I'm developing a simple library in Rcpp that builds Huffman trees. It has a working R interface I can call from other packages, but I'd also like to call the C++ functions directly from C++ code in other Rcpp-based packages I'm developing.

I've figured out how to put the header for the first package in the inst/include directory so that it is available in the second package. However, when useDynLib is called in the second package's NAMESPACE file to load it's C++ code that calls a function in the first package, I get an undefined symbol error for the function I am trying to use. I have the first package listed in the second package's DESCRIPTION file under Import, Depends, and LinkingTo.

This is my first foray into doing any non-R based packages, and I'm doing all my development via Rstudio's "Build & Reload" command and used the "Package w/ Rcpp" option when I created the packages to generate the initial directory structure.


3 Answers 3


The general mechanism for doing this in R is to make function pointers available through R_RegisterCCallable and R_GetCCallable. See R-exts for an example.

This implies that the symbols are resolved dynamically as needed -- you don't actually need to 'link' to the other package per-se; you just need the headers so that the symbols can be properly resolved later when the code is executed. Note that the LinkingTo: field is really a misnomer -- it just gives you headers, it does not actually link you to the (library generated for the) package.

Thankfully, this can be automated with the Rcpp::interfaces attribute, which essentially auto-generates the R_RegisterCCallable entrypoints in RcppExports.cpp, and provides wrapper functions using R_GetCCallable in the header file generated.

For example, suppose I have a silly package called RcppInterfaces, containing this in src/test.cpp (with DESCRIPTION having Rcpp in Includes: and LinkingTo:). Note the // [[Rcpp::interfaces(r, cpp)]] comment, which signals to Rcpp that this file should get both R exports, and C++ header exports.

// [[Rcpp::interfaces(r, cpp)]]

#include <Rcpp.h>

// [[Rcpp::export]]
void hello() {
    Rcpp::Rcout << "Hello!\n";

If I call Rcpp::compileAttributes(), you'll see the following 'stuff' written out to RcppExports.cpp:

// This file was generated by Rcpp::compileAttributes
// Generator token: 10BE3573-1514-4C36-9D1C-5A225CD40393

#include <Rcpp.h>
#include <string>
#include <set>

using namespace Rcpp;

// hello
void hello();
static SEXP RcppInterfaces_hello_try() {
    return R_NilValue;
RcppExport SEXP RcppInterfaces_hello() {
    SEXP __result;
        Rcpp::RNGScope __rngScope;
        __result = PROTECT(RcppInterfaces_hello_try());
    Rboolean __isInterrupt = Rf_inherits(__result, "interrupted-error");
    if (__isInterrupt) {
    Rboolean __isError = Rf_inherits(__result, "try-error");
    if (__isError) {
        SEXP __msgSEXP = Rf_asChar(__result);
    return __result;

// validate (ensure exported C++ functions exist before calling them)
static int RcppInterfaces_RcppExport_validate(const char* sig) { 
    static std::set<std::string> signatures;
    if (signatures.empty()) {
    return signatures.find(sig) != signatures.end();

// registerCCallable (register entry points for exported C++ functions)
RcppExport SEXP RcppInterfaces_RcppExport_registerCCallable() { 
    R_RegisterCCallable("RcppInterfaces", "RcppInterfaces_hello", (DL_FUNC)RcppInterfaces_hello_try);
    R_RegisterCCallable("RcppInterfaces", "RcppInterfaces_RcppExport_validate", (DL_FUNC)RcppInterfaces_RcppExport_validate);
    return R_NilValue;

Note that most of the early stuff is boilerplate that ensures an exception-safe version of the function is made callable; at the end you have essentially the mechanism for registering callable functions for other packages.

In inst/include/RcppInterfaces_RcppExports.h, we have:

// This file was generated by Rcpp::compileAttributes
// Generator token: 10BE3573-1514-4C36-9D1C-5A225CD40393

#ifndef __RcppInterfaces_RcppExports_h__
#define __RcppInterfaces_RcppExports_h__

#include <Rcpp.h>

namespace RcppInterfaces {

    using namespace Rcpp;

    namespace {
        void validateSignature(const char* sig) {
            Rcpp::Function require = Rcpp::Environment::base_env()["require"];
            require("RcppInterfaces", Rcpp::Named("quietly") = true);
            typedef int(*Ptr_validate)(const char*);
            static Ptr_validate p_validate = (Ptr_validate)
                R_GetCCallable("RcppInterfaces", "RcppInterfaces_RcppExport_validate");
            if (!p_validate(sig)) {
                throw Rcpp::function_not_exported(
                    "C++ function with signature '" + std::string(sig) + "' not found in RcppInterfaces");

    inline void hello() {
        typedef SEXP(*Ptr_hello)();
        static Ptr_hello p_hello = NULL;
        if (p_hello == NULL) {
            p_hello = (Ptr_hello)R_GetCCallable("RcppInterfaces", "RcppInterfaces_hello");
        RObject __result;
            RNGScope __rngScope;
            __result = p_hello();
        if (__result.inherits("interrupted-error"))
            throw Rcpp::internal::InterruptedException();
        if (__result.inherits("try-error"))
            throw Rcpp::exception(as<std::string>(__result).c_str());
        return Rcpp::as<void >(__result);


#endif // __RcppInterfaces_RcppExports_h__

which is some more exception-safety boilerplate, but with the interesting portion being the R_GetCCallable call that allows other package authors to 'just use' that function, with the R_GetCCallable stuff inlines and managed directly in the function call (with a static pointer that gets populated once when necessary).

So, as far as users of this RcppInterfaces package are concerned, they can just call


in their code, and we just automatically ensure that the function pointer is looked up and used (safely!) at runtime, using R's own mechanisms.


Yes, the linking step is harder but still doable.

Look e.g. at how the RcppXts package imports symbols which the xts package exports. This is all pretty tedious.

I think Kevin has some helpers for the required registration step in his Kmisc package. I have been meaning to read up on those but have not needed them / had time yet.

  • Thanks for the pointers; I'll put together a short example when I sort it all out. Also, thanks for Rcpp. :D
    – bskaggs
    Nov 22, 2014 at 19:11
  • 1
    In this case, Kmisc just automates registration of 'native routines', e.g. here. But I recently found out with Hadley that just writing useDynLib(<pkg>, <functionA>, <functionB>) in the NAMESPACE is effectively equivalent... Nov 22, 2014 at 19:52
  • 1
    Portably? That would be a huge help. Nov 22, 2014 at 20:31
  • 1
    I didn't know about C-level function registration, so I've only done it with useDynLib() in the NAMESPACE. Seems to work cross-platform and be blessed by CRAN
    – hadley
    Nov 24, 2014 at 21:40

Nice description from Kevin about R_RegisterCCallable and R_GetCCallable. Personally, I'd argue in the direction of having all the code that can be either used by your package or other packages in headers. This is IMO less fragile.

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