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1 ##############################################################################
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2
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3 # Modified 06/29/12: Kar Ming Chu
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4 # Modified to work with Galaxy
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5
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6 # Usage: Rscript batch-consistency-analysis.r peakfile1 peakfile2 half.width overlap.ratio is.broadpeak sig.value gtable r.output overlap.output npeaks.output em.sav.output uri.sav.output
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7
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8 # Changes:
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9 # - Appended parameter for input gnome table called gtable
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10 # - Appended parameter for specifying Rout output file name (required by Galaxy)
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11 # - Appended parameter for specifying Peak overlap output file name (required by Galaxy)
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12 # - Appended parameter for specifying Npeak above IDR output file name (required by Galaxy)
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13 # - Removed parameter outfile.prefix since main output files are replaced with strict naming
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14 # - Appended parameter for specifying em.sav output file (for use with batch-consistency-plot.r)
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15 # - Appended parameter for specifying uri.sav output file (for use with batch-consistency-plot.r)
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16
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17 ##############################################################################
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18
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19 # modified 3-29-10: Qunhua Li
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20 # add 2 columns in the output of "-overlapped-peaks.txt": local.idr and IDR
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21
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22 # 01-20-2010 Qunhua Li
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23 #
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24 # This program performs consistency analysis for a pair of peak calling outputs
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25 # It takes narrowPeak or broadPeak formats.
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26 #
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27 # usage: Rscript batch-consistency-analysis2.r peakfile1 peakfile2 half.width outfile.prefix overlap.ratio is.broadpeak sig.value
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28 #
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29 # peakfile1 and peakfile2 : the output from peak callers in narrowPeak or broadPeak format
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30 # half.width: -1 if using the reported peak width,
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31 # a numerical value to truncate the peaks to
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32 # outfile.prefix: prefix of output file
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33 # overlap.ratio: a value between 0 and 1. It controls how much overlaps two peaks need to have to be called as calling the same region. It is the ratio of overlap / short peak of the two. When setting at 0, it means as long as overlapped width >=1bp, two peaks are deemed as calling the same region.
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34 # is.broadpeak: a logical value. If broadpeak is used, set as T; if narrowpeak is used, set as F
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35 # sig.value: type of significant values, "q.value", "p.value" or "signal.value" (default, i.e. fold of enrichment)
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36
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37 args <- commandArgs(trailingOnly=T)
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38
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39 # consistency between peakfile1 and peakfile2
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40 #input1.dir <- args[1]
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41 #input2.dir <- args[2] # directories of the two input files
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42 peakfile1 <- args[1]
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43 peakfile2 <- args[2]
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44
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45 if(as.numeric(args[3])==-1){ # enter -1 when using the reported length
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46 half.width <- NULL
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47 }else{
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48 half.width <- as.numeric(args[3])
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49 }
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50
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51 overlap.ratio <- args[4]
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52
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53 if(args[5] == "T"){
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54 is.broadpeak <- T
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55 }else{
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56 is.broadpeak <- F
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57 }
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58
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59 sig.value <- args[6]
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60
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61
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62 #dir1 <- "~/ENCODE/anshul/data/"
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63 #dir2 <- dir1
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64 #peakfile1 <- "../data/SPP.YaleRep1Gm12878Cfos.VS.Gm12878Input.PointPeak.narrowPeak"
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65 #peakfile2 <- "../data/SPP.YaleRep3Gm12878Cfos.VS.Gm12878Input.PointPeak.narrowPeak"
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66 #half.width <- NULL
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67 #overlap.ratio <- 0.1
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68 #sig.value <- "signal.value"
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69
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70
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71 source("/mnt/galaxyTools/galaxy-central/tools/modENCODE_DCC_tools/idr/functions-all-clayton-12-13.r")
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72
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73 # read the length of the chromosomes, which will be used to concatenate chr's
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74 # chr.file <- "genome_table.txt"
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75 # args[7] is the gtable
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76 chr.file <- args[7]
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77
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78 chr.size <- read.table(chr.file)
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79
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80 # setting output files
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81 r.output <- args[8]
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82 overlap.output <- args[9]
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83 npeaks.output <- args[10]
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84 em.sav.output <- args[11]
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85 uri.sav.output <- args[12]
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86
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87 # sink(paste(output.prefix, "-Rout.txt", sep=""))
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88 sink(r.output)
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89
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90 ############# process the data
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91 cat("is.broadpeak", is.broadpeak, "\n")
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92 # process data, summit: the representation of the location of summit
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93 rep1 <- process.narrowpeak(paste(peakfile1, sep=""), chr.size, half.width=half.width, summit="offset", broadpeak=is.broadpeak)
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94 rep2 <- process.narrowpeak(paste(peakfile2, sep=""), chr.size, half.width=half.width, summit="offset", broadpeak=is.broadpeak)
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95
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96 cat(paste("read", peakfile1, ": ", nrow(rep1$data.ori), "peaks\n", nrow(rep1$data.cleaned), "peaks are left after cleaning\n", peakfile2, ": ", nrow(rep2$data.ori), "peaks\n", nrow(rep2$data.cleaned), " peaks are left after cleaning"))
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97
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98 if(args[3]==-1){
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99 cat(paste("half.width=", "reported", "\n"))
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100 }else{
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101 cat(paste("half.width=", half.width, "\n"))
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102 }
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103 cat(paste("significant measure=", sig.value, "\n"))
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104
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105 # compute correspondence profile (URI)
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106 uri.output <- compute.pair.uri(rep1$data.cleaned, rep2$data.cleaned, sig.value1=sig.value, sig.value2=sig.value, overlap.ratio=overlap.ratio)
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107
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108 #uri.output <- compute.pair.uri(rep1$data.cleaned, rep2$data.cleaned)
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109
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110 cat(paste("URI is done\n"))
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111
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112 # save output
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113 # save(uri.output, file=paste(output.prefix, "-uri.sav", sep=""))
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114 save(uri.output, file=uri.sav.output)
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115 cat(paste("URI is saved at: ", uri.sav.output))
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116
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117
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118 # EM procedure for inference
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119 em.output <- fit.em(uri.output$data12.enrich, fix.rho2=T)
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120
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121 #em.output <- fit.2copula.em(uri.output$data12.enrich, fix.rho2=T, "gaussian")
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122
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123 cat(paste("EM is done\n\n"))
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124
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125 save(em.output, file=em.sav.output)
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126 cat(paste("EM is saved at: ", em.sav.output))
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127
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128
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129 # write em output into a file
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130
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131 cat(paste("EM estimation for the following files\n", peakfile1, "\n", peakfile2, "\n", sep=""))
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132
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133 print(em.output$em.fit$para)
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134
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135 # add on 3-29-10
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136 # output both local idr and IDR
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137 idr.local <- 1-em.output$em.fit$e.z
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138 IDR <- c()
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139 o <- order(idr.local)
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140 IDR[o] <- cumsum(idr.local[o])/c(1:length(o))
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141
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142
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143 write.out.data <- data.frame(chr1=em.output$data.pruned$sample1[, "chr"],
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144 start1=em.output$data.pruned$sample1[, "start.ori"],
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145 stop1=em.output$data.pruned$sample1[, "stop.ori"],
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146 sig.value1=em.output$data.pruned$sample1[, "sig.value"],
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147 chr2=em.output$data.pruned$sample2[, "chr"],
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148 start2=em.output$data.pruned$sample2[, "start.ori"],
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149 stop2=em.output$data.pruned$sample2[, "stop.ori"],
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150 sig.value2=em.output$data.pruned$sample2[, "sig.value"],
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151 idr.local=1-em.output$em.fit$e.z, IDR=IDR)
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152
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153 # write.table(write.out.data, file=paste(output.prefix, "-overlapped-peaks.txt", sep=""))
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154 write.table(write.out.data, file=overlap.output)
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155 cat(paste("Write overlapped peaks and local idr to: ", overlap.output, sep=""))
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156
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157 # number of peaks passing IDR range (0.01-0.25)
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158 IDR.cutoff <- seq(0.01, 0.25, by=0.01)
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159 idr.o <- order(write.out.data$idr.local)
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160 idr.ordered <- write.out.data$idr.local[idr.o]
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161 IDR.sum <- cumsum(idr.ordered)/c(1:length(idr.ordered))
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162
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163 IDR.count <- c()
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164 n.cutoff <- length(IDR.cutoff)
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165 for(i in 1:n.cutoff){
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166 IDR.count[i] <- sum(IDR.sum <= IDR.cutoff[i])
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167 }
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168
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169
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170 # write the number of peaks passing various IDR range into a file
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171 idr.cut <- data.frame(peakfile1, peakfile2, IDR.cutoff=IDR.cutoff, IDR.count=IDR.count)
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172 write.table(idr.cut, file=npeaks.output, append=T, quote=F, row.names=F, col.names=F)
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173 cat(paste("Write number of peaks above IDR cutoff [0.01, 0.25]: ","npeaks-aboveIDR.txt\n", sep=""))
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174
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175 mar.mean <- get.mar.mean(em.output$em.fit)
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176
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177 cat(paste("Marginal mean of two components:\n"))
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178 print(mar.mean)
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179
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180 sink()
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181
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182
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