R/internal.R
In dgiguer/omicplotR: Visual Exploration of Omic Datasets Using a Shiny App
Defines functions
omicplotr.anosim
omicplotr.clr
omicplotr.colouredPCA
omicplotr.getRemovedFeatures
omicplotr.getRemovedSamples
omicplotr.metadataFilter
omicplotr.permanova
omicplotr.report
omicplotr.filter
omicplotr.colvec
Documented in
omicplotr.anosim
omicplotr.clr
omicplotr.colouredPCA
omicplotr.colvec
omicplotr.filter
omicplotr.getRemovedFeatures
omicplotr.getRemovedSamples
omicplotr.metadataFilter
omicplotr.permanova
omicplotr.report
#' Internal omicplotR functions.
#'
#' Internal functions for the app are not intended to be called by the
#' user. Please refer to \link{omicplotr.run}.
#'
#' @author Daniel Giguere, Greg Gloor.
#'
#' @aliases omicplotr.anosim omicplotr.clr omicplotr.colvec omicplotr.filter
#' omicplotr.colouredPCA omicplotr.getRemovedSamples
#' omicplotr.getRemovedFeatures omicplotr.metadataFilter omicplotr.permanova
#' omicplotr.report
#'
#' @export
#'
#' @examples
#' # These functions are not meant to be called by the user. However, some
#' # functions can be useful.
#'
#' data(otu_table)
#' # Filter out your OTU table to remove rows that sum to less than 10.
#'
#' d <- omicplotr.filter(otu_table, min.reads = 10)
#'
#' @import ALDEx2
#'
omicplotr.anosim <- function(x, conds) {
#get rid of tax column
x$taxonomy <- NULL
#replace zeros
d <- zCompositions::cmultRepl(t(x), label = 0, method = "CZM")
#calculate clr
d.clr <- t(log(d) - rowMeans(log(d)))
#dissimilarity matrix
d.dist <- dist(d.clr)
#calculate anosim, requires
anosim(d.dist, conds, permutations = 999)
#p-value of between conditions
return(anosim$signif)
}
omicplotr.clr <- function(data, var.filt = 0, zero.method="CZM") {
# replace zeros catch error if no 0 present
if (any(data == 0)) {
if (zero.method == "CZM") {
data.0 <- zCompositions::cmultRepl(t(data), label = 0, method = "CZM")
}
if (zero.method == "pseudo") {
data.0 <- t(data + 0.5)
}
} else {
data.0 <- t(data)
}
# calculate CLR
#x.clr <- t(apply(data.0, 1, function(x) {log(x) - mean(log(x))}))
# calculate CLR
x.clr <- as.matrix(log(data.0) - rowMeans(log(data.0)))
# filter by variance
if (var.filt == 0) {
x.clr.var <- x.clr
} else {
# calculate variance
var.clr <- matrixStats::colVars(x.clr)
#replace names since colVars gets rid of them
names(var.clr) <- colnames(x.clr)
names.hvar <- names(var.clr)[which(var.clr > var.filt)]
x.clr.var <- x.clr[, names.hvar]
}
# generate prcomp object
x.pcx <- prcomp(x.clr.var)
}
omicplotr.colouredPCA <- function(data, colourvector, scale = 0, arrows = TRUE,
taxonomy = NULL, show.taxonomy = FALSE, tax.level = 6, removenames = FALSE,
names.cex = 1, points.cex = 0.8,
main = "Principal Component Analysis Biplot") {
x.var <- sum(data$sdev^2)
PC1 <- paste("PC 1 Variance: %", round(sum(data$sdev[1]^2)/x.var *
100, 1))
PC2 <- paste("PC 2 Variance: %", round(sum(data$sdev[2]^2)/x.var *
100, 1))
points <- c(rep(".", length(dimnames(data$rotation)[[1]])))
if ((isTRUE(show.taxonomy)) & (!is.null(taxonomy))) {
genus <- vapply(strsplit(as.character(taxonomy), ";"), "[", tax.level, FUN.VALUE=character(1))
}
col = c("black", rgb(0, 0, 0, 0.4))
# remove sample names
if (isTRUE(removenames)) {
xlabs <- c(rep(".", length(dimnames(data$x)[[1]])))
names.cex = 5 * names.cex
points.cex = points.cex
} else {
xlabs = unlist(dimnames(data$x)[1])
names.cex = names.cex
points.cex = points.cex
}
# if taxonomy is present, plot using taxonomies
if (!isTRUE(show.taxonomy)) {
points <- points
} else {
if (isTRUE(show.taxonomy)) {
points <- genus
} else {
points <- points
}
}
compositions::coloredBiplot(data, col = col, main = main, cex.main = 1.5,
cex = c(names.cex, points.cex), xlabs.col = colourvector,
var.axes = arrows, scale = scale, xlab = PC1, ylab = PC2,
xlabs = xlabs, ylabs = points)
}
omicplotr.getRemovedFeatures <- function(x, x.clr) {
# get rid of taxonomy column if it exists.
x$taxonomy <- NULL
# get original samples and retained samples
otu.names <- rownames(x)
otus <- dimnames(x.clr$rotation)[[1]]
otu.missing <- c()
# get missing samples
otu.missing <- otu.names[!otu.names %in% otus]
# samples that aren't na.
otu.missing <- otu.missing[!is.na(otu.missing)]
output <- x[otu.missing, ]
# include OTUs as column because renderDataTable doesn't include
# rownames
output <- cbind(OTUs = rownames(output), output)
return(output)
}
omicplotr.getRemovedSamples <- function(x, x.clr) {
# get rid of taxonomy column if it exists
x$taxonomy <- NULL
# get original samples and retained samples
names <- colnames(x)
samples <- dimnames(x.clr$x)[[1]]
missing <- c()
# samples
missing <- names[!names %in% samples]
missing <- missing[!is.na(missing)]
if (is.null(missing)) {
output <- missing
} else {
output <- x[, missing]
# work around for including rownames in dataTableOutput
output <- cbind(OTUs = rownames(output), output)
}
return(output)
}
omicplotr.metadataFilter <- function(data, meta, column, values) {
# order the metadata
meta <- meta[order(rownames(meta)), ]
# get rid of blank values
s <- values[values != ""]
# make list of samples
meta.filt <- rownames(meta[which(meta[[column]] %in% s), ])
# filter the data based on which samples remain in metadata
x <- data[which(colnames(data) %in% meta.filt)]
if (is.null(data$taxonomy)) {
x <- x
} else {
x$taxonomy <- data$taxonomy
}
return(x)
}
omicplotr.permanova <- function(x, conds) {
d.clr <- t(log(x) - rowMeans(log(x)))
dist.clr <- dist(d.clr)
conds <- data.frame(conds)
colnames(conds) <- "grp"
test <- adonis(dist.clr ~ grp, data = conds, method = "euclidean",
permutations = 10000)
return(test$`Pr(>F)`)
}
omicplotr.report <- function(x.all, feature = NULL) {
features <- rownames(x.all)[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# effect sizes
effect <- x.all$effect[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# diff btw and diff win
diff.btw <- x.all$diff.btw[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
diff.win <- x.all$diff.win[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# table of of significantly different OTUs with BH fdr < 0.1.
sig.output <- cbind(features, effect, diff.btw, diff.win)
}
omicplotr.filter <- function(data, min.reads = 0, min.count = 0, min.sum = 0,
min.prop = 0, max.prop = 1) {
if (is.null(data$taxonomy)) {
taxCheck <- TRUE
} else {
taxCheck <- FALSE
}
if (isTRUE(taxCheck)) {
# order for colouring
# make a matrix for vectorization
x <- as.matrix(data[order(colnames(data))])
# filter by min reads per sample
data.0 <- x[, which(colSums(x) > min.reads)]
# filter by min count per feature
data.1 <- data.0[which(matrixStats::rowMaxs(data.0) >= min.count), ]
# filter by sum of count per feature
data.2 <- data.1[which(rowSums(data.1) >= min.sum), ]
# calculate proportions
d.frac <- t(t(data.2)/colSums(data.2))
# filter by proportions, back to dataframe
x.filt <- as.data.frame(data.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop)),])
} else {
# order for colouring
tax <- data$taxonomy
x <- data[order(colnames(data[seq_len(length(data) - 1)]))]
# filter by min reads per sample
data.0 <- as.matrix(x[, which(colSums(x[, seq_along(x)]) >= min.reads)])
# since tax and data.0 are in the same order, separate, convert to matrix, and remove rows in both tax and data.0 that have max counts less than expected.
# filter by min count per feature, do the same for the tax
data.1 <- data.0[which(matrixStats::rowMaxs(data.0) >= min.count), ]
tax.1 <- tax[which(matrixStats::rowMaxs(data.0) >= min.count)]
# filter by sum of count per feature
data.2 <- data.1[which(rowSums(data.1) >= min.sum),]
tax.2 <- tax.1[which(rowSums(data.1) >= min.sum)]
# calculate proportions
d.frac <- t(t(data.2)/colSums(data.2))
# filter by proportions
x.filt <- as.data.frame(data.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop)),])
tax.filt <- as.data.frame(tax.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop))])
colnames(tax.filt) <- "taxonomy"
x.filt <- cbind(x.filt, tax.filt)
}
return(x.filt)
}
omicplotr.colvec <- function(data, meta, opacity = 1, column, type = 3) {
df <- as.data.frame(unlist(dimnames(data$x)[1]))
colnames(df) <- "samples"
# add empty column (which is gonna be the ample list for colouring)
df$correct <- NA
# introduces NA where metadata is not present for sample the important
# thing is that this keeps the order of the data
for (i in seq_along(df$samples)) {
if (df$samples[i] %in% rownames(meta)) {
df$correct[i] <- as.character(df$samples[i])
} else {
df$correct[i] <- NA
}
}
# colour column
df$colour <- NA
# if correct != present, colour black. this means metadata was missing
# for data point
df$colour[is.na(df$correct)] <- "black"
# get unique features of columns in metadata
u <- unique(meta[[column]])
# get rid of NAs
u <- u[!is.na(u)]
# default colour palette
colours <- c("indianred1", "steelblue3", "skyblue1", "mediumorchid",
"royalblue4", "olivedrab3", "pink", "#FFED6F", "mediumorchid3",
"ivory2")
# colour the colour column for up to ten colours
idx = match(meta[column][df$correct,], as.character(u))
df$colour = colours[idx]
df$colour[is.na(df$colour)] = "black"
# different colouringtype
if (type == 1) {
# TODO get rid of this if using command line
validate(need(is.integer(meta[[column]]), "Nonnumeric
data detected. Please click 'Nonnumeric metadata'"))
# get rid of old column made
df$colour <- NULL
# make age column
df$age <- NA
# get the age of each sample
for (i in seq_along(df$correct)) {
if (is.na(meta[column][df$correct[i], ])) {
df$age[i] <- NA
} else {
df$age[i] <- meta[column][df$correct[i], ]
}
}
# order data frame in order
df.sort <- df[order(df$age), ]
df.sort$col <- NA
# colour each unique number seperately
df.u <- unique(df.sort$age)
len <- length(df.u)
# generate colour function
c.hex <- colorRampPalette(c("red", "blue"))(len)
#convert colour value to rgb, get alpha input from opacity, convert
#back to hex
new.cols <- c()
for (i in seq_along(c.hex)) {
#get colour
col <- c.hex[i]
#convert to rgb
new.col <- col2rgb(col, alpha=TRUE)
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(new.col["red",1], new.col["green",1], new.col["blue",1], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
# colour each unique age
for (i in seq_along(df.sort$age)) {
df.sort$col[df.sort$age == df.u[i]] <- new.cols[i]
}
# colour the NAs black. these are missing data points.
for (i in seq_along(df.sort$age)) {
if (is.na(df.sort$col[i])) {
df.sort$col[i] <- rgb(0,0,0,opacity)
}
}
# reorder the df by sample now so it matches the data
df.sort <- df.sort[order(df.sort$samples), ]
# voila, c'est le colour!
sorted <- c()
sorted$col <- df.sort$col
} else if (type == 2) {
validate(need(is.integer(meta[[column]]), "Nonnumeric
data detected. Please click 'Nonnumeric metadata'"))
# quartile
df$colour <- NULL
# make age column
df$age <- NA
# get the age of each sample
for (i in seq_along(df$correct)) {
if (is.na(meta[column][df$correct[i], ])) {
df$age[i] <- NA
} else {
df$age[i] <- meta[column][df$correct[i], ]
}
}
df$col <- NA
c <- colorRampPalette(c("red", "blue"))(4)
#convert into rgb
c.rgb <- col2rgb(c, alpha = TRUE)
#convert back to hex with new alpha
new.cols <- c()
for (i in seq(dim(c.rgb)[2])) {
#get colour as rgb
c.rgb.1 <- c.rgb[,i]
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(c.rgb.1["red"], c.rgb.1["green"], c.rgb.1["blue"], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
# make quartile rank column
sorted <- within(df, col <- as.integer(cut(df$age, quantile(df$age,
na.rm = TRUE), include.lowest = TRUE)))
sorted$col <- new.cols[sorted$col]
# replace any NAs with black
sorted$col[is.na(sorted$col)] <- rgb(0,0,0,opacity)
} else if (type == 3) {
sorted <- c()
c.rgb <- col2rgb(df$colour, alpha = TRUE)
#convert back to hex with new alpha
new.cols <- c()
for (i in seq(dim(c.rgb)[2])) {
#get colour as rgb
c.rgb.1 <- c.rgb[,i]
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(c.rgb.1["red"], c.rgb.1["green"], c.rgb.1["blue"], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
sorted$col <- new.cols
} else {
return("")
}
return(sorted$col)
}
dgiguer/omicplotR documentation built on Nov. 19, 2019, 9:05 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Defines functions omicplotr.anosim omicplotr.clr omicplotr.colouredPCA omicplotr.getRemovedFeatures omicplotr.getRemovedSamples omicplotr.metadataFilter omicplotr.permanova omicplotr.report omicplotr.filter omicplotr.colvec
Documented in omicplotr.anosim omicplotr.clr omicplotr.colouredPCA omicplotr.colvec omicplotr.filter omicplotr.getRemovedFeatures omicplotr.getRemovedSamples omicplotr.metadataFilter omicplotr.permanova omicplotr.report
#' Internal omicplotR functions.
#'
#' Internal functions for the app are not intended to be called by the
#' user. Please refer to \link{omicplotr.run}.
#'
#' @author Daniel Giguere, Greg Gloor.
#'
#' @aliases omicplotr.anosim omicplotr.clr omicplotr.colvec omicplotr.filter
#' omicplotr.colouredPCA omicplotr.getRemovedSamples
#' omicplotr.getRemovedFeatures omicplotr.metadataFilter omicplotr.permanova
#' omicplotr.report
#'
#' @export
#'
#' @examples
#' # These functions are not meant to be called by the user. However, some
#' # functions can be useful.
#'
#' data(otu_table)
#' # Filter out your OTU table to remove rows that sum to less than 10.
#'
#' d <- omicplotr.filter(otu_table, min.reads = 10)
#'
#' @import ALDEx2
#'
omicplotr.anosim <- function(x, conds) {
#get rid of tax column
x$taxonomy <- NULL
#replace zeros
d <- zCompositions::cmultRepl(t(x), label = 0, method = "CZM")
#calculate clr
d.clr <- t(log(d) - rowMeans(log(d)))
#dissimilarity matrix
d.dist <- dist(d.clr)
#calculate anosim, requires
anosim(d.dist, conds, permutations = 999)
#p-value of between conditions
return(anosim$signif)
}
omicplotr.clr <- function(data, var.filt = 0, zero.method="CZM") {
# replace zeros catch error if no 0 present
if (any(data == 0)) {
if (zero.method == "CZM") {
data.0 <- zCompositions::cmultRepl(t(data), label = 0, method = "CZM")
}
if (zero.method == "pseudo") {
data.0 <- t(data + 0.5)
}
} else {
data.0 <- t(data)
}
# calculate CLR
#x.clr <- t(apply(data.0, 1, function(x) {log(x) - mean(log(x))}))
# calculate CLR
x.clr <- as.matrix(log(data.0) - rowMeans(log(data.0)))
# filter by variance
if (var.filt == 0) {
x.clr.var <- x.clr
} else {
# calculate variance
var.clr <- matrixStats::colVars(x.clr)
#replace names since colVars gets rid of them
names(var.clr) <- colnames(x.clr)
names.hvar <- names(var.clr)[which(var.clr > var.filt)]
x.clr.var <- x.clr[, names.hvar]
}
# generate prcomp object
x.pcx <- prcomp(x.clr.var)
}
omicplotr.colouredPCA <- function(data, colourvector, scale = 0, arrows = TRUE,
taxonomy = NULL, show.taxonomy = FALSE, tax.level = 6, removenames = FALSE,
names.cex = 1, points.cex = 0.8,
main = "Principal Component Analysis Biplot") {
x.var <- sum(data$sdev^2)
PC1 <- paste("PC 1 Variance: %", round(sum(data$sdev[1]^2)/x.var *
100, 1))
PC2 <- paste("PC 2 Variance: %", round(sum(data$sdev[2]^2)/x.var *
100, 1))
points <- c(rep(".", length(dimnames(data$rotation)[[1]])))
if ((isTRUE(show.taxonomy)) & (!is.null(taxonomy))) {
genus <- vapply(strsplit(as.character(taxonomy), ";"), "[", tax.level, FUN.VALUE=character(1))
}
col = c("black", rgb(0, 0, 0, 0.4))
# remove sample names
if (isTRUE(removenames)) {
xlabs <- c(rep(".", length(dimnames(data$x)[[1]])))
names.cex = 5 * names.cex
points.cex = points.cex
} else {
xlabs = unlist(dimnames(data$x)[1])
names.cex = names.cex
points.cex = points.cex
}
# if taxonomy is present, plot using taxonomies
if (!isTRUE(show.taxonomy)) {
points <- points
} else {
if (isTRUE(show.taxonomy)) {
points <- genus
} else {
points <- points
}
}
compositions::coloredBiplot(data, col = col, main = main, cex.main = 1.5,
cex = c(names.cex, points.cex), xlabs.col = colourvector,
var.axes = arrows, scale = scale, xlab = PC1, ylab = PC2,
xlabs = xlabs, ylabs = points)
}
omicplotr.getRemovedFeatures <- function(x, x.clr) {
# get rid of taxonomy column if it exists.
x$taxonomy <- NULL
# get original samples and retained samples
otu.names <- rownames(x)
otus <- dimnames(x.clr$rotation)[[1]]
otu.missing <- c()
# get missing samples
otu.missing <- otu.names[!otu.names %in% otus]
# samples that aren't na.
otu.missing <- otu.missing[!is.na(otu.missing)]
output <- x[otu.missing, ]
# include OTUs as column because renderDataTable doesn't include
# rownames
output <- cbind(OTUs = rownames(output), output)
return(output)
}
omicplotr.getRemovedSamples <- function(x, x.clr) {
# get rid of taxonomy column if it exists
x$taxonomy <- NULL
# get original samples and retained samples
names <- colnames(x)
samples <- dimnames(x.clr$x)[[1]]
missing <- c()
# samples
missing <- names[!names %in% samples]
missing <- missing[!is.na(missing)]
if (is.null(missing)) {
output <- missing
} else {
output <- x[, missing]
# work around for including rownames in dataTableOutput
output <- cbind(OTUs = rownames(output), output)
}
return(output)
}
omicplotr.metadataFilter <- function(data, meta, column, values) {
# order the metadata
meta <- meta[order(rownames(meta)), ]
# get rid of blank values
s <- values[values != ""]
# make list of samples
meta.filt <- rownames(meta[which(meta[[column]] %in% s), ])
# filter the data based on which samples remain in metadata
x <- data[which(colnames(data) %in% meta.filt)]
if (is.null(data$taxonomy)) {
x <- x
} else {
x$taxonomy <- data$taxonomy
}
return(x)
}
omicplotr.permanova <- function(x, conds) {
d.clr <- t(log(x) - rowMeans(log(x)))
dist.clr <- dist(d.clr)
conds <- data.frame(conds)
colnames(conds) <- "grp"
test <- adonis(dist.clr ~ grp, data = conds, method = "euclidean",
permutations = 10000)
return(test$`Pr(>F)`)
}
omicplotr.report <- function(x.all, feature = NULL) {
features <- rownames(x.all)[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# effect sizes
effect <- x.all$effect[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# diff btw and diff win
diff.btw <- x.all$diff.btw[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
diff.win <- x.all$diff.win[which(abs(x.all$effect) > 1 & x.all$we.eBH <
0.1)]
# table of of significantly different OTUs with BH fdr < 0.1.
sig.output <- cbind(features, effect, diff.btw, diff.win)
}
omicplotr.filter <- function(data, min.reads = 0, min.count = 0, min.sum = 0,
min.prop = 0, max.prop = 1) {
if (is.null(data$taxonomy)) {
taxCheck <- TRUE
} else {
taxCheck <- FALSE
}
if (isTRUE(taxCheck)) {
# order for colouring
# make a matrix for vectorization
x <- as.matrix(data[order(colnames(data))])
# filter by min reads per sample
data.0 <- x[, which(colSums(x) > min.reads)]
# filter by min count per feature
data.1 <- data.0[which(matrixStats::rowMaxs(data.0) >= min.count), ]
# filter by sum of count per feature
data.2 <- data.1[which(rowSums(data.1) >= min.sum), ]
# calculate proportions
d.frac <- t(t(data.2)/colSums(data.2))
# filter by proportions, back to dataframe
x.filt <- as.data.frame(data.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop)),])
} else {
# order for colouring
tax <- data$taxonomy
x <- data[order(colnames(data[seq_len(length(data) - 1)]))]
# filter by min reads per sample
data.0 <- as.matrix(x[, which(colSums(x[, seq_along(x)]) >= min.reads)])
# since tax and data.0 are in the same order, separate, convert to matrix, and remove rows in both tax and data.0 that have max counts less than expected.
# filter by min count per feature, do the same for the tax
data.1 <- data.0[which(matrixStats::rowMaxs(data.0) >= min.count), ]
tax.1 <- tax[which(matrixStats::rowMaxs(data.0) >= min.count)]
# filter by sum of count per feature
data.2 <- data.1[which(rowSums(data.1) >= min.sum),]
tax.2 <- tax.1[which(rowSums(data.1) >= min.sum)]
# calculate proportions
d.frac <- t(t(data.2)/colSums(data.2))
# filter by proportions
x.filt <- as.data.frame(data.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop)),])
tax.filt <- as.data.frame(tax.2[which((matrixStats::rowMaxs(d.frac) > min.prop) & (matrixStats::rowMaxs(d.frac) < max.prop))])
colnames(tax.filt) <- "taxonomy"
x.filt <- cbind(x.filt, tax.filt)
}
return(x.filt)
}
omicplotr.colvec <- function(data, meta, opacity = 1, column, type = 3) {
df <- as.data.frame(unlist(dimnames(data$x)[1]))
colnames(df) <- "samples"
# add empty column (which is gonna be the ample list for colouring)
df$correct <- NA
# introduces NA where metadata is not present for sample the important
# thing is that this keeps the order of the data
for (i in seq_along(df$samples)) {
if (df$samples[i] %in% rownames(meta)) {
df$correct[i] <- as.character(df$samples[i])
} else {
df$correct[i] <- NA
}
}
# colour column
df$colour <- NA
# if correct != present, colour black. this means metadata was missing
# for data point
df$colour[is.na(df$correct)] <- "black"
# get unique features of columns in metadata
u <- unique(meta[[column]])
# get rid of NAs
u <- u[!is.na(u)]
# default colour palette
colours <- c("indianred1", "steelblue3", "skyblue1", "mediumorchid",
"royalblue4", "olivedrab3", "pink", "#FFED6F", "mediumorchid3",
"ivory2")
# colour the colour column for up to ten colours
idx = match(meta[column][df$correct,], as.character(u))
df$colour = colours[idx]
df$colour[is.na(df$colour)] = "black"
# different colouringtype
if (type == 1) {
# TODO get rid of this if using command line
validate(need(is.integer(meta[[column]]), "Nonnumeric
data detected. Please click 'Nonnumeric metadata'"))
# get rid of old column made
df$colour <- NULL
# make age column
df$age <- NA
# get the age of each sample
for (i in seq_along(df$correct)) {
if (is.na(meta[column][df$correct[i], ])) {
df$age[i] <- NA
} else {
df$age[i] <- meta[column][df$correct[i], ]
}
}
# order data frame in order
df.sort <- df[order(df$age), ]
df.sort$col <- NA
# colour each unique number seperately
df.u <- unique(df.sort$age)
len <- length(df.u)
# generate colour function
c.hex <- colorRampPalette(c("red", "blue"))(len)
#convert colour value to rgb, get alpha input from opacity, convert
#back to hex
new.cols <- c()
for (i in seq_along(c.hex)) {
#get colour
col <- c.hex[i]
#convert to rgb
new.col <- col2rgb(col, alpha=TRUE)
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(new.col["red",1], new.col["green",1], new.col["blue",1], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
# colour each unique age
for (i in seq_along(df.sort$age)) {
df.sort$col[df.sort$age == df.u[i]] <- new.cols[i]
}
# colour the NAs black. these are missing data points.
for (i in seq_along(df.sort$age)) {
if (is.na(df.sort$col[i])) {
df.sort$col[i] <- rgb(0,0,0,opacity)
}
}
# reorder the df by sample now so it matches the data
df.sort <- df.sort[order(df.sort$samples), ]
# voila, c'est le colour!
sorted <- c()
sorted$col <- df.sort$col
} else if (type == 2) {
validate(need(is.integer(meta[[column]]), "Nonnumeric
data detected. Please click 'Nonnumeric metadata'"))
# quartile
df$colour <- NULL
# make age column
df$age <- NA
# get the age of each sample
for (i in seq_along(df$correct)) {
if (is.na(meta[column][df$correct[i], ])) {
df$age[i] <- NA
} else {
df$age[i] <- meta[column][df$correct[i], ]
}
}
df$col <- NA
c <- colorRampPalette(c("red", "blue"))(4)
#convert into rgb
c.rgb <- col2rgb(c, alpha = TRUE)
#convert back to hex with new alpha
new.cols <- c()
for (i in seq(dim(c.rgb)[2])) {
#get colour as rgb
c.rgb.1 <- c.rgb[,i]
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(c.rgb.1["red"], c.rgb.1["green"], c.rgb.1["blue"], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
# make quartile rank column
sorted <- within(df, col <- as.integer(cut(df$age, quantile(df$age,
na.rm = TRUE), include.lowest = TRUE)))
sorted$col <- new.cols[sorted$col]
# replace any NAs with black
sorted$col[is.na(sorted$col)] <- rgb(0,0,0,opacity)
} else if (type == 3) {
sorted <- c()
c.rgb <- col2rgb(df$colour, alpha = TRUE)
#convert back to hex with new alpha
new.cols <- c()
for (i in seq(dim(c.rgb)[2])) {
#get colour as rgb
c.rgb.1 <- c.rgb[,i]
#replace alpha with sliderInput
#convert colour with new opacity to hex
col.fin <- rgb(c.rgb.1["red"], c.rgb.1["green"], c.rgb.1["blue"], (opacity*255), maxColorValue=255)
new.cols <- c(new.cols, col.fin)
}
sorted$col <- new.cols
} else {
return("")
}
return(sorted$col)
}
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.