unsigned argc = _sig->nargs;
void **argv = _args;
ffi_arg *res = _result;
- decl *decl = _data;
- size_t i;
+ let_stmt *let;
+ decl_arg *darg = let->var->arg;
+ decl *decl_cb = darg->type->func;
+ let_callback *cb = let->val->data.callback;
+ impl_arg *iarg = cb->func->arg;
+ size_t i, argc = cb->args->count;
+ zval *argv = calloc(argc, sizeof(*argv));
// prepare args for the userland call
- for (i = 0; i < decl->args->count; ++i) {
+ for (i = 0; i < decl_cb->args->count; ++i) {
}
- // marshal return value of the userland call
- switch (decl->func->type->type) {
-
+ for (i = 0; i < cb->args->count; ++i) {
+ psi_do_set(&argv[i], cb->args->vals[i]);
}
+ zend_fcall_info_argp(iarg->val.zend.cb->fci, argc, argv);
+ // marshal return value of the userland call
+ darg->ptr = psi_let_val(cb->func->type, iarg, darg->ptr, real_decl_type(darg->type)->strct, &darg->mem);
}
static inline ffi_type *psi_ffi_decl_arg_type(decl_arg *darg);
PSI_LibffiCall *call = PSI_LibffiCallAlloc(&PSI_G(context), real->func);
ffi_status rc;
- rc = psi_ffi_prep_closure(&real->func->call.closure.data, &real->func->call.sym,
- &call->signature, psi_ffi_handler, NULL);
+ rc = psi_ffi_prep_closure(
+ (void *) &real->func->call.closure.data,
+ &real->func->call.sym, &call->signature, psi_ffi_handler, NULL);
if (FFI_OK == rc) {
real->func->call.info = call;
real->func->call.closure.dtor = psi_ffi_closure_free;