4.4BSD/usr/src/sys/pmax/dev/if_lereg.h
/*-
* Copyright (c) 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Ralph Campbell and Rick Macklem.
*
* 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.
*
* @(#)if_lereg.h 8.1 (Berkeley) 6/10/93
*/
#define LEMTU 1518
#define LEBLEN 1520 /* LEMTU up to a multiple of 16 */
#define LEMINSIZE 60 /* should be 64 if mode DTCR is set */
#define LERBUF 32
#define LERBUFLOG2 5
#define LE_RLEN (LERBUFLOG2 << 13)
#define LETBUF 8
#define LETBUFLOG2 3
#define LE_TLEN (LETBUFLOG2 << 13)
/*
* LANCE registers.
*/
struct lereg1 {
u_short ler1_rdp; /* data port */
short pad0;
u_short ler1_rap; /* register select port */
short pad1;
};
/*
* This structure is overlayed on the network dual-port RAM.
* Currently 32 * 1520 receive plus 8 * 1520 transmit buffers plus
* buffer descriptor rings.
* There are two variants of the structure, one for the Pmax/3min/maxine
* with 2 byte pads between entries and one for the 3max and turbochannel
* option densely packed.
*/
struct lermd { /* +0x0020 */
u_short rmd0;
u_short rmd1;
short rmd2;
u_short rmd3;
};
struct letmd { /* +0x0058 */
u_short tmd0;
u_short tmd1;
short tmd2;
u_short tmd3;
};
struct lermdpad { /* +0x0020 */
u_short rmd0;
short pad0;
u_short rmd1;
short pad1;
short rmd2;
short pad2;
u_short rmd3;
short pad3;
};
struct letmdpad { /* +0x0058 */
u_short tmd0;
short pad0;
u_short tmd1;
short pad1;
short tmd2;
short pad2;
u_short tmd3;
short pad3;
};
struct lereg2 {
/* init block */ /* CHIP address */
u_short ler2_mode; /* +0x0000 */
u_short ler2_padr0; /* +0x0002 */
u_short ler2_padr1; /* +0x0004 */
u_short ler2_padr2; /* +0x0006 */
u_short ler2_ladrf0; /* +0x0008 */
u_short ler2_ladrf1; /* +0x000A */
u_short ler2_ladrf2; /* +0x000C */
u_short ler2_ladrf3; /* +0x000E */
u_short ler2_rdra; /* +0x0010 */
u_short ler2_rlen; /* +0x0012 */
u_short ler2_tdra; /* +0x0014 */
u_short ler2_tlen; /* +0x0016 */
short pad0[4]; /* Pad to 16 shorts */
/* receive message descriptors */
struct lermd ler2_rmd[LERBUF];
/* transmit message descriptors */
struct letmd ler2_tmd[LETBUF];
char ler2_rbuf[LERBUF][LEBLEN]; /* +0x0060 */
char ler2_tbuf[LETBUF][LEBLEN]; /* +0x2FD0 */
};
struct lereg2pad {
/* init block */ /* CHIP address */
u_short ler2_mode; /* +0x0000 */
short pad0;
u_short ler2_padr0; /* +0x0002 */
short pad1;
u_short ler2_padr1; /* +0x0004 */
short pad2;
u_short ler2_padr2; /* +0x0006 */
short pad3;
u_short ler2_ladrf0; /* +0x0008 */
short pad4;
u_short ler2_ladrf1; /* +0x000A */
short pad5;
u_short ler2_ladrf2; /* +0x000C */
short pad6;
u_short ler2_ladrf3; /* +0x000E */
short pad7;
u_short ler2_rdra; /* +0x0010 */
short pad8;
u_short ler2_rlen; /* +0x0012 */
short pad9;
u_short ler2_tdra; /* +0x0014 */
short pad10;
u_short ler2_tlen; /* +0x0016 */
short pad11[9]; /* Pad to 32 shorts */
/* receive message descriptors */
struct lermdpad ler2_rmd[LERBUF];
/* transmit message descriptors */
struct letmdpad ler2_tmd[LETBUF];
short ler2_rbuf[LERBUF][LEBLEN]; /* +0x0060 */
short ler2_tbuf[LETBUF][LEBLEN]; /* +0x2FD0 */
};
/*
* Now for some truly ugly macros to access the structure fields
* padded/non-padded at runtime. (For once, a Pascal like record variant
* would be nice to have.)
*/
#define LER2_RMDADDR(p, i) \
(le->sc_ler2pad ? \
(volatile void *)&(((struct lereg2pad *)(p))->ler2_rmd[(i)]) : \
(volatile void *)&(((struct lereg2 *)(p))->ler2_rmd[(i)]))
#define LER2_TMDADDR(p, i) \
((le->sc_ler2pad ? \
(volatile void *)&(((struct lereg2pad *)(p))->ler2_tmd[(i)]) : \
(volatile void *)&(((struct lereg2 *)(p))->ler2_tmd[(i)])))
#define LER2_RBUFADDR(p, i) \
((le->sc_ler2pad ? \
(volatile void *)(((struct lereg2pad *)(p))->ler2_rbuf[(i)]) : \
(volatile void *)(((struct lereg2 *)(p))->ler2_rbuf[(i)])))
#define LER2_TBUFADDR(p, i) \
((le->sc_ler2pad ? \
(volatile void *)(((struct lereg2pad *)(p))->ler2_tbuf[(i)]) : \
(volatile void *)(((struct lereg2 *)(p))->ler2_tbuf[(i)])))
#define LER2_mode(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_mode = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_mode = (v)))
#define LER2V_mode(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_mode : \
((volatile struct lereg2 *)(p))->ler2_mode)
#define LER2_padr0(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_padr0 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_padr0 = (v)))
#define LER2V_padr0(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_padr0 : \
((volatile struct lereg2 *)(p))->ler2_padr0)
#define LER2_padr1(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_padr1 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_padr1 = (v)))
#define LER2V_padr1(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_padr1 : \
((volatile struct lereg2 *)(p))->ler2_padr1)
#define LER2_padr2(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_padr2 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_padr2 = (v)))
#define LER2V_padr2(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_padr2 : \
((volatile struct lereg2 *)(p))->ler2_padr2)
#define LER2_ladrf0(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_ladrf0 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_ladrf0 = (v)))
#define LER2V_ladrf0(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_ladrf0 : \
((volatile struct lereg2 *)(p))->ler2_ladrf0)
#define LER2_ladrf1(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_ladrf1 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_ladrf1 = (v)))
#define LER2V_ladrf1(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_ladrf1 : \
((volatile struct lereg2 *)(p))->ler2_ladrf1)
#define LER2_ladrf2(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_ladrf2 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_ladrf2 = (v)))
#define LER2V_ladrf2(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_ladrf2 : \
((volatile struct lereg2 *)(p))->ler2_ladrf2)
#define LER2_ladrf3(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_ladrf3 = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_ladrf3 = (v)))
#define LER2V_ladrf3(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_ladrf3 : \
((volatile struct lereg2 *)(p))->ler2_ladrf3)
#define LER2_rdra(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_rdra = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_rdra = (v)))
#define LER2V_rdra(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_rdra : \
((volatile struct lereg2 *)(p))->ler2_rdra)
#define LER2_rlen(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_rlen = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_rlen = (v)))
#define LER2V_rlen(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_rlen : \
((volatile struct lereg2 *)(p))->ler2_rlen)
#define LER2_tdra(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_tdra = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_tdra = (v)))
#define LER2V_tdra(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_tdra : \
((volatile struct lereg2 *)(p))->ler2_tdra)
#define LER2_tlen(p, v) \
(le->sc_ler2pad ? (((volatile struct lereg2pad *)(p))->ler2_tlen = (v)) : \
(((volatile struct lereg2 *)(p))->ler2_tlen = (v)))
#define LER2V_tlen(p) \
(le->sc_ler2pad ? ((volatile struct lereg2pad *)(p))->ler2_tlen : \
((volatile struct lereg2 *)(p))->ler2_tlen)
#define LER2_rmd0(p, v) \
(le->sc_ler2pad ? (((volatile struct lermdpad *)(p))->rmd0 = (v)) : \
((((volatile struct lermd *)(p))->rmd0 = (v))))
#define LER2V_rmd0(p) \
(le->sc_ler2pad ? ((volatile struct lermdpad *)(p))->rmd0 : \
((volatile struct lermd *)(p))->rmd0)
#define LER2_rmd1(p, v) \
(le->sc_ler2pad ? (((volatile struct lermdpad *)(p))->rmd1 = (v)) : \
(((volatile struct lermd *)(p))->rmd1 = (v)))
#define LER2V_rmd1(p) \
(le->sc_ler2pad ? ((volatile struct lermdpad *)(p))->rmd1 : \
((volatile struct lermd *)(p))->rmd1)
#define LER2_rmd2(p, v) \
(le->sc_ler2pad ? (((volatile struct lermdpad *)(p))->rmd2 = (v)) : \
(((volatile struct lermd *)(p))->rmd2 = (v)))
#define LER2V_rmd2(p) \
(le->sc_ler2pad ? ((volatile struct lermdpad *)(p))->rmd2 : \
((volatile struct lermd *)(p))->rmd2)
#define LER2_rmd3(p, v) \
(le->sc_ler2pad ? (((volatile struct lermdpad *)(p))->rmd3 = (v)) : \
(((volatile struct lermd *)(p))->rmd3 = (v)))
#define LER2V_rmd3(p) \
(le->sc_ler2pad ? ((volatile struct lermdpad *)(p))->rmd3 : \
((volatile struct lermd *)(p))->rmd3)
#define LER2_tmd0(p, v) \
(le->sc_ler2pad ? (((volatile struct letmdpad *)(p))->tmd0 = (v)) : \
(((volatile struct letmd *)(p))->tmd0 = (v)))
#define LER2V_tmd0(p) \
(le->sc_ler2pad ? ((volatile struct letmdpad *)(p))->tmd0 : \
((volatile struct letmd *)(p))->tmd0)
#define LER2_tmd1(p, v) \
(le->sc_ler2pad ? (((volatile struct letmdpad *)(p))->tmd1 = (v)) : \
(((volatile struct letmd *)(p))->tmd1 = (v)))
#define LER2V_tmd1(p) \
(le->sc_ler2pad ? ((volatile struct letmdpad *)(p))->tmd1 : \
((volatile struct letmd *)(p))->tmd1)
#define LER2_tmd2(p, v) \
(le->sc_ler2pad ? (((volatile struct letmdpad *)(p))->tmd2 = (v)) : \
(((volatile struct letmd *)(p))->tmd2 = (v)))
#define LER2V_tmd2(p) \
(le->sc_ler2pad ? ((volatile struct letmdpad *)(p))->tmd2 : \
((volatile struct letmd *)(p))->tmd2)
#define LER2_tmd3(p, v) \
(le->sc_ler2pad ? (((volatile struct letmdpad *)(p))->tmd3 = (v)) : \
(((volatile struct letmd *)(p))->tmd3 = (v)))
#define LER2V_tmd3(p) \
(le->sc_ler2pad ? ((volatile struct letmdpad *)(p))->tmd3 : \
((volatile struct letmd *)(p))->tmd3)
/*
* Control and status bits -- lereg0
*/
#define LE_IE 0x80 /* interrupt enable */
#define LE_IR 0x40 /* interrupt requested */
#define LE_LOCK 0x08 /* lock status register */
#define LE_ACK 0x04 /* ack of lock */
#define LE_JAB 0x02 /* loss of tx clock (???) */
#define LE_IPL(x) ((((x) >> 4) & 0x3) + 3)
/*
* Control and status bits -- lereg1
*/
#define LE_CSR0 0
#define LE_CSR1 1
#define LE_CSR2 2
#define LE_CSR3 3
#define LE_SERR 0x8000
#define LE_BABL 0x4000
#define LE_CERR 0x2000
#define LE_MISS 0x1000
#define LE_MERR 0x0800
#define LE_RINT 0x0400
#define LE_TINT 0x0200
#define LE_IDON 0x0100
#define LE_INTR 0x0080
#define LE_INEA 0x0040
#define LE_RXON 0x0020
#define LE_TXON 0x0010
#define LE_TDMD 0x0008
#define LE_STOP 0x0004
#define LE_STRT 0x0002
#define LE_INIT 0x0001
#define LE_BSWP 0x4
#define LE_MODE 0x0
/*
* Control and status bits -- lereg2
*/
#define LE_OWN 0x8000
#define LE_ERR 0x4000
#define LE_STP 0x0200
#define LE_ENP 0x0100
#define LE_FRAM 0x2000
#define LE_OFLO 0x1000
#define LE_CRC 0x0800
#define LE_RBUFF 0x0400
#define LE_MORE 0x1000
#define LE_ONE 0x0800
#define LE_DEF 0x0400
#define LE_TBUFF 0x8000
#define LE_UFLO 0x4000
#define LE_LCOL 0x1000
#define LE_LCAR 0x0800
#define LE_RTRY 0x0400