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I am writing an application in C++ which relies on various resources in my project. Right now, I have the relative path from the produced executable to each resource hard-coded in my sources, and that allows my program to open the files and read in the data in each resource. This works ok, but it requires that I start the executable from a specific path relative to the resources. So if I try to start my executable from anywhere else, it fails to open the files and cannot proceed.

Is there a portable way to have CMake embed my resources into the executables (or libraries) such that I can simply access them in memory at runtime instead of opening files whose paths are brittle? I have found a related question, and it looks like embedding resources can be done well enough with some ld magic. So my question is how do I do this in a portable, cross platform manner using CMake? I actually need my application run on both x86 and ARM. I am ok with supporting only Linux (Embedded), but bonus points if anyone can suggest how to do this for Windows (Embedded) as well.

EDIT: I forgot to mention a desired property of the solution. I would like to be able to use CMake to cross-compile the application when I am building for ARM rather than have to compile it natively on my ARM target.

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3 Answers 3

up vote 11 down vote accepted

One of the easiest ways to do this is to include a small, portable C program in your build that reads the resource and generates a C file that contains the length of the resource data and the actual resource data as an array of constant character literals. This will be entirely platform independent, but should only be used for resources that are reasonably small. For larger resources, you probably don't want to embed the files in your program.

For resource "foo", the generated C file "foo.c" would contain:

const char foo[] = { /* bytes of resource foo */ };
const size_t foo_len = sizeof(foo);

To access the resource from C++, you declare the following two symbols in either a header or the cpp file where they're used:

extern "C" const char foo[];
extern "C" const size_t foo_len;

To generate foo.c in the build, you need a target for the C program (call it embedfile.c), and you need to use the ADD_CUSTOM_COMMAND command to call this program:

add_executable(embedfile embedfile.c)

  OUTPUT foo.c
  COMMAND embedfile foo foo.rsrc
  DEPENDS foo.rsrc)

Then, include foo.c on the source list of a target that requires the "foo" resource. You now have access to the bytes of "foo".

The program embedfile.c is:

#include <stdlib.h>
#include <stdio.h>

FILE* open_or_exit(const char* fname, const char* mode)
  FILE* f = fopen(fname, mode);
  if (f == NULL) {
  return f;

int main(int argc, char** argv)
  if (argc < 3) {
    fprintf(stderr, "USAGE: %s {sym} {rsrc}\n\n"
        "  Creates {sym}.c from the contents of {rsrc}\n",
    return EXIT_FAILURE;

  const char* sym = argv[1];
  FILE* in = open_or_exit(argv[2], "r");

  char symfile[256];
  snprintf(symfile, sizeof(symfile), "%s.c", sym);

  FILE* out = open_or_exit(symfile,"w");
  fprintf(out, "#include <stdlib.h>\n");
  fprintf(out, "const char %s[] = {\n", sym);

  char buf[256];
  size_t nread = 0;
  size_t linecount = 0;
  do {
    nread = fread(buf, 1, sizeof(buf), in);
    size_t i;
    for (i=0; i < nread; i++) {
      fprintf(out, "0x%02x, ", buf[i]);
      if (++linecount == 10) { fprintf(out, "\n"); linecount = 0; }
  } while (nread > 0);
  if (linecount > 0) fprintf(out, "\n");
  fprintf(out, "};\n");
  fprintf(out, "const size_t %s_len = sizeof(%s);\n\n",sym,sym);


  return EXIT_SUCCESS;
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This looks like a very elegant, platform-independent solution, +1. I will try it out. However, there is one small downfall regarding something I forgot to mention originally (see my edit). If I incorporate this solution into the project and try to cross-compile it, I will run into trouble when trying to execute embedfile since that executable will have been compiled for ARM and I would be trying to execute it on x86. I suppose I can just compile embedfile separately for my host platform and install it to my path. Slightly inconvenient, but I only need to do it once. –  SchighSchagh Aug 5 '12 at 19:47
@SchighSchagh There are probably CMake flags for that, but I don't have a lot of experience with cross-compiling at the moment. embedfile would be easy to rewrite in a language like Python or Perl, if you know that the interpreter is available on the host platforms of interest. –  sfstewman Aug 5 '12 at 19:59
@SchighSchagh: You might want to look at this: cmake.org/Wiki/… –  sfstewman Aug 5 '12 at 20:02
I ended up porting your embedfile.c to Python, and I've been rather happy with the solution so far. :) –  SchighSchagh Sep 4 '12 at 17:15
@SchighSchagh: Glad that it's worked well for you! –  sfstewman Sep 4 '12 at 20:19

I'd say the most elegant way to have embedded resources in C++ is simply to use the Qt Resource System which is portable across different platforms, compatible with CMake, and essentially wraps up everything done in the answer above, besides providing compression, being fully tested and fool-proof, everything else.

Create a Qt resource file - an XML listing the files to be embedded:

    <qresource prefix="/">

Call call the file qtres.qrc. The resource file above will have the two png files (located in the same directory as qtres.qrc) embedded in the final executable. You can easily add/remove monitor resources to a qrc file using QtCreator (the Qt IDE).

Now in your CMakeLists.txt file add:

qt5_add_resources(QT_RESOURCE qtres.qrc)

In your main.cpp, before you need to access the resource, add the following line:


Now you can access any of the resources above using Qt classes compatible with Qt Resource System, such as QPixmap, QImage ... and mosty importantly maybe in general cases the QResource wrapper class which wraps an embedded Qt resource and enables access to it through a friendly interface. As an example, to access data within downtriangle.png in the above resources, the following lines will do the trick:

#include <QtCore>
#include <QtGui>

// ...

int main(int argc, char **argv)

    // ...


    // ...
    QResource res("://downtriangle.png"); // Here's your data, anyway you like
    // OR
    QPixmap pm("://downtriangle.png");  // Use it with Qt classes already

    // ...


Here, res can be used to directly access the data using res.data(), res.size() ... To parse the image content of the file use pm. Use pm.size(), pm.width() ...

And you're good to go. I hope it helped.

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Qt is a pretty heavy dependency for my taste, but +1 anyway for a good answer. –  SchighSchagh Jul 24 at 13:54
I am at the moment developing an embedded application for the ARM/DSP platform which uses exclusively STL + Boost and have managed to use QtResources with it, which essentially wraps up what is done in the first answer under the hood. No dependencies (not at least heavy ones) besides the QResource (if you're using the file as a raw binary resource) and the Qt5Core cmake module (which comes with the framework and is also found standalone with default distro configurations). Take a look at the resource file that is generated by qt5_add_resources(QT_RESOURCE qtres.qrc) command. –  polonium Jul 31 at 17:39

As an alternative to the answer of sfstewman, here's a small cmake (2.8) function to convert all files in a specific folder to C data and write them in wished output file:

# Creates C resources file from files in given directory
function(create_resources dir output)
    # Create empty output file
    file(WRITE ${output} "")
    # Collect input files
    file(GLOB bins ${dir}/*)
    # Iterate through input files
    foreach(bin ${bins})
        # Get short filename
        string(REGEX MATCH "([^/]+)$" filename ${bin})
        # Replace filename spaces & extension separator for C compatibility
        string(REGEX REPLACE "\\.| " "_" filename ${filename})
        # Read hex data from file
        file(READ ${bin} filedata HEX)
        # Convert hex data for C compatibility
        string(REGEX REPLACE "([0-9a-f][0-9a-f])" "0x\\1," filedata ${filedata})
        # Append data to output file
        file(APPEND ${output} "const unsigned char ${filename}[] = {${filedata}};\nconst unsigned ${filename}_size = sizeof(${filename});\n")
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