xref: /titanic_50/usr/src/uts/sun/sys/ser_zscc.h (revision 1e1ddd6cc98ab5af8293f7ebd132be62900730fd)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License, Version 1.0 only
6  * (the "License").  You may not use this file except in compliance
7  * with the License.
8  *
9  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
10  * or http://www.opensolaris.org/os/licensing.
11  * See the License for the specific language governing permissions
12  * and limitations under the License.
13  *
14  * When distributing Covered Code, include this CDDL HEADER in each
15  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
16  * If applicable, add the following below this CDDL HEADER, with the
17  * fields enclosed by brackets "[]" replaced with your own identifying
18  * information: Portions Copyright [yyyy] [name of copyright owner]
19  *
20  * CDDL HEADER END
21  */
22 /*
23  * Copyright (c) 1983, 1991, by Sun Microsystems, Inc.
24  */
25 
26 #ifndef _SYS_SER_ZSCC_H
27 #define	_SYS_SER_ZSCC_H
28 
29 #pragma ident	"%Z%%M%	%I%	%E% SMI"
30 
31 /*
32  * Zilog 8530 SCC Serial Communications Controller
33  *
34  * This is a dual uart chip with on-chip baud rate generators.
35  * It is about as brain-damaged as the typical modern uart chip,
36  * but it does have a lot of features as well as the usual lot of
37  * brain damage around addressing, write-onlyness, etc.
38  */
39 
40 #ifdef	__cplusplus
41 extern "C" {
42 #endif
43 
44 /*
45  * SCC registers:
46  *
47  * There are 16 write registers and 9 read registers in each channel.
48  * As usual, the two channels are ALMOST orthogonal, not exactly.  Most regs
49  * can only be written to, or read, but not both.  To access one, you must
50  * first write to register 0 with the number of the register you
51  * are interested in, then read/write the actual value, and hope that
52  * nobody interrupts you in between.
53  */
54 
55 /* bits in RR0 */
56 #define	ZSRR0_RX_READY		0x01	/* received character available */
57 #define	ZSRR0_TIMER		0x02	/* if R15_TIMER, timer reached 0 */
58 #define	ZSRR0_TX_READY		0x04	/* transmit buffer empty */
59 #define	ZSRR0_CD		0x08	/* CD input (latched if R15_CD) */
60 #define	ZSRR0_SYNC		0x10	/* SYNC input (latched if R15_SYNC) */
61 #define	ZSRR0_CTS		0x20	/* CTS input (latched if R15_CTS) */
62 #define	ZSRR0_TXUNDER		0x40	/* (SYNC) Xmitter underran */
63 #define	ZSRR0_BREAK		0x80	/* received break detected */
64 
65 /* bits in RR1 */
66 #define	ZSRR1_ALL_SENT		0x01	/* all chars fully transmitted */
67 #define	ZSRR1_PE		0x10	/* parity error (latched, must reset) */
68 #define	ZSRR1_DO		0x20	/* data overrun (latched, must reset) */
69 #define	ZSRR1_FE		0x40	/* framing/CRC error (not latched) */
70 #define	ZSRR1_RXEOF		0x80	/* end of recv sdlc frame */
71 
72 /*
73  * bits in R/WR2 -- interrupt vector number.
74  *
75  * NOTE that RR2 in channel A is unmodified, while in channel B it is
76  * modified by the current status of the UARTs.  (This is independent
77  * of the setting of WR9_VIS.)  If no interrupts are pending, the modified
78  * status is Channel B Special Receive.  It can be written from
79  * either channel.
80  */
81 
82 #define	ZSR2_TX_EMPTY_B		0x0
83 #define	ZSR2_XSINT_B		0x2
84 #define	ZSR2_RX_AVAIL_B		0x4
85 #define	ZSR2_SRINT_B_OR_NONE	0x6
86 #define	ZSR2_TX_EMPTY_A		0x8
87 #define	ZSR2_XSINT_A		0xA
88 #define	ZSR2_RX_AVAIL_A		0xC
89 #define	ZSR2_SRINT_A		0xE
90 
91 #define	ZSR2_STATUS_ALL		0xE
92 
93 
94 /*
95  * bits in RR3 -- Interrupt Pending flags for both channels (this reg can
96  * only be read in Channel A, tho.  Thanks guys.)
97  */
98 #define	ZSRR3_IP_B_STAT		0x01	/* Ext/status int pending, chan B */
99 #define	ZSRR3_IP_B_TX		0x02	/* Transmit int pending, chan B */
100 #define	ZSRR3_IP_B_RX		0x04	/* Receive int pending, chan B */
101 #define	ZSRR3_IP_A_STAT		0x08	/* Ditto for channel A */
102 #define	ZSRR3_IP_A_TX		0x10
103 #define	ZSRR3_IP_A_RX		0x20
104 
105 /* bits in RR8 -- this is the same as reading the Data port */
106 
107 /* bits in RR10 -- DPLL and SDLC Loop Mode status -- not entered */
108 
109 /* bits in R/WR12 -- lower byte of time constant for baud rate generator */
110 /* bits in R/WR13 -- upper byte of time constant for baud rate generator */
111 
112 /* bits in R/WR15 -- interrupt enables for status conditions */
113 #define	ZSR15_TIMER		0x02	/* ie if baud rate generator = 0 */
114 #define	ZSR15_CD		0x08	/* ie transition on CD (car. det.) */
115 #define	ZSR15_SYNC		0x10	/* ie transition on SYNC (gen purp) */
116 #define	ZSR15_CTS		0x20	/* ie transition on CTS (clr to send) */
117 #define	ZSR15_TX_UNDER		0x40	/* (SYNC) ie transmit underrun */
118 #define	ZSR15_BREAK		0x80	/* ie on start, and end, of break */
119 
120 /* Write register 0 -- common commands and Register Pointers */
121 #define	ZSWR0_REG		0x0F	/* mask: next reg to read/write */
122 #define	ZSWR0_RESET_STATUS	0x10	/* reset status bit latches */
123 #define	ZSWR0_SEND_ABORT	0x18	/* SDLC: send abort */
124 #define	ZSWR0_FIRST_RX		0x20	/* in WR1_RX_FIRST_IE, enab next int */
125 #define	ZSWR0_RESET_TXINT	0x28	/* reset transmitter interrupt */
126 #define	ZSWR0_RESET_ERRORS	0x30	/* reset read character errors */
127 #define	ZSWR0_CLR_INTR		0x38	/* Reset Interrupt In Service */
128 #define	ZSWR0_RESET_RXCRC	0x40	/* Reset Rx CRC generator */
129 #define	ZSWR0_RESET_TXCRC	0x80	/* Reset Tx CRC generator */
130 #define	ZSWR0_RESET_EOM		0xC0	/* Reset Tx underrun / EOM */
131 
132 /* bits in WR1 */
133 #define	ZSWR1_SIE		0x01	/* status change master int enable */
134 					/* Also see R15 for individual enabs */
135 #define	ZSWR1_TIE		0x02	/* transmitter interrupt enable */
136 #define	ZSWR1_PARITY_SPECIAL	0x04	/* parity err causes special rx int */
137 #define	ZSWR1_RIE_FIRST_SPECIAL	0x08	/* r.i.e. on 1st char of msg */
138 #define	ZSWR1_RIE		0x10	/* receiver interrupt enable */
139 #define	ZSWR1_RIE_SPECIAL_ONLY	0x18	/* rie on special only */
140 #define	ZSWR1_REQ_IS_RX		0x20	/* REQ pin is for receiver */
141 #define	ZSWR1_REQ_NOT_WAIT	0x40	/* REQ/WAIT pin is REQ */
142 #define	ZSWR1_REQ_ENABLE	0x80	/* enable REQ/WAIT */
143 /* There are other Receive interrupt options defined, see data sheet. */
144 
145 /* bits in WR2 are defined above as R/WR2. */
146 
147 /* bits in WR3 */
148 #define	ZSWR3_RX_ENABLE		0x01	/* receiver enable */
149 #define	ZSWR3_RXCRC_ENABLE	0x08	/* receiver CRC enable */
150 #define	ZSWR3_HUNT		0x10	/* enter hunt mode */
151 #define	ZSWR3_AUTO_CD_CTS	0x20	/* auto-enable CD&CTS rcv&xmit ctl */
152 #define	ZSWR3_RX_5		0x00	/* receive 5-bit characters */
153 #define	ZSWR3_RX_6		0x80	/* receive 6 bit characters */
154 #define	ZSWR3_RX_7		0x40	/* receive 7 bit characters */
155 #define	ZSWR3_RX_8		0xC0	/* receive 8 bit characters */
156 
157 /* bits in WR4 */
158 #define	ZSWR4_PARITY_ENABLE	0x01	/* Gen/check parity bit */
159 #define	ZSWR4_PARITY_EVEN	0x02	/* Gen/check even parity */
160 #define	ZSWR4_1_STOP		0x04	/* 1 stop bit */
161 #define	ZSWR4_1_5_STOP		0x08	/* 1.5 stop bits */
162 #define	ZSWR4_2_STOP		0x0C	/* 2 stop bits */
163 #define	ZSWR4_BISYNC		0x10	/* Bisync mode */
164 #define	ZSWR4_SDLC		0x20	/* SDLC mode */
165 #define	ZSWR4_X1_CLK		0x00	/* clock is 1x */
166 #define	ZSWR4_X16_CLK		0x40	/* clock is 16x */
167 #define	ZSWR4_X32_CLK		0x80	/* clock is 32x */
168 #define	ZSWR4_X64_CLK		0xC0	/* clock is 64x */
169 
170 /* bits in WR5 */
171 #define	ZSWR5_TXCRC_ENABLE	0x01	/* transmitter CRC enable */
172 #define	ZSWR5_RTS		0x02	/* RTS output */
173 #define	ZSWR5_CRC16		0x04	/* Use CRC-16 for checksum */
174 #define	ZSWR5_TX_ENABLE		0x08	/* transmitter enable */
175 #define	ZSWR5_BREAK		0x10	/* send break continuously */
176 #define	ZSWR5_TX_5		0x00	/* transmit 5 bit chars or less */
177 #define	ZSWR5_TX_6		0x40	/* transmit 6 bit characters */
178 #define	ZSWR5_TX_7		0x20	/* transmit 7 bit characters */
179 #define	ZSWR5_TX_8		0x60	/* transmit 8 bit characters */
180 #define	ZSWR5_DTR		0x80	/* DTR output */
181 
182 /* bits in WR6 -- Sync characters or SDLC address field. */
183 
184 /* bits in WR7 -- Sync character or SDLC flag */
185 
186 /* bits in WR8 -- transmit buffer.  Same as writing to data port. */
187 
188 /*
189  * bits in WR9 -- Master interrupt control and reset.  Accessible thru
190  * either channel, there's only one of them.
191  */
192 #define	ZSWR9_VECTOR_INCL_STAT	0x01	/* Include status bits in int vector */
193 #define	ZSWR9_NO_VECTOR		0x02	/* Do not respond to int ack cycles */
194 #define	ZSWR9_DIS_LOWER_CHAIN	0x04	/* Disable ints lower in daisy chain */
195 #define	ZSWR9_MASTER_IE		0x08	/* Master interrupt enable */
196 #define	ZSWR9_STAT_HIGH		0x10	/* Modify ivec bits 6-4, not 1-3 */
197 #define	ZSWR9_RESET_CHAN_B	0x40	/* Reset just channel B */
198 #define	ZSWR9_RESET_CHAN_A	0x80	/* Reset just channel A */
199 #define	ZSWR9_RESET_WORLD	0xC0	/* Force hardware reset */
200 
201 /* bits in WR10 -- SDLC, NRZI, FM control bits */
202 #define	ZSWR10_UNDERRUN_ABORT	0x04	/* send abort on TX underrun */
203 #define	ZSWR10_NRZI		0x20	/* NRZI mode (SDLC) */
204 #define	ZSWR10_PRESET_ONES	0x80	/* preset CRC to ones (SDLC) */
205 
206 /* bits in WR11 -- clock mode control */
207 #define	ZSWR11_TRXC_XTAL	0x00	/* TRxC output = xtal osc */
208 #define	ZSWR11_TRXC_XMIT	0x01	/* TRxC output = xmitter clk */
209 #define	ZSWR11_TRXC_BAUD	0x02	/* TRxC output = baud rate gen */
210 #define	ZSWR11_TRXC_DPLL	0x03	/* TRxC output = Phase Locked Loop */
211 #define	ZSWR11_TRXC_OUT_ENA	0x04	/* TRxC output enable (unless input) */
212 #define	ZSWR11_TXCLK_RTXC	0x00	/* Tx clock is RTxC pin */
213 #define	ZSWR11_TXCLK_TRXC	0x08	/* Tx clock is TRxC pin */
214 #define	ZSWR11_TXCLK_BAUD	0x10	/* Tx clock is baud rate gen output */
215 #define	ZSWR11_TXCLK_DPLL	0x18	/* Tx clock is Phase Locked Loop o/p */
216 #define	ZSWR11_RXCLK_RTXC	0x00	/* Rx clock is RTxC pin */
217 #define	ZSWR11_RXCLK_TRXC	0x20	/* Rx clock is TRxC pin */
218 #define	ZSWR11_RXCLK_BAUD	0x40	/* Rx clock is baud rate gen output */
219 #define	ZSWR11_RXCLK_DPLL	0x60	/* Rx clock is Phase Locked Loop o/p */
220 #define	ZSWR11_RTXC_XTAL	0x80	/* RTxC uses crystal, not TTL signal */
221 
222 /* bits in WR12 -- described above as R/WR12 */
223 
224 /* bits in WR13 -- described above as R/WR13 */
225 
226 /* bits in WR14 -- misc control bits, and DPLL control */
227 #define	ZSWR14_BAUD_ENA		0x01	/* enables baud rate counter */
228 #define	ZSWR14_BAUD_FROM_PCLK	0x02	/* Baud rate gen src = PCLK not RTxC */
229 #define	ZSWR14_DTR_IS_REQUEST	0x04	/* Changes DTR line to DMA Request */
230 #define	ZSWR14_AUTO_ECHO	0x08	/* Echoes RXD to TXD */
231 #define	ZSWR14_LOCAL_LOOPBACK	0x10	/* Echoes TX to RX in chip */
232 #define	ZSWR14_DPLL_NOP		0x00	/* These 8 commands are mut. exclu. */
233 #define	ZSWR14_DPLL_SEARCH	0x20	/* Enter search mode in DPLL */
234 #define	ZSWR14_DPLL_RESET	0x40	/* Reset missing clock in DPLL */
235 #define	ZSWR14_DPLL_DISABLE	0x60	/* Disable DPLL */
236 #define	ZSWR14_DPLL_SRC_BAUD	0x80	/* Source for DPLL is baud rate gen */
237 #define	ZSWR14_DPLL_SRC_RTXC	0xA0	/* Source for DPLL is RTxC pin */
238 #define	ZSWR14_DPLL_FM		0xC0	/* DPLL should run in FM mode */
239 #define	ZSWR14_DPLL_NRZI	0xE0	/* DPLL should run in NRZI mode */
240 
241 /* bits in WR15 -- described above as R/WR15 */
242 
243 /*
244  * UART register addressing
245  *
246  * It would be nice if they used 4 address pins to address 15 registers,
247  * but they only used 1.  So you have to write to the control port then
248  * read or write it; the 2nd cycle is done to whatever register number
249  * you wrote in the first cycle.
250  *
251  * The data register can also be accessed as Read/Write register 8.
252  */
253 
254 #ifdef	_KERNEL
255 struct zscc_device {
256 	volatile unsigned char	zscc_control;
257 	volatile unsigned char	:8;		/* Filler */
258 	volatile unsigned char	zscc_data;
259 	volatile unsigned char	:8;		/* Filler */
260 };
261 
262 #define	ZSOFF	4
263 
264 
265 #endif	/* _KERNEL */
266 
267 #ifdef	__cplusplus
268 }
269 #endif
270 
271 #endif /* !_SYS_SER_ZSCC_H */
272