/* * tkWinX.c -- * * This file contains Windows emulation procedures for X routines. * * Copyright (c) 1995-1996 Sun Microsystems, Inc. * Copyright (c) 1994 Software Research Associates, Inc. * Copyright (c) 1998 by Scriptics Corporation. * * See the file "license.terms" for information on usage and redistribution * of this file, and for a DISCLAIMER OF ALL WARRANTIES. * * RCS: @(#) $Id: tkWinX.c,v 1.1.4.9 1999/03/09 01:47:28 lfb Exp $ */ #include "tkWinInt.h" /* * The zmouse.h file includes the definition for WM_MOUSEWHEEL. */ #include /* * Definitions of extern variables supplied by this file. */ int tkpIsWin32s = -1; /* * Declarations of static variables used in this file. */ static char winScreenName[] = ":0"; /* Default name of windows display. */ static HINSTANCE tkInstance; /* Application instance handle. */ static int childClassInitialized; /* Registered child class? */ static WNDCLASS childClass; /* Window class for child windows. */ TCL_DECLARE_MUTEX(winXMutex) /* * Thread local storage. Notice that now each thread must have its * own TkDisplay structure, since this structure contains most of * the thread-specific date for threads. */ typedef struct ThreadSpecificData { TkDisplay *winDisplay; /* TkDisplay structure that * * represents Windows screen. */ } ThreadSpecificData; static Tcl_ThreadDataKey dataKey; /* * Forward declarations of procedures used in this file. */ static void GenerateXEvent _ANSI_ARGS_((HWND hwnd, UINT message, WPARAM wParam, LPARAM lParam)); static unsigned int GetState _ANSI_ARGS_((UINT message, WPARAM wParam, LPARAM lParam)); static void GetTranslatedKey _ANSI_ARGS_((XKeyEvent *xkey)); /* *---------------------------------------------------------------------- * * TkGetServerInfo -- * * Given a window, this procedure returns information about * the window server for that window. This procedure provides * the guts of the "winfo server" command. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ void TkGetServerInfo(interp, tkwin) Tcl_Interp *interp; /* The server information is returned in * this interpreter's result. */ Tk_Window tkwin; /* Token for window; this selects a * particular display and server. */ { char buffer[50]; OSVERSIONINFO info; info.dwOSVersionInfoSize = sizeof(OSVERSIONINFO); GetVersionEx(&info); sprintf(buffer, "Windows %d.%d %d ", info.dwMajorVersion, info.dwMinorVersion, info.dwBuildNumber); Tcl_AppendResult(interp, buffer, (info.dwPlatformId == VER_PLATFORM_WIN32s) ? "Win32s" : "Win32", (char *) NULL); } /* *---------------------------------------------------------------------- * * Tk_GetHINSTANCE -- * * Retrieves the global instance handle used by the Tk library. * * Results: * Returns the global instance handle. * * Side effects: * None. * *---------------------------------------------------------------------- */ HINSTANCE Tk_GetHINSTANCE() { return tkInstance; } /* *---------------------------------------------------------------------- * * TkWinXInit -- * * Initialize Xlib emulation layer. * * Results: * None. * * Side effects: * Sets up various data structures. * *---------------------------------------------------------------------- */ void TkWinXInit(hInstance) HINSTANCE hInstance; { OSVERSIONINFO info; info.dwOSVersionInfoSize = sizeof(OSVERSIONINFO); GetVersionEx(&info); tkpIsWin32s = (info.dwPlatformId == VER_PLATFORM_WIN32s); if (childClassInitialized != 0) { return; } childClassInitialized = 1; tkInstance = hInstance; /* * When threads are enabled, we cannot use CLASSDC because * threads will then write into the same device context. * * This is a hack; we should add a subsystem that manages * device context on a per-thread basis. See also tkWinWm.c, * which also initializes a WNDCLASS structure. */ #ifdef TCL_THREADS childClass.style = CS_HREDRAW | CS_VREDRAW; #else childClass.style = CS_HREDRAW | CS_VREDRAW | CS_CLASSDC; #endif childClass.cbClsExtra = 0; childClass.cbWndExtra = 0; childClass.hInstance = hInstance; childClass.hbrBackground = NULL; childClass.lpszMenuName = NULL; /* * Register the Child window class. */ childClass.lpszClassName = TK_WIN_CHILD_CLASS_NAME; childClass.lpfnWndProc = TkWinChildProc; childClass.hIcon = NULL; childClass.hCursor = NULL; if (!RegisterClass(&childClass)) { panic("Unable to register TkChild class"); } } /* *---------------------------------------------------------------------- * * TkWinXCleanup -- * * Removes the registered classes for Tk. * * Results: * None. * * Side effects: * Removes window classes from the system. * *---------------------------------------------------------------------- */ void TkWinXCleanup(hInstance) HINSTANCE hInstance; { /* * Clean up our own class. */ if (childClassInitialized) { childClassInitialized = 0; UnregisterClass(TK_WIN_CHILD_CLASS_NAME, hInstance); } /* * And let the window manager clean up its own class(es). */ TkWinWmCleanup(hInstance); } /* *---------------------------------------------------------------------- * * TkGetDefaultScreenName -- * * Returns the name of the screen that Tk should use during * initialization. * * Results: * Returns a statically allocated string. * * Side effects: * None. * *---------------------------------------------------------------------- */ char * TkGetDefaultScreenName(interp, screenName) Tcl_Interp *interp; /* Not used. */ char *screenName; /* If NULL, use default string. */ { if ((screenName == NULL) || (screenName[0] == '\0')) { screenName = winScreenName; } return screenName; } /* *---------------------------------------------------------------------- * * TkpOpenDisplay -- * * Create the Display structure and fill it with device * specific information. * * Results: * Returns a TkDisplay structure on success or NULL on failure. * * Side effects: * Allocates a new TkDisplay structure. * *---------------------------------------------------------------------- */ TkDisplay * TkpOpenDisplay(display_name) char *display_name; { Screen *screen; HDC dc; TkWinDrawable *twdPtr; Display *display; ThreadSpecificData *tsdPtr = (ThreadSpecificData *) Tcl_GetThreadData(&dataKey, sizeof(ThreadSpecificData)); if (tsdPtr->winDisplay != NULL) { if (strcmp(tsdPtr->winDisplay->display->display_name, display_name) == 0) { return tsdPtr->winDisplay; } else { return NULL; } } display = (Display *) ckalloc(sizeof(Display)); display->display_name = (char *) ckalloc(strlen(display_name)+1); strcpy(display->display_name, display_name); display->cursor_font = 1; display->nscreens = 1; display->request = 1; display->qlen = 0; screen = (Screen *) ckalloc(sizeof(Screen)); screen->display = display; dc = GetDC(NULL); screen->width = GetDeviceCaps(dc, HORZRES); screen->height = GetDeviceCaps(dc, VERTRES); screen->mwidth = MulDiv(screen->width, 254, GetDeviceCaps(dc, LOGPIXELSX) * 10); screen->mheight = MulDiv(screen->height, 254, GetDeviceCaps(dc, LOGPIXELSY) * 10); /* * Set up the root window. */ twdPtr = (TkWinDrawable*) ckalloc(sizeof(TkWinDrawable)); if (twdPtr == NULL) { return None; } twdPtr->type = TWD_WINDOW; twdPtr->window.winPtr = NULL; twdPtr->window.handle = NULL; screen->root = (Window)twdPtr; /* * On windows, when creating a color bitmap, need two pieces of * information: the number of color planes and the number of * pixels per plane. Need to remember both quantities so that * when constructing an HBITMAP for offscreen rendering, we can * specify the correct value for the number of planes. Otherwise * the HBITMAP won't be compatible with the HWND and we'll just * get blank spots copied onto the screen. */ screen->ext_data = (XExtData *) GetDeviceCaps(dc, PLANES); screen->root_depth = GetDeviceCaps(dc, BITSPIXEL) * (int) screen->ext_data; screen->root_visual = (Visual *) ckalloc(sizeof(Visual)); screen->root_visual->visualid = 0; if (GetDeviceCaps(dc, RASTERCAPS) & RC_PALETTE) { screen->root_visual->map_entries = GetDeviceCaps(dc, SIZEPALETTE); screen->root_visual->class = PseudoColor; screen->root_visual->red_mask = 0x0; screen->root_visual->green_mask = 0x0; screen->root_visual->blue_mask = 0x0; } else { if (screen->root_depth == 4) { screen->root_visual->class = StaticColor; screen->root_visual->map_entries = 16; } else if (screen->root_depth == 8) { screen->root_visual->class = StaticColor; screen->root_visual->map_entries = 256; } else if (screen->root_depth == 12) { screen->root_visual->class = TrueColor; screen->root_visual->map_entries = 32; screen->root_visual->red_mask = 0xf0; screen->root_visual->green_mask = 0xf000; screen->root_visual->blue_mask = 0xf00000; } else if (screen->root_depth == 16) { screen->root_visual->class = TrueColor; screen->root_visual->map_entries = 64; screen->root_visual->red_mask = 0xf8; screen->root_visual->green_mask = 0xfc00; screen->root_visual->blue_mask = 0xf80000; } else if (screen->root_depth >= 24) { screen->root_visual->class = TrueColor; screen->root_visual->map_entries = 256; screen->root_visual->red_mask = 0xff; screen->root_visual->green_mask = 0xff00; screen->root_visual->blue_mask = 0xff0000; } } screen->root_visual->bits_per_rgb = screen->root_depth; ReleaseDC(NULL, dc); /* * Note that these pixel values are not palette relative. */ screen->white_pixel = RGB(255, 255, 255); screen->black_pixel = RGB(0, 0, 0); display->screens = screen; display->nscreens = 1; display->default_screen = 0; screen->cmap = XCreateColormap(display, None, screen->root_visual, AllocNone); tsdPtr->winDisplay = (TkDisplay *) ckalloc(sizeof(TkDisplay)); tsdPtr->winDisplay->display = display; return tsdPtr->winDisplay; } /* *---------------------------------------------------------------------- * * TkpCloseDisplay -- * * Closes and deallocates a Display structure created with the * TkpOpenDisplay function. * * Results: * None. * * Side effects: * Frees up memory. * *---------------------------------------------------------------------- */ void TkpCloseDisplay(dispPtr) TkDisplay *dispPtr; { Display *display = dispPtr->display; HWND hwnd; ThreadSpecificData *tsdPtr = (ThreadSpecificData *) Tcl_GetThreadData(&dataKey, sizeof(ThreadSpecificData)); if (dispPtr != tsdPtr->winDisplay) { panic("TkpCloseDisplay: tried to call TkpCloseDisplay on another display"); return; } /* * Force the clipboard to be rendered if we are the clipboard owner. */ if (dispPtr->clipWindow) { hwnd = Tk_GetHWND(Tk_WindowId(dispPtr->clipWindow)); if (GetClipboardOwner() == hwnd) { OpenClipboard(hwnd); EmptyClipboard(); TkWinClipboardRender(dispPtr, CF_TEXT); CloseClipboard(); } } tsdPtr->winDisplay = NULL; if (display->display_name != (char *) NULL) { ckfree(display->display_name); } if (display->screens != (Screen *) NULL) { if (display->screens->root_visual != NULL) { ckfree((char *) display->screens->root_visual); } if (display->screens->root != None) { ckfree((char *) display->screens->root); } if (display->screens->cmap != None) { XFreeColormap(display, display->screens->cmap); } ckfree((char *) display->screens); } ckfree((char *) display); ckfree((char *) dispPtr); } /* *---------------------------------------------------------------------- * * XBell -- * * Generate a beep. * * Results: * None. * * Side effects: * Plays a sounds out the system speakers. * *---------------------------------------------------------------------- */ void XBell(display, percent) Display* display; int percent; { MessageBeep(MB_OK); } /* *---------------------------------------------------------------------- * * TkWinChildProc -- * * Callback from Windows whenever an event occurs on a child * window. * * Results: * Standard Windows return value. * * Side effects: * May process events off the Tk event queue. * *---------------------------------------------------------------------- */ LRESULT CALLBACK TkWinChildProc(hwnd, message, wParam, lParam) HWND hwnd; UINT message; WPARAM wParam; LPARAM lParam; { LRESULT result; switch (message) { case WM_SETCURSOR: /* * Short circuit the WM_SETCURSOR message since we set * the cursor elsewhere. */ result = TRUE; break; case WM_CREATE: case WM_ERASEBKGND: case WM_WINDOWPOSCHANGED: result = 0; break; case WM_PAINT: GenerateXEvent(hwnd, message, wParam, lParam); result = DefWindowProc(hwnd, message, wParam, lParam); break; case TK_CLAIMFOCUS: case TK_GEOMETRYREQ: case TK_ATTACHWINDOW: case TK_DETACHWINDOW: result = TkWinEmbeddedEventProc(hwnd, message, wParam, lParam); break; default: if (!Tk_TranslateWinEvent(hwnd, message, wParam, lParam, &result)) { result = DefWindowProc(hwnd, message, wParam, lParam); } break; } /* * Handle any newly queued events before returning control to Windows. */ Tcl_ServiceAll(); return result; } /* *---------------------------------------------------------------------- * * Tk_TranslateWinEvent -- * * This function is called by widget window procedures to handle * the translation from Win32 events to Tk events. * * Results: * Returns 1 if the event was handled, else 0. * * Side effects: * Depends on the event. * *---------------------------------------------------------------------- */ int Tk_TranslateWinEvent(hwnd, message, wParam, lParam, resultPtr) HWND hwnd; UINT message; WPARAM wParam; LPARAM lParam; LRESULT *resultPtr; { *resultPtr = 0; switch (message) { case WM_RENDERFORMAT: { TkWindow *winPtr = (TkWindow *) Tk_HWNDToWindow(hwnd); if (winPtr) { TkWinClipboardRender(winPtr->dispPtr, wParam); } return 1; } case WM_COMMAND: case WM_NOTIFY: case WM_VSCROLL: case WM_HSCROLL: { /* * Reflect these messages back to the sender so that they * can be handled by the window proc for the control. Note * that we need to be careful not to reflect a message that * is targeted to this window, or we will loop. */ HWND target = (message == WM_NOTIFY) ? ((NMHDR*)lParam)->hwndFrom : (HWND) lParam; if (target && target != hwnd) { *resultPtr = SendMessage(target, message, wParam, lParam); return 1; } break; } case WM_LBUTTONDOWN: case WM_LBUTTONDBLCLK: case WM_MBUTTONDOWN: case WM_MBUTTONDBLCLK: case WM_RBUTTONDOWN: case WM_RBUTTONDBLCLK: case WM_LBUTTONUP: case WM_MBUTTONUP: case WM_RBUTTONUP: case WM_MOUSEMOVE: Tk_PointerEvent(hwnd, (short) LOWORD(lParam), (short) HIWORD(lParam)); return 1; case WM_CLOSE: case WM_SETFOCUS: case WM_KILLFOCUS: case WM_DESTROYCLIPBOARD: case WM_CHAR: case WM_SYSKEYDOWN: case WM_SYSKEYUP: case WM_KEYDOWN: case WM_KEYUP: case WM_MOUSEWHEEL: GenerateXEvent(hwnd, message, wParam, lParam); return 1; case WM_MENUCHAR: GenerateXEvent(hwnd, message, wParam, lParam); /* MNC_CLOSE is the only one that looks right. This is a hack. */ *resultPtr = MAKELONG (0, MNC_CLOSE); return 1; } return 0; } /* *---------------------------------------------------------------------- * * GenerateXEvent -- * * This routine generates an X event from the corresponding * Windows event. * * Results: * None. * * Side effects: * Queues one or more X events. * *---------------------------------------------------------------------- */ static void GenerateXEvent(hwnd, message, wParam, lParam) HWND hwnd; UINT message; WPARAM wParam; LPARAM lParam; { XEvent event; TkWindow *winPtr = (TkWindow *)Tk_HWNDToWindow(hwnd); if (!winPtr || winPtr->window == None) { return; } event.xany.serial = winPtr->display->request++; event.xany.send_event = False; event.xany.display = winPtr->display; event.xany.window = winPtr->window; switch (message) { case WM_PAINT: { PAINTSTRUCT ps; event.type = Expose; BeginPaint(hwnd, &ps); event.xexpose.x = ps.rcPaint.left; event.xexpose.y = ps.rcPaint.top; event.xexpose.width = ps.rcPaint.right - ps.rcPaint.left; event.xexpose.height = ps.rcPaint.bottom - ps.rcPaint.top; EndPaint(hwnd, &ps); event.xexpose.count = 0; break; } case WM_CLOSE: event.type = ClientMessage; event.xclient.message_type = Tk_InternAtom((Tk_Window) winPtr, "WM_PROTOCOLS"); event.xclient.format = 32; event.xclient.data.l[0] = Tk_InternAtom((Tk_Window) winPtr, "WM_DELETE_WINDOW"); break; case WM_SETFOCUS: case WM_KILLFOCUS: { TkWindow *otherWinPtr = (TkWindow *)Tk_HWNDToWindow((HWND) wParam); /* * Compare toplevel windows to avoid reporting focus * changes within the same toplevel. */ while (!(winPtr->flags & TK_TOP_LEVEL)) { winPtr = winPtr->parentPtr; if (winPtr == NULL) { return; } } while (otherWinPtr && !(otherWinPtr->flags & TK_TOP_LEVEL)) { otherWinPtr = otherWinPtr->parentPtr; } if (otherWinPtr == winPtr) { return; } event.xany.window = winPtr->window; event.type = (message == WM_SETFOCUS) ? FocusIn : FocusOut; event.xfocus.mode = NotifyNormal; event.xfocus.detail = NotifyNonlinear; break; } case WM_DESTROYCLIPBOARD: event.type = SelectionClear; event.xselectionclear.selection = Tk_InternAtom((Tk_Window)winPtr, "CLIPBOARD"); event.xselectionclear.time = TkpGetMS(); break; case WM_MOUSEWHEEL: /* * The mouse wheel event is closer to a key event than a * mouse event in that the message is sent to the window * that has focus. */ case WM_CHAR: case WM_SYSKEYDOWN: case WM_SYSKEYUP: case WM_KEYDOWN: case WM_KEYUP: { unsigned int state = GetState(message, wParam, lParam); Time time = TkpGetMS(); POINT clientPoint; POINTS rootPoint; /* Note: POINT and POINTS are different */ DWORD msgPos; /* * Compute the screen and window coordinates of the event. */ msgPos = GetMessagePos(); rootPoint = MAKEPOINTS(msgPos); clientPoint.x = rootPoint.x; clientPoint.y = rootPoint.y; ScreenToClient(hwnd, &clientPoint); /* * Set up the common event fields. */ event.xbutton.root = RootWindow(winPtr->display, winPtr->screenNum); event.xbutton.subwindow = None; event.xbutton.x = clientPoint.x; event.xbutton.y = clientPoint.y; event.xbutton.x_root = rootPoint.x; event.xbutton.y_root = rootPoint.y; event.xbutton.state = state; event.xbutton.time = time; event.xbutton.same_screen = True; /* * Now set up event specific fields. */ switch (message) { case WM_MOUSEWHEEL: /* * We have invented a new X event type to handle * this event. It still uses the KeyPress struct. * However, the keycode field has been overloaded * to hold the zDelta of the wheel. */ event.type = MouseWheelEvent; event.xany.send_event = -1; event.xkey.keycode = (short) HIWORD(wParam); break; case WM_SYSKEYDOWN: case WM_KEYDOWN: /* * Check for translated characters in the event queue. * Setting xany.send_event to -1 indicates to the * Windows implementation of XLookupString that this * event was generated by windows and that the Windows * extension xkey.trans_chars is filled with the * characters that came from the TranslateMessage * call. If it is not -1, xkey.keycode is the * virtual key being sent programmatically by generic * code. */ event.type = KeyPress; event.xany.send_event = -1; event.xkey.keycode = wParam; GetTranslatedKey(&event.xkey); break; case WM_SYSKEYUP: case WM_KEYUP: /* * We don't check for translated characters on keyup * because Tk won't know what to do with them. Instead, we * wait for the WM_CHAR messages which will follow. */ event.type = KeyRelease; event.xkey.keycode = wParam; event.xkey.nbytes = 0; break; case WM_CHAR: /* * Synthesize both a KeyPress and a KeyRelease. * Strings generated by Input Method Editor are handled * in the following manner: * 1. A series of WM_KEYDOWN & WM_KEYUP messages that * cause GetTranslatedKey() to be called and return * immediately because the WM_KEYDOWNs have no * associated WM_CHAR messages -- the IME window is * accumulating the characters and translating them * itself. In the "bind" command, you get an event * with a mystery keysym and %A == "" for each * WM_KEYDOWN that actually was meant for the IME. * 2. A WM_KEYDOWN corresponding to the "confirm typing" * character. This causes GetTranslatedKey() to be * called. * 3. A WM_IME_NOTIFY message saying that the IME is * done. A side effect of this message is that * GetTranslatedKey() thinks this means that there * are no WM_CHAR messages and returns immediately. * In the "bind" command, you get an another event * with a mystery keysym and %A == "". * 4. A sequence of WM_CHAR messages that correspond to * the characters in the IME window. A bunch of * simulated KeyPress/KeyRelease events will be * generated, one for each character. Adjacent * WM_CHAR messages may actually specify the high * and low bytes of a multi-byte character -- in that * case the two WM_CHAR messages will be combined into * one event. It is the event-consumer's * responsibility to convert the string returned from * XLookupString from system encoding to UTF-8. * 5. And finally we get the WM_KEYUP for the "confirm * typing" character. */ event.type = KeyPress; event.xany.send_event = -1; event.xkey.keycode = 0; event.xkey.nbytes = 1; event.xkey.trans_chars[0] = (char) wParam; if (IsDBCSLeadByte((BYTE) wParam)) { MSG msg; if ((PeekMessage(&msg, NULL, 0, 0, PM_NOREMOVE) != 0) && (msg.message == WM_CHAR)) { GetMessage(&msg, NULL, 0, 0); event.xkey.nbytes = 2; event.xkey.trans_chars[1] = (char) msg.wParam; } } Tk_QueueWindowEvent(&event, TCL_QUEUE_TAIL); event.type = KeyRelease; break; } break; } default: return; } Tk_QueueWindowEvent(&event, TCL_QUEUE_TAIL); } /* *---------------------------------------------------------------------- * * GetState -- * * This function constructs a state mask for the mouse buttons * and modifier keys as they were before the event occured. * * Results: * Returns a composite value of all the modifier and button state * flags that were set at the time the event occurred. * * Side effects: * None. * *---------------------------------------------------------------------- */ static unsigned int GetState(message, wParam, lParam) UINT message; /* Win32 message type */ WPARAM wParam; /* wParam of message, used if key message */ LPARAM lParam; /* lParam of message, used if key message */ { int mask; int prevState; /* 1 if key was previously down */ unsigned int state = TkWinGetModifierState(); /* * If the event is a key press or release, we check for modifier * keys so we can report the state of the world before the event. */ if (message == WM_SYSKEYDOWN || message == WM_KEYDOWN || message == WM_SYSKEYUP || message == WM_KEYUP) { mask = 0; prevState = HIWORD(lParam) & KF_REPEAT; switch(wParam) { case VK_SHIFT: mask = ShiftMask; break; case VK_CONTROL: mask = ControlMask; break; case VK_MENU: mask = Mod2Mask; break; case VK_CAPITAL: if (message == WM_SYSKEYDOWN || message == WM_KEYDOWN) { mask = LockMask; prevState = ((state & mask) ^ prevState) ? 0 : 1; } break; case VK_NUMLOCK: if (message == WM_SYSKEYDOWN || message == WM_KEYDOWN) { mask = Mod1Mask; prevState = ((state & mask) ^ prevState) ? 0 : 1; } break; case VK_SCROLL: if (message == WM_SYSKEYDOWN || message == WM_KEYDOWN) { mask = Mod3Mask; prevState = ((state & mask) ^ prevState) ? 0 : 1; } break; } if (prevState) { state |= mask; } else { state &= ~mask; } } return state; } /* *---------------------------------------------------------------------- * * GetTranslatedKey -- * * Retrieves WM_CHAR messages that are placed on the system queue * by the TranslateMessage system call and places them in the * given KeyPress event. * * Results: * Sets the trans_chars and nbytes member of the key event. * * Side effects: * Removes any WM_CHAR messages waiting on the top of the system * event queue. * *---------------------------------------------------------------------- */ static void GetTranslatedKey(xkey) XKeyEvent *xkey; { MSG msg; char buf[XMaxTransChars]; xkey->nbytes = 0; while ((xkey->nbytes < XMaxTransChars) && PeekMessage(&msg, NULL, 0, 0, PM_NOREMOVE)) { if ((msg.message == WM_CHAR) || (msg.message == WM_SYSCHAR)) { GetMessage(&msg, NULL, 0, 0); /* * If this is a normal character message, we may need to strip * off the Alt modifier (e.g. Alt-digits). Note that we don't * want to do this for system messages, because those were * presumably generated as an Alt-char sequence (e.g. accelerator * keys). */ if ((msg.message == WM_CHAR) && (msg.lParam & 0x20000000)) { xkey->state = 0; } buf[xkey->nbytes] = (char) msg.wParam; xkey->trans_chars[xkey->nbytes] = (char) msg.wParam; xkey->nbytes++; } else { break; } } } /* *---------------------------------------------------------------------- * * Tk_FreeXId -- * * This inteface is not needed under Windows. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ void Tk_FreeXId(display, xid) Display *display; XID xid; { } /* *---------------------------------------------------------------------- * * TkWinResendEvent -- * * This function converts an X event into a Windows event and * invokes the specified windo procedure. * * Results: * A standard Windows result. * * Side effects: * Invokes the window procedure * *---------------------------------------------------------------------- */ LRESULT TkWinResendEvent(wndproc, hwnd, eventPtr) WNDPROC wndproc; HWND hwnd; XEvent *eventPtr; { UINT msg; WPARAM wparam; LPARAM lparam; if (eventPtr->type == ButtonPress) { switch (eventPtr->xbutton.button) { case Button1: msg = WM_LBUTTONDOWN; wparam = MK_LBUTTON; break; case Button2: msg = WM_MBUTTONDOWN; wparam = MK_MBUTTON; break; case Button3: msg = WM_RBUTTONDOWN; wparam = MK_RBUTTON; break; default: return 0; } if (eventPtr->xbutton.state & Button1Mask) { wparam |= MK_LBUTTON; } if (eventPtr->xbutton.state & Button2Mask) { wparam |= MK_MBUTTON; } if (eventPtr->xbutton.state & Button3Mask) { wparam |= MK_RBUTTON; } if (eventPtr->xbutton.state & ShiftMask) { wparam |= MK_SHIFT; } if (eventPtr->xbutton.state & ControlMask) { wparam |= MK_CONTROL; } lparam = MAKELPARAM((short) eventPtr->xbutton.x, (short) eventPtr->xbutton.y); } else { return 0; } return CallWindowProc(wndproc, hwnd, msg, wparam, lparam); } /* *---------------------------------------------------------------------- * * TkpGetMS -- * * Return a relative time in milliseconds. It doesn't matter * when the epoch was. * * Results: * Number of milliseconds. * * Side effects: * None. * *---------------------------------------------------------------------- */ unsigned long TkpGetMS() { return GetCurrentTime(); }