lpe-skeletalstrokes.cpp revision aec1b94c999035922cd8c19878a4618883f5179b
#define INKSCAPE_LPE_SKELETAL_STROKES_CPP
/*
* Copyright (C) Johan Engelen 2007 <j.b.c.engelen@utwente.nl>
*
* Released under GNU GPL, read the file 'COPYING' for more information
*/
#include "live_effects/lpe-skeletalstrokes.h"
#include "sp-shape.h"
#include "display/curve.h"
#include <libnr/n-art-bpath.h>
#include "live_effects/n-art-bpath-2geom.h"
#include "svg/svg.h"
#include "ui/widget/scalar.h"
#include <2geom/sbasis.h>
#include <2geom/sbasis-geometric.h>
#include <2geom/bezier-to-sbasis.h>
#include <2geom/sbasis-to-bezier.h>
#include <2geom/d2.h>
#include <2geom/piecewise.h>
#include <algorithm>
using std::vector;
/* Theory in e-mail from J.F. Barraud
Let B be the skeleton path, and P the pattern (the path to be deformed).
P is a map t --> P(t) = ( x(t), y(t) ).
B is a map t --> B(t) = ( a(t), b(t) ).
The first step is to re-parametrize B by its arc length: this is the parametrization in which a point p on B is located by its distance s from start. One obtains a new map s --> U(s) = (a'(s),b'(s)), that still describes the same path B, but where the distance along B from start to
U(s) is s itself.
We also need a unit normal to the path. This can be obtained by computing a unit tangent vector, and rotate it by 90�. Call this normal vector N(s).
The basic deformation associated to B is then given by:
(x,y) --> U(x)+y*N(x)
(i.e. we go for distance x along the path, and then for distance y along the normal)
Of course this formula needs some minor adaptations (as is it depends on the absolute position of P for instance, so a little translation is needed
first) but I think we can first forget about them.
*/
namespace Inkscape {
namespace LivePathEffect {
static const Util::EnumData<SkelCopyType> SkelCopyTypeData[SSCT_END] = {
{SSCT_SINGLE, N_("Single"), "single"},
{SSCT_SINGLE_STRETCHED, N_("Single, stretched"), "single_stretched"},
{SSCT_REPEATED, N_("Repeated"), "repeated"},
{SSCT_REPEATED_STRETCHED, N_("Repeated, stretched"), "repeated_stretched"}
};
static const Util::EnumDataConverter<SkelCopyType> SkelCopyTypeConverter(SkelCopyTypeData, SSCT_END);
LPESkeletalStrokes::LPESkeletalStrokes(LivePathEffectObject *lpeobject) :
Effect(lpeobject),
pattern(_("Pattern source"), _("Path to put along the skeleton path"), "pattern", &wr, this, "M0,0 L1,0"),
copytype(_("Pattern copies"), _("How many pattern copies to place along the skeleton path"), "copytype", SkelCopyTypeConverter, &wr, this, SSCT_SINGLE_STRETCHED),
prop_scale(_("Width"), _("Width of the pattern"), "prop_scale", &wr, this, 1),
scale_y_rel(_("Width in units of length"), _("Scale the width of the pattern in units of its length"), "scale_y_rel", &wr, this, false),
spacing(_("Spacing"), _("Space between copies of the pattern"), "spacing", &wr, this, 0),
normal_offset(_("Normal offset"), "", "normal_offset", &wr, this, 0),
tang_offset(_("Tangential offset"), "", "tang_offset", &wr, this, 0),
vertical_pattern(_("Pattern is vertical"), "Rotate pattern 90 deg before applying", "vertical_pattern", &wr, this, false)
{
registerParameter( dynamic_cast<Parameter *>(&pattern) );
registerParameter( dynamic_cast<Parameter *>(&copytype) );
registerParameter( dynamic_cast<Parameter *>(&prop_scale) );
registerParameter( dynamic_cast<Parameter *>(&scale_y_rel) );
// registerParameter( dynamic_cast<Parameter *>(&spacing) );
// registerParameter( dynamic_cast<Parameter *>(&normal_offset) );
// registerParameter( dynamic_cast<Parameter *>(&tang_offset) );
registerParameter( dynamic_cast<Parameter *>(&vertical_pattern) );
prop_scale.param_set_digits(3);
prop_scale.param_set_increments(0.01, 0.10);
}
LPESkeletalStrokes::~LPESkeletalStrokes()
{
}
Geom::Piecewise<Geom::D2<Geom::SBasis> >
LPESkeletalStrokes::doEffect_pwd2 (Geom::Piecewise<Geom::D2<Geom::SBasis> > & pwd2_in)
{
using namespace Geom;
/* Much credit should go to jfb and mgsloan of lib2geom development for the code below! */
SkelCopyType type = copytype.get_value();
Piecewise<D2<SBasis> > uskeleton = arc_length_parametrization(Piecewise<D2<SBasis> >(pwd2_in),2,.1);
uskeleton = remove_short_cuts(uskeleton,.01);
Piecewise<D2<SBasis> > n = rot90(derivative(uskeleton));
n = force_continuity(remove_short_cuts(n,.1));
D2<Piecewise<SBasis> > patternd2 = make_cuts_independant(pattern);
Piecewise<SBasis> x = vertical_pattern.get_value() ? Piecewise<SBasis>(patternd2[1]) : Piecewise<SBasis>(patternd2[0]);
Piecewise<SBasis> y = vertical_pattern.get_value() ? Piecewise<SBasis>(patternd2[0]) : Piecewise<SBasis>(patternd2[1]);
Interval pattBnds = bounds_exact(x);
x -= pattBnds.min();
Interval pattBndsY = bounds_exact(y);
y -= pattBndsY.middle();
int nbCopies = int(uskeleton.cuts.back()/pattBnds.extent());
double scaling = 1;
switch(type) {
case SSCT_REPEATED:
break;
case SSCT_SINGLE:
nbCopies = (nbCopies > 0) ? 1 : 0;
break;
case SSCT_SINGLE_STRETCHED:
nbCopies = 1;
scaling = uskeleton.cuts.back()/pattBnds.extent();
break;
case SSCT_REPEATED_STRETCHED:
scaling = uskeleton.cuts.back()/(((double)nbCopies)*pattBnds.extent());
break;
default:
return pwd2_in;
};
double pattWidth = pattBnds.extent() * scaling;
if (scaling != 1.0) {
x*=scaling;
}
if ( scale_y_rel.get_value() ) {
y*=(scaling*prop_scale);
} else {
if (prop_scale != 1.0) y *= prop_scale;
}
double offs = 0;
Piecewise<D2<SBasis> > output;
for (int i=0; i<nbCopies; i++){
output.concat(compose(uskeleton,x+offs)+y*compose(n,x+offs));
offs+=pattWidth;
}
return output;
}
} // namespace LivePathEffect
} /* namespace Inkscape */
/*
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 :