) { // Avoid overrecursion exceptions when the script has a ton of stack slots // by forcing such scripts to run in the C++ interpreter with heap-allocated // stack frames. return false; } return true; } static MethodStatus CanEnterBaselineInterpreter(JSContext* cx, JSScript* script) { MOZ_ASSERT(IsBaselineInterpreterEnabled()); if (script->hasJitScript()) { return Method_Compiled; } if (!CanBaselineInterpretScript(script)) { return Method_CantCompile; } // Check script warm-up counter. if (script->getWarmUpCount() <= JitOptions.baselineInterpreterWarmUpThreshold) { return Method_Skipped; } if (!cx->realm()->ensureJitRealmExists(cx)) { return Method_Error; } AutoKeepJitScripts keepJitScript(cx); if (!script->ensureHasJitScript(cx, keepJitScript)) { return Method_Error; } return Method_Compiled; } MethodStatus jit::CanEnterBaselineInterpreterAtBranch(JSContext* cx, InterpreterFrame* fp) { if (!CheckFrame(fp)) { return Method_CantCompile; } // JITs do not respect the debugger's OnNativeCall hook, so JIT execution is // disabled if this hook might need to be called. if (cx->insideDebuggerEvaluationWithOnNativeCallHook) { return Method_CantCompile; } return CanEnterBaselineInterpreter(cx, fp->script()); } template MethodStatus jit::CanEnterBaselineMethod(JSContext* cx, RunState& state) { if (state.isInvoke()) { InvokeState& invoke = *state.asInvoke(); if (invoke.args().length() > BASELINE_MAX_ARGS_LENGTH) { JitSpew(JitSpew_BaselineAbort, "Too many arguments (%u)", invoke.args().length()); return Method_CantCompile; } } else { if (state.asExecute()->isDebuggerEval()) { JitSpew(JitSpew_BaselineAbort, "debugger frame"); return Method_CantCompile; } } RootedScript script(cx, state.script()); switch (Tier) { case BaselineTier::Interpreter: return CanEnterBaselineInterpreter(cx, script); case BaselineTier::Compiler: return CanEnterBaselineJIT(cx, script, /* osrSourceFrame = */ NullFramePtr()); } MOZ_CRASH("Unexpected tier"); } template MethodStatus jit::CanEnterBaselineMethod( JSContext* cx, RunState& state); template MethodStatus jit::CanEnterBaselineMethod( JSContext* cx, RunState& state); bool jit::BaselineCompileFromBaselineInterpreter(JSContext* cx, BaselineFrame* frame, uint8_t** res) { MOZ_ASSERT(frame->runningInInterpreter()); RootedScript script(cx, frame->script()); jsbytecode* pc = frame->interpreterPC(); MOZ_ASSERT(pc == script->code() || JSOp(*pc) == JSOp::LoopHead); MethodStatus status = CanEnterBaselineJIT(cx, script, /* osrSourceFrame = */ frame); switch (status) { case Method_Error: return false; case Method_CantCompile: case Method_Skipped: *res = nullptr; return true; case Method_Compiled: { if (JSOp(*pc) == JSOp::LoopHead) { MOZ_ASSERT(pc > script->code(), "Prologue vs OSR cases must not be ambiguous"); BaselineScript* baselineScript = script->baselineScript(); uint32_t pcOffset = script->pcToOffset(pc); *res = baselineScript->nativeCodeForOSREntry(pcOffset); } else { *res = script->baselineScript()->warmUpCheckPrologueAddr(); } frame->prepareForBaselineInterpreterToJitOSR(); return true; } } MOZ_CRASH("Unexpected status"); } BaselineScript* BaselineScript::New(JSContext* cx, uint32_t warmUpCheckPrologueOffset, uint32_t profilerEnterToggleOffset, uint32_t profilerExitToggleOffset, size_t retAddrEntries, size_t osrEntries, size_t debugTrapEntries, size_t resumeEntries) { // Compute size including trailing arrays. CheckedInt size = sizeof(BaselineScript); size += CheckedInt(resumeEntries) * sizeof(uintptr_t); size += CheckedInt(retAddrEntries) * sizeof(RetAddrEntry); size += CheckedInt(osrEntries) * sizeof(OSREntry); size += CheckedInt(debugTrapEntries) * sizeof(DebugTrapEntry); if (!size.isValid()) { ReportAllocationOverflow(cx); return nullptr; } // Allocate contiguous raw buffer. void* raw = cx->pod_malloc(size.value()); MOZ_ASSERT(uintptr_t(raw) % alignof(BaselineScript) == 0); if (!raw) { return nullptr; } BaselineScript* script = new (raw) BaselineScript(warmUpCheckPrologueOffset, profilerEnterToggleOffset, profilerExitToggleOffset); Offset cursor = sizeof(BaselineScript); MOZ_ASSERT(isAlignedOffset(cursor)); script->resumeEntriesOffset_ = cursor; cursor += resumeEntries * sizeof(uintptr_t); MOZ_ASSERT(isAlignedOffset(cursor)); script->retAddrEntriesOffset_ = cursor; cursor += retAddrEntries * sizeof(RetAddrEntry); MOZ_ASSERT(isAlignedOffset(cursor)); script->osrEntriesOffset_ = cursor; cursor += osrEntries * sizeof(OSREntry); MOZ_ASSERT(isAlignedOffset(cursor)); script->debugTrapEntriesOffset_ = cursor; cursor += debugTrapEntries * sizeof(DebugTrapEntry); MOZ_ASSERT(isAlignedOffset(cursor)); script->allocBytes_ = cursor; MOZ_ASSERT(script->endOffset() == size.value()); return script; } void BaselineScript::trace(JSTracer* trc) { TraceEdge(trc, &method_, "baseline-method"); } void BaselineScript::Destroy(JS::GCContext* gcx, BaselineScript* script) { MOZ_ASSERT(!script->hasPendingIonCompileTask()); // This allocation is tracked by JSScript::setBaselineScriptImpl. gcx->deleteUntracked(script); } void JS::DeletePolicy::operator()( const js::jit::BaselineScript* script) { BaselineScript::Destroy(rt_->gcContext(), const_cast(script)); } const RetAddrEntry& BaselineScript::retAddrEntryFromReturnOffset( CodeOffset returnOffset) { mozilla::Span entries = retAddrEntries(); size_t loc; #ifdef DEBUG bool found = #endif BinarySearchIf( entries.data(), 0, entries.size(), [&returnOffset](const RetAddrEntry& entry) { size_t roffset = returnOffset.offset(); size_t entryRoffset = entry.returnOffset().offset(); if (roffset < entryRoffset) { return -1; } if (entryRoffset < roffset) { return 1; } return 0; }, &loc); MOZ_ASSERT(found); MOZ_ASSERT(entries[loc].returnOffset().offset() == returnOffset.offset()); return entries[loc]; } template static bool ComputeBinarySearchMid(mozilla::Span entries, uint32_t pcOffset, size_t* loc) { return BinarySearchIf( entries.data(), 0, entries.size(), [pcOffset](const Entry& entry) { uint32_t entryOffset = entry.pcOffset(); if (pcOffset < entryOffset) { return -1; } if (entryOffset < pcOffset) { return 1; } return 0; }, loc); } uint8_t* BaselineScript::returnAddressForEntry(const RetAddrEntry& ent) { return method()->raw() + ent.returnOffset().offset(); } const RetAddrEntry& BaselineScript::retAddrEntryFromPCOffset( uint32_t pcOffset, RetAddrEntry::Kind kind) { mozilla::Span entries = retAddrEntries(); size_t mid; MOZ_ALWAYS_TRUE(ComputeBinarySearchMid(entries, pcOffset, &mid)); MOZ_ASSERT(mid < entries.size()); // Search for the first entry for this pc. size_t first = mid; while (first > 0 && entries[first - 1].pcOffset() == pcOffset) { first--; } // Search for the last entry for this pc. size_t last = mid; while (last + 1 < entries.size() && entries[last + 1].pcOffset() == pcOffset) { last++; } MOZ_ASSERT(first <= last); MOZ_ASSERT(entries[first].pcOffset() == pcOffset); MOZ_ASSERT(entries[last].pcOffset() == pcOffset); for (size_t i = first; i <= last; i++) { const RetAddrEntry& entry = entries[i]; if (entry.kind() != kind) { continue; } #ifdef DEBUG // There must be a unique entry for this pcOffset and Kind to ensure our // return value is well-defined. for (size_t j = i + 1; j <= last; j++) { MOZ_ASSERT(entries[j].kind() != kind); } #endif return entry; } MOZ_CRASH("Didn't find RetAddrEntry."); } const RetAddrEntry& BaselineScript::prologueRetAddrEntry( RetAddrEntry::Kind kind) { MOZ_ASSERT(kind == RetAddrEntry::Kind::StackCheck); // The prologue entries will always be at a very low offset, so just do a // linear search from the beginning. for (const RetAddrEntry& entry : retAddrEntries()) { if (entry.pcOffset() != 0) { break; } if (entry.kind() == kind) { return entry; } } MOZ_CRASH("Didn't find prologue RetAddrEntry."); } const RetAddrEntry& BaselineScript::retAddrEntryFromReturnAddress( const uint8_t* returnAddr) { MOZ_ASSERT(returnAddr > method_->raw()); MOZ_ASSERT(returnAddr < method_->raw() + method_->instructionsSize()); CodeOffset offset(returnAddr - method_->raw()); return retAddrEntryFromReturnOffset(offset); } uint8_t* BaselineScript::nativeCodeForOSREntry(uint32_t pcOffset) { mozilla::Span entries = osrEntries(); size_t mid; if (!ComputeBinarySearchMid(entries, pcOffset, &mid)) { return nullptr; } uint32_t nativeOffset = entries[mid].nativeOffset(); return method_->raw() + nativeOffset; } void BaselineScript::computeResumeNativeOffsets( JSScript* script, const ResumeOffsetEntryVector& entries) { // Translate pcOffset to BaselineScript native address. This may return // nullptr if compiler decided code was unreachable. auto computeNative = [this, &entries](uint32_t pcOffset) -> uint8_t* { mozilla::Span entriesSpan = mozilla::Span(entries.begin(), entries.length()); size_t mid; if (!ComputeBinarySearchMid(entriesSpan, pcOffset, &mid)) { return nullptr; } uint32_t nativeOffset = entries[mid].nativeOffset(); return method_->raw() + nativeOffset; }; mozilla::Span pcOffsets = script->resumeOffsets(); mozilla::Span nativeOffsets = resumeEntryList(); std::transform(pcOffsets.begin(), pcOffsets.end(), nativeOffsets.begin(), computeNative); } void BaselineScript::copyRetAddrEntries(const RetAddrEntry* entries) { std::copy_n(entries, retAddrEntries().size(), retAddrEntries().data()); } void BaselineScript::copyOSREntries(const OSREntry* entries) { std::copy_n(entries, osrEntries().size(), osrEntries().data()); } void BaselineScript::copyDebugTrapEntries(const DebugTrapEntry* entries) { std::copy_n(entries, debugTrapEntries().size(), debugTrapEntries().data()); } jsbytecode* BaselineScript::approximatePcForNativeAddress( JSScript* script, uint8_t* nativeAddress) { MOZ_ASSERT(script->baselineScript() == this); MOZ_ASSERT(containsCodeAddress(nativeAddress)); uint32_t nativeOffset = nativeAddress - method_->raw(); // Use the RetAddrEntry list (sorted on pc and return address) to look for the // first pc that has a return address >= nativeOffset. This isn't perfect but // it's a reasonable approximation for the profiler because most non-trivial // bytecode ops have a RetAddrEntry. for (const RetAddrEntry& entry : retAddrEntries()) { uint32_t retOffset = entry.returnOffset().offset(); if (retOffset >= nativeOffset) { return script->offsetToPC(entry.pcOffset()); } } // Return the last entry's pc. Every BaselineScript has at least one // RetAddrEntry for the prologue stack overflow check. MOZ_ASSERT(!retAddrEntries().empty()); const RetAddrEntry& lastEntry = retAddrEntries()[retAddrEntries().size() - 1]; return script->offsetToPC(lastEntry.pcOffset()); } void BaselineScript::toggleDebugTraps(JSScript* script, jsbytecode* pc) { MOZ_ASSERT(script->baselineScript() == this); // Only scripts compiled for debug mode have toggled calls. if (!hasDebugInstrumentation()) { return; } AutoWritableJitCode awjc(method()); for (const DebugTrapEntry& entry : debugTrapEntries()) { jsbytecode* entryPC = script->offsetToPC(entry.pcOffset()); // If the |pc| argument is non-null we can skip all other bytecode ops. if (pc && pc != entryPC) { continue; } bool enabled = DebugAPI::stepModeEnabled(script) || DebugAPI::hasBreakpointsAt(script, entryPC); // Patch the trap. CodeLocationLabel label(method(), CodeOffset(entry.nativeOffset())); Assembler::ToggleCall(label, enabled); } } void BaselineScript::setPendingIonCompileTask(JSRuntime* rt, JSScript* script, IonCompileTask* task) { MOZ_ASSERT(script->baselineScript() == this); MOZ_ASSERT(task); MOZ_ASSERT(!hasPendingIonCompileTask()); if (script->isIonCompilingOffThread()) { script->jitScript()->clearIsIonCompilingOffThread(script); } pendingIonCompileTask_ = task; script->updateJitCodeRaw(rt); } void BaselineScript::removePendingIonCompileTask(JSRuntime* rt, JSScript* script) { MOZ_ASSERT(script->baselineScript() == this); MOZ_ASSERT(hasPendingIonCompileTask()); pendingIonCompileTask_ = nullptr; script->updateJitCodeRaw(rt); } static void ToggleProfilerInstrumentation(JitCode* code, uint32_t profilerEnterToggleOffset, uint32_t profilerExitToggleOffset, bool enable) { CodeLocationLabel enterToggleLocation(code, CodeOffset(profilerEnterToggleOffset)); CodeLocationLabel exitToggleLocation(code, CodeOffset(profilerExitToggleOffset)); if (enable) { Assembler::ToggleToCmp(enterToggleLocation); Assembler::ToggleToCmp(exitToggleLocation); } else { Assembler::ToggleToJmp(enterToggleLocation); Assembler::ToggleToJmp(exitToggleLocation); } } void BaselineScript::toggleProfilerInstrumentation(bool enable) { if (enable == isProfilerInstrumentationOn()) { return; } JitSpew(JitSpew_BaselineIC, " toggling profiling %s for BaselineScript %p", enable ? "on" : "off", this); ToggleProfilerInstrumentation(method_, profilerEnterToggleOffset_, profilerExitToggleOffset_, enable); if (enable) { flags_ |= uint32_t(PROFILER_INSTRUMENTATION_ON); } else { flags_ &= ~uint32_t(PROFILER_INSTRUMENTATION_ON); } } void BaselineInterpreter::toggleProfilerInstrumentation(bool enable) { if (!IsBaselineInterpreterEnabled()) { return; } AutoWritableJitCode awjc(code_); ToggleProfilerInstrumentation(code_, profilerEnterToggleOffset_, profilerExitToggleOffset_, enable); } void BaselineInterpreter::toggleDebuggerInstrumentation(bool enable) { if (!IsBaselineInterpreterEnabled()) { return; } AutoWritableJitCode awjc(code_); // Toggle jumps for debugger instrumentation. for (uint32_t offset : debugInstrumentationOffsets_) { CodeLocationLabel label(code_, CodeOffset(offset)); if (enable) { Assembler::ToggleToCmp(label); } else { Assembler::ToggleToJmp(label); } } // Toggle DebugTrapHandler calls. uint8_t* debugTrapHandler = codeAtOffset(debugTrapHandlerOffset_); for (uint32_t offset : debugTrapOffsets_) { uint8_t* trap = codeAtOffset(offset); if (enable) { MacroAssembler::patchNopToCall(trap, debugTrapHandler); } else { MacroAssembler::patchCallToNop(trap); } } } void BaselineInterpreter::toggleCodeCoverageInstrumentationUnchecked( bool enable) { if (!IsBaselineInterpreterEnabled()) { return; } AutoWritableJitCode awjc(code_); for (uint32_t offset : codeCoverageOffsets_) { CodeLocationLabel label(code_, CodeOffset(offset)); if (enable) { Assembler::ToggleToCmp(label); } else { Assembler::ToggleToJmp(label); } } } void BaselineInterpreter::toggleCodeCoverageInstrumentation(bool enable) { if (coverage::IsLCovEnabled()) { // Instrumentation is enabled no matter what. return; } toggleCodeCoverageInstrumentationUnchecked(enable); } void jit::FinishDiscardBaselineScript(JS::GCContext* gcx, JSScript* script) { MOZ_ASSERT(script->hasBaselineScript()); MOZ_ASSERT(!script->jitScript()->active()); BaselineScript* baseline = script->jitScript()->clearBaselineScript(gcx, script); BaselineScript::Destroy(gcx, baseline); } void jit::AddSizeOfBaselineData(JSScript* script, mozilla::MallocSizeOf mallocSizeOf, size_t* data) { if (script->hasBaselineScript()) { script->baselineScript()->addSizeOfIncludingThis(mallocSizeOf, data); } } void jit::ToggleBaselineProfiling(JSContext* cx, bool enable) { JitRuntime* jrt = cx->runtime()->jitRuntime(); if (!jrt) { return; } jrt->baselineInterpreter().toggleProfilerInstrumentation(enable); for (ZonesIter zone(cx->runtime(), SkipAtoms); !zone.done(); zone.next()) { for (auto base = zone->cellIter(); !base.done(); base.next()) { if (!base->hasJitScript()) { continue; } JSScript* script = base->asJSScript(); if (enable) { script->jitScript()->ensureProfileString(cx, script); } if (!script->hasBaselineScript()) { continue; } AutoWritableJitCode awjc(script->baselineScript()->method()); script->baselineScript()->toggleProfilerInstrumentation(enable); } } } void BaselineInterpreter::init(JitCode* code, uint32_t interpretOpOffset, uint32_t interpretOpNoDebugTrapOffset, uint32_t bailoutPrologueOffset, uint32_t profilerEnterToggleOffset, uint32_t profilerExitToggleOffset, uint32_t debugTrapHandlerOffset, CodeOffsetVector&& debugInstrumentationOffsets, CodeOffsetVector&& debugTrapOffsets, CodeOffsetVector&& codeCoverageOffsets, ICReturnOffsetVector&& icReturnOffsets, const CallVMOffsets& callVMOffsets) { code_ = code; interpretOpOffset_ = interpretOpOffset; interpretOpNoDebugTrapOffset_ = interpretOpNoDebugTrapOffset; bailoutPrologueOffset_ = bailoutPrologueOffset; profilerEnterToggleOffset_ = profilerEnterToggleOffset; profilerExitToggleOffset_ = profilerExitToggleOffset; debugTrapHandlerOffset_ = debugTrapHandlerOffset; debugInstrumentationOffsets_ = std::move(debugInstrumentationOffsets); debugTrapOffsets_ = std::move(debugTrapOffsets); codeCoverageOffsets_ = std::move(codeCoverageOffsets); icReturnOffsets_ = std::move(icReturnOffsets); callVMOffsets_ = callVMOffsets; } uint8_t* BaselineInterpreter::retAddrForIC(JSOp op) const { for (const ICReturnOffset& entry : icReturnOffsets_) { if (entry.op == op) { return codeAtOffset(entry.offset); } } MOZ_CRASH("Unexpected op"); } bool jit::GenerateBaselineInterpreter(JSContext* cx, BaselineInterpreter& interpreter) { if (IsBaselineInterpreterEnabled()) { TempAllocator temp(&cx->tempLifoAlloc()); BaselineInterpreterGenerator generator(cx, temp); return generator.generate(interpreter); } return true; }