@Override public void duplicate(Solver solver, THashMap<Object, Object> identitymap) { if (!identitymap.containsKey(this)) { this.var.duplicate(solver, identitymap); OffsetView clone = new OffsetView((IntVar) identitymap.get(this.var), this.cste, solver); identitymap.put(this, clone); } }
@Override public void duplicate(Solver solver, THashMap<Object, Object> identitymap) { if (!identitymap.containsKey(this)) { this.vars[0].duplicate(solver, identitymap); IntVar X = (IntVar) identitymap.get(this.vars[0]); this.vars[1].duplicate(solver, identitymap); IntVar Y = (IntVar) identitymap.get(this.vars[1]); identitymap.put(this, new PropEqualX_YC(new IntVar[] {X, Y}, this.cste)); } }
/** * Build an unbounded {@link solver.variables.Variable} named {@code name}, defined by {@code * type}. * * @param name name of the variable * @param expression * @param map * @param solver @return {@link solver.variables.Variable} */ private static IntVar buildWithInt( String name, Expression expression, THashMap<String, Object> map, Solver solver) { final IntVar iv; if (expression != null) { iv = buildOnExpression(DEBUG ? name : NO_NAME, expression, map, solver); } else { iv = VariableFactory.bounded(DEBUG ? name : NO_NAME, -999999, 999999, solver); } map.put(name, iv); return iv; }
/** * Build a {@link solver.variables.Variable} named {@code name}. * * @param name name of the boolean variable * @param map * @param solver * @return {@link solver.variables.Variable} */ private static BoolVar buildWithBool( String name, Expression expression, THashMap<String, Object> map, Solver solver) { final BoolVar bi; if (expression != null) { bi = (BoolVar) buildOnExpression(DEBUG ? name : NO_NAME, expression, map, solver); } else { bi = VariableFactory.bool(DEBUG ? name : NO_NAME, solver); } map.put(name, bi); return bi; }
/** * Build an array of <? extends {@link solver.variables.Variable}>. </br>WARNING: array's indice * are from 1 to n. * * @param name name of the array of variables.</br> Each variable is named like {@code name}_i. * @param type {@link parser.flatzinc.ast.declaration.DArray} object. * @param earr array of {@link parser.flatzinc.ast.expression.Expression} * @param map * @param solver */ private static void buildWithDArray( String name, DArray type, Expression expression, EArray earr, THashMap<String, Object> map, Solver solver) { final DInt2 index = (DInt2) type.getIndex(0); // no need to get lowB, it is always 1 (see specification of FZN for more informations) final int size = index.getUpp(); final Declaration what = type.getWhat(); switch (what.typeOf) { case BOOL: final BoolVar[] bs = new BoolVar[size]; for (int i = 0; i < size; i++) { bs[i] = earr.getWhat_i(i).boolVarValue(solver); } map.put(name, bs); break; case INT: case INT2: case INTN: final IntVar[] vs = new IntVar[size]; for (int i = 0; i < size; i++) { vs[i] = earr.getWhat_i(i).intVarValue(solver); } map.put(name, vs); break; case SET: // final SetVariable[] svs = new SetVariable[size]; // for (int i = 0; i < size; i++) { // svs[i] = earr.getWhat_i(i).setVarValue(); // } // map.put(name, svs); Exit.log("SET VAR"); break; default: break; } }
@Override public void duplicate(Solver solver, THashMap<Object, Object> identitymap) { if (!identitymap.containsKey(this)) { int size = vars.length; RealVar[] rvars = new RealVar[size]; for (int i = 0; i < size; i++) { vars[i].duplicate(solver, identitymap); rvars[i] = (RealVar) identitymap.get(vars[i]); } identitymap.put(this, new RealPropagator(functions, rvars, option)); } }
public User(boolean mTrue) { try { ResultSet mResult = Legion.getDetabase().executeQuery("SELECT * FROM `users`"); while (mResult.next()) { User h = new User(); h.Id = mResult.getInt("id"); h.userName = mResult.getString("username"); h.realName = mResult.getString("realname"); h.Look = mResult.getString("look"); h.SSO = mResult.getString("ssoTicket"); h.Email = mResult.getString("email"); h.Mission = mResult.getString("mission"); h.Coin = mResult.getInt("coins"); h.OtherCoin = mResult.getInt("othercoins"); h.Score = mResult.getInt("score"); h.Gender = mResult.getString("Gender"); h.Respects = mResult.getInt("Respects"); h.maxUserRespects = mResult.getInt("Max_Users_Respects"); h.maxPetsRespects = mResult.getInt("Max_Pets_Respects"); h.Rank = mResult.getInt("rank"); h.bannTime = mResult.getInt("ban_time"); h.banCount = mResult.getInt("ban_count"); h.habboClubInit = mResult.getString("Habbo_Club_Init"); h.habboClubExpire = mResult.getString("Habbo_Club_Expire"); DateFormat dateFormat = new SimpleDateFormat("yyyy/MM/dd HH:mm:ss"); Date date = new Date(); Date mDate = dateFormat.parse(h.habboClubExpire); h.Habbo_Club = (date.getTime() < mDate.getTime()); h.isBanned = mResult.getBoolean("ban"); h.isKuick = mResult.getBoolean("kuick"); h.registredTime = mResult.getString("registred_time"); h.lastLogin = mResult.getString("last_login"); h.isOnline = false; h.isInRoom = false; h.isWriting = false; h.isWalking = false; h.x = 0; h.y = 0; h.z = 0.0; h.rot = 0; h.rothead = 0; getUserFromId.put(h.Id, h); } System.out.println("Loaded ".concat(getUserFromId.size() + " ").concat("user/s.")); System.gc(); } catch (Exception ex) { ex.printStackTrace(); } }
public THashMap<String, String> findCoordinates() { THashMap<String, String> airportGeoSet = new THashMap<String, String>(); // extract all characteristics of certain variables System.out.println("Finding coordinates from Airports"); StringTokenizer st; String airportCode, longitude, latitude; try { BufferedReader br = new BufferedReader(new FileReader(new File(dirURL_geo))); System.out.println("scan " + dirURL_geo); String line = br.readLine(); // for(int i = numberOfLinesToReadTestMode; i > 0; --i){ while (line != null) { st = new StringTokenizer(line, ","); // jump to airport code and removes "". airportCode = st.nextToken(); if (debug) System.out.print(" " + airportCode); // jump to latitude and removes "". latitude = st.nextToken(); if (debug) System.out.print(" " + latitude); // jump to longitude and removes "". longitude = st.nextToken(); if (debug) System.out.println(" " + longitude + "\n"); // put airportCode as key and lat,long as value in airportGeoSet, hashmap. airportGeoSet.put(airportCode, new String(latitude + ";" + longitude)); // if(debug) System.out.println(airportGeoSet); // System.out.println(airportCode+";"+airportGeoSet.get(airportCode)); line = br.readLine(); } br.close(); } catch (FileNotFoundException e) { e.printStackTrace(); } catch (IOException e) { e.printStackTrace(); } return airportGeoSet; }
/** * Build a {@link solver.variables.Variable} named {@code name}, defined by {@code type}. {@code * type} is expected to be a {@link parser.flatzinc.ast.declaration.DManyInt} object. * * @param name name of the variable * @param type {@link parser.flatzinc.ast.declaration.DManyInt} object. * @param map * @param solver * @return {@link solver.variables.Variable} */ private static IntVar buildWithManyInt( String name, DManyInt type, Expression expression, THashMap<String, Object> map, Solver solver) { final IntVar iv; if (expression != null) { iv = buildOnExpression(DEBUG ? name : NO_NAME, expression, map, solver); int[] values = type.getValues(); solver.post(IntConstraintFactory.member(iv, values)); } else { iv = VariableFactory.enumerated(DEBUG ? name : NO_NAME, type.getValues(), solver); } map.put(name, iv); return iv; }
@Override public void duplicate(Solver solver, THashMap<Object, Object> identitymap) { if (!identitymap.containsKey(this)) { int size = this.n; IntVar[] iVars = new IntVar[size]; for (int i = 0; i < size; i++) { this.vars[i].duplicate(solver, identitymap); iVars[i] = (IntVar) identitymap.get(this.vars[i]); } RealVar[] rVars = new RealVar[size]; for (int i = 0; i < size; i++) { this.vars[i + n].duplicate(solver, identitymap); rVars[i] = (RealVar) identitymap.get(this.vars[i + n]); } identitymap.put(this, new PropIntEqReal(iVars, rVars, epsilon)); } }
@Override public void duplicate(Solver solver, THashMap<Object, Object> identitymap) { if (!identitymap.containsKey(this)) { int s1 = sets.length; SetVar[] set1 = new SetVar[s1]; for (int i = 0; i < s1; i++) { sets[i].duplicate(solver, identitymap); set1[i] = (SetVar) identitymap.get(sets[i]); } int s2 = invsets.length; SetVar[] set2 = new SetVar[s2]; for (int i = 0; i < s2; i++) { invsets[i].duplicate(solver, identitymap); set2[i] = (SetVar) identitymap.get(invsets[i]); } identitymap.put(this, new PropInverse(set1, set2, offSet1, offSet2)); } }
/** * Build a {@link solver.variables.Variable} named {@code name}, defined by {@code type}. * * @param name name of the variable * @param type {@link parser.flatzinc.ast.declaration.DInt2} object * @param map * @param solver * @return {@link solver.variables.Variable} */ private static IntVar buildWithInt2( String name, DInt2 type, Expression expression, THashMap<String, Object> map, Solver solver) { final IntVar iv; if (expression != null) { iv = buildOnExpression(DEBUG ? name : NO_NAME, expression, map, solver); int lb = type.getLow(); int ub = type.getUpp(); solver.post(IntConstraintFactory.member(iv, lb, ub)); } else { int size = type.getUpp() - type.getLow() + 1; if (size < 256) { iv = VariableFactory.enumerated( DEBUG ? name : NO_NAME, type.getLow(), type.getUpp(), solver); } else { iv = VariableFactory.bounded(DEBUG ? name : NO_NAME, type.getLow(), type.getUpp(), solver); } } map.put(name, iv); return iv; }
public static User getHabboFromSSO(String SSO) { User mResult = null; try { Iterator reader = getUserFromId.entrySet().iterator(); while (reader.hasNext()) { User nUser = (User) (((Map.Entry) reader.next()).getValue()); if (nUser.SSO.equals(SSO)) { return nUser; } } ResultSet mResult2 = Legion.getDetabase() .executeQuery("SELECT * FROM `users` WHERE `ssoTicket`='" + SSO + "'"); if (mResult2.next()) { User h = new User(); h.Id = mResult2.getInt("id"); h.userName = mResult2.getString("username"); h.realName = mResult2.getString("realname"); h.Look = mResult2.getString("look"); h.SSO = mResult2.getString("ssoTicket"); h.Email = mResult2.getString("email"); h.Mission = mResult2.getString("mission"); h.Coin = mResult2.getInt("coins"); h.OtherCoin = mResult2.getInt("othercoins"); h.Score = mResult2.getInt("score"); h.Gender = mResult2.getString("Gender"); h.Respects = mResult2.getInt("Respects"); h.maxUserRespects = mResult2.getInt("Max_Users_Respects"); h.maxPetsRespects = mResult2.getInt("Max_Pets_Respects"); h.Rank = mResult2.getInt("rank"); h.bannTime = mResult2.getInt("ban_time"); h.banCount = mResult2.getInt("ban_count"); h.habboClubInit = mResult2.getString("Habbo_Club_Init"); h.habboClubExpire = mResult2.getString("Habbo_Club_Expire"); DateFormat dateFormat = new SimpleDateFormat("yyyy/MM/dd HH:mm:ss"); Date date = new Date(); Date mDate = dateFormat.parse(h.habboClubExpire); h.Habbo_Club = (date.getTime() < mDate.getTime()); h.isBanned = mResult2.getBoolean("ban"); h.isKuick = mResult2.getBoolean("kuick"); h.registredTime = mResult2.getString("registred_time"); h.lastLogin = mResult2.getString("last_login"); h.isOnline = false; h.isInRoom = false; h.isWriting = false; h.isWalking = false; h.x = 0; h.y = 0; h.z = 0.0; h.rot = 0; h.rothead = 0; if (!getUserFromId.containsKey(h.Id)) getUserFromId.put(h.Id, h); else { getUserFromId.remove(h.Id); getUserFromId.put(h.Id, h); } mResult = h; } } catch (Exception ex) { ex.printStackTrace(); return null; } return mResult; }
public final void compareOverlapAndZScoreDirectionTwoEQTLFiles( String eQTL, String meQTL, String eQTMFile, String outputFile, boolean matchOnGeneName, double fdrCutt, boolean matchSnpOnPos, boolean splitGeneNames, boolean flipUsingEQTM, boolean topeffect) throws IOException, Exception { System.out.println("Performing comparison of eQTLs and meQTLs"); double filterOnFDR = fdrCutt; // Do we want to use another FDR measure? When set to -1 this is not used at all. HashSet<String> hashExcludeEQTLs = new HashSet< String>(); // We can exclude some eQTLs from the analysis. If requested, put the entire // eQTL string in this HashMap for each eQTL. Does not work in combination // with mathcing based on chr and pos HashSet<String> hashConfineAnalysisToSubsetOfProbes = new HashSet< String>(); // We can confine the analysis to only a subset of probes. If requested put // the probe name in this HapMap HashSet<String> hashTestedSNPsThatPassedQC = null; // We can confine the analysis to only those eQTLs for which the SNP has been // successfully passed QC, otherwise sometimes unfair comparisons are made. If // requested, put the SNP name in this HashMap // Load the eQTM File QTLTextFile eQTLsTextFile = new QTLTextFile(eQTMFile, QTLTextFile.R); HashMap<String, ArrayList<EQTL>> eQtmInfo = new HashMap<String, ArrayList<EQTL>>(); for (Iterator<EQTL> eQtlIt = eQTLsTextFile.getEQtlIterator(); eQtlIt.hasNext(); ) { EQTL eQtm = eQtlIt.next(); String eQtmKey = eQtm.getRsName(); if (!eQtm.getAlleleAssessed().equals("C")) { eQtm.setAlleleAssessed("C"); eQtm.setZscore(eQtm.getZscore() * -1); Double[] zscores = eQtm.getDatasetZScores(); Double[] correlation = eQtm.getCorrelations(); for (int i = 0; i < eQtm.getDatasets().length; ++i) { zscores[i] *= -1; correlation[i] *= -1; } eQtm.setDatasetZScores(zscores); eQtm.setCorrelations(correlation); } ArrayList<EQTL> posEqtls = eQtmInfo.get(eQtmKey); if (posEqtls == null) { posEqtls = new ArrayList<EQTL>(1); posEqtls.add(eQtm); eQtmInfo.put(eQtmKey, posEqtls); } else if (!topeffect) { eQtmInfo.get(eQtmKey).add(eQtm); } } System.out.println("eQTMs read in: " + eQtmInfo.size()); // Now load the eQTLs for file 1: THashMap<String, String[]> hashEQTLs = new THashMap<String, String[]>(); THashSet<String> hashUniqueProbes = new THashSet<String>(); THashSet<String> hashUniqueGenes = new THashSet<String>(); TextFile in = new TextFile(eQTL, TextFile.R); in.readLine(); String[] data = in.readLineElemsReturnReference(SPLIT_ON_TAB); if (data.length < 5) { throw new IllegalStateException( "QTL File does not have enough columns. Detected columns: " + data.length + " in file " + in.getFileName()); } while (data != null) { if (filterOnFDR == -1 || Double.parseDouble(data[18]) <= filterOnFDR) { if (hashConfineAnalysisToSubsetOfProbes.isEmpty() || hashConfineAnalysisToSubsetOfProbes.contains(data[4])) { if (matchOnGeneName) { if (data[16].length() > 1) { if (splitGeneNames) { for (String gene : SEMI_COLON_PATTERN.split(data[16])) { hashEQTLs.put( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + gene, data); hashUniqueProbes.add(data[4]); hashUniqueGenes.add(gene); } } else { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[16])) { hashEQTLs.put( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[16], data); hashUniqueProbes.add(data[4]); hashUniqueGenes.add(data[16]); // log.write("Added eQTL from original file " + (matchSnpOnPos ? data[2] + ":" + // data[3] : data[1]) + "\t" + data[16]); } } } } else { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[4])) { hashEQTLs.put( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[4], data); hashUniqueProbes.add(data[4]); hashUniqueGenes.add(data[16]); // log.write("Added eQTL from original file " + (matchSnpOnPos ? data[2] + ":" + // data[3] : data[1]) + "\t" + data[4]); } } } data = in.readLineElemsReturnReference(SPLIT_ON_TAB); } } in.close(); int nrUniqueProbes = hashUniqueProbes.size(); int nrUniqueGenes = hashUniqueGenes.size(); hashUniqueProbes = null; hashUniqueGenes = null; // Initialize Graphics2D for the Z-Score allelic direction comparison: // int width = 1000; // int height = 1000; // int margin = 100; // int x0 = margin; // int x1 = width - margin; // int y0 = margin; // int y1 = height - margin; ZScorePlot zs = new ZScorePlot(); String zsOutFileName = outputFile + "-ZScoreComparison.pdf"; zs.init(2, new String[] {"eQTLs", "meQTLs"}, true, zsOutFileName); // Variables holding variousStatistics: int nreQTLsIdenticalDirection = 0; int nreQTLsOppositeDirection = 0; HashMap<String, Integer> hashEQTLNrTimesAssessed = new HashMap<String, Integer>(); THashSet<String> hashEQTLs2 = new THashSet<String>(); THashSet<String> hashUniqueProbes2 = new THashSet<String>(); THashSet<String> hashUniqueGenes2 = new THashSet<String>(); THashSet<String> hashUniqueProbesOverlap = new THashSet<String>(); THashSet<String> hashUniqueGenesOverlap = new THashSet<String>(); int counterFile2 = 0; int overlap = 0; ArrayDoubleList vecX = new ArrayDoubleList(); ArrayDoubleList vecY = new ArrayDoubleList(); // Vector holding all opposite allelic effects: // LinkedHashSet<String> vecOppositeEQTLs = new LinkedHashSet<String>(); // Now process file 2: in = new TextFile(meQTL, TextFile.R); in.readLine(); int skippedDueToMapping = 0; data = null; TextFile identicalOut = new TextFile(outputFile + "-eQTLsWithIdenticalDirecton.txt.gz", TextFile.W); TextFile disconcordantOut = new TextFile(outputFile + "-OppositeEQTLs.txt", TextFile.W); TextFile log = new TextFile(outputFile + "-eQTL-meQTL-ComparisonLog.txt", TextFile.W); TextFile log2 = new TextFile(outputFile + "-eQTM-missingnessLog.txt", TextFile.W); THashSet<String> identifiersUsed = new THashSet<String>(); while ((data = in.readLineElemsReturnReference(SPLIT_ON_TAB)) != null) { if (filterOnFDR == -1 || Double.parseDouble(data[18]) <= filterOnFDR) { if (!eQtmInfo.containsKey(data[4])) { skippedDueToMapping++; log2.write( "meQTL probe not present In eQTM file:\t" + data[4] + ", effect statistics: \t" + data[0] + "\t" + data[2] + "\t" + data[3] + "\t" + data[16] + "\n"); continue; } String orgDataFour = data[4]; for (int i = 0; i < eQtmInfo.get(orgDataFour).size(); ++i) { if (topeffect && i > 0) { break; } data[16] = eQtmInfo.get(orgDataFour).get(i).getProbeHUGO(); data[4] = eQtmInfo.get(orgDataFour).get(i).getProbe(); if (flipUsingEQTM) { Double zScoreQTM = eQtmInfo.get(orgDataFour).get(i).getZscore(); if (zScoreQTM < 0) { data[10] = String.valueOf(Double.parseDouble(data[10]) * -1); } } if (hashConfineAnalysisToSubsetOfProbes.isEmpty() || hashConfineAnalysisToSubsetOfProbes.contains(data[4])) { if (matchOnGeneName) { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[16])) { if (data[16].length() > 1) { if (splitGeneNames) { for (String gene : SEMI_COLON_PATTERN.split(data[16])) { hashUniqueProbes2.add(data[4]); hashUniqueGenes2.add(gene); if (!hashEQTLs2.contains( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + gene)) { hashEQTLs2.add( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + gene); counterFile2++; } } } else { hashUniqueProbes2.add(data[4]); hashUniqueGenes2.add(data[16]); if (!hashEQTLs2.contains( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[16])) { hashEQTLs2.add( (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[16]); counterFile2++; } } } } } else { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[4])) { // hashEQTLs2.put(data[1] + "\t" + data[4], str); hashUniqueProbes2.add(data[4]); hashUniqueGenes2.add(data[16]); counterFile2++; } } } String[] QTL = null; String identifier = null; if (matchOnGeneName) { if (data.length > 16 && data[16].length() > 1) { if (splitGeneNames) { // NB Plotting and processing of all QTLs here is not okay! for (String gene : SEMI_COLON_PATTERN.split(data[16])) { if (!hashExcludeEQTLs.contains(data[1] + "\t" + gene)) { identifier = (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + gene; if (hashEQTLs.containsKey(identifier)) { QTL = hashEQTLs.get(identifier); } } } } else { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[16])) { identifier = (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[16]; if (hashEQTLs.containsKey(identifier)) { QTL = hashEQTLs.get(identifier); } } } } } else { if (!hashExcludeEQTLs.contains(data[1] + "\t" + data[4])) { identifier = (matchSnpOnPos ? data[2] + ":" + data[3] : data[1]) + "\t" + data[4]; if (hashEQTLs.containsKey(identifier)) { QTL = hashEQTLs.get(identifier); } } } if (QTL == null) { // The eQTL, present in file 2 is not present in file 1: // if (Double.parseDouble(data[0]); < 1E-4) { if (hashTestedSNPsThatPassedQC == null || hashTestedSNPsThatPassedQC.contains(data[1])) { log.write( "eQTL Present In New file But Not In Original File:\t" + identifier + "\t" + data[0] + "\t" + data[2] + "\t" + data[3] + "\t" + data[16] + "\n"); } // } double zScore2 = Double.parseDouble(data[10]); // int posX = 500 + (int) 0; // int posY = 500 - (int) Math.round(zScore2 * 10); zs.draw(null, zScore2, 0, 1); } else { identifiersUsed.add(identifier); String[] eQtlData = QTL; boolean identicalProbe = true; String probe = data[4]; String probeFound = eQtlData[4]; if (!probe.equals(probeFound)) { identicalProbe = false; } hashUniqueProbesOverlap.add(data[4]); hashUniqueGenesOverlap.add(data[16]); if (!hashEQTLNrTimesAssessed.containsKey(identifier)) { hashEQTLNrTimesAssessed.put(identifier, 1); } else { hashEQTLNrTimesAssessed.put(identifier, 1 + hashEQTLNrTimesAssessed.get(identifier)); } String alleles = eQtlData[8]; String alleleAssessed = eQtlData[9]; String correlations[] = (eQtlData[17]).split(";"); double correlation = 0; int numCorr1 = 0; for (int c = 0; c < correlations.length; c++) { try { if (!correlations[c].equals("-")) { correlation += Double.parseDouble(correlations[c]); numCorr1++; } } catch (Exception e) { } } correlation /= (double) numCorr1; // if(numCorr1 == 0){ // System.out.println("Warning: no correlations defined for // eqtl file 1"); // } double zScore = Double.parseDouble(eQtlData[10]); // double pValue = Double.parseDouble(eQtlData[0]); String alleles2 = data[8]; String alleleAssessed2 = data[9]; double zScore2 = Double.parseDouble(data[10]); // double pValue2 = Double.parseDouble(data[0]); String correlations2[] = data[17].split(";"); double correlation2 = 0; boolean alleleflipped = false; if (!alleleAssessed.equals(data[9])) { if (data[9].equals(eQtlData[8].split("/")[0])) { alleleflipped = true; } else { // System.out.println("WTF BBQ!"); } } int numCorr2 = 0; for (int c = 0; c < correlations2.length; c++) { try { if (!correlations2[c].equals("-")) { correlation2 += (Double.parseDouble(correlations2[c])); numCorr2++; } } catch (NumberFormatException e) { } } // if(numCorr2 == 0){ // System.out.println("Warning: no correlations defined for // eqtl file 2"); // } correlation2 /= (double) numCorr2; if (alleleflipped) { correlation2 = -correlation2; } boolean sameDirection = false; int nrIdenticalAlleles = 0; if (alleles.length() > 2 && alleles2.length() > 2) { for (int a = 0; a < 3; a++) { for (int b = 0; b < 3; b++) { if (a != 1 && b != 1) { if (alleles.getBytes()[a] == alleles2.getBytes()[b]) { nrIdenticalAlleles++; } } } } } if (nrIdenticalAlleles == 0) { alleles2 = (char) BaseAnnot.getComplement((byte) alleles2.charAt(0)) + "/" + (char) BaseAnnot.getComplement((byte) alleles2.charAt(2)); alleleAssessed2 = BaseAnnot.getComplement(alleleAssessed2); if (alleles.length() > 2 && alleles2.length() > 2) { for (int a = 0; a < 3; a++) { for (int b = 0; b < 3; b++) { if (a != 1 && b != 1) { if (alleles.getBytes()[a] == alleles2.getBytes()[b]) { nrIdenticalAlleles++; } } } } } } if (nrIdenticalAlleles != 2) { log.write( "Error! SNPs have incompatible alleles!!:\t" + alleles + "\t" + alleles2 + "\t" + identifier + "\n"); } else { overlap++; if (!alleleAssessed.equals(alleleAssessed2)) { zScore2 = -zScore2; // correlation2 = -correlation2; alleleAssessed2 = alleleAssessed; } // Recode alleles: // if contains T, but no A, take complement // if (alleles.contains("T") && !alleles.contains("A")) { // alleles = BaseAnnot.getComplement(alleles); // alleleAssessed = // BaseAnnot.getComplement(alleleAssessed); // alleleAssessed2 = // BaseAnnot.getComplement(alleleAssessed2); // } if (zScore2 * zScore > 0) { sameDirection = true; } // if(correlation != correlation2 && (numCorr1 > 0 && numCorr2 > // 0)){ // if(Math.abs(correlation - correlation2) > 0.00001){ // System.out.println("Correlations are different: // "+lineno+"\t"+correlation +"\t"+correlation2+"\t"+str); // } // // } zs.draw(zScore, zScore2, 0, 1); if (!sameDirection) { nreQTLsOppositeDirection++; if (matchOnGeneName) { disconcordantOut.append( data[1] + '\t' + data[16] + '\t' + alleles + '\t' + alleleAssessed + '\t' + zScore + '\t' + alleles2 + '\t' + alleleAssessed2 + '\t' + zScore2); } else { disconcordantOut.append( data[1] + '\t' + data[4] + '\t' + alleles + '\t' + alleleAssessed + '\t' + zScore + '\t' + alleles2 + '\t' + alleleAssessed2 + '\t' + zScore2); } // int posX = 500 + (int) Math.round(zScore * 10); // int posY = 500 - (int) Math.round(zScore2 * 10); vecX.add(zScore); vecY.add(zScore2); } else { // write to output identicalOut.writeln( identifier + '\t' + alleles + '\t' + alleleAssessed + '\t' + zScore + '\t' + alleles2 + '\t' + alleleAssessed2 + '\t' + zScore2); nreQTLsIdenticalDirection++; if (alleles.length() > 2 && !alleles.equals("A/T") && !alleles.equals("T/A") && !alleles.equals("C/G") && !alleles.equals("G/C")) { // int posX = 500 + (int) Math.round(zScore * 10); // int posY = 500 - (int) Math.round(zScore2 * 10); vecX.add(zScore); vecY.add(zScore2); } } } } } } } identicalOut.close(); disconcordantOut.close(); in.close(); log2.close(); log.write( "\n/// Writing missing QTLs observed in original file but not in the new file ////\n\n"); for (Entry<String, String[]> QTL : hashEQTLs.entrySet()) { if (!identifiersUsed.contains(QTL.getKey())) { // The eQTL, present in file 1 is not present in file 2: // if (Double.parseDouble(QTL.getValue()[0]) < 1E-4) { if (hashTestedSNPsThatPassedQC == null || hashTestedSNPsThatPassedQC.contains(data[1])) { log.write( "eQTL Present In Original file But Not In New File:\t" + QTL.getKey() + "\t" + QTL.getValue()[0] + "\t" + QTL.getValue()[2] + "\t" + QTL.getValue()[3] + "\t" + QTL.getValue()[16] + "\n"); } // } double zScore = Double.parseDouble(QTL.getValue()[10]); // int posX = 500 + (int) 0; // int posY = 500 - (int) Math.round(zScore * 10); zs.draw(zScore, null, 0, 1); } } log.close(); zs.write(zsOutFileName); double[] valsX = vecX.toArray(); double[] valsY = vecY.toArray(); if (valsX.length > 2) { double correlation = JSci.maths.ArrayMath.correlation(valsX, valsY); double r2 = correlation * correlation; cern.jet.random.tdouble.engine.DoubleRandomEngine randomEngine = new cern.jet.random.tdouble.engine.DRand(); cern.jet.random.tdouble.StudentT tDistColt = new cern.jet.random.tdouble.StudentT(valsX.length - 2, randomEngine); double pValuePearson = 1; double tValue = correlation / (Math.sqrt((1 - r2) / (double) (valsX.length - 2))); if (tValue < 0) { pValuePearson = tDistColt.cdf(tValue); } else { pValuePearson = tDistColt.cdf(-tValue); } pValuePearson *= 2; System.out.println( "\nCorrelation between the Z-Scores of the overlapping set of eQTLs:\t" + correlation + "\tP-Value:\t" + pValuePearson); } TextFile outSummary = new TextFile(outputFile + "-Summary.txt", TextFile.W); System.out.println(""); System.out.println( "Nr of eQTLs:\t" + hashEQTLs.size() + "\tin file:\t" + eQTL + "\tNrUniqueProbes:\t" + nrUniqueProbes + "\tNrUniqueGenes:\t" + nrUniqueGenes); outSummary.writeln( "Nr of eQTLs:\t" + hashEQTLs.size() + "\tin file:\t" + eQTL + "\tNrUniqueProbes:\t" + nrUniqueProbes + "\tNrUniqueGenes:\t" + nrUniqueGenes); System.out.println( "Nr of meQTLs:\t" + counterFile2 + "\tin file:\t" + meQTL + "\tNrUniqueProbes:\t" + hashUniqueProbes2.size() + "\tNrUniqueGenes:\t" + hashUniqueGenes2.size() + " *With eQTM mapping."); outSummary.writeln( "Nr of meQTLs:\t" + counterFile2 + "\tin file:\t" + meQTL + "\tNrUniqueProbes:\t" + hashUniqueProbes2.size() + "\tNrUniqueGenes:\t" + hashUniqueGenes2.size() + " *With eQTM mapping."); System.out.println("Skipped over meQTLs:\t" + skippedDueToMapping); outSummary.writeln("Skipped over meQTLs:\t" + skippedDueToMapping); System.out.println( "Overlap:\t" + overlap + "\tNrUniqueProbesOverlap:\t" + hashUniqueProbesOverlap.size() + "\tNrUniqueGenesOverlap:\t" + hashUniqueGenesOverlap.size()); outSummary.writeln( "Overlap:\t" + overlap + "\tNrUniqueProbesOverlap:\t" + hashUniqueProbesOverlap.size() + "\tNrUniqueGenesOverlap:\t" + hashUniqueGenesOverlap.size()); System.out.println(""); outSummary.writeln(); System.out.println("Nr eQTLs with identical direction:\t" + nreQTLsIdenticalDirection); outSummary.writeln("Nr eQTLs with identical direction:\t" + nreQTLsIdenticalDirection); double proportionOppositeDirection = 100d * (double) nreQTLsOppositeDirection / (double) (nreQTLsOppositeDirection + nreQTLsIdenticalDirection); String proportionOppositeDirectionString = (new java.text.DecimalFormat( "0.00;-0.00", new java.text.DecimalFormatSymbols(java.util.Locale.US))) .format(proportionOppositeDirection); System.out.println( "Nr eQTLs with opposite direction:\t" + nreQTLsOppositeDirection + "\t(" + proportionOppositeDirectionString + "%)"); outSummary.writeln( "Nr eQTLs with opposite direction:\t" + nreQTLsOppositeDirection + "\t(" + proportionOppositeDirectionString + "%)"); outSummary.close(); nrShared = hashUniqueProbesOverlap.size(); nrOpposite = nreQTLsOppositeDirection; }
/** * Build an array of <? extends {@link solver.variables.Variable}>. </br>WARNING: array's indice * are from 1 to n. * * @param name name of the array of variables.</br> Each variable is named like {@code name}_i. * @param type {@link parser.flatzinc.ast.declaration.DArray} object. * @param map * @param solver */ private static void buildWithDArray( String name, DArray type, Expression expression, THashMap<String, Object> map, Solver solver) { final DInt2 index = (DInt2) type.getIndex(0); // no need to get lowB, it is always 1 (see specification of FZN for more informations) final int size = index.getUpp(); final Declaration what = type.getWhat(); final IntVar[] vs; switch (what.typeOf) { case BOOL: BoolVar[] bs = new BoolVar[size]; if (expression == null) { for (int i = 1; i <= size; i++) { bs[i - 1] = buildWithBool(name + '_' + i, expression, map, solver); } } else if (expression.getTypeOf().equals(Expression.EType.ARR)) { EArray array = (EArray) expression; // build the array for (int i = 0; i < size; i++) { bs[i] = array.getWhat_i(i).boolVarValue(solver); } } map.put(name, bs); break; case INT: vs = new IntVar[size]; if (expression == null) { for (int i = 1; i <= size; i++) { vs[i - 1] = buildWithInt(name + '_' + i, null, map, solver); } } else if (expression.getTypeOf().equals(Expression.EType.ARR)) { buildFromIntArray(vs, (EArray) expression, size, solver); } map.put(name, vs); break; case INT2: vs = new IntVar[size]; if (expression == null) { for (int i = 1; i <= size; i++) { vs[i - 1] = buildWithInt2(name + '_' + i, (DInt2) what, expression, map, solver); } } else if (expression.getTypeOf().equals(Expression.EType.ARR)) { buildFromIntArray(vs, (EArray) expression, size, solver); } map.put(name, vs); break; case INTN: vs = new IntVar[size]; if (expression == null) { for (int i = 1; i <= size; i++) { vs[i - 1] = buildWithManyInt(name + '_' + i, (DManyInt) what, expression, map, solver); } } else if (expression.getTypeOf().equals(Expression.EType.ARR)) { buildFromIntArray(vs, (EArray) expression, size, solver); } map.put(name, vs); break; case SET: // final SetVariable[] svs = new SetVariable[size]; // for (int i = 1; i <= size; i++) { // svs[i - 1] = buildWithSet(name + '_' + i, (DSet) what, map); // } // map.put(name, svs); Exit.log("SET VAR"); break; default: break; } }