#define __SP_OBJECT_EDIT_C__

#ifdef HAVE_CONFIG_H

# include "config.h"

#endif

#include "sp-item.h"

#include "sp-rect.h"

#include "box3d.h"

#include "sp-ellipse.h"

#include "sp-star.h"

#include "sp-spiral.h"

#include "sp-offset.h"

#include "sp-flowtext.h"

#include "prefs-utils.h"

#include "inkscape.h"

#include "snap.h"

#include "desktop-affine.h"

#include "style.h"

#include "desktop.h"

#include "desktop-handles.h"

#include "sp-namedview.h"

#include "live_effects/effect.h"

#include "sp-pattern.h"

#include "sp-path.h"

#include <glibmm/i18n.h>

#include "object-edit.h"

#include <libnr/nr-scale-ops.h>

#include <libnr/nr-matrix-div.h>

#include "xml/repr.h"

#include "2geom/isnan.h"

#define sp_round(v,m) (((v) < 0.0) ? ((ceil((v) / (m) - 0.5)) * (m)) : ((floor((v) / (m) + 0.5)) * (m)))

static KnotHolder *sp_lpe_knot_holder(SPItem *item, SPDesktop *desktop)

{

KnotHolder *knot_holder = new KnotHolder(desktop, item, NULL);

Inkscape::LivePathEffect::Effect *effect = sp_lpe_item_get_current_lpe(SP_LPE_ITEM(item));

if (!effect) {

g_error("sp_lpe_knot_holder: logical error, this method cannot be called with item having an LPE");

} else {

effect->addHandles(knot_holder);

}

return knot_holder;

}

KnotHolder *

sp_item_knot_holder(SPItem *item, SPDesktop *desktop)

{

KnotHolder *knotholder = NULL;

if (SP_IS_LPE_ITEM(item) &&

sp_lpe_item_get_current_lpe(SP_LPE_ITEM(item)) &&

sp_lpe_item_get_current_lpe(SP_LPE_ITEM(item))->isVisible() &&

sp_lpe_item_get_current_lpe(SP_LPE_ITEM(item))->providesKnotholder()) {

knotholder = sp_lpe_knot_holder(item, desktop);

} else if (SP_IS_RECT(item)) {

knotholder = new RectKnotHolder(desktop, item, NULL);

} else if (SP_IS_BOX3D(item)) {

knotholder = new Box3DKnotHolder(desktop, item, NULL);

} else if (SP_IS_ARC(item)) {

knotholder = new ArcKnotHolder(desktop, item, NULL);

} else if (SP_IS_STAR(item)) {

knotholder = new StarKnotHolder(desktop, item, NULL);

} else if (SP_IS_SPIRAL(item)) {

knotholder = new SpiralKnotHolder(desktop, item, NULL);

} else if (SP_IS_OFFSET(item)) {

knotholder = new OffsetKnotHolder(desktop, item, NULL);

} else if (SP_IS_FLOWTEXT(item) && SP_FLOWTEXT(item)->has_internal_frame()) {

knotholder = new FlowtextKnotHolder(desktop, SP_FLOWTEXT(item)->get_frame(NULL), NULL);

} else if ((SP_OBJECT(item)->style->fill.isPaintserver())

&& SP_IS_PATTERN(SP_STYLE_FILL_SERVER(SP_OBJECT(item)->style))) {

knotholder->add_pattern_knotholder();

}

return knotholder;

}

class RectKnotHolderEntityRX : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class RectKnotHolderEntityRY : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class RectKnotHolderEntityWH : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class RectKnotHolderEntityXY : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

static NR::Point snap_knot_position(SPItem *item, NR::Point const &p)

{

SPDesktop const *desktop = inkscape_active_desktop();

NR::Matrix const i2d (sp_item_i2d_affine (item));

NR::Point s = p * i2d;

SnapManager &m = desktop->namedview->snap_manager;

m.setup(desktop, item);

m.freeSnapReturnByRef(Inkscape::Snapper::SNAPPOINT_NODE, s);

return s * i2d.inverse();

}

NR::Point

RectKnotHolderEntityRX::knot_get()

{

SPRect *rect = SP_RECT(item);

return NR::Point(rect->x.computed + rect->width.computed - rect->rx.computed, rect->y.computed);

}

RectKnotHolderEntityRX::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPRect *rect = SP_RECT(item);

//In general we cannot just snap this radius to an arbitrary point, as we have only a single

//degree of freedom. For snapping to an arbitrary point we need two DOF. If we're going to snap

//the radius then we should have a constrained snap. snap_knot_position() is unconstrained

if (state & GDK_CONTROL_MASK) {

gdouble temp = MIN(rect->height.computed, rect->width.computed) / 2.0;

rect->rx.computed = rect->ry.computed = CLAMP(rect->x.computed + rect->width.computed - p[NR::X], 0.0, temp);

rect->rx._set = rect->ry._set = true;

} else {

rect->rx.computed = CLAMP(rect->x.computed + rect->width.computed - p[NR::X], 0.0, rect->width.computed / 2.0);

rect->rx._set = true;

}

update_knot();

((SPObject*)rect)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

RectKnotHolderEntityRX::knot_click(guint state)

{

SPRect *rect = SP_RECT(item);

if (state & GDK_SHIFT_MASK) {

/* remove rounding from rectangle */

SP_OBJECT_REPR(rect)->setAttribute("rx", NULL);

SP_OBJECT_REPR(rect)->setAttribute("ry", NULL);

} else if (state & GDK_CONTROL_MASK) {

/* Ctrl-click sets the vertical rounding to be the same as the horizontal */

SP_OBJECT_REPR(rect)->setAttribute("ry", SP_OBJECT_REPR(rect)->attribute("rx"));

}

update_knot();

}

NR::Point

RectKnotHolderEntityRY::knot_get()

{

SPRect *rect = SP_RECT(item);

return NR::Point(rect->x.computed + rect->width.computed, rect->y.computed + rect->ry.computed);

}

RectKnotHolderEntityRY::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPRect *rect = SP_RECT(item);

//In general we cannot just snap this radius to an arbitrary point, as we have only a single

//degree of freedom. For snapping to an arbitrary point we need two DOF. If we're going to snap

//the radius then we should have a constrained snap. snap_knot_position() is unconstrained

if (state & GDK_CONTROL_MASK) {

gdouble temp = MIN(rect->height.computed, rect->width.computed) / 2.0;

rect->rx.computed = rect->ry.computed = CLAMP(p[NR::Y] - rect->y.computed, 0.0, temp);

rect->ry._set = rect->rx._set = true;

} else {

if (!rect->rx._set || rect->rx.computed == 0) {

rect->ry.computed = CLAMP(p[NR::Y] - rect->y.computed,

0.0,

MIN(rect->height.computed / 2.0, rect->width.computed / 2.0));

} else {

rect->ry.computed = CLAMP(p[NR::Y] - rect->y.computed,

0.0,

rect->height.computed / 2.0);

}

rect->ry._set = true;

}

update_knot();

((SPObject *)rect)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

RectKnotHolderEntityRY::knot_click(guint state)

{

SPRect *rect = SP_RECT(item);

if (state & GDK_SHIFT_MASK) {

/* remove rounding */

SP_OBJECT_REPR(rect)->setAttribute("rx", NULL);

SP_OBJECT_REPR(rect)->setAttribute("ry", NULL);

} else if (state & GDK_CONTROL_MASK) {

/* Ctrl-click sets the vertical rounding to be the same as the horizontal */

SP_OBJECT_REPR(rect)->setAttribute("rx", SP_OBJECT_REPR(rect)->attribute("ry"));

}

}

#define SGN(x) ((x)>0?1:((x)<0?-1:0))

static void sp_rect_clamp_radii(SPRect *rect)

{

// clamp rounding radii so that they do not exceed width/height

if (2 * rect->rx.computed > rect->width.computed) {

rect->rx.computed = 0.5 * rect->width.computed;

rect->rx._set = true;

}

if (2 * rect->ry.computed > rect->height.computed) {

rect->ry.computed = 0.5 * rect->height.computed;

rect->ry._set = true;

}

}

NR::Point

RectKnotHolderEntityWH::knot_get()

{

SPRect *rect = SP_RECT(item);

return NR::Point(rect->x.computed + rect->width.computed, rect->y.computed + rect->height.computed);

}

static void sp_rect_wh_set_internal(SPRect *rect, NR::Point const &p, NR::Point const &origin, guint state)

{

NR::Point const s = snap_knot_position(rect, p);

if (state & GDK_CONTROL_MASK) {

// original width/height when drag started

gdouble const w_orig = (origin[NR::X] - rect->x.computed);

gdouble const h_orig = (origin[NR::Y] - rect->y.computed);

//original ratio

gdouble const ratio = (w_orig / h_orig);

// mouse displacement since drag started

gdouble const minx = s[NR::X] - origin[NR::X];

gdouble const miny = s[NR::Y] - origin[NR::Y];

if (fabs(minx) > fabs(miny)) {

// snap to horizontal or diagonal

rect->width.computed = MAX(w_orig + minx, 0);

if (minx != 0 && fabs(miny/minx) > 0.5 * 1/ratio && (SGN(minx) == SGN(miny))) {

// closer to the diagonal and in same-sign quarters, change both using ratio

rect->height.computed = MAX(h_orig + minx / ratio, 0);

} else {

// closer to the horizontal, change only width, height is h_orig

rect->height.computed = MAX(h_orig, 0);

}

} else {

// snap to vertical or diagonal

rect->height.computed = MAX(h_orig + miny, 0);

if (miny != 0 && fabs(minx/miny) > 0.5 * ratio && (SGN(minx) == SGN(miny))) {

// closer to the diagonal and in same-sign quarters, change both using ratio

rect->width.computed = MAX(w_orig + miny * ratio, 0);

} else {

// closer to the vertical, change only height, width is w_orig

rect->width.computed = MAX(w_orig, 0);

}

}

rect->width._set = rect->height._set = true;

} else {

// move freely

rect->width.computed = MAX(s[NR::X] - rect->x.computed, 0);

rect->height.computed = MAX(s[NR::Y] - rect->y.computed, 0);

rect->width._set = rect->height._set = true;

}

sp_rect_clamp_radii(rect);

((SPObject *)rect)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

RectKnotHolderEntityWH::knot_set(NR::Point const &p, NR::Point const &origin, guint state)

{

SPRect *rect = SP_RECT(item);

sp_rect_wh_set_internal(rect, p, origin, state);

update_knot();

}

NR::Point

RectKnotHolderEntityXY::knot_get()

{

SPRect *rect = SP_RECT(item);

return NR::Point(rect->x.computed, rect->y.computed);

}

RectKnotHolderEntityXY::knot_set(NR::Point const &p, NR::Point const &origin, guint state)

{

SPRect *rect = SP_RECT(item);

// opposite corner (unmoved)

gdouble opposite_x = (rect->x.computed + rect->width.computed);

gdouble opposite_y = (rect->y.computed + rect->height.computed);

// original width/height when drag started

gdouble w_orig = opposite_x - origin[NR::X];

gdouble h_orig = opposite_y - origin[NR::Y];

NR::Point const s = snap_knot_position(rect, p);

// mouse displacement since drag started

gdouble minx = s[NR::X] - origin[NR::X];

gdouble miny = s[NR::Y] - origin[NR::Y];

if (state & GDK_CONTROL_MASK) {

//original ratio

gdouble ratio = (w_orig / h_orig);

if (fabs(minx) > fabs(miny)) {

// snap to horizontal or diagonal

rect->x.computed = MIN(s[NR::X], opposite_x);

rect->width.computed = MAX(w_orig - minx, 0);

if (minx != 0 && fabs(miny/minx) > 0.5 * 1/ratio && (SGN(minx) == SGN(miny))) {

// closer to the diagonal and in same-sign quarters, change both using ratio

rect->y.computed = MIN(origin[NR::Y] + minx / ratio, opposite_y);

rect->height.computed = MAX(h_orig - minx / ratio, 0);

} else {

// closer to the horizontal, change only width, height is h_orig

rect->y.computed = MIN(origin[NR::Y], opposite_y);

rect->height.computed = MAX(h_orig, 0);

}

} else {

// snap to vertical or diagonal

rect->y.computed = MIN(s[NR::Y], opposite_y);

rect->height.computed = MAX(h_orig - miny, 0);

if (miny != 0 && fabs(minx/miny) > 0.5 *ratio && (SGN(minx) == SGN(miny))) {

// closer to the diagonal and in same-sign quarters, change both using ratio

rect->x.computed = MIN(origin[NR::X] + miny * ratio, opposite_x);

rect->width.computed = MAX(w_orig - miny * ratio, 0);

} else {

// closer to the vertical, change only height, width is w_orig

rect->x.computed = MIN(origin[NR::X], opposite_x);

rect->width.computed = MAX(w_orig, 0);

}

}

rect->width._set = rect->height._set = rect->x._set = rect->y._set = true;

} else {

// move freely

rect->x.computed = MIN(s[NR::X], opposite_x);

rect->width.computed = MAX(w_orig - minx, 0);

rect->y.computed = MIN(s[NR::Y], opposite_y);

rect->height.computed = MAX(h_orig - miny, 0);

rect->width._set = rect->height._set = rect->x._set = rect->y._set = true;

}

sp_rect_clamp_radii(rect);

update_knot();

((SPObject *)rect)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

RectKnotHolder::RectKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

RectKnotHolderEntityRX *entity_rx = new RectKnotHolderEntityRX();

RectKnotHolderEntityRY *entity_ry = new RectKnotHolderEntityRY();

RectKnotHolderEntityWH *entity_wh = new RectKnotHolderEntityWH();

RectKnotHolderEntityXY *entity_xy = new RectKnotHolderEntityXY();

entity_rx->create(desktop, item, this,

_("Adjust the <b>horizontal rounding</b> radius; with <b>Ctrl</b> "

"to make the vertical radius the same"),

SP_KNOT_SHAPE_CIRCLE, SP_KNOT_MODE_XOR);

entity_ry->create(desktop, item, this,

_("Adjust the <b>vertical rounding</b> radius; with <b>Ctrl</b> "

"to make the horizontal radius the same"),

SP_KNOT_SHAPE_CIRCLE, SP_KNOT_MODE_XOR);

entity_wh->create(desktop, item, this,

_("Adjust the <b>width and height</b> of the rectangle; with <b>Ctrl</b>"

"to lock ratio or stretch in one dimension only"),

SP_KNOT_SHAPE_SQUARE, SP_KNOT_MODE_XOR);

entity_xy->create(desktop, item, this,

_("Adjust the <b>width and height</b> of the rectangle; with <b>Ctrl</b>"

"to lock ratio or stretch in one dimension only"),

SP_KNOT_SHAPE_SQUARE, SP_KNOT_MODE_XOR);

entity.push_back(entity_rx);

entity.push_back(entity_ry);

entity.push_back(entity_wh);

entity.push_back(entity_xy);

add_pattern_knotholder();

}

class Box3DKnotHolderEntity : public KnotHolderEntity {

public:

virtual NR::Point knot_get() = 0;

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state) = 0;

static NR::Point knot_get_generic(SPItem *item, unsigned int knot_id);

static void knot_set_generic(SPItem *item, unsigned int knot_id, NR::Point const &p, guint state);

};

NR::Point

Box3DKnotHolderEntity::knot_get_generic(SPItem *item, unsigned int knot_id)

{

return box3d_get_corner_screen(SP_BOX3D(item), knot_id);

}

Box3DKnotHolderEntity::knot_set_generic(SPItem *item, unsigned int knot_id, NR::Point const &new_pos, guint state)

{

NR::Point const s = snap_knot_position(item, new_pos);

g_assert(item != NULL);

SPBox3D *box = SP_BOX3D(item);

NR::Matrix const i2d (sp_item_i2d_affine (item));

Box3D::Axis movement;

if ((knot_id < 4) != (state & GDK_SHIFT_MASK)) {

movement = Box3D::XY;

} else {

movement = Box3D::Z;

}

box3d_set_corner (box, knot_id, s * i2d, movement, (state & GDK_CONTROL_MASK));

box3d_set_z_orders(box);

box3d_position_set(box);

}

class Box3DKnotHolderEntity0 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity1 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity2 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity3 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity4 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity5 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity6 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntity7 : public Box3DKnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class Box3DKnotHolderEntityCenter : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

NR::Point

Box3DKnotHolderEntity0::knot_get()

{

return knot_get_generic(item, 0);

}

NR::Point

Box3DKnotHolderEntity1::knot_get()

{

return knot_get_generic(item, 1);

}

NR::Point

Box3DKnotHolderEntity2::knot_get()

{

return knot_get_generic(item, 2);

}

NR::Point

Box3DKnotHolderEntity3::knot_get()

{

return knot_get_generic(item, 3);

}

NR::Point

Box3DKnotHolderEntity4::knot_get()

{

return knot_get_generic(item, 4);

}

NR::Point

Box3DKnotHolderEntity5::knot_get()

{

return knot_get_generic(item, 5);

}

NR::Point

Box3DKnotHolderEntity6::knot_get()

{

return knot_get_generic(item, 6);

}

NR::Point

Box3DKnotHolderEntity7::knot_get()

{

return knot_get_generic(item, 7);

}

NR::Point

Box3DKnotHolderEntityCenter::knot_get()

{

return box3d_get_center_screen(SP_BOX3D(item));

}

Box3DKnotHolderEntity0::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 0, new_pos, state);

}

Box3DKnotHolderEntity1::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 1, new_pos, state);

}

Box3DKnotHolderEntity2::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 2, new_pos, state);

}

Box3DKnotHolderEntity3::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 3, new_pos, state);

}

Box3DKnotHolderEntity4::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 4, new_pos, state);

}

Box3DKnotHolderEntity5::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 5, new_pos, state);

}

Box3DKnotHolderEntity6::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 6, new_pos, state);

}

Box3DKnotHolderEntity7::knot_set(NR::Point const &new_pos, NR::Point const &/*origin*/, guint state)

{

knot_set_generic(item, 7, new_pos, state);

}

Box3DKnotHolderEntityCenter::knot_set(NR::Point const &new_pos, NR::Point const &origin, guint state)

{

NR::Point const s = snap_knot_position(item, new_pos);

SPBox3D *box = SP_BOX3D(item);

NR::Matrix const i2d (sp_item_i2d_affine (item));

box3d_set_center (SP_BOX3D(item), s * i2d, origin * i2d, !(state & GDK_SHIFT_MASK) ? Box3D::XY : Box3D::Z,

state & GDK_CONTROL_MASK);

box3d_set_z_orders(box);

box3d_position_set(box);

}

Box3DKnotHolder::Box3DKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

Box3DKnotHolderEntity0 *entity_corner0 = new Box3DKnotHolderEntity0();

Box3DKnotHolderEntity1 *entity_corner1 = new Box3DKnotHolderEntity1();

Box3DKnotHolderEntity2 *entity_corner2 = new Box3DKnotHolderEntity2();

Box3DKnotHolderEntity3 *entity_corner3 = new Box3DKnotHolderEntity3();

Box3DKnotHolderEntity4 *entity_corner4 = new Box3DKnotHolderEntity4();

Box3DKnotHolderEntity5 *entity_corner5 = new Box3DKnotHolderEntity5();

Box3DKnotHolderEntity6 *entity_corner6 = new Box3DKnotHolderEntity6();

Box3DKnotHolderEntity7 *entity_corner7 = new Box3DKnotHolderEntity7();

Box3DKnotHolderEntityCenter *entity_center = new Box3DKnotHolderEntityCenter();

entity_corner0->create(desktop, item, this,

_("Resize box in X/Y direction; with <b>Shift</b> along the Z axis; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner1->create(desktop, item, this,

_("Resize box in X/Y direction; with <b>Shift</b> along the Z axis; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner2->create(desktop, item, this,

_("Resize box in X/Y direction; with <b>Shift</b> along the Z axis; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner3->create(desktop, item, this,

_("Resize box in X/Y direction; with <b>Shift</b> along the Z axis; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner4->create(desktop, item, this,

_("Resize box along the Z axis; with <b>Shift</b> in X/Y direction; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner5->create(desktop, item, this,

_("Resize box along the Z axis; with <b>Shift</b> in X/Y direction; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner6->create(desktop, item, this,

_("Resize box along the Z axis; with <b>Shift</b> in X/Y direction; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_corner7->create(desktop, item, this,

_("Resize box along the Z axis; with <b>Shift</b> in X/Y direction; "

"with <b>Ctrl</b> to constrain to the directions of edges or diagonals"));

entity_center->create(desktop, item, this,

_("Move the box in perspective"),

SP_KNOT_SHAPE_CROSS);

entity.push_back(entity_corner0);

entity.push_back(entity_corner1);

entity.push_back(entity_corner2);

entity.push_back(entity_corner3);

entity.push_back(entity_corner4);

entity.push_back(entity_corner5);

entity.push_back(entity_corner6);

entity.push_back(entity_corner7);

entity.push_back(entity_center);

add_pattern_knotholder();

}

class ArcKnotHolderEntityStart : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

class ArcKnotHolderEntityEnd : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class ArcKnotHolderEntityRX : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class ArcKnotHolderEntityRY : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

static gint

sp_genericellipse_side(SPGenericEllipse *ellipse, NR::Point const &p)

{

gdouble dx = (p[NR::X] - ellipse->cx.computed) / ellipse->rx.computed;

gdouble dy = (p[NR::Y] - ellipse->cy.computed) / ellipse->ry.computed;

gdouble s = dx * dx + dy * dy;

if (s < 1.0) return 1;

if (s > 1.0) return -1;

return 0;

}

ArcKnotHolderEntityStart::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

int snaps = prefs_get_int_attribute("options.rotationsnapsperpi", "value", 12);

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

ge->closed = (sp_genericellipse_side(ge, p) == -1) ? TRUE : FALSE;

NR::Point delta = p - NR::Point(ge->cx.computed, ge->cy.computed);

NR::scale sc(ge->rx.computed, ge->ry.computed);

ge->start = atan2(delta * sc.inverse());

if ( ( state & GDK_CONTROL_MASK )

&& snaps )

{

ge->start = sp_round(ge->start, M_PI/snaps);

}

sp_genericellipse_normalize(ge);

((SPObject *)arc)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

ArcKnotHolderEntityStart::knot_get()

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

return sp_arc_get_xy(arc, ge->start);

}

ArcKnotHolderEntityEnd::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

int snaps = prefs_get_int_attribute("options.rotationsnapsperpi", "value", 12);

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

ge->closed = (sp_genericellipse_side(ge, p) == -1) ? TRUE : FALSE;

NR::Point delta = p - NR::Point(ge->cx.computed, ge->cy.computed);

NR::scale sc(ge->rx.computed, ge->ry.computed);

ge->end = atan2(delta * sc.inverse());

if ( ( state & GDK_CONTROL_MASK )

&& snaps )

{

ge->end = sp_round(ge->end, M_PI/snaps);

}

sp_genericellipse_normalize(ge);

((SPObject *)arc)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

ArcKnotHolderEntityEnd::knot_get()

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

return sp_arc_get_xy(arc, ge->end);

}

ArcKnotHolderEntityEnd::knot_click(guint state)

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

if (state & GDK_SHIFT_MASK) {

ge->end = ge->start = 0;

((SPObject *)ge)->updateRepr();

}

}

ArcKnotHolderEntityRX::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

NR::Point const s = snap_knot_position(arc, p);

ge->rx.computed = fabs( ge->cx.computed - s[NR::X] );

if ( state & GDK_CONTROL_MASK ) {

ge->ry.computed = ge->rx.computed;

}

((SPObject *)arc)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

ArcKnotHolderEntityRX::knot_get()

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

return (NR::Point(ge->cx.computed, ge->cy.computed) - NR::Point(ge->rx.computed, 0));

}

ArcKnotHolderEntityRX::knot_click(guint state)

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

if (state & GDK_CONTROL_MASK) {

ge->ry.computed = ge->rx.computed;

((SPObject *)ge)->updateRepr();

}

}

ArcKnotHolderEntityRY::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

SPArc *arc = SP_ARC(item);

NR::Point const s = snap_knot_position(arc, p);

ge->ry.computed = fabs( ge->cy.computed - s[NR::Y] );

if ( state & GDK_CONTROL_MASK ) {

ge->rx.computed = ge->ry.computed;

}

((SPObject *)arc)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

ArcKnotHolderEntityRY::knot_get()

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

return (NR::Point(ge->cx.computed, ge->cy.computed) - NR::Point(0, ge->ry.computed));

}

ArcKnotHolderEntityRY::knot_click(guint state)

{

SPGenericEllipse *ge = SP_GENERICELLIPSE(item);

if (state & GDK_CONTROL_MASK) {

ge->rx.computed = ge->ry.computed;

((SPObject *)ge)->updateRepr();

}

}

ArcKnotHolder::ArcKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

ArcKnotHolderEntityRX *entity_rx = new ArcKnotHolderEntityRX();

ArcKnotHolderEntityRY *entity_ry = new ArcKnotHolderEntityRY();

ArcKnotHolderEntityStart *entity_start = new ArcKnotHolderEntityStart();

ArcKnotHolderEntityEnd *entity_end = new ArcKnotHolderEntityEnd();

entity_rx->create(desktop, item, this,

_("Adjust ellipse <b>width</b>, with <b>Ctrl</b> to make circle"),

SP_KNOT_SHAPE_SQUARE, SP_KNOT_MODE_XOR);

entity_ry->create(desktop, item, this,

_("Adjust ellipse <b>height</b>, with <b>Ctrl</b> to make circle"),

SP_KNOT_SHAPE_SQUARE, SP_KNOT_MODE_XOR);

entity_start->create(desktop, item, this,

_("Position the <b>start point</b> of the arc or segment; with <b>Ctrl</b>"

"to snap angle; drag <b>inside</b> the ellipse for arc, <b>outside</b> for segment"),

SP_KNOT_SHAPE_CIRCLE, SP_KNOT_MODE_XOR);

entity_end->create(desktop, item, this,

_("Position the <b>end point</b> of the arc or segment; with <b>Ctrl</b> to snap angle; "

"drag <b>inside</b> the ellipse for arc, <b>outside</b> for segment"),

SP_KNOT_SHAPE_CIRCLE, SP_KNOT_MODE_XOR);

entity.push_back(entity_rx);

entity.push_back(entity_ry);

entity.push_back(entity_start);

entity.push_back(entity_end);

add_pattern_knotholder();

}

class StarKnotHolderEntity1 : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class StarKnotHolderEntity2 : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

StarKnotHolderEntity1::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPStar *star = SP_STAR(item);

NR::Point const s = snap_knot_position(star, p);

NR::Point d = s - star->center;

double arg1 = atan2(d);

double darg1 = arg1 - star->arg[0];

if (state & GDK_MOD1_MASK) {

star->randomized = darg1/(star->arg[0] - star->arg[1]);

} else if (state & GDK_SHIFT_MASK) {

star->rounded = darg1/(star->arg[0] - star->arg[1]);

} else if (state & GDK_CONTROL_MASK) {

star->r[0] = L2(d);

} else {

star->r[0] = L2(d);

star->arg[0] = arg1;

star->arg[1] += darg1;

}

((SPObject *)star)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

StarKnotHolderEntity2::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

SPStar *star = SP_STAR(item);

NR::Point const s = snap_knot_position(star, p);

if (star->flatsided == false) {

NR::Point d = s - star->center;

double arg1 = atan2(d);

double darg1 = arg1 - star->arg[1];

if (state & GDK_MOD1_MASK) {

star->randomized = darg1/(star->arg[0] - star->arg[1]);

} else if (state & GDK_SHIFT_MASK) {

star->rounded = fabs(darg1/(star->arg[0] - star->arg[1]));

} else if (state & GDK_CONTROL_MASK) {

star->r[1] = L2(d);

star->arg[1] = star->arg[0] + M_PI / star->sides;

}

else {

star->r[1] = L2(d);

star->arg[1] = atan2(d);

}

((SPObject *)star)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

}

NR::Point

StarKnotHolderEntity1::knot_get()

{

g_assert(item != NULL);

SPStar *star = SP_STAR(item);

return sp_star_get_xy(star, SP_STAR_POINT_KNOT1, 0);

}

NR::Point

StarKnotHolderEntity2::knot_get()

{

g_assert(item != NULL);

SPStar *star = SP_STAR(item);

return sp_star_get_xy(star, SP_STAR_POINT_KNOT2, 0);

}

static void

sp_star_knot_click(SPItem *item, guint state)

{

SPStar *star = SP_STAR(item);

if (state & GDK_MOD1_MASK) {

star->randomized = 0;

((SPObject *)star)->updateRepr();

} else if (state & GDK_SHIFT_MASK) {

star->rounded = 0;

((SPObject *)star)->updateRepr();

} else if (state & GDK_CONTROL_MASK) {

star->arg[1] = star->arg[0] + M_PI / star->sides;

((SPObject *)star)->updateRepr();

}

}

StarKnotHolderEntity1::knot_click(guint state)

{

return sp_star_knot_click(item, state);

}

StarKnotHolderEntity2::knot_click(guint state)

{

return sp_star_knot_click(item, state);

}

StarKnotHolder::StarKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

SPStar *star = SP_STAR(item);

StarKnotHolderEntity1 *entity1 = new StarKnotHolderEntity1();

entity1->create(desktop, item, this,

_("Adjust the <b>tip radius</b> of the star or polygon; "

"with <b>Shift</b> to round; with <b>Alt</b> to randomize"));

entity.push_back(entity1);

if (star->flatsided == false) {

StarKnotHolderEntity2 *entity2 = new StarKnotHolderEntity2();

entity2->create(desktop, item, this,

_("Adjust the <b>base radius</b> of the star; with <b>Ctrl</b> to keep star rays "

"radial (no skew); with <b>Shift</b> to round; with <b>Alt</b> to randomize"));

entity.push_back(entity2);

}

add_pattern_knotholder();

}

class SpiralKnotHolderEntityInner : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

virtual void knot_click(guint state);

};

class SpiralKnotHolderEntityOuter : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

SpiralKnotHolderEntityInner::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

int snaps = prefs_get_int_attribute("options.rotationsnapsperpi", "value", 12);

SPSpiral *spiral = SP_SPIRAL(item);

gdouble dx = p[NR::X] - spiral->cx;

gdouble dy = p[NR::Y] - spiral->cy;

if (state & GDK_MOD1_MASK) {

// adjust divergence by vertical drag, relative to rad

double new_exp = (spiral->rad + dy)/(spiral->rad);

spiral->exp = new_exp > 0? new_exp : 0;

} else {

// roll/unroll from inside

gdouble arg_t0;

sp_spiral_get_polar(spiral, spiral->t0, NULL, &arg_t0);

gdouble arg_tmp = atan2(dy, dx) - arg_t0;

gdouble arg_t0_new = arg_tmp - floor((arg_tmp+M_PI)/(2.0*M_PI))*2.0*M_PI + arg_t0;

spiral->t0 = (arg_t0_new - spiral->arg) / (2.0*M_PI*spiral->revo);

/* round inner arg per PI/snaps, if CTRL is pressed */

if ( ( state & GDK_CONTROL_MASK )

&& ( fabs(spiral->revo) > SP_EPSILON_2 )

&& ( snaps != 0 ) ) {

gdouble arg = 2.0*M_PI*spiral->revo*spiral->t0 + spiral->arg;

spiral->t0 = (sp_round(arg, M_PI/snaps) - spiral->arg)/(2.0*M_PI*spiral->revo);

}

spiral->t0 = CLAMP(spiral->t0, 0.0, 0.999);

}

((SPObject *)spiral)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

SpiralKnotHolderEntityOuter::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint state)

{

int snaps = prefs_get_int_attribute("options.rotationsnapsperpi", "value", 12);

SPSpiral *spiral = SP_SPIRAL(item);

gdouble dx = p[NR::X] - spiral->cx;

gdouble dy = p[NR::Y] - spiral->cy;

if (state & GDK_SHIFT_MASK) { // rotate without roll/unroll

spiral->arg = atan2(dy, dx) - 2.0*M_PI*spiral->revo;

if (!(state & GDK_MOD1_MASK)) {

// if alt not pressed, change also rad; otherwise it is locked

spiral->rad = MAX(hypot(dx, dy), 0.001);

}

if ( ( state & GDK_CONTROL_MASK )

&& snaps ) {

spiral->arg = sp_round(spiral->arg, M_PI/snaps);

}

} else { // roll/unroll

// arg of the spiral outer end

double arg_1;

sp_spiral_get_polar(spiral, 1, NULL, &arg_1);

// its fractional part after the whole turns are subtracted

double arg_r = arg_1 - sp_round(arg_1, 2.0*M_PI);

// arg of the mouse point relative to spiral center

double mouse_angle = atan2(dy, dx);

if (mouse_angle < 0)

mouse_angle += 2*M_PI;

// snap if ctrl

if ( ( state & GDK_CONTROL_MASK ) && snaps ) {

mouse_angle = sp_round(mouse_angle, M_PI/snaps);

}

// by how much we want to rotate the outer point

double diff = mouse_angle - arg_r;

if (diff > M_PI)

diff -= 2*M_PI;

else if (diff < -M_PI)

diff += 2*M_PI;

// calculate the new rad;

// the value of t corresponding to the angle arg_1 + diff:

double t_temp = ((arg_1 + diff) - spiral->arg)/(2*M_PI*spiral->revo);

// the rad at that t:

double rad_new = 0;

if (t_temp > spiral->t0)

sp_spiral_get_polar(spiral, t_temp, &rad_new, NULL);

// change the revo (converting diff from radians to the number of turns)

spiral->revo += diff/(2*M_PI);

if (spiral->revo < 1e-3)

spiral->revo = 1e-3;

// if alt not pressed and the values are sane, change the rad

if (!(state & GDK_MOD1_MASK) && rad_new > 1e-3 && rad_new/spiral->rad < 2) {

// adjust t0 too so that the inner point stays unmoved

double r0;

sp_spiral_get_polar(spiral, spiral->t0, &r0, NULL);

spiral->rad = rad_new;

spiral->t0 = pow(r0 / spiral->rad, 1.0/spiral->exp);

}

if (!IS_FINITE(spiral->t0)) spiral->t0 = 0.0;

spiral->t0 = CLAMP(spiral->t0, 0.0, 0.999);

}

((SPObject *)spiral)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

SpiralKnotHolderEntityInner::knot_get()

{

SPSpiral *spiral = SP_SPIRAL(item);

return sp_spiral_get_xy(spiral, spiral->t0);

}

NR::Point

SpiralKnotHolderEntityOuter::knot_get()

{

SPSpiral *spiral = SP_SPIRAL(item);

return sp_spiral_get_xy(spiral, 1.0);

}

SpiralKnotHolderEntityInner::knot_click(guint state)

{

SPSpiral *spiral = SP_SPIRAL(item);

if (state & GDK_MOD1_MASK) {

spiral->exp = 1;

((SPObject *)spiral)->updateRepr();

} else if (state & GDK_SHIFT_MASK) {

spiral->t0 = 0;

((SPObject *)spiral)->updateRepr();

}

}

SpiralKnotHolder::SpiralKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

SpiralKnotHolderEntityInner *entity_inner = new SpiralKnotHolderEntityInner();

SpiralKnotHolderEntityOuter *entity_outer = new SpiralKnotHolderEntityOuter();

entity_inner->create(desktop, item, this,

_("Roll/unroll the spiral from <b>inside</b>; with <b>Ctrl</b> to snap angle; "

"with <b>Alt</b> to converge/diverge"));

entity_outer->create(desktop, item, this,

_("Roll/unroll the spiral from <b>outside</b>; with <b>Ctrl</b> to snap angle; "

"with <b>Shift</b> to scale/rotate"));

entity.push_back(entity_inner);

entity.push_back(entity_outer);

add_pattern_knotholder();

}

class OffsetKnotHolderEntity : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

OffsetKnotHolderEntity::knot_set(NR::Point const &p, NR::Point const &/*origin*/, guint /*state*/)

{

SPOffset *offset = SP_OFFSET(item);

offset->rad = sp_offset_distance_to_original(offset, p);

offset->knot = p;

offset->knotSet = true;

((SPObject *)offset)->requestDisplayUpdate(SP_OBJECT_MODIFIED_FLAG);

}

NR::Point

OffsetKnotHolderEntity::knot_get()

{

SPOffset *offset = SP_OFFSET(item);

NR::Point np;

sp_offset_top_point(offset,&np);

return np;

}

OffsetKnotHolder::OffsetKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

OffsetKnotHolderEntity *entity_offset = new OffsetKnotHolderEntity();

entity_offset->create(desktop, item, this,

_("Adjust the <b>offset distance</b>"));

entity.push_back(entity_offset);

add_pattern_knotholder();

}

class FlowtextKnotHolderEntity : public KnotHolderEntity {

public:

virtual NR::Point knot_get();

virtual void knot_set(NR::Point const &p, NR::Point const &origin, guint state);

};

NR::Point

FlowtextKnotHolderEntity::knot_get()

{

SPRect *rect = SP_RECT(item);

return NR::Point(rect->x.computed + rect->width.computed, rect->y.computed + rect->height.computed);

}

FlowtextKnotHolderEntity::knot_set(NR::Point const &p, NR::Point const &origin, guint state)

{

SPRect *rect = SP_RECT(item);

sp_rect_wh_set_internal(rect, p, origin, state);

}

FlowtextKnotHolder::FlowtextKnotHolder(SPDesktop *desktop, SPItem *item, SPKnotHolderReleasedFunc relhandler) :

KnotHolder(desktop, item, relhandler)

{

g_assert(item != NULL);

FlowtextKnotHolderEntity *entity_flowtext = new FlowtextKnotHolderEntity();

entity_flowtext->create(desktop, item, this,

_("Drag to resize the <b>flowed text frame</b>"));

entity.push_back(entity_flowtext);

}