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ipxe/src/drivers/net/dmfe.c

dmfe.c 32KB
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  1. /**************************************************************************

  2. *

  3. *    dmfe.c -- Etherboot device driver for the Davicom 

  4. *	DM9102/DM9102A/DM9102A+DM9801/DM9102A+DM9802 NIC fast ethernet card

  5. *

  6. *    Written 2003-2003 by Timothy Legge <tlegge@rogers.com>

  7. *

  8. *    This program is free software; you can redistribute it and/or modify

  9. *    it under the terms of the GNU General Public License as published by

  10. *    the Free Software Foundation; either version 2 of the License, or

  11. *    (at your option) any later version.

  12. *

  13. *    This program is distributed in the hope that it will be useful,

  14. *    but WITHOUT ANY WARRANTY; without even the implied warranty of

  15. *    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  16. *    GNU General Public License for more details.

  17. *

  18. *    You should have received a copy of the GNU General Public License

  19. *    along with this program; if not, write to the Free Software

  20. *    Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.

  21. *

  22. *    Portions of this code based on:

  23. *

  24. *       dmfe.c:     A Davicom DM9102/DM9102A/DM9102A+DM9801/DM9102A+DM9802 

  25. *		NIC fast ethernet driver for Linux.

  26. *       Copyright (C) 1997  Sten Wang

  27. *       (C)Copyright 1997-1998 DAVICOM Semiconductor,Inc. All Rights Reserved.

  28. *

  29. *

  30. *    REVISION HISTORY:

  31. *    ================

  32. *    v1.0       10-02-2004      timlegge        Boots ltsp needs cleanup 

  33. *

  34. *    Indent Options: indent -kr -i8

  35. *

  36. *

  37. ***************************************************************************/

  38. 

  39. /* to get some global routines like printf */

  40. #include "etherboot.h"

  41. /* to get the interface to the body of the program */

  42. #include "nic.h"

  43. /* to get the PCI support functions, if this is a PCI NIC */

  44. #include "pci.h"

  45. #include "timer.h"

  46. 

  47. /* #define EDEBUG 1 */

  48. #ifdef EDEBUG

  49. #define dprintf(x) printf x

  50. #else

  51. #define dprintf(x)

  52. #endif

  53. 

  54. typedef unsigned char u8;

  55. typedef signed char s8;

  56. typedef unsigned short u16;

  57. typedef signed short s16;

  58. typedef unsigned int u32;

  59. typedef signed int s32;

  60. 

  61. /* Condensed operations for readability. */

  62. #define virt_to_le32desc(addr)  cpu_to_le32(virt_to_bus(addr))

  63. #define le32desc_to_virt(addr)  bus_to_virt(le32_to_cpu(addr))

  64. 

  65. /* Board/System/Debug information/definition ---------------- */

  66. #define PCI_DM9132_ID   0x91321282	/* Davicom DM9132 ID */

  67. #define PCI_DM9102_ID   0x91021282	/* Davicom DM9102 ID */

  68. #define PCI_DM9100_ID   0x91001282	/* Davicom DM9100 ID */

  69. #define PCI_DM9009_ID   0x90091282	/* Davicom DM9009 ID */

  70. 

  71. #define DM9102_IO_SIZE  0x80

  72. #define DM9102A_IO_SIZE 0x100

  73. #define TX_MAX_SEND_CNT 0x1	/* Maximum tx packet per time */

  74. #define TX_DESC_CNT     0x10	/* Allocated Tx descriptors */

  75. #define RX_DESC_CNT     0x20	/* Allocated Rx descriptors */

  76. #define TX_FREE_DESC_CNT (TX_DESC_CNT - 2)	/* Max TX packet count */

  77. #define TX_WAKE_DESC_CNT (TX_DESC_CNT - 3)	/* TX wakeup count */

  78. #define DESC_ALL_CNT    (TX_DESC_CNT + RX_DESC_CNT)

  79. #define TX_BUF_ALLOC    0x600

  80. #define RX_ALLOC_SIZE   0x620

  81. #define DM910X_RESET    1

  82. #define CR0_DEFAULT     0x00E00000	/* TX & RX burst mode */

  83. #define CR6_DEFAULT     0x00080000	/* HD */

  84. #define CR7_DEFAULT     0x180c1

  85. #define CR15_DEFAULT    0x06	/* TxJabber RxWatchdog */

  86. #define TDES0_ERR_MASK  0x4302	/* TXJT, LC, EC, FUE */

  87. #define MAX_PACKET_SIZE 1514

  88. #define DMFE_MAX_MULTICAST 14

  89. #define RX_COPY_SIZE	100

  90. #define MAX_CHECK_PACKET 0x8000

  91. #define DM9801_NOISE_FLOOR 8

  92. #define DM9802_NOISE_FLOOR 5

  93. 

  94. #define DMFE_10MHF      0

  95. #define DMFE_100MHF     1

  96. #define DMFE_10MFD      4

  97. #define DMFE_100MFD     5

  98. #define DMFE_AUTO       8

  99. #define DMFE_1M_HPNA    0x10

  100. 

  101. #define DMFE_TXTH_72	0x400000	/* TX TH 72 byte */

  102. #define DMFE_TXTH_96	0x404000	/* TX TH 96 byte */

  103. #define DMFE_TXTH_128	0x0000	/* TX TH 128 byte */

  104. #define DMFE_TXTH_256	0x4000	/* TX TH 256 byte */

  105. #define DMFE_TXTH_512	0x8000	/* TX TH 512 byte */

  106. #define DMFE_TXTH_1K	0xC000	/* TX TH 1K  byte */

  107. 

  108. #define DMFE_TIMER_WUT  (jiffies + HZ * 1)	/* timer wakeup time : 1 second */

  109. #define DMFE_TX_TIMEOUT ((3*HZ)/2)	/* tx packet time-out time 1.5 s" */

  110. #define DMFE_TX_KICK 	(HZ/2)	/* tx packet Kick-out time 0.5 s" */

  111. 

  112. #define DMFE_DBUG(dbug_now, msg, value) if (dmfe_debug || (dbug_now)) printk(KERN_ERR DRV_NAME ": %s %lx\n", (msg), (long) (value))

  113. 

  114. #define SHOW_MEDIA_TYPE(mode) printk(KERN_ERR DRV_NAME ": Change Speed to %sMhz %s duplex\n",mode & 1 ?"100":"10", mode & 4 ? "full":"half");

  115. 

  116. 

  117. /* CR9 definition: SROM/MII */

  118. #define CR9_SROM_READ   0x4800

  119. #define CR9_SRCS        0x1

  120. #define CR9_SRCLK       0x2

  121. #define CR9_CRDOUT      0x8

  122. #define SROM_DATA_0     0x0

  123. #define SROM_DATA_1     0x4

  124. #define PHY_DATA_1      0x20000

  125. #define PHY_DATA_0      0x00000

  126. #define MDCLKH          0x10000

  127. 

  128. #define PHY_POWER_DOWN	0x800

  129. 

  130. #define SROM_V41_CODE   0x14

  131. 

  132. #define SROM_CLK_WRITE(data, ioaddr) outl(data|CR9_SROM_READ|CR9_SRCS,ioaddr);udelay(5);outl(data|CR9_SROM_READ|CR9_SRCS|CR9_SRCLK,ioaddr);udelay(5);outl(data|CR9_SROM_READ|CR9_SRCS,ioaddr);udelay(5);

  133. 

  134. #define __CHK_IO_SIZE(pci_id, dev_rev) ( ((pci_id)==PCI_DM9132_ID) || ((dev_rev) >= 0x02000030) ) ? DM9102A_IO_SIZE: DM9102_IO_SIZE

  135. #define CHK_IO_SIZE(pci_dev, dev_rev) __CHK_IO_SIZE(((pci_dev)->device << 16) | (pci_dev)->vendor, dev_rev)

  136. 

  137. /* Sten Check */

  138. #define DEVICE net_device

  139. 

  140. /* Structure/enum declaration ------------------------------- */

  141. struct tx_desc {

  142. 	u32 tdes0, tdes1, tdes2, tdes3;	/* Data for the card */

  143. 	u32 tx_buf_ptr;		/* Data for us */

  144. 	 u32 /* struct tx_desc * */ next_tx_desc;

  145. } __attribute__ ((aligned(32)));

  146. 

  147. struct rx_desc {

  148. 	u32 rdes0, rdes1, rdes2, rdes3;	/* Data for the card */

  149. 	u32 rx_skb_ptr;		/* Data for us */

  150. 	 u32 /* struct rx_desc * */ next_rx_desc;

  151. } __attribute__ ((aligned(32)));

  152. 

  153. struct dmfe_private {

  154. 	u32 chip_id;		/* Chip vendor/Device ID */

  155. 	u32 chip_revision;	/* Chip revision */

  156. 	u32 cr0_data;

  157. //	u32 cr5_data;

  158. 	u32 cr6_data;

  159. 	u32 cr7_data;

  160. 	u32 cr15_data;

  161. 

  162. 	u16 HPNA_command;	/* For HPNA register 16 */

  163. 	u16 HPNA_timer;		/* For HPNA remote device check */

  164. 	u16 NIC_capability;	/* NIC media capability */

  165. 	u16 PHY_reg4;		/* Saved Phyxcer register 4 value */

  166. 

  167. 	u8 HPNA_present;	/* 0:none, 1:DM9801, 2:DM9802 */

  168. 	u8 chip_type;		/* Keep DM9102A chip type */

  169. 	u8 media_mode;		/* user specify media mode */

  170. 	u8 op_mode;		/* real work media mode */

  171. 	u8 phy_addr;

  172. 	u8 dm910x_chk_mode;	/* Operating mode check */

  173. 

  174. 	/* NIC SROM data */

  175. 	unsigned char srom[128];

  176. 	/* Etherboot Only */

  177. 	u8 cur_tx;

  178. 	u8 cur_rx;

  179. } dfx;

  180. 

  181. static struct dmfe_private *db;

  182. 

  183. enum dmfe_offsets {

  184. 	DCR0 = 0x00, DCR1 = 0x08, DCR2 = 0x10, DCR3 = 0x18, DCR4 = 0x20,

  185. 	DCR5 = 0x28, DCR6 = 0x30, DCR7 = 0x38, DCR8 = 0x40, DCR9 = 0x48,

  186. 	DCR10 = 0x50, DCR11 = 0x58, DCR12 = 0x60, DCR13 = 0x68, DCR14 =

  187. 	    0x70,

  188. 	DCR15 = 0x78

  189. };

  190. 

  191. enum dmfe_CR6_bits {

  192. 	CR6_RXSC = 0x2, CR6_PBF = 0x8, CR6_PM = 0x40, CR6_PAM = 0x80,

  193. 	CR6_FDM = 0x200, CR6_TXSC = 0x2000, CR6_STI = 0x100000,

  194. 	CR6_SFT = 0x200000, CR6_RXA = 0x40000000, CR6_NO_PURGE = 0x20000000

  195. };

  196. 

  197. /* Global variable declaration ----------------------------- */

  198. static struct nic_operations dmfe_operations;

  199. static struct pci_driver dmfe_driver;

  200. 

  201. static unsigned char dmfe_media_mode = DMFE_AUTO;

  202. static u32 dmfe_cr6_user_set;

  203. 

  204. /* For module input parameter */

  205. static u8 chkmode = 1;

  206. static u8 HPNA_mode;		/* Default: Low Power/High Speed */

  207. static u8 HPNA_rx_cmd;		/* Default: Disable Rx remote command */

  208. static u8 HPNA_tx_cmd;		/* Default: Don't issue remote command */

  209. static u8 HPNA_NoiseFloor;	/* Default: HPNA NoiseFloor */

  210. static u8 SF_mode;		/* Special Function: 1:VLAN, 2:RX Flow Control

  211. 				   4: TX pause packet */

  212. 

  213. 

  214. /**********************************************

  215. * Descriptor Ring and Buffer defination

  216. ***********************************************/

  217. /* Define the TX Descriptor */

  218. static struct tx_desc txd[TX_DESC_CNT]

  219.     __attribute__ ((aligned(32)));

  220. 

  221. /* Create a static buffer of size PKT_BUF_SZ for each TX Descriptor.

  222.   All descriptors point to a part of this buffer */

  223. static unsigned char txb[TX_BUF_ALLOC * TX_DESC_CNT]

  224.     __attribute__ ((aligned(32)));

  225. 

  226. /* Define the RX Descriptor */

  227. static struct rx_desc rxd[RX_DESC_CNT]

  228. __attribute__ ((aligned(32)));

  229. 

  230. /* Create a static buffer of size PKT_BUF_SZ for each RX Descriptor.

  231.    All descriptors point to a part of this buffer */

  232. static unsigned char rxb[RX_ALLOC_SIZE * RX_DESC_CNT]

  233. __attribute__ ((aligned(32)));

  234. 

  235. /* NIC specific static variables go here */

  236. long int BASE;

  237. 

  238. static u16 read_srom_word(long ioaddr, int offset);

  239. static void dmfe_init_dm910x(struct nic *nic);

  240. static void dmfe_descriptor_init(struct nic *, unsigned long ioaddr);

  241. static void update_cr6(u32, unsigned long);

  242. static void send_filter_frame(struct nic *nic);

  243. static void dm9132_id_table(struct nic *nic);

  244. 

  245. static u16 phy_read(unsigned long, u8, u8, u32);

  246. static void phy_write(unsigned long, u8, u8, u16, u32);

  247. static void phy_write_1bit(unsigned long, u32);

  248. static u16 phy_read_1bit(unsigned long);

  249. static void dmfe_set_phyxcer(struct nic *nic);

  250. 

  251. static void dmfe_parse_srom(struct nic *nic);

  252. static void dmfe_program_DM9801(struct nic *nic, int);

  253. static void dmfe_program_DM9802(struct nic *nic);

  254. 

  255. static void dmfe_reset(struct nic *nic)

  256. {

  257. 	/* system variable init */

  258. 	db->cr6_data = CR6_DEFAULT | dmfe_cr6_user_set;

  259. 

  260. 	db->NIC_capability = 0xf;	/* All capability */

  261. 	db->PHY_reg4 = 0x1e0;

  262. 

  263. 	/* CR6 operation mode decision */

  264. 	if (!chkmode || (db->chip_id == PCI_DM9132_ID) ||

  265. 	    (db->chip_revision >= 0x02000030)) {

  266. 		db->cr6_data |= DMFE_TXTH_256;

  267. 		db->cr0_data = CR0_DEFAULT;

  268. 		db->dm910x_chk_mode = 4;	/* Enter the normal mode */

  269. 	} else {

  270. 		db->cr6_data |= CR6_SFT;	/* Store & Forward mode */

  271. 		db->cr0_data = 0;

  272. 		db->dm910x_chk_mode = 1;	/* Enter the check mode */

  273. 	}

  274. 	/* Initilize DM910X board */

  275. 	dmfe_init_dm910x(nic);

  276. 

  277. 	return;

  278. }

  279. 

  280. /*	Initilize DM910X board

  281.  *	Reset DM910X board

  282.  *	Initilize TX/Rx descriptor chain structure

  283.  *	Send the set-up frame

  284.  *	Enable Tx/Rx machine

  285.  */

  286. 

  287. static void dmfe_init_dm910x(struct nic *nic)

  288. {

  289. 	unsigned long ioaddr = BASE;

  290. 

  291. 	/* Reset DM910x MAC controller */

  292. 	outl(DM910X_RESET, ioaddr + DCR0);	/* RESET MAC */

  293. 	udelay(100);

  294. 	outl(db->cr0_data, ioaddr + DCR0);

  295. 	udelay(5);

  296. 

  297. 	/* Phy addr : DM910(A)2/DM9132/9801, phy address = 1 */

  298. 	db->phy_addr = 1;

  299. 

  300. 	/* Parser SROM and media mode */

  301. 	dmfe_parse_srom(nic);

  302. 	db->media_mode = dmfe_media_mode;

  303. 

  304. 	/* RESET Phyxcer Chip by GPR port bit 7 */

  305. 	outl(0x180, ioaddr + DCR12);	/* Let bit 7 output port */

  306. 	if (db->chip_id == PCI_DM9009_ID) {

  307. 		outl(0x80, ioaddr + DCR12);	/* Issue RESET signal */

  308. 		mdelay(300);	/* Delay 300 ms */

  309. 	}

  310. 	outl(0x0, ioaddr + DCR12);	/* Clear RESET signal */

  311. 

  312. 	/* Process Phyxcer Media Mode */

  313. 	if (!(db->media_mode & 0x10))	/* Force 1M mode */

  314. 		dmfe_set_phyxcer(nic);

  315. 

  316. 	/* Media Mode Process */

  317. 	if (!(db->media_mode & DMFE_AUTO))

  318. 		db->op_mode = db->media_mode;	/* Force Mode */

  319. 

  320. 	/* Initiliaze Transmit/Receive decriptor and CR3/4 */

  321. 	dmfe_descriptor_init(nic, ioaddr);

  322. 

  323. 	/* tx descriptor start pointer */

  324. 	outl(virt_to_le32desc(&txd[0]), ioaddr + DCR4);	/* TX DESC address */

  325. 

  326. 	/* rx descriptor start pointer */

  327. 	outl(virt_to_le32desc(&rxd[0]), ioaddr + DCR3);	/* RX DESC address */

  328. 

  329. 	/* Init CR6 to program DM910x operation */

  330. 	update_cr6(db->cr6_data, ioaddr);

  331. 

  332. 	/* Send setup frame */

  333. 	if (db->chip_id == PCI_DM9132_ID) {

  334. 		dm9132_id_table(nic);	/* DM9132 */

  335. 	} else {

  336. 		send_filter_frame(nic);	/* DM9102/DM9102A */

  337. 	}

  338. 

  339. 	/* Init CR7, interrupt active bit */

  340. 	db->cr7_data = CR7_DEFAULT;

  341. 	outl(db->cr7_data, ioaddr + DCR7);

  342. 	/* Init CR15, Tx jabber and Rx watchdog timer */

  343. 	outl(db->cr15_data, ioaddr + DCR15);

  344. 	/* Enable DM910X Tx/Rx function */

  345. 	db->cr6_data |= CR6_RXSC | CR6_TXSC | 0x40000;

  346. 	update_cr6(db->cr6_data, ioaddr);

  347. }

  348. #ifdef EDEBUG

  349. void hex_dump(const char *data, const unsigned int len);

  350. #endif

  351. /**************************************************************************

  352. POLL - Wait for a frame

  353. ***************************************************************************/

  354. static int dmfe_poll(struct nic *nic, int retrieve)

  355. {

  356. 	u32 rdes0;

  357. 	int entry = db->cur_rx % RX_DESC_CNT;

  358. 	int rxlen;

  359. 	rdes0 = le32_to_cpu(rxd[entry].rdes0);

  360. 	if (rdes0 & 0x80000000)

  361. 		return 0;

  362. 

  363. 	if (!retrieve)

  364. 		return 1;

  365. 

  366. 	if ((rdes0 & 0x300) != 0x300) {

  367. 		/* A packet without First/Last flag */

  368. 		printf("strange Packet\n");

  369. 		rxd[entry].rdes0 = cpu_to_le32(0x80000000);

  370. 		return 0;

  371. 	} else {

  372. 		/* A packet with First/Last flag */

  373. 		rxlen = ((rdes0 >> 16) & 0x3fff) - 4;

  374. 		/* error summary bit check */

  375. 		if (rdes0 & 0x8000) {

  376. 			printf("Error\n");

  377. 			return 0;

  378. 		}

  379. 		if (!(rdes0 & 0x8000) ||

  380. 		    ((db->cr6_data & CR6_PM) && (rxlen > 6))) {

  381. 			if (db->dm910x_chk_mode & 1)

  382. 				printf("Silly check mode\n");

  383. 

  384. 			nic->packetlen = rxlen;

  385. 			memcpy(nic->packet, rxb + (entry * RX_ALLOC_SIZE),

  386. 			       nic->packetlen);

  387. 		}

  388. 	}

  389. 	rxd[entry].rdes0 = cpu_to_le32(0x80000000);

  390. 	db->cur_rx++;

  391. 	return 1;

  392. }

  393. 

  394. static void dmfe_irq(struct nic *nic __unused, irq_action_t action __unused)

  395. {

  396. 	switch ( action ) {

  397. 		case DISABLE :

  398. 			break;

  399. 		case ENABLE :

  400. 			break;

  401. 		case FORCE :

  402. 			break;

  403. 	}

  404. }

  405. 

  406. /**************************************************************************

  407. TRANSMIT - Transmit a frame

  408. ***************************************************************************/

  409. static void dmfe_transmit(struct nic *nic, 

  410. 	const char *dest,	/* Destination */

  411. 	unsigned int type,	/* Type */

  412. 	unsigned int size,	/* size */

  413. 	const char *packet)	/* Packet */

  414. {	

  415. 	u16 nstype;

  416. 	u8 *ptxb;

  417. 

  418. 	ptxb = &txb[db->cur_tx];

  419. 

  420. 	/* Stop Tx */

  421. 	outl(0, BASE + DCR7);

  422. 	memcpy(ptxb, dest, ETH_ALEN);

  423. 	memcpy(ptxb + ETH_ALEN, nic->node_addr, ETH_ALEN);

  424. 	nstype = htons((u16) type);

  425. 	memcpy(ptxb + 2 * ETH_ALEN, (u8 *) & nstype, 2);

  426. 	memcpy(ptxb + ETH_HLEN, packet, size);

  427. 

  428. 	size += ETH_HLEN;

  429. 	while (size < ETH_ZLEN)

  430. 		ptxb[size++] = '\0';

  431. 

  432. 	/* setup the transmit descriptor */

  433. 	txd[db->cur_tx].tdes1 = cpu_to_le32(0xe1000000 | size);

  434. 	txd[db->cur_tx].tdes0 = cpu_to_le32(0x80000000);	/* give ownership to device */

  435. 

  436. 	/* immediate transmit demand */

  437. 	outl(0x1, BASE + DCR1);

  438. 	outl(db->cr7_data, BASE + DCR7);

  439. 

  440. 	/* Point to next TX descriptor */

  441. 	db->cur_tx++;

  442. 	db->cur_tx = db->cur_tx % TX_DESC_CNT;

  443. }

  444. 

  445. /**************************************************************************

  446. DISABLE - Turn off ethernet interface

  447. ***************************************************************************/

  448. static void dmfe_disable ( struct nic *nic __unused ) {

  449. 	/* Reset & stop DM910X board */

  450. 	outl(DM910X_RESET, BASE + DCR0);

  451. 	udelay(5);

  452. 	phy_write(BASE, db->phy_addr, 0, 0x8000, db->chip_id);

  453. 

  454. }

  455. 

  456. /**************************************************************************

  457. PROBE - Look for an adapter, this routine's visible to the outside

  458. ***************************************************************************/

  459. 

  460. #define board_found 1

  461. #define valid_link 0

  462. static int dmfe_probe ( struct dev *dev, struct pci_device *pci ) {

  463. 	struct nic *nic = nic_device ( dev );

  464. 	uint32_t dev_rev, pci_pmr;

  465. 	int i;

  466. 

  467. 	if (pci->ioaddr == 0)

  468. 		return 0;

  469. 

  470. 	BASE = pci->ioaddr;

  471. 	printf("dmfe.c: Found %s Vendor=0x%hX Device=0x%hX\n",

  472. 	       dev->name, pci->vendor, pci->dev_id);

  473. 

  474. 	/* Read Chip revision */

  475. 	pci_read_config_dword(pci, PCI_REVISION_ID, &dev_rev);

  476. 	dprintf(("Revision %lX\n", dev_rev));

  477. 

  478. 	/* point to private storage */

  479. 	db = &dfx;

  480. 

  481. 	db->chip_id = ((u32) pci->dev_id << 16) | pci->vendor;

  482. 	BASE = pci_bar_start(pci, PCI_BASE_ADDRESS_0);

  483. 	db->chip_revision = dev_rev;

  484. 

  485. 	pci_read_config_dword(pci, 0x50, &pci_pmr);

  486. 	pci_pmr &= 0x70000;

  487. 	if ((pci_pmr == 0x10000) && (dev_rev == 0x02000031))

  488. 		db->chip_type = 1;	/* DM9102A E3 */

  489. 	else

  490. 		db->chip_type = 0;

  491. 

  492. 	dprintf(("Chip type : %d\n", db->chip_type));

  493. 

  494. 	/* read 64 word srom data */

  495. 	for (i = 0; i < 64; i++)

  496. 		((u16 *) db->srom)[i] = cpu_to_le16(read_srom_word(BASE, i));

  497. 

  498. 	/* Set Node address */

  499. 	for (i = 0; i < 6; i++)

  500. 		nic->node_addr[i] = db->srom[20 + i];

  501. 

  502. 	/* Print out some hardware info */

  503. 	printf("%s: %! at ioaddr %hX\n", dev->name, nic->node_addr, BASE);

  504. 

  505. 	/* Set the card as PCI Bus Master */

  506. 	adjust_pci_device(pci);

  507. 

  508. 	dmfe_reset(nic);

  509. 

  510. 	nic->irqno  = 0;

  511. 	nic->ioaddr = pci->ioaddr;

  512. 

  513. 	/* point to NIC specific routines */

  514. 	nic->nic_op	= &dmfe_operations;

  515. 

  516. 	return 1;

  517. }

  518. 

  519. /*

  520.  *	Initialize transmit/Receive descriptor

  521.  *	Using Chain structure, and allocate Tx/Rx buffer

  522.  */

  523. 

  524. static void dmfe_descriptor_init(struct nic *nic __unused, unsigned long ioaddr)

  525. {

  526. 	int i;

  527. 	db->cur_tx = 0;

  528. 	db->cur_rx = 0;

  529. 

  530. 	/* tx descriptor start pointer */

  531. 	outl(virt_to_le32desc(&txd[0]), ioaddr + DCR4);	/* TX DESC address */

  532. 

  533. 	/* rx descriptor start pointer */

  534. 	outl(virt_to_le32desc(&rxd[0]), ioaddr + DCR3);	/* RX DESC address */

  535. 

  536. 	/* Init Transmit chain */

  537. 	for (i = 0; i < TX_DESC_CNT; i++) {

  538. 		txd[i].tx_buf_ptr = (u32) & txb[i];

  539. 		txd[i].tdes0 = cpu_to_le32(0);

  540. 		txd[i].tdes1 = cpu_to_le32(0x81000000);	/* IC, chain */

  541. 		txd[i].tdes2 = cpu_to_le32(virt_to_bus(&txb[i]));

  542. 		txd[i].tdes3 = cpu_to_le32(virt_to_bus(&txd[i + 1]));

  543. 		txd[i].next_tx_desc = virt_to_le32desc(&txd[i + 1]);	

  544. 	}

  545. 	/* Mark the last entry as wrapping the ring */

  546. 	txd[i - 1].tdes3 = virt_to_le32desc(&txd[0]);

  547. 	txd[i - 1].next_tx_desc = (u32) & txd[0];

  548. 

  549. 	/* receive descriptor chain */

  550. 	for (i = 0; i < RX_DESC_CNT; i++) {

  551. 		rxd[i].rx_skb_ptr = (u32) & rxb[i * RX_ALLOC_SIZE];

  552. 		rxd[i].rdes0 = cpu_to_le32(0x80000000);

  553. 		rxd[i].rdes1 = cpu_to_le32(0x01000600);

  554. 		rxd[i].rdes2 =

  555. 		    cpu_to_le32(virt_to_bus(&rxb[i * RX_ALLOC_SIZE]));

  556. 		rxd[i].rdes3 = cpu_to_le32(virt_to_bus(&rxd[i + 1]));

  557. 		rxd[i].next_rx_desc = virt_to_le32desc(&rxd[i + 1]);

  558. 	}

  559. 	/* Mark the last entry as wrapping the ring */

  560. 	rxd[i - 1].rdes3 = cpu_to_le32(virt_to_bus(&rxd[0]));

  561. 	rxd[i - 1].next_rx_desc = virt_to_le32desc(&rxd[0]);

  562. 

  563. }

  564. 

  565. /*

  566.  *	Update CR6 value

  567.  *	Firstly stop DM910X , then written value and start

  568.  */

  569. 

  570. static void update_cr6(u32 cr6_data, unsigned long ioaddr)

  571. {

  572. 	u32 cr6_tmp;

  573. 

  574. 	cr6_tmp = cr6_data & ~0x2002;	/* stop Tx/Rx */

  575. 	outl(cr6_tmp, ioaddr + DCR6);

  576. 	udelay(5);

  577. 	outl(cr6_data, ioaddr + DCR6);

  578. 	udelay(5);

  579. }

  580. 

  581. 

  582. /*

  583.  *	Send a setup frame for DM9132

  584.  *	This setup frame initilize DM910X addres filter mode

  585. */

  586. 

  587. static void dm9132_id_table(struct nic *nic __unused)

  588. {

  589. #ifdef LINUX

  590. 	u16 *addrptr;

  591. 	u8 dmi_addr[8];

  592. 	unsigned long ioaddr = BASE + 0xc0;	/* ID Table */

  593. 	u32 hash_val;

  594. 	u16 i, hash_table[4];

  595. #endif

  596. 	dprintf(("dm9132_id_table\n"));

  597. 

  598. 	printf("FIXME: This function is broken.  If you have this card contact "

  599. 		"Timothy Legge at the etherboot-user list\n");

  600. 

  601. #ifdef LINUX

  602. 	//DMFE_DBUG(0, "dm9132_id_table()", 0);

  603. 

  604. 	/* Node address */

  605. 	addrptr = (u16 *) nic->node_addr;

  606. 	outw(addrptr[0], ioaddr);

  607. 	ioaddr += 4;

  608. 	outw(addrptr[1], ioaddr);

  609. 	ioaddr += 4;

  610. 	outw(addrptr[2], ioaddr);

  611. 	ioaddr += 4;

  612. 

  613. 	/* Clear Hash Table */

  614. 	for (i = 0; i < 4; i++)

  615. 		hash_table[i] = 0x0;

  616. 

  617. 	/* broadcast address */

  618. 	hash_table[3] = 0x8000;

  619. 

  620. 	/* the multicast address in Hash Table : 64 bits */

  621. 	for (mcptr = mc_list, i = 0; i < mc_cnt; i++, mcptr = mcptr->next) {

  622. 		hash_val = cal_CRC((char *) mcptr->dmi_addr, 6, 0) & 0x3f;

  623. 		hash_table[hash_val / 16] |= (u16) 1 << (hash_val % 16);

  624. 	}

  625. 

  626. 	/* Write the hash table to MAC MD table */

  627. 	for (i = 0; i < 4; i++, ioaddr += 4)

  628. 		outw(hash_table[i], ioaddr);

  629. #endif

  630. }

  631. 

  632. 

  633. /*

  634.  *	Send a setup frame for DM9102/DM9102A

  635.  *	This setup frame initilize DM910X addres filter mode

  636.  */

  637. 

  638. static void send_filter_frame(struct nic *nic)

  639. {

  640. 

  641. 	u8 *ptxb;

  642. 	int i;

  643. 

  644. 	dprintf(("send_filter_frame\n"));

  645. 	/* point to the current txb incase multiple tx_rings are used */

  646. 	ptxb = &txb[db->cur_tx];

  647. 

  648. 	/* construct perfect filter frame with mac address as first match

  649. 	   and broadcast address for all others */

  650. 	for (i = 0; i < 192; i++)

  651. 		ptxb[i] = 0xFF;

  652. 	ptxb[0] = nic->node_addr[0];

  653. 	ptxb[1] = nic->node_addr[1];

  654. 	ptxb[4] = nic->node_addr[2];

  655. 	ptxb[5] = nic->node_addr[3];

  656. 	ptxb[8] = nic->node_addr[4];

  657. 	ptxb[9] = nic->node_addr[5];

  658. 

  659. 	/* prepare the setup frame */

  660. 	txd[db->cur_tx].tdes1 = cpu_to_le32(0x890000c0);

  661. 	txd[db->cur_tx].tdes0 = cpu_to_le32(0x80000000);

  662. 	update_cr6(db->cr6_data | 0x2000, BASE);

  663. 	outl(0x1, BASE + DCR1);	/* Issue Tx polling */

  664. 	update_cr6(db->cr6_data, BASE);

  665. 	db->cur_tx++;

  666. }

  667. 

  668. /*

  669.  *	Read one word data from the serial ROM

  670.  */

  671. 

  672. static u16 read_srom_word(long ioaddr, int offset)

  673. {

  674. 	int i;

  675. 	u16 srom_data = 0;

  676. 	long cr9_ioaddr = ioaddr + DCR9;

  677. 

  678. 	outl(CR9_SROM_READ, cr9_ioaddr);

  679. 	outl(CR9_SROM_READ | CR9_SRCS, cr9_ioaddr);

  680. 

  681. 	/* Send the Read Command 110b */

  682. 	SROM_CLK_WRITE(SROM_DATA_1, cr9_ioaddr);

  683. 	SROM_CLK_WRITE(SROM_DATA_1, cr9_ioaddr);

  684. 	SROM_CLK_WRITE(SROM_DATA_0, cr9_ioaddr);

  685. 

  686. 	/* Send the offset */

  687. 	for (i = 5; i >= 0; i--) {

  688. 		srom_data =

  689. 		    (offset & (1 << i)) ? SROM_DATA_1 : SROM_DATA_0;

  690. 		SROM_CLK_WRITE(srom_data, cr9_ioaddr);

  691. 	}

  692. 

  693. 	outl(CR9_SROM_READ | CR9_SRCS, cr9_ioaddr);

  694. 

  695. 	for (i = 16; i > 0; i--) {

  696. 		outl(CR9_SROM_READ | CR9_SRCS | CR9_SRCLK, cr9_ioaddr);

  697. 		udelay(5);

  698. 		srom_data =

  699. 		    (srom_data << 1) | ((inl(cr9_ioaddr) & CR9_CRDOUT) ? 1

  700. 					: 0);

  701. 		outl(CR9_SROM_READ | CR9_SRCS, cr9_ioaddr);

  702. 		udelay(5);

  703. 	}

  704. 

  705. 	outl(CR9_SROM_READ, cr9_ioaddr);

  706. 	return srom_data;

  707. }

  708. 

  709. 

  710. /*

  711.  *	Auto sense the media mode

  712.  */

  713. 

  714. #if 0 /* not used */

  715. static u8 dmfe_sense_speed(struct nic *nic __unused)

  716. {

  717. 	u8 ErrFlag = 0;

  718. 	u16 phy_mode;

  719. 

  720. 	/* CR6 bit18=0, select 10/100M */

  721. 	update_cr6((db->cr6_data & ~0x40000), BASE);

  722. 

  723. 	phy_mode = phy_read(BASE, db->phy_addr, 1, db->chip_id);

  724. 	phy_mode = phy_read(BASE, db->phy_addr, 1, db->chip_id);

  725. 

  726. 	if ((phy_mode & 0x24) == 0x24) {

  727. 		if (db->chip_id == PCI_DM9132_ID)	/* DM9132 */

  728. 			phy_mode =

  729. 			    phy_read(BASE, db->phy_addr, 7,

  730. 				     db->chip_id) & 0xf000;

  731. 		else		/* DM9102/DM9102A */

  732. 			phy_mode =

  733. 			    phy_read(BASE, db->phy_addr, 17,

  734. 				     db->chip_id) & 0xf000;

  735. 		/* printk(DRV_NAME ": Phy_mode %x ",phy_mode); */

  736. 		switch (phy_mode) {

  737. 		case 0x1000:

  738. 			db->op_mode = DMFE_10MHF;

  739. 			break;

  740. 		case 0x2000:

  741. 			db->op_mode = DMFE_10MFD;

  742. 			break;

  743. 		case 0x4000:

  744. 			db->op_mode = DMFE_100MHF;

  745. 			break;

  746. 		case 0x8000:

  747. 			db->op_mode = DMFE_100MFD;

  748. 			break;

  749. 		default:

  750. 			db->op_mode = DMFE_10MHF;

  751. 			ErrFlag = 1;

  752. 			break;

  753. 		}

  754. 	} else {

  755. 		db->op_mode = DMFE_10MHF;

  756. 		//DMFE_DBUG(0, "Link Failed :", phy_mode);

  757. 		ErrFlag = 1;

  758. 	}

  759. 

  760. 	return ErrFlag;

  761. }

  762. #endif

  763. 

  764. /*

  765.  *	Set 10/100 phyxcer capability

  766.  *	AUTO mode : phyxcer register4 is NIC capability

  767.  *	Force mode: phyxcer register4 is the force media

  768.  */

  769. 

  770. static void dmfe_set_phyxcer(struct nic *nic __unused)

  771. {

  772. 	u16 phy_reg;

  773. 

  774. 	/* Select 10/100M phyxcer */

  775. 	db->cr6_data &= ~0x40000;

  776. 	update_cr6(db->cr6_data, BASE);

  777. 

  778. 	/* DM9009 Chip: Phyxcer reg18 bit12=0 */

  779. 	if (db->chip_id == PCI_DM9009_ID) {

  780. 		phy_reg =

  781. 		    phy_read(BASE, db->phy_addr, 18,

  782. 			     db->chip_id) & ~0x1000;

  783. 		phy_write(BASE, db->phy_addr, 18, phy_reg, db->chip_id);

  784. 	}

  785. 

  786. 	/* Phyxcer capability setting */

  787. 	phy_reg = phy_read(BASE, db->phy_addr, 4, db->chip_id) & ~0x01e0;

  788. 

  789. 	if (db->media_mode & DMFE_AUTO) {

  790. 		/* AUTO Mode */

  791. 		phy_reg |= db->PHY_reg4;

  792. 	} else {

  793. 		/* Force Mode */

  794. 		switch (db->media_mode) {

  795. 		case DMFE_10MHF:

  796. 			phy_reg |= 0x20;

  797. 			break;

  798. 		case DMFE_10MFD:

  799. 			phy_reg |= 0x40;

  800. 			break;

  801. 		case DMFE_100MHF:

  802. 			phy_reg |= 0x80;

  803. 			break;

  804. 		case DMFE_100MFD:

  805. 			phy_reg |= 0x100;

  806. 			break;

  807. 		}

  808. 		if (db->chip_id == PCI_DM9009_ID)

  809. 			phy_reg &= 0x61;

  810. 	}

  811. 

  812. 	/* Write new capability to Phyxcer Reg4 */

  813. 	if (!(phy_reg & 0x01e0)) {

  814. 		phy_reg |= db->PHY_reg4;

  815. 		db->media_mode |= DMFE_AUTO;

  816. 	}

  817. 	phy_write(BASE, db->phy_addr, 4, phy_reg, db->chip_id);

  818. 

  819. 	/* Restart Auto-Negotiation */

  820. 	if (db->chip_type && (db->chip_id == PCI_DM9102_ID))

  821. 		phy_write(BASE, db->phy_addr, 0, 0x1800, db->chip_id);

  822. 	if (!db->chip_type)

  823. 		phy_write(BASE, db->phy_addr, 0, 0x1200, db->chip_id);

  824. }

  825. 

  826. 

  827. /*

  828.  *	Process op-mode

  829.  *	AUTO mode : PHY controller in Auto-negotiation Mode

  830.  *	Force mode: PHY controller in force mode with HUB

  831.  *			N-way force capability with SWITCH

  832.  */

  833. 

  834. #if 0 /* not used */

  835. static void dmfe_process_mode(struct nic *nic __unused)

  836. {

  837. 	u16 phy_reg;

  838. 

  839. 	/* Full Duplex Mode Check */

  840. 	if (db->op_mode & 0x4)

  841. 		db->cr6_data |= CR6_FDM;	/* Set Full Duplex Bit */

  842. 	else

  843. 		db->cr6_data &= ~CR6_FDM;	/* Clear Full Duplex Bit */

  844. 

  845. 	/* Transciver Selection */

  846. 	if (db->op_mode & 0x10)	/* 1M HomePNA */

  847. 		db->cr6_data |= 0x40000;	/* External MII select */

  848. 	else

  849. 		db->cr6_data &= ~0x40000;	/* Internal 10/100 transciver */

  850. 

  851. 	update_cr6(db->cr6_data, BASE);

  852. 

  853. 	/* 10/100M phyxcer force mode need */

  854. 	if (!(db->media_mode & 0x18)) {

  855. 		/* Forece Mode */

  856. 		phy_reg = phy_read(BASE, db->phy_addr, 6, db->chip_id);

  857. 		if (!(phy_reg & 0x1)) {

  858. 			/* parter without N-Way capability */

  859. 			phy_reg = 0x0;

  860. 			switch (db->op_mode) {

  861. 			case DMFE_10MHF:

  862. 				phy_reg = 0x0;

  863. 				break;

  864. 			case DMFE_10MFD:

  865. 				phy_reg = 0x100;

  866. 				break;

  867. 			case DMFE_100MHF:

  868. 				phy_reg = 0x2000;

  869. 				break;

  870. 			case DMFE_100MFD:

  871. 				phy_reg = 0x2100;

  872. 				break;

  873. 			}

  874. 			phy_write(BASE, db->phy_addr, 0, phy_reg,

  875. 				  db->chip_id);

  876. 			if (db->chip_type

  877. 			    && (db->chip_id == PCI_DM9102_ID))

  878. 				mdelay(20);

  879. 			phy_write(BASE, db->phy_addr, 0, phy_reg,

  880. 				  db->chip_id);

  881. 		}

  882. 	}

  883. }

  884. #endif

  885. 

  886. /*

  887.  *	Write a word to Phy register

  888.  */

  889. 

  890. static void phy_write(unsigned long iobase, u8 phy_addr, u8 offset,

  891. 		      u16 phy_data, u32 chip_id)

  892. {

  893. 	u16 i;

  894. 	unsigned long ioaddr;

  895. 

  896. 	if (chip_id == PCI_DM9132_ID) {

  897. 		ioaddr = iobase + 0x80 + offset * 4;

  898. 		outw(phy_data, ioaddr);

  899. 	} else {

  900. 		/* DM9102/DM9102A Chip */

  901. 		ioaddr = iobase + DCR9;

  902. 

  903. 		/* Send 33 synchronization clock to Phy controller */

  904. 		for (i = 0; i < 35; i++)

  905. 			phy_write_1bit(ioaddr, PHY_DATA_1);

  906. 

  907. 		/* Send start command(01) to Phy */

  908. 		phy_write_1bit(ioaddr, PHY_DATA_0);

  909. 		phy_write_1bit(ioaddr, PHY_DATA_1);

  910. 

  911. 		/* Send write command(01) to Phy */

  912. 		phy_write_1bit(ioaddr, PHY_DATA_0);

  913. 		phy_write_1bit(ioaddr, PHY_DATA_1);

  914. 

  915. 		/* Send Phy addres */

  916. 		for (i = 0x10; i > 0; i = i >> 1)

  917. 			phy_write_1bit(ioaddr,

  918. 				       phy_addr & i ? PHY_DATA_1 :

  919. 				       PHY_DATA_0);

  920. 

  921. 		/* Send register addres */

  922. 		for (i = 0x10; i > 0; i = i >> 1)

  923. 			phy_write_1bit(ioaddr,

  924. 				       offset & i ? PHY_DATA_1 :

  925. 				       PHY_DATA_0);

  926. 

  927. 		/* written trasnition */

  928. 		phy_write_1bit(ioaddr, PHY_DATA_1);

  929. 		phy_write_1bit(ioaddr, PHY_DATA_0);

  930. 

  931. 		/* Write a word data to PHY controller */

  932. 		for (i = 0x8000; i > 0; i >>= 1)

  933. 			phy_write_1bit(ioaddr,

  934. 				       phy_data & i ? PHY_DATA_1 :

  935. 				       PHY_DATA_0);

  936. 	}

  937. }

  938. 

  939. 

  940. /*

  941.  *	Read a word data from phy register

  942.  */

  943. 

  944. static u16 phy_read(unsigned long iobase, u8 phy_addr, u8 offset,

  945. 		    u32 chip_id)

  946. {

  947. 	int i;

  948. 	u16 phy_data;

  949. 	unsigned long ioaddr;

  950. 

  951. 	if (chip_id == PCI_DM9132_ID) {

  952. 		/* DM9132 Chip */

  953. 		ioaddr = iobase + 0x80 + offset * 4;

  954. 		phy_data = inw(ioaddr);

  955. 	} else {

  956. 		/* DM9102/DM9102A Chip */

  957. 		ioaddr = iobase + DCR9;

  958. 

  959. 		/* Send 33 synchronization clock to Phy controller */

  960. 		for (i = 0; i < 35; i++)

  961. 			phy_write_1bit(ioaddr, PHY_DATA_1);

  962. 

  963. 		/* Send start command(01) to Phy */

  964. 		phy_write_1bit(ioaddr, PHY_DATA_0);

  965. 		phy_write_1bit(ioaddr, PHY_DATA_1);

  966. 

  967. 		/* Send read command(10) to Phy */

  968. 		phy_write_1bit(ioaddr, PHY_DATA_1);

  969. 		phy_write_1bit(ioaddr, PHY_DATA_0);

  970. 

  971. 		/* Send Phy addres */

  972. 		for (i = 0x10; i > 0; i = i >> 1)

  973. 			phy_write_1bit(ioaddr,

  974. 				       phy_addr & i ? PHY_DATA_1 :

  975. 				       PHY_DATA_0);

  976. 

  977. 		/* Send register addres */

  978. 		for (i = 0x10; i > 0; i = i >> 1)

  979. 			phy_write_1bit(ioaddr,

  980. 				       offset & i ? PHY_DATA_1 :

  981. 				       PHY_DATA_0);

  982. 

  983. 		/* Skip transition state */

  984. 		phy_read_1bit(ioaddr);

  985. 

  986. 		/* read 16bit data */

  987. 		for (phy_data = 0, i = 0; i < 16; i++) {

  988. 			phy_data <<= 1;

  989. 			phy_data |= phy_read_1bit(ioaddr);

  990. 		}

  991. 	}

  992. 

  993. 	return phy_data;

  994. }

  995. 

  996. 

  997. /*

  998.  *	Write one bit data to Phy Controller

  999.  */

  1000. 

  1001. static void phy_write_1bit(unsigned long ioaddr, u32 phy_data)

  1002. {

  1003. 	outl(phy_data, ioaddr);	/* MII Clock Low */

  1004. 	udelay(1);

  1005. 	outl(phy_data | MDCLKH, ioaddr);	/* MII Clock High */

  1006. 	udelay(1);

  1007. 	outl(phy_data, ioaddr);	/* MII Clock Low */

  1008. 	udelay(1);

  1009. }

  1010. 

  1011. 

  1012. /*

  1013.  *	Read one bit phy data from PHY controller

  1014.  */

  1015. 

  1016. static u16 phy_read_1bit(unsigned long ioaddr)

  1017. {

  1018. 	u16 phy_data;

  1019. 

  1020. 	outl(0x50000, ioaddr);

  1021. 	udelay(1);

  1022. 	phy_data = (inl(ioaddr) >> 19) & 0x1;

  1023. 	outl(0x40000, ioaddr);

  1024. 	udelay(1);

  1025. 

  1026. 	return phy_data;

  1027. }

  1028. 

  1029. 

  1030. /*

  1031.  *	Parser SROM and media mode

  1032.  */

  1033. 

  1034. static void dmfe_parse_srom(struct nic *nic)

  1035. {

  1036. 	char *srom = db->srom;

  1037. 	int dmfe_mode, tmp_reg;

  1038. 

  1039. 	/* Init CR15 */

  1040. 	db->cr15_data = CR15_DEFAULT;

  1041. 

  1042. 	/* Check SROM Version */

  1043. 	if (((int) srom[18] & 0xff) == SROM_V41_CODE) {

  1044. 		/* SROM V4.01 */

  1045. 		/* Get NIC support media mode */

  1046. 		db->NIC_capability = *(u16 *) (srom + 34);

  1047. 		db->PHY_reg4 = 0;

  1048. 		for (tmp_reg = 1; tmp_reg < 0x10; tmp_reg <<= 1) {

  1049. 			switch (db->NIC_capability & tmp_reg) {

  1050. 			case 0x1:

  1051. 				db->PHY_reg4 |= 0x0020;

  1052. 				break;

  1053. 			case 0x2:

  1054. 				db->PHY_reg4 |= 0x0040;

  1055. 				break;

  1056. 			case 0x4:

  1057. 				db->PHY_reg4 |= 0x0080;

  1058. 				break;

  1059. 			case 0x8:

  1060. 				db->PHY_reg4 |= 0x0100;

  1061. 				break;

  1062. 			}

  1063. 		}

  1064. 

  1065. 		/* Media Mode Force or not check */

  1066. 		dmfe_mode = *((int *) srom + 34) & *((int *) srom + 36);

  1067. 		switch (dmfe_mode) {

  1068. 		case 0x4:

  1069. 			dmfe_media_mode = DMFE_100MHF;

  1070. 			break;	/* 100MHF */

  1071. 		case 0x2:

  1072. 			dmfe_media_mode = DMFE_10MFD;

  1073. 			break;	/* 10MFD */

  1074. 		case 0x8:

  1075. 			dmfe_media_mode = DMFE_100MFD;

  1076. 			break;	/* 100MFD */

  1077. 		case 0x100:

  1078. 		case 0x200:

  1079. 			dmfe_media_mode = DMFE_1M_HPNA;

  1080. 			break;	/* HomePNA */

  1081. 		}

  1082. 

  1083. 		/* Special Function setting */

  1084. 		/* VLAN function */

  1085. 		if ((SF_mode & 0x1) || (srom[43] & 0x80))

  1086. 			db->cr15_data |= 0x40;

  1087. 

  1088. 		/* Flow Control */

  1089. 		if ((SF_mode & 0x2) || (srom[40] & 0x1))

  1090. 			db->cr15_data |= 0x400;

  1091. 

  1092. 		/* TX pause packet */

  1093. 		if ((SF_mode & 0x4) || (srom[40] & 0xe))

  1094. 			db->cr15_data |= 0x9800;

  1095. 	}

  1096. 

  1097. 	/* Parse HPNA parameter */

  1098. 	db->HPNA_command = 1;

  1099. 

  1100. 	/* Accept remote command or not */

  1101. 	if (HPNA_rx_cmd == 0)

  1102. 		db->HPNA_command |= 0x8000;

  1103. 

  1104. 	/* Issue remote command & operation mode */

  1105. 	if (HPNA_tx_cmd == 1)

  1106. 		switch (HPNA_mode) {	/* Issue Remote Command */

  1107. 		case 0:

  1108. 			db->HPNA_command |= 0x0904;

  1109. 			break;

  1110. 		case 1:

  1111. 			db->HPNA_command |= 0x0a00;

  1112. 			break;

  1113. 		case 2:

  1114. 			db->HPNA_command |= 0x0506;

  1115. 			break;

  1116. 		case 3:

  1117. 			db->HPNA_command |= 0x0602;

  1118. 			break;

  1119. 	} else

  1120. 		switch (HPNA_mode) {	/* Don't Issue */

  1121. 		case 0:

  1122. 			db->HPNA_command |= 0x0004;

  1123. 			break;

  1124. 		case 1:

  1125. 			db->HPNA_command |= 0x0000;

  1126. 			break;

  1127. 		case 2:

  1128. 			db->HPNA_command |= 0x0006;

  1129. 			break;

  1130. 		case 3:

  1131. 			db->HPNA_command |= 0x0002;

  1132. 			break;

  1133. 		}

  1134. 

  1135. 	/* Check DM9801 or DM9802 present or not */

  1136. 	db->HPNA_present = 0;

  1137. 	update_cr6(db->cr6_data | 0x40000, BASE);

  1138. 	tmp_reg = phy_read(BASE, db->phy_addr, 3, db->chip_id);

  1139. 	if ((tmp_reg & 0xfff0) == 0xb900) {

  1140. 		/* DM9801 or DM9802 present */

  1141. 		db->HPNA_timer = 8;

  1142. 		if (phy_read(BASE, db->phy_addr, 31, db->chip_id) ==

  1143. 		    0x4404) {

  1144. 			/* DM9801 HomeRun */

  1145. 			db->HPNA_present = 1;

  1146. 			dmfe_program_DM9801(nic, tmp_reg);

  1147. 		} else {

  1148. 			/* DM9802 LongRun */

  1149. 			db->HPNA_present = 2;

  1150. 			dmfe_program_DM9802(nic);

  1151. 		}

  1152. 	}

  1153. 

  1154. }

  1155. 

  1156. /*

  1157.  *	Init HomeRun DM9801

  1158.  */

  1159. 

  1160. static void dmfe_program_DM9801(struct nic *nic __unused, int HPNA_rev)

  1161. {

  1162. 	u32 reg17, reg25;

  1163. 

  1164. 	if (!HPNA_NoiseFloor)

  1165. 		HPNA_NoiseFloor = DM9801_NOISE_FLOOR;

  1166. 	switch (HPNA_rev) {

  1167. 	case 0xb900:		/* DM9801 E3 */

  1168. 		db->HPNA_command |= 0x1000;

  1169. 		reg25 = phy_read(BASE, db->phy_addr, 24, db->chip_id);

  1170. 		reg25 = ((reg25 + HPNA_NoiseFloor) & 0xff) | 0xf000;

  1171. 		reg17 = phy_read(BASE, db->phy_addr, 17, db->chip_id);

  1172. 		break;

  1173. 	case 0xb901:		/* DM9801 E4 */

  1174. 		reg25 = phy_read(BASE, db->phy_addr, 25, db->chip_id);

  1175. 		reg25 = (reg25 & 0xff00) + HPNA_NoiseFloor;

  1176. 		reg17 = phy_read(BASE, db->phy_addr, 17, db->chip_id);

  1177. 		reg17 = (reg17 & 0xfff0) + HPNA_NoiseFloor + 3;

  1178. 		break;

  1179. 	case 0xb902:		/* DM9801 E5 */

  1180. 	case 0xb903:		/* DM9801 E6 */

  1181. 	default:

  1182. 		db->HPNA_command |= 0x1000;

  1183. 		reg25 = phy_read(BASE, db->phy_addr, 25, db->chip_id);

  1184. 		reg25 = (reg25 & 0xff00) + HPNA_NoiseFloor - 5;

  1185. 		reg17 = phy_read(BASE, db->phy_addr, 17, db->chip_id);

  1186. 		reg17 = (reg17 & 0xfff0) + HPNA_NoiseFloor;

  1187. 		break;

  1188. 	}

  1189. 	phy_write(BASE, db->phy_addr, 16, db->HPNA_command, db->chip_id);

  1190. 	phy_write(BASE, db->phy_addr, 17, reg17, db->chip_id);

  1191. 	phy_write(BASE, db->phy_addr, 25, reg25, db->chip_id);

  1192. }

  1193. 

  1194. 

  1195. /*

  1196.  *	Init HomeRun DM9802

  1197.  */

  1198. 

  1199. static void dmfe_program_DM9802(struct nic *nic __unused)

  1200. {

  1201. 	u32 phy_reg;

  1202. 

  1203. 	if (!HPNA_NoiseFloor)

  1204. 		HPNA_NoiseFloor = DM9802_NOISE_FLOOR;

  1205. 	phy_write(BASE, db->phy_addr, 16, db->HPNA_command, db->chip_id);

  1206. 	phy_reg = phy_read(BASE, db->phy_addr, 25, db->chip_id);

  1207. 	phy_reg = (phy_reg & 0xff00) + HPNA_NoiseFloor;

  1208. 	phy_write(BASE, db->phy_addr, 25, phy_reg, db->chip_id);

  1209. }

  1210. 

  1211. static struct nic_operations dmfe_operations = {

  1212. 	.connect	= dummy_connect,

  1213. 	.poll		= dmfe_poll,

  1214. 	.transmit	= dmfe_transmit,

  1215. 	.irq		= dmfe_irq,

  1216. 	.disable	= dmfe_disable,

  1217. };

  1218. 

  1219. static struct pci_id dmfe_nics[] = {

  1220. 	PCI_ROM(0x1282, 0x9100, "dmfe9100", "Davicom 9100"),

  1221. 	PCI_ROM(0x1282, 0x9102, "dmfe9102", "Davicom 9102"),

  1222. 	PCI_ROM(0x1282, 0x9009, "dmfe9009", "Davicom 9009"),

  1223. 	PCI_ROM(0x1282, 0x9132, "dmfe9132", "Davicom 9132"),	/* Needs probably some fixing */

  1224. };

  1225. 

  1226. static struct pci_driver dmfe_driver =

  1227. 	PCI_DRIVER ( "DMFE/PCI", dmfe_nics, PCI_NO_CLASS );

  1228. 

  1229. BOOT_DRIVER ( "DMFE/PCI", find_pci_boot_device, dmfe_driver, dmfe_probe );