void FakeMDEventData::addFakeUniformData( typename MDEventWorkspace<MDE, nd>::sptr ws) { std::vector<double> params = getProperty("UniformParams"); if (params.empty()) return; bool randomEvents = true; if (params[0] < 0) { randomEvents = false; params[0] = -params[0]; } if (params.size() == 1) { if (randomEvents) { for (size_t d = 0; d < nd; ++d) { params.push_back(ws->getDimension(d)->getMinimum()); params.push_back(ws->getDimension(d)->getMaximum()); } } else // regular events { size_t nPoints = size_t(params[0]); double Vol = 1; for (size_t d = 0; d < nd; ++d) Vol *= (ws->getDimension(d)->getMaximum() - ws->getDimension(d)->getMinimum()); if (Vol == 0 || Vol > std::numeric_limits<float>::max()) throw std::invalid_argument( " Domain ranges are not defined properly for workspace: " + ws->getName()); double dV = Vol / double(nPoints); double delta0 = std::pow(dV, 1. / double(nd)); for (size_t d = 0; d < nd; ++d) { double min = ws->getDimension(d)->getMinimum(); params.push_back(min * (1 + FLT_EPSILON) - min + FLT_EPSILON); double extent = ws->getDimension(d)->getMaximum() - min; size_t nStrides = size_t(extent / delta0); if (nStrides < 1) nStrides = 1; params.push_back(extent / static_cast<double>(nStrides)); } } } if ((params.size() != 1 + nd * 2)) throw std::invalid_argument( "UniformParams: needs to have ndims*2+1 arguments "); if (randomEvents) addFakeRandomData<MDE, nd>(params, ws); else addFakeRegularData<MDE, nd>(params, ws); ws->splitBox(); Kernel::ThreadScheduler *ts = new ThreadSchedulerFIFO(); ThreadPool tp(ts); ws->splitAllIfNeeded(ts); tp.joinAll(); ws->refreshCache(); }
void MinusMD::doMinus(typename MDEventWorkspace<MDE, nd>::sptr ws) { typename MDEventWorkspace<MDE, nd>::sptr ws1 = ws; typename MDEventWorkspace<MDE, nd>::sptr ws2 = boost::dynamic_pointer_cast<MDEventWorkspace<MDE, nd> >(m_operand_event); if (!ws1 || !ws2) throw std::runtime_error("Incompatible workspace types passed to MinusMD."); MDBoxBase<MDE,nd> * box1 = ws1->getBox(); MDBoxBase<MDE,nd> * box2 = ws2->getBox(); Progress prog(this, 0.0, 0.4, box2->getBoxController()->getTotalNumMDBoxes()); // How many events you started with size_t initial_numEvents = ws1->getNPoints(); // Make a leaf-only iterator through all boxes with events in the RHS workspace MDBoxIterator<MDE,nd> it2(box2, 1000, true); do { MDBox<MDE,nd> * box = dynamic_cast<MDBox<MDE,nd> *>(it2.getBox()); if (box) { // Copy the events from WS2 and add them into WS1 const std::vector<MDE> & events = box->getConstEvents(); // Perform a copy while flipping the signal std::vector<MDE> eventsCopy; eventsCopy.reserve(events.size()); for (auto it = events.begin(); it != events.end(); it++) { MDE eventCopy(*it); eventCopy.setSignal( -eventCopy.getSignal()); eventsCopy.push_back(eventCopy); } // Add events, with bounds checking box1->addEvents(eventsCopy); box->releaseEvents(); } prog.report("Adding Events"); } while (it2.next()); this->progress(0.41, "Splitting Boxes"); Progress * prog2 = new Progress(this, 0.4, 0.9, 100); ThreadScheduler * ts = new ThreadSchedulerFIFO(); ThreadPool tp(ts, 0, prog2); ws1->splitAllIfNeeded(ts); prog2->resetNumSteps( ts->size(), 0.4, 0.6); tp.joinAll(); this->progress(0.95, "Refreshing cache"); ws1->refreshCache(); // Set a marker that the file-back-end needs updating if the # of events changed. if (ws1->getNPoints() != initial_numEvents) ws1->setFileNeedsUpdating(true); }
void SliceMD::slice(typename MDEventWorkspace<MDE, nd>::sptr ws) { // Create the ouput workspace typename MDEventWorkspace<OMDE, ond>::sptr outWS( new MDEventWorkspace<OMDE, ond>()); for (size_t od = 0; od < m_binDimensions.size(); od++) { outWS->addDimension(m_binDimensions[od]); } outWS->setCoordinateSystem(ws->getSpecialCoordinateSystem()); outWS->initialize(); // Copy settings from the original box controller BoxController_sptr bc = ws->getBoxController(); // store wrute buffer size for the future // uint64_t writeBufSize = // bc->getFileIO()getDiskBuffer().getWriteBufferSize(); // and disable write buffer (if any) for input MD Events for this algorithm // purposes; // bc->setCacheParameters(1,0); BoxController_sptr obc = outWS->getBoxController(); // Use the "number of bins" as the "split into" parameter for (size_t od = 0; od < m_binDimensions.size(); od++) obc->setSplitInto(od, m_binDimensions[od]->getNBins()); obc->setSplitThreshold(bc->getSplitThreshold()); bool bTakeDepthFromInputWorkspace = getProperty("TakeMaxRecursionDepthFromInput"); int tempDepth = getProperty("MaxRecursionDepth"); size_t maxDepth = bTakeDepthFromInputWorkspace ? bc->getMaxDepth() : size_t(tempDepth); obc->setMaxDepth(maxDepth); // size_t outputSize = writeBufSize; // obc->setCacheParameters(sizeof(OMDE),outputSize); obc->resetNumBoxes(); // Perform the first box splitting outWS->splitBox(); size_t lastNumBoxes = obc->getTotalNumMDBoxes(); // --- File back end ? ---------------- std::string filename = getProperty("OutputFilename"); if (!filename.empty()) { // First save to the NXS file g_log.notice() << "Running SaveMD to create file back-end" << std::endl; IAlgorithm_sptr alg = createChildAlgorithm("SaveMD"); alg->setPropertyValue("Filename", filename); alg->setProperty("InputWorkspace", outWS); alg->setProperty("MakeFileBacked", true); alg->executeAsChildAlg(); if (!obc->isFileBacked()) throw std::runtime_error("SliceMD with file-backed output: Can not set " "up file-backed output workspace "); auto IOptr = obc->getFileIO(); size_t outBufSize = IOptr->getWriteBufferSize(); // the buffer size for resulting workspace; reasonable size is at least 10 // data chunk sizes (nice to verify) if (outBufSize < 10 * IOptr->getDataChunk()) { outBufSize = 10 * IOptr->getDataChunk(); IOptr->setWriteBufferSize(outBufSize); } } // Function defining which events (in the input dimensions) to place in the // output MDImplicitFunction *function = this->getImplicitFunctionForChunk(NULL, NULL); std::vector<API::IMDNode *> boxes; // Leaf-only; no depth limit; with the implicit function passed to it. ws->getBox()->getBoxes(boxes, 1000, true, function); // Sort boxes by file position IF file backed. This reduces seeking time, // hopefully. bool fileBackedWS = bc->isFileBacked(); if (fileBackedWS) API::IMDNode::sortObjByID(boxes); Progress *prog = new Progress(this, 0.0, 1.0, boxes.size()); // The root of the output workspace MDBoxBase<OMDE, ond> *outRootBox = outWS->getBox(); // if target workspace has events, we should count them as added uint64_t totalAdded = outWS->getNEvents(); uint64_t numSinceSplit = 0; // Go through every box for this chunk. // PARALLEL_FOR_IF( !bc->isFileBacked() ) for (int i = 0; i < int(boxes.size()); i++) { MDBox<MDE, nd> *box = dynamic_cast<MDBox<MDE, nd> *>(boxes[i]); // Perform the binning in this separate method. if (box) { // An array to hold the rotated/transformed coordinates coord_t outCenter[ond]; const std::vector<MDE> &events = box->getConstEvents(); typename std::vector<MDE>::const_iterator it = events.begin(); typename std::vector<MDE>::const_iterator it_end = events.end(); for (; it != it_end; it++) { // Cache the center of the event (again for speed) const coord_t *inCenter = it->getCenter(); if (function->isPointContained(inCenter)) { // Now transform to the output dimensions m_transformFromOriginal->apply(inCenter, outCenter); // Create the event OMDE newEvent(it->getSignal(), it->getErrorSquared(), outCenter); // Copy extra data, if any copyEvent(*it, newEvent); // Add it to the workspace outRootBox->addEvent(newEvent); numSinceSplit++; } } box->releaseEvents(); // Ask BC if one needs to split boxes if (obc->shouldSplitBoxes(totalAdded, numSinceSplit, lastNumBoxes)) // if (numSinceSplit > 20000000 || (i == int(boxes.size()-1))) { // This splits up all the boxes according to split thresholds and sizes. Kernel::ThreadScheduler *ts = new ThreadSchedulerFIFO(); ThreadPool tp(ts); outWS->splitAllIfNeeded(ts); tp.joinAll(); // Accumulate stats totalAdded += numSinceSplit; numSinceSplit = 0; lastNumBoxes = obc->getTotalNumMDBoxes(); // Progress reporting if (!fileBackedWS) prog->report(i); } if (fileBackedWS) { if (!(i % 10)) prog->report(i); } } // is box } // for each box in the vector prog->report(); outWS->splitAllIfNeeded(NULL); // Refresh all cache. outWS->refreshCache(); g_log.notice() << totalAdded << " " << OMDE::getTypeName() << "'s added to the output workspace." << std::endl; if (outWS->isFileBacked()) { // Update the file-back-end g_log.notice() << "Running SaveMD" << std::endl; IAlgorithm_sptr alg = createChildAlgorithm("SaveMD"); alg->setProperty("UpdateFileBackEnd", true); alg->setProperty("InputWorkspace", outWS); alg->executeAsChildAlg(); } // return the size of the input workspace write buffer to its initial value // bc->setCacheParameters(sizeof(MDE),writeBufSize); this->setProperty("OutputWorkspace", boost::dynamic_pointer_cast<IMDEventWorkspace>(outWS)); delete prog; }
void PlusMD::doPlus(typename MDEventWorkspace<MDE, nd>::sptr ws) { typename MDEventWorkspace<MDE, nd>::sptr ws1 = ws; typename MDEventWorkspace<MDE, nd>::sptr ws2 = boost::dynamic_pointer_cast<MDEventWorkspace<MDE, nd> >(m_operand_event); if (!ws1 || !ws2) throw std::runtime_error("Incompatible workspace types passed to PlusMD."); MDBoxBase<MDE,nd> * box1 = ws1->getBox(); MDBoxBase<MDE,nd> * box2 = ws2->getBox(); Progress prog(this, 0.0, 0.4, box2->getBoxController()->getTotalNumMDBoxes()); // How many events you started with size_t initial_numEvents = ws1->getNPoints(); // Make a leaf-only iterator through all boxes with events in the RHS workspace MDBoxIterator<MDE,nd> it2(box2, 1000, true); do { MDBox<MDE,nd> * box = dynamic_cast<MDBox<MDE,nd> *>(it2.getBox()); if (box) { // Copy the events from WS2 and add them into WS1 const std::vector<MDE> & events = box->getConstEvents(); // Add events, with bounds checking box1->addEvents(events); box->releaseEvents(); } prog.report("Adding Events"); } while (it2.next()); this->progress(0.41, "Splitting Boxes"); Progress * prog2 = new Progress(this, 0.4, 0.9, 100); ThreadScheduler * ts = new ThreadSchedulerFIFO(); ThreadPool tp(ts, 0, prog2); ws1->splitAllIfNeeded(ts); prog2->resetNumSteps( ts->size(), 0.4, 0.6); tp.joinAll(); // // Now we need to save all the data that was not saved before. // if (ws1->isFileBacked()) // { // // Flush anything else in the to-write buffer // BoxController_sptr bc = ws1->getBoxController(); // // prog.resetNumSteps(bc->getTotalNumMDBoxes(), 0.6, 1.0); // MDBoxIterator<MDE,nd> it1(box1, 1000, true); // while (true) // { // MDBox<MDE,nd> * box = dynamic_cast<MDBox<MDE,nd> *>(it1.getBox()); // if (box) // { // // Something was maybe added to this box // if (box->getEventVectorSize() > 0) // { // // By getting the events, this will merge the newly added and the cached events. // box->getEvents(); // // The MRU to-write cache will optimize writes by reducing seek times // box->releaseEvents(); // } // } // prog.report("Saving"); // if (!it1.next()) break; // } // //bc->getDiskBuffer().flushCache(); // // Flush the data writes to disk. // box1->flushData(); // } this->progress(0.95, "Refreshing cache"); ws1->refreshCache(); // Set a marker that the file-back-end needs updating if the # of events changed. if (ws1->getNPoints() != initial_numEvents) ws1->setFileNeedsUpdating(true); }
void FakeMDEventData::addFakePeak(typename MDEventWorkspace<MDE, nd>::sptr ws) { std::vector<double> params = getProperty("PeakParams"); bool RandomizeSignal = getProperty("RandomizeSignal"); if (params.empty()) return; if (params.size() != nd + 2) throw std::invalid_argument("PeakParams needs to have ndims+2 arguments."); if (params[0] <= 0) throw std::invalid_argument("PeakParams: number_of_events needs to be > 0"); size_t num = size_t(params[0]); Progress prog(this, 0.0, 1.0, 100); size_t progIncrement = num / 100; if (progIncrement == 0) progIncrement = 1; // Width of the peak double desiredRadius = params.back(); boost::mt19937 rng; boost::uniform_real<coord_t> u2(0, 1.0); // Random from 0 to 1.0 boost::variate_generator<boost::mt19937 &, boost::uniform_real<coord_t>> genUnit(rng, u2); int randomSeed = getProperty("RandomSeed"); rng.seed((unsigned int)(randomSeed)); // Inserter to help choose the correct event type auto eventHelper = MDEvents::MDEventInserter<typename MDEventWorkspace<MDE, nd>::sptr>(ws); for (size_t i = 0; i < num; ++i) { // Algorithm to generate points along a random n-sphere (sphere with not // necessarily 3 dimensions) // from http://en.wikipedia.org/wiki/N-sphere as of May 6, 2011. // First, points in a hyper-cube of size 1.0, centered at 0. coord_t centers[nd]; coord_t radiusSquared = 0; for (size_t d = 0; d < nd; d++) { centers[d] = genUnit() - 0.5f; // Distribute around +- the center radiusSquared += centers[d] * centers[d]; } // Make a unit vector pointing in this direction coord_t radius = static_cast<coord_t>(sqrt(radiusSquared)); for (size_t d = 0; d < nd; d++) centers[d] /= radius; // Now place the point along this radius, scaled with ^1/n for uniformity. coord_t radPos = genUnit(); radPos = static_cast<coord_t>( pow(radPos, static_cast<coord_t>(1.0 / static_cast<coord_t>(nd)))); for (size_t d = 0; d < nd; d++) { // Multiply by the scaling and the desired peak radius centers[d] *= (radPos * static_cast<coord_t>(desiredRadius)); // Also offset by the center of the peak, as taken in Params centers[d] += static_cast<coord_t>(params[d + 1]); } // Default or randomized error/signal float signal = 1.0; float errorSquared = 1.0; if (RandomizeSignal) { signal = float(0.5 + genUnit()); errorSquared = float(0.5 + genUnit()); } // Create and add the event. eventHelper.insertMDEvent(signal, errorSquared, 1, pickDetectorID(), centers); // 1 = run number // Progress report if ((i % progIncrement) == 0) prog.report(); } ws->splitBox(); Kernel::ThreadScheduler *ts = new ThreadSchedulerFIFO(); ThreadPool tp(ts); ws->splitAllIfNeeded(ts); tp.joinAll(); ws->refreshCache(); }