/* $NetBSD: zsreg.h,v 1.4 1994/11/21 21:31:29 gwr Exp $ */ /* * Copyright (c) 1992, 1993 * The Regents of the University of California. All rights reserved. * * This software was developed by the Computer Systems Engineering group * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and * contributed to Berkeley. * * All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Lawrence Berkeley Laboratory. * * 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 University of * California, Berkeley and its contributors. * 4. Neither the name of the University 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 REGENTS 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 REGENTS 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. * * @(#)zsreg.h 8.1 (Berkeley) 6/11/93 * from: Hdr: zsreg.h,v 1.7 92/11/26 01:27:18 torek Exp (LBL) */ /* * Zilog SCC registers, as implemented on the Sun-4c. * * Each Z8530 implements two channels (called `a' and `b'). * * The damnable chip was designed to fit on Z80 I/O ports, and thus * has everything multiplexed out the wazoo. We have to select * a register, then read or write the register, and so on. Worse, * the parameter bits are scattered all over the register space. * This thing is full of `miscellaneous' control registers. * * Worse yet, the registers have incompatible functions on read * and write operations. We describe the registers below according * to whether they are `read registers' (RR) or `write registers' (WR). * As if this were not enough, some of the channel B status bits show * up in channel A, and vice versa. The blasted thing shares write * registers 2 and 9 across both channels, and reads registers 2 and 3 * differently for the two channels. We can, however, ignore this much * of the time. */ #ifndef LOCORE struct zschan { u_char zc_csr; /* control and status, and indirect access */ u_char zc_xxx0; u_char zc_data; /* data */ u_char zc_xxx1; }; /* * N.B.: the keyboard is channel 1, the mouse channel 0; ttyb is 1, ttya * is 0. In other words, the things are BACKWARDS. */ struct zsdevice { struct zschan zs_chan[2]; /* channel A = 1, B = 0 */ }; #define CHAN_A 1 #define CHAN_B 0 #endif /* * Some of the names in this files were chosen to make the hsis driver * work unchanged (which means that they will match some in SunOS). * * `S.C.' stands for Special Condition, which is any of these: * receiver overrun (aka silo overflow) * framing error (missing stop bit, etc) * end of frame (in synchronous modes) * parity error (when `parity error is S.C.' is set) */ /* * Registers with only a single `numeric value' get a name. * Other registers hold bits and are only numbered; the bit * definitions imply the register number (see below). * * We never use the receive and transmit data registers as * indirects (choosing instead the zc_data register), so they * are not defined here. */ #define ZSRR_IVEC 2 /* interrupt vector (channel 0) */ #define ZSRR_IPEND 3 /* interrupt pending (ch. 0 only) */ #define ZSRR_BAUDLO 12 /* baud rate generator (low half) */ #define ZSRR_BAUDHI 13 /* baud rate generator (high half) */ #define ZSWR_IVEC 2 /* interrupt vector (shared) */ #define ZSWR_TXSYNC 6 /* sync transmit char (monosync mode) */ #define ZSWR_RXSYNC 7 /* sync receive char (monosync mode) */ #define ZSWR_SYNCLO 6 /* sync low byte (bisync mode) */ #define ZSWR_SYNCHI 7 /* sync high byte (bisync mode) */ #define ZSWR_SDLC_ADDR 6 /* SDLC address (SDLC mode) */ #define ZSWR_SDLC_FLAG 7 /* SDLC flag 0x7E (SDLC mode) */ #define ZSWR_BAUDLO 12 /* baud rate generator (low half) */ #define ZSWR_BAUDHI 13 /* baud rate generator (high half) */ /* * Registers 0 through 7 may be written with any one of the 8 command * modifiers, and/or any one of the 4 reset modifiers, defined below. * To write registers 8 through 15, however, the command modifier must * always be `point high'. Rather than track this bizzareness all over * the driver, we try to avoid using any modifiers, ever (but they are * defined here if you want them). */ #define ZSM_RESET_TXUEOM 0xc0 /* reset xmit underrun / eom latch */ #define ZSM_RESET_TXCRC 0x80 /* reset xmit crc generator */ #define ZSM_RESET_RXCRC 0x40 /* reset recv crc checker */ #define ZSM_NULL 0x00 /* nothing special */ #define ZSM_RESET_IUS 0x38 /* reset interrupt under service */ #define ZSM_RESET_ERR 0x30 /* reset error cond */ #define ZSM_RESET_TXINT 0x28 /* reset xmit interrupt pending */ #define ZSM_EI_NEXTRXC 0x20 /* enable int. on next rcvd char */ #define ZSM_SEND_ABORT 0x18 /* send abort (SDLC) */ #define ZSM_RESET_STINT 0x10 /* reset external/status interrupt */ #define ZSM_POINTHIGH 0x08 /* `point high' (use r8-r15) */ #define ZSM_NULL 0x00 /* nothing special */ /* * Commands for Write Register 0 (`Command Register'). * These are just the command modifiers or'ed with register number 0 * (which of course equals the command modifier). */ #define ZSWR0_RESET_EOM ZSM_RESET_TXUEOM #define ZSWR0_RESET_TXCRC ZSM_RESET_TXCRC #define ZSWR0_RESET_RXCRC ZSM_RESET_RXCRC #define ZSWR0_CLR_INTR ZSM_RESET_IUS #define ZSWR0_RESET_ERRORS ZSM_RESET_ERR #define ZSWR0_EI_NEXTRXC ZSM_EI_NEXTRXC #define ZSWR0_SEND_ABORT ZSM_SEND_ABORT #define ZSWR0_RESET_STATUS ZSM_RESET_STINT #define ZSWR0_RESET_TXINT ZSM_RESET_TXINT /* * Bits in Write Register 1 (`Transmit/Receive Interrupt and Data * Transfer Mode Definition'). Note that bits 3 and 4 are taken together * as a single unit, and bits 5 and 6 are useful only if bit 7 is set. */ #define ZSWR1_REQ_WAIT 0x80 /* WAIT*-REQ* pin gives WAIT* */ #define ZSWR1_REQ_REQ 0xc0 /* WAIT*-REQ* pin gives REQ* */ #define ZSWR1_REQ_TX 0x00 /* WAIT*-REQ* pin follows xmit buf */ #define ZSWR1_REQ_RX 0x20 /* WAIT*-REQ* pin follows recv buf */ #define ZSWR1_RIE_NONE 0x00 /* disable rxint entirely */ #define ZSWR1_RIE_FIRST 0x08 /* rxint on first char & on S.C. */ #define ZSWR1_RIE 0x10 /* rxint per char & on S.C. */ #define ZSWR1_RIE_SPECIAL_ONLY 0x18 /* rxint on S.C. only */ #define ZSWR1_PE_SC 0x04 /* parity error is special condition */ #define ZSWR1_TIE 0x02 /* transmit interrupt enable */ #define ZSWR1_SIE 0x01 /* external/status interrupt enable */ /* HSIS compat */ #define ZSWR1_REQ_ENABLE (ZSWR1_REQ_WAIT | ZSWR1_REQ_TX) /* * Bits in Write Register 3 (`Receive Parameters and Control'). * Bits 7 and 6 are taken as a unit. Note that the receive bits * per character ordering is insane. * * Here `hardware flow control' means CTS enables the transmitter * and DCD enables the receiver. The latter is neither interesting * nor useful, and gets in our way, making it almost unusable. */ #define ZSWR3_RX_5 0x00 /* receive 5 bits per char */ #define ZSWR3_RX_7 0x40 /* receive 7 bits per char */ #define ZSWR3_RX_6 0x80 /* receive 6 bits per char */ #define ZSWR3_RX_8 0xc0 /* receive 8 bits per char */ #define ZSWR3_HFC 0x20 /* hardware flow control */ #define ZSWR3_HUNT 0x10 /* enter hunt mode */ #define ZSWR3_RXCRC_ENABLE 0x08 /* enable recv crc calculation */ #define ZSWR3_ADDR_SEARCH_MODE 0x04 /* address search mode (SDLC only) */ #define ZSWR3_SYNC_LOAD_INH 0x02 /* sync character load inhibit */ #define ZSWR3_RX_ENABLE 0x01 /* receiver enable */ /* * Bits in Write Register 4 (`Transmit/Receive Miscellaneous Parameters * and Modes'). Bits 7&6, 5&4, and 3&2 are taken as units. */ #define ZSWR4_CLK_X1 0x00 /* clock divisor = 1 */ #define ZSWR4_CLK_X16 0x40 /* clock divisor = 16 */ #define ZSWR4_CLK_X32 0x80 /* clock divisor = 32 */ #define ZSWR4_CLK_X64 0xc0 /* clock divisor = 64 */ #define ZSWR4_MONOSYNC 0x00 /* 8 bit sync char (sync only) */ #define ZSWR4_BISYNC 0x10 /* 16 bit sync char (sync only) */ #define ZSWR4_SDLC 0x20 /* SDLC mode */ #define ZSWR4_EXTSYNC 0x30 /* external sync mode */ #define ZSWR4_SYNCMODE 0x00 /* one of the above sync modes */ #define ZSWR4_ONESB 0x04 /* 1 stop bit */ #define ZSWR4_1P5SB 0x08 /* 1.5 stop bits (clk cannot be 1x) */ #define ZSWR4_TWOSB 0x0c /* 2 stop bits */ #define ZSWR4_EVENP 0x02 /* check for even parity */ #define ZSWR4_PARENB 0x01 /* enable parity checking */ /* * Bits in Write Register 5 (`Transmit Parameter and Controls'). * Bits 6 and 5 are taken as a unit; the ordering is, as with RX * bits per char, not sensible. */ #define ZSWR5_DTR 0x80 /* assert (set to -12V) DTR */ #define ZSWR5_TX_5 0x00 /* transmit 5 or fewer bits */ #define ZSWR5_TX_7 0x20 /* transmit 7 bits */ #define ZSWR5_TX_6 0x40 /* transmit 6 bits */ #define ZSWR5_TX_8 0x60 /* transmit 8 bits */ #define ZSWR5_BREAK 0x10 /* send break (continuous 0s) */ #define ZSWR5_TX_ENABLE 0x08 /* enable transmitter */ #define ZSWR5_CRC16 0x04 /* use CRC16 (off => use SDLC) */ #define ZSWR5_RTS 0x02 /* assert RTS */ #define ZSWR5_TXCRC_ENABLE 0x01 /* enable xmit crc calculation */ #ifdef not_done_here /* * Bits in Write Register 7 when the chip is in SDLC mode. */ #define ZSWR7_SDLCFLAG 0x7e /* this value makes SDLC mode work */ #endif /* * Bits in Write Register 9 (`Master Interrupt Control'). Bits 7 & 6 * are taken as a unit and indicate the type of reset; 00 means no reset * (and is not defined here). */ #define ZSWR9_HARD_RESET 0xc0 /* force hardware reset */ #define ZSWR9_A_RESET 0x80 /* reset channel A (0) */ #define ZSWR9_B_RESET 0x40 /* reset channel B (1) */ /* 0x20 unused */ #define ZSWR9_STATUS_HIGH 0x10 /* status in high bits of intr vec */ #define ZSWR9_MASTER_IE 0x08 /* master interrupt enable */ #define ZSWR9_DLC 0x04 /* disable lower chain */ #define ZSWR9_NO_VECTOR 0x02 /* no vector */ #define ZSWR9_VECTOR_INCL_STAT 0x01 /* vector includes status */ /* * Bits in Write Register 10 (`Miscellaneous Transmitter/Receiver Control * Bits'). Bits 6 & 5 are taken as a unit, and some of the bits are * meaningful only in certain modes. Bleah. */ #define ZSWR10_PRESET_ONES 0x80 /* preset CRC to all 1 (else all 0) */ #define ZSWR10_NRZ 0x00 /* NRZ encoding */ #define ZSWR10_NRZI 0x20 /* NRZI encoding */ #define ZSWR10_FM1 0x40 /* FM1 encoding */ #define ZSWR10_FM0 0x60 /* FM0 encoding */ #define ZSWR10_GA_ON_POLL 0x10 /* go active on poll (loop mode) */ #define ZSWR10_MARK_IDLE 0x08 /* all 1s (vs flag) when idle (SDLC) */ #define ZSWR10_ABORT_ON_UNDERRUN 0x4 /* abort on xmit underrun (SDLC) */ #define ZSWR10_LOOP_MODE 0x02 /* loop mode (SDLC) */ #define ZSWR10_6_BIT_SYNC 0x01 /* 6 bits per sync char (sync modes) */ /* * Bits in Write Register 11 (`Clock Mode Control'). Bits 6&5, 4&3, and * 1&0 are taken as units. Various bits depend on other bits in complex * ways; see the Zilog manual. */ #define ZSWR11_XTAL 0x80 /* have xtal between RTxC* and SYNC* */ /* (else have TTL oscil. on RTxC*) */ #define ZSWR11_RXCLK_RTXC 0x00 /* recv clock taken from TRxC* pin */ #define ZSWR11_RXCLK_TRXC 0x20 /* recv clock taken from TRxC* pin */ #define ZSWR11_RXCLK_BAUD 0x40 /* recv clock taken from BRG */ #define ZSWR11_RXCLK_DPLL 0x60 /* recv clock taken from DPLL */ #define ZSWR11_TXCLK_RTXC 0x00 /* xmit clock taken from TRxC* pin */ #define ZSWR11_TXCLK_TRXC 0x08 /* xmit clock taken from RTxC* pin */ #define ZSWR11_TXCLK_BAUD 0x10 /* xmit clock taken from BRG */ #define ZSWR11_TXCLK_DPLL 0x18 /* xmit clock taken from DPLL */ #define ZSWR11_TRXC_OUT_ENA 0x04 /* TRxC* pin will be an output */ /* (unless it is being used above) */ #define ZSWR11_TRXC_XTAL 0x00 /* TRxC output from xtal oscillator */ #define ZSWR11_TRXC_XMIT 0x01 /* TRxC output from xmit clock */ #define ZSWR11_TRXC_BAUD 0x02 /* TRxC output from BRG */ #define ZSWR11_TRXC_DPLL 0x03 /* TRxC output from DPLL */ /* * Formula for Write Registers 12 and 13 (`Lower Byte of Baud Rate * Generator Time Constant' and `Upper Byte of ...'). Inputs: * * f BRG input clock frequency (in Hz) AFTER division * by 1, 16, 32, or 64 (per clock divisor in WR4) * bps desired rate in bits per second (9600, etc) * * We want * * f * ----- + 0.5 - 2 * 2 bps * * rounded down to an integer. This can be computed entirely * in integer arithemtic as: * * f + bps * ------- - 2 * 2 bps */ #define BPS_TO_TCONST(f, bps) ((((f) + (bps)) / (2 * (bps))) - 2) /* inverse of above: given a BRG Time Constant, return Bits Per Second */ #define TCONST_TO_BPS(f, tc) ((f) / 2 / ((tc) + 2)) /* * Bits in Write Register 14 (`Miscellaneous Control Bits'). * Bits 7 through 5 are taken as a unit and make up a `DPLL command'. */ #define ZSWR14_DPLL_NOOP 0x00 /* leave DPLL alone */ #define ZSWR14_DPLL_SEARCH 0x20 /* enter search mode */ #define ZSWR14_DPLL_RESET_CM 0x40 /* reset `clock missing' in RR10 */ #define ZSWR14_DPLL_DISABLE 0x60 /* disable DPLL (continuous search) */ #define ZSWR14_DPLL_SRC_BAUD 0x80 /* set DPLL src = BRG */ #define ZSWR14_DPLL_SRC_RTXC 0xa0 /* set DPLL src = RTxC* or xtal osc */ #define ZSWR14_DPLL_FM 0xc0 /* operate in FM mode */ #define ZSWR14_DPLL_NRZI 0xe0 /* operate in NRZI mode */ #define ZSWR14_LOCAL_LOOPBACK 0x10 /* set local loopback mode */ #define ZSWR14_AUTO_ECHO 0x08 /* set auto echo mode */ #define ZSWR14_DTR_REQ 0x04 /* DTR*/REQ* pin gives REQ* */ #define ZSWR14_BAUD_FROM_PCLK 0x02 /* BRG clock taken from PCLK */ /* (else from RTxC* pin or xtal osc) */ #define ZSWR14_BAUD_ENA 0x01 /* enable BRG countdown */ /* * Bits in Write Register 15 (`External/Status Interrupt Control'). * Most of these cause status interrupts whenever the corresponding * bit or pin changes state (i.e., any rising or falling edge). */ #define ZSWR15_BREAK_IE 0x80 /* enable break/abort status int */ #define ZSWR15_TXUEOM_IE 0x40 /* enable TX underrun/EOM status int */ #define ZSWR15_CTS_IE 0x20 /* enable CTS* pin status int */ #define ZSWR15_SYNCHUNT_IE 0x10 /* enable SYNC* pin/hunt status int */ #define ZSWR15_DCD_IE 0x08 /* enable DCD* pin status int */ /* 0x04 unused, must be zero */ #define ZSWR15_ZERO_COUNT_IE 0x02 /* enable BRG-counter = 0 status int */ /* 0x01 unused, must be zero */ /* * Bits in Read Register 0 (`Transmit/Receive Buffer Status and External * Status'). */ #define ZSRR0_BREAK 0x80 /* break/abort detected */ #define ZSRR0_TXUNDER 0x40 /* transmit underrun/EOM (sync) */ #define ZSRR0_CTS 0x20 /* clear to send */ #define ZSRR0_SYNC_HUNT 0x10 /* sync/hunt (sync mode) */ #define ZSRR0_DCD 0x08 /* data carrier detect */ #define ZSRR0_TX_READY 0x04 /* transmit buffer empty */ #define ZSRR0_ZERO_COUNT 0x02 /* zero count in baud clock */ #define ZSRR0_RX_READY 0x01 /* received character ready */ /* * Bits in Read Register 1 (the Zilog book does not name this one). */ #define ZSRR1_EOF 0x80 /* end of frame (SDLC mode) */ #define ZSRR1_FE 0x40 /* CRC/framing error */ #define ZSRR1_DO 0x20 /* data (receiver) overrun */ #define ZSRR1_PE 0x10 /* parity error */ #define ZSRR1_RC0 0x08 /* residue code 0 (SDLC mode) */ #define ZSRR1_RC1 0x04 /* residue code 1 (SDLC mode) */ #define ZSRR1_RC2 0x02 /* residue code 2 (SDLC mode) */ #define ZSRR1_ALL_SENT 0x01 /* all chars out of xmitter (async) */ /* * Read Register 2 in B channel contains status bits if VECTOR_INCL_STAT * is set. */ /* * Bits in Read Register 3 (`Interrupt Pending'). Only channel A * has an RR3. */ /* 0x80 unused, returned as 0 */ /* 0x40 unused, returned as 0 */ #define ZSRR3_IP_A_RX 0x20 /* channel A recv int pending */ #define ZSRR3_IP_A_TX 0x10 /* channel A xmit int pending */ #define ZSRR3_IP_A_STAT 0x08 /* channel A status int pending */ #define ZSRR3_IP_B_RX 0x04 /* channel B recv int pending */ #define ZSRR3_IP_B_TX 0x02 /* channel B xmit int pending */ #define ZSRR3_IP_B_STAT 0x01 /* channel B status int pending */ /* * Bits in Read Register 10 (`contains some miscellaneous status bits'). */ #define ZSRR10_1_CLOCK_MISSING 0x80 /* 1 clock edge missing (FM mode) */ #define ZSRR10_2_CLOCKS_MISSING 0x40 /* 2 clock edges missing (FM mode) */ /* 0x20 unused */ #define ZSRR10_LOOP_SENDING 0x10 /* xmitter controls loop (SDLC loop) */ /* 0x08 unused */ /* 0x04 unused */ #define ZSRR10_ON_LOOP 0x02 /* SCC is on loop (SDLC/X.21 modes) */ /* * Bits in Read Register 15. This register is one of the few that * simply reads back the corresponding Write Register. */ #define ZSRR15_BREAK_IE 0x80 /* break/abort status int enable */ #define ZSRR15_TXUEOM_IE 0x40 /* TX underrun/EOM status int enable */ #define ZSRR15_CTS_IE 0x20 /* CTS* pin status int enable */ #define ZSRR15_SYNCHUNT_IE 0x10 /* SYNC* pin/hunt status int enable */ #define ZSRR15_DCD_IE 0x08 /* DCD* pin status int enable */ /* 0x04 unused, returned as zero */ #define ZSRR15_ZERO_COUNT_IE 0x02 /* BRG-counter = 0 status int enable */ /* 0x01 unused, returned as zero */