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refactoed and extended ocl::transpose

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This commit is contained in:
Ilya Lavrenov 2013-09-24 14:07:54 +04:00
parent 799afab23b
commit b4ad128218
2 changed files with 65 additions and 483 deletions
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72
modules/ocl/src/arithm.cpp
View File

@ -1511,57 +1511,51 @@ oclMatExpr::operator oclMat() const
//////////////////////////////////////////////////////////////////////////////
/////////////////////////////// transpose ////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
#define TILE_DIM (32)
#define BLOCK_ROWS (256/TILE_DIM)
static void transpose_run(const oclMat &src, oclMat &dst, string kernelName)
{
if(!src.clCxt->supportsFeature(Context::CL_DOUBLE) && src.type() == CV_64F)
Context *clCxt = src.clCxt;
if (!clCxt->supportsFeature(Context::CL_DOUBLE) && src.depth() == CV_64F)
{
CV_Error(CV_GpuNotSupported, "Selected device don't support double\r\n");
CV_Error(CV_GpuNotSupported, "Selected device doesn't support double\r\n");
return;
}
CV_Assert(src.cols == dst.rows && src.rows == dst.cols);
Context *clCxt = src.clCxt;
int channels = src.oclchannels();
int depth = src.depth();
int vector_lengths[4][7] = {{1, 0, 0, 0, 1, 1, 0},
{0, 0, 1, 1, 0, 0, 0},
{0, 0, 0, 0 , 0, 0, 0},
{1, 1, 0, 0, 0, 0, 0}
};
size_t vector_length = vector_lengths[channels - 1][depth];
int offset_cols = ((dst.offset % dst.step) / dst.elemSize()) & (vector_length - 1);
int cols = divUp(src.cols + offset_cols, vector_length);
const char * const typeMap[] = { "uchar", "char", "ushort", "short", "int", "float", "double" };
const char channelsString[] = { ' ', ' ', '2', '4', '4' };
std::string buildOptions = format("-D T=%s%c", typeMap[src.depth()],
channelsString[src.channels()]);
size_t localThreads[3] = { TILE_DIM, BLOCK_ROWS, 1 };
size_t globalThreads[3] = { cols, src.rows, 1 };
size_t globalThreads[3] = { src.cols, src.rows, 1 };
int srcstep1 = src.step / src.elemSize(), dststep1 = dst.step / dst.elemSize();
int srcoffset1 = src.offset / src.elemSize(), dstoffset1 = dst.offset / dst.elemSize();
vector<pair<size_t , const void *> > args;
args.push_back( make_pair( sizeof(cl_mem), (void *)&src.data ));
args.push_back( make_pair( sizeof(cl_int), (void *)&src.step ));
args.push_back( make_pair( sizeof(cl_int), (void *)&src.offset ));
args.push_back( make_pair( sizeof(cl_mem), (void *)&dst.data ));
args.push_back( make_pair( sizeof(cl_int), (void *)&dst.step ));
args.push_back( make_pair( sizeof(cl_int), (void *)&dst.offset ));
args.push_back( make_pair( sizeof(cl_int), (void *)&src.cols ));
args.push_back( make_pair( sizeof(cl_int), (void *)&src.rows ));
args.push_back( make_pair( sizeof(cl_int), (void *)&cols ));
args.push_back( make_pair( sizeof(cl_int), (void *)&srcstep1 ));
args.push_back( make_pair( sizeof(cl_int), (void *)&dststep1 ));
args.push_back( make_pair( sizeof(cl_int), (void *)&srcoffset1 ));
args.push_back( make_pair( sizeof(cl_int), (void *)&dstoffset1 ));
openCLExecuteKernel(clCxt, &arithm_transpose, kernelName, globalThreads, localThreads, args, channels, depth);
openCLExecuteKernel(clCxt, &arithm_transpose, kernelName, globalThreads, localThreads,
args, -1, -1, buildOptions.c_str());
}
void cv::ocl::transpose(const oclMat &src, oclMat &dst)
{
CV_Assert(src.type() == CV_8UC1 || src.type() == CV_8UC3 || src.type() == CV_8UC4 || src.type() == CV_8SC3 || src.type() == CV_8SC4 ||
src.type() == CV_16UC2 || src.type() == CV_16SC2 || src.type() == CV_32SC1 || src.type() == CV_32FC1);
CV_Assert(src.depth() <= CV_64F && src.channels() <= 4);
oclMat emptyMat;
if( src.data == dst.data && dst.cols == dst.rows )
transpose_run( src, emptyMat, "transposeI_");
if ( src.data == dst.data && src.cols == src.rows && dst.offset == src.offset
&& dst.rows == dst.cols && src.cols == dst.cols)
transpose_run( src, dst, "transpose_inplace");
else
{
dst.create(src.cols, src.rows, src.type());
@ -1569,6 +1563,10 @@ void cv::ocl::transpose(const oclMat &src, oclMat &dst)
}
}
//////////////////////////////////////////////////////////////////////////////
////////////////////////////// addWeighted ///////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
void cv::ocl::addWeighted(const oclMat &src1, double alpha, const oclMat &src2, double beta, double gama, oclMat &dst)
{
Context *clCxt = src1.clCxt;
@ -1633,6 +1631,10 @@ void cv::ocl::addWeighted(const oclMat &src1, double alpha, const oclMat &src2,
args, -1, -1, buildOptions.c_str());
}
//////////////////////////////////////////////////////////////////////////////
/////////////////////////////////// Pow //////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
static void arithmetic_pow_run(const oclMat &src1, double p, oclMat &dst, string kernelName, const char **kernelString)
{
CV_Assert(src1.cols == dst.cols && src1.rows == dst.rows);
@ -1671,6 +1673,7 @@ static void arithmetic_pow_run(const oclMat &src1, double p, oclMat &dst, string
openCLExecuteKernel(clCxt, kernelString, kernelName, globalThreads, localThreads, args, -1, depth);
}
void cv::ocl::pow(const oclMat &x, double p, oclMat &y)
{
if(!x.clCxt->supportsFeature(Context::CL_DOUBLE) && x.type() == CV_64F)
@ -1685,6 +1688,11 @@ void cv::ocl::pow(const oclMat &x, double p, oclMat &y)
arithmetic_pow_run(x, p, y, kernelName, &arithm_pow);
}
//////////////////////////////////////////////////////////////////////////////
/////////////////////////////// setIdentity //////////////////////////////////
//////////////////////////////////////////////////////////////////////////////
void cv::ocl::setIdentity(oclMat& src, double scalar)
{
CV_Assert(src.empty() == false && src.rows == src.cols);
@ -1711,7 +1719,6 @@ void cv::ocl::setIdentity(oclMat& src, double scalar)
}
vector<pair<size_t , const void *> > args;
args.push_back( make_pair( sizeof(cl_mem), (void *)&src.data ));
args.push_back( make_pair( sizeof(cl_int), (void *)&src.rows));
@ -1735,7 +1742,8 @@ void cv::ocl::setIdentity(oclMat& src, double scalar)
{
scalar_i = (int)scalar;
args.push_back(make_pair(sizeof(cl_int), (void*)&scalar_i));
}else
}
else
{
scalar_f = (float)scalar;
args.push_back(make_pair(sizeof(cl_float), (void*)&scalar_f));

476
modules/ocl/src/opencl/arithm_transpose.cl
View File

@ -43,468 +43,42 @@
//
//M*/
#define TILE_DIM 32
#define BLOCK_ROWS 8
#define LDS_STEP (TILE_DIM + 1)
#if defined (DOUBLE_SUPPORT)
#pragma OPENCL EXTENSION cl_khr_fp64:enable
#endif
//8UC1 is not unoptimized, as the size of write per thread is 8
//which will use completepath
__kernel void transpose_C1_D0(__global uchar* src, int src_step, int src_offset,
__global uchar* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
__kernel void transpose(__global const T* src, __global T* dst,
int src_cols, int src_rows,
int src_step, int dst_step,
int src_offset, int dst_offset)
{
int x = get_global_id(0);
int y = get_global_id(1);
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
if (x < src_cols && y < src_rows)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int srcIdx = mad24(y, src_step, src_offset + x);
int dstIdx = mad24(x, dst_step, dst_offset + y);
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local uchar title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, x);
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] =*(src + src_offset + index_src);
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, x_index);
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*(dst + dst_offset + index_dst ) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
dst[dstIdx] = src[srcIdx];
}
}
__kernel void transpose_C1_D4(__global int* src, int src_step, int src_offset,
__global int* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
__kernel void transpose_inplace(__global T* src, __global T* dst,
int src_cols, int src_rows,
int src_step, int dst_step,
int src_offset, int dst_offset)
{
int x = get_global_id(0);
int y = get_global_id(1);
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
if (x < src_cols && y < src_rows && x < y)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int srcIdx = mad24(y, src_step, src_offset + x);
int dstIdx = mad24(x, dst_step, dst_offset + y);
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local int title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global int *)((__global char*)src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global int*)((__global char*)dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
}
}
__kernel void transpose_C1_D5(__global float* src, int src_step, int src_offset,
__global float* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
{
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local float title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global float *)((__global char*)src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global float*)((__global char*)dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
}
}
__kernel void transpose_C2_D2(__global ushort* src, int src_step, int src_offset,
__global ushort* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
{
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local ushort2 title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global ushort2 *)((__global char*)src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global ushort2*)((__global char*)dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
}
}
__kernel void transpose_C2_D3(__global short* src, int src_step, int src_offset,
__global short* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
{
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local short2 title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global short2 *)((__global char*)src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global short2*)((__global char*)dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
}
}
__kernel void transpose_C4_D0(__global uchar* src, int src_step, int src_offset,
__global uchar* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
{
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local uchar4 title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global uchar4 *)(src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global uchar4*)(dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
}
}
__kernel void transpose_C4_D1(__global char* src, int src_step, int src_offset,
__global char* dst, int dst_step, int dst_offset,
int src_rows, int src_cols)
{
int gp_x = get_group_id(0), gp_y = get_group_id(1);
int gs_x = get_num_groups(0), gs_y = get_num_groups(1);
int groupId_x, groupId_y;
if(src_rows == src_cols)
{
groupId_y = gp_x;
groupId_x = (gp_x + gp_y) % gs_x;
}
else
{
int bid = gp_x + gs_x * gp_y;
groupId_y = bid % gs_y;
groupId_x = ((bid / gs_y) + groupId_y) % gs_x;
}
int lx = get_local_id(0);
int ly = get_local_id(1);
int x = groupId_x * TILE_DIM + lx;
int y = groupId_y * TILE_DIM + ly;
int x_index = groupId_y * TILE_DIM + lx;
int y_index = groupId_x * TILE_DIM + ly;
__local char4 title[TILE_DIM * LDS_STEP];
if(x < src_cols && y < src_rows)
{
int index_src = mad24(y, src_step, (x << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if(y + i < src_rows)
{
title[(ly + i) * LDS_STEP + lx] = *((__global char4 *)(src + src_offset + index_src));
index_src = mad24(BLOCK_ROWS, src_step, index_src);
}
}
}
barrier(CLK_LOCAL_MEM_FENCE);
if(x_index < src_rows && y_index < src_cols)
{
int index_dst = mad24(y_index, dst_step, (x_index << 2));
#pragma unroll
for(int i = 0; i < TILE_DIM; i += BLOCK_ROWS)
{
if((y_index + i) < src_cols)
{
*((__global char4*)(dst + dst_offset + index_dst )) = title[lx * LDS_STEP + ly + i];
index_dst += dst_step * BLOCK_ROWS ;
}
}
T tmp = dst[dstIdx];
dst[dstIdx] = src[srcIdx];
src[srcIdx] = tmp;
}
}