hp300/dev/rd.c

1.1  cgd /*
1.1  cgd  * Copyright (c) 1988 University of Utah.
1.1  cgd  * Copyright (c) 1982, 1990 The Regents of the University of California.
1.1  cgd  * All rights reserved.
1.1  cgd  *
1.1  cgd  * This code is derived from software contributed to Berkeley by
1.1  cgd  * the Systems Programming Group of the University of Utah Computer
1.1  cgd  * Science Department.
1.1  cgd  *
1.1  cgd  * Redistribution and use in source and binary forms, with or without
1.1  cgd  * modification, are permitted provided that the following conditions
1.1  cgd  * are met:
1.1  cgd  * 1. Redistributions of source code must retain the above copyright
1.1  cgd  *    notice, this list of conditions and the following disclaimer.
1.1  cgd  * 2. Redistributions in binary form must reproduce the above copyright
1.1  cgd  *    notice, this list of conditions and the following disclaimer in the
1.1  cgd  *    documentation and/or other materials provided with the distribution.
1.1  cgd  * 3. All advertising materials mentioning features or use of this software
1.1  cgd  *    must display the following acknowledgement:
1.1  cgd  *	This product includes software developed by the University of
1.1  cgd  *	California, Berkeley and its contributors.
1.1  cgd  * 4. Neither the name of the University nor the names of its contributors
1.1  cgd  *    may be used to endorse or promote products derived from this software
1.1  cgd  *    without specific prior written permission.
1.1  cgd  *
1.1  cgd  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  cgd  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  cgd  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  cgd  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  cgd  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  cgd  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  cgd  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  cgd  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  cgd  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  cgd  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  cgd  * SUCH DAMAGE.
1.1  cgd  *
1.1  cgd  * from: Utah $Hdr: rd.c 1.38 90/10/12$
1.1  cgd  *
1.2  cgd  *	from: @(#)rd.c	7.9 (Berkeley) 5/7/91
1.2  cgd  *	$Id: rd.c,v 1.2 1993/05/22 07:56:45 cgd Exp $
1.1  cgd  */
1.1  cgd
1.1  cgd /*
1.1  cgd  * CS80/SS80 disk driver
1.1  cgd  */
1.1  cgd #include "rd.h"
1.1  cgd #if NRD > 0
1.1  cgd
1.1  cgd #include "sys/param.h"
1.1  cgd #include "sys/systm.h"
1.1  cgd #include "sys/errno.h"
1.1  cgd #include "sys/dkstat.h"
1.1  cgd #include "sys/disklabel.h"
1.1  cgd #include "sys/buf.h"
1.1  cgd #include "sys/uio.h"
1.1  cgd
1.1  cgd #include "device.h"
1.1  cgd #include "rdreg.h"
1.1  cgd
1.1  cgd #include "vm/vm_param.h"
1.1  cgd #include "vm/lock.h"
1.1  cgd #include "vm/vm_statistics.h"
1.1  cgd #include "vm/pmap.h"
1.1  cgd #include "vm/vm_prot.h"
1.1  cgd
1.1  cgd int	rdinit(), rdstart(), rdgo(), rdintr();
1.1  cgd struct	driver rddriver = {
1.1  cgd 	rdinit, "rd", rdstart, rdgo, rdintr,
1.1  cgd };
1.1  cgd
1.1  cgd struct	rd_softc {
1.1  cgd 	struct	hp_device *sc_hd;
1.1  cgd 	int	sc_flags;
1.1  cgd 	short	sc_type;
1.1  cgd 	short	sc_punit;
1.1  cgd 	char	*sc_addr;
1.1  cgd 	int	sc_resid;
1.1  cgd 	u_int	sc_wpms;
1.1  cgd 	struct	rdinfo *sc_info;
1.1  cgd 	struct	devqueue sc_dq;
1.1  cgd 	struct	rd_iocmd sc_ioc;
1.1  cgd 	struct	rd_rscmd sc_rsc;
1.1  cgd 	struct	rd_stat sc_stat;
1.1  cgd 	struct	rd_ssmcmd sc_ssmc;
1.1  cgd 	struct	rd_srcmd sc_src;
1.1  cgd 	struct	rd_clearcmd sc_clear;
1.1  cgd } rd_softc[NRD];
1.1  cgd
1.1  cgd /* sc_flags values */
1.1  cgd #define	RDF_ALIVE	0x1
1.1  cgd #define	RDF_SEEK	0x2
1.1  cgd #define RDF_SWAIT	0x4
1.1  cgd
1.1  cgd struct	size {
1.1  cgd 	daddr_t	nblocks;
1.1  cgd 	int	cyloff;
1.1  cgd };
1.1  cgd
1.1  cgd #ifdef DEBUG
1.1  cgd int rddebug = 0x80;
1.1  cgd #define RDB_FOLLOW	0x01
1.1  cgd #define RDB_STATUS	0x02
1.1  cgd #define RDB_IDENT	0x04
1.1  cgd #define RDB_IO		0x08
1.1  cgd #define RDB_ASYNC	0x10
1.1  cgd #define RDB_ERROR	0x80
1.1  cgd #define RDB_DUMP	0x80000000
1.1  cgd
1.1  cgd struct rdstats {
1.1  cgd 	long	rdretries;
1.1  cgd 	long	rdresets;
1.1  cgd 	long	rdtimeouts;
1.1  cgd 	long	rdpolltries;
1.1  cgd 	long	rdpollwaits;
1.1  cgd } rdstats[NRD];
1.1  cgd
1.1  cgd /* error message tables */
1.1  cgd char *err_reject[] = {
1.1  cgd 	0, 0,
1.1  cgd 	"channel parity error",		/* 0x2000 */
1.1  cgd 	0, 0,
1.1  cgd 	"illegal opcode",		/* 0x0400 */
1.1  cgd 	"module addressing",		/* 0x0200 */
1.1  cgd 	"address bounds",		/* 0x0100 */
1.1  cgd 	"parameter bounds",		/* 0x0080 */
1.1  cgd 	"illegal parameter",		/* 0x0040 */
1.1  cgd 	"message sequence",		/* 0x0020 */
1.1  cgd 	0,
1.1  cgd 	"message length",		/* 0x0008 */
1.1  cgd 	0, 0, 0
1.1  cgd };
1.1  cgd
1.1  cgd char *err_fault[] = {
1.1  cgd 	0,
1.1  cgd 	"cross unit",			/* 0x4000 */
1.1  cgd 	0,
1.1  cgd 	"controller fault",		/* 0x1000 */
1.1  cgd 	0, 0,
1.1  cgd 	"unit fault",			/* 0x0200 */
1.1  cgd 	0,
1.1  cgd 	"diagnostic result",		/* 0x0080 */
1.1  cgd 	0,
1.1  cgd 	"operator release request",	/* 0x0020 */
1.1  cgd 	"diagnostic release request",	/* 0x0010 */
1.1  cgd 	"internal maintenance release request",	/* 0x0008 */
1.1  cgd 	0,
1.1  cgd 	"power fail",			/* 0x0002 */
1.1  cgd 	"retransmit"			/* 0x0001 */
1.1  cgd };
1.1  cgd
1.1  cgd char *err_access[] = {
1.1  cgd 	"illegal parallel operation",	/* 0x8000 */
1.1  cgd 	"uninitialized media",		/* 0x4000 */
1.1  cgd 	"no spares available",		/* 0x2000 */
1.1  cgd 	"not ready",			/* 0x1000 */
1.1  cgd 	"write protect",		/* 0x0800 */
1.1  cgd 	"no data found",		/* 0x0400 */
1.1  cgd 	0, 0,
1.1  cgd 	"unrecoverable data overflow",	/* 0x0080 */
1.1  cgd 	"unrecoverable data",		/* 0x0040 */
1.1  cgd 	0,
1.1  cgd 	"end of file",			/* 0x0010 */
1.1  cgd 	"end of volume",		/* 0x0008 */
1.1  cgd 	0, 0, 0
1.1  cgd };
1.1  cgd
1.1  cgd char *err_info[] = {
1.1  cgd 	"operator release request",	/* 0x8000 */
1.1  cgd 	"diagnostic release request",	/* 0x4000 */
1.1  cgd 	"internal maintenance release request",	/* 0x2000 */
1.1  cgd 	"media wear",			/* 0x1000 */
1.1  cgd 	"latency induced",		/* 0x0800 */
1.1  cgd 	0, 0,
1.1  cgd 	"auto sparing invoked",		/* 0x0100 */
1.1  cgd 	0,
1.1  cgd 	"recoverable data overflow",	/* 0x0040 */
1.1  cgd 	"marginal data",		/* 0x0020 */
1.1  cgd 	"recoverable data",		/* 0x0010 */
1.1  cgd 	0,
1.1  cgd 	"maintenance track overflow",	/* 0x0004 */
1.1  cgd 	0, 0
1.1  cgd };
1.1  cgd #endif
1.1  cgd
1.1  cgd /*
1.1  cgd  * CS/80 partitions.  We reserve the first cylinder for a LIF
1.1  cgd  * style boot directory (the 8k allowed in the BSD filesystem
1.1  cgd  * is just way too small).  This boot area is outside of all but
1.1  cgd  * the C partition.  This implies that you cannot use the C
1.1  cgd  * partition on a bootable disk since the filesystem would overlay
1.1  cgd  * the boot area.  You must use the A partition.
1.1  cgd  *
1.1  cgd  * These maps support four basic layouts:
1.1  cgd  *
1.1  cgd  *	A/B/G:   This is the "traditional" setup for a bootable disk.
1.1  cgd  *	         A is the root partition, B the swap, and G a user partition.
1.1  cgd  *	A/D/H:   This is a setup for bootable systems requiring more swap
1.1  cgd  *		 (e.g. those who use HPCL).  It has A as the root, D as a
1.1  cgd  *		 larger swap, and H as a smaller user partition.
1.1  cgd  *	A/D/E/F: Similar to A/D/H with E and F breaking H into two partitions.
1.1  cgd  *		 E could be used for /usr and F for users.
1.1  cgd  *	C:       This gives a single, non-bootable, large user filesystem.
1.1  cgd  *	         Good for second drives on a machine (e.g. /usr/src).
1.1  cgd  */
1.1  cgd struct size rd7945A_sizes[8] = {
1.1  cgd 	RDSZ(15904),	1,		/* A=cyl 1 thru 142 */
1.1  cgd 	RDSZ(20160),	143,		/* B=cyl 143 thru 322 */
1.1  cgd 	RDSZ(108416),	0,		/* C=cyl 0 thru 967 */
1.1  cgd 	RDSZ(40320),	143,		/* D=cyl 143 thru 502 */
1.1  cgd 	RDSZ(0),	0,		/* E=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* F=<undefined> */
1.1  cgd 	RDSZ(72240),	323,		/* G=cyl 323 thru 967 */
1.1  cgd 	RDSZ(52080),	503,		/* H=cyl 503 thru 967 */
1.1  cgd }, rd9134D_sizes[8] = {
1.1  cgd 	RDSZ(15936),	1,		/* A=cyl 1 thru 166 */
1.1  cgd 	RDSZ(13056),	167,		/* B=cyl 167 thru 302 */
1.1  cgd 	RDSZ(29088),	0,		/* C=cyl 0 thru 302 */
1.1  cgd 	RDSZ(0),	0,		/* D=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* E=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* F=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* G=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* H=<undefined> */
1.1  cgd }, rd9122S_sizes[8] = {
1.1  cgd 	RDSZ(0),	0,		/* A=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* B=<undefined> */
1.1  cgd 	RDSZ(1232),	0,		/* C=cyl 0 thru 76 */
1.1  cgd 	RDSZ(0),	0,		/* D=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* E=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* F=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* G=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* H=<undefined> */
1.1  cgd }, rd7912P_sizes[8] = {
1.1  cgd 	RDSZ(15904),	0,		/* A=cyl 1 thru 71 */
1.1  cgd 	RDSZ(22400),	72,		/* B=cyl 72 thru 171 */
1.1  cgd 	RDSZ(128128),	0,		/* C=cyl 0 thru 571 */
1.1  cgd 	RDSZ(42560),	72,		/* D=cyl 72 thru 261 */
1.1  cgd 	RDSZ(0),	292,		/* E=<undefined> */
1.1  cgd 	RDSZ(0),	542,		/* F=<undefined> */
1.1  cgd 	RDSZ(89600),	172,		/* G=cyl 221 thru 571 */
1.1  cgd 	RDSZ(69440),	262,		/* H=cyl 262 thru 571 */
1.1  cgd }, rd7914P_sizes[8] = {
1.1  cgd 	RDSZ(15904),	1,		/* A=cyl 1 thru 71 */
1.1  cgd 	RDSZ(40320),	72,		/* B=cyl 72 thru 251 */
1.1  cgd 	RDSZ(258048),	0,		/* C=cyl 0 thru 1151 */
1.1  cgd 	RDSZ(64960),	72,		/* D=cyl 72 thru 361 */
1.1  cgd 	RDSZ(98560),	362,		/* E=cyl 362 thru 801 */
1.1  cgd 	RDSZ(78400),	802,		/* F=cyl 802 thru 1151 */
1.1  cgd 	RDSZ(201600),	252,		/* G=cyl 221 thru 1151 */
1.1  cgd 	RDSZ(176960),	362,		/* H=cyl 362 thru 1151 */
1.1  cgd }, rd7933H_sizes[8] = {
1.1  cgd 	RDSZ(16146),	1,		/* A=cyl 1 thru 27 */
1.1  cgd 	RDSZ(66976),	28,		/* B=cyl 28 thru 139 */
1.1  cgd 	RDSZ(789958),	0,		/* C=cyl 0 thru 1320 */
1.1  cgd 	RDSZ(16146),	140,		/* D=cyl 140 thru 166 */
1.1  cgd 	RDSZ(165646),	167,		/* E=cyl 167 thru 443 */
1.1  cgd 	RDSZ(165646),	444,		/* F=cyl 444 thru 720 */
1.1  cgd 	RDSZ(706238),	140,		/* G=cyl 140 thru 1320 */
1.1  cgd 	RDSZ(358800),	721,		/* H=cyl 721 thru 1320 */
1.1  cgd }, rd9134L_sizes[8] = {
1.1  cgd 	RDSZ(15920),	1,		/* A=cyl 1 thru 199 */
1.1  cgd 	RDSZ(20000),	200,		/* B=cyl 200 thru 449 */
1.1  cgd 	RDSZ(77840),	0,		/* C=cyl 0 thru 972 */
1.1  cgd 	RDSZ(32000),	200,		/* D=cyl 200 thru 599 */
1.1  cgd 	RDSZ(0),	0,		/* E=<undefined> */
1.1  cgd 	RDSZ(0),	0,		/* F=<undefined> */
1.1  cgd 	RDSZ(41840),	450,		/* G=cyl 450 thru 972 */
1.1  cgd 	RDSZ(29840),	600,		/* H=cyl 600 thru 972 */
1.1  cgd }, rd7957A_sizes[8] = {
1.1  cgd 	RDSZ(16016),	1,		/* A=cyl 1 thru 104 */
1.1  cgd 	RDSZ(24640),	105,		/* B=cyl 105 thru 264 */
1.1  cgd 	RDSZ(159544),	0,		/* C=cyl 0 thru 1035 */
1.1  cgd 	RDSZ(42350),	105,		/* D=cyl 105 thru 379 */
1.1  cgd 	RDSZ(54824),	380,		/* E=cyl 380 thru 735 */
1.1  cgd 	RDSZ(46200),	736,		/* F=cyl 736 thru 1035 */
1.1  cgd 	RDSZ(118734),	265,		/* G=cyl 265 thru 1035 */
1.1  cgd 	RDSZ(101024),	380,		/* H=cyl 380 thru 1035 */
1.1  cgd }, rd7958A_sizes[8] = {
1.1  cgd 	RDSZ(16128),	1,		/* A=cyl 1 thru 64 */
1.1  cgd 	RDSZ(32256),	65,		/* B=cyl 65 thru 192 */
1.1  cgd 	RDSZ(255276),	0,		/* C=cyl 0 thru 1012 */
1.1  cgd 	RDSZ(48384),	65,		/* D=cyl 65 thru 256 */
1.1  cgd 	RDSZ(100800),	257,		/* E=cyl 257 thru 656 */
1.1  cgd 	RDSZ(89712),	657,		/* F=cyl 657 thru 1012 */
1.1  cgd 	RDSZ(206640),	193,		/* G=cyl 193 thru 1012 */
1.1  cgd 	RDSZ(190512),	257,		/* H=cyl 257 thru 1012 */
1.1  cgd }, rd7957B_sizes[8] = {
1.1  cgd 	RDSZ(16002),	1,		/* A=cyl 1 thru 127 */
1.1  cgd 	RDSZ(32760),	128,		/* B=cyl 128 thru 387 */
1.1  cgd 	RDSZ(159894),	0,		/* C=cyl 0 thru 1268 */
1.1  cgd 	RDSZ(49140),	128,		/* D=cyl 128 thru 517 */
1.1  cgd 	RDSZ(50400),	518,		/* E=cyl 518 thru 917 */
1.1  cgd 	RDSZ(44226),	918,		/* F=cyl 918 thru 1268 */
1.1  cgd 	RDSZ(111006),	388,		/* G=cyl 388 thru 1268 */
1.1  cgd 	RDSZ(94626),	518,		/* H=cyl 518 thru 1268 */
1.1  cgd }, rd7958B_sizes[8] = {
1.1  cgd 	RDSZ(16254),	1,		/* A=cyl 1 thru 43 */
1.1  cgd 	RDSZ(32886),	44,		/* B=cyl 44 thru 130 */
1.1  cgd 	RDSZ(297108),	0,		/* C=cyl 0 thru 785 */
1.1  cgd 	RDSZ(49140),	44,		/* D=cyl 44 thru 173 */
1.1  cgd 	RDSZ(121716),	174,		/* E=cyl 174 thru 495 */
1.1  cgd 	RDSZ(109620),	496,		/* F=cyl 496 thru 785 */
1.1  cgd 	RDSZ(247590),	131,		/* G=cyl 131 thru 785 */
1.1  cgd 	RDSZ(231336),	174,		/* H=cyl 174 thru 785 */
1.1  cgd }, rd7959B_sizes[8] = {
1.1  cgd 	RDSZ(16254),	1,		/* A=cyl 1 thru 43 */
1.1  cgd 	RDSZ(49140),	44,		/* B=cyl 44 thru 173 */
1.1  cgd 	RDSZ(594216),	0,		/* C=cyl 0 thru 1571 */
1.1  cgd 	RDSZ(65772),	44,		/* D=cyl 44 thru 217 */
1.1  cgd 	RDSZ(303912),	218,		/* E=cyl 218 thru 1021 */
1.1  cgd 	RDSZ(207900),	1022,		/* F=cyl 1022 thru 1571 */
1.1  cgd 	RDSZ(528444),	174,		/* G=cyl 174 thru 1571 */
1.1  cgd 	RDSZ(511812),	218,		/* H=cyl 218 thru 1571 */
1.1  cgd }, rd2200A_sizes[8] = {
1.1  cgd 	RDSZ(16272),	1,		/* A=cyl 1 thru 36 */
1.1  cgd 	RDSZ(49720),	37,		/* B=cyl 37 thru 146 */
1.1  cgd 	RDSZ(654948),	0,		/* C=cyl 0 thru 1448 */
1.1  cgd 	RDSZ(65992),	37,		/* D=cyl 37 thru 182 */
1.1  cgd 	RDSZ(304648),	183,		/* E=cyl 183 thru 856 */
1.1  cgd 	RDSZ(267584),	857,		/* F=cyl 857 thru 1448 */
1.1  cgd 	RDSZ(588504),	147,		/* G=cyl 147 thru 1448 */
1.1  cgd 	RDSZ(572232),	183,		/* H=cyl 183 thru 1448 */
1.1  cgd }, rd2203A_sizes[8] = {
1.1  cgd 	/* modelled after the 7937; i.e. bogus */
1.1  cgd 	RDSZ(16272),	1,		/* A=cyl 1 thru 18 */
1.1  cgd 	RDSZ(67800),	19,		/* B=cyl 19 thru 93 */
1.1  cgd 	RDSZ(1309896),	0,		/* C=cyl 0 thru 1448 */
1.1  cgd 	RDSZ(16272),	94,		/* D=cyl 19 thru 111 */
1.1  cgd 	RDSZ(305552),	112,		/* E=cyl 112 thru 449 */
1.1  cgd 	RDSZ(305552),	450,		/* F=cyl 450 thru 787 */
1.1  cgd 	RDSZ(1224920),	94,		/* G=cyl 94 thru 1448 */
1.1  cgd 	RDSZ(597544),	788,		/* H=cyl 788 thru 1448 */
1.1  cgd
1.1  cgd #if DEV_BSIZE == 512
1.1  cgd /*
1.1  cgd  * These values would not work for 1k,
1.1  cgd  * since the number of cylinders would be different.
1.1  cgd  */
1.1  cgd }, rd7936H_sizes[8] = {
1.1  cgd 	RDSZ(16359),	1,		/* A=cyl 1 thru 19 */
1.1  cgd 	RDSZ(67158),	20,		/* B=cyl 20 thru 97 */
1.1  cgd 	RDSZ(600978),	0,		/* C=cyl 0 thru 697 */
1.1  cgd 	RDSZ(16359),	98,		/* D=cyl 98 thru 116 */
1.1  cgd 	RDSZ(120540),	117,		/* E=cyl 117 thru 256 */
1.1  cgd 	RDSZ(120540),	256,		/* F=cyl 256 thru 396 */
1.1  cgd 	RDSZ(516600),	98,		/* G=cyl 98 thru 697 */
1.1  cgd 	RDSZ(259161),	397,		/* H=cyl 397 thru 697 */
1.1  cgd }, rd7937H_sizes[8] = {
1.1  cgd #ifdef UTAH
1.1  cgd 	RDSZ(15990),	1,		/* A=cyl 1 thru 10 */
1.1  cgd 	RDSZ(67158),	11,		/* B=cyl 11 thru 52 */
1.1  cgd 	RDSZ(1116102),	0,		/* C=cyl 0 thru 697 */
1.1  cgd 	RDSZ(124722),	53,		/* D=cyl 53 thru 130 */
1.1  cgd 	RDSZ(163098),	131,		/* E=cyl 131 thru 232 */
1.1  cgd 	RDSZ(287820),	233,		/* F=cyl 233 thru 412 */
1.1  cgd 	RDSZ(1031355),	53,		/* G=cyl 53 thru 697 */
1.1  cgd 	RDSZ(455715),	413,		/* H=cyl 413 thru 697 */
1.1  cgd #else
1.1  cgd 	RDSZ(15990),	1,		/* A=cyl 1 thru 10 */
1.1  cgd 	RDSZ(67158),	11,		/* B=cyl 11 thru 52 */
1.1  cgd 	RDSZ(1116102),	0,		/* C=cyl 0 thru 697 */
1.1  cgd 	RDSZ(15990),	53,		/* D=cyl 53 thru 62 */
1.1  cgd 	RDSZ(246246),	63,		/* E=cyl 63 thru 216 */
1.1  cgd 	RDSZ(246246),	217,		/* F=cyl 217 thru 370 */
1.1  cgd 	RDSZ(1031355),	53,		/* G=cyl 53 thru 697 */
1.1  cgd 	RDSZ(522873),	371,		/* H=cyl 371 thru 697 */
1.1  cgd #endif
1.1  cgd #endif
1.1  cgd };
1.1  cgd
1.1  cgd struct	rdinfo {
1.1  cgd 	int	nbpt;		/* DEV_BSIZE blocks per track */
1.1  cgd 	int	ntpc;		/* tracks per cylinder */
1.1  cgd 	int	nbpc;		/* blocks per cylinder */
1.1  cgd 	struct	size *sizes;	/* default partition info (if no disklabel) */
1.1  cgd 	short	hwid;		/* 2 byte HW id */
1.1  cgd 	short	maxunum;	/* maximum allowed unit number */
1.1  cgd 	char	*desc;		/* drive type description */
1.1  cgd };
1.1  cgd
1.1  cgd struct rdinfo rdinfo[] = {
1.1  cgd 	NRD7945ABPT,	NRD7945ATRK,	NRD7945ABPT * NRD7945ATRK,
1.1  cgd 	rd7945A_sizes,	RD7946AID,	0,	"7945A",
1.1  cgd 	NRD9134DBPT,	NRD9134DTRK,	NRD9134DBPT * NRD9134DTRK,
1.1  cgd 	rd9134D_sizes,	RD9134DID,	1,	"9134D",
1.1  cgd 	NRD9122SBPT,	NRD9122STRK,	NRD9122SBPT * NRD9122STRK,
1.1  cgd 	rd9122S_sizes,	RD9134LID,	1,	"9122S",
1.1  cgd 	NRD7912PBPT,	NRD7912PTRK,	NRD7912PBPT * NRD7912PTRK,
1.1  cgd 	rd7912P_sizes,	RD7912PID,	0,	"7912P",
1.1  cgd 	NRD7914PBPT,	NRD7914PTRK,	NRD7914PBPT * NRD7914PTRK,
1.1  cgd 	rd7914P_sizes,	RD7914PID,	0,	"7914P",
1.1  cgd 	NRD7958ABPT,	NRD7958ATRK,	NRD7958ABPT * NRD7958ATRK,
1.1  cgd 	rd7958A_sizes,	RD7958AID,	0,	"7958A",
1.1  cgd 	NRD7957ABPT,	NRD7957ATRK,	NRD7957ABPT * NRD7957ATRK,
1.1  cgd 	rd7957A_sizes,	RD7957AID,	0,	"7957A",
1.1  cgd 	NRD7933HBPT,	NRD7933HTRK,	NRD7933HBPT * NRD7933HTRK,
1.1  cgd 	rd7933H_sizes,	RD7933HID,	0,	"7933H",
1.1  cgd 	NRD9134LBPT,	NRD9134LTRK,	NRD9134LBPT * NRD9134LTRK,
1.1  cgd 	rd9134L_sizes,	RD9134LID,	1,	"9134L",
1.1  cgd 	NRD7936HBPT,	NRD7936HTRK,	NRD7936HBPT * NRD7936HTRK,
1.1  cgd 	rd7936H_sizes,	RD7936HID,	0,	"7936H",
1.1  cgd 	NRD7937HBPT,	NRD7937HTRK,	NRD7937HBPT * NRD7937HTRK,
1.1  cgd 	rd7937H_sizes,	RD7937HID,	0,	"7937H",
1.1  cgd 	NRD7914PBPT,	NRD7914PTRK,	NRD7914PBPT * NRD7914PTRK,
1.1  cgd 	rd7914P_sizes,	RD7914CTID,	0,	"7914CT",
1.1  cgd 	NRD7945ABPT,	NRD7945ATRK,	NRD7945ABPT * NRD7945ATRK,
1.1  cgd 	rd7945A_sizes,	RD7946AID,	0,	"7946A",
1.1  cgd 	NRD9122SBPT,	NRD9122STRK,	NRD9122SBPT * NRD9122STRK,
1.1  cgd 	rd9122S_sizes,	RD9134LID,	1,	"9122D",
1.1  cgd 	NRD7957BBPT,	NRD7957BTRK,	NRD7957BBPT * NRD7957BTRK,
1.1  cgd 	rd7957B_sizes,	RD7957BID,	0,	"7957B",
1.1  cgd 	NRD7958BBPT,	NRD7958BTRK,	NRD7958BBPT * NRD7958BTRK,
1.1  cgd 	rd7958B_sizes,	RD7958BID,	0,	"7958B",
1.1  cgd 	NRD7959BBPT,	NRD7959BTRK,	NRD7959BBPT * NRD7959BTRK,
1.1  cgd 	rd7959B_sizes,	RD7959BID,	0,	"7959B",
1.1  cgd 	NRD2200ABPT,	NRD2200ATRK,	NRD2200ABPT * NRD2200ATRK,
1.1  cgd 	rd2200A_sizes,	RD2200AID,	0,	"2200A",
1.1  cgd 	NRD2203ABPT,	NRD2203ATRK,	NRD2203ABPT * NRD2203ATRK,
1.1  cgd 	rd2203A_sizes,	RD2203AID,	0,	"2203A",
1.1  cgd };
1.1  cgd int nrdinfo = sizeof(rdinfo) / sizeof(rdinfo[0]);
1.1  cgd
1.1  cgd struct	buf rdtab[NRD];
1.1  cgd
1.1  cgd #define	rdunit(x)	(minor(x) >> 3)
1.1  cgd #define rdpart(x)	(minor(x) & 0x7)
1.1  cgd #define	rdpunit(x)	((x) & 7)
1.1  cgd #define	b_cylin		b_resid
1.1  cgd #define	RDRETRY		5
1.1  cgd #define RDWAITC		1	/* min time for timeout in seconds */
1.1  cgd
1.1  cgd int rderrthresh = RDRETRY-1;	/* when to start reporting errors */
1.1  cgd
1.1  cgd rdinit(hd)
1.1  cgd 	register struct hp_device *hd;
1.1  cgd {
1.1  cgd 	register struct rd_softc *rs = &rd_softc[hd->hp_unit];
1.1  cgd
1.1  cgd 	rs->sc_hd = hd;
1.1  cgd 	rs->sc_punit = rdpunit(hd->hp_flags);
1.1  cgd 	rs->sc_type = rdident(rs, hd);
1.1  cgd 	if (rs->sc_type < 0)
1.1  cgd 		return(0);
1.1  cgd 	rs->sc_dq.dq_ctlr = hd->hp_ctlr;
1.1  cgd 	rs->sc_dq.dq_unit = hd->hp_unit;
1.1  cgd 	rs->sc_dq.dq_slave = hd->hp_slave;
1.1  cgd 	rs->sc_dq.dq_driver = &rddriver;
1.1  cgd 	rs->sc_info = &rdinfo[rs->sc_type];
1.1  cgd 	rs->sc_flags = RDF_ALIVE;
1.1  cgd #ifdef DEBUG
1.1  cgd 	/* always report errors */
1.1  cgd 	if (rddebug & RDB_ERROR)
1.1  cgd 		rderrthresh = 0;
1.1  cgd #endif
1.1  cgd 	return(1);
1.1  cgd }
1.1  cgd
1.1  cgd rdident(rs, hd)
1.1  cgd 	struct rd_softc *rs;
1.1  cgd 	struct hp_device *hd;
1.1  cgd {
1.1  cgd 	struct rd_describe desc;
1.1  cgd 	u_char stat, cmd[3];
1.1  cgd 	int unit, lunit;
1.1  cgd 	char name[7];
1.1  cgd 	register int ctlr, slave, id, i;
1.1  cgd
1.1  cgd 	ctlr = hd->hp_ctlr;
1.1  cgd 	slave = hd->hp_slave;
1.1  cgd 	unit = rs->sc_punit;
1.1  cgd 	lunit = hd->hp_unit;
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * Grab device id and make sure:
1.1  cgd 	 * 1. It is a CS80 device.
1.1  cgd 	 * 2. It is one of the types we support.
1.1  cgd 	 * 3. If it is a 7946, we are accessing the disk unit (0)
1.1  cgd 	 */
1.1  cgd 	id = hpibid(ctlr, slave);
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_IDENT)
1.1  cgd 		printf("hpibid(%d, %d) -> %x\n", ctlr, slave, id);
1.1  cgd #endif
1.1  cgd 	if ((id & 0x200) == 0)
1.1  cgd 		return(-1);
1.1  cgd 	for (i = 0; i < nrdinfo; i++)
1.1  cgd 		if (id == rdinfo[i].hwid)
1.1  cgd 			break;
1.1  cgd 	if (i == nrdinfo || unit > rdinfo[i].maxunum)
1.1  cgd 		return(-1);
1.1  cgd 	id = i;
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * Reset drive and collect device description.
1.1  cgd 	 * Don't really use the description info right now but
1.1  cgd 	 * might come in handy in the future (for disk labels).
1.1  cgd 	 */
1.1  cgd 	rdreset(rs, hd);
1.1  cgd 	cmd[0] = C_SUNIT(unit);
1.1  cgd 	cmd[1] = C_SVOL(0);
1.1  cgd 	cmd[2] = C_DESC;
1.1  cgd 	hpibsend(ctlr, slave, C_CMD, cmd, sizeof(cmd));
1.1  cgd 	hpibrecv(ctlr, slave, C_EXEC, &desc, 37);
1.1  cgd 	hpibrecv(ctlr, slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	bzero(name, sizeof(name));
1.1  cgd 	if (!stat) {
1.1  cgd 		register int n = desc.d_name;
1.1  cgd 		for (i = 5; i >= 0; i--) {
1.1  cgd 			name[i] = (n & 0xf) + '0';
1.1  cgd 			n >>= 4;
1.1  cgd 		}
1.1  cgd 		/* use drive characteristics to calculate xfer rate */
1.1  cgd 		rs->sc_wpms = 1000000 * (desc.d_sectsize/2) / desc.d_blocktime;
1.1  cgd 	}
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_IDENT) {
1.1  cgd 		printf("rd%d: name: %x ('%s')\n",
1.1  cgd 		       lunit, desc.d_name, name);
1.1  cgd 		printf("  iuw %x, maxxfr %d, ctype %d\n",
1.1  cgd 		       desc.d_iuw, desc.d_cmaxxfr, desc.d_ctype);
1.1  cgd 		printf("  utype %d, bps %d, blkbuf %d, burst %d, blktime %d\n",
1.1  cgd 		       desc.d_utype, desc.d_sectsize,
1.1  cgd 		       desc.d_blkbuf, desc.d_burstsize, desc.d_blocktime);
1.1  cgd 		printf("  avxfr %d, ort %d, atp %d, maxint %d, fv %x, rv %x\n",
1.1  cgd 		       desc.d_uavexfr, desc.d_retry, desc.d_access,
1.1  cgd 		       desc.d_maxint, desc.d_fvbyte, desc.d_rvbyte);
1.1  cgd 		printf("  maxcyl/head/sect %d/%d/%d, maxvsect %d, inter %d\n",
1.1  cgd 		       desc.d_maxcyl, desc.d_maxhead, desc.d_maxsect,
1.1  cgd 		       desc.d_maxvsectl, desc.d_interleave);
1.1  cgd 	}
1.1  cgd #endif
1.1  cgd 	/*
1.1  cgd 	 * Take care of a couple of anomolies:
1.1  cgd 	 * 1. 7945A and 7946A both return same HW id
1.1  cgd 	 * 2. 9122S and 9134D both return same HW id
1.1  cgd 	 * 3. 9122D and 9134L both return same HW id
1.1  cgd 	 */
1.1  cgd 	switch (rdinfo[id].hwid) {
1.1  cgd 	case RD7946AID:
1.1  cgd 		if (bcmp(name, "079450", 6) == 0)
1.1  cgd 			id = RD7945A;
1.1  cgd 		else
1.1  cgd 			id = RD7946A;
1.1  cgd 		break;
1.1  cgd
1.1  cgd 	case RD9134LID:
1.1  cgd 		if (bcmp(name, "091340", 6) == 0)
1.1  cgd 			id = RD9134L;
1.1  cgd 		else
1.1  cgd 			id = RD9122D;
1.1  cgd 		break;
1.1  cgd
1.1  cgd 	case RD9134DID:
1.1  cgd 		if (bcmp(name, "091220", 6) == 0)
1.1  cgd 			id = RD9122S;
1.1  cgd 		else
1.1  cgd 			id = RD9134D;
1.1  cgd 		break;
1.1  cgd 	}
1.1  cgd 	printf("rd%d: %s\n", lunit, rdinfo[id].desc);
1.1  cgd 	return(id);
1.1  cgd }
1.1  cgd
1.1  cgd rdreset(rs, hd)
1.1  cgd 	register struct rd_softc *rs;
1.1  cgd 	register struct hp_device *hd;
1.1  cgd {
1.1  cgd 	u_char stat;
1.1  cgd
1.1  cgd 	rs->sc_clear.c_unit = C_SUNIT(rs->sc_punit);
1.1  cgd 	rs->sc_clear.c_cmd = C_CLEAR;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_TCMD, &rs->sc_clear,
1.1  cgd 		sizeof(rs->sc_clear));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	rs->sc_src.c_unit = C_SUNIT(RDCTLR);
1.1  cgd 	rs->sc_src.c_nop = C_NOP;
1.1  cgd 	rs->sc_src.c_cmd = C_SREL;
1.1  cgd 	rs->sc_src.c_param = C_REL;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, &rs->sc_src,
1.1  cgd 		sizeof(rs->sc_src));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	rs->sc_ssmc.c_unit = C_SUNIT(rs->sc_punit);
1.1  cgd 	rs->sc_ssmc.c_cmd = C_SSM;
1.1  cgd 	rs->sc_ssmc.c_refm = REF_MASK;
1.1  cgd 	rs->sc_ssmc.c_fefm = FEF_MASK;
1.1  cgd 	rs->sc_ssmc.c_aefm = AEF_MASK;
1.1  cgd 	rs->sc_ssmc.c_iefm = IEF_MASK;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, &rs->sc_ssmc,
1.1  cgd 		sizeof(rs->sc_ssmc));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd #ifdef DEBUG
1.1  cgd 	rdstats[hd->hp_unit].rdresets++;
1.1  cgd #endif
1.1  cgd }
1.1  cgd
1.1  cgd int
1.1  cgd rdopen(dev, flags, mode, p)
1.1  cgd 	dev_t dev;
1.1  cgd 	int flags, mode;
1.1  cgd 	struct proc *p;
1.1  cgd {
1.1  cgd 	register int unit = rdunit(dev);
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd
1.1  cgd 	if (unit >= NRD || (rs->sc_flags & RDF_ALIVE) == 0)
1.1  cgd 		return(ENXIO);
1.1  cgd 	if (rs->sc_hd->hp_dk >= 0) {
1.1  cgd 		/* guess at xfer rate based on 3600 rpm (60 rps) */
1.1  cgd 		if (rs->sc_wpms == 0)
1.1  cgd 			rs->sc_wpms = 60 * rs->sc_info->nbpt * DEV_BSIZE / 2;
1.1  cgd 		dk_wpms[rs->sc_hd->hp_dk] = rs->sc_wpms;
1.1  cgd 	}
1.1  cgd 	return(0);
1.1  cgd }
1.1  cgd
1.1  cgd rdstrategy(bp)
1.1  cgd 	register struct buf *bp;
1.1  cgd {
1.1  cgd 	register int unit = rdunit(bp->b_dev);
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct size *pinfo = &rs->sc_info->sizes[rdpart(bp->b_dev)];
1.1  cgd 	register struct buf *dp = &rdtab[unit];
1.1  cgd 	register daddr_t bn;
1.1  cgd 	register int sz, s;
1.1  cgd
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_FOLLOW)
1.1  cgd 		printf("rdstrategy(%x): dev %x, bn %x, bcount %x, %c\n",
1.1  cgd 		       bp, bp->b_dev, bp->b_blkno, bp->b_bcount,
1.1  cgd 		       (bp->b_flags & B_READ) ? 'R' : 'W');
1.1  cgd #endif
1.1  cgd 	bn = bp->b_blkno;
1.1  cgd 	sz = howmany(bp->b_bcount, DEV_BSIZE);
1.1  cgd 	if (bn < 0 || bn + sz > pinfo->nblocks) {
1.1  cgd 		sz = pinfo->nblocks - bn;
1.1  cgd 		if (sz == 0) {
1.1  cgd 			bp->b_resid = bp->b_bcount;
1.1  cgd 			goto done;
1.1  cgd 		}
1.1  cgd 		if (sz < 0) {
1.1  cgd 			bp->b_error = EINVAL;
1.1  cgd 			bp->b_flags |= B_ERROR;
1.1  cgd 			goto done;
1.1  cgd 		}
1.1  cgd 		bp->b_bcount = dbtob(sz);
1.1  cgd 	}
1.1  cgd 	bp->b_cylin = bn / rs->sc_info->nbpc + pinfo->cyloff;
1.1  cgd 	s = splbio();
1.1  cgd 	disksort(dp, bp);
1.1  cgd 	if (dp->b_active == 0) {
1.1  cgd 		dp->b_active = 1;
1.1  cgd 		rdustart(unit);
1.1  cgd 	}
1.1  cgd 	splx(s);
1.1  cgd 	return;
1.1  cgd done:
1.1  cgd 	biodone(bp);
1.1  cgd }
1.1  cgd
1.1  cgd /*
1.1  cgd  * Called from timeout() when handling maintenance releases
1.1  cgd  */
1.1  cgd rdrestart(unit)
1.1  cgd 	int unit;
1.1  cgd {
1.1  cgd 	int s = splbio();
1.1  cgd 	rdustart(unit);
1.1  cgd 	splx(s);
1.1  cgd }
1.1  cgd
1.1  cgd rdustart(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct buf *bp;
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd
1.1  cgd 	bp = rdtab[unit].b_actf;
1.1  cgd 	rs->sc_addr = bp->b_un.b_addr;
1.1  cgd 	rs->sc_resid = bp->b_bcount;
1.1  cgd 	if (hpibreq(&rs->sc_dq))
1.1  cgd 		rdstart(unit);
1.1  cgd }
1.1  cgd
1.1  cgd rdstart(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct buf *bp = rdtab[unit].b_actf;
1.1  cgd 	register struct hp_device *hp = rs->sc_hd;
1.1  cgd 	register int part;
1.1  cgd
1.1  cgd again:
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_FOLLOW)
1.1  cgd 		printf("rdstart(%d): bp %x, %c\n", unit, bp,
1.1  cgd 		       (bp->b_flags & B_READ) ? 'R' : 'W');
1.1  cgd #endif
1.1  cgd 	part = rdpart(bp->b_dev);
1.1  cgd 	rs->sc_flags |= RDF_SEEK;
1.1  cgd 	rs->sc_ioc.c_unit = C_SUNIT(rs->sc_punit);
1.1  cgd 	rs->sc_ioc.c_volume = C_SVOL(0);
1.1  cgd 	rs->sc_ioc.c_saddr = C_SADDR;
1.1  cgd 	rs->sc_ioc.c_hiaddr = 0;
1.1  cgd 	rs->sc_ioc.c_addr = RDBTOS(bp->b_blkno + rs->sc_info->nbpc *
1.1  cgd 		rs->sc_info->sizes[part].cyloff);
1.1  cgd 	rs->sc_ioc.c_nop2 = C_NOP;
1.1  cgd 	rs->sc_ioc.c_slen = C_SLEN;
1.1  cgd 	rs->sc_ioc.c_len = rs->sc_resid;
1.1  cgd 	rs->sc_ioc.c_cmd = bp->b_flags & B_READ ? C_READ : C_WRITE;
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_IO)
1.1  cgd 		printf("rdstart: hpibsend(%x, %x, %x, %x, %x)\n",
1.1  cgd 		       hp->hp_ctlr, hp->hp_slave, C_CMD,
1.1  cgd 		       &rs->sc_ioc.c_unit, sizeof(rs->sc_ioc)-2);
1.1  cgd #endif
1.1  cgd 	if (hpibsend(hp->hp_ctlr, hp->hp_slave, C_CMD, &rs->sc_ioc.c_unit,
1.1  cgd 		     sizeof(rs->sc_ioc)-2) == sizeof(rs->sc_ioc)-2) {
1.1  cgd 		if (hp->hp_dk >= 0) {
1.1  cgd 			dk_busy |= 1 << hp->hp_dk;
1.1  cgd 			dk_seek[hp->hp_dk]++;
1.1  cgd 		}
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (rddebug & RDB_IO)
1.1  cgd 			printf("rdstart: hpibawait(%x)\n", hp->hp_ctlr);
1.1  cgd #endif
1.1  cgd 		hpibawait(hp->hp_ctlr);
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Experience has shown that the hpibwait in this hpibsend will
1.1  cgd 	 * occasionally timeout.  It appears to occur mostly on old 7914
1.1  cgd 	 * drives with full maintenance tracks.  We should probably
1.1  cgd 	 * integrate this with the backoff code in rderror.
1.1  cgd 	 */
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_ERROR)
1.1  cgd 		printf("rd%d: rdstart: cmd %x adr %d blk %d len %d ecnt %d\n",
1.1  cgd 		       unit, rs->sc_ioc.c_cmd, rs->sc_ioc.c_addr,
1.1  cgd 		       bp->b_blkno, rs->sc_resid, rdtab[unit].b_errcnt);
1.1  cgd 	rdstats[unit].rdretries++;
1.1  cgd #endif
1.1  cgd 	rs->sc_flags &= ~RDF_SEEK;
1.1  cgd 	rdreset(rs, hp);
1.1  cgd 	if (rdtab[unit].b_errcnt++ < RDRETRY)
1.1  cgd 		goto again;
1.1  cgd 	printf("rd%d: rdstart err: cmd 0x%x sect %d blk %d len %d\n",
1.1  cgd 	       unit, rs->sc_ioc.c_cmd, rs->sc_ioc.c_addr,
1.1  cgd 	       bp->b_blkno, rs->sc_resid);
1.1  cgd 	rdtab[unit].b_errcnt = 0;
1.1  cgd 	rdtab[unit].b_actf = bp->b_actf;
1.1  cgd 	bp->b_flags |= B_ERROR;
1.1  cgd 	bp->b_error = EIO;
1.1  cgd 	bp->b_resid = 0;
1.1  cgd 	biodone(bp);
1.1  cgd 	hpibfree(&rs->sc_dq);
1.1  cgd 	bp = rdtab[unit].b_actf;
1.1  cgd 	if (bp == NULL) {
1.1  cgd 		rdtab[unit].b_active = 0;
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	rs->sc_addr = bp->b_un.b_addr;
1.1  cgd 	rs->sc_resid = bp->b_bcount;
1.1  cgd 	if (hpibreq(&rs->sc_dq))
1.1  cgd 		goto again;
1.1  cgd }
1.1  cgd
1.1  cgd rdgo(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct hp_device *hp = rs->sc_hd;
1.1  cgd 	struct buf *bp = rdtab[unit].b_actf;
1.1  cgd
1.1  cgd 	if (hp->hp_dk >= 0) {
1.1  cgd 		dk_busy |= 1 << hp->hp_dk;
1.1  cgd 		dk_xfer[hp->hp_dk]++;
1.1  cgd 		dk_wds[hp->hp_dk] += rs->sc_resid >> 6;
1.1  cgd 	}
1.1  cgd 	hpibgo(hp->hp_ctlr, hp->hp_slave, C_EXEC,
1.1  cgd 	       rs->sc_addr, rs->sc_resid, bp->b_flags & B_READ);
1.1  cgd }
1.1  cgd
1.1  cgd rdintr(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct buf *bp = rdtab[unit].b_actf;
1.1  cgd 	register struct hp_device *hp = rs->sc_hd;
1.1  cgd 	u_char stat = 13;	/* in case hpibrecv fails */
1.1  cgd 	int rv, restart;
1.1  cgd
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_FOLLOW)
1.1  cgd 		printf("rdintr(%d): bp %x, %c, flags %x\n", unit, bp,
1.1  cgd 		       (bp->b_flags & B_READ) ? 'R' : 'W', rs->sc_flags);
1.1  cgd 	if (bp == NULL) {
1.1  cgd 		printf("rd%d: bp == NULL\n", unit);
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd #endif
1.1  cgd 	if (hp->hp_dk >= 0)
1.1  cgd 		dk_busy &= ~(1 << hp->hp_dk);
1.1  cgd 	if (rs->sc_flags & RDF_SEEK) {
1.1  cgd 		rs->sc_flags &= ~RDF_SEEK;
1.1  cgd 		if (hpibustart(hp->hp_ctlr))
1.1  cgd 			rdgo(unit);
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	if ((rs->sc_flags & RDF_SWAIT) == 0) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		rdstats[unit].rdpolltries++;
1.1  cgd #endif
1.1  cgd 		if (hpibpptest(hp->hp_ctlr, hp->hp_slave) == 0) {
1.1  cgd #ifdef DEBUG
1.1  cgd 			rdstats[unit].rdpollwaits++;
1.1  cgd #endif
1.1  cgd 			if (hp->hp_dk >= 0)
1.1  cgd 				dk_busy |= 1 << hp->hp_dk;
1.1  cgd 			rs->sc_flags |= RDF_SWAIT;
1.1  cgd 			hpibawait(hp->hp_ctlr);
1.1  cgd 			return;
1.1  cgd 		}
1.1  cgd 	} else
1.1  cgd 		rs->sc_flags &= ~RDF_SWAIT;
1.1  cgd 	rv = hpibrecv(hp->hp_ctlr, hp->hp_slave, C_QSTAT, &stat, 1);
1.1  cgd 	if (rv != 1 || stat) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (rddebug & RDB_ERROR)
1.1  cgd 			printf("rdintr: recv failed or bad stat %d\n", stat);
1.1  cgd #endif
1.1  cgd 		restart = rderror(unit);
1.1  cgd #ifdef DEBUG
1.1  cgd 		rdstats[unit].rdretries++;
1.1  cgd #endif
1.1  cgd 		if (rdtab[unit].b_errcnt++ < RDRETRY) {
1.1  cgd 			if (restart)
1.1  cgd 				rdstart(unit);
1.1  cgd 			return;
1.1  cgd 		}
1.1  cgd 		bp->b_flags |= B_ERROR;
1.1  cgd 		bp->b_error = EIO;
1.1  cgd 	}
1.1  cgd 	rdtab[unit].b_errcnt = 0;
1.1  cgd 	rdtab[unit].b_actf = bp->b_actf;
1.1  cgd 	bp->b_resid = 0;
1.1  cgd 	biodone(bp);
1.1  cgd 	hpibfree(&rs->sc_dq);
1.1  cgd 	if (rdtab[unit].b_actf)
1.1  cgd 		rdustart(unit);
1.1  cgd 	else
1.1  cgd 		rdtab[unit].b_active = 0;
1.1  cgd }
1.1  cgd
1.1  cgd rdstatus(rs)
1.1  cgd 	register struct rd_softc *rs;
1.1  cgd {
1.1  cgd 	register int c, s;
1.1  cgd 	u_char stat;
1.1  cgd 	int rv;
1.1  cgd
1.1  cgd 	c = rs->sc_hd->hp_ctlr;
1.1  cgd 	s = rs->sc_hd->hp_slave;
1.1  cgd 	rs->sc_rsc.c_unit = C_SUNIT(rs->sc_punit);
1.1  cgd 	rs->sc_rsc.c_sram = C_SRAM;
1.1  cgd 	rs->sc_rsc.c_ram = C_RAM;
1.1  cgd 	rs->sc_rsc.c_cmd = C_STATUS;
1.1  cgd 	bzero((caddr_t)&rs->sc_stat, sizeof(rs->sc_stat));
1.1  cgd 	rv = hpibsend(c, s, C_CMD, &rs->sc_rsc, sizeof(rs->sc_rsc));
1.1  cgd 	if (rv != sizeof(rs->sc_rsc)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (rddebug & RDB_STATUS)
1.1  cgd 			printf("rdstatus: send C_CMD failed %d != %d\n",
1.1  cgd 			       rv, sizeof(rs->sc_rsc));
1.1  cgd #endif
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd 	rv = hpibrecv(c, s, C_EXEC, &rs->sc_stat, sizeof(rs->sc_stat));
1.1  cgd 	if (rv != sizeof(rs->sc_stat)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (rddebug & RDB_STATUS)
1.1  cgd 			printf("rdstatus: send C_EXEC failed %d != %d\n",
1.1  cgd 			       rv, sizeof(rs->sc_stat));
1.1  cgd #endif
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd 	rv = hpibrecv(c, s, C_QSTAT, &stat, 1);
1.1  cgd 	if (rv != 1 || stat) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (rddebug & RDB_STATUS)
1.1  cgd 			printf("rdstatus: recv failed %d or bad stat %d\n",
1.1  cgd 			       rv, stat);
1.1  cgd #endif
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd 	return(0);
1.1  cgd }
1.1  cgd
1.1  cgd /*
1.1  cgd  * Deal with errors.
1.1  cgd  * Returns 1 if request should be restarted,
1.1  cgd  * 0 if we should just quietly give up.
1.1  cgd  */
1.1  cgd rderror(unit)
1.1  cgd 	int unit;
1.1  cgd {
1.1  cgd 	struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct rd_stat *sp;
1.1  cgd 	struct buf *bp;
1.1  cgd 	daddr_t hwbn, pbn;
1.1  cgd
1.1  cgd 	if (rdstatus(rs)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		printf("rd%d: couldn't get status\n", unit);
1.1  cgd #endif
1.1  cgd 		rdreset(rs, rs->sc_hd);
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd 	sp = &rs->sc_stat;
1.1  cgd 	if (sp->c_fef & FEF_REXMT)
1.1  cgd 		return(1);
1.1  cgd 	if (sp->c_fef & FEF_PF) {
1.1  cgd 		rdreset(rs, rs->sc_hd);
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Unit requests release for internal maintenance.
1.1  cgd 	 * We just delay awhile and try again later.  Use expontially
1.1  cgd 	 * increasing backoff ala ethernet drivers since we don't really
1.1  cgd 	 * know how long the maintenance will take.  With RDWAITC and
1.1  cgd 	 * RDRETRY as defined, the range is 1 to 32 seconds.
1.1  cgd 	 */
1.1  cgd 	if (sp->c_fef & FEF_IMR) {
1.1  cgd 		extern int hz;
1.1  cgd 		int rdtimo = RDWAITC << rdtab[unit].b_errcnt;
1.1  cgd #ifdef DEBUG
1.1  cgd 		printf("rd%d: internal maintenance, %d second timeout\n",
1.1  cgd 		       unit, rdtimo);
1.1  cgd 		rdstats[unit].rdtimeouts++;
1.1  cgd #endif
1.1  cgd 		hpibfree(&rs->sc_dq);
1.1  cgd 		timeout(rdrestart, unit, rdtimo*hz);
1.1  cgd 		return(0);
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Only report error if we have reached the error reporting
1.1  cgd 	 * threshhold.  By default, this will only report after the
1.1  cgd 	 * retry limit has been exceeded.
1.1  cgd 	 */
1.1  cgd 	if (rdtab[unit].b_errcnt < rderrthresh)
1.1  cgd 		return(1);
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * First conjure up the block number at which the error occured.
1.1  cgd 	 * Note that not all errors report a block number, in that case
1.1  cgd 	 * we just use b_blkno.
1.1  cgd  	 */
1.1  cgd 	bp = rdtab[unit].b_actf;
1.1  cgd 	pbn = rs->sc_info->nbpc *
1.1  cgd 		rs->sc_info->sizes[rdpart(bp->b_dev)].cyloff;
1.1  cgd 	if ((sp->c_fef & FEF_CU) || (sp->c_fef & FEF_DR) ||
1.1  cgd 	    (sp->c_ief & IEF_RRMASK)) {
1.1  cgd 		hwbn = RDBTOS(pbn + bp->b_blkno);
1.1  cgd 		pbn = bp->b_blkno;
1.1  cgd 	} else {
1.1  cgd 		hwbn = sp->c_blk;
1.1  cgd 		pbn = RDSTOB(hwbn) - pbn;
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Now output a generic message suitable for badsect.
1.1  cgd 	 * Note that we don't use harderr cuz it just prints
1.1  cgd 	 * out b_blkno which is just the beginning block number
1.1  cgd 	 * of the transfer, not necessary where the error occured.
1.1  cgd 	 */
1.1  cgd 	printf("rd%d%c: hard error sn%d\n",
1.1  cgd 	       rdunit(bp->b_dev), 'a'+rdpart(bp->b_dev), pbn);
1.1  cgd 	/*
1.1  cgd 	 * Now report the status as returned by the hardware with
1.1  cgd 	 * attempt at interpretation (unless debugging).
1.1  cgd 	 */
1.1  cgd 	printf("rd%d %s error:",
1.1  cgd 	       unit, (bp->b_flags & B_READ) ? "read" : "write");
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_ERROR) {
1.1  cgd 		/* status info */
1.1  cgd 		printf("\n    volume: %d, unit: %d\n",
1.1  cgd 		       (sp->c_vu>>4)&0xF, sp->c_vu&0xF);
1.1  cgd 		rdprinterr("reject", sp->c_ref, err_reject);
1.1  cgd 		rdprinterr("fault", sp->c_fef, err_fault);
1.1  cgd 		rdprinterr("access", sp->c_aef, err_access);
1.1  cgd 		rdprinterr("info", sp->c_ief, err_info);
1.1  cgd 		printf("    block: %d, P1-P10: ", hwbn);
1.1  cgd 		printf("%s", hexstr(*(u_int *)&sp->c_raw[0], 8));
1.1  cgd 		printf("%s", hexstr(*(u_int *)&sp->c_raw[4], 8));
1.1  cgd 		printf("%s\n", hexstr(*(u_short *)&sp->c_raw[8], 4));
1.1  cgd 		/* command */
1.1  cgd 		printf("    ioc: ");
1.1  cgd 		printf("%s", hexstr(*(u_int *)&rs->sc_ioc.c_pad, 8));
1.1  cgd 		printf("%s", hexstr(*(u_short *)&rs->sc_ioc.c_hiaddr, 4));
1.1  cgd 		printf("%s", hexstr(*(u_int *)&rs->sc_ioc.c_addr, 8));
1.1  cgd 		printf("%s", hexstr(*(u_short *)&rs->sc_ioc.c_nop2, 4));
1.1  cgd 		printf("%s", hexstr(*(u_int *)&rs->sc_ioc.c_len, 8));
1.1  cgd 		printf("%s\n", hexstr(*(u_short *)&rs->sc_ioc.c_cmd, 4));
1.1  cgd 		return(1);
1.1  cgd 	}
1.1  cgd #endif
1.1  cgd 	printf(" v%d u%d, R0x%x F0x%x A0x%x I0x%x\n",
1.1  cgd 	       (sp->c_vu>>4)&0xF, sp->c_vu&0xF,
1.1  cgd 	       sp->c_ref, sp->c_fef, sp->c_aef, sp->c_ief);
1.1  cgd 	printf("P1-P10: ");
1.1  cgd 	printf("%s", hexstr(*(u_int *)&sp->c_raw[0], 8));
1.1  cgd 	printf("%s", hexstr(*(u_int *)&sp->c_raw[4], 8));
1.1  cgd 	printf("%s\n", hexstr(*(u_short *)&sp->c_raw[8], 4));
1.1  cgd 	return(1);
1.1  cgd }
1.1  cgd
1.1  cgd int
1.1  cgd rdread(dev, uio, flags)
1.1  cgd 	dev_t dev;
1.1  cgd 	struct uio *uio;
1.1  cgd 	int flags;
1.1  cgd {
1.1  cgd 	register int unit = rdunit(dev);
1.1  cgd
1.1  cgd 	return (physio(rdstrategy, NULL, dev, B_READ, minphys, uio));
1.1  cgd }
1.1  cgd
1.1  cgd int
1.1  cgd rdwrite(dev, uio, flags)
1.1  cgd 	dev_t dev;
1.1  cgd 	struct uio *uio;
1.1  cgd 	int flags;
1.1  cgd {
1.1  cgd 	register int unit = rdunit(dev);
1.1  cgd
1.1  cgd 	return (physio(rdstrategy, NULL, dev, B_WRITE, minphys, uio));
1.1  cgd }
1.1  cgd
1.1  cgd int
1.1  cgd rdioctl(dev, cmd, data, flag, p)
1.1  cgd 	dev_t dev;
1.1  cgd 	int cmd;
1.1  cgd 	caddr_t data;
1.1  cgd 	int flag;
1.1  cgd 	struct proc *p;
1.1  cgd {
1.1  cgd 	return(EINVAL);
1.1  cgd }
1.1  cgd
1.1  cgd int
1.1  cgd rdsize(dev)
1.1  cgd 	dev_t dev;
1.1  cgd {
1.1  cgd 	register int unit = rdunit(dev);
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd
1.1  cgd 	if (unit >= NRD || (rs->sc_flags & RDF_ALIVE) == 0)
1.1  cgd 		return(-1);
1.1  cgd 	return(rs->sc_info->sizes[rdpart(dev)].nblocks);
1.1  cgd }
1.1  cgd
1.1  cgd #ifdef DEBUG
1.1  cgd rdprinterr(str, err, tab)
1.1  cgd 	char *str;
1.1  cgd 	short err;
1.1  cgd 	char *tab[];
1.1  cgd {
1.1  cgd 	register int i;
1.1  cgd 	int printed;
1.1  cgd
1.1  cgd 	if (err == 0)
1.1  cgd 		return;
1.1  cgd 	printf("    %s error field:", str, err);
1.1  cgd 	printed = 0;
1.1  cgd 	for (i = 0; i < 16; i++)
1.1  cgd 		if (err & (0x8000 >> i))
1.1  cgd 			printf("%s%s", printed++ ? " + " : " ", tab[i]);
1.1  cgd 	printf("\n");
1.1  cgd }
1.1  cgd #endif
1.1  cgd
1.1  cgd /*
1.1  cgd  * Non-interrupt driven, non-dma dump routine.
1.1  cgd  */
1.1  cgd int
1.1  cgd rddump(dev)
1.1  cgd 	dev_t dev;
1.1  cgd {
1.1  cgd 	int part = rdpart(dev);
1.1  cgd 	int unit = rdunit(dev);
1.1  cgd 	register struct rd_softc *rs = &rd_softc[unit];
1.1  cgd 	register struct hp_device *hp = rs->sc_hd;
1.1  cgd 	register daddr_t baddr;
1.1  cgd 	register int maddr, pages, i;
1.1  cgd 	char stat;
1.1  cgd 	extern int lowram, dumpsize;
1.1  cgd #ifdef DEBUG
1.1  cgd 	extern int pmapdebug;
1.1  cgd 	pmapdebug = 0;
1.1  cgd #endif
1.1  cgd
1.1  cgd 	pages = dumpsize;
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_DUMP)
1.1  cgd 		printf("rddump(%x): u %d p %d dumplo %d ram %x pmem %d\n",
1.1  cgd 		       dev, unit, part, dumplo, lowram, ctod(pages));
1.1  cgd #endif
1.1  cgd 	/* is drive ok? */
1.1  cgd 	if (unit >= NRD || (rs->sc_flags & RDF_ALIVE) == 0)
1.1  cgd 		return (ENXIO);
1.1  cgd 	/* HPIB idle? */
1.1  cgd 	if (!hpibreq(&rs->sc_dq)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 		/* is this a safe thing to do?? */
1.1  cgd 		hpibreset(hp->hp_ctlr);
1.1  cgd 		rdreset(rs, rs->sc_hd);
1.1  cgd 		printf("[ drive %d reset ] ", unit);
1.1  cgd #else
1.1  cgd 		return (EFAULT);
1.1  cgd #endif
1.1  cgd 	}
1.1  cgd 	/* dump parameters in range? */
1.1  cgd 	if (dumplo < 0 || dumplo >= rs->sc_info->sizes[part].nblocks)
1.1  cgd 		return (EINVAL);
1.1  cgd 	if (dumplo + ctod(pages) > rs->sc_info->sizes[part].nblocks)
1.1  cgd 		pages = dtoc(rs->sc_info->sizes[part].nblocks - dumplo);
1.1  cgd 	maddr = lowram;
1.1  cgd 	baddr = dumplo + rs->sc_info->nbpc * rs->sc_info->sizes[part].cyloff;
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (rddebug & RDB_DUMP)
1.1  cgd 		printf("rddump: dumping %d pages from %x to disk block %d\n",
1.1  cgd 		       pages, maddr, baddr);
1.1  cgd #endif
1.1  cgd 	for (i = 0; i < pages; i++) {
1.1  cgd #ifdef DEBUG
1.1  cgd #define NPGMB	(1024*1024/NBPG)
1.1  cgd 		/* print out how many Mbs we have dumped */
1.1  cgd 		if (i && (i % NPGMB) == 0)
1.1  cgd 			printf("%d ", i / NPGMB);
1.1  cgd #undef NPBMG
1.1  cgd #endif
1.1  cgd 		rs->sc_ioc.c_unit = C_SUNIT(rs->sc_punit);
1.1  cgd 		rs->sc_ioc.c_volume = C_SVOL(0);
1.1  cgd 		rs->sc_ioc.c_saddr = C_SADDR;
1.1  cgd 		rs->sc_ioc.c_hiaddr = 0;
1.1  cgd 		rs->sc_ioc.c_addr = RDBTOS(baddr);
1.1  cgd 		rs->sc_ioc.c_nop2 = C_NOP;
1.1  cgd 		rs->sc_ioc.c_slen = C_SLEN;
1.1  cgd 		rs->sc_ioc.c_len = NBPG;
1.1  cgd 		rs->sc_ioc.c_cmd = C_WRITE;
1.1  cgd 		hpibsend(hp->hp_ctlr, hp->hp_slave, C_CMD,
1.1  cgd 			 &rs->sc_ioc.c_unit, sizeof(rs->sc_ioc)-2);
1.1  cgd 		if (hpibswait(hp->hp_ctlr, hp->hp_slave)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 			if (rddebug & RDB_DUMP)
1.1  cgd 				printf("rddump: IOC wait timeout\n");
1.1  cgd #endif
1.1  cgd 			return (EIO);
1.1  cgd 		}
1.1  cgd 		pmap_enter(pmap_kernel(), vmmap, maddr, VM_PROT_READ, TRUE);
1.1  cgd 		hpibsend(hp->hp_ctlr, hp->hp_slave, C_EXEC, vmmap, NBPG);
1.1  cgd 		if (hpibswait(hp->hp_ctlr, hp->hp_slave)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 			if (rddebug & RDB_DUMP)
1.1  cgd 				printf("rddump: write wait timeout\n");
1.1  cgd #endif
1.1  cgd 		}
1.1  cgd 		hpibrecv(hp->hp_ctlr, hp->hp_slave, C_QSTAT, &stat, 1);
1.1  cgd 		if (stat) {
1.1  cgd #ifdef DEBUG
1.1  cgd 			if (rddebug & RDB_DUMP)
1.1  cgd 				printf("rddump: write failed, status %x\n",
1.1  cgd 				       stat);
1.1  cgd #endif
1.1  cgd 			return (EIO);
1.1  cgd 		}
1.1  cgd 		maddr += NBPG;
1.1  cgd 		baddr += ctod(1);
1.1  cgd 	}
1.1  cgd 	return (0);
1.1  cgd }
1.1  cgd #endif