drivers/mtd/chips/amd_flash.c at v2.6.16 · tjh.dev/kernel

tjh.dev / kernel
Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel os linux
kernel / drivers / mtd / chips / amd_flash.c
at v2.6.16 1403 lines 34 kB view raw
   1/*
   2 * MTD map driver for AMD compatible flash chips (non-CFI)
   3 *
   4 * Author: Jonas Holmberg <jonas.holmberg@axis.com>
   5 *
   6 * $Id: amd_flash.c,v 1.28 2005/11/07 11:14:22 gleixner Exp $
   7 *
   8 * Copyright (c) 2001 Axis Communications AB
   9 *
  10 * This file is under GPL.
  11 *
  12 */
  13
  14#include <linux/module.h>
  15#include <linux/types.h>
  16#include <linux/kernel.h>
  17#include <linux/sched.h>
  18#include <linux/errno.h>
  19#include <linux/slab.h>
  20#include <linux/delay.h>
  21#include <linux/interrupt.h>
  22#include <linux/init.h>
  23#include <linux/mtd/map.h>
  24#include <linux/mtd/mtd.h>
  25#include <linux/mtd/flashchip.h>
  26
  27/* There's no limit. It exists only to avoid realloc. */
  28#define MAX_AMD_CHIPS 8
  29
  30#define DEVICE_TYPE_X8	(8 / 8)
  31#define DEVICE_TYPE_X16	(16 / 8)
  32#define DEVICE_TYPE_X32	(32 / 8)
  33
  34/* Addresses */
  35#define ADDR_MANUFACTURER		0x0000
  36#define ADDR_DEVICE_ID			0x0001
  37#define ADDR_SECTOR_LOCK		0x0002
  38#define ADDR_HANDSHAKE			0x0003
  39#define ADDR_UNLOCK_1			0x0555
  40#define ADDR_UNLOCK_2			0x02AA
  41
  42/* Commands */
  43#define CMD_UNLOCK_DATA_1		0x00AA
  44#define CMD_UNLOCK_DATA_2		0x0055
  45#define CMD_MANUFACTURER_UNLOCK_DATA	0x0090
  46#define CMD_UNLOCK_BYPASS_MODE		0x0020
  47#define CMD_PROGRAM_UNLOCK_DATA		0x00A0
  48#define CMD_RESET_DATA			0x00F0
  49#define CMD_SECTOR_ERASE_UNLOCK_DATA	0x0080
  50#define CMD_SECTOR_ERASE_UNLOCK_DATA_2	0x0030
  51
  52#define CMD_UNLOCK_SECTOR		0x0060
  53
  54/* Manufacturers */
  55#define MANUFACTURER_AMD	0x0001
  56#define MANUFACTURER_ATMEL	0x001F
  57#define MANUFACTURER_FUJITSU	0x0004
  58#define MANUFACTURER_ST		0x0020
  59#define MANUFACTURER_SST	0x00BF
  60#define MANUFACTURER_TOSHIBA	0x0098
  61
  62/* AMD */
  63#define AM29F800BB	0x2258
  64#define AM29F800BT	0x22D6
  65#define AM29LV800BB	0x225B
  66#define AM29LV800BT	0x22DA
  67#define AM29LV160DT	0x22C4
  68#define AM29LV160DB	0x2249
  69#define AM29BDS323D     0x22D1
  70
  71/* Atmel */
  72#define AT49xV16x	0x00C0
  73#define AT49xV16xT	0x00C2
  74
  75/* Fujitsu */
  76#define MBM29LV160TE	0x22C4
  77#define MBM29LV160BE	0x2249
  78#define MBM29LV800BB	0x225B
  79
  80/* ST - www.st.com */
  81#define M29W800T	0x00D7
  82#define M29W160DT	0x22C4
  83#define M29W160DB	0x2249
  84
  85/* SST */
  86#define SST39LF800	0x2781
  87#define SST39LF160	0x2782
  88
  89/* Toshiba */
  90#define TC58FVT160	0x00C2
  91#define TC58FVB160	0x0043
  92
  93#define D6_MASK	0x40
  94
  95struct amd_flash_private {
  96	int device_type;
  97	int interleave;
  98	int numchips;
  99	unsigned long chipshift;
 100//	const char *im_name;
 101	struct flchip chips[0];
 102};
 103
 104struct amd_flash_info {
 105	const __u16 mfr_id;
 106	const __u16 dev_id;
 107	const char *name;
 108	const u_long size;
 109	const int numeraseregions;
 110	const struct mtd_erase_region_info regions[4];
 111};
 112
 113
 114
 115static int amd_flash_read(struct mtd_info *, loff_t, size_t, size_t *,
 116			  u_char *);
 117static int amd_flash_write(struct mtd_info *, loff_t, size_t, size_t *,
 118			   const u_char *);
 119static int amd_flash_erase(struct mtd_info *, struct erase_info *);
 120static void amd_flash_sync(struct mtd_info *);
 121static int amd_flash_suspend(struct mtd_info *);
 122static void amd_flash_resume(struct mtd_info *);
 123static void amd_flash_destroy(struct mtd_info *);
 124static struct mtd_info *amd_flash_probe(struct map_info *map);
 125
 126
 127static struct mtd_chip_driver amd_flash_chipdrv = {
 128	.probe = amd_flash_probe,
 129	.destroy = amd_flash_destroy,
 130	.name = "amd_flash",
 131	.module = THIS_MODULE
 132};
 133
 134
 135
 136static const char im_name[] = "amd_flash";
 137
 138
 139
 140static inline __u32 wide_read(struct map_info *map, __u32 addr)
 141{
 142	if (map->buswidth == 1) {
 143		return map_read8(map, addr);
 144	} else if (map->buswidth == 2) {
 145		return map_read16(map, addr);
 146	} else if (map->buswidth == 4) {
 147		return map_read32(map, addr);
 148        }
 149
 150	return 0;
 151}
 152
 153static inline void wide_write(struct map_info *map, __u32 val, __u32 addr)
 154{
 155	if (map->buswidth == 1) {
 156		map_write8(map, val, addr);
 157	} else if (map->buswidth == 2) {
 158		map_write16(map, val, addr);
 159	} else if (map->buswidth == 4) {
 160		map_write32(map, val, addr);
 161	}
 162}
 163
 164static inline __u32 make_cmd(struct map_info *map, __u32 cmd)
 165{
 166	const struct amd_flash_private *private = map->fldrv_priv;
 167	if ((private->interleave == 2) &&
 168	    (private->device_type == DEVICE_TYPE_X16)) {
 169		cmd |= (cmd << 16);
 170	}
 171
 172	return cmd;
 173}
 174
 175static inline void send_unlock(struct map_info *map, unsigned long base)
 176{
 177	wide_write(map, (CMD_UNLOCK_DATA_1 << 16) | CMD_UNLOCK_DATA_1,
 178		   base + (map->buswidth * ADDR_UNLOCK_1));
 179	wide_write(map, (CMD_UNLOCK_DATA_2 << 16) | CMD_UNLOCK_DATA_2,
 180		   base + (map->buswidth * ADDR_UNLOCK_2));
 181}
 182
 183static inline void send_cmd(struct map_info *map, unsigned long base, __u32 cmd)
 184{
 185	send_unlock(map, base);
 186	wide_write(map, make_cmd(map, cmd),
 187		   base + (map->buswidth * ADDR_UNLOCK_1));
 188}
 189
 190static inline void send_cmd_to_addr(struct map_info *map, unsigned long base,
 191				    __u32 cmd, unsigned long addr)
 192{
 193	send_unlock(map, base);
 194	wide_write(map, make_cmd(map, cmd), addr);
 195}
 196
 197static inline int flash_is_busy(struct map_info *map, unsigned long addr,
 198				int interleave)
 199{
 200
 201	if ((interleave == 2) && (map->buswidth == 4)) {
 202		__u32 read1, read2;
 203
 204		read1 = wide_read(map, addr);
 205		read2 = wide_read(map, addr);
 206
 207		return (((read1 >> 16) & D6_MASK) !=
 208			((read2 >> 16) & D6_MASK)) ||
 209		       (((read1 & 0xffff) & D6_MASK) !=
 210			((read2 & 0xffff) & D6_MASK));
 211	}
 212
 213	return ((wide_read(map, addr) & D6_MASK) !=
 214		(wide_read(map, addr) & D6_MASK));
 215}
 216
 217static inline void unlock_sector(struct map_info *map, unsigned long sect_addr,
 218				 int unlock)
 219{
 220	/* Sector lock address. A6 = 1 for unlock, A6 = 0 for lock */
 221	int SLA = unlock ?
 222		(sect_addr |  (0x40 * map->buswidth)) :
 223		(sect_addr & ~(0x40 * map->buswidth)) ;
 224
 225	__u32 cmd = make_cmd(map, CMD_UNLOCK_SECTOR);
 226
 227	wide_write(map, make_cmd(map, CMD_RESET_DATA), 0);
 228	wide_write(map, cmd, SLA); /* 1st cycle: write cmd to any address */
 229	wide_write(map, cmd, SLA); /* 2nd cycle: write cmd to any address */
 230	wide_write(map, cmd, SLA); /* 3rd cycle: write cmd to SLA */
 231}
 232
 233static inline int is_sector_locked(struct map_info *map,
 234				   unsigned long sect_addr)
 235{
 236	int status;
 237
 238	wide_write(map, CMD_RESET_DATA, 0);
 239	send_cmd(map, sect_addr, CMD_MANUFACTURER_UNLOCK_DATA);
 240
 241	/* status is 0x0000 for unlocked and 0x0001 for locked */
 242	status = wide_read(map, sect_addr + (map->buswidth * ADDR_SECTOR_LOCK));
 243	wide_write(map, CMD_RESET_DATA, 0);
 244	return status;
 245}
 246
 247static int amd_flash_do_unlock(struct mtd_info *mtd, loff_t ofs, size_t len,
 248			       int is_unlock)
 249{
 250	struct map_info *map;
 251	struct mtd_erase_region_info *merip;
 252	int eraseoffset, erasesize, eraseblocks;
 253	int i;
 254	int retval = 0;
 255	int lock_status;
 256
 257	map = mtd->priv;
 258
 259	/* Pass the whole chip through sector by sector and check for each
 260	   sector if the sector and the given interval overlap */
 261	for(i = 0; i < mtd->numeraseregions; i++) {
 262		merip = &mtd->eraseregions[i];
 263
 264		eraseoffset = merip->offset;
 265		erasesize = merip->erasesize;
 266		eraseblocks = merip->numblocks;
 267
 268		if (ofs > eraseoffset + erasesize)
 269			continue;
 270
 271		while (eraseblocks > 0) {
 272			if (ofs < eraseoffset + erasesize && ofs + len > eraseoffset) {
 273				unlock_sector(map, eraseoffset, is_unlock);
 274
 275				lock_status = is_sector_locked(map, eraseoffset);
 276
 277				if (is_unlock && lock_status) {
 278					printk("Cannot unlock sector at address %x length %xx\n",
 279					       eraseoffset, merip->erasesize);
 280					retval = -1;
 281				} else if (!is_unlock && !lock_status) {
 282					printk("Cannot lock sector at address %x length %x\n",
 283					       eraseoffset, merip->erasesize);
 284					retval = -1;
 285				}
 286			}
 287			eraseoffset += erasesize;
 288			eraseblocks --;
 289		}
 290	}
 291	return retval;
 292}
 293
 294static int amd_flash_unlock(struct mtd_info *mtd, loff_t ofs, size_t len)
 295{
 296	return amd_flash_do_unlock(mtd, ofs, len, 1);
 297}
 298
 299static int amd_flash_lock(struct mtd_info *mtd, loff_t ofs, size_t len)
 300{
 301	return amd_flash_do_unlock(mtd, ofs, len, 0);
 302}
 303
 304
 305/*
 306 * Reads JEDEC manufacturer ID and device ID and returns the index of the first
 307 * matching table entry (-1 if not found or alias for already found chip).
 308 */
 309static int probe_new_chip(struct mtd_info *mtd, __u32 base,
 310			  struct flchip *chips,
 311			  struct amd_flash_private *private,
 312			  const struct amd_flash_info *table, int table_size)
 313{
 314	__u32 mfr_id;
 315	__u32 dev_id;
 316	struct map_info *map = mtd->priv;
 317	struct amd_flash_private temp;
 318	int i;
 319
 320	temp.device_type = DEVICE_TYPE_X16;	// Assume X16 (FIXME)
 321	temp.interleave = 2;
 322	map->fldrv_priv = &temp;
 323
 324	/* Enter autoselect mode. */
 325	send_cmd(map, base, CMD_RESET_DATA);
 326	send_cmd(map, base, CMD_MANUFACTURER_UNLOCK_DATA);
 327
 328	mfr_id = wide_read(map, base + (map->buswidth * ADDR_MANUFACTURER));
 329	dev_id = wide_read(map, base + (map->buswidth * ADDR_DEVICE_ID));
 330
 331	if ((map->buswidth == 4) && ((mfr_id >> 16) == (mfr_id & 0xffff)) &&
 332	    ((dev_id >> 16) == (dev_id & 0xffff))) {
 333		mfr_id &= 0xffff;
 334		dev_id &= 0xffff;
 335	} else {
 336		temp.interleave = 1;
 337	}
 338
 339	for (i = 0; i < table_size; i++) {
 340		if ((mfr_id == table[i].mfr_id) &&
 341		    (dev_id == table[i].dev_id)) {
 342			if (chips) {
 343				int j;
 344
 345				/* Is this an alias for an already found chip?
 346				 * In that case that chip should be in
 347				 * autoselect mode now.
 348				 */
 349				for (j = 0; j < private->numchips; j++) {
 350					__u32 mfr_id_other;
 351					__u32 dev_id_other;
 352
 353					mfr_id_other =
 354						wide_read(map, chips[j].start +
 355							       (map->buswidth *
 356								ADDR_MANUFACTURER
 357							       ));
 358					dev_id_other =
 359						wide_read(map, chips[j].start +
 360					    		       (map->buswidth *
 361							        ADDR_DEVICE_ID));
 362					if (temp.interleave == 2) {
 363						mfr_id_other &= 0xffff;
 364						dev_id_other &= 0xffff;
 365					}
 366					if ((mfr_id_other == mfr_id) &&
 367					    (dev_id_other == dev_id)) {
 368
 369						/* Exit autoselect mode. */
 370						send_cmd(map, base,
 371							 CMD_RESET_DATA);
 372
 373						return -1;
 374					}
 375				}
 376
 377				if (private->numchips == MAX_AMD_CHIPS) {
 378					printk(KERN_WARNING
 379					       "%s: Too many flash chips "
 380					       "detected. Increase "
 381					       "MAX_AMD_CHIPS from %d.\n",
 382					       map->name, MAX_AMD_CHIPS);
 383
 384					return -1;
 385				}
 386
 387				chips[private->numchips].start = base;
 388				chips[private->numchips].state = FL_READY;
 389				chips[private->numchips].mutex =
 390					&chips[private->numchips]._spinlock;
 391				private->numchips++;
 392			}
 393
 394			printk("%s: Found %d x %ldMiB %s at 0x%x\n", map->name,
 395			       temp.interleave, (table[i].size)/(1024*1024),
 396			       table[i].name, base);
 397
 398			mtd->size += table[i].size * temp.interleave;
 399			mtd->numeraseregions += table[i].numeraseregions;
 400
 401			break;
 402		}
 403	}
 404
 405	/* Exit autoselect mode. */
 406	send_cmd(map, base, CMD_RESET_DATA);
 407
 408	if (i == table_size) {
 409		printk(KERN_DEBUG "%s: unknown flash device at 0x%x, "
 410		       "mfr id 0x%x, dev id 0x%x\n", map->name,
 411		       base, mfr_id, dev_id);
 412		map->fldrv_priv = NULL;
 413
 414		return -1;
 415	}
 416
 417	private->device_type = temp.device_type;
 418	private->interleave = temp.interleave;
 419
 420	return i;
 421}
 422
 423
 424
 425static struct mtd_info *amd_flash_probe(struct map_info *map)
 426{
 427	static const struct amd_flash_info table[] = {
 428	{
 429		.mfr_id = MANUFACTURER_AMD,
 430		.dev_id = AM29LV160DT,
 431		.name = "AMD AM29LV160DT",
 432		.size = 0x00200000,
 433		.numeraseregions = 4,
 434		.regions = {
 435			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 31 },
 436			{ .offset = 0x1F0000, .erasesize = 0x08000, .numblocks =  1 },
 437			{ .offset = 0x1F8000, .erasesize = 0x02000, .numblocks =  2 },
 438			{ .offset = 0x1FC000, .erasesize = 0x04000, .numblocks =  1 }
 439		}
 440	}, {
 441		.mfr_id = MANUFACTURER_AMD,
 442		.dev_id = AM29LV160DB,
 443		.name = "AMD AM29LV160DB",
 444		.size = 0x00200000,
 445		.numeraseregions = 4,
 446		.regions = {
 447			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 448			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 449			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 450			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 31 }
 451		}
 452	}, {
 453		.mfr_id = MANUFACTURER_TOSHIBA,
 454		.dev_id = TC58FVT160,
 455		.name = "Toshiba TC58FVT160",
 456		.size = 0x00200000,
 457		.numeraseregions = 4,
 458		.regions = {
 459			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 31 },
 460			{ .offset = 0x1F0000, .erasesize = 0x08000, .numblocks =  1 },
 461			{ .offset = 0x1F8000, .erasesize = 0x02000, .numblocks =  2 },
 462			{ .offset = 0x1FC000, .erasesize = 0x04000, .numblocks =  1 }
 463		}
 464	}, {
 465		.mfr_id = MANUFACTURER_FUJITSU,
 466		.dev_id = MBM29LV160TE,
 467		.name = "Fujitsu MBM29LV160TE",
 468		.size = 0x00200000,
 469		.numeraseregions = 4,
 470		.regions = {
 471			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 31 },
 472			{ .offset = 0x1F0000, .erasesize = 0x08000, .numblocks =  1 },
 473			{ .offset = 0x1F8000, .erasesize = 0x02000, .numblocks =  2 },
 474			{ .offset = 0x1FC000, .erasesize = 0x04000, .numblocks =  1 }
 475		}
 476	}, {
 477		.mfr_id = MANUFACTURER_TOSHIBA,
 478		.dev_id = TC58FVB160,
 479		.name = "Toshiba TC58FVB160",
 480		.size = 0x00200000,
 481		.numeraseregions = 4,
 482		.regions = {
 483			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 484			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 485			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 486			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 31 }
 487		}
 488	}, {
 489		.mfr_id = MANUFACTURER_FUJITSU,
 490		.dev_id = MBM29LV160BE,
 491		.name = "Fujitsu MBM29LV160BE",
 492		.size = 0x00200000,
 493		.numeraseregions = 4,
 494		.regions = {
 495			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 496			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 497			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 498			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 31 }
 499		}
 500	}, {
 501		.mfr_id = MANUFACTURER_AMD,
 502		.dev_id = AM29LV800BB,
 503		.name = "AMD AM29LV800BB",
 504		.size = 0x00100000,
 505		.numeraseregions = 4,
 506		.regions = {
 507			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 508			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 509			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 510			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 15 }
 511		}
 512	}, {
 513		.mfr_id = MANUFACTURER_AMD,
 514		.dev_id = AM29F800BB,
 515		.name = "AMD AM29F800BB",
 516		.size = 0x00100000,
 517		.numeraseregions = 4,
 518		.regions = {
 519			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 520			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 521			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 522			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 15 }
 523		}
 524	}, {
 525		.mfr_id = MANUFACTURER_AMD,
 526		.dev_id = AM29LV800BT,
 527		.name = "AMD AM29LV800BT",
 528		.size = 0x00100000,
 529		.numeraseregions = 4,
 530		.regions = {
 531			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 15 },
 532			{ .offset = 0x0F0000, .erasesize = 0x08000, .numblocks =  1 },
 533			{ .offset = 0x0F8000, .erasesize = 0x02000, .numblocks =  2 },
 534			{ .offset = 0x0FC000, .erasesize = 0x04000, .numblocks =  1 }
 535		}
 536	}, {
 537		.mfr_id = MANUFACTURER_AMD,
 538		.dev_id = AM29F800BT,
 539		.name = "AMD AM29F800BT",
 540		.size = 0x00100000,
 541		.numeraseregions = 4,
 542		.regions = {
 543			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 15 },
 544			{ .offset = 0x0F0000, .erasesize = 0x08000, .numblocks =  1 },
 545			{ .offset = 0x0F8000, .erasesize = 0x02000, .numblocks =  2 },
 546			{ .offset = 0x0FC000, .erasesize = 0x04000, .numblocks =  1 }
 547		}
 548	}, {
 549		.mfr_id = MANUFACTURER_AMD,
 550		.dev_id = AM29LV800BB,
 551		.name = "AMD AM29LV800BB",
 552		.size = 0x00100000,
 553		.numeraseregions = 4,
 554		.regions = {
 555			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 15 },
 556			{ .offset = 0x0F0000, .erasesize = 0x08000, .numblocks =  1 },
 557			{ .offset = 0x0F8000, .erasesize = 0x02000, .numblocks =  2 },
 558			{ .offset = 0x0FC000, .erasesize = 0x04000, .numblocks =  1 }
 559		}
 560	}, {
 561		.mfr_id = MANUFACTURER_FUJITSU,
 562		.dev_id = MBM29LV800BB,
 563		.name = "Fujitsu MBM29LV800BB",
 564		.size = 0x00100000,
 565		.numeraseregions = 4,
 566		.regions = {
 567			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 568			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 569			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 570			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 15 }
 571		}
 572	}, {
 573		.mfr_id = MANUFACTURER_ST,
 574		.dev_id = M29W800T,
 575		.name = "ST M29W800T",
 576		.size = 0x00100000,
 577		.numeraseregions = 4,
 578		.regions = {
 579			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 15 },
 580			{ .offset = 0x0F0000, .erasesize = 0x08000, .numblocks =  1 },
 581			{ .offset = 0x0F8000, .erasesize = 0x02000, .numblocks =  2 },
 582			{ .offset = 0x0FC000, .erasesize = 0x04000, .numblocks =  1 }
 583		}
 584	}, {
 585		.mfr_id = MANUFACTURER_ST,
 586		.dev_id = M29W160DT,
 587		.name = "ST M29W160DT",
 588		.size = 0x00200000,
 589		.numeraseregions = 4,
 590		.regions = {
 591			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 31 },
 592			{ .offset = 0x1F0000, .erasesize = 0x08000, .numblocks =  1 },
 593			{ .offset = 0x1F8000, .erasesize = 0x02000, .numblocks =  2 },
 594			{ .offset = 0x1FC000, .erasesize = 0x04000, .numblocks =  1 }
 595		}
 596	}, {
 597		.mfr_id = MANUFACTURER_ST,
 598		.dev_id = M29W160DB,
 599		.name = "ST M29W160DB",
 600		.size = 0x00200000,
 601		.numeraseregions = 4,
 602		.regions = {
 603			{ .offset = 0x000000, .erasesize = 0x04000, .numblocks =  1 },
 604			{ .offset = 0x004000, .erasesize = 0x02000, .numblocks =  2 },
 605			{ .offset = 0x008000, .erasesize = 0x08000, .numblocks =  1 },
 606			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 31 }
 607		}
 608	}, {
 609		.mfr_id = MANUFACTURER_AMD,
 610		.dev_id = AM29BDS323D,
 611		.name = "AMD AM29BDS323D",
 612		.size = 0x00400000,
 613		.numeraseregions = 3,
 614		.regions = {
 615			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 48 },
 616			{ .offset = 0x300000, .erasesize = 0x10000, .numblocks = 15 },
 617			{ .offset = 0x3f0000, .erasesize = 0x02000, .numblocks =  8 },
 618		}
 619	}, {
 620		.mfr_id = MANUFACTURER_ATMEL,
 621		.dev_id = AT49xV16x,
 622		.name = "Atmel AT49xV16x",
 623		.size = 0x00200000,
 624		.numeraseregions = 2,
 625		.regions = {
 626			{ .offset = 0x000000, .erasesize = 0x02000, .numblocks =  8 },
 627			{ .offset = 0x010000, .erasesize = 0x10000, .numblocks = 31 }
 628		}
 629	}, {
 630		.mfr_id = MANUFACTURER_ATMEL,
 631		.dev_id = AT49xV16xT,
 632		.name = "Atmel AT49xV16xT",
 633		.size = 0x00200000,
 634		.numeraseregions = 2,
 635		.regions = {
 636			{ .offset = 0x000000, .erasesize = 0x10000, .numblocks = 31 },
 637			{ .offset = 0x1F0000, .erasesize = 0x02000, .numblocks =  8 }
 638		}
 639	}
 640	};
 641
 642	struct mtd_info *mtd;
 643	struct flchip chips[MAX_AMD_CHIPS];
 644	int table_pos[MAX_AMD_CHIPS];
 645	struct amd_flash_private temp;
 646	struct amd_flash_private *private;
 647	u_long size;
 648	unsigned long base;
 649	int i;
 650	int reg_idx;
 651	int offset;
 652
 653	mtd = (struct mtd_info*)kmalloc(sizeof(*mtd), GFP_KERNEL);
 654	if (!mtd) {
 655		printk(KERN_WARNING
 656		       "%s: kmalloc failed for info structure\n", map->name);
 657		return NULL;
 658	}
 659	memset(mtd, 0, sizeof(*mtd));
 660	mtd->priv = map;
 661
 662	memset(&temp, 0, sizeof(temp));
 663
 664	printk("%s: Probing for AMD compatible flash...\n", map->name);
 665
 666	if ((table_pos[0] = probe_new_chip(mtd, 0, NULL, &temp, table,
 667					   sizeof(table)/sizeof(table[0])))
 668	    == -1) {
 669		printk(KERN_WARNING
 670		       "%s: Found no AMD compatible device at location zero\n",
 671		       map->name);
 672		kfree(mtd);
 673
 674		return NULL;
 675	}
 676
 677	chips[0].start = 0;
 678	chips[0].state = FL_READY;
 679	chips[0].mutex = &chips[0]._spinlock;
 680	temp.numchips = 1;
 681	for (size = mtd->size; size > 1; size >>= 1) {
 682		temp.chipshift++;
 683	}
 684	switch (temp.interleave) {
 685		case 2:
 686			temp.chipshift += 1;
 687			break;
 688		case 4:
 689			temp.chipshift += 2;
 690			break;
 691	}
 692
 693	/* Find out if there are any more chips in the map. */
 694	for (base = (1 << temp.chipshift);
 695	     base < map->size;
 696	     base += (1 << temp.chipshift)) {
 697	     	int numchips = temp.numchips;
 698		table_pos[numchips] = probe_new_chip(mtd, base, chips,
 699			&temp, table, sizeof(table)/sizeof(table[0]));
 700	}
 701
 702	mtd->eraseregions = kmalloc(sizeof(struct mtd_erase_region_info) *
 703				    mtd->numeraseregions, GFP_KERNEL);
 704	if (!mtd->eraseregions) {
 705		printk(KERN_WARNING "%s: Failed to allocate "
 706		       "memory for MTD erase region info\n", map->name);
 707		kfree(mtd);
 708		map->fldrv_priv = NULL;
 709		return NULL;
 710	}
 711
 712	reg_idx = 0;
 713	offset = 0;
 714	for (i = 0; i < temp.numchips; i++) {
 715		int dev_size;
 716		int j;
 717
 718		dev_size = 0;
 719		for (j = 0; j < table[table_pos[i]].numeraseregions; j++) {
 720			mtd->eraseregions[reg_idx].offset = offset +
 721				(table[table_pos[i]].regions[j].offset *
 722				 temp.interleave);
 723			mtd->eraseregions[reg_idx].erasesize =
 724				table[table_pos[i]].regions[j].erasesize *
 725				temp.interleave;
 726			mtd->eraseregions[reg_idx].numblocks =
 727				table[table_pos[i]].regions[j].numblocks;
 728			if (mtd->erasesize <
 729			    mtd->eraseregions[reg_idx].erasesize) {
 730				mtd->erasesize =
 731					mtd->eraseregions[reg_idx].erasesize;
 732			}
 733			dev_size += mtd->eraseregions[reg_idx].erasesize *
 734				    mtd->eraseregions[reg_idx].numblocks;
 735			reg_idx++;
 736		}
 737		offset += dev_size;
 738	}
 739	mtd->type = MTD_NORFLASH;
 740	mtd->flags = MTD_CAP_NORFLASH;
 741	mtd->name = map->name;
 742	mtd->erase = amd_flash_erase;
 743	mtd->read = amd_flash_read;
 744	mtd->write = amd_flash_write;
 745	mtd->sync = amd_flash_sync;
 746	mtd->suspend = amd_flash_suspend;
 747	mtd->resume = amd_flash_resume;
 748	mtd->lock = amd_flash_lock;
 749	mtd->unlock = amd_flash_unlock;
 750
 751	private = kmalloc(sizeof(*private) + (sizeof(struct flchip) *
 752					      temp.numchips), GFP_KERNEL);
 753	if (!private) {
 754		printk(KERN_WARNING
 755		       "%s: kmalloc failed for private structure\n", map->name);
 756		kfree(mtd);
 757		map->fldrv_priv = NULL;
 758		return NULL;
 759	}
 760	memcpy(private, &temp, sizeof(temp));
 761	memcpy(private->chips, chips,
 762	       sizeof(struct flchip) * private->numchips);
 763	for (i = 0; i < private->numchips; i++) {
 764		init_waitqueue_head(&private->chips[i].wq);
 765		spin_lock_init(&private->chips[i]._spinlock);
 766	}
 767
 768	map->fldrv_priv = private;
 769
 770	map->fldrv = &amd_flash_chipdrv;
 771
 772	__module_get(THIS_MODULE);
 773	return mtd;
 774}
 775
 776
 777
 778static inline int read_one_chip(struct map_info *map, struct flchip *chip,
 779			       loff_t adr, size_t len, u_char *buf)
 780{
 781	DECLARE_WAITQUEUE(wait, current);
 782	unsigned long timeo = jiffies + HZ;
 783
 784retry:
 785	spin_lock_bh(chip->mutex);
 786
 787	if (chip->state != FL_READY){
 788		printk(KERN_INFO "%s: waiting for chip to read, state = %d\n",
 789		       map->name, chip->state);
 790		set_current_state(TASK_UNINTERRUPTIBLE);
 791		add_wait_queue(&chip->wq, &wait);
 792
 793		spin_unlock_bh(chip->mutex);
 794
 795		schedule();
 796		remove_wait_queue(&chip->wq, &wait);
 797
 798		if(signal_pending(current)) {
 799			return -EINTR;
 800		}
 801
 802		timeo = jiffies + HZ;
 803
 804		goto retry;
 805	}
 806
 807	adr += chip->start;
 808
 809	chip->state = FL_READY;
 810
 811	map_copy_from(map, buf, adr, len);
 812
 813	wake_up(&chip->wq);
 814	spin_unlock_bh(chip->mutex);
 815
 816	return 0;
 817}
 818
 819
 820
 821static int amd_flash_read(struct mtd_info *mtd, loff_t from, size_t len,
 822			  size_t *retlen, u_char *buf)
 823{
 824	struct map_info *map = mtd->priv;
 825	struct amd_flash_private *private = map->fldrv_priv;
 826	unsigned long ofs;
 827	int chipnum;
 828	int ret = 0;
 829
 830	if ((from + len) > mtd->size) {
 831		printk(KERN_WARNING "%s: read request past end of device "
 832		       "(0x%lx)\n", map->name, (unsigned long)from + len);
 833
 834		return -EINVAL;
 835	}
 836
 837	/* Offset within the first chip that the first read should start. */
 838	chipnum = (from >> private->chipshift);
 839	ofs = from - (chipnum <<  private->chipshift);
 840
 841	*retlen = 0;
 842
 843	while (len) {
 844		unsigned long this_len;
 845
 846		if (chipnum >= private->numchips) {
 847			break;
 848		}
 849
 850		if ((len + ofs - 1) >> private->chipshift) {
 851			this_len = (1 << private->chipshift) - ofs;
 852		} else {
 853			this_len = len;
 854		}
 855
 856		ret = read_one_chip(map, &private->chips[chipnum], ofs,
 857				    this_len, buf);
 858		if (ret) {
 859			break;
 860		}
 861
 862		*retlen += this_len;
 863		len -= this_len;
 864		buf += this_len;
 865
 866		ofs = 0;
 867		chipnum++;
 868	}
 869
 870	return ret;
 871}
 872
 873
 874
 875static int write_one_word(struct map_info *map, struct flchip *chip,
 876			  unsigned long adr, __u32 datum)
 877{
 878	unsigned long timeo = jiffies + HZ;
 879	struct amd_flash_private *private = map->fldrv_priv;
 880	DECLARE_WAITQUEUE(wait, current);
 881	int ret = 0;
 882	int times_left;
 883
 884retry:
 885	spin_lock_bh(chip->mutex);
 886
 887	if (chip->state != FL_READY){
 888		printk("%s: waiting for chip to write, state = %d\n",
 889		       map->name, chip->state);
 890		set_current_state(TASK_UNINTERRUPTIBLE);
 891		add_wait_queue(&chip->wq, &wait);
 892
 893		spin_unlock_bh(chip->mutex);
 894
 895		schedule();
 896		remove_wait_queue(&chip->wq, &wait);
 897		printk(KERN_INFO "%s: woke up to write\n", map->name);
 898		if(signal_pending(current))
 899			return -EINTR;
 900
 901		timeo = jiffies + HZ;
 902
 903		goto retry;
 904	}
 905
 906	chip->state = FL_WRITING;
 907
 908	adr += chip->start;
 909	ENABLE_VPP(map);
 910	send_cmd(map, chip->start, CMD_PROGRAM_UNLOCK_DATA);
 911	wide_write(map, datum, adr);
 912
 913	times_left = 500000;
 914	while (times_left-- && flash_is_busy(map, adr, private->interleave)) {
 915		if (need_resched()) {
 916			spin_unlock_bh(chip->mutex);
 917			schedule();
 918			spin_lock_bh(chip->mutex);
 919		}
 920	}
 921
 922	if (!times_left) {
 923		printk(KERN_WARNING "%s: write to 0x%lx timed out!\n",
 924		       map->name, adr);
 925		ret = -EIO;
 926	} else {
 927		__u32 verify;
 928		if ((verify = wide_read(map, adr)) != datum) {
 929			printk(KERN_WARNING "%s: write to 0x%lx failed. "
 930			       "datum = %x, verify = %x\n",
 931			       map->name, adr, datum, verify);
 932			ret = -EIO;
 933		}
 934	}
 935
 936	DISABLE_VPP(map);
 937	chip->state = FL_READY;
 938	wake_up(&chip->wq);
 939	spin_unlock_bh(chip->mutex);
 940
 941	return ret;
 942}
 943
 944
 945
 946static int amd_flash_write(struct mtd_info *mtd, loff_t to , size_t len,
 947			   size_t *retlen, const u_char *buf)
 948{
 949	struct map_info *map = mtd->priv;
 950	struct amd_flash_private *private = map->fldrv_priv;
 951	int ret = 0;
 952	int chipnum;
 953	unsigned long ofs;
 954	unsigned long chipstart;
 955
 956	*retlen = 0;
 957	if (!len) {
 958		return 0;
 959	}
 960
 961	chipnum = to >> private->chipshift;
 962	ofs = to  - (chipnum << private->chipshift);
 963	chipstart = private->chips[chipnum].start;
 964
 965	/* If it's not bus-aligned, do the first byte write. */
 966	if (ofs & (map->buswidth - 1)) {
 967		unsigned long bus_ofs = ofs & ~(map->buswidth - 1);
 968		int i = ofs - bus_ofs;
 969		int n = 0;
 970		u_char tmp_buf[4];
 971		__u32 datum;
 972
 973		map_copy_from(map, tmp_buf,
 974			       bus_ofs + private->chips[chipnum].start,
 975			       map->buswidth);
 976		while (len && i < map->buswidth)
 977			tmp_buf[i++] = buf[n++], len--;
 978
 979		if (map->buswidth == 2) {
 980			datum = *(__u16*)tmp_buf;
 981		} else if (map->buswidth == 4) {
 982			datum = *(__u32*)tmp_buf;
 983		} else {
 984			return -EINVAL;  /* should never happen, but be safe */
 985		}
 986
 987		ret = write_one_word(map, &private->chips[chipnum], bus_ofs,
 988				     datum);
 989		if (ret) {
 990			return ret;
 991		}
 992
 993		ofs += n;
 994		buf += n;
 995		(*retlen) += n;
 996
 997		if (ofs >> private->chipshift) {
 998			chipnum++;
 999			ofs = 0;
1000			if (chipnum == private->numchips) {
1001				return 0;
1002			}
1003		}
1004	}
1005
1006	/* We are now aligned, write as much as possible. */
1007	while(len >= map->buswidth) {
1008		__u32 datum;
1009
1010		if (map->buswidth == 1) {
1011			datum = *(__u8*)buf;
1012		} else if (map->buswidth == 2) {
1013			datum = *(__u16*)buf;
1014		} else if (map->buswidth == 4) {
1015			datum = *(__u32*)buf;
1016		} else {
1017			return -EINVAL;
1018		}
1019
1020		ret = write_one_word(map, &private->chips[chipnum], ofs, datum);
1021
1022		if (ret) {
1023			return ret;
1024		}
1025
1026		ofs += map->buswidth;
1027		buf += map->buswidth;
1028		(*retlen) += map->buswidth;
1029		len -= map->buswidth;
1030
1031		if (ofs >> private->chipshift) {
1032			chipnum++;
1033			ofs = 0;
1034			if (chipnum == private->numchips) {
1035				return 0;
1036			}
1037			chipstart = private->chips[chipnum].start;
1038		}
1039	}
1040
1041	if (len & (map->buswidth - 1)) {
1042		int i = 0, n = 0;
1043		u_char tmp_buf[2];
1044		__u32 datum;
1045
1046		map_copy_from(map, tmp_buf,
1047			       ofs + private->chips[chipnum].start,
1048			       map->buswidth);
1049		while (len--) {
1050			tmp_buf[i++] = buf[n++];
1051		}
1052
1053		if (map->buswidth == 2) {
1054			datum = *(__u16*)tmp_buf;
1055		} else if (map->buswidth == 4) {
1056			datum = *(__u32*)tmp_buf;
1057		} else {
1058			return -EINVAL;  /* should never happen, but be safe */
1059		}
1060
1061		ret = write_one_word(map, &private->chips[chipnum], ofs, datum);
1062
1063		if (ret) {
1064			return ret;
1065		}
1066
1067		(*retlen) += n;
1068	}
1069
1070	return 0;
1071}
1072
1073
1074
1075static inline int erase_one_block(struct map_info *map, struct flchip *chip,
1076				  unsigned long adr, u_long size)
1077{
1078	unsigned long timeo = jiffies + HZ;
1079	struct amd_flash_private *private = map->fldrv_priv;
1080	DECLARE_WAITQUEUE(wait, current);
1081
1082retry:
1083	spin_lock_bh(chip->mutex);
1084
1085	if (chip->state != FL_READY){
1086		set_current_state(TASK_UNINTERRUPTIBLE);
1087		add_wait_queue(&chip->wq, &wait);
1088
1089		spin_unlock_bh(chip->mutex);
1090
1091		schedule();
1092		remove_wait_queue(&chip->wq, &wait);
1093
1094		if (signal_pending(current)) {
1095			return -EINTR;
1096		}
1097
1098		timeo = jiffies + HZ;
1099
1100		goto retry;
1101	}
1102
1103	chip->state = FL_ERASING;
1104
1105	adr += chip->start;
1106	ENABLE_VPP(map);
1107	send_cmd(map, chip->start, CMD_SECTOR_ERASE_UNLOCK_DATA);
1108	send_cmd_to_addr(map, chip->start, CMD_SECTOR_ERASE_UNLOCK_DATA_2, adr);
1109
1110	timeo = jiffies + (HZ * 20);
1111
1112	spin_unlock_bh(chip->mutex);
1113	msleep(1000);
1114	spin_lock_bh(chip->mutex);
1115
1116	while (flash_is_busy(map, adr, private->interleave)) {
1117
1118		if (chip->state != FL_ERASING) {
1119			/* Someone's suspended the erase. Sleep */
1120			set_current_state(TASK_UNINTERRUPTIBLE);
1121			add_wait_queue(&chip->wq, &wait);
1122
1123			spin_unlock_bh(chip->mutex);
1124			printk(KERN_INFO "%s: erase suspended. Sleeping\n",
1125			       map->name);
1126			schedule();
1127			remove_wait_queue(&chip->wq, &wait);
1128
1129			if (signal_pending(current)) {
1130				return -EINTR;
1131			}
1132
1133			timeo = jiffies + (HZ*2); /* FIXME */
1134			spin_lock_bh(chip->mutex);
1135			continue;
1136		}
1137
1138		/* OK Still waiting */
1139		if (time_after(jiffies, timeo)) {
1140			chip->state = FL_READY;
1141			spin_unlock_bh(chip->mutex);
1142			printk(KERN_WARNING "%s: waiting for erase to complete "
1143			       "timed out.\n", map->name);
1144			DISABLE_VPP(map);
1145
1146			return -EIO;
1147		}
1148
1149		/* Latency issues. Drop the lock, wait a while and retry */
1150		spin_unlock_bh(chip->mutex);
1151
1152		if (need_resched())
1153			schedule();
1154		else
1155			udelay(1);
1156
1157		spin_lock_bh(chip->mutex);
1158	}
1159
1160	/* Verify every single word */
1161	{
1162		int address;
1163		int error = 0;
1164		__u8 verify;
1165
1166		for (address = adr; address < (adr + size); address++) {
1167			if ((verify = map_read8(map, address)) != 0xFF) {
1168				error = 1;
1169				break;
1170			}
1171		}
1172		if (error) {
1173			chip->state = FL_READY;
1174			spin_unlock_bh(chip->mutex);
1175			printk(KERN_WARNING
1176			       "%s: verify error at 0x%x, size %ld.\n",
1177			       map->name, address, size);
1178			DISABLE_VPP(map);
1179
1180			return -EIO;
1181		}
1182	}
1183
1184	DISABLE_VPP(map);
1185	chip->state = FL_READY;
1186	wake_up(&chip->wq);
1187	spin_unlock_bh(chip->mutex);
1188
1189	return 0;
1190}
1191
1192
1193
1194static int amd_flash_erase(struct mtd_info *mtd, struct erase_info *instr)
1195{
1196	struct map_info *map = mtd->priv;
1197	struct amd_flash_private *private = map->fldrv_priv;
1198	unsigned long adr, len;
1199	int chipnum;
1200	int ret = 0;
1201	int i;
1202	int first;
1203	struct mtd_erase_region_info *regions = mtd->eraseregions;
1204
1205	if (instr->addr > mtd->size) {
1206		return -EINVAL;
1207	}
1208
1209	if ((instr->len + instr->addr) > mtd->size) {
1210		return -EINVAL;
1211	}
1212
1213	/* Check that both start and end of the requested erase are
1214	 * aligned with the erasesize at the appropriate addresses.
1215	 */
1216
1217	i = 0;
1218
1219        /* Skip all erase regions which are ended before the start of
1220           the requested erase. Actually, to save on the calculations,
1221           we skip to the first erase region which starts after the
1222           start of the requested erase, and then go back one.
1223        */
1224
1225        while ((i < mtd->numeraseregions) &&
1226	       (instr->addr >= regions[i].offset)) {
1227               i++;
1228	}
1229        i--;
1230
1231	/* OK, now i is pointing at the erase region in which this
1232	 * erase request starts. Check the start of the requested
1233	 * erase range is aligned with the erase size which is in
1234	 * effect here.
1235	 */
1236
1237	if (instr->addr & (regions[i].erasesize-1)) {
1238		return -EINVAL;
1239	}
1240
1241	/* Remember the erase region we start on. */
1242
1243	first = i;
1244
1245	/* Next, check that the end of the requested erase is aligned
1246	 * with the erase region at that address.
1247	 */
1248
1249	while ((i < mtd->numeraseregions) &&
1250	       ((instr->addr + instr->len) >= regions[i].offset)) {
1251                i++;
1252	}
1253
1254	/* As before, drop back one to point at the region in which
1255	 * the address actually falls.
1256	 */
1257
1258	i--;
1259
1260	if ((instr->addr + instr->len) & (regions[i].erasesize-1)) {
1261                return -EINVAL;
1262	}
1263
1264	chipnum = instr->addr >> private->chipshift;
1265	adr = instr->addr - (chipnum << private->chipshift);
1266	len = instr->len;
1267
1268	i = first;
1269
1270	while (len) {
1271		ret = erase_one_block(map, &private->chips[chipnum], adr,
1272				      regions[i].erasesize);
1273
1274		if (ret) {
1275			return ret;
1276		}
1277
1278		adr += regions[i].erasesize;
1279		len -= regions[i].erasesize;
1280
1281		if ((adr % (1 << private->chipshift)) ==
1282		    ((regions[i].offset + (regions[i].erasesize *
1283		    			   regions[i].numblocks))
1284		     % (1 << private->chipshift))) {
1285			i++;
1286		}
1287
1288		if (adr >> private->chipshift) {
1289			adr = 0;
1290			chipnum++;
1291			if (chipnum >= private->numchips) {
1292				break;
1293			}
1294		}
1295	}
1296
1297	instr->state = MTD_ERASE_DONE;
1298	mtd_erase_callback(instr);
1299
1300	return 0;
1301}
1302
1303
1304
1305static void amd_flash_sync(struct mtd_info *mtd)
1306{
1307	struct map_info *map = mtd->priv;
1308	struct amd_flash_private *private = map->fldrv_priv;
1309	int i;
1310	struct flchip *chip;
1311	int ret = 0;
1312	DECLARE_WAITQUEUE(wait, current);
1313
1314	for (i = 0; !ret && (i < private->numchips); i++) {
1315		chip = &private->chips[i];
1316
1317	retry:
1318		spin_lock_bh(chip->mutex);
1319
1320		switch(chip->state) {
1321		case FL_READY:
1322		case FL_STATUS:
1323		case FL_CFI_QUERY:
1324		case FL_JEDEC_QUERY:
1325			chip->oldstate = chip->state;
1326			chip->state = FL_SYNCING;
1327			/* No need to wake_up() on this state change -
1328			 * as the whole point is that nobody can do anything
1329			 * with the chip now anyway.
1330			 */
1331		case FL_SYNCING:
1332			spin_unlock_bh(chip->mutex);
1333			break;
1334
1335		default:
1336			/* Not an idle state */
1337			add_wait_queue(&chip->wq, &wait);
1338
1339			spin_unlock_bh(chip->mutex);
1340
1341			schedule();
1342
1343		        remove_wait_queue(&chip->wq, &wait);
1344
1345			goto retry;
1346		}
1347	}
1348
1349	/* Unlock the chips again */
1350	for (i--; i >= 0; i--) {
1351		chip = &private->chips[i];
1352
1353		spin_lock_bh(chip->mutex);
1354
1355		if (chip->state == FL_SYNCING) {
1356			chip->state = chip->oldstate;
1357			wake_up(&chip->wq);
1358		}
1359		spin_unlock_bh(chip->mutex);
1360	}
1361}
1362
1363
1364
1365static int amd_flash_suspend(struct mtd_info *mtd)
1366{
1367printk("amd_flash_suspend(): not implemented!\n");
1368	return -EINVAL;
1369}
1370
1371
1372
1373static void amd_flash_resume(struct mtd_info *mtd)
1374{
1375printk("amd_flash_resume(): not implemented!\n");
1376}
1377
1378
1379
1380static void amd_flash_destroy(struct mtd_info *mtd)
1381{
1382	struct map_info *map = mtd->priv;
1383	struct amd_flash_private *private = map->fldrv_priv;
1384	kfree(private);
1385}
1386
1387int __init amd_flash_init(void)
1388{
1389	register_mtd_chip_driver(&amd_flash_chipdrv);
1390	return 0;
1391}
1392
1393void __exit amd_flash_exit(void)
1394{
1395	unregister_mtd_chip_driver(&amd_flash_chipdrv);
1396}
1397
1398module_init(amd_flash_init);
1399module_exit(amd_flash_exit);
1400
1401MODULE_LICENSE("GPL");
1402MODULE_AUTHOR("Jonas Holmberg <jonas.holmberg@axis.com>");
1403MODULE_DESCRIPTION("Old MTD chip driver for AMD flash chips");