Difference between revisions of "Getting started with GCC"

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  cat libfib.s
  cat libfib.s
Follow the [https://www.ic.unicamp.br/~ranido/mc404/arm/arm-instructionset.pdf ARM mnemonics list on page 3] and try to understand what goes on inside the processor with execution of each instruction.
If most of this make sense so far, try to do some [https://wiki.itcollege.ee/index.php/Category:I600_Introduction_to_Computers_and_Informatics#Assignment:_Investigating_compilers exercises]. ARM mnemonics and all relevant links are there.

Latest revision as of 15:00, 13 October 2016


GCC (GNU Compiler Collection) is a suite of tools aimed at compiling various programming languages for different CPU architectures. There are many competitive alternatives such as LLVM. Following instructions can be carried out at enos.itcollege.ee via SSH, the software is already installed there so you don't have to run apt-get install lines. On your personal Ubuntu machine you can install GCC via APT:

sudo apt-get install build-essential

In order to compile binaries for foreign architecure you need cross-compiler. In Ubuntu repositories you may find ARM cross compilers:

sudo apt-get install g++-arm-linux-gnueabihf g++-arm-linux-gnueabi

The point of this article is to get familiar with tools provided by GCC toolchain. GCC, especially as a cross-compiler is widely used to compile firmware for Raspberry Pi, Arduino, Ubuntu, routers and other embedded devices. You can also manually compile a compiler for foreign architectures which isn't supported out of the box for your distribution, see here for more information


It's also possible to run foreign binaries if you install QEMU emulation layer and binary detection support:

sudo apt-get install qemu-user-static binfmt-support

Sample source files

Create a plain-text file libfib.c with following content:

int fib(n) {
    if (n == 1 || n== 2) {
        return 1;
    } else {
        return fib(n-1) + fib(n-2);

Create another plain-text file hello.c to invoke the function described above:

#include <stdio.h>

int main(int argc, char **argv) {
    if (argc != 2) {
        printf("Please specify only one argument\n");
        return -1;
    } else {
        int n;
        sscanf(argv[1], "%d", &n);
        printf("%dth fibonacci number is %d\n", n, fib(n));
        return 0;

Compiling native binaries

Verify that the code works:

gcc libfib.c hello.c -o hello-simple

Invocation of the binary should result in output 42th fibonacci number is 267914296:

./hello-simple 42

Use file to inspect what kind of executable was created:

file hello-simple

Compiling assembly

Generate assembly for the C file which contains fib function:

gcc libfib.c -S -o libfib.s

Investigate the assembly corresponding to fib:

cat libfib.s

Dynamic vs static linking

The hello-simple compiled above is dynamically linked library, you can list dependant libraries width ldd:

ldd hello-simple

Compile the static version:

gcc -static libfib.c hello.c -o hello-simple-static

Attempting to run ldd against such binary will result in error not a dynamic executable. List the files and their sizes, what is the difference and why?

ls -lah hello-simple hello-simple-static


Use the compiler to compile assembly from the C source code:

gcc -fPIC libfib.c -S -o libfib-native.s
gcc hello.c -S -o hello-native.s

Turn assembly into object files:

gcc -fPIC -c libfib-native.s -o libfib-native.o
gcc -c hello-native.s -o hello-native.o

Finally link the object file against system libraries to produce usable binary:

mkdir mylibs
gcc -fPIC libfib-native.o -shared -o mylibs/libfib-native.so
gcc hello-native.o -o hello-native -L mylibs -l fib-native

Invoke the binary to test if it actually works, expect the program to print line Hello, World!:

LD_LIBRARY_PATH=mylibs ./hello-native 42

The binary was compiled dynamically which means that during it's invocation OS is requested to load dependent libraries to the memory is necessary. You can use ldd to investigate which libraries are required to invoke the binaries:

LD_LIBRARY_PATH=mylibs ldd hello-native

Alternatively you can compile the binary statically, in that case all the necessary machinery get's bundled into the resulting binary:

gcc libfib-native.o hello-native.o -static -o hello-native-static

Deassembling a binary

Use objdump to locate the section corresponding to function fib.

objdump -D mylibs/libfib-native.so


Use ARM cross-compiler to compile ARM binaries on x86:

arm-linux-gnueabihf-gcc libfib.c hello.c -static -o hello-foreign

Use file, ldd and objdump to inspect the binary. Assuming binfmt-support has been set up properly and QEMU emulation layer is available a static ARM binary can be invoked on x86 host via emulation:


For dynamically linked binaries you need also dependant libraries, the simplest way is to bootstrap a LXC container for ARM.


Makefiles are used to simplify building a software project. Ant is a corresponding tool for Java projects. Maven complements Ant with automatic JAR downloading capabilities. Python does dependency tracking already internally, pip also installs dependant libraries if necessary.

Create file Makefile:

CC=$(CROSSCOMPILE)gcc      # Make cross-compilation easy
CFLAGS=-fPIC               # Create position independent code, so it would be possible to generate .so libraries

hello: libfib.o hello.o
	$(CC) -static -o $@ $?

	$(CC) -shared -o $@ $?

	$(CC) -c -o $@ $?

%.s: %.c
	$(CC) -S -o $@ $?

	rm -Rfv *.s *.o *.so

Invoke the command in the directory that contains the Makefile:


To clean binaries:

make clean

To cross-compile:

CROSSCOMPILE=arm-linux-gnueabihf- make hello

Generate ARM assembly for the function of calculating Fibonacci numbers:

CROSSCOMPILE=arm-linux-gnueabihf- make libfib.s

Store it for later:

cat libfib.s

If most of this make sense so far, try to do some exercises. ARM mnemonics and all relevant links are there.