/* $OpenBSD: akbd.c,v 1.11 2011/11/09 14:22:37 shadchin Exp $ */ /* $NetBSD: akbd.c,v 1.17 2005/01/15 16:00:59 chs Exp $ */ /* * Copyright (C) 1998 Colin Wood * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Colin Wood. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Function declarations. */ int akbdmatch(struct device *, void *, void *); void akbdattach(struct device *, struct device *, void *); /* Driver definition. */ struct cfattach akbd_ca = { sizeof(struct akbd_softc), akbdmatch, akbdattach }; struct cfdriver akbd_cd = { NULL, "akbd", DV_DULL }; int akbd_enable(void *, int); void akbd_set_leds(void *, int); int akbd_ioctl(void *, u_long, caddr_t, int, struct proc *); struct wskbd_accessops akbd_accessops = { akbd_enable, akbd_set_leds, akbd_ioctl, }; struct wskbd_mapdata akbd_keymapdata = { akbd_keydesctab, #ifdef AKBD_LAYOUT AKBD_LAYOUT, #else KB_US, #endif }; void akbd_adbcomplete(caddr_t, caddr_t, int); void akbd_capslockwrapper(struct akbd_softc *, int); void akbd_input(struct akbd_softc *, int); void akbd_processevent(struct akbd_softc *, adb_event_t *); #ifdef notyet u_char getleds(int); int setleds(struct akbd_softc *, u_char); void blinkleds(struct akbd_softc *); #endif int akbdmatch(struct device *parent, void *vcf, void *aux) { struct adb_attach_args *aa_args = (struct adb_attach_args *)aux; if (strcmp(aa_args->name, adb_device_name) != 0) return (0); if (aa_args->origaddr == ADBADDR_KBD) return (1); else return (0); } void akbdattach(struct device *parent, struct device *self, void *aux) { ADBSetInfoBlock adbinfo; struct akbd_softc *sc = (struct akbd_softc *)self; struct adb_attach_args *aa_args = (struct adb_attach_args *)aux; int error, kbd_done; short cmd; u_char buffer[9]; struct wskbddev_attach_args a; static int akbd_console_initted; int wskbd_eligible = 1; sc->origaddr = aa_args->origaddr; sc->adbaddr = aa_args->adbaddr; sc->handler_id = aa_args->handler_id; sc->sc_leds = (u_int8_t)0x00; /* initially off */ sc->sc_caps = 0; adbinfo.siServiceRtPtr = (Ptr)akbd_adbcomplete; adbinfo.siDataAreaAddr = (caddr_t)sc; printf(": "); switch (sc->handler_id) { case ADB_STDKBD: printf("standard keyboard\n"); break; case ADB_ISOKBD: printf("standard keyboard (ISO layout)\n"); break; case ADB_EXTKBD: cmd = ADBTALK(sc->adbaddr, 1); kbd_done = (adb_op_sync((Ptr)buffer, cmd) == 0); /* Ignore Logitech MouseMan/Trackman pseudo keyboard */ if (kbd_done && buffer[1] == 0x9a && buffer[2] == 0x20) { printf("Mouseman (non-EMP) pseudo keyboard\n"); adbinfo.siServiceRtPtr = (Ptr)0; adbinfo.siDataAreaAddr = (Ptr)0; wskbd_eligible = 0; } else if (kbd_done && buffer[1] == 0x9a && buffer[2] == 0x21) { printf("Trackman (non-EMP) pseudo keyboard\n"); adbinfo.siServiceRtPtr = (Ptr)0; adbinfo.siDataAreaAddr = (Ptr)0; wskbd_eligible = 0; } else { printf("extended keyboard\n"); #ifdef notyet blinkleds(sc); #endif } break; case ADB_EXTISOKBD: printf("extended keyboard (ISO layout)\n"); #ifdef notyet blinkleds(sc); #endif break; case ADB_KBDII: printf("keyboard II\n"); break; case ADB_ISOKBDII: printf("keyboard II (ISO layout)\n"); break; case ADB_PBKBD: printf("PowerBook keyboard\n"); break; case ADB_PBISOKBD: printf("PowerBook keyboard (ISO layout)\n"); break; case ADB_ADJKPD: printf("adjustable keypad\n"); wskbd_eligible = 0; break; case ADB_ADJKBD: printf("adjustable keyboard\n"); break; case ADB_ADJISOKBD: printf("adjustable keyboard (ISO layout)\n"); break; case ADB_ADJJAPKBD: printf("adjustable keyboard (Japanese layout)\n"); break; case ADB_PBEXTISOKBD: printf("PowerBook extended keyboard (ISO layout)\n"); break; case ADB_PBEXTJAPKBD: printf("PowerBook extended keyboard (Japanese layout)\n"); break; case ADB_JPKBDII: printf("keyboard II (Japanese layout)\n"); break; case ADB_PBEXTKBD: printf("PowerBook extended keyboard\n"); break; case ADB_DESIGNKBD: printf("extended keyboard\n"); #ifdef notyet blinkleds(sc); #endif break; case ADB_PBJPKBD: printf("PowerBook keyboard (Japanese layout)\n"); break; case ADB_PBG3JPKBD: printf("PowerBook G3 keyboard (Japanese layout)\n"); break; case ADB_PBG4KBD: printf("PowerBook G4 keyboard (Inverted T)\n"); break; case ADB_IBITISOKBD: printf("iBook keyboard with inverted T (ISO layout)\n"); break; default: printf("mapped device (%d)\n", sc->handler_id); #if 0 wskbd_eligible = 0; #endif break; } error = set_adb_info(&adbinfo, sc->adbaddr); #ifdef ADB_DEBUG if (adb_debug) printf("akbd: returned %d from set_adb_info\n", error); #endif if (akbd_is_console() && wskbd_eligible) a.console = (++akbd_console_initted == 1); else a.console = 0; a.keymap = &akbd_keymapdata; a.accessops = &akbd_accessops; a.accesscookie = sc; sc->sc_wskbddev = config_found(self, &a, wskbddevprint); } /* * Handle putting the keyboard data received from the ADB into * an ADB event record. */ void akbd_adbcomplete(caddr_t buffer, caddr_t data_area, int adb_command) { adb_event_t event; struct akbd_softc *sc; int adbaddr; #ifdef ADB_DEBUG int i; if (adb_debug) printf("adb: transaction completion\n"); #endif adbaddr = ADB_CMDADDR(adb_command); sc = (struct akbd_softc *)data_area; event.byte_count = buffer[0]; memcpy(event.bytes, buffer + 1, event.byte_count); #ifdef ADB_DEBUG if (adb_debug) { printf("akbd: from %d at %d (org %d) %d:", adbaddr, sc->handler_id, sc->origaddr, buffer[0]); for (i = 1; i <= buffer[0]; i++) printf(" %x", buffer[i]); printf("\n"); } #endif if (sc->sc_wskbddev != NULL) akbd_processevent(sc, &event); } #ifdef notyet /* * Get the actual hardware LED state and convert it to softc format. */ u_char getleds(int addr) { short cmd; u_char buffer[9], leds; leds = 0x00; /* all off */ buffer[0] = 0; cmd = ADBTALK(addr, 2); if (adb_op_sync((Ptr)buffer, cmd) == 0 && buffer[0] > 0) leds = ~(buffer[2]) & 0x07; return (leds); } /* * Set the keyboard LED's. * * Automatically translates from ioctl/softc format to the * actual keyboard register format */ int setleds(struct akbd_softc *sc, u_char leds) { int addr; short cmd; u_char buffer[9]; addr = sc->adbaddr; buffer[0] = 0; cmd = ADBTALK(addr, 2); if (adb_op_sync((Ptr)buffer, cmd) || buffer[0] == 0) return (EIO); leds = ~leds & 0x07; buffer[2] &= 0xf8; buffer[2] |= leds; cmd = ADBLISTEN(addr, 2); adb_op_sync((Ptr)buffer, cmd); /* talk R2 */ cmd = ADBTALK(addr, 2); if (adb_op_sync((Ptr)buffer, cmd) || buffer[0] == 0) return (EIO); if ((buffer[2] & 0xf8) != leds) return (EIO); else return (0); } /* * Toggle all of the LED's on and off, just for show. */ void blinkleds(struct akbd_softc *sc) { u_char origleds; origleds = getleds(sc->adbaddr); setleds(sc, LED_NUMLOCK | LED_CAPSLOCK | LED_SCROLL_LOCK); delay(400000); setleds(sc, origleds); if (origleds & LED_NUMLOCK) sc->sc_leds |= WSKBD_LED_NUM; if (origleds & LED_CAPSLOCK) sc->sc_leds |= WSKBD_LED_CAPS; if (origleds & LED_SCROLL_LOCK) sc->sc_leds |= WSKBD_LED_SCROLL; } #endif int akbd_enable(void *v, int on) { return 0; } void akbd_set_leds(void *v, int on) { #ifdef notyet struct akbd_softc *sc = v; int leds; if (sc->sc_extended) { if (sc->sc_leds == on) return; leds = 0; if (on & WSKBD_LED_NUM) leds |= LED_NUMLOCK; if (on & WSKBD_LED_CAPS) leds |= LED_CAPSLOCK; if (on & WSKBD_LED_SCROLL) leds |= LED_SCROLL_LOCK; setleds(sc, leds); } #endif } int akbd_ioctl(void *v, u_long cmd, caddr_t data, int flag, struct proc *p) { struct akbd_softc *sc = v; switch (cmd) { case WSKBDIO_GTYPE: *(int *)data = WSKBD_TYPE_ADB; return 0; case WSKBDIO_SETLEDS: akbd_set_leds(v, *(int *)data); return 0; case WSKBDIO_GETLEDS: *(int *)data = sc->sc_leds; return 0; #ifdef WSDISPLAY_COMPAT_RAWKBD case WSKBDIO_SETMODE: sc->sc_rawkbd = *(int *)data == WSKBD_RAW; return (0); #endif #if defined(__mac68k__) /* XXX not worth creating akbd_machdep_ioctl() */ case WSKBDIO_BELL: case WSKBDIO_COMPLEXBELL: #define d ((struct wskbd_bell_data *)data) mac68k_ring_bell(d->pitch, d->period * hz / 1000, d->volume); #undef d return (0); #endif default: return (-1); } } /* * The ``caps lock'' key is special: since on earlier keyboards, the physical * key stays down when pressed, we will get a notification of the key press, * but not of the key release. Then, when it is pressed again, we will not get * a notification of the key press, but will see the key release. * * This is not exactly true. We see the missing release and press events both * as the release of the power (reset) key. * * To avoid confusing them with real power key presses, we maintain two * states for the caps lock key: logically down (from wscons' point of view), * and ``physically'' down (from the adb messages point of view), to ignore * the power key. But since one may press the power key while the caps lock * is held down, we also have to remember the state of the power key... this * is quite messy. */ /* * Values for caps lock state machine */ #define CL_DOWN_ADB 0x01 #define CL_DOWN_LOGICAL 0x02 #define CL_DOWN_RESET 0x04 /* * Given a keyboard ADB event, decode the keycodes and pass them to wskbd. */ void akbd_processevent(struct akbd_softc *sc, adb_event_t *event) { switch (event->byte_count) { case 1: akbd_capslockwrapper(sc, event->bytes[0]); break; case 2: /* * The reset (or power) key sends 0x7f7f on press and * 0xffff on release, and we ignore it. */ if (event->bytes[0] == event->bytes[1] && ADBK_KEYVAL(event->bytes[0]) == ADBK_RESET) { if (event->bytes[0] == ADBK_KEYDOWN(ADBK_RESET)) SET(sc->sc_caps, CL_DOWN_RESET); else { if (ISSET(sc->sc_caps, CL_DOWN_RESET)) CLR(sc->sc_caps, CL_DOWN_RESET); else if (ISSET(sc->sc_caps, CL_DOWN_ADB)) { akbd_input(sc, ISSET(sc->sc_caps, CL_DOWN_LOGICAL) ? ADBK_KEYDOWN(ADBK_CAPSLOCK) : ADBK_KEYUP(ADBK_CAPSLOCK)); sc->sc_caps ^= CL_DOWN_LOGICAL; } } } else { akbd_capslockwrapper(sc, event->bytes[0]); akbd_capslockwrapper(sc, event->bytes[1]); } break; default: #ifdef DIAGNOSTIC printf("%s: unexpected message length %d\n", sc->sc_dev.dv_xname, event->byte_count); #endif break; } } void akbd_capslockwrapper(struct akbd_softc *sc, int key) { if (ADBK_KEYVAL(key) == ADBK_CAPSLOCK) sc->sc_caps ^= CL_DOWN_ADB; if (key != 0xff) akbd_input(sc, key); } int adb_polledkey; void akbd_input(struct akbd_softc *sc, int key) { int press, val; int type; press = ADBK_PRESS(key); val = ADBK_KEYVAL(key); type = press ? WSCONS_EVENT_KEY_DOWN : WSCONS_EVENT_KEY_UP; if (adb_polling) { adb_polledkey = key; #ifdef WSDISPLAY_COMPAT_RAWKBD } else if (sc->sc_rawkbd) { char cbuf[2]; int c, j, s; j = 0; c = keyboard[val]; if (c == 0) { return; /* XXX */ } if (c & 0x80) cbuf[j++] = 0xe0; cbuf[j] = c & 0x7f; if (type == WSCONS_EVENT_KEY_UP) cbuf[j] |= 0x80; j++; s = spltty(); wskbd_rawinput(sc->sc_wskbddev, cbuf, j); splx(s); #endif } else { wskbd_input(sc->sc_wskbddev, type, val); } }