inst/shiny/server.R
In haoeric/cytofkit_devel: cytofkit: an integrated mass cytometry data analysis pipeline
## max data size
options(shiny.maxRequestSize=1024^10)
shinyServer(function(input, output, session) {
##------------------Reactive Values and Reactive Objects-------------------
v <- reactiveValues(data = NULL, sampleInfo = NULL)
c <- reactiveValues(clusterCol = list())
p <- reactiveValues(progressionCluster = NULL)
## Scatter plot methods
visualizationMethods <- reactive({
if(is.null(v$data) || is.null(v$data$visualizationMethods)){
return(NULL)
}else{
return(v$data$visualizationMethods)
}
})
## Scatter plot functions
visualizationFunctions <- reactive({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
return(c(names(v$data$clusterRes),
"Sample",
"Density",
"None"))
}
})
## cluster methods
clusterMethods <- reactive({
if(is.null(v$data))
return(NULL)
cMethods <- names(v$data$clusterRes)
return(cMethods)
})
## progression labs
progressionLabs <- reactive({
if(is.null(v$data))
return(NULL)
if(is.null(v$data$progressionRes))
return(NULL)
progressionLabs <- colnames(v$data$progressionRes[[3]])
return(progressionLabs)
})
##--------------------------------Side Panel-------------------------------
## Load cytofkit RData object
observeEvent(input$goButton, {
cytofkitObj <- input$cytofkitObj
if (is.null(cytofkitObj)){
v$data <- NULL
}else{
cat(cytofkitObj$datapath)
load(cytofkitObj$datapath)
v$data <- analysis_results
if(is.null(v$data$projectName)){
v$data$projectName <- "cytofkit_shinyAPP_output"
}
if(!is.null(v$data$progressionRes)){
## default the first cluster results are used for progression analysis
p$progressionCluster <- names(v$data$clusterRes)[1]
}
# Need modification later
# currently doesn't update sampleInfo with v$data$sampleInfo
v$sampleInfo <- data.frame(cellID = row.names(v$data$expressionData),
cellSample = factor(sub("_[0-9]*$", "", row.names(v$data$expressionData))),
stringsAsFactors = FALSE)
v$data$sampleInfo <- v$sampleInfo
}
})
output$sampleSelect <- renderUI({
if(is.null(v$data) || is.null(v$sampleInfo)){
return(NULL)
}else{
sampleNames <- unique(as.character(v$sampleInfo$cellSample))
checkboxGroupInput('samples', NULL,
sampleNames, selected = sampleNames)
}
})
output$summaryText1 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", nrow(v$data[[1]]), " cells x ", ncol(v$data[[1]]), " markers")
})
output$summaryText2 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", paste(names(v$data$clusterRes), collapse = " | "))
})
output$summaryText3 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", paste(v$data$visualizationMethods, collapse = " | "))
})
output$summaryText4 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", ifelse(is.null(v$data$progressionRes), "NULL",
sub("_[0-9]*$", "", colnames(v$data$progressionRes$progressionData)[1])))
})
## Save and parse cytofkit RData object
observeEvent(input$saveButton, {
if (!is.null(v$data)){
withProgress(message='Saving Results ', value=0, {
## check results saving path
if(is.null(v$data$resultDir) || !dir.exists(v$data$resultDir)){
v$data$resultDir <- path.expand("~") ## default save to home if not specified
}
saveToFCS <- TRUE
if(is.null(v$data$rawFCSdir)){
saveToFCS <- FALSE
warning("Path for original FCS files is not provided,
data cannnot be saved to new copies of FCS files.")
}else if(!dir.exists(v$data$rawFCSdir)){
saveToFCS <- FALSE
warning(paste0("Path for original FCS files doesn't exits,
data cannnot be saved to new copies of FCS files.",
"Please check path: ", v$data$rawFCSdir))
}
## NOTE: if samples are regrouped, then new FCS file cannot be saved
incProgress(1/2, message = paste0("To ", v$data$resultDir))
analysis_results <<- v$data
cytof_writeResults(analysis_results,
saveToRData = TRUE,
saveToFCS = saveToFCS,
saveToFiles = FALSE)
incProgress(1/2)
## open the results directory
opendir(v$data$resultDir)
})
}
})
##------------------------------Cluster Panel------------------------------
##-----cluster plot-----
output$C_PlotMethod <- renderUI({
if(is.null(v$data) || is.null(visualizationMethods())){
return(NULL)
}else{
selectInput('c_PlotMethod', 'Visualization Method:', choices = visualizationMethods(),
selected = visualizationMethods()[1], width = "100%")
}
})
output$C_PlotFunction <- renderUI({
if(is.null(v$data) || is.null(visualizationFunctions())){
return(NULL)
}else{
selectInput('c_PlotFunction', 'Cluster By:', choices = visualizationFunctions(),
selected = visualizationFunctions()[1], width = "100%")
}
})
output$C_markerSelect <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markerNames <- colnames(v$data$expressionData)
checkboxGroupInput('c_markerSelect', strong('Select Markers:'),
markerNames, selected = markerNames, inline = TRUE)
}
})
output$C_clusterSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_PlotFunction))
return(NULL)
if(input$c_PlotFunction %in% c("Sample", "Density","None")){
return(NULL)
}else{
clusterMethod <- input$c_PlotFunction
clusterIDs <- sort(unique(v$data$clusterRes[[clusterMethod]]))
selectizeInput('c_clusterSelect', 'Clusters Filter:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_clusterSelect', strong('Select Clusters:'),
# clusterIDs, selected = clusterIDs, inline = TRUE)
}
})
## Complex dependencies here: --> (depends on)
## C_ScatterPlotInput --> c_PlotMethod + c_clusterSelect
## c_clusterSelect --> c_PlotMethod
## carefull checkings are applied to solve concurrency conflicts
C_ScatterPlotInput <- function(){
if(is.null(v$data) || is.null(input$c_PlotMethod) ||
is.null(input$c_PlotFunction) || is.null(input$c_clusterSelect)){
return(NULL)
}else if(!all(input$c_clusterSelect %in% v$data$clusterRes[[input$c_PlotFunction]]) &&
!(input$c_PlotFunction %in% c("Sample", "Density","None"))){
return(NULL)
}else{
withProgress(message="Generating Cluster Scatter Plot", value=0, {
if(input$c_PlotFunction %in% c("Sample", "Density", "None")){
clusterSelect <- NULL
clusterColor <- NULL
}else{
clusterSelect <- input$c_clusterSelect
clusterMethod <- input$c_PlotFunction
if(!is.null(c$clusterCol[[clusterMethod]])){
clusterColor <- c$clusterCol[[clusterMethod]]
}else{
cluster_num <- length(unique(v$data$clusterRes[[clusterMethod]]))
clusterColor <- rainbow(cluster_num)
}
}
gp <- scatterPlot(obj = v$data,
plotMethod = input$c_PlotMethod,
plotFunction = input$c_PlotFunction,
pointSize = input$C_PointSize,
addLabel = input$C_addLabel,
labelSize = input$C_LabelSize,
sampleLabel = FALSE,
FlowSOM_k = input$C_FlowSOM_k,
selectCluster = clusterSelect,
selectSamples = input$samples,
facetPlot = input$C_facetPlot,
labelRepel = input$C_labelRepel,
removeOutlier = TRUE,
clusterColor = clusterColor)
incProgress(1/2)
plot(gp)
incProgress(1/2)
})
}
}
output$C_ScatterPlot <- renderPlot({
C_ScatterPlotInput()
}, height = 900, width = 950)
output$C_download_cluster_plot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_cluster_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = C_ScatterPlotInput(),
width=as.numeric(input$C_tab1_w),
height=as.numeric(input$C_tab1_h))
}
)
##----- change cluster colour -----
output$C_colourCluster <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_colourCluster', 'Choose Cluster to Change the Colour :',
choices = clusterMethods,
selected = clusterMethods[1], width = "50%")
}
})
## currently use 100 as a limit for cluster numbers
## --- TODO: use reactiveValues to automatically retrive cluster numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Cluster_', i, "_col")]] <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_colourCluster)){
return(NULL)
}
clusters <- v$data$clusterRes[[input$c_colourCluster]]
clusterLabel <- levels(as.factor(clusters))
if(is.null(c$clusterCol[[input$c_colourCluster]])){
clusterColor <- rainbow(length(unique(clusters)))
}else{
clusterColor <- c$clusterCol[[input$c_colourCluster]]
}
if (i <= length(clusterLabel)){
x <- clusterLabel[i]
colourInput(inputId=paste0('cluster_', i, '_col'),
label=paste0('Cluster ', x," Colour :"),
value = clusterColor[i], showColour = "both",
palette = "square")
}
})
})
## update cluster color
observeEvent(input$C_updateClusterColor, {
if(!is.null(v$data) && !is.null(input$c_colourCluster)){
clusterMethod <- input$c_colourCluster
clusterVec<- v$data$clusterRes[[clusterMethod]]
clusters <- levels(as.factor(clusterVec))
clusterCols <- NULL
for (i in 1:length(clusters)){
clusteri <- clusters[i]
iCol <- input[[paste0('cluster_', i, '_col')]]
clusterCols <- c(clusterCols, iCol)
}
## update new cluster colours
c$clusterCol[[clusterMethod]] <- clusterCols
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
## revert default cluster colors
observeEvent(input$C_revertClusterColor, {
if(!is.null(v$data) && !is.null(input$c_colourCluster)){
clusterMethod <- input$c_colourCluster
c$clusterCol[[clusterMethod]] <- NULL
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
## ------annotate clusters-----
output$C_labelCluster <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_labelCluster', 'Choose Cluster Results to Annotate:',
choices = clusterMethods,
selected = clusterMethods[1], width = "50%")
}
})
output$C_labelCluster_name <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_labelCluster)){
return(NULL)
}else{
textInput("c_labelCluster_name", label = "Type In Your Name for Annotated Cluster",
value = paste0("Annotated_", input$c_labelCluster), width = "50%")
}
})
## currently use 100 as a limit for cluster numbers
## --- TODO: use reactiveValues to automatically retrive cluster numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Cluster', i)]] <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_labelCluster)){
return(NULL)
}
clusters <- sort(unique(v$data$clusterRes[[input$c_labelCluster]]))
if (i <= length(clusters)){
x <- clusters[i]
textInput(paste0('cluster', i), paste0('Cluster ', x," :"),
value = "", width = "30%", placeholder = "Type in the cell type")
}
})
})
## update cluster labels
observeEvent(input$updatelabel, {
if(!is.null(v$data) && !is.null(input$c_labelCluster) && !is.null(input$c_labelCluster_name)){
obj <- v$data
clusterMethod <- input$c_labelCluster
clusterVec<- obj$clusterRes[[clusterMethod]]
clusterLabels <- clusterVec
clusters <- sort(unique(clusterVec))
for (i in 1:length(clusters)){
clusteri <- clusters[i]
ilabel <- input[[paste0('cluster', i)]]
if(ilabel == ""){
clusterLabels[clusterLabels==clusteri] <- "Unknown"
}else{
clusterLabels[clusterLabels==clusteri] <- ilabel
}
}
## update new cluster results
labelName <- input$c_labelCluster_name
obj$clusterRes[[labelName]] <- clusterLabels
## update the project name
obj$projectName <- paste0(obj$projectName, "_annotated_", clusterMethod)
v$data <- obj
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
##-----RUN flowSOM-----
## result object which will be updated by C_runFlowSOM
observeEvent(input$C_runFlowSOM, {
if(!is.null(v$data) && !is.null(input$c_markerSelect)){
obj <- v$data
withProgress(message=paste0('Runing FlowSOM using k=', input$C_FlowSOM_k), value=0, {
FlowSOM_cluster <- cytof_cluster(xdata = obj$expressionData[ ,input$c_markerSelect],
method = "FlowSOM",
FlowSOM_k = input$C_FlowSOM_k)
incProgress(1/2)
## update FlowSOM cluster results
obj$clusterRes[["FlowSOM"]] <- FlowSOM_cluster
## update the project name
obj$projectName <- paste0(obj$projectName, "_add_FlowSOM")
v$data <- obj
incProgress(1/2)
})
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
##------------------------------Marker Panel-------------------------------
##-----heat map plot-----
output$M_plotCluster <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('m_plotCluster', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
M_heatmapPlotInput <- reactive({
if(is.null(v$data) || is.null(input$m_plotCluster))
return(NULL)
heatMap(data = v$data,
clusterMethod = input$m_plotCluster,
type = input$M_plotMethod,
dendrogram = input$M_heatmap_dendrogram,
colPalette = input$M_heatmap_colorPalette,
selectSamples = input$samples,
cex_row_label= input$M_rowLabelSize,
cex_col_label= input$M_colLabelSize,
scaleMethod = input$M_scaleMethod)
dev.copy2pdf(file = "cytofkit_shinyAPP_marker_heatmap_plot.pdf",
width=as.numeric(input$M_tab3_w),
height=as.numeric(input$M_tab3_h))
})
output$M_heatmapPlot <- renderPlot({
M_heatmapPlotInput()
}, height = 900, width = 950)
output$M_download_heatmapPlot = downloadHandler(
filename = "cytofkit_shinyAPP_marker_heatmap_plot.pdf",
content = function(file) {
file.copy("cytofkit_shinyAPP_marker_heatmap_plot.pdf", file)
}
)
##-----level plot-----
output$M_PlotMethod <- renderUI({
if(is.null(v$data) || is.null(visualizationMethods())){
return(NULL)
}else{
selectInput('m_PlotMethod', 'Visualization Method:', choices = visualizationMethods(),
selected = visualizationMethods()[1], width = "100%")
}
})
output$M_PlotMarker <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markers <- c(colnames(v$data$expressionData), "All Markers", "All Markers(scaled)")
selectInput('m_PlotMarker', 'Plot Marker:', choices = markers,
selected = markers[1], width = "100%")
}
})
M_markerExpressionPlotInput <- function(){
if(is.null(v$data) || is.null(input$m_PlotMethod) || is.null(input$m_PlotMarker)){
return(NULL)
}else{
withProgress(message="Generating Marker Expression Plot", value=0, {
gp <- scatterPlot(obj = v$data,
plotMethod = input$m_PlotMethod,
plotFunction = input$m_PlotMarker,
pointSize = input$M_PointSize,
addLabel = FALSE,
labelSize = input$S_LabelSize,
sampleLabel = FALSE,
FlowSOM_k = input$C_FlowSOM_k,
selectSamples = input$samples,
facetPlot = FALSE,
colorPalette = input$M_colorPalette,
labelRepel = FALSE,
removeOutlier = TRUE)
incProgress(1/2)
plot(gp)
incProgress(1/2)
})
}
}
output$M_markerExpressionPlot <- renderPlot({
M_markerExpressionPlotInput()
}, height = 900, width = 950)
output$M_download_expression_plot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_marker_expression_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = M_markerExpressionPlotInput(),
width=as.numeric(input$M_tab1_w),
height=as.numeric(input$M_tab1_h))
}
)
##-----histogram plot-----
output$M_stackFactor <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
stackFactorChoice <- c(names(v$data$clusterRes), "sample")
selectInput('m_stackFactor', 'Stack Factor:', choices = stackFactorChoice,
selected = stackFactorChoice[1], width = "100%")
}
})
output$M_markerSelect <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markerNames <- colnames(v$data$expressionData)
initNum <- ifelse(length(markerNames) >=4, 4, 1)
selectizeInput('m_markerSelect', 'Select Markers:',
choices = markerNames, selected = markerNames[1:initNum],
multiple = TRUE, width = "100%")
}
})
M_stackDensityPlotInput <- function(){
m_markerSelect <- isolate(input$m_markerSelect)
if(is.null(v$data) || is.null(input$m_stackFactor) || is.null(m_markerSelect)){
return(NULL)
}else{
withProgress(message="Generating Stack Density Plot", value=0, {
data <- data.frame(v$data$expressionData, check.names = FALSE)
samples <- as.character(v$sampleInfo$cellSample)
mySamples <- samples %in% input$samples
sfactors <- data.frame(do.call(cbind, v$data$clusterRes),
sample = samples,
stringsAsFactors = FALSE,
check.names = FALSE)
data <- data[mySamples, ,drop=FALSE]
stackFactor <- sfactors[mySamples, input$m_stackFactor]
if(input$m_stackFactor == "sample"){
stackFactorColours <- NULL
}else{
clusterMethod <- input$m_stackFactor
clusterVec <- v$data$clusterRes[[clusterMethod]]
cluster_num <- length(unique(clusterVec))
selectColors <- match(levels(as.factor(stackFactor)), levels(as.factor(clusterVec)))
if(!is.null(c$clusterCol[[clusterMethod]])){
stackFactorColours <- c$clusterCol[[clusterMethod]][selectColors]
}else{
stackFactorColours <- rainbow(cluster_num)[selectColors]
}
}
incProgress(1/3)
gp <- stackDenistyPlot(data = data,
densityCols=m_markerSelect,
stackFactor = stackFactor,
kernel = "gaussian",
bw = "nrd0",
adjust = 1,
stackRotation = 0,
stackSeperation = "auto",
x_text_size = input$M_xlab_size,
strip_text_size = input$M_markerTextSize,
legend_text_size = input$M_legendTextSize,
legendRow = input$M_legendRow,
legend_title = input$m_stackFactor,
stackFactorColours = stackFactorColours)
incProgress(1/3)
plot(gp)
incProgress(1/3)
})
}
}
observeEvent(input$M_updateDensityPlot, {
output$M_stackDensityPlot <- renderPlot({
M_stackDensityPlotInput()
}, height = 900, width = 950)
})
output$M_download_stackDensityPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_marker_stackDensity_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = M_stackDensityPlotInput(),
width=as.numeric(input$M_tab2_w),
height=as.numeric(input$M_tab2_h))
}
)
##----- update marker names -----
## currently use 100 as a limit for marker number
## --- TODO: use reactiveValues to automatically retrive marker numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Marker_', i, "_name")]] <- renderUI({
if(is.null(v$data)){
return(NULL)
}
markerNames <- colnames(v$data$expressionData)
if (i <= length(markerNames)){
markeri <- markerNames[i]
textInput(inputId = paste0('marker_', i, "_name"),
label = markeri, value = markeri, width = "30%",
placeholder = "Type in your new name for this marker")
}
})
})
## update cluster labels
observeEvent(input$C_updateMarkerNames, {
if(!is.null(v$data)){
markerNames <- colnames(v$data$expressionData)
newMarkerNames <- NULL
for (i in 1:length(markerNames)){
iName <- input[[paste0('marker_', i, '_name')]]
newMarkerNames <- c(newMarkerNames, iName)
}
## update new cluster colours
colnames(v$data$expressionData) <- newMarkerNames
## jump to C_tab1
updateTabsetPanel(session, "M_markerTabs", selected = "M_tab1")
}
})
##------------------------------Sample Panel-------------------------------
##-----cell percentage heatmap-----
output$S_plotCluster <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('s_plotCluster', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
S_heatmapPlotInput <- reactive({
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_plotCluster))
return(NULL)
heatMap(data = v$data,
clusterMethod = input$s_plotCluster,
type = input$S_plotMethod,
dendrogram = input$S_heatmap_dendrogram,
colPalette = input$S_heatmap_colorPalette,
selectSamples = input$samples,
cex_row_label= input$S_rowLabelSize,
cex_col_label= input$S_colLabelSize,
scaleMethod = input$S_scaleMethod)
dev.copy2pdf(file = "cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf",
width=as.numeric(input$S_tab1_w),
height=as.numeric(input$S_tab1_h))
})
output$S_heatmapPlot <- renderPlot({
S_heatmapPlotInput()
}, height = 900, width = 950)
output$S_download_heatmapPlot = downloadHandler(
filename = "cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf",
content = function(file) {
file.copy("cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf", file)
}
)
##-----cell percentage line chart-----
output$S_clusterMethod2 <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('s_clusterMethod2', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
output$S_clusterFilter <- renderUI({
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2)){
return(NULL)
}else{
clusterIDs <- sort(unique(v$data$clusterRes[[input$s_clusterMethod2]]))
selectizeInput('s_clusterFilter', 'Filter Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
}
})
S_rateChangePlotInput <- function(){
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2) || is.null(input$s_clusterFilter))
return(NULL)
withProgress(message="Generating Rate Change Plot", value=0, {
## percentage stat
data <- data.frame(sample = v$sampleInfo$cellSample,
cluster = as.factor(v$data$clusterRes[[input$s_clusterMethod2]]),
counts = 1)
statData1 <- aggregate(counts ~ ., data = data, sum)
statData2 <- aggregate(counts ~ sample, data = data, sum)
statData <- merge(statData1, statData2, by="sample", suffixes = c("InAll","InSample"))
statData$percentageInSample <- statData$countsInAll/statData$countsInSample
incProgress(1/3)
## filter clusters
usedClusters <- input$s_clusterFilter
clusterCheck <- as.character(statData$cluster) %in% usedClusters
statData <- statData[clusterCheck, ,drop=FALSE]
incProgress(1/3)
gp <- ggplot(data = statData, aes_string(x="sample",
y="percentageInSample",
color = "cluster",
group = "cluster")) +
geom_point(size = 2) + geom_line(size = 1.5) +
xlab("Cell Group") + ylab("Percentage of Cells in Group") + theme_bw() +
theme(axis.text=element_text(size=12), axis.title=element_text(size=14,face="bold"))
incProgress(1/3)
plot(gp)
})
}
output$S_rateChangePlot <- renderPlot({
S_rateChangePlotInput()
}, height = 500, width = 950)
output$S_download_rateChangePlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_cells_lineChart_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = S_rateChangePlotInput(),
width=as.numeric(input$S_tab2_w),
height=as.numeric(input$S_tab2_h))
}
)
# output$S_clusterTable <- renderTable({
# if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2)){
# return(NULL)
# }else{
# data <- data.frame(sample = v$sampleInfo$cellSample,
# cluster = as.factor(v$data$clusterRes[[input$s_clusterMethod2]]),
# counts = 1)
#
# statData1 <- aggregate(counts ~ ., data = data, sum)
# statData2 <- aggregate(counts ~ sample, data = data, sum)
# statData <- merge(statData1, statData2, by="sample", suffixes = c("InAll","InSample"))
# if(is.numeric(statData$cluster)) statData$cluster <- as.integer(statData$cluster)
# statData$counts <- as.integer(statData$countsInAll)
# statData$percentageInAll <- round(statData$countsInAll/nrow(data), 4)
# statData$percentageInSample <- round(statData$countsInAll/statData$countsInSample, 2)
# statData[, c("sample", "cluster", "counts", "percentageInSample", "percentageInAll")]
# }
# })
##-----Regroup samples-----
output$S_groupSamples <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_labelCluster', 'Choose Cluster Results to Annotate:',
choices = clusterMethods,
selected = clusterMethods[1], width = "30%")
}
})
## currently use 100 as a limit for sample numbers
## --- TODO: use reactiveValues to automatically retrive sample numbers --- ##
lapply(1:100, function(i) {
output[[paste0('S_sample', i)]] <- renderUI({
if(is.null(v$data) || is.null(v$sampleInfo)){
return(NULL)
}
uniqueSampleNames <- sort(unique(v$sampleInfo$cellSample))
if (i <= length(uniqueSampleNames)){
x <- uniqueSampleNames[i]
textInput(paste0('Sample', i), paste0(x," :"),
value = "", width = "40%",
placeholder = "Type in the group name for this sample")
}
})
})
## update sample groups
observeEvent(input$updateSampleGroups, {
if(!is.null(v$data) && !is.null(v$sampleInfo)){
v$sampleInfo$originalCellSample <- v$sampleInfo$cellSample
uniqueSampleNames <- sort(unique(v$sampleInfo$originalCellSample))
sampleGroupNames <- NULL
for(i in 1:length(uniqueSampleNames)){
sampleGroupNames <- c(sampleGroupNames, input[[paste0("Sample", i)]])
}
groupNameLevels <- strsplit(input$sampleGroupLevels, ";", fixed = TRUE)[[1]]
if(groupNameLevels != "" && all(sampleGroupNames != "")
&& length(groupNameLevels) == length(unique(sampleGroupNames))
&& all(as.character(groupNameLevels) %in% sampleGroupNames)){
sampleMatchID <- match(v$sampleInfo$originalCellSample, uniqueSampleNames)
v$sampleInfo$cellSample <- factor(sampleGroupNames[sampleMatchID],
levels = groupNameLevels)
}else{
sampleGroupNames[sampleGroupNames == ""] <- uniqueSampleNames[sampleGroupNames == ""]
sampleMatchID <- match(v$sampleInfo$originalCellSample, uniqueSampleNames)
v$sampleInfo$cellSample <- factor(sampleGroupNames[sampleMatchID])
}
cellID_number <- do.call(base::c, regmatches(v$sampleInfo$cellID,
gregexpr("_[0-9]*$", v$sampleInfo$cellID, perl=T)))
## update reactive object v$sampleInfo
## newCellID = "sampleGroup" + "_cellID" + "globalID" to avoid dumplicates
v$sampleInfo$newCellID <- paste0(as.character(v$sampleInfo$cellSample),
"_",
1:length(cellID_number))
## update reactive object v$data
expressionData <- v$data$expressionData
row.names(expressionData) <- v$sampleInfo$newCellID
v$data$expressionData <- expressionData
## update the project name
v$data$projectName <- paste0(v$data$projectName, "_grouped_samples")
## update v$data$progressionRes
if(!is.null(v$data$progressionRes)){
sampleExpressData <- v$data$progressionRes$sampleData
row.names(sampleExpressData) <- v$sampleInfo$newCellID[match(row.names(sampleExpressData),
v$sampleInfo$cellID)]
v$data$progressionRes$sampleData <- sampleExpressData
}
## jump to S_tab1
updateTabsetPanel(session, "S_sampleTabs", selected = "S_tab1")
}
})
## revert old sample names
observeEvent(input$revertSampleNames, {
if(!is.null(v$data) && !is.null(v$sampleInfo)){
if(!is.null(v$sampleInfo$originalCellSample)){
v$sampleInfo$cellSample <- v$sampleInfo$originalCellSample
v$sampleInfo$originalCellSample <- NULL
## update reactive object v$data
expressionData <- v$data$expressionData
row.names(expressionData) <- v$sampleInfo$cellID
v$data$expressionData <- expressionData
## update the project name
v$data$projectName <- sub("_grouped_samples", "", v$data$projectName)
## update reactive object v$sampleInfo
if(!is.null(v$data$progressionRes)){
sampleExpressData <- v$data$progressionRes$sampleData
row.names(sampleExpressData) <- v$sampleInfo$cellID[match(row.names(sampleExpressData),
v$sampleInfo$newCellID)]
v$data$progressionRes$sampleData <- sampleExpressData
}
}
## jump to S_tab1
updateTabsetPanel(session, "S_sampleTabs", selected = "S_tab1")
}
})
##---------------------------Progression Panel------------------------------
##-----subset relationship plot-----
output$P_xlab <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_xlab', 'Plot X:', choices = progressionLabs(),
selected = progressionLabs()[1], width = "100%")
}
})
output$P_ylab <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_ylab', 'Plot Y:', choices = progressionLabs(),
selected = progressionLabs()[2], width = "100%")
}
})
P_scatterPlotInput <- function(){
if(is.null(v$data) || is.null(v$data$progressionRes) || is.null(input$p_xlab) || is.null(input$p_ylab)){
return(NULL)
}else{
withProgress(message="Generating Progression Scatter Plot", value=0, {
obj <- v$data$progressionRes
data <- data.frame(obj$progressionData,
cluster = obj$sampleCluster,
sample = sub("_[0-9]*$", "", row.names(obj$sampleData)))
incProgress(1/3)
data <- data[data$sample %in% input$samples, ,drop=FALSE]
clusterMethod <- p$progressionCluster
clusterVec <- v$data$clusterRes[[clusterMethod]]
cluster_num <- length(unique(clusterVec))
selectColors <- match(levels(as.factor(data$cluster)), levels(as.factor(clusterVec)))
if(!is.null(c$clusterCol[[clusterMethod]])){
clusterColor <- c$clusterCol[[clusterMethod]][selectColors]
}else{
clusterColor <- rainbow(cluster_num)[selectColors]
}
gp <- cytof_clusterPlot(data = data,
xlab = input$p_xlab,
ylab = input$p_ylab,
cluster = "cluster",
sample = "sample",
title = "Subset Relationship",
type = ifelse(input$P_facetPlot, 2, 1),
point_size = input$P_PointSize,
addLabel = input$P_addLabel,
labelSize = input$P_LabelSize,
sampleLabel = FALSE,
labelRepel = input$P_labelRepel,
fixCoord = FALSE,
clusterColor = clusterColor)
incProgress(1/3)
plot(gp)
incProgress(1/3)
})
}
}
output$P_scatterPlot <- renderPlot({
P_scatterPlotInput()
}, height = 900, width = 950)
output$P_download_scatterPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_progression_scatter_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = P_scatterPlotInput(),
width=as.numeric(input$P_tab1_w),
height=as.numeric(input$P_tab1_h))
}
)
##-----marker expression profile-----
output$P_orderBy <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_orderBy', 'Cell Order By:', choices = progressionLabs(),
selected = progressionLabs()[1], width = "100%")
}
})
output$P_markerSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$progressionRes)){
return(NULL)
}else{
markerNames <- colnames(v$data$progressionRes$sampleData)
initNum <- ifelse(length(markerNames) >=4, 4, 1)
selectizeInput('p_markerSelect', 'Select Markers:',
choices = markerNames, selected = markerNames[1:initNum],
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_markerSelect', strong('Select Markers:'),
# markerNames, selected = markerNames, inline = TRUE)
}
})
output$P_clusterSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$progressionRes)){
return(NULL)
}else{
clusterIDs <- sort(unique(v$data$progressionRes$sampleCluster))
selectizeInput('p_clusterSelect', 'Select Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_clusterSelect', strong('Select Clusters:'),
# clusterIDs, selected = clusterIDs, inline = TRUE)
}
})
P_markerPlotInput <- function(){
p_markerSelect <- isolate(input$p_markerSelect)
p_clusterSelect <- isolate(input$p_clusterSelect)
if(is.null(v$data) || is.null(v$data$progressionRes) || is.null(p_markerSelect) || is.null(p_clusterSelect) || is.null(input$p_orderBy))
return(NULL)
withProgress(message="Generating Marker Expression Profile", value=0, {
data <- data.frame(v$data$progressionRes$sampleData,
cluster = v$data$progressionRes$sampleCluster,
v$data$progressionRes$progressionData,
check.names = FALSE)
sampleNames <- sub("_[0-9]*$", "", row.names(v$data$progressionRes$sampleData))
data <- data[sampleNames %in% input$samples, ,drop=FALSE]
incProgress(1/3)
if(input$P_combineTrends){
pp <- cytof_expressionTrends(data,
markers = p_markerSelect,
clusters = p_clusterSelect,
orderCol = input$p_orderBy,
clusterCol = "cluster",
reverseOrder = input$P_reverseOrder,
addClusterLabel = input$P_addLabel2,
clusterLabelSize = input$P_LabelSize2,
segmentSize = 0.5,
min_expr = NULL)
}else{
pp <- cytof_progressionPlot(data,
markers = p_markerSelect,
clusters = p_clusterSelect,
orderCol = input$p_orderBy,
clusterCol = "cluster",
reverseOrder = input$P_reverseOrder,
addClusterLabel = input$P_addLabel2,
clusterLabelSize = input$P_LabelSize2,
segmentSize = 0.5,
min_expr = NULL)
}
incProgress(1/3)
plot(pp)
incProgress(1/3)
})
}
observeEvent(input$P_updateRegressionPlot, {
output$P_markerPlot <- renderPlot({
P_markerPlotInput()
}, height = 900, width = 950)
})
output$P_download_markerPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_progression_marker_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = P_markerPlotInput(),
width=as.numeric(input$P_tab2_w),
height=as.numeric(input$P_tab2_h))
}
)
##-----Run Diffusionmap-----
output$P_clusterTable <- renderTable({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
clusterTable <- t(as.matrix(table(v$data$clusterRes[[input$p_clusterMethod]])))
out <- as.data.frame(clusterTable, row.names = "Cell Counts")
colnames(out) <- paste("Cluster", colnames(out))
out
}
})
output$P_clusterFilter <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
obj <- v$data
clusterIDs <- sort(unique(obj$clusterRes[[input$p_clusterMethod]]))
selectizeInput('p_clusterFilter', 'Filter Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
}
})
output$P_clusterMethod <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('p_clusterMethod', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
## result object which will be updated by P_runDiffusionmap
observeEvent(input$P_runDiffusionmap, {
if(!is.null(v$data)){
obj <- v$data
usedClusters <- input$p_clusterFilter
clusterCheck <- obj$clusterRes[[input$p_clusterMethod]] %in% usedClusters
mdata <- obj$expressionData[clusterCheck, ]
mcluster <- obj$clusterRes[[input$p_clusterMethod]][clusterCheck]
withProgress(message="Runing Diffusionmap", value=0, {
diffmapRes <- cytof_progression(data = mdata,
cluster = mcluster,
method = "diffusionmap",
distMethod = input$P_distMethod,
out_dim = input$P_outDim,
clusterSampleMethod = input$P_sampleMethod,
clusterSampleSize = input$P_clusterSampleSize)
incProgress(1/2)
## update progressionRes results
obj$progressionRes <- diffmapRes
## update the project name
obj$projectName <- paste0(obj$projectName, "_added_diffusionmap")
v$data <- obj
incProgress(1/2)
})
p$progressionCluster <- input$p_clusterMethod
## jump to P_tab1
updateTabsetPanel(session, "P_progressionTabs", selected = "P_tab1")
}
})
})
haoeric/cytofkit_devel documentation built on May 17, 2019, 2:29 p.m.
R Package Documentation
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
## max data size
options(shiny.maxRequestSize=1024^10)
shinyServer(function(input, output, session) {
##------------------Reactive Values and Reactive Objects-------------------
v <- reactiveValues(data = NULL, sampleInfo = NULL)
c <- reactiveValues(clusterCol = list())
p <- reactiveValues(progressionCluster = NULL)
## Scatter plot methods
visualizationMethods <- reactive({
if(is.null(v$data) || is.null(v$data$visualizationMethods)){
return(NULL)
}else{
return(v$data$visualizationMethods)
}
})
## Scatter plot functions
visualizationFunctions <- reactive({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
return(c(names(v$data$clusterRes),
"Sample",
"Density",
"None"))
}
})
## cluster methods
clusterMethods <- reactive({
if(is.null(v$data))
return(NULL)
cMethods <- names(v$data$clusterRes)
return(cMethods)
})
## progression labs
progressionLabs <- reactive({
if(is.null(v$data))
return(NULL)
if(is.null(v$data$progressionRes))
return(NULL)
progressionLabs <- colnames(v$data$progressionRes[[3]])
return(progressionLabs)
})
##--------------------------------Side Panel-------------------------------
## Load cytofkit RData object
observeEvent(input$goButton, {
cytofkitObj <- input$cytofkitObj
if (is.null(cytofkitObj)){
v$data <- NULL
}else{
cat(cytofkitObj$datapath)
load(cytofkitObj$datapath)
v$data <- analysis_results
if(is.null(v$data$projectName)){
v$data$projectName <- "cytofkit_shinyAPP_output"
}
if(!is.null(v$data$progressionRes)){
## default the first cluster results are used for progression analysis
p$progressionCluster <- names(v$data$clusterRes)[1]
}
# Need modification later
# currently doesn't update sampleInfo with v$data$sampleInfo
v$sampleInfo <- data.frame(cellID = row.names(v$data$expressionData),
cellSample = factor(sub("_[0-9]*$", "", row.names(v$data$expressionData))),
stringsAsFactors = FALSE)
v$data$sampleInfo <- v$sampleInfo
}
})
output$sampleSelect <- renderUI({
if(is.null(v$data) || is.null(v$sampleInfo)){
return(NULL)
}else{
sampleNames <- unique(as.character(v$sampleInfo$cellSample))
checkboxGroupInput('samples', NULL,
sampleNames, selected = sampleNames)
}
})
output$summaryText1 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", nrow(v$data[[1]]), " cells x ", ncol(v$data[[1]]), " markers")
})
output$summaryText2 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", paste(names(v$data$clusterRes), collapse = " | "))
})
output$summaryText3 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", paste(v$data$visualizationMethods, collapse = " | "))
})
output$summaryText4 <- renderText({
if(is.null(v$data))
return(NULL)
paste0("-- ", ifelse(is.null(v$data$progressionRes), "NULL",
sub("_[0-9]*$", "", colnames(v$data$progressionRes$progressionData)[1])))
})
## Save and parse cytofkit RData object
observeEvent(input$saveButton, {
if (!is.null(v$data)){
withProgress(message='Saving Results ', value=0, {
## check results saving path
if(is.null(v$data$resultDir) || !dir.exists(v$data$resultDir)){
v$data$resultDir <- path.expand("~") ## default save to home if not specified
}
saveToFCS <- TRUE
if(is.null(v$data$rawFCSdir)){
saveToFCS <- FALSE
warning("Path for original FCS files is not provided,
data cannnot be saved to new copies of FCS files.")
}else if(!dir.exists(v$data$rawFCSdir)){
saveToFCS <- FALSE
warning(paste0("Path for original FCS files doesn't exits,
data cannnot be saved to new copies of FCS files.",
"Please check path: ", v$data$rawFCSdir))
}
## NOTE: if samples are regrouped, then new FCS file cannot be saved
incProgress(1/2, message = paste0("To ", v$data$resultDir))
analysis_results <<- v$data
cytof_writeResults(analysis_results,
saveToRData = TRUE,
saveToFCS = saveToFCS,
saveToFiles = FALSE)
incProgress(1/2)
## open the results directory
opendir(v$data$resultDir)
})
}
})
##------------------------------Cluster Panel------------------------------
##-----cluster plot-----
output$C_PlotMethod <- renderUI({
if(is.null(v$data) || is.null(visualizationMethods())){
return(NULL)
}else{
selectInput('c_PlotMethod', 'Visualization Method:', choices = visualizationMethods(),
selected = visualizationMethods()[1], width = "100%")
}
})
output$C_PlotFunction <- renderUI({
if(is.null(v$data) || is.null(visualizationFunctions())){
return(NULL)
}else{
selectInput('c_PlotFunction', 'Cluster By:', choices = visualizationFunctions(),
selected = visualizationFunctions()[1], width = "100%")
}
})
output$C_markerSelect <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markerNames <- colnames(v$data$expressionData)
checkboxGroupInput('c_markerSelect', strong('Select Markers:'),
markerNames, selected = markerNames, inline = TRUE)
}
})
output$C_clusterSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_PlotFunction))
return(NULL)
if(input$c_PlotFunction %in% c("Sample", "Density","None")){
return(NULL)
}else{
clusterMethod <- input$c_PlotFunction
clusterIDs <- sort(unique(v$data$clusterRes[[clusterMethod]]))
selectizeInput('c_clusterSelect', 'Clusters Filter:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_clusterSelect', strong('Select Clusters:'),
# clusterIDs, selected = clusterIDs, inline = TRUE)
}
})
## Complex dependencies here: --> (depends on)
## C_ScatterPlotInput --> c_PlotMethod + c_clusterSelect
## c_clusterSelect --> c_PlotMethod
## carefull checkings are applied to solve concurrency conflicts
C_ScatterPlotInput <- function(){
if(is.null(v$data) || is.null(input$c_PlotMethod) ||
is.null(input$c_PlotFunction) || is.null(input$c_clusterSelect)){
return(NULL)
}else if(!all(input$c_clusterSelect %in% v$data$clusterRes[[input$c_PlotFunction]]) &&
!(input$c_PlotFunction %in% c("Sample", "Density","None"))){
return(NULL)
}else{
withProgress(message="Generating Cluster Scatter Plot", value=0, {
if(input$c_PlotFunction %in% c("Sample", "Density", "None")){
clusterSelect <- NULL
clusterColor <- NULL
}else{
clusterSelect <- input$c_clusterSelect
clusterMethod <- input$c_PlotFunction
if(!is.null(c$clusterCol[[clusterMethod]])){
clusterColor <- c$clusterCol[[clusterMethod]]
}else{
cluster_num <- length(unique(v$data$clusterRes[[clusterMethod]]))
clusterColor <- rainbow(cluster_num)
}
}
gp <- scatterPlot(obj = v$data,
plotMethod = input$c_PlotMethod,
plotFunction = input$c_PlotFunction,
pointSize = input$C_PointSize,
addLabel = input$C_addLabel,
labelSize = input$C_LabelSize,
sampleLabel = FALSE,
FlowSOM_k = input$C_FlowSOM_k,
selectCluster = clusterSelect,
selectSamples = input$samples,
facetPlot = input$C_facetPlot,
labelRepel = input$C_labelRepel,
removeOutlier = TRUE,
clusterColor = clusterColor)
incProgress(1/2)
plot(gp)
incProgress(1/2)
})
}
}
output$C_ScatterPlot <- renderPlot({
C_ScatterPlotInput()
}, height = 900, width = 950)
output$C_download_cluster_plot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_cluster_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = C_ScatterPlotInput(),
width=as.numeric(input$C_tab1_w),
height=as.numeric(input$C_tab1_h))
}
)
##----- change cluster colour -----
output$C_colourCluster <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_colourCluster', 'Choose Cluster to Change the Colour :',
choices = clusterMethods,
selected = clusterMethods[1], width = "50%")
}
})
## currently use 100 as a limit for cluster numbers
## --- TODO: use reactiveValues to automatically retrive cluster numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Cluster_', i, "_col")]] <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_colourCluster)){
return(NULL)
}
clusters <- v$data$clusterRes[[input$c_colourCluster]]
clusterLabel <- levels(as.factor(clusters))
if(is.null(c$clusterCol[[input$c_colourCluster]])){
clusterColor <- rainbow(length(unique(clusters)))
}else{
clusterColor <- c$clusterCol[[input$c_colourCluster]]
}
if (i <= length(clusterLabel)){
x <- clusterLabel[i]
colourInput(inputId=paste0('cluster_', i, '_col'),
label=paste0('Cluster ', x," Colour :"),
value = clusterColor[i], showColour = "both",
palette = "square")
}
})
})
## update cluster color
observeEvent(input$C_updateClusterColor, {
if(!is.null(v$data) && !is.null(input$c_colourCluster)){
clusterMethod <- input$c_colourCluster
clusterVec<- v$data$clusterRes[[clusterMethod]]
clusters <- levels(as.factor(clusterVec))
clusterCols <- NULL
for (i in 1:length(clusters)){
clusteri <- clusters[i]
iCol <- input[[paste0('cluster_', i, '_col')]]
clusterCols <- c(clusterCols, iCol)
}
## update new cluster colours
c$clusterCol[[clusterMethod]] <- clusterCols
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
## revert default cluster colors
observeEvent(input$C_revertClusterColor, {
if(!is.null(v$data) && !is.null(input$c_colourCluster)){
clusterMethod <- input$c_colourCluster
c$clusterCol[[clusterMethod]] <- NULL
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
## ------annotate clusters-----
output$C_labelCluster <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_labelCluster', 'Choose Cluster Results to Annotate:',
choices = clusterMethods,
selected = clusterMethods[1], width = "50%")
}
})
output$C_labelCluster_name <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_labelCluster)){
return(NULL)
}else{
textInput("c_labelCluster_name", label = "Type In Your Name for Annotated Cluster",
value = paste0("Annotated_", input$c_labelCluster), width = "50%")
}
})
## currently use 100 as a limit for cluster numbers
## --- TODO: use reactiveValues to automatically retrive cluster numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Cluster', i)]] <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes) || is.null(input$c_labelCluster)){
return(NULL)
}
clusters <- sort(unique(v$data$clusterRes[[input$c_labelCluster]]))
if (i <= length(clusters)){
x <- clusters[i]
textInput(paste0('cluster', i), paste0('Cluster ', x," :"),
value = "", width = "30%", placeholder = "Type in the cell type")
}
})
})
## update cluster labels
observeEvent(input$updatelabel, {
if(!is.null(v$data) && !is.null(input$c_labelCluster) && !is.null(input$c_labelCluster_name)){
obj <- v$data
clusterMethod <- input$c_labelCluster
clusterVec<- obj$clusterRes[[clusterMethod]]
clusterLabels <- clusterVec
clusters <- sort(unique(clusterVec))
for (i in 1:length(clusters)){
clusteri <- clusters[i]
ilabel <- input[[paste0('cluster', i)]]
if(ilabel == ""){
clusterLabels[clusterLabels==clusteri] <- "Unknown"
}else{
clusterLabels[clusterLabels==clusteri] <- ilabel
}
}
## update new cluster results
labelName <- input$c_labelCluster_name
obj$clusterRes[[labelName]] <- clusterLabels
## update the project name
obj$projectName <- paste0(obj$projectName, "_annotated_", clusterMethod)
v$data <- obj
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
##-----RUN flowSOM-----
## result object which will be updated by C_runFlowSOM
observeEvent(input$C_runFlowSOM, {
if(!is.null(v$data) && !is.null(input$c_markerSelect)){
obj <- v$data
withProgress(message=paste0('Runing FlowSOM using k=', input$C_FlowSOM_k), value=0, {
FlowSOM_cluster <- cytof_cluster(xdata = obj$expressionData[ ,input$c_markerSelect],
method = "FlowSOM",
FlowSOM_k = input$C_FlowSOM_k)
incProgress(1/2)
## update FlowSOM cluster results
obj$clusterRes[["FlowSOM"]] <- FlowSOM_cluster
## update the project name
obj$projectName <- paste0(obj$projectName, "_add_FlowSOM")
v$data <- obj
incProgress(1/2)
})
## jump to C_tab1
updateTabsetPanel(session, "C_clusterTabs", selected = "C_tab1")
}
})
##------------------------------Marker Panel-------------------------------
##-----heat map plot-----
output$M_plotCluster <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('m_plotCluster', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
M_heatmapPlotInput <- reactive({
if(is.null(v$data) || is.null(input$m_plotCluster))
return(NULL)
heatMap(data = v$data,
clusterMethod = input$m_plotCluster,
type = input$M_plotMethod,
dendrogram = input$M_heatmap_dendrogram,
colPalette = input$M_heatmap_colorPalette,
selectSamples = input$samples,
cex_row_label= input$M_rowLabelSize,
cex_col_label= input$M_colLabelSize,
scaleMethod = input$M_scaleMethod)
dev.copy2pdf(file = "cytofkit_shinyAPP_marker_heatmap_plot.pdf",
width=as.numeric(input$M_tab3_w),
height=as.numeric(input$M_tab3_h))
})
output$M_heatmapPlot <- renderPlot({
M_heatmapPlotInput()
}, height = 900, width = 950)
output$M_download_heatmapPlot = downloadHandler(
filename = "cytofkit_shinyAPP_marker_heatmap_plot.pdf",
content = function(file) {
file.copy("cytofkit_shinyAPP_marker_heatmap_plot.pdf", file)
}
)
##-----level plot-----
output$M_PlotMethod <- renderUI({
if(is.null(v$data) || is.null(visualizationMethods())){
return(NULL)
}else{
selectInput('m_PlotMethod', 'Visualization Method:', choices = visualizationMethods(),
selected = visualizationMethods()[1], width = "100%")
}
})
output$M_PlotMarker <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markers <- c(colnames(v$data$expressionData), "All Markers", "All Markers(scaled)")
selectInput('m_PlotMarker', 'Plot Marker:', choices = markers,
selected = markers[1], width = "100%")
}
})
M_markerExpressionPlotInput <- function(){
if(is.null(v$data) || is.null(input$m_PlotMethod) || is.null(input$m_PlotMarker)){
return(NULL)
}else{
withProgress(message="Generating Marker Expression Plot", value=0, {
gp <- scatterPlot(obj = v$data,
plotMethod = input$m_PlotMethod,
plotFunction = input$m_PlotMarker,
pointSize = input$M_PointSize,
addLabel = FALSE,
labelSize = input$S_LabelSize,
sampleLabel = FALSE,
FlowSOM_k = input$C_FlowSOM_k,
selectSamples = input$samples,
facetPlot = FALSE,
colorPalette = input$M_colorPalette,
labelRepel = FALSE,
removeOutlier = TRUE)
incProgress(1/2)
plot(gp)
incProgress(1/2)
})
}
}
output$M_markerExpressionPlot <- renderPlot({
M_markerExpressionPlotInput()
}, height = 900, width = 950)
output$M_download_expression_plot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_marker_expression_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = M_markerExpressionPlotInput(),
width=as.numeric(input$M_tab1_w),
height=as.numeric(input$M_tab1_h))
}
)
##-----histogram plot-----
output$M_stackFactor <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
stackFactorChoice <- c(names(v$data$clusterRes), "sample")
selectInput('m_stackFactor', 'Stack Factor:', choices = stackFactorChoice,
selected = stackFactorChoice[1], width = "100%")
}
})
output$M_markerSelect <- renderUI({
if(is.null(v$data)){
return(NULL)
}else{
markerNames <- colnames(v$data$expressionData)
initNum <- ifelse(length(markerNames) >=4, 4, 1)
selectizeInput('m_markerSelect', 'Select Markers:',
choices = markerNames, selected = markerNames[1:initNum],
multiple = TRUE, width = "100%")
}
})
M_stackDensityPlotInput <- function(){
m_markerSelect <- isolate(input$m_markerSelect)
if(is.null(v$data) || is.null(input$m_stackFactor) || is.null(m_markerSelect)){
return(NULL)
}else{
withProgress(message="Generating Stack Density Plot", value=0, {
data <- data.frame(v$data$expressionData, check.names = FALSE)
samples <- as.character(v$sampleInfo$cellSample)
mySamples <- samples %in% input$samples
sfactors <- data.frame(do.call(cbind, v$data$clusterRes),
sample = samples,
stringsAsFactors = FALSE,
check.names = FALSE)
data <- data[mySamples, ,drop=FALSE]
stackFactor <- sfactors[mySamples, input$m_stackFactor]
if(input$m_stackFactor == "sample"){
stackFactorColours <- NULL
}else{
clusterMethod <- input$m_stackFactor
clusterVec <- v$data$clusterRes[[clusterMethod]]
cluster_num <- length(unique(clusterVec))
selectColors <- match(levels(as.factor(stackFactor)), levels(as.factor(clusterVec)))
if(!is.null(c$clusterCol[[clusterMethod]])){
stackFactorColours <- c$clusterCol[[clusterMethod]][selectColors]
}else{
stackFactorColours <- rainbow(cluster_num)[selectColors]
}
}
incProgress(1/3)
gp <- stackDenistyPlot(data = data,
densityCols=m_markerSelect,
stackFactor = stackFactor,
kernel = "gaussian",
bw = "nrd0",
adjust = 1,
stackRotation = 0,
stackSeperation = "auto",
x_text_size = input$M_xlab_size,
strip_text_size = input$M_markerTextSize,
legend_text_size = input$M_legendTextSize,
legendRow = input$M_legendRow,
legend_title = input$m_stackFactor,
stackFactorColours = stackFactorColours)
incProgress(1/3)
plot(gp)
incProgress(1/3)
})
}
}
observeEvent(input$M_updateDensityPlot, {
output$M_stackDensityPlot <- renderPlot({
M_stackDensityPlotInput()
}, height = 900, width = 950)
})
output$M_download_stackDensityPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_marker_stackDensity_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = M_stackDensityPlotInput(),
width=as.numeric(input$M_tab2_w),
height=as.numeric(input$M_tab2_h))
}
)
##----- update marker names -----
## currently use 100 as a limit for marker number
## --- TODO: use reactiveValues to automatically retrive marker numbers --- ##
lapply(1:100, function(i) {
output[[paste0('Marker_', i, "_name")]] <- renderUI({
if(is.null(v$data)){
return(NULL)
}
markerNames <- colnames(v$data$expressionData)
if (i <= length(markerNames)){
markeri <- markerNames[i]
textInput(inputId = paste0('marker_', i, "_name"),
label = markeri, value = markeri, width = "30%",
placeholder = "Type in your new name for this marker")
}
})
})
## update cluster labels
observeEvent(input$C_updateMarkerNames, {
if(!is.null(v$data)){
markerNames <- colnames(v$data$expressionData)
newMarkerNames <- NULL
for (i in 1:length(markerNames)){
iName <- input[[paste0('marker_', i, '_name')]]
newMarkerNames <- c(newMarkerNames, iName)
}
## update new cluster colours
colnames(v$data$expressionData) <- newMarkerNames
## jump to C_tab1
updateTabsetPanel(session, "M_markerTabs", selected = "M_tab1")
}
})
##------------------------------Sample Panel-------------------------------
##-----cell percentage heatmap-----
output$S_plotCluster <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('s_plotCluster', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
S_heatmapPlotInput <- reactive({
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_plotCluster))
return(NULL)
heatMap(data = v$data,
clusterMethod = input$s_plotCluster,
type = input$S_plotMethod,
dendrogram = input$S_heatmap_dendrogram,
colPalette = input$S_heatmap_colorPalette,
selectSamples = input$samples,
cex_row_label= input$S_rowLabelSize,
cex_col_label= input$S_colLabelSize,
scaleMethod = input$S_scaleMethod)
dev.copy2pdf(file = "cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf",
width=as.numeric(input$S_tab1_w),
height=as.numeric(input$S_tab1_h))
})
output$S_heatmapPlot <- renderPlot({
S_heatmapPlotInput()
}, height = 900, width = 950)
output$S_download_heatmapPlot = downloadHandler(
filename = "cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf",
content = function(file) {
file.copy("cytofkit_shinyAPP_cells_heatmap_plot_plot.pdf", file)
}
)
##-----cell percentage line chart-----
output$S_clusterMethod2 <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('s_clusterMethod2', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
output$S_clusterFilter <- renderUI({
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2)){
return(NULL)
}else{
clusterIDs <- sort(unique(v$data$clusterRes[[input$s_clusterMethod2]]))
selectizeInput('s_clusterFilter', 'Filter Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
}
})
S_rateChangePlotInput <- function(){
if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2) || is.null(input$s_clusterFilter))
return(NULL)
withProgress(message="Generating Rate Change Plot", value=0, {
## percentage stat
data <- data.frame(sample = v$sampleInfo$cellSample,
cluster = as.factor(v$data$clusterRes[[input$s_clusterMethod2]]),
counts = 1)
statData1 <- aggregate(counts ~ ., data = data, sum)
statData2 <- aggregate(counts ~ sample, data = data, sum)
statData <- merge(statData1, statData2, by="sample", suffixes = c("InAll","InSample"))
statData$percentageInSample <- statData$countsInAll/statData$countsInSample
incProgress(1/3)
## filter clusters
usedClusters <- input$s_clusterFilter
clusterCheck <- as.character(statData$cluster) %in% usedClusters
statData <- statData[clusterCheck, ,drop=FALSE]
incProgress(1/3)
gp <- ggplot(data = statData, aes_string(x="sample",
y="percentageInSample",
color = "cluster",
group = "cluster")) +
geom_point(size = 2) + geom_line(size = 1.5) +
xlab("Cell Group") + ylab("Percentage of Cells in Group") + theme_bw() +
theme(axis.text=element_text(size=12), axis.title=element_text(size=14,face="bold"))
incProgress(1/3)
plot(gp)
})
}
output$S_rateChangePlot <- renderPlot({
S_rateChangePlotInput()
}, height = 500, width = 950)
output$S_download_rateChangePlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_cells_lineChart_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = S_rateChangePlotInput(),
width=as.numeric(input$S_tab2_w),
height=as.numeric(input$S_tab2_h))
}
)
# output$S_clusterTable <- renderTable({
# if(is.null(v$data) || is.null(clusterMethods()) || is.null(input$s_clusterMethod2)){
# return(NULL)
# }else{
# data <- data.frame(sample = v$sampleInfo$cellSample,
# cluster = as.factor(v$data$clusterRes[[input$s_clusterMethod2]]),
# counts = 1)
#
# statData1 <- aggregate(counts ~ ., data = data, sum)
# statData2 <- aggregate(counts ~ sample, data = data, sum)
# statData <- merge(statData1, statData2, by="sample", suffixes = c("InAll","InSample"))
# if(is.numeric(statData$cluster)) statData$cluster <- as.integer(statData$cluster)
# statData$counts <- as.integer(statData$countsInAll)
# statData$percentageInAll <- round(statData$countsInAll/nrow(data), 4)
# statData$percentageInSample <- round(statData$countsInAll/statData$countsInSample, 2)
# statData[, c("sample", "cluster", "counts", "percentageInSample", "percentageInAll")]
# }
# })
##-----Regroup samples-----
output$S_groupSamples <- renderUI({
if(is.null(v$data) || is.null(v$data$clusterRes)){
return(NULL)
}else{
clusterMethods <- c(names(v$data$clusterRes))
#clusterMethods <- clusterMethods[!grepl("Subset", clusterMethods)]
selectInput('c_labelCluster', 'Choose Cluster Results to Annotate:',
choices = clusterMethods,
selected = clusterMethods[1], width = "30%")
}
})
## currently use 100 as a limit for sample numbers
## --- TODO: use reactiveValues to automatically retrive sample numbers --- ##
lapply(1:100, function(i) {
output[[paste0('S_sample', i)]] <- renderUI({
if(is.null(v$data) || is.null(v$sampleInfo)){
return(NULL)
}
uniqueSampleNames <- sort(unique(v$sampleInfo$cellSample))
if (i <= length(uniqueSampleNames)){
x <- uniqueSampleNames[i]
textInput(paste0('Sample', i), paste0(x," :"),
value = "", width = "40%",
placeholder = "Type in the group name for this sample")
}
})
})
## update sample groups
observeEvent(input$updateSampleGroups, {
if(!is.null(v$data) && !is.null(v$sampleInfo)){
v$sampleInfo$originalCellSample <- v$sampleInfo$cellSample
uniqueSampleNames <- sort(unique(v$sampleInfo$originalCellSample))
sampleGroupNames <- NULL
for(i in 1:length(uniqueSampleNames)){
sampleGroupNames <- c(sampleGroupNames, input[[paste0("Sample", i)]])
}
groupNameLevels <- strsplit(input$sampleGroupLevels, ";", fixed = TRUE)[[1]]
if(groupNameLevels != "" && all(sampleGroupNames != "")
&& length(groupNameLevels) == length(unique(sampleGroupNames))
&& all(as.character(groupNameLevels) %in% sampleGroupNames)){
sampleMatchID <- match(v$sampleInfo$originalCellSample, uniqueSampleNames)
v$sampleInfo$cellSample <- factor(sampleGroupNames[sampleMatchID],
levels = groupNameLevels)
}else{
sampleGroupNames[sampleGroupNames == ""] <- uniqueSampleNames[sampleGroupNames == ""]
sampleMatchID <- match(v$sampleInfo$originalCellSample, uniqueSampleNames)
v$sampleInfo$cellSample <- factor(sampleGroupNames[sampleMatchID])
}
cellID_number <- do.call(base::c, regmatches(v$sampleInfo$cellID,
gregexpr("_[0-9]*$", v$sampleInfo$cellID, perl=T)))
## update reactive object v$sampleInfo
## newCellID = "sampleGroup" + "_cellID" + "globalID" to avoid dumplicates
v$sampleInfo$newCellID <- paste0(as.character(v$sampleInfo$cellSample),
"_",
1:length(cellID_number))
## update reactive object v$data
expressionData <- v$data$expressionData
row.names(expressionData) <- v$sampleInfo$newCellID
v$data$expressionData <- expressionData
## update the project name
v$data$projectName <- paste0(v$data$projectName, "_grouped_samples")
## update v$data$progressionRes
if(!is.null(v$data$progressionRes)){
sampleExpressData <- v$data$progressionRes$sampleData
row.names(sampleExpressData) <- v$sampleInfo$newCellID[match(row.names(sampleExpressData),
v$sampleInfo$cellID)]
v$data$progressionRes$sampleData <- sampleExpressData
}
## jump to S_tab1
updateTabsetPanel(session, "S_sampleTabs", selected = "S_tab1")
}
})
## revert old sample names
observeEvent(input$revertSampleNames, {
if(!is.null(v$data) && !is.null(v$sampleInfo)){
if(!is.null(v$sampleInfo$originalCellSample)){
v$sampleInfo$cellSample <- v$sampleInfo$originalCellSample
v$sampleInfo$originalCellSample <- NULL
## update reactive object v$data
expressionData <- v$data$expressionData
row.names(expressionData) <- v$sampleInfo$cellID
v$data$expressionData <- expressionData
## update the project name
v$data$projectName <- sub("_grouped_samples", "", v$data$projectName)
## update reactive object v$sampleInfo
if(!is.null(v$data$progressionRes)){
sampleExpressData <- v$data$progressionRes$sampleData
row.names(sampleExpressData) <- v$sampleInfo$cellID[match(row.names(sampleExpressData),
v$sampleInfo$newCellID)]
v$data$progressionRes$sampleData <- sampleExpressData
}
}
## jump to S_tab1
updateTabsetPanel(session, "S_sampleTabs", selected = "S_tab1")
}
})
##---------------------------Progression Panel------------------------------
##-----subset relationship plot-----
output$P_xlab <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_xlab', 'Plot X:', choices = progressionLabs(),
selected = progressionLabs()[1], width = "100%")
}
})
output$P_ylab <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_ylab', 'Plot Y:', choices = progressionLabs(),
selected = progressionLabs()[2], width = "100%")
}
})
P_scatterPlotInput <- function(){
if(is.null(v$data) || is.null(v$data$progressionRes) || is.null(input$p_xlab) || is.null(input$p_ylab)){
return(NULL)
}else{
withProgress(message="Generating Progression Scatter Plot", value=0, {
obj <- v$data$progressionRes
data <- data.frame(obj$progressionData,
cluster = obj$sampleCluster,
sample = sub("_[0-9]*$", "", row.names(obj$sampleData)))
incProgress(1/3)
data <- data[data$sample %in% input$samples, ,drop=FALSE]
clusterMethod <- p$progressionCluster
clusterVec <- v$data$clusterRes[[clusterMethod]]
cluster_num <- length(unique(clusterVec))
selectColors <- match(levels(as.factor(data$cluster)), levels(as.factor(clusterVec)))
if(!is.null(c$clusterCol[[clusterMethod]])){
clusterColor <- c$clusterCol[[clusterMethod]][selectColors]
}else{
clusterColor <- rainbow(cluster_num)[selectColors]
}
gp <- cytof_clusterPlot(data = data,
xlab = input$p_xlab,
ylab = input$p_ylab,
cluster = "cluster",
sample = "sample",
title = "Subset Relationship",
type = ifelse(input$P_facetPlot, 2, 1),
point_size = input$P_PointSize,
addLabel = input$P_addLabel,
labelSize = input$P_LabelSize,
sampleLabel = FALSE,
labelRepel = input$P_labelRepel,
fixCoord = FALSE,
clusterColor = clusterColor)
incProgress(1/3)
plot(gp)
incProgress(1/3)
})
}
}
output$P_scatterPlot <- renderPlot({
P_scatterPlotInput()
}, height = 900, width = 950)
output$P_download_scatterPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_progression_scatter_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = P_scatterPlotInput(),
width=as.numeric(input$P_tab1_w),
height=as.numeric(input$P_tab1_h))
}
)
##-----marker expression profile-----
output$P_orderBy <- renderUI({
if(is.null(v$data) || is.null(progressionLabs())){
return(NULL)
}else{
selectInput('p_orderBy', 'Cell Order By:', choices = progressionLabs(),
selected = progressionLabs()[1], width = "100%")
}
})
output$P_markerSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$progressionRes)){
return(NULL)
}else{
markerNames <- colnames(v$data$progressionRes$sampleData)
initNum <- ifelse(length(markerNames) >=4, 4, 1)
selectizeInput('p_markerSelect', 'Select Markers:',
choices = markerNames, selected = markerNames[1:initNum],
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_markerSelect', strong('Select Markers:'),
# markerNames, selected = markerNames, inline = TRUE)
}
})
output$P_clusterSelect <- renderUI({
if(is.null(v$data) || is.null(v$data$progressionRes)){
return(NULL)
}else{
clusterIDs <- sort(unique(v$data$progressionRes$sampleCluster))
selectizeInput('p_clusterSelect', 'Select Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
# checkboxGroupInput('p_clusterSelect', strong('Select Clusters:'),
# clusterIDs, selected = clusterIDs, inline = TRUE)
}
})
P_markerPlotInput <- function(){
p_markerSelect <- isolate(input$p_markerSelect)
p_clusterSelect <- isolate(input$p_clusterSelect)
if(is.null(v$data) || is.null(v$data$progressionRes) || is.null(p_markerSelect) || is.null(p_clusterSelect) || is.null(input$p_orderBy))
return(NULL)
withProgress(message="Generating Marker Expression Profile", value=0, {
data <- data.frame(v$data$progressionRes$sampleData,
cluster = v$data$progressionRes$sampleCluster,
v$data$progressionRes$progressionData,
check.names = FALSE)
sampleNames <- sub("_[0-9]*$", "", row.names(v$data$progressionRes$sampleData))
data <- data[sampleNames %in% input$samples, ,drop=FALSE]
incProgress(1/3)
if(input$P_combineTrends){
pp <- cytof_expressionTrends(data,
markers = p_markerSelect,
clusters = p_clusterSelect,
orderCol = input$p_orderBy,
clusterCol = "cluster",
reverseOrder = input$P_reverseOrder,
addClusterLabel = input$P_addLabel2,
clusterLabelSize = input$P_LabelSize2,
segmentSize = 0.5,
min_expr = NULL)
}else{
pp <- cytof_progressionPlot(data,
markers = p_markerSelect,
clusters = p_clusterSelect,
orderCol = input$p_orderBy,
clusterCol = "cluster",
reverseOrder = input$P_reverseOrder,
addClusterLabel = input$P_addLabel2,
clusterLabelSize = input$P_LabelSize2,
segmentSize = 0.5,
min_expr = NULL)
}
incProgress(1/3)
plot(pp)
incProgress(1/3)
})
}
observeEvent(input$P_updateRegressionPlot, {
output$P_markerPlot <- renderPlot({
P_markerPlotInput()
}, height = 900, width = 950)
})
output$P_download_markerPlot = downloadHandler(
filename = function() { paste("cytofkit_shinyAPP_progression_marker_plot", '.pdf', sep='') },
content = function(file) {
ggsave(file, plot = P_markerPlotInput(),
width=as.numeric(input$P_tab2_w),
height=as.numeric(input$P_tab2_h))
}
)
##-----Run Diffusionmap-----
output$P_clusterTable <- renderTable({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
clusterTable <- t(as.matrix(table(v$data$clusterRes[[input$p_clusterMethod]])))
out <- as.data.frame(clusterTable, row.names = "Cell Counts")
colnames(out) <- paste("Cluster", colnames(out))
out
}
})
output$P_clusterFilter <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
obj <- v$data
clusterIDs <- sort(unique(obj$clusterRes[[input$p_clusterMethod]]))
selectizeInput('p_clusterFilter', 'Filter Clusters:',
choices = clusterIDs, selected = clusterIDs,
multiple = TRUE, width = "100%")
}
})
output$P_clusterMethod <- renderUI({
if(is.null(v$data) || is.null(clusterMethods())){
return(NULL)
}else{
selectInput('p_clusterMethod', 'Cluster Method:', choices = clusterMethods(),
selected = clusterMethods()[1], width = "100%")
}
})
## result object which will be updated by P_runDiffusionmap
observeEvent(input$P_runDiffusionmap, {
if(!is.null(v$data)){
obj <- v$data
usedClusters <- input$p_clusterFilter
clusterCheck <- obj$clusterRes[[input$p_clusterMethod]] %in% usedClusters
mdata <- obj$expressionData[clusterCheck, ]
mcluster <- obj$clusterRes[[input$p_clusterMethod]][clusterCheck]
withProgress(message="Runing Diffusionmap", value=0, {
diffmapRes <- cytof_progression(data = mdata,
cluster = mcluster,
method = "diffusionmap",
distMethod = input$P_distMethod,
out_dim = input$P_outDim,
clusterSampleMethod = input$P_sampleMethod,
clusterSampleSize = input$P_clusterSampleSize)
incProgress(1/2)
## update progressionRes results
obj$progressionRes <- diffmapRes
## update the project name
obj$projectName <- paste0(obj$projectName, "_added_diffusionmap")
v$data <- obj
incProgress(1/2)
})
p$progressionCluster <- input$p_clusterMethod
## jump to P_tab1
updateTabsetPanel(session, "P_progressionTabs", selected = "P_tab1")
}
})
})
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