/* $NetBSD: ucbtp.c,v 1.5 2001/02/22 18:38:02 uch Exp $ */ /*- * Copyright (c) 2000, 2001 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by UCHIYAMA Yasushi. * * 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 the NetBSD * Foundation, Inc. and its contributors. * 4. Neither the name of The NetBSD Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS * ``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 FOUNDATION OR CONTRIBUTORS * 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. */ /* * Device driver for PHILIPS UCB1200 Advanced modem/audio analog front-end * Touch panel part. */ #define UCBTPDEBUG #include "opt_tx39_debug.h" #include "opt_use_poll.h" #include #include #include #include #include #include /* bootinfo */ #include #include #include #include #include #include #include #include #include #include #include /* debug */ #ifdef UCBTPDEBUG int ucbtp_debug = 0; #define DPRINTF(arg) if (ucbtp_debug) printf arg; #define DPRINTFN(n, arg) if (ucbtp_debug > (n)) printf arg; #else #define DPRINTF(arg) #define DPRINTFN(n, arg) #endif enum ucbts_stat { UCBTS_STAT_DISABLE, UCBTS_STAT_RELEASE, UCBTS_STAT_TOUCH, UCBTS_STAT_DRAG, }; #define UCBTS_POSX 1 #define UCBTS_POSY 2 #define UCBTS_PRESS 3 #define UCBTS_PRESS_THRESHOLD 80 #define UCBTS_TAP_THRESHOLD 5 enum ucbadc_state { /* 0 */ UCBADC_IDLE, /* 1 */ UCBADC_ADC_INIT, /* 2 */ UCBADC_ADC_FINI, /* 3 */ UCBADC_MEASUMENT_INIT, /* 4 */ UCBADC_MEASUMENT_FINI, /* 5 */ UCBADC_ADC_ENABLE, /* 6 */ UCBADC_ADC_START0, /* 7 */ UCBADC_ADC_START1, /* 8 */ UCBADC_ADC_DATAREAD, /* 9 */ UCBADC_ADC_DATAREAD_WAIT, /*10 */ UCBADC_ADC_DISABLE, /*11 */ UCBADC_ADC_INTRMODE, /*12 */ UCBADC_ADC_INPUT, /*13 */ UCBADC_INTR_ACK0, /*14 */ UCBADC_INTR_ACK1, /*15 */ UCBADC_INTR_ACK2, /*16 */ UCBADC_REGREAD, /*17 */ UCBADC_REGWRITE }; struct ucbtp_softc { struct device sc_dev; struct device *sc_sib; /* parent (TX39 SIB module) */ struct device *sc_ucb; /* parent (UCB1200 module) */ tx_chipset_tag_t sc_tc; enum ucbts_stat sc_stat; int sc_polling; int sc_polling_finish; void *sc_pollh; struct tpcalib_softc sc_tpcalib; int sc_calibrated; /* measurement value */ int sc_x, sc_y, sc_p; int sc_ox, sc_oy; int sc_xy_reverse; /* some platform pin connect interchanged */ /* * touch panel state machine */ void *sm_ih; /* TX39 SIB subframe 0 interrupt handler */ int sm_addr; /* UCB1200 register address */ u_int32_t sm_reg; /* UCB1200 register data & TX39 SIB header */ int sm_tmpreg; #define UCBADC_RETRY_DEFAULT 200 int sm_retry; /* retry counter */ enum ucbadc_state sm_state; int sm_measurement; /* X, Y, Pressure */ #define UCBADC_MEASUREMENT_X 0 #define UCBADC_MEASUREMENT_Y 1 #define UCBADC_MEASUREMENT_PRESSURE 2 int sm_returnstate; int sm_read_state, sm_write_state; int sm_writing; /* writing state flag */ u_int32_t sm_write_val; /* temporary buffer */ int sm_rw_retry; /* retry counter for r/w */ /* wsmouse */ struct device *sc_wsmousedev; }; int ucbtp_match __P((struct device*, struct cfdata*, void*)); void ucbtp_attach __P((struct device*, struct device*, void*)); int ucbtp_sibintr __P((void*)); int ucbtp_poll __P((void*)); int ucbtp_adc_async __P((void*)); int ucbtp_input __P((struct ucbtp_softc*)); int ucbtp_busy __P((void*)); int ucbtp_enable __P((void*)); int ucbtp_ioctl __P((void*, u_long, caddr_t, int, struct proc*)); void ucbtp_disable __P((void*)); struct cfattach ucbtp_ca = { sizeof(struct ucbtp_softc), ucbtp_match, ucbtp_attach }; const struct wsmouse_accessops ucbtp_accessops = { ucbtp_enable, ucbtp_ioctl, ucbtp_disable, }; /* * XXX currently no calibration method. this is temporary hack. */ #include struct wsmouse_calibcoords *calibration_sample_lookup __P((void)); int ucbtp_calibration __P((struct ucbtp_softc*)); struct calibration_sample_table { platid_t cst_platform; struct wsmouse_calibcoords cst_sample; } calibration_sample_table[] = { {{{PLATID_WILD, PLATID_MACH_COMPAQ_C_8XX}}, /* uch machine */ { 0, 0, 639, 239, 5, {{ 507, 510, 320, 120 }, { 898, 757, 40, 40 }, { 900, 255, 40, 200 }, { 109, 249, 600, 200 }, { 110, 753, 600, 40 }}}}, {{{PLATID_WILD, PLATID_MACH_COMPAQ_C_2010}}, /* uch machine */ { 0, 0, 639, 239, 5, {{ 506, 487, 320, 120 }, { 880, 250, 40, 40 }, { 880, 718, 40, 200 }, { 140, 726, 600, 200 }, { 137, 250, 600, 40 }}}}, {{{PLATID_WILD, PLATID_MACH_SHARP_MOBILON_HC4100}}, /* uch machine */ { 0, 0, 639, 239, 5, {{ 497, 501, 320, 120 }, { 752, 893, 40, 40 }, { 242, 891, 40, 200 }, { 241, 115, 600, 200 }, { 747, 101, 600, 40 }}}}, {{{PLATID_WILD, PLATID_MACH_SHARP_TELIOS_HCAJ1}}, /* uch machine */ { 0, 0, 799, 479, 5, {{ 850, 150, 1, 1 }, { 850, 880, 1, 479 }, { 850, 880, 1, 479 }, { 85, 880, 799, 479 }, { 85, 150, 799, 1 }}}}, {{{PLATID_UNKNOWN, PLATID_UNKNOWN}}, { 0, 0, 639, 239, 5, {{0, 0, 0, 0}, {0, 0, 0, 0}, {0, 0, 0, 0}, {0, 0, 0, 0}, {0, 0, 0, 0}}}}, }; struct wsmouse_calibcoords * calibration_sample_lookup() { struct calibration_sample_table *tab; platid_mask_t mask; for (tab = calibration_sample_table; tab->cst_platform.dw.dw1 != PLATID_UNKNOWN; tab++) { mask = PLATID_DEREF(&tab->cst_platform); if (platid_match(&platid, &mask)) { return (&tab->cst_sample); } } return (0); } int ucbtp_calibration(sc) struct ucbtp_softc *sc; { struct wsmouse_calibcoords *cs; if (sc->sc_tc->tc_videot) video_calibration_pattern(sc->sc_tc->tc_videot); /* debug */ tpcalib_init(&sc->sc_tpcalib); if (!(cs = calibration_sample_lookup())) { DPRINTF(("no calibration data")); return (1); } sc->sc_calibrated = tpcalib_ioctl(&sc->sc_tpcalib, WSMOUSEIO_SCALIBCOORDS, (caddr_t)cs, 0, 0) == 0 ? 1 : 0; if (!sc->sc_calibrated) printf("not "); printf("calibrated"); return (0); } int ucbtp_match(parent, cf, aux) struct device *parent; struct cfdata *cf; void *aux; { return (1); } void ucbtp_attach(parent, self, aux) struct device *parent; struct device *self; void *aux; { struct ucb1200_attach_args *ucba = aux; struct ucbtp_softc *sc = (void*)self; struct wsmousedev_attach_args wsmaa; tx_chipset_tag_t tc; tc = sc->sc_tc = ucba->ucba_tc; sc->sc_sib = ucba->ucba_sib; sc->sc_ucb = ucba->ucba_ucb; printf(": "); /* touch panel interrupt */ tx_intr_establish(tc, MAKEINTR(1, TX39_INTRSTATUS1_SIBIRQPOSINT), IST_EDGE, IPL_TTY, ucbtp_sibintr, sc); /* attempt to calibrate touch panel */ ucbtp_calibration(sc); #ifdef TX392X /* hack for Telios HC-VJ1C */ sc->sc_xy_reverse = 1; #endif printf("\n"); wsmaa.accessops = &ucbtp_accessops; wsmaa.accesscookie = sc; ucb1200_state_install(parent, ucbtp_busy, self, UCB1200_TP_MODULE); /* * attach the wsmouse */ sc->sc_wsmousedev = config_found(self, &wsmaa, wsmousedevprint); } int ucbtp_busy(arg) void *arg; { struct ucbtp_softc *sc = arg; return (sc->sm_state != UCBADC_IDLE); } int ucbtp_poll(arg) void *arg; { struct ucbtp_softc *sc = arg; if (!ucb1200_state_idle(sc->sc_ucb)) /* subframe0 busy */ return (POLL_CONT); if (sc->sc_polling_finish) { sc->sc_polling_finish = 0; return (POLL_END); } /* execute A-D converter */ sc->sm_state = UCBADC_ADC_INIT; ucbtp_adc_async(sc); return (POLL_CONT); } int ucbtp_sibintr(arg) void *arg; { struct ucbtp_softc *sc = arg; sc->sc_stat = UCBTS_STAT_TOUCH; /* click! */ tx_sound_click(sc->sc_tc); /* invoke touch panel polling */ if (!sc->sc_polling) { sc->sc_pollh = tx39_poll_establish(sc->sc_tc, 1, IST_EDGE, ucbtp_poll, sc); if (!sc->sc_pollh) { printf("%s: can't poll\n", sc->sc_dev.dv_xname); } } /* don't acknoledge interrupt until polling finish */ return (0); } #define REGWRITE(addr, reg, ret) ( \ sc->sm_addr = (addr), \ sc->sm_reg = (reg), \ sc->sm_returnstate = (ret), \ sc->sm_state = UCBADC_REGWRITE) #define REGREAD(addr, ret) ( \ sc->sm_addr = (addr), \ sc->sm_returnstate = (ret), \ sc->sm_state = UCBADC_REGREAD) int ucbtp_adc_async(arg) void *arg; { struct ucbtp_softc *sc = arg; tx_chipset_tag_t tc = sc->sc_tc; txreg_t reg; u_int16_t reg16; DPRINTFN(9, ("state: %d\n", sc->sm_state)); switch (sc->sm_state) { default: panic("ucbtp_adc: invalid state %d", sc->sm_state); /* NOTREACHED */ break; case UCBADC_IDLE: /* nothing to do */ break; case UCBADC_ADC_INIT: sc->sc_polling++; sc->sc_stat = UCBTS_STAT_DRAG; /* enable heart beat of this state machine */ sc->sm_ih = tx_intr_establish( tc, MAKEINTR(1, TX39_INTRSTATUS1_SIBSF0INT), IST_EDGE, IPL_TTY, ucbtp_adc_async, sc); sc->sm_state = UCBADC_MEASUMENT_INIT; break; case UCBADC_ADC_FINI: /* disable heart beat of this state machine */ tx_intr_disestablish(tc, sc->sm_ih); sc->sm_state = UCBADC_IDLE; break; case UCBADC_MEASUMENT_INIT: switch (sc->sm_measurement) { default: panic("unknown measurement spec."); /* NOTREACHED */ break; case UCBADC_MEASUREMENT_X: REGWRITE(UCB1200_TSCTRL_REG, UCB1200_TSCTRL_XPOSITION, UCBADC_ADC_ENABLE); break; case UCBADC_MEASUREMENT_Y: REGWRITE(UCB1200_TSCTRL_REG, UCB1200_TSCTRL_YPOSITION, UCBADC_ADC_ENABLE); break; case UCBADC_MEASUREMENT_PRESSURE: REGWRITE(UCB1200_TSCTRL_REG, UCB1200_TSCTRL_PRESSURE, UCBADC_ADC_ENABLE); break; } break; case UCBADC_MEASUMENT_FINI: switch (sc->sm_measurement) { case UCBADC_MEASUREMENT_X: sc->sm_measurement = UCBADC_MEASUREMENT_Y; sc->sm_state = UCBADC_MEASUMENT_INIT; break; case UCBADC_MEASUREMENT_Y: sc->sm_measurement = UCBADC_MEASUREMENT_PRESSURE; sc->sm_state = UCBADC_MEASUMENT_INIT; break; case UCBADC_MEASUREMENT_PRESSURE: sc->sm_measurement = UCBADC_MEASUREMENT_X; /* measument complete. pass down to wsmouse_input */ sc->sm_state = UCBADC_ADC_INPUT; break; } break; case UCBADC_ADC_ENABLE: switch (sc->sm_measurement) { case UCBADC_MEASUREMENT_PRESSURE: /* FALLTHROUGH */ case UCBADC_MEASUREMENT_X: sc->sm_tmpreg = UCB1200_ADCCTRL_INPUT_SET( UCB1200_ADCCTRL_ENABLE, UCB1200_ADCCTRL_INPUT_TSPX); REGWRITE(UCB1200_ADCCTRL_REG, sc->sm_tmpreg, UCBADC_ADC_START0); break; case UCBADC_MEASUREMENT_Y: sc->sm_tmpreg = UCB1200_ADCCTRL_INPUT_SET( UCB1200_ADCCTRL_ENABLE, UCB1200_ADCCTRL_INPUT_TSPY); REGWRITE(UCB1200_ADCCTRL_REG, sc->sm_tmpreg, UCBADC_ADC_START0); break; } break; case UCBADC_ADC_START0: REGWRITE(UCB1200_ADCCTRL_REG, sc->sm_tmpreg | UCB1200_ADCCTRL_START, UCBADC_ADC_START1); break; case UCBADC_ADC_START1: REGWRITE(UCB1200_ADCCTRL_REG, sc->sm_tmpreg, UCBADC_ADC_DATAREAD); sc->sm_retry = UCBADC_RETRY_DEFAULT; break; case UCBADC_ADC_DATAREAD: REGREAD(UCB1200_ADCDATA_REG, UCBADC_ADC_DATAREAD_WAIT); break; case UCBADC_ADC_DATAREAD_WAIT: reg16 = TX39_SIBSF0_REGDATA(sc->sm_reg); if (!(reg16 & UCB1200_ADCDATA_INPROGRESS) && --sc->sm_retry > 0) { sc->sm_state = UCBADC_ADC_DATAREAD; } else { if (sc->sm_retry <= 0) { printf("dataread failed\n"); sc->sm_state = UCBADC_ADC_FINI; break; } switch (sc->sm_measurement) { case UCBADC_MEASUREMENT_X: sc->sc_x = UCB1200_ADCDATA(reg16); DPRINTFN(9, ("x=%d\n", sc->sc_x)); break; case UCBADC_MEASUREMENT_Y: sc->sc_y = UCB1200_ADCDATA(reg16); DPRINTFN(9, ("y=%d\n", sc->sc_y)); break; case UCBADC_MEASUREMENT_PRESSURE: sc->sc_p = UCB1200_ADCDATA(reg16); DPRINTFN(9, ("p=%d\n", sc->sc_p)); break; } sc->sm_state = UCBADC_ADC_DISABLE; } break; case UCBADC_ADC_DISABLE: REGWRITE(UCB1200_ADCCTRL_REG, 0, UCBADC_ADC_INTRMODE); break; case UCBADC_ADC_INTRMODE: REGWRITE(UCB1200_TSCTRL_REG, UCB1200_TSCTRL_INTERRUPT, UCBADC_MEASUMENT_FINI); break; case UCBADC_ADC_INPUT: if (ucbtp_input(sc) == 0) sc->sm_state = UCBADC_ADC_FINI; else sc->sm_state = UCBADC_INTR_ACK0; break; case UCBADC_INTR_ACK0: REGREAD(UCB1200_INTSTAT_REG, UCBADC_INTR_ACK1); break; case UCBADC_INTR_ACK1: REGWRITE(UCB1200_INTSTAT_REG, sc->sm_reg, UCBADC_INTR_ACK2); break; case UCBADC_INTR_ACK2: sc->sc_polling_finish = 1; REGWRITE(UCB1200_INTSTAT_REG, 0, UCBADC_ADC_FINI); break; /* * UCB1200 register access state */ case UCBADC_REGREAD: /* * In : sc->sm_addr * Out : sc->sm_reg (with SIBtag) */ #define TXSIB_REGREAD_INIT 0 #define TXSIB_REGREAD_READ 1 switch (sc->sm_read_state) { case TXSIB_REGREAD_INIT: reg = TX39_SIBSF0_REGADDR_SET(0, sc->sm_addr); tx_conf_write(tc, TX39_SIBSF0CTRL_REG, reg); sc->sm_rw_retry = UCBADC_RETRY_DEFAULT; sc->sm_read_state = TXSIB_REGREAD_READ; break; case TXSIB_REGREAD_READ: reg = tx_conf_read(tc, TX39_SIBSF0STAT_REG); if ((TX39_SIBSF0_REGADDR(reg) != sc->sm_addr) && --sc->sm_rw_retry > 0) { break; } if (sc->sm_rw_retry <= 0) { printf("sf0read: command failed\n"); sc->sm_state = UCBADC_ADC_FINI; } else { sc->sm_reg = reg; sc->sm_read_state = TXSIB_REGREAD_INIT; DPRINTFN(9, ("%08x\n", reg)); if (sc->sm_writing) sc->sm_state = UCBADC_REGWRITE; else sc->sm_state = sc->sm_returnstate; } break; } break; case UCBADC_REGWRITE: /* * In : sc->sm_addr, sc->sm_reg (lower 16bit only) */ #define TXSIB_REGWRITE_INIT 0 #define TXSIB_REGWRITE_WRITE 1 switch (sc->sm_write_state) { case TXSIB_REGWRITE_INIT: sc->sm_writing = 1; sc->sm_write_state = TXSIB_REGWRITE_WRITE; sc->sm_state = UCBADC_REGREAD; sc->sm_write_val = sc->sm_reg; break; case TXSIB_REGWRITE_WRITE: sc->sm_writing = 0; sc->sm_write_state = TXSIB_REGWRITE_INIT; sc->sm_state = sc->sm_returnstate; reg = sc->sm_reg; reg |= TX39_SIBSF0_WRITE; TX39_SIBSF0_REGDATA_CLR(reg); reg = TX39_SIBSF0_REGDATA_SET(reg, sc->sm_write_val); tx_conf_write(tc, TX39_SIBSF0CTRL_REG, reg); break; } break; } return (0); } int ucbtp_input(sc) struct ucbtp_softc *sc; { int rx, ry, x, y, p; rx = sc->sc_x; ry = sc->sc_y; p = sc->sc_p; if (!sc->sc_calibrated) { DPRINTFN(2, ("x=%4d y=%4d p=%4d\n", rx, ry, p)); DPRINTF(("ucbtp_input: no calibration data\n")); } if (p < UCBTS_PRESS_THRESHOLD || rx == 0x3ff || ry == 0x3ff || rx == 0 || ry == 0) { sc->sc_stat = UCBTS_STAT_RELEASE; if (sc->sc_polling < UCBTS_TAP_THRESHOLD) { DPRINTFN(2, ("TAP!\n")); /* button 0 DOWN */ wsmouse_input(sc->sc_wsmousedev, 1, 0, 0, 0, 0); /* button 0 UP */ wsmouse_input(sc->sc_wsmousedev, 0, 0, 0, 0, 0); } else { wsmouse_input(sc->sc_wsmousedev, 0, sc->sc_ox, sc->sc_oy, 0, WSMOUSE_INPUT_ABSOLUTE_X | WSMOUSE_INPUT_ABSOLUTE_Y); DPRINTFN(2, ("RELEASE\n")); } sc->sc_polling = 0; return (1); } if (sc->sc_xy_reverse) tpcalib_trans(&sc->sc_tpcalib, ry, rx, &x, &y); else tpcalib_trans(&sc->sc_tpcalib, rx, ry, &x, &y); DPRINTFN(2, ("x: %4d->%4d y: %4d->%4d pressure=%4d\n", rx, x, ry, y, p)); /* debug draw */ if (sc->sc_tc->tc_videot) { if (sc->sc_polling == 1) video_dot(sc->sc_tc->tc_videot, x, y); else video_line(sc->sc_tc->tc_videot, sc->sc_ox, sc->sc_oy, x, y); } sc->sc_ox = x, sc->sc_oy = y; wsmouse_input(sc->sc_wsmousedev, 1, x, y, 0, WSMOUSE_INPUT_ABSOLUTE_X | WSMOUSE_INPUT_ABSOLUTE_Y); return (0); } /* * access ops. */ int ucbtp_enable(v) void *v; { /* not yet */ return (0); } void ucbtp_disable(v) void *v; { /* not yet */ } int ucbtp_ioctl(v, cmd, data, flag, p) void *v; u_long cmd; caddr_t data; int flag; struct proc *p; { struct ucbtp_softc *sc = v; DPRINTF(("%s(%d): ucbtp_ioctl(%08lx)\n", __FILE__, __LINE__, cmd)); switch (cmd) { case WSMOUSEIO_GTYPE: *(u_int *)data = WSMOUSE_TYPE_TPANEL; break; case WSMOUSEIO_SRES: printf("%s(%d): WSMOUSRIO_SRES is not supported", __FILE__, __LINE__); break; case WSMOUSEIO_SCALIBCOORDS: case WSMOUSEIO_GCALIBCOORDS: return tpcalib_ioctl(&sc->sc_tpcalib, cmd, data, flag, p); default: return (-1); } return (0); }