context("plots") test_that("Test that plot_loglik_vs_rank works",{ set.seed(1) dat <- generate_test_data(80,100,3) X <- dat$X # Fit matrix factorizations with rank k = 2, 3, 5, 10. capture.output(fit2 <- fit_poisson_nmf(X,k = 2,numiter = 100)) capture.output(fit3 <- fit_poisson_nmf(X,k = 3,numiter = 100)) capture.output(fit5 <- fit_poisson_nmf(X,k = 5,numiter = 100)) capture.output(fit10 <- fit_poisson_nmf(X,k = 10,numiter = 100)) # Plot log-likelihood vs. rank. p1 <- plot_loglik_vs_rank(list(fit2,fit3,fit5,fit10)) p2 <- plot_loglik_vs_rank(lapply(list(fit2,fit3,fit5,fit10), poisson2multinom)) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") }) test_that("Test that pca_plot and pca_hexbin_plot work",{ set.seed(1) k <- 3 X <- simulate_toy_gene_data(n = 400,m = 40,k = k,s = 1000)$X capture.output(fit1 <- fit_poisson_nmf(X,k = k,numiter = 100, control = list(extrapolate = TRUE))) fit2 <- poisson2multinom(fit1) # Test pca_plot. p1 <- pca_plot(fit1) p2 <- pca_plot(fit2) p3 <- pca_hexbin_plot(fit2) p4 <- pca_hexbin_plot(fit2) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") expect_s3_class(p3,"ggplot") expect_s3_class(p4,"ggplot") # Test the other variants of pca_plot. y <- factor(apply(fit2$L,1,which.max)) levels(y) <- paste0("k",1:k) p5 <- pca_plot(fit1,fill = "none") p6 <- pca_plot(fit1,fill = fit2$L[,1]) p7 <- pca_plot(fit1,fill = y) expect_s3_class(p5,"ggplot") expect_s3_class(p6,"ggplot") expect_s3_class(p7,"ggplot") }) test_that("Test that other plotting functions work",{ set.seed(1) dat <- generate_test_data(200,100,3) X <- dat$X capture.output(fit0 <- init_poisson_nmf(X,k = 3)) capture.output( fit1 <- fit_poisson_nmf(X,fit0 = fit0,numiter = 50,method = "scd", control = list(extrapolate = TRUE))) capture.output( fit2 <- fit_poisson_nmf(X,fit0 = fit0,numiter = 50,method = "em", control = list(extrapolate = TRUE))) # Test plot_progress. plot_progress(list(scd = fit1,em = fit2),y = "loglik") plot_progress(list(scd = fit1,em = fit2),y = "dev") plot_progress(list(scd = fit1,em = fit2),y = "res") plot_progress(list(scd = poisson2multinom(fit1),em = poisson2multinom(fit2))) # Test loadings_plot. x <- factor(sample(1:4,200,replace = TRUE)) p1 <- loadings_plot(fit1,x) p2 <- loadings_plot(poisson2multinom(fit1),x) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") # Test structure_plot. grouping <- factor(apply(poisson2multinom(fit1)$L,1,which.max)) capture.output(y <- drop(tsne_from_topics(poisson2multinom(fit1),dims = 1))) capture.output(p1 <- structure_plot(fit1)) capture.output(p2 <- structure_plot(fit1,grouping = grouping,gap = 5)) capture.output(p3 <- structure_plot(poisson2multinom(fit1)$L)) capture.output(p4 <- structure_plot(fit1$L)) capture.output(p5 <- structure_plot(fit1,loadings_order = order(y))) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") expect_s3_class(p3,"ggplot") expect_s3_class(p4,"ggplot") expect_s3_class(p5,"ggplot") # Test the "plot" S3 method (which creates a Structure plot). fit2 <- poisson2multinom(fit1) capture.output(p1 <- plot(fit1)) capture.output(p2 <- plot(fit2)) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") skip_if(on_cran) # Test tsne_plot and umap_plot. capture.output(p1 <- tsne_plot(fit1,fill = "loading")) capture.output(p2 <- tsne_plot(fit2,fill = "loading")) capture.output(p3 <- umap_plot(fit1,fill = "loading",verbose = FALSE)) capture.output(p4 <- umap_plot(fit2,fill = "loading",verbose = FALSE)) expect_s3_class(p1,"ggplot") expect_s3_class(p2,"ggplot") expect_s3_class(p3,"ggplot") expect_s3_class(p4,"ggplot") })