Nothing
R/plot-methods.R
In cn.mops: cn.mops - Mixture of Poissons for CNV detection in NGS data
Defines functions
.replaceNames
.makeLogRatios
.convertToFastSegRes
# Copyright (C) 2011 Klambauer Guenter
# <klambauer@bioinf.jku.at>
.convertToFastSegRes <- function(mopsres,segStat){
ol <- IRanges::findOverlaps(gr(mopsres),segmentation(mopsres))
ID <- as.character(values(segmentation(mopsres))$sampleName)
if (segStat=="mean")
seg.mean <- values(segmentation(mopsres))$mean
else
seg.mean <- values(segmentation(mopsres))$median
T <- table(subjectHits(ol))
nn <- length(gr(mopsres))
cs <- cumsum(T)%%nn
num.mark <- as.integer(T)
startRow <- c(1,(cs+1)[-length(cs)])
endRow <- cs
endRow[which(endRow==0)] <- nn
grRet <- segmentation(mopsres)
values(grRet) <- data.frame(ID=ID,num.mark=num.mark,seg.mean=seg.mean,
startRow=startRow,endRow=endRow,stringsAsFactors=FALSE)
return(grRet)
}
.makeLogRatios <- function(mopsres,mainCN="CN2"){
X <- mopsres@normalizedData
if (!is.null(mopsres@params$L[,mainCN])){
r <- mopsres@params$L[,mainCN]
#cat("lambda.\n")
} else {
#r <- apply(X,1,median)
r <- Biobase::rowMedians(X)
}
R <- (X+0.01)/(r+0.01)
#R[which(is.na(R))] <- 1
#R[which(R==Inf)] <- max(R[which(is.finite(R))],na.rm=TRUE)
#R[which(R==0)] <- min(R[which(R>0)],na.rm=TRUE)
R <- log2(R)
gr <- normalizedData(mopsres)
colnames(R) <- unique(as.character(
IRanges::values(segmentation(mopsres))$sampleName))
values(gr) <- R
return(gr)
}
# A function to replace the sample names in a CNVDetectionResult
# oldNames <- sample(colnames(r@normalizedData))
# newNames <- sapply(strsplit(oldNames,"/|\\."),.subset2,8)
.replaceNames <- function(r, oldNames, newNames){
#r is a CNVDetectionResult
idx <- match(colnames(r@normalizedData),oldNames)
colnames(r@normalizedData) <- newNames[idx]
colnames(r@localAssessments) <- newNames[idx]
colnames(r@individualCall) <- newNames[idx]
values(r@cnvs)["sampleName"] <- newNames[match(as.character(values(r@cnvs)[,1]),oldNames)]
CN <- values(r@cnvr)
colnames(CN) <- newNames[idx]
values(r@cnvr) <- CN
values(r@segmentation)["sampleName"] <-
newNames[match(as.character(values(r@segmentation)[,1]),oldNames)]
colnames(r@integerCopyNumber) <- newNames[idx]
r@sampleNames <- newNames[idx]
return(r)
}
#' @title Visualization of a CNV detection result.
#'
#' @description Plots read counts, call values and CNV calls in an identified CNV region.
#'
#' @param x An instance of "CNVDetectionResult"
#' @param which The index of the CNV region to be plotted.
#' @param margin Vector of two positive integers that states how many segments
#' left and right of the CNV region should be included in the plot. Default =
#' c(10,10).
#' @param toFile Logical value whether the output should be plotted to a file.
#' Default = FALSE.
#' @examples
#' data(cn.mops)
#' r <- cn.mops(X[1:200, ])
#' plot(r)
#' @return Generates a CNV calling plot.
#' @author Guenter Klambauer \email{klambauer@@bioinf.jku.at}
#' @noRd
#' @export
#' @importFrom graphics plot
setMethod("plot", signature(x="CNVDetectionResult",y="missing"),
function(x,which,margin=c(10,10),toFile=FALSE){
if (missing(which)){
message("Missing argument \"which\". Plotting the first CNVR.")
which <- 1
}
tmp <- GRanges(seqnames(x@cnvr), IRanges(start(x@cnvr), start(x@cnvr)))
MMstart <- findOverlaps(tmp, x@gr, select="first" )
tmp <- GRanges(seqnames(x@cnvr), IRanges(end(x@cnvr), end(x@cnvr)))
MMend <- findOverlaps(tmp, x@gr, select="first" )
for (select in which){
if (!toFile){
dev.new()
}
if (select>length(x@cnvr)){
stop("Selected unknown CNVR for plotting.")
}
refSeq <- as.character(seqnames(x@cnvr)[select])
start <- MMstart[select]
end <- MMend[select]
plotStart <- max(start - margin[1], 1)
plotEnd <- min(end + margin[2], nrow(x@normalizedData))
if (plotEnd == plotStart) {
plotStart <- plotStart - 1
}
layout(matrix(1:4,nrow=2))
normDataSel <- x@normalizedData[plotStart:plotEnd, ,drop=FALSE]
refSeqName <- unique(as.character(seqnames(x@cnvr)))
xlab <- paste(refSeq,": ", unlist(start(x@gr))[plotStart], " - ",
unlist(end(x@gr))[plotEnd], sep="")
lt <- x@params$lowerThreshold
ut <- x@params$upperThreshold
col <- rep("grey", ncol(x@normalizedData))
if (length(col)==1){
sampOrd <- 1
colOrd <- 1
} else {
if (is.numeric(lt) & is.numeric(ut)){
col[apply(x@individualCall[start:end, ,drop=FALSE] >= ut, 2, any)] <- "red"
col[apply(x@individualCall[start:end, ,drop=FALSE] <= lt, 2, any)] <- "blue"
}
sampOrd <- c(which(col == "grey"), which(col == "red"), which(col == "blue"))
colOrd <- col[sampOrd]
}
lty <- sample(2:6, replace=TRUE, size=ncol(x@normalizedData))
matplot(normDataSel[, sampOrd,drop=FALSE], type="l", lty=lty, lwd=2,
main="Normalized Read Counts", ylab="Read Count",
xlab=xlab, xaxt="n", col=colOrd)
axis(1, at=1:length(plotStart:plotEnd), labels=FALSE)
matplot(x@localAssessments[plotStart:plotEnd, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="Local Assessments",ylab="Local Assessment Score",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd), labels=FALSE)
RA <- (normDataSel + 0.1) / apply(normDataSel + 0.1, 1, median)
matplot(RA[, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="Read Count Ratios",ylab="Ratio",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd),
labels=FALSE)
matplot(x@individualCall[plotStart:plotEnd, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="CNV Call",ylab="CNV Call Value",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd),
labels=FALSE)
}
})
#setMethod("segPlot", signature(r="CNVDetectionResult"),
setGeneric("segplot",
function(r,mainCN="CN2", sampleIdx, seqnames, segStat="mean", plot.type="chrombysample",
altcol=TRUE, sbyc.layout, cbys.nchrom=1,
cbys.layout, include.means=TRUE, zeroline=TRUE,
pt.pch=".", pt.cex=3, pt.cols=c("green","black"),segcol,
zlcol="grey", ylim, lwd=3, ...) {
standardGeneric("segplot")
})
#' @title Visualization of a CNV detection result.
#'
#' @description Plots the log normalized read counts and the detected segments as a
#' segmentation plot.
#'
#' @param r An instance of "CNVDetectionResult"
#' @param mainCN The name of the main copy number. That is "CN2" for diploid
#' individuals. For haplocn.mops this should be set to "CN1".
#' @param sampleIdx The index of the samples to be plotted. (Default = missing)
#' @param seqnames The names of the reference sequence (chromosomes) to
#' be plotted. (Default = missing)
#' @param segStat Whether the segment line should display the mean or the
#' median of a segments calls. (Default = "mean").
#' @param plot.type the type of plot. (Default = "s").
#' @param altcol logical flag to indicate if chromosomes should be
#' plotted in alternating colors in the whole genome plot. (Default = TRUE).
#' @param sbyc.layout \code{layout} settings for the multifigure grid layout
#' for the `samplebychrom' type. It should be specified as a vector of
#' two integers which are the number of rows and columns. The default
#' values are chosen based on the number of chromosomes to produce a
#' near square graph. For normal genome it is 4x6 (24 chromosomes)
#' plotted by rows. (Default = NULL).
#' @param cbys.layout \code{layout} settings for the multifigure grid layout
#' for the `chrombysample' type. As above it should be specified as
#' number of rows and columns and the default chosen based on the
#' number of samples. (Default = NULL).
#' @param cbys.nchrom the number of chromosomes per page in the layout.
#'(Default = 1).
#' @param include.means logical flag to indicate whether segment means
#' are to be drawn. (Default = TRUE).
#' @param zeroline logical flag to indicate whether a horizontal line at
#' y=0 is to be drawn. (Default = TRUE).
#' @param pt.pch the plotting character used for plotting the log-ratio
#' values. (Default = ".")
#' @param pt.cex the size of plotting character used for the log-ratio
#' values (Default = 3).
#' @param pt.cols the color list for the points. The colors alternate
#' between chromosomes. (Default = c("green","black").)
#' @param segcol the color of the lines indicating the segment means.
#' (Default = "red").
#' @param zlcol the color of the zeroline. (Default = "grey").
#' @param ylim this argument is present to override the default limits
#' which is the range of symmetrized log-ratios. (Default = NULL).
#' @param lwd line weight of lines for segment mean and zeroline. (Default = 3).
#' @param ... other arguments which will be passed to \code{plot}
#' commands.
#' @examples
#' data(cn.mops)
#' r <- cn.mops(X[1:200, ])
#' segplot(r,sampleIdx=1)
#' @return Generates a segmentation plot.
#' @author Guenter Klambauer \email{klambauer@@bioinf.jku.at}
#' @export
setMethod("segplot",
signature(r="CNVDetectionResult"),
function(r, mainCN="CN2",sampleIdx, seqnames, segStat="mean",
plot.type="s",
altcol=TRUE, sbyc.layout, cbys.nchrom=1,
cbys.layout, include.means=TRUE, zeroline=TRUE,
pt.pch=".", pt.cex=3, pt.cols=c("green","black"),
segcol="red", zlcol="grey", ylim, lwd=3, ...) {
if (any(grepl("[^0-9A-Za-z]",colnames(r@normalizedData)))){
message(
paste("Segplot might not work because of special characters",
"in the sample names. Use only A-Z,a-z and 0-9! \n There",
"is a hidden function cn.mops:::.replaceNames that replaces",
"the names in the \"CNVDetectionResult\" object."))
}
if (any(!grepl("^[A-Za-z]",colnames(r@normalizedData)))){
message(
paste("Segplot might not work because of special characters",
"in the sample names. Use only A-Z,a-z and 0-9! \n There",
"is a hidden function cn.mops:::.replaceNames that replaces",
"the names in the \"CNVDetectionResult\" object."))
}
if (!missing(sampleIdx)){
sn <- sampleNames(r)
idx <- which(as.character(
values(segmentation(r))
$sampleName) %in% sn[sampleIdx])
r@segmentation <- segmentation(r)[idx]
#nd <- normalizedData(r)
#IRanges::values(nd) <- IRanges::values(nd)[,sampleIdx]
#IRanges::colnames(IRanges::values(nd)) <- sn[sampleIdx]
r@normalizedData <- r@normalizedData[ ,sampleIdx,drop=FALSE]
}
if (!missing(seqnames)){
idx <- which(as.character(GenomicRanges::seqnames(
segmentation(r))) %in% seqnames)
r@segmentation <- segmentation(r)[idx]
nd <- normalizedData(r)
idx2 <- which(as.character(GenomicRanges::seqnames(nd))
%in% seqnames)
if (length(idx2)==0){
stop(paste("Given \"seqnames\" do not appear in result",
"object. Try to exchange \"chr1\" <--> \"1\"."))
}
#nd <- nd[idx2]
r@gr <- r@gr[idx2]
r@normalizedData <- r@normalizedData[idx2, ,drop=FALSE]
if (!is.null(r@params$L)){
r@params$L <- r@params$L[idx2, ]
}
}
R <- .makeLogRatios(r,mainCN)
segm <- .convertToFastSegRes(r,segStat=segStat)
.segPlot(x=R,
res=segm,
plot.type=plot.type,
altcol=altcol,
cbys.nchrom=cbys.nchrom,
include.means=include.means,zeroline=zeroline,
pt.pch=pt.pch,pt.cex=pt.cex, pt.cols=pt.cols,segcol=segcol,
zlcol=zlcol, ylim=ylim, lwd=lwd, ...)
})
Try the cn.mops package in your browser
Any scripts or data that you put into this service are public.
cn.mops documentation built on Nov. 8, 2020, 5:59 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Defines functions .replaceNames .makeLogRatios .convertToFastSegRes
# Copyright (C) 2011 Klambauer Guenter
# <klambauer@bioinf.jku.at>
.convertToFastSegRes <- function(mopsres,segStat){
ol <- IRanges::findOverlaps(gr(mopsres),segmentation(mopsres))
ID <- as.character(values(segmentation(mopsres))$sampleName)
if (segStat=="mean")
seg.mean <- values(segmentation(mopsres))$mean
else
seg.mean <- values(segmentation(mopsres))$median
T <- table(subjectHits(ol))
nn <- length(gr(mopsres))
cs <- cumsum(T)%%nn
num.mark <- as.integer(T)
startRow <- c(1,(cs+1)[-length(cs)])
endRow <- cs
endRow[which(endRow==0)] <- nn
grRet <- segmentation(mopsres)
values(grRet) <- data.frame(ID=ID,num.mark=num.mark,seg.mean=seg.mean,
startRow=startRow,endRow=endRow,stringsAsFactors=FALSE)
return(grRet)
}
.makeLogRatios <- function(mopsres,mainCN="CN2"){
X <- mopsres@normalizedData
if (!is.null(mopsres@params$L[,mainCN])){
r <- mopsres@params$L[,mainCN]
#cat("lambda.\n")
} else {
#r <- apply(X,1,median)
r <- Biobase::rowMedians(X)
}
R <- (X+0.01)/(r+0.01)
#R[which(is.na(R))] <- 1
#R[which(R==Inf)] <- max(R[which(is.finite(R))],na.rm=TRUE)
#R[which(R==0)] <- min(R[which(R>0)],na.rm=TRUE)
R <- log2(R)
gr <- normalizedData(mopsres)
colnames(R) <- unique(as.character(
IRanges::values(segmentation(mopsres))$sampleName))
values(gr) <- R
return(gr)
}
# A function to replace the sample names in a CNVDetectionResult
# oldNames <- sample(colnames(r@normalizedData))
# newNames <- sapply(strsplit(oldNames,"/|\\."),.subset2,8)
.replaceNames <- function(r, oldNames, newNames){
#r is a CNVDetectionResult
idx <- match(colnames(r@normalizedData),oldNames)
colnames(r@normalizedData) <- newNames[idx]
colnames(r@localAssessments) <- newNames[idx]
colnames(r@individualCall) <- newNames[idx]
values(r@cnvs)["sampleName"] <- newNames[match(as.character(values(r@cnvs)[,1]),oldNames)]
CN <- values(r@cnvr)
colnames(CN) <- newNames[idx]
values(r@cnvr) <- CN
values(r@segmentation)["sampleName"] <-
newNames[match(as.character(values(r@segmentation)[,1]),oldNames)]
colnames(r@integerCopyNumber) <- newNames[idx]
r@sampleNames <- newNames[idx]
return(r)
}
#' @title Visualization of a CNV detection result.
#'
#' @description Plots read counts, call values and CNV calls in an identified CNV region.
#'
#' @param x An instance of "CNVDetectionResult"
#' @param which The index of the CNV region to be plotted.
#' @param margin Vector of two positive integers that states how many segments
#' left and right of the CNV region should be included in the plot. Default =
#' c(10,10).
#' @param toFile Logical value whether the output should be plotted to a file.
#' Default = FALSE.
#' @examples
#' data(cn.mops)
#' r <- cn.mops(X[1:200, ])
#' plot(r)
#' @return Generates a CNV calling plot.
#' @author Guenter Klambauer \email{klambauer@@bioinf.jku.at}
#' @noRd
#' @export
#' @importFrom graphics plot
setMethod("plot", signature(x="CNVDetectionResult",y="missing"),
function(x,which,margin=c(10,10),toFile=FALSE){
if (missing(which)){
message("Missing argument \"which\". Plotting the first CNVR.")
which <- 1
}
tmp <- GRanges(seqnames(x@cnvr), IRanges(start(x@cnvr), start(x@cnvr)))
MMstart <- findOverlaps(tmp, x@gr, select="first" )
tmp <- GRanges(seqnames(x@cnvr), IRanges(end(x@cnvr), end(x@cnvr)))
MMend <- findOverlaps(tmp, x@gr, select="first" )
for (select in which){
if (!toFile){
dev.new()
}
if (select>length(x@cnvr)){
stop("Selected unknown CNVR for plotting.")
}
refSeq <- as.character(seqnames(x@cnvr)[select])
start <- MMstart[select]
end <- MMend[select]
plotStart <- max(start - margin[1], 1)
plotEnd <- min(end + margin[2], nrow(x@normalizedData))
if (plotEnd == plotStart) {
plotStart <- plotStart - 1
}
layout(matrix(1:4,nrow=2))
normDataSel <- x@normalizedData[plotStart:plotEnd, ,drop=FALSE]
refSeqName <- unique(as.character(seqnames(x@cnvr)))
xlab <- paste(refSeq,": ", unlist(start(x@gr))[plotStart], " - ",
unlist(end(x@gr))[plotEnd], sep="")
lt <- x@params$lowerThreshold
ut <- x@params$upperThreshold
col <- rep("grey", ncol(x@normalizedData))
if (length(col)==1){
sampOrd <- 1
colOrd <- 1
} else {
if (is.numeric(lt) & is.numeric(ut)){
col[apply(x@individualCall[start:end, ,drop=FALSE] >= ut, 2, any)] <- "red"
col[apply(x@individualCall[start:end, ,drop=FALSE] <= lt, 2, any)] <- "blue"
}
sampOrd <- c(which(col == "grey"), which(col == "red"), which(col == "blue"))
colOrd <- col[sampOrd]
}
lty <- sample(2:6, replace=TRUE, size=ncol(x@normalizedData))
matplot(normDataSel[, sampOrd,drop=FALSE], type="l", lty=lty, lwd=2,
main="Normalized Read Counts", ylab="Read Count",
xlab=xlab, xaxt="n", col=colOrd)
axis(1, at=1:length(plotStart:plotEnd), labels=FALSE)
matplot(x@localAssessments[plotStart:plotEnd, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="Local Assessments",ylab="Local Assessment Score",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd), labels=FALSE)
RA <- (normDataSel + 0.1) / apply(normDataSel + 0.1, 1, median)
matplot(RA[, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="Read Count Ratios",ylab="Ratio",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd),
labels=FALSE)
matplot(x@individualCall[plotStart:plotEnd, sampOrd,drop=FALSE],type="l",lty=lty,lwd=2,
main="CNV Call",ylab="CNV Call Value",
xlab=xlab,xaxt="n",col=colOrd)
axis(1,at=1:length(plotStart:plotEnd),
labels=FALSE)
}
})
#setMethod("segPlot", signature(r="CNVDetectionResult"),
setGeneric("segplot",
function(r,mainCN="CN2", sampleIdx, seqnames, segStat="mean", plot.type="chrombysample",
altcol=TRUE, sbyc.layout, cbys.nchrom=1,
cbys.layout, include.means=TRUE, zeroline=TRUE,
pt.pch=".", pt.cex=3, pt.cols=c("green","black"),segcol,
zlcol="grey", ylim, lwd=3, ...) {
standardGeneric("segplot")
})
#' @title Visualization of a CNV detection result.
#'
#' @description Plots the log normalized read counts and the detected segments as a
#' segmentation plot.
#'
#' @param r An instance of "CNVDetectionResult"
#' @param mainCN The name of the main copy number. That is "CN2" for diploid
#' individuals. For haplocn.mops this should be set to "CN1".
#' @param sampleIdx The index of the samples to be plotted. (Default = missing)
#' @param seqnames The names of the reference sequence (chromosomes) to
#' be plotted. (Default = missing)
#' @param segStat Whether the segment line should display the mean or the
#' median of a segments calls. (Default = "mean").
#' @param plot.type the type of plot. (Default = "s").
#' @param altcol logical flag to indicate if chromosomes should be
#' plotted in alternating colors in the whole genome plot. (Default = TRUE).
#' @param sbyc.layout \code{layout} settings for the multifigure grid layout
#' for the `samplebychrom' type. It should be specified as a vector of
#' two integers which are the number of rows and columns. The default
#' values are chosen based on the number of chromosomes to produce a
#' near square graph. For normal genome it is 4x6 (24 chromosomes)
#' plotted by rows. (Default = NULL).
#' @param cbys.layout \code{layout} settings for the multifigure grid layout
#' for the `chrombysample' type. As above it should be specified as
#' number of rows and columns and the default chosen based on the
#' number of samples. (Default = NULL).
#' @param cbys.nchrom the number of chromosomes per page in the layout.
#'(Default = 1).
#' @param include.means logical flag to indicate whether segment means
#' are to be drawn. (Default = TRUE).
#' @param zeroline logical flag to indicate whether a horizontal line at
#' y=0 is to be drawn. (Default = TRUE).
#' @param pt.pch the plotting character used for plotting the log-ratio
#' values. (Default = ".")
#' @param pt.cex the size of plotting character used for the log-ratio
#' values (Default = 3).
#' @param pt.cols the color list for the points. The colors alternate
#' between chromosomes. (Default = c("green","black").)
#' @param segcol the color of the lines indicating the segment means.
#' (Default = "red").
#' @param zlcol the color of the zeroline. (Default = "grey").
#' @param ylim this argument is present to override the default limits
#' which is the range of symmetrized log-ratios. (Default = NULL).
#' @param lwd line weight of lines for segment mean and zeroline. (Default = 3).
#' @param ... other arguments which will be passed to \code{plot}
#' commands.
#' @examples
#' data(cn.mops)
#' r <- cn.mops(X[1:200, ])
#' segplot(r,sampleIdx=1)
#' @return Generates a segmentation plot.
#' @author Guenter Klambauer \email{klambauer@@bioinf.jku.at}
#' @export
setMethod("segplot",
signature(r="CNVDetectionResult"),
function(r, mainCN="CN2",sampleIdx, seqnames, segStat="mean",
plot.type="s",
altcol=TRUE, sbyc.layout, cbys.nchrom=1,
cbys.layout, include.means=TRUE, zeroline=TRUE,
pt.pch=".", pt.cex=3, pt.cols=c("green","black"),
segcol="red", zlcol="grey", ylim, lwd=3, ...) {
if (any(grepl("[^0-9A-Za-z]",colnames(r@normalizedData)))){
message(
paste("Segplot might not work because of special characters",
"in the sample names. Use only A-Z,a-z and 0-9! \n There",
"is a hidden function cn.mops:::.replaceNames that replaces",
"the names in the \"CNVDetectionResult\" object."))
}
if (any(!grepl("^[A-Za-z]",colnames(r@normalizedData)))){
message(
paste("Segplot might not work because of special characters",
"in the sample names. Use only A-Z,a-z and 0-9! \n There",
"is a hidden function cn.mops:::.replaceNames that replaces",
"the names in the \"CNVDetectionResult\" object."))
}
if (!missing(sampleIdx)){
sn <- sampleNames(r)
idx <- which(as.character(
values(segmentation(r))
$sampleName) %in% sn[sampleIdx])
r@segmentation <- segmentation(r)[idx]
#nd <- normalizedData(r)
#IRanges::values(nd) <- IRanges::values(nd)[,sampleIdx]
#IRanges::colnames(IRanges::values(nd)) <- sn[sampleIdx]
r@normalizedData <- r@normalizedData[ ,sampleIdx,drop=FALSE]
}
if (!missing(seqnames)){
idx <- which(as.character(GenomicRanges::seqnames(
segmentation(r))) %in% seqnames)
r@segmentation <- segmentation(r)[idx]
nd <- normalizedData(r)
idx2 <- which(as.character(GenomicRanges::seqnames(nd))
%in% seqnames)
if (length(idx2)==0){
stop(paste("Given \"seqnames\" do not appear in result",
"object. Try to exchange \"chr1\" <--> \"1\"."))
}
#nd <- nd[idx2]
r@gr <- r@gr[idx2]
r@normalizedData <- r@normalizedData[idx2, ,drop=FALSE]
if (!is.null(r@params$L)){
r@params$L <- r@params$L[idx2, ]
}
}
R <- .makeLogRatios(r,mainCN)
segm <- .convertToFastSegRes(r,segStat=segStat)
.segPlot(x=R,
res=segm,
plot.type=plot.type,
altcol=altcol,
cbys.nchrom=cbys.nchrom,
include.means=include.means,zeroline=zeroline,
pt.pch=pt.pch,pt.cex=pt.cex, pt.cols=pt.cols,segcol=segcol,
zlcol=zlcol, ylim=ylim, lwd=lwd, ...)
})
Try the cn.mops package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.