1 /* $NetBSD: mc146818reg.h,v 1.2 1997/03/12 06:53:42 cgd Exp $ */
2
3 /*
4 * Copyright (c) 1995 Carnegie-Mellon University.
5 * All rights reserved.
6 *
7 * Permission to use, copy, modify and distribute this software and
8 * its documentation is hereby granted, provided that both the copyright
9 * notice and this permission notice appear in all copies of the
10 * software, derivative works or modified versions, and any portions
11 * thereof, and that both notices appear in supporting documentation.
12 *
13 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
14 * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
15 * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
16 *
17 * Carnegie Mellon requests users of this software to return to
18 *
19 * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
20 * School of Computer Science
21 * Carnegie Mellon University
22 * Pittsburgh PA 15213-3890
23 *
24 * any improvements or extensions that they make and grant Carnegie the
25 * rights to redistribute these changes.
26 */
27
28 /*
29 * Definitions for the Motorola MC146818A Real Time Clock.
30 * They also apply for the (compatible) Dallas Semicontuctor DS1287A RTC.
31 *
32 * Though there are undoubtedly other (better) sources, this material was
33 * culled from the DEC "KN121 System Module Programmer's Reference
34 * Information."
35 *
36 * The MC146818A has 16 registers. The first 10 contain time-of-year
37 * and alarm data. The rest contain various control and status bits.
38 *
39 * To read or write the registers, one writes the register number to
40 * the RTC's control port, then either reads from or writes the new
41 * data to the RTC's data port. Since the locations of these ports
42 * and the method used to access them can be machine-dependent, the
43 * low-level details of reading and writing the RTC's registers are
44 * handled by machine-specific functions.
45 *
46 * The time-of-year and alarm data can be expressed in either binary
47 * or BCD, and they are selected by a bit in register B.
48 *
49 * The "hour" time-of-year and alarm fields can either be expressed in
50 * AM/PM format, or in 24-hour format. If AM/PM format is chosen, the
51 * hour fields can have the values: 1-12 and 81-92 (the latter being
52 * PM). If the 24-hour format is chosen, they can have the values
53 * 0-24. The hour format is selectable by a bit in register B.
54 * (XXX IS AM/PM MODE DESCRIPTION CORRECT?)
55 *
56 * It is assumed the if systems are going to use BCD (rather than
57 * binary) mode, or AM/PM hour format, they'll do the appropriate
58 * conversions in machine-dependent code. Also, if the clock is
59 * switched between BCD and binary mode, or between AM/PM mode and
60 * 24-hour mode, the time-of-day and alarm registers are NOT
61 * automatically reset; they must be reprogrammed with correct values.
62 */
63
64 /*
65 * The registers, and the bits within each register.
66 */
67
68 #define MC_SEC 0x0 /* Time of year: seconds (0-59) */
69 #define MC_ASEC 0x1 /* Alarm: seconds */
70 #define MC_MIN 0x2 /* Time of year: minutes (0-59) */
71 #define MC_AMIN 0x3 /* Alarm: minutes */
72 #define MC_HOUR 0x4 /* Time of year: hour (see above) */
73 #define MC_AHOUR 0x5 /* Alarm: hour */
74 #define MC_DOW 0x6 /* Time of year: day of week (1-7) */
75 #define MC_DOM 0x7 /* Time of year: day of month (1-31) */
76 #define MC_MONTH 0x8 /* Time of year: month (1-12) */
77 #define MC_YEAR 0x9 /* Time of year: year in century (0-99) */
78
79 #define MC_REGA 0xa /* Control register A */
80
81 #define MC_REGA_RSMASK 0x0f /* Interrupt rate select mask (see below) */
82 #define MC_REGA_DVMASK 0x70 /* Divisor select mask (see below) */
83 #define MC_REGA_UIP 0x80 /* Update in progress; read only. */
84
85 #define MC_REGB 0xb /* Control register B */
86
87 #define MC_REGB_DSE 0x01 /* Daylight Savings Enable */
88 #define MC_REGB_24HR 0x02 /* 24-hour mode (AM/PM mode when clear) */
89 #define MC_REGB_BINARY 0x04 /* Binary mode (BCD mode when clear) */
90 #define MC_REGB_SQWE 0x08 /* Square Wave Enable */
91 #define MC_REGB_UIE 0x10 /* Update End interrupt enable */
92 #define MC_REGB_AIE 0x20 /* Alarm interrupt enable */
93 #define MC_REGB_PIE 0x40 /* Periodic interrupt enable */
94 #define MC_REGB_SET 0x80 /* Allow time to be set; stops updates */
95
96 #define MC_REGC 0xc /* Control register C */
97
98 /* MC_REGC_UNUSED 0x0f UNUSED */
99 #define MC_REGC_UF 0x10 /* Update End interrupt flag */
100 #define MC_REGC_AF 0x20 /* Alarm interrupt flag */
101 #define MC_REGC_PF 0x40 /* Periodic interrupt flag */
102 #define MC_REGC_IRQF 0x80 /* Interrupt request pending flag */
103
104 #define MC_REGD 0xd /* Control register D */
105
106 /* MC_REGD_UNUSED 0x7f UNUSED */
107 #define MC_REGD_VRT 0x80 /* Valid RAM and Time bit */
108
109
110 #define MC_NREGS 0xe /* 14 registers; CMOS follows */
111 #define MC_NTODREGS 0xa /* 10 of those regs are for TOD and alarm */
112
113 #define MC_NVRAM_START 0xe /* start of NVRAM: offset 14 */
114 #define MC_NVRAM_SIZE 50 /* 50 bytes of NVRAM */
115
116 /*
117 * Periodic Interrupt Rate Select constants (Control register A)
118 */
119 #define MC_RATE_NONE 0x0 /* No periodic interrupt */
120 #define MC_RATE_1 0x1 /* 256 Hz if MC_BASE_32_KHz, else 32768 Hz */
121 #define MC_RATE_2 0x2 /* 128 Hz if MC_BASE_32_KHz, else 16384 Hz */
122 #define MC_RATE_8192_Hz 0x3 /* 122.070 us period */
123 #define MC_RATE_4096_Hz 0x4 /* 244.141 us period */
124 #define MC_RATE_2048_Hz 0x5 /* 488.281 us period */
125 #define MC_RATE_1024_Hz 0x6 /* 976.562 us period */
126 #define MC_RATE_512_Hz 0x7 /* 1.953125 ms period */
127 #define MC_RATE_256_Hz 0x8 /* 3.90625 ms period */
128 #define MC_RATE_128_Hz 0x9 /* 7.8125 ms period */
129 #define MC_RATE_64_Hz 0xa /* 15.625 ms period */
130 #define MC_RATE_32_Hz 0xb /* 31.25 ms period */
131 #define MC_RATE_16_Hz 0xc /* 62.5 ms period */
132 #define MC_RATE_8_Hz 0xd /* 125 ms period */
133 #define MC_RATE_4_Hz 0xe /* 250 ms period */
134 #define MC_RATE_2_Hz 0xf /* 500 ms period */
135
136 /*
137 * Time base (divisor select) constants (Control register A)
138 */
139 #define MC_BASE_4_MHz 0x00 /* 4MHz crystal */
140 #define MC_BASE_1_MHz 0x10 /* 1MHz crystal */
141 #define MC_BASE_32_KHz 0x20 /* 32KHz crystal */
142 #define MC_BASE_NONE 0x60 /* actually, both of these reset */
143 #define MC_BASE_RESET 0x70
144
145 /*
146 * A collection of TOD/Alarm registers.
147 */
148 typedef u_int mc_todregs[MC_NTODREGS];
149
150 /*
151 * Get all of the TOD/Alarm registers
152 * Must be called at splhigh(), and with the RTC properly set up.
153 */
154 #define MC146818_GETTOD(dev, regs) \
155 do { \
156 int i; \
157 \
158 /* update in progress; spin loop */ \
159 while (MCCLOCK_READ(dev, MC_REGA) & MC_REGA_UIP) \
160 ; \
161 \
162 /* read all of the tod/alarm regs */ \
163 for (i = 0; i < MC_NTODREGS; i++) \
164 (*regs)[i] = MCCLOCK_READ(dev, i); \
165 } while (0);
166
167 /*
168 * Set all of the TOD/Alarm registers
169 * Must be called at splhigh(), and with the RTC properly set up.
170 */
171 #define MC146818_PUTTOD(dev, regs) \
172 do { \
173 int i; \
174 \
175 /* stop updates while setting */ \
176 MCCLOCK_WRITE(dev, MC_REGB, \
177 MCCLOCK_READ(dev, MC_REGB) | MC_REGB_SET); \
178 \
179 /* write all of the tod/alarm regs */ \
180 for (i = 0; i < MC_NTODREGS; i++) \
181 MCCLOCK_WRITE(dev, i, (*regs)[i]); \
182 \
183 /* reenable updates */ \
184 MCCLOCK_WRITE(dev, MC_REGB, \
185 MCCLOCK_READ(dev, MC_REGB) & ~MC_REGB_SET); \
186 } while (0);
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