lldb/source/Utility/ReproducerInstrumentation.cpp - llvm-project - Git at Google

 //===-- ReproducerInstrumentation.cpp -------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "lldb/Utility/ReproducerInstrumentation.h"
 #include "lldb/Utility/Reproducer.h"
 #include <cstdio>
 #include <cstdlib>
 #include <limits>
 #include <thread>

 using namespace lldb_private;
 using namespace lldb_private::repro;

 // Whether we're currently across the API boundary.
 static thread_local bool g_global_boundary = false;

 void *IndexToObject::GetObjectForIndexImpl(unsigned idx) {
   return m_mapping.lookup(idx);
 }

 void IndexToObject::AddObjectForIndexImpl(unsigned idx, void *object) {
   assert(idx != 0 && "Cannot add object for sentinel");
   m_mapping[idx] = object;
 }

 std::vector<void *> IndexToObject::GetAllObjects() const {
   std::vector<std::pair<unsigned, void *>> pairs;
   for (auto &e : m_mapping) {
     pairs.emplace_back(e.first, e.second);
   }

   // Sort based on index.
   std::sort(pairs.begin(), pairs.end(),
             [](auto &lhs, auto &rhs) { return lhs.first < rhs.first; });

   std::vector<void *> objects;
   objects.reserve(pairs.size());
   for (auto &p : pairs) {
     objects.push_back(p.second);
   }

   return objects;
 }

 template <> const uint8_t *Deserializer::Deserialize<const uint8_t *>() {
   return Deserialize<uint8_t *>();
 }

 template <> void *Deserializer::Deserialize<void *>() {
   return const_cast<void *>(Deserialize<const void *>());
 }

 template <> const void *Deserializer::Deserialize<const void *>() {
   return nullptr;
 }

 template <> char *Deserializer::Deserialize<char *>() {
   return const_cast<char *>(Deserialize<const char *>());
 }

 template <> const char *Deserializer::Deserialize<const char *>() {
   const size_t size = Deserialize<size_t>();
   if (size == std::numeric_limits<size_t>::max())
     return nullptr;
   assert(HasData(size + 1));
   const char *str = m_buffer.data();
   m_buffer = m_buffer.drop_front(size + 1);
 #ifdef LLDB_REPRO_INSTR_TRACE
   llvm::errs() << "Deserializing with " << LLVM_PRETTY_FUNCTION << " -> \""
                << str << "\"\n";
 #endif
   return str;
 }

 template <> const char **Deserializer::Deserialize<const char **>() {
   const size_t size = Deserialize<size_t>();
   if (size == 0)
     return nullptr;
   const char **r =
       reinterpret_cast<const char **>(calloc(size + 1, sizeof(char *)));
   for (size_t i = 0; i < size; ++i)
     r[i] = Deserialize<const char *>();
   return r;
 }

 void Deserializer::CheckSequence(unsigned sequence) {
   if (m_expected_sequence && *m_expected_sequence != sequence)
     llvm::report_fatal_error(
         "The result does not match the preceding "
         "function. This is probably the result of concurrent "
         "use of the SB API during capture, which is currently not "
         "supported.");
   m_expected_sequence.reset();
 }

 bool Registry::Replay(const FileSpec &file) {
   auto error_or_file = llvm::MemoryBuffer::getFile(file.GetPath());
   if (auto err = error_or_file.getError())
     return false;

   return Replay((*error_or_file)->getBuffer());
 }

 bool Registry::Replay(llvm::StringRef buffer) {
   Deserializer deserializer(buffer);
   return Replay(deserializer);
 }

 bool Registry::Replay(Deserializer &deserializer) {
 #ifndef LLDB_REPRO_INSTR_TRACE
   Log *log = GetLogIfAllCategoriesSet(LIBLLDB_LOG_API);
 #endif

   // Disable buffering stdout so that we approximate the way things get flushed
   // during an interactive session.
   setvbuf(stdout, nullptr, _IONBF, 0);

   while (deserializer.HasData(1)) {
     unsigned sequence = deserializer.Deserialize<unsigned>();
     unsigned id = deserializer.Deserialize<unsigned>();

 #ifndef LLDB_REPRO_INSTR_TRACE
     LLDB_LOG(log, "Replaying {0}: {1}", id, GetSignature(id));
 #else
     llvm::errs() << "Replaying " << id << ": " << GetSignature(id) << "\n";
 #endif

     deserializer.SetExpectedSequence(sequence);
     GetReplayer(id)->operator()(deserializer);
   }

   // Add a small artificial delay to ensure that all asynchronous events have
   // completed before we exit.
   std::this_thread::sleep_for(std::chrono::milliseconds(100));

   return true;
 }

 void Registry::DoRegister(uintptr_t RunID, std::unique_ptr<Replayer> replayer,
                           SignatureStr signature) {
   const unsigned id = m_replayers.size() + 1;
   assert(m_replayers.find(RunID) == m_replayers.end());
   m_replayers[RunID] = std::make_pair(std::move(replayer), id);
   m_ids[id] =
       std::make_pair(m_replayers[RunID].first.get(), std::move(signature));
 }

 unsigned Registry::GetID(uintptr_t addr) {
   unsigned id = m_replayers[addr].second;
   assert(id != 0 && "Forgot to add function to registry?");
   return id;
 }

 std::string Registry::GetSignature(unsigned id) {
   assert(m_ids.count(id) != 0 && "ID not in registry");
   return m_ids[id].second.ToString();
 }

 void Registry::CheckID(unsigned expected, unsigned actual) {
   if (expected != actual) {
     llvm::errs() << "Reproducer expected signature " << expected << ": '"
                  << GetSignature(expected) << "'\n";
     llvm::errs() << "Reproducer actual signature " << actual << ": '"
                  << GetSignature(actual) << "'\n";
     llvm::report_fatal_error(
         "Detected reproducer replay divergence. Refusing to continue.");
   }

 #ifdef LLDB_REPRO_INSTR_TRACE
   llvm::errs() << "Replaying " << actual << ": " << GetSignature(actual)
                << "\n";
 #endif
 }

 Replayer *Registry::GetReplayer(unsigned id) {
   assert(m_ids.count(id) != 0 && "ID not in registry");
   return m_ids[id].first;
 }

 std::string Registry::SignatureStr::ToString() const {
   return (result + (result.empty() ? "" : " ") + scope + "::" + name + args)
       .str();
 }

 unsigned ObjectToIndex::GetIndexForObjectImpl(const void *object) {
   unsigned index = m_mapping.size() + 1;
   auto it = m_mapping.find(object);
   if (it == m_mapping.end())
     m_mapping[object] = index;
   return m_mapping[object];
 }

 Recorder::Recorder()
     : m_pretty_func(), m_pretty_args(),

       m_sequence(std::numeric_limits<unsigned>::max()) {
   if (!g_global_boundary) {
     g_global_boundary = true;
     m_local_boundary = true;
     m_sequence = GetNextSequenceNumber();
   }
 }

 Recorder::Recorder(llvm::StringRef pretty_func, std::string &&pretty_args)
     : m_serializer(nullptr), m_pretty_func(pretty_func),
       m_pretty_args(pretty_args), m_local_boundary(false),
       m_result_recorded(true),
       m_sequence(std::numeric_limits<unsigned>::max()) {
   if (!g_global_boundary) {
     g_global_boundary = true;
     m_local_boundary = true;
     m_sequence = GetNextSequenceNumber();
     LLDB_LOG(GetLogIfAllCategoriesSet(LIBLLDB_LOG_API), "{0} ({1})",
              m_pretty_func, m_pretty_args);
   }
 }

 Recorder::~Recorder() {
   assert(m_result_recorded && "Did you forget LLDB_RECORD_RESULT?");
   UpdateBoundary();
 }

 unsigned Recorder::GetSequenceNumber() const {
   assert(m_sequence != std::numeric_limits<unsigned>::max());
   return m_sequence;
 }

 void Recorder::PrivateThread() { g_global_boundary = true; }

 void Recorder::UpdateBoundary() {
   if (m_local_boundary)
     g_global_boundary = false;
 }

 void InstrumentationData::Initialize(Serializer &serializer,
                                      Registry &registry) {
   InstanceImpl().emplace(serializer, registry);
 }

 void InstrumentationData::Initialize(Deserializer &deserializer,
                                      Registry &registry) {
   InstanceImpl().emplace(deserializer, registry);
 }

 InstrumentationData &InstrumentationData::Instance() {
   if (!InstanceImpl())
     InstanceImpl().emplace();
   return *InstanceImpl();
 }

 llvm::Optional<InstrumentationData> &InstrumentationData::InstanceImpl() {
   static llvm::Optional<InstrumentationData> g_instrumentation_data;
   return g_instrumentation_data;
 }

 std::atomic<unsigned> lldb_private::repro::Recorder::g_sequence;
 std::mutex lldb_private::repro::Recorder::g_mutex;
	//===-- ReproducerInstrumentation.cpp -------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "lldb/Utility/ReproducerInstrumentation.h"
	#include "lldb/Utility/Reproducer.h"
	#include <cstdio>
	#include <cstdlib>
	#include <limits>
	#include <thread>

	using namespace lldb_private;
	using namespace lldb_private::repro;

	// Whether we're currently across the API boundary.
	static thread_local bool g_global_boundary = false;

	void *IndexToObject::GetObjectForIndexImpl(unsigned idx) {
	return m_mapping.lookup(idx);
	}

	void IndexToObject::AddObjectForIndexImpl(unsigned idx, void *object) {
	assert(idx != 0 && "Cannot add object for sentinel");
	m_mapping[idx] = object;
	}

	std::vector<void *> IndexToObject::GetAllObjects() const {
	std::vector<std::pair<unsigned, void *>> pairs;
	for (auto &e : m_mapping) {
	pairs.emplace_back(e.first, e.second);
	}

	// Sort based on index.
	std::sort(pairs.begin(), pairs.end(),
	[](auto &lhs, auto &rhs) { return lhs.first < rhs.first; });

	std::vector<void *> objects;
	objects.reserve(pairs.size());
	for (auto &p : pairs) {
	objects.push_back(p.second);
	}

	return objects;
	}

	template <> const uint8_t Deserializer::Deserialize<const uint8_t >() {
	return Deserialize<uint8_t *>();
	}

	template <> void Deserializer::Deserialize<void >() {
	return const_cast<void >(Deserialize<const void >());
	}

	template <> const void Deserializer::Deserialize<const void >() {
	return nullptr;
	}

	template <> char Deserializer::Deserialize<char >() {
	return const_cast<char >(Deserialize<const char >());
	}

	template <> const char Deserializer::Deserialize<const char >() {
	const size_t size = Deserialize<size_t>();
	if (size == std::numeric_limits<size_t>::max())
	return nullptr;
	assert(HasData(size + 1));
	const char *str = m_buffer.data();
	m_buffer = m_buffer.drop_front(size + 1);
	#ifdef LLDB_REPRO_INSTR_TRACE
	llvm::errs() << "Deserializing with " << LLVM_PRETTY_FUNCTION << " -> \""
	<< str << "\"\n";
	#endif
	return str;
	}

	template <> const char Deserializer::Deserialize<const char >() {
	const size_t size = Deserialize<size_t>();
	if (size == 0)
	return nullptr;
	const char **r =
	reinterpret_cast<const char *>(calloc(size + 1, sizeof(char )));
	for (size_t i = 0; i < size; ++i)
	r[i] = Deserialize<const char *>();
	return r;
	}

	void Deserializer::CheckSequence(unsigned sequence) {
	if (m_expected_sequence && *m_expected_sequence != sequence)
	llvm::report_fatal_error(
	"The result does not match the preceding "
	"function. This is probably the result of concurrent "
	"use of the SB API during capture, which is currently not "
	"supported.");
	m_expected_sequence.reset();
	}

	bool Registry::Replay(const FileSpec &file) {
	auto error_or_file = llvm::MemoryBuffer::getFile(file.GetPath());
	if (auto err = error_or_file.getError())
	return false;

	return Replay((*error_or_file)->getBuffer());
	}

	bool Registry::Replay(llvm::StringRef buffer) {
	Deserializer deserializer(buffer);
	return Replay(deserializer);
	}

	bool Registry::Replay(Deserializer &deserializer) {
	#ifndef LLDB_REPRO_INSTR_TRACE
	Log *log = GetLogIfAllCategoriesSet(LIBLLDB_LOG_API);
	#endif

	// Disable buffering stdout so that we approximate the way things get flushed
	// during an interactive session.
	setvbuf(stdout, nullptr, _IONBF, 0);

	while (deserializer.HasData(1)) {
	unsigned sequence = deserializer.Deserialize<unsigned>();
	unsigned id = deserializer.Deserialize<unsigned>();

	#ifndef LLDB_REPRO_INSTR_TRACE
	LLDB_LOG(log, "Replaying {0}: {1}", id, GetSignature(id));
	#else
	llvm::errs() << "Replaying " << id << ": " << GetSignature(id) << "\n";
	#endif

	deserializer.SetExpectedSequence(sequence);
	GetReplayer(id)->operator()(deserializer);
	}

	// Add a small artificial delay to ensure that all asynchronous events have
	// completed before we exit.
	std::this_thread::sleep_for(std::chrono::milliseconds(100));

	return true;
	}

	void Registry::DoRegister(uintptr_t RunID, std::unique_ptr<Replayer> replayer,
	SignatureStr signature) {
	const unsigned id = m_replayers.size() + 1;
	assert(m_replayers.find(RunID) == m_replayers.end());
	m_replayers[RunID] = std::make_pair(std::move(replayer), id);
	m_ids[id] =
	std::make_pair(m_replayers[RunID].first.get(), std::move(signature));
	}

	unsigned Registry::GetID(uintptr_t addr) {
	unsigned id = m_replayers[addr].second;
	assert(id != 0 && "Forgot to add function to registry?");
	return id;
	}

	std::string Registry::GetSignature(unsigned id) {
	assert(m_ids.count(id) != 0 && "ID not in registry");
	return m_ids[id].second.ToString();
	}

	void Registry::CheckID(unsigned expected, unsigned actual) {
	if (expected != actual) {
	llvm::errs() << "Reproducer expected signature " << expected << ": '"
	<< GetSignature(expected) << "'\n";
	llvm::errs() << "Reproducer actual signature " << actual << ": '"
	<< GetSignature(actual) << "'\n";
	llvm::report_fatal_error(
	"Detected reproducer replay divergence. Refusing to continue.");
	}

	#ifdef LLDB_REPRO_INSTR_TRACE
	llvm::errs() << "Replaying " << actual << ": " << GetSignature(actual)
	<< "\n";
	#endif
	}

	Replayer *Registry::GetReplayer(unsigned id) {
	assert(m_ids.count(id) != 0 && "ID not in registry");
	return m_ids[id].first;
	}

	std::string Registry::SignatureStr::ToString() const {
	return (result + (result.empty() ? "" : " ") + scope + "::" + name + args)
	.str();
	}

	unsigned ObjectToIndex::GetIndexForObjectImpl(const void *object) {
	unsigned index = m_mapping.size() + 1;
	auto it = m_mapping.find(object);
	if (it == m_mapping.end())
	m_mapping[object] = index;
	return m_mapping[object];
	}

	Recorder::Recorder()
	: m_pretty_func(), m_pretty_args(),

	m_sequence(std::numeric_limits<unsigned>::max()) {
	if (!g_global_boundary) {
	g_global_boundary = true;
	m_local_boundary = true;
	m_sequence = GetNextSequenceNumber();
	}
	}

	Recorder::Recorder(llvm::StringRef pretty_func, std::string &&pretty_args)
	: m_serializer(nullptr), m_pretty_func(pretty_func),
	m_pretty_args(pretty_args), m_local_boundary(false),
	m_result_recorded(true),
	m_sequence(std::numeric_limits<unsigned>::max()) {
	if (!g_global_boundary) {
	g_global_boundary = true;
	m_local_boundary = true;
	m_sequence = GetNextSequenceNumber();
	LLDB_LOG(GetLogIfAllCategoriesSet(LIBLLDB_LOG_API), "{0} ({1})",
	m_pretty_func, m_pretty_args);
	}
	}

	Recorder::~Recorder() {
	assert(m_result_recorded && "Did you forget LLDB_RECORD_RESULT?");
	UpdateBoundary();
	}

	unsigned Recorder::GetSequenceNumber() const {
	assert(m_sequence != std::numeric_limits<unsigned>::max());
	return m_sequence;
	}

	void Recorder::PrivateThread() { g_global_boundary = true; }

	void Recorder::UpdateBoundary() {
	if (m_local_boundary)
	g_global_boundary = false;
	}

	void InstrumentationData::Initialize(Serializer &serializer,
	Registry &registry) {
	InstanceImpl().emplace(serializer, registry);
	}

	void InstrumentationData::Initialize(Deserializer &deserializer,
	Registry &registry) {
	InstanceImpl().emplace(deserializer, registry);
	}

	InstrumentationData &InstrumentationData::Instance() {
	if (!InstanceImpl())
	InstanceImpl().emplace();
	return *InstanceImpl();
	}

	llvm::Optional<InstrumentationData> &InstrumentationData::InstanceImpl() {
	static llvm::Optional<InstrumentationData> g_instrumentation_data;
	return g_instrumentation_data;
	}

	std::atomic<unsigned> lldb_private::repro::Recorder::g_sequence;
	std::mutex lldb_private::repro::Recorder::g_mutex;