test_that("sits summary", { sum <- summary(samples_modis_ndvi) expect_equal(sum$label, c("Cerrado", "Forest", "Pasture", "Soy_Corn")) expect_equal(sum$count, c(379, 131, 344, 364)) sum1 <- suppressWarnings(sits_labels_summary(samples_modis_ndvi)) expect_equal(sum1$label, c("Cerrado", "Forest", "Pasture", "Soy_Corn")) expect_equal(sum1$count, c(379, 131, 344, 364)) }) test_that("summary cube",{ # create a data cube from local files data_dir <- system.file("extdata/raster/mod13q1", package = "sits") cube <- sits_cube( source = "BDC", collection = "MOD13Q1-6.1", data_dir = data_dir ) sum <- capture.output(summary(cube)) expect_true(grepl("MODIS", sum[1])) expect_true(grepl("Median", sum[4])) }) test_that("summary sits accuracy", { data(cerrado_2classes) # split training and test data train_data <- sits_sample(cerrado_2classes, frac = 0.5) test_data <- sits_sample(cerrado_2classes, frac = 0.5) # train a random forest model rfor_model <- sits_train(train_data, sits_rfor()) # classify test data points_class <- sits_classify( data = test_data, ml_model = rfor_model, progress = FALSE ) # measure accuracy acc <- sits_accuracy(points_class) sum <- capture.output(summary(acc)) expect_true(grepl("Accuracy", sum[2])) expect_true(grepl("Kappa", sum[4])) }) test_that("summary sits area accuracy", { # create a data cube from local files data_dir <- system.file("extdata/raster/mod13q1", package = "sits") cube <- sits_cube( source = "BDC", collection = "MOD13Q1-6.1", data_dir = data_dir, progress = FALSE ) sum_cube <- capture.output(suppressWarnings(summary(cube))) expect_true(grepl("TERRA", sum_cube[1])) # create a random forest model rfor_model <- sits_train(samples_modis_ndvi, sits_rfor()) # classify a data cube probs_cube <- sits_classify( data = cube, ml_model = rfor_model, output_dir = tempdir(), progress = FALSE ) sum_probs <- capture.output(suppressWarnings(summary(probs_cube))) expect_true(any(grepl("Min", sum_probs))) # get the variance cube variance_cube <- sits_variance( probs_cube, output_dir = tempdir() ) sum_var <- capture.output(suppressWarnings(summary(variance_cube))) expect_true(any(grepl("80%", sum_var))) # label the probability cube label_cube <- sits_label_classification( probs_cube, output_dir = tempdir(), progress = FALSE ) sum_label <- capture.output(suppressWarnings(summary(label_cube))) expect_true(any(grepl("area_km2", sum_label))) # obtain the ground truth for accuracy assessment ground_truth <- system.file("extdata/samples/samples_sinop_crop.csv", package = "sits" ) # make accuracy assessment as <- sits_accuracy(label_cube, validation = ground_truth) sum_as <- capture.output(summary(as)) expect_true(grepl("Accuracy", sum_as[2])) expect_true(grepl("Mapped", sum_as[11])) expect_true(grepl("Cerrado", sum_as[13])) }) test_that("summary BDC cube",{ tiles <- c("007004", "007005") start_date <- "2022-05-01" end_date <- "2022-08-29" bands <- c("NDVI", "EVI", "B13", "B14", "B15", "B16", "CLOUD") # create a raster cube file from BDC cbers_cube_8d <- .try( { sits_cube( source = "BDC", collection = "CBERS-WFI-8D", tiles = tiles, start_date = start_date, end_date = end_date, progress = FALSE ) }, .default = NULL ) sum2 <- capture.output(summary(cbers_cube_8d, tile = "007004")) expect_true(grepl("007004", sum2[4])) expect_true(grepl("007004", sum2[48])) })