src/base/tools_sanity_unittest.cc - cobalt - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //
 // This file contains intentional memory errors, some of which may lead to
 // crashes if the test is ran without special memory testing tools. We use these
 // errors to verify the sanity of the tools.

 #include "base/atomicops.h"
 #include "base/message_loop.h"
 #include "base/third_party/dynamic_annotations/dynamic_annotations.h"
 #include "base/threading/thread.h"
 #include "build/build_config.h"
 #include "testing/gtest/include/gtest/gtest.h"

 #if defined(OS_STARBOARD)
 #include "starboard/memory.h"
 #define free SbMemoryDeallocate
 #define malloc SbMemoryAllocate
 #endif

 namespace base {

 namespace {

 const base::subtle::Atomic32 kMagicValue = 42;

 // Helper for memory accesses that can potentially corrupt memory or cause a
 // crash during a native run.
 #if defined(ADDRESS_SANITIZER)
 #if defined(OS_IOS) || defined(__LB_SHELL__) || defined(OS_STARBOARD)
 // EXPECT_DEATH is not supported on IOS.
 // TODO: We have EXPECT_DEATH disabled for all Steel platforms,
 // but we could potentially support it on Linux.
 #define HARMFUL_ACCESS(action,error_regexp) do { action; } while (0)
 #else
 #define HARMFUL_ACCESS(action,error_regexp) EXPECT_DEATH(action,error_regexp)
 #endif  // !OS_IOS
 #else
 #define HARMFUL_ACCESS(action,error_regexp) \
 do { if (RunningOnValgrind()) { action; } } while (0)
 #endif

 void ReadUninitializedValue(char *ptr) {
   // Comparison with 64 is to prevent clang from optimizing away the
   // jump -- valgrind only catches jumps and conditional moves, but clang uses
   // the borrow flag if the condition is just `*ptr == '\0'`.
   if (*ptr == 64) {
     (*ptr)++;
   } else {
     (*ptr)--;
   }
 }

 void ReadValueOutOfArrayBoundsLeft(char *ptr) {
   char c = ptr[-2];
   VLOG(1) << "Reading a byte out of bounds: " << c;
 }

 void ReadValueOutOfArrayBoundsRight(char *ptr, size_t size) {
   char c = ptr[size + 1];
   VLOG(1) << "Reading a byte out of bounds: " << c;
 }

 // This is harmless if you run it under Valgrind thanks to redzones.
 void WriteValueOutOfArrayBoundsLeft(char *ptr) {
   ptr[-1] = kMagicValue;
 }

 // This is harmless if you run it under Valgrind thanks to redzones.
 void WriteValueOutOfArrayBoundsRight(char *ptr, size_t size) {
   ptr[size] = kMagicValue;
 }

 void MakeSomeErrors(char *ptr, size_t size) {
   ReadUninitializedValue(ptr);
   HARMFUL_ACCESS(ReadValueOutOfArrayBoundsLeft(ptr),
                  "heap-buffer-overflow.*2 bytes to the left");
   HARMFUL_ACCESS(ReadValueOutOfArrayBoundsRight(ptr, size),
                  "heap-buffer-overflow.*1 bytes to the right");
   HARMFUL_ACCESS(WriteValueOutOfArrayBoundsLeft(ptr),
                  "heap-buffer-overflow.*1 bytes to the left");
   HARMFUL_ACCESS(WriteValueOutOfArrayBoundsRight(ptr, size),
                  "heap-buffer-overflow.*0 bytes to the right");
 }

 }  // namespace

 #if defined(ADDRESS_SANITIZER) && \
   (defined(OS_IOS) || defined(__LB_SHELL__) || defined(OS_STARBOARD))
 // Because iOS doesn't support death tests, each of the following tests will
 // crash the whole program under ASan.
 #define MAYBE_AccessesToNewMemory DISABLED_AccessesToNewMemory
 #define MAYBE_AccessesToMallocMemory DISABLED_AccessesToMallocMemory
 #define MAYBE_ArrayDeletedWithoutBraces DISABLED_ArrayDeletedWithoutBraces
 #define MAYBE_MemoryLeak DISABLED_MemoryLeak
 #define MAYBE_SingleElementDeletedWithBraces \
     DISABLED_SingleElementDeletedWithBraces
 #else
 #define MAYBE_AccessesToNewMemory AccessesToNewMemory
 #define MAYBE_AccessesToMallocMemory AccessesToMallocMemory
 #define MAYBE_ArrayDeletedWithoutBraces ArrayDeletedWithoutBraces
 #define MAYBE_MemoryLeak MemoryLeak
 #define MAYBE_SingleElementDeletedWithBraces SingleElementDeletedWithBraces
 #endif
 // A memory leak detector should report an error in this test.
 TEST(ToolsSanityTest, MAYBE_MemoryLeak) {
   // Without the |volatile|, clang optimizes away the next two lines.
   int* volatile leak = new int[256];  // Leak some memory intentionally.
   leak[4] = 1;  // Make sure the allocated memory is used.
 }

 TEST(ToolsSanityTest, MAYBE_AccessesToNewMemory) {
   char *foo = new char[10];
   MakeSomeErrors(foo, 10);
   delete [] foo;
   // Use after delete.
   HARMFUL_ACCESS(foo[5] = 0, "heap-use-after-free");
 }

 TEST(ToolsSanityTest, MAYBE_AccessesToMallocMemory) {
   char *foo = reinterpret_cast<char*>(malloc(10));
   MakeSomeErrors(foo, 10);
   free(foo);
   // Use after free.
   HARMFUL_ACCESS(foo[5] = 0, "heap-use-after-free");
 }


 static int* allocateArray() {
   // Clang warns about the mismatched new[]/delete if they occur in the same
   // function.
   return new int[10];
 }

 TEST(ToolsSanityTest, MAYBE_ArrayDeletedWithoutBraces) {
 #if !defined(ADDRESS_SANITIZER)
   // This test may corrupt memory if not run under Valgrind or compiled with
   // AddressSanitizer.
   if (!RunningOnValgrind())
     return;
 #endif

   // Without the |volatile|, clang optimizes away the next two lines.
   int* volatile foo = allocateArray();
   delete foo;
 }

 static int* allocateScalar() {
   // Clang warns about the mismatched new/delete[] if they occur in the same
   // function.
   return new int;
 }

 TEST(ToolsSanityTest, MAYBE_SingleElementDeletedWithBraces) {
 #if !defined(ADDRESS_SANITIZER)
   // This test may corrupt memory if not run under Valgrind or compiled with
   // AddressSanitizer.
   if (!RunningOnValgrind())
     return;
 #endif

   // Without the |volatile|, clang optimizes away the next two lines.
   int* volatile foo = allocateScalar();
   (void) foo;
   delete [] foo;
 }

 #if defined(ADDRESS_SANITIZER)
 TEST(ToolsSanityTest, DISABLED_AddressSanitizerNullDerefCrashTest) {
   // Intentionally crash to make sure AddressSanitizer is running.
   // This test should not be ran on bots.
   int* volatile zero = NULL;
   *zero = 0;
 }

 TEST(ToolsSanityTest, DISABLED_AddressSanitizerLocalOOBCrashTest) {
   // Intentionally crash to make sure AddressSanitizer is instrumenting
   // the local variables.
   // This test should not be ran on bots.
   int array[5];
   // Work around the OOB warning reported by Clang.
   int* volatile access = &array[5];
   *access = 43;
 }

 namespace {
 int g_asan_test_global_array[10];
 }  // namespace

 TEST(ToolsSanityTest, DISABLED_AddressSanitizerGlobalOOBCrashTest) {
   // Intentionally crash to make sure AddressSanitizer is instrumenting
   // the global variables.
   // This test should not be ran on bots.

   // Work around the OOB warning reported by Clang.
   int* volatile access = g_asan_test_global_array - 1;
   *access = 43;
 }

 #endif

 namespace {

 // We use caps here just to ensure that the method name doesn't interfere with
 // the wildcarded suppressions.
 class TOOLS_SANITY_TEST_CONCURRENT_THREAD : public PlatformThread::Delegate {
  public:
   explicit TOOLS_SANITY_TEST_CONCURRENT_THREAD(bool *value) : value_(value) {}
   virtual ~TOOLS_SANITY_TEST_CONCURRENT_THREAD() {}
   virtual void ThreadMain() OVERRIDE {
     *value_ = true;

     // Sleep for a few milliseconds so the two threads are more likely to live
     // simultaneously. Otherwise we may miss the report due to mutex
     // lock/unlock's inside thread creation code in pure-happens-before mode...
     PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
   }
  private:
   bool *value_;
 };

 class ReleaseStoreThread : public PlatformThread::Delegate {
  public:
   explicit ReleaseStoreThread(base::subtle::Atomic32 *value) : value_(value) {}
   virtual ~ReleaseStoreThread() {}
   virtual void ThreadMain() OVERRIDE {
     base::subtle::Release_Store(value_, kMagicValue);

     // Sleep for a few milliseconds so the two threads are more likely to live
     // simultaneously. Otherwise we may miss the report due to mutex
     // lock/unlock's inside thread creation code in pure-happens-before mode...
     PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
   }
  private:
   base::subtle::Atomic32 *value_;
 };

 class AcquireLoadThread : public PlatformThread::Delegate {
  public:
   explicit AcquireLoadThread(base::subtle::Atomic32 *value) : value_(value) {}
   virtual ~AcquireLoadThread() {}
   virtual void ThreadMain() OVERRIDE {
     // Wait for the other thread to make Release_Store
     PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
     base::subtle::Acquire_Load(value_);
   }
  private:
   base::subtle::Atomic32 *value_;
 };

 void RunInParallel(PlatformThread::Delegate *d1, PlatformThread::Delegate *d2) {
   PlatformThreadHandle a;
   PlatformThreadHandle b;
   PlatformThread::Create(0, d1, &a);
   PlatformThread::Create(0, d2, &b);
   PlatformThread::Join(a);
   PlatformThread::Join(b);
 }

 }  // namespace

 // A data race detector should report an error in this test.
 TEST(ToolsSanityTest, DataRace) {
   bool shared = false;
   TOOLS_SANITY_TEST_CONCURRENT_THREAD thread1(&shared), thread2(&shared);
   RunInParallel(&thread1, &thread2);
   EXPECT_TRUE(shared);
 }

 TEST(ToolsSanityTest, AnnotateBenignRace) {
   bool shared = false;
   ANNOTATE_BENIGN_RACE(&shared, "Intentional race - make sure doesn't show up");
   TOOLS_SANITY_TEST_CONCURRENT_THREAD thread1(&shared), thread2(&shared);
   RunInParallel(&thread1, &thread2);
   EXPECT_TRUE(shared);
 }

 TEST(ToolsSanityTest, AtomicsAreIgnored) {
   base::subtle::Atomic32 shared = 0;
   ReleaseStoreThread thread1(&shared);
   AcquireLoadThread thread2(&shared);
   RunInParallel(&thread1, &thread2);
   EXPECT_EQ(kMagicValue, shared);
 }

 }  // namespace base
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//
	// This file contains intentional memory errors, some of which may lead to
	// crashes if the test is ran without special memory testing tools. We use these
	// errors to verify the sanity of the tools.

	#include "base/atomicops.h"
	#include "base/message_loop.h"
	#include "base/third_party/dynamic_annotations/dynamic_annotations.h"
	#include "base/threading/thread.h"
	#include "build/build_config.h"
	#include "testing/gtest/include/gtest/gtest.h"

	#if defined(OS_STARBOARD)
	#include "starboard/memory.h"
	#define free SbMemoryDeallocate
	#define malloc SbMemoryAllocate
	#endif

	namespace base {

	namespace {

	const base::subtle::Atomic32 kMagicValue = 42;

	// Helper for memory accesses that can potentially corrupt memory or cause a
	// crash during a native run.
	#if defined(ADDRESS_SANITIZER)
	#if defined(OS_IOS) \|\| defined(__LB_SHELL__) \|\| defined(OS_STARBOARD)
	// EXPECT_DEATH is not supported on IOS.
	// TODO: We have EXPECT_DEATH disabled for all Steel platforms,
	// but we could potentially support it on Linux.
	#define HARMFUL_ACCESS(action,error_regexp) do { action; } while (0)
	#else
	#define HARMFUL_ACCESS(action,error_regexp) EXPECT_DEATH(action,error_regexp)
	#endif // !OS_IOS
	#else
	#define HARMFUL_ACCESS(action,error_regexp) \
	do { if (RunningOnValgrind()) { action; } } while (0)
	#endif

	void ReadUninitializedValue(char *ptr) {
	// Comparison with 64 is to prevent clang from optimizing away the
	// jump -- valgrind only catches jumps and conditional moves, but clang uses
	// the borrow flag if the condition is just `*ptr == '\0'`.
	if (*ptr == 64) {
	(*ptr)++;
	} else {
	(*ptr)--;
	}
	}

	void ReadValueOutOfArrayBoundsLeft(char *ptr) {
	char c = ptr[-2];
	VLOG(1) << "Reading a byte out of bounds: " << c;
	}

	void ReadValueOutOfArrayBoundsRight(char *ptr, size_t size) {
	char c = ptr[size + 1];
	VLOG(1) << "Reading a byte out of bounds: " << c;
	}

	// This is harmless if you run it under Valgrind thanks to redzones.
	void WriteValueOutOfArrayBoundsLeft(char *ptr) {
	ptr[-1] = kMagicValue;
	}

	// This is harmless if you run it under Valgrind thanks to redzones.
	void WriteValueOutOfArrayBoundsRight(char *ptr, size_t size) {
	ptr[size] = kMagicValue;
	}

	void MakeSomeErrors(char *ptr, size_t size) {
	ReadUninitializedValue(ptr);
	HARMFUL_ACCESS(ReadValueOutOfArrayBoundsLeft(ptr),
	"heap-buffer-overflow.*2 bytes to the left");
	HARMFUL_ACCESS(ReadValueOutOfArrayBoundsRight(ptr, size),
	"heap-buffer-overflow.*1 bytes to the right");
	HARMFUL_ACCESS(WriteValueOutOfArrayBoundsLeft(ptr),
	"heap-buffer-overflow.*1 bytes to the left");
	HARMFUL_ACCESS(WriteValueOutOfArrayBoundsRight(ptr, size),
	"heap-buffer-overflow.*0 bytes to the right");
	}

	} // namespace

	#if defined(ADDRESS_SANITIZER) && \
	(defined(OS_IOS) \|\| defined(__LB_SHELL__) \|\| defined(OS_STARBOARD))
	// Because iOS doesn't support death tests, each of the following tests will
	// crash the whole program under ASan.
	#define MAYBE_AccessesToNewMemory DISABLED_AccessesToNewMemory
	#define MAYBE_AccessesToMallocMemory DISABLED_AccessesToMallocMemory
	#define MAYBE_ArrayDeletedWithoutBraces DISABLED_ArrayDeletedWithoutBraces
	#define MAYBE_MemoryLeak DISABLED_MemoryLeak
	#define MAYBE_SingleElementDeletedWithBraces \
	DISABLED_SingleElementDeletedWithBraces
	#else
	#define MAYBE_AccessesToNewMemory AccessesToNewMemory
	#define MAYBE_AccessesToMallocMemory AccessesToMallocMemory
	#define MAYBE_ArrayDeletedWithoutBraces ArrayDeletedWithoutBraces
	#define MAYBE_MemoryLeak MemoryLeak
	#define MAYBE_SingleElementDeletedWithBraces SingleElementDeletedWithBraces
	#endif
	// A memory leak detector should report an error in this test.
	TEST(ToolsSanityTest, MAYBE_MemoryLeak) {
	// Without the \|volatile\|, clang optimizes away the next two lines.
	int* volatile leak = new int[256]; // Leak some memory intentionally.
	leak[4] = 1; // Make sure the allocated memory is used.
	}

	TEST(ToolsSanityTest, MAYBE_AccessesToNewMemory) {
	char *foo = new char[10];
	MakeSomeErrors(foo, 10);
	delete [] foo;
	// Use after delete.
	HARMFUL_ACCESS(foo[5] = 0, "heap-use-after-free");
	}

	TEST(ToolsSanityTest, MAYBE_AccessesToMallocMemory) {
	char foo = reinterpret_cast<char>(malloc(10));
	MakeSomeErrors(foo, 10);
	free(foo);
	// Use after free.
	HARMFUL_ACCESS(foo[5] = 0, "heap-use-after-free");
	}


	static int* allocateArray() {
	// Clang warns about the mismatched new[]/delete if they occur in the same
	// function.
	return new int[10];
	}

	TEST(ToolsSanityTest, MAYBE_ArrayDeletedWithoutBraces) {
	#if !defined(ADDRESS_SANITIZER)
	// This test may corrupt memory if not run under Valgrind or compiled with
	// AddressSanitizer.
	if (!RunningOnValgrind())
	return;
	#endif

	// Without the \|volatile\|, clang optimizes away the next two lines.
	int* volatile foo = allocateArray();
	delete foo;
	}

	static int* allocateScalar() {
	// Clang warns about the mismatched new/delete[] if they occur in the same
	// function.
	return new int;
	}

	TEST(ToolsSanityTest, MAYBE_SingleElementDeletedWithBraces) {
	#if !defined(ADDRESS_SANITIZER)
	// This test may corrupt memory if not run under Valgrind or compiled with
	// AddressSanitizer.
	if (!RunningOnValgrind())
	return;
	#endif

	// Without the \|volatile\|, clang optimizes away the next two lines.
	int* volatile foo = allocateScalar();
	(void) foo;
	delete [] foo;
	}

	#if defined(ADDRESS_SANITIZER)
	TEST(ToolsSanityTest, DISABLED_AddressSanitizerNullDerefCrashTest) {
	// Intentionally crash to make sure AddressSanitizer is running.
	// This test should not be ran on bots.
	int* volatile zero = NULL;
	*zero = 0;
	}

	TEST(ToolsSanityTest, DISABLED_AddressSanitizerLocalOOBCrashTest) {
	// Intentionally crash to make sure AddressSanitizer is instrumenting
	// the local variables.
	// This test should not be ran on bots.
	int array[5];
	// Work around the OOB warning reported by Clang.
	int* volatile access = &array[5];
	*access = 43;
	}

	namespace {
	int g_asan_test_global_array[10];
	} // namespace

	TEST(ToolsSanityTest, DISABLED_AddressSanitizerGlobalOOBCrashTest) {
	// Intentionally crash to make sure AddressSanitizer is instrumenting
	// the global variables.
	// This test should not be ran on bots.

	// Work around the OOB warning reported by Clang.
	int* volatile access = g_asan_test_global_array - 1;
	*access = 43;
	}

	#endif

	namespace {

	// We use caps here just to ensure that the method name doesn't interfere with
	// the wildcarded suppressions.
	class TOOLS_SANITY_TEST_CONCURRENT_THREAD : public PlatformThread::Delegate {
	public:
	explicit TOOLS_SANITY_TEST_CONCURRENT_THREAD(bool *value) : value_(value) {}
	virtual ~TOOLS_SANITY_TEST_CONCURRENT_THREAD() {}
	virtual void ThreadMain() OVERRIDE {
	*value_ = true;

	// Sleep for a few milliseconds so the two threads are more likely to live
	// simultaneously. Otherwise we may miss the report due to mutex
	// lock/unlock's inside thread creation code in pure-happens-before mode...
	PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
	}
	private:
	bool *value_;
	};

	class ReleaseStoreThread : public PlatformThread::Delegate {
	public:
	explicit ReleaseStoreThread(base::subtle::Atomic32 *value) : value_(value) {}
	virtual ~ReleaseStoreThread() {}
	virtual void ThreadMain() OVERRIDE {
	base::subtle::Release_Store(value_, kMagicValue);

	// Sleep for a few milliseconds so the two threads are more likely to live
	// simultaneously. Otherwise we may miss the report due to mutex
	// lock/unlock's inside thread creation code in pure-happens-before mode...
	PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
	}
	private:
	base::subtle::Atomic32 *value_;
	};

	class AcquireLoadThread : public PlatformThread::Delegate {
	public:
	explicit AcquireLoadThread(base::subtle::Atomic32 *value) : value_(value) {}
	virtual ~AcquireLoadThread() {}
	virtual void ThreadMain() OVERRIDE {
	// Wait for the other thread to make Release_Store
	PlatformThread::Sleep(TimeDelta::FromMilliseconds(100));
	base::subtle::Acquire_Load(value_);
	}
	private:
	base::subtle::Atomic32 *value_;
	};

	void RunInParallel(PlatformThread::Delegate d1, PlatformThread::Delegate d2) {
	PlatformThreadHandle a;
	PlatformThreadHandle b;
	PlatformThread::Create(0, d1, &a);
	PlatformThread::Create(0, d2, &b);
	PlatformThread::Join(a);
	PlatformThread::Join(b);
	}

	} // namespace

	// A data race detector should report an error in this test.
	TEST(ToolsSanityTest, DataRace) {
	bool shared = false;
	TOOLS_SANITY_TEST_CONCURRENT_THREAD thread1(&shared), thread2(&shared);
	RunInParallel(&thread1, &thread2);
	EXPECT_TRUE(shared);
	}

	TEST(ToolsSanityTest, AnnotateBenignRace) {
	bool shared = false;
	ANNOTATE_BENIGN_RACE(&shared, "Intentional race - make sure doesn't show up");
	TOOLS_SANITY_TEST_CONCURRENT_THREAD thread1(&shared), thread2(&shared);
	RunInParallel(&thread1, &thread2);
	EXPECT_TRUE(shared);
	}

	TEST(ToolsSanityTest, AtomicsAreIgnored) {
	base::subtle::Atomic32 shared = 0;
	ReleaseStoreThread thread1(&shared);
	AcquireLoadThread thread2(&shared);
	RunInParallel(&thread1, &thread2);
	EXPECT_EQ(kMagicValue, shared);
	}

	} // namespace base