src/v8/test/unittests/register-configuration-unittest.cc - cobalt - Git at Google

 // Copyright 2016 the V8 project 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 "src/register-configuration.h"
 #include "testing/gtest-support.h"

 namespace v8 {
 namespace internal {

 const MachineRepresentation kFloat32 = MachineRepresentation::kFloat32;
 const MachineRepresentation kFloat64 = MachineRepresentation::kFloat64;
 const MachineRepresentation kSimd128 = MachineRepresentation::kSimd128;

 class RegisterConfigurationUnitTest : public ::testing::Test {
  public:
   RegisterConfigurationUnitTest() {}
   virtual ~RegisterConfigurationUnitTest() {}
 };

 TEST_F(RegisterConfigurationUnitTest, BasicProperties) {
   const int kNumGeneralRegs = 3;
   const int kNumDoubleRegs = 4;
   const int kNumAllocatableGeneralRegs = 2;
   const int kNumAllocatableDoubleRegs = 2;
   int general_codes[kNumAllocatableGeneralRegs] = {1, 2};
   int double_codes[kNumAllocatableDoubleRegs] = {2, 3};

   RegisterConfiguration test(
       kNumGeneralRegs, kNumDoubleRegs, kNumAllocatableGeneralRegs,
       kNumAllocatableDoubleRegs, general_codes, double_codes,
       RegisterConfiguration::OVERLAP, nullptr, nullptr, nullptr, nullptr);

   EXPECT_EQ(test.num_general_registers(), kNumGeneralRegs);
   EXPECT_EQ(test.num_double_registers(), kNumDoubleRegs);
   EXPECT_EQ(test.num_allocatable_general_registers(),
             kNumAllocatableGeneralRegs);
   EXPECT_EQ(test.num_allocatable_double_registers(), kNumAllocatableDoubleRegs);
   EXPECT_EQ(test.num_allocatable_float_registers(), kNumAllocatableDoubleRegs);
   EXPECT_EQ(test.num_allocatable_simd128_registers(),
             kNumAllocatableDoubleRegs);

   EXPECT_EQ(test.allocatable_general_codes_mask(),
             (1 << general_codes[0]) | (1 << general_codes[1]));
   EXPECT_EQ(test.GetAllocatableGeneralCode(0), general_codes[0]);
   EXPECT_EQ(test.GetAllocatableGeneralCode(1), general_codes[1]);
   EXPECT_EQ(test.allocatable_double_codes_mask(),
             (1 << double_codes[0]) | (1 << double_codes[1]));
   EXPECT_EQ(test.GetAllocatableFloatCode(0), double_codes[0]);
   EXPECT_EQ(test.GetAllocatableDoubleCode(0), double_codes[0]);
   EXPECT_EQ(test.GetAllocatableSimd128Code(0), double_codes[0]);
   EXPECT_EQ(test.GetAllocatableFloatCode(1), double_codes[1]);
   EXPECT_EQ(test.GetAllocatableDoubleCode(1), double_codes[1]);
   EXPECT_EQ(test.GetAllocatableSimd128Code(1), double_codes[1]);
 }

 TEST_F(RegisterConfigurationUnitTest, CombineAliasing) {
   const int kNumGeneralRegs = 3;
   const int kNumDoubleRegs = 4;
   const int kNumAllocatableGeneralRegs = 2;
   const int kNumAllocatableDoubleRegs = 3;
   int general_codes[] = {1, 2};
   int double_codes[] = {2, 3, 16};  // reg 16 should not alias registers 32, 33.

   RegisterConfiguration test(
       kNumGeneralRegs, kNumDoubleRegs, kNumAllocatableGeneralRegs,
       kNumAllocatableDoubleRegs, general_codes, double_codes,
       RegisterConfiguration::COMBINE, nullptr, nullptr, nullptr, nullptr);

   // There are 3 allocatable double regs, but only 2 can alias float regs.
   EXPECT_EQ(test.num_allocatable_float_registers(), 4);

   // Test that float registers combine in pairs to form double registers.
   EXPECT_EQ(test.GetAllocatableFloatCode(0), double_codes[0] * 2);
   EXPECT_EQ(test.GetAllocatableFloatCode(1), double_codes[0] * 2 + 1);
   EXPECT_EQ(test.GetAllocatableFloatCode(2), double_codes[1] * 2);
   EXPECT_EQ(test.GetAllocatableFloatCode(3), double_codes[1] * 2 + 1);

   // There are 3 allocatable double regs, but only 2 pair to form 1 SIMD reg.
   EXPECT_EQ(test.num_allocatable_simd128_registers(), 1);

   // Test that even-odd pairs of double regs combine to form a SIMD reg.
   EXPECT_EQ(test.GetAllocatableSimd128Code(0), double_codes[0] / 2);

   // Registers alias themselves.
   EXPECT_TRUE(test.AreAliases(kFloat32, 0, kFloat32, 0));
   EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat64, 0));
   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kSimd128, 0));
   // Registers don't alias other registers of the same size.
   EXPECT_FALSE(test.AreAliases(kFloat32, 1, kFloat32, 0));
   EXPECT_FALSE(test.AreAliases(kFloat64, 1, kFloat64, 0));
   EXPECT_FALSE(test.AreAliases(kSimd128, 1, kSimd128, 0));
   // Float registers combine in pairs to alias a double with index / 2, and
   // in 4's to alias a simd128 with index / 4.
   EXPECT_TRUE(test.AreAliases(kFloat32, 0, kFloat64, 0));
   EXPECT_TRUE(test.AreAliases(kFloat32, 1, kFloat64, 0));
   EXPECT_TRUE(test.AreAliases(kFloat32, 0, kSimd128, 0));
   EXPECT_TRUE(test.AreAliases(kFloat32, 1, kSimd128, 0));
   EXPECT_TRUE(test.AreAliases(kFloat32, 2, kSimd128, 0));
   EXPECT_TRUE(test.AreAliases(kFloat32, 3, kSimd128, 0));
   EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 0));
   EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 1));
   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 0));
   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 1));
   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 2));
   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 3));

   EXPECT_FALSE(test.AreAliases(kFloat32, 0, kFloat64, 1));
   EXPECT_FALSE(test.AreAliases(kFloat32, 1, kFloat64, 1));
   EXPECT_FALSE(test.AreAliases(kFloat32, 0, kSimd128, 1));
   EXPECT_FALSE(test.AreAliases(kFloat32, 1, kSimd128, 1));
   EXPECT_FALSE(test.AreAliases(kFloat64, 0, kSimd128, 1));
   EXPECT_FALSE(test.AreAliases(kFloat64, 1, kSimd128, 1));

   EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 1));
   EXPECT_TRUE(test.AreAliases(kFloat64, 1, kFloat32, 2));
   EXPECT_TRUE(test.AreAliases(kFloat64, 1, kFloat32, 3));
   EXPECT_TRUE(test.AreAliases(kFloat64, 2, kFloat32, 4));
   EXPECT_TRUE(test.AreAliases(kFloat64, 2, kFloat32, 5));

   EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat64, 1));
   EXPECT_TRUE(test.AreAliases(kSimd128, 1, kFloat64, 2));
   EXPECT_TRUE(test.AreAliases(kSimd128, 1, kFloat64, 3));
   EXPECT_TRUE(test.AreAliases(kSimd128, 2, kFloat64, 4));
   EXPECT_TRUE(test.AreAliases(kSimd128, 2, kFloat64, 5));

   int alias_base_index = -1;
   EXPECT_EQ(test.GetAliases(kFloat32, 0, kFloat32, &alias_base_index), 1);
   EXPECT_EQ(alias_base_index, 0);
   EXPECT_EQ(test.GetAliases(kFloat64, 1, kFloat64, &alias_base_index), 1);
   EXPECT_EQ(alias_base_index, 1);
   EXPECT_EQ(test.GetAliases(kFloat32, 0, kFloat64, &alias_base_index), 1);
   EXPECT_EQ(alias_base_index, 0);
   EXPECT_EQ(test.GetAliases(kFloat32, 1, kFloat64, &alias_base_index), 1);
   EXPECT_EQ(test.GetAliases(kFloat32, 2, kFloat64, &alias_base_index), 1);
   EXPECT_EQ(alias_base_index, 1);
   EXPECT_EQ(test.GetAliases(kFloat32, 3, kFloat64, &alias_base_index), 1);
   EXPECT_EQ(alias_base_index, 1);
   EXPECT_EQ(test.GetAliases(kFloat64, 0, kFloat32, &alias_base_index), 2);
   EXPECT_EQ(alias_base_index, 0);
   EXPECT_EQ(test.GetAliases(kFloat64, 1, kFloat32, &alias_base_index), 2);
   EXPECT_EQ(alias_base_index, 2);

   // Non-allocatable codes still alias.
   EXPECT_EQ(test.GetAliases(kFloat64, 2, kFloat32, &alias_base_index), 2);
   EXPECT_EQ(alias_base_index, 4);
   // High numbered double and simd regs don't alias nonexistent float registers.
   EXPECT_EQ(
       test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters / 2,
                       kFloat32, &alias_base_index),
       0);
   EXPECT_EQ(
       test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters / 2 + 1,
                       kFloat32, &alias_base_index),
       0);
   EXPECT_EQ(
       test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters - 1,
                       kFloat32, &alias_base_index),
       0);
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2016 the V8 project 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 "src/register-configuration.h"
	#include "testing/gtest-support.h"

	namespace v8 {
	namespace internal {

	const MachineRepresentation kFloat32 = MachineRepresentation::kFloat32;
	const MachineRepresentation kFloat64 = MachineRepresentation::kFloat64;
	const MachineRepresentation kSimd128 = MachineRepresentation::kSimd128;

	class RegisterConfigurationUnitTest : public ::testing::Test {
	public:
	RegisterConfigurationUnitTest() {}
	virtual ~RegisterConfigurationUnitTest() {}
	};

	TEST_F(RegisterConfigurationUnitTest, BasicProperties) {
	const int kNumGeneralRegs = 3;
	const int kNumDoubleRegs = 4;
	const int kNumAllocatableGeneralRegs = 2;
	const int kNumAllocatableDoubleRegs = 2;
	int general_codes[kNumAllocatableGeneralRegs] = {1, 2};
	int double_codes[kNumAllocatableDoubleRegs] = {2, 3};

	RegisterConfiguration test(
	kNumGeneralRegs, kNumDoubleRegs, kNumAllocatableGeneralRegs,
	kNumAllocatableDoubleRegs, general_codes, double_codes,
	RegisterConfiguration::OVERLAP, nullptr, nullptr, nullptr, nullptr);

	EXPECT_EQ(test.num_general_registers(), kNumGeneralRegs);
	EXPECT_EQ(test.num_double_registers(), kNumDoubleRegs);
	EXPECT_EQ(test.num_allocatable_general_registers(),
	kNumAllocatableGeneralRegs);
	EXPECT_EQ(test.num_allocatable_double_registers(), kNumAllocatableDoubleRegs);
	EXPECT_EQ(test.num_allocatable_float_registers(), kNumAllocatableDoubleRegs);
	EXPECT_EQ(test.num_allocatable_simd128_registers(),
	kNumAllocatableDoubleRegs);

	EXPECT_EQ(test.allocatable_general_codes_mask(),
	(1 << general_codes[0]) \| (1 << general_codes[1]));
	EXPECT_EQ(test.GetAllocatableGeneralCode(0), general_codes[0]);
	EXPECT_EQ(test.GetAllocatableGeneralCode(1), general_codes[1]);
	EXPECT_EQ(test.allocatable_double_codes_mask(),
	(1 << double_codes[0]) \| (1 << double_codes[1]));
	EXPECT_EQ(test.GetAllocatableFloatCode(0), double_codes[0]);
	EXPECT_EQ(test.GetAllocatableDoubleCode(0), double_codes[0]);
	EXPECT_EQ(test.GetAllocatableSimd128Code(0), double_codes[0]);
	EXPECT_EQ(test.GetAllocatableFloatCode(1), double_codes[1]);
	EXPECT_EQ(test.GetAllocatableDoubleCode(1), double_codes[1]);
	EXPECT_EQ(test.GetAllocatableSimd128Code(1), double_codes[1]);
	}

	TEST_F(RegisterConfigurationUnitTest, CombineAliasing) {
	const int kNumGeneralRegs = 3;
	const int kNumDoubleRegs = 4;
	const int kNumAllocatableGeneralRegs = 2;
	const int kNumAllocatableDoubleRegs = 3;
	int general_codes[] = {1, 2};
	int double_codes[] = {2, 3, 16}; // reg 16 should not alias registers 32, 33.

	RegisterConfiguration test(
	kNumGeneralRegs, kNumDoubleRegs, kNumAllocatableGeneralRegs,
	kNumAllocatableDoubleRegs, general_codes, double_codes,
	RegisterConfiguration::COMBINE, nullptr, nullptr, nullptr, nullptr);

	// There are 3 allocatable double regs, but only 2 can alias float regs.
	EXPECT_EQ(test.num_allocatable_float_registers(), 4);

	// Test that float registers combine in pairs to form double registers.
	EXPECT_EQ(test.GetAllocatableFloatCode(0), double_codes[0] * 2);
	EXPECT_EQ(test.GetAllocatableFloatCode(1), double_codes[0] * 2 + 1);
	EXPECT_EQ(test.GetAllocatableFloatCode(2), double_codes[1] * 2);
	EXPECT_EQ(test.GetAllocatableFloatCode(3), double_codes[1] * 2 + 1);

	// There are 3 allocatable double regs, but only 2 pair to form 1 SIMD reg.
	EXPECT_EQ(test.num_allocatable_simd128_registers(), 1);

	// Test that even-odd pairs of double regs combine to form a SIMD reg.
	EXPECT_EQ(test.GetAllocatableSimd128Code(0), double_codes[0] / 2);

	// Registers alias themselves.
	EXPECT_TRUE(test.AreAliases(kFloat32, 0, kFloat32, 0));
	EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat64, 0));
	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kSimd128, 0));
	// Registers don't alias other registers of the same size.
	EXPECT_FALSE(test.AreAliases(kFloat32, 1, kFloat32, 0));
	EXPECT_FALSE(test.AreAliases(kFloat64, 1, kFloat64, 0));
	EXPECT_FALSE(test.AreAliases(kSimd128, 1, kSimd128, 0));
	// Float registers combine in pairs to alias a double with index / 2, and
	// in 4's to alias a simd128 with index / 4.
	EXPECT_TRUE(test.AreAliases(kFloat32, 0, kFloat64, 0));
	EXPECT_TRUE(test.AreAliases(kFloat32, 1, kFloat64, 0));
	EXPECT_TRUE(test.AreAliases(kFloat32, 0, kSimd128, 0));
	EXPECT_TRUE(test.AreAliases(kFloat32, 1, kSimd128, 0));
	EXPECT_TRUE(test.AreAliases(kFloat32, 2, kSimd128, 0));
	EXPECT_TRUE(test.AreAliases(kFloat32, 3, kSimd128, 0));
	EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 0));
	EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 1));
	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 0));
	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 1));
	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 2));
	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat32, 3));

	EXPECT_FALSE(test.AreAliases(kFloat32, 0, kFloat64, 1));
	EXPECT_FALSE(test.AreAliases(kFloat32, 1, kFloat64, 1));
	EXPECT_FALSE(test.AreAliases(kFloat32, 0, kSimd128, 1));
	EXPECT_FALSE(test.AreAliases(kFloat32, 1, kSimd128, 1));
	EXPECT_FALSE(test.AreAliases(kFloat64, 0, kSimd128, 1));
	EXPECT_FALSE(test.AreAliases(kFloat64, 1, kSimd128, 1));

	EXPECT_TRUE(test.AreAliases(kFloat64, 0, kFloat32, 1));
	EXPECT_TRUE(test.AreAliases(kFloat64, 1, kFloat32, 2));
	EXPECT_TRUE(test.AreAliases(kFloat64, 1, kFloat32, 3));
	EXPECT_TRUE(test.AreAliases(kFloat64, 2, kFloat32, 4));
	EXPECT_TRUE(test.AreAliases(kFloat64, 2, kFloat32, 5));

	EXPECT_TRUE(test.AreAliases(kSimd128, 0, kFloat64, 1));
	EXPECT_TRUE(test.AreAliases(kSimd128, 1, kFloat64, 2));
	EXPECT_TRUE(test.AreAliases(kSimd128, 1, kFloat64, 3));
	EXPECT_TRUE(test.AreAliases(kSimd128, 2, kFloat64, 4));
	EXPECT_TRUE(test.AreAliases(kSimd128, 2, kFloat64, 5));

	int alias_base_index = -1;
	EXPECT_EQ(test.GetAliases(kFloat32, 0, kFloat32, &alias_base_index), 1);
	EXPECT_EQ(alias_base_index, 0);
	EXPECT_EQ(test.GetAliases(kFloat64, 1, kFloat64, &alias_base_index), 1);
	EXPECT_EQ(alias_base_index, 1);
	EXPECT_EQ(test.GetAliases(kFloat32, 0, kFloat64, &alias_base_index), 1);
	EXPECT_EQ(alias_base_index, 0);
	EXPECT_EQ(test.GetAliases(kFloat32, 1, kFloat64, &alias_base_index), 1);
	EXPECT_EQ(test.GetAliases(kFloat32, 2, kFloat64, &alias_base_index), 1);
	EXPECT_EQ(alias_base_index, 1);
	EXPECT_EQ(test.GetAliases(kFloat32, 3, kFloat64, &alias_base_index), 1);
	EXPECT_EQ(alias_base_index, 1);
	EXPECT_EQ(test.GetAliases(kFloat64, 0, kFloat32, &alias_base_index), 2);
	EXPECT_EQ(alias_base_index, 0);
	EXPECT_EQ(test.GetAliases(kFloat64, 1, kFloat32, &alias_base_index), 2);
	EXPECT_EQ(alias_base_index, 2);

	// Non-allocatable codes still alias.
	EXPECT_EQ(test.GetAliases(kFloat64, 2, kFloat32, &alias_base_index), 2);
	EXPECT_EQ(alias_base_index, 4);
	// High numbered double and simd regs don't alias nonexistent float registers.
	EXPECT_EQ(
	test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters / 2,
	kFloat32, &alias_base_index),
	0);
	EXPECT_EQ(
	test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters / 2 + 1,
	kFloat32, &alias_base_index),
	0);
	EXPECT_EQ(
	test.GetAliases(kFloat64, RegisterConfiguration::kMaxFPRegisters - 1,
	kFloat32, &alias_base_index),
	0);
	}

	} // namespace internal
	} // namespace v8