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I routinely work on several different computers and several different operating systems, which are Mac OS X, Linux, or Solaris. For the project I'm working on, I pull my code from a remote git repository.

I like to be able to work on my projects regardless of which terminal I'm at. So far, I've found ways to get around the OS changes by changing the makefile every time I switch computers. However, this is tedious and causes a bunch of headaches.

How can I modify my makefile so that it detects which OS I'm using and modifies syntax accordingly?

Here is the makefile:

 cc = gcc -g
CC = g++ -g

all: assembler

assembler: lex.yy.o
        $(CC) -o assembler lex.yy.o -ll -l y

assembler.o: assembler.c
        $(cc) -o assembler.o assembler.c assem.y
        $(yacc) -d assem.y
        $(CC) -c

lex.yy.o: assem.l
        $(lex) assem.l
        $(cc) -c lex.yy.c

        rm -f lex.yy.c assembler *.o *.tmp *.debug *.acts
share|improve this question

11 Answers 11

up vote 120 down vote accepted

There are many good answers here already, but I wanted to share a more complete example that both a) doesn't assume uname exists on Windows and b) also detects the processor. The CCFLAGS defined here aren't necessarily recommended or ideal; they're just what the project to which I was adding OS/CPU auto-detection happened to be using.

ifeq ($(OS),Windows_NT)
    CCFLAGS += -D WIN32
        CCFLAGS += -D AMD64
        CCFLAGS += -D IA32
    UNAME_S := $(shell uname -s)
    ifeq ($(UNAME_S),Linux)
        CCFLAGS += -D LINUX
    ifeq ($(UNAME_S),Darwin)
        CCFLAGS += -D OSX
    UNAME_P := $(shell uname -p)
    ifeq ($(UNAME_P),x86_64)
        CCFLAGS += -D AMD64
    ifneq ($(filter %86,$(UNAME_P)),)
        CCFLAGS += -D IA32
    ifneq ($(filter arm%,$(UNAME_P)),)
        CCFLAGS += -D ARM
share|improve this answer
Sadly the PROCESSOR_ARCHITECTURE envvar seems to be virtualized depending on whether the process is 32-bit or 64-bit. So if your make is 32-bit and you're trying to build a 64-bit application, it will fail. Using it in combination with PROCESSOR_ARCHITEW6432 worked for me (see this, and that) – Thomas Nov 29 '13 at 12:59
Would be nice if the make team add a couple of magic variables with os and arch, probably too much trouble. – Alex Aug 25 '14 at 15:00
this breaks on FreeBSD, as $OS is not set. $OSTYPE can be freebsd10.1 though. – Janus Troelsen Oct 2 at 11:56
@JanusTroelsen: it shouldn't matter whether OS is set on non-Windows systems. Make treats unset the same as empty, which will cause a jump to the uname-based block. You just need to add a FreeBSD check there. – Trevor Robinson Oct 2 at 16:53

The uname command ( with no parameters should tell you the operating system name. I'd use that, then make conditionals based on the return value.


UNAME := $(shell uname)

ifeq ($(UNAME), Linux)
# do something Linux-y
ifeq ($(UNAME), Solaris)
# do something Solaris-y
share|improve this answer
The UNAME := $(shell uname) command fails when I try it. – samoz Apr 3 '09 at 15:08
Just to be explicit, that line goes in your Makefile. I just tried that construct in Makefiles in Cygwin and OSX, and it worked as expected. Something to try: Type uname on your command line. That'll tell you the value for that OS. OSX will likely be "Darwin". – dbrown0708 Apr 3 '09 at 18:10
The GnuWin32 project has both uname and Gnu make available as native Windows applications, making this technique portable to MingW at a command prompt as well as Cygwin on Windows. – RBerteig Apr 4 '09 at 1:52
Note that if you put this inside a Maketarget it must not be indented. – nylund Feb 5 '12 at 15:28
Isn't the ":=" syntax specific to GNU Make? – Ankur Sethi Apr 15 '12 at 15:06

The git makefile contains numerous examples of how to manage without autoconf/automake, yet still work on a multitude of unixy platforms.

share|improve this answer
Knowing that Git doesn't use the Autofools somehow makes me feel justified in my aversion to them ... – Dan Moulding Jun 12 '12 at 13:23
"Autofools"? Was that a deliberate typo? :) – JesperE Jun 12 '12 at 13:40
It was. But on second thought, I think I like "Autostools" even better. :D – Dan Moulding Jun 12 '12 at 15:02
Btw, who did you mean by "them"? The Git or Autotools people? :D – JesperE Jun 12 '12 at 15:11
English is such an imprecise language. How about this: if (!usesAutotools(git)) aversionTo(autotools) = justified; I'll clarify also that it's only the tools I'm averse to. I'm sure the Autotools people are nice folks. – Dan Moulding Jun 12 '12 at 15:50

I was recently experimenting in order to answer to this question I was asking myself. Here are my conclusions :

Since in Windows, you can't be sure that the uname command is available, you can use gcc -dumpmachine. This will display the compiler target.

There may be also a problem when using uname if you want to do some cross-compilation.

Here's a example list of possible output of gcc -dumpmachine :

  • mingw32
  • i686-pc-cygwin
  • x86_64-redhat-linux

You can check the result in the makefile like this :

SYS := $(shell gcc -dumpmachine)
ifneq (, $(findstring linux, $(SYS)))
 # Do linux things
else ifneq(, $(findstring mingw, $(SYS)))
 # Do mingw things
else ifneq(, $(findstring cygwin, $(SYS)))
 # Do cygwin things
 # Do things for others

It worked well for me, but I'm not sure it's a reliable way of getting the system type. At least it's reliable about MinGW and that's all I need since it does not require to have the uname command or MSYS package in Windows.

To sum up, uname gives you the system on which you're compiling, gcc -dumpmachine gives you the system for which you are compiling.

Hope it helped someone.

share|improve this answer
This is a good point. However, doesn't uname come with MinGW anyway? Nevertheless, the extra note regarding cross-compilation is great. – Shahbaz Sep 11 '12 at 14:48
@Shahbaz MinGW setup can install MSYS (which contains uname) but it's optionnal. It's still possible to find systems with only MinGW gcc tools – phsym Sep 11 '12 at 16:05
This doesn't work if you use $(CC), and CC=clang or cl – Sebastian Godelet Mar 1 '14 at 19:57

If your makefile may be running on non-cygwin Windows, uname may not be available. That's awkward, but this is a potential solution. You have to check for Cygwin first to rule it out, because it has WINDOWS in it's PATH too.

ifneq (,$(findstring /cygdrive/,$(PATH)))
    UNAME := Cygwin
ifneq (,$(findstring WINDOWS,$(PATH)))
    UNAME := Windows
    UNAME := $(shell uname -s)
share|improve this answer
This is good to now! Can you tell me one thing, though? I don't use Cygwin, but I have MinGW installed with it's bin path in PATH. If I issue uname from a normal cmd terminal it gives me MINGW. What I mean is, I still have uname without using Cygwin. I also have git bash, but I haven't tried uname on it (right now I'm in Linux). Can you tell me how these two can be incorporated in your code? – Shahbaz May 16 '12 at 11:56
If you are sure that uname is available, that's the best solution. But in my environment, everyone is using Windows and few people have either cygwin or mingw installed, so I have no guarantee that anything even as standard as uname will work. I'm currently having some difficulty with the above code running make.exe in a cmd shell. Windows is a very frustrating platform to work with. – Ken Jackson May 17 '12 at 21:34
What I mean is, before testing for existence of WINDOWS in PATH, you make sure you are not dealing with cygwin, how can you make sure you are not dealing with MinGW? For example, is it possible in Makefile to test whether a command can be run, and if uname couldn't be run we would understand we are in Windows? – Shahbaz May 17 '12 at 22:49
I'm struggling to find a clean solution to this Mingw/cygwin/shell-or-cmd/Linux as well. At the end of the day, something like premake or cmake seems like the best idea. – Isaac Remuant Apr 22 '13 at 17:45

Determine any modern Operating System using environment variable OS and command uname -s.

ifeq ($(OS),Windows_NT)
    OS_detected := Windows
    OS_detected := $(shell uname -s)

Please see also this detailed answer about importance of uname -s (it lists many uname -s outputs depending on the Operating System).

The use of OS (instead of uname -s) simplifies the identification algorithm. You can still use solely uname -s but you have to deal with if/else blocks to check all MinGW/Cygwin/... variations.

Note: The environment variable OS is always set to "Windows_NT" on any Windows platform (see Windows Environment Variables on Wikipedia). An alternative of OS is the environment variable MSVC (it checks the presence of MS Visual Studio, see example using MSVC).

Below I provide a complete example using make and gcc to build a shared library: *.so or *.dll depending on the platform. The example is as simplest as possible to be more understandable :-)

To use make and gcc on MS-Windows, you can install Cygwin or MinGW.

My example is based on 5 files

 ├── lib
 │   └── Makefile
 │   └── hello.h
 │   └── hello.c
 └── app
     └── Makefile
     └── main.c

Do not forget: files Makefile are indented using tabulations.

The two files Makefile


ifeq ($(OS),Windows_NT)
    uname_S := Windows
    uname_S := $(shell uname -s)

ifeq ($(uname_S), Windows)
    target = hello.dll
ifeq ($(uname_S), Linux)
    target =
#ifeq ($(uname_S), .....) #See
#    target = .....

%.o: %.c
    gcc  -c $<  -fPIC  -o $@    
    # -c $<  => $< is first file after ':' => Compile hello.c
    # -fPIC  => Position-Independent Code (required for shared lib)
    # -o $@  => $@ is the target => Output file (-o) is hello.o

$(target): hello.o
    gcc  $^  -shared  -o $@
    # $^      => $^ expand to all prerequisites (after ':') => hello.o
    # -shared => Generate shared library
    # -o $@   => Output file (-o) is $@ ( or hello.dll)


%.o: %.c
    gcc  -c $< -I ../lib  -o $@
    # -c $<     => compile (-c) $< (first file after :) = main.c
    # -I ../lib => search headers (*.h) in directory ../lib
    # -o $@     => output file (-o) is $@ (target) = main.o

app.exe: main.o
    gcc  $^  -L../lib  -lhello  -o $@
    # $^       => $^ (all files after the :) = main.o (here only one file)
    # -L../lib => look for libraries in directory ../lib
    # -lhello  => use shared library hello ( or hello.dll)
    # -o $@    => output file (-o) is $@ (target) = app.exe

To learn more, read Automatic Variables documentation as pointed out by cfi.

The source code


#ifndef HELLO_H_
#define HELLO_H_

const char* hello();



#include "hello.h"

const char* hello()
    return "hello";


#include "hello.h" //hello()
#include <stdio.h> //puts()

int main()
    const char* str = hello();

The build

Fix the copy-paste of Makefiles (replace leading spaces by tabulation).

> sed  's/^  */\t/'  -i  */Makefile

The make command is the same on both platforms. The given output is on GNU/Linux:

> make -C lib
make: Entering directory '/tmp/lib'
gcc  -c hello.c  -fPIC  -o hello.o    
# -c hello.c  => hello.c is first file after ':' => Compile hello.c
# -fPIC  => Position-Independent Code (required for shared lib)
# -o hello.o  => hello.o is the target => Output file (-o) is hello.o
gcc  hello.o  -shared  -o
# hello.o      => hello.o is the first after ':' => Link hello.o
# -shared => Generate shared library
# -o   => Output file (-o) is ( or hello.dll)
make: Leaving directory '/tmp/lib'

> make -C app
make: Entering directory '/tmp/app'
gcc  -c main.c -I ../lib  -o main.o
# -c main.c     => compile (-c) main.c (first file after :) = main.cpp
# -I ../lib => search headers (*.h) in directory ../lib
# -o main.o     => output file (-o) is main.o (target) = main.o
gcc  main.o  -L../lib  -lhello  -o app.exe
# main.o       => main.o (all files after the :) = main.o (here only one file)
# -L../lib => look for libraries in directory ../lib
# -lhello  => use shared library hello ( or hello.dll)
# -o app.exe    => output file (-o) is app.exe (target) = app.exe
make: Leaving directory '/tmp/app'

The run

The application requires to know where is the shared library.

On MS-Windows, a simple solution is to copy the library where the application is:

> cp -v lib/hello.dll app
`lib/hello.dll' -> `app/hello.dll'

On Linux, use the LD_LIBRARY_PATH environment variable:

> export LD_LIBRARY_PATH=lib

The run command line and output are the same on both platforms:

> app/app.exe
share|improve this answer
I appreciate your effort, but the main question was to detect the operating system. Your example only detects Linux and otherwise outright assumes Windows. – Shahbaz Feb 9 '13 at 16:58
Hi @Shahbaz. You are right, my answer does not give a different approach than the other answers. Moreover, my script assumes the platform is Windows when uname is not Linux. I give just an example you may not need, but this may help someone searching (on the web) a way to implement a Makefile for both platforms ;-) What should I change in my answer? Cheers – olibre Feb 11 '13 at 8:59
try to come up with ways to correctly identify other operating systems too! The goal is to find a method that is not too complicated, but more importantly is bullet proof. That is, it wouldn't make mistake no matter what. – Shahbaz Feb 11 '13 at 9:52
Hi @Shahbaz. When I will find a more safe way to detect the platform, I will update this answer... for the moment I do not have enough time to investigate. Have a fine week end, Cheers ;-) – olibre Feb 22 '13 at 16:04
Hi @Shahbaz. After more than two years, I finally reworked my answer. Hope the proposed operating system identification is enough bullet proof. What do you think? Cheers – olibre Oct 8 at 9:54

That's the job that GNU's automake/autoconf are designed to solve. You might want to investigate them.

Alternatively you can set environment variables on your different platforms and make you Makefile conditional against them.

share|improve this answer
I strongly advise against using automake/autoconf. They are tedious to use, add a lot of overhead to your files, to your build time. They simply add complexity for usually very little effect (still no portability between systems). – Johannes Overmann Nov 4 '13 at 15:48
I just spent a couple of days learning to get make to do what I want. Do I now want to get into automake/autoconf as well? - NO. What can be done in the makefile, certainly should be done in the makefile, if only so that I don't have several stop-off points every time I want to amend compile & link. – Arcane Engineer Jul 4 at 18:32
How many platforms do your makefiles support? automake and autoconf really come into their own when you want portability to many platforms. – Douglas Leeder Jul 6 at 18:43

I ran into this problem today and I needed it on Solaris so here is a POSIX standard way to do (something very close to) this.

#Detect OS
UNAME = `uname`

# Build based on OS name
    -@make $(UNAME)

# OS is Linux, use GCC
Linux: program.c
    rm -f program
    gcc $(SHELL_VARIABLE) -o program program.c

# OS is Solaris, use c99
SunOS: program.c
    rm -f program
    c99 $(SHELL_VARIABLE) -o program program.c
share|improve this answer
Getting error on OSX: "Makefile:22: *** missing separator. Stop.". On this line: "-@make $(UNAME_S)". – Czarek Tomczak Feb 13 '14 at 11:55
OSX likely isn't compliant so try these in order. (1) Make sure you are using a TAB as the first character on the line (2) Remove the "-@" in front of the make (2a) If 2 worked, try one character and then the other (3) Ensure that UNAME_S is defined, try echo $(UNAME_S) instead of -@make $(UNAME_S) – Huckle Feb 16 '14 at 3:41

Note that Makefiles are extremely sensitive to spacing. Here's an example of a Makefile that runs an extra command on OSX and which works on OSX and Linux. Overall, though, autoconf/automake is the way to go for anything at all non-trivial.

UNAME := $(shell uname -s)
CPP = g++
CPPFLAGS = -pthread -ansi -Wall -Werror -pedantic -O0 -g3 -I /nexopia/include
LDFLAGS = -pthread -L/nexopia/lib -lboost_system

HEADERS = data_structures.h http_client.h load.h lock.h search.h server.h thread.h utility.h
OBJECTS = http_client.o load.o lock.o search.o server.o thread.o utility.o vor.o

all: vor

    rm -f $(OBJECTS) vor

vor: $(OBJECTS)
    $(CPP) $(LDFLAGS) -o vor $(OBJECTS)
ifeq ($(UNAME),Darwin)
    # Set the boost library location
    install_name_tool -change libboost_system.dylib /nexopia/lib/libboost_system.dylib vor

%.o: %.cpp $(HEADERS) Makefile
    $(CPP) $(CPPFLAGS) -c $
share|improve this answer

Another way to do this is by using a "configure" script. If you are already using one with your makefile, you can use a combination of uname and sed to get things to work out. First, in your script, do:


Then, in order to put this in your Makefile, start out with which should have something like


in it.

Use the following sed command in your configure script after the UNAME=uname bit.

sed -e "s|@@UNAME@@|$UNAME|" < > Makefile

Now your makefile should have UNAME defined as desired. If/elif/else statements are all that's left!

share|improve this answer

Here's a simple solution that checks if you are in a Windows or posix-like environment:

ifeq ($(shell echo "check_quotes"),"check_quotes")
   WINDOWS := yes
   WINDOWS := no

It takes advantage of the fact that echo exists on both posix-like and Windows environments, and that in Windows the shell does not filter the quotes.

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