# basic operators --------------------------------------------------------- test_that("math operators works", { x_array = array(1:24, dim = c(4,2,3), dimnames = list(NULL,letters[1:2],letters[3:5])) x = new_rvar(x_array) y_array = array(c(2:13,12:1), dim = c(4,2,3)) y = new_rvar(y_array) expect_equal(log(x), new_rvar(log(x_array))) expect_equal(-x, new_rvar(-x_array)) expect_equal(x + 2, new_rvar(x_array + 2)) expect_equal(2 + x, new_rvar(x_array + 2)) expect_equal(x + y, new_rvar(x_array + y_array)) expect_equal(x - 2, new_rvar(x_array - 2)) expect_equal(2 - x, new_rvar(2 - x_array)) expect_equal(x - y, new_rvar(x_array - y_array)) expect_equal(x * 2, new_rvar(x_array * 2)) expect_equal(2 * x, new_rvar(x_array * 2)) expect_equal(x * y, new_rvar(x_array * y_array)) expect_equal(x / 2, new_rvar(x_array / 2)) expect_equal(2 / x, new_rvar(2 / x_array)) expect_equal(x / y, new_rvar(x_array / y_array)) expect_equal(x ^ 2, new_rvar((x_array) ^ 2)) expect_equal(2 ^ x, new_rvar(2 ^ (x_array))) expect_equal(x ^ y, new_rvar(x_array ^ y_array)) # ensure broadcasting of constants retains shape z2 <- new_rvar(array(1, dim = c(1,1))) z4 <- new_rvar(array(2, dim = c(1,1,1,1))) expect_equal(z2 + z4, new_rvar(array(3, dim = c(1,1,1,1)))) }) test_that("math operators work on rvar_factors", { x_array = array(letters[1:24], dim = c(4,2,3), dimnames = list(NULL,letters[1:2],letters[3:5])) x = rvar_factor(x_array) x_ordered = rvar_ordered(x_array) expect_error(log(x), "Cannot apply `log` function to rvar_factor") expect_error(x + 1, "Cannot apply `\\+` operator to rvar_factor") expect_error(1 + x, "Cannot apply `\\+` operator to rvar_factor") expect_error(log(x_ordered), "Cannot apply `log` function to rvar_factor") expect_error(x_ordered + 1, "Cannot apply `\\+` operator to rvar_ordered") expect_error(1 + x_ordered, "Cannot apply `\\+` operator to rvar_ordered") }) test_that("logical operators work", { x_array = c(TRUE,TRUE,FALSE,FALSE) y_array = c(TRUE,FALSE,TRUE,FALSE) x = as_rvar(x_array) y = as_rvar(y_array) expect_equal(x | y_array, as_rvar(x_array | y_array)) expect_equal(y_array | x, as_rvar(x_array | y_array)) expect_equal(x | y, as_rvar(x_array | y_array)) expect_equal(x & y_array, as_rvar(x_array & y_array)) expect_equal(y_array & x, as_rvar(x_array & y_array)) expect_equal(x & y, as_rvar(x_array & y_array)) }) test_that("comparison operators work", { x_array = array(1:24, dim = c(4,2,3)) x = new_rvar(x_array) y_array = array(c(2:13,12:1), dim = c(4,2,3)) y = new_rvar(y_array) expect_equal(x < 5, new_rvar(x_array < 5)) expect_equal(5 < x, new_rvar(5 < x_array)) expect_equal(x < y, new_rvar(x_array < y_array)) expect_equal(x <= 5, new_rvar(x_array <= 5)) expect_equal(5 <= x, new_rvar(5 <= x_array)) expect_equal(x <= y, new_rvar(x_array <= y_array)) expect_equal(x > 5, new_rvar(x_array > 5)) expect_equal(5 > x, new_rvar(5 > x_array)) expect_equal(x > y, new_rvar(x_array > y_array)) expect_equal(x >= 5, new_rvar(x_array >= 5)) expect_equal(5 >= x, new_rvar(5 >= x_array)) expect_equal(x >= y, new_rvar(x_array >= y_array)) expect_equal(x == 5, new_rvar(x_array == 5)) expect_equal(5 == x, new_rvar(5 == x_array)) expect_equal(x == y, new_rvar(x_array == y_array)) expect_equal(x != 5, new_rvar(x_array != 5)) expect_equal(5 != x, new_rvar(5 != x_array)) expect_equal(x != y, new_rvar(x_array != y_array)) }) test_that("comparison operators work on rvar_factors", { x_array = array(1:24, dim = c(4,2,3)) x_array_letters = array(letters[1:24], dim = c(4,2,3)) x = rvar_factor(x_array_letters, levels = letters) y_array = array(c(2:13,12:1), dim = c(4,2,3)) y_array_letters = array(letters[c(2:13,12:1)], dim = c(4,2,3)) y = rvar_factor(y_array_letters, levels = letters) expect_error(x < "e", "Cannot apply `<` operator to rvar_factor") expect_error(x > "e", "Cannot apply `>` operator to rvar_factor") expect_error(x <= "e", "Cannot apply `<=` operator to rvar_factor") expect_error(x >= "e", "Cannot apply `>=` operator to rvar_factor") expect_equal(x == "e", new_rvar(x_array == 5)) expect_equal("e" == x, new_rvar(5 == x_array)) expect_equal(x == y, new_rvar(x_array == y_array)) expect_equal(x == "XX", new_rvar(x_array == 0)) expect_equal("XX" == x, new_rvar(0 == x_array)) expect_equal(x != "e", new_rvar(x_array != 5)) expect_equal("e" != x, new_rvar(5 != x_array)) expect_equal(x != y, new_rvar(x_array != y_array)) expect_equal(x != "XX", new_rvar(x_array != 0)) expect_equal("XX" != x, new_rvar(0 != x_array)) }) test_that("comparison operators work on rvar_ordereds", { x_array = array(1:24, dim = c(4,2,3)) x_array_letters = array(letters[1:24], dim = c(4,2,3)) x = rvar_ordered(x_array_letters, levels = letters) y_array = array(c(2:13,12:1), dim = c(4,2,3)) y_array_letters = array(letters[c(2:13,12:1)], dim = c(4,2,3)) y = rvar_ordered(y_array_letters, levels = letters) expect_equal(x < "e", new_rvar(x_array < 5)) expect_equal("e" < x, new_rvar(5 < x_array)) expect_equal(x < y, new_rvar(x_array < y_array)) expect_equal(x < "XX", new_rvar(x_array < NA)) expect_equal("XX" < x, new_rvar(NA < x_array)) expect_equal(x <= "e", new_rvar(x_array <= 5)) expect_equal("e" <= x, new_rvar(5 <= x_array)) expect_equal(x <= y, new_rvar(x_array <= y_array)) expect_equal(x <= "XX", new_rvar(x_array <= NA)) expect_equal("XX" <= x, new_rvar(NA <= x_array)) expect_equal(x > "e", new_rvar(x_array > 5)) expect_equal("e" > x, new_rvar(5 > x_array)) expect_equal(x > y, new_rvar(x_array > y_array)) expect_equal(x > "XX", new_rvar(x_array > NA)) expect_equal("XX" > x, new_rvar(NA > x_array)) expect_equal(x >= "e", new_rvar(x_array >= 5)) expect_equal("e" >= x, new_rvar(5 >= x_array)) expect_equal(x >= y, new_rvar(x_array >= y_array)) expect_equal(x >= "XX", new_rvar(x_array >= NA)) expect_equal("XX" >= x, new_rvar(NA >= x_array)) expect_equal(x == "e", new_rvar(x_array == 5)) expect_equal("e" == x, new_rvar(5 == x_array)) expect_equal(x == y, new_rvar(x_array == y_array)) expect_equal(x == "XX", new_rvar(x_array == 0)) expect_equal("XX" == x, new_rvar(0 == x_array)) expect_equal(x != "e", new_rvar(x_array != 5)) expect_equal("e" != x, new_rvar(5 != x_array)) expect_equal(x != y, new_rvar(x_array != y_array)) expect_equal(x != "XX", new_rvar(x_array != 0)) expect_equal("XX" != x, new_rvar(0 != x_array)) }) test_that("functions in the Math generic with extra arguments work", { expect_equal(round(rvar(11), -1), rvar(10)) expect_equal(signif(rvar(11), 1), rvar(10)) expect_equal(log(rvar(c(2,4,8)), base = 2), rvar(1:3)) }) test_that("cumulative functions work", { x_array = array(1:12, dim = c(2,2,3)) x = new_rvar(x_array) cumsum_ref = new_rvar(rbind( cumsum(draws_of(x)[1,,]), cumsum(draws_of(x)[2,,]) )) expect_equal(cumsum(x), cumsum_ref) cumprod_ref = new_rvar(rbind( cumprod(draws_of(x)[1,,]), cumprod(draws_of(x)[2,,]) )) expect_equal(cumprod(x), cumprod_ref) cummax_ref = new_rvar(rbind( cummax(draws_of(x)[1,,]), cummax(draws_of(x)[2,,]) )) expect_equal(cummax(x), cummax_ref) cummin_ref = new_rvar(rbind( cummin(draws_of(x)[1,,]), cummin(draws_of(x)[2,,]) )) expect_equal(cummin(x), cummin_ref) }) # matrix stuff ------------------------------------------------------------ test_that("matrix multiplication works", { x_array = array(1:24, dim = c(4,2,3)) x = new_rvar(x_array) y_array = array(c(2:13,12:1), dim = c(4,3,2)) y = new_rvar(y_array) xy_ref = new_rvar(abind::abind(along = 0, x_array[1,,] %*% y_array[1,,], x_array[2,,] %*% y_array[2,,], x_array[3,,] %*% y_array[3,,], x_array[4,,] %*% y_array[4,,] )) expect_equal(x %**% y, xy_ref) x_array = array(1:6, dim = c(2,3)) x = new_rvar(x_array) y_array = array(7:12, dim = c(2,3)) y = new_rvar(y_array) xy_ref = new_rvar(abind::abind(along = 0, x_array[1,] %*% y_array[1,], x_array[2,] %*% y_array[2,] )) expect_equal(x %**% y, xy_ref) # automatic promotion to row/col vector of numeric vectors x_meany_ref = new_rvar(abind::abind(along = 0, x_array[1,] %*% colMeans(y_array), x_array[2,] %*% colMeans(y_array) )) expect_equal(x %**% colMeans(y_array), x_meany_ref) meanx_y_ref = new_rvar(abind::abind(along = 0, colMeans(x_array) %*% y_array[1,], colMeans(x_array) %*% y_array[2,] )) expect_equal(colMeans(x_array) %**% y, meanx_y_ref) # dimension name preservation m1 <- as_rvar(diag(1:3)) dimnames(m1) <- list(a = paste0("a", 1:3), b = paste0("b", 1:3)) m2 <- as_rvar(diag(1:3)[,1:2]) dimnames(m2) <- list(c = paste0("c", 1:3), d = paste0("d", 1:2)) expect_equal(dimnames(m1 %**% m2), list(a = paste0("a", 1:3), d = paste0("d", 1:2))) # errors x_array = array(1:24, dim = c(4,1,2,3)) x = new_rvar(x_array) expect_error(x %**% 1, "not a vector or matrix") expect_error(1 %**% x, "not a vector or matrix") expect_error(rvar_factor("a") %**% x, "Cannot apply `%\\*\\*%` operator to rvar_factor") expect_error(x %**% rvar_factor("a"), "Cannot apply `%\\*\\*%` operator to rvar_factor") }) test_that("diag works", { Sigma <- as_draws_rvars(example_draws("multi_normal"))$Sigma sigma_diag <- c(Sigma[1,1], Sigma[2,2], Sigma[3,3]) expect_equal(diag(Sigma), sigma_diag) Sigma_ref <- Sigma Sigma_ref[1,1] <- 2 Sigma_ref[2,2] <- 3 Sigma_ref[3,3] <- 4 Sigma_test <- Sigma diag(Sigma_test) <- 2:4 expect_equal(Sigma_test, Sigma_ref) Sigma_ref <- Sigma Sigma_ref[1,2:3] <- 0 Sigma_ref[2,c(1,3)] <- 0 Sigma_ref[3,1:2] <- 0 expect_equal(diag(sigma_diag), Sigma_ref) expect_equal(diag(sigma_diag, nrow = 2), Sigma_ref[1:2,1:2]) expect_equal(diag(sigma_diag, nrow = 2, ncol = 2), Sigma_ref[1:2,1:2]) expect_equal(diag(sigma_diag, nrow = 2, ncol = 3), Sigma_ref[1:2,]) expect_equal(diag(sigma_diag, nrow = 1, ncol = 3), Sigma_ref[1,]) expect_equal(diag(sigma_diag, nrow = 0, ncol = 3), rvar(array(numeric(), dim = c(400,0)), nchains = 4)) expect_equal(diag(sigma_diag, ncol = 2), Sigma_ref[,1:2]) expect_equal(diag(sigma_diag, ncol = 1), Sigma_ref[,1]) expect_equal(diag(sigma_diag, ncol = 0), rvar(array(numeric(), dim = c(400,0)), nchains = 4)) expect_equal(diag(sigma_diag, nrow = 4), cbind(rbind(Sigma_ref, 0), c(rvar(0), 0, 0, Sigma[1,1]))) # ensure our override of base diag does not break its weird corner cases expect_equal(diag(matrix(1:9, nrow = 3)), c(1, 5, 9)) expect_equal(diag(1:2), matrix(c(1, 0, 0, 2), nrow = 2)) expect_equal(diag(3L), matrix(c(1, 0, 0, 0, 1, 0, 0, 0, 1), nrow = 3)) expect_equal(diag(nrow = 3), matrix(c(1, 0, 0, 0, 1, 0, 0, 0, 1), nrow = 3)) }) test_that("Cholesky decomposition works", { Sigma <- as_draws_rvars(example_draws("multi_normal"))$Sigma # adding dimensions because we should expect these to be dropped dimnames(Sigma) <- list( a = paste0("a", 1:3), b = paste0("b", 1:3) ) expect_equal(chol(Sigma), rdo(chol(Sigma))) expect_error(chol(rvar(1)), "must be a random matrix") }) # array transpose and permutation ----------------------------------------- test_that("vector transpose works", { x_array = array(1:6, dim = c(2,3), dimnames = list(NULL, c("a","b","c"))) x = new_rvar(x_array) x_array_t = array(1:6, dim = c(2,1,3), dimnames = list(NULL, NULL, c("a","b","c"))) x_t = new_rvar(x_array_t) x_array_t_t = array(1:6, dim = c(2,3,1), dimnames = list(NULL, c("a","b","c"), NULL)) x_t_t = new_rvar(x_array_t_t) # ensure it works with dimnames... expect_equal(t(x), x_t) expect_equal(t(t(x)), x_t_t) # ... and without dimnames dimnames(x) = NULL dimnames(x_t) = NULL dimnames(x_t_t) = NULL expect_equal(t(x), x_t) expect_equal(t(t(x)), x_t_t) }) test_that("vector transpose works on rvar_factor", { x_array = array(letters[1:6], dim = c(2,3), dimnames = list(NULL, c("a","b","c"))) x = rvar_factor(x_array) x_array_t = array(letters[1:6], dim = c(2,1,3), dimnames = list(NULL, NULL, c("a","b","c"))) x_t = rvar_factor(x_array_t) x_array_t_t = array(letters[1:6], dim = c(2,3,1), dimnames = list(NULL, c("a","b","c"), NULL)) x_t_t = rvar_factor(x_array_t_t) # ensure it works with dimnames... expect_equal(t(x), x_t) expect_equal(t(t(x)), x_t_t) }) test_that("vector transpose works on rvar_ordered", { x_array = array(letters[1:6], dim = c(2,3), dimnames = list(NULL, c("a","b","c"))) x = rvar_ordered(x_array) x_array_t = array(letters[1:6], dim = c(2,1,3), dimnames = list(NULL, NULL, c("a","b","c"))) x_t = rvar_ordered(x_array_t) x_array_t_t = array(letters[1:6], dim = c(2,3,1), dimnames = list(NULL, c("a","b","c"), NULL)) x_t_t = rvar_ordered(x_array_t_t) # ensure it works with dimnames... expect_equal(t(x), x_t) expect_equal(t(t(x)), x_t_t) }) test_that("matrix transpose works", { x_array = array(1:24, dim = c(4,3,2)) x = new_rvar(x_array) x_t = new_rvar(aperm(x_array, c(1,3,2))) expect_error(t(rvar())) expect_equal(t(x), x_t) expect_equal(t(t(x)), x) expect_equal(t(new_rvar(array(1:10, c(1,10)))), new_rvar(array(1:10, c(1,1,10)))) expect_equal(t(new_rvar(array(1:10, c(2,1,5)))), new_rvar(array(1:10, c(2,5,1)))) expect_equal(t(new_rvar(array(1:10, c(2,1,5)))), new_rvar(array(1:10, c(2,5,1)))) expect_equal(t(new_rvar(array(1:10, c(2,5)))), new_rvar(array(1:10, c(2,1,5)))) }) test_that("matrix transpose works on rvar_factor", { x_array = array(letters[1:24], dim = c(4,3,2)) x = rvar_factor(x_array) x_t = rvar_factor(aperm(x_array, c(1,3,2))) expect_equal(t(x), x_t) expect_equal(t(t(x)), x) }) test_that("matrix transpose works on rvar_ordered", { x_array = array(letters[1:24], dim = c(4,3,2)) x = rvar_ordered(x_array) x_t = rvar_ordered(aperm(x_array, c(1,3,2))) expect_equal(t(x), x_t) expect_equal(t(t(x)), x) }) test_that("array permutation works", { x_array = array( 1:24, dim = c(2,2,3,2), dimnames = list(NULL, A = paste0("a", 1:2), B = paste0("b", 1:3), C = paste0("c", 1:2)) ) x = new_rvar(x_array) x_perm = new_rvar(aperm(x_array, c(1,2,4,3))) expect_equal(aperm(x, c(1,3,2)), x_perm) }) test_that("array permutation works on rvar_factor", { x_array = array( letters[1:24], dim = c(2,2,3,2), dimnames = list(NULL, A = paste0("a", 1:2), B = paste0("b", 1:3), C = paste0("c", 1:2)) ) x = rvar_factor(x_array) x_perm = rvar_factor(aperm(x_array, c(1,2,4,3))) expect_equal(aperm(x, c(1,3,2)), x_perm) }) test_that("array permutation works on rvar_ordered", { x_array = array( letters[1:24], dim = c(2,2,3,2), dimnames = list(NULL, A = paste0("a", 1:2), B = paste0("b", 1:3), C = paste0("c", 1:2)) ) x = rvar_ordered(x_array) x_perm = rvar_ordered(aperm(x_array, c(1,2,4,3))) expect_equal(aperm(x, c(1,3,2)), x_perm) })