/* -*- Mode: c; tab-width: 8; c-basic-offset: 4; indent-tabs-mode: t; -*- */ /* cairo - a vector graphics library with display and print output * * Copyright © 2002 University of Southern California * Copyright © 2005 Red Hat, Inc. * Copyright © 2009 Chris Wilson * * 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 University of Southern * California. * * Contributor(s): * Carl D. Worth * Kristian Høgsberg * Chris Wilson */ #include "cairoint.h" #include "cairo-box-private.h" #include "cairo-clip-private.h" #include "cairo-error-private.h" #include "cairo-freed-pool-private.h" #include "cairo-gstate-private.h" #include "cairo-path-fixed-private.h" #include "cairo-pattern-private.h" #include "cairo-composite-rectangles-private.h" #include "cairo-region-private.h" static inline int pot (int v) { v--; v |= v >> 1; v |= v >> 2; v |= v >> 4; v |= v >> 8; v |= v >> 16; v++; return v; } static cairo_bool_t _cairo_clip_contains_rectangle_box (const cairo_clip_t *clip, const cairo_rectangle_int_t *rect, const cairo_box_t *box) { int i; /* clip == NULL means no clip, so the clip contains everything */ if (clip == NULL) return TRUE; if (_cairo_clip_is_all_clipped (clip)) return FALSE; /* If we have a non-trivial path, just say no */ if (clip->path) return FALSE; if (! _cairo_rectangle_contains_rectangle (&clip->extents, rect)) return FALSE; if (clip->num_boxes == 0) return TRUE; /* Check for a clip-box that wholly contains the rectangle */ for (i = 0; i < clip->num_boxes; i++) { if (box->p1.x >= clip->boxes[i].p1.x && box->p1.y >= clip->boxes[i].p1.y && box->p2.x <= clip->boxes[i].p2.x && box->p2.y <= clip->boxes[i].p2.y) { return TRUE; } } return FALSE; } cairo_bool_t _cairo_clip_contains_box (const cairo_clip_t *clip, const cairo_box_t *box) { cairo_rectangle_int_t rect; _cairo_box_round_to_rectangle (box, &rect); return _cairo_clip_contains_rectangle_box(clip, &rect, box); } cairo_bool_t _cairo_clip_contains_rectangle (const cairo_clip_t *clip, const cairo_rectangle_int_t *rect) { cairo_box_t box; box.p1.x = _cairo_fixed_from_int (rect->x); box.p1.y = _cairo_fixed_from_int (rect->y); box.p2.x = _cairo_fixed_from_int (rect->x + rect->width); box.p2.y = _cairo_fixed_from_int (rect->y + rect->height); return _cairo_clip_contains_rectangle_box (clip, rect, &box); } cairo_clip_t * _cairo_clip_intersect_rectilinear_path (cairo_clip_t *clip, const cairo_path_fixed_t *path, cairo_fill_rule_t fill_rule, cairo_antialias_t antialias) { cairo_status_t status; cairo_boxes_t boxes; _cairo_boxes_init (&boxes); status = _cairo_path_fixed_fill_rectilinear_to_boxes (path, fill_rule, antialias, &boxes); if (likely (status == CAIRO_STATUS_SUCCESS && boxes.num_boxes)) clip = _cairo_clip_intersect_boxes (clip, &boxes); else clip = _cairo_clip_set_all_clipped (clip); _cairo_boxes_fini (&boxes); return clip; } static cairo_clip_t * _cairo_clip_intersect_rectangle_box (cairo_clip_t *clip, const cairo_rectangle_int_t *r, const cairo_box_t *box) { cairo_box_t extents_box; cairo_bool_t changed = FALSE; int i, j; if (clip == NULL) { clip = _cairo_clip_create (); if (clip == NULL) return _cairo_clip_set_all_clipped (clip); } if (clip->num_boxes == 0) { clip->boxes = &clip->embedded_box; clip->boxes[0] = *box; clip->num_boxes = 1; if (clip->path == NULL) { clip->extents = *r; } else { if (! _cairo_rectangle_intersect (&clip->extents, r)) clip = _cairo_clip_set_all_clipped (clip); } if (clip->path == NULL) clip->is_region = _cairo_box_is_pixel_aligned (box); return clip; } /* Does the new box wholly subsume the clip? Perform a cheap check * for the common condition of a single clip rectangle. */ if (clip->num_boxes == 1 && clip->boxes[0].p1.x >= box->p1.x && clip->boxes[0].p1.y >= box->p1.y && clip->boxes[0].p2.x <= box->p2.x && clip->boxes[0].p2.y <= box->p2.y) { return clip; } for (i = j = 0; i < clip->num_boxes; i++) { cairo_box_t *b = &clip->boxes[j]; if (j != i) *b = clip->boxes[i]; if (box->p1.x > b->p1.x) b->p1.x = box->p1.x, changed = TRUE; if (box->p2.x < b->p2.x) b->p2.x = box->p2.x, changed = TRUE; if (box->p1.y > b->p1.y) b->p1.y = box->p1.y, changed = TRUE; if (box->p2.y < b->p2.y) b->p2.y = box->p2.y, changed = TRUE; j += b->p2.x > b->p1.x && b->p2.y > b->p1.y; } clip->num_boxes = j; if (clip->num_boxes == 0) return _cairo_clip_set_all_clipped (clip); if (! changed) return clip; extents_box = clip->boxes[0]; for (i = 1; i < clip->num_boxes; i++) { if (clip->boxes[i].p1.x < extents_box.p1.x) extents_box.p1.x = clip->boxes[i].p1.x; if (clip->boxes[i].p1.y < extents_box.p1.y) extents_box.p1.y = clip->boxes[i].p1.y; if (clip->boxes[i].p2.x > extents_box.p2.x) extents_box.p2.x = clip->boxes[i].p2.x; if (clip->boxes[i].p2.y > extents_box.p2.y) extents_box.p2.y = clip->boxes[i].p2.y; } if (clip->path == NULL) { _cairo_box_round_to_rectangle (&extents_box, &clip->extents); } else { cairo_rectangle_int_t extents_rect; _cairo_box_round_to_rectangle (&extents_box, &extents_rect); if (! _cairo_rectangle_intersect (&clip->extents, &extents_rect)) return _cairo_clip_set_all_clipped (clip); } if (clip->region) { cairo_region_destroy (clip->region); clip->region = NULL; } clip->is_region = FALSE; return clip; } cairo_clip_t * _cairo_clip_intersect_box (cairo_clip_t *clip, const cairo_box_t *box) { cairo_rectangle_int_t r; _cairo_box_round_to_rectangle (box, &r); if (r.width == 0 || r.height == 0) return _cairo_clip_set_all_clipped (clip); return _cairo_clip_intersect_rectangle_box (clip, &r, box); } cairo_clip_t * _cairo_clip_intersect_boxes (cairo_clip_t *clip, const cairo_boxes_t *boxes) { cairo_boxes_t clip_boxes; cairo_box_t limits; cairo_rectangle_int_t extents; if (_cairo_clip_is_all_clipped (clip)) return clip; if (boxes->num_boxes == 0) return _cairo_clip_set_all_clipped (clip); if (boxes->num_boxes == 1) return _cairo_clip_intersect_box (clip, boxes->chunks.base); if (clip == NULL) clip = _cairo_clip_create (); if (clip->num_boxes) { _cairo_boxes_init_for_array (&clip_boxes, clip->boxes, clip->num_boxes); if (unlikely (_cairo_boxes_intersect (&clip_boxes, boxes, &clip_boxes))) { clip = _cairo_clip_set_all_clipped (clip); goto out; } if (clip->boxes != &clip->embedded_box) free (clip->boxes); clip->boxes = NULL; boxes = &clip_boxes; } if (boxes->num_boxes == 0) { clip = _cairo_clip_set_all_clipped (clip); goto out; } else if (boxes->num_boxes == 1) { clip->boxes = &clip->embedded_box; clip->boxes[0] = boxes->chunks.base[0]; clip->num_boxes = 1; } else { clip->boxes = _cairo_boxes_to_array (boxes, &clip->num_boxes, TRUE); } _cairo_boxes_extents (boxes, &limits); _cairo_box_round_to_rectangle (&limits, &extents); if (clip->path == NULL) clip->extents = extents; else if (! _cairo_rectangle_intersect (&clip->extents, &extents)) clip = _cairo_clip_set_all_clipped (clip); if (clip->region) { cairo_region_destroy (clip->region); clip->region = NULL; } clip->is_region = FALSE; out: if (boxes == &clip_boxes) _cairo_boxes_fini (&clip_boxes); return clip; } cairo_clip_t * _cairo_clip_intersect_rectangle (cairo_clip_t *clip, const cairo_rectangle_int_t *r) { cairo_box_t box; if (_cairo_clip_is_all_clipped (clip)) return clip; if (r->width == 0 || r->height == 0) return _cairo_clip_set_all_clipped (clip); box.p1.x = _cairo_fixed_from_int (r->x); box.p1.y = _cairo_fixed_from_int (r->y); box.p2.x = _cairo_fixed_from_int (r->x + r->width); box.p2.y = _cairo_fixed_from_int (r->y + r->height); return _cairo_clip_intersect_rectangle_box (clip, r, &box); } struct reduce { cairo_clip_t *clip; cairo_box_t limit; cairo_box_t extents; cairo_bool_t inside; cairo_point_t current_point; cairo_point_t last_move_to; }; static void _add_clipped_edge (struct reduce *r, const cairo_point_t *p1, const cairo_point_t *p2, int y1, int y2) { cairo_fixed_t x; x = _cairo_edge_compute_intersection_x_for_y (p1, p2, y1); if (x < r->extents.p1.x) r->extents.p1.x = x; x = _cairo_edge_compute_intersection_x_for_y (p1, p2, y2); if (x > r->extents.p2.x) r->extents.p2.x = x; if (y1 < r->extents.p1.y) r->extents.p1.y = y1; if (y2 > r->extents.p2.y) r->extents.p2.y = y2; r->inside = TRUE; } static void _add_edge (struct reduce *r, const cairo_point_t *p1, const cairo_point_t *p2) { int top, bottom; int top_y, bot_y; int n; if (p1->y < p2->y) { top = p1->y; bottom = p2->y; } else { top = p2->y; bottom = p1->y; } if (bottom < r->limit.p1.y || top > r->limit.p2.y) return; if (p1->x > p2->x) { const cairo_point_t *t = p1; p1 = p2; p2 = t; } if (p2->x <= r->limit.p1.x || p1->x >= r->limit.p2.x) return; for (n = 0; n < r->clip->num_boxes; n++) { const cairo_box_t *limits = &r->clip->boxes[n]; if (bottom < limits->p1.y || top > limits->p2.y) continue; if (p2->x <= limits->p1.x || p1->x >= limits->p2.x) continue; if (p1->x >= limits->p1.x && p2->x <= limits->p1.x) { top_y = top; bot_y = bottom; } else { int p1_y, p2_y; p1_y = _cairo_edge_compute_intersection_y_for_x (p1, p2, limits->p1.x); p2_y = _cairo_edge_compute_intersection_y_for_x (p1, p2, limits->p2.x); if (p1_y < p2_y) { top_y = p1_y; bot_y = p2_y; } else { top_y = p2_y; bot_y = p1_y; } if (top_y < top) top_y = top; if (bot_y > bottom) bot_y = bottom; } if (top_y < limits->p1.y) top_y = limits->p1.y; if (bot_y > limits->p2.y) bot_y = limits->p2.y; if (bot_y > top_y) _add_clipped_edge (r, p1, p2, top_y, bot_y); } } static cairo_status_t _reduce_line_to (void *closure, const cairo_point_t *point) { struct reduce *r = closure; _add_edge (r, &r->current_point, point); r->current_point = *point; return CAIRO_STATUS_SUCCESS; } static cairo_status_t _reduce_close (void *closure) { struct reduce *r = closure; return _reduce_line_to (r, &r->last_move_to); } static cairo_status_t _reduce_move_to (void *closure, const cairo_point_t *point) { struct reduce *r = closure; cairo_status_t status; /* close current subpath */ status = _reduce_close (closure); /* make sure that the closure represents a degenerate path */ r->current_point = *point; r->last_move_to = *point; return status; } static cairo_clip_t * _cairo_clip_reduce_to_boxes (cairo_clip_t *clip) { struct reduce r; cairo_clip_path_t *clip_path; cairo_status_t status; return clip; if (clip->path == NULL) return clip; r.clip = clip; r.extents.p1.x = r.extents.p1.y = INT_MAX; r.extents.p2.x = r.extents.p2.y = INT_MIN; r.inside = FALSE; r.limit.p1.x = _cairo_fixed_from_int (clip->extents.x); r.limit.p1.y = _cairo_fixed_from_int (clip->extents.y); r.limit.p2.x = _cairo_fixed_from_int (clip->extents.x + clip->extents.width); r.limit.p2.y = _cairo_fixed_from_int (clip->extents.y + clip->extents.height); clip_path = clip->path; do { r.current_point.x = 0; r.current_point.y = 0; r.last_move_to = r.current_point; status = _cairo_path_fixed_interpret_flat (&clip_path->path, _reduce_move_to, _reduce_line_to, _reduce_close, &r, clip_path->tolerance); assert (status == CAIRO_STATUS_SUCCESS); _reduce_close (&r); } while ((clip_path = clip_path->prev)); if (! r.inside) { _cairo_clip_path_destroy (clip->path); clip->path = NULL; } return _cairo_clip_intersect_box (clip, &r.extents); } cairo_clip_t * _cairo_clip_reduce_to_rectangle (const cairo_clip_t *clip, const cairo_rectangle_int_t *r) { cairo_clip_t *copy; if (_cairo_clip_is_all_clipped (clip)) return (cairo_clip_t *) clip; if (_cairo_clip_contains_rectangle (clip, r)) return _cairo_clip_intersect_rectangle (NULL, r); copy = _cairo_clip_copy_intersect_rectangle (clip, r); if (_cairo_clip_is_all_clipped (copy)) return copy; return _cairo_clip_reduce_to_boxes (copy); } cairo_clip_t * _cairo_clip_reduce_for_composite (const cairo_clip_t *clip, cairo_composite_rectangles_t *extents) { const cairo_rectangle_int_t *r; r = extents->is_bounded ? &extents->bounded : &extents->unbounded; return _cairo_clip_reduce_to_rectangle (clip, r); } cairo_clip_t * _cairo_clip_from_boxes (const cairo_boxes_t *boxes) { cairo_box_t extents; cairo_clip_t *clip = _cairo_clip_create (); if (clip == NULL) return _cairo_clip_set_all_clipped (clip); /* XXX cow-boxes? */ if(boxes->num_boxes == 1) { clip->boxes = &clip->embedded_box; clip->boxes[0] = boxes->chunks.base[0]; clip->num_boxes = 1; } else { clip->boxes = _cairo_boxes_to_array (boxes, &clip->num_boxes, TRUE); if (clip->boxes == NULL) return _cairo_clip_set_all_clipped (clip); } _cairo_boxes_extents (boxes, &extents); _cairo_box_round_to_rectangle (&extents, &clip->extents); return clip; }