https://github.com/cran/RandomFields
Tip revision: f5e4e9ee01c1569e39dffdd0295f7a2131c83516 authored by Martin Schlather on 13 January 2015, 00:00:00 UTC
version 3.0.55
version 3.0.55
Tip revision: f5e4e9e
rf-plots.R
## use only via calls of 'eval(body())' from 'plotRFspatialGridDataFrame' or
## 'plotRFspatialPointsDataFrame'
default.image.par <- function(data.range, var.range, legend=TRUE) {
ip <- installed.packages()
if ("colorspace" %in% ip) {
data.col <- colorspace::heat_hcl(12, c. = c(80, 30), l = c(30, 90),
power = c(1/5, 1.5))
var.col <- colorspace::rainbow_hcl(12, c = 50, l = 70)
} else if ("RColorBrewer" %in% ip) {
data.col <- RColorBrewer::brewer.pal(9, "Reds")
var.col <- RColorBrewer::brewer.pal(9, "Blues")
} else {
if (RFoptions()$warn$colour_palette) {
RFoptions(warn.colour_palette = FALSE)
message("Better install the package 'colorspace' or 'RColorBrewer'. (This message appears only once per session.)")
}
data.col <- heat.colors(36)
var.col <- cm.colors(36)
}
#data.col <- colorspace::heat_hcl(12, c. =c(80, 30), l = c(30, 90), power = c(1/5, 1.5))
# var.col <- colorspace::rainbow_hcl(12, c = 50, l = 70)
list(data=list(dot.name="col", default.col=data.col,
pch=16, cex=1, range=data.range),
var=list(dot.name="var.col", default.col=var.col,
pch=16, cex=1, range=var.range),
#mar = c(2,2,1,0),
#mar.leg = c(0, 2.2, 2, 0.2),
legend = legend,
lower.leg = if (legend) 0.85 else 1,
arrows = list(reduction = 1.5, nx.vectors = 20, leg.pos=c(1, 0.7)),
text.col="blue"
)
}
my.arrows <- function(xy, z, r, thinning, col, nrow) {
half <- as.integer(thinning / 2)
thinned <- c(rep(FALSE, half), TRUE, rep(FALSE, thinning - half))
if (!missing(nrow) && !is.null(nrow)) {
thinned <- as.vector(outer(rep(thinned, length = nrow),
rep(thinned, length = nrow(xy) / nrow), "&"))
}
# Print(thinned, z, xy, nrow, thinning); xxx
arrows(x0=xy[thinned, 1] - r/2*z[thinned,1],
y0=xy[thinned, 2] - r/2*z[thinned,2],
x1=xy[thinned, 1] + r/2*z[thinned,1],
y1=xy[thinned, 2] + r/2*z[thinned,2], length=0.03, col=col)
}
prepareplotRFsp <- function(x, vdim, select, plot.var,
data.range, var.range,
MARGIN, n,
n.slices, plot.legend, zlim,
...) {
# Print(vdim, select)
if (vdim == 1 && !identical(select, vdim))
stop("the given select.variables does not match the data")
timespacedim <-
if (is(x, "RFspatialGridDataFrame")) length(x@grid@cellsize)
else ncol(x@coords)
if (!(length(MARGIN)==2))
stop("MARGIN must have length 2")
if (!all(MARGIN %in% 1:timespacedim))
stop("chosen MARGINS are out of bounds")
if (!missing(zlim)){
if (is.character(zlim)) stopifnot(zlim=="joint")
mychk <- function(zlim) stopifnot((is.null(dim(zlim)) && length(zlim)==2) ||
(is.matrix(zlim) && nrow(zlim)==2))
if (is.numeric(zlim)) mychk(zlim)
if (is.list(zlim)) {
stopifnot(names(zlim) %in% c("data", "var"))
lapply(zlim, mychk)
}
}
coord.units=x@.RFparams$coord.units
variab.units=x@.RFparams$variab.units;
graphics <- RFoptions()$graphics
image.par <- default.image.par(data.range, var.range, legend=plot.legend)
names.rep <- c(paste("realization", 1:(n-plot.var), sep=" "),
"kriging variance")
names.vdim <-
if (!is.null(names(x@data)) && all(nchar(names(x@data))>0)) {
if (is.list(select)) {
u <- unlist(lapply(strsplit(names(x@data), ".n"),
FUN=function(li) li[[1]]))
lapply(select, function(indices)
if (length(indices)==3) {
if (FALSE) warning("first component interpreted as scalar, the other two as vector")
paste(u[indices[1]], paste(u[indices[-1]], collapse="/"),
sep=" and ")
} else if (length(indices)>3) {
stop("currently, only two-dimensional vectors can be plotted")
} else paste(u[indices], collapse="/"))
} else unlist(lapply(strsplit(names(x@data)[unlist(select)], ".n"),
FUN=function(li) li[[1]]))
} else {
paste("variable", select)
}
names.coords <-
if (.hasSlot(x, "coords"))
dimnames(x@coords)[[2]]
else
names(x@grid@cellcentre.offset)
dots <- list(...)
names.graphics <- names(graphics)
for (i in 1:length(graphics)) {
dots[[names.graphics[i]]] <- NULL
}
dotnames <- names(dots)
if (bgInDots <- "bg" %in% dotnames) {
bgdots <- dots$bg
dots$bg <- NULL
}
lab <- xylabs(names.coords[MARGIN[1]], names.coords[MARGIN[2]],
units=coord.units )
if (!("xlab" %in% dotnames)) dots$xlab <- lab$x
if (!("ylab" %in% dotnames)) dots$ylab <- lab$y
if (!("pch" %in% dotnames)) dots$pch=image.par$data$pch
if (!("cex" %in% dotnames)) dots$cex=image.par$data$cex
## colours, legend
for (i in c("data", "var")) {
if (i=="var" && !plot.var) next
if (is.null(colour <- dots[[ image.par[[i]]$dot.name ]]))
colour <- image.par[[i]]$default.col
image.par[[i]]$col <- if (is.list(colour)) colour else list(colour)
dots[[ image.par[[i]]$dot.name ]] <- NULL
lencol <- length(colour)
image.par[[i]]$range <-
apply(image.par[[i]]$range, 2, function(x) {
if (is.logical(all.equal(x[1], x[2])))
warning("range of data is a single value")
stopifnot(all(is.finite(x)))
r <- range(outer(x, 1 + 0.05 * c(-1,1), "*"))
if (identical(r[1], r[2])) r[2] <- r[2]+1
return(r)
} )
if (!missing(zlim)) {
idx <- unlist(lapply(as.list(select),
FUN=function(x) if (length(x) != 2) x[1] else NA))
idx <- idx[!is.na(idx)]
if (is.character(zlim) && zlim=="joint") {
image.par[[i]]$range[,idx] <- c(min(image.par[[i]]$range[,idx]),
max(image.par[[i]]$range[,idx]))
} else {
zz <- if (is.list(zlim)) zlim[[i]] else zlim
if (!is.null(zz))
image.par[[i]]$range[,idx] <- matrix(zz, nrow=2, ncol=length(idx))
}
}
image.par[[i]]$z.legend <-
as.matrix(apply(image.par[[i]]$range, 2,
function(x) seq(x[1], x[2], length=lencol)))
image.par[[i]]$breaks <-
as.matrix(apply(image.par[[i]]$range, 2,
function(x) seq(x[1]-abs((x[2] - x[1])*1e-3),
x[2]+abs((x[2]-x[1])*1e-3), len=lencol+1)
))
}
### Splitting & Legend Plotting
if (vdim>1) # note: one of n and n.slices is always equal to 1
split.main <- c(n * n.slices, length(select))
else {
if (n * n.slices > 1)
split.main <- c(ceiling(n * n.slices/2), 2) else {
split.main <- c(1,1)
}
}
ArrangeDevice(graphics, figs=split.main) ## NIE par() o.ae. vor ArrangeDevice !!!!
if (length(dev.list()) > 0 &&
any(par()$mfcol != c(1,1))) par(mfcol=c(1,1)) ## first figure appears
par(cex=dots$cex) ## NIE par() o.ae. vor ArrangeDevice !!!!
if (bgInDots) par(bgdots)
xlab.given <- 1 - as.integer("xlab" %in% dotnames && (is.null(dots$xlab) ||
dots$xlab==""))
#if (always.close <- any(split.main > 1) || graphics$always_close_screen){
mar <- c(1,1,0,0)
image.par$data$mar.leg <- mar #+ c(0,0,2,0)
image.par$var$mar.leg <- mar + c(0,0,0,0)
oma.top <- 2*plot.legend + if (is.null(dots$main)) 0 else 2# + xlab.given
oma.left <- 2 * (1 + xlab.given)
oma.bottom <- oma.left + 0*(plot.legend && plot.var)
oma <- c(oma.bottom, oma.left, oma.top, xlab.given) + 0.2
#} else {
# mar <- c(rep(2 * (1 + xlab.given), 2), 0, 0)
# image.par$mar.leg <- c(1, mar[2], 2, 0)
# oma <- rep(0.2, 4) + (!is.null(dots$main)) * c(0,0,2,0)
#}
figs <- c(length(select), prod(split.main) / length(select))
# scr <- split.screen(rbind(c(0,1,if (plot.var) 1-image.par$lower.leg else 0,
# image.par$lower.leg),
# if (plot.legend) c(0, 1, image.par$lower.leg, 1),
# if (plot.var && plot.legend)
# c(0,1,0, 1-image.par$lower.leg)
# ))
scr <- split.screen(rbind(
c(0,1, 0,
if (plot.var) 1-2*(1-image.par$lower.leg) else image.par$lower.leg),
if (plot.legend) c(0, 1, image.par$lower.leg, 1),
if (plot.var && plot.legend) c(0,1,1-2*(1-image.par$lower.leg),
image.par$lower.leg)
))
scr.main <- matrix(nrow = figs[2],
split.screen(split.main, scr[1]),
byrow=TRUE) # statt nr=split.main[1]
scr.legends <- integer(0)
if (plot.legend) {
SCR <- scr
for (i in c("data", "var")) {
if (i == "var" && !plot.var) next
SCR <- SCR[-1]
screen(SCR[1])
scr.leg <- split.screen(figs=c(1, length(select)))
scr.legends <- c(scr.legends, scr.leg)
for (jx in 1:length(scr.leg)) {
j <- if (is.list(select)) select[[jx]] else select[jx]
screen(scr.leg[jx])
par(oma=oma, mar=image.par[[i]]$mar.leg)
if (!is.list(select) || length(select[[jx]]) != 2) {
#Print(i,j,image.par)
lab <- xylabs("", "", units=coord.units)
image(x=image.par[[i]]$z.legend[, j[1]], y=c(0,1),
z=matrix(ncol=2, rep(image.par[[i]]$z.legend[, j[1]], 2)),
axes=FALSE,
xlab=lab$x, ylab=lab$y,
col=image.par[[i]]$col[[1 +(jx-1) %% length(image.par[[i]]$col)]]
)
axis(3, mgp=if (plot.var) c(3,0,0), hadj=if (plot.var) -0.5 else NA)#1 + 2 * (i =="data"))
box()
}
}
}
}
#close.screen(scr)
return(c(image.par,
dots=list(dots),
list(names.coords = names.coords, names.rep = names.rep,
names.vdim = names.vdim,
mar=mar, oma=oma, scr.main=scr.main, scr.legends=scr.legends,
scr = scr,
split.main=split.main,
#always.close=always.close,
grPrintlevel = graphics$grPrintlevel)))
}
PlotTitle <- function(x, main) {
p <- x@.RFparams
if (!is.null(p$krige.method)) main <- paste(p$krige.method, "\n", main)
par(mar=rep(0, 4), new=TRUE)
plot(Inf, Inf, xlim=c(0,1), ylim=c(0,1), axes=FALSE)
text(0, 0.5, labels=main, adj=1, xpd=NA, col="blue", cex=0.8) # links davon
}
plotRFspatialDataFrame <-
function(x, y,
MARGIN, #=c(1,2), # which dimensions are to be plotted
MARGIN.slices, #=NULL,
# in which dimension a sequence of slices is to be plotted
n.slices, #=if (!is.null(MARGIN.slices)) 6 else 1,
nmax, #=6, # max number of repetitins plotted
plot.variance, # = !is.null(x@.RFparams$has.variance) && x@.RFparams$has.variance,
select, #1:vdim,
zlim, # default: missing,
legend, #=TRUE,
MARGIN.movie,
..., plotmethod="image") {
x.grid <- is(x, "RFspatialGridDataFrame")
do.slices <- !is.null(MARGIN.slices)
do.movie <- !is.null(MARGIN.movie)
if (length(MARGIN.slices) > 1) stop("MARGIN.slices must be a scalar.")
if (length(MARGIN.movie) > 1) stop("MARGIN.movie must be a scalar.")
if (!x.grid) {
if (is(x, "RFspatialPointsDataFrame")) {
if (do.slices || n.slices[length(n.slices)] != 1)
stop("'MARGIN.slices' must be 'NULL' and 'n.slices' must be 1.")
} else {
stop("method only for objects of class 'RFspatialPointsDataFrame' and 'RFspatialGridDataFrame'")
}
}
NEWMARGIN <- MARGIN
has.variance <-
!is.null(x@.RFparams$has.variance) && x@.RFparams$has.variance
if (!has.variance) plot.variance <- FALSE
if (x.grid) {
conventional <- rfspDataFrame2conventional(x)
x.grid.vectors <-
GridTopology2gridVectors(cbind(conventional$x,conventional$T))
## array with dims (space-time-dims, vdim, n) AND drop=FALSE!!
timespacedim <- genuine.timespacedim <- length(x.grid.vectors)
if (timespacedim!=length(x@grid@cellsize))
stop("sollte nicht auftauchen: programming error in plotRFspatialGridDataFrame, timespacedim wrong ... (AM)")
if (do.slices){
if (!(MARGIN.slices <= timespacedim))
stop("chosen MARGIN.slices out of bounds")
if (MARGIN.slices %in% MARGIN)
stop("MARGIN.slices must be different from MARGIN")
}
if (length(n.slices)!=1 && length(n.slices)!=3)
stop("n.slices must be an integer of length 1 or 3")
data.arr <- RFspDataFrame2dataArray(x)
vdim <- dim(data.arr)[timespacedim+1]
n.orig <- dim(data.arr)[timespacedim+2] ## including the kriging variance as one repet
n.ohne.var <- n.orig - has.variance
n <- min(n.ohne.var, nmax) + plot.variance
## want to have at least 3 space-time dims, if only 2,
## generate artificial dim
dimdata <- dim(data.arr) # new dims
if (timespacedim <= 3){
if (timespacedim == 3)
dim(data.arr) <- c(dimdata[1:3], 1, dimdata[4:5])
else if (timespacedim==2)
dim(data.arr) <- c(dimdata[1:2], 1, 1, dimdata[3:4])
else stop("dimension too small: dim=", timespacedim)
timespacedim <- 4
}
if (!all(MARGIN %in% 1:(length(dimdata) - 2))) stop("MARGIN out of range.")
if (any(MARGIN.slices %in% MARGIN.movie))
stop("MARGIN.slices and MARGIN.movie are not disjoint.")
if (length(MARGIN.slices) < 1)
MARGIN.slices <-
(1:(max(MARGIN, MARGIN.movie) + 1))[-c(MARGIN, MARGIN.movie)][1]
if (length(MARGIN.movie) < 1)
MARGIN.movie <-
(1:(max(MARGIN, MARGIN.slices) + 1))[-c(MARGIN, MARGIN.slices)][1]
dimdata <- dim(data.arr)
vdimrep <- dimdata[(-1:0) + length(dimdata)]
if (!all(c(MARGIN.movie, MARGIN.slices) %in%
1:(length(dimdata) - 2))) stop("MARGINs out of range.")
xx <- x.grid.vectors[[MARGIN[1]]]
xy <- x.grid.vectors[[MARGIN[2]]]
## reduce the data array by taking a section with respect
## to the dimensions not covered by MARGIN*
mar.vec <- c(MARGIN, MARGIN.slices, MARGIN.movie)
ind <- as.list(rep(1, length(dimdata) - 2))
ind[mar.vec] <- TRUE
data.arr <- do.call("[", c(list(data.arr), ind, TRUE, TRUE, drop=FALSE))
dim(data.arr) <- c(dimdata[sort(mar.vec)], vdimrep)
## re-oredered dimensions such that MARGIN and MARGIN.slices
## and MARGIN.movie are the first 4 dimensions
perm.tmp <- c(mar.vec, (-1:0) + length(dimdata))
data.arr <- aperm(data.arr, perm.tmp)
dimdata <- dim(data.arr)
NEWMARGIN <- 1:2
MARGIN.slices <- 3
MARGIN.movie <- 4
if (do.slices) {
if (n != 1) {
n <- 1
message("only first realization is shown")
}
if (plot.variance){
plot.variance <- FALSE
message("plot.variance was set to FALSE")
}
mar.len <- dimdata[MARGIN.slices]
if (n.slices[length(n.slices)] > mar.len)
n.slices[length(n.slices)] <- mar.len
slices.ind <-
if (length(n.slices) == 1) seq(1, mar.len, length=n.slices)
else seq(n.slices[1], n.slices[2], length=n.slices[3])
slices.ind <- unique(round(slices.ind))
slices.ind <- slices.ind[slices.ind >= 1 & slices.ind <= mar.len]
## which indices in the slices dimension are taken
} else {
slices.ind <- 1
## the first dimension which is not in MARGIN
}
n.slices <- length(slices.ind)
## ersten n.orig-1 sind wiederholungen, die letzte 'Spalte'
## ist die Varianz falls existent
data.idx <- 1 : (n.ohne.var*vdim)
all.i <- as.matrix(expand.grid(1:n.slices, 1:n)[2:1]) ## i, ii
coords <- as.matrix(expand.grid(xx, xy))
m.range <- if (do.movie) 1:dimdata[MARGIN.movie] else 1
# Print(m.range, do.movie, dimdata, MARGIN.movie); kk
} else { ## not grid
vdim <- x@.RFparams$vdim
n <- min(x@.RFparams$n, nmax) + plot.variance
nc <- ncol(x@data)
if (nc < n*vdim)
if (n==1) vdim <- nc else if (vdim==1) n <- nc else {
stop("ncol(x@data) does not match 'x@.RFparams'; change 'x@.RFparams'")
}
data.idx <- 1:(x@.RFparams$n*vdim)
all.i <- cbind(1:n, 1)
genuine.timespacedim <- ncol(x@coords)
coords <- x@coords[, MARGIN]
m.range <- 1
}
if (!(missing.y <- missing(y))) {
if (do.slices)
stop("'y' and 'MARGIN.slices' may not be given at the same time")
#
if (is(y, 'RFspatialGridDataFrame')) {
y.coords <- as(y, "RFspatialPointsDataFrame")@coords
y.data <- y@data
} else if (is(y, "matrix") || is(y, "data.frame")) {
dc <- data.columns(y, xdim = dimensions(x), force=TRUE)
y.coords <- y[, dc$x, drop=FALSE]
y.data <- y[, dc$data, drop=FALSE]
} else {
y.coords <- y@coords
y.data <- y@data
}
}
data.range <-
apply(as.matrix(1:vdim), 1, # statt data.idx # pro vdim eine legend
function(z)
range(if (missing.y)
x@data[z + vdim * 0:(n-plot.variance-1)] else {
idx <- z + vdim * 0:(n-plot.variance-1)
# Print(idx, ncol(y.data), idx[idx <= ncol(y.data)])
c(#x@data[idx],
y.data[, idx[idx <= ncol(y.data)]])
},
na.rm=TRUE))
# Print(data.range, vdim * 0:(n-plot.variance-1))
var.range <- if (plot.variance) sapply(x@data[-data.idx],
range, na.rm=TRUE) else NULL
if (missing(select)) select <- 1:vdim
image.par <- prepareplotRFsp(x=x, vdim=vdim, select=select,
data.range = data.range, var.range=var.range,
plot.var=plot.variance, MARGIN=NEWMARGIN,
n=n, n.slices=n.slices, plot.legend=legend,
zlim=zlim,
...)
image.par$names.vdim <-
add.units(image.par$names.vdim, x@.RFparams$variab.units)
if (x.grid) {
nx.vectors <- min(length(xx), image.par$arrow$nx.vectors)
thinning <- as.integer( (length(xx)-1) / nx.vectors)
} else {
nx.vectors <- min(nrow(coords), image.par$arrow$nx.vectors^2)
thinning <- as.integer( (nrow(coords)-1) / nx.vectors^2)
}
## split the left part according to 'split.main' for different vdims and
## repetitions
# Print(dim(data.arr))
for (m in m.range) {
for (jx in 1:length(select)) {
j <- if (is.list(select)) select[[jx]] else select[jx]
for (ix in 1:nrow(all.i)) {
# Print(m.range, length(select), all.i)
i <- all.i[ix, ]
dots <- dots.with.main.lab <- image.par$dots
main <- dots$main
dots$main <- NULL
lab <- xylabs("", "", units=x@.RFparams$coord.units)
dots$xlab <- lab$x
dots$ylab <- lab$y
if (do.plot.var <- (plot.variance && i[1]==n)){
k <- if (x.grid) n.orig else x@.RFparams$n + 1;
dv <- "var"
} else {
k <- i[1]
dv <- "data"
}
screen(image.par$scr.main[ix, jx])
par(mar=image.par$mar, oma=image.par$oma)
col <-
image.par[[dv]]$col[[1 + (j[1]-1) %% length(image.par[[dv]]$col) ]]
breaks <- image.par[[dv]]$breaks[, j[1]]
genuine.image <- (length(j) == 1 || length(j)==3)
if (x.grid) {
dots$type <- NULL
dots$col <- if (genuine.image) col else par()$bg
plot.return <- do.call(plotmethod,
args=c(dots, list(
x=xx, y=xy, z=data.arr[,,i[2], m, j[1], k],
zlim = image.par[[dv]]$range[, j[1]],
axes=plotmethod == "persp"))
)
} else {
idx <- if (n==1) j else if (vdim==1) k else (k-1)*vdim+j
dots$col <- if (genuine.image)
col[ cut(x@data[,idx[1]], breaks=breaks) ] else par()$bg
do.call(graphics::plot,
args=c(dots, list(x=coords[, 1], y=coords[, 2],
axes=FALSE)))
box()
}
if (n.slices > 1)
legend("bottomright", bty="n",
legend=paste(image.par$names.coords[MARGIN.slices], "=",
x.grid.vectors[[MARGIN.slices]][slices.ind[i[2]]]))
if (do.plot.arrows <- length(j) >= 2 && !do.plot.var) {
jj <- if (length(j) == 3) j[-1] else jj <- j
rx <- range(coords[, 1])
ry <- range(coords[, 2])
col.arrow <- if (length(image.par[["data"]]$col) >= jj[1] &&
length(image.par[["data"]]$col[[jj[1]]]) == 1)
image.par[["data"]]$col[[jj[1]]] else "black"
if (ix == 1) { ## to do: document in a paper?
factor <- image.par$arrow$reduction *
sqrt(diff(rx) * diff(ry) / max(x@data[jj[1]]^2 +
x@data[jj[2]]^2)) / nx.vectors
}
my.arrows(coords, x@data[jj], r = factor, thinning = thinning,
col = col.arrow,
nrow = if (x.grid) length(xx))
}
if (!do.plot.var && !missing.y && (length(j) == 1 || (length(j)==3))) {
idx <- if (n==1) j else if (vdim==1) i[1] else (i[1]-1)*vdim+j
if (ncol(y.data) < idx) idx <- 1
if (plotmethod == "persp") {
# theta = 30, phi = 30, expand = 0.5,
xy <- trans3d(y.coords[, MARGIN[1]], y.coords[, MARGIN[2]],
data[ , idx], pmat=plot.return)
points(xy, pch=16, col="black")
} else {
col2 <- col[ cut(y.data[ , idx], breaks=breaks) ]
dots2 <- dots
dots2[c("type", "pch", "lty", "col", "bg", "cex", "lwd")] <- NULL
addpoints <- function(pch, col, cex) {
do.call(graphics::plot.xy,
args=c(dots2,
list(xy=xy.coords(y.coords[, MARGIN[1]],
y.coords[, MARGIN[2]]),
type="p", pch=pch, lty=1, col=col, bg=NA, cex=cex,
lwd=1)))
}
if (plotmethod=="image") addpoints(15, "darkgray", dots$cex*2)
addpoints(dots$pch, col2, dots$cex)
}
}
if (ix==1 ||
((image.par$split.main[1] != nrow(all.i)) &&
(ix <= image.par$split.main[2]))) { # nrow(all.i) || ) #!image.par$always.close ||
axis(1, outer=TRUE)#image.par$always.close)
}
if (jx==1 &&
((image.par$split.main[2] == length(select)) ||
((ix-1) %% image.par$split.main[2] == 0))) # !image.par$always.close ||
axis(2, outer=TRUE)#image.par$always.close)
##if (!image.par$always.close){
## dots2 <- dots.with.main.lab
## dots2$xlab <- dots2$ylab <- ""
## do.call(graphics::title, args=c(dots2, list(outer=TRUE, line=NA)))
##}
## if (!image.par$always.close) {
## if (x.grid) do.call(graphics::title, args=c(dots, list(outer=FALSE, line=NA)))
## else do.call(graphics::title, args=c(dots, line=2)) # line=-1 (ersetzt (AM))
## ##if (i==1) axis(1, outer=image.par$always.close)
## ##if (j==1) axis(2, outer=image.par$always.close)
## }
if (all(i==1) && (image.par$grPrintlevel > 1 || vdim>1)) {
mtext(text = image.par$names.vdim[jx], # names(x)[j[1]]
side=3, line=-1,
col = image.par$text.col, cex=dots$cex)
##legend("topleft", bty="n", legend=c("", image.par$names.vdim[jx]),
## text.col=image.par$text.col)
}
if (n>1 && jx==1){
mtext(text = image.par$names.rep[ix], side=3, line=-2, cex=dots$cex)
##legend.pos <- "topright" #if (vdim==1) "topright" else "left"
##legend(legend.pos, bty="n", legend=c("", image.par$names.rep[ix]))
}
if (do.plot.arrows && ix == 1) {
## do not merge with ix==1 above !!
## reason: screen is changed here and going back
## is not a good idea
if (image.par$legend) {
screen(image.par$scr.legends[jx])
do.call(graphics::plot, args=c(dots, list(x=Inf, y=Inf,
xlim=rx, ylim=c(0,1), axes=FALSE)))
len <- max(pretty(diff(rx) / image.par$arrows$nx.vectors/2 /factor))
x.arrow<- cbind(mean(rx), image.par$arrows$leg.pos[1+genuine.image])
my.arrows(x.arrow, cbind(len, 0), r = factor,
thinning=0, col=col.arrow)
text(x.arrow, pos=1, labels = len)
}
}
}
}
#if (image.par$always.close) {
#if (x.grid){
dots.with.main.lab$type <- NULL # woher kommt dieses type??
## falls nicht auf NULL gesetzt gibt es einen Fehler. Warum?
do.call(graphics::title,
args=list(main=dots.with.main.lab$main,
outer=TRUE, line=image.par$oma[3]-1.5))
dots.with.main.lab$main <- NULL
do.call(graphics::title, args=c(dots.with.main.lab, list(outer=TRUE, line=NA)))
##} else {
## do.call(graphics::title, args=c(dots, list(outer=TRUE)))
##}
if (image.par$grPrintlevel > 0) {
screen(image.par$scr[1 + image.par$legend], new=FALSE)
PlotTitle(x, if (is.null(main)) "" else main)
}
}
graphics <- RFoptions()$graphics
if (graphics$always_close_screen){
close.screen(all.screens=TRUE)
} else {
close.screen(c(image.par$scr.main, image.par$scr.legends, image.par$scr))
}
return(invisible())
}
# plotRFgridDataFrame <- function(x, y, nmax, plot.variance, ...)
# siehe nicht.nachladbar.R
plotRFdataFrame <- function(x, y, nmax=6, plot.variance, legend, ...) {
## grid : sorted = TRUE
## points : sorted = FALSE
# Print(close.screen(), dev.cur()); print(dev.list())
stopifnot(!missing(x))
x <- trafo_pointsdata(x)
nc <- ncol(x$data)
if (!missing(y)) {
y <- trafo_pointsdata(y, dimensions(dim))
y$data <- rep(y$data, length.out=nrow(y$data) * nc)
dim(y$data) <- c(length(y$coords), nc)
}
has.variance <- !is.null(x$RFparams$has.variance) && x$RFparams$has.variance
if (!has.variance) plot.variance <- FALSE
n <- min(x$RFparams$n, nmax) + plot.variance
vdim <- x$RFparams$vdim
if (nc < n*vdim) {
if (n==1) vdim <- nc else if (vdim==1) n <- nc else {
stop("ncol(x@data) does not match 'x@.RFparams'; change 'x@.RFparams'")
}
}
graphics <- RFoptions()$graphics
# Print(graphics, close.screen(), dev.cur()); print(dev.list())
ArrangeDevice(graphics, c(1, n)) ## NIE par vor ArrangeDevice !!!!
# Print(close.screen(), dev.cur()); print(dev.list())
always.close <- n > 1 || graphics$always_close_screen
if (any(par()$mfcol != c(1,1))) par(mfcol=c(1,1))
dots <- list(...)
dotnames <- names(dots)
if ("bg" %in% dotnames) {
par(bg=dots$bg)
dots$bg <- NULL
}
if (!("xlab" %in% dotnames)) dots$xlab <- x$lab$x
if (!("type" %in% dotnames)) dots$type <- "l"
make.small.mar <- ("xlab" %in% dotnames &&
is.null(dots$xlab) && is.null(dots$ylab))
## variable names
## Print(x); lll
if (!is.null(x$labdata) && all(nchar(x$labdata)>0))
names.vdim <- unlist(lapply(strsplit(x$labdata[1:vdim], ".n"),
FUN=function(li) li[[1]]))
else {
names.vdim <- paste("variable", 1:vdim)
x$labdata <- names.vdim
}
if (n>1){
ylab.vec <- c(paste("realization ", 1:(n-plot.variance), sep=""),
if (plot.variance) "kriging variance")
} else {
ylab.vec <- if (vdim==1) x$colnames else ""
}
if ("ylab" %in% dotnames) {
if (!is.null(dots$ylab))
ylab.vec[1:length(ylab.vec)] <- dots$ylab
dots$ylab <- NULL
}
col <- 1:vdim
if ("col" %in% dotnames) {
if (!is.null(dots$col))
col[1:length(col)] <- dots$col
dots$col <- NULL
}
split.screen(c(n,1))
# if (always.close) {
# close.screen(all.screens=TRUE)
# par(mfrow=c(1,1))
# split.screen(c(n,1))
# }
for (i in 1:n){
screen(i)
if (make.small.mar)
par(oma=c(3,0,1,1)+.1, mar=c(0,3,0,0))
else
par(oma=c(4,0,1,1)+.1, mar=c(0,4,0,0))
ylab <- ylab.vec[i]
if (tmp.idx <- (plot.variance && i==n)){
i <- x$RFparams$n + plot.variance
}
do.call(graphics::plot,
args=c(dots, list(
x=x$coords, y=x$data[ , vdim*(i-1)+1],
xaxt="n", yaxt="n", ylab=ylab, col=col[1]))
)
if (!missing(y)) {
points(x=y$coords, y=y$data[ , vdim*(i-1)+1], pch=22, col="red")
}
axis(2)
if (tmp.idx) i <- n
if(i==n){
axis(1, outer=always.close)
title(xlab=dots$xlab, outer=TRUE) # always.close)
}
else axis(1, labels=FALSE)
for (j in 1:vdim){
if (j==1) next
do.call(graphics::points, quote=TRUE,
args=c(dots, list(
x=x$coords, y=x$data[ , vdim*(i-1)+j], col=col[j]))
)
if (!missing(y)) {
points(x=y$coords, y=y$data[ , vdim*(i-1)+j], pch=22, col="red")
}
if (i==1) {
if ( (!TRUE || vdim > 1) && legend) {
legend("topright", col=col, lty=1, legend = c(names.vdim))
}
}
}
}
if (always.close) close.screen(all.screens=TRUE)
}