sp-item.cpp revision e898e8dd3fbc3e21f3a35f089a0d1c1dc6d48850
/** \file
* Base class for visual SVG elements
*/
/*
* Authors:
* Lauris Kaplinski <lauris@kaplinski.com>
* bulia byak <buliabyak@users.sf.net>
* Johan Engelen <j.b.c.engelen@ewi.utwente.nl>
* Abhishek Sharma
* Jon A. Cruz <jon@joncruz.org>
*
* Copyright (C) 2001-2006 authors
* Copyright (C) 2001 Ximian, Inc.
*
* Released under GNU GPL, read the file 'COPYING' for more information
*/
/** \class SPItem
*
* SPItem is an abstract base class for all graphic (visible) SVG nodes. It
* is a subclass of SPObject, with great deal of specific functionality.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sp-item.h"
#include "svg/svg.h"
#include "print.h"
#include "display/nr-arena.h"
#include "display/nr-arena-item.h"
#include "attributes.h"
#include "document.h"
#include "uri.h"
#include "inkscape.h"
#include "desktop.h"
#include "desktop-handles.h"
#include "style.h"
#include <glibmm/i18n.h>
#include "sp-root.h"
#include "sp-clippath.h"
#include "sp-mask.h"
#include "sp-rect.h"
#include "sp-use.h"
#include "sp-text.h"
#include "sp-item-rm-unsatisfied-cns.h"
#include "sp-pattern.h"
#include "sp-paint-server.h"
#include "sp-switch.h"
#include "sp-guide-constraint.h"
#include "gradient-chemistry.h"
#include "preferences.h"
#include "conn-avoid-ref.h"
#include "conditions.h"
#include "sp-filter-reference.h"
#include "filter-chemistry.h"
#include "sp-guide.h"
#include "sp-title.h"
#include "sp-desc.h"
#include "libnr/nr-convert2geom.h"
#include "util/find-last-if.h"
#include "util/reverse-list.h"
#include <2geom/rect.h>
#include <2geom/affine.h>
#include <2geom/transforms.h>
#include "xml/repr.h"
#include "extract-uri.h"
#include "helper/geom.h"
#include "live_effects/lpeobject.h"
#include "live_effects/effect.h"
#include "live_effects/lpeobject-reference.h"
#define noSP_ITEM_DEBUG_IDLE
SPObjectClass * SPItemClass::static_parent_class=0;
/**
* Registers SPItem class and returns its type number.
*/
GType
SPItem::getType(void)
{
static GType type = 0;
if (!type) {
GTypeInfo info = {
sizeof(SPItemClass),
NULL, NULL,
(GClassInitFunc) SPItemClass::sp_item_class_init,
NULL, NULL,
sizeof(SPItem),
16,
(GInstanceInitFunc) sp_item_init,
NULL, /* value_table */
};
type = g_type_register_static(SP_TYPE_OBJECT, "SPItem", &info, (GTypeFlags)0);
}
return type;
}
/**
* SPItem vtable initialization.
*/
void
SPItemClass::sp_item_class_init(SPItemClass *klass)
{
SPObjectClass *sp_object_class = (SPObjectClass *) klass;
static_parent_class = (SPObjectClass *)g_type_class_ref(SP_TYPE_OBJECT);
sp_object_class->build = SPItem::sp_item_build;
sp_object_class->release = SPItem::sp_item_release;
sp_object_class->set = SPItem::sp_item_set;
sp_object_class->update = SPItem::sp_item_update;
sp_object_class->write = SPItem::sp_item_write;
klass->description = SPItem::sp_item_private_description;
klass->snappoints = SPItem::sp_item_private_snappoints;
}
/**
* Callback for SPItem object initialization.
*/
void SPItem::sp_item_init(SPItem *item)
{
item->init();
}
void SPItem::init() {
sensitive = TRUE;
transform_center_x = 0;
transform_center_y = 0;
_is_evaluated = true;
_evaluated_status = StatusUnknown;
transform = Geom::identity();
display = NULL;
clip_ref = new SPClipPathReference(this);
sigc::signal<void, SPObject *, SPObject *> cs1 = clip_ref->changedSignal();
sigc::slot2<void,SPObject*, SPObject *> sl1 = sigc::bind(sigc::ptr_fun(clip_ref_changed), this);
_clip_ref_connection = cs1.connect(sl1);
mask_ref = new SPMaskReference(this);
sigc::signal<void, SPObject *, SPObject *> cs2 = mask_ref->changedSignal();
sigc::slot2<void,SPObject*, SPObject *> sl2=sigc::bind(sigc::ptr_fun(mask_ref_changed), this);
_mask_ref_connection = cs2.connect(sl2);
avoidRef = new SPAvoidRef(this);
new (&constraints) std::vector<SPGuideConstraint>();
new (&_transformed_signal) sigc::signal<void, Geom::Affine const *, SPItem *>();
}
bool SPItem::isVisibleAndUnlocked() const {
return (!isHidden() && !isLocked());
}
bool SPItem::isVisibleAndUnlocked(unsigned display_key) const {
return (!isHidden(display_key) && !isLocked());
}
bool SPItem::isLocked() const {
for (SPObject const *o = this; o != NULL; o = o->parent) {
if (SP_IS_ITEM(o) && !(SP_ITEM(o)->sensitive)) {
return true;
}
}
return false;
}
void SPItem::setLocked(bool locked) {
setAttribute("sodipodi:insensitive",
( locked ? "1" : NULL ));
updateRepr();
}
bool SPItem::isHidden() const {
if (!isEvaluated())
return true;
return style->display.computed == SP_CSS_DISPLAY_NONE;
}
void SPItem::setHidden(bool hide) {
style->display.set = TRUE;
style->display.value = ( hide ? SP_CSS_DISPLAY_NONE : SP_CSS_DISPLAY_INLINE );
style->display.computed = style->display.value;
style->display.inherit = FALSE;
updateRepr();
}
bool SPItem::isHidden(unsigned display_key) const {
if (!isEvaluated())
return true;
for ( SPItemView *view(display) ; view ; view = view->next ) {
if ( view->key == display_key ) {
g_assert(view->arenaitem != NULL);
for ( NRArenaItem *arenaitem = view->arenaitem ;
arenaitem ; arenaitem = arenaitem->parent )
{
if (!arenaitem->visible) {
return true;
}
}
return false;
}
}
return true;
}
void SPItem::setEvaluated(bool evaluated) {
_is_evaluated = evaluated;
_evaluated_status = StatusSet;
}
void SPItem::resetEvaluated() {
if ( StatusCalculated == _evaluated_status ) {
_evaluated_status = StatusUnknown;
bool oldValue = _is_evaluated;
if ( oldValue != isEvaluated() ) {
requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG | SP_OBJECT_STYLE_MODIFIED_FLAG);
}
} if ( StatusSet == _evaluated_status ) {
if (SP_IS_SWITCH(parent)) {
SP_SWITCH(parent)->resetChildEvaluated();
}
}
}
bool SPItem::isEvaluated() const {
if ( StatusUnknown == _evaluated_status ) {
_is_evaluated = sp_item_evaluate(this);
_evaluated_status = StatusCalculated;
}
return _is_evaluated;
}
/**
* Returns something suitable for the `Hide' checkbox in the Object Properties dialog box.
* Corresponds to setExplicitlyHidden.
*/
bool SPItem::isExplicitlyHidden() const
{
return (style->display.set
&& style->display.value == SP_CSS_DISPLAY_NONE);
}
/**
* Sets the display CSS property to `hidden' if \a val is true,
* otherwise makes it unset
*/
void SPItem::setExplicitlyHidden(bool const val) {
style->display.set = val;
style->display.value = ( val ? SP_CSS_DISPLAY_NONE : SP_CSS_DISPLAY_INLINE );
style->display.computed = style->display.value;
updateRepr();
}
/**
* Sets the transform_center_x and transform_center_y properties to retain the rotation centre
*/
void SPItem::setCenter(Geom::Point object_centre) {
// for getBounds() to work
document->ensureUpToDate();
Geom::OptRect bbox = getBounds(i2dt_affine());
if (bbox) {
transform_center_x = object_centre[Geom::X] - bbox->midpoint()[Geom::X];
if (fabs(transform_center_x) < 1e-5) // rounding error
transform_center_x = 0;
transform_center_y = object_centre[Geom::Y] - bbox->midpoint()[Geom::Y];
if (fabs(transform_center_y) < 1e-5) // rounding error
transform_center_y = 0;
}
}
void
SPItem::unsetCenter() {
transform_center_x = 0;
transform_center_y = 0;
}
bool SPItem::isCenterSet() {
return (transform_center_x != 0 || transform_center_y != 0);
}
Geom::Point SPItem::getCenter() const {
// for getBounds() to work
document->ensureUpToDate();
Geom::OptRect bbox = getBounds(i2dt_affine());
if (bbox) {
return bbox->midpoint() + Geom::Point (transform_center_x, transform_center_y);
} else {
return Geom::Point(0, 0); // something's wrong!
}
}
namespace {
bool is_item(SPObject const &object) {
return SP_IS_ITEM(&object);
}
}
void SPItem::raiseToTop() {
using Inkscape::Algorithms::find_last_if;
SPObject *topmost=find_last_if<SPObject::SiblingIterator>(
next, NULL, &is_item
);
if (topmost) {
getRepr()->parent()->changeOrder( getRepr(), topmost->getRepr() );
}
}
void SPItem::raiseOne() {
SPObject *next_higher=std::find_if<SPObject::SiblingIterator>(
next, NULL, &is_item
);
if (next_higher) {
Inkscape::XML::Node *ref = next_higher->getRepr();
getRepr()->parent()->changeOrder(getRepr(), ref);
}
}
void SPItem::lowerOne() {
using Inkscape::Util::MutableList;
using Inkscape::Util::reverse_list;
MutableList<SPObject &> next_lower=std::find_if(
reverse_list<SPObject::SiblingIterator>(
parent->firstChild(), this
),
MutableList<SPObject &>(),
&is_item
);
if (next_lower) {
++next_lower;
Inkscape::XML::Node *ref = ( next_lower ? next_lower->getRepr() : NULL );
getRepr()->parent()->changeOrder(getRepr(), ref);
}
}
void SPItem::lowerToBottom() {
using Inkscape::Algorithms::find_last_if;
using Inkscape::Util::MutableList;
using Inkscape::Util::reverse_list;
MutableList<SPObject &> bottom=find_last_if(
reverse_list<SPObject::SiblingIterator>(
parent->firstChild(), this
),
MutableList<SPObject &>(),
&is_item
);
if (bottom) {
++bottom;
Inkscape::XML::Node *ref = ( bottom ? bottom->getRepr() : NULL );
getRepr()->parent()->changeOrder(getRepr(), ref);
}
}
void SPItem::sp_item_build(SPObject *object, SPDocument *document, Inkscape::XML::Node *repr)
{
object->readAttr( "style" );
object->readAttr( "transform" );
object->readAttr( "clip-path" );
object->readAttr( "mask" );
object->readAttr( "sodipodi:insensitive" );
object->readAttr( "sodipodi:nonprintable" );
object->readAttr( "inkscape:transform-center-x" );
object->readAttr( "inkscape:transform-center-y" );
object->readAttr( "inkscape:connector-avoid" );
object->readAttr( "inkscape:connection-points" );
if (((SPObjectClass *) (SPItemClass::static_parent_class))->build) {
(* ((SPObjectClass *) (SPItemClass::static_parent_class))->build)(object, document, repr);
}
}
void SPItem::sp_item_release(SPObject *object)
{
SPItem *item = (SPItem *) object;
item->_clip_ref_connection.disconnect();
item->_mask_ref_connection.disconnect();
// Note: do this here before the clip_ref is deleted, since calling
// ensureUpToDate() for triggered routing may reference
// the deleted clip_ref.
if (item->avoidRef) {
delete item->avoidRef;
item->avoidRef = NULL;
}
if (item->clip_ref) {
item->clip_ref->detach();
delete item->clip_ref;
item->clip_ref = NULL;
}
if (item->mask_ref) {
item->mask_ref->detach();
delete item->mask_ref;
item->mask_ref = NULL;
}
if (((SPObjectClass *) (SPItemClass::static_parent_class))->release) {
((SPObjectClass *) SPItemClass::static_parent_class)->release(object);
}
while (item->display) {
nr_arena_item_unparent(item->display->arenaitem);
item->display = sp_item_view_list_remove(item->display, item->display);
}
item->_transformed_signal.~signal();
}
void SPItem::sp_item_set(SPObject *object, unsigned key, gchar const *value)
{
SPItem *item = (SPItem *) object;
switch (key) {
case SP_ATTR_TRANSFORM: {
Geom::Affine t;
if (value && sp_svg_transform_read(value, &t)) {
item->set_item_transform(t);
} else {
item->set_item_transform(Geom::identity());
}
break;
}
case SP_PROP_CLIP_PATH: {
gchar *uri = extract_uri(value);
if (uri) {
try {
item->clip_ref->attach(Inkscape::URI(uri));
} catch (Inkscape::BadURIException &e) {
g_warning("%s", e.what());
item->clip_ref->detach();
}
g_free(uri);
} else {
item->clip_ref->detach();
}
break;
}
case SP_PROP_MASK: {
gchar *uri = extract_uri(value);
if (uri) {
try {
item->mask_ref->attach(Inkscape::URI(uri));
} catch (Inkscape::BadURIException &e) {
g_warning("%s", e.what());
item->mask_ref->detach();
}
g_free(uri);
} else {
item->mask_ref->detach();
}
break;
}
case SP_ATTR_SODIPODI_INSENSITIVE:
item->sensitive = !value;
for (SPItemView *v = item->display; v != NULL; v = v->next) {
nr_arena_item_set_sensitive(v->arenaitem, item->sensitive);
}
break;
case SP_ATTR_CONNECTOR_AVOID:
item->avoidRef->setAvoid(value);
break;
case SP_ATTR_CONNECTION_POINTS:
item->avoidRef->setConnectionPoints(value);
break;
case SP_ATTR_TRANSFORM_CENTER_X:
if (value) {
item->transform_center_x = g_strtod(value, NULL);
} else {
item->transform_center_x = 0;
}
object->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
break;
case SP_ATTR_TRANSFORM_CENTER_Y:
if (value) {
item->transform_center_y = g_strtod(value, NULL);
} else {
item->transform_center_y = 0;
}
object->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
break;
case SP_PROP_SYSTEM_LANGUAGE:
case SP_PROP_REQUIRED_FEATURES:
case SP_PROP_REQUIRED_EXTENSIONS:
{
item->resetEvaluated();
// pass to default handler
}
default:
if (SP_ATTRIBUTE_IS_CSS(key)) {
sp_style_read_from_object(object->style, object);
object->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG | SP_OBJECT_STYLE_MODIFIED_FLAG);
} else {
if (((SPObjectClass *) (SPItemClass::static_parent_class))->set) {
(* ((SPObjectClass *) (SPItemClass::static_parent_class))->set)(object, key, value);
}
}
break;
}
}
void SPItem::clip_ref_changed(SPObject *old_clip, SPObject *clip, SPItem *item)
{
if (old_clip) {
SPItemView *v;
/* Hide clippath */
for (v = item->display; v != NULL; v = v->next) {
SP_CLIPPATH(old_clip)->hide(NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_clip(v->arenaitem, NULL);
}
}
if (SP_IS_CLIPPATH(clip)) {
NRRect bbox;
item->invoke_bbox( &bbox, Geom::identity(), TRUE);
for (SPItemView *v = item->display; v != NULL; v = v->next) {
if (!v->arenaitem->key) {
NR_ARENA_ITEM_SET_KEY(v->arenaitem, SPItem::display_key_new(3));
}
NRArenaItem *ai = SP_CLIPPATH(clip)->show(
NR_ARENA_ITEM_ARENA(v->arenaitem),
NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_clip(v->arenaitem, ai);
nr_arena_item_unref(ai);
SP_CLIPPATH(clip)->setBBox(NR_ARENA_ITEM_GET_KEY(v->arenaitem), &bbox);
clip->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
}
}
}
void SPItem::mask_ref_changed(SPObject *old_mask, SPObject *mask, SPItem *item)
{
if (old_mask) {
/* Hide mask */
for (SPItemView *v = item->display; v != NULL; v = v->next) {
sp_mask_hide(SP_MASK(old_mask), NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_mask(v->arenaitem, NULL);
}
}
if (SP_IS_MASK(mask)) {
NRRect bbox;
item->invoke_bbox( &bbox, Geom::identity(), TRUE);
for (SPItemView *v = item->display; v != NULL; v = v->next) {
if (!v->arenaitem->key) {
NR_ARENA_ITEM_SET_KEY(v->arenaitem, SPItem::display_key_new(3));
}
NRArenaItem *ai = sp_mask_show(SP_MASK(mask),
NR_ARENA_ITEM_ARENA(v->arenaitem),
NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_mask(v->arenaitem, ai);
nr_arena_item_unref(ai);
sp_mask_set_bbox(SP_MASK(mask), NR_ARENA_ITEM_GET_KEY(v->arenaitem), &bbox);
mask->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
}
}
}
void SPItem::sp_item_update(SPObject *object, SPCtx *ctx, guint flags)
{
SPItem *item = SP_ITEM(object);
if (((SPObjectClass *) (SPItemClass::static_parent_class))->update) {
(* ((SPObjectClass *) (SPItemClass::static_parent_class))->update)(object, ctx, flags);
}
if (flags & (SP_OBJECT_CHILD_MODIFIED_FLAG | SP_OBJECT_MODIFIED_FLAG | SP_OBJECT_STYLE_MODIFIED_FLAG)) {
if (flags & SP_OBJECT_MODIFIED_FLAG) {
for (SPItemView *v = item->display; v != NULL; v = v->next) {
nr_arena_item_set_transform(v->arenaitem, item->transform);
}
}
SPClipPath *clip_path = item->clip_ref ? item->clip_ref->getObject() : NULL;
SPMask *mask = item->mask_ref ? item->mask_ref->getObject() : NULL;
if ( clip_path || mask ) {
NRRect bbox;
item->invoke_bbox( &bbox, Geom::identity(), TRUE);
if (clip_path) {
for (SPItemView *v = item->display; v != NULL; v = v->next) {
clip_path->setBBox(NR_ARENA_ITEM_GET_KEY(v->arenaitem), &bbox);
}
}
if (mask) {
for (SPItemView *v = item->display; v != NULL; v = v->next) {
sp_mask_set_bbox(mask, NR_ARENA_ITEM_GET_KEY(v->arenaitem), &bbox);
}
}
}
if (flags & SP_OBJECT_STYLE_MODIFIED_FLAG) {
for (SPItemView *v = item->display; v != NULL; v = v->next) {
nr_arena_item_set_opacity(v->arenaitem, SP_SCALE24_TO_FLOAT(object->style->opacity.value));
nr_arena_item_set_visible(v->arenaitem, !item->isHidden());
}
}
}
/* Update bounding box data used by filters */
if (item->style->filter.set && item->display) {
Geom::OptRect item_bbox;
item->invoke_bbox( item_bbox, Geom::identity(), TRUE, SPItem::GEOMETRIC_BBOX);
SPItemView *itemview = item->display;
do {
if (itemview->arenaitem)
nr_arena_item_set_item_bbox(itemview->arenaitem, item_bbox);
} while ( (itemview = itemview->next) );
}
// Update libavoid with item geometry (for connector routing).
if (item->avoidRef)
item->avoidRef->handleSettingChange();
}
Inkscape::XML::Node *SPItem::sp_item_write(SPObject *const object, Inkscape::XML::Document *xml_doc, Inkscape::XML::Node *repr, guint flags)
{
SPItem *item = SP_ITEM(object);
// in the case of SP_OBJECT_WRITE_BUILD, the item should always be newly created,
// so we need to add any children from the underlying object to the new repr
if (flags & SP_OBJECT_WRITE_BUILD) {
GSList *l = NULL;
for (SPObject *child = object->firstChild(); child != NULL; child = child->next ) {
if (SP_IS_TITLE(child) || SP_IS_DESC(child)) {
Inkscape::XML::Node *crepr = child->updateRepr(xml_doc, NULL, flags);
if (crepr) {
l = g_slist_prepend (l, crepr);
}
}
}
while (l) {
repr->addChild((Inkscape::XML::Node *) l->data, NULL);
Inkscape::GC::release((Inkscape::XML::Node *) l->data);
l = g_slist_remove (l, l->data);
}
} else {
for (SPObject *child = object->firstChild() ; child != NULL; child = child->next ) {
if (SP_IS_TITLE(child) || SP_IS_DESC(child)) {
child->updateRepr(flags);
}
}
}
gchar *c = sp_svg_transform_write(item->transform);
repr->setAttribute("transform", c);
g_free(c);
if (flags & SP_OBJECT_WRITE_EXT) {
repr->setAttribute("sodipodi:insensitive", ( item->sensitive ? NULL : "true" ));
if (item->transform_center_x != 0)
sp_repr_set_svg_double (repr, "inkscape:transform-center-x", item->transform_center_x);
else
repr->setAttribute ("inkscape:transform-center-x", NULL);
if (item->transform_center_y != 0)
sp_repr_set_svg_double (repr, "inkscape:transform-center-y", item->transform_center_y);
else
repr->setAttribute ("inkscape:transform-center-y", NULL);
}
if (item->clip_ref->getObject()) {
const gchar *value = g_strdup_printf ("url(%s)", item->clip_ref->getURI()->toString());
repr->setAttribute ("clip-path", value);
g_free ((void *) value);
}
if (item->mask_ref->getObject()) {
const gchar *value = g_strdup_printf ("url(%s)", item->mask_ref->getURI()->toString());
repr->setAttribute ("mask", value);
g_free ((void *) value);
}
if (((SPObjectClass *) (SPItemClass::static_parent_class))->write) {
((SPObjectClass *) (SPItemClass::static_parent_class))->write(object, xml_doc, repr, flags);
}
return repr;
}
/**
* \return There is no guarantee that the return value will contain a rectangle.
If this item does not have a boundingbox, it might well be empty.
*/
Geom::OptRect SPItem::getBounds(Geom::Affine const &transform,
SPItem::BBoxType type,
unsigned int /*dkey*/) const
{
Geom::OptRect r;
invoke_bbox_full( r, transform, type, TRUE);
return r;
}
void SPItem::invoke_bbox( Geom::OptRect &bbox, Geom::Affine const &transform, unsigned const clear, SPItem::BBoxType type)
{
invoke_bbox_full( bbox, transform, type, clear);
}
// DEPRECATED to phase out the use of NRRect in favor of Geom::OptRect
void SPItem::invoke_bbox( NRRect *bbox, Geom::Affine const &transform, unsigned const clear, SPItem::BBoxType type)
{
invoke_bbox_full( bbox, transform, type, clear);
}
/** Calls \a item's subclass' bounding box method; clips it by the bbox of clippath, if any; and
* unions the resulting bbox with \a bbox. If \a clear is true, empties \a bbox first. Passes the
* transform and the flags to the actual bbox methods. Note that many of subclasses (e.g. groups,
* clones), in turn, call this function in their bbox methods.
* \retval bbox Note that there is no guarantee that bbox will contain a rectangle when the
* function returns. If this item does not have a boundingbox, this might well be empty.
*/
void SPItem::invoke_bbox_full( Geom::OptRect &bbox, Geom::Affine const &transform, unsigned const flags, unsigned const clear) const
{
if (clear) {
bbox = Geom::OptRect();
}
// TODO: replace NRRect by Geom::Rect, for all SPItemClasses, and for SP_CLIPPATH
NRRect temp_bbox;
temp_bbox.x0 = temp_bbox.y0 = Geom::infinity();
temp_bbox.x1 = temp_bbox.y1 = -Geom::infinity();
// call the subclass method
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->bbox) {
((SPItemClass *) G_OBJECT_GET_CLASS(this))->bbox(this, &temp_bbox, transform, flags);
}
// unless this is geometric bbox, extend by filter area and crop the bbox by clip path, if any
if ((SPItem::BBoxType) flags != SPItem::GEOMETRIC_BBOX) {
if ( style && style->filter.href) {
SPObject *filter = style->getFilter();
if (filter && SP_IS_FILTER(filter)) {
// default filer area per the SVG spec:
double x = -0.1;
double y = -0.1;
double w = 1.2;
double h = 1.2;
// if area is explicitly set, override:
if (SP_FILTER(filter)->x._set)
x = SP_FILTER(filter)->x.computed;
if (SP_FILTER(filter)->y._set)
y = SP_FILTER(filter)->y.computed;
if (SP_FILTER(filter)->width._set)
w = SP_FILTER(filter)->width.computed;
if (SP_FILTER(filter)->height._set)
h = SP_FILTER(filter)->height.computed;
double dx0 = 0;
double dx1 = 0;
double dy0 = 0;
double dy1 = 0;
if (filter_is_single_gaussian_blur(SP_FILTER(filter))) {
// if this is a single blur, use 2.4*radius
// which may be smaller than the default area;
// see set_filter_area for why it's 2.4
double r = get_single_gaussian_blur_radius (SP_FILTER(filter));
dx0 = -2.4 * r;
dx1 = 2.4 * r;
dy0 = -2.4 * r;
dy1 = 2.4 * r;
} else {
// otherwise, calculate expansion from relative to absolute units:
dx0 = x * (temp_bbox.x1 - temp_bbox.x0);
dx1 = (w + x - 1) * (temp_bbox.x1 - temp_bbox.x0);
dy0 = y * (temp_bbox.y1 - temp_bbox.y0);
dy1 = (h + y - 1) * (temp_bbox.y1 - temp_bbox.y0);
}
// transform the expansions by the item's transform:
Geom::Affine i2dt(i2dt_affine ());
dx0 *= i2dt.expansionX();
dx1 *= i2dt.expansionX();
dy0 *= i2dt.expansionY();
dy1 *= i2dt.expansionY();
// expand the bbox
temp_bbox.x0 += dx0;
temp_bbox.x1 += dx1;
temp_bbox.y0 += dy0;
temp_bbox.y1 += dy1;
}
}
if (clip_ref->getObject()) {
NRRect b;
SP_CLIPPATH(clip_ref->getObject())->getBBox(&b, transform, flags);
nr_rect_d_intersect (&temp_bbox, &temp_bbox, &b);
}
}
if (temp_bbox.x0 > temp_bbox.x1 || temp_bbox.y0 > temp_bbox.y1) {
// Either the bbox hasn't been touched by the SPItemClass' bbox method
// (it still has its initial values, see above: x0 = y0 = Geom::infinity() and x1 = y1 = -Geom::infinity())
// or it has explicitely been set to be like this (e.g. in sp_shape_bbox)
// When x0 > x1 or y0 > y1, the bbox is considered to be "nothing", although it has not been
// explicitely defined this way for NRRects (as opposed to Geom::OptRect)
// So union bbox with nothing = do nothing, just return
return;
}
// Do not use temp_bbox.upgrade() here, because it uses a test that returns an empty Geom::OptRect()
// for any rectangle with zero area. The geometrical bbox of for example a vertical line
// would therefore be translated into empty Geom::OptRect() (see bug https://bugs.launchpad.net/inkscape/+bug/168684)
Geom::OptRect temp_bbox_new = Geom::Rect(Geom::Point(temp_bbox.x0, temp_bbox.y0), Geom::Point(temp_bbox.x1, temp_bbox.y1));
bbox.unionWith(temp_bbox_new);
}
// DEPRECATED to phase out the use of NRRect in favor of Geom::OptRect
/** Calls \a item's subclass' bounding box method; clips it by the bbox of clippath, if any; and
* unions the resulting bbox with \a bbox. If \a clear is true, empties \a bbox first. Passes the
* transform and the flags to the actual bbox methods. Note that many of subclasses (e.g. groups,
* clones), in turn, call this function in their bbox methods. */
void SPItem::invoke_bbox_full( NRRect *bbox, Geom::Affine const &transform, unsigned const flags, unsigned const clear)
{
g_assert(bbox != NULL);
if (clear) {
bbox->x0 = bbox->y0 = 1e18;
bbox->x1 = bbox->y1 = -1e18;
}
NRRect this_bbox;
this_bbox.x0 = this_bbox.y0 = 1e18;
this_bbox.x1 = this_bbox.y1 = -1e18;
// call the subclass method
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->bbox) {
((SPItemClass *) G_OBJECT_GET_CLASS(this))->bbox(this, &this_bbox, transform, flags);
}
// unless this is geometric bbox, crop the bbox by clip path, if any
if ((SPItem::BBoxType) flags != SPItem::GEOMETRIC_BBOX && clip_ref->getObject()) {
NRRect b;
SP_CLIPPATH(clip_ref->getObject())->getBBox(&b, transform, flags);
nr_rect_d_intersect (&this_bbox, &this_bbox, &b);
}
// if non-empty (with some tolerance - ?) union this_bbox with the bbox we've got passed
if ( fabs(this_bbox.x1-this_bbox.x0) > -0.00001 && fabs(this_bbox.y1-this_bbox.y0) > -0.00001 ) {
nr_rect_d_union (bbox, bbox, &this_bbox);
}
}
unsigned SPItem::pos_in_parent()
{
g_assert(parent != NULL);
g_assert(SP_IS_OBJECT(parent));
SPObject *object = this;
unsigned pos=0;
for ( SPObject *iter = parent->firstChild() ; iter ; iter = iter->next) {
if ( iter == object ) {
return pos;
}
if (SP_IS_ITEM(iter)) {
pos++;
}
}
g_assert_not_reached();
return 0;
}
void SPItem::getBboxDesktop(NRRect *bbox, SPItem::BBoxType type)
{
g_assert(bbox != NULL);
invoke_bbox( bbox, i2dt_affine(), TRUE, type);
}
Geom::OptRect SPItem::getBboxDesktop(SPItem::BBoxType type)
{
Geom::OptRect rect = Geom::OptRect();
invoke_bbox( rect, i2dt_affine(), TRUE, type);
return rect;
}
void SPItem::sp_item_private_snappoints(SPItem const *item, std::vector<Inkscape::SnapCandidatePoint> &p, Inkscape::SnapPreferences const */*snapprefs*/)
{
/* This will only be called if the derived class doesn't override this.
* see for example sp_genericellipse_snappoints in sp-ellipse.cpp
* We don't know what shape we could be dealing with here, so we'll just
* return the corners of the bounding box */
Geom::OptRect bbox = item->getBounds(item->i2dt_affine());
if (bbox) {
Geom::Point p1, p2;
p1 = bbox->min();
p2 = bbox->max();
p.push_back(Inkscape::SnapCandidatePoint(p1, Inkscape::SNAPSOURCE_BBOX_CORNER, Inkscape::SNAPTARGET_BBOX_CORNER));
p.push_back(Inkscape::SnapCandidatePoint(Geom::Point(p1[Geom::X], p2[Geom::Y]), Inkscape::SNAPSOURCE_BBOX_CORNER, Inkscape::SNAPTARGET_BBOX_CORNER));
p.push_back(Inkscape::SnapCandidatePoint(p2, Inkscape::SNAPSOURCE_BBOX_CORNER, Inkscape::SNAPTARGET_BBOX_CORNER));
p.push_back(Inkscape::SnapCandidatePoint(Geom::Point(p2[Geom::X], p1[Geom::Y]), Inkscape::SNAPSOURCE_BBOX_CORNER, Inkscape::SNAPTARGET_BBOX_CORNER));
}
}
void SPItem::getSnappoints(std::vector<Inkscape::SnapCandidatePoint> &p, Inkscape::SnapPreferences const *snapprefs) const
{
// Get the snappoints of the item
SPItemClass const &item_class = *(SPItemClass const *) G_OBJECT_GET_CLASS(this);
if (item_class.snappoints) {
item_class.snappoints(this, p, snapprefs);
}
// Get the snappoints at the item's center
if (snapprefs != NULL && snapprefs->getIncludeItemCenter()) {
p.push_back(Inkscape::SnapCandidatePoint(getCenter(), Inkscape::SNAPSOURCE_ROTATION_CENTER, Inkscape::SNAPTARGET_ROTATION_CENTER));
}
// Get the snappoints of clipping paths and mask, if any
std::list<SPObject const *> clips_and_masks;
clips_and_masks.push_back(clip_ref->getObject());
clips_and_masks.push_back(mask_ref->getObject());
SPDesktop *desktop = inkscape_active_desktop();
for (std::list<SPObject const *>::const_iterator o = clips_and_masks.begin(); o != clips_and_masks.end(); o++) {
if (*o) {
// obj is a group object, the children are the actual clippers
for (SPObject *child = (*o)->children ; child ; child = child->next) {
if (SP_IS_ITEM(child)) {
std::vector<Inkscape::SnapCandidatePoint> p_clip_or_mask;
// Please note the recursive call here!
SP_ITEM(child)->getSnappoints(p_clip_or_mask, snapprefs);
// Take into account the transformation of the item being clipped or masked
for (std::vector<Inkscape::SnapCandidatePoint>::const_iterator p_orig = p_clip_or_mask.begin(); p_orig != p_clip_or_mask.end(); p_orig++) {
// All snappoints are in desktop coordinates, but the item's transformation is
// in document coordinates. Hence the awkward construction below
Geom::Point pt = desktop->dt2doc((*p_orig).getPoint()) * i2dt_affine();
p.push_back(Inkscape::SnapCandidatePoint(pt, (*p_orig).getSourceType(), (*p_orig).getTargetType()));
}
}
}
}
}
}
void SPItem::invoke_print(SPPrintContext *ctx)
{
if ( !isHidden() ) {
if ( reinterpret_cast<SPItemClass *>(G_OBJECT_GET_CLASS(this))->print ) {
if (!transform.isIdentity()
|| style->opacity.value != SP_SCALE24_MAX)
{
sp_print_bind(ctx, transform, SP_SCALE24_TO_FLOAT(style->opacity.value));
reinterpret_cast<SPItemClass *>(G_OBJECT_GET_CLASS(this))->print(this, ctx);
sp_print_release(ctx);
} else {
reinterpret_cast<SPItemClass *>(G_OBJECT_GET_CLASS(this))->print(this, ctx);
}
}
}
}
gchar *SPItem::sp_item_private_description(SPItem */*item*/)
{
return g_strdup(_("Object"));
}
/**
* Returns a string suitable for status bar, formatted in pango markup language.
*
* Must be freed by caller.
*/
gchar *SPItem::description()
{
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->description) {
gchar *s = ((SPItemClass *) G_OBJECT_GET_CLASS(this))->description(this);
if (s && clip_ref->getObject()) {
gchar *snew = g_strdup_printf (_("%s; <i>clipped</i>"), s);
g_free (s);
s = snew;
}
if (s && mask_ref->getObject()) {
gchar *snew = g_strdup_printf (_("%s; <i>masked</i>"), s);
g_free (s);
s = snew;
}
if ( style && style->filter.href && style->filter.href->getObject() ) {
const gchar *label = style->filter.href->getObject()->label();
gchar *snew = 0;
if (label) {
snew = g_strdup_printf (_("%s; <i>filtered (%s)</i>"), s, _(label));
} else {
snew = g_strdup_printf (_("%s; <i>filtered</i>"), s);
}
g_free (s);
s = snew;
}
return s;
}
g_assert_not_reached();
return NULL;
}
/**
* Allocates unique integer keys.
* \param numkeys Number of keys required.
* \return First allocated key; hence if the returned key is n
* you can use n, n + 1, ..., n + (numkeys - 1)
*/
unsigned SPItem::display_key_new(unsigned numkeys)
{
static unsigned dkey = 0;
dkey += numkeys;
return dkey - numkeys;
}
NRArenaItem *SPItem::invoke_show(NRArena *arena, unsigned key, unsigned flags)
{
g_assert(arena != NULL);
g_assert(NR_IS_ARENA(arena));
NRArenaItem *ai = NULL;
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->show) {
ai = ((SPItemClass *) G_OBJECT_GET_CLASS(this))->show(this, arena, key, flags);
}
if (ai != NULL) {
display = sp_item_view_new_prepend(display, this, flags, key, ai);
nr_arena_item_set_transform(ai, transform);
nr_arena_item_set_opacity(ai, SP_SCALE24_TO_FLOAT(style->opacity.value));
nr_arena_item_set_visible(ai, !isHidden());
nr_arena_item_set_sensitive(ai, sensitive);
if (clip_ref->getObject()) {
SPClipPath *cp = clip_ref->getObject();
if (!display->arenaitem->key) {
NR_ARENA_ITEM_SET_KEY(display->arenaitem, display_key_new(3));
}
int clip_key = NR_ARENA_ITEM_GET_KEY(display->arenaitem);
// Show and set clip
NRArenaItem *ac = cp->show(arena, clip_key);
nr_arena_item_set_clip(ai, ac);
nr_arena_item_unref(ac);
// Update bbox, in case the clip uses bbox units
NRRect bbox;
invoke_bbox( &bbox, Geom::identity(), TRUE);
SP_CLIPPATH(cp)->setBBox(clip_key, &bbox);
cp->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
}
if (mask_ref->getObject()) {
SPMask *mask = mask_ref->getObject();
if (!display->arenaitem->key) {
NR_ARENA_ITEM_SET_KEY(display->arenaitem, display_key_new(3));
}
int mask_key = NR_ARENA_ITEM_GET_KEY(display->arenaitem);
// Show and set mask
NRArenaItem *ac = sp_mask_show(mask, arena, mask_key);
nr_arena_item_set_mask(ai, ac);
nr_arena_item_unref(ac);
// Update bbox, in case the mask uses bbox units
NRRect bbox;
invoke_bbox( &bbox, Geom::identity(), TRUE);
sp_mask_set_bbox(SP_MASK(mask), mask_key, &bbox);
mask->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);
}
NR_ARENA_ITEM_SET_DATA(ai, this);
Geom::OptRect item_bbox;
invoke_bbox( item_bbox, Geom::identity(), TRUE, SPItem::GEOMETRIC_BBOX);
nr_arena_item_set_item_bbox(ai, item_bbox);
}
return ai;
}
void SPItem::invoke_hide(unsigned key)
{
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->hide) {
((SPItemClass *) G_OBJECT_GET_CLASS(this))->hide(this, key);
}
SPItemView *ref = NULL;
SPItemView *v = display;
while (v != NULL) {
SPItemView *next = v->next;
if (v->key == key) {
if (clip_ref->getObject()) {
(clip_ref->getObject())->hide(NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_clip(v->arenaitem, NULL);
}
if (mask_ref->getObject()) {
sp_mask_hide(mask_ref->getObject(), NR_ARENA_ITEM_GET_KEY(v->arenaitem));
nr_arena_item_set_mask(v->arenaitem, NULL);
}
if (!ref) {
display = v->next;
} else {
ref->next = v->next;
}
nr_arena_item_unparent(v->arenaitem);
nr_arena_item_unref(v->arenaitem);
g_free(v);
} else {
ref = v;
}
v = next;
}
}
// Adjusters
void SPItem::adjust_pattern (Geom::Affine const &postmul, bool set)
{
if (style && (style->fill.isPaintserver())) {
SPObject *server = style->getFillPaintServer();
if ( SP_IS_PATTERN(server) ) {
SPPattern *pattern = sp_pattern_clone_if_necessary(this, SP_PATTERN(server), "fill");
sp_pattern_transform_multiply(pattern, postmul, set);
}
}
if (style && (style->stroke.isPaintserver())) {
SPObject *server = style->getStrokePaintServer();
if ( SP_IS_PATTERN(server) ) {
SPPattern *pattern = sp_pattern_clone_if_necessary(this, SP_PATTERN(server), "stroke");
sp_pattern_transform_multiply(pattern, postmul, set);
}
}
}
void SPItem::adjust_gradient( Geom::Affine const &postmul, bool set )
{
if ( style && style->fill.isPaintserver() ) {
SPPaintServer *server = style->getFillPaintServer();
if ( SP_IS_GRADIENT(server) ) {
/**
* \note Bbox units for a gradient are generally a bad idea because
* with them, you cannot preserve the relative position of the
* object and its gradient after rotation or skew. So now we
* convert them to userspace units which are easy to keep in sync
* just by adding the object's transform to gradientTransform.
* \todo FIXME: convert back to bbox units after transforming with
* the item, so as to preserve the original units.
*/
SPGradient *gradient = sp_gradient_convert_to_userspace( SP_GRADIENT(server), this, "fill" );
sp_gradient_transform_multiply( gradient, postmul, set );
}
}
if ( style && style->stroke.isPaintserver() ) {
SPPaintServer *server = style->getStrokePaintServer();
if ( SP_IS_GRADIENT(server) ) {
SPGradient *gradient = sp_gradient_convert_to_userspace( SP_GRADIENT(server), this, "stroke");
sp_gradient_transform_multiply( gradient, postmul, set );
}
}
}
void SPItem::adjust_stroke( gdouble ex )
{
SPStyle *style = this->style;
if (style && !style->stroke.isNone() && !Geom::are_near(ex, 1.0, Geom::EPSILON)) {
style->stroke_width.computed *= ex;
style->stroke_width.set = TRUE;
if ( style->stroke_dash.n_dash != 0 ) {
for (int i = 0; i < style->stroke_dash.n_dash; i++) {
style->stroke_dash.dash[i] *= ex;
}
style->stroke_dash.offset *= ex;
}
updateRepr();
}
}
/**
* Find out the inverse of previous transform of an item (from its repr)
*/
Geom::Affine sp_item_transform_repr (SPItem *item)
{
Geom::Affine t_old(Geom::identity());
gchar const *t_attr = item->getRepr()->attribute("transform");
if (t_attr) {
Geom::Affine t;
if (sp_svg_transform_read(t_attr, &t)) {
t_old = t;
}
}
return t_old;
}
/**
* Recursively scale stroke width in \a item and its children by \a expansion.
*/
void SPItem::adjust_stroke_width_recursive(double expansion)
{
adjust_stroke (expansion);
// A clone's child is the ghost of its original - we must not touch it, skip recursion
if ( !SP_IS_USE(this) ) {
for ( SPObject *o = children; o; o = o->getNext() ) {
if (SP_IS_ITEM(o)) {
SP_ITEM(o)->adjust_stroke_width_recursive(expansion);
}
}
}
}
/**
* Recursively adjust rx and ry of rects.
*/
void
sp_item_adjust_rects_recursive(SPItem *item, Geom::Affine advertized_transform)
{
if (SP_IS_RECT (item)) {
sp_rect_compensate_rxry (SP_RECT(item), advertized_transform);
}
for (SPObject *o = item->children; o != NULL; o = o->next) {
if (SP_IS_ITEM(o))
sp_item_adjust_rects_recursive(SP_ITEM(o), advertized_transform);
}
}
/**
* Recursively compensate pattern or gradient transform.
*/
void SPItem::adjust_paint_recursive (Geom::Affine advertized_transform, Geom::Affine t_ancestors, bool is_pattern)
{
// _Before_ full pattern/gradient transform: t_paint * t_item * t_ancestors
// _After_ full pattern/gradient transform: t_paint_new * t_item * t_ancestors * advertised_transform
// By equating these two expressions we get t_paint_new = t_paint * paint_delta, where:
Geom::Affine t_item = sp_item_transform_repr (this);
Geom::Affine paint_delta = t_item * t_ancestors * advertized_transform * t_ancestors.inverse() * t_item.inverse();
// Within text, we do not fork gradients, and so must not recurse to avoid double compensation;
// also we do not recurse into clones, because a clone's child is the ghost of its original -
// we must not touch it
if (!(this && (SP_IS_TEXT(this) || SP_IS_USE(this)))) {
for (SPObject *o = children; o != NULL; o = o->next) {
if (SP_IS_ITEM(o)) {
// At the level of the transformed item, t_ancestors is identity;
// below it, it is the accmmulated chain of transforms from this level to the top level
SP_ITEM(o)->adjust_paint_recursive (advertized_transform, t_item * t_ancestors, is_pattern);
}
}
}
// We recursed into children first, and are now adjusting this object second;
// this is so that adjustments in a tree are done from leaves up to the root,
// and paintservers on leaves inheriting their values from ancestors could adjust themselves properly
// before ancestors themselves are adjusted, probably differently (bug 1286535)
if (is_pattern) {
adjust_pattern(paint_delta);
} else {
adjust_gradient(paint_delta);
}
}
void SPItem::adjust_livepatheffect (Geom::Affine const &postmul, bool set)
{
if ( SP_IS_LPE_ITEM(this) ) {
SPLPEItem *lpeitem = SP_LPE_ITEM (this);
if ( sp_lpe_item_has_path_effect(lpeitem) ) {
sp_lpe_item_fork_path_effects_if_necessary(lpeitem);
// now that all LPEs are forked_if_necessary, we can apply the transform
PathEffectList effect_list = sp_lpe_item_get_effect_list(lpeitem);
for (PathEffectList::iterator it = effect_list.begin(); it != effect_list.end(); it++)
{
LivePathEffectObject *lpeobj = (*it)->lpeobject;
if (lpeobj && lpeobj->get_lpe()) {
Inkscape::LivePathEffect::Effect * effect = lpeobj->get_lpe();
effect->transform_multiply(postmul, set);
}
}
}
}
}
/**
* Set a new transform on an object.
*
* Compensate for stroke scaling and gradient/pattern fill transform, if
* necessary. Call the object's set_transform method if transforms are
* stored optimized. Send _transformed_signal. Invoke _write method so that
* the repr is updated with the new transform.
*/
void SPItem::doWriteTransform(Inkscape::XML::Node *repr, Geom::Affine const &transform, Geom::Affine const *adv, bool compensate)
{
g_return_if_fail(repr != NULL);
// calculate the relative transform, if not given by the adv attribute
Geom::Affine advertized_transform;
if (adv != NULL) {
advertized_transform = *adv;
} else {
advertized_transform = sp_item_transform_repr (this).inverse() * transform;
}
Inkscape::Preferences *prefs = Inkscape::Preferences::get();
if (compensate) {
// recursively compensate for stroke scaling, depending on user preference
if (!prefs->getBool("/options/transform/stroke", true)) {
double const expansion = 1. / advertized_transform.descrim();
adjust_stroke_width_recursive(expansion);
}
// recursively compensate rx/ry of a rect if requested
if (!prefs->getBool("/options/transform/rectcorners", true)) {
sp_item_adjust_rects_recursive(this, advertized_transform);
}
// recursively compensate pattern fill if it's not to be transformed
if (!prefs->getBool("/options/transform/pattern", true)) {
adjust_paint_recursive (advertized_transform.inverse(), Geom::identity(), true);
}
/// \todo FIXME: add the same else branch as for gradients below, to convert patterns to userSpaceOnUse as well
/// recursively compensate gradient fill if it's not to be transformed
if (!prefs->getBool("/options/transform/gradient", true)) {
adjust_paint_recursive (advertized_transform.inverse(), Geom::identity(), false);
} else {
// this converts the gradient/pattern fill/stroke, if any, to userSpaceOnUse; we need to do
// it here _before_ the new transform is set, so as to use the pre-transform bbox
adjust_paint_recursive (Geom::identity(), Geom::identity(), false);
}
} // endif(compensate)
gint preserve = prefs->getBool("/options/preservetransform/value", 0);
Geom::Affine transform_attr (transform);
if ( // run the object's set_transform (i.e. embed transform) only if:
((SPItemClass *) G_OBJECT_GET_CLASS(this))->set_transform && // it does have a set_transform method
!preserve && // user did not chose to preserve all transforms
!clip_ref->getObject() && // the object does not have a clippath
!mask_ref->getObject() && // the object does not have a mask
!(!transform.isTranslation() && style && style->getFilter())
// the object does not have a filter, or the transform is translation (which is supposed to not affect filters)
) {
transform_attr = ((SPItemClass *) G_OBJECT_GET_CLASS(this))->set_transform(this, transform);
}
set_item_transform(transform_attr);
// Note: updateRepr comes before emitting the transformed signal since
// it causes clone SPUse's copy of the original object to brought up to
// date with the original. Otherwise, sp_use_bbox returns incorrect
// values if called in code handling the transformed signal.
updateRepr();
// send the relative transform with a _transformed_signal
_transformed_signal.emit(&advertized_transform, this);
}
gint SPItem::emitEvent(SPEvent &event)
{
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->event) {
return ((SPItemClass *) G_OBJECT_GET_CLASS(this))->event(this, &event);
}
return FALSE;
}
/**
* Sets item private transform (not propagated to repr), without compensating stroke widths,
* gradients, patterns as sp_item_write_transform does.
*/
void SPItem::set_item_transform(Geom::Affine const &transform_matrix)
{
if (!matrix_equalp(transform_matrix, transform, NR_EPSILON)) {
transform = transform_matrix;
/* The SP_OBJECT_USER_MODIFIED_FLAG_B is used to mark the fact that it's only a
transformation. It's apparently not used anywhere else. */
requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG | SP_OBJECT_USER_MODIFIED_FLAG_B);
sp_item_rm_unsatisfied_cns(*this);
}
}
void SPItem::convert_item_to_guides() {
// Use derived method if present ...
if (((SPItemClass *) G_OBJECT_GET_CLASS(this))->convert_to_guides) {
(*((SPItemClass *) G_OBJECT_GET_CLASS(this))->convert_to_guides)(this);
} else {
// .. otherwise simply place the guides around the item's bounding box
convert_to_guides();
}
}
/**
* \pre \a ancestor really is an ancestor (\>=) of \a object, or NULL.
* ("Ancestor (\>=)" here includes as far as \a object itself.)
*/
Geom::Affine
i2anc_affine(SPObject const *object, SPObject const *const ancestor) {
Geom::Affine ret(Geom::identity());
g_return_val_if_fail(object != NULL, ret);
/* stop at first non-renderable ancestor */
while ( object != ancestor && SP_IS_ITEM(object) ) {
if (SP_IS_ROOT(object)) {
ret *= SP_ROOT(object)->c2p;
} else {
ret *= SP_ITEM(object)->transform;
}
object = object->parent;
}
return ret;
}
Geom::Affine
i2i_affine(SPObject const *src, SPObject const *dest) {
g_return_val_if_fail(src != NULL && dest != NULL, Geom::identity());
SPObject const *ancestor = src->nearestCommonAncestor(dest);
return i2anc_affine(src, ancestor) * i2anc_affine(dest, ancestor).inverse();
}
Geom::Affine SPItem::getRelativeTransform(SPObject const *dest) const {
return i2i_affine(this, dest);
}
/**
* Returns the accumulated transformation of the item and all its ancestors, including root's viewport.
* \pre (item != NULL) and SP_IS_ITEM(item).
*/
Geom::Affine SPItem::i2doc_affine() const
{
return i2anc_affine(this, NULL);
}
/**
* Returns the transformation from item to desktop coords
*/
Geom::Affine SPItem::i2dt_affine() const
{
// Geom::Affine const ret( i2doc_affine()
// * Geom::Scale(1, -1)
// * Geom::Translate(0, document->getHeight()) );
SPDesktop const *desktop = inkscape_active_desktop();
Geom::Affine const ret( i2doc_affine() * desktop->doc2dt() );
return ret;
}
void SPItem::set_i2d_affine(Geom::Affine const &i2dt)
{
Geom::Affine dt2p; /* desktop to item parent transform */
if (parent) {
dt2p = static_cast<SPItem *>(parent)->i2dt_affine().inverse();
} else {
dt2p = ( Geom::Translate(0, -document->getHeight())
* Geom::Scale(1, -1) ); /// @fixme hardcoded doc2dt transform?
}
Geom::Affine const i2p( i2dt * dt2p );
set_item_transform(i2p);
}
/**
* should rather be named "sp_item_d2i_affine" to match "sp_item_i2d_affine" (or vice versa)
*/
Geom::Affine SPItem::dt2i_affine() const
{
/* fixme: Implement the right way (Lauris) */
return i2dt_affine().inverse();
}
/* Item views */
SPItemView *SPItem::sp_item_view_new_prepend(SPItemView *list, SPItem *item, unsigned flags, unsigned key, NRArenaItem *arenaitem)
{
g_assert(item != NULL);
g_assert(SP_IS_ITEM(item));
g_assert(arenaitem != NULL);
g_assert(NR_IS_ARENA_ITEM(arenaitem));
SPItemView *new_view = g_new(SPItemView, 1);
new_view->next = list;
new_view->flags = flags;
new_view->key = key;
new_view->arenaitem = arenaitem;
return new_view;
}
SPItemView *SPItem::sp_item_view_list_remove(SPItemView *list, SPItemView *view)
{
if (view == list) {
list = list->next;
} else {
SPItemView *prev;
prev = list;
while (prev->next != view) prev = prev->next;
prev->next = view->next;
}
nr_arena_item_unref(view->arenaitem);
g_free(view);
return list;
}
/**
* Return the arenaitem corresponding to the given item in the display
* with the given key
*/
NRArenaItem *SPItem::get_arenaitem(unsigned key)
{
for ( SPItemView *iv = display ; iv ; iv = iv->next ) {
if ( iv->key == key ) {
return iv->arenaitem;
}
}
return NULL;
}
int sp_item_repr_compare_position(SPItem const *first, SPItem const *second)
{
return sp_repr_compare_position(first->getRepr(),
second->getRepr());
}
SPItem const *sp_item_first_item_child(SPObject const *obj)
{
return sp_item_first_item_child( const_cast<SPObject *>(obj) );
}
SPItem *sp_item_first_item_child(SPObject *obj)
{
SPItem *child = 0;
for ( SPObject *iter = obj->firstChild() ; iter ; iter = iter->next ) {
if ( SP_IS_ITEM(iter) ) {
child = SP_ITEM(iter);
break;
}
}
return child;
}
void SPItem::convert_to_guides() {
SPDesktop *dt = inkscape_active_desktop();
sp_desktop_namedview(dt);
Inkscape::Preferences *prefs = Inkscape::Preferences::get();
int prefs_bbox = prefs->getInt("/tools/bounding_box", 0);
SPItem::BBoxType bbox_type = (prefs_bbox ==0)?
SPItem::APPROXIMATE_BBOX : SPItem::GEOMETRIC_BBOX;
Geom::OptRect bbox = getBboxDesktop(bbox_type);
if (!bbox) {
g_warning ("Cannot determine item's bounding box during conversion to guides.\n");
return;
}
std::list<std::pair<Geom::Point, Geom::Point> > pts;
Geom::Point A((*bbox).min());
Geom::Point C((*bbox).max());
Geom::Point B(A[Geom::X], C[Geom::Y]);
Geom::Point D(C[Geom::X], A[Geom::Y]);
pts.push_back(std::make_pair(A, B));
pts.push_back(std::make_pair(B, C));
pts.push_back(std::make_pair(C, D));
pts.push_back(std::make_pair(D, A));
sp_guide_pt_pairs_to_guides(dt, pts);
}
/*
Local Variables:
mode:c++
c-file-style:"stroustrup"
c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +))
indent-tabs-mode:nil
fill-column:99
End:
*/
// vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4 :