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maximization_step.d
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maximization_step.d
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/* Copyright (c) 2012,2013 Genome Research Ltd.
*
* Author: Stephan Schiffels <[email protected]>
*
* This file is part of msmc.
* msmc is free software: you can redistribute it and/or modify it under
* the terms of the GNU General Public License as published by the Free Software
* Foundation; either version 3 of the License, or (at your option) any later
* version.
*
* This program is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
* FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
* details.
*
* You should have received a copy of the GNU General Public License along with
* this program. If not, see <http://www.gnu.org/licenses/>.
*/
import std.math;
import std.stdio;
import std.random;
import std.exception;
import std.algorithm;
import std.string;
import model.msmc_model;
import model.triple_index;
import model.triple_index_marginal;
import powell;
import logger;
MSMCmodel getMaximization(double[] eVec, double[][] eMat, MSMCmodel params,
in size_t[] timeSegmentPattern, bool fixedPopSize, bool fixedRecombination, bool boundCrossCoal,
double loBoundLambda, double hiBoundLambda) {
auto minFunc = new MinFunc(eVec, eMat, params, timeSegmentPattern, fixedPopSize,
fixedRecombination, boundCrossCoal, loBoundLambda, hiBoundLambda);
auto powell = new Powell!MinFunc(minFunc);
auto x = minFunc.initialValues();
auto startVal = minFunc(x);
auto xNew = powell.minimize(x);
auto endVal = minFunc(xNew);
logInfo(format(", Q-function before: %s, after:%s\n", startVal, endVal));
return minFunc.makeParamsFromVec(xNew);
}
class MinFunc {
MSMCmodel initialParams;
const size_t[] timeSegmentPattern;
size_t nrSubpopPairs, nrParams;
const double[] expectationResultVec;
const double[][] expectationResultMat;
bool fixedPopSize, fixedRecombination, boundCrossCoal;
double loBoundLambda, hiBoundLambda;
this(in double[] expectationResultVec, in double[][] expectationResultMat, MSMCmodel
initialParams, in size_t[] timeSegmentPattern, bool fixedPopSize, bool fixedRecombination,
bool boundCrossCoal, double loBoundLambda, double hiBoundLambda) {
this.initialParams = initialParams;
this.timeSegmentPattern = timeSegmentPattern;
this.expectationResultVec = expectationResultVec;
this.expectationResultMat = expectationResultMat;
this.fixedPopSize = fixedPopSize;
this.fixedRecombination = fixedRecombination;
this.boundCrossCoal = boundCrossCoal;
this.loBoundLambda = loBoundLambda;
this.hiBoundLambda = hiBoundLambda;
nrSubpopPairs = initialParams.nrSubpopulations * (initialParams.nrSubpopulations + 1) / 2;
nrParams = nrSubpopPairs * cast(size_t)timeSegmentPattern.length;
if(!fixedRecombination)
nrParams += 1;
if(fixedPopSize)
nrParams -= initialParams.nrSubpopulations * cast(size_t)timeSegmentPattern.length;
}
double opCall(in double[] x) {
MSMCmodel newParams = makeParamsFromVec(x);
return -logLikelihood(newParams);
};
double[] initialValues()
out(x) {
assert(x.length == nrParams);
}
do {
auto x = getXfromLambdaVec(initialParams.lambdaVec);
if(!fixedRecombination)
x ~= toScaledRecombination(initialParams.recombinationRate);
return x;
}
double toScaledRecombination(double rec) {
return log(rec);
}
double fromScaledRecombination(double scaledRec) {
return exp(scaledRec);
}
double[] getXfromLambdaVec(double[] lambdaVec)
out(x) {
if(fixedPopSize)
assert(x.length == timeSegmentPattern.length *
(nrSubpopPairs - initialParams.nrSubpopulations));
else
assert(x.length == timeSegmentPattern.length * nrSubpopPairs);
}
do {
double[] ret;
size_t count = 0;
foreach(nrIntervalsInSegment; timeSegmentPattern) {
foreach(subpopPairIndex; 0 .. nrSubpopPairs) {
auto lIndex = count * nrSubpopPairs + subpopPairIndex;
auto tripleIndex = initialParams.marginalIndex.getIndexFromMarginalIndex(lIndex);
auto triple = initialParams.marginalIndex.getTripleFromIndex(tripleIndex);
auto p1 = initialParams.subpopLabels[triple.ind1];
auto p2 = initialParams.subpopLabels[triple.ind2];
if(p1 == p2) {
if(!fixedPopSize) {
auto l = lambdaVec[lIndex];
if(l < loBoundLambda)
l = loBoundLambda + 0.000000001;
if(l > hiBoundLambda)
l = hiBoundLambda - 0.000000001;
ret ~= toScaledLambda(l);
}
}
else {
auto marginalIndex1 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p1][p1];
auto marginalIndex2 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p2][p2];
auto lambda1 = lambdaVec[marginalIndex1];
auto lambda2 = lambdaVec[marginalIndex2];
auto lambda12 = lambdaVec[lIndex];
if(boundCrossCoal) {
if(lambda12 >= 0.5 * (lambda1 + lambda2))
lambda12 = 0.4999999999 * (lambda1 + lambda2);
}
else {
if(lambda12 < loBoundLambda)
lambda12 = loBoundLambda + 0.000000001;
if(lambda12 > hiBoundLambda)
lambda12 = hiBoundLambda - 0.000000001;
}
ret ~= toScaledCrossLambda(lambda12, lambda1, lambda2);
}
}
count += nrIntervalsInSegment;
}
return ret;
}
double toScaledLambda(double lambda) {
if(hiBoundLambda < double.infinity) {
auto frac = (lambda - loBoundLambda) / (hiBoundLambda - loBoundLambda);
return tan(frac * PI - PI_2);
}
else
return log(lambda - loBoundLambda);
}
double fromScaledLambda(double scaledLambda) {
if(hiBoundLambda < double.infinity) {
auto scaledFrac = (atan(scaledLambda) + PI_2) / PI;
return scaledFrac * (hiBoundLambda - loBoundLambda) + loBoundLambda;
}
else {
return exp(scaledLambda) + loBoundLambda;
}
}
double toScaledCrossLambda(double crossLambda, double lambda1, double lambda2) {
if(boundCrossCoal) {
auto ratio = 2.0 * crossLambda / (lambda1 + lambda2);
return tan(ratio * PI - PI_2);
}
else
return toScaledLambda(crossLambda);
}
double fromScaledCrossLambda(double scaledCrossLambda, double lambda1, double lambda2) {
if(boundCrossCoal) {
auto ratio = (atan(scaledCrossLambda) + PI_2) / PI;
return ratio * 0.5 * (lambda1 + lambda2);
}
else
return fromScaledLambda(scaledCrossLambda);
}
MSMCmodel makeParamsFromVec(in double[] x) {
auto lambdaVec = fixedPopSize ? getLambdaVecFromXfixedPop(x) : getLambdaVecFromX(x);
auto recombinationRate =
fixedRecombination ? initialParams.recombinationRate : getRecombinationRateFromX(x);
return new MSMCmodel(initialParams.mutationRate, recombinationRate, initialParams.subpopLabels,
lambdaVec, initialParams.nrTimeIntervals, initialParams.nrTtotIntervals,
initialParams.emissionRate.directedEmissions);
}
double[] getLambdaVecFromXfixedPop(in double[] x)
in {
assert(x.length == nrParams);
}
do {
auto lambdaVec = initialParams.lambdaVec.dup;
auto timeIndex = 0U;
auto valuesPerTime = nrSubpopPairs - initialParams.nrSubpopulations;
foreach(segmentIndex, nrIntervalsInSegment; timeSegmentPattern) {
foreach(intervalIndex; 0 .. nrIntervalsInSegment) {
auto xIndex = 0;
foreach(subpopPairIndex; 0 .. nrSubpopPairs) {
auto lIndex = timeIndex * nrSubpopPairs + subpopPairIndex;
auto tripleIndex = initialParams.marginalIndex.getIndexFromMarginalIndex(lIndex);
auto triple = initialParams.marginalIndex.getTripleFromIndex(tripleIndex);
auto p1 = initialParams.subpopLabels[triple.ind1];
auto p2 = initialParams.subpopLabels[triple.ind2];
if(p1 != p2) {
auto marginalIndex1 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p1][p1];
auto marginalIndex2 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p2][p2];
auto lambda1 = lambdaVec[marginalIndex1];
auto lambda2 = lambdaVec[marginalIndex2];
auto scaledCrossLambda = x[segmentIndex * valuesPerTime + xIndex];
lambdaVec[lIndex] = fromScaledCrossLambda(scaledCrossLambda, lambda1, lambda2);
xIndex += 1;
}
}
timeIndex += 1;
}
}
return lambdaVec;
}
double[] getLambdaVecFromX(in double[] x)
in {
assert(x.length == nrParams);
}
do {
auto lambdaVec = initialParams.lambdaVec.dup;
auto timeIndex = 0U;
foreach(segmentIndex, nrIntervalsInSegment; timeSegmentPattern) {
foreach(intervalIndex; 0 .. nrIntervalsInSegment) {
foreach(subpopPairIndex; 0 .. nrSubpopPairs) {
auto lIndex = timeIndex * nrSubpopPairs + subpopPairIndex;
auto xIndex = segmentIndex * nrSubpopPairs + subpopPairIndex;
lambdaVec[lIndex] = fromScaledLambda(x[xIndex]);
}
foreach(subpopPairIndex; 0 .. nrSubpopPairs) {
auto lIndex = timeIndex * nrSubpopPairs + subpopPairIndex;
auto tripleIndex = initialParams.marginalIndex.getIndexFromMarginalIndex(lIndex);
auto triple = initialParams.marginalIndex.getTripleFromIndex(tripleIndex);
auto p1 = initialParams.subpopLabels[triple.ind1];
auto p2 = initialParams.subpopLabels[triple.ind2];
if(p1 != p2) {
auto xIndex = segmentIndex * nrSubpopPairs + subpopPairIndex;
auto marginalIndex1 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p1][p1];
auto marginalIndex2 =
initialParams.marginalIndex.subpopulationTripleToMarginalIndexMap[triple.time][p2][p2];
auto lambda1 = lambdaVec[marginalIndex1];
auto lambda2 = lambdaVec[marginalIndex2];
lambdaVec[lIndex] = fromScaledCrossLambda(x[xIndex], lambda1, lambda2);
}
}
timeIndex += 1;
}
}
return lambdaVec;
}
double getRecombinationRateFromX(in double[] x)
in {
assert(!fixedRecombination);
}
do {
return fromScaledRecombination(x[$ - 1]);
}
double logLikelihood(MSMCmodel params) {
double ret = 0.0;
foreach(au; 0 .. initialParams.nrMarginals) {
foreach(bv; 0 .. initialParams.nrMarginals) {
ret +=
expectationResultMat[au][bv] * log(params.transitionRate.transitionProbabilityQ2(au, bv));
}
ret += expectationResultVec[au] * log(
params.transitionRate.transitionProbabilityQ1(au) +
params.transitionRate.transitionProbabilityQ2(au, au)
);
}
return ret;
}
}
unittest {
writeln("test minfunc.getLambdaFromX");
import std.conv;
auto lambdaVec = [1, 1.5, 3, 1, 1.5, 3, 4, 4.5, 6, 4, 4.5, 6];
auto params = new MSMCmodel(0.01, 0.001, [0U, 0, 1, 1], lambdaVec, 4, 4, false);
auto expectationResultVec = new double[params.nrMarginals];
auto expectationResultMat = new double[][](params.nrMarginals, params.nrMarginals);
auto timeSegmentPattern = [2UL, 2];
auto minFunc = new MinFunc(expectationResultVec, expectationResultMat, params, timeSegmentPattern, false, false, false, 0, double.infinity);
auto rho = 0.001;
auto x = minFunc.getXfromLambdaVec(lambdaVec);
x ~= minFunc.toScaledRecombination(rho);
auto lambdaFromX = minFunc.getLambdaVecFromX(x);
auto rhoFromX = minFunc.getRecombinationRateFromX(x);
foreach(i; 0 .. lambdaVec.length)
assert(approxEqual(lambdaFromX[i], lambdaVec[i], 1.0e-8, 0.0), text(lambdaFromX[i], " ", lambdaVec[i]));
assert(approxEqual(rhoFromX, rho, 1.0e-8, 0.0));
minFunc = new MinFunc(expectationResultVec, expectationResultMat, params, timeSegmentPattern, true, false, false, 0, double.infinity);
x = minFunc.getXfromLambdaVec(lambdaVec);
x ~= minFunc.toScaledRecombination(rho);
lambdaFromX = minFunc.getLambdaVecFromXfixedPop(x);
rhoFromX = minFunc.getRecombinationRateFromX(x);
foreach(i; 0 .. lambdaVec.length)
assert(approxEqual(lambdaFromX[i], lambdaVec[i], 1.0e-8, 0.0), text(lambdaFromX[i], " ", lambdaVec[i]));
assert(approxEqual(rhoFromX, rho, 1.0e-8, 0.0));
minFunc = new MinFunc(expectationResultVec, expectationResultMat, params, timeSegmentPattern, false, true, false, 0, double.infinity);
x = minFunc.getXfromLambdaVec(lambdaVec);
lambdaFromX = minFunc.getLambdaVecFromX(x);
foreach(i; 0 .. lambdaVec.length)
assert(approxEqual(lambdaFromX[i], lambdaVec[i], 1.0e-8, 0.0), text(lambdaFromX[i], " ", lambdaVec[i]));
}
// unittest {
// import std.random;
// writeln("test maximization step");
// auto lambdaVec = new double[12];
// lambdaVec[] = 1.0;
// auto params = new MSMCmodel(0.01, 0.001, [0UL, 0, 1, 1], lambdaVec, 4, 4);
//
// auto expectationMatrix = new double[][](12, 12);
// foreach(i; 0 .. 12) foreach(j; 0 .. 12)
// expectationMatrix[i][j] = params.transitionRate.transitionProbabilityMarginal(i, j) * uniform(700, 1300);
// auto timeSegmentPattern = [2UL, 2];
// auto updatedParams = getMaximization(expectationMatrix, params, timeSegmentPattern, false, true);
//
// writeln("Maximization test: actual params: ", params);
// writeln("Maximization test: inferred params: ", updatedParams);
// }