drivers/net/hp100.c at v2.6.15-rc3

tjh.dev / kernel
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Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel os linux
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kernel / drivers / net / hp100.c
at v2.6.15-rc3 3088 lines 91 kB view raw
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   1/*
   2** hp100.c 
   3** HP CASCADE Architecture Driver for 100VG-AnyLan Network Adapters
   4**
   5** $Id: hp100.c,v 1.58 2001/09/24 18:03:01 perex Exp perex $
   6**
   7** Based on the HP100 driver written by Jaroslav Kysela <perex@jcu.cz>
   8** Extended for new busmaster capable chipsets by 
   9** Siegfried "Frieder" Loeffler (dg1sek) <floeff@mathematik.uni-stuttgart.de>
  10**
  11** Maintained by: Jaroslav Kysela <perex@suse.cz>
  12** 
  13** This driver has only been tested with
  14** -- HP J2585B 10/100 Mbit/s PCI Busmaster
  15** -- HP J2585A 10/100 Mbit/s PCI 
  16** -- HP J2970A 10 Mbit/s PCI Combo 10base-T/BNC
  17** -- HP J2973A 10 Mbit/s PCI 10base-T
  18** -- HP J2573  10/100 ISA
  19** -- Compex ReadyLink ENET100-VG4  10/100 Mbit/s PCI / EISA
  20** -- Compex FreedomLine 100/VG  10/100 Mbit/s ISA / EISA / PCI
  21** 
  22** but it should also work with the other CASCADE based adapters.
  23**
  24** TODO:
  25**       -  J2573 seems to hang sometimes when in shared memory mode.
  26**       -  Mode for Priority TX
  27**       -  Check PCI registers, performance might be improved?
  28**       -  To reduce interrupt load in busmaster, one could switch off
  29**          the interrupts that are used to refill the queues whenever the
  30**          queues are filled up to more than a certain threshold.
  31**       -  some updates for EISA version of card
  32**
  33**
  34**   This code is free software; you can redistribute it and/or modify
  35**   it under the terms of the GNU General Public License as published by
  36**   the Free Software Foundation; either version 2 of the License, or
  37**   (at your option) any later version.
  38**
  39**   This code is distributed in the hope that it will be useful,
  40**   but WITHOUT ANY WARRANTY; without even the implied warranty of
  41**   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  42**   GNU General Public License for more details.
  43**
  44**   You should have received a copy of the GNU General Public License
  45**   along with this program; if not, write to the Free Software
  46**   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
  47**
  48** 1.57c -> 1.58
  49**   - used indent to change coding-style
  50**   - added KTI DP-200 EISA ID
  51**   - ioremap is also used for low (<1MB) memory (multi-architecture support)
  52**
  53** 1.57b -> 1.57c - Arnaldo Carvalho de Melo <acme@conectiva.com.br>
  54**   - release resources on failure in init_module
  55**
  56** 1.57 -> 1.57b - Jean II
  57**   - fix spinlocks, SMP is now working !
  58**
  59** 1.56 -> 1.57
  60**   - updates for new PCI interface for 2.1 kernels
  61**
  62** 1.55 -> 1.56
  63**   - removed printk in misc. interrupt and update statistics to allow
  64**     monitoring of card status
  65**   - timing changes in xmit routines, relogin to 100VG hub added when
  66**     driver does reset
  67**   - included fix for Compex FreedomLine PCI adapter
  68** 
  69** 1.54 -> 1.55
  70**   - fixed bad initialization in init_module
  71**   - added Compex FreedomLine adapter
  72**   - some fixes in card initialization
  73**
  74** 1.53 -> 1.54
  75**   - added hardware multicast filter support (doesn't work)
  76**   - little changes in hp100_sense_lan routine 
  77**     - added support for Coax and AUI (J2970)
  78**   - fix for multiple cards and hp100_mode parameter (insmod)
  79**   - fix for shared IRQ 
  80**
  81** 1.52 -> 1.53
  82**   - fixed bug in multicast support
  83**
  84*/
  85
  86#define HP100_DEFAULT_PRIORITY_TX 0
  87
  88#undef HP100_DEBUG
  89#undef HP100_DEBUG_B		/* Trace  */
  90#undef HP100_DEBUG_BM		/* Debug busmaster code (PDL stuff) */
  91
  92#undef HP100_DEBUG_TRAINING	/* Debug login-to-hub procedure */
  93#undef HP100_DEBUG_TX
  94#undef HP100_DEBUG_IRQ
  95#undef HP100_DEBUG_RX
  96
  97#undef HP100_MULTICAST_FILTER	/* Need to be debugged... */
  98
  99#include <linux/module.h>
 100#include <linux/kernel.h>
 101#include <linux/string.h>
 102#include <linux/errno.h>
 103#include <linux/ioport.h>
 104#include <linux/slab.h>
 105#include <linux/interrupt.h>
 106#include <linux/eisa.h>
 107#include <linux/pci.h>
 108#include <linux/dma-mapping.h>
 109#include <linux/spinlock.h>
 110#include <linux/netdevice.h>
 111#include <linux/etherdevice.h>
 112#include <linux/skbuff.h>
 113#include <linux/types.h>
 114#include <linux/config.h>	/* for CONFIG_PCI */
 115#include <linux/delay.h>
 116#include <linux/init.h>
 117#include <linux/bitops.h>
 118
 119#include <asm/io.h>
 120
 121#include "hp100.h"
 122
 123/*
 124 *  defines
 125 */
 126
 127#define HP100_BUS_ISA     0
 128#define HP100_BUS_EISA    1
 129#define HP100_BUS_PCI     2
 130
 131#define HP100_REGION_SIZE	0x20	/* for ioports */
 132#define HP100_SIG_LEN		8	/* same as EISA_SIG_LEN */
 133
 134#define HP100_MAX_PACKET_SIZE	(1536+4)
 135#define HP100_MIN_PACKET_SIZE	60
 136
 137#ifndef HP100_DEFAULT_RX_RATIO
 138/* default - 75% onboard memory on the card are used for RX packets */
 139#define HP100_DEFAULT_RX_RATIO	75
 140#endif
 141
 142#ifndef HP100_DEFAULT_PRIORITY_TX
 143/* default - don't enable transmit outgoing packets as priority */
 144#define HP100_DEFAULT_PRIORITY_TX 0
 145#endif
 146
 147/*
 148 *  structures
 149 */
 150
 151struct hp100_private {
 152	spinlock_t lock;
 153	char id[HP100_SIG_LEN];
 154	u_short chip;
 155	u_short soft_model;
 156	u_int memory_size;
 157	u_int virt_memory_size;
 158	u_short rx_ratio;	/* 1 - 99 */
 159	u_short priority_tx;	/* != 0 - priority tx */
 160	u_short mode;		/* PIO, Shared Mem or Busmaster */
 161	u_char bus;
 162	struct pci_dev *pci_dev;
 163	short mem_mapped;	/* memory mapped access */
 164	void __iomem *mem_ptr_virt;	/* virtual memory mapped area, maybe NULL */
 165	unsigned long mem_ptr_phys;	/* physical memory mapped area */
 166	short lan_type;		/* 10Mb/s, 100Mb/s or -1 (error) */
 167	int hub_status;		/* was login to hub successful? */
 168	u_char mac1_mode;
 169	u_char mac2_mode;
 170	u_char hash_bytes[8];
 171	struct net_device_stats stats;
 172
 173	/* Rings for busmaster mode: */
 174	hp100_ring_t *rxrhead;	/* Head (oldest) index into rxring */
 175	hp100_ring_t *rxrtail;	/* Tail (newest) index into rxring */
 176	hp100_ring_t *txrhead;	/* Head (oldest) index into txring */
 177	hp100_ring_t *txrtail;	/* Tail (newest) index into txring */
 178
 179	hp100_ring_t rxring[MAX_RX_PDL];
 180	hp100_ring_t txring[MAX_TX_PDL];
 181
 182	u_int *page_vaddr_algn;	/* Aligned virtual address of allocated page */
 183	u_long whatever_offset;	/* Offset to bus/phys/dma address */
 184	int rxrcommit;		/* # Rx PDLs commited to adapter */
 185	int txrcommit;		/* # Tx PDLs commited to adapter */
 186};
 187
 188/*
 189 *  variables
 190 */
 191static const char *hp100_isa_tbl[] = {
 192	"HWPF150", /* HP J2573 rev A */
 193	"HWP1950", /* HP J2573 */
 194};
 195
 196#ifdef CONFIG_EISA
 197static struct eisa_device_id hp100_eisa_tbl[] = {
 198	{ "HWPF180" }, /* HP J2577 rev A */
 199	{ "HWP1920" }, /* HP 27248B */
 200	{ "HWP1940" }, /* HP J2577 */
 201	{ "HWP1990" }, /* HP J2577 */
 202	{ "CPX0301" }, /* ReadyLink ENET100-VG4 */
 203	{ "CPX0401" }, /* FreedomLine 100/VG */
 204	{ "" }	       /* Mandatory final entry ! */
 205};
 206MODULE_DEVICE_TABLE(eisa, hp100_eisa_tbl);
 207#endif
 208
 209#ifdef CONFIG_PCI
 210static struct pci_device_id hp100_pci_tbl[] = {
 211	{PCI_VENDOR_ID_HP, PCI_DEVICE_ID_HP_J2585A, PCI_ANY_ID, PCI_ANY_ID,},
 212	{PCI_VENDOR_ID_HP, PCI_DEVICE_ID_HP_J2585B, PCI_ANY_ID, PCI_ANY_ID,},
 213	{PCI_VENDOR_ID_HP, PCI_DEVICE_ID_HP_J2970A, PCI_ANY_ID, PCI_ANY_ID,},
 214	{PCI_VENDOR_ID_HP, PCI_DEVICE_ID_HP_J2973A, PCI_ANY_ID, PCI_ANY_ID,},
 215	{PCI_VENDOR_ID_COMPEX, PCI_DEVICE_ID_COMPEX_ENET100VG4, PCI_ANY_ID, PCI_ANY_ID,},
 216	{PCI_VENDOR_ID_COMPEX2, PCI_DEVICE_ID_COMPEX2_100VG, PCI_ANY_ID, PCI_ANY_ID,},
 217/*	{PCI_VENDOR_ID_KTI, PCI_DEVICE_ID_KTI_DP200, PCI_ANY_ID, PCI_ANY_ID }, */
 218	{}			/* Terminating entry */
 219};
 220MODULE_DEVICE_TABLE(pci, hp100_pci_tbl);
 221#endif
 222
 223static int hp100_rx_ratio = HP100_DEFAULT_RX_RATIO;
 224static int hp100_priority_tx = HP100_DEFAULT_PRIORITY_TX;
 225static int hp100_mode = 1;
 226
 227module_param(hp100_rx_ratio, int, 0);
 228module_param(hp100_priority_tx, int, 0);
 229module_param(hp100_mode, int, 0);
 230
 231/*
 232 *  prototypes
 233 */
 234
 235static int hp100_probe1(struct net_device *dev, int ioaddr, u_char bus,
 236			struct pci_dev *pci_dev);
 237
 238
 239static int hp100_open(struct net_device *dev);
 240static int hp100_close(struct net_device *dev);
 241static int hp100_start_xmit(struct sk_buff *skb, struct net_device *dev);
 242static int hp100_start_xmit_bm(struct sk_buff *skb,
 243			       struct net_device *dev);
 244static void hp100_rx(struct net_device *dev);
 245static struct net_device_stats *hp100_get_stats(struct net_device *dev);
 246static void hp100_misc_interrupt(struct net_device *dev);
 247static void hp100_update_stats(struct net_device *dev);
 248static void hp100_clear_stats(struct hp100_private *lp, int ioaddr);
 249static void hp100_set_multicast_list(struct net_device *dev);
 250static irqreturn_t hp100_interrupt(int irq, void *dev_id, struct pt_regs *regs);
 251static void hp100_start_interface(struct net_device *dev);
 252static void hp100_stop_interface(struct net_device *dev);
 253static void hp100_load_eeprom(struct net_device *dev, u_short ioaddr);
 254static int hp100_sense_lan(struct net_device *dev);
 255static int hp100_login_to_vg_hub(struct net_device *dev,
 256				 u_short force_relogin);
 257static int hp100_down_vg_link(struct net_device *dev);
 258static void hp100_cascade_reset(struct net_device *dev, u_short enable);
 259static void hp100_BM_shutdown(struct net_device *dev);
 260static void hp100_mmuinit(struct net_device *dev);
 261static void hp100_init_pdls(struct net_device *dev);
 262static int hp100_init_rxpdl(struct net_device *dev,
 263			    register hp100_ring_t * ringptr,
 264			    register u_int * pdlptr);
 265static int hp100_init_txpdl(struct net_device *dev,
 266			    register hp100_ring_t * ringptr,
 267			    register u_int * pdlptr);
 268static void hp100_rxfill(struct net_device *dev);
 269static void hp100_hwinit(struct net_device *dev);
 270static void hp100_clean_txring(struct net_device *dev);
 271#ifdef HP100_DEBUG
 272static void hp100_RegisterDump(struct net_device *dev);
 273#endif
 274
 275/* Conversion to new PCI API :
 276 * Convert an address in a kernel buffer to a bus/phys/dma address.
 277 * This work *only* for memory fragments part of lp->page_vaddr,
 278 * because it was properly DMA allocated via pci_alloc_consistent(),
 279 * so we just need to "retreive" the original mapping to bus/phys/dma
 280 * address - Jean II */
 281static inline dma_addr_t virt_to_whatever(struct net_device *dev, u32 * ptr)
 282{
 283	struct hp100_private *lp = netdev_priv(dev);
 284	return ((u_long) ptr) + lp->whatever_offset;
 285}
 286
 287static inline u_int pdl_map_data(struct hp100_private *lp, void *data)
 288{
 289	return pci_map_single(lp->pci_dev, data, 
 290			      MAX_ETHER_SIZE, PCI_DMA_FROMDEVICE);
 291}
 292
 293/* TODO: This function should not really be needed in a good design... */
 294static void wait(void)
 295{
 296	mdelay(1);
 297}
 298
 299/*
 300 *  probe functions
 301 *  These functions should - if possible - avoid doing write operations
 302 *  since this could cause problems when the card is not installed.
 303 */
 304
 305/*
 306 * Read board id and convert to string.
 307 * Effectively same code as decode_eisa_sig
 308 */
 309static __devinit const char *hp100_read_id(int ioaddr)
 310{
 311	int i;
 312	static char str[HP100_SIG_LEN];
 313	unsigned char sig[4], sum;
 314        unsigned short rev;
 315
 316	hp100_page(ID_MAC_ADDR);
 317	sum = 0;
 318	for (i = 0; i < 4; i++) {
 319		sig[i] = hp100_inb(BOARD_ID + i);
 320		sum += sig[i];
 321	}
 322
 323	sum += hp100_inb(BOARD_ID + i);
 324	if (sum != 0xff)
 325		return NULL;	/* bad checksum */
 326
 327        str[0] = ((sig[0] >> 2) & 0x1f) + ('A' - 1);
 328        str[1] = (((sig[0] & 3) << 3) | (sig[1] >> 5)) + ('A' - 1);
 329        str[2] = (sig[1] & 0x1f) + ('A' - 1);
 330        rev = (sig[2] << 8) | sig[3];
 331        sprintf(str + 3, "%04X", rev);
 332
 333	return str;
 334}
 335
 336static __init int hp100_isa_probe1(struct net_device *dev, int ioaddr)
 337{
 338	const char *sig;
 339	int i;
 340
 341	if (!request_region(ioaddr, HP100_REGION_SIZE, "hp100"))
 342		goto err;
 343
 344	if (hp100_inw(HW_ID) != HP100_HW_ID_CASCADE) {
 345		release_region(ioaddr, HP100_REGION_SIZE);
 346		goto err;
 347	}
 348
 349	sig = hp100_read_id(ioaddr);
 350	release_region(ioaddr, HP100_REGION_SIZE);
 351
 352	if (sig == NULL)
 353		goto err;
 354
 355	for (i = 0; i < ARRAY_SIZE(hp100_isa_tbl); i++) {
 356		if (!strcmp(hp100_isa_tbl[i], sig)) 
 357			break;
 358
 359	}
 360
 361	if (i < ARRAY_SIZE(hp100_isa_tbl))
 362		return hp100_probe1(dev, ioaddr, HP100_BUS_ISA, NULL);
 363 err:
 364	return -ENODEV;
 365
 366}
 367/*
 368 * Probe for ISA board.
 369 * EISA and PCI are handled by device infrastructure.
 370 */
 371
 372static int  __init hp100_isa_probe(struct net_device *dev, int addr)
 373{
 374	int err = -ENODEV;
 375
 376	/* Probe for a specific ISA address */		
 377	if (addr > 0xff && addr < 0x400)
 378		err = hp100_isa_probe1(dev, addr);
 379
 380	else if (addr != 0) 
 381		err = -ENXIO;
 382
 383	else {
 384		/* Probe all ISA possible port regions */
 385		for (addr = 0x100; addr < 0x400; addr += 0x20) {
 386			err = hp100_isa_probe1(dev, addr);
 387			if (!err)
 388				break;
 389		}
 390	}
 391	return err;
 392}
 393
 394
 395#ifndef MODULE
 396struct net_device * __init hp100_probe(int unit)
 397{
 398	struct net_device *dev = alloc_etherdev(sizeof(struct hp100_private));
 399	int err;
 400
 401	if (!dev)
 402		return ERR_PTR(-ENODEV);
 403
 404	SET_MODULE_OWNER(dev);
 405
 406#ifdef HP100_DEBUG_B
 407	hp100_outw(0x4200, TRACE);
 408	printk("hp100: %s: probe\n", dev->name);
 409#endif
 410
 411	if (unit >= 0) {
 412		sprintf(dev->name, "eth%d", unit);
 413		netdev_boot_setup_check(dev);
 414	}
 415
 416	err = hp100_isa_probe(dev, dev->base_addr);
 417	if (err)
 418		goto out;
 419
 420	return dev;
 421 out:
 422	free_netdev(dev);
 423	return ERR_PTR(err);
 424}
 425#endif
 426
 427static int __devinit hp100_probe1(struct net_device *dev, int ioaddr,
 428				  u_char bus, struct pci_dev *pci_dev)
 429{
 430	int i;
 431	int err = -ENODEV;
 432	const char *eid;
 433	u_int chip;
 434	u_char uc;
 435	u_int memory_size = 0, virt_memory_size = 0;
 436	u_short local_mode, lsw;
 437	short mem_mapped;
 438	unsigned long mem_ptr_phys;
 439	void __iomem *mem_ptr_virt;
 440	struct hp100_private *lp;
 441
 442#ifdef HP100_DEBUG_B
 443	hp100_outw(0x4201, TRACE);
 444	printk("hp100: %s: probe1\n", dev->name);
 445#endif
 446
 447	/* memory region for programmed i/o */
 448	if (!request_region(ioaddr, HP100_REGION_SIZE, "hp100"))
 449		goto out1;
 450
 451	if (hp100_inw(HW_ID) != HP100_HW_ID_CASCADE) 
 452		goto out2;
 453
 454	chip = hp100_inw(PAGING) & HP100_CHIPID_MASK;
 455#ifdef HP100_DEBUG
 456	if (chip == HP100_CHIPID_SHASTA)
 457		printk("hp100: %s: Shasta Chip detected. (This is a pre 802.12 chip)\n", dev->name);
 458	else if (chip == HP100_CHIPID_RAINIER)
 459		printk("hp100: %s: Rainier Chip detected. (This is a pre 802.12 chip)\n", dev->name);
 460	else if (chip == HP100_CHIPID_LASSEN)
 461		printk("hp100: %s: Lassen Chip detected.\n", dev->name);
 462	else
 463		printk("hp100: %s: Warning: Unknown CASCADE chip (id=0x%.4x).\n", dev->name, chip);
 464#endif
 465
 466	dev->base_addr = ioaddr;
 467
 468	eid = hp100_read_id(ioaddr);
 469	if (eid == NULL) {	/* bad checksum? */
 470		printk(KERN_WARNING "hp100_probe: bad ID checksum at base port 0x%x\n", ioaddr);
 471		goto out2;
 472	}
 473
 474	hp100_page(ID_MAC_ADDR);
 475	for (i = uc = 0; i < 7; i++)
 476		uc += hp100_inb(LAN_ADDR + i);
 477	if (uc != 0xff) {
 478		printk(KERN_WARNING "hp100_probe: bad lan address checksum at port 0x%x)\n", ioaddr);
 479		err = -EIO;
 480		goto out2;
 481	}
 482
 483	/* Make sure, that all registers are correctly updated... */
 484
 485	hp100_load_eeprom(dev, ioaddr);
 486	wait();
 487
 488	/*
 489	 * Determine driver operation mode
 490	 *
 491	 * Use the variable "hp100_mode" upon insmod or as kernel parameter to
 492	 * force driver modes:
 493	 * hp100_mode=1 -> default, use busmaster mode if configured.
 494	 * hp100_mode=2 -> enable shared memory mode 
 495	 * hp100_mode=3 -> force use of i/o mapped mode.
 496	 * hp100_mode=4 -> same as 1, but re-set the enable bit on the card.
 497	 */
 498
 499	/*
 500	 * LSW values:
 501	 *   0x2278 -> J2585B, PnP shared memory mode
 502	 *   0x2270 -> J2585B, shared memory mode, 0xdc000
 503	 *   0xa23c -> J2585B, I/O mapped mode
 504	 *   0x2240 -> EISA COMPEX, BusMaster (Shasta Chip)
 505	 *   0x2220 -> EISA HP, I/O (Shasta Chip)
 506	 *   0x2260 -> EISA HP, BusMaster (Shasta Chip)
 507	 */
 508
 509#if 0
 510	local_mode = 0x2270;
 511	hp100_outw(0xfefe, OPTION_LSW);
 512	hp100_outw(local_mode | HP100_SET_LB | HP100_SET_HB, OPTION_LSW);
 513#endif
 514
 515	/* hp100_mode value maybe used in future by another card */
 516	local_mode = hp100_mode;
 517	if (local_mode < 1 || local_mode > 4)
 518		local_mode = 1;	/* default */
 519#ifdef HP100_DEBUG
 520	printk("hp100: %s: original LSW = 0x%x\n", dev->name,
 521	       hp100_inw(OPTION_LSW));
 522#endif
 523
 524	if (local_mode == 3) {
 525		hp100_outw(HP100_MEM_EN | HP100_RESET_LB, OPTION_LSW);
 526		hp100_outw(HP100_IO_EN | HP100_SET_LB, OPTION_LSW);
 527		hp100_outw(HP100_BM_WRITE | HP100_BM_READ | HP100_RESET_HB, OPTION_LSW);
 528		printk("hp100: IO mapped mode forced.\n");
 529	} else if (local_mode == 2) {
 530		hp100_outw(HP100_MEM_EN | HP100_SET_LB, OPTION_LSW);
 531		hp100_outw(HP100_IO_EN | HP100_SET_LB, OPTION_LSW);
 532		hp100_outw(HP100_BM_WRITE | HP100_BM_READ | HP100_RESET_HB, OPTION_LSW);
 533		printk("hp100: Shared memory mode requested.\n");
 534	} else if (local_mode == 4) {
 535		if (chip == HP100_CHIPID_LASSEN) {
 536			hp100_outw(HP100_BM_WRITE | HP100_BM_READ | HP100_SET_HB, OPTION_LSW);
 537			hp100_outw(HP100_IO_EN | HP100_MEM_EN | HP100_RESET_LB, OPTION_LSW);
 538			printk("hp100: Busmaster mode requested.\n");
 539		}
 540		local_mode = 1;
 541	}
 542
 543	if (local_mode == 1) {	/* default behaviour */
 544		lsw = hp100_inw(OPTION_LSW);
 545
 546		if ((lsw & HP100_IO_EN) && (~lsw & HP100_MEM_EN) &&
 547		    (~lsw & (HP100_BM_WRITE | HP100_BM_READ))) {
 548#ifdef HP100_DEBUG
 549			printk("hp100: %s: IO_EN bit is set on card.\n", dev->name);
 550#endif
 551			local_mode = 3;
 552		} else if (chip == HP100_CHIPID_LASSEN &&
 553			   (lsw & (HP100_BM_WRITE | HP100_BM_READ)) == (HP100_BM_WRITE | HP100_BM_READ)) {
 554			/* Conversion to new PCI API :
 555			 * I don't have the doc, but I assume that the card
 556			 * can map the full 32bit address space.
 557			 * Also, we can have EISA Busmaster cards (not tested),
 558			 * so beware !!! - Jean II */
 559			if((bus == HP100_BUS_PCI) &&
 560			   (pci_set_dma_mask(pci_dev, DMA_32BIT_MASK))) {
 561				/* Gracefully fallback to shared memory */
 562				goto busmasterfail;
 563			}
 564			printk("hp100: Busmaster mode enabled.\n");
 565			hp100_outw(HP100_MEM_EN | HP100_IO_EN | HP100_RESET_LB, OPTION_LSW);
 566		} else {
 567		busmasterfail:
 568#ifdef HP100_DEBUG
 569			printk("hp100: %s: Card not configured for BM or BM not supported with this card.\n", dev->name);
 570			printk("hp100: %s: Trying shared memory mode.\n", dev->name);
 571#endif
 572			/* In this case, try shared memory mode */
 573			local_mode = 2;
 574			hp100_outw(HP100_MEM_EN | HP100_SET_LB, OPTION_LSW);
 575			/* hp100_outw(HP100_IO_EN|HP100_RESET_LB, OPTION_LSW); */
 576		}
 577	}
 578#ifdef HP100_DEBUG
 579	printk("hp100: %s: new LSW = 0x%x\n", dev->name, hp100_inw(OPTION_LSW));
 580#endif
 581
 582	/* Check for shared memory on the card, eventually remap it */
 583	hp100_page(HW_MAP);
 584	mem_mapped = ((hp100_inw(OPTION_LSW) & (HP100_MEM_EN)) != 0);
 585	mem_ptr_phys = 0UL;
 586	mem_ptr_virt = NULL;
 587	memory_size = (8192 << ((hp100_inb(SRAM) >> 5) & 0x07));
 588	virt_memory_size = 0;
 589
 590	/* For memory mapped or busmaster mode, we want the memory address */
 591	if (mem_mapped || (local_mode == 1)) {
 592		mem_ptr_phys = (hp100_inw(MEM_MAP_LSW) | (hp100_inw(MEM_MAP_MSW) << 16));
 593		mem_ptr_phys &= ~0x1fff;	/* 8k alignment */
 594
 595		if (bus == HP100_BUS_ISA && (mem_ptr_phys & ~0xfffff) != 0) {
 596			printk("hp100: Can only use programmed i/o mode.\n");
 597			mem_ptr_phys = 0;
 598			mem_mapped = 0;
 599			local_mode = 3;	/* Use programmed i/o */
 600		}
 601
 602		/* We do not need access to shared memory in busmaster mode */
 603		/* However in slave mode we need to remap high (>1GB) card memory  */
 604		if (local_mode != 1) {	/* = not busmaster */
 605			/* We try with smaller memory sizes, if ioremap fails */
 606			for (virt_memory_size = memory_size; virt_memory_size > 16383; virt_memory_size >>= 1) {
 607				if ((mem_ptr_virt = ioremap((u_long) mem_ptr_phys, virt_memory_size)) == NULL) {
 608#ifdef HP100_DEBUG
 609					printk("hp100: %s: ioremap for 0x%x bytes high PCI memory at 0x%lx failed\n", dev->name, virt_memory_size, mem_ptr_phys);
 610#endif
 611				} else {
 612#ifdef HP100_DEBUG
 613					printk("hp100: %s: remapped 0x%x bytes high PCI memory at 0x%lx to %p.\n", dev->name, virt_memory_size, mem_ptr_phys, mem_ptr_virt);
 614#endif
 615					break;
 616				}
 617			}
 618
 619			if (mem_ptr_virt == NULL) {	/* all ioremap tries failed */
 620				printk("hp100: Failed to ioremap the PCI card memory. Will have to use i/o mapped mode.\n");
 621				local_mode = 3;
 622				virt_memory_size = 0;
 623			}
 624		}
 625	}
 626
 627	if (local_mode == 3) {	/* io mapped forced */
 628		mem_mapped = 0;
 629		mem_ptr_phys = 0;
 630		mem_ptr_virt = NULL;
 631		printk("hp100: Using (slow) programmed i/o mode.\n");
 632	}
 633
 634	/* Initialise the "private" data structure for this card. */
 635	lp = netdev_priv(dev);
 636
 637	spin_lock_init(&lp->lock);
 638	strlcpy(lp->id, eid, HP100_SIG_LEN);
 639	lp->chip = chip;
 640	lp->mode = local_mode;
 641	lp->bus = bus;
 642	lp->pci_dev = pci_dev;
 643	lp->priority_tx = hp100_priority_tx;
 644	lp->rx_ratio = hp100_rx_ratio;
 645	lp->mem_ptr_phys = mem_ptr_phys;
 646	lp->mem_ptr_virt = mem_ptr_virt;
 647	hp100_page(ID_MAC_ADDR);
 648	lp->soft_model = hp100_inb(SOFT_MODEL);
 649	lp->mac1_mode = HP100_MAC1MODE3;
 650	lp->mac2_mode = HP100_MAC2MODE3;
 651	memset(&lp->hash_bytes, 0x00, 8);
 652
 653	dev->base_addr = ioaddr;
 654
 655	lp->memory_size = memory_size;
 656	lp->virt_memory_size = virt_memory_size;
 657	lp->rx_ratio = hp100_rx_ratio;	/* can be conf'd with insmod */
 658
 659	dev->open = hp100_open;
 660	dev->stop = hp100_close;
 661
 662	if (lp->mode == 1)	/* busmaster */
 663		dev->hard_start_xmit = hp100_start_xmit_bm;
 664	else
 665		dev->hard_start_xmit = hp100_start_xmit;
 666
 667	dev->get_stats = hp100_get_stats;
 668	dev->set_multicast_list = &hp100_set_multicast_list;
 669
 670	/* Ask the card for which IRQ line it is configured */
 671	if (bus == HP100_BUS_PCI) {
 672		dev->irq = pci_dev->irq;
 673	} else {
 674		hp100_page(HW_MAP);
 675		dev->irq = hp100_inb(IRQ_CHANNEL) & HP100_IRQMASK;
 676		if (dev->irq == 2)
 677			dev->irq = 9;
 678	}
 679
 680	if (lp->mode == 1)	/* busmaster */
 681		dev->dma = 4;
 682
 683	/* Ask the card for its MAC address and store it for later use. */
 684	hp100_page(ID_MAC_ADDR);
 685	for (i = uc = 0; i < 6; i++)
 686		dev->dev_addr[i] = hp100_inb(LAN_ADDR + i);
 687
 688	/* Reset statistics (counters) */
 689	hp100_clear_stats(lp, ioaddr);
 690
 691	/* If busmaster mode is wanted, a dma-capable memory area is needed for
 692	 * the rx and tx PDLs 
 693	 * PCI cards can access the whole PC memory. Therefore GFP_DMA is not
 694	 * needed for the allocation of the memory area. 
 695	 */
 696
 697	/* TODO: We do not need this with old cards, where PDLs are stored
 698	 * in the cards shared memory area. But currently, busmaster has been
 699	 * implemented/tested only with the lassen chip anyway... */
 700	if (lp->mode == 1) {	/* busmaster */
 701		dma_addr_t page_baddr;
 702		/* Get physically continous memory for TX & RX PDLs    */
 703		/* Conversion to new PCI API :
 704		 * Pages are always aligned and zeroed, no need to it ourself.
 705		 * Doc says should be OK for EISA bus as well - Jean II */
 706		if ((lp->page_vaddr_algn = pci_alloc_consistent(lp->pci_dev, MAX_RINGSIZE, &page_baddr)) == NULL) {
 707			err = -ENOMEM;
 708			goto out2;
 709		}
 710		lp->whatever_offset = ((u_long) page_baddr) - ((u_long) lp->page_vaddr_algn);
 711
 712#ifdef HP100_DEBUG_BM
 713		printk("hp100: %s: Reserved DMA memory from 0x%x to 0x%x\n", dev->name, (u_int) lp->page_vaddr_algn, (u_int) lp->page_vaddr_algn + MAX_RINGSIZE);
 714#endif
 715		lp->rxrcommit = lp->txrcommit = 0;
 716		lp->rxrhead = lp->rxrtail = &(lp->rxring[0]);
 717		lp->txrhead = lp->txrtail = &(lp->txring[0]);
 718	}
 719
 720	/* Initialise the card. */
 721	/* (I'm not really sure if it's a good idea to do this during probing, but 
 722	 * like this it's assured that the lan connection type can be sensed
 723	 * correctly)
 724	 */
 725	hp100_hwinit(dev);
 726
 727	/* Try to find out which kind of LAN the card is connected to. */
 728	lp->lan_type = hp100_sense_lan(dev);
 729
 730	/* Print out a message what about what we think we have probed. */
 731	printk("hp100: at 0x%x, IRQ %d, ", ioaddr, dev->irq);
 732	switch (bus) {
 733	case HP100_BUS_EISA:
 734		printk("EISA");
 735		break;
 736	case HP100_BUS_PCI:
 737		printk("PCI");
 738		break;
 739	default:
 740		printk("ISA");
 741		break;
 742	}
 743	printk(" bus, %dk SRAM (rx/tx %d%%).\n", lp->memory_size >> 10, lp->rx_ratio);
 744
 745	if (lp->mode == 2) {	/* memory mapped */
 746		printk("hp100: Memory area at 0x%lx-0x%lx", mem_ptr_phys,
 747				(mem_ptr_phys + (mem_ptr_phys > 0x100000 ? (u_long) lp->memory_size : 16 * 1024)) - 1);
 748		if (mem_ptr_virt)
 749			printk(" (virtual base %p)", mem_ptr_virt);
 750		printk(".\n");
 751
 752		/* Set for info when doing ifconfig */
 753		dev->mem_start = mem_ptr_phys;
 754		dev->mem_end = mem_ptr_phys + lp->memory_size;
 755	}
 756
 757	printk("hp100: ");
 758	if (lp->lan_type != HP100_LAN_ERR)
 759		printk("Adapter is attached to ");
 760	switch (lp->lan_type) {
 761	case HP100_LAN_100:
 762		printk("100Mb/s Voice Grade AnyLAN network.\n");
 763		break;
 764	case HP100_LAN_10:
 765		printk("10Mb/s network (10baseT).\n");
 766		break;
 767	case HP100_LAN_COAX:
 768		printk("10Mb/s network (coax).\n");
 769		break;
 770	default:
 771		printk("Warning! Link down.\n");
 772	}
 773
 774	err = register_netdev(dev);
 775	if (err)
 776		goto out3;
 777
 778	return 0;
 779out3:
 780	if (local_mode == 1)
 781		pci_free_consistent(lp->pci_dev, MAX_RINGSIZE + 0x0f, 
 782				    lp->page_vaddr_algn, 
 783				    virt_to_whatever(dev, lp->page_vaddr_algn));
 784	if (mem_ptr_virt)
 785		iounmap(mem_ptr_virt);
 786out2:
 787	release_region(ioaddr, HP100_REGION_SIZE);
 788out1:
 789	return err;
 790}
 791
 792/* This procedure puts the card into a stable init state */
 793static void hp100_hwinit(struct net_device *dev)
 794{
 795	int ioaddr = dev->base_addr;
 796	struct hp100_private *lp = netdev_priv(dev);
 797
 798#ifdef HP100_DEBUG_B
 799	hp100_outw(0x4202, TRACE);
 800	printk("hp100: %s: hwinit\n", dev->name);
 801#endif
 802
 803	/* Initialise the card. -------------------------------------------- */
 804
 805	/* Clear all pending Ints and disable Ints */
 806	hp100_page(PERFORMANCE);
 807	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
 808	hp100_outw(0xffff, IRQ_STATUS);	/* clear all pending ints */
 809
 810	hp100_outw(HP100_INT_EN | HP100_RESET_LB, OPTION_LSW);
 811	hp100_outw(HP100_TRI_INT | HP100_SET_HB, OPTION_LSW);
 812
 813	if (lp->mode == 1) {
 814		hp100_BM_shutdown(dev);	/* disables BM, puts cascade in reset */
 815		wait();
 816	} else {
 817		hp100_outw(HP100_INT_EN | HP100_RESET_LB, OPTION_LSW);
 818		hp100_cascade_reset(dev, 1);
 819		hp100_page(MAC_CTRL);
 820		hp100_andb(~(HP100_RX_EN | HP100_TX_EN), MAC_CFG_1);
 821	}
 822
 823	/* Initiate EEPROM reload */
 824	hp100_load_eeprom(dev, 0);
 825
 826	wait();
 827
 828	/* Go into reset again. */
 829	hp100_cascade_reset(dev, 1);
 830
 831	/* Set Option Registers to a safe state  */
 832	hp100_outw(HP100_DEBUG_EN |
 833		   HP100_RX_HDR |
 834		   HP100_EE_EN |
 835		   HP100_BM_WRITE |
 836		   HP100_BM_READ | HP100_RESET_HB |
 837		   HP100_FAKE_INT |
 838		   HP100_INT_EN |
 839		   HP100_MEM_EN |
 840		   HP100_IO_EN | HP100_RESET_LB, OPTION_LSW);
 841
 842	hp100_outw(HP100_TRI_INT |
 843		   HP100_MMAP_DIS | HP100_SET_HB, OPTION_LSW);
 844
 845	hp100_outb(HP100_PRIORITY_TX |
 846		   HP100_ADV_NXT_PKT |
 847		   HP100_TX_CMD | HP100_RESET_LB, OPTION_MSW);
 848
 849	/* TODO: Configure MMU for Ram Test. */
 850	/* TODO: Ram Test. */
 851
 852	/* Re-check if adapter is still at same i/o location      */
 853	/* (If the base i/o in eeprom has been changed but the    */
 854	/* registers had not been changed, a reload of the eeprom */
 855	/* would move the adapter to the address stored in eeprom */
 856
 857	/* TODO: Code to implement. */
 858
 859	/* Until here it was code from HWdiscover procedure. */
 860	/* Next comes code from mmuinit procedure of SCO BM driver which is
 861	 * called from HWconfigure in the SCO driver.  */
 862
 863	/* Initialise MMU, eventually switch on Busmaster Mode, initialise 
 864	 * multicast filter...
 865	 */
 866	hp100_mmuinit(dev);
 867
 868	/* We don't turn the interrupts on here - this is done by start_interface. */
 869	wait();			/* TODO: Do we really need this? */
 870
 871	/* Enable Hardware (e.g. unreset) */
 872	hp100_cascade_reset(dev, 0);
 873
 874	/* ------- initialisation complete ----------- */
 875
 876	/* Finally try to log in the Hub if there may be a VG connection. */
 877	if ((lp->lan_type == HP100_LAN_100) || (lp->lan_type == HP100_LAN_ERR))
 878		hp100_login_to_vg_hub(dev, 0);	/* relogin */
 879
 880}
 881
 882
 883/* 
 884 * mmuinit - Reinitialise Cascade MMU and MAC settings.
 885 * Note: Must already be in reset and leaves card in reset. 
 886 */
 887static void hp100_mmuinit(struct net_device *dev)
 888{
 889	int ioaddr = dev->base_addr;
 890	struct hp100_private *lp = netdev_priv(dev);
 891	int i;
 892
 893#ifdef HP100_DEBUG_B
 894	hp100_outw(0x4203, TRACE);
 895	printk("hp100: %s: mmuinit\n", dev->name);
 896#endif
 897
 898#ifdef HP100_DEBUG
 899	if (0 != (hp100_inw(OPTION_LSW) & HP100_HW_RST)) {
 900		printk("hp100: %s: Not in reset when entering mmuinit. Fix me.\n", dev->name);
 901		return;
 902	}
 903#endif
 904
 905	/* Make sure IRQs are masked off and ack'ed. */
 906	hp100_page(PERFORMANCE);
 907	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
 908	hp100_outw(0xffff, IRQ_STATUS);	/* ack IRQ */
 909
 910	/*
 911	 * Enable Hardware 
 912	 * - Clear Debug En, Rx Hdr Pipe, EE En, I/O En, Fake Int and Intr En
 913	 * - Set Tri-State Int, Bus Master Rd/Wr, and Mem Map Disable
 914	 * - Clear Priority, Advance Pkt and Xmit Cmd
 915	 */
 916
 917	hp100_outw(HP100_DEBUG_EN |
 918		   HP100_RX_HDR |
 919		   HP100_EE_EN | HP100_RESET_HB |
 920		   HP100_IO_EN |
 921		   HP100_FAKE_INT |
 922		   HP100_INT_EN | HP100_RESET_LB, OPTION_LSW);
 923
 924	hp100_outw(HP100_TRI_INT | HP100_SET_HB, OPTION_LSW);
 925
 926	if (lp->mode == 1) {	/* busmaster */
 927		hp100_outw(HP100_BM_WRITE |
 928			   HP100_BM_READ |
 929			   HP100_MMAP_DIS | HP100_SET_HB, OPTION_LSW);
 930	} else if (lp->mode == 2) {	/* memory mapped */
 931		hp100_outw(HP100_BM_WRITE |
 932			   HP100_BM_READ | HP100_RESET_HB, OPTION_LSW);
 933		hp100_outw(HP100_MMAP_DIS | HP100_RESET_HB, OPTION_LSW);
 934		hp100_outw(HP100_MEM_EN | HP100_SET_LB, OPTION_LSW);
 935		hp100_outw(HP100_IO_EN | HP100_SET_LB, OPTION_LSW);
 936	} else if (lp->mode == 3) {	/* i/o mapped mode */
 937		hp100_outw(HP100_MMAP_DIS | HP100_SET_HB |
 938			   HP100_IO_EN | HP100_SET_LB, OPTION_LSW);
 939	}
 940
 941	hp100_page(HW_MAP);
 942	hp100_outb(0, EARLYRXCFG);
 943	hp100_outw(0, EARLYTXCFG);
 944
 945	/*
 946	 * Enable Bus Master mode
 947	 */
 948	if (lp->mode == 1) {	/* busmaster */
 949		/* Experimental: Set some PCI configuration bits */
 950		hp100_page(HW_MAP);
 951		hp100_andb(~HP100_PDL_USE3, MODECTRL1);	/* BM engine read maximum */
 952		hp100_andb(~HP100_TX_DUALQ, MODECTRL1);	/* No Queue for Priority TX */
 953
 954		/* PCI Bus failures should result in a Misc. Interrupt */
 955		hp100_orb(HP100_EN_BUS_FAIL, MODECTRL2);
 956
 957		hp100_outw(HP100_BM_READ | HP100_BM_WRITE | HP100_SET_HB, OPTION_LSW);
 958		hp100_page(HW_MAP);
 959		/* Use Burst Mode and switch on PAGE_CK */
 960		hp100_orb(HP100_BM_BURST_RD | HP100_BM_BURST_WR, BM);
 961		if ((lp->chip == HP100_CHIPID_RAINIER) || (lp->chip == HP100_CHIPID_SHASTA))
 962			hp100_orb(HP100_BM_PAGE_CK, BM);
 963		hp100_orb(HP100_BM_MASTER, BM);
 964	} else {		/* not busmaster */
 965
 966		hp100_page(HW_MAP);
 967		hp100_andb(~HP100_BM_MASTER, BM);
 968	}
 969
 970	/*
 971	 * Divide card memory into regions for Rx, Tx and, if non-ETR chip, PDLs
 972	 */
 973	hp100_page(MMU_CFG);
 974	if (lp->mode == 1) {	/* only needed for Busmaster */
 975		int xmit_stop, recv_stop;
 976
 977		if ((lp->chip == HP100_CHIPID_RAINIER)
 978		    || (lp->chip == HP100_CHIPID_SHASTA)) {
 979			int pdl_stop;
 980
 981			/*
 982			 * Each pdl is 508 bytes long. (63 frags * 4 bytes for address and
 983			 * 4 bytes for header). We will leave NUM_RXPDLS * 508 (rounded
 984			 * to the next higher 1k boundary) bytes for the rx-pdl's
 985			 * Note: For non-etr chips the transmit stop register must be
 986			 * programmed on a 1k boundary, i.e. bits 9:0 must be zero. 
 987			 */
 988			pdl_stop = lp->memory_size;
 989			xmit_stop = (pdl_stop - 508 * (MAX_RX_PDL) - 16) & ~(0x03ff);
 990			recv_stop = (xmit_stop * (lp->rx_ratio) / 100) & ~(0x03ff);
 991			hp100_outw((pdl_stop >> 4) - 1, PDL_MEM_STOP);
 992#ifdef HP100_DEBUG_BM
 993			printk("hp100: %s: PDL_STOP = 0x%x\n", dev->name, pdl_stop);
 994#endif
 995		} else {
 996			/* ETR chip (Lassen) in busmaster mode */
 997			xmit_stop = (lp->memory_size) - 1;
 998			recv_stop = ((lp->memory_size * lp->rx_ratio) / 100) & ~(0x03ff);
 999		}
1000
1001		hp100_outw(xmit_stop >> 4, TX_MEM_STOP);
1002		hp100_outw(recv_stop >> 4, RX_MEM_STOP);
1003#ifdef HP100_DEBUG_BM
1004		printk("hp100: %s: TX_STOP  = 0x%x\n", dev->name, xmit_stop >> 4);
1005		printk("hp100: %s: RX_STOP  = 0x%x\n", dev->name, recv_stop >> 4);
1006#endif
1007	} else {
1008		/* Slave modes (memory mapped and programmed io)  */
1009		hp100_outw((((lp->memory_size * lp->rx_ratio) / 100) >> 4), RX_MEM_STOP);
1010		hp100_outw(((lp->memory_size - 1) >> 4), TX_MEM_STOP);
1011#ifdef HP100_DEBUG
1012		printk("hp100: %s: TX_MEM_STOP: 0x%x\n", dev->name, hp100_inw(TX_MEM_STOP));
1013		printk("hp100: %s: RX_MEM_STOP: 0x%x\n", dev->name, hp100_inw(RX_MEM_STOP));
1014#endif
1015	}
1016
1017	/* Write MAC address into page 1 */
1018	hp100_page(MAC_ADDRESS);
1019	for (i = 0; i < 6; i++)
1020		hp100_outb(dev->dev_addr[i], MAC_ADDR + i);
1021
1022	/* Zero the multicast hash registers */
1023	for (i = 0; i < 8; i++)
1024		hp100_outb(0x0, HASH_BYTE0 + i);
1025
1026	/* Set up MAC defaults */
1027	hp100_page(MAC_CTRL);
1028
1029	/* Go to LAN Page and zero all filter bits */
1030	/* Zero accept error, accept multicast, accept broadcast and accept */
1031	/* all directed packet bits */
1032	hp100_andb(~(HP100_RX_EN |
1033		     HP100_TX_EN |
1034		     HP100_ACC_ERRORED |
1035		     HP100_ACC_MC |
1036		     HP100_ACC_BC | HP100_ACC_PHY), MAC_CFG_1);
1037
1038	hp100_outb(0x00, MAC_CFG_2);
1039
1040	/* Zero the frame format bit. This works around a training bug in the */
1041	/* new hubs. */
1042	hp100_outb(0x00, VG_LAN_CFG_2);	/* (use 802.3) */
1043
1044	if (lp->priority_tx)
1045		hp100_outb(HP100_PRIORITY_TX | HP100_SET_LB, OPTION_MSW);
1046	else
1047		hp100_outb(HP100_PRIORITY_TX | HP100_RESET_LB, OPTION_MSW);
1048
1049	hp100_outb(HP100_ADV_NXT_PKT |
1050		   HP100_TX_CMD | HP100_RESET_LB, OPTION_MSW);
1051
1052	/* If busmaster, initialize the PDLs */
1053	if (lp->mode == 1)
1054		hp100_init_pdls(dev);
1055
1056	/* Go to performance page and initalize isr and imr registers */
1057	hp100_page(PERFORMANCE);
1058	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
1059	hp100_outw(0xffff, IRQ_STATUS);	/* ack IRQ */
1060}
1061
1062/*
1063 *  open/close functions
1064 */
1065
1066static int hp100_open(struct net_device *dev)
1067{
1068	struct hp100_private *lp = netdev_priv(dev);
1069#ifdef HP100_DEBUG_B
1070	int ioaddr = dev->base_addr;
1071#endif
1072
1073#ifdef HP100_DEBUG_B
1074	hp100_outw(0x4204, TRACE);
1075	printk("hp100: %s: open\n", dev->name);
1076#endif
1077
1078	/* New: if bus is PCI or EISA, interrupts might be shared interrupts */
1079	if (request_irq(dev->irq, hp100_interrupt,
1080			lp->bus == HP100_BUS_PCI || lp->bus ==
1081			HP100_BUS_EISA ? SA_SHIRQ : SA_INTERRUPT,
1082			"hp100", dev)) {
1083		printk("hp100: %s: unable to get IRQ %d\n", dev->name, dev->irq);
1084		return -EAGAIN;
1085	}
1086
1087	dev->trans_start = jiffies;
1088	netif_start_queue(dev);
1089
1090	lp->lan_type = hp100_sense_lan(dev);
1091	lp->mac1_mode = HP100_MAC1MODE3;
1092	lp->mac2_mode = HP100_MAC2MODE3;
1093	memset(&lp->hash_bytes, 0x00, 8);
1094
1095	hp100_stop_interface(dev);
1096
1097	hp100_hwinit(dev);
1098
1099	hp100_start_interface(dev);	/* sets mac modes, enables interrupts */
1100
1101	return 0;
1102}
1103
1104/* The close function is called when the interface is to be brought down */
1105static int hp100_close(struct net_device *dev)
1106{
1107	int ioaddr = dev->base_addr;
1108	struct hp100_private *lp = netdev_priv(dev);
1109
1110#ifdef HP100_DEBUG_B
1111	hp100_outw(0x4205, TRACE);
1112	printk("hp100: %s: close\n", dev->name);
1113#endif
1114
1115	hp100_page(PERFORMANCE);
1116	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all IRQs */
1117
1118	hp100_stop_interface(dev);
1119
1120	if (lp->lan_type == HP100_LAN_100)
1121		lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1122
1123	netif_stop_queue(dev);
1124
1125	free_irq(dev->irq, dev);
1126
1127#ifdef HP100_DEBUG
1128	printk("hp100: %s: close LSW = 0x%x\n", dev->name,
1129	       hp100_inw(OPTION_LSW));
1130#endif
1131
1132	return 0;
1133}
1134
1135
1136/*
1137 * Configure the PDL Rx rings and LAN 
1138 */
1139static void hp100_init_pdls(struct net_device *dev)
1140{
1141	struct hp100_private *lp = netdev_priv(dev);
1142	hp100_ring_t *ringptr;
1143	u_int *pageptr;		/* Warning : increment by 4 - Jean II */
1144	int i;
1145
1146#ifdef HP100_DEBUG_B
1147	int ioaddr = dev->base_addr;
1148#endif
1149
1150#ifdef HP100_DEBUG_B
1151	hp100_outw(0x4206, TRACE);
1152	printk("hp100: %s: init pdls\n", dev->name);
1153#endif
1154
1155	if (0 == lp->page_vaddr_algn)
1156		printk("hp100: %s: Warning: lp->page_vaddr_algn not initialised!\n", dev->name);
1157	else {
1158		/* pageptr shall point into the DMA accessible memory region  */
1159		/* we use this pointer to status the upper limit of allocated */
1160		/* memory in the allocated page. */
1161		/* note: align the pointers to the pci cache line size */
1162		memset(lp->page_vaddr_algn, 0, MAX_RINGSIZE);	/* Zero  Rx/Tx ring page */
1163		pageptr = lp->page_vaddr_algn;
1164
1165		lp->rxrcommit = 0;
1166		ringptr = lp->rxrhead = lp->rxrtail = &(lp->rxring[0]);
1167
1168		/* Initialise Rx Ring */
1169		for (i = MAX_RX_PDL - 1; i >= 0; i--) {
1170			lp->rxring[i].next = ringptr;
1171			ringptr = &(lp->rxring[i]);
1172			pageptr += hp100_init_rxpdl(dev, ringptr, pageptr);
1173		}
1174
1175		/* Initialise Tx Ring */
1176		lp->txrcommit = 0;
1177		ringptr = lp->txrhead = lp->txrtail = &(lp->txring[0]);
1178		for (i = MAX_TX_PDL - 1; i >= 0; i--) {
1179			lp->txring[i].next = ringptr;
1180			ringptr = &(lp->txring[i]);
1181			pageptr += hp100_init_txpdl(dev, ringptr, pageptr);
1182		}
1183	}
1184}
1185
1186
1187/* These functions "format" the entries in the pdl structure   */
1188/* They return how much memory the fragments need.            */
1189static int hp100_init_rxpdl(struct net_device *dev,
1190			    register hp100_ring_t * ringptr,
1191			    register u32 * pdlptr)
1192{
1193	/* pdlptr is starting address for this pdl */
1194
1195	if (0 != (((unsigned long) pdlptr) & 0xf))
1196		printk("hp100: %s: Init rxpdl: Unaligned pdlptr 0x%lx.\n",
1197		       dev->name, (unsigned long) pdlptr);
1198
1199	ringptr->pdl = pdlptr + 1;
1200	ringptr->pdl_paddr = virt_to_whatever(dev, pdlptr + 1);
1201	ringptr->skb = (void *) NULL;
1202
1203	/* 
1204	 * Write address and length of first PDL Fragment (which is used for
1205	 * storing the RX-Header
1206	 * We use the 4 bytes _before_ the PDH in the pdl memory area to 
1207	 * store this information. (PDH is at offset 0x04)
1208	 */
1209	/* Note that pdlptr+1 and not pdlptr is the pointer to the PDH */
1210
1211	*(pdlptr + 2) = (u_int) virt_to_whatever(dev, pdlptr);	/* Address Frag 1 */
1212	*(pdlptr + 3) = 4;	/* Length  Frag 1 */
1213
1214	return ((((MAX_RX_FRAG * 2 + 2) + 3) / 4) * 4);
1215}
1216
1217
1218static int hp100_init_txpdl(struct net_device *dev,
1219			    register hp100_ring_t * ringptr,
1220			    register u32 * pdlptr)
1221{
1222	if (0 != (((unsigned long) pdlptr) & 0xf))
1223		printk("hp100: %s: Init txpdl: Unaligned pdlptr 0x%lx.\n", dev->name, (unsigned long) pdlptr);
1224
1225	ringptr->pdl = pdlptr;	/* +1; */
1226	ringptr->pdl_paddr = virt_to_whatever(dev, pdlptr);	/* +1 */
1227	ringptr->skb = (void *) NULL;
1228
1229	return ((((MAX_TX_FRAG * 2 + 2) + 3) / 4) * 4);
1230}
1231
1232/*
1233 * hp100_build_rx_pdl allocates an skb_buff of maximum size plus two bytes 
1234 * for possible odd word alignment rounding up to next dword and set PDL
1235 * address for fragment#2 
1236 * Returns: 0 if unable to allocate skb_buff
1237 *          1 if successful
1238 */
1239static int hp100_build_rx_pdl(hp100_ring_t * ringptr,
1240			      struct net_device *dev)
1241{
1242#ifdef HP100_DEBUG_B
1243	int ioaddr = dev->base_addr;
1244#endif
1245#ifdef HP100_DEBUG_BM
1246	u_int *p;
1247#endif
1248
1249#ifdef HP100_DEBUG_B
1250	hp100_outw(0x4207, TRACE);
1251	printk("hp100: %s: build rx pdl\n", dev->name);
1252#endif
1253
1254	/* Allocate skb buffer of maximum size */
1255	/* Note: This depends on the alloc_skb functions allocating more 
1256	 * space than requested, i.e. aligning to 16bytes */
1257
1258	ringptr->skb = dev_alloc_skb(((MAX_ETHER_SIZE + 2 + 3) / 4) * 4);
1259
1260	if (NULL != ringptr->skb) {
1261		/* 
1262		 * Reserve 2 bytes at the head of the buffer to land the IP header
1263		 * on a long word boundary (According to the Network Driver section
1264		 * in the Linux KHG, this should help to increase performance.)
1265		 */
1266		skb_reserve(ringptr->skb, 2);
1267
1268		ringptr->skb->dev = dev;
1269		ringptr->skb->data = (u_char *) skb_put(ringptr->skb, MAX_ETHER_SIZE);
1270
1271		/* ringptr->pdl points to the beginning of the PDL, i.e. the PDH */
1272		/* Note: 1st Fragment is used for the 4 byte packet status
1273		 * (receive header). Its PDL entries are set up by init_rxpdl. So 
1274		 * here we only have to set up the PDL fragment entries for the data
1275		 * part. Those 4 bytes will be stored in the DMA memory region 
1276		 * directly before the PDL. 
1277		 */
1278#ifdef HP100_DEBUG_BM
1279		printk("hp100: %s: build_rx_pdl: PDH@0x%x, skb->data (len %d) at 0x%x\n",
1280				     dev->name, (u_int) ringptr->pdl,
1281				     ((MAX_ETHER_SIZE + 2 + 3) / 4) * 4,
1282				     (unsigned int) ringptr->skb->data);
1283#endif
1284
1285		/* Conversion to new PCI API : map skbuf data to PCI bus.
1286		 * Doc says it's OK for EISA as well - Jean II */
1287		ringptr->pdl[0] = 0x00020000;	/* Write PDH */
1288		ringptr->pdl[3] = pdl_map_data(netdev_priv(dev), 
1289					       ringptr->skb->data);
1290		ringptr->pdl[4] = MAX_ETHER_SIZE;	/* Length of Data */
1291
1292#ifdef HP100_DEBUG_BM
1293		for (p = (ringptr->pdl); p < (ringptr->pdl + 5); p++)
1294			printk("hp100: %s: Adr 0x%.8x = 0x%.8x\n", dev->name, (u_int) p, (u_int) * p);
1295#endif
1296		return (1);
1297	}
1298	/* else: */
1299	/* alloc_skb failed (no memory) -> still can receive the header
1300	 * fragment into PDL memory. make PDL safe by clearing msgptr and
1301	 * making the PDL only 1 fragment (i.e. the 4 byte packet status)
1302	 */
1303#ifdef HP100_DEBUG_BM
1304	printk("hp100: %s: build_rx_pdl: PDH@0x%x, No space for skb.\n", dev->name, (u_int) ringptr->pdl);
1305#endif
1306
1307	ringptr->pdl[0] = 0x00010000;	/* PDH: Count=1 Fragment */
1308
1309	return (0);
1310}
1311
1312/*
1313 *  hp100_rxfill - attempt to fill the Rx Ring will empty skb's
1314 *
1315 * Makes assumption that skb's are always contiguous memory areas and
1316 * therefore PDLs contain only 2 physical fragments.
1317 * -  While the number of Rx PDLs with buffers is less than maximum
1318 *      a.  Get a maximum packet size skb
1319 *      b.  Put the physical address of the buffer into the PDL.
1320 *      c.  Output physical address of PDL to adapter.
1321 */
1322static void hp100_rxfill(struct net_device *dev)
1323{
1324	int ioaddr = dev->base_addr;
1325
1326	struct hp100_private *lp = netdev_priv(dev);
1327	hp100_ring_t *ringptr;
1328
1329#ifdef HP100_DEBUG_B
1330	hp100_outw(0x4208, TRACE);
1331	printk("hp100: %s: rxfill\n", dev->name);
1332#endif
1333
1334	hp100_page(PERFORMANCE);
1335
1336	while (lp->rxrcommit < MAX_RX_PDL) {
1337		/*
1338		   ** Attempt to get a buffer and build a Rx PDL.
1339		 */
1340		ringptr = lp->rxrtail;
1341		if (0 == hp100_build_rx_pdl(ringptr, dev)) {
1342			return;	/* None available, return */
1343		}
1344
1345		/* Hand this PDL over to the card */
1346		/* Note: This needs performance page selected! */
1347#ifdef HP100_DEBUG_BM
1348		printk("hp100: %s: rxfill: Hand to card: pdl #%d @0x%x phys:0x%x, buffer: 0x%x\n",
1349				     dev->name, lp->rxrcommit, (u_int) ringptr->pdl,
1350				     (u_int) ringptr->pdl_paddr, (u_int) ringptr->pdl[3]);
1351#endif
1352
1353		hp100_outl((u32) ringptr->pdl_paddr, RX_PDA);
1354
1355		lp->rxrcommit += 1;
1356		lp->rxrtail = ringptr->next;
1357	}
1358}
1359
1360/*
1361 * BM_shutdown - shutdown bus mastering and leave chip in reset state
1362 */
1363
1364static void hp100_BM_shutdown(struct net_device *dev)
1365{
1366	int ioaddr = dev->base_addr;
1367	struct hp100_private *lp = netdev_priv(dev);
1368	unsigned long time;
1369
1370#ifdef HP100_DEBUG_B
1371	hp100_outw(0x4209, TRACE);
1372	printk("hp100: %s: bm shutdown\n", dev->name);
1373#endif
1374
1375	hp100_page(PERFORMANCE);
1376	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
1377	hp100_outw(0xffff, IRQ_STATUS);	/* Ack all ints */
1378
1379	/* Ensure Interrupts are off */
1380	hp100_outw(HP100_INT_EN | HP100_RESET_LB, OPTION_LSW);
1381
1382	/* Disable all MAC activity */
1383	hp100_page(MAC_CTRL);
1384	hp100_andb(~(HP100_RX_EN | HP100_TX_EN), MAC_CFG_1);	/* stop rx/tx */
1385
1386	/* If cascade MMU is not already in reset */
1387	if (0 != (hp100_inw(OPTION_LSW) & HP100_HW_RST)) {
1388		/* Wait 1.3ms (10Mb max packet time) to ensure MAC is idle so
1389		 * MMU pointers will not be reset out from underneath
1390		 */
1391		hp100_page(MAC_CTRL);
1392		for (time = 0; time < 5000; time++) {
1393			if ((hp100_inb(MAC_CFG_1) & (HP100_TX_IDLE | HP100_RX_IDLE)) == (HP100_TX_IDLE | HP100_RX_IDLE))
1394				break;
1395		}
1396
1397		/* Shutdown algorithm depends on the generation of Cascade */
1398		if (lp->chip == HP100_CHIPID_LASSEN) {	/* ETR shutdown/reset */
1399			/* Disable Busmaster mode and wait for bit to go to zero. */
1400			hp100_page(HW_MAP);
1401			hp100_andb(~HP100_BM_MASTER, BM);
1402			/* 100 ms timeout */
1403			for (time = 0; time < 32000; time++) {
1404				if (0 == (hp100_inb(BM) & HP100_BM_MASTER))
1405					break;
1406			}
1407		} else {	/* Shasta or Rainier Shutdown/Reset */
1408			/* To ensure all bus master inloading activity has ceased,
1409			 * wait for no Rx PDAs or no Rx packets on card. 
1410			 */
1411			hp100_page(PERFORMANCE);
1412			/* 100 ms timeout */
1413			for (time = 0; time < 10000; time++) {
1414				/* RX_PDL: PDLs not executed. */
1415				/* RX_PKT_CNT: RX'd packets on card. */
1416				if ((hp100_inb(RX_PDL) == 0) && (hp100_inb(RX_PKT_CNT) == 0))
1417					break;
1418			}
1419
1420			if (time >= 10000)
1421				printk("hp100: %s: BM shutdown error.\n", dev->name);
1422
1423			/* To ensure all bus master outloading activity has ceased,
1424			 * wait until the Tx PDA count goes to zero or no more Tx space
1425			 * available in the Tx region of the card. 
1426			 */
1427			/* 100 ms timeout */
1428			for (time = 0; time < 10000; time++) {
1429				if ((0 == hp100_inb(TX_PKT_CNT)) &&
1430				    (0 != (hp100_inb(TX_MEM_FREE) & HP100_AUTO_COMPARE)))
1431					break;
1432			}
1433
1434			/* Disable Busmaster mode */
1435			hp100_page(HW_MAP);
1436			hp100_andb(~HP100_BM_MASTER, BM);
1437		}	/* end of shutdown procedure for non-etr parts */
1438
1439		hp100_cascade_reset(dev, 1);
1440	}
1441	hp100_page(PERFORMANCE);
1442	/* hp100_outw( HP100_BM_READ | HP100_BM_WRITE | HP100_RESET_HB, OPTION_LSW ); */
1443	/* Busmaster mode should be shut down now. */
1444}
1445
1446static int hp100_check_lan(struct net_device *dev)
1447{
1448	struct hp100_private *lp = netdev_priv(dev);
1449
1450	if (lp->lan_type < 0) {	/* no LAN type detected yet? */
1451		hp100_stop_interface(dev);
1452		if ((lp->lan_type = hp100_sense_lan(dev)) < 0) {
1453			printk("hp100: %s: no connection found - check wire\n", dev->name);
1454			hp100_start_interface(dev);	/* 10Mb/s RX packets maybe handled */
1455			return -EIO;
1456		}
1457		if (lp->lan_type == HP100_LAN_100)
1458			lp->hub_status = hp100_login_to_vg_hub(dev, 0);	/* relogin */
1459		hp100_start_interface(dev);
1460	}
1461	return 0;
1462}
1463
1464/* 
1465 *  transmit functions
1466 */
1467
1468/* tx function for busmaster mode */
1469static int hp100_start_xmit_bm(struct sk_buff *skb, struct net_device *dev)
1470{
1471	unsigned long flags;
1472	int i, ok_flag;
1473	int ioaddr = dev->base_addr;
1474	struct hp100_private *lp = netdev_priv(dev);
1475	hp100_ring_t *ringptr;
1476
1477#ifdef HP100_DEBUG_B
1478	hp100_outw(0x4210, TRACE);
1479	printk("hp100: %s: start_xmit_bm\n", dev->name);
1480#endif
1481
1482	if (skb == NULL) {
1483		return 0;
1484	}
1485
1486	if (skb->len <= 0)
1487		return 0;
1488		
1489	if (skb->len < ETH_ZLEN && lp->chip == HP100_CHIPID_SHASTA) {
1490		skb = skb_padto(skb, ETH_ZLEN);
1491		if (skb == NULL)
1492			return 0;
1493	}
1494
1495	/* Get Tx ring tail pointer */
1496	if (lp->txrtail->next == lp->txrhead) {
1497		/* No memory. */
1498#ifdef HP100_DEBUG
1499		printk("hp100: %s: start_xmit_bm: No TX PDL available.\n", dev->name);
1500#endif
1501		/* not waited long enough since last tx? */
1502		if (jiffies - dev->trans_start < HZ)
1503			return -EAGAIN;
1504
1505		if (hp100_check_lan(dev))
1506			return -EIO;
1507
1508		if (lp->lan_type == HP100_LAN_100 && lp->hub_status < 0) {
1509			/* we have a 100Mb/s adapter but it isn't connected to hub */
1510			printk("hp100: %s: login to 100Mb/s hub retry\n", dev->name);
1511			hp100_stop_interface(dev);
1512			lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1513			hp100_start_interface(dev);
1514		} else {
1515			spin_lock_irqsave(&lp->lock, flags);
1516			hp100_ints_off();	/* Useful ? Jean II */
1517			i = hp100_sense_lan(dev);
1518			hp100_ints_on();
1519			spin_unlock_irqrestore(&lp->lock, flags);
1520			if (i == HP100_LAN_ERR)
1521				printk("hp100: %s: link down detected\n", dev->name);
1522			else if (lp->lan_type != i) {	/* cable change! */
1523				/* it's very hard - all network settings must be changed!!! */
1524				printk("hp100: %s: cable change 10Mb/s <-> 100Mb/s detected\n", dev->name);
1525				lp->lan_type = i;
1526				hp100_stop_interface(dev);
1527				if (lp->lan_type == HP100_LAN_100)
1528					lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1529				hp100_start_interface(dev);
1530			} else {
1531				printk("hp100: %s: interface reset\n", dev->name);
1532				hp100_stop_interface(dev);
1533				if (lp->lan_type == HP100_LAN_100)
1534					lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1535				hp100_start_interface(dev);
1536			}
1537		}
1538
1539		dev->trans_start = jiffies;
1540		return -EAGAIN;
1541	}
1542
1543	/*
1544	 * we have to turn int's off before modifying this, otherwise
1545	 * a tx_pdl_cleanup could occur at the same time
1546	 */
1547	spin_lock_irqsave(&lp->lock, flags);
1548	ringptr = lp->txrtail;
1549	lp->txrtail = ringptr->next;
1550
1551	/* Check whether packet has minimal packet size */
1552	ok_flag = skb->len >= HP100_MIN_PACKET_SIZE;
1553	i = ok_flag ? skb->len : HP100_MIN_PACKET_SIZE;
1554
1555	ringptr->skb = skb;
1556	ringptr->pdl[0] = ((1 << 16) | i);	/* PDH: 1 Fragment & length */
1557	if (lp->chip == HP100_CHIPID_SHASTA) {
1558		/* TODO:Could someone who has the EISA card please check if this works? */
1559		ringptr->pdl[2] = i;
1560	} else {		/* Lassen */
1561		/* In the PDL, don't use the padded size but the real packet size: */
1562		ringptr->pdl[2] = skb->len;	/* 1st Frag: Length of frag */
1563	}
1564	/* Conversion to new PCI API : map skbuf data to PCI bus.
1565	 * Doc says it's OK for EISA as well - Jean II */
1566	ringptr->pdl[1] = ((u32) pci_map_single(lp->pci_dev, skb->data, ringptr->pdl[2], PCI_DMA_TODEVICE));	/* 1st Frag: Adr. of data */
1567
1568	/* Hand this PDL to the card. */
1569	hp100_outl(ringptr->pdl_paddr, TX_PDA_L);	/* Low Prio. Queue */
1570
1571	lp->txrcommit++;
1572	spin_unlock_irqrestore(&lp->lock, flags);
1573
1574	/* Update statistics */
1575	lp->stats.tx_packets++;
1576	lp->stats.tx_bytes += skb->len;
1577	dev->trans_start = jiffies;
1578
1579	return 0;
1580}
1581
1582
1583/* clean_txring checks if packets have been sent by the card by reading
1584 * the TX_PDL register from the performance page and comparing it to the
1585 * number of commited packets. It then frees the skb's of the packets that
1586 * obviously have been sent to the network.
1587 *
1588 * Needs the PERFORMANCE page selected. 
1589 */
1590static void hp100_clean_txring(struct net_device *dev)
1591{
1592	struct hp100_private *lp = netdev_priv(dev);
1593	int ioaddr = dev->base_addr;
1594	int donecount;
1595
1596#ifdef HP100_DEBUG_B
1597	hp100_outw(0x4211, TRACE);
1598	printk("hp100: %s: clean txring\n", dev->name);
1599#endif
1600
1601	/* How many PDLs have been transmitted? */
1602	donecount = (lp->txrcommit) - hp100_inb(TX_PDL);
1603
1604#ifdef HP100_DEBUG
1605	if (donecount > MAX_TX_PDL)
1606		printk("hp100: %s: Warning: More PDLs transmitted than commited to card???\n", dev->name);
1607#endif
1608
1609	for (; 0 != donecount; donecount--) {
1610#ifdef HP100_DEBUG_BM
1611		printk("hp100: %s: Free skb: data @0x%.8x txrcommit=0x%x TXPDL=0x%x, done=0x%x\n",
1612				dev->name, (u_int) lp->txrhead->skb->data,
1613				lp->txrcommit, hp100_inb(TX_PDL), donecount);
1614#endif
1615		/* Conversion to new PCI API : NOP */
1616		pci_unmap_single(lp->pci_dev, (dma_addr_t) lp->txrhead->pdl[1], lp->txrhead->pdl[2], PCI_DMA_TODEVICE);
1617		dev_kfree_skb_any(lp->txrhead->skb);
1618		lp->txrhead->skb = (void *) NULL;
1619		lp->txrhead = lp->txrhead->next;
1620		lp->txrcommit--;
1621	}
1622}
1623
1624/* tx function for slave modes */
1625static int hp100_start_xmit(struct sk_buff *skb, struct net_device *dev)
1626{
1627	unsigned long flags;
1628	int i, ok_flag;
1629	int ioaddr = dev->base_addr;
1630	u_short val;
1631	struct hp100_private *lp = netdev_priv(dev);
1632
1633#ifdef HP100_DEBUG_B
1634	hp100_outw(0x4212, TRACE);
1635	printk("hp100: %s: start_xmit\n", dev->name);
1636#endif
1637
1638	if (skb == NULL) {
1639		return 0;
1640	}
1641
1642	if (skb->len <= 0)
1643		return 0;
1644
1645	if (hp100_check_lan(dev))
1646		return -EIO;
1647
1648	/* If there is not enough free memory on the card... */
1649	i = hp100_inl(TX_MEM_FREE) & 0x7fffffff;
1650	if (!(((i / 2) - 539) > (skb->len + 16) && (hp100_inb(TX_PKT_CNT) < 255))) {
1651#ifdef HP100_DEBUG
1652		printk("hp100: %s: start_xmit: tx free mem = 0x%x\n", dev->name, i);
1653#endif
1654		/* not waited long enough since last failed tx try? */
1655		if (jiffies - dev->trans_start < HZ) {
1656#ifdef HP100_DEBUG
1657			printk("hp100: %s: trans_start timing problem\n",
1658			       dev->name);
1659#endif
1660			return -EAGAIN;
1661		}
1662		if (lp->lan_type == HP100_LAN_100 && lp->hub_status < 0) {
1663			/* we have a 100Mb/s adapter but it isn't connected to hub */
1664			printk("hp100: %s: login to 100Mb/s hub retry\n", dev->name);
1665			hp100_stop_interface(dev);
1666			lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1667			hp100_start_interface(dev);
1668		} else {
1669			spin_lock_irqsave(&lp->lock, flags);
1670			hp100_ints_off();	/* Useful ? Jean II */
1671			i = hp100_sense_lan(dev);
1672			hp100_ints_on();
1673			spin_unlock_irqrestore(&lp->lock, flags);
1674			if (i == HP100_LAN_ERR)
1675				printk("hp100: %s: link down detected\n", dev->name);
1676			else if (lp->lan_type != i) {	/* cable change! */
1677				/* it's very hard - all network setting must be changed!!! */
1678				printk("hp100: %s: cable change 10Mb/s <-> 100Mb/s detected\n", dev->name);
1679				lp->lan_type = i;
1680				hp100_stop_interface(dev);
1681				if (lp->lan_type == HP100_LAN_100)
1682					lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1683				hp100_start_interface(dev);
1684			} else {
1685				printk("hp100: %s: interface reset\n", dev->name);
1686				hp100_stop_interface(dev);
1687				if (lp->lan_type == HP100_LAN_100)
1688					lp->hub_status = hp100_login_to_vg_hub(dev, 0);
1689				hp100_start_interface(dev);
1690				mdelay(1);
1691			}
1692		}
1693		dev->trans_start = jiffies;
1694		return -EAGAIN;
1695	}
1696
1697	for (i = 0; i < 6000 && (hp100_inb(OPTION_MSW) & HP100_TX_CMD); i++) {
1698#ifdef HP100_DEBUG_TX
1699		printk("hp100: %s: start_xmit: busy\n", dev->name);
1700#endif
1701	}
1702
1703	spin_lock_irqsave(&lp->lock, flags);
1704	hp100_ints_off();
1705	val = hp100_inw(IRQ_STATUS);
1706	/* Ack / clear the interrupt TX_COMPLETE interrupt - this interrupt is set
1707	 * when the current packet being transmitted on the wire is completed. */
1708	hp100_outw(HP100_TX_COMPLETE, IRQ_STATUS);
1709#ifdef HP100_DEBUG_TX
1710	printk("hp100: %s: start_xmit: irq_status=0x%.4x, irqmask=0x%.4x, len=%d\n",
1711			dev->name, val, hp100_inw(IRQ_MASK), (int) skb->len);
1712#endif
1713
1714	ok_flag = skb->len >= HP100_MIN_PACKET_SIZE;
1715	i = ok_flag ? skb->len : HP100_MIN_PACKET_SIZE;
1716
1717	hp100_outw(i, DATA32);	/* tell card the total packet length */
1718	hp100_outw(i, FRAGMENT_LEN);	/* and first/only fragment length    */
1719
1720	if (lp->mode == 2) {	/* memory mapped */
1721		if (lp->mem_ptr_virt) {	/* high pci memory was remapped */
1722			/* Note: The J2585B needs alignment to 32bits here!  */
1723			memcpy_toio(lp->mem_ptr_virt, skb->data, (skb->len + 3) & ~3);
1724			if (!ok_flag)
1725				memset_io(lp->mem_ptr_virt, 0, HP100_MIN_PACKET_SIZE - skb->len);
1726		} else {
1727			/* Note: The J2585B needs alignment to 32bits here!  */
1728			isa_memcpy_toio(lp->mem_ptr_phys, skb->data, (skb->len + 3) & ~3);
1729			if (!ok_flag)
1730				isa_memset_io(lp->mem_ptr_phys, 0, HP100_MIN_PACKET_SIZE - skb->len);
1731		}
1732	} else {		/* programmed i/o */
1733		outsl(ioaddr + HP100_REG_DATA32, skb->data,
1734		      (skb->len + 3) >> 2);
1735		if (!ok_flag)
1736			for (i = (skb->len + 3) & ~3; i < HP100_MIN_PACKET_SIZE; i += 4)
1737				hp100_outl(0, DATA32);
1738	}
1739
1740	hp100_outb(HP100_TX_CMD | HP100_SET_LB, OPTION_MSW);	/* send packet */
1741
1742	lp->stats.tx_packets++;
1743	lp->stats.tx_bytes += skb->len;
1744	dev->trans_start = jiffies;
1745	hp100_ints_on();
1746	spin_unlock_irqrestore(&lp->lock, flags);
1747
1748	dev_kfree_skb_any(skb);
1749
1750#ifdef HP100_DEBUG_TX
1751	printk("hp100: %s: start_xmit: end\n", dev->name);
1752#endif
1753
1754	return 0;
1755}
1756
1757
1758/*
1759 * Receive Function (Non-Busmaster mode)
1760 * Called when an "Receive Packet" interrupt occurs, i.e. the receive 
1761 * packet counter is non-zero.
1762 * For non-busmaster, this function does the whole work of transfering
1763 * the packet to the host memory and then up to higher layers via skb
1764 * and netif_rx. 
1765 */
1766
1767static void hp100_rx(struct net_device *dev)
1768{
1769	int packets, pkt_len;
1770	int ioaddr = dev->base_addr;
1771	struct hp100_private *lp = netdev_priv(dev);
1772	u_int header;
1773	struct sk_buff *skb;
1774
1775#ifdef DEBUG_B
1776	hp100_outw(0x4213, TRACE);
1777	printk("hp100: %s: rx\n", dev->name);
1778#endif
1779
1780	/* First get indication of received lan packet */
1781	/* RX_PKT_CND indicates the number of packets which have been fully */
1782	/* received onto the card but have not been fully transferred of the card */
1783	packets = hp100_inb(RX_PKT_CNT);
1784#ifdef HP100_DEBUG_RX
1785	if (packets > 1)
1786		printk("hp100: %s: rx: waiting packets = %d\n", dev->name, packets);
1787#endif
1788
1789	while (packets-- > 0) {
1790		/* If ADV_NXT_PKT is still set, we have to wait until the card has */
1791		/* really advanced to the next packet. */
1792		for (pkt_len = 0; pkt_len < 6000 && (hp100_inb(OPTION_MSW) & HP100_ADV_NXT_PKT); pkt_len++) {
1793#ifdef HP100_DEBUG_RX
1794			printk ("hp100: %s: rx: busy, remaining packets = %d\n", dev->name, packets);
1795#endif
1796		}
1797
1798		/* First we get the header, which contains information about the */
1799		/* actual length of the received packet. */
1800		if (lp->mode == 2) {	/* memory mapped mode */
1801			if (lp->mem_ptr_virt)	/* if memory was remapped */
1802				header = readl(lp->mem_ptr_virt);
1803			else
1804				header = isa_readl(lp->mem_ptr_phys);
1805		} else		/* programmed i/o */
1806			header = hp100_inl(DATA32);
1807
1808		pkt_len = ((header & HP100_PKT_LEN_MASK) + 3) & ~3;
1809
1810#ifdef HP100_DEBUG_RX
1811		printk("hp100: %s: rx: new packet - length=%d, errors=0x%x, dest=0x%x\n",
1812				     dev->name, header & HP100_PKT_LEN_MASK,
1813				     (header >> 16) & 0xfff8, (header >> 16) & 7);
1814#endif
1815
1816		/* Now we allocate the skb and transfer the data into it. */
1817		skb = dev_alloc_skb(pkt_len+2);
1818		if (skb == NULL) {	/* Not enough memory->drop packet */
1819#ifdef HP100_DEBUG
1820			printk("hp100: %s: rx: couldn't allocate a sk_buff of size %d\n",
1821					     dev->name, pkt_len);
1822#endif
1823			lp->stats.rx_dropped++;
1824		} else {	/* skb successfully allocated */
1825
1826			u_char *ptr;
1827
1828			skb_reserve(skb,2);
1829			skb->dev = dev;
1830
1831			/* ptr to start of the sk_buff data area */
1832			skb_put(skb, pkt_len);
1833			ptr = skb->data;
1834
1835			/* Now transfer the data from the card into that area */
1836			if (lp->mode == 2) {
1837				if (lp->mem_ptr_virt)
1838					memcpy_fromio(ptr, lp->mem_ptr_virt,pkt_len);
1839				/* Note alignment to 32bit transfers */
1840				else
1841					isa_memcpy_fromio(ptr, lp->mem_ptr_phys, pkt_len);
1842			} else	/* io mapped */
1843				insl(ioaddr + HP100_REG_DATA32, ptr, pkt_len >> 2);
1844
1845			skb->protocol = eth_type_trans(skb, dev);
1846
1847#ifdef HP100_DEBUG_RX
1848			printk("hp100: %s: rx: %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x\n",
1849					dev->name, ptr[0], ptr[1], ptr[2], ptr[3],
1850		 			ptr[4], ptr[5], ptr[6], ptr[7], ptr[8],
1851					ptr[9], ptr[10], ptr[11]);
1852#endif
1853			netif_rx(skb);
1854			dev->last_rx = jiffies;
1855			lp->stats.rx_packets++;
1856			lp->stats.rx_bytes += pkt_len;
1857		}
1858
1859		/* Indicate the card that we have got the packet */
1860		hp100_outb(HP100_ADV_NXT_PKT | HP100_SET_LB, OPTION_MSW);
1861
1862		switch (header & 0x00070000) {
1863		case (HP100_MULTI_ADDR_HASH << 16):
1864		case (HP100_MULTI_ADDR_NO_HASH << 16):
1865			lp->stats.multicast++;
1866			break;
1867		}
1868	}			/* end of while(there are packets) loop */
1869#ifdef HP100_DEBUG_RX
1870	printk("hp100_rx: %s: end\n", dev->name);
1871#endif
1872}
1873
1874/* 
1875 * Receive Function for Busmaster Mode
1876 */
1877static void hp100_rx_bm(struct net_device *dev)
1878{
1879	int ioaddr = dev->base_addr;
1880	struct hp100_private *lp = netdev_priv(dev);
1881	hp100_ring_t *ptr;
1882	u_int header;
1883	int pkt_len;
1884
1885#ifdef HP100_DEBUG_B
1886	hp100_outw(0x4214, TRACE);
1887	printk("hp100: %s: rx_bm\n", dev->name);
1888#endif
1889
1890#ifdef HP100_DEBUG
1891	if (0 == lp->rxrcommit) {
1892		printk("hp100: %s: rx_bm called although no PDLs were committed to adapter?\n", dev->name);
1893		return;
1894	} else
1895		/* RX_PKT_CNT states how many PDLs are currently formatted and available to 
1896		 * the cards BM engine */
1897	if ((hp100_inw(RX_PKT_CNT) & 0x00ff) >= lp->rxrcommit) {
1898		printk("hp100: %s: More packets received than commited? RX_PKT_CNT=0x%x, commit=0x%x\n",
1899				     dev->name, hp100_inw(RX_PKT_CNT) & 0x00ff,
1900				     lp->rxrcommit);
1901		return;
1902	}
1903#endif
1904
1905	while ((lp->rxrcommit > hp100_inb(RX_PDL))) {
1906		/*
1907		 * The packet was received into the pdl pointed to by lp->rxrhead (
1908		 * the oldest pdl in the ring 
1909		 */
1910
1911		/* First we get the header, which contains information about the */
1912		/* actual length of the received packet. */
1913
1914		ptr = lp->rxrhead;
1915
1916		header = *(ptr->pdl - 1);
1917		pkt_len = (header & HP100_PKT_LEN_MASK);
1918
1919		/* Conversion to new PCI API : NOP */
1920		pci_unmap_single(lp->pci_dev, (dma_addr_t) ptr->pdl[3], MAX_ETHER_SIZE, PCI_DMA_FROMDEVICE);
1921
1922#ifdef HP100_DEBUG_BM
1923		printk("hp100: %s: rx_bm: header@0x%x=0x%x length=%d, errors=0x%x, dest=0x%x\n",
1924				dev->name, (u_int) (ptr->pdl - 1), (u_int) header,
1925				pkt_len, (header >> 16) & 0xfff8, (header >> 16) & 7);
1926		printk("hp100: %s: RX_PDL_COUNT:0x%x TX_PDL_COUNT:0x%x, RX_PKT_CNT=0x%x PDH=0x%x, Data@0x%x len=0x%x\n",
1927		   		dev->name, hp100_inb(RX_PDL), hp100_inb(TX_PDL),
1928				hp100_inb(RX_PKT_CNT), (u_int) * (ptr->pdl),
1929				(u_int) * (ptr->pdl + 3), (u_int) * (ptr->pdl + 4));
1930#endif
1931
1932		if ((pkt_len >= MIN_ETHER_SIZE) &&
1933		    (pkt_len <= MAX_ETHER_SIZE)) {
1934			if (ptr->skb == NULL) {
1935				printk("hp100: %s: rx_bm: skb null\n", dev->name);
1936				/* can happen if we only allocated room for the pdh due to memory shortage. */
1937				lp->stats.rx_dropped++;
1938			} else {
1939				skb_trim(ptr->skb, pkt_len);	/* Shorten it */
1940				ptr->skb->protocol =
1941				    eth_type_trans(ptr->skb, dev);
1942
1943				netif_rx(ptr->skb);	/* Up and away... */
1944
1945				dev->last_rx = jiffies;
1946				lp->stats.rx_packets++;
1947				lp->stats.rx_bytes += pkt_len;
1948			}
1949
1950			switch (header & 0x00070000) {
1951			case (HP100_MULTI_ADDR_HASH << 16):
1952			case (HP100_MULTI_ADDR_NO_HASH << 16):
1953				lp->stats.multicast++;
1954				break;
1955			}
1956		} else {
1957#ifdef HP100_DEBUG
1958			printk("hp100: %s: rx_bm: Received bad packet (length=%d)\n", dev->name, pkt_len);
1959#endif
1960			if (ptr->skb != NULL)
1961				dev_kfree_skb_any(ptr->skb);
1962			lp->stats.rx_errors++;
1963		}
1964
1965		lp->rxrhead = lp->rxrhead->next;
1966
1967		/* Allocate a new rx PDL (so lp->rxrcommit stays the same) */
1968		if (0 == hp100_build_rx_pdl(lp->rxrtail, dev)) {
1969			/* No space for skb, header can still be received. */
1970#ifdef HP100_DEBUG
1971			printk("hp100: %s: rx_bm: No space for new PDL.\n", dev->name);
1972#endif
1973			return;
1974		} else {	/* successfully allocated new PDL - put it in ringlist at tail. */
1975			hp100_outl((u32) lp->rxrtail->pdl_paddr, RX_PDA);
1976			lp->rxrtail = lp->rxrtail->next;
1977		}
1978
1979	}
1980}
1981
1982/*
1983 *  statistics
1984 */
1985static struct net_device_stats *hp100_get_stats(struct net_device *dev)
1986{
1987	unsigned long flags;
1988	int ioaddr = dev->base_addr;
1989	struct hp100_private *lp = netdev_priv(dev);
1990
1991#ifdef HP100_DEBUG_B
1992	hp100_outw(0x4215, TRACE);
1993#endif
1994
1995	spin_lock_irqsave(&lp->lock, flags);
1996	hp100_ints_off();	/* Useful ? Jean II */
1997	hp100_update_stats(dev);
1998	hp100_ints_on();
1999	spin_unlock_irqrestore(&lp->lock, flags);
2000	return &(lp->stats);
2001}
2002
2003static void hp100_update_stats(struct net_device *dev)
2004{
2005	int ioaddr = dev->base_addr;
2006	u_short val;
2007	struct hp100_private *lp = netdev_priv(dev);
2008
2009#ifdef HP100_DEBUG_B
2010	hp100_outw(0x4216, TRACE);
2011	printk("hp100: %s: update-stats\n", dev->name);
2012#endif
2013
2014	/* Note: Statistics counters clear when read. */
2015	hp100_page(MAC_CTRL);
2016	val = hp100_inw(DROPPED) & 0x0fff;
2017	lp->stats.rx_errors += val;
2018	lp->stats.rx_over_errors += val;
2019	val = hp100_inb(CRC);
2020	lp->stats.rx_errors += val;
2021	lp->stats.rx_crc_errors += val;
2022	val = hp100_inb(ABORT);
2023	lp->stats.tx_errors += val;
2024	lp->stats.tx_aborted_errors += val;
2025	hp100_page(PERFORMANCE);
2026}
2027
2028static void hp100_misc_interrupt(struct net_device *dev)
2029{
2030#ifdef HP100_DEBUG_B
2031	int ioaddr = dev->base_addr;
2032#endif
2033	struct hp100_private *lp = netdev_priv(dev);
2034
2035#ifdef HP100_DEBUG_B
2036	int ioaddr = dev->base_addr;
2037	hp100_outw(0x4216, TRACE);
2038	printk("hp100: %s: misc_interrupt\n", dev->name);
2039#endif
2040
2041	/* Note: Statistics counters clear when read. */
2042	lp->stats.rx_errors++;
2043	lp->stats.tx_errors++;
2044}
2045
2046static void hp100_clear_stats(struct hp100_private *lp, int ioaddr)
2047{
2048	unsigned long flags;
2049
2050#ifdef HP100_DEBUG_B
2051	hp100_outw(0x4217, TRACE);
2052	printk("hp100: %s: clear_stats\n", dev->name);
2053#endif
2054
2055	spin_lock_irqsave(&lp->lock, flags);
2056	hp100_page(MAC_CTRL);	/* get all statistics bytes */
2057	hp100_inw(DROPPED);
2058	hp100_inb(CRC);
2059	hp100_inb(ABORT);
2060	hp100_page(PERFORMANCE);
2061	spin_unlock_irqrestore(&lp->lock, flags);
2062}
2063
2064
2065/*
2066 *  multicast setup
2067 */
2068
2069/*
2070 *  Set or clear the multicast filter for this adapter.
2071 */
2072
2073static void hp100_set_multicast_list(struct net_device *dev)
2074{
2075	unsigned long flags;
2076	int ioaddr = dev->base_addr;
2077	struct hp100_private *lp = netdev_priv(dev);
2078
2079#ifdef HP100_DEBUG_B
2080	hp100_outw(0x4218, TRACE);
2081	printk("hp100: %s: set_mc_list\n", dev->name);
2082#endif
2083
2084	spin_lock_irqsave(&lp->lock, flags);
2085	hp100_ints_off();
2086	hp100_page(MAC_CTRL);
2087	hp100_andb(~(HP100_RX_EN | HP100_TX_EN), MAC_CFG_1);	/* stop rx/tx */
2088
2089	if (dev->flags & IFF_PROMISC) {
2090		lp->mac2_mode = HP100_MAC2MODE6;	/* promiscuous mode = get all good */
2091		lp->mac1_mode = HP100_MAC1MODE6;	/* packets on the net */
2092		memset(&lp->hash_bytes, 0xff, 8);
2093	} else if (dev->mc_count || (dev->flags & IFF_ALLMULTI)) {
2094		lp->mac2_mode = HP100_MAC2MODE5;	/* multicast mode = get packets for */
2095		lp->mac1_mode = HP100_MAC1MODE5;	/* me, broadcasts and all multicasts */
2096#ifdef HP100_MULTICAST_FILTER	/* doesn't work!!! */
2097		if (dev->flags & IFF_ALLMULTI) {
2098			/* set hash filter to receive all multicast packets */
2099			memset(&lp->hash_bytes, 0xff, 8);
2100		} else {
2101			int i, j, idx;
2102			u_char *addrs;
2103			struct dev_mc_list *dmi;
2104
2105			memset(&lp->hash_bytes, 0x00, 8);
2106#ifdef HP100_DEBUG
2107			printk("hp100: %s: computing hash filter - mc_count = %i\n", dev->name, dev->mc_count);
2108#endif
2109			for (i = 0, dmi = dev->mc_list; i < dev->mc_count; i++, dmi = dmi->next) {
2110				addrs = dmi->dmi_addr;
2111				if ((*addrs & 0x01) == 0x01) {	/* multicast address? */
2112#ifdef HP100_DEBUG
2113					printk("hp100: %s: multicast = %02x:%02x:%02x:%02x:%02x:%02x, ",
2114						     dev->name, addrs[0], addrs[1], addrs[2],
2115						     addrs[3], addrs[4], addrs[5]);
2116#endif
2117					for (j = idx = 0; j < 6; j++) {
2118						idx ^= *addrs++ & 0x3f;
2119						printk(":%02x:", idx);
2120					}
2121#ifdef HP100_DEBUG
2122					printk("idx = %i\n", idx);
2123#endif
2124					lp->hash_bytes[idx >> 3] |= (1 << (idx & 7));
2125				}
2126			}
2127		}
2128#else
2129		memset(&lp->hash_bytes, 0xff, 8);
2130#endif
2131	} else {
2132		lp->mac2_mode = HP100_MAC2MODE3;	/* normal mode = get packets for me */
2133		lp->mac1_mode = HP100_MAC1MODE3;	/* and broadcasts */
2134		memset(&lp->hash_bytes, 0x00, 8);
2135	}
2136
2137	if (((hp100_inb(MAC_CFG_1) & 0x0f) != lp->mac1_mode) ||
2138	    (hp100_inb(MAC_CFG_2) != lp->mac2_mode)) {
2139		int i;
2140
2141		hp100_outb(lp->mac2_mode, MAC_CFG_2);
2142		hp100_andb(HP100_MAC1MODEMASK, MAC_CFG_1);	/* clear mac1 mode bits */
2143		hp100_orb(lp->mac1_mode, MAC_CFG_1);	/* and set the new mode */
2144
2145		hp100_page(MAC_ADDRESS);
2146		for (i = 0; i < 8; i++)
2147			hp100_outb(lp->hash_bytes[i], HASH_BYTE0 + i);
2148#ifdef HP100_DEBUG
2149		printk("hp100: %s: mac1 = 0x%x, mac2 = 0x%x, multicast hash = %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n",
2150				     dev->name, lp->mac1_mode, lp->mac2_mode,
2151				     lp->hash_bytes[0], lp->hash_bytes[1],
2152				     lp->hash_bytes[2], lp->hash_bytes[3],
2153				     lp->hash_bytes[4], lp->hash_bytes[5],
2154				     lp->hash_bytes[6], lp->hash_bytes[7]);
2155#endif
2156
2157		if (lp->lan_type == HP100_LAN_100) {
2158#ifdef HP100_DEBUG
2159			printk("hp100: %s: 100VG MAC settings have changed - relogin.\n", dev->name);
2160#endif
2161			lp->hub_status = hp100_login_to_vg_hub(dev, 1);	/* force a relogin to the hub */
2162		}
2163	} else {
2164		int i;
2165		u_char old_hash_bytes[8];
2166
2167		hp100_page(MAC_ADDRESS);
2168		for (i = 0; i < 8; i++)
2169			old_hash_bytes[i] = hp100_inb(HASH_BYTE0 + i);
2170		if (memcmp(old_hash_bytes, &lp->hash_bytes, 8)) {
2171			for (i = 0; i < 8; i++)
2172				hp100_outb(lp->hash_bytes[i], HASH_BYTE0 + i);
2173#ifdef HP100_DEBUG
2174			printk("hp100: %s: multicast hash = %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n",
2175					dev->name, lp->hash_bytes[0],
2176					lp->hash_bytes[1], lp->hash_bytes[2],
2177					lp->hash_bytes[3], lp->hash_bytes[4],
2178					lp->hash_bytes[5], lp->hash_bytes[6],
2179					lp->hash_bytes[7]);
2180#endif
2181
2182			if (lp->lan_type == HP100_LAN_100) {
2183#ifdef HP100_DEBUG
2184				printk("hp100: %s: 100VG MAC settings have changed - relogin.\n", dev->name);
2185#endif
2186				lp->hub_status = hp100_login_to_vg_hub(dev, 1);	/* force a relogin to the hub */
2187			}
2188		}
2189	}
2190
2191	hp100_page(MAC_CTRL);
2192	hp100_orb(HP100_RX_EN | HP100_RX_IDLE |	/* enable rx */
2193		  HP100_TX_EN | HP100_TX_IDLE, MAC_CFG_1);	/* enable tx */
2194
2195	hp100_page(PERFORMANCE);
2196	hp100_ints_on();
2197	spin_unlock_irqrestore(&lp->lock, flags);
2198}
2199
2200/*
2201 *  hardware interrupt handling
2202 */
2203
2204static irqreturn_t hp100_interrupt(int irq, void *dev_id, struct pt_regs *regs)
2205{
2206	struct net_device *dev = (struct net_device *) dev_id;
2207	struct hp100_private *lp = netdev_priv(dev);
2208
2209	int ioaddr;
2210	u_int val;
2211
2212	if (dev == NULL)
2213		return IRQ_NONE;
2214	ioaddr = dev->base_addr;
2215
2216	spin_lock(&lp->lock);
2217
2218	hp100_ints_off();
2219
2220#ifdef HP100_DEBUG_B
2221	hp100_outw(0x4219, TRACE);
2222#endif
2223
2224	/*  hp100_page( PERFORMANCE ); */
2225	val = hp100_inw(IRQ_STATUS);
2226#ifdef HP100_DEBUG_IRQ
2227	printk("hp100: %s: mode=%x,IRQ_STAT=0x%.4x,RXPKTCNT=0x%.2x RXPDL=0x%.2x TXPKTCNT=0x%.2x TXPDL=0x%.2x\n",
2228			     dev->name, lp->mode, (u_int) val, hp100_inb(RX_PKT_CNT),
2229			     hp100_inb(RX_PDL), hp100_inb(TX_PKT_CNT), hp100_inb(TX_PDL));
2230#endif
2231
2232	if (val == 0) {		/* might be a shared interrupt */
2233		spin_unlock(&lp->lock);
2234		hp100_ints_on();
2235		return IRQ_NONE;
2236	}
2237	/* We're only interested in those interrupts we really enabled. */
2238	/* val &= hp100_inw( IRQ_MASK ); */
2239
2240	/* 
2241	 * RX_PDL_FILL_COMPL is set whenever a RX_PDL has been executed. A RX_PDL 
2242	 * is considered executed whenever the RX_PDL data structure is no longer 
2243	 * needed.
2244	 */
2245	if (val & HP100_RX_PDL_FILL_COMPL) {
2246		if (lp->mode == 1)
2247			hp100_rx_bm(dev);
2248		else {
2249			printk("hp100: %s: rx_pdl_fill_compl interrupt although not busmaster?\n", dev->name);
2250		}
2251	}
2252
2253	/* 
2254	 * The RX_PACKET interrupt is set, when the receive packet counter is
2255	 * non zero. We use this interrupt for receiving in slave mode. In
2256	 * busmaster mode, we use it to make sure we did not miss any rx_pdl_fill
2257	 * interrupts. If rx_pdl_fill_compl is not set and rx_packet is set, then
2258	 * we somehow have missed a rx_pdl_fill_compl interrupt.
2259	 */
2260
2261	if (val & HP100_RX_PACKET) {	/* Receive Packet Counter is non zero */
2262		if (lp->mode != 1)	/* non busmaster */
2263			hp100_rx(dev);
2264		else if (!(val & HP100_RX_PDL_FILL_COMPL)) {
2265			/* Shouldnt happen - maybe we missed a RX_PDL_FILL Interrupt?  */
2266			hp100_rx_bm(dev);
2267		}
2268	}
2269
2270	/*
2271	 * Ack. that we have noticed the interrupt and thereby allow next one.
2272	 * Note that this is now done after the slave rx function, since first
2273	 * acknowledging and then setting ADV_NXT_PKT caused an extra interrupt
2274	 * on the J2573.
2275	 */
2276	hp100_outw(val, IRQ_STATUS);
2277
2278	/*
2279	 * RX_ERROR is set when a packet is dropped due to no memory resources on 
2280	 * the card or when a RCV_ERR occurs. 
2281	 * TX_ERROR is set when a TX_ABORT condition occurs in the MAC->exists  
2282	 * only in the 802.3 MAC and happens when 16 collisions occur during a TX 
2283	 */
2284	if (val & (HP100_TX_ERROR | HP100_RX_ERROR)) {
2285#ifdef HP100_DEBUG_IRQ
2286		printk("hp100: %s: TX/RX Error IRQ\n", dev->name);
2287#endif
2288		hp100_update_stats(dev);
2289		if (lp->mode == 1) {
2290			hp100_rxfill(dev);
2291			hp100_clean_txring(dev);
2292		}
2293	}
2294
2295	/* 
2296	 * RX_PDA_ZERO is set when the PDA count goes from non-zero to zero. 
2297	 */
2298	if ((lp->mode == 1) && (val & (HP100_RX_PDA_ZERO)))
2299		hp100_rxfill(dev);
2300
2301	/* 
2302	 * HP100_TX_COMPLETE interrupt occurs when packet transmitted on wire 
2303	 * is completed 
2304	 */
2305	if ((lp->mode == 1) && (val & (HP100_TX_COMPLETE)))
2306		hp100_clean_txring(dev);
2307
2308	/* 
2309	 * MISC_ERROR is set when either the LAN link goes down or a detected
2310	 * bus error occurs.
2311	 */
2312	if (val & HP100_MISC_ERROR) {	/* New for J2585B */
2313#ifdef HP100_DEBUG_IRQ
2314		printk
2315		    ("hp100: %s: Misc. Error Interrupt - Check cabling.\n",
2316		     dev->name);
2317#endif
2318		if (lp->mode == 1) {
2319			hp100_clean_txring(dev);
2320			hp100_rxfill(dev);
2321		}
2322		hp100_misc_interrupt(dev);
2323	}
2324
2325	spin_unlock(&lp->lock);
2326	hp100_ints_on();
2327	return IRQ_HANDLED;
2328}
2329
2330/*
2331 *  some misc functions
2332 */
2333
2334static void hp100_start_interface(struct net_device *dev)
2335{
2336	unsigned long flags;
2337	int ioaddr = dev->base_addr;
2338	struct hp100_private *lp = netdev_priv(dev);
2339
2340#ifdef HP100_DEBUG_B
2341	hp100_outw(0x4220, TRACE);
2342	printk("hp100: %s: hp100_start_interface\n", dev->name);
2343#endif
2344
2345	spin_lock_irqsave(&lp->lock, flags);
2346
2347	/* Ensure the adapter does not want to request an interrupt when */
2348	/* enabling the IRQ line to be active on the bus (i.e. not tri-stated) */
2349	hp100_page(PERFORMANCE);
2350	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
2351	hp100_outw(0xffff, IRQ_STATUS);	/* ack all IRQs */
2352	hp100_outw(HP100_FAKE_INT | HP100_INT_EN | HP100_RESET_LB,
2353		   OPTION_LSW);
2354	/* Un Tri-state int. TODO: Check if shared interrupts can be realised? */
2355	hp100_outw(HP100_TRI_INT | HP100_RESET_HB, OPTION_LSW);
2356
2357	if (lp->mode == 1) {
2358		/* Make sure BM bit is set... */
2359		hp100_page(HW_MAP);
2360		hp100_orb(HP100_BM_MASTER, BM);
2361		hp100_rxfill(dev);
2362	} else if (lp->mode == 2) {
2363		/* Enable memory mapping. Note: Don't do this when busmaster. */
2364		hp100_outw(HP100_MMAP_DIS | HP100_RESET_HB, OPTION_LSW);
2365	}
2366
2367	hp100_page(PERFORMANCE);
2368	hp100_outw(0xfefe, IRQ_MASK);	/* mask off all ints */
2369	hp100_outw(0xffff, IRQ_STATUS);	/* ack IRQ */
2370
2371	/* enable a few interrupts: */
2372	if (lp->mode == 1) {	/* busmaster mode */
2373		hp100_outw(HP100_RX_PDL_FILL_COMPL |
2374			   HP100_RX_PDA_ZERO | HP100_RX_ERROR |
2375			   /* HP100_RX_PACKET    | */
2376			   /* HP100_RX_EARLY_INT |  */ HP100_SET_HB |
2377			   /* HP100_TX_PDA_ZERO  |  */
2378			   HP100_TX_COMPLETE |
2379			   /* HP100_MISC_ERROR   |  */
2380			   HP100_TX_ERROR | HP100_SET_LB, IRQ_MASK);
2381	} else {
2382		hp100_outw(HP100_RX_PACKET |
2383			   HP100_RX_ERROR | HP100_SET_HB |
2384			   HP100_TX_ERROR | HP100_SET_LB, IRQ_MASK);
2385	}
2386
2387	/* Note : before hp100_set_multicast_list(), because it will play with
2388	 * spinlock itself... Jean II */
2389	spin_unlock_irqrestore(&lp->lock, flags);
2390
2391	/* Enable MAC Tx and RX, set MAC modes, ... */
2392	hp100_set_multicast_list(dev);
2393}
2394
2395static void hp100_stop_interface(struct net_device *dev)
2396{
2397	struct hp100_private *lp = netdev_priv(dev);
2398	int ioaddr = dev->base_addr;
2399	u_int val;
2400
2401#ifdef HP100_DEBUG_B
2402	printk("hp100: %s: hp100_stop_interface\n", dev->name);
2403	hp100_outw(0x4221, TRACE);
2404#endif
2405
2406	if (lp->mode == 1)
2407		hp100_BM_shutdown(dev);
2408	else {
2409		/* Note: MMAP_DIS will be reenabled by start_interface */
2410		hp100_outw(HP100_INT_EN | HP100_RESET_LB |
2411			   HP100_TRI_INT | HP100_MMAP_DIS | HP100_SET_HB,
2412			   OPTION_LSW);
2413		val = hp100_inw(OPTION_LSW);
2414
2415		hp100_page(MAC_CTRL);
2416		hp100_andb(~(HP100_RX_EN | HP100_TX_EN), MAC_CFG_1);
2417
2418		if (!(val & HP100_HW_RST))
2419			return;	/* If reset, imm. return ... */
2420		/* ... else: busy wait until idle */
2421		for (val = 0; val < 6000; val++)
2422			if ((hp100_inb(MAC_CFG_1) & (HP100_TX_IDLE | HP100_RX_IDLE)) == (HP100_TX_IDLE | HP100_RX_IDLE)) {
2423				hp100_page(PERFORMANCE);
2424				return;
2425			}
2426		printk("hp100: %s: hp100_stop_interface - timeout\n", dev->name);
2427		hp100_page(PERFORMANCE);
2428	}
2429}
2430
2431static void hp100_load_eeprom(struct net_device *dev, u_short probe_ioaddr)
2432{
2433	int i;
2434	int ioaddr = probe_ioaddr > 0 ? probe_ioaddr : dev->base_addr;
2435
2436#ifdef HP100_DEBUG_B
2437	hp100_outw(0x4222, TRACE);
2438#endif
2439
2440	hp100_page(EEPROM_CTRL);
2441	hp100_andw(~HP100_EEPROM_LOAD, EEPROM_CTRL);
2442	hp100_orw(HP100_EEPROM_LOAD, EEPROM_CTRL);
2443	for (i = 0; i < 10000; i++)
2444		if (!(hp100_inb(OPTION_MSW) & HP100_EE_LOAD))
2445			return;
2446	printk("hp100: %s: hp100_load_eeprom - timeout\n", dev->name);
2447}
2448
2449/*  Sense connection status.
2450 *  return values: LAN_10  - Connected to 10Mbit/s network
2451 *                 LAN_100 - Connected to 100Mbit/s network
2452 *                 LAN_ERR - not connected or 100Mbit/s Hub down
2453 */
2454static int hp100_sense_lan(struct net_device *dev)
2455{
2456	int ioaddr = dev->base_addr;
2457	u_short val_VG, val_10;
2458	struct hp100_private *lp = netdev_priv(dev);
2459
2460#ifdef HP100_DEBUG_B
2461	hp100_outw(0x4223, TRACE);
2462#endif
2463
2464	hp100_page(MAC_CTRL);
2465	val_10 = hp100_inb(10_LAN_CFG_1);
2466	val_VG = hp100_inb(VG_LAN_CFG_1);
2467	hp100_page(PERFORMANCE);
2468#ifdef HP100_DEBUG
2469	printk("hp100: %s: sense_lan: val_VG = 0x%04x, val_10 = 0x%04x\n",
2470	       dev->name, val_VG, val_10);
2471#endif
2472
2473	if (val_10 & HP100_LINK_BEAT_ST)	/* 10Mb connection is active */
2474		return HP100_LAN_10;
2475
2476	if (val_10 & HP100_AUI_ST) {	/* have we BNC or AUI onboard? */
2477		/*
2478		 * This can be overriden by dos utility, so if this has no effect,
2479		 * perhaps you need to download that utility from HP and set card
2480		 * back to "auto detect".
2481		 */
2482		val_10 |= HP100_AUI_SEL | HP100_LOW_TH;
2483		hp100_page(MAC_CTRL);
2484		hp100_outb(val_10, 10_LAN_CFG_1);
2485		hp100_page(PERFORMANCE);
2486		return HP100_LAN_COAX;
2487	}
2488
2489	/* Those cards don't have a 100 Mbit connector */
2490	if ( !strcmp(lp->id, "HWP1920")  ||
2491	     (lp->pci_dev && 
2492	      lp->pci_dev->vendor == PCI_VENDOR_ID && 
2493	      (lp->pci_dev->device == PCI_DEVICE_ID_HP_J2970A ||
2494	       lp->pci_dev->device == PCI_DEVICE_ID_HP_J2973A)))
2495		return HP100_LAN_ERR;
2496	
2497	if (val_VG & HP100_LINK_CABLE_ST)	/* Can hear the HUBs tone. */
2498		return HP100_LAN_100;
2499	return HP100_LAN_ERR;
2500}
2501
2502static int hp100_down_vg_link(struct net_device *dev)
2503{
2504	struct hp100_private *lp = netdev_priv(dev);
2505	int ioaddr = dev->base_addr;
2506	unsigned long time;
2507	long savelan, newlan;
2508
2509#ifdef HP100_DEBUG_B
2510	hp100_outw(0x4224, TRACE);
2511	printk("hp100: %s: down_vg_link\n", dev->name);
2512#endif
2513
2514	hp100_page(MAC_CTRL);
2515	time = jiffies + (HZ / 4);
2516	do {
2517		if (hp100_inb(VG_LAN_CFG_1) & HP100_LINK_CABLE_ST)
2518			break;
2519		if (!in_interrupt())
2520			schedule_timeout_interruptible(1);
2521	} while (time_after(time, jiffies));
2522
2523	if (time_after_eq(jiffies, time))	/* no signal->no logout */
2524		return 0;
2525
2526	/* Drop the VG Link by clearing the link up cmd and load addr. */
2527
2528	hp100_andb(~(HP100_LOAD_ADDR | HP100_LINK_CMD), VG_LAN_CFG_1);
2529	hp100_orb(HP100_VG_SEL, VG_LAN_CFG_1);
2530
2531	/* Conditionally stall for >250ms on Link-Up Status (to go down) */
2532	time = jiffies + (HZ / 2);
2533	do {
2534		if (!(hp100_inb(VG_LAN_CFG_1) & HP100_LINK_UP_ST))
2535			break;
2536		if (!in_interrupt())
2537			schedule_timeout_interruptible(1);
2538	} while (time_after(time, jiffies));
2539
2540#ifdef HP100_DEBUG
2541	if (time_after_eq(jiffies, time))
2542		printk("hp100: %s: down_vg_link: Link does not go down?\n", dev->name);
2543#endif
2544
2545	/* To prevent condition where Rev 1 VG MAC and old hubs do not complete */
2546	/* logout under traffic (even though all the status bits are cleared),  */
2547	/* do this workaround to get the Rev 1 MAC in its idle state */
2548	if (lp->chip == HP100_CHIPID_LASSEN) {
2549		/* Reset VG MAC to insure it leaves the logoff state even if */
2550		/* the Hub is still emitting tones */
2551		hp100_andb(~HP100_VG_RESET, VG_LAN_CFG_1);
2552		udelay(1500);	/* wait for >1ms */
2553		hp100_orb(HP100_VG_RESET, VG_LAN_CFG_1);	/* Release Reset */
2554		udelay(1500);
2555	}
2556
2557	/* New: For lassen, switch to 10 Mbps mac briefly to clear training ACK */
2558	/* to get the VG mac to full reset. This is not req.d with later chips */
2559	/* Note: It will take the between 1 and 2 seconds for the VG mac to be */
2560	/* selected again! This will be left to the connect hub function to */
2561	/* perform if desired.  */
2562	if (lp->chip == HP100_CHIPID_LASSEN) {
2563		/* Have to write to 10 and 100VG control registers simultaneously */
2564		savelan = newlan = hp100_inl(10_LAN_CFG_1);	/* read 10+100 LAN_CFG regs */
2565		newlan &= ~(HP100_VG_SEL << 16);
2566		newlan |= (HP100_DOT3_MAC) << 8;
2567		hp100_andb(~HP100_AUTO_MODE, MAC_CFG_3);	/* Autosel off */
2568		hp100_outl(newlan, 10_LAN_CFG_1);
2569
2570		/* Conditionally stall for 5sec on VG selected. */
2571		time = jiffies + (HZ * 5);
2572		do {
2573			if (!(hp100_inb(MAC_CFG_4) & HP100_MAC_SEL_ST))
2574				break;
2575			if (!in_interrupt())
2576				schedule_timeout_interruptible(1);
2577		} while (time_after(time, jiffies));
2578
2579		hp100_orb(HP100_AUTO_MODE, MAC_CFG_3);	/* Autosel back on */
2580		hp100_outl(savelan, 10_LAN_CFG_1);
2581	}
2582
2583	time = jiffies + (3 * HZ);	/* Timeout 3s */
2584	do {
2585		if ((hp100_inb(VG_LAN_CFG_1) & HP100_LINK_CABLE_ST) == 0)
2586			break;
2587		if (!in_interrupt())
2588			schedule_timeout_interruptible(1);
2589	} while (time_after(time, jiffies));
2590
2591	if (time_before_eq(time, jiffies)) {
2592#ifdef HP100_DEBUG
2593		printk("hp100: %s: down_vg_link: timeout\n", dev->name);
2594#endif
2595		return -EIO;
2596	}
2597
2598	time = jiffies + (2 * HZ);	/* This seems to take a while.... */
2599	do {
2600		if (!in_interrupt())
2601			schedule_timeout_interruptible(1);
2602	} while (time_after(time, jiffies));
2603
2604	return 0;
2605}
2606
2607static int hp100_login_to_vg_hub(struct net_device *dev, u_short force_relogin)
2608{
2609	int ioaddr = dev->base_addr;
2610	struct hp100_private *lp = netdev_priv(dev);
2611	u_short val = 0;
2612	unsigned long time;
2613	int startst;
2614
2615#ifdef HP100_DEBUG_B
2616	hp100_outw(0x4225, TRACE);
2617	printk("hp100: %s: login_to_vg_hub\n", dev->name);
2618#endif
2619
2620	/* Initiate a login sequence iff VG MAC is enabled and either Load Address
2621	 * bit is zero or the force relogin flag is set (e.g. due to MAC address or
2622	 * promiscuous mode change)
2623	 */
2624	hp100_page(MAC_CTRL);
2625	startst = hp100_inb(VG_LAN_CFG_1);
2626	if ((force_relogin == 1) || (hp100_inb(MAC_CFG_4) & HP100_MAC_SEL_ST)) {
2627#ifdef HP100_DEBUG_TRAINING
2628		printk("hp100: %s: Start training\n", dev->name);
2629#endif
2630
2631		/* Ensure VG Reset bit is 1 (i.e., do not reset) */
2632		hp100_orb(HP100_VG_RESET, VG_LAN_CFG_1);
2633
2634		/* If Lassen AND auto-select-mode AND VG tones were sensed on */
2635		/* entry then temporarily put them into force 100Mbit mode */
2636		if ((lp->chip == HP100_CHIPID_LASSEN) && (startst & HP100_LINK_CABLE_ST))
2637			hp100_andb(~HP100_DOT3_MAC, 10_LAN_CFG_2);
2638
2639		/* Drop the VG link by zeroing Link Up Command and Load Address  */
2640		hp100_andb(~(HP100_LINK_CMD /* |HP100_LOAD_ADDR */ ), VG_LAN_CFG_1);
2641
2642#ifdef HP100_DEBUG_TRAINING
2643		printk("hp100: %s: Bring down the link\n", dev->name);
2644#endif
2645
2646		/* Wait for link to drop */
2647		time = jiffies + (HZ / 10);
2648		do {
2649			if (~(hp100_inb(VG_LAN_CFG_1) & HP100_LINK_UP_ST))
2650				break;
2651			if (!in_interrupt())
2652				schedule_timeout_interruptible(1);
2653		} while (time_after(time, jiffies));
2654
2655		/* Start an addressed training and optionally request promiscuous port */
2656		if ((dev->flags) & IFF_PROMISC) {
2657			hp100_orb(HP100_PROM_MODE, VG_LAN_CFG_2);
2658			if (lp->chip == HP100_CHIPID_LASSEN)
2659				hp100_orw(HP100_MACRQ_PROMSC, TRAIN_REQUEST);
2660		} else {
2661			hp100_andb(~HP100_PROM_MODE, VG_LAN_CFG_2);
2662			/* For ETR parts we need to reset the prom. bit in the training
2663			 * register, otherwise promiscious mode won't be disabled.
2664			 */
2665			if (lp->chip == HP100_CHIPID_LASSEN) {
2666				hp100_andw(~HP100_MACRQ_PROMSC, TRAIN_REQUEST);
2667			}
2668		}
2669
2670		/* With ETR parts, frame format request bits can be set. */
2671		if (lp->chip == HP100_CHIPID_LASSEN)
2672			hp100_orb(HP100_MACRQ_FRAMEFMT_EITHER, TRAIN_REQUEST);
2673
2674		hp100_orb(HP100_LINK_CMD | HP100_LOAD_ADDR | HP100_VG_RESET, VG_LAN_CFG_1);
2675
2676		/* Note: Next wait could be omitted for Hood and earlier chips under */
2677		/* certain circumstances */
2678		/* TODO: check if hood/earlier and skip wait. */
2679
2680		/* Wait for either short timeout for VG tones or long for login    */
2681		/* Wait for the card hardware to signalise link cable status ok... */
2682		hp100_page(MAC_CTRL);
2683		time = jiffies + (1 * HZ);	/* 1 sec timeout for cable st */
2684		do {
2685			if (hp100_inb(VG_LAN_CFG_1) & HP100_LINK_CABLE_ST)
2686				break;
2687			if (!in_interrupt())
2688				schedule_timeout_interruptible(1);
2689		} while (time_before(jiffies, time));
2690
2691		if (time_after_eq(jiffies, time)) {
2692#ifdef HP100_DEBUG_TRAINING
2693			printk("hp100: %s: Link cable status not ok? Training aborted.\n", dev->name);
2694#endif
2695		} else {
2696#ifdef HP100_DEBUG_TRAINING
2697			printk
2698			    ("hp100: %s: HUB tones detected. Trying to train.\n",
2699			     dev->name);
2700#endif
2701
2702			time = jiffies + (2 * HZ);	/* again a timeout */
2703			do {
2704				val = hp100_inb(VG_LAN_CFG_1);
2705				if ((val & (HP100_LINK_UP_ST))) {
2706#ifdef HP100_DEBUG_TRAINING
2707					printk("hp100: %s: Passed training.\n", dev->name);
2708#endif
2709					break;
2710				}
2711				if (!in_interrupt())
2712					schedule_timeout_interruptible(1);
2713			} while (time_after(time, jiffies));
2714		}
2715
2716		/* If LINK_UP_ST is set, then we are logged into the hub. */
2717		if (time_before_eq(jiffies, time) && (val & HP100_LINK_UP_ST)) {
2718#ifdef HP100_DEBUG_TRAINING
2719			printk("hp100: %s: Successfully logged into the HUB.\n", dev->name);
2720			if (lp->chip == HP100_CHIPID_LASSEN) {
2721				val = hp100_inw(TRAIN_ALLOW);
2722				printk("hp100: %s: Card supports 100VG MAC Version \"%s\" ",
2723					     dev->name, (hp100_inw(TRAIN_REQUEST) & HP100_CARD_MACVER) ? "802.12" : "Pre");
2724				printk("Driver will use MAC Version \"%s\"\n", (val & HP100_HUB_MACVER) ? "802.12" : "Pre");
2725				printk("hp100: %s: Frame format is %s.\n", dev->name, (val & HP100_MALLOW_FRAMEFMT) ? "802.5" : "802.3");
2726			}
2727#endif
2728		} else {
2729			/* If LINK_UP_ST is not set, login was not successful */
2730			printk("hp100: %s: Problem logging into the HUB.\n", dev->name);
2731			if (lp->chip == HP100_CHIPID_LASSEN) {
2732				/* Check allowed Register to find out why there is a problem. */
2733				val = hp100_inw(TRAIN_ALLOW);	/* won't work on non-ETR card */
2734#ifdef HP100_DEBUG_TRAINING
2735				printk("hp100: %s: MAC Configuration requested: 0x%04x, HUB allowed: 0x%04x\n", dev->name, hp100_inw(TRAIN_REQUEST), val);
2736#endif
2737				if (val & HP100_MALLOW_ACCDENIED)
2738					printk("hp100: %s: HUB access denied.\n", dev->name);
2739				if (val & HP100_MALLOW_CONFIGURE)
2740					printk("hp100: %s: MAC Configuration is incompatible with the Network.\n", dev->name);
2741				if (val & HP100_MALLOW_DUPADDR)
2742					printk("hp100: %s: Duplicate MAC Address on the Network.\n", dev->name);
2743			}
2744		}
2745
2746		/* If we have put the chip into forced 100 Mbit mode earlier, go back */
2747		/* to auto-select mode */
2748
2749		if ((lp->chip == HP100_CHIPID_LASSEN) && (startst & HP100_LINK_CABLE_ST)) {
2750			hp100_page(MAC_CTRL);
2751			hp100_orb(HP100_DOT3_MAC, 10_LAN_CFG_2);
2752		}
2753
2754		val = hp100_inb(VG_LAN_CFG_1);
2755
2756		/* Clear the MISC_ERROR Interrupt, which might be generated when doing the relogin */
2757		hp100_page(PERFORMANCE);
2758		hp100_outw(HP100_MISC_ERROR, IRQ_STATUS);
2759
2760		if (val & HP100_LINK_UP_ST)
2761			return (0);	/* login was ok */
2762		else {
2763			printk("hp100: %s: Training failed.\n", dev->name);
2764			hp100_down_vg_link(dev);
2765			return -EIO;
2766		}
2767	}
2768	/* no forced relogin & already link there->no training. */
2769	return -EIO;
2770}
2771
2772static void hp100_cascade_reset(struct net_device *dev, u_short enable)
2773{
2774	int ioaddr = dev->base_addr;
2775	struct hp100_private *lp = netdev_priv(dev);
2776
2777#ifdef HP100_DEBUG_B
2778	hp100_outw(0x4226, TRACE);
2779	printk("hp100: %s: cascade_reset\n", dev->name);
2780#endif
2781
2782	if (enable) {
2783		hp100_outw(HP100_HW_RST | HP100_RESET_LB, OPTION_LSW);
2784		if (lp->chip == HP100_CHIPID_LASSEN) {
2785			/* Lassen requires a PCI transmit fifo reset */
2786			hp100_page(HW_MAP);
2787			hp100_andb(~HP100_PCI_RESET, PCICTRL2);
2788			hp100_orb(HP100_PCI_RESET, PCICTRL2);
2789			/* Wait for min. 300 ns */
2790			/* we can't use jiffies here, because it may be */
2791			/* that we have disabled the timer... */
2792			udelay(400);
2793			hp100_andb(~HP100_PCI_RESET, PCICTRL2);
2794			hp100_page(PERFORMANCE);
2795		}
2796	} else {		/* bring out of reset */
2797		hp100_outw(HP100_HW_RST | HP100_SET_LB, OPTION_LSW);
2798		udelay(400);
2799		hp100_page(PERFORMANCE);
2800	}
2801}
2802
2803#ifdef HP100_DEBUG
2804void hp100_RegisterDump(struct net_device *dev)
2805{
2806	int ioaddr = dev->base_addr;
2807	int Page;
2808	int Register;
2809
2810	/* Dump common registers */
2811	printk("hp100: %s: Cascade Register Dump\n", dev->name);
2812	printk("hardware id #1: 0x%.2x\n", hp100_inb(HW_ID));
2813	printk("hardware id #2/paging: 0x%.2x\n", hp100_inb(PAGING));
2814	printk("option #1: 0x%.4x\n", hp100_inw(OPTION_LSW));
2815	printk("option #2: 0x%.4x\n", hp100_inw(OPTION_MSW));
2816
2817	/* Dump paged registers */
2818	for (Page = 0; Page < 8; Page++) {
2819		/* Dump registers */
2820		printk("page: 0x%.2x\n", Page);
2821		outw(Page, ioaddr + 0x02);
2822		for (Register = 0x8; Register < 0x22; Register += 2) {
2823			/* Display Register contents except data port */
2824			if (((Register != 0x10) && (Register != 0x12)) || (Page > 0)) {
2825				printk("0x%.2x = 0x%.4x\n", Register, inw(ioaddr + Register));
2826			}
2827		}
2828	}
2829	hp100_page(PERFORMANCE);
2830}
2831#endif
2832
2833
2834static void cleanup_dev(struct net_device *d)
2835{
2836	struct hp100_private *p = netdev_priv(d);
2837
2838	unregister_netdev(d);
2839	release_region(d->base_addr, HP100_REGION_SIZE);
2840
2841	if (p->mode == 1)	/* busmaster */
2842		pci_free_consistent(p->pci_dev, MAX_RINGSIZE + 0x0f, 
2843				    p->page_vaddr_algn, 
2844				    virt_to_whatever(d, p->page_vaddr_algn));
2845	if (p->mem_ptr_virt)
2846		iounmap(p->mem_ptr_virt);
2847
2848	free_netdev(d);
2849}
2850
2851#ifdef CONFIG_EISA
2852static int __init hp100_eisa_probe (struct device *gendev)
2853{
2854	struct net_device *dev = alloc_etherdev(sizeof(struct hp100_private));
2855	struct eisa_device *edev = to_eisa_device(gendev);
2856	int err;
2857
2858	if (!dev)
2859		return -ENOMEM;
2860
2861	SET_MODULE_OWNER(dev);
2862	SET_NETDEV_DEV(dev, &edev->dev);
2863
2864	err = hp100_probe1(dev, edev->base_addr + 0xC38, HP100_BUS_EISA, NULL);
2865	if (err)
2866		goto out1;
2867
2868#ifdef HP100_DEBUG
2869	printk("hp100: %s: EISA adapter found at 0x%x\n", dev->name, 
2870	       dev->base_addr);
2871#endif
2872	gendev->driver_data = dev;
2873	return 0;
2874 out1:
2875	free_netdev(dev);
2876	return err;
2877}
2878
2879static int __devexit hp100_eisa_remove (struct device *gendev)
2880{
2881	struct net_device *dev = gendev->driver_data;
2882	cleanup_dev(dev);
2883	return 0;
2884}
2885
2886static struct eisa_driver hp100_eisa_driver = {
2887        .id_table = hp100_eisa_tbl,
2888        .driver   = {
2889                .name    = "hp100",
2890                .probe   = hp100_eisa_probe,
2891                .remove  = __devexit_p (hp100_eisa_remove),
2892        }
2893};
2894#endif
2895
2896#ifdef CONFIG_PCI
2897static int __devinit hp100_pci_probe (struct pci_dev *pdev,
2898				     const struct pci_device_id *ent)
2899{
2900	struct net_device *dev;
2901	int ioaddr;
2902	u_short pci_command;
2903	int err;
2904
2905	if (pci_enable_device(pdev))
2906		return -ENODEV;
2907
2908	dev = alloc_etherdev(sizeof(struct hp100_private));
2909	if (!dev) {
2910		err = -ENOMEM;
2911		goto out0;
2912	}
2913
2914	SET_MODULE_OWNER(dev);
2915	SET_NETDEV_DEV(dev, &pdev->dev);
2916
2917	pci_read_config_word(pdev, PCI_COMMAND, &pci_command);
2918	if (!(pci_command & PCI_COMMAND_IO)) {
2919#ifdef HP100_DEBUG
2920		printk("hp100: %s: PCI I/O Bit has not been set. Setting...\n", dev->name);
2921#endif
2922		pci_command |= PCI_COMMAND_IO;
2923		pci_write_config_word(pdev, PCI_COMMAND, pci_command);
2924	}
2925
2926	if (!(pci_command & PCI_COMMAND_MASTER)) {
2927#ifdef HP100_DEBUG
2928		printk("hp100: %s: PCI Master Bit has not been set. Setting...\n", dev->name);
2929#endif
2930		pci_command |= PCI_COMMAND_MASTER;
2931		pci_write_config_word(pdev, PCI_COMMAND, pci_command);
2932	}
2933	
2934	ioaddr = pci_resource_start(pdev, 0);
2935	err = hp100_probe1(dev, ioaddr, HP100_BUS_PCI, pdev);
2936	if (err) 
2937		goto out1;
2938	
2939#ifdef HP100_DEBUG
2940	printk("hp100: %s: PCI adapter found at 0x%x\n", dev->name, ioaddr);
2941#endif
2942	pci_set_drvdata(pdev, dev);
2943	return 0;
2944 out1:
2945	free_netdev(dev);
2946 out0:
2947	pci_disable_device(pdev);
2948	return err;
2949}
2950
2951static void __devexit hp100_pci_remove (struct pci_dev *pdev)
2952{
2953	struct net_device *dev = pci_get_drvdata(pdev);
2954
2955	cleanup_dev(dev);
2956	pci_disable_device(pdev);
2957}
2958
2959
2960static struct pci_driver hp100_pci_driver = {
2961	.name		= "hp100",
2962	.id_table	= hp100_pci_tbl,
2963	.probe		= hp100_pci_probe,
2964	.remove		= __devexit_p(hp100_pci_remove),
2965};
2966#endif
2967
2968/*
2969 *  module section
2970 */
2971
2972MODULE_LICENSE("GPL");
2973MODULE_AUTHOR("Jaroslav Kysela <perex@suse.cz>, "
2974              "Siegfried \"Frieder\" Loeffler (dg1sek) <floeff@mathematik.uni-stuttgart.de>");
2975MODULE_DESCRIPTION("HP CASCADE Architecture Driver for 100VG-AnyLan Network Adapters");
2976
2977/*
2978 * Note: to register three isa devices, use:
2979 * option hp100 hp100_port=0,0,0
2980 *        to register one card at io 0x280 as eth239, use:
2981 * option hp100 hp100_port=0x280
2982 */
2983#if defined(MODULE) && defined(CONFIG_ISA)
2984#define HP100_DEVICES 5
2985/* Parameters set by insmod */
2986static int hp100_port[HP100_DEVICES] = { 0, [1 ... (HP100_DEVICES-1)] = -1 };
2987module_param_array(hp100_port, int, NULL, 0);
2988
2989/* List of devices */
2990static struct net_device *hp100_devlist[HP100_DEVICES];
2991
2992static int __init hp100_isa_init(void)
2993{
2994	struct net_device *dev;
2995	int i, err, cards = 0;
2996
2997	/* Don't autoprobe ISA bus */
2998	if (hp100_port[0] == 0)
2999		return -ENODEV;
3000
3001	/* Loop on all possible base addresses */
3002	for (i = 0; i < HP100_DEVICES && hp100_port[i] != -1; ++i) {
3003		dev = alloc_etherdev(sizeof(struct hp100_private));
3004		if (!dev) {
3005			printk(KERN_WARNING "hp100: no memory for network device\n");
3006			while (cards > 0)
3007				cleanup_dev(hp100_devlist[--cards]);
3008
3009			return -ENOMEM;
3010		}
3011		SET_MODULE_OWNER(dev);
3012
3013		err = hp100_isa_probe(dev, hp100_port[i]);
3014		if (!err)
3015			hp100_devlist[cards++] = dev;
3016		else
3017			free_netdev(dev);
3018	}
3019
3020	return cards > 0 ? 0 : -ENODEV;
3021}
3022
3023static void __exit hp100_isa_cleanup(void) 
3024{
3025	int i;
3026
3027	for (i = 0; i < HP100_DEVICES; i++) {
3028		struct net_device *dev = hp100_devlist[i];
3029		if (dev)
3030			cleanup_dev(dev);
3031	}
3032}
3033#else
3034#define hp100_isa_init()	(0)
3035#define hp100_isa_cleanup()	do { } while(0)
3036#endif
3037
3038static int __init hp100_module_init(void)
3039{
3040	int err;
3041
3042	err = hp100_isa_init();
3043	if (err && err != -ENODEV)
3044		goto out;
3045#ifdef CONFIG_EISA
3046	err = eisa_driver_register(&hp100_eisa_driver);
3047	if (err && err != -ENODEV) 
3048		goto out2;
3049#endif
3050#ifdef CONFIG_PCI
3051	err = pci_module_init(&hp100_pci_driver);
3052	if (err && err != -ENODEV) 
3053		goto out3;
3054#endif
3055 out:
3056	return err;
3057 out3:
3058#ifdef CONFIG_EISA
3059	eisa_driver_unregister (&hp100_eisa_driver);
3060 out2:
3061#endif
3062	hp100_isa_cleanup();
3063	goto out;
3064}
3065
3066
3067static void __exit hp100_module_exit(void)
3068{
3069	hp100_isa_cleanup();
3070#ifdef CONFIG_EISA
3071	eisa_driver_unregister (&hp100_eisa_driver);
3072#endif
3073#ifdef CONFIG_PCI
3074	pci_unregister_driver (&hp100_pci_driver);
3075#endif
3076}
3077
3078module_init(hp100_module_init)
3079module_exit(hp100_module_exit)
3080
3081
3082/*
3083 * Local variables:
3084 *  compile-command: "gcc -D__KERNEL__ -I/usr/src/linux/net/inet -Wall -Wstrict-prototypes -O6 -m486 -c hp100.c"
3085 *  c-indent-level: 2
3086 *  tab-width: 8
3087 * End:
3088 */
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