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android / platform / external / bluetooth / glib.git / refs/tags/upstream/2.79.2 / . / girepository / gicallableinfo.c
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/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*-
* GObject introspection: Callable implementation
*
* Copyright (C) 2005 Matthias Clasen
* Copyright (C) 2008,2009 Red Hat, Inc.
*
* SPDX-License-Identifier: LGPL-2.1-or-later
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
#include "config.h"
#include <stdlib.h>
#include <glib.h>
#include <girepository/girepository.h>
#include "gibaseinfo-private.h"
#include "girepository-private.h"
#include "gitypelib-internal.h"
#include "girffi.h"
#include "gicallableinfo.h"
/* GICallableInfo functions */
/**
* GICallableInfo:
*
* `GICallableInfo` represents an entity which is callable.
*
* Examples of callable are:
*
* - functions ([class@GIRepository.FunctionInfo])
* - virtual functions ([class@GIRepository.VFuncInfo])
* - callbacks ([class@GIRepository.CallbackInfo]).
*
* A callable has a list of arguments ([class@GIRepository.ArgInfo]), a return
* type, direction and a flag which decides if it returns `NULL`.
*
* Since: 2.80
*/
static uint32_t
signature_offset (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo*)info;
int sigoff = -1;
switch (gi_base_info_get_info_type ((GIBaseInfo *) info))
{
case GI_INFO_TYPE_FUNCTION:
sigoff = G_STRUCT_OFFSET (FunctionBlob, signature);
break;
case GI_INFO_TYPE_VFUNC:
sigoff = G_STRUCT_OFFSET (VFuncBlob, signature);
break;
case GI_INFO_TYPE_CALLBACK:
sigoff = G_STRUCT_OFFSET (CallbackBlob, signature);
break;
case GI_INFO_TYPE_SIGNAL:
sigoff = G_STRUCT_OFFSET (SignalBlob, signature);
break;
default:
g_assert_not_reached ();
}
if (sigoff >= 0)
return *(uint32_t *)&rinfo->typelib->data[rinfo->offset + sigoff];
return 0;
}
/**
* gi_callable_info_can_throw_gerror:
* @info: a #GICallableInfo
*
* Whether the callable can throw a [type@GLib.Error]
*
* Returns: `TRUE` if this `GICallableInfo` can throw a [type@GLib.Error]
* Since: 2.80
*/
gboolean
gi_callable_info_can_throw_gerror (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo*)info;
SignatureBlob *signature;
signature = (SignatureBlob *)&rinfo->typelib->data[signature_offset (info)];
if (signature->throws)
return TRUE;
/* Functions and VFuncs store "throws" in their own blobs.
* This info was additionally added to the SignatureBlob
* to support the other callables. For Functions and VFuncs,
* also check their legacy flag for compatibility.
*/
switch (gi_base_info_get_info_type ((GIBaseInfo *) info)) {
case GI_INFO_TYPE_FUNCTION:
{
FunctionBlob *blob;
blob = (FunctionBlob *)&rinfo->typelib->data[rinfo->offset];
return blob->throws;
}
case GI_INFO_TYPE_VFUNC:
{
VFuncBlob *blob;
blob = (VFuncBlob *)&rinfo->typelib->data[rinfo->offset];
return blob->throws;
}
case GI_INFO_TYPE_CALLBACK:
case GI_INFO_TYPE_SIGNAL:
return FALSE;
default:
g_assert_not_reached ();
}
}
/**
* gi_callable_info_is_method:
* @info: a #GICallableInfo
*
* Determines if the callable info is a method.
*
* For [class@GIRepository.VFuncInfo]s, [class@GIRepository.CallbackInfo]s, and
* [class@GIRepository.SignalInfo]s, this is always true. Otherwise, this looks
* at the `GI_FUNCTION_IS_METHOD` flag on the [class@GIRepository.FunctionInfo].
*
* Concretely, this function returns whether
* [method@GIRepository.CallableInfo.get_n_args] matches the number of arguments
* in the raw C method. For methods, there is one more C argument than is
* exposed by introspection: the `self` or `this` object.
*
* Returns: `TRUE` if @info is a method, `FALSE` otherwise
* Since: 2.80
*/
gboolean
gi_callable_info_is_method (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo*)info;
switch (gi_base_info_get_info_type ((GIBaseInfo *) info)) {
case GI_INFO_TYPE_FUNCTION:
{
FunctionBlob *blob;
blob = (FunctionBlob *)&rinfo->typelib->data[rinfo->offset];
return (!blob->constructor && !blob->is_static);
}
case GI_INFO_TYPE_VFUNC:
case GI_INFO_TYPE_SIGNAL:
return TRUE;
case GI_INFO_TYPE_CALLBACK:
return FALSE;
default:
g_assert_not_reached ();
}
}
/**
* gi_callable_info_get_return_type:
* @info: a #GICallableInfo
*
* Obtain the return type of a callable item as a [class@GIRepository.TypeInfo].
*
* If the callable doesn’t return anything, a [class@GIRepository.TypeInfo] of
* type [enum@GIRepository.TypeTag.VOID] will be returned.
*
* Returns: (transfer full): the [class@GIRepository.TypeInfo]. Free the struct
* by calling [method@GIRepository.BaseInfo.unref] when done.
* Since: 2.80
*/
GITypeInfo *
gi_callable_info_get_return_type (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
uint32_t offset;
g_return_val_if_fail (info != NULL, NULL);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), NULL);
offset = signature_offset (info);
return gi_type_info_new ((GIBaseInfo*)info, rinfo->typelib, offset);
}
/**
* gi_callable_info_load_return_type:
* @info: a #GICallableInfo
* @type: (out caller-allocates): Initialized with return type of @info
*
* Obtain information about a return value of callable; this
* function is a variant of [method@GIRepository.CallableInfo.get_return_type]
* designed for stack allocation.
*
* The initialized @type must not be referenced after @info is deallocated.
*
* Once you are done with @type, it must be cleared using
* [method@GIRepository.BaseInfo.clear].
*
* Since: 2.80
*/
void
gi_callable_info_load_return_type (GICallableInfo *info,
GITypeInfo *type)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
uint32_t offset;
g_return_if_fail (info != NULL);
g_return_if_fail (GI_IS_CALLABLE_INFO (info));
offset = signature_offset (info);
gi_type_info_init (type, (GIBaseInfo*)info, rinfo->typelib, offset);
}
/**
* gi_callable_info_may_return_null:
* @info: a #GICallableInfo
*
* See if a callable could return `NULL`.
*
* Returns: `TRUE` if callable could return `NULL`
* Since: 2.80
*/
gboolean
gi_callable_info_may_return_null (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
SignatureBlob *blob;
g_return_val_if_fail (info != NULL, FALSE);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), FALSE);
blob = (SignatureBlob *)&rinfo->typelib->data[signature_offset (info)];
return blob->may_return_null;
}
/**
* gi_callable_info_skip_return:
* @info: a #GICallableInfo
*
* See if a callable’s return value is only useful in C.
*
* Returns: `TRUE` if return value is only useful in C.
* Since: 2.80
*/
gboolean
gi_callable_info_skip_return (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
SignatureBlob *blob;
g_return_val_if_fail (info != NULL, FALSE);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), FALSE);
blob = (SignatureBlob *)&rinfo->typelib->data[signature_offset (info)];
return blob->skip_return;
}
/**
* gi_callable_info_get_caller_owns:
* @info: a #GICallableInfo
*
* See whether the caller owns the return value of this callable.
*
* [type@GIRepository.Transfer] contains a list of possible transfer values.
*
* Returns: the transfer mode for the return value of the callable
* Since: 2.80
*/
GITransfer
gi_callable_info_get_caller_owns (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo*) info;
SignatureBlob *blob;
g_return_val_if_fail (info != NULL, -1);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), -1);
blob = (SignatureBlob *)&rinfo->typelib->data[signature_offset (info)];
if (blob->caller_owns_return_value)
return GI_TRANSFER_EVERYTHING;
else if (blob->caller_owns_return_container)
return GI_TRANSFER_CONTAINER;
else
return GI_TRANSFER_NOTHING;
}
/**
* gi_callable_info_get_instance_ownership_transfer:
* @info: a #GICallableInfo
*
* Obtains the ownership transfer for the instance argument.
*
* [type@GIRepository.Transfer] contains a list of possible transfer values.
*
* Returns: the transfer mode of the instance argument
* Since: 2.80
*/
GITransfer
gi_callable_info_get_instance_ownership_transfer (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo*) info;
SignatureBlob *blob;
g_return_val_if_fail (info != NULL, -1);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), -1);
blob = (SignatureBlob *)&rinfo->typelib->data[signature_offset (info)];
if (blob->instance_transfer_ownership)
return GI_TRANSFER_EVERYTHING;
else
return GI_TRANSFER_NOTHING;
}
/**
* gi_callable_info_get_n_args:
* @info: a #GICallableInfo
*
* Obtain the number of arguments (both ‘in’ and ‘out’) for this callable.
*
* Returns: The number of arguments this callable expects.
* Since: 2.80
*/
unsigned int
gi_callable_info_get_n_args (GICallableInfo *info)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
uint32_t offset;
SignatureBlob *blob;
g_return_val_if_fail (info != NULL, -1);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), -1);
offset = signature_offset (info);
blob = (SignatureBlob *)&rinfo->typelib->data[offset];
return blob->n_arguments;
}
/**
* gi_callable_info_get_arg:
* @info: a #GICallableInfo
* @n: the argument index to fetch
*
* Obtain information about a particular argument of this callable.
*
* Returns: (transfer full): the [class@GIRepository.ArgInfo]. Free it with
* [method@GIRepository.BaseInfo.unref] when done.
* Since: 2.80
*/
GIArgInfo *
gi_callable_info_get_arg (GICallableInfo *info,
unsigned int n)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
Header *header;
uint32_t offset;
g_return_val_if_fail (info != NULL, NULL);
g_return_val_if_fail (GI_IS_CALLABLE_INFO (info), NULL);
g_return_val_if_fail (n <= G_MAXUINT16, NULL);
offset = signature_offset (info);
header = (Header *)rinfo->typelib->data;
return (GIArgInfo *) gi_base_info_new (GI_INFO_TYPE_ARG, (GIBaseInfo*)info, rinfo->typelib,
offset + header->signature_blob_size + n * header->arg_blob_size);
}
/**
* gi_callable_info_load_arg:
* @info: a #GICallableInfo
* @n: the argument index to fetch
* @arg: (out caller-allocates): Initialize with argument number @n
*
* Obtain information about a particular argument of this callable; this
* function is a variant of [method@GIRepository.CallableInfo.get_arg] designed
* for stack allocation.
*
* The initialized @arg must not be referenced after @info is deallocated.
*
* Once you are done with @arg, it must be cleared using
* [method@GIRepository.BaseInfo.clear].
*
* Since: 2.80
*/
void
gi_callable_info_load_arg (GICallableInfo *info,
unsigned int n,
GIArgInfo *arg)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
Header *header;
uint32_t offset;
g_return_if_fail (info != NULL);
g_return_if_fail (GI_IS_CALLABLE_INFO (info));
g_return_if_fail (n <= G_MAXUINT16);
offset = signature_offset (info);
header = (Header *)rinfo->typelib->data;
gi_info_init ((GIRealInfo*)arg, GI_TYPE_ARG_INFO, rinfo->repository, (GIBaseInfo*)info, rinfo->typelib,
offset + header->signature_blob_size + n * header->arg_blob_size);
}
/**
* gi_callable_info_get_return_attribute:
* @info: a #GICallableInfo
* @name: a freeform string naming an attribute
*
* Retrieve an arbitrary attribute associated with the return value.
*
* Returns: (nullable): The value of the attribute, or `NULL` if no such
* attribute exists
* Since: 2.80
*/
const char *
gi_callable_info_get_return_attribute (GICallableInfo *info,
const char *name)
{
GIAttributeIter iter = GI_ATTRIBUTE_ITER_INIT;
const char *curname, *curvalue;
while (gi_callable_info_iterate_return_attributes (info, &iter, &curname, &curvalue))
{
if (g_strcmp0 (name, curname) == 0)
return (const char*) curvalue;
}
return NULL;
}
/**
* gi_callable_info_iterate_return_attributes:
* @info: a #GICallableInfo
* @iterator: (inout): a [type@GIRepository.AttributeIter] structure, must be
* initialized; see below
* @name: (out) (transfer none): Returned name, must not be freed
* @value: (out) (transfer none): Returned name, must not be freed
*
* Iterate over all attributes associated with the return value.
*
* The iterator structure is typically stack allocated, and must have its
* first member initialized to `NULL`.
*
* Both the @name and @value should be treated as constants
* and must not be freed.
*
* See [method@GIRepository.BaseInfo.iterate_attributes] for an example of how
* to use a similar API.
*
* Returns: `TRUE` if there are more attributes
* Since: 2.80
*/
gboolean
gi_callable_info_iterate_return_attributes (GICallableInfo *info,
GIAttributeIter *iterator,
const char **name,
const char **value)
{
GIRealInfo *rinfo = (GIRealInfo *)info;
Header *header = (Header *)rinfo->typelib->data;
AttributeBlob *next, *after;
uint32_t blob_offset;
after = (AttributeBlob *) &rinfo->typelib->data[header->attributes +
header->n_attributes * header->attribute_blob_size];
blob_offset = signature_offset (info);
if (iterator->data != NULL)
next = (AttributeBlob *) iterator->data;
else
next = _attribute_blob_find_first ((GIBaseInfo *) info, blob_offset);
if (next == NULL || next->offset != blob_offset || next >= after)
return FALSE;
*name = gi_typelib_get_string (rinfo->typelib, next->name);
*value = gi_typelib_get_string (rinfo->typelib, next->value);
iterator->data = next + 1;
return TRUE;
}
/**
* gi_type_tag_extract_ffi_return_value:
* @return_tag: [type@GIRepository.TypeTag] of the return value
* @interface_type: [type@GObject.Type] of the underlying interface type
* @ffi_value: pointer to [type@GIRepository.FFIReturnValue] union containing
* the return value from `ffi_call()`
* @arg: (out caller-allocates): pointer to an allocated
* [class@GIRepository.Argument]
*
* Extract the correct bits from an `ffi_arg` return value into
* [class@GIRepository.Argument].
*
* See: https://bugzilla.gnome.org/show_bug.cgi?id=665152
*
* Also see [`ffi_call()`](man:ffi_call(3)): the storage requirements for return
* values are ‘special’.
*
* The @interface_type argument only applies if @return_tag is
* `GI_TYPE_TAG_INTERFACE`. Otherwise it is ignored.
*
* Since: 2.80
*/
void
gi_type_tag_extract_ffi_return_value (GITypeTag return_tag,
GType interface_type,
GIFFIReturnValue *ffi_value,
GIArgument *arg)
{
switch (return_tag) {
case GI_TYPE_TAG_INT8:
arg->v_int8 = (int8_t) ffi_value->v_long;
break;
case GI_TYPE_TAG_UINT8:
arg->v_uint8 = (uint8_t) ffi_value->v_ulong;
break;
case GI_TYPE_TAG_INT16:
arg->v_int16 = (int16_t) ffi_value->v_long;
break;
case GI_TYPE_TAG_UINT16:
arg->v_uint16 = (uint16_t) ffi_value->v_ulong;
break;
case GI_TYPE_TAG_INT32:
arg->v_int32 = (int32_t) ffi_value->v_long;
break;
case GI_TYPE_TAG_UINT32:
case GI_TYPE_TAG_BOOLEAN:
case GI_TYPE_TAG_UNICHAR:
arg->v_uint32 = (uint32_t) ffi_value->v_ulong;
break;
case GI_TYPE_TAG_INT64:
arg->v_int64 = (int64_t) ffi_value->v_int64;
break;
case GI_TYPE_TAG_UINT64:
arg->v_uint64 = (uint64_t) ffi_value->v_uint64;
break;
case GI_TYPE_TAG_FLOAT:
arg->v_float = ffi_value->v_float;
break;
case GI_TYPE_TAG_DOUBLE:
arg->v_double = ffi_value->v_double;
break;
case GI_TYPE_TAG_INTERFACE:
if (interface_type == GI_TYPE_ENUM_INFO ||
interface_type == GI_TYPE_FLAGS_INFO)
arg->v_int32 = (int32_t) ffi_value->v_long;
else
arg->v_pointer = (void *) ffi_value->v_pointer;
break;
default:
arg->v_pointer = (void *) ffi_value->v_pointer;
break;
}
}
/**
* gi_type_info_extract_ffi_return_value:
* @return_info: [type@GIRepository.TypeInfo] describing the return type
* @ffi_value: pointer to [type@GIRepository.FFIReturnValue] union containing
* the return value from `ffi_call()`
* @arg: (out caller-allocates): pointer to an allocated
* [class@GIRepository.Argument]
*
* Extract the correct bits from an `ffi_arg` return value into
* [class@GIRepository.Argument].
*
* See: https://bugzilla.gnome.org/show_bug.cgi?id=665152
*
* Also see [`ffi_call()`](man:ffi_call(3)): the storage requirements for return
* values are ‘special’.
*
* Since: 2.80
*/
void
gi_type_info_extract_ffi_return_value (GITypeInfo *return_info,
GIFFIReturnValue *ffi_value,
GIArgument *arg)
{
GITypeTag return_tag = gi_type_info_get_tag (return_info);
GType interface_type = G_TYPE_INVALID;
if (return_tag == GI_TYPE_TAG_INTERFACE)
{
GIBaseInfo *interface_info = gi_type_info_get_interface (return_info);
interface_type = G_TYPE_FROM_INSTANCE (interface_info);
gi_base_info_unref (interface_info);
}
gi_type_tag_extract_ffi_return_value (return_tag, interface_type,
ffi_value, arg);
}
/**
* gi_callable_info_invoke:
* @info: a #GICallableInfo
* @function: function pointer to call
* @in_args: (array length=n_in_args): array of ‘in’ arguments
* @n_in_args: number of arguments in @in_args
* @out_args: (array length=n_out_args): array of ‘out’ arguments allocated by
* the caller, to be populated with outputted values
* @n_out_args: number of arguments in @out_args
* @return_value: (out caller-allocates) (not optional) (nullable): return
* location for the return value from the callable; `NULL` may be returned if
* the callable returns that
* @error: return location for a [type@GLib.Error], or `NULL`
*
* Invoke the given `GICallableInfo` by calling the given @function pointer.
*
* The set of arguments passed to @function will be constructed according to the
* introspected type of the `GICallableInfo`, using @in_args, @out_args
* and @error.
*
* Returns: `TRUE` if the callable was executed successfully and didn’t throw
* a [type@GLib.Error]; `FALSE` if @error is set
* Since: 2.80
*/
gboolean
gi_callable_info_invoke (GICallableInfo *info,
void *function,
const GIArgument *in_args,
size_t n_in_args,
GIArgument *out_args,
size_t n_out_args,
GIArgument *return_value,
GError **error)
{
ffi_cif cif;
ffi_type *rtype;
ffi_type **atypes;
GITypeInfo *tinfo;
GITypeInfo *rinfo;
GITypeTag rtag;
GIArgInfo *ainfo;
size_t n_args, n_invoke_args, in_pos, out_pos, i;
void **args;
gboolean success = FALSE;
GError *local_error = NULL;
void *error_address = &local_error;
GIFFIReturnValue ffi_return_value;
void *return_value_p; /* Will point inside the union return_value */
gboolean is_method, throws;
rinfo = gi_callable_info_get_return_type ((GICallableInfo *)info);
rtype = gi_type_info_get_ffi_type (rinfo);
rtag = gi_type_info_get_tag(rinfo);
is_method = gi_callable_info_is_method (info);
throws = gi_callable_info_can_throw_gerror (info);
in_pos = 0;
out_pos = 0;
n_args = gi_callable_info_get_n_args ((GICallableInfo *)info);
if (is_method)
{
if (n_in_args == 0)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too few \"in\" arguments (handling this)");
goto out;
}
n_invoke_args = n_args+1;
in_pos++;
}
else
n_invoke_args = n_args;
if (throws)
/* Add an argument for the GError */
n_invoke_args ++;
atypes = g_alloca (sizeof (ffi_type*) * n_invoke_args);
args = g_alloca (sizeof (void *) * n_invoke_args);
if (is_method)
{
atypes[0] = &ffi_type_pointer;
args[0] = (void *) &in_args[0];
}
for (i = 0; i < n_args; i++)
{
int offset = (is_method ? 1 : 0);
ainfo = gi_callable_info_get_arg ((GICallableInfo *)info, i);
switch (gi_arg_info_get_direction (ainfo))
{
case GI_DIRECTION_IN:
tinfo = gi_arg_info_get_type_info (ainfo);
atypes[i+offset] = gi_type_info_get_ffi_type (tinfo);
gi_base_info_unref ((GIBaseInfo *)ainfo);
gi_base_info_unref ((GIBaseInfo *)tinfo);
if (in_pos >= n_in_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too few \"in\" arguments (handling in)");
goto out;
}
args[i+offset] = (void *)&in_args[in_pos];
in_pos++;
break;
case GI_DIRECTION_OUT:
atypes[i+offset] = &ffi_type_pointer;
gi_base_info_unref ((GIBaseInfo *)ainfo);
if (out_pos >= n_out_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too few \"out\" arguments (handling out)");
goto out;
}
args[i+offset] = (void *)&out_args[out_pos];
out_pos++;
break;
case GI_DIRECTION_INOUT:
atypes[i+offset] = &ffi_type_pointer;
gi_base_info_unref ((GIBaseInfo *)ainfo);
if (in_pos >= n_in_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too few \"in\" arguments (handling inout)");
goto out;
}
if (out_pos >= n_out_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too few \"out\" arguments (handling inout)");
goto out;
}
args[i+offset] = (void *)&in_args[in_pos];
in_pos++;
out_pos++;
break;
default:
gi_base_info_unref ((GIBaseInfo *)ainfo);
g_assert_not_reached ();
}
}
if (throws)
{
args[n_invoke_args - 1] = &error_address;
atypes[n_invoke_args - 1] = &ffi_type_pointer;
}
if (in_pos < n_in_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too many \"in\" arguments (at end)");
goto out;
}
if (out_pos < n_out_args)
{
g_set_error (error,
GI_INVOKE_ERROR,
GI_INVOKE_ERROR_ARGUMENT_MISMATCH,
"Too many \"out\" arguments (at end)");
goto out;
}
if (ffi_prep_cif (&cif, FFI_DEFAULT_ABI, n_invoke_args, rtype, atypes) != FFI_OK)
goto out;
g_return_val_if_fail (return_value, FALSE);
/* See comment for GIFFIReturnValue above */
switch (rtag)
{
case GI_TYPE_TAG_FLOAT:
return_value_p = &ffi_return_value.v_float;
break;
case GI_TYPE_TAG_DOUBLE:
return_value_p = &ffi_return_value.v_double;
break;
case GI_TYPE_TAG_INT64:
case GI_TYPE_TAG_UINT64:
return_value_p = &ffi_return_value.v_uint64;
break;
default:
return_value_p = &ffi_return_value.v_long;
}
ffi_call (&cif, function, return_value_p, args);
if (local_error)
{
g_propagate_error (error, local_error);
success = FALSE;
}
else
{
gi_type_info_extract_ffi_return_value (rinfo, &ffi_return_value, return_value);
success = TRUE;
}
out:
gi_base_info_unref ((GIBaseInfo *)rinfo);
return success;
}
void
gi_callable_info_class_init (gpointer g_class,
gpointer class_data)
{
GIBaseInfoClass *info_class = g_class;
info_class->info_type = GI_INFO_TYPE_CALLABLE;
}