h3lib
is an R pacakge. But it’s also not an R package.
There aren’t any R functions you can call, nor can you import this package as-is into your own.
h3lib
exposes Uber’s H3 source files (written in
C) through Callable routines.
It’s these routines that you can then use in your own package.
Firstly, take a look at /src/init.c
. You’ll see a whole load of
R_RegisterCCallable()
calls:
// Indexing
R_RegisterCCallable("h3lib", "latLngToCell", (DL_FUNC) &latLngToCell);
R_RegisterCCallable("h3lib", "cellToLatLng", (DL_FUNC) &cellToLatLng);
R_RegisterCCallable("h3lib", "cellToBoundary", (DL_FUNC) &cellToBoundary);
These are essentially saying
Here are some C functions I’d like you to register and make available to other packages
Now look in /inst/include/h3libapi.h
. Here you’ll see all the function
definitions for these registered routines
// Indexing
inline H3Error latLngToCell(const LatLng *g, int res, H3Index *out) {
H3Error(*fun)(const LatLng*, int, H3Index*) =
(H3Error(*)(const LatLng*, int, H3Index*)) R_GetCCallable("h3lib","latLngToCell");
return fun(g, res, out);
}
The registered routines in init.c
and the definitions in h3libapi.h
should match. If there’s something missing, please let us know!
Yes, I’m getting to that.
To demonstrate how to actually call these routines, let’s use the h3r package as an example.
Here are the steps to call the latLngToCell
routine defined in h3lib
In the DESCRIPTION
file you need to link to {h3lib}
Depends:
h3lib
LinkingTo:
h3lib
If you look in the /src/
directory you’ll see various .c
files.
The init.c
also contains some R_RegisterCCallable()
(because it too
is exposing some of its C code to the wider R ecosystem).
But it also defines which Routines it wants to import
H3Error (*latLngToCell);
H3Error (*cellToLatLng);
H3Error (*cellToBoundary);
... etc
Then in a .c file, you need to include the h3libapi.h
file, and that’s
it!
(I’ve highlighted the bit of code that calls the latLngToCell
routine)
#include "h3libapi.h"
SEXP h3rLatLngToCell(SEXP lat, SEXP lon, SEXP res) {
R_xlen_t n = Rf_xlength(lat);
R_xlen_t i;
SEXP cells = PROTECT(Rf_allocVector(STRSXP, n));
LatLng latLng;
H3Index h3Index;
// char str[17];
for( i = 0; i < n; i++ ) {
int ires = INTEGER(res)[i];
sexpToLatLng(&latLng, lat, lon, i);
h3error(latLngToCell(&latLng, ires, &h3Index), i); // <-- LOOK HERE; this is calling h3lib latLngToCell
// h3ToString(h3Index, str, 17);
SET_STRING_ELT(cells, i, h3ToSexpString(h3Index));
}
UNPROTECT(1);
return cells;
}
Let’s build our own example that uses cellToLatLng
to build {sf}
polygons.
For this we can link to both {h3lib}
and {sfheaders}
library(Rcpp)
cppFunction(
depends = c(
"h3lib"
, "geometries" ## <- required because sfheaders depends on it
, "sfheaders" ## <- for building sf objects through C++ code
)
, includes = c(
'#include "h3libapi.h"'
, '#include "sfheaders/sfg/polygon/sfg_polygon.hpp"'
)
, code = '
SEXP cellToPolygon(SEXP h3) {
R_xlen_t n = Rf_xlength(h3);
R_xlen_t i, j;
Rcpp::List poylgons(n); // for storing the sfg_polygons
for(i = 0; i < n; ++i) {
H3Index idx;
CellBoundary cb;
// convert the SEXP cell (stringVector) to H3Index
int e1 = stringToH3(CHAR(STRING_ELT(h3, i)), &idx);
// TODO: handle the error-code `e1`
// Convert H3Index to CellBoundary object
int e2 = cellToBoundary(idx, &cb);
// TODO: handle the rror-code `e2`;
// Convert the CellBoundary to sfg_polygon
// where sfheaders::sfg_polygon accepts a matrix or data-frame
Rcpp::NumericMatrix latLng(cb.numVerts, 2);
for(j = 0; j < cb.numVerts; ++j) {
latLng(j, 0) = radsToDegs(cb.verts[i].lng);
latLng(j, 1) = radsToDegs(cb.verts[j].lat);
}
poylgons[i] = sfheaders::sfg::sfg_polygon(latLng, "XY");
}
return poylgons;
}
'
)
cellToPolygon(c("8cbe63562a54bff","8cbe635631103ff"))
# [[1]]
# [[1]]
# [,1] [,2]
# [1,] 144.9833 -37.82030
# [2,] 144.9833 -37.82019
# [3,] 144.9833 -37.82012
# [4,] 144.9833 -37.82016
# [5,] 144.9833 -37.82026
# [6,] 144.9833 -37.82033
# [7,] 144.9833 -37.82030
#
# attr(,"class")
# [1] "XY" "POLYGON" "sfg"
#
# [[2]]
# [[1]]
# [,1] [,2]
# [1,] 144.9675 -37.81851
# [2,] 144.9675 -37.81840
# [3,] 144.9675 -37.81833
# [4,] 144.9675 -37.81837
# [5,] 144.9675 -37.81847
# [6,] 144.9675 -37.81854
# [7,] 144.9675 -37.81851
#
# attr(,"class")
# [1] "XY" "POLYGON" "sfg"