Ops {sf} | R Documentation |
Arithmetic operators for simple feature geometries
Description
Arithmetic operators for simple feature geometries
Usage
## S3 method for class 'sfg'
Ops(e1, e2)
## S3 method for class 'sfc'
Ops(e1, e2)
Arguments
e1 |
object of class |
e2 |
numeric, or object of class |
Details
in case e2
is numeric, +, -, *, /, %% and %/% add, subtract, multiply, divide, modulo, or integer-divide by e2
. In case e2
is an n x n matrix, * matrix-multiplies and / multiplies by its inverse. If e2
is an sfg
object, |, /, & and %/% result in the geometric union, difference, intersection and symmetric difference respectively, and ==
and !=
return geometric (in)equality, using st_equals. If e2
is an sfg
or sfc
object, for operations +
and -
it has to have POINT
geometries.
If e1
is of class sfc
, and e2
is a length 2 numeric, then it is considered a two-dimensional point (and if needed repeated as such) only for operations +
and -
, in other cases the individual numbers are repeated; see commented examples.
It has been reported (https://github.com/r-spatial/sf/issues/2067) that certain ATLAS versions result in invalid polygons, where the final point in a ring is no longer equal to the first point. In that case, setting the precisions with st_set_precision may help.
Value
object of class sfg
Examples
st_point(c(1,2,3)) + 4
st_point(c(1,2,3)) * 3 + 4
m = matrix(0, 2, 2)
diag(m) = c(1, 3)
# affine:
st_point(c(1,2)) * m + c(2,5)
# world in 0-360 range:
if (require(maps, quietly = TRUE)) {
w = st_as_sf(map('world', plot = FALSE, fill = TRUE))
w2 = (st_geometry(w) + c(360,90)) %% c(360) - c(0,90)
w3 = st_wrap_dateline(st_set_crs(w2 - c(180,0), 4326)) + c(180,0)
plot(st_set_crs(w3, 4326), axes = TRUE)
}
(mp <- st_point(c(1,2)) + st_point(c(3,4))) # MULTIPOINT (1 2, 3 4)
mp - st_point(c(3,4)) # POINT (1 2)
opar = par(mfrow = c(2,2), mar = c(0, 0, 1, 0))
a = st_buffer(st_point(c(0,0)), 2)
b = a + c(2, 0)
p = function(m) { plot(c(a,b)); plot(eval(parse(text=m)), col=grey(.9), add = TRUE); title(m) }
o = lapply(c('a | b', 'a / b', 'a & b', 'a %/% b'), p)
par(opar)
sfc = st_sfc(st_point(0:1), st_point(2:3))
sfc + c(2,3) # added to EACH geometry
sfc * c(2,3) # first geometry multiplied by 2, second by 3
nc = st_transform(st_read(system.file("gpkg/nc.gpkg", package="sf")), 32119) # nc state plane, m
b = st_buffer(st_centroid(st_union(nc)), units::set_units(50, km)) # shoot a hole in nc:
plot(st_geometry(nc) / b, col = grey(.9))