'update'

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

#' Neighbors Forecaster
#'
#' Predict next serie as a weighted combination of "futures of the past" days,
#' where days in the past are chosen and weighted according to some similarity measures.
#'
#' The main method is \code{predictShape()}, taking arguments data, today, memory,
#' horizon respectively for the dataset (object output of \code{getData()}), the current
#' index, the data depth (in days) and the number of time steps to forecast.
#' In addition, optional arguments can be passed:
#' \itemize{
#'   \item local : TRUE (default) to constrain neighbors to be "same days within same
#'     season"
#'   \item simtype : 'endo' for a similarity based on the series only,<cr>
#'             'exo' for a similaruty based on exogenous variables only,<cr>
#'             'mix' for the product of 'endo' and 'exo',<cr>
#'             'none' (default) to apply a simple average: no computed weights
#'   \item window : A window for similarities computations; override cross-validation
#'     window estimation.
#' }
#' The method is summarized as follows:
#' \enumerate{
#'   \item Determine N (=20) recent days without missing values, and followed by a
#'     tomorrow also without missing values.
#'   \item Optimize the window parameters (if relevant) on the N chosen days.
#'   \item Considering the optimized window, compute the neighbors (with locality
#'     constraint or not), compute their similarities -- using a gaussian kernel if
#'     simtype != "none" -- and average accordingly the "tomorrows of neigbors" to
#'     obtain the final prediction.
#' }
#'
#' @docType class
#' @format R6 class, inherits Forecaster
#' @aliases F_Neighbors
#'
NeighborsForecaster = R6::R6Class("NeighborsForecaster",
    inherit = Forecaster,

    public = list(
        predictShape = function(data, today, memory, horizon, ...)
        {
            # (re)initialize computed parameters
            private$.params <- list("weights"=NA, "indices"=NA, "window"=NA)

            # Do not forecast on days with NAs (TODO: softer condition...)
            if (any(is.na(data$getCenteredSerie(today))))
                return (NA)

            # Determine indices of no-NAs days followed by no-NAs tomorrows
            fdays = .getNoNA2(data, max(today-memory,1), today-1)

            # Get optional args
            local = ifelse(hasArg("local"), list(...)$local, TRUE) #same level + season?
            simtype = ifelse(hasArg("simtype"), list(...)$simtype, "none") #or "endo", or "exo"
            if (hasArg("window"))
            {
                return ( private$.predictShapeAux(data,
                    fdays, today, horizon, local, list(...)$window, simtype, TRUE) )
            }

            # Indices of similar days for cross-validation; TODO: 20 = magic number
            cv_days = getSimilarDaysIndices(today, data, limit=20, same_season=FALSE,
                days_in=fdays)

            # Optimize h : h |--> sum of prediction errors on last N "similar" days
            errorOnLastNdays = function(window, simtype)
            {
                error = 0
                nb_jours = 0
                for (i in seq_along(cv_days))
                {
                    # mix_strategy is never used here (simtype != "mix"), therefore left blank
                    prediction = private$.predictShapeAux(data, fdays, cv_days[i], horizon, local,
                        window, simtype, FALSE)
                    if (!is.na(prediction[1]))
                    {
                        nb_jours = nb_jours + 1
                        error = error +
                            mean((data$getSerie(cv_days[i]+1)[1:horizon] - prediction)^2)
                    }
                }
                return (error / nb_jours)
            }

            # TODO: 7 == magic number
            if (simtype=="endo" || simtype=="mix")
            {
                best_window_endo = optimize(
                    errorOnLastNdays, c(0,7), simtype="endo")$minimum
            }
            if (simtype=="exo" || simtype=="mix")
            {
                best_window_exo = optimize(
                    errorOnLastNdays, c(0,7), simtype="exo")$minimum
            }

            best_window =
                if (simtype == "endo")
                    best_window_endo
                else if (simtype == "exo")
                    best_window_exo
                else if (simtype == "mix")
                    c(best_window_endo,best_window_exo)
                else #none: value doesn't matter
                    1

            return(private$.predictShapeAux(data, fdays, today, horizon, local,
                best_window, simtype, TRUE))
        }
    ),
    private = list(
        # Precondition: "today" is full (no NAs)
        .predictShapeAux = function(data, fdays, today, horizon, local, window, simtype,
            final_call)
        {
            fdays_cut = fdays[ fdays < today ]
            if (length(fdays_cut) <= 1)
                return (NA)

            if (local)
            {
                # TODO: 60 == magic number
                fdays = getSimilarDaysIndices(today, data, limit=60, same_season=TRUE,
                    days_in=fdays_cut)
                if (length(fdays) <= 1)
                    return (NA)
                # TODO: 10, 12 == magic numbers
                fdays = .getConstrainedNeighbs(today,data,fdays,min_neighbs=10,max_neighbs=12)
                if (length(fdays) == 1)
                {
                    if (final_call)
                    {
                        private$.params$weights <- 1
                        private$.params$indices <- fdays
                        private$.params$window <- 1
                    }
                    return ( data$getSerie(fdays[1])[1:horizon] )
                }
            }
            else
                fdays = fdays_cut #no conditioning

            if (simtype == "endo" || simtype == "mix")
            {
                # Compute endogen similarities using given window
                window_endo = ifelse(simtype=="mix", window[1], window)

                # Distances from last observed day to days in the past
                serieToday = data$getSerie(today)
                distances2 = sapply(fdays, function(i) {
                    delta = serieToday - data$getSerie(i)
                    mean(delta^2)
                })

                simils_endo <- .computeSimils(distances2, window_endo)
            }

            if (simtype == "exo" || simtype == "mix")
            {
                # Compute exogen similarities using given window
                window_exo = ifelse(simtype=="mix", window[2], window)

                M = matrix( nrow=1+length(fdays), ncol=1+length(data$getExo(today)) )
                M[1,] = c( data$getLevel(today), as.double(data$getExo(today)) )
                for (i in seq_along(fdays))
                    M[i+1,] = c( data$getLevel(fdays[i]), as.double(data$getExo(fdays[i])) )

                sigma = cov(M) #NOTE: robust covariance is way too slow
                # TODO: 10 == magic number; more robust way == det, or always ginv()
                sigma_inv =
                    if (length(fdays) > 10)
                        solve(sigma)
                    else
                        MASS::ginv(sigma)

                # Distances from last observed day to days in the past
                distances2 = sapply(seq_along(fdays), function(i) {
                    delta = M[1,] - M[i+1,]
                    delta %*% sigma_inv %*% delta
                })

                simils_exo <- .computeSimils(distances2, window_exo)
            }

            similarities =
                if (simtype == "exo")
                    simils_exo
                else if (simtype == "endo")
                    simils_endo
                else if (simtype == "mix")
                    simils_endo * simils_exo
                else #none
                    rep(1, length(fdays))
            similarities = similarities / sum(similarities)

            prediction = rep(0, horizon)
            for (i in seq_along(fdays))
                prediction = prediction + similarities[i] * data$getSerie(fdays[i]+1)[1:horizon]

            if (final_call)
            {
                private$.params$weights <- similarities
                private$.params$indices <- fdays
                private$.params$window <-
                    if (simtype=="endo")
                        window_endo
                    else if (simtype=="exo")
                        window_exo
                    else if (simtype=="mix")
                        c(window_endo,window_exo)
                    else #none
                        1
            }

            return (prediction)
        }
    )
)

#' getConstrainedNeighbs
#'
#' Get indices of neighbors of similar pollution level (among same season + day type).
#'
#' @param today Index of current day
#' @param data Object of class Data
#' @param fdays Current set of "first days" (no-NA pairs)
#' @param min_neighbs Minimum number of points in a neighborhood
#' @param max_neighbs Maximum number of points in a neighborhood
#'
.getConstrainedNeighbs = function(today, data, fdays, min_neighbs=10, max_neighbs=12)
{
    levelToday = data$getLevel(today)
    distances = sapply(fdays, function(i) abs(data$getLevel(i)-levelToday))
    #TODO: 2, +3 : magic numbers
    dist_thresh = 2
    min_neighbs = min(min_neighbs,length(fdays))
    repeat
    {
        same_pollution = (distances <= dist_thresh)
        nb_neighbs = sum(same_pollution)
        if (nb_neighbs >= min_neighbs) #will eventually happen
            break
        dist_thresh = dist_thresh + 3
    }
    fdays = fdays[same_pollution]
    max_neighbs = 12
    if (nb_neighbs > max_neighbs)
    {
        # Keep only max_neighbs closest neighbors
        fdays = fdays[
            sort(distances[same_pollution],index.return=TRUE)$ix[1:max_neighbs] ]
    }
    fdays
}

#' compute similarities
#'
#' Apply the gaussian kernel on computed squared distances.
#'
#' @param distances2 Squared distances
#' @param window Window parameter for the kernel
#'
.computeSimils <- function(distances2, window)
{
    sd_dist = sd(distances2)
    if (sd_dist < .25 * sqrt(.Machine$double.eps))
    {
#       warning("All computed distances are very close: stdev too small")
        sd_dist = 1 #mostly for tests... FIXME:
    }
    exp(-distances2/(sd_dist*window^2))
}