R/utils.R
In cole-trapnell-lab/cicero: Predict cis-co-accessibility from single-cell chromatin accessibility data
Defines functions
estimate_sf_dense
estimate_sf_sparse
estimateSizeFactorsSimp
split_peak_names
is_color
is_chr
find_overlapping_coordinates
compare_connections
make_sparse_matrix
annotate_cds_by_site
df_for_coords
ranges_for_coords
make_atac_cds
Documented in
annotate_cds_by_site
compare_connections
df_for_coords
find_overlapping_coordinates
make_atac_cds
make_sparse_matrix
ranges_for_coords
#' Make ATAC CDS object
#'
#' This function takes as input a data frame or a path to a file in a sparse
#' matrix format and returns a properly formatted \code{CellDataSet} (CDS)
#' object.
#'
#' @param input Either a data frame or a path to input data. If a file, it
#' should be a tab-delimited text file with three columns and no header. For
#' either a file or a data frame, the first column is the peak coordinates in
#' the form "chr10_100013372_100013596", the second column is the cell name,
#' and the third column is an integer that represents the number of reads
#' from that cell overlapping that peak. Zero values do not need to be
#' included (sparse matrix format).
#' @param binarize Logical. Should the count matrix be converted to binary?
#'
#' @return A CDS object containing your ATAC data in proper format.
#' @export
#'
#' @examples
#' data("cicero_data")
#' input_cds <- make_atac_cds(cicero_data, binarize = TRUE)
#'
make_atac_cds <- function(input, binarize = FALSE) {
#check input:
if(is(input, "character")) {
assertthat::is.readable(input)
intersect_lean <- as.data.frame(data.table::fread(input, header=FALSE))
} else if (class(input) %in% c("matrix", "data.frame")) {
intersect_lean <- input
} else {
stop("Input must be file path, matrix, or data.frame")
}
assertthat::assert_that(assertthat::are_equal(ncol(intersect_lean), 3))
assertthat::assert_that(is.logical(binarize))
names(intersect_lean) <- c("site_name", "cell_name", "read_count")
assertthat::assert_that(is.numeric(intersect_lean$read_count))
intersect_lean$site_name <- as.factor(intersect_lean$site_name)
intersect_lean$cell_name <- as.factor(intersect_lean$cell_name)
cellinfo <- data.frame(cells=levels(intersect_lean$cell_name))
row.names(cellinfo) <- cellinfo$cells
cellinfo$temp <- seq_len(nrow(cellinfo))
dhsinfo <- data.frame(site_name = levels(intersect_lean$site_name))
dhsinfo <- cbind(dhsinfo, split_peak_names(dhsinfo$site_name))
row.names(dhsinfo) <- dhsinfo$site_name
names(dhsinfo) <- c("site_name", "chr", "bp1", "bp2")
dhsinfo$chr <- gsub("chr","", dhsinfo$chr)
dhsinfo <- dhsinfo[order(as.character(dhsinfo$chr),
as.numeric(as.character(dhsinfo$bp2))),]
intersect_lean_ord <- intersect_lean[order(intersect_lean$site_name,
intersect_lean$cell_name),]
dhsinfo <- dhsinfo[order(dhsinfo$site_name),]
cellinfo <- cellinfo[order(cellinfo$cells),]
intersect_lean_ord$site_name <- factor(intersect_lean_ord$site_name)
intersect_lean_ord$cell_name <- factor(intersect_lean_ord$cell_name)
intersect_lean_ord$site_name_num <- as.numeric(intersect_lean_ord$site_name)
intersect_lean_ord$cell_name_num <- as.numeric(intersect_lean_ord$cell_name)
if(binarize) intersect_lean_ord$read_count <-
as.numeric(intersect_lean_ord$read_count > 0)
sparse_intersect <- Matrix::sparseMatrix(i=intersect_lean_ord$site_name_num,
j=intersect_lean_ord$cell_name_num,
x=intersect_lean_ord$read_count)
fd <- methods::new("AnnotatedDataFrame", data = dhsinfo)
pd <- methods::new("AnnotatedDataFrame", data = cellinfo)
atac_cds <- suppressWarnings(newCellDataSet(methods::as(sparse_intersect,
"sparseMatrix"),
phenoData = pd,
featureData = fd,
expressionFamily=negbinomial.size(),
lowerDetectionLimit=0))
if(binarize) {
atac_cds@expressionFamily <- binomialff()
atac_cds@expressionFamily@vfamily <- "binomialff"
}
pData(atac_cds)$temp <- NULL
fData(atac_cds)$chr <- as.character(fData(atac_cds)$chr)
fData(atac_cds)$bp1 <- as.numeric(as.character(fData(atac_cds)$bp1))
fData(atac_cds)$bp2 <- as.numeric(as.character(fData(atac_cds)$bp2))
atac_cds <- atac_cds[order(fData(atac_cds)$chr, fData(atac_cds)$bp1),]
atac_cds <- monocle::detectGenes(atac_cds)
atac_cds
}
#' Construct GRanges objects from coordinate strings
#'
#' @param coord_strings A list of coordinate strings (in the form
#' "chr1:500000-1000000")
#' @param with_names logical - should meta data include coordinate string
#' (field coord_string)?
#' @param meta_data_df A data frame with any meta data columns you want
#' included with the ranges. Must be in the same order as coord_strings.
#'
#' @details Coordinate strings consist of three pieces of information:
#' chromosome, start, and stop. These pieces of information can be separated
#' by the characters ":", "_", or "-". Commas will be removed, not used as
#' separators (ex: "chr18:8,575,097-8,839,855" is ok).
#'
#' @return GRanges object of the input strings
#'
#' @examples
#' ran1 <- ranges_for_coords("chr1:2039-30239", with_names = TRUE)
#' ran2 <- ranges_for_coords(c("chr1:2049-203902", "chrX:489249-1389389"),
#' meta_data_df = data.frame(dat = c("1", "X")))
#' ran3 <- ranges_for_coords(c("chr1:2049-203902", "chrX:489249-1389389"),
#' with_names = TRUE,
#' meta_data_df = data.frame(dat = c("1", "X"),
#' stringsAsFactors = FALSE))
#'
#' @seealso \code{\link[GenomicRanges]{GRanges-class}}
#'
#' @export
ranges_for_coords <- function(coord_strings,
meta_data_df = NULL,
with_names = FALSE) {
assertthat::assert_that(is.logical(with_names))
if (!is.null(meta_data_df)) {
assertthat::assert_that(is.data.frame(meta_data_df))
assertthat::assert_that(assertthat::are_equal(length(coord_strings),
nrow(meta_data_df)))
}
coord_strings <- gsub(",", "", coord_strings)
coord_cols <- split_peak_names(coord_strings)
gr <- GenomicRanges::GRanges(coord_cols[, 1],
ranges = IRanges::IRanges(as.numeric(coord_cols[,2]),
as.numeric(coord_cols[, 3])),
mcols = meta_data_df)
if (!is.null(meta_data_df)) {
for (n in names(meta_data_df)) {
newname <- paste0("mcols.", n)
names(GenomicRanges::mcols(gr))[which(names(GenomicRanges::mcols(gr)) ==
newname)] <- n
}
}
if (with_names) {
gr$coord_string <- coord_strings
}
gr
}
#' Construct a data frame of coordinate info from coordinate strings
#'
#' @param coord_strings A list of coordinate strings (each like
#' "chr1:500000-1000000")
#'
#' @details Coordinate strings consist of three pieces of information:
#' chromosome, start, and stop. These pieces of information can be separated
#' by the characters ":", "_", or "-". Commas will be removed, not used as
#' separators (ex: "chr18:8,575,097-8,839,855" is ok).
#'
#' @return data.frame with three columns, chromosome, starting base pair and
#' ending base pair
#'
#' @examples
#' df_for_coords(c("chr1:2,039-30,239", "chrX:28884:101293"))
#'
#' @export
df_for_coords <- function(coord_strings) {
coord_strings <- gsub(",", "", coord_strings)
coord_cols <- as.data.frame(split_peak_names(coord_strings),
stringsAsFactors = FALSE )
names(coord_cols) <- c("chr", "bp1", "bp2")
coord_cols$Peak <- coord_strings
coord_cols$bp1 <- as.numeric(coord_cols$bp1)
coord_cols$bp2 <- as.numeric(coord_cols$bp2)
coord_cols
}
#' Add feature data columns to fData
#'
#' Annotate the sites of your CDS with feature data based on coordinate overlap.
#'
#' @param cds A CDS object.
#' @param feature_data Data frame, or a character path to a file of
#' feature data. If a path, the file should be tab separated. Default assumes
#' no header, if your file has a header, set \code{header = FALSE}. For
#' either a data frame or a path, the file should be in bed-like format, with
#' the first 3 columns containing chromosome, start and stop respectively.
#' The remaining columns will be added to the \code{fData} table as feature
#' data.
#' @param verbose Logical, should progress messages be printed?
#' @param maxgap The maximum number of base pairs allowed between the peak and
#' the feature for the feature and peak to be considered overlapping.
#' Default = 0 (overlapping). Details in
#' \code{\link[IRanges]{findOverlaps-methods}}. If \code{maxgap}
#' is set to "nearest" then the nearest feature will be assigned regardless
#' of distance.
#' @param all Logical, should all overlapping intervals be reported? If all is
#' FALSE, the largest overlap is reported.
#' @param header Logical, if reading a file, is there a header?
#'
#' @details \code{annotate_cds_by_site} will add columns to the \code{fData}
#' table of a CDS object based on the overlap of peaks with features in a
#' data frame or file. An "overlap" column will be added, along with any
#' columns beyond the three required columns in the feature data. The
#' "overlap" column is the number of base pairs overlapping the \code{fData}
#' site. When maxgap is used, the true overlap is still calculated (overlap
#' will be 0 if the two features only overlap because of maxgap) \code{NA}
#' means that there was no overlapping feature. If a peak overlaps multiple
#' data intervals and all is FALSE, the largest overlapping interval will be
#' chosen (in a tie, the first entry is taken), otherwise all intervals will
#' be chosen and annotations will be collapsed using a comma as a separator.
#'
#' @return A CDS object with updated \code{fData} table.
#'
#' @examples
#' data("cicero_data")
#' input_cds <- make_atac_cds(cicero_data, binarize = TRUE)
#' feat <- data.frame(chr = c("chr18", "chr18", "chr18", "chr18"),
#' bp1 = c(10000, 10800, 50000, 100000),
#' bp2 = c(10700, 11000, 60000, 110000),
#' type = c("Acetylated", "Methylated", "Acetylated",
#' "Methylated"))
#' input_cds <- annotate_cds_by_site(input_cds, feat)
#'
#' @importFrom IRanges findOverlaps
#'
#' @export
annotate_cds_by_site <- function(cds,
feature_data,
verbose = FALSE,
maxgap = 0,
all = FALSE,
header = FALSE) {
assertthat::assert_that(is(cds, "CellDataSet"))
assertthat::assert_that(is.character(feature_data) |
is.data.frame(feature_data))
assertthat::assert_that(assertthat::is.number(maxgap) | maxgap == "nearest")
assertthat::assert_that(is.logical(verbose))
assertthat::assert_that(is.logical(all))
assertthat::assert_that(is.logical(header))
if (verbose) print("Generating fData ranges")
granges <- ranges_for_coords(rownames(fData(cds)), with_names=TRUE)
if (is(feature_data, "character")) {
if (verbose) print("Reading data file")
ch <- read.table(feature_data, header=header, stringsAsFactors = FALSE)
if (verbose) print("Generating feature data ranges")
names(ch)[c(1,2,3)] <- c("chr", "start", "stop")
dtt <- GenomicRanges::makeGRangesFromDataFrame(ch,
keep.extra.columns = TRUE)
} else {
if (verbose) print("Generating feature data ranges")
names(feature_data)[c(1,2,3)] <- c("chr", "start", "stop")
dtt <- GenomicRanges::makeGRangesFromDataFrame(feature_data,
keep.extra.columns = TRUE)
}
if (verbose) print("Determining overlaps")
if(maxgap == "nearest") {
ol <- GenomicRanges::nearest(granges, dtt, select = "all")
} else {
ol <- GenomicRanges::findOverlaps(granges, dtt, select = "all",
maxgap = maxgap)
}
olaps <- data.frame(
row_name = GenomicRanges::mcols(granges[
S4Vectors::queryHits(ol)])@listData$coord_string,
width = GenomicRanges::width(
IRanges::pintersect(granges[S4Vectors::queryHits(ol)],
dtt[S4Vectors::subjectHits(ol)]))
)
olaps <- cbind(olaps,
as.data.frame(GenomicRanges::mcols(
dtt[S4Vectors::subjectHits(ol)])))
if (verbose) print("Assigning labels")
if (all) {
olaps <- olaps %>%
dplyr::rename(overlap = width) %>%
dplyr::group_by(row_name) %>%
dplyr::summarise_all(paste, collapse=",")
} else {
olaps <- olaps[order(olaps$width, decreasing = TRUE),]
olaps <- olaps[!duplicated(olaps$row_name),]
olaps <- olaps %>% dplyr::rename(overlap = width)
}
if (verbose) print("Merging to fData table")
fd <- fData(cds)
fd$row_name <- row.names(fd)
fd <- data.table::as.data.table(fd)
data.table::setkey(fd, "row_name")
fd <- merge(fd, olaps, by="row_name", all.x=TRUE)
fData(cds) <- as.data.frame(fd)
row.names(fData(cds)) <- fData(cds)$row_name
fData(cds)$row_name <- NULL
fData(cds) <- fData(cds)[row.names(exprs(cds)),]
cds
}
#' Make a symmetric square sparse matrix from data frame
#'
#' Convert a data frame into a square sparse matrix (all versus all)
#'
#' @param data data frame
#' @param i.name name of i column
#' @param j.name name of j column
#' @param x.name name of value column
#'
#' @return sparse matrix
#'
#'
make_sparse_matrix <- function(data,
i.name = "Peak1",
j.name = "Peak2",
x.name = "value") {
if(!i.name %in% names(data) |
!j.name %in% names(data) |
!x.name %in% names(data)) {
stop('i.name, j.name, and x.name must be columns in data')
}
data$i <- as.character(data[,i.name])
data$j <- as.character(data[,j.name])
data$x <- data[,x.name]
if(!class(data$x) %in% c("numeric", "integer"))
stop('x.name column must be numeric')
peaks <- data.frame(Peak = unique(c(data$i, data$j)),
index = seq_len(length(unique(c(data$i, data$j)))))
data <- data[,c("i", "j", "x")]
data <- rbind(data, data.frame(i=peaks$Peak, j = peaks$Peak, x = 0))
data <- data[!duplicated(data[,c("i", "j", "x")]),]
data <- data.table::as.data.table(data)
peaks <- data.table::as.data.table(peaks)
data.table::setkey(data, "i")
data.table::setkey(peaks, "Peak")
data <- data[peaks]
data.table::setkey(data, "j")
data <- data[peaks]
data <- as.data.frame(data)
data <- data[,c("index", "i.index", "x")]
data2 <- data
names(data2) <- c("i.index", "index", "x")
data <- rbind(data, data2)
data <- data[!duplicated(data[,c("index", "i.index")]),]
data <- data[data$index >= data$i.index,]
sp_mat <- Matrix::sparseMatrix(i=as.numeric(data$index),
j=as.numeric(data$i.index),
x=data$x,
symmetric = TRUE)
colnames(sp_mat) <- peaks[order(peaks$index),]$Peak
row.names(sp_mat) <- peaks[order(peaks$index),]$Peak
return(sp_mat)
}
#' Compare Cicero connections to other datasets
#'
#' Compare two sets of connections and return a vector of logicals for whether
#' connections in one are present in the other.
#'
#' @param conns1 A data frame of Cicero connections, like those output from
#' \code{assemble_connections}. The first two columns must be the coordinates
#' of peaks that are connected.
#' @param conns2 A data frame of connections to be searched for overlap. The
#' first two columns must be coordinates of genomic sites that are connected.
#' @param maxgap The number of base pairs between peaks allowed to be called
#' overlapping. See \code{\link[IRanges]{findOverlaps-methods}} in the IRanges
#' package for further description.
#'
#'
#' @return A vector of logicals of whether the Cicero pair is present in the
#' alternate dataset.
#' @export
#'
#' @examples
#' \dontrun{
#' cons$in_dataset <- compare_connections(conns, alt_data)
#' }
#'
compare_connections <- function(conns1,
conns2,
maxgap = 0) {
assertthat::assert_that(is(conns1, "data.frame"))
assertthat::assert_that(is(conns2, "data.frame"))
assertthat::assert_that(assertthat::is.number(maxgap))
conns2 <- conns2[,c(1,2)]
names(conns2) <- c("Peak1", "Peak2")
conns22 <- conns2[,c(2,1)]
names(conns22) <- c("Peak1", "Peak2")
conns2 <- rbind(conns2, conns22)
conns2 <- conns2[!duplicated(conns2),]
alt1 <- ranges_for_coords(conns2$Peak1)
alt2 <- ranges_for_coords(conns2$Peak2)
conns11 <- ranges_for_coords(conns1$Peak1)
conns12 <- ranges_for_coords(conns1$Peak2)
ol1 <- GenomicRanges::findOverlaps(conns11,
alt1,
maxgap = maxgap,
select="all")
ol2 <- GenomicRanges::findOverlaps(conns12,
alt2,
maxgap = maxgap,
select="all")
ol1 <- as.list(ol1)
ol2 <- as.list(ol2)
olap <- mapply(function(o1, o2) {
if (length(o1) == 0) out <- FALSE
else if (length(intersect(o1,o2) > 0)) out <- TRUE
else out <- FALSE
return(out)
}, ol1, ol2)
return(olap)
}
#' Find peaks that overlap a specific genomic location
#'
#' @param coord_list A list of coordinates to be searched for overlap in the
#' form chr_100_2000.
#' @param coord The coordinates that you want to find in the form chr1_100_2000.
#' @param maxgap The maximum distance in base pairs between coord and the
#' coord_list that should count as overlapping. Default is 0.
#'
#' @return A character vector of the peaks that overlap coord.
#' @export
#'
#' @examples
#' test_coords <- c("chr18_10025_10225", "chr18_10603_11103",
#' "chr18_11604_13986",
#' "chr18_157883_158536", "chr18_217477_218555",
#' "chr18_245734_246234")
#' find_overlapping_coordinates(test_coords, "chr18:10,100-1246234")
#'
#'
find_overlapping_coordinates <- function(coord_list,
coord,
maxgap = 0) {
coord <- gsub(",", "", coord)
cons_gr <- ranges_for_coords(coord_list)
if(length(coord) == 1) {
ol1 <- GenomicRanges::findOverlaps(ranges_for_coords(coord),
cons_gr,
maxgap = maxgap,
select="all")
ol1 <- as.list(ol1)
return(as.character(coord_list[unlist(ol1)]))
} else {
ol1 <- lapply(coord, function(x) {
y <- suppressWarnings(unlist(as.list(
GenomicRanges::findOverlaps(ranges_for_coords(x),
cons_gr,
maxgap = maxgap,
select="all"))))
if(length(y) == 0) return(NA)
return(coord_list[y])
})
return(as.character(unlist(ol1)))
}
}
is_chr <- function(x) {
assertthat::assert_that(is.character(x))
grepl("chr", x)
}
assertthat::on_failure(is_chr) <- function(call, env) {
paste0(deparse(call$x), " must be of format 'chr1'")
}
is_color <- function(x, df=NULL) {
if (!is.null(df)) {
if (all(vapply(x, function(y) y %in% names(df), TRUE))) return(TRUE)
tryCatch(is.matrix(col2rgb(x)), error = function(e) FALSE)
} else {
tryCatch(is.matrix(col2rgb(x)), error = function(e) FALSE)
}
}
assertthat::on_failure(is_color) <- function(call, env) {
paste0(deparse(call$x),
" must be a valid color or a column in input data frame")
}
split_peak_names <- function(inp) {
out <- stringr::str_split_fixed(stringi::stri_reverse(inp),
":|-|_", 3)
out[,1] <- stringi::stri_reverse(out[,1])
out[,2] <- stringi::stri_reverse(out[,2])
out[,3] <- stringi::stri_reverse(out[,3])
out[,c(3,2,1), drop=FALSE]
}
########### Borrowed from monocle to avoid bug ##############
estimateSizeFactorsSimp <- function(cds) {
if (any(class(exprs(cds)) %in% c("dgCMatrix", "dgTMatrix"))) {
sizeFactors(cds) <- estimate_sf_sparse(exprs(cds))
}else{
sizeFactors(cds) <- estimate_sf_dense(exprs(cds))
}
return(cds)
}
estimate_sf_sparse <- function(counts){
counts <- round(counts)
cell_total <- Matrix::colSums(counts)
sfs <- cell_total / exp(mean(log(cell_total)))
sfs[is.na(sfs)] <- 1
sfs
}
estimate_sf_dense <- function(counts){
CM <- round(counts)
cell_total <- apply(CM, 2, sum)
sfs <- cell_total / exp(mean(log(cell_total)))
sfs[is.na(sfs)] <- 1
sfs
}
estimateDispersionsSimp <- function (object, modelFormulaStr = "~ 1",
relative_expr = TRUE,
min_cells_detected = 1,
remove_outliers = TRUE, cores = 1,
...) {
dispModelName = "blind"
object@dispFitInfo = new.env(hash = TRUE)
dfi <- estimateDispersionsForCellDataSet(object, modelFormulaStr,
relative_expr, min_cells_detected,
remove_outliers,
cores)
object@dispFitInfo[[dispModelName]] <- dfi
object
}
estimateDispersionsForCellDataSet <- function (cds, modelFormulaStr,
relative_expr,
min_cells_detected,
removeOutliers, verbose = FALSE)
{
mu <- NA
model_terms <- unlist(lapply(stringr::str_split(modelFormulaStr, "~|\\+|\\*"),
stringr::str_trim))
model_terms <- model_terms[model_terms != ""]
cds_pdata <- dplyr::group_by(dplyr::select(tibble::rownames_to_column(pData(cds)),
"rowname"))
disp_table <- as.data.frame(cds_pdata %>%
dplyr::do(disp_calc_helper_NB(cds[, .$rowname],
cds@expressionFamily,
min_cells_detected)))
disp_table <- subset(disp_table, is.na(mu) == FALSE)
res <- parametricDispersionFit(disp_table, verbose)
fit <- res[[1]]
coefs <- res[[2]]
CD <- cooks.distance(fit)
cooksCutoff <- 4/nrow(disp_table)
outliers <- union(names(CD[CD > cooksCutoff]), setdiff(row.names(disp_table),
names(CD)))
res <- parametricDispersionFit(disp_table[row.names(disp_table) %in%
outliers == FALSE, ], verbose)
fit <- res[[1]]
coefs <- res[[2]]
names(coefs) <- c("asymptDisp", "extraPois")
ans <- function(q) coefs[1] + coefs[2]/q
attr(ans, "coefficients") <- coefs
res <- list(disp_table = disp_table, disp_func = ans)
return(res)
}
disp_calc_helper_NB <- function (cds, expressionFamily, min_cells_detected)
{
rounded <- round(exprs(cds))
nzGenes <- Matrix::rowSums(rounded > cds@lowerDetectionLimit)
nzGenes <- names(nzGenes[nzGenes > min_cells_detected])
x <- t(t(rounded[nzGenes, ])/pData(cds[nzGenes, ])$Size_Factor)
xim <- mean(1/pData(cds[nzGenes, ])$Size_Factor)
f_expression_mean <- Matrix::rowMeans(x)
f_expression_var <- Matrix::rowMeans((x - f_expression_mean)^2)
disp_guess_meth_moments <- f_expression_var - xim * f_expression_mean
disp_guess_meth_moments <- disp_guess_meth_moments/(f_expression_mean^2)
res <- data.frame(mu = as.vector(f_expression_mean),
disp = as.vector(disp_guess_meth_moments))
res[res$mu == 0]$mu = NA
res[res$mu == 0]$disp = NA
res$disp[res$disp < 0] <- 0
res <- cbind(gene_id = row.names(fData(cds[nzGenes, ])),
res)
res
}
parametricDispersionFit <- function (disp_table, verbose = FALSE,
initial_coefs = c(1e-06, 1)) {
coefs <- initial_coefs
iter <- 0
while (TRUE) {
residuals <- disp_table$disp/(coefs[1] + coefs[2]/disp_table$mu)
good <- disp_table[which((residuals > initial_coefs[1]) &
(residuals < 10000)), ]
if (verbose)
fit <- glm(disp ~ I(1/mu), data = good, family = Gamma(link = "identity"),
start = coefs)
else suppressWarnings(fit <- glm(disp ~ I(1/mu), data = good,
family = Gamma(link = "identity"),
start = coefs))
oldcoefs <- coefs
coefs <- coefficients(fit)
if (coefs[1] < initial_coefs[1]) {
coefs[1] <- initial_coefs[1]
}
if (coefs[2] < 0) {
stop("Parametric dispersion fit failed. Try a local fit and/or a pooled estimation. (See '?estimateDispersions')")
}
if (sum(log(coefs/oldcoefs)^2) < initial_coefs[1])
break
iter <- iter + 1
if (iter > 10) {
warning("Dispersion fit did not converge.")
break
}
}
if (!all(coefs > 0)) {
stop("Parametric dispersion fit failed. Try a local fit and/or a pooled estimation. (See '?estimateDispersions')")
}
list(fit, coefs)
}
cole-trapnell-lab/cicero documentation built on March 13, 2023, 6:02 p.m.
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Defines functions estimate_sf_dense estimate_sf_sparse estimateSizeFactorsSimp split_peak_names is_color is_chr find_overlapping_coordinates compare_connections make_sparse_matrix annotate_cds_by_site df_for_coords ranges_for_coords make_atac_cds
Documented in annotate_cds_by_site compare_connections df_for_coords find_overlapping_coordinates make_atac_cds make_sparse_matrix ranges_for_coords
#' Make ATAC CDS object
#'
#' This function takes as input a data frame or a path to a file in a sparse
#' matrix format and returns a properly formatted \code{CellDataSet} (CDS)
#' object.
#'
#' @param input Either a data frame or a path to input data. If a file, it
#' should be a tab-delimited text file with three columns and no header. For
#' either a file or a data frame, the first column is the peak coordinates in
#' the form "chr10_100013372_100013596", the second column is the cell name,
#' and the third column is an integer that represents the number of reads
#' from that cell overlapping that peak. Zero values do not need to be
#' included (sparse matrix format).
#' @param binarize Logical. Should the count matrix be converted to binary?
#'
#' @return A CDS object containing your ATAC data in proper format.
#' @export
#'
#' @examples
#' data("cicero_data")
#' input_cds <- make_atac_cds(cicero_data, binarize = TRUE)
#'
make_atac_cds <- function(input, binarize = FALSE) {
#check input:
if(is(input, "character")) {
assertthat::is.readable(input)
intersect_lean <- as.data.frame(data.table::fread(input, header=FALSE))
} else if (class(input) %in% c("matrix", "data.frame")) {
intersect_lean <- input
} else {
stop("Input must be file path, matrix, or data.frame")
}
assertthat::assert_that(assertthat::are_equal(ncol(intersect_lean), 3))
assertthat::assert_that(is.logical(binarize))
names(intersect_lean) <- c("site_name", "cell_name", "read_count")
assertthat::assert_that(is.numeric(intersect_lean$read_count))
intersect_lean$site_name <- as.factor(intersect_lean$site_name)
intersect_lean$cell_name <- as.factor(intersect_lean$cell_name)
cellinfo <- data.frame(cells=levels(intersect_lean$cell_name))
row.names(cellinfo) <- cellinfo$cells
cellinfo$temp <- seq_len(nrow(cellinfo))
dhsinfo <- data.frame(site_name = levels(intersect_lean$site_name))
dhsinfo <- cbind(dhsinfo, split_peak_names(dhsinfo$site_name))
row.names(dhsinfo) <- dhsinfo$site_name
names(dhsinfo) <- c("site_name", "chr", "bp1", "bp2")
dhsinfo$chr <- gsub("chr","", dhsinfo$chr)
dhsinfo <- dhsinfo[order(as.character(dhsinfo$chr),
as.numeric(as.character(dhsinfo$bp2))),]
intersect_lean_ord <- intersect_lean[order(intersect_lean$site_name,
intersect_lean$cell_name),]
dhsinfo <- dhsinfo[order(dhsinfo$site_name),]
cellinfo <- cellinfo[order(cellinfo$cells),]
intersect_lean_ord$site_name <- factor(intersect_lean_ord$site_name)
intersect_lean_ord$cell_name <- factor(intersect_lean_ord$cell_name)
intersect_lean_ord$site_name_num <- as.numeric(intersect_lean_ord$site_name)
intersect_lean_ord$cell_name_num <- as.numeric(intersect_lean_ord$cell_name)
if(binarize) intersect_lean_ord$read_count <-
as.numeric(intersect_lean_ord$read_count > 0)
sparse_intersect <- Matrix::sparseMatrix(i=intersect_lean_ord$site_name_num,
j=intersect_lean_ord$cell_name_num,
x=intersect_lean_ord$read_count)
fd <- methods::new("AnnotatedDataFrame", data = dhsinfo)
pd <- methods::new("AnnotatedDataFrame", data = cellinfo)
atac_cds <- suppressWarnings(newCellDataSet(methods::as(sparse_intersect,
"sparseMatrix"),
phenoData = pd,
featureData = fd,
expressionFamily=negbinomial.size(),
lowerDetectionLimit=0))
if(binarize) {
atac_cds@expressionFamily <- binomialff()
atac_cds@expressionFamily@vfamily <- "binomialff"
}
pData(atac_cds)$temp <- NULL
fData(atac_cds)$chr <- as.character(fData(atac_cds)$chr)
fData(atac_cds)$bp1 <- as.numeric(as.character(fData(atac_cds)$bp1))
fData(atac_cds)$bp2 <- as.numeric(as.character(fData(atac_cds)$bp2))
atac_cds <- atac_cds[order(fData(atac_cds)$chr, fData(atac_cds)$bp1),]
atac_cds <- monocle::detectGenes(atac_cds)
atac_cds
}
#' Construct GRanges objects from coordinate strings
#'
#' @param coord_strings A list of coordinate strings (in the form
#' "chr1:500000-1000000")
#' @param with_names logical - should meta data include coordinate string
#' (field coord_string)?
#' @param meta_data_df A data frame with any meta data columns you want
#' included with the ranges. Must be in the same order as coord_strings.
#'
#' @details Coordinate strings consist of three pieces of information:
#' chromosome, start, and stop. These pieces of information can be separated
#' by the characters ":", "_", or "-". Commas will be removed, not used as
#' separators (ex: "chr18:8,575,097-8,839,855" is ok).
#'
#' @return GRanges object of the input strings
#'
#' @examples
#' ran1 <- ranges_for_coords("chr1:2039-30239", with_names = TRUE)
#' ran2 <- ranges_for_coords(c("chr1:2049-203902", "chrX:489249-1389389"),
#' meta_data_df = data.frame(dat = c("1", "X")))
#' ran3 <- ranges_for_coords(c("chr1:2049-203902", "chrX:489249-1389389"),
#' with_names = TRUE,
#' meta_data_df = data.frame(dat = c("1", "X"),
#' stringsAsFactors = FALSE))
#'
#' @seealso \code{\link[GenomicRanges]{GRanges-class}}
#'
#' @export
ranges_for_coords <- function(coord_strings,
meta_data_df = NULL,
with_names = FALSE) {
assertthat::assert_that(is.logical(with_names))
if (!is.null(meta_data_df)) {
assertthat::assert_that(is.data.frame(meta_data_df))
assertthat::assert_that(assertthat::are_equal(length(coord_strings),
nrow(meta_data_df)))
}
coord_strings <- gsub(",", "", coord_strings)
coord_cols <- split_peak_names(coord_strings)
gr <- GenomicRanges::GRanges(coord_cols[, 1],
ranges = IRanges::IRanges(as.numeric(coord_cols[,2]),
as.numeric(coord_cols[, 3])),
mcols = meta_data_df)
if (!is.null(meta_data_df)) {
for (n in names(meta_data_df)) {
newname <- paste0("mcols.", n)
names(GenomicRanges::mcols(gr))[which(names(GenomicRanges::mcols(gr)) ==
newname)] <- n
}
}
if (with_names) {
gr$coord_string <- coord_strings
}
gr
}
#' Construct a data frame of coordinate info from coordinate strings
#'
#' @param coord_strings A list of coordinate strings (each like
#' "chr1:500000-1000000")
#'
#' @details Coordinate strings consist of three pieces of information:
#' chromosome, start, and stop. These pieces of information can be separated
#' by the characters ":", "_", or "-". Commas will be removed, not used as
#' separators (ex: "chr18:8,575,097-8,839,855" is ok).
#'
#' @return data.frame with three columns, chromosome, starting base pair and
#' ending base pair
#'
#' @examples
#' df_for_coords(c("chr1:2,039-30,239", "chrX:28884:101293"))
#'
#' @export
df_for_coords <- function(coord_strings) {
coord_strings <- gsub(",", "", coord_strings)
coord_cols <- as.data.frame(split_peak_names(coord_strings),
stringsAsFactors = FALSE )
names(coord_cols) <- c("chr", "bp1", "bp2")
coord_cols$Peak <- coord_strings
coord_cols$bp1 <- as.numeric(coord_cols$bp1)
coord_cols$bp2 <- as.numeric(coord_cols$bp2)
coord_cols
}
#' Add feature data columns to fData
#'
#' Annotate the sites of your CDS with feature data based on coordinate overlap.
#'
#' @param cds A CDS object.
#' @param feature_data Data frame, or a character path to a file of
#' feature data. If a path, the file should be tab separated. Default assumes
#' no header, if your file has a header, set \code{header = FALSE}. For
#' either a data frame or a path, the file should be in bed-like format, with
#' the first 3 columns containing chromosome, start and stop respectively.
#' The remaining columns will be added to the \code{fData} table as feature
#' data.
#' @param verbose Logical, should progress messages be printed?
#' @param maxgap The maximum number of base pairs allowed between the peak and
#' the feature for the feature and peak to be considered overlapping.
#' Default = 0 (overlapping). Details in
#' \code{\link[IRanges]{findOverlaps-methods}}. If \code{maxgap}
#' is set to "nearest" then the nearest feature will be assigned regardless
#' of distance.
#' @param all Logical, should all overlapping intervals be reported? If all is
#' FALSE, the largest overlap is reported.
#' @param header Logical, if reading a file, is there a header?
#'
#' @details \code{annotate_cds_by_site} will add columns to the \code{fData}
#' table of a CDS object based on the overlap of peaks with features in a
#' data frame or file. An "overlap" column will be added, along with any
#' columns beyond the three required columns in the feature data. The
#' "overlap" column is the number of base pairs overlapping the \code{fData}
#' site. When maxgap is used, the true overlap is still calculated (overlap
#' will be 0 if the two features only overlap because of maxgap) \code{NA}
#' means that there was no overlapping feature. If a peak overlaps multiple
#' data intervals and all is FALSE, the largest overlapping interval will be
#' chosen (in a tie, the first entry is taken), otherwise all intervals will
#' be chosen and annotations will be collapsed using a comma as a separator.
#'
#' @return A CDS object with updated \code{fData} table.
#'
#' @examples
#' data("cicero_data")
#' input_cds <- make_atac_cds(cicero_data, binarize = TRUE)
#' feat <- data.frame(chr = c("chr18", "chr18", "chr18", "chr18"),
#' bp1 = c(10000, 10800, 50000, 100000),
#' bp2 = c(10700, 11000, 60000, 110000),
#' type = c("Acetylated", "Methylated", "Acetylated",
#' "Methylated"))
#' input_cds <- annotate_cds_by_site(input_cds, feat)
#'
#' @importFrom IRanges findOverlaps
#'
#' @export
annotate_cds_by_site <- function(cds,
feature_data,
verbose = FALSE,
maxgap = 0,
all = FALSE,
header = FALSE) {
assertthat::assert_that(is(cds, "CellDataSet"))
assertthat::assert_that(is.character(feature_data) |
is.data.frame(feature_data))
assertthat::assert_that(assertthat::is.number(maxgap) | maxgap == "nearest")
assertthat::assert_that(is.logical(verbose))
assertthat::assert_that(is.logical(all))
assertthat::assert_that(is.logical(header))
if (verbose) print("Generating fData ranges")
granges <- ranges_for_coords(rownames(fData(cds)), with_names=TRUE)
if (is(feature_data, "character")) {
if (verbose) print("Reading data file")
ch <- read.table(feature_data, header=header, stringsAsFactors = FALSE)
if (verbose) print("Generating feature data ranges")
names(ch)[c(1,2,3)] <- c("chr", "start", "stop")
dtt <- GenomicRanges::makeGRangesFromDataFrame(ch,
keep.extra.columns = TRUE)
} else {
if (verbose) print("Generating feature data ranges")
names(feature_data)[c(1,2,3)] <- c("chr", "start", "stop")
dtt <- GenomicRanges::makeGRangesFromDataFrame(feature_data,
keep.extra.columns = TRUE)
}
if (verbose) print("Determining overlaps")
if(maxgap == "nearest") {
ol <- GenomicRanges::nearest(granges, dtt, select = "all")
} else {
ol <- GenomicRanges::findOverlaps(granges, dtt, select = "all",
maxgap = maxgap)
}
olaps <- data.frame(
row_name = GenomicRanges::mcols(granges[
S4Vectors::queryHits(ol)])@listData$coord_string,
width = GenomicRanges::width(
IRanges::pintersect(granges[S4Vectors::queryHits(ol)],
dtt[S4Vectors::subjectHits(ol)]))
)
olaps <- cbind(olaps,
as.data.frame(GenomicRanges::mcols(
dtt[S4Vectors::subjectHits(ol)])))
if (verbose) print("Assigning labels")
if (all) {
olaps <- olaps %>%
dplyr::rename(overlap = width) %>%
dplyr::group_by(row_name) %>%
dplyr::summarise_all(paste, collapse=",")
} else {
olaps <- olaps[order(olaps$width, decreasing = TRUE),]
olaps <- olaps[!duplicated(olaps$row_name),]
olaps <- olaps %>% dplyr::rename(overlap = width)
}
if (verbose) print("Merging to fData table")
fd <- fData(cds)
fd$row_name <- row.names(fd)
fd <- data.table::as.data.table(fd)
data.table::setkey(fd, "row_name")
fd <- merge(fd, olaps, by="row_name", all.x=TRUE)
fData(cds) <- as.data.frame(fd)
row.names(fData(cds)) <- fData(cds)$row_name
fData(cds)$row_name <- NULL
fData(cds) <- fData(cds)[row.names(exprs(cds)),]
cds
}
#' Make a symmetric square sparse matrix from data frame
#'
#' Convert a data frame into a square sparse matrix (all versus all)
#'
#' @param data data frame
#' @param i.name name of i column
#' @param j.name name of j column
#' @param x.name name of value column
#'
#' @return sparse matrix
#'
#'
make_sparse_matrix <- function(data,
i.name = "Peak1",
j.name = "Peak2",
x.name = "value") {
if(!i.name %in% names(data) |
!j.name %in% names(data) |
!x.name %in% names(data)) {
stop('i.name, j.name, and x.name must be columns in data')
}
data$i <- as.character(data[,i.name])
data$j <- as.character(data[,j.name])
data$x <- data[,x.name]
if(!class(data$x) %in% c("numeric", "integer"))
stop('x.name column must be numeric')
peaks <- data.frame(Peak = unique(c(data$i, data$j)),
index = seq_len(length(unique(c(data$i, data$j)))))
data <- data[,c("i", "j", "x")]
data <- rbind(data, data.frame(i=peaks$Peak, j = peaks$Peak, x = 0))
data <- data[!duplicated(data[,c("i", "j", "x")]),]
data <- data.table::as.data.table(data)
peaks <- data.table::as.data.table(peaks)
data.table::setkey(data, "i")
data.table::setkey(peaks, "Peak")
data <- data[peaks]
data.table::setkey(data, "j")
data <- data[peaks]
data <- as.data.frame(data)
data <- data[,c("index", "i.index", "x")]
data2 <- data
names(data2) <- c("i.index", "index", "x")
data <- rbind(data, data2)
data <- data[!duplicated(data[,c("index", "i.index")]),]
data <- data[data$index >= data$i.index,]
sp_mat <- Matrix::sparseMatrix(i=as.numeric(data$index),
j=as.numeric(data$i.index),
x=data$x,
symmetric = TRUE)
colnames(sp_mat) <- peaks[order(peaks$index),]$Peak
row.names(sp_mat) <- peaks[order(peaks$index),]$Peak
return(sp_mat)
}
#' Compare Cicero connections to other datasets
#'
#' Compare two sets of connections and return a vector of logicals for whether
#' connections in one are present in the other.
#'
#' @param conns1 A data frame of Cicero connections, like those output from
#' \code{assemble_connections}. The first two columns must be the coordinates
#' of peaks that are connected.
#' @param conns2 A data frame of connections to be searched for overlap. The
#' first two columns must be coordinates of genomic sites that are connected.
#' @param maxgap The number of base pairs between peaks allowed to be called
#' overlapping. See \code{\link[IRanges]{findOverlaps-methods}} in the IRanges
#' package for further description.
#'
#'
#' @return A vector of logicals of whether the Cicero pair is present in the
#' alternate dataset.
#' @export
#'
#' @examples
#' \dontrun{
#' cons$in_dataset <- compare_connections(conns, alt_data)
#' }
#'
compare_connections <- function(conns1,
conns2,
maxgap = 0) {
assertthat::assert_that(is(conns1, "data.frame"))
assertthat::assert_that(is(conns2, "data.frame"))
assertthat::assert_that(assertthat::is.number(maxgap))
conns2 <- conns2[,c(1,2)]
names(conns2) <- c("Peak1", "Peak2")
conns22 <- conns2[,c(2,1)]
names(conns22) <- c("Peak1", "Peak2")
conns2 <- rbind(conns2, conns22)
conns2 <- conns2[!duplicated(conns2),]
alt1 <- ranges_for_coords(conns2$Peak1)
alt2 <- ranges_for_coords(conns2$Peak2)
conns11 <- ranges_for_coords(conns1$Peak1)
conns12 <- ranges_for_coords(conns1$Peak2)
ol1 <- GenomicRanges::findOverlaps(conns11,
alt1,
maxgap = maxgap,
select="all")
ol2 <- GenomicRanges::findOverlaps(conns12,
alt2,
maxgap = maxgap,
select="all")
ol1 <- as.list(ol1)
ol2 <- as.list(ol2)
olap <- mapply(function(o1, o2) {
if (length(o1) == 0) out <- FALSE
else if (length(intersect(o1,o2) > 0)) out <- TRUE
else out <- FALSE
return(out)
}, ol1, ol2)
return(olap)
}
#' Find peaks that overlap a specific genomic location
#'
#' @param coord_list A list of coordinates to be searched for overlap in the
#' form chr_100_2000.
#' @param coord The coordinates that you want to find in the form chr1_100_2000.
#' @param maxgap The maximum distance in base pairs between coord and the
#' coord_list that should count as overlapping. Default is 0.
#'
#' @return A character vector of the peaks that overlap coord.
#' @export
#'
#' @examples
#' test_coords <- c("chr18_10025_10225", "chr18_10603_11103",
#' "chr18_11604_13986",
#' "chr18_157883_158536", "chr18_217477_218555",
#' "chr18_245734_246234")
#' find_overlapping_coordinates(test_coords, "chr18:10,100-1246234")
#'
#'
find_overlapping_coordinates <- function(coord_list,
coord,
maxgap = 0) {
coord <- gsub(",", "", coord)
cons_gr <- ranges_for_coords(coord_list)
if(length(coord) == 1) {
ol1 <- GenomicRanges::findOverlaps(ranges_for_coords(coord),
cons_gr,
maxgap = maxgap,
select="all")
ol1 <- as.list(ol1)
return(as.character(coord_list[unlist(ol1)]))
} else {
ol1 <- lapply(coord, function(x) {
y <- suppressWarnings(unlist(as.list(
GenomicRanges::findOverlaps(ranges_for_coords(x),
cons_gr,
maxgap = maxgap,
select="all"))))
if(length(y) == 0) return(NA)
return(coord_list[y])
})
return(as.character(unlist(ol1)))
}
}
is_chr <- function(x) {
assertthat::assert_that(is.character(x))
grepl("chr", x)
}
assertthat::on_failure(is_chr) <- function(call, env) {
paste0(deparse(call$x), " must be of format 'chr1'")
}
is_color <- function(x, df=NULL) {
if (!is.null(df)) {
if (all(vapply(x, function(y) y %in% names(df), TRUE))) return(TRUE)
tryCatch(is.matrix(col2rgb(x)), error = function(e) FALSE)
} else {
tryCatch(is.matrix(col2rgb(x)), error = function(e) FALSE)
}
}
assertthat::on_failure(is_color) <- function(call, env) {
paste0(deparse(call$x),
" must be a valid color or a column in input data frame")
}
split_peak_names <- function(inp) {
out <- stringr::str_split_fixed(stringi::stri_reverse(inp),
":|-|_", 3)
out[,1] <- stringi::stri_reverse(out[,1])
out[,2] <- stringi::stri_reverse(out[,2])
out[,3] <- stringi::stri_reverse(out[,3])
out[,c(3,2,1), drop=FALSE]
}
########### Borrowed from monocle to avoid bug ##############
estimateSizeFactorsSimp <- function(cds) {
if (any(class(exprs(cds)) %in% c("dgCMatrix", "dgTMatrix"))) {
sizeFactors(cds) <- estimate_sf_sparse(exprs(cds))
}else{
sizeFactors(cds) <- estimate_sf_dense(exprs(cds))
}
return(cds)
}
estimate_sf_sparse <- function(counts){
counts <- round(counts)
cell_total <- Matrix::colSums(counts)
sfs <- cell_total / exp(mean(log(cell_total)))
sfs[is.na(sfs)] <- 1
sfs
}
estimate_sf_dense <- function(counts){
CM <- round(counts)
cell_total <- apply(CM, 2, sum)
sfs <- cell_total / exp(mean(log(cell_total)))
sfs[is.na(sfs)] <- 1
sfs
}
estimateDispersionsSimp <- function (object, modelFormulaStr = "~ 1",
relative_expr = TRUE,
min_cells_detected = 1,
remove_outliers = TRUE, cores = 1,
...) {
dispModelName = "blind"
object@dispFitInfo = new.env(hash = TRUE)
dfi <- estimateDispersionsForCellDataSet(object, modelFormulaStr,
relative_expr, min_cells_detected,
remove_outliers,
cores)
object@dispFitInfo[[dispModelName]] <- dfi
object
}
estimateDispersionsForCellDataSet <- function (cds, modelFormulaStr,
relative_expr,
min_cells_detected,
removeOutliers, verbose = FALSE)
{
mu <- NA
model_terms <- unlist(lapply(stringr::str_split(modelFormulaStr, "~|\\+|\\*"),
stringr::str_trim))
model_terms <- model_terms[model_terms != ""]
cds_pdata <- dplyr::group_by(dplyr::select(tibble::rownames_to_column(pData(cds)),
"rowname"))
disp_table <- as.data.frame(cds_pdata %>%
dplyr::do(disp_calc_helper_NB(cds[, .$rowname],
cds@expressionFamily,
min_cells_detected)))
disp_table <- subset(disp_table, is.na(mu) == FALSE)
res <- parametricDispersionFit(disp_table, verbose)
fit <- res[[1]]
coefs <- res[[2]]
CD <- cooks.distance(fit)
cooksCutoff <- 4/nrow(disp_table)
outliers <- union(names(CD[CD > cooksCutoff]), setdiff(row.names(disp_table),
names(CD)))
res <- parametricDispersionFit(disp_table[row.names(disp_table) %in%
outliers == FALSE, ], verbose)
fit <- res[[1]]
coefs <- res[[2]]
names(coefs) <- c("asymptDisp", "extraPois")
ans <- function(q) coefs[1] + coefs[2]/q
attr(ans, "coefficients") <- coefs
res <- list(disp_table = disp_table, disp_func = ans)
return(res)
}
disp_calc_helper_NB <- function (cds, expressionFamily, min_cells_detected)
{
rounded <- round(exprs(cds))
nzGenes <- Matrix::rowSums(rounded > cds@lowerDetectionLimit)
nzGenes <- names(nzGenes[nzGenes > min_cells_detected])
x <- t(t(rounded[nzGenes, ])/pData(cds[nzGenes, ])$Size_Factor)
xim <- mean(1/pData(cds[nzGenes, ])$Size_Factor)
f_expression_mean <- Matrix::rowMeans(x)
f_expression_var <- Matrix::rowMeans((x - f_expression_mean)^2)
disp_guess_meth_moments <- f_expression_var - xim * f_expression_mean
disp_guess_meth_moments <- disp_guess_meth_moments/(f_expression_mean^2)
res <- data.frame(mu = as.vector(f_expression_mean),
disp = as.vector(disp_guess_meth_moments))
res[res$mu == 0]$mu = NA
res[res$mu == 0]$disp = NA
res$disp[res$disp < 0] <- 0
res <- cbind(gene_id = row.names(fData(cds[nzGenes, ])),
res)
res
}
parametricDispersionFit <- function (disp_table, verbose = FALSE,
initial_coefs = c(1e-06, 1)) {
coefs <- initial_coefs
iter <- 0
while (TRUE) {
residuals <- disp_table$disp/(coefs[1] + coefs[2]/disp_table$mu)
good <- disp_table[which((residuals > initial_coefs[1]) &
(residuals < 10000)), ]
if (verbose)
fit <- glm(disp ~ I(1/mu), data = good, family = Gamma(link = "identity"),
start = coefs)
else suppressWarnings(fit <- glm(disp ~ I(1/mu), data = good,
family = Gamma(link = "identity"),
start = coefs))
oldcoefs <- coefs
coefs <- coefficients(fit)
if (coefs[1] < initial_coefs[1]) {
coefs[1] <- initial_coefs[1]
}
if (coefs[2] < 0) {
stop("Parametric dispersion fit failed. Try a local fit and/or a pooled estimation. (See '?estimateDispersions')")
}
if (sum(log(coefs/oldcoefs)^2) < initial_coefs[1])
break
iter <- iter + 1
if (iter > 10) {
warning("Dispersion fit did not converge.")
break
}
}
if (!all(coefs > 0)) {
stop("Parametric dispersion fit failed. Try a local fit and/or a pooled estimation. (See '?estimateDispersions')")
}
list(fit, coefs)
}
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