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library(WGCNA);
library(stringi);
library(rjson)
options(stringsAsFactors = FALSE);
cat("Running the wgcna analysis script\n")
# load expression data **assumes from json files row(traits)(columns info+samples)
# pass the file_path as arg
# pass the file path to read json data
args = commandArgs(trailingOnly=TRUE)
if (length(args)==0) {
stop("Argument for the file location is required", call.=FALSE)
} else {
# default output file
json_file_path = args[1]
}
inputData <- fromJSON(file = json_file_path)
imgDir = inputData$TMPDIR
inputData
trait_sample_data <- do.call(rbind, inputData$trait_sample_data)
dataExpr <- data.frame(apply(trait_sample_data, 2, function(x) as.numeric(as.character(x))))
# transform expressionData
dataExpr <- data.frame(t(dataExpr))
gsg = goodSamplesGenes(dataExpr, verbose = 3)
if (!gsg$allOK)
{
if (sum(!gsg$goodGenes)>0)
printFlush(paste("Removing genes:", paste(names(dataExpr)[!gsg$goodGenes], collapse = ", ")));
if (sum(!gsg$goodSamples)>0)
printFlush(paste("Removing samples:", paste(rownames(dataExpr)[!gsg$goodSamples], collapse = ", ")));
# Remove the offending genes and samples from the data:
dataExpr <- dataExpr[gsg$goodSamples, gsg$goodGenes]
}
## network constructions and modules
names(dataExpr) = inputData$trait_names
# Allow multi-threading within WGCNA
enableWGCNAThreads()
# powers <- c(c(1:10), seq(from = 12, to=20, by=2))
powers <- unlist(c(inputData$SoftThresholds))
sft <- pickSoftThreshold(dataExpr, powerVector = powers, verbose = 5)
# check the power estimate
if (is.na(sft$powerEstimate)){
powerEst = 1
}else{
powerEst = sft$powerEstimate
}
# pass user options
network <- blockwiseModules(dataExpr,
#similarity matrix options
corType = inputData$corType,
#adjacency matrix options
power = powerEst,
networkType = "unsigned",
#TOM options
TOMtype = inputData$TOMtype,
#module indentification
verbose = 3,
minmodulesSize = inputData$minModuleSize,
deepSplit = 3,
PamRespectsDendro = FALSE
)
cat("Generated network \n")
network
genImageRandStr <- function(prefix){
randStr <- paste(prefix,stri_rand_strings(1, 9, pattern = "[A-Za-z0-9]"),sep="_")
return(paste(randStr,".png",sep=""))
}
mergedColors <- labels2colors(network$colors)
imageLoc <- file.path(imgDir,genImageRandStr("WGCNAoutput"))
png(imageLoc,width=1000,height=600,type='cairo-png')
cat("Generating the CLuster dendrogram\n")
plotDendroAndColors(network$dendrograms[[1]],mergedColors[network$blockGenes[[1]]],
"Module colors",
dendroLabels = NULL, hang = 0.03,
addGuide = TRUE, guideHang = 0.05)
json_data <- list(input = inputData,
output = list(ModEigens=network$MEs,
soft_threshold=sft$fitIndices,
blockGenes =network$blockGenes[[1]],
net_colors =network$colors,
power_used_for_analy=powerEst,
net_unmerged=network$unmergedColors,
imageLoc=imageLoc))
json_data <- toJSON(json_data)
write(json_data,file= json_file_path)
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