This vignette summarises the various formats that grid drawing functions take. Most of this information is available scattered throughout the R documentation. This appendix brings it all together in one place.
Almost every geom has either colour, fill, or both. Colours and fills can be specified in the following ways:
A name, e.g., "red"
. R has 657
built-in named colours, which can be listed with
colours()
.
An rgb specification, with a string of the form
"#RRGGBB"
where each of the pairs RR
,
GG
, BB
consists of two hexadecimal digits
giving a value in the range 00
to FF
You can optionally make the colour transparent by using the form
"#RRGGBBAA"
.
An NA, for a completely transparent colour.
The munsell package, by Charlotte Wickham, makes it easy to choose specific colours using a system designed by Albert H. Munsell. If you invest a little in learning the system, it provides a convenient way of specifying aesthetically pleasing colours.
As well as colour
, the appearance of a line is affected
by linewidth
, linetype
, linejoin
and lineend
.
Line types can be specified with:
An integer or name: 0 = blank, 1 = solid, 2 = dashed, 3 = dotted, 4 = dotdash, 5 = longdash, 6 = twodash, as shown below:
lty <- c("solid", "dashed", "dotted", "dotdash", "longdash", "twodash")
linetypes <- data.frame(
y = seq_along(lty),
lty = lty
)
ggplot(linetypes, aes(0, y)) +
geom_segment(aes(xend = 5, yend = y, linetype = lty)) +
scale_linetype_identity() +
geom_text(aes(label = lty), hjust = 0, nudge_y = 0.2) +
scale_x_continuous(NULL, breaks = NULL) +
scale_y_reverse(NULL, breaks = NULL)
The lengths of on/off stretches of line. This is done with a
string containing 2, 4, 6, or 8 hexadecimal digits which give the
lengths of consecutive lengths. For example, the string
"33"
specifies three units on followed by three off and
"3313"
specifies three units on followed by three off
followed by one on and finally three off.
lty <- c("11", "18", "1f", "81", "88", "8f", "f1", "f8", "ff")
linetypes <- data.frame(
y = seq_along(lty),
lty = lty
)
ggplot(linetypes, aes(0, y)) +
geom_segment(aes(xend = 5, yend = y, linetype = lty)) +
scale_linetype_identity() +
geom_text(aes(label = lty), hjust = 0, nudge_y = 0.2) +
scale_x_continuous(NULL, breaks = NULL) +
scale_y_reverse(NULL, breaks = NULL)
The five standard dash-dot line types described above correspond to 44, 13, 1343, 73, and 2262.
Due to a historical error, the unit of linewidth is roughly 0.75 mm. Making it exactly 1 mm would change a very large number of existing plots, so we’re stuck with this mistake.
The appearance of the line end is controlled by the
lineend
paramter, and can be one of “round”, “butt” (the
default), or “square”.
df <- data.frame(x = 1:3, y = c(4, 1, 9))
base <- ggplot(df, aes(x, y)) + xlim(0.5, 3.5) + ylim(0, 10)
base +
geom_path(linewidth = 10) +
geom_path(linewidth = 1, colour = "red")
base +
geom_path(linewidth = 10, lineend = "round") +
geom_path(linewidth = 1, colour = "red")
base +
geom_path(linewidth = 10, lineend = "square") +
geom_path(linewidth = 1, colour = "red")
The appearance of line joins is controlled by
linejoin
and can be one of “round” (the default), “mitre”,
or “bevel”.
df <- data.frame(x = 1:3, y = c(9, 1, 9))
base <- ggplot(df, aes(x, y)) + ylim(0, 10)
base +
geom_path(linewidth = 10) +
geom_path(linewidth = 1, colour = "red")
base +
geom_path(linewidth = 10, linejoin = "mitre") +
geom_path(linewidth = 1, colour = "red")
base +
geom_path(linewidth = 10, linejoin = "bevel") +
geom_path(linewidth = 1, colour = "red")
Mitre joins are automatically converted to bevel joins whenever the
angle is too small (which would create a very long bevel). This is
controlled by the linemitre
parameter which specifies the
maximum ratio between the line width and the length of the mitre.
The border of the polygon is controlled by the colour
,
linetype
, and linewidth
aesthetics as
described above. The inside is controlled by fill
.
Shapes take five types of values:
An integer in [0, 25]:
shapes <- data.frame(
shape = c(0:19, 22, 21, 24, 23, 20),
x = 0:24 %/% 5,
y = -(0:24 %% 5)
)
ggplot(shapes, aes(x, y)) +
geom_point(aes(shape = shape), size = 5, fill = "red") +
geom_text(aes(label = shape), hjust = 0, nudge_x = 0.15) +
scale_shape_identity() +
expand_limits(x = 4.1) +
theme_void()
The name of the shape:
shape_names <- c(
"circle", paste("circle", c("open", "filled", "cross", "plus", "small")), "bullet",
"square", paste("square", c("open", "filled", "cross", "plus", "triangle")),
"diamond", paste("diamond", c("open", "filled", "plus")),
"triangle", paste("triangle", c("open", "filled", "square")),
paste("triangle down", c("open", "filled")),
"plus", "cross", "asterisk"
)
shapes <- data.frame(
shape_names = shape_names,
x = c(1:7, 1:6, 1:3, 5, 1:3, 6, 2:3, 1:3),
y = -rep(1:6, c(7, 6, 4, 4, 2, 3))
)
ggplot(shapes, aes(x, y)) +
geom_point(aes(shape = shape_names), fill = "red", size = 5) +
geom_text(aes(label = shape_names), nudge_y = -0.3, size = 3.5) +
scale_shape_identity() +
theme_void()
A single character, to use that character as a plotting symbol.
A .
to draw the smallest rectangle that is visible,
usually 1 pixel.
An NA
, to draw nothing.
While colour
applies to all shapes, fill
only applies to shapes 21-25, as can be seen above. The size of the
filled part is controlled by size
, the size of the stroke
is controlled by stroke
. Each is measured in mm, and the
total size of the point is the sum of the two. Note that the size is
constant along the diagonal in the following figure.
sizes <- expand.grid(size = (0:3) * 2, stroke = (0:3) * 2)
ggplot(sizes, aes(size, stroke, size = size, stroke = stroke)) +
geom_abline(slope = -1, intercept = 6, colour = "white", linewidth = 6) +
geom_point(shape = 21, fill = "red") +
scale_size_identity()
Because points are not typically filled, you may need to change some
default settings when using these shapes and mapping fill
.
In particular, discrete fill
guides will be drawn with an
unfilled shape unless overridden (refer to geom_point()
for
an example of this).
There are only three fonts that are guaranteed to work everywhere: “sans” (the default), “serif”, or “mono”:
df <- data.frame(x = 1, y = 3:1, family = c("sans", "serif", "mono"))
ggplot(df, aes(x, y)) +
geom_text(aes(label = family, family = family))
It’s trickier to include a system font on a plot because text drawing
is done differently by each graphics device (GD). There are five GDs in
common use (png()
, pdf()
, on screen devices
for Windows, Mac and Linux), so to have a font work everywhere you need
to configure five devices in five different ways. Two packages simplify
the quandary a bit:
showtext
makes GD-independent plots by rendering all
text as polygons.
extrafont
converts fonts to a standard format that
all devices can use.
Both approaches have pros and cons, so you will to need to try both of them and see which works best for your needs.
The size
of text is measured in mm by default. This is
unusual, but makes the size of text consistent with the size of lines
and points. Typically you specify font size using points (or pt for
short), where 1 pt = 0.35mm. In geom_text()
and
geom_label()
, you can set size.unit = "pt"
to
use points instead of millimeters. In addition, ggplot2 provides a
conversion factor as the variable .pt
, so if you want to
draw 12pt text, you can also set size = 12 / .pt
.
Horizontal and vertical justification have the same parameterisation, either a string (“top”, “middle”, “bottom”, “left”, “center”, “right”) or a number between 0 and 1:
just <- expand.grid(hjust = c(0, 0.5, 1), vjust = c(0, 0.5, 1))
just$label <- paste0(just$hjust, ", ", just$vjust)
ggplot(just, aes(hjust, vjust)) +
geom_point(colour = "grey70", size = 5) +
geom_text(aes(label = label, hjust = hjust, vjust = vjust))
Note that you can use numbers outside the range (0, 1), but it’s not recommended.