mojo/system/raw_shared_buffer_unittest.cc - platform/external/chromium_org - Git at Google

 // Copyright 2014 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 "mojo/system/raw_shared_buffer.h"

 #include <limits>

 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "base/memory/scoped_ptr.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace mojo {
 namespace system {
 namespace {

 TEST(RawSharedBufferTest, Basic) {
   const size_t kNumInts = 100;
   const size_t kNumBytes = kNumInts * sizeof(int);
   // A fudge so that we're not just writing zero bytes 75% of the time.
   const int kFudge = 1234567890;

   // Make some memory.
   scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kNumBytes));
   ASSERT_TRUE(buffer);

   // Map it all, scribble some stuff, and then unmap it.
   {
     EXPECT_TRUE(buffer->IsValidMap(0, kNumBytes));
     scoped_ptr<RawSharedBufferMapping> mapping(buffer->Map(0, kNumBytes));
     ASSERT_TRUE(mapping);
     ASSERT_TRUE(mapping->base());
     int* stuff = static_cast<int*>(mapping->base());
     for (size_t i = 0; i < kNumInts; i++)
       stuff[i] = static_cast<int>(i) + kFudge;
   }

   // Map it all again, check that our scribbling is still there, then do a
   // partial mapping and scribble on that, check that everything is coherent,
   // unmap the first mapping, scribble on some of the second mapping, and then
   // unmap it.
   {
     ASSERT_TRUE(buffer->IsValidMap(0, kNumBytes));
     // Use |MapNoCheck()| this time.
     scoped_ptr<RawSharedBufferMapping> mapping1(
         buffer->MapNoCheck(0, kNumBytes));
     ASSERT_TRUE(mapping1);
     ASSERT_TRUE(mapping1->base());
     int* stuff1 = static_cast<int*>(mapping1->base());
     for (size_t i = 0; i < kNumInts; i++)
       EXPECT_EQ(static_cast<int>(i) + kFudge, stuff1[i]) << i;

     scoped_ptr<RawSharedBufferMapping> mapping2(
         buffer->Map((kNumInts / 2) * sizeof(int), 2 * sizeof(int)));
     ASSERT_TRUE(mapping2);
     ASSERT_TRUE(mapping2->base());
     int* stuff2 = static_cast<int*>(mapping2->base());
     EXPECT_EQ(static_cast<int>(kNumInts / 2) + kFudge, stuff2[0]);
     EXPECT_EQ(static_cast<int>(kNumInts / 2) + 1 + kFudge, stuff2[1]);

     stuff2[0] = 123;
     stuff2[1] = 456;
     EXPECT_EQ(123, stuff1[kNumInts / 2]);
     EXPECT_EQ(456, stuff1[kNumInts / 2 + 1]);

     mapping1.reset();

     EXPECT_EQ(123, stuff2[0]);
     EXPECT_EQ(456, stuff2[1]);
     stuff2[1] = 789;
   }

   // Do another partial mapping and check that everything is the way we expect
   // it to be.
   {
     EXPECT_TRUE(buffer->IsValidMap(sizeof(int), kNumBytes - sizeof(int)));
     scoped_ptr<RawSharedBufferMapping> mapping(
         buffer->Map(sizeof(int), kNumBytes - sizeof(int)));
     ASSERT_TRUE(mapping);
     ASSERT_TRUE(mapping->base());
     int* stuff = static_cast<int*>(mapping->base());

     for (size_t j = 0; j < kNumInts - 1; j++) {
       int i = static_cast<int>(j) + 1;
       if (i == kNumInts / 2) {
         EXPECT_EQ(123, stuff[j]);
       } else if (i == kNumInts / 2 + 1) {
         EXPECT_EQ(789, stuff[j]);
       } else {
         EXPECT_EQ(i + kFudge, stuff[j]) << i;
       }
     }
   }
 }

 // TODO(vtl): Bigger buffers.

 TEST(RawSharedBufferTest, InvalidMappings) {
   scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
   ASSERT_TRUE(buffer);

   // Zero length not allowed.
   EXPECT_FALSE(buffer->Map(0, 0));
   EXPECT_FALSE(buffer->IsValidMap(0, 0));

   // Okay:
   EXPECT_TRUE(buffer->Map(0, 100));
   EXPECT_TRUE(buffer->IsValidMap(0, 100));
   // Offset + length too big.
   EXPECT_FALSE(buffer->Map(0, 101));
   EXPECT_FALSE(buffer->IsValidMap(0, 101));
   EXPECT_FALSE(buffer->Map(1, 100));
   EXPECT_FALSE(buffer->IsValidMap(1, 100));

   // Okay:
   EXPECT_TRUE(buffer->Map(50, 50));
   EXPECT_TRUE(buffer->IsValidMap(50, 50));
   // Offset + length too big.
   EXPECT_FALSE(buffer->Map(50, 51));
   EXPECT_FALSE(buffer->IsValidMap(50, 51));
   EXPECT_FALSE(buffer->Map(51, 50));
   EXPECT_FALSE(buffer->IsValidMap(51, 50));
 }

 TEST(RawSharedBufferTest, TooBig) {
   // If |size_t| is 32-bit, it's quite possible/likely that |Create()| succeeds
   // (since it only involves creating a 4 GB file).
   const size_t kMaxSizeT = std::numeric_limits<size_t>::max();
   scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kMaxSizeT));
   // But, assuming |sizeof(size_t) == sizeof(void*)|, mapping all of it should
   // always fail.
   if (buffer)
     EXPECT_FALSE(buffer->Map(0, kMaxSizeT));
 }

 // Tests that separate mappings get distinct addresses.
 // Note: It's not inconceivable that the OS could ref-count identical mappings
 // and reuse the same address, in which case we'd have to be more careful about
 // using the address as the key for unmapping.
 TEST(RawSharedBufferTest, MappingsDistinct) {
   scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
   scoped_ptr<RawSharedBufferMapping> mapping1(buffer->Map(0, 100));
   scoped_ptr<RawSharedBufferMapping> mapping2(buffer->Map(0, 100));
   EXPECT_NE(mapping1->base(), mapping2->base());
 }

 TEST(RawSharedBufferTest, BufferZeroInitialized) {
   static const size_t kSizes[] = { 10, 100, 1000, 10000, 100000 };
   for (size_t i = 0; i < arraysize(kSizes); i++) {
     scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kSizes[i]));
     scoped_ptr<RawSharedBufferMapping> mapping(buffer->Map(0, kSizes[i]));
     for (size_t j = 0; j < kSizes[i]; j++) {
       // "Assert" instead of "expect" so we don't spam the output with thousands
       // of failures if we fail.
       ASSERT_EQ('\0', static_cast<char*>(mapping->base())[j])
           << "size " << kSizes[i] << ", offset " << j;
     }
   }
 }

 TEST(RawSharedBufferTest, MappingsOutliveBuffer) {
   scoped_ptr<RawSharedBufferMapping> mapping1;
   scoped_ptr<RawSharedBufferMapping> mapping2;

   {
     scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
     mapping1 = buffer->Map(0, 100).Pass();
     mapping2 = buffer->Map(50, 50).Pass();
     static_cast<char*>(mapping1->base())[50] = 'x';
   }

   EXPECT_EQ('x', static_cast<char*>(mapping2->base())[0]);

   static_cast<char*>(mapping2->base())[1] = 'y';
   EXPECT_EQ('y', static_cast<char*>(mapping1->base())[51]);
 }

 }  // namespace
 }  // namespace system
 }  // namespace mojo
	// Copyright 2014 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 "mojo/system/raw_shared_buffer.h"

	#include <limits>

	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "base/memory/scoped_ptr.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace mojo {
	namespace system {
	namespace {

	TEST(RawSharedBufferTest, Basic) {
	const size_t kNumInts = 100;
	const size_t kNumBytes = kNumInts * sizeof(int);
	// A fudge so that we're not just writing zero bytes 75% of the time.
	const int kFudge = 1234567890;

	// Make some memory.
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kNumBytes));
	ASSERT_TRUE(buffer);

	// Map it all, scribble some stuff, and then unmap it.
	{
	EXPECT_TRUE(buffer->IsValidMap(0, kNumBytes));
	scoped_ptr<RawSharedBufferMapping> mapping(buffer->Map(0, kNumBytes));
	ASSERT_TRUE(mapping);
	ASSERT_TRUE(mapping->base());
	int* stuff = static_cast<int*>(mapping->base());
	for (size_t i = 0; i < kNumInts; i++)
	stuff[i] = static_cast<int>(i) + kFudge;
	}

	// Map it all again, check that our scribbling is still there, then do a
	// partial mapping and scribble on that, check that everything is coherent,
	// unmap the first mapping, scribble on some of the second mapping, and then
	// unmap it.
	{
	ASSERT_TRUE(buffer->IsValidMap(0, kNumBytes));
	// Use \|MapNoCheck()\| this time.
	scoped_ptr<RawSharedBufferMapping> mapping1(
	buffer->MapNoCheck(0, kNumBytes));
	ASSERT_TRUE(mapping1);
	ASSERT_TRUE(mapping1->base());
	int* stuff1 = static_cast<int*>(mapping1->base());
	for (size_t i = 0; i < kNumInts; i++)
	EXPECT_EQ(static_cast<int>(i) + kFudge, stuff1[i]) << i;

	scoped_ptr<RawSharedBufferMapping> mapping2(
	buffer->Map((kNumInts / 2) * sizeof(int), 2 * sizeof(int)));
	ASSERT_TRUE(mapping2);
	ASSERT_TRUE(mapping2->base());
	int* stuff2 = static_cast<int*>(mapping2->base());
	EXPECT_EQ(static_cast<int>(kNumInts / 2) + kFudge, stuff2[0]);
	EXPECT_EQ(static_cast<int>(kNumInts / 2) + 1 + kFudge, stuff2[1]);

	stuff2[0] = 123;
	stuff2[1] = 456;
	EXPECT_EQ(123, stuff1[kNumInts / 2]);
	EXPECT_EQ(456, stuff1[kNumInts / 2 + 1]);

	mapping1.reset();

	EXPECT_EQ(123, stuff2[0]);
	EXPECT_EQ(456, stuff2[1]);
	stuff2[1] = 789;
	}

	// Do another partial mapping and check that everything is the way we expect
	// it to be.
	{
	EXPECT_TRUE(buffer->IsValidMap(sizeof(int), kNumBytes - sizeof(int)));
	scoped_ptr<RawSharedBufferMapping> mapping(
	buffer->Map(sizeof(int), kNumBytes - sizeof(int)));
	ASSERT_TRUE(mapping);
	ASSERT_TRUE(mapping->base());
	int* stuff = static_cast<int*>(mapping->base());

	for (size_t j = 0; j < kNumInts - 1; j++) {
	int i = static_cast<int>(j) + 1;
	if (i == kNumInts / 2) {
	EXPECT_EQ(123, stuff[j]);
	} else if (i == kNumInts / 2 + 1) {
	EXPECT_EQ(789, stuff[j]);
	} else {
	EXPECT_EQ(i + kFudge, stuff[j]) << i;
	}
	}
	}
	}

	// TODO(vtl): Bigger buffers.

	TEST(RawSharedBufferTest, InvalidMappings) {
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
	ASSERT_TRUE(buffer);

	// Zero length not allowed.
	EXPECT_FALSE(buffer->Map(0, 0));
	EXPECT_FALSE(buffer->IsValidMap(0, 0));

	// Okay:
	EXPECT_TRUE(buffer->Map(0, 100));
	EXPECT_TRUE(buffer->IsValidMap(0, 100));
	// Offset + length too big.
	EXPECT_FALSE(buffer->Map(0, 101));
	EXPECT_FALSE(buffer->IsValidMap(0, 101));
	EXPECT_FALSE(buffer->Map(1, 100));
	EXPECT_FALSE(buffer->IsValidMap(1, 100));

	// Okay:
	EXPECT_TRUE(buffer->Map(50, 50));
	EXPECT_TRUE(buffer->IsValidMap(50, 50));
	// Offset + length too big.
	EXPECT_FALSE(buffer->Map(50, 51));
	EXPECT_FALSE(buffer->IsValidMap(50, 51));
	EXPECT_FALSE(buffer->Map(51, 50));
	EXPECT_FALSE(buffer->IsValidMap(51, 50));
	}

	TEST(RawSharedBufferTest, TooBig) {
	// If \|size_t\| is 32-bit, it's quite possible/likely that \|Create()\| succeeds
	// (since it only involves creating a 4 GB file).
	const size_t kMaxSizeT = std::numeric_limits<size_t>::max();
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kMaxSizeT));
	// But, assuming \|sizeof(size_t) == sizeof(void*)\|, mapping all of it should
	// always fail.
	if (buffer)
	EXPECT_FALSE(buffer->Map(0, kMaxSizeT));
	}

	// Tests that separate mappings get distinct addresses.
	// Note: It's not inconceivable that the OS could ref-count identical mappings
	// and reuse the same address, in which case we'd have to be more careful about
	// using the address as the key for unmapping.
	TEST(RawSharedBufferTest, MappingsDistinct) {
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
	scoped_ptr<RawSharedBufferMapping> mapping1(buffer->Map(0, 100));
	scoped_ptr<RawSharedBufferMapping> mapping2(buffer->Map(0, 100));
	EXPECT_NE(mapping1->base(), mapping2->base());
	}

	TEST(RawSharedBufferTest, BufferZeroInitialized) {
	static const size_t kSizes[] = { 10, 100, 1000, 10000, 100000 };
	for (size_t i = 0; i < arraysize(kSizes); i++) {
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(kSizes[i]));
	scoped_ptr<RawSharedBufferMapping> mapping(buffer->Map(0, kSizes[i]));
	for (size_t j = 0; j < kSizes[i]; j++) {
	// "Assert" instead of "expect" so we don't spam the output with thousands
	// of failures if we fail.
	ASSERT_EQ('\0', static_cast<char*>(mapping->base())[j])
	<< "size " << kSizes[i] << ", offset " << j;
	}
	}
	}

	TEST(RawSharedBufferTest, MappingsOutliveBuffer) {
	scoped_ptr<RawSharedBufferMapping> mapping1;
	scoped_ptr<RawSharedBufferMapping> mapping2;

	{
	scoped_refptr<RawSharedBuffer> buffer(RawSharedBuffer::Create(100));
	mapping1 = buffer->Map(0, 100).Pass();
	mapping2 = buffer->Map(50, 50).Pass();
	static_cast<char*>(mapping1->base())[50] = 'x';
	}

	EXPECT_EQ('x', static_cast<char*>(mapping2->base())[0]);

	static_cast<char*>(mapping2->base())[1] = 'y';
	EXPECT_EQ('y', static_cast<char*>(mapping1->base())[51]);
	}

	} // namespace
	} // namespace system
	} // namespace mojo