/* * tkMacKeyboard.c -- * * Routines to support keyboard events on the Macintosh. * * Copyright (c) 1995-1997 Sun Microsystems, Inc. * * See the file "license.terms" for information on usage and redistribution * of this file, and for a DISCLAIMER OF ALL WARRANTIES. * * RCS: @(#) $Id: tkMacKeyboard.c,v 1.8 2002/02/08 02:57:11 dgp Exp $ */ #include "tkInt.h" #include "Xlib.h" #include "keysym.h" #include #include typedef struct { short keycode; /* Macintosh keycode */ KeySym keysym; /* X windows Keysym */ } KeyInfo; static KeyInfo keyArray[] = { {0x4C, XK_Return}, {0x24, XK_Return}, {0x33, XK_BackSpace}, {0x75, XK_Delete}, {0x30, XK_Tab}, {0x74, XK_Page_Up}, {0x79, XK_Page_Down}, {0x73, XK_Home}, {0x77, XK_End}, {0x7B, XK_Left}, {0x7C, XK_Right}, {0x7E, XK_Up}, {0x7D, XK_Down}, {0x72, XK_Help}, {0x35, XK_Escape}, {0x47, XK_Clear}, {0, 0} }; static KeyInfo vituralkeyArray[] = { {122, XK_F1}, {120, XK_F2}, {99, XK_F3}, {118, XK_F4}, {96, XK_F5}, {97, XK_F6}, {98, XK_F7}, {100, XK_F8}, {101, XK_F9}, {109, XK_F10}, {103, XK_F11}, {111, XK_F12}, {105, XK_F13}, {107, XK_F14}, {113, XK_F15}, {0, 0} }; static int initialized = 0; static Tcl_HashTable keycodeTable; /* keyArray hashed by keycode value. */ static Tcl_HashTable vkeyTable; /* vituralkeyArray hashed by virtual keycode value. */ static Ptr KCHRPtr; /* Pointer to 'KCHR' resource. */ /* * Prototypes for static functions used in this file. */ static void InitKeyMaps _ANSI_ARGS_((void)); /* *---------------------------------------------------------------------- * * InitKeyMaps -- * * Creates hash tables used by some of the functions in this file. * * Results: * None. * * Side effects: * Allocates memory & creates some hash tables. * *---------------------------------------------------------------------- */ static void InitKeyMaps() { register Tcl_HashEntry *hPtr; register KeyInfo *kPtr; int dummy; Tcl_InitHashTable(&keycodeTable, TCL_ONE_WORD_KEYS); for (kPtr = keyArray; kPtr->keycode != 0; kPtr++) { hPtr = Tcl_CreateHashEntry(&keycodeTable, (char *) kPtr->keycode, &dummy); Tcl_SetHashValue(hPtr, kPtr->keysym); } Tcl_InitHashTable(&vkeyTable, TCL_ONE_WORD_KEYS); for (kPtr = vituralkeyArray; kPtr->keycode != 0; kPtr++) { hPtr = Tcl_CreateHashEntry(&vkeyTable, (char *) kPtr->keycode, &dummy); Tcl_SetHashValue(hPtr, kPtr->keysym); } KCHRPtr = (Ptr) GetScriptManagerVariable(smKCHRCache); initialized = 1; } /* *---------------------------------------------------------------------- * * XKeycodeToKeysym -- * * Translate from a system-dependent keycode to a * system-independent keysym. * * Results: * Returns the translated keysym, or NoSymbol on failure. * * Side effects: * None. * *---------------------------------------------------------------------- */ KeySym XKeycodeToKeysym( Display* display, KeyCode keycode, int index) { register Tcl_HashEntry *hPtr; int c; char virtualKey; int newKeycode; unsigned long dummy, newChar; if (!initialized) { InitKeyMaps(); } virtualKey = (char) (keycode >> 16); c = (keycode) & 0xffff; if (c > 255) { return NoSymbol; } /* * When determining what keysym to produce we firt check to see if * the key is a function key. We then check to see if the character * is another non-printing key. Finally, we return the key syms * for all ASCI chars. */ if (c == 0x10) { hPtr = Tcl_FindHashEntry(&vkeyTable, (char *) virtualKey); if (hPtr != NULL) { return (KeySym) Tcl_GetHashValue(hPtr); } } hPtr = Tcl_FindHashEntry(&keycodeTable, (char *) virtualKey); if (hPtr != NULL) { return (KeySym) Tcl_GetHashValue(hPtr); } /* * Recompute the character based on the Shift key only. * TODO: The index may also specify the NUM_LOCK. */ newKeycode = virtualKey; if (index & 0x01) { newKeycode += 0x0200; } dummy = 0; newChar = KeyTranslate(KCHRPtr, (short) newKeycode, &dummy); c = newChar & charCodeMask; if (c >= XK_space && c < XK_asciitilde) { return c; } return NoSymbol; } /* *---------------------------------------------------------------------- * * TkpGetString -- * * Retrieve the string equivalent for the given keyboard event. * * Results: * Returns the UTF string. * * Side effects: * None. * *---------------------------------------------------------------------- */ char * TkpGetString( TkWindow *winPtr, /* Window where event occurred: needed to * get input context. */ XEvent *eventPtr, /* X keyboard event. */ Tcl_DString *dsPtr) /* Uninitialized or empty string to hold * result. */ { register Tcl_HashEntry *hPtr; char string[3]; char virtualKey; int c, len; if (!initialized) { InitKeyMaps(); } Tcl_DStringInit(dsPtr); virtualKey = (char) (eventPtr->xkey.keycode >> 16); c = (eventPtr->xkey.keycode) & 0xffff; if (c < 256) { string[0] = (char) c; len = 1; } else { string[0] = (char) (c >> 8); string[1] = (char) c; len = 2; } /* * Just return NULL if the character is a function key or another * non-printing key. */ if (c == 0x10) { len = 0; } else { hPtr = Tcl_FindHashEntry(&keycodeTable, (char *) virtualKey); if (hPtr != NULL) { len = 0; } } return Tcl_ExternalToUtfDString(NULL, string, len, dsPtr); } /* *---------------------------------------------------------------------- * * XGetModifierMapping -- * * Fetch the current keycodes used as modifiers. * * Results: * Returns a new modifier map. * * Side effects: * Allocates a new modifier map data structure. * *---------------------------------------------------------------------- */ XModifierKeymap * XGetModifierMapping( Display* display) { XModifierKeymap * modmap; modmap = (XModifierKeymap *) ckalloc(sizeof(XModifierKeymap)); modmap->max_keypermod = 0; modmap->modifiermap = NULL; return modmap; } /* *---------------------------------------------------------------------- * * XFreeModifiermap -- * * Deallocate a modifier map that was created by * XGetModifierMapping. * * Results: * None. * * Side effects: * Frees the datastructure referenced by modmap. * *---------------------------------------------------------------------- */ void XFreeModifiermap( XModifierKeymap *modmap) { if (modmap->modifiermap != NULL) { ckfree((char *) modmap->modifiermap); } ckfree((char *) modmap); } /* *---------------------------------------------------------------------- * * XKeysymToString, XStringToKeysym -- * * These X window functions map Keysyms to strings & strings to * keysyms. However, Tk already does this for the most common keysyms. * Therefor, these functions only need to support keysyms that will be * specific to the Macintosh. Currently, there are none. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ char * XKeysymToString( KeySym keysym) { return NULL; } KeySym XStringToKeysym( const char* string) { return NoSymbol; } /* *---------------------------------------------------------------------- * * XKeysymToKeycode -- * * The function XKeysymToKeycode is only used by tkTest.c and * currently only implementes the support for keys used in the * Tk test suite. * FIXME - This is no longer true. This function is now used in * "event generate" so we really should make it work. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ KeyCode XKeysymToKeycode( Display* display, KeySym keysym) { KeyCode keycode = 0; char virtualKeyCode = 0; if ((keysym >= XK_space) && (XK_asciitilde)) { if (keysym == 'a') { virtualKeyCode = 0x00; } else if (keysym == 'b' || keysym == 'B') { virtualKeyCode = 0x0B; } else if (keysym == 'c') { virtualKeyCode = 0x08; } else if (keysym == 'x' || keysym == 'X') { virtualKeyCode = 0x07; } else if (keysym == 'z') { virtualKeyCode = 0x06; } else if (keysym == ' ') { virtualKeyCode = 0x31; } else if (keysym == XK_Return) { virtualKeyCode = 0x24; keysym = '\r'; } keycode = keysym + (virtualKeyCode <<16); } return keycode; } /* * When mapping from a keysym to a keycode, need * information about the modifier state that should be used * so that when they call XKeycodeToKeysym taking into * account the xkey.state, they will get back the original * keysym. */ void TkpSetKeycodeAndState(tkwin, keySym, eventPtr) Tk_Window tkwin; KeySym keySym; XEvent *eventPtr; { Display *display; int state; KeyCode keycode; display = Tk_Display(tkwin); if (keySym == NoSymbol) { keycode = 0; } else { keycode = XKeysymToKeycode(display, keySym); } if (keycode != 0) { for (state = 0; state < 4; state++) { if (XKeycodeToKeysym(display, keycode, state) == keySym) { if (state & 1) { eventPtr->xkey.state |= ShiftMask; } if (state & 2) { TkDisplay *dispPtr; dispPtr = ((TkWindow *) tkwin)->dispPtr; eventPtr->xkey.state |= dispPtr->modeModMask; } break; } } } eventPtr->xkey.keycode = keycode; } /* *---------------------------------------------------------------------- * * TkpGetKeySym -- * * Given an X KeyPress or KeyRelease event, map the * keycode in the event into a KeySym. * * Results: * The return value is the KeySym corresponding to * eventPtr, or NoSymbol if no matching Keysym could be * found. * * Side effects: * In the first call for a given display, keycode-to- * KeySym maps get loaded. * *---------------------------------------------------------------------- */ KeySym TkpGetKeySym(dispPtr, eventPtr) TkDisplay *dispPtr; /* Display in which to * map keycode. */ XEvent *eventPtr; /* Description of X event. */ { KeySym sym; int index; /* * Refresh the mapping information if it's stale */ if (dispPtr->bindInfoStale) { TkpInitKeymapInfo(dispPtr); } /* * Figure out which of the four slots in the keymap vector to * use for this key. Refer to Xlib documentation for more info * on how this computation works. */ index = 0; if (eventPtr->xkey.state & dispPtr->modeModMask) { index = 2; } if ((eventPtr->xkey.state & ShiftMask) || ((dispPtr->lockUsage != LU_IGNORE) && (eventPtr->xkey.state & LockMask))) { index += 1; } sym = XKeycodeToKeysym(dispPtr->display, eventPtr->xkey.keycode, index); /* * Special handling: if the key was shifted because of Lock, but * lock is only caps lock, not shift lock, and the shifted keysym * isn't upper-case alphabetic, then switch back to the unshifted * keysym. */ if ((index & 1) && !(eventPtr->xkey.state & ShiftMask) && (dispPtr->lockUsage == LU_CAPS)) { if (!(((sym >= XK_A) && (sym <= XK_Z)) || ((sym >= XK_Agrave) && (sym <= XK_Odiaeresis)) || ((sym >= XK_Ooblique) && (sym <= XK_Thorn)))) { index &= ~1; sym = XKeycodeToKeysym(dispPtr->display, eventPtr->xkey.keycode, index); } } /* * Another bit of special handling: if this is a shifted key and there * is no keysym defined, then use the keysym for the unshifted key. */ if ((index & 1) && (sym == NoSymbol)) { sym = XKeycodeToKeysym(dispPtr->display, eventPtr->xkey.keycode, index & ~1); } return sym; } /* *-------------------------------------------------------------- * * TkpInitKeymapInfo -- * * This procedure is invoked to scan keymap information * to recompute stuff that's important for binding, such * as the modifier key (if any) that corresponds to "mode * switch". * * Results: * None. * * Side effects: * Keymap-related information in dispPtr is updated. * *-------------------------------------------------------------- */ void TkpInitKeymapInfo(dispPtr) TkDisplay *dispPtr; /* Display for which to recompute keymap * information. */ { XModifierKeymap *modMapPtr; KeyCode *codePtr; KeySym keysym; int count, i, j, max, arraySize; #define KEYCODE_ARRAY_SIZE 20 dispPtr->bindInfoStale = 0; modMapPtr = XGetModifierMapping(dispPtr->display); /* * Check the keycodes associated with the Lock modifier. If * any of them is associated with the XK_Shift_Lock modifier, * then Lock has to be interpreted as Shift Lock, not Caps Lock. */ dispPtr->lockUsage = LU_IGNORE; codePtr = modMapPtr->modifiermap + modMapPtr->max_keypermod*LockMapIndex; for (count = modMapPtr->max_keypermod; count > 0; count--, codePtr++) { if (*codePtr == 0) { continue; } keysym = XKeycodeToKeysym(dispPtr->display, *codePtr, 0); if (keysym == XK_Shift_Lock) { dispPtr->lockUsage = LU_SHIFT; break; } if (keysym == XK_Caps_Lock) { dispPtr->lockUsage = LU_CAPS; break; } } /* * Look through the keycodes associated with modifiers to see if * the the "mode switch", "meta", or "alt" keysyms are associated * with any modifiers. If so, remember their modifier mask bits. */ dispPtr->modeModMask = 0; dispPtr->metaModMask = 0; dispPtr->altModMask = 0; codePtr = modMapPtr->modifiermap; max = 8*modMapPtr->max_keypermod; for (i = 0; i < max; i++, codePtr++) { if (*codePtr == 0) { continue; } keysym = XKeycodeToKeysym(dispPtr->display, *codePtr, 0); if (keysym == XK_Mode_switch) { dispPtr->modeModMask |= ShiftMask << (i/modMapPtr->max_keypermod); } if ((keysym == XK_Meta_L) || (keysym == XK_Meta_R)) { dispPtr->metaModMask |= ShiftMask << (i/modMapPtr->max_keypermod); } if ((keysym == XK_Alt_L) || (keysym == XK_Alt_R)) { dispPtr->altModMask |= ShiftMask << (i/modMapPtr->max_keypermod); } } /* * Create an array of the keycodes for all modifier keys. */ if (dispPtr->modKeyCodes != NULL) { ckfree((char *) dispPtr->modKeyCodes); } dispPtr->numModKeyCodes = 0; arraySize = KEYCODE_ARRAY_SIZE; dispPtr->modKeyCodes = (KeyCode *) ckalloc((unsigned) (KEYCODE_ARRAY_SIZE * sizeof(KeyCode))); for (i = 0, codePtr = modMapPtr->modifiermap; i < max; i++, codePtr++) { if (*codePtr == 0) { continue; } /* * Make sure that the keycode isn't already in the array. */ for (j = 0; j < dispPtr->numModKeyCodes; j++) { if (dispPtr->modKeyCodes[j] == *codePtr) { goto nextModCode; } } if (dispPtr->numModKeyCodes >= arraySize) { KeyCode *new; /* * Ran out of space in the array; grow it. */ arraySize *= 2; new = (KeyCode *) ckalloc((unsigned) (arraySize * sizeof(KeyCode))); memcpy((VOID *) new, (VOID *) dispPtr->modKeyCodes, (dispPtr->numModKeyCodes * sizeof(KeyCode))); ckfree((char *) dispPtr->modKeyCodes); dispPtr->modKeyCodes = new; } dispPtr->modKeyCodes[dispPtr->numModKeyCodes] = *codePtr; dispPtr->numModKeyCodes++; nextModCode: continue; } XFreeModifiermap(modMapPtr); }