mutter/src/core/stack.c

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/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/*
* SECTION:stack
* @short_description: Which windows cover which other windows
*/
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/*
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* Copyright (C) 2001 Havoc Pennington
* Copyright (C) 2002, 2003 Red Hat, Inc.
* Copyright (C) 2004 Rob Adams
* Copyright (C) 2004, 2005 Elijah Newren
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*
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* 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.
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*
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* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
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*/
#include <config.h>
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#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>
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#include <X11/Xatom.h>
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#include "x11/group-private.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) \
(WINDOW_HAS_TRANSIENT_TYPE (w) && w->transient_for == NULL)
#define WINDOW_IN_STACK(w) (w->stack_position >= 0)
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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static void stack_sync_to_xserver (MetaStack *stack);
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
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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);
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MetaStack*
meta_stack_new (MetaScreen *screen)
{
MetaStack *stack;
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stack = g_new (MetaStack, 1);
stack->screen = screen;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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stack->xwindows = g_array_new (FALSE, FALSE, sizeof (Window));
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stack->sorted = NULL;
stack->added = NULL;
stack->removed = NULL;
stack->freeze_count = 0;
stack->n_positions = 0;
stack->need_resort = FALSE;
stack->need_relayer = FALSE;
stack->need_constrain = FALSE;
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return stack;
}
void
meta_stack_free (MetaStack *stack)
{
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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g_array_free (stack->xwindows, TRUE);
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g_list_free (stack->sorted);
g_list_free (stack->added);
g_list_free (stack->removed);
g_free (stack);
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}
void
meta_stack_add (MetaStack *stack,
MetaWindow *window)
{
g_return_if_fail (!window->override_redirect);
meta_topic (META_DEBUG_STACK, "Adding window %s to the stack\n", window->desc);
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if (window->stack_position >= 0)
meta_bug ("Window %s had stack position already\n", window->desc);
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stack->added = g_list_prepend (stack->added, window);
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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);
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
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}
void
meta_stack_remove (MetaStack *stack,
MetaWindow *window)
{
meta_topic (META_DEBUG_STACK, "Removing window %s from the stack\n", window->desc);
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if (window->stack_position < 0)
meta_bug ("Window %s removed from stack but had no stack position\n",
window->desc);
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/* Set window to top position, so removing it will not leave gaps
* in the set of positions
*/
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
2004-06-24 11:47:05 -04:00
meta_window_set_stack_position_no_sync (window,
stack->n_positions - 1);
window->stack_position = -1;
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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));
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
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}
void
meta_stack_update_layer (MetaStack *stack,
MetaWindow *window)
{
stack->need_relayer = TRUE;
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
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}
void
meta_stack_update_transient (MetaStack *stack,
MetaWindow *window)
{
stack->need_constrain = TRUE;
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
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}
/* 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);
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
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}
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);
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, window->screen->active_workspace);
2001-06-10 03:27:11 -04:00
}
void
meta_stack_freeze (MetaStack *stack)
{
stack->freeze_count += 1;
}
void
meta_stack_thaw (MetaStack *stack)
{
g_return_if_fail (stack->freeze_count > 0);
2014-05-02 09:34:02 -04:00
2001-06-10 03:27:11 -04:00
stack->freeze_count -= 1;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
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);
2001-06-10 03:27:11 -04:00
}
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;
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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;
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max = META_LAYER_DESKTOP;
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group = meta_window_get_group (window);
if (group != NULL)
members = meta_group_list_windows (group);
else
members = NULL;
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tmp = members;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
if (!w->override_redirect)
{
layer = get_standalone_layer (w);
if (layer > max)
max = layer;
}
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tmp = tmp->next;
}
g_slist_free (members);
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return max;
}
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static void
compute_layer (MetaWindow *window)
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{
MetaStackLayer old_layer = window->layer;
window->layer = get_standalone_layer (window);
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/* 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->transient_for == NULL)
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{
/* 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.
*/
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MetaStackLayer group_max;
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group_max = get_maximum_layer_in_group (window);
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if (group_max > window->layer)
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{
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;
2001-06-10 15:23:28 -04:00
}
}
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);
}
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/* 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;
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/* 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;
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else
return 0; /* not reached */
}
2014-05-02 09:34:02 -04:00
/*
* Stacking constraints
2014-05-02 09:34:02 -04:00
*
* 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:
2014-05-02 09:34:02 -04:00
*
* 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:
2014-05-02 09:34:02 -04:00
*
* 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;
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/* 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);
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/* check if constraint is a duplicate */
c = constraints[below->stack_position];
while (c != NULL)
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{
if (c->above == above)
return;
c = c->next;
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}
/* 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;
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}
static void
create_constraints (Constraint **constraints,
GList *windows)
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{
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GList *tmp;
2014-05-02 09:34:02 -04:00
tmp = windows;
2001-06-10 15:23:28 -04:00
while (tmp != NULL)
2001-06-10 03:52:35 -04:00
{
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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;
}
2014-05-02 09:34:02 -04:00
if (WINDOW_TRANSIENT_FOR_WHOLE_GROUP (w))
{
GSList *group_windows;
GSList *tmp2;
MetaGroup *group;
2001-06-10 15:23:28 -04:00
group = meta_window_get_group (w);
if (group != NULL)
group_windows = meta_group_list_windows (group);
else
group_windows = NULL;
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tmp2 = group_windows;
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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;
}
2014-05-02 09:34:02 -04:00
#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);
}
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tmp2 = tmp2->next;
}
g_slist_free (group_windows);
}
else if (w->transient_for != NULL)
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{
MetaWindow *parent;
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parent = w->transient_for;
2001-06-10 15:23:28 -04:00
if (parent && WINDOW_IN_STACK (parent))
2001-06-10 15:23:28 -04:00
{
meta_topic (META_DEBUG_STACK, "Constraining %s above %s due to transiency\n",
w->desc, parent->desc);
add_constraint (constraints, w, parent);
2001-06-10 15:23:28 -04:00
}
}
2014-05-02 09:34:02 -04:00
2001-06-10 15:23:28 -04:00
tmp = tmp->next;
2001-06-10 03:52:35 -04:00
}
}
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.
*/
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c = constraints[i];
while (c != NULL)
{
Constraint *n;
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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;
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n = n->next;
}
2014-05-02 09:34:02 -04:00
c = c->next;
}
++i;
}
}
static void
free_constraints (Constraint **constraints,
int n_constraints)
{
int i;
i = 0;
while (i < n_constraints)
{
Constraint *c;
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c = constraints[i];
while (c != NULL)
{
Constraint *next = c->next;
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g_slist_free (c->next_nodes);
g_free (c);
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c = next;
}
++i;
}
}
static void
ensure_above (MetaWindow *above,
MetaWindow *below)
2014-05-02 09:34:02 -04:00
{
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 */
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
2004-06-24 11:47:05 -04:00
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;
2014-05-02 09:34:02 -04:00
ensure_above (c->above, c->below);
c->applied = TRUE;
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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;
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c = constraints[i];
while (c != NULL)
{
if (!c->has_prev)
heads = g_slist_prepend (heads, c);
2014-05-02 09:34:02 -04:00
c = c->next;
}
++i;
}
/* Now traverse the chain and apply constraints */
tmp = heads;
while (tmp != NULL)
{
Constraint *c = tmp->data;
traverse_constraint (c);
2014-05-02 09:34:02 -04:00
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;
2014-05-02 09:34:02 -04:00
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.
*/
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
i = stack->xwindows->len;
while (i > 0)
{
--i;
2014-05-02 09:34:02 -04:00
/* 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.
*/
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
if (xwindow == g_array_index (stack->xwindows, Window, i))
{
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
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);
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
old_size = stack->xwindows->len;
g_array_set_size (stack->xwindows, old_size + n_added);
2014-05-02 09:34:02 -04:00
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
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);
2014-05-02 09:34:02 -04:00
i = 0;
tmp = stack->added;
while (tmp != NULL)
{
MetaWindow *w;
2014-05-02 09:34:02 -04:00
w = tmp->data;
2014-05-02 09:34:02 -04:00
end[i] = w->xwindow;
/* add to the main list */
stack->sorted = g_list_prepend (stack->sorted, w);
2014-05-02 09:34:02 -04:00
++i;
tmp = tmp->next;
}
2014-05-02 09:34:02 -04:00
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;
2014-05-02 09:34:02 -04:00
if (!stack->need_relayer)
2014-08-19 14:03:43 -04:00
return;
2014-05-02 09:34:02 -04:00
meta_topic (META_DEBUG_STACK,
"Recomputing layers\n");
2014-05-02 09:34:02 -04:00
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
*/
}
2014-05-02 09:34:02 -04:00
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 */
2014-05-02 09:34:02 -04:00
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);
2014-05-02 09:34:02 -04:00
free_constraints (constraints, stack->n_positions);
g_free (constraints);
2014-05-02 09:34:02 -04:00
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;
2014-05-02 09:34:02 -04:00
meta_topic (META_DEBUG_STACK,
"Sorting stack list\n");
2014-05-02 09:34:02 -04:00
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);
2001-06-10 03:27:11 -04:00
}
/**
* 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.
*/
2001-06-10 03:27:11 -04:00
static void
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (MetaStack *stack)
2001-06-10 03:27:11 -04:00
{
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
GArray *x11_stacked;
GArray *all_root_children_stacked; /* wayland OR x11 */
GList *tmp;
GArray *x11_hidden_stack_ids;
2014-05-02 09:34:02 -04:00
2001-06-10 03:27:11 -04:00
/* Bail out if frozen */
if (stack->freeze_count > 0)
return;
2014-05-02 09:34:02 -04:00
meta_topic (META_DEBUG_STACK, "Syncing window stack to server\n");
2001-06-10 03:27:11 -04:00
stack_ensure_sorted (stack);
/* Create stacked xwindow arrays, in bottom-to-top order
2001-06-23 02:54:28 -04:00
*/
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
x11_stacked = g_array_new (FALSE, FALSE, sizeof (Window));
all_root_children_stacked = g_array_new (FALSE, FALSE, sizeof (guint64));
x11_hidden_stack_ids = g_array_new (FALSE, FALSE, sizeof (guint64));
/* 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_ids, stack->screen->guard_window);
meta_topic (META_DEBUG_STACK, "Top to bottom: ");
meta_push_no_msg_prefix ();
for (tmp = g_list_last(stack->sorted); tmp != NULL; tmp = tmp->prev)
2001-06-10 15:23:28 -04:00
{
MetaWindow *w = tmp->data;
Window top_level_window;
guint64 stack_id;
2014-05-02 09:34:02 -04:00
if (w->unmanaging)
continue;
meta_topic (META_DEBUG_STACK, "%u:%d - %s ",
w->layer, w->stack_position, w->desc);
g_array_append_val (x11_stacked, w->xwindow);
2014-05-02 09:34:02 -04:00
if (w->frame)
top_level_window = w->frame->xwindow;
else
top_level_window = w->xwindow;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
if (w->client_type == META_WINDOW_CLIENT_TYPE_X11)
stack_id = top_level_window;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
else
stack_id = w->stamp;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
/* 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)
{
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
if (w->client_type == META_WINDOW_CLIENT_TYPE_X11)
{
guint64 stack_id = top_level_window;
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
g_array_append_val (x11_hidden_stack_ids, stack_id);
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
}
continue;
}
g_array_append_val (all_root_children_stacked, stack_id);
2001-06-10 03:52:35 -04:00
}
meta_topic (META_DEBUG_STACK, "\n");
meta_pop_no_msg_prefix ();
2001-06-10 03:52:35 -04:00
2001-06-10 03:27:11 -04:00
/* Sync to server */
2001-06-10 03:52:35 -04:00
meta_topic (META_DEBUG_STACK, "Restacking %u windows\n",
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
all_root_children_stacked->len);
2014-05-02 09:34:02 -04:00
meta_stack_tracker_restack_managed (stack->screen->stack_tracker,
(guint64 *)all_root_children_stacked->data,
all_root_children_stacked->len);
meta_stack_tracker_restack_at_bottom (stack->screen->stack_tracker,
(guint64 *)x11_hidden_stack_ids->data,
x11_hidden_stack_ids->len);
2014-05-02 09:34:02 -04:00
2001-06-10 03:27:11 -04:00
/* Sync _NET_CLIENT_LIST and _NET_CLIENT_LIST_STACKING */
2001-06-10 03:52:35 -04:00
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST,
2001-06-10 15:23:28 -04:00
XA_WINDOW,
2001-06-10 03:52:35 -04:00
32, PropModeReplace,
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
(unsigned char *)stack->xwindows->data,
stack->xwindows->len);
2001-06-10 03:52:35 -04:00
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST_STACKING,
2001-06-10 15:23:28 -04:00
XA_WINDOW,
2001-06-10 03:52:35 -04:00
32, PropModeReplace,
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
(unsigned char *)x11_stacked->data,
x11_stacked->len);
g_array_free (x11_stacked, TRUE);
g_array_free (all_root_children_stacked, TRUE);
2001-06-10 03:27:11 -04:00
}
2001-06-23 23:18:10 -04:00
MetaWindow*
meta_stack_get_top (MetaStack *stack)
{
stack_ensure_sorted (stack);
if (stack->sorted)
return stack->sorted->data;
else
return NULL;
2001-06-23 23:18:10 -04:00
}
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;
2001-06-23 23:18:10 -04:00
}
MetaWindow*
meta_stack_get_above (MetaStack *stack,
MetaWindow *window,
gboolean only_within_layer)
2001-06-23 23:18:10 -04:00
{
GList *link;
MetaWindow *above;
2014-05-02 09:34:02 -04:00
stack_ensure_sorted (stack);
2014-05-02 09:34:02 -04:00
link = g_list_find (stack->sorted, window);
2001-06-23 23:18:10 -04:00
if (link == NULL)
return NULL;
if (link->prev == NULL)
return NULL;
above = link->prev->data;
2001-06-23 23:18:10 -04:00
if (only_within_layer &&
above->layer != window->layer)
return NULL;
2001-06-23 23:18:10 -04:00
else
return above;
2001-06-23 23:18:10 -04:00
}
MetaWindow*
meta_stack_get_below (MetaStack *stack,
MetaWindow *window,
gboolean only_within_layer)
2001-06-23 23:18:10 -04:00
{
GList *link;
MetaWindow *below;
2014-05-02 09:34:02 -04:00
stack_ensure_sorted (stack);
2001-06-23 23:18:10 -04:00
link = g_list_find (stack->sorted, window);
2001-06-23 23:18:10 -04:00
if (link == NULL)
return NULL;
if (link->next == NULL)
return NULL;
2014-05-02 09:34:02 -04:00
below = link->next->data;
2001-06-23 23:18:10 -04:00
if (only_within_layer &&
below->layer != window->layer)
return NULL;
2001-06-23 23:18:10 -04:00
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 *l;
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 */
for (l = stack->sorted; l != NULL; l = l->next)
{
MetaWindow *window = l->data;
if (!window)
continue;
if (window == not_this_one)
continue;
if (window->unmaps_pending > 0)
continue;
if (window->minimized)
continue;
if (window->unmanaging)
continue;
if (!(window->input || window->take_focus))
continue;
if (workspace != NULL && !meta_window_located_on_workspace (window, workspace))
continue;
if (must_be_at_point && !window_contains_point (window, root_x, root_y))
continue;
if (not_this_one != NULL)
{
if (transient_parent == NULL &&
meta_window_get_transient_for (not_this_one) == window)
transient_parent = window;
if (topmost_in_group == NULL &&
not_this_one_group != NULL &&
not_this_one_group == meta_window_get_group (window))
topmost_in_group = window;
}
if (topmost_overall == NULL && window->type != META_WINDOW_DOCK)
topmost_overall = window;
/* We could try to bail out early here for efficiency in
* some cases, but it's just not worth the code.
*/
}
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;
2001-06-23 23:18:10 -04:00
}
2001-06-23 23:41:44 -04:00
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;
2014-05-02 09:34:02 -04:00
stack_ensure_sorted (stack); /* do adds/removes */
2014-05-02 09:34:02 -04:00
link = stack->sorted;
2014-05-02 09:34:02 -04:00
while (link)
{
MetaWindow *window = link->data;
2014-05-02 09:34:02 -04:00
if (window &&
(workspace == NULL || meta_window_located_on_workspace (window, workspace)))
{
workspace_windows = g_list_prepend (workspace_windows,
window);
}
2014-05-02 09:34:02 -04:00
link = link->next;
}
return workspace_windows;
}
2001-06-24 04:09:10 -04:00
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 */
2014-05-02 09:34:02 -04:00
2001-06-24 04:09:10 -04:00
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;
2014-05-02 09:34:02 -04:00
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);
2014-05-02 09:34:02 -04:00
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;
2014-05-02 09:34:02 -04:00
i = 0;
tmp = windows;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
w->stack_position = i++;
tmp = tmp->next;
}
2014-05-02 09:34:02 -04:00
meta_topic (META_DEBUG_STACK,
"Reset the stack positions of (nearly) all windows\n");
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
2012-04-05 06:22:13 -04:00
stack_sync_to_xserver (stack);
meta_stack_update_window_tile_matches (stack, NULL);
}
void
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
2004-06-24 11:47:05 -04:00
meta_window_set_stack_position_no_sync (MetaWindow *window,
int position)
{
int low, high, delta;
GList *tmp;
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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;
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if (position < window->stack_position)
{
low = position;
high = window->stack_position - 1;
delta = 1;
}
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else
{
low = window->stack_position + 1;
high = position;
delta = -1;
}
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tmp = window->screen->stack->sorted;
while (tmp != NULL)
{
MetaWindow *w = tmp->data;
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if (w->stack_position >= low &&
w->stack_position <= high)
w->stack_position += delta;
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tmp = tmp->next;
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}
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window->stack_position = position;
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meta_topic (META_DEBUG_STACK,
"Window %s had stack_position set to %d\n",
window->desc, window->stack_position);
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}
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
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void
meta_window_set_stack_position (MetaWindow *window,
int position)
{
meta_window_set_stack_position_no_sync (window, position);
Add support for stacking X and Wayland windows together This breaks down the assumptions in stack-tracker.c and stack.c that Mutter is only stacking X windows. The stack tracker now tracks windows using a MetaStackWindow structure which is a union with a type member so that X windows can be distinguished from Wayland windows. Some notable changes are: Queued stack tracker operations that affect Wayland windows will not be associated with an X serial number. If an operation only affects a Wayland window and there are no queued stack tracker operations ("unvalidated predictions") then the operation is applied immediately since there is no server involved with changing the stacking for Wayland windows. The stack tracker can no longer respond to X events by turning them into stack operations and discarding the predicted operations made prior to that event because operations based on X events don't know anything about the stacking of Wayland windows. Instead of discarding old predictions the new approach is to trust the predictions but whenever we receive an event from the server that affects stacking we cross-reference with the predicted stack and check for consistency. So e.g. if we have an event that says ADD window A then we apply the predictions (up to the serial for that event) and verify the predicted state includes a window A. Similarly if an event says RAISE_ABOVE(B, C) we can apply the predictions (up to the serial for that event) and verify that window B is above C. If we ever receive spurious stacking events (with a serial older than we would expect) or find an inconsistency (some things aren't possible to predict from the compositor) then we hit a re-synchronization code-path that will query the X server for the full stacking order and then use that stack to walk through our combined stack and force the X windows to match the just queried stack but avoiding disrupting the relative stacking of Wayland windows. This will be relatively expensive but shouldn't be hit for compositor initiated restacking operations where our predictions should be accurate. The code in core/stack.c that deals with synchronizing the window stack with the X server had to be updated quite heavily. In general the patch avoids changing the fundamental approach being used but most of the code did need some amount of re-factoring to consider what re-stacking operations actually involve X or not and when we need to restack X windows we sometimes need to search for a suitable X sibling to restack relative too since the closest siblings may be Wayland windows.
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stack_sync_to_xserver (window->screen->stack);
meta_stack_update_window_tile_matches (window->screen->stack,
window->screen->active_workspace);
Add support for _NET_WM_USER_TIME 2004-06-17 Elijah Newren <newren@math.utah.edu> Add support for _NET_WM_USER_TIME * src/display.c: (meta_display_open): Add _NET_WM_USER_TIME to atom_names[], (event_callback): Manually set _NET_WM_USER_TIME upon KeyPress (doesn't work since keyboard isn't grabbed) and ButtonPress (does work), this is just a fallback for applications that don't update this themselves. * src/display.h: (struct _MetaDisplay): Add atom_net_wm_user_time field * src/screen.c: (meta_screen_apply_startup_properties): Check for TIMESTAMP provided from startup sequence as well. * src/stack.c: s/meta_window_set_stack_position/meta_window_set_stack_position_no_sync/, (meta_window_set_stack_position): New function which calls the meta_window_set_stack_position_no_sync function followed immediately by calling meta_stack_sync_to_server. * src/window-props.c: (init_net_wm_user_time), (reload_net_wm_user_time): new functions, (reload_wm_hints): also load atom_net_wm_user_time * src/window.c: new XSERVER_TIME_IS_LATER macro (accounts for timestamp wraparound), (meta_window_new_with_attrs): add timestamp attributes, (window_takes_focus_on_map): use TIMESTAMP from startup notification and _NET_WM_USER_TIME to decide whether to focus new windows, (meta_window_show): if app doesn't take focus on map, place it just below the focused window in the stack (process_property_notify): check for changes to _NET_WM_USRE_TIME, (meta_window_stack_just_below): new function * src/window.h: (_MetaWindow struct): new fields for initial_timestamp, initial_timestamp_set, net_wm_user_time_set, and net_wm_user_time, (meta_window_stack_just_below): new function
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}