prepare EMGLLF / EMGrank wrappers, simplify folder generateTestData

[valse.git] / R / selectVariables.R

#' selectVaribles
#' It is a function which construct, for a given lambda, the sets of
#' relevant variables and irrelevant variables.
#'
#' @param phiInit an initial estimator for phi (size: p*m*k)
#' @param rhoInit an initial estimator for rho (size: m*m*k)
#' @param piInit    an initial estimator for pi (size : k)
#' @param gamInit an initial estimator for gamma
#' @param mini      minimum number of iterations in EM algorithm
#' @param maxi      maximum number of iterations in EM algorithm
#' @param gamma  power in the penalty
#' @param glambda grid of regularization parameters
#' @param X          matrix of regressors
#' @param Y          matrix of responses
#' @param thres  threshold to consider a coefficient to be equal to 0
#' @param tau        threshold to say that EM algorithm has converged
#'
#' @return TODO
#'
#' @examples TODO
#'
#' @export
selectVariables <- function(phiInit,rhoInit,piInit,gamInit,
    mini,maxi,gamma,glambda,X,Y,thres,tau)
{
    dimphi <- dim(phiInit)
    p <- dimPhi[1]
    m <- dimPhi[2]
    k <- dimPhi[3]
    L <- length(glambda);
    A1 <- array(0, dim <- c(p,m+1,L))
    A2 <- array(0, dim <- c(p,m+1,L))
    Rho <- array(0, dim <- c(m,m,k,L))
    Pi <- array(0, dim <- c(k,L));

    # For every lambda in gridLambda, comutation of the coefficients
    for (lambdaIndex in c(1:L))
    {
        Res <- EMGLLF(phiInit,rhoInit,piInit,gamInit,mini,maxi,
            gamma,glambda[lambdaIndex],X,Y,tau);
        phi <- Res$phi
        rho <- Res$rho
        pi <- Res$pi

        # If a coefficient is larger than the threshold, we keep it
        selectedVariables <- array(0, dim = c(p,m))
        discardedVariables <- array(0, dim = c(p,m))
        atLeastOneSelectedVariable <- false
        for (j in c(1:p))
        {
            cpt <- 1
            cpt2 <-1
            for (mm in c(1:m))
            {
                if (max(abs(phi[j,mm,])) > thres)
                {
                    selectedVariables[j,cpt] <- mm
                    cpt <- cpt+1
                    atLeastOneSelectedVariable <- true
                } else
                {
                    discardedVariables[j,cpt2] <- mm
                    cpt2 <- cpt2+1
                }
            }
        }

        # If no coefficients have been selected, we provide the zero matrix
        # We delete zero coefficients: vec = indices of zero values
        if (atLeastOneSelectedVariable)
        {
            vec <- c()
            for (j in c(1:p))
            {
                if (selectedVariables(j,1) != 0)
                    vec <- c(vec,j)
                # Else ( NOTE: [auder] else ?! TODO: explain? )
                # we provide the indices of relevant coefficients
                A1[,1,lambdaIndex] <- c(vec,rep(0,p-length(vec)))
                A1[1:length(vec),2:(m+1),lambdaIndex] <- selectedVariables[vec,]
                A2[,1,lambdaIndex] <- 1:p
                A2[,2:(m+1),lambdaIndex] <- discardedVariables
                Rho[,,,lambdaIndex] <- rho
                Pi[,lambdaIndex] <- pi
            }
        }
    }

    return(res = list(A1 = A1, A2 = A2 , Rho = Rho, Pi = Pi))
}