Unix cc compiler to Microsoft's cl compiler wrapper at https://github.com/swig/cccl
cccl is a wrapper around Microsoft's cl.exe Visual C++ compiler. It converts traditional Unix cc command line parameters to their cl.exe equivalents.
The main use for cccl is for using Unix build processes with the Microsoft C/C++ compiler. Using cccl in conjunction with ports of Unix utilities, it is possible to build many Unix packages using MSVC, without modifying the build process. This is especially useful if you want to use GNU autotools (autoconf/automake/libtool) with MSVC.
Why would one use a wrapper script to make cl.exe act like gcc, when gcc is available for Windows?
There are a few reasons but the primary reason is usually to support
cross-platform projects that need to use autoconf/automake/libtool for the
build process. The obvious thing might be to use gcc on all platforms. But on
Windows, not all third-party libraries work with gcc, some only work with MSVC.
cccl allows one to use the same build process with the MSVC compiler, but with
only minimal changes to the build process.
Even though it's a somewhat simple approach, the original author, Geoffery Wossum, wrote the initial version of cccl and released it for others to use as it saved him a lot of hassle in the build process.
cccl assumes cl.exe is in your path. cccl is run the same way that a Unix C or C++ compiler is used. Below shows usage to compile a simple C program:
$ cccl main.c -o runme.exe
main.c
By default cccl quietly passes the converted command line options to cl.exe.
These can be displayed by using the --cccl-verbose
option and can be useful
for analysing compilation problems, for example:
$ cccl --cccl-verbose main.c -o runme.exe
cl "/nologo" "main.c" "/Ferunme.exe"
main.c
First, you'll want to install cccl. Then, you'll probably want to learn using autotools and MSVC together.
cccl is known to work on Cygwin, MinGW, MinGW-w64 and MSYS2.
You can either copy the cccl script to somewhere on your system, or you can do
a ./bootstrap && ./configure && make install
from the source if you have a
Unixish enough environment installed. The configure and Makefile don't really
do anything but copy the cccl script, though.
cccl uses and hence requires ports of the following Unix utilities:
- bash
- sed
- tr
cccl is a bash shell script which makes use of these utilities. Therefore, you will need at the very least a Windows versions of these utilities. The easiest and best source of these (as well as many other Unix tools) has traditionally been RedHat's Cygwin. Other well known Unix-like systems can also be used - MinGW, MinGW-w64, MSYS2.
Install one of these and if you are planning on using cccl to build autotools projects, make sure that you install autoconf, automake and libtool as well.
Once you have a working Unix-like environment, you have two options. You
may manually copy the cccl file to somewhere in your path, since it's just a
script. Alternatively, you may do the normal Unix
./bootstrap && ./configure && make && make install
routine.
Obviously you'll want cccl to be in your path. Since cccl directly invokes cl.exe, you'll need to make sure it is in your path as well. This may have been done for you during your Visual Studio install. If not, there should be a file called vcvars32.bat or vcvarsall.bat which can be run from an MS-DOS command prompt to set your path. Visual Studio usually installs a menu item to run a Visual Studio Command Prompt and is commonly under the Visual Studio Tools menu. This invokes one of the aforementioned batch files. Refer to the documentation included with Visual Studio for more details about running the Visual Studio command line tools. Note that the GNU linker is also called link.exe and is usually present in the Unix-like systems running on Windows, but this shouldn't be a problem as cccl does not invoke the linker directly, it relies on cl.exe to invoke the appropriate Microsoft linker.
Autotools (autoconf, automake, libtool) and MSVC were never originally made to work together, but with cccl you can make them become reluctant friends.
Autoconf requires a file called configure.ac, which on legacy projects may still be called configure.in. In order to use autoconf and MSVC, make sure the following line is in your configure.ac file:
AC_CANONICAL_HOST
If your configure.ac file contains a reference to LT_INIT
, add the [win32-dll]
option:
LT_INIT [win32-dll]
Or if your configure.ac file is using the legacy, deprecated equivalent syntax and contains a reference to AM_PROG_LIBTOOL
, add the
following line before AM_PROG_LIBTOOL
:
AC_LIBTOOL_WIN32_DLL
Believe it or not, your Makefile.am files will probably not require any changes to work.
Convenience libraries (noinst .a targets) work fine without any changes.
No changes required. However, you may want to create a resource file to add the explorer icon to the .exe file.
Autotools can build static libraries (.lib files) fine. However, you will probably want the output file to have a different name under Windows (super.lib vs. libsuper.a). You can accomplish this using some automake conditionals.
Older versions of the autotools (2.13 and earlier) didn't really support dynamic link libraries (.dll files) very well. Newer versions of Libtool have much improved Windows support for supporting dynamic link libraries.
Once you've generated your configure script and Makefiles by running aclocal, autoheader, autoconf and automake, you're ready to compile.
Before you run the configure script (from within your Unix-like system, of course), you'll need to set the compiler and linker environment variables to use cccl.
export CC=cccl
export CXX=cccl
export LD=cccl
You may not need to set all these depending on whether your code base is just C or C++ and how the linker is invoked, but it is safest to set all three to begin with.
The options in Visual C++ are numerous and have changed over the years but have got a bit simpler more recently. Unlike gcc, the default options are not all that good though and often need tweaking. The good news is that the compiler will often tell you if you need to add an option, for example if you have C++ code that uses exceptions (any code that uses the STL uses exceptions), you should see a warning:
foo.cxx(10) : warning C4530: C++ exception handler used, but unwind semantics
are not enabled. Specify /EHsc
Modern versions require /EHsc
, but older versions require /GX
. Depending
on the version of cl.exe, you may need to add /GR
to enable run-time type
information (RTTI). Use:
export CXXFLAGS="/EHsc"
for new versions or for older versions:
export CXXFLAGS="/GX /GR"
The options starting with /
such as /EHsc
and /GX
are unrecognized by
cccl and are therefore passed directly to cl.exe.
Now, cross your fingers, and ./configure
and make
.
The Automake silent
rules
can control the verbosity of the output via the V
variable. When make V=1
is used, cccl will display the options passed to cl.exe as if cccl --cccl-verbose
was used.
cc on Unix serves as a front end to the compiler and the linker. Microsoft's cl.exe can operate the same but most usage is as a compiler.
Any traditional cc options that cccl does not convert into options for cl.exe
are passed unchanged to cl.exe. So options starting with -
may or may not
be converted. Any /
options are expected to be for cl.exe and no attempt
is made to convert them; they are passed directly to cl.exe unmodified.
Further details about option conversions are in the Options
section.
If cccl sees a C++ file with an extension other than .cpp (i.e. .cc, .C, or
.cxx), then cccl will prepend a /Tp
option to the cl.exe command line to
force cl.exe to process it as a C++ source file.
cl.exe interprets all options after /link
to be linker options. cccl may
convert some options and if necessary pass them as a linker option by adding
them after /link
. There are a few approaches to passing additional options
to the linker directly. The first is to specify them as you would with cl.exe
where everything after /link
or -link
is a linker option:
cccl main.c /W3 /link /LTCG /INCREMENTAL:NO
The second approach is to use the cccl option --cccl-link
which passes just
the single next option to the linker. If using this approach, the above example
can be rewritten as follows:
cccl main.c --cccl-link /LTCG /W3 --cccl-link /INCREMENTAL:NO
Note that the first approach requires the compiler option /W3
to be placed
before /link
, whereas with the second approach the compiler option /W3
can
be placed either before, after or as shown above right in between two linker
options.
Both of the above examples will thus invoke cl.exe as follows:
cl main.c /W3 /link /LTCG /INCREMENTAL:NO
In the MinGW/MSYS based systems, /
options are not supported very well and so are
instead converted to -
options and hence cccl will invoke cl.exe as
follows:
cl main.c -W3 -link -LTCG -INCREMENTAL:NO
Visual C++ is unusually verbose for a compiler and displays the names of the files it is compiling and sometimes "Creating library" and similiar messages. For example, default output for compiling two or more files is shown below:
$ cccl main.c stuff.c -o runme.exe
main.c
stuff.c
Generating Code...
cccl supports the --cccl-muffle
option which parses the output from cl.exe
and suppresses this extra verbiage. Adding this option to the example results
in silent output like traditional Unix compilers:
$ cccl main.c stuff.c -o runme.exe --cccl-muffle
The --cccl-verbose
option will display exactly how cl.exe is invoked:
$ cccl main.c stuff.c -o runme.exe --cccl-verbose
cl "/nologo" "main.c" "stuff.c" "/Ferunme.exe"
main.c
stuff.c
Generating Code...
cccl supports the CCCL_OPTIONS
environment variable. The contents of the
environment variable are treated as additional command line options to cccl.
This can be handy for adding additional options or tweaking the verbosity
options without changing the build system. For example:
$ export CCCL_OPTIONS="--cccl-muffle --cccl-verbose /W3"
$ cccl -O2 main.c
cl "/nologo" "/W3" "/O2" "main.c"
and assuming CCCL_OPTIONS
is not set, then the above is the same as:
$ cccl --cccl-muffle --cccl-verbose /W3 -O2 main.c
cl "/nologo" "/W3" "/O2" "main.c"
There is one notable difference using CCCL_OPTIONS
compare to using actual options and
that is the handling of spaces within options, for example -I"My Headers"
. For this to
work, you must pass it as a real cccl command line option and CCCL_OPTIONS
can't be used.
The following Unix compiler cc/gcc options are understood by cccl:
- -ansi Converts to cl.exe's /Za
- -c Converts to cl.exe's /C
- -g[0-9] Converts to cl.exe's /Zi
- -O0 Converts to cl.exe's /Ot optimization option
- -L_path_ Converts to linker option /LIBPATH:path
- -l_library_ Converts to lib_library_.lib (except -link)
- -m386 Converts to cl.exe's /G3
- -m486 Converts to cl.exe's /G4
- -mpentium Converts to cl.exe's /G5
- -mpentiumpro Converts to cl.exe's /G6
- -o is converted to /Fo for object files and /Fe for executables and dlls
- -pedantic Removed/ignored, cl.exe does not support any equivalent
- -std=standard Converts to cl.exe' /std:standard
- -Wl,(,) Options are passed to the linker
- -W Removed/ignored
- -fno-strict-aliasing Removed/ignored
- -isystem Converted to /I
- -MT Due to conflict with cl.exe's /MT option, there is no support and cccl exits
- -mno-cygwin Removed/ignored
- -rpath Removed/ignored
- -shared Converts to cl.exe's /LD or /LDd if -g is used
- *.(cc|cxx|C) C++ source file is passed using /Tp
The following are cccl specific options:
- --help Displays cccl help
- --cccl-link Passes the following option as a linker option
- --cccl-muffle Removes cl.exe's verbiage (file names being compiled etc) from being displayed
- --cccl-verbose Displays how cl.exe is invoked
- --cccl-version Displays cccl's version string
The following are Visual C++ options
- -link All remaining options are passed on as linker options
- /link All remaining options are passed on as linker options
All other -
options are passed untouched to cl.exe. All /
options are
passed unmodified to cl.exe. All other non-options (file/path names) are
also passed on unmodified.
Geoffrey Wossum (gwossum@acm.org) first wrote cccl as a Bourne shell script and released it under the GPL license at http://cccl.sf.net on 9 August 2001. The original cccl SourceForge project page is located at http://sf.net/projects/cccl.
This version contained a few patches and was released in January 2003 and was the last version released on Sourceforge.
The original was forked a few times. The known public forks are:
- SWIFT http://swift.im/git/swift in the autoconf/cccl directory which was subsequently deleted.
- Open vSwitch https://github.com/openvswitch/ovs/commits/master/build-aux/cccl which built on top of the SWIFT fork.
- BalaBit which is described in a blog titled Compiling autoconf/make projects under msvc. The BalaBit fork is a lot more complex than the others and performance is consequently somewhat slower. The Git repo is at git://git.balabit.hu/folti/cccl.git.
William Fulton had been using cccl with some unpublished modifications for testing and building SWIG releases for many years. In 2015, these were made public and merged with the Open vSwitch fork and released on Github at https://github.com/swig/cccl under the newer GPL version 3 license.
The documentation was also converted to Markdown format and brought up to date.
The main improvements in version 1.0 over the original cccl release 0.03 are:
- Support for compiling and linking in a single step works with a mix of C, C++ and object files as inputs.
- Support for spaces in paths, such as include paths and spaces in file names.
- Support for creating dynamic link libraries (dlls).
- Support for running under MinGW.
- Adding control of output verbosity.
- Simpler setup configuration by avoiding using link.exe directly, which previously may have incorrectly invoked the GNU linker.
- Convert -dll to /LD to achieve compatibility with libtool.
- Ignore -rpath option.
- Previously -Wl options were ignored, now they are passed to the Microsoft linker.
- Support -link option the same as /link
- Add conversion for -std option
- Add support for space after -I and -L options
- Documentation updates
The move to Github at https://github.com/swig/cccl is hoped to inject some life into the project on a modern open source platform as the Sourceforge project had been defunct for 12 years.
The goal is for cccl to remain simple and lightweight so that the performance degradation added by the wrapper is kept small. Pull requests from users for bug fixes and improvements that meet these goals are encouraged.
wgcc is another cccl like tool for Interix but was superceded by parity.