# test that the p_bp and q_bp functions return as expected for all the different # source options library(pedbp) # first, verify that the source input options are as expected x <- tryCatch(q_bp(p_sbp = 1, p_dbp = 1, male = 1, age = numeric(1), source = "Not a real source"), error = function(e) e) stopifnot(identical(class(x), c("simpleError", "error", "condition"))) # the message appears to print in one of two ways, using the unicode \u8220 and # \u8221 for the double quotes when in an interactive session, and \u22 when not # interactive stopifnot( identical(x$message, "'arg' should be one of “martin2022”, “gemelli1990”, “nhlbi”, “lo2013”, “flynn2017”") | identical(x$message, "'arg' should be one of \"martin2022\", \"gemelli1990\", \"nhlbi\", \"lo2013\", \"flynn2017\"") ) ################################################################################ qbp_expected <- list(sbp = rep(NA_real_, 9), dbp = rep(NA_real_, 9)) # return NA for age out of bounds # too young stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 0.9) , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 0.9, source = "martin2022") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 0.9, source = "gemelli1990") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 35.9, source = "lo2013") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 11.9, source = "nhlbi") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 11.9, source = "flynn2017") , qbp_expected , check.attributes = FALSE ) ) ) # too old stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 19*12, source = "flynn2017") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 19*12, source = "nhlbi") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 19*12, source = "martin2022") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 19*12) , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 19*12, source = "lo2013") , qbp_expected , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( q_bp(p_sbp = 1:9/10, p_dbp = 1:9/10, male = 0, age = 13, source = "gemelli1990") , qbp_expected , check.attributes = FALSE ) ) ) ################################################################################ # nhlbi and flynn2017 values will be different from the publications. # The difference is due to having a Gaussian mean and variance estimated by the # three or four percentiles published. The tests here are to verify that the # estimates are not too different. # NOTE: IF THIS FAILS UPDATE THE VIGNETTE fq <- q_bp( p_sbp = flynn2017$bp_percentile/100, p_dbp = flynn2017$bp_percentile/100, male = flynn2017$male, age = flynn2017$age, height_percentile = flynn2017$height_percentile, source = "flynn2017") fp <- p_bp( q_sbp = flynn2017$sbp, q_dbp = flynn2017$dbp, male = flynn2017$male, age = flynn2017$age, height_percentile = flynn2017$height_percentile, source = "flynn2017") nq <- q_bp( p_sbp = nhlbi_bp_norms$bp_percentile/100, p_dbp = nhlbi_bp_norms$bp_percentile/100, male = nhlbi_bp_norms$male, age = nhlbi_bp_norms$age, height_percentile = nhlbi_bp_norms$height_percentile, source = "nhlbi") np <- p_bp( q_sbp = nhlbi_bp_norms$sbp, q_dbp = nhlbi_bp_norms$dbp, male = nhlbi_bp_norms$male, age = nhlbi_bp_norms$age, height_percentile = nhlbi_bp_norms$height_percentile, source = "nhlbi") flynn2017 <- cbind(flynn2017, pedbp_sbp = fq$sbp, pedbp_dbp = fq$dbp, pedbp_sbp_p = fp$sbp_p * 100, pedbp_dbp_p = fp$dbp_p * 100 ) nhlbi_bp_norms <- cbind(nhlbi_bp_norms, pedbp_sbp = nq$sbp, pedbp_dbp = nq$dbp, pedbp_sbp_p = np$sbp_p * 100, pedbp_dbp_p = np$dbp_p * 100 ) # all estimates within 2 mmHg or 2 percentage points stopifnot(max(abs(flynn2017$pedbp_sbp - flynn2017$sbp)) < 2) stopifnot(max(abs(flynn2017$pedbp_dbp - flynn2017$dbp)) < 2) stopifnot(max(abs(flynn2017$pedbp_sbp_p - flynn2017$bp_percentile)) < 2) stopifnot(max(abs(flynn2017$pedbp_dbp_p - flynn2017$bp_percentile)) < 2) stopifnot(max(abs(nhlbi_bp_norms$pedbp_sbp - nhlbi_bp_norms$sbp)) < 2) stopifnot(max(abs(nhlbi_bp_norms$pedbp_dbp - nhlbi_bp_norms$dbp)) < 2) stopifnot(max(abs(nhlbi_bp_norms$pedbp_sbp_p - nhlbi_bp_norms$bp_percentile)) < 2) stopifnot(max(abs(nhlbi_bp_norms$pedbp_dbp_p - nhlbi_bp_norms$bp_percentile)) < 2) if (interactive()) { par(mfrow = c(1, 2)) plot(flynn2017$sbp, flynn2017$pedbp_sbp); abline(0, 1) plot(flynn2017$dbp, flynn2017$pedbp_dbp); abline(0, 1) summary(flynn2017$pedbp_sbp - flynn2017$sbp) summary(flynn2017$pedbp_dbp - flynn2017$dbp) summary(flynn2017$pedbp_sbp_p*100 - flynn2017$bp_percentile) summary(flynn2017$pedbp_dbp_p*100 - flynn2017$bp_percentile) qwraps2::qblandaltman(flynn2017[, c("sbp", "pedbp_sbp")]) qwraps2::qblandaltman(flynn2017[, c("dbp", "pedbp_dbp")]) qwraps2::qblandaltman(flynn2017[, c("bp_percentile", "pedbp_sbp_p")]) qwraps2::qblandaltman(flynn2017[, c("bp_percentile", "pedbp_dbp_p")]) par(mfrow = c(1, 2)) plot(nhlbi_bp_norms$sbp, nhlbi_bp_norms$pedbp_sbp); abline(0, 1) plot(nhlbi_bp_norms$dbp, nhlbi_bp_norms$pedbp_dbp); abline(0, 1) summary(nhlbi_bp_norms$pedbp_sbp - nhlbi_bp_norms$sbp) summary(nhlbi_bp_norms$pedbp_dbp - nhlbi_bp_norms$dbp) summary(nhlbi_bp_norms$pedbp_sbp_p*100 - nhlbi_bp_norms$bp_percentile) summary(nhlbi_bp_norms$pedbp_dbp_p*100 - nhlbi_bp_norms$bp_percentile) qwraps2::qblandaltman(nhlbi_bp_norms[, c("sbp", "pedbp_sbp")]) qwraps2::qblandaltman(nhlbi_bp_norms[, c("dbp", "pedbp_dbp")]) qwraps2::qblandaltman(nhlbi_bp_norms[, c("bp_percentile", "pedbp_sbp_p")]) qwraps2::qblandaltman(nhlbi_bp_norms[, c("bp_percentile", "pedbp_dbp_p")]) } ################################################################################ # Verify that the expected median is returned from q_bp calls for gemelli1990 # and lo2013 stopifnot( isTRUE( all.equal( unname(q_bp(p_sbp = 0.5, p_dbp = 0.5, male = gemelli1990$male, age = gemelli1990$age, source = "gemelli1990")) , unname(as.list(gemelli1990[c("sbp_mean", "dbp_mean")])) , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( unname(q_bp(p_sbp = 0.5, p_dbp = 0.5, male = lo2013$male, age = lo2013$age, source = "lo2013")) , unname(as.list(lo2013[c("sbp_mean", "dbp_mean")])) , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( unname(p_bp(q_sbp = gemelli1990$sbp_mean, q_dbp = gemelli1990$dbp_mean, male = gemelli1990$male, age = gemelli1990$age, source = "gemelli1990")) , list(rep(0.5, nrow(gemelli1990)), rep(0.5, nrow(gemelli1990))) , check.attributes = FALSE ) ) ) stopifnot( isTRUE( all.equal( unname(p_bp(q_sbp = lo2013$sbp_mean, q_dbp = lo2013$dbp_mean, male = lo2013$male, age = lo2013$age, source = "lo2013")) , list(rep(0.5, nrow(lo2013)), rep(0.5, nrow(lo2013))) , check.attributes = FALSE ) ) ) ################################################################################ # End of file # ################################################################################