stand/boot/en.c

1.4  christos /*      $NetBSD: en.c,v 1.4 2002/07/11 16:03:18 christos Exp $        */
1.1       dbj /*
1.1       dbj  * Copyright (c) 1996 Rolf Grossmann
1.1       dbj  * All rights reserved.
1.1       dbj  *
1.1       dbj  * Redistribution and use in source and binary forms, with or without
1.1       dbj  * modification, are permitted provided that the following conditions
1.1       dbj  * are met:
1.1       dbj  * 1. Redistributions of source code must retain the above copyright
1.1       dbj  *    notice, this list of conditions and the following disclaimer.
1.1       dbj  * 2. Redistributions in binary form must reproduce the above copyright
1.1       dbj  *    notice, this list of conditions and the following disclaimer in the
1.1       dbj  *    documentation and/or other materials provided with the distribution.
1.1       dbj  * 3. All advertising materials mentioning features or use of this software
1.1       dbj  *    must display the following acknowledgement:
1.1       dbj  *      This product includes software developed by Rolf Grossmann.
1.1       dbj  * 4. The name of the author may not be used to endorse or promote products
1.1       dbj  *    derived from this software without specific prior written permission
1.1       dbj  *
1.1       dbj  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1       dbj  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1       dbj  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1       dbj  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1       dbj  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1       dbj  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1       dbj  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1       dbj  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1       dbj  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1       dbj  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1       dbj  */
1.1       dbj
1.1       dbj #include <sys/param.h>
1.1       dbj #include <sys/types.h>
1.1       dbj #include <netinet/in.h>
1.1       dbj #include <netinet/in_systm.h>
1.1       dbj #include <next68k/dev/enreg.h>
1.1       dbj #include <next68k/next68k/nextrom.h>
1.1       dbj #include "enreg.h"
1.1       dbj #include "dmareg.h"
1.1       dbj
1.1       dbj #include <stand.h>
1.1       dbj #include <netif.h>
1.1       dbj #include <net.h>
1.1       dbj #include <nfs.h>
1.3  drochner
1.3  drochner #include <lib/libkern/libkern.h>
1.1       dbj
1.1       dbj extern char *mg;
1.1       dbj #define	MON(type, off) (*(type *)((u_int) (mg) + off))
1.1       dbj
1.1       dbj #ifdef EN_DEBUG
1.1       dbj #define DPRINTF(x) printf x;
1.1       dbj #else
1.1       dbj #define DPRINTF(x)
1.1       dbj #endif
1.1       dbj
1.1       dbj #define	EN_TIMEOUT	2000000
1.1       dbj #define EN_RETRIES	10
1.1       dbj
1.1       dbj int en_match __P((struct netif *nif, void *machdep_hint));
1.1       dbj int en_probe __P((struct netif *nif, void *machdep_hint));
1.1       dbj void en_init __P((struct iodesc *desc, void *machdep_hint));
1.1       dbj int en_get __P((struct iodesc *a, void *b, size_t c, time_t d));
1.1       dbj int en_put __P((struct iodesc *a, void *b, size_t c));
1.1       dbj void en_end __P((struct netif *a));
1.1       dbj
1.1       dbj /* ### static int mountroot __P((int sock)); */
1.1       dbj static int en_wait_for_intr __P((int flag));
1.1       dbj
1.1       dbj struct netif_stats en_stats;
1.1       dbj
1.1       dbj struct netif_dif en_ifs[] = {
1.1       dbj /* dif_unit	dif_nsel	dif_stats	dif_private     */
1.1       dbj {  0,		1,		&en_stats,	NULL,	},
1.1       dbj };
1.1       dbj
1.1       dbj struct netif_driver en_driver = {
1.1       dbj 	"en",
1.1       dbj 	en_match, en_probe, en_init, en_get, en_put, en_end,
1.1       dbj 	en_ifs, NENTS(en_ifs)
1.1       dbj };
1.1       dbj
1.1       dbj /* ### int netdev_sock;
1.1       dbj static int open_count; */
1.1       dbj
1.1       dbj char dma_buffer1[MAX_DMASIZE+DMA_ENDALIGNMENT],
1.1       dbj      dma_buffer2[MAX_DMASIZE+DMA_ENDALIGNMENT],
1.1       dbj      *dma_buffers[2];
1.1       dbj int next_dma_buffer;
1.1       dbj
1.1       dbj
1.1       dbj int
1.1       dbj en_match(struct netif *nif, void *machdep_hint)
1.1       dbj {
1.1       dbj 	/* we always match, because every NeXT has an ethernet interface
1.1       dbj 	 * and we've checked the unit numbers before we even started this
1.1       dbj 	 * search.
1.1       dbj 	 * ### now that open is generic, we should check the params!
1.1       dbj 	 */
1.1       dbj 	return 1;
1.1       dbj }
1.1       dbj
1.1       dbj int
1.1       dbj en_probe(struct netif *nif, void *machdep_hint)
1.1       dbj {
1.1       dbj 	/* we also always probe ok, see en_match. */
1.1       dbj 	return 0;
1.1       dbj }
1.1       dbj
1.1       dbj void
1.1       dbj en_init(struct iodesc *desc, void *machdep_hint)
1.1       dbj {
1.1       dbj 	volatile struct en_regs *er;
1.1       dbj 	volatile u_int *bmap_chip;
1.1       dbj 	int i;
1.1       dbj
1.1       dbj 	DPRINTF(("en_init\n"));
1.1       dbj
1.1       dbj 	er = (struct en_regs *)P_ENET;
1.1       dbj 	bmap_chip = (u_int *)P_BMAP;
1.1       dbj
1.1       dbj 	dma_buffers[0] = DMA_ALIGN(char *, dma_buffer1);
1.1       dbj 	dma_buffers[1] = DMA_ALIGN(char *, dma_buffer2);
1.1       dbj
1.1       dbj 	er->reset = EN_RST_RESET;
1.1       dbj
1.4  christos 	/* ### we'll need this when we need to decide which interface to use	 */
1.4  christos 	/* bmap_chip[12] = 0x90000000; */
1.4  christos 	/* bmap_chip[13] = ~(0x80000000|0x10000000); */ /* BMAP_TPE  ??? */
1.4  christos 	DPRINTF (("en_media: %s\n",
1.4  christos 		  (bmap_chip[13] & 0x20000000) ? "BNC" : "TP"));
1.4  christos 	if (!(bmap_chip[13] & 0x20000000)) {
1.4  christos 		bmap_chip[12] |= 0x90000000;
1.4  christos 		bmap_chip[13] |= (0x80000000|0x10000000); /* TP */
1.4  christos 	}
1.1       dbj
1.1       dbj 	er->txmode = EN_TMD_LB_DISABLE;
1.1       dbj 	er->txmask = 0;
1.1       dbj 	er->txstat = 0xff;
1.1       dbj 	er->rxmode = EN_RMD_RECV_NORMAL;
1.1       dbj 	er->rxmask = 0;
1.1       dbj 	er->rxstat = 0xff;
1.1       dbj 	for (i=0; i<6; i++)
1.1       dbj 	  er->addr[i] = desc->myea[i] = MON(char *,MG_clientetheraddr)[i];
1.1       dbj
1.1       dbj 	DPRINTF(("ethernet addr (%x:%x:%x:%x:%x:%x)\n",
1.1       dbj 			desc->myea[0],desc->myea[1],desc->myea[2],
1.1       dbj 			desc->myea[3],desc->myea[4],desc->myea[5]));
1.1       dbj
1.1       dbj 	er->reset = 0;
1.1       dbj }
1.1       dbj
1.2       dbj #if 0
1.1       dbj /* ### remove this when things work! */
1.1       dbj #define XCHR(x) "0123456789abcdef"[(x) & 0xf]
1.1       dbj void
1.1       dbj dump_pkt(unsigned char *pkt, size_t len)
1.1       dbj {
1.1       dbj 	size_t i, j;
1.1       dbj
1.1       dbj 	printf("0000: ");
1.1       dbj 	for(i=0; i<len; i++) {
1.1       dbj 		printf("%c%c ", XCHR(pkt[i]>>4), XCHR(pkt[i]));
1.1       dbj 		if ((i+1) % 16 == 0) {
1.1       dbj 			printf("  %c", '"');
1.1       dbj 			for(j=0; j<16; j++)
1.1       dbj 				printf("%c", pkt[i-15+j]>=32 && pkt[i-15+j]<127?pkt[i-15+j]:'.');
1.1       dbj 			printf("%c\n%c%c%c%c: ", '"', XCHR((i+1)>>12),
1.1       dbj 				XCHR((i+1)>>8), XCHR((i+1)>>4), XCHR(i+1));
1.1       dbj 		}
1.1       dbj 	}
1.1       dbj 	printf("\n");
1.1       dbj }
1.2       dbj #endif
1.1       dbj
1.1       dbj int
1.1       dbj en_put(struct iodesc *desc, void *pkt, size_t len)
1.1       dbj {
1.1       dbj 	volatile struct en_regs *er;
1.1       dbj 	volatile struct dma_dev *txdma;
1.1       dbj 	int state, txs;
1.1       dbj 	int retries;
1.1       dbj
1.1       dbj 	DPRINTF(("en_put: %d bytes at 0x%lx\n", len, (unsigned long)pkt));
1.1       dbj #if 0
1.1       dbj 	dump_pkt(pkt,len);
1.1       dbj #endif
1.1       dbj
1.1       dbj 	er = (struct en_regs *)P_ENET;
1.1       dbj 	txdma = (struct dma_dev *)P_ENETX_CSR;
1.1       dbj
1.1       dbj 	DPRINTF(("en_put: txdma->dd_csr = %x\n",txdma->dd_csr));
1.1       dbj
1.1       dbj 	if (len > 1600) {
1.1       dbj 		errno = EINVAL;
1.1       dbj 		return -1;
1.1       dbj 	}
1.1       dbj
1.1       dbj 	while ((er->txstat & EN_TXS_READY) == 0)
1.1       dbj 		printf("en: tx not ready\n");
1.1       dbj
1.1       dbj 	for (retries = 0; retries < EN_RETRIES; retries++) {
1.1       dbj 		er->txstat = 0xff;
1.1       dbj 		bcopy(pkt, dma_buffers[0], len);
1.1       dbj 		txdma->dd_csr = 0;
1.1       dbj 		txdma->dd_csr = DMACSR_INITBUF | DMACSR_RESET | DMACSR_WRITE;
1.1       dbj 		txdma->dd_next_initbuf = dma_buffers[0];
1.1       dbj 		txdma->dd_limit = ENDMA_ENDALIGN(char *,  dma_buffers[0]+len);
1.1       dbj 		txdma->dd_start = 0;
1.1       dbj 		txdma->dd_stop = 0;
1.1       dbj 		txdma->dd_csr = DMACSR_SETENABLE;
1.1       dbj
1.1       dbj 		while(1) {
1.1       dbj 			if (en_wait_for_intr(ENETX_DMA_INTR)) {
1.1       dbj 				errno = EIO;
1.1       dbj 				return -1;
1.1       dbj 			}
1.1       dbj
1.1       dbj 			state = txdma->dd_csr &
1.1       dbj 				(DMACSR_BUSEXC | DMACSR_COMPLETE
1.1       dbj 				 | DMACSR_SUPDATE | DMACSR_ENABLE);
1.1       dbj
1.1       dbj #if 0
1.1       dbj 			DPRINTF(("en_put: dma state = 0x%x.\n", state));
1.1       dbj #endif
1.1       dbj 			if (state & (DMACSR_COMPLETE|DMACSR_BUSEXC))
1.1       dbj 				txdma->dd_csr = DMACSR_RESET | DMACSR_CLRCOMPLETE;
1.1       dbj 				break;
1.1       dbj 		}
1.1       dbj
1.1       dbj 		txs = er->txstat;
1.1       dbj
1.1       dbj #if 0
1.1       dbj 		DPRINTF(("en_put: done txstat=%x.\n", txs));
1.1       dbj #endif
1.1       dbj
1.1       dbj #define EN_TXS_ERROR (EN_TXS_SHORTED | EN_TXS_UNDERFLOW | EN_TXS_PARERR)
1.1       dbj 		if ((state & DMACSR_COMPLETE) == 0 ||
1.1       dbj 		    (txs & EN_TXS_ERROR) != 0) {
1.1       dbj 			errno = EIO;
1.1       dbj 			return -1;
1.1       dbj 		}
1.1       dbj 		if ((txs & EN_TXS_COLLERR) == 0)
1.1       dbj 			return len;		/* success */
1.1       dbj 	}
1.1       dbj
1.1       dbj 	errno = EIO;		/* too many retries */
1.1       dbj 	return -1;
1.1       dbj }
1.1       dbj
1.1       dbj int
1.1       dbj en_get(struct iodesc *desc, void *pkt, size_t len, time_t timeout)
1.1       dbj {
1.1       dbj 	volatile struct en_regs *er;
1.1       dbj 	volatile struct dma_dev *rxdma;
1.1       dbj 	int state, rxs;
1.1       dbj 	size_t rlen;
1.1       dbj 	char *gotpkt;
1.1       dbj
1.1       dbj 	rxdma = (struct dma_dev *)P_ENETR_CSR;
1.1       dbj 	er = (struct en_regs *)P_ENET;
1.1       dbj
1.1       dbj 	er->rxstat = 0xff;
1.1       dbj
1.1       dbj 	/* this is mouse's code now ... still doesn't work :( */
1.1       dbj 	/* The previous comment is now a lie, this does work
1.1       dbj 	 * Darrin B Jewell <jewell (at) mit.edu>  Sat Jan 24 21:44:56 1998
1.1       dbj 	 */
1.1       dbj
1.1       dbj 	rxdma->dd_csr = 0;
1.1       dbj 	rxdma->dd_csr = DMACSR_INITBUF | DMACSR_READ | DMACSR_RESET;
1.1       dbj
1.1       dbj 	rxdma->dd_saved_next = 0;
1.1       dbj 	rxdma->dd_saved_limit = 0;
1.1       dbj 	rxdma->dd_saved_start = 0;
1.1       dbj 	rxdma->dd_saved_stop = 0;
1.1       dbj
1.1       dbj 	rxdma->dd_next = dma_buffers[0];
1.1       dbj 	rxdma->dd_limit = DMA_ENDALIGN(char *, dma_buffers[0]+MAX_DMASIZE);
1.1       dbj 	rxdma->dd_start = 0;
1.1       dbj 	rxdma->dd_stop = 0;
1.1       dbj 	rxdma->dd_csr = DMACSR_SETENABLE;
1.1       dbj
1.1       dbj #if 0
1.1       dbj 	DPRINTF(("en_get: blocking on rcv dma\n"));
1.1       dbj #endif
1.1       dbj
1.1       dbj 	while(1) {
1.1       dbj 		if (en_wait_for_intr(ENETR_DMA_INTR)) {	/* ### use timeout? */
1.1       dbj 			errno = EIO;
1.1       dbj  			return -1;
1.1       dbj 		}
1.1       dbj
1.1       dbj 		state = rxdma->dd_csr &
1.1       dbj 			(DMACSR_BUSEXC | DMACSR_COMPLETE
1.1       dbj 			 | DMACSR_SUPDATE | DMACSR_ENABLE);
1.1       dbj 		DPRINTF(("en_get: dma state = 0x%x.\n", state));
1.1       dbj 		if ((state & DMACSR_ENABLE) == 0) {
1.1       dbj 			rxdma->dd_csr = DMACSR_RESET | DMACSR_CLRCOMPLETE;
1.1       dbj 			break;
1.1       dbj 		}
1.1       dbj
1.1       dbj 		if (state & DMACSR_COMPLETE) {
1.1       dbj 			DPRINTF(("en_get: ending dma sequence\n"));
1.1       dbj 			rxdma->dd_csr = DMACSR_CLRCOMPLETE;
1.1       dbj 		}
1.1       dbj
1.1       dbj 	}
1.1       dbj
1.1       dbj 	rxs = er->rxstat;
1.1       dbj
1.1       dbj 	if ((state & DMACSR_COMPLETE) == 0 ||
1.1       dbj 	    (rxs & EN_RX_OK) == 0) {
1.1       dbj 		errno = EIO;
1.1       dbj 		return -1;	/* receive failed */
1.1       dbj 	}
1.1       dbj
1.1       dbj 	gotpkt = rxdma->dd_saved_next;
1.1       dbj 	rlen = rxdma->dd_next - rxdma->dd_saved_next;
1.1       dbj
1.1       dbj 	if (gotpkt != dma_buffers[0]) {
1.1       dbj 		printf("Unexpected received packet location\n");
1.1       dbj 		printf("DEBUG: rxstat=%x.\n", rxs);
1.1       dbj 		printf("DEBUG: gotpkt = 0x%lx, rlen = %d, len = %d\n",(u_long)gotpkt,rlen,len);
1.1       dbj 		printf("DEBUG: rxdma->dd_csr = 0x%lx\n",(u_long)rxdma->dd_csr);
1.1       dbj 		printf("DEBUG: rxdma->dd_saved_next = 0x%lx\n",(u_long)rxdma->dd_saved_next);
1.1       dbj 		printf("DEBUG: rxdma->dd_saved_limit = 0x%lx\n",(u_long)rxdma->dd_saved_limit);
1.1       dbj 		printf("DEBUG: rxdma->dd_saved_start = 0x%lx\n",(u_long)rxdma->dd_saved_start);
1.1       dbj 		printf("DEBUG: rxdma->dd_saved_stop = 0x%lx\n",(u_long)rxdma->dd_saved_stop);
1.1       dbj 		printf("DEBUG: rxdma->dd_next = 0x%lx\n",(u_long)rxdma->dd_next);
1.1       dbj 		printf("DEBUG: rxdma->dd_limit = 0x%lx\n",(u_long)rxdma->dd_limit);
1.1       dbj 		printf("DEBUG: rxdma->dd_start = 0x%lx\n",(u_long)rxdma->dd_start);
1.1       dbj 		printf("DEBUG: rxdma->dd_stop = 0x%lx\n",(u_long)rxdma->dd_stop);
1.1       dbj 		printf("DEBUG: rxdma->dd_next_initbuf = 0x%lx\n",(u_long)rxdma->dd_next_initbuf);
1.1       dbj 	}
1.1       dbj
1.1       dbj #if 0
1.1       dbj dump_pkt(gotpkt, rlen < 255 ? rlen : 128);
1.1       dbj #endif
1.1       dbj
1.1       dbj  DPRINTF(("en_get: done rxstat=%x.\n", rxs));
1.1       dbj
1.1       dbj 	if (rlen > len) {
1.1       dbj 		DPRINTF(("en_get: buffer too small. want %d, got %d\n",
1.1       dbj 			 len, rlen));
1.1       dbj 		rlen = len;
1.1       dbj 	}
1.1       dbj
1.1       dbj
1.1       dbj 	bcopy(gotpkt, pkt, rlen);
1.1       dbj
1.1       dbj #if 0
1.1       dbj 	printf("DEBUG: gotpkt = 0x%lx, pkt = 0x%lx, rlen = %d\n",
1.1       dbj 			(u_long)gotpkt,(u_long)pkt,rlen);
1.1       dbj 	dump_pkt(gotpkt, rlen < 255 ? rlen : 128);
1.1       dbj 	dump_pkt(pkt, rlen < 255 ? rlen : 128);
1.1       dbj #endif
1.1       dbj
1.1       dbj 	return rlen;
1.1       dbj }
1.1       dbj
1.1       dbj
1.1       dbj void
1.1       dbj en_end(struct netif *a)
1.1       dbj {
1.1       dbj   DPRINTF(("en_end: WARNING not doing anything\n"));
1.1       dbj }
1.1       dbj
1.1       dbj #if 0
1.1       dbj
1.1       dbj #define MKPANIC(ret,name,args) \
1.1       dbj 	ret name args { panic(#name ## ": not implemented.\n"); }
1.1       dbj
1.1       dbj MKPANIC(void, en_end, (struct netif *a));
1.1       dbj
1.1       dbj /* device functions */
1.1       dbj
1.1       dbj int
1.1       dbj enopen(struct open_file *f, char count, char lun, char part)
1.1       dbj {
1.1       dbj 	int error;
1.1       dbj
1.1       dbj 	DPRINTF(("open: en(%d,%d,%d)\n", count, lun, part));
1.1       dbj
1.1       dbj 	if (count != 0 || lun != 0 || part != 0)
1.1       dbj 		return EUNIT;	/* there can be exactly one ethernet */
1.1       dbj
1.1       dbj 	if (open_count == 0) {
1.1       dbj 		/* Find network interface. */
1.1       dbj 		if ((netdev_sock = netif_open(NULL)) < 0)
1.1       dbj 			return errno;
1.1       dbj 		if ((error = mountroot(netdev_sock)) != 0) {
1.1       dbj 			if (open_count == 0)
1.1       dbj 				netif_close(netdev_sock);
1.1       dbj 			return error;
1.1       dbj 		}
1.1       dbj 	}
1.1       dbj 	open_count++;
1.1       dbj 	f->f_devdata = NULL; /* ### nfs_root_node ?! */
1.1       dbj 	return 0;
1.1       dbj }
1.1       dbj
1.1       dbj int
1.1       dbj enclose(struct open_file *f)
1.1       dbj {
1.1       dbj 	if (open_count > 0)
1.1       dbj 		if (--open_count == 0)
1.1       dbj 			netif_close(netdev_sock);
1.1       dbj 	f->f_devdata = NULL;
1.1       dbj 	return 0;
1.1       dbj }
1.1       dbj
1.1       dbj int
1.1       dbj enstrategy(void *devdata, int rw, daddr_t dblk,
1.1       dbj 	   size_t size, void *buf, size_t *rsize)
1.1       dbj {
1.1       dbj 	return ENXIO;		/* wrong access method */
1.1       dbj }
1.1       dbj
1.1       dbj /* private function */
1.1       dbj
1.1       dbj static int
1.1       dbj mountroot(int sock)
1.1       dbj {
1.1       dbj 	/* Mount the root directory from a boot server */
1.1       dbj #if 0
1.1       dbj 	struct in_addr in = {
1.1       dbj 		0xc2793418
1.1       dbj 	};
1.1       dbj 	u_char *res;
1.1       dbj
1.1       dbj 	res = arpwhohas(socktodesc(sock), in);
1.1       dbj 	panic("arpwhohas returned %s", res);
1.1       dbj #endif
1.1       dbj 	/* 1. use bootp. This does most of the work for us. */
1.1       dbj 	bootp(sock);
1.1       dbj
1.1       dbj 	if (myip.s_addr == 0 || rootip.s_addr == 0 || rootpath[0] == '\0')
1.1       dbj 		return ETIMEDOUT;
1.1       dbj
1.1       dbj 	printf("Using IP address: %s\n", inet_ntoa(myip));
1.1       dbj 	printf("root addr=%s path=%s\n", inet_ntoa(rootip), rootpath);
1.1       dbj
1.1       dbj 	/* 2. mount. */
1.1       dbj 	if (nfs_mount(sock, rootip, rootpath) < 0)
1.1       dbj 		return errno;
1.1       dbj
1.1       dbj 	return 0;
1.1       dbj }
1.1       dbj #endif
1.1       dbj
1.1       dbj static int
1.1       dbj en_wait_for_intr(int flag)
1.1       dbj {
1.1       dbj   volatile int *intrstat = MON(volatile int *,MG_intrstat);
1.1       dbj
1.1       dbj 	int count;
1.1       dbj
1.1       dbj 	for(count = 0; count < EN_TIMEOUT; count++)
1.1       dbj 		if (*intrstat & flag)
1.1       dbj 			return 0;
1.1       dbj
1.1       dbj 	printf("enintr: timed out.\n");
1.1       dbj 	return -1;
1.1       dbj }