https://github.com/cran/cutpointr
Revision d461e559d4a76b7fcbd728470ca12cce56d3ffab authored by Christian Thiele on 19 June 2020, 11:00:06 UTC, committed by cran-robot on 19 June 2020, 11:00:06 UTC
1 parent bbfd829
Tip revision: d461e559d4a76b7fcbd728470ca12cce56d3ffab authored by Christian Thiele on 19 June 2020, 11:00:06 UTC
version 1.0.32
version 1.0.32
Tip revision: d461e55
utils.R
find_metric_name <- function(object) {
if ("subgroup" %in% colnames(object)) {
return(colnames(object)[5])
} else {
return(colnames(object)[4])
}
}
find_metric_name_boot <- function(object) {
if ("subgroup" %in% colnames(object)) {
return(colnames(object)[6])
} else {
return(colnames(object)[5])
}
}
default_cols <- c("m", "subgroup", "direction", "optimal_cutpoint",
"method", "acc", "sensitivity", "specificity", "AUC",
"pos_class", "neg_class", "prevalence",
"outcome", "predictor", "grouping", "data", "roc_curve",
"boot", "tn", "fn", "tp", "fp", "tpr", "tnr", "fpr", "fnr")
check_method_cols <- function(method_result) {
cn <- colnames(method_result)
n_col <- ncol(method_result)
identified_cols <- 0
oc_col <- which(cn == "optimal_cutpoint")
if (!is.null(oc_col)) identified_cols <- identified_cols + 1
if ("roc_curve" %in% cn) {
roc_col <- which(cn == "roc_curve")
identified_cols <- identified_cols + 1
}
if (identified_cols == 1 & n_col == 2) {
metric_col <- (1:n_col)[-oc_col]
} else if (identified_cols < n_col) {
stopifnot(exists("roc_col"))
metric_col <- (1:n_col)[-c(oc_col, roc_col)]
if (length(metric_col) >= 2) {
stop(paste("method function returned too many columns.",
"Should return optimal_cutpoint, roc_curve (optional)",
"and a metric column (optional)."))
}
metric_name <- cn[metric_col]
if (metric_name %in% default_cols) {
colnames(method_result)[metric_col] <- paste0("metric_", metric_name)
}
}
return(method_result)
}
check_metric_name <- function(met) {
# Numeric vector
if (!is.array(met) & is.numeric(met)) return(met)
cn <- colnames(met)
if (cn %in% default_cols) {
colnames(met) <- paste0("metric_", cn)
return(met)
} else {
return(met)
}
}
check_method_name <- function(mod_name) {
if (length(mod_name) > 1) {
if (mod_name[1] %in% c("::", ":::") & length(mod_name) == 3) {
mod_name <- mod_name[3]
} else {
stop("Could not parse method name")
}
}
return(mod_name)
}
check_colnames <- function(cutpointr_object) {
if ("subgroup" %in% colnames(cutpointr_object)) col_nr <- 4 else col_nr <- 3
metric_name <- colnames(cutpointr_object)[col_nr]
if (metric_name %in% default_cols) {
metric_name2 <- paste0("metric_", metric_name)
colnames(cutpointr_object)[col_nr] <- metric_name2
cutpointr_object$metric_name <- metric_name2
} else {
cutpointr_object$metric_name <- metric_name
}
return(cutpointr_object)
}
check_roc_curve <- function(object) {
if (!("roc_cutpointr" %in% class(object$roc_curve[[1]]))) {
stop(paste("roc_curve as returned by the method function is not an",
"object of the class roc_cutpointr"))
}
}
has_column <- function(x, colname) {
if (colname %in% colnames(x) | colname %in% names(x)) {
return(TRUE)
} else {
return(FALSE)
}
}
has_boot_results <- function(x) {
if (has_column(x, "boot")) {
if (all(is.na(x[["boot"]]))) {
return(FALSE)
} else {
return(TRUE)
}
} else {
return(FALSE)
}
}
ifel_pos_neg <- function(logi_vec, pos_class, neg_class) {
predictions <- rep(neg_class, length(logi_vec))
predictions[logi_vec] <- pos_class
return(predictions)
}
get_fnth <- function(x, n = 1) {
x <- unlist(x)
if (length(x) == 1) {
return(x[1])
} else {
return(x[n])
}
stop("no conditions apply in get_fnth")
}
get_numeric_cols <- function(x, class_col) {
cols <- colnames(x)[unlist(lapply(x, is.numeric))]
cols <- cols[cols != class_col]
cols
}
midpoint <- function(oc, x, direction) {
sapply(oc, function(oc) {
x <- c(oc, x)
if (direction == ">=") {
x <- sort(unique(x))
} else {
x <- sort(unique(x), decreasing = TRUE)
}
if (direction == ">=") {
mean(c(oc, x[utils::tail(which(x <= oc), 1) - 1]))
} else if (direction == "<=") {
mean(c(oc, x[utils::tail(which(x >= oc), 1) - 1]))
}
})
}
apply_break_ties <- function(oc, f) {
stopifnot(nrow(oc) == 1)
optimal_cutpoint <- f(oc[["optimal_cutpoint"]][[1]])
if (length(optimal_cutpoint) > 1) {
optimal_cutpoint <- list(optimal_cutpoint)
}
oc$optimal_cutpoint <- optimal_cutpoint
return(oc)
}
get_opt_ind <- function(roc_curve, oc, direction) {
stopifnot(is.numeric(oc) | is.na(oc))
sapply(oc, function(x) {
if (direction == ">=") {
opt_ind <- max(which(roc_curve$x.sorted >= x))
} else if (direction == "<=") {
opt_ind <- max(which(roc_curve$x.sorted <= x))
}
return(opt_ind)
})
}
summary_sd <- function(x, round_digits = 3) {
x <- unlist(x)
s <- summary(x)[1:6]
result <- c(s[1],
stats::quantile(x, 0.05, na.rm = TRUE),
s[2:5],
stats::quantile(x, 0.95, na.rm = TRUE),
s[6],
SD = stats::sd(x, na.rm = TRUE),
NAs = sum(is.na(x)))
round(result, round_digits)
}
# If the output of the metric function is no named matrix with one column,
# convert it to one. Also run some checks.
sanitize_metric <- function(m, m_name, n, silent = TRUE) {
if ("data.frame" %in% class(m)) {
m <- as.matrix(m)
}
if (!is.null(dim(m))) {
if (dim(m)[2] == 1 & ("matrix" %in% class(m))) {
res <- m
if (is.null(colnames(res))) colnames(res) <- m_name
} else {
stop(paste("The metric function should return a numeric vector",
"or a one-column matrix or data.frame."))
}
} else if (is.numeric(m)) {
res <- matrix(m, ncol = 1, dimnames = list(NULL, m_name))
} else {
stop(paste("Can't process metric of type", class(m)))
}
finite_res <- is.finite(res)
if (any(!finite_res)) {
if (!silent) message("Converting non-finite metric values to NA")
res[!finite_res] <- NA
}
if (nrow(res) != n) {
stop("Number of returned metric values not equal to n")
}
colnames(res) <- make.names(colnames(res))
return(res)
}
only_one_unique <- function(x) {
if (is.character(x) | is.factor(x)) {
one_unique_char(x)
} else {
one_unique_num(x)
}
}
which_cpp <- function(x, y) {
if (is.numeric(x)) {
return(which_are_num(x, y))
} else {
return(which_are_char(x, y))
}
}
is_equal_cpp <- function(x, y) {
if (is.numeric(x)) {
return(is_equal_cpp_num(x, y))
} else {
return(is_equal_cpp_char(x, as.character(y)))
}
}
na_inf_omit <- function(x) {
x <- stats::na.omit(x)
x <- x[is.finite(x)]
return(x)
}
.onUnload <- function (libpath) {
library.dynam.unload("cutpointr", libpath)
}
add_list <- function(x, y, name) {
if (length(y) > 1) {
x[[name]] <- list(y)
} else {
x[[name]] <- y
}
return(x)
}
# rbind list elements that are tibbles with different column types (list or dbl,
# may be necessary for bootstrap results, if only one bootstrap resulted in
# multiple optimal cutpoints)
# Convert non-list columns to list so that bind_rows doesn't complain
prepare_bind_rows <- function(x) {
stopifnot(inherits(x, "list"))
if (length(x) < 2) {
return(x)
} else {
list_cols <- purrr::map(x, function(df) {
df %>%
purrr::map(function(col) (is.list(col)))
})
list_cols <- purrr::map(list_cols, function(coltypes) {
which(unlist(coltypes))
})
list_cols <- unique(unlist(list_cols))
x <- purrr::map(x, function(x) {
dplyr::mutate_at(.tbl = x, .vars = list_cols, .funs = function(x) {
if (!is.list(x)) {
purrr::map(x, function(x) x)
} else {
x
}
})
})
return(x)
}
}
# Return indices for observations based on nonparametric bootstrap per class.
# Preliminary tests suggested that per_class = FALSE leads to better
# confidence intervals.
simple_boot <- function(ind_pos = NULL, ind_neg = NULL,
data = NULL, dep_var = NULL,
stratify) {
if (stratify) {
b_ind_pos <- sample(ind_pos, size = length(ind_pos), replace = TRUE)
b_ind_neg <- sample(ind_neg, size = length(ind_neg), replace = TRUE)
return(c(b_ind_pos, b_ind_neg))
} else {
b_ind <- sample(1:nrow(data), size = nrow(data), replace = TRUE)
return(b_ind)
}
}
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