base/profiler/stack_copier_unittest.cc - chromium/src - Git at Google

 // Copyright 2019 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.

 #include <memory>
 #include <numeric>

 #include "base/profiler/stack_buffer.h"
 #include "base/profiler/stack_copier.h"
 #include "base/stl_util.h"
 #include "testing/gmock/include/gmock/gmock.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace base {

 namespace {

 class CopyFunctions : public StackCopier {
  public:
   using StackCopier::CopyStackContentsAndRewritePointers;
   using StackCopier::RewritePointerIfInOriginalStack;
 };

 static constexpr size_t kTestStackBufferSize = sizeof(uintptr_t) * 4;

 union alignas(StackBuffer::kPlatformStackAlignment) TestStackBuffer {
   uintptr_t as_uintptr[kTestStackBufferSize / sizeof(uintptr_t)];
   uint16_t as_uint16[kTestStackBufferSize / sizeof(uint16_t)];
   uint8_t as_uint8[kTestStackBufferSize / sizeof(uint8_t)];
 };

 }  // namespace

 TEST(StackCopierTest, RewritePointerIfInOriginalStack_InStack) {
   uintptr_t original_stack[4];
   uintptr_t stack_copy[4];
   EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy[2]),
             CopyFunctions::RewritePointerIfInOriginalStack(
                 reinterpret_cast<uint8_t*>(&original_stack[0]),
                 &original_stack[0] + size(original_stack),
                 reinterpret_cast<uint8_t*>(&stack_copy[0]),
                 reinterpret_cast<uintptr_t>(&original_stack[2])));
 }

 TEST(StackCopierTest, RewritePointerIfInOriginalStack_NotInStack) {
   // We use this variable only for its address, which is outside of
   // original_stack.
   uintptr_t non_stack_location;
   uintptr_t original_stack[4];
   uintptr_t stack_copy[4];

   EXPECT_EQ(reinterpret_cast<uintptr_t>(&non_stack_location),
             CopyFunctions::RewritePointerIfInOriginalStack(
                 reinterpret_cast<uint8_t*>(&original_stack[0]),
                 &original_stack[0] + size(original_stack),
                 reinterpret_cast<uint8_t*>(&stack_copy[0]),
                 reinterpret_cast<uintptr_t>(&non_stack_location)));
 }

 TEST(StackCopierTest, StackCopy) {
   TestStackBuffer original_stack;
   // Fill the stack buffer with increasing uintptr_t values.
   std::iota(&original_stack.as_uintptr[0],
             &original_stack.as_uintptr[0] + size(original_stack.as_uintptr),
             100);
   // Replace the third value with an address within the buffer.
   original_stack.as_uintptr[2] =
       reinterpret_cast<uintptr_t>(&original_stack.as_uintptr[1]);
   TestStackBuffer stack_copy;

   CopyFunctions::CopyStackContentsAndRewritePointers(
       &original_stack.as_uint8[0],
       &original_stack.as_uintptr[0] + size(original_stack.as_uintptr),
       StackBuffer::kPlatformStackAlignment, &stack_copy.as_uintptr[0]);

   EXPECT_EQ(original_stack.as_uintptr[0], stack_copy.as_uintptr[0]);
   EXPECT_EQ(original_stack.as_uintptr[1], stack_copy.as_uintptr[1]);
   EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy.as_uintptr[1]),
             stack_copy.as_uintptr[2]);
   EXPECT_EQ(original_stack.as_uintptr[3], stack_copy.as_uintptr[3]);
 }

 TEST(StackCopierTest, StackCopy_NonAlignedStackPointerCopy) {
   TestStackBuffer stack_buffer;

   // Fill the stack buffer with increasing uint16_t values.
   std::iota(&stack_buffer.as_uint16[0],
             &stack_buffer.as_uint16[0] + size(stack_buffer.as_uint16), 100);

   // Set the stack bottom to the unaligned location one uint16_t into the
   // buffer.
   uint8_t* unaligned_stack_bottom =
       reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

   // Leave extra space within the stack buffer beyond the end of the stack, but
   // preserve the platform alignment.
   const size_t extra_space = StackBuffer::kPlatformStackAlignment;
   uintptr_t* stack_top =
       &stack_buffer.as_uintptr[size(stack_buffer.as_uintptr) -
                                extra_space / sizeof(uintptr_t)];

   // Initialize the copy to all zeros.
   TestStackBuffer stack_copy_buffer = {{0}};

   const uint8_t* stack_copy_bottom =
       CopyFunctions::CopyStackContentsAndRewritePointers(
           unaligned_stack_bottom, stack_top,
           StackBuffer::kPlatformStackAlignment,
           &stack_copy_buffer.as_uintptr[0]);

   // The stack copy bottom address is expected to be at the same offset into the
   // stack copy buffer as the unaligned stack bottom is from the stack buffer.
   // Since the buffers have the same platform stack alignment this also ensures
   // the alignment of the bottom addresses is the same.
   EXPECT_EQ(unaligned_stack_bottom - &stack_buffer.as_uint8[0],
             stack_copy_bottom - &stack_copy_buffer.as_uint8[0]);

   // The first value in the copy should not be overwritten since the stack
   // starts at the second uint16_t.
   EXPECT_EQ(0u, stack_copy_buffer.as_uint16[0]);

   // The next values up to the extra space should have been copied.
   const size_t max_index =
       size(stack_copy_buffer.as_uint16) - extra_space / sizeof(uint16_t);
   for (size_t i = 1; i < max_index; ++i)
     EXPECT_EQ(i + 100, stack_copy_buffer.as_uint16[i]);

   // None of the values in the empty space should have been copied.
   for (size_t i = max_index; i < size(stack_copy_buffer.as_uint16); ++i)
     EXPECT_EQ(0u, stack_copy_buffer.as_uint16[i]);
 }

 // Checks that an unaligned within-stack pointer value at the start of the stack
 // is not rewritten.
 TEST(StackCopierTest, StackCopy_NonAlignedStackPointerUnalignedRewriteAtStart) {
   // Initially fill the buffer with 0s.
   TestStackBuffer stack_buffer = {{0}};

   // Set the stack bottom to the unaligned location one uint16_t into the
   // buffer.
   uint8_t* unaligned_stack_bottom =
       reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

   // Set the first unaligned pointer-sized value to an address within the stack.
   uintptr_t within_stack_pointer =
       reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);
   std::memcpy(unaligned_stack_bottom, &within_stack_pointer,
               sizeof(within_stack_pointer));

   TestStackBuffer stack_copy_buffer = {{0}};

   const uint8_t* stack_copy_bottom =
       CopyFunctions::CopyStackContentsAndRewritePointers(
           unaligned_stack_bottom,
           &stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
           StackBuffer::kPlatformStackAlignment,
           &stack_copy_buffer.as_uintptr[0]);

   uintptr_t copied_within_stack_pointer;
   std::memcpy(&copied_within_stack_pointer, stack_copy_bottom,
               sizeof(copied_within_stack_pointer));

   // The rewriting should only operate on pointer-aligned values so the
   // unaligned value should be copied verbatim.
   EXPECT_EQ(within_stack_pointer, copied_within_stack_pointer);
 }

 // Checks that an unaligned within-stack pointer after the start of the stack is
 // not rewritten.
 TEST(StackCopierTest,
      StackCopy_NonAlignedStackPointerUnalignedRewriteAfterStart) {
   // Initially fill the buffer with 0s.
   TestStackBuffer stack_buffer = {{0}};

   // Set the stack bottom to the unaligned location one uint16_t into the
   // buffer.
   uint8_t* unaligned_stack_bottom =
       reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

   // Set the second unaligned pointer-sized value to an address within the
   // stack.
   uintptr_t within_stack_pointer =
       reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);
   std::memcpy(unaligned_stack_bottom + sizeof(uintptr_t), &within_stack_pointer,
               sizeof(within_stack_pointer));

   TestStackBuffer stack_copy_buffer = {{0}};

   const uint8_t* stack_copy_bottom =
       CopyFunctions::CopyStackContentsAndRewritePointers(
           unaligned_stack_bottom,
           &stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
           StackBuffer::kPlatformStackAlignment,
           &stack_copy_buffer.as_uintptr[0]);

   uintptr_t copied_within_stack_pointer;
   std::memcpy(&copied_within_stack_pointer,
               stack_copy_bottom + sizeof(uintptr_t),
               sizeof(copied_within_stack_pointer));

   // The rewriting should only operate on pointer-aligned values so the
   // unaligned value should be copied verbatim.
   EXPECT_EQ(within_stack_pointer, copied_within_stack_pointer);
 }

 TEST(StackCopierTest, StackCopy_NonAlignedStackPointerAlignedRewrite) {
   // Initially fill the buffer with 0s.
   TestStackBuffer stack_buffer = {{0}};

   // Set the stack bottom to the unaligned location one uint16_t into the
   // buffer.
   uint8_t* unaligned_stack_bottom =
       reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

   // Set the second aligned pointer-sized value to an address within the stack.
   stack_buffer.as_uintptr[1] =
       reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);

   TestStackBuffer stack_copy_buffer = {{0}};

   CopyFunctions::CopyStackContentsAndRewritePointers(
       unaligned_stack_bottom,
       &stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
       StackBuffer::kPlatformStackAlignment, &stack_copy_buffer.as_uintptr[0]);

   // The aligned pointer should have been rewritten to point within the stack
   // copy.
   EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy_buffer.as_uintptr[2]),
             stack_copy_buffer.as_uintptr[1]);
 }

 }  // namespace base
	// Copyright 2019 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.

	#include <memory>
	#include <numeric>

	#include "base/profiler/stack_buffer.h"
	#include "base/profiler/stack_copier.h"
	#include "base/stl_util.h"
	#include "testing/gmock/include/gmock/gmock.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace base {

	namespace {

	class CopyFunctions : public StackCopier {
	public:
	using StackCopier::CopyStackContentsAndRewritePointers;
	using StackCopier::RewritePointerIfInOriginalStack;
	};

	static constexpr size_t kTestStackBufferSize = sizeof(uintptr_t) * 4;

	union alignas(StackBuffer::kPlatformStackAlignment) TestStackBuffer {
	uintptr_t as_uintptr[kTestStackBufferSize / sizeof(uintptr_t)];
	uint16_t as_uint16[kTestStackBufferSize / sizeof(uint16_t)];
	uint8_t as_uint8[kTestStackBufferSize / sizeof(uint8_t)];
	};

	} // namespace

	TEST(StackCopierTest, RewritePointerIfInOriginalStack_InStack) {
	uintptr_t original_stack[4];
	uintptr_t stack_copy[4];
	EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy[2]),
	CopyFunctions::RewritePointerIfInOriginalStack(
	reinterpret_cast<uint8_t*>(&original_stack[0]),
	&original_stack[0] + size(original_stack),
	reinterpret_cast<uint8_t*>(&stack_copy[0]),
	reinterpret_cast<uintptr_t>(&original_stack[2])));
	}

	TEST(StackCopierTest, RewritePointerIfInOriginalStack_NotInStack) {
	// We use this variable only for its address, which is outside of
	// original_stack.
	uintptr_t non_stack_location;
	uintptr_t original_stack[4];
	uintptr_t stack_copy[4];

	EXPECT_EQ(reinterpret_cast<uintptr_t>(&non_stack_location),
	CopyFunctions::RewritePointerIfInOriginalStack(
	reinterpret_cast<uint8_t*>(&original_stack[0]),
	&original_stack[0] + size(original_stack),
	reinterpret_cast<uint8_t*>(&stack_copy[0]),
	reinterpret_cast<uintptr_t>(&non_stack_location)));
	}

	TEST(StackCopierTest, StackCopy) {
	TestStackBuffer original_stack;
	// Fill the stack buffer with increasing uintptr_t values.
	std::iota(&original_stack.as_uintptr[0],
	&original_stack.as_uintptr[0] + size(original_stack.as_uintptr),
	100);
	// Replace the third value with an address within the buffer.
	original_stack.as_uintptr[2] =
	reinterpret_cast<uintptr_t>(&original_stack.as_uintptr[1]);
	TestStackBuffer stack_copy;

	CopyFunctions::CopyStackContentsAndRewritePointers(
	&original_stack.as_uint8[0],
	&original_stack.as_uintptr[0] + size(original_stack.as_uintptr),
	StackBuffer::kPlatformStackAlignment, &stack_copy.as_uintptr[0]);

	EXPECT_EQ(original_stack.as_uintptr[0], stack_copy.as_uintptr[0]);
	EXPECT_EQ(original_stack.as_uintptr[1], stack_copy.as_uintptr[1]);
	EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy.as_uintptr[1]),
	stack_copy.as_uintptr[2]);
	EXPECT_EQ(original_stack.as_uintptr[3], stack_copy.as_uintptr[3]);
	}

	TEST(StackCopierTest, StackCopy_NonAlignedStackPointerCopy) {
	TestStackBuffer stack_buffer;

	// Fill the stack buffer with increasing uint16_t values.
	std::iota(&stack_buffer.as_uint16[0],
	&stack_buffer.as_uint16[0] + size(stack_buffer.as_uint16), 100);

	// Set the stack bottom to the unaligned location one uint16_t into the
	// buffer.
	uint8_t* unaligned_stack_bottom =
	reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

	// Leave extra space within the stack buffer beyond the end of the stack, but
	// preserve the platform alignment.
	const size_t extra_space = StackBuffer::kPlatformStackAlignment;
	uintptr_t* stack_top =
	&stack_buffer.as_uintptr[size(stack_buffer.as_uintptr) -
	extra_space / sizeof(uintptr_t)];

	// Initialize the copy to all zeros.
	TestStackBuffer stack_copy_buffer = {{0}};

	const uint8_t* stack_copy_bottom =
	CopyFunctions::CopyStackContentsAndRewritePointers(
	unaligned_stack_bottom, stack_top,
	StackBuffer::kPlatformStackAlignment,
	&stack_copy_buffer.as_uintptr[0]);

	// The stack copy bottom address is expected to be at the same offset into the
	// stack copy buffer as the unaligned stack bottom is from the stack buffer.
	// Since the buffers have the same platform stack alignment this also ensures
	// the alignment of the bottom addresses is the same.
	EXPECT_EQ(unaligned_stack_bottom - &stack_buffer.as_uint8[0],
	stack_copy_bottom - &stack_copy_buffer.as_uint8[0]);

	// The first value in the copy should not be overwritten since the stack
	// starts at the second uint16_t.
	EXPECT_EQ(0u, stack_copy_buffer.as_uint16[0]);

	// The next values up to the extra space should have been copied.
	const size_t max_index =
	size(stack_copy_buffer.as_uint16) - extra_space / sizeof(uint16_t);
	for (size_t i = 1; i < max_index; ++i)
	EXPECT_EQ(i + 100, stack_copy_buffer.as_uint16[i]);

	// None of the values in the empty space should have been copied.
	for (size_t i = max_index; i < size(stack_copy_buffer.as_uint16); ++i)
	EXPECT_EQ(0u, stack_copy_buffer.as_uint16[i]);
	}

	// Checks that an unaligned within-stack pointer value at the start of the stack
	// is not rewritten.
	TEST(StackCopierTest, StackCopy_NonAlignedStackPointerUnalignedRewriteAtStart) {
	// Initially fill the buffer with 0s.
	TestStackBuffer stack_buffer = {{0}};

	// Set the stack bottom to the unaligned location one uint16_t into the
	// buffer.
	uint8_t* unaligned_stack_bottom =
	reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

	// Set the first unaligned pointer-sized value to an address within the stack.
	uintptr_t within_stack_pointer =
	reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);
	std::memcpy(unaligned_stack_bottom, &within_stack_pointer,
	sizeof(within_stack_pointer));

	TestStackBuffer stack_copy_buffer = {{0}};

	const uint8_t* stack_copy_bottom =
	CopyFunctions::CopyStackContentsAndRewritePointers(
	unaligned_stack_bottom,
	&stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
	StackBuffer::kPlatformStackAlignment,
	&stack_copy_buffer.as_uintptr[0]);

	uintptr_t copied_within_stack_pointer;
	std::memcpy(&copied_within_stack_pointer, stack_copy_bottom,
	sizeof(copied_within_stack_pointer));

	// The rewriting should only operate on pointer-aligned values so the
	// unaligned value should be copied verbatim.
	EXPECT_EQ(within_stack_pointer, copied_within_stack_pointer);
	}

	// Checks that an unaligned within-stack pointer after the start of the stack is
	// not rewritten.
	TEST(StackCopierTest,
	StackCopy_NonAlignedStackPointerUnalignedRewriteAfterStart) {
	// Initially fill the buffer with 0s.
	TestStackBuffer stack_buffer = {{0}};

	// Set the stack bottom to the unaligned location one uint16_t into the
	// buffer.
	uint8_t* unaligned_stack_bottom =
	reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

	// Set the second unaligned pointer-sized value to an address within the
	// stack.
	uintptr_t within_stack_pointer =
	reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);
	std::memcpy(unaligned_stack_bottom + sizeof(uintptr_t), &within_stack_pointer,
	sizeof(within_stack_pointer));

	TestStackBuffer stack_copy_buffer = {{0}};

	const uint8_t* stack_copy_bottom =
	CopyFunctions::CopyStackContentsAndRewritePointers(
	unaligned_stack_bottom,
	&stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
	StackBuffer::kPlatformStackAlignment,
	&stack_copy_buffer.as_uintptr[0]);

	uintptr_t copied_within_stack_pointer;
	std::memcpy(&copied_within_stack_pointer,
	stack_copy_bottom + sizeof(uintptr_t),
	sizeof(copied_within_stack_pointer));

	// The rewriting should only operate on pointer-aligned values so the
	// unaligned value should be copied verbatim.
	EXPECT_EQ(within_stack_pointer, copied_within_stack_pointer);
	}

	TEST(StackCopierTest, StackCopy_NonAlignedStackPointerAlignedRewrite) {
	// Initially fill the buffer with 0s.
	TestStackBuffer stack_buffer = {{0}};

	// Set the stack bottom to the unaligned location one uint16_t into the
	// buffer.
	uint8_t* unaligned_stack_bottom =
	reinterpret_cast<uint8_t*>(&stack_buffer.as_uint16[1]);

	// Set the second aligned pointer-sized value to an address within the stack.
	stack_buffer.as_uintptr[1] =
	reinterpret_cast<uintptr_t>(&stack_buffer.as_uintptr[2]);

	TestStackBuffer stack_copy_buffer = {{0}};

	CopyFunctions::CopyStackContentsAndRewritePointers(
	unaligned_stack_bottom,
	&stack_buffer.as_uintptr[0] + size(stack_buffer.as_uintptr),
	StackBuffer::kPlatformStackAlignment, &stack_copy_buffer.as_uintptr[0]);

	// The aligned pointer should have been rewritten to point within the stack
	// copy.
	EXPECT_EQ(reinterpret_cast<uintptr_t>(&stack_copy_buffer.as_uintptr[2]),
	stack_copy_buffer.as_uintptr[1]);
	}

	} // namespace base