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d9be59e872f8a112f31b73f07fe41efb51a08ad9
blender-archive/source/blender/makesrna/intern/rna_access.c
Bastien Montagne 18f4182e98 LibOverride: Fixed bug in removing override op operator. 
In case the property is a RNA pointer, `RNA_path_resolve()` will try to
resolve it and return that pointer, instead of returning expected
container... That is a bad inconsistency in the rNA path API, but no
proper way to solve it for now...
2019-08-23 15:55:00 +02:00

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/*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
/** \file
* \ingroup RNA
*/
#include <stdlib.h>
#include <stddef.h>
#include <string.h>
#include <ctype.h>
#include "MEM_guardedalloc.h"
#include "DNA_ID.h"
#include "DNA_scene_types.h"
#include "DNA_constraint_types.h"
#include "DNA_modifier_types.h"
#include "DNA_windowmanager_types.h"
#include "BLI_blenlib.h"
#include "BLI_utildefines.h"
#include "BLI_dynstr.h"
#include "BLI_ghash.h"
#include "BLI_math.h"
#include "BLF_api.h"
#include "BLT_translation.h"
#include "BKE_animsys.h"
#include "BKE_context.h"
#include "BKE_idcode.h"
#include "BKE_idprop.h"
#include "BKE_fcurve.h"
#include "BKE_main.h"
#include "BKE_report.h"
#include "DEG_depsgraph.h"
#include "RNA_access.h"
#include "RNA_define.h"
#include "RNA_enum_types.h"
#include "WM_api.h"
#include "WM_message.h"
/* flush updates */
#include "DNA_object_types.h"
#include "WM_types.h"
#include "rna_internal.h"
#include "rna_access_internal.h"
const PointerRNA PointerRNA_NULL = {NULL};
/* Init/Exit */
void RNA_init(void)
{
StructRNA *srna;
PropertyRNA *prop;
BLENDER_RNA.structs_map = BLI_ghash_str_new_ex(__func__, 2048);
BLENDER_RNA.structs_len = 0;
for (srna = BLENDER_RNA.structs.first; srna; srna = srna->cont.next) {
if (!srna->cont.prophash) {
srna->cont.prophash = BLI_ghash_str_new("RNA_init gh");
for (prop = srna->cont.properties.first; prop; prop = prop->next) {
if (!(prop->flag_internal & PROP_INTERN_BUILTIN)) {
BLI_ghash_insert(srna->cont.prophash, (void *)prop->identifier, prop);
}
}
}
BLI_assert(srna->flag & STRUCT_PUBLIC_NAMESPACE);
BLI_ghash_insert(BLENDER_RNA.structs_map, (void *)srna->identifier, srna);
BLENDER_RNA.structs_len += 1;
}
}
void RNA_exit(void)
{
StructRNA *srna;
RNA_property_update_cache_free();
for (srna = BLENDER_RNA.structs.first; srna; srna = srna->cont.next) {
if (srna->cont.prophash) {
BLI_ghash_free(srna->cont.prophash, NULL, NULL);
srna->cont.prophash = NULL;
}
}
RNA_free(&BLENDER_RNA);
}
/* Pointer */
void RNA_main_pointer_create(struct Main *main, PointerRNA *r_ptr)
{
r_ptr->owner_id = NULL;
r_ptr->type = &RNA_BlendData;
r_ptr->data = main;
}
void RNA_id_pointer_create(ID *id, PointerRNA *r_ptr)
{
StructRNA *type, *idtype = NULL;
if (id) {
PointerRNA tmp = {NULL};
tmp.data = id;
idtype = rna_ID_refine(&tmp);
while (idtype->refine) {
type = idtype->refine(&tmp);
if (type == idtype) {
break;
}
else {
idtype = type;
}
}
}
r_ptr->owner_id = id;
r_ptr->type = idtype;
r_ptr->data = id;
}
void RNA_pointer_create(ID *id, StructRNA *type, void *data, PointerRNA *r_ptr)
{
#if 0 /* UNUSED */
StructRNA *idtype = NULL;
if (id) {
PointerRNA tmp = {0};
tmp.data = id;
idtype = rna_ID_refine(&tmp);
}
#endif
r_ptr->owner_id = id;
r_ptr->type = type;
r_ptr->data = data;
if (data) {
while (r_ptr->type && r_ptr->type->refine) {
StructRNA *rtype = r_ptr->type->refine(r_ptr);
if (rtype == r_ptr->type) {
break;
}
else {
r_ptr->type = rtype;
}
}
}
}
bool RNA_pointer_is_null(const PointerRNA *ptr)
{
return !((ptr->data != NULL) && (ptr->owner_id != NULL) && (ptr->type != NULL));
}
static void rna_pointer_inherit_id(StructRNA *type, PointerRNA *parent, PointerRNA *ptr)
{
if (type && type->flag & STRUCT_ID) {
ptr->owner_id = ptr->data;
}
else {
ptr->owner_id = parent->owner_id;
}
}
void RNA_blender_rna_pointer_create(PointerRNA *r_ptr)
{
r_ptr->owner_id = NULL;
r_ptr->type = &RNA_BlenderRNA;
r_ptr->data = &BLENDER_RNA;
}
PointerRNA rna_pointer_inherit_refine(PointerRNA *ptr, StructRNA *type, void *data)
{
if (data) {
PointerRNA result;
result.data = data;
result.type = type;
rna_pointer_inherit_id(type, ptr, &result);
while (result.type->refine) {
type = result.type->refine(&result);
if (type == result.type) {
break;
}
else {
result.type = type;
}
}
return result;
}
else {
return PointerRNA_NULL;
}
}
void RNA_pointer_recast(PointerRNA *ptr, PointerRNA *r_ptr)
{
#if 0 /* works but this case if covered by more general code below. */
if (RNA_struct_is_ID(ptr->type)) {
/* simple case */
RNA_id_pointer_create(ptr->owner_id, r_ptr);
}
else
#endif
{
StructRNA *base;
PointerRNA t_ptr;
*r_ptr = *ptr; /* initialize as the same in case cant recast */
for (base = ptr->type->base; base; base = base->base) {
t_ptr = rna_pointer_inherit_refine(ptr, base, ptr->data);
if (t_ptr.type && t_ptr.type != ptr->type) {
*r_ptr = t_ptr;
}
}
}
}
/* ID Properties */
void rna_idproperty_touch(IDProperty *idprop)
{
/* so the property is seen as 'set' by rna */
idprop->flag &= ~IDP_FLAG_GHOST;
}
static IDProperty *rna_idproperty_ui_container(PropertyRNA *prop)
{
IDProperty *idprop;
for (idprop = ((IDProperty *)prop)->prev; idprop; idprop = idprop->prev) {
if (STREQ(RNA_IDP_UI, idprop->name)) {
break;
}
}
if (idprop == NULL) {
for (idprop = ((IDProperty *)prop)->next; idprop; idprop = idprop->next) {
if (STREQ(RNA_IDP_UI, idprop->name)) {
break;
}
}
}
return idprop;
}
/* return a UI local ID prop definition for this prop */
static IDProperty *rna_idproperty_ui(PropertyRNA *prop)
{
IDProperty *idprop = rna_idproperty_ui_container(prop);
if (idprop) {
return IDP_GetPropertyTypeFromGroup(idprop, ((IDProperty *)prop)->name, IDP_GROUP);
}
return NULL;
}
/* return or create a UI local ID prop definition for this prop */
static IDProperty *rna_idproperty_ui_ensure(PointerRNA *ptr, PropertyRNA *prop, bool create)
{
IDProperty *idprop = rna_idproperty_ui_container(prop);
IDPropertyTemplate dummy = {0};
if (idprop == NULL && create) {
IDProperty *props = RNA_struct_idprops(ptr, false);
/* Sanity check: props is the actual container of this property. */
if (props != NULL && BLI_findindex(&props->data.group, prop) >= 0) {
idprop = IDP_New(IDP_GROUP, &dummy, RNA_IDP_UI);
if (!IDP_AddToGroup(props, idprop)) {
IDP_FreePropertyContent(idprop);
return NULL;
}
}
}
if (idprop) {
const char *name = ((IDProperty *)prop)->name;
IDProperty *rv = IDP_GetPropertyTypeFromGroup(idprop, name, IDP_GROUP);
if (rv == NULL && create) {
rv = IDP_New(IDP_GROUP, &dummy, name);
if (!IDP_AddToGroup(idprop, rv)) {
IDP_FreePropertyContent(rv);
return NULL;
}
}
return rv;
}
return NULL;
}
static bool rna_idproperty_ui_set_default(PointerRNA *ptr,
PropertyRNA *prop,
const char type,
IDPropertyTemplate *value)
{
BLI_assert(ELEM(type, IDP_INT, IDP_DOUBLE));
if (prop->magic == RNA_MAGIC) {
return false;
}
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui_ensure(ptr, prop, value != NULL);
if (idp_ui == NULL) {
return (value == NULL);
}
IDProperty *item = IDP_GetPropertyTypeFromGroup(idp_ui, "default", type);
if (value == NULL) {
if (item != NULL) {
IDP_RemoveFromGroup(idp_ui, item);
}
}
else {
if (item != NULL) {
switch (type) {
case IDP_INT:
IDP_Int(item) = value->i;
break;
case IDP_DOUBLE:
IDP_Double(item) = value->d;
break;
default:
BLI_assert(false);
return false;
}
}
else {
item = IDP_New(type, value, "default");
if (!IDP_AddToGroup(idp_ui, item)) {
IDP_FreePropertyContent(item);
return false;
}
}
}
return true;
}
IDProperty *RNA_struct_idprops(PointerRNA *ptr, bool create)
{
StructRNA *type = ptr->type;
if (type && type->idproperties) {
return type->idproperties(ptr, create);
}
return NULL;
}
bool RNA_struct_idprops_check(StructRNA *srna)
{
return (srna && srna->idproperties);
}
static IDProperty *rna_idproperty_find(PointerRNA *ptr, const char *name)
{
IDProperty *group = RNA_struct_idprops(ptr, 0);
if (group) {
if (group->type == IDP_GROUP) {
return IDP_GetPropertyFromGroup(group, name);
}
else {
/* Not sure why that happens sometimes, with nested properties... */
/* Seems to be actually array prop, name is usually "0"... To be sorted out later. */
#if 0
printf(
"Got unexpected IDProp container when trying to retrieve %s: %d\n", name, group->type);
#endif
}
}
return NULL;
}
static void rna_idproperty_free(PointerRNA *ptr, const char *name)
{
IDProperty *group = RNA_struct_idprops(ptr, 0);
if (group) {
IDProperty *idprop = IDP_GetPropertyFromGroup(group, name);
if (idprop) {
IDP_FreeFromGroup(group, idprop);
}
}
}
static int rna_ensure_property_array_length(PointerRNA *ptr, PropertyRNA *prop)
{
if (prop->magic == RNA_MAGIC) {
int arraylen[RNA_MAX_ARRAY_DIMENSION];
return (prop->getlength && ptr->data) ? prop->getlength(ptr, arraylen) : prop->totarraylength;
}
else {
IDProperty *idprop = (IDProperty *)prop;
if (idprop->type == IDP_ARRAY) {
return idprop->len;
}
else {
return 0;
}
}
}
static bool rna_ensure_property_array_check(PropertyRNA *prop)
{
if (prop->magic == RNA_MAGIC) {
return (prop->getlength || prop->totarraylength);
}
else {
IDProperty *idprop = (IDProperty *)prop;
return (idprop->type == IDP_ARRAY);
}
}
static void rna_ensure_property_multi_array_length(PointerRNA *ptr,
PropertyRNA *prop,
int length[])
{
if (prop->magic == RNA_MAGIC) {
if (prop->getlength) {
prop->getlength(ptr, length);
}
else {
memcpy(length, prop->arraylength, prop->arraydimension * sizeof(int));
}
}
else {
IDProperty *idprop = (IDProperty *)prop;
if (idprop->type == IDP_ARRAY) {
length[0] = idprop->len;
}
else {
length[0] = 0;
}
}
}
static bool rna_idproperty_verify_valid(PointerRNA *ptr, PropertyRNA *prop, IDProperty *idprop)
{
/* this verifies if the idproperty actually matches the property
* description and otherwise removes it. this is to ensure that
* rna property access is type safe, e.g. if you defined the rna
* to have a certain array length you can count on that staying so */
switch (idprop->type) {
case IDP_IDPARRAY:
if (prop->type != PROP_COLLECTION) {
return false;
}
break;
case IDP_ARRAY:
if (rna_ensure_property_array_length(ptr, prop) != idprop->len) {
return false;
}
if (idprop->subtype == IDP_FLOAT && prop->type != PROP_FLOAT) {
return false;
}
if (idprop->subtype == IDP_INT && !ELEM(prop->type, PROP_BOOLEAN, PROP_INT, PROP_ENUM)) {
return false;
}
break;
case IDP_INT:
if (!ELEM(prop->type, PROP_BOOLEAN, PROP_INT, PROP_ENUM)) {
return false;
}
break;
case IDP_FLOAT:
case IDP_DOUBLE:
if (prop->type != PROP_FLOAT) {
return false;
}
break;
case IDP_STRING:
if (prop->type != PROP_STRING) {
return false;
}
break;
case IDP_GROUP:
case IDP_ID:
if (prop->type != PROP_POINTER) {
return false;
}
break;
default:
return false;
}
return true;
}
static PropertyRNA *typemap[IDP_NUMTYPES] = {
(PropertyRNA *)&rna_PropertyGroupItem_string,
(PropertyRNA *)&rna_PropertyGroupItem_int,
(PropertyRNA *)&rna_PropertyGroupItem_float,
NULL,
NULL,
NULL,
(PropertyRNA *)&rna_PropertyGroupItem_group,
(PropertyRNA *)&rna_PropertyGroupItem_id,
(PropertyRNA *)&rna_PropertyGroupItem_double,
(PropertyRNA *)&rna_PropertyGroupItem_idp_array,
};
static PropertyRNA *arraytypemap[IDP_NUMTYPES] = {
NULL,
(PropertyRNA *)&rna_PropertyGroupItem_int_array,
(PropertyRNA *)&rna_PropertyGroupItem_float_array,
NULL,
NULL,
NULL,
(PropertyRNA *)&rna_PropertyGroupItem_collection,
NULL,
(PropertyRNA *)&rna_PropertyGroupItem_double_array,
};
static void *rna_idproperty_check_ex(PropertyRNA **prop,
PointerRNA *ptr,
const bool return_rnaprop)
{
/* This is quite a hack, but avoids some complexity in the API. we
* pass IDProperty structs as PropertyRNA pointers to the outside.
* We store some bytes in PropertyRNA structs that allows us to
* distinguish it from IDProperty structs. If it is an ID property,
* we look up an IDP PropertyRNA based on the type, and set the data
* pointer to the IDProperty. */
if ((*prop)->magic == RNA_MAGIC) {
if ((*prop)->flag & PROP_IDPROPERTY) {
IDProperty *idprop = rna_idproperty_find(ptr, (*prop)->identifier);
if (idprop && !rna_idproperty_verify_valid(ptr, *prop, idprop)) {
IDProperty *group = RNA_struct_idprops(ptr, 0);
IDP_FreeFromGroup(group, idprop);
return NULL;
}
return idprop;
}
else {
return return_rnaprop ? *prop : NULL;
}
}
{
IDProperty *idprop = (IDProperty *)(*prop);
if (idprop->type == IDP_ARRAY) {
*prop = arraytypemap[(int)(idprop->subtype)];
}
else {
*prop = typemap[(int)(idprop->type)];
}
return idprop;
}
}
/* This function only returns an IDProperty,
* or NULL (in case IDProp could not be found, or prop is a real RNA property). */
IDProperty *rna_idproperty_check(PropertyRNA **prop, PointerRNA *ptr)
{
return rna_idproperty_check_ex(prop, ptr, false);
}
/* This function always return the valid, real data pointer, be it a regular RNA property one,
* or an IDProperty one. */
PropertyRNA *rna_ensure_property_realdata(PropertyRNA **prop, PointerRNA *ptr)
{
return rna_idproperty_check_ex(prop, ptr, true);
}
PropertyRNA *rna_ensure_property(PropertyRNA *prop)
{
/* the quick version if we don't need the idproperty */
if (prop->magic == RNA_MAGIC) {
return prop;
}
{
IDProperty *idprop = (IDProperty *)prop;
if (idprop->type == IDP_ARRAY) {
return arraytypemap[(int)(idprop->subtype)];
}
else {
return typemap[(int)(idprop->type)];
}
}
}
static const char *rna_ensure_property_identifier(const PropertyRNA *prop)
{
if (prop->magic == RNA_MAGIC) {
return prop->identifier;
}
else {
return ((const IDProperty *)prop)->name;
}
}
static const char *rna_ensure_property_description(PropertyRNA *prop)
{
const char *description = NULL;
if (prop->magic == RNA_MAGIC) {
description = prop->description;
}
else {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item = IDP_GetPropertyTypeFromGroup(idp_ui, "description", IDP_STRING);
if (item) {
description = IDP_String(item);
}
}
if (description == NULL) {
description = ((IDProperty *)prop)->name; /* XXX - not correct */
}
}
return description;
}
static const char *rna_ensure_property_name(const PropertyRNA *prop)
{
const char *name;
if (prop->magic == RNA_MAGIC) {
name = prop->name;
}
else {
name = ((const IDProperty *)prop)->name;
}
return name;
}
/* Structs */
StructRNA *RNA_struct_find(const char *identifier)
{
return BLI_ghash_lookup(BLENDER_RNA.structs_map, identifier);
}
const char *RNA_struct_identifier(const StructRNA *type)
{
return type->identifier;
}
const char *RNA_struct_ui_name(const StructRNA *type)
{
return CTX_IFACE_(type->translation_context, type->name);
}
const char *RNA_struct_ui_name_raw(const StructRNA *type)
{
return type->name;
}
int RNA_struct_ui_icon(const StructRNA *type)
{
if (type) {
return type->icon;
}
else {
return ICON_DOT;
}
}
const char *RNA_struct_ui_description(const StructRNA *type)
{
return TIP_(type->description);
}
const char *RNA_struct_ui_description_raw(const StructRNA *type)
{
return type->description;
}
const char *RNA_struct_translation_context(const StructRNA *type)
{
return type->translation_context;
}
PropertyRNA *RNA_struct_name_property(const StructRNA *type)
{
return type->nameproperty;
}
const EnumPropertyItem *RNA_struct_property_tag_defines(const StructRNA *type)
{
return type->prop_tag_defines;
}
PropertyRNA *RNA_struct_iterator_property(StructRNA *type)
{
return type->iteratorproperty;
}
StructRNA *RNA_struct_base(StructRNA *type)
{
return type->base;
}
/**
* Use to find the subtype directly below a base-type.
*
* So if type were `RNA_SpotLIght`, `RNA_struct_base_of(type, &RNA_ID)` would return `&RNA_Light`.
*/
const StructRNA *RNA_struct_base_child_of(const StructRNA *type, const StructRNA *parent_type)
{
while (type) {
if (type->base == parent_type) {
return type;
}
type = type->base;
}
return NULL;
}
bool RNA_struct_is_ID(const StructRNA *type)
{
return (type->flag & STRUCT_ID) != 0;
}
bool RNA_struct_undo_check(const StructRNA *type)
{
return (type->flag & STRUCT_UNDO) != 0;
}
bool RNA_struct_idprops_register_check(const StructRNA *type)
{
return (type->flag & STRUCT_NO_IDPROPERTIES) == 0;
}
bool RNA_struct_idprops_datablock_allowed(const StructRNA *type)
{
return (type->flag & (STRUCT_NO_DATABLOCK_IDPROPERTIES | STRUCT_NO_IDPROPERTIES)) == 0;
}
/**
* Whether given type implies datablock usage by IDProperties.
* This is used to prevent classes allowed to have IDProperties,
* but not datablock ones, to indirectly use some
* (e.g. by assigning an IDP_GROUP containing some IDP_ID pointers...).
*/
bool RNA_struct_idprops_contains_datablock(const StructRNA *type)
{
return (type->flag & (STRUCT_CONTAINS_DATABLOCK_IDPROPERTIES | STRUCT_ID)) != 0;
}
/* remove an id-property */
bool RNA_struct_idprops_unset(PointerRNA *ptr, const char *identifier)
{
IDProperty *group = RNA_struct_idprops(ptr, 0);
if (group) {
IDProperty *idp = IDP_GetPropertyFromGroup(group, identifier);
if (idp) {
IDP_FreeFromGroup(group, idp);
return true;
}
}
return false;
}
bool RNA_struct_is_a(const StructRNA *type, const StructRNA *srna)
{
const StructRNA *base;
if (srna == &RNA_AnyType) {
return true;
}
if (!type) {
return false;
}
/* ptr->type is always maximally refined */
for (base = type; base; base = base->base) {
if (base == srna) {
return true;
}
}
return false;
}
PropertyRNA *RNA_struct_find_property(PointerRNA *ptr, const char *identifier)
{
if (identifier[0] == '[' && identifier[1] == '"') { /* " (dummy comment to avoid confusing some
* function lists in text editors) */
/* id prop lookup, not so common */
PropertyRNA *r_prop = NULL;
PointerRNA r_ptr; /* only support single level props */
if (RNA_path_resolve_property(ptr, identifier, &r_ptr, &r_prop) && (r_ptr.type == ptr->type) &&
(r_ptr.data == ptr->data)) {
return r_prop;
}
}
else {
/* most common case */
PropertyRNA *iterprop = RNA_struct_iterator_property(ptr->type);
PointerRNA propptr;
if (RNA_property_collection_lookup_string(ptr, iterprop, identifier, &propptr)) {
return propptr.data;
}
}
return NULL;
}
/* Find the property which uses the given nested struct */
static PropertyRNA *RNA_struct_find_nested(PointerRNA *ptr, StructRNA *srna)
{
PropertyRNA *prop = NULL;
RNA_STRUCT_BEGIN (ptr, iprop) {
/* This assumes that there can only be one user of this nested struct */
if (RNA_property_pointer_type(ptr, iprop) == srna) {
prop = iprop;
break;
}
}
RNA_PROP_END;
return prop;
}
bool RNA_struct_contains_property(PointerRNA *ptr, PropertyRNA *prop_test)
{
/* note, prop_test could be freed memory, only use for comparison */
/* validate the RNA is ok */
PropertyRNA *iterprop;
bool found = false;
iterprop = RNA_struct_iterator_property(ptr->type);
RNA_PROP_BEGIN (ptr, itemptr, iterprop) {
/* PropertyRNA *prop = itemptr.data; */
if (prop_test == (PropertyRNA *)itemptr.data) {
found = true;
break;
}
}
RNA_PROP_END;
return found;
}
unsigned int RNA_struct_count_properties(StructRNA *srna)
{
PointerRNA struct_ptr;
unsigned int counter = 0;
RNA_pointer_create(NULL, srna, NULL, &struct_ptr);
RNA_STRUCT_BEGIN (&struct_ptr, prop) {
counter++;
UNUSED_VARS(prop);
}
RNA_STRUCT_END;
return counter;
}
/* Low level direct access to type->properties,
* note this ignores parent classes so should be used with care. */
const struct ListBase *RNA_struct_type_properties(StructRNA *srna)
{
return &srna->cont.properties;
}
PropertyRNA *RNA_struct_type_find_property(StructRNA *srna, const char *identifier)
{
return BLI_findstring_ptr(&srna->cont.properties, identifier, offsetof(PropertyRNA, identifier));
}
FunctionRNA *RNA_struct_find_function(StructRNA *srna, const char *identifier)
{
#if 1
FunctionRNA *func;
StructRNA *type;
for (type = srna; type; type = type->base) {
func = (FunctionRNA *)BLI_findstring_ptr(
&type->functions, identifier, offsetof(FunctionRNA, identifier));
if (func) {
return func;
}
}
return NULL;
/* functional but slow */
#else
PointerRNA tptr;
PropertyRNA *iterprop;
FunctionRNA *func;
RNA_pointer_create(NULL, &RNA_Struct, srna, &tptr);
iterprop = RNA_struct_find_property(&tptr, "functions");
func = NULL;
RNA_PROP_BEGIN (&tptr, funcptr, iterprop) {
if (STREQ(identifier, RNA_function_identifier(funcptr.data))) {
func = funcptr.data;
break;
}
}
RNA_PROP_END;
return func;
#endif
}
const ListBase *RNA_struct_type_functions(StructRNA *srna)
{
return &srna->functions;
}
StructRegisterFunc RNA_struct_register(StructRNA *type)
{
return type->reg;
}
StructUnregisterFunc RNA_struct_unregister(StructRNA *type)
{
do {
if (type->unreg) {
return type->unreg;
}
} while ((type = type->base));
return NULL;
}
void **RNA_struct_instance(PointerRNA *ptr)
{
StructRNA *type = ptr->type;
do {
if (type->instance) {
return type->instance(ptr);
}
} while ((type = type->base));
return NULL;
}
void *RNA_struct_py_type_get(StructRNA *srna)
{
return srna->py_type;
}
void RNA_struct_py_type_set(StructRNA *srna, void *py_type)
{
srna->py_type = py_type;
}
void *RNA_struct_blender_type_get(StructRNA *srna)
{
return srna->blender_type;
}
void RNA_struct_blender_type_set(StructRNA *srna, void *blender_type)
{
srna->blender_type = blender_type;
}
char *RNA_struct_name_get_alloc(PointerRNA *ptr, char *fixedbuf, int fixedlen, int *r_len)
{
PropertyRNA *nameprop;
if (ptr->data && (nameprop = RNA_struct_name_property(ptr->type))) {
return RNA_property_string_get_alloc(ptr, nameprop, fixedbuf, fixedlen, r_len);
}
return NULL;
}
/**
* Use when registering structs with the #STRUCT_PUBLIC_NAMESPACE flag.
*/
bool RNA_struct_available_or_report(ReportList *reports, const char *identifier)
{
const StructRNA *srna_exists = RNA_struct_find(identifier);
if (UNLIKELY(srna_exists != NULL)) {
/* Use comprehensive string construction since this is such a rare occurrence
* and information here may cut down time troubleshooting. */
DynStr *dynstr = BLI_dynstr_new();
BLI_dynstr_appendf(dynstr, "Type identifier '%s' is already in use: '", identifier);
BLI_dynstr_append(dynstr, srna_exists->identifier);
int i = 0;
if (srna_exists->base) {
for (const StructRNA *base = srna_exists->base; base; base = base->base) {
BLI_dynstr_append(dynstr, "(");
BLI_dynstr_append(dynstr, base->identifier);
i += 1;
}
while (i--) {
BLI_dynstr_append(dynstr, ")");
}
}
BLI_dynstr_append(dynstr, "'.");
char *result = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
BKE_report(reports, RPT_ERROR, result);
MEM_freeN(result);
return false;
}
else {
return true;
}
}
bool RNA_struct_bl_idname_ok_or_report(ReportList *reports,
const char *identifier,
const char *sep)
{
const int len_sep = strlen(sep);
const int len_id = strlen(identifier);
const char *p = strstr(identifier, sep);
/* TODO: make error, for now warning until add-ons update. */
#if 1
const int report_level = RPT_WARNING;
const bool failure = true;
#else
const int report_level = RPT_ERROR;
const bool failure = false;
#endif
if (p == NULL || p == identifier || p + len_sep >= identifier + len_id) {
BKE_reportf(
reports, report_level, "'%s' doesn't contain '%s' with prefix & suffix", identifier, sep);
return failure;
}
const char *c, *start, *end, *last;
start = identifier;
end = p;
last = end - 1;
for (c = start; c != end; c++) {
if (((*c >= 'A' && *c <= 'Z') || ((c != start) && (*c >= '0' && *c <= '9')) ||
((c != start) && (c != last) && (*c == '_'))) == 0) {
BKE_reportf(
reports, report_level, "'%s' doesn't have upper case alpha-numeric prefix", identifier);
return failure;
}
}
start = p + len_sep;
end = identifier + len_id;
last = end - 1;
for (c = start; c != end; c++) {
if (((*c >= 'A' && *c <= 'Z') || (*c >= 'a' && *c <= 'z') || (*c >= '0' && *c <= '9') ||
((c != start) && (c != last) && (*c == '_'))) == 0) {
BKE_reportf(reports, report_level, "'%s' doesn't have an alpha-numeric suffix", identifier);
return failure;
}
}
return true;
}
/* Property Information */
const char *RNA_property_identifier(const PropertyRNA *prop)
{
return rna_ensure_property_identifier(prop);
}
const char *RNA_property_description(PropertyRNA *prop)
{
return TIP_(rna_ensure_property_description(prop));
}
PropertyType RNA_property_type(PropertyRNA *prop)
{
return rna_ensure_property(prop)->type;
}
PropertySubType RNA_property_subtype(PropertyRNA *prop)
{
PropertyRNA *rna_prop = rna_ensure_property(prop);
/* For custom properties, find and parse the 'subtype' metadata field. */
if (prop->magic != RNA_MAGIC) {
IDProperty *idprop = (IDProperty *)prop;
/* Restrict to arrays only for now for performance reasons. */
if (idprop->type == IDP_ARRAY && ELEM(idprop->subtype, IDP_INT, IDP_FLOAT, IDP_DOUBLE)) {
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item = IDP_GetPropertyTypeFromGroup(idp_ui, "subtype", IDP_STRING);
if (item) {
int result = PROP_NONE;
RNA_enum_value_from_id(rna_enum_property_subtype_items, IDP_String(item), &result);
return (PropertySubType)result;
}
}
}
}
return rna_prop->subtype;
}
PropertyUnit RNA_property_unit(PropertyRNA *prop)
{
return RNA_SUBTYPE_UNIT(RNA_property_subtype(prop));
}
int RNA_property_flag(PropertyRNA *prop)
{
return rna_ensure_property(prop)->flag;
}
/**
* Get the tags set for \a prop as int bitfield.
* \note Doesn't perform any validity check on the set bits. #RNA_def_property_tags does this
* in debug builds (to avoid performance issues in non-debug builds), which should be
* the only way to set tags. Hence, at this point we assume the tag bitfield to be valid.
*/
int RNA_property_tags(PropertyRNA *prop)
{
return rna_ensure_property(prop)->tags;
}
bool RNA_property_builtin(PropertyRNA *prop)
{
return (rna_ensure_property(prop)->flag_internal & PROP_INTERN_BUILTIN) != 0;
}
void *RNA_property_py_data_get(PropertyRNA *prop)
{
return prop->py_data;
}
int RNA_property_array_length(PointerRNA *ptr, PropertyRNA *prop)
{
return rna_ensure_property_array_length(ptr, prop);
}
bool RNA_property_array_check(PropertyRNA *prop)
{
return rna_ensure_property_array_check(prop);
}
/* used by BPY to make an array from the python object */
int RNA_property_array_dimension(PointerRNA *ptr, PropertyRNA *prop, int length[])
{
PropertyRNA *rprop = rna_ensure_property(prop);
if (length) {
rna_ensure_property_multi_array_length(ptr, prop, length);
}
return rprop->arraydimension;
}
/* Return the size of Nth dimension. */
int RNA_property_multi_array_length(PointerRNA *ptr, PropertyRNA *prop, int dim)
{
int len[RNA_MAX_ARRAY_DIMENSION];
rna_ensure_property_multi_array_length(ptr, prop, len);
return len[dim];
}
char RNA_property_array_item_char(PropertyRNA *prop, int index)
{
const char *vectoritem = "XYZW";
const char *quatitem = "WXYZ";
const char *coloritem = "RGBA";
PropertySubType subtype = RNA_property_subtype(prop);
BLI_assert(index >= 0);
/* get string to use for array index */
if ((index < 4) && ELEM(subtype, PROP_QUATERNION, PROP_AXISANGLE)) {
return quatitem[index];
}
else if ((index < 4) && ELEM(subtype,
PROP_TRANSLATION,
PROP_DIRECTION,
PROP_XYZ,
PROP_XYZ_LENGTH,
PROP_EULER,
PROP_VELOCITY,
PROP_ACCELERATION,
PROP_COORDS)) {
return vectoritem[index];
}
else if ((index < 4) && ELEM(subtype, PROP_COLOR, PROP_COLOR_GAMMA)) {
return coloritem[index];
}
return '\0';
}
int RNA_property_array_item_index(PropertyRNA *prop, char name)
{
/* Don't use custom property subtypes in RNA path lookup. */
PropertySubType subtype = rna_ensure_property(prop)->subtype;
/* get index based on string name/alias */
/* maybe a function to find char index in string would be better than all the switches */
if (ELEM(subtype, PROP_QUATERNION, PROP_AXISANGLE)) {
switch (name) {
case 'w':
return 0;
case 'x':
return 1;
case 'y':
return 2;
case 'z':
return 3;
}
}
else if (ELEM(subtype,
PROP_TRANSLATION,
PROP_DIRECTION,
PROP_XYZ,
PROP_XYZ_LENGTH,
PROP_EULER,
PROP_VELOCITY,
PROP_ACCELERATION)) {
switch (name) {
case 'x':
return 0;
case 'y':
return 1;
case 'z':
return 2;
case 'w':
return 3;
}
}
else if (ELEM(subtype, PROP_COLOR, PROP_COLOR_GAMMA)) {
switch (name) {
case 'r':
return 0;
case 'g':
return 1;
case 'b':
return 2;
case 'a':
return 3;
}
}
return -1;
}
void RNA_property_int_range(PointerRNA *ptr, PropertyRNA *prop, int *hardmin, int *hardmax)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)rna_ensure_property(prop);
int softmin, softmax;
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "min", IDP_INT);
*hardmin = item ? IDP_Int(item) : INT_MIN;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "max", IDP_INT);
*hardmax = item ? IDP_Int(item) : INT_MAX;
return;
}
}
if (iprop->range) {
*hardmin = INT_MIN;
*hardmax = INT_MAX;
iprop->range(ptr, hardmin, hardmax, &softmin, &softmax);
}
else if (iprop->range_ex) {
*hardmin = INT_MIN;
*hardmax = INT_MAX;
iprop->range_ex(ptr, prop, hardmin, hardmax, &softmin, &softmax);
}
else {
*hardmin = iprop->hardmin;
*hardmax = iprop->hardmax;
}
}
void RNA_property_int_ui_range(
PointerRNA *ptr, PropertyRNA *prop, int *softmin, int *softmax, int *step)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)rna_ensure_property(prop);
int hardmin, hardmax;
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "soft_min", IDP_INT);
*softmin = item ? IDP_Int(item) : INT_MIN;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "soft_max", IDP_INT);
*softmax = item ? IDP_Int(item) : INT_MAX;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "step", IDP_INT);
*step = item ? IDP_Int(item) : 1;
return;
}
}
*softmin = iprop->softmin;
*softmax = iprop->softmax;
if (iprop->range) {
hardmin = INT_MIN;
hardmax = INT_MAX;
iprop->range(ptr, &hardmin, &hardmax, softmin, softmax);
*softmin = max_ii(*softmin, hardmin);
*softmax = min_ii(*softmax, hardmax);
}
else if (iprop->range_ex) {
hardmin = INT_MIN;
hardmax = INT_MAX;
iprop->range_ex(ptr, prop, &hardmin, &hardmax, softmin, softmax);
*softmin = max_ii(*softmin, hardmin);
*softmax = min_ii(*softmax, hardmax);
}
*step = iprop->step;
}
void RNA_property_float_range(PointerRNA *ptr, PropertyRNA *prop, float *hardmin, float *hardmax)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)rna_ensure_property(prop);
float softmin, softmax;
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "min", IDP_DOUBLE);
*hardmin = item ? (float)IDP_Double(item) : -FLT_MAX;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "max", IDP_DOUBLE);
*hardmax = item ? (float)IDP_Double(item) : FLT_MAX;
return;
}
}
if (fprop->range) {
*hardmin = -FLT_MAX;
*hardmax = FLT_MAX;
fprop->range(ptr, hardmin, hardmax, &softmin, &softmax);
}
else if (fprop->range_ex) {
*hardmin = -FLT_MAX;
*hardmax = FLT_MAX;
fprop->range_ex(ptr, prop, hardmin, hardmax, &softmin, &softmax);
}
else {
*hardmin = fprop->hardmin;
*hardmax = fprop->hardmax;
}
}
void RNA_property_float_ui_range(PointerRNA *ptr,
PropertyRNA *prop,
float *softmin,
float *softmax,
float *step,
float *precision)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)rna_ensure_property(prop);
float hardmin, hardmax;
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "soft_min", IDP_DOUBLE);
*softmin = item ? (float)IDP_Double(item) : -FLT_MAX;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "soft_max", IDP_DOUBLE);
*softmax = item ? (float)IDP_Double(item) : FLT_MAX;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "step", IDP_DOUBLE);
*step = item ? (float)IDP_Double(item) : 1.0f;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "precision", IDP_DOUBLE);
*precision = item ? (float)IDP_Double(item) : 3.0f;
return;
}
}
*softmin = fprop->softmin;
*softmax = fprop->softmax;
if (fprop->range) {
hardmin = -FLT_MAX;
hardmax = FLT_MAX;
fprop->range(ptr, &hardmin, &hardmax, softmin, softmax);
*softmin = max_ff(*softmin, hardmin);
*softmax = min_ff(*softmax, hardmax);
}
else if (fprop->range_ex) {
hardmin = -FLT_MAX;
hardmax = FLT_MAX;
fprop->range_ex(ptr, prop, &hardmin, &hardmax, softmin, softmax);
*softmin = max_ff(*softmin, hardmin);
*softmax = min_ff(*softmax, hardmax);
}
*step = fprop->step;
*precision = (float)fprop->precision;
}
int RNA_property_float_clamp(PointerRNA *ptr, PropertyRNA *prop, float *value)
{
float min, max;
RNA_property_float_range(ptr, prop, &min, &max);
if (*value < min) {
*value = min;
return -1;
}
else if (*value > max) {
*value = max;
return 1;
}
else {
return 0;
}
}
int RNA_property_int_clamp(PointerRNA *ptr, PropertyRNA *prop, int *value)
{
int min, max;
RNA_property_int_range(ptr, prop, &min, &max);
if (*value < min) {
*value = min;
return -1;
}
else if (*value > max) {
*value = max;
return 1;
}
else {
return 0;
}
}
/* this is the max length including \0 terminator.
* '0' used when their is no maximum */
int RNA_property_string_maxlength(PropertyRNA *prop)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)rna_ensure_property(prop);
return sprop->maxlength;
}
StructRNA *RNA_property_pointer_type(PointerRNA *ptr, PropertyRNA *prop)
{
prop = rna_ensure_property(prop);
if (prop->type == PROP_POINTER) {
PointerPropertyRNA *pprop = (PointerPropertyRNA *)prop;
if (pprop->typef) {
return pprop->typef(ptr);
}
else if (pprop->type) {
return pprop->type;
}
}
else if (prop->type == PROP_COLLECTION) {
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop;
if (cprop->item_type) {
return cprop->item_type;
}
}
/* ignore other types, RNA_struct_find_nested calls with unchecked props */
return &RNA_UnknownType;
}
bool RNA_property_pointer_poll(PointerRNA *ptr, PropertyRNA *prop, PointerRNA *value)
{
prop = rna_ensure_property(prop);
if (prop->type == PROP_POINTER) {
PointerPropertyRNA *pprop = (PointerPropertyRNA *)prop;
if (pprop->poll) {
if (rna_idproperty_check(&prop, ptr)) {
return ((PropPointerPollFuncPy)pprop->poll)(ptr, *value, prop);
}
else {
return pprop->poll(ptr, *value);
}
}
return 1;
}
printf("%s: %s is not a pointer property.\n", __func__, prop->identifier);
return 0;
}
void RNA_property_enum_items_ex(bContext *C,
PointerRNA *ptr,
PropertyRNA *prop,
const bool use_static,
const EnumPropertyItem **r_item,
int *r_totitem,
bool *r_free)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)rna_ensure_property(prop);
*r_free = false;
if (!use_static && eprop->itemf && (C != NULL || (prop->flag & PROP_ENUM_NO_CONTEXT))) {
const EnumPropertyItem *item;
if (prop->flag & PROP_ENUM_NO_CONTEXT) {
item = eprop->itemf(NULL, ptr, prop, r_free);
}
else {
item = eprop->itemf(C, ptr, prop, r_free);
}
/* any callbacks returning NULL should be fixed */
BLI_assert(item != NULL);
if (r_totitem) {
int tot;
for (tot = 0; item[tot].identifier; tot++) {
/* pass */
}
*r_totitem = tot;
}
*r_item = item;
}
else {
*r_item = eprop->item;
if (r_totitem) {
*r_totitem = eprop->totitem;
}
}
}
void RNA_property_enum_items(bContext *C,
PointerRNA *ptr,
PropertyRNA *prop,
const EnumPropertyItem **r_item,
int *r_totitem,
bool *r_free)
{
RNA_property_enum_items_ex(C, ptr, prop, false, r_item, r_totitem, r_free);
}
#ifdef WITH_INTERNATIONAL
static void property_enum_translate(PropertyRNA *prop,
EnumPropertyItem **r_item,
int *r_totitem,
bool *r_free)
{
if (!(prop->flag & PROP_ENUM_NO_TRANSLATE)) {
int i;
/* Note: Only do those tests once, and then use BLT_pgettext. */
bool do_iface = BLT_translate_iface();
bool do_tooltip = BLT_translate_tooltips();
EnumPropertyItem *nitem;
if (!(do_iface || do_tooltip)) {
return;
}
if (*r_free) {
nitem = *r_item;
}
else {
const EnumPropertyItem *item = *r_item;
int tot;
if (r_totitem) {
tot = *r_totitem;
}
else {
/* count */
for (tot = 0; item[tot].identifier; tot++) {
/* pass */
}
}
nitem = MEM_mallocN(sizeof(EnumPropertyItem) * (tot + 1), "enum_items_gettexted");
memcpy(nitem, item, sizeof(EnumPropertyItem) * (tot + 1));
*r_free = true;
}
for (i = 0; nitem[i].identifier; i++) {
if (nitem[i].name && do_iface) {
nitem[i].name = BLT_pgettext(prop->translation_context, nitem[i].name);
}
if (nitem[i].description && do_tooltip) {
nitem[i].description = BLT_pgettext(NULL, nitem[i].description);
}
}
*r_item = nitem;
}
}
#endif
void RNA_property_enum_items_gettexted(bContext *C,
PointerRNA *ptr,
PropertyRNA *prop,
const EnumPropertyItem **r_item,
int *r_totitem,
bool *r_free)
{
RNA_property_enum_items(C, ptr, prop, r_item, r_totitem, r_free);
#ifdef WITH_INTERNATIONAL
/* Normally dropping 'const' is _not_ ok, in this case it's only modified if we own the memory
* so allow the exception (callers are creating new arrays in this case). */
property_enum_translate(prop, (EnumPropertyItem **)r_item, r_totitem, r_free);
#endif
}
void RNA_property_enum_items_gettexted_all(bContext *C,
PointerRNA *ptr,
PropertyRNA *prop,
const EnumPropertyItem **r_item,
int *r_totitem,
bool *r_free)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)rna_ensure_property(prop);
int mem_size = sizeof(EnumPropertyItem) * (eprop->totitem + 1);
/* first return all items */
EnumPropertyItem *item_array = MEM_mallocN(mem_size, "enum_gettext_all");
*r_free = true;
memcpy(item_array, eprop->item, mem_size);
if (r_totitem) {
*r_totitem = eprop->totitem;
}
if (eprop->itemf && (C != NULL || (prop->flag & PROP_ENUM_NO_CONTEXT))) {
const EnumPropertyItem *item;
int i;
bool free = false;
if (prop->flag & PROP_ENUM_NO_CONTEXT) {
item = eprop->itemf(NULL, ptr, prop, &free);
}
else {
item = eprop->itemf(C, ptr, prop, &free);
}
/* any callbacks returning NULL should be fixed */
BLI_assert(item != NULL);
for (i = 0; i < eprop->totitem; i++) {
bool exists = false;
int i_fixed;
/* Items that do not exist on list are returned,
* but have their names/identifiers NULL'ed out. */
for (i_fixed = 0; item[i_fixed].identifier; i_fixed++) {
if (STREQ(item[i_fixed].identifier, item_array[i].identifier)) {
exists = true;
break;
}
}
if (!exists) {
item_array[i].name = NULL;
item_array[i].identifier = "";
}
}
if (free) {
MEM_freeN((void *)item);
}
}
#ifdef WITH_INTERNATIONAL
property_enum_translate(prop, &item_array, r_totitem, r_free);
#endif
*r_item = item_array;
}
bool RNA_property_enum_value(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const char *identifier, int *r_value)
{
const EnumPropertyItem *item;
bool free;
bool found;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
if (item) {
const int i = RNA_enum_from_identifier(item, identifier);
if (i != -1) {
*r_value = item[i].value;
found = true;
}
else {
found = false;
}
if (free) {
MEM_freeN((void *)item);
}
}
else {
found = false;
}
return found;
}
bool RNA_enum_identifier(const EnumPropertyItem *item, const int value, const char **r_identifier)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_identifier = item[i].identifier;
return true;
}
else {
return false;
}
}
int RNA_enum_bitflag_identifiers(const EnumPropertyItem *item,
const int value,
const char **r_identifier)
{
int index = 0;
for (; item->identifier; item++) {
if (item->identifier[0] && item->value & value) {
r_identifier[index++] = item->identifier;
}
}
r_identifier[index] = NULL;
return index;
}
bool RNA_enum_name(const EnumPropertyItem *item, const int value, const char **r_name)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_name = item[i].name;
return true;
}
else {
return false;
}
}
bool RNA_enum_description(const EnumPropertyItem *item,
const int value,
const char **r_description)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_description = item[i].description;
return true;
}
else {
return false;
}
}
int RNA_enum_from_identifier(const EnumPropertyItem *item, const char *identifier)
{
int i = 0;
for (; item->identifier; item++, i++) {
if (item->identifier[0] && STREQ(item->identifier, identifier)) {
return i;
}
}
return -1;
}
/**
* Take care using this with translated enums,
* prefer #RNA_enum_from_identifier where possible.
*/
int RNA_enum_from_name(const EnumPropertyItem *item, const char *name)
{
int i = 0;
for (; item->identifier; item++, i++) {
if (item->identifier[0] && STREQ(item->name, name)) {
return i;
}
}
return -1;
}
int RNA_enum_from_value(const EnumPropertyItem *item, const int value)
{
int i = 0;
for (; item->identifier; item++, i++) {
if (item->identifier[0] && item->value == value) {
return i;
}
}
return -1;
}
unsigned int RNA_enum_items_count(const EnumPropertyItem *item)
{
unsigned int i = 0;
while (item->identifier) {
item++;
i++;
}
return i;
}
bool RNA_property_enum_identifier(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, const char **identifier)
{
const EnumPropertyItem *item = NULL;
bool free;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
if (item) {
bool result;
result = RNA_enum_identifier(item, value, identifier);
if (free) {
MEM_freeN((void *)item);
}
return result;
}
return false;
}
bool RNA_property_enum_name(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, const char **name)
{
const EnumPropertyItem *item = NULL;
bool free;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
if (item) {
bool result;
result = RNA_enum_name(item, value, name);
if (free) {
MEM_freeN((void *)item);
}
return result;
}
return false;
}
bool RNA_property_enum_name_gettexted(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, const char **name)
{
bool result;
result = RNA_property_enum_name(C, ptr, prop, value, name);
if (result) {
if (!(prop->flag & PROP_ENUM_NO_TRANSLATE)) {
if (BLT_translate_iface()) {
*name = BLT_pgettext(prop->translation_context, *name);
}
}
}
return result;
}
bool RNA_property_enum_item_from_value(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, EnumPropertyItem *r_item)
{
const EnumPropertyItem *item = NULL;
bool free;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
if (item) {
const int i = RNA_enum_from_value(item, value);
bool result;
if (i != -1) {
*r_item = item[i];
result = true;
}
else {
result = false;
}
if (free) {
MEM_freeN((void *)item);
}
return result;
}
return false;
}
bool RNA_property_enum_item_from_value_gettexted(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, EnumPropertyItem *r_item)
{
bool result;
result = RNA_property_enum_item_from_value(C, ptr, prop, value, r_item);
if (!(prop->flag & PROP_ENUM_NO_TRANSLATE)) {
if (BLT_translate_iface()) {
r_item->name = BLT_pgettext(prop->translation_context, r_item->name);
}
}
return result;
}
int RNA_property_enum_bitflag_identifiers(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, const int value, const char **identifier)
{
const EnumPropertyItem *item = NULL;
bool free;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
if (item) {
int result;
result = RNA_enum_bitflag_identifiers(item, value, identifier);
if (free) {
MEM_freeN((void *)item);
}
return result;
}
return 0;
}
const char *RNA_property_ui_name(PropertyRNA *prop)
{
return CTX_IFACE_(prop->translation_context, rna_ensure_property_name(prop));
}
const char *RNA_property_ui_name_raw(PropertyRNA *prop)
{
return rna_ensure_property_name(prop);
}
const char *RNA_property_ui_description(PropertyRNA *prop)
{
return TIP_(rna_ensure_property_description(prop));
}
const char *RNA_property_ui_description_raw(PropertyRNA *prop)
{
return rna_ensure_property_description(prop);
}
const char *RNA_property_translation_context(PropertyRNA *_prop)
{
PropertyRNA *prop = rna_ensure_property(_prop);
return prop->translation_context;
}
int RNA_property_ui_icon(PropertyRNA *prop)
{
return rna_ensure_property(prop)->icon;
}
bool RNA_property_editable(PointerRNA *ptr, PropertyRNA *prop)
{
ID *id = ptr->owner_id;
int flag;
const char *dummy_info;
prop = rna_ensure_property(prop);
flag = prop->editable ? prop->editable(ptr, &dummy_info) : prop->flag;
return ((flag & PROP_EDITABLE) && (flag & PROP_REGISTER) == 0 &&
(!id || ((!ID_IS_LINKED(id) || (prop->flag & PROP_LIB_EXCEPTION)) &&
(!id->override_library || RNA_property_overridable_get(ptr, prop)))));
}
/**
* Version of #RNA_property_editable that tries to return additional info in \a r_info
* that can be exposed in UI.
*/
bool RNA_property_editable_info(PointerRNA *ptr, PropertyRNA *prop, const char **r_info)
{
ID *id = ptr->owner_id;
int flag;
prop = rna_ensure_property(prop);
*r_info = "";
/* get flag */
if (prop->editable) {
flag = prop->editable(ptr, r_info);
}
else {
flag = prop->flag;
if ((flag & PROP_EDITABLE) == 0 || (flag & PROP_REGISTER)) {
*r_info = N_("This property is for internal use only and can't be edited");
}
}
/* property from linked data-block */
if (id) {
if (ID_IS_LINKED(id) && (prop->flag & PROP_LIB_EXCEPTION) == 0) {
if (!(*r_info)[0]) {
*r_info = N_("Can't edit this property from a linked data-block");
}
return false;
}
if (id->override_library != NULL && !RNA_property_overridable_get(ptr, prop)) {
if (!(*r_info)[0]) {
*r_info = N_("Can't edit this property from an override data-block");
}
return false;
}
}
return ((flag & PROP_EDITABLE) && (flag & PROP_REGISTER) == 0);
}
bool RNA_property_editable_flag(PointerRNA *ptr, PropertyRNA *prop)
{
int flag;
const char *dummy_info;
prop = rna_ensure_property(prop);
flag = prop->editable ? prop->editable(ptr, &dummy_info) : prop->flag;
return (flag & PROP_EDITABLE) != 0;
}
/* same as RNA_property_editable(), except this checks individual items in an array */
bool RNA_property_editable_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
ID *id;
int flag;
BLI_assert(index >= 0);
prop = rna_ensure_property(prop);
flag = prop->flag;
if (prop->editable) {
const char *dummy_info;
flag &= prop->editable(ptr, &dummy_info);
}
if (prop->itemeditable) {
flag &= prop->itemeditable(ptr, index);
}
id = ptr->owner_id;
return (flag & PROP_EDITABLE) && (!id || !ID_IS_LINKED(id) || (prop->flag & PROP_LIB_EXCEPTION));
}
bool RNA_property_animateable(PointerRNA *ptr, PropertyRNA *prop)
{
/* check that base ID-block can support animation data */
if (!id_can_have_animdata(ptr->owner_id)) {
return false;
}
prop = rna_ensure_property(prop);
if (!(prop->flag & PROP_ANIMATABLE)) {
return false;
}
return (prop->flag & PROP_EDITABLE) != 0;
}
bool RNA_property_animated(PointerRNA *ptr, PropertyRNA *prop)
{
int len = 1, index;
bool driven, special;
if (!prop) {
return false;
}
if (RNA_property_array_check(prop)) {
len = RNA_property_array_length(ptr, prop);
}
for (index = 0; index < len; index++) {
if (rna_get_fcurve(ptr, prop, index, NULL, NULL, &driven, &special)) {
return true;
}
}
return false;
}
/* this function is to check if its possible to create a valid path from the ID
* its slow so don't call in a loop */
bool RNA_property_path_from_ID_check(PointerRNA *ptr, PropertyRNA *prop)
{
char *path = RNA_path_from_ID_to_property(ptr, prop);
bool ret = false;
if (path) {
PointerRNA id_ptr;
PointerRNA r_ptr;
PropertyRNA *r_prop;
RNA_id_pointer_create(ptr->owner_id, &id_ptr);
if (RNA_path_resolve(&id_ptr, path, &r_ptr, &r_prop) == true) {
ret = (prop == r_prop);
}
MEM_freeN(path);
}
return ret;
}
static void rna_property_update(
bContext *C, Main *bmain, Scene *scene, PointerRNA *ptr, PropertyRNA *prop)
{
const bool is_rna = (prop->magic == RNA_MAGIC);
prop = rna_ensure_property(prop);
if (is_rna) {
if (prop->update) {
/* ideally no context would be needed for update, but there's some
* parts of the code that need it still, so we have this exception */
if (prop->flag & PROP_CONTEXT_UPDATE) {
if (C) {
if ((prop->flag & PROP_CONTEXT_PROPERTY_UPDATE) == PROP_CONTEXT_PROPERTY_UPDATE) {
((ContextPropUpdateFunc)prop->update)(C, ptr, prop);
}
else {
((ContextUpdateFunc)prop->update)(C, ptr);
}
}
}
else {
prop->update(bmain, scene, ptr);
}
}
#if 1
/* TODO(campbell): Should eventually be replaced entirely by message bus (below)
* for now keep since COW, bugs are hard to track when we have other missing updates. */
if (prop->noteflag) {
WM_main_add_notifier(prop->noteflag, ptr->owner_id);
}
#endif
/* if C is NULL, we're updating from animation.
* avoid slow-down from f-curves by not publishing (for now). */
if (C != NULL) {
struct wmMsgBus *mbus = CTX_wm_message_bus(C);
/* we could add NULL check, for now don't */
WM_msg_publish_rna(mbus, ptr, prop);
}
if (ptr->owner_id != NULL && ((prop->flag & PROP_NO_DEG_UPDATE) == 0)) {
const short id_type = GS(ptr->owner_id->name);
if (ID_TYPE_IS_COW(id_type)) {
DEG_id_tag_update(ptr->owner_id, ID_RECALC_COPY_ON_WRITE);
}
}
/* End message bus. */
}
if (!is_rna || (prop->flag & PROP_IDPROPERTY)) {
/* WARNING! This is so property drivers update the display!
* not especially nice */
DEG_id_tag_update(ptr->owner_id,
ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY | ID_RECALC_PARAMETERS);
WM_main_add_notifier(NC_WINDOW, NULL);
/* Not nice as well, but the only way to make sure material preview
* is updated with custom nodes.
*/
if ((prop->flag & PROP_IDPROPERTY) != 0 && (ptr->owner_id != NULL) &&
(GS(ptr->owner_id->name) == ID_NT)) {
WM_main_add_notifier(NC_MATERIAL | ND_SHADING, NULL);
}
}
}
/* must keep in sync with 'rna_property_update'
* note, its possible this returns a false positive in the case of PROP_CONTEXT_UPDATE
* but this isn't likely to be a performance problem. */
bool RNA_property_update_check(PropertyRNA *prop)
{
return (prop->magic != RNA_MAGIC || prop->update || prop->noteflag);
}
void RNA_property_update(bContext *C, PointerRNA *ptr, PropertyRNA *prop)
{
rna_property_update(C, CTX_data_main(C), CTX_data_scene(C), ptr, prop);
}
void RNA_property_update_main(Main *bmain, Scene *scene, PointerRNA *ptr, PropertyRNA *prop)
{
rna_property_update(NULL, bmain, scene, ptr, prop);
}
/* RNA Updates Cache ------------------------ */
/* Overview of RNA Update cache system:
*
* RNA Update calls need to be cached in order to maintain reasonable performance
* of the animation system (i.e. maintaining a somewhat interactive framerate)
* while still allowing updates to be called (necessary in particular for modifier
* property updates to actually work).
*
* The cache is structured with a dual-layer structure
* - L1 = PointerRNA used as key; owner_id is used (it should always be defined,
* and most updates end up using just that anyways)
* - L2 = Update functions to be called on those PointerRNA's
*/
/* cache element */
typedef struct tRnaUpdateCacheElem {
struct tRnaUpdateCacheElem *next, *prev;
PointerRNA ptr; /* L1 key - id as primary, data secondary/ignored? */
ListBase L2Funcs; /* L2 functions (LinkData<RnaUpdateFuncRef>) */
} tRnaUpdateCacheElem;
/* cache global (tRnaUpdateCacheElem's) - only accessible using these API calls */
static ListBase rna_updates_cache = {NULL, NULL};
/* ........................... */
void RNA_property_update_cache_add(PointerRNA *ptr, PropertyRNA *prop)
{
const bool is_rna = (prop->magic == RNA_MAGIC);
tRnaUpdateCacheElem *uce = NULL;
UpdateFunc fn = NULL;
LinkData *ld;
/* sanity check */
if (NULL == ptr) {
return;
}
prop = rna_ensure_property(prop);
/* we can only handle update calls with no context args for now (makes animsys updates easier) */
if ((is_rna == false) || (prop->update == NULL) || (prop->flag & PROP_CONTEXT_UPDATE)) {
return;
}
fn = prop->update;
/* find cache element for which key matches... */
for (uce = rna_updates_cache.first; uce; uce = uce->next) {
/* Just match by id only for now,
* since most update calls that we'll encounter only really care about this. */
/* TODO: later, the cache might need to have some nesting on L1 to cope better
* with these problems + some tagging to indicate we need this */
if (uce->ptr.owner_id == ptr->owner_id) {
break;
}
}
if (uce == NULL) {
/* create new instance */
uce = MEM_callocN(sizeof(tRnaUpdateCacheElem), "tRnaUpdateCacheElem");
BLI_addtail(&rna_updates_cache, uce);
/* copy pointer */
RNA_pointer_create(ptr->owner_id, ptr->type, ptr->data, &uce->ptr);
}
/* check on the update func */
for (ld = uce->L2Funcs.first; ld; ld = ld->next) {
/* stop on match - function already cached */
if (fn == ld->data) {
return;
}
}
/* else... if still here, we need to add it */
BLI_addtail(&uce->L2Funcs, BLI_genericNodeN(fn));
}
void RNA_property_update_cache_flush(Main *bmain, Scene *scene)
{
tRnaUpdateCacheElem *uce;
/* TODO: should we check that bmain and scene are valid? The above stuff doesn't! */
/* execute the cached updates */
for (uce = rna_updates_cache.first; uce; uce = uce->next) {
LinkData *ld;
for (ld = uce->L2Funcs.first; ld; ld = ld->next) {
UpdateFunc fn = (UpdateFunc)ld->data;
fn(bmain, scene, &uce->ptr);
}
}
}
void RNA_property_update_cache_free(void)
{
tRnaUpdateCacheElem *uce, *ucn;
for (uce = rna_updates_cache.first; uce; uce = ucn) {
ucn = uce->next;
/* free L2 cache */
BLI_freelistN(&uce->L2Funcs);
/* remove self */
BLI_freelinkN(&rna_updates_cache, uce);
}
}
/* ---------------------------------------------------------------------- */
/* Property Data */
bool RNA_property_boolean_get(PointerRNA *ptr, PropertyRNA *prop)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)prop;
IDProperty *idprop;
bool value;
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) == false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
value = IDP_Int(idprop) != 0;
}
else if (bprop->get) {
value = bprop->get(ptr);
}
else if (bprop->get_ex) {
value = bprop->get_ex(ptr, prop);
}
else {
value = bprop->defaultvalue;
}
BLI_assert(ELEM(value, false, true));
return value;
}
void RNA_property_boolean_set(PointerRNA *ptr, PropertyRNA *prop, bool value)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) == false);
BLI_assert(ELEM(value, false, true));
/* just in case other values are passed */
BLI_assert(ELEM(value, true, false));
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDP_Int(idprop) = (int)value;
rna_idproperty_touch(idprop);
}
else if (bprop->set) {
bprop->set(ptr, value);
}
else if (bprop->set_ex) {
bprop->set_ex(ptr, prop, value);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
val.i = value;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group, IDP_New(IDP_INT, &val, prop->identifier));
}
}
}
static void rna_property_boolean_fill_default_array_values(
const bool *defarr, int defarr_length, bool defvalue, int out_length, bool *r_values)
{
if (defarr && defarr_length > 0) {
defarr_length = MIN2(defarr_length, out_length);
memcpy(r_values, defarr, sizeof(bool) * defarr_length);
}
else {
defarr_length = 0;
}
for (int i = defarr_length; i < out_length; i++) {
r_values[i] = defvalue;
}
}
static void rna_property_boolean_get_default_array_values(PointerRNA *ptr,
BoolPropertyRNA *bprop,
bool *r_values)
{
int length = bprop->property.totarraylength;
int out_length = RNA_property_array_length(ptr, (PropertyRNA *)bprop);
rna_property_boolean_fill_default_array_values(
bprop->defaultarray, length, bprop->defaultvalue, out_length, r_values);
}
void RNA_property_boolean_get_array(PointerRNA *ptr, PropertyRNA *prop, bool *values)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
if (prop->arraydimension == 0) {
values[0] = RNA_property_boolean_get(ptr, prop);
}
else {
int *values_src = IDP_Array(idprop);
for (uint i = 0; i < idprop->len; i++) {
values[i] = (bool)values_src[i];
}
}
}
else if (prop->arraydimension == 0) {
values[0] = RNA_property_boolean_get(ptr, prop);
}
else if (bprop->getarray) {
bprop->getarray(ptr, values);
}
else if (bprop->getarray_ex) {
bprop->getarray_ex(ptr, prop, values);
}
else {
rna_property_boolean_get_default_array_values(ptr, bprop, values);
}
}
bool RNA_property_boolean_get_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
bool tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
bool value;
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_boolean_get_array(ptr, prop, tmp);
value = tmp[index];
}
else {
bool *tmparray;
tmparray = MEM_mallocN(sizeof(bool) * len, __func__);
RNA_property_boolean_get_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
}
BLI_assert(ELEM(value, false, true));
return value;
}
void RNA_property_boolean_set_array(PointerRNA *ptr, PropertyRNA *prop, const bool *values)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
if (prop->arraydimension == 0) {
IDP_Int(idprop) = values[0];
}
else {
int *values_dst = IDP_Array(idprop);
for (uint i = 0; i < idprop->len; i++) {
values_dst[i] = (int)values[i];
}
}
rna_idproperty_touch(idprop);
}
else if (prop->arraydimension == 0) {
RNA_property_boolean_set(ptr, prop, values[0]);
}
else if (bprop->setarray) {
bprop->setarray(ptr, values);
}
else if (bprop->setarray_ex) {
bprop->setarray_ex(ptr, prop, values);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
val.array.len = prop->totarraylength;
val.array.type = IDP_INT;
group = RNA_struct_idprops(ptr, 1);
if (group) {
idprop = IDP_New(IDP_ARRAY, &val, prop->identifier);
IDP_AddToGroup(group, idprop);
int *values_dst = IDP_Array(idprop);
for (uint i = 0; i < idprop->len; i++) {
values_dst[i] = (int)values[i];
}
}
}
}
void RNA_property_boolean_set_index(PointerRNA *ptr, PropertyRNA *prop, int index, bool value)
{
bool tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
BLI_assert(ELEM(value, false, true));
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_boolean_get_array(ptr, prop, tmp);
tmp[index] = value;
RNA_property_boolean_set_array(ptr, prop, tmp);
}
else {
bool *tmparray;
tmparray = MEM_mallocN(sizeof(bool) * len, __func__);
RNA_property_boolean_get_array(ptr, prop, tmparray);
tmparray[index] = value;
RNA_property_boolean_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
}
bool RNA_property_boolean_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *prop)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) == false);
BLI_assert(ELEM(bprop->defaultvalue, false, true));
return bprop->defaultvalue;
}
void RNA_property_boolean_get_default_array(PointerRNA *ptr, PropertyRNA *prop, bool *values)
{
BoolPropertyRNA *bprop = (BoolPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
if (prop->arraydimension == 0) {
values[0] = bprop->defaultvalue;
}
else {
rna_property_boolean_get_default_array_values(ptr, bprop, values);
}
}
bool RNA_property_boolean_get_default_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
bool tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_BOOLEAN);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_boolean_get_default_array(ptr, prop, tmp);
return tmp[index];
}
else {
bool *tmparray, value;
tmparray = MEM_mallocN(sizeof(bool) * len, __func__);
RNA_property_boolean_get_default_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
return value;
}
}
int RNA_property_int_get(PointerRNA *ptr, PropertyRNA *prop)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) == false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
return IDP_Int(idprop);
}
else if (iprop->get) {
return iprop->get(ptr);
}
else if (iprop->get_ex) {
return iprop->get_ex(ptr, prop);
}
else {
return iprop->defaultvalue;
}
}
void RNA_property_int_set(PointerRNA *ptr, PropertyRNA *prop, int value)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) == false);
/* useful to check on bad values but set function should clamp */
/* BLI_assert(RNA_property_int_clamp(ptr, prop, &value) == 0); */
if ((idprop = rna_idproperty_check(&prop, ptr))) {
RNA_property_int_clamp(ptr, prop, &value);
IDP_Int(idprop) = value;
rna_idproperty_touch(idprop);
}
else if (iprop->set) {
iprop->set(ptr, value);
}
else if (iprop->set_ex) {
iprop->set_ex(ptr, prop, value);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
RNA_property_int_clamp(ptr, prop, &value);
val.i = value;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group, IDP_New(IDP_INT, &val, prop->identifier));
}
}
}
static void rna_property_int_fill_default_array_values(
const int *defarr, int defarr_length, int defvalue, int out_length, int *r_values)
{
if (defarr && defarr_length > 0) {
defarr_length = MIN2(defarr_length, out_length);
memcpy(r_values, defarr, sizeof(int) * defarr_length);
}
else {
defarr_length = 0;
}
for (int i = defarr_length; i < out_length; i++) {
r_values[i] = defvalue;
}
}
static void rna_property_int_get_default_array_values(PointerRNA *ptr,
IntPropertyRNA *iprop,
int *r_values)
{
int length = iprop->property.totarraylength;
int out_length = RNA_property_array_length(ptr, (PropertyRNA *)iprop);
rna_property_int_fill_default_array_values(
iprop->defaultarray, length, iprop->defaultvalue, out_length, r_values);
}
void RNA_property_int_get_array(PointerRNA *ptr, PropertyRNA *prop, int *values)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
BLI_assert(idprop->len == RNA_property_array_length(ptr, prop) ||
(prop->flag & PROP_IDPROPERTY));
if (prop->arraydimension == 0) {
values[0] = RNA_property_int_get(ptr, prop);
}
else {
memcpy(values, IDP_Array(idprop), sizeof(int) * idprop->len);
}
}
else if (prop->arraydimension == 0) {
values[0] = RNA_property_int_get(ptr, prop);
}
else if (iprop->getarray) {
iprop->getarray(ptr, values);
}
else if (iprop->getarray_ex) {
iprop->getarray_ex(ptr, prop, values);
}
else {
rna_property_int_get_default_array_values(ptr, iprop, values);
}
}
void RNA_property_int_get_array_range(PointerRNA *ptr, PropertyRNA *prop, int values[2])
{
const int array_len = RNA_property_array_length(ptr, prop);
if (array_len <= 0) {
values[0] = 0;
values[1] = 0;
}
else if (array_len == 1) {
RNA_property_int_get_array(ptr, prop, values);
values[1] = values[0];
}
else {
int arr_stack[32];
int *arr;
int i;
if (array_len > 32) {
arr = MEM_mallocN(sizeof(int) * array_len, __func__);
}
else {
arr = arr_stack;
}
RNA_property_int_get_array(ptr, prop, arr);
values[0] = values[1] = arr[0];
for (i = 1; i < array_len; i++) {
values[0] = MIN2(values[0], arr[i]);
values[1] = MAX2(values[1], arr[i]);
}
if (arr != arr_stack) {
MEM_freeN(arr);
}
}
}
int RNA_property_int_get_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
int tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_int_get_array(ptr, prop, tmp);
return tmp[index];
}
else {
int *tmparray, value;
tmparray = MEM_mallocN(sizeof(int) * len, __func__);
RNA_property_int_get_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
return value;
}
}
void RNA_property_int_set_array(PointerRNA *ptr, PropertyRNA *prop, const int *values)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
BLI_assert(idprop->len == RNA_property_array_length(ptr, prop) ||
(prop->flag & PROP_IDPROPERTY));
if (prop->arraydimension == 0) {
IDP_Int(idprop) = values[0];
}
else {
memcpy(IDP_Array(idprop), values, sizeof(int) * idprop->len);
}
rna_idproperty_touch(idprop);
}
else if (prop->arraydimension == 0) {
RNA_property_int_set(ptr, prop, values[0]);
}
else if (iprop->setarray) {
iprop->setarray(ptr, values);
}
else if (iprop->setarray_ex) {
iprop->setarray_ex(ptr, prop, values);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
/* TODO: RNA_property_int_clamp_array(ptr, prop, &value); */
val.array.len = prop->totarraylength;
val.array.type = IDP_INT;
group = RNA_struct_idprops(ptr, 1);
if (group) {
idprop = IDP_New(IDP_ARRAY, &val, prop->identifier);
IDP_AddToGroup(group, idprop);
memcpy(IDP_Array(idprop), values, sizeof(int) * idprop->len);
}
}
}
void RNA_property_int_set_index(PointerRNA *ptr, PropertyRNA *prop, int index, int value)
{
int tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_int_get_array(ptr, prop, tmp);
tmp[index] = value;
RNA_property_int_set_array(ptr, prop, tmp);
}
else {
int *tmparray;
tmparray = MEM_mallocN(sizeof(int) * len, __func__);
RNA_property_int_get_array(ptr, prop, tmparray);
tmparray[index] = value;
RNA_property_int_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
}
int RNA_property_int_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *prop)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)rna_ensure_property(prop);
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "default", IDP_INT);
return item ? IDP_Int(item) : iprop->defaultvalue;
}
}
return iprop->defaultvalue;
}
bool RNA_property_int_set_default(PointerRNA *ptr, PropertyRNA *prop, int value)
{
if (value != 0) {
IDPropertyTemplate val = {
.i = value,
};
return rna_idproperty_ui_set_default(ptr, prop, IDP_INT, &val);
}
else {
return rna_idproperty_ui_set_default(ptr, prop, IDP_INT, NULL);
}
}
void RNA_property_int_get_default_array(PointerRNA *ptr, PropertyRNA *prop, int *values)
{
IntPropertyRNA *iprop = (IntPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
if (prop->magic != RNA_MAGIC) {
int length = rna_ensure_property_array_length(ptr, prop);
IDProperty *idp_ui = rna_idproperty_ui(prop);
IDProperty *item = idp_ui ? IDP_GetPropertyFromGroup(idp_ui, "default") : NULL;
int defval = (item && item->type == IDP_INT) ? IDP_Int(item) : iprop->defaultvalue;
if (item && item->type == IDP_ARRAY && item->subtype == IDP_INT) {
rna_property_int_fill_default_array_values(
IDP_Array(item), item->len, defval, length, values);
}
else {
rna_property_int_fill_default_array_values(NULL, 0, defval, length, values);
}
}
else if (prop->arraydimension == 0) {
values[0] = iprop->defaultvalue;
}
else {
rna_property_int_get_default_array_values(ptr, iprop, values);
}
}
int RNA_property_int_get_default_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
int tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_INT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_int_get_default_array(ptr, prop, tmp);
return tmp[index];
}
else {
int *tmparray, value;
tmparray = MEM_mallocN(sizeof(int) * len, __func__);
RNA_property_int_get_default_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
return value;
}
}
float RNA_property_float_get(PointerRNA *ptr, PropertyRNA *prop)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) == false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
if (idprop->type == IDP_FLOAT) {
return IDP_Float(idprop);
}
else {
return (float)IDP_Double(idprop);
}
}
else if (fprop->get) {
return fprop->get(ptr);
}
else if (fprop->get_ex) {
return fprop->get_ex(ptr, prop);
}
else {
return fprop->defaultvalue;
}
}
void RNA_property_float_set(PointerRNA *ptr, PropertyRNA *prop, float value)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) == false);
/* useful to check on bad values but set function should clamp */
/* BLI_assert(RNA_property_float_clamp(ptr, prop, &value) == 0); */
if ((idprop = rna_idproperty_check(&prop, ptr))) {
RNA_property_float_clamp(ptr, prop, &value);
if (idprop->type == IDP_FLOAT) {
IDP_Float(idprop) = value;
}
else {
IDP_Double(idprop) = value;
}
rna_idproperty_touch(idprop);
}
else if (fprop->set) {
fprop->set(ptr, value);
}
else if (fprop->set_ex) {
fprop->set_ex(ptr, prop, value);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
RNA_property_float_clamp(ptr, prop, &value);
val.f = value;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group, IDP_New(IDP_FLOAT, &val, prop->identifier));
}
}
}
static void rna_property_float_fill_default_array_values(
const float *defarr, int defarr_length, float defvalue, int out_length, float *r_values)
{
if (defarr && defarr_length > 0) {
defarr_length = MIN2(defarr_length, out_length);
memcpy(r_values, defarr, sizeof(float) * defarr_length);
}
else {
defarr_length = 0;
}
for (int i = defarr_length; i < out_length; i++) {
r_values[i] = defvalue;
}
}
static void rna_property_float_get_default_array_values(PointerRNA *ptr,
FloatPropertyRNA *fprop,
float *r_values)
{
int length = fprop->property.totarraylength;
int out_length = RNA_property_array_length(ptr, (PropertyRNA *)fprop);
rna_property_float_fill_default_array_values(
fprop->defaultarray, length, fprop->defaultvalue, out_length, r_values);
}
void RNA_property_float_get_array(PointerRNA *ptr, PropertyRNA *prop, float *values)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)prop;
IDProperty *idprop;
int i;
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
BLI_assert(idprop->len == RNA_property_array_length(ptr, prop) ||
(prop->flag & PROP_IDPROPERTY));
if (prop->arraydimension == 0) {
values[0] = RNA_property_float_get(ptr, prop);
}
else if (idprop->subtype == IDP_FLOAT) {
memcpy(values, IDP_Array(idprop), sizeof(float) * idprop->len);
}
else {
for (i = 0; i < idprop->len; i++) {
values[i] = (float)(((double *)IDP_Array(idprop))[i]);
}
}
}
else if (prop->arraydimension == 0) {
values[0] = RNA_property_float_get(ptr, prop);
}
else if (fprop->getarray) {
fprop->getarray(ptr, values);
}
else if (fprop->getarray_ex) {
fprop->getarray_ex(ptr, prop, values);
}
else {
rna_property_float_get_default_array_values(ptr, fprop, values);
}
}
void RNA_property_float_get_array_range(PointerRNA *ptr, PropertyRNA *prop, float values[2])
{
const int array_len = RNA_property_array_length(ptr, prop);
if (array_len <= 0) {
values[0] = 0.0f;
values[1] = 0.0f;
}
else if (array_len == 1) {
RNA_property_float_get_array(ptr, prop, values);
values[1] = values[0];
}
else {
float arr_stack[32];
float *arr;
int i;
if (array_len > 32) {
arr = MEM_mallocN(sizeof(float) * array_len, __func__);
}
else {
arr = arr_stack;
}
RNA_property_float_get_array(ptr, prop, arr);
values[0] = values[1] = arr[0];
for (i = 1; i < array_len; i++) {
values[0] = MIN2(values[0], arr[i]);
values[1] = MAX2(values[1], arr[i]);
}
if (arr != arr_stack) {
MEM_freeN(arr);
}
}
}
float RNA_property_float_get_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
float tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_float_get_array(ptr, prop, tmp);
return tmp[index];
}
else {
float *tmparray, value;
tmparray = MEM_mallocN(sizeof(float) * len, __func__);
RNA_property_float_get_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
return value;
}
}
void RNA_property_float_set_array(PointerRNA *ptr, PropertyRNA *prop, const float *values)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)prop;
IDProperty *idprop;
int i;
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
BLI_assert(idprop->len == RNA_property_array_length(ptr, prop) ||
(prop->flag & PROP_IDPROPERTY));
if (prop->arraydimension == 0) {
if (idprop->type == IDP_FLOAT) {
IDP_Float(idprop) = values[0];
}
else {
IDP_Double(idprop) = values[0];
}
}
else if (idprop->subtype == IDP_FLOAT) {
memcpy(IDP_Array(idprop), values, sizeof(float) * idprop->len);
}
else {
for (i = 0; i < idprop->len; i++) {
((double *)IDP_Array(idprop))[i] = values[i];
}
}
rna_idproperty_touch(idprop);
}
else if (prop->arraydimension == 0) {
RNA_property_float_set(ptr, prop, values[0]);
}
else if (fprop->setarray) {
fprop->setarray(ptr, values);
}
else if (fprop->setarray_ex) {
fprop->setarray_ex(ptr, prop, values);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
/* TODO: RNA_property_float_clamp_array(ptr, prop, &value); */
val.array.len = prop->totarraylength;
val.array.type = IDP_FLOAT;
group = RNA_struct_idprops(ptr, 1);
if (group) {
idprop = IDP_New(IDP_ARRAY, &val, prop->identifier);
IDP_AddToGroup(group, idprop);
memcpy(IDP_Array(idprop), values, sizeof(float) * idprop->len);
}
}
}
void RNA_property_float_set_index(PointerRNA *ptr, PropertyRNA *prop, int index, float value)
{
float tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_float_get_array(ptr, prop, tmp);
tmp[index] = value;
RNA_property_float_set_array(ptr, prop, tmp);
}
else {
float *tmparray;
tmparray = MEM_mallocN(sizeof(float) * len, __func__);
RNA_property_float_get_array(ptr, prop, tmparray);
tmparray[index] = value;
RNA_property_float_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
}
float RNA_property_float_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *prop)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) == false);
if (prop->magic != RNA_MAGIC) {
/* attempt to get the local ID values */
IDProperty *idp_ui = rna_idproperty_ui(prop);
if (idp_ui) {
IDProperty *item;
item = IDP_GetPropertyTypeFromGroup(idp_ui, "default", IDP_DOUBLE);
return item ? IDP_Double(item) : fprop->defaultvalue;
}
}
return fprop->defaultvalue;
}
bool RNA_property_float_set_default(PointerRNA *ptr, PropertyRNA *prop, float value)
{
if (value != 0) {
IDPropertyTemplate val = {
.d = value,
};
return rna_idproperty_ui_set_default(ptr, prop, IDP_DOUBLE, &val);
}
else {
return rna_idproperty_ui_set_default(ptr, prop, IDP_DOUBLE, NULL);
}
}
void RNA_property_float_get_default_array(PointerRNA *ptr, PropertyRNA *prop, float *values)
{
FloatPropertyRNA *fprop = (FloatPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
if (prop->magic != RNA_MAGIC) {
int length = rna_ensure_property_array_length(ptr, prop);
IDProperty *idp_ui = rna_idproperty_ui(prop);
IDProperty *item = idp_ui ? IDP_GetPropertyFromGroup(idp_ui, "default") : NULL;
float defval = (item && item->type == IDP_DOUBLE) ? IDP_Double(item) : fprop->defaultvalue;
if (item && item->type == IDP_ARRAY && item->subtype == IDP_DOUBLE) {
double *defarr = IDP_Array(item);
for (int i = 0; i < length; i++) {
values[i] = (i < item->len) ? (float)defarr[i] : defval;
}
}
else if (item && item->type == IDP_ARRAY && item->subtype == IDP_FLOAT) {
rna_property_float_fill_default_array_values(
IDP_Array(item), item->len, defval, length, values);
}
else {
rna_property_float_fill_default_array_values(NULL, 0, defval, length, values);
}
}
else if (prop->arraydimension == 0) {
values[0] = fprop->defaultvalue;
}
else {
rna_property_float_get_default_array_values(ptr, fprop, values);
}
}
float RNA_property_float_get_default_index(PointerRNA *ptr, PropertyRNA *prop, int index)
{
float tmp[RNA_MAX_ARRAY_LENGTH];
int len = rna_ensure_property_array_length(ptr, prop);
BLI_assert(RNA_property_type(prop) == PROP_FLOAT);
BLI_assert(RNA_property_array_check(prop) != false);
BLI_assert(index >= 0);
BLI_assert(index < len);
if (len <= RNA_MAX_ARRAY_LENGTH) {
RNA_property_float_get_default_array(ptr, prop, tmp);
return tmp[index];
}
else {
float *tmparray, value;
tmparray = MEM_mallocN(sizeof(float) * len, __func__);
RNA_property_float_get_default_array(ptr, prop, tmparray);
value = tmparray[index];
MEM_freeN(tmparray);
return value;
}
}
void RNA_property_string_get(PointerRNA *ptr, PropertyRNA *prop, char *value)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
/* editing bytes is not 100% supported
* since they can contain NIL chars */
if (idprop->subtype == IDP_STRING_SUB_BYTE) {
memcpy(value, IDP_String(idprop), idprop->len);
value[idprop->len] = '\0';
}
else {
memcpy(value, IDP_String(idprop), idprop->len);
}
}
else if (sprop->get) {
sprop->get(ptr, value);
}
else if (sprop->get_ex) {
sprop->get_ex(ptr, prop, value);
}
else {
strcpy(value, sprop->defaultvalue);
}
}
char *RNA_property_string_get_alloc(
PointerRNA *ptr, PropertyRNA *prop, char *fixedbuf, int fixedlen, int *r_len)
{
char *buf;
int length;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
length = RNA_property_string_length(ptr, prop);
if (length + 1 < fixedlen) {
buf = fixedbuf;
}
else {
buf = MEM_mallocN(sizeof(char) * (length + 1), "RNA_string_get_alloc");
}
#ifndef NDEBUG
/* safety check to ensure the string is actually set */
buf[length] = 255;
#endif
RNA_property_string_get(ptr, prop, buf);
#ifndef NDEBUG
BLI_assert(buf[length] == '\0');
#endif
if (r_len) {
*r_len = length;
}
return buf;
}
/* this is the length without \0 terminator */
int RNA_property_string_length(PointerRNA *ptr, PropertyRNA *prop)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
if (idprop->subtype == IDP_STRING_SUB_BYTE) {
return idprop->len;
}
else {
#ifndef NDEBUG
/* these _must_ stay in sync */
BLI_assert(strlen(IDP_String(idprop)) == idprop->len - 1);
#endif
return idprop->len - 1;
}
}
else if (sprop->length) {
return sprop->length(ptr);
}
else if (sprop->length_ex) {
return sprop->length_ex(ptr, prop);
}
else {
return strlen(sprop->defaultvalue);
}
}
void RNA_property_string_set(PointerRNA *ptr, PropertyRNA *prop, const char *value)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
/* both IDP_STRING_SUB_BYTE / IDP_STRING_SUB_UTF8 */
IDP_AssignString(idprop, value, RNA_property_string_maxlength(prop) - 1);
rna_idproperty_touch(idprop);
}
else if (sprop->set) {
sprop->set(ptr, value); /* set function needs to clamp its self */
}
else if (sprop->set_ex) {
sprop->set_ex(ptr, prop, value); /* set function needs to clamp its self */
}
else if (prop->flag & PROP_EDITABLE) {
IDProperty *group;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group,
IDP_NewString(value, prop->identifier, RNA_property_string_maxlength(prop)));
}
}
}
void RNA_property_string_set_bytes(PointerRNA *ptr, PropertyRNA *prop, const char *value, int len)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
BLI_assert(RNA_property_subtype(prop) == PROP_BYTESTRING);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDP_ResizeArray(idprop, len);
memcpy(idprop->data.pointer, value, (size_t)len);
rna_idproperty_touch(idprop);
}
else if (sprop->set) {
/* XXX, should take length argument (currently not used). */
sprop->set(ptr, value); /* set function needs to clamp its self */
}
else if (sprop->set_ex) {
/* XXX, should take length argument (currently not used). */
sprop->set_ex(ptr, prop, value); /* set function needs to clamp its self */
}
else if (prop->flag & PROP_EDITABLE) {
IDProperty *group;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDPropertyTemplate val = {0};
val.string.str = value;
val.string.len = len;
val.string.subtype = IDP_STRING_SUB_BYTE;
IDP_AddToGroup(group, IDP_New(IDP_STRING, &val, prop->identifier));
}
}
}
void RNA_property_string_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *prop, char *value)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_STRING);
strcpy(value, sprop->defaultvalue);
}
char *RNA_property_string_get_default_alloc(PointerRNA *ptr,
PropertyRNA *prop,
char *fixedbuf,
int fixedlen)
{
char *buf;
int length;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
length = RNA_property_string_default_length(ptr, prop);
if (length + 1 < fixedlen) {
buf = fixedbuf;
}
else {
buf = MEM_callocN(sizeof(char) * (length + 1), "RNA_string_get_alloc");
}
RNA_property_string_get_default(ptr, prop, buf);
return buf;
}
/* this is the length without \0 terminator */
int RNA_property_string_default_length(PointerRNA *UNUSED(ptr), PropertyRNA *prop)
{
StringPropertyRNA *sprop = (StringPropertyRNA *)prop;
BLI_assert(RNA_property_type(prop) == PROP_STRING);
return strlen(sprop->defaultvalue);
}
int RNA_property_enum_get(PointerRNA *ptr, PropertyRNA *prop)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_ENUM);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
return IDP_Int(idprop);
}
else if (eprop->get) {
return eprop->get(ptr);
}
else if (eprop->get_ex) {
return eprop->get_ex(ptr, prop);
}
else {
return eprop->defaultvalue;
}
}
void RNA_property_enum_set(PointerRNA *ptr, PropertyRNA *prop, int value)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_ENUM);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDP_Int(idprop) = value;
rna_idproperty_touch(idprop);
}
else if (eprop->set) {
eprop->set(ptr, value);
}
else if (eprop->set_ex) {
eprop->set_ex(ptr, prop, value);
}
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
val.i = value;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group, IDP_New(IDP_INT, &val, prop->identifier));
}
}
}
int RNA_property_enum_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *prop)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_ENUM);
return eprop->defaultvalue;
}
void *RNA_property_enum_py_data_get(PropertyRNA *prop)
{
EnumPropertyRNA *eprop = (EnumPropertyRNA *)prop;
BLI_assert(RNA_property_type(prop) == PROP_ENUM);
return eprop->py_data;
}
/**
* Get the value of the item that is \a step items away from \a from_value.
*
* \param from_value: Item value to start stepping from.
* \param step: Absolute value defines step size, sign defines direction.
* E.g to get the next item, pass 1, for the previous -1.
*/
int RNA_property_enum_step(
const bContext *C, PointerRNA *ptr, PropertyRNA *prop, int from_value, int step)
{
const EnumPropertyItem *item_array;
int totitem;
bool free;
int result_value = from_value;
int i, i_init;
int single_step = (step < 0) ? -1 : 1;
int step_tot = 0;
RNA_property_enum_items((bContext *)C, ptr, prop, &item_array, &totitem, &free);
i = RNA_enum_from_value(item_array, from_value);
i_init = i;
do {
i = mod_i(i + single_step, totitem);
if (item_array[i].identifier[0]) {
step_tot += single_step;
}
} while ((i != i_init) && (step_tot != step));
if (i != i_init) {
result_value = item_array[i].value;
}
if (free) {
MEM_freeN((void *)item_array);
}
return result_value;
}
PointerRNA RNA_property_pointer_get(PointerRNA *ptr, PropertyRNA *prop)
{
PointerPropertyRNA *pprop = (PointerPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_POINTER);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
pprop = (PointerPropertyRNA *)prop;
if (RNA_struct_is_ID(pprop->type)) {
return rna_pointer_inherit_refine(ptr, pprop->type, IDP_Id(idprop));
}
/* for groups, data is idprop itself */
if (pprop->typef) {
return rna_pointer_inherit_refine(ptr, pprop->typef(ptr), idprop);
}
else {
return rna_pointer_inherit_refine(ptr, pprop->type, idprop);
}
}
else if (pprop->get) {
return pprop->get(ptr);
}
else if (prop->flag & PROP_IDPROPERTY) {
/* XXX temporary hack to add it automatically, reading should
* never do any write ops, to ensure thread safety etc .. */
RNA_property_pointer_add(ptr, prop);
return RNA_property_pointer_get(ptr, prop);
}
else {
return PointerRNA_NULL;
}
}
void RNA_property_pointer_set(PointerRNA *ptr,
PropertyRNA *prop,
PointerRNA ptr_value,
ReportList *reports)
{
PointerPropertyRNA *pprop = (PointerPropertyRNA *)prop;
BLI_assert(RNA_property_type(prop) == PROP_POINTER);
/* Check types */
if (ptr_value.type != NULL && !RNA_struct_is_a(ptr_value.type, pprop->type)) {
BKE_reportf(reports,
RPT_ERROR,
"%s: expected %s type, not %s.\n",
__func__,
pprop->type->identifier,
ptr_value.type->identifier);
return;
}
/* RNA */
if (pprop->set && !((prop->flag & PROP_NEVER_NULL) && ptr_value.data == NULL) &&
!((prop->flag & PROP_ID_SELF_CHECK) && ptr->owner_id == ptr_value.owner_id)) {
pprop->set(ptr, ptr_value, reports);
}
/* IDProperty */
else if (prop->flag & PROP_EDITABLE) {
IDPropertyTemplate val = {0};
IDProperty *group;
val.id = ptr_value.data;
group = RNA_struct_idprops(ptr, true);
if (group) {
IDP_ReplaceInGroup(group, IDP_New(IDP_ID, &val, prop->identifier));
}
}
}
PointerRNA RNA_property_pointer_get_default(PointerRNA *UNUSED(ptr), PropertyRNA *UNUSED(prop))
{
/*PointerPropertyRNA *pprop = (PointerPropertyRNA *)prop; */
/* BLI_assert(RNA_property_type(prop) == PROP_POINTER); */
return PointerRNA_NULL; /* FIXME: there has to be a way... */
}
void RNA_property_pointer_add(PointerRNA *ptr, PropertyRNA *prop)
{
/*IDProperty *idprop;*/
BLI_assert(RNA_property_type(prop) == PROP_POINTER);
if ((/*idprop=*/rna_idproperty_check(&prop, ptr))) {
/* already exists */
}
else if (prop->flag & PROP_IDPROPERTY) {
IDPropertyTemplate val = {0};
IDProperty *group;
val.i = 0;
group = RNA_struct_idprops(ptr, 1);
if (group) {
IDP_AddToGroup(group, IDP_New(IDP_GROUP, &val, prop->identifier));
}
}
else {
printf("%s %s.%s: only supported for id properties.\n",
__func__,
ptr->type->identifier,
prop->identifier);
}
}
void RNA_property_pointer_remove(PointerRNA *ptr, PropertyRNA *prop)
{
IDProperty *idprop, *group;
BLI_assert(RNA_property_type(prop) == PROP_POINTER);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
group = RNA_struct_idprops(ptr, 0);
if (group) {
IDP_FreeFromGroup(group, idprop);
}
}
else {
printf("%s %s.%s: only supported for id properties.\n",
__func__,
ptr->type->identifier,
prop->identifier);
}
}
static void rna_property_collection_get_idp(CollectionPropertyIterator *iter)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)iter->prop;
iter->ptr.data = rna_iterator_array_get(iter);
iter->ptr.type = cprop->item_type;
rna_pointer_inherit_id(cprop->item_type, &iter->parent, &iter->ptr);
}
void RNA_property_collection_begin(PointerRNA *ptr,
PropertyRNA *prop,
CollectionPropertyIterator *iter)
{
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
memset(iter, 0, sizeof(*iter));
if ((idprop = rna_idproperty_check(&prop, ptr)) || (prop->flag & PROP_IDPROPERTY)) {
iter->parent = *ptr;
iter->prop = prop;
if (idprop) {
rna_iterator_array_begin(
iter, IDP_IDPArray(idprop), sizeof(IDProperty), idprop->len, 0, NULL);
}
else {
rna_iterator_array_begin(iter, NULL, sizeof(IDProperty), 0, 0, NULL);
}
if (iter->valid) {
rna_property_collection_get_idp(iter);
}
iter->idprop = 1;
}
else {
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop;
cprop->begin(iter, ptr);
}
}
void RNA_property_collection_next(CollectionPropertyIterator *iter)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(iter->prop);
if (iter->idprop) {
rna_iterator_array_next(iter);
if (iter->valid) {
rna_property_collection_get_idp(iter);
}
}
else {
cprop->next(iter);
}
}
void RNA_property_collection_skip(CollectionPropertyIterator *iter, int num)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(iter->prop);
int i;
if (num > 1 && (iter->idprop || (cprop->property.flag_internal & PROP_INTERN_RAW_ARRAY))) {
/* fast skip for array */
ArrayIterator *internal = &iter->internal.array;
if (!internal->skip) {
internal->ptr += internal->itemsize * (num - 1);
iter->valid = (internal->ptr < internal->endptr);
if (iter->valid) {
RNA_property_collection_next(iter);
}
return;
}
}
/* slow iteration otherwise */
for (i = 0; i < num && iter->valid; i++) {
RNA_property_collection_next(iter);
}
}
void RNA_property_collection_end(CollectionPropertyIterator *iter)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(iter->prop);
if (iter->idprop) {
rna_iterator_array_end(iter);
}
else {
cprop->end(iter);
}
}
int RNA_property_collection_length(PointerRNA *ptr, PropertyRNA *prop)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop;
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
return idprop->len;
}
else if (cprop->length) {
return cprop->length(ptr);
}
else {
CollectionPropertyIterator iter;
int length = 0;
RNA_property_collection_begin(ptr, prop, &iter);
for (; iter.valid; RNA_property_collection_next(&iter)) {
length++;
}
RNA_property_collection_end(&iter);
return length;
}
}
void RNA_property_collection_add(PointerRNA *ptr, PropertyRNA *prop, PointerRNA *r_ptr)
{
IDProperty *idprop;
/* CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop; */
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDPropertyTemplate val = {0};
IDProperty *item;
item = IDP_New(IDP_GROUP, &val, "");
IDP_AppendArray(idprop, item);
/* IDP_AppendArray does a shallow copy (memcpy), only free memory */
/* IDP_FreePropertyContent(item); */
MEM_freeN(item);
rna_idproperty_touch(idprop);
}
else if (prop->flag & PROP_IDPROPERTY) {
IDProperty *group, *item;
IDPropertyTemplate val = {0};
group = RNA_struct_idprops(ptr, 1);
if (group) {
idprop = IDP_NewIDPArray(prop->identifier);
IDP_AddToGroup(group, idprop);
item = IDP_New(IDP_GROUP, &val, "");
IDP_AppendArray(idprop, item);
/* IDP_AppendArray does a shallow copy (memcpy), only free memory */
/* IDP_FreePropertyContent(item); */
MEM_freeN(item);
}
}
/* py api calls directly */
#if 0
else if (cprop->add) {
if (!(cprop->add->flag & FUNC_USE_CONTEXT)) { /* XXX check for this somewhere else */
ParameterList params;
RNA_parameter_list_create(&params, ptr, cprop->add);
RNA_function_call(NULL, NULL, ptr, cprop->add, &params);
RNA_parameter_list_free(&params);
}
}
# if 0
else {
printf("%s %s.%s: not implemented for this property.\n",
__func__,
ptr->type->identifier,
prop->identifier);
}
# endif
#endif
if (r_ptr) {
if (idprop) {
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop;
r_ptr->data = IDP_GetIndexArray(idprop, idprop->len - 1);
r_ptr->type = cprop->item_type;
rna_pointer_inherit_id(NULL, ptr, r_ptr);
}
else {
memset(r_ptr, 0, sizeof(*r_ptr));
}
}
}
bool RNA_property_collection_remove(PointerRNA *ptr, PropertyRNA *prop, int key)
{
IDProperty *idprop;
/* CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)prop; */
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDProperty tmp, *array;
int len;
len = idprop->len;
array = IDP_IDPArray(idprop);
if (key >= 0 && key < len) {
if (key + 1 < len) {
/* move element to be removed to the back */
memcpy(&tmp, &array[key], sizeof(IDProperty));
memmove(array + key, array + key + 1, sizeof(IDProperty) * (len - (key + 1)));
memcpy(&array[len - 1], &tmp, sizeof(IDProperty));
}
IDP_ResizeIDPArray(idprop, len - 1);
}
return true;
}
else if (prop->flag & PROP_IDPROPERTY) {
return true;
}
/* py api calls directly */
#if 0
else if (cprop->remove) {
if (!(cprop->remove->flag & FUNC_USE_CONTEXT)) { /* XXX check for this somewhere else */
ParameterList params;
RNA_parameter_list_create(&params, ptr, cprop->remove);
RNA_function_call(NULL, NULL, ptr, cprop->remove, &params);
RNA_parameter_list_free(&params);
}
return false;
}
# if 0
else {
printf("%s %s.%s: only supported for id properties.\n",
__func__,
ptr->type->identifier,
prop->identifier);
}
# endif
#endif
return false;
}
bool RNA_property_collection_move(PointerRNA *ptr, PropertyRNA *prop, int key, int pos)
{
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDProperty tmp, *array;
int len;
len = idprop->len;
array = IDP_IDPArray(idprop);
if (key >= 0 && key < len && pos >= 0 && pos < len && key != pos) {
memcpy(&tmp, &array[key], sizeof(IDProperty));
if (pos < key) {
memmove(array + pos + 1, array + pos, sizeof(IDProperty) * (key - pos));
}
else {
memmove(array + key, array + key + 1, sizeof(IDProperty) * (pos - key));
}
memcpy(&array[pos], &tmp, sizeof(IDProperty));
}
return true;
}
else if (prop->flag & PROP_IDPROPERTY) {
return true;
}
return false;
}
void RNA_property_collection_clear(PointerRNA *ptr, PropertyRNA *prop)
{
IDProperty *idprop;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if ((idprop = rna_idproperty_check(&prop, ptr))) {
IDP_ResizeIDPArray(idprop, 0);
rna_idproperty_touch(idprop);
}
}
int RNA_property_collection_lookup_index(PointerRNA *ptr, PropertyRNA *prop, PointerRNA *t_ptr)
{
CollectionPropertyIterator iter;
int index = 0;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
RNA_property_collection_begin(ptr, prop, &iter);
for (index = 0; iter.valid; RNA_property_collection_next(&iter), index++) {
if (iter.ptr.data == t_ptr->data) {
break;
}
}
RNA_property_collection_end(&iter);
/* did we find it? */
if (iter.valid) {
return index;
}
else {
return -1;
}
}
int RNA_property_collection_lookup_int(PointerRNA *ptr,
PropertyRNA *prop,
int key,
PointerRNA *r_ptr)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if (cprop->lookupint) {
/* we have a callback defined, use it */
return cprop->lookupint(ptr, key, r_ptr);
}
else {
/* no callback defined, just iterate and find the nth item */
CollectionPropertyIterator iter;
int i;
RNA_property_collection_begin(ptr, prop, &iter);
for (i = 0; iter.valid; RNA_property_collection_next(&iter), i++) {
if (i == key) {
*r_ptr = iter.ptr;
break;
}
}
RNA_property_collection_end(&iter);
if (!iter.valid) {
memset(r_ptr, 0, sizeof(*r_ptr));
}
return iter.valid;
}
}
int RNA_property_collection_lookup_string(PointerRNA *ptr,
PropertyRNA *prop,
const char *key,
PointerRNA *r_ptr)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if (cprop->lookupstring) {
/* we have a callback defined, use it */
return cprop->lookupstring(ptr, key, r_ptr);
}
else {
/* no callback defined, compare with name properties if they exist */
CollectionPropertyIterator iter;
PropertyRNA *nameprop;
char name[256], *nameptr;
int found = 0;
int keylen = strlen(key);
int namelen;
RNA_property_collection_begin(ptr, prop, &iter);
for (; iter.valid; RNA_property_collection_next(&iter)) {
if (iter.ptr.data && iter.ptr.type->nameproperty) {
nameprop = iter.ptr.type->nameproperty;
nameptr = RNA_property_string_get_alloc(&iter.ptr, nameprop, name, sizeof(name), &namelen);
if ((keylen == namelen) && STREQ(nameptr, key)) {
*r_ptr = iter.ptr;
found = 1;
}
if ((char *)&name != nameptr) {
MEM_freeN(nameptr);
}
if (found) {
break;
}
}
}
RNA_property_collection_end(&iter);
if (!iter.valid) {
memset(r_ptr, 0, sizeof(*r_ptr));
}
return iter.valid;
}
}
/* zero return is an assignment error */
int RNA_property_collection_assign_int(PointerRNA *ptr,
PropertyRNA *prop,
const int key,
const PointerRNA *assign_ptr)
{
CollectionPropertyRNA *cprop = (CollectionPropertyRNA *)rna_ensure_property(prop);
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if (cprop->assignint) {
/* we have a callback defined, use it */
return cprop->assignint(ptr, key, assign_ptr);
}
return 0;
}
bool RNA_property_collection_type_get(PointerRNA *ptr, PropertyRNA *prop, PointerRNA *r_ptr)
{
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
*r_ptr = *ptr;
return ((r_ptr->type = rna_ensure_property(prop)->srna) ? 1 : 0);
}
int RNA_property_collection_raw_array(PointerRNA *ptr,
PropertyRNA *prop,
PropertyRNA *itemprop,
RawArray *array)
{
CollectionPropertyIterator iter;
ArrayIterator *internal;
char *arrayp;
BLI_assert(RNA_property_type(prop) == PROP_COLLECTION);
if (!(prop->flag_internal & PROP_INTERN_RAW_ARRAY) ||
!(itemprop->flag_internal & PROP_INTERN_RAW_ACCESS)) {
return 0;
}
RNA_property_collection_begin(ptr, prop, &iter);
if (iter.valid) {
/* get data from array iterator and item property */
internal = &iter.internal.array;
arrayp = (iter.valid) ? iter.ptr.data : NULL;
if (internal->skip || !RNA_property_editable(&iter.ptr, itemprop)) {
/* we might skip some items, so it's not a proper array */
RNA_property_collection_end(&iter);
return 0;
}
array->array = arrayp + itemprop->rawoffset;
array->stride = internal->itemsize;
array->len = ((char *)internal->endptr - arrayp) / internal->itemsize;
array->type = itemprop->rawtype;
}
else {
memset(array, 0, sizeof(RawArray));
}
RNA_property_collection_end(&iter);
return 1;
}
#define RAW_GET(dtype, var, raw, a) \
{ \
switch (raw.type) { \
case PROP_RAW_CHAR: \
var = (dtype)((char *)raw.array)[a]; \
break; \
case PROP_RAW_SHORT: \
var = (dtype)((short *)raw.array)[a]; \
break; \
case PROP_RAW_INT: \
var = (dtype)((int *)raw.array)[a]; \
break; \
case PROP_RAW_BOOLEAN: \
var = (dtype)((bool *)raw.array)[a]; \
break; \
case PROP_RAW_FLOAT: \
var = (dtype)((float *)raw.array)[a]; \
break; \
case PROP_RAW_DOUBLE: \
var = (dtype)((double *)raw.array)[a]; \
break; \
default: \
var = (dtype)0; \
} \
} \
(void)0
#define RAW_SET(dtype, raw, a, var) \
{ \
switch (raw.type) { \
case PROP_RAW_CHAR: \
((char *)raw.array)[a] = (char)var; \
break; \
case PROP_RAW_SHORT: \
((short *)raw.array)[a] = (short)var; \
break; \
case PROP_RAW_INT: \
((int *)raw.array)[a] = (int)var; \
break; \
case PROP_RAW_BOOLEAN: \
((bool *)raw.array)[a] = (bool)var; \
break; \
case PROP_RAW_FLOAT: \
((float *)raw.array)[a] = (float)var; \
break; \
case PROP_RAW_DOUBLE: \
((double *)raw.array)[a] = (double)var; \
break; \
default: \
break; \
} \
} \
(void)0
int RNA_raw_type_sizeof(RawPropertyType type)
{
switch (type) {
case PROP_RAW_CHAR:
return sizeof(char);
case PROP_RAW_SHORT:
return sizeof(short);
case PROP_RAW_INT:
return sizeof(int);
case PROP_RAW_BOOLEAN:
return sizeof(bool);
case PROP_RAW_FLOAT:
return sizeof(float);
case PROP_RAW_DOUBLE:
return sizeof(double);
default:
return 0;
}
}
static int rna_property_array_length_all_dimensions(PointerRNA *ptr, PropertyRNA *prop)
{
int i, len[RNA_MAX_ARRAY_DIMENSION];
const int dim = RNA_property_array_dimension(ptr, prop, len);
int size;
if (dim == 0) {
return 0;
}
for (size = 1, i = 0; i < dim; i++) {
size *= len[i];
}
return size;
}
static int rna_raw_access(ReportList *reports,
PointerRNA *ptr,
PropertyRNA *prop,
const char *propname,
void *inarray,
RawPropertyType intype,
int inlen,
int set)
{
StructRNA *ptype;
PointerRNA itemptr_base;
PropertyRNA *itemprop, *iprop;
PropertyType itemtype = 0;
RawArray in;
int itemlen = 0;
/* initialize in array, stride assumed 0 in following code */
in.array = inarray;
in.type = intype;
in.len = inlen;
in.stride = 0;
ptype = RNA_property_pointer_type(ptr, prop);
/* try to get item property pointer */
RNA_pointer_create(NULL, ptype, NULL, &itemptr_base);
itemprop = RNA_struct_find_property(&itemptr_base, propname);
if (itemprop) {
/* we have item property pointer */
RawArray out;
/* check type */
itemtype = RNA_property_type(itemprop);
if (!ELEM(itemtype, PROP_BOOLEAN, PROP_INT, PROP_FLOAT)) {
BKE_report(reports, RPT_ERROR, "Only boolean, int and float properties supported");
return 0;
}
/* check item array */
itemlen = RNA_property_array_length(&itemptr_base, itemprop);
/* dynamic array? need to get length per item */
if (itemprop->getlength) {
itemprop = NULL;
}
/* try to access as raw array */
else if (RNA_property_collection_raw_array(ptr, prop, itemprop, &out)) {
int arraylen = (itemlen == 0) ? 1 : itemlen;
if (in.len != arraylen * out.len) {
BKE_reportf(reports,
RPT_ERROR,
"Array length mismatch (expected %d, got %d)",
out.len * arraylen,
in.len);
return 0;
}
/* matching raw types */
if (out.type == in.type) {
void *inp = in.array;
void *outp = out.array;
int a, size;
size = RNA_raw_type_sizeof(out.type) * arraylen;
for (a = 0; a < out.len; a++) {
if (set) {
memcpy(outp, inp, size);
}
else {
memcpy(inp, outp, size);
}
inp = (char *)inp + size;
outp = (char *)outp + out.stride;
}
return 1;
}
/* could also be faster with non-matching types,
* for now we just do slower loop .. */
}
}
{
void *tmparray = NULL;
int tmplen = 0;
int err = 0, j, a = 0;
int needconv = 1;
if (((itemtype == PROP_INT) && (in.type == PROP_RAW_INT)) ||
((itemtype == PROP_BOOLEAN) && (in.type == PROP_RAW_BOOLEAN)) ||
((itemtype == PROP_FLOAT) && (in.type == PROP_RAW_FLOAT))) {
/* avoid creating temporary buffer if the data type match */
needconv = 0;
}
/* no item property pointer, can still be id property, or
* property of a type derived from the collection pointer type */
RNA_PROP_BEGIN (ptr, itemptr, prop) {
if (itemptr.data) {
if (itemprop) {
/* we got the property already */
iprop = itemprop;
}
else {
/* not yet, look it up and verify if it is valid */
iprop = RNA_struct_find_property(&itemptr, propname);
if (iprop) {
itemlen = rna_property_array_length_all_dimensions(&itemptr, iprop);
itemtype = RNA_property_type(iprop);
}
else {
BKE_reportf(reports, RPT_ERROR, "Property named '%s' not found", propname);
err = 1;
break;
}
if (!ELEM(itemtype, PROP_BOOLEAN, PROP_INT, PROP_FLOAT)) {
BKE_report(reports, RPT_ERROR, "Only boolean, int and float properties supported");
err = 1;
break;
}
}
/* editable check */
if (!set || RNA_property_editable(&itemptr, iprop)) {
if (a + itemlen > in.len) {
BKE_reportf(
reports, RPT_ERROR, "Array length mismatch (got %d, expected more)", in.len);
err = 1;
break;
}
if (itemlen == 0) {
/* handle conversions */
if (set) {
switch (itemtype) {
case PROP_BOOLEAN: {
int b;
RAW_GET(bool, b, in, a);
RNA_property_boolean_set(&itemptr, iprop, b);
break;
}
case PROP_INT: {
int i;
RAW_GET(int, i, in, a);
RNA_property_int_set(&itemptr, iprop, i);
break;
}
case PROP_FLOAT: {
float f;
RAW_GET(float, f, in, a);
RNA_property_float_set(&itemptr, iprop, f);
break;
}
default:
break;
}
}
else {
switch (itemtype) {
case PROP_BOOLEAN: {
int b = RNA_property_boolean_get(&itemptr, iprop);
RAW_SET(bool, in, a, b);
break;
}
case PROP_INT: {
int i = RNA_property_int_get(&itemptr, iprop);
RAW_SET(int, in, a, i);
break;
}
case PROP_FLOAT: {
float f = RNA_property_float_get(&itemptr, iprop);
RAW_SET(float, in, a, f);
break;
}
default:
break;
}
}
a++;
}
else if (needconv == 1) {
/* allocate temporary array if needed */
if (tmparray && tmplen != itemlen) {
MEM_freeN(tmparray);
tmparray = NULL;
}
if (!tmparray) {
tmparray = MEM_callocN(sizeof(float) * itemlen, "RNA tmparray");
tmplen = itemlen;
}
/* handle conversions */
if (set) {
switch (itemtype) {
case PROP_BOOLEAN: {
for (j = 0; j < itemlen; j++, a++) {
RAW_GET(bool, ((bool *)tmparray)[j], in, a);
}
RNA_property_boolean_set_array(&itemptr, iprop, tmparray);
break;
}
case PROP_INT: {
for (j = 0; j < itemlen; j++, a++) {
RAW_GET(int, ((int *)tmparray)[j], in, a);
}
RNA_property_int_set_array(&itemptr, iprop, tmparray);
break;
}
case PROP_FLOAT: {
for (j = 0; j < itemlen; j++, a++) {
RAW_GET(float, ((float *)tmparray)[j], in, a);
}
RNA_property_float_set_array(&itemptr, iprop, tmparray);
break;
}
default:
break;
}
}
else {
switch (itemtype) {
case PROP_BOOLEAN: {
RNA_property_boolean_get_array(&itemptr, iprop, tmparray);
for (j = 0; j < itemlen; j++, a++) {
RAW_SET(int, in, a, ((bool *)tmparray)[j]);
}
break;
}
case PROP_INT: {
RNA_property_int_get_array(&itemptr, iprop, tmparray);
for (j = 0; j < itemlen; j++, a++) {
RAW_SET(int, in, a, ((int *)tmparray)[j]);
}
break;
}
case PROP_FLOAT: {
RNA_property_float_get_array(&itemptr, iprop, tmparray);
for (j = 0; j < itemlen; j++, a++) {
RAW_SET(float, in, a, ((float *)tmparray)[j]);
}
break;
}
default:
break;
}
}
}
else {
if (set) {
switch (itemtype) {
case PROP_BOOLEAN: {
RNA_property_boolean_set_array(&itemptr, iprop, &((bool *)in.array)[a]);
a += itemlen;
break;
}
case PROP_INT: {
RNA_property_int_set_array(&itemptr, iprop, &((int *)in.array)[a]);
a += itemlen;
break;
}
case PROP_FLOAT: {
RNA_property_float_set_array(&itemptr, iprop, &((float *)in.array)[a]);
a += itemlen;
break;
}
default:
break;
}
}
else {
switch (itemtype) {
case PROP_BOOLEAN: {
RNA_property_boolean_get_array(&itemptr, iprop, &((bool *)in.array)[a]);
a += itemlen;
break;
}
case PROP_INT: {
RNA_property_int_get_array(&itemptr, iprop, &((int *)in.array)[a]);
a += itemlen;
break;
}
case PROP_FLOAT: {
RNA_property_float_get_array(&itemptr, iprop, &((float *)in.array)[a]);
a += itemlen;
break;
}
default:
break;
}
}
}
}
}
}
RNA_PROP_END;
if (tmparray) {
MEM_freeN(tmparray);
}
return !err;
}
}
RawPropertyType RNA_property_raw_type(PropertyRNA *prop)
{
if (prop->rawtype == PROP_RAW_UNSET) {
/* this property has no raw access,
* yet we try to provide a raw type to help building the array. */
switch (prop->type) {
case PROP_BOOLEAN:
return PROP_RAW_BOOLEAN;
case PROP_INT:
return PROP_RAW_INT;
case PROP_FLOAT:
return PROP_RAW_FLOAT;
case PROP_ENUM:
return PROP_RAW_INT;
default:
break;
}
}
return prop->rawtype;
}
int RNA_property_collection_raw_get(ReportList *reports,
PointerRNA *ptr,
PropertyRNA *prop,
const char *propname,
void *array,
RawPropertyType type,
int len)
{
return rna_raw_access(reports, ptr, prop, propname, array, type, len, 0);
}
int RNA_property_collection_raw_set(ReportList *reports,
PointerRNA *ptr,
PropertyRNA *prop,
const char *propname,
void *array,
RawPropertyType type,
int len)
{
return rna_raw_access(reports, ptr, prop, propname, array, type, len, 1);
}
/* Standard iterator functions */
void rna_iterator_listbase_begin(CollectionPropertyIterator *iter,
ListBase *lb,
IteratorSkipFunc skip)
{
ListBaseIterator *internal = &iter->internal.listbase;
internal->link = (lb) ? lb->first : NULL;
internal->skip = skip;
iter->valid = (internal->link != NULL);
if (skip && iter->valid && skip(iter, internal->link)) {
rna_iterator_listbase_next(iter);
}
}
void rna_iterator_listbase_next(CollectionPropertyIterator *iter)
{
ListBaseIterator *internal = &iter->internal.listbase;
if (internal->skip) {
do {
internal->link = internal->link->next;
iter->valid = (internal->link != NULL);
} while (iter->valid && internal->skip(iter, internal->link));
}
else {
internal->link = internal->link->next;
iter->valid = (internal->link != NULL);
}
}
void *rna_iterator_listbase_get(CollectionPropertyIterator *iter)
{
ListBaseIterator *internal = &iter->internal.listbase;
return internal->link;
}
void rna_iterator_listbase_end(CollectionPropertyIterator *UNUSED(iter))
{
}
PointerRNA rna_listbase_lookup_int(PointerRNA *ptr,
StructRNA *type,
struct ListBase *lb,
int index)
{
void *data = BLI_findlink(lb, index);
return rna_pointer_inherit_refine(ptr, type, data);
}
void rna_iterator_array_begin(CollectionPropertyIterator *iter,
void *ptr,
int itemsize,
int length,
bool free_ptr,
IteratorSkipFunc skip)
{
ArrayIterator *internal;
if (ptr == NULL) {
length = 0;
}
else if (length == 0) {
ptr = NULL;
itemsize = 0;
}
internal = &iter->internal.array;
internal->ptr = ptr;
internal->free_ptr = free_ptr ? ptr : NULL;
internal->endptr = ((char *)ptr) + length * itemsize;
internal->itemsize = itemsize;
internal->skip = skip;
internal->length = length;
iter->valid = (internal->ptr != internal->endptr);
if (skip && iter->valid && skip(iter, internal->ptr)) {
rna_iterator_array_next(iter);
}
}
void rna_iterator_array_next(CollectionPropertyIterator *iter)
{
ArrayIterator *internal = &iter->internal.array;
if (internal->skip) {
do {
internal->ptr += internal->itemsize;
iter->valid = (internal->ptr != internal->endptr);
} while (iter->valid && internal->skip(iter, internal->ptr));
}
else {
internal->ptr += internal->itemsize;
iter->valid = (internal->ptr != internal->endptr);
}
}
void *rna_iterator_array_get(CollectionPropertyIterator *iter)
{
ArrayIterator *internal = &iter->internal.array;
return internal->ptr;
}
void *rna_iterator_array_dereference_get(CollectionPropertyIterator *iter)
{
ArrayIterator *internal = &iter->internal.array;
/* for ** arrays */
return *(void **)(internal->ptr);
}
void rna_iterator_array_end(CollectionPropertyIterator *iter)
{
ArrayIterator *internal = &iter->internal.array;
if (internal->free_ptr) {
MEM_freeN(internal->free_ptr);
internal->free_ptr = NULL;
}
}
PointerRNA rna_array_lookup_int(
PointerRNA *ptr, StructRNA *type, void *data, int itemsize, int length, int index)
{
if (index < 0 || index >= length) {
return PointerRNA_NULL;
}
return rna_pointer_inherit_refine(ptr, type, ((char *)data) + index * itemsize);
}
/* RNA Path - Experiment */
static char *rna_path_token(const char **path, char *fixedbuf, int fixedlen, int bracket)
{
const char *p;
char *buf;
char quote = '\0';
int i, j, len, escape;
len = 0;
if (bracket) {
/* get data between [], check escaping ] with \] */
if (**path == '[') {
(*path)++;
}
else {
return NULL;
}
p = *path;
/* 2 kinds of lookups now, quoted or unquoted */
quote = *p;
if (quote != '"') { /* " - this comment is hack for Aligorith's text editor's sanity */
quote = 0;
}
if (quote == 0) {
while (*p && (*p != ']')) {
len++;
p++;
}
}
else {
escape = 0;
/* skip the first quote */
len++;
p++;
while (*p && (*p != quote || escape)) {
escape = (*p == '\\');
len++;
p++;
}
/* skip the last quoted char to get the ']' */
len++;
p++;
}
if (*p != ']') {
return NULL;
}
}
else {
/* get data until . or [ */
p = *path;
while (*p && *p != '.' && *p != '[') {
len++;
p++;
}
}
/* empty, return */
if (len == 0) {
return NULL;
}
/* try to use fixed buffer if possible */
if (len + 1 < fixedlen) {
buf = fixedbuf;
}
else {
buf = MEM_mallocN(sizeof(char) * (len + 1), "rna_path_token");
}
/* copy string, taking into account escaped ] */
if (bracket) {
for (p = *path, i = 0, j = 0; i < len; i++, p++) {
if (*p == '\\' && *(p + 1) == quote) {
}
else {
buf[j++] = *p;
}
}
buf[j] = 0;
}
else {
memcpy(buf, *path, sizeof(char) * len);
buf[len] = '\0';
}
/* set path to start of next token */
if (*p == ']') {
p++;
}
if (*p == '.') {
p++;
}
*path = p;
return buf;
}
static int rna_token_strip_quotes(char *token)
{
if (token[0] == '"') {
int len = strlen(token);
if (len >= 2 && token[len - 1] == '"') {
/* strip away "" */
token[len - 1] = '\0';
return 1;
}
}
return 0;
}
static bool rna_path_parse_collection_key(const char **path,
PointerRNA *ptr,
PropertyRNA *prop,
PointerRNA *r_nextptr)
{
char fixedbuf[256];
int intkey;
*r_nextptr = *ptr;
/* end of path, ok */
if (!(**path)) {
return true;
}
if (**path == '[') {
char *token;
/* resolve the lookup with [] brackets */
token = rna_path_token(path, fixedbuf, sizeof(fixedbuf), 1);
if (!token) {
return false;
}
/* check for "" to see if it is a string */
if (rna_token_strip_quotes(token)) {
if (RNA_property_collection_lookup_string(ptr, prop, token + 1, r_nextptr)) {
/* pass */
}
else {
r_nextptr->data = NULL;
}
}
else {
/* otherwise do int lookup */
intkey = atoi(token);
if (intkey == 0 && (token[0] != '0' || token[1] != '\0')) {
return false; /* we can be sure the fixedbuf was used in this case */
}
if (RNA_property_collection_lookup_int(ptr, prop, intkey, r_nextptr)) {
/* pass */
}
else {
r_nextptr->data = NULL;
}
}
if (token != fixedbuf) {
MEM_freeN(token);
}
}
else {
if (RNA_property_collection_type_get(ptr, prop, r_nextptr)) {
/* pass */
}
else {
/* ensure we quit on invalid values */
r_nextptr->data = NULL;
}
}
return true;
}
static bool rna_path_parse_array_index(const char **path,
PointerRNA *ptr,
PropertyRNA *prop,
int *r_index)
{
char fixedbuf[256];
int index_arr[RNA_MAX_ARRAY_DIMENSION] = {0};
int len[RNA_MAX_ARRAY_DIMENSION];
const int dim = RNA_property_array_dimension(ptr, prop, len);
int i;
*r_index = -1;
/* end of path, ok */
if (!(**path)) {
return true;
}
for (i = 0; i < dim; i++) {
int temp_index = -1;
char *token;
/* multi index resolve */
if (**path == '[') {
token = rna_path_token(path, fixedbuf, sizeof(fixedbuf), 1);
if (token == NULL) {
/* invalid syntax blah[] */
return false;
}
/* check for "" to see if it is a string */
else if (rna_token_strip_quotes(token)) {
temp_index = RNA_property_array_item_index(prop, *(token + 1));
}
else {
/* otherwise do int lookup */
temp_index = atoi(token);
if (temp_index == 0 && (token[0] != '0' || token[1] != '\0')) {
if (token != fixedbuf) {
MEM_freeN(token);
}
return false;
}
}
}
else if (dim == 1) {
/* location.x || scale.X, single dimension arrays only */
token = rna_path_token(path, fixedbuf, sizeof(fixedbuf), 0);
if (token == NULL) {
/* invalid syntax blah.. */
return false;
}
temp_index = RNA_property_array_item_index(prop, *token);
}
else {
/* just to avoid uninitialized pointer use */
token = fixedbuf;
}
if (token != fixedbuf) {
MEM_freeN(token);
}
/* out of range */
if (temp_index < 0 || temp_index >= len[i]) {
return false;
}
index_arr[i] = temp_index;
/* end multi index resolve */
}
/* arrays always contain numbers so further values are not valid */
if (**path) {
return false;
}
/* flatten index over all dimensions */
{
int totdim = 1;
int flat_index = 0;
for (i = dim - 1; i >= 0; i--) {
flat_index += index_arr[i] * totdim;
totdim *= len[i];
}
*r_index = flat_index;
}
return true;
}
/**
* Generic rna path parser.
*
* \note All parameters besides \a ptr and \a path are optional.
*
* \param ptr: The root of given RNA path.
* \param path: The RNA path.
* \param r_ptr: The final RNA data holding the last property in \a path.
* \param r_prop: The final property of \a r_ptr, from \a path.
* \param r_index: The final index in the \a r_prop, if defined by \a path.
* \param r_item_ptr: Only valid for Pointer and Collection,
* return the actual value of the pointer, or of the collection item.
* Mutually exclusive with \a eval_pointer option.
* \param r_elements: A list of \a PropertyElemRNA items
* (pairs of \a PointerRNA, \a PropertyRNA that represent the whole given \a path).
* \param eval_pointer: If \a true, and \a path leads to a Pointer property,
* or an item in a Collection property,
* \a r_ptr will be set to the value of that property, and \a r_prop will be NULL.
* Mutually exclusive with \a r_item_ptr.
* \return \a true on success, \a false if the path is somehow invalid.
*/
static bool rna_path_parse(PointerRNA *ptr,
const char *path,
PointerRNA *r_ptr,
PropertyRNA **r_prop,
int *r_index,
PointerRNA *r_item_ptr,
ListBase *r_elements,
const bool eval_pointer)
{
BLI_assert(r_item_ptr == NULL || !eval_pointer);
PropertyRNA *prop;
PointerRNA curptr, nextptr;
PropertyElemRNA *prop_elem = NULL;
int index = -1;
char fixedbuf[256];
int type;
const bool do_item_ptr = r_item_ptr != NULL && !eval_pointer;
if (do_item_ptr) {
RNA_POINTER_INVALIDATE(&nextptr);
}
prop = NULL;
curptr = *ptr;
if (path == NULL || *path == '\0') {
return false;
}
while (*path) {
if (do_item_ptr) {
RNA_POINTER_INVALIDATE(&nextptr);
}
int use_id_prop = (*path == '[') ? 1 : 0;
char *token;
/* custom property lookup ?
* C.object["someprop"]
*/
if (!curptr.data) {
return false;
}
/* look up property name in current struct */
token = rna_path_token(&path, fixedbuf, sizeof(fixedbuf), use_id_prop);
if (!token) {
return false;
}
prop = NULL;
if (use_id_prop) { /* look up property name in current struct */
IDProperty *group = RNA_struct_idprops(&curptr, 0);
if (group && rna_token_strip_quotes(token)) {
prop = (PropertyRNA *)IDP_GetPropertyFromGroup(group, token + 1);
}
}
else {
prop = RNA_struct_find_property(&curptr, token);
}
if (token != fixedbuf) {
MEM_freeN(token);
}
if (!prop) {
return false;
}
if (r_elements) {
prop_elem = MEM_mallocN(sizeof(PropertyElemRNA), __func__);
prop_elem->ptr = curptr;
prop_elem->prop = prop;
prop_elem->index = -1; /* index will be added later, if needed. */
BLI_addtail(r_elements, prop_elem);
}
type = RNA_property_type(prop);
/* now look up the value of this property if it is a pointer or
* collection, otherwise return the property rna so that the
* caller can read the value of the property itself */
switch (type) {
case PROP_POINTER: {
/* resolve pointer if further path elements follow
* or explicitly requested
*/
if (do_item_ptr || eval_pointer || *path != '\0') {
nextptr = RNA_property_pointer_get(&curptr, prop);
}
if (eval_pointer || *path != '\0') {
curptr = nextptr;
prop = NULL; /* now we have a PointerRNA, the prop is our parent so forget it */
index = -1;
}
break;
}
case PROP_COLLECTION: {
/* Resolve pointer if further path elements follow.
* Note that if path is empty, rna_path_parse_collection_key will do nothing anyway,
* so do_item_ptr is of no use in that case.
*/
if (*path) {
if (!rna_path_parse_collection_key(&path, &curptr, prop, &nextptr)) {
return false;
}
if (eval_pointer || *path != '\0') {
curptr = nextptr;
prop = NULL; /* now we have a PointerRNA, the prop is our parent so forget it */
index = -1;
}
}
break;
}
default:
if (r_index || prop_elem) {
if (!rna_path_parse_array_index(&path, &curptr, prop, &index)) {
return false;
}
if (prop_elem) {
prop_elem->index = index;
}
}
break;
}
}
if (r_ptr) {
*r_ptr = curptr;
}
if (r_prop) {
*r_prop = prop;
}
if (r_index) {
*r_index = index;
}
if (r_item_ptr && do_item_ptr) {
*r_item_ptr = nextptr;
}
if (prop_elem && (prop_elem->ptr.data != curptr.data || prop_elem->prop != prop ||
prop_elem->index != index)) {
prop_elem = MEM_mallocN(sizeof(PropertyElemRNA), __func__);
prop_elem->ptr = curptr;
prop_elem->prop = prop;
prop_elem->index = index;
BLI_addtail(r_elements, prop_elem);
}
return true;
}
/**
* Resolve the given RNA Path to find the pointer and/or property
* indicated by fully resolving the path.
*
* \warning Unlike \a RNA_path_resolve_property(), that one *will* try to follow RNAPointers,
* e.g. the path 'parent' applied to a RNAObject \a ptr will return the object.parent in \a r_ptr,
* and a NULL \a r_prop...
*
* \note Assumes all pointers provided are valid
* \return True if path can be resolved to a valid "pointer + property" OR "pointer only"
*/
bool RNA_path_resolve(PointerRNA *ptr, const char *path, PointerRNA *r_ptr, PropertyRNA **r_prop)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, NULL, NULL, NULL, true)) {
return false;
}
return r_ptr->data != NULL;
}
/**
* Resolve the given RNA Path to find the pointer and/or property + array index
* indicated by fully resolving the path.
*
* \note Assumes all pointers provided are valid.
* \return True if path can be resolved to a valid "pointer + property" OR "pointer only"
*/
bool RNA_path_resolve_full(
PointerRNA *ptr, const char *path, PointerRNA *r_ptr, PropertyRNA **r_prop, int *r_index)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, r_index, NULL, NULL, true)) {
return false;
}
return r_ptr->data != NULL;
}
/**
* Resolve the given RNA Path to find both the pointer AND property
* indicated by fully resolving the path.
*
* This is a convenience method to avoid logic errors and ugly syntax.
* \note Assumes all pointers provided are valid
* \return True only if both a valid pointer and property are found after resolving the path
*/
bool RNA_path_resolve_property(PointerRNA *ptr,
const char *path,
PointerRNA *r_ptr,
PropertyRNA **r_prop)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, NULL, NULL, NULL, false)) {
return false;
}
return r_ptr->data != NULL && *r_prop != NULL;
}
/**
* Resolve the given RNA Path to find the pointer AND property (as well as the array index)
* indicated by fully resolving the path.
*
* This is a convenience method to avoid logic errors and ugly syntax.
* \note Assumes all pointers provided are valid
* \return True only if both a valid pointer and property are found after resolving the path
*/
bool RNA_path_resolve_property_full(
PointerRNA *ptr, const char *path, PointerRNA *r_ptr, PropertyRNA **r_prop, int *r_index)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, r_index, NULL, NULL, false)) {
return false;
}
return r_ptr->data != NULL && *r_prop != NULL;
}
/**
* Resolve the given RNA Path to find both the pointer AND property
* indicated by fully resolving the path, and get the value of the Pointer property
* (or item of the collection).
*
* This is a convenience method to avoid logic errors and ugly syntax,
* it combines both \a RNA_path_resolve and #RNA_path_resolve_property in a single call.
* \note Assumes all pointers provided are valid.
* \param r_item_pointer: The final Pointer or Collection item value.
* You must check for its validity before use!
* \return True only if both a valid pointer and property are found after resolving the path
*/
bool RNA_path_resolve_property_and_item_pointer(PointerRNA *ptr,
const char *path,
PointerRNA *r_ptr,
PropertyRNA **r_prop,
PointerRNA *r_item_ptr)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, NULL, r_item_ptr, NULL, false)) {
return false;
}
return r_ptr->data != NULL && *r_prop != NULL;
}
/**
* Resolve the given RNA Path to find both the pointer AND property (as well as the array index)
* indicated by fully resolving the path,
* and get the value of the Pointer property (or item of the collection).
*
* This is a convenience method to avoid logic errors and ugly syntax,
* it combines both \a RNA_path_resolve_full and
* \a RNA_path_resolve_property_full in a single call.
* \note Assumes all pointers provided are valid.
* \param r_item_pointer: The final Pointer or Collection item value.
* You must check for its validity before use!
* \return True only if both a valid pointer and property are found after resolving the path
*/
bool RNA_path_resolve_property_and_item_pointer_full(PointerRNA *ptr,
const char *path,
PointerRNA *r_ptr,
PropertyRNA **r_prop,
int *r_index,
PointerRNA *r_item_ptr)
{
if (!rna_path_parse(ptr, path, r_ptr, r_prop, r_index, r_item_ptr, NULL, false)) {
return false;
}
return r_ptr->data != NULL && *r_prop != NULL;
}
/**
* Resolve the given RNA Path into a linked list of PropertyElemRNA's.
*
* To be used when complex operations over path are needed, like e.g. get relative paths,
* to avoid too much string operations.
*
* \return True if there was no error while resolving the path
* \note Assumes all pointers provided are valid
*/
bool RNA_path_resolve_elements(PointerRNA *ptr, const char *path, ListBase *r_elements)
{
return rna_path_parse(ptr, path, NULL, NULL, NULL, NULL, r_elements, false);
}
char *RNA_path_append(
const char *path, PointerRNA *UNUSED(ptr), PropertyRNA *prop, int intkey, const char *strkey)
{
DynStr *dynstr;
const char *s;
char appendstr[128], *result;
dynstr = BLI_dynstr_new();
/* add .identifier */
if (path) {
BLI_dynstr_append(dynstr, path);
if (*path) {
BLI_dynstr_append(dynstr, ".");
}
}
BLI_dynstr_append(dynstr, RNA_property_identifier(prop));
if (RNA_property_type(prop) == PROP_COLLECTION) {
/* add ["strkey"] or [intkey] */
BLI_dynstr_append(dynstr, "[");
if (strkey) {
BLI_dynstr_append(dynstr, "\"");
for (s = strkey; *s; s++) {
if (*s == '[') {
appendstr[0] = '\\';
appendstr[1] = *s;
appendstr[2] = 0;
}
else {
appendstr[0] = *s;
appendstr[1] = 0;
}
BLI_dynstr_append(dynstr, appendstr);
}
BLI_dynstr_append(dynstr, "\"");
}
else {
BLI_snprintf(appendstr, sizeof(appendstr), "%d", intkey);
BLI_dynstr_append(dynstr, appendstr);
}
BLI_dynstr_append(dynstr, "]");
}
result = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
return result;
}
char *RNA_path_back(const char *path)
{
char fixedbuf[256];
const char *previous, *current;
char *result;
int i;
if (!path) {
return NULL;
}
previous = NULL;
current = path;
/* parse token by token until the end, then we back up to the previous
* position and strip of the next token to get the path one step back */
while (*current) {
char *token;
token = rna_path_token(&current, fixedbuf, sizeof(fixedbuf), 0);
if (!token) {
return NULL;
}
if (token != fixedbuf) {
MEM_freeN(token);
}
/* in case of collection we also need to strip off [] */
token = rna_path_token(&current, fixedbuf, sizeof(fixedbuf), 1);
if (token && token != fixedbuf) {
MEM_freeN(token);
}
if (!*current) {
break;
}
previous = current;
}
if (!previous) {
return NULL;
}
/* copy and strip off last token */
i = previous - path;
result = BLI_strdup(path);
if (i > 0 && result[i - 1] == '.') {
i--;
}
result[i] = 0;
return result;
}
/* generic path search func
* if its needed this could also reference the IDProperty direct */
typedef struct IDP_Chain {
struct IDP_Chain *up; /* parent member, reverse and set to child for path conversion. */
const char *name;
int index;
} IDP_Chain;
static char *rna_idp_path_create(IDP_Chain *child_link)
{
DynStr *dynstr = BLI_dynstr_new();
char *path;
bool is_first = true;
int tot = 0;
IDP_Chain *link = child_link;
/* reverse the list */
IDP_Chain *link_prev;
link_prev = NULL;
while (link) {
IDP_Chain *link_next = link->up;
link->up = link_prev;
link_prev = link;
link = link_next;
tot++;
}
for (link = link_prev; link; link = link->up) {
/* pass */
if (link->index >= 0) {
BLI_dynstr_appendf(dynstr, is_first ? "%s[%d]" : ".%s[%d]", link->name, link->index);
}
else {
BLI_dynstr_appendf(dynstr, is_first ? "%s" : ".%s", link->name);
}
is_first = false;
}
path = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
if (*path == '\0') {
MEM_freeN(path);
path = NULL;
}
return path;
}
static char *rna_idp_path(PointerRNA *ptr,
IDProperty *haystack,
IDProperty *needle,
IDP_Chain *parent_link)
{
char *path = NULL;
IDP_Chain link;
IDProperty *iter;
int i;
BLI_assert(haystack->type == IDP_GROUP);
link.up = parent_link;
/* always set both name and index,
* else a stale value might get used */
link.name = NULL;
link.index = -1;
for (i = 0, iter = haystack->data.group.first; iter; iter = iter->next, i++) {
if (needle == iter) { /* found! */
link.name = iter->name;
link.index = -1;
path = rna_idp_path_create(&link);
break;
}
else {
if (iter->type == IDP_GROUP) {
/* ensure this is RNA */
PropertyRNA *prop = RNA_struct_find_property(ptr, iter->name);
if (prop && prop->type == PROP_POINTER) {
PointerRNA child_ptr = RNA_property_pointer_get(ptr, prop);
link.name = iter->name;
link.index = -1;
if ((path = rna_idp_path(&child_ptr, iter, needle, &link))) {
break;
}
}
}
else if (iter->type == IDP_IDPARRAY) {
PropertyRNA *prop = RNA_struct_find_property(ptr, iter->name);
if (prop && prop->type == PROP_COLLECTION) {
IDProperty *array = IDP_IDPArray(iter);
if (needle >= array && needle < (iter->len + array)) { /* found! */
link.name = iter->name;
link.index = (int)(needle - array);
path = rna_idp_path_create(&link);
break;
}
else {
int j;
link.name = iter->name;
for (j = 0; j < iter->len; j++, array++) {
PointerRNA child_ptr;
if (RNA_property_collection_lookup_int(ptr, prop, j, &child_ptr)) {
link.index = j;
if ((path = rna_idp_path(&child_ptr, array, needle, &link))) {
break;
}
}
}
if (path) {
break;
}
}
}
}
}
}
return path;
}
static char *rna_path_from_ID_to_idpgroup(PointerRNA *ptr)
{
PointerRNA id_ptr;
IDProperty *haystack;
IDProperty *needle;
BLI_assert(ptr->owner_id != NULL);
/* TODO, Support Bones/PoseBones. no pointers stored to the bones from here, only the ID.
* See example in T25746.
* Unless this is added only way to find this is to also search
* all bones and pose bones of an armature or object.
*/
RNA_id_pointer_create(ptr->owner_id, &id_ptr);
haystack = RNA_struct_idprops(&id_ptr, false);
if (haystack) { /* can fail when called on bones */
needle = ptr->data;
return rna_idp_path(&id_ptr, haystack, needle, NULL);
}
else {
return NULL;
}
}
char *RNA_path_from_ID_to_struct(PointerRNA *ptr)
{
char *ptrpath = NULL;
if (!ptr->owner_id || !ptr->data) {
return NULL;
}
if (!RNA_struct_is_ID(ptr->type)) {
if (ptr->type->path) {
/* if type has a path to some ID, use it */
ptrpath = ptr->type->path(ptr);
}
else if (ptr->type->nested && RNA_struct_is_ID(ptr->type->nested)) {
PointerRNA parentptr;
PropertyRNA *userprop;
/* find the property in the struct we're nested in that references this struct, and
* use its identifier as the first part of the path used...
*/
RNA_id_pointer_create(ptr->owner_id, &parentptr);
userprop = RNA_struct_find_nested(&parentptr, ptr->type);
if (userprop) {
ptrpath = BLI_strdup(RNA_property_identifier(userprop));
}
else {
return NULL; /* can't do anything about this case yet... */
}
}
else if (RNA_struct_is_a(ptr->type, &RNA_PropertyGroup)) {
/* special case, easier to deal with here then in ptr->type->path() */
return rna_path_from_ID_to_idpgroup(ptr);
}
else {
return NULL;
}
}
return ptrpath;
}
static void rna_path_array_multi_from_flat_index(const int dimsize[RNA_MAX_ARRAY_LENGTH],
const int totdims,
const int index_dim,
int index,
int r_index_multi[RNA_MAX_ARRAY_LENGTH])
{
int dimsize_step[RNA_MAX_ARRAY_LENGTH + 1];
int i = totdims - 1;
dimsize_step[i + 1] = 1;
dimsize_step[i] = dimsize[i];
while (--i != -1) {
dimsize_step[i] = dimsize[i] * dimsize_step[i + 1];
}
while (++i != index_dim) {
int index_round = index / dimsize_step[i + 1];
r_index_multi[i] = index_round;
index -= (index_round * dimsize_step[i + 1]);
}
BLI_assert(index == 0);
}
static void rna_path_array_multi_string_from_flat_index(PointerRNA *ptr,
PropertyRNA *prop,
int index_dim,
int index,
char *index_str,
int index_str_len)
{
int dimsize[RNA_MAX_ARRAY_LENGTH];
int totdims = RNA_property_array_dimension(ptr, prop, dimsize);
int index_multi[RNA_MAX_ARRAY_LENGTH];
rna_path_array_multi_from_flat_index(dimsize, totdims, index_dim, index, index_multi);
for (int i = 0, offset = 0; (i < index_dim) && (offset < index_str_len); i++) {
offset += BLI_snprintf_rlen(
&index_str[offset], index_str_len - offset, "[%d]", index_multi[i]);
}
}
/**
* \param index_dim: The dimension to show, 0 disables. 1 for 1d array, 2 for 2d. etc.
* \param index: The *flattened* index to use when \a ``index_dim > 0``,
* this is expanded when used with multi-dimensional arrays.
*/
char *RNA_path_from_ID_to_property_index(PointerRNA *ptr,
PropertyRNA *prop,
int index_dim,
int index)
{
const bool is_rna = (prop->magic == RNA_MAGIC);
const char *propname;
char *ptrpath, *path;
if (!ptr->owner_id || !ptr->data) {
return NULL;
}
/* path from ID to the struct holding this property */
ptrpath = RNA_path_from_ID_to_struct(ptr);
propname = RNA_property_identifier(prop);
/* support indexing w/ multi-dimensional arrays */
char index_str[RNA_MAX_ARRAY_LENGTH * 12 + 1];
if (index_dim == 0) {
index_str[0] = '\0';
}
else {
rna_path_array_multi_string_from_flat_index(
ptr, prop, index_dim, index, index_str, sizeof(index_str));
}
if (ptrpath) {
if (is_rna) {
path = BLI_sprintfN("%s.%s%s", ptrpath, propname, index_str);
}
else {
char propname_esc[MAX_IDPROP_NAME * 2];
BLI_strescape(propname_esc, propname, sizeof(propname_esc));
path = BLI_sprintfN("%s[\"%s\"]%s", ptrpath, propname_esc, index_str);
}
MEM_freeN(ptrpath);
}
else if (RNA_struct_is_ID(ptr->type)) {
if (is_rna) {
path = BLI_sprintfN("%s%s", propname, index_str);
}
else {
char propname_esc[MAX_IDPROP_NAME * 2];
BLI_strescape(propname_esc, propname, sizeof(propname_esc));
path = BLI_sprintfN("[\"%s\"]%s", propname_esc, index_str);
}
}
else {
path = NULL;
}
return path;
}
char *RNA_path_from_ID_to_property(PointerRNA *ptr, PropertyRNA *prop)
{
return RNA_path_from_ID_to_property_index(ptr, prop, 0, -1);
}
/**
* \return the path to given ptr/prop from the closest ancestor of given type,
* if any (else return NULL).
*/
char *RNA_path_resolve_from_type_to_property(PointerRNA *ptr,
PropertyRNA *prop,
const StructRNA *type)
{
/* Try to recursively find an "type"'d ancestor,
* to handle situations where path from ID is not enough. */
PointerRNA idptr;
ListBase path_elems = {NULL};
char *path = NULL;
char *full_path = RNA_path_from_ID_to_property(ptr, prop);
if (full_path == NULL) {
return NULL;
}
RNA_id_pointer_create(ptr->owner_id, &idptr);
if (RNA_path_resolve_elements(&idptr, full_path, &path_elems)) {
PropertyElemRNA *prop_elem;
for (prop_elem = path_elems.last; prop_elem; prop_elem = prop_elem->prev) {
if (RNA_struct_is_a(prop_elem->ptr.type, type)) {
char *ref_path = RNA_path_from_ID_to_struct(&prop_elem->ptr);
if (ref_path) {
path = BLI_strdup(full_path + strlen(ref_path) + 1); /* +1 for the linking '.' */
MEM_freeN(ref_path);
}
break;
}
}
BLI_freelistN(&path_elems);
}
MEM_freeN(full_path);
return path;
}
/**
* Get the ID as a python representation, eg:
* bpy.data.foo["bar"]
*/
char *RNA_path_full_ID_py(ID *id)
{
char id_esc[(sizeof(id->name) - 2) * 2];
BLI_strescape(id_esc, id->name + 2, sizeof(id_esc));
return BLI_sprintfN("bpy.data.%s[\"%s\"]", BKE_idcode_to_name_plural(GS(id->name)), id_esc);
}
/**
* Get the ID.struct as a python representation, eg:
* bpy.data.foo["bar"].some_struct
*/
char *RNA_path_full_struct_py(struct PointerRNA *ptr)
{
char *id_path;
char *data_path;
char *ret;
if (!ptr->owner_id) {
return NULL;
}
/* never fails */
id_path = RNA_path_full_ID_py(ptr->owner_id);
data_path = RNA_path_from_ID_to_struct(ptr);
/* XXX data_path may be NULL (see T36788),
* do we want to get the 'bpy.data.foo["bar"].(null)' stuff? */
ret = BLI_sprintfN("%s.%s", id_path, data_path);
if (data_path) {
MEM_freeN(data_path);
}
MEM_freeN(id_path);
return ret;
}
/**
* Get the ID.struct.property as a python representation, eg:
* bpy.data.foo["bar"].some_struct.some_prop[10]
*/
char *RNA_path_full_property_py_ex(PointerRNA *ptr,
PropertyRNA *prop,
int index,
bool use_fallback)
{
char *id_path;
const char *data_delim;
const char *data_path;
bool data_path_free;
char *ret;
if (!ptr->owner_id) {
return NULL;
}
/* never fails */
id_path = RNA_path_full_ID_py(ptr->owner_id);
data_path = RNA_path_from_ID_to_property(ptr, prop);
if (data_path) {
data_delim = (data_path[0] == '[') ? "" : ".";
data_path_free = true;
}
else {
if (use_fallback) {
/* fuzzy fallback. be explicit in our ignoranc. */
data_path = RNA_property_identifier(prop);
data_delim = " ... ";
}
else {
data_delim = ".";
}
data_path_free = false;
}
if ((index == -1) || (RNA_property_array_check(prop) == false)) {
ret = BLI_sprintfN("%s%s%s", id_path, data_delim, data_path);
}
else {
ret = BLI_sprintfN("%s%s%s[%d]", id_path, data_delim, data_path, index);
}
MEM_freeN(id_path);
if (data_path_free) {
MEM_freeN((void *)data_path);
}
return ret;
}
char *RNA_path_full_property_py(PointerRNA *ptr, PropertyRNA *prop, int index)
{
return RNA_path_full_property_py_ex(ptr, prop, index, false);
}
/**
* Get the struct.property as a python representation, eg:
* some_struct.some_prop[10]
*/
char *RNA_path_struct_property_py(PointerRNA *ptr, PropertyRNA *prop, int index)
{
char *data_path;
char *ret;
if (!ptr->owner_id) {
return NULL;
}
data_path = RNA_path_from_ID_to_property(ptr, prop);
if (data_path == NULL) {
/* this may not be an ID at all, check for simple when pointer owns property.
* TODO, more complex nested case */
if (!RNA_struct_is_ID(ptr->type)) {
const char *prop_identifier = RNA_property_identifier(prop);
if (RNA_struct_find_property(ptr, prop_identifier) == prop) {
data_path = BLI_strdup(prop_identifier);
}
}
}
if ((index == -1) || (RNA_property_array_check(prop) == false)) {
ret = BLI_sprintfN("%s", data_path);
}
else {
ret = BLI_sprintfN("%s[%d]", data_path, index);
}
if (data_path) {
MEM_freeN(data_path);
}
return ret;
}
/**
* Get the struct.property as a python representation, eg:
* some_prop[10]
*/
char *RNA_path_property_py(PointerRNA *UNUSED(ptr), PropertyRNA *prop, int index)
{
char *ret;
if ((index == -1) || (RNA_property_array_check(prop) == false)) {
ret = BLI_sprintfN("%s", RNA_property_identifier(prop));
}
else {
ret = BLI_sprintfN("%s[%d]", RNA_property_identifier(prop), index);
}
return ret;
}
/* Quick name based property access */
bool RNA_boolean_get(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_boolean_get(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
void RNA_boolean_set(PointerRNA *ptr, const char *name, bool value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_boolean_set(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_boolean_get_array(PointerRNA *ptr, const char *name, bool *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_boolean_get_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_boolean_set_array(PointerRNA *ptr, const char *name, const bool *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_boolean_set_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
int RNA_int_get(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_int_get(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
void RNA_int_set(PointerRNA *ptr, const char *name, int value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_int_set(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_int_get_array(PointerRNA *ptr, const char *name, int *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_int_get_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_int_set_array(PointerRNA *ptr, const char *name, const int *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_int_set_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
float RNA_float_get(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_float_get(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
void RNA_float_set(PointerRNA *ptr, const char *name, float value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_float_set(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_float_get_array(PointerRNA *ptr, const char *name, float *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_float_get_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_float_set_array(PointerRNA *ptr, const char *name, const float *values)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_float_set_array(ptr, prop, values);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
int RNA_enum_get(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_enum_get(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
void RNA_enum_set(PointerRNA *ptr, const char *name, int value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_enum_set(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_enum_set_identifier(bContext *C, PointerRNA *ptr, const char *name, const char *id)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
int value;
if (RNA_property_enum_value(C, ptr, prop, id, &value)) {
RNA_property_enum_set(ptr, prop, value);
}
else {
printf("%s: %s.%s has no enum id '%s'.\n", __func__, ptr->type->identifier, name, id);
}
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
bool RNA_enum_is_equal(bContext *C, PointerRNA *ptr, const char *name, const char *enumname)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
const EnumPropertyItem *item;
bool free;
if (prop) {
int i;
bool cmp = false;
RNA_property_enum_items(C, ptr, prop, &item, NULL, &free);
i = RNA_enum_from_identifier(item, enumname);
if (i != -1) {
cmp = (item[i].value == RNA_property_enum_get(ptr, prop));
}
if (free) {
MEM_freeN((void *)item);
}
if (i != -1) {
return cmp;
}
printf("%s: %s.%s item %s not found.\n", __func__, ptr->type->identifier, name, enumname);
return false;
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return false;
}
}
bool RNA_enum_value_from_id(const EnumPropertyItem *item, const char *identifier, int *r_value)
{
const int i = RNA_enum_from_identifier(item, identifier);
if (i != -1) {
*r_value = item[i].value;
return true;
}
else {
return false;
}
}
bool RNA_enum_id_from_value(const EnumPropertyItem *item, int value, const char **r_identifier)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_identifier = item[i].identifier;
return true;
}
else {
return false;
}
}
bool RNA_enum_icon_from_value(const EnumPropertyItem *item, int value, int *r_icon)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_icon = item[i].icon;
return true;
}
else {
return false;
}
}
bool RNA_enum_name_from_value(const EnumPropertyItem *item, int value, const char **r_name)
{
const int i = RNA_enum_from_value(item, value);
if (i != -1) {
*r_name = item[i].name;
return true;
}
else {
return false;
}
}
void RNA_string_get(PointerRNA *ptr, const char *name, char *value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_string_get(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
value[0] = '\0';
}
}
char *RNA_string_get_alloc(PointerRNA *ptr, const char *name, char *fixedbuf, int fixedlen)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
/* TODO, pass length */
return RNA_property_string_get_alloc(ptr, prop, fixedbuf, fixedlen, NULL);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return NULL;
}
}
int RNA_string_length(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_string_length(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
void RNA_string_set(PointerRNA *ptr, const char *name, const char *value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_string_set(ptr, prop, value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
PointerRNA RNA_pointer_get(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_pointer_get(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return PointerRNA_NULL;
}
}
void RNA_pointer_set(PointerRNA *ptr, const char *name, PointerRNA ptr_value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_pointer_set(ptr, prop, ptr_value, NULL);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_pointer_add(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_pointer_add(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_collection_begin(PointerRNA *ptr, const char *name, CollectionPropertyIterator *iter)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_collection_begin(ptr, prop, iter);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_collection_add(PointerRNA *ptr, const char *name, PointerRNA *r_value)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_collection_add(ptr, prop, r_value);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
void RNA_collection_clear(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
RNA_property_collection_clear(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
}
}
int RNA_collection_length(PointerRNA *ptr, const char *name)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, name);
if (prop) {
return RNA_property_collection_length(ptr, prop);
}
else {
printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name);
return 0;
}
}
bool RNA_property_is_set_ex(PointerRNA *ptr, PropertyRNA *prop, bool use_ghost)
{
prop = rna_ensure_property(prop);
if (prop->flag & PROP_IDPROPERTY) {
IDProperty *idprop = rna_idproperty_find(ptr, prop->identifier);
return ((idprop != NULL) && (use_ghost == false || !(idprop->flag & IDP_FLAG_GHOST)));
}
else {
return true;
}
}
bool RNA_property_is_set(PointerRNA *ptr, PropertyRNA *prop)
{
prop = rna_ensure_property(prop);
if (prop->flag & PROP_IDPROPERTY) {
IDProperty *idprop = rna_idproperty_find(ptr, prop->identifier);
return ((idprop != NULL) && !(idprop->flag & IDP_FLAG_GHOST));
}
else {
return true;
}
}
void RNA_property_unset(PointerRNA *ptr, PropertyRNA *prop)
{
prop = rna_ensure_property(prop);
if (prop->flag & PROP_IDPROPERTY) {
rna_idproperty_free(ptr, prop->identifier);
}
}
bool RNA_struct_property_is_set_ex(PointerRNA *ptr, const char *identifier, bool use_ghost)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, identifier);
if (prop) {
return RNA_property_is_set_ex(ptr, prop, use_ghost);
}
else {
/* python raises an error */
/* printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name); */
return 0;
}
}
bool RNA_struct_property_is_set(PointerRNA *ptr, const char *identifier)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, identifier);
if (prop) {
return RNA_property_is_set(ptr, prop);
}
else {
/* python raises an error */
/* printf("%s: %s.%s not found.\n", __func__, ptr->type->identifier, name); */
return 0;
}
}
void RNA_struct_property_unset(PointerRNA *ptr, const char *identifier)
{
PropertyRNA *prop = RNA_struct_find_property(ptr, identifier);
if (prop) {
RNA_property_unset(ptr, prop);
}
}
bool RNA_property_is_idprop(const PropertyRNA *prop)
{
return (prop->magic != RNA_MAGIC);
}
/* mainly for the UI */
bool RNA_property_is_unlink(PropertyRNA *prop)
{
const int flag = RNA_property_flag(prop);
if (RNA_property_type(prop) == PROP_STRING) {
return (flag & PROP_NEVER_UNLINK) == 0;
}
else {
return (flag & (PROP_NEVER_UNLINK | PROP_NEVER_NULL)) == 0;
}
}
/* string representation of a property, python
* compatible but can be used for display too,
* context may be NULL */
char *RNA_pointer_as_string_id(bContext *C, PointerRNA *ptr)
{
DynStr *dynstr = BLI_dynstr_new();
char *cstring;
const char *propname;
int first_time = 1;
BLI_dynstr_append(dynstr, "{");
RNA_STRUCT_BEGIN (ptr, prop) {
propname = RNA_property_identifier(prop);
if (STREQ(propname, "rna_type")) {
continue;
}
if (first_time == 0) {
BLI_dynstr_append(dynstr, ", ");
}
first_time = 0;
cstring = RNA_property_as_string(C, ptr, prop, -1, INT_MAX);
BLI_dynstr_appendf(dynstr, "\"%s\":%s", propname, cstring);
MEM_freeN(cstring);
}
RNA_STRUCT_END;
BLI_dynstr_append(dynstr, "}");
cstring = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
return cstring;
}
static char *rna_pointer_as_string__bldata(PointerRNA *ptr)
{
if (ptr->type == NULL || ptr->owner_id == NULL) {
return BLI_strdup("None");
}
else if (RNA_struct_is_ID(ptr->type)) {
return RNA_path_full_ID_py(ptr->owner_id);
}
else {
return RNA_path_full_struct_py(ptr);
}
}
char *RNA_pointer_as_string(bContext *C,
PointerRNA *ptr,
PropertyRNA *prop_ptr,
PointerRNA *ptr_prop)
{
IDProperty *prop;
if (ptr_prop->data == NULL) {
return BLI_strdup("None");
}
else if ((prop = rna_idproperty_check(&prop_ptr, ptr)) && prop->type != IDP_ID) {
return RNA_pointer_as_string_id(C, ptr_prop);
}
else {
return rna_pointer_as_string__bldata(ptr_prop);
}
}
/* context can be NULL */
char *RNA_pointer_as_string_keywords_ex(bContext *C,
PointerRNA *ptr,
const bool as_function,
const bool all_args,
const bool nested_args,
const int max_prop_length,
PropertyRNA *iterprop)
{
const char *arg_name = NULL;
PropertyRNA *prop;
DynStr *dynstr = BLI_dynstr_new();
char *cstring, *buf;
bool first_iter = true;
int flag, flag_parameter;
RNA_PROP_BEGIN (ptr, propptr, iterprop) {
prop = propptr.data;
flag = RNA_property_flag(prop);
flag_parameter = RNA_parameter_flag(prop);
if (as_function && (flag_parameter & PARM_OUTPUT)) {
continue;
}
arg_name = RNA_property_identifier(prop);
if (STREQ(arg_name, "rna_type")) {
continue;
}
if ((nested_args == false) && (RNA_property_type(prop) == PROP_POINTER)) {
continue;
}
if (as_function && (prop->flag_parameter & PARM_REQUIRED)) {
/* required args don't have useful defaults */
BLI_dynstr_appendf(dynstr, first_iter ? "%s" : ", %s", arg_name);
first_iter = false;
}
else {
bool ok = true;
if (all_args == true) {
/* pass */
}
else if (RNA_struct_idprops_check(ptr->type)) {
ok = RNA_property_is_set(ptr, prop);
}
if (ok) {
if (as_function && RNA_property_type(prop) == PROP_POINTER) {
/* don't expand pointers for functions */
if (flag & PROP_NEVER_NULL) {
/* we cant really do the right thing here. arg=arg?, hrmf! */
buf = BLI_strdup(arg_name);
}
else {
buf = BLI_strdup("None");
}
}
else {
buf = RNA_property_as_string(C, ptr, prop, -1, max_prop_length);
}
BLI_dynstr_appendf(dynstr, first_iter ? "%s=%s" : ", %s=%s", arg_name, buf);
first_iter = false;
MEM_freeN(buf);
}
}
}
RNA_PROP_END;
cstring = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
return cstring;
}
char *RNA_pointer_as_string_keywords(bContext *C,
PointerRNA *ptr,
const bool as_function,
const bool all_args,
const bool nested_args,
const int max_prop_length)
{
PropertyRNA *iterprop;
iterprop = RNA_struct_iterator_property(ptr->type);
return RNA_pointer_as_string_keywords_ex(
C, ptr, as_function, all_args, nested_args, max_prop_length, iterprop);
}
char *RNA_function_as_string_keywords(bContext *C,
FunctionRNA *func,
const bool as_function,
const bool all_args,
const int max_prop_length)
{
PointerRNA funcptr;
PropertyRNA *iterprop;
RNA_pointer_create(NULL, &RNA_Function, func, &funcptr);
iterprop = RNA_struct_find_property(&funcptr, "parameters");
RNA_struct_iterator_property(funcptr.type);
return RNA_pointer_as_string_keywords_ex(
C, &funcptr, as_function, all_args, true, max_prop_length, iterprop);
}
static const char *bool_as_py_string(const int var)
{
return var ? "True" : "False";
}
static void *rna_array_as_string_alloc(
int type, int len, PointerRNA *ptr, PropertyRNA *prop, void **r_buf_end)
{
void *buf_ret = NULL;
if (type == PROP_BOOLEAN) {
bool *buf = buf_ret = MEM_mallocN(sizeof(*buf) * len, __func__);
RNA_property_boolean_get_array(ptr, prop, buf);
*r_buf_end = buf + len;
}
else if (type == PROP_INT) {
int *buf = buf_ret = MEM_mallocN(sizeof(*buf) * len, __func__);
RNA_property_int_get_array(ptr, prop, buf);
*r_buf_end = buf + len;
}
else if (type == PROP_FLOAT) {
float *buf = buf_ret = MEM_mallocN(sizeof(*buf) * len, __func__);
RNA_property_float_get_array(ptr, prop, buf);
*r_buf_end = buf + len;
}
else {
BLI_assert(0);
}
return buf_ret;
}
static void rna_array_as_string_elem(int type, void **buf_p, int len, DynStr *dynstr)
{
/* This will print a comma separated string of the array elements from
* buf start to len. We will add a comma if len == 1 to preserve tuples. */
const int end = len - 1;
if (type == PROP_BOOLEAN) {
bool *buf = *buf_p;
for (int i = 0; i < len; i++, buf++) {
BLI_dynstr_appendf(dynstr, (i < end || !end) ? "%s, " : "%s", bool_as_py_string(*buf));
}
*buf_p = buf;
}
else if (type == PROP_INT) {
int *buf = *buf_p;
for (int i = 0; i < len; i++, buf++) {
BLI_dynstr_appendf(dynstr, (i < end || !end) ? "%d, " : "%d", *buf);
}
*buf_p = buf;
}
else if (type == PROP_FLOAT) {
float *buf = *buf_p;
for (int i = 0; i < len; i++, buf++) {
BLI_dynstr_appendf(dynstr, (i < end || !end) ? "%g, " : "%g", *buf);
}
*buf_p = buf;
}
else {
BLI_assert(0);
}
}
static void rna_array_as_string_recursive(
int type, void **buf_p, int totdim, const int *dim_size, DynStr *dynstr)
{
BLI_dynstr_append(dynstr, "(");
if (totdim > 1) {
totdim--;
const int end = dim_size[totdim] - 1;
for (int i = 0; i <= end; i++) {
rna_array_as_string_recursive(type, buf_p, totdim, dim_size, dynstr);
if (i < end || !end) {
BLI_dynstr_append(dynstr, ", ");
}
}
}
else {
rna_array_as_string_elem(type, buf_p, dim_size[0], dynstr);
}
BLI_dynstr_append(dynstr, ")");
}
static void rna_array_as_string(
int type, int len, PointerRNA *ptr, PropertyRNA *prop, DynStr *dynstr)
{
void *buf_end;
void *buf = rna_array_as_string_alloc(type, len, ptr, prop, &buf_end);
void *buf_step = buf;
int totdim, dim_size[RNA_MAX_ARRAY_DIMENSION];
totdim = RNA_property_array_dimension(ptr, prop, dim_size);
rna_array_as_string_recursive(type, &buf_step, totdim, dim_size, dynstr);
BLI_assert(buf_step == buf_end);
MEM_freeN(buf);
}
char *RNA_property_as_string(
bContext *C, PointerRNA *ptr, PropertyRNA *prop, int index, int max_prop_length)
{
int type = RNA_property_type(prop);
int len = RNA_property_array_length(ptr, prop);
DynStr *dynstr = BLI_dynstr_new();
char *cstring;
/* see if we can coerce into a python type - PropertyType */
switch (type) {
case PROP_BOOLEAN:
if (len == 0) {
BLI_dynstr_append(dynstr, bool_as_py_string(RNA_property_boolean_get(ptr, prop)));
}
else {
if (index != -1) {
BLI_dynstr_append(dynstr,
bool_as_py_string(RNA_property_boolean_get_index(ptr, prop, index)));
}
else {
rna_array_as_string(type, len, ptr, prop, dynstr);
}
}
break;
case PROP_INT:
if (len == 0) {
BLI_dynstr_appendf(dynstr, "%d", RNA_property_int_get(ptr, prop));
}
else {
if (index != -1) {
BLI_dynstr_appendf(dynstr, "%d", RNA_property_int_get_index(ptr, prop, index));
}
else {
rna_array_as_string(type, len, ptr, prop, dynstr);
}
}
break;
case PROP_FLOAT:
if (len == 0) {
BLI_dynstr_appendf(dynstr, "%g", RNA_property_float_get(ptr, prop));
}
else {
if (index != -1) {
BLI_dynstr_appendf(dynstr, "%g", RNA_property_float_get_index(ptr, prop, index));
}
else {
rna_array_as_string(type, len, ptr, prop, dynstr);
}
}
break;
case PROP_STRING: {
char *buf_esc;
char *buf;
int length;
length = RNA_property_string_length(ptr, prop);
buf = MEM_mallocN(sizeof(char) * (length + 1), "RNA_property_as_string");
buf_esc = MEM_mallocN(sizeof(char) * (length * 2 + 1), "RNA_property_as_string esc");
RNA_property_string_get(ptr, prop, buf);
BLI_strescape(buf_esc, buf, length * 2 + 1);
MEM_freeN(buf);
BLI_dynstr_appendf(dynstr, "\"%s\"", buf_esc);
MEM_freeN(buf_esc);
break;
}
case PROP_ENUM: {
/* string arrays don't exist */
const char *identifier;
int val = RNA_property_enum_get(ptr, prop);
if (RNA_property_flag(prop) & PROP_ENUM_FLAG) {
/* represent as a python set */
if (val) {
const EnumPropertyItem *item_array;
bool free;
BLI_dynstr_append(dynstr, "{");
RNA_property_enum_items(C, ptr, prop, &item_array, NULL, &free);
if (item_array) {
const EnumPropertyItem *item = item_array;
bool is_first = true;
for (; item->identifier; item++) {
if (item->identifier[0] && item->value & val) {
BLI_dynstr_appendf(dynstr, is_first ? "'%s'" : ", '%s'", item->identifier);
is_first = false;
}
}
if (free) {
MEM_freeN((void *)item_array);
}
}
BLI_dynstr_append(dynstr, "}");
}
else {
/* annoying exception, don't confuse with dictionary syntax above: {} */
BLI_dynstr_append(dynstr, "set()");
}
}
else if (RNA_property_enum_identifier(C, ptr, prop, val, &identifier)) {
BLI_dynstr_appendf(dynstr, "'%s'", identifier);
}
else {
BLI_dynstr_append(dynstr, "'<UNKNOWN ENUM>'");
}
break;
}
case PROP_POINTER: {
PointerRNA tptr = RNA_property_pointer_get(ptr, prop);
cstring = RNA_pointer_as_string(C, ptr, prop, &tptr);
BLI_dynstr_append(dynstr, cstring);
MEM_freeN(cstring);
break;
}
case PROP_COLLECTION: {
int i = 0;
CollectionPropertyIterator collect_iter;
BLI_dynstr_append(dynstr, "[");
for (RNA_property_collection_begin(ptr, prop, &collect_iter);
(i < max_prop_length) && collect_iter.valid;
RNA_property_collection_next(&collect_iter), i++) {
PointerRNA itemptr = collect_iter.ptr;
if (i != 0) {
BLI_dynstr_append(dynstr, ", ");
}
/* now get every prop of the collection */
cstring = RNA_pointer_as_string(C, ptr, prop, &itemptr);
BLI_dynstr_append(dynstr, cstring);
MEM_freeN(cstring);
}
RNA_property_collection_end(&collect_iter);
BLI_dynstr_append(dynstr, "]");
break;
}
default:
BLI_dynstr_append(dynstr, "'<UNKNOWN TYPE>'"); /* TODO */
break;
}
cstring = BLI_dynstr_get_cstring(dynstr);
BLI_dynstr_free(dynstr);
return cstring;
}
/* Function */
const char *RNA_function_identifier(FunctionRNA *func)
{
return func->identifier;
}
const char *RNA_function_ui_description(FunctionRNA *func)
{
return TIP_(func->description);
}
const char *RNA_function_ui_description_raw(FunctionRNA *func)
{
return func->description;
}
int RNA_function_flag(FunctionRNA *func)
{
return func->flag;
}
int RNA_function_defined(FunctionRNA *func)
{
return func->call != NULL;
}
PropertyRNA *RNA_function_get_parameter(PointerRNA *UNUSED(ptr), FunctionRNA *func, int index)
{
return BLI_findlink(&func->cont.properties, index);
}
PropertyRNA *RNA_function_find_parameter(PointerRNA *UNUSED(ptr),
FunctionRNA *func,
const char *identifier)
{
PropertyRNA *parm;
parm = func->cont.properties.first;
for (; parm; parm = parm->next) {
if (STREQ(RNA_property_identifier(parm), identifier)) {
break;
}
}
return parm;
}
const ListBase *RNA_function_defined_parameters(FunctionRNA *func)
{
return &func->cont.properties;
}
/* Utility */
int RNA_parameter_flag(PropertyRNA *prop)
{
return (int)rna_ensure_property(prop)->flag_parameter;
}
ParameterList *RNA_parameter_list_create(ParameterList *parms,
PointerRNA *UNUSED(ptr),
FunctionRNA *func)
{
PropertyRNA *parm;
PointerRNA null_ptr = PointerRNA_NULL;
void *data;
int alloc_size = 0, size;
parms->arg_count = 0;
parms->ret_count = 0;
/* allocate data */
for (parm = func->cont.properties.first; parm; parm = parm->next) {
alloc_size += rna_parameter_size(parm);
if (parm->flag_parameter & PARM_OUTPUT) {
parms->ret_count++;
}
else {
parms->arg_count++;
}
}
parms->data = MEM_callocN(alloc_size, "RNA_parameter_list_create");
parms->func = func;
parms->alloc_size = alloc_size;
/* set default values */
data = parms->data;
for (parm = func->cont.properties.first; parm; parm = parm->next) {
size = rna_parameter_size(parm);
/* set length to 0, these need to be set later, see bpy_array.c's py_to_array */
if (parm->flag & PROP_DYNAMIC) {
ParameterDynAlloc *data_alloc = data;
data_alloc->array_tot = 0;
data_alloc->array = NULL;
}
if (!(parm->flag_parameter & PARM_REQUIRED) && !(parm->flag & PROP_DYNAMIC)) {
switch (parm->type) {
case PROP_BOOLEAN:
if (parm->arraydimension) {
rna_property_boolean_get_default_array_values(
&null_ptr, (BoolPropertyRNA *)parm, data);
}
else {
memcpy(data, &((BoolPropertyRNA *)parm)->defaultvalue, size);
}
break;
case PROP_INT:
if (parm->arraydimension) {
rna_property_int_get_default_array_values(&null_ptr, (IntPropertyRNA *)parm, data);
}
else {
memcpy(data, &((IntPropertyRNA *)parm)->defaultvalue, size);
}
break;
case PROP_FLOAT:
if (parm->arraydimension) {
rna_property_float_get_default_array_values(&null_ptr, (FloatPropertyRNA *)parm, data);
}
else {
memcpy(data, &((FloatPropertyRNA *)parm)->defaultvalue, size);
}
break;
case PROP_ENUM:
memcpy(data, &((EnumPropertyRNA *)parm)->defaultvalue, size);
break;
case PROP_STRING: {
const char *defvalue = ((StringPropertyRNA *)parm)->defaultvalue;
if (defvalue && defvalue[0]) {
/* causes bug [#29988], possibly this is only correct for thick wrapped
* need to look further into it - campbell */
#if 0
BLI_strncpy(data, defvalue, size);
#else
memcpy(data, &defvalue, size);
#endif
}
break;
}
case PROP_POINTER:
case PROP_COLLECTION:
break;
}
}
data = ((char *)data) + rna_parameter_size(parm);
}
return parms;
}
void RNA_parameter_list_free(ParameterList *parms)
{
PropertyRNA *parm;
int tot;
parm = parms->func->cont.properties.first;
for (tot = 0; parm; parm = parm->next) {
if (parm->type == PROP_COLLECTION) {
BLI_freelistN((ListBase *)((char *)parms->data + tot));
}
else if (parm->flag & PROP_DYNAMIC) {
/* for dynamic arrays and strings, data is a pointer to an array */
ParameterDynAlloc *data_alloc = (void *)(((char *)parms->data) + tot);
if (data_alloc->array) {
MEM_freeN(data_alloc->array);
}
}
tot += rna_parameter_size(parm);
}
MEM_freeN(parms->data);
parms->data = NULL;
parms->func = NULL;
}
int RNA_parameter_list_size(ParameterList *parms)
{
return parms->alloc_size;
}
int RNA_parameter_list_arg_count(ParameterList *parms)
{
return parms->arg_count;
}
int RNA_parameter_list_ret_count(ParameterList *parms)
{
return parms->ret_count;
}
void RNA_parameter_list_begin(ParameterList *parms, ParameterIterator *iter)
{
/* may be useful but unused now */
/* RNA_pointer_create(NULL, &RNA_Function, parms->func, &iter->funcptr); */ /*UNUSED*/
iter->parms = parms;
iter->parm = parms->func->cont.properties.first;
iter->valid = iter->parm != NULL;
iter->offset = 0;
if (iter->valid) {
iter->size = rna_parameter_size(iter->parm);
iter->data = (((char *)iter->parms->data)); /* +iter->offset, always 0 */
}
}
void RNA_parameter_list_next(ParameterIterator *iter)
{
iter->offset += iter->size;
iter->parm = iter->parm->next;
iter->valid = iter->parm != NULL;
if (iter->valid) {
iter->size = rna_parameter_size(iter->parm);
iter->data = (((char *)iter->parms->data) + iter->offset);
}
}
void RNA_parameter_list_end(ParameterIterator *UNUSED(iter))
{
/* nothing to do */
}
void RNA_parameter_get(ParameterList *parms, PropertyRNA *parm, void **value)
{
ParameterIterator iter;
RNA_parameter_list_begin(parms, &iter);
for (; iter.valid; RNA_parameter_list_next(&iter)) {
if (iter.parm == parm) {
break;
}
}
if (iter.valid) {
if (parm->flag & PROP_DYNAMIC) {
/* for dynamic arrays and strings, data is a pointer to an array */
ParameterDynAlloc *data_alloc = iter.data;
*value = data_alloc->array;
}
else {
*value = iter.data;
}
}
else {
*value = NULL;
}
RNA_parameter_list_end(&iter);
}
void RNA_parameter_get_lookup(ParameterList *parms, const char *identifier, void **value)
{
PropertyRNA *parm;
parm = parms->func->cont.properties.first;
for (; parm; parm = parm->next) {
if (STREQ(RNA_property_identifier(parm), identifier)) {
break;
}
}
if (parm) {
RNA_parameter_get(parms, parm, value);
}
}
void RNA_parameter_set(ParameterList *parms, PropertyRNA *parm, const void *value)
{
ParameterIterator iter;
RNA_parameter_list_begin(parms, &iter);
for (; iter.valid; RNA_parameter_list_next(&iter)) {
if (iter.parm == parm) {
break;
}
}
if (iter.valid) {
if (parm->flag & PROP_DYNAMIC) {
/* for dynamic arrays and strings, data is a pointer to an array */
ParameterDynAlloc *data_alloc = iter.data;
size_t size = 0;
switch (parm->type) {
case PROP_STRING:
size = sizeof(char);
break;
case PROP_INT:
case PROP_BOOLEAN:
size = sizeof(int);
break;
case PROP_FLOAT:
size = sizeof(float);
break;
default:
break;
}
size *= data_alloc->array_tot;
if (data_alloc->array) {
MEM_freeN(data_alloc->array);
}
data_alloc->array = MEM_mallocN(size, __func__);
memcpy(data_alloc->array, value, size);
}
else {
memcpy(iter.data, value, iter.size);
}
}
RNA_parameter_list_end(&iter);
}
void RNA_parameter_set_lookup(ParameterList *parms, const char *identifier, const void *value)
{
PropertyRNA *parm;
parm = parms->func->cont.properties.first;
for (; parm; parm = parm->next) {
if (STREQ(RNA_property_identifier(parm), identifier)) {
break;
}
}
if (parm) {
RNA_parameter_set(parms, parm, value);
}
}
int RNA_parameter_dynamic_length_get(ParameterList *parms, PropertyRNA *parm)
{
ParameterIterator iter;
int len = 0;
RNA_parameter_list_begin(parms, &iter);
for (; iter.valid; RNA_parameter_list_next(&iter)) {
if (iter.parm == parm) {
break;
}
}
if (iter.valid) {
len = RNA_parameter_dynamic_length_get_data(parms, parm, iter.data);
}
RNA_parameter_list_end(&iter);
return len;
}
void RNA_parameter_dynamic_length_set(ParameterList *parms, PropertyRNA *parm, int length)
{
ParameterIterator iter;
RNA_parameter_list_begin(parms, &iter);
for (; iter.valid; RNA_parameter_list_next(&iter)) {
if (iter.parm == parm) {
break;
}
}
if (iter.valid) {
RNA_parameter_dynamic_length_set_data(parms, parm, iter.data, length);
}
RNA_parameter_list_end(&iter);
}
int RNA_parameter_dynamic_length_get_data(ParameterList *UNUSED(parms),
PropertyRNA *parm,
void *data)
{
if (parm->flag & PROP_DYNAMIC) {
return (int)((ParameterDynAlloc *)data)->array_tot;
}
return 0;
}
void RNA_parameter_dynamic_length_set_data(ParameterList *UNUSED(parms),
PropertyRNA *parm,
void *data,
int length)
{
if (parm->flag & PROP_DYNAMIC) {
((ParameterDynAlloc *)data)->array_tot = (intptr_t)length;
}
}
int RNA_function_call(
bContext *C, ReportList *reports, PointerRNA *ptr, FunctionRNA *func, ParameterList *parms)
{
if (func->call) {
func->call(C, reports, ptr, parms);
return 0;
}
return -1;
}
int RNA_function_call_lookup(bContext *C,
ReportList *reports,
PointerRNA *ptr,
const char *identifier,
ParameterList *parms)
{
FunctionRNA *func;
func = RNA_struct_find_function(ptr->type, identifier);
if (func) {
return RNA_function_call(C, reports, ptr, func, parms);
}
return -1;
}
int RNA_function_call_direct(
bContext *C, ReportList *reports, PointerRNA *ptr, FunctionRNA *func, const char *format, ...)
{
va_list args;
int ret;
va_start(args, format);
ret = RNA_function_call_direct_va(C, reports, ptr, func, format, args);
va_end(args);
return ret;
}
int RNA_function_call_direct_lookup(bContext *C,
ReportList *reports,
PointerRNA *ptr,
const char *identifier,
const char *format,
...)
{
FunctionRNA *func;
func = RNA_struct_find_function(ptr->type, identifier);
if (func) {
va_list args;
int ret;
va_start(args, format);
ret = RNA_function_call_direct_va(C, reports, ptr, func, format, args);
va_end(args);
return ret;
}
return -1;
}
static int rna_function_format_array_length(const char *format, int ofs, int flen)
{
char lenbuf[16];
int idx = 0;
if (format[ofs++] == '[') {
for (; ofs < flen && format[ofs] != ']' && idx < sizeof(lenbuf) - 1; idx++, ofs++) {
lenbuf[idx] = format[ofs];
}
}
if (ofs < flen && format[ofs + 1] == ']') {
/* XXX put better error reporting for (ofs >= flen) or idx over lenbuf capacity */
lenbuf[idx] = '\0';
return atoi(lenbuf);
}
return 0;
}
static int rna_function_parameter_parse(PointerRNA *ptr,
PropertyRNA *prop,
PropertyType type,
char ftype,
int len,
void *dest,
const void *src,
StructRNA *srna,
const char *tid,
const char *fid,
const char *pid)
{
/* ptr is always a function pointer, prop always a parameter */
switch (type) {
case PROP_BOOLEAN: {
if (ftype != 'b') {
fprintf(
stderr, "%s.%s: wrong type for parameter %s, a boolean was expected\n", tid, fid, pid);
return -1;
}
if (len == 0) {
*((bool *)dest) = *((bool *)src);
}
else {
memcpy(dest, src, len * sizeof(bool));
}
break;
}
case PROP_INT: {
if (ftype != 'i') {
fprintf(stderr,
"%s.%s: wrong type for parameter %s, an integer was expected\n",
tid,
fid,
pid);
return -1;
}
if (len == 0) {
*((int *)dest) = *((int *)src);
}
else {
memcpy(dest, src, len * sizeof(int));
}
break;
}
case PROP_FLOAT: {
if (ftype != 'f') {
fprintf(
stderr, "%s.%s: wrong type for parameter %s, a float was expected\n", tid, fid, pid);
return -1;
}
if (len == 0) {
*((float *)dest) = *((float *)src);
}
else {
memcpy(dest, src, len * sizeof(float));
}
break;
}
case PROP_STRING: {
if (ftype != 's') {
fprintf(
stderr, "%s.%s: wrong type for parameter %s, a string was expected\n", tid, fid, pid);
return -1;
}
*((char **)dest) = *((char **)src);
break;
}
case PROP_ENUM: {
if (ftype != 'e') {
fprintf(
stderr, "%s.%s: wrong type for parameter %s, an enum was expected\n", tid, fid, pid);
return -1;
}
*((int *)dest) = *((int *)src);
break;
}
case PROP_POINTER: {
StructRNA *ptype;
if (ftype != 'O') {
fprintf(
stderr, "%s.%s: wrong type for parameter %s, an object was expected\n", tid, fid, pid);
return -1;
}
ptype = RNA_property_pointer_type(ptr, prop);
if (prop->flag_parameter & PARM_RNAPTR) {
*((PointerRNA *)dest) = *((PointerRNA *)src);
break;
}
if (ptype != srna && !RNA_struct_is_a(srna, ptype)) {
fprintf(stderr,
"%s.%s: wrong type for parameter %s, "
"an object of type %s was expected, passed an object of type %s\n",
tid,
fid,
pid,
RNA_struct_identifier(ptype),
RNA_struct_identifier(srna));
return -1;
}
*((void **)dest) = *((void **)src);
break;
}
case PROP_COLLECTION: {
StructRNA *ptype;
ListBase *lb, *clb;
Link *link;
CollectionPointerLink *clink;
if (ftype != 'C') {
fprintf(stderr,
"%s.%s: wrong type for parameter %s, a collection was expected\n",
tid,
fid,
pid);
return -1;
}
lb = (ListBase *)src;
clb = (ListBase *)dest;
ptype = RNA_property_pointer_type(ptr, prop);
if (ptype != srna && !RNA_struct_is_a(srna, ptype)) {
fprintf(stderr,
"%s.%s: wrong type for parameter %s, "
"a collection of objects of type %s was expected, "
"passed a collection of objects of type %s\n",
tid,
fid,
pid,
RNA_struct_identifier(ptype),
RNA_struct_identifier(srna));
return -1;
}
for (link = lb->first; link; link = link->next) {
clink = MEM_callocN(sizeof(CollectionPointerLink), "CCollectionPointerLink");
RNA_pointer_create(NULL, srna, link, &clink->ptr);
BLI_addtail(clb, clink);
}
break;
}
default: {
if (len == 0) {
fprintf(stderr, "%s.%s: unknown type for parameter %s\n", tid, fid, pid);
}
else {
fprintf(stderr, "%s.%s: unknown array type for parameter %s\n", tid, fid, pid);
}
return -1;
}
}
return 0;
}
int RNA_function_call_direct_va(bContext *C,
ReportList *reports,
PointerRNA *ptr,
FunctionRNA *func,
const char *format,
va_list args)
{
PointerRNA funcptr;
ParameterList parms;
ParameterIterator iter;
PropertyRNA *pret, *parm;
PropertyType type;
int i, ofs, flen, flag_parameter, len, alen, err = 0;
const char *tid, *fid, *pid = NULL;
char ftype;
void **retdata = NULL;
RNA_pointer_create(NULL, &RNA_Function, func, &funcptr);
tid = RNA_struct_identifier(ptr->type);
fid = RNA_function_identifier(func);
pret = func->c_ret;
flen = strlen(format);
RNA_parameter_list_create(&parms, ptr, func);
RNA_parameter_list_begin(&parms, &iter);
for (i = 0, ofs = 0; iter.valid; RNA_parameter_list_next(&iter), i++) {
parm = iter.parm;
flag_parameter = RNA_parameter_flag(parm);
if (parm == pret) {
retdata = iter.data;
continue;
}
else if (flag_parameter & PARM_OUTPUT) {
continue;
}
pid = RNA_property_identifier(parm);
if (ofs >= flen || format[ofs] == 'N') {
if (parm->flag_parameter & PARM_REQUIRED) {
err = -1;
fprintf(stderr, "%s.%s: missing required parameter %s\n", tid, fid, pid);
break;
}
ofs++;
continue;
}
type = RNA_property_type(parm);
ftype = format[ofs++];
len = RNA_property_array_length(&funcptr, parm);
alen = rna_function_format_array_length(format, ofs, flen);
if (len != alen) {
err = -1;
fprintf(stderr,
"%s.%s: for parameter %s, "
"was expecting an array of %i elements, "
"passed %i elements instead\n",
tid,
fid,
pid,
len,
alen);
break;
}
switch (type) {
case PROP_BOOLEAN:
case PROP_INT:
case PROP_ENUM: {
int arg = va_arg(args, int);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, &arg, NULL, tid, fid, pid);
break;
}
case PROP_FLOAT: {
double arg = va_arg(args, double);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, &arg, NULL, tid, fid, pid);
break;
}
case PROP_STRING: {
const char *arg = va_arg(args, char *);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, &arg, NULL, tid, fid, pid);
break;
}
case PROP_POINTER: {
StructRNA *srna = va_arg(args, StructRNA *);
void *arg = va_arg(args, void *);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, &arg, srna, tid, fid, pid);
break;
}
case PROP_COLLECTION: {
StructRNA *srna = va_arg(args, StructRNA *);
ListBase *arg = va_arg(args, ListBase *);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, &arg, srna, tid, fid, pid);
break;
}
default: {
/* handle errors */
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, iter.data, NULL, NULL, tid, fid, pid);
break;
}
}
if (err != 0) {
break;
}
}
if (err == 0) {
err = RNA_function_call(C, reports, ptr, func, &parms);
}
/* XXX throw error when more parameters than those needed are passed or leave silent? */
if (err == 0 && pret && ofs < flen && format[ofs++] == 'R') {
parm = pret;
type = RNA_property_type(parm);
ftype = format[ofs++];
len = RNA_property_array_length(&funcptr, parm);
alen = rna_function_format_array_length(format, ofs, flen);
if (len != alen) {
err = -1;
fprintf(stderr,
"%s.%s: for return parameter %s, "
"was expecting an array of %i elements, passed %i elements instead\n",
tid,
fid,
pid,
len,
alen);
}
else {
switch (type) {
case PROP_BOOLEAN:
case PROP_INT:
case PROP_ENUM: {
int *arg = va_arg(args, int *);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, arg, retdata, NULL, tid, fid, pid);
break;
}
case PROP_FLOAT: {
float *arg = va_arg(args, float *);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, arg, retdata, NULL, tid, fid, pid);
break;
}
case PROP_STRING: {
char **arg = va_arg(args, char **);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, arg, retdata, NULL, tid, fid, pid);
break;
}
case PROP_POINTER: {
StructRNA *srna = va_arg(args, StructRNA *);
void **arg = va_arg(args, void **);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, arg, retdata, srna, tid, fid, pid);
break;
}
case PROP_COLLECTION: {
StructRNA *srna = va_arg(args, StructRNA *);
ListBase **arg = va_arg(args, ListBase **);
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, arg, retdata, srna, tid, fid, pid);
break;
}
default: {
/* handle errors */
err = rna_function_parameter_parse(
&funcptr, parm, type, ftype, len, NULL, NULL, NULL, tid, fid, pid);
break;
}
}
}
}
RNA_parameter_list_end(&iter);
RNA_parameter_list_free(&parms);
return err;
}
int RNA_function_call_direct_va_lookup(bContext *C,
ReportList *reports,
PointerRNA *ptr,
const char *identifier,
const char *format,
va_list args)
{
FunctionRNA *func;
func = RNA_struct_find_function(ptr->type, identifier);
if (func) {
return RNA_function_call_direct_va(C, reports, ptr, func, format, args);
}
return 0;
}
const char *RNA_translate_ui_text(
const char *text, const char *text_ctxt, StructRNA *type, PropertyRNA *prop, int translate)
{
return rna_translate_ui_text(text, text_ctxt, type, prop, translate);
}
bool RNA_property_reset(PointerRNA *ptr, PropertyRNA *prop, int index)
{
int len;
/* get the length of the array to work with */
len = RNA_property_array_length(ptr, prop);
/* get and set the default values as appropriate for the various types */
switch (RNA_property_type(prop)) {
case PROP_BOOLEAN:
if (len) {
if (index == -1) {
bool *tmparray = MEM_callocN(sizeof(bool) * len, "reset_defaults - boolean");
RNA_property_boolean_get_default_array(ptr, prop, tmparray);
RNA_property_boolean_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
else {
int value = RNA_property_boolean_get_default_index(ptr, prop, index);
RNA_property_boolean_set_index(ptr, prop, index, value);
}
}
else {
int value = RNA_property_boolean_get_default(ptr, prop);
RNA_property_boolean_set(ptr, prop, value);
}
return true;
case PROP_INT:
if (len) {
if (index == -1) {
int *tmparray = MEM_callocN(sizeof(int) * len, "reset_defaults - int");
RNA_property_int_get_default_array(ptr, prop, tmparray);
RNA_property_int_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
else {
int value = RNA_property_int_get_default_index(ptr, prop, index);
RNA_property_int_set_index(ptr, prop, index, value);
}
}
else {
int value = RNA_property_int_get_default(ptr, prop);
RNA_property_int_set(ptr, prop, value);
}
return true;
case PROP_FLOAT:
if (len) {
if (index == -1) {
float *tmparray = MEM_callocN(sizeof(float) * len, "reset_defaults - float");
RNA_property_float_get_default_array(ptr, prop, tmparray);
RNA_property_float_set_array(ptr, prop, tmparray);
MEM_freeN(tmparray);
}
else {
float value = RNA_property_float_get_default_index(ptr, prop, index);
RNA_property_float_set_index(ptr, prop, index, value);
}
}
else {
float value = RNA_property_float_get_default(ptr, prop);
RNA_property_float_set(ptr, prop, value);
}
return true;
case PROP_ENUM: {
int value = RNA_property_enum_get_default(ptr, prop);
RNA_property_enum_set(ptr, prop, value);
return true;
}
case PROP_STRING: {
char *value = RNA_property_string_get_default_alloc(ptr, prop, NULL, 0);
RNA_property_string_set(ptr, prop, value);
MEM_freeN(value);
return true;
}
case PROP_POINTER: {
PointerRNA value = RNA_property_pointer_get_default(ptr, prop);
RNA_property_pointer_set(ptr, prop, value, NULL);
return true;
}
default:
/* FIXME: are there still any cases that haven't been handled?
* comment out "default" block to check :) */
return false;
}
}
bool RNA_property_assign_default(PointerRNA *ptr, PropertyRNA *prop)
{
if (!RNA_property_is_idprop(prop) || RNA_property_array_check(prop)) {
return false;
}
/* get and set the default values as appropriate for the various types */
switch (RNA_property_type(prop)) {
case PROP_INT: {
int value = RNA_property_int_get(ptr, prop);
return RNA_property_int_set_default(ptr, prop, value);
}
case PROP_FLOAT: {
float value = RNA_property_float_get(ptr, prop);
return RNA_property_float_set_default(ptr, prop, value);
}
default:
return false;
}
}
/* use RNA_warning macro which includes __func__ suffix */
void _RNA_warning(const char *format, ...)
{
va_list args;
va_start(args, format);
vprintf(format, args);
va_end(args);
/* gcc macro adds '\n', but cant use for other compilers */
#ifndef __GNUC__
fputc('\n', stdout);
#endif
#ifdef WITH_PYTHON
{
extern void PyC_LineSpit(void);
PyC_LineSpit();
}
#endif
}
bool RNA_path_resolved_create(PointerRNA *ptr,
struct PropertyRNA *prop,
const int prop_index,
PathResolvedRNA *r_anim_rna)
{
int array_len = RNA_property_array_length(ptr, prop);
if ((array_len == 0) || (prop_index < array_len)) {
r_anim_rna->ptr = *ptr;
r_anim_rna->prop = prop;
r_anim_rna->prop_index = array_len ? prop_index : -1;
return true;
}
else {
return false;
}
}
static char rna_struct_state_owner[64];
void RNA_struct_state_owner_set(const char *name)
{
if (name) {
BLI_strncpy(rna_struct_state_owner, name, sizeof(rna_struct_state_owner));
}
else {
rna_struct_state_owner[0] = '\0';
}
}
const char *RNA_struct_state_owner_get(void)
{
if (rna_struct_state_owner[0]) {
return rna_struct_state_owner;
}
return NULL;
}
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