revdep/library/simts/new/ggplot2/doc/extending-ggplot2.R
In SMAC-Group/simts: Time Series Analysis Tools
## ---- include = FALSE---------------------------------------------------------
knitr::opts_chunk$set(collapse = TRUE, comment = "#>", fig.width = 7, fig.height = 7, fig.align = "center")
library(ggplot2)
## ----ggproto-intro------------------------------------------------------------
A <- ggproto("A", NULL,
x = 1,
inc = function(self) {
self$x <- self$x + 1
}
)
A$x
A$inc()
A$x
A$inc()
A$inc()
A$x
## ----chull--------------------------------------------------------------------
StatChull <- ggproto("StatChull", Stat,
compute_group = function(data, scales) {
data[chull(data$x, data$y), , drop = FALSE]
},
required_aes = c("x", "y")
)
## -----------------------------------------------------------------------------
stat_chull <- function(mapping = NULL, data = NULL, geom = "polygon",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatChull, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_chull(fill = NA, colour = "black")
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy, colour = drv)) +
geom_point() +
stat_chull(fill = NA)
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy)) +
stat_chull(geom = "point", size = 4, colour = "red") +
geom_point()
## -----------------------------------------------------------------------------
StatLm <- ggproto("StatLm", Stat,
required_aes = c("x", "y"),
compute_group = function(data, scales) {
rng <- range(data$x, na.rm = TRUE)
grid <- data.frame(x = rng)
mod <- lm(y ~ x, data = data)
grid$y <- predict(mod, newdata = grid)
grid
}
)
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_lm()
## -----------------------------------------------------------------------------
StatLm <- ggproto("StatLm", Stat,
required_aes = c("x", "y"),
compute_group = function(data, scales, params, n = 100, formula = y ~ x) {
rng <- range(data$x, na.rm = TRUE)
grid <- data.frame(x = seq(rng[1], rng[2], length = n))
mod <- lm(formula, data = data)
grid$y <- predict(mod, newdata = grid)
grid
}
)
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, n = 50, formula = y ~ x,
...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(n = n, formula = formula, na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_lm(formula = y ~ poly(x, 10)) +
stat_lm(formula = y ~ poly(x, 10), geom = "point", colour = "red", n = 20)
## -----------------------------------------------------------------------------
#' @export
#' @inheritParams ggplot2::stat_identity
#' @param formula The modelling formula passed to \code{lm}. Should only
#' involve \code{y} and \code{x}
#' @param n Number of points used for interpolation.
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, n = 50, formula = y ~ x,
...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(n = n, formula = formula, na.rm = na.rm, ...)
)
}
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensityCommon", Stat,
required_aes = "x",
setup_params = function(data, params) {
if (!is.null(params$bandwidth))
return(params)
xs <- split(data$x, data$group)
bws <- vapply(xs, bw.nrd0, numeric(1))
bw <- mean(bws)
message("Picking bandwidth of ", signif(bw, 3))
params$bandwidth <- bw
params
},
compute_group = function(data, scales, bandwidth = 1) {
d <- density(data$x, bw = bandwidth)
data.frame(x = d$x, y = d$y)
}
)
stat_density_common <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, bandwidth = NULL,
...) {
layer(
stat = StatDensityCommon, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(bandwidth = bandwidth, na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, colour = drv)) +
stat_density_common()
ggplot(mpg, aes(displ, colour = drv)) +
stat_density_common(bandwidth = 0.5)
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensity2", Stat,
required_aes = "x",
default_aes = aes(y = stat(density)),
compute_group = function(data, scales, bandwidth = 1) {
d <- density(data$x, bw = bandwidth)
data.frame(x = d$x, density = d$y)
}
)
ggplot(mpg, aes(displ, drv, colour = stat(density))) +
stat_density_common(bandwidth = 1, geom = "point")
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, fill = drv)) +
stat_density_common(bandwidth = 1, geom = "area", position = "stack")
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensityCommon", Stat,
required_aes = "x",
default_aes = aes(y = stat(density)),
setup_params = function(data, params) {
min <- min(data$x) - 3 * params$bandwidth
max <- max(data$x) + 3 * params$bandwidth
list(
bandwidth = params$bandwidth,
min = min,
max = max,
na.rm = params$na.rm
)
},
compute_group = function(data, scales, min, max, bandwidth = 1) {
d <- density(data$x, bw = bandwidth, from = min, to = max)
data.frame(x = d$x, density = d$y)
}
)
ggplot(mpg, aes(displ, fill = drv)) +
stat_density_common(bandwidth = 1, geom = "area", position = "stack")
ggplot(mpg, aes(displ, drv, fill = stat(density))) +
stat_density_common(bandwidth = 1, geom = "raster")
## ----GeomSimplePoint----------------------------------------------------------
GeomSimplePoint <- ggproto("GeomSimplePoint", Geom,
required_aes = c("x", "y"),
default_aes = aes(shape = 19, colour = "black"),
draw_key = draw_key_point,
draw_panel = function(data, panel_params, coord) {
coords <- coord$transform(data, panel_params)
grid::pointsGrob(
coords$x, coords$y,
pch = coords$shape,
gp = grid::gpar(col = coords$colour)
)
}
)
geom_simple_point <- function(mapping = NULL, data = NULL, stat = "identity",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
geom = GeomSimplePoint, mapping = mapping, data = data, stat = stat,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_simple_point()
## -----------------------------------------------------------------------------
GeomSimplePolygon <- ggproto("GeomPolygon", Geom,
required_aes = c("x", "y"),
default_aes = aes(
colour = NA, fill = "grey20", size = 0.5,
linetype = 1, alpha = 1
),
draw_key = draw_key_polygon,
draw_group = function(data, panel_params, coord) {
n <- nrow(data)
if (n <= 2) return(grid::nullGrob())
coords <- coord$transform(data, panel_params)
# A polygon can only have a single colour, fill, etc, so take from first row
first_row <- coords[1, , drop = FALSE]
grid::polygonGrob(
coords$x, coords$y,
default.units = "native",
gp = grid::gpar(
col = first_row$colour,
fill = scales::alpha(first_row$fill, first_row$alpha),
lwd = first_row$size * .pt,
lty = first_row$linetype
)
)
}
)
geom_simple_polygon <- function(mapping = NULL, data = NULL, stat = "chull",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
geom = GeomSimplePolygon, mapping = mapping, data = data, stat = stat,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
geom_simple_polygon(aes(colour = class), fill = NA)
## -----------------------------------------------------------------------------
GeomPolygonHollow <- ggproto("GeomPolygonHollow", GeomPolygon,
default_aes = aes(colour = "black", fill = NA, size = 0.5, linetype = 1,
alpha = NA)
)
geom_chull <- function(mapping = NULL, data = NULL,
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatChull, geom = GeomPolygonHollow, data = data, mapping = mapping,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
geom_chull()
## -----------------------------------------------------------------------------
StatBoxplot$setup_params
## -----------------------------------------------------------------------------
StatBoxplot$setup_data
## -----------------------------------------------------------------------------
GeomBoxplot$setup_data
## -----------------------------------------------------------------------------
GeomBoxplot$required_aes
## -----------------------------------------------------------------------------
GeomLine$setup_params
## -----------------------------------------------------------------------------
theme_grey()$legend.key
new_theme <- theme_grey() + theme(legend.key = element_rect(colour = "red"))
new_theme$legend.key
## -----------------------------------------------------------------------------
new_theme <- theme_grey() %+replace% theme(legend.key = element_rect(colour = "red"))
new_theme$legend.key
## ----axis-line-ex-------------------------------------------------------------
df <- data.frame(x = 1:3, y = 1:3)
base <- ggplot(df, aes(x, y)) +
geom_point() +
theme_minimal()
base
base + theme(text = element_text(colour = "red"))
## -----------------------------------------------------------------------------
layout <- function(data, params) {
data.frame(PANEL = c(1L, 2L), SCALE_X = 1L, SCALE_Y = 1L)
}
## -----------------------------------------------------------------------------
mapping <- function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
rbind(
cbind(data, PANEL = 1L),
cbind(data, PANEL = 2L)
)
}
## -----------------------------------------------------------------------------
render <- function(panels, layout, x_scales, y_scales, ranges, coord, data,
theme, params) {
# Place panels according to settings
if (params$horizontal) {
# Put panels in matrix and convert to a gtable
panels <- matrix(panels, ncol = 2)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(c(1, 1), "null"), heights = unit(1, "null"), clip = "on")
# Add spacing according to theme
panel_spacing <- if (is.null(theme$panel.spacing.x)) {
theme$panel.spacing
} else {
theme$panel.spacing.x
}
panel_table <- gtable::gtable_add_col_space(panel_table, panel_spacing)
} else {
panels <- matrix(panels, ncol = 1)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(1, "null"), heights = unit(c(1, 1), "null"), clip = "on")
panel_spacing <- if (is.null(theme$panel.spacing.y)) {
theme$panel.spacing
} else {
theme$panel.spacing.y
}
panel_table <- gtable::gtable_add_row_space(panel_table, panel_spacing)
}
# Name panel grobs so they can be found later
panel_table$layout$name <- paste0("panel-", c(1, 2))
# Construct the axes
axes <- render_axes(ranges[1], ranges[1], coord, theme,
transpose = TRUE)
# Add axes around each panel
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_width_l <- unit(grid::convertWidth(
grid::grobWidth(axes$y$left[[1]]), "cm", TRUE), "cm")
axis_width_r <- unit(grid::convertWidth(
grid::grobWidth(axes$y$right[[1]]), "cm", TRUE), "cm")
## We do it reverse so we don't change the position of panels when we add axes
for (i in rev(panel_pos_h)) {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$y$right, length(panel_pos_v)), t = panel_pos_v, l = i + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$y$left, length(panel_pos_v)), t = panel_pos_v, l = i,
clip = "off")
}
## Recalculate as gtable has changed
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_height_t <- unit(grid::convertHeight(
grid::grobHeight(axes$x$top[[1]]), "cm", TRUE), "cm")
axis_height_b <- unit(grid::convertHeight(
grid::grobHeight(axes$x$bottom[[1]]), "cm", TRUE), "cm")
for (i in rev(panel_pos_v)) {
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_b, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$bottom, length(panel_pos_h)), t = i + 1, l = panel_pos_h,
clip = "off")
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_t, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$top, length(panel_pos_h)), t = i, l = panel_pos_h,
clip = "off")
}
panel_table
}
## -----------------------------------------------------------------------------
# Constructor: shrink is required to govern whether scales are trained on
# Stat-transformed data or not.
facet_duplicate <- function(horizontal = TRUE, shrink = TRUE) {
ggproto(NULL, FacetDuplicate,
shrink = shrink,
params = list(
horizontal = horizontal
)
)
}
FacetDuplicate <- ggproto("FacetDuplicate", Facet,
compute_layout = layout,
map_data = mapping,
draw_panels = render
)
## -----------------------------------------------------------------------------
p <- ggplot(mtcars, aes(x = hp, y = mpg)) + geom_point()
p
p + facet_duplicate()
## -----------------------------------------------------------------------------
library(scales)
facet_trans <- function(trans, horizontal = TRUE, shrink = TRUE) {
ggproto(NULL, FacetTrans,
shrink = shrink,
params = list(
trans = scales::as.trans(trans),
horizontal = horizontal
)
)
}
FacetTrans <- ggproto("FacetTrans", Facet,
# Almost as before but we want different y-scales for each panel
compute_layout = function(data, params) {
data.frame(PANEL = c(1L, 2L), SCALE_X = 1L, SCALE_Y = c(1L, 2L))
},
# Same as before
map_data = function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
rbind(
cbind(data, PANEL = 1L),
cbind(data, PANEL = 2L)
)
},
# This is new. We create a new scale with the defined transformation
init_scales = function(layout, x_scale = NULL, y_scale = NULL, params) {
scales <- list()
if (!is.null(x_scale)) {
scales$x <- lapply(seq_len(max(layout$SCALE_X)), function(i) x_scale$clone())
}
if (!is.null(y_scale)) {
y_scale_orig <- y_scale$clone()
y_scale_new <- y_scale$clone()
y_scale_new$trans <- params$trans
# Make sure that oob values are kept
y_scale_new$oob <- function(x, ...) x
scales$y <- list(y_scale_orig, y_scale_new)
}
scales
},
# We must make sure that the second scale is trained on transformed data
train_scales = function(x_scales, y_scales, layout, data, params) {
# Transform data for second panel prior to scale training
if (!is.null(y_scales)) {
data <- lapply(data, function(layer_data) {
match_id <- match(layer_data$PANEL, layout$PANEL)
y_vars <- intersect(y_scales[[1]]$aesthetics, names(layer_data))
trans_scale <- layer_data$PANEL == 2L
for (i in y_vars) {
layer_data[trans_scale, i] <- y_scales[[2]]$transform(layer_data[trans_scale, i])
}
layer_data
})
}
Facet$train_scales(x_scales, y_scales, layout, data, params)
},
# this is where we actually modify the data. It cannot be done in $map_data as that function
# doesn't have access to the scales
finish_data = function(data, layout, x_scales, y_scales, params) {
match_id <- match(data$PANEL, layout$PANEL)
y_vars <- intersect(y_scales[[1]]$aesthetics, names(data))
trans_scale <- data$PANEL == 2L
for (i in y_vars) {
data[trans_scale, i] <- y_scales[[2]]$transform(data[trans_scale, i])
}
data
},
# A few changes from before to accommodate that axes are now not duplicate of each other
# We also add a panel strip to annotate the different panels
draw_panels = function(panels, layout, x_scales, y_scales, ranges, coord,
data, theme, params) {
# Place panels according to settings
if (params$horizontal) {
# Put panels in matrix and convert to a gtable
panels <- matrix(panels, ncol = 2)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(c(1, 1), "null"), heights = unit(1, "null"), clip = "on")
# Add spacing according to theme
panel_spacing <- if (is.null(theme$panel.spacing.x)) {
theme$panel.spacing
} else {
theme$panel.spacing.x
}
panel_table <- gtable::gtable_add_col_space(panel_table, panel_spacing)
} else {
panels <- matrix(panels, ncol = 1)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(1, "null"), heights = unit(c(1, 1), "null"), clip = "on")
panel_spacing <- if (is.null(theme$panel.spacing.y)) {
theme$panel.spacing
} else {
theme$panel.spacing.y
}
panel_table <- gtable::gtable_add_row_space(panel_table, panel_spacing)
}
# Name panel grobs so they can be found later
panel_table$layout$name <- paste0("panel-", c(1, 2))
# Construct the axes
axes <- render_axes(ranges[1], ranges, coord, theme,
transpose = TRUE)
# Add axes around each panel
grobWidths <- function(x) {
unit(vapply(x, function(x) {
grid::convertWidth(
grid::grobWidth(x), "cm", TRUE)
}, numeric(1)), "cm")
}
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_width_l <- grobWidths(axes$y$left)
axis_width_r <- grobWidths(axes$y$right)
## We do it reverse so we don't change the position of panels when we add axes
if (params$horizontal) {
for (i in rev(seq_along(panel_pos_h))) {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r[i], panel_pos_h[i])
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$right[i], t = panel_pos_v, l = panel_pos_h[i] + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l[i], panel_pos_h[i] - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$left[i], t = panel_pos_v, l = panel_pos_h[i],
clip = "off")
}
} else {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r[1], panel_pos_h)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$right, t = panel_pos_v, l = panel_pos_h + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l[1], panel_pos_h - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$left, t = panel_pos_v, l = panel_pos_h,
clip = "off")
}
## Recalculate as gtable has changed
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_height_t <- unit(grid::convertHeight(
grid::grobHeight(axes$x$top[[1]]), "cm", TRUE), "cm")
axis_height_b <- unit(grid::convertHeight(
grid::grobHeight(axes$x$bottom[[1]]), "cm", TRUE), "cm")
for (i in rev(panel_pos_v)) {
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_b, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$bottom, length(panel_pos_h)), t = i + 1, l = panel_pos_h,
clip = "off")
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_t, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$top, length(panel_pos_h)), t = i, l = panel_pos_h,
clip = "off")
}
# Add strips
strips <- render_strips(
x = data.frame(name = c("Original", paste0("Transformed (", params$trans$name, ")"))),
labeller = label_value, theme = theme)
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
strip_height <- unit(grid::convertHeight(
grid::grobHeight(strips$x$top[[1]]), "cm", TRUE), "cm")
for (i in rev(seq_along(panel_pos_v))) {
panel_table <- gtable::gtable_add_rows(panel_table, strip_height, panel_pos_v[i] - 1)
if (params$horizontal) {
panel_table <- gtable::gtable_add_grob(panel_table, strips$x$top,
t = panel_pos_v[i], l = panel_pos_h, clip = "off")
} else {
panel_table <- gtable::gtable_add_grob(panel_table, strips$x$top[i],
t = panel_pos_v[i], l = panel_pos_h, clip = "off")
}
}
panel_table
}
)
## -----------------------------------------------------------------------------
ggplot(mtcars, aes(x = hp, y = mpg)) + geom_point() + facet_trans('sqrt')
## -----------------------------------------------------------------------------
facet_bootstrap <- function(n = 9, prop = 0.2, nrow = NULL, ncol = NULL,
scales = "fixed", shrink = TRUE, strip.position = "top") {
facet <- facet_wrap(~.bootstrap, nrow = nrow, ncol = ncol, scales = scales,
shrink = shrink, strip.position = strip.position)
facet$params$n <- n
facet$params$prop <- prop
ggproto(NULL, FacetBootstrap,
shrink = shrink,
params = facet$params
)
}
FacetBootstrap <- ggproto("FacetBootstrap", FacetWrap,
compute_layout = function(data, params) {
id <- seq_len(params$n)
dims <- wrap_dims(params$n, params$nrow, params$ncol)
layout <- data.frame(PANEL = factor(id))
if (params$as.table) {
layout$ROW <- as.integer((id - 1L) %/% dims[2] + 1L)
} else {
layout$ROW <- as.integer(dims[1] - (id - 1L) %/% dims[2])
}
layout$COL <- as.integer((id - 1L) %% dims[2] + 1L)
layout <- layout[order(layout$PANEL), , drop = FALSE]
rownames(layout) <- NULL
# Add scale identification
layout$SCALE_X <- if (params$free$x) id else 1L
layout$SCALE_Y <- if (params$free$y) id else 1L
cbind(layout, .bootstrap = id)
},
map_data = function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
n_samples <- round(nrow(data) * params$prop)
new_data <- lapply(seq_len(params$n), function(i) {
cbind(data[sample(nrow(data), n_samples), , drop = FALSE], PANEL = i)
})
do.call(rbind, new_data)
}
)
ggplot(diamonds, aes(carat, price)) +
geom_point(alpha = 0.1) +
facet_bootstrap(n = 9, prop = 0.05)
SMAC-Group/simts documentation built on Sept. 4, 2023, 5:25 a.m.
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## ---- include = FALSE---------------------------------------------------------
knitr::opts_chunk$set(collapse = TRUE, comment = "#>", fig.width = 7, fig.height = 7, fig.align = "center")
library(ggplot2)
## ----ggproto-intro------------------------------------------------------------
A <- ggproto("A", NULL,
x = 1,
inc = function(self) {
self$x <- self$x + 1
}
)
A$x
A$inc()
A$x
A$inc()
A$inc()
A$x
## ----chull--------------------------------------------------------------------
StatChull <- ggproto("StatChull", Stat,
compute_group = function(data, scales) {
data[chull(data$x, data$y), , drop = FALSE]
},
required_aes = c("x", "y")
)
## -----------------------------------------------------------------------------
stat_chull <- function(mapping = NULL, data = NULL, geom = "polygon",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatChull, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_chull(fill = NA, colour = "black")
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy, colour = drv)) +
geom_point() +
stat_chull(fill = NA)
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, hwy)) +
stat_chull(geom = "point", size = 4, colour = "red") +
geom_point()
## -----------------------------------------------------------------------------
StatLm <- ggproto("StatLm", Stat,
required_aes = c("x", "y"),
compute_group = function(data, scales) {
rng <- range(data$x, na.rm = TRUE)
grid <- data.frame(x = rng)
mod <- lm(y ~ x, data = data)
grid$y <- predict(mod, newdata = grid)
grid
}
)
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_lm()
## -----------------------------------------------------------------------------
StatLm <- ggproto("StatLm", Stat,
required_aes = c("x", "y"),
compute_group = function(data, scales, params, n = 100, formula = y ~ x) {
rng <- range(data$x, na.rm = TRUE)
grid <- data.frame(x = seq(rng[1], rng[2], length = n))
mod <- lm(formula, data = data)
grid$y <- predict(mod, newdata = grid)
grid
}
)
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, n = 50, formula = y ~ x,
...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(n = n, formula = formula, na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
stat_lm(formula = y ~ poly(x, 10)) +
stat_lm(formula = y ~ poly(x, 10), geom = "point", colour = "red", n = 20)
## -----------------------------------------------------------------------------
#' @export
#' @inheritParams ggplot2::stat_identity
#' @param formula The modelling formula passed to \code{lm}. Should only
#' involve \code{y} and \code{x}
#' @param n Number of points used for interpolation.
stat_lm <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, n = 50, formula = y ~ x,
...) {
layer(
stat = StatLm, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(n = n, formula = formula, na.rm = na.rm, ...)
)
}
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensityCommon", Stat,
required_aes = "x",
setup_params = function(data, params) {
if (!is.null(params$bandwidth))
return(params)
xs <- split(data$x, data$group)
bws <- vapply(xs, bw.nrd0, numeric(1))
bw <- mean(bws)
message("Picking bandwidth of ", signif(bw, 3))
params$bandwidth <- bw
params
},
compute_group = function(data, scales, bandwidth = 1) {
d <- density(data$x, bw = bandwidth)
data.frame(x = d$x, y = d$y)
}
)
stat_density_common <- function(mapping = NULL, data = NULL, geom = "line",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, bandwidth = NULL,
...) {
layer(
stat = StatDensityCommon, data = data, mapping = mapping, geom = geom,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(bandwidth = bandwidth, na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, colour = drv)) +
stat_density_common()
ggplot(mpg, aes(displ, colour = drv)) +
stat_density_common(bandwidth = 0.5)
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensity2", Stat,
required_aes = "x",
default_aes = aes(y = stat(density)),
compute_group = function(data, scales, bandwidth = 1) {
d <- density(data$x, bw = bandwidth)
data.frame(x = d$x, density = d$y)
}
)
ggplot(mpg, aes(displ, drv, colour = stat(density))) +
stat_density_common(bandwidth = 1, geom = "point")
## -----------------------------------------------------------------------------
ggplot(mpg, aes(displ, fill = drv)) +
stat_density_common(bandwidth = 1, geom = "area", position = "stack")
## -----------------------------------------------------------------------------
StatDensityCommon <- ggproto("StatDensityCommon", Stat,
required_aes = "x",
default_aes = aes(y = stat(density)),
setup_params = function(data, params) {
min <- min(data$x) - 3 * params$bandwidth
max <- max(data$x) + 3 * params$bandwidth
list(
bandwidth = params$bandwidth,
min = min,
max = max,
na.rm = params$na.rm
)
},
compute_group = function(data, scales, min, max, bandwidth = 1) {
d <- density(data$x, bw = bandwidth, from = min, to = max)
data.frame(x = d$x, density = d$y)
}
)
ggplot(mpg, aes(displ, fill = drv)) +
stat_density_common(bandwidth = 1, geom = "area", position = "stack")
ggplot(mpg, aes(displ, drv, fill = stat(density))) +
stat_density_common(bandwidth = 1, geom = "raster")
## ----GeomSimplePoint----------------------------------------------------------
GeomSimplePoint <- ggproto("GeomSimplePoint", Geom,
required_aes = c("x", "y"),
default_aes = aes(shape = 19, colour = "black"),
draw_key = draw_key_point,
draw_panel = function(data, panel_params, coord) {
coords <- coord$transform(data, panel_params)
grid::pointsGrob(
coords$x, coords$y,
pch = coords$shape,
gp = grid::gpar(col = coords$colour)
)
}
)
geom_simple_point <- function(mapping = NULL, data = NULL, stat = "identity",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
geom = GeomSimplePoint, mapping = mapping, data = data, stat = stat,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_simple_point()
## -----------------------------------------------------------------------------
GeomSimplePolygon <- ggproto("GeomPolygon", Geom,
required_aes = c("x", "y"),
default_aes = aes(
colour = NA, fill = "grey20", size = 0.5,
linetype = 1, alpha = 1
),
draw_key = draw_key_polygon,
draw_group = function(data, panel_params, coord) {
n <- nrow(data)
if (n <= 2) return(grid::nullGrob())
coords <- coord$transform(data, panel_params)
# A polygon can only have a single colour, fill, etc, so take from first row
first_row <- coords[1, , drop = FALSE]
grid::polygonGrob(
coords$x, coords$y,
default.units = "native",
gp = grid::gpar(
col = first_row$colour,
fill = scales::alpha(first_row$fill, first_row$alpha),
lwd = first_row$size * .pt,
lty = first_row$linetype
)
)
}
)
geom_simple_polygon <- function(mapping = NULL, data = NULL, stat = "chull",
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
geom = GeomSimplePolygon, mapping = mapping, data = data, stat = stat,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
geom_simple_polygon(aes(colour = class), fill = NA)
## -----------------------------------------------------------------------------
GeomPolygonHollow <- ggproto("GeomPolygonHollow", GeomPolygon,
default_aes = aes(colour = "black", fill = NA, size = 0.5, linetype = 1,
alpha = NA)
)
geom_chull <- function(mapping = NULL, data = NULL,
position = "identity", na.rm = FALSE, show.legend = NA,
inherit.aes = TRUE, ...) {
layer(
stat = StatChull, geom = GeomPolygonHollow, data = data, mapping = mapping,
position = position, show.legend = show.legend, inherit.aes = inherit.aes,
params = list(na.rm = na.rm, ...)
)
}
ggplot(mpg, aes(displ, hwy)) +
geom_point() +
geom_chull()
## -----------------------------------------------------------------------------
StatBoxplot$setup_params
## -----------------------------------------------------------------------------
StatBoxplot$setup_data
## -----------------------------------------------------------------------------
GeomBoxplot$setup_data
## -----------------------------------------------------------------------------
GeomBoxplot$required_aes
## -----------------------------------------------------------------------------
GeomLine$setup_params
## -----------------------------------------------------------------------------
theme_grey()$legend.key
new_theme <- theme_grey() + theme(legend.key = element_rect(colour = "red"))
new_theme$legend.key
## -----------------------------------------------------------------------------
new_theme <- theme_grey() %+replace% theme(legend.key = element_rect(colour = "red"))
new_theme$legend.key
## ----axis-line-ex-------------------------------------------------------------
df <- data.frame(x = 1:3, y = 1:3)
base <- ggplot(df, aes(x, y)) +
geom_point() +
theme_minimal()
base
base + theme(text = element_text(colour = "red"))
## -----------------------------------------------------------------------------
layout <- function(data, params) {
data.frame(PANEL = c(1L, 2L), SCALE_X = 1L, SCALE_Y = 1L)
}
## -----------------------------------------------------------------------------
mapping <- function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
rbind(
cbind(data, PANEL = 1L),
cbind(data, PANEL = 2L)
)
}
## -----------------------------------------------------------------------------
render <- function(panels, layout, x_scales, y_scales, ranges, coord, data,
theme, params) {
# Place panels according to settings
if (params$horizontal) {
# Put panels in matrix and convert to a gtable
panels <- matrix(panels, ncol = 2)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(c(1, 1), "null"), heights = unit(1, "null"), clip = "on")
# Add spacing according to theme
panel_spacing <- if (is.null(theme$panel.spacing.x)) {
theme$panel.spacing
} else {
theme$panel.spacing.x
}
panel_table <- gtable::gtable_add_col_space(panel_table, panel_spacing)
} else {
panels <- matrix(panels, ncol = 1)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(1, "null"), heights = unit(c(1, 1), "null"), clip = "on")
panel_spacing <- if (is.null(theme$panel.spacing.y)) {
theme$panel.spacing
} else {
theme$panel.spacing.y
}
panel_table <- gtable::gtable_add_row_space(panel_table, panel_spacing)
}
# Name panel grobs so they can be found later
panel_table$layout$name <- paste0("panel-", c(1, 2))
# Construct the axes
axes <- render_axes(ranges[1], ranges[1], coord, theme,
transpose = TRUE)
# Add axes around each panel
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_width_l <- unit(grid::convertWidth(
grid::grobWidth(axes$y$left[[1]]), "cm", TRUE), "cm")
axis_width_r <- unit(grid::convertWidth(
grid::grobWidth(axes$y$right[[1]]), "cm", TRUE), "cm")
## We do it reverse so we don't change the position of panels when we add axes
for (i in rev(panel_pos_h)) {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$y$right, length(panel_pos_v)), t = panel_pos_v, l = i + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$y$left, length(panel_pos_v)), t = panel_pos_v, l = i,
clip = "off")
}
## Recalculate as gtable has changed
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_height_t <- unit(grid::convertHeight(
grid::grobHeight(axes$x$top[[1]]), "cm", TRUE), "cm")
axis_height_b <- unit(grid::convertHeight(
grid::grobHeight(axes$x$bottom[[1]]), "cm", TRUE), "cm")
for (i in rev(panel_pos_v)) {
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_b, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$bottom, length(panel_pos_h)), t = i + 1, l = panel_pos_h,
clip = "off")
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_t, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$top, length(panel_pos_h)), t = i, l = panel_pos_h,
clip = "off")
}
panel_table
}
## -----------------------------------------------------------------------------
# Constructor: shrink is required to govern whether scales are trained on
# Stat-transformed data or not.
facet_duplicate <- function(horizontal = TRUE, shrink = TRUE) {
ggproto(NULL, FacetDuplicate,
shrink = shrink,
params = list(
horizontal = horizontal
)
)
}
FacetDuplicate <- ggproto("FacetDuplicate", Facet,
compute_layout = layout,
map_data = mapping,
draw_panels = render
)
## -----------------------------------------------------------------------------
p <- ggplot(mtcars, aes(x = hp, y = mpg)) + geom_point()
p
p + facet_duplicate()
## -----------------------------------------------------------------------------
library(scales)
facet_trans <- function(trans, horizontal = TRUE, shrink = TRUE) {
ggproto(NULL, FacetTrans,
shrink = shrink,
params = list(
trans = scales::as.trans(trans),
horizontal = horizontal
)
)
}
FacetTrans <- ggproto("FacetTrans", Facet,
# Almost as before but we want different y-scales for each panel
compute_layout = function(data, params) {
data.frame(PANEL = c(1L, 2L), SCALE_X = 1L, SCALE_Y = c(1L, 2L))
},
# Same as before
map_data = function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
rbind(
cbind(data, PANEL = 1L),
cbind(data, PANEL = 2L)
)
},
# This is new. We create a new scale with the defined transformation
init_scales = function(layout, x_scale = NULL, y_scale = NULL, params) {
scales <- list()
if (!is.null(x_scale)) {
scales$x <- lapply(seq_len(max(layout$SCALE_X)), function(i) x_scale$clone())
}
if (!is.null(y_scale)) {
y_scale_orig <- y_scale$clone()
y_scale_new <- y_scale$clone()
y_scale_new$trans <- params$trans
# Make sure that oob values are kept
y_scale_new$oob <- function(x, ...) x
scales$y <- list(y_scale_orig, y_scale_new)
}
scales
},
# We must make sure that the second scale is trained on transformed data
train_scales = function(x_scales, y_scales, layout, data, params) {
# Transform data for second panel prior to scale training
if (!is.null(y_scales)) {
data <- lapply(data, function(layer_data) {
match_id <- match(layer_data$PANEL, layout$PANEL)
y_vars <- intersect(y_scales[[1]]$aesthetics, names(layer_data))
trans_scale <- layer_data$PANEL == 2L
for (i in y_vars) {
layer_data[trans_scale, i] <- y_scales[[2]]$transform(layer_data[trans_scale, i])
}
layer_data
})
}
Facet$train_scales(x_scales, y_scales, layout, data, params)
},
# this is where we actually modify the data. It cannot be done in $map_data as that function
# doesn't have access to the scales
finish_data = function(data, layout, x_scales, y_scales, params) {
match_id <- match(data$PANEL, layout$PANEL)
y_vars <- intersect(y_scales[[1]]$aesthetics, names(data))
trans_scale <- data$PANEL == 2L
for (i in y_vars) {
data[trans_scale, i] <- y_scales[[2]]$transform(data[trans_scale, i])
}
data
},
# A few changes from before to accommodate that axes are now not duplicate of each other
# We also add a panel strip to annotate the different panels
draw_panels = function(panels, layout, x_scales, y_scales, ranges, coord,
data, theme, params) {
# Place panels according to settings
if (params$horizontal) {
# Put panels in matrix and convert to a gtable
panels <- matrix(panels, ncol = 2)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(c(1, 1), "null"), heights = unit(1, "null"), clip = "on")
# Add spacing according to theme
panel_spacing <- if (is.null(theme$panel.spacing.x)) {
theme$panel.spacing
} else {
theme$panel.spacing.x
}
panel_table <- gtable::gtable_add_col_space(panel_table, panel_spacing)
} else {
panels <- matrix(panels, ncol = 1)
panel_table <- gtable::gtable_matrix("layout", panels,
widths = unit(1, "null"), heights = unit(c(1, 1), "null"), clip = "on")
panel_spacing <- if (is.null(theme$panel.spacing.y)) {
theme$panel.spacing
} else {
theme$panel.spacing.y
}
panel_table <- gtable::gtable_add_row_space(panel_table, panel_spacing)
}
# Name panel grobs so they can be found later
panel_table$layout$name <- paste0("panel-", c(1, 2))
# Construct the axes
axes <- render_axes(ranges[1], ranges, coord, theme,
transpose = TRUE)
# Add axes around each panel
grobWidths <- function(x) {
unit(vapply(x, function(x) {
grid::convertWidth(
grid::grobWidth(x), "cm", TRUE)
}, numeric(1)), "cm")
}
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_width_l <- grobWidths(axes$y$left)
axis_width_r <- grobWidths(axes$y$right)
## We do it reverse so we don't change the position of panels when we add axes
if (params$horizontal) {
for (i in rev(seq_along(panel_pos_h))) {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r[i], panel_pos_h[i])
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$right[i], t = panel_pos_v, l = panel_pos_h[i] + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l[i], panel_pos_h[i] - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$left[i], t = panel_pos_v, l = panel_pos_h[i],
clip = "off")
}
} else {
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_r[1], panel_pos_h)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$right, t = panel_pos_v, l = panel_pos_h + 1,
clip = "off")
panel_table <- gtable::gtable_add_cols(panel_table, axis_width_l[1], panel_pos_h - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
axes$y$left, t = panel_pos_v, l = panel_pos_h,
clip = "off")
}
## Recalculate as gtable has changed
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
axis_height_t <- unit(grid::convertHeight(
grid::grobHeight(axes$x$top[[1]]), "cm", TRUE), "cm")
axis_height_b <- unit(grid::convertHeight(
grid::grobHeight(axes$x$bottom[[1]]), "cm", TRUE), "cm")
for (i in rev(panel_pos_v)) {
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_b, i)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$bottom, length(panel_pos_h)), t = i + 1, l = panel_pos_h,
clip = "off")
panel_table <- gtable::gtable_add_rows(panel_table, axis_height_t, i - 1)
panel_table <- gtable::gtable_add_grob(panel_table,
rep(axes$x$top, length(panel_pos_h)), t = i, l = panel_pos_h,
clip = "off")
}
# Add strips
strips <- render_strips(
x = data.frame(name = c("Original", paste0("Transformed (", params$trans$name, ")"))),
labeller = label_value, theme = theme)
panel_pos_h <- panel_cols(panel_table)$l
panel_pos_v <- panel_rows(panel_table)$t
strip_height <- unit(grid::convertHeight(
grid::grobHeight(strips$x$top[[1]]), "cm", TRUE), "cm")
for (i in rev(seq_along(panel_pos_v))) {
panel_table <- gtable::gtable_add_rows(panel_table, strip_height, panel_pos_v[i] - 1)
if (params$horizontal) {
panel_table <- gtable::gtable_add_grob(panel_table, strips$x$top,
t = panel_pos_v[i], l = panel_pos_h, clip = "off")
} else {
panel_table <- gtable::gtable_add_grob(panel_table, strips$x$top[i],
t = panel_pos_v[i], l = panel_pos_h, clip = "off")
}
}
panel_table
}
)
## -----------------------------------------------------------------------------
ggplot(mtcars, aes(x = hp, y = mpg)) + geom_point() + facet_trans('sqrt')
## -----------------------------------------------------------------------------
facet_bootstrap <- function(n = 9, prop = 0.2, nrow = NULL, ncol = NULL,
scales = "fixed", shrink = TRUE, strip.position = "top") {
facet <- facet_wrap(~.bootstrap, nrow = nrow, ncol = ncol, scales = scales,
shrink = shrink, strip.position = strip.position)
facet$params$n <- n
facet$params$prop <- prop
ggproto(NULL, FacetBootstrap,
shrink = shrink,
params = facet$params
)
}
FacetBootstrap <- ggproto("FacetBootstrap", FacetWrap,
compute_layout = function(data, params) {
id <- seq_len(params$n)
dims <- wrap_dims(params$n, params$nrow, params$ncol)
layout <- data.frame(PANEL = factor(id))
if (params$as.table) {
layout$ROW <- as.integer((id - 1L) %/% dims[2] + 1L)
} else {
layout$ROW <- as.integer(dims[1] - (id - 1L) %/% dims[2])
}
layout$COL <- as.integer((id - 1L) %% dims[2] + 1L)
layout <- layout[order(layout$PANEL), , drop = FALSE]
rownames(layout) <- NULL
# Add scale identification
layout$SCALE_X <- if (params$free$x) id else 1L
layout$SCALE_Y <- if (params$free$y) id else 1L
cbind(layout, .bootstrap = id)
},
map_data = function(data, layout, params) {
if (is.null(data) || nrow(data) == 0) {
return(cbind(data, PANEL = integer(0)))
}
n_samples <- round(nrow(data) * params$prop)
new_data <- lapply(seq_len(params$n), function(i) {
cbind(data[sample(nrow(data), n_samples), , drop = FALSE], PANEL = i)
})
do.call(rbind, new_data)
}
)
ggplot(diamonds, aes(carat, price)) +
geom_point(alpha = 0.1) +
facet_bootstrap(n = 9, prop = 0.05)
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