diff options
48 files changed, 841 insertions, 2532 deletions
diff --git a/build/linux/Makefile.in b/build/linux/Makefile.in index 209206e..f478bb7 100644 --- a/build/linux/Makefile.in +++ b/build/linux/Makefile.in @@ -257,8 +257,6 @@ endif TEST_OBJECTS=\ tests/main.o \ tests/test_AstraObjectManager.o \ - tests/test_ParallelBeamLineKernelProjector2D.o \ - tests/test_ParallelBeamLinearKernelProjector2D.o \ tests/test_Float32Data2D.o \ tests/test_VolumeGeometry2D.o \ tests/test_ParallelProjectionGeometry2D.o \ diff --git a/build/linux/acinclude.m4 b/build/linux/acinclude.m4 index 92f263a..4d278c7 100644 --- a/build/linux/acinclude.m4 +++ b/build/linux/acinclude.m4 @@ -166,3 +166,20 @@ fi rm -f conftest.cu conftest.o conftest.nvcc.out ]) +dnl ASTRA_CHECK_CUDA_BOOST(action-if-ok, action-if-not-ok) +dnl Check for a specific incompatibility between boost and cuda version +dnl (See https://github.com/boostorg/config/pull/175 ) +AC_DEFUN([ASTRA_CHECK_CUDA_BOOST],[ +cat >conftest.cu <<_ACEOF +#include <boost/shared_ptr.hpp> +int main() { + return 0; +} +_ACEOF +ASTRA_RUN_LOGOUTPUT([$NVCC -c -o conftest.o conftest.cu $NVCCFLAGS]) +AS_IF([test $? = 0],[$1],[ + AS_ECHO(["$as_me: failed program was:"]) >&AS_MESSAGE_LOG_FD + sed 's/^/| /' conftest.cu >&AS_MESSAGE_LOG_FD + $2]) +]) + diff --git a/build/linux/configure.ac b/build/linux/configure.ac index 0a9024e..bb4d113 100644 --- a/build/linux/configure.ac +++ b/build/linux/configure.ac @@ -122,6 +122,14 @@ if test x"$HAVECUDA" = xyes; then AC_MSG_RESULT($HAVECUDA) fi +if test x"$HAVECUDA" = xyes; then + AC_MSG_CHECKING([if boost and CUDA versions are compatible]) + ASTRA_CHECK_CUDA_BOOST(AC_MSG_RESULT([yes]),[ + AC_MSG_RESULT([no]) + AC_MSG_ERROR([Boost and CUDA versions are incompatible. You probably have to upgrade boost.]) + ]) +fi + AC_ARG_WITH(cuda_compute, [[ --with-cuda-compute=archs comma separated list of CUDA compute models (optional)]],,) if test x"$HAVECUDA" = xyes; then AC_MSG_CHECKING([for nvcc archs]) diff --git a/cuda/2d/algo.cu b/cuda/2d/algo.cu index b4c2864..be15b25 100644 --- a/cuda/2d/algo.cu +++ b/cuda/2d/algo.cu @@ -134,8 +134,8 @@ bool ReconAlgo::setGeometry(const astra::CVolumeGeometry2D* pVolGeom, delete[] fanProjs; fanProjs = 0; - fOutputScale = 1.0f; - ok = convertAstraGeometry(pVolGeom, pProjGeom, parProjs, fanProjs, fOutputScale); + fProjectorScale = 1.0f; + ok = convertAstraGeometry(pVolGeom, pProjGeom, parProjs, fanProjs, fProjectorScale); if (!ok) return false; @@ -242,7 +242,7 @@ bool ReconAlgo::allocateBuffers() return true; } -bool ReconAlgo::copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, float fSinogramScale, +bool ReconAlgo::copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, const float* pfReconstruction, unsigned int iReconstructionPitch, const float* pfVolMask, unsigned int iVolMaskPitch, const float* pfSinoMask, unsigned int iSinoMaskPitch) @@ -258,11 +258,6 @@ bool ReconAlgo::copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPit if (!ok) return false; - // rescale sinogram to adjust for pixel size - processSino<opMul>(D_sinoData, fSinogramScale, - //1.0f/(fPixelSize*fPixelSize), - sinoPitch, dims); - ok = copyVolumeToDevice(pfReconstruction, iReconstructionPitch, dims, D_volumeData, volumePitch); @@ -316,11 +311,11 @@ bool ReconAlgo::callFP(float* D_volumeData, unsigned int volumePitch, if (parProjs) { assert(!fanProjs); return FP(D_volumeData, volumePitch, D_projData, projPitch, - dims, parProjs, fOutputScale * outputScale); + dims, parProjs, fProjectorScale * outputScale); } else { assert(fanProjs); return FanFP(D_volumeData, volumePitch, D_projData, projPitch, - dims, fanProjs, fOutputScale * outputScale); + dims, fanProjs, fProjectorScale * outputScale); } } @@ -331,11 +326,11 @@ bool ReconAlgo::callBP(float* D_volumeData, unsigned int volumePitch, if (parProjs) { assert(!fanProjs); return BP(D_volumeData, volumePitch, D_projData, projPitch, - dims, parProjs, outputScale); + dims, parProjs, fProjectorScale * outputScale); } else { assert(fanProjs); return FanBP(D_volumeData, volumePitch, D_projData, projPitch, - dims, fanProjs, outputScale); + dims, fanProjs, fProjectorScale * outputScale); } } diff --git a/cuda/2d/astra.cu b/cuda/2d/astra.cu index ec03517..7ff1c95 100644 --- a/cuda/2d/astra.cu +++ b/cuda/2d/astra.cu @@ -302,7 +302,8 @@ static bool convertAstraGeometry_internal(const CVolumeGeometry2D* pVolGeom, pProjs[i].scale(factor); } // CHECKME: Check factor - fOutputScale *= pVolGeom->getPixelLengthX() * pVolGeom->getPixelLengthY(); + // NB: Only valid for square pixels + fOutputScale *= pVolGeom->getPixelLengthX(); return true; } diff --git a/cuda/2d/cgls.cu b/cuda/2d/cgls.cu index b6a9fae..e7238b9 100644 --- a/cuda/2d/cgls.cu +++ b/cuda/2d/cgls.cu @@ -29,10 +29,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> @@ -102,14 +98,14 @@ bool CGLS::setBuffers(float* _D_volumeData, unsigned int _volumePitch, return true; } -bool CGLS::copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, float fSinogramScale, +bool CGLS::copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, const float* pfReconstruction, unsigned int iReconstructionPitch, const float* pfVolMask, unsigned int iVolMaskPitch, const float* pfSinoMask, unsigned int iSinoMaskPitch) { sliceInitialized = false; - return ReconAlgo::copyDataToGPU(pfSinogram, iSinogramPitch, fSinogramScale, pfReconstruction, iReconstructionPitch, pfVolMask, iVolMaskPitch, pfSinoMask, iSinoMaskPitch); + return ReconAlgo::copyDataToGPU(pfSinogram, iSinogramPitch, pfReconstruction, iReconstructionPitch, pfVolMask, iVolMaskPitch, pfSinoMask, iSinoMaskPitch); } bool CGLS::iterate(unsigned int iterations) @@ -206,60 +202,3 @@ float CGLS::computeDiffNorm() } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_sinoData; - - SDimensions dims; - dims.iVolWidth = 1024; - dims.iVolHeight = 1024; - dims.iProjAngles = 512; - dims.iProjDets = 1536; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, sinoPitch; - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - zeroVolume(D_volumeData, volumePitch, dims.iVolWidth, dims.iVolHeight); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_sinoData, dims.iProjDets, dims.iProjAngles, sinoPitch); - zeroVolume(D_sinoData, sinoPitch, dims.iProjDets, dims.iProjAngles); - printf("pitch: %u\n", sinoPitch); - - unsigned int y, x; - float* sino = loadImage("sino.png", y, x); - - float* img = new float[dims.iVolWidth*dims.iVolHeight]; - - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_sinoData, sinoPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - CGLS cgls; - - cgls.setGeometry(dims, angle); - cgls.init(); - - cgls.setBuffers(D_volumeData, volumePitch, D_sinoData, sinoPitch); - - cgls.iterate(25); - - delete[] angle; - - copyVolumeFromDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - - saveImage("vol.png",dims.iVolHeight,dims.iVolWidth,img); - - return 0; -} -#endif diff --git a/cuda/2d/em.cu b/cuda/2d/em.cu index aa272d8..df140ec 100644 --- a/cuda/2d/em.cu +++ b/cuda/2d/em.cu @@ -29,10 +29,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> @@ -168,64 +164,3 @@ float EM::computeDiffNorm() } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_sinoData; - - SDimensions dims; - dims.iVolWidth = 1024; - dims.iVolHeight = 1024; - dims.iProjAngles = 512; - dims.iProjDets = 1536; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, sinoPitch; - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - zeroVolume(D_volumeData, volumePitch, dims.iVolWidth, dims.iVolHeight); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_sinoData, dims.iProjDets, dims.iProjAngles, sinoPitch); - zeroVolume(D_sinoData, sinoPitch, dims.iProjDets, dims.iProjAngles); - printf("pitch: %u\n", sinoPitch); - - unsigned int y, x; - float* sino = loadImage("sino.png", y, x); - - float* img = new float[dims.iVolWidth*dims.iVolHeight]; - - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_sinoData, sinoPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - EM em; - - em.setGeometry(dims, angle); - em.init(); - - // TODO: Initialize D_volumeData with an unfiltered backprojection - - em.setBuffers(D_volumeData, volumePitch, D_sinoData, sinoPitch); - - em.iterate(25); - - - delete[] angle; - - copyVolumeFromDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - - saveImage("vol.png",dims.iVolHeight,dims.iVolWidth,img); - - return 0; -} - -#endif diff --git a/cuda/2d/fan_bp.cu b/cuda/2d/fan_bp.cu index dac3ac2..76d2fb9 100644 --- a/cuda/2d/fan_bp.cu +++ b/cuda/2d/fan_bp.cu @@ -28,10 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -50,12 +46,16 @@ const unsigned int g_blockSlices = 16; const unsigned int g_MaxAngles = 2560; -__constant__ float gC_SrcX[g_MaxAngles]; -__constant__ float gC_SrcY[g_MaxAngles]; -__constant__ float gC_DetSX[g_MaxAngles]; -__constant__ float gC_DetSY[g_MaxAngles]; -__constant__ float gC_DetUX[g_MaxAngles]; -__constant__ float gC_DetUY[g_MaxAngles]; +struct DevFanParams { + float fNumC; + float fNumX; + float fNumY; + float fDenC; + float fDenX; + float fDenY; +}; + +__constant__ DevFanParams gC_C[g_MaxAngles]; static bool bindProjDataTexture(float* data, unsigned int pitch, unsigned int width, unsigned int height, cudaTextureAddressMode mode = cudaAddressModeBorder) @@ -74,6 +74,7 @@ static bool bindProjDataTexture(float* data, unsigned int pitch, unsigned int wi return true; } +template<bool FBPWEIGHT> __global__ void devFanBP(float* D_volData, unsigned int volPitch, unsigned int startAngle, const SDimensions dims, float fOutputScale) { const int relX = threadIdx.x; @@ -96,25 +97,25 @@ __global__ void devFanBP(float* D_volData, unsigned int volPitch, unsigned int s float fVal = 0.0f; float fA = startAngle + 0.5f; - // TODO: Distance correction? - for (int angle = startAngle; angle < endAngle; ++angle) { - const float fSrcX = gC_SrcX[angle]; - const float fSrcY = gC_SrcY[angle]; - const float fDetSX = gC_DetSX[angle]; - const float fDetSY = gC_DetSY[angle]; - const float fDetUX = gC_DetUX[angle]; - const float fDetUY = gC_DetUY[angle]; - - const float fXD = fSrcX - fX; - const float fYD = fSrcY - fY; - - const float fNum = fDetSY * fXD - fDetSX * fYD + fX*fSrcY - fY*fSrcX; - const float fDen = fDetUX * fYD - fDetUY * fXD; - - const float fT = fNum / fDen; - fVal += tex2D(gT_FanProjTexture, fT, fA); + const float fNumC = gC_C[angle].fNumC; + const float fNumX = gC_C[angle].fNumX; + const float fNumY = gC_C[angle].fNumY; + const float fDenX = gC_C[angle].fDenX; + const float fDenY = gC_C[angle].fDenY; + + const float fNum = fNumC + fNumX * fX + fNumY * fY; + const float fDen = (FBPWEIGHT ? 1.0 : gC_C[angle].fDenC) + fDenX * fX + fDenY * fY; + + // Scale factor is the approximate number of rays traversing this pixel, + // given by the inverse size of a detector pixel scaled by the magnification + // factor of this pixel. + // Magnification factor is || u (d-s) || / || u (x-s) || + + const float fr = __fdividef(1.0f, fDen); + const float fT = fNum * fr; + fVal += tex2D(gT_FanProjTexture, fT, fA) * (FBPWEIGHT ? fr * fr : fr); fA += 1.0f; } @@ -148,30 +149,27 @@ __global__ void devFanBP_SS(float* D_volData, unsigned int volPitch, unsigned in float fVal = 0.0f; float fA = startAngle + 0.5f; - // TODO: Distance correction? - for (int angle = startAngle; angle < endAngle; ++angle) { - const float fSrcX = gC_SrcX[angle]; - const float fSrcY = gC_SrcY[angle]; - const float fDetSX = gC_DetSX[angle]; - const float fDetSY = gC_DetSY[angle]; - const float fDetUX = gC_DetUX[angle]; - const float fDetUY = gC_DetUY[angle]; + const float fNumC = gC_C[angle].fNumC; + const float fNumX = gC_C[angle].fNumX; + const float fNumY = gC_C[angle].fNumY; + const float fDenC = gC_C[angle].fDenC; + const float fDenX = gC_C[angle].fDenX; + const float fDenY = gC_C[angle].fDenY; // TODO: Optimize these loops... float fX = fXb; for (int iSubX = 0; iSubX < dims.iRaysPerPixelDim; ++iSubX) { float fY = fYb; for (int iSubY = 0; iSubY < dims.iRaysPerPixelDim; ++iSubY) { - const float fXD = fSrcX - fX; - const float fYD = fSrcY - fY; - - const float fNum = fDetSY * fXD - fDetSX * fYD + fX*fSrcY - fY*fSrcX; - const float fDen = fDetUX * fYD - fDetUY * fXD; - - const float fT = fNum / fDen; - fVal += tex2D(gT_FanProjTexture, fT, fA); + + const float fNum = fNumC + fNumX * fX + fNumY * fY; + const float fDen = fDenC + fDenX * fX + fDenY * fY; + const float fr = __fdividef(1.0f, fDen); + + const float fT = fNum * fr; + fVal += tex2D(gT_FanProjTexture, fT, fA) * fr; fY -= fSubStep; } fX += fSubStep; @@ -202,77 +200,97 @@ __global__ void devFanBP_SART(float* D_volData, unsigned int volPitch, const SDi float* volData = (float*)D_volData; - // TODO: Distance correction? - - // TODO: Constant memory vs parameters. - const float fSrcX = gC_SrcX[0]; - const float fSrcY = gC_SrcY[0]; - const float fDetSX = gC_DetSX[0]; - const float fDetSY = gC_DetSY[0]; - const float fDetUX = gC_DetUX[0]; - const float fDetUY = gC_DetUY[0]; + const float fNumC = gC_C[0].fNumC; + const float fNumX = gC_C[0].fNumX; + const float fNumY = gC_C[0].fNumY; + const float fDenC = gC_C[0].fDenC; + const float fDenX = gC_C[0].fDenX; + const float fDenY = gC_C[0].fDenY; - const float fXD = fSrcX - fX; - const float fYD = fSrcY - fY; + const float fNum = fNumC + fNumX * fX + fNumY * fY; + const float fDen = fDenC + fDenX * fX + fDenY * fY; - const float fNum = fDetSY * fXD - fDetSX * fYD + fX*fSrcY - fY*fSrcX; - const float fDen = fDetUX * fYD - fDetUY * fXD; - - const float fT = fNum / fDen; + const float fr = __fdividef(1.0f, fDen); + const float fT = fNum * fr; + // NB: The scale constant in devBP is cancelled out by the SART weighting const float fVal = tex2D(gT_FanProjTexture, fT, 0.5f); volData[Y*volPitch+X] += fVal * fOutputScale; } -// Weighted BP for use in fan beam FBP -// Each pixel/ray is weighted by 1/L^2 where L is the distance to the source. -__global__ void devFanBP_FBPWeighted(float* D_volData, unsigned int volPitch, unsigned int startAngle, const SDimensions dims, float fOutputScale) +struct Vec2 { + double x; + double y; + Vec2(double x_, double y_) : x(x_), y(y_) { } + Vec2 operator+(const Vec2 &b) const { + return Vec2(x + b.x, y + b.y); + } + Vec2 operator-(const Vec2 &b) const { + return Vec2(x - b.x, y - b.y); + } + Vec2 operator-() const { + return Vec2(-x, -y); + } + double norm() const { + return sqrt(x*x + y*y); + } +}; + +double det2(const Vec2 &a, const Vec2 &b) { + return a.x * b.y - a.y * b.x; +} + + +bool transferConstants(const SFanProjection* angles, unsigned int iProjAngles, bool FBP) { - const int relX = threadIdx.x; - const int relY = threadIdx.y; + DevFanParams *p = new DevFanParams[iProjAngles]; - int endAngle = startAngle + g_anglesPerBlock; - if (endAngle > dims.iProjAngles) - endAngle = dims.iProjAngles; - const int X = blockIdx.x * g_blockSlices + relX; - const int Y = blockIdx.y * g_blockSliceSize + relY; + // We need three values in the kernel: + // projected coordinates of pixels on the detector: + // || x (s-d) || + ||s d|| / || u (s-x) || - if (X >= dims.iVolWidth || Y >= dims.iVolHeight) - return; + // ray density weighting factor for the adjoint + // || u (s-d) || / ( |u| * || u (s-x) || ) - const float fX = ( X - 0.5f*dims.iVolWidth + 0.5f ); - const float fY = - ( Y - 0.5f*dims.iVolHeight + 0.5f ); + // fan-beam FBP weighting factor + // ( || u s || / || u (s-x) || ) ^ 2 - float* volData = (float*)D_volData; - float fVal = 0.0f; - float fA = startAngle + 0.5f; - // TODO: Distance correction? + for (unsigned int i = 0; i < iProjAngles; ++i) { + Vec2 u(angles[i].fDetUX, angles[i].fDetUY); + Vec2 s(angles[i].fSrcX, angles[i].fSrcY); + Vec2 d(angles[i].fDetSX, angles[i].fDetSY); - for (int angle = startAngle; angle < endAngle; ++angle) - { - const float fSrcX = gC_SrcX[angle]; - const float fSrcY = gC_SrcY[angle]; - const float fDetSX = gC_DetSX[angle]; - const float fDetSY = gC_DetSY[angle]; - const float fDetUX = gC_DetUX[angle]; - const float fDetUY = gC_DetUY[angle]; - - const float fXD = fSrcX - fX; - const float fYD = fSrcY - fY; - - const float fNum = fDetSY * fXD - fDetSX * fYD + fX*fSrcY - fY*fSrcX; - const float fDen = fDetUX * fYD - fDetUY * fXD; - - const float fWeight = fXD*fXD + fYD*fYD; - - const float fT = fNum / fDen; - fVal += tex2D(gT_FanProjTexture, fT, fA) / fWeight; - fA += 1.0f; + + + double fScale; + if (!FBP) { + // goal: 1/fDen = || u (s-d) || / ( |u| * || u (s-x) || ) + // fDen = ( |u| * || u (s-x) || ) / || u (s-d) || + // i.e. scale = |u| / || u (s-d) || + + fScale = u.norm() / det2(u, s-d); + } else { + // goal: 1/fDen = || u s || / || u (s-x) || + // fDen = || u (s-x) || / || u s || + // i.e., scale = 1 / || u s || + + fScale = 1.0 / det2(u, s); + } + + p[i].fNumC = fScale * det2(s,d); + p[i].fNumX = fScale * (s-d).y; + p[i].fNumY = -fScale * (s-d).x; + p[i].fDenC = fScale * det2(u, s); // == 1.0 for FBP + p[i].fDenX = fScale * u.y; + p[i].fDenY = -fScale * u.x; } - volData[Y*volPitch+X] += fVal * fOutputScale; + // TODO: Check for errors + cudaMemcpyToSymbol(gC_C, p, iProjAngles*sizeof(DevFanParams), 0, cudaMemcpyHostToDevice); + + return true; } @@ -285,21 +303,9 @@ bool FanBP_internal(float* D_volumeData, unsigned int volumePitch, bindProjDataTexture(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); - // transfer angles to constant memory - float* tmp = new float[dims.iProjAngles]; - -#define TRANSFER_TO_CONSTANT(name) do { for (unsigned int i = 0; i < dims.iProjAngles; ++i) tmp[i] = angles[i].f##name ; cudaMemcpyToSymbol(gC_##name, tmp, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); } while (0) - - TRANSFER_TO_CONSTANT(SrcX); - TRANSFER_TO_CONSTANT(SrcY); - TRANSFER_TO_CONSTANT(DetSX); - TRANSFER_TO_CONSTANT(DetSY); - TRANSFER_TO_CONSTANT(DetUX); - TRANSFER_TO_CONSTANT(DetUY); - -#undef TRANSFER_TO_CONSTANT - - delete[] tmp; + bool ok = transferConstants(angles, dims.iProjAngles, false); + if (!ok) + return false; dim3 dimBlock(g_blockSlices, g_blockSliceSize); dim3 dimGrid((dims.iVolWidth+g_blockSlices-1)/g_blockSlices, @@ -312,7 +318,7 @@ bool FanBP_internal(float* D_volumeData, unsigned int volumePitch, if (dims.iRaysPerPixelDim > 1) devFanBP_SS<<<dimGrid, dimBlock, 0, stream>>>(D_volumeData, volumePitch, i, dims, fOutputScale); else - devFanBP<<<dimGrid, dimBlock, 0, stream>>>(D_volumeData, volumePitch, i, dims, fOutputScale); + devFanBP<false><<<dimGrid, dimBlock, 0, stream>>>(D_volumeData, volumePitch, i, dims, fOutputScale); } cudaThreadSynchronize(); @@ -332,21 +338,9 @@ bool FanBP_FBPWeighted_internal(float* D_volumeData, unsigned int volumePitch, bindProjDataTexture(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); - // transfer angles to constant memory - float* tmp = new float[dims.iProjAngles]; - -#define TRANSFER_TO_CONSTANT(name) do { for (unsigned int i = 0; i < dims.iProjAngles; ++i) tmp[i] = angles[i].f##name ; cudaMemcpyToSymbol(gC_##name, tmp, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); } while (0) - - TRANSFER_TO_CONSTANT(SrcX); - TRANSFER_TO_CONSTANT(SrcY); - TRANSFER_TO_CONSTANT(DetSX); - TRANSFER_TO_CONSTANT(DetSY); - TRANSFER_TO_CONSTANT(DetUX); - TRANSFER_TO_CONSTANT(DetUY); - -#undef TRANSFER_TO_CONSTANT - - delete[] tmp; + bool ok = transferConstants(angles, dims.iProjAngles, true); + if (!ok) + return false; dim3 dimBlock(g_blockSlices, g_blockSliceSize); dim3 dimGrid((dims.iVolWidth+g_blockSlices-1)/g_blockSlices, @@ -356,7 +350,7 @@ bool FanBP_FBPWeighted_internal(float* D_volumeData, unsigned int volumePitch, cudaStreamCreate(&stream); for (unsigned int i = 0; i < dims.iProjAngles; i += g_anglesPerBlock) { - devFanBP_FBPWeighted<<<dimGrid, dimBlock, 0, stream>>>(D_volumeData, volumePitch, i, dims, fOutputScale); + devFanBP<true><<<dimGrid, dimBlock, 0, stream>>>(D_volumeData, volumePitch, i, dims, fOutputScale); } cudaThreadSynchronize(); @@ -377,17 +371,9 @@ bool FanBP_SART(float* D_volumeData, unsigned int volumePitch, // only one angle bindProjDataTexture(D_projData, projPitch, dims.iProjDets, 1, cudaAddressModeClamp); - // transfer angle to constant memory -#define TRANSFER_TO_CONSTANT(name) do { cudaMemcpyToSymbol(gC_##name, &(angles[angle].f##name), sizeof(float), 0, cudaMemcpyHostToDevice); } while (0) - - TRANSFER_TO_CONSTANT(SrcX); - TRANSFER_TO_CONSTANT(SrcY); - TRANSFER_TO_CONSTANT(DetSX); - TRANSFER_TO_CONSTANT(DetSY); - TRANSFER_TO_CONSTANT(DetUX); - TRANSFER_TO_CONSTANT(DetUY); - -#undef TRANSFER_TO_CONSTANT + bool ok = transferConstants(angles + angle, 1, false); + if (!ok) + return false; dim3 dimBlock(g_blockSlices, g_blockSliceSize); dim3 dimGrid((dims.iVolWidth+g_blockSlices-1)/g_blockSlices, @@ -448,66 +434,3 @@ bool FanBP_FBPWeighted(float* D_volumeData, unsigned int volumePitch, } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_projData; - - SDimensions dims; - dims.iVolWidth = 128; - dims.iVolHeight = 128; - dims.iProjAngles = 180; - dims.iProjDets = 256; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, projPitch; - - SFanProjection projs[180]; - - projs[0].fSrcX = 0.0f; - projs[0].fSrcY = 1536.0f; - projs[0].fDetSX = 128.0f; - projs[0].fDetSY = -512.0f; - projs[0].fDetUX = -1.0f; - projs[0].fDetUY = 0.0f; - -#define ROTATE0(name,i,alpha) do { projs[i].f##name##X = projs[0].f##name##X * cos(alpha) - projs[0].f##name##Y * sin(alpha); projs[i].f##name##Y = projs[0].f##name##X * sin(alpha) + projs[0].f##name##Y * cos(alpha); } while(0) - - for (int i = 1; i < 180; ++i) { - ROTATE0(Src, i, i*2*M_PI/180); - ROTATE0(DetS, i, i*2*M_PI/180); - ROTATE0(DetU, i, i*2*M_PI/180); - } - -#undef ROTATE0 - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_projData, dims.iProjDets, dims.iProjAngles, projPitch); - printf("pitch: %u\n", projPitch); - - unsigned int y, x; - float* sino = loadImage("sino.png", y, x); - - float* img = new float[dims.iVolWidth*dims.iVolHeight]; - - memset(img, 0, dims.iVolWidth*dims.iVolHeight*sizeof(float)); - - copyVolumeToDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - FanBP(D_volumeData, volumePitch, D_projData, projPitch, dims, projs, 1.0f); - - copyVolumeFromDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - - saveImage("vol.png",dims.iVolHeight,dims.iVolWidth,img); - - return 0; -} -#endif diff --git a/cuda/2d/fan_fp.cu b/cuda/2d/fan_fp.cu index 3479650..60c02f8 100644 --- a/cuda/2d/fan_fp.cu +++ b/cuda/2d/fan_fp.cu @@ -28,10 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -308,84 +304,3 @@ bool FanFP(float* D_volumeData, unsigned int volumePitch, } } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_projData; - - SDimensions dims; - dims.iVolWidth = 128; - dims.iVolHeight = 128; - dims.iProjAngles = 180; - dims.iProjDets = 256; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, projPitch; - - SFanProjection projs[180]; - - projs[0].fSrcX = 0.0f; - projs[0].fSrcY = 1536.0f; - projs[0].fDetSX = 128.0f; - projs[0].fDetSY = -512.0f; - projs[0].fDetUX = -1.0f; - projs[0].fDetUY = 0.0f; - -#define ROTATE0(name,i,alpha) do { projs[i].f##name##X = projs[0].f##name##X * cos(alpha) - projs[0].f##name##Y * sin(alpha); projs[i].f##name##Y = projs[0].f##name##X * sin(alpha) + projs[0].f##name##Y * cos(alpha); } while(0) - - for (int i = 1; i < 180; ++i) { - ROTATE0(Src, i, i*2*M_PI/180); - ROTATE0(DetS, i, i*2*M_PI/180); - ROTATE0(DetU, i, i*2*M_PI/180); - } - -#undef ROTATE0 - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_projData, dims.iProjDets, dims.iProjAngles, projPitch); - printf("pitch: %u\n", projPitch); - - unsigned int y, x; - float* img = loadImage("phantom128.png", y, x); - - float* sino = new float[dims.iProjAngles * dims.iProjDets]; - - memset(sino, 0, dims.iProjAngles * dims.iProjDets * sizeof(float)); - - copyVolumeToDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - FanFP(D_volumeData, volumePitch, D_projData, projPitch, dims, projs, 1.0f); - - delete[] angle; - - copySinogramFromDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - float s = 0.0f; - for (unsigned int y = 0; y < dims.iProjAngles; ++y) - for (unsigned int x = 0; x < dims.iProjDets; ++x) - s += sino[y*dims.iProjDets+x] * sino[y*dims.iProjDets+x]; - printf("cpu norm: %f\n", s); - - //zeroVolume(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); - s = dotProduct2D(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); - printf("gpu norm: %f\n", s); - - saveImage("sino.png",dims.iProjAngles,dims.iProjDets,sino); - - - return 0; -} -#endif diff --git a/cuda/2d/fbp.cu b/cuda/2d/fbp.cu index a5b8a7a..4fc3983 100644 --- a/cuda/2d/fbp.cu +++ b/cuda/2d/fbp.cu @@ -58,7 +58,8 @@ int FBP::calcFourierFilterSize(int _iDetectorCount) FBP::FBP() : ReconAlgo() { D_filter = 0; - + m_bShortScan = false; + fReconstructionScale = 1.0f; } FBP::~FBP() @@ -72,6 +73,8 @@ void FBP::reset() freeComplexOnDevice((cufftComplex *)D_filter); D_filter = 0; } + m_bShortScan = false; + fReconstructionScale = 1.0f; } bool FBP::init() @@ -79,6 +82,12 @@ bool FBP::init() return true; } +bool FBP::setReconstructionScale(float fScale) +{ + fReconstructionScale = fScale; + return true; +} + bool FBP::setFilter(const astra::SFilterConfig &_cfg) { if (D_filter) @@ -292,7 +301,7 @@ bool FBP::iterate(unsigned int iterations) astraCUDA3d::FDK_PreWeight(tmp, fOriginSource, fOriginDetector, 0.0f, - fFanDetSize, 1.0f, /* fPixelSize */ 1.0f, + fFanDetSize, 1.0f, m_bShortScan, dims3d, pfAngles); } else { // TODO: How should different detector pixel size in different @@ -319,17 +328,14 @@ bool FBP::iterate(unsigned int iterations) } if (fanProjs) { - float fOutputScale = 1.0 / (/*fPixelSize * fPixelSize * fPixelSize * */ fFanDetSize * fFanDetSize); - - ok = FanBP_FBPWeighted(D_volumeData, volumePitch, D_sinoData, sinoPitch, dims, fanProjs, fOutputScale); + ok = FanBP_FBPWeighted(D_volumeData, volumePitch, D_sinoData, sinoPitch, dims, fanProjs, fProjectorScale * fReconstructionScale); } else { // scale by number of angles. For the fan-beam case, this is already // handled by FDK_PreWeight float fOutputScale = (M_PI / 2.0f) / (float)dims.iProjAngles; - //fOutputScale /= fDetSize * fDetSize; - ok = BP(D_volumeData, volumePitch, D_sinoData, sinoPitch, dims, parProjs, fOutputScale); + ok = BP(D_volumeData, volumePitch, D_sinoData, sinoPitch, dims, parProjs, fOutputScale * fProjectorScale * fReconstructionScale); } if(!ok) { diff --git a/cuda/2d/fft.cu b/cuda/2d/fft.cu index 2e94b79..8361ad2 100644 --- a/cuda/2d/fft.cu +++ b/cuda/2d/fft.cu @@ -314,210 +314,3 @@ void genCuFFTFilter(const SFilterConfig &_cfg, int _iProjectionCount, } - - -#ifdef STANDALONE - -__global__ static void doubleFourierOutput_kernel(int _iProjectionCount, - int _iDetectorCount, - cufftComplex* _pFourierOutput) -{ - int iIndex = threadIdx.x + blockIdx.x * blockDim.x; - int iProjectionIndex = iIndex / _iDetectorCount; - int iDetectorIndex = iIndex % _iDetectorCount; - - if(iProjectionIndex >= _iProjectionCount) - { - return; - } - - if(iDetectorIndex <= (_iDetectorCount / 2)) - { - return; - } - - int iOtherDetectorIndex = _iDetectorCount - iDetectorIndex; - - _pFourierOutput[iProjectionIndex * _iDetectorCount + iDetectorIndex].x = _pFourierOutput[iProjectionIndex * _iDetectorCount + iOtherDetectorIndex].x; - _pFourierOutput[iProjectionIndex * _iDetectorCount + iDetectorIndex].y = -_pFourierOutput[iProjectionIndex * _iDetectorCount + iOtherDetectorIndex].y; -} - -static void doubleFourierOutput(int _iProjectionCount, int _iDetectorCount, - cufftComplex * _pFourierOutput) -{ - const int iBlockSize = 256; - int iElementCount = _iProjectionCount * _iDetectorCount; - int iBlockCount = (iElementCount + iBlockSize - 1) / iBlockSize; - - doubleFourierOutput_kernel<<< iBlockCount, iBlockSize >>>(_iProjectionCount, - _iDetectorCount, - _pFourierOutput); - CHECK_ERROR("doubleFourierOutput_kernel failed"); -} - - - -static void writeToMatlabFile(const char * _fileName, const float * _pfData, - int _iRowCount, int _iColumnCount) -{ - std::ofstream out(_fileName); - - for(int iRowIndex = 0; iRowIndex < _iRowCount; iRowIndex++) - { - for(int iColumnIndex = 0; iColumnIndex < _iColumnCount; iColumnIndex++) - { - out << _pfData[iColumnIndex + iRowIndex * _iColumnCount] << " "; - } - - out << std::endl; - } -} - -static void convertComplexToRealImg(const cufftComplex * _pComplex, - int _iElementCount, - float * _pfReal, float * _pfImaginary) -{ - for(int iIndex = 0; iIndex < _iElementCount; iIndex++) - { - _pfReal[iIndex] = _pComplex[iIndex].x; - _pfImaginary[iIndex] = _pComplex[iIndex].y; - } -} - -void testCudaFFT() -{ - const int iProjectionCount = 2; - const int iDetectorCount = 1024; - const int iTotalElementCount = iProjectionCount * iDetectorCount; - - float * pfHostProj = new float[iTotalElementCount]; - memset(pfHostProj, 0, sizeof(float) * iTotalElementCount); - - for(int iProjectionIndex = 0; iProjectionIndex < iProjectionCount; iProjectionIndex++) - { - for(int iDetectorIndex = 0; iDetectorIndex < iDetectorCount; iDetectorIndex++) - { -// int - -// pfHostProj[iIndex] = (float)rand() / (float)RAND_MAX; - } - } - - writeToMatlabFile("proj.mat", pfHostProj, iProjectionCount, iDetectorCount); - - float * pfDevProj = NULL; - SAFE_CALL(cudaMalloc((void **)&pfDevProj, sizeof(float) * iTotalElementCount)); - SAFE_CALL(cudaMemcpy(pfDevProj, pfHostProj, sizeof(float) * iTotalElementCount, cudaMemcpyHostToDevice)); - - cufftComplex * pDevFourProj = NULL; - SAFE_CALL(cudaMalloc((void **)&pDevFourProj, sizeof(cufftComplex) * iTotalElementCount)); - - cufftHandle plan; - cufftResult result; - - result = cufftPlan1d(&plan, iDetectorCount, CUFFT_R2C, iProjectionCount); - if(result != CUFFT_SUCCESS) - { - ASTRA_ERROR("Failed to plan 1d r2c fft"); - } - - result = cufftExecR2C(plan, pfDevProj, pDevFourProj); - if(result != CUFFT_SUCCESS) - { - ASTRA_ERROR("Failed to exec 1d r2c fft"); - } - - cufftDestroy(plan); - - doubleFourierOutput(iProjectionCount, iDetectorCount, pDevFourProj); - - cufftComplex * pHostFourProj = new cufftComplex[iTotalElementCount]; - SAFE_CALL(cudaMemcpy(pHostFourProj, pDevFourProj, sizeof(cufftComplex) * iTotalElementCount, cudaMemcpyDeviceToHost)); - - float * pfHostFourProjReal = new float[iTotalElementCount]; - float * pfHostFourProjImaginary = new float[iTotalElementCount]; - - convertComplexToRealImg(pHostFourProj, iTotalElementCount, pfHostFourProjReal, pfHostFourProjImaginary); - - writeToMatlabFile("proj_four_real.mat", pfHostFourProjReal, iProjectionCount, iDetectorCount); - writeToMatlabFile("proj_four_imaginary.mat", pfHostFourProjImaginary, iProjectionCount, iDetectorCount); - - float * pfDevInFourProj = NULL; - SAFE_CALL(cudaMalloc((void **)&pfDevInFourProj, sizeof(float) * iTotalElementCount)); - - result = cufftPlan1d(&plan, iDetectorCount, CUFFT_C2R, iProjectionCount); - if(result != CUFFT_SUCCESS) - { - ASTRA_ERROR("Failed to plan 1d c2r fft"); - } - - result = cufftExecC2R(plan, pDevFourProj, pfDevInFourProj); - if(result != CUFFT_SUCCESS) - { - ASTRA_ERROR("Failed to exec 1d c2r fft"); - } - - cufftDestroy(plan); - - rescaleInverseFourier(iProjectionCount, iDetectorCount, pfDevInFourProj); - - float * pfHostInFourProj = new float[iTotalElementCount]; - SAFE_CALL(cudaMemcpy(pfHostInFourProj, pfDevInFourProj, sizeof(float) * iTotalElementCount, cudaMemcpyDeviceToHost)); - - writeToMatlabFile("in_four.mat", pfHostInFourProj, iProjectionCount, iDetectorCount); - - SAFE_CALL(cudaFree(pDevFourProj)); - SAFE_CALL(cudaFree(pfDevProj)); - - delete [] pfHostInFourProj; - delete [] pfHostFourProjReal; - delete [] pfHostFourProjImaginary; - delete [] pfHostProj; - delete [] pHostFourProj; -} - -void downloadDebugFilterComplex(float * _pfHostSinogram, int _iProjectionCount, - int _iDetectorCount, - cufftComplex * _pDevFilter, - int _iFilterDetCount) -{ - cufftComplex * pHostFilter = NULL; - size_t complMemSize = sizeof(cufftComplex) * _iFilterDetCount * _iProjectionCount; - pHostFilter = (cufftComplex *)malloc(complMemSize); - SAFE_CALL(cudaMemcpy(pHostFilter, _pDevFilter, complMemSize, cudaMemcpyDeviceToHost)); - - for(int iTargetProjIndex = 0; iTargetProjIndex < _iProjectionCount; iTargetProjIndex++) - { - for(int iTargetDetIndex = 0; iTargetDetIndex < min(_iDetectorCount, _iFilterDetCount); iTargetDetIndex++) - { - cufftComplex source = pHostFilter[iTargetDetIndex + iTargetProjIndex * _iFilterDetCount]; - float fReadValue = sqrtf(source.x * source.x + source.y * source.y); - _pfHostSinogram[iTargetDetIndex + iTargetProjIndex * _iDetectorCount] = fReadValue; - } - } - - free(pHostFilter); -} - -void downloadDebugFilterReal(float * _pfHostSinogram, int _iProjectionCount, - int _iDetectorCount, float * _pfDevFilter, - int _iFilterDetCount) -{ - float * pfHostFilter = NULL; - size_t memSize = sizeof(float) * _iFilterDetCount * _iProjectionCount; - pfHostFilter = (float *)malloc(memSize); - SAFE_CALL(cudaMemcpy(pfHostFilter, _pfDevFilter, memSize, cudaMemcpyDeviceToHost)); - - for(int iTargetProjIndex = 0; iTargetProjIndex < _iProjectionCount; iTargetProjIndex++) - { - for(int iTargetDetIndex = 0; iTargetDetIndex < min(_iDetectorCount, _iFilterDetCount); iTargetDetIndex++) - { - float fSource = pfHostFilter[iTargetDetIndex + iTargetProjIndex * _iFilterDetCount]; - _pfHostSinogram[iTargetDetIndex + iTargetProjIndex * _iDetectorCount] = fSource; - } - } - - free(pfHostFilter); -} - -#endif diff --git a/cuda/2d/par_bp.cu b/cuda/2d/par_bp.cu index 09a6554..f080abb 100644 --- a/cuda/2d/par_bp.cu +++ b/cuda/2d/par_bp.cu @@ -28,10 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -53,6 +49,7 @@ const unsigned int g_MaxAngles = 2560; __constant__ float gC_angle_scaled_sin[g_MaxAngles]; __constant__ float gC_angle_scaled_cos[g_MaxAngles]; __constant__ float gC_angle_offset[g_MaxAngles]; +__constant__ float gC_angle_scale[g_MaxAngles]; static bool bindProjDataTexture(float* data, unsigned int pitch, unsigned int width, unsigned int height, cudaTextureAddressMode mode = cudaAddressModeBorder) { @@ -70,6 +67,7 @@ static bool bindProjDataTexture(float* data, unsigned int pitch, unsigned int wi return true; } +// TODO: Templated version with/without scale? (Or only the global outputscale) __global__ void devBP(float* D_volData, unsigned int volPitch, unsigned int startAngle, const SDimensions dims, float fOutputScale) { const int relX = threadIdx.x; @@ -97,9 +95,10 @@ __global__ void devBP(float* D_volData, unsigned int volPitch, unsigned int star const float scaled_cos_theta = gC_angle_scaled_cos[angle]; const float scaled_sin_theta = gC_angle_scaled_sin[angle]; const float TOffset = gC_angle_offset[angle]; + const float scale = gC_angle_scale[angle]; const float fT = fX * scaled_cos_theta - fY * scaled_sin_theta + TOffset; - fVal += tex2D(gT_projTexture, fT, fA); + fVal += tex2D(gT_projTexture, fT, fA) * scale; fA += 1.0f; } @@ -138,6 +137,7 @@ __global__ void devBP_SS(float* D_volData, unsigned int volPitch, unsigned int s const float cos_theta = gC_angle_scaled_cos[angle]; const float sin_theta = gC_angle_scaled_sin[angle]; const float TOffset = gC_angle_offset[angle]; + const float scale = gC_angle_scale[angle]; float fT = fX * cos_theta - fY * sin_theta + TOffset; @@ -145,7 +145,7 @@ __global__ void devBP_SS(float* D_volData, unsigned int volPitch, unsigned int s float fTy = fT; fT += fSubStep * cos_theta; for (int iSubY = 0; iSubY < dims.iRaysPerPixelDim; ++iSubY) { - fVal += tex2D(gT_projTexture, fTy, fA); + fVal += tex2D(gT_projTexture, fTy, fA) * scale; fTy -= fSubStep * sin_theta; } } @@ -172,6 +172,8 @@ __global__ void devBP_SART(float* D_volData, unsigned int volPitch, float offset const float fT = fX * angle_cos - fY * angle_sin + offset; const float fVal = tex2D(gT_projTexture, fT, 0.5f); + // NB: The 'scale' constant in devBP is cancelled out by the SART weighting + D_volData[Y*volPitch+X] += fVal * fOutputScale; } @@ -186,27 +188,34 @@ bool BP_internal(float* D_volumeData, unsigned int volumePitch, float* angle_scaled_sin = new float[dims.iProjAngles]; float* angle_scaled_cos = new float[dims.iProjAngles]; float* angle_offset = new float[dims.iProjAngles]; + float* angle_scale = new float[dims.iProjAngles]; bindProjDataTexture(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); for (unsigned int i = 0; i < dims.iProjAngles; ++i) { double d = angles[i].fDetUX * angles[i].fRayY - angles[i].fDetUY * angles[i].fRayX; angle_scaled_cos[i] = angles[i].fRayY / d; - angle_scaled_sin[i] = -angles[i].fRayX / d; // TODO: Check signs + angle_scaled_sin[i] = -angles[i].fRayX / d; angle_offset[i] = (angles[i].fDetSY * angles[i].fRayX - angles[i].fDetSX * angles[i].fRayY) / d; + angle_scale[i] = sqrt(angles[i].fRayX * angles[i].fRayX + angles[i].fRayY * angles[i].fRayY) / abs(d); } + //fprintf(stderr, "outputscale in BP_internal: %f, %f\n", fOutputScale, angle_scale[0]); + //fprintf(stderr, "ray in BP_internal: %f,%f (length %f)\n", angles[0].fRayX, angles[0].fRayY, sqrt(angles[0].fRayX * angles[0].fRayX + angles[0].fRayY * angles[0].fRayY)); cudaError_t e1 = cudaMemcpyToSymbol(gC_angle_scaled_sin, angle_scaled_sin, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); cudaError_t e2 = cudaMemcpyToSymbol(gC_angle_scaled_cos, angle_scaled_cos, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); cudaError_t e3 = cudaMemcpyToSymbol(gC_angle_offset, angle_offset, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); + cudaError_t e4 = cudaMemcpyToSymbol(gC_angle_scale, angle_scale, dims.iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); assert(e1 == cudaSuccess); assert(e2 == cudaSuccess); assert(e3 == cudaSuccess); + assert(e4 == cudaSuccess); delete[] angle_scaled_sin; delete[] angle_scaled_cos; delete[] angle_offset; + delete[] angle_scale; dim3 dimBlock(g_blockSlices, g_blockSliceSize); dim3 dimGrid((dims.iVolWidth+g_blockSlices-1)/g_blockSlices, @@ -267,6 +276,8 @@ bool BP_SART(float* D_volumeData, unsigned int volumePitch, float angle_scaled_cos = angles[angle].fRayY / d; float angle_scaled_sin = -angles[angle].fRayX / d; // TODO: Check signs float angle_offset = (angles[angle].fDetSY * angles[angle].fRayX - angles[angle].fDetSX * angles[angle].fRayY) / d; + // NB: The adjoint scaling factor from regular BP is cancelled out by the SART weighting + //fOutputScale *= sqrt(angles[angle].fRayX * angles[angle].fRayX + angles[angle].fRayY * angles[angle].fRayY) / abs(d); dim3 dimBlock(g_blockSlices, g_blockSliceSize); dim3 dimGrid((dims.iVolWidth+g_blockSlices-1)/g_blockSlices, @@ -282,55 +293,3 @@ bool BP_SART(float* D_volumeData, unsigned int volumePitch, } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_projData; - - SDimensions dims; - dims.iVolWidth = 1024; - dims.iVolHeight = 1024; - dims.iProjAngles = 512; - dims.iProjDets = 1536; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - - unsigned int volumePitch, projPitch; - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_projData, dims.iProjDets, dims.iProjAngles, projPitch); - printf("pitch: %u\n", projPitch); - - unsigned int y, x; - float* sino = loadImage("sino.png", y, x); - - float* img = new float[dims.iVolWidth*dims.iVolHeight]; - - memset(img, 0, dims.iVolWidth*dims.iVolHeight*sizeof(float)); - - copyVolumeToDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - BP(D_volumeData, volumePitch, D_projData, projPitch, dims, angle, 0, 1.0f); - - delete[] angle; - - copyVolumeFromDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - - saveImage("vol.png",dims.iVolHeight,dims.iVolWidth,img); - - return 0; -} -#endif diff --git a/cuda/2d/par_fp.cu b/cuda/2d/par_fp.cu index 0835301..ea436c3 100644 --- a/cuda/2d/par_fp.cu +++ b/cuda/2d/par_fp.cu @@ -28,10 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -115,10 +111,9 @@ __global__ void FPhorizontal_simple(float* D_projData, unsigned int projPitch, u float fSliceStep = cos_theta / sin_theta; float fDistCorr; if (sin_theta > 0.0f) - fDistCorr = -fDetStep; + fDistCorr = outputScale / sin_theta; else - fDistCorr = fDetStep; - fDistCorr *= outputScale; + fDistCorr = -outputScale / sin_theta; float fVal = 0.0f; // project detector on slice @@ -193,10 +188,9 @@ __global__ void FPvertical_simple(float* D_projData, unsigned int projPitch, uns float fSliceStep = sin_theta / cos_theta; float fDistCorr; if (cos_theta < 0.0f) - fDistCorr = -fDetStep; + fDistCorr = -outputScale / cos_theta; else - fDistCorr = fDetStep; - fDistCorr *= outputScale; + fDistCorr = outputScale / cos_theta; float fVal = 0.0f; float fP = (detector - 0.5f*dims.iProjDets + 0.5f - gC_angle_offset[angle]) * fDetStep + (startSlice - 0.5f*dims.iVolHeight + 0.5f) * fSliceStep + 0.5f*dims.iVolWidth - 0.5f + 0.5f; @@ -375,65 +369,3 @@ bool FP(float* D_volumeData, unsigned int volumePitch, } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_projData; - - SDimensions dims; - dims.iVolWidth = 1024; - dims.iVolHeight = 1024; - dims.iProjAngles = 512; - dims.iProjDets = 1536; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, projPitch; - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_projData, dims.iProjDets, dims.iProjAngles, projPitch); - printf("pitch: %u\n", projPitch); - - unsigned int y, x; - float* img = loadImage("phantom.png", y, x); - - float* sino = new float[dims.iProjAngles * dims.iProjDets]; - - memset(sino, 0, dims.iProjAngles * dims.iProjDets * sizeof(float)); - - copyVolumeToDevice(img, dims.iVolWidth, dims.iVolWidth, dims.iVolHeight, D_volumeData, volumePitch); - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - FP(D_volumeData, volumePitch, D_projData, projPitch, dims, angle, 0, 1.0f); - - delete[] angle; - - copySinogramFromDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_projData, projPitch); - - float s = 0.0f; - for (unsigned int y = 0; y < dims.iProjAngles; ++y) - for (unsigned int x = 0; x < dims.iProjDets; ++x) - s += sino[y*dims.iProjDets+x] * sino[y*dims.iProjDets+x]; - printf("cpu norm: %f\n", s); - - //zeroVolume(D_projData, projPitch, dims.iProjDets, dims.iProjAngles); - s = dotProduct2D(D_projData, projPitch, dims.iProjDets, dims.iProjAngles, 1, 0); - printf("gpu norm: %f\n", s); - - saveImage("sino.png",dims.iProjAngles,dims.iProjDets,sino); - - - return 0; -} -#endif diff --git a/cuda/2d/sart.cu b/cuda/2d/sart.cu index 64973ba..12ad6df 100644 --- a/cuda/2d/sart.cu +++ b/cuda/2d/sart.cu @@ -254,11 +254,11 @@ bool SART::callFP_SART(float* D_volumeData, unsigned int volumePitch, if (parProjs) { assert(!fanProjs); return FP(D_volumeData, volumePitch, D_projData, projPitch, - d, &parProjs[angle], outputScale); + d, &parProjs[angle], outputScale * fProjectorScale); } else { assert(fanProjs); return FanFP(D_volumeData, volumePitch, D_projData, projPitch, - d, &fanProjs[angle], outputScale); + d, &fanProjs[angle], outputScale * fProjectorScale); } } @@ -266,6 +266,7 @@ bool SART::callBP_SART(float* D_volumeData, unsigned int volumePitch, float* D_projData, unsigned int projPitch, unsigned int angle, float outputScale) { + // NB: No fProjectorScale here, as that it is cancelled out in the SART weighting if (parProjs) { assert(!fanProjs); return BP_SART(D_volumeData, volumePitch, D_projData, projPitch, diff --git a/cuda/2d/sirt.cu b/cuda/2d/sirt.cu index 2621490..2c5fdc9 100644 --- a/cuda/2d/sirt.cu +++ b/cuda/2d/sirt.cu @@ -29,10 +29,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/util.h" #include "astra/cuda/2d/arith.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> @@ -302,62 +298,3 @@ float SIRT::computeDiffNorm() } - -#ifdef STANDALONE - -using namespace astraCUDA; - -int main() -{ - float* D_volumeData; - float* D_sinoData; - - SDimensions dims; - dims.iVolWidth = 1024; - dims.iVolHeight = 1024; - dims.iProjAngles = 512; - dims.iProjDets = 1536; - dims.fDetScale = 1.0f; - dims.iRaysPerDet = 1; - unsigned int volumePitch, sinoPitch; - - allocateVolume(D_volumeData, dims.iVolWidth, dims.iVolHeight, volumePitch); - zeroVolume(D_volumeData, volumePitch, dims.iVolWidth, dims.iVolHeight); - printf("pitch: %u\n", volumePitch); - - allocateVolume(D_sinoData, dims.iProjDets, dims.iProjAngles, sinoPitch); - zeroVolume(D_sinoData, sinoPitch, dims.iProjDets, dims.iProjAngles); - printf("pitch: %u\n", sinoPitch); - - unsigned int y, x; - float* sino = loadImage("sino.png", y, x); - - float* img = new float[dims.iVolWidth*dims.iVolHeight]; - - copySinogramToDevice(sino, dims.iProjDets, dims.iProjDets, dims.iProjAngles, D_sinoData, sinoPitch); - - float* angle = new float[dims.iProjAngles]; - - for (unsigned int i = 0; i < dims.iProjAngles; ++i) - angle[i] = i*(M_PI/dims.iProjAngles); - - SIRT sirt; - - sirt.setGeometry(dims, angle); - sirt.init(); - - sirt.setBuffers(D_volumeData, volumePitch, D_sinoData, sinoPitch); - - sirt.iterate(25); - - - delete[] angle; - - copyVolumeFromDevice(img, dims.iVolWidth, dims, D_volumeData, volumePitch); - - saveImage("vol.png",dims.iVolHeight,dims.iVolWidth,img); - - return 0; -} -#endif - diff --git a/cuda/3d/cgls3d.cu b/cuda/3d/cgls3d.cu index 10c5f1e..4829574 100644 --- a/cuda/3d/cgls3d.cu +++ b/cuda/3d/cgls3d.cu @@ -33,10 +33,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include <cstdio> #include <cassert> -#ifdef STANDALONE -#include "testutil.h" -#endif - namespace astraCUDA3d { CGLS::CGLS() : ReconAlgo3D() @@ -263,161 +259,3 @@ bool doCGLS(cudaPitchedPtr& D_volumeData, } } - -#ifdef STANDALONE - -using namespace astraCUDA3d; - -int main() -{ - SDimensions3D dims; - dims.iVolX = 256; - dims.iVolY = 256; - dims.iVolZ = 256; - dims.iProjAngles = 100; - dims.iProjU = 512; - dims.iProjV = 512; - dims.iRaysPerDet = 1; - - SConeProjection angle[100]; - angle[0].fSrcX = -2905.6; - angle[0].fSrcY = 0; - angle[0].fSrcZ = 0; - - angle[0].fDetSX = 694.4; - angle[0].fDetSY = -122.4704; - angle[0].fDetSZ = -122.4704; - - angle[0].fDetUX = 0; - angle[0].fDetUY = .4784; - //angle[0].fDetUY = .5; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = .4784; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 100; ++i) { - angle[i] = angle[0]; - ROTATE0(Src, i, i*2*M_PI/100); - ROTATE0(DetS, i, i*2*M_PI/100); - ROTATE0(DetU, i, i*2*M_PI/100); - ROTATE0(DetV, i, i*2*M_PI/100); - } -#undef ROTATE0 - - - cudaPitchedPtr volData = allocateVolumeData(dims); - cudaPitchedPtr projData = allocateProjectionData(dims); - zeroProjectionData(projData, dims); - - float* pbuf = new float[100*512*512]; - copyProjectionsFromDevice(pbuf, projData, dims); - copyProjectionsToDevice(pbuf, projData, dims); - delete[] pbuf; - -#if 0 - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256; ++i) { - for (unsigned int y = 0; y < 256; ++y) - for (unsigned int x = 0; x < 256; ++x) - slice[y*256+x] = (i-127.5)*(i-127.5)+(y-127.5)*(y-127.5)+(x-127.5)*(x-127.5) < 4900 ? 1.0f : 0.0f; - - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); - } - astraCUDA3d::ConeFP(volData, projData, dims, angle, 1.0f); - -#else - - for (int i = 0; i < 100; ++i) { - char fname[32]; - sprintf(fname, "Tiffs/%04d.png", 4*i); - unsigned int w,h; - float* bufp = loadImage(fname, w,h); - - for (int j = 0; j < 512*512; ++j) { - float v = bufp[j]; - if (v > 236.0f) v = 236.0f; - v = logf(236.0f / v); - bufp[j] = 256*v; - } - - for (int j = 0; j < 512; ++j) { - cudaMemcpy(((float*)projData.ptr)+100*512*j+512*i, bufp+512*j, 512*sizeof(float), cudaMemcpyHostToDevice); - } - - delete[] bufp; - - } -#endif - -#if 0 - float* bufs = new float[100*512]; - - for (int i = 0; i < 512; ++i) { - cudaMemcpy(bufs, ((float*)projData.ptr)+100*512*i, 100*512*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", projData.pitch, projData.xsize, projData.ysize); - - char fname[20]; - sprintf(fname, "sino%03d.png", i); - saveImage(fname, 100, 512, bufs); - } - - float* bufp = new float[512*512]; - - for (int i = 0; i < 100; ++i) { - for (int j = 0; j < 512; ++j) { - cudaMemcpy(bufp+512*j, ((float*)projData.ptr)+100*512*j+512*i, 512*sizeof(float), cudaMemcpyDeviceToHost); - } - - char fname[20]; - sprintf(fname, "proj%03d.png", i); - saveImage(fname, 512, 512, bufp); - } -#endif - - zeroVolumeData(volData, dims); - - cudaPitchedPtr maskData; - maskData.ptr = 0; - - astraCUDA3d::doCGLS(volData, projData, maskData, dims, angle, 50); -#if 1 - float* buf = new float[256*256]; - - for (int i = 0; i < 256; ++i) { - cudaMemcpy(buf, ((float*)volData.ptr)+256*256*i, 256*256*sizeof(float), cudaMemcpyDeviceToHost); - - char fname[20]; - sprintf(fname, "vol%03d.png", i); - saveImage(fname, 256, 256, buf); - } -#endif - - return 0; -} -#endif - diff --git a/cuda/3d/cone_bp.cu b/cuda/3d/cone_bp.cu index feebda2..7312bbc 100644 --- a/cuda/3d/cone_bp.cu +++ b/cuda/3d/cone_bp.cu @@ -28,11 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/3d/util3d.h" #include "astra/cuda/3d/dims3d.h" -#ifdef STANDALONE -#include "astra/cuda/3d/cone_fp.h" -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -55,7 +50,13 @@ static const unsigned int g_volBlockY = 32; static const unsigned g_MaxAngles = 1024; -__constant__ float gC_C[12*g_MaxAngles]; +struct DevConeParams { + float4 fNumU; + float4 fNumV; + float4 fDen; +}; + +__constant__ DevConeParams gC_C[g_MaxAngles]; bool bindProjDataTexture(const cudaArray* array) { @@ -118,16 +119,13 @@ __global__ void dev_cone_BP(void* D_volData, unsigned int volPitch, int startAng for (int angle = startAngle; angle < endAngle; ++angle, fAngle += 1.0f) { - float4 fCu = make_float4(gC_C[12*angle+0], gC_C[12*angle+1], gC_C[12*angle+2], gC_C[12*angle+3]); - float4 fCv = make_float4(gC_C[12*angle+4], gC_C[12*angle+5], gC_C[12*angle+6], gC_C[12*angle+7]); - float4 fCd = make_float4(gC_C[12*angle+8], gC_C[12*angle+9], gC_C[12*angle+10], gC_C[12*angle+11]); + float4 fCu = gC_C[angle].fNumU; + float4 fCv = gC_C[angle].fNumV; + float4 fCd = gC_C[angle].fDen; float fUNum = fCu.w + fX * fCu.x + fY * fCu.y + fZ * fCu.z; float fVNum = fCv.w + fX * fCv.x + fY * fCv.y + fZ * fCv.z; - float fDen = fCd.w + fX * fCd.x + fY * fCd.y + fZ * fCd.z; - - // fCd.w = -|| u v s || (determinant of 3x3 matrix with cols u,v,s) - // fDen = || u v (x-s) || + float fDen = (FDKWEIGHT ? 1.0f : fCd.w) + fX * fCd.x + fY * fCd.y + fZ * fCd.z; float fU,fV, fr; @@ -137,18 +135,7 @@ __global__ void dev_cone_BP(void* D_volData, unsigned int volPitch, int startAng fU = fUNum * fr; fV = fVNum * fr; float fVal = tex3D(gT_coneProjTexture, fU, fAngle, fV); - if (FDKWEIGHT) { - // The correct factor here is this one: - // Z[idx] += (fr*fCd.w)*(fr*fCd.w)*fVal; - // This is the square of the inverse magnification factor - // from fX,fY,fZ to the detector. - - // Since we are assuming we have a circular cone - // beam trajectory, fCd.w is constant, and we instead - // multiply by fCd.w*fCd.w in the FDK preweighting step. - Z[idx] += fr*fr*fVal; - } else - Z[idx] += fVal; + Z[idx] += fr*fr*fVal; fUNum += fCu.z; fVNum += fCv.z; @@ -215,19 +202,9 @@ __global__ void dev_cone_BP_SS(void* D_volData, unsigned int volPitch, int start for (int angle = startAngle; angle < endAngle; ++angle, fAngle += 1.0f) { - - const float fCux = gC_C[12*angle+0]; - const float fCuy = gC_C[12*angle+1]; - const float fCuz = gC_C[12*angle+2]; - const float fCuc = gC_C[12*angle+3]; - const float fCvx = gC_C[12*angle+4]; - const float fCvy = gC_C[12*angle+5]; - const float fCvz = gC_C[12*angle+6]; - const float fCvc = gC_C[12*angle+7]; - const float fCdx = gC_C[12*angle+8]; - const float fCdy = gC_C[12*angle+9]; - const float fCdz = gC_C[12*angle+10]; - const float fCdc = gC_C[12*angle+11]; + float4 fCu = gC_C[angle].fNumU; + float4 fCv = gC_C[angle].fNumV; + float4 fCd = gC_C[angle].fDen; float fXs = fX; for (int iSubX = 0; iSubX < iRaysPerVoxelDim; ++iSubX) { @@ -236,14 +213,15 @@ __global__ void dev_cone_BP_SS(void* D_volData, unsigned int volPitch, int start float fZs = fZ; for (int iSubZ = 0; iSubZ < iRaysPerVoxelDim; ++iSubZ) { - const float fUNum = fCuc + fXs * fCux + fYs * fCuy + fZs * fCuz; - const float fVNum = fCvc + fXs * fCvx + fYs * fCvy + fZs * fCvz; - const float fDen = fCdc + fXs * fCdx + fYs * fCdy + fZs * fCdz; + const float fUNum = fCu.w + fX * fCu.x + fY * fCu.y + fZ * fCu.z; + const float fVNum = fCv.w + fX * fCv.x + fY * fCv.y + fZ * fCv.z; + const float fDen = fCd.w + fX * fCd.x + fY * fCd.y + fZ * fCd.z; - const float fU = fUNum / fDen; - const float fV = fVNum / fDen; + const float fr = __fdividef(1.0f, fDen); + const float fU = fUNum * fr; + const float fV = fVNum * fr; - fVal += tex3D(gT_coneProjTexture, fU, fV, fAngle); + fVal += tex3D(gT_coneProjTexture, fU, fV, fAngle) * fr; fZs += fSubStep; } @@ -259,6 +237,76 @@ __global__ void dev_cone_BP_SS(void* D_volData, unsigned int volPitch, int start } +bool transferConstants(const SConeProjection* angles, unsigned int iProjAngles, const SProjectorParams3D& params) +{ + DevConeParams *p = new DevConeParams[iProjAngles]; + + // We need three things in the kernel: + // projected coordinates of pixels on the detector: + + // u: || (x-s) v (s-d) || / || u v (s-x) || + // v: -|| u (x-s) (s-d) || / || u v (s-x) || + + // ray density weighting factor for the adjoint + // || u v (s-d) ||^2 / ( |cross(u,v)| * || u v (s-x) ||^2 ) + + // FDK weighting factor + // ( || u v s || / || u v (s-x) || ) ^ 2 + + // Since u and v are ratios with the same denominator, we have + // a degree of freedom to scale the denominator. We use that to make + // the square of the denominator equal to the relevant weighting factor. + + + for (unsigned int i = 0; i < iProjAngles; ++i) { + Vec3 u(angles[i].fDetUX, angles[i].fDetUY, angles[i].fDetUZ); + Vec3 v(angles[i].fDetVX, angles[i].fDetVY, angles[i].fDetVZ); + Vec3 s(angles[i].fSrcX, angles[i].fSrcY, angles[i].fSrcZ); + Vec3 d(angles[i].fDetSX, angles[i].fDetSY, angles[i].fDetSZ); + + + + double fScale; + if (!params.bFDKWeighting) { + // goal: 1/fDen^2 = || u v (s-d) ||^2 / ( |cross(u,v)| * || u v (s-x) ||^2 ) + // fDen = ( sqrt(|cross(u,v)|) * || u v (s-x) || ) / || u v (s-d) || + // i.e. scale = sqrt(|cross(u,v)|) * / || u v (s-d) || + + + // NB: for cross(u,v) we invert the volume scaling (for the voxel + // size normalization) to get the proper dimensions for + // the scaling of the adjoint + + fScale = sqrt(scaled_cross3(u,v,Vec3(params.fVolScaleX,params.fVolScaleY,params.fVolScaleZ)).norm()) / det3(u, v, s-d); + } else { + // goal: 1/fDen = || u v s || / || u v (s-x) || + // fDen = || u v (s-x) || / || u v s || + // i.e., scale = 1 / || u v s || + + fScale = 1.0 / det3(u, v, s); + } + + p[i].fNumU.w = fScale * det3(s,v,d); + p[i].fNumU.x = fScale * det3x(v,s-d); + p[i].fNumU.y = fScale * det3y(v,s-d); + p[i].fNumU.z = fScale * det3z(v,s-d); + p[i].fNumV.w = -fScale * det3(s,u,d); + p[i].fNumV.x = -fScale * det3x(u,s-d); + p[i].fNumV.y = -fScale * det3y(u,s-d); + p[i].fNumV.z = -fScale * det3z(u,s-d); + p[i].fDen.w = fScale * det3(u, v, s); // == 1.0 for FDK + p[i].fDen.x = -fScale * det3x(u, v); + p[i].fDen.y = -fScale * det3y(u, v); + p[i].fDen.z = -fScale * det3z(u, v); + } + + // TODO: Check for errors + cudaMemcpyToSymbol(gC_C, p, iProjAngles*sizeof(DevConeParams), 0, cudaMemcpyHostToDevice); + + return true; +} + + bool ConeBP_Array(cudaPitchedPtr D_volumeData, cudaArray *D_projArray, const SDimensions3D& dims, const SConeProjection* angles, @@ -267,44 +315,21 @@ bool ConeBP_Array(cudaPitchedPtr D_volumeData, bindProjDataTexture(D_projArray); float fOutputScale; - if (params.bFDKWeighting) - fOutputScale = params.fOutputScale / (params.fVolScaleX * params.fVolScaleY * params.fVolScaleZ); - else + if (params.bFDKWeighting) { + // NB: assuming cube voxels here + fOutputScale = params.fOutputScale / (params.fVolScaleX); + } else { fOutputScale = params.fOutputScale * (params.fVolScaleX * params.fVolScaleY * params.fVolScaleZ); + } for (unsigned int th = 0; th < dims.iProjAngles; th += g_MaxAngles) { unsigned int angleCount = g_MaxAngles; if (th + angleCount > dims.iProjAngles) angleCount = dims.iProjAngles - th; - // transfer angles to constant memory - float* tmp = new float[12*angleCount]; - - - // NB: We increment angles at the end of the loop body. - - -#define TRANSFER_TO_CONSTANT(expr,name) do { for (unsigned int i = 0; i < angleCount; ++i) tmp[12*i+name] = (expr) ; } while (0) - - TRANSFER_TO_CONSTANT( (angles[i].fDetSZ - angles[i].fSrcZ)*angles[i].fDetVY - (angles[i].fDetSY - angles[i].fSrcY)*angles[i].fDetVZ , 0 ); - TRANSFER_TO_CONSTANT( (angles[i].fDetSX - angles[i].fSrcX)*angles[i].fDetVZ -(angles[i].fDetSZ - angles[i].fSrcZ)*angles[i].fDetVX , 1 ); - TRANSFER_TO_CONSTANT( (angles[i].fDetSY - angles[i].fSrcY)*angles[i].fDetVX - (angles[i].fDetSX - angles[i].fSrcX)*angles[i].fDetVY , 2 ); - TRANSFER_TO_CONSTANT( (angles[i].fDetSY*angles[i].fDetVZ - angles[i].fDetSZ*angles[i].fDetVY)*angles[i].fSrcX - (angles[i].fDetSX*angles[i].fDetVZ - angles[i].fDetSZ*angles[i].fDetVX)*angles[i].fSrcY + (angles[i].fDetSX*angles[i].fDetVY - angles[i].fDetSY*angles[i].fDetVX)*angles[i].fSrcZ , 3 ); - - TRANSFER_TO_CONSTANT( (angles[i].fDetSY - angles[i].fSrcY)*angles[i].fDetUZ-(angles[i].fDetSZ - angles[i].fSrcZ)*angles[i].fDetUY, 4 ); - TRANSFER_TO_CONSTANT( (angles[i].fDetSZ - angles[i].fSrcZ)*angles[i].fDetUX - (angles[i].fDetSX - angles[i].fSrcX)*angles[i].fDetUZ , 5 ); - TRANSFER_TO_CONSTANT((angles[i].fDetSX - angles[i].fSrcX)*angles[i].fDetUY-(angles[i].fDetSY - angles[i].fSrcY)*angles[i].fDetUX , 6 ); - TRANSFER_TO_CONSTANT( -(angles[i].fDetSY*angles[i].fDetUZ - angles[i].fDetSZ*angles[i].fDetUY)*angles[i].fSrcX + (angles[i].fDetSX*angles[i].fDetUZ - angles[i].fDetSZ*angles[i].fDetUX)*angles[i].fSrcY - (angles[i].fDetSX*angles[i].fDetUY - angles[i].fDetSY*angles[i].fDetUX)*angles[i].fSrcZ , 7 ); - - TRANSFER_TO_CONSTANT( angles[i].fDetUY*angles[i].fDetVZ - angles[i].fDetUZ*angles[i].fDetVY , 8 ); - TRANSFER_TO_CONSTANT( angles[i].fDetUZ*angles[i].fDetVX - angles[i].fDetUX*angles[i].fDetVZ , 9 ); - TRANSFER_TO_CONSTANT( angles[i].fDetUX*angles[i].fDetVY - angles[i].fDetUY*angles[i].fDetVX , 10 ); - TRANSFER_TO_CONSTANT( -angles[i].fSrcX * (angles[i].fDetUY*angles[i].fDetVZ - angles[i].fDetUZ*angles[i].fDetVY) - angles[i].fSrcY * (angles[i].fDetUZ*angles[i].fDetVX - angles[i].fDetUX*angles[i].fDetVZ) - angles[i].fSrcZ * (angles[i].fDetUX*angles[i].fDetVY - angles[i].fDetUY*angles[i].fDetVX) , 11 ); - -#undef TRANSFER_TO_CONSTANT - cudaMemcpyToSymbol(gC_C, tmp, angleCount*12*sizeof(float), 0, cudaMemcpyHostToDevice); - - delete[] tmp; + bool ok = transferConstants(angles, angleCount, params); + if (!ok) + return false; dim3 dimBlock(g_volBlockX, g_volBlockY); @@ -353,168 +378,3 @@ bool ConeBP(cudaPitchedPtr D_volumeData, } - -#ifdef STANDALONE -int main() -{ - astraCUDA3d::SDimensions3D dims; - dims.iVolX = 512; - dims.iVolY = 512; - dims.iVolZ = 512; - dims.iProjAngles = 496; - dims.iProjU = 512; - dims.iProjV = 512; - dims.iRaysPerDetDim = 1; - dims.iRaysPerVoxelDim = 1; - - cudaExtent extentV; - extentV.width = dims.iVolX*sizeof(float); - extentV.height = dims.iVolY; - extentV.depth = dims.iVolZ; - - cudaPitchedPtr volData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&volData, extentV); - - cudaExtent extentP; - extentP.width = dims.iProjU*sizeof(float); - extentP.height = dims.iProjAngles; - extentP.depth = dims.iProjV; - - cudaPitchedPtr projData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&projData, extentP); - cudaMemset3D(projData, 0, extentP); - -#if 0 - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 1.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); -#if 0 - if (i == 128) { - for (unsigned int j = 0; j < 256*256; ++j) - slice[j] = 0.0f; - } -#endif - } -#endif - - - astraCUDA3d::SConeProjection angle[512]; - angle[0].fSrcX = -5120; - angle[0].fSrcY = 0; - angle[0].fSrcZ = 0; - - angle[0].fDetSX = 512; - angle[0].fDetSY = -256; - angle[0].fDetSZ = -256; - - angle[0].fDetUX = 0; - angle[0].fDetUY = 1; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = 1; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 512; ++i) { - angle[i] = angle[0]; - ROTATE0(Src, i, i*2*M_PI/512); - ROTATE0(DetS, i, i*2*M_PI/512); - ROTATE0(DetU, i, i*2*M_PI/512); - ROTATE0(DetV, i, i*2*M_PI/512); - } -#undef ROTATE0 - -#if 0 - astraCUDA3d::ConeFP(volData, projData, dims, angle, 1.0f); -#endif -#if 0 - float* bufs = new float[180*512]; - - for (int i = 0; i < 512; ++i) { - cudaMemcpy(bufs, ((float*)projData.ptr)+180*512*i, 180*512*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", projData.pitch, projData.xsize, projData.ysize); - - char fname[20]; - sprintf(fname, "sino%03d.png", i); - saveImage(fname, 180, 512, bufs); - } - - float* bufp = new float[512*512]; - - for (int i = 0; i < 180; ++i) { - for (int j = 0; j < 512; ++j) { - cudaMemcpy(bufp+512*j, ((float*)projData.ptr)+180*512*j+512*i, 512*sizeof(float), cudaMemcpyDeviceToHost); - } - - char fname[20]; - sprintf(fname, "proj%03d.png", i); - saveImage(fname, 512, 512, bufp); - } -#endif -#if 0 - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 0.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); - } -#endif - - astraCUDA3d::ConeBP(volData, projData, dims, angle, 1.0f); -#if 0 - float* buf = new float[256*256]; - - for (int i = 0; i < 256; ++i) { - cudaMemcpy(buf, ((float*)volData.ptr)+256*256*i, 256*256*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", volData.pitch, volData.xsize, volData.ysize); - - char fname[20]; - sprintf(fname, "vol%03d.png", i); - saveImage(fname, 256, 256, buf); - } -#endif - -} -#endif diff --git a/cuda/3d/cone_fp.cu b/cuda/3d/cone_fp.cu index 7e0fae8..bd607fa 100644 --- a/cuda/3d/cone_fp.cu +++ b/cuda/3d/cone_fp.cu @@ -28,10 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/3d/util3d.h" #include "astra/cuda/3d/dims3d.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -368,7 +364,7 @@ bool ConeFP_Array_internal(cudaPitchedPtr D_projData, SCALE_NONCUBE snoncubeY; fS1 = params.fVolScaleX / params.fVolScaleY; snoncubeY.fScale1 = fS1 * fS1; - fS2 = params.fVolScaleY / params.fVolScaleY; + fS2 = params.fVolScaleZ / params.fVolScaleY; snoncubeY.fScale2 = fS2 * fS2; snoncubeY.fOutputScale = params.fOutputScale * params.fVolScaleY; @@ -498,105 +494,3 @@ bool ConeFP(cudaPitchedPtr D_volumeData, } - -#ifdef STANDALONE -int main() -{ - SDimensions3D dims; - dims.iVolX = 256; - dims.iVolY = 256; - dims.iVolZ = 256; - dims.iProjAngles = 32; - dims.iProjU = 512; - dims.iProjV = 512; - dims.iRaysPerDet = 1; - - cudaExtent extentV; - extentV.width = dims.iVolX*sizeof(float); - extentV.height = dims.iVolY; - extentV.depth = dims.iVolZ; - - cudaPitchedPtr volData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&volData, extentV); - - cudaExtent extentP; - extentP.width = dims.iProjU*sizeof(float); - extentP.height = dims.iProjV; - extentP.depth = dims.iProjAngles; - - cudaPitchedPtr projData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&projData, extentP); - cudaMemset3D(projData, 0, extentP); - - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 1.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaError err = cudaMemcpy3D(&p); - assert(!err); - } - - - SConeProjection angle[32]; - angle[0].fSrcX = -1536; - angle[0].fSrcY = 0; - angle[0].fSrcZ = 200; - - angle[0].fDetSX = 512; - angle[0].fDetSY = -256; - angle[0].fDetSZ = -256; - - angle[0].fDetUX = 0; - angle[0].fDetUY = 1; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = 1; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 32; ++i) { - angle[i] = angle[0]; - ROTATE0(Src, i, i*1*M_PI/180); - ROTATE0(DetS, i, i*1*M_PI/180); - ROTATE0(DetU, i, i*1*M_PI/180); - ROTATE0(DetV, i, i*1*M_PI/180); - } -#undef ROTATE0 - - astraCUDA3d::ConeFP(volData, projData, dims, angle, 1.0f); - - float* buf = new float[512*512]; - - cudaMemcpy(buf, ((float*)projData.ptr)+512*512*8, 512*512*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", projData.pitch, projData.xsize, projData.ysize); - - saveImage("proj.png", 512, 512, buf); - - -} -#endif diff --git a/cuda/3d/fdk.cu b/cuda/3d/fdk.cu index 1294721..456694f 100644 --- a/cuda/3d/fdk.cu +++ b/cuda/3d/fdk.cu @@ -32,11 +32,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/2d/fft.h" -#ifdef STANDALONE -#include "astra/cuda/3d/cone_fp.h" -#include "testutil.h" -#endif - #include "astra/Logging.h" #include <cstdio> @@ -57,10 +52,13 @@ static const unsigned g_MaxAngles = 12000; __constant__ float gC_angle[g_MaxAngles]; -// per-detector u/v shifts? +// TODO: To support non-cube voxels, preweighting needs per-view +// parameters. NB: Need to properly take into account the +// anisotropic volume normalization done for that too. -__global__ void devFDK_preweight(void* D_projData, unsigned int projPitch, unsigned int startAngle, unsigned int endAngle, float fSrcOrigin, float fDetOrigin, float fZShift, float fDetUSize, float fDetVSize, float fVoxSize, const SDimensions3D dims) + +__global__ void devFDK_preweight(void* D_projData, unsigned int projPitch, unsigned int startAngle, unsigned int endAngle, float fSrcOrigin, float fDetOrigin, float fZShift, float fDetUSize, float fDetVSize, const SDimensions3D dims) { float* projData = (float*)D_projData; int angle = startAngle + blockIdx.y * g_anglesPerWeightBlock + threadIdx.y; @@ -88,14 +86,10 @@ __global__ void devFDK_preweight(void* D_projData, unsigned int projPitch, unsig // fCentralRayLength / fRayLength : the main FDK preweighting factor // fSrcOrigin / (fDetUSize * fCentralRayLength) // : to adjust the filter to the det width - // || u v s || ^ 2 : see cone_bp.cu, FDKWEIGHT // pi / (2 * iProjAngles) : scaling of the integral over angles - // fVoxSize ^ 2 : ... - const float fW1 = fSrcOrigin * fDetUSize * fDetVSize; const float fW2 = fCentralRayLength / (fDetUSize * fSrcOrigin); - const float fW3 = fVoxSize * fVoxSize; - const float fW = fCentralRayLength * fW1 * fW1 * fW2 * fW3 * (M_PI / 2.0f) / (float)dims.iProjAngles; + const float fW = fCentralRayLength * fW2 * (M_PI / 2.0f) / (float)dims.iProjAngles; for (int detectorV = startDetectorV; detectorV < endDetectorV; ++detectorV) { @@ -167,7 +161,7 @@ __global__ void devFDK_ParkerWeight(void* D_projData, unsigned int projPitch, un bool FDK_PreWeight(cudaPitchedPtr D_projData, float fSrcOrigin, float fDetOrigin, float fZShift, - float fDetUSize, float fDetVSize, float fVoxSize, + float fDetUSize, float fDetVSize, bool bShortScan, const SDimensions3D& dims, const float* angles) { @@ -180,7 +174,7 @@ bool FDK_PreWeight(cudaPitchedPtr D_projData, int projPitch = D_projData.pitch/sizeof(float); - devFDK_preweight<<<dimGrid, dimBlock>>>(D_projData.ptr, projPitch, 0, dims.iProjAngles, fSrcOrigin, fDetOrigin, fZShift, fDetUSize, fDetVSize, fVoxSize, dims); + devFDK_preweight<<<dimGrid, dimBlock>>>(D_projData.ptr, projPitch, 0, dims.iProjAngles, fSrcOrigin, fDetOrigin, fZShift, fDetUSize, fDetVSize, dims); cudaTextForceKernelsCompletion(); @@ -344,9 +338,8 @@ bool FDK(cudaPitchedPtr D_volumeData, #if 1 - // NB: assuming cube voxels (params.fVolScaleX) ok = FDK_PreWeight(D_projData, fSrcOrigin, fDetOrigin, - fZShift, fDetUSize, fDetVSize, params.fVolScaleX, + fZShift, fDetUSize, fDetVSize, bShortScan, dims, pfAngles); #else ok = true; @@ -379,220 +372,3 @@ bool FDK(cudaPitchedPtr D_volumeData, } - -#ifdef STANDALONE -void dumpVolume(const char* filespec, const cudaPitchedPtr& data, const SDimensions3D& dims, float fMin, float fMax) -{ - float* buf = new float[dims.iVolX*dims.iVolY]; - unsigned int pitch = data.pitch / sizeof(float); - - for (int i = 0; i < dims.iVolZ; ++i) { - cudaMemcpy2D(buf, dims.iVolX*sizeof(float), ((float*)data.ptr)+pitch*dims.iVolY*i, data.pitch, dims.iVolX*sizeof(float), dims.iVolY, cudaMemcpyDeviceToHost); - - char fname[512]; - sprintf(fname, filespec, dims.iVolZ-i-1); - saveImage(fname, dims.iVolY, dims.iVolX, buf, fMin, fMax); - } -} - -void dumpSinograms(const char* filespec, const cudaPitchedPtr& data, const SDimensions3D& dims, float fMin, float fMax) -{ - float* bufs = new float[dims.iProjAngles*dims.iProjU]; - unsigned int pitch = data.pitch / sizeof(float); - - for (int i = 0; i < dims.iProjV; ++i) { - cudaMemcpy2D(bufs, dims.iProjU*sizeof(float), ((float*)data.ptr)+pitch*dims.iProjAngles*i, data.pitch, dims.iProjU*sizeof(float), dims.iProjAngles, cudaMemcpyDeviceToHost); - - char fname[512]; - sprintf(fname, filespec, i); - saveImage(fname, dims.iProjAngles, dims.iProjU, bufs, fMin, fMax); - } -} - -void dumpProjections(const char* filespec, const cudaPitchedPtr& data, const SDimensions3D& dims, float fMin, float fMax) -{ - float* bufp = new float[dims.iProjV*dims.iProjU]; - unsigned int pitch = data.pitch / sizeof(float); - - for (int i = 0; i < dims.iProjAngles; ++i) { - for (int j = 0; j < dims.iProjV; ++j) { - cudaMemcpy(bufp+dims.iProjU*j, ((float*)data.ptr)+pitch*dims.iProjAngles*j+pitch*i, dims.iProjU*sizeof(float), cudaMemcpyDeviceToHost); - } - - char fname[512]; - sprintf(fname, filespec, i); - saveImage(fname, dims.iProjV, dims.iProjU, bufp, fMin, fMax); - } -} - - - - -int main() -{ -#if 0 - SDimensions3D dims; - dims.iVolX = 512; - dims.iVolY = 512; - dims.iVolZ = 512; - dims.iProjAngles = 180; - dims.iProjU = 1024; - dims.iProjV = 1024; - dims.iRaysPerDet = 1; - - cudaExtent extentV; - extentV.width = dims.iVolX*sizeof(float); - extentV.height = dims.iVolY; - extentV.depth = dims.iVolZ; - - cudaPitchedPtr volData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&volData, extentV); - - cudaExtent extentP; - extentP.width = dims.iProjU*sizeof(float); - extentP.height = dims.iProjAngles; - extentP.depth = dims.iProjV; - - cudaPitchedPtr projData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&projData, extentP); - cudaMemset3D(projData, 0, extentP); - -#if 0 - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 1.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); -#if 0 - if (i == 128) { - for (unsigned int j = 0; j < 256*256; ++j) - slice[j] = 0.0f; - } -#endif - } -#endif - - SConeProjection angle[180]; - angle[0].fSrcX = -1536; - angle[0].fSrcY = 0; - angle[0].fSrcZ = 0; - - angle[0].fDetSX = 1024; - angle[0].fDetSY = -512; - angle[0].fDetSZ = 512; - - angle[0].fDetUX = 0; - angle[0].fDetUY = 1; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = -1; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 180; ++i) { - angle[i] = angle[0]; - ROTATE0(Src, i, i*2*M_PI/180); - ROTATE0(DetS, i, i*2*M_PI/180); - ROTATE0(DetU, i, i*2*M_PI/180); - ROTATE0(DetV, i, i*2*M_PI/180); - } -#undef ROTATE0 - - astraCUDA3d::ConeFP(volData, projData, dims, angle, 1.0f); - - //dumpSinograms("sino%03d.png", projData, dims, 0, 512); - //dumpProjections("proj%03d.png", projData, dims, 0, 512); - - astraCUDA3d::zeroVolumeData(volData, dims); - - float* angles = new float[dims.iProjAngles]; - for (int i = 0; i < 180; ++i) - angles[i] = i*2*M_PI/180; - - astraCUDA3d::FDK(volData, projData, 1536, 512, 0, 0, dims, angles); - - dumpVolume("vol%03d.png", volData, dims, -20, 100); - - -#else - - SDimensions3D dims; - dims.iVolX = 1000; - dims.iVolY = 999; - dims.iVolZ = 500; - dims.iProjAngles = 376; - dims.iProjU = 1024; - dims.iProjV = 524; - dims.iRaysPerDet = 1; - - float* angles = new float[dims.iProjAngles]; - for (int i = 0; i < dims.iProjAngles; ++i) - angles[i] = -i*(M_PI)/360; - - cudaPitchedPtr volData = astraCUDA3d::allocateVolumeData(dims); - cudaPitchedPtr projData = astraCUDA3d::allocateProjectionData(dims); - astraCUDA3d::zeroProjectionData(projData, dims); - astraCUDA3d::zeroVolumeData(volData, dims); - - timeval t; - tic(t); - - for (int i = 0; i < dims.iProjAngles; ++i) { - char fname[256]; - sprintf(fname, "/home/wpalenst/tmp/Elke/proj%04d.png", i); - unsigned int w,h; - float* bufp = loadImage(fname, w,h); - - int pitch = projData.pitch / sizeof(float); - for (int j = 0; j < dims.iProjV; ++j) { - cudaMemcpy(((float*)projData.ptr)+dims.iProjAngles*pitch*j+pitch*i, bufp+dims.iProjU*j, dims.iProjU*sizeof(float), cudaMemcpyHostToDevice); - } - - delete[] bufp; - } - printf("Load time: %f\n", toc(t)); - - //dumpSinograms("sino%03d.png", projData, dims, -8.0f, 256.0f); - //astraCUDA3d::FDK(volData, projData, 7350, 62355, 0, 10, dims, angles); - //astraCUDA3d::FDK(volData, projData, 7350, -380, 0, 10, dims, angles); - - tic(t); - - astraCUDA3d::FDK(volData, projData, 7383.29867, 0, 0, 10, dims, angles); - - printf("FDK time: %f\n", toc(t)); - tic(t); - - dumpVolume("vol%03d.png", volData, dims, -65.9f, 200.0f); - //dumpVolume("vol%03d.png", volData, dims, 0.0f, 256.0f); - printf("Save time: %f\n", toc(t)); - -#endif - - -} -#endif diff --git a/cuda/3d/mem3d.cu b/cuda/3d/mem3d.cu index 697d2d2..50cfe75 100644 --- a/cuda/3d/mem3d.cu +++ b/cuda/3d/mem3d.cu @@ -268,7 +268,7 @@ bool FP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, con return ok; } -bool BP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, int iVoxelSuperSampling, bool bFDKWeighting) +bool BP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, int iVoxelSuperSampling) { assert(!volData.d->arr); SDimensions3D dims; @@ -289,7 +289,7 @@ bool BP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, con pParProjs, pConeProjs, params); - params.bFDKWeighting = bFDKWeighting; + params.bFDKWeighting = false; if (pParProjs) { if (projData.d->arr) diff --git a/cuda/3d/par3d_bp.cu b/cuda/3d/par3d_bp.cu index 3656f78..602f209 100644 --- a/cuda/3d/par3d_bp.cu +++ b/cuda/3d/par3d_bp.cu @@ -28,11 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/3d/util3d.h" #include "astra/cuda/3d/dims3d.h" -#ifdef STANDALONE -#include "astra/cuda/3d/par3d_fp.h" -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> #include <iostream> @@ -55,7 +50,13 @@ static const unsigned int g_volBlockY = 32; static const unsigned g_MaxAngles = 1024; -__constant__ float gC_C[8*g_MaxAngles]; +struct DevPar3DParams { + float4 fNumU; + float4 fNumV; +}; + +__constant__ DevPar3DParams gC_C[g_MaxAngles]; +__constant__ float gC_scale[g_MaxAngles]; static bool bindProjDataTexture(const cudaArray* array) @@ -115,8 +116,9 @@ __global__ void dev_par3D_BP(void* D_volData, unsigned int volPitch, int startAn for (int angle = startAngle; angle < endAngle; ++angle, fAngle += 1.0f) { - float4 fCu = make_float4(gC_C[8*angle+0], gC_C[8*angle+1], gC_C[8*angle+2], gC_C[8*angle+3]); - float4 fCv = make_float4(gC_C[8*angle+4], gC_C[8*angle+5], gC_C[8*angle+6], gC_C[8*angle+7]); + float4 fCu = gC_C[angle].fNumU; + float4 fCv = gC_C[angle].fNumV; + float fS = gC_scale[angle]; float fU = fCu.w + fX * fCu.x + fY * fCu.y + fZ * fCu.z; float fV = fCv.w + fX * fCv.x + fY * fCv.y + fZ * fCv.z; @@ -124,7 +126,7 @@ __global__ void dev_par3D_BP(void* D_volData, unsigned int volPitch, int startAn for (int idx = 0; idx < ZSIZE; ++idx) { float fVal = tex3D(gT_par3DProjTexture, fU, fAngle, fV); - Z[idx] += fVal; + Z[idx] += fVal * fS; fU += fCu.z; fV += fCv.z; @@ -190,14 +192,9 @@ __global__ void dev_par3D_BP_SS(void* D_volData, unsigned int volPitch, int star for (int angle = startAngle; angle < endAngle; ++angle, fAngle += 1.0f) { - const float fCux = gC_C[8*angle+0]; - const float fCuy = gC_C[8*angle+1]; - const float fCuz = gC_C[8*angle+2]; - const float fCuc = gC_C[8*angle+3]; - const float fCvx = gC_C[8*angle+4]; - const float fCvy = gC_C[8*angle+5]; - const float fCvz = gC_C[8*angle+6]; - const float fCvc = gC_C[8*angle+7]; + float4 fCu = gC_C[angle].fNumU; + float4 fCv = gC_C[angle].fNumV; + float fS = gC_scale[angle]; float fXs = fX; for (int iSubX = 0; iSubX < iRaysPerVoxelDim; ++iSubX) { @@ -206,10 +203,10 @@ __global__ void dev_par3D_BP_SS(void* D_volData, unsigned int volPitch, int star float fZs = fZ; for (int iSubZ = 0; iSubZ < iRaysPerVoxelDim; ++iSubZ) { - const float fU = fCuc + fXs * fCux + fYs * fCuy + fZs * fCuz; - const float fV = fCvc + fXs * fCvx + fYs * fCvy + fZs * fCvz; + const float fU = fCu.w + fXs * fCu.x + fYs * fCu.y + fZs * fCu.z; + const float fV = fCv.w + fXs * fCv.x + fYs * fCv.y + fZs * fCv.z; - fVal += tex3D(gT_par3DProjTexture, fU, fAngle, fV); + fVal += tex3D(gT_par3DProjTexture, fU, fAngle, fV) * fS; fZs += fSubStep; } fYs += fSubStep; @@ -224,6 +221,35 @@ __global__ void dev_par3D_BP_SS(void* D_volData, unsigned int volPitch, int star } +bool transferConstants(const SPar3DProjection* angles, unsigned int iProjAngles, const SProjectorParams3D& params) +{ + DevPar3DParams *p = new DevPar3DParams[iProjAngles]; + float *s = new float[iProjAngles]; + + for (unsigned int i = 0; i < iProjAngles; ++i) { + Vec3 u(angles[i].fDetUX, angles[i].fDetUY, angles[i].fDetUZ); + Vec3 v(angles[i].fDetVX, angles[i].fDetVY, angles[i].fDetVZ); + Vec3 r(angles[i].fRayX, angles[i].fRayY, angles[i].fRayZ); + Vec3 d(angles[i].fDetSX, angles[i].fDetSY, angles[i].fDetSZ); + + double fDen = det3(r,u,v); + p[i].fNumU.x = -det3x(r,v) / fDen; + p[i].fNumU.y = -det3y(r,v) / fDen; + p[i].fNumU.z = -det3z(r,v) / fDen; + p[i].fNumU.w = -det3(r,d,v) / fDen; + p[i].fNumV.x = det3x(r,u) / fDen; + p[i].fNumV.y = det3y(r,u) / fDen; + p[i].fNumV.z = det3z(r,u) / fDen; + p[i].fNumV.w = det3(r,d,u) / fDen; + + s[i] = 1.0 / scaled_cross3(u,v,Vec3(params.fVolScaleX,params.fVolScaleY,params.fVolScaleZ)).norm(); + } + + cudaMemcpyToSymbol(gC_C, p, iProjAngles*sizeof(DevPar3DParams), 0, cudaMemcpyHostToDevice); + cudaMemcpyToSymbol(gC_scale, s, iProjAngles*sizeof(float), 0, cudaMemcpyHostToDevice); + return true; +} + bool Par3DBP_Array(cudaPitchedPtr D_volumeData, cudaArray *D_projArray, const SDimensions3D& dims, const SPar3DProjection* angles, @@ -238,33 +264,9 @@ bool Par3DBP_Array(cudaPitchedPtr D_volumeData, if (th + angleCount > dims.iProjAngles) angleCount = dims.iProjAngles - th; - // transfer angles to constant memory - float* tmp = new float[8*dims.iProjAngles]; - - // NB: We increment angles at the end of the loop body. - - - // TODO: Use functions from dims3d.cu for this: - -#define TRANSFER_TO_CONSTANT(expr,name) do { for (unsigned int i = 0; i < angleCount; ++i) tmp[8*i + name] = (expr) ; } while (0) - -#define DENOM (angles[i].fRayX*angles[i].fDetUY*angles[i].fDetVZ - angles[i].fRayX*angles[i].fDetUZ*angles[i].fDetVY - angles[i].fRayY*angles[i].fDetUX*angles[i].fDetVZ + angles[i].fRayY*angles[i].fDetUZ*angles[i].fDetVX + angles[i].fRayZ*angles[i].fDetUX*angles[i].fDetVY - angles[i].fRayZ*angles[i].fDetUY*angles[i].fDetVX) - - TRANSFER_TO_CONSTANT( ( - (angles[i].fRayY*angles[i].fDetVZ - angles[i].fRayZ*angles[i].fDetVY)) / DENOM , 0 ); - TRANSFER_TO_CONSTANT( ( (angles[i].fRayX*angles[i].fDetVZ - angles[i].fRayZ*angles[i].fDetVX)) / DENOM , 1 ); - TRANSFER_TO_CONSTANT( (- (angles[i].fRayX*angles[i].fDetVY - angles[i].fRayY*angles[i].fDetVX) ) / DENOM , 2 ); - TRANSFER_TO_CONSTANT( (-(angles[i].fDetSY*angles[i].fDetVZ - angles[i].fDetSZ*angles[i].fDetVY)*angles[i].fRayX + (angles[i].fRayY*angles[i].fDetVZ - angles[i].fRayZ*angles[i].fDetVY)*angles[i].fDetSX - (angles[i].fRayY*angles[i].fDetSZ - angles[i].fRayZ*angles[i].fDetSY)*angles[i].fDetVX) / DENOM , 3 ); - - TRANSFER_TO_CONSTANT( ((angles[i].fRayY*angles[i].fDetUZ - angles[i].fRayZ*angles[i].fDetUY) ) / DENOM , 4 ); - TRANSFER_TO_CONSTANT( (- (angles[i].fRayX*angles[i].fDetUZ - angles[i].fRayZ*angles[i].fDetUX) ) / DENOM , 5 ); - TRANSFER_TO_CONSTANT( ((angles[i].fRayX*angles[i].fDetUY - angles[i].fRayY*angles[i].fDetUX) ) / DENOM , 6 ); - TRANSFER_TO_CONSTANT( ((angles[i].fDetSY*angles[i].fDetUZ - angles[i].fDetSZ*angles[i].fDetUY)*angles[i].fRayX - (angles[i].fRayY*angles[i].fDetUZ - angles[i].fRayZ*angles[i].fDetUY)*angles[i].fDetSX + (angles[i].fRayY*angles[i].fDetSZ - angles[i].fRayZ*angles[i].fDetSY)*angles[i].fDetUX ) / DENOM , 7 ); - -#undef TRANSFER_TO_CONSTANT -#undef DENOM - cudaMemcpyToSymbol(gC_C, tmp, angleCount*8*sizeof(float), 0, cudaMemcpyHostToDevice); - - delete[] tmp; + bool ok = transferConstants(angles, dims.iProjAngles, params); + if (!ok) + return false; dim3 dimBlock(g_volBlockX, g_volBlockY); @@ -310,161 +312,3 @@ bool Par3DBP(cudaPitchedPtr D_volumeData, } - -#ifdef STANDALONE -int main() -{ - SDimensions3D dims; - dims.iVolX = 256; - dims.iVolY = 256; - dims.iVolZ = 256; - dims.iProjAngles = 180; - dims.iProjU = 512; - dims.iProjV = 512; - dims.iRaysPerDet = 1; - - cudaExtent extentV; - extentV.width = dims.iVolX*sizeof(float); - extentV.height = dims.iVolY; - extentV.depth = dims.iVolZ; - - cudaPitchedPtr volData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&volData, extentV); - - cudaExtent extentP; - extentP.width = dims.iProjU*sizeof(float); - extentP.height = dims.iProjAngles; - extentP.depth = dims.iProjV; - - cudaPitchedPtr projData; // pitch, ptr, xsize, ysize - - cudaMalloc3D(&projData, extentP); - cudaMemset3D(projData, 0, extentP); - - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 1.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); -#if 0 - if (i == 128) { - for (unsigned int j = 0; j < 256*256; ++j) - slice[j] = 0.0f; - } -#endif - } - - - SPar3DProjection angle[180]; - angle[0].fRayX = 1; - angle[0].fRayY = 0; - angle[0].fRayZ = 0; - - angle[0].fDetSX = 512; - angle[0].fDetSY = -256; - angle[0].fDetSZ = -256; - - angle[0].fDetUX = 0; - angle[0].fDetUY = 1; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = 1; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 180; ++i) { - angle[i] = angle[0]; - ROTATE0(Ray, i, i*2*M_PI/180); - ROTATE0(DetS, i, i*2*M_PI/180); - ROTATE0(DetU, i, i*2*M_PI/180); - ROTATE0(DetV, i, i*2*M_PI/180); - } -#undef ROTATE0 - - astraCUDA3d::Par3DFP(volData, projData, dims, angle, 1.0f); -#if 1 - float* bufs = new float[180*512]; - - for (int i = 0; i < 512; ++i) { - cudaMemcpy(bufs, ((float*)projData.ptr)+180*512*i, 180*512*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", projData.pitch, projData.xsize, projData.ysize); - - char fname[20]; - sprintf(fname, "sino%03d.png", i); - saveImage(fname, 180, 512, bufs, 0, 512); - } - - float* bufp = new float[512*512]; - - for (int i = 0; i < 180; ++i) { - for (int j = 0; j < 512; ++j) { - cudaMemcpy(bufp+512*j, ((float*)projData.ptr)+180*512*j+512*i, 512*sizeof(float), cudaMemcpyDeviceToHost); - } - - char fname[20]; - sprintf(fname, "proj%03d.png", i); - saveImage(fname, 512, 512, bufp, 0, 512); - } -#endif - for (unsigned int i = 0; i < 256*256; ++i) - slice[i] = 0.0f; - for (unsigned int i = 0; i < 256; ++i) { - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); - } - - astraCUDA3d::Par3DBP(volData, projData, dims, angle, 1.0f); -#if 1 - float* buf = new float[256*256]; - - for (int i = 0; i < 256; ++i) { - cudaMemcpy(buf, ((float*)volData.ptr)+256*256*i, 256*256*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", volData.pitch, volData.xsize, volData.ysize); - - char fname[20]; - sprintf(fname, "vol%03d.png", i); - saveImage(fname, 256, 256, buf, 0, 60000); - } -#endif - -} -#endif diff --git a/cuda/3d/par3d_fp.cu b/cuda/3d/par3d_fp.cu index 515b1ba..0a4a5cc 100644 --- a/cuda/3d/par3d_fp.cu +++ b/cuda/3d/par3d_fp.cu @@ -28,11 +28,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/3d/util3d.h" #include "astra/cuda/3d/dims3d.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - - #include <cstdio> #include <cassert> #include <iostream> @@ -751,166 +746,3 @@ bool Par3DFP_SumSqW(cudaPitchedPtr D_volumeData, } - -#ifdef STANDALONE - -using namespace astraCUDA3d; - -int main() -{ - cudaSetDevice(1); - - - SDimensions3D dims; - dims.iVolX = 500; - dims.iVolY = 500; - dims.iVolZ = 81; - dims.iProjAngles = 241; - dims.iProjU = 600; - dims.iProjV = 100; - dims.iRaysPerDet = 1; - - SPar3DProjection base; - base.fRayX = 1.0f; - base.fRayY = 0.0f; - base.fRayZ = 0.1f; - - base.fDetSX = 0.0f; - base.fDetSY = -300.0f; - base.fDetSZ = -50.0f; - - base.fDetUX = 0.0f; - base.fDetUY = 1.0f; - base.fDetUZ = 0.0f; - - base.fDetVX = 0.0f; - base.fDetVY = 0.0f; - base.fDetVZ = 1.0f; - - SPar3DProjection angle[dims.iProjAngles]; - - cudaPitchedPtr volData; // pitch, ptr, xsize, ysize - - volData = allocateVolumeData(dims); - - cudaPitchedPtr projData; // pitch, ptr, xsize, ysize - - projData = allocateProjectionData(dims); - - unsigned int ix = 500,iy = 500; - - float* buf = new float[dims.iProjU*dims.iProjV]; - - float* slice = new float[dims.iVolX*dims.iVolY]; - for (int i = 0; i < dims.iVolX*dims.iVolY; ++i) - slice[i] = 1.0f; - - for (unsigned int a = 0; a < 241; a += dims.iProjAngles) { - - zeroProjectionData(projData, dims); - - for (int y = 0; y < iy; y += dims.iVolY) { - for (int x = 0; x < ix; x += dims.iVolX) { - - timeval st; - tic(st); - - for (int z = 0; z < dims.iVolZ; ++z) { -// char sfn[256]; -// sprintf(sfn, "/home/wpalenst/projects/cone_simulation/phantom_4096/mouse_fem_phantom_%04d.png", 30+z); -// float* slice = loadSubImage(sfn, x, y, dims.iVolX, dims.iVolY); - - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = dims.iVolX*sizeof(float); - ptr.xsize = dims.iVolX*sizeof(float); - ptr.ysize = dims.iVolY; - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, z }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaError err = cudaMemcpy3D(&p); - assert(!err); -// delete[] slice; - } - - printf("Load: %f\n", toc(st)); - -#if 0 - - cudaPos zp = { 0, 0, 0 }; - - cudaPitchedPtr t; - t.ptr = new float[1024*1024]; - t.pitch = 1024*4; - t.xsize = 1024*4; - t.ysize = 1024; - - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = zp; - p.srcPtr = volData; - p.extent = extentS; - p.dstArray = 0; - p.dstPtr = t; - p.dstPos = zp; - p.kind = cudaMemcpyDeviceToHost; - cudaError err = cudaMemcpy3D(&p); - assert(!err); - - char fn[32]; - sprintf(fn, "t%d%d.png", x / dims.iVolX, y / dims.iVolY); - saveImage(fn, 1024, 1024, (float*)t.ptr); - saveImage("s.png", 4096, 4096, slice); - delete[] (float*)t.ptr; -#endif - - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = base.f##name##X * cos(alpha) - base.f##name##Y * sin(alpha); angle[i].f##name##Y = base.f##name##X * sin(alpha) + base.f##name##Y * cos(alpha); angle[i].f##name##Z = base.f##name##Z; } while(0) -#define SHIFT(name,i,x,y) do { angle[i].f##name##X += x; angle[i].f##name##Y += y; } while(0) - for (int i = 0; i < dims.iProjAngles; ++i) { - ROTATE0(Ray, i, (a+i)*.8*M_PI/180); - ROTATE0(DetS, i, (a+i)*.8*M_PI/180); - ROTATE0(DetU, i, (a+i)*.8*M_PI/180); - ROTATE0(DetV, i, (a+i)*.8*M_PI/180); - - -// SHIFT(Src, i, (-x+1536), (-y+1536)); -// SHIFT(DetS, i, (-x+1536), (-y+1536)); - } -#undef ROTATE0 -#undef SHIFT - tic(st); - - astraCUDA3d::Par3DFP(volData, projData, dims, angle, 1.0f); - - printf("FP: %f\n", toc(st)); - - } - } - for (unsigned int aa = 0; aa < dims.iProjAngles; ++aa) { - for (unsigned int v = 0; v < dims.iProjV; ++v) - cudaMemcpy(buf+v*dims.iProjU, ((float*)projData.ptr)+(v*dims.iProjAngles+aa)*(projData.pitch/sizeof(float)), dims.iProjU*sizeof(float), cudaMemcpyDeviceToHost); - - char fname[32]; - sprintf(fname, "proj%03d.png", a+aa); - saveImage(fname, dims.iProjV, dims.iProjU, buf, 0.0f, 1000.0f); - } - } - - delete[] buf; - -} -#endif diff --git a/cuda/3d/sirt3d.cu b/cuda/3d/sirt3d.cu index 869b2fd..e68bde8 100644 --- a/cuda/3d/sirt3d.cu +++ b/cuda/3d/sirt3d.cu @@ -30,10 +30,6 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/cuda/3d/arith3d.h" #include "astra/cuda/3d/cone_fp.h" -#ifdef STANDALONE -#include "testutil.h" -#endif - #include <cstdio> #include <cassert> @@ -375,160 +371,3 @@ bool doSIRT(cudaPitchedPtr& D_volumeData, } -#ifdef STANDALONE - -using namespace astraCUDA3d; - -int main() -{ - SDimensions3D dims; - dims.iVolX = 256; - dims.iVolY = 256; - dims.iVolZ = 256; - dims.iProjAngles = 100; - dims.iProjU = 512; - dims.iProjV = 512; - dims.iRaysPerDet = 1; - - SConeProjection angle[100]; - angle[0].fSrcX = -2905.6; - angle[0].fSrcY = 0; - angle[0].fSrcZ = 0; - - angle[0].fDetSX = 694.4; - angle[0].fDetSY = -122.4704; - angle[0].fDetSZ = -122.4704; - - angle[0].fDetUX = 0; - angle[0].fDetUY = .4784; - //angle[0].fDetUY = .5; - angle[0].fDetUZ = 0; - - angle[0].fDetVX = 0; - angle[0].fDetVY = 0; - angle[0].fDetVZ = .4784; - -#define ROTATE0(name,i,alpha) do { angle[i].f##name##X = angle[0].f##name##X * cos(alpha) - angle[0].f##name##Y * sin(alpha); angle[i].f##name##Y = angle[0].f##name##X * sin(alpha) + angle[0].f##name##Y * cos(alpha); } while(0) - for (int i = 1; i < 100; ++i) { - angle[i] = angle[0]; - ROTATE0(Src, i, i*2*M_PI/100); - ROTATE0(DetS, i, i*2*M_PI/100); - ROTATE0(DetU, i, i*2*M_PI/100); - ROTATE0(DetV, i, i*2*M_PI/100); - } -#undef ROTATE0 - - - cudaPitchedPtr volData = allocateVolumeData(dims); - cudaPitchedPtr projData = allocateProjectionData(dims); - zeroProjectionData(projData, dims); - - float* pbuf = new float[100*512*512]; - copyProjectionsFromDevice(pbuf, projData, dims); - copyProjectionsToDevice(pbuf, projData, dims); - delete[] pbuf; - -#if 0 - float* slice = new float[256*256]; - cudaPitchedPtr ptr; - ptr.ptr = slice; - ptr.pitch = 256*sizeof(float); - ptr.xsize = 256*sizeof(float); - ptr.ysize = 256; - - for (unsigned int i = 0; i < 256; ++i) { - for (unsigned int y = 0; y < 256; ++y) - for (unsigned int x = 0; x < 256; ++x) - slice[y*256+x] = (i-127.5)*(i-127.5)+(y-127.5)*(y-127.5)+(x-127.5)*(x-127.5) < 4900 ? 1.0f : 0.0f; - - cudaExtent extentS; - extentS.width = dims.iVolX*sizeof(float); - extentS.height = dims.iVolY; - extentS.depth = 1; - cudaPos sp = { 0, 0, 0 }; - cudaPos dp = { 0, 0, i }; - cudaMemcpy3DParms p; - p.srcArray = 0; - p.srcPos = sp; - p.srcPtr = ptr; - p.dstArray = 0; - p.dstPos = dp; - p.dstPtr = volData; - p.extent = extentS; - p.kind = cudaMemcpyHostToDevice; - cudaMemcpy3D(&p); - } - astraCUDA3d::ConeFP(volData, projData, dims, angle, 1.0f); - -#else - - for (int i = 0; i < 100; ++i) { - char fname[32]; - sprintf(fname, "Tiffs/%04d.png", 4*i); - unsigned int w,h; - float* bufp = loadImage(fname, w,h); - - for (int j = 0; j < 512*512; ++j) { - float v = bufp[j]; - if (v > 236.0f) v = 236.0f; - v = logf(236.0f / v); - bufp[j] = 256*v; - } - - for (int j = 0; j < 512; ++j) { - cudaMemcpy(((float*)projData.ptr)+100*512*j+512*i, bufp+512*j, 512*sizeof(float), cudaMemcpyHostToDevice); - } - - delete[] bufp; - - } -#endif - -#if 0 - float* bufs = new float[100*512]; - - for (int i = 0; i < 512; ++i) { - cudaMemcpy(bufs, ((float*)projData.ptr)+100*512*i, 100*512*sizeof(float), cudaMemcpyDeviceToHost); - - printf("%d %d %d\n", projData.pitch, projData.xsize, projData.ysize); - - char fname[20]; - sprintf(fname, "sino%03d.png", i); - saveImage(fname, 100, 512, bufs); - } - - float* bufp = new float[512*512]; - - for (int i = 0; i < 100; ++i) { - for (int j = 0; j < 512; ++j) { - cudaMemcpy(bufp+512*j, ((float*)projData.ptr)+100*512*j+512*i, 512*sizeof(float), cudaMemcpyDeviceToHost); - } - - char fname[20]; - sprintf(fname, "proj%03d.png", i); - saveImage(fname, 512, 512, bufp); - } -#endif - - zeroVolumeData(volData, dims); - - cudaPitchedPtr maskData; - maskData.ptr = 0; - - astraCUDA3d::doSIRT(volData, projData, maskData, dims, angle, 50); -#if 1 - float* buf = new float[256*256]; - - for (int i = 0; i < 256; ++i) { - cudaMemcpy(buf, ((float*)volData.ptr)+256*256*i, 256*256*sizeof(float), cudaMemcpyDeviceToHost); - - char fname[20]; - sprintf(fname, "vol%03d.png", i); - saveImage(fname, 256, 256, buf); - } -#endif - - return 0; -} -#endif - diff --git a/include/astra/CudaProjector3D.h b/include/astra/CudaProjector3D.h index 60df7bb..9b4ff1f 100644 --- a/include/astra/CudaProjector3D.h +++ b/include/astra/CudaProjector3D.h @@ -117,7 +117,6 @@ public: int getVoxelSuperSampling() const { return m_iVoxelSuperSampling; } int getDetectorSuperSampling() const { return m_iDetectorSuperSampling; } int getGPUIndex() const { return m_iGPUIndex; } - bool getDensityWeighting() const { return m_bDensityWeighting; } protected: @@ -125,7 +124,6 @@ protected: int m_iVoxelSuperSampling; int m_iDetectorSuperSampling; int m_iGPUIndex; - bool m_bDensityWeighting; }; diff --git a/include/astra/FanFlatBeamLineKernelProjector2D.inl b/include/astra/FanFlatBeamLineKernelProjector2D.inl index 58dec61..8f2e673 100644 --- a/include/astra/FanFlatBeamLineKernelProjector2D.inl +++ b/include/astra/FanFlatBeamLineKernelProjector2D.inl @@ -82,8 +82,6 @@ void CFanFlatBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, in const SFanProjection * proj = &pVecProjectionGeometry->getProjectionVectors()[iAngle]; - float32 detSize = sqrt(proj->fDetUX * proj->fDetUX + proj->fDetUY * proj->fDetUY); - // loop detectors for (iDetector = _iDetFrom; iDetector < _iDetTo; ++iDetector) { @@ -104,7 +102,7 @@ void CFanFlatBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, in // vertically if (vertical) { RxOverRy = Rx/Ry; - lengthPerRow = detSize * pixelLengthX * sqrt(Rx*Rx + Ry*Ry) / abs(Ry); + lengthPerRow = pixelLengthX * sqrt(Rx*Rx + Ry*Ry) / abs(Ry); deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; S = 0.5f - 0.5f*fabs(RxOverRy); T = 0.5f + 0.5f*fabs(RxOverRy); @@ -154,7 +152,7 @@ void CFanFlatBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, in // horizontally else { RyOverRx = Ry/Rx; - lengthPerCol = detSize * pixelLengthY * sqrt(Rx*Rx + Ry*Ry) / abs(Rx); + lengthPerCol = pixelLengthY * sqrt(Rx*Rx + Ry*Ry) / abs(Rx); deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; S = 0.5f - 0.5f*fabs(RyOverRx); T = 0.5f + 0.5f*fabs(RyOverRx); diff --git a/include/astra/FanFlatBeamStripKernelProjector2D.inl b/include/astra/FanFlatBeamStripKernelProjector2D.inl index 889d0a3..f5a688c 100644 --- a/include/astra/FanFlatBeamStripKernelProjector2D.inl +++ b/include/astra/FanFlatBeamStripKernelProjector2D.inl @@ -109,8 +109,12 @@ void CFanFlatBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, i // POLICY: RAY PRIOR if (!p.rayPrior(iRayIndex)) continue; - float32 dist_srcDetPixSquared = projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() + - (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * DW * DW; + float32 dist_srcDetPixSquared = projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() + (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * DW * DW; + dist_srcDetPixSquared = dist_srcDetPixSquared * dist_srcDetPixSquared / (projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() * DW * DW); + + + + //float32 InvRayWidthSquared = (projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance()) / dist_srcDetPixSquared; float32 sin_theta_left, cos_theta_left; float32 sin_theta_right, cos_theta_right; @@ -257,8 +261,8 @@ void CFanFlatBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, i // POLICY: RAY PRIOR if (!p.rayPrior(iRayIndex)) continue; - float32 dist_srcDetPixSquared = projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() + - (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * DW * DW; + float32 dist_srcDetPixSquared = projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() + (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * (iDetector + 0.5f - m_pProjectionGeometry->getDetectorCount()*0.5f) * DW * DW; + dist_srcDetPixSquared = dist_srcDetPixSquared * dist_srcDetPixSquared / (projgeom->getSourceDetectorDistance() * projgeom->getSourceDetectorDistance() * DW * DW); // get theta_l = alpha_left + theta and theta_r = alpha_right + theta float32 sin_theta_left, cos_theta_left; diff --git a/include/astra/Features.h b/include/astra/Features.h index d88ae71..c7ef98c 100644 --- a/include/astra/Features.h +++ b/include/astra/Features.h @@ -38,10 +38,22 @@ _AstraExport bool hasFeature(const std::string &feature); FEATURES: -cuda: is cuda support compiled in? +cuda + is cuda support compiled in? NB: To check if there is also actually a usable GPU, use cudaAvailable() -mex_link: is there support for the matlab command astra_mex_data3d('link')? +mex_link + is there support for the matlab command astra_mex_data3d('link')? + +projectors_scaled_as_line_integrals + This is set since all 2D and 3D, CPU and GPU projectors scale their outputs + to approximate line integrals. (Previously, some 2D projectors were scaled + as area integrals.) + +fan_cone_BP_density_weighting_by_default + This is set since fan beam and cone beam BP operations perform ray density + weighting by default to more closely approximate the true mathematical adjoint. + The DensityWeighting cuda3d projector option is removed. For future backward-incompatible changes, extra features will be added here diff --git a/include/astra/ParallelBeamDistanceDrivenProjector2D.inl b/include/astra/ParallelBeamDistanceDrivenProjector2D.inl index aedcee9..3a18c6f 100644 --- a/include/astra/ParallelBeamDistanceDrivenProjector2D.inl +++ b/include/astra/ParallelBeamDistanceDrivenProjector2D.inl @@ -72,7 +72,7 @@ void CParallelBeamDistanceDrivenProjector2D::projectBlock_internal(int _iProjFro const int rowCount = m_pVolumeGeometry->getGridRowCount(); // Performance note: - // This is not a very well optimizated version of the distance driven + // This is not a very well optimized version of the distance driven // projector. The CPU projector model in ASTRA requires ray-driven iteration, // which limits re-use of intermediate computations. @@ -86,6 +86,9 @@ void CParallelBeamDistanceDrivenProjector2D::projectBlock_internal(int _iProjFro const float32 Ex = m_pVolumeGeometry->getWindowMinX() + pixelLengthX*0.5f; const float32 Ey = m_pVolumeGeometry->getWindowMaxY() - pixelLengthY*0.5f; + const float32 rayWidth = fabs(proj->fDetUX * proj->fRayY - proj->fDetUY * proj->fRayX) / + sqrt(proj->fRayX * proj->fRayX + proj->fRayY * proj->fRayY); + // loop detectors for (int iDetector = _iDetFrom; iDetector < _iDetTo; ++iDetector) { @@ -100,7 +103,7 @@ void CParallelBeamDistanceDrivenProjector2D::projectBlock_internal(int _iProjFro if (vertical) { const float32 RxOverRy = proj->fRayX/proj->fRayY; - const float32 lengthPerRow = m_pVolumeGeometry->getPixelLengthX() * m_pVolumeGeometry->getPixelLengthY(); + const float32 lengthPerRow = m_pVolumeGeometry->getPixelLengthX() * m_pVolumeGeometry->getPixelLengthY() / rayWidth; const float32 deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; const float32 deltad = 0.5f * fabs((proj->fDetUX - proj->fDetUY * RxOverRy) * inv_pixelLengthX); @@ -157,7 +160,7 @@ void CParallelBeamDistanceDrivenProjector2D::projectBlock_internal(int _iProjFro } else { const float32 RyOverRx = proj->fRayY/proj->fRayX; - const float32 lengthPerCol = m_pVolumeGeometry->getPixelLengthX() * m_pVolumeGeometry->getPixelLengthY(); + const float32 lengthPerCol = m_pVolumeGeometry->getPixelLengthX() * m_pVolumeGeometry->getPixelLengthY() / rayWidth; const float32 deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; const float32 deltad = 0.5f * fabs((proj->fDetUY - proj->fDetUX * RyOverRx) * inv_pixelLengthY); diff --git a/include/astra/ParallelBeamLineKernelProjector2D.inl b/include/astra/ParallelBeamLineKernelProjector2D.inl index a9f1aa0..903ebb6 100644 --- a/include/astra/ParallelBeamLineKernelProjector2D.inl +++ b/include/astra/ParallelBeamLineKernelProjector2D.inl @@ -166,24 +166,7 @@ void CParallelBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, i const SParProjection * proj = &pVecProjectionGeometry->getProjectionVectors()[iAngle]; - float32 detSize = sqrt(proj->fDetUX * proj->fDetUX + proj->fDetUY * proj->fDetUY); - bool vertical = fabs(proj->fRayX) < fabs(proj->fRayY); - if (vertical) { - RxOverRy = proj->fRayX/proj->fRayY; - lengthPerRow = detSize * pixelLengthX * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayY); - deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; - S = 0.5f - 0.5f*fabs(RxOverRy); - T = 0.5f + 0.5f*fabs(RxOverRy); - invTminSTimesLengthPerRow = lengthPerRow / (T - S); - } else { - RyOverRx = proj->fRayY/proj->fRayX; - lengthPerCol = detSize * pixelLengthY * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayX); - deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; - S = 0.5f - 0.5f*fabs(RyOverRx); - T = 0.5f + 0.5f*fabs(RyOverRx); - invTminSTimesLengthPerCol = lengthPerCol / (T - S); - } Ex = m_pVolumeGeometry->getWindowMinX() + pixelLengthX*0.5f; Ey = m_pVolumeGeometry->getWindowMaxY() - pixelLengthY*0.5f; @@ -204,6 +187,13 @@ void CParallelBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, i // vertically if (vertical) { + RxOverRy = proj->fRayX/proj->fRayY; + lengthPerRow = pixelLengthX * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayY); + deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; + S = 0.5f - 0.5f*fabs(RxOverRy); + T = 0.5f + 0.5f*fabs(RxOverRy); + invTminSTimesLengthPerRow = lengthPerRow / (T - S); + // calculate c for row 0 c = (Dx + (Ey - Dy)*RxOverRy - Ex) * inv_pixelLengthX; @@ -248,6 +238,13 @@ void CParallelBeamLineKernelProjector2D::projectBlock_internal(int _iProjFrom, i // horizontally else { + RyOverRx = proj->fRayY/proj->fRayX; + lengthPerCol = pixelLengthY * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayX); + deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; + S = 0.5f - 0.5f*fabs(RyOverRx); + T = 0.5f + 0.5f*fabs(RyOverRx); + invTminSTimesLengthPerCol = lengthPerCol / (T - S); + // calculate r for col 0 r = -(Dy + (Ex - Dx)*RyOverRx - Ey) * inv_pixelLengthY; diff --git a/include/astra/ParallelBeamLinearKernelProjector2D.inl b/include/astra/ParallelBeamLinearKernelProjector2D.inl index 10d4892..53451e5 100644 --- a/include/astra/ParallelBeamLinearKernelProjector2D.inl +++ b/include/astra/ParallelBeamLinearKernelProjector2D.inl @@ -154,18 +154,7 @@ void CParallelBeamLinearKernelProjector2D::projectBlock_internal(int _iProjFrom, const SParProjection * proj = &pVecProjectionGeometry->getProjectionVectors()[iAngle]; - float32 detSize = sqrt(proj->fDetUX * proj->fDetUX + proj->fDetUY * proj->fDetUY); - const bool vertical = fabs(proj->fRayX) < fabs(proj->fRayY); - if (vertical) { - RxOverRy = proj->fRayX/proj->fRayY; - lengthPerRow = detSize * m_pVolumeGeometry->getPixelLengthX() * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayY); - deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; - } else { - RyOverRx = proj->fRayY/proj->fRayX; - lengthPerCol = detSize * m_pVolumeGeometry->getPixelLengthY() * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayX); - deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; - } Ex = m_pVolumeGeometry->getWindowMinX() + pixelLengthX*0.5f; Ey = m_pVolumeGeometry->getWindowMaxY() - pixelLengthY*0.5f; @@ -186,6 +175,10 @@ void CParallelBeamLinearKernelProjector2D::projectBlock_internal(int _iProjFrom, // vertically if (vertical) { + RxOverRy = proj->fRayX/proj->fRayY; + lengthPerRow = m_pVolumeGeometry->getPixelLengthX() * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayY); + deltac = -pixelLengthY * RxOverRy * inv_pixelLengthX; + // calculate c for row 0 c = (Dx + (Ey - Dy)*RxOverRy - Ex) * inv_pixelLengthX; @@ -209,6 +202,10 @@ void CParallelBeamLinearKernelProjector2D::projectBlock_internal(int _iProjFrom, // horizontally else { + RyOverRx = proj->fRayY/proj->fRayX; + lengthPerCol = m_pVolumeGeometry->getPixelLengthY() * sqrt(proj->fRayY*proj->fRayY + proj->fRayX*proj->fRayX) / abs(proj->fRayX); + deltar = -pixelLengthX * RyOverRx * inv_pixelLengthY; + // calculate r for col 0 r = -(Dy + (Ex - Dx)*RyOverRx - Ey) * inv_pixelLengthY; diff --git a/include/astra/ParallelBeamStripKernelProjector2D.inl b/include/astra/ParallelBeamStripKernelProjector2D.inl index 0d775b3..2031560 100644 --- a/include/astra/ParallelBeamStripKernelProjector2D.inl +++ b/include/astra/ParallelBeamStripKernelProjector2D.inl @@ -142,20 +142,11 @@ void CParallelBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, const SParProjection * proj = &pVecProjectionGeometry->getProjectionVectors()[iAngle]; + const float32 rayWidth = fabs(proj->fDetUX * proj->fRayY - proj->fDetUY * proj->fRayX) / + sqrt(proj->fRayX * proj->fRayX + proj->fRayY * proj->fRayY); + const float32 relPixelArea = pixelArea / rayWidth; + bool vertical = fabs(proj->fRayX) < fabs(proj->fRayY); - if (vertical) { - RxOverRy = proj->fRayX/proj->fRayY; - deltac = -m_pVolumeGeometry->getPixelLengthY() * RxOverRy * inv_pixelLengthX; - S = 0.5f - 0.5f*fabs(RxOverRy); - T = 0.5f + 0.5f*fabs(RxOverRy); - invTminS = 1.0f / (T-S); - } else { - RyOverRx = proj->fRayY/proj->fRayX; - deltar = -m_pVolumeGeometry->getPixelLengthX() * RyOverRx * inv_pixelLengthY; - S = 0.5f - 0.5f*fabs(RyOverRx); - T = 0.5f + 0.5f*fabs(RyOverRx); - invTminS = 1.0f / (T-S); - } Ex = m_pVolumeGeometry->getWindowMinX() + pixelLengthX*0.5f; Ey = m_pVolumeGeometry->getWindowMaxY() - pixelLengthY*0.5f; @@ -176,6 +167,12 @@ void CParallelBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, // vertically if (vertical) { + RxOverRy = proj->fRayX/proj->fRayY; + deltac = -m_pVolumeGeometry->getPixelLengthY() * RxOverRy * inv_pixelLengthX; + S = 0.5f - 0.5f*fabs(RxOverRy); + T = 0.5f + 0.5f*fabs(RxOverRy); + invTminS = 1.0f / (T-S); + // calculate cL and cR for row 0 cL = (DLx + (Ey - DLy)*RxOverRy - Ex) * inv_pixelLengthX; cR = (DRx + (Ey - DRy)*RxOverRy - Ex) * inv_pixelLengthX; @@ -219,7 +216,7 @@ void CParallelBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, else if (-S < offsetL) res -= 0.5f + offsetL; else if (-T < offsetL) res -= 0.5f*(offsetL+T)*(offsetL+T)*invTminS; - p.addWeight(iRayIndex, iVolumeIndex, pixelArea*res); + p.addWeight(iRayIndex, iVolumeIndex, relPixelArea*res); p.pixelPosterior(iVolumeIndex); } } @@ -229,6 +226,12 @@ void CParallelBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, // horizontally else { + RyOverRx = proj->fRayY/proj->fRayX; + deltar = -m_pVolumeGeometry->getPixelLengthX() * RyOverRx * inv_pixelLengthY; + S = 0.5f - 0.5f*fabs(RyOverRx); + T = 0.5f + 0.5f*fabs(RyOverRx); + invTminS = 1.0f / (T-S); + // calculate rL and rR for row 0 rL = -(DLy + (Ex - DLx)*RyOverRx - Ey) * inv_pixelLengthY; rR = -(DRy + (Ex - DRx)*RyOverRx - Ey) * inv_pixelLengthY; @@ -272,7 +275,7 @@ void CParallelBeamStripKernelProjector2D::projectBlock_internal(int _iProjFrom, else if (-S < offsetL) res -= 0.5f + offsetL; else if (-T < offsetL) res -= 0.5f*(offsetL+T)*(offsetL+T)*invTminS; - p.addWeight(iRayIndex, iVolumeIndex, pixelArea*res); + p.addWeight(iRayIndex, iVolumeIndex, relPixelArea*res); p.pixelPosterior(iVolumeIndex); } } diff --git a/include/astra/cuda/2d/algo.h b/include/astra/cuda/2d/algo.h index 3fccdef..b670b8b 100644 --- a/include/astra/cuda/2d/algo.h +++ b/include/astra/cuda/2d/algo.h @@ -56,6 +56,10 @@ public: bool setSuperSampling(int raysPerDet, int raysPerPixelDim); + // Scale the final reconstruction. + // May be called at any time after setGeometry and before iterate(). Multiple calls stack. + bool setReconstructionScale(float fScale); + virtual bool enableVolumeMask(); virtual bool enableSinogramMask(); @@ -88,8 +92,7 @@ public: // sinogram, reconstruction, volume mask and sinogram mask in system RAM, // respectively. The corresponding pitch variables give the pitches // of these buffers, measured in floats. - // The sinogram is multiplied by fSinogramScale after uploading it. - virtual bool copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, float fSinogramScale, + virtual bool copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, const float* pfReconstruction, unsigned int iReconstructionPitch, const float* pfVolMask, unsigned int iVolMaskPitch, const float* pfSinoMask, unsigned int iSinoMaskPitch); @@ -133,7 +136,7 @@ protected: SDimensions dims; SParProjection* parProjs; SFanProjection* fanProjs; - float fOutputScale; + float fProjectorScale; bool freeGPUMemory; diff --git a/include/astra/cuda/2d/cgls.h b/include/astra/cuda/2d/cgls.h index 375a425..a854a74 100644 --- a/include/astra/cuda/2d/cgls.h +++ b/include/astra/cuda/2d/cgls.h @@ -47,7 +47,7 @@ public: virtual bool setBuffers(float* D_volumeData, unsigned int volumePitch, float* D_projData, unsigned int projPitch); - virtual bool copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, float fSinogramScale, + virtual bool copyDataToGPU(const float* pfSinogram, unsigned int iSinogramPitch, const float* pfReconstruction, unsigned int iReconstructionPitch, const float* pfVolMask, unsigned int iVolMaskPitch, const float* pfSinoMask, unsigned int iSinoMaskPitch); diff --git a/include/astra/cuda/2d/fbp.h b/include/astra/cuda/2d/fbp.h index 1adf3b1..3aa4741 100644 --- a/include/astra/cuda/2d/fbp.h +++ b/include/astra/cuda/2d/fbp.h @@ -79,6 +79,11 @@ public: bool setShortScan(bool ss) { m_bShortScan = ss; return true; } + // Scale the final reconstruction. + // May be called at any time before iterate(). + bool setReconstructionScale(float fScale); + + virtual bool init(); virtual bool iterate(unsigned int iterations); @@ -90,6 +95,7 @@ protected: void* D_filter; // cufftComplex* bool m_bShortScan; + float fReconstructionScale; }; } diff --git a/include/astra/cuda/3d/fdk.h b/include/astra/cuda/3d/fdk.h index 3b1a9e1..6817154 100644 --- a/include/astra/cuda/3d/fdk.h +++ b/include/astra/cuda/3d/fdk.h @@ -35,7 +35,7 @@ namespace astraCUDA3d { bool FDK_PreWeight(cudaPitchedPtr D_projData, float fSrcOrigin, float fDetOrigin, float fZShift, - float fDetUSize, float fDetVSize, float fVoxSize, + float fDetUSize, float fDetVSize, bool bShortScan, const SDimensions3D& dims, const float* angles); diff --git a/include/astra/cuda/3d/mem3d.h b/include/astra/cuda/3d/mem3d.h index 8c3956e..fff1490 100644 --- a/include/astra/cuda/3d/mem3d.h +++ b/include/astra/cuda/3d/mem3d.h @@ -110,7 +110,7 @@ bool copyIntoArray(MemHandle3D handle, MemHandle3D subdata, const SSubDimensions bool FP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, int iDetectorSuperSampling, astra::Cuda3DProjectionKernel projKernel); -bool BP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, int iVoxelSuperSampling, bool bFDKWeighting); +bool BP(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, int iVoxelSuperSampling); bool FDK(const astra::CProjectionGeometry3D* pProjGeom, MemHandle3D projData, const astra::CVolumeGeometry3D* pVolGeom, MemHandle3D volData, bool bShortScan, const float *pfFilter = 0); diff --git a/include/astra/cuda/3d/util3d.h b/include/astra/cuda/3d/util3d.h index 0146d2d..200abfc 100644 --- a/include/astra/cuda/3d/util3d.h +++ b/include/astra/cuda/3d/util3d.h @@ -64,6 +64,53 @@ float dotProduct3D(cudaPitchedPtr data, unsigned int x, unsigned int y, unsigned int calcNextPowerOfTwo(int _iValue); +struct Vec3 { + double x; + double y; + double z; + Vec3(double x_, double y_, double z_) : x(x_), y(y_), z(z_) { } + Vec3 operator+(const Vec3 &b) const { + return Vec3(x + b.x, y + b.y, z + b.z); + } + Vec3 operator-(const Vec3 &b) const { + return Vec3(x - b.x, y - b.y, z - b.z); + } + Vec3 operator-() const { + return Vec3(-x, -y, -z); + } + double norm() const { + return sqrt(x*x + y*y + z*z); + } +}; + +static double det3x(const Vec3 &b, const Vec3 &c) { + return (b.y * c.z - b.z * c.y); +} +static double det3y(const Vec3 &b, const Vec3 &c) { + return -(b.x * c.z - b.z * c.x); +} + +static double det3z(const Vec3 &b, const Vec3 &c) { + return (b.x * c.y - b.y * c.x); +} + +static double det3(const Vec3 &a, const Vec3 &b, const Vec3 &c) { + return a.x * det3x(b,c) + a.y * det3y(b,c) + a.z * det3z(b,c); +} + +static Vec3 cross3(const Vec3 &a, const Vec3 &b) { + return Vec3(det3x(a,b), det3y(a,b), det3z(a,b)); +} + +static Vec3 scaled_cross3(const Vec3 &a, const Vec3 &b, const Vec3 &sc) { + Vec3 ret = cross3(a, b); + ret.x *= sc.y * sc.z; + ret.y *= sc.x * sc.z; + ret.z *= sc.x * sc.y; + return ret; +} + + } #endif diff --git a/src/CompositeGeometryManager.cpp b/src/CompositeGeometryManager.cpp index 1319a87..822f746 100644 --- a/src/CompositeGeometryManager.cpp +++ b/src/CompositeGeometryManager.cpp @@ -1462,12 +1462,10 @@ static bool doJob(const CCompositeGeometryManager::TJobSet::const_iterator& iter Cuda3DProjectionKernel projKernel = ker3d_default; int detectorSuperSampling = 1; int voxelSuperSampling = 1; - bool densityWeighting = false; if (projector) { projKernel = projector->getProjectionKernel(); detectorSuperSampling = projector->getDetectorSuperSampling(); voxelSuperSampling = projector->getVoxelSuperSampling(); - densityWeighting = projector->getDensityWeighting(); } size_t inx, iny, inz; @@ -1513,7 +1511,7 @@ static bool doJob(const CCompositeGeometryManager::TJobSet::const_iterator& iter ASTRA_DEBUG("CCompositeGeometryManager::doJobs: doing BP"); - ok = astraCUDA3d::BP(((CCompositeGeometryManager::CProjectionPart*)j.pInput.get())->pGeom, srcMem->hnd, ((CCompositeGeometryManager::CVolumePart*)j.pOutput.get())->pGeom, dstMem->hnd, voxelSuperSampling, densityWeighting); + ok = astraCUDA3d::BP(((CCompositeGeometryManager::CProjectionPart*)j.pInput.get())->pGeom, srcMem->hnd, ((CCompositeGeometryManager::CVolumePart*)j.pOutput.get())->pGeom, dstMem->hnd, voxelSuperSampling); if (!ok) ASTRA_ERROR("Error performing sub-BP"); ASTRA_DEBUG("CCompositeGeometryManager::doJobs: BP done"); } diff --git a/src/CudaFilteredBackProjectionAlgorithm.cpp b/src/CudaFilteredBackProjectionAlgorithm.cpp index 88e235b..c1d3dc8 100644 --- a/src/CudaFilteredBackProjectionAlgorithm.cpp +++ b/src/CudaFilteredBackProjectionAlgorithm.cpp @@ -151,6 +151,13 @@ void CCudaFilteredBackProjectionAlgorithm::initCUDAAlgorithm() if (!ok) { ASTRA_ERROR("CCudaFilteredBackProjectionAlgorithm: Failed to set short-scan mode"); } + + const CVolumeGeometry2D& volGeom = *m_pReconstruction->getGeometry(); + float fPixelArea = volGeom.getPixelArea(); + ok &= pFBP->setReconstructionScale(1.0f/fPixelArea); + if (!ok) { + ASTRA_ERROR("CCudaFilteredBackProjectionAlgorithm: Failed to set reconstruction scale"); + } } diff --git a/src/CudaProjector3D.cpp b/src/CudaProjector3D.cpp index 3ea7043..e5c55cc 100644 --- a/src/CudaProjector3D.cpp +++ b/src/CudaProjector3D.cpp @@ -67,7 +67,6 @@ void CCudaProjector3D::_clear() m_iVoxelSuperSampling = 1; m_iDetectorSuperSampling = 1; m_iGPUIndex = -1; - m_bDensityWeighting = false; } //---------------------------------------------------------------------------------------- @@ -132,13 +131,6 @@ bool CCudaProjector3D::initialize(const Config& _cfg) m_iDetectorSuperSampling = (int)_cfg.self.getOptionNumerical("DetectorSuperSampling", 1); CC.markOptionParsed("DetectorSuperSampling"); - if (dynamic_cast<CConeProjectionGeometry3D*>(m_pProjectionGeometry) || - dynamic_cast<CConeVecProjectionGeometry3D*>(m_pProjectionGeometry)) - { - m_bDensityWeighting = _cfg.self.getOptionBool("DensityWeighting", false); - CC.markOptionParsed("DensityWeighting"); - } - m_iGPUIndex = (int)_cfg.self.getOptionNumerical("GPUindex", -1); m_iGPUIndex = (int)_cfg.self.getOptionNumerical("GPUIndex", m_iGPUIndex); CC.markOptionParsed("GPUIndex"); diff --git a/src/CudaReconstructionAlgorithm2D.cpp b/src/CudaReconstructionAlgorithm2D.cpp index 1e81390..6730cea 100644 --- a/src/CudaReconstructionAlgorithm2D.cpp +++ b/src/CudaReconstructionAlgorithm2D.cpp @@ -309,10 +309,7 @@ void CCudaReconstructionAlgorithm2D::run(int _iNrIterations) m_bAlgoInit = true; } - float fPixelSize = volgeom.getPixelLengthX(); - float fSinogramScale = 1.0f/(fPixelSize*fPixelSize); - - ok = m_pAlgo->copyDataToGPU(m_pSinogram->getDataConst(), m_pSinogram->getGeometry()->getDetectorCount(), fSinogramScale, + ok = m_pAlgo->copyDataToGPU(m_pSinogram->getDataConst(), m_pSinogram->getGeometry()->getDetectorCount(), m_pReconstruction->getDataConst(), volgeom.getGridColCount(), m_bUseReconstructionMask ? m_pReconstructionMask->getDataConst() : 0, volgeom.getGridColCount(), m_bUseSinogramMask ? m_pSinogramMask->getDataConst() : 0, m_pSinogram->getGeometry()->getDetectorCount()); diff --git a/src/Features.cpp b/src/Features.cpp index 9114131..09a3499 100644 --- a/src/Features.cpp +++ b/src/Features.cpp @@ -34,6 +34,12 @@ _AstraExport bool hasFeature(const std::string &flag) { if (flag == "cuda") { return cudaEnabled(); } + if (flag == "projectors_scaled_as_line_integrals") { + return true; + } + if (flag == "fan_cone_BP_density_weighting_by_default") { + return true; + } return false; } diff --git a/src/FilteredBackProjectionAlgorithm.cpp b/src/FilteredBackProjectionAlgorithm.cpp index 423dc6c..6b4093d 100644 --- a/src/FilteredBackProjectionAlgorithm.cpp +++ b/src/FilteredBackProjectionAlgorithm.cpp @@ -167,6 +167,11 @@ bool CFilteredBackProjectionAlgorithm::initialize(const Config& _cfg) m_filterConfig = getFilterConfigForAlgorithm(_cfg, this); + const CParallelProjectionGeometry2D* parprojgeom = dynamic_cast<CParallelProjectionGeometry2D*>(m_pSinogram->getGeometry()); + if (!parprojgeom) { + ASTRA_ERROR("FBP currently only supports parallel projection geometries."); + return false; + } // TODO: check that the angles are linearly spaced between 0 and pi @@ -264,8 +269,12 @@ void CFilteredBackProjectionAlgorithm::run(int _iNrIterations) DefaultBPPolicy(m_pReconstruction, &filteredSinogram)); // Scale data - int iAngleCount = m_pProjector->getProjectionGeometry()->getProjectionAngleCount(); - (*m_pReconstruction) *= (PI/2)/iAngleCount; + const CVolumeGeometry2D& volGeom = *m_pProjector->getVolumeGeometry(); + const CProjectionGeometry2D& projGeom = *m_pProjector->getProjectionGeometry(); + + int iAngleCount = projGeom.getProjectionAngleCount(); + float fPixelArea = volGeom.getPixelArea(); + (*m_pReconstruction) *= PI/(2*iAngleCount*fPixelArea); m_pReconstruction->updateStatistics(); } diff --git a/src/GeometryUtil2D.cpp b/src/GeometryUtil2D.cpp index e09a3bc..806572f 100644 --- a/src/GeometryUtil2D.cpp +++ b/src/GeometryUtil2D.cpp @@ -28,6 +28,7 @@ along with the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>. #include "astra/GeometryUtil2D.h" #include <cmath> +#include <cstdio> namespace astra { @@ -158,14 +159,16 @@ bool getFanParameters(const SFanProjection &proj, unsigned int iProjDets, float // project origin on detector line ( == project source on detector line) double t = (- proj.fDetSX) * proj.fDetUX + (- proj.fDetSY) * proj.fDetUY; + t /= (proj.fDetUX * proj.fDetUX + proj.fDetUY * proj.fDetUY); fOffset = (float)t - 0.5*iProjDets; - // TODO: CHECKME fOriginDetector = sqrt((proj.fDetSX + t * proj.fDetUX)*(proj.fDetSX + t * proj.fDetUX) + (proj.fDetSY + t * proj.fDetUY)*(proj.fDetSY + t * proj.fDetUY)); - //float fAngle = atan2(proj.fDetSX + t * proj.fDetUX - proj.fSrcX, proj.fDetSY + t * proj.fDetUY); // TODO: Fix order + sign - fAngle = atan2(proj.fDetUY, proj.fDetUX); // TODO: Check order + sign + fAngle = atan2(proj.fDetUY, proj.fDetUX); + + //fprintf(stderr, "getFanParams: s = (%f,%f) d = (%f,%f) u = (%f,%f)\n", proj.fSrcX, proj.fSrcY, proj.fDetSX, proj.fDetSY, proj.fDetUX, proj.fDetUY); + //fprintf(stderr, "getFanParams: fOS = %f, fOD = %f, detsize = %f, offset = %f (t = %f), angle = %f\n", fOriginSource, fOriginDetector, fDetSize, fOffset, t, fAngle); return true; } diff --git a/tests/python/test_line2d.py b/tests/python/test_line2d.py index d04ffb8..e5d8f2b 100644 --- a/tests/python/test_line2d.py +++ b/tests/python/test_line2d.py @@ -7,9 +7,9 @@ import pylab # Display sinograms with mismatch on test failure DISPLAY=False -NONUNITDET=False -OBLIQUE=False -FLEXVOL=False +NONUNITDET=True +OBLIQUE=True +FLEXVOL=True NONSQUARE=False # non-square pixels not supported yet by most projectors # Round interpolation weight to 8 bits to emulate CUDA texture unit precision @@ -20,15 +20,8 @@ nloops = 50 seed = 123 -# FAILURES: -# fan/cuda with flexible volume -# detweight for fan/cuda -# fan/strip relatively high numerical errors? -# parvec/line+linear for oblique - -# INCONSISTENCY: -# effective_detweight vs norm(detu) in line/linear (oblique) - +# KNOWN FAILURES: +# fan/strip relatively high numerical errors around 45 degrees # return length of intersection of the line through points src = (x,y) @@ -454,23 +447,15 @@ class Test2DKernel(unittest.TestCase): for i, (center, edge1, edge2) in enumerate(gen_lines(pg)): (src, det) = center - try: - detweight = pg['DetectorWidth'] - except KeyError: - if 'fan' not in type: - detweight = effective_detweight(src, det, pg['Vectors'][i//pg['DetectorCount'],4:6]) - else: - detweight = np.linalg.norm(pg['Vectors'][i//pg['DetectorCount'],4:6], ord=2) - # We compute line intersections with slightly bigger (cw) and # smaller (aw) rectangles, and see if the kernel falls # between these two values. (aw,bw,cw) = intersect_line_rectangle_interval(src, det, xmin, xmax, ymin, ymax, 1e-3) - a[i] = aw * detweight - b[i] = bw * detweight - c[i] = cw * detweight + a[i] = aw + b[i] = bw + c[i] = cw a = a.reshape(astra.functions.geom_size(pg)) b = b.reshape(astra.functions.geom_size(pg)) c = c.reshape(astra.functions.geom_size(pg)) @@ -494,17 +479,9 @@ class Test2DKernel(unittest.TestCase): for i, (center, edge1, edge2) in enumerate(gen_lines(pg)): (src, det) = center (xd, yd) = det - src - try: - detweight = pg['DetectorWidth'] - except KeyError: - if 'fan' not in type: - detweight = effective_detweight(src, det, pg['Vectors'][i//pg['DetectorCount'],4:6]) - else: - detweight = np.linalg.norm(pg['Vectors'][i//pg['DetectorCount'],4:6], ord=2) - l = 0.0 if np.abs(xd) > np.abs(yd): # horizontal ray - length = math.sqrt(1.0 + abs(yd/xd)**2) + length = math.sqrt(1.0 + abs(yd/xd)**2) * pixsize[0] y_seg = (ymin, ymax) for j in range(rect_min[0], rect_max[0]): x = origin[0] + (-0.5 * shape[0] + j + 0.5) * pixsize[0] @@ -512,9 +489,9 @@ class Test2DKernel(unittest.TestCase): # limited interpolation precision with cuda if CUDA_8BIT_LINEAR and proj_type == 'cuda': w = np.round(w * 256.0) / 256.0 - l += w * length * pixsize[0] * detweight + l += w * length else: - length = math.sqrt(1.0 + abs(xd/yd)**2) + length = math.sqrt(1.0 + abs(xd/yd)**2) * pixsize[1] x_seg = (xmin, xmax) for j in range(rect_min[1], rect_max[1]): y = origin[1] + (+0.5 * shape[1] - j - 0.5) * pixsize[1] @@ -522,7 +499,7 @@ class Test2DKernel(unittest.TestCase): # limited interpolation precision with cuda if CUDA_8BIT_LINEAR and proj_type == 'cuda': w = np.round(w * 256.0) / 256.0 - l += w * length * pixsize[1] * detweight + l += w * length a[i] = l a = a.reshape(astra.functions.geom_size(pg)) if not np.all(np.isfinite(a)): @@ -532,21 +509,26 @@ class Test2DKernel(unittest.TestCase): if DISPLAY and x > TOL: display_mismatch(data, sinogram, a) self.assertFalse(x > TOL) - elif proj_type == 'distance_driven': + elif proj_type == 'distance_driven' and 'par' in type: a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32) for i, (center, edge1, edge2) in enumerate(gen_lines(pg)): - (xd, yd) = center[1] - center[0] + (src, det) = center + try: + detweight = pg['DetectorWidth'] + except KeyError: + detweight = effective_detweight(src, det, pg['Vectors'][i//pg['DetectorCount'],4:6]) + (xd, yd) = det - src l = 0.0 if np.abs(xd) > np.abs(yd): # horizontal ray y_seg = (ymin, ymax) for j in range(rect_min[0], rect_max[0]): x = origin[0] + (-0.5 * shape[0] + j + 0.5) * pixsize[0] - l += intersect_ray_vertical_segment(edge1, edge2, x, y_seg) * pixsize[0] + l += intersect_ray_vertical_segment(edge1, edge2, x, y_seg) * pixsize[0] / detweight else: x_seg = (xmin, xmax) for j in range(rect_min[1], rect_max[1]): y = origin[1] + (+0.5 * shape[1] - j - 0.5) * pixsize[1] - l += intersect_ray_horizontal_segment(edge1, edge2, y, x_seg) * pixsize[1] + l += intersect_ray_horizontal_segment(edge1, edge2, y, x_seg) * pixsize[1] / detweight a[i] = l a = a.reshape(astra.functions.geom_size(pg)) if not np.all(np.isfinite(a)): @@ -560,6 +542,7 @@ class Test2DKernel(unittest.TestCase): a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32) for i, (center, edge1, edge2) in enumerate(gen_lines(pg)): (src, det) = center + detweight = effective_detweight(src, det, edge2[1] - edge1[1]) det_dist = np.linalg.norm(src-det, ord=2) l = 0.0 for j in range(rect_min[0], rect_max[0]): @@ -570,7 +553,7 @@ class Test2DKernel(unittest.TestCase): ymin = origin[1] + (+0.5 * shape[1] - k - 1) * pixsize[1] ymax = origin[1] + (+0.5 * shape[1] - k) * pixsize[1] ycen = 0.5 * (ymin + ymax) - scale = det_dist / np.linalg.norm( src - np.array((xcen,ycen)), ord=2 ) + scale = det_dist / (np.linalg.norm( src - np.array((xcen,ycen)), ord=2 ) * detweight) w = intersect_ray_rect(edge1, edge2, xmin, xmax, ymin, ymax) l += w * scale a[i] = l @@ -578,14 +561,20 @@ class Test2DKernel(unittest.TestCase): if not np.all(np.isfinite(a)): raise RuntimeError("Invalid value in reference sinogram") x = np.max(np.abs(sinogram-a)) - TOL = 8e-3 + # BUG: Known bug in fan/strip code around 45 degree projections causing larger errors than desirable + TOL = 4e-2 if DISPLAY and x > TOL: display_mismatch(data, sinogram, a) self.assertFalse(x > TOL) elif proj_type == 'strip': a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32) for i, (center, edge1, edge2) in enumerate(gen_lines(pg)): - a[i] = intersect_ray_rect(edge1, edge2, xmin, xmax, ymin, ymax) + (src, det) = center + try: + detweight = pg['DetectorWidth'] + except KeyError: + detweight = effective_detweight(src, det, pg['Vectors'][i//pg['DetectorCount'],4:6]) + a[i] = intersect_ray_rect(edge1, edge2, xmin, xmax, ymin, ymax) / detweight a = a.reshape(astra.functions.geom_size(pg)) if not np.all(np.isfinite(a)): raise RuntimeError("Invalid value in reference sinogram") @@ -594,46 +583,83 @@ class Test2DKernel(unittest.TestCase): if DISPLAY and x > TOL: display_mismatch(data, sinogram, a) self.assertFalse(x > TOL) + else: + raise RuntimeError("Unsupported projector") - def multi_test(self, type, proj_type): - np.random.seed(seed) - for _ in range(nloops): - self.single_test(type, proj_type) - - def test_par(self): - self.multi_test('parallel', 'line') - def test_par_linear(self): - self.multi_test('parallel', 'linear') - def test_par_cuda(self): - self.multi_test('parallel', 'cuda') - def test_par_dd(self): - self.multi_test('parallel', 'distance_driven') - def test_par_strip(self): - self.multi_test('parallel', 'strip') - def test_fan(self): - self.multi_test('fanflat', 'line') - def test_fan_strip(self): - self.multi_test('fanflat', 'strip') - def test_fan_cuda(self): - self.multi_test('fanflat', 'cuda') - def test_parvec(self): - self.multi_test('parallel_vec', 'line') - def test_parvec_linear(self): - self.multi_test('parallel_vec', 'linear') - def test_parvec_dd(self): - self.multi_test('parallel_vec', 'distance_driven') - def test_parvec_strip(self): - self.multi_test('parallel_vec', 'strip') - def test_parvec_cuda(self): - self.multi_test('parallel_vec', 'cuda') - def test_fanvec(self): - self.multi_test('fanflat_vec', 'line') - def test_fanvec_cuda(self): - self.multi_test('fanflat_vec', 'cuda') + def single_test_adjoint(self, type, proj_type): + shape = np.random.randint(*range2d, size=2) + if FLEXVOL: + if not NONSQUARE: + pixsize = np.array([0.5, 0.5]) + np.random.random() + else: + pixsize = 0.5 + np.random.random(size=2) + origin = 10 * np.random.random(size=2) + else: + pixsize = (1.,1.) + origin = (0.,0.) + vg = astra.create_vol_geom(shape[1], shape[0], + origin[0] - 0.5 * shape[0] * pixsize[0], + origin[0] + 0.5 * shape[0] * pixsize[0], + origin[1] - 0.5 * shape[1] * pixsize[1], + origin[1] + 0.5 * shape[1] * pixsize[1]) + if type == 'parallel': + pg = gen_random_geometry_parallel() + projector_id = astra.create_projector(proj_type, pg, vg) + elif type == 'parallel_vec': + pg = gen_random_geometry_parallel_vec() + projector_id = astra.create_projector(proj_type, pg, vg) + elif type == 'fanflat': + pg = gen_random_geometry_fanflat() + projector_id = astra.create_projector(proj_type_to_fan(proj_type), pg, vg) + elif type == 'fanflat_vec': + pg = gen_random_geometry_fanflat_vec() + projector_id = astra.create_projector(proj_type_to_fan(proj_type), pg, vg) + for i in range(5): + X = np.random.random((shape[1], shape[0])) + Y = np.random.random(astra.geom_size(pg)) + + sinogram_id, fX = astra.create_sino(X, projector_id) + bp_id, fTY = astra.create_backprojection(Y, projector_id) + + astra.data2d.delete(sinogram_id) + astra.data2d.delete(bp_id) + + da = np.dot(fX.ravel(), Y.ravel()) + db = np.dot(X.ravel(), fTY.ravel()) + m = np.abs(da - db) + TOL = 1e-3 if 'cuda' not in proj_type else 1e-1 + if m / da >= TOL: + print(vg) + print(pg) + print(m/da, da/db, da, db) + self.assertTrue(m / da < TOL) + astra.projector.delete(projector_id) + def multi_test(self, type, proj_type): + np.random.seed(seed) + for _ in range(nloops): + self.single_test(type, proj_type) + def multi_test_adjoint(self, type, proj_type): + np.random.seed(seed) + for _ in range(nloops): + self.single_test_adjoint(type, proj_type) + +__combinations = { 'parallel': [ 'line', 'linear', 'distance_driven', 'strip', 'cuda' ], + 'parallel_vec': [ 'line', 'linear', 'distance_driven', 'strip', 'cuda' ], + 'fanflat': [ 'line', 'strip', 'cuda' ], + 'fanflat_vec': [ 'line', 'cuda' ] } + +for k, l in __combinations.items(): + for v in l: + def f(k,v): + return lambda self: self.multi_test(k, v) + def f_adj(k,v): + return lambda self: self.multi_test_adjoint(k, v) + setattr(Test2DKernel, 'test_' + k + '_' + v, f(k,v)) + setattr(Test2DKernel, 'test_' + k + '_' + v + '_adjoint', f_adj(k,v)) if __name__ == '__main__': unittest.main() diff --git a/tests/python/test_rec_scaling.py b/tests/python/test_rec_scaling.py new file mode 100644 index 0000000..621fd8a --- /dev/null +++ b/tests/python/test_rec_scaling.py @@ -0,0 +1,213 @@ +import numpy as np +import unittest +import astra +import math +import pylab + +DISPLAY=False + +def VolumeGeometries(is3D,noncube): + if not is3D: + for s in [0.8, 1.0, 1.25]: + yield astra.create_vol_geom(128, 128, -64*s, 64*s, -64*s, 64*s) + elif noncube: + for sx in [0.8, 1.0]: + for sy in [0.8, 1.0]: + for sz in [0.8, 1.0]: + yield astra.create_vol_geom(64, 64, 64, -32*sx, 32*sx, -32*sy, 32*sy, -32*sz, 32*sz) + else: + for s in [0.8, 1.0]: + yield astra.create_vol_geom(64, 64, 64, -32*s, 32*s, -32*s, 32*s, -32*s, 32*s) + + +def ProjectionGeometries(type): + if type == 'parallel': + for dU in [0.8, 1.0, 1.25]: + yield astra.create_proj_geom('parallel', dU, 256, np.linspace(0,np.pi,180,False)) + elif type == 'fanflat': + for dU in [0.8, 1.0, 1.25]: + for src in [500, 1000]: + for det in [0, 250, 500]: + yield astra.create_proj_geom('fanflat', dU, 256, np.linspace(0,2*np.pi,180,False), src, det) + elif type == 'parallel3d': + for dU in [0.8, 1.0]: + for dV in [0.8, 1.0]: + yield astra.create_proj_geom('parallel3d', dU, dV, 128, 128, np.linspace(0,np.pi,180,False)) + elif type == 'parallel3d_vec': + for j in range(10): + Vectors = np.zeros([180,12]) + wu = 0.6 + 0.8 * np.random.random() + wv = 0.6 + 0.8 * np.random.random() + for i in range(Vectors.shape[0]): + l = 0.6 + 0.8 * np.random.random() + angle1 = 2*np.pi*np.random.random() + angle2 = angle1 + 0.5 * np.random.random() + angle3 = 0.1*np.pi*np.random.random() + detc = 10 * np.random.random(size=3) + detu = [ math.cos(angle1) * wu, math.sin(angle1) * wu, 0 ] + detv = [ -math.sin(angle1) * math.sin(angle3) * wv, math.cos(angle1) * math.sin(angle3) * wv, math.cos(angle3) * wv ] + ray = [ math.sin(angle2) * l, -math.cos(angle2) * l, 0 ] + Vectors[i, :] = [ ray[0], ray[1], ray[2], detc[0], detc[1], detc[2], detu[0], detu[1], detu[2], detv[0], detv[1], detv[2] ] + pg = astra.create_proj_geom('parallel3d_vec', 128, 128, Vectors) + yield pg + elif type == 'cone': + for dU in [0.8, 1.0]: + for dV in [0.8, 1.0]: + for src in [500, 1000]: + for det in [0, 250]: + yield astra.create_proj_geom('cone', dU, dV, 128, 128, np.linspace(0,2*np.pi,180,False), src, det) + elif type == 'cone_vec': + for j in range(10): + Vectors = np.zeros([180,12]) + wu = 0.6 + 0.8 * np.random.random() + wv = 0.6 + 0.8 * np.random.random() + for i in range(Vectors.shape[0]): + l = 256 * (0.5 * np.random.random()) + angle1 = 2*np.pi*np.random.random() + angle2 = angle1 + 0.5 * np.random.random() + angle3 = 0.1*np.pi*np.random.random() + detc = 10 * np.random.random(size=3) + detu = [ math.cos(angle1) * wu, math.sin(angle1) * wu, 0 ] + detv = [ -math.sin(angle1) * math.sin(angle3) * wv, math.cos(angle1) * math.sin(angle3) * wv, math.cos(angle3) * wv ] + src = [ math.sin(angle2) * l, -math.cos(angle2) * l, 0 ] + Vectors[i, :] = [ src[0], src[1], src[2], detc[0], detc[1], detc[2], detu[0], detu[1], detu[2], detv[0], detv[1], detv[2] ] + pg = astra.create_proj_geom('parallel3d_vec', 128, 128, Vectors) + yield pg + + +class TestRecScale(unittest.TestCase): + def single_test(self, geom_type, proj_type, alg, iters): + if alg == 'FBP' and 'fanflat' in geom_type: + self.skipTest('CPU FBP is parallel-beam only') + is3D = (geom_type in ['parallel3d', 'cone']) + for vg in VolumeGeometries(is3D, 'FDK' not in alg): + for pg in ProjectionGeometries(geom_type): + if not is3D: + vol = np.zeros((128,128),dtype=np.float32) + vol[50:70,50:70] = 1 + else: + vol = np.zeros((64,64,64),dtype=np.float32) + vol[25:35,25:35,25:35] = 1 + proj_id = astra.create_projector(proj_type, pg, vg) + if not is3D: + sino_id, sinogram = astra.create_sino(vol, proj_id) + else: + sino_id, sinogram = astra.create_sino3d_gpu(vol, pg, vg) + if not is3D: + DATA = astra.data2d + else: + DATA = astra.data3d + + rec_id = DATA.create('-vol', vg, 0.0 if 'EM' not in alg else 1.0) + + cfg = astra.astra_dict(alg) + cfg['ReconstructionDataId'] = rec_id + cfg['ProjectionDataId'] = sino_id + cfg['ProjectorId'] = proj_id + alg_id = astra.algorithm.create(cfg) + + for i in range(iters): + astra.algorithm.run(alg_id, 1) + rec = DATA.get(rec_id) + astra.astra.delete([sino_id, alg_id, alg_id, proj_id]) + if not is3D: + val = np.sum(rec[55:65,55:65]) / 100. + else: + val = np.sum(rec[27:32,27:32,27:32]) / 125. + TOL = 5e-2 + if DISPLAY and abs(val-1.0) >= TOL: + print(geom_type, proj_type, alg, vg, pg) + print(val) + pylab.gray() + if not is3D: + pylab.imshow(rec) + else: + pylab.imshow(rec[:,32,:]) + pylab.show() + self.assertTrue(abs(val-1.0) < TOL) + + def single_test_adjoint3D(self, geom_type, proj_type): + for vg in VolumeGeometries(True, True): + for pg in ProjectionGeometries(geom_type): + for i in range(5): + X = np.random.random(astra.geom_size(vg)) + Y = np.random.random(astra.geom_size(pg)) + proj_id, fX = astra.create_sino3d_gpu(X, pg, vg) + bp_id, fTY = astra.create_backprojection3d_gpu(Y, pg, vg) + + astra.data3d.delete([proj_id, bp_id]) + + da = np.dot(fX.ravel(), Y.ravel()) + db = np.dot(X.ravel(), fTY.ravel()) + m = np.abs(da - db) + TOL = 1e-1 + if m / da >= TOL: + print(vg) + print(pg) + print(m/da, da/db, da, db) + self.assertTrue(m / da < TOL) + + + + + +__combinations = { + 'parallel': [ 'line', 'linear', 'distance_driven', 'strip', 'cuda' ], + 'fanflat': [ 'line_fanflat', 'strip_fanflat', 'cuda' ], + 'parallel3d': [ 'cuda3d' ], + 'cone': [ 'cuda3d' ], +} + +__combinations_adjoint = { + 'parallel3d': [ 'cuda3d' ], + 'cone': [ 'cuda3d' ], + 'parallel3d_vec': [ 'cuda3d' ], + 'cone_vec': [ 'cuda3d' ], +} + +__algs = { + 'SIRT': 50, 'SART': 10*180, 'CGLS': 30, + 'FBP': 1 +} + +__algs_CUDA = { + 'SIRT_CUDA': 50, 'SART_CUDA': 10*180, 'CGLS_CUDA': 30, 'EM_CUDA': 50, + 'FBP_CUDA': 1 +} + +__algs_parallel3d = { + 'SIRT3D_CUDA': 200, 'CGLS3D_CUDA': 20, +} + +__algs_cone = { + 'SIRT3D_CUDA': 200, 'CGLS3D_CUDA': 20, + 'FDK_CUDA': 1 +} + + + +for k, l in __combinations.items(): + for v in l: + is3D = (k in ['parallel3d', 'cone']) + if k == 'parallel3d': + A = __algs_parallel3d + elif k == 'cone': + A = __algs_cone + elif v == 'cuda': + A = __algs_CUDA + else: + A = __algs + for a, i in A.items(): + def f(k, v, a, i): + return lambda self: self.single_test(k, v, a, i) + setattr(TestRecScale, 'test_' + a + '_' + k + '_' + v, f(k,v,a,i)) + +for k, l in __combinations_adjoint.items(): + for v in l: + def g(k, v): + return lambda self: self.single_test_adjoint3D(k, v) + setattr(TestRecScale, 'test_adjoint_' + k + '_' + v, g(k,v)) + +if __name__ == '__main__': + unittest.main() + diff --git a/tests/test_ParallelBeamLineKernelProjector2D.cpp b/tests/test_ParallelBeamLineKernelProjector2D.cpp deleted file mode 100644 index 71130c1..0000000 --- a/tests/test_ParallelBeamLineKernelProjector2D.cpp +++ /dev/null @@ -1,82 +0,0 @@ -/* ------------------------------------------------------------------------ -Copyright: 2010-2018, imec Vision Lab, University of Antwerp - 2014-2018, CWI, Amsterdam - -Contact: astra@astra-toolbox.com -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 <http://www.gnu.org/licenses/>. - ------------------------------------------------------------------------ -*/ - - -#define BOOST_TEST_DYN_LINK -#include <boost/test/unit_test.hpp> -#include <boost/test/auto_unit_test.hpp> -#include <boost/test/floating_point_comparison.hpp> - -#include "astra/ParallelBeamLineKernelProjector2D.h" -#include "astra/ParallelProjectionGeometry2D.h" -#include "astra/VolumeGeometry2D.h" - -struct TestParallelBeamLineKernelProjector2D { - TestParallelBeamLineKernelProjector2D() - { - astra::float32 angles[] = { 1.0f }; - BOOST_REQUIRE( projGeom.initialize(1, 9, 1.0f, angles) ); - BOOST_REQUIRE( volGeom.initialize(6, 4) ); - BOOST_REQUIRE( proj.initialize(&projGeom, &volGeom) ); - } - ~TestParallelBeamLineKernelProjector2D() - { - - } - - astra::CParallelBeamLineKernelProjector2D proj; - astra::CParallelProjectionGeometry2D projGeom; - astra::CVolumeGeometry2D volGeom; -}; - -BOOST_FIXTURE_TEST_CASE( testParallelBeamLineKernelProjector2D_General, TestParallelBeamLineKernelProjector2D ) -{ - -} - -BOOST_FIXTURE_TEST_CASE( testParallelBeamLineKernelProjector2D_Rectangle, TestParallelBeamLineKernelProjector2D ) -{ - int iMax = proj.getProjectionWeightsCount(0); - BOOST_REQUIRE(iMax > 0); - - astra::SPixelWeight* pPix = new astra::SPixelWeight[iMax]; - BOOST_REQUIRE(pPix); - - int iCount; - proj.computeSingleRayWeights(0, 4, pPix, iMax, iCount); - BOOST_REQUIRE(iCount <= iMax); - - astra::float32 fWeight = 0; - for (int i = 0; i < iCount; ++i) - fWeight += pPix[i].m_fWeight; - - BOOST_CHECK_SMALL(fWeight - 7.13037f, 0.00001f); // 6 / sin(1) - - delete[] pPix; -} - - diff --git a/tests/test_ParallelBeamLinearKernelProjector2D.cpp b/tests/test_ParallelBeamLinearKernelProjector2D.cpp deleted file mode 100644 index 4610aa5..0000000 --- a/tests/test_ParallelBeamLinearKernelProjector2D.cpp +++ /dev/null @@ -1,170 +0,0 @@ -/* ------------------------------------------------------------------------ -Copyright: 2010-2018, imec Vision Lab, University of Antwerp - 2014-2018, CWI, Amsterdam - -Contact: astra@astra-toolbox.com -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 <http://www.gnu.org/licenses/>. - ------------------------------------------------------------------------ -*/ - - -#define BOOST_TEST_DYN_LINK -#include <boost/test/unit_test.hpp> -#include <boost/test/auto_unit_test.hpp> -#include <boost/test/floating_point_comparison.hpp> - -#include "astra/ParallelBeamLineKernelProjector2D.h" -#include "astra/ParallelBeamLinearKernelProjector2D.h" -#include "astra/ParallelBeamStripKernelProjector2D.h" -#include "astra/ParallelProjectionGeometry2D.h" -#include "astra/VolumeGeometry2D.h" -#include "astra/ProjectionGeometry2D.h" - -#include <ctime> - -using astra::float32; - -struct TestParallelBeamLinearKernelProjector2D { - TestParallelBeamLinearKernelProjector2D() - { - astra::float32 angles[] = { 2.6f }; - BOOST_REQUIRE( projGeom.initialize(1, 3, 1.0f, angles) ); - BOOST_REQUIRE( volGeom.initialize(3, 2) ); - BOOST_REQUIRE( proj.initialize(&projGeom, &volGeom) ); - } - ~TestParallelBeamLinearKernelProjector2D() - { - - } - - astra::CParallelBeamLinearKernelProjector2D proj; - astra::CParallelProjectionGeometry2D projGeom; - astra::CVolumeGeometry2D volGeom; -}; - -BOOST_FIXTURE_TEST_CASE( testParallelBeamLinearKernelProjector2D_General, TestParallelBeamLinearKernelProjector2D ) -{ - -} - - -// Compute linear kernel for a single volume pixel/detector pixel combination -float32 compute_linear_kernel(const astra::CProjectionGeometry2D& projgeom, const astra::CVolumeGeometry2D& volgeom, - int iX, int iY, int iDet, float32 fAngle) -{ - // projection of center of volume pixel on detector array - float32 fDetProj = (iX - (volgeom.getGridColCount()-1.0f)/2.0f ) * volgeom.getPixelLengthX() * cos(fAngle) - (iY - (volgeom.getGridRowCount()-1.0f)/2.0f ) * volgeom.getPixelLengthY() * sin(fAngle); - - // start of detector pixel on detector array - float32 fDetStart = projgeom.indexToDetectorOffset(iDet) - 0.5f; - -// printf("(%d,%d,%d): %f in (%f,%f)\n", iX,iY,iDet,fDetProj, fDetStart, fDetStart+1.0f); - - // projection of center of next volume pixel on detector array - float32 fDetStep; - // length of projection ray through volume pixel - float32 fWeight; - - if (fabs(cos(fAngle)) > fabs(sin(fAngle))) { - fDetStep = volgeom.getPixelLengthY() * fabs(cos(fAngle)); - fWeight = projgeom.getDetectorWidth() * volgeom.getPixelLengthX() * 1.0f / fabs(cos(fAngle)); - } else { - fDetStep = volgeom.getPixelLengthX() * fabs(sin(fAngle)); - fWeight = projgeom.getDetectorWidth() * volgeom.getPixelLengthY() * 1.0f / fabs(sin(fAngle)); - } - -// printf("step: %f\n weight: %f\n", fDetStep, fWeight); - - // center of detector pixel on detector array - float32 fDetCenter = fDetStart + 0.5f; - - // unweighted contribution of this volume pixel: - // linear interpolation between - // fDetCenter - fDetStep |---> 0 - // fDetCenter |---> 1 - // fDetCenter + fDetStep |---> 0 - float32 fBase; - if (fDetCenter <= fDetProj) { - fBase = (fDetCenter - (fDetProj - fDetStep))/fDetStep; - } else { - fBase = ((fDetProj + fDetStep) - fDetCenter)/fDetStep; - } -// printf("base: %f\n", fBase); - if (fBase < 0) fBase = 0; - return fBase * fWeight; -} - -BOOST_AUTO_TEST_CASE( testParallelBeamLinearKernelProjector2D_Rectangles ) -{ - astra::CParallelBeamLinearKernelProjector2D proj; - astra::CParallelProjectionGeometry2D projGeom; - astra::CVolumeGeometry2D volGeom; - - const unsigned int iRandomTestCount = 100; - - unsigned int iSeed = time(0); - srand(iSeed); - - for (unsigned int iTest = 0; iTest < iRandomTestCount; ++iTest) { - int iDetectorCount = 1 + (rand() % 100); - int iRows = 1 + (rand() % 100); - int iCols = 1 + (rand() % 100); - - - astra::float32 angles[] = { rand() * 2.0f*astra::PI / RAND_MAX }; - projGeom.initialize(1, iDetectorCount, 0.8f, angles); - volGeom.initialize(iCols, iRows); - proj.initialize(&projGeom, &volGeom); - - int iMax = proj.getProjectionWeightsCount(0); - BOOST_REQUIRE(iMax > 0); - - astra::SPixelWeight* pPix = new astra::SPixelWeight[iMax]; - BOOST_REQUIRE(pPix); - - astra::float32 fWeight = 0; - for (int iDet = 0; iDet < projGeom.getDetectorCount(); ++iDet) { - int iCount; - proj.computeSingleRayWeights(0, iDet, pPix, iMax, iCount); - BOOST_REQUIRE(iCount <= iMax); - - astra::float32 fW = 0; - for (int i = 0; i < iCount; ++i) { - float32 fTest = compute_linear_kernel( - projGeom, - volGeom, - pPix[i].m_iIndex % volGeom.getGridColCount(), - pPix[i].m_iIndex / volGeom.getGridColCount(), - iDet, - projGeom.getProjectionAngle(0)); - BOOST_CHECK_SMALL( pPix[i].m_fWeight - fTest, 0.0004f); - fW += pPix[i].m_fWeight; - } - - fWeight += fW; - - } - - delete[] pPix; - } -} - - |