Exemple #1
0
Geom::Path half_outline_old(Geom::Path const& input, double width, double miter, Inkscape::LineJoinType join = Inkscape::JOIN_BEVEL)
{
    Geom::Path res;
    if (input.size() == 0) return res;

    Geom::Point tang1 = input[0].unitTangentAt(0);
    Geom::Point start = input.initialPoint() + tang1 * width;
    Geom::Path temp;
    Geom::Point tang[2];

    res.setStitching(true);
    temp.setStitching(true);

    res.start(start);

    // Do two curves at a time for efficiency, since the join function needs to know the outgoing curve as well
    const size_t k = (input.back_closed().isDegenerate() && input.closed())
            ?input.size_default()-1:input.size_default();
    for (size_t u = 0; u < k; u += 2) {
        temp.clear();

        offset_curve_old(temp, &input[u], width);

        // on the first run through, there isn't a join
        if (u == 0) {
            res.append(temp);
        } else {
            tangents_old(tang, input[u-1], input[u]);
            outline_join(res, temp, tang[0], tang[1], width, miter, join);
        }

        // odd number of paths
        if (u < k - 1) {
            temp.clear();
            offset_curve_old(temp, &input[u+1], width);
            tangents_old(tang, input[u], input[u+1]);
            outline_join(res, temp, tang[0], tang[1], width, miter, join);
        }
    }

    if (input.closed()) {
        Geom::Curve const &c1 = res.back();
        Geom::Curve const &c2 = res.front();
        temp.clear();
        temp.append(c1);
        Geom::Path temp2;
        temp2.append(c2);
        tangents_old(tang, input.back(), input.front());
        outline_join(temp, temp2, tang[0], tang[1], width, miter, join);
        res.erase(res.begin());
        res.erase_last();
        //
        res.append(temp);
        res.close();
    }

    return res;
}
Exemple #2
0
static void _circle(Geom::Point center, double radius, std::vector<Geom::Path> &path_out) {
    using namespace Geom;

    Geom::Path pb;

    D2<SBasis> B;
    Linear bo = Linear(0, 2 * M_PI);

    B[0] = cos(bo,4);
    B[1] = sin(bo,4);

    B = B * radius + center;

    pb.append(SBasisCurve(B));

    path_out.push_back(pb);
}
Exemple #3
0
void offset_curve_old(Geom::Path& res, Geom::Curve const* current, double width)
{
    double const tolerance = 0.0025;
    size_t levels = 8;

    if (current->isDegenerate()) return; // don't do anything

    // TODO: we can handle SVGEllipticalArc here as well, do that!

    if (Geom::BezierCurve const *b = dynamic_cast<Geom::BezierCurve const*>(current)) {
        size_t order = b->order();
        switch (order) {
        case 1:
            res.append(offset_line_old(static_cast<Geom::LineSegment const&>(*current), width));
            break;
        case 2: {
            Geom::QuadraticBezier const& q = static_cast<Geom::QuadraticBezier const&>(*current);
            offset_quadratic_old(res, q, width, tolerance, levels);
            break;
        }
        case 3: {
            Geom::CubicBezier const& cb = static_cast<Geom::CubicBezier const&>(*current);
            offset_cubic_old(res, cb, width, tolerance, levels);
            break;
        }
        default: {
            Geom::Path sbasis_path = Geom::cubicbezierpath_from_sbasis(current->toSBasis(), tolerance);
            for (size_t i = 0; i < sbasis_path.size(); ++i)
                offset_curve_old(res, &sbasis_path[i], width);
            break;
        }
        }
    } else {
        Geom::Path sbasis_path = Geom::cubicbezierpath_from_sbasis(current->toSBasis(), 0.1);
        for (size_t i = 0; i < sbasis_path.size(); ++i)
            offset_curve_old(res, &sbasis_path[i], width);
    }
}
Exemple #4
0
void offset_cubic_old(Geom::Path& p, Geom::CubicBezier const& bez, double width, double tol, size_t levels)
{
    using Geom::X;
    using Geom::Y;

    Geom::Point start_pos = bez.initialPoint();
    Geom::Point end_pos = bez.finalPoint();

    Geom::Point start_normal = Geom::rot90(bez.unitTangentAt(0));
    Geom::Point end_normal = -Geom::rot90(Geom::unitTangentAt(Geom::reverse(bez.toSBasis()), 0.));

    // offset the start and end control points out by the width
    Geom::Point start_new = start_pos + start_normal*width;
    Geom::Point end_new = end_pos + end_normal*width;

    // --------
    double start_rad, end_rad;
    double start_len, end_len; // tangent lengths
    get_cubic_data_old(bez, 0, start_len, start_rad);
    get_cubic_data_old(bez, 1, end_len, end_rad);

    double start_off = 1, end_off = 1;
    // correction of the lengths of the tangent to the offset
    if (!Geom::are_near(start_rad, 0))
        start_off += width / start_rad;
    if (!Geom::are_near(end_rad, 0))
        end_off += width / end_rad;
    start_off *= start_len;
    end_off *= end_len;
    // --------

    Geom::Point mid1_new = start_normal.ccw()*start_off;
    mid1_new = Geom::Point(start_new[X] + mid1_new[X]/3., start_new[Y] + mid1_new[Y]/3.);
    Geom::Point mid2_new = end_normal.ccw()*end_off;
    mid2_new = Geom::Point(end_new[X] - mid2_new[X]/3., end_new[Y] - mid2_new[Y]/3.);

    // create the estimate curve
    Geom::CubicBezier c = Geom::CubicBezier(start_new, mid1_new, mid2_new, end_new);

    // reached maximum recursive depth
    // don't bother with any more correction
    if (levels == 0) {
        p.append(c);
        return;
    }

    // check the tolerance for our estimate to be a parallel curve
    Geom::Point chk = c.pointAt(.5);
    Geom::Point req = bez.pointAt(.5) + Geom::rot90(bez.unitTangentAt(.5))*width; // required accuracy

    Geom::Point const diff = req - chk;
    double const err = Geom::dot(diff, diff);

    if (err < tol) {
        if (Geom::are_near(start_new, p.finalPoint())) {
            p.setFinal(start_new); // if it isn't near, we throw
        }

        // we're good, curve is accurate enough
        try {
          p.append(c);}
        catch (...) {

        }

        return;
    } else {
        // split the curve in two
        std::pair<Geom::CubicBezier, Geom::CubicBezier> s = bez.subdivide(.5);
        offset_cubic_old(p, s.first, width, tol, levels - 1);
        offset_cubic_old(p, s.second, width, tol, levels - 1);
    }
}
Exemple #5
0
Geom::Path Gear::path() {
    Geom::Path pb;

    // angle covered by a full tooth and fillet
    double tooth_rotation = 2.0 * tooth_thickness_angle();
    // angle covered by an involute
    double involute_advance = involute_intersect_angle(outer_radius()) - involute_intersect_angle(root_radius());
    // angle covered by the tooth tip
    double tip_advance = tooth_thickness_angle() - (2 * (involute_intersect_angle(outer_radius()) - involute_intersect_angle(pitch_radius())));
    // angle covered by the toothe root
    double root_advance = (tooth_rotation - tip_advance) - (2.0 * involute_advance);
    // begin drawing the involute at t if the root circle is larger than the base circle
    double involute_t = involute_swath_angle(root_radius())/involute_swath_angle(outer_radius());

    //rewind angle to start drawing from the leading edge of the tooth
    double first_tooth_angle = _angle - ((0.5 * tip_advance) + involute_advance);

    Geom::Point prev;
    for (int i=0; i < _number_of_teeth; i++)
    {
        double cursor = first_tooth_angle + (i * tooth_rotation);

        D2<SBasis> leading_I = compose(_involute(cursor, cursor + involute_swath_angle(outer_radius())), Linear(involute_t,1));
        if(i != 0) makeContinuous(leading_I, prev);
        pb.append(SBasisCurve(leading_I));
        cursor += involute_advance;
        prev = leading_I.at1();

        D2<SBasis> tip = _arc(cursor, cursor+tip_advance, outer_radius());
        makeContinuous(tip, prev);
        pb.append(SBasisCurve(tip));
        cursor += tip_advance;
        prev = tip.at1();

        cursor += involute_advance;
        D2<SBasis> trailing_I = compose(_involute(cursor, cursor - involute_swath_angle(outer_radius())), Linear(1,involute_t));
        makeContinuous(trailing_I, prev);
        pb.append(SBasisCurve(trailing_I));
        prev = trailing_I.at1();

        if (base_radius() > root_radius()) {
            Geom::Point leading_start = trailing_I.at1();
            Geom::Point leading_end = (root_radius() * unit_vector(leading_start - _centre)) + _centre;
            prev = leading_end;
            pb.appendNew<LineSegment>(leading_end);
        }

        D2<SBasis> root = _arc(cursor, cursor+root_advance, root_radius());
        makeContinuous(root, prev);
        pb.append(SBasisCurve(root));
        //cursor += root_advance;
        prev = root.at1();

        if (base_radius() > root_radius()) {
            Geom::Point trailing_start = root.at1();
            Geom::Point trailing_end = (base_radius() * unit_vector(trailing_start - _centre)) + _centre;
            pb.appendNew<LineSegment>(trailing_end);
            prev = trailing_end;
        }
    }

    return pb;
}
Exemple #6
0
    virtual void draw(cairo_t *cr, std::ostringstream *notify, int width, int height, bool save, std::ostringstream *timer_stream) {
        D2<SBasis2d> sb2;
        for(unsigned dim = 0; dim < 2; dim++) {
            sb2[dim].us = 2;
            sb2[dim].vs = 2;
            const int depth = sb2[dim].us*sb2[dim].vs;
            sb2[dim].resize(depth, Linear2d(0));
        }
        Geom::Point dir(1,-2);
        if(hand.pts.empty()) {
            for(unsigned vi = 0; vi < sb2[0].vs; vi++)
                for(unsigned ui = 0; ui < sb2[0].us; ui++)
                    for(unsigned iv = 0; iv < 2; iv++)
                        for(unsigned iu = 0; iu < 2; iu++)
                            hand.pts.push_back(Geom::Point((2*(iu+ui)/(2.*ui+1)+1)*width/4.,
                                                           (2*(iv+vi)/(2.*vi+1)+1)*width/4.));

        }

        for(int dim = 0; dim < 2; dim++) {
            Geom::Point dir(0,0);
            dir[dim] = 1;
            for(unsigned vi = 0; vi < sb2[dim].vs; vi++)
                for(unsigned ui = 0; ui < sb2[dim].us; ui++)
                    for(unsigned iv = 0; iv < 2; iv++)
                        for(unsigned iu = 0; iu < 2; iu++) {
                            unsigned corner = iu + 2*iv;
                            unsigned i = ui + vi*sb2[dim].us;
                            Geom::Point base((2*(iu+ui)/(2.*ui+1)+1)*width/4.,
                                             (2*(iv+vi)/(2.*vi+1)+1)*width/4.);
                            if(vi == 0 && ui == 0) {
                                base = Geom::Point(width/4., width/4.);
                            }
                            double dl = dot((hand.pts[corner+4*i] - base), dir)/dot(dir,dir);
                            sb2[dim][i][corner] = dl/(width/2)*pow(4.0,(double)ui+vi);
                        }
        }
        cairo_d2_sb2d(cr, sb2, dir*0.1, width);
        cairo_set_source_rgba (cr, 0., 0., 0, 0.5);
        cairo_stroke(cr);
        for(unsigned vi = 0; vi < v_subs; vi++) {
            double tv = vi * inv_v_subs;
            for(unsigned ui = 0; ui < u_subs; ui++) {
                double tu = ui * inv_u_subs;

                Geom::Path pb;
                D2<SBasis> B;
                D2<SBasis> tB;

                B[0] = Linear(tu-fudge, tu+fudge + inv_u_subs );
                B[1] = Linear(tv-fudge, tv-fudge);
                tB = compose_each(sb2, B);
                tB = tB*(width/2) + Geom::Point(width/4, width/4);
                pb.append(tB);

                B[0] = Linear(tu+fudge + inv_u_subs , tu+fudge + inv_u_subs);
                B[1] = Linear(tv-fudge,               tv+fudge + inv_v_subs);
                tB = compose_each(sb2, B);
                tB = tB*(width/2) + Geom::Point(width/4, width/4);
                pb.append(tB);

                B[0] = Linear(tu+fudge + inv_u_subs, tu-fudge);
                B[1] = Linear(tv+fudge + inv_v_subs, tv+fudge + inv_v_subs);
                tB = compose_each(sb2, B);
                tB = tB*(width/2) + Geom::Point(width/4, width/4);
                pb.append(tB);

                B[0] = Linear(tu-fudge,              tu-fudge);
                B[1] = Linear(tv+fudge + inv_v_subs, tv-fudge);
                tB = compose_each(sb2, B);
                tB = tB*(width/2) + Geom::Point(width/4, width/4);
                pb.append(tB);

                cairo_path(cr, pb);

                //std::cout <<  pb.peek().end() - pb.peek().begin() << std::endl;
                cairo_set_source_rgba (cr, tu, tv, 0, 1);
                cairo_fill(cr);
            }
        }
        //*notify << "bo = " << sb2.index(0,0);
        Toy::draw(cr, notify, width, height, save,timer_stream);
    }
Exemple #7
0
void Inkscape::ObjectSnapper::_snapPathsConstrained(IntermSnapResults &isr,
                                     SnapCandidatePoint const &p,
                                     SnapConstraint const &c,
                                     Geom::Point const &p_proj_on_constraint) const
{

    _collectPaths(p_proj_on_constraint, p.getSourceType(), p.getSourceNum() <= 0);

    // Now we can finally do the real snapping, using the paths collected above

    SPDesktop const *dt = _snapmanager->getDesktop();
    g_assert(dt != NULL);

    Geom::Point direction_vector = c.getDirection();
    if (!is_zero(direction_vector)) {
        direction_vector = Geom::unit_vector(direction_vector);
    }

    // The intersection point of the constraint line with any path, must lie within two points on the
    // SnapConstraint: p_min_on_cl and p_max_on_cl. The distance between those points is twice the snapping tolerance
    Geom::Point const p_min_on_cl = dt->dt2doc(p_proj_on_constraint - getSnapperTolerance() * direction_vector);
    Geom::Point const p_max_on_cl = dt->dt2doc(p_proj_on_constraint + getSnapperTolerance() * direction_vector);
    Geom::Coord tolerance = getSnapperTolerance();

    // PS: Because the paths we're about to snap to are all expressed relative to document coordinate system, we will have
    // to convert the snapper coordinates from the desktop coordinates to document coordinates

    std::vector<Geom::Path> constraint_path;
    if (c.isCircular()) {
        Geom::Circle constraint_circle(dt->dt2doc(c.getPoint()), c.getRadius());
        constraint_circle.getPath(constraint_path);
    } else {
        Geom::Path constraint_line;
        constraint_line.start(p_min_on_cl);
        constraint_line.appendNew<Geom::LineSegment>(p_max_on_cl);
        constraint_path.push_back(constraint_line);
    }
    // Length of constraint_path will always be one

    bool strict_snapping = _snapmanager->snapprefs.getStrictSnapping();

    // Find all intersections of the constrained path with the snap target candidates
    std::vector<Geom::Point> intersections;
    for (std::vector<SnapCandidatePath >::const_iterator k = _paths_to_snap_to->begin(); k != _paths_to_snap_to->end(); ++k) {
        if (k->path_vector && _allowSourceToSnapToTarget(p.getSourceType(), (*k).target_type, strict_snapping)) {
            // Do the intersection math
            Geom::CrossingSet cs = Geom::crossings(constraint_path, *(k->path_vector));
            // Store the results as intersection points
            unsigned int index = 0;
            for (Geom::CrossingSet::const_iterator i = cs.begin(); i != cs.end(); ++i) {
                if (index >= constraint_path.size()) {
                    break;
                }
                // Reconstruct and store the points of intersection
                for (Geom::Crossings::const_iterator m = (*i).begin(); m != (*i).end(); ++m) {
                    intersections.push_back(constraint_path[index].pointAt((*m).ta));
                }
                index++;
            }

            //Geom::crossings will not consider the closing segment apparently, so we'll handle that separately here
            //TODO: This should have been fixed in rev. #9859, which makes this workaround obsolete
            for(Geom::PathVector::iterator it_pv = k->path_vector->begin(); it_pv != k->path_vector->end(); ++it_pv) {
                if (it_pv->closed()) {
                    // Get the closing linesegment and convert it to a path
                    Geom::Path cls;
                    cls.close(false);
                    cls.append(it_pv->back_closed());
                    // Intersect that closing path with the constrained path
                    Geom::Crossings cs = Geom::crossings(constraint_path.front(), cls);
                    // Reconstruct and store the points of intersection
                    index = 0; // assuming the constraint path vector has only one path
                    for (Geom::Crossings::const_iterator m = cs.begin(); m != cs.end(); ++m) {
                        intersections.push_back(constraint_path[index].pointAt((*m).ta));
                    }
                }
            }

            // Convert the collected points of intersection to snapped points
            for (std::vector<Geom::Point>::iterator p_inters = intersections.begin(); p_inters != intersections.end(); ++p_inters) {
                // Convert to desktop coordinates
                (*p_inters) = dt->doc2dt(*p_inters);
                // Construct a snapped point
                Geom::Coord dist = Geom::L2(p.getPoint() - *p_inters);
                SnappedPoint s = SnappedPoint(*p_inters, p.getSourceType(), p.getSourceNum(), k->target_type, dist, getSnapperTolerance(), getSnapperAlwaysSnap(), true, k->target_bbox);;
                // Store the snapped point
                if (dist <= tolerance) { // If the intersection is within snapping range, then we might snap to it
                    isr.points.push_back(s);
                }
            }
        }
    }
}