test_that("sum of kernel weights is 1", { for (p in 2:10) { expect_equal(sum(kernel_weights(p)), 1.0) } }) test_that("Sum of kernel weights is 1, even for subset of domain", { expect_equal(sum(kernel_weights(10L, S = 2:5)), 1.0) }) p <- 10L m <- 100L test_that("Random z have right output dim and the sums are between 1 and p-1", { Z <- sample_Z(p, m = m, feature_names = LETTERS[1:p]) expect_equal(dim(Z), c(m, p)) expect_true(all(rowSums(Z) %in% 1:(p - 1L))) }) test_that("Random z have right output dim and the sums are in subset S", { S <- 2:3 Z <- sample_Z(p, m = m, feature_names = LETTERS[1:p], S = S) expect_equal(dim(Z), c(m, p)) expect_true(all(rowSums(Z) %in% S)) }) test_that("Sampling input structure is ok (deg = 0)", { input <- input_sampling( p, m = m, deg = 0L, paired = TRUE, feature_names = LETTERS[1:p] ) expect_equal(dim(input$Z), c(m, p)) expect_equal(sum(input$w), 1.0) expect_equal(dim(input$A), c(p, p)) expect_equal(unname(diag(input$A)), rep(0.5, p)) }) test_that("Sampling input structure is ok (deg = 0, unpaired)", { input <- input_sampling( p, m = m, deg = 0L, paired = FALSE, feature_names = LETTERS[1:p] ) expect_equal(dim(input$Z), c(m, p)) expect_equal(sum(input$w), 1.0) expect_equal(dim(input$A), c(p, p)) # expect_equal(diag(input$A), rep(0.5, p)) # This is not TRUE }) test_that("Sampling input structure is ok (deg = 1)", { input <- input_sampling( p, m = m, deg = 1L, paired = TRUE, feature_names = LETTERS[1:p] ) expect_equal(dim(input$Z), c(m, p)) expect_true(sum(input$w) < 1.0) expect_equal(dim(input$A), c(p, p)) expect_true(all(diag(input$A) < 0.5)) }) test_that("Sampling input input structure ok (deg = 2)", { input <- input_sampling( p, m = m, deg = 2L, paired = TRUE, feature_names = LETTERS[1:p] ) expect_equal(dim(input$Z), c(m, p)) expect_true(sum(input$w) < 1.0) expect_equal(dim(input$A), c(p, p)) expect_true(all(diag(input$A) < 0.5)) }) test_that("Partly exact A, w, Z equal exact for sufficiently large deg", { for (p in 2:10) { pa <- input_partly_exact(p, deg = trunc(p / 2), feature_names = LETTERS[1:p]) ex <- input_exact(p, feature_names = LETTERS[1:p]) pa_rs <- rowSums(pa$Z) ex_rs <- rowSums(ex$Z) expect_equal(pa$A, ex$A) expect_equal(pa$w[order(pa_rs)], ex$w[order(ex_rs)]) expect_equal(tabulate(pa_rs), tabulate(ex_rs)) } }) test_that("hybrid weights sum to 1 for different p and degree 1", { deg <- 1L expect_error(input_sampling(2L, deg = deg, feature_names = LETTERS[1:p])) expect_error(input_sampling(3L, deg = deg, feature_names = LETTERS[1:p])) for (p in 4:20) { pa <- input_partly_exact(p, deg = deg, feature_names = LETTERS[1:p]) sa <- input_sampling( p, m = 100L, deg = deg, paired = TRUE, feature_names = LETTERS[1:p] ) expect_equal(sum(pa$w) + sum(sa$w), 1.0) } }) test_that("hybrid weights sum to 1 for different p and degree 2", { deg <- 2L expect_error(input_sampling(4L, deg = deg, feature_names = LETTERS[1:p])) expect_error(input_sampling(5L, deg = deg, feature_names = LETTERS[1:p])) for (p in 6:20) { pa <- input_partly_exact(p, deg = deg, feature_names = LETTERS[1:p]) sa <- input_sampling( p, m = 100L, deg = deg, paired = FALSE, feature_names = LETTERS[1:p] ) expect_equal(sum(pa$w) + sum(sa$w), 1L) } }) test_that("partly_exact_Z(p, k) fails for bad p or k", { expect_error(partly_exact_Z(0L, k = 1L, feature_names = LETTERS[1:p])) expect_error(partly_exact_Z(5L, k = 3L, feature_names = LETTERS[1:p])) expect_error(partly_exact_Z(5L, k = 0L, feature_names = LETTERS[1:p])) }) test_that("input_partly_exact(p, deg) fails for bad p or deg", { expect_error(input_partly_exact(2L, deg = 0L, feature_names = LETTERS[1:p])) expect_error(input_partly_exact(5L, deg = 3L, feature_names = LETTERS[1:p])) })