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

#' Compute forecast
#'
#' Predict time-series curves for the selected days indices (lines in data).
#'
#' @param data Dataset, object of type \code{Data} output of \code{getData}
#' @param indices Days indices where to forecast (the day after)
#' @param forecaster Name of the main forcaster
#' \itemize{
#'   \item Persistence : use values of last (similar, next) day
#'   \item Neighbors : use values from the k closest neighbors' tomorrows
#'   \item Average : global average of all the (similar) "tomorrow of past"
#'   \item Zero : just output 0 (benchmarking purpose)
#' }
#' @param pjump How to predict the jump at the interface between two days ?
#' \itemize{
#'   \item Persistence : use last (similar) day values
#'   \item Neighbors: re-use the weights optimized in corresponding forecaster
#'   \item Zero: just output 0 (no adjustment)
#' }
#' @param memory Data depth (in days) to be used for prediction
#' @param horizon Number of time steps to predict
#' @param ncores Number of cores for parallel execution (1 to disable)
#' @param ... Additional parameters for the forecasting models;
#'   In particular, realtime=TRUE to use predictions instead of measurements
#'
#' @return An object of class Forecast
#'
#' @examples
#' ts_data = system.file("extdata","pm10_mesures_H_loc.csv",package="talweg")
#' exo_data = system.file("extdata","meteo_extra_noNAs.csv",package="talweg")
#' data = getData(ts_data, exo_data, input_tz="GMT", working_tz="GMT", predict_at=7)
#' pred = computeForecast(data, 2200:2230, "Persistence", "Persistence", 500, 12)
#' \dontrun{#Sketch for real-time mode:
#' data = new("Data", ...)
#' forecaster = new(..., data=data)
#' repeat {
#'   data$append(some_new_data)
#'   pred = forecaster$predict(data$getSize(), ...)
#'   #do_something_with_pred
#' }}
#' @export
computeForecast = function(data, indices, forecaster, pjump,
	memory=Inf, horizon=data$getStdHorizon(), ncores=3, ...)
{
	# (basic) Arguments sanity checks
	horizon = as.integer(horizon)[1]
	if (horizon<=0 || horizon>length(data$getCenteredSerie(1)))
		stop("Horizon too short or too long")
	integer_indices = sapply(indices, function(i) dateIndexToInteger(i,data))
	if (any(integer_indices<=0 | integer_indices>data$getSize()))
		stop("Indices out of range")
	if (!is.character(forecaster) || !is.character(pjump))
		stop("forecaster (name) and pjump (function) should be of class character")

	pred = Forecast$new( sapply(indices, function(i) integerIndexToDate(i,data)) )
	forecaster_class_name = getFromNamespace(
		paste(forecaster,"Forecaster",sep=""), "talweg")
	forecaster = forecaster_class_name$new( #.pjump =
		getFromNamespace(paste("get",pjump,"JumpPredict",sep=""), "talweg"))

	if (ncores > 1 && requireNamespace("parallel",quietly=TRUE))
	{
		p <- parallel::mclapply(seq_along(integer_indices), function(i) {
			list(
				"forecast" = forecaster$predictSerie(
					data, integer_indices[i], memory, horizon, ...),
				"params"= forecaster$getParameters(),
				"index" = integer_indices[i] )
			}, mc.cores=ncores)
	}
	else
	{
		p <- lapply(seq_along(integer_indices), function(i) {
			list(
				"forecast" = forecaster$predictSerie(
					data, integer_indices[i], memory, horizon, ...),
				"params"= forecaster$getParameters(),
				"index" = integer_indices[i] )
			})
	}

	# TODO: find a way to fill pred in //...
	for (i in seq_along(integer_indices))
	{
		pred$append(
			forecast = p[[i]]$forecast,
			params = p[[i]]$params,
			index_in_data = p[[i]]$index
		)
	}
	pred
}
Commit	Line	Data
af3b84f4	1	#' Compute forecast
3d69ff21	2	#'
af3b84f4	3	#' Predict time-series curves for the selected days indices (lines in data).
3d69ff21 BA	4	#'
	5	#' @param data Dataset, object of type \code{Data} output of \code{getData}
	6	#' @param indices Days indices where to forecast (the day after)
e030a6e3	7	#' @param forecaster Name of the main forcaster
3d69ff21 BA	8	#' \itemize{
3d69ff21 BA	9	#' \item Persistence : use values of last (similar, next) day
e030a6e3	10	#' \item Neighbors : use values from the k closest neighbors' tomorrows
3d69ff21	11	#' \item Average : global average of all the (similar) "tomorrow of past"
e030a6e3	12	#' \item Zero : just output 0 (benchmarking purpose)
3d69ff21	13	#' }
e030a6e3	14	#' @param pjump How to predict the jump at the interface between two days ?
3d69ff21 BA	15	#' \itemize{
3d69ff21 BA	16	#' \item Persistence : use last (similar) day values
e030a6e3	17	#' \item Neighbors: re-use the weights optimized in corresponding forecaster
3d69ff21 BA	18	#' \item Zero: just output 0 (no adjustment)
3d69ff21 BA	19	#' }
e030a6e3 BA	20	#' @param memory Data depth (in days) to be used for prediction
e030a6e3 BA	21	#' @param horizon Number of time steps to predict
ee8b1b4e	22	#' @param ncores Number of cores for parallel execution (1 to disable)
72b9c501 BA	23	#' @param ... Additional parameters for the forecasting models;
72b9c501 BA	24	#' In particular, realtime=TRUE to use predictions instead of measurements
3d69ff21	25	#'
a66a84b5	26	#' @return An object of class Forecast
3d69ff21 BA	27	#'
3d69ff21 BA	28	#' @examples
44a9990b BA	29	#' ts_data = system.file("extdata","pm10_mesures_H_loc.csv",package="talweg")
44a9990b BA	30	#' exo_data = system.file("extdata","meteo_extra_noNAs.csv",package="talweg")
445e7bbc	31	#' data = getData(ts_data, exo_data, input_tz="GMT", working_tz="GMT", predict_at=7)
99f83c9a	32	#' pred = computeForecast(data, 2200:2230, "Persistence", "Persistence", 500, 12)
3d69ff21 BA	33	#' \dontrun{#Sketch for real-time mode:
3d69ff21 BA	34	#' data = new("Data", ...)
e030a6e3	35	#' forecaster = new(..., data=data)
3d69ff21 BA	36	#' repeat {
3d69ff21 BA	37	#' data$append(some_new_data)
e030a6e3	38	#' pred = forecaster$predict(data$getSize(), ...)
3d69ff21 BA	39	#' #do_something_with_pred
	40	#' }}
	41	#' @export
25b75559	42	computeForecast = function(data, indices, forecaster, pjump,
ee8b1b4e	43	memory=Inf, horizon=data$getStdHorizon(), ncores=3, ...)
3d69ff21	44	{
e030a6e3	45	# (basic) Arguments sanity checks
3d69ff21	46	horizon = as.integer(horizon)[1]
72b9c501	47	if (horizon<=0 \|\| horizon>length(data$getCenteredSerie(1)))
3d69ff21	48	stop("Horizon too short or too long")
98e958ca	49	integer_indices = sapply(indices, function(i) dateIndexToInteger(i,data))
a66a84b5	50	if (any(integer_indices<=0 \| integer_indices>data$getSize()))
3d69ff21	51	stop("Indices out of range")
a66a84b5 BA	52	if (!is.character(forecaster) \|\| !is.character(pjump))
a66a84b5 BA	53	stop("forecaster (name) and pjump (function) should be of class character")
3d69ff21	54
98e958ca	55	pred = Forecast$new( sapply(indices, function(i) integerIndexToDate(i,data)) )
72b9c501 BA	56	forecaster_class_name = getFromNamespace(
72b9c501 BA	57	paste(forecaster,"Forecaster",sep=""), "talweg")
98e958ca BA	58	forecaster = forecaster_class_name$new( #.pjump =
98e958ca BA	59	getFromNamespace(paste("get",pjump,"JumpPredict",sep=""), "talweg"))
5e838b3e	60
ee8b1b4e	61	if (ncores > 1 && requireNamespace("parallel",quietly=TRUE))
a866acb3	62	{
ee8b1b4e	63	p <- parallel::mclapply(seq_along(integer_indices), function(i) {
a866acb3	64	list(
72b9c501 BA	65	"forecast" = forecaster$predictSerie(
72b9c501 BA	66	data, integer_indices[i], memory, horizon, ...),
a866acb3 BA	67	"params"= forecaster$getParameters(),
a866acb3 BA	68	"index" = integer_indices[i] )
ee8b1b4e	69	}, mc.cores=ncores)
a866acb3 BA	70	}
	71	else
	72	{
ee8b1b4e	73	p <- lapply(seq_along(integer_indices), function(i) {
a866acb3	74	list(
72b9c501 BA	75	"forecast" = forecaster$predictSerie(
72b9c501 BA	76	data, integer_indices[i], memory, horizon, ...),
a866acb3 BA	77	"params"= forecaster$getParameters(),
	78	"index" = integer_indices[i] )
	79	})
	80	}
5e838b3e	81
ee8b1b4e BA	82	# TODO: find a way to fill pred in //...
	83	for (i in seq_along(integer_indices))
	84	{
	85	pred$append(
72b9c501 BA	86	forecast = p[[i]]$forecast,
	87	params = p[[i]]$params,
	88	index_in_data = p[[i]]$index
ee8b1b4e BA	89	)
ee8b1b4e BA	90	}
25b75559	91	pred
3d69ff21	92	}