R/GPrank.R
In ahonkela/tigre: Transcription factor Inference through Gaussian process Reconstruction of Expression
Defines functions
.filterTargets
.getProcessedData
generateModels
.formModel
GPRankTFs
GPRankTargets
GPLearn
Documented in
generateModels
GPLearn
GPRankTargets
GPRankTFs
GPLearn <- function(preprocData, TF = NULL, targets = NULL,
useGpdisim = !is.null(TF), randomize = FALSE,
addPriors = FALSE, fixedParams = FALSE,
initParams = NULL, initialZero = TRUE,
fixComps = NULL, dontOptimise = FALSE,
allowNegativeSensitivities = FALSE, quiet = FALSE,
gpsimOptions = NULL, allArgs = NULL) {
if (!is.null(allArgs)) {
for (i in seq(along=allArgs))
assign(names(allArgs)[[i]], allArgs[[i]])
}
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(targets))
stop("no target genes specified, unable to define a model")
if (is.list(targets))
targets <- unlist(targets)
if (useGpdisim)
genes <- c(TF, targets)
else
genes <- targets
if (class(try(preprocData[genes,], silent=TRUE)) == "try-error") {
if (! all(TF %in% featureNames(preprocData))) {
stop("unknown TF")
} else {
stop("unknown target gene")
}
}
# The preprocessed data is searched for the data of the specified genes.
newData <- .getProcessedData(preprocData[genes,])
y <- newData$y
yvar <- newData$yvar
times <- newData$times
Nrep <- length(y)
options <- list(includeNoise=0, optimiser="SCG")
if (any(yvar[[1]] == 0))
options$includeNoise = 1
if (!is.null(gpsimOptions)) {
for (i in seq(along=gpsimOptions))
options[[names(gpsimOptions)[[i]]]] <- gpsimOptions[[i]]
}
if (addPriors)
options$addPriors <- TRUE
if (!initialZero && useGpdisim)
options$timeSkew <- 1000.0
#options$gaussianInitial <- TRUE
if (useGpdisim) {
Ngenes <- length(genes) - 1
options$fix$names <- "di_variance"
options$fix$value <- expTransform(c(1), "xtoa")
}
else {
Ngenes <- length(genes)
if (allowNegativeSensitivities) {
options$fix$names <- "sim1_sensitivity"
options$fix$value <- 1
}
else {
options$fix$names <- "sim1_variance"
options$fix$value <- expTransform(c(1), "xtoa")
}
}
Ntf <- 1
if (initialZero && !useGpdisim) {
options$proteinPrior <- list(values=array(0), times=array(0))
## Set the variance of the latent function to 1.
options$fix$names <- append(options$fix$names, "rbf1_variance")
options$fix$value <- append(options$fix$value, expTransform(1, "xtoa"))
}
# fixing first output sensitivity to fix the scaling
if (fixedParams && !is.null(initParams)) {
if (is.list(initParams))
initParams <- unlist(initParams)
if (!is.null(names(initParams))) {
options$fix$names <- names(initParams)
options$fix$value <- initParams
}
else {
I <- which(!is.na(initParams))
for (k in 1:length(I)) {
options$fix$index[k+1] <- I[k]
options$fix$value[k+1] <- initParams[I[k]]
}
}
}
if (! is.null(fixComps))
options$fixedBlocks <- fixComps
if (allowNegativeSensitivities)
options$isNegativeS <- TRUE
# initializing the model
if (useGpdisim)
model <- list(type="cgpdisim")
else
model <- list(type="cgpsim")
if (length(annotation(preprocData)) > 0)
dataAnnotation <- annotation(preprocData)
else
dataAnnotation <- NULL
for ( i in seq(length=Nrep) ) {
#repNames <- names(model$comp)
if (useGpdisim) {
model$comp[[i]] <- gpdisimCreate(Ngenes, Ntf, times, t(y[[i]]), t(yvar[[i]]), options, genes = featureNames(preprocData[genes,]), annotation=dataAnnotation)
}
else {
model$comp[[i]] <- gpsimCreate(Ngenes, Ntf, times, t(y[[i]]), t(yvar[[i]]), options, genes = featureNames(preprocData[genes,]), annotation=dataAnnotation)
}
#names(model$comp) <- c(repNames, paste("rep", i, sep=""))
#if (fixedParams) {
# model$comp[[i]]$kern <- multiKernFixBlocks(model$comp[[i]]$kern, fixComps)
#}
}
optOptions <- optimiDefaultOptions()
optOptions$maxit <- 3000
optOptions$optimiser <- "SCG"
if (quiet)
optOptions$display <- FALSE
if (randomize) {
a <- modelExtractParam(model)
#I <- a==0
n <- length(a)
a <- array(rnorm(n), dim = c(1, n))
#a[I] <- 0
model <- modelExpandParam(model, a)
}
if (!is.null(initParams)) {
if (!is.list(initParams) && all(is.finite(initParams))
&& is.null(names(initParams)))
model <- modelExpandParam(model, initParams)
else if (!is.null(names(initParams))) {
params <- modelExtractParam(model, only.values=FALSE)
for (i in seq(along=initParams)) {
j <- grep(names(initParams)[i], names(params))
if (length(j) > 0)
params[j] <- initParams[i]
else
warning(paste("Ignoring invalid initial parameter specification:", initParams$names[i]))
}
model <- modelExpandParam(model, params)
}
}
if (!dontOptimise) {
if (useGpdisim) {
message(paste(c("Optimising the model.\nTF: ", TF, "\nTargets: ", paste(targets, collapse=' '), "\n"), sep=" "))
} else {
message(paste(c("Optimising the model.\nTargets: ", paste(genes, collapse=' '), "\n"), sep=" "))
}
model <- modelOptimise(model, optOptions)
}
model <- modelUpdateProcesses(model)
model$allArgs <- list(TF=TF, targets=targets, useGpdisim=useGpdisim,
randomize=randomize, addPriors=addPriors,
fixedParams=fixedParams, initParams=initParams,
initialZero=initialZero, fixComps=fixComps,
dontOptimise=dontOptimise, gpsimOptions=gpsimOptions)
return (new("GPModel", model))
}
GPRankTargets <- function(preprocData, TF = NULL, knownTargets = NULL,
testTargets = NULL, filterLimit = 1.8,
returnModels = FALSE, options = NULL,
scoreSaveFile = NULL,
datasetName = "", experimentSet = "") {
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(testTargets))
testTargets <- featureNames(preprocData)
if (is.list(testTargets))
testTargets <- unlist(testTargets)
if (is.list(knownTargets))
knownTargets <- unlist(knownTargets)
if (!is.null(TF) && !all(TF %in% featureNames(preprocData))) {
stop("unknown TF")
}
if (!all(knownTargets %in% featureNames(preprocData))) {
stop("unknown genes in knownTargets")
}
if (class(try(preprocData[testTargets,], silent=TRUE)) == "try-error") {
stop("unknown genes in testTargets")
}
if ('var.exprs' %in% assayDataElementNames(preprocData))
testTargets <- .filterTargets(preprocData[testTargets,], filterLimit)
else
testTargets <- featureNames(preprocData[testTargets,])
if (length(testTargets) < 1)
stop("No test targets passed filtering")
# The variable useGpdisim determines whether GPDISIM is used in creating the
# models. GPSIM (default) is used if no TF has been specified.
useGpdisim = !is.null(TF)
if (!useGpdisim && is.null(knownTargets))
stop("There are no known targets for GPSIM.")
if (useGpdisim)
numberOfKnownGenes <- length(knownTargets) + 1
else
numberOfKnownGenes <- length(knownTargets)
logLikelihoods <- rep(NA, length.out=length(testTargets))
baselogLikelihoods <- rep(NA, length.out=length(testTargets))
modelParams <- list()
modelArgs <- list()
if (returnModels)
rankedModels <- list()
genes <- list()
if (!is.null(options)) {
allArgs <- options
allArgs$useGpdisim <- useGpdisim
}
else
allArgs <- list(useGpdisim=useGpdisim)
if (!is.null(knownTargets) && length(knownTargets) > 0) {
baselineModel <- .formModel(preprocData, TF, knownTargets, allArgs=allArgs)
baselineParameters <- modelExtractParam(baselineModel$model,
only.values=FALSE)
sharedModel <- list(ll=baselineModel$ll,
params=baselineModel$params,
args=modelStruct(baselineModel$model)$allArgs)
allArgs$fixedParams <- TRUE
allArgs$initParams <- baselineParameters
J <- grep('Basal', names(allArgs$initParams))
names(allArgs$initParams)[J] <-
paste(names(allArgs$initParams)[J], '$', sep='')
allArgs$fixComps <- 1:numberOfKnownGenes
}
else {
baselineModel <- NULL
}
for (i in seq(along=testTargets)) {
returnData <- .formModel(preprocData, TF, knownTargets,
testTargets[i], allArgs = allArgs)
if (!is.finite(returnData$ll)) {
logLikelihoods[i] <- NA
modelParams[[i]] <- NA
modelArgs[[i]] <- NA
if (returnModels)
rankedModels[[i]] <- NA
}
else {
logLikelihoods[i] <- returnData$ll
modelParams[[i]] <- returnData$params
modelArgs[[i]] <- modelStruct(returnData$model)$allArgs
if (returnModels)
rankedModels[[i]] <- returnData$model
}
genes[[i]] <- testTargets[[i]]
testdata <- preprocData[testTargets[i],]
testdata$experiments <- rep(1, length(testdata$experiments))
newData <- .getProcessedData(testdata)
baselogLikelihoods[i] <- .baselineOptimise(newData$y[[1]], newData$yvar[[1]], list(includeNoise=(any(newData$yvar[[1]]==0))))
if (!is.null(scoreSaveFile)) {
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
baseloglikelihoods = baselogLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = knownTargets, TF = TF,
sharedModel = sharedModel,
datasetName = datasetName,
experimentSet = experimentSet)
save(scoreList, file=scoreSaveFile)
}
}
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
baseloglikelihoods = baselogLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = knownTargets, TF = TF,
sharedModel = sharedModel,
datasetName = datasetName,
experimentSet = experimentSet)
if (returnModels)
return (list(scores=scoreList, models=rankedModels))
else
return (scoreList)
}
GPRankTFs <- function(preprocData, TFs, targets,
filterLimit = 1.8,
returnModels = FALSE, options = NULL,
scoreSaveFile = NULL,
datasetName = "", experimentSet = "") {
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(targets)) stop("No targets specified.")
if (is.list(targets))
targets <- unlist(targets)
numberOfTargets <- length(targets)
genes = c(TFs, targets)
if (class(try(preprocData[TFs,], silent=TRUE)) == "try-error") {
stop("unknown genes in TFs")
}
if (!all(targets %in% featureNames(preprocData))) {
stop("unknown genes in targets")
}
## Filtering the genes based on the calculated ratios. If the limit is 0, all genes are accepted.
if ('var.exprs' %in% assayDataElementNames(preprocData))
TFs <- .filterTargets(preprocData[TFs,], filterLimit)
else
TFs <- featureNames(preprocData[TFs,])
if (length(TFs) < 1)
stop("No TFs passed the filtering.")
logLikelihoods <- rep(NA, length.out=length(TFs))
modelParams <- list()
modelArgs <- list()
if (returnModels)
rankedModels <- list()
if (!is.null(options)) {
allArgs <- options
allArgs$useGpdisim <- TRUE
}
else
allArgs <- list(useGpdisim=TRUE)
numberOfTargets <- length(targets)
genes <- list()
for (i in 1:length(TFs)) {
returnData <- .formModel(preprocData, TF = TFs[i], targets, allArgs=allArgs)
if (!is.finite(returnData$ll)) {
logLikelihoods[i] <- NA
modelParams[[i]] <- NA
modelArgs[[i]] <- NA
if (returnModels)
rankedModels[[i]] <- NA
}
else {
logLikelihoods[i] <- returnData$ll
modelParams[[i]] <- returnData$params
modelArgs[[i]] <- modelStruct(returnData$model)$allArgs
if (returnModels)
rankedModels[[i]] <- returnData$model
}
genes[[i]] <- TFs[[i]]
if (!is.null(scoreSaveFile)) {
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = targets, TF = '(see genes)',
datasetName = datasetName,
experimentSet = experimentSet)
save(scoreList, file=scoreSaveFile)
}
}
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = targets, TF = '(see genes)',
datasetName = datasetName,
experimentSet = experimentSet)
if (returnModels)
return (list(scores=scoreList, models=rankedModels))
else
return (scoreList)
}
.formModel <- function(preprocData, TF = NULL, knownTargets = NULL,
testTarget = NULL, allArgs = NULL) {
if (!is.null(testTarget))
targets <- append(knownTargets, testTarget)
else
targets <- knownTargets
error1 <- TRUE
error2 <- TRUE
tryCatch({
model <- GPLearn(preprocData, TF, targets, allArgs = allArgs)
error1 <- FALSE
}, error = function(ex) {
warning("Stopped due to an error.\n")
})
if (error1) {
success <- FALSE
i <- 0
allArgs$randomize <- TRUE
while (!success && i < 10) {
tryCatch({
message("Trying again with different parameters.\n")
model <- GPLearn(preprocData, TF, targets, allArgs = allArgs)
success <- TRUE
error2 <- FALSE
}, error = function(ex) {
warning("Stopped due to an error.\n")
})
i <- i + 1
}
}
else {
error2 <- FALSE
}
if (error2) {
logLikelihood <- -Inf
params <- NA
rankedModel <- NA
}
else {
logLikelihood <- modelLogLikelihood(model)
params <- modelExtractParam(model)
rankedModel <- model
}
return (list(ll=logLikelihood, model=rankedModel, params=params))
}
generateModels <- function(preprocData, scores) {
models <- list()
# recreate the models for each gene in the scoreList
for (i in seq(along=params(scores))) {
args <- modelArgs(scores)[[i]]
args$initParams <- params(scores)[[i]]
args$dontOptimise <- TRUE
models[[i]] <- GPLearn(preprocData, allArgs=args)
}
return (models)
}
.getProcessedData <- function(data) {
times <- data$modeltime
experiments <- data$experiments
y <- assayDataElement(data, 'exprs')
if ('var.exprs' %in% assayDataElementNames(data))
yvar <- assayDataElement(data, 'var.exprs')
else
yvar <- 0 * y
scale <- sqrt(rowMeans(y^2))
scale[scale==0] <- 1
scaleMat <- scale %*% array(1, dim = c(1, ncol(data)))
y <- y / scaleMat
yvar <- yvar / scaleMat^2
ylist <- list()
yvarlist <- list()
expids <- unique(experiments)
for (i in seq(along=expids)) {
ylist[[i]] <- y[,experiments==expids[i], drop=FALSE]
yvarlist[[i]] <- yvar[,experiments==expids[i], drop=FALSE]
}
times <- times[experiments==expids[1]]
genes <- featureNames(data)
newData <- list(y = ylist, yvar = yvarlist, genes = genes, times = times)
return (newData)
}
.filterTargets <- function(data, filterLimit) {
y <- assayDataElement(data, 'exprs')
yvar <- assayDataElement(data, 'var.exprs')
zScores <- rowMeans(y / sqrt(yvar))
testTargets <- names(which(zScores > filterLimit))
return (testTargets)
}
ahonkela/tigre documentation built on Aug. 6, 2021, 12:08 p.m.
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Defines functions .filterTargets .getProcessedData generateModels .formModel GPRankTFs GPRankTargets GPLearn
Documented in generateModels GPLearn GPRankTargets GPRankTFs
GPLearn <- function(preprocData, TF = NULL, targets = NULL,
useGpdisim = !is.null(TF), randomize = FALSE,
addPriors = FALSE, fixedParams = FALSE,
initParams = NULL, initialZero = TRUE,
fixComps = NULL, dontOptimise = FALSE,
allowNegativeSensitivities = FALSE, quiet = FALSE,
gpsimOptions = NULL, allArgs = NULL) {
if (!is.null(allArgs)) {
for (i in seq(along=allArgs))
assign(names(allArgs)[[i]], allArgs[[i]])
}
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(targets))
stop("no target genes specified, unable to define a model")
if (is.list(targets))
targets <- unlist(targets)
if (useGpdisim)
genes <- c(TF, targets)
else
genes <- targets
if (class(try(preprocData[genes,], silent=TRUE)) == "try-error") {
if (! all(TF %in% featureNames(preprocData))) {
stop("unknown TF")
} else {
stop("unknown target gene")
}
}
# The preprocessed data is searched for the data of the specified genes.
newData <- .getProcessedData(preprocData[genes,])
y <- newData$y
yvar <- newData$yvar
times <- newData$times
Nrep <- length(y)
options <- list(includeNoise=0, optimiser="SCG")
if (any(yvar[[1]] == 0))
options$includeNoise = 1
if (!is.null(gpsimOptions)) {
for (i in seq(along=gpsimOptions))
options[[names(gpsimOptions)[[i]]]] <- gpsimOptions[[i]]
}
if (addPriors)
options$addPriors <- TRUE
if (!initialZero && useGpdisim)
options$timeSkew <- 1000.0
#options$gaussianInitial <- TRUE
if (useGpdisim) {
Ngenes <- length(genes) - 1
options$fix$names <- "di_variance"
options$fix$value <- expTransform(c(1), "xtoa")
}
else {
Ngenes <- length(genes)
if (allowNegativeSensitivities) {
options$fix$names <- "sim1_sensitivity"
options$fix$value <- 1
}
else {
options$fix$names <- "sim1_variance"
options$fix$value <- expTransform(c(1), "xtoa")
}
}
Ntf <- 1
if (initialZero && !useGpdisim) {
options$proteinPrior <- list(values=array(0), times=array(0))
## Set the variance of the latent function to 1.
options$fix$names <- append(options$fix$names, "rbf1_variance")
options$fix$value <- append(options$fix$value, expTransform(1, "xtoa"))
}
# fixing first output sensitivity to fix the scaling
if (fixedParams && !is.null(initParams)) {
if (is.list(initParams))
initParams <- unlist(initParams)
if (!is.null(names(initParams))) {
options$fix$names <- names(initParams)
options$fix$value <- initParams
}
else {
I <- which(!is.na(initParams))
for (k in 1:length(I)) {
options$fix$index[k+1] <- I[k]
options$fix$value[k+1] <- initParams[I[k]]
}
}
}
if (! is.null(fixComps))
options$fixedBlocks <- fixComps
if (allowNegativeSensitivities)
options$isNegativeS <- TRUE
# initializing the model
if (useGpdisim)
model <- list(type="cgpdisim")
else
model <- list(type="cgpsim")
if (length(annotation(preprocData)) > 0)
dataAnnotation <- annotation(preprocData)
else
dataAnnotation <- NULL
for ( i in seq(length=Nrep) ) {
#repNames <- names(model$comp)
if (useGpdisim) {
model$comp[[i]] <- gpdisimCreate(Ngenes, Ntf, times, t(y[[i]]), t(yvar[[i]]), options, genes = featureNames(preprocData[genes,]), annotation=dataAnnotation)
}
else {
model$comp[[i]] <- gpsimCreate(Ngenes, Ntf, times, t(y[[i]]), t(yvar[[i]]), options, genes = featureNames(preprocData[genes,]), annotation=dataAnnotation)
}
#names(model$comp) <- c(repNames, paste("rep", i, sep=""))
#if (fixedParams) {
# model$comp[[i]]$kern <- multiKernFixBlocks(model$comp[[i]]$kern, fixComps)
#}
}
optOptions <- optimiDefaultOptions()
optOptions$maxit <- 3000
optOptions$optimiser <- "SCG"
if (quiet)
optOptions$display <- FALSE
if (randomize) {
a <- modelExtractParam(model)
#I <- a==0
n <- length(a)
a <- array(rnorm(n), dim = c(1, n))
#a[I] <- 0
model <- modelExpandParam(model, a)
}
if (!is.null(initParams)) {
if (!is.list(initParams) && all(is.finite(initParams))
&& is.null(names(initParams)))
model <- modelExpandParam(model, initParams)
else if (!is.null(names(initParams))) {
params <- modelExtractParam(model, only.values=FALSE)
for (i in seq(along=initParams)) {
j <- grep(names(initParams)[i], names(params))
if (length(j) > 0)
params[j] <- initParams[i]
else
warning(paste("Ignoring invalid initial parameter specification:", initParams$names[i]))
}
model <- modelExpandParam(model, params)
}
}
if (!dontOptimise) {
if (useGpdisim) {
message(paste(c("Optimising the model.\nTF: ", TF, "\nTargets: ", paste(targets, collapse=' '), "\n"), sep=" "))
} else {
message(paste(c("Optimising the model.\nTargets: ", paste(genes, collapse=' '), "\n"), sep=" "))
}
model <- modelOptimise(model, optOptions)
}
model <- modelUpdateProcesses(model)
model$allArgs <- list(TF=TF, targets=targets, useGpdisim=useGpdisim,
randomize=randomize, addPriors=addPriors,
fixedParams=fixedParams, initParams=initParams,
initialZero=initialZero, fixComps=fixComps,
dontOptimise=dontOptimise, gpsimOptions=gpsimOptions)
return (new("GPModel", model))
}
GPRankTargets <- function(preprocData, TF = NULL, knownTargets = NULL,
testTargets = NULL, filterLimit = 1.8,
returnModels = FALSE, options = NULL,
scoreSaveFile = NULL,
datasetName = "", experimentSet = "") {
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(testTargets))
testTargets <- featureNames(preprocData)
if (is.list(testTargets))
testTargets <- unlist(testTargets)
if (is.list(knownTargets))
knownTargets <- unlist(knownTargets)
if (!is.null(TF) && !all(TF %in% featureNames(preprocData))) {
stop("unknown TF")
}
if (!all(knownTargets %in% featureNames(preprocData))) {
stop("unknown genes in knownTargets")
}
if (class(try(preprocData[testTargets,], silent=TRUE)) == "try-error") {
stop("unknown genes in testTargets")
}
if ('var.exprs' %in% assayDataElementNames(preprocData))
testTargets <- .filterTargets(preprocData[testTargets,], filterLimit)
else
testTargets <- featureNames(preprocData[testTargets,])
if (length(testTargets) < 1)
stop("No test targets passed filtering")
# The variable useGpdisim determines whether GPDISIM is used in creating the
# models. GPSIM (default) is used if no TF has been specified.
useGpdisim = !is.null(TF)
if (!useGpdisim && is.null(knownTargets))
stop("There are no known targets for GPSIM.")
if (useGpdisim)
numberOfKnownGenes <- length(knownTargets) + 1
else
numberOfKnownGenes <- length(knownTargets)
logLikelihoods <- rep(NA, length.out=length(testTargets))
baselogLikelihoods <- rep(NA, length.out=length(testTargets))
modelParams <- list()
modelArgs <- list()
if (returnModels)
rankedModels <- list()
genes <- list()
if (!is.null(options)) {
allArgs <- options
allArgs$useGpdisim <- useGpdisim
}
else
allArgs <- list(useGpdisim=useGpdisim)
if (!is.null(knownTargets) && length(knownTargets) > 0) {
baselineModel <- .formModel(preprocData, TF, knownTargets, allArgs=allArgs)
baselineParameters <- modelExtractParam(baselineModel$model,
only.values=FALSE)
sharedModel <- list(ll=baselineModel$ll,
params=baselineModel$params,
args=modelStruct(baselineModel$model)$allArgs)
allArgs$fixedParams <- TRUE
allArgs$initParams <- baselineParameters
J <- grep('Basal', names(allArgs$initParams))
names(allArgs$initParams)[J] <-
paste(names(allArgs$initParams)[J], '$', sep='')
allArgs$fixComps <- 1:numberOfKnownGenes
}
else {
baselineModel <- NULL
}
for (i in seq(along=testTargets)) {
returnData <- .formModel(preprocData, TF, knownTargets,
testTargets[i], allArgs = allArgs)
if (!is.finite(returnData$ll)) {
logLikelihoods[i] <- NA
modelParams[[i]] <- NA
modelArgs[[i]] <- NA
if (returnModels)
rankedModels[[i]] <- NA
}
else {
logLikelihoods[i] <- returnData$ll
modelParams[[i]] <- returnData$params
modelArgs[[i]] <- modelStruct(returnData$model)$allArgs
if (returnModels)
rankedModels[[i]] <- returnData$model
}
genes[[i]] <- testTargets[[i]]
testdata <- preprocData[testTargets[i],]
testdata$experiments <- rep(1, length(testdata$experiments))
newData <- .getProcessedData(testdata)
baselogLikelihoods[i] <- .baselineOptimise(newData$y[[1]], newData$yvar[[1]], list(includeNoise=(any(newData$yvar[[1]]==0))))
if (!is.null(scoreSaveFile)) {
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
baseloglikelihoods = baselogLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = knownTargets, TF = TF,
sharedModel = sharedModel,
datasetName = datasetName,
experimentSet = experimentSet)
save(scoreList, file=scoreSaveFile)
}
}
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
baseloglikelihoods = baselogLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = knownTargets, TF = TF,
sharedModel = sharedModel,
datasetName = datasetName,
experimentSet = experimentSet)
if (returnModels)
return (list(scores=scoreList, models=rankedModels))
else
return (scoreList)
}
GPRankTFs <- function(preprocData, TFs, targets,
filterLimit = 1.8,
returnModels = FALSE, options = NULL,
scoreSaveFile = NULL,
datasetName = "", experimentSet = "") {
if (class(preprocData) != "ExpressionTimeSeries")
stop("preprocData should be an instance of ExpressionTimeSeries. Please use processData or processRawData to create one.")
if (is.null(targets)) stop("No targets specified.")
if (is.list(targets))
targets <- unlist(targets)
numberOfTargets <- length(targets)
genes = c(TFs, targets)
if (class(try(preprocData[TFs,], silent=TRUE)) == "try-error") {
stop("unknown genes in TFs")
}
if (!all(targets %in% featureNames(preprocData))) {
stop("unknown genes in targets")
}
## Filtering the genes based on the calculated ratios. If the limit is 0, all genes are accepted.
if ('var.exprs' %in% assayDataElementNames(preprocData))
TFs <- .filterTargets(preprocData[TFs,], filterLimit)
else
TFs <- featureNames(preprocData[TFs,])
if (length(TFs) < 1)
stop("No TFs passed the filtering.")
logLikelihoods <- rep(NA, length.out=length(TFs))
modelParams <- list()
modelArgs <- list()
if (returnModels)
rankedModels <- list()
if (!is.null(options)) {
allArgs <- options
allArgs$useGpdisim <- TRUE
}
else
allArgs <- list(useGpdisim=TRUE)
numberOfTargets <- length(targets)
genes <- list()
for (i in 1:length(TFs)) {
returnData <- .formModel(preprocData, TF = TFs[i], targets, allArgs=allArgs)
if (!is.finite(returnData$ll)) {
logLikelihoods[i] <- NA
modelParams[[i]] <- NA
modelArgs[[i]] <- NA
if (returnModels)
rankedModels[[i]] <- NA
}
else {
logLikelihoods[i] <- returnData$ll
modelParams[[i]] <- returnData$params
modelArgs[[i]] <- modelStruct(returnData$model)$allArgs
if (returnModels)
rankedModels[[i]] <- returnData$model
}
genes[[i]] <- TFs[[i]]
if (!is.null(scoreSaveFile)) {
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = targets, TF = '(see genes)',
datasetName = datasetName,
experimentSet = experimentSet)
save(scoreList, file=scoreSaveFile)
}
}
scoreList <- new("scoreList", params = modelParams,
loglikelihoods = logLikelihoods,
genes = genes, modelArgs = modelArgs,
knownTargets = targets, TF = '(see genes)',
datasetName = datasetName,
experimentSet = experimentSet)
if (returnModels)
return (list(scores=scoreList, models=rankedModels))
else
return (scoreList)
}
.formModel <- function(preprocData, TF = NULL, knownTargets = NULL,
testTarget = NULL, allArgs = NULL) {
if (!is.null(testTarget))
targets <- append(knownTargets, testTarget)
else
targets <- knownTargets
error1 <- TRUE
error2 <- TRUE
tryCatch({
model <- GPLearn(preprocData, TF, targets, allArgs = allArgs)
error1 <- FALSE
}, error = function(ex) {
warning("Stopped due to an error.\n")
})
if (error1) {
success <- FALSE
i <- 0
allArgs$randomize <- TRUE
while (!success && i < 10) {
tryCatch({
message("Trying again with different parameters.\n")
model <- GPLearn(preprocData, TF, targets, allArgs = allArgs)
success <- TRUE
error2 <- FALSE
}, error = function(ex) {
warning("Stopped due to an error.\n")
})
i <- i + 1
}
}
else {
error2 <- FALSE
}
if (error2) {
logLikelihood <- -Inf
params <- NA
rankedModel <- NA
}
else {
logLikelihood <- modelLogLikelihood(model)
params <- modelExtractParam(model)
rankedModel <- model
}
return (list(ll=logLikelihood, model=rankedModel, params=params))
}
generateModels <- function(preprocData, scores) {
models <- list()
# recreate the models for each gene in the scoreList
for (i in seq(along=params(scores))) {
args <- modelArgs(scores)[[i]]
args$initParams <- params(scores)[[i]]
args$dontOptimise <- TRUE
models[[i]] <- GPLearn(preprocData, allArgs=args)
}
return (models)
}
.getProcessedData <- function(data) {
times <- data$modeltime
experiments <- data$experiments
y <- assayDataElement(data, 'exprs')
if ('var.exprs' %in% assayDataElementNames(data))
yvar <- assayDataElement(data, 'var.exprs')
else
yvar <- 0 * y
scale <- sqrt(rowMeans(y^2))
scale[scale==0] <- 1
scaleMat <- scale %*% array(1, dim = c(1, ncol(data)))
y <- y / scaleMat
yvar <- yvar / scaleMat^2
ylist <- list()
yvarlist <- list()
expids <- unique(experiments)
for (i in seq(along=expids)) {
ylist[[i]] <- y[,experiments==expids[i], drop=FALSE]
yvarlist[[i]] <- yvar[,experiments==expids[i], drop=FALSE]
}
times <- times[experiments==expids[1]]
genes <- featureNames(data)
newData <- list(y = ylist, yvar = yvarlist, genes = genes, times = times)
return (newData)
}
.filterTargets <- function(data, filterLimit) {
y <- assayDataElement(data, 'exprs')
yvar <- assayDataElement(data, 'var.exprs')
zScores <- rowMeans(y / sqrt(yvar))
testTargets <- names(which(zScores > filterLimit))
return (testTargets)
}
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