Mercurial > repos > iuc > scater_filter
view scater-plot-dist-scatter.R @ 3:652923ce664f draft default tip
"planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/scater commit 9961b5acbf9081f10e14bc272406b36854fa2924"
author | iuc |
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date | Mon, 08 Nov 2021 12:03:34 +0000 |
parents | 7a365ec81b52 |
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#!/usr/bin/env Rscript # Plot the distribution of read counts and feature counts, side by side, then a scatter plot of read counts vs feature counts below # Load optparse we need to check inputs library(optparse) library(workflowscriptscommon) library(LoomExperiment) library(scater) library(ggpubr) library(scales) # parse options option_list <- list( make_option( c("-i", "--input-loom"), action = "store", default = NA, type = "character", help = "A SingleCellExperiment object file in Loom format." ), make_option( c("-o", "--output-plot-file"), action = "store", default = NA, type = "character", help = "Path of the PDF output file to save plot to." ), make_option( c("-l", "--log-scale"), action = "store_true", default = FALSE, type = "logical", help = "Plot on log scale (recommended for large datasets)." ) ) opt <- wsc_parse_args(option_list, mandatory = c("input_loom", "output_plot_file")) # Check parameter values if (! file.exists(opt$input_loom)) { stop((paste("File", opt$input_loom, "does not exist"))) } # Filter out unexpressed features sce <- import(opt$input_loom, format = "loom", type = "SingleCellLoomExperiment") # Do the scatter plot of reads vs genes total_counts <- sce$total total_features <- sce$detected count_feats <- cbind(total_counts, total_features) cf_dm <- as.data.frame(count_feats) # Calculate binwidths for reads and features plots. Use 20 bins read_bins <- max(total_counts / 1e6) / 20 feat_bins <- max(total_features) / 20 plot1 <- qplot(total_counts / 1e6, geom = "histogram", binwidth = read_bins, ylab = "Number of cells", xlab = "Read counts (millions)", fill = I("darkseagreen3")) + ggtitle("Read counts per cell") plot2 <- qplot(total_features, geom = "histogram", binwidth = feat_bins, ylab = "Number of cells", xlab = "Feature counts", fill = I("darkseagreen3")) + ggtitle("Feature counts per cell") plot3 <- ggplot(cf_dm, aes(x = total_counts / 1e6, y = total_features)) + geom_point(shape = 1) + geom_smooth() + xlab("Read count (millions)") + ylab("Feature count") + ggtitle("Scatterplot of reads vs features") plot4 <- plotColData(sce, y = "subsets_Mito_percent", x = "detected") + ggtitle("% MT genes") + geom_point(shape = 1) + theme(text = element_text(size = 15)) + theme(plot.title = element_text(size = 15)) + xlab("Total features") + ylab("% MT") if (! opt$log_scale) { final_plot <- ggarrange(plot1, plot2, plot3, plot4, ncol = 2, nrow = 2) ggsave(opt$output_plot_file, final_plot, device = "pdf") } else { plot1_log <- plot1 + scale_x_continuous(trans = "log10") + scale_y_continuous(trans = "log10") plot2_log <- plot2 + scale_y_continuous(trans = "log10") plot3_log <- plot3 + scale_y_continuous(trans = "log10") plot4_log <- plot4 + scale_y_log10(labels = number) final_plot_log <- ggarrange(plot1_log, plot2_log, plot3_log, plot4_log, ncol = 2, nrow = 2) ggsave(opt$output_plot_file, final_plot_log, device = "pdf") }