-## plot.phylo.R (2009-03-27)
+## plot.phylo.R (2009-09-23)
## Plot Phylogenies
lab4ut = "horizontal", tip.color = "black", ...)
{
Ntip <- length(x$tip.label)
- if (Ntip == 1) stop("found only one tip in the tree!")
- Nedge <- dim(x$edge)[1]
+ if (Ntip == 1) {
+ warning("found only one tip in the tree")
+ return(NULL)
+ }
if (any(tabulate(x$edge[, 1]) == 1))
- stop("there are single (non-splitting) nodes in your tree; you may need to use collapse.singles().")
+ stop("there are single (non-splitting) nodes in your tree; you may need to use collapse.singles()")
+
+ .nodeHeight <- function(Ntip, Nnode, edge, Nedge, yy)
+ .C("node_height", as.integer(Ntip), as.integer(Nnode),
+ as.integer(edge[, 1]), as.integer(edge[, 2]),
+ as.integer(Nedge), as.double(yy),
+ DUP = FALSE, PACKAGE = "ape")[[6]]
+
+ .nodeDepth <- function(Ntip, Nnode, edge, Nedge)
+ .C("node_depth", as.integer(Ntip), as.integer(Nnode),
+ as.integer(edge[, 1]), as.integer(edge[, 2]),
+ as.integer(Nedge), double(Ntip + Nnode),
+ DUP = FALSE, PACKAGE = "ape")[[6]]
+
+ .nodeDepthEdgelength <- function(Ntip, Nnode, edge, Nedge, edge.length)
+ .C("node_depth_edgelength", as.integer(Ntip),
+ as.integer(Nnode), as.integer(edge[, 1]),
+ as.integer(edge[, 2]), as.integer(Nedge),
+ as.double(edge.length), double(Ntip + Nnode),
+ DUP = FALSE, PACKAGE = "ape")[[7]]
+
+ Nedge <- dim(x$edge)[1]
Nnode <- x$Nnode
ROOT <- Ntip + 1
type <- match.arg(type, c("phylogram", "cladogram", "fan",
direction <- match.arg(direction, c("rightwards", "leftwards",
"upwards", "downwards"))
if (is.null(x$edge.length)) use.edge.length <- FALSE
- if (type == "unrooted" || !use.edge.length) root.edge <- FALSE
+
+ ## the order of the last two conditions is important:
+ if (type %in% c("unrooted", "radial") || !use.edge.length ||
+ is.null(x$root.edge) || !x$root.edge) root.edge <- FALSE
+ if (type == "fan" && root.edge) {
+ warning("drawing root edge with type = 'fan' is not yet supported")
+ root.edge <- FALSE
+ }
+
phyloORclado <- type %in% c("phylogram", "cladogram")
horizontal <- direction %in% c("rightwards", "leftwards")
if (phyloORclado) {
## we first compute the y-coordinates of the tips.
- ## Fix from Klaus Schliep (2007-06-16):
- if (!is.null(attr(x, "order")))
- if (attr(x, "order") == "pruningwise")
- x <- reorder(x)
- ## End of fix
+ phyOrder <- attr(x, "order")
+ ## make sure the tree is in cladewise order:
+ if (is.null(phyOrder) || phyOrder != "cladewise") {
+ xe <- x$edge
+ x <- reorder(x) # fix from Klaus Schliep (2007-06-16)
+ if (!identical(x$edge, xe)) {
+ ## modified from Li-San Wang's fix (2007-01-23):
+ ereorder <- match(x$edge[, 2], xe[, 2])
+ if (length(edge.color) > 1) {
+ edge.color <- rep(edge.color, length.out = Nedge)
+ edge.color <- edge.color[ereorder]
+ }
+ if (length(edge.width) > 1) {
+ edge.width <- rep(edge.width, length.out = Nedge)
+ edge.width <- edge.width[ereorder]
+ }
+ if (length(edge.lty) > 1) {
+ edge.lty <- rep(edge.lty, length.out = Nedge)
+ edge.lty <- edge.lty[ereorder]
+ }
+ }
+ }
+### By contrats to ape (< 2.4), the arguments edge.color, etc., are
+### not elongated before being passed to segments(), except if needed
+### to be reordered
yy <- numeric(Ntip + Nnode)
TIPS <- x$edge[x$edge[, 2] <= Ntip, 2]
yy[TIPS] <- 1:Ntip
}
- edge.color <- rep(edge.color, length.out = Nedge)
- edge.width <- rep(edge.width, length.out = Nedge)
- edge.lty <- rep(edge.lty, length.out = Nedge)
- ## fix from Li-San Wang (2007-01-23):
- xe <- x$edge
- x <- reorder(x, order = "pruningwise")
- ereorder <- match(x$edge[, 2], xe[, 2])
- edge.color <- edge.color[ereorder]
- edge.width <- edge.width[ereorder]
- ## End of fix
+ ## 'z' is the tree in pruningwise order used in calls to .C
+ z <- reorder(x, order = "pruningwise")
+### edge.color <- rep(edge.color, length.out = Nedge)
+### edge.width <- rep(edge.width, length.out = Nedge)
+### edge.lty <- rep(edge.lty, length.out = Nedge)
+### ## fix from Li-San Wang (2007-01-23):
+### xe <- x$edge
+### x <- reorder(x, order = "pruningwise")
+### ereorder <- match(x$edge[, 2], xe[, 2])
+### edge.color <- edge.color[ereorder]
+### edge.width <- edge.width[ereorder]
+### edge.lty <- edge.lty[ereorder]
+### ## end of fix
if (phyloORclado) {
if (is.null(node.pos)) {
node.pos <- 1
if (type == "cladogram" && !use.edge.length) node.pos <- 2
}
if (node.pos == 1)
- yy <- .C("node_height", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), as.double(yy),
- DUP = FALSE, PACKAGE = "ape")[[6]]
+ yy <- .nodeHeight(Ntip, Nnode, z$edge, Nedge, yy)
else {
## node_height_clado requires the number of descendants
## for each node, so we compute `xx' at the same time
ans <- .C("node_height_clado", as.integer(Ntip),
- as.integer(Nnode), as.integer(x$edge[, 1]),
- as.integer(x$edge[, 2]), as.integer(Nedge),
+ as.integer(Nnode), as.integer(z$edge[, 1]),
+ as.integer(z$edge[, 2]), as.integer(Nedge),
double(Ntip + Nnode), as.double(yy),
DUP = FALSE, PACKAGE = "ape")
xx <- ans[[6]] - 1
yy <- ans[[7]]
}
if (!use.edge.length) {
- if(node.pos != 2)
- xx <- .C("node_depth", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[6]] - 1
+ if (node.pos != 2) xx <- .nodeDepth(Ntip, Nnode, z$edge, Nedge) - 1
xx <- max(xx) - xx
} else {
- xx <- .C("node_depth_edgelength", as.integer(Ntip),
- as.integer(Nnode), as.integer(x$edge[, 1]),
- as.integer(x$edge[, 2]), as.integer(Nedge),
- as.double(x$edge.length), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[7]]
+ xx <- .nodeDepthEdgelength(Ntip, Nnode, z$edge, Nedge, z$edge.length)
}
}
if (type == "fan") {
## if the tips are not in the same order in tip.label
## and in edge[, 2], we must reorder the angles: we
## use `xx' to store temporarily the angles
- TIPS <- xe[which(xe[, 2] <= Ntip), 2]
+ TIPS <- x$edge[which(x$edge[, 2] <= Ntip), 2]
xx <- seq(0, 2*pi*(1 - 1/Ntip), 2*pi/Ntip)
theta <- double(Ntip)
theta[TIPS] <- xx
theta <- c(theta, numeric(Nnode))
- theta <- .C("node_height", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), theta, DUP = FALSE,
- PACKAGE = "ape")[[6]]
+ theta <- .nodeHeight(Ntip, Nnode, z$edge, Nedge, theta)
if (use.edge.length) {
- r <- .C("node_depth_edgelength", as.integer(Ntip),
- as.integer(Nnode), as.integer(x$edge[, 1]),
- as.integer(x$edge[, 2]), as.integer(Nedge),
- as.double(x$edge.length), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[7]]
+ r <- .nodeDepthEdgelength(Ntip, Nnode, z$edge, Nedge, z$edge.length)
} else {
- r <- .C("node_depth", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[6]]
+ r <- .nodeDepth(Ntip, Nnode, z$edge, Nedge)
r <- 1/r
}
xx <- r*cos(theta)
}
if (type == "unrooted") {
+ nb.sp <- .nodeDepth(Ntip, Nnode, z$edge, Nedge)
XY <- if (use.edge.length)
- unrooted.xy(Ntip, Nnode, x$edge, x$edge.length)
+ unrooted.xy(Ntip, Nnode, z$edge, z$edge.length, nb.sp)
else
- unrooted.xy(Ntip, Nnode, x$edge, rep(1, Nedge))
+ unrooted.xy(Ntip, Nnode, z$edge, rep(1, Nedge), nb.sp)
## rescale so that we have only positive values
xx <- XY$M[, 1] - min(XY$M[, 1])
yy <- XY$M[, 2] - min(XY$M[, 2])
}
if (type == "radial") {
- X <- .C("node_depth", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[6]]
+ X <- .nodeDepth(Ntip, Nnode, z$edge, Nedge)
X[X == 1] <- 0
## radius:
X <- 1 - X/Ntip
## angle (1st compute the angles for the tips):
yy <- c((1:Ntip)*2*pi/Ntip, rep(0, Nnode))
- Y <- .C("node_height", as.integer(Ntip), as.integer(Nnode),
- as.integer(x$edge[, 1]), as.integer(x$edge[, 2]),
- as.integer(Nedge), as.double(yy),
- DUP = FALSE, PACKAGE = "ape")[[6]]
+ Y <- .nodeHeight(Ntip, Nnode, z$edge, Nedge, yy)
xx <- X * cos(Y)
yy <- X * sin(Y)
}
- if (phyloORclado && direction != "rightwards") {
- if (direction == "leftwards") {
- xx <- -xx
- xx <- xx - min(xx)
- }
+ if (phyloORclado) {
if (!horizontal) {
tmp <- yy
yy <- xx
xx <- tmp - min(tmp) + 1
- if (direction == "downwards") {
- yy <- -yy
- yy <- yy - min(yy)
- }
}
- }
- if (phyloORclado && root.edge) {
- if (direction == "rightwards") xx <- xx + x$root.edge
- if (direction == "upwards") yy <- yy + x$root.edge
+ if (root.edge) {
+ if (direction == "rightwards") xx <- xx + x$root.edge
+ if (direction == "upwards") yy <- yy + x$root.edge
+ }
}
if (no.margin) par(mai = rep(0, 4))
if (is.null(x.lim)) {
if (phyloORclado) {
if (horizontal) {
x.lim <- c(0, NA)
- tmp <-
- if (show.tip.label) nchar(x$tip.label) * 0.018 * max(xx) * cex
- else 0
- x.lim[2] <-
- if (direction == "leftwards") max(xx[ROOT] + tmp)
- else max(xx[1:Ntip] + tmp)
+ pin1 <- par("pin")[1] # width of the device in inches
+ strWi <- strwidth(x$tip.label, "inches") # id. for the tip labels
+ ## 1.04 comes from that we are using a regular axis system
+ ## with 4% on both sides of the range of x:
+ xx.tips <- xx[1:Ntip] * 1.04
+ ## 'alp' is the conversion coefficient from
+ ## user coordinates to inches:
+ alp <- try(uniroot(function(a) max(a*xx.tips + strWi) - pin1,
+ c(0, 1e6))$root, silent = TRUE)
+ ## if the above fails, give 1/3 of the device for the tip labels:
+ if (is.character(alp)) tmp <- max(xx.tips)*1.5 else {
+ tmp <- if (show.tip.label) max(xx.tips + strWi/alp) else max(xx.tips)
+ }
+ x.lim[2] <- tmp
+ if (direction == "leftwards") xx <- x.lim[2] - xx #max(xx[ROOT] + tmp)
+# else max(xx[1:Ntip] + tmp)
} else x.lim <- c(1, Ntip)
}
if (type == "fan") {
if (phyloORclado) {
if (horizontal) y.lim <- c(1, Ntip) else {
y.lim <- c(0, NA)
- tmp <-
- if (show.tip.label) nchar(x$tip.label) * 0.018 * max(yy) * cex
- else 0
- y.lim[2] <-
- if (direction == "downwards") max(yy[ROOT] + tmp)
- else max(yy[1:Ntip] + tmp)
+ pin2 <- par("pin")[2] # height of the device in inches
+ strWi <- strwidth(x$tip.label, "inches")
+ ## 1.04 comes from that we are using a regular axis system
+ ## with 4% on both sides of the range of x:
+ yy.tips <- yy[1:Ntip] * 1.04
+ ## 'alp' is the conversion coefficient from
+ ## user coordinates to inches:
+ alp <- try(uniroot(function(a) max(a*yy.tips + strWi) - pin2,
+ c(0, 1e6))$root, silent = TRUE)
+ ## if the above fails, give 1/3 of the device for the tip labels:
+ if (is.character(alp)) tmp <- max(yy.tips)*1.5 else {
+ tmp <- if (show.tip.label) max(yy.tips + strWi/alp) else max(yy.tips)
+ }
+ y.lim[2] <- tmp
+ if (direction == "downwards") yy <- y.lim[2] - yy
}
}
if (type == "fan") {
}
## fix by Klaus Schliep (2008-03-28):
asp <- if (type %in% c("fan", "radial")) 1 else NA
- plot(0, type = "n", xlim = x.lim, ylim = y.lim, xlab = "",
- ylab = "", xaxt = "n", yaxt = "n", bty = "n", asp = asp, ...)
+ plot(0, type = "n", xlim = x.lim, ylim = y.lim, ann = FALSE, axes = FALSE, asp = asp, ...)
if (is.null(adj))
- adj <- if (phyloORclado && direction == "leftwards") 1 else 0
- if (phyloORclado) {
+ adj <- if (phyloORclado && direction == "leftwards") 1 else 0
+ if (phyloORclado && show.tip.label) {
MAXSTRING <- max(strwidth(x$tip.label, cex = cex))
+ loy <- 0
if (direction == "rightwards") {
lox <- label.offset + MAXSTRING * 1.05 * adj
- loy <- 0
}
if (direction == "leftwards") {
lox <- -label.offset - MAXSTRING * 1.05 * (1 - adj)
- loy <- 0
- xx <- xx + MAXSTRING
+ #xx <- xx + MAXSTRING
}
if (!horizontal) {
psr <- par("usr")
- MAXSTRING <- MAXSTRING * 1.09 * (psr[4] - psr[3]) / (psr[2] - psr[1])
+ MAXSTRING <- MAXSTRING * 1.09 * (psr[4] - psr[3])/(psr[2] - psr[1])
loy <- label.offset + MAXSTRING * 1.05 * adj
lox <- 0
srt <- 90 + srt
if (direction == "downwards") {
loy <- -loy
- yy <- yy + MAXSTRING
+ ##yy <- yy + MAXSTRING
srt <- 180 + srt
}
}
phylogram.plot(x$edge, Ntip, Nnode, xx, yy,
horizontal, edge.color, edge.width, edge.lty)
} else {
- if (type == "fan")
- circular.plot(x$edge, Ntip, Nnode, xx, yy, theta,
- r, edge.color, edge.width, edge.lty)
- else
+ if (type == "fan") {
+ ereorder <- match(z$edge[, 2], x$edge[, 2])
+ if (length(edge.color) > 1) {
+ edge.color <- rep(edge.color, length.out = Nedge)
+ edge.color <- edge.color[ereorder]
+ }
+ if (length(edge.width) > 1) {
+ edge.width <- rep(edge.width, length.out = Nedge)
+ edge.width <- edge.width[ereorder]
+ }
+ if (length(edge.lty) > 1) {
+ edge.lty <- rep(edge.lty, length.out = Nedge)
+ edge.lty <- edge.lty[ereorder]
+ }
+ circular.plot(z$edge, Ntip, Nnode, xx, yy, theta,
+ r, edge.color, edge.width, edge.lty)
+ } else
cladogram.plot(x$edge, xx, yy, edge.color, edge.width, edge.lty)
}
if (root.edge)
"downwards" = segments(xx[ROOT], yy[ROOT], xx[ROOT], yy[ROOT] + x$root.edge))
if (show.tip.label) {
if (!underscore) x$tip.label <- gsub("_", " ", x$tip.label)
- if (phyloORclado) {
+
+ if (phyloORclado)
text(xx[1:Ntip] + lox, yy[1:Ntip] + loy, x$tip.label, adj = adj,
font = font, srt = srt, cex = cex, col = tip.color)
- }
+
if (type == "unrooted") {
if (lab4ut == "horizontal") {
y.adj <- x.adj <- numeric(Ntip)
adj <- as.numeric(abs(XY$axe) > pi/2)
srt <- 180*XY$axe/pi
srt[as.logical(adj)] <- srt[as.logical(adj)] - 180
- ## <FIXME> temporary check of the values of `srt':
- ## set to 0 if "-0.000001 < srt < 0"
- sel <- srt > -1e-6 & srt < 0
- if (any(sel)) srt[sel] <- 0
- ## </FIXME>
- ## `srt' takes only a single value, so we cannot vectorize this:
+ ## `srt' takes only a single value, so can't vectorize this:
for (i in 1:Ntip)
text(xx[i], yy[i], cex = cex, x$tip.label[i], adj = adj[i],
font = font, srt = srt[i], col = tip.color[i])
angle[s3] <- 180 - angle[s3]
adj <- numeric(Ntip)
adj[xx[1:Ntip] < 0] <- 1
- ## `srt' takes only a single value, so we cannot vectorize this:
+ ## `srt' takes only a single value, so can't vectorize this:
for (i in 1:Ntip)
text(xx[i], yy[i], x$tip.label[i], font = font, cex = cex,
srt = angle[i], adj = adj[i], col = tip.color[i])
label.offset = label.offset, x.lim = x.lim, y.lim = y.lim,
direction = direction, tip.color = tip.color,
Ntip = Ntip, Nnode = Nnode)
- assign("last_plot.phylo", c(L, list(edge = xe, xx = xx, yy = yy)),
+ assign("last_plot.phylo", c(L, list(edge = x$edge, xx = xx, yy = yy)),
envir = .PlotPhyloEnv)
invisible(L)
}
## un trait vertical à chaque noeud...
x0v <- xx[nodes]
y0v <- y1v <- numeric(Nnode)
+ ## store the index of each node in the 1st column of edge:
+ NodeInEdge1 <- vector("list", Nnode)
for (i in nodes) {
- j <- edge[which(edge[, 1] == i), 2]
- y0v[i - Ntip] <- min(yy[j])
- y1v[i - Ntip] <- max(yy[j])
+ ii <- i - Ntip
+ j <- NodeInEdge1[[ii]] <- which(edge[, 1] == i)
+ tmp <- range(yy[edge[j, 2]])
+ y0v[ii] <- tmp[1]
+ y1v[ii] <- tmp[2]
}
## ... et un trait horizontal partant de chaque tip et chaque noeud
## vers la racine
- sq <- if (Nnode == 1) 1:Ntip else c(1:Ntip, nodes[-1])
- y0h <- yy[sq]
- x1h <- xx[sq]
- ## match() is very useful here becoz each element in edge[, 2] is
- ## unique (not sure this is so useful in edge[, 1]; needs to be checked)
- ## `pos' gives for each element in `sq' its index in edge[, 2]
- pos <- match(sq, edge[, 2])
- x0h <- xx[edge[pos, 1]]
+### sq <- c(1:Ntip, nodes[-1])
+### y0h <- yy[sq]
+### x1h <- xx[sq]
+### ## match() is very useful here becoz each element in edge[, 2] is
+### ## unique (not sure this is so useful in edge[, 1]; needs to be checked)
+### ## `pos' gives for each element in `sq' its index in edge[, 2]
+### pos <- match(sq, edge[, 2])
+### x0h <- xx[edge[pos, 1]]
+ x0h <- xx[edge[, 1]]
+ x1h <- xx[edge[, 2]]
+ y0h <- yy[edge[, 2]]
+### donc plus besoin de 'pos' ni 'sq'
- ## function dispatching the features to the vertical edges
- foo <- function(edge.feat, default) {
- e <- unique(edge.feat)
- if (length(e) == 1) return(rep(e, Nnode)) else {
- feat.v <- rep(default, Nnode)
- for (i in 1:Nnode) {
- br <- which(edge[, 1] == i + Ntip)
- x <- unique(edge.feat[br])
- if (length(x) == 1) feat.v[i] <- x
+ nc <- length(edge.color)
+ nw <- length(edge.width)
+ nl <- length(edge.lty)
+
+ if (nc + nw + nl == 3) {
+ color.v <- edge.color
+ width.v <- edge.width
+ lty.v <- edge.lty
+ } else {
+ Nedge <- dim(edge)[1]
+ edge.color <- rep(edge.color, length.out = Nedge)
+ edge.width <- rep(edge.width, length.out = Nedge)
+ edge.lty <- rep(edge.lty, length.out = Nedge)
+ DF <- data.frame(edge.color, edge.width, edge.lty)
+ color.v <- rep("black", Nnode)
+ width.v <- rep(1, Nnode)
+ lty.v <- rep(1, Nnode)
+ for (i in 1:Nnode) {
+ br <- NodeInEdge1[[i]]
+ if (length(br) > 2) {
+ x <- unique(DF[br, 1])
+ if (length(x) == 1) color.v[i] <- x
+ x <- unique(DF[br, 2])
+ if (length(x) == 1) width.v[i] <- x
+ x <- unique(DF[br, 3])
+ if (length(x) == 1) lty.v[i] <- x
+ } else {
+ A <- br[1]
+ B <- br[2]
+ if (any(DF[A, ] != DF[B, ])) {
+ color.v[i] <- edge.color[B]
+ width.v[i] <- edge.width[B]
+ lty.v[i] <- edge.lty[B]
+ ## add a new line:
+ y0v <- c(y0v, y0v[i])
+ y1v <- c(y1v, yy[i + Ntip])
+ x0v <- c(x0v, x0v[i])
+ color.v <- c(color.v, edge.color[A])
+ width.v <- c(width.v, edge.width[A])
+ lty.v <- c(lty.v, edge.lty[A])
+ ## shorten the line:
+ y0v[i] <- yy[i + Ntip]
+ } else {
+ color.v[i] <- edge.color[A]
+ width.v[i] <- edge.width[A]
+ lty.v[i] <- edge.lty[A]
+ }
}
}
- feat.v
}
- color.v <- foo(edge.color, "black")
- width.v <- foo(edge.width, 1)
- lty.v <- foo(edge.lty, 1)
- ## we need to reorder:
- edge.width <- edge.width[pos]
- edge.color <- edge.color[pos]
- edge.lty <- edge.lty[pos]
+### ## function dispatching the features to the vertical edges
+### foo <- function(edge.feat, default) {
+### e <- unique(edge.feat)
+### if (length(e) == 1) return(rep(e, Nnode))
+### else {
+### feat.v <- rep(default, Nnode)
+### for (i in 1:Nnode) {
+### br <- NodeInEdge1[[i]]
+### if (length(br) > 2) {
+### x <- unique(edge.feat[br])
+### if (length(x) == 1) feat.v[i] <- x
+### } else {
+### if (edge.feat[br[1]] == edge.feat[br[2]])
+### feat.v[i] <- edge.feat[br[1]]
+### else {
+### feat.v[i] <- edge.feat[br[2]]
+### ## add a new line:
+### y0v <<- c(y0v, y0v[i])
+### y1v <<- c(y1v, yy[i + Ntip])
+### x0v <<- c(x0v, x0v[i])
+### feat.v <- c(feat.v, edge.feat[br[1]])
+### ## shorten the line:
+### y0v[i] <<- yy[i + Ntip]
+### }
+### }
+### }
+### }
+### feat.v
+### }
+### color.v <- foo(edge.color, "black")
+### width.v <- foo(edge.width, 1)
+### lty.v <- foo(edge.lty, 1)
+
+### ## we need to reorder:
+### edge.width <- edge.width[pos]
+### edge.color <- edge.color[pos]
+### edge.lty <- edge.lty[pos]
+
if (horizontal) {
- segments(x0v, y0v, x0v, y1v, col = color.v, lwd = width.v, lty = lty.v) # draws vertical lines
segments(x0h, y0h, x1h, y0h, col = edge.color, lwd = edge.width, lty = edge.lty) # draws horizontal lines
+ segments(x0v, y0v, x0v, y1v, col = color.v, lwd = width.v, lty = lty.v) # draws vertical lines
} else {
- segments(y0v, x0v, y1v, x0v, col = color.v, lwd = width.v, lty = lty.v) # draws horizontal lines
segments(y0h, x0h, y0h, x1h, col = edge.color, lwd = edge.width, lty = edge.lty) # draws vertical lines
+ segments(y0v, x0v, y1v, x0v, col = color.v, lwd = width.v, lty = lty.v) # draws horizontal lines
}
}
cladogram.plot <- function(edge, xx, yy, edge.color, edge.width, edge.lty)
- segments(xx[edge[, 1]], yy[edge[, 1]], xx[edge[, 2]], yy[edge[, 2]],
- col = edge.color, lwd = edge.width, lty = edge.lty)
+ segments(xx[edge[, 1]], yy[edge[, 1]], xx[edge[, 2]], yy[edge[, 2]],
+ col = edge.color, lwd = edge.width, lty = edge.lty)
circular.plot <- function(edge, Ntip, Nnode, xx, yy, theta,
r, edge.color, edge.width, edge.lty)
+### 'edge' must be in pruningwise order
{
r0 <- r[edge[, 1]]
r1 <- r[edge[, 2]]
theta0 <- theta[edge[, 2]]
+ costheta0 <- cos(theta0)
+ sintheta0 <- sin(theta0)
- x0 <- r0*cos(theta0)
- y0 <- r0*sin(theta0)
- x1 <- r1*cos(theta0)
- y1 <- r1*sin(theta0)
+ x0 <- r0 * costheta0
+ y0 <- r0 * sintheta0
+ x1 <- r1 * costheta0
+ y1 <- r1 * sintheta0
segments(x0, y0, x1, y1, col = edge.color, lwd = edge.width, lty = edge.lty)
tmp <- which(diff(edge[, 1]) != 0)
start <- c(1, tmp + 1)
- end <- c(tmp, dim(edge)[1])
+ Nedge <- dim(edge)[1]
+ end <- c(tmp, Nedge)
+
+ ## function dispatching the features to the arcs
+ foo <- function(edge.feat, default) {
+ if (length(edge.feat) == 1) return(rep(edge.feat, Nnode))
+ else {
+ edge.feat <- rep(edge.feat, length.out = Nedge)
+ feat.arc <- rep(default, Nnode)
+ for (k in 1:Nnode) {
+ tmp <- edge.feat[start[k]]
+ if (tmp == edge.feat[end[k]]) feat.arc[k] <- tmp
+ }
+ }
+ feat.arc
+ }
+ co <- foo(edge.color, "black")
+ lw <- foo(edge.width, 1)
+ ly <- foo(edge.lty, 1)
for (k in 1:Nnode) {
i <- start[k]
j <- end[k]
X <- rep(r[edge[i, 1]], 100)
Y <- seq(theta[edge[i, 2]], theta[edge[j, 2]], length.out = 100)
- co <- if (edge.color[i] == edge.color[j]) edge.color[i] else "black"
- lw <- if (edge.width[i] == edge.width[j]) edge.width[i] else 1
- ly <- if (edge.lty[i] == edge.lty[j]) edge.lty[i] else 1
- lines(X*cos(Y), X*sin(Y), col = co, lwd = lw, lty = ly)
+ lines(X*cos(Y), X*sin(Y), col = co[k], lwd = lw[k], lty = ly[k])
}
}
-unrooted.xy <- function(Ntip, Nnode, edge, edge.length)
+unrooted.xy <- function(Ntip, Nnode, edge, edge.length, nb.sp)
{
foo <- function(node, ANGLE, AXIS) {
ind <- which(edge[, 1] == node)
for (i in sons)
if (i > Ntip) foo(i, angle[i], axis[i])
}
- root <- Ntip + 1
Nedge <- dim(edge)[1]
yy <- xx <- numeric(Ntip + Nnode)
- nb.sp <- .C("node_depth", as.integer(Ntip), as.integer(Nnode),
- as.integer(edge[, 1]), as.integer(edge[, 2]),
- as.integer(Nedge), double(Ntip + Nnode),
- DUP = FALSE, PACKAGE = "ape")[[6]]
## `angle': the angle allocated to each node wrt their nb of tips
## `axis': the axis of each branch
axis <- angle <- numeric(Ntip + Nnode)
## start with the root...
- ## xx[root] <- yy[root] <- 0 # already set!
- foo(root, 2*pi, 0)
+ foo(Ntip + 1L, 2*pi, 0)
M <- cbind(xx, yy)
axe <- axis[1:Ntip] # the axis of the terminal branches (for export)
par(ask = TRUE)
on.exit(par(ask = FALSE))
}
- for (i in 1:length(x)) plot(x[[i]], ...)
+ for (i in x) plot(i, ...)
}
projects / ape.git / blobdiff