bool BlockSolver<Traits>::buildSystem() { // clear b vector # ifdef G2O_OPENMP # pragma omp parallel for default (shared) if (_optimizer->indexMapping().size() > 1000) # endif for (int i = 0; i < static_cast<int>(_optimizer->indexMapping().size()); ++i) { OptimizableGraph::Vertex* v=_optimizer->indexMapping()[i]; assert(v); v->clearQuadraticForm(); } _Hpp->clear(); if (_doSchur) { _Hll->clear(); _Hpl->clear(); } // resetting the terms for the pairwise constraints // built up the current system by storing the Hessian blocks in the edges and vertices # ifndef G2O_OPENMP // no threading, we do not need to copy the workspace JacobianWorkspace& jacobianWorkspace = _optimizer->jacobianWorkspace(); # else // if running with threads need to produce copies of the workspace for each thread JacobianWorkspace jacobianWorkspace = _optimizer->jacobianWorkspace(); # pragma omp parallel for default (shared) firstprivate(jacobianWorkspace) if (_optimizer->activeEdges().size() > 100) # endif for (int k = 0; k < static_cast<int>(_optimizer->activeEdges().size()); ++k) { OptimizableGraph::Edge* e = _optimizer->activeEdges()[k]; e->linearizeOplus(jacobianWorkspace); // jacobian of the nodes' oplus (manifold) e->constructQuadraticForm(); # ifndef NDEBUG for (size_t i = 0; i < e->vertices().size(); ++i) { const OptimizableGraph::Vertex* v = static_cast<const OptimizableGraph::Vertex*>(e->vertex(i)); if (! v->fixed()) { bool hasANan = arrayHasNaN(jacobianWorkspace.workspaceForVertex(i), e->dimension() * v->dimension()); if (hasANan) { std::cerr << "buildSystem(): NaN within Jacobian for edge " << e << " for vertex " << i << std::endl; break; } } } # endif } // flush the current system in a sparse block matrix # ifdef G2O_OPENMP # pragma omp parallel for default (shared) if (_optimizer->indexMapping().size() > 1000) # endif for (int i = 0; i < static_cast<int>(_optimizer->indexMapping().size()); ++i) { OptimizableGraph::Vertex* v=_optimizer->indexMapping()[i]; int iBase = v->colInHessian(); if (v->marginalized()) iBase+=_sizePoses; v->copyB(_b+iBase); } return 0; }
void SparseOptimizer::linearizeSystem() { # ifdef G2O_OPENMP # pragma omp parallel for default (shared) if (_activeEdges.size() > 50) # endif for (size_t k = 0; k < _activeEdges.size(); ++k) { OptimizableGraph::Edge* e = _activeEdges[k]; // jacobian of the nodes' oplus (manifold) e->linearizeOplus(); } }
bool SparseOptimizerIncremental::updateInitialization(HyperGraph::VertexSet& vset, HyperGraph::EdgeSet& eset) { if (batchStep) { return SparseOptimizerOnline::updateInitialization(vset, eset); } for (HyperGraph::VertexSet::iterator it = vset.begin(); it != vset.end(); ++it) { OptimizableGraph::Vertex* v = static_cast<OptimizableGraph::Vertex*>(*it); v->clearQuadraticForm(); // be sure that b is zero for this vertex } // get the touched vertices _touchedVertices.clear(); for (HyperGraph::EdgeSet::iterator it = eset.begin(); it != eset.end(); ++it) { OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it); OptimizableGraph::Vertex* v1 = static_cast<OptimizableGraph::Vertex*>(e->vertices()[0]); OptimizableGraph::Vertex* v2 = static_cast<OptimizableGraph::Vertex*>(e->vertices()[1]); if (! v1->fixed()) _touchedVertices.insert(v1); if (! v2->fixed()) _touchedVertices.insert(v2); } //cerr << PVAR(_touchedVertices.size()) << endl; // updating the internal structures std::vector<HyperGraph::Vertex*> newVertices; newVertices.reserve(vset.size()); _activeVertices.reserve(_activeVertices.size() + vset.size()); _activeEdges.reserve(_activeEdges.size() + eset.size()); for (HyperGraph::EdgeSet::iterator it = eset.begin(); it != eset.end(); ++it) _activeEdges.push_back(static_cast<OptimizableGraph::Edge*>(*it)); //cerr << "updating internal done." << endl; // update the index mapping size_t next = _ivMap.size(); for (HyperGraph::VertexSet::iterator it = vset.begin(); it != vset.end(); ++it) { OptimizableGraph::Vertex* v=static_cast<OptimizableGraph::Vertex*>(*it); if (! v->fixed()){ if (! v->marginalized()){ v->setHessianIndex(next); _ivMap.push_back(v); newVertices.push_back(v); _activeVertices.push_back(v); next++; } else // not supported right now abort(); } else { v->setHessianIndex(-1); } } //cerr << "updating index mapping done." << endl; // backup the tempindex and prepare sorting structure VertexBackup backupIdx[_touchedVertices.size()]; memset(backupIdx, 0, sizeof(VertexBackup) * _touchedVertices.size()); int idx = 0; for (HyperGraph::VertexSet::iterator it = _touchedVertices.begin(); it != _touchedVertices.end(); ++it) { OptimizableGraph::Vertex* v = static_cast<OptimizableGraph::Vertex*>(*it); backupIdx[idx].hessianIndex = v->hessianIndex(); backupIdx[idx].vertex = v; backupIdx[idx].hessianData = v->hessianData(); ++idx; } sort(backupIdx, backupIdx + _touchedVertices.size()); // sort according to the hessianIndex which is the same order as used later by the optimizer for (int i = 0; i < idx; ++i) { backupIdx[i].vertex->setHessianIndex(i); } //cerr << "backup tempindex done." << endl; // building the structure of the update _updateMat.clear(true); // get rid of the old matrix structure _updateMat.rowBlockIndices().clear(); _updateMat.colBlockIndices().clear(); _updateMat.blockCols().clear(); // placing the current stuff in _updateMat MatrixXd* lastBlock = 0; int sizePoses = 0; for (int i = 0; i < idx; ++i) { OptimizableGraph::Vertex* v = backupIdx[i].vertex; int dim = v->dimension(); sizePoses+=dim; _updateMat.rowBlockIndices().push_back(sizePoses); _updateMat.colBlockIndices().push_back(sizePoses); _updateMat.blockCols().push_back(SparseBlockMatrix<MatrixXd>::IntBlockMap()); int ind = v->hessianIndex(); //cerr << PVAR(ind) << endl; if (ind >= 0) { MatrixXd* m = _updateMat.block(ind, ind, true); v->mapHessianMemory(m->data()); lastBlock = m; } } lastBlock->diagonal().array() += 1e-6; // HACK to get Eigen value > 0 for (HyperGraph::EdgeSet::const_iterator it = eset.begin(); it != eset.end(); ++it) { OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it); OptimizableGraph::Vertex* v1 = (OptimizableGraph::Vertex*) e->vertices()[0]; OptimizableGraph::Vertex* v2 = (OptimizableGraph::Vertex*) e->vertices()[1]; int ind1 = v1->hessianIndex(); if (ind1 == -1) continue; int ind2 = v2->hessianIndex(); if (ind2 == -1) continue; bool transposedBlock = ind1 > ind2; if (transposedBlock) // make sure, we allocate the upper triangular block swap(ind1, ind2); MatrixXd* m = _updateMat.block(ind1, ind2, true); e->mapHessianMemory(m->data(), 0, 1, transposedBlock); } // build the system into _updateMat for (HyperGraph::EdgeSet::iterator it = eset.begin(); it != eset.end(); ++it) { OptimizableGraph::Edge * e = static_cast<OptimizableGraph::Edge*>(*it); e->computeError(); } for (HyperGraph::EdgeSet::iterator it = eset.begin(); it != eset.end(); ++it) { OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it); e->linearizeOplus(); } for (HyperGraph::EdgeSet::iterator it = eset.begin(); it != eset.end(); ++it) { OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it); e->constructQuadraticForm(); } // restore the original data for the vertex for (int i = 0; i < idx; ++i) { backupIdx[i].vertex->setHessianIndex(backupIdx[i].hessianIndex); if (backupIdx[i].hessianData) backupIdx[i].vertex->mapHessianMemory(backupIdx[i].hessianData); } // update the structure of the real block matrix bool solverStatus = _algorithm->updateStructure(newVertices, eset); bool updateStatus = computeCholeskyUpdate(); if (! updateStatus) { cerr << "Error while computing update" << endl; } cholmod_sparse* updateAsSparseFactor = cholmod_factor_to_sparse(_cholmodFactor, &_cholmodCommon); // convert CCS update by permuting back to the permutation of L if (updateAsSparseFactor->nzmax > _permutedUpdate->nzmax) { //cerr << "realloc _permutedUpdate" << endl; cholmod_reallocate_triplet(updateAsSparseFactor->nzmax, _permutedUpdate, &_cholmodCommon); } _permutedUpdate->nnz = 0; _permutedUpdate->nrow = _permutedUpdate->ncol = _L->n; { int* Ap = (int*)updateAsSparseFactor->p; int* Ai = (int*)updateAsSparseFactor->i; double* Ax = (double*)updateAsSparseFactor->x; int* Bj = (int*)_permutedUpdate->j; int* Bi = (int*)_permutedUpdate->i; double* Bx = (double*)_permutedUpdate->x; for (size_t c = 0; c < updateAsSparseFactor->ncol; ++c) { const int& rbeg = Ap[c]; const int& rend = Ap[c+1]; int cc = c / slamDimension; int coff = c % slamDimension; const int& cbase = backupIdx[cc].vertex->colInHessian(); const int& ccol = _perm(cbase + coff); for (int j = rbeg; j < rend; j++) { const int& r = Ai[j]; const double& val = Ax[j]; int rr = r / slamDimension; int roff = r % slamDimension; const int& rbase = backupIdx[rr].vertex->colInHessian(); int row = _perm(rbase + roff); int col = ccol; if (col > row) // lower triangular entry swap(col, row); Bi[_permutedUpdate->nnz] = row; Bj[_permutedUpdate->nnz] = col; Bx[_permutedUpdate->nnz] = val; ++_permutedUpdate->nnz; } } } cholmod_free_sparse(&updateAsSparseFactor, &_cholmodCommon); #if 0 cholmod_sparse* updatePermuted = cholmod_triplet_to_sparse(_permutedUpdate, _permutedUpdate->nnz, &_cholmodCommon); //writeCCSMatrix("update-permuted.txt", updatePermuted->nrow, updatePermuted->ncol, (int*)updatePermuted->p, (int*)updatePermuted->i, (double*)updatePermuted->x, false); _solverInterface->choleskyUpdate(updatePermuted); cholmod_free_sparse(&updatePermuted, &_cholmodCommon); #else convertTripletUpdateToSparse(); _solverInterface->choleskyUpdate(_permutedUpdateAsSparse); #endif return solverStatus; }