src/ftrace_reader/ftrace_controller.cc - platform/external/perfetto - Gitiles

 /*
  * Copyright (C) 2017 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "perfetto/ftrace_reader/ftrace_controller.h"

 #include <fcntl.h>
 #include <stdint.h>
 #include <string.h>
 #include <sys/stat.h>
 #include <sys/types.h>
 #include <sys/wait.h>
 #include <unistd.h>

 #include <array>
 #include <string>
 #include <utility>

 #include "perfetto/base/build_config.h"
 #include "perfetto/base/logging.h"
 #include "perfetto/base/time.h"
 #include "perfetto/base/utils.h"
 #include "src/ftrace_reader/cpu_reader.h"
 #include "src/ftrace_reader/event_info.h"
 #include "src/ftrace_reader/ftrace_config_muxer.h"
 #include "src/ftrace_reader/ftrace_procfs.h"
 #include "src/ftrace_reader/proto_translation_table.h"

 #include "perfetto/trace/ftrace/ftrace_event_bundle.pbzero.h"

 namespace perfetto {
 namespace {

 #if PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID)
 constexpr const char* kTracingPaths[] = {
     "/sys/kernel/tracing/", "/sys/kernel/debug/tracing/", nullptr,
 };
 #else
 constexpr const char* kTracingPaths[] = {
     "/sys/kernel/debug/tracing/", nullptr,
 };
 #endif

 constexpr int kDefaultDrainPeriodMs = 100;
 constexpr int kMinDrainPeriodMs = 1;
 constexpr int kMaxDrainPeriodMs = 1000 * 60;

 uint32_t ClampDrainPeriodMs(uint32_t drain_period_ms) {
   if (drain_period_ms == 0) {
     return kDefaultDrainPeriodMs;
   }
   if (drain_period_ms < kMinDrainPeriodMs ||
       kMaxDrainPeriodMs < drain_period_ms) {
     PERFETTO_LOG("drain_period_ms was %u should be between %u and %u",
                  drain_period_ms, kMinDrainPeriodMs, kMaxDrainPeriodMs);
     return kDefaultDrainPeriodMs;
   }
   return drain_period_ms;
 }

 void WriteToFile(const char* path, const char* str) {
   int fd = open(path, O_WRONLY);
   if (fd == -1)
     return;
   perfetto::base::ignore_result(write(fd, str, strlen(str)));
   perfetto::base::ignore_result(close(fd));
 }

 void ClearFile(const char* path) {
   int fd = open(path, O_WRONLY | O_TRUNC);
   if (fd == -1)
     return;
   perfetto::base::ignore_result(close(fd));
 }

 }  // namespace

 // Method of last resort to reset ftrace state.
 // We don't know what state the rest of the system and process is so as far
 // as possible avoid allocations.
 void HardResetFtraceState() {
   WriteToFile("/sys/kernel/debug/tracing/tracing_on", "0");
   WriteToFile("/sys/kernel/debug/tracing/buffer_size_kb", "4");
   WriteToFile("/sys/kernel/debug/tracing/events/enable", "0");
   ClearFile("/sys/kernel/debug/tracing/trace");

   WriteToFile("/sys/kernel/tracing/tracing_on", "0");
   WriteToFile("/sys/kernel/tracing/buffer_size_kb", "4");
   WriteToFile("/sys/kernel/tracing/events/enable", "0");
   ClearFile("/sys/kernel/tracing/trace");
 }

 // static
 // TODO(taylori): Add a test for tracing paths in integration tests.
 std::unique_ptr<FtraceController> FtraceController::Create(
     base::TaskRunner* runner) {
   size_t index = 0;
   std::unique_ptr<FtraceProcfs> ftrace_procfs = nullptr;
   while (!ftrace_procfs && kTracingPaths[index]) {
     ftrace_procfs = FtraceProcfs::Create(kTracingPaths[index++]);
   }

   if (!ftrace_procfs)
     return nullptr;

   auto table = ProtoTranslationTable::Create(
       ftrace_procfs.get(), GetStaticEventInfo(), GetStaticCommonFieldsInfo());

   std::unique_ptr<FtraceConfigMuxer> model = std::unique_ptr<FtraceConfigMuxer>(
       new FtraceConfigMuxer(ftrace_procfs.get(), table.get()));
   return std::unique_ptr<FtraceController>(new FtraceController(
       std::move(ftrace_procfs), std::move(table), std::move(model), runner));
 }

 FtraceController::FtraceController(std::unique_ptr<FtraceProcfs> ftrace_procfs,
                                    std::unique_ptr<ProtoTranslationTable> table,
                                    std::unique_ptr<FtraceConfigMuxer> model,
                                    base::TaskRunner* task_runner)
     : ftrace_procfs_(std::move(ftrace_procfs)),
       table_(std::move(table)),
       ftrace_config_muxer_(std::move(model)),
       task_runner_(task_runner),
       weak_factory_(this) {}

 FtraceController::~FtraceController() {
   PERFETTO_DCHECK_THREAD(thread_checker_);
   for (const auto* sink : sinks_)
     ftrace_config_muxer_->RemoveConfig(sink->id_);
   sinks_.clear();
   StopIfNeeded();
 }

 uint64_t FtraceController::NowMs() const {
   return static_cast<uint64_t>(base::GetWallTimeMs().count());
 }

 // static
 void FtraceController::DrainCPUs(base::WeakPtr<FtraceController> weak_this,
                                  size_t generation) {
   // The controller might be gone.
   if (!weak_this)
     return;
   // We might have stopped tracing then quickly re-enabled it, in this case
   // we don't want to end up with two periodic tasks for each CPU:
   if (weak_this->generation_ != generation)
     return;

   PERFETTO_DCHECK_THREAD(weak_this->thread_checker_);
   std::bitset<kMaxCpus> cpus_to_drain;
   {
     std::unique_lock<std::mutex> lock(weak_this->lock_);
     // We might have stopped caring about events.
     if (!weak_this->listening_for_raw_trace_data_)
       return;
     std::swap(cpus_to_drain, weak_this->cpus_to_drain_);
   }

   for (size_t cpu = 0; cpu < weak_this->ftrace_procfs_->NumberOfCpus(); cpu++) {
     if (!cpus_to_drain[cpu])
       continue;
     weak_this->OnRawFtraceDataAvailable(cpu);
   }

   // If we filled up any SHM pages while draining the data, we will have posted
   // a task to notify traced about this. Only unblock the readers after this
   // notification is sent to make it less likely that they steal CPU time away
   // from traced.
   weak_this->task_runner_->PostTask(
       std::bind(&FtraceController::UnblockReaders, weak_this));
 }

 // static
 void FtraceController::UnblockReaders(
     const base::WeakPtr<FtraceController>& weak_this) {
   if (!weak_this)
     return;
   // Unblock all waiting readers to start moving more data into their
   // respective staging pipes.
   weak_this->data_drained_.notify_all();
 }

 void FtraceController::StartIfNeeded() {
   if (sinks_.size() > 1)
     return;
   PERFETTO_CHECK(!sinks_.empty());
   {
     std::unique_lock<std::mutex> lock(lock_);
     PERFETTO_CHECK(!listening_for_raw_trace_data_);
     listening_for_raw_trace_data_ = true;
   }
   generation_++;
   base::WeakPtr<FtraceController> weak_this = weak_factory_.GetWeakPtr();
   for (size_t cpu = 0; cpu < ftrace_procfs_->NumberOfCpus(); cpu++) {
     readers_.emplace(
         cpu, std::unique_ptr<CpuReader>(new CpuReader(
                  table_.get(), cpu, ftrace_procfs_->OpenPipeForCpu(cpu),
                  std::bind(&FtraceController::OnDataAvailable, this, weak_this,
                            generation_, cpu, GetDrainPeriodMs()))));
   }
 }

 uint32_t FtraceController::GetDrainPeriodMs() {
   if (sinks_.empty())
     return kDefaultDrainPeriodMs;
   uint32_t min_drain_period_ms = kMaxDrainPeriodMs + 1;
   for (const FtraceSink* sink : sinks_) {
     if (sink->config().drain_period_ms() < min_drain_period_ms)
       min_drain_period_ms = sink->config().drain_period_ms();
   }
   return ClampDrainPeriodMs(min_drain_period_ms);
 }

 void FtraceController::ClearTrace() {
   ftrace_procfs_->ClearTrace();
 }

 void FtraceController::DisableAllEvents() {
   ftrace_procfs_->DisableAllEvents();
 }

 void FtraceController::WriteTraceMarker(const std::string& s) {
   ftrace_procfs_->WriteTraceMarker(s);
 }

 void FtraceController::StopIfNeeded() {
   if (!sinks_.empty())
     return;
   {
     // Unblock any readers that are waiting for us to drain data.
     std::unique_lock<std::mutex> lock(lock_);
     listening_for_raw_trace_data_ = false;
     cpus_to_drain_.reset();
   }
   data_drained_.notify_all();
   readers_.clear();
 }

 void FtraceController::OnRawFtraceDataAvailable(size_t cpu) {
   PERFETTO_CHECK(cpu < ftrace_procfs_->NumberOfCpus());
   CpuReader* reader = readers_[cpu].get();
   using BundleHandle =
       protozero::MessageHandle<protos::pbzero::FtraceEventBundle>;
   std::array<const EventFilter*, kMaxSinks> filters{};
   std::array<BundleHandle, kMaxSinks> bundles{};
   std::array<FtraceMetadata*, kMaxSinks> metadatas{};
   size_t sink_count = sinks_.size();
   size_t i = 0;
   for (FtraceSink* sink : sinks_) {
     filters[i] = sink->event_filter();
     metadatas[i] = sink->metadata_mutable();
     bundles[i++] = sink->GetBundleForCpu(cpu);
   }
   reader->Drain(filters, bundles, metadatas);
   i = 0;
   for (FtraceSink* sink : sinks_)
     sink->OnBundleComplete(cpu, std::move(bundles[i++]));
   PERFETTO_DCHECK(sinks_.size() == sink_count);
 }

 std::unique_ptr<FtraceSink> FtraceController::CreateSink(
     FtraceConfig config,
     FtraceSink::Delegate* delegate) {
   PERFETTO_DCHECK_THREAD(thread_checker_);
   if (sinks_.size() >= kMaxSinks)
     return nullptr;
   if (!ValidConfig(config))
     return nullptr;

   FtraceConfigId id = ftrace_config_muxer_->RequestConfig(config);
   if (!id)
     return nullptr;

   auto controller_weak = weak_factory_.GetWeakPtr();
   auto filter = std::unique_ptr<EventFilter>(new EventFilter(
       *table_, FtraceEventsAsSet(*ftrace_config_muxer_->GetConfig(id))));

   auto sink = std::unique_ptr<FtraceSink>(
       new FtraceSink(std::move(controller_weak), id, std::move(config),
                      std::move(filter), delegate));
   Register(sink.get());
   return sink;
 }

 void FtraceController::OnDataAvailable(
     base::WeakPtr<FtraceController> weak_this,
     size_t generation,
     size_t cpu,
     uint32_t drain_period_ms) {
   // Called on the worker thread.
   PERFETTO_DCHECK(cpu < ftrace_procfs_->NumberOfCpus());
   std::unique_lock<std::mutex> lock(lock_);
   if (!listening_for_raw_trace_data_)
     return;
   if (cpus_to_drain_.none()) {
     // If this was the first CPU to wake up, schedule a drain for the next drain
     // interval.
     uint32_t delay_ms = drain_period_ms - (NowMs() % drain_period_ms);
     task_runner_->PostDelayedTask(
         std::bind(&FtraceController::DrainCPUs, weak_this, generation),
         delay_ms);
   }
   cpus_to_drain_[cpu] = true;

   // Wait until the main thread has finished draining.
   // TODO(skyostil): The threads waiting here will all try to grab lock_
   // when woken up. Find a way to avoid this.
   data_drained_.wait(lock, [this, cpu] {
     return !cpus_to_drain_[cpu] || !listening_for_raw_trace_data_;
   });
 }

 void FtraceController::Register(FtraceSink* sink) {
   PERFETTO_DCHECK_THREAD(thread_checker_);
   auto it_and_inserted = sinks_.insert(sink);
   PERFETTO_DCHECK(it_and_inserted.second);
   StartIfNeeded();
 }

 void FtraceController::Unregister(FtraceSink* sink) {
   PERFETTO_DCHECK_THREAD(thread_checker_);

   size_t removed = sinks_.erase(sink);
   PERFETTO_DCHECK(removed == 1);

   ftrace_config_muxer_->RemoveConfig(sink->id_);

   StopIfNeeded();
 }

 FtraceSink::FtraceSink(base::WeakPtr<FtraceController> controller_weak,
                        FtraceConfigId id,
                        FtraceConfig config,
                        std::unique_ptr<EventFilter> filter,
                        Delegate* delegate)
     : controller_weak_(std::move(controller_weak)),
       id_(id),
       config_(std::move(config)),
       filter_(std::move(filter)),
       delegate_(delegate){};

 FtraceSink::~FtraceSink() {
   if (controller_weak_)
     controller_weak_->Unregister(this);
 };

 const std::set<std::string>& FtraceSink::enabled_events() {
   return filter_->enabled_names();
 }

 FtraceMetadata::FtraceMetadata() {
   // A lot of the time there will only be a small number of inodes.
   inode_and_device.reserve(10);
   pids.reserve(10);
 }

 void FtraceMetadata::AddDevice(BlockDeviceID device_id) {
   last_seen_device_id = device_id;
 #if PERFETTO_DCHECK_IS_ON()
   seen_device_id = true;
 #endif
 }

 void FtraceMetadata::AddInode(Inode inode_number) {
 #if PERFETTO_DCHECK_IS_ON()
   PERFETTO_DCHECK(seen_device_id);
 #endif
   static int32_t cached_pid = 0;
   if (!cached_pid)
     cached_pid = getpid();

   PERFETTO_DCHECK(last_seen_common_pid);
   PERFETTO_DCHECK(cached_pid == getpid());
   // Ignore own scanning activity.
   if (cached_pid != last_seen_common_pid) {
     inode_and_device.push_back(
         std::make_pair(inode_number, last_seen_device_id));
   }
 }

 void FtraceMetadata::AddCommonPid(int32_t pid) {
   last_seen_common_pid = pid;
 }

 void FtraceMetadata::AddPid(int32_t pid) {
   // Speculative optimization aginst repated pid's while keeping
   // faster insertion than a set.
   if (!pids.empty() && pids.back() == pid)
     return;
   pids.push_back(pid);
 }

 void FtraceMetadata::FinishEvent() {
   last_seen_device_id = 0;
 #if PERFETTO_DCHECK_IS_ON()
   seen_device_id = false;
 #endif
   last_seen_common_pid = 0;
 }

 void FtraceMetadata::Clear() {
   inode_and_device.clear();
   pids.clear();
   overwrite_count = 0;
   FinishEvent();
 }

 FtraceSink::Delegate::~Delegate() = default;

 }  // namespace perfetto
	/*
	* Copyright (C) 2017 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "perfetto/ftrace_reader/ftrace_controller.h"

	#include <fcntl.h>
	#include <stdint.h>
	#include <string.h>
	#include <sys/stat.h>
	#include <sys/types.h>
	#include <sys/wait.h>
	#include <unistd.h>

	#include <array>
	#include <string>
	#include <utility>

	#include "perfetto/base/build_config.h"
	#include "perfetto/base/logging.h"
	#include "perfetto/base/time.h"
	#include "perfetto/base/utils.h"
	#include "src/ftrace_reader/cpu_reader.h"
	#include "src/ftrace_reader/event_info.h"
	#include "src/ftrace_reader/ftrace_config_muxer.h"
	#include "src/ftrace_reader/ftrace_procfs.h"
	#include "src/ftrace_reader/proto_translation_table.h"

	#include "perfetto/trace/ftrace/ftrace_event_bundle.pbzero.h"

	namespace perfetto {
	namespace {

	#if PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID)
	constexpr const char* kTracingPaths[] = {
	"/sys/kernel/tracing/", "/sys/kernel/debug/tracing/", nullptr,
	};
	#else
	constexpr const char* kTracingPaths[] = {
	"/sys/kernel/debug/tracing/", nullptr,
	};
	#endif

	constexpr int kDefaultDrainPeriodMs = 100;
	constexpr int kMinDrainPeriodMs = 1;
	constexpr int kMaxDrainPeriodMs = 1000 * 60;

	uint32_t ClampDrainPeriodMs(uint32_t drain_period_ms) {
	if (drain_period_ms == 0) {
	return kDefaultDrainPeriodMs;
	}
	if (drain_period_ms < kMinDrainPeriodMs \|\|
	kMaxDrainPeriodMs < drain_period_ms) {
	PERFETTO_LOG("drain_period_ms was %u should be between %u and %u",
	drain_period_ms, kMinDrainPeriodMs, kMaxDrainPeriodMs);
	return kDefaultDrainPeriodMs;
	}
	return drain_period_ms;
	}

	void WriteToFile(const char* path, const char* str) {
	int fd = open(path, O_WRONLY);
	if (fd == -1)
	return;
	perfetto::base::ignore_result(write(fd, str, strlen(str)));
	perfetto::base::ignore_result(close(fd));
	}

	void ClearFile(const char* path) {
	int fd = open(path, O_WRONLY \| O_TRUNC);
	if (fd == -1)
	return;
	perfetto::base::ignore_result(close(fd));
	}

	} // namespace

	// Method of last resort to reset ftrace state.
	// We don't know what state the rest of the system and process is so as far
	// as possible avoid allocations.
	void HardResetFtraceState() {
	WriteToFile("/sys/kernel/debug/tracing/tracing_on", "0");
	WriteToFile("/sys/kernel/debug/tracing/buffer_size_kb", "4");
	WriteToFile("/sys/kernel/debug/tracing/events/enable", "0");
	ClearFile("/sys/kernel/debug/tracing/trace");

	WriteToFile("/sys/kernel/tracing/tracing_on", "0");
	WriteToFile("/sys/kernel/tracing/buffer_size_kb", "4");
	WriteToFile("/sys/kernel/tracing/events/enable", "0");
	ClearFile("/sys/kernel/tracing/trace");
	}

	// static
	// TODO(taylori): Add a test for tracing paths in integration tests.
	std::unique_ptr<FtraceController> FtraceController::Create(
	base::TaskRunner* runner) {
	size_t index = 0;
	std::unique_ptr<FtraceProcfs> ftrace_procfs = nullptr;
	while (!ftrace_procfs && kTracingPaths[index]) {
	ftrace_procfs = FtraceProcfs::Create(kTracingPaths[index++]);
	}

	if (!ftrace_procfs)
	return nullptr;

	auto table = ProtoTranslationTable::Create(
	ftrace_procfs.get(), GetStaticEventInfo(), GetStaticCommonFieldsInfo());

	std::unique_ptr<FtraceConfigMuxer> model = std::unique_ptr<FtraceConfigMuxer>(
	new FtraceConfigMuxer(ftrace_procfs.get(), table.get()));
	return std::unique_ptr<FtraceController>(new FtraceController(
	std::move(ftrace_procfs), std::move(table), std::move(model), runner));
	}

	FtraceController::FtraceController(std::unique_ptr<FtraceProcfs> ftrace_procfs,
	std::unique_ptr<ProtoTranslationTable> table,
	std::unique_ptr<FtraceConfigMuxer> model,
	base::TaskRunner* task_runner)
	: ftrace_procfs_(std::move(ftrace_procfs)),
	table_(std::move(table)),
	ftrace_config_muxer_(std::move(model)),
	task_runner_(task_runner),
	weak_factory_(this) {}

	FtraceController::~FtraceController() {
	PERFETTO_DCHECK_THREAD(thread_checker_);
	for (const auto* sink : sinks_)
	ftrace_config_muxer_->RemoveConfig(sink->id_);
	sinks_.clear();
	StopIfNeeded();
	}

	uint64_t FtraceController::NowMs() const {
	return static_cast<uint64_t>(base::GetWallTimeMs().count());
	}

	// static
	void FtraceController::DrainCPUs(base::WeakPtr<FtraceController> weak_this,
	size_t generation) {
	// The controller might be gone.
	if (!weak_this)
	return;
	// We might have stopped tracing then quickly re-enabled it, in this case
	// we don't want to end up with two periodic tasks for each CPU:
	if (weak_this->generation_ != generation)
	return;

	PERFETTO_DCHECK_THREAD(weak_this->thread_checker_);
	std::bitset<kMaxCpus> cpus_to_drain;
	{
	std::unique_lock<std::mutex> lock(weak_this->lock_);
	// We might have stopped caring about events.
	if (!weak_this->listening_for_raw_trace_data_)
	return;
	std::swap(cpus_to_drain, weak_this->cpus_to_drain_);
	}

	for (size_t cpu = 0; cpu < weak_this->ftrace_procfs_->NumberOfCpus(); cpu++) {
	if (!cpus_to_drain[cpu])
	continue;
	weak_this->OnRawFtraceDataAvailable(cpu);
	}

	// If we filled up any SHM pages while draining the data, we will have posted
	// a task to notify traced about this. Only unblock the readers after this
	// notification is sent to make it less likely that they steal CPU time away
	// from traced.
	weak_this->task_runner_->PostTask(
	std::bind(&FtraceController::UnblockReaders, weak_this));
	}

	// static
	void FtraceController::UnblockReaders(
	const base::WeakPtr<FtraceController>& weak_this) {
	if (!weak_this)
	return;
	// Unblock all waiting readers to start moving more data into their
	// respective staging pipes.
	weak_this->data_drained_.notify_all();
	}

	void FtraceController::StartIfNeeded() {
	if (sinks_.size() > 1)
	return;
	PERFETTO_CHECK(!sinks_.empty());
	{
	std::unique_lock<std::mutex> lock(lock_);
	PERFETTO_CHECK(!listening_for_raw_trace_data_);
	listening_for_raw_trace_data_ = true;
	}
	generation_++;
	base::WeakPtr<FtraceController> weak_this = weak_factory_.GetWeakPtr();
	for (size_t cpu = 0; cpu < ftrace_procfs_->NumberOfCpus(); cpu++) {
	readers_.emplace(
	cpu, std::unique_ptr<CpuReader>(new CpuReader(
	table_.get(), cpu, ftrace_procfs_->OpenPipeForCpu(cpu),
	std::bind(&FtraceController::OnDataAvailable, this, weak_this,
	generation_, cpu, GetDrainPeriodMs()))));
	}
	}

	uint32_t FtraceController::GetDrainPeriodMs() {
	if (sinks_.empty())
	return kDefaultDrainPeriodMs;
	uint32_t min_drain_period_ms = kMaxDrainPeriodMs + 1;
	for (const FtraceSink* sink : sinks_) {
	if (sink->config().drain_period_ms() < min_drain_period_ms)
	min_drain_period_ms = sink->config().drain_period_ms();
	}
	return ClampDrainPeriodMs(min_drain_period_ms);
	}

	void FtraceController::ClearTrace() {
	ftrace_procfs_->ClearTrace();
	}

	void FtraceController::DisableAllEvents() {
	ftrace_procfs_->DisableAllEvents();
	}

	void FtraceController::WriteTraceMarker(const std::string& s) {
	ftrace_procfs_->WriteTraceMarker(s);
	}

	void FtraceController::StopIfNeeded() {
	if (!sinks_.empty())
	return;
	{
	// Unblock any readers that are waiting for us to drain data.
	std::unique_lock<std::mutex> lock(lock_);
	listening_for_raw_trace_data_ = false;
	cpus_to_drain_.reset();
	}
	data_drained_.notify_all();
	readers_.clear();
	}

	void FtraceController::OnRawFtraceDataAvailable(size_t cpu) {
	PERFETTO_CHECK(cpu < ftrace_procfs_->NumberOfCpus());
	CpuReader* reader = readers_[cpu].get();
	using BundleHandle =
	protozero::MessageHandle<protos::pbzero::FtraceEventBundle>;
	std::array<const EventFilter*, kMaxSinks> filters{};
	std::array<BundleHandle, kMaxSinks> bundles{};
	std::array<FtraceMetadata*, kMaxSinks> metadatas{};
	size_t sink_count = sinks_.size();
	size_t i = 0;
	for (FtraceSink* sink : sinks_) {
	filters[i] = sink->event_filter();
	metadatas[i] = sink->metadata_mutable();
	bundles[i++] = sink->GetBundleForCpu(cpu);
	}
	reader->Drain(filters, bundles, metadatas);
	i = 0;
	for (FtraceSink* sink : sinks_)
	sink->OnBundleComplete(cpu, std::move(bundles[i++]));
	PERFETTO_DCHECK(sinks_.size() == sink_count);
	}

	std::unique_ptr<FtraceSink> FtraceController::CreateSink(
	FtraceConfig config,
	FtraceSink::Delegate* delegate) {
	PERFETTO_DCHECK_THREAD(thread_checker_);
	if (sinks_.size() >= kMaxSinks)
	return nullptr;
	if (!ValidConfig(config))
	return nullptr;

	FtraceConfigId id = ftrace_config_muxer_->RequestConfig(config);
	if (!id)
	return nullptr;

	auto controller_weak = weak_factory_.GetWeakPtr();
	auto filter = std::unique_ptr<EventFilter>(new EventFilter(
	table_, FtraceEventsAsSet(ftrace_config_muxer_->GetConfig(id))));

	auto sink = std::unique_ptr<FtraceSink>(
	new FtraceSink(std::move(controller_weak), id, std::move(config),
	std::move(filter), delegate));
	Register(sink.get());
	return sink;
	}

	void FtraceController::OnDataAvailable(
	base::WeakPtr<FtraceController> weak_this,
	size_t generation,
	size_t cpu,
	uint32_t drain_period_ms) {
	// Called on the worker thread.
	PERFETTO_DCHECK(cpu < ftrace_procfs_->NumberOfCpus());
	std::unique_lock<std::mutex> lock(lock_);
	if (!listening_for_raw_trace_data_)
	return;
	if (cpus_to_drain_.none()) {
	// If this was the first CPU to wake up, schedule a drain for the next drain
	// interval.
	uint32_t delay_ms = drain_period_ms - (NowMs() % drain_period_ms);
	task_runner_->PostDelayedTask(
	std::bind(&FtraceController::DrainCPUs, weak_this, generation),
	delay_ms);
	}
	cpus_to_drain_[cpu] = true;

	// Wait until the main thread has finished draining.
	// TODO(skyostil): The threads waiting here will all try to grab lock_
	// when woken up. Find a way to avoid this.
	data_drained_.wait(lock, [this, cpu] {
	return !cpus_to_drain_[cpu] \|\| !listening_for_raw_trace_data_;
	});
	}

	void FtraceController::Register(FtraceSink* sink) {
	PERFETTO_DCHECK_THREAD(thread_checker_);
	auto it_and_inserted = sinks_.insert(sink);
	PERFETTO_DCHECK(it_and_inserted.second);
	StartIfNeeded();
	}

	void FtraceController::Unregister(FtraceSink* sink) {
	PERFETTO_DCHECK_THREAD(thread_checker_);

	size_t removed = sinks_.erase(sink);
	PERFETTO_DCHECK(removed == 1);

	ftrace_config_muxer_->RemoveConfig(sink->id_);

	StopIfNeeded();
	}

	FtraceSink::FtraceSink(base::WeakPtr<FtraceController> controller_weak,
	FtraceConfigId id,
	FtraceConfig config,
	std::unique_ptr<EventFilter> filter,
	Delegate* delegate)
	: controller_weak_(std::move(controller_weak)),
	id_(id),
	config_(std::move(config)),
	filter_(std::move(filter)),
	delegate_(delegate){};

	FtraceSink::~FtraceSink() {
	if (controller_weak_)
	controller_weak_->Unregister(this);
	};

	const std::set<std::string>& FtraceSink::enabled_events() {
	return filter_->enabled_names();
	}

	FtraceMetadata::FtraceMetadata() {
	// A lot of the time there will only be a small number of inodes.
	inode_and_device.reserve(10);
	pids.reserve(10);
	}

	void FtraceMetadata::AddDevice(BlockDeviceID device_id) {
	last_seen_device_id = device_id;
	#if PERFETTO_DCHECK_IS_ON()
	seen_device_id = true;
	#endif
	}

	void FtraceMetadata::AddInode(Inode inode_number) {
	#if PERFETTO_DCHECK_IS_ON()
	PERFETTO_DCHECK(seen_device_id);
	#endif
	static int32_t cached_pid = 0;
	if (!cached_pid)
	cached_pid = getpid();

	PERFETTO_DCHECK(last_seen_common_pid);
	PERFETTO_DCHECK(cached_pid == getpid());
	// Ignore own scanning activity.
	if (cached_pid != last_seen_common_pid) {
	inode_and_device.push_back(
	std::make_pair(inode_number, last_seen_device_id));
	}
	}

	void FtraceMetadata::AddCommonPid(int32_t pid) {
	last_seen_common_pid = pid;
	}

	void FtraceMetadata::AddPid(int32_t pid) {
	// Speculative optimization aginst repated pid's while keeping
	// faster insertion than a set.
	if (!pids.empty() && pids.back() == pid)
	return;
	pids.push_back(pid);
	}

	void FtraceMetadata::FinishEvent() {
	last_seen_device_id = 0;
	#if PERFETTO_DCHECK_IS_ON()
	seen_device_id = false;
	#endif
	last_seen_common_pid = 0;
	}

	void FtraceMetadata::Clear() {
	inode_and_device.clear();
	pids.clear();
	overwrite_count = 0;
	FinishEvent();
	}

	FtraceSink::Delegate::~Delegate() = default;

	} // namespace perfetto