#define noDYNA_DRAW_VERBOSE

#include "config.h"

#include <gtk/gtk.h>

#include <gdk/gdkkeysyms.h>

#include <glibmm/i18n.h>

#include <string>

#include <cstring>

#include <numeric>

#include "svg/svg.h"

#include "display/canvas-bpath.h"

#include "display/cairo-utils.h"

#include <2geom/math-utils.h>

#include <2geom/pathvector.h>

#include <2geom/bezier-utils.h>

#include <2geom/circle.h>

#include "display/curve.h"

#include <glib.h>

#include "macros.h"

#include "document.h"

#include "document-undo.h"

#include "selection.h"

#include "desktop.h"

#include "desktop-events.h"

#include "desktop-style.h"

#include "message-context.h"

#include "preferences.h"

#include "pixmaps/cursor-calligraphy.xpm"

#include "xml/repr.h"

#include "context-fns.h"

#include "sp-item.h"

#include "inkscape.h"

#include "color.h"

#include "splivarot.h"

#include "sp-item-group.h"

#include "sp-shape.h"

#include "sp-path.h"

#include "sp-text.h"

#include "display/sp-canvas.h"

#include "display/canvas-bpath.h"

#include "display/canvas-arena.h"

#include "livarot/Shape.h"

#include "verbs.h"

#include "ui/tools/calligraphic-tool.h"

using Inkscape::DocumentUndo;

#define DDC_RED_RGBA 0xff0000ff

#define TOLERANCE_CALLIGRAPHIC 0.1

#define DYNA_EPSILON 0.5e-6

#define DYNA_EPSILON_START 0.5e-2

#define DYNA_VEL_START 1e-5

#define DYNA_MIN_WIDTH 1.0e-6

#include "ui/tool-factory.h"

namespace Inkscape {

namespace UI {

namespace Tools {

static void add_cap(SPCurve *curve, Geom::Point const &from, Geom::Point const &to, double rounding);

namespace {

ToolBase* createCalligraphicContext() {

return new CalligraphicTool();

}

bool calligraphicContextRegistered = ToolFactory::instance().registerObject("/tools/calligraphic", createCalligraphicContext);

}

const std::string& CalligraphicTool::getPrefsPath() {

return CalligraphicTool::prefsPath;

}

const std::string CalligraphicTool::prefsPath = "/tools/calligraphic";

CalligraphicTool::CalligraphicTool()

: DynamicBase(cursor_calligraphy_xpm, 4, 4)

, keep_selected(true)

, hatch_spacing(0)

, hatch_spacing_step(0)

, hatch_item(NULL)

, hatch_livarot_path(NULL)

, hatch_last_nearest(Geom::Point(0,0))

, hatch_last_pointer(Geom::Point(0,0))

, hatch_escaped(false)

, hatch_area(NULL)

, just_started_drawing(false)

, trace_bg(false)

{

this->vel_thin = 0.1;

this->flatness = 0.9;

this->cap_rounding = 0.0;

this->abs_width = false;

}

CalligraphicTool::~CalligraphicTool() {

if (this->hatch_area) {

sp_canvas_item_destroy(this->hatch_area);

this->hatch_area = NULL;

}

}

void CalligraphicTool::setup() {

DynamicBase::setup();

this->accumulated = new SPCurve();

this->currentcurve = new SPCurve();

this->cal1 = new SPCurve();

this->cal2 = new SPCurve();

this->currentshape = sp_canvas_item_new(this->desktop->getSketch(), SP_TYPE_CANVAS_BPATH, NULL);

sp_canvas_bpath_set_fill(SP_CANVAS_BPATH(this->currentshape), DDC_RED_RGBA, SP_WIND_RULE_EVENODD);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->currentshape), 0x00000000, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

/* fixme: Cannot we cascade it to root more clearly? */

g_signal_connect(G_OBJECT(this->currentshape), "event", G_CALLBACK(sp_desktop_root_handler), this->desktop);

{

/* TODO: have a look at DropperTool::setup where the same is done.. generalize? */

Geom::PathVector path;

Geom::Circle(0, 0, 1).getPath(path);

SPCurve *c = new SPCurve(path);

this->hatch_area = sp_canvas_bpath_new(this->desktop->getControls(), c);

c->unref();

sp_canvas_bpath_set_fill(SP_CANVAS_BPATH(this->hatch_area), 0x00000000,(SPWindRule)0);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->hatch_area), 0x0000007f, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_item_hide(this->hatch_area);

}

sp_event_context_read(this, "mass");

sp_event_context_read(this, "wiggle");

sp_event_context_read(this, "angle");

sp_event_context_read(this, "width");

sp_event_context_read(this, "thinning");

sp_event_context_read(this, "tremor");

sp_event_context_read(this, "flatness");

sp_event_context_read(this, "tracebackground");

sp_event_context_read(this, "usepressure");

sp_event_context_read(this, "usetilt");

sp_event_context_read(this, "abs_width");

sp_event_context_read(this, "keep_selected");

sp_event_context_read(this, "cap_rounding");

this->is_drawing = false;

Inkscape::Preferences *prefs = Inkscape::Preferences::get();

if (prefs->getBool("/tools/calligraphic/selcue")) {

this->enableSelectionCue();

}

}

void CalligraphicTool::set(const Inkscape::Preferences::Entry& val) {

Glib::ustring path = val.getEntryName();

if (path == "tracebackground") {

this->trace_bg = val.getBool();

} else if (path == "keep_selected") {

this->keep_selected = val.getBool();

} else {

//pass on up to parent class to handle common attributes.

DynamicBase::set(val);

}

//g_print("DDC: %g %g %g %g\n", ddc->mass, ddc->drag, ddc->angle, ddc->width);

}

static double

flerp(double f0, double f1, double p)

{

return f0 + ( f1 - f0 ) * p;

}

void CalligraphicTool::reset(Geom::Point p) {

this->last = this->cur = this->getNormalizedPoint(p);

this->vel = Geom::Point(0,0);

this->vel_max = 0;

this->acc = Geom::Point(0,0);

this->ang = Geom::Point(0,0);

this->del = Geom::Point(0,0);

}

void CalligraphicTool::extinput(GdkEvent *event) {

if (gdk_event_get_axis (event, GDK_AXIS_PRESSURE, &this->pressure)) {

this->pressure = CLAMP (this->pressure, DDC_MIN_PRESSURE, DDC_MAX_PRESSURE);

} else {

this->pressure = DDC_DEFAULT_PRESSURE;

}

if (gdk_event_get_axis (event, GDK_AXIS_XTILT, &this->xtilt)) {

this->xtilt = CLAMP (this->xtilt, DDC_MIN_TILT, DDC_MAX_TILT);

} else {

this->xtilt = DDC_DEFAULT_TILT;

}

if (gdk_event_get_axis (event, GDK_AXIS_YTILT, &this->ytilt)) {

this->ytilt = CLAMP (this->ytilt, DDC_MIN_TILT, DDC_MAX_TILT);

} else {

this->ytilt = DDC_DEFAULT_TILT;

}

}

bool CalligraphicTool::apply(Geom::Point p) {

Geom::Point n = this->getNormalizedPoint(p);

/* Calculate mass and drag */

double const mass = flerp(1.0, 160.0, this->mass);

double const drag = flerp(0.0, 0.5, this->drag * this->drag);

/* Calculate force and acceleration */

Geom::Point force = n - this->cur;

// If force is below the absolute threshold DYNA_EPSILON,

// or we haven't yet reached DYNA_VEL_START (i.e. at the beginning of stroke)

// _and_ the force is below the (higher) DYNA_EPSILON_START threshold,

// discard this move.

// This prevents flips, blobs, and jerks caused by microscopic tremor of the tablet pen,

// especially bothersome at the start of the stroke where we don't yet have the inertia to

// smooth them out.

if ( Geom::L2(force) < DYNA_EPSILON || (this->vel_max < DYNA_VEL_START && Geom::L2(force) < DYNA_EPSILON_START)) {

return FALSE;

}

this->acc = force / mass;

/* Calculate new velocity */

this->vel += this->acc;

if (Geom::L2(this->vel) > this->vel_max)

this->vel_max = Geom::L2(this->vel);

/* Calculate angle of drawing tool */

double a1;

if (this->usetilt) {

// 1a. calculate nib angle from input device tilt:

gdouble length = std::sqrt(this->xtilt*this->xtilt + this->ytilt*this->ytilt);;

if (length > 0) {

Geom::Point ang1 = Geom::Point(this->ytilt/length, this->xtilt/length);

a1 = atan2(ang1);

}

else

a1 = 0.0;

}

else {

// 1b. fixed dc->angle (absolutely flat nib):

double const radians = ( (this->angle - 90) / 180.0 ) * M_PI;

Geom::Point ang1 = Geom::Point(-sin(radians), cos(radians));

a1 = atan2(ang1);

}

// 2. perpendicular to dc->vel (absolutely non-flat nib):

gdouble const mag_vel = Geom::L2(this->vel);

if ( mag_vel < DYNA_EPSILON ) {

return FALSE;

}

Geom::Point ang2 = Geom::rot90(this->vel) / mag_vel;

// 3. Average them using flatness parameter:

// calculate angles

double a2 = atan2(ang2);

// flip a2 to force it to be in the same half-circle as a1

bool flipped = false;

if (fabs (a2-a1) > 0.5*M_PI) {

a2 += M_PI;

flipped = true;

}

// normalize a2

if (a2 > M_PI)

a2 -= 2*M_PI;

if (a2 < -M_PI)

a2 += 2*M_PI;

// find the flatness-weighted bisector angle, unflip if a2 was flipped

// FIXME: when dc->vel is oscillating around the fixed angle, the new_ang flips back and forth. How to avoid this?

double new_ang = a1 + (1 - this->flatness) * (a2 - a1) - (flipped? M_PI : 0);

// Try to detect a sudden flip when the new angle differs too much from the previous for the

// current velocity; in that case discard this move

double angle_delta = Geom::L2(Geom::Point (cos (new_ang), sin (new_ang)) - this->ang);

if ( angle_delta / Geom::L2(this->vel) > 4000 ) {

return FALSE;

}

// convert to point

this->ang = Geom::Point (cos (new_ang), sin (new_ang));

/* Apply drag */

this->vel *= 1.0 - drag;

/* Update position */

this->last = this->cur;

this->cur += this->vel;

return TRUE;

}

void CalligraphicTool::brush() {

g_assert( this->npoints >= 0 && this->npoints < SAMPLING_SIZE );

// How much velocity thins strokestyle

double vel_thin = flerp (0, 160, this->vel_thin);

// Influence of pressure on thickness

double pressure_thick = (this->usepressure ? this->pressure : 1.0);

// get the real brush point, not the same as pointer (affected by hatch tracking and/or mass

// drag)

Geom::Point brush = this->getViewPoint(this->cur);

Geom::Point brush_w = SP_EVENT_CONTEXT(this)->desktop->d2w(brush);

double trace_thick = 1;

if (this->trace_bg) {

// pick single pixel

double R, G, B, A;

Geom::IntRect area = Geom::IntRect::from_xywh(brush_w.floor(), Geom::IntPoint(1, 1));

cairo_surface_t *s = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, 1, 1);

sp_canvas_arena_render_surface(SP_CANVAS_ARENA(this->desktop->getDrawing()), s, area);

ink_cairo_surface_average_color_premul(s, R, G, B, A);

cairo_surface_destroy(s);

double max = MAX (MAX (R, G), B);

double min = MIN (MIN (R, G), B);

double L = A * (max + min)/2 + (1 - A); // blend with white bg

trace_thick = 1 - L;

//g_print ("L %g thick %g\n", L, trace_thick);

}

double width = (pressure_thick * trace_thick - vel_thin * Geom::L2(this->vel)) * this->width;

double tremble_left = 0, tremble_right = 0;

if (this->tremor > 0) {

// obtain two normally distributed random variables, using polar Box-Muller transform

double x1, x2, w, y1, y2;

do {

x1 = 2.0 * g_random_double_range(0,1) - 1.0;

x2 = 2.0 * g_random_double_range(0,1) - 1.0;

w = x1 * x1 + x2 * x2;

} while ( w >= 1.0 );

w = sqrt( (-2.0 * log( w ) ) / w );

y1 = x1 * w;

y2 = x2 * w;

// deflect both left and right edges randomly and independently, so that:

// (1) dc->tremor=1 corresponds to sigma=1, decreasing dc->tremor narrows the bell curve;

// (2) deflection depends on width, but is upped for small widths for better visual uniformity across widths;

// (3) deflection somewhat depends on speed, to prevent fast strokes looking

// comparatively smooth and slow ones excessively jittery

tremble_left = (y1)*this->tremor * (0.15 + 0.8*width) * (0.35 + 14*Geom::L2(this->vel));

tremble_right = (y2)*this->tremor * (0.15 + 0.8*width) * (0.35 + 14*Geom::L2(this->vel));

}

if ( width < 0.02 * this->width ) {

width = 0.02 * this->width;

}

double dezoomify_factor = 0.05 * 1000;

if (!this->abs_width) {

dezoomify_factor /= SP_EVENT_CONTEXT(this)->desktop->current_zoom();

}

Geom::Point del_left = dezoomify_factor * (width + tremble_left) * this->ang;

Geom::Point del_right = dezoomify_factor * (width + tremble_right) * this->ang;

this->point1[this->npoints] = brush + del_left;

this->point2[this->npoints] = brush - del_right;

this->del = 0.5*(del_left + del_right);

this->npoints++;

}

static void

sp_ddc_update_toolbox (SPDesktop *desktop, const gchar *id, double value)

{

desktop->setToolboxAdjustmentValue (id, value);

}

void CalligraphicTool::cancel() {

this->dragging = false;

this->is_drawing = false;

sp_canvas_item_ungrab(SP_CANVAS_ITEM(desktop->acetate), 0);

/* Remove all temporary line segments */

while (this->segments) {

sp_canvas_item_destroy(SP_CANVAS_ITEM(this->segments->data));

this->segments = g_slist_remove(this->segments, this->segments->data);

}

/* reset accumulated curve */

this->accumulated->reset();

this->clear_current();

if (this->repr) {

this->repr = NULL;

}

}

bool CalligraphicTool::root_handler(GdkEvent* event) {

gint ret = FALSE;

switch (event->type) {

case GDK_BUTTON_PRESS:

if (event->button.button == 1 && !this->space_panning) {

if (Inkscape::have_viable_layer(desktop, this->message_context) == false) {

return TRUE;

}

this->accumulated->reset();

if (this->repr) {

this->repr = NULL;

}

/* initialize first point */

this->npoints = 0;

sp_canvas_item_grab(SP_CANVAS_ITEM(desktop->acetate),

( GDK_KEY_PRESS_MASK |

GDK_BUTTON_RELEASE_MASK |

GDK_POINTER_MOTION_MASK |

GDK_BUTTON_PRESS_MASK ),

NULL,

event->button.time);

ret = TRUE;

desktop->canvas->forceFullRedrawAfterInterruptions(3);

this->is_drawing = true;

this->just_started_drawing = true;

}

break;

case GDK_MOTION_NOTIFY:

{

Geom::Point const motion_w(event->motion.x,

event->motion.y);

Geom::Point motion_dt(desktop->w2d(motion_w));

this->extinput(event);

this->message_context->clear();

// for hatching:

double hatch_dist = 0;

Geom::Point hatch_unit_vector(0,0);

Geom::Point nearest(0,0);

Geom::Point pointer(0,0);

Geom::Affine motion_to_curve(Geom::identity());

if (event->motion.state & GDK_CONTROL_MASK) { // hatching - sense the item

SPItem *selected = desktop->getSelection()->singleItem();

if (selected && (SP_IS_SHAPE(selected) || SP_IS_TEXT(selected))) {

// One item selected, and it's a path;

// let's try to track it as a guide

if (selected != this->hatch_item) {

this->hatch_item = selected;

if (this->hatch_livarot_path)

delete this->hatch_livarot_path;

this->hatch_livarot_path = Path_for_item (this->hatch_item, true, true);

this->hatch_livarot_path->ConvertWithBackData(0.01);

}

// calculate pointer point in the guide item's coords

motion_to_curve = selected->dt2i_affine() * selected->i2doc_affine();

pointer = motion_dt * motion_to_curve;

// calculate the nearest point on the guide path

boost::optional<Path::cut_position> position = get_nearest_position_on_Path(this->hatch_livarot_path, pointer);

nearest = get_point_on_Path(this->hatch_livarot_path, position->piece, position->t);

// distance from pointer to nearest

hatch_dist = Geom::L2(pointer - nearest);

// unit-length vector

hatch_unit_vector = (pointer - nearest)/hatch_dist;

this->message_context->set(Inkscape::NORMAL_MESSAGE, _("<b>Guide path selected</b>; start drawing along the guide with <b>Ctrl</b>"));

} else {

this->message_context->set(Inkscape::NORMAL_MESSAGE, _("<b>Select a guide path</b> to track with <b>Ctrl</b>"));

}

}

if ( this->is_drawing && (event->motion.state & GDK_BUTTON1_MASK) && !this->space_panning) {

this->dragging = TRUE;

if (event->motion.state & GDK_CONTROL_MASK && this->hatch_item) { // hatching

#define HATCH_VECTOR_ELEMENTS 12

#define INERTIA_ELEMENTS 24

#define SPEED_ELEMENTS 12

#define SPEED_MIN 0.3

#define SPEED_NORMAL 0.35

#define INERTIA_FORCE 0.5

// speed is the movement of the nearest point along the guide path, divided by

// the movement of the pointer at the same period; it is averaged for the last

// SPEED_ELEMENTS motion events. Normally, as you track the guide path, speed

// is about 1, i.e. the nearest point on the path is moved by about the same

// distance as the pointer. If the speed starts to decrease, we are losing

// contact with the guide; if it drops below SPEED_MIN, we are on our own and

// not attracted to guide anymore. Most often this happens when you have

// tracked to the end of a guide calligraphic stroke and keep moving

// further. We try to handle this situation gracefully: not stick with the

// guide forever but let go of it smoothly and without sharp jerks (non-zero

// mass recommended; with zero mass, jerks are still quite noticeable).

double speed = 1;

if (Geom::L2(this->hatch_last_nearest) != 0) {

// the distance nearest moved since the last motion event

double nearest_moved = Geom::L2(nearest - this->hatch_last_nearest);

// the distance pointer moved since the last motion event

double pointer_moved = Geom::L2(pointer - this->hatch_last_pointer);

// store them in stacks limited to SPEED_ELEMENTS

this->hatch_nearest_past.push_front(nearest_moved);

if (this->hatch_nearest_past.size() > SPEED_ELEMENTS)

this->hatch_nearest_past.pop_back();

this->hatch_pointer_past.push_front(pointer_moved);

if (this->hatch_pointer_past.size() > SPEED_ELEMENTS)

this->hatch_pointer_past.pop_back();

// If the stacks are full,

if (this->hatch_nearest_past.size() == SPEED_ELEMENTS) {

// calculate the sums of all stored movements

double nearest_sum = std::accumulate (this->hatch_nearest_past.begin(), this->hatch_nearest_past.end(), 0.0);

double pointer_sum = std::accumulate (this->hatch_pointer_past.begin(), this->hatch_pointer_past.end(), 0.0);

// and divide to get the speed

speed = nearest_sum/pointer_sum;

//g_print ("nearest sum %g pointer_sum %g speed %g\n", nearest_sum, pointer_sum, speed);

}

}

if ( this->hatch_escaped // already escaped, do not reattach

|| (speed < SPEED_MIN) // stuck; most likely reached end of traced stroke

|| (this->hatch_spacing > 0 && hatch_dist > 50 * this->hatch_spacing) // went too far from the guide

) {

// We are NOT attracted to the guide!

//g_print ("\nlast_nearest %g %g nearest %g %g pointer %g %g pos %d %g\n", dc->last_nearest[Geom::X], dc->last_nearest[Geom::Y], nearest[Geom::X], nearest[Geom::Y], pointer[Geom::X], pointer[Geom::Y], position->piece, position->t);

// Remember hatch_escaped so we don't get

// attracted again until the end of this stroke

this->hatch_escaped = true;

if (this->inertia_vectors.size() >= INERTIA_ELEMENTS/2) { // move by inertia

Geom::Point moved_past_escape = motion_dt - this->inertia_vectors.front();

Geom::Point inertia =

this->inertia_vectors.front() - this->inertia_vectors.back();

double dot = Geom::dot (moved_past_escape, inertia);

dot /= Geom::L2(moved_past_escape) * Geom::L2(inertia);

if (dot > 0) { // mouse is still moving in approx the same direction

Geom::Point should_have_moved =

(inertia) * (1/Geom::L2(inertia)) * Geom::L2(moved_past_escape);

motion_dt = this->inertia_vectors.front() +

(INERTIA_FORCE * should_have_moved + (1 - INERTIA_FORCE) * moved_past_escape);

}

}

} else {

// Calculate angle cosine of this vector-to-guide and all past vectors

// summed, to detect if we accidentally flipped to the other side of the

// guide

Geom::Point hatch_vector_accumulated = std::accumulate

(this->hatch_vectors.begin(), this->hatch_vectors.end(), Geom::Point(0,0));

double dot = Geom::dot (pointer - nearest, hatch_vector_accumulated);

dot /= Geom::L2(pointer - nearest) * Geom::L2(hatch_vector_accumulated);

if (this->hatch_spacing != 0) { // spacing was already set

double target;

if (speed > SPEED_NORMAL) {

// all ok, strictly obey the spacing

target = this->hatch_spacing;

} else {

// looks like we're starting to lose speed,

// so _gradually_ let go attraction to prevent jerks

target = (this->hatch_spacing * speed + hatch_dist * (SPEED_NORMAL - speed))/SPEED_NORMAL;

}

if (!IS_NAN(dot) && dot < -0.5) {// flip

target = -target;

}

// This is the track pointer that we will use instead of the real one

Geom::Point new_pointer = nearest + target * hatch_unit_vector;

// some limited feedback: allow persistent pulling to slightly change

// the spacing

this->hatch_spacing += (hatch_dist - this->hatch_spacing)/3500;

// return it to the desktop coords

motion_dt = new_pointer * motion_to_curve.inverse();

if (speed >= SPEED_NORMAL) {

this->inertia_vectors.push_front(motion_dt);

if (this->inertia_vectors.size() > INERTIA_ELEMENTS)

this->inertia_vectors.pop_back();

}

} else {

// this is the first motion event, set the dist

this->hatch_spacing = hatch_dist;

}

// remember last points

this->hatch_last_pointer = pointer;

this->hatch_last_nearest = nearest;

this->hatch_vectors.push_front(pointer - nearest);

if (this->hatch_vectors.size() > HATCH_VECTOR_ELEMENTS)

this->hatch_vectors.pop_back();

}

this->message_context->set(Inkscape::NORMAL_MESSAGE, this->hatch_escaped? _("Tracking: <b>connection to guide path lost!</b>") : _("<b>Tracking</b> a guide path"));

} else {

this->message_context->set(Inkscape::NORMAL_MESSAGE, _("<b>Drawing</b> a calligraphic stroke"));

}

if (this->just_started_drawing) {

this->just_started_drawing = false;

this->reset(motion_dt);

}

if (!this->apply(motion_dt)) {

ret = TRUE;

break;

}

if ( this->cur != this->last ) {

this->brush();

g_assert( this->npoints > 0 );

this->fit_and_split(false);

}

ret = TRUE;

}

// Draw the hatching circle if necessary

if (event->motion.state & GDK_CONTROL_MASK) {

if (this->hatch_spacing == 0 && hatch_dist != 0) {

// Haven't set spacing yet: gray, center free, update radius live

Geom::Point c = desktop->w2d(motion_w);

Geom::Affine const sm (Geom::Scale(hatch_dist, hatch_dist) * Geom::Translate(c));

sp_canvas_item_affine_absolute(this->hatch_area, sm);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->hatch_area), 0x7f7f7fff, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_item_show(this->hatch_area);

} else if (this->dragging && !this->hatch_escaped) {

// Tracking: green, center snapped, fixed radius

Geom::Point c = motion_dt;

Geom::Affine const sm (Geom::Scale(this->hatch_spacing, this->hatch_spacing) * Geom::Translate(c));

sp_canvas_item_affine_absolute(this->hatch_area, sm);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->hatch_area), 0x00FF00ff, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_item_show(this->hatch_area);

} else if (this->dragging && this->hatch_escaped) {

// Tracking escaped: red, center free, fixed radius

Geom::Point c = motion_dt;

Geom::Affine const sm (Geom::Scale(this->hatch_spacing, this->hatch_spacing) * Geom::Translate(c));

sp_canvas_item_affine_absolute(this->hatch_area, sm);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->hatch_area), 0xFF0000ff, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_item_show(this->hatch_area);

} else {

// Not drawing but spacing set: gray, center snapped, fixed radius

Geom::Point c = (nearest + this->hatch_spacing * hatch_unit_vector) * motion_to_curve.inverse();

if (!IS_NAN(c[Geom::X]) && !IS_NAN(c[Geom::Y])) {

Geom::Affine const sm (Geom::Scale(this->hatch_spacing, this->hatch_spacing) * Geom::Translate(c));

sp_canvas_item_affine_absolute(this->hatch_area, sm);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(this->hatch_area), 0x7f7f7fff, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_item_show(this->hatch_area);

}

}

} else {

sp_canvas_item_hide(this->hatch_area);

}

}

break;

case GDK_BUTTON_RELEASE:

{

Geom::Point const motion_w(event->button.x, event->button.y);

Geom::Point const motion_dt(desktop->w2d(motion_w));

sp_canvas_item_ungrab(SP_CANVAS_ITEM(desktop->acetate), event->button.time);

desktop->canvas->endForcedFullRedraws();

this->is_drawing = false;

if (this->dragging && event->button.button == 1 && !this->space_panning) {

this->dragging = FALSE;

this->apply(motion_dt);

/* Remove all temporary line segments */

while (this->segments) {

sp_canvas_item_destroy(SP_CANVAS_ITEM(this->segments->data));

this->segments = g_slist_remove(this->segments, this->segments->data);

}

/* Create object */

this->fit_and_split(true);

if (this->accumulate())

this->set_to_accumulated(event->button.state & GDK_SHIFT_MASK, event->button.state & GDK_MOD1_MASK); // performs document_done

else

g_warning ("Failed to create path: invalid data in dc->cal1 or dc->cal2");

/* reset accumulated curve */

this->accumulated->reset();

this->clear_current();

if (this->repr) {

this->repr = NULL;

}

if (!this->hatch_pointer_past.empty()) this->hatch_pointer_past.clear();

if (!this->hatch_nearest_past.empty()) this->hatch_nearest_past.clear();

if (!this->inertia_vectors.empty()) this->inertia_vectors.clear();

if (!this->hatch_vectors.empty()) this->hatch_vectors.clear();

this->hatch_last_nearest = Geom::Point(0,0);

this->hatch_last_pointer = Geom::Point(0,0);

this->hatch_escaped = false;

this->hatch_item = NULL;

this->hatch_livarot_path = NULL;

this->just_started_drawing = false;

if (this->hatch_spacing != 0 && !this->keep_selected) {

// we do not select the newly drawn path, so increase spacing by step

if (this->hatch_spacing_step == 0) {

this->hatch_spacing_step = this->hatch_spacing;

}

this->hatch_spacing += this->hatch_spacing_step;

}

this->message_context->clear();

ret = TRUE;

}

break;

}

case GDK_KEY_PRESS:

switch (get_group0_keyval (&event->key)) {

case GDK_KEY_Up:

case GDK_KEY_KP_Up:

if (!MOD__CTRL_ONLY(event)) {

this->angle += 5.0;

if (this->angle > 90.0)

this->angle = 90.0;

sp_ddc_update_toolbox (desktop, "calligraphy-angle", this->angle);

ret = TRUE;

}

break;

case GDK_KEY_Down:

case GDK_KEY_KP_Down:

if (!MOD__CTRL_ONLY(event)) {

this->angle -= 5.0;

if (this->angle < -90.0)

this->angle = -90.0;

sp_ddc_update_toolbox (desktop, "calligraphy-angle", this->angle);

ret = TRUE;

}

break;

case GDK_KEY_Right:

case GDK_KEY_KP_Right:

if (!MOD__CTRL_ONLY(event)) {

this->width += 0.01;

if (this->width > 1.0)

this->width = 1.0;

sp_ddc_update_toolbox (desktop, "altx-calligraphy", this->width * 100); // the same spinbutton is for alt+x

ret = TRUE;

}

break;

case GDK_KEY_Left:

case GDK_KEY_KP_Left:

if (!MOD__CTRL_ONLY(event)) {

this->width -= 0.01;

if (this->width < 0.01)

this->width = 0.01;

sp_ddc_update_toolbox (desktop, "altx-calligraphy", this->width * 100);

ret = TRUE;

}

break;

case GDK_KEY_Home:

case GDK_KEY_KP_Home:

this->width = 0.01;

sp_ddc_update_toolbox (desktop, "altx-calligraphy", this->width * 100);

ret = TRUE;

break;

case GDK_KEY_End:

case GDK_KEY_KP_End:

this->width = 1.0;

sp_ddc_update_toolbox (desktop, "altx-calligraphy", this->width * 100);

ret = TRUE;

break;

case GDK_KEY_x:

case GDK_KEY_X:

if (MOD__ALT_ONLY(event)) {

desktop->setToolboxFocusTo ("altx-calligraphy");

ret = TRUE;

}

break;

case GDK_KEY_Escape:

if (this->is_drawing) {

// if drawing, cancel, otherwise pass it up for deselecting

this->cancel();

ret = TRUE;

}

break;

case GDK_KEY_z:

case GDK_KEY_Z:

if (MOD__CTRL_ONLY(event) && this->is_drawing) {

// if drawing, cancel, otherwise pass it up for undo

this->cancel();

ret = TRUE;

}

break;

default:

break;

}

break;

case GDK_KEY_RELEASE:

switch (get_group0_keyval(&event->key)) {

case GDK_KEY_Control_L:

case GDK_KEY_Control_R:

this->message_context->clear();

this->hatch_spacing = 0;

this->hatch_spacing_step = 0;

break;

default:

break;

}

break;

default:

break;

}

if (!ret) {

ret = DynamicBase::root_handler(event);

}

return ret;

}

void CalligraphicTool::clear_current() {

/* reset bpath */

sp_canvas_bpath_set_bpath(SP_CANVAS_BPATH(this->currentshape), NULL);

/* reset curve */

this->currentcurve->reset();

this->cal1->reset();

this->cal2->reset();

/* reset points */

this->npoints = 0;

}

void CalligraphicTool::set_to_accumulated(bool unionize, bool subtract) {

if (!this->accumulated->is_empty()) {

if (!this->repr) {

/* Create object */

Inkscape::XML::Document *xml_doc = desktop->doc()->getReprDoc();

Inkscape::XML::Node *repr = xml_doc->createElement("svg:path");

/* Set style */

sp_desktop_apply_style_tool (desktop, repr, "/tools/calligraphic", false);

this->repr = repr;

SPItem *item=SP_ITEM(desktop->currentLayer()->appendChildRepr(this->repr));

Inkscape::GC::release(this->repr);

item->transform = SP_ITEM(desktop->currentLayer())->i2doc_affine().inverse();

item->updateRepr();

}

Geom::PathVector pathv = this->accumulated->get_pathvector() * desktop->dt2doc();

gchar *str = sp_svg_write_path(pathv);

g_assert( str != NULL );

this->repr->setAttribute("d", str);

g_free(str);

if (unionize) {

desktop->getSelection()->add(this->repr);

sp_selected_path_union_skip_undo(desktop->getSelection(), desktop);

} else if (subtract) {

desktop->getSelection()->add(this->repr);

sp_selected_path_diff_skip_undo(desktop->getSelection(), desktop);

} else {

if (this->keep_selected) {

desktop->getSelection()->set(this->repr);

}

}

// Now we need to write the transform information.

// First, find out whether our repr is still linked to a valid object. In this case,

// we need to write the transform data only for this element.

// Either there was no boolean op or it failed.

SPItem *result = SP_ITEM(desktop->doc()->getObjectByRepr(this->repr));

if (result == NULL) {

// The boolean operation succeeded.

// Now we fetch the single item, that has been set as selected by the boolean op.

// This is its result.

result = desktop->getSelection()->singleItem();

}

result->doWriteTransform(result->getRepr(), result->transform, NULL, true);

} else {

if (this->repr) {

sp_repr_unparent(this->repr);

}

this->repr = NULL;

}

DocumentUndo::done(desktop->getDocument(), SP_VERB_CONTEXT_CALLIGRAPHIC,

_("Draw calligraphic stroke"));

}

static void

add_cap(SPCurve *curve,

Geom::Point const &from,

Geom::Point const &to,

double rounding)

{

if (Geom::L2( to - from ) > DYNA_EPSILON) {

Geom::Point vel = rounding * Geom::rot90( to - from ) / sqrt(2.0);

double mag = Geom::L2(vel);

Geom::Point v = mag * Geom::rot90( to - from ) / Geom::L2( to - from );

curve->curveto(from + v, to + v, to);

}

}

bool CalligraphicTool::accumulate() {

if (

this->cal1->is_empty() ||

this->cal2->is_empty() ||

(this->cal1->get_segment_count() <= 0) ||

this->cal1->first_path()->closed()

) {

this->cal1->reset();

this->cal2->reset();

return false; // failure

}

SPCurve *rev_cal2 = this->cal2->create_reverse();

if ((rev_cal2->get_segment_count() <= 0) || rev_cal2->first_path()->closed()) {

rev_cal2->unref();

this->cal1->reset();

this->cal2->reset();

return false; // failure

}

Geom::Curve const * dc_cal1_firstseg = this->cal1->first_segment();

Geom::Curve const * rev_cal2_firstseg = rev_cal2->first_segment();

Geom::Curve const * dc_cal1_lastseg = this->cal1->last_segment();

Geom::Curve const * rev_cal2_lastseg = rev_cal2->last_segment();

this->accumulated->reset(); /* Is this required ?? */

this->accumulated->append(this->cal1, false);

add_cap(this->accumulated, dc_cal1_lastseg->finalPoint(), rev_cal2_firstseg->initialPoint(), this->cap_rounding);

this->accumulated->append(rev_cal2, true);

add_cap(this->accumulated, rev_cal2_lastseg->finalPoint(), dc_cal1_firstseg->initialPoint(), this->cap_rounding);

this->accumulated->closepath();

rev_cal2->unref();

this->cal1->reset();

this->cal2->reset();

return true; // success

}

static double square(double const x)

{

return x * x;

}

void CalligraphicTool::fit_and_split(bool release) {

double const tolerance_sq = square( desktop->w2d().descrim() * TOLERANCE_CALLIGRAPHIC );

#ifdef DYNA_DRAW_VERBOSE

g_print("[F&S:R=%c]", release?'T':'F');

#endif

if (!( this->npoints > 0 && this->npoints < SAMPLING_SIZE )) {

return; // just clicked

}

if ( this->npoints == SAMPLING_SIZE - 1 || release ) {

#define BEZIER_SIZE 4

#define BEZIER_MAX_BEZIERS 8

#define BEZIER_MAX_LENGTH ( BEZIER_SIZE * BEZIER_MAX_BEZIERS )

#ifdef DYNA_DRAW_VERBOSE

g_print("[F&S:#] dc->npoints:%d, release:%s\n",

this->npoints, release ? "TRUE" : "FALSE");

#endif

/* Current calligraphic */

if ( this->cal1->is_empty() || this->cal2->is_empty() ) {

/* dc->npoints > 0 */

/* g_print("calligraphics(1|2) reset\n"); */

this->cal1->reset();

this->cal2->reset();

this->cal1->moveto(this->point1[0]);

this->cal2->moveto(this->point2[0]);

}

Geom::Point b1[BEZIER_MAX_LENGTH];

gint const nb1 = Geom::bezier_fit_cubic_r(b1, this->point1, this->npoints,

tolerance_sq, BEZIER_MAX_BEZIERS);

g_assert( nb1 * BEZIER_SIZE <= gint(G_N_ELEMENTS(b1)) );

Geom::Point b2[BEZIER_MAX_LENGTH];

gint const nb2 = Geom::bezier_fit_cubic_r(b2, this->point2, this->npoints,

tolerance_sq, BEZIER_MAX_BEZIERS);

g_assert( nb2 * BEZIER_SIZE <= gint(G_N_ELEMENTS(b2)) );

if ( nb1 != -1 && nb2 != -1 ) {

/* Fit and draw and reset state */

#ifdef DYNA_DRAW_VERBOSE

g_print("nb1:%d nb2:%d\n", nb1, nb2);

#endif

/* CanvasShape */

if (! release) {

this->currentcurve->reset();

this->currentcurve->moveto(b1[0]);

for (Geom::Point *bp1 = b1; bp1 < b1 + BEZIER_SIZE * nb1; bp1 += BEZIER_SIZE) {

this->currentcurve->curveto(bp1[1], bp1[2], bp1[3]);

}

this->currentcurve->lineto(b2[BEZIER_SIZE*(nb2-1) + 3]);

for (Geom::Point *bp2 = b2 + BEZIER_SIZE * ( nb2 - 1 ); bp2 >= b2; bp2 -= BEZIER_SIZE) {

this->currentcurve->curveto(bp2[2], bp2[1], bp2[0]);

}

// FIXME: dc->segments is always NULL at this point??

if (!this->segments) { // first segment

add_cap(this->currentcurve, b2[0], b1[0], this->cap_rounding);

}

this->currentcurve->closepath();

sp_canvas_bpath_set_bpath(SP_CANVAS_BPATH(this->currentshape), this->currentcurve);

}

/* Current calligraphic */

for (Geom::Point *bp1 = b1; bp1 < b1 + BEZIER_SIZE * nb1; bp1 += BEZIER_SIZE) {

this->cal1->curveto(bp1[1], bp1[2], bp1[3]);

}

for (Geom::Point *bp2 = b2; bp2 < b2 + BEZIER_SIZE * nb2; bp2 += BEZIER_SIZE) {

this->cal2->curveto(bp2[1], bp2[2], bp2[3]);

}

} else {

/* fixme: ??? */

#ifdef DYNA_DRAW_VERBOSE

g_print("[fit_and_split] failed to fit-cubic.\n");

#endif

this->draw_temporary_box();

for (gint i = 1; i < this->npoints; i++) {

this->cal1->lineto(this->point1[i]);

}

for (gint i = 1; i < this->npoints; i++) {

this->cal2->lineto(this->point2[i]);

}

}

/* Fit and draw and copy last point */

#ifdef DYNA_DRAW_VERBOSE

g_print("[%d]Yup\n", this->npoints);

#endif

if (!release) {

g_assert(!this->currentcurve->is_empty());

SPCanvasItem *cbp = sp_canvas_item_new(desktop->getSketch(),

SP_TYPE_CANVAS_BPATH,

NULL);

SPCurve *curve = this->currentcurve->copy();

sp_canvas_bpath_set_bpath(SP_CANVAS_BPATH (cbp), curve);

curve->unref();

guint32 fillColor = sp_desktop_get_color_tool (desktop, "/tools/calligraphic", true);

//guint32 strokeColor = sp_desktop_get_color_tool (desktop, "/tools/calligraphic", false);

double opacity = sp_desktop_get_master_opacity_tool (desktop, "/tools/calligraphic");

double fillOpacity = sp_desktop_get_opacity_tool (desktop, "/tools/calligraphic", true);

//double strokeOpacity = sp_desktop_get_opacity_tool (desktop, "/tools/calligraphic", false);

sp_canvas_bpath_set_fill(SP_CANVAS_BPATH(cbp), ((fillColor & 0xffffff00) | SP_COLOR_F_TO_U(opacity*fillOpacity)), SP_WIND_RULE_EVENODD);

//on second thougtht don't do stroke yet because we don't have stoke-width yet and because stoke appears between segments while drawing

//sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(cbp), ((strokeColor & 0xffffff00) | SP_COLOR_F_TO_U(opacity*strokeOpacity)), 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

sp_canvas_bpath_set_stroke(SP_CANVAS_BPATH(cbp), 0x00000000, 1.0, SP_STROKE_LINEJOIN_MITER, SP_STROKE_LINECAP_BUTT);

/* fixme: Cannot we cascade it to root more clearly? */

g_signal_connect(G_OBJECT(cbp), "event", G_CALLBACK(sp_desktop_root_handler), desktop);

this->segments = g_slist_prepend(this->segments, cbp);

}

this->point1[0] = this->point1[this->npoints - 1];

this->point2[0] = this->point2[this->npoints - 1];

this->npoints = 1;

} else {

this->draw_temporary_box();

}

}

void CalligraphicTool::draw_temporary_box() {

this->currentcurve->reset();

this->currentcurve->moveto(this->point2[this->npoints-1]);

for (gint i = this->npoints-2; i >= 0; i--) {

this->currentcurve->lineto(this->point2[i]);

}

for (gint i = 0; i < this->npoints; i++) {

this->currentcurve->lineto(this->point1[i]);

}

if (this->npoints >= 2) {

add_cap(this->currentcurve, this->point1[this->npoints-1], this->point2[this->npoints-1], this->cap_rounding);

}

this->currentcurve->closepath();

sp_canvas_bpath_set_bpath(SP_CANVAS_BPATH(this->currentshape), this->currentcurve);

}

}

}

}