// included by glib2.pas {$IFDEF read_forward_definitions} PGTypeCValue = ^TGTypeCValue; {$ENDIF read_forward_definitions} //------------------------------------------------------------------------------ {$IFDEF read_interface_types} TGTypeCValue = record case longint of 0 : ( v_int : gint ); 1 : ( v_long : glong ); 2 : ( v_int64 : gint64 ); 3 : ( v_double : gdouble ); 4 : ( v_pointer : gpointer ); end; {$ENDIF read_interface_types} //------------------------------------------------------------------------------ {$IFDEF read_interface_rest} { we may want to add aggregate types here some day, if requested by users. the basic C types are covered already, everything smaller than an int is promoted to an integer and floats are always promoted to doubles for varargs call constructions. } {< skip > } const G_VALUE_COLLECT_INT = 'i'; G_VALUE_COLLECT_LONG = 'l'; G_VALUE_COLLECT_INT64 = 'q'; G_VALUE_COLLECT_DOUBLE = 'd'; G_VALUE_COLLECT_POINTER = 'p'; { G_VALUE_COLLECT() collects a variable argument value from a va_list. we have to implement the varargs collection as a macro, because on some systems va_list variables cannot be passed by reference. value is supposed to be initialized according to the value type to be collected. var_args is the va_list variable and may be evaluated multiple times. __error is a gchar variable that will be modified to hold a g_new() allocated error messages if something fails. } (* ToDo: #define G_VALUE_COLLECT(value, var_args, flags, __error) \ G_STMT_START { \ GValue _value = (value); \ guint _flags = (flags); \ GType _value_type = G_VALUE_TYPE (_value); \ GTypeValueTable _vtable = g_type_value_table_peek (_value_type); \ gchar _collect_format = _vtable->collect_format; \ GTypeCValue _cvalues[G_VALUE_COLLECT_FORMAT_MAX_LENGTH] = { { 0, }, }; \ guint _n_values = 0; \ \ if (_vtable->value_free) \ _vtable->value_free (_value); \ _value->g_type = _value_type; // value_meminit() from gvalue.c \ memset (_value->data, 0, sizeof (_value->data)); \ while ( _collect_format) \ { \ GTypeCValue _cvalue = _cvalues + _n_values++; \ \ switch ( _collect_format++) \ { \ case G_VALUE_COLLECT_INT: \ _cvalue->v_int = va_arg ((var_args), gint); \ break; \ case G_VALUE_COLLECT_LONG: \ _cvalue->v_long = va_arg ((var_args), glong); \ break; \ case G_VALUE_COLLECT_INT64: \ _cvalue->v_int64 = va_arg ((var_args), gint64); \ break; \ case G_VALUE_COLLECT_DOUBLE: \ _cvalue->v_double = va_arg ((var_args), gdouble); \ break; \ case G_VALUE_COLLECT_POINTER: \ _cvalue->v_pointer = va_arg ((var_args), gpointer); \ break; \ default: \ g_assert_not_reached (); \ } \ } \ (__error) = _vtable->collect_value (_value, \ _n_values, \ _cvalues, \ _flags); \ } G_STMT_END *) { G_VALUE_LCOPY() collects a value's variable argument locations from a va_list. usage is analogous to G_VALUE_COLLECT(). } (* ToDo: #define G_VALUE_LCOPY(value, var_args, flags, __error) \ G_STMT_START { \ const GValue _value = (value); \ guint _flags = (flags); \ GType _value_type = G_VALUE_TYPE (_value); \ GTypeValueTable _vtable = g_type_value_table_peek (_value_type); \ gchar _lcopy_format = _vtable->lcopy_format; \ GTypeCValue _cvalues[G_VALUE_COLLECT_FORMAT_MAX_LENGTH] = { { 0, }, }; \ guint _n_values = 0; \ \ while ( _lcopy_format) \ { \ GTypeCValue _cvalue = _cvalues + _n_values++; \ \ switch ( _lcopy_format++) \ { \ case G_VALUE_COLLECT_INT: \ _cvalue->v_int = va_arg ((var_args), gint); \ break; \ case G_VALUE_COLLECT_LONG: \ _cvalue->v_long = va_arg ((var_args), glong); \ break; \ case G_VALUE_COLLECT_INT64: \ _cvalue->v_int64 = va_arg ((var_args), gint64); \ break; \ case G_VALUE_COLLECT_DOUBLE: \ _cvalue->v_double = va_arg ((var_args), gdouble); \ break; \ case G_VALUE_COLLECT_POINTER: \ _cvalue->v_pointer = va_arg ((var_args), gpointer); \ break; \ default: \ g_assert_not_reached (); \ } \ } \ (__error) = _vtable->lcopy_value (_value, \ _n_values, \ _cvalues, \ _flags); \ } G_STMT_END *) const G_VALUE_COLLECT_FORMAT_MAX_LENGTH = 8; {$ENDIF read_interface_rest} // included by glib2.pas