sdk/android/native_unittests/stacktrace/stacktrace_unittest.cc - src - Git at Google

 /*
  *  Copyright 2019 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "sdk/android/native_api/stacktrace/stacktrace.h"

 #include <dlfcn.h>

 #include <atomic>
 #include <memory>
 #include <vector>

 #include "rtc_base/event.h"
 #include "rtc_base/logging.h"
 #include "rtc_base/platform_thread.h"
 #include "rtc_base/string_utils.h"
 #include "rtc_base/strings/string_builder.h"
 #include "rtc_base/synchronization/mutex.h"
 #include "rtc_base/system/inline.h"
 #include "system_wrappers/include/sleep.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace test {

 namespace {

 // A simple atomic spin event. Implemented with std::atomic_flag, since the C++
 // standard guarantees that that type is implemented with actual atomic
 // instructions (as opposed to e.g. with a mutex). Uses sequentially consistent
 // memory order since this is a test, where simplicity trumps performance.
 class SimpleSpinEvent {
  public:
   // Initialize the event to its blocked state.
   SimpleSpinEvent() {
     static_cast<void>(blocked_.test_and_set(std::memory_order_seq_cst));
   }

   // Busy-wait for the event to become unblocked, and block it behind us as we
   // leave.
   void Wait() {
     bool was_blocked;
     do {
       // Check if the event was blocked, and set it to blocked.
       was_blocked = blocked_.test_and_set(std::memory_order_seq_cst);
     } while (was_blocked);
   }

   // Unblock the event.
   void Set() { blocked_.clear(std::memory_order_seq_cst); }

  private:
   std::atomic_flag blocked_;
 };

 // Returns the execution address relative to the .so base address. This matches
 // the addresses we get from GetStacktrace().
 RTC_NO_INLINE uint32_t GetCurrentRelativeExecutionAddress() {
   void* pc = __builtin_return_address(0);
   Dl_info dl_info = {};
   const bool success = dladdr(pc, &dl_info);
   EXPECT_TRUE(success);
   return static_cast<uint32_t>(reinterpret_cast<uintptr_t>(pc) -
                                reinterpret_cast<uintptr_t>(dl_info.dli_fbase));
 }

 // Returns true if any of the stack trace element is inside the specified
 // region.
 bool StackTraceContainsRange(const std::vector<StackTraceElement>& stack_trace,
                              uintptr_t pc_low,
                              uintptr_t pc_high) {
   for (const StackTraceElement& stack_trace_element : stack_trace) {
     if (pc_low <= stack_trace_element.relative_address &&
         pc_high >= stack_trace_element.relative_address) {
       return true;
     }
   }
   return false;
 }

 class DeadlockInterface {
  public:
   virtual ~DeadlockInterface() {}

   // This function should deadlock until Release() is called.
   virtual void Deadlock() = 0;

   // This function should release the thread stuck in Deadlock().
   virtual void Release() = 0;
 };

 struct ThreadParams {
   volatile int tid;
   // Signaled when the deadlock region is entered.
   SimpleSpinEvent deadlock_start_event;
   DeadlockInterface* volatile deadlock_impl;
   // Defines an address range within the deadlock will occur.
   volatile uint32_t deadlock_region_start_address;
   volatile uint32_t deadlock_region_end_address;
   // Signaled when the deadlock is done.
   rtc::Event deadlock_done_event;
 };

 class RtcEventDeadlock : public DeadlockInterface {
  private:
   void Deadlock() override { event.Wait(rtc::Event::kForever); }
   void Release() override { event.Set(); }

   rtc::Event event;
 };

 class RtcCriticalSectionDeadlock : public DeadlockInterface {
  public:
   RtcCriticalSectionDeadlock()
       : mutex_lock_(std::make_unique<MutexLock>(&mutex_)) {}

  private:
   void Deadlock() override { MutexLock lock(&mutex_); }

   void Release() override { mutex_lock_.reset(); }

   Mutex mutex_;
   std::unique_ptr<MutexLock> mutex_lock_;
 };

 class SpinDeadlock : public DeadlockInterface {
  public:
   SpinDeadlock() : is_deadlocked_(true) {}

  private:
   void Deadlock() override {
     while (is_deadlocked_) {
     }
   }

   void Release() override { is_deadlocked_ = false; }

   std::atomic<bool> is_deadlocked_;
 };

 class SleepDeadlock : public DeadlockInterface {
  private:
   void Deadlock() override { sleep(1000000); }

   void Release() override {
     // The interrupt itself will break free from the sleep.
   }
 };

 void TestStacktrace(std::unique_ptr<DeadlockInterface> deadlock_impl) {
   // Set params that will be sent to other thread.
   ThreadParams params;
   params.deadlock_impl = deadlock_impl.get();

   // Spawn thread.
   auto thread = rtc::PlatformThread::SpawnJoinable(
       [&params] {
         params.tid = gettid();
         params.deadlock_region_start_address =
             GetCurrentRelativeExecutionAddress();
         params.deadlock_start_event.Set();
         params.deadlock_impl->Deadlock();
         params.deadlock_region_end_address =
             GetCurrentRelativeExecutionAddress();
         params.deadlock_done_event.Set();
       },
       "StacktraceTest");

   // Wait until the thread has entered the deadlock region, and take a very
   // brief nap to give it time to reach the actual deadlock.
   params.deadlock_start_event.Wait();
   SleepMs(1);

   // Acquire the stack trace of the thread which should now be deadlocking.
   std::vector<StackTraceElement> stack_trace = GetStackTrace(params.tid);

   // Release the deadlock so that the thread can continue.
   deadlock_impl->Release();

   // Wait until the thread has left the deadlock.
   params.deadlock_done_event.Wait(rtc::Event::kForever);

   // Assert that the stack trace contains the deadlock region.
   EXPECT_TRUE(StackTraceContainsRange(stack_trace,
                                       params.deadlock_region_start_address,
                                       params.deadlock_region_end_address))
       << "Deadlock region: ["
       << rtc::ToHex(params.deadlock_region_start_address) << ", "
       << rtc::ToHex(params.deadlock_region_end_address)
       << "] not contained in: " << StackTraceToString(stack_trace);
 }

 class LookoutLogSink final : public rtc::LogSink {
  public:
   explicit LookoutLogSink(std::string look_for)
       : look_for_(std::move(look_for)) {}
   void OnLogMessage(const std::string& message) override {
     if (message.find(look_for_) != std::string::npos) {
       when_found_.Set();
     }
   }
   rtc::Event& WhenFound() { return when_found_; }

  private:
   const std::string look_for_;
   rtc::Event when_found_;
 };

 }  // namespace

 TEST(Stacktrace, TestCurrentThread) {
   const uint32_t start_addr = GetCurrentRelativeExecutionAddress();
   const std::vector<StackTraceElement> stack_trace = GetStackTrace();
   const uint32_t end_addr = GetCurrentRelativeExecutionAddress();
   EXPECT_TRUE(StackTraceContainsRange(stack_trace, start_addr, end_addr))
       << "Caller region: [" << rtc::ToHex(start_addr) << ", "
       << rtc::ToHex(end_addr)
       << "] not contained in: " << StackTraceToString(stack_trace);
 }

 TEST(Stacktrace, TestSpinLock) {
   TestStacktrace(std::make_unique<SpinDeadlock>());
 }

 TEST(Stacktrace, TestSleep) {
   TestStacktrace(std::make_unique<SleepDeadlock>());
 }

 // Stack traces originating from kernel space does not include user space stack
 // traces for ARM 32.
 #ifdef WEBRTC_ARCH_ARM64

 TEST(Stacktrace, TestRtcEvent) {
   TestStacktrace(std::make_unique<RtcEventDeadlock>());
 }

 TEST(Stacktrace, TestRtcCriticalSection) {
   TestStacktrace(std::make_unique<RtcCriticalSectionDeadlock>());
 }

 #endif

 TEST(Stacktrace, TestRtcEventDeadlockDetection) {
   // Start looking for the expected log output.
   LookoutLogSink sink(/*look_for=*/"Probable deadlock");
   rtc::LogMessage::AddLogToStream(&sink, rtc::LS_WARNING);

   // Start a thread that waits for an event.
   rtc::Event ev;
   auto thread = rtc::PlatformThread::SpawnJoinable(
       [&ev] { ev.Wait(rtc::Event::kForever); },
       "TestRtcEventDeadlockDetection");

   // The message should appear after 3 sec. We'll wait up to 10 sec in an
   // attempt to not be flaky.
   EXPECT_TRUE(sink.WhenFound().Wait(10000));

   // Unblock the thread and shut it down.
   ev.Set();
   thread.Finalize();
   rtc::LogMessage::RemoveLogToStream(&sink);
 }

 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright 2019 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "sdk/android/native_api/stacktrace/stacktrace.h"

	#include <dlfcn.h>

	#include <atomic>
	#include <memory>
	#include <vector>

	#include "rtc_base/event.h"
	#include "rtc_base/logging.h"
	#include "rtc_base/platform_thread.h"
	#include "rtc_base/string_utils.h"
	#include "rtc_base/strings/string_builder.h"
	#include "rtc_base/synchronization/mutex.h"
	#include "rtc_base/system/inline.h"
	#include "system_wrappers/include/sleep.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace test {

	namespace {

	// A simple atomic spin event. Implemented with std::atomic_flag, since the C++
	// standard guarantees that that type is implemented with actual atomic
	// instructions (as opposed to e.g. with a mutex). Uses sequentially consistent
	// memory order since this is a test, where simplicity trumps performance.
	class SimpleSpinEvent {
	public:
	// Initialize the event to its blocked state.
	SimpleSpinEvent() {
	static_cast<void>(blocked_.test_and_set(std::memory_order_seq_cst));
	}

	// Busy-wait for the event to become unblocked, and block it behind us as we
	// leave.
	void Wait() {
	bool was_blocked;
	do {
	// Check if the event was blocked, and set it to blocked.
	was_blocked = blocked_.test_and_set(std::memory_order_seq_cst);
	} while (was_blocked);
	}

	// Unblock the event.
	void Set() { blocked_.clear(std::memory_order_seq_cst); }

	private:
	std::atomic_flag blocked_;
	};

	// Returns the execution address relative to the .so base address. This matches
	// the addresses we get from GetStacktrace().
	RTC_NO_INLINE uint32_t GetCurrentRelativeExecutionAddress() {
	void* pc = __builtin_return_address(0);
	Dl_info dl_info = {};
	const bool success = dladdr(pc, &dl_info);
	EXPECT_TRUE(success);
	return static_cast<uint32_t>(reinterpret_cast<uintptr_t>(pc) -
	reinterpret_cast<uintptr_t>(dl_info.dli_fbase));
	}

	// Returns true if any of the stack trace element is inside the specified
	// region.
	bool StackTraceContainsRange(const std::vector<StackTraceElement>& stack_trace,
	uintptr_t pc_low,
	uintptr_t pc_high) {
	for (const StackTraceElement& stack_trace_element : stack_trace) {
	if (pc_low <= stack_trace_element.relative_address &&
	pc_high >= stack_trace_element.relative_address) {
	return true;
	}
	}
	return false;
	}

	class DeadlockInterface {
	public:
	virtual ~DeadlockInterface() {}

	// This function should deadlock until Release() is called.
	virtual void Deadlock() = 0;

	// This function should release the thread stuck in Deadlock().
	virtual void Release() = 0;
	};

	struct ThreadParams {
	volatile int tid;
	// Signaled when the deadlock region is entered.
	SimpleSpinEvent deadlock_start_event;
	DeadlockInterface* volatile deadlock_impl;
	// Defines an address range within the deadlock will occur.
	volatile uint32_t deadlock_region_start_address;
	volatile uint32_t deadlock_region_end_address;
	// Signaled when the deadlock is done.
	rtc::Event deadlock_done_event;
	};

	class RtcEventDeadlock : public DeadlockInterface {
	private:
	void Deadlock() override { event.Wait(rtc::Event::kForever); }
	void Release() override { event.Set(); }

	rtc::Event event;
	};

	class RtcCriticalSectionDeadlock : public DeadlockInterface {
	public:
	RtcCriticalSectionDeadlock()
	: mutex_lock_(std::make_unique<MutexLock>(&mutex_)) {}

	private:
	void Deadlock() override { MutexLock lock(&mutex_); }

	void Release() override { mutex_lock_.reset(); }

	Mutex mutex_;
	std::unique_ptr<MutexLock> mutex_lock_;
	};

	class SpinDeadlock : public DeadlockInterface {
	public:
	SpinDeadlock() : is_deadlocked_(true) {}

	private:
	void Deadlock() override {
	while (is_deadlocked_) {
	}
	}

	void Release() override { is_deadlocked_ = false; }

	std::atomic<bool> is_deadlocked_;
	};

	class SleepDeadlock : public DeadlockInterface {
	private:
	void Deadlock() override { sleep(1000000); }

	void Release() override {
	// The interrupt itself will break free from the sleep.
	}
	};

	void TestStacktrace(std::unique_ptr<DeadlockInterface> deadlock_impl) {
	// Set params that will be sent to other thread.
	ThreadParams params;
	params.deadlock_impl = deadlock_impl.get();

	// Spawn thread.
	auto thread = rtc::PlatformThread::SpawnJoinable(
	[&params] {
	params.tid = gettid();
	params.deadlock_region_start_address =
	GetCurrentRelativeExecutionAddress();
	params.deadlock_start_event.Set();
	params.deadlock_impl->Deadlock();
	params.deadlock_region_end_address =
	GetCurrentRelativeExecutionAddress();
	params.deadlock_done_event.Set();
	},
	"StacktraceTest");

	// Wait until the thread has entered the deadlock region, and take a very
	// brief nap to give it time to reach the actual deadlock.
	params.deadlock_start_event.Wait();
	SleepMs(1);

	// Acquire the stack trace of the thread which should now be deadlocking.
	std::vector<StackTraceElement> stack_trace = GetStackTrace(params.tid);

	// Release the deadlock so that the thread can continue.
	deadlock_impl->Release();

	// Wait until the thread has left the deadlock.
	params.deadlock_done_event.Wait(rtc::Event::kForever);

	// Assert that the stack trace contains the deadlock region.
	EXPECT_TRUE(StackTraceContainsRange(stack_trace,
	params.deadlock_region_start_address,
	params.deadlock_region_end_address))
	<< "Deadlock region: ["
	<< rtc::ToHex(params.deadlock_region_start_address) << ", "
	<< rtc::ToHex(params.deadlock_region_end_address)
	<< "] not contained in: " << StackTraceToString(stack_trace);
	}

	class LookoutLogSink final : public rtc::LogSink {
	public:
	explicit LookoutLogSink(std::string look_for)
	: look_for_(std::move(look_for)) {}
	void OnLogMessage(const std::string& message) override {
	if (message.find(look_for_) != std::string::npos) {
	when_found_.Set();
	}
	}
	rtc::Event& WhenFound() { return when_found_; }

	private:
	const std::string look_for_;
	rtc::Event when_found_;
	};

	} // namespace

	TEST(Stacktrace, TestCurrentThread) {
	const uint32_t start_addr = GetCurrentRelativeExecutionAddress();
	const std::vector<StackTraceElement> stack_trace = GetStackTrace();
	const uint32_t end_addr = GetCurrentRelativeExecutionAddress();
	EXPECT_TRUE(StackTraceContainsRange(stack_trace, start_addr, end_addr))
	<< "Caller region: [" << rtc::ToHex(start_addr) << ", "
	<< rtc::ToHex(end_addr)
	<< "] not contained in: " << StackTraceToString(stack_trace);
	}

	TEST(Stacktrace, TestSpinLock) {
	TestStacktrace(std::make_unique<SpinDeadlock>());
	}

	TEST(Stacktrace, TestSleep) {
	TestStacktrace(std::make_unique<SleepDeadlock>());
	}

	// Stack traces originating from kernel space does not include user space stack
	// traces for ARM 32.
	#ifdef WEBRTC_ARCH_ARM64

	TEST(Stacktrace, TestRtcEvent) {
	TestStacktrace(std::make_unique<RtcEventDeadlock>());
	}

	TEST(Stacktrace, TestRtcCriticalSection) {
	TestStacktrace(std::make_unique<RtcCriticalSectionDeadlock>());
	}

	#endif

	TEST(Stacktrace, TestRtcEventDeadlockDetection) {
	// Start looking for the expected log output.
	LookoutLogSink sink(/look_for=/"Probable deadlock");
	rtc::LogMessage::AddLogToStream(&sink, rtc::LS_WARNING);

	// Start a thread that waits for an event.
	rtc::Event ev;
	auto thread = rtc::PlatformThread::SpawnJoinable(
	[&ev] { ev.Wait(rtc::Event::kForever); },
	"TestRtcEventDeadlockDetection");

	// The message should appear after 3 sec. We'll wait up to 10 sec in an
	// attempt to not be flaky.
	EXPECT_TRUE(sink.WhenFound().Wait(10000));

	// Unblock the thread and shut it down.
	ev.Set();
	thread.Finalize();
	rtc::LogMessage::RemoveLogToStream(&sink);
	}

	} // namespace test
	} // namespace webrtc