/*
-----------------------------------------------------------------------
Copyright: 2010-2016, iMinds-Vision Lab, University of Antwerp
2014-2016, CWI, Amsterdam
Contact: astra@uantwerpen.be
Website: http://www.astra-toolbox.com/
This file is part of the ASTRA Toolbox.
The ASTRA Toolbox is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
The ASTRA Toolbox is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with the ASTRA Toolbox. If not, see .
-----------------------------------------------------------------------
*/
#include "util3d.h"
#include "arith3d.h"
#include
namespace astraCUDA3d {
struct opAddScaled {
__device__ void operator()(float& out, const float in, const float inp) {
out += in * inp;
}
};
struct opScaleAndAdd {
__device__ void operator()(float& out, const float in, const float inp) {
out = in + out * inp;
}
};
struct opAddMulScaled {
__device__ void operator()(float& out, const float in1, const float in2, const float inp) {
out += in1 * in2 * inp;
}
};
struct opAddMul {
__device__ void operator()(float& out, const float in1, const float in2) {
out += in1 * in2;
}
};
struct opAdd {
__device__ void operator()(float& out, const float in) {
out += in;
}
};
struct opMul {
__device__ void operator()(float& out, const float in) {
out *= in;
}
};
struct opMul2 {
__device__ void operator()(float& out, const float in1, const float in2) {
out *= in1 * in2;
}
};
struct opDividedBy {
__device__ void operator()(float& out, const float in) {
if (out > 0.000001f) // out is assumed to be positive
out = in / out;
else
out = 0.0f;
}
};
struct opInvert {
__device__ void operator()(float& out) {
if (out > 0.000001f) // out is assumed to be positive
out = 1 / out;
else
out = 0.0f;
}
};
struct opSet {
__device__ void operator()(float& out, const float inp) {
out = inp;
}
};
struct opClampMin {
__device__ void operator()(float& out, const float inp) {
if (out < inp)
out = inp;
}
};
struct opClampMax {
__device__ void operator()(float& out, const float inp) {
if (out > inp)
out = inp;
}
};
template
__global__ void devtoD(float* pfOut, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off]);
off += pitch;
y++;
}
}
template
__global__ void devFtoD(float* pfOut, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off], fParam);
off += pitch;
y++;
}
}
template
__global__ void devDtoD(float* pfOut, const float* pfIn, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off], pfIn[off]);
off += pitch;
y++;
}
}
template
__global__ void devDFtoD(float* pfOut, const float* pfIn, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off], pfIn[off], fParam);
off += pitch;
y++;
}
}
template
__global__ void devDDtoD(float* pfOut, const float* pfIn1, const float* pfIn2, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off], pfIn1[off], pfIn2[off]);
off += pitch;
y++;
}
}
template
__global__ void devDDFtoD(float* pfOut, const float* pfIn1, const float* pfIn2, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
unsigned int x = threadIdx.x + 16*blockIdx.x;
if (x >= width) return;
unsigned int y = (threadIdx.y + 16*blockIdx.y)*repeat;
unsigned int off = y*pitch+x;
for (unsigned int i = 0; i < repeat; ++i) {
if (y >= height)
break;
op()(pfOut[off], pfIn1[off], pfIn2[off], fParam);
off += pitch;
y++;
}
}
template
void processVol(CUdeviceptr* out, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+511)/512);
float *pfOut = (float*)out;
devtoD<<>>(pfOut, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol(CUdeviceptr* out, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+15)/16);
float *pfOut = (float*)out;
devFtoD<<>>(pfOut, fParam, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol(CUdeviceptr* out, const CUdeviceptr* in, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+15)/16);
float *pfOut = (float*)out;
const float *pfIn = (const float*)in;
devDtoD<<>>(pfOut, pfIn, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol(CUdeviceptr* out, const CUdeviceptr* in, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+15)/16);
float *pfOut = (float*)out;
const float *pfIn = (const float*)in;
devDFtoD<<>>(pfOut, pfIn, fParam, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol(CUdeviceptr* out, const CUdeviceptr* in1, const CUdeviceptr* in2, float fParam, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+15)/16);
float *pfOut = (float*)out;
const float *pfIn1 = (const float*)in1;
const float *pfIn2 = (const float*)in2;
devDDFtoD<<>>(pfOut, pfIn1, pfIn2, fParam, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol(CUdeviceptr* out, const CUdeviceptr* in1, const CUdeviceptr* in2, unsigned int pitch, unsigned int width, unsigned int height)
{
dim3 blockSize(16,16);
dim3 gridSize((width+15)/16, (height+15)/16);
float *pfOut = (float*)out;
const float *pfIn1 = (const float*)in1;
const float *pfIn2 = (const float*)in2;
devDDtoD<<>>(pfOut, pfIn1, pfIn2, pitch, width, height);
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devtoD<<>>(pfOut, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
}
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devFtoD<<>>(pfOut, fParam, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
}
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn = (float*)in.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devDtoD<<>>(pfOut, pfIn, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
pfIn += step;
}
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn = (float*)in.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devDFtoD<<>>(pfOut, pfIn, fParam, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
pfIn += step;
}
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn1 = (float*)in1.ptr;
float *pfIn2 = (float*)in2.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devDDFtoD<<>>(pfOut, pfIn1, pfIn2, fParam, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
pfIn1 += step;
pfIn2 += step;
}
cudaTextForceKernelsCompletion();
}
template
void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iVolX+15)/16, (dims.iVolY+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn1 = (float*)in1.ptr;
float *pfIn2 = (float*)in2.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iVolY;
for (unsigned int i = 0; i < dims.iVolZ; ++i) {
devDDtoD<<>>(pfOut, pfIn1, pfIn2, out.pitch/sizeof(float), dims.iVolX, dims.iVolY);
pfOut += step;
pfIn1 += step;
pfIn2 += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devtoD<<>>(pfOut, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devFtoD<<>>(pfOut, fParam, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn = (float*)in.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devDtoD<<>>(pfOut, pfIn, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
pfIn += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn = (float*)in.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devDFtoD<<>>(pfOut, pfIn, fParam, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
pfIn += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, float fParam, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn1 = (float*)in1.ptr;
float *pfIn2 = (float*)in2.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devDDFtoD<<>>(pfOut, pfIn1, pfIn2, fParam, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
pfIn1 += step;
pfIn2 += step;
}
cudaTextForceKernelsCompletion();
}
template
void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, const SDimensions3D& dims)
{
dim3 blockSize(16,16);
dim3 gridSize((dims.iProjU+15)/16, (dims.iProjAngles+511)/512);
float *pfOut = (float*)out.ptr;
float *pfIn1 = (float*)in1.ptr;
float *pfIn2 = (float*)in2.ptr;
unsigned int step = out.pitch/sizeof(float) * dims.iProjAngles;
for (unsigned int i = 0; i < dims.iProjV; ++i) {
devDDtoD<<>>(pfOut, pfIn1, pfIn2, out.pitch/sizeof(float), dims.iProjU, dims.iProjAngles);
pfOut += step;
pfIn1 += step;
pfIn2 += step;
}
cudaTextForceKernelsCompletion();
}
#define INST_DFtoD(name) \
template void processVol(CUdeviceptr* out, const CUdeviceptr* in, float fParam, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, float fParam, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, float fParam, const SDimensions3D& dims);
#define INST_DtoD(name) \
template void processVol(CUdeviceptr* out, const CUdeviceptr* in, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in, const SDimensions3D& dims);
#define INST_DDtoD(name) \
template void processVol(CUdeviceptr* out, const CUdeviceptr* in1, const CUdeviceptr* in2, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, const SDimensions3D& dims);
#define INST_DDFtoD(name) \
template void processVol(CUdeviceptr* out, const CUdeviceptr* in1, const CUdeviceptr* in2, float fParam, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, float fParam, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, const cudaPitchedPtr& in1, const cudaPitchedPtr& in2, float fParam, const SDimensions3D& dims);
#define INST_toD(name) \
template void processVol(CUdeviceptr* out, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, const SDimensions3D& dims);
#define INST_FtoD(name) \
template void processVol(CUdeviceptr* out, float fParam, unsigned int pitch, unsigned int width, unsigned int height); \
template void processVol3D(cudaPitchedPtr& out, float fParam, const SDimensions3D& dims); \
template void processSino3D(cudaPitchedPtr& out, float fParam, const SDimensions3D& dims);
INST_DFtoD(opAddScaled)
INST_DFtoD(opScaleAndAdd)
INST_DDFtoD(opAddMulScaled)
INST_DDtoD(opAddMul)
INST_DDtoD(opMul2)
INST_DtoD(opMul)
INST_DtoD(opAdd)
INST_DtoD(opDividedBy)
INST_toD(opInvert)
INST_FtoD(opMul)
INST_FtoD(opSet)
INST_FtoD(opClampMin)
INST_FtoD(opClampMax)
}