====================================== Preparing and Distributing modules ====================================== .. contents:: There are three or four different ways to use CFFI in a project. In order of complexity: * The **"in-line", "ABI mode"**: .. code-block:: python import cffi ffi = cffi.FFI() ffi.cdef("C-like declarations") lib = ffi.dlopen("libpath") # use ffi and lib here .. _out-of-line-abi: * The **"out-of-line",** but still **"ABI mode",** useful to organize the code and reduce the import time: .. code-block:: python # in a separate file "package/foo_build.py" import cffi ffibuilder = cffi.FFI() ffibuilder.set_source("package._foo", None) ffibuilder.cdef("C-like declarations") if __name__ == "__main__": ffibuilder.compile() Running ``python foo_build.py`` produces a file ``_foo.py``, which can then be imported in the main program: .. code-block:: python from package._foo import ffi lib = ffi.dlopen("libpath") # use ffi and lib here .. _out-of-line-api: * The **"out-of-line", "API mode"** gives you the most flexibility and speed to access a C library at the level of C, instead of at the binary level: .. code-block:: python # in a separate file "package/foo_build.py" import cffi ffibuilder = cffi.FFI() ffibuilder.set_source("package._foo", r"""real C code""") # <= ffibuilder.cdef("C-like declarations with '...'") if __name__ == "__main__": ffibuilder.compile(verbose=True) Running ``python foo_build.py`` produces a file ``_foo.c`` and invokes the C compiler to turn it into a file ``_foo.so`` (or ``_foo.pyd`` or ``_foo.dylib``). It is a C extension module which can be imported in the main program: .. code-block:: python from package._foo import ffi, lib # no ffi.dlopen() # use ffi and lib here .. _distutils-setuptools: * Finally, you can (but don't have to) use CFFI's **Distutils** or **Setuptools integration** when writing a ``setup.py``. For Distutils (only in out-of-line API mode): .. code-block:: python # setup.py (requires CFFI to be installed first) from distutils.core import setup import foo_build # possibly with sys.path tricks to find it setup( ..., ext_modules=[foo_build.ffibuilder.distutils_extension()], ) For Setuptools (out-of-line, but works in ABI or API mode; recommended): .. code-block:: python # setup.py (with automatic dependency tracking) from setuptools import setup setup( ..., setup_requires=["cffi>=1.0.0"], cffi_modules=["package/foo_build.py:ffibuilder"], install_requires=["cffi>=1.0.0"], ) Note again that the ``foo_build.py`` example contains the following lines, which mean that the ``ffibuilder`` is not actually compiled when ``package.foo_build`` is merely imported---it will be compiled independently by the Setuptools logic, using compilation parameters provided by Setuptools: .. code-block:: python if __name__ == "__main__": # not when running with setuptools ffibuilder.compile(verbose=True) * Note that some bundler tools that try to find all modules used by a project, like PyInstaller, will miss ``_cffi_backend`` in the out-of-line mode because your program contains no explicit ``import cffi`` or ``import _cffi_backend``. You need to add ``_cffi_backend`` explicitly (as a "hidden import" in PyInstaller, but it can also be done more generally by adding the line ``import _cffi_backend`` in your main program). Note that CFFI actually contains two different ``FFI`` classes. The page `Using the ffi/lib objects`_ describes the common functionality. It is what you get in the ``from package._foo import ffi`` lines above. On the other hand, the extended ``FFI`` class is the one you get from ``import cffi; ffi_or_ffibuilder = cffi.FFI()``. It has the same functionality (for in-line use), but also the extra methods described below (to prepare the FFI). NOTE: We use the name ``ffibuilder`` instead of ``ffi`` in the out-of-line context, when the code is about producing a ``_foo.so`` file; this is an attempt to distinguish it from the different ``ffi`` object that you get by later saying ``from _foo import ffi``. .. _`Using the ffi/lib objects`: using.html The reason for this split of functionality is that a regular program using CFFI out-of-line does not need to import the ``cffi`` pure Python package at all. (Internally it still needs ``_cffi_backend``, a C extension module that comes with CFFI; this is why CFFI is also listed in ``install_requires=..`` above. In the future this might be split into a different PyPI package that only installs ``_cffi_backend``.) Note that a few small differences do exist: notably, ``from _foo import ffi`` returns an object of a type written in C, which does not let you add random attributes to it (nor does it have all the underscore-prefixed internal attributes of the Python version). Similarly, the ``lib`` objects returned by the C version are read-only, apart from writes to global variables. Also, ``lib.__dict__`` does not work before version 1.2 or if ``lib`` happens to declare a name called ``__dict__`` (use instead ``dir(lib)``). The same is true for ``lib.__class__``, ``lib.__all__`` and ``lib.__name__`` added in successive versions. .. _cdef: ffi/ffibuilder.cdef(): declaring types and functions ---------------------------------------------------- **ffi/ffibuilder.cdef(source)**: parses the given C source. It registers all the functions, types, constants and global variables in the C source. The types can be used immediately in ``ffi.new()`` and other functions. Before you can access the functions and global variables, you need to give ``ffi`` another piece of information: where they actually come from (which you do with either ``ffi.dlopen()`` or ``ffi.set_source()``). .. _`all types listed above`: The C source is parsed internally (using ``pycparser``). This code cannot contain ``#include``. It should typically be a self-contained piece of declarations extracted from a man page. The only things it can assume to exist are the standard types: * char, short, int, long, long long (both signed and unsigned) * float, double, long double * intN_t, uintN_t (for N=8,16,32,64), intptr_t, uintptr_t, ptrdiff_t, size_t, ssize_t * wchar_t (if supported by the backend). *New in version 1.11:* char16_t and char32_t. * _Bool and bool (equivalent). If not directly supported by the C compiler, this is declared with the size of ``unsigned char``. * FILE. `See here.`__ * all `common Windows types`_ are defined if you run on Windows (``DWORD``, ``LPARAM``, etc.). Exception: ``TBYTE TCHAR LPCTSTR PCTSTR LPTSTR PTSTR PTBYTE PTCHAR`` are not automatically defined; see `ffi.set_unicode()`_. * the other standard integer types from stdint.h, like ``intmax_t``, as long as they map to integers of 1, 2, 4 or 8 bytes. Larger integers are not supported. .. __: ref.html#file .. _`common Windows types`: http://msdn.microsoft.com/en-us/library/windows/desktop/aa383751%28v=vs.85%29.aspx The declarations can also contain "``...``" at various places; these are placeholders that will be completed by the compiler. More information about it below in `Letting the C compiler fill the gaps`_. Note that all standard type names listed above are handled as *defaults* only (apart from the ones that are keywords in the C language). If your ``cdef`` contains an explicit typedef that redefines one of the types above, then the default described above is ignored. (This is a bit hard to implement cleanly, so in some corner cases it might fail, notably with the error ``Multiple type specifiers with a type tag``. Please report it as a bug if it does.) Multiple calls to ``ffi.cdef()`` are possible. Beware that it can be slow to call ``ffi.cdef()`` a lot of times, a consideration that is important mainly in in-line mode. The ``ffi.cdef()`` call optionally takes an extra argument: either ``packed`` or ``pack``. If you pass ``packed=True``, then all structs declared within this cdef are "packed". (If you need both packed and non-packed structs, use several cdefs in sequence.) This has a meaning similar to ``__attribute__((packed))`` in GCC. It specifies that all structure fields should have an alignment of one byte. (Note that the packed attribute has no effect on bit fields so far, which mean that they may be packed differently than on GCC. Also, this has no effect on structs declared with ``"...;"``---more about it later in `Letting the C compiler fill the gaps`_. In particular, if your C source uses other attributes like ``__attribute__((aligned(16)))``, there is no way to declare this fact in the ``cdef()``, but you can generally just declare the struct with ``"...;"`` as the last field.) *New in version 1.12:* In ABI mode, you can also pass ``pack=n``, with an integer ``n`` which must be a power of two. Then the alignment of any field is limited to ``n`` if it would otherwise be greater than ``n``. Passing ``pack=1`` is equivalent to passing ``packed=True``. This is meant to emulate ``#pragma pack(n)`` from the MSVC compiler. On Windows, the default is ``pack=8`` (from cffi 1.12 onwards); on other platforms, the default is ``pack=None``. Note that you can use the type-qualifiers ``const`` and ``restrict`` (but not ``__restrict`` or ``__restrict__``) in the ``cdef()``, but this has no effect on the cdata objects that you get at run-time (they are never ``const``). The effect is limited to knowing if a global variable is meant to be a constant or not. Also, *new in version 1.3:* when using ``set_source()`` or ``verify()``, these two qualifiers are copied from the cdef to the generated C code; this fixes warnings by the C compiler. Note a trick if you copy-paste code from sources in which there are extra macros (for example, the Windows documentation uses SAL annotations like ``_In_`` or ``_Out_``). These hints must be removed in the string given to cdef(), but it can be done programmatically like this:: ffi.cdef(re.sub(r"\b(_In_|_Inout_|_Out_|_Outptr_)(opt_)?\b", " ", """ DWORD WINAPI GetModuleFileName( _In_opt_ HMODULE hModule, _Out_ LPTSTR lpFilename, _In_ DWORD nSize ); """)) Note also that pycparser, the underlying C parser, recognizes preprocessor-like directives in the following format: ``# NUMBER "FILE"``. For example, if you put ``# 42 "foo.h"`` in the middle of the string passed to ``cdef()`` and there is an error two lines later, then it is reported with an error message that starts with ``foo.h:43:`` (the line which is given the number 42 is the line immediately after the directive). *New in version 1.10.1:* CFFI automatically puts the line ``# 1 ""`` just before the string you give to ``cdef()``. .. _`ffi.set_unicode()`: **ffi.set_unicode(enabled_flag)**: Windows: if ``enabled_flag`` is True, enable the ``UNICODE`` and ``_UNICODE`` defines in C, and declare the types ``TBYTE TCHAR LPCTSTR PCTSTR LPTSTR PTSTR PTBYTE PTCHAR`` to be (pointers to) ``wchar_t``. If ``enabled_flag`` is False, declare these types to be (pointers to) plain 8-bit characters. (These types are not predeclared at all if you don't call ``set_unicode()``.) The reason behind this method is that a lot of standard functions have two versions, like ``MessageBoxA()`` and ``MessageBoxW()``. The official interface is ``MessageBox()`` with arguments like ``LPTCSTR``. Depending on whether ``UNICODE`` is defined or not, the standard header renames the generic function name to one of the two specialized versions, and declares the correct (unicode or not) types. Usually, the right thing to do is to call this method with True. Be aware (particularly on Python 2) that, afterwards, you need to pass unicode strings as arguments instead of byte strings. .. _loading-libraries: ffi.dlopen(): loading libraries in ABI mode ------------------------------------------- ``ffi.dlopen(libpath, [flags])``: this function opens a shared library and returns a module-like library object. Use this when you are fine with the limitations of ABI-level access to the system (dependency on ABI details, getting crashes instead of C compiler errors/warnings, and higher overhead to call the C functions). In case of doubt, read again `ABI versus API`_ in the overview. .. _`ABI versus API`: overview.html#abi-versus-api You can use the library object to call the functions previously declared by ``ffi.cdef()``, to read constants, and to read or write global variables. Note that you can use a single ``cdef()`` to declare functions from multiple libraries, as long as you load each of them with ``dlopen()`` and access the functions from the correct one. The ``libpath`` is the file name of the shared library, which can contain a full path or not (in which case it is searched in standard locations, as described in ``man dlopen``), with extensions or not. Alternatively, if ``libpath`` is None, it returns the standard C library (which can be used to access the functions of glibc, on Linux). Note that ``libpath`` `cannot be None`__ on Windows with Python 3. .. __: http://bugs.python.org/issue23606 Let me state it again: this gives ABI-level access to the library, so you need to have all types declared manually exactly as they were while the library was made. No checking is done. Mismatches can cause random crashes. API-level access, on the other hand, is safer. Speed-wise, API-level access is much faster (it is common to have the opposite misconception about performance). Note that only functions and global variables live in library objects; the types exist in the ``ffi`` instance independently of library objects. This is due to the C model: the types you declare in C are not tied to a particular library, as long as you ``#include`` their headers; but you cannot call functions from a library without linking it in your program, as ``dlopen()`` does dynamically in C. For the optional ``flags`` argument, see ``man dlopen`` (ignored on Windows). It defaults to ``ffi.RTLD_NOW``. This function returns a "library" object that gets closed when it goes out of scope. Make sure you keep the library object around as long as needed. (Alternatively, the out-of-line FFIs have a method ``ffi.dlclose(lib)``.) .. _dlopen-note: Note: the old version of ``ffi.dlopen()`` from the in-line ABI mode tries to use ``ctypes.util.find_library()`` if it cannot directly find the library. The newer out-of-line ``ffi.dlopen()`` no longer does it automatically; it simply passes the argument it receives to the underlying ``dlopen()`` or ``LoadLibrary()`` function. If needed, it is up to you to use ``ctypes.util.find_library()`` or any other way to look for the library's filename. This also means that ``ffi.dlopen(None)`` no longer work on Windows; try instead ``ffi.dlopen(ctypes.util.find_library('c'))``. *New in version 1.14:* ``ffi.dlopen(handle)``: instead of a file path, you can give an already-opened library handle, as a cdata of type ``void *``. Such a call converts this handle into a regular FFI object with the functions and global variables declared by ``ffi.cdef()``. Useful if you have special needs (e.g. you need the GNU extension ``dlmopen()``, which you can itself declare and call using a different ``ffi`` object). Note that in this variant, ``dlclose()`` is not called automatically if the FFI object is garbage-collected (but you can still call ``ffi.dlclose()`` explicitly if needed). ffibuilder.set_source(): preparing out-of-line modules ------------------------------------------------------ **ffibuilder.set_source(module_name, c_header_source, [\*\*keywords...])**: prepare the ffi for producing out-of-line an external module called ``module_name``. ``ffibuilder.set_source()`` by itself does not write any file, but merely records its arguments for later. It can therefore be called before or after ``ffibuilder.cdef()``. In **ABI mode,** you call ``ffibuilder.set_source(module_name, None)``. The argument is the name (or dotted name inside a package) of the Python module to generate. In this mode, no C compiler is called. In **API mode,** the ``c_header_source`` argument is a string that will be pasted into the .c file generated. Typically, it is specified as ``r""" ...multiple lines of C code... """`` (the ``r`` prefix allows these lines to contain a literal ``\n``, for example). This piece of C code typically contains some ``#include``, but may also contain more, like definitions for custom "wrapper" C functions. The goal is that the .c file can be generated like this:: // C file "module_name.c" #include ...c_header_source... ...magic code... where the "magic code" is automatically generated from the ``cdef()``. For example, if the ``cdef()`` contains ``int foo(int x);`` then the magic code will contain logic to call the function ``foo()`` with an integer argument, itself wrapped inside some CPython or PyPy-specific code. The keywords arguments to ``set_source()`` control how the C compiler will be called. They are passed directly to distutils_ or setuptools_ and include at least ``sources``, ``include_dirs``, ``define_macros``, ``undef_macros``, ``libraries``, ``library_dirs``, ``extra_objects``, ``extra_compile_args`` and ``extra_link_args``. You typically need at least ``libraries=['foo']`` in order to link with ``libfoo.so`` or ``libfoo.so.X.Y``, or ``foo.dll`` on Windows. The ``sources`` is a list of extra .c files compiled and linked together (the file ``module_name.c`` shown above is always generated and automatically added as the first argument to ``sources``). See the distutils documentations for `more information about the other arguments`__. .. __: http://docs.python.org/distutils/setupscript.html#library-options .. _distutils: http://docs.python.org/distutils/setupscript.html#describing-extension-modules .. _setuptools: https://pythonhosted.org/setuptools/setuptools.html An extra keyword argument processed internally is ``source_extension``, defaulting to ``".c"``. The file generated will be actually called ``module_name + source_extension``. Example for C++ (but note that there are still a few known issues of C-versus-C++ compatibility): .. code-block:: python ffibuilder.set_source("mymodule", r''' extern "C" { int somefunc(int somearg) { return real_cpp_func(somearg); } } ''', source_extension='.cpp') .. _pkgconfig: **ffibuilder.set_source_pkgconfig(module_name, pkgconfig_libs, c_header_source, [\*\*keywords...])**: *New in version 1.12.* This is equivalent to ``set_source()`` but it first calls the system utility ``pkg-config`` with the package names given in the list ``pkgconfig_libs``. It collects the information obtained in this way and adds it to the explicitly-provided ``**keywords`` (if any). This should probably not be used on Windows. If the ``pkg-config`` program is not installed or does not know about the requested library, the call fails with ``cffi.PkgConfigError``. If necessary, you can catch this error and try to call ``set_source()`` directly. (Ideally, you should also do that if the ``ffibuilder`` instance has no method ``set_source_pkgconfig()``, to support older versions of cffi.) Letting the C compiler fill the gaps ------------------------------------ If you are using a C compiler ("API mode"), then: * functions taking or returning integer or float-point arguments can be misdeclared: if e.g. a function is declared by ``cdef()`` as taking a ``int``, but actually takes a ``long``, then the C compiler handles the difference. * other arguments are checked: you get a compilation warning or error if you pass a ``int *`` argument to a function expecting a ``long *``. * similarly, most other things declared in the ``cdef()`` are checked, to the best we implemented so far; mistakes give compilation warnings or errors. Moreover, you can use "``...``" (literally, dot-dot-dot) in the ``cdef()`` at various places, in order to ask the C compiler to fill in the details. These places are: * structure declarations: any ``struct { }`` or ``union { }`` that ends with "``...;``" as the last "field" is partial: it may be missing fields, have them declared out of order, use non-standard alignment, etc. Precisely, the field offsets, total struct size, and total struct alignment deduced by looking at the ``cdef`` are not relied upon and will instead be corrected by the compiler. (But note that you can only access fields that you declared, not others.) Any ``struct`` declaration which doesn't use "``...``" is assumed to be exact, but this is checked: you get an error if it is not correct. * integer types: the syntax "``typedef int... foo_t;``" declares the type ``foo_t`` as an integer type whose exact size and signedness is not specified. The compiler will figure it out. (Note that this requires ``set_source()``; it does not work with ``verify()``.) The ``int...`` can be replaced with ``long...`` or ``unsigned long long...`` or any other primitive integer type, with no effect. The type will always map to one of ``(u)int(8,16,32,64)_t`` in Python, but in the generated C code, only ``foo_t`` is used. * *New in version 1.3:* floating-point types: "``typedef float... foo_t;``" (or equivalently "``typedef double... foo_t;``") declares ``foo_t`` as a-float-or-a-double; the compiler will figure out which it is. Note that if the actual C type is even larger (``long double`` on some platforms), then compilation will fail. The problem is that the Python "float" type cannot be used to store the extra precision. (Use the non-dot-dot-dot syntax ``typedef long double foo_t;`` as usual, which returns values that are not Python floats at all but cdata "long double" objects.) * unknown types: the syntax "``typedef ... foo_t;``" declares the type ``foo_t`` as opaque. Useful mainly for when the API takes and returns ``foo_t *`` without you needing to look inside the ``foo_t``. Also works with "``typedef ... *foo_p;``" which declares the pointer type ``foo_p`` without giving a name to the opaque type itself. Note that such an opaque struct has no known size, which prevents some operations from working (mostly like in C). *You cannot use this syntax to declare a specific type, like an integer type! It declares opaque struct-like types only.* In some cases you need to say that ``foo_t`` is not opaque, but just a struct where you don't know any field; then you would use "``typedef struct { ...; } foo_t;``". * array lengths: when used as structure fields or in global variables, arrays can have an unspecified length, as in "``extern int n[...];``". The length is completed by the C compiler. This is slightly different from "``extern int n[];``", because the latter means that the length is not known even to the C compiler, and thus no attempt is made to complete it. This supports multidimensional arrays: "``extern int n[...][...];``". *New in version 1.2:* "``extern int m[][...];``", i.e. ``...`` can be used in the innermost dimensions without being also used in the outermost dimension. In the example given, the length of the ``m`` array is assumed not to be known to the C compiler, but the length of every item (like the sub-array ``m[0]``) is always known the C compiler. In other words, only the outermost dimension can be specified as ``[]``, both in C and in CFFI, but any dimension can be given as ``[...]`` in CFFI. * enums: if you don't know the exact order (or values) of the declared constants, then use this syntax: "``enum foo { A, B, C, ... };``" (with a trailing "``...``"). The C compiler will be used to figure out the exact values of the constants. An alternative syntax is "``enum foo { A=..., B, C };``" or even "``enum foo { A=..., B=..., C=... };``". Like with structs, an ``enum`` without "``...``" is assumed to be exact, and this is checked. * integer constants and macros: you can write in the ``cdef`` the line "``#define FOO ...``", with any macro name FOO but with ``...`` as a value. Provided the macro is defined to be an integer value, this value will be available via an attribute of the library object. The same effect can be achieved by writing a declaration ``static const int FOO;``. The latter is more general because it supports other types than integer types (note: the C syntax is then to write the ``const`` together with the variable name, as in ``static char *const FOO;``). Currently, it is not supported to find automatically which of the various integer or float types you need at which place---except in the following case: if such a type is explicitly named. For an integer type, use ``typedef int... the_type_name;``, or another type like ``typedef unsigned long... the_type_name;``. Both are equivalent and replaced by the real C type, which must be an integer type. Similarly, for floating-point types, use ``typedef float... the_type_name;`` or equivalently ``typedef double... the_type_name;``. Note that ``long double`` cannot be detected this way. In the case of function arguments or return types, when it is a simple integer/float type, you can simply misdeclare it. If you misdeclare a function ``void f(long)`` as ``void f(int)``, it still works (but you have to call it with arguments that fit an int). It works because the C compiler will do the casting for us. This C-level casting of arguments and return types only works for regular function, and not for function pointer types; currently, it also does not work for variadic functions. For more complex types, you have no choice but be precise. For example, you cannot misdeclare a ``int *`` argument as ``long *``, or a global array ``extern int a[5];`` as ``extern long a[5];``. CFFI considers `all types listed above`_ as primitive (so ``extern long long a[5];`` and ``extern int64_t a[5]`` are different declarations). The reason for that is detailed in `a comment about an issue.`__ .. __: https://foss.heptapod.net/pypy/cffi/-/issues/265#note_50393 ffibuilder.compile() etc.: compiling out-of-line modules -------------------------------------------------------- You can use one of the following functions to actually generate the .py or .c file prepared with ``ffibuilder.set_source()`` and ``ffibuilder.cdef()``. Note that these function won't overwrite a .py/.c file with exactly the same content, to preserve the mtime. In some cases where you need the mtime to be updated anyway, delete the file before calling the functions. *New in version 1.8:* the C code produced by ``emit_c_code()`` or ``compile()`` contains ``#define Py_LIMITED_API``. This means that on CPython >= 3.2, compiling this source produces a binary .so/.dll that should work for any version of CPython >= 3.2 (as opposed to only for the same version of CPython x.y). However, the standard ``distutils`` package will still produce a file called e.g. ``NAME.cpython-35m-x86_64-linux-gnu.so``. You can manually rename it to ``NAME.abi3.so``, or use setuptools version 26 or later. Also, note that compiling with a debug version of Python will not actually define ``Py_LIMITED_API``, as doing so makes ``Python.h`` unhappy. *New in version 1.12:* ``Py_LIMITED_API`` is now defined on Windows too. If you use ``virtualenv``, you need a recent version of it: versions older than 16.0.0 forgot to copy ``python3.dll`` into the virtual environment. In case upgrading ``virtualenv`` is a real problem, you can manually edit the C code to remove the first line ``# define Py_LIMITED_API``. **ffibuilder.compile(tmpdir='.', verbose=False, debug=None):** explicitly generate the .py or .c file, and (if .c) compile it. The output file is (or are) put in the directory given by ``tmpdir``. In the examples given here, we use ``if __name__ == "__main__": ffibuilder.compile()`` in the build scripts---if they are directly executed, this makes them rebuild the .py/.c file in the current directory. (Note: if a package is specified in the call to ``set_source()``, then a corresponding subdirectory of the ``tmpdir`` is used.) *New in version 1.4:* ``verbose`` argument. If True, it prints the usual distutils output, including the command lines that call the compiler. (This parameter might be changed to True by default in a future release.) *New in version 1.8.1:* ``debug`` argument. If set to a bool, it controls whether the C code is compiled in debug mode or not. The default None means to use the host Python's ``sys.flags.debug``. Starting with version 1.8.1, if you are running a debug-mode Python, the C code is thus compiled in debug mode by default (note that it is anyway necessary to do so on Windows). **ffibuilder.emit_python_code(filename):** generate the given .py file (same as ``ffibuilder.compile()`` for ABI mode, with an explicitly-named file to write). If you choose, you can include this .py file pre-packaged in your own distributions: it is identical for any Python version (2 or 3). **ffibuilder.emit_c_code(filename):** generate the given .c file (for API mode) without compiling it. Can be used if you have some other method to compile it, e.g. if you want to integrate with some larger build system that will compile this file for you. You can also distribute the .c file: unless the build script you used depends on the OS or platform, the .c file itself is generic (it would be exactly the same if produced on a different OS, with a different version of CPython, or with PyPy; it is done with generating the appropriate ``#ifdef``). **ffibuilder.distutils_extension(tmpdir='build', verbose=True):** for distutils-based ``setup.py`` files. Calling this creates the .c file if needed in the given ``tmpdir``, and returns a ``distutils.core.Extension`` instance. For Setuptools, you use instead the line ``cffi_modules=["path/to/foo_build.py:ffibuilder"]`` in ``setup.py``. This line asks Setuptools to import and use a helper provided by CFFI, which in turn executes the file ``path/to/foo_build.py`` (as with ``execfile()``) and looks up its global variable called ``ffibuilder``. You can also say ``cffi_modules=["path/to/foo_build.py:maker"]``, where ``maker`` names a global function; it is called with no argument and is supposed to return a ``FFI`` object. ffi/ffibuilder.include(): combining multiple CFFI interfaces ------------------------------------------------------------ **ffi/ffibuilder.include(other_ffi)**: includes the typedefs, structs, unions, enums and constants defined in another FFI instance. This is meant for large projects where one CFFI-based interface depends on some types declared in a different CFFI-based interface. *Note that you should only use one ffi object per library; the intended usage of ffi.include() is if you want to interface with several inter-dependent libraries.* For only one library, make one ``ffi`` object. (You can write several ``cdef()`` calls over the same ``ffi`` from several Python files, if one file would be too large.) For out-of-line modules, the ``ffibuilder.include(other_ffibuilder)`` line should occur in the build script, and the ``other_ffibuilder`` argument should be another FFI instance that comes from another build script. When the two build scripts are turned into generated files, say ``_ffi.so`` and ``_other_ffi.so``, then importing ``_ffi.so`` will internally cause ``_other_ffi.so`` to be imported. At that point, the real declarations from ``_other_ffi.so`` are combined with the real declarations from ``_ffi.so``. The usage of ``ffi.include()`` is the cdef-level equivalent of a ``#include`` in C, where a part of the program might include types and functions defined in another part for its own usage. You can see on the ``ffi`` object (and associated ``lib`` objects on the *including* side) the types and constants declared on the included side. In API mode, you can also see the functions and global variables directly. In ABI mode, these must be accessed via the original ``other_lib`` object returned by the ``dlopen()`` method on ``other_ffi``. ffi.cdef() limitations ---------------------- All of the ANSI C *declarations* should be supported in ``cdef()``, and some of C99. (This excludes any ``#include`` or ``#ifdef``.) Known missing features that are either in C99, or are GCC or MSVC extensions: * Any ``__attribute__`` or ``#pragma pack(n)`` * Additional types: special-size floating and fixed point types, vector types, and so on. * The C99 types ``float _Complex`` and ``double _Complex`` are supported by cffi since version 1.11, but not libffi: you cannot call C functions with complex arguments or return value, except if they are directly API-mode functions. The type ``long double _Complex`` is not supported at all (declare and use it as if it were an array of two ``long double``, and write wrapper functions in C with set_source()). * ``__restrict__`` or ``__restrict`` are extensions of, respectively, GCC and MSVC. They are not recognized. But ``restrict`` is a C keyword and is accepted (and ignored). Note that declarations like ``int field[];`` in structures are interpreted as variable-length structures. Declarations like ``int field[...];`` on the other hand are arrays whose length is going to be completed by the compiler. You can use ``int field[];`` for array fields that are not, in fact, variable-length; it works too, but in this case, as CFFI believes it cannot ask the C compiler for the length of the array, you get reduced safety checks: for example, you risk overwriting the following fields by passing too many array items in the constructor. *New in version 1.2:* Thread-local variables (``__thread``) can be accessed, as well as variables defined as dynamic macros (``#define myvar (*fetchme())``). Before version 1.2, you need to write getter/setter functions. Note that if you declare a variable in ``cdef()`` without using ``const``, CFFI assumes it is a read-write variable and generates two pieces of code, one to read it and one to write it. If the variable cannot in fact be written to in C code, for one reason or another, it will not compile. In this case, you can declare it as a constant: for example, instead of ``foo_t *myglob;`` you would use ``foo_t *const myglob;``. Note also that ``const foo_t *myglob;`` is a *variable;* it contains a variable pointer to a constant ``foo_t``. Debugging dlopen'ed C libraries ------------------------------- A few C libraries are actually hard to use correctly in a ``dlopen()`` setting. This is because most C libraries are intended for, and tested with, a situation where they are *linked* with another program, using either static linking or dynamic linking --- but from a program written in C, at start-up, using the linker's capabilities instead of ``dlopen()``. This can occasionally create issues. You would have the same issues in another setting than CFFI, like with ``ctypes`` or even plain C code that calls ``dlopen()``. This section contains a few generally useful environment variables (on Linux) that can help when debugging these issues. **export LD_TRACE_LOADED_OBJECTS=all** provides a lot of information, sometimes too much depending on the setting. Output verbose debugging information about the dynamic linker. If set to ``all`` prints all debugging information it has, if set to ``help`` prints a help message about which categories can be specified in this environment variable **export LD_VERBOSE=1** (glibc since 2.1) If set to a nonempty string, output symbol versioning information about the program if querying information about the program (i.e., either ``LD_TRACE_LOADED_OBJECTS`` has been set, or ``--list`` or ``--verify`` options have been given to the dynamic linker). **export LD_WARN=1** (ELF only)(glibc since 2.1.3) If set to a nonempty string, warn about unresolved symbols. ffi.verify(): in-line API-mode ------------------------------ **ffi.verify()** is supported for backward compatibility, but is deprecated. ``ffi.verify(c_header_source, tmpdir=.., ext_package=.., modulename=.., flags=.., **kwargs)`` makes and compiles a C file from the ``ffi.cdef()``, like ``ffi.set_source()`` in API mode, and then immediately loads and returns the dynamic library object. Some non-trivial logic is used to decide if the dynamic library must be recompiled or not; see below for ways to control it. The ``c_header_source`` and the extra keyword arguments have the same meaning as in ``ffi.set_source()``. One remaining use case for ``ffi.verify()`` would be the following hack to find explicitly the size of any type, in bytes, and have it available in Python immediately (e.g. because it is needed in order to write the rest of the build script): .. code-block:: python ffi = cffi.FFI() ffi.cdef("const int mysize;") lib = ffi.verify("const int mysize = sizeof(THE_TYPE);") print lib.mysize Extra arguments to ``ffi.verify()``: * ``tmpdir`` controls where the C files are created and compiled. Unless the ``CFFI_TMPDIR`` environment variable is set, the default is ``directory_containing_the_py_file/__pycache__`` using the directory name of the .py file that contains the actual call to ``ffi.verify()``. (This is a bit of a hack but is generally consistent with the location of the .pyc files for your library. The name ``__pycache__`` itself comes from Python 3.) * ``ext_package`` controls in which package the compiled extension module should be looked from. This is only useful after distributing ffi.verify()-based modules. * The ``tag`` argument gives an extra string inserted in the middle of the extension module's name: ``_cffi__``. Useful to give a bit more context, e.g. when debugging. * The ``modulename`` argument can be used to force a specific module name, overriding the name ``_cffi__``. Use with care, e.g. if you are passing variable information to ``verify()`` but still want the module name to be always the same (e.g. absolute paths to local files). In this case, no hash is computed and if the module name already exists it will be reused without further check. Be sure to have other means of clearing the ``tmpdir`` whenever you change your sources. * ``source_extension`` has the same meaning as in ``ffibuilder.set_source()``. * The optional ``flags`` argument (ignored on Windows) defaults to ``ffi.RTLD_NOW``; see ``man dlopen``. (With ``ffibuilder.set_source()``, you would use ``sys.setdlopenflags()``.) * The optional ``relative_to`` argument is useful if you need to list local files passed to the C compiler:: ext = ffi.verify(..., sources=['foo.c'], relative_to=__file__) The line above is roughly the same as:: ext = ffi.verify(..., sources=['/path/to/this/file/foo.c']) except that the default name of the produced library is built from the CRC checkum of the argument ``sources``, as well as most other arguments you give to ``ffi.verify()`` -- but not ``relative_to``. So if you used the second line, it would stop finding the already-compiled library after your project is installed, because the ``'/path/to/this/file'`` suddenly changed. The first line does not have this problem. Note that during development, every time you change the C sources that you pass to ``cdef()`` or ``verify()``, then the latter will create a new module file name, based on two CRC32 hashes computed from these strings. This creates more and more files in the ``__pycache__`` directory. It is recommended that you clean it up from time to time. A nice way to do that is to add, in your test suite, a call to ``cffi.verifier.cleanup_tmpdir()``. Alternatively, you can manually remove the whole ``__pycache__`` directory. An alternative cache directory can be given as the ``tmpdir`` argument to ``verify()``, via the environment variable ``CFFI_TMPDIR``, or by calling ``cffi.verifier.set_tmpdir(path)`` prior to calling ``verify``. Upgrading from CFFI 0.9 to CFFI 1.0 ----------------------------------- CFFI 1.0 is backward-compatible, but it is still a good idea to consider moving to the out-of-line approach new in 1.0. Here are the steps. **ABI mode** if your CFFI project uses ``ffi.dlopen()``: .. code-block:: python import cffi ffi = cffi.FFI() ffi.cdef("stuff") lib = ffi.dlopen("libpath") and *if* the "stuff" part is big enough that import time is a concern, then rewrite it as described in `the out-of-line but still ABI mode`__ above. Optionally, see also the `setuptools integration`__ paragraph. .. __: out-of-line-abi_ .. __: distutils-setuptools_ **API mode** if your CFFI project uses ``ffi.verify()``: .. code-block:: python import cffi ffi = cffi.FFI() ffi.cdef("stuff") lib = ffi.verify("real C code") then you should really rewrite it as described in `the out-of-line, API mode`__ above. It avoids a number of issues that have caused ``ffi.verify()`` to grow a number of extra arguments over time. Then see the `distutils or setuptools`__ paragraph. Also, remember to remove the ``ext_package=".."`` from your ``setup.py``, which was sometimes needed with ``verify()`` but is just creating confusion with ``set_source()``. .. __: out-of-line-api_ .. __: distutils-setuptools_ The following example should work both with old (pre-1.0) and new versions of CFFI---supporting both is important to run on old versions of PyPy (CFFI 1.0 does not work in PyPy < 2.6): .. code-block:: python # in a separate file "package/foo_build.py" import cffi ffi = cffi.FFI() C_HEADER_SRC = r''' #include "somelib.h" ''' C_KEYWORDS = dict(libraries=['somelib']) if hasattr(ffi, 'set_source'): ffi.set_source("package._foo", C_HEADER_SRC, **C_KEYWORDS) ffi.cdef(''' int foo(int); ''') if __name__ == "__main__": ffi.compile() And in the main program: .. code-block:: python try: from package._foo import ffi, lib except ImportError: from package.foo_build import ffi, C_HEADER_SRC, C_KEYWORDS lib = ffi.verify(C_HEADER_SRC, **C_KEYWORDS) (FWIW, this latest trick can be used more generally to allow the import to "work" even if the ``_foo`` module was not generated.) Writing a ``setup.py`` script that works both with CFFI 0.9 and 1.0 requires explicitly checking the version of CFFI that we can have---it is hard-coded as a built-in module in PyPy: .. code-block:: python if '_cffi_backend' in sys.builtin_module_names: # PyPy import _cffi_backend requires_cffi = "cffi==" + _cffi_backend.__version__ else: requires_cffi = "cffi>=1.0.0" Then we use the ``requires_cffi`` variable to give different arguments to ``setup()`` as needed, e.g.: .. code-block:: python if requires_cffi.startswith("cffi==0."): # backward compatibility: we have "cffi==0.*" from package.foo_build import ffi extra_args = dict( ext_modules=[ffi.verifier.get_extension()], ext_package="...", # if needed ) else: extra_args = dict( setup_requires=[requires_cffi], cffi_modules=['package/foo_build.py:ffi'], ) setup( name=..., ..., install_requires=[requires_cffi], **extra_args )