/* * Copyright © 2002 University of Southern California * * Permission to use, copy, modify, distribute, and sell this software * and its documentation for any purpose is hereby granted without * fee, provided that the above copyright notice appear in all copies * and that both that copyright notice and this permission notice * appear in supporting documentation, and that the name of the * University of Southern California not be used in advertising or * publicity pertaining to distribution of the software without * specific, written prior permission. The University of Southern * California makes no representations about the suitability of this * software for any purpose. It is provided "as is" without express * or implied warranty. * * THE UNIVERSITY OF SOUTHERN CALIFORNIA DISCLAIMS ALL WARRANTIES WITH * REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL THE UNIVERSITY OF * SOUTHERN CALIFORNIA BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS * OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, * NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * * Author: Carl D. Worth */ #include "cairoint.h" static int _cairo_pen_vertices_needed (double radius, double tolerance, double expansion); static void _cairo_pen_compute_slopes (cairo_pen_t *pen); static cairo_status_t _cairo_pen_stroke_spline_half (cairo_pen_t *pen, cairo_spline_t *spline, cairo_direction_t dir, cairo_polygon_t *polygon); cairo_status_t _cairo_pen_init_empty (cairo_pen_t *pen) { pen->radius = 0; pen->tolerance = 0; pen->vertices = NULL; pen->num_vertices = 0; return CAIRO_STATUS_SUCCESS; } cairo_status_t _cairo_pen_init (cairo_pen_t *pen, double radius, cairo_gstate_t *gstate) { int i; int reflect; double det, expansion; if (pen->num_vertices) { /* XXX: It would be nice to notice that the pen is already properly constructed. However, this test would also have to account for possible changes in the transformation matrix. if (pen->radius == radius && pen->tolerance == tolerance) return CAIRO_STATUS_SUCCESS; */ _cairo_pen_fini (pen); } pen->radius = radius; pen->tolerance = gstate->tolerance; /* The determinant represents the area expansion factor of the transform. In the worst case, this is entirely in one dimension, which is what we assume here. */ _cairo_matrix_compute_determinant (&gstate->ctm, &det); if (det >= 0) { reflect = 0; expansion = det; } else { reflect = 1; expansion = -det; } pen->num_vertices = _cairo_pen_vertices_needed (radius, gstate->tolerance, expansion); /* number of vertices must be even */ if (pen->num_vertices % 2) pen->num_vertices++; pen->vertices = malloc (pen->num_vertices * sizeof (cairo_pen_vertex_t)); if (pen->vertices == NULL) { return CAIRO_STATUS_NO_MEMORY; } /* * Compute pen coordinates. To generate the right ellipse, compute points around * a circle in user space and transform them to device space. To get a consistent * orientation in device space, flip the pen if the transformation matrix * is reflecting */ for (i=0; i < pen->num_vertices; i++) { double theta = 2 * M_PI * i / (double) pen->num_vertices; double dx = radius * cos (reflect ? -theta : theta); double dy = radius * sin (reflect ? -theta : theta); cairo_pen_vertex_t *v = &pen->vertices[i]; cairo_matrix_transform_distance (&gstate->ctm, &dx, &dy); v->point.x = _cairo_fixed_from_double (dx); v->point.y = _cairo_fixed_from_double (dy); } _cairo_pen_compute_slopes (pen); return CAIRO_STATUS_SUCCESS; } void _cairo_pen_fini (cairo_pen_t *pen) { free (pen->vertices); pen->vertices = NULL; _cairo_pen_init_empty (pen); } cairo_status_t _cairo_pen_init_copy (cairo_pen_t *pen, cairo_pen_t *other) { *pen = *other; if (pen->num_vertices) { pen->vertices = malloc (pen->num_vertices * sizeof (cairo_pen_vertex_t)); if (pen->vertices == NULL) { return CAIRO_STATUS_NO_MEMORY; } memcpy (pen->vertices, other->vertices, pen->num_vertices * sizeof (cairo_pen_vertex_t)); } return CAIRO_STATUS_SUCCESS; } cairo_status_t _cairo_pen_add_points (cairo_pen_t *pen, cairo_point_t *point, int num_points) { cairo_pen_vertex_t *vertices; int num_vertices; int i; num_vertices = pen->num_vertices + num_points; vertices = realloc (pen->vertices, num_vertices * sizeof (cairo_pen_vertex_t)); if (vertices == NULL) return CAIRO_STATUS_NO_MEMORY; pen->vertices = vertices; pen->num_vertices = num_vertices; /* initialize new vertices */ for (i=0; i < num_points; i++) pen->vertices[pen->num_vertices-num_points+i].point = point[i]; _cairo_hull_compute (pen->vertices, &pen->num_vertices); _cairo_pen_compute_slopes (pen); return CAIRO_STATUS_SUCCESS; } static int _cairo_pen_vertices_needed (double radius, double tolerance, double expansion) { double theta; if (tolerance > expansion*radius) { return 4; } theta = acos (1 - tolerance/(expansion * radius)); return ceil (M_PI / theta); } static void _cairo_pen_compute_slopes (cairo_pen_t *pen) { int i, i_prev; cairo_pen_vertex_t *prev, *v, *next; for (i=0, i_prev = pen->num_vertices - 1; i < pen->num_vertices; i_prev = i++) { prev = &pen->vertices[i_prev]; v = &pen->vertices[i]; next = &pen->vertices[(i + 1) % pen->num_vertices]; _cairo_slope_init (&v->slope_cw, &prev->point, &v->point); _cairo_slope_init (&v->slope_ccw, &v->point, &next->point); } } /* Find active pen vertex for clockwise edge of stroke at the given slope. * * NOTE: The behavior of this function is sensitive to the sense of * the inequality within _cairo_slope_clockwise/_cairo_slope_counter_clockwise. * * The issue is that the slope_ccw member of one pen vertex will be * equivalent to the slope_cw member of the next pen vertex in a * counterclockwise order. However, for this function, we care * strongly about which vertex is returned. */ cairo_status_t _cairo_pen_find_active_cw_vertex_index (cairo_pen_t *pen, cairo_slope_t *slope, int *active) { int i; for (i=0; i < pen->num_vertices; i++) { if (_cairo_slope_clockwise (slope, &pen->vertices[i].slope_ccw) && _cairo_slope_counter_clockwise (slope, &pen->vertices[i].slope_cw)) break; } *active = i; return CAIRO_STATUS_SUCCESS; } /* Find active pen vertex for counterclockwise edge of stroke at the given slope. * * NOTE: The behavior of this function is sensitive to the sense of * the inequality within _cairo_slope_clockwise/_cairo_slope_counter_clockwise. */ cairo_status_t _cairo_pen_find_active_ccw_vertex_index (cairo_pen_t *pen, cairo_slope_t *slope, int *active) { int i; cairo_slope_t slope_reverse; slope_reverse = *slope; slope_reverse.dx = -slope_reverse.dx; slope_reverse.dy = -slope_reverse.dy; for (i=pen->num_vertices-1; i >= 0; i--) { if (_cairo_slope_counter_clockwise (&pen->vertices[i].slope_ccw, &slope_reverse) && _cairo_slope_clockwise (&pen->vertices[i].slope_cw, &slope_reverse)) break; } *active = i; return CAIRO_STATUS_SUCCESS; } static cairo_status_t _cairo_pen_stroke_spline_half (cairo_pen_t *pen, cairo_spline_t *spline, cairo_direction_t dir, cairo_polygon_t *polygon) { int i; cairo_status_t status; int start, stop, step; int active = 0; cairo_point_t hull_point; cairo_slope_t slope, initial_slope, final_slope; cairo_point_t *point = spline->points; int num_points = spline->num_points; if (dir == CAIRO_DIRECTION_FORWARD) { start = 0; stop = num_points; step = 1; initial_slope = spline->initial_slope; final_slope = spline->final_slope; } else { start = num_points - 1; stop = -1; step = -1; initial_slope = spline->final_slope; initial_slope.dx = -initial_slope.dx; initial_slope.dy = -initial_slope.dy; final_slope = spline->initial_slope; final_slope.dx = -final_slope.dx; final_slope.dy = -final_slope.dy; } _cairo_pen_find_active_cw_vertex_index (pen, &initial_slope, &active); i = start; while (i != stop) { hull_point.x = point[i].x + pen->vertices[active].point.x; hull_point.y = point[i].y + pen->vertices[active].point.y; status = _cairo_polygon_line_to (polygon, &hull_point); if (status) return status; if (i + step == stop) slope = final_slope; else _cairo_slope_init (&slope, &point[i], &point[i+step]); if (_cairo_slope_counter_clockwise (&slope, &pen->vertices[active].slope_ccw)) { if (++active == pen->num_vertices) active = 0; } else if (_cairo_slope_clockwise (&slope, &pen->vertices[active].slope_cw)) { if (--active == -1) active = pen->num_vertices - 1; } else { i += step; } } return CAIRO_STATUS_SUCCESS; } /* Compute outline of a given spline using the pen. The trapezoids needed to fill that outline will be added to traps */ cairo_status_t _cairo_pen_stroke_spline (cairo_pen_t *pen, cairo_spline_t *spline, double tolerance, cairo_traps_t *traps) { cairo_status_t status; cairo_polygon_t polygon; /* If the line width is so small that the pen is reduced to a single point, then we have nothing to do. */ if (pen->num_vertices <= 1) return CAIRO_STATUS_SUCCESS; _cairo_polygon_init (&polygon); status = _cairo_spline_decompose (spline, tolerance); if (status) return status; status = _cairo_pen_stroke_spline_half (pen, spline, CAIRO_DIRECTION_FORWARD, &polygon); if (status) return status; status = _cairo_pen_stroke_spline_half (pen, spline, CAIRO_DIRECTION_REVERSE, &polygon); if (status) return status; _cairo_polygon_close (&polygon); _cairo_traps_tessellate_polygon (traps, &polygon, CAIRO_FILL_RULE_WINDING); _cairo_polygon_fini (&polygon); return CAIRO_STATUS_SUCCESS; }