suppressPackageStartupMessages(library(sf)) # nc = st_read(system.file("gpkg/nc.gpkg", package="sf")) nc = st_read(system.file("shape/nc.shp", package="sf"), quiet = TRUE) nc_checked = st_transform(nc, 32119, check = TRUE) ncm = st_transform(nc, 32119) x = st_transform(nc[1:10,], 32119) st_distance(x) st_is_valid(nc) st_is_empty(st_sfc(st_point(), st_linestring())) ops = c("intersects", #"disjoint", "touches", "crosses", "within", "contains", "overlaps", "equals", "covers", "covered_by", "equals_exact") for (op in ops) { x = sf:::st_geos_binop(op, ncm[1:50,], ncm[51:100,], 0, NA_character_, FALSE) x = sf:::st_geos_binop(op, ncm[1:50,], ncm[51:100,], 0, NA_character_, TRUE) } ops = c("intersects", #"disjoint", "touches", "crosses", "within", "contains", "overlaps", "covers", "covered_by") df = data.frame(ops = ops) df$equal = NA for (op in ops) df[df$ops == op, "equal"] = identical( sf:::st_geos_binop(op, ncm[1:50,], ncm[51:100,], 0, NA_character_, TRUE, FALSE), sf:::st_geos_binop(op, ncm[1:50,], ncm[51:100,], 0, NA_character_, TRUE, TRUE) ) df st_contains_properly(ncm[1:3,], ncm[1:3]) st_combine(nc) st_dimension(st_sfc(st_point(0:1), st_linestring(rbind(c(0,0),c(1,1))), st_polygon(list(rbind(c(0,0), c(1,0), c(1,1), c(0,1), c(0,0)))))) ncbb = st_as_sfc(st_bbox(nc)) g = st_make_grid(ncbb) x = st_intersection(nc, g) x = st_intersection(g, nc) ls = st_sfc(st_linestring(rbind(c(0,0),c(0,1))), st_linestring(rbind(c(0,0),c(10,0)))) suppressWarnings(RNGversion("3.5.3")) set.seed(13531) st_line_sample(ls, density = 1, type = "random") g = st_make_grid(ncbb, n = c(20,10)) a1 = st_interpolate_aw(nc["BIR74"], g, FALSE) sum(a1$BIR74) / sum(nc$BIR74) # not close to one: property is assumed spatially intensive a2 = st_interpolate_aw(nc["BIR74"], g, extensive = TRUE) sum(a2$BIR74) / sum(nc$BIR74) # missing x: g = st_make_grid(offset = c(0,0), cellsize = c(1,1), n = c(10,10)) g = st_make_grid(what = "centers") length(g) g = st_make_grid(what = "corners") length(g) g1 = st_make_grid(ncbb, 0.1, what = "polygons", square = FALSE) g2 = st_make_grid(ncbb, 0.1, what = "points", square = FALSE) # st_line_merge: mls = st_multilinestring(list(rbind(c(0,0), c(1,1)), rbind(c(2,0), c(1,1)))) st_line_merge(mls) if (isTRUE(try(compareVersion(sf_extSoftVersion()["GEOS"], "3.5.0") > -1, silent = TRUE))) { # voronoi: set.seed(1) m = matrix(runif(10),,2) x = st_multipoint(m) box = st_polygon(list(rbind(c(0,0),c(1,0),c(1,1),c(0,1),c(0,0)))) v = st_sfc(st_voronoi(x, st_sfc(box))) plot(v, col = 0, border = 1, axes = TRUE) plot(box, add = TRUE, col = 0, border = 1) # a larger box is returned, as documented plot(x, add = TRUE, col = 'red', cex=2, pch=16) plot(st_intersection(st_cast(v), box)) # clip to smaller box plot(x, add = TRUE, col = 'red', cex=2, pch=16) v0 = st_sfc(st_voronoi(st_sfc(x), st_sfc(box))) pal <- c("black", "red", "green", "blue", "orange") opar = par(mfrow=c(1,2)) plot(st_collection_extract(v0, "POLYGON"), col=pal) text(m[,1], m[,2], label=1:5, col="white") if (isTRUE(try(compareVersion(sf_extSoftVersion()["GEOS"], "3.12.0") > -1, silent = TRUE))) { v2 = st_sfc(st_voronoi(st_sfc(x), st_sfc(box), point_order=TRUE)) plot(st_collection_extract(v2, "POLYGON"), col=pal) text(m[,1], m[,2], label=1:5, col="white") } par(opar) v = st_voronoi(x) print(class(v)) v = st_sfc(st_voronoi(st_sfc(x))) print(class(v)) v = st_voronoi(st_sf(a = 1, geom = st_sfc(x))) print(class(v)) } i = st_intersects(ncm, ncm[1:88,]) all.equal(i, t(t(i))) # check use of pattern in st_relate: sfc = st_as_sfc(st_bbox(st_sfc(st_point(c(0,0)), st_point(c(3,3))))) grd = st_make_grid(sfc, n = c(3,3)) st_intersects(grd) st_relate(grd, pattern = "****1****") st_relate(grd, pattern = "****0****") st_rook = function(a, b = a, ...) st_relate(a, b, pattern = "F***1****", ...) st_rook(grd, sparse = FALSE) #if (Sys.getenv("USER") %in% c("edzer", "travis")) { # memory leaks: try(st_relate(st_point(), st_point(), pattern = "FF*FF****")) # error: use st_disjoint #} a = st_is_within_distance(nc[c(1:3,20),], nc[1:3,], 100000, sparse = FALSE) b = st_is_within_distance(nc[c(1:3,20),], nc[1:3,], units::set_units(100000, m), sparse = FALSE) all.equal(a, b) x = st_is_within_distance(nc[1:3,], nc[1:5,], 100000) y = st_is_within_distance(nc[1:3,], nc[1:5,], units::set_units(100, km)) all.equal(x, y) nc_3857 = st_transform(nc, 3857) a = st_is_within_distance(nc_3857[c(1:3,20),], nc_3857[1:3,], 100000, sparse = FALSE) b = st_is_within_distance(nc_3857[c(1:3,20),], nc_3857[1:3,], units::set_units(100000, m), sparse = FALSE) all.equal(a, b) x = st_is_within_distance(nc_3857, nc_3857, 100000) y = st_is_within_distance(nc_3857, nc_3857, units::set_units(100, km)) all.equal(x, y) pe = st_sfc(st_point()) p = st_sfc(st_point(c(0,0)), st_point(c(0,1)), st_point(c(0,2))) st_distance(p, p) st_distance(p, pe) st_distance(p, p, by_element = TRUE) st_crs(p) = 4326 st_distance(p, p[c(2,3,1)], by_element = TRUE) p = st_transform(p, 3587) st_distance(p, p[c(2,3,1)], by_element = TRUE) # from https://github.com/r-spatial/sf/issues/458 : pts <- st_sfc(st_point(c(.5,.5)), st_point(c(1.5, 1.5)), st_point(c(2.5, 2.5))) pol <- st_polygon(list(rbind(c(0,0), c(2,0), c(2,2), c(0,2), c(0,0)))) pol_df <- data.frame(id = 1) st_geometry(pol_df) <- st_sfc(pol) st_intersects(pts, pol_df[pol_df$id == 2,]) # with empty sf/sfc st_intersects(pts, pol_df[pol_df$id == 2,], sparse = FALSE) # with empty sf/sfc # st_node l = st_linestring(rbind(c(0,0), c(1,1), c(0,1), c(1,0), c(0,0))) st_node(l) st_node(st_sfc(l)) st_node(st_sf(a = 1, st_sfc(l))) # print.sgbp: (lst = st_disjoint(nc, nc)) # dim.sgbp: dim(lst) # as.matrix.sgbp: as.matrix(lst)[1:5, 1:5] # negate: !lst # as.data.frame: head(as.data.frame(lst), 10) # snap: nc1 = st_transform(nc, 32119) g = st_make_grid(nc1, c(5000,5000), what = "centers") s = st_snap(nc1[1:3,], g, 2501*sqrt(2)) sfg = st_snap(st_geometry(nc1)[[1]], g, 2501*sqrt(2)) sfg = st_snap(st_geometry(nc1)[[1]], st_combine(g), 2501*sqrt(2)) # Hausdorff distance: http://geos.refractions.net/ro/doxygen_docs/html/classgeos_1_1algorithm_1_1distance_1_1DiscreteHausdorffDistance.html A = st_as_sfc("LINESTRING (0 0, 100 0, 10 100, 10 100)") B = st_as_sfc("LINESTRING (0 100, 0 10, 80 10)") st_distance(c(A,B)) st_distance(c(A,B), which = "Hausdorff") st_distance(c(A,B), which = "Hausdorff", par = 0.001) LE = st_as_sfc("LINESTRING EMPTY") st_distance(c(A, LE), which = "Hausdorff", par = 0.001) # one-argument st_intersection and st_difference: set.seed(131) m = rbind(c(0,0), c(1,0), c(1,1), c(0,1), c(0,0)) p = st_polygon(list(m)) n = 100 l = vector("list", n) for (i in 1:n) l[[i]] = p + 10 * runif(2) s = st_sfc(l) plot(s, col = sf.colors(categorical = TRUE, alpha = .5)) d = st_difference(s) # sequential differences: s1, s2-s1, s3-s2-s1, ... plot(d, col = sf.colors(categorical = TRUE, alpha = .5)) i = st_intersection(s) # all intersections plot(i, col = sf.colors(categorical = TRUE, alpha = .5)) summary(lengths(st_overlaps(s, s))) summary(lengths(st_overlaps(d, d))) summary(lengths(st_overlaps(i, i))) sf = st_sf(s) i = st_intersection(sf) # all intersections plot(i["n.overlaps"]) summary(i$n.overlaps - lengths(i$origins)) # st_nearest_points: pt1 = st_point(c(.1,.1)) pt2 = st_point(c(.9,.9)) b1 = st_buffer(pt1, 0.1) b2 = st_buffer(pt2, 0.1) plot(b1, xlim = c(0,1), ylim = c(0,1)) plot(b2, add = TRUE) (ls0 = try(st_nearest_points(b1, b2))) # sfg (ls = try(st_nearest_points(st_sfc(b1), st_sfc(b2)))) # sfc (ls = try(st_nearest_points(st_sfc(b1), st_sfc(b2), pairwise = TRUE))) # sfc identical(ls0, ls) # plot(ls, add = TRUE, col = 'red') nc = read_sf(system.file("gpkg/nc.gpkg", package="sf")) plot(st_geometry(nc)) ls = try(st_nearest_points(nc[1,], nc)) # plot(ls, col = 'red', add = TRUE) pts = st_cast(ls, "POINT") # gives all start & end points # starting, "from" points, corresponding to x: plot(pts[seq(1, 200, 2)], add = TRUE, col = 'blue') # ending, "to" points, corresponding to y: plot(pts[seq(2, 200, 2)], add = TRUE, col = 'red') # points to nearest features ls1 = st_linestring(rbind(c(0,0), c(1,0))) ls2 = st_linestring(rbind(c(0,0.1), c(1,0.1))) ls3 = st_linestring(rbind(c(0,1), c(1,1))) (l = st_sfc(ls1, ls2, ls3)) p1 = st_point(c(0.1, -0.1)) p2 = st_point(c(0.1, 0.11)) p3 = st_point(c(0.1, 0.09)) p4 = st_point(c(0.1, 0.9)) p5 = st_point() (p = st_sfc(p1, p2, p3, p4, p5)) #st_nearest_points(p, l) n = try(st_nearest_feature(p,l)) if (!inherits(n, "try-error")) { print(st_nearest_points(p, l[n], pairwise = TRUE)) print(st_nearest_feature(p, l)) print(st_nearest_feature(p, st_sfc())) print(st_nearest_feature(st_sfc(), l)) } # can do centroid of empty geom: st_centroid(st_polygon()) #999: pt = data.frame(x=1:2, y=1:2,a=letters[1:2]) pt = st_as_sf(pt, coords=c("x","y")) bf =st_buffer(pt, dist=0.3) st_within(pt,bf, sparse=FALSE) st_within(pt[1,], bf[1,], sparse = FALSE) st_relate(pt[1,], bf[1,], pattern = "T*F**F***", sparse = FALSE) sf:::is_symmetric(pattern = "010121010") sf:::is_symmetric(pattern = "010121021") st_intersects(st_point(0:1), st_point(2:3)) # sfg method if (isTRUE(try(compareVersion(sf_extSoftVersion()["GEOS"], "3.7.0") > -1, silent = TRUE))) { ls = st_linestring(rbind(c(1,1), c(2,2), c(3,3))) print(st_reverse(ls)) print(st_reverse(st_sfc(ls))) print(st_reverse(st_sf(a = 2, geom = st_sfc(ls)))) } p = st_polygon(list(rbind(c(0,0), c(1,0), c(1,1), c(0,1), c(0,0)))) y = st_sfc(p) x = st_sfc(p + 1.001) x %>% st_set_precision(0) %>% st_intersects(y) x %>% st_set_precision(10000) %>% st_intersects(y) x %>% st_set_precision(1000) %>% st_intersects(y) x %>% st_set_precision(501) %>% st_intersects(y) # no x %>% st_set_precision(500) %>% st_intersects(y) # yes x %>% st_set_precision(100) %>% st_intersects(y) x %>% st_set_precision(10) %>% st_intersects(y) p1 = st_point(0:1) p2 = st_point(2:1) p = st_sf(a = letters[1:8], geom = st_sfc(p1, p1, p2, p1, p1, p2, p2, p1)) st_equals(p) st_equals(p, remove_self = TRUE) (u = st_equals(p, retain_unique = TRUE)) # retain the records with unique geometries: p[-unlist(u),]