OS detecting makefile
Solution 1:
There are many good answers here already, but I wanted to share a more complete example that both:
- doesn't assume
uname
exists on Windows - 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 ($(OS),Windows_NT)
CCFLAGS += -D WIN32
ifeq ($(PROCESSOR_ARCHITEW6432),AMD64)
CCFLAGS += -D AMD64
else
ifeq ($(PROCESSOR_ARCHITECTURE),AMD64)
CCFLAGS += -D AMD64
endif
ifeq ($(PROCESSOR_ARCHITECTURE),x86)
CCFLAGS += -D IA32
endif
endif
else
UNAME_S := $(shell uname -s)
ifeq ($(UNAME_S),Linux)
CCFLAGS += -D LINUX
endif
ifeq ($(UNAME_S),Darwin)
CCFLAGS += -D OSX
endif
UNAME_P := $(shell uname -p)
ifeq ($(UNAME_P),x86_64)
CCFLAGS += -D AMD64
endif
ifneq ($(filter %86,$(UNAME_P)),)
CCFLAGS += -D IA32
endif
ifneq ($(filter arm%,$(UNAME_P)),)
CCFLAGS += -D ARM
endif
endif
Solution 2:
The uname command (http://developer.apple.com/documentation/Darwin/Reference/ManPages/man1/uname.1.html) with no parameters should tell you the operating system name. I'd use that, then make conditionals based on the return value.
Example
UNAME := $(shell uname)
ifeq ($(UNAME), Linux)
# do something Linux-y
endif
ifeq ($(UNAME), Solaris)
# do something Solaris-y
endif
Solution 3:
Detect the operating system using two simple tricks:
- First the environment variable
OS
- Then the
uname
command
ifeq ($(OS),Windows_NT) # is Windows_NT on XP, 2000, 7, Vista, 10...
detected_OS := Windows
else
detected_OS := $(shell uname) # same as "uname -s"
endif
Or a more safe way, if not on Windows and uname
unavailable:
ifeq ($(OS),Windows_NT)
detected_OS := Windows
else
detected_OS := $(shell sh -c 'uname 2>/dev/null || echo Unknown')
endif
Ken Jackson proposes an interesting alternative if you want to distinguish Cygwin/MinGW/MSYS/Windows. See his answer that looks like that:
ifeq '$(findstring ;,$(PATH))' ';'
detected_OS := Windows
else
detected_OS := $(shell uname 2>/dev/null || echo Unknown)
detected_OS := $(patsubst CYGWIN%,Cygwin,$(detected_OS))
detected_OS := $(patsubst MSYS%,MSYS,$(detected_OS))
detected_OS := $(patsubst MINGW%,MSYS,$(detected_OS))
endif
Then you can select the relevant stuff depending on detected_OS
:
ifeq ($(detected_OS),Windows)
CFLAGS += -D WIN32
endif
ifeq ($(detected_OS),Darwin) # Mac OS X
CFLAGS += -D OSX
endif
ifeq ($(detected_OS),Linux)
CFLAGS += -D LINUX
endif
ifeq ($(detected_OS),GNU) # Debian GNU Hurd
CFLAGS += -D GNU_HURD
endif
ifeq ($(detected_OS),GNU/kFreeBSD) # Debian kFreeBSD
CFLAGS += -D GNU_kFreeBSD
endif
ifeq ($(detected_OS),FreeBSD)
CFLAGS += -D FreeBSD
endif
ifeq ($(detected_OS),NetBSD)
CFLAGS += -D NetBSD
endif
ifeq ($(detected_OS),DragonFly)
CFLAGS += -D DragonFly
endif
ifeq ($(detected_OS),Haiku)
CFLAGS += -D Haiku
endif
Notes:
Command
uname
is same asuname -s
because option-s
(--kernel-name
) is the default. See whyuname -s
is better thanuname -o
.The use of
OS
(instead ofuname
) simplifies the identification algorithm. You can still use solelyuname
, but you have to deal withif/else
blocks to check all MinGW, Cygwin, etc. variations.The environment variable
OS
is always set to"Windows_NT"
on different Windows versions (see%OS%
environment variable on Wikipedia).An alternative of
OS
is the environment variableMSVC
(it checks the presence of MS Visual Studio, see example using Visual C++).
Below I provide a complete example using make
and gcc
to build a shared library: *.so
or *.dll
depending on the platform. The example is as simplest as possible to be more understandable.
To install make
and gcc
on Windows see Cygwin or MinGW.
My example is based on five files
├── lib
│ └── Makefile
│ └── hello.h
│ └── hello.c
└── app
└── Makefile
└── main.c
Reminder: Makefile
is indented using tabulation. Caution when copy-pasting below sample files.
The two Makefile
files
1. lib/Makefile
ifeq ($(OS),Windows_NT)
uname_S := Windows
else
uname_S := $(shell uname -s)
endif
ifeq ($(uname_S), Windows)
target = hello.dll
endif
ifeq ($(uname_S), Linux)
target = libhello.so
endif
#ifeq ($(uname_S), .....) #See https://stackoverflow.com/a/27776822/938111
# target = .....
#endif
%.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 $@ (libhello.so or hello.dll)
2. app/Makefile
ifeq ($(OS),Windows_NT)
uname_S := Windows
else
uname_S := $(shell uname -s)
endif
ifeq ($(uname_S), Windows)
target = app.exe
endif
ifeq ($(uname_S), Linux)
target = app
endif
#ifeq ($(uname_S), .....) #See https://stackoverflow.com/a/27776822/938111
# target = .....
#endif
%.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
$(target): 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 (libhello.so or hello.dll)
# -o $@ => output file (-o) is $@ (target) = "app.exe" or "app"
To learn more, read Automatic Variables documentation as pointed out by cfi.
The source code
- lib/hello.h
#ifndef HELLO_H_
#define HELLO_H_
const char* hello();
#endif
- lib/hello.c
#include "hello.h"
const char* hello()
{
return "hello";
}
- app/main.c
#include "hello.h" //hello()
#include <stdio.h> //puts()
int main()
{
const char* str = hello();
puts(str);
}
The build
Fix the copy-paste of Makefile
(replace leading spaces by one tabulation).
> sed 's/^ */\t/' -i */Makefile
The make
command is the same on both platforms. The given output is on Unix-like OSes:
> 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 libhello.so
# hello.o => hello.o is the first after ':' => Link hello.o
# -shared => Generate shared library
# -o libhello.so => Output file (-o) is libhello.so (libhello.so 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
# 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 (libhello.so or hello.dll)
# -o app => output file (-o) is app.exe (target) = "app.exe" or "app"
make: Leaving directory '/tmp/app'
The run
The application requires to know where is the shared library.
On 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 Unix-like OSes, you can use the LD_LIBRARY_PATH
environment variable:
> export LD_LIBRARY_PATH=lib
Run the command on Windows:
> app/app.exe
hello
Run the command on Unix-like OSes:
> app/app
hello
Solution 4:
I was recently experimenting in order to answer 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
else
# Do things for others
endif
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, and gcc -dumpmachine
gives you the system for which you are compiling.
Solution 5:
The git makefile contains numerous examples of how to manage without autoconf/automake, yet still work on a multitude of unixy platforms.