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

#' Neighbors Forecaster
#'
#' Predict next serie as a weighted combination of curves observed on "similar" days in
#' the past (and future if 'opera'=FALSE); the nature of the similarity is controlled by
#' the options 'simtype' and 'local' (see below).
#'
#' Optional arguments:
#' \itemize{
#'   \item local: TRUE (default) to constrain neighbors to be "same days in same season"
#'   \item simtype: 'endo' for a similarity based on the series only,<cr>
#'             'exo' for a similarity 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 preceded by a
#'     curve 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.
#' }
#'
#' @usage # NeighborsForecaster$new(pjump)
#'
#' @docType class
#' @format R6 class, inherits Forecaster
#' @aliases F_Neighbors
#'
NeighborsForecaster = R6::R6Class("NeighborsForecaster",
	inherit = Forecaster,

	public = list(
		predictShape = function(data, today, memory, predict_from, 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$getSerie(today-1))) ||
				(predict_from>=2 && any(is.na(data$getSerie(today)[1:(predict_from-1)]))))
			{
				return (NA)
			}

			# Get optional args
			local = ifelse(hasArg("local"), list(...)$local, TRUE) #same level + season?
			simtype = ifelse(hasArg("simtype"), list(...)$simtype, "none") #or "endo", or "exo"
			opera = ifelse(hasArg("opera"), list(...)$opera, FALSE) #operational mode?

			# Determine indices of no-NAs days preceded by no-NAs yerstedays
			tdays = .getNoNA2(data, max(today-memory,2), ifelse(opera,today-1,data$getSize()))
			if (!opera)
				tdays = setdiff(tdays, today) #always exclude current day

			# Shortcut if window is known or local==TRUE && simtype==none
			if (hasArg("window") || (local && simtype=="none"))
			{
				return ( private$.predictShapeAux(data, tdays, today, predict_from, horizon,
					local, list(...)$window, simtype, opera, TRUE) )
			}

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

			# 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$.predictShapeAux(data, tdays, cv_days[i], predict_from,
						horizon, local, window, simtype, opera, FALSE)
					if (!is.na(prediction[1]))
					{
						nb_jours = nb_jours + 1
						error = error +
							mean((data$getSerie(cv_days[i])[predict_from: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, tdays, today, predict_from, horizon, local,
				best_window, simtype, opera, TRUE) )
		}
	),
	private = list(
		# Precondition: "yersteday until predict_from-1" is full (no NAs)
		.predictShapeAux = function(data, tdays, today, predict_from, horizon, local, window,
			simtype, opera, final_call)
		{
			tdays_cut = tdays[ tdays != today ]
			if (length(tdays_cut) == 0)
				return (NA)

			if (local)
			{
				# limit=Inf to not censor any day (TODO: finite limit? 60?)
				tdays = getSimilarDaysIndices(today, data, limit=Inf, same_season=TRUE,
					days_in=tdays_cut, operational=opera)
				# TODO: 10 == magic number
				tdays = .getConstrainedNeighbs(today, data, tdays, min_neighbs=10)
				if (length(tdays) == 1)
				{
					if (final_call)
					{
						private$.params$weights <- 1
						private$.params$indices <- tdays
						private$.params$window <- 1
					}
					return ( data$getSerie(tdays[1])[predict_from:horizon] )
				}
				max_neighbs = 10 #TODO: 10 or 12 or... ?
				if (length(tdays) > max_neighbs)
				{
					distances2 <- .computeDistsEndo(data, today, tdays, predict_from)
					ordering <- order(distances2)
					tdays <- tdays[ ordering[1:max_neighbs] ]
				}
			}
			else
				tdays = tdays_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 selected days in the past
				# TODO: redundant computation if local==TRUE
				distances2 <- .computeDistsEndo(data, today, tdays, predict_from)

				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)

				distances2 <- .computeDistsExo(data, today, tdays)

				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(tdays))
			similarities = similarities / sum(similarities)

			prediction = rep(0, horizon-predict_from+1)
			for (i in seq_along(tdays))
			{
				prediction = prediction +
					similarities[i] * data$getSerie(tdays[i])[predict_from:horizon]
			}

			if (final_call)
			{
				private$.params$weights <- similarities
				private$.params$indices <- tdays
				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 tdays Current set of "second 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, tdays, min_neighbs=10)
{
	levelToday = data$getLevelHat(today)
	distances = sapply( tdays, function(i) abs(data$getLevel(i) - levelToday) )
	#TODO: 1, +1, +3 : magic numbers
	dist_thresh = 1
	min_neighbs = min(min_neighbs,length(tdays))
	repeat
	{
		same_pollution = (distances <= dist_thresh)
		nb_neighbs = sum(same_pollution)
		if (nb_neighbs >= min_neighbs) #will eventually happen
			break
		dist_thresh = dist_thresh + ifelse(dist_thresh>1,3,1)
	}
	tdays[same_pollution]
}

# 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))
}

.computeDistsEndo <- function(data, today, tdays, predict_from)
{
	lastSerie = c( data$getSerie(today-1),
		data$getSerie(today)[if (predict_from>=2) 1:(predict_from-1) else c()] )
	sapply(tdays, function(i) {
		delta = lastSerie - c(data$getSerie(i-1),
			data$getSerie(i)[if (predict_from>=2) 1:(predict_from-1) else c()])
		sqrt(mean(delta^2))
	})
}

.computeDistsExo <- function(data, today, tdays)
{
	M = matrix( ncol=1+length(tdays), nrow=1+length(data$getExo(1)) )
	M[,1] = c( data$getLevelHat(today), as.double(data$getExoHat(today)) )
	for (i in seq_along(tdays))
		M[,i+1] = c( data$getLevel(tdays[i]), as.double(data$getExo(tdays[i])) )

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

	# Distances from last observed day to days in the past
	sapply(seq_along(tdays), function(i) {
		delta = M[,1] - M[,i+1]
		delta %*% sigma_inv %*% delta
	})
}
Commit	Line	Data
25b75559	1	#' Neighbors Forecaster
3d69ff21	2	#'
4f3fdbb8 BA	3	#' Predict next serie as a weighted combination of curves observed on "similar" days in
	4	#' the past (and future if 'opera'=FALSE); the nature of the similarity is controlled by
	5	#' the options 'simtype' and 'local' (see below).
c4c329f6	6	#'
4f3fdbb8	7	#' Optional arguments:
102bcfda	8	#' \itemize{
4f3fdbb8 BA	9	#' \item local: TRUE (default) to constrain neighbors to be "same days in same season"
4f3fdbb8 BA	10	#' \item simtype: 'endo' for a similarity based on the series only,<cr>
d2ab47a7	11	#' 'exo' for a similarity based on exogenous variables only,<cr>
102bcfda BA	12	#' 'mix' for the product of 'endo' and 'exo',<cr>
102bcfda BA	13	#' 'none' (default) to apply a simple average: no computed weights
4f3fdbb8	14	#' \item window: A window for similarities computations; override cross-validation
102bcfda BA	15	#' window estimation.
	16	#' }
	17	#' The method is summarized as follows:
	18	#' \enumerate{
4f3fdbb8 BA	19	#' \item Determine N (=20) recent days without missing values, and preceded by a
4f3fdbb8 BA	20	#' curve also without missing values.
102bcfda BA	21	#' \item Optimize the window parameters (if relevant) on the N chosen days.
	22	#' \item Considering the optimized window, compute the neighbors (with locality
	23	#' constraint or not), compute their similarities -- using a gaussian kernel if
	24	#' simtype != "none" -- and average accordingly the "tomorrows of neigbors" to
	25	#' obtain the final prediction.
	26	#' }
c4c329f6	27	#'
4e821712	28	#' @usage # NeighborsForecaster$new(pjump)
689aa1d3	29	#'
102bcfda	30	#' @docType class
c4c329f6	31	#' @format R6 class, inherits Forecaster
3ddf1c12	32	#' @aliases F_Neighbors
546b0cb6	33	#'
25b75559	34	NeighborsForecaster = R6::R6Class("NeighborsForecaster",
a66a84b5	35	inherit = Forecaster,
25b75559 BA	36
25b75559 BA	37	public = list(
d2ab47a7	38	predictShape = function(data, today, memory, predict_from, horizon, ...)
3d69ff21 BA	39	{
3d69ff21 BA	40	# (re)initialize computed parameters
a66a84b5	41	private$.params <- list("weights"=NA, "indices"=NA, "window"=NA)
3d69ff21	42
a5a3a294	43	# Do not forecast on days with NAs (TODO: softer condition...)
cf3bb001 BA	44	if (any(is.na(data$getSerie(today-1))) \|\|
cf3bb001 BA	45	(predict_from>=2 && any(is.na(data$getSerie(today)[1:(predict_from-1)]))))
d2ab47a7	46	{
a5a3a294	47	return (NA)
d2ab47a7	48	}
a5a3a294	49
f17665c7	50	# Get optional args
445e7bbc BA	51	local = ifelse(hasArg("local"), list(...)$local, TRUE) #same level + season?
445e7bbc BA	52	simtype = ifelse(hasArg("simtype"), list(...)$simtype, "none") #or "endo", or "exo"
638f27f4 BA	53	opera = ifelse(hasArg("opera"), list(...)$opera, FALSE) #operational mode?
	54
	55	# Determine indices of no-NAs days preceded by no-NAs yerstedays
	56	tdays = .getNoNA2(data, max(today-memory,2), ifelse(opera,today-1,data$getSize()))
	57	if (!opera)
	58	tdays = setdiff(tdays, today) #always exclude current day
	59
dca259e4 BA	60	# Shortcut if window is known or local==TRUE && simtype==none
dca259e4 BA	61	if (hasArg("window") \|\| (local && simtype=="none"))
a66a84b5	62	{
638f27f4 BA	63	return ( private$.predictShapeAux(data, tdays, today, predict_from, horizon,
638f27f4 BA	64	local, list(...)$window, simtype, opera, TRUE) )
a66a84b5	65	}
3d69ff21	66
6774e53d	67	# Indices of similar days for cross-validation; TODO: 20 = magic number
aa059de7	68	cv_days = getSimilarDaysIndices(today, data, limit=20, same_season=FALSE,
638f27f4	69	days_in=tdays, operational=opera)
5e838b3e	70
445e7bbc	71	# Optimize h : h \|--> sum of prediction errors on last N "similar" days
aa059de7	72	errorOnLastNdays = function(window, simtype)
3d69ff21 BA	73	{
	74	error = 0
	75	nb_jours = 0
5e838b3e	76	for (i in seq_along(cv_days))
3d69ff21	77	{
f17665c7	78	# mix_strategy is never used here (simtype != "mix"), therefore left blank
cf3bb001	79	prediction = private$.predictShapeAux(data, tdays, cv_days[i], predict_from,
638f27f4	80	horizon, local, window, simtype, opera, FALSE)
f17665c7	81	if (!is.na(prediction[1]))
3d69ff21 BA	82	{
3d69ff21 BA	83	nb_jours = nb_jours + 1
af3b84f4	84	error = error +
cf3bb001	85	mean((data$getSerie(cv_days[i])[predict_from:horizon] - prediction)^2)
3d69ff21 BA	86	}
	87	}
	88	return (error / nb_jours)
	89	}
	90
445e7bbc	91	# TODO: 7 == magic number
eef54517	92	if (simtype=="endo" \|\| simtype=="mix")
af3b84f4	93	{
aa059de7 BA	94	best_window_endo = optimize(
aa059de7 BA	95	errorOnLastNdays, c(0,7), simtype="endo")$minimum
af3b84f4	96	}
eef54517	97	if (simtype=="exo" \|\| simtype=="mix")
af3b84f4	98	{
eef54517 BA	99	best_window_exo = optimize(
eef54517 BA	100	errorOnLastNdays, c(0,7), simtype="exo")$minimum
3d69ff21	101	}
eef54517 BA	102
	103	best_window =
	104	if (simtype == "endo")
	105	best_window_endo
	106	else if (simtype == "exo")
	107	best_window_exo
	108	else if (simtype == "mix")
	109	c(best_window_endo,best_window_exo)
	110	else #none: value doesn't matter
	111	1
	112
cf3bb001	113	return( private$.predictShapeAux(data, tdays, today, predict_from, horizon, local,
638f27f4	114	best_window, simtype, opera, TRUE) )
25b75559 BA	115	}
	116	),
	117	private = list(
638f27f4	118	# Precondition: "yersteday until predict_from-1" is full (no NAs)
cf3bb001	119	.predictShapeAux = function(data, tdays, today, predict_from, horizon, local, window,
638f27f4	120	simtype, opera, final_call)
3d69ff21	121	{
638f27f4 BA	122	tdays_cut = tdays[ tdays != today ]
638f27f4 BA	123	if (length(tdays_cut) == 0)
3d69ff21 BA	124	return (NA)
3d69ff21 BA	125
aa059de7 BA	126	if (local)
aa059de7 BA	127	{
dca259e4 BA	128	# limit=Inf to not censor any day (TODO: finite limit? 60?)
dca259e4 BA	129	tdays = getSimilarDaysIndices(today, data, limit=Inf, same_season=TRUE,
638f27f4	130	days_in=tdays_cut, operational=opera)
638f27f4 BA	131	# TODO: 10 == magic number
638f27f4 BA	132	tdays = .getConstrainedNeighbs(today, data, tdays, min_neighbs=10)
cf3bb001	133	if (length(tdays) == 1)
aa059de7 BA	134	{
	135	if (final_call)
	136	{
	137	private$.params$weights <- 1
cf3bb001	138	private$.params$indices <- tdays
aa059de7 BA	139	private$.params$window <- 1
aa059de7 BA	140	}
cf3bb001	141	return ( data$getSerie(tdays[1])[predict_from:horizon] )
aa059de7	142	}
9b9bb2d4	143	max_neighbs = 10 #TODO: 10 or 12 or... ?
dca259e4 BA	144	if (length(tdays) > max_neighbs)
	145	{
	146	distances2 <- .computeDistsEndo(data, today, tdays, predict_from)
	147	ordering <- order(distances2)
	148	tdays <- tdays[ ordering[1:max_neighbs] ]
	149	}
aa059de7 BA	150	}
aa059de7 BA	151	else
cf3bb001	152	tdays = tdays_cut #no conditioning
aa059de7	153
445e7bbc	154	if (simtype == "endo" \|\| simtype == "mix")
3d69ff21	155	{
aa059de7 BA	156	# Compute endogen similarities using given window
aa059de7 BA	157	window_endo = ifelse(simtype=="mix", window[1], window)
3d69ff21	158
638f27f4	159	# Distances from last observed day to selected days in the past
dca259e4	160	# TODO: redundant computation if local==TRUE
638f27f4 BA	161	distances2 <- .computeDistsEndo(data, today, tdays, predict_from)
638f27f4 BA	162
3ddf1c12	163	simils_endo <- .computeSimils(distances2, window_endo)
3d69ff21 BA	164	}
3d69ff21 BA	165
445e7bbc	166	if (simtype == "exo" \|\| simtype == "mix")
3d69ff21	167	{
aa059de7	168	# Compute exogen similarities using given window
445e7bbc	169	window_exo = ifelse(simtype=="mix", window[2], window)
3d69ff21	170
638f27f4	171	distances2 <- .computeDistsExo(data, today, tdays)
3d69ff21	172
3ddf1c12	173	simils_exo <- .computeSimils(distances2, window_exo)
3d69ff21 BA	174	}
3d69ff21 BA	175
3d69ff21	176	similarities =
f17665c7	177	if (simtype == "exo")
3d69ff21	178	simils_exo
f17665c7 BA	179	else if (simtype == "endo")
f17665c7 BA	180	simils_endo
445e7bbc	181	else if (simtype == "mix")
f17665c7	182	simils_endo * simils_exo
445e7bbc	183	else #none
cf3bb001	184	rep(1, length(tdays))
ea5c7e56	185	similarities = similarities / sum(similarities)
3d69ff21	186
d2ab47a7	187	prediction = rep(0, horizon-predict_from+1)
cf3bb001	188	for (i in seq_along(tdays))
d2ab47a7 BA	189	{
d2ab47a7 BA	190	prediction = prediction +
cf3bb001	191	similarities[i] * data$getSerie(tdays[i])[predict_from:horizon]
d2ab47a7	192	}
99f83c9a	193
3d69ff21 BA	194	if (final_call)
3d69ff21 BA	195	{
a66a84b5	196	private$.params$weights <- similarities
cf3bb001	197	private$.params$indices <- tdays
a66a84b5	198	private$.params$window <-
546b0cb6	199	if (simtype=="endo")
aa059de7	200	window_endo
546b0cb6	201	else if (simtype=="exo")
aa059de7	202	window_exo
eef54517	203	else if (simtype=="mix")
aa059de7	204	c(window_endo,window_exo)
eef54517 BA	205	else #none
eef54517 BA	206	1
3d69ff21	207	}
99f83c9a	208
3d69ff21 BA	209	return (prediction)
	210	}
	211	)
	212	)
3ddf1c12	213
689aa1d3 BA	214	# getConstrainedNeighbs
	215	#
	216	# Get indices of neighbors of similar pollution level (among same season + day type).
	217	#
	218	# @param today Index of current day
	219	# @param data Object of class Data
cf3bb001	220	# @param tdays Current set of "second days" (no-NA pairs)
689aa1d3 BA	221	# @param min_neighbs Minimum number of points in a neighborhood
	222	# @param max_neighbs Maximum number of points in a neighborhood
	223	#
638f27f4	224	.getConstrainedNeighbs = function(today, data, tdays, min_neighbs=10)
3ddf1c12	225	{
d2ab47a7	226	levelToday = data$getLevelHat(today)
9b9bb2d4	227	distances = sapply( tdays, function(i) abs(data$getLevel(i) - levelToday) )
d2ab47a7 BA	228	#TODO: 1, +1, +3 : magic numbers
d2ab47a7 BA	229	dist_thresh = 1
cf3bb001	230	min_neighbs = min(min_neighbs,length(tdays))
3ddf1c12 BA	231	repeat
	232	{
	233	same_pollution = (distances <= dist_thresh)
	234	nb_neighbs = sum(same_pollution)
	235	if (nb_neighbs >= min_neighbs) #will eventually happen
	236	break
d2ab47a7	237	dist_thresh = dist_thresh + ifelse(dist_thresh>1,3,1)
3ddf1c12	238	}
9b9bb2d4	239	tdays[same_pollution]
3ddf1c12 BA	240	}
3ddf1c12 BA	241
689aa1d3 BA	242	# compute similarities
	243	#
	244	# Apply the gaussian kernel on computed squared distances.
	245	#
	246	# @param distances2 Squared distances
	247	# @param window Window parameter for the kernel
	248	#
3ddf1c12 BA	249	.computeSimils <- function(distances2, window)
	250	{
	251	sd_dist = sd(distances2)
	252	if (sd_dist < .25 * sqrt(.Machine$double.eps))
	253	{
	254	# warning("All computed distances are very close: stdev too small")
	255	sd_dist = 1 #mostly for tests... FIXME:
	256	}
	257	exp(-distances2/(sd_dist*window^2))
	258	}
638f27f4 BA	259
	260	.computeDistsEndo <- function(data, today, tdays, predict_from)
	261	{
	262	lastSerie = c( data$getSerie(today-1),
	263	data$getSerie(today)[if (predict_from>=2) 1:(predict_from-1) else c()] )
	264	sapply(tdays, function(i) {
	265	delta = lastSerie - c(data$getSerie(i-1),
	266	data$getSerie(i)[if (predict_from>=2) 1:(predict_from-1) else c()])
9b9bb2d4	267	sqrt(mean(delta^2))
638f27f4 BA	268	})
	269	}
	270
	271	.computeDistsExo <- function(data, today, tdays)
	272	{
	273	M = matrix( ncol=1+length(tdays), nrow=1+length(data$getExo(1)) )
	274	M[,1] = c( data$getLevelHat(today), as.double(data$getExoHat(today)) )
	275	for (i in seq_along(tdays))
	276	M[,i+1] = c( data$getLevel(tdays[i]), as.double(data$getExo(tdays[i])) )
	277
	278	sigma = cov(t(M)) #NOTE: robust covariance is way too slow
	279	# TODO: 10 == magic number; more robust way == det, or always ginv()
	280	sigma_inv =
	281	if (length(tdays) > 10)
	282	solve(sigma)
	283	else
	284	MASS::ginv(sigma)
	285
	286	# Distances from last observed day to days in the past
	287	sapply(seq_along(tdays), function(i) {
	288	delta = M[,1] - M[,i+1]
	289	delta %% sigma_inv %% delta
	290	})
	291	}