#' @export
generateSampleIO = function(n, p, β, b, link)
{
- # Check arguments
- tryCatch({n = as.integer(n)}, error=function(e) stop("Cannot convert n to integer"))
- if (length(n) > 1)
- warning("n is a vector but should be scalar: only first element used")
- if (n <= 0)
- stop("n: positive integer")
- if (!is.matrix(β) || !is.numeric(β) || any(is.na(β)))
- stop("β: real matrix, no NAs")
- K = ncol(β)
- if (!is.numeric(p) || length(p)!=K-1 || any(is.na(p)) || any(p<0) || sum(p) > 1)
- stop("p: positive vector of size K-1, no NA, sum<=1")
- p <- c(p, 1-sum(p))
- if (!is.numeric(b) || length(b)!=K || any(is.na(b)))
- stop("b: real vector of size K, no NA")
+ # Check arguments
+ tryCatch({n = as.integer(n)}, error=function(e) stop("Cannot convert n to integer"))
+ if (length(n) > 1)
+ warning("n is a vector but should be scalar: only first element used")
+ if (n <= 0)
+ stop("n: positive integer")
+ if (!is.matrix(β) || !is.numeric(β) || any(is.na(β)))
+ stop("β: real matrix, no NAs")
+ K = ncol(β)
+ if (!is.numeric(p) || length(p)!=K-1 || any(is.na(p)) || any(p<0) || sum(p) > 1)
+ stop("p: positive vector of size K-1, no NA, sum<=1")
+ p <- c(p, 1-sum(p))
+ if (!is.numeric(b) || length(b)!=K || any(is.na(b)))
+ stop("b: real vector of size K, no NA")
- #random generation of the size of each population in X~Y (unordered)
- classes = rmultinom(1, n, p)
+ #random generation of the size of each population in X~Y (unordered)
+ classes = rmultinom(1, n, p)
- d = nrow(β)
- zero_mean = rep(0,d)
- id_sigma = diag(rep(1,d))
- # Always consider an intercept (use b=0 for none)
- d = d + 1
- β = rbind(β, b)
- X = matrix(nrow=0, ncol=d)
- Y = c()
- index = c()
- for (i in 1:ncol(β))
- {
- index = c(index, rep(i, classes[i]))
- newXblock = cbind( MASS::mvrnorm(classes[i], zero_mean, id_sigma), 1 )
- arg_link = newXblock %*% β[,i] #β
- probas =
- if (link == "logit")
- {
- e_arg_link = exp(arg_link)
- e_arg_link / (1 + e_arg_link)
- }
- else #"probit"
- pnorm(arg_link)
- probas[is.nan(probas)] = 1 #overflow of exp(x)
- #probas = rowSums(p * probas)
- X = rbind(X, newXblock)
- #Y = c( Y, vapply(probas, function(p) (ifelse(p >= .5, 1, 0)), 1) )
- Y = c( Y, vapply(probas, function(p) (rbinom(1,1,p)), 1) )
- }
- shuffle = sample(n)
- # Returned X should not contain an intercept column (it's an argument of estimation
- # methods)
- list("X"=X[shuffle,-d], "Y"=Y[shuffle], "index"=index[shuffle])
+ d = nrow(β)
+ zero_mean = rep(0,d)
+ id_sigma = diag(rep(1,d))
+ # Always consider an intercept (use b=0 for none)
+ d = d + 1
+ β = rbind(β, b)
+ X = matrix(nrow=0, ncol=d)
+ Y = c()
+ index = c()
+ for (i in 1:ncol(β))
+ {
+ index = c(index, rep(i, classes[i]))
+ newXblock = cbind( MASS::mvrnorm(classes[i], zero_mean, id_sigma), 1 )
+ arg_link = newXblock %*% β[,i] #β
+ probas =
+ if (link == "logit")
+ {
+ e_arg_link = exp(arg_link)
+ e_arg_link / (1 + e_arg_link)
+ }
+ else #"probit"
+ pnorm(arg_link)
+ probas[is.nan(probas)] = 1 #overflow of exp(x)
+ #probas = rowSums(p * probas)
+ X = rbind(X, newXblock)
+ #Y = c( Y, vapply(probas, function(p) (ifelse(p >= .5, 1, 0)), 1) )
+ Y = c( Y, vapply(probas, function(p) (rbinom(1,1,p)), 1) )
+ }
+ shuffle = sample(n)
+ # Returned X should not contain an intercept column (it's an argument of estimation
+ # methods)
+ list("X"=X[shuffle,-d], "Y"=Y[shuffle], "index"=index[shuffle])
}