mm58167.c revision 1.9.20.2
1 1.9.20.2 yamt /* $NetBSD: mm58167.c,v 1.9.20.2 2009/05/04 08:12:42 yamt Exp $ */ 2 1.1 fredette 3 1.1 fredette /* 4 1.1 fredette * Copyright (c) 2001 The NetBSD Foundation, Inc. 5 1.1 fredette * All rights reserved. 6 1.1 fredette * 7 1.1 fredette * This code is derived from software contributed to The NetBSD Foundation 8 1.1 fredette * by Matthew Fredette. 9 1.1 fredette * 10 1.1 fredette * Redistribution and use in source and binary forms, with or without 11 1.1 fredette * modification, are permitted provided that the following conditions 12 1.1 fredette * are met: 13 1.1 fredette * 1. Redistributions of source code must retain the above copyright 14 1.1 fredette * notice, this list of conditions and the following disclaimer. 15 1.1 fredette * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 fredette * notice, this list of conditions and the following disclaimer in the 17 1.1 fredette * documentation and/or other materials provided with the distribution. 18 1.1 fredette * 19 1.1 fredette * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 fredette * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 fredette * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 fredette * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 fredette * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 fredette * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 fredette * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 fredette * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 fredette * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 fredette * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 fredette * POSSIBILITY OF SUCH DAMAGE. 30 1.1 fredette */ 31 1.1 fredette 32 1.1 fredette /* 33 1.1 fredette * National Semiconductor MM58167 time-of-day chip subroutines. 34 1.1 fredette */ 35 1.3 lukem 36 1.3 lukem #include <sys/cdefs.h> 37 1.9.20.2 yamt __KERNEL_RCSID(0, "$NetBSD: mm58167.c,v 1.9.20.2 2009/05/04 08:12:42 yamt Exp $"); 38 1.1 fredette 39 1.1 fredette #include <sys/param.h> 40 1.1 fredette #include <sys/malloc.h> 41 1.1 fredette #include <sys/systm.h> 42 1.1 fredette #include <sys/errno.h> 43 1.1 fredette #include <sys/device.h> 44 1.1 fredette 45 1.9 ad #include <sys/bus.h> 46 1.1 fredette #include <dev/clock_subr.h> 47 1.1 fredette #include <dev/ic/mm58167var.h> 48 1.1 fredette 49 1.6 he int mm58167_gettime(todr_chip_handle_t, volatile struct timeval *); 50 1.6 he int mm58167_settime(todr_chip_handle_t, volatile struct timeval *); 51 1.1 fredette 52 1.1 fredette /* 53 1.1 fredette * To quote SunOS's todreg.h: 54 1.1 fredette * "This brain damaged chip insists on keeping the time in 55 1.1 fredette * MM/DD HH:MM:SS format, even though it doesn't know about 56 1.1 fredette * leap years and Feb. 29, thus making it nearly worthless." 57 1.1 fredette */ 58 1.9.20.2 yamt #define mm58167_read(sc, r) \ 59 1.9.20.2 yamt bus_space_read_1(sc->mm58167_regt, sc->mm58167_regh, sc-> r) 60 1.9.20.2 yamt #define mm58167_write(sc, r, v) \ 61 1.9.20.2 yamt bus_space_write_1(sc->mm58167_regt, sc->mm58167_regh, sc-> r, v) 62 1.1 fredette 63 1.1 fredette todr_chip_handle_t 64 1.9.20.2 yamt mm58167_attach(struct mm58167_softc *sc) 65 1.1 fredette { 66 1.1 fredette struct todr_chip_handle *handle; 67 1.5 perry 68 1.9.20.2 yamt aprint_normal(": mm58167"); 69 1.1 fredette 70 1.1 fredette handle = &sc->_mm58167_todr_handle; 71 1.2 thorpej memset(handle, 0, sizeof(handle)); 72 1.1 fredette handle->cookie = sc; 73 1.1 fredette handle->todr_gettime = mm58167_gettime; 74 1.1 fredette handle->todr_settime = mm58167_settime; 75 1.9.20.2 yamt return handle; 76 1.1 fredette } 77 1.1 fredette 78 1.1 fredette /* 79 1.1 fredette * Set up the system's time, given a `reasonable' time value. 80 1.1 fredette */ 81 1.1 fredette int 82 1.9.20.2 yamt mm58167_gettime(todr_chip_handle_t handle, volatile struct timeval *tv) 83 1.1 fredette { 84 1.1 fredette struct mm58167_softc *sc = handle->cookie; 85 1.1 fredette struct clock_ymdhms dt_hardware; 86 1.1 fredette struct clock_ymdhms dt_reasonable; 87 1.1 fredette int s; 88 1.9.20.2 yamt uint8_t byte_value; 89 1.1 fredette int leap_year, had_leap_day; 90 1.1 fredette 91 1.1 fredette /* First, read the date out of the chip. */ 92 1.1 fredette 93 1.1 fredette /* No interrupts while we're in the chip. */ 94 1.1 fredette s = splhigh(); 95 1.1 fredette 96 1.1 fredette /* Reset the status bit: */ 97 1.1 fredette byte_value = mm58167_read(sc, mm58167_status); 98 1.1 fredette 99 1.1 fredette /* 100 1.1 fredette * Read the date values until we get a coherent read (one 101 1.1 fredette * where the status stays zero, indicating no increment was 102 1.1 fredette * rippling through while we were reading). 103 1.1 fredette */ 104 1.1 fredette do { 105 1.9.20.2 yamt #define _MM58167_GET(dt_f, mm_f) \ 106 1.9.20.2 yamt byte_value = mm58167_read(sc, mm_f); \ 107 1.9.20.2 yamt dt_hardware.dt_f = FROMBCD(byte_value) 108 1.9.20.2 yamt 109 1.1 fredette _MM58167_GET(dt_mon, mm58167_mon); 110 1.1 fredette _MM58167_GET(dt_day, mm58167_day); 111 1.1 fredette _MM58167_GET(dt_hour, mm58167_hour); 112 1.1 fredette _MM58167_GET(dt_min, mm58167_min); 113 1.1 fredette _MM58167_GET(dt_sec, mm58167_sec); 114 1.1 fredette #undef _MM58167_GET 115 1.1 fredette } while ((mm58167_read(sc, mm58167_status) & 1) == 0); 116 1.1 fredette 117 1.1 fredette splx(s); 118 1.1 fredette 119 1.1 fredette /* Convert the reasonable time into a date: */ 120 1.1 fredette clock_secs_to_ymdhms(tv->tv_sec, &dt_reasonable); 121 1.1 fredette 122 1.1 fredette /* 123 1.1 fredette * We need to fake a hardware year. if the hardware MM/DD 124 1.1 fredette * HH:MM:SS date is less than the reasonable MM/DD 125 1.1 fredette * HH:MM:SS, call it the reasonable year plus one, else call 126 1.1 fredette * it the reasonable year. 127 1.1 fredette */ 128 1.1 fredette if (dt_hardware.dt_mon < dt_reasonable.dt_mon || 129 1.1 fredette (dt_hardware.dt_mon == dt_reasonable.dt_mon && 130 1.9.20.2 yamt (dt_hardware.dt_day < dt_reasonable.dt_day || 131 1.9.20.2 yamt (dt_hardware.dt_day == dt_reasonable.dt_day && 132 1.9.20.2 yamt (dt_hardware.dt_hour < dt_reasonable.dt_hour || 133 1.9.20.2 yamt (dt_hardware.dt_hour == dt_reasonable.dt_hour && 134 1.9.20.2 yamt (dt_hardware.dt_min < dt_reasonable.dt_min || 135 1.9.20.2 yamt (dt_hardware.dt_min == dt_reasonable.dt_min && 136 1.9.20.2 yamt (dt_hardware.dt_sec < dt_reasonable.dt_sec))))))))) { 137 1.9.20.2 yamt dt_hardware.dt_year = dt_reasonable.dt_year + 1; 138 1.1 fredette } else { 139 1.9.20.2 yamt dt_hardware.dt_year = dt_reasonable.dt_year; 140 1.1 fredette } 141 1.1 fredette 142 1.1 fredette /* convert the hardware date into a time: */ 143 1.1 fredette tv->tv_sec = clock_ymdhms_to_secs(&dt_hardware); 144 1.1 fredette tv->tv_usec = 0; 145 1.5 perry 146 1.1 fredette /* 147 1.1 fredette * Make a reasonable effort to see if a leap day has passed 148 1.1 fredette * that we need to account for. This does the right thing 149 1.1 fredette * only when the system was shut down before a leap day, and 150 1.1 fredette * it is now after that leap day. It doesn't do the right 151 1.1 fredette * thing when a leap day happened while the machine was last 152 1.1 fredette * up. When that happens, the hardware clock becomes 153 1.1 fredette * instantly wrong forever, until it gets fixed for some 154 1.1 fredette * reason. Use NTP to deal. 155 1.1 fredette */ 156 1.1 fredette 157 1.1 fredette /* 158 1.1 fredette * This may have happened if the hardware says we're into 159 1.1 fredette * March in the following year. Check that following year for 160 1.1 fredette * a leap day. 161 1.1 fredette */ 162 1.1 fredette if (dt_hardware.dt_year > dt_reasonable.dt_year && 163 1.1 fredette dt_hardware.dt_mon >= 3) { 164 1.9.20.2 yamt leap_year = dt_hardware.dt_year; 165 1.1 fredette } 166 1.1 fredette 167 1.1 fredette /* 168 1.1 fredette * This may have happened if the hardware says we're in the 169 1.1 fredette * following year, and the system was shut down before March 170 1.1 fredette * the previous year. check that previous year for a leap 171 1.1 fredette * day. 172 1.1 fredette */ 173 1.1 fredette else if (dt_hardware.dt_year > dt_reasonable.dt_year && 174 1.9.20.2 yamt dt_reasonable.dt_mon < 3) { 175 1.9.20.2 yamt leap_year = dt_reasonable.dt_year; 176 1.1 fredette } 177 1.1 fredette 178 1.1 fredette /* 179 1.1 fredette * This may have happened if the hardware says we're in the 180 1.1 fredette * same year, but we weren't to March before, and we're in or 181 1.1 fredette * past March now. Check this year for a leap day. 182 1.1 fredette */ 183 1.1 fredette else if (dt_hardware.dt_year == dt_reasonable.dt_year 184 1.9.20.2 yamt && dt_reasonable.dt_mon < 3 185 1.9.20.2 yamt && dt_hardware.dt_mon >= 3) { 186 1.9.20.2 yamt leap_year = dt_reasonable.dt_year; 187 1.1 fredette } 188 1.1 fredette 189 1.1 fredette /* 190 1.1 fredette * Otherwise, no leap year to check. 191 1.1 fredette */ 192 1.1 fredette else { 193 1.9.20.2 yamt leap_year = 0; 194 1.1 fredette } 195 1.1 fredette 196 1.1 fredette /* Do the real leap day check. */ 197 1.1 fredette had_leap_day = 0; 198 1.1 fredette if (leap_year > 0) { 199 1.1 fredette if ((leap_year & 3) == 0) { 200 1.1 fredette had_leap_day = 1; 201 1.1 fredette if ((leap_year % 100) == 0) { 202 1.1 fredette had_leap_day = 0; 203 1.1 fredette if ((leap_year % 400) == 0) 204 1.1 fredette had_leap_day = 1; 205 1.1 fredette } 206 1.1 fredette } 207 1.1 fredette } 208 1.1 fredette 209 1.1 fredette /* 210 1.1 fredette * If we had a leap day, adjust the value we will return, and 211 1.1 fredette * also update the hardware clock. 212 1.5 perry */ 213 1.5 perry /* 214 1.1 fredette * XXX - Since this update just writes back a corrected 215 1.5 perry * version of what we read out above, we lose whatever 216 1.1 fredette * amount of time the clock has advanced since that read. 217 1.1 fredette * Use NTP to deal. 218 1.1 fredette */ 219 1.1 fredette if (had_leap_day) { 220 1.9.20.2 yamt tv->tv_sec += SECDAY; 221 1.9.20.2 yamt todr_settime(handle, tv); 222 1.1 fredette } 223 1.1 fredette 224 1.9.20.2 yamt return 0; 225 1.1 fredette } 226 1.1 fredette 227 1.1 fredette int 228 1.9.20.2 yamt mm58167_settime(todr_chip_handle_t handle, volatile struct timeval *tv) 229 1.1 fredette { 230 1.1 fredette struct mm58167_softc *sc = handle->cookie; 231 1.1 fredette struct clock_ymdhms dt_hardware; 232 1.1 fredette int s; 233 1.9.20.2 yamt uint8_t byte_value; 234 1.1 fredette 235 1.1 fredette /* Convert the seconds into ymdhms. */ 236 1.1 fredette clock_secs_to_ymdhms(tv->tv_sec, &dt_hardware); 237 1.1 fredette 238 1.1 fredette /* No interrupts while we're in the chip. */ 239 1.1 fredette s = splhigh(); 240 1.1 fredette 241 1.5 perry /* 242 1.1 fredette * Issue a GO command to reset everything less significant 243 1.1 fredette * than the minutes to zero. 244 1.1 fredette */ 245 1.1 fredette mm58167_write(sc, mm58167_go, 0xFF); 246 1.5 perry 247 1.1 fredette /* Load everything. */ 248 1.9.20.2 yamt #define _MM58167_PUT(dt_f, mm_f) \ 249 1.9.20.2 yamt byte_value = TOBCD(dt_hardware.dt_f); \ 250 1.9.20.2 yamt mm58167_write(sc, mm_f, byte_value) 251 1.9.20.2 yamt 252 1.1 fredette _MM58167_PUT(dt_mon, mm58167_mon); 253 1.1 fredette _MM58167_PUT(dt_day, mm58167_day); 254 1.1 fredette _MM58167_PUT(dt_hour, mm58167_hour); 255 1.1 fredette _MM58167_PUT(dt_min, mm58167_min); 256 1.1 fredette _MM58167_PUT(dt_sec, mm58167_sec); 257 1.1 fredette #undef _MM58167_PUT 258 1.1 fredette 259 1.1 fredette splx(s); 260 1.9.20.2 yamt return 0; 261 1.1 fredette } 262
Indexes created Mon Oct 20 20:10:13 GMT 2025