/* * tkMacOSXKeyboard.c -- * * Routines to support keyboard events on the Macintosh. * * Copyright © 1995-1997 Sun Microsystems, Inc. * Copyright © 2001-2009, Apple Inc. * Copyright © 2005-2009 Daniel A. Steffen * Copyright © 2020 Marc Culler * * See the file "license.terms" for information on usage and redistribution * of this file, and for a DISCLAIMER OF ALL WARRANTIES. */ #include "tkMacOSXPrivate.h" #include "tkMacOSXInt.h" #include "tkMacOSXConstants.h" #include "tkMacOSXKeysyms.h" /* * About keyboards * --------------- * Keyboards are complicated. This long comment is an attempt to provide * enough information about them to make it possible to read and understand * the code in this file. * * Every key on a keyboard is identified by a number between 0 and 127. In * macOS, pressing or releasing a key on the keyboard generates an NSEvent of * type KeyDown, KeyUp or FlagsChanged. The 8-bit identifier of the key that * was involved in this event is provided in the attribute [NSEvent keyCode]. * Apple also refers to this number as a "Virtual KeyCode". In this file, to * avoid confusion with other uses of the word keycode, we will refer to this * key identifier as a "virtual keycode", usually the value of a variable named * "virtual". * * Some of the keys on a keyboard, such as the Shift, Option, Command or * Control keys, are "modifier" keys. The effect of pressing or releasing a * key depends on three quantities: * - which key is being pressed or released * - which modifier keys are being held down at the moment * - the current keyboard layout * If the key is a modifier key then the effect of pressing or releasing it is * only to change the list of which modifier keys are being held down. Apple * reports this by sending an NSEvent of type FlagsChanged. X11 reports this * as a KeyPress or KeyRelease event for the modifier key. Note that there may * be combinations of modifier key states and key presses which have no effect. * * In X11 every meaningful effect from a key action is identified by a 16 bit * value known as a keysym. Every keysym has an associated string name, also * known as a keysym. The Tk bind command uses the X11 keysym string to * specify a key event which should invoke a certain action and it provides the * numeric and symbolic keysyms to the bound proc as %N and %K respectively. * An X11 XEvent which reports a KeyPress or KeyRelease does not include the * keysym. Instead it includes a platform-specific numerical value called a * keycode which is available to the bound procedure as %k. A platform port of * Tk must provide functions which convert between keycodes and numerical * keysyms. Conversion between numerical and symbolic keysyms is provided by * the generic Tk code, although platforms are allowed to provide their own by * defining the XKeysymToString and XStringToKeysym functions and undefining * the macro REDO_KEYSYM_LOOKUP. This macOS port uses the conversion provided * by the generic code. * * When the keyboard focus is on a Tk widget which provides text input, there * are some X11 KeyPress events which cause text to be inserted. We will call * these "printable" events. The UCS-32 character stored in the keycode field * of an XKeyEvent depends on more than the three items above. It may also * depend on the sequence of keypresses that preceded the one being reported by * the XKeyEvent. For example, on macOS an event does not cause text * to be inserted but a following event causes an accented 'a' to be * inserted. The events in such a composition sequence, other than the final * one, are known as "dead-key" events. * * MacOS packages the information described above in a different way. Every * meaningful effect from a key action *other than changing the state of * modifier keys* is identified by a unicode string which is provided as the * [NSEvent characters] attribute of a KeyDown or KeyUp event. FlagsChanged * events do not have characters. In principle, the characters attribute could * be an arbitrary unicode string but in practice it is always a single UTF-16 * character which we usually store in a variable named keychar. While the * keychar is a legal unicode code point, it does not necessarily represent a * glyph. MacOS uses unicode code points in the private-use range 0xF700-0xF8FF * for non-printable events which have no associated ASCII code point. For * example, pressing the F2 key generates an NSEvent with the character 0xF705, * the Backspace key produces 0x7F (ASCII del) and the Delete key produces * 0xF728. * * With the exception of modifier keys, it is possible to translate between * numerical X11 keysyms and macOS keychars; this file constructs Tcl hash * tables to do this job, using data defined in the file tkMacOSXKeysyms.h. * The code here adopts the convention that the keychar of any modifier key * is MOD_KEYCHAR. Keys which do not appear on any Macintosh keyboard, such * as the Menu key on PC keyboards, are assigned UNKNOWN_KEYCHAR. * * The macosx platform-specific scheme for generating a keycode when mapping an * NSEvent of type KeyUp, KeyDown or FlagsChanged to an XEvent of type KeyPress * or KeyRelease is as follows: * keycode = (virtual << 24) | index << 22 | keychar * where index is a 2-bit quantity whose bits indicate the state of the Option * and Shift keys. * * A few remarks are in order. First, we are using 32 bits for the keycode and * we are allowing room for up to 22 bits for the keychar. This means that * there is enough room in the keycode to hold a UTF-32 character, which only * requires 21 bits. Second, the KeyCode type for the keycode field in an * XEvent is currently defined as unsigned int, which was modified from the * unsigned short used in X11 in order to accomodate macOS. Finally, there is * no obstruction to generating KeyPress events for keys that represent letters * which do not exist on the current keyboard layout. And different keyboard * layouts can assign a given letter to different keys. So we need a * convention for what value to assign to "virtual" when computing the keycode * for a generated event. The convention used here is as follows: If there is * a key on the current keyboard which produces the keychar, use the virtual * keycode of that key. Otherwise set virtual = NO_VIRTUAL. */ /* * See tkMacOSXPrivate.h for macros and structures related to key event processing. */ /* * Hash tables and array used to translate between various key attributes. */ static Tcl_HashTable special2keysym; /* Special virtual keycode to keysym */ static Tcl_HashTable keysym2keycode; /* keysym to XEvent keycode */ static Tcl_HashTable keysym2unichar; /* keysym to unichar */ static Tcl_HashTable unichar2keysym; /* unichar to X11 keysym */ static Tcl_HashTable unichar2xvirtual; /* unichar to virtual with index */ static UniChar xvirtual2unichar[512]; /* virtual with index to unichar */ /* * Flags. */ static BOOL initialized = NO; static BOOL keyboardChanged = YES; /* * Prototypes for static functions used in this file. */ static void InitHashTables(void); static void UpdateKeymaps(void); static int KeyDataToUnicode(UniChar *uniChars, int maxChars, UInt16 keyaction, UInt32 virt, UInt32 modifiers, UInt32 * deadKeyStatePtr); #pragma mark TKApplication(TKKeyboard) @implementation TKApplication(TKKeyboard) - (void) keyboardChanged: (NSNotification *) notification { (void)notification; #ifdef TK_MAC_DEBUG_NOTIFICATIONS TKLog(@"-[%@(%p) %s] %@", [self class], self, _cmd, notification); #endif keyboardChanged = YES; UpdateKeymaps(); } @end #pragma mark - /* *---------------------------------------------------------------------- * * InitHashTables -- * * Creates hash tables used by some of the functions in this file. * * Results: * None. * * Side effects: * Allocates memory & creates some hash tables. * *---------------------------------------------------------------------- */ static void InitHashTables(void) { Tcl_HashEntry *hPtr; const KeyInfo *kPtr; const KeysymInfo *ksPtr; int dummy, index; Tcl_InitHashTable(&special2keysym, TCL_ONE_WORD_KEYS); Tcl_InitHashTable(&keysym2keycode, TCL_ONE_WORD_KEYS); for (kPtr = keyArray; kPtr->virt != 0; kPtr++) { MacKeycode macKC; macKC.v.o_s = 0; hPtr = Tcl_CreateHashEntry(&special2keysym, INT2PTR(kPtr->virt), &dummy); Tcl_SetHashValue(hPtr, INT2PTR(kPtr->keysym)); hPtr = Tcl_CreateHashEntry(&keysym2keycode, INT2PTR(kPtr->keysym), &dummy); macKC.v.virt = kPtr->virt; macKC.v.keychar = kPtr->keychar; Tcl_SetHashValue(hPtr, INT2PTR(macKC.uint)); /* * The Carbon framework does not work for finding the unicode character * of a special key. But that does not depend on the keyboard layout, * so we can record the information here. */ for (index = 3; index >= 0; index--) { macKC.v.o_s = index; xvirtual2unichar[macKC.x.xvirtual] = macKC.x.keychar; } } Tcl_InitHashTable(&keysym2unichar, TCL_ONE_WORD_KEYS); Tcl_InitHashTable(&unichar2keysym, TCL_ONE_WORD_KEYS); for (ksPtr = keysymTable; ksPtr->keysym != 0; ksPtr++) { hPtr = Tcl_CreateHashEntry(&keysym2unichar, INT2PTR(ksPtr->keysym), &dummy); Tcl_SetHashValue(hPtr, INT2PTR(ksPtr->keycode)); hPtr = Tcl_CreateHashEntry(&unichar2keysym, INT2PTR(ksPtr->keycode), &dummy); Tcl_SetHashValue(hPtr, INT2PTR(ksPtr->keysym)); } UpdateKeymaps(); initialized = YES; } /* *---------------------------------------------------------------------- * * UpdateKeymaps -- * * Called when the keyboard changes to update the hash tables that provide * maps between unicode characters and virtual keycodes with indexes. In * order for the map from characters to virtual keycodes to be * well-defined we have to ignore virtual keycodes for keypad keys, since * each keypad key has the same character as the corresponding key on the * main keyboard. * * Results: * None. * * Side effects: * Initializes, if necessary, and updates the unichar2xvirtual hash table * and the xvirtual2unichar array. * *---------------------------------------------------------------------- */ static void UpdateKeymaps() { static Bool keymapInitialized = false; Tcl_HashEntry *hPtr; int virt, index, dummy; if (!keymapInitialized) { Tcl_InitHashTable(&unichar2xvirtual, TCL_ONE_WORD_KEYS); keymapInitialized = true; } else { Tcl_DeleteHashTable(&unichar2xvirtual); Tcl_InitHashTable(&unichar2xvirtual, TCL_ONE_WORD_KEYS); } /* * This loop goes backwards so that a lookup by keychar will provide the * minimal modifier mask. Simpler combinations will overwrite more complex * ones when constructing the table. */ for (index = 3; index >= 0; index--) { for (virt = 0; virt < 128; virt++) { MacKeycode macKC; macKC.v = (keycode_v) {.virt = virt, .o_s = index, .keychar = 0}; int modifiers = INDEX2CARBON(index), result; UniChar keychar = 0; result = KeyDataToUnicode(&keychar, 1, kUCKeyActionDown, virt, modifiers, NULL); if (keychar == 0x10) { /* * This is a special key, handled in InitHashTables. */ continue; } macKC.v.keychar = keychar; if (! ON_KEYPAD(virt)) { hPtr = Tcl_CreateHashEntry(&unichar2xvirtual, INT2PTR(macKC.x.keychar), &dummy); Tcl_SetHashValue(hPtr, INT2PTR(macKC.x.xvirtual)); } xvirtual2unichar[macKC.x.xvirtual] = macKC.x.keychar; } } } /* *---------------------------------------------------------------------- * * KeyDataToUnicode -- * * Given MacOS key event data this function generates the keychar. It * does this by using OS resources from the Carbon framework. Note that * the Carbon functions used here are not aware of the keychars in the * private-use range which macOS now uses for special keys. For those * keys this function returns 0x10 (ASCII dle). * * The parameter deadKeyStatePtr can be NULL, if no deadkey handling is * needed (which is always the case here). * * This function is called in XKeycodeToKeysym and UpdateKeymaps. * * Results: * The number of characters generated if any, 0 if we are waiting for * another byte of a dead-key sequence. * * Side Effects: * Fills in the uniChars array with a Unicode string. * *---------------------------------------------------------------------- */ static int KeyDataToUnicode( UniChar *uniChars, int maxChars, UInt16 keyaction, UInt32 virt, UInt32 modifiers, UInt32 *deadKeyStatePtr) { static const void *layoutData = NULL; static UInt32 keyboardType = 0; UniCharCount actuallength = 0; if (keyboardChanged) { TISInputSourceRef currentKeyboardLayout = TISCopyCurrentKeyboardLayoutInputSource(); if (currentKeyboardLayout) { CFDataRef keyLayoutData = (CFDataRef) TISGetInputSourceProperty( currentKeyboardLayout, kTISPropertyUnicodeKeyLayoutData); if (keyLayoutData) { layoutData = CFDataGetBytePtr(keyLayoutData); keyboardType = LMGetKbdType(); } CFRelease(currentKeyboardLayout); } keyboardChanged = 0; } if (layoutData) { OptionBits options = 0; UInt32 dummyState; OSStatus err; virt &= 0xFF; modifiers = (modifiers >> 8) & 0xFF; if (!deadKeyStatePtr) { options = kUCKeyTranslateNoDeadKeysMask; dummyState = 0; deadKeyStatePtr = &dummyState; } err = ChkErr(UCKeyTranslate, (const UCKeyboardLayout *)layoutData, virt, keyaction, modifiers, keyboardType, options, deadKeyStatePtr, maxChars, &actuallength, uniChars); if (!actuallength && *deadKeyStatePtr) { /* * We are waiting for another key. */ return 0; } *deadKeyStatePtr = 0; if (err != noErr) { actuallength = 0; } } return actuallength; } /* *---------------------------------------------------------------------- * * XKeycodeToKeysym -- * * This is a stub function which translates from the keycode used in an * XEvent to a numerical keysym. On macOS, the display parameter is * ignored and only the the virtual keycode stored in the .virtual bitfield * of a MacKeycode.v. * * Results: * Returns the corresponding numerical keysym, or NoSymbol if the keysym * cannot be found. * * Side effects: * None. * *---------------------------------------------------------------------- */ KeySym XkbKeycodeToKeysym( TCL_UNUSED(Display *), unsigned int keycode, TCL_UNUSED(int), int index) { Tcl_HashEntry *hPtr; MacKeycode macKC; int modifiers, result; UniChar keychar = 0; if (!initialized) { InitHashTables(); } macKC.uint = keycode; macKC.v.o_s = index; /* * First check if the virtual keycode corresponds to a special key, such as * an Fn function key or Tab, Backspace, Home, End, etc. */ hPtr = Tcl_FindHashEntry(&special2keysym, INT2PTR(macKC.v.virt)); if (hPtr != NULL) { return (KeySym) Tcl_GetHashValue(hPtr); } /* * If the virtual value in this keycode does not correspond to an actual * key in the current keyboard layout, try using its keychar to look up a * keysym. */ if (macKC.v.virt > 127) { hPtr = Tcl_FindHashEntry(&unichar2keysym, INT2PTR(macKC.v.keychar)); if (hPtr != NULL) { return (KeySym) Tcl_GetHashValue(hPtr); } } /* * If the virtual keycode does belong to a key, use the virtual and the * Option-Shift from index to look up a keychar by using the Carbon * Framework; then translate the keychar to a keysym using the * unicode2keysym hash table. */ modifiers = INDEX2CARBON(macKC.v.o_s); result = KeyDataToUnicode(&keychar, 1, kUCKeyActionDown, macKC.v.virt, modifiers, NULL); if (result) { hPtr = Tcl_FindHashEntry(&unichar2keysym, INT2PTR(keychar)); if (hPtr != NULL) { return (KeySym) Tcl_GetHashValue(hPtr); } } return NoSymbol; } KeySym XKeycodeToKeysym( TCL_UNUSED(Display *), unsigned int keycode, int index) { return XkbKeycodeToKeysym(NULL, keycode, 0, index); } /* *---------------------------------------------------------------------- * * TkpGetString -- * * This is a stub function which retrieves the string stored in the * transchars field of an XEvent and converts it to a Tcl_DString. * * Results: * Returns a pointer to the string value of the DString. * * Side effects: * None. * *---------------------------------------------------------------------- */ const char * TkpGetString( TCL_UNUSED(TkWindow *), /* Window where event occurred: Needed to get * input context. */ XEvent *eventPtr, /* X keyboard event. */ Tcl_DString *dsPtr) /* Uninitialized or empty string to hold * result. */ { MacKeycode macKC; char utfChars[8]; int length = 0; macKC.uint = eventPtr->xkey.keycode; if (IS_PRINTABLE(macKC.v.keychar)) { length = TkUniCharToUtf(macKC.v.keychar, utfChars); } utfChars[length] = 0; Tcl_DStringInit(dsPtr); return Tcl_DStringAppend(dsPtr, utfChars, length); } /* *---------------------------------------------------------------------- * * XGetModifierMapping -- * * X11 stub function to get the keycodes used as modifiers. This * is never called by the macOS port. * * Results: * Returns a newly allocated modifier map. * * Side effects: * Allocates a new modifier map data structure. * *---------------------------------------------------------------------- */ XModifierKeymap * XGetModifierMapping( TCL_UNUSED(Display *)) { XModifierKeymap *modmap; modmap = (XModifierKeymap *)ckalloc(sizeof(XModifierKeymap)); modmap->max_keypermod = 0; modmap->modifiermap = NULL; return modmap; } /* *---------------------------------------------------------------------- * * XFreeModifiermap -- * * Deallocates a modifier map that was created by XGetModifierMapping. * This is also never called by the macOS port. * * Results: * None. * * Side effects: * Frees the datastructure referenced by modmap. * *---------------------------------------------------------------------- */ int XFreeModifiermap( XModifierKeymap *modmap) { if (modmap->modifiermap != NULL) { ckfree(modmap->modifiermap); } ckfree(modmap); return Success; } /* *---------------------------------------------------------------------- * * XKeysymToString, XStringToKeysym -- * * These X11 stub functions map keysyms to strings & strings to keysyms. * A platform can do its own conversion by defining these and undefining * REDO_KEYSYM_LOOKUP. The macOS port defines REDO_KEYSYM_LOOKUP so these * are never called and Tk does the conversion for us. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ char * XKeysymToString( TCL_UNUSED(KeySym)) { return NULL; } KeySym XStringToKeysym( TCL_UNUSED(const char *)) { return NoSymbol; } /* *---------------------------------------------------------------------- * * XKeysymToKeycode -- * * This is a stub function which converts a numerical keysym to the * platform-specific keycode used in a KeyPress or KeyRelease XEvent. * For macOS the keycode is an unsigned int with bitfields described * in the definition of the MacKeycode type. * * Results: * * A macOS KeyCode. See the description of keycodes at the top of this * file and the definition of the MacKeycode type in tkMacOSXPrivate.h. * * Side effects: * None. * *---------------------------------------------------------------------- */ KeyCode XKeysymToKeycode( TCL_UNUSED(Display *), KeySym keysym) { Tcl_HashEntry *hPtr; MacKeycode macKC; if (!initialized) { InitHashTables(); } /* * First check for a special key. */ hPtr = Tcl_FindHashEntry(&keysym2keycode, INT2PTR(keysym)); if (hPtr != NULL) { return (KeyCode) PTR2INT(Tcl_GetHashValue(hPtr)); } /* * Initialize the keycode as if the keysym cannot be converted to anything * else. */ macKC.v.virt = NO_VIRTUAL; macKC.v.o_s = 0; macKC.v.keychar = 0; /* * If the keysym is recognized fill in the keychar. Also fill in the * xvirtual field if the key exists on the current keyboard. */ hPtr = (Tcl_HashEntry *) Tcl_FindHashEntry(&keysym2unichar, INT2PTR(keysym)); if (hPtr != NULL) { unsigned long data = (unsigned long) Tcl_GetHashValue(hPtr); macKC.x.keychar = (unsigned int) data; hPtr = Tcl_FindHashEntry(&unichar2xvirtual, INT2PTR(macKC.x.keychar)); if (hPtr != NULL) { data = (unsigned long) Tcl_GetHashValue(hPtr); macKC.x.xvirtual = (unsigned int) data; } } return (KeyCode) macKC.uint; } /* *---------------------------------------------------------------------- * * TkpSetKeycodeAndState -- * * This function accepts a keysym and an XEvent and sets some fields of * the XEvent. It is used by the event generate command. * * Results: * None * * Side effects: * * Modifies the XEvent. Sets the xkey.keycode to a keycode value formatted * by XKeysymToKeycode and updates the shift and option flags in * xkey.state if either of those modifiers is required to generate the * keysym. * *---------------------------------------------------------------------- */ void TkpSetKeycodeAndState( TCL_UNUSED(Tk_Window), KeySym keysym, XEvent *eventPtr) { if (keysym == NoSymbol) { eventPtr->xkey.keycode = 0; } else { int eventIndex = STATE2INDEX(eventPtr->xkey.state); MacKeycode macKC; macKC.uint = XKeysymToKeycode(NULL, keysym); /* * We have a virtual keycode and a minimal choice for Shift and Option * modifiers which generates the keychar that corresponds to the * specified keysym. But we might not have the correct keychar yet, * because the xEvent may have specified modifiers beyond our minimal * set. For example, the events described by , , * and should all produce the same * uppercase Danish O. So we may need to add the extra modifiers and * do another lookup for the keychar. We don't want to do this for * special keys, however. */ if (macKC.v.o_s != eventIndex) { macKC.v.o_s |= eventIndex; } if (macKC.v.keychar < 0xF700) { UniChar keychar = macKC.v.keychar; NSString *str, *lower, *upper; if (macKC.v.virt != NO_VIRTUAL) { macKC.x.keychar = xvirtual2unichar[macKC.x.xvirtual]; } else { str = [[NSString alloc] initWithCharacters:&keychar length:1]; lower = [str lowercaseString]; upper = [str uppercaseString]; if (![str isEqual: lower]) { macKC.v.o_s |= INDEX_SHIFT; } if (macKC.v.o_s & INDEX_SHIFT) { macKC.v.keychar = [upper characterAtIndex:0]; } } } eventPtr->xkey.keycode = macKC.uint; eventPtr->xkey.state |= INDEX2STATE(macKC.v.o_s); } } /* *---------------------------------------------------------------------- * * TkpGetKeySym -- * * This is a stub function called in tkBind.c. Given a KeyPress or * KeyRelease XEvent, it maps the keycode in the event to a numerical * 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, calls TkpInitKeymapInfo. * * *---------------------------------------------------------------------- */ KeySym TkpGetKeySym( TkDisplay *dispPtr, /* Display in which to map keycode. */ XEvent *eventPtr) /* Description of X event. */ { KeySym sym; int index; MacKeycode macKC; macKC.uint = eventPtr->xkey.keycode; /* * Refresh the mapping information if it's stale. */ if (dispPtr->bindInfoStale) { TkpInitKeymapInfo(dispPtr); } /* * Modifier key events have a special mac keycode (see tkProcessKeyEvent). */ if (macKC.v.keychar == MOD_KEYCHAR) { switch (macKC.v.virt) { case 54: return XK_Meta_R; case 55: return XK_Meta_L; case 56: return XK_Shift_L; case 57: return XK_Caps_Lock; case 58: return XK_Alt_L; case 59: return XK_Control_L; case 60: return XK_Shift_R; case 61: return XK_Alt_R; case 62: return XK_Control_R; case 63: return XK_Super_L; default: return NoSymbol; } } /* * 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 = STATE2INDEX(eventPtr->xkey.state); if (eventPtr->xkey.state & LockMask) { index |= INDEX_SHIFT; } /* * First do the straightforward lookup. */ sym = XkbKeycodeToKeysym(dispPtr->display, macKC.uint, 0, index); /* * Special handling: If the key was shifted because of Lock, which is only * caps lock on macOS, not shift lock, and if the shifted keysym isn't * upper-case alphabetic, then switch back to the unshifted keysym. */ if ((index & INDEX_SHIFT) && !(eventPtr->xkey.state & ShiftMask)) { if ((sym == NoSymbol) || !Tcl_UniCharIsUpper(sym)) { sym = XkbKeycodeToKeysym(dispPtr->display, macKC.uint, 0, index & ~INDEX_SHIFT); } } /* * 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 & INDEX_SHIFT) && (sym == NoSymbol)) { sym = XkbKeycodeToKeysym(dispPtr->display, macKC.uint, 0, index & ~INDEX_SHIFT); } return sym; } /* *-------------------------------------------------------------- * * TkpInitKeymapInfo -- * * This procedure initializes fields in the display that pertain * to modifier keys. * * Results: * None. * * Side effects: * Modifier key information in dispPtr is initialized. * *-------------------------------------------------------------- */ void TkpInitKeymapInfo( TkDisplay *dispPtr) /* Display for which to recompute keymap * information. */ { dispPtr->bindInfoStale = 0; /* * On macOS the caps lock key is always interpreted to mean that alphabetic * keys become uppercase but other keys do not get shifted. (X11 allows * a configuration option which makes the caps lock equivalent to holding * down the shift key.) * There is no offical "Mode_switch" key. */ dispPtr->lockUsage = LU_CAPS; /* This field is no longer used by tkBind.c */ dispPtr->modeModMask = 0; /* The Alt and Meta keys are interchanged on Macintosh keyboards compared * to PC keyboards. These fields could be set to make the Alt key on a PC * keyboard behave likd an Alt key. That would also require interchanging * Mod1Mask and Mod2Mask in tkMacOSXKeyEvent.c. */ dispPtr->altModMask = 0; dispPtr->metaModMask = 0; /* * The modKeyCodes table lists the keycodes that appear in KeyPress or * KeyRelease XEvents for modifier keys. In tkBind.c this table is * searched to determine whether an XEvent corresponds to a modifier key. */ if (dispPtr->modKeyCodes != NULL) { ckfree(dispPtr->modKeyCodes); } dispPtr->numModKeyCodes = NUM_MOD_KEYCODES; dispPtr->modKeyCodes = (KeyCode *)ckalloc(NUM_MOD_KEYCODES * sizeof(KeyCode)); for (int i = 0; i < NUM_MOD_KEYCODES; i++) { dispPtr->modKeyCodes[i] = XKeysymToKeycode(NULL, modKeyArray[i]); } } /* *-------------------------------------------------------------- * * TkMacOSXAddVirtual -- * * This procedure is an internal utility which accepts an unsigned int * that has been partially filled as a MacKeycode, having the Option and * Shift state set in the o_s field and the keychar field set but with the * virtual keycode blank. It looks up the virtual keycode for the keychar * (possibly NO_VIRTUAL) and returns an unsigned int which is a complete * MacKeycode with the looked up virtual keycode added. This is used when * creating XEvents for the unicode characters which are generated by the * NSTextInputClient. * * Results: * An unsigned int which is a complete MacKeycode, including a virtual * keycode which matches the Option-Shift state and keychar. * * Side effects: * None * *-------------------------------------------------------------- */ unsigned TkMacOSXAddVirtual( unsigned int keycode) { MacKeycode macKC; Tcl_HashEntry *hPtr; macKC.uint = keycode; if (!initialized) { InitHashTables(); } hPtr = (Tcl_HashEntry *) Tcl_FindHashEntry(&unichar2xvirtual, INT2PTR(macKC.v.keychar)); if (hPtr != NULL) { unsigned long data = (unsigned long) Tcl_GetHashValue(hPtr); macKC.x.xvirtual = (unsigned int) data; } else { macKC.v.virt = NO_VIRTUAL; } return macKC.uint; } /* * Local Variables: * mode: objc * c-basic-offset: 4 * fill-column: 79 * coding: utf-8 * End: */