third_party/llvm-7.0/llvm/unittests/Support/ArrayRecyclerTest.cpp - SwiftShader.git - Git at Google

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

 #include "llvm/Support/ArrayRecycler.h"
 #include "llvm/Support/Allocator.h"
 #include "gtest/gtest.h"
 #include <cstdlib>

 using namespace llvm;

 namespace {

 struct Object {
   int Num;
   Object *Other;
 };
 typedef ArrayRecycler<Object> ARO;

 TEST(ArrayRecyclerTest, Capacity) {
   // Capacity size should never be 0.
   ARO::Capacity Cap = ARO::Capacity::get(0);
   EXPECT_LT(0u, Cap.getSize());

   size_t PrevSize = Cap.getSize();
   for (unsigned N = 1; N != 100; ++N) {
     Cap = ARO::Capacity::get(N);
     EXPECT_LE(N, Cap.getSize());
     if (PrevSize >= N)
       EXPECT_EQ(PrevSize, Cap.getSize());
     else
       EXPECT_LT(PrevSize, Cap.getSize());
     PrevSize = Cap.getSize();
   }

   // Check that the buckets are monotonically increasing.
   Cap = ARO::Capacity::get(0);
   PrevSize = Cap.getSize();
   for (unsigned N = 0; N != 20; ++N) {
     Cap = Cap.getNext();
     EXPECT_LT(PrevSize, Cap.getSize());
     PrevSize = Cap.getSize();
   }
 }

 TEST(ArrayRecyclerTest, Basics) {
   BumpPtrAllocator Allocator;
   ArrayRecycler<Object> DUT;

   ARO::Capacity Cap = ARO::Capacity::get(8);
   Object *A1 = DUT.allocate(Cap, Allocator);
   A1[0].Num = 21;
   A1[7].Num = 17;

   Object *A2 = DUT.allocate(Cap, Allocator);
   A2[0].Num = 121;
   A2[7].Num = 117;

   Object *A3 = DUT.allocate(Cap, Allocator);
   A3[0].Num = 221;
   A3[7].Num = 217;

   EXPECT_EQ(21, A1[0].Num);
   EXPECT_EQ(17, A1[7].Num);
   EXPECT_EQ(121, A2[0].Num);
   EXPECT_EQ(117, A2[7].Num);
   EXPECT_EQ(221, A3[0].Num);
   EXPECT_EQ(217, A3[7].Num);

   DUT.deallocate(Cap, A2);

   // Check that deallocation didn't clobber anything.
   EXPECT_EQ(21, A1[0].Num);
   EXPECT_EQ(17, A1[7].Num);
   EXPECT_EQ(221, A3[0].Num);
   EXPECT_EQ(217, A3[7].Num);

   // Verify recycling.
   Object *A2x = DUT.allocate(Cap, Allocator);
   EXPECT_EQ(A2, A2x);

   DUT.deallocate(Cap, A2x);
   DUT.deallocate(Cap, A1);
   DUT.deallocate(Cap, A3);

   // Objects are not required to be recycled in reverse deallocation order, but
   // that is what the current implementation does.
   Object *A3x = DUT.allocate(Cap, Allocator);
   EXPECT_EQ(A3, A3x);
   Object *A1x = DUT.allocate(Cap, Allocator);
   EXPECT_EQ(A1, A1x);
   Object *A2y = DUT.allocate(Cap, Allocator);
   EXPECT_EQ(A2, A2y);

   // Back to allocation from the BumpPtrAllocator.
   Object *A4 = DUT.allocate(Cap, Allocator);
   EXPECT_NE(A1, A4);
   EXPECT_NE(A2, A4);
   EXPECT_NE(A3, A4);

   DUT.clear(Allocator);
 }

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

	#include "llvm/Support/ArrayRecycler.h"
	#include "llvm/Support/Allocator.h"
	#include "gtest/gtest.h"
	#include <cstdlib>

	using namespace llvm;

	namespace {

	struct Object {
	int Num;
	Object *Other;
	};
	typedef ArrayRecycler<Object> ARO;

	TEST(ArrayRecyclerTest, Capacity) {
	// Capacity size should never be 0.
	ARO::Capacity Cap = ARO::Capacity::get(0);
	EXPECT_LT(0u, Cap.getSize());

	size_t PrevSize = Cap.getSize();
	for (unsigned N = 1; N != 100; ++N) {
	Cap = ARO::Capacity::get(N);
	EXPECT_LE(N, Cap.getSize());
	if (PrevSize >= N)
	EXPECT_EQ(PrevSize, Cap.getSize());
	else
	EXPECT_LT(PrevSize, Cap.getSize());
	PrevSize = Cap.getSize();
	}

	// Check that the buckets are monotonically increasing.
	Cap = ARO::Capacity::get(0);
	PrevSize = Cap.getSize();
	for (unsigned N = 0; N != 20; ++N) {
	Cap = Cap.getNext();
	EXPECT_LT(PrevSize, Cap.getSize());
	PrevSize = Cap.getSize();
	}
	}

	TEST(ArrayRecyclerTest, Basics) {
	BumpPtrAllocator Allocator;
	ArrayRecycler<Object> DUT;

	ARO::Capacity Cap = ARO::Capacity::get(8);
	Object *A1 = DUT.allocate(Cap, Allocator);
	A1[0].Num = 21;
	A1[7].Num = 17;

	Object *A2 = DUT.allocate(Cap, Allocator);
	A2[0].Num = 121;
	A2[7].Num = 117;

	Object *A3 = DUT.allocate(Cap, Allocator);
	A3[0].Num = 221;
	A3[7].Num = 217;

	EXPECT_EQ(21, A1[0].Num);
	EXPECT_EQ(17, A1[7].Num);
	EXPECT_EQ(121, A2[0].Num);
	EXPECT_EQ(117, A2[7].Num);
	EXPECT_EQ(221, A3[0].Num);
	EXPECT_EQ(217, A3[7].Num);

	DUT.deallocate(Cap, A2);

	// Check that deallocation didn't clobber anything.
	EXPECT_EQ(21, A1[0].Num);
	EXPECT_EQ(17, A1[7].Num);
	EXPECT_EQ(221, A3[0].Num);
	EXPECT_EQ(217, A3[7].Num);

	// Verify recycling.
	Object *A2x = DUT.allocate(Cap, Allocator);
	EXPECT_EQ(A2, A2x);

	DUT.deallocate(Cap, A2x);
	DUT.deallocate(Cap, A1);
	DUT.deallocate(Cap, A3);

	// Objects are not required to be recycled in reverse deallocation order, but
	// that is what the current implementation does.
	Object *A3x = DUT.allocate(Cap, Allocator);
	EXPECT_EQ(A3, A3x);
	Object *A1x = DUT.allocate(Cap, Allocator);
	EXPECT_EQ(A1, A1x);
	Object *A2y = DUT.allocate(Cap, Allocator);
	EXPECT_EQ(A2, A2y);

	// Back to allocation from the BumpPtrAllocator.
	Object *A4 = DUT.allocate(Cap, Allocator);
	EXPECT_NE(A1, A4);
	EXPECT_NE(A2, A4);
	EXPECT_NE(A3, A4);

	DUT.clear(Allocator);
	}

	} // end anonymous namespace