This is an FFI for Emacs. It is based on libffi and relies on the dynamic modules work (available on the Emacs 25 branch) in order to be loaded into Emacs. It is relatively full-featured, but for the time being low-level.
I'd appreciate your feedback, either via email or issues on github.
Currently the library supports primitive and structure types for arguments and return types.
Primitive types are described using keywords:
-
:void
. The void type. This does not make sense as an argument type. -
:int8
,:uint8
,:int16
,:uint16
,:int32
,:uint32
,:int64
,:uint64
: signed or unsigned integers of the indicated size. -
:float
,:double
. Self-explanatory. -
:char
,:uchar
,:schar
,:ushort
,:short
,:uint
,:int
,:ulong
,:long
,:ulonglong
,:longlong
. Signed or unsigned integers corresponding to the C type of the same name.:char
is treated specially because whether it is signed or unsigned is platform-dependent (and also command-line-argument-dependent, though normally this doesn't matter). -
:pointer
. A C pointer type. Pointers currently aren't typed, in the sense that they aren't differentiated based on what they point to. -
:size_t
,:ssize_t
,:ptrdiff_t
,:wchar_t
. These correspond to the C type of the same name and internally are just aliases for one of the other integral types. -
:bool
. Booleans are treated in a Lisp style. As an argument type,nil
is converted to a Cfalse
value, and other Lisp values are converted totrue
. As a return type,true
is converted tot
andfalse
is converted tonil
. Note that0
is not converted tofalse
. If you want a "numeric" boolean type, you can use the size and alignment to find the corresponding primitive type and use that instead.
Structure types are represented by a user-pointer object that wraps an
ffi_type
. The best way to manipulate structures is to use
define-ffi-struct
, which is a limited form of cl-defstruct
that
works on foreign objects directly.
A structure object is also represented by a user-pointer object. If a
function's return type is a structure type, then the object allocated
by the FFI will automatically be reclaimed by the garbage collector --
there is no need to explicitly free it. (Contrast this with the
behavior of ffi-make-c-string
, which requires an explicit free.)
Currently all type conversions work the same in both directions.
-
A function declared with a
:void
return type will always returnnil
to Lisp. -
A function returning any integer or character type will return a Lisp integer. Note that this may result in the value being truncated; currently there is nothing that can be done about this.
-
A C pointer will be returned as a user-pointer (a new Lisp type introduced by the dynamic module patch).
-
A structure is also represented as a user-pointer. When a structure is returned by value from a foreign function, the resulting user-pointer will have a finalizer attached that will free the memory when the user-pointer is garbage collected.
-
(define-ffi-library SYMBOL NAME)
. Used to define a function that lazily loads a library. Like:(define-ffi-library libwhatever "libwhatever")
ffi-module uses libltdl (from libtool), which will automatically supply the correct extension if none is specified, so it's generally best to leave off the
.so
. -
(define-ffi-function NAME C-NAME RETURN-TYPE ARG-TYPES LIBRARY)
.A macro that defines a new Lisp function. It takes as many arguments as were in ARG-TYPES. (While there is internal support for varargs functions, it is not exposed by
define-ffi-function
.)NAME is the symbol to define. C-NAME is a string, the name of the underlying C function.
RETURN-TYPE describes the return type of the C function and ARG-TYPES describes the argument types. ARG-TYPES may be a vector or a list.
LIBRARY is the library where the C function should be found. This is just a symbol, most usually defined with
define-ffi-library
. -
(ffi-lambda FUNCTION RETURN-TYPE ARG-TYPES)
. Take a C function pointer and a description of its type, and return a Lisp function. Unlikedefine-ffi-function
, this is not a macro. You may wish to cache these as each call toffi-lambda
makes a new CIF. -
(ffi-make-closure CIF FUNCTION)
. Make a C pointer to the Lisp function. This pointer can then be passed to C functions that need a pointer-to-function argument, and FUNCTION will be called with whatever arguments are passed in.CIF is a CIF as returned by
ffi--prep-cif
. It describes the function's type (as needed by C).This returns a C function pointer, wrapped in the usual way as a user-pointer object.
-
(ffi-get-c-string POINTER)
. Assume the pointer points to a C string, and return a Lisp string with those contents. -
(ffi-make-c-string STRING)
. Allocate a C string with the same contents as the given Lisp string. Note that the memory allocated by this must be freed by the caller. It is done this way so that Lisp code has the option of transferring ownership of the pointer to some C code. -
(define-ffi-struct NAME &rest SLOT...)
. A limited form ofcl-defstruct
that works on foreign objects. This defines a new foreign structure type named NAME. Each SLOT is of the form(SLOT-NAME :type TYPE)
. Each TYPE must be a foreign type.define-ffi-struct
makes accessors for each slot of the formNAME-SLOT-NAME
.setf
works on these accessors. -
(define-ffi-union NAME &rest SLOT...)
. Likedefine-ffi-struct
, but defines a union. -
(ffi-pointer+ POINTER NUMBER)
. Pointer math in Lisp. -
(ffi-pointer-null-p POINTER)
. Returnt
if the argument is a null pointer. If the argument is not a pointer or is not null, returnnil
. -
(ffi-pointer= POINTER1 POINTER2)
. Returnt
if the two pointers are equal,nil
if not. -
(ffi-allocate TYPE-OR-NUMBER)
. Allocate some memory. If a type is given, allocates according to the type's size. If a number is given, allocates that many bytes. The returned memory will not be automatically reclaimed; you must useffi-free
for that. -
(ffi-free POINTER)
. Free some memory allocated withffi-allocate
orffi-make-c-string
.
-
(ffi--dlopen STR)
. A simple wrapper fordlopen
(actuallylt_dlopen
). This returns the library handle, a C pointer. -
(ffi--dlsym STR HANDLE)
. A simple wrapper fordlsym
(actuallylt_dlsym
). This finds the C symbol named STR in a library. HANDLE is a library handle, as returned by a function defined bydefine-ffi-library
.This returns a C pointer to the indicated symbol, or
nil
if it can't be found. These pointers need not be freed. -
(ffi--prep-cif RETURN-TYPE ARG-TYPES &optional N-FIXED-ARGS)
. A simple wrapper for libffi'sffi_prep_cif
andffi_prep_cif_var
. RETURN-TYPE is the return type; ARG-TYPES is a vector of argument types. If given, N-FIXED-ARGS is an integer holding the number of fixed args. Its presence, even if 0, means that a varargs call is being made. This function returns a C pointer wrapped in a Lisp object; the garbage collector will handle any needed finalization. -
(ffi--call CIF FUNCTION &rest ARG...)
. Make an FFI call.CIF is the return from
ffi--prep-cif
.FUNCTION is a C pointer to the function to call, normally from
ffi--dlsym
.ARGS are the arguments to pass to FUNCTION.
-
(ffi--mem-ref POINTER TYPE)
. Read memory from POINTER and convert it, using the usual conversions, as the given type. This is the Lisp equivalent of*pointer
in C. -
(ffi--mem-set POINTER TYPE VALUE)
. Copy the Lisp value to the memory pointed at by the pointer, using the type to guide the conversion. This is the Lisp equivalent of*pointer = value
in C. -
(ffi--type-size TYPE)
. Return the size of TYPE. -
(ffi--type-alignment TYPE)
. Return the alignment needed by TYPE. -
(ffi--define-struct &rest TYPE...)
. Define a new foreign structure type, whose fields are the indicated types. -
(ffi--define-union &rest TYPE...)
. Define a new foreign union type, whose fields are the indicated types.
- See the github issues.