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Example 6 with DemographicModel

use of dr.evomodel.coalescent.demographicmodel.DemographicModel in project beast-mcmc by beast-dev.

the class CoalescentSimulatorParser method parseXMLObject.

public Object parseXMLObject(XMLObject xo) throws XMLParseException {
    CoalescentSimulator simulator = new CoalescentSimulator();
    DemographicModel demoModel = (DemographicModel) xo.getChild(DemographicModel.class);
    List<TaxonList> taxonLists = new ArrayList<TaxonList>();
    List<Tree> subtrees = new ArrayList<Tree>();
    double height = xo.getAttribute(HEIGHT, Double.NaN);
    Tree constraintsTree = null;
    if (xo.hasChildNamed((CONSTRAINTS_TREE))) {
        XMLObject cxo = xo.getChild(CONSTRAINTS_TREE);
        constraintsTree = (Tree) cxo.getChild(Tree.class);
    }
    // should have one child that is node
    for (int i = 0; i < xo.getChildCount(); i++) {
        final Object child = xo.getChild(i);
        if (child != constraintsTree) {
            // AER - swapped the order of these round because Trees are TaxonLists...
            if (child instanceof Tree) {
                subtrees.add((Tree) child);
            } else if (child instanceof TaxonList) {
                taxonLists.add((TaxonList) child);
            }
        }
    }
    if (taxonLists.size() == 0) {
        if (subtrees.size() == 1) {
            return subtrees.get(0);
        }
        if (constraintsTree == null) {
            throw new XMLParseException("Expected at least one taxonList or two subtrees or a constraints tree in " + getParserName() + " element.");
        }
    }
    Taxa remainingTaxa = new Taxa();
    for (int i = 0; i < taxonLists.size(); i++) {
        remainingTaxa.addTaxa(taxonLists.get(i));
    }
    for (int i = 0; i < subtrees.size(); i++) {
        remainingTaxa.removeTaxa(subtrees.get(i));
    }
    if (constraintsTree != null) {
        remainingTaxa.removeTaxa(constraintsTree);
    }
    try {
        if (constraintsTree != null) {
            subtrees.add(simulator.simulateTree(constraintsTree, constraintsTree.getRoot(), demoModel));
        }
        Tree[] trees = new Tree[subtrees.size() + remainingTaxa.getTaxonCount()];
        // add the preset trees
        for (int i = 0; i < subtrees.size(); i++) {
            trees[i] = subtrees.get(i);
        }
        // add all the remaining taxa in as single tip trees...
        for (int i = 0; i < remainingTaxa.getTaxonCount(); i++) {
            Taxa tip = new Taxa();
            tip.addTaxon(remainingTaxa.getTaxon(i));
            trees[i + subtrees.size()] = simulator.simulateTree(tip, demoModel);
        }
        return simulator.simulateTree(trees, demoModel, height, trees.length != 1);
    } catch (IllegalArgumentException iae) {
        throw new XMLParseException(iae.getMessage());
    }
}
Also used : TaxonList(dr.evolution.util.TaxonList) ArrayList(java.util.ArrayList) DemographicModel(dr.evomodel.coalescent.demographicmodel.DemographicModel) CoalescentSimulator(dr.evomodel.coalescent.CoalescentSimulator) Taxa(dr.evolution.util.Taxa) Tree(dr.evolution.tree.Tree)

Example 7 with DemographicModel

use of dr.evomodel.coalescent.demographicmodel.DemographicModel in project beast-mcmc by beast-dev.

the class OldCoalescentSimulatorParser method parseXMLObject.

public Object parseXMLObject(XMLObject xo) throws XMLParseException {
    CoalescentSimulator simulator = new CoalescentSimulator();
    DemographicModel demoModel = (DemographicModel) xo.getChild(DemographicModel.class);
    List<TaxonList> taxonLists = new ArrayList<TaxonList>();
    List<Tree> subtrees = new ArrayList<Tree>();
    double rootHeight = xo.getAttribute(ROOT_HEIGHT, -1.0);
    if (xo.hasAttribute(RESCALE_HEIGHT)) {
        rootHeight = xo.getDoubleAttribute(RESCALE_HEIGHT);
    }
    // should have one child that is node
    for (int i = 0; i < xo.getChildCount(); i++) {
        final Object child = xo.getChild(i);
        // AER - swapped the order of these round because Trees are TaxonLists...
        if (child instanceof Tree) {
            subtrees.add((Tree) child);
        } else if (child instanceof TaxonList) {
            taxonLists.add((TaxonList) child);
        } else if (xo.getChildName(i).equals(CONSTRAINED_TAXA)) {
            XMLObject constrainedTaxa = (XMLObject) child;
            // all taxa
            final TaxonList taxa = (TaxonList) constrainedTaxa.getChild(TaxonList.class);
            List<CoalescentSimulator.TaxaConstraint> constraints = new ArrayList<CoalescentSimulator.TaxaConstraint>();
            final String setsNotCompatibleMessage = "taxa sets not compatible";
            for (int nc = 0; nc < constrainedTaxa.getChildCount(); ++nc) {
                final Object object = constrainedTaxa.getChild(nc);
                if (object instanceof XMLObject) {
                    final XMLObject constraint = (XMLObject) object;
                    if (constraint.getName().equals(TMRCA_CONSTRAINT)) {
                        TaxonList taxaSubSet = (TaxonList) constraint.getChild(TaxonList.class);
                        ParametricDistributionModel dist = (ParametricDistributionModel) constraint.getChild(ParametricDistributionModel.class);
                        boolean isMono = constraint.getAttribute(IS_MONOPHYLETIC, true);
                        final CoalescentSimulator.TaxaConstraint taxaConstraint = new CoalescentSimulator.TaxaConstraint(taxaSubSet, dist, isMono);
                        int insertPoint;
                        for (insertPoint = 0; insertPoint < constraints.size(); ++insertPoint) {
                            // if new <= constraints[insertPoint] insert before insertPoint
                            final CoalescentSimulator.TaxaConstraint iConstraint = constraints.get(insertPoint);
                            if (iConstraint.isMonophyletic) {
                                if (!taxaConstraint.isMonophyletic) {
                                    continue;
                                }
                                final TaxonList taxonsip = iConstraint.taxons;
                                final int nIn = simulator.sizeOfIntersection(taxonsip, taxaSubSet);
                                if (nIn == taxaSubSet.getTaxonCount()) {
                                    break;
                                }
                                if (nIn > 0 && nIn != taxonsip.getTaxonCount()) {
                                    throw new XMLParseException(setsNotCompatibleMessage);
                                }
                            } else {
                                // reached non mono area
                                if (!taxaConstraint.isMonophyletic) {
                                    if (iConstraint.upper >= taxaConstraint.upper) {
                                        break;
                                    }
                                } else {
                                    break;
                                }
                            }
                        }
                        constraints.add(insertPoint, taxaConstraint);
                    }
                }
            }
            final int nConstraints = constraints.size();
            if (nConstraints == 0) {
                if (taxa != null) {
                    taxonLists.add(taxa);
                }
            } else {
                for (int nc = 0; nc < nConstraints; ++nc) {
                    CoalescentSimulator.TaxaConstraint cnc = constraints.get(nc);
                    if (!cnc.isMonophyletic) {
                        for (int nc1 = nc - 1; nc1 >= 0; --nc1) {
                            CoalescentSimulator.TaxaConstraint cnc1 = constraints.get(nc1);
                            int x = simulator.sizeOfIntersection(cnc.taxons, cnc1.taxons);
                            if (x > 0) {
                                Taxa combinedTaxa = new Taxa(cnc.taxons);
                                combinedTaxa.addTaxa(cnc1.taxons);
                                cnc = new CoalescentSimulator.TaxaConstraint(combinedTaxa, cnc.lower, cnc.upper, cnc.isMonophyletic);
                                constraints.set(nc, cnc);
                            }
                        }
                    }
                }
                // determine upper bound for each set.
                double[] upper = new double[nConstraints];
                for (int nc = nConstraints - 1; nc >= 0; --nc) {
                    final CoalescentSimulator.TaxaConstraint cnc = constraints.get(nc);
                    if (cnc.realLimits()) {
                        upper[nc] = cnc.upper;
                    } else {
                        upper[nc] = Double.POSITIVE_INFINITY;
                    }
                }
                for (int nc = nConstraints - 1; nc >= 0; --nc) {
                    final CoalescentSimulator.TaxaConstraint cnc = constraints.get(nc);
                    if (upper[nc] < Double.POSITIVE_INFINITY) {
                        for (int nc1 = nc - 1; nc1 >= 0; --nc1) {
                            final CoalescentSimulator.TaxaConstraint cnc1 = constraints.get(nc1);
                            if (simulator.contained(cnc1.taxons, cnc.taxons)) {
                                upper[nc1] = Math.min(upper[nc1], upper[nc]);
                                if (cnc1.realLimits() && cnc1.lower > upper[nc1]) {
                                    throw new XMLParseException(setsNotCompatibleMessage);
                                }
                                break;
                            }
                        }
                    }
                }
                // collect subtrees here
                List<Tree> st = new ArrayList<Tree>();
                for (int nc = 0; nc < constraints.size(); ++nc) {
                    final CoalescentSimulator.TaxaConstraint nxt = constraints.get(nc);
                    // collect all previously built subtrees which are a subset of taxa set to be added
                    List<Tree> subs = new ArrayList<Tree>();
                    Taxa newTaxons = new Taxa(nxt.taxons);
                    for (int k = 0; k < st.size(); ++k) {
                        final Tree stk = st.get(k);
                        int x = simulator.sizeOfIntersection(stk, nxt.taxons);
                        if (x == st.get(k).getTaxonCount()) {
                            final Tree tree = st.remove(k);
                            --k;
                            subs.add(tree);
                            newTaxons.removeTaxa(tree);
                        }
                    }
                    SimpleTree tree = simulator.simulateTree(newTaxons, demoModel);
                    final double lower = nxt.realLimits() ? nxt.lower : 0;
                    if (upper[nc] < Double.MAX_VALUE) {
                        simulator.attemptToScaleTree(tree, (lower + upper[nc]) / 2);
                    }
                    if (subs.size() > 0) {
                        if (tree.getTaxonCount() > 0)
                            subs.add(tree);
                        double h = -1;
                        if (upper[nc] < Double.MAX_VALUE) {
                            for (Tree t : subs) {
                                // protect against 1 taxa tree with height 0
                                final double rh = t.getNodeHeight(t.getRoot());
                                h = Math.max(h, rh > 0 ? rh : (lower + upper[nc]) / 2);
                            }
                            h = (h + upper[nc]) / 2;
                        }
                        tree = simulator.simulateTree(subs.toArray(new Tree[subs.size()]), demoModel, h, true);
                    }
                    st.add(tree);
                }
                // add a taxon list for remaining taxa
                if (taxa != null) {
                    final Taxa list = new Taxa();
                    for (int j = 0; j < taxa.getTaxonCount(); ++j) {
                        Taxon taxonj = taxa.getTaxon(j);
                        for (Tree aSt : st) {
                            if (aSt.getTaxonIndex(taxonj) >= 0) {
                                taxonj = null;
                                break;
                            }
                        }
                        if (taxonj != null) {
                            list.addTaxon(taxonj);
                        }
                    }
                    if (list.getTaxonCount() > 0) {
                        taxonLists.add(list);
                    }
                }
                if (st.size() > 1) {
                    final Tree t = simulator.simulateTree(st.toArray(new Tree[st.size()]), demoModel, -1, false);
                    subtrees.add(t);
                } else {
                    subtrees.add(st.get(0));
                }
            }
        }
    }
    if (taxonLists.size() == 0) {
        if (subtrees.size() == 1) {
            return subtrees.get(0);
        }
        throw new XMLParseException("Expected at least one taxonList or two subtrees in " + getParserName() + " element.");
    }
    try {
        Tree[] trees = new Tree[taxonLists.size() + subtrees.size()];
        // simulate each taxonList separately
        for (int i = 0; i < taxonLists.size(); i++) {
            trees[i] = simulator.simulateTree(taxonLists.get(i), demoModel);
        }
        // add the preset trees
        for (int i = 0; i < subtrees.size(); i++) {
            trees[i + taxonLists.size()] = subtrees.get(i);
        }
        return simulator.simulateTree(trees, demoModel, rootHeight, trees.length != 1);
    } catch (IllegalArgumentException iae) {
        throw new XMLParseException(iae.getMessage());
    }
}
Also used : TaxonList(dr.evolution.util.TaxonList) Taxon(dr.evolution.util.Taxon) ArrayList(java.util.ArrayList) DemographicModel(dr.evomodel.coalescent.demographicmodel.DemographicModel) SimpleTree(dr.evolution.tree.SimpleTree) CoalescentSimulator(dr.evomodel.coalescent.CoalescentSimulator) Taxa(dr.evolution.util.Taxa) ParametricDistributionModel(dr.inference.distribution.ParametricDistributionModel) Tree(dr.evolution.tree.Tree) SimpleTree(dr.evolution.tree.SimpleTree)

Aggregations

DemographicModel (dr.evomodel.coalescent.demographicmodel.DemographicModel)7 Tree (dr.evolution.tree.Tree)4 TaxonList (dr.evolution.util.TaxonList)3 ArrayList (java.util.ArrayList)3 NewickImporter (dr.evolution.io.NewickImporter)2 Taxa (dr.evolution.util.Taxa)2 CoalescentSimulator (dr.evomodel.coalescent.CoalescentSimulator)2 PiecewisePopulationModel (dr.evomodel.coalescent.demographicmodel.PiecewisePopulationModel)2 TreeModel (dr.evomodel.tree.TreeModel)2 Parameter (dr.inference.model.Parameter)2 IntervalList (dr.evolution.coalescent.IntervalList)1 SimpleTree (dr.evolution.tree.SimpleTree)1 TreeUtils (dr.evolution.tree.TreeUtils)1 Taxon (dr.evolution.util.Taxon)1 Units (dr.evolution.util.Units)1 BNPRSamplingLikelihood (dr.evomodel.coalescent.BNPRSamplingLikelihood)1 CoalescentLikelihood (dr.evomodel.coalescent.CoalescentLikelihood)1 TreeIntervals (dr.evomodel.coalescent.TreeIntervals)1 TwoEpochDemographicModel (dr.evomodel.coalescent.demographicmodel.TwoEpochDemographicModel)1 XMLUnits (dr.evoxml.util.XMLUnits)1