Gitiles
Code Review Sign In
review.mlplatform.org / ml / ComputeLibrary / d9eaf614975afad18fd13b9e8c7a7dd21ff6a1dd / . / src / core / CL / cl_kernels / gemm_helpers.h
blob: 08e737d3b094d2896bfd7aca9d7c6e790c4b9bff [file] [log] [blame]
/*
* Copyright (c) 2019-2020 Arm Limited.
*
* SPDX-License-Identifier: MIT
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "activation_float_helpers.h"
#include "helpers.h"
/** Loads the rows from 0 to n-1 in the given variables (BASENAME0 to BASENAMEn-1).
* @name LOAD_ROW_n
*
* @param[in] N0 The number of rows to load
* @param[in] DATA_TYPE The data type of variables
* @param[in] BASENAME The basename of the destination variables for the loaded rows
* @param[in] PTR The base pointer
* @param[in] OFFSET The offset within a row
* @param[in] STRIDE_Y The stride value in y-axis direction
* @param[in] Z The z-axis offset vector
* @{
*/
#define LOAD_ROW_1(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##0 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 0 * STRIDE_Y + Z##0));
#define LOAD_ROW_2(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_1(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##1 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 1 * STRIDE_Y + Z##1));
#define LOAD_ROW_3(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_2(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##2 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 2 * STRIDE_Y + Z##2));
#define LOAD_ROW_4(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_3(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##3 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 3 * STRIDE_Y + Z##3));
#define LOAD_ROW_5(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_4(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##4 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 4 * STRIDE_Y + Z##4));
#define LOAD_ROW_6(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_5(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##5 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 5 * STRIDE_Y + Z##5));
#define LOAD_ROW_7(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_6(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##6 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 6 * STRIDE_Y + Z##6));
#define LOAD_ROW_8(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_7(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##7 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 7 * STRIDE_Y + Z##7));
#define LOAD_ROW_9(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_8(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##8 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 8 * STRIDE_Y + Z##8));
#define LOAD_ROW_10(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_9(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##9 = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 9 * STRIDE_Y + Z##9));
#define LOAD_ROW_11(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_10(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##A = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 10 * STRIDE_Y + Z##A));
#define LOAD_ROW_12(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_11(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##B = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 11 * STRIDE_Y + Z##B));
#define LOAD_ROW_13(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_12(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##C = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 12 * STRIDE_Y + Z##C));
#define LOAD_ROW_14(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_13(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##D = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 13 * STRIDE_Y + Z##D));
#define LOAD_ROW_15(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_14(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##E = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 14 * STRIDE_Y + Z##E));
#define LOAD_ROW_16(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
LOAD_ROW_15(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##F = VLOAD(N0)(0, (__global DATA_TYPE *)(PTR + OFFSET + 15 * STRIDE_Y + Z##F));
/** @}*/ // end of group LOAD_ROW_n
/** Load Blocks (consecutive rows and columns) with Z offset.
* @name LOAD_BLOCK
*
* Supported cases are M0=1,2,3,...,16 and N0=1,2,3,4,8,16
* The data to load is expected to have consecutive names for each row.
* E.g., for M0=3, and BASENAME=c, the expected data is c0, c1 and c2.
* The Z offset is expected to have consecutive names.
* E.g., for M0=3, and Z=zin, the expected Z offsets are zin0, zin1 and zin2.
*
* @param[in] M0 The number of consecutive rows
* @param[in] N0 The number of consecutive columns
* @param[in] DATA_TYPE The data type of the target
* @param[in] BASENAME The basename of the result variables
* @param[in] PTR The base pointer for the data
* @param[in] OFFSET The offset within a row
* @param[in] STRIDE_Y The stride in y-axis direction
* @param[in] Z The z-axis offset vector
* @{
*/
#define LOAD_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) LOAD_ROW_##M0(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z)
#define LOAD_BLOCK(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z) LOAD_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y, Z)
/** @} */ // end of group LOAD_BLOCK
/** Loads the rows from 0 to n-1 in the given variables (BASENAME0 to BASENAMEn-1).
* @name LOAD_TEXTURE2D_ROW_n
*
* @param[in] N0 The number of pixels to read
* @param[in] DATA_TYPE The data type of variables
* @param[in] BASENAME The basename of the destination variables for the loaded rows
* @param[in] IMG The 2D OpenCL image object
* @param[in] X_COORD The x coordinate for the top-left pixel
* @param[in] Y_COORD The y coordinate for the top-left pixel
* @param[in] X_STEP_ROW The incremental step row for the x coordinate (in pixels)
* @param[in] Y_STEP_ROW The incremental step row for the y coordinate (in pixels)
* @{
*/
#define LOAD_TEXTURE2D_ROW_1(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##0 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 0 * X_STEP_ROW), (Y_COORD + 0 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_2(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_1(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##1 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 1 * X_STEP_ROW), (Y_COORD + 1 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_3(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_2(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##2 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 2 * X_STEP_ROW), (Y_COORD + 2 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_4(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_3(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##3 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 3 * X_STEP_ROW), (Y_COORD + 3 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_5(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_4(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##4 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 4 * X_STEP_ROW), (Y_COORD + 4 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_6(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_5(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##5 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 5 * X_STEP_ROW), (Y_COORD + 5 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_7(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_6(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##6 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 6 * X_STEP_ROW), (Y_COORD + 6 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_8(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_7(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##7 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 7 * X_STEP_ROW), (Y_COORD + 7 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_9(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_8(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##8 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 8 * X_STEP_ROW), (Y_COORD + 8 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_10(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_9(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##9 = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 9 * X_STEP_ROW), (Y_COORD + 9 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_11(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_10(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##A = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 10 * X_STEP_ROW), (Y_COORD + 10 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_12(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_11(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##B = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 11 * X_STEP_ROW), (Y_COORD + 11 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_13(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_12(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##C = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 12 * X_STEP_ROW), (Y_COORD + 12 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_14(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_13(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##D = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 13 * X_STEP_ROW), (Y_COORD + 13 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_15(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_14(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##E = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 14 * X_STEP_ROW), (Y_COORD + 14 * Y_STEP_ROW))
#define LOAD_TEXTURE2D_ROW_16(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
LOAD_TEXTURE2D_ROW_15(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) \
BASENAME##F = READ_IMAGE2D(DATA_TYPE, N0, IMG, (X_COORD + 15 * X_STEP_ROW), (Y_COORD + 15 * Y_STEP_ROW))
/** @} */ // end of group LOAD_TEXTURE2D_ROW_n
/** Load a 2D texture in unit of pixel. A pixel is made of 4 floating point values
* @name LOAD_TEXTURE2D
*
* Supported cases are M0=1,2,3,...,16 and N0=1
* The data to load is expected to have consecutive names for each row.
* E.g., for M0=3, and BASENAME=c, the expected data is c0, c1 and c2.
*
* @param[in] M0 The number of consecutive rows
* @param[in] N0 The number of consecutive pixels. Only 1, 2 and 4 are supported
* @param[in] DATA_TYPE The data type of the target
* @param[in] BASENAME The basename of the result variables
* @param[in] IMG The 2D OpenCL image object
* @param[in] X_COORD The x coordinate for the top-left pixel
* @param[in] Y_COORD The y coordinate for the top-left pixel
* @param[in] X_STEP_ROW The incremental step row for the x coordinate (in pixels)
* @param[in] Y_STEP_ROW The incremental step row for the y coordinate (in pixels)
* @{
*/
#define LOAD_TEXTURE2D_STR(M0, N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) LOAD_TEXTURE2D_ROW_##M0(N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW)
#define LOAD_TEXTURE2D(M0, N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW) LOAD_TEXTURE2D_STR(M0, N0, DATA_TYPE, BASENAME, IMG, X_COORD, Y_COORD, X_STEP_ROW, Y_STEP_ROW)
/** @} */ // end of group LOAD_TEXTURE2D
/** Loads the elements from 0 to n-1 in the given variables (BASENAME0 to BASENAMEn-1).
* @name LOAD_ELEMENT_n
*
* @param[in] N0 The number of rows to load
* @param[in] DATA_TYPE The data type of variables
* @param[in] BASENAME The basename of the destination variables for the loaded rows
* @param[in] PTR The base pointer
* @param[in] OFFSET The offset within a row
* @param[in] STRIDE_Y The stride value in y-axis direction
* @{
*/
#define LOAD_ELEMENT_1(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##0 = *((__global DATA_TYPE *)(PTR + OFFSET + 0 * STRIDE_Y));
#define LOAD_ELEMENT_2(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_1(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##1 = *((__global DATA_TYPE *)(PTR + OFFSET + 1 * STRIDE_Y));
#define LOAD_ELEMENT_3(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_2(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##2 = *((__global DATA_TYPE *)(PTR + OFFSET + 2 * STRIDE_Y));
#define LOAD_ELEMENT_4(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_3(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##3 = *((__global DATA_TYPE *)(PTR + OFFSET + 3 * STRIDE_Y));
#define LOAD_ELEMENT_5(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_4(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##4 = *((__global DATA_TYPE *)(PTR + OFFSET + 4 * STRIDE_Y));
#define LOAD_ELEMENT_6(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_5(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##5 = *((__global DATA_TYPE *)(PTR + OFFSET + 5 * STRIDE_Y));
#define LOAD_ELEMENT_7(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_6(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##6 = *((__global DATA_TYPE *)(PTR + OFFSET + 6 * STRIDE_Y));
#define LOAD_ELEMENT_8(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_7(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##7 = *((__global DATA_TYPE *)(PTR + OFFSET + 7 * STRIDE_Y));
#define LOAD_ELEMENT_9(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_8(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##8 = *((__global DATA_TYPE *)(PTR + OFFSET + 8 * STRIDE_Y));
#define LOAD_ELEMENT_10(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_9(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##9 = *((__global DATA_TYPE *)(PTR + OFFSET + 9 * STRIDE_Y));
#define LOAD_ELEMENT_11(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_10(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##A = *((__global DATA_TYPE *)(PTR + OFFSET + 10 * STRIDE_Y));
#define LOAD_ELEMENT_12(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_11(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##B = *((__global DATA_TYPE *)(PTR + OFFSET + 11 * STRIDE_Y));
#define LOAD_ELEMENT_13(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_12(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##C = *((__global DATA_TYPE *)(PTR + OFFSET + 12 * STRIDE_Y));
#define LOAD_ELEMENT_14(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_13(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##D = *((__global DATA_TYPE *)(PTR + OFFSET + 13 * STRIDE_Y));
#define LOAD_ELEMENT_15(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_14(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##E = *((__global DATA_TYPE *)(PTR + OFFSET + 14 * STRIDE_Y));
#define LOAD_ELEMENT_16(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
LOAD_ELEMENT_15(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) \
VEC_DATA_TYPE(DATA_TYPE, N0) \
BASENAME##F = *((__global DATA_TYPE *)(PTR + OFFSET + 15 * STRIDE_Y));
/** @}*/ // end of group LOAD_ELEMENT_n
/** Load Scalar as Vector (consecutive elements).
* @name LOAD_SCALAR_AS_VECTOR
*
* Supported cases are M0=1,2,3,...,16 and N0=1,2,3,4,8,16
* The data to load is expected to have consecutive names for each row.
* E.g., for M0=3, and BASENAME=c, the expected data is c0, c1 and c2.
*
* @param[in] M0 The number of consecutive rows
* @param[in] N0 The number of consecutive columns
* @param[in] DATA_TYPE The data type of the target
* @param[in] BASENAME The basename of the result variables
* @param[in] PTR The base pointer for the data
* @param[in] OFFSET The offset within a row
* @param[in] STRIDE_Y The stride in y-axis direction
* @{
*/
#define LOAD_SCALAR_AS_VECTOR_STR(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) LOAD_ELEMENT_##M0(N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y)
#define LOAD_SCALAR_AS_VECTOR(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y) LOAD_SCALAR_AS_VECTOR_STR(M0, N0, DATA_TYPE, BASENAME, PTR, OFFSET, STRIDE_Y)
/** @} */ // end of group LOAD_SCALAR_AS_VECTOR
/** Basic macros to calculate Z offset values from Z0 to Zn-1
* @name CALCULATE_Z_OFFSET_n
*
* @param[in] M0 The number of offset values to calculate
* @param[in] DATA_TYPE The data type of the results
* @param[in] Z The basename of the result variables
* @param[in] Y The work-itme ID of y-axis
* @param[in] HEIGHT_GEMM3D The height of GEMM3D
* @param[in] DEPTH_GEMM3D The depth of GEMM3D
* @param[in] CROSS_PLANE_PAD The padding required for plane changes accross the z-dimension
* @param[in] STRIDE_Y The stride value in y-axis direction
*
* @{
*/
#define CALCULATE_Z_OFFSET_1(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##0 = (0 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##0 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##0); \
Z##0 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_2(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_1(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##1 = (1 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##1 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##1); \
Z##1 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_3(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_2(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##2 = (2 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##2 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##2); \
Z##2 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_4(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_3(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##3 = (3 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##3 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##3); \
Z##3 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_5(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_4(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##4 = (4 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##4 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##4); \
Z##4 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_6(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_5(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##5 = (5 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##5 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##5); \
Z##5 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_7(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_6(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##6 = (6 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##6 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##6); \
Z##6 *= (CROSS_PLANE_PAD * STRIDE_Y);
#define CALCULATE_Z_OFFSET_8(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
CALCULATE_Z_OFFSET_7(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) \
Z##7 = (7 + (DATA_TYPE)(Y * (DATA_TYPE)M0)) / (DATA_TYPE)HEIGHT_GEMM3D; \
Z##7 = min((DATA_TYPE)(DEPTH_GEMM3D - 1), Z##7); \
Z##7 *= (CROSS_PLANE_PAD * STRIDE_Y);
/** @} */ // end of group CALCULATE_Z_OFFSET_n
/** Calculate Z offset values from Z0 to Zn-1
* @name CALCULATE_Z_OFFSET
*
* The Z offsets are expected to have consecutive names.
* E.g., for M0=3 and Z=zin, the expected names of Z offsets are zin1, zin2, zin3.
* Note that, CROSS_PLANE_PAD (cross plain padding) is required to take into account
* the possible cross plane paddings in case of the plance changes across the z-dimension.
*
* <!--
* | |
* | plane0 |
* | |
* |__________________|
* |******************|
* | cross_plane_pad |
* |******************|
* | |
* | plane1 |
* | |
* |__________________|
* -->
*
* @param[in] M0 The number of offset values to calculate
* @param[in] DATA_TYPE The data type of the results
* @param[in] Z The basename of the result variables
* @param[in] Y The work-itme ID of y-axis
* @param[in] HEIGHT_GEMM3D The height of GEMM3D
* @param[in] DEPTH_GEMM3D The depth of GEMM3D
* @param[in] CROSS_PLANE_PAD The padding required for plane changes accross the z-dimension
* @param[in] STRIDE_Y The stride value in y-axis direction
* @{
*/
#define CALCULATE_Z_OFFSET_STR(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) CALCULATE_Z_OFFSET_##M0(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y)
#define CALCULATE_Z_OFFSET(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y) CALCULATE_Z_OFFSET_STR(M0, DATA_TYPE, Z, Y, HEIGHT_GEMM3D, DEPTH_GEMM3D, CROSS_PLANE_PAD, STRIDE_Y)
/** @} */ // end of group CALCULATE_Z_OFFSET
/** Store the 0 to (n-1)th rows of the given variables
* @name STORE_ROW_n
*
* @param[in] N0 The size of the vectors
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] PTR The base pointer
* @param[in] STRIDE_Y The stride value in y-axis direction
* @param[in] Z The offset in z-axis direction
* @{
*/
#define STORE_ROW_1(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##0, 0, (__global DATA_TYPE *)(PTR + 0 * STRIDE_Y + Z##0));
#define STORE_ROW_2(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_1(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##1, 0, (__global DATA_TYPE *)(PTR + 1 * STRIDE_Y + Z##1));
#define STORE_ROW_3(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_2(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##2, 0, (__global DATA_TYPE *)(PTR + 2 * STRIDE_Y + Z##2));
#define STORE_ROW_4(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_3(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##3, 0, (__global DATA_TYPE *)(PTR + 3 * STRIDE_Y + Z##3));
#define STORE_ROW_5(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_4(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##4, 0, (__global DATA_TYPE *)(PTR + 4 * STRIDE_Y + Z##4));
#define STORE_ROW_6(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_5(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##5, 0, (__global DATA_TYPE *)(PTR + 5 * STRIDE_Y + Z##5));
#define STORE_ROW_7(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_6(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##6, 0, (__global DATA_TYPE *)(PTR + 6 * STRIDE_Y + Z##6));
#define STORE_ROW_8(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_7(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##7, 0, (__global DATA_TYPE *)(PTR + 7 * STRIDE_Y + Z##7));
#define STORE_ROW_9(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_8(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##8, 0, (__global DATA_TYPE *)(PTR + 8 * STRIDE_Y + Z##8));
#define STORE_ROW_10(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_9(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##9, 0, (__global DATA_TYPE *)(PTR + 9 * STRIDE_Y + Z##9));
#define STORE_ROW_11(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_10(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##A, 0, (__global DATA_TYPE *)(PTR + 10 * STRIDE_Y + Z##A));
#define STORE_ROW_12(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_11(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##B, 0, (__global DATA_TYPE *)(PTR + 11 * STRIDE_Y + Z##B));
#define STORE_ROW_13(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_12(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##C, 0, (__global DATA_TYPE *)(PTR + 12 * STRIDE_Y + Z##C));
#define STORE_ROW_14(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_13(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##D, 0, (__global DATA_TYPE *)(PTR + 13 * STRIDE_Y + Z##D));
#define STORE_ROW_15(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_14(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##E, 0, (__global DATA_TYPE *)(PTR + 14 * STRIDE_Y + Z##E));
#define STORE_ROW_16(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
STORE_ROW_15(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(BASENAME##F, 0, (__global DATA_TYPE *)(PTR + 15 * STRIDE_Y + Z##F));
/** @} */ // end of groupd STORE_ROW_n
/** Convert and store the 0th to (n-1)th rows of the given variables
* @name CONVERT_STORE_ROW_n
*
* @param[in] N0 The size of the vectors
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] PTR The base pointer
* @param[in] STRIDE_Y The stride value in y-axis direction
* @param[in] Z The offset in z-axis direction
* @{
*/
#define CONVERT_STORE_ROW_1(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##0), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 0 * STRIDE_Y + Z##0));
#define CONVERT_STORE_ROW_2(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_1(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##1), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 1 * STRIDE_Y + Z##1));
#define CONVERT_STORE_ROW_3(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_2(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##2), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 2 * STRIDE_Y + Z##2));
#define CONVERT_STORE_ROW_4(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_3(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##3), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 3 * STRIDE_Y + Z##3));
#define CONVERT_STORE_ROW_5(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_4(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##4), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 4 * STRIDE_Y + Z##4));
#define CONVERT_STORE_ROW_6(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_5(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##5), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 5 * STRIDE_Y + Z##5));
#define CONVERT_STORE_ROW_7(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_6(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##6), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 6 * STRIDE_Y + Z##6));
#define CONVERT_STORE_ROW_8(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_7(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##7), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 7 * STRIDE_Y + Z##7));
#define CONVERT_STORE_ROW_9(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_8(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##8), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 8 * STRIDE_Y + Z##8));
#define CONVERT_STORE_ROW_10(N0, DATA, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_9(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##9), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 9 * STRIDE_Y + Z##9));
#define CONVERT_STORE_ROW_11(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_10(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##A), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 10 * STRIDE_Y + Z##A));
#define CONVERT_STORE_ROW_12(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_11(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##B), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 11 * STRIDE_Y + Z##B));
#define CONVERT_STORE_ROW_13(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_12(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##C), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 12 * STRIDE_Y + Z##C));
#define CONVERT_STORE_ROW_14(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_13(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##D), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 13 * STRIDE_Y + Z##D));
#define CONVERT_STORE_ROW_15(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_14(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##E), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 14 * STRIDE_Y + Z##E));
#define CONVERT_STORE_ROW_16(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
CONVERT_STORE_ROW_15(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) \
VSTORE(N0) \
(CONVERT_SAT((BASENAME##F), VEC_DATA_TYPE(DATA_TYPE, N0)), 0, (__global DATA_TYPE *)(PTR + 15 * STRIDE_Y + Z##F));
/** @} */ // end of groupd CONVERT_STORE_ROW_n
/** Store a block of the given size M0xN0
* @name STORE_BLOCK
*
* Supported cases are M0=1,2,3,...,16 and N0=2,3,4,8,16.
* The data to store is expected to have consecutive names for each row.
* E.g., for M0=3 and basename=c, the expected names are c0, c1 and c2.
* The Z offset is expected to have consecutive names.
* E.g., for M0=3 and Z=zin, the expected z offset names are zin0, zin1 and zin2.
*
* @param[in] M0 The number of rows to store
* @param[in] N0 The size of each vector
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] PTR The base pointer
* @param[in] STRIDE_Y The stride value in y-axis direction
* @param[in] Z The offset in z-axis direction
* @{
*/
#define STORE_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) STORE_ROW_##M0(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z)
#define STORE_BLOCK(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) STORE_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z)
/** @} */ // end of group STORE_BLOCK
/** Convert and store a block of the given size M0xN0
* @name CONVERT_STORE_BLOCK
*
* Supported cases are M0=1,2,3,...,16 and N0=2,3,4,8,16.
* The data to store is expected to have consecutive names for each row.
* E.g., for M0=3 and basename=c, the expected names are c0, c1 and c2.
* The Z offset is expected to have consecutive names.
* E.g., for M0=3 and Z=zin, the expected z offset names are zin0, zin1 and zin2.
*
* @param[in] M0 The number of rows to store
* @param[in] N0 The size of each vector
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] PTR The base pointer
* @param[in] STRIDE_Y The stride value in y-axis direction
* @param[in] Z The offset in z-axis direction
* @{
*/
#define CONVERT_STORE_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) CONVERT_STORE_ROW_##M0(N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z)
#define CONVERT_STORE_BLOCK(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z) CONVERT_STORE_BLOCK_STR(M0, N0, DATA_TYPE, BASENAME, PTR, STRIDE_Y, Z)
/** @} */ // end of group CONVERT_STORE_BLOCK
/** Scale the rows in the given variables (BASENAME0 to BASENAMEn-1)
* @name SCALE_ROW_n
*
* @param[in] DATA_TYPE The data type of the variables
* @param[in] BASENAME The basename of the variables
* @param[in] SCALE The scale factor
* @{
*/
#define SCALE_ROW_1(DATA_TYPE, BASENAME, SCALE) \
BASENAME##0 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_2(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_1(DATA_TYPE, BASENAME, SCALE) \
BASENAME##1 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_3(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_2(DATA_TYPE, BASENAME, SCALE) \
BASENAME##2 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_4(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_3(DATA_TYPE, BASENAME, SCALE) \
BASENAME##3 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_5(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_4(DATA_TYPE, BASENAME, SCALE) \
BASENAME##4 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_6(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_5(DATA_TYPE, BASENAME, SCALE) \
BASENAME##5 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_7(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_6(DATA_TYPE, BASENAME, SCALE) \
BASENAME##6 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_8(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_7(DATA_TYPE, BASENAME, SCALE) \
BASENAME##7 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_9(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_8(DATA_TYPE, BASENAME, SCALE) \
BASENAME##8 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_10(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_9(DATA_TYPE, BASENAME, SCALE) \
BASENAME##9 *= (DATA_TYPE)SCALE;
#define SCALE_ROW_11(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_10(DATA_TYPE, BASENAME, SCALE) \
BASENAME##A *= (DATA_TYPE)SCALE;
#define SCALE_ROW_12(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_11(DATA_TYPE, BASENAME, SCALE) \
BASENAME##B *= (DATA_TYPE)SCALE;
#define SCALE_ROW_13(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_12(DATA_TYPE, BASENAME, SCALE) \
BASENAME##C *= (DATA_TYPE)SCALE;
#define SCALE_ROW_14(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_13(DATA_TYPE, BASENAME, SCALE) \
BASENAME##D *= (DATA_TYPE)SCALE;
#define SCALE_ROW_15(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_14(DATA_TYPE, BASENAME, SCALE) \
BASENAME##E *= (DATA_TYPE)SCALE;
#define SCALE_ROW_16(DATA_TYPE, BASENAME, SCALE) \
SCALE_ROW_15(DATA_TYPE, BASENAME, SCALE) \
BASENAME##F *= (DATA_TYPE)SCALE;
/** @} */ // end of group SCALE_ROW_n
/** Scale elements stored in a block (BASENAME)
* @name SCALE_BLOCK
*
* Supported cases are N=1,2,3,...,16
*
* @param[in] N The number of rows in the block
* @param[in] DATA_TYPE The data type of the block
* @param[in] BASENAME The basename of the block
* @param[in] SCALE The scale factor
* @{
*/
#define SCALE_BLOCK_STR(N, DATA_TYPE, BASENAME, SCALE) SCALE_ROW_##N(DATA_TYPE, BASENAME, SCALE)
#define SCALE_BLOCK(N, DATA_TYPE, BASENAME, SCALE) SCALE_BLOCK_STR(N, DATA_TYPE, BASENAME, SCALE)
/** @} */ // end of group SCALE_BLOCK
/** Create a new vector containing the values at the given index for a set of given vectors
* @name COLUMN_VECTORn
*
* @param[in] IDX_COL The index value
* @param[in] BASENAME The basename of the destination vectors
* @param[in] X The basename of the source vectors
* @param[in] TYPE The data type of the destination vectors
* @{
*/
#define COLUMN_VECTOR1(IDX_COL, BASENAME, X, TYPE) \
TYPE BASENAME##IDX_COL = (TYPE)((X##0).s##IDX_COL);
#define COLUMN_VECTOR2(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 2) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 2))((X##0).s##IDX_COL, (X##1).s##IDX_COL);
#define COLUMN_VECTOR3(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 3) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 3))((X##0).s##IDX_COL, (X##1).s##IDX_COL, (X##2).s##IDX_COL);
#define COLUMN_VECTOR4(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 4) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 4))((X##0).s##IDX_COL, (X##1).s##IDX_COL, (X##2).s##IDX_COL, (X##3).s##IDX_COL);
#define COLUMN_VECTOR8(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 8) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 8))((X##0).s##IDX_COL, (X##1).s##IDX_COL, (X##2).s##IDX_COL, (X##3).s##IDX_COL, (X##4).s##IDX_COL, (X##5).s##IDX_COL, (X##6).s##IDX_COL, (X##7).s##IDX_COL);
#define COLUMN_VECTOR16(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 16) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 16))((X##0).s##IDX_COL, (X##1).s##IDX_COL, (X##2).s##IDX_COL, (X##3).s##IDX_COL, (X##4).s##IDX_COL, (X##5).s##IDX_COL, (X##6).s##IDX_COL, (X##7).s##IDX_COL, (X##8).s##IDX_COL, (X##9).s##IDX_COL, (X##A).s##IDX_COL, (X##B).s##IDX_COL, (X##C).s##IDX_COL, (X##D).s##IDX_COL, (X##E).s##IDX_COL, (X##F).s##IDX_COL);
/** @} */ // end of group COLUMN_VECTORn
/** Create a new vector containing the values at the given index. Utility macros for transposing a colum-vector
* @name COLUMN_VECTOR_SCALARn
*
* @param[in] IDX_COL The index value
* @param[in] BASENAME The basename of the destination vectors
* @param[in] X The basename of the source vectors
* @param[in] TYPE The data type of the destination vectors
* @{
*/
#define COLUMN_VECTOR_SCALAR1(IDX_COL, BASENAME, X, TYPE) \
TYPE BASENAME##IDX_COL = (TYPE)((X##0));
#define COLUMN_VECTOR_SCALAR2(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 2) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 2))((X##0), (X##1));
#define COLUMN_VECTOR_SCALAR3(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 3) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 3))((X##0), (X##1), (X##2));
#define COLUMN_VECTOR_SCALAR4(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 4) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 4))((X##0), (X##1), (X##2), (X##3));
#define COLUMN_VECTOR_SCALAR8(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 8) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 8))((X##0), (X##1), (X##2), (X##3), (X##4), (X##5), (X##6), (X##7));
#define COLUMN_VECTOR_SCALAR16(IDX_COL, BASENAME, X, TYPE) \
VEC_DATA_TYPE(TYPE, 16) \
BASENAME##IDX_COL = (VEC_DATA_TYPE(TYPE, 16))((X##0), (X##1), (X##2), (X##3), (X##4), (X##5), (X##6), (X##7), (X##8), (X##9), (X##A), (X##B), (X##C), (X##D), (X##E), (X##F));
/** @} */ // end of group COLUMN_VECTORn
/** Create transposed vectors of the given vectors
* @name TRANSPOSE_K0Xn
*
* @param[in] K0 The size of the source vectors
* @param[in] BASENAME The basename of transposed vectors
* @param[in] B The basename of source vectors for transposition
* @param[in] TYPE The data type of the transposed vectors
* @{
*/
#define TRANSPOSE_K0X1(K0, BASENAME, B, TYPE) \
COLUMN_VECTOR_SCALAR(K0, 0, BASENAME, B, TYPE);
#define TRANSPOSE_K0X2(K0, BASENAME, B, TYPE) \
COLUMN_VECTOR(K0, 0, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 1, BASENAME, B, TYPE);
#define TRANSPOSE_K0X3(K0, BASENAME, B, TYPE) \
TRANSPOSE_K0X2(K0, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 2, BASENAME, B, TYPE);
#define TRANSPOSE_K0X4(K0, BASENAME, B, TYPE) \
TRANSPOSE_K0X3(K0, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 3, BASENAME, B, TYPE);
#define TRANSPOSE_K0X8(K0, BASENAME, B, TYPE) \
TRANSPOSE_K0X4(K0, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 4, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 5, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 6, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 7, BASENAME, B, TYPE);
#define TRANSPOSE_K0X16(K0, BASENAME, B, TYPE) \
TRANSPOSE_K0X8(K0, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 8, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, 9, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, A, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, B, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, C, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, D, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, E, BASENAME, B, TYPE); \
COLUMN_VECTOR(K0, F, BASENAME, B, TYPE);
/** @} */ // end of group TRANSPOSE_K0Xn
/** Create column vectors to contain the values at the given index for a set of given vectors
*
* @param[in] K0 The number of source vectors
* @param[in] IDX_COL The index value
* @param[in] BASENAME The basename of the destination vectors
* @param[in] B The basename of the source vectors
* @param[in] TYPE The data type of the destination vectors
*/
#define COLUMN_VECTOR(K0, IDX_COL, BASENAME, B, TYPE) \
CONCAT(COLUMN_VECTOR, K0) \
(IDX_COL, BASENAME, B, TYPE);
/** Create column vectors to contain the values at the given index. Utility macro for transposing a column-vector
*
* @param[in] K0 The number of source vectors
* @param[in] IDX_COL The index value
* @param[in] BASENAME The basename of the destination vectors
* @param[in] B The basename of the source vectors
* @param[in] TYPE The data type of the destination vectors
*/
#define COLUMN_VECTOR_SCALAR(K0, IDX_COL, BASENAME, B, TYPE) \
CONCAT(COLUMN_VECTOR_SCALAR, K0) \
(IDX_COL, BASENAME, B, TYPE);
/** Create transposed vectors form the given source vectors
*
* @param[in] K0 The size of source vectors
* @param[in] N0 The number of source vectors
* @param[in] BASENAME The basename of transposed vectors
* @param[in] B The basename of source vectors for transposition
* @param[in] TYPE The data type of the transposed vectors
*
*/
#define TRANSPOSE_K0XN0(K0, N0, BASENAME, B, TYPE) \
CONCAT(TRANSPOSE_K0X, N0) \
(K0, BASENAME, B, TYPE);
/** Add the variables (BIAS0 to BIASn-1) to the others (BASENAME0 to BASENAMEn-1)
* @name ADD_ROW_n
*
* @param[in] BASENAME The basename of the destination variables
* @param[in] BIAS The basename of the added variables
* @{
*/
#define ADD_ROW_1(BASENAME, BIAS) \
BASENAME##0 += BIAS##0;
#define ADD_ROW_2(BASENAME, BIAS) \
ADD_ROW_1(BASENAME, BIAS) \
BASENAME##1 += BIAS##1;
#define ADD_ROW_3(BASENAME, BIAS) \
ADD_ROW_2(BASENAME, BIAS) \
BASENAME##2 += BIAS##2;
#define ADD_ROW_4(BASENAME, BIAS) \
ADD_ROW_3(BASENAME, BIAS) \
BASENAME##3 += BIAS##3;
#define ADD_ROW_5(BASENAME, BIAS) \
ADD_ROW_4(BASENAME, BIAS) \
BASENAME##4 += BIAS##4;
#define ADD_ROW_6(BASENAME, BIAS) \
ADD_ROW_5(BASENAME, BIAS) \
BASENAME##5 += BIAS##5;
#define ADD_ROW_7(BASENAME, BIAS) \
ADD_ROW_6(BASENAME, BIAS) \
BASENAME##6 += BIAS##6;
#define ADD_ROW_8(BASENAME, BIAS) \
ADD_ROW_7(BASENAME, BIAS) \
BASENAME##7 += BIAS##7;
#define ADD_ROW_9(BASENAME, BIAS) \
ADD_ROW_8(BASENAME, BIAS) \
BASENAME##8 += BIAS##8;
#define ADD_ROW_10(BASENAME, BIAS) \
ADD_ROW_9(BASENAME, BIAS) \
BASENAME##9 += BIAS##9;
#define ADD_ROW_11(BASENAME, BIAS) \
ADD_ROW_10(BASENAME, BIAS) \
BASENAME##A += BIAS##A;
#define ADD_ROW_12(BASENAME, BIAS) \
ADD_ROW_11(BASENAME, BIAS) \
BASENAME##B += BIAS##B;
#define ADD_ROW_13(BASENAME, BIAS) \
ADD_ROW_12(BASENAME, BIAS) \
BASENAME##C += BIAS##C;
#define ADD_ROW_14(BASENAME, BIAS) \
ADD_ROW_13(BASENAME, BIAS) \
BASENAME##D += BIAS##D;
#define ADD_ROW_15(BASENAME, BIAS) \
ADD_ROW_14(BASENAME, BIAS) \
BASENAME##E += BIAS##E;
#define ADD_ROW_16(BASENAME, BIAS) \
ADD_ROW_15(BASENAME, BIAS) \
BASENAME##F += BIAS##F;
/** @} */ // end of group ADD_ROW_n
/** Add the block (BIAS) to another block (BASENAME)
* @name ADD_BLOCK
*
* Supported cases are N=1,2,3,...,16
*
* @param[in] N The number of vectors in the block
* @param[in] BASENAME The basename of the destination variables
* @param[in] BIAS The basename of the added variables
* @{
*/
#define ADD_BLOCK_STR(N, BASENAME, BIAS) ADD_ROW_##N(BASENAME, BIAS)
#define ADD_BLOCK(N, BASENAME, BIAS) ADD_BLOCK_STR(N, BASENAME, BIAS)
/** @} */ // end of group ADD_BLOCK
/** Broadcast (add single value) to the each element of the destination variables
* @name ADD_ROW_BROADCAST_n
*
* @param[in] BASENAME The basename of the destination variables
* @param[in] BIAS The variable containing the value to add
* @{
*/
#define ADD_ROW_BROADCAST_1(BASENAME, BIAS) \
BASENAME##0 += BIAS;
#define ADD_ROW_BROADCAST_2(BASENAME, BIAS) \
ADD_ROW_BROADCAST_1(BASENAME, BIAS) \
BASENAME##1 += BIAS;
#define ADD_ROW_BROADCAST_3(BASENAME, BIAS) \
ADD_ROW_BROADCAST_2(BASENAME, BIAS) \
BASENAME##2 += BIAS;
#define ADD_ROW_BROADCAST_4(BASENAME, BIAS) \
ADD_ROW_BROADCAST_3(BASENAME, BIAS) \
BASENAME##3 += BIAS;
#define ADD_ROW_BROADCAST_5(BASENAME, BIAS) \
ADD_ROW_BROADCAST_4(BASENAME, BIAS) \
BASENAME##4 += BIAS;
#define ADD_ROW_BROADCAST_6(BASENAME, BIAS) \
ADD_ROW_BROADCAST_5(BASENAME, BIAS) \
BASENAME##5 += BIAS;
#define ADD_ROW_BROADCAST_7(BASENAME, BIAS) \
ADD_ROW_BROADCAST_6(BASENAME, BIAS) \
BASENAME##6 += BIAS;
#define ADD_ROW_BROADCAST_8(BASENAME, BIAS) \
ADD_ROW_BROADCAST_7(BASENAME, BIAS) \
BASENAME##7 += BIAS;
#define ADD_ROW_BROADCAST_9(BASENAME, BIAS) \
ADD_ROW_BROADCAST_8(BASENAME, BIAS) \
BASENAME##8 += BIAS;
#define ADD_ROW_BROADCAST_10(BASENAME, BIAS) \
ADD_ROW_BROADCAST_9(BASENAME, BIAS) \
BASENAME##9 += BIAS;
#define ADD_ROW_BROADCAST_11(BASENAME, BIAS) \
ADD_ROW_BROADCAST_10(BASENAME, BIAS) \
BASENAME##A += BIAS;
#define ADD_ROW_BROADCAST_12(BASENAME, BIAS) \
ADD_ROW_BROADCAST_11(BASENAME, BIAS) \
BASENAME##B += BIAS;
#define ADD_ROW_BROADCAST_13(BASENAME, BIAS) \
ADD_ROW_BROADCAST_12(BASENAME, BIAS) \
BASENAME##C += BIAS;
#define ADD_ROW_BROADCAST_14(BASENAME, BIAS) \
ADD_ROW_BROADCAST_13(BASENAME, BIAS) \
BASENAME##D += BIAS;
#define ADD_ROW_BROADCAST_15(BASENAME, BIAS) \
ADD_ROW_BROADCAST_14(BASENAME, BIAS) \
BASENAME##E += BIAS;
#define ADD_ROW_BROADCAST_16(BASENAME, BIAS) \
ADD_ROW_BROADCAST_15(BASENAME, BIAS) \
BASENAME##F += BIAS;
/** Broadcast (add a value) to the each element of the destination block (BASENAME)
* @name ADD_BLOCK_BROADCAST
*
* Supported cases are N=1,2,3,...,16.
*
* @param[in] N The number of vectors in the block
* @param[in] BASENAME The basename of the destination variables
* @param[in] BIAS The variable containing the value to add
* @{
*/
#define ADD_BLOCK_BROADCAST_STR(N, BASENAME, BIAS) ADD_ROW_BROADCAST_##N(BASENAME, BIAS)
#define ADD_BLOCK_BROADCAST(N, BASENAME, BIAS) ADD_BLOCK_BROADCAST_STR(N, BASENAME, BIAS)
/** @} */ // end of group ADD_BLOCK_BROADCAST
/** Apply activation to the given variables
* @name ACTIVATION_ROW_n
*
* @param[in] ACTIVATION_TYPE The type of the activation
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] A_VAL Additional value required by the activation
* @param[in] B_VAL Additional value required by the activation
* @{
*/
#define ACTIVATION_ROW_1(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##0 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##0, A_VAL, B_VAL);
#define ACTIVATION_ROW_2(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_1(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##1 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##1, A_VAL, B_VAL);
#define ACTIVATION_ROW_3(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_2(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##2 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##2, A_VAL, B_VAL);
#define ACTIVATION_ROW_4(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_3(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##3 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##3, A_VAL, B_VAL);
#define ACTIVATION_ROW_5(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_4(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##4 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##4, A_VAL, B_VAL);
#define ACTIVATION_ROW_6(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_5(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##5 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##5, A_VAL, B_VAL);
#define ACTIVATION_ROW_7(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_6(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##6 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##6, A_VAL, B_VAL);
#define ACTIVATION_ROW_8(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_7(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##7 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##7, A_VAL, B_VAL);
#define ACTIVATION_ROW_9(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_8(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##8 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##8, A_VAL, B_VAL);
#define ACTIVATION_ROW_10(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_9(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##9 = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##9, A_VAL, B_VAL);
#define ACTIVATION_ROW_11(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_10(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##A = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##A, A_VAL, B_VAL);
#define ACTIVATION_ROW_12(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_11(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##B = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##B, A_VAL, B_VAL);
#define ACTIVATION_ROW_13(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_12(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##C = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##C, A_VAL, B_VAL);
#define ACTIVATION_ROW_14(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_13(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##D = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##D, A_VAL, B_VAL);
#define ACTIVATION_ROW_15(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_14(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##E = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##E, A_VAL, B_VAL);
#define ACTIVATION_ROW_16(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
ACTIVATION_ROW_15(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) \
BASENAME##F = ACTIVATION(ACTIVATION_TYPE, DATA_TYPE, BASENAME##F, A_VAL, B_VAL);
/** @} */ // end of group ACTIVATION_ROW_n
/** Apply activation to a block (BASENAME)
* @name ACTIVATION_BLOCK
*
* Supported cases are N=1,2,3,...,16.
*
* @param[in] N The number of vectors in the block
* @param[in] ACTIVATION_TYPE The type of the activation
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME The basename of the variables
* @param[in] A_VAL Additional value required by the activation
* @param[in] B_VAL Additional value required by the activation
* @{
*/
#define ACTIVATION_BLOCK_STR(N, ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) ACTIVATION_ROW_##N(ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL)
#define ACTIVATION_BLOCK(N, ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL) ACTIVATION_BLOCK_STR(N, ACTIVATION_TYPE, DATA_TYPE, BASENAME, A_VAL, B_VAL)
/** @} */ // end of group ACTIVATION_BLOCK
/** Apply convert_<data_type> to the given variables
* @name CONVERT_ROW_n
*
* @param[in] N The size of the vectors
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME_SRC The basename of the source variables
* @param[in] BASENAME_DST The basename of the destination variables
*/
#define CONVERT_ROW_1(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##0 = CONVERT(BASENAME_SRC##0, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_2(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_1(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##1 = CONVERT(BASENAME_SRC##1, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_3(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_2(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##2 = CONVERT(BASENAME_SRC##2, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_4(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_3(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##3 = CONVERT(BASENAME_SRC##3, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_5(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_4(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##4 = CONVERT(BASENAME_SRC##4, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_6(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_5(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##5 = CONVERT(BASENAME_SRC##5, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_7(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_6(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##6 = CONVERT(BASENAME_SRC##6, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_8(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_7(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##7 = CONVERT(BASENAME_SRC##7, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_9(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_8(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##8 = CONVERT(BASENAME_SRC##8, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_10(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_9(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##9 = CONVERT(BASENAME_SRC##9, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_11(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_10(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##A = CONVERT(BASENAME_SRC##A, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_12(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_11(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##B = CONVERT(BASENAME_SRC##B, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_13(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_12(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##C = CONVERT(BASENAME_SRC##C, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_14(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_13(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##D = CONVERT(BASENAME_SRC##D, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_15(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_14(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##E = CONVERT(BASENAME_SRC##E, VEC_DATA_TYPE(DATA_TYPE, N));
#define CONVERT_ROW_16(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
CONVERT_ROW_15(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) \
VEC_DATA_TYPE(DATA_TYPE, N) \
BASENAME_DST##F = CONVERT(BASENAME_SRC##F, VEC_DATA_TYPE(DATA_TYPE, N));
/** @} */ // end of group CONVERT_ROW_n
/** Apply convert_<data_type> to a block (BASENAME_SRC) and save to another block (BASENAME_DST)
* @name CONVERT_BLOCK
*
* Supported cases N=1,2,3,...,16.
*
* @param[in] M The number of vectors to convert
* @param[in] N The size of the vectors
* @param[in] DATA_TYPE The data type of the vectors
* @param[in] BASENAME_SRC The basename of the source variables
* @param[in] BASENAME_DST The basename of the destination variables
*/
#define CONVERT_BLOCK_STR(M, N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) CONVERT_ROW_##M(N, DATA_TYPE, BASENAME_SRC, BASENAME_DST)
#define CONVERT_BLOCK(M, N, DATA_TYPE, BASENAME_SRC, BASENAME_DST) CONVERT_BLOCK_STR(M, N, DATA_TYPE, BASENAME_SRC, BASENAME_DST)
/** @} */ // end of group CONVERT_BLOCK