R/GenoGAMDataSet-class.R
In gstricker/fastGenoGAM: A GAM based framework for analysis of ChIP-Seq data
## ====================
## GenoGAMDataset class
## ====================
#' @include GenoGAMSettings-class.R
#' @include GenoGAM-class.R
NULL
setClassUnion("HDF5OrMatrix", c("matrix", "HDF5Matrix"))
#' GenoGAMDataSet
#'
#' The GenoGAMDataSet class contains the pre-processed raw data and
#' additional slots that define the input and framework for the model.
#' It extends the RangedSummarizedExperiment class by adding an index
#' that defines ranges on the entire genome, mostly for purposes of
#' parallel evaluation. Furthermore adding a couple more slots to hold
#' information such as experiment design. It also contains the
#' \code{\link[fastGenoGAM]{GenoGAMSettings}} class that defines global
#' settings for the session. For information on the slots inherited from
#' SummarizedExperiment check the respective class.
#'
#' @slot settings The global and local settings that will be used to compute the
#' model.
#' @slot design The formula describing how to evaluate the data. See details.
#' @slot sizeFactors The normalized values for each sample. A named numeric vector.
#' @slot index A GRanges object representing an index of the ranges defined
#' on the genome. Mostly used to store tiles.
#' @slot hdf5 A logical slot indicating if the object should be stored as HDF5
#' @slot countMatrix Either a matrix or HDF5Matrix to store the sums of counts of
#' the regions (could also be seen as bins) for later use especially by DESeq2
#' @name GenoGAMDataSet-class
#' @rdname GenoGAMDataSet-class
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @exportClass GenoGAMDataSet
setClass("GenoGAMDataSet",
contains = "RangedSummarizedExperiment",
slots = list(settings = "GenoGAMSettings",
design = "formula", sizeFactors = "numeric",
hdf5 = "logical", index = "GRanges", countMatrix = "HDF5OrMatrix"),
prototype = list(settings = GenoGAMSettings(),
design = ~ s(x), sizeFactors = numeric(),
hdf5 = FALSE, index = GenomicRanges::GRanges(),
countMatrix = matrix()))
## Validity
## ========
.validateSettingsType <- function(object) {
if(!is(slot(object, "settings"), "GenoGAMSettings")) {
return("'settings' must be a GenoGAMSettings object")
}
NULL
}
.validateDesignType <- function(object) {
if(!is(slot(object, "design"), "formula")) {
return("'design' must be a formula object")
}
NULL
}
.validateSFType <- function(object) {
if(!is(slot(object, "sizeFactors"), "numeric")) {
return("'sizeFactors' must be a numeric object")
}
NULL
}
## Validating the correct type
.validateIndexType <- function(object) {
if(!is(object@index, "GRanges")) {
return("'index' must be a GRanges object")
}
NULL
}
.validateChromosomes <- function(object) {
cindex <- GenomeInfoDb::seqlevels(object@index)
cobject <- GenomeInfoDb::seqlevels(rowRanges(object))
if(!all(cindex %in% cobject)) {
return("Different chromosomes for data and index objects.")
}
NULL
}
## Validating the correct type
.validateCountMatrixType <- function(object) {
if(!is(object@countMatrix, "matrix") & !is(object@countMatrix, "HDF5Matrix")) {
return("'countMatrix' must be either a matrix or HDF5Matrix object")
}
NULL
}
.validateH5Type <- function(object) {
if(!is(object@hdf5, "logical")) {
return("'hdf5' must be a logical object")
}
NULL
}
## general validate function
.validateGenoGAMDataSet <- function(object) {
c(.validateSettingsType(object), .validateDesignType(object),
.validateSFType(object), .validateIndexType(object),
.validateChromosomes(object), .validateCountMatrixType(object),
.validateH5Type(object))
}
S4Vectors::setValidity2("GenoGAMDataSet", .validateGenoGAMDataSet)
## Constructor
## ===========
#' GenoGAMDataSet constructor.
#'
#' GenoGAMDataSet is the constructor function for the GenoGAMDataSet-class.
#'
#' @aliases getIndex tileSettings dataRange getChromosomes getTileSize getChunkSize getOverhangSize getTileNumber
#' getChunkSize<- getTileSize<- getOverhangSize<- getTileNumber<-
#' @param experimentDesign Either a character object specifying the path to a
#' delimited text file (the delimiter will be determined automatically),
#' a data.frame specifying the experiment design or a RangedSummarizedExperiment
#' object with the GPos class being the rowRanges. See details for the structure
#' of the experimentDesign.
#' @param chunkSize An integer specifying the size of one chunk in bp.
#' @param overhangSize An integer specifying the size of the overhang in bp.
#' As the overhang is taken to be symmetrical, only the overhang of one side
#' should be provided.
#' @param design A formula object. See details for its structure.
#' @param directory The directory from which to read the data. By default
#' the current working directory is taken.
#' @param settings A GenoGAMSettings object. Not needed by default, but might
#' be of use if only specific regions should be read in.
#' See \code{\link{GenoGAMSettings}}.
#' @param hdf5 Should the data be stored on HDD in HDF5 format? By default this
#' is disabled, as the Rle representation of count data already provides a
#' decent compression of the data. However in case of large organisms, a complex
#' experiment design or just limited memory, this might further decrease the
#' memory footprint. Note this only applies to the input count data, results are
#' usually stored in HDF5 format due to their space requirements for type double.
#' Exceptions are small organisms like yeast.
#' @param split A logical argument specifying if the data should be stored as
#' a list split by chromosome. This is useful and necessary for huge organisms like
#' human, as R does not support long integers.
#' @param fromHDF5 A logical argument specifying if the data is already present in
#' form of HDF5 files and should be rather read in from there.
#' @param ignoreM A logical argument to ignore the Mitochondria DNA on data read in.
#' This is useful, if one is not interested in chrM, but it's size prevents the tiles
#' to be larger, as all tiles has to be of some size.
#' @param ... Further parameters, mostly for arguments of custom processing
#' functions or to specify a different method for fragment size estimation.
#' See details for further information.
#' @param object For use of S4 methods. The GenoGAMDataSet object.
#' @param value For use of S4 methods. The value to be assigned to the slot.
#' @return An object of class \code{\link{GenoGAMDataSet}} or the respective slot.
#' @section Config:
#'
#' The config file/data.frame contains the actual experiment design. It must
#' contain at least three columns with fixed names: 'ID', 'file' and 'paired'.
#'
#' The field 'ID' stores a unique identifier for each alignment file.
#' It is recommended to use short and easy to understand identifiers because
#' they are subsequently used for labelling data and plots.
#'
#' The field 'file' stores the BAM file name.
#'
#' The field 'paired', values TRUE for paired-end sequencing data, and FALSE for
#' single-end sequencing data.
#'
#' All other columns are stored in the colData slot of the GenoGAMDataSet
#' object. Note that all columns which will be used for analysis must have at
#' most two conditions, which are for now restricted to 0 and 1. For example,
#' if the IP data schould be corrected for input, then the input will be 0
#' and IP will be 1, since we are interested in the corrected IP. See examples.
#'
#' @section Design/Formula:
#'
#' Design must be a formula. At the moment only the following is
#' possible: Either ~ s(x) for a smooth fit over the entire data or
#' s(x, by = myColumn), where 'myColumn' is a column name
#' in the experimentDesign. Any combination of this is possible:
#'
#' ~ s(x) + s(x, by = myColumn) + s(x, by = ...) + ...
#'
#' For example the formula for correcting IP for input would look like this:
#'
#' ~ s(x) + s(x, by = experiment)
#'
#' where 'experiment' is a column with 0s and 1s, with the ip samples annotated
#' with 1 and input samples with 0.
#''
#' @section Further parameters:
#'
#' In case of single-end data it might be usefull to specify a different
#' method for fragment size estimation. The argument 'shiftMethod' can be
#' supplied with the values 'coverage' (default), 'correlation' or 'SISSR'.
#' See ?chipseq::estimate.mean.fraglen for explanation.
#' @examples
#' # Build from config file
#'
#' config <- system.file("extdata/Set1", "experimentDesign.txt", package = "fastGenoGAM")
#' dir <- system.file("extdata/Set1/bam", package = "fastGenoGAM")
#'
#' ## For all data
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir)
#' ggd
#'
#' ## Read data of a particular chromosome
#' settings <- GenoGAMSettings(chromosomeList = "chrXIV")
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' ## Read data of particular range
#' region <- GenomicRanges::GRanges("chrI", IRanges(10000, 15000))
#' params <- Rsamtools::ScanBamParam(which = region)
#' settings <- GenoGAMSettings(bamParams = params)
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' # Build from data.frame config
#'
#' df <- read.table(config, header = TRUE, sep = '\t')
#' ggd <- GenoGAMDataSet(df, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' # Build from SummarizedExperiment
#'
#' gr <- GenomicRanges::GPos(GRanges("chr1", IRanges(1, 10000)))
#' seqlengths(gr) <- 1e6
#' df <- S4Vectors::DataFrame(colA = 1:10000, colB = round(runif(10000)))
#' se <- SummarizedExperiment::SummarizedExperiment(rowRanges = gr, assays = list(df))
#' ggd <- GenoGAMDataSet(se, chunkSize = 2000, overhangSize = 250,
#' design = ~ s(x) + s(x, by = experiment))
#' ggd
#' @name GenoGAMDataSet
#' @rdname GenoGAMDataSet-class
#' @export
GenoGAMDataSet <- function(experimentDesign, design, chunkSize = NULL, overhangSize = NULL,
directory = ".", settings = NULL, hdf5 = FALSE, split = hdf5,
fromHDF5 = FALSE, ignoreM = FALSE, ...) {
if(missing(experimentDesign)) {
futile.logger::flog.debug("No input provided. Creating empty GenoGAMDataSet")
return(new("GenoGAMDataSet"))
}
futile.logger::flog.info("Creating GenoGAMDataSet")
if(is.null(settings)) {
settings <- GenoGAMSettings()
}
## optimal chunk size
if(is.null(chunkSize)) {
## need initial overhangsize if null to compute chunk size
ov <- ifelse(is.null(overhangSize), 1000, overhangSize)
bpknots <- slot(settings, "dataControl")$bpknots
chunkSize <- .setOptimalChunkSize(experimentDesign, design, ov, bpknots, hdf5)
}
if(is.null(overhangSize)) {
## overhang size not bigger than half of the chunk
overhangSize <- min(1000, chunkSize/2 - 1)
}
if(overhangSize >= chunkSize/2) {
overhangSize <- round(chunkSize/2) - 1
warning("Overhang size exceeds the total size of the chunk. Adjusted to chunkSize/2 - 1")
}
input <- paste0("Building GenoGAMDataSet with the following parameters:\n",
" Class of experimentDesign: ", class(experimentDesign), "\n",
" Chunk size: ", chunkSize, "\n",
" Overhang size: ", overhangSize, "\n",
" Design: ", paste(as.character(design, collapse= " ")), "\n",
" Directory: ", directory, "\n",
" HDF5: ", hdf5, "\n",
" Split: ", split, "\n",
" Specific Settings: ",
" From HDF5: ", fromHDF5, "\n")
futile.logger::flog.debug(input)
futile.logger::flog.debug(show(settings))
futile.logger::flog.debug(show(list(...)))
if(fromHDF5) {
futile.logger::flog.debug(paste0("Building GenoGAMDataSet from HDF5: ", settings@hdf5Control$dir))
ggd <- .GenoGAMDataSetFromHDF5(config = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
directory = directory,
settings = settings,
split = split,
ignoreM = ignoreM, ...)
}
else {
if(is(experimentDesign, "RangedSummarizedExperiment") |
is(experimentDesign, "SummarizedExperiment")) {
futile.logger::flog.debug("Building GenoGAMDataSet from SummarizedExperiment object")
ggd <- .GenoGAMDataSetFromSE(se = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
settings = settings,
hdf5 = hdf5, ...)
}
else {
futile.logger::flog.debug(paste0("Building GenoGAMDataSet from config file: ", experimentDesign))
ggd <- .GenoGAMDataSetFromConfig(config = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
directory = directory,
settings = settings,
hdf5 = hdf5,
split = split, ignoreM = ignoreM, ...)
}
}
futile.logger::flog.info("GenoGAMDataSet created")
return(ggd)
}
## The underlying function to build a GenoGAMDataSet from a
## SummarizedExperiment
.GenoGAMDataSetFromSE <- function(se, chunkSize, overhangSize,
design, settings, hdf5, ...) {
gr <- .extractGR(rowRanges(se))
## check for overlapping ranges
if(sum(countOverlaps(gr)) > length(gr)) {
stop("Overlapping regions encountered. Please reduce ranges and data first.")
}
if(any(is.na(seqlengths(se)))) {
stop("Sequence lengths missing in the Seqinfo object of SummarizedExperiment")
}
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## initiate size factors
sf <- rep(0, length(colnames(se)))
##names(sf) <- colnames(se)
## initialize sumMatrix on hdf5 if needed
if(hdf5) {
## make tiles for sum matrix storage
suml <- list(chromosomes = gr,
chunkSize = slot(settings, "dataControl")$regionSize,
overhangSize = min(overhangSize, slot(settings, "dataControl")$regionSize - 1))
sumTiles <- .makeTiles(suml)
d <- c(length(sumTiles), nrow(colData(se)))
chunk <- c(1, nrow(colData(se)))
h5SumMatrix <- .createH5DF("sumMatrix", settings, d, chunk, what = "sumMatrix")
}
else {
h5SumMatrix <- NULL
}
## update chromosome list
if(is.null(slot(settings, "chromosomeList"))) {
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
}
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = hdf5)
## compute sum matrix
## backup original tile index
index_backup <- getIndex(ggd)
## make new tile index
metadata(slot(ggd, "index"))$chunkSize <- slot(settings, "dataControl")$regionSize
newTiles <- .makeTiles(tileSettings(ggd))
slot(ggd, "index") <- newTiles
## compute the matrix
sumMatrix <- sum(ggd)
slot(ggd, "countMatrix") <- sumMatrix
## set tiles back to original
slot(ggd, "index") <- index_backup
## write to hdf5 if necessary
if(hdf5){
## write assay to HDF5 and substitute
coords <- .getCoordinates(ggd)
chunks <- .getChunkCoords(coords)
h5df <- .writeToHDF5(assay(se), file = "dataset", chunks = as(chunks, "IRanges"),
settings = settings)
assays(ggd) <- list(h5df)
## write sumMatrix to HDF5 and substitute
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "sumMatrix")
h5sm <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
slot(ggd, "countMatrix") <- h5sm
}
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
#' A function to produce a GRanges index from a list of settings.
#'
#' @param l A list of settings involving:
#' chunkSize, chromosomes, tileSize and overhangSize
#' @return A GRanges object of the tiles.
#'
#' @noRd
.makeTiles <- function(l) {
if(length(l) == 0) return(GenomicRanges::GRanges())
if(l$overhangSize < 0) stop("Overhang size must be equal or greater than 0")
if(length(l$chromosomes) == 0) stop("Chromosome list should contain at least one entry")
## tiles should be not bigger than any pre-specified region
l$tileSize <- min(l$chunkSize + 2*l$overhangSize, min(width(l$chromosomes)))
## adjust chunks and overhang accordingly
l$chunkSize <- l$tileSize - 2*l$overhangSize
if(l$chunkSize <= 0) stop("Tile size must be greater than twice the overhang size. Check your chromosome lengths. Your smallest chromosome might be smaller than 2 * overhangSize")
input <- paste0("Building Tiles with the following parameters:\n",
" Chunk size: ", l$chunkSize, "\n",
" Overhang size: ", l$overhangSize, "\n",
" Chromosomes: \n")
futile.logger::flog.debug(input)
futile.logger::flog.debug(show(l$chromosomes))
futile.logger::flog.debug(paste0("GenoGAMDataSet: Tile size computed to be ", l$tileSize))
## deal with overlapping ranges to reduce complexity and redundancy
l$chromosomes <- GenomicRanges::reduce(l$chromosomes)
.local <- function(id, sl, chromList) {
y <- chromList[id,]
## load package for SnowParam or BatchJobs backend
suppressPackageStartupMessages(require(fastGenoGAM, quietly = TRUE))
## generate break points for chunks
nchunks <- ceiling(IRanges::width(y)/sl$chunkSize)
startSeq <- seq(0, nchunks - 1, length.out = nchunks) * sl$chunkSize
endSeq <- seq(1, nchunks - 1, length.out = (nchunks - 1)) * sl$chunkSize - 1
starts <- IRanges::start(y) + startSeq
ends <- c(IRanges::start(y) + endSeq, IRanges::end(y))
ir <- IRanges::IRanges(starts, ends)
chunks <- GenomicRanges::GRanges(seqnames = GenomeInfoDb::seqnames(y), ir)
GenomeInfoDb::seqinfo(chunks) <- GenomeInfoDb::seqinfo(y)
## flank to tiles
if(sl$tileSize == sl$chunkSize) {
tiles <- chunks
}
else {
ov <- round(IRanges::width(chunks)/2)
## shift to center to get a point to flank from
centeredChunks <- suppressWarnings(IRanges::shift(chunks, ov))
## flank to get tiles
ir <- suppressWarnings(IRanges::flank(centeredChunks,
round(sl$tileSize/2),
both = TRUE))
## trim tiles if overhang caused it to go out of bounds
tiles <- suppressWarnings(IRanges::trim(ir))
## remove smaller tiles at the borders that are completely
## contained by bigger tiles
tiles <- tiles[!overlapsAny(tiles, type="within", drop.self=TRUE)]
}
## adjust first tile
startsToResize <- which(IRanges::start(tiles) < IRanges::start(y))
trimmedEnd <- IRanges::end(tiles[startsToResize]) + IRanges::start(y) - IRanges::start(tiles[startsToResize])
IRanges::end(tiles[startsToResize]) <- min(trimmedEnd, IRanges::end(y))
IRanges::start(tiles[startsToResize]) <- IRanges::start(y)
## adjust last tile
endsToResize <- which(IRanges::end(tiles) > IRanges::end(y))
trimmedStarts <- IRanges::start(tiles[endsToResize]) - IRanges::end(tiles[endsToResize]) + IRanges::end(y)
IRanges::start(tiles[endsToResize]) <- max(trimmedStarts, IRanges::start(y))
IRanges::end(tiles[endsToResize]) <- IRanges::end(y)
## remove duplicate tiles if present
tiles <- unique(tiles)
return(tiles)
}
## run local function
tileList <- BiocParallel::bplapply(1:length(l$chromosomes), .local, sl = l, chromList = l$chromosomes)
## concatenate results into one list
tiles <- do.call("c", tileList)
GenomeInfoDb::seqlengths(tiles) <- GenomeInfoDb::seqlengths(l$chromosomes)
GenomeInfoDb::seqlevels(tiles, pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(tiles)
## resize start and end tiles till correct tile size is reached
## find tiles that are at the start of the regions of interest
startPos <- GRanges(seqnames(l$chromosomes), IRanges(start(l$chromosomes), start(l$chromosomes)))
isStart <- logical(length(tiles))
isStart[queryHits(findOverlaps(tiles, startPos))] <- TRUE
startsToResize <- which(width(tiles) < l$tileSize & isStart)
suppressWarnings(tiles[startsToResize] <- resize(tiles[startsToResize], width = l$tileSize))
endsToResize <- which(width(tiles) < l$tileSize)
suppressWarnings(tiles[endsToResize] <- resize(tiles[endsToResize], width = l$tileSize, fix = "end"))
tiles <- IRanges::trim(tiles)
## remove duplicate tiles if present
tiles <- unique(tiles)
## add 'id' column, check element and put settings in metadata
S4Vectors::mcols(tiles)$id <- 1:length(tiles)
l$numTiles <- length(tiles)
futile.logger::flog.debug(paste0("GenoGAMDataSet: Data split into ", l$numTiles, " tiles"))
l$check <- TRUE
S4Vectors::metadata(tiles) <- l
return(tiles)
}
## set optimal chunk length if not provided
## based on number of cores, samples, splines and
## in case of HDF5, the block size
.setOptimalChunkSize <- function(expDesign, design, ov, bpknots, hdf5) {
## determine number of samples
if(is(expDesign, "RangedSummarizedExperiment")) {
nsamples <- nrow(colData(expDesign))
}
else {
if(is(expDesign, "data.frame")) {
nsamples <- nrow(expDesign)
}
else {
nsamples <- count.fields(expDesign)[1]
}
}
## if(hdf5) {
## maxBlockSize <- DelayedArray:::get_max_block_length("integer")
## tileSize <- floor(maxBlockSize/nsamples)
## chunkSize <- tileSize - 2*ov
## }
## else {
## workers <- BiocParallel::registered()[[1]]$workers
## maximal chunk size to work with and use only 1GB per core
posPerGB <- 8000000L / bpknots
## we don't want to exceed this number of GByte per core
GBlimit <- 4L
## number of splines
nsplines <- length(.getVars(design))
## chunkSize <- (workers * posPerGB * GBlimit) / (nsamples * nsplines)
chunkSize <- (posPerGB * GBlimit) / (nsamples * nsplines)
## }
return(chunkSize)
}
## make the 'by' argument for the 'makeSumMatrix' function
.makeBy <- function(x, from) {
rr <- range(from)
if(length(rr) == 1 &
IRanges::start(rr) == 1 &
IRanges::end(rr) == max(GenomicRanges::pos(x)))
{
return(ranges(from))
}
ovRanges <- IRanges::findOverlaps(x, from)
res <- sapply(unique(S4Vectors::subjectHits(ovRanges)), function(y) {
qh <- S4Vectors::queryHits(ovRanges)[S4Vectors::subjectHits(ovRanges) == y]
IRanges::IRanges(min(qh), max(qh))
})
return(do.call("c", res))
}
## make sum matrix for each DataFrame
.makeSumMatrix <- function(x, by) {
cols <- names(x)
res <- sapply(cols, function(y) {
## extract cuts. Because of overlaps the data will be partly replicated
## and thus increase in row dimension. It is important to
## compute further things on the 'stretched' data
rle <- IRanges::extractList(x[,y], by)
values <- cumsum(rle@unlistData)
sums <- values[end(rle@partitioning)]
## keep first values and change the rest to the differences
if(length(sums) > 1) {
sums[2:length(sums)] <- diff(sums)
}
return(as.integer(sums))
})
return(res)
}
## get the identifier of the HDF5 files, that belong together to one dataset
.getIdentifier <- function(path, fits = FALSE) {
identPos <- 2
if(fits) identPos <- 3
files <- list.files(path)
splitFiles <- strsplit(files, "_")
## check the second element of the split name, which should be the
## identifier (and the creation date). Discard invalid files (which give NA)
## and in case of multiple identifiers select the first.
possibleIdentifiers <- unique(na.omit(sapply(splitFiles, function(y) y[identPos])))
return(possibleIdentifiers[1])
}
#' Convert the config columns to the right type.
#'
#' @param config A data.frame with pre-specified columns.
#' @param directory The directory of the files
#' @return The same data.frame with the columns of the right type.
#' @noRd
.normalizeConfig <- function(config, directory) {
if(is(config, "character")) {
config <- data.table::fread(config, header = TRUE, data.table = FALSE)
}
config$ID <- as.factor(config$ID)
config$file <- file.path(directory, as.character(config$file))
config$paired <- as.logical(config$paired)
futile.logger::flog.debug("Using the following config file:")
futile.logger::flog.debug(show(config))
return(config)
}
## a list of names for the Mitochondria chromosome
.mnames <- function() {
c("chrM", "MT", "chromosomeM", "ChromosomeMT", "2micron")
}
## The underlying function to build a GenoGAMDataSet from a
## config file or a data.frame
.GenoGAMDataSetFromConfig <- function(config, chunkSize, overhangSize, design,
directory, settings, hdf5 = FALSE, split = hdf5, ignoreM = FALSE, ...) {
## initialize some variables
args <- list()
## normalize config object
config <- .normalizeConfig(config, directory)
center <- slot(settings, "center")
if(!is.null(center)) {
slot(settings, "processFunction") <- .processCountChunks
}
## get chromosomeLengths to check if a split of data along the chromosomes is necessary
header <- Rsamtools::scanBamHeader(config$file[1])
chroms <- header[[1]]$targets
nsamples <- nrow(config)
totalLength <- sum(as.numeric(chroms))*nsamples
## split if data vectors are to big
if(totalLength > 2^31) {
split <- TRUE
}
## ignore Mito chromosome
if(ignoreM) {
keep <- !(names(chroms) %in% .mnames())
chroms <- chroms[keep]
}
## generate rowRanges
bamParamsWhich <- Rsamtools::bamWhich(slot(settings, "bamParams"))
if(length(bamParamsWhich) != 0) {
gr <- GenomicRanges::GRanges(bamParamsWhich)
lengths <- chroms[GenomeInfoDb::seqlevels(GenomicRanges::GRanges(bamParamsWhich))]
if(all(!is.na(lengths))){
GenomeInfoDb::seqlengths(gr) <- lengths
}
else {
futile.logger::flog.error("The data does not match the region specification in the bamParams settings.")
return(new("GenoGAMDataSet"))
}
}
else {
if(!is.null(slot(settings, "chromosomeList"))) {
chroms <- chroms[names(chroms) %in% slot(settings, "chromosomeList")]
}
starts <- rep(1, length(chroms))
ends <- chroms
gr <- GenomicRanges::GRanges(names(chroms),
IRanges::IRanges(starts, ends))
GenomeInfoDb::seqlengths(gr) <- chroms
}
## update chromosome list
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
if(length(slot(settings, "chromosomeList")) == 0) {
futile.logger::flog.error("No chromosomes to read in. Check either the specified settings or the header of BAM file")
return(new("GenoGAMDataSet"))
}
futile.logger::flog.debug("Following row ranges created:")
futile.logger::flog.debug(show(gr))
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## make tiles for sum matrix computation
suml <- list(chromosomes = gr,
chunkSize = slot(settings, "dataControl")$regionSize,
overhangSize = min(overhangSize, slot(settings, "dataControl")$regionSize - 1))
sumTiles <- .makeTiles(suml)
## make colData
colData <- S4Vectors::DataFrame(config)[,-c(1:3), drop = FALSE]
rownames(colData) <- config$ID
## initiate size factors
sf <- rep(0, nrow(colData))
## initialize sumMatrix on hdf5 if needed
if(hdf5) {
d <- c(length(sumTiles), nrow(colData))
chunk <- c(1, nrow(colData))
h5SumMatrix <- .createH5DF("sumMatrix", settings, d, chunk, what = "sumMatrix")
}
else {
h5SumMatrix <- NULL
}
## final build object
## if split make sure to keep the seqinfo same for all list elements,
## as this will make it easily possible to merge them later if necessary
if(split) {
splitid <- gr
splitid$id <- as.character(GenomeInfoDb::seqnames(splitid))
## backup chromosomeList
chrBackup <- slot(settings, "chromosomeList")
## make queue for sum matrix
qdir <- .init_Queue(h5SumMatrix)
selist <- BiocParallel::bplapply(splitid$id, function(id) {
## read data and make SummarizedExperiment objects
slot(settings, "chromosomeList") <- id
countData <- readData(config, settings = settings, ...)
if(length(countData) == 0) {
return(new("GenoGAMDataSet"))
}
rr <- GenomicRanges::GPos(gr[GenomeInfoDb::seqnames(gr) == id,])
smRanges <- sumTiles[GenomeInfoDb::seqnames(sumTiles) == id]
## make sumMatrix
by <- .makeBy(rr, smRanges)
sumMatrix <- .makeSumMatrix(countData, by)
## make SummarizedExperiment objects and write to HDD if necessary
if(hdf5) {
## make chunks for faster writing
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = 0)
hdf5_tiles <- fastGenoGAM:::.makeTiles(l)
hdf5_ranges <- hdf5_tiles[GenomeInfoDb::seqnames(hdf5_tiles) == id]
## write chromosome data to HDF5
h5df <- .writeToHDF5(countData, file = id, chunks = hdf5_ranges, settings = settings)
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = rr,
assays = list(h5df), colData = colData)
qid <- .queue(qdir)
## wait till it's your turn
while(list.files(qdir)[1] != qid){
Sys.sleep(0.1)
}
## write sum matrix to HDF5
rows <- which(GenomeInfoDb::seqnames(sumTiles) == id)
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "/sumMatrix",
index = list(rows, 1:ncol(sumMatrix)))
## unqueue
.unqueue(qid, qdir)
res <- se
}
else {
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = rr,
assays = list(countData), colData = colData)
res <- list(se = se, sm = sumMatrix)
}
rm(countData)
gc()
return(res)
})
.end_Queue(qdir)
if(hdf5) {
names(selist) <- chrBackup
sumMatrix <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
}
else {
## combine sum matrices to one and
## extract the SummarizedExperiment objects only
sumMatrix <- lapply(selist, function(y) y$sm)
sumMatrix <- do.call("rbind", sumMatrix)
selist <- lapply(selist, function(y) y$se)
names(selist) <- chrBackup
}
## Make new GenoGAMDataSetList object
slot(settings, "chromosomeList") <- chrBackup
ggd <- new("GenoGAMDataSetList", settings = settings,
design = design, sizeFactors = sf, index = tiles,
data = selist, id = splitid, hdf5 = hdf5, countMatrix = sumMatrix)
}
else {
## read data and make SummarizedExperiment objects
countData <- readData(config, settings = settings, ...)
if(length(countData) == 0) {
return(new("GenoGAMDataSet"))
}
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr),
assays = list(countData),
colData = colData)
## first make GenoGAMDataSet object and then compute
## the sum matrix and write to hdf5 if necessary
## this avoids special functions for those particular steps
## only.
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = hdf5)
## compute sum matrix
## backup original tile index
index_backup <- getIndex(ggd)
## set new tiles
slot(ggd, "index") <- sumTiles
## compute the matrix
sumMatrix <- sum(ggd)
slot(ggd, "countMatrix") <- sumMatrix
## set tiles back to original
slot(ggd, "index") <- index_backup
if(hdf5){
## write assay to HDF5 and substitute
coords <- .getCoordinates(ggd)
chunks <- .getChunkCoords(coords)
h5df <- .writeToHDF5(countData, file = "dataset", chunks = as(chunks, "IRanges"),
settings = settings)
assays(ggd) <- list(h5df)
## write sumMatrix to HDF5 and substitute
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "sumMatrix")
h5sm <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
slot(ggd, "countMatrix") <- h5sm
}
}
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
## The underlying function to build a GenoGAMDataSet from an
## already present HDF5 file
.GenoGAMDataSetFromHDF5 <- function(config, chunkSize, overhangSize,
design, directory, settings, split, ignoreM = FALSE, ...) {
## initialize some variables
args <- list()
## normalize config object
config <- .normalizeConfig(config, directory)
## get chromosomeLengths to check if a split of data along the chromosomes is necessary
header <- Rsamtools::scanBamHeader(config$file[1])
chroms <- header[[1]]$targets
## ignore Mito chromosome
if(ignoreM) {
keep <- !(names(chroms) %in% .mnames())
chroms <- chroms[keep]
}
if(!is.null(slot(settings, "chromosomeList"))) {
chroms <- chroms[names(chroms) %in% slot(settings, "chromosomeList")]
}
## generate rowRanges
bamParamsWhich <- Rsamtools::bamWhich(slot(settings, "bamParams"))
if(length(bamParamsWhich) != 0) {
gr <- GenomicRanges::GRanges(bamParamsWhich)
lengths <- chroms[GenomeInfoDb::seqlevels(GenomicRanges::GRanges(bamParamsWhich))]
if(all(!is.na(lengths))){
GenomeInfoDb::seqlengths(gr) <- lengths
}
else {
futile.logger::flog.error("The data does not match the region specification in the bamParams settings.")
return(new("GenoGAMDataSet"))
}
}
else {
starts <- rep(1, length(chroms))
ends <- chroms
gr <- GenomicRanges::GRanges(names(chroms),
IRanges::IRanges(starts, ends))
GenomeInfoDb::seqlengths(gr) <- chroms
}
futile.logger::flog.debug("Following row ranges created:")
futile.logger::flog.debug(show(gr))
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## make colData
colData <- S4Vectors::DataFrame(config)[,-c(1:3), drop = FALSE]
rownames(colData) <- config$ID
## initiate size factors
sf <- rep(0, nrow(colData))
##names(sf) <- config$ID
## update chromosome list
if(is.null(slot(settings, "chromosomeList"))) {
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
}
## get Identifier for the data
path <- slot(settings, "hdf5Control")$dir
ident <- .getIdentifier(path)
if(split) {
## finally build object
splitid <- gr
splitid$id <- as.character(GenomeInfoDb::seqnames(splitid))
selist <- lapply(splitid$id, function(id) {
## read HDF5 file
h5file <- file.path(path, paste0(id, "_", ident))
## read HDF5 data and make SummarizedExperiment objects
h5df <- HDF5Array::HDF5Array(h5file, id)
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr[GenomeInfoDb::seqnames(gr) == id,]),
assays = list(h5df), colData = colData)
return(se)
})
names(selist) <- splitid$id
ggd <- new("GenoGAMDataSetList", settings = settings,
design = design, sizeFactors = sf, index = tiles,
data = selist, id = splitid, hdf5 = TRUE)
}
else {
## read HDF5 file
h5file <- file.path(path, paste0("dataset", "_", ident))
## read HDF5 data and make SummarizedExperiment objects
h5df <- HDF5Array::HDF5Array(h5file, "dataset")
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr),
assays = list(h5df), colData = colData)
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = TRUE)
}
## read sum matrix file
smFile <- file.path(path, paste0("sumMatrix", "_", ident))
sumMatrix <- HDF5Array::HDF5Array(smFile, "sumMatrix")
slot(ggd, "countMatrix") <- sumMatrix
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
#' Make an example /code{GenoGAMDataSet}
#'
#' @param sim Use simulated data (TRUE) or test data from a real experiment
#' @return A /code{GenoGAMDataSet} object
#' @examples
#' realdt <- makeTestGenoGAMDataSet()
#' simdt <- makeTestGenoGAMDataSet(sim = TRUE)
#' @export
makeTestGenoGAMDataSet <- function(sim = FALSE) {
if(sim) {
k <- 10000
sinCurve <- sin(seq(-7, 5, length.out = k)) + 1
ip <- rnbinom(k, size = 2, mu = sinCurve/max(sinCurve))
sinCurve <- c(sin(seq(-7, -1, length.out = k/2)) + 1, runif(k/2, 0, 0.2))
background <- rnbinom(k, size = 2, mu = sinCurve/max(sinCurve)/2)
gr <- GenomicRanges::GPos(GenomicRanges::GRanges("chrXYZ", IRanges::IRanges(1, k)))
GenomeInfoDb::seqlengths(gr) <- 1e6
df <- S4Vectors::DataFrame(input = background, IP = ip)
se <- SummarizedExperiment(rowRanges = gr, assays = list(df))
ggd <- GenoGAMDataSet(se, chunkSize = 2000, overhangSize = 250,
design = ~ s(x))
coldf <- S4Vectors::DataFrame(experiment = c(0, 1))
rownames(coldf) <- c("input", "IP")
colData(ggd) <- coldf
design(ggd) <- ~ s(x) + s(x, by = experiment)
}
else {
config <- system.file("extdata/Set1", "experimentDesign.txt",
package = "fastGenoGAM")
dir <- system.file("extdata/Set1/bam", package = "fastGenoGAM")
region <- GRanges("chrI", IRanges(10000, 20000))
params <- Rsamtools::ScanBamParam(which = region)
settings <- GenoGAMSettings(bamParams = params)
ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
design = ~ s(x) + s(x, by = genotype),
directory = dir, settings = settings)
}
return(ggd)
}
## Check functions
## ===============
## Check a specified setting of GenoGAMDataSet
.checkSettings <- function(object, params = c("chunkSize", "tileSize",
"equality", "tileRanges",
"chromosomes", "numTiles", "formula")) {
param <- match.arg(params)
switch(param,
chunkSize = .checkChunkSize(object),
tileSize = .checkTileSize(object),
equality = .checkEqualityOfTiles(object),
chromosomes = .checkChromosomes(object),
numTiles = .checkNumberOfTiles(object),
tileRanges = .checkTileRanges(object),
formula = .checkFormulaVariables(object))
}
## check the chunk size and return a logical value
.checkChunkSize <- function(object) {
widths <- IRanges::width(getIndex(object))
diffs <- (widths - 2*getOverhangSize(object)) - getChunkSize(object)
res <- all.equal(diffs, rep(0, length(diffs)), tolerance = 0)
return(res)
}
## check the tile size and return a logical value
.checkTileSize <- function(object) {
widths <- IRanges::width(getIndex(object))
diffs <- widths - getTileSize(object)
res <- all.equal(diffs, rep(0, length(diffs)), tolerance = 0)
return(res)
}
## check the overhang size and return a logical value
.checkEqualityOfTiles <- function(object) {
widths <- width(getIndex(object))
res <- all.equal(min(widths), max(widths))
return(res)
}
## check the chromosome list and return a logical value
.checkChromosomes <- function(object) {
objChroms <- GenomeInfoDb::seqlengths(object)
indexChroms <- GenomeInfoDb::seqlengths(getIndex(object))
validChroms <- GenomeInfoDb::seqlengths(getChromosomes(object))
objChroms <- objChroms[order(names(objChroms))]
indexChroms <- indexChroms[order(names(indexChroms))]
validChroms <- validChroms[order(names(validChroms))]
res1 <- all.equal(indexChroms, validChroms, objChroms)
res2 <- all.equal(names(indexChroms), names(validChroms), names(objChroms))
if(is(res1, "character") | is(res2, "character")) {
ans <- paste("Chromosome Lengths:", res1, "\n", "Chromosome Names:", res2, "\n")
return(ans)
}
return(res1 & res2)
}
## check the number of tiles and return a logical value
.checkNumberOfTiles <- function(object) {
tiles <- length(getIndex(object))
validTiles <- getTileNumber(object)
res <- all.equal(tiles, validTiles)
return(res)
}
## check ranges
.checkTileRanges <- function(object) {
tileRanges <- tileSettings(object)$chromosomes
dataRanges <- dataRange(object)
res <- all.equal(tileRanges, dataRanges)
return(res)
}
.checkFormulaVariables <- function(object) {
formulaCols <- as.vector(na.omit(.getVars(design(object))))
res <- all(formulaCols %in% colnames(colData(object)))
if(!res) {
res <- "'by' variables in design don't match colData"
}
return(res)
}
## Function to check the GenoGAMDataSet object
.checkGenoGAMDataSet <- function(object) {
futile.logger::flog.debug("Check if tile settings match the data.")
params = c("chunkSize", "tileSize", "tileRanges",
"equality", "chromosomes", "numTiles", "formula")
settings <- tileSettings(object)
if(is.null(settings$check)) {
futile.logger::flog.warn("Checks dismissed due to empty object or forgotten setting")
return(FALSE)
}
if(!settings$check) {
futile.logger::flog.warn("Settings checking deactivated. Modeling on these tiles might yield wrong results.")
return(FALSE)
}
res <- sapply(params, .checkSettings, object = object)
if(is(res, "character")) {
errorIndx <- which(res != "TRUE")
futile.logger::flog.error("Checks failed. Following settings display errors:")
futile.logger::flog.error(show(res[errorIndx]))
return(FALSE)
}
futile.logger::flog.debug("All checks passed.")
return(TRUE)
}
#' @noRd
setGeneric("checkObject", function(object) standardGeneric("checkObject"))
#' Check data compliance with tile settings
#'
#' Check if the indices were build correctly, according to the
#' specified parameters
#'
#' @rdname checkObject
#' @param object A /code{GenomicTiles} object.
#' @return A logical value
#' @examples
#' gt <- makeTestGenomicTiles()
#' checkSettings(gt)
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @noRd
setMethod("checkObject", "GenoGAMDataSet", function(object) {
.checkGenoGAMDataSet(object)
})
## Accessors
## =========
#' @export
setGeneric("getIndex", function(object) standardGeneric("getIndex"))
#' @describeIn GenoGAMDataSet An accessor to the index slot
setMethod("getIndex", signature(object = "GenoGAMDataSet"), function(object) {
return(slot(object, "index"))
})
#' @export
setGeneric("getCountMatrix", function(object) standardGeneric("getCountMatrix"))
#' @describeIn GenoGAMDataSet An accessor to the countMatrix slot
setMethod("getCountMatrix", signature(object = "GenoGAMDataSet"), function(object) {
res <- slot(object, "countMatrix")
colnames(res) <- colnames(object)
return(res)
})
#' @export
setGeneric("tileSettings", function(object) standardGeneric("tileSettings"))
#' @describeIn GenoGAMDataSet The accessor to the list of settings,
#' that were used to generate the tiles.
setMethod("tileSettings", "GenoGAMDataSet", function(object) {
S4Vectors::metadata(getIndex(object))
})
#' @export
setGeneric("dataRange", function(object) standardGeneric("dataRange"))
#' @describeIn GenoGAMDataSet The actual underlying GRanges showing
#' the range of the data.
setMethod("dataRange", "GenoGAMDataSet", function(object) {
.extractGR(rowRanges(object))
})
#' @export
setGeneric("getChromosomes", function(object) standardGeneric("getChromosomes"))
#' @describeIn GenoGAMDataSet A GRanges object representing the chromosomes
#' or chromosome regions on which the model will be computed
setMethod("getChromosomes", "GenoGAMDataSet", function(object) {
tileSettings(object)$chromosomes
})
#' @export
setGeneric("getTileSize", function(object) standardGeneric("getTileSize"))
#' @describeIn GenoGAMDataSet The size of the tiles
setMethod("getTileSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$tileSize
})
#' @export
setGeneric("getChunkSize", function(object) standardGeneric("getChunkSize"))
#' @describeIn GenoGAMDataSet The size of the chunks
setMethod("getChunkSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$chunkSize
})
#' @export
setGeneric("getOverhangSize", function(object) standardGeneric("getOverhangSize"))
#' @describeIn GenoGAMDataSet The size of the overhang (on one side)
setMethod("getOverhangSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$overhangSize
})
#' @export
setGeneric("getTileNumber", function(object) standardGeneric("getTileNumber"))
#' @describeIn GenoGAMDataSet The total number of tiles
setMethod("getTileNumber", "GenoGAMDataSet", function(object) {
tileSettings(object)$numTiles
})
#' @describeIn GenoGAMDataSet A boolean function that is true if object uses HDF5 backend
setMethod("is.HDF5", signature(object = "GenoGAMDataSet"), function(object) {
res <- slot(object, "hdf5")
return(res)
})
#' @describeIn GenoGAMDataSet Access to the design slot.
setMethod("design", "GenoGAMDataSet", function(object) {
slot(object, "design")
})
#' @describeIn GenoGAMDataSet Replace method of the design slot.
setReplaceMethod("design", "GenoGAMDataSet", function(object, value) {
newCols <- as.vector(na.omit(.getVars(value)))
if(!all(newCols %in% colnames(colData(object)))) {
futile.logger::flog.error("'by' variables could not be found in colData")
stop("'by' variables could not be found in colData")
}
slot(object, "design") <- value
return(object)
})
#' @describeIn GenoGAMDataSet Access to the sizeFactors slot
setMethod("sizeFactors", "GenoGAMDataSet", function(object) {
sf <- slot(object, "sizeFactors")
names(sf) <- colnames(object)
return(sf)
})
#' @describeIn GenoGAMDataSet Replace method of the sizeFactors slot
setReplaceMethod("sizeFactors", "GenoGAMDataSet", function(object, value) {
slot(object, "sizeFactors") <- value
return(object)
})
## change Settings
## ===============
#' @export
setGeneric("getChunkSize<-", function(object, value) standardGeneric("getChunkSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the chunkSize parameter,
#' that triggers a new computation of the tiles based on the new chunk size.
setReplaceMethod("getChunkSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$chunkSize <- value
settings$tileSize <- value + 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getTileSize<-", function(object, value) standardGeneric("getTileSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the tileSize parameter,
#' that triggers a new computation of the tiles based on the new tile size.
setReplaceMethod("getTileSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$tileSize <- value
settings$chunkSize <- value - 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getOverhangSize<-", function(object, value) standardGeneric("getOverhangSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the overhangSize parameter,
#' that triggers a new computation of the tiles based on the new overhang size.
setReplaceMethod("getOverhangSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$overhangSize <- value
settings$tileSize <- settings$chunkSize + 2*value
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getTileNumber<-", function(object, value) standardGeneric("getTileNumber<-"))
#' @describeIn GenoGAMDataSet Replace method of the tileNumber parameter,
#' that triggers a new computation of the tiles based on the new number of tiles.
setReplaceMethod("getTileNumber", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
size <- min(width(settings$chromosomes))
if(size > sum(width(dataRange(object)))) {
warning("The settings indicated a longer total genome size than actually present. it was trimmed accordingly.")
size <- sum(width(dataRange(object)))
}
settings$chunkSize <- round(size/value)
settings$tileSize <- value + 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
## Subsetting
## ==========
#' Subset methods for GenoGAMDataSet
#'
#' @details
#' Those are various methods to subset the GenoGAMDataSet object.
#' By logical statement or GRanges overlap. The '[' subsetter is
#' just a short version of 'subsetByOverlaps'.
#'
#' @param x A GenoGAMDataSet object.
#' @param ranges,i A GRanges object. In case of subsetting by double brackets
#' 'i' is the index of the tile.
#' @param maxgap,minoverlap Intervals with a separation of 'maxgap' or
#' less and a minimum of 'minoverlap' overlapping positions, allowing for
#' 'maxgap', are considered to be overlapping. 'maxgap' should
#' be a scalar, non-negative, integer. 'minoverlap' should be a scalar,
#' positive integer.
#' @param type By default, any overlap is accepted. By specifying the 'type'
#' parameter, one can select for specific types of overlap. The types correspond
#' to operations in Allen's Interval Algebra (see references in). If \code{type}
#' is \code{start} or \code{end}, the intervals are required to have matching
#' starts or ends, respectively. While this operation seems trivial, the naive
#' implementation using \code{outer} would be much less efficient. Specifying
#' \code{equal} as the type returns the intersection of the \code{start} and
#' \code{end} matches. If \code{type} is \code{within}, the query interval must
#' be wholly contained within the subject interval. Note that all matches must
#' additionally satisfy the \code{minoverlap} constraint described above.
#'
#' The \code{maxgap} parameter has special meaning with the special
#' overlap types. For \code{start}, \code{end}, and \code{equal}, it specifies
#' the maximum difference in the starts, ends or both, respectively. For
#' \code{within}, it is the maximum amount by which the query may be wider
#' than the subject.
#' @param invert If TRUE, keep only the query ranges that do _not_ overlap
#' the subject.
#' @param ... Further arguments. Mostly a logical statement
#' in case of the 'subset' function. Note that the columnnames
#' for chromosomes and positions are: 'seqnames' and 'pos'.
#' @examples
#'
#' # subset by overlaps
#' ggd <- makeTestGenoGAMDataSet()
#' SummarizedExperiment::rowRanges(ggd)
#' gr <- GenomicRanges::GRanges("chrI", IRanges(10000,19000))
#' res <- IRanges::subsetByOverlaps(ggd, gr)
#' SummarizedExperiment::rowRanges(res)
#'
#' # Subset by logical statement
#' ggd <- makeTestGenoGAMDataSet()
#' SummarizedExperiment::rowRanges(ggd)
#' res <- subset(ggd, seqnames == "chrI" & pos <= 17000)
#' SummarizedExperiment::rowRanges(res)
#' @references
#' Allen's Interval Algebra: James F. Allen: Maintaining knowledge
#' about temporal intervals. In: Communications of the ACM.
#' 26/11/1983. ACM Press. S. 832-843, ISSN 0001-0782
#' @return A subsetted GenoGAMDataSet object.
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @rdname GenoGAMDataSet-subsetting
setMethod("subset", "GenoGAMDataSet", function(x, ...) {
if(all(dim(x) == c(0, 0))) return(x)
settings <- slot(x, "settings")
design <- design(x)
sf <- sizeFactors(x)
se <- subset(SummarizedExperiment(assays = assays(x),
rowRanges = rowRanges(x),
colData = colData(x)), ...)
if(any(dim(se) == 0)) {
index <- GenomicRanges::GRanges()
}
else {
GenomeInfoDb::seqlevels(rowRanges(se), pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(rowRanges(se))
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(se)
index <- .subsetIndex(se, getIndex(x))
}
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = index)
return(ggd)
})
#' Method to subset the index of GenoGAMDataSet
#'
#' Subsetting the indeces of GenoGAMDataSet based on a SummarizedExperiment.
#'
#' @param x A SummarizedExperiment object.
#' @param index The index of the GenoGAMDataSet object to be subsetted.
#' @return A GRanges object representing the index
#' @noRd
.subsetIndex <- function(se, index) {
res <- NULL
if(is(se, "RangedSummarizedExperiment")) {
res <- .subsetIndexGGD(se, index)
}
if(is(se, "list")) {
res <- .subsetIndexGGDL(se, index)
}
return(res)
}
.subsetIndexGGD <- function(se, index) {
gpCoords <- .extractGR(rowRanges(se))
l <- S4Vectors::metadata(index)
l$chromosomes <- gpCoords
minWidth <- min(width(gpCoords))
if(minWidth < l$tileSize) {
l$tileSize <- minWidth
l$chunkSize <- minWidth - 2*l$overhangSize
}
indx <- .makeTiles(l)
GenomeInfoDb::seqinfo(indx) <- GenomeInfoDb::seqinfo(gpCoords)
return(indx)
}
.subsetByOverlapsGGD <- function(query, subject, maxgap = -1L, minoverlap = 0L,
type = c("any", "start", "end", "within", "equal"),
invert = FALSE, ...) {
if(any((width(subject) %% 2) == 1)) {
futile.logger::flog.info("Some subset ranges have odd widths. Rounding to the next even number.")
idx <- which((width(subject) %% 2) == 1)
width(subject)[idx] <- width(subject)[idx] + 1
}
settings <- slot(query, "settings")
design <- design(query)
sf <- sizeFactors(query)
se <- SummarizedExperiment(assays = assays(query),
rowRanges = rowRanges(query),
colData = colData(query))
subse <- subsetByOverlaps(se, subject, maxgap = maxgap,
minoverlap = minoverlap,
type=type, invert = invert, ...)
if(any(dim(subse) == 0)) {
index <- GenomicRanges::GRanges()
}
else {
GenomeInfoDb::seqlevels(rowRanges(subse), pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(rowRanges(subse))
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(subse)
index <- .subsetIndex(subse, getIndex(query))
}
ggd <- new("GenoGAMDataSet", subse, settings = settings,
design = design, sizeFactors = sf, index = index)
return(ggd)
}
#' @rdname GenoGAMDataSet-subsetting
setMethod("subsetByOverlaps", signature(x = "GenoGAMDataSet", ranges = "GRanges"),
function(x, ranges, maxgap = -1L, minoverlap = 0L,
type = c("any", "start", "end", "within", "equal"),
invert = FALSE, ...) {
type <- match.arg(type)
if(type == "any") {
maxgap <- -1L
minoverlap <- 0L
}
res <- .subsetByOverlapsGGD(query = x, subject = ranges,
maxgap = maxgap, minoverlap = minoverlap,
type = type, invert = invert)
return(res)
})
#' @rdname GenoGAMDataSet-subsetting
setMethod("[", c("GenoGAMDataSet", "GRanges"), function(x, i) {
ggd <- subsetByOverlaps(x, i)
return(ggd)
})
## #' @rdname GenoGAMDataSet-subsetting
## setMethod("[[", c("GenoGAMDataSet", "numeric"), function(x, i) {
## gr <- getIndex(x)[i]
## ggd <- subsetByOverlaps(x,gr)
## return(ggd)
## })
## Tile computation
## ================
#' Function to retrieve the row coordinates as a list
#' @param x The GenoGAMDataSet object
#' @return An integerList with the row numbers for each tile
#' @noRd
.getCoordinates <- function(x) {
l <- NULL
if(is(x,"GenoGAMDataSet")) {
l <- .getCoordinatesGGD(x)
}
if(is(x, "GenoGAMDataSetList")) {
l <- .getCoordinatesGGDL(x)
}
return(l)
}
#' Function to retrieve the row coordinates
#' @param x The GenoGAMDataSet object
#' @return A Coordinates object specifying the row coordinates
#' of each tile
#' @noRd
.getCoordinatesGGD <- function(x) {
## if genome is complete use the fast Bioconductor function
totalLen <- sum(as.numeric(GenomeInfoDb::seqlengths(x)))
if(totalLen == length(x)) {
l <- .absRanges(x)
}
## otherwise the slower version 'by bloc
else {
ov <- IRanges::findOverlaps(rowRanges(x), getIndex(x))
sh <- S4Vectors::subjectHits(ov)
qh <- S4Vectors::queryHits(ov)
l <- range(IRanges::splitAsList(qh, sh))
l <- Coordinates(l[,1], l[,2])
}
return(l)
}
#' Function to establish chunk coordinates
#' @param x An Coordinates object as the output of .getCoordinates
#' @return The same object as x but with not overlapping ranges
#' which were cut at the center of the overhang
#' @noRd
.getChunkCoords <- function(x) {
if(length(x) == 0) {
return(x)
}
start <- c(start(x[1,]), ceiling((end(x[-length(x),]) + start(x[-1,]))/2))
end <- c((start[-1] - 1), end(x[length(x),]))
ir <- Coordinates(start, end)
return(ir)
}
#' compute metrics for each tile
#' @param x The GenoGAMDataSet object
#' @param what A character naming the metric
#' @param na.rm Should NAs be ignored
#' @return The metric value
#' @noRd
.MetricsFun <- function(x, what, na.rm = FALSE) {
res <- NULL
if(is(x, "GenoGAMDataSet")) {
res <- .MetricsFunGGD(x, what, na.rm = na.rm)
}
if(is(x, "GenoGAMDataSetList")) {
res <- .MetricsFunGGDL(x, what, na.rm = na.rm)
}
return(res)
}
#' compute metrics for each tile
#' @param x The GenoGAMDataSet object
#' @param what A character naming the metric
#' @param na.rm Should NAs be ignored
#' @return The metric value
#' @noRd
.MetricsFunGGD <- function(x, what, na.rm = FALSE) {
l <- as(.getCoordinates(x), "IRanges")
## for HDF5
if(slot(x, "hdf5")) {
res <- sapply(1:dim(x)[2], function(ii) {
df <- assay(x)[,ii]
rleDF <- as(df, "DataFrame")
rle <- IRanges::extractList(rleDF[,1], l)
eval(call(what, rle, na.rm = na.rm))
})
}
else { ## Otherwise
res <- sapply(colnames(x), function(y) {
rle <- IRanges::extractList(assay(x)[[y]], l)
eval(call(what, rle, na.rm = na.rm))
})
}
if(!is(res, "matrix")) {
if(is(res, "list") & is.null(dim(res))) {
res <- matrix()
}
else {
res <- t(matrix(res))
}
}
colnames(res) <- colnames(x)
rownames(res) <- getIndex(x)$id
return(res)
}
#' Computing metrics
#'
#' Computing metrics on each tile of the GenoGAMDataSet object.
#' All metrics from the Summary generics group, as well as
#' mean, var, sd, median, mad and IQR are supported.
#'
#' @param x A GenoGAMDataSet object
#' @param ... Additional arguments
#' @param na.rm Should NAs be dropped. Otherwise the result is NA
#' @return A matrix with the specified metric computed per tile per column
#' of the assay data.
#' @examples
#' ggd <- makeTestGenoGAMDataSet()
#' sum(ggd)
#' min(ggd)
#' max(ggd)
#' mean(ggd)
#' var(ggd)
#' sd(ggd)
#' median(ggd)
#' mad(ggd)
#' IQR(ggd)
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @rdname GenoGAMDataSet-metrics
setMethod("Summary", "GenoGAMDataSet", function(x, ..., na.rm = FALSE) {
l <- as(.getCoordinates(x), "IRanges")
## for HDF5
if(slot(x, "hdf5")) {
res <- sapply(1:dim(x)[2], function(ii) {
df <- assay(x)[,ii]
rleDF <- as(df, "DataFrame")
rle <- IRanges::extractList(rleDF[,1], l)
(getFunction(.Generic))(rle, na.rm = na.rm)
})
}
else { ## Otherwise
res <- sapply(colnames(x), function(y) {
rle <- IRanges::extractList(assay(x)[[y]], l)
(getFunction(.Generic))(rle, na.rm = na.rm)
})
}
if(!is(res, "matrix")) {
if(is(res, "list") & is.null(dim(res))) {
res <- matrix()
}
else {
res <- t(matrix(res))
}
}
colnames(res) <- colnames(x)
rownames(res) <- getIndex(x)$id
return(res)
})
#' @rdname GenoGAMDataSet-metrics
setMethod("mean", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "mean")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("var", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "var")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("sd", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "sd")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("median", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "median")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("mad", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "mad")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("IQR", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "IQR")
})
## Cosmetics
## =========
.showGenoGAMDataSet <- function(object) {
cl <- class(object)
dims <- dim(object)
md <- unique(names(colData(object)))
cnames <- colnames(object)
cdata <- names(colData(object))
sf <- sizeFactors(object)
form <- design(object)
if(length(tileSettings(object)) != 0) {
tsize <- tileSettings(object)$tileSize
tname <- "tiles"
unit <- ""
if(!is.null(tsize)) {
unit = "bp"
if(tsize/1000 > 1) {
unit <- "kbp"
tsize <- tsize/1000
}
if(tsize/1e6 > 1) {
unit <- "Mbp"
tsize <- tsize/1e6
}
}
chroms <- GenomeInfoDb::seqlevels(tileSettings(object)$chromosomes)
}
tnum <- length(getIndex(object))
cat("class:", cl, "\n")
cat("dimension:", dims, "\n")
cat(paste0("samples(", length(cnames), "):"), cnames, "\n")
cat(paste0("design variables(", length(md), "):"), md, "\n")
if(length(tileSettings(object)) != 0) {
cat(paste0(tname, " size: ", tsize, unit), "\n")
cat(paste0("number of ", tname, ": ", tnum), "\n")
cat("chromosomes:", chroms, "\n")
}
cat("size factors:\n")
show(sf)
cat("formula:\n")
cat(paste(as.character(form), collapse = " "), "\n")
}
## Show method for GenomicTiles.
setMethod("show", "GenoGAMDataSet", function(object) {
.showGenoGAMDataSet(object)
})
gstricker/fastGenoGAM documentation built on May 17, 2019, 8:56 a.m.
R Package Documentation
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## ====================
## GenoGAMDataset class
## ====================
#' @include GenoGAMSettings-class.R
#' @include GenoGAM-class.R
NULL
setClassUnion("HDF5OrMatrix", c("matrix", "HDF5Matrix"))
#' GenoGAMDataSet
#'
#' The GenoGAMDataSet class contains the pre-processed raw data and
#' additional slots that define the input and framework for the model.
#' It extends the RangedSummarizedExperiment class by adding an index
#' that defines ranges on the entire genome, mostly for purposes of
#' parallel evaluation. Furthermore adding a couple more slots to hold
#' information such as experiment design. It also contains the
#' \code{\link[fastGenoGAM]{GenoGAMSettings}} class that defines global
#' settings for the session. For information on the slots inherited from
#' SummarizedExperiment check the respective class.
#'
#' @slot settings The global and local settings that will be used to compute the
#' model.
#' @slot design The formula describing how to evaluate the data. See details.
#' @slot sizeFactors The normalized values for each sample. A named numeric vector.
#' @slot index A GRanges object representing an index of the ranges defined
#' on the genome. Mostly used to store tiles.
#' @slot hdf5 A logical slot indicating if the object should be stored as HDF5
#' @slot countMatrix Either a matrix or HDF5Matrix to store the sums of counts of
#' the regions (could also be seen as bins) for later use especially by DESeq2
#' @name GenoGAMDataSet-class
#' @rdname GenoGAMDataSet-class
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @exportClass GenoGAMDataSet
setClass("GenoGAMDataSet",
contains = "RangedSummarizedExperiment",
slots = list(settings = "GenoGAMSettings",
design = "formula", sizeFactors = "numeric",
hdf5 = "logical", index = "GRanges", countMatrix = "HDF5OrMatrix"),
prototype = list(settings = GenoGAMSettings(),
design = ~ s(x), sizeFactors = numeric(),
hdf5 = FALSE, index = GenomicRanges::GRanges(),
countMatrix = matrix()))
## Validity
## ========
.validateSettingsType <- function(object) {
if(!is(slot(object, "settings"), "GenoGAMSettings")) {
return("'settings' must be a GenoGAMSettings object")
}
NULL
}
.validateDesignType <- function(object) {
if(!is(slot(object, "design"), "formula")) {
return("'design' must be a formula object")
}
NULL
}
.validateSFType <- function(object) {
if(!is(slot(object, "sizeFactors"), "numeric")) {
return("'sizeFactors' must be a numeric object")
}
NULL
}
## Validating the correct type
.validateIndexType <- function(object) {
if(!is(object@index, "GRanges")) {
return("'index' must be a GRanges object")
}
NULL
}
.validateChromosomes <- function(object) {
cindex <- GenomeInfoDb::seqlevels(object@index)
cobject <- GenomeInfoDb::seqlevels(rowRanges(object))
if(!all(cindex %in% cobject)) {
return("Different chromosomes for data and index objects.")
}
NULL
}
## Validating the correct type
.validateCountMatrixType <- function(object) {
if(!is(object@countMatrix, "matrix") & !is(object@countMatrix, "HDF5Matrix")) {
return("'countMatrix' must be either a matrix or HDF5Matrix object")
}
NULL
}
.validateH5Type <- function(object) {
if(!is(object@hdf5, "logical")) {
return("'hdf5' must be a logical object")
}
NULL
}
## general validate function
.validateGenoGAMDataSet <- function(object) {
c(.validateSettingsType(object), .validateDesignType(object),
.validateSFType(object), .validateIndexType(object),
.validateChromosomes(object), .validateCountMatrixType(object),
.validateH5Type(object))
}
S4Vectors::setValidity2("GenoGAMDataSet", .validateGenoGAMDataSet)
## Constructor
## ===========
#' GenoGAMDataSet constructor.
#'
#' GenoGAMDataSet is the constructor function for the GenoGAMDataSet-class.
#'
#' @aliases getIndex tileSettings dataRange getChromosomes getTileSize getChunkSize getOverhangSize getTileNumber
#' getChunkSize<- getTileSize<- getOverhangSize<- getTileNumber<-
#' @param experimentDesign Either a character object specifying the path to a
#' delimited text file (the delimiter will be determined automatically),
#' a data.frame specifying the experiment design or a RangedSummarizedExperiment
#' object with the GPos class being the rowRanges. See details for the structure
#' of the experimentDesign.
#' @param chunkSize An integer specifying the size of one chunk in bp.
#' @param overhangSize An integer specifying the size of the overhang in bp.
#' As the overhang is taken to be symmetrical, only the overhang of one side
#' should be provided.
#' @param design A formula object. See details for its structure.
#' @param directory The directory from which to read the data. By default
#' the current working directory is taken.
#' @param settings A GenoGAMSettings object. Not needed by default, but might
#' be of use if only specific regions should be read in.
#' See \code{\link{GenoGAMSettings}}.
#' @param hdf5 Should the data be stored on HDD in HDF5 format? By default this
#' is disabled, as the Rle representation of count data already provides a
#' decent compression of the data. However in case of large organisms, a complex
#' experiment design or just limited memory, this might further decrease the
#' memory footprint. Note this only applies to the input count data, results are
#' usually stored in HDF5 format due to their space requirements for type double.
#' Exceptions are small organisms like yeast.
#' @param split A logical argument specifying if the data should be stored as
#' a list split by chromosome. This is useful and necessary for huge organisms like
#' human, as R does not support long integers.
#' @param fromHDF5 A logical argument specifying if the data is already present in
#' form of HDF5 files and should be rather read in from there.
#' @param ignoreM A logical argument to ignore the Mitochondria DNA on data read in.
#' This is useful, if one is not interested in chrM, but it's size prevents the tiles
#' to be larger, as all tiles has to be of some size.
#' @param ... Further parameters, mostly for arguments of custom processing
#' functions or to specify a different method for fragment size estimation.
#' See details for further information.
#' @param object For use of S4 methods. The GenoGAMDataSet object.
#' @param value For use of S4 methods. The value to be assigned to the slot.
#' @return An object of class \code{\link{GenoGAMDataSet}} or the respective slot.
#' @section Config:
#'
#' The config file/data.frame contains the actual experiment design. It must
#' contain at least three columns with fixed names: 'ID', 'file' and 'paired'.
#'
#' The field 'ID' stores a unique identifier for each alignment file.
#' It is recommended to use short and easy to understand identifiers because
#' they are subsequently used for labelling data and plots.
#'
#' The field 'file' stores the BAM file name.
#'
#' The field 'paired', values TRUE for paired-end sequencing data, and FALSE for
#' single-end sequencing data.
#'
#' All other columns are stored in the colData slot of the GenoGAMDataSet
#' object. Note that all columns which will be used for analysis must have at
#' most two conditions, which are for now restricted to 0 and 1. For example,
#' if the IP data schould be corrected for input, then the input will be 0
#' and IP will be 1, since we are interested in the corrected IP. See examples.
#'
#' @section Design/Formula:
#'
#' Design must be a formula. At the moment only the following is
#' possible: Either ~ s(x) for a smooth fit over the entire data or
#' s(x, by = myColumn), where 'myColumn' is a column name
#' in the experimentDesign. Any combination of this is possible:
#'
#' ~ s(x) + s(x, by = myColumn) + s(x, by = ...) + ...
#'
#' For example the formula for correcting IP for input would look like this:
#'
#' ~ s(x) + s(x, by = experiment)
#'
#' where 'experiment' is a column with 0s and 1s, with the ip samples annotated
#' with 1 and input samples with 0.
#''
#' @section Further parameters:
#'
#' In case of single-end data it might be usefull to specify a different
#' method for fragment size estimation. The argument 'shiftMethod' can be
#' supplied with the values 'coverage' (default), 'correlation' or 'SISSR'.
#' See ?chipseq::estimate.mean.fraglen for explanation.
#' @examples
#' # Build from config file
#'
#' config <- system.file("extdata/Set1", "experimentDesign.txt", package = "fastGenoGAM")
#' dir <- system.file("extdata/Set1/bam", package = "fastGenoGAM")
#'
#' ## For all data
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir)
#' ggd
#'
#' ## Read data of a particular chromosome
#' settings <- GenoGAMSettings(chromosomeList = "chrXIV")
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' ## Read data of particular range
#' region <- GenomicRanges::GRanges("chrI", IRanges(10000, 15000))
#' params <- Rsamtools::ScanBamParam(which = region)
#' settings <- GenoGAMSettings(bamParams = params)
#' ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' # Build from data.frame config
#'
#' df <- read.table(config, header = TRUE, sep = '\t')
#' ggd <- GenoGAMDataSet(df, chunkSize = 1000, overhangSize = 200,
#' design = ~ s(x) + s(x, by = genotype), directory = dir,
#' settings = settings)
#' ggd
#'
#' # Build from SummarizedExperiment
#'
#' gr <- GenomicRanges::GPos(GRanges("chr1", IRanges(1, 10000)))
#' seqlengths(gr) <- 1e6
#' df <- S4Vectors::DataFrame(colA = 1:10000, colB = round(runif(10000)))
#' se <- SummarizedExperiment::SummarizedExperiment(rowRanges = gr, assays = list(df))
#' ggd <- GenoGAMDataSet(se, chunkSize = 2000, overhangSize = 250,
#' design = ~ s(x) + s(x, by = experiment))
#' ggd
#' @name GenoGAMDataSet
#' @rdname GenoGAMDataSet-class
#' @export
GenoGAMDataSet <- function(experimentDesign, design, chunkSize = NULL, overhangSize = NULL,
directory = ".", settings = NULL, hdf5 = FALSE, split = hdf5,
fromHDF5 = FALSE, ignoreM = FALSE, ...) {
if(missing(experimentDesign)) {
futile.logger::flog.debug("No input provided. Creating empty GenoGAMDataSet")
return(new("GenoGAMDataSet"))
}
futile.logger::flog.info("Creating GenoGAMDataSet")
if(is.null(settings)) {
settings <- GenoGAMSettings()
}
## optimal chunk size
if(is.null(chunkSize)) {
## need initial overhangsize if null to compute chunk size
ov <- ifelse(is.null(overhangSize), 1000, overhangSize)
bpknots <- slot(settings, "dataControl")$bpknots
chunkSize <- .setOptimalChunkSize(experimentDesign, design, ov, bpknots, hdf5)
}
if(is.null(overhangSize)) {
## overhang size not bigger than half of the chunk
overhangSize <- min(1000, chunkSize/2 - 1)
}
if(overhangSize >= chunkSize/2) {
overhangSize <- round(chunkSize/2) - 1
warning("Overhang size exceeds the total size of the chunk. Adjusted to chunkSize/2 - 1")
}
input <- paste0("Building GenoGAMDataSet with the following parameters:\n",
" Class of experimentDesign: ", class(experimentDesign), "\n",
" Chunk size: ", chunkSize, "\n",
" Overhang size: ", overhangSize, "\n",
" Design: ", paste(as.character(design, collapse= " ")), "\n",
" Directory: ", directory, "\n",
" HDF5: ", hdf5, "\n",
" Split: ", split, "\n",
" Specific Settings: ",
" From HDF5: ", fromHDF5, "\n")
futile.logger::flog.debug(input)
futile.logger::flog.debug(show(settings))
futile.logger::flog.debug(show(list(...)))
if(fromHDF5) {
futile.logger::flog.debug(paste0("Building GenoGAMDataSet from HDF5: ", settings@hdf5Control$dir))
ggd <- .GenoGAMDataSetFromHDF5(config = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
directory = directory,
settings = settings,
split = split,
ignoreM = ignoreM, ...)
}
else {
if(is(experimentDesign, "RangedSummarizedExperiment") |
is(experimentDesign, "SummarizedExperiment")) {
futile.logger::flog.debug("Building GenoGAMDataSet from SummarizedExperiment object")
ggd <- .GenoGAMDataSetFromSE(se = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
settings = settings,
hdf5 = hdf5, ...)
}
else {
futile.logger::flog.debug(paste0("Building GenoGAMDataSet from config file: ", experimentDesign))
ggd <- .GenoGAMDataSetFromConfig(config = experimentDesign,
chunkSize = chunkSize,
overhangSize = overhangSize,
design = design,
directory = directory,
settings = settings,
hdf5 = hdf5,
split = split, ignoreM = ignoreM, ...)
}
}
futile.logger::flog.info("GenoGAMDataSet created")
return(ggd)
}
## The underlying function to build a GenoGAMDataSet from a
## SummarizedExperiment
.GenoGAMDataSetFromSE <- function(se, chunkSize, overhangSize,
design, settings, hdf5, ...) {
gr <- .extractGR(rowRanges(se))
## check for overlapping ranges
if(sum(countOverlaps(gr)) > length(gr)) {
stop("Overlapping regions encountered. Please reduce ranges and data first.")
}
if(any(is.na(seqlengths(se)))) {
stop("Sequence lengths missing in the Seqinfo object of SummarizedExperiment")
}
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## initiate size factors
sf <- rep(0, length(colnames(se)))
##names(sf) <- colnames(se)
## initialize sumMatrix on hdf5 if needed
if(hdf5) {
## make tiles for sum matrix storage
suml <- list(chromosomes = gr,
chunkSize = slot(settings, "dataControl")$regionSize,
overhangSize = min(overhangSize, slot(settings, "dataControl")$regionSize - 1))
sumTiles <- .makeTiles(suml)
d <- c(length(sumTiles), nrow(colData(se)))
chunk <- c(1, nrow(colData(se)))
h5SumMatrix <- .createH5DF("sumMatrix", settings, d, chunk, what = "sumMatrix")
}
else {
h5SumMatrix <- NULL
}
## update chromosome list
if(is.null(slot(settings, "chromosomeList"))) {
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
}
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = hdf5)
## compute sum matrix
## backup original tile index
index_backup <- getIndex(ggd)
## make new tile index
metadata(slot(ggd, "index"))$chunkSize <- slot(settings, "dataControl")$regionSize
newTiles <- .makeTiles(tileSettings(ggd))
slot(ggd, "index") <- newTiles
## compute the matrix
sumMatrix <- sum(ggd)
slot(ggd, "countMatrix") <- sumMatrix
## set tiles back to original
slot(ggd, "index") <- index_backup
## write to hdf5 if necessary
if(hdf5){
## write assay to HDF5 and substitute
coords <- .getCoordinates(ggd)
chunks <- .getChunkCoords(coords)
h5df <- .writeToHDF5(assay(se), file = "dataset", chunks = as(chunks, "IRanges"),
settings = settings)
assays(ggd) <- list(h5df)
## write sumMatrix to HDF5 and substitute
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "sumMatrix")
h5sm <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
slot(ggd, "countMatrix") <- h5sm
}
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
#' A function to produce a GRanges index from a list of settings.
#'
#' @param l A list of settings involving:
#' chunkSize, chromosomes, tileSize and overhangSize
#' @return A GRanges object of the tiles.
#'
#' @noRd
.makeTiles <- function(l) {
if(length(l) == 0) return(GenomicRanges::GRanges())
if(l$overhangSize < 0) stop("Overhang size must be equal or greater than 0")
if(length(l$chromosomes) == 0) stop("Chromosome list should contain at least one entry")
## tiles should be not bigger than any pre-specified region
l$tileSize <- min(l$chunkSize + 2*l$overhangSize, min(width(l$chromosomes)))
## adjust chunks and overhang accordingly
l$chunkSize <- l$tileSize - 2*l$overhangSize
if(l$chunkSize <= 0) stop("Tile size must be greater than twice the overhang size. Check your chromosome lengths. Your smallest chromosome might be smaller than 2 * overhangSize")
input <- paste0("Building Tiles with the following parameters:\n",
" Chunk size: ", l$chunkSize, "\n",
" Overhang size: ", l$overhangSize, "\n",
" Chromosomes: \n")
futile.logger::flog.debug(input)
futile.logger::flog.debug(show(l$chromosomes))
futile.logger::flog.debug(paste0("GenoGAMDataSet: Tile size computed to be ", l$tileSize))
## deal with overlapping ranges to reduce complexity and redundancy
l$chromosomes <- GenomicRanges::reduce(l$chromosomes)
.local <- function(id, sl, chromList) {
y <- chromList[id,]
## load package for SnowParam or BatchJobs backend
suppressPackageStartupMessages(require(fastGenoGAM, quietly = TRUE))
## generate break points for chunks
nchunks <- ceiling(IRanges::width(y)/sl$chunkSize)
startSeq <- seq(0, nchunks - 1, length.out = nchunks) * sl$chunkSize
endSeq <- seq(1, nchunks - 1, length.out = (nchunks - 1)) * sl$chunkSize - 1
starts <- IRanges::start(y) + startSeq
ends <- c(IRanges::start(y) + endSeq, IRanges::end(y))
ir <- IRanges::IRanges(starts, ends)
chunks <- GenomicRanges::GRanges(seqnames = GenomeInfoDb::seqnames(y), ir)
GenomeInfoDb::seqinfo(chunks) <- GenomeInfoDb::seqinfo(y)
## flank to tiles
if(sl$tileSize == sl$chunkSize) {
tiles <- chunks
}
else {
ov <- round(IRanges::width(chunks)/2)
## shift to center to get a point to flank from
centeredChunks <- suppressWarnings(IRanges::shift(chunks, ov))
## flank to get tiles
ir <- suppressWarnings(IRanges::flank(centeredChunks,
round(sl$tileSize/2),
both = TRUE))
## trim tiles if overhang caused it to go out of bounds
tiles <- suppressWarnings(IRanges::trim(ir))
## remove smaller tiles at the borders that are completely
## contained by bigger tiles
tiles <- tiles[!overlapsAny(tiles, type="within", drop.self=TRUE)]
}
## adjust first tile
startsToResize <- which(IRanges::start(tiles) < IRanges::start(y))
trimmedEnd <- IRanges::end(tiles[startsToResize]) + IRanges::start(y) - IRanges::start(tiles[startsToResize])
IRanges::end(tiles[startsToResize]) <- min(trimmedEnd, IRanges::end(y))
IRanges::start(tiles[startsToResize]) <- IRanges::start(y)
## adjust last tile
endsToResize <- which(IRanges::end(tiles) > IRanges::end(y))
trimmedStarts <- IRanges::start(tiles[endsToResize]) - IRanges::end(tiles[endsToResize]) + IRanges::end(y)
IRanges::start(tiles[endsToResize]) <- max(trimmedStarts, IRanges::start(y))
IRanges::end(tiles[endsToResize]) <- IRanges::end(y)
## remove duplicate tiles if present
tiles <- unique(tiles)
return(tiles)
}
## run local function
tileList <- BiocParallel::bplapply(1:length(l$chromosomes), .local, sl = l, chromList = l$chromosomes)
## concatenate results into one list
tiles <- do.call("c", tileList)
GenomeInfoDb::seqlengths(tiles) <- GenomeInfoDb::seqlengths(l$chromosomes)
GenomeInfoDb::seqlevels(tiles, pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(tiles)
## resize start and end tiles till correct tile size is reached
## find tiles that are at the start of the regions of interest
startPos <- GRanges(seqnames(l$chromosomes), IRanges(start(l$chromosomes), start(l$chromosomes)))
isStart <- logical(length(tiles))
isStart[queryHits(findOverlaps(tiles, startPos))] <- TRUE
startsToResize <- which(width(tiles) < l$tileSize & isStart)
suppressWarnings(tiles[startsToResize] <- resize(tiles[startsToResize], width = l$tileSize))
endsToResize <- which(width(tiles) < l$tileSize)
suppressWarnings(tiles[endsToResize] <- resize(tiles[endsToResize], width = l$tileSize, fix = "end"))
tiles <- IRanges::trim(tiles)
## remove duplicate tiles if present
tiles <- unique(tiles)
## add 'id' column, check element and put settings in metadata
S4Vectors::mcols(tiles)$id <- 1:length(tiles)
l$numTiles <- length(tiles)
futile.logger::flog.debug(paste0("GenoGAMDataSet: Data split into ", l$numTiles, " tiles"))
l$check <- TRUE
S4Vectors::metadata(tiles) <- l
return(tiles)
}
## set optimal chunk length if not provided
## based on number of cores, samples, splines and
## in case of HDF5, the block size
.setOptimalChunkSize <- function(expDesign, design, ov, bpknots, hdf5) {
## determine number of samples
if(is(expDesign, "RangedSummarizedExperiment")) {
nsamples <- nrow(colData(expDesign))
}
else {
if(is(expDesign, "data.frame")) {
nsamples <- nrow(expDesign)
}
else {
nsamples <- count.fields(expDesign)[1]
}
}
## if(hdf5) {
## maxBlockSize <- DelayedArray:::get_max_block_length("integer")
## tileSize <- floor(maxBlockSize/nsamples)
## chunkSize <- tileSize - 2*ov
## }
## else {
## workers <- BiocParallel::registered()[[1]]$workers
## maximal chunk size to work with and use only 1GB per core
posPerGB <- 8000000L / bpknots
## we don't want to exceed this number of GByte per core
GBlimit <- 4L
## number of splines
nsplines <- length(.getVars(design))
## chunkSize <- (workers * posPerGB * GBlimit) / (nsamples * nsplines)
chunkSize <- (posPerGB * GBlimit) / (nsamples * nsplines)
## }
return(chunkSize)
}
## make the 'by' argument for the 'makeSumMatrix' function
.makeBy <- function(x, from) {
rr <- range(from)
if(length(rr) == 1 &
IRanges::start(rr) == 1 &
IRanges::end(rr) == max(GenomicRanges::pos(x)))
{
return(ranges(from))
}
ovRanges <- IRanges::findOverlaps(x, from)
res <- sapply(unique(S4Vectors::subjectHits(ovRanges)), function(y) {
qh <- S4Vectors::queryHits(ovRanges)[S4Vectors::subjectHits(ovRanges) == y]
IRanges::IRanges(min(qh), max(qh))
})
return(do.call("c", res))
}
## make sum matrix for each DataFrame
.makeSumMatrix <- function(x, by) {
cols <- names(x)
res <- sapply(cols, function(y) {
## extract cuts. Because of overlaps the data will be partly replicated
## and thus increase in row dimension. It is important to
## compute further things on the 'stretched' data
rle <- IRanges::extractList(x[,y], by)
values <- cumsum(rle@unlistData)
sums <- values[end(rle@partitioning)]
## keep first values and change the rest to the differences
if(length(sums) > 1) {
sums[2:length(sums)] <- diff(sums)
}
return(as.integer(sums))
})
return(res)
}
## get the identifier of the HDF5 files, that belong together to one dataset
.getIdentifier <- function(path, fits = FALSE) {
identPos <- 2
if(fits) identPos <- 3
files <- list.files(path)
splitFiles <- strsplit(files, "_")
## check the second element of the split name, which should be the
## identifier (and the creation date). Discard invalid files (which give NA)
## and in case of multiple identifiers select the first.
possibleIdentifiers <- unique(na.omit(sapply(splitFiles, function(y) y[identPos])))
return(possibleIdentifiers[1])
}
#' Convert the config columns to the right type.
#'
#' @param config A data.frame with pre-specified columns.
#' @param directory The directory of the files
#' @return The same data.frame with the columns of the right type.
#' @noRd
.normalizeConfig <- function(config, directory) {
if(is(config, "character")) {
config <- data.table::fread(config, header = TRUE, data.table = FALSE)
}
config$ID <- as.factor(config$ID)
config$file <- file.path(directory, as.character(config$file))
config$paired <- as.logical(config$paired)
futile.logger::flog.debug("Using the following config file:")
futile.logger::flog.debug(show(config))
return(config)
}
## a list of names for the Mitochondria chromosome
.mnames <- function() {
c("chrM", "MT", "chromosomeM", "ChromosomeMT", "2micron")
}
## The underlying function to build a GenoGAMDataSet from a
## config file or a data.frame
.GenoGAMDataSetFromConfig <- function(config, chunkSize, overhangSize, design,
directory, settings, hdf5 = FALSE, split = hdf5, ignoreM = FALSE, ...) {
## initialize some variables
args <- list()
## normalize config object
config <- .normalizeConfig(config, directory)
center <- slot(settings, "center")
if(!is.null(center)) {
slot(settings, "processFunction") <- .processCountChunks
}
## get chromosomeLengths to check if a split of data along the chromosomes is necessary
header <- Rsamtools::scanBamHeader(config$file[1])
chroms <- header[[1]]$targets
nsamples <- nrow(config)
totalLength <- sum(as.numeric(chroms))*nsamples
## split if data vectors are to big
if(totalLength > 2^31) {
split <- TRUE
}
## ignore Mito chromosome
if(ignoreM) {
keep <- !(names(chroms) %in% .mnames())
chroms <- chroms[keep]
}
## generate rowRanges
bamParamsWhich <- Rsamtools::bamWhich(slot(settings, "bamParams"))
if(length(bamParamsWhich) != 0) {
gr <- GenomicRanges::GRanges(bamParamsWhich)
lengths <- chroms[GenomeInfoDb::seqlevels(GenomicRanges::GRanges(bamParamsWhich))]
if(all(!is.na(lengths))){
GenomeInfoDb::seqlengths(gr) <- lengths
}
else {
futile.logger::flog.error("The data does not match the region specification in the bamParams settings.")
return(new("GenoGAMDataSet"))
}
}
else {
if(!is.null(slot(settings, "chromosomeList"))) {
chroms <- chroms[names(chroms) %in% slot(settings, "chromosomeList")]
}
starts <- rep(1, length(chroms))
ends <- chroms
gr <- GenomicRanges::GRanges(names(chroms),
IRanges::IRanges(starts, ends))
GenomeInfoDb::seqlengths(gr) <- chroms
}
## update chromosome list
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
if(length(slot(settings, "chromosomeList")) == 0) {
futile.logger::flog.error("No chromosomes to read in. Check either the specified settings or the header of BAM file")
return(new("GenoGAMDataSet"))
}
futile.logger::flog.debug("Following row ranges created:")
futile.logger::flog.debug(show(gr))
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## make tiles for sum matrix computation
suml <- list(chromosomes = gr,
chunkSize = slot(settings, "dataControl")$regionSize,
overhangSize = min(overhangSize, slot(settings, "dataControl")$regionSize - 1))
sumTiles <- .makeTiles(suml)
## make colData
colData <- S4Vectors::DataFrame(config)[,-c(1:3), drop = FALSE]
rownames(colData) <- config$ID
## initiate size factors
sf <- rep(0, nrow(colData))
## initialize sumMatrix on hdf5 if needed
if(hdf5) {
d <- c(length(sumTiles), nrow(colData))
chunk <- c(1, nrow(colData))
h5SumMatrix <- .createH5DF("sumMatrix", settings, d, chunk, what = "sumMatrix")
}
else {
h5SumMatrix <- NULL
}
## final build object
## if split make sure to keep the seqinfo same for all list elements,
## as this will make it easily possible to merge them later if necessary
if(split) {
splitid <- gr
splitid$id <- as.character(GenomeInfoDb::seqnames(splitid))
## backup chromosomeList
chrBackup <- slot(settings, "chromosomeList")
## make queue for sum matrix
qdir <- .init_Queue(h5SumMatrix)
selist <- BiocParallel::bplapply(splitid$id, function(id) {
## read data and make SummarizedExperiment objects
slot(settings, "chromosomeList") <- id
countData <- readData(config, settings = settings, ...)
if(length(countData) == 0) {
return(new("GenoGAMDataSet"))
}
rr <- GenomicRanges::GPos(gr[GenomeInfoDb::seqnames(gr) == id,])
smRanges <- sumTiles[GenomeInfoDb::seqnames(sumTiles) == id]
## make sumMatrix
by <- .makeBy(rr, smRanges)
sumMatrix <- .makeSumMatrix(countData, by)
## make SummarizedExperiment objects and write to HDD if necessary
if(hdf5) {
## make chunks for faster writing
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = 0)
hdf5_tiles <- fastGenoGAM:::.makeTiles(l)
hdf5_ranges <- hdf5_tiles[GenomeInfoDb::seqnames(hdf5_tiles) == id]
## write chromosome data to HDF5
h5df <- .writeToHDF5(countData, file = id, chunks = hdf5_ranges, settings = settings)
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = rr,
assays = list(h5df), colData = colData)
qid <- .queue(qdir)
## wait till it's your turn
while(list.files(qdir)[1] != qid){
Sys.sleep(0.1)
}
## write sum matrix to HDF5
rows <- which(GenomeInfoDb::seqnames(sumTiles) == id)
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "/sumMatrix",
index = list(rows, 1:ncol(sumMatrix)))
## unqueue
.unqueue(qid, qdir)
res <- se
}
else {
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = rr,
assays = list(countData), colData = colData)
res <- list(se = se, sm = sumMatrix)
}
rm(countData)
gc()
return(res)
})
.end_Queue(qdir)
if(hdf5) {
names(selist) <- chrBackup
sumMatrix <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
}
else {
## combine sum matrices to one and
## extract the SummarizedExperiment objects only
sumMatrix <- lapply(selist, function(y) y$sm)
sumMatrix <- do.call("rbind", sumMatrix)
selist <- lapply(selist, function(y) y$se)
names(selist) <- chrBackup
}
## Make new GenoGAMDataSetList object
slot(settings, "chromosomeList") <- chrBackup
ggd <- new("GenoGAMDataSetList", settings = settings,
design = design, sizeFactors = sf, index = tiles,
data = selist, id = splitid, hdf5 = hdf5, countMatrix = sumMatrix)
}
else {
## read data and make SummarizedExperiment objects
countData <- readData(config, settings = settings, ...)
if(length(countData) == 0) {
return(new("GenoGAMDataSet"))
}
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr),
assays = list(countData),
colData = colData)
## first make GenoGAMDataSet object and then compute
## the sum matrix and write to hdf5 if necessary
## this avoids special functions for those particular steps
## only.
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = hdf5)
## compute sum matrix
## backup original tile index
index_backup <- getIndex(ggd)
## set new tiles
slot(ggd, "index") <- sumTiles
## compute the matrix
sumMatrix <- sum(ggd)
slot(ggd, "countMatrix") <- sumMatrix
## set tiles back to original
slot(ggd, "index") <- index_backup
if(hdf5){
## write assay to HDF5 and substitute
coords <- .getCoordinates(ggd)
chunks <- .getChunkCoords(coords)
h5df <- .writeToHDF5(countData, file = "dataset", chunks = as(chunks, "IRanges"),
settings = settings)
assays(ggd) <- list(h5df)
## write sumMatrix to HDF5 and substitute
rhdf5::h5write(sumMatrix, file = h5SumMatrix, name = "sumMatrix")
h5sm <- HDF5Array::HDF5Array(h5SumMatrix, name = "/sumMatrix")
slot(ggd, "countMatrix") <- h5sm
}
}
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
## The underlying function to build a GenoGAMDataSet from an
## already present HDF5 file
.GenoGAMDataSetFromHDF5 <- function(config, chunkSize, overhangSize,
design, directory, settings, split, ignoreM = FALSE, ...) {
## initialize some variables
args <- list()
## normalize config object
config <- .normalizeConfig(config, directory)
## get chromosomeLengths to check if a split of data along the chromosomes is necessary
header <- Rsamtools::scanBamHeader(config$file[1])
chroms <- header[[1]]$targets
## ignore Mito chromosome
if(ignoreM) {
keep <- !(names(chroms) %in% .mnames())
chroms <- chroms[keep]
}
if(!is.null(slot(settings, "chromosomeList"))) {
chroms <- chroms[names(chroms) %in% slot(settings, "chromosomeList")]
}
## generate rowRanges
bamParamsWhich <- Rsamtools::bamWhich(slot(settings, "bamParams"))
if(length(bamParamsWhich) != 0) {
gr <- GenomicRanges::GRanges(bamParamsWhich)
lengths <- chroms[GenomeInfoDb::seqlevels(GenomicRanges::GRanges(bamParamsWhich))]
if(all(!is.na(lengths))){
GenomeInfoDb::seqlengths(gr) <- lengths
}
else {
futile.logger::flog.error("The data does not match the region specification in the bamParams settings.")
return(new("GenoGAMDataSet"))
}
}
else {
starts <- rep(1, length(chroms))
ends <- chroms
gr <- GenomicRanges::GRanges(names(chroms),
IRanges::IRanges(starts, ends))
GenomeInfoDb::seqlengths(gr) <- chroms
}
futile.logger::flog.debug("Following row ranges created:")
futile.logger::flog.debug(show(gr))
## make tiles
l <- list(chromosomes = gr,
chunkSize = chunkSize,
overhangSize = overhangSize)
tiles <- .makeTiles(l)
## make colData
colData <- S4Vectors::DataFrame(config)[,-c(1:3), drop = FALSE]
rownames(colData) <- config$ID
## initiate size factors
sf <- rep(0, nrow(colData))
##names(sf) <- config$ID
## update chromosome list
if(is.null(slot(settings, "chromosomeList"))) {
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(gr)
}
## get Identifier for the data
path <- slot(settings, "hdf5Control")$dir
ident <- .getIdentifier(path)
if(split) {
## finally build object
splitid <- gr
splitid$id <- as.character(GenomeInfoDb::seqnames(splitid))
selist <- lapply(splitid$id, function(id) {
## read HDF5 file
h5file <- file.path(path, paste0(id, "_", ident))
## read HDF5 data and make SummarizedExperiment objects
h5df <- HDF5Array::HDF5Array(h5file, id)
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr[GenomeInfoDb::seqnames(gr) == id,]),
assays = list(h5df), colData = colData)
return(se)
})
names(selist) <- splitid$id
ggd <- new("GenoGAMDataSetList", settings = settings,
design = design, sizeFactors = sf, index = tiles,
data = selist, id = splitid, hdf5 = TRUE)
}
else {
## read HDF5 file
h5file <- file.path(path, paste0("dataset", "_", ident))
## read HDF5 data and make SummarizedExperiment objects
h5df <- HDF5Array::HDF5Array(h5file, "dataset")
se <- SummarizedExperiment::SummarizedExperiment(rowRanges = GenomicRanges::GPos(gr),
assays = list(h5df), colData = colData)
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = tiles,
hdf5 = TRUE)
}
## read sum matrix file
smFile <- file.path(path, paste0("sumMatrix", "_", ident))
sumMatrix <- HDF5Array::HDF5Array(smFile, "sumMatrix")
slot(ggd, "countMatrix") <- sumMatrix
## check if everything was set fine
correct <- checkObject(ggd)
return(ggd)
}
#' Make an example /code{GenoGAMDataSet}
#'
#' @param sim Use simulated data (TRUE) or test data from a real experiment
#' @return A /code{GenoGAMDataSet} object
#' @examples
#' realdt <- makeTestGenoGAMDataSet()
#' simdt <- makeTestGenoGAMDataSet(sim = TRUE)
#' @export
makeTestGenoGAMDataSet <- function(sim = FALSE) {
if(sim) {
k <- 10000
sinCurve <- sin(seq(-7, 5, length.out = k)) + 1
ip <- rnbinom(k, size = 2, mu = sinCurve/max(sinCurve))
sinCurve <- c(sin(seq(-7, -1, length.out = k/2)) + 1, runif(k/2, 0, 0.2))
background <- rnbinom(k, size = 2, mu = sinCurve/max(sinCurve)/2)
gr <- GenomicRanges::GPos(GenomicRanges::GRanges("chrXYZ", IRanges::IRanges(1, k)))
GenomeInfoDb::seqlengths(gr) <- 1e6
df <- S4Vectors::DataFrame(input = background, IP = ip)
se <- SummarizedExperiment(rowRanges = gr, assays = list(df))
ggd <- GenoGAMDataSet(se, chunkSize = 2000, overhangSize = 250,
design = ~ s(x))
coldf <- S4Vectors::DataFrame(experiment = c(0, 1))
rownames(coldf) <- c("input", "IP")
colData(ggd) <- coldf
design(ggd) <- ~ s(x) + s(x, by = experiment)
}
else {
config <- system.file("extdata/Set1", "experimentDesign.txt",
package = "fastGenoGAM")
dir <- system.file("extdata/Set1/bam", package = "fastGenoGAM")
region <- GRanges("chrI", IRanges(10000, 20000))
params <- Rsamtools::ScanBamParam(which = region)
settings <- GenoGAMSettings(bamParams = params)
ggd <- GenoGAMDataSet(config, chunkSize = 1000, overhangSize = 200,
design = ~ s(x) + s(x, by = genotype),
directory = dir, settings = settings)
}
return(ggd)
}
## Check functions
## ===============
## Check a specified setting of GenoGAMDataSet
.checkSettings <- function(object, params = c("chunkSize", "tileSize",
"equality", "tileRanges",
"chromosomes", "numTiles", "formula")) {
param <- match.arg(params)
switch(param,
chunkSize = .checkChunkSize(object),
tileSize = .checkTileSize(object),
equality = .checkEqualityOfTiles(object),
chromosomes = .checkChromosomes(object),
numTiles = .checkNumberOfTiles(object),
tileRanges = .checkTileRanges(object),
formula = .checkFormulaVariables(object))
}
## check the chunk size and return a logical value
.checkChunkSize <- function(object) {
widths <- IRanges::width(getIndex(object))
diffs <- (widths - 2*getOverhangSize(object)) - getChunkSize(object)
res <- all.equal(diffs, rep(0, length(diffs)), tolerance = 0)
return(res)
}
## check the tile size and return a logical value
.checkTileSize <- function(object) {
widths <- IRanges::width(getIndex(object))
diffs <- widths - getTileSize(object)
res <- all.equal(diffs, rep(0, length(diffs)), tolerance = 0)
return(res)
}
## check the overhang size and return a logical value
.checkEqualityOfTiles <- function(object) {
widths <- width(getIndex(object))
res <- all.equal(min(widths), max(widths))
return(res)
}
## check the chromosome list and return a logical value
.checkChromosomes <- function(object) {
objChroms <- GenomeInfoDb::seqlengths(object)
indexChroms <- GenomeInfoDb::seqlengths(getIndex(object))
validChroms <- GenomeInfoDb::seqlengths(getChromosomes(object))
objChroms <- objChroms[order(names(objChroms))]
indexChroms <- indexChroms[order(names(indexChroms))]
validChroms <- validChroms[order(names(validChroms))]
res1 <- all.equal(indexChroms, validChroms, objChroms)
res2 <- all.equal(names(indexChroms), names(validChroms), names(objChroms))
if(is(res1, "character") | is(res2, "character")) {
ans <- paste("Chromosome Lengths:", res1, "\n", "Chromosome Names:", res2, "\n")
return(ans)
}
return(res1 & res2)
}
## check the number of tiles and return a logical value
.checkNumberOfTiles <- function(object) {
tiles <- length(getIndex(object))
validTiles <- getTileNumber(object)
res <- all.equal(tiles, validTiles)
return(res)
}
## check ranges
.checkTileRanges <- function(object) {
tileRanges <- tileSettings(object)$chromosomes
dataRanges <- dataRange(object)
res <- all.equal(tileRanges, dataRanges)
return(res)
}
.checkFormulaVariables <- function(object) {
formulaCols <- as.vector(na.omit(.getVars(design(object))))
res <- all(formulaCols %in% colnames(colData(object)))
if(!res) {
res <- "'by' variables in design don't match colData"
}
return(res)
}
## Function to check the GenoGAMDataSet object
.checkGenoGAMDataSet <- function(object) {
futile.logger::flog.debug("Check if tile settings match the data.")
params = c("chunkSize", "tileSize", "tileRanges",
"equality", "chromosomes", "numTiles", "formula")
settings <- tileSettings(object)
if(is.null(settings$check)) {
futile.logger::flog.warn("Checks dismissed due to empty object or forgotten setting")
return(FALSE)
}
if(!settings$check) {
futile.logger::flog.warn("Settings checking deactivated. Modeling on these tiles might yield wrong results.")
return(FALSE)
}
res <- sapply(params, .checkSettings, object = object)
if(is(res, "character")) {
errorIndx <- which(res != "TRUE")
futile.logger::flog.error("Checks failed. Following settings display errors:")
futile.logger::flog.error(show(res[errorIndx]))
return(FALSE)
}
futile.logger::flog.debug("All checks passed.")
return(TRUE)
}
#' @noRd
setGeneric("checkObject", function(object) standardGeneric("checkObject"))
#' Check data compliance with tile settings
#'
#' Check if the indices were build correctly, according to the
#' specified parameters
#'
#' @rdname checkObject
#' @param object A /code{GenomicTiles} object.
#' @return A logical value
#' @examples
#' gt <- makeTestGenomicTiles()
#' checkSettings(gt)
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @noRd
setMethod("checkObject", "GenoGAMDataSet", function(object) {
.checkGenoGAMDataSet(object)
})
## Accessors
## =========
#' @export
setGeneric("getIndex", function(object) standardGeneric("getIndex"))
#' @describeIn GenoGAMDataSet An accessor to the index slot
setMethod("getIndex", signature(object = "GenoGAMDataSet"), function(object) {
return(slot(object, "index"))
})
#' @export
setGeneric("getCountMatrix", function(object) standardGeneric("getCountMatrix"))
#' @describeIn GenoGAMDataSet An accessor to the countMatrix slot
setMethod("getCountMatrix", signature(object = "GenoGAMDataSet"), function(object) {
res <- slot(object, "countMatrix")
colnames(res) <- colnames(object)
return(res)
})
#' @export
setGeneric("tileSettings", function(object) standardGeneric("tileSettings"))
#' @describeIn GenoGAMDataSet The accessor to the list of settings,
#' that were used to generate the tiles.
setMethod("tileSettings", "GenoGAMDataSet", function(object) {
S4Vectors::metadata(getIndex(object))
})
#' @export
setGeneric("dataRange", function(object) standardGeneric("dataRange"))
#' @describeIn GenoGAMDataSet The actual underlying GRanges showing
#' the range of the data.
setMethod("dataRange", "GenoGAMDataSet", function(object) {
.extractGR(rowRanges(object))
})
#' @export
setGeneric("getChromosomes", function(object) standardGeneric("getChromosomes"))
#' @describeIn GenoGAMDataSet A GRanges object representing the chromosomes
#' or chromosome regions on which the model will be computed
setMethod("getChromosomes", "GenoGAMDataSet", function(object) {
tileSettings(object)$chromosomes
})
#' @export
setGeneric("getTileSize", function(object) standardGeneric("getTileSize"))
#' @describeIn GenoGAMDataSet The size of the tiles
setMethod("getTileSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$tileSize
})
#' @export
setGeneric("getChunkSize", function(object) standardGeneric("getChunkSize"))
#' @describeIn GenoGAMDataSet The size of the chunks
setMethod("getChunkSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$chunkSize
})
#' @export
setGeneric("getOverhangSize", function(object) standardGeneric("getOverhangSize"))
#' @describeIn GenoGAMDataSet The size of the overhang (on one side)
setMethod("getOverhangSize", "GenoGAMDataSet", function(object) {
tileSettings(object)$overhangSize
})
#' @export
setGeneric("getTileNumber", function(object) standardGeneric("getTileNumber"))
#' @describeIn GenoGAMDataSet The total number of tiles
setMethod("getTileNumber", "GenoGAMDataSet", function(object) {
tileSettings(object)$numTiles
})
#' @describeIn GenoGAMDataSet A boolean function that is true if object uses HDF5 backend
setMethod("is.HDF5", signature(object = "GenoGAMDataSet"), function(object) {
res <- slot(object, "hdf5")
return(res)
})
#' @describeIn GenoGAMDataSet Access to the design slot.
setMethod("design", "GenoGAMDataSet", function(object) {
slot(object, "design")
})
#' @describeIn GenoGAMDataSet Replace method of the design slot.
setReplaceMethod("design", "GenoGAMDataSet", function(object, value) {
newCols <- as.vector(na.omit(.getVars(value)))
if(!all(newCols %in% colnames(colData(object)))) {
futile.logger::flog.error("'by' variables could not be found in colData")
stop("'by' variables could not be found in colData")
}
slot(object, "design") <- value
return(object)
})
#' @describeIn GenoGAMDataSet Access to the sizeFactors slot
setMethod("sizeFactors", "GenoGAMDataSet", function(object) {
sf <- slot(object, "sizeFactors")
names(sf) <- colnames(object)
return(sf)
})
#' @describeIn GenoGAMDataSet Replace method of the sizeFactors slot
setReplaceMethod("sizeFactors", "GenoGAMDataSet", function(object, value) {
slot(object, "sizeFactors") <- value
return(object)
})
## change Settings
## ===============
#' @export
setGeneric("getChunkSize<-", function(object, value) standardGeneric("getChunkSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the chunkSize parameter,
#' that triggers a new computation of the tiles based on the new chunk size.
setReplaceMethod("getChunkSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$chunkSize <- value
settings$tileSize <- value + 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getTileSize<-", function(object, value) standardGeneric("getTileSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the tileSize parameter,
#' that triggers a new computation of the tiles based on the new tile size.
setReplaceMethod("getTileSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$tileSize <- value
settings$chunkSize <- value - 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getOverhangSize<-", function(object, value) standardGeneric("getOverhangSize<-"))
#' @describeIn GenoGAMDataSet Replace method of the overhangSize parameter,
#' that triggers a new computation of the tiles based on the new overhang size.
setReplaceMethod("getOverhangSize", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
settings$overhangSize <- value
settings$tileSize <- settings$chunkSize + 2*value
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
#' @export
setGeneric("getTileNumber<-", function(object, value) standardGeneric("getTileNumber<-"))
#' @describeIn GenoGAMDataSet Replace method of the tileNumber parameter,
#' that triggers a new computation of the tiles based on the new number of tiles.
setReplaceMethod("getTileNumber", signature = c("GenoGAMDataSet", "numeric"),
function(object, value) {
settings <- tileSettings(object)
size <- min(width(settings$chromosomes))
if(size > sum(width(dataRange(object)))) {
warning("The settings indicated a longer total genome size than actually present. it was trimmed accordingly.")
size <- sum(width(dataRange(object)))
}
settings$chunkSize <- round(size/value)
settings$tileSize <- value + 2*settings$overhangSize
newIndex <- .makeTiles(settings)
slot(object, "index") <- newIndex
return(object)
})
## Subsetting
## ==========
#' Subset methods for GenoGAMDataSet
#'
#' @details
#' Those are various methods to subset the GenoGAMDataSet object.
#' By logical statement or GRanges overlap. The '[' subsetter is
#' just a short version of 'subsetByOverlaps'.
#'
#' @param x A GenoGAMDataSet object.
#' @param ranges,i A GRanges object. In case of subsetting by double brackets
#' 'i' is the index of the tile.
#' @param maxgap,minoverlap Intervals with a separation of 'maxgap' or
#' less and a minimum of 'minoverlap' overlapping positions, allowing for
#' 'maxgap', are considered to be overlapping. 'maxgap' should
#' be a scalar, non-negative, integer. 'minoverlap' should be a scalar,
#' positive integer.
#' @param type By default, any overlap is accepted. By specifying the 'type'
#' parameter, one can select for specific types of overlap. The types correspond
#' to operations in Allen's Interval Algebra (see references in). If \code{type}
#' is \code{start} or \code{end}, the intervals are required to have matching
#' starts or ends, respectively. While this operation seems trivial, the naive
#' implementation using \code{outer} would be much less efficient. Specifying
#' \code{equal} as the type returns the intersection of the \code{start} and
#' \code{end} matches. If \code{type} is \code{within}, the query interval must
#' be wholly contained within the subject interval. Note that all matches must
#' additionally satisfy the \code{minoverlap} constraint described above.
#'
#' The \code{maxgap} parameter has special meaning with the special
#' overlap types. For \code{start}, \code{end}, and \code{equal}, it specifies
#' the maximum difference in the starts, ends or both, respectively. For
#' \code{within}, it is the maximum amount by which the query may be wider
#' than the subject.
#' @param invert If TRUE, keep only the query ranges that do _not_ overlap
#' the subject.
#' @param ... Further arguments. Mostly a logical statement
#' in case of the 'subset' function. Note that the columnnames
#' for chromosomes and positions are: 'seqnames' and 'pos'.
#' @examples
#'
#' # subset by overlaps
#' ggd <- makeTestGenoGAMDataSet()
#' SummarizedExperiment::rowRanges(ggd)
#' gr <- GenomicRanges::GRanges("chrI", IRanges(10000,19000))
#' res <- IRanges::subsetByOverlaps(ggd, gr)
#' SummarizedExperiment::rowRanges(res)
#'
#' # Subset by logical statement
#' ggd <- makeTestGenoGAMDataSet()
#' SummarizedExperiment::rowRanges(ggd)
#' res <- subset(ggd, seqnames == "chrI" & pos <= 17000)
#' SummarizedExperiment::rowRanges(res)
#' @references
#' Allen's Interval Algebra: James F. Allen: Maintaining knowledge
#' about temporal intervals. In: Communications of the ACM.
#' 26/11/1983. ACM Press. S. 832-843, ISSN 0001-0782
#' @return A subsetted GenoGAMDataSet object.
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @rdname GenoGAMDataSet-subsetting
setMethod("subset", "GenoGAMDataSet", function(x, ...) {
if(all(dim(x) == c(0, 0))) return(x)
settings <- slot(x, "settings")
design <- design(x)
sf <- sizeFactors(x)
se <- subset(SummarizedExperiment(assays = assays(x),
rowRanges = rowRanges(x),
colData = colData(x)), ...)
if(any(dim(se) == 0)) {
index <- GenomicRanges::GRanges()
}
else {
GenomeInfoDb::seqlevels(rowRanges(se), pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(rowRanges(se))
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(se)
index <- .subsetIndex(se, getIndex(x))
}
ggd <- new("GenoGAMDataSet", se, settings = settings,
design = design, sizeFactors = sf, index = index)
return(ggd)
})
#' Method to subset the index of GenoGAMDataSet
#'
#' Subsetting the indeces of GenoGAMDataSet based on a SummarizedExperiment.
#'
#' @param x A SummarizedExperiment object.
#' @param index The index of the GenoGAMDataSet object to be subsetted.
#' @return A GRanges object representing the index
#' @noRd
.subsetIndex <- function(se, index) {
res <- NULL
if(is(se, "RangedSummarizedExperiment")) {
res <- .subsetIndexGGD(se, index)
}
if(is(se, "list")) {
res <- .subsetIndexGGDL(se, index)
}
return(res)
}
.subsetIndexGGD <- function(se, index) {
gpCoords <- .extractGR(rowRanges(se))
l <- S4Vectors::metadata(index)
l$chromosomes <- gpCoords
minWidth <- min(width(gpCoords))
if(minWidth < l$tileSize) {
l$tileSize <- minWidth
l$chunkSize <- minWidth - 2*l$overhangSize
}
indx <- .makeTiles(l)
GenomeInfoDb::seqinfo(indx) <- GenomeInfoDb::seqinfo(gpCoords)
return(indx)
}
.subsetByOverlapsGGD <- function(query, subject, maxgap = -1L, minoverlap = 0L,
type = c("any", "start", "end", "within", "equal"),
invert = FALSE, ...) {
if(any((width(subject) %% 2) == 1)) {
futile.logger::flog.info("Some subset ranges have odd widths. Rounding to the next even number.")
idx <- which((width(subject) %% 2) == 1)
width(subject)[idx] <- width(subject)[idx] + 1
}
settings <- slot(query, "settings")
design <- design(query)
sf <- sizeFactors(query)
se <- SummarizedExperiment(assays = assays(query),
rowRanges = rowRanges(query),
colData = colData(query))
subse <- subsetByOverlaps(se, subject, maxgap = maxgap,
minoverlap = minoverlap,
type=type, invert = invert, ...)
if(any(dim(subse) == 0)) {
index <- GenomicRanges::GRanges()
}
else {
GenomeInfoDb::seqlevels(rowRanges(subse), pruning.mode="coarse") <- GenomeInfoDb::seqlevelsInUse(rowRanges(subse))
slot(settings, "chromosomeList") <- GenomeInfoDb::seqlevels(subse)
index <- .subsetIndex(subse, getIndex(query))
}
ggd <- new("GenoGAMDataSet", subse, settings = settings,
design = design, sizeFactors = sf, index = index)
return(ggd)
}
#' @rdname GenoGAMDataSet-subsetting
setMethod("subsetByOverlaps", signature(x = "GenoGAMDataSet", ranges = "GRanges"),
function(x, ranges, maxgap = -1L, minoverlap = 0L,
type = c("any", "start", "end", "within", "equal"),
invert = FALSE, ...) {
type <- match.arg(type)
if(type == "any") {
maxgap <- -1L
minoverlap <- 0L
}
res <- .subsetByOverlapsGGD(query = x, subject = ranges,
maxgap = maxgap, minoverlap = minoverlap,
type = type, invert = invert)
return(res)
})
#' @rdname GenoGAMDataSet-subsetting
setMethod("[", c("GenoGAMDataSet", "GRanges"), function(x, i) {
ggd <- subsetByOverlaps(x, i)
return(ggd)
})
## #' @rdname GenoGAMDataSet-subsetting
## setMethod("[[", c("GenoGAMDataSet", "numeric"), function(x, i) {
## gr <- getIndex(x)[i]
## ggd <- subsetByOverlaps(x,gr)
## return(ggd)
## })
## Tile computation
## ================
#' Function to retrieve the row coordinates as a list
#' @param x The GenoGAMDataSet object
#' @return An integerList with the row numbers for each tile
#' @noRd
.getCoordinates <- function(x) {
l <- NULL
if(is(x,"GenoGAMDataSet")) {
l <- .getCoordinatesGGD(x)
}
if(is(x, "GenoGAMDataSetList")) {
l <- .getCoordinatesGGDL(x)
}
return(l)
}
#' Function to retrieve the row coordinates
#' @param x The GenoGAMDataSet object
#' @return A Coordinates object specifying the row coordinates
#' of each tile
#' @noRd
.getCoordinatesGGD <- function(x) {
## if genome is complete use the fast Bioconductor function
totalLen <- sum(as.numeric(GenomeInfoDb::seqlengths(x)))
if(totalLen == length(x)) {
l <- .absRanges(x)
}
## otherwise the slower version 'by bloc
else {
ov <- IRanges::findOverlaps(rowRanges(x), getIndex(x))
sh <- S4Vectors::subjectHits(ov)
qh <- S4Vectors::queryHits(ov)
l <- range(IRanges::splitAsList(qh, sh))
l <- Coordinates(l[,1], l[,2])
}
return(l)
}
#' Function to establish chunk coordinates
#' @param x An Coordinates object as the output of .getCoordinates
#' @return The same object as x but with not overlapping ranges
#' which were cut at the center of the overhang
#' @noRd
.getChunkCoords <- function(x) {
if(length(x) == 0) {
return(x)
}
start <- c(start(x[1,]), ceiling((end(x[-length(x),]) + start(x[-1,]))/2))
end <- c((start[-1] - 1), end(x[length(x),]))
ir <- Coordinates(start, end)
return(ir)
}
#' compute metrics for each tile
#' @param x The GenoGAMDataSet object
#' @param what A character naming the metric
#' @param na.rm Should NAs be ignored
#' @return The metric value
#' @noRd
.MetricsFun <- function(x, what, na.rm = FALSE) {
res <- NULL
if(is(x, "GenoGAMDataSet")) {
res <- .MetricsFunGGD(x, what, na.rm = na.rm)
}
if(is(x, "GenoGAMDataSetList")) {
res <- .MetricsFunGGDL(x, what, na.rm = na.rm)
}
return(res)
}
#' compute metrics for each tile
#' @param x The GenoGAMDataSet object
#' @param what A character naming the metric
#' @param na.rm Should NAs be ignored
#' @return The metric value
#' @noRd
.MetricsFunGGD <- function(x, what, na.rm = FALSE) {
l <- as(.getCoordinates(x), "IRanges")
## for HDF5
if(slot(x, "hdf5")) {
res <- sapply(1:dim(x)[2], function(ii) {
df <- assay(x)[,ii]
rleDF <- as(df, "DataFrame")
rle <- IRanges::extractList(rleDF[,1], l)
eval(call(what, rle, na.rm = na.rm))
})
}
else { ## Otherwise
res <- sapply(colnames(x), function(y) {
rle <- IRanges::extractList(assay(x)[[y]], l)
eval(call(what, rle, na.rm = na.rm))
})
}
if(!is(res, "matrix")) {
if(is(res, "list") & is.null(dim(res))) {
res <- matrix()
}
else {
res <- t(matrix(res))
}
}
colnames(res) <- colnames(x)
rownames(res) <- getIndex(x)$id
return(res)
}
#' Computing metrics
#'
#' Computing metrics on each tile of the GenoGAMDataSet object.
#' All metrics from the Summary generics group, as well as
#' mean, var, sd, median, mad and IQR are supported.
#'
#' @param x A GenoGAMDataSet object
#' @param ... Additional arguments
#' @param na.rm Should NAs be dropped. Otherwise the result is NA
#' @return A matrix with the specified metric computed per tile per column
#' of the assay data.
#' @examples
#' ggd <- makeTestGenoGAMDataSet()
#' sum(ggd)
#' min(ggd)
#' max(ggd)
#' mean(ggd)
#' var(ggd)
#' sd(ggd)
#' median(ggd)
#' mad(ggd)
#' IQR(ggd)
#' @author Georg Stricker \email{georg.stricker@@in.tum.de}
#' @rdname GenoGAMDataSet-metrics
setMethod("Summary", "GenoGAMDataSet", function(x, ..., na.rm = FALSE) {
l <- as(.getCoordinates(x), "IRanges")
## for HDF5
if(slot(x, "hdf5")) {
res <- sapply(1:dim(x)[2], function(ii) {
df <- assay(x)[,ii]
rleDF <- as(df, "DataFrame")
rle <- IRanges::extractList(rleDF[,1], l)
(getFunction(.Generic))(rle, na.rm = na.rm)
})
}
else { ## Otherwise
res <- sapply(colnames(x), function(y) {
rle <- IRanges::extractList(assay(x)[[y]], l)
(getFunction(.Generic))(rle, na.rm = na.rm)
})
}
if(!is(res, "matrix")) {
if(is(res, "list") & is.null(dim(res))) {
res <- matrix()
}
else {
res <- t(matrix(res))
}
}
colnames(res) <- colnames(x)
rownames(res) <- getIndex(x)$id
return(res)
})
#' @rdname GenoGAMDataSet-metrics
setMethod("mean", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "mean")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("var", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "var")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("sd", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "sd")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("median", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "median")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("mad", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "mad")
})
#' @rdname GenoGAMDataSet-metrics
setMethod("IQR", "GenoGAMDataSet", function(x) {
.MetricsFun(x, "IQR")
})
## Cosmetics
## =========
.showGenoGAMDataSet <- function(object) {
cl <- class(object)
dims <- dim(object)
md <- unique(names(colData(object)))
cnames <- colnames(object)
cdata <- names(colData(object))
sf <- sizeFactors(object)
form <- design(object)
if(length(tileSettings(object)) != 0) {
tsize <- tileSettings(object)$tileSize
tname <- "tiles"
unit <- ""
if(!is.null(tsize)) {
unit = "bp"
if(tsize/1000 > 1) {
unit <- "kbp"
tsize <- tsize/1000
}
if(tsize/1e6 > 1) {
unit <- "Mbp"
tsize <- tsize/1e6
}
}
chroms <- GenomeInfoDb::seqlevels(tileSettings(object)$chromosomes)
}
tnum <- length(getIndex(object))
cat("class:", cl, "\n")
cat("dimension:", dims, "\n")
cat(paste0("samples(", length(cnames), "):"), cnames, "\n")
cat(paste0("design variables(", length(md), "):"), md, "\n")
if(length(tileSettings(object)) != 0) {
cat(paste0(tname, " size: ", tsize, unit), "\n")
cat(paste0("number of ", tname, ": ", tnum), "\n")
cat("chromosomes:", chroms, "\n")
}
cat("size factors:\n")
show(sf)
cat("formula:\n")
cat(paste(as.character(form), collapse = " "), "\n")
}
## Show method for GenomicTiles.
setMethod("show", "GenoGAMDataSet", function(object) {
.showGenoGAMDataSet(object)
})
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Add the following code to your website.
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