mutter/src/core/stack.c
Owen W. Taylor b9da43b753 Rename meta_window_get_outer_rect() to meta_window_get_frame_rect()
For clarity, rename meta_window_get_outer_rect() to match terminology
we use elsewhere. The old function is left as a deprecated
compatibility wrapper.
2013-11-19 14:04:16 -05:00

2026 lines
58 KiB
C

/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/*
* SECTION:stack
* @short_description: Which windows cover which other windows
*/
/*
* Copyright (C) 2001 Havoc Pennington
* Copyright (C) 2002, 2003 Red Hat, Inc.
* Copyright (C) 2004 Rob Adams
* Copyright (C) 2004, 2005 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.
*/
#include <config.h>
#include "stack.h"
#include "window-private.h"
#include <meta/errors.h>
#include "frame.h"
#include <meta/group.h>
#include <meta/prefs.h>
#include <meta/workspace.h>
#include <X11/Xatom.h>
#define WINDOW_HAS_TRANSIENT_TYPE(w) \
(w->type == META_WINDOW_DIALOG || \
w->type == META_WINDOW_MODAL_DIALOG || \
w->type == META_WINDOW_TOOLBAR || \
w->type == META_WINDOW_MENU || \
w->type == META_WINDOW_UTILITY)
#define WINDOW_TRANSIENT_FOR_WHOLE_GROUP(w) \
((w->xtransient_for == None || \
w->transient_parent_is_root_window) && \
WINDOW_HAS_TRANSIENT_TYPE (w))
#define WINDOW_IN_STACK(w) (w->stack_position >= 0)
static void stack_sync_to_xserver (MetaStack *stack);
static void meta_window_set_stack_position_no_sync (MetaWindow *window,
int position);
static void stack_do_window_deletions (MetaStack *stack);
static void stack_do_window_additions (MetaStack *stack);
static void stack_do_relayer (MetaStack *stack);
static void stack_do_constrain (MetaStack *stack);
static void stack_do_resort (MetaStack *stack);
static void stack_ensure_sorted (MetaStack *stack);
MetaStack*
meta_stack_new (MetaScreen *screen)
{
MetaStack *stack;
stack = g_new (MetaStack, 1);
stack->screen = screen;
stack->xwindows = g_array_new (FALSE, FALSE, sizeof (Window));
stack->sorted = NULL;
stack->added = NULL;
stack->removed = NULL;
stack->freeze_count = 0;
stack->last_all_root_children_stacked = NULL;
stack->n_positions = 0;
stack->need_resort = FALSE;
stack->need_relayer = FALSE;
stack->need_constrain = FALSE;
return stack;
}
static void
free_last_all_root_children_stacked_cache (MetaStack *stack)
{
g_array_free (stack->last_all_root_children_stacked, TRUE);
stack->last_all_root_children_stacked = NULL;
}
void
meta_stack_free (MetaStack *stack)
{
g_array_free (stack->xwindows, TRUE);
g_list_free (stack->sorted);
g_list_free (stack->added);
g_list_free (stack->removed);
if (stack->last_all_root_children_stacked)
free_last_all_root_children_stacked_cache (stack);
g_free (stack);
}
void
meta_stack_add (MetaStack *stack,
MetaWindow *window)
{
meta_topic (META_DEBUG_STACK, "Adding window %s to the stack\n", window->desc);
if (window->stack_position >= 0)
meta_bug ("Window %s had stack position already\n", window->desc);
stack->added = g_list_prepend (stack->added, window);
window->stack_position = stack->n_positions;
stack->n_positions += 1;
meta_topic (META_DEBUG_STACK,
"Window %s has stack_position initialized to %d\n",
window->desc, window->stack_position);
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
void
meta_stack_remove (MetaStack *stack,
MetaWindow *window)
{
meta_topic (META_DEBUG_STACK, "Removing window %s from the stack\n", window->desc);
if (window->stack_position < 0)
meta_bug ("Window %s removed from stack but had no stack position\n",
window->desc);
/* Set window to top position, so removing it will not leave gaps
* in the set of positions
*/
meta_window_set_stack_position_no_sync (window,
stack->n_positions - 1);
window->stack_position = -1;
stack->n_positions -= 1;
/* We don't know if it's been moved from "added" to "stack" yet */
stack->added = g_list_remove (stack->added, window);
stack->sorted = g_list_remove (stack->sorted, window);
/* Remember the window ID to remove it from the stack array.
* The macro is safe to use: Window is guaranteed to be 32 bits, and
* GUINT_TO_POINTER says it only works on 32 bits.
*/
stack->removed = g_list_prepend (stack->removed,
GUINT_TO_POINTER (window->xwindow));
if (window->frame)
stack->removed = g_list_prepend (stack->removed,
GUINT_TO_POINTER (window->frame->xwindow));
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
void
meta_stack_update_layer (MetaStack *stack,
MetaWindow *window)
{
stack->need_relayer = TRUE;
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
void
meta_stack_update_transient (MetaStack *stack,
MetaWindow *window)
{
stack->need_constrain = TRUE;
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
/* raise/lower within a layer */
void
meta_stack_raise (MetaStack *stack,
MetaWindow *window)
{
GList *l;
int max_stack_position = window->stack_position;
MetaWorkspace *workspace;
stack_ensure_sorted (stack);
workspace = meta_window_get_workspace (window);
for (l = stack->sorted; l; l = l->next)
{
MetaWindow *w = (MetaWindow *) l->data;
if (meta_window_located_on_workspace (w, workspace) &&
w->stack_position > max_stack_position)
max_stack_position = w->stack_position;
}
if (max_stack_position == window->stack_position)
return;
meta_window_set_stack_position_no_sync (window, max_stack_position);
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
void
meta_stack_lower (MetaStack *stack,
MetaWindow *window)
{
GList *l;
int min_stack_position = window->stack_position;
MetaWorkspace *workspace;
stack_ensure_sorted (stack);
workspace = meta_window_get_workspace (window);
for (l = stack->sorted; l; l = l->next)
{
MetaWindow *w = (MetaWindow *) l->data;
if (meta_window_located_on_workspace (w, workspace) &&
w->stack_position < min_stack_position)
min_stack_position = w->stack_position;
}
if (min_stack_position == window->stack_position)
return;
meta_window_set_stack_position_no_sync (window, min_stack_position);
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
}
void
meta_stack_freeze (MetaStack *stack)
{
stack->freeze_count += 1;
}
void
meta_stack_thaw (MetaStack *stack)
{
g_return_if_fail (stack->freeze_count > 0);
stack->freeze_count -= 1;
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, NULL);
}
void
meta_stack_update_window_tile_matches (MetaStack *stack,
MetaWorkspace *workspace)
{
GList *windows, *tmp;
if (stack->freeze_count > 0)
return;
windows = meta_stack_list_windows (stack, workspace);
tmp = windows;
while (tmp)
{
meta_window_compute_tile_match ((MetaWindow *) tmp->data);
tmp = tmp->next;
}
g_list_free (windows);
}
static gboolean
is_focused_foreach (MetaWindow *window,
void *data)
{
if (window->has_focus)
{
*((gboolean*) data) = TRUE;
return FALSE;
}
return TRUE;
}
static gboolean
windows_on_different_monitor (MetaWindow *a,
MetaWindow *b)
{
if (a->screen != b->screen)
return TRUE;
return meta_screen_get_monitor_for_window (a->screen, a) !=
meta_screen_get_monitor_for_window (b->screen, b);
}
/* Get layer ignoring any transient or group relationships */
static MetaStackLayer
get_standalone_layer (MetaWindow *window)
{
MetaStackLayer layer;
gboolean focused_transient = FALSE;
switch (window->type)
{
case META_WINDOW_DESKTOP:
layer = META_LAYER_DESKTOP;
break;
case META_WINDOW_DOCK:
/* still experimenting here */
if (window->wm_state_below)
layer = META_LAYER_BOTTOM;
else
layer = META_LAYER_DOCK;
break;
case META_WINDOW_DROPDOWN_MENU:
case META_WINDOW_POPUP_MENU:
case META_WINDOW_TOOLTIP:
case META_WINDOW_NOTIFICATION:
case META_WINDOW_COMBO:
case META_WINDOW_OVERRIDE_OTHER:
layer = META_LAYER_OVERRIDE_REDIRECT;
break;
default:
meta_window_foreach_transient (window,
is_focused_foreach,
&focused_transient);
if (window->wm_state_below)
layer = META_LAYER_BOTTOM;
else if (window->fullscreen &&
(focused_transient ||
window == window->display->focus_window ||
window->display->focus_window == NULL ||
(window->display->focus_window != NULL &&
windows_on_different_monitor (window,
window->display->focus_window))))
layer = META_LAYER_FULLSCREEN;
else if (window->wm_state_above && !META_WINDOW_MAXIMIZED (window))
layer = META_LAYER_TOP;
else
layer = META_LAYER_NORMAL;
break;
}
return layer;
}
/* Note that this function can never use window->layer only
* get_standalone_layer, or we'd have issues.
*/
static MetaStackLayer
get_maximum_layer_in_group (MetaWindow *window)
{
GSList *members;
MetaGroup *group;
GSList *tmp;
MetaStackLayer max;
MetaStackLayer layer;
max = META_LAYER_DESKTOP;
group = meta_window_get_group (window);
if (group != NULL)
members = meta_group_list_windows (group);
else
members = NULL;
tmp = members;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (!w->override_redirect)
{
layer = get_standalone_layer (w);
if (layer > max)
max = layer;
}
tmp = tmp->next;
}
g_slist_free (members);
return max;
}
static void
compute_layer (MetaWindow *window)
{
MetaStackLayer old_layer = window->layer;
window->layer = get_standalone_layer (window);
/* We can only do promotion-due-to-group for dialogs and other
* transients, or weird stuff happens like the desktop window and
* nautilus windows getting in the same layer, or all gnome-terminal
* windows getting in fullscreen layer if any terminal is
* fullscreen.
*/
if (window->layer != META_LAYER_DESKTOP &&
WINDOW_HAS_TRANSIENT_TYPE(window) &&
(window->xtransient_for == None ||
window->transient_parent_is_root_window))
{
/* We only do the group thing if the dialog is NOT transient for
* a particular window. Imagine a group with a normal window, a dock,
* and a dialog transient for the normal window; you don't want the dialog
* above the dock if it wouldn't normally be.
*/
MetaStackLayer group_max;
group_max = get_maximum_layer_in_group (window);
if (group_max > window->layer)
{
meta_topic (META_DEBUG_STACK,
"Promoting window %s from layer %u to %u due to group membership\n",
window->desc, window->layer, group_max);
window->layer = group_max;
}
}
meta_topic (META_DEBUG_STACK, "Window %s on layer %u type = %u has_focus = %d\n",
window->desc, window->layer,
window->type, window->has_focus);
if (window->layer != old_layer &&
(old_layer == META_LAYER_FULLSCREEN || window->layer == META_LAYER_FULLSCREEN))
meta_screen_queue_check_fullscreen (window->screen);
}
/* Front of the layer list is the topmost window,
* so the lower stack position is later in the list
*/
static int
compare_window_position (void *a,
void *b)
{
MetaWindow *window_a = a;
MetaWindow *window_b = b;
/* Go by layer, then stack_position */
if (window_a->layer < window_b->layer)
return 1; /* move window_a later in list */
else if (window_a->layer > window_b->layer)
return -1;
else if (window_a->stack_position < window_b->stack_position)
return 1; /* move window_a later in list */
else if (window_a->stack_position > window_b->stack_position)
return -1;
else
return 0; /* not reached */
}
/*
* Stacking constraints
*
* Assume constraints of the form "AB" meaning "window A must be
* below window B"
*
* If we have windows stacked from bottom to top
* "ABC" then raise A we get "BCA". Say C is
* transient for B is transient for A. So
* we have constraints AB and BC.
*
* After raising A, we need to reapply the constraints.
* If we do this by raising one window at a time -
*
* start: BCA
* apply AB: CAB
* apply BC: ABC
*
* but apply constraints in the wrong order and it breaks:
*
* start: BCA
* apply BC: BCA
* apply AB: CAB
*
* We make a directed graph of the constraints by linking
* from "above windows" to "below windows as follows:
*
* AB -> BC -> CD
* \
* CE
*
* If we then walk that graph and apply the constraints in the order
* that they appear, we will apply them correctly. Note that the
* graph MAY have cycles, so we have to guard against that.
*
*/
typedef struct Constraint Constraint;
struct Constraint
{
MetaWindow *above;
MetaWindow *below;
/* used to keep the constraint in the
* list of constraints for window "below"
*/
Constraint *next;
/* used to create the graph. */
GSList *next_nodes;
/* constraint has been applied, used
* to detect cycles.
*/
unsigned int applied : 1;
/* constraint has a previous node in the graph,
* used to find places to start in the graph.
* (I think this also has the side effect
* of preventing cycles, since cycles will
* have no starting point - so maybe
* the "applied" flag isn't needed.)
*/
unsigned int has_prev : 1;
};
/* We index the array of constraints by window
* stack positions, just because the stack
* positions are a convenient index.
*/
static void
add_constraint (Constraint **constraints,
MetaWindow *above,
MetaWindow *below)
{
Constraint *c;
g_assert (above->screen == below->screen);
/* check if constraint is a duplicate */
c = constraints[below->stack_position];
while (c != NULL)
{
if (c->above == above)
return;
c = c->next;
}
/* if not, add the constraint */
c = g_new (Constraint, 1);
c->above = above;
c->below = below;
c->next = constraints[below->stack_position];
c->next_nodes = NULL;
c->applied = FALSE;
c->has_prev = FALSE;
constraints[below->stack_position] = c;
}
static void
create_constraints (Constraint **constraints,
GList *windows)
{
GList *tmp;
tmp = windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (!WINDOW_IN_STACK (w))
{
meta_topic (META_DEBUG_STACK, "Window %s not in the stack, not constraining it\n",
w->desc);
tmp = tmp->next;
continue;
}
if (WINDOW_TRANSIENT_FOR_WHOLE_GROUP (w))
{
GSList *group_windows;
GSList *tmp2;
MetaGroup *group;
group = meta_window_get_group (w);
if (group != NULL)
group_windows = meta_group_list_windows (group);
else
group_windows = NULL;
tmp2 = group_windows;
while (tmp2 != NULL)
{
MetaWindow *group_window = tmp2->data;
if (!WINDOW_IN_STACK (group_window) ||
w->screen != group_window->screen ||
group_window->override_redirect)
{
tmp2 = tmp2->next;
continue;
}
#if 0
/* old way of doing it */
if (!(meta_window_is_ancestor_of_transient (w, group_window)) &&
!WINDOW_TRANSIENT_FOR_WHOLE_GROUP (group_window)) /* note */;/*note*/
#else
/* better way I think, so transient-for-group are constrained
* only above non-transient-type windows in their group
*/
if (!WINDOW_HAS_TRANSIENT_TYPE (group_window))
#endif
{
meta_topic (META_DEBUG_STACK, "Constraining %s above %s as it's transient for its group\n",
w->desc, group_window->desc);
add_constraint (constraints, w, group_window);
}
tmp2 = tmp2->next;
}
g_slist_free (group_windows);
}
else if (w->xtransient_for != None &&
!w->transient_parent_is_root_window)
{
MetaWindow *parent;
parent =
meta_display_lookup_x_window (w->display, w->xtransient_for);
if (parent && WINDOW_IN_STACK (parent) &&
parent->screen == w->screen)
{
meta_topic (META_DEBUG_STACK, "Constraining %s above %s due to transiency\n",
w->desc, parent->desc);
add_constraint (constraints, w, parent);
}
}
tmp = tmp->next;
}
}
static void
graph_constraints (Constraint **constraints,
int n_constraints)
{
int i;
i = 0;
while (i < n_constraints)
{
Constraint *c;
/* If we have "A below B" and "B below C" then AB -> BC so we
* add BC to next_nodes in AB.
*/
c = constraints[i];
while (c != NULL)
{
Constraint *n;
g_assert (c->below->stack_position == i);
/* Constraints where ->above is below are our
* next_nodes and we are their previous
*/
n = constraints[c->above->stack_position];
while (n != NULL)
{
c->next_nodes = g_slist_prepend (c->next_nodes,
n);
/* c is a previous node of n */
n->has_prev = TRUE;
n = n->next;
}
c = c->next;
}
++i;
}
}
static void
free_constraints (Constraint **constraints,
int n_constraints)
{
int i;
i = 0;
while (i < n_constraints)
{
Constraint *c;
c = constraints[i];
while (c != NULL)
{
Constraint *next = c->next;
g_slist_free (c->next_nodes);
g_free (c);
c = next;
}
++i;
}
}
static void
ensure_above (MetaWindow *above,
MetaWindow *below)
{
if (WINDOW_HAS_TRANSIENT_TYPE(above) &&
above->layer < below->layer)
{
meta_topic (META_DEBUG_STACK,
"Promoting window %s from layer %u to %u due to contraint\n",
above->desc, above->layer, below->layer);
above->layer = below->layer;
}
if (above->stack_position < below->stack_position)
{
/* move above to below->stack_position bumping below down the stack */
meta_window_set_stack_position_no_sync (above, below->stack_position);
g_assert (below->stack_position + 1 == above->stack_position);
}
meta_topic (META_DEBUG_STACK, "%s above at %d > %s below at %d\n",
above->desc, above->stack_position,
below->desc, below->stack_position);
}
static void
traverse_constraint (Constraint *c)
{
GSList *tmp;
if (c->applied)
return;
ensure_above (c->above, c->below);
c->applied = TRUE;
tmp = c->next_nodes;
while (tmp != NULL)
{
traverse_constraint (tmp->data);
tmp = tmp->next;
}
}
static void
apply_constraints (Constraint **constraints,
int n_constraints)
{
GSList *heads;
GSList *tmp;
int i;
/* List all heads in an ordered constraint chain */
heads = NULL;
i = 0;
while (i < n_constraints)
{
Constraint *c;
c = constraints[i];
while (c != NULL)
{
if (!c->has_prev)
heads = g_slist_prepend (heads, c);
c = c->next;
}
++i;
}
/* Now traverse the chain and apply constraints */
tmp = heads;
while (tmp != NULL)
{
Constraint *c = tmp->data;
traverse_constraint (c);
tmp = tmp->next;
}
g_slist_free (heads);
}
/**
* stack_do_window_deletions:
*
* Go through "deleted" and take the matching windows
* out of "windows".
*/
static void
stack_do_window_deletions (MetaStack *stack)
{
/* Do removals before adds, with paranoid idea that we might re-add
* the same window IDs.
*/
GList *tmp;
int i;
tmp = stack->removed;
while (tmp != NULL)
{
Window xwindow;
xwindow = GPOINTER_TO_UINT (tmp->data);
/* We go from the end figuring removals are more
* likely to be recent.
*/
i = stack->xwindows->len;
while (i > 0)
{
--i;
/* there's no guarantee we'll actually find windows to
* remove, e.g. the same xwindow could have been
* added/removed before we ever synced, and we put
* both the window->xwindow and window->frame->xwindow
* in the removal list.
*/
if (xwindow == g_array_index (stack->xwindows, Window, i))
{
g_array_remove_index (stack->xwindows, i);
goto next;
}
}
next:
tmp = tmp->next;
}
g_list_free (stack->removed);
stack->removed = NULL;
}
static void
stack_do_window_additions (MetaStack *stack)
{
GList *tmp;
gint i, n_added;
n_added = g_list_length (stack->added);
if (n_added > 0)
{
Window *end;
int old_size;
meta_topic (META_DEBUG_STACK,
"Adding %d windows to sorted list\n",
n_added);
old_size = stack->xwindows->len;
g_array_set_size (stack->xwindows, old_size + n_added);
end = &g_array_index (stack->xwindows, Window, old_size);
/* stack->added has the most recent additions at the
* front of the list, so we need to reverse it
*/
stack->added = g_list_reverse (stack->added);
i = 0;
tmp = stack->added;
while (tmp != NULL)
{
MetaWindow *w;
w = tmp->data;
end[i] = w->xwindow;
/* add to the main list */
stack->sorted = g_list_prepend (stack->sorted, w);
++i;
tmp = tmp->next;
}
stack->need_resort = TRUE; /* may not be needed as we add to top */
stack->need_constrain = TRUE;
stack->need_relayer = TRUE;
}
g_list_free (stack->added);
stack->added = NULL;
}
/**
* stack_do_relayer:
*
* Update the layers that windows are in
*/
static void
stack_do_relayer (MetaStack *stack)
{
GList *tmp;
if (!stack->need_relayer)
return;
meta_topic (META_DEBUG_STACK,
"Recomputing layers\n");
tmp = stack->sorted;
while (tmp != NULL)
{
MetaWindow *w;
MetaStackLayer old_layer;
w = tmp->data;
old_layer = w->layer;
compute_layer (w);
if (w->layer != old_layer)
{
meta_topic (META_DEBUG_STACK,
"Window %s moved from layer %u to %u\n",
w->desc, old_layer, w->layer);
stack->need_resort = TRUE;
stack->need_constrain = TRUE;
/* don't need to constrain as constraining
* purely operates in terms of stack_position
* not layer
*/
}
tmp = tmp->next;
}
stack->need_relayer = FALSE;
}
/**
* stack_do_constrain:
*
* Update stack_position and layer to reflect transiency
* constraints
*/
static void
stack_do_constrain (MetaStack *stack)
{
Constraint **constraints;
/* It'd be nice if this were all faster, probably */
if (!stack->need_constrain)
return;
meta_topic (META_DEBUG_STACK,
"Reapplying constraints\n");
constraints = g_new0 (Constraint*,
stack->n_positions);
create_constraints (constraints, stack->sorted);
graph_constraints (constraints, stack->n_positions);
apply_constraints (constraints, stack->n_positions);
free_constraints (constraints, stack->n_positions);
g_free (constraints);
stack->need_constrain = FALSE;
}
/**
* stack_do_resort:
*
* Sort stack->sorted with layers having priority over stack_position.
*/
static void
stack_do_resort (MetaStack *stack)
{
if (!stack->need_resort)
return;
meta_topic (META_DEBUG_STACK,
"Sorting stack list\n");
stack->sorted = g_list_sort (stack->sorted,
(GCompareFunc) compare_window_position);
stack->need_resort = FALSE;
}
/**
* stack_ensure_sorted:
*
* Puts the stack into canonical form.
*
* Honour the removed and added lists of the stack, and then recalculate
* all the layers (if the flag is set), re-run all the constraint calculations
* (if the flag is set), and finally re-sort the stack (if the flag is set,
* and if it wasn't already it might have become so during all the previous
* activity).
*/
static void
stack_ensure_sorted (MetaStack *stack)
{
stack_do_window_deletions (stack);
stack_do_window_additions (stack);
stack_do_relayer (stack);
stack_do_constrain (stack);
stack_do_resort (stack);
}
static MetaStackWindow *
find_top_most_managed_window (MetaScreen *screen,
const MetaStackWindow *ignore)
{
MetaStackTracker *stack_tracker = screen->stack_tracker;
MetaStackWindow *windows;
int n_windows;
int i;
meta_stack_tracker_get_stack (stack_tracker,
&windows, &n_windows);
/* Children are in order from bottom to top. We want to
* find the topmost managed child, then configure
* our window to be above it.
*/
for (i = n_windows -1; i >= 0; i--)
{
MetaStackWindow *other_window = &windows[i];
if (other_window->any.type == ignore->any.type &&
((other_window->any.type == META_WINDOW_CLIENT_TYPE_X11 &&
other_window->x11.xwindow == ignore->x11.xwindow) ||
other_window->wayland.meta_window == ignore->wayland.meta_window))
{
/* Do nothing. This means we're already the topmost managed
* window, but it DOES NOT mean we are already just above
* the topmost managed window. This is important because if
* an override redirect window is up, and we map a new
* managed window, the new window is probably above the old
* popup by default, and we want to push it below that
* popup. So keep looking for a sibling managed window
* to be moved below.
*/
}
else
{
if (other_window->any.type == META_WINDOW_CLIENT_TYPE_X11)
{
MetaWindow *other = meta_display_lookup_x_window (screen->display,
other_window->x11.xwindow);
if (other != NULL && !other->override_redirect)
return other_window;
}
else
{
/* All wayland windows are currently considered "managed"
* TODO: consider wayland pop-up windows like override
* redirect windows here. */
return other_window;
}
}
}
return NULL;
}
/* When moving an X window we sometimes need an X based sibling.
*
* If the given sibling is X based this function returns it back
* otherwise it searches downwards looking for the nearest X window.
*
* If no X based sibling could be found return NULL. */
static MetaStackWindow *
find_x11_sibling_downwards (MetaScreen *screen,
MetaStackWindow *sibling)
{
MetaStackTracker *stack_tracker = screen->stack_tracker;
MetaStackWindow *windows;
int n_windows;
int i;
if (sibling->any.type == META_WINDOW_CLIENT_TYPE_X11)
return sibling;
meta_stack_tracker_get_stack (stack_tracker,
&windows, &n_windows);
/* NB: Children are in order from bottom to top and we
* want to search downwards for the nearest X window.
*/
for (i = n_windows - 1; i >= 0; i--)
if (meta_stack_window_equal (&windows[i], sibling))
break;
for (; i >= 0; i--)
{
if (windows[i].any.type == META_WINDOW_CLIENT_TYPE_X11)
return &windows[i];
}
return NULL;
}
/**
* raise_window_relative_to_managed_windows:
*
* This function is used to avoid raising a window above popup
* menus and other such things.
*
* The key to the operation of this function is that we are expecting
* at most one window to be added at a time. If xwindow is newly added,
* then its own stack position will be too high (the frame window
* is created at the top of the stack), but if we ignore xwindow,
* then the *next* managed window in the stack will be a window that
* we've already stacked.
*
* We could generalize this and remove the assumption that windows
* are added one at a time by keeping an explicit ->stacked flag in
* MetaWindow.
*
* An alternate approach would be to reverse the stacking algorithm to
* work by placing each window above the others, and start by lowering
* a window to the bottom (instead of the current way, which works by
* placing each window below another and starting with a raise)
*/
static void
raise_window_relative_to_managed_windows (MetaScreen *screen,
const MetaStackWindow *window)
{
gulong serial = 0;
MetaStackWindow *sibling;
sibling = find_top_most_managed_window (screen, window);
if (!sibling)
{
if (window->any.type == META_WINDOW_CLIENT_TYPE_X11)
{
serial = XNextRequest (screen->display->xdisplay);
meta_error_trap_push (screen->display);
XLowerWindow (screen->display->xdisplay,
window->x11.xwindow);
meta_error_trap_pop (screen->display);
}
/* No sibling to use, just lower ourselves to the bottom
* to be sure we're below any override redirect windows.
*/
meta_stack_tracker_record_lower (screen->stack_tracker,
window,
serial);
return;
}
/* window is the topmost managed child */
meta_topic (META_DEBUG_STACK,
"Moving 0x%lx above topmost managed child window 0x%lx\n",
window->any.type == META_WINDOW_CLIENT_TYPE_X11 ? window->x11.xwindow: 0,
sibling->any.type == META_WINDOW_CLIENT_TYPE_X11 ? sibling->x11.xwindow: 0);
if (window->any.type == META_WINDOW_CLIENT_TYPE_X11)
{
XWindowChanges changes;
MetaStackWindow *x11_sibling = find_x11_sibling_downwards (screen, sibling);
serial = XNextRequest (screen->display->xdisplay);
if (x11_sibling)
{
changes.sibling = x11_sibling->x11.xwindow;
changes.stack_mode = Above;
meta_error_trap_push (screen->display);
XConfigureWindow (screen->display->xdisplay,
window->x11.xwindow,
CWSibling | CWStackMode,
&changes);
meta_error_trap_pop (screen->display);
}
else
{
/* No sibling to use, just lower ourselves to the bottom
* to be sure we're below any override redirect windows.
*/
meta_error_trap_push (screen->display);
XLowerWindow (screen->display->xdisplay,
window->x11.xwindow);
meta_error_trap_pop (screen->display);
}
}
meta_stack_tracker_record_raise_above (screen->stack_tracker,
window,
sibling,
serial);
}
/**
* stack_sync_to_server:
*
* Order the windows on the X server to be the same as in our structure.
* We do this using XRestackWindows if we don't know the previous order,
* or XConfigureWindow on a few particular windows if we do and can figure
* out the minimum set of changes. After that, we set __NET_CLIENT_LIST
* and __NET_CLIENT_LIST_STACKING.
*
* FIXME: Now that we have a good view of the stacking order on the server
* with MetaStackTracker it should be possible to do a simpler and better
* job of computing the minimal set of stacking requests needed.
*/
static void
stack_sync_to_xserver (MetaStack *stack)
{
GArray *x11_stacked;
GArray *x11_root_children_stacked;
GArray *all_root_children_stacked; /* wayland OR x11 */
GList *tmp;
GArray *x11_hidden;
GArray *x11_hidden_stack_windows;
int n_override_redirect = 0;
MetaStackWindow guard_stack_window;
/* Bail out if frozen */
if (stack->freeze_count > 0)
return;
meta_topic (META_DEBUG_STACK, "Syncing window stack to server\n");
stack_ensure_sorted (stack);
/* Create stacked xwindow arrays.
* Painfully, "stacked" is in bottom-to-top order for the
* _NET hints, and "root_children_stacked" is in top-to-bottom
* order for XRestackWindows()
*/
x11_stacked = g_array_new (FALSE, FALSE, sizeof (Window));
all_root_children_stacked = g_array_new (FALSE, FALSE, sizeof (MetaStackWindow));
x11_root_children_stacked = g_array_new (FALSE, FALSE, sizeof (Window));
x11_hidden_stack_windows = g_array_new (FALSE, FALSE, sizeof (MetaStackWindow));
x11_hidden = g_array_new (FALSE, FALSE, sizeof (Window));
/* The screen guard window sits above all hidden windows and acts as
* a barrier to input reaching these windows. */
g_array_append_val (x11_hidden, stack->screen->guard_window);
meta_topic (META_DEBUG_STACK, "Top to bottom: ");
meta_push_no_msg_prefix ();
for (tmp = stack->sorted; tmp != NULL; tmp = tmp->next)
{
MetaWindow *w = tmp->data;
Window top_level_window;
MetaStackWindow stack_window;
stack_window.any.type = w->client_type;
meta_topic (META_DEBUG_STACK, "%u:%d - %s ",
w->layer, w->stack_position, w->desc);
/* remember, stacked is in reverse order (bottom to top) */
if (w->override_redirect)
n_override_redirect++;
else
g_array_prepend_val (x11_stacked, w->xwindow);
if (w->frame)
top_level_window = w->frame->xwindow;
else
top_level_window = w->xwindow;
if (w->client_type == META_WINDOW_CLIENT_TYPE_X11)
stack_window.x11.xwindow = top_level_window;
else
stack_window.wayland.meta_window = w;
/* We don't restack hidden windows along with the rest, though they are
* reflected in the _NET hints. Hidden windows all get pushed below
* the screens fullscreen guard_window. */
if (w->hidden)
{
if (w->client_type == META_WINDOW_CLIENT_TYPE_X11)
{
MetaStackWindow stack_window;
stack_window.any.type = META_WINDOW_CLIENT_TYPE_X11;
stack_window.x11.xwindow = top_level_window;
g_array_append_val (x11_hidden_stack_windows, stack_window);
g_array_append_val (x11_hidden, top_level_window);
}
continue;
}
g_array_append_val (all_root_children_stacked, stack_window);
/* build XRestackWindows() array from top to bottom */
if (w->client_type == META_WINDOW_CLIENT_TYPE_X11)
g_array_append_val (x11_root_children_stacked, top_level_window);
else
{
MetaStackWindow *new;
/* So we can determine later if a cached stack window is
* stale because the corresponding window has been freed we
* associate a weak pointer with the new window. */
new = &g_array_index (all_root_children_stacked, MetaStackWindow, all_root_children_stacked->len - 1);
}
}
meta_topic (META_DEBUG_STACK, "\n");
meta_pop_no_msg_prefix ();
/* All X windows should be in some stacking order */
if (x11_stacked->len != stack->xwindows->len - n_override_redirect)
meta_bug ("%u windows stacked, %u windows exist in stack\n",
x11_stacked->len, stack->xwindows->len);
/* Sync to server */
meta_topic (META_DEBUG_STACK, "Restacking %u windows\n",
all_root_children_stacked->len);
meta_error_trap_push (stack->screen->display);
if (stack->last_all_root_children_stacked == NULL)
{
/* Just impose our stack, we don't know the previous state.
* This involves a ton of circulate requests and may flicker.
*/
meta_topic (META_DEBUG_STACK, "Don't know last stack state, restacking everything\n");
if (all_root_children_stacked->len > 1)
{
gulong serial = 0;
if (x11_root_children_stacked->len > 1)
{
serial = XNextRequest (stack->screen->display->xdisplay);
XRestackWindows (stack->screen->display->xdisplay,
(Window *) x11_root_children_stacked->data,
x11_root_children_stacked->len);
}
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
(MetaStackWindow *) all_root_children_stacked->data,
all_root_children_stacked->len,
serial);
}
}
else if (all_root_children_stacked->len > 0)
{
/* Try to do minimal window moves to get the stack in order */
/* A point of note: these arrays include frames not client windows,
* so if a client window has changed frame since last_root_children_stacked
* was saved, then we may have inefficiency, but I don't think things
* break...
*/
const MetaStackWindow *old_stack = (MetaStackWindow *) stack->last_all_root_children_stacked->data;
const MetaStackWindow *new_stack = (MetaStackWindow *) all_root_children_stacked->data;
const int old_len = stack->last_all_root_children_stacked->len;
const int new_len = all_root_children_stacked->len;
const MetaStackWindow *oldp = old_stack;
const MetaStackWindow *newp = new_stack;
const MetaStackWindow *old_end = old_stack + old_len;
const MetaStackWindow *new_end = new_stack + new_len;
Window last_xwindow = None;
const MetaStackWindow *last_window = NULL;
while (oldp != old_end &&
newp != new_end)
{
if (meta_stack_window_equal (oldp, newp))
{
/* Stacks are the same here, move on */
++oldp;
if (newp->any.type == META_WINDOW_CLIENT_TYPE_X11)
last_xwindow = newp->x11.xwindow;
last_window = newp;
++newp;
}
else if ((oldp->any.type == META_WINDOW_CLIENT_TYPE_X11 &&
meta_display_lookup_x_window (stack->screen->display,
oldp->x11.xwindow) == NULL) ||
(oldp->any.type == META_WINDOW_CLIENT_TYPE_WAYLAND &&
oldp->wayland.meta_window == NULL))
{
/* *oldp is no longer known to us (probably destroyed),
* so we can just skip it
*/
++oldp;
}
else
{
/* Move *newp below the last_window */
if (!last_window)
{
meta_topic (META_DEBUG_STACK, "Using window 0x%lx as topmost (but leaving it in-place)\n",
newp->x11.xwindow);
raise_window_relative_to_managed_windows (stack->screen, newp);
}
else if (newp->any.type == META_WINDOW_CLIENT_TYPE_X11 &&
last_xwindow == None)
{
/* In this case we have an X window that we need to
* put below a wayland window and this is the
* topmost X window. */
/* In X terms (because this is the topmost X window)
* we want to
* raise_window_relative_to_managed_windows() to
* ensure the X window is below override-redirect
* pop-up windows.
*
* In Wayland terms we just want to ensure
* newp is lowered below last_window (which
* notably doesn't require an X request because we
* know last_window isn't an X window).
*/
raise_window_relative_to_managed_windows (stack->screen, newp);
meta_stack_tracker_record_lower_below (stack->screen->stack_tracker,
newp, last_window,
0); /* no x request serial */
}
else
{
gulong serial = 0;
/* This means that if last_xwindow is dead, but not
* *newp, then we fail to restack *newp; but on
* unmanaging last_xwindow, we'll fix it up.
*/
meta_topic (META_DEBUG_STACK, "Placing window 0x%lx below 0x%lx\n",
newp->any.type == META_WINDOW_CLIENT_TYPE_X11 ? newp->x11.xwindow : 0,
last_xwindow);
if (newp->any.type == META_WINDOW_CLIENT_TYPE_X11)
{
XWindowChanges changes;
serial = XNextRequest (stack->screen->display->xdisplay);
changes.sibling = last_xwindow;
changes.stack_mode = Below;
XConfigureWindow (stack->screen->display->xdisplay,
newp->x11.xwindow,
CWSibling | CWStackMode,
&changes);
}
meta_stack_tracker_record_lower_below (stack->screen->stack_tracker,
newp, last_window,
serial);
}
if (newp->any.type == META_WINDOW_CLIENT_TYPE_X11)
last_xwindow = newp->x11.xwindow;
last_window = newp;
++newp;
}
}
if (newp != new_end)
{
const MetaStackWindow *x_ref;
unsigned long serial = 0;
/* Restack remaining windows */
meta_topic (META_DEBUG_STACK, "Restacking remaining %d windows\n",
(int) (new_end - newp));
/* rewind until we find the last stacked X window that we can use
* as a reference point for re-stacking remaining X windows */
if (newp != new_stack)
for (x_ref = newp - 1;
x_ref->any.type != META_WINDOW_CLIENT_TYPE_X11 && x_ref > new_stack;
x_ref--)
;
else
x_ref = new_stack;
/* If we didn't find an X window looking backwards then walk forwards
* through the remaining windows to find the first remaining X window
* instead. */
if (x_ref->any.type != META_WINDOW_CLIENT_TYPE_X11)
{
for (x_ref = newp;
x_ref->any.type != META_WINDOW_CLIENT_TYPE_X11 && x_ref > new_stack;
x_ref++)
;
}
/* If there are any X windows remaining unstacked then restack them */
if (x_ref->any.type == META_WINDOW_CLIENT_TYPE_X11)
{
int i;
for (i = x11_root_children_stacked->len - 1; i; i--)
{
Window *reference = &g_array_index (x11_root_children_stacked, Window, i);
if (*reference == x_ref->x11.xwindow)
{
int n = x11_root_children_stacked->len - i;
/* There's no point restacking if there's only one X window */
if (n == 1)
break;
serial = XNextRequest (stack->screen->display->xdisplay);
XRestackWindows (stack->screen->display->xdisplay,
reference, n);
break;
}
}
}
/* We need to include an already-stacked window
* in the restack call, so we get in the proper position
* with respect to it.
*/
if (newp != new_stack)
newp = MIN (newp - 1, x_ref);
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
newp, new_end - newp,
serial);
}
}
/* Push hidden X windows to the bottom of the stack under the guard window */
guard_stack_window.any.type = META_WINDOW_CLIENT_TYPE_X11;
guard_stack_window.x11.xwindow = stack->screen->guard_window;
meta_stack_tracker_record_lower (stack->screen->stack_tracker,
&guard_stack_window,
XNextRequest (stack->screen->display->xdisplay));
XLowerWindow (stack->screen->display->xdisplay, stack->screen->guard_window);
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
(MetaStackWindow *)x11_hidden_stack_windows->data,
x11_hidden_stack_windows->len,
XNextRequest (stack->screen->display->xdisplay));
XRestackWindows (stack->screen->display->xdisplay,
(Window *)x11_hidden->data,
x11_hidden->len);
g_array_free (x11_hidden, TRUE);
g_array_free (x11_hidden_stack_windows, TRUE);
meta_error_trap_pop (stack->screen->display);
/* on error, a window was destroyed; it should eventually
* get removed from the stacking list when we unmanage it
* and we'll fix stacking at that time.
*/
/* Sync _NET_CLIENT_LIST and _NET_CLIENT_LIST_STACKING */
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST,
XA_WINDOW,
32, PropModeReplace,
(unsigned char *)stack->xwindows->data,
stack->xwindows->len);
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST_STACKING,
XA_WINDOW,
32, PropModeReplace,
(unsigned char *)x11_stacked->data,
x11_stacked->len);
g_array_free (x11_stacked, TRUE);
if (stack->last_all_root_children_stacked)
free_last_all_root_children_stacked_cache (stack);
stack->last_all_root_children_stacked = all_root_children_stacked;
g_array_free (x11_root_children_stacked, TRUE);
/* That was scary... */
}
MetaWindow*
meta_stack_get_top (MetaStack *stack)
{
stack_ensure_sorted (stack);
if (stack->sorted)
return stack->sorted->data;
else
return NULL;
}
MetaWindow*
meta_stack_get_bottom (MetaStack *stack)
{
GList *link;
stack_ensure_sorted (stack);
link = g_list_last (stack->sorted);
if (link != NULL)
return link->data;
else
return NULL;
}
MetaWindow*
meta_stack_get_above (MetaStack *stack,
MetaWindow *window,
gboolean only_within_layer)
{
GList *link;
MetaWindow *above;
stack_ensure_sorted (stack);
link = g_list_find (stack->sorted, window);
if (link == NULL)
return NULL;
if (link->prev == NULL)
return NULL;
above = link->prev->data;
if (only_within_layer &&
above->layer != window->layer)
return NULL;
else
return above;
}
MetaWindow*
meta_stack_get_below (MetaStack *stack,
MetaWindow *window,
gboolean only_within_layer)
{
GList *link;
MetaWindow *below;
stack_ensure_sorted (stack);
link = g_list_find (stack->sorted, window);
if (link == NULL)
return NULL;
if (link->next == NULL)
return NULL;
below = link->next->data;
if (only_within_layer &&
below->layer != window->layer)
return NULL;
else
return below;
}
static gboolean
window_contains_point (MetaWindow *window,
int root_x,
int root_y)
{
MetaRectangle rect;
meta_window_get_frame_rect (window, &rect);
return POINT_IN_RECT (root_x, root_y, rect);
}
static MetaWindow*
get_default_focus_window (MetaStack *stack,
MetaWorkspace *workspace,
MetaWindow *not_this_one,
gboolean must_be_at_point,
int root_x,
int root_y)
{
/* Find the topmost, focusable, mapped, window.
* not_this_one is being unfocused or going away, so exclude it.
* Also, prefer to focus transient parent of not_this_one,
* or top window in same group as not_this_one.
*/
MetaWindow *transient_parent;
MetaWindow *topmost_in_group;
MetaWindow *topmost_overall;
MetaGroup *not_this_one_group;
GList *link;
transient_parent = NULL;
topmost_in_group = NULL;
topmost_overall = NULL;
if (not_this_one)
not_this_one_group = meta_window_get_group (not_this_one);
else
not_this_one_group = NULL;
stack_ensure_sorted (stack);
/* top of this layer is at the front of the list */
link = stack->sorted;
while (link)
{
MetaWindow *window = link->data;
if (window &&
window != not_this_one &&
(window->unmaps_pending == 0) &&
!window->minimized &&
(window->input || window->take_focus) &&
(workspace == NULL ||
meta_window_located_on_workspace (window, workspace)))
{
if (not_this_one != NULL)
{
if (transient_parent == NULL &&
not_this_one->xtransient_for != None &&
not_this_one->xtransient_for == window->xwindow &&
(!must_be_at_point ||
window_contains_point (window, root_x, root_y)))
transient_parent = window;
if (topmost_in_group == NULL &&
not_this_one_group != NULL &&
not_this_one_group == meta_window_get_group (window) &&
(!must_be_at_point ||
window_contains_point (window, root_x, root_y)))
topmost_in_group = window;
}
if (topmost_overall == NULL &&
window->type != META_WINDOW_DOCK &&
(!must_be_at_point ||
window_contains_point (window, root_x, root_y)))
topmost_overall = window;
/* We could try to bail out early here for efficiency in
* some cases, but it's just not worth the code.
*/
}
link = link->next;
}
if (transient_parent)
return transient_parent;
else if (topmost_in_group)
return topmost_in_group;
else if (topmost_overall)
return topmost_overall;
else
return NULL;
}
MetaWindow*
meta_stack_get_default_focus_window_at_point (MetaStack *stack,
MetaWorkspace *workspace,
MetaWindow *not_this_one,
int root_x,
int root_y)
{
return get_default_focus_window (stack, workspace, not_this_one,
TRUE, root_x, root_y);
}
MetaWindow*
meta_stack_get_default_focus_window (MetaStack *stack,
MetaWorkspace *workspace,
MetaWindow *not_this_one)
{
return get_default_focus_window (stack, workspace, not_this_one,
FALSE, 0, 0);
}
GList*
meta_stack_list_windows (MetaStack *stack,
MetaWorkspace *workspace)
{
GList *workspace_windows = NULL;
GList *link;
stack_ensure_sorted (stack); /* do adds/removes */
link = stack->sorted;
while (link)
{
MetaWindow *window = link->data;
if (window &&
(workspace == NULL || meta_window_located_on_workspace (window, workspace)))
{
workspace_windows = g_list_prepend (workspace_windows,
window);
}
link = link->next;
}
return workspace_windows;
}
int
meta_stack_windows_cmp (MetaStack *stack,
MetaWindow *window_a,
MetaWindow *window_b)
{
g_return_val_if_fail (window_a->screen == window_b->screen, 0);
/* -1 means a below b */
stack_ensure_sorted (stack); /* update constraints, layers */
if (window_a->layer < window_b->layer)
return -1;
else if (window_a->layer > window_b->layer)
return 1;
else if (window_a->stack_position < window_b->stack_position)
return -1;
else if (window_a->stack_position > window_b->stack_position)
return 1;
else
return 0; /* not reached */
}
static int
compare_just_window_stack_position (void *a,
void *b)
{
MetaWindow *window_a = a;
MetaWindow *window_b = b;
if (window_a->stack_position < window_b->stack_position)
return -1; /* move window_a earlier in list */
else if (window_a->stack_position > window_b->stack_position)
return 1;
else
return 0; /* not reached */
}
GList*
meta_stack_get_positions (MetaStack *stack)
{
GList *tmp;
/* Make sure to handle any adds or removes */
stack_ensure_sorted (stack);
tmp = g_list_copy (stack->sorted);
tmp = g_list_sort (tmp, (GCompareFunc) compare_just_window_stack_position);
return tmp;
}
static gint
compare_pointers (gconstpointer a,
gconstpointer b)
{
if (a > b)
return 1;
else if (a < b)
return -1;
else
return 0;
}
static gboolean
lists_contain_same_windows (GList *a,
GList *b)
{
GList *copy1, *copy2;
GList *tmp1, *tmp2;
if (g_list_length (a) != g_list_length (b))
return FALSE;
tmp1 = copy1 = g_list_sort (g_list_copy (a), compare_pointers);
tmp2 = copy2 = g_list_sort (g_list_copy (b), compare_pointers);
while (tmp1 && tmp1->data == tmp2->data) /* tmp2 is non-NULL if tmp1 is */
{
tmp1 = tmp1->next;
tmp2 = tmp2->next;
}
g_list_free (copy1);
g_list_free (copy2);
return (tmp1 == NULL); /* tmp2 is non-NULL if tmp1 is */
}
void
meta_stack_set_positions (MetaStack *stack,
GList *windows)
{
int i;
GList *tmp;
/* Make sure any adds or removes aren't in limbo -- is this needed? */
stack_ensure_sorted (stack);
if (!lists_contain_same_windows (windows, stack->sorted))
{
meta_warning ("This list of windows has somehow changed; not resetting "
"positions of the windows.\n");
return;
}
g_list_free (stack->sorted);
stack->sorted = g_list_copy (windows);
stack->need_resort = TRUE;
stack->need_constrain = TRUE;
i = 0;
tmp = windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
w->stack_position = i++;
tmp = tmp->next;
}
meta_topic (META_DEBUG_STACK,
"Reset the stack positions of (nearly) all windows\n");
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, NULL);
}
void
meta_window_set_stack_position_no_sync (MetaWindow *window,
int position)
{
int low, high, delta;
GList *tmp;
g_return_if_fail (window->screen->stack != NULL);
g_return_if_fail (window->stack_position >= 0);
g_return_if_fail (position >= 0);
g_return_if_fail (position < window->screen->stack->n_positions);
if (position == window->stack_position)
{
meta_topic (META_DEBUG_STACK, "Window %s already has position %d\n",
window->desc, position);
return;
}
window->screen->stack->need_resort = TRUE;
window->screen->stack->need_constrain = TRUE;
if (position < window->stack_position)
{
low = position;
high = window->stack_position - 1;
delta = 1;
}
else
{
low = window->stack_position + 1;
high = position;
delta = -1;
}
tmp = window->screen->stack->sorted;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (w->stack_position >= low &&
w->stack_position <= high)
w->stack_position += delta;
tmp = tmp->next;
}
window->stack_position = position;
meta_topic (META_DEBUG_STACK,
"Window %s had stack_position set to %d\n",
window->desc, window->stack_position);
}
void
meta_window_set_stack_position (MetaWindow *window,
int position)
{
meta_window_set_stack_position_no_sync (window, position);
stack_sync_to_xserver (window->screen->stack);
meta_stack_update_window_tile_matches (window->screen->stack,
window->screen->active_workspace);
}