stand/boot2440/dm9000.c

1.2  nisimura /* $NetBSD: dm9000.c,v 1.2 2012/02/23 22:20:51 nisimura Exp $ */
1.1  nisimura
1.1  nisimura /*-
1.1  nisimura  * Copyright (c) 2012 The NetBSD Foundation, Inc.
1.1  nisimura  * All rights reserved.
1.1  nisimura  *
1.1  nisimura  * This code is derived from software contributed to The NetBSD Foundation
1.1  nisimura  * by Tohru Nishimura.
1.1  nisimura  *
1.1  nisimura  * Redistribution and use in source and binary forms, with or without
1.1  nisimura  * modification, are permitted provided that the following conditions
1.1  nisimura  * are met:
1.1  nisimura  * 1. Redistributions of source code must retain the above copyright
1.1  nisimura  *    notice, this list of conditions and the following disclaimer.
1.1  nisimura  * 2. Redistributions in binary form must reproduce the above copyright
1.1  nisimura  *    notice, this list of conditions and the following disclaimer in the
1.1  nisimura  *    documentation and/or other materials provided with the distribution.
1.1  nisimura  *
1.1  nisimura  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  nisimura  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  nisimura  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  nisimura  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  nisimura  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  nisimura  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  nisimura  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  nisimura  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  nisimura  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  nisimura  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  nisimura  * POSSIBILITY OF SUCH DAMAGE.
1.1  nisimura  */
1.1  nisimura
1.1  nisimura #include <sys/param.h>
1.1  nisimura #include <netinet/in.h>
1.1  nisimura #include <netinet/in_systm.h>
1.1  nisimura
1.1  nisimura #include <lib/libsa/stand.h>
1.1  nisimura #include <lib/libsa/net.h>
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * This DM9000 is wired as a 16bit device and manages Tx/Rx SRAM buffer
1.1  nisimura  * in 16bit quantity.  MRCMD/MWCMD access increments buffer pointer
1.1  nisimura  * by two regardless of r/w size.  Mixing 16/8bit access is not possible.
1.1  nisimura  * Byte read would end up with loosing every odd indexed datum.
1.1  nisimura  *
1.1  nisimura  * The DM9000 CMD pin is tied with SoC LADDR2 address line.  SA9-SA4
1.1  nisimura  * pins are hardwired to fixed decoding 0x300.  Thus address [26:3] in
1.1  nisimura  * CS4 range 0x2000'0000 are don't-care bits to manipulate the chip.
1.1  nisimura  * The DM9000 INDEX port is accessed at the address b'000 while the
1.1  nisimura  * DATA port at the address b'100.
1.1  nisimura  *
1.1  nisimura  * This code assumes Little endian CPU.
1.1  nisimura  */
1.1  nisimura
1.1  nisimura #define NCR	0x00		/* control */
1.1  nisimura #define  NCR_FDX	(1<<3)	/* FDX link detection report */
1.1  nisimura #define  NCR_RST	(1<<0)	/* instruct reset, goes 0 at done */
1.1  nisimura #define NSR	0x01		/* status */
1.1  nisimura #define  NSR_SPEED	(1<<7)	/* 1->100M, 0->10M, when link is up */
1.1  nisimura #define  NSR_LINKST	(1<<6)	/* 1->linkup, 0->linkdown */
1.1  nisimura #define  NSR_TX2END	(1<<3)	/* Tx frame #2 completed */
1.1  nisimura #define  NSR_TX1END	(1<<2)	/* Tx frame #1 completed */
1.1  nisimura #define  NSR_RXOV	(1<<1)	/* Rx FIFO overflow detected */
1.1  nisimura #define TCR	0x02		/* Tx control */
1.1  nisimura #define  TCR_TXREQ	0x01	/* request to start transmit, goes 0 at done */
1.1  nisimura #define TCR2	0x2d		/* Tx control #2 */
1.1  nisimura #define  TCR2_ONEPM	0x10	/* send single Tx frame at a time */
1.1  nisimura #define RCR	0x05		/* Rx control */
1.1  nisimura #define  RCR_WTDIS	0x40	/* disable frame receipt watchdog timer */
1.1  nisimura #define  RCR_DIS_LONG	0x20	/* discard too-long Rx frame */
1.1  nisimura #define  RCR_DIS_CRC	0x10	/* discard CRC error Rx frame */
1.1  nisimura #define  RCR_ALL	0x08	/* accept MCAST frames */
1.1  nisimura #define  RCR_RUNT	0x04	/* accept runt Rx frame */
1.1  nisimura #define  RCR_PRMSC	0x02	/* promiscous */
1.1  nisimura #define  RCR_RXEN	0x01	/* enable frame reception */
1.1  nisimura #define RSR	0x06		/* RX status */
1.1  nisimura #define  RSR_MF		(1<<6)	/* bcast/mcast frame found */
1.1  nisimura #define FCR	0x0a		/* flow control */
1.1  nisimura #define  FCR_FLCE	0x01	/* enable Tx/Rx flow control */
1.1  nisimura #define EPCR	0x0b		/* EEPROM and PHY control */
1.1  nisimura #define  EP_EPOS	(1<<3)	/* 1 for PHY op, 0 for EEPROM op */
1.1  nisimura #define  EP_ERPRR	(1<<2)	/* instruct to start read op */
1.1  nisimura #define  EP_ERPRW	(1<<1)	/* instruct to start write op */
1.1  nisimura #define  EP_ERRE	(1<<0)	/* 1 while operation is in progress */
1.1  nisimura #define EPAR	0x0c		/* [7:6] for PHY#, [5:0] for addr */
1.1  nisimura #define EPDRL	0x0d		/* EEPROM/PHY data low byte */
1.1  nisimura #define EPDRH	0x0e		/* EEPROM/PHY data high byte */
1.1  nisimura #define PAR	0x10		/* station address */
1.1  nisimura #define MAR	0x16		/* multicast filter hash value */
1.1  nisimura #define GPR	0x1f		/* gpio control */
1.1  nisimura #define  GPR_PHYPWROFF	0x01	/* powerdown internal PHY */
1.1  nisimura #define VID0	0x28		/* vendor ID low byte */
1.1  nisimura #define VID1	0x29		/* vendor ID high byte */
1.1  nisimura #define PID0	0x2a		/* product ID low byte */
1.1  nisimura #define PID1	0x2b		/* product ID high byte */
1.1  nisimura #define CHIPR	0x2c		/* chip revision */
1.1  nisimura #define MRCMDX	0xf0		/* read data w/o pointer incr */
1.1  nisimura #define MRCMD	0xf2		/* read data with pointer auto incr */
1.1  nisimura #define MWCMD	0xf8		/* write data with pointer auto incr */
1.1  nisimura #define TXPLL	0xfc		/* Tx frame length low byte */
1.1  nisimura #define TXPLH	0xfd		/* Tx frame length high byte */
1.1  nisimura #define ISR	0xfe		/* interrupt status report */
1.1  nisimura #define  ISR_LNKCHG	0x20	/* link status change detected */
1.1  nisimura #define  ISR_UDRUN	0x10	/* transmit underrun detected */
1.1  nisimura #define  ISR_PTM	(1<<1)	/* frame Tx completed */
1.1  nisimura #define  ISR_PRS	(1<<0)	/* frame Rx completed */
1.1  nisimura #define IMR	0xff		/* interrupt mask */
1.1  nisimura #define  IMR_PAR	(1<<7)	/* use 3/13K SRAM partitioning with autowrap */
1.1  nisimura #define  IMR_PRM	(1<<0)	/* post interrupt when Rx completed */
1.1  nisimura
1.1  nisimura #ifndef DM9000MAC
1.1  nisimura #define DM9000MAC 0x08,0x08,0x11,0x18,0x12,0x27
1.1  nisimura #endif
1.1  nisimura
1.1  nisimura struct local {
1.1  nisimura 	unsigned int csr;
1.1  nisimura 	unsigned int phy, bmsr, anlpar;
1.1  nisimura 	uint8_t en[6];
1.1  nisimura };
1.1  nisimura
1.1  nisimura static struct local dm9000local;
1.1  nisimura
1.1  nisimura int dm9k_match(unsigned int, void *);
1.1  nisimura void *dm9k_init(unsigned int, void *);
1.1  nisimura int dm9k_send(void *, char *, unsigned int);
1.1  nisimura int dm9k_recv(void *, char *, unsigned int, unsigned int);
1.1  nisimura
1.1  nisimura static unsigned mii_read(struct local *, int, int);
1.1  nisimura static void mii_write(struct local *, int, int, int);
1.1  nisimura static void mii_dealan(struct local *, unsigned int);
1.1  nisimura
1.1  nisimura extern void usleep(int);
1.1  nisimura
1.1  nisimura static inline int
1.1  nisimura CSR_READ_1(struct local *l, int reg)
1.1  nisimura {
1.1  nisimura 	*(volatile uint8_t *)(l->csr) = reg;
1.1  nisimura 	return *(volatile uint8_t*)(l->csr + 4);
1.1  nisimura }
1.1  nisimura
1.1  nisimura static inline int
1.1  nisimura CSR_READ_2(struct local *l, int reg)
1.1  nisimura {
1.1  nisimura 	*(volatile uint8_t *)(l->csr) = reg;
1.1  nisimura 	return *(volatile uint16_t *)(l->csr + 4);
1.1  nisimura }
1.1  nisimura
1.1  nisimura static inline void
1.1  nisimura CSR_WRITE_1(struct local *l, int reg, int data)
1.1  nisimura {
1.1  nisimura 	*(volatile uint8_t *)(l->csr) = reg;
1.1  nisimura 	*(volatile uint8_t *)(l->csr + 4) = data;
1.1  nisimura }
1.1  nisimura
1.1  nisimura static inline void
1.1  nisimura CSR_WRITE_2(struct local *l, int reg, int data)
1.1  nisimura {
1.1  nisimura 	*(volatile uint8_t *)(l->csr) = reg;
1.1  nisimura 	*(volatile uint16_t *)(l->csr + 4) = data;
1.1  nisimura }
1.1  nisimura
1.1  nisimura int
1.1  nisimura dm9k_match(unsigned int tag, void *aux)
1.1  nisimura {
1.1  nisimura 	struct local *l = &dm9000local;
1.1  nisimura 	uint8_t *en = aux;
1.1  nisimura 	uint8_t std[6] = { DM9000MAC };
1.1  nisimura 	int val;
1.1  nisimura
1.1  nisimura 	l->csr = 0x20000000;
1.1  nisimura 	val =  CSR_READ_1(l, PID0);
1.1  nisimura 	val |= CSR_READ_1(l, PID1) << 8;
1.1  nisimura 	val |= CSR_READ_1(l, VID0) << 16;
1.1  nisimura 	val |= CSR_READ_1(l, VID1) << 24;
1.1  nisimura 	if (val != 0x0a469000) {
1.1  nisimura 		printf("DM9000 not found at 0x%x\n", l->csr);
1.1  nisimura 		return 0;
1.1  nisimura 	}
1.1  nisimura 	if (en != NULL
1.1  nisimura 	    && en[0] && en[1] && en[2] && en[3] && en[4] && en[5])
1.1  nisimura 		memcpy(l->en, en, 6);
1.1  nisimura 	else if (en != NULL) {
1.1  nisimura 		memcpy(en, std, 6);
1.1  nisimura 		memcpy(l->en, std, 6);
1.1  nisimura 	}
1.1  nisimura 	return 1;
1.1  nisimura }
1.1  nisimura
1.1  nisimura void *
1.1  nisimura dm9k_init(unsigned int tag, void *aux)
1.1  nisimura {
1.1  nisimura 	struct local *l = &dm9000local;
1.1  nisimura 	uint8_t *en = l->en;
1.1  nisimura 	unsigned int val, fdx;
1.1  nisimura
1.1  nisimura 	val = CSR_READ_1(l, CHIPR);
1.1  nisimura 	printf("DM9000 rev. 0x%d", val);
1.1  nisimura 	val = CSR_READ_1(l, ISR);
1.1  nisimura 	printf(", %d bit mode\n", (val & 1<<7) ? 8 : 16);
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, NCR, 0);	/* use internal PHY */
1.1  nisimura 	l->phy = 1;
1.1  nisimura
1.1  nisimura 	/* force PHY poweroff */
1.1  nisimura 	CSR_WRITE_1(l, GPR, GPR_PHYPWROFF);
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, IMR, 0);
1.1  nisimura 	CSR_WRITE_1(l, TCR, 0);
1.1  nisimura 	CSR_WRITE_1(l, RCR, 0);
1.1  nisimura
1.1  nisimura 	/* SW reset */
1.1  nisimura 	CSR_WRITE_1(l, NCR, NCR_RST);
1.1  nisimura 	do {
1.1  nisimura 		usleep(1);
1.1  nisimura 	} while (NCR_RST & CSR_READ_1(l, NCR));
1.1  nisimura
1.1  nisimura 	/* negate PHY poweroff condition */
1.1  nisimura 	CSR_WRITE_1(l, GPR, 0);
1.1  nisimura
1.1  nisimura 	/* SW reset, again */
1.1  nisimura 	CSR_WRITE_1(l, NCR, NCR_RST);
1.1  nisimura 	do {
1.1  nisimura 		usleep(1);
1.1  nisimura 	} while (NCR_RST & CSR_READ_1(l, NCR));
1.1  nisimura
1.1  nisimura 	/* clear NSR bits */
1.1  nisimura 	(void) CSR_READ_1(l, NSR);
1.1  nisimura
1.1  nisimura 	printf("MAC address %02x:%02x:%02x:%02x:%02x:%02x\n",
1.1  nisimura 	       en[0], en[1], en[2], en[3], en[4], en[5]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 0, en[0]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 1, en[1]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 2, en[2]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 3, en[3]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 4, en[4]);
1.1  nisimura 	CSR_WRITE_1(l, PAR + 5, en[5]);
1.1  nisimura
1.1  nisimura 	/* make sure not to receive bcast/mcast frames */
1.1  nisimura 	CSR_WRITE_1(l, MAR + 0, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 1, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 2, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 3, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 4, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 5, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 6, 0);
1.1  nisimura 	CSR_WRITE_1(l, MAR + 7, 0);
1.1  nisimura
1.1  nisimura 	/* perform link auto-negotiation */
1.1  nisimura 	printf("waiting for linkup ... ");
1.1  nisimura 	mii_dealan(l, 5);
1.1  nisimura
1.1  nisimura 	val = CSR_READ_1(l, NSR);
1.1  nisimura 	if ((val & NSR_LINKST) == 0) {
1.1  nisimura 		printf("failed; cable problem?\n");
1.1  nisimura 		return NULL;
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * speed and duplexity can be seen in MII 17.
1.1  nisimura 	 *  bit15 100Mbps-FDX
1.1  nisimura 	 *  bit14 100Mbps
1.1  nisimura 	 *  bit13 10Mbps-FDX
1.1  nisimura 	 *  bit12 10Mbps
1.1  nisimura 	 * also available in NSR[SPEED] and NCR[FDX] respectively.
1.1  nisimura 	 */
1.1  nisimura 	val = mii_read(l, l->phy, 17);
1.1  nisimura 	if (val & (03 << 14))
1.1  nisimura 		printf("100Mbps");
1.1  nisimura 	if (val & (03 << 12))
1.1  nisimura 		printf("10Mbps");
1.1  nisimura 	fdx = !!(val & (05 << 13));
1.1  nisimura 	if (fdx) {
1.1  nisimura 		printf("-FDX");
1.1  nisimura 		val = CSR_READ_1(l, FCR);
1.1  nisimura 		CSR_WRITE_1(l, FCR, val | FCR_FLCE);
1.1  nisimura 	}
1.1  nisimura 	printf("\n");
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, NSR, ~0);
1.1  nisimura 	CSR_WRITE_1(l, ISR, ~0);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * - send one frame at a time.
1.1  nisimura 	 * - disable Rx watchdog timer, discard too-long/CRC error frames.
1.1  nisimura 	 * - 3/13K SRAM partitioning, r/w pointer autowrap.
1.1  nisimura 	 */
1.1  nisimura 	CSR_WRITE_1(l, TCR2, TCR2_ONEPM);
1.1  nisimura 	CSR_WRITE_1(l, RCR, RCR_RXEN | RCR_WTDIS | RCR_DIS_LONG | RCR_DIS_CRC);
1.1  nisimura 	CSR_WRITE_1(l, IMR, IMR_PAR);
1.1  nisimura
1.1  nisimura 	memcpy(aux, l->en, 6);
1.1  nisimura 	return l;
1.1  nisimura }
1.1  nisimura
1.1  nisimura int
1.1  nisimura dm9k_send(void *dev, char *buf, unsigned int len)
1.1  nisimura {
1.1  nisimura 	struct local *l = dev;
1.1  nisimura 	unsigned int val, cnt, bound;
1.1  nisimura
1.1  nisimura 	if (len > 1520) {
1.1  nisimura 		printf("dm9k_send: len > 1520 (%u)\n", len);
1.1  nisimura 		len = 1520;
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, ISR, ISR_PTM); /* clear ISR Tx complete bit */
1.1  nisimura 	for (cnt = 0; cnt < len; cnt += 2) {
1.1  nisimura 		val = (buf[1] << 8) | buf[0];
1.1  nisimura 		CSR_WRITE_2(l, MWCMD, val);
1.1  nisimura 		buf += 2;
1.1  nisimura 	}
1.1  nisimura 	CSR_WRITE_1(l, TXPLL, len);
1.1  nisimura 	CSR_WRITE_1(l, TXPLH, len >> 8);
1.1  nisimura 	CSR_WRITE_1(l, TCR, TCR_TXREQ);	/* request to transmit */
1.1  nisimura
1.1  nisimura 	bound = getsecs() + 1;
1.1  nisimura 	do {
1.1  nisimura 		val = CSR_READ_1(l, TCR);
1.1  nisimura 		if ((val & TCR_TXREQ) == 0)
1.1  nisimura 			goto done;
1.1  nisimura 	} while (getsecs() < bound);
1.1  nisimura 	printf("xmit failed\n");
1.1  nisimura 	return -1;
1.1  nisimura   done:
1.1  nisimura 	return len;
1.1  nisimura }
1.1  nisimura
1.1  nisimura int
1.1  nisimura dm9k_recv(void *dev, char *buf, unsigned int maxlen, unsigned int timo)
1.1  nisimura {
1.1  nisimura 	struct local *l = dev;
1.1  nisimura 	unsigned int bound, val, mark, stat, len, upto, cnt;
1.1  nisimura 	char *ptr;
1.1  nisimura
1.1  nisimura 	bound = getsecs() + timo; /* second */
1.1  nisimura   again:
1.1  nisimura 	do {
1.1  nisimura 		/* wait for Rx completion */
1.1  nisimura 		val = CSR_READ_1(l, ISR);
1.1  nisimura 		if (val & ISR_PRS)
1.1  nisimura 			goto gotone;
1.1  nisimura 		/* usleep(10); this makes a stuck in mid transfer */
1.1  nisimura 	} while (getsecs() < bound);
1.1  nisimura 	printf("receive timeout (%d seconds wait)\n", timo);
1.1  nisimura 	errno = 0;
1.1  nisimura 	return -1;
1.1  nisimura   gotone:
1.1  nisimura 	CSR_WRITE_1(l, ISR, ISR_PRS); /* clear ISR Rx complete bit */
1.1  nisimura 	(void) CSR_READ_2(l, MRCMDX); /* dummy read */
1.2  nisimura 	mark = CSR_READ_2(l, MRCMDX); /* mark in [7:0] */
1.1  nisimura 	if ((mark & 03) != 01) {
1.1  nisimura 		stat = CSR_READ_1(l, RSR);
1.1  nisimura 		printf("dm9k_recv: mark %x, RSR %x\n", mark, stat);
1.1  nisimura 		/* XXX got hosed, need full scale reinitialise XXX */
1.1  nisimura 		goto again;
1.1  nisimura 	}
1.1  nisimura
1.2  nisimura 	stat = CSR_READ_2(l, MRCMD); /* stat in [15:8] */
1.1  nisimura 	len  = CSR_READ_2(l, MRCMD);
1.1  nisimura
1.1  nisimura 	/* should not happen, make sure to discard bcast/mcast frames */
1.1  nisimura 	if (stat & (RSR_MF<<8)) {
1.1  nisimura 		for (cnt = 0; cnt < len; cnt += 2)
1.1  nisimura 			(void) CSR_READ_2(l, MRCMD);
1.1  nisimura 		printf("bcast/mcast frame, len = %d\n", len);
1.1  nisimura 		goto again;
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	upto = len - 4;	/* HASFCS */
1.1  nisimura 	if (upto > maxlen)
1.1  nisimura 		upto = maxlen;
1.1  nisimura 	ptr = buf;
1.1  nisimura 	for (cnt = 0; cnt < upto; cnt += 2) {
1.1  nisimura 		val = CSR_READ_2(l, MRCMD);
1.1  nisimura 		ptr[0] = val;
1.1  nisimura 		ptr[1] = val >> 8;
1.1  nisimura 		ptr += 2;
1.1  nisimura 	}
1.1  nisimura 	/* discard trailing bytes */
1.1  nisimura 	for (; cnt < len; cnt += 2)
1.1  nisimura 		(void) CSR_READ_2(l, MRCMD);
1.1  nisimura
1.1  nisimura 	return upto;
1.1  nisimura }
1.1  nisimura
1.1  nisimura static unsigned int
1.1  nisimura mii_read(struct local *l, int phy, int reg)
1.1  nisimura {
1.1  nisimura 	int v;
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, EPAR, phy << 6 | reg);
1.1  nisimura 	CSR_WRITE_1(l, EPCR, EP_EPOS | EP_ERPRR);
1.1  nisimura 	do {
1.1  nisimura 		v = CSR_READ_1(l, EPCR);
1.1  nisimura 	} while (v & EP_ERRE);
1.1  nisimura 	CSR_WRITE_1(l, EPCR, 0);
1.1  nisimura 	v = (CSR_READ_1(l, EPDRH) << 8) | CSR_READ_1(l, EPDRL);
1.1  nisimura 	return v;
1.1  nisimura }
1.1  nisimura
1.1  nisimura static void
1.1  nisimura mii_write(struct local *l, int phy, int reg, int data)
1.1  nisimura {
1.1  nisimura 	int v;
1.1  nisimura
1.1  nisimura 	CSR_WRITE_1(l, EPAR, phy << 6 | reg);
1.1  nisimura 	CSR_WRITE_1(l, EPDRL, data);
1.1  nisimura 	CSR_WRITE_1(l, EPDRH, data >> 8);
1.1  nisimura 	CSR_WRITE_1(l, EPCR, EP_EPOS | EP_ERPRW);
1.1  nisimura 	do {
1.1  nisimura 		v = CSR_READ_1(l, EPCR);
1.1  nisimura 	} while (v & EP_ERRE);
1.1  nisimura 	CSR_WRITE_1(l, EPCR, 0);
1.1  nisimura }
1.1  nisimura
1.1  nisimura #define MII_BMCR	0x00	/* Basic mode control register (rw) */
1.1  nisimura #define  BMCR_RESET	0x8000	/* reset */
1.1  nisimura #define  BMCR_AUTOEN	0x1000	/* autonegotiation enable */
1.1  nisimura #define  BMCR_ISO	0x0400	/* isolate */
1.1  nisimura #define  BMCR_STARTNEG	0x0200	/* restart autonegotiation */
1.1  nisimura #define MII_BMSR	0x01	/* Basic mode status register (ro) */
1.1  nisimura #define  BMSR_ACOMP	0x0020	/* Autonegotiation complete */
1.1  nisimura #define  BMSR_LINK	0x0004	/* Link status */
1.1  nisimura #define MII_ANAR	0x04	/* Autonegotiation advertisement (rw) */
1.1  nisimura #define  ANAR_FC	0x0400	/* local device supports PAUSE */
1.1  nisimura #define  ANAR_TX_FD	0x0100	/* local device supports 100bTx FD */
1.1  nisimura #define  ANAR_TX	0x0080	/* local device supports 100bTx */
1.1  nisimura #define  ANAR_10_FD	0x0040	/* local device supports 10bT FD */
1.1  nisimura #define  ANAR_10	0x0020	/* local device supports 10bT */
1.1  nisimura #define  ANAR_CSMA	0x0001	/* protocol selector CSMA/CD */
1.1  nisimura #define MII_ANLPAR	0x05	/* Autonegotiation lnk partner abilities (rw) */
1.1  nisimura
1.1  nisimura static void
1.1  nisimura mii_dealan(struct local *l, unsigned int timo)
1.1  nisimura {
1.1  nisimura 	unsigned int bound;
1.1  nisimura
1.1  nisimura 	mii_write(l, l->phy, MII_ANAR, ANAR_TX_FD | ANAR_TX | ANAR_10_FD |
1.1  nisimura 	    ANAR_10 | ANAR_CSMA | ANAR_FC);
1.1  nisimura 	mii_write(l, l->phy, MII_BMCR, BMCR_AUTOEN | BMCR_STARTNEG);
1.1  nisimura 	l->anlpar = 0;
1.1  nisimura 	bound = getsecs() + timo;
1.1  nisimura 	do {
1.1  nisimura 		l->bmsr = mii_read(l, l->phy, MII_BMSR) |
1.1  nisimura 		   mii_read(l, l->phy, MII_BMSR); /* read twice */
1.1  nisimura 		if ((l->bmsr & BMSR_LINK) && (l->bmsr & BMSR_ACOMP)) {
1.1  nisimura 			l->anlpar = mii_read(l, l->phy, MII_ANLPAR);
1.1  nisimura 			break;
1.1  nisimura 		}
1.1  nisimura 		usleep(10 * 1000);
1.1  nisimura 	} while (getsecs() < bound);
1.1  nisimura 	return;
1.1  nisimura }