/** * initialize before simulation begins. Rewind/forward any population model values to the start * time of the sequencer * * @param time */ public void initialize(STEMTime time) { EList<Decorator> redoList = new BasicEList<Decorator>(); boolean redo = false; for (Decorator d : this.getDecorators()) { if (d instanceof IntegrationDecorator) { EList<DynamicLabel> labels = d.getLabelsToUpdate(); for (DynamicLabel l : labels) { if (l instanceof IntegrationLabel) { IntegrationLabel il = (IntegrationLabel) l; il.reset(time); if (((SimpleDataExchangeLabelValue) il.getDeltaValue()).getArrivals().size() > 0 || ((SimpleDataExchangeLabelValue) il.getDeltaValue()).getDepartures().size() > 0) redo = true; } } } if (!redo) redoList.add(d); } // Fix decorators with unapplied deltas if (redo) { for (Decorator d : redoList) { if (d instanceof IntegrationDecorator) { EList<DynamicLabel> labels = d.getLabelsToUpdate(); for (DynamicLabel l : labels) { if (l instanceof IntegrationLabel) { IntegrationLabel il = (IntegrationLabel) l; il.reset(time); } } } } } this.setInitialized(true); }
/** * * <!-- begin-user-doc --> * <!-- end-user-doc --> * * @generated */ public Decorator getDecorator() { if (decorator != null && decorator.eIsProxy()) { InternalEObject oldDecorator = (InternalEObject) decorator; decorator = (Decorator) eResolveProxy(oldDecorator); if (decorator != oldDecorator) { if (eNotificationRequired()) eNotify( new ENotificationImpl( this, Notification.RESOLVE, TransportPackage.LOAD_UNLOAD_EDGE_LABEL__DECORATOR, oldDecorator, decorator)); } } return decorator; }
/** * _step Do the step for a single thread * * @param time * @param timeDelta * @param cycle * @param threadnum */ protected void _step(STEMTime time, long timeDelta, int cycle, short threadnum) { // this.setProgress(0.0); // We only deal with standard disease model decorators ArrayList<Decorator> iDecorators = new ArrayList<Decorator>(); for (Decorator d : getDecorators()) { if (d instanceof IntegrationDecorator) iDecorators.add(d); } // First we get the step size, either the default step size // (initially 1.0) or the last step size used. double h = this.getStepSize(); // x is to keep track of how far we have advanced in the solution. It is essentially // a double cycle representation double x = this.getCurrentX(); // Substantial performance can be gained here. Basically if the current cycle // is greater than the cycle requested by the simulation, we are done. This // means that the error tolerance between last step and this step is small // enough so we don't need to update the labels. The error tolerance is // specified in the disease model // *** OBSERVE: Since we limit h to max 1 below, this code is never invoked. It's kept // *** around in case we want to allow time to be calculated far out in the future if // *** the error is small enough if (x >= cycle) { // Just copy the next value the same as the current value for all labels for (Decorator sdm : iDecorators) { EList<DynamicLabel> myLabels = sdm.getLabelsToUpdate(threadnum, num_threads); int numLabels = myLabels.size(); double n = 0.0; int setProgressEveryNthNode = num_threads * numLabels / (MAX_PROGRESS_REPORTS); if (setProgressEveryNthNode == 0) setProgressEveryNthNode = 1; for (final Iterator<DynamicLabel> currentStateLabelIter = myLabels.iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); // The estimated disease value contains the value calculated at position x IntegrationLabelValue nextValueAtX = (IntegrationLabelValue) EcoreUtil.copy(diseaseLabel.getProbeValue()); IntegrationLabelValue currentValueAtCycle = (IntegrationLabelValue) diseaseLabel.getCurrentValue(); IntegrationLabelValue nextState = (IntegrationLabelValue) diseaseLabel.getNextValue(); adjustValuesToCycle(currentValueAtCycle, nextValueAtX, x, cycle); // NextValueAtX has been modified here to the correct value for this cycle. nextState.set(nextValueAtX); // The next value is valid now. diseaseLabel.setNextValueValid(true); double progress = n / numLabels; jobs[threadnum].setProgress(progress); if (n % setProgressEveryNthNode == 0) { // Get the progress for all threads for (int i = 0; i < num_threads; ++i) if (i != threadnum && jobs[i] != null) progress += jobs[i].getProgress(); progress /= num_threads; sdm.setProgress(progress); } n += 1.0; } } // For each decorator // So that validation code above is happy jobs[threadnum].h = h; jobs[threadnum].t = x; return; } // When x (or time) is this we're done double end = Math.floor(this.getCurrentX()) + 1.0; // Make sure we actually have labels to update boolean workToDo = false; for (Decorator sdm : iDecorators) if (sdm.getLabelsToUpdate(threadnum, num_threads).size() > 0) { workToDo = true; break; } if (!workToDo) { // Nothing to do, just advance x and set h jobs[threadnum].h = h; jobs[threadnum].t = x; // Be nice and walk in step with others until done while (x < end) { try { // Set to a large number to make sure it's larger than any step size reported // by another thread do { jobs[threadnum].h = Double.MAX_VALUE; stepSizeBarrier.await(); } while (this.maximumError > 1.0); updateDoneBarrier.await(); } catch (InterruptedException ie) { // Should never happen Activator.logError(ie.getMessage(), ie); } catch (BrokenBarrierException bbe) { // Should never happen Activator.logError(bbe.getMessage(), bbe); } // Set to the smallest value reported by another thread h = this.smallestH; x += h; jobs[threadnum].h = h; jobs[threadnum].t = x; } return; } // We use the Runge Kutta Kash Carp method to advance to the next // step in the simulation. Two estimates of the disease deltas // are calculated and compared to each other. If they differ // by more than a maximum error (determined by a parameter for // the disease model), we reduce the step size until an acceptable // error is reached. // These are used during Runge Kutta calculations: Map<IntegrationLabel, IntegrationLabelValue> k1map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); Map<IntegrationLabel, IntegrationLabelValue> k2map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); Map<IntegrationLabel, IntegrationLabelValue> k3map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); Map<IntegrationLabel, IntegrationLabelValue> k4map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); Map<IntegrationLabel, IntegrationLabelValue> k5map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); Map<IntegrationLabel, IntegrationLabelValue> k6map = new HashMap<IntegrationLabel, IntegrationLabelValue>(); // Used below as temporary place holder, one for each decorator IntegrationLabelValue _k1[], _k2[], _k3[], _k4[], _k5[], _k6[]; int numDecorators = iDecorators.size(); _k1 = new IntegrationLabelValue[numDecorators]; _k2 = new IntegrationLabelValue[numDecorators]; _k3 = new IntegrationLabelValue[numDecorators]; _k4 = new IntegrationLabelValue[numDecorators]; _k5 = new IntegrationLabelValue[numDecorators]; _k6 = new IntegrationLabelValue[numDecorators]; // The final estimates for label values are stored here Map<IntegrationLabel, IntegrationLabelValue> finalEstimate = new HashMap<IntegrationLabel, IntegrationLabelValue>(); // Delta is used to scale the step (h) double delta = 0.0; int n = 0; for (Decorator sdm : iDecorators) { Iterator<DynamicLabel> iter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); IntegrationLabel firstLabel = (IntegrationLabel) iter.next(); // Initialize temporary place holders just by creating dups of the first label available _k1[n] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); _k2[n] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); _k3[n] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); _k4[n] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); _k5[n] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); _k6[n++] = (IntegrationLabelValue) EcoreUtil.copy(firstLabel.getCurrentValue()); } // Keep track if whether anyone want to stop // or pause updating labels boolean interrupt = false, pause = false; // We keep these around to determine when to call setProgress(...) on the decorators. // If we call too frequently we can too many callbacks which affects performance. double nextProgressReportStep = num_threads * (end - x) / MAX_PROGRESS_REPORTS; double nextProgressReport = x + nextProgressReportStep; // HashMap<StandardDiseaseModelLabel, StandardDiseaseModelLabelValue> validate = new // HashMap<StandardDiseaseModelLabel, StandardDiseaseModelLabelValue>(); // This is the main loop we keep iterating over until we are done with the step while (x < end) { k1map.clear(); k2map.clear(); k3map.clear(); k4map.clear(); k5map.clear(); k6map.clear(); finalEstimate.clear(); // Validation code kept here if needed in the future /* HashMap<StandardDiseaseModelLabel, StandardDiseaseModelLabelValue> validate = new HashMap<StandardDiseaseModelLabel, StandardDiseaseModelLabelValue>(); if(!redo) for(StandardDiseaseModelImpl sdm:diseaseModelDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads) .iterator(); currentStateLabelIter.hasNext();) { final StandardDiseaseModelLabel diseaseLabel = (StandardDiseaseModelLabel) currentStateLabelIter .next(); final StandardDiseaseModelLabelValue val = (StandardDiseaseModelLabelValue)diseaseLabel.getCurrentDiseaseModelTempLabelValue(); validate.put(diseaseLabel, val); } } else { for(StandardDiseaseModelImpl sdm:diseaseModelDecorators) for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads) .iterator(); currentStateLabelIter.hasNext();) { final StandardDiseaseModelLabel diseaseLabel = (StandardDiseaseModelLabel) currentStateLabelIter .next(); final SIRLabelValue val = (SIRLabelValue)diseaseLabel.getCurrentDiseaseModelTempLabelValue(); validate.put(diseaseLabel, val); final SIRLabelValue oldVal = (SIRLabelValue)validate.get(diseaseLabel); if(val.getI() != oldVal.getI() || val.getS() != oldVal.getS() || val.getR() != oldVal.getR() || //val.getE() != oldVal.getE() || val.getBirths() != oldVal.getBirths() || val.getDeaths() != oldVal.getDeaths() || val.getDiseaseDeaths() != oldVal.getDiseaseDeaths() ) Activator.logError("Error, old and new value not the same label: "+diseaseLabel, new Exception()); } } */ // ToDo: We should check if a maximum number of iterations have been // exceeded here and throw an error. // First, get the delta values at the current state for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Set the scaling factor for disease parameters for each decorator and location for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue scale = (IntegrationLabelValue) diseaseLabel.getErrorScale(); scale.set((IntegrationLabelValue) diseaseLabel.getTempValue()); IntegrationLabelValue dt = (IntegrationLabelValue) EcoreUtil.copy(diseaseLabel.getDeltaValue()); dt.scale(h); dt.abs(); dt.add(TINY); scale.abs(); scale.add(dt); } } // Step 1 in Runge Kutta Fehlberg. // Get the delta values out of each node label and // build a first estimate of the next value' for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k1map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); deltaLabel.scale(h); deltaLabel.scale(b21); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(deltaLabel.add((IntegrationLabelValue) diseaseLabel.getTempValue())); } } // Now get the next delta values for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Step 2 in Runge Kutta Fehlberg. // Get the delta values out of each node label and // build a second estimate of the next value n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k2map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); _k1[n].set(k1map.get(diseaseLabel)); _k2[n].set(deltaLabel); IntegrationLabelValue estDelta = _k1[n].scale(b31); _k2[n].scale(b32); estDelta.add(_k2[n]); estDelta.scale(h); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(estDelta.add((IntegrationLabelValue) diseaseLabel.getTempValue())); } ++n; } // Now get the next delta values for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Step 3 in Runge Kutta Fehlberg. // Get the delta values out of each node label and // build a third estimate of the next value n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k3map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); _k1[n].set(k1map.get(diseaseLabel)); _k2[n].set(k2map.get(diseaseLabel)); _k3[n].set(deltaLabel); _k1[n].scale(b41); _k2[n].scale(b42); _k3[n].scale(b43); IntegrationLabelValue estDelta = _k1[n]; estDelta.add(_k2[n]); estDelta.add(_k3[n]); estDelta.scale(h); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(estDelta.add((IntegrationLabelValue) diseaseLabel.getTempValue())); } ++n; } // Now get the next delta values for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Step 4 in Runge Kutta Fehlberg. // Get the delta values out of each node label and // build a fourth estimate of the next value n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k4map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); _k1[n].set(k1map.get(diseaseLabel)); _k2[n].set(k2map.get(diseaseLabel)); _k3[n].set(k3map.get(diseaseLabel)); _k4[n].set(deltaLabel); _k1[n].scale(b51); _k2[n].scale(b52); _k3[n].scale(b53); _k4[n].scale(b54); IntegrationLabelValue estDelta = _k1[n]; estDelta.add(_k2[n]); estDelta.add(_k3[n]); estDelta.add(_k4[n]); estDelta.scale(h); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(estDelta.add((IntegrationLabelValue) diseaseLabel.getTempValue())); } ++n; } // Now get the next delta values for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Step 5 in Runge Kutta Fehlberg. // Get the delta values out of each node label and // build a fifth estimate of the next value n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k5map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); _k1[n].set(k1map.get(diseaseLabel)); _k2[n].set(k2map.get(diseaseLabel)); _k3[n].set(k3map.get(diseaseLabel)); _k4[n].set(k4map.get(diseaseLabel)); _k5[n].set(deltaLabel); _k1[n].scale(b61); _k2[n].scale(b62); _k3[n].scale(b63); _k4[n].scale(b64); _k5[n].scale(b65); IntegrationLabelValue estDelta = _k1[n]; estDelta.add(_k2[n]); estDelta.add(_k3[n]); estDelta.add(_k4[n]); estDelta.add(_k5[n]); estDelta.scale(h); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(estDelta.add((IntegrationLabelValue) diseaseLabel.getTempValue())); } ++n; } // Now get the next delta values for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .calculateDelta(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); for (Decorator sdm : iDecorators) ((IntegrationDecorator) sdm) .applyExternalDeltas(time, timeDelta, sdm.getLabelsToUpdate(threadnum, num_threads)); // Step 6 in Runge Kutta Fehlberg. // Calculate k6 n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue deltaLabel = (IntegrationLabelValue) diseaseLabel.getDeltaValue(); k6map.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(deltaLabel)); } ++n; } // Step 7 in Runge Kutta Fehlberg // Calculate the two estimates from k1, .. k6 values // and determine the maximum difference (error) between them. boolean success = true; // Were we able to update all labels without a large enough error? double maxerror = 0.0; n = 0; for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); IntegrationLabelValue currentValue = (IntegrationLabelValue) diseaseLabel.getTempValue(); _k1[n].set(k1map.get(diseaseLabel)); _k3[n].set(k3map.get(diseaseLabel)); _k4[n].set(k4map.get(diseaseLabel)); _k5[n].set(k5map.get(diseaseLabel)); _k6[n].set(k6map.get(diseaseLabel)); _k1[n].scale(c1); _k3[n].scale(c3); _k4[n].scale(c4); _k6[n].scale(c6); // New Y IntegrationLabelValue yout = (IntegrationLabelValue) EcoreUtil.copy(_k1[n].add(_k3[n]).add(_k4[n]).add(_k6[n])); yout.scale(h); yout.add(currentValue); // Get the error _k1[n].set(k1map.get(diseaseLabel)); _k3[n].set(k3map.get(diseaseLabel)); _k4[n].set(k4map.get(diseaseLabel)); _k5[n].set(k5map.get(diseaseLabel)); _k6[n].set(k6map.get(diseaseLabel)); _k1[n].scale(dc1); _k3[n].scale(dc3); _k4[n].scale(dc4); _k5[n].scale(dc5); _k6[n].scale(dc6); IntegrationLabelValue yerror = (IntegrationLabelValue) EcoreUtil.copy(_k1[n].add(_k3[n]).add(_k4[n]).add(_k5[n]).add(_k6[n])); yerror.scale(h); yerror.divide((IntegrationLabelValue) diseaseLabel.getErrorScale()); double error = yerror.max(); error /= relativeTolerance; if (error > maxerror) { maxerror = error; } if (error <= 1.0) finalEstimate.put(diseaseLabel, (IntegrationLabelValue) EcoreUtil.copy(yout)); } ++n; } jobs[threadnum].h = h; jobs[threadnum].maxerror = maxerror; try { stepSizeBarrier.await(); } catch (InterruptedException ie) { // Should never happen Activator.logError(ie.getMessage(), ie); } catch (BrokenBarrierException bbe) { // Should never happen Activator.logError(bbe.getMessage(), bbe); } // At least one of the threads had to large of an error, fail if (this.maximumError > 1.0) success = false; // Are we done? if (success) { // Check to make sure if (this.smallestH > h) Activator.logError( "Error, h was less than the smallest, perhaps barrier process failed to execute? h:" + h + " vs " + this.smallestH, new Exception()); // Yes, hurrah, advance x using the step size h x += h; if (this.maximumError > ERRCON) h = SAFETY * h * Math.pow(this.maximumError, PGROW); else h = 5.0 * h; // Limit to max 1 if (h > 1.0) h = 1.0; // Make sure we don't overshoot if (x < end && x + h > end) h = (end - x); // Update the current value to the new position for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); ((IntegrationLabelValue) diseaseLabel.getTempValue()) .set(finalEstimate.get(diseaseLabel)); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set(finalEstimate.get(diseaseLabel)); } } // Wait until all other threads have updated the current value try { updateDoneBarrier.await(); } catch (InterruptedException ie) { // Should never happen Activator.logError(ie.getMessage(), ie); } catch (BrokenBarrierException bbe) { // Should never happen Activator.logError(bbe.getMessage(), bbe); } double progress = (end - x < 0.0) ? 1.0 : 1.0 - (end - x); jobs[threadnum].setProgress(progress); if (x > nextProgressReport) { // Get the progress for all threads for (int i = 0; i < num_threads; ++i) if (i != threadnum && jobs[i] != null) progress += jobs[i].getProgress(); progress /= num_threads; for (Decorator sdm : iDecorators) sdm.setProgress(progress); nextProgressReport += nextProgressReportStep; } } else { // At least one thread failed, change the step size // Problem, error too big, we need to reduce the step size delta = SAFETY * h * Math.pow(this.maximumError, PSHRNK); if (h > 0.0) h = (delta > 0.1 * h) ? delta : 0.1 * h; else h = (delta > 0.1 * h) ? 0.1 * h : delta; // We didn't succeed. // Reset the estimated value back to the original, the step size // has been reduced so we well try again. // Set the estimated value back to the current original value for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); ((IntegrationLabelValue) diseaseLabel.getProbeValue()) .set((IntegrationLabelValue) diseaseLabel.getTempValue()); } } } } // While x < end jobs[threadnum].t = x; jobs[threadnum].h = h; // Remember the step size and position in the solver this.setStepSize(h); this.setCurrentX(x); // We're done for (Decorator sdm : iDecorators) { for (final Iterator<DynamicLabel> currentStateLabelIter = sdm.getLabelsToUpdate(threadnum, num_threads).iterator(); currentStateLabelIter.hasNext(); ) { final IntegrationLabel diseaseLabel = (IntegrationLabel) currentStateLabelIter.next(); // This is the next state for the label IntegrationLabelValue nextState = (IntegrationLabelValue) diseaseLabel.getNextValue(); // This is the original current state at the previous cycle IntegrationLabelValue originalState = (IntegrationLabelValue) diseaseLabel.getCurrentValue(); // This is the final value calculated at position x. IntegrationLabelValue newValue = finalEstimate.get(diseaseLabel); // x could be larger than the requested cycle, so we do a linear interpolation // to fit it exactly to the requested cycle // *** Not needed since we always end exactly at the requested cycle // adjustValuesToCycle(originalState, newValue, x, cycle); // New value has been modified here to fit the requested cycle nextState.set(newValue); // Do any model specific work for instance add noise ((IntegrationDecorator) sdm).doModelSpecificAdjustments((LabelValue) nextState); // The next value is valid now. diseaseLabel.setNextValueValid(true); } } }
/** * * <!-- begin-user-doc --> * <!-- end-user-doc --> * * @generated NOT */ @Override public boolean step(STEMTime time, long timeDelta, int cycle) { // Validate all decorators that return deltas to make sure // they are of deterministic nature. The Runge Kutta integratio // can only handle determininistic variants for (Decorator decorator : this.getDecorators()) if (decorator instanceof IntegrationDecorator) { IntegrationDecorator idec = (IntegrationDecorator) decorator; if (!idec.isDeterministic()) { Activator.logError( "Error, decorator: " + idec + " is not deterministic. The Runge Kutta Integrator can only handle deterministic models.", new Exception()); return false; } } Activator act = org.eclipse.stem.ui.Activator.getDefault(); if (act != null) { final Preferences preferences = act.getPluginPreferences(); num_threads = (short) preferences.getInt( org.eclipse.stem.ui.preferences.PreferenceConstants.SIMULATION_THREADS); } else num_threads = 2; // Just so we can run inside junit test final int c = cycle; // Initialize latches stepSizeBarrier = new CyclicBarrier( num_threads, new Runnable() { public void run() { // All threads successfully advanced time by some step h. // Find the smallest smallestH = Double.MAX_VALUE; maximumError = -Double.MAX_VALUE; for (int i = 0; i < num_threads; ++i) { if (jobs[i].h <= smallestH) { if (maximumError < jobs[i].maxerror) maximumError = jobs[i].maxerror; smallestH = jobs[i].h; } } } }); updateDoneBarrier = new CyclicBarrier(num_threads); // Find triggers and make sure they are invoked for (Decorator decorator : this.getDecorators()) { if (decorator instanceof Trigger) { decorator.updateLabels(time, timeDelta, cycle); } } // First initialize the probe and temp label values from the current // label values. for (Decorator decorator : this.getDecorators()) { EList<DynamicLabel> allLabels = decorator.getLabelsToUpdate(); for (final Iterator<DynamicLabel> currentStateLabelIter = allLabels.iterator(); currentStateLabelIter.hasNext(); ) { if (decorator instanceof IntegrationDecorator) { // It's a standard disease model with a standard disease model label final IntegrationLabel iLabel = (IntegrationLabel) currentStateLabelIter.next(); ((IntegrationLabelValue) iLabel.getProbeValue()) .set((IntegrationLabelValue) iLabel.getCurrentValue()); ((IntegrationLabelValue) iLabel.getTempValue()) .set((IntegrationLabelValue) iLabel.getCurrentValue()); ((IntegrationLabelValue) iLabel.getTempValue()).prepareCycle(); ((IntegrationLabelValue) iLabel.getProbeValue()).prepareCycle(); } else currentStateLabelIter.next(); } } if (jobs == null || jobs.length != num_threads) { // Initialize the jobs if not done yet or of the number of threads changes jobs = new RkJob[num_threads]; for (short i = 0; i < num_threads; ++i) { final short threadnum = i; jobs[i] = new RkJob("Worker " + i, threadnum, this); } // For each job } // If not initialized // Initialize int thread = 0; for (RkJob j : jobs) { j.cycle = c; j.time = time; j.timeDelta = timeDelta; } // Schedule. Jobs can be rescheduled after finished for (RkJob j : jobs) j.schedule(); // Wait until all jobs completed for (RkJob j : jobs) { try { j.join(); } catch (InterruptedException ie) { Activator.logError(ie.getMessage(), ie); } } // Set the common time and step size here and validate everything is right double minStep = Double.MAX_VALUE; double currentT = jobs[0].t; for (RkJob j : jobs) { // The jobs have calculated new step sizes after they finished. Pick the // smallest one for the next cycle if (j.h < minStep) minStep = j.h; if (j.t != currentT) Activator.logError( "Error, one thread was in misstep with other threads, its time was " + j.t + " versus " + currentT, new Exception()); } return true; }