test/operator_register_test.cpp - openbmc/openpower-libhei - Gitiles

 #include <hei_chip.hpp>
 #include <register/hei_operator_register.hpp>
 #include <util/hei_flyweight.hpp>

 #include "gtest/gtest.h"

 using namespace libhei;

 constexpr uint16_t CONST1 = 0x1458;
 constexpr uint16_t CONST2 = 0x5368;

 #define MATH(x) static_cast<uint16_t>(x)

 uint64_t __getVal(Register::ConstPtr i_reg)
 {
     Chip CHIP{nullptr, 0};
     auto bs = i_reg->getBitString(CHIP);
     return bs->getFieldRight(0, bs->getBitLen());
 }

 size_t __getBW(Register::ConstPtr i_reg)
 {
     Chip CHIP{nullptr, 0};
     return i_reg->getBitString(CHIP)->getBitLen();
 }

 TEST(OperatorRegisterTest, BasicOperations)
 {
     auto const1 = std::make_shared<const ConstantRegister>(CONST1);
     ASSERT_EQ(MATH(CONST1), __getVal(const1));

     auto const2 = std::make_shared<const ConstantRegister>(CONST2);
     ASSERT_EQ(MATH(CONST2), __getVal(const2));

     auto and1 = std::make_shared<const AndRegister>(const1, const2);
     ASSERT_EQ(MATH(CONST1 & CONST2), __getVal(and1));

     auto or1 = std::make_shared<const OrRegister>(const1, const2);
     ASSERT_EQ(MATH(CONST1 | CONST2), __getVal(or1));

     auto not1 = std::make_shared<const NotRegister>(const1);
     ASSERT_EQ(MATH(~CONST1), __getVal(not1));

     auto not2 = std::make_shared<const NotRegister>(const2);
     ASSERT_EQ(MATH(~CONST2), __getVal(not2));
 }

 TEST(OperatorRegisterTest, BasicOperationsWithFlyweights)
 {
     auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
     auto& and_factory   = Flyweight<const AndRegister>::getSingleton();
     auto& or_factory    = Flyweight<const OrRegister>::getSingleton();
     auto& not_factory   = Flyweight<const NotRegister>::getSingleton();

     auto const1 = const_factory.get(CONST1);
     auto const2 = const_factory.get(CONST2);

     ASSERT_EQ(MATH(CONST1), __getVal(const1));
     ASSERT_EQ(MATH(CONST2), __getVal(const2));
     ASSERT_EQ(MATH(CONST1 & CONST2), __getVal(and_factory.get(const1, const2)));
     ASSERT_EQ(MATH(CONST1 | CONST2), __getVal(or_factory.get(const1, const2)));
     ASSERT_EQ(MATH(~CONST1), __getVal(not_factory.get(const1)));
     ASSERT_EQ(MATH(~CONST2), __getVal(not_factory.get(const2)));

     const_factory.clear();
     and_factory.clear();
     or_factory.clear();
     not_factory.clear();
 }

 TEST(OperatorRegisterTest, ShiftOperations)
 {
     auto& const_factory  = Flyweight<const ConstantRegister>::getSingleton();
     auto& lshift_factory = Flyweight<const LeftShiftRegister>::getSingleton();
     auto& rshift_factory = Flyweight<const RightShiftRegister>::getSingleton();

     auto const1 = const_factory.get(CONST1);

     for (size_t i = 0; i < __getBW(const1); i++)
     {
         ASSERT_EQ(MATH(CONST1 << i), __getVal(lshift_factory.get(const1, i)));
     }

     for (size_t i = 0; i < __getBW(const1); i++)
     {
         ASSERT_EQ(MATH(CONST1 >> i), __getVal(rshift_factory.get(const1, i)));
     }

     const_factory.clear();
     lshift_factory.clear();
     rshift_factory.clear();
 }

 TEST(OperatorRegisterTest, ComplexOperation)
 {
     // Something seemingly complex:
     //   ~(((CONST1 & CONST2) << 12) | ((CONST1 | CONST2) >> 4)))

     auto& const_factory  = Flyweight<const ConstantRegister>::getSingleton();
     auto& and_factory    = Flyweight<const AndRegister>::getSingleton();
     auto& or_factory     = Flyweight<const OrRegister>::getSingleton();
     auto& not_factory    = Flyweight<const NotRegister>::getSingleton();
     auto& lshift_factory = Flyweight<const LeftShiftRegister>::getSingleton();
     auto& rshift_factory = Flyweight<const RightShiftRegister>::getSingleton();

     auto const1 = const_factory.get(CONST1);
     auto const2 = const_factory.get(CONST2);

     auto lshift = lshift_factory.get(and_factory.get(const1, const2), 12);
     auto rshift = rshift_factory.get(or_factory.get(const1, const2), 4);

     auto expr = not_factory.get(or_factory.get(lshift, rshift));

     ASSERT_EQ(MATH(~(((CONST1 & CONST2) << 12) | ((CONST1 | CONST2) >> 4))),
               __getVal(expr));

     const_factory.clear();
     and_factory.clear();
     or_factory.clear();
     not_factory.clear();
     lshift_factory.clear();
     rshift_factory.clear();
 }

 TEST(OperatorRegisterTest, ConstRegConstructor)
 {
     auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
     auto& and_factory   = Flyweight<const AndRegister>::getSingleton();

     // The ConstRegister constructor is a template that requires some integer
     // type.

     auto const1 = const_factory.get(CONST1); // CONST1 is uint16_t, GOOD

     auto const2 = const_factory.get(uint16_t{0x1458}); // This also works

     ASSERT_EQ(const1, const2); // Should point to the same thing.

     // If you pass in a constant with no type the compiler assumes it is the
     // implicit int type. This value is the same as const2, but the size will be
     // different.
     auto const3 = const_factory.get(0x1458);

     // The values are the same, but the bit strings are are different sizes.
     ASSERT_NE(const2, const3);

     // AND and OR operators will not like different sizes either.
     ASSERT_DEATH(and_factory.get(const2, const3), "");

     const_factory.clear();
     and_factory.clear();
 }
	#include <hei_chip.hpp>
	#include <register/hei_operator_register.hpp>
	#include <util/hei_flyweight.hpp>

	#include "gtest/gtest.h"

	using namespace libhei;

	constexpr uint16_t CONST1 = 0x1458;
	constexpr uint16_t CONST2 = 0x5368;

	#define MATH(x) static_cast<uint16_t>(x)

	uint64_t __getVal(Register::ConstPtr i_reg)
	{
	Chip CHIP{nullptr, 0};
	auto bs = i_reg->getBitString(CHIP);
	return bs->getFieldRight(0, bs->getBitLen());
	}

	size_t __getBW(Register::ConstPtr i_reg)
	{
	Chip CHIP{nullptr, 0};
	return i_reg->getBitString(CHIP)->getBitLen();
	}

	TEST(OperatorRegisterTest, BasicOperations)
	{
	auto const1 = std::make_shared<const ConstantRegister>(CONST1);
	ASSERT_EQ(MATH(CONST1), __getVal(const1));

	auto const2 = std::make_shared<const ConstantRegister>(CONST2);
	ASSERT_EQ(MATH(CONST2), __getVal(const2));

	auto and1 = std::make_shared<const AndRegister>(const1, const2);
	ASSERT_EQ(MATH(CONST1 & CONST2), __getVal(and1));

	auto or1 = std::make_shared<const OrRegister>(const1, const2);
	ASSERT_EQ(MATH(CONST1 \| CONST2), __getVal(or1));

	auto not1 = std::make_shared<const NotRegister>(const1);
	ASSERT_EQ(MATH(~CONST1), __getVal(not1));

	auto not2 = std::make_shared<const NotRegister>(const2);
	ASSERT_EQ(MATH(~CONST2), __getVal(not2));
	}

	TEST(OperatorRegisterTest, BasicOperationsWithFlyweights)
	{
	auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
	auto& and_factory = Flyweight<const AndRegister>::getSingleton();
	auto& or_factory = Flyweight<const OrRegister>::getSingleton();
	auto& not_factory = Flyweight<const NotRegister>::getSingleton();

	auto const1 = const_factory.get(CONST1);
	auto const2 = const_factory.get(CONST2);

	ASSERT_EQ(MATH(CONST1), __getVal(const1));
	ASSERT_EQ(MATH(CONST2), __getVal(const2));
	ASSERT_EQ(MATH(CONST1 & CONST2), __getVal(and_factory.get(const1, const2)));
	ASSERT_EQ(MATH(CONST1 \| CONST2), __getVal(or_factory.get(const1, const2)));
	ASSERT_EQ(MATH(~CONST1), __getVal(not_factory.get(const1)));
	ASSERT_EQ(MATH(~CONST2), __getVal(not_factory.get(const2)));

	const_factory.clear();
	and_factory.clear();
	or_factory.clear();
	not_factory.clear();
	}

	TEST(OperatorRegisterTest, ShiftOperations)
	{
	auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
	auto& lshift_factory = Flyweight<const LeftShiftRegister>::getSingleton();
	auto& rshift_factory = Flyweight<const RightShiftRegister>::getSingleton();

	auto const1 = const_factory.get(CONST1);

	for (size_t i = 0; i < __getBW(const1); i++)
	{
	ASSERT_EQ(MATH(CONST1 << i), __getVal(lshift_factory.get(const1, i)));
	}

	for (size_t i = 0; i < __getBW(const1); i++)
	{
	ASSERT_EQ(MATH(CONST1 >> i), __getVal(rshift_factory.get(const1, i)));
	}

	const_factory.clear();
	lshift_factory.clear();
	rshift_factory.clear();
	}

	TEST(OperatorRegisterTest, ComplexOperation)
	{
	// Something seemingly complex:
	// ~(((CONST1 & CONST2) << 12) \| ((CONST1 \| CONST2) >> 4)))

	auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
	auto& and_factory = Flyweight<const AndRegister>::getSingleton();
	auto& or_factory = Flyweight<const OrRegister>::getSingleton();
	auto& not_factory = Flyweight<const NotRegister>::getSingleton();
	auto& lshift_factory = Flyweight<const LeftShiftRegister>::getSingleton();
	auto& rshift_factory = Flyweight<const RightShiftRegister>::getSingleton();

	auto const1 = const_factory.get(CONST1);
	auto const2 = const_factory.get(CONST2);

	auto lshift = lshift_factory.get(and_factory.get(const1, const2), 12);
	auto rshift = rshift_factory.get(or_factory.get(const1, const2), 4);

	auto expr = not_factory.get(or_factory.get(lshift, rshift));

	ASSERT_EQ(MATH(~(((CONST1 & CONST2) << 12) \| ((CONST1 \| CONST2) >> 4))),
	__getVal(expr));

	const_factory.clear();
	and_factory.clear();
	or_factory.clear();
	not_factory.clear();
	lshift_factory.clear();
	rshift_factory.clear();
	}

	TEST(OperatorRegisterTest, ConstRegConstructor)
	{
	auto& const_factory = Flyweight<const ConstantRegister>::getSingleton();
	auto& and_factory = Flyweight<const AndRegister>::getSingleton();

	// The ConstRegister constructor is a template that requires some integer
	// type.

	auto const1 = const_factory.get(CONST1); // CONST1 is uint16_t, GOOD

	auto const2 = const_factory.get(uint16_t{0x1458}); // This also works

	ASSERT_EQ(const1, const2); // Should point to the same thing.

	// If you pass in a constant with no type the compiler assumes it is the
	// implicit int type. This value is the same as const2, but the size will be
	// different.
	auto const3 = const_factory.get(0x1458);

	// The values are the same, but the bit strings are are different sizes.
	ASSERT_NE(const2, const3);

	// AND and OR operators will not like different sizes either.
	ASSERT_DEATH(and_factory.get(const2, const3), "");

	const_factory.clear();
	and_factory.clear();
	}