thanks to nvidia ❤

8ae5fc5 over 2 years ago

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	#include <unittest/unittest.h>
	#include <thrust/functional.h>
	#include <thrust/transform.h>

	#include <functional>
	#include <algorithm>

	THRUST_DISABLE_MSVC_POSSIBLE_LOSS_OF_DATA_WARNING_BEGIN

	const size_t NUM_SAMPLES = 10000;

	template <class InputVector, class OutputVector, class Operator, class ReferenceOperator>
	void TestUnaryFunctional(void)
	{
	typedef typename InputVector::value_type InputType;
	typedef typename OutputVector::value_type OutputType;

	thrust::host_vector<InputType> std_input = unittest::random_samples<InputType>(NUM_SAMPLES);
	thrust::host_vector<OutputType> std_output(NUM_SAMPLES);

	InputVector input = std_input;
	OutputVector output(NUM_SAMPLES);

	thrust::transform( input.begin(), input.end(), output.begin(), Operator());
	thrust::transform(std_input.begin(), std_input.end(), std_output.begin(), ReferenceOperator());

	ASSERT_EQUAL(output, std_output);
	}

	template <class InputVector, class OutputVector, class Operator, class ReferenceOperator>
	void TestBinaryFunctional(void)
	{
	typedef typename InputVector::value_type InputType;
	typedef typename OutputVector::value_type OutputType;

	thrust::host_vector<InputType> std_input1 = unittest::random_samples<InputType>(NUM_SAMPLES);
	thrust::host_vector<InputType> std_input2 = unittest::random_samples<InputType>(NUM_SAMPLES);
	thrust::host_vector<OutputType> std_output(NUM_SAMPLES);

	// Replace zeros to avoid divide by zero exceptions
	std::replace(std_input2.begin(), std_input2.end(), (InputType) 0, (InputType) 1);

	InputVector input1 = std_input1;
	InputVector input2 = std_input2;
	OutputVector output(NUM_SAMPLES);

	thrust::transform( input1.begin(), input1.end(), input2.begin(), output.begin(), Operator());
	thrust::transform(std_input1.begin(), std_input1.end(), std_input2.begin(), std_output.begin(), ReferenceOperator());

	// Note: FP division is not bit-equal, even when nvcc is invoked with --prec-div
	ASSERT_ALMOST_EQUAL(output, std_output);
	}



	// XXX add bool to list
	// Instantiate a macro for all integer-like data types
	#define INSTANTIATE_INTEGER_TYPES(Macro, vector_type, operator_name) \
	Macro(vector_type, operator_name, unittest::int8_t ) \
	Macro(vector_type, operator_name, unittest::uint8_t ) \
	Macro(vector_type, operator_name, unittest::int16_t ) \
	Macro(vector_type, operator_name, unittest::uint16_t) \
	Macro(vector_type, operator_name, unittest::int32_t ) \
	Macro(vector_type, operator_name, unittest::uint32_t) \
	Macro(vector_type, operator_name, unittest::int64_t ) \
	Macro(vector_type, operator_name, unittest::uint64_t)

	// Instantiate a macro for all integer and floating point data types
	#define INSTANTIATE_ALL_TYPES(Macro, vector_type, operator_name) \
	INSTANTIATE_INTEGER_TYPES(Macro, vector_type, operator_name) \
	Macro(vector_type, operator_name, float)


	// op(T) -> T
	#define INSTANTIATE_UNARY_ARITHMETIC_FUNCTIONAL_TEST(vector_type, operator_name, data_type) \
	TestUnaryFunctional< thrust::vector_type<data_type>, \
	thrust::vector_type<data_type>, \
	thrust::operator_name<data_type>, \
	std::operator_name<data_type> >();
	// XXX revert OutputVector<T> back to bool
	// op(T) -> bool
	#define INSTANTIATE_UNARY_LOGICAL_FUNCTIONAL_TEST(vector_type, operator_name, data_type) \
	TestUnaryFunctional< thrust::vector_type<data_type>, \
	thrust::vector_type<data_type>, \
	thrust::operator_name<data_type>, \
	std::operator_name<data_type> >();
	// op(T,T) -> T
	#define INSTANTIATE_BINARY_ARITHMETIC_FUNCTIONAL_TEST(vector_type, operator_name, data_type) \
	TestBinaryFunctional< thrust::vector_type<data_type>, \
	thrust::vector_type<data_type>, \
	thrust::operator_name<data_type>, \
	std::operator_name<data_type> >();
	// XXX revert OutputVector<T> back to bool
	// op(T,T) -> bool
	#define INSTANTIATE_BINARY_LOGICAL_FUNCTIONAL_TEST(vector_type, operator_name, data_type) \
	TestBinaryFunctional< thrust::vector_type<data_type>, \
	thrust::vector_type<data_type>, \
	thrust::operator_name<data_type>, \
	std::operator_name<data_type> >();




	// op(T) -> T
	#define DECLARE_UNARY_ARITHMETIC_FUNCTIONAL_UNITTEST(operator_name, OperatorName) \
	void Test##OperatorName##FunctionalHost(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_UNARY_ARITHMETIC_FUNCTIONAL_TEST, host_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalHost); \
	void Test##OperatorName##FunctionalDevice(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_UNARY_ARITHMETIC_FUNCTIONAL_TEST, device_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalDevice);

	// op(T) -> bool
	#define DECLARE_UNARY_LOGICAL_FUNCTIONAL_UNITTEST(operator_name, OperatorName) \
	void Test##OperatorName##FunctionalHost(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_UNARY_LOGICAL_FUNCTIONAL_TEST, host_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalHost); \
	void Test##OperatorName##FunctionalDevice(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_UNARY_LOGICAL_FUNCTIONAL_TEST, device_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalDevice);

	// op(T,T) -> T
	#define DECLARE_BINARY_ARITHMETIC_FUNCTIONAL_UNITTEST(operator_name, OperatorName) \
	void Test##OperatorName##FunctionalHost(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_BINARY_ARITHMETIC_FUNCTIONAL_TEST, host_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalHost); \
	void Test##OperatorName##FunctionalDevice(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_BINARY_ARITHMETIC_FUNCTIONAL_TEST, device_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalDevice);

	// op(T,T) -> T (for integer T only)
	#define DECLARE_BINARY_INTEGER_ARITHMETIC_FUNCTIONAL_UNITTEST(operator_name, OperatorName) \
	void Test##OperatorName##FunctionalHost(void) \
	{ \
	INSTANTIATE_INTEGER_TYPES( INSTANTIATE_BINARY_ARITHMETIC_FUNCTIONAL_TEST, host_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalHost); \
	void Test##OperatorName##FunctionalDevice(void) \
	{ \
	INSTANTIATE_INTEGER_TYPES( INSTANTIATE_BINARY_ARITHMETIC_FUNCTIONAL_TEST, device_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalDevice);

	// op(T,T) -> bool
	#define DECLARE_BINARY_LOGICAL_FUNCTIONAL_UNITTEST(operator_name, OperatorName) \
	void Test##OperatorName##FunctionalHost(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_BINARY_LOGICAL_FUNCTIONAL_TEST, host_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalHost); \
	void Test##OperatorName##FunctionalDevice(void) \
	{ \
	INSTANTIATE_ALL_TYPES( INSTANTIATE_BINARY_LOGICAL_FUNCTIONAL_TEST, device_vector, operator_name); \
	} \
	DECLARE_UNITTEST(Test##OperatorName##FunctionalDevice);




	// Create the unit tests
	DECLARE_UNARY_ARITHMETIC_FUNCTIONAL_UNITTEST(negate, Negate);
	DECLARE_UNARY_LOGICAL_FUNCTIONAL_UNITTEST(logical_not, LogicalNot);

	// Ad-hoc testing for other functionals
	template <class Vector>
	void TestIdentityFunctional(void)
	{
	typedef typename Vector::value_type T;

	Vector input(3);
	input[0] = 0; input[1] = 1; input[2] = 2;

	Vector output(3);

	thrust::transform(input.begin(), input.end(), output.begin(), thrust::identity<T>());

	ASSERT_EQUAL(input, output);
	}
	DECLARE_VECTOR_UNITTEST(TestIdentityFunctional);

	template <class Vector>
	void TestProject1stFunctional(void)
	{
	typedef typename Vector::value_type T;

	Vector lhs(3);
	Vector rhs(3);
	lhs[0] = 0; rhs[0] = 3;
	lhs[1] = 1; rhs[1] = 4;
	lhs[2] = 2; rhs[2] = 5;

	Vector output(3);

	thrust::transform(lhs.begin(), lhs.end(), rhs.begin(), output.begin(), thrust::project1st<T,T>());

	ASSERT_EQUAL(output, lhs);
	}
	DECLARE_VECTOR_UNITTEST(TestProject1stFunctional);

	template <class Vector>
	void TestProject2ndFunctional(void)
	{
	typedef typename Vector::value_type T;

	Vector lhs(3);
	Vector rhs(3);
	lhs[0] = 0; rhs[0] = 3;
	lhs[1] = 1; rhs[1] = 4;
	lhs[2] = 2; rhs[2] = 5;

	Vector output(3);

	thrust::transform(lhs.begin(), lhs.end(), rhs.begin(), output.begin(), thrust::project2nd<T,T>());

	ASSERT_EQUAL(output, rhs);
	}
	DECLARE_VECTOR_UNITTEST(TestProject2ndFunctional);

	template <class Vector>
	void TestMaximumFunctional(void)
	{
	typedef typename Vector::value_type T;

	Vector input1(3);
	Vector input2(3);
	input1[0] = 8; input1[1] = 3; input1[2] = 7;
	input2[0] = 5; input2[1] = 6; input2[2] = 9;

	Vector output(3);

	thrust::transform(input1.begin(), input1.end(),
	input2.begin(),
	output.begin(),
	thrust::maximum<T>());

	ASSERT_EQUAL(output[0], 8);
	ASSERT_EQUAL(output[1], 6);
	ASSERT_EQUAL(output[2], 9);
	}
	DECLARE_VECTOR_UNITTEST(TestMaximumFunctional);

	template <class Vector>
	void TestMinimumFunctional(void)
	{
	typedef typename Vector::value_type T;

	Vector input1(3);
	Vector input2(3);
	input1[0] = 8; input1[1] = 3; input1[2] = 7;
	input2[0] = 5; input2[1] = 6; input2[2] = 9;

	Vector output(3);

	thrust::transform(input1.begin(), input1.end(),
	input2.begin(),
	output.begin(),
	thrust::minimum<T>());

	ASSERT_EQUAL(output[0], 5);
	ASSERT_EQUAL(output[1], 3);
	ASSERT_EQUAL(output[2], 7);
	}
	DECLARE_VECTOR_UNITTEST(TestMinimumFunctional);

	template <class Vector>
	void TestNot1(void)
	{
	typedef typename Vector::value_type T;

	Vector input(5);
	input[0] = 1; input[1] = 0; input[2] = 1; input[3] = 1; input[4] = 0;

	Vector output(5);

	thrust::transform(input.begin(), input.end(),
	output.begin(),
	thrust::not1(thrust::identity<T>()));

	ASSERT_EQUAL(output[0], 0);
	ASSERT_EQUAL(output[1], 1);
	ASSERT_EQUAL(output[2], 0);
	ASSERT_EQUAL(output[3], 0);
	ASSERT_EQUAL(output[4], 1);
	}
	DECLARE_INTEGRAL_VECTOR_UNITTEST(TestNot1);


	// GCC 11 fails to build this test case with a spurious error in a
	// very specific scenario:
	// - GCC 11
	// - CPP system for both host and device
	// - C++11 dialect
	#if !(defined(THRUST_GCC_VERSION) && \
	THRUST_GCC_VERSION >= 110000 && \
	THRUST_GCC_VERSION < 120000 && \
	THRUST_HOST_SYSTEM == THRUST_HOST_SYSTEM_CPP && \
	THRUST_DEVICE_SYSTEM == THRUST_DEVICE_SYSTEM_CPP && \
	THRUST_CPP_DIALECT == 2011)

	template <class Vector>
	void TestNot2(void)
	{
	typedef typename Vector::value_type T;

	Vector input1(5);
	Vector input2(5);
	input1[0] = 1; input1[1] = 0; input1[2] = 1; input1[3] = 1; input1[4] = 0;
	input2[0] = 1; input2[1] = 1; input2[2] = 0; input2[3] = 1; input2[4] = 1;

	Vector output(5);

	thrust::transform(input1.begin(), input1.end(),
	input2.begin(),
	output.begin(),
	thrust::not2(thrust::equal_to<T>()));

	ASSERT_EQUAL(output[0], 0);
	ASSERT_EQUAL(output[1], 1);
	ASSERT_EQUAL(output[2], 1);
	ASSERT_EQUAL(output[3], 0);
	ASSERT_EQUAL(output[4], 1);
	}
	DECLARE_VECTOR_UNITTEST(TestNot2);

	#endif // Weird GCC11 failure case

	THRUST_DISABLE_MSVC_POSSIBLE_LOSS_OF_DATA_WARNING_END