mutter/src/place.c
Havoc Pennington ff5315d551 handle queue/unqueue of calc showings as we are iterating over the pending
2001-10-29  Havoc Pennington  <hp@pobox.com>

	* src/window.c (idle_calc_showing): handle queue/unqueue of
	calc showings as we are iterating over the pending list
	(meta_window_show): focus placed transients in here instead
	of in meta_window_place - now it should actually work, yay

	* src/place.c (meta_window_place): remove focusing of transient
	child from here; this was really broken
2001-10-30 02:00:53 +00:00

840 lines
18 KiB
C

/* Metacity window placement */
/*
* Copyright (C) 2001 Havoc Pennington
*
* 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.
*/
#include "place.h"
#include "workspace.h"
#include <gdk/gdkregion.h>
#include <math.h>
#include <stdlib.h>
static gint
northwestcmp (gconstpointer a, gconstpointer b)
{
MetaWindow *aw = (gpointer) a;
MetaWindow *bw = (gpointer) b;
int from_origin_a;
int from_origin_b;
int ax, ay, bx, by;
/* we're interested in the frame position for cascading,
* not meta_window_get_position()
*/
if (aw->frame)
{
ax = aw->frame->rect.x;
ay = aw->frame->rect.y;
}
else
{
ax = aw->rect.x;
ay = aw->rect.y;
}
if (bw->frame)
{
bx = bw->frame->rect.x;
by = bw->frame->rect.y;
}
else
{
bx = bw->rect.x;
by = bw->rect.y;
}
/* probably there's a fast good-enough-guess we could use here. */
from_origin_a = sqrt (ax * ax + ay * ay);
from_origin_b = sqrt (bx * bx + by * by);
if (from_origin_a < from_origin_b)
return -1;
else if (from_origin_a > from_origin_b)
return 1;
else
return 0;
}
static void
find_next_cascade (MetaWindow *window,
MetaFrameGeometry *fgeom,
/* visible windows on relevant workspaces */
GList *windows,
int x,
int y,
int *new_x,
int *new_y)
{
GList *tmp;
GList *sorted;
int cascade_x, cascade_y;
int x_threshold, y_threshold;
sorted = g_list_copy (windows);
sorted = g_list_sort (sorted, northwestcmp);
/* This is a "fuzzy" cascade algorithm.
* For each window in the list, we find where we'd cascade a
* new window after it. If a window is already nearly at that
* position, we move on.
*/
/* Find furthest-SE origin of all workspaces.
* cascade_x, cascade_y are the target position
* of NW corner of window frame.
*/
cascade_x = 0;
cascade_y = 0;
tmp = window->workspaces;
while (tmp != NULL)
{
MetaWorkspace *space = tmp->data;
cascade_x = MAX (cascade_x, space->workarea.x);
cascade_y = MAX (cascade_y, space->workarea.y);
tmp = tmp->next;
}
/* Find first cascade position that's not used. */
/* arbitrary-ish threshold, honors user attempts to
* manually cascade.
*/
if (fgeom)
{
x_threshold = MAX (fgeom->left_width, 10);
y_threshold = MAX (fgeom->top_height, 10);
}
else
{
x_threshold = 10;
y_threshold = 10;
}
tmp = sorted;
while (tmp != NULL)
{
MetaWindow *w;
int wx, wy;
w = tmp->data;
/* we want frame position, not window position */
if (w->frame)
{
wx = w->frame->rect.x;
wy = w->frame->rect.y;
}
else
{
wx = w->rect.x;
wy = w->rect.y;
}
if (ABS (wx - cascade_x) < x_threshold &&
ABS (wy - cascade_y) < y_threshold)
{
/* This window is "in the way", move to next cascade
* point. The new window frame should go at the origin
* of the client window we're stacking above.
*/
meta_window_get_position (w, &wx, &wy);
cascade_x = wx;
cascade_y = wy;
}
else
goto found; /* no window at this cascade point. */
tmp = tmp->next;
}
/* cascade_x and cascade_y will match the last window in the list. */
found:
g_list_free (sorted);
/* Convert coords to position of window, not position of frame. */
if (fgeom == NULL)
{
*new_x = cascade_x;
*new_y = cascade_y;
}
else
{
*new_x = cascade_x + fgeom->left_width;
*new_y = cascade_y + fgeom->top_height;
}
}
/* Find the leftmost, then topmost, empty area on the workspace
* that can contain the new window.
*
* Cool feature to have: if we can't fit the current window size,
* try shrinking the window (within geometry constraints). But
* beware windows such as Emacs with no sane minimum size, we
* don't want to create a 1x1 Emacs.
*/
static gboolean
find_first_fit (MetaWindow *window,
MetaFrameGeometry *fgeom,
/* visible windows on relevant workspaces */
GList *windows,
int x,
int y,
int *new_x,
int *new_y)
{
/* FIXME */
}
void
meta_window_place (MetaWindow *window,
MetaFrameGeometry *fgeom,
int x,
int y,
int *new_x,
int *new_y)
{
GList *windows;
/* frame member variables should NEVER be used in here, only
* MetaFrameGeometry. But remember fgeom == NULL
* for undecorated windows. Also, this function should
* NEVER have side effects other than computing the
* placement coordinates.
*/
meta_verbose ("Placing window %s\n", window->desc);
/* FIXME copying Mac, when placing a dialog
* put it at 1/5 down and horizontally centered
*/
if (window->xtransient_for != None)
{
/* Center horizontally, at top of parent vertically */
MetaWindow *parent;
parent =
meta_display_lookup_x_window (window->display,
window->xtransient_for);
if (parent)
{
int w;
meta_window_get_position (parent, &x, &y);
w = parent->rect.width;
/* center of parent */
x = x + w / 2;
/* center of child over center of parent */
x -= window->rect.width / 2;
if (fgeom)
y += fgeom->top_height;
meta_verbose ("Centered window %s over transient parent\n",
window->desc);
goto done;
}
}
if (window->type == META_WINDOW_DIALOG ||
window->type == META_WINDOW_MODAL_DIALOG)
{
/* Center on screen */
int w, h;
/* I think whole screen will look nicer than workarea */
w = window->screen->width;
h = window->screen->height;
x = (w - window->rect.width) / 2;
y = (y - window->rect.height) / 2;
meta_verbose ("Centered window %s on screen\n",
window->desc);
goto done;
}
/* Find windows that matter (not minimized, on same workspace
* as placed window, may be shaded - if shaded we pretend it isn't
* for placement purposes)
*/
windows = NULL;
{
GSList *all_windows;
GSList *tmp;
all_windows = meta_display_list_windows (window->display);
tmp = all_windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (!w->minimized &&
w != window &&
meta_window_shares_some_workspace (window, w))
windows = g_list_prepend (windows, w);
tmp = tmp->next;
}
}
/* "Origin" placement algorithm */
x = 0;
y = 0;
/* Cascade */
find_next_cascade (window, fgeom, windows, x, y, &x, &y);
g_list_free (windows);
done:
*new_x = x;
*new_y = y;
}
/* These are used while moving or resizing to "snap" to useful
* places; the return value is the x/y position of the window to
* be snapped to the given edge.
*
* They only use edges on the current workspace, since things
* would be weird otherwise.
*/
static GSList*
get_windows_on_same_workspace (MetaWindow *window,
int *n_windows)
{
GSList *windows;
GSList *all_windows;
GSList *tmp;
int i;
windows = NULL;
i = 0;
all_windows = meta_display_list_windows (window->display);
tmp = all_windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (!w->minimized &&
w != window &&
meta_window_visible_on_workspace (w,
window->screen->active_workspace))
{
windows = g_slist_prepend (windows, w);
++i;
}
tmp = tmp->next;
}
if (n_windows)
*n_windows = i;
return windows;
}
static void
window_get_edges (MetaWindow *w,
int *left,
int *right,
int *top,
int *bottom)
{
int left_edge;
int right_edge;
int top_edge;
int bottom_edge;
MetaRectangle rect;
meta_window_get_outer_rect (w, &rect);
left_edge = rect.x;
right_edge = rect.x + rect.width;
top_edge = rect.y;
bottom_edge = rect.y + rect.height;
if (left)
*left = left_edge;
if (right)
*right = right_edge;
if (top)
*top = top_edge;
if (bottom)
*bottom = bottom_edge;
}
static int
intcmp (const void* a, const void* b)
{
const int *ai = a;
const int *bi = b;
if (*ai < *bi)
return -1;
else if (*ai > *bi)
return 1;
else
return 0;
}
static gboolean
rects_overlap_vertically (const MetaRectangle *a,
const MetaRectangle *b)
{
/* if they don't overlap, then either a is above b
* or b is above a
*/
if ((a->y + a->height) < b->y)
return FALSE;
else if ((b->y + b->height) < a->y)
return FALSE;
else
return TRUE;
}
static gboolean
rects_overlap_horizontally (const MetaRectangle *a,
const MetaRectangle *b)
{
if ((a->x + a->width) < b->x)
return FALSE;
else if ((b->x + b->width) < a->x)
return FALSE;
else
return TRUE;
}
static void
get_vertical_edges (MetaWindow *window,
int **edges_p,
int *n_edges_p)
{
GSList *windows;
GSList *tmp;
int n_windows;
int *edges;
int i;
int n_edges;
MetaRectangle rect;
windows = get_windows_on_same_workspace (window, &n_windows);
i = 0;
n_edges = n_windows * 2 + 4; /* 4 = workspace/screen edges */
edges = g_new (int, n_edges);
/* workspace/screen edges */
edges[i] = window->screen->active_workspace->workarea.x;
++i;
edges[i] =
window->screen->active_workspace->workarea.x +
window->screen->active_workspace->workarea.width;
++i;
edges[i] = 0;
++i;
edges[i] = window->screen->width;
++i;
g_assert (i == 4);
meta_window_get_outer_rect (window, &rect);
/* get window edges */
tmp = windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
MetaRectangle w_rect;
meta_window_get_outer_rect (w, &w_rect);
if (rects_overlap_vertically (&rect, &w_rect))
{
window_get_edges (w, &edges[i], &edges[i+1], NULL, NULL);
i += 2;
}
tmp = tmp->next;
}
n_edges = i;
g_slist_free (windows);
/* Sort */
qsort (edges, n_edges, sizeof (int), intcmp);
*edges_p = edges;
*n_edges_p = n_edges;
}
static void
get_horizontal_edges (MetaWindow *window,
int **edges_p,
int *n_edges_p)
{
GSList *windows;
GSList *tmp;
int n_windows;
int *edges;
int i;
int n_edges;
MetaRectangle rect;
windows = get_windows_on_same_workspace (window, &n_windows);
i = 0;
n_edges = n_windows * 2 + 4; /* 4 = workspace/screen edges */
edges = g_new (int, n_edges);
/* workspace/screen edges */
edges[i] = window->screen->active_workspace->workarea.y;
++i;
edges[i] =
window->screen->active_workspace->workarea.y +
window->screen->active_workspace->workarea.height;
++i;
edges[i] = 0;
++i;
edges[i] = window->screen->height;
++i;
g_assert (i == 4);
meta_window_get_outer_rect (window, &rect);
/* get window edges */
tmp = windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
MetaRectangle w_rect;
meta_window_get_outer_rect (w, &w_rect);
if (rects_overlap_horizontally (&rect, &w_rect))
{
window_get_edges (w, NULL, NULL, &edges[i], &edges[i+1]);
i += 2;
}
tmp = tmp->next;
}
n_edges = i;
g_slist_free (windows);
/* Sort */
qsort (edges, n_edges, sizeof (int), intcmp);
*edges_p = edges;
*n_edges_p = n_edges;
}
int
meta_window_find_next_vertical_edge (MetaWindow *window,
gboolean right)
{
int left_edge, right_edge;
int *edges;
int i;
int n_edges;
int retval;
get_vertical_edges (window, &edges, &n_edges);
/* Find next */
meta_window_get_position (window, &retval, NULL);
window_get_edges (window, &left_edge, &right_edge, NULL, NULL);
if (right)
{
i = 0;
while (i < n_edges)
{
if (edges[i] > right_edge)
{
/* This is the one we want, snap right
* edge of window to edges[i]
*/
retval = edges[i];
if (window->frame)
{
retval -= window->frame->rect.width;
retval += window->frame->child_x;
}
else
{
retval -= window->rect.width;
}
break;
}
++i;
}
}
else
{
i = n_edges;
do
{
--i;
if (edges[i] < left_edge)
{
/* This is the one we want */
retval = edges[i];
if (window->frame)
retval += window->frame->child_x;
break;
}
}
while (i > 0);
}
g_free (edges);
return retval;
}
int
meta_window_find_next_horizontal_edge (MetaWindow *window,
gboolean down)
{
int top_edge, bottom_edge;
int *edges;
int i;
int n_edges;
int retval;
get_horizontal_edges (window, &edges, &n_edges);
/* Find next */
meta_window_get_position (window, NULL, &retval);
window_get_edges (window, NULL, NULL, &top_edge, &bottom_edge);
if (down)
{
i = 0;
while (i < n_edges)
{
if (edges[i] > bottom_edge)
{
/* This is the one we want, snap right
* edge of window to edges[i]
*/
retval = edges[i];
if (window->frame)
{
retval -= window->frame->rect.height;
retval += window->frame->child_y;
}
else
{
retval -= window->rect.height;
}
break;
}
++i;
}
}
else
{
i = n_edges;
do
{
--i;
if (edges[i] < top_edge)
{
/* This is the one we want */
retval = edges[i];
if (window->frame)
retval += window->frame->child_y;
break;
}
}
while (i > 0);
}
g_free (edges);
return retval;
}
int
meta_window_find_nearest_vertical_edge (MetaWindow *window,
int x_pos)
{
int *edges;
int i;
int n_edges;
int *positions;
int n_positions;
int retval;
get_vertical_edges (window, &edges, &n_edges);
/* Create an array of all snapped positions our window could have */
n_positions = n_edges * 2;
positions = g_new (int, n_positions);
i = 0;
while (i < n_edges)
{
int left_pos, right_pos;
left_pos = edges[i];
if (window->frame)
left_pos += window->frame->child_x;
if (window->frame)
{
right_pos = edges[i] - window->frame->rect.width;
right_pos += window->frame->child_x;
}
else
{
right_pos = edges[i] - window->rect.width;
}
positions[i * 2] = left_pos;
positions[i * 2 + 1] = right_pos;
++i;
}
g_free (edges);
/* Sort */
qsort (positions, n_positions, sizeof (int), intcmp);
/* Find nearest */
retval = positions[0];
i = 1;
while (i < n_positions)
{
int delta;
int best_delta;
delta = ABS (x_pos - positions[i]);
best_delta = ABS (x_pos - retval);
if (delta < best_delta)
retval = positions[i];
++i;
}
g_free (positions);
return retval;
}
int
meta_window_find_nearest_horizontal_edge (MetaWindow *window,
int y_pos)
{
int *edges;
int i;
int n_edges;
int *positions;
int n_positions;
int retval;
get_horizontal_edges (window, &edges, &n_edges);
/* Create an array of all snapped positions our window could have */
n_positions = n_edges * 2;
positions = g_new (int, n_positions);
i = 0;
while (i < n_edges)
{
int top_pos, bottom_pos;
top_pos = edges[i];
if (window->frame)
top_pos += window->frame->child_y;
if (window->frame)
{
bottom_pos = edges[i] - window->frame->rect.height;
bottom_pos += window->frame->child_y;
}
else
{
bottom_pos = edges[i] - window->rect.height;
}
positions[i * 2] = top_pos;
positions[i * 2 + 1] = bottom_pos;
++i;
}
g_free (edges);
/* Sort */
qsort (positions, n_positions, sizeof (int), intcmp);
/* Find nearest */
retval = positions[0];
i = 1;
while (i < n_positions)
{
int delta;
int best_delta;
delta = ABS (y_pos - positions[i]);
best_delta = ABS (y_pos - retval);
if (delta < best_delta)
retval = positions[i];
++i;
}
g_free (positions);
return retval;
}