/* $NetBSD: wzero3_kbd.c,v 1.8 2012/10/27 17:17:52 chs Exp $ */ /*- * Copyright (C) 2008, 2009, 2010 NONAKA Kimihiro * 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. * * 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 __KERNEL_RCSID(0, "$NetBSD: wzero3_kbd.c,v 1.8 2012/10/27 17:17:52 chs Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DEBUG #define DPRINTF(arg) printf arg #else #define DPRINTF(arg) /* nothing */ #endif #define CSR_READ1(r) bus_space_read_1(sc->sc_iot, sc->sc_ioh, (r)) #define CSR_WRITE1(r,v) bus_space_write_1(sc->sc_iot, sc->sc_ioh, (r), (v)) #define CSR_READ2(r) bus_space_read_2(sc->sc_iot, sc->sc_ioh, (r)) #define CSR_WRITE2(r,v) bus_space_write_2(sc->sc_iot, sc->sc_ioh, (r), (v)) #define CSR_READ4(r) bus_space_read_4(sc->sc_iot, sc->sc_ioh, (r)) #define CSR_WRITE4(r,v) bus_space_write_4(sc->sc_iot, sc->sc_ioh, (r), (v)) /* register */ #define KBDCOL_L (0x00) /* Write */ #define KBDCOL_U (0x04) /* Write */ #define KBDCHARGE (0x08) /* Write */ #define KBDDATA (0x08) /* Read */ #define REGMAPSIZE 0x0c #define KEYWAIT 20 /* us */ #define WS003SH_NCOLUMN 12 #define WS003SH_NROW 7 struct wzero3kbd_softc { device_t sc_dev; bus_space_tag_t sc_iot; bus_space_handle_t sc_ioh; int sc_ncolumn; int sc_nrow; uint8_t *sc_okeystat; uint8_t *sc_keystat; void *sc_key_ih; void *sc_power_ih; void *sc_reset_ih; int sc_key_pin; int sc_power_pin; int sc_reset_pin; struct hpckbd_ic_if sc_if; struct hpckbd_if *sc_hpckbd; struct sysmon_pswitch sc_smpsw; /* for reset key */ int sc_enabled; /* polling stuff */ struct callout sc_keyscan_ch; int sc_interval; #define KEY_INTERVAL 50 /* ms */ #if defined(KEYTEST) || defined(KEYTEST2) || defined(KEYTEST3) || defined(KEYTEST4) || defined(KEYTEST5) void *sc_test_ih; int sc_test_pin; int sc_nouse_pin; int sc_nouse_pin2; int sc_nouse_pin3; int sc_bit; #endif }; static int wzero3kbd_match(device_t, cfdata_t, void *); static void wzero3kbd_attach(device_t, device_t, void *); CFATTACH_DECL_NEW(wzero3kbd, sizeof(struct wzero3kbd_softc), wzero3kbd_match, wzero3kbd_attach, NULL, NULL); static int wzero3kbd_intr(void *arg); #if defined(KEYTEST) static int wzero3kbd_intr2(void *arg); #endif #if defined(KEYTEST3) static int wzero3kbd_intr3(void *arg); #endif static void wzero3kbd_tick(void *arg); static int wzero3kbd_power_intr(void *arg); static int wzero3kbd_reset_intr(void *arg); static int wzero3kbd_input_establish(void *arg, struct hpckbd_if *kbdif); static void wzero3kbd_sysmon_reset_event(void *arg); static int wzero3kbd_poll(void *arg); static int wzero3kbd_poll1(void *arg); /* * WS003SH/WS004SH/WS007SH keyscan map col#0 col#1 col#2 col#3 col#4 col#5 col#6 col#7 col#8 col#9 col#10 col#11 row#0: CTRL 1 3 5 6 7 9 0 BS (none) ROTATE CAMERA row#1: (none) 2 4 r y 8 i o p (none) VOL- VOL+ row#2: TAB q e t g u j k (none) (none) (none) (none) row#3: (none) w s f v h m l (none) (none) SHIFT (none) row#4: CALL a d c b n . (none) ENTER (none) WIN (none) row#5: MAIL z x - SPACE / (none) UP (none) (none) LSOFT FN row#6: IE MOJI (none) OK ACTION , LEFT DOWN RIGHT (none) RSOFT (none) */ /* * WS011SH keyscan map col#0 col#1 col#2 col#3 col#4 col#5 col#6 col#7 col#8 col#9 col#10 col#11 row#0 Ctrl (none) (none) (none) (none) (none) (none) (none) Del (none) ROTATE (none) row#1 (none) (none) (none) R Y (none) I O P (none) (none) (none) row#2 Tab Q E T G U J K (none) (none) (none) (none) row#3 (none) W S F V H M L (none) (none) Shift (none) row#4 (none) A D C B N . (none) Enter (none) (none) (none) row#5 (none) Z X - Space / (none) UP (none) (none) (none) Fn row#6 (none) MOJI HAN/ZEN OK (none) , LEFT DOWN RIGHT (none) (none) (none) */ /* * WS020SH keyscan map col#0 col#1 col#2 col#3 col#4 col#5 col#6 col#7 col#8 col#9 col#10 col#11 row#0 Ctrl (none) (none) (none) (none) (none) (none) (none) Del (none) ROTATE (none) row#1 (none) (none) (none) R Y (none) I O P (none) MEDIA (none) row#2 Tab Q E T G U J K (none) (none) (none) (none) row#3 (none) W S F V H M L (none) (none) LShift (none) row#4 (none) A D C B N . (none) Enter (none) RShift (none) row#5 (none) Z X - Space / (none) UP (none) DOWN (none) Fn row#6 (none) MOJI HAN/ZEN OK (none) , LEFT (none) RIGHT (none) (none) (none) */ static const struct wzero3kbd_model { platid_mask_t *platid; int key_pin; int power_pin; int reset_pin; int ncolumn; int nrow; } wzero3kbd_table[] = { /* WS003SH */ { &platid_mask_MACH_SHARP_WZERO3_WS003SH, -1, /* XXX */ GPIO_WS003SH_POWER_BUTTON, -1, /* None */ WS003SH_NCOLUMN, WS003SH_NROW, }, /* WS004SH */ { &platid_mask_MACH_SHARP_WZERO3_WS004SH, -1, /* XXX */ GPIO_WS003SH_POWER_BUTTON, -1, /* None */ WS003SH_NCOLUMN, WS003SH_NROW, }, /* WS007SH */ { &platid_mask_MACH_SHARP_WZERO3_WS007SH, -1, /* XXX */ GPIO_WS007SH_POWER_BUTTON, GPIO_WS007SH_RESET_BUTTON, WS003SH_NCOLUMN, WS003SH_NROW, }, /* WS011SH */ { &platid_mask_MACH_SHARP_WZERO3_WS011SH, -1, /* XXX */ GPIO_WS011SH_POWER_BUTTON, GPIO_WS011SH_RESET_BUTTON, WS003SH_NCOLUMN, WS003SH_NROW, }, /* WS020SH */ { &platid_mask_MACH_SHARP_WZERO3_WS020SH, -1, /* XXX */ GPIO_WS020SH_POWER_BUTTON, GPIO_WS020SH_RESET_BUTTON, WS003SH_NCOLUMN, WS003SH_NROW, }, { NULL, -1, -1, -1, 0, 0, } }; static const struct wzero3kbd_model * wzero3kbd_lookup(void) { const struct wzero3kbd_model *model; for (model = wzero3kbd_table; model->platid != NULL; model++) { if (platid_match(&platid, model->platid)) { return model; } } return NULL; } static int wzero3kbd_match(device_t parent, cfdata_t cf, void *aux) { if (strcmp(cf->cf_name, "wzero3kbd") != 0) return 0; if (wzero3kbd_lookup() == NULL) return 0; return 1; } static void wzero3kbd_attach(device_t parent, device_t self, void *aux) { struct wzero3kbd_softc *sc = device_private(self); struct pxaip_attach_args *pxa = (struct pxaip_attach_args *)aux; struct hpckbd_attach_args haa; const struct wzero3kbd_model *model; sc->sc_dev = self; model = wzero3kbd_lookup(); if (model == NULL) { aprint_error(": unknown model\n"); return; } aprint_normal(": keyboard\n"); aprint_naive("\n"); sc->sc_key_pin = model->key_pin; sc->sc_power_pin = model->power_pin; sc->sc_reset_pin = model->reset_pin; sc->sc_ncolumn = model->ncolumn; sc->sc_nrow = model->nrow; sc->sc_iot = pxa->pxa_iot; if (bus_space_map(sc->sc_iot, PXA2X0_CS2_START, REGMAPSIZE, 0, &sc->sc_ioh)) { aprint_error_dev(self, "couldn't map registers.\n"); return; } sc->sc_okeystat = malloc(sc->sc_nrow * sc->sc_ncolumn, M_DEVBUF, M_NOWAIT | M_ZERO); sc->sc_keystat = malloc(sc->sc_nrow * sc->sc_ncolumn, M_DEVBUF, M_NOWAIT | M_ZERO); if (sc->sc_okeystat == NULL || sc->sc_keystat == NULL) { aprint_error_dev(self, "couldn't alloc memory.\n"); if (sc->sc_okeystat) free(sc->sc_okeystat, M_DEVBUF); if (sc->sc_keystat) free(sc->sc_keystat, M_DEVBUF); return; } sc->sc_if.hii_ctx = sc; sc->sc_if.hii_establish = wzero3kbd_input_establish; sc->sc_if.hii_poll = wzero3kbd_poll; /* Attach console if not using serial. */ if (!(bootinfo->bi_cnuse & BI_CNUSE_SERIAL)) hpckbd_cnattach(&sc->sc_if); /* Install interrupt handler. */ if (sc->sc_key_pin >= 0) { pxa2x0_gpio_set_function(sc->sc_key_pin, GPIO_IN); sc->sc_key_ih = pxa2x0_gpio_intr_establish(sc->sc_key_pin, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_intr, sc); if (sc->sc_key_ih == NULL) { aprint_error_dev(sc->sc_dev, "couldn't establish key interrupt\n"); } } else { sc->sc_interval = KEY_INTERVAL / (1000 / hz); if (sc->sc_interval < 1) sc->sc_interval = 1; callout_init(&sc->sc_keyscan_ch, 0); callout_reset(&sc->sc_keyscan_ch, sc->sc_interval, wzero3kbd_tick, sc); } /* power key */ if (sc->sc_power_pin >= 0) { pxa2x0_gpio_set_function(sc->sc_power_pin, GPIO_IN); sc->sc_power_ih = pxa2x0_gpio_intr_establish( sc->sc_power_pin, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_power_intr, sc); if (sc->sc_power_ih == NULL) { aprint_error_dev(sc->sc_dev, "couldn't establish power key interrupt\n"); } } /* reset button */ if (sc->sc_reset_pin >= 0) { pxa2x0_gpio_set_function(sc->sc_reset_pin, GPIO_IN); sc->sc_reset_ih = pxa2x0_gpio_intr_establish( sc->sc_reset_pin, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_reset_intr, sc); if (sc->sc_reset_ih == NULL) { aprint_error_dev(sc->sc_dev, "couldn't establish reset key interrupt\n"); } sc->sc_smpsw.smpsw_name = device_xname(self); sc->sc_smpsw.smpsw_type = PSWITCH_TYPE_RESET; if (sysmon_pswitch_register(&sc->sc_smpsw) != 0) { aprint_error_dev(sc->sc_dev, "unable to register reset event handler\n"); } } /* Attach hpckbd. */ haa.haa_ic = &sc->sc_if; config_found(self, &haa, hpckbd_print); #if defined(KEYTEST) || defined(KEYTEST2) || defined(KEYTEST3) || defined(KEYTEST4) || defined(KEYTEST5) sc->sc_test_ih = NULL; sc->sc_test_pin = -1; sc->sc_nouse_pin = -1; sc->sc_nouse_pin2 = -1; sc->sc_nouse_pin3 = -1; sc->sc_bit = 0x01; if (platid_match(&platid, &platid_mask_MACH_SHARP_WZERO3_WS003SH) || platid_match(&platid, &platid_mask_MACH_SHARP_WZERO3_WS004SH)) { sc->sc_nouse_pin = GPIO_WS003SH_SD_DETECT; /* SD_DETECT */ sc->sc_nouse_pin2 = 86; /* Vsync? */ sc->sc_nouse_pin3 = 89; /* RESET? */ } if (platid_match(&platid, &platid_mask_MACH_SHARP_WZERO3_WS007SH)) { sc->sc_nouse_pin = GPIO_WS007SH_SD_DETECT; /* SD_DETECT */ sc->sc_nouse_pin2 = 77; /* Vsync? */ } if (platid_match(&platid, &platid_mask_MACH_SHARP_WZERO3_WS011SH)) { sc->sc_nouse_pin = GPIO_WS011SH_SD_DETECT; /* SD_DETECT */ sc->sc_nouse_pin2 = 77; /* Vsync? */ } if (platid_match(&platid, &platid_mask_MACH_SHARP_WZERO3_WS020SH)) { sc->sc_nouse_pin = GPIO_WS020SH_SD_DETECT; /* SD_DETECT */ sc->sc_nouse_pin2 = 77; /* Vsync? */ } #ifdef KEYTEST for (sc->sc_test_pin = 2; sc->sc_test_pin < PXA270_GPIO_NPINS; sc->sc_test_pin++) { if (sc->sc_test_pin != sc->sc_nouse_pin && sc->sc_test_pin != sc->sc_nouse_pin2 && sc->sc_test_pin != sc->sc_nouse_pin3 && sc->sc_test_pin != sc->sc_key_pin && sc->sc_test_pin != sc->sc_power_pin && sc->sc_test_pin != sc->sc_reset_pin && GPIO_IS_GPIO_IN(pxa2x0_gpio_get_function(sc->sc_test_pin))) break; } if (sc->sc_test_pin < PXA270_GPIO_NPINS) { printf("GPIO_IN: GPIO pin #%d\n", sc->sc_test_pin); sc->sc_test_ih = pxa2x0_gpio_intr_establish(sc->sc_test_pin, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_intr2, sc); } else { sc->sc_test_pin = -1; } #endif #ifdef KEYTEST3 { int i; printf("pin: "); for (i = 0; i < PXA270_GPIO_NPINS; i++) { if (i == sc->sc_nouse_pin || i == sc->sc_nouse_pin2 || i == sc->sc_nouse_pin3 || i == sc->sc_key_pin || i == sc->sc_power_pin || i == sc->sc_reset_pin) continue; printf("%d, ", i); if (GPIO_IS_GPIO_IN(pxa2x0_gpio_get_function(i))) { pxa2x0_gpio_intr_establish(i, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_intr3, (void *)(long)i); } } } #endif #ifdef KEYTEST4 for (sc->sc_test_pin = 2; sc->sc_test_pin < PXA270_GPIO_NPINS; sc->sc_test_pin++) { if (sc->sc_test_pin != sc->sc_nouse_pin && sc->sc_test_pin != sc->sc_nouse_pin2 && sc->sc_test_pin != sc->sc_nouse_pin3 && sc->sc_test_pin != sc->sc_key_pin && sc->sc_test_pin != sc->sc_power_pin && sc->sc_test_pin != sc->sc_reset_pin && GPIO_IS_GPIO_OUT(pxa2x0_gpio_get_function(sc->sc_test_pin))) break; } if (sc->sc_test_pin < PXA270_GPIO_NPINS) { printf("GPIO_OUT: GPIO pin #%d\n", sc->sc_test_pin); } else { sc->sc_test_pin = -1; } #endif #ifdef KEYTEST5 sc->sc_test_pin = 0x00; sc->sc_bit = 0x01; #endif #endif } static int wzero3kbd_intr(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; #if defined(KEYTEST) || defined(KEYTEST2) || defined(KEYTEST3) || defined(KEYTEST4) || defined(KEYTEST5) printf("wzero3kbd_intr: GPIO pin #%d = %s\n", sc->sc_key_pin, pxa2x0_gpio_get_bit(sc->sc_key_pin) ? "on" : "off"); #endif #if defined(KEYTEST4) if (sc->sc_test_pin >= 0) { if (pxa2x0_gpio_get_bit(sc->sc_test_pin)) { printf("GPIO_OUT: GPIO pin #%d: L\n",sc->sc_test_pin); pxa2x0_gpio_clear_bit(sc->sc_test_pin); } else { printf("GPIO_OUT: GPIO pin #%d: H\n", sc->sc_test_pin); pxa2x0_gpio_set_bit(sc->sc_test_pin); } } #endif #if defined(KEYTEST5) printf("CPLD(%#x): value=%#x, mask=%#x\n", sc->sc_test_pin, CSR_READ4(sc->sc_test_pin), sc->sc_bit); if (CSR_READ4(sc->sc_test_pin) & sc->sc_bit) { printf("CPLD_OUT: CPLD: L\n"); CSR_WRITE4(sc->sc_test_pin, CSR_READ4(sc->sc_test_pin) & ~sc->sc_bit); } else { printf("CPLD_OUT: CPLD: H\n"); CSR_WRITE4(sc->sc_test_pin, CSR_READ4(sc->sc_test_pin) | sc->sc_bit); } #endif (void) wzero3kbd_poll1(sc); pxa2x0_gpio_clear_intr(sc->sc_key_pin); return 1; } #if defined(KEYTEST) static int wzero3kbd_intr2(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; printf("wzero3kbd_intr2: GPIO_IN: GPIO pin #%d = %s\n", sc->sc_test_pin, pxa2x0_gpio_get_bit(sc->sc_test_pin) ? "on" : "off"); return 1; } #endif #if defined(KEYTEST3) static int wzero3kbd_intr3(void *arg) { int pin = (int)arg; printf("wzero3kbd_intr3: GPIO pin #%d = %s\n", pin, pxa2x0_gpio_get_bit(pin) ? "on" : "off"); return 1; } #endif static void wzero3kbd_tick(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; (void) wzero3kbd_poll1(sc); callout_schedule(&sc->sc_keyscan_ch, sc->sc_interval); } static int wzero3kbd_power_intr(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; #if defined(KEYTEST) || defined(KEYTEST2) || defined(KEYTEST3) || defined(KEYTEST4) printf("wzero3kbd_power_intr: status = %s\n", pxa2x0_gpio_get_bit(sc->sc_power_pin) ? "on" : "off"); #endif #if defined(KEYTEST) if (pxa2x0_gpio_get_bit(sc->sc_power_pin)) { if (sc->sc_test_pin >= 0) { int orig_pin = sc->sc_test_pin; pxa2x0_gpio_intr_disestablish(sc->sc_test_ih); sc->sc_test_ih = NULL; for (;;) { if (++sc->sc_test_pin >= PXA270_GPIO_NPINS) sc->sc_test_pin = 2; if (sc->sc_test_pin == orig_pin) break; if (sc->sc_test_pin != sc->sc_nouse_pin && sc->sc_test_pin != sc->sc_nouse_pin2 && sc->sc_test_pin != sc->sc_nouse_pin3 && sc->sc_test_pin != sc->sc_key_pin && sc->sc_test_pin != sc->sc_power_pin && sc->sc_test_pin != sc->sc_reset_pin && GPIO_IS_GPIO_IN(pxa2x0_gpio_get_function(sc->sc_test_pin))) break; } if (sc->sc_test_pin != orig_pin) { printf("GPIO_IN: GPIO pin #%d\n", sc->sc_test_pin); sc->sc_test_ih = pxa2x0_gpio_intr_establish(sc->sc_test_pin, IST_EDGE_BOTH, IPL_TTY, wzero3kbd_intr2,sc); } else { sc->sc_test_pin = -1; } } } #endif #if defined(KEYTEST2) if (pxa2x0_gpio_get_bit(sc->sc_power_pin)) { sc->sc_enabled ^= 2; if (sc->sc_enabled & 2) { printf("print col/row\n"); } else { printf("keyscan\n"); } } #endif #if defined(KEYTEST4) if (pxa2x0_gpio_get_bit(sc->sc_power_pin)) { if (sc->sc_test_pin >= 0) { int orig_pin = sc->sc_test_pin; for (;;) { if (++sc->sc_test_pin >= PXA270_GPIO_NPINS) sc->sc_test_pin = 2; if (sc->sc_test_pin == orig_pin) break; if (sc->sc_test_pin != sc->sc_nouse_pin && sc->sc_test_pin != sc->sc_nouse_pin2 && sc->sc_test_pin != sc->sc_nouse_pin3 && sc->sc_test_pin != sc->sc_key_pin && sc->sc_test_pin != sc->sc_power_pin && sc->sc_test_pin != sc->sc_reset_pin && GPIO_IS_GPIO_OUT(pxa2x0_gpio_get_function(sc->sc_test_pin))) break; } if (sc->sc_test_pin != orig_pin) { printf("GPIO_OUT: GPIO pin #%d\n", sc->sc_test_pin); } else { sc->sc_test_pin = -1; } } } #endif #if defined(KEYTEST5) if (pxa2x0_gpio_get_bit(sc->sc_power_pin)) { sc->sc_bit <<= 1; if (sc->sc_bit & ~0xff) { sc->sc_bit = 0x01; sc->sc_test_pin += 0x4; if (sc->sc_test_pin >= 0x20) { sc->sc_test_pin = 0x00; } } printf("CPLD(%#x), mask=%#x\n", sc->sc_test_pin, sc->sc_bit); } #endif pxa2x0_gpio_clear_intr(sc->sc_power_pin); return 1; } static int wzero3kbd_reset_intr(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; sysmon_task_queue_sched(0, wzero3kbd_sysmon_reset_event, sc); pxa2x0_gpio_clear_intr(sc->sc_reset_pin); return 1; } static int wzero3kbd_input_establish(void *arg, struct hpckbd_if *kbdif) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; /* Save hpckbd interface. */ sc->sc_hpckbd = kbdif; sc->sc_enabled = 1; return 0; } static void wzero3kbd_sysmon_reset_event(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; sysmon_pswitch_event(&sc->sc_smpsw, PSWITCH_EVENT_PRESSED); } static int wzero3kbd_poll(void *arg) { int keydown; keydown = wzero3kbd_poll1(arg); return keydown; } static int wzero3kbd_poll1(void *arg) { struct wzero3kbd_softc *sc = (struct wzero3kbd_softc *)arg; int row, col, data; int keycol; int keydown; int i; int s; if (!sc->sc_enabled) { DPRINTF(("wzero3kbd_poll: disabled\n")); return 0; } s = spltty(); for (col = 0; col < sc->sc_ncolumn; col++) { /* deselect column# and charge */ CSR_WRITE1(KBDCOL_L, 0); CSR_WRITE1(KBDCOL_U, 0); CSR_WRITE1(KBDCHARGE, 1); delay(KEYWAIT); CSR_WRITE1(KBDCHARGE, 0); /* select scan column# */ keycol = 1 << col; CSR_WRITE1(KBDCOL_L, keycol & 0xff); CSR_WRITE1(KBDCOL_U, keycol >> 8); delay(KEYWAIT); CSR_WRITE1(KBDCHARGE, 0); /* read key data */ data = CSR_READ1(KBDDATA); for (row = 0; row < sc->sc_nrow; row++) { #ifdef KEYTEST2 if (!(sc->sc_enabled & 2)) { #endif sc->sc_keystat[row + col * sc->sc_nrow] = (data >> row) & 1; #ifdef KEYTEST2 } else if (data & (1 << row)) { printf("col = %d, row = %d, idx = %d, data = 0x%02x\n", col, row, row + col * sc->sc_nrow, data); } #endif } } /* deselect column# and charge */ CSR_WRITE1(KBDCOL_L, 0); CSR_WRITE1(KBDCOL_U, 0); CSR_WRITE1(KBDCHARGE, 1); delay(KEYWAIT); CSR_WRITE1(KBDCHARGE, 0); /* send key scan code */ keydown = 0; for (i = 0; i < sc->sc_nrow * sc->sc_ncolumn; i++) { if (sc->sc_keystat[i] == sc->sc_okeystat[i]) continue; keydown |= sc->sc_keystat[i]; hpckbd_input(sc->sc_hpckbd, sc->sc_keystat[i], i); sc->sc_okeystat[i] = sc->sc_keystat[i]; } splx(s); return keydown; }