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Sun Feb 15 12:02:59 1998 Alexandre Julliard <julliard@lrc.epfl.ch> * [graphics/x11drv/*.c] [objects/*.c] A few X11 critical section optimizations, mostly with XGet/PutPixel. * [scheduler/sysdeps.c] [misc/main.c] Make sure X11 critical section is available before any Xlib call. * [if1632/relay.c] [tools/build.c] Yet another attempt at fixing Catch/Throw. * [loader/pe_image.c] Fixed broken PE DLL loading. * [include/winnt.h] [scheduler/handle.c] [scheduler/*.c] Implemented handle access rights. Added Get/SetHandleInformation. Sun Feb 15 09:45:23 1997 Andreas Mohr <100.30936@germany.net> * [misc/winsock.c] Fixed bug in WSACleanup which lead to crashes in WINSOCK_HandleIO. * [graphics/fontengine.c] [include/font.h] Minor improvements. * [memory/global.c] Implemented GlobalEntryHandle. * [misc/toolhelp.c] Fixed a memory bug in Notify*register. * [misc/w32scomb.c] Improved Get16DLLAddress. * [objects/gdiobj.c] Implemented GdiSeeGdiDo. Sat Feb 14 14:57:39 1998 John Richardson <jrichard@zko.dec.com> * [win32/console.c] Added the console implementation, AllocConsole, FreeConsole, CONSOLE_InheritConsole. * [documentation/console] Some documentation on the console. * [include/winerror.h] Added some error defines. * [scheduler/k32obj.c] Registered the scheduler ops. Fri Feb 13 19:35:35 1998 James Moody <013263m@dragon.acadiau.ca> * [ole/ole2nls.c] Some English language fixes for missing values. * [controls/listbox.c] Fix to allow an empty listbox to deselect all items. * [relay32/user32.spec] [windows/keyboard.c] CreateAcceleratorTableA stub method. * [windows/sysmetrics.c] Added missing SM_CXCURSOR & SM_CYCURSOR initializers. * [windows/message.c] PostThreadMessage32A stub method. Fri Feb 13 17:12:24 1998 Jim Peterson <jspeter@roanoke.infi.net> * [libtest/hello3res.rc] [libtest/hello3.c] [libtest/Makefile.in] Updated the 'hello3' test so that it functions properly again. Fri Feb 13 14:08:07 1998 Martin Boehme <boehme@informatik.mu-luebeck.de> * [graphics/mapping.c] Fixed the embarrassing bugs I introduced into DPtoLP and LPtoDP. * [windows/scroll.c] Prevent ScrollWindow32 from sending WM_ERASEBKGND. Thu Feb 12 22:46:53 1998 Huw D M Davies <h.davies1@physics.oxford.ac.uk> * [objects/metafile] [include/ldt.h] Fix to cope with records longer than 64K. * [windows/clipboard.c] Clean up bitmaps and metapicts properly. Mon Feb 3 21:52:18 1998 Karl Backström <karl_b@geocities.com> * [programs/winhelp/Sw.rc] [resources/sysres_Sw.rc] Minor update of Swedish language support.
350 lines
16 KiB
Text
350 lines
16 KiB
Text
KERNEL MODULE
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=============
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...
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GDI MODULE
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==========
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1. X Windows System interface
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-----------------------------
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The X libraries used to implement X clients (such as Wine) do not work
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properly if multiple threads access the same display concurrently. It is
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possible to compile the X libraries to perform their own synchronization
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(initiated by calling XInitThreads()). However, Wine does not use this
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approach. Instead Wine performs its own synchronization py putting a
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wrapper around every X call that is used. This wrapper protects library
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access with a critical section, and also arranges things so that X
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libraries compiled without -D_REENTRANT (eg. with global errno variable)
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will work with Wine.
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To make this scheme work, all calls to X must use the proper wrapper
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functions (or do their own synchronization that is compatible with the
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wrappers). The wrapper for a function X...() is calles TSX...() (for
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"Thread Safe X ..."). So for example, instead of calling XOpenDisplay()
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in the code, TSXOpenDisplay() must be used. Likewise, X include files
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that contain function prototypes are wrapped, so that eg. "ts_xutil.h"
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must be included rather than <X11/Xutil.h>. It is important that this
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scheme is used everywhere to avoid the introduction of nondeterministic
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and hard-to-find errors in Wine.
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The code for the thread safe X wrappers is contained in the tsx11/
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directory and in include/ts*.h. To use a new (ie. not previously used) X
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function in Wine, a new wrapper must be created. The wrappers are
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generated (semi-)automatically from the X11R6 includes using the
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tools/make_X11wrappers perl script. In simple cases it should be enough
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to add the name of the new function to the list in tsx11/X11_calls; if
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this does not work the wrapper must be added manually to the
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make_X11wrappers script. See comments in tsx11/X11_calls and
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tools/make_X11wrappers for further details.
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USER MODULE
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===========
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USER implements windowing and messaging subsystems. It also
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contains code for common controls and for other miscellaneous
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stuff (rectangles, clipboard, WNet, etc). Wine USER code is
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located in windows/, controls/, and misc/ directories.
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1. Windowing subsystem
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----------------------
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windows/win.c
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windows/winpos.c
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Windows are arranged into parent/child hierarchy with one
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common ancestor for all windows (desktop window). Each window
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structure contains a pointer to the immediate ancestor (parent
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window if WS_CHILD style bit is set), a pointer to the sibling
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(returned by GetWindow(..., GW_NEXT)), a pointer to the owner
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window (set only for popup window if it was created with valid
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hwndParent parameter), and a pointer to the first child
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window (GetWindow(.., GW_CHILD)). All popup and non-child windows
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are therefore placed in the first level of this hierarchy and their
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ancestor link (wnd->parent) points to the desktop window.
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Desktop window - root window
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| \ `-.
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| \ `-.
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popup -> wnd1 -> wnd2 - top level windows
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| \ `-. `-.
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| \ `-. `-.
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child1 child2 -> child3 child4 - child windows
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Horizontal arrows denote sibling relationship, vertical lines
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- ancestor/child. To summarize, all windows with the same immediate
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ancestor are sibling windows, all windows which do not have desktop
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as their immediate ancestor are child windows. Popup windows behave
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as topmost top-level windows unless they are owned. In this case the
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only requirement is that they must precede their owners in the top-level
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sibling list (they are not topmost). Child windows are confined to the
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client area of their parent windows (client area is where window gets
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to do its own drawing, non-client area consists of caption, menu, borders,
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intrinsic scrollbars, and minimize/maximize/close/help buttons).
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Another fairly important concept is "z-order". It is derived from
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the ancestor/child hierarchy and is used to determine "above/below"
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relationship. For instance, in the example above, z-order is
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child1->popup->child2->child3->wnd1->child4->wnd2->desktop. Current
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active window ("foreground window" in Win32) is moved to the front
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of z-order unless its top-level ancestor owns popup windows.
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All these issues are dealt with (or supposed to be) in windows/winpos.c
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with SetWindowPos() being the primary interface to the window manager.
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Wine specifics: in default and managed mode each top-level window
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gets its own X counterpart with desktop window being basically a
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fake stub. In desktop mode, however, only desktop window has an X
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window associated with it. Also, SetWindowPos() should eventually be
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implemented via Begin/End/DeferWindowPos() calls and not the other way
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around.
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1.1 Visible region, clipping region and update region
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windows/dce.c
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windows/winpos.c
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windows/painting.c
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________________________
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|_________ | A and B are child windows of C
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| A |______ |
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| | | |
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|---------' | |
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| | B | |
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| | | |
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| `------------' |
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| C |
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`------------------------'
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Visible region determines which part of the window is not obscured
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by other windows. If a window has the WS_CLIPCHILDREN style then all
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areas below its children are considered invisible. Similarily, if
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the WS_CLIPSIBLINGS bit is in effect then all areas obscured by its
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siblings are invisible. Child windows are always clipped by the
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boundaries of their parent windows.
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B has a WS_CLIPSIBLINGS style:
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. ______
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: | |
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| ,-----' |
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| | B | - visible region of B
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| | |
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: `------------'
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When the program requests a display context (DC) for a window it
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can specify an optional clipping region that further restricts the
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area where the graphics output can appear. This area is calculated
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as an intersection of the visible region and a clipping region.
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Program asked for a DC with a clipping region:
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______
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,--|--. | . ,--.
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,--+--' | | : _: |
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| | B | | => | | | - DC region where the painting will
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| | | | | | | be visible
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`--|-----|---' : `----'
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`-----'
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When the window manager detects that some part of the window
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became visible it adds this area to the update region of this
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window and then generates WM_ERASEBKGND and WM_PAINT messages.
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In addition, WM_NCPAINT message is sent when the uncovered area
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intersects a nonclient part of the window. Application must reply
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to the WM_PAINT message by calling BeginPaint()/EndPaint() pair of
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functions. BeginPaint() returns a DC that uses accumulated update
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region as a clipping region. This operation cleans up invalidated
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area and the window will not receive another WM_PAINT until the
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window manager creates a new update region.
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A was moved to the left:
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________________________ ... / C update region
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|______ | : .___ /
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| A |_________ | => | ...|___|..
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| | | | | : | |
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|------' | | | : '---'
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| | B | | | : \
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| | | | : \
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| `------------' | B update region
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| C |
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`------------------------'
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Windows maintains a display context cache consisting of entries that
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include DC itself, window to which it belongs, and an optional clipping
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region (visible region is stored in the DC itself). When an API call
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changes the state of the window tree, window manager has to go through
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the DC cache to recalculate visible regions for entries whose windows
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were involved in the operation. DC entries (DCE) can be either private
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to the window, or private to the window class, or shared between all
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windows (Windows 3.1 limits the number of shared DCEs to 5).
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1.2
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2. Messaging subsystem
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----------------------
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windows/queue.c
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windows/message.c
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Each Windows task/thread has its own message queue - this is where
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it gets messages from. Messages can be generated on the fly
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(WM_PAINT, WM_NCPAINT, WM_TIMER), they can be created by the system
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(hardware messages), they can be posted by other tasks/threads
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(PostMessage), or they can be sent by other tasks/threads (SendMessage).
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Message priority:
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First the system looks for sent messages, then for posted messages,
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then for hardware messages, then it checks if the queue has the
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"dirty window" bit set, and, finally, it checks for expired
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timers. See windows/message.c.
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From all these different types of messages, only posted messages go
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directly into the private message queue. System messages (even in
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Win95) are first collected in the system message queue and then
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they either sit there until Get/PeekMessage gets to process them
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or, as in Win95, if system queue is getting clobbered, a special
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thread ("raw input thread") assigns them to the private
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queues. Sent messages are queued separately and the sender sleeps
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until it gets a reply. Special messages are generated on the fly
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depending on the window/queue state. If the window update region is
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not empty, the system sets the QS_PAINT bit in the owning queue and
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eventually this window receives a WM_PAINT message (WM_NCPAINT too
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if the update region intersects with the non-client area). A timer
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event is raised when one of the queue timers expire. Depending on
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the timer parameters DispatchMessage either calls the callback
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function or the window procedure. If there are no messages pending
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the task/thread sleeps until messages appear.
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There are several tricky moments (open for discussion) -
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a) System message order has to be honored and messages should be
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processed within correct task/thread context. Therefore when
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Get/PeekMessage encounters unassigned system message and this
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message appears not to be for the current task/thread it should
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either skip it (or get rid of it by moving it into the private
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message queue of the target task/thread - Win95, AFAIK) and
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look further or roll back and then yield until this message
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gets processed when system switches to the correct context
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(Win16). In the first case we lose correct message ordering, in
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the second case we have the infamous synchronous system message
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queue. Here is a post to one of the OS/2 newsgroup I found to
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be relevant:
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" Here's the problem in a nutshell, and there is no good solution.
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Every possible solution creates a different problem.
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With a windowing system, events can go to many different windows.
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Most are sent by applications or by the OS when things relating to
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that window happen (like repainting, timers, etc.)
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Mouse input events go to the window you click on (unless some window
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captures the mouse).
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So far, no problem. Whenever an event happens, you put a message on
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the target window's message queue. Every process has a message
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queue. If the process queue fills up, the messages back up onto the
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system queue.
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This is the first cause of apps hanging the GUI. If an app doesn't
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handle messages and they back up into the system queue, other apps
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can't get any more messages. The reason is that the next message in
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line can't go anywhere, and the system won't skip over it.
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This can be fixed by making apps have bigger private message queues.
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The SIQ fix does this. PMQSIZE does this for systems without the SIQ
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fix. Applications can also request large queues on their own.
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Another source of the problem, however, happens when you include
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keyboard events. When you press a key, there's no easy way to know
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what window the keystroke message should be delivered to.
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Most windowing systems use a concept known as "focus". The window
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with focus gets all incoming keyboard messages. Focus can be changed
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from window to window by apps or by users clicking on winodws.
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This is the second source of the problem. Suppose window A has focus.
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You click on window B and start typing before the window gets focus.
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Where should the keystrokes go? On the one hand, they should go to A
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until the focus actually changes to B. On the other hand, you
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probably want the keystrokes to go to B, since you clicked there
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first.
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OS/2's solution is that when a focus-changing event happens (like
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clicking on a window), OS/2 holds all messages in the system queue
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until the focus change actually happens. This way, subsequent
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keystrokes go to the window you clicked on, even if it takes a while
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for that window to get focus.
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The downside is that if the window takes a real long time to get focus
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(maybe it's not handling events, or maybe the window losing focus
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isn't handling events), everything backs up in the system queue and
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the system appears hung.
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There are a few solutions to this problem.
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One is to make focus policy asynchronous. That is, focus changing has
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absolutely nothing to do with the keyboard. If you click on a window
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and start typing before the focus actually changes, the keystrokes go
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to the first window until focus changes, then they go to the second.
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This is what X-windows does.
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Another is what NT does. When focus changes, keyboard events are held
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in the system message queue, but other events are allowed through.
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This is "asynchronous" because the messages in the system queue are
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delivered to the application queues in a different order from that
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with which they were posted. If a bad app won't handle the "lose
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focus" message, it's of no consequence - the app receiving focus will
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get its "gain focus" message, and the keystrokes will go to it.
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The NT solution also takes care of the application queue filling up
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problem. Since the system delivers messages asynchronously, messages
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waiting in the system queue will just sit there and the rest of the
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messages will be delivered to their apps.
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The OS/2 SIQ solution is this: When a focus-changing event happens,
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in addition to blocking further messages from the application queues,
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a timer is started. When the timer goes off, if the focus change has
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not yet happened, the bad app has its focus taken away and all
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messages targetted at that window are skipped. When the bad app
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finally handles the focus change message, OS/2 will detect this and
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stop skipping its messages.
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As for the pros and cons:
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The X-windows solution is probably the easiest. The problem is that
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users generally don't like having to wait for the focus to change
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before they start typing. On many occasions, you can type and the
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characters end up in the wrong window because something (usually heavy
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system load) is preventing the focus change from happening in a timely
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manner.
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The NT solution seems pretty nice, but making the system message queue
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asynchronous can cause similar problems to the X-windows problem.
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Since messages can be delivered out of order, programs must not assume
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that two messages posted in a particular order will be delivered in
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that same order. This can break legacy apps, but since Win32 always
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had an asynchronous queue, it is fair to simply tell app designers
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"don't do that". It's harder to tell app designers something like
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that on OS/2 - they'll complain "you changed the rules and our apps
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are breaking."
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The OS/2 solution's problem is that nothing happens until you try to
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change window focus, and then wait for the timeout. Until then, the
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bad app is not detected and nothing is done." (by David Charlap)
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b) Intertask/interthread SendMessage. The system has to inform the
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target queue about the forthcoming message, then it has to carry
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out the context switch and wait until the result is available.
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Win16 stores necessary parameters in the queue structure and then
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calls DirectedYield() function. However, in Win32 there could be
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several messages pending sent by preemptively executing threads,
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and in this case SendMessage has to build some sort of message
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queue for sent messages. Another issue is what to do with messages
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sent to the sender when it is blocked inside its own SendMessage.
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