Source/JavaScriptCore/tools/VMInspector.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2017-2019 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "VMInspector.h"

 #include "CodeBlock.h"
 #include "CodeBlockSet.h"
 #include "HeapInlines.h"
 #include "HeapIterationScope.h"
 #include "JSCInlines.h"
 #include "MachineContext.h"
 #include "MarkedSpaceInlines.h"
 #include "StackVisitor.h"
 #include <mutex>
 #include <wtf/Expected.h>

 #if !OS(WINDOWS)
 #include <unistd.h>
 #endif

 namespace JSC {

 VMInspector& VMInspector::instance()
 {
     static VMInspector* manager;
     static std::once_flag once;
     std::call_once(once, [] {
         manager = new VMInspector();
     });
     return *manager;
 }

 void VMInspector::add(VM* vm)
 {
     auto locker = holdLock(m_lock);
     m_vmList.append(vm);
 }

 void VMInspector::remove(VM* vm)
 {
     auto locker = holdLock(m_lock);
     m_vmList.remove(vm);
 }

 auto VMInspector::lock(Seconds timeout) -> Expected<Locker, Error>
 {
     // This function may be called from a signal handler (e.g. via visit()). Hence,
     // it should only use APIs that are safe to call from signal handlers. This is
     // why we use unistd.h's sleep() instead of its alternatives.

     // We'll be doing sleep(1) between tries below. Hence, sleepPerRetry is 1.
     unsigned maxRetries = (timeout < Seconds::infinity()) ? timeout.value() : UINT_MAX;

     Expected<Locker, Error> locker = Locker::tryLock(m_lock);
     unsigned tryCount = 0;
     while (!locker && tryCount < maxRetries) {
         // We want the version of sleep from unistd.h. Cast to disambiguate.
 #if !OS(WINDOWS)
         (static_cast<unsigned (*)(unsigned)>(sleep))(1);
 #endif
         locker = Locker::tryLock(m_lock);
     }

     if (!locker)
         return makeUnexpected(Error::TimedOut);
     return locker;
 }

 #if ENABLE(JIT)
 static bool ensureIsSafeToLock(Lock& lock)
 {
     unsigned maxRetries = 2;
     unsigned tryCount = 0;
     while (tryCount <= maxRetries) {
         bool success = lock.tryLock();
         if (success) {
             lock.unlock();
             return true;
         }
         tryCount++;
     }
     return false;
 };
 #endif // ENABLE(JIT)

 auto VMInspector::isValidExecutableMemory(const VMInspector::Locker&, void* machinePC) -> Expected<bool, Error>
 {
 #if ENABLE(JIT)
     bool found = false;
     bool hasTimeout = false;
     iterate([&] (VM&) -> FunctorStatus {
         auto& allocator = ExecutableAllocator::singleton();
         auto& lock = allocator.getLock();

         bool isSafeToLock = ensureIsSafeToLock(lock);
         if (!isSafeToLock) {
             hasTimeout = true;
             return FunctorStatus::Continue; // Skip this VM.
         }

         LockHolder executableAllocatorLocker(lock);
         if (allocator.isValidExecutableMemory(executableAllocatorLocker, machinePC)) {
             found = true;
             return FunctorStatus::Done;
         }
         return FunctorStatus::Continue;
     });

     if (!found && hasTimeout)
         return makeUnexpected(Error::TimedOut);
     return found;
 #else
     UNUSED_PARAM(machinePC);
     return false;
 #endif
 }

 auto VMInspector::codeBlockForMachinePC(const VMInspector::Locker&, void* machinePC) -> Expected<CodeBlock*, Error>
 {
 #if ENABLE(JIT)
     CodeBlock* codeBlock = nullptr;
     bool hasTimeout = false;
     iterate([&] (VM& vm) {
         if (!vm.currentThreadIsHoldingAPILock())
             return FunctorStatus::Continue;

         // It is safe to call Heap::forEachCodeBlockIgnoringJITPlans here because:
         // 1. CodeBlocks are added to the CodeBlockSet from the main thread before
         //    they are handed to the JIT plans. Those codeBlocks will have a null jitCode,
         //    but we check for that in our lambda functor.
         // 2. We will acquire the CodeBlockSet lock before iterating.
         //    This ensures that a CodeBlock won't be GCed while we're iterating.
         // 3. We do a tryLock on the CodeBlockSet's lock first to ensure that it is
         //    safe for the current thread to lock it before calling
         //    Heap::forEachCodeBlockIgnoringJITPlans(). Hence, there's no risk of
         //    re-entering the lock and deadlocking on it.

         auto& codeBlockSetLock = vm.heap.codeBlockSet().getLock();
         bool isSafeToLock = ensureIsSafeToLock(codeBlockSetLock);
         if (!isSafeToLock) {
             hasTimeout = true;
             return FunctorStatus::Continue; // Skip this VM.
         }

         auto locker = holdLock(codeBlockSetLock);
         vm.heap.forEachCodeBlockIgnoringJITPlans(locker, [&] (CodeBlock* cb) {
             JITCode* jitCode = cb->jitCode().get();
             if (!jitCode) {
                 // If the codeBlock is a replacement codeBlock which is in the process of being
                 // compiled, its jitCode will be null, and we can disregard it as a match for
                 // the machinePC we're searching for.
                 return;
             }

             if (!JITCode::isJIT(jitCode->jitType()))
                 return;

             if (jitCode->contains(machinePC)) {
                 codeBlock = cb;
                 return;
             }
         });
         if (codeBlock)
             return FunctorStatus::Done;
         return FunctorStatus::Continue;
     });

     if (!codeBlock && hasTimeout)
         return makeUnexpected(Error::TimedOut);
     return codeBlock;
 #else
     UNUSED_PARAM(machinePC);
     return nullptr;
 #endif
 }

 bool VMInspector::currentThreadOwnsJSLock(ExecState* exec)
 {
     return exec->vm().currentThreadIsHoldingAPILock();
 }

 static bool ensureCurrentThreadOwnsJSLock(ExecState* exec)
 {
     if (VMInspector::currentThreadOwnsJSLock(exec))
         return true;
     dataLog("ERROR: current thread does not own the JSLock\n");
     return false;
 }

 void VMInspector::gc(ExecState* exec)
 {
     VM& vm = exec->vm();
     if (!ensureCurrentThreadOwnsJSLock(exec))
         return;
     vm.heap.collectNow(Sync, CollectionScope::Full);
 }

 void VMInspector::edenGC(ExecState* exec)
 {
     VM& vm = exec->vm();
     if (!ensureCurrentThreadOwnsJSLock(exec))
         return;
     vm.heap.collectSync(CollectionScope::Eden);
 }

 bool VMInspector::isInHeap(Heap* heap, void* ptr)
 {
     MarkedBlock* candidate = MarkedBlock::blockFor(ptr);
     if (heap->objectSpace().blocks().set().contains(candidate))
         return true;
     for (LargeAllocation* allocation : heap->objectSpace().largeAllocations()) {
         if (allocation->contains(ptr))
             return true;
     }
     return false;
 }

 struct CellAddressCheckFunctor : MarkedBlock::CountFunctor {
     CellAddressCheckFunctor(JSCell* candidate)
         : candidate(candidate)
     {
     }

     IterationStatus operator()(HeapCell* cell, HeapCell::Kind) const
     {
         if (cell == candidate) {
             found = true;
             return IterationStatus::Done;
         }
         return IterationStatus::Continue;
     }

     JSCell* candidate;
     mutable bool found { false };
 };

 bool VMInspector::isValidCell(Heap* heap, JSCell* candidate)
 {
     HeapIterationScope iterationScope(*heap);
     CellAddressCheckFunctor functor(candidate);
     heap->objectSpace().forEachLiveCell(iterationScope, functor);
     return functor.found;
 }

 bool VMInspector::isValidCodeBlock(ExecState* exec, CodeBlock* candidate)
 {
     if (!ensureCurrentThreadOwnsJSLock(exec))
         return false;

     struct CodeBlockValidationFunctor {
         CodeBlockValidationFunctor(CodeBlock* candidate)
             : candidate(candidate)
         {
         }

         void operator()(CodeBlock* codeBlock) const
         {
             if (codeBlock == candidate)
                 found = true;
         }

         CodeBlock* candidate;
         mutable bool found { false };
     };

     VM& vm = exec->vm();
     CodeBlockValidationFunctor functor(candidate);
     vm.heap.forEachCodeBlock(functor);
     return functor.found;
 }

 CodeBlock* VMInspector::codeBlockForFrame(CallFrame* topCallFrame, unsigned frameNumber)
 {
     if (!ensureCurrentThreadOwnsJSLock(topCallFrame))
         return nullptr;

     if (!topCallFrame)
         return nullptr;

     struct FetchCodeBlockFunctor {
     public:
         FetchCodeBlockFunctor(unsigned targetFrameNumber)
             : targetFrame(targetFrameNumber)
         {
         }

         StackVisitor::Status operator()(StackVisitor& visitor) const
         {
             auto currentFrame = nextFrame++;
             if (currentFrame == targetFrame) {
                 codeBlock = visitor->codeBlock();
                 return StackVisitor::Done;
             }
             return StackVisitor::Continue;
         }

         unsigned targetFrame;
         mutable unsigned nextFrame { 0 };
         mutable CodeBlock* codeBlock { nullptr };
     };

     FetchCodeBlockFunctor functor(frameNumber);
     topCallFrame->iterate(functor);
     return functor.codeBlock;
 }

 class DumpFrameFunctor {
 public:
     enum Action {
         DumpOne,
         DumpAll
     };

     DumpFrameFunctor(Action action, unsigned framesToSkip)
         : m_action(action)
         , m_framesToSkip(framesToSkip)
     {
     }

     StackVisitor::Status operator()(StackVisitor& visitor) const
     {
         m_currentFrame++;
         if (m_currentFrame > m_framesToSkip) {
             visitor->dump(WTF::dataFile(), Indenter(2), [&] (PrintStream& out) {
                 out.print("[", (m_currentFrame - m_framesToSkip - 1), "] ");
             });
         }
         if (m_action == DumpOne && m_currentFrame > m_framesToSkip)
             return StackVisitor::Done;
         return StackVisitor::Continue;
     }

 private:
     Action m_action;
     unsigned m_framesToSkip;
     mutable unsigned m_currentFrame { 0 };
 };

 void VMInspector::dumpCallFrame(CallFrame* callFrame, unsigned framesToSkip)
 {
     if (!ensureCurrentThreadOwnsJSLock(callFrame))
         return;
     DumpFrameFunctor functor(DumpFrameFunctor::DumpOne, framesToSkip);
     callFrame->iterate(functor);
 }

 void VMInspector::dumpRegisters(CallFrame* callFrame)
 {
     CodeBlock* codeBlock = callFrame->codeBlock();
     if (!codeBlock) {
         dataLog("Dumping host frame registers not supported.\n");
         return;
     }
     VM& vm = codeBlock->vm();
     auto valueAsString = [&] (JSValue v) -> CString {
         if (!v.isCell() || VMInspector::isValidCell(&vm.heap, reinterpret_cast<JSCell*>(JSValue::encode(v))))
             return toCString(v);
         return "";
     };

     dataLogF("Register frame: \n\n");
     dataLogF("-----------------------------------------------------------------------------\n");
     dataLogF("            use            |   address  |                value               \n");
     dataLogF("-----------------------------------------------------------------------------\n");

     const Register* it;
     const Register* end;

     it = callFrame->registers() + CallFrameSlot::thisArgument + callFrame->argumentCount();
     end = callFrame->registers() + CallFrameSlot::thisArgument - 1;
     while (it > end) {
         JSValue v = it->jsValue();
         int registerNumber = it - callFrame->registers();
         String name = codeBlock->nameForRegister(VirtualRegister(registerNumber));
         dataLogF("[r% 3d %14s]      | %10p | 0x%-16llx %s\n", registerNumber, name.ascii().data(), it, (long long)JSValue::encode(v), valueAsString(v).data());
         --it;
     }

     dataLogF("-----------------------------------------------------------------------------\n");
     dataLogF("[ArgumentCount]            | %10p | %lu \n", it, (unsigned long) callFrame->argumentCount());

     callFrame->iterate([&] (StackVisitor& visitor) {
         if (visitor->callFrame() == callFrame) {
             unsigned line = 0;
             unsigned unusedColumn = 0;
             visitor->computeLineAndColumn(line, unusedColumn);
             dataLogF("[ReturnVPC]                | %10p | %d (line %d)\n", it, visitor->bytecodeOffset(), line);
             return StackVisitor::Done;
         }
         return StackVisitor::Continue;
     });

     --it;
     dataLogF("[Callee]                   | %10p | 0x%-16llx %s\n", it, (long long)callFrame->callee().rawPtr(), valueAsString(it->jsValue()).data());
     --it;
     dataLogF("[CodeBlock]                | %10p | 0x%-16llx ", it, (long long)codeBlock);
     dataLogLn(codeBlock);
     --it;
 #if ENABLE(JIT)
     AbstractPC pc = callFrame->abstractReturnPC(callFrame->vm());
     if (pc.hasJITReturnAddress())
         dataLogF("[ReturnPC]                 | %10p | %p \n", it, pc.jitReturnAddress().value());
     --it;
 #endif
     dataLogF("[CallerFrame]              | %10p | %p \n", it, callFrame->callerFrame());
     --it;
     dataLogF("-----------------------------------------------------------------------------\n");

     size_t numberOfCalleeSaveSlots = codeBlock->calleeSaveSpaceAsVirtualRegisters();
     const Register* endOfCalleeSaves = it - numberOfCalleeSaveSlots;

     end = it - codeBlock->numVars();
     if (it != end) {
         do {
             JSValue v = it->jsValue();
             int registerNumber = it - callFrame->registers();
             String name = (it > endOfCalleeSaves)
                 ? "CalleeSaveReg"
                 : codeBlock->nameForRegister(VirtualRegister(registerNumber));
             dataLogF("[r% 3d %14s]      | %10p | 0x%-16llx %s\n", registerNumber, name.ascii().data(), it, (long long)JSValue::encode(v), valueAsString(v).data());
             --it;
         } while (it != end);
     }
     dataLogF("-----------------------------------------------------------------------------\n");

     end = it - codeBlock->numCalleeLocals() + codeBlock->numVars();
     if (it != end) {
         do {
             JSValue v = (*it).jsValue();
             int registerNumber = it - callFrame->registers();
             dataLogF("[r% 3d]                     | %10p | 0x%-16llx %s\n", registerNumber, it, (long long)JSValue::encode(v), valueAsString(v).data());
             --it;
         } while (it != end);
     }
     dataLogF("-----------------------------------------------------------------------------\n");
 }

 void VMInspector::dumpStack(CallFrame* topCallFrame, unsigned framesToSkip)
 {
     if (!ensureCurrentThreadOwnsJSLock(topCallFrame))
         return;
     if (!topCallFrame)
         return;
     DumpFrameFunctor functor(DumpFrameFunctor::DumpAll, framesToSkip);
     topCallFrame->iterate(functor);
 }

 void VMInspector::dumpValue(JSValue value)
 {
     dataLogLn(value);
 }

 void VMInspector::dumpCellMemory(JSCell* cell)
 {
     dumpCellMemoryToStream(cell, WTF::dataFile());
 }

 class IndentationScope {
 public:
     IndentationScope(unsigned& indentation)
         : m_indentation(indentation)
     {
         ++m_indentation;
     }

     ~IndentationScope()
     {
         --m_indentation;
     }

 private:
     unsigned& m_indentation;
 };

 void VMInspector::dumpCellMemoryToStream(JSCell* cell, PrintStream& out)
 {
     VM& vm = cell->vm();
     StructureID structureID = cell->structureID();
     Structure* structure = cell->structure(vm);
     IndexingType indexingTypeAndMisc = cell->indexingTypeAndMisc();
     IndexingType indexingType = structure->indexingType();
     IndexingType indexingMode = structure->indexingMode();
     JSType type = cell->type();
     TypeInfo::InlineTypeFlags inlineTypeFlags = cell->inlineTypeFlags();
     CellState cellState = cell->cellState();
     size_t cellSize = cell->cellSize();
     size_t slotCount = cellSize / sizeof(EncodedJSValue);

     EncodedJSValue* slots = bitwise_cast<EncodedJSValue*>(cell);
     unsigned indentation = 0;

     auto indent = [&] {
         for (unsigned i = 0 ; i < indentation; ++i)
             out.print("  ");
     };

 #define INDENT indent(),

     auto dumpSlot = [&] (EncodedJSValue* slots, unsigned index, const char* label = nullptr) {
         out.print("[", index, "] ", format("%p : 0x%016" PRIx64, &slots[index], slots[index]));
         if (label)
             out.print(" ", label);
         out.print("\n");
     };

     out.printf("<%p, %s>\n", cell, cell->className(vm));
     IndentationScope scope(indentation);

     INDENT dumpSlot(slots, 0, "header");
     {
         IndentationScope scope(indentation);
         INDENT out.println("structureID ", format("%d 0x%" PRIx32, structureID, structureID), " structure ", RawPointer(structure));
         INDENT out.println("indexingTypeAndMisc ", format("%d 0x%" PRIx8, indexingTypeAndMisc, indexingTypeAndMisc), " ", IndexingTypeDump(indexingMode));
         INDENT out.println("type ", format("%d 0x%" PRIx8, type, type));
         INDENT out.println("flags ", format("%d 0x%" PRIx8, inlineTypeFlags, inlineTypeFlags));
         INDENT out.println("cellState ", format("%d", cellState));
     }

     unsigned slotIndex = 1;
     if (cell->isObject()) {
         JSObject* obj = static_cast<JSObject*>(const_cast<JSCell*>(cell));
         Butterfly* butterfly = obj->butterfly();
         size_t butterflySize = obj->butterflyTotalSize();

         INDENT dumpSlot(slots, slotIndex, "butterfly");
         slotIndex++;

         if (butterfly) {
             IndentationScope scope(indentation);

             bool hasIndexingHeader = structure->hasIndexingHeader(cell);
             bool hasAnyArrayStorage = JSC::hasAnyArrayStorage(indexingType);

             size_t preCapacity = obj->butterflyPreCapacity();
             size_t propertyCapacity = structure->outOfLineCapacity();

             void* base = hasIndexingHeader
                 ? butterfly->base(preCapacity, propertyCapacity)
                 : butterfly->base(structure);

             unsigned publicLength = butterfly->publicLength();
             unsigned vectorLength = butterfly->vectorLength();
             size_t butterflyCellSize = MarkedSpace::optimalSizeFor(butterflySize);

             size_t endOfIndexedPropertiesIndex = butterflySize / sizeof(EncodedJSValue);
             size_t endOfButterflyIndex = butterflyCellSize / sizeof(EncodedJSValue);

             INDENT out.println("base ", RawPointer(base));
             INDENT out.println("hasIndexingHeader ", (hasIndexingHeader ? "YES" : "NO"), " hasAnyArrayStorage ", (hasAnyArrayStorage ? "YES" : "NO"));
             if (hasIndexingHeader) {
                 INDENT out.print("publicLength ", publicLength, " vectorLength ", vectorLength);
                 if (hasAnyArrayStorage)
                     out.print(" indexBias ", butterfly->arrayStorage()->m_indexBias);
                 out.print("\n");
             }
             INDENT out.println("preCapacity ", preCapacity, " propertyCapacity ", propertyCapacity);

             unsigned index = 0;
             EncodedJSValue* slots = reinterpret_cast<EncodedJSValue*>(base);

             auto asVoidPtr = [] (void* p) {
                 return p;
             };

             auto dumpSectionHeader = [&] (const char* name) {
                 out.println("<--- ", name);
             };

             auto dumpSection = [&] (unsigned startIndex, unsigned endIndex, const char* name) -> unsigned {
                 for (unsigned index = startIndex; index < endIndex; ++index) {
                     if (name && index == startIndex)
                         INDENT dumpSectionHeader(name);
                     INDENT dumpSlot(slots, index);
                 }
                 return endIndex;
             };

             {
                 IndentationScope scope(indentation);

                 index = dumpSection(index, preCapacity, "preCapacity");
                 index = dumpSection(index, preCapacity + propertyCapacity, "propertyCapacity");

                 if (hasIndexingHeader)
                     index = dumpSection(index, index + 1, "indexingHeader");

                 INDENT dumpSectionHeader("butterfly");
                 if (hasAnyArrayStorage) {
                     RELEASE_ASSERT(asVoidPtr(butterfly->arrayStorage()) == asVoidPtr(&slots[index]));
                     RELEASE_ASSERT(ArrayStorage::vectorOffset() == 2 * sizeof(EncodedJSValue));
                     index = dumpSection(index, index + 2, "arrayStorage");
                 }

                 index = dumpSection(index, endOfIndexedPropertiesIndex, "indexedProperties");
                 index = dumpSection(index, endOfButterflyIndex, "unallocated capacity");
             }
         }
     }

     for (; slotIndex < slotCount; ++slotIndex)
         INDENT dumpSlot(slots, slotIndex);

 #undef INDENT
 }

 void VMInspector::dumpSubspaceHashes(VM* vm)
 {
     unsigned count = 0;
     vm->heap.objectSpace().forEachSubspace([&] (const Subspace& subspace) -> IterationStatus {
         const char* name = subspace.name();
         unsigned hash = StringHasher::computeHash(name);
         void* hashAsPtr = reinterpret_cast<void*>(static_cast<uintptr_t>(hash));
         dataLogLn("    [", count++, "] ", name, " Hash:", RawPointer(hashAsPtr));
         return IterationStatus::Continue;
     });
     dataLogLn();
 }

 } // namespace JSC
	/*
	* Copyright (C) 2017-2019 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "VMInspector.h"

	#include "CodeBlock.h"
	#include "CodeBlockSet.h"
	#include "HeapInlines.h"
	#include "HeapIterationScope.h"
	#include "JSCInlines.h"
	#include "MachineContext.h"
	#include "MarkedSpaceInlines.h"
	#include "StackVisitor.h"
	#include <mutex>
	#include <wtf/Expected.h>

	#if !OS(WINDOWS)
	#include <unistd.h>
	#endif

	namespace JSC {

	VMInspector& VMInspector::instance()
	{
	static VMInspector* manager;
	static std::once_flag once;
	std::call_once(once, [] {
	manager = new VMInspector();
	});
	return *manager;
	}

	void VMInspector::add(VM* vm)
	{
	auto locker = holdLock(m_lock);
	m_vmList.append(vm);
	}

	void VMInspector::remove(VM* vm)
	{
	auto locker = holdLock(m_lock);
	m_vmList.remove(vm);
	}

	auto VMInspector::lock(Seconds timeout) -> Expected<Locker, Error>
	{
	// This function may be called from a signal handler (e.g. via visit()). Hence,
	// it should only use APIs that are safe to call from signal handlers. This is
	// why we use unistd.h's sleep() instead of its alternatives.

	// We'll be doing sleep(1) between tries below. Hence, sleepPerRetry is 1.
	unsigned maxRetries = (timeout < Seconds::infinity()) ? timeout.value() : UINT_MAX;

	Expected<Locker, Error> locker = Locker::tryLock(m_lock);
	unsigned tryCount = 0;
	while (!locker && tryCount < maxRetries) {
	// We want the version of sleep from unistd.h. Cast to disambiguate.
	#if !OS(WINDOWS)
	(static_cast<unsigned (*)(unsigned)>(sleep))(1);
	#endif
	locker = Locker::tryLock(m_lock);
	}

	if (!locker)
	return makeUnexpected(Error::TimedOut);
	return locker;
	}

	#if ENABLE(JIT)
	static bool ensureIsSafeToLock(Lock& lock)
	{
	unsigned maxRetries = 2;
	unsigned tryCount = 0;
	while (tryCount <= maxRetries) {
	bool success = lock.tryLock();
	if (success) {
	lock.unlock();
	return true;
	}
	tryCount++;
	}
	return false;
	};
	#endif // ENABLE(JIT)

	auto VMInspector::isValidExecutableMemory(const VMInspector::Locker&, void* machinePC) -> Expected<bool, Error>
	{
	#if ENABLE(JIT)
	bool found = false;
	bool hasTimeout = false;
	iterate([&] (VM&) -> FunctorStatus {
	auto& allocator = ExecutableAllocator::singleton();
	auto& lock = allocator.getLock();

	bool isSafeToLock = ensureIsSafeToLock(lock);
	if (!isSafeToLock) {
	hasTimeout = true;
	return FunctorStatus::Continue; // Skip this VM.
	}

	LockHolder executableAllocatorLocker(lock);
	if (allocator.isValidExecutableMemory(executableAllocatorLocker, machinePC)) {
	found = true;
	return FunctorStatus::Done;
	}
	return FunctorStatus::Continue;
	});

	if (!found && hasTimeout)
	return makeUnexpected(Error::TimedOut);
	return found;
	#else
	UNUSED_PARAM(machinePC);
	return false;
	#endif
	}

	auto VMInspector::codeBlockForMachinePC(const VMInspector::Locker&, void* machinePC) -> Expected<CodeBlock*, Error>
	{
	#if ENABLE(JIT)
	CodeBlock* codeBlock = nullptr;
	bool hasTimeout = false;
	iterate([&] (VM& vm) {
	if (!vm.currentThreadIsHoldingAPILock())
	return FunctorStatus::Continue;

	// It is safe to call Heap::forEachCodeBlockIgnoringJITPlans here because:
	// 1. CodeBlocks are added to the CodeBlockSet from the main thread before
	// they are handed to the JIT plans. Those codeBlocks will have a null jitCode,
	// but we check for that in our lambda functor.
	// 2. We will acquire the CodeBlockSet lock before iterating.
	// This ensures that a CodeBlock won't be GCed while we're iterating.
	// 3. We do a tryLock on the CodeBlockSet's lock first to ensure that it is
	// safe for the current thread to lock it before calling
	// Heap::forEachCodeBlockIgnoringJITPlans(). Hence, there's no risk of
	// re-entering the lock and deadlocking on it.

	auto& codeBlockSetLock = vm.heap.codeBlockSet().getLock();
	bool isSafeToLock = ensureIsSafeToLock(codeBlockSetLock);
	if (!isSafeToLock) {
	hasTimeout = true;
	return FunctorStatus::Continue; // Skip this VM.
	}

	auto locker = holdLock(codeBlockSetLock);
	vm.heap.forEachCodeBlockIgnoringJITPlans(locker, [&] (CodeBlock* cb) {
	JITCode* jitCode = cb->jitCode().get();
	if (!jitCode) {
	// If the codeBlock is a replacement codeBlock which is in the process of being
	// compiled, its jitCode will be null, and we can disregard it as a match for
	// the machinePC we're searching for.
	return;
	}

	if (!JITCode::isJIT(jitCode->jitType()))
	return;

	if (jitCode->contains(machinePC)) {
	codeBlock = cb;
	return;
	}
	});
	if (codeBlock)
	return FunctorStatus::Done;
	return FunctorStatus::Continue;
	});

	if (!codeBlock && hasTimeout)
	return makeUnexpected(Error::TimedOut);
	return codeBlock;
	#else
	UNUSED_PARAM(machinePC);
	return nullptr;
	#endif
	}

	bool VMInspector::currentThreadOwnsJSLock(ExecState* exec)
	{
	return exec->vm().currentThreadIsHoldingAPILock();
	}

	static bool ensureCurrentThreadOwnsJSLock(ExecState* exec)
	{
	if (VMInspector::currentThreadOwnsJSLock(exec))
	return true;
	dataLog("ERROR: current thread does not own the JSLock\n");
	return false;
	}

	void VMInspector::gc(ExecState* exec)
	{
	VM& vm = exec->vm();
	if (!ensureCurrentThreadOwnsJSLock(exec))
	return;
	vm.heap.collectNow(Sync, CollectionScope::Full);
	}

	void VMInspector::edenGC(ExecState* exec)
	{
	VM& vm = exec->vm();
	if (!ensureCurrentThreadOwnsJSLock(exec))
	return;
	vm.heap.collectSync(CollectionScope::Eden);
	}

	bool VMInspector::isInHeap(Heap* heap, void* ptr)
	{
	MarkedBlock* candidate = MarkedBlock::blockFor(ptr);
	if (heap->objectSpace().blocks().set().contains(candidate))
	return true;
	for (LargeAllocation* allocation : heap->objectSpace().largeAllocations()) {
	if (allocation->contains(ptr))
	return true;
	}
	return false;
	}

	struct CellAddressCheckFunctor : MarkedBlock::CountFunctor {
	CellAddressCheckFunctor(JSCell* candidate)
	: candidate(candidate)
	{
	}

	IterationStatus operator()(HeapCell* cell, HeapCell::Kind) const
	{
	if (cell == candidate) {
	found = true;
	return IterationStatus::Done;
	}
	return IterationStatus::Continue;
	}

	JSCell* candidate;
	mutable bool found { false };
	};

	bool VMInspector::isValidCell(Heap* heap, JSCell* candidate)
	{
	HeapIterationScope iterationScope(*heap);
	CellAddressCheckFunctor functor(candidate);
	heap->objectSpace().forEachLiveCell(iterationScope, functor);
	return functor.found;
	}

	bool VMInspector::isValidCodeBlock(ExecState* exec, CodeBlock* candidate)
	{
	if (!ensureCurrentThreadOwnsJSLock(exec))
	return false;

	struct CodeBlockValidationFunctor {
	CodeBlockValidationFunctor(CodeBlock* candidate)
	: candidate(candidate)
	{
	}

	void operator()(CodeBlock* codeBlock) const
	{
	if (codeBlock == candidate)
	found = true;
	}

	CodeBlock* candidate;
	mutable bool found { false };
	};

	VM& vm = exec->vm();
	CodeBlockValidationFunctor functor(candidate);
	vm.heap.forEachCodeBlock(functor);
	return functor.found;
	}

	CodeBlock* VMInspector::codeBlockForFrame(CallFrame* topCallFrame, unsigned frameNumber)
	{
	if (!ensureCurrentThreadOwnsJSLock(topCallFrame))
	return nullptr;

	if (!topCallFrame)
	return nullptr;

	struct FetchCodeBlockFunctor {
	public:
	FetchCodeBlockFunctor(unsigned targetFrameNumber)
	: targetFrame(targetFrameNumber)
	{
	}

	StackVisitor::Status operator()(StackVisitor& visitor) const
	{
	auto currentFrame = nextFrame++;
	if (currentFrame == targetFrame) {
	codeBlock = visitor->codeBlock();
	return StackVisitor::Done;
	}
	return StackVisitor::Continue;
	}

	unsigned targetFrame;
	mutable unsigned nextFrame { 0 };
	mutable CodeBlock* codeBlock { nullptr };
	};

	FetchCodeBlockFunctor functor(frameNumber);
	topCallFrame->iterate(functor);
	return functor.codeBlock;
	}

	class DumpFrameFunctor {
	public:
	enum Action {
	DumpOne,
	DumpAll
	};

	DumpFrameFunctor(Action action, unsigned framesToSkip)
	: m_action(action)
	, m_framesToSkip(framesToSkip)
	{
	}

	StackVisitor::Status operator()(StackVisitor& visitor) const
	{
	m_currentFrame++;
	if (m_currentFrame > m_framesToSkip) {
	visitor->dump(WTF::dataFile(), Indenter(2), [&] (PrintStream& out) {
	out.print("[", (m_currentFrame - m_framesToSkip - 1), "] ");
	});
	}
	if (m_action == DumpOne && m_currentFrame > m_framesToSkip)
	return StackVisitor::Done;
	return StackVisitor::Continue;
	}

	private:
	Action m_action;
	unsigned m_framesToSkip;
	mutable unsigned m_currentFrame { 0 };
	};

	void VMInspector::dumpCallFrame(CallFrame* callFrame, unsigned framesToSkip)
	{
	if (!ensureCurrentThreadOwnsJSLock(callFrame))
	return;
	DumpFrameFunctor functor(DumpFrameFunctor::DumpOne, framesToSkip);
	callFrame->iterate(functor);
	}

	void VMInspector::dumpRegisters(CallFrame* callFrame)
	{
	CodeBlock* codeBlock = callFrame->codeBlock();
	if (!codeBlock) {
	dataLog("Dumping host frame registers not supported.\n");
	return;
	}
	VM& vm = codeBlock->vm();
	auto valueAsString = [&] (JSValue v) -> CString {
	if (!v.isCell() \|\| VMInspector::isValidCell(&vm.heap, reinterpret_cast<JSCell*>(JSValue::encode(v))))
	return toCString(v);
	return "";
	};

	dataLogF("Register frame: \n\n");
	dataLogF("-----------------------------------------------------------------------------\n");
	dataLogF(" use \| address \| value \n");
	dataLogF("-----------------------------------------------------------------------------\n");

	const Register* it;
	const Register* end;

	it = callFrame->registers() + CallFrameSlot::thisArgument + callFrame->argumentCount();
	end = callFrame->registers() + CallFrameSlot::thisArgument - 1;
	while (it > end) {
	JSValue v = it->jsValue();
	int registerNumber = it - callFrame->registers();
	String name = codeBlock->nameForRegister(VirtualRegister(registerNumber));
	dataLogF("[r% 3d %14s] \| %10p \| 0x%-16llx %s\n", registerNumber, name.ascii().data(), it, (long long)JSValue::encode(v), valueAsString(v).data());
	--it;
	}

	dataLogF("-----------------------------------------------------------------------------\n");
	dataLogF("[ArgumentCount] \| %10p \| %lu \n", it, (unsigned long) callFrame->argumentCount());

	callFrame->iterate([&] (StackVisitor& visitor) {
	if (visitor->callFrame() == callFrame) {
	unsigned line = 0;
	unsigned unusedColumn = 0;
	visitor->computeLineAndColumn(line, unusedColumn);
	dataLogF("[ReturnVPC] \| %10p \| %d (line %d)\n", it, visitor->bytecodeOffset(), line);
	return StackVisitor::Done;
	}
	return StackVisitor::Continue;
	});

	--it;
	dataLogF("[Callee] \| %10p \| 0x%-16llx %s\n", it, (long long)callFrame->callee().rawPtr(), valueAsString(it->jsValue()).data());
	--it;
	dataLogF("[CodeBlock] \| %10p \| 0x%-16llx ", it, (long long)codeBlock);
	dataLogLn(codeBlock);
	--it;
	#if ENABLE(JIT)
	AbstractPC pc = callFrame->abstractReturnPC(callFrame->vm());
	if (pc.hasJITReturnAddress())
	dataLogF("[ReturnPC] \| %10p \| %p \n", it, pc.jitReturnAddress().value());
	--it;
	#endif
	dataLogF("[CallerFrame] \| %10p \| %p \n", it, callFrame->callerFrame());
	--it;
	dataLogF("-----------------------------------------------------------------------------\n");

	size_t numberOfCalleeSaveSlots = codeBlock->calleeSaveSpaceAsVirtualRegisters();
	const Register* endOfCalleeSaves = it - numberOfCalleeSaveSlots;

	end = it - codeBlock->numVars();
	if (it != end) {
	do {
	JSValue v = it->jsValue();
	int registerNumber = it - callFrame->registers();
	String name = (it > endOfCalleeSaves)
	? "CalleeSaveReg"
	: codeBlock->nameForRegister(VirtualRegister(registerNumber));
	dataLogF("[r% 3d %14s] \| %10p \| 0x%-16llx %s\n", registerNumber, name.ascii().data(), it, (long long)JSValue::encode(v), valueAsString(v).data());
	--it;
	} while (it != end);
	}
	dataLogF("-----------------------------------------------------------------------------\n");

	end = it - codeBlock->numCalleeLocals() + codeBlock->numVars();
	if (it != end) {
	do {
	JSValue v = (*it).jsValue();
	int registerNumber = it - callFrame->registers();
	dataLogF("[r% 3d] \| %10p \| 0x%-16llx %s\n", registerNumber, it, (long long)JSValue::encode(v), valueAsString(v).data());
	--it;
	} while (it != end);
	}
	dataLogF("-----------------------------------------------------------------------------\n");
	}

	void VMInspector::dumpStack(CallFrame* topCallFrame, unsigned framesToSkip)
	{
	if (!ensureCurrentThreadOwnsJSLock(topCallFrame))
	return;
	if (!topCallFrame)
	return;
	DumpFrameFunctor functor(DumpFrameFunctor::DumpAll, framesToSkip);
	topCallFrame->iterate(functor);
	}

	void VMInspector::dumpValue(JSValue value)
	{
	dataLogLn(value);
	}

	void VMInspector::dumpCellMemory(JSCell* cell)
	{
	dumpCellMemoryToStream(cell, WTF::dataFile());
	}

	class IndentationScope {
	public:
	IndentationScope(unsigned& indentation)
	: m_indentation(indentation)
	{
	++m_indentation;
	}

	~IndentationScope()
	{
	--m_indentation;
	}

	private:
	unsigned& m_indentation;
	};

	void VMInspector::dumpCellMemoryToStream(JSCell* cell, PrintStream& out)
	{
	VM& vm = cell->vm();
	StructureID structureID = cell->structureID();
	Structure* structure = cell->structure(vm);
	IndexingType indexingTypeAndMisc = cell->indexingTypeAndMisc();
	IndexingType indexingType = structure->indexingType();
	IndexingType indexingMode = structure->indexingMode();
	JSType type = cell->type();
	TypeInfo::InlineTypeFlags inlineTypeFlags = cell->inlineTypeFlags();
	CellState cellState = cell->cellState();
	size_t cellSize = cell->cellSize();
	size_t slotCount = cellSize / sizeof(EncodedJSValue);

	EncodedJSValue* slots = bitwise_cast<EncodedJSValue*>(cell);
	unsigned indentation = 0;

	auto indent = [&] {
	for (unsigned i = 0 ; i < indentation; ++i)
	out.print(" ");
	};

	#define INDENT indent(),

	auto dumpSlot = [&] (EncodedJSValue* slots, unsigned index, const char* label = nullptr) {
	out.print("[", index, "] ", format("%p : 0x%016" PRIx64, &slots[index], slots[index]));
	if (label)
	out.print(" ", label);
	out.print("\n");
	};

	out.printf("<%p, %s>\n", cell, cell->className(vm));
	IndentationScope scope(indentation);

	INDENT dumpSlot(slots, 0, "header");
	{
	IndentationScope scope(indentation);
	INDENT out.println("structureID ", format("%d 0x%" PRIx32, structureID, structureID), " structure ", RawPointer(structure));
	INDENT out.println("indexingTypeAndMisc ", format("%d 0x%" PRIx8, indexingTypeAndMisc, indexingTypeAndMisc), " ", IndexingTypeDump(indexingMode));
	INDENT out.println("type ", format("%d 0x%" PRIx8, type, type));
	INDENT out.println("flags ", format("%d 0x%" PRIx8, inlineTypeFlags, inlineTypeFlags));
	INDENT out.println("cellState ", format("%d", cellState));
	}

	unsigned slotIndex = 1;
	if (cell->isObject()) {
	JSObject* obj = static_cast<JSObject>(const_cast<JSCell>(cell));
	Butterfly* butterfly = obj->butterfly();
	size_t butterflySize = obj->butterflyTotalSize();

	INDENT dumpSlot(slots, slotIndex, "butterfly");
	slotIndex++;

	if (butterfly) {
	IndentationScope scope(indentation);

	bool hasIndexingHeader = structure->hasIndexingHeader(cell);
	bool hasAnyArrayStorage = JSC::hasAnyArrayStorage(indexingType);

	size_t preCapacity = obj->butterflyPreCapacity();
	size_t propertyCapacity = structure->outOfLineCapacity();

	void* base = hasIndexingHeader
	? butterfly->base(preCapacity, propertyCapacity)
	: butterfly->base(structure);

	unsigned publicLength = butterfly->publicLength();
	unsigned vectorLength = butterfly->vectorLength();
	size_t butterflyCellSize = MarkedSpace::optimalSizeFor(butterflySize);

	size_t endOfIndexedPropertiesIndex = butterflySize / sizeof(EncodedJSValue);
	size_t endOfButterflyIndex = butterflyCellSize / sizeof(EncodedJSValue);

	INDENT out.println("base ", RawPointer(base));
	INDENT out.println("hasIndexingHeader ", (hasIndexingHeader ? "YES" : "NO"), " hasAnyArrayStorage ", (hasAnyArrayStorage ? "YES" : "NO"));
	if (hasIndexingHeader) {
	INDENT out.print("publicLength ", publicLength, " vectorLength ", vectorLength);
	if (hasAnyArrayStorage)
	out.print(" indexBias ", butterfly->arrayStorage()->m_indexBias);
	out.print("\n");
	}
	INDENT out.println("preCapacity ", preCapacity, " propertyCapacity ", propertyCapacity);

	unsigned index = 0;
	EncodedJSValue* slots = reinterpret_cast<EncodedJSValue*>(base);

	auto asVoidPtr = [] (void* p) {
	return p;
	};

	auto dumpSectionHeader = [&] (const char* name) {
	out.println("<--- ", name);
	};

	auto dumpSection = [&] (unsigned startIndex, unsigned endIndex, const char* name) -> unsigned {
	for (unsigned index = startIndex; index < endIndex; ++index) {
	if (name && index == startIndex)
	INDENT dumpSectionHeader(name);
	INDENT dumpSlot(slots, index);
	}
	return endIndex;
	};

	{
	IndentationScope scope(indentation);

	index = dumpSection(index, preCapacity, "preCapacity");
	index = dumpSection(index, preCapacity + propertyCapacity, "propertyCapacity");

	if (hasIndexingHeader)
	index = dumpSection(index, index + 1, "indexingHeader");

	INDENT dumpSectionHeader("butterfly");
	if (hasAnyArrayStorage) {
	RELEASE_ASSERT(asVoidPtr(butterfly->arrayStorage()) == asVoidPtr(&slots[index]));
	RELEASE_ASSERT(ArrayStorage::vectorOffset() == 2 * sizeof(EncodedJSValue));
	index = dumpSection(index, index + 2, "arrayStorage");
	}

	index = dumpSection(index, endOfIndexedPropertiesIndex, "indexedProperties");
	index = dumpSection(index, endOfButterflyIndex, "unallocated capacity");
	}
	}
	}

	for (; slotIndex < slotCount; ++slotIndex)
	INDENT dumpSlot(slots, slotIndex);

	#undef INDENT
	}

	void VMInspector::dumpSubspaceHashes(VM* vm)
	{
	unsigned count = 0;
	vm->heap.objectSpace().forEachSubspace([&] (const Subspace& subspace) -> IterationStatus {
	const char* name = subspace.name();
	unsigned hash = StringHasher::computeHash(name);
	void* hashAsPtr = reinterpret_cast<void*>(static_cast<uintptr_t>(hash));
	dataLogLn(" [", count++, "] ", name, " Hash:", RawPointer(hashAsPtr));
	return IterationStatus::Continue;
	});
	dataLogLn();
	}

	} // namespace JSC