An FFI closure wrapper, for handling callbacks.
closure = Class.new(Fiddle::Closure) { def call 10 end }.new(Fiddle::TYPE_INT, []) #=> #<#<Class:0x0000000150d308>:0x0000000150d240> func = Fiddle::Function.new(closure, [], Fiddle::TYPE_INT) #=> #<Fiddle::Function:0x00000001516e58> func.call #=> 10
Construct a new Closure object.
ret
is the C type to be returned
args
is an Array of arguments, passed to the callback function
abi
is the abi of the closure
If there is an error in preparing the ffi_cif or ffi_prep_closure, then a RuntimeError will be raised.
static VALUE initialize(int rbargc, VALUE argv[], VALUE self) { VALUE ret; VALUE args; VALUE abi; fiddle_closure * cl; ffi_cif * cif; ffi_closure *pcl; ffi_status result; int i, argc; if (2 == rb_scan_args(rbargc, argv, "21", &ret, &args, &abi)) abi = INT2NUM(FFI_DEFAULT_ABI); Check_Type(args, T_ARRAY); argc = RARRAY_LENINT(args); TypedData_Get_Struct(self, fiddle_closure, &closure_data_type, cl); cl->argv = (ffi_type **)xcalloc(argc + 1, sizeof(ffi_type *)); for (i = 0; i < argc; i++) { int type = NUM2INT(RARRAY_AREF(args, i)); cl->argv[i] = INT2FFI_TYPE(type); } cl->argv[argc] = NULL; rb_iv_set(self, "@ctype", ret); rb_iv_set(self, "@args", args); cif = &cl->cif; pcl = cl->pcl; result = ffi_prep_cif(cif, NUM2INT(abi), argc, INT2FFI_TYPE(NUM2INT(ret)), cl->argv); if (FFI_OK != result) rb_raise(rb_eRuntimeError, "error prepping CIF %d", result); #if USE_FFI_CLOSURE_ALLOC result = ffi_prep_closure_loc(pcl, cif, callback, (void *)self, cl->code); #else result = ffi_prep_closure(pcl, cif, callback, (void *)self); cl->code = (void *)pcl; i = mprotect(pcl, sizeof(*pcl), PROT_READ | PROT_EXEC); if (i) { rb_sys_fail("mprotect"); } #endif if (FFI_OK != result) rb_raise(rb_eRuntimeError, "error prepping closure %d", result); return self; }