R/projection.R
In cole-trapnell-lab/monocle3: Clustering, Differential Expression, and Trajectory Analysis for Single-Cell RNA-Seq
Defines functions
align_beta_transform
reduce_dimension_transform
align_transform
preprocess_transform
Documented in
align_transform
preprocess_transform
reduce_dimension_transform
#' @title Apply a preprocess transform model to a cell_data_set.
#'
#' @description Applies a previously calculated preprocess
#' transform model to a new count matrix. For more
#' information read the help information for save_transform_models.
#'
#' @param cds a cell_data_set to be transformed.
#' @param reduction_method a previously loaded transform
#' model that is used to reduce the dimensions of the
#' count matrix in the cell_data_set. The "PCA" and "LSI"
#' transforms are supported. The default is "PCA".
#' @param block_size a numeric value for the DelayedArray
#' block size used only in this function. Default is
#' NULL, which does not affect the current block size.
#' @param cores the number of cores to use for the matrix
#' multiplication. The default is 1.
#'
#' @return a cell_data_set with a preprocess reduced count
#' matrix.
#'
#' @section Preprocessing notes:
#' \describe{
#' \item{Filtering:}{apply the same filters to the query and
#' reference data set. For example, use the
#' same UMI cutoff value for both data sets.
#' You can check the cutoff value by finding
#' the range of UMI values before applying
#' normalization using range(counts(cds)).}
#' \item{Size factors:}{use the same method and round_exprs
#' parameters to calculate the Size_Factor
#' values for both data sets. See the
#' estimate_size_factors() help for
#' additional information.}
#' \item{Troubleshooting:}{if the projection fails, try
#' comparing histograms of various
#' values of the reference and query
#' data sets. For example, in order to
#' examine the size factor values use
#' hist(colData(cds)\[\['Size_Factor'\]\], breaks=100).}
#' }
#'
#' @examples
#' \dontrun{
#' cell_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_coldata.rds',
#' package='monocle3'))
#' gene_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_rowdata.rds',
#' package='monocle3'))
#' expression_matrix <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_expression_matrix.rds',
#' package='monocle3'))
#'
#' cds <- new_cell_data_set(expression_data=expression_matrix,
#' cell_metadata=cell_metadata,
#' gene_metadata=gene_metadata)
#'
#' ncell <- nrow(colData(cds))
#' cell_sample <- sample(seq(ncell), 2 * ncell / 3)
#' cell_set <- seq(ncell) %in% cell_sample
#' cds1 <- cds[,cell_set]
#' cds1 <- preprocess_cds(cds1)
#' save_transform_models(cds1, 'tm')
#' cds2 <- cds[,!cell_set]
#' cds2 <- load_transform_models(cds2, 'tm')
#' cds2 <- preprocess_transform(cds2, 'PCA')
#' }
#'
#' @export
# Bioconductor forbids writing to user directories so examples
# is not run.
preprocess_transform <- function(cds, reduction_method=c('PCA', 'LSI'), block_size=NULL, cores=1) {
#
# Need to add processing for LSI. TF-IDF transform etc.
#
assertthat::assert_that(methods::is(cds, 'cell_data_set'),
msg=paste('cds parameter is not a cell_data_set'))
assertthat::assert_that(
tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
error = function(e) FALSE),
msg = "reduction_method must be 'PCA' or 'LSI'")
reduction_method <- match.arg(reduction_method)
assertthat::assert_that(!is.null(size_factors(cds)),
msg = paste("You must call estimate_size_factors before calling",
"preprocess_cds."))
assertthat::assert_that(sum(is.na(size_factors(cds))) == 0,
msg=paste("One or more cells has a size factor of",
"NA."))
assertthat::assert_that(!is.null(cds@reduce_dim_aux[[reduction_method]]),
msg=paste0("Reduction method '", reduction_method, "' is not in the model",
" object."))
if(!is.null(block_size)) {
block_size0 <- DelayedArray::getAutoBlockSize()
DelayedArray::setAutoBlockSize(block_size)
}
set.seed(2016)
if(reduction_method == 'PCA') {
norm_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['norm_method']]
pseudo_count <- cds@reduce_dim_aux[[reduction_method]][['model']][['pseudo_count']]
rotation_matrix <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_v
vcenter <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_center
vscale <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_scale
FM <- normalize_expr_data(cds, norm_method=norm_method, pseudo_count=pseudo_count)
if (nrow(FM) == 0) {
stop("all rows have standard deviation zero")
}
# Don't select matrix rows by use_genes because intersect() does
# it implicitly through the rotation matrix.
fm_rowsums = Matrix::rowSums(FM)
FM <- FM[is.finite(fm_rowsums) & fm_rowsums != 0, ]
# Thank you Maddy.
intersect_genes <- intersect(rownames(rotation_matrix), rownames(FM))
intersect_indices <- match(intersect_genes, rownames(rotation_matrix))
if(any(is.na(intersect_indices))) {
stop('gene sets differ: genes in the subject matrix are not in the reference matrix')
}
if((length(intersect_indices)/length(rownames(FM))) < 0.5) {
warning('fewer than half the genes in the subject matrix are also in the reference matrix: are the matrices prepared using the same gene set?')
}
# [intersect_genes,] orders FM rows by intersect_genes
FM <- FM[intersect_genes,]
xt <- Matrix::t(FM)
xtda <- DelayedArray::DelayedArray(xt)
vcenter <- vcenter[intersect_indices]
vscale <- vscale[intersect_indices]
xtdasc <- t(xtda) - vcenter
xtdasc <- t(xtdasc / vscale)
irlba_res <- list()
# irlba_res$x <- xtdasc %*% rotation_matrix[intersect_indices,]
irlba_res$x <- matrix_multiply_multicore(mat_a=xtdasc,
mat_b=rotation_matrix[intersect_indices,],
cores)
irlba_res$x <- as.matrix(irlba_res$x)
class(irlba_res) <- c('irlba_prcomp', 'prcomp')
# 'reference' gene names are in the cds@preproc
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- irlba_res$x
}
else if(reduction_method == 'LSI') {
norm_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['norm_method']]
pseudo_count <- cds@reduce_dim_aux[[reduction_method]][['model']][['pseudo_count']]
rotation_matrix <- cds@reduce_dim_aux[[reduction_method]][['model']][['svd_v']]
log_scale_tf <- cds@reduce_dim_aux[[reduction_method]][['model']][['log_scale_tf']]
frequencies <- cds@reduce_dim_aux[[reduction_method]][['model']][['frequencies']]
scale_factor <- cds@reduce_dim_aux[[reduction_method]][['model']][['scale_factor']]
col_sums <- cds@reduce_dim_aux[[reduction_method]][['model']][['col_sums']]
row_sums <- cds@reduce_dim_aux[[reduction_method]][['model']][['row_sums']]
num_cols <- cds@reduce_dim_aux[[reduction_method]][['model']][['num_cols']]
FM <- normalize_expr_data(cds, norm_method=norm_method, pseudo_count=pseudo_count)
if (nrow(FM) == 0) {
stop("all rows have standard deviation zero")
}
fm_rowsums = Matrix::rowSums(FM)
FM <- FM[is.finite(fm_rowsums) & fm_rowsums != 0, ]
intersect_features <- intersect(rownames(rotation_matrix), rownames(FM))
intersect_indices <- match(intersect_features, rownames(rotation_matrix))
if(any(is.na(intersect_indices))) {
stop('feature sets differ: features in the subject matrix are not in the reference matrix')
}
if((length(intersect_indices)/length(rownames(FM))) < 0.5) {
warning('fewer than half the features in the subject matrix are also in the reference matrix: are the matrices prepared using the same feature set?')
}
# [intersect_features,] orders FM rows by intersect_features
FM <- FM[intersect_features,]
# Andrew's tfidf with modifications
if (frequencies) {
# "term frequency" method
tf <- Matrix::t(Matrix::t(FM) / Matrix::colSums(FM))
} else {
# "raw count" method
tf <- FM
}
# Either TF method can optionally be log scaled
if (log_scale_tf) {
if (frequencies) {
tf@x = log1p(tf@x * scale_factor)
} else {
tf@x = log1p(tf@x * 1)
}
}
idf <- log(1 + num_cols / row_sums)
idf <- idf[intersect_indices]
tf_idf_counts = tryCatch({
tf_idf_counts = tf * idf
}, error = function(e) {
print(paste("TF*IDF multiplication too large for in-memory, falling back",
"on DelayedArray."))
options(DelayedArray.block.size=block_size)
DelayedArray:::set_verbose_block_processing(TRUE)
tf = DelayedArray::DelayedArray(tf)
idf = as.matrix(idf)
tf_idf_counts = tf * idf
})
rownames(tf_idf_counts) = rownames(FM)
colnames(tf_idf_counts) = colnames(FM)
tf_idf_counts = methods::as(tf_idf_counts, "sparseMatrix")
xt <- Matrix::t(tf_idf_counts)
xtda <- DelayedArray::DelayedArray(xt)
irlba_res <- list()
irlba_res$x <- matrix_multiply_multicore(mat_a=xtda,
mat_b=rotation_matrix[intersect_indices,],
cores)
irlba_res$x <- as.matrix(irlba_res$x)
class(irlba_res) <- c('irlba_prcomp', 'prcomp')
# 'reference' gene names are in the cds@preproc
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- irlba_res$x
}
if(!is.null(block_size)) {
DelayedArray::setAutoBlockSize(block_size0)
}
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[[reduction_method]])
counts_identity <- get_counts_identity(cds)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:',reduction_method),
matrix_id,
counts_identity[['matrix_type']],
counts_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
#' @title Apply an alignment transform model to a cell_data_set.
#'
#' @description align_transform is not supported. Co-embed your
#' data sets if you need batch correction.
#'
#' @param cds a cell_data_set to be transformed.
#' @param reduction_method a previously loaded transform
#' model that is used to reduce the dimensions of the
#' count matrix in the cell_data_set. The "Aligned"
#' transform is not supported.
#'
#' @return The cds is returned without processing.
#'
#' @export
align_transform <- function(cds, reduction_method=c('Aligned')) {
stop('align_transform is not supported. If you need batch correction ',
'you will need to co-embed the data sets.')
return(cds)
}
# #' Apply an align_cds transform model to a cell_data_set.
# #'
# #' Applies a previously calculated align_cds transform model
# #' to a new preprocess transformed matrix. For more
# #' information read the help information for
# #' save_transform_models.
# #'
# #' Note: this function is a place holder. It does not
# #' map the transformed count matrix to aligned space
# #' at this time because I don't know how to do so.
# #'
# #' @param cds A cell_data_set to be transformed.
# #' @param reduction_method A previously loaded transform model that
# #' is used to reduce the dimensions of the preprocessed
# #' count matrix in cds.
# #'
# #' @return A cell_data_set with an align_cds transformed
# #' reduced count matrix.
# #'
# #' @export
# align_transform <- function(cds, reduction_method=c('Aligned')) {
# #
# # Need to add transformation code.
# #
# assertthat::assert_that(methods::is(cds, 'cell_data_set'),
# msg=paste('cds parameter is not a cell_data_set'))
# assertthat::assert_that(
# tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
# error = function(e) FALSE),
# msg = "reduction_method must be 'Aligned'")
#
# reduction_method <- match.arg(reduction_method)
#
# preprocess_method <- cds@reduce_dim_aux[['Aligned']][['model']][['preprocess_method']]
# preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
# assertthat::assert_that(!is.null(preproc_res),
# msg=paste("Preprocessing for '",
# preprocess_method,
# "' does not exist.",
# " Please preprocess the matrix before",
# " calling align_transform using preprocess_transform."))
#
# stop('This function is a place holder. It does not map the transformed count matrix to aligned space at this time because we don\'t know how to it yet.')
#
# set.seed(2016)
# alignment_group <- cds@reduce_dim_aux[['Aligned']][['model']][['alignment_group']]
# alignment_k <- cds@reduce_dim_aux[['Aligned']][['model']][['alignment_k']]
# residual_model_formula_str <- cds@reduce_dim_aux[['Aligned']][['model']][['residual_model_formula_str']]
# X.model_mat <- Matrix::sparse.model.matrix( stats::as.formula(residual_model_formula_str), data = colData(cds), drop.unused.levels = TRUE)
# fit <- limma::lmFit(Matrix::t(preproc_res), X.model_mat)
# beta <- fit$coefficients[, -1, drop = FALSE]
# cds@reduce_dim_aux[['Aligned']][['model']][['beta']] <- beta
# preproc_res <- Matrix::t(as.matrix(Matrix::t(preproc_res)) - beta %*% Matrix::t(X.model_mat[, -1]))
# corrected_PCA = batchelor::reducedMNN(as.matrix(preproc_res), batch=colData(cds)[,alignment_group], k=alignment_k)
# preproc_res = corrected_PCA$corrected
# SingleCellExperiment::reducedDims(cds)[['Aligned']] <- as.matrix(preproc_res)
#
# matrix_id <- get_unique_id()
# reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
# reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
# cds <- initialize_reduce_dim_metadata(cds, reduction_method)
# cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
# paste0('matrix:', reduction_method),
# matrix_id,
# reduce_dim_matrix_identity[['matrix_type']],
# reduce_dim_matrix_identity[['matrix_id']],
# reduce_dim_model_identity[['model_type']],
# reduce_dim_model_identity[['model_id']])
# # Keep the existing, loaded, reduce_dim_model_identity information.
#
# return(cds)
# }
#' @title Apply a reduce_dimension transform model to a cell_data_set.
#'
#' @description Applies a previously calculated reduce_dimension
#' transform model to a new preprocess transformed matrix. For
#' more information read the help information for
#' save_transform_models.
#'
#' @param cds a cell_data_set to be transformed.
#' @param preprocess_method the reduced dimension matrix to be
#' transformed using the reduction_method transform model.
#' The default is NULL, which uses the preprocess_method that
#' was used when the reduce_dimension model was built.
#' @param reduction_method a previously loaded reduce_dimension transform
#' model that is used to reduce the dimensions of the preprocessed
#' matrix in the cell_data_set. Only "UMAP" is supported.
#'
#' @return a cell_data_set with a transformed
#' reduced count matrix.
#'
#' @examples
#' \dontrun{
#' cell_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_coldata.rds',
#' package='monocle3'))
#' gene_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_rowdata.rds',
#' package='monocle3'))
#' expression_matrix <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_expression_matrix.rds',
#' package='monocle3'))
#' cds <- new_cell_data_set(expression_data=expression_matrix,
#' cell_metadata=cell_metadata,
#' gene_metadata=gene_metadata)
#' ncell <- nrow(colData(cds))
#' cell_sample <- sample(seq(ncell), 2 * ncell / 3)
#' cell_set <- seq(ncell) %in% cell_sample
#' cds1 <- cds[,cell_set]
#' cds1 <- preprocess_cds(cds1)
#' cds1 <- reduce_dimension(cds1)
#' save_transform_models(cds1, 'tm')
#' cds2 <- cds[,!cell_set]
#' cds2 <- load_transform_models(cds2, 'tm')
#' cds2 <- preprocess_transform(cds2, 'PCA')
#' cds2 <- reduce_dimension_transform(cds2)
#' }
#'
#' @export
#'
# Bioconductor forbids writing to user directories so examples
# is not run.
reduce_dimension_transform <- function(cds, preprocess_method=NULL, reduction_method=c('UMAP')) {
assertthat::assert_that(methods::is(cds, 'cell_data_set'),
msg=paste('cds parameter is not a cell_data_set'))
assertthat::assert_that(
tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
error = function(e) FALSE),
msg = "reduction_method must be 'UMAP'")
if(is.null(preprocess_method)) {
preprocess_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['umap_preprocess_method']]
} else
if(!is.null(preprocess_method) && !(preprocess_method %in% c('PCA', 'LSI', 'Aligned'))) {
stop('Preprocess_method must be one of \'PCA\', \'LSI\', or \'Aligned\'.')
}
if(is.null(cds@reduce_dim_aux[[preprocess_method]])) {
stop('There is no transform model for preprocess_method \'', preprocess_method, '\'.')
}
reduction_method <- match.arg(reduction_method)
preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
assertthat::assert_that(!is.null(preproc_res),
msg=paste("Preprocessing for '",
preprocess_method,
"' does not exist.",
" Please preprocess the matrix before",
" calling reduce_dimension_transform using preprocess_transform",
" or align_transform."))
# Notes:
# o uwot::umap_transform() depends on the RNG state and we want
# consistent results when called here and in reduce_dimensions()
# function(s).
#
set.seed(2016)
umap_model <- cds@reduce_dim_aux[[reduction_method]][['model']][['umap_model']]
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- uwot::umap_transform(X=preproc_res, model=umap_model, init='weighted', n_sgd_threads=1)
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[[reduction_method]])
reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:', reduction_method),
matrix_id,
reduce_dim_matrix_identity[['matrix_type']],
reduce_dim_matrix_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
#
# Note: this transformation is not generally effective.
#
align_beta_transform <- function(cds, preprocess_method = 'PCA') {
reduction_method <- 'Aligned'
preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
beta <- cds@reduce_dim_aux[['Aligned']][['model']][['beta']]
residual_model_formula_str <- cds@reduce_dim_aux[['Aligned']][['model']][['residual_model_formula_str']]
X.model_mat <- Matrix::sparse.model.matrix(
stats::as.formula(residual_model_formula_str),
data = colData(cds),
drop.unused.levels = TRUE)
SingleCellExperiment::reducedDims(cds)[['Aligned']] <- Matrix::t(as.matrix(Matrix::t(preproc_res)) -
beta %*% Matrix::t(X.model_mat[, -1]))
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[['Aligned']])
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:', reduction_method),
matrix_id,
reduce_dim_matrix_identity[['matrix_type']],
reduce_dim_matrix_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
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Defines functions align_beta_transform reduce_dimension_transform align_transform preprocess_transform
Documented in align_transform preprocess_transform reduce_dimension_transform
#' @title Apply a preprocess transform model to a cell_data_set.
#'
#' @description Applies a previously calculated preprocess
#' transform model to a new count matrix. For more
#' information read the help information for save_transform_models.
#'
#' @param cds a cell_data_set to be transformed.
#' @param reduction_method a previously loaded transform
#' model that is used to reduce the dimensions of the
#' count matrix in the cell_data_set. The "PCA" and "LSI"
#' transforms are supported. The default is "PCA".
#' @param block_size a numeric value for the DelayedArray
#' block size used only in this function. Default is
#' NULL, which does not affect the current block size.
#' @param cores the number of cores to use for the matrix
#' multiplication. The default is 1.
#'
#' @return a cell_data_set with a preprocess reduced count
#' matrix.
#'
#' @section Preprocessing notes:
#' \describe{
#' \item{Filtering:}{apply the same filters to the query and
#' reference data set. For example, use the
#' same UMI cutoff value for both data sets.
#' You can check the cutoff value by finding
#' the range of UMI values before applying
#' normalization using range(counts(cds)).}
#' \item{Size factors:}{use the same method and round_exprs
#' parameters to calculate the Size_Factor
#' values for both data sets. See the
#' estimate_size_factors() help for
#' additional information.}
#' \item{Troubleshooting:}{if the projection fails, try
#' comparing histograms of various
#' values of the reference and query
#' data sets. For example, in order to
#' examine the size factor values use
#' hist(colData(cds)\[\['Size_Factor'\]\], breaks=100).}
#' }
#'
#' @examples
#' \dontrun{
#' cell_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_coldata.rds',
#' package='monocle3'))
#' gene_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_rowdata.rds',
#' package='monocle3'))
#' expression_matrix <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_expression_matrix.rds',
#' package='monocle3'))
#'
#' cds <- new_cell_data_set(expression_data=expression_matrix,
#' cell_metadata=cell_metadata,
#' gene_metadata=gene_metadata)
#'
#' ncell <- nrow(colData(cds))
#' cell_sample <- sample(seq(ncell), 2 * ncell / 3)
#' cell_set <- seq(ncell) %in% cell_sample
#' cds1 <- cds[,cell_set]
#' cds1 <- preprocess_cds(cds1)
#' save_transform_models(cds1, 'tm')
#' cds2 <- cds[,!cell_set]
#' cds2 <- load_transform_models(cds2, 'tm')
#' cds2 <- preprocess_transform(cds2, 'PCA')
#' }
#'
#' @export
# Bioconductor forbids writing to user directories so examples
# is not run.
preprocess_transform <- function(cds, reduction_method=c('PCA', 'LSI'), block_size=NULL, cores=1) {
#
# Need to add processing for LSI. TF-IDF transform etc.
#
assertthat::assert_that(methods::is(cds, 'cell_data_set'),
msg=paste('cds parameter is not a cell_data_set'))
assertthat::assert_that(
tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
error = function(e) FALSE),
msg = "reduction_method must be 'PCA' or 'LSI'")
reduction_method <- match.arg(reduction_method)
assertthat::assert_that(!is.null(size_factors(cds)),
msg = paste("You must call estimate_size_factors before calling",
"preprocess_cds."))
assertthat::assert_that(sum(is.na(size_factors(cds))) == 0,
msg=paste("One or more cells has a size factor of",
"NA."))
assertthat::assert_that(!is.null(cds@reduce_dim_aux[[reduction_method]]),
msg=paste0("Reduction method '", reduction_method, "' is not in the model",
" object."))
if(!is.null(block_size)) {
block_size0 <- DelayedArray::getAutoBlockSize()
DelayedArray::setAutoBlockSize(block_size)
}
set.seed(2016)
if(reduction_method == 'PCA') {
norm_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['norm_method']]
pseudo_count <- cds@reduce_dim_aux[[reduction_method]][['model']][['pseudo_count']]
rotation_matrix <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_v
vcenter <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_center
vscale <- cds@reduce_dim_aux[[reduction_method]][['model']]$svd_scale
FM <- normalize_expr_data(cds, norm_method=norm_method, pseudo_count=pseudo_count)
if (nrow(FM) == 0) {
stop("all rows have standard deviation zero")
}
# Don't select matrix rows by use_genes because intersect() does
# it implicitly through the rotation matrix.
fm_rowsums = Matrix::rowSums(FM)
FM <- FM[is.finite(fm_rowsums) & fm_rowsums != 0, ]
# Thank you Maddy.
intersect_genes <- intersect(rownames(rotation_matrix), rownames(FM))
intersect_indices <- match(intersect_genes, rownames(rotation_matrix))
if(any(is.na(intersect_indices))) {
stop('gene sets differ: genes in the subject matrix are not in the reference matrix')
}
if((length(intersect_indices)/length(rownames(FM))) < 0.5) {
warning('fewer than half the genes in the subject matrix are also in the reference matrix: are the matrices prepared using the same gene set?')
}
# [intersect_genes,] orders FM rows by intersect_genes
FM <- FM[intersect_genes,]
xt <- Matrix::t(FM)
xtda <- DelayedArray::DelayedArray(xt)
vcenter <- vcenter[intersect_indices]
vscale <- vscale[intersect_indices]
xtdasc <- t(xtda) - vcenter
xtdasc <- t(xtdasc / vscale)
irlba_res <- list()
# irlba_res$x <- xtdasc %*% rotation_matrix[intersect_indices,]
irlba_res$x <- matrix_multiply_multicore(mat_a=xtdasc,
mat_b=rotation_matrix[intersect_indices,],
cores)
irlba_res$x <- as.matrix(irlba_res$x)
class(irlba_res) <- c('irlba_prcomp', 'prcomp')
# 'reference' gene names are in the cds@preproc
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- irlba_res$x
}
else if(reduction_method == 'LSI') {
norm_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['norm_method']]
pseudo_count <- cds@reduce_dim_aux[[reduction_method]][['model']][['pseudo_count']]
rotation_matrix <- cds@reduce_dim_aux[[reduction_method]][['model']][['svd_v']]
log_scale_tf <- cds@reduce_dim_aux[[reduction_method]][['model']][['log_scale_tf']]
frequencies <- cds@reduce_dim_aux[[reduction_method]][['model']][['frequencies']]
scale_factor <- cds@reduce_dim_aux[[reduction_method]][['model']][['scale_factor']]
col_sums <- cds@reduce_dim_aux[[reduction_method]][['model']][['col_sums']]
row_sums <- cds@reduce_dim_aux[[reduction_method]][['model']][['row_sums']]
num_cols <- cds@reduce_dim_aux[[reduction_method]][['model']][['num_cols']]
FM <- normalize_expr_data(cds, norm_method=norm_method, pseudo_count=pseudo_count)
if (nrow(FM) == 0) {
stop("all rows have standard deviation zero")
}
fm_rowsums = Matrix::rowSums(FM)
FM <- FM[is.finite(fm_rowsums) & fm_rowsums != 0, ]
intersect_features <- intersect(rownames(rotation_matrix), rownames(FM))
intersect_indices <- match(intersect_features, rownames(rotation_matrix))
if(any(is.na(intersect_indices))) {
stop('feature sets differ: features in the subject matrix are not in the reference matrix')
}
if((length(intersect_indices)/length(rownames(FM))) < 0.5) {
warning('fewer than half the features in the subject matrix are also in the reference matrix: are the matrices prepared using the same feature set?')
}
# [intersect_features,] orders FM rows by intersect_features
FM <- FM[intersect_features,]
# Andrew's tfidf with modifications
if (frequencies) {
# "term frequency" method
tf <- Matrix::t(Matrix::t(FM) / Matrix::colSums(FM))
} else {
# "raw count" method
tf <- FM
}
# Either TF method can optionally be log scaled
if (log_scale_tf) {
if (frequencies) {
tf@x = log1p(tf@x * scale_factor)
} else {
tf@x = log1p(tf@x * 1)
}
}
idf <- log(1 + num_cols / row_sums)
idf <- idf[intersect_indices]
tf_idf_counts = tryCatch({
tf_idf_counts = tf * idf
}, error = function(e) {
print(paste("TF*IDF multiplication too large for in-memory, falling back",
"on DelayedArray."))
options(DelayedArray.block.size=block_size)
DelayedArray:::set_verbose_block_processing(TRUE)
tf = DelayedArray::DelayedArray(tf)
idf = as.matrix(idf)
tf_idf_counts = tf * idf
})
rownames(tf_idf_counts) = rownames(FM)
colnames(tf_idf_counts) = colnames(FM)
tf_idf_counts = methods::as(tf_idf_counts, "sparseMatrix")
xt <- Matrix::t(tf_idf_counts)
xtda <- DelayedArray::DelayedArray(xt)
irlba_res <- list()
irlba_res$x <- matrix_multiply_multicore(mat_a=xtda,
mat_b=rotation_matrix[intersect_indices,],
cores)
irlba_res$x <- as.matrix(irlba_res$x)
class(irlba_res) <- c('irlba_prcomp', 'prcomp')
# 'reference' gene names are in the cds@preproc
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- irlba_res$x
}
if(!is.null(block_size)) {
DelayedArray::setAutoBlockSize(block_size0)
}
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[[reduction_method]])
counts_identity <- get_counts_identity(cds)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:',reduction_method),
matrix_id,
counts_identity[['matrix_type']],
counts_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
#' @title Apply an alignment transform model to a cell_data_set.
#'
#' @description align_transform is not supported. Co-embed your
#' data sets if you need batch correction.
#'
#' @param cds a cell_data_set to be transformed.
#' @param reduction_method a previously loaded transform
#' model that is used to reduce the dimensions of the
#' count matrix in the cell_data_set. The "Aligned"
#' transform is not supported.
#'
#' @return The cds is returned without processing.
#'
#' @export
align_transform <- function(cds, reduction_method=c('Aligned')) {
stop('align_transform is not supported. If you need batch correction ',
'you will need to co-embed the data sets.')
return(cds)
}
# #' Apply an align_cds transform model to a cell_data_set.
# #'
# #' Applies a previously calculated align_cds transform model
# #' to a new preprocess transformed matrix. For more
# #' information read the help information for
# #' save_transform_models.
# #'
# #' Note: this function is a place holder. It does not
# #' map the transformed count matrix to aligned space
# #' at this time because I don't know how to do so.
# #'
# #' @param cds A cell_data_set to be transformed.
# #' @param reduction_method A previously loaded transform model that
# #' is used to reduce the dimensions of the preprocessed
# #' count matrix in cds.
# #'
# #' @return A cell_data_set with an align_cds transformed
# #' reduced count matrix.
# #'
# #' @export
# align_transform <- function(cds, reduction_method=c('Aligned')) {
# #
# # Need to add transformation code.
# #
# assertthat::assert_that(methods::is(cds, 'cell_data_set'),
# msg=paste('cds parameter is not a cell_data_set'))
# assertthat::assert_that(
# tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
# error = function(e) FALSE),
# msg = "reduction_method must be 'Aligned'")
#
# reduction_method <- match.arg(reduction_method)
#
# preprocess_method <- cds@reduce_dim_aux[['Aligned']][['model']][['preprocess_method']]
# preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
# assertthat::assert_that(!is.null(preproc_res),
# msg=paste("Preprocessing for '",
# preprocess_method,
# "' does not exist.",
# " Please preprocess the matrix before",
# " calling align_transform using preprocess_transform."))
#
# stop('This function is a place holder. It does not map the transformed count matrix to aligned space at this time because we don\'t know how to it yet.')
#
# set.seed(2016)
# alignment_group <- cds@reduce_dim_aux[['Aligned']][['model']][['alignment_group']]
# alignment_k <- cds@reduce_dim_aux[['Aligned']][['model']][['alignment_k']]
# residual_model_formula_str <- cds@reduce_dim_aux[['Aligned']][['model']][['residual_model_formula_str']]
# X.model_mat <- Matrix::sparse.model.matrix( stats::as.formula(residual_model_formula_str), data = colData(cds), drop.unused.levels = TRUE)
# fit <- limma::lmFit(Matrix::t(preproc_res), X.model_mat)
# beta <- fit$coefficients[, -1, drop = FALSE]
# cds@reduce_dim_aux[['Aligned']][['model']][['beta']] <- beta
# preproc_res <- Matrix::t(as.matrix(Matrix::t(preproc_res)) - beta %*% Matrix::t(X.model_mat[, -1]))
# corrected_PCA = batchelor::reducedMNN(as.matrix(preproc_res), batch=colData(cds)[,alignment_group], k=alignment_k)
# preproc_res = corrected_PCA$corrected
# SingleCellExperiment::reducedDims(cds)[['Aligned']] <- as.matrix(preproc_res)
#
# matrix_id <- get_unique_id()
# reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
# reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
# cds <- initialize_reduce_dim_metadata(cds, reduction_method)
# cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
# paste0('matrix:', reduction_method),
# matrix_id,
# reduce_dim_matrix_identity[['matrix_type']],
# reduce_dim_matrix_identity[['matrix_id']],
# reduce_dim_model_identity[['model_type']],
# reduce_dim_model_identity[['model_id']])
# # Keep the existing, loaded, reduce_dim_model_identity information.
#
# return(cds)
# }
#' @title Apply a reduce_dimension transform model to a cell_data_set.
#'
#' @description Applies a previously calculated reduce_dimension
#' transform model to a new preprocess transformed matrix. For
#' more information read the help information for
#' save_transform_models.
#'
#' @param cds a cell_data_set to be transformed.
#' @param preprocess_method the reduced dimension matrix to be
#' transformed using the reduction_method transform model.
#' The default is NULL, which uses the preprocess_method that
#' was used when the reduce_dimension model was built.
#' @param reduction_method a previously loaded reduce_dimension transform
#' model that is used to reduce the dimensions of the preprocessed
#' matrix in the cell_data_set. Only "UMAP" is supported.
#'
#' @return a cell_data_set with a transformed
#' reduced count matrix.
#'
#' @examples
#' \dontrun{
#' cell_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_coldata.rds',
#' package='monocle3'))
#' gene_metadata <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_rowdata.rds',
#' package='monocle3'))
#' expression_matrix <- readRDS(system.file('extdata',
#' 'worm_embryo/worm_embryo_expression_matrix.rds',
#' package='monocle3'))
#' cds <- new_cell_data_set(expression_data=expression_matrix,
#' cell_metadata=cell_metadata,
#' gene_metadata=gene_metadata)
#' ncell <- nrow(colData(cds))
#' cell_sample <- sample(seq(ncell), 2 * ncell / 3)
#' cell_set <- seq(ncell) %in% cell_sample
#' cds1 <- cds[,cell_set]
#' cds1 <- preprocess_cds(cds1)
#' cds1 <- reduce_dimension(cds1)
#' save_transform_models(cds1, 'tm')
#' cds2 <- cds[,!cell_set]
#' cds2 <- load_transform_models(cds2, 'tm')
#' cds2 <- preprocess_transform(cds2, 'PCA')
#' cds2 <- reduce_dimension_transform(cds2)
#' }
#'
#' @export
#'
# Bioconductor forbids writing to user directories so examples
# is not run.
reduce_dimension_transform <- function(cds, preprocess_method=NULL, reduction_method=c('UMAP')) {
assertthat::assert_that(methods::is(cds, 'cell_data_set'),
msg=paste('cds parameter is not a cell_data_set'))
assertthat::assert_that(
tryCatch(expr = ifelse(match.arg(reduction_method) == "",TRUE, TRUE),
error = function(e) FALSE),
msg = "reduction_method must be 'UMAP'")
if(is.null(preprocess_method)) {
preprocess_method <- cds@reduce_dim_aux[[reduction_method]][['model']][['umap_preprocess_method']]
} else
if(!is.null(preprocess_method) && !(preprocess_method %in% c('PCA', 'LSI', 'Aligned'))) {
stop('Preprocess_method must be one of \'PCA\', \'LSI\', or \'Aligned\'.')
}
if(is.null(cds@reduce_dim_aux[[preprocess_method]])) {
stop('There is no transform model for preprocess_method \'', preprocess_method, '\'.')
}
reduction_method <- match.arg(reduction_method)
preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
assertthat::assert_that(!is.null(preproc_res),
msg=paste("Preprocessing for '",
preprocess_method,
"' does not exist.",
" Please preprocess the matrix before",
" calling reduce_dimension_transform using preprocess_transform",
" or align_transform."))
# Notes:
# o uwot::umap_transform() depends on the RNG state and we want
# consistent results when called here and in reduce_dimensions()
# function(s).
#
set.seed(2016)
umap_model <- cds@reduce_dim_aux[[reduction_method]][['model']][['umap_model']]
SingleCellExperiment::reducedDims(cds)[[reduction_method]] <- uwot::umap_transform(X=preproc_res, model=umap_model, init='weighted', n_sgd_threads=1)
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[[reduction_method]])
reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:', reduction_method),
matrix_id,
reduce_dim_matrix_identity[['matrix_type']],
reduce_dim_matrix_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
#
# Note: this transformation is not generally effective.
#
align_beta_transform <- function(cds, preprocess_method = 'PCA') {
reduction_method <- 'Aligned'
preproc_res <- SingleCellExperiment::reducedDims(cds)[[preprocess_method]]
beta <- cds@reduce_dim_aux[['Aligned']][['model']][['beta']]
residual_model_formula_str <- cds@reduce_dim_aux[['Aligned']][['model']][['residual_model_formula_str']]
X.model_mat <- Matrix::sparse.model.matrix(
stats::as.formula(residual_model_formula_str),
data = colData(cds),
drop.unused.levels = TRUE)
SingleCellExperiment::reducedDims(cds)[['Aligned']] <- Matrix::t(as.matrix(Matrix::t(preproc_res)) -
beta %*% Matrix::t(X.model_mat[, -1]))
matrix_id <- get_unique_id(SingleCellExperiment::reducedDims(cds)[['Aligned']])
cds <- initialize_reduce_dim_metadata(cds, reduction_method)
reduce_dim_matrix_identity <- get_reduce_dim_matrix_identity(cds, preprocess_method)
reduce_dim_model_identity <- get_reduce_dim_model_identity(cds, reduction_method)
cds <- set_reduce_dim_matrix_identity(cds, reduction_method,
paste0('matrix:', reduction_method),
matrix_id,
reduce_dim_matrix_identity[['matrix_type']],
reduce_dim_matrix_identity[['matrix_id']],
reduce_dim_model_identity[['model_type']],
reduce_dim_model_identity[['model_id']])
# Keep the existing, loaded, reduce_dim_model_identity information.
return(cds)
}
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