R/BASiCS-simulate.R
In Oshlack/splatter: Simple Simulation of Single-cell RNA Sequencing Data
Defines functions
BASiCSSimulate
Documented in
BASiCSSimulate
#' BASiCS simulation
#'
#' Simulate counts using the BASiCS method.
#'
#' @param params BASiCSParams object containing simulation parameters.
#' @param sparsify logical. Whether to automatically convert assays to sparse
#' matrices if there will be a size reduction.
#' @param verbose logical. Whether to print progress messages
#' @param ... any additional parameter settings to override what is provided in
#' \code{params}.
#'
#' @details
#' This function is just a wrapper around \code{\link[BASiCS]{BASiCS_Sim}} that
#' takes a \code{\link{BASiCSParams}}, runs the simulation then converts the
#' output to a \code{\link[SingleCellExperiment]{SingleCellExperiment}} object.
#' See \code{\link[BASiCS]{BASiCS_Sim}} for more details of how the simulation
#' works.
#'
#' @return SingleCellExperiment containing simulated counts
#'
#' @references
#' Vallejos CA, Marioni JC, Richardson S. BASiCS: Bayesian Analysis of
#' Single-Cell Sequencing data. PLoS Computational Biology (2015).
#'
#' Paper: \url{10.1371/journal.pcbi.1004333}
#'
#' Code: \url{https://github.com/catavallejos/BASiCS}
#'
#' @examples
#' if (requireNamespace("BASiCS", quietly = TRUE)) {
#' sim <- BASiCSSimulate()
#' }
#' @export
BASiCSSimulate <- function(params = newBASiCSParams(), sparsify = TRUE,
verbose = TRUE, ...) {
checkmate::assertClass(params, "BASiCSParams")
params <- setParams(params, ...)
params <- expandParams(params)
validObject(params)
# Set random seed
seed <- getParam(params, "seed")
withr::with_seed(seed, {
if (verbose) {
message("Getting parameters...")
}
nGenes <- getParam(params, "nGenes")
nCells <- getParam(params, "nCells")
nSpikes <- getParam(params, "nSpikes")
nBatches <- getParam(params, "nBatches")
batch.cells <- getParam(params, "batchCells")
gene.params <- getParam(params, "gene.params")
if (nSpikes == 0 && nBatches == 1) {
stop("If there are no spikes there must be multiple batches")
}
# Sample gene.params if necessary
if (nrow(gene.params) != nGenes) {
warning(
"Number of gene.params not equal to nGenes, ",
"gene.params will be sampled."
)
selected <- sample(nrow(gene.params), nGenes, replace = TRUE)
gene.params <- gene.params[selected, ]
}
mu <- gene.params$Mean
delta <- gene.params$Delta
has.spikes <- nSpikes > 0
spike.mu <- NULL
if (has.spikes) {
spike.mu <- getParam(params, "spike.means")
if (length(spike.mu) != nSpikes) {
warning(
"Number of spike-in means not equal to nSpikes, ",
"spike.means will be sampled."
)
selected <- sample(length(spike.mu), nSpikes, replace = TRUE)
spike.mu <- spike.mu[selected]
params <- setParam(params, "spike.means", spike.mu)
}
}
cell.params <- getParam(params, "cell.params")
if (nrow(cell.params) != nCells) {
warning(
"Number of cell.params not equal to nCells, ",
"cell.params will be sampled."
)
selected <- sample(nrow(cell.params), nCells, replace = TRUE)
cell.params <- cell.params[selected, ]
cell.params$Phi <- (cell.params$Phi / sum(cell.params$Phi)) * nCells
params <- setParam(params, "cell.params", cell.params)
}
thetas <- getParam(params, "theta")
batches <- lapply(seq_len(nBatches), function(i, b) {
rep(i, b[i])
},
b = batch.cells
)
batches <- unlist(batches)
if (verbose) {
message("Simulating counts with BASiCS...")
}
if (has.spikes) {
BASiCS.sim <- suppressMessages(
BASiCS::BASiCS_Sim(
Mu = mu,
Mu_spikes = spike.mu,
Delta = delta,
Phi = cell.params$Phi,
S = cell.params$S,
Theta = thetas,
BatchInfo = batches
)
)
counts <- SingleCellExperiment::counts(BASiCS.sim)
spike.counts <- SummarizedExperiment::assay(
SingleCellExperiment::altExp(BASiCS.sim)
)
counts <- rbind(counts, spike.counts)
} else {
if (verbose) {
message("Simulating without spikes")
}
BASiCS.sim <- suppressMessages(
BASiCS::BASiCS_Sim(
Mu = mu,
Mu_spikes = NULL,
Delta = delta,
Phi = NULL,
S = cell.params$S,
Theta = thetas,
BatchInfo = batches
)
)
counts <- SingleCellExperiment::counts(BASiCS.sim)
}
if (verbose) {
message("Creating final dataset...")
}
cell.names <- paste0("Cell", seq_len(nCells))
gene.names <- paste0("Gene", seq_len(nGenes))
if (has.spikes) {
gene.names <- c(gene.names, paste0("Spike", seq_len(nSpikes)))
}
rownames(counts) <- gene.names
colnames(counts) <- cell.names
cells <- data.frame(
Cell = cell.names,
Phi = cell.params[, "Phi"],
S = cell.params[, "S"],
Batch = batches,
BatchTheta = thetas[batches]
)
rownames(cells) <- cell.names
features <- data.frame(
Gene = gene.names,
Mean = c(mu, spike.mu),
Delta = c(delta, rep(NA, nSpikes)),
IsSpike = c(rep(FALSE, nGenes), rep(TRUE, nSpikes))
)
rownames(features) <- gene.names
sim <- SingleCellExperiment(
assays = list(counts = counts),
rowData = features,
colData = cells,
metadata = list(Params = params)
)
if (sparsify) {
if (verbose) {
message("Sparsifying assays...")
}
assays(sim) <- sparsifyMatrices(assays(sim),
auto = TRUE,
verbose = verbose
)
}
if (verbose) {
message("Done!")
}
})
return(sim)
}
Oshlack/splatter documentation built on May 8, 2024, 5:33 a.m.
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Defines functions BASiCSSimulate
Documented in BASiCSSimulate
#' BASiCS simulation
#'
#' Simulate counts using the BASiCS method.
#'
#' @param params BASiCSParams object containing simulation parameters.
#' @param sparsify logical. Whether to automatically convert assays to sparse
#' matrices if there will be a size reduction.
#' @param verbose logical. Whether to print progress messages
#' @param ... any additional parameter settings to override what is provided in
#' \code{params}.
#'
#' @details
#' This function is just a wrapper around \code{\link[BASiCS]{BASiCS_Sim}} that
#' takes a \code{\link{BASiCSParams}}, runs the simulation then converts the
#' output to a \code{\link[SingleCellExperiment]{SingleCellExperiment}} object.
#' See \code{\link[BASiCS]{BASiCS_Sim}} for more details of how the simulation
#' works.
#'
#' @return SingleCellExperiment containing simulated counts
#'
#' @references
#' Vallejos CA, Marioni JC, Richardson S. BASiCS: Bayesian Analysis of
#' Single-Cell Sequencing data. PLoS Computational Biology (2015).
#'
#' Paper: \url{10.1371/journal.pcbi.1004333}
#'
#' Code: \url{https://github.com/catavallejos/BASiCS}
#'
#' @examples
#' if (requireNamespace("BASiCS", quietly = TRUE)) {
#' sim <- BASiCSSimulate()
#' }
#' @export
BASiCSSimulate <- function(params = newBASiCSParams(), sparsify = TRUE,
verbose = TRUE, ...) {
checkmate::assertClass(params, "BASiCSParams")
params <- setParams(params, ...)
params <- expandParams(params)
validObject(params)
# Set random seed
seed <- getParam(params, "seed")
withr::with_seed(seed, {
if (verbose) {
message("Getting parameters...")
}
nGenes <- getParam(params, "nGenes")
nCells <- getParam(params, "nCells")
nSpikes <- getParam(params, "nSpikes")
nBatches <- getParam(params, "nBatches")
batch.cells <- getParam(params, "batchCells")
gene.params <- getParam(params, "gene.params")
if (nSpikes == 0 && nBatches == 1) {
stop("If there are no spikes there must be multiple batches")
}
# Sample gene.params if necessary
if (nrow(gene.params) != nGenes) {
warning(
"Number of gene.params not equal to nGenes, ",
"gene.params will be sampled."
)
selected <- sample(nrow(gene.params), nGenes, replace = TRUE)
gene.params <- gene.params[selected, ]
}
mu <- gene.params$Mean
delta <- gene.params$Delta
has.spikes <- nSpikes > 0
spike.mu <- NULL
if (has.spikes) {
spike.mu <- getParam(params, "spike.means")
if (length(spike.mu) != nSpikes) {
warning(
"Number of spike-in means not equal to nSpikes, ",
"spike.means will be sampled."
)
selected <- sample(length(spike.mu), nSpikes, replace = TRUE)
spike.mu <- spike.mu[selected]
params <- setParam(params, "spike.means", spike.mu)
}
}
cell.params <- getParam(params, "cell.params")
if (nrow(cell.params) != nCells) {
warning(
"Number of cell.params not equal to nCells, ",
"cell.params will be sampled."
)
selected <- sample(nrow(cell.params), nCells, replace = TRUE)
cell.params <- cell.params[selected, ]
cell.params$Phi <- (cell.params$Phi / sum(cell.params$Phi)) * nCells
params <- setParam(params, "cell.params", cell.params)
}
thetas <- getParam(params, "theta")
batches <- lapply(seq_len(nBatches), function(i, b) {
rep(i, b[i])
},
b = batch.cells
)
batches <- unlist(batches)
if (verbose) {
message("Simulating counts with BASiCS...")
}
if (has.spikes) {
BASiCS.sim <- suppressMessages(
BASiCS::BASiCS_Sim(
Mu = mu,
Mu_spikes = spike.mu,
Delta = delta,
Phi = cell.params$Phi,
S = cell.params$S,
Theta = thetas,
BatchInfo = batches
)
)
counts <- SingleCellExperiment::counts(BASiCS.sim)
spike.counts <- SummarizedExperiment::assay(
SingleCellExperiment::altExp(BASiCS.sim)
)
counts <- rbind(counts, spike.counts)
} else {
if (verbose) {
message("Simulating without spikes")
}
BASiCS.sim <- suppressMessages(
BASiCS::BASiCS_Sim(
Mu = mu,
Mu_spikes = NULL,
Delta = delta,
Phi = NULL,
S = cell.params$S,
Theta = thetas,
BatchInfo = batches
)
)
counts <- SingleCellExperiment::counts(BASiCS.sim)
}
if (verbose) {
message("Creating final dataset...")
}
cell.names <- paste0("Cell", seq_len(nCells))
gene.names <- paste0("Gene", seq_len(nGenes))
if (has.spikes) {
gene.names <- c(gene.names, paste0("Spike", seq_len(nSpikes)))
}
rownames(counts) <- gene.names
colnames(counts) <- cell.names
cells <- data.frame(
Cell = cell.names,
Phi = cell.params[, "Phi"],
S = cell.params[, "S"],
Batch = batches,
BatchTheta = thetas[batches]
)
rownames(cells) <- cell.names
features <- data.frame(
Gene = gene.names,
Mean = c(mu, spike.mu),
Delta = c(delta, rep(NA, nSpikes)),
IsSpike = c(rep(FALSE, nGenes), rep(TRUE, nSpikes))
)
rownames(features) <- gene.names
sim <- SingleCellExperiment(
assays = list(counts = counts),
rowData = features,
colData = cells,
metadata = list(Params = params)
)
if (sparsify) {
if (verbose) {
message("Sparsifying assays...")
}
assays(sim) <- sparsifyMatrices(assays(sim),
auto = TRUE,
verbose = verbose
)
}
if (verbose) {
message("Done!")
}
})
return(sim)
}
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