Mercurial > repos > iuc > scater_plot_dist_scatter
diff scater-plot-dist-scatter.R @ 0:4887c4c69847 draft
planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/scater commit 5fdcafccb6c645d301db040dfeed693d7b6b4278
| author | iuc |
|---|---|
| date | Thu, 18 Jul 2019 11:12:33 -0400 |
| parents | |
| children | 2e41b35b5bdd |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/scater-plot-dist-scatter.R Thu Jul 18 11:12:33 2019 -0400 @@ -0,0 +1,62 @@ +#!/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) + +# 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." + ) +) + +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'))) +} + +# Input from Loom format + +scle <- import(opt$input_loom, format='loom', type='SingleCellLoomExperiment') + +#do the scatter plot of reads vs genes +total_counts <- scle$total_counts +total_features <- scle$total_features_by_counts +count_feats <- cbind(total_counts, total_features) +cf_dm <- as.data.frame(count_feats) + +# Calculate binwidths for reads and features plots. Use 20 bins +read_bins <- max(total_counts / 1e6) / 20 +feat_bins <- max(total_features) / 20 + +#make the plots +plot <- ggplot(cf_dm, aes(x=total_counts / 1e6, y=total_features)) + geom_point(shape=1) + geom_smooth() + xlab("Read count (millions)") + + ylab("Feature count") + ggtitle("Scatterplot of reads vs features") +plot1 <- qplot(total_counts / 1e6, geom="histogram", binwidth = read_bins, ylab="Number of cells", xlab = "Read counts (millions)", fill=I("darkseagreen3")) + ggtitle("Read counts per cell") +plot2 <- qplot(total_features, geom="histogram", binwidth = feat_bins, ylab="Number of cells", xlab = "Feature counts", fill=I("darkseagreen3")) + ggtitle("Feature counts per cell") +plot3 <- plotColData(scle, y="pct_counts_MT", x="total_features_by_counts") + ggtitle("% MT genes") + geom_point(shape=1) + theme(text = element_text(size=15)) + theme(plot.title = element_text(size=15)) + +final_plot <- ggarrange(plot1, plot2, plot, plot3, ncol=2, nrow=2) +ggsave(opt$output_plot_file, final_plot, device="pdf")