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Diffstat (limited to 'silx/resources/opencl/convolution_textures.cl')
-rw-r--r-- | silx/resources/opencl/convolution_textures.cl | 374 |
1 files changed, 374 insertions, 0 deletions
diff --git a/silx/resources/opencl/convolution_textures.cl b/silx/resources/opencl/convolution_textures.cl new file mode 100644 index 0000000..517a67c --- /dev/null +++ b/silx/resources/opencl/convolution_textures.cl @@ -0,0 +1,374 @@ +/******************************************************************************/ +/**************************** Macros ******************************************/ +/******************************************************************************/ + +// Error handling +#ifndef IMAGE_DIMS + #error "IMAGE_DIMS must be defined" +#endif +#ifndef FILTER_DIMS + #error "FILTER_DIMS must be defined" +#endif +#if FILTER_DIMS > IMAGE_DIMS + #error "Filter cannot have more dimensions than image" +#endif + +// Boundary handling modes +#define CONV_MODE_REFLECT 0 // CLK_ADDRESS_MIRRORED_REPEAT : cba|abcd|dcb +#define CONV_MODE_NEAREST 1 // CLK_ADDRESS_CLAMP_TO_EDGE : aaa|abcd|ddd +#define CONV_MODE_WRAP 2 // CLK_ADDRESS_REPEAT : bcd|abcd|abc +#define CONV_MODE_CONSTANT 3 // CLK_ADDRESS_CLAMP : 000|abcd|000 +#ifndef USED_CONV_MODE + #define USED_CONV_MODE CONV_MODE_NEAREST +#endif +#if USED_CONV_MODE == CONV_MODE_REFLECT + #define CLK_BOUNDARY CLK_ADDRESS_MIRRORED_REPEAT + #define CLK_COORDS CLK_NORMALIZED_COORDS_TRUE + #define USE_NORM_COORDS +#elif USED_CONV_MODE == CONV_MODE_NEAREST + #define CLK_BOUNDARY CLK_ADDRESS_CLAMP_TO_EDGE + #define CLK_COORDS CLK_NORMALIZED_COORDS_FALSE +#elif USED_CONV_MODE == CONV_MODE_WRAP + #define CLK_BOUNDARY CLK_ADDRESS_REPEAT + #define CLK_COORDS CLK_NORMALIZED_COORDS_TRUE + #define USE_NORM_COORDS +#elif USED_CONV_MODE == CONV_MODE_CONSTANT + #define CLK_BOUNDARY CLK_ADDRESS_CLAMP + #define CLK_COORDS CLK_NORMALIZED_COORDS_FALSE +#else + #error "Unknown convolution mode" +#endif + + + +// Convolution index for filter +#define FILTER_INDEX(j) (Lx - 1 - j) + +// Filter access patterns +#define READ_FILTER_1D(j) read_imagef(filter, (int2) (FILTER_INDEX(j), 0)).x; +#define READ_FILTER_2D(jx, jy) read_imagef(filter, (int2) (FILTER_INDEX(jx), FILTER_INDEX(jy))).x; +#define READ_FILTER_3D(jx, jy, jz) read_imagef(filter, (int4) (FILTER_INDEX(jx), FILTER_INDEX(jy), FILTER_INDEX(jz), 0)).x; + + +// Convolution index for image +#ifdef USE_NORM_COORDS + #define IMAGE_INDEX_X (gidx*1.0f +0.5f - c + jx)/Nx + #define IMAGE_INDEX_Y (gidy*1.0f +0.5f - c + jy)/Ny + #define IMAGE_INDEX_Z (gidz*1.0f +0.5f - c + jz)/Nz + #define RET_TYPE_1 float + #define RET_TYPE_2 float2 + #define RET_TYPE_4 float4 + #define C_ZERO 0.5f + #define GIDX (gidx*1.0f + 0.5f)/Nx + #define GIDY (gidy*1.0f + 0.5f)/Ny + #define GIDZ (gidz*1.0f + 0.5f)/Nz +#else + #define IMAGE_INDEX_X (gidx - c + jx) + #define IMAGE_INDEX_Y (gidy - c + jy) + #define IMAGE_INDEX_Z (gidz - c + jz) + #define RET_TYPE_1 int + #define RET_TYPE_2 int2 + #define RET_TYPE_4 int4 + #define C_ZERO 0 + #define GIDX gidx + #define GIDY gidy + #define GIDZ gidz +#endif + +static const sampler_t sampler = CLK_COORDS | CLK_BOUNDARY | CLK_FILTER_NEAREST; + +// Image access patterns +#define READ_IMAGE_1D read_imagef(input, sampler, (RET_TYPE_2) (IMAGE_INDEX_X, C_ZERO)).x + +#define READ_IMAGE_2D_X read_imagef(input, sampler, (RET_TYPE_2) (IMAGE_INDEX_X , GIDY)).x +#define READ_IMAGE_2D_Y read_imagef(input, sampler, (RET_TYPE_2) (GIDX, IMAGE_INDEX_Y)).x +#define READ_IMAGE_2D_XY read_imagef(input, sampler, (RET_TYPE_2) (IMAGE_INDEX_X, IMAGE_INDEX_Y)).x + +#define READ_IMAGE_3D_X read_imagef(input, sampler, (RET_TYPE_4) (IMAGE_INDEX_X, GIDY, GIDZ, C_ZERO)).x +#define READ_IMAGE_3D_Y read_imagef(input, sampler, (RET_TYPE_4) (GIDX, IMAGE_INDEX_Y, GIDZ, C_ZERO)).x +#define READ_IMAGE_3D_Z read_imagef(input, sampler, (RET_TYPE_4) (GIDX, GIDY, IMAGE_INDEX_Z, C_ZERO)).x +#define READ_IMAGE_3D_XY read_imagef(input, sampler, (RET_TYPE_4) (IMAGE_INDEX_X, IMAGE_INDEX_Y, GIDZ, C_ZERO)).x +#define READ_IMAGE_3D_XZ read_imagef(input, sampler, (RET_TYPE_4) (IMAGE_INDEX_X, GIDY, IMAGE_INDEX_Z, C_ZERO)).x +#define READ_IMAGE_3D_YZ read_imagef(input, sampler, (RET_TYPE_4) (GIDX, IMAGE_INDEX_Y, IMAGE_INDEX_Z, C_ZERO)).x +#define READ_IMAGE_3D_XYZ read_imagef(input, sampler, (RET_TYPE_4) (IMAGE_INDEX_X, IMAGE_INDEX_Y, IMAGE_INDEX_Z, C_ZERO)).x + + +// NOTE: pyopencl and OpenCL < 1.2 do not support image1d_t +#if FILTER_DIMS == 1 + #define FILTER_TYPE image2d_t + #define READ_FILTER_VAL(j) READ_FILTER_1D(j) +#elif FILTER_DIMS == 2 + #define FILTER_TYPE image2d_t + #define READ_FILTER_VAL(jx, jy) READ_FILTER_2D(jx, jy) +#elif FILTER_DIMS == 3 + #define FILTER_TYPE image3d_t + #define READ_FILTER_VAL(jx, jy, jz) READ_FILTER_3D(jx, jy, jz) +#endif + +#if IMAGE_DIMS == 1 + #define IMAGE_TYPE image2d_t + #define READ_IMAGE_X READ_IMAGE_1D +#elif IMAGE_DIMS == 2 + #define IMAGE_TYPE image2d_t + #define READ_IMAGE_X READ_IMAGE_2D_X + #define READ_IMAGE_Y READ_IMAGE_2D_Y + #define READ_IMAGE_XY READ_IMAGE_2D_XY +#elif IMAGE_DIMS == 3 + #define IMAGE_TYPE image3d_t + #define READ_IMAGE_X READ_IMAGE_3D_X + #define READ_IMAGE_Y READ_IMAGE_3D_Y + #define READ_IMAGE_Z READ_IMAGE_3D_Z + #define READ_IMAGE_XY READ_IMAGE_3D_XY + #define READ_IMAGE_XZ READ_IMAGE_3D_XZ + #define READ_IMAGE_YZ READ_IMAGE_3D_YZ + #define READ_IMAGE_XYZ READ_IMAGE_3D_XYZ +#endif + + +// Get the center index of the filter, +// and the "half-Left" and "half-Right" lengths. +// In the case of an even-sized filter, the center is shifted to the left. +#define GET_CENTER_HL(hlen){\ + if (hlen & 1) {\ + c = hlen/2;\ + hL = c;\ + hR = c;\ + }\ + else {\ + c = hlen/2 - 1;\ + hL = c;\ + hR = c+1;\ + }\ +}\ + + + +/******************************************************************************/ +/**************************** 1D Convolution **********************************/ +/******************************************************************************/ + +#if FILTER_DIMS == 1 +// Convolution with 1D kernel along axis "X" (fast dimension) +// Works for batched 1D on 2D and batched 2D on 3D, along axis "X". +__kernel void convol_1D_X_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter size + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jx = 0; jx <= hR+hL; jx++) { + sum += READ_IMAGE_X * READ_FILTER_VAL(jx); + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} + + +#if IMAGE_DIMS >= 2 +// Convolution with 1D kernel along axis "Y" +// Works for batched 1D on 2D and batched 2D on 3D, along axis "Y". +__kernel void convol_1D_Y_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter size + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jy = 0; jy <= hR+hL; jy++) { + sum += READ_IMAGE_Y * READ_FILTER_VAL(jy); + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} +#endif + +#if IMAGE_DIMS == 3 +// Convolution with 1D kernel along axis "Z" +// Works for batched 1D on 2D and batched 2D on 3D, along axis "Z". +__kernel void convol_1D_Z_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter size + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jz = 0; jz <= hR+hL; jz++) { + sum += READ_IMAGE_Z * READ_FILTER_VAL(jz); + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} +#endif +#endif + +/******************************************************************************/ +/**************************** 2D Convolution **********************************/ +/******************************************************************************/ + +#if IMAGE_DIMS >= 2 && FILTER_DIMS == 2 +// Convolution with 2D kernel +// Works for batched 2D on 3D. +__kernel void convol_2D_XY_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter number of columns, + int Ly, // filter number of rows, + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jy = 0; jy <= hR+hL; jy++) { + for (int jx = 0; jx <= hR+hL; jx++) { + sum += READ_IMAGE_XY * READ_FILTER_VAL(jx, jy); + } + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} +#endif + +#if IMAGE_DIMS == 3 && FILTER_DIMS == 2 +// Convolution with 2D kernel +// Works for batched 2D on 3D. +__kernel void convol_2D_XZ_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter number of columns, + int Lz, // filter number of rows, + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jz = 0; jz <= hR+hL; jz++) { + for (int jx = 0; jx <= hR+hL; jx++) { + sum += READ_IMAGE_XZ * READ_FILTER_VAL(jx, jz); + } + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} + + +// Convolution with 2D kernel +// Works for batched 2D on 3D. +__kernel void convol_2D_YZ_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter number of columns, + int Lz, // filter number of rows, + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jz = 0; jz <= hR+hL; jz++) { + for (int jy = 0; jy <= hR+hL; jy++) { + sum += READ_IMAGE_YZ * READ_FILTER_VAL(jy, jz); + } + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} +#endif + + +/******************************************************************************/ +/**************************** 3D Convolution **********************************/ +/******************************************************************************/ + +#if IMAGE_DIMS == 3 && FILTER_DIMS == 3 +// Convolution with 3D kernel +__kernel void convol_3D_XYZ_tex( + read_only IMAGE_TYPE input, + __global float * output, + read_only FILTER_TYPE filter, + int Lx, // filter number of columns, + int Ly, // filter number of rows, + int Lz, // filter number of rows, + int Nx, // input/output number of columns + int Ny, // input/output number of rows + int Nz // input/output depth +) +{ + uint gidx = get_global_id(0); + uint gidy = get_global_id(1); + uint gidz = get_global_id(2); + if ((gidx >= Nx) || (gidy >= Ny) || (gidz >= Nz)) return; + + int c, hL, hR; + GET_CENTER_HL(Lx); + float sum = 0.0f; + + for (int jz = 0; jz <= hR+hL; jz++) { + for (int jy = 0; jy <= hR+hL; jy++) { + for (int jx = 0; jx <= hR+hL; jx++) { + sum += READ_IMAGE_XYZ * READ_FILTER_VAL(jx, jy, jz); + } + } + } + output[(gidz*Ny + gidy)*Nx + gidx] = sum; +} +#endif |