forked from KolibriOS/kolibrios
754f9336f0
git-svn-id: svn://kolibrios.org@4349 a494cfbc-eb01-0410-851d-a64ba20cac60
476 lines
13 KiB
C
476 lines
13 KiB
C
/* cairo - a vector graphics library with display and print output
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*
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* Copyright © 2002 University of Southern California
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* Copyright © 2008 Chris Wilson
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*
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* This library is free software; you can redistribute it and/or
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* modify it either under the terms of the GNU Lesser General Public
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* License version 2.1 as published by the Free Software Foundation
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* (the "LGPL") or, at your option, under the terms of the Mozilla
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* Public License Version 1.1 (the "MPL"). If you do not alter this
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* notice, a recipient may use your version of this file under either
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* the MPL or the LGPL.
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*
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* You should have received a copy of the LGPL along with this library
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* in the file COPYING-LGPL-2.1; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Suite 500, Boston, MA 02110-1335, USA
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* You should have received a copy of the MPL along with this library
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* in the file COPYING-MPL-1.1
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*
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* The contents of this file are subject to the Mozilla Public License
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* Version 1.1 (the "License"); you may not use this file except in
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* compliance with the License. You may obtain a copy of the License at
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* http://www.mozilla.org/MPL/
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*
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* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY
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* OF ANY KIND, either express or implied. See the LGPL or the MPL for
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* the specific language governing rights and limitations.
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*
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* The Original Code is the cairo graphics library.
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*
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* The Initial Developer of the Original Code is University of Southern
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* California.
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*
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* Contributor(s):
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* Carl D. Worth <cworth@cworth.org>
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* Chris Wilson <chris@chris-wilson.co.uk>
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*/
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#include "cairoint.h"
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#include "cairo-error-private.h"
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#include "cairo-slope-private.h"
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static void
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_cairo_pen_compute_slopes (cairo_pen_t *pen);
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cairo_status_t
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_cairo_pen_init (cairo_pen_t *pen,
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double radius,
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double tolerance,
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const cairo_matrix_t *ctm)
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{
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int i;
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int reflect;
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if (CAIRO_INJECT_FAULT ())
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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VG (VALGRIND_MAKE_MEM_UNDEFINED (pen, sizeof (cairo_pen_t)));
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pen->radius = radius;
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pen->tolerance = tolerance;
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reflect = _cairo_matrix_compute_determinant (ctm) < 0.;
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pen->num_vertices = _cairo_pen_vertices_needed (tolerance,
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radius,
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ctm);
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if (pen->num_vertices > ARRAY_LENGTH (pen->vertices_embedded)) {
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pen->vertices = _cairo_malloc_ab (pen->num_vertices,
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sizeof (cairo_pen_vertex_t));
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if (unlikely (pen->vertices == NULL))
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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} else {
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pen->vertices = pen->vertices_embedded;
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}
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/*
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* Compute pen coordinates. To generate the right ellipse, compute points around
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* a circle in user space and transform them to device space. To get a consistent
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* orientation in device space, flip the pen if the transformation matrix
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* is reflecting
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*/
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for (i=0; i < pen->num_vertices; i++) {
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cairo_pen_vertex_t *v = &pen->vertices[i];
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double theta = 2 * M_PI * i / (double) pen->num_vertices, dx, dy;
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if (reflect)
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theta = -theta;
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dx = radius * cos (theta);
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dy = radius * sin (theta);
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cairo_matrix_transform_distance (ctm, &dx, &dy);
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v->point.x = _cairo_fixed_from_double (dx);
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v->point.y = _cairo_fixed_from_double (dy);
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}
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_cairo_pen_compute_slopes (pen);
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return CAIRO_STATUS_SUCCESS;
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}
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void
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_cairo_pen_fini (cairo_pen_t *pen)
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{
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if (pen->vertices != pen->vertices_embedded)
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free (pen->vertices);
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VG (VALGRIND_MAKE_MEM_NOACCESS (pen, sizeof (cairo_pen_t)));
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}
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cairo_status_t
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_cairo_pen_init_copy (cairo_pen_t *pen, const cairo_pen_t *other)
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{
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VG (VALGRIND_MAKE_MEM_UNDEFINED (pen, sizeof (cairo_pen_t)));
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*pen = *other;
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if (CAIRO_INJECT_FAULT ())
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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pen->vertices = pen->vertices_embedded;
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if (pen->num_vertices) {
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if (pen->num_vertices > ARRAY_LENGTH (pen->vertices_embedded)) {
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pen->vertices = _cairo_malloc_ab (pen->num_vertices,
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sizeof (cairo_pen_vertex_t));
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if (unlikely (pen->vertices == NULL))
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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}
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memcpy (pen->vertices, other->vertices,
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pen->num_vertices * sizeof (cairo_pen_vertex_t));
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}
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return CAIRO_STATUS_SUCCESS;
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}
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cairo_status_t
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_cairo_pen_add_points (cairo_pen_t *pen, cairo_point_t *point, int num_points)
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{
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cairo_status_t status;
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int num_vertices;
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int i;
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if (CAIRO_INJECT_FAULT ())
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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num_vertices = pen->num_vertices + num_points;
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if (num_vertices > ARRAY_LENGTH (pen->vertices_embedded) ||
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pen->vertices != pen->vertices_embedded)
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{
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cairo_pen_vertex_t *vertices;
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if (pen->vertices == pen->vertices_embedded) {
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vertices = _cairo_malloc_ab (num_vertices,
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sizeof (cairo_pen_vertex_t));
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if (unlikely (vertices == NULL))
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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memcpy (vertices, pen->vertices,
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pen->num_vertices * sizeof (cairo_pen_vertex_t));
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} else {
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vertices = _cairo_realloc_ab (pen->vertices,
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num_vertices,
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sizeof (cairo_pen_vertex_t));
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if (unlikely (vertices == NULL))
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return _cairo_error (CAIRO_STATUS_NO_MEMORY);
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}
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pen->vertices = vertices;
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}
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pen->num_vertices = num_vertices;
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/* initialize new vertices */
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for (i=0; i < num_points; i++)
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pen->vertices[pen->num_vertices-num_points+i].point = point[i];
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status = _cairo_hull_compute (pen->vertices, &pen->num_vertices);
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if (unlikely (status))
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return status;
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_cairo_pen_compute_slopes (pen);
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return CAIRO_STATUS_SUCCESS;
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}
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/*
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The circular pen in user space is transformed into an ellipse in
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device space.
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We construct the pen by computing points along the circumference
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using equally spaced angles.
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We show that this approximation to the ellipse has maximum error at the
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major axis of the ellipse.
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Set
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M = major axis length
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m = minor axis length
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Align 'M' along the X axis and 'm' along the Y axis and draw
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an ellipse parameterized by angle 't':
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x = M cos t y = m sin t
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Perturb t by ± d and compute two new points (x+,y+), (x-,y-).
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The distance from the average of these two points to (x,y) represents
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the maximum error in approximating the ellipse with a polygon formed
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from vertices 2∆ radians apart.
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x+ = M cos (t+∆) y+ = m sin (t+∆)
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x- = M cos (t-∆) y- = m sin (t-∆)
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Now compute the approximation error, E:
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Ex = (x - (x+ + x-) / 2)
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Ex = (M cos(t) - (Mcos(t+∆) + Mcos(t-∆))/2)
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= M (cos(t) - (cos(t)cos(∆) + sin(t)sin(∆) +
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cos(t)cos(∆) - sin(t)sin(∆))/2)
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= M(cos(t) - cos(t)cos(∆))
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= M cos(t) (1 - cos(∆))
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Ey = y - (y+ - y-) / 2
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= m sin (t) - (m sin(t+∆) + m sin(t-∆)) / 2
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= m (sin(t) - (sin(t)cos(∆) + cos(t)sin(∆) +
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sin(t)cos(∆) - cos(t)sin(∆))/2)
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= m (sin(t) - sin(t)cos(∆))
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= m sin(t) (1 - cos(∆))
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E² = Ex² + Ey²
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= (M cos(t) (1 - cos (∆)))² + (m sin(t) (1-cos(∆)))²
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= (1 - cos(∆))² (M² cos²(t) + m² sin²(t))
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= (1 - cos(∆))² ((m² + M² - m²) cos² (t) + m² sin²(t))
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= (1 - cos(∆))² (M² - m²) cos² (t) + (1 - cos(∆))² m²
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Find the extremum by differentiation wrt t and setting that to zero
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∂(E²)/∂(t) = (1-cos(∆))² (M² - m²) (-2 cos(t) sin(t))
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0 = 2 cos (t) sin (t)
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0 = sin (2t)
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t = nπ
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Which is to say that the maximum and minimum errors occur on the
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axes of the ellipse at 0 and π radians:
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E²(0) = (1-cos(∆))² (M² - m²) + (1-cos(∆))² m²
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= (1-cos(∆))² M²
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E²(π) = (1-cos(∆))² m²
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maximum error = M (1-cos(∆))
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minimum error = m (1-cos(∆))
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We must make maximum error ≤ tolerance, so compute the ∆ needed:
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tolerance = M (1-cos(∆))
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tolerance / M = 1 - cos (∆)
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cos(∆) = 1 - tolerance/M
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∆ = acos (1 - tolerance / M);
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Remembering that ∆ is half of our angle between vertices,
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the number of vertices is then
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vertices = ceil(2π/2∆).
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= ceil(π/∆).
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Note that this also equation works for M == m (a circle) as it
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doesn't matter where on the circle the error is computed.
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*/
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int
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_cairo_pen_vertices_needed (double tolerance,
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double radius,
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const cairo_matrix_t *matrix)
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{
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/*
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* the pen is a circle that gets transformed to an ellipse by matrix.
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* compute major axis length for a pen with the specified radius.
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* we don't need the minor axis length.
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*/
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double major_axis = _cairo_matrix_transformed_circle_major_axis (matrix,
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radius);
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int num_vertices;
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if (tolerance >= 4*major_axis) { /* XXX relaxed from 2*major for inkscape */
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num_vertices = 1;
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} else if (tolerance >= major_axis) {
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num_vertices = 4;
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} else {
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num_vertices = ceil (2*M_PI / acos (1 - tolerance / major_axis));
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/* number of vertices must be even */
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if (num_vertices % 2)
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num_vertices++;
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/* And we must always have at least 4 vertices. */
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if (num_vertices < 4)
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num_vertices = 4;
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}
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return num_vertices;
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}
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static void
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_cairo_pen_compute_slopes (cairo_pen_t *pen)
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{
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int i, i_prev;
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cairo_pen_vertex_t *prev, *v, *next;
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for (i=0, i_prev = pen->num_vertices - 1;
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i < pen->num_vertices;
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i_prev = i++) {
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prev = &pen->vertices[i_prev];
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v = &pen->vertices[i];
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next = &pen->vertices[(i + 1) % pen->num_vertices];
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_cairo_slope_init (&v->slope_cw, &prev->point, &v->point);
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_cairo_slope_init (&v->slope_ccw, &v->point, &next->point);
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}
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}
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/*
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* Find active pen vertex for clockwise edge of stroke at the given slope.
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*
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* The strictness of the inequalities here is delicate. The issue is
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* that the slope_ccw member of one pen vertex will be equivalent to
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* the slope_cw member of the next pen vertex in a counterclockwise
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* order. However, for this function, we care strongly about which
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* vertex is returned.
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*
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* [I think the "care strongly" above has to do with ensuring that the
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* pen's "extra points" from the spline's initial and final slopes are
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* properly found when beginning the spline stroking.]
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*/
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int
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_cairo_pen_find_active_cw_vertex_index (const cairo_pen_t *pen,
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const cairo_slope_t *slope)
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{
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int i;
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for (i=0; i < pen->num_vertices; i++) {
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if ((_cairo_slope_compare (slope, &pen->vertices[i].slope_ccw) < 0) &&
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(_cairo_slope_compare (slope, &pen->vertices[i].slope_cw) >= 0))
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break;
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}
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/* If the desired slope cannot be found between any of the pen
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* vertices, then we must have a degenerate pen, (such as a pen
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* that's been transformed to a line). In that case, we consider
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* the first pen vertex as the appropriate clockwise vertex.
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*/
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if (i == pen->num_vertices)
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i = 0;
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return i;
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}
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/* Find active pen vertex for counterclockwise edge of stroke at the given slope.
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*
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* Note: See the comments for _cairo_pen_find_active_cw_vertex_index
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* for some details about the strictness of the inequalities here.
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*/
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int
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_cairo_pen_find_active_ccw_vertex_index (const cairo_pen_t *pen,
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const cairo_slope_t *slope)
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{
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cairo_slope_t slope_reverse;
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int i;
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slope_reverse = *slope;
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slope_reverse.dx = -slope_reverse.dx;
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slope_reverse.dy = -slope_reverse.dy;
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for (i=pen->num_vertices-1; i >= 0; i--) {
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if ((_cairo_slope_compare (&pen->vertices[i].slope_ccw, &slope_reverse) >= 0) &&
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(_cairo_slope_compare (&pen->vertices[i].slope_cw, &slope_reverse) < 0))
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break;
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}
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/* If the desired slope cannot be found between any of the pen
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* vertices, then we must have a degenerate pen, (such as a pen
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* that's been transformed to a line). In that case, we consider
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* the last pen vertex as the appropriate counterclockwise vertex.
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*/
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if (i < 0)
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i = pen->num_vertices - 1;
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return i;
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}
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void
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_cairo_pen_find_active_cw_vertices (const cairo_pen_t *pen,
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const cairo_slope_t *in,
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const cairo_slope_t *out,
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int *start, int *stop)
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{
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int lo = 0, hi = pen->num_vertices;
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int i;
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i = (lo + hi) >> 1;
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do {
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if (_cairo_slope_compare (&pen->vertices[i].slope_cw, in) < 0)
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lo = i;
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else
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hi = i;
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i = (lo + hi) >> 1;
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} while (hi - lo > 1);
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if (_cairo_slope_compare (&pen->vertices[i].slope_cw, in) < 0)
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if (++i == pen->num_vertices)
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i = 0;
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*start = i;
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if (_cairo_slope_compare (out, &pen->vertices[i].slope_ccw) >= 0) {
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lo = i;
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hi = i + pen->num_vertices;
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i = (lo + hi) >> 1;
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do {
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int j = i;
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if (j >= pen->num_vertices)
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j -= pen->num_vertices;
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if (_cairo_slope_compare (&pen->vertices[j].slope_cw, out) > 0)
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hi = i;
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else
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lo = i;
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i = (lo + hi) >> 1;
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} while (hi - lo > 1);
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if (i >= pen->num_vertices)
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i -= pen->num_vertices;
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}
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*stop = i;
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}
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void
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_cairo_pen_find_active_ccw_vertices (const cairo_pen_t *pen,
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const cairo_slope_t *in,
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const cairo_slope_t *out,
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int *start, int *stop)
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{
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int lo = 0, hi = pen->num_vertices;
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int i;
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i = (lo + hi) >> 1;
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do {
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if (_cairo_slope_compare (in, &pen->vertices[i].slope_ccw) < 0)
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lo = i;
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else
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hi = i;
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i = (lo + hi) >> 1;
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} while (hi - lo > 1);
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if (_cairo_slope_compare (in, &pen->vertices[i].slope_ccw) < 0)
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if (++i == pen->num_vertices)
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i = 0;
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*start = i;
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if (_cairo_slope_compare (&pen->vertices[i].slope_cw, out) <= 0) {
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lo = i;
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hi = i + pen->num_vertices;
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i = (lo + hi) >> 1;
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do {
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int j = i;
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if (j >= pen->num_vertices)
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j -= pen->num_vertices;
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if (_cairo_slope_compare (out, &pen->vertices[j].slope_ccw) > 0)
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hi = i;
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else
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lo = i;
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i = (lo + hi) >> 1;
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} while (hi - lo > 1);
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if (i >= pen->num_vertices)
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i -= pen->num_vertices;
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}
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*stop = i;
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}
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