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Is is possible to compile a C++ (or the like) program without generating the executable file but writting it and executing it directly from memory?

For example with GCC and clang, something that has a similar effect to:

c++ hello.cpp -o hello.x && ./hello.x $@ && rm -f hello.x

in the command line.

But without the burden of writing an executable to disk to immediately load/run it again.

(If possible the procedure may not use disk space.)

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@David Heffernan, alfC never explicitly specified using Linux. He just provided a gcc build process as an example of what he wanted to do. –  Matt Kline Dec 3 '12 at 19:49
3  
If you think this is even worth considering as a useful optimization, you should probably replace your 1970's era disk platters. –  TJD Dec 3 '12 at 19:52
    
@TJD Using a RAM disk to decrease build times is a fairly common idea. See this thread for example. –  Matt Kline Dec 3 '12 at 19:54
1  
@slavik262 The question specifically mentions Linux. Anyway, any answer is going to be heavily OS specific. –  David Heffernan Dec 3 '12 at 19:55
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I know you are probably interested in methods that will work with current tools, but historically the answer is absolutely yes. The method is called "compile and go." It is discussed in older compiler textoobks and has been around since at least the 60's. The idea was to eliminate file system delays, and it worked well. E.g. from mid-80's to mid-90's there were several versions of Turbo Pascal that did this. They were blazingly fast: 10's of thousands of lines per second on the 80486 processors of the day, when file-based compilation schemes were doing thousands or hundreds. –  Gene Dec 24 '12 at 1:17

4 Answers 4

Yes, though doing it properly requires designing significant parts of the compiler with this in mind. The LLVM guys have done this, first with a kinda-separate JIT, and later with the MC subproject. I don't think there's a ready-made tool doing it. But in principle, it's just a matter of linking to clang and llvm, passing the source to clang, and passing the IR it creates to MCJIT. Maybe a demo does this (I vaguely recall a basic C interpreter that worked like this, though I think it was based on the legacy JIT).

Edit: Found the demo I recalled. Also, there's cling, which seems to do basically what I described, but better.

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Although not a solution and I wasn't looking for an interpreter, this is the kind of answer I was expecting. +1 –  alfC Dec 3 '12 at 21:53
    
+1 for link to cling. –  Lei Mou Dec 6 '12 at 7:58
    
@alfC - You can do exactly what you want with LLVM JIT. Create an llvm::Module from LLVM IR code (get it by compiling your C/C++ code into LLVM IR via clang linked into your executable). Create an llvm::ExecutionEngine from that Module, and then call yourEngine->FindFunctionNamed(someFunction), and then yourEngine->runFunction(pSomeFunction) via JIT. It can even give you a return value. As long as you don't blow away your ExecutionEngine, the JITed code can be called again & again, faster on subsequent calls because it's JITed on the 1st call. –  phonetagger Dec 20 '12 at 16:30

Possible? Not the way you seem to wish. The task has two parts:

1) How to get the binary into memory

When we specify /dev/stdout as output file in Linux we can then pipe into our program x0 that reads an executable from stdin and executes it:

  gcc -pipe YourFiles1.cpp YourFile2.cpp -o/dev/stdout -Wall | ./x0

In x0 we can just read from stdin until reaching the end of the file:

int main(int argc, const char ** argv)
{
    const int stdin = 0;
    size_t ntotal = 0;
    char * buf = 0;
    while(true)
    {
        /* increasing buffer size dynamically since we do not know how many bytes to read */
        buf = (char*)realloc(buf, ntotal+4096*sizeof(char));
        int nread = read(stdin, buf+ntotal, 4096); 
        if (nread<0) break;
        ntotal += nread;
    }
    memexec(buf, ntotal, argv); 
}

It would also be possible for x0 directly execute the compiler and read the output. This question has been answered here: Redirecting exec output to a buffer or file

Caveat: I just figured out that for some strange reason this does not work when I use pipe | but works when I use the x0 < foo.

Note: If you are willing to modify your compiler or you do JIT like LLVM, clang and other frameworks you could directly generate executable code. However for the rest of this discussion I assume you want to use an existing compiler.

Note: Execution via temporary file

Other programs such as UPX achieve a similar behavior by executing a temporary file, this is easier and more portable than the approach outlined below. On systems where /tmp is mapped to a RAM disk for example typical servers, the temporary file will be memory based anyway.

int memexec(void * exe, size_t exe_size, const char * argv)
{
    /* random temporary file name in /tmp */
    char name[15] = "/tmp/fooXXXXXX"; 
    /* creates temporary file, returns writeable file descriptor */
    int fd_wr = mkostemp(name,  O_WRONLY);
    /* makes file executable and readonly */
    chmod(name, S_IRUSR | S_IXUSR);
    /* creates read-only file descriptor before deleting the file */
    int fd_ro = open(name, O_RDONLY);
    /* removes file from file system, kernel buffers content in memory until all fd closed */
    unlink(name);
    /* writes executable to file */
    write(fd_wr, exe, exe_size);
    /* fexecve will not work as long as there in a open writeable file descriptor */
    close(fd_wr);
    char *const newenviron[] = { NULL };
    /* -fpermissive */
    fexecve(fd_ro, argv, newenviron);
    perror("failed");
}

Caveat: Error handling is left out for clarities sake. Includes for sake of brevity.

Note: By combining step main() and memexec() into a single function and using splice(2) for copying directly between stdin and fd_wr the program could be significantly optimized.

2) Execution directly from memory

One does not simply load and execute an ELF binary from memory. Some preparation, mostly related to dynamic linking, has to happen. There is a lot of material explaining the various steps of the ELF linking process and studying it makes me believe that theoretically possible. See for example this closely related question on SO however there seems not to exist a working solution.

Update UserModeExec seems to come very close.

Writing a working implementation would be very time consuming, and surely raise some interesting questions in its own right. I like to believe this is by design: for most applications it is strongly undesirable to (accidentially) execute its input data because it allows code injection.

What happens exactly when an ELF is executed? Normally the kernel receives a file name and then creates a process, loads and maps the different sections of the executable into memory, performs a lot of sanity checks and marks it as executable before passing control and a file name back to the run-time linker ld-linux.so (part of libc). The takes care of relocating functions, handling additional libraries, setting up global objects and jumping to the executables entry point. AIU this heavy lifting is done by dl_main() (implemented in libc/elf/rtld.c).

Even fexecve is implemented using a file in /proc and it is this need for a file name that leads us to reimplement parts of this linking process.

Libraries

Reading

Related Questions at SO

So it seems possible, you decide whether is also practical.

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ok, so I issued the first command and get the executable output (binary codes) to the screen. That looks promising, where do I pipe this to? Do I have to pipe it a special executable made from your C code? Where are pipe, fork, exec used? How the piped binary code is related to `"fooXXXXX"? –  alfC Dec 18 '12 at 8:27
    
You are right, maybe I made somewhat of a jump. The piped binary code will be written using the file descriptor fd which will have a random name starting with foo. Hope I can provide an example later. In any case my starting point would be this: users.encs.concordia.ca/~mia/tutorials/coen346/IPC_threads/… –  Lothar_K Dec 18 '12 at 10:28
    
@alfC I hope this update provides the neccessary details. –  Lothar_K Dec 21 '12 at 9:53
    
Awesome answer, first I wonder why something like your program is not one of the programs included in the operating system, that is a program that takes a binary stream and executes it. Second there it seems to be a problem with the main part of the code as the ./x0 hangs while reading a stream. I had to change to if (nread != 0) break; in order to finish reading the stream. And with this change I get a message failed: Exec format error. I am trying implementation 2) so far. –  alfC Dec 22 '12 at 3:40
    
@alfC I assume it is loading the file. Unfortunately I am away from my computer. Try using a fixed size read on char buf[SOME_BIG_NUMBER] –  Lothar_K Dec 22 '12 at 9:19

Linux can create virtual file systems in RAM using tempfs. For example, I have my tmp directory set up in my file system table like so:

tmpfs       /tmp    tmpfs   nodev,nosuid    0   0

Using this, any files I put in /tmp are stored in my RAM.

Windows doesn't seem to have any "official" way of doing this, but has many third-party options.

Without this "RAM disk" concept, you would likely have to heavily modify a compiler and linker to operate completely in memory.

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Hear hear. I believe this is sometimes known as a "RAM disk". –  Ross Rogers Dec 3 '12 at 19:46
    
Actually, the modifications needed on Windows would be fairly small. Just pass FILE_ATTRIBUTE_TEMPORARY when creating the output file. This suppresses the flush to disk, keeping the file in cache. The documentation explicitly states that this may avoid a write if the file is deleted soon after, as is intended here. –  MSalters Dec 21 '12 at 16:37

If you are not specifically tied to C++, you may also consider other JIT based solutions:

  • in Common Lisp SBCL is able to generate machine code on the fly
  • you could use TinyCC and its libtcc.a which emits quickly poor (i.e. unoptimized) machine code from C code in memory.
  • consider also any JITing library, e.g. libjit, GNU Lightning, LLVM, asmjit
  • of course emitting C++ code on some tmpfs and compiling it...

But if you want good machine code, you'll need it to be optimized, and that is not fast (so the time to write to a filesystem is negligible).

If you are tied to C++ generated code, you need a good C++ optimizing compiler (e.g. g++ or clang++); they take significant time to compile C++ code to optimized binary, so you should generate to some file foo.cc (perhaps in a RAM file system like some tmpfs, but that would give a minor gain, since most of the time is spent inside g++ or clang++ optimization passes, not reading from disk), then compile that foo.cc to foo.so (using perhaps make, or at least forking g++ -Wall -shared -O2 foo.cc -o foo.so, perhaps with additional libraries). At last have your main program dlopen that generated foo.so. FWIW, MELT is doing exactly that.

Alternatively, generate a self-contained source program foobar.cc, compile it to an executable foobarbin e.g. with g++ -O2 foobar.cc -o foobarbin and execute with execve that foobarbin executable binary

When generating C++ code, you may want to avoid generating tiny C++ source files (e.g. a dozen lines only; if possible, generate C++ files of a few hundred lines at least). For instance, try if possible to put several generated C++ functions in the same generated C++ file (but avoid having very big generated C++ functions, e.g. 10KLOC in a single function; they take a lot of time to be compiled by GCC). You could consider, if relevant, to have only one single #include in that generated C++ file, and pre-compile that commonly included header.

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