mutter/src/compositor/meta-window-shape.c

253 lines
6.9 KiB
C

/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/*
* MetaWindowShape
*
* Extracted invariant window shape
*
* Copyright (C) 2010 Red Hat, Inc.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include <string.h>
#include "meta-window-shape.h"
#include "region-utils.h"
struct _MetaWindowShape
{
guint ref_count;
int top, right, bottom, left;
int n_rectangles;
cairo_rectangle_int_t *rectangles;
guint hash;
};
MetaWindowShape *
meta_window_shape_new (cairo_region_t *region)
{
MetaWindowShape *shape;
MetaRegionIterator iter;
cairo_rectangle_int_t extents;
int max_yspan_y1 = 0;
int max_yspan_y2 = 0;
int max_xspan_x1 = -1;
int max_xspan_x2 = -1;
guint hash;
shape = g_slice_new0 (MetaWindowShape);
shape->ref_count = 1;
cairo_region_get_extents (region, &extents);
shape->n_rectangles = cairo_region_num_rectangles (region);
if (shape->n_rectangles == 0)
{
shape->rectangles = NULL;
shape->top = shape->right = shape->bottom = shape->left = 0;
shape->hash = 0;
return shape;
}
for (meta_region_iterator_init (&iter, region);
!meta_region_iterator_at_end (&iter);
meta_region_iterator_next (&iter))
{
int max_line_xspan_x1 = -1;
int max_line_xspan_x2 = -1;
if (iter.rectangle.width > max_line_xspan_x2 - max_line_xspan_x1)
{
max_line_xspan_x1 = iter.rectangle.x;
max_line_xspan_x2 = iter.rectangle.x + iter.rectangle.width;
}
if (iter.line_end)
{
if (iter.rectangle.height > max_yspan_y2 - max_yspan_y1)
{
max_yspan_y1 = iter.rectangle.y;
max_yspan_y2 = iter.rectangle.y + iter.rectangle.height;
}
if (max_xspan_x1 < 0) /* First line */
{
max_xspan_x1 = max_line_xspan_x1;
max_xspan_x2 = max_line_xspan_x2;
}
else
{
max_xspan_x1 = MAX (max_xspan_x1, max_line_xspan_x1);
max_xspan_x2 = MIN (max_xspan_x2, max_line_xspan_x2);
if (max_xspan_x2 < max_xspan_x1)
max_xspan_x2 = max_xspan_x1;
}
}
}
#if 0
g_print ("xspan: %d -> %d, yspan: %d -> %d\n",
max_xspan_x1, max_xspan_x2,
max_yspan_y1, max_yspan_y2);
#endif
shape->top = max_yspan_y1 - extents.y;
shape->right = extents.x + extents.width - max_xspan_x2;
shape->bottom = extents.y + extents.height - max_yspan_y2;
shape->left = max_xspan_x1 - extents.x;
shape->rectangles = g_new (cairo_rectangle_int_t, shape->n_rectangles);
hash = 0;
for (meta_region_iterator_init (&iter, region);
!meta_region_iterator_at_end (&iter);
meta_region_iterator_next (&iter))
{
int x1, x2, y1, y2;
x1 = iter.rectangle.x;
x2 = iter.rectangle.x + iter.rectangle.width;
y1 = iter.rectangle.y;
y2 = iter.rectangle.y + iter.rectangle.height;
if (x1 > max_xspan_x1)
x1 -= MIN (x1, max_xspan_x2 - 1) - max_xspan_x1;
if (x2 > max_xspan_x1)
x2 -= MIN (x2, max_xspan_x2 - 1) - max_xspan_x1;
if (y1 > max_yspan_y1)
y1 -= MIN (y1, max_yspan_y2 - 1) - max_yspan_y1;
if (y2 > max_yspan_y1)
y2 -= MIN (y2, max_yspan_y2 - 1) - max_yspan_y1;
shape->rectangles[iter.i].x = x1 - extents.x;
shape->rectangles[iter.i].y = y1 - extents.y;
shape->rectangles[iter.i].width = x2 - x1;
shape->rectangles[iter.i].height = y2 - y1;
#if 0
g_print ("%d: +%d+%dx%dx%d => +%d+%dx%dx%d\n",
iter.i, iter.rectangle.x, iter.rectangle.y, iter.rectangle.width, iter.rectangle.height,
shape->rectangles[iter.i].x, shape->rectangles[iter.i].y,
hape->rectangles[iter.i].width, shape->rectangles[iter.i].height);
#endif
hash = hash * 31 + x1 * 17 + x2 * 27 + y1 * 37 + y2 * 43;
}
shape->hash = hash;
#if 0
g_print ("%d %d %d %d: %#x\n\n", shape->top, shape->right, shape->bottom, shape->left, shape->hash);
#endif
return shape;
}
MetaWindowShape *
meta_window_shape_ref (MetaWindowShape *shape)
{
shape->ref_count++;
return shape;
}
void
meta_window_shape_unref (MetaWindowShape *shape)
{
shape->ref_count--;
if (shape->ref_count == 0)
{
g_free (shape->rectangles);
g_slice_free (MetaWindowShape, shape);
}
}
guint
meta_window_shape_hash (MetaWindowShape *shape)
{
return shape->hash;
}
gboolean
meta_window_shape_equal (MetaWindowShape *shape_a,
MetaWindowShape *shape_b)
{
if (shape_a->n_rectangles != shape_b->n_rectangles)
return FALSE;
return memcmp (shape_a->rectangles, shape_b->rectangles,
sizeof (cairo_rectangle_int_t) * shape_a->n_rectangles) == 0;
}
void
meta_window_shape_get_borders (MetaWindowShape *shape,
int *border_top,
int *border_right,
int *border_bottom,
int *border_left)
{
if (border_top)
*border_top = shape->top;
if (border_right)
*border_right = shape->right;
if (border_bottom)
*border_bottom = shape->bottom;
if (border_left)
*border_left = shape->left;
}
/**
* meta_window_shape_to_region:
* @shape: a #MetaWindowShape
* @center_width: size of the central region horizontally
* @center_height: size of the central region vertically
*
* Converts the shape to to a cairo_region_t using the given width
* and height for the central scaled region.
*
* Return value: a newly created region
*/
cairo_region_t *
meta_window_shape_to_region (MetaWindowShape *shape,
int center_width,
int center_height)
{
cairo_region_t *region;
int i;
region = cairo_region_create ();
for (i = 0; i < shape->n_rectangles; i++)
{
cairo_rectangle_int_t rect = shape->rectangles[i];
if (rect.x <= shape->left && rect.x + rect.width >= shape->left + 1)
rect.width += center_width;
else if (rect.x >= shape->left + 1)
rect.x += center_width;
if (rect.y <= shape->top && rect.y + rect.height >= shape->top + 1)
rect.height += center_height;
else if (rect.y >= shape->top + 1)
rect.y += center_height;
cairo_region_union_rectangle (region, &rect);
}
return region;
}