suppressPackageStartupMessages(library(gsalib)); suppressPackageStartupMessages(library(gplots)); eval.getMetrics <- function(eval, jexl_expression) { callset.counts = eval$CountVariants[which(eval$CountVariants$evaluation_name == "eval" & eval$CountVariants$comparison_name == "dbsnp" & eval$CountVariants$jexl_expression == jexl_expression),]; callset.counts.titv = eval$TiTv[which(eval$TiTv$evaluation_name == "eval" & eval$TiTv$comparison_name == "dbsnp" & eval$TiTv$jexl_expression == jexl_expression),]; callset.calledCounts = callset.counts[which(callset.counts$filter_name == "called" & callset.counts$novelty_name == "all"),]$nVariantLoci; callset.calledCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "called" & callset.counts.titv$novelty_name == "all"),]$ti.tv_ratio; callset.knownCounts = callset.counts[which(callset.counts$filter_name == "called" & callset.counts$novelty_name == "known"),]$nVariantLoci; callset.knownCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "called" & callset.counts.titv$novelty_name == "known"),]$ti.tv_ratio; callset.novelCounts = callset.counts[which(callset.counts$filter_name == "called" & callset.counts$novelty_name == "novel"),]$nVariantLoci; callset.novelCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "called" & callset.counts.titv$novelty_name == "novel"),]$ti.tv_ratio; callset.allFilteredCounts = callset.counts[which(callset.counts$filter_name == "filtered" & callset.counts$novelty_name == "all"),]$nVariantLoci; callset.allFilteredCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "filtered" & callset.counts.titv$novelty_name == "all"),]$ti.tv_ratio; callset.knownFilteredCounts = callset.counts[which(callset.counts$filter_name == "filtered" & callset.counts$novelty_name == "known"),]$nVariantLoci; callset.knownFilteredCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "filtered" & callset.counts.titv$novelty_name == "known"),]$ti.tv_ratio; callset.novelFilteredCounts = callset.counts[which(callset.counts$filter_name == "filtered" & callset.counts$novelty_name == "novel"),]$nVariantLoci; callset.novelFilteredCounts.titv = callset.counts.titv[which(callset.counts.titv$filter_name == "filtered" & callset.counts.titv$novelty_name == "novel"),]$ti.tv_ratio; metrics = list( all = callset.calledCounts, all.titv = callset.calledCounts.titv, known = callset.knownCounts, known.titv = callset.knownCounts.titv, novel = callset.novelCounts, novel.titv = callset.novelCounts.titv, filtered.all = callset.allFilteredCounts, filtered.all.titv = callset.allFilteredCounts.titv, filtered.known = callset.knownFilteredCounts, filtered.known.titv = callset.knownFilteredCounts.titv, filtered.novel = callset.novelFilteredCounts, filtered.novel.titv = callset.novelFilteredCounts.titv ); } .plot.callsetConcordance.getLabelText <- function(name, othername, metrics, filtered.metrics=NA, union) { if (is.na(filtered.metrics)) { text = sprintf("%s (%0.01f%% of union)\nCalled:\nAll: %d, Ti/Tv: %0.2f\nKnown: %d, Ti/Tv: %0.2f\nNovel: %d, Ti/Tv: %0.2f", name, 100*metrics$all/union$all.withfiltered, metrics$all, metrics$all.titv, metrics$known, metrics$known.titv, metrics$novel, metrics$novel.titv ); } else { text = sprintf("%s (%0.01f%% of union)\nCalled in %s, filtered in %s:\nAll: %d, Ti/Tv: %0.2f\nKnown: %d, Ti/Tv: %0.2f\nNovel: %d, Ti/Tv: %0.2f\n\nCalled in %s, absent in %s:\nAll: %d, Ti/Tv: %0.2f\nKnown: %d, Ti/Tv: %0.2f\nNovel: %d, Ti/Tv: %0.2f", name, 100*(metrics$all + filtered.metrics$all)/union$all.withfiltered, name, othername, filtered.metrics$all, filtered.metrics$all.titv, filtered.metrics$known, filtered.metrics$known.titv, filtered.metrics$novel, filtered.metrics$novel.titv, name, othername, metrics$all, metrics$all.titv, metrics$known, metrics$known.titv, metrics$novel, metrics$novel.titv ); } } plot.titlePage <- function(title, author) { textplot(sprintf("Automated Variant Report\n\n%s\n%s\n%s\n", title, author, Sys.Date())); } .plot.variantTable.getRowText <- function(eval, jexl_expression) { allVariants = eval$CountVariants[which(eval$CountVariants$jexl_expression == jexl_expression & eval$CountVariants$filter_name == "called" & eval$CountVariants$novelty_name == "all"),]$nVariantLoci; knownVariants = eval$CountVariants[which(eval$CountVariants$jexl_expression == jexl_expression & eval$CountVariants$filter_name == "called" & eval$CountVariants$novelty_name == "known"),]$nVariantLoci; novelVariants = eval$CountVariants[which(eval$CountVariants$jexl_expression == jexl_expression & eval$CountVariants$filter_name == "called" & eval$CountVariants$novelty_name == "novel"),]$nVariantLoci; allTiTv = eval$TiTv[which(eval$TiTv$jexl_expression == jexl_expression & eval$TiTv$filter_name == "called" & eval$TiTv$novelty_name == "all"),]$ti.tv_ratio; knownTiTv = eval$TiTv[which(eval$TiTv$jexl_expression == jexl_expression & eval$TiTv$filter_name == "called" & eval$TiTv$novelty_name == "known"),]$ti.tv_ratio; novelTiTv = eval$TiTv[which(eval$TiTv$jexl_expression == jexl_expression & eval$TiTv$filter_name == "called" & eval$TiTv$novelty_name == "novel"),]$ti.tv_ratio; cbind(allVariants, knownVariants, sprintf("%0.2f", knownTiTv), novelVariants, sprintf("%0.2f", novelTiTv)); } plot.variantTable <- function(eval, title) { aonly.row = .plot.variantTable.getRowText(eval, eval$CallsetOnlyNames[1]); aonly.filtered.row = .plot.variantTable.getRowText(eval, eval$CallsetFilteredNames[1]); intersection.row = .plot.variantTable.getRowText(eval, "Intersection"); bonly.row = .plot.variantTable.getRowText(eval, eval$CallsetOnlyNames[2]); bonly.filtered.row = .plot.variantTable.getRowText(eval, eval$CallsetFilteredNames[2]); variantsummary = as.data.frame(rbind(bonly.row, bonly.filtered.row, intersection.row, aonly.filtered.row, aonly.row)); rownames(variantsummary) = c( sprintf("Called in %s, absent in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), sprintf("Called in %s, filtered in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), "Intersection", sprintf("Called in %s, filtered in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]), sprintf("Called in %s, absent in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]) ); colnames(variantsummary) = c("counts (all)", "counts (known)", "ti/tv (known)", "counts (novel)", "ti/tv (novel)"); textplot(variantsummary); } plot.callsetConcordance <- function(eval, col=c("#FF6342", "#63C6DE", "#ADDE63")) { aonly = eval.getMetrics(eval, eval$CallsetOnlyNames[1]); aonly.filtered = eval.getMetrics(eval, eval$CallsetFilteredNames[1]); intersection = eval.getMetrics(eval, "Intersection"); bonly = eval.getMetrics(eval, eval$CallsetOnlyNames[2]); bonly.filtered = eval.getMetrics(eval, eval$CallsetFilteredNames[2]); union = list( all = intersection$all + aonly$all + bonly$all, all.withfiltered = intersection$all + aonly$all + bonly$all + aonly.filtered$all + bonly.filtered$all ); gsa.plot.venn(aonly$all + intersection$all + aonly.filtered$all, bonly$all + intersection$all + bonly.filtered$all, 0, intersection$all, 0, 0, pos=c(0.32, 0.32, 0.68, 0.70), col=col); text(0, 0.45, cex=1.2, pos=4, .plot.callsetConcordance.getLabelText(eval$CallsetNames[1], eval$CallsetNames[2], aonly, aonly.filtered, union)); text(0.5, 0.75, cex=1.2, adj=c(0.5, 0.33), .plot.callsetConcordance.getLabelText("Intersection", NA, intersection, NA, union)); text(1, 0.45, cex=1.2, pos=2, .plot.callsetConcordance.getLabelText(eval$CallsetNames[2], eval$CallsetNames[1], bonly, bonly.filtered, union)); } plot.callsetConcordanceByAC <- function(eval, normalize=TRUE, novelty_name="all", col=c("#FF6342", "#FF9675", "#5C92A4", "#88EEFF", "#55BBFF")) { aonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[1], novelty_name); aonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[1]); intersection = eval.getMetricsByAc(eval, "Intersection", novelty_name); bonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[2], novelty_name); bonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[2]); title = paste("Callset concordance per allele count (", novelty_name, " variants)", sep=""); if (length(intersection$AC) > 0 && length(aonly$AC) == 0) { aonly = intersection; aonly$n = 0; } if (length(intersection$AC) > 0 && length(bonly$AC) == 0) { bonly = intersection; bonly$n = 0; } if (length(intersection$AC) > 0 && length(aonly.filtered$AC) == 0) { aonly.filtered = intersection; aonly.filtered$n = 0; } if (length(intersection$AC) > 0 && length(bonly.filtered$AC) == 0) { bonly.filtered = intersection; bonly.filtered$n = 0; } #par.def = par(no.readonly = TRUE); #par(mar=c(5, 5, 3, 5)); if (normalize == TRUE) { norm = aonly$n + aonly.filtered$n + intersection$n + bonly$n + bonly.filtered$n; matnorm = rbind(aonly$n/norm, aonly.filtered$n/norm, intersection$n/norm, bonly.filtered$n/norm, bonly$n/norm); barplot(matnorm, col=col, xlab="Allele count", ylab="", main=title, names.arg=intersection$AC, xlim=c(1, 1.2*max(intersection$AC)), ylim=c(0, 1.3), border=NA, yaxt="n", cex=1.3, cex.axis=1.3, cex.lab=1.3); axis(2, at=seq(from=0, to=1, by=0.2), seq(from=0, to=1, by=0.2), cex=1.3, cex.axis=1.3); mtext("Fraction", side=2, at=0.5, padj=-3.0, cex=1.3); } else { mat = rbind(aonly$n, aonly.filtered$n, intersection$n, bonly.filtered$n, bonly$n); #barplot(mat, col=col, xlab="Allele count", ylab="counts", main=title, names.arg=intersection$AC, xlim=c(1, max(intersection$AC)), ylim=c(0, 1), border=NA, cex=1.3, cex.axis=1.3, cex.lab=1.3); barplot(mat, col=col, xlab="Allele count", ylab="counts", main=title, names.arg=intersection$AC, xlim=c(1, 1.2*max(intersection$AC)), border=NA, cex=1.3, cex.axis=1.3, cex.lab=1.3); #axis(2, at=seq(from=0, to=1, by=0.2), seq(from=0, to=1, by=0.2), cex=1.3, cex.axis=1.3); #mtext("Fraction", side=2, at=0.5, padj=-3.0, cex=1.3); } legend( "topright", c( sprintf("Called in %s, absent in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), sprintf("Called in %s, filtered in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), "Intersection", sprintf("Called in %s, filtered in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]), sprintf("Called in %s, absent in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]) ), fill=rev(col), cex=1.3 ); #par(par.def); } plot.alleleCountSpectrum <- function(eval, novelty_name="all", col=c("#FF6342", "#FF9675", "#5C92A4", "#88EEFF", "#55BBFF")) { aonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[1], novelty_name); aonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[1]); intersection = eval.getMetricsByAc(eval, "Intersection", novelty_name); intersection.all = eval.getMetrics(eval, "Intersection"); bonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[2], novelty_name); bonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[2]); title = paste("Allele count spectrum (", novelty_name, " variants)", sep=""); if (length(intersection$AC) > 0 && length(aonly$AC) == 0) { aonly = intersection; aonly$n = 0; } if (length(intersection$AC) > 0 && length(bonly$AC) == 0) { bonly = intersection; bonly$n = 0; } if (length(intersection$AC) > 0 && length(aonly.filtered$AC) == 0) { aonly.filtered = intersection; aonly.filtered$n = 0; } if (length(intersection$AC) > 0 && length(bonly.filtered$AC) == 0) { bonly.filtered = intersection; bonly.filtered$n = 0; } loci = (unique(eval$CountVariants$nProcessedLoci))[1]; ymax = 10*max((1/1000)*loci*(1/c(1:max(intersection$AC)))); suppressWarnings(plot(0, 0, type="n", xlim=c(1, length(intersection$AC)), ylim=c(1, ymax), xlab="Allele count", ylab="Number of variants", main=title, log="xy", bty="n", cex=1.3, cex.lab=1.3, cex.axis=1.3)); suppressWarnings(points(intersection$AC, aonly$n + aonly.filtered$n + intersection$n, type="l", lwd=2, col=col[1])); suppressWarnings(points(intersection$AC, aonly$n + intersection$n, type="l", lwd=2, lty=2, col=col[1])); suppressWarnings(points(intersection$AC, intersection$n, type="l", lwd=2, col=col[3])); suppressWarnings(points(intersection$AC, bonly$n + intersection$n, type="l", lwd=2, lty=2, col=col[4])); suppressWarnings(points(intersection$AC, bonly$n + bonly.filtered$n + intersection$n, type="l", lwd=2, col=col[5])); #points(c(1:max(intersection$AC)), 0.9*(1/1000)*loci*(1/c(1:max(intersection$AC))), type="l", lwd=2, lty=2, col="black"); legend( "bottomleft", c( sprintf("Intersection + called in %s, absent or filtered in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), sprintf("Intersection + called in %s, absent in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), "Intersection", sprintf("Intersection + called in %s, absent in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]), sprintf("Intersection + called in %s, absent or filtered in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2])#, #sprintf("Neutral expectation ( 0.9*(1/1000)*%0.1f*(1/c(1:max(%d))) )", loci, max(intersection$AC)) ), lwd=c(2, 2, 3, 2, 2, 2), lty=c(1, 2, 1, 2, 1, 2), col=c(rev(col), "black"), cex=1.3 ); } eval.getMetricsByAc <- function(eval, jexl, novelty="all") { piece = subset(eval$MetricsByAc, evaluation_name == "eval" & comparison_name == "dbsnp" & as.character(jexl_expression) == as.character(jexl) & filter_name == "called" & novelty_name == novelty ); } plot.titvSpectrum <- function(eval, novelty_name="all", col=c("#FF6342", "#FF9675", "#5C92A4", "#88EEFF", "#55BBFF")) { aonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[1], novelty_name); aonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[1]); intersection = eval.getMetricsByAc(eval, "Intersection", novelty_name); bonly = eval.getMetricsByAc(eval, eval$CallsetOnlyNames[2], novelty_name); bonly.filtered = eval.getMetricsByAc(eval, eval$CallsetFilteredNames[2]); title = paste("Ti/Tv spectrum (", novelty_name, " variants)", sep=""); if (length(intersection$AC) > 0 && length(aonly$AC) == 0) { aonly = intersection; aonly$n = 0; aonly$nTi = 0; aonly$nTv = 0; } if (length(intersection$AC) > 0 && length(bonly$AC) == 0) { bonly = intersection; bonly$n = 0; bonly$nTi = 0; bonly$nTv = 0; } if (length(intersection$AC) > 0 && length(aonly.filtered$AC) == 0) { aonly.filtered = intersection; aonly.filtered$n = 0; aonly.filtered$nTi = 0; aonly.filtered$nTv = 0; } if (length(intersection$AC) > 0 && length(bonly.filtered$AC) == 0) { bonly.filtered = intersection; bonly.filtered$n = 0; bonly.filtered$nTi = 0; bonly.filtered$nTv = 0; } titv.aonly.withfiltered = (aonly$nTi + aonly.filtered$nTi + intersection$nTi)/(aonly$nTv + aonly.filtered$nTv + intersection$nTv); titv.aonly.withfiltered.finite = titv.aonly.withfiltered[which(is.finite(titv.aonly.withfiltered))]; titv.aonly = (aonly$nTi + intersection$nTi)/(aonly$nTv + intersection$nTv); titv.aonly.finite = titv.aonly[which(is.finite(titv.aonly))]; titv.intersection.finite = intersection$Ti.Tv[which(is.finite(intersection$Ti.Tv))]; titv.bonly = (bonly$nTi + intersection$nTi)/(bonly$nTv + intersection$nTv); titv.bonly.finite = titv.bonly[which(is.finite(titv.bonly))]; titv.bonly.withfiltered = (bonly$nTi + bonly.filtered$nTi + intersection$nTi)/(bonly$nTv + bonly.filtered$nTv + intersection$nTv); titv.bonly.withfiltered.finite = titv.bonly.withfiltered[which(is.finite(titv.bonly.withfiltered))]; titv.min = min(titv.aonly.withfiltered.finite, titv.aonly.finite, titv.intersection.finite, titv.bonly.finite, titv.bonly.withfiltered.finite); titv.max = max(titv.aonly.withfiltered.finite, titv.aonly.finite, titv.intersection.finite, titv.bonly.finite, titv.bonly.withfiltered.finite); plot(0, 0, type="n", xlim=c(1, length(intersection$AC)), ylim=c(0, 4), xlab="Allele count", ylab="Transition/transversion (Ti/Tv) ratio", main=title, bty="n", cex=1.3, cex.lab=1.3, cex.axis=1.3); points(intersection$AC, (aonly.filtered$nTi + intersection$nTi)/(aonly.filtered$nTv + intersection$nTv), type="l", lwd=2, col=col[1]); points(intersection$AC, (aonly$nTi + intersection$nTi)/(aonly$nTv + intersection$nTv), type="l", lwd=2, lty=2, col=col[2]); points(intersection$AC, intersection$Ti.Tv, type="l", lwd=2, col=col[3]); points(intersection$AC, (bonly$nTi + intersection$nTi)/(bonly$nTv + intersection$nTv), type="l", lwd=2, lty=2, col=col[4]); points(intersection$AC, (bonly.filtered$nTi + intersection$nTi)/(bonly.filtered$nTv + intersection$nTv), type="l", lwd=2, col=col[5]); abline(h=2.3, lty=2); mtext("2.3", side=4, at=2.3, cex=0.9); abline(h=3.3, lty=2); mtext("3.3", side=4, at=3.3, cex=0.9); #legend("topleft", c(eval$CallsetOnlyNames[1], "Intersection", eval$CallsetOnlyNames[2]), fill=col); legend( "topleft", c( sprintf("Intersection + called in %s, absent or filtered in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), sprintf("Intersection + called in %s, absent in %s", eval$CallsetOnlyNames[2], eval$CallsetOnlyNames[1]), "Intersection", sprintf("Intersection + called in %s, absent in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]), sprintf("Intersection + called in %s, absent or filtered in %s", eval$CallsetOnlyNames[1], eval$CallsetOnlyNames[2]) ), lwd=c(2, 2, 3, 2, 2), lty=c(1, 2, 1, 2, 1), col=rev(col), cex=1.3 ); } plot.variantsPerSample2 <- function(eval) { if (!is.na(eval$MetricsBySample)) { metrics.all = eval$MetricsBySample[which(eval$MetricsBySample$evaluation_name == "eval" & eval$MetricsBySample$comparison_name == "dbsnp" & as.character(eval$MetricsBySample$jexl_expression) == "none" & eval$MetricsBySample$filter_name == "called" & eval$MetricsBySample$novelty_name == "all"),]; metrics.known = eval$MetricsBySample[which(eval$MetricsBySample$evaluation_name == "eval" & eval$MetricsBySample$comparison_name == "dbsnp" & as.character(eval$MetricsBySample$jexl_expression) == "none" & eval$MetricsBySample$filter_name == "called" & eval$MetricsBySample$novelty_name == "known"),]; metrics.novel = eval$MetricsBySample[which(eval$MetricsBySample$evaluation_name == "eval" & eval$MetricsBySample$comparison_name == "dbsnp" & as.character(eval$MetricsBySample$jexl_expression) == "none" & eval$MetricsBySample$filter_name == "called" & eval$MetricsBySample$novelty_name == "novel"),]; title = "Calls per sample"; indices = order(metrics.all$nVariants, decreasing=TRUE); plot(0, 0, type="n", xaxt="n", xlim=c(1, length(metrics.all$sample)), ylim=c(0, max(metrics.all$nVariants)), xlab="", ylab="Number of variants", main=title, bty="n"); points(c(1:length(metrics.all$sample)), (metrics.all$nVariants)[indices], pch=21, col="black"); points(c(1:length(metrics.known$sample)), (metrics.known$nVariants)[indices], pch=21, col="blue"); points(c(1:length(metrics.novel$sample)), (metrics.novel$nVariants)[indices], pch=21, col="red"); legend("topright", c("All", "Known", "Novel"), pch=21, col=c("black", "blue", "red")); axis(1, at=c(1:length(metrics.all$sample)), labels=(metrics.all$sample)[indices], las=2, cex.axis=0.4); } } plot.variantsPerSample <- function(eval, novelty_name="all") { if (!is.na(eval$SimpleMetricsBySample)) { metrics = eval$SimpleMetricsBySample[which(eval$SimpleMetricsBySample$evaluation_name == "eval" & eval$SimpleMetricsBySample$comparison_name == "dbsnp" & as.character(eval$SimpleMetricsBySample$jexl_expression) == "none" & eval$SimpleMetricsBySample$filter_name == "called" & eval$SimpleMetricsBySample$novelty_name == novelty_name),]; title = paste("Calls per sample (", novelty_name, ")", sep=""); indices = order(metrics$CountVariants, decreasing=TRUE); par.def = par(no.readonly = TRUE); par(mar=c(5, 4, 4, 4)); plot(0, 0, type="n", xaxt="n", xlim=c(1, length(metrics$row)), ylim=c(0, max(metrics$CountVariants)), xlab="", ylab="Number of variants", main=title, bty="n"); points(c(1:length(metrics$row)), (metrics$CountVariants)[indices], pch=21, col="black"); axis(1, at=c(1:length(metrics$row)), labels=(metrics$row)[indices], las=2, cex.axis=0.4); par(new=TRUE); plot(0, 0, type="n", xaxt="n", yaxt="n", xlim=c(1, length(metrics$row)), ylim=c(min(metrics$TiTvRatio), 1.2*max(metrics$TiTvRatio)), xlab="", ylab="", main=title, bty="n"); points(c(1:length(metrics$row)), (metrics$TiTvRatio)[indices], pch=19, col="black"); titvaxis = c(min(metrics$TiTvRatio), max(metrics$TiTvRatio)); axis(4, at=titvaxis, labels=titvaxis, las=2); par(par.def); } } argspec = list( evalRoot = list(value = NA, doc = "Path to the VariantEval R-output (omit the '.Analysis_Type.csv' part of the filename)"), plotOut = list(value = NA, doc = "Path to the output PDF file"), title = list(value = NA, doc = "The title of the report"), author = list(value = NA, doc = "The author of the report") ); cmdargs = gsa.getargs(argspec, doc="Take VariantEval R-output and generate a series of plots summarizing the contents"); eval = gsa.read.eval(cmdargs$evalRoot); pdf(cmdargs$plotOut, width=10, height=10); plot.titlePage(cmdargs$title, cmdargs$author); plot.variantTable(eval); if (length(eval$CallsetNames) > 0) { # Venn diagram plot.callsetConcordance(eval); # Venn by AC (normalized) plot.callsetConcordanceByAC(eval, novelty_name="all"); plot.callsetConcordanceByAC(eval, novelty_name="known"); plot.callsetConcordanceByAC(eval, novelty_name="novel"); # Venn by AC (unnormalized) plot.callsetConcordanceByAC(eval, novelty_name="all", normalize=FALSE); plot.callsetConcordanceByAC(eval, novelty_name="known", normalize=FALSE); plot.callsetConcordanceByAC(eval, novelty_name="novel", normalize=FALSE); # Allele count spectrum plot.alleleCountSpectrum(eval, novelty_name="all"); plot.alleleCountSpectrum(eval, novelty_name="known"); plot.alleleCountSpectrum(eval, novelty_name="novel"); # Ti/Tv spectrum plot.titvSpectrum(eval, novelty_name="all"); plot.titvSpectrum(eval, novelty_name="known"); plot.titvSpectrum(eval, novelty_name="novel"); # Per-sample #plot.variantsPerSample(eval); } else { #plot.variantsPerSample(eval, novelty_name="all"); #plot.variantsPerSample(eval, novelty_name="known"); #plot.variantsPerSample(eval, novelty_name="novel"); } dev.off();