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Unverified Commit dda18da0 authored by Illia Silin's avatar Illia Silin Committed by GitHub
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Merge branch 'develop' into ck_migraphx_integration

parents 3b2a7aee 4cf70b36
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Showing with 893 additions and 20 deletions
profiler/src/CMakeLists.txt
View file @ dda18da0
...@@ -24,7 +24,7 @@ set(PROFILER_SOURCES ...@@ -24,7 +24,7 @@ set(PROFILER_SOURCES
profile_permute_scale.cpp profile_permute_scale.cpp
) )
if(GPU_TARGETS MATCHES "gfx9") if(SUPPORTED_GPU_TARGETS MATCHES "gfx9")
if(DTYPES MATCHES "fp32" OR DTYPES MATCHES "fp64" OR NOT DEFINED DTYPES) if(DTYPES MATCHES "fp32" OR DTYPES MATCHES "fp64" OR NOT DEFINED DTYPES)
list(APPEND PROFILER_SOURCES profile_contraction_bilinear.cpp) list(APPEND PROFILER_SOURCES profile_contraction_bilinear.cpp)
list(APPEND PROFILER_SOURCES profile_contraction_scale.cpp) list(APPEND PROFILER_SOURCES profile_contraction_scale.cpp)
...@@ -49,7 +49,7 @@ if(GPU_TARGETS MATCHES "gfx9") ...@@ -49,7 +49,7 @@ if(GPU_TARGETS MATCHES "gfx9")
list(APPEND PROFILER_SOURCES profile_grouped_gemm_multiply_tile_loop.cpp) list(APPEND PROFILER_SOURCES profile_grouped_gemm_multiply_tile_loop.cpp)
endif() endif()
list(APPEND PROFILER_SOURCES profile_gemm_multiply_add.cpp) list(APPEND PROFILER_SOURCES profile_gemm_multiply_add.cpp)
if(GPU_TARGETS MATCHES "gfx94") if(SUPPORTED_GPU_TARGETS MATCHES "gfx94")
list(APPEND PROFILER_SOURCES profile_gemm_multiply_multiply.cpp) list(APPEND PROFILER_SOURCES profile_gemm_multiply_multiply.cpp)
list(APPEND PROFILER_SOURCES profile_gemm_ab_scale.cpp) list(APPEND PROFILER_SOURCES profile_gemm_ab_scale.cpp)
endif() endif()
...@@ -69,7 +69,7 @@ if(GPU_TARGETS MATCHES "gfx9") ...@@ -69,7 +69,7 @@ if(GPU_TARGETS MATCHES "gfx9")
endif() endif()
if(GPU_TARGETS MATCHES "gfx11" OR GPU_TARGETS MATCHES "gfx12" OR GPU_TARGETS MATCHES "gfx9") if(SUPPORTED_GPU_TARGETS MATCHES "gfx11" OR SUPPORTED_GPU_TARGETS MATCHES "gfx12" OR SUPPORTED_GPU_TARGETS MATCHES "gfx9")
if(DTYPES MATCHES "fp16" OR NOT DEFINED DTYPES) if(DTYPES MATCHES "fp16" OR NOT DEFINED DTYPES)
list(APPEND PROFILER_SOURCES profile_gemm_bilinear.cpp) list(APPEND PROFILER_SOURCES profile_gemm_bilinear.cpp)
endif() endif()
...@@ -111,7 +111,7 @@ target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_column_to_image_inst ...@@ -111,7 +111,7 @@ target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_column_to_image_inst
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_transpose_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_transpose_instance)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_permute_scale_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_permute_scale_instance)
if(GPU_TARGETS MATCHES "gfx9") if(SUPPORTED_GPU_TARGETS MATCHES "gfx9")
if(DTYPES MATCHES "fp32" OR DTYPES MATCHES "fp64" OR NOT DEFINED DTYPES) if(DTYPES MATCHES "fp32" OR DTYPES MATCHES "fp64" OR NOT DEFINED DTYPES)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_contraction_bilinear_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_contraction_bilinear_instance)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_contraction_scale_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_contraction_scale_instance)
...@@ -135,7 +135,7 @@ if(GPU_TARGETS MATCHES "gfx9") ...@@ -135,7 +135,7 @@ if(GPU_TARGETS MATCHES "gfx9")
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_batched_gemm_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_batched_gemm_instance)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_batched_gemm_reduce_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_batched_gemm_reduce_instance)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_multiply_add_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_multiply_add_instance)
if(GPU_TARGETS MATCHES "gfx94") if(SUPPORTED_GPU_TARGETS MATCHES "gfx94")
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_multiply_multiply_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_multiply_multiply_instance)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_ab_scale_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_ab_scale_instance)
endif() endif()
...@@ -159,7 +159,7 @@ if(GPU_TARGETS MATCHES "gfx9") ...@@ -159,7 +159,7 @@ if(GPU_TARGETS MATCHES "gfx9")
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_grouped_conv3d_fwd_convinvscale_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_grouped_conv3d_fwd_convinvscale_instance)
endif() endif()
if(GPU_TARGETS MATCHES "gfx9" OR GPU_TARGETS MATCHES "gfx11" OR GPU_TARGETS MATCHES "gfx12") if(SUPPORTED_GPU_TARGETS MATCHES "gfx9" OR SUPPORTED_GPU_TARGETS MATCHES "gfx11" OR SUPPORTED_GPU_TARGETS MATCHES "gfx12")
if(DTYPES MATCHES "fp16" OR NOT DEFINED DTYPES) if(DTYPES MATCHES "fp16" OR NOT DEFINED DTYPES)
target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_bilinear_instance) target_link_libraries(${PROFILER_EXECUTABLE} PRIVATE device_gemm_bilinear_instance)
endif() endif()
......
script/cmake-ck-dev.sh
View file @ dda18da0
...@@ -7,7 +7,8 @@ MY_PROJECT_SOURCE=$1 ...@@ -7,7 +7,8 @@ MY_PROJECT_SOURCE=$1
if [ $# -ge 2 ] ; then if [ $# -ge 2 ] ; then
GPU_TARGETS=$2 GPU_TARGETS=$2
REST_ARGS=${@:3} shift 2
REST_ARGS=$@
else else
GPU_TARGETS="gfx908;gfx90a;gfx940" GPU_TARGETS="gfx908;gfx90a;gfx940"
REST_ARGS= REST_ARGS=
......
script/cmake-ck-release.sh
View file @ dda18da0
...@@ -7,7 +7,8 @@ MY_PROJECT_SOURCE=$1 ...@@ -7,7 +7,8 @@ MY_PROJECT_SOURCE=$1
if [ $# -ge 2 ] ; then if [ $# -ge 2 ] ; then
GPU_TARGETS=$2 GPU_TARGETS=$2
REST_ARGS=${@:3} shift 2
REST_ARGS=$@
else else
GPU_TARGETS="gfx908;gfx90a;gfx940" GPU_TARGETS="gfx908;gfx90a;gfx940"
REST_ARGS= REST_ARGS=
......
test/CMakeLists.txt
View file @ dda18da0
...@@ -41,11 +41,7 @@ function(add_test_executable TEST_NAME) ...@@ -41,11 +41,7 @@ function(add_test_executable TEST_NAME)
endforeach() endforeach()
endif() endif()
if(INSTANCES_ONLY) set(TEST_TARGETS ${SUPPORTED_GPU_TARGETS})
set(TEST_TARGETS ${DEFAULT_GPU_TARGETS})
else()
set(TEST_TARGETS ${GPU_TARGETS})
endif()
foreach(source IN LISTS ARGN) foreach(source IN LISTS ARGN)
if(NOT DEFINED DL_KERNELS AND source MATCHES "_dl") if(NOT DEFINED DL_KERNELS AND source MATCHES "_dl")
...@@ -122,11 +118,7 @@ function(add_gtest_executable TEST_NAME) ...@@ -122,11 +118,7 @@ function(add_gtest_executable TEST_NAME)
endforeach() endforeach()
endif() endif()
if(INSTANCES_ONLY) set(TEST_TARGETS ${SUPPORTED_GPU_TARGETS})
set(TEST_TARGETS ${DEFAULT_GPU_TARGETS})
else()
set(TEST_TARGETS ${GPU_TARGETS})
endif()
foreach(source IN LISTS ARGN) foreach(source IN LISTS ARGN)
if(NOT DEFINED DL_KERNELS AND source MATCHES "_dl") if(NOT DEFINED DL_KERNELS AND source MATCHES "_dl")
...@@ -211,10 +203,10 @@ add_subdirectory(conv_tensor_rearrange) ...@@ -211,10 +203,10 @@ add_subdirectory(conv_tensor_rearrange)
add_subdirectory(transpose) add_subdirectory(transpose)
add_subdirectory(permute_scale) add_subdirectory(permute_scale)
add_subdirectory(wrapper) add_subdirectory(wrapper)
if(GPU_TARGETS MATCHES "gfx11") if(SUPPORTED_GPU_TARGETS MATCHES "gfx11")
add_subdirectory(wmma_op) add_subdirectory(wmma_op)
endif() endif()
if(GPU_TARGETS MATCHES "gfx942" AND CK_HIP_VERSION_MAJOR GREATER_EQUAL 6 AND CK_HIP_VERSION_MINOR GREATER_EQUAL 2) # smfmac needs ROCm6.2 if(SUPPORTED_GPU_TARGETS MATCHES "gfx942" AND CK_HIP_VERSION_MAJOR GREATER_EQUAL 6 AND CK_HIP_VERSION_MINOR GREATER_EQUAL 2) # smfmac needs ROCm6.2
add_subdirectory(smfmac_op) add_subdirectory(smfmac_op)
endif() endif()
add_subdirectory(position_embedding) add_subdirectory(position_embedding)
test/data_type/CMakeLists.txt
View file @ dda18da0
...@@ -18,4 +18,9 @@ if(result EQUAL 0) ...@@ -18,4 +18,9 @@ if(result EQUAL 0)
target_link_libraries(test_bf8 PRIVATE utility) target_link_libraries(test_bf8 PRIVATE utility)
endif() endif()
add_gtest_executable(test_custom_type test_custom_type.cpp)
if(result EQUAL 0)
target_link_libraries(test_custom_type PRIVATE utility)
endif()
add_gtest_executable(test_type_convert_const type_convert_const.cpp) add_gtest_executable(test_type_convert_const type_convert_const.cpp)
test/data_type/test_custom_type.cpp 0 → 100644
View file @ dda18da0
// SPDX-License-Identifier: MIT
// Copyright (c) 2024, Advanced Micro Devices, Inc. All rights reserved.
#include "gtest/gtest.h"
#include "ck/utility/data_type.hpp"
#include "ck/utility/type_convert.hpp"
using ck::bf8_t;
using ck::bhalf_t;
using ck::f8_t;
using ck::half_t;
using ck::Number;
using ck::type_convert;
using ck::vector_type;
TEST(Custom_bool, TestSize)
{
struct custom_bool_t
{
bool data;
};
ASSERT_EQ(sizeof(custom_bool_t), sizeof(bool));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 2>), sizeof(vector_type<bool, 2>));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 4>), sizeof(vector_type<bool, 4>));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 8>), sizeof(vector_type<bool, 8>));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 16>), sizeof(vector_type<bool, 16>));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 32>), sizeof(vector_type<bool, 32>));
ASSERT_EQ(sizeof(vector_type<custom_bool_t, 64>), sizeof(vector_type<bool, 64>));
}
TEST(Custom_bool, TestAsType)
{
struct custom_bool_t
{
using type = bool;
type data;
custom_bool_t() : data{type{}} {}
custom_bool_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<bool> test_vec = {false, true, false, true};
// reference vector
vector_type<custom_bool_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_bool_t>()(Number<i>{}).data, false);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bool_t>()(Number<i>{}) = custom_bool_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_bool_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bool_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_bool, TestAsTypeReshape)
{
struct custom_bool_t
{
using type = bool;
type data;
custom_bool_t() : data{type{}} {}
custom_bool_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<bool> test_vec = {false, true, false, true};
// reference vector
vector_type<custom_bool_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_bool_t>()(Number<i>{}).data, false);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bool_t>()(Number<i>{}) = custom_bool_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_bool_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_bool_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bool_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_int8, TestSize)
{
struct custom_int8_t
{
int8_t data;
};
ASSERT_EQ(sizeof(custom_int8_t), sizeof(int8_t));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 2>), sizeof(vector_type<int8_t, 2>));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 4>), sizeof(vector_type<int8_t, 4>));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 8>), sizeof(vector_type<int8_t, 8>));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 16>), sizeof(vector_type<int8_t, 16>));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 32>), sizeof(vector_type<int8_t, 32>));
ASSERT_EQ(sizeof(vector_type<custom_int8_t, 64>), sizeof(vector_type<int8_t, 64>));
}
TEST(Custom_int8, TestAsType)
{
struct custom_int8_t
{
using type = int8_t;
type data;
custom_int8_t() : data{type{}} {}
custom_int8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<int8_t> test_vec = {3, -6, 8, -2};
// reference vector
vector_type<custom_int8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_int8_t>()(Number<i>{}).data, 0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_int8_t>()(Number<i>{}) = custom_int8_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_int8_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_int8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_int8, TestAsTypeReshape)
{
struct custom_int8_t
{
using type = int8_t;
type data;
custom_int8_t() : data{type{}} {}
custom_int8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<int8_t> test_vec = {3, -6, 8, -2};
// reference vector
vector_type<custom_int8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_int8_t>()(Number<i>{}).data, 0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_int8_t>()(Number<i>{}) = custom_int8_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_int8_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_int8_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_int8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_uint8, TestSize)
{
struct custom_uint8_t
{
uint8_t data;
};
ASSERT_EQ(sizeof(custom_uint8_t), sizeof(uint8_t));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 2>), sizeof(vector_type<uint8_t, 2>));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 4>), sizeof(vector_type<uint8_t, 4>));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 8>), sizeof(vector_type<uint8_t, 8>));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 16>), sizeof(vector_type<uint8_t, 16>));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 32>), sizeof(vector_type<uint8_t, 32>));
ASSERT_EQ(sizeof(vector_type<custom_uint8_t, 64>), sizeof(vector_type<uint8_t, 64>));
}
TEST(Custom_uint8, TestAsType)
{
struct custom_uint8_t
{
using type = uint8_t;
type data;
custom_uint8_t() : data{type{}} {}
custom_uint8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<uint8_t> test_vec = {3, 6, 8, 2};
// reference vector
vector_type<custom_uint8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_uint8_t>()(Number<i>{}).data, 0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_uint8_t>()(Number<i>{}) = custom_uint8_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_uint8_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_uint8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_uint8, TestAsTypeReshape)
{
struct custom_uint8_t
{
using type = uint8_t;
type data;
custom_uint8_t() : data{type{}} {}
custom_uint8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<uint8_t> test_vec = {3, 6, 8, 2};
// reference vector
vector_type<custom_uint8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_uint8_t>()(Number<i>{}).data, 0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_uint8_t>()(Number<i>{}) = custom_uint8_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_uint8_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_uint8_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_uint8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_f8, TestSize)
{
struct custom_f8_t
{
_BitInt(8) data;
};
ASSERT_EQ(sizeof(custom_f8_t), sizeof(_BitInt(8)));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 2>), sizeof(vector_type<_BitInt(8), 2>));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 4>), sizeof(vector_type<_BitInt(8), 4>));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 8>), sizeof(vector_type<_BitInt(8), 8>));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 16>), sizeof(vector_type<_BitInt(8), 16>));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 32>), sizeof(vector_type<_BitInt(8), 32>));
ASSERT_EQ(sizeof(vector_type<custom_f8_t, 64>), sizeof(vector_type<_BitInt(8), 64>));
}
TEST(Custom_f8, TestAsType)
{
struct custom_f8_t
{
using type = _BitInt(8);
type data;
custom_f8_t() : data{type{}} {}
custom_f8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<_BitInt(8)> test_vec = {type_convert<_BitInt(8)>(0.3f),
type_convert<_BitInt(8)>(-0.6f),
type_convert<_BitInt(8)>(0.8f),
type_convert<_BitInt(8)>(-0.2f)};
// reference vector
vector_type<custom_f8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}(
[&](auto i) { ASSERT_EQ(right_vec.template AsType<custom_f8_t>()(Number<i>{}).data, 0); });
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_f8_t>()(Number<i>{}) = custom_f8_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_f8_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_f8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_f8, TestAsTypeReshape)
{
struct custom_f8_t
{
using type = _BitInt(8);
type data;
custom_f8_t() : data{type{}} {}
custom_f8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<_BitInt(8)> test_vec = {type_convert<_BitInt(8)>(0.3f),
type_convert<_BitInt(8)>(-0.6f),
type_convert<_BitInt(8)>(0.8f),
type_convert<_BitInt(8)>(-0.2f)};
// reference vector
vector_type<custom_f8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}(
[&](auto i) { ASSERT_EQ(right_vec.template AsType<custom_f8_t>()(Number<i>{}).data, 0); });
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_f8_t>()(Number<i>{}) = custom_f8_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_f8_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_f8_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_f8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_bf8, TestSize)
{
struct custom_bf8_t
{
unsigned _BitInt(8) data;
};
ASSERT_EQ(sizeof(custom_bf8_t), sizeof(unsigned _BitInt(8)));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 2>), sizeof(vector_type<unsigned _BitInt(8), 2>));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 4>), sizeof(vector_type<unsigned _BitInt(8), 4>));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 8>), sizeof(vector_type<unsigned _BitInt(8), 8>));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 16>), sizeof(vector_type<unsigned _BitInt(8), 16>));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 32>), sizeof(vector_type<unsigned _BitInt(8), 32>));
ASSERT_EQ(sizeof(vector_type<custom_bf8_t, 64>), sizeof(vector_type<unsigned _BitInt(8), 64>));
}
TEST(Custom_bf8, TestAsType)
{
struct custom_bf8_t
{
using type = unsigned _BitInt(8);
type data;
custom_bf8_t() : data{type{}} {}
custom_bf8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<unsigned _BitInt(8)> test_vec = {type_convert<unsigned _BitInt(8)>(0.3f),
type_convert<unsigned _BitInt(8)>(-0.6f),
type_convert<unsigned _BitInt(8)>(0.8f),
type_convert<unsigned _BitInt(8)>(-0.2f)};
// reference vector
vector_type<custom_bf8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}(
[&](auto i) { ASSERT_EQ(right_vec.template AsType<custom_bf8_t>()(Number<i>{}).data, 0); });
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bf8_t>()(Number<i>{}) = custom_bf8_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_bf8_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bf8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_bf8, TestAsTypeReshape)
{
struct custom_bf8_t
{
using type = unsigned _BitInt(8);
type data;
custom_bf8_t() : data{type{}} {}
custom_bf8_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<unsigned _BitInt(8)> test_vec = {type_convert<unsigned _BitInt(8)>(0.3f),
type_convert<unsigned _BitInt(8)>(-0.6f),
type_convert<unsigned _BitInt(8)>(0.8f),
type_convert<unsigned _BitInt(8)>(-0.2f)};
// reference vector
vector_type<custom_bf8_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}(
[&](auto i) { ASSERT_EQ(right_vec.template AsType<custom_bf8_t>()(Number<i>{}).data, 0); });
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bf8_t>()(Number<i>{}) = custom_bf8_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_bf8_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_bf8_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bf8_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_half, TestSize)
{
struct custom_half_t
{
half_t data;
};
ASSERT_EQ(sizeof(custom_half_t), sizeof(half_t));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 2>), sizeof(vector_type<half_t, 2>));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 4>), sizeof(vector_type<half_t, 4>));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 8>), sizeof(vector_type<half_t, 8>));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 16>), sizeof(vector_type<half_t, 16>));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 32>), sizeof(vector_type<half_t, 32>));
ASSERT_EQ(sizeof(vector_type<custom_half_t, 64>), sizeof(vector_type<half_t, 64>));
}
TEST(Custom_half, TestAsType)
{
struct custom_half_t
{
using type = half_t;
type data;
custom_half_t() : data{type{}} {}
custom_half_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<half_t> test_vec = {half_t{0.3f}, half_t{-0.6f}, half_t{0.8f}, half_t{-0.2f}};
// reference vector
vector_type<custom_half_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_half_t>()(Number<i>{}).data,
type_convert<half_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_half_t>()(Number<i>{}) = custom_half_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_half_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_half_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_half, TestAsTypeReshape)
{
struct custom_half_t
{
using type = half_t;
type data;
custom_half_t() : data{type{}} {}
custom_half_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<half_t> test_vec = {half_t{0.3f}, half_t{-0.6f}, half_t{0.8f}, half_t{-0.2f}};
// reference vector
vector_type<custom_half_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_half_t>()(Number<i>{}).data,
type_convert<half_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_half_t>()(Number<i>{}) = custom_half_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_half_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_half_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_half_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_bhalf, TestSize)
{
struct custom_bhalf_t
{
bhalf_t data;
};
ASSERT_EQ(sizeof(custom_bhalf_t), sizeof(bhalf_t));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 2>), sizeof(vector_type<bhalf_t, 2>));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 4>), sizeof(vector_type<bhalf_t, 4>));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 8>), sizeof(vector_type<bhalf_t, 8>));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 16>), sizeof(vector_type<bhalf_t, 16>));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 32>), sizeof(vector_type<bhalf_t, 32>));
ASSERT_EQ(sizeof(vector_type<custom_bhalf_t, 64>), sizeof(vector_type<bhalf_t, 64>));
}
TEST(Custom_bhalf, TestAsType)
{
struct custom_bhalf_t
{
using type = bhalf_t;
type data;
custom_bhalf_t() : data{type{}} {}
custom_bhalf_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<bhalf_t> test_vec = {type_convert<bhalf_t>(0.3f),
type_convert<bhalf_t>(-0.6f),
type_convert<bhalf_t>(0.8f),
type_convert<bhalf_t>(-0.2f)};
// reference vector
vector_type<custom_bhalf_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_bhalf_t>()(Number<i>{}).data,
type_convert<bhalf_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bhalf_t>()(Number<i>{}) = custom_bhalf_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_bhalf_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bhalf_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_bhalf, TestAsTypeReshape)
{
struct custom_bhalf_t
{
using type = bhalf_t;
type data;
custom_bhalf_t() : data{type{}} {}
custom_bhalf_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<bhalf_t> test_vec = {type_convert<bhalf_t>(0.3f),
type_convert<bhalf_t>(-0.6f),
type_convert<bhalf_t>(0.8f),
type_convert<bhalf_t>(-0.2f)};
// reference vector
vector_type<custom_bhalf_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_bhalf_t>()(Number<i>{}).data,
type_convert<bhalf_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_bhalf_t>()(Number<i>{}) = custom_bhalf_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_bhalf_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_bhalf_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_bhalf_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_float, TestSize)
{
struct custom_float_t
{
float data;
};
ASSERT_EQ(sizeof(custom_float_t), sizeof(float));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 2>), sizeof(vector_type<float, 2>));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 4>), sizeof(vector_type<float, 4>));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 8>), sizeof(vector_type<float, 8>));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 16>), sizeof(vector_type<float, 16>));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 32>), sizeof(vector_type<float, 32>));
ASSERT_EQ(sizeof(vector_type<custom_float_t, 64>), sizeof(vector_type<float, 64>));
}
TEST(Custom_float, TestAsType)
{
struct custom_float_t
{
using type = float;
type data;
custom_float_t() : data{type{}} {}
custom_float_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<float> test_vec = {0.3f, -0.6f, 0.8f, -0.2f};
// reference vector
vector_type<custom_float_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_float_t>()(Number<i>{}).data, 0.0f);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_float_t>()(Number<i>{}) = custom_float_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_float_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_float_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_float, TestAsTypeReshape)
{
struct custom_float_t
{
using type = float;
type data;
custom_float_t() : data{type{}} {}
custom_float_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<float> test_vec = {0.3f, -0.6f, 0.8f, -0.2f};
// reference vector
vector_type<custom_float_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_float_t>()(Number<i>{}).data, 0.0f);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_float_t>()(Number<i>{}) = custom_float_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_float_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_float_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_float_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_double, TestSize)
{
struct custom_double_t
{
double data;
};
ASSERT_EQ(sizeof(custom_double_t), sizeof(double));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 2>), sizeof(vector_type<double, 2>));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 4>), sizeof(vector_type<double, 4>));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 8>), sizeof(vector_type<double, 8>));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 16>), sizeof(vector_type<double, 16>));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 32>), sizeof(vector_type<double, 32>));
ASSERT_EQ(sizeof(vector_type<custom_double_t, 64>), sizeof(vector_type<double, 64>));
}
TEST(Custom_double, TestAsType)
{
struct custom_double_t
{
using type = double;
type data;
custom_double_t() : data{type{}} {}
custom_double_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<double> test_vec = {0.3, 0.6, 0.8, 0.2};
// reference vector
vector_type<custom_double_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_double_t>()(Number<i>{}).data, 0.0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_double_t>()(Number<i>{}) = custom_double_t{test_vec.at(i)};
});
// copy the vector
vector_type<custom_double_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_double_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Custom_double, TestAsTypeReshape)
{
struct custom_double_t
{
using type = double;
type data;
custom_double_t() : data{type{}} {}
custom_double_t(type init) : data{init} {}
};
// test size
const int size = 4;
std::vector<double> test_vec = {0.3, 0.6, 0.8, 0.2};
// reference vector
vector_type<custom_double_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<custom_double_t>()(Number<i>{}).data, 0.0);
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<custom_double_t>()(Number<i>{}) = custom_double_t{test_vec.at(i)};
});
// copy the first half of a vector
vector_type<custom_double_t, size / 2> left_vec{
right_vec.template AsType<vector_type<custom_double_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<custom_double_t>()(Number<i>{}).data, test_vec.at(i));
});
}
TEST(Complex_half, TestSize)
{
struct complex_half_t
{
half_t real;
half_t img;
};
ASSERT_EQ(sizeof(complex_half_t), sizeof(half_t) + sizeof(half_t));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 2>),
sizeof(vector_type<half_t, 2>) + sizeof(vector_type<half_t, 2>));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 4>),
sizeof(vector_type<half_t, 4>) + sizeof(vector_type<half_t, 4>));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 8>),
sizeof(vector_type<half_t, 8>) + sizeof(vector_type<half_t, 8>));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 16>),
sizeof(vector_type<half_t, 16>) + sizeof(vector_type<half_t, 16>));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 32>),
sizeof(vector_type<half_t, 32>) + sizeof(vector_type<half_t, 32>));
ASSERT_EQ(sizeof(vector_type<complex_half_t, 64>),
sizeof(vector_type<half_t, 64>) + sizeof(vector_type<half_t, 64>));
}
TEST(Complex_half, TestAlignment)
{
struct complex_half_t
{
half_t real;
half_t img;
};
ASSERT_EQ(alignof(vector_type<complex_half_t, 2>),
alignof(vector_type<half_t, 2>) + alignof(vector_type<half_t, 2>));
ASSERT_EQ(alignof(vector_type<complex_half_t, 4>),
alignof(vector_type<half_t, 4>) + alignof(vector_type<half_t, 4>));
ASSERT_EQ(alignof(vector_type<complex_half_t, 8>),
alignof(vector_type<half_t, 8>) + alignof(vector_type<half_t, 8>));
ASSERT_EQ(alignof(vector_type<complex_half_t, 16>),
alignof(vector_type<half_t, 16>) + alignof(vector_type<half_t, 16>));
ASSERT_EQ(alignof(vector_type<complex_half_t, 32>),
alignof(vector_type<half_t, 32>) + alignof(vector_type<half_t, 32>));
ASSERT_EQ(alignof(vector_type<complex_half_t, 64>),
alignof(vector_type<half_t, 64>) + alignof(vector_type<half_t, 64>));
}
TEST(Complex_half, TestAsType)
{
struct complex_half_t
{
using type = half_t;
type real;
type img;
complex_half_t() : real{type{}}, img{type{}} {}
complex_half_t(type real_init, type img_init) : real{real_init}, img{img_init} {}
};
// test size
const int size = 4;
// custom type number of elements
const int num_elem = sizeof(complex_half_t) / sizeof(complex_half_t::type);
std::vector<half_t> test_vec = {half_t{0.3f},
half_t{-0.6f},
half_t{0.8f},
half_t{-0.2f},
half_t{0.5f},
half_t{-0.7f},
half_t{0.9f},
half_t{-0.3f}};
// reference vector
vector_type<complex_half_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<complex_half_t>()(Number<i>{}).real,
type_convert<half_t>(0.0f));
ASSERT_EQ(right_vec.template AsType<complex_half_t>()(Number<i>{}).img,
type_convert<half_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<complex_half_t>()(Number<i>{}) =
complex_half_t{test_vec.at(num_elem * i), test_vec.at(num_elem * i + 1)};
});
// copy the vector
vector_type<complex_half_t, size> left_vec{right_vec};
// check if values were copied correctly
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<complex_half_t>()(Number<i>{}).real,
test_vec.at(num_elem * i));
ASSERT_EQ(left_vec.template AsType<complex_half_t>()(Number<i>{}).img,
test_vec.at(num_elem * i + 1));
});
}
TEST(Complex_half, TestAsTypeReshape)
{
struct complex_half_t
{
using type = half_t;
type real;
type img;
complex_half_t() : real{type{}}, img{type{}} {}
complex_half_t(type real_init, type img_init) : real{real_init}, img{img_init} {}
};
// test size
const int size = 4;
// custom type number of elements
const int num_elem = sizeof(complex_half_t) / sizeof(complex_half_t::type);
std::vector<half_t> test_vec = {half_t{0.3f},
half_t{-0.6f},
half_t{0.8f},
half_t{-0.2f},
half_t{0.5f},
half_t{-0.7f},
half_t{0.9f},
half_t{-0.3f}};
// reference vector
vector_type<complex_half_t, size> right_vec;
// check default CTOR
ck::static_for<0, size, 1>{}([&](auto i) {
ASSERT_EQ(right_vec.template AsType<complex_half_t>()(Number<i>{}).real,
type_convert<half_t>(0.0f));
ASSERT_EQ(right_vec.template AsType<complex_half_t>()(Number<i>{}).img,
type_convert<half_t>(0.0f));
});
// assign test values to the vector
ck::static_for<0, size, 1>{}([&](auto i) {
right_vec.template AsType<complex_half_t>()(Number<i>{}) =
complex_half_t{test_vec.at(num_elem * i), test_vec.at(num_elem * i + 1)};
});
// copy the first half of a vector
vector_type<complex_half_t, size / 2> left_vec{
right_vec.template AsType<vector_type<complex_half_t, size / 2>::type>()(Number<0>{})};
// check if values were copied correctly
ck::static_for<0, size / 2, 1>{}([&](auto i) {
ASSERT_EQ(left_vec.template AsType<complex_half_t>()(Number<i>{}).real,
test_vec.at(num_elem * i));
ASSERT_EQ(left_vec.template AsType<complex_half_t>()(Number<i>{}).img,
test_vec.at(num_elem * i + 1));
});
}
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