//---------------------------------------------------------------------------------------- // Iterate void CBackProjectionAlgorithm::run(int _iNrIterations) { // check initialized ASTRA_ASSERT(m_bIsInitialized); m_bShouldAbort = false; CDataProjectorInterface* pBackProjector; pBackProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DefaultBPPolicy(m_pReconstruction, m_pSinogram), // backprojection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); m_pReconstruction->setData(0.0f); pBackProjector->project(); ASTRA_DELETE(pBackProjector); }
//---------------------------------------------------------------------------------------- // Iterate void CCglsAlgorithm::run(int _iNrIterations) { // check initialized ASTRA_ASSERT(m_bIsInitialized); // data projectors CDataProjectorInterface* pForwardProjector; CDataProjectorInterface* pFirstForwardProjector; CDataProjectorInterface* pBackProjector; // Clear reconstruction volume. if (m_bClearReconstruction) { m_pReconstruction->setData(0.0f); } // forward projection data projector if (m_bUseJacobiPreconditioner) { // w = A t pForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DefaultFPPolicy(t, w), // forward projection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); } else { // w = A p pForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DefaultFPPolicy(p, w), // forward projection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); } // backprojection data projector pBackProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DefaultBPPolicy(z, r), // backprojection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // First forward projector to compute the Jacobi preconditioner, which // is just the norm squares of the columns of the projection matrix A // (it is diagonal of A' * A) pFirstForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask TotalPixelWeightPolicy(c, false, true), // forward projection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // Compute the Jacobi preconditioner. if (m_bUseJacobiPreconditioner) { c->setData(0.f); pFirstForwardProjector->project(); // Compute sqrt c->sqrt(); } int i; if (m_iIteration == 0) { // r = b; r->copyData(m_pSinogram->getData()); // w = A*x0 p->copyData(m_pReconstruction->getData()); pForwardProjector->project(); // r = b - A*x0 *r -= *w; // z = A' * (b - A * x0) = A' * r z->setData(0.0f); pBackProjector->project(); // CHECK //if (m_bUseMinConstraint) // z->clampMin(m_fMinValue); //if (m_bUseMaxConstraint) // z->clampMax(m_fMaxValue); // Precondition? if (m_bUseJacobiPreconditioner) { *z /= *c; } // p = z; p->copyData(z->getData()); // gamma = dot(z,z); gamma = 0.0f; for (i = 0; i < z->getSize(); ++i) { gamma += z->getData()[i] * z->getData()[i]; } m_iIteration++; } // start iterations //for (int iIteration = _iNrIterations-1; iIteration >= 0; --iIteration) { for (int iIteration = 0; iIteration < _iNrIterations; ++iIteration) { // start timer m_ulTimer = CPlatformDepSystemCode::getMSCount(); if (m_bUseJacobiPreconditioner) { // t = C^-1 p t->copyData(p->getData()); *t /= *c; } // w = A*p (or A*t if precondioning) w->setData(0); pForwardProjector->project(); // alpha = gamma/dot(w,w); float32 tmp = 0; for (i = 0; i < w->getSize(); ++i) { tmp += w->getData()[i] * w->getData()[i]; } alpha = gamma / tmp; if (m_bUseJacobiPreconditioner) { // x = x + alpha*t; for (i = 0; i < m_pReconstruction->getSize(); ++i) { m_pReconstruction->getData()[i] += alpha * t->getData()[i]; } } else { // x = x + alpha*p; for (i = 0; i < m_pReconstruction->getSize(); ++i) { m_pReconstruction->getData()[i] += alpha * p->getData()[i]; } } // r = r - alpha*w; for (i = 0; i < r->getSize(); ++i) { r->getData()[i] -= alpha * w->getData()[i]; } // z = A'*r; z->setData(0.0f); pBackProjector->project(); // Precondition? if (m_bUseJacobiPreconditioner) { // z = C^-1 C *z /= *c; } // CHECKME: should these be here? // This was z. CHECK if (m_bUseMinConstraint) m_pReconstruction->clampMin(m_fMinValue); if (m_bUseMaxConstraint) m_pReconstruction->clampMax(m_fMaxValue); // beta = 1/gamma; beta = 1.0f / gamma; // gamma = dot(z,z); gamma = 0; for (i = 0; i < z->getSize(); ++i) { gamma += z->getData()[i] * z->getData()[i]; } // beta = gamma*beta; beta *= gamma; // p = z + beta*p; for (i = 0; i < z->getSize(); ++i) { p->getData()[i] = z->getData()[i] + beta * p->getData()[i]; } // end timer m_ulTimer = CPlatformDepSystemCode::getMSCount() - m_ulTimer; // Compute metrics. computeIterationMetrics(iIteration, _iNrIterations, r); m_iIteration++; } ASTRA_DELETE(pForwardProjector); ASTRA_DELETE(pBackProjector); ASTRA_DELETE(pFirstForwardProjector); //if (m_iIteration == 0) { // // r = b; // r->copyData(m_pSinogram->getData()); // // z = A'*b; // z->setData(0.0f); // pBackProjector->project(); // // CHECK // //if (m_bUseMinConstraint) // // z->clampMin(m_fMinValue); // //if (m_bUseMaxConstraint) // // z->clampMax(m_fMaxValue); // // p = z; // p->copyData(z->getData()); // // gamma = dot(z,z); // gamma = 0.0f; // for (i = 0; i < z->getSize(); ++i) { // gamma += z->getData()[i] * z->getData()[i]; // } // // m_iIteration++; //} //// start iterations ////for (int iIteration = _iNrIterations-1; iIteration >= 0; --iIteration) { //for (int iIteration = 0; iIteration < _iNrIterations; ++iIteration) { // // start timer // m_ulTimer = CPlatformDepSystemCode::getMSCount(); // // // w = A*p; // pForwardProjector->project(); // // // alpha = gamma/dot(w,w); // float32 tmp = 0; // for (i = 0; i < w->getSize(); ++i) { // tmp += w->getData()[i] * w->getData()[i]; // } // alpha = gamma / tmp; // // x = x + alpha*p; // for (i = 0; i < m_pReconstruction->getSize(); ++i) { // m_pReconstruction->getData()[i] += alpha * p->getData()[i]; // } // // r = r - alpha*w; // for (i = 0; i < r->getSize(); ++i) { // r->getData()[i] -= alpha * w->getData()[i]; // } // // z = A'*r; // z->setData(0.0f); // pBackProjector->project(); // // CHECKME: should these be here? // // This was z. CHECK // if (m_bUseMinConstraint) // m_pReconstruction->clampMin(m_fMinValue); // if (m_bUseMaxConstraint) // m_pReconstruction->clampMax(m_fMaxValue); // // beta = 1/gamma; // beta = 1.0f / gamma; // // gamma = dot(z,z); // gamma = 0; // for (i = 0; i < z->getSize(); ++i) { // gamma += z->getData()[i] * z->getData()[i]; // } // // beta = gamma*beta; // beta *= gamma; // // p = z + beta*p; // for (i = 0; i < z->getSize(); ++i) { // p->getData()[i] = z->getData()[i] + beta * p->getData()[i]; // } // // // end timer // m_ulTotalTime += CPlatformDepSystemCode::getMSCount() - m_ulTimer; // // Compute metrics. // computeIterationMetrics(iIteration, _iNrIterations); // m_iIteration++; //} }
//---------------------------------------------------------------------------------------- // Iterate void CSirtAlgorithm::run(int _iNrIterations) { // check initialized ASTRA_ASSERT(m_bIsInitialized); m_bShouldAbort = false; int iIteration = 0; // data projectors CDataProjectorInterface* pForwardProjector; CDataProjectorInterface* pBackProjector; CDataProjectorInterface* pFirstForwardProjector; m_pTotalRayLength->setData(0.0f); m_pTotalPixelWeight->setData(0.0f); // forward projection data projector pForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // backprojection data projector pBackProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DefaultBPPolicy(m_pTmpVolume, m_pDiffSinogram), // backprojection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // first time forward projection data projector, // also computes total pixel weight and total ray length pFirstForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask Combine3Policy<DiffFPPolicy, TotalPixelWeightPolicy, TotalRayLengthPolicy>( // 3 basic operations DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation TotalPixelWeightPolicy(m_pTotalPixelWeight), // calculate the total pixel weights TotalRayLengthPolicy(m_pTotalRayLength)), // calculate the total ray lengths m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // forward projection, difference calculation and raylength/pixelweight computation pFirstForwardProjector->project(); float32* pfT = m_pTotalPixelWeight->getData(); for (int i = 0; i < m_pTotalPixelWeight->getSize(); ++i) { float32 x = pfT[i]; if (x < -eps || x > eps) x = 1.0f / x; else x = 0.0f; pfT[i] = x; } pfT = m_pTotalRayLength->getData(); for (int i = 0; i < m_pTotalRayLength->getSize(); ++i) { float32 x = pfT[i]; if (x < -eps || x > eps) x = 1.0f / x; else x = 0.0f; pfT[i] = x; } // divide by line weights (*m_pDiffSinogram) *= (*m_pTotalRayLength); // backprojection m_pTmpVolume->setData(0.0f); pBackProjector->project(); // divide by pixel weights (*m_pTmpVolume) *= (*m_pTotalPixelWeight); (*m_pReconstruction) += (*m_pTmpVolume); if (m_bUseMinConstraint) m_pReconstruction->clampMin(m_fMinValue); if (m_bUseMaxConstraint) m_pReconstruction->clampMax(m_fMaxValue); // update iteration count m_iIterationCount++; iIteration++; // iteration loop for (; iIteration < _iNrIterations && !m_bShouldAbort; ++iIteration) { // forward projection and difference calculation pForwardProjector->project(); // divide by line weights (*m_pDiffSinogram) *= (*m_pTotalRayLength); // backprojection m_pTmpVolume->setData(0.0f); pBackProjector->project(); // divide by pixel weights (*m_pTmpVolume) *= (*m_pTotalPixelWeight); (*m_pReconstruction) += (*m_pTmpVolume); if (m_bUseMinConstraint) m_pReconstruction->clampMin(m_fMinValue); if (m_bUseMaxConstraint) m_pReconstruction->clampMax(m_fMaxValue); // update iteration count m_iIterationCount++; } ASTRA_DELETE(pForwardProjector); ASTRA_DELETE(pBackProjector); ASTRA_DELETE(pFirstForwardProjector); }
//---------------------------------------------------------------------------------------- // Iterate void CSirtAlgorithm::run(int _iNrIterations) { // check initialized ASTRA_ASSERT(m_bIsInitialized); m_bShouldAbort = false; // data projectors CDataProjectorInterface* pForwardProjector; CDataProjectorInterface* pBackProjector; CDataProjectorInterface* pFirstForwardProjector; // Initialize m_pReconstruction to zero. if (m_bClearReconstruction) { m_pReconstruction->setData(0.f); } // forward projection data projector pForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // backprojection data projector pBackProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask SIRTBPPolicy(m_pReconstruction, m_pDiffSinogram, m_pTotalPixelWeight, m_pTotalRayLength, m_fAlpha), // SIRT backprojection m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // first time forward projection data projector, // also computes total pixel weight and total ray length pFirstForwardProjector = dispatchDataProjector( m_pProjector, SinogramMaskPolicy(m_pSinogramMask), // sinogram mask ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask Combine3Policy<DiffFPPolicy, TotalPixelWeightPolicy, TotalRayLengthPolicy>( // 3 basic operations DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation TotalPixelWeightPolicy(m_pTotalPixelWeight), // calculate the total pixel weights TotalRayLengthPolicy(m_pTotalRayLength)), // calculate the total ray lengths m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off ); // Perform the first forward projection to compute ray lengths and pixel weights m_pTotalRayLength->setData(0.0f); m_pTotalPixelWeight->setData(0.0f); pFirstForwardProjector->project(); // iteration loop, each iteration loops over all available projections for (int iIteration = 0; iIteration < _iNrIterations && !m_bShouldAbort; ++iIteration) { // start timer m_ulTimer = CPlatformDepSystemCode::getMSCount(); // forward projection to compute differences. pForwardProjector->project(); // backprojection pBackProjector->project(); // update iteration count m_iIterationCount++; if (m_bUseMinConstraint) m_pReconstruction->clampMin(m_fMinValue); if (m_bUseMaxConstraint) m_pReconstruction->clampMax(m_fMaxValue); // end timer m_ulTimer = CPlatformDepSystemCode::getMSCount() - m_ulTimer; // Compute metrics. computeIterationMetrics(iIteration, _iNrIterations, m_pDiffSinogram); } ASTRA_DELETE(pForwardProjector); ASTRA_DELETE(pBackProjector); ASTRA_DELETE(pFirstForwardProjector); //// check initialized //ASTRA_ASSERT(m_bIsInitialized); //m_bShouldAbort = false; //int iIteration = 0; //// data projectors //CDataProjectorInterface* pForwardProjector; //CDataProjectorInterface* pBackProjector; //CDataProjectorInterface* pFirstForwardProjector; //m_pTotalRayLength->setData(0.0f); //m_pTotalPixelWeight->setData(0.0f); //// forward projection data projector //pForwardProjector = dispatchDataProjector( // m_pProjector, // SinogramMaskPolicy(m_pSinogramMask), // sinogram mask // ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask // DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation // m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off // ); //// backprojection data projector //pBackProjector = dispatchDataProjector( // m_pProjector, // SinogramMaskPolicy(m_pSinogramMask), // sinogram mask // ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask // DefaultBPPolicy(m_pTmpVolume, m_pDiffSinogram), // backprojection // m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off // ); //// first time forward projection data projector, //// also computes total pixel weight and total ray length //pFirstForwardProjector = dispatchDataProjector( // m_pProjector, // SinogramMaskPolicy(m_pSinogramMask), // sinogram mask // ReconstructionMaskPolicy(m_pReconstructionMask), // reconstruction mask // Combine3Policy<DiffFPPolicy, TotalPixelWeightPolicy, TotalRayLengthPolicy>( // 3 basic operations // DiffFPPolicy(m_pReconstruction, m_pDiffSinogram, m_pSinogram), // forward projection with difference calculation // TotalPixelWeightPolicy(m_pTotalPixelWeight), // calculate the total pixel weights // TotalRayLengthPolicy(m_pTotalRayLength)), // calculate the total ray lengths // m_bUseSinogramMask, m_bUseReconstructionMask, true // options on/off // ); //// forward projection, difference calculation and raylength/pixelweight computation //pFirstForwardProjector->project(); //float32* pfT = m_pTotalPixelWeight->getData(); //for (int i = 0; i < m_pTotalPixelWeight->getSize(); ++i) { // float32 x = pfT[i]; // if (x < -eps || x > eps) // x = 1.0f / x; // else // x = 0.0f; // pfT[i] = x; //} //pfT = m_pTotalRayLength->getData(); //for (int i = 0; i < m_pTotalRayLength->getSize(); ++i) { // float32 x = pfT[i]; // if (x < -eps || x > eps) // x = 1.0f / x; // else // x = 0.0f; // pfT[i] = x; //} //// divide by line weights //(*m_pDiffSinogram) *= (*m_pTotalRayLength); //// backprojection //m_pTmpVolume->setData(0.0f); //pBackProjector->project(); //// divide by pixel weights //(*m_pTmpVolume) *= (*m_pTotalPixelWeight); //(*m_pReconstruction) += (*m_pTmpVolume); //if (m_bUseMinConstraint) // m_pReconstruction->clampMin(m_fMinValue); //if (m_bUseMaxConstraint) // m_pReconstruction->clampMax(m_fMaxValue); //// update iteration count //m_iIterationCount++; //iIteration++; // //// iteration loop //for (; iIteration < _iNrIterations && !m_bShouldAbort; ++iIteration) { // // forward projection and difference calculation // pForwardProjector->project(); // // divide by line weights // (*m_pDiffSinogram) *= (*m_pTotalRayLength); // // backprojection // m_pTmpVolume->setData(0.0f); // pBackProjector->project(); // // divide by pixel weights // (*m_pTmpVolume) *= (*m_pTotalPixelWeight); // (*m_pReconstruction) += (*m_pTmpVolume); // if (m_bUseMinConstraint) // m_pReconstruction->clampMin(m_fMinValue); // if (m_bUseMaxConstraint) // m_pReconstruction->clampMax(m_fMaxValue); // // update iteration count // m_iIterationCount++; //} //ASTRA_DELETE(pForwardProjector); //ASTRA_DELETE(pBackProjector); //ASTRA_DELETE(pFirstForwardProjector); }