I am new to Julia and and I am trying to access my C++ code from Julia. More precisely, I am trying to call a C++ function from Julia using Cxx. The input and output parameters of the C++ function are std::vectors, see the function compute_sum in the example below:

#include <vector>
#include <iostream>

std::vector< int > compute_sum( const std::vector< std::vector<int> >& input )
    std::vector< int > resut( input.size() , 0 );
    for ( std::size_t i = 0 ; i != input.size() ; ++i )
        for ( std::size_t j = 0 ; j != input[i].size() ; ++j )
            resut[i] += input[i][j];
    return resut;

void simple_function( int i )
    std::cout << "The numbers is : " << i << std::endl;

Assuming this function is stored as code.cpp I am compiling it to a shared object code.so using:

 g++ -shared -fPIC code.cpp -o code.so

and as a result I obtain a file code.so

Having this, I run Julia in the same folder as code.so. My version of Julia is 0.6.2. Then I import Cxx and the code.so file using:

julia> using Cxx
julia> const path_to_lib = pwd()
julia> addHeaderDir(path_to_lib, kind=C_System)
julia> Libdl.dlopen(path_to_lib * "/code.so", Libdl.RTLD_GLOBAL)
Ptr{Void} @0x00000000044bda30
julia> cxxinclude("code.cpp")

In odder to test if the process is successful I am calling the simple_function and obtain the correct results:

julia> @cxx simple_function(1234)
The numbers is : 1234

Then I want to call compute_sum function. For that I need somehow to create, or convert Julia vector into C++ std::vector< std::vector >. I am trying the following:

julia> cxx" std::vector< std::vector<int> > a;"
julia> icxx" a.push_back( std::vector<int>(1,2) ); "
julia> icxx" a.push_back( std::vector<int>(1,3) ); "
julia> icxx" a.push_back( std::vector<int>(1,4) ); "
julia> icxx" a.size(); "

So I assume that the vector is created in a correct way. Then I trying to call the function with it, but I fail:

julia> @cxx compute_sum(a)
ERROR: UndefVarError: a not defined
julia> @cxx compute_sum("a")
ERROR: Got bad type information while compiling Cxx.CppNNS{Tuple{:compute_sum}} (got String for argument 1)
julia> icxx " compute_sum(a);"
ERROR: syntax: extra token """ after end of expression

Could anyone help me please with the following question(s):

  1. How to call compute_sum function from Julia? I am happy to use any technique (not necessary Cxx) that works and is reasonably fast.
  2. How to convert the result of compute_sum to Julia array?

Thank you very much!


  • "I am compiling it to a static library using: g++ -shared -fPIC code.cpp -o code.so" - there's some confusion here. You say you build a static library, but the -shared compiler option says otherwise. Also, static libraries are usually named with a ".a" extension while ".so" is for shared libraries ("so" being short for "shared object"). So, what do you actually mean to do? Feb 18, 2018 at 13:35
  • Thank you for pointing it out, I did mean shared object. Changed the line to: "I am compiling it to a shared object code.so using". Hope it is more clear now.
    – user47459
    Feb 18, 2018 at 15:40
  • For what purpose will you be using this for? Is it like the row sums of a matrix, or are the vectors inside input allowed to have different sizes? Plus, you seem to have a small glitch in your code --- the inner loop is also incrementing i. Is this intended? Feb 21, 2018 at 10:04

3 Answers 3


The trick is to use the icxx string macro, this allows interpolating Julia variables using $. Here is a full example:

using Cxx

#include <iostream>
#include <vector>

std::vector<int> compute_sum(const std::vector<std::vector<int>> &input)
  std::vector<int> result(input.size(), 0);
  for (std::size_t i = 0; i != input.size(); ++i)
    for (std::size_t j = 0; j != input[i].size(); ++j) // corrected to ++j here
      result[i] += input[i][j];
  return result;

cxx_v = icxx"std::vector<std::vector<int>>{{1,2},{1,2,3}};"
println("Input vectors:")
for v in cxx_v
  println("  ", collect(v))

cxx_sum = icxx"compute_sum($cxx_v);"
println("Cxx sums: $(collect(cxx_sum))")

Running this in Julia should print:

Input vectors:
  Int32[1, 2]
  Int32[1, 2, 3]
Cxx sums: Int32[3, 6]

To do this using a shared library, create vector.hpp like this:

#include <vector>
std::vector<int> compute_sum(const std::vector<std::vector<int>> &input);


#include "vector.hpp"

std::vector<int> compute_sum(const std::vector<std::vector<int>> &input)
     // same as before


g++ -shared -fPIC -o libvector.so vector.cpp

In Julia:

using Cxx

const path_to_lib = pwd()
addHeaderDir(path_to_lib, kind=C_System)
Libdl.dlopen(joinpath(path_to_lib, "libvector"), Libdl.RTLD_GLOBAL)

cxx_v = icxx"std::vector<std::vector<int>>{{1,2},{1,2,3}};"
println("Input vectors:")
for v in cxx_v
  println("  ", collect(v))

cxx_sum = icxx"compute_sum($cxx_v);"
println("Cxx sums: $(collect(cxx_sum))")
  • Thank you for your help. I have one more question. This solution work when a function compute_sum is given in Julia. However, when I am trying to call a function from a precompiled shared object, I am getting an segmentation fault: julia> icxx"compute_sum($cxx_v);" signal (11): Segmentation fault while loading no file, in expression starting on line 0 unknown function (ip: 0x7f4fa27de7d9) unknown function (ip: 0x7f4fa27de6db) unknown function (ip: 0x7f4fa27de6bc) Do you happen to know if this can be fixed?
    – user47459
    Feb 23, 2018 at 6:10
  • I have updated the answer, you need a separate header and also make sure the second ++i is changed to ++j, that gives a segfault too. Feb 23, 2018 at 8:33
  • Thank you very much. That is exactly what i need. Now I have two working solutions. Appreciate it!
    – user47459
    Feb 23, 2018 at 21:14

Because you are willing to work on Julia arrays, I assume that you would like to work on matrices, i.e., arrays having constant lengths in the dimensions. For this reason, I would suggest you do not use vectors of vectors, but instead use just vectors. Then, you should remember that Julia uses column-major arrays, whereas in C/C++, the memory layout is row-major.

Below, you can find a templated version of your code using iterators. This way, you can compile compute_sum for use in C++ with your favourite std::vectors. Or else, you can ask your compiler to generate the appropriate code with pointers, to be able to use with other languages, such as Julia.

#include <cstdint>
#include <iterator>
#include <vector>

template <class RandomIt, class OutputIt>
OutputIt compute_sum(const std::uint64_t nrows, RandomIt xbegin, RandomIt xend,
                     OutputIt rbegin) {
  const std::size_t ncols{std::distance(xbegin, xend) / nrows};
  typename std::iterator_traits<OutputIt>::value_type sum{0};
  for (std::size_t row = 0; row < nrows; row++) {
    for (std::size_t col = 0; col < ncols; col++)
      sum += xbegin[col * nrows + row];

    *rbegin++ = sum;
    sum = 0;
  return rbegin;

/* you can use the above code in your C++ applications as follows */
// int main() {
//   std::vector<int> matrix{1, 2, 3, 4, 5,
//                           6, 7, 8, 9}; /* 3x3 matrix in column-major */
//   std::vector<int> result(3);
//   compute_sum(3, std::begin(matrix), std::end(matrix), std::begin(result));
//   return 0;
// }

/* or, ask your compiler to generate code with C linkage (no name mangling) */
extern "C" {
void compute_sum(const std::uint64_t m /* use fixed-size integers */,
                 const std::uint64_t n /* use fixed-size integers */,
                 const std::int64_t *xbegin /* use fixed-size integers */,
                 std::int64_t *rbegin /* use fixed-size integers */) {
  compute_sum(m, xbegin, xbegin + m * n, rbegin);

then, compile the code as usual:

g++ -Wall -std=c++11 -O3 -fPIC -shared code.cpp -o code.so

Then, use Julia's capabilities to call the compiled C code:

const libhandle = Libdl.dlopen(joinpath(pwd(), "code.so"))
const funhandle = Libdl.dlsym(libhandle, :compute_sum)

function compute_sum(A::Matrix{Int64})
    result = Vector{Int64}(size(A, 1))
    ccall(funhandle, Void, (UInt64, UInt64, Ref{Int64}, Ref{Int64}),
          size(A, 1), size(A, 2), A, result)
    return result

result = compute_sum(ones(Int64, 5, 6)) # prints Int64[6, 6, 6, 6, 6]

I hope this helps. Cheers!

  • Thank you so much! That certainly help and make my example work.
    – user47459
    Feb 23, 2018 at 6:08

I would like to thank Arda Aytekin and Bart Janssens for their great help and suggestions. Both solutions works perfectly and I would like to mark them both as an answer to my question, but it seems I can only mark one answer...
In the next days I will run speed comparison test to see if one the solution which is based on pure C interface is faster or not to the one using Cxx. I will update you once this is ready.

  • Solutions are not comparable to each other. My solution uses fixed dimension lengths and uses contiguous iterators, whereas Bart's solution uses arrays of arrays (one extra pointer resolution for each row). In fragmented memories, contiguous arrays might be faster, in general. The other one is more flexible in the sense that it does not assume fixed lengths in dimensions. So it is dependent on your use case. Feb 23, 2018 at 21:53

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