add realtime option, slightly refactor data acquisition

[talweg.git] / pkg / R / plot.R

#' Plot curves
#'
#' Plot a range of curves in data
#'
#' @param data Object of class Data
#' @param indices Range of indices (integers or dates)
#'
#' @export
plotCurves <- function(data, indices=seq_len(data$getSize()))
{
    series = data$getSeries(indices)
    yrange = quantile(series, probs=c(0.025,0.975), na.rm=TRUE)
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5)
    for (i in seq_along(indices))
    {
        plot(series[,i], type="l", ylim=yrange,
            xlab=ifelse(i==1,"Time (hours)",""), ylab=ifelse(i==1,"PM10",""))
        if (i < length(indices))
            par(new=TRUE)
    }
}

#' Plot error
#'
#' Draw error graphs, potentially from several runs of \code{computeForecast}
#'
#' @param err Error as returned by \code{computeError}
#' @param cols Colors for each error (default: 1,2,3,...)
#'
#' @seealso \code{\link{plotCurves}}, \code{\link{plotPredReal}},
#'   \code{\link{plotSimils}}, \code{\link{plotFbox}}, \code{\link{computeFilaments}},
#'   \code{\link{plotFilamentsBox}}, \code{\link{plotRelVar}}
#'
#' @export
plotError <- function(err, cols=seq_along(err))
{
    if (!is.null(err$abs))
        err = list(err)
    par(mfrow=c(2,2), mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5, lwd=2)
    L = length(err)
    yrange = range( sapply(1:L, function(i) ( err[[i]]$abs$day ) ), na.rm=TRUE )
    for (i in seq_len(L))
    {
        plot(err[[i]]$abs$day, type="l", xlab=ifelse(i==1,"Time (hours)",""),
            ylab=ifelse(i==1,"Mean |y - y_hat|",""), ylim=yrange, col=cols[i])
        if (i < L)
            par(new=TRUE)
    }
    yrange = range( sapply(1:L, function(i) ( err[[i]]$abs$indices ) ), na.rm=TRUE )
    for (i in seq_len(L))
    {
        plot(err[[i]]$abs$indices, type="l", xlab=ifelse(i==1,"Time (days)",""),
            ylab=ifelse(i==1,"Mean |y - y_hat|",""), ylim=yrange, col=cols[i])
        if (i < L)
            par(new=TRUE)
    }
    yrange = range( sapply(1:L, function(i) ( err[[i]]$MAPE$day ) ), na.rm=TRUE )
    for (i in seq_len(L))
    {
        plot(err[[i]]$MAPE$day, type="l", xlab=ifelse(i==1,"Time (hours)",""),
            ylab=ifelse(i==1,"Mean MAPE",""), ylim=yrange, col=cols[i])
        if (i < L)
            par(new=TRUE)
    }
    yrange = range( sapply(1:L, function(i) ( err[[i]]$MAPE$indices ) ), na.rm=TRUE )
    for (i in seq_len(L))
    {
        plot(err[[i]]$MAPE$indices, type="l", xlab=ifelse(i==1,"Time (days)",""),
            ylab=ifelse(i==1,"Mean MAPE",""), ylim=yrange, col=cols[i])
        if (i < L)
            par(new=TRUE)
    }
}

#' Plot measured / predicted
#'
#' Plot measured curve (in black) and predicted curve (in blue)
#'
#' @param data Object return by \code{getData}
#' @param pred Object as returned by \code{computeForecast}
#' @param index Index in forecasts (integer or date)
#'
#' @export
plotPredReal <- function(data, pred, index)
{
    horizon = length(pred$getForecast(1))
    measure = data$getSerie( pred$getIndexInData(index)+1 )[1:horizon]
    prediction = pred$getForecast(index)
    yrange = range(measure, prediction)
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5, lwd=3)
    plot(measure, type="l", ylim=yrange, xlab="Time (hours)", ylab="PM10")
    par(new=TRUE)
    plot(prediction, type="l", col="#0000FF", ylim=yrange, xlab="", ylab="")
}

#' Plot similarities
#'
#' Plot histogram of similarities (weights)
#'
#' @param pred Object as returned by \code{computeForecast}
#' @param index Index in forecasts (integer or date)
#'
#' @export
plotSimils <- function(pred, index)
{
    weights = pred$getParams(index)$weights
    if (is.null(weights))
        stop("plotSimils only works on 'Neighbors' forecasts")
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5)
    hist(pred$getParams(index)$weights, nclass=20, main="", xlab="Weight", ylab="Count")
}

#' Functional boxplot
#'
#' Draw the functional boxplot on the left, and bivariate plot on the right
#'
#' @param data Object return by \code{getData}
#' @param indices integer or date indices to process
#'
#' @export
plotFbox <- function(data, indices=seq_len(data$getSize()))
{
    if (!requireNamespace("rainbow", quietly=TRUE))
        stop("Functional boxplot requires the rainbow package")

    series_matrix = data$getSeries(indices)
    # Remove series with NAs
    no_NAs_indices = sapply( 1:ncol(series_matrix),
        function(i) all(!is.na(series_matrix[,i])) )
    series_matrix = series_matrix[,no_NAs_indices]

    series_fds = rainbow::fds(seq_len(nrow(series_matrix)), series_matrix)
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5)
    rainbow::fboxplot(series_fds, "functional", "hdr", xlab="Time (hours)", ylab="PM10",
        plotlegend=FALSE, lwd=2)
    rainbow::fboxplot(series_fds, "bivariate", "hdr", plotlegend=FALSE)
}

#' Compute filaments
#'
#' Get similar days in the past, as black as distances are small
#'
#' @param data Object as returned by \code{getData}
#' @param pred Object of class Forecast
#' @param index Index in forecast (integer or date)
#' @param limit Number of neighbors to consider
#' @param plot Should the result be plotted?
#'
#' @return A list with
#' \itemize{
#'   \item index : index of the current serie ('today')
#'   \item neighb_indices : indices of its neighbors
#'   \item colors : colors of neighbors curves (shades of gray)
#' }
#'
#' @export
computeFilaments <- function(data, pred, index, limit=60, plot=TRUE)
{
    ref_serie = data$getCenteredSerie( pred$getIndexInData(index) )
    if (any(is.na(ref_serie)))
        stop("computeFilaments requires a serie without NAs")

    # Compute colors for each neighbor (from darkest to lightest)
    sorted_dists = sort(-log(pred$getParams(index)$weights), index.return=TRUE)
    nn = min(limit, length(sorted_dists$x))
    min_dist = min(sorted_dists$x[1:nn])
    max_dist = max(sorted_dists$x[1:nn])
    color_values = floor(19.5*(sorted_dists$x[1:nn]-min_dist)/(max_dist-min_dist)) + 1
    colors = gray.colors(20,0.1,0.9)[color_values] #TODO: 20 == magic number

    if (plot)
    {
        # Complete series with (past and present) tomorrows
        ref_serie = c(ref_serie, data$getCenteredSerie( pred$getIndexInData(index)+1 ))
        centered_series = rbind(
            data$getCenteredSeries( pred$getParams(index)$indices ),
            data$getCenteredSeries( pred$getParams(index)$indices+1 ) )
        yrange = range( ref_serie,
            quantile(centered_series, probs=c(0.025,0.975), na.rm=TRUE) )
        par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5, lwd=2)
        for (i in nn:1)
        {
            plot(centered_series[,sorted_dists$ix[i]], ylim=yrange, type="l", col=colors[i],
                xlab=ifelse(i==1,"Time (hours)",""), ylab=ifelse(i==1,"Centered PM10",""))
            par(new=TRUE)
        }
        # Also plot ref curve, in red
        plot(ref_serie, ylim=yrange, type="l", col="#FF0000", xlab="", ylab="")
        abline(v=24, lty=2, col=colors()[56], lwd=1)
    }

    list(
        "index"=pred$getIndexInData(index),
        "neighb_indices"=pred$getParams(index)$indices[sorted_dists$ix[1:nn]],
        "colors"=colors)
}

#' Functional boxplot on filaments
#'
#' Draw the functional boxplot on filaments obtained by \code{computeFilaments}
#'
#' @param data Object return by \code{getData}
#' @param fil Output of \code{computeFilaments}
#'
#' @export
plotFilamentsBox = function(data, fil)
{
    if (!requireNamespace("rainbow", quietly=TRUE))
        stop("Functional boxplot requires the rainbow package")

    series_matrix = rbind(
        data$getSeries(fil$neighb_indices), data$getSeries(fil$neighb_indices+1) )
    series_fds = rainbow::fds(seq_len(nrow(series_matrix)), series_matrix)
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5)
    rainbow::fboxplot(series_fds, "functional", "hdr", xlab="Time (hours)", ylab="PM10",
        plotlegend=FALSE, lwd=2)

    # "Magic": http://stackoverflow.com/questions/13842560/get-xlim-from-a-plot-in-r
    usr <- par("usr")
    yr <- (usr[4] - usr[3]) / 27
    par(new=TRUE)
    plot(c(data$getSerie(fil$index),data$getSerie(fil$index+1)), type="l", lwd=2, lty=2,
        ylim=c(usr[3] + yr, usr[4] - yr), xlab="", ylab="")
    abline(v=24, lty=2, col=colors()[56])
}

#' Plot relative conditional variability / absolute variability
#'
#' Draw the relative conditional variability / absolute variability based on filaments
#' obtained by \code{computeFilaments}
#'
#' @param data Object return by \code{getData}
#' @param fil Output of \code{computeFilaments}
#'
#' @export
plotRelVar = function(data, fil)
{
    ref_var = c( apply(data$getSeries(fil$neighb_indices),1,sd),
        apply(data$getSeries(fil$neighb_indices+1),1,sd) )
    fdays = getNoNA2(data, 1, fil$index-1)
    global_var = c(
        apply(data$getSeries(fdays),1,sd),
        apply(data$getSeries(fdays+1),1,sd) )

    yrange = range(ref_var, global_var)
    par(mar=c(4.7,5,1,1), cex.axis=1.5, cex.lab=1.5)
    plot(ref_var, type="l", col=1, lwd=3, ylim=yrange,
        xlab="Time (hours)", ylab="Standard deviation")
    par(new=TRUE)
    plot(global_var, type="l", col=2, lwd=3, ylim=yrange, xlab="", ylab="")
    abline(v=24, lty=2, col=colors()[56])
}