mutter/src/boxes.h
Elijah Newren 0201fcfc6c Stick an emacs comment directive at the beginning of all the code files so
2006-10-01  Elijah Newren  <newren gmail com>

	* src/*.[ch]: Stick an emacs comment directive at the beginning of
	all the code files so that people using emacs will be more likely
	to get coding style correct in their patches.  We still need a
	similar vi directive.  #358866
2006-10-01 22:30:10 +00:00

269 lines
12 KiB
C

/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/* Simple box operations */
/*
* Copyright (C) 2005, 2006 Elijah Newren
*
* 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, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
* 02111-1307, USA.
*/
#ifndef META_BOXES_H
#define META_BOXES_H
#include <glib.h>
#include "common.h"
typedef struct _MetaRectangle MetaRectangle;
struct _MetaRectangle
{
int x;
int y;
int width;
int height;
};
#define BOX_LEFT(box) ((box).x) /* Leftmost pixel of rect */
#define BOX_RIGHT(box) ((box).x + (box).width) /* One pixel past right */
#define BOX_TOP(box) ((box).y) /* Topmost pixel of rect */
#define BOX_BOTTOM(box) ((box).y + (box).height) /* One pixel past bottom */
typedef enum
{
FIXED_DIRECTION_X = 1 << 0,
FIXED_DIRECTION_Y = 1 << 1,
} FixedDirections;
typedef enum
{
META_EDGE_WINDOW,
META_EDGE_XINERAMA,
META_EDGE_SCREEN
} MetaEdgeType;
typedef struct _MetaEdge MetaEdge;
struct _MetaEdge
{
MetaRectangle rect; /* width or height should be 1 */
MetaDirection side_type; /* should only have 1 of the 4 directions set */
MetaEdgeType edge_type;
};
/* Output functions -- note that the output buffer had better be big enough:
* rect_to_string: RECT_LENGTH
* region_to_string: (RECT_LENGTH+strlen(separator_string)) *
* g_list_length (region)
* edge_to_string: EDGE_LENGTH
* edge_list_to_...: (EDGE_LENGTH+strlen(separator_string)) *
* g_list_length (edge_list)
*/
#define RECT_LENGTH 27
#define EDGE_LENGTH 37
char* meta_rectangle_to_string (const MetaRectangle *rect,
char *output);
char* meta_rectangle_region_to_string (GList *region,
const char *separator_string,
char *output);
char* meta_rectangle_edge_to_string (const MetaEdge *edge,
char *output);
char* meta_rectangle_edge_list_to_string (
GList *edge_list,
const char *separator_string,
char *output);
/* Function to make initializing a rect with a single line of code easy */
MetaRectangle meta_rect (int x, int y, int width, int height);
/* Basic comparison functions */
int meta_rectangle_area (const MetaRectangle *rect);
gboolean meta_rectangle_intersect (const MetaRectangle *src1,
const MetaRectangle *src2,
MetaRectangle *dest);
gboolean meta_rectangle_equal (const MetaRectangle *src1,
const MetaRectangle *src2);
/* overlap is similar to intersect but doesn't provide location of
* intersection information.
*/
gboolean meta_rectangle_overlap (const MetaRectangle *rect1,
const MetaRectangle *rect2);
/* vert_overlap means ignore the horizontal location and ask if the
* vertical parts overlap. An alternate way to think of it is "Does there
* exist a way to shift either rect horizontally so that the two rects
* overlap?" horiz_overlap is similar.
*/
gboolean meta_rectangle_vert_overlap (const MetaRectangle *rect1,
const MetaRectangle *rect2);
gboolean meta_rectangle_horiz_overlap (const MetaRectangle *rect1,
const MetaRectangle *rect2);
/* could_fit_rect determines whether "outer_rect" is big enough to contain
* inner_rect. contains_rect checks whether it actually contains it.
*/
gboolean meta_rectangle_could_fit_rect (const MetaRectangle *outer_rect,
const MetaRectangle *inner_rect);
gboolean meta_rectangle_contains_rect (const MetaRectangle *outer_rect,
const MetaRectangle *inner_rect);
/* Resize old_rect to the given new_width and new_height, but store the
* result in rect. NOTE THAT THIS IS RESIZE ONLY SO IT CANNOT BE USED FOR
* A MOVERESIZE OPERATION (that simplies the routine a little bit as it
* means there's no difference between NorthWestGravity and StaticGravity.
* Also, I lied a little bit--technically, you could use it in a MoveResize
* operation if you muck with old_rect just right).
*/
void meta_rectangle_resize_with_gravity (const MetaRectangle *old_rect,
MetaRectangle *rect,
int gravity,
int new_width,
int new_height);
/* find a list of rectangles with the property that a window is contained
* in the given region if and only if it is contained in one of the
* rectangles in the list.
*
* In this case, the region is given by taking basic_rect, removing from
* it the intersections with all the rectangles in the all_struts list,
* then expanding all the rectangles in the resulting list by the given
* amounts on each side.
*
* See boxes.c for more details.
*/
GList* meta_rectangle_get_minimal_spanning_set_for_region (
const MetaRectangle *basic_rect,
const GSList *all_struts);
/* Expand all rectangles in region by the given amount on each side */
GList* meta_rectangle_expand_region (GList *region,
const int left_expand,
const int right_expand,
const int top_expand,
const int bottom_expand);
/* Same as for meta_rectangle_expand_region except that rectangles not at
* least min_x or min_y in size are not expanded in that direction
*/
GList* meta_rectangle_expand_region_conditionally (
GList *region,
const int left_expand,
const int right_expand,
const int top_expand,
const int bottom_expand,
const int min_x,
const int min_y);
/* Free the list created by
* meta_rectangle_get_minimal_spanning_set_for_region()
* or
* meta_rectangle_find_onscreen_edges ()
* or
* meta_rectangle_find_nonintersected_xinerama_edges()
*/
void meta_rectangle_free_list_and_elements (GList *filled_list);
/* could_fit_in_region determines whether one of the spanning_rects is
* big enough to contain rect. contained_in_region checks whether one
* actually contains it.
*/
gboolean meta_rectangle_could_fit_in_region (
const GList *spanning_rects,
const MetaRectangle *rect);
gboolean meta_rectangle_contained_in_region (
const GList *spanning_rects,
const MetaRectangle *rect);
gboolean meta_rectangle_overlaps_with_region (
const GList *spanning_rects,
const MetaRectangle *rect);
/* Make the rectangle small enough to fit into one of the spanning_rects,
* but make it no smaller than min_size.
*/
void meta_rectangle_clamp_to_fit_into_region (
const GList *spanning_rects,
FixedDirections fixed_directions,
MetaRectangle *rect,
const MetaRectangle *min_size);
/* Clip the rectangle so that it fits into one of the spanning_rects, assuming
* it overlaps with at least one of them
*/
void meta_rectangle_clip_to_region (const GList *spanning_rects,
FixedDirections fixed_directions,
MetaRectangle *rect);
/* Shove the rectangle into one of the spanning_rects, assuming it fits in
* one of them.
*/
void meta_rectangle_shove_into_region(
const GList *spanning_rects,
FixedDirections fixed_directions,
MetaRectangle *rect);
/* Finds the point on the line connecting (x1,y1) to (x2,y2) which is closest
* to (px, py). Useful for finding an optimal rectangle size when given a
* range between two sizes that are all candidates.
*/
void meta_rectangle_find_linepoint_closest_to_point (double x1, double y1,
double x2, double y2,
double px, double py,
double *valx, double *valy);
/***************************************************************************/
/* */
/* Switching gears to code for edges instead of just rectangles */
/* */
/***************************************************************************/
/* Return whether an edge overlaps or is adjacent to the rectangle in the
* nonzero-width dimension of the edge.
*/
gboolean meta_rectangle_edge_aligns (const MetaRectangle *rect,
const MetaEdge *edge);
/* Compare two edges, so that sorting functions can put a list of edges in
* canonical order.
*/
gint meta_rectangle_edge_cmp (gconstpointer a, gconstpointer b);
/* Compare two edges, so that sorting functions can put a list of edges in
* order. This function doesn't separate left edges first, then right edges,
* etc., but rather compares only upon location.
*/
gint meta_rectangle_edge_cmp_ignore_type (gconstpointer a, gconstpointer b);
/* Removes an parts of edges in the given list that intersect any box in the
* given rectangle list. Returns the result.
*/
GList* meta_rectangle_remove_intersections_with_boxes_from_edges (
GList *edges,
const GSList *rectangles);
/* Finds all the edges of an onscreen region, returning a GList* of
* MetaEdgeRect's.
*/
GList* meta_rectangle_find_onscreen_edges (const MetaRectangle *basic_rect,
const GSList *all_struts);
/* Finds edges between adjacent xineramas which are not covered by the given
* struts.
*/
GList* meta_rectangle_find_nonintersected_xinerama_edges (
const GList *xinerama_rects,
const GSList *all_struts);
#endif /* META_BOXES_H */