unittests/Support/MemoryTest.cpp - platform/external/llvm - Git at Google

 //===- llvm/unittest/Support/AllocatorTest.cpp - BumpPtrAllocator tests ---===//
 //
 //		       The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Support/Memory.h"
 #include "llvm/Support/Process.h"
 #include "gtest/gtest.h"
 #include <cstdlib>

 using namespace llvm;
 using namespace sys;

 namespace {

 class MappedMemoryTest : public ::testing::TestWithParam<unsigned> {
 public:
   MappedMemoryTest() {
     Flags = GetParam();
     PageSize = sys::process::get_self()->page_size();
   }

 protected:
   // Adds RW flags to permit testing of the resulting memory
   unsigned getTestableEquivalent(unsigned RequestedFlags) {
     switch (RequestedFlags) {
     case Memory::MF_READ:
     case Memory::MF_WRITE:
     case Memory::MF_READ|Memory::MF_WRITE:
       return Memory::MF_READ|Memory::MF_WRITE;
     case Memory::MF_READ|Memory::MF_EXEC:
     case Memory::MF_READ|Memory::MF_WRITE|Memory::MF_EXEC:
     case Memory::MF_EXEC:
       return Memory::MF_READ|Memory::MF_WRITE|Memory::MF_EXEC;
     }
     // Default in case values are added to the enum, as required by some compilers
     return Memory::MF_READ|Memory::MF_WRITE;
   }

   // Returns true if the memory blocks overlap
   bool doesOverlap(MemoryBlock M1, MemoryBlock M2) {
     if (M1.base() == M2.base())
       return true;

     if (M1.base() > M2.base())
       return (unsigned char *)M2.base() + M2.size() > M1.base();

     return (unsigned char *)M1.base() + M1.size() > M2.base();
   }

   unsigned Flags;
   size_t   PageSize;
 };

 TEST_P(MappedMemoryTest, AllocAndRelease) {
   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(sizeof(int), M1.size());

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
 }

 TEST_P(MappedMemoryTest, MultipleAllocAndRelease) {
   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(16, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(64, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(32, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(16U, M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(64U, M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(32U, M3.size());

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   MemoryBlock M4 = Memory::allocateMappedMemory(16, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   EXPECT_NE((void*)0, M4.base());
   EXPECT_LE(16U, M4.size());
   EXPECT_FALSE(Memory::releaseMappedMemory(M4));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, BasicWrite) {
   // This test applies only to readable and writeable combinations
   if (Flags &&
       !((Flags & Memory::MF_READ) && (Flags & Memory::MF_WRITE)))
     return;

   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(sizeof(int), M1.size());

   int *a = (int*)M1.base();
   *a = 1;
   EXPECT_EQ(1, *a);

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
 }

 TEST_P(MappedMemoryTest, MultipleWrite) {
   // This test applies only to readable and writeable combinations
   if (Flags &&
       !((Flags & Memory::MF_READ) && (Flags & Memory::MF_WRITE)))
     return;
   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(8 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(4 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(1U * sizeof(int), M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(8U * sizeof(int), M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(4U * sizeof(int), M3.size());

   int *x = (int*)M1.base();
   *x = 1;

   int *y = (int*)M2.base();
   for (int i = 0; i < 8; i++) {
     y[i] = i;
   }

   int *z = (int*)M3.base();
   *z = 42;

   EXPECT_EQ(1, *x);
   EXPECT_EQ(7, y[7]);
   EXPECT_EQ(42, *z);

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));

   MemoryBlock M4 = Memory::allocateMappedMemory(64 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   EXPECT_NE((void*)0, M4.base());
   EXPECT_LE(64U * sizeof(int), M4.size());
   x = (int*)M4.base();
   *x = 4;
   EXPECT_EQ(4, *x);
   EXPECT_FALSE(Memory::releaseMappedMemory(M4));

   // Verify that M2 remains unaffected by other activity
   for (int i = 0; i < 8; i++) {
     EXPECT_EQ(i, y[i]);
   }
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, EnabledWrite) {
   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(2 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(8 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(4 * sizeof(int), 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(2U * sizeof(int), M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(8U * sizeof(int), M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(4U * sizeof(int), M3.size());

   EXPECT_FALSE(Memory::protectMappedMemory(M1, getTestableEquivalent(Flags)));
   EXPECT_FALSE(Memory::protectMappedMemory(M2, getTestableEquivalent(Flags)));
   EXPECT_FALSE(Memory::protectMappedMemory(M3, getTestableEquivalent(Flags)));

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   int *x = (int*)M1.base();
   *x = 1;
   int *y = (int*)M2.base();
   for (unsigned int i = 0; i < 8; i++) {
     y[i] = i;
   }
   int *z = (int*)M3.base();
   *z = 42;

   EXPECT_EQ(1, *x);
   EXPECT_EQ(7, y[7]);
   EXPECT_EQ(42, *z);

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   EXPECT_EQ(6, y[6]);

   MemoryBlock M4 = Memory::allocateMappedMemory(16, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   EXPECT_NE((void*)0, M4.base());
   EXPECT_LE(16U, M4.size());
   EXPECT_EQ(error_code::success(), Memory::protectMappedMemory(M4, getTestableEquivalent(Flags)));
   x = (int*)M4.base();
   *x = 4;
   EXPECT_EQ(4, *x);
   EXPECT_FALSE(Memory::releaseMappedMemory(M4));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, SuccessiveNear) {
   error_code EC;
   MemoryBlock M1 = Memory::allocateMappedMemory(16, 0, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(64, &M1, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(32, &M2, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(16U, M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(64U, M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(32U, M3.size());

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, DuplicateNear) {
   error_code EC;
   MemoryBlock Near((void*)(3*PageSize), 16);
   MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(16U, M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(64U, M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(32U, M3.size());

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, ZeroNear) {
   error_code EC;
   MemoryBlock Near(0, 0);
   MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(16U, M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(64U, M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(32U, M3.size());

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, ZeroSizeNear) {
   error_code EC;
   MemoryBlock Near((void*)(4*PageSize), 0);
   MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);
   MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(16U, M1.size());
   EXPECT_NE((void*)0, M2.base());
   EXPECT_LE(64U, M2.size());
   EXPECT_NE((void*)0, M3.base());
   EXPECT_LE(32U, M3.size());

   EXPECT_FALSE(doesOverlap(M1, M2));
   EXPECT_FALSE(doesOverlap(M2, M3));
   EXPECT_FALSE(doesOverlap(M1, M3));

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
   EXPECT_FALSE(Memory::releaseMappedMemory(M3));
   EXPECT_FALSE(Memory::releaseMappedMemory(M2));
 }

 TEST_P(MappedMemoryTest, UnalignedNear) {
   error_code EC;
   MemoryBlock Near((void*)(2*PageSize+5), 0);
   MemoryBlock M1 = Memory::allocateMappedMemory(15, &Near, Flags, EC);
   EXPECT_EQ(error_code::success(), EC);

   EXPECT_NE((void*)0, M1.base());
   EXPECT_LE(sizeof(int), M1.size());

   EXPECT_FALSE(Memory::releaseMappedMemory(M1));
 }

 // Note that Memory::MF_WRITE is not supported exclusively across
 // operating systems and architectures and can imply MF_READ|MF_WRITE
 unsigned MemoryFlags[] = {
 			   Memory::MF_READ,
 			   Memory::MF_WRITE,
 			   Memory::MF_READ|Memory::MF_WRITE,
 			   Memory::MF_EXEC,
 			   Memory::MF_READ|Memory::MF_EXEC,
 			   Memory::MF_READ|Memory::MF_WRITE|Memory::MF_EXEC
 			 };

 INSTANTIATE_TEST_CASE_P(AllocationTests,
 			MappedMemoryTest,
 			::testing::ValuesIn(MemoryFlags));

 }  // anonymous namespace
	//===- llvm/unittest/Support/AllocatorTest.cpp - BumpPtrAllocator tests ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Support/Memory.h"
	#include "llvm/Support/Process.h"
	#include "gtest/gtest.h"
	#include <cstdlib>

	using namespace llvm;
	using namespace sys;

	namespace {

	class MappedMemoryTest : public ::testing::TestWithParam<unsigned> {
	public:
	MappedMemoryTest() {
	Flags = GetParam();
	PageSize = sys::process::get_self()->page_size();
	}

	protected:
	// Adds RW flags to permit testing of the resulting memory
	unsigned getTestableEquivalent(unsigned RequestedFlags) {
	switch (RequestedFlags) {
	case Memory::MF_READ:
	case Memory::MF_WRITE:
	case Memory::MF_READ\|Memory::MF_WRITE:
	return Memory::MF_READ\|Memory::MF_WRITE;
	case Memory::MF_READ\|Memory::MF_EXEC:
	case Memory::MF_READ\|Memory::MF_WRITE\|Memory::MF_EXEC:
	case Memory::MF_EXEC:
	return Memory::MF_READ\|Memory::MF_WRITE\|Memory::MF_EXEC;
	}
	// Default in case values are added to the enum, as required by some compilers
	return Memory::MF_READ\|Memory::MF_WRITE;
	}

	// Returns true if the memory blocks overlap
	bool doesOverlap(MemoryBlock M1, MemoryBlock M2) {
	if (M1.base() == M2.base())
	return true;

	if (M1.base() > M2.base())
	return (unsigned char *)M2.base() + M2.size() > M1.base();

	return (unsigned char *)M1.base() + M1.size() > M2.base();
	}

	unsigned Flags;
	size_t PageSize;
	};

	TEST_P(MappedMemoryTest, AllocAndRelease) {
	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(sizeof(int), M1.size());

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	}

	TEST_P(MappedMemoryTest, MultipleAllocAndRelease) {
	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(16, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(64, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(32, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(16U, M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(64U, M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(32U, M3.size());

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	MemoryBlock M4 = Memory::allocateMappedMemory(16, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	EXPECT_NE((void*)0, M4.base());
	EXPECT_LE(16U, M4.size());
	EXPECT_FALSE(Memory::releaseMappedMemory(M4));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, BasicWrite) {
	// This test applies only to readable and writeable combinations
	if (Flags &&
	!((Flags & Memory::MF_READ) && (Flags & Memory::MF_WRITE)))
	return;

	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(sizeof(int), M1.size());

	int a = (int)M1.base();
	*a = 1;
	EXPECT_EQ(1, *a);

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	}

	TEST_P(MappedMemoryTest, MultipleWrite) {
	// This test applies only to readable and writeable combinations
	if (Flags &&
	!((Flags & Memory::MF_READ) && (Flags & Memory::MF_WRITE)))
	return;
	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(8 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(4 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(1U * sizeof(int), M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(8U * sizeof(int), M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(4U * sizeof(int), M3.size());

	int x = (int)M1.base();
	*x = 1;

	int y = (int)M2.base();
	for (int i = 0; i < 8; i++) {
	y[i] = i;
	}

	int z = (int)M3.base();
	*z = 42;

	EXPECT_EQ(1, *x);
	EXPECT_EQ(7, y[7]);
	EXPECT_EQ(42, *z);

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));

	MemoryBlock M4 = Memory::allocateMappedMemory(64 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	EXPECT_NE((void*)0, M4.base());
	EXPECT_LE(64U * sizeof(int), M4.size());
	x = (int*)M4.base();
	*x = 4;
	EXPECT_EQ(4, *x);
	EXPECT_FALSE(Memory::releaseMappedMemory(M4));

	// Verify that M2 remains unaffected by other activity
	for (int i = 0; i < 8; i++) {
	EXPECT_EQ(i, y[i]);
	}
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, EnabledWrite) {
	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(2 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(8 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(4 * sizeof(int), 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(2U * sizeof(int), M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(8U * sizeof(int), M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(4U * sizeof(int), M3.size());

	EXPECT_FALSE(Memory::protectMappedMemory(M1, getTestableEquivalent(Flags)));
	EXPECT_FALSE(Memory::protectMappedMemory(M2, getTestableEquivalent(Flags)));
	EXPECT_FALSE(Memory::protectMappedMemory(M3, getTestableEquivalent(Flags)));

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	int x = (int)M1.base();
	*x = 1;
	int y = (int)M2.base();
	for (unsigned int i = 0; i < 8; i++) {
	y[i] = i;
	}
	int z = (int)M3.base();
	*z = 42;

	EXPECT_EQ(1, *x);
	EXPECT_EQ(7, y[7]);
	EXPECT_EQ(42, *z);

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	EXPECT_EQ(6, y[6]);

	MemoryBlock M4 = Memory::allocateMappedMemory(16, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	EXPECT_NE((void*)0, M4.base());
	EXPECT_LE(16U, M4.size());
	EXPECT_EQ(error_code::success(), Memory::protectMappedMemory(M4, getTestableEquivalent(Flags)));
	x = (int*)M4.base();
	*x = 4;
	EXPECT_EQ(4, *x);
	EXPECT_FALSE(Memory::releaseMappedMemory(M4));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, SuccessiveNear) {
	error_code EC;
	MemoryBlock M1 = Memory::allocateMappedMemory(16, 0, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(64, &M1, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(32, &M2, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(16U, M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(64U, M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(32U, M3.size());

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, DuplicateNear) {
	error_code EC;
	MemoryBlock Near((void)(3PageSize), 16);
	MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(16U, M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(64U, M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(32U, M3.size());

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, ZeroNear) {
	error_code EC;
	MemoryBlock Near(0, 0);
	MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(16U, M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(64U, M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(32U, M3.size());

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, ZeroSizeNear) {
	error_code EC;
	MemoryBlock Near((void)(4PageSize), 0);
	MemoryBlock M1 = Memory::allocateMappedMemory(16, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M2 = Memory::allocateMappedMemory(64, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);
	MemoryBlock M3 = Memory::allocateMappedMemory(32, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(16U, M1.size());
	EXPECT_NE((void*)0, M2.base());
	EXPECT_LE(64U, M2.size());
	EXPECT_NE((void*)0, M3.base());
	EXPECT_LE(32U, M3.size());

	EXPECT_FALSE(doesOverlap(M1, M2));
	EXPECT_FALSE(doesOverlap(M2, M3));
	EXPECT_FALSE(doesOverlap(M1, M3));

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	EXPECT_FALSE(Memory::releaseMappedMemory(M3));
	EXPECT_FALSE(Memory::releaseMappedMemory(M2));
	}

	TEST_P(MappedMemoryTest, UnalignedNear) {
	error_code EC;
	MemoryBlock Near((void)(2PageSize+5), 0);
	MemoryBlock M1 = Memory::allocateMappedMemory(15, &Near, Flags, EC);
	EXPECT_EQ(error_code::success(), EC);

	EXPECT_NE((void*)0, M1.base());
	EXPECT_LE(sizeof(int), M1.size());

	EXPECT_FALSE(Memory::releaseMappedMemory(M1));
	}

	// Note that Memory::MF_WRITE is not supported exclusively across
	// operating systems and architectures and can imply MF_READ\|MF_WRITE
	unsigned MemoryFlags[] = {
	Memory::MF_READ,
	Memory::MF_WRITE,
	Memory::MF_READ\|Memory::MF_WRITE,
	Memory::MF_EXEC,
	Memory::MF_READ\|Memory::MF_EXEC,
	Memory::MF_READ\|Memory::MF_WRITE\|Memory::MF_EXEC
	};

	INSTANTIATE_TEST_CASE_P(AllocationTests,
	MappedMemoryTest,
	::testing::ValuesIn(MemoryFlags));

	} // anonymous namespace