/* * Copyright © 2004 Carl Worth * Copyright © 2006 Red Hat, Inc. * Copyright © 2008 Chris Wilson * Copyright © 2011 Intel Corporation * * This library is free software; you can redistribute it and/or * modify it either under the terms of the GNU Lesser General Public * License version 2.1 as published by the Free Software Foundation * (the "LGPL") or, at your option, under the terms of the Mozilla * Public License Version 1.1 (the "MPL"). If you do not alter this * notice, a recipient may use your version of this file under either * the MPL or the LGPL. * * You should have received a copy of the LGPL along with this library * in the file COPYING-LGPL-2.1; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Suite 500, Boston, MA 02110-1335, USA * You should have received a copy of the MPL along with this library * in the file COPYING-MPL-1.1 * * The contents of this file are subject to the Mozilla Public License * Version 1.1 (the "License"); you may not use this file except in * compliance with the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY * OF ANY KIND, either express or implied. See the LGPL or the MPL for * the specific language governing rights and limitations. * * The Original Code is the cairo graphics library. * * The Initial Developer of the Original Code is Carl Worth * * Contributor(s): * Carl D. Worth * Chris Wilson */ #include "cairoint.h" #include "cairo-error-private.h" #include "cairo-freelist-private.h" #include "cairo-combsort-inline.h" #include "cairo-contour-inline.h" #include "cairo-contour-private.h" void _cairo_contour_init (cairo_contour_t *contour, int direction) { contour->direction = direction; contour->chain.points = contour->embedded_points; contour->chain.next = NULL; contour->chain.num_points = 0; contour->chain.size_points = ARRAY_LENGTH (contour->embedded_points); contour->tail = &contour->chain; } cairo_int_status_t __cairo_contour_add_point (cairo_contour_t *contour, const cairo_point_t *point) { cairo_contour_chain_t *tail = contour->tail; cairo_contour_chain_t *next; assert (tail->next == NULL); next = _cairo_malloc_ab_plus_c (tail->size_points*2, sizeof (cairo_point_t), sizeof (cairo_contour_chain_t)); if (unlikely (next == NULL)) return _cairo_error (CAIRO_STATUS_NO_MEMORY); next->size_points = tail->size_points*2; next->num_points = 1; next->points = (cairo_point_t *)(next+1); next->next = NULL; tail->next = next; contour->tail = next; next->points[0] = *point; return CAIRO_INT_STATUS_SUCCESS; } static void first_inc (cairo_contour_t *contour, cairo_point_t **p, cairo_contour_chain_t **chain) { if (*p == (*chain)->points + (*chain)->num_points) { assert ((*chain)->next); *chain = (*chain)->next; *p = &(*chain)->points[0]; } else ++*p; } static void last_dec (cairo_contour_t *contour, cairo_point_t **p, cairo_contour_chain_t **chain) { if (*p == (*chain)->points) { cairo_contour_chain_t *prev; assert (*chain != &contour->chain); for (prev = &contour->chain; prev->next != *chain; prev = prev->next) ; *chain = prev; *p = &(*chain)->points[(*chain)->num_points-1]; } else --*p; } void _cairo_contour_reverse (cairo_contour_t *contour) { cairo_contour_chain_t *first_chain, *last_chain; cairo_point_t *first, *last; contour->direction = -contour->direction; if (contour->chain.num_points <= 1) return; first_chain = &contour->chain; last_chain = contour->tail; first = &first_chain->points[0]; last = &last_chain->points[last_chain->num_points-1]; while (first != last) { cairo_point_t p; p = *first; *first = *last; *last = p; first_inc (contour, &first, &first_chain); last_dec (contour, &last, &last_chain); } } cairo_int_status_t _cairo_contour_add (cairo_contour_t *dst, const cairo_contour_t *src) { const cairo_contour_chain_t *chain; cairo_int_status_t status; int i; for (chain = &src->chain; chain; chain = chain->next) { for (i = 0; i < chain->num_points; i++) { status = _cairo_contour_add_point (dst, &chain->points[i]); if (unlikely (status)) return status; } } return CAIRO_INT_STATUS_SUCCESS; } static inline cairo_bool_t iter_next (cairo_contour_iter_t *iter) { if (iter->point == &iter->chain->points[iter->chain->size_points-1]) { iter->chain = iter->chain->next; if (iter->chain == NULL) return FALSE; iter->point = &iter->chain->points[0]; return TRUE; } else { iter->point++; return TRUE; } } static cairo_bool_t iter_equal (const cairo_contour_iter_t *i1, const cairo_contour_iter_t *i2) { return i1->chain == i2->chain && i1->point == i2->point; } static void iter_init (cairo_contour_iter_t *iter, cairo_contour_t *contour) { iter->chain = &contour->chain; iter->point = &contour->chain.points[0]; } static void iter_init_last (cairo_contour_iter_t *iter, cairo_contour_t *contour) { iter->chain = contour->tail; iter->point = &contour->tail->points[contour->tail->num_points-1]; } static const cairo_contour_chain_t *prev_const_chain(const cairo_contour_t *contour, const cairo_contour_chain_t *chain) { const cairo_contour_chain_t *prev; if (chain == &contour->chain) return NULL; for (prev = &contour->chain; prev->next != chain; prev = prev->next) ; return prev; } cairo_int_status_t _cairo_contour_add_reversed (cairo_contour_t *dst, const cairo_contour_t *src) { const cairo_contour_chain_t *last; cairo_int_status_t status; int i; if (src->chain.num_points == 0) return CAIRO_INT_STATUS_SUCCESS; for (last = src->tail; last; last = prev_const_chain (src, last)) { for (i = last->num_points-1; i >= 0; i--) { status = _cairo_contour_add_point (dst, &last->points[i]); if (unlikely (status)) return status; } } return CAIRO_INT_STATUS_SUCCESS; } static cairo_uint64_t point_distance_sq (const cairo_point_t *p1, const cairo_point_t *p2) { int32_t dx = p1->x - p2->x; int32_t dy = p1->y - p2->y; return _cairo_int32x32_64_mul (dx, dx) + _cairo_int32x32_64_mul (dy, dy); } #define DELETED(p) ((p)->x == INT_MIN && (p)->y == INT_MAX) #define MARK_DELETED(p) ((p)->x = INT_MIN, (p)->y = INT_MAX) static cairo_bool_t _cairo_contour_simplify_chain (cairo_contour_t *contour, const double tolerance, const cairo_contour_iter_t *first, const cairo_contour_iter_t *last) { cairo_contour_iter_t iter, furthest; uint64_t max_error; int x0, y0; int nx, ny; int count; iter = *first; iter_next (&iter); if (iter_equal (&iter, last)) return FALSE; x0 = first->point->x; y0 = first->point->y; nx = last->point->y - y0; ny = x0 - last->point->x; count = 0; max_error = 0; do { cairo_point_t *p = iter.point; if (! DELETED(p)) { uint64_t d = (uint64_t)nx * (x0 - p->x) + (uint64_t)ny * (y0 - p->y); if (d * d > max_error) { max_error = d * d; furthest = iter; } count++; } iter_next (&iter); } while (! iter_equal (&iter, last)); if (count == 0) return FALSE; if (max_error > tolerance * ((uint64_t)nx * nx + (uint64_t)ny * ny)) { cairo_bool_t simplified; simplified = FALSE; simplified |= _cairo_contour_simplify_chain (contour, tolerance, first, &furthest); simplified |= _cairo_contour_simplify_chain (contour, tolerance, &furthest, last); return simplified; } else { iter = *first; iter_next (&iter); do { MARK_DELETED (iter.point); iter_next (&iter); } while (! iter_equal (&iter, last)); return TRUE; } } void _cairo_contour_simplify (cairo_contour_t *contour, double tolerance) { cairo_contour_chain_t *chain; cairo_point_t *last = NULL; cairo_contour_iter_t iter, furthest; cairo_bool_t simplified; uint64_t max = 0; int i; if (contour->chain.num_points <= 2) return; tolerance = tolerance * CAIRO_FIXED_ONE; tolerance *= tolerance; /* stage 1: vertex reduction */ for (chain = &contour->chain; chain; chain = chain->next) { for (i = 0; i < chain->num_points; i++) { if (last == NULL || point_distance_sq (last, &chain->points[i]) > tolerance) { last = &chain->points[i]; } else { MARK_DELETED (&chain->points[i]); } } } /* stage2: polygon simplification using Douglas-Peucker */ do { last = &contour->chain.points[0]; iter_init (&furthest, contour); max = 0; for (chain = &contour->chain; chain; chain = chain->next) { for (i = 0; i < chain->num_points; i++) { uint64_t d; if (DELETED (&chain->points[i])) continue; d = point_distance_sq (last, &chain->points[i]); if (d > max) { furthest.chain = chain; furthest.point = &chain->points[i]; max = d; } } } assert (max); simplified = FALSE; iter_init (&iter, contour); simplified |= _cairo_contour_simplify_chain (contour, tolerance, &iter, &furthest); iter_init_last (&iter, contour); if (! iter_equal (&furthest, &iter)) simplified |= _cairo_contour_simplify_chain (contour, tolerance, &furthest, &iter); } while (simplified); iter_init (&iter, contour); for (chain = &contour->chain; chain; chain = chain->next) { int num_points = chain->num_points; chain->num_points = 0; for (i = 0; i < num_points; i++) { if (! DELETED(&chain->points[i])) { if (iter.point != &chain->points[i]) *iter.point = chain->points[i]; iter.chain->num_points++; iter_next (&iter); } } } if (iter.chain) { cairo_contour_chain_t *next; for (chain = iter.chain->next; chain; chain = next) { next = chain->next; free (chain); } iter.chain->next = NULL; contour->tail = iter.chain; } } void _cairo_contour_reset (cairo_contour_t *contour) { _cairo_contour_fini (contour); _cairo_contour_init (contour, contour->direction); } void _cairo_contour_fini (cairo_contour_t *contour) { cairo_contour_chain_t *chain, *next; for (chain = contour->chain.next; chain; chain = next) { next = chain->next; free (chain); } } void _cairo_debug_print_contour (FILE *file, cairo_contour_t *contour) { cairo_contour_chain_t *chain; int num_points, size_points; int i; num_points = 0; size_points = 0; for (chain = &contour->chain; chain; chain = chain->next) { num_points += chain->num_points; size_points += chain->size_points; } fprintf (file, "contour: direction=%d, num_points=%d / %d\n", contour->direction, num_points, size_points); num_points = 0; for (chain = &contour->chain; chain; chain = chain->next) { for (i = 0; i < chain->num_points; i++) { fprintf (file, " [%d] = (%f, %f)\n", num_points++, _cairo_fixed_to_double (chain->points[i].x), _cairo_fixed_to_double (chain->points[i].y)); } } } void __cairo_contour_remove_last_chain (cairo_contour_t *contour) { cairo_contour_chain_t *chain; if (contour->tail == &contour->chain) return; for (chain = &contour->chain; chain->next != contour->tail; chain = chain->next) ; free (contour->tail); contour->tail = chain; chain->next = NULL; }