1 2/* 3 * MTD driver for the 28F160F3 Flash Memory (non-CFI) on LART. 4 * 5 * Author: Abraham vd Merwe <abraham@2d3d.co.za> 6 * 7 * Copyright (c) 2001, 2d3D, Inc. 8 * 9 * This code is free software; you can redistribute it and/or modify 10 * it under the terms of the GNU General Public License version 2 as 11 * published by the Free Software Foundation. 12 * 13 * References: 14 * 15 * [1] 3 Volt Fast Boot Block Flash Memory" Intel Datasheet 16 * - Order Number: 290644-005 17 * - January 2000 18 * 19 * [2] MTD internal API documentation 20 * - http://www.linux-mtd.infradead.org/tech/ 21 * 22 * Limitations: 23 * 24 * Even though this driver is written for 3 Volt Fast Boot 25 * Block Flash Memory, it is rather specific to LART. With 26 * Minor modifications, notably the without data/address line 27 * mangling and different bus settings, etc. it should be 28 * trivial to adapt to other platforms. 29 * 30 * If somebody would sponsor me a different board, I'll 31 * adapt the driver (: 32 */ 33 34/* debugging */ 35//#define LART_DEBUG 36 37/* partition support */ 38#define HAVE_PARTITIONS 39 40#include <linux/kernel.h> 41#include <linux/module.h> 42#include <linux/types.h> 43#include <linux/init.h> 44#include <linux/errno.h> 45#include <linux/string.h> 46#include <linux/mtd/mtd.h> 47#ifdef HAVE_PARTITIONS 48#include <linux/mtd/partitions.h> 49#endif 50 51#ifndef CONFIG_SA1100_LART 52#error This is for LART architecture only 53#endif 54 55static char module_name[] = "lart"; 56 57/* 58 * These values is specific to 28Fxxxx3 flash memory. 59 * See section 2.3.1 in "3 Volt Fast Boot Block Flash Memory" Intel Datasheet 60 */ 61#define FLASH_BLOCKSIZE_PARAM (4096 * BUSWIDTH) 62#define FLASH_NUMBLOCKS_16m_PARAM 8 63#define FLASH_NUMBLOCKS_8m_PARAM 8 64 65/* 66 * These values is specific to 28Fxxxx3 flash memory. 67 * See section 2.3.2 in "3 Volt Fast Boot Block Flash Memory" Intel Datasheet 68 */ 69#define FLASH_BLOCKSIZE_MAIN (32768 * BUSWIDTH) 70#define FLASH_NUMBLOCKS_16m_MAIN 31 71#define FLASH_NUMBLOCKS_8m_MAIN 15 72 73/* 74 * These values are specific to LART 75 */ 76 77/* general */ 78#define BUSWIDTH 4 /* don't change this - a lot of the code _will_ break if you change this */ 79#define FLASH_OFFSET 0xe8000000 /* see linux/arch/arm/mach-sa1100/lart.c */ 80 81/* blob */ 82#define NUM_BLOB_BLOCKS FLASH_NUMBLOCKS_16m_PARAM 83#define BLOB_START 0x00000000 84#define BLOB_LEN (NUM_BLOB_BLOCKS * FLASH_BLOCKSIZE_PARAM) 85 86/* kernel */ 87#define NUM_KERNEL_BLOCKS 7 88#define KERNEL_START (BLOB_START + BLOB_LEN) 89#define KERNEL_LEN (NUM_KERNEL_BLOCKS * FLASH_BLOCKSIZE_MAIN) 90 91/* initial ramdisk */ 92#define NUM_INITRD_BLOCKS 24 93#define INITRD_START (KERNEL_START + KERNEL_LEN) 94#define INITRD_LEN (NUM_INITRD_BLOCKS * FLASH_BLOCKSIZE_MAIN) 95 96/* 97 * See section 4.0 in "3 Volt Fast Boot Block Flash Memory" Intel Datasheet 98 */ 99#define READ_ARRAY 0x00FF00FF /* Read Array/Reset */ 100#define READ_ID_CODES 0x00900090 /* Read Identifier Codes */ 101#define ERASE_SETUP 0x00200020 /* Block Erase */ 102#define ERASE_CONFIRM 0x00D000D0 /* Block Erase and Program Resume */ 103#define PGM_SETUP 0x00400040 /* Program */ 104#define STATUS_READ 0x00700070 /* Read Status Register */ 105#define STATUS_CLEAR 0x00500050 /* Clear Status Register */ 106#define STATUS_BUSY 0x00800080 /* Write State Machine Status (WSMS) */ 107#define STATUS_ERASE_ERR 0x00200020 /* Erase Status (ES) */ 108#define STATUS_PGM_ERR 0x00100010 /* Program Status (PS) */ 109 110/* 111 * See section 4.2 in "3 Volt Fast Boot Block Flash Memory" Intel Datasheet 112 */ 113#define FLASH_MANUFACTURER 0x00890089 114#define FLASH_DEVICE_8mbit_TOP 0x88f188f1 115#define FLASH_DEVICE_8mbit_BOTTOM 0x88f288f2 116#define FLASH_DEVICE_16mbit_TOP 0x88f388f3 117#define FLASH_DEVICE_16mbit_BOTTOM 0x88f488f4 118 119/***************************************************************************************************/ 120 121/* 122 * The data line mapping on LART is as follows: 123 * 124 * U2 CPU | U3 CPU 125 * ------------------- 126 * 0 20 | 0 12 127 * 1 22 | 1 14 128 * 2 19 | 2 11 129 * 3 17 | 3 9 130 * 4 24 | 4 0 131 * 5 26 | 5 2 132 * 6 31 | 6 7 133 * 7 29 | 7 5 134 * 8 21 | 8 13 135 * 9 23 | 9 15 136 * 10 18 | 10 10 137 * 11 16 | 11 8 138 * 12 25 | 12 1 139 * 13 27 | 13 3 140 * 14 30 | 14 6 141 * 15 28 | 15 4 142 */ 143 144/* Mangle data (x) */ 145#define DATA_TO_FLASH(x) \ 146 ( \ 147 (((x) & 0x08009000) >> 11) + \ 148 (((x) & 0x00002000) >> 10) + \ 149 (((x) & 0x04004000) >> 8) + \ 150 (((x) & 0x00000010) >> 4) + \ 151 (((x) & 0x91000820) >> 3) + \ 152 (((x) & 0x22080080) >> 2) + \ 153 ((x) & 0x40000400) + \ 154 (((x) & 0x00040040) << 1) + \ 155 (((x) & 0x00110000) << 4) + \ 156 (((x) & 0x00220100) << 5) + \ 157 (((x) & 0x00800208) << 6) + \ 158 (((x) & 0x00400004) << 9) + \ 159 (((x) & 0x00000001) << 12) + \ 160 (((x) & 0x00000002) << 13) \ 161 ) 162 163/* Unmangle data (x) */ 164#define FLASH_TO_DATA(x) \ 165 ( \ 166 (((x) & 0x00010012) << 11) + \ 167 (((x) & 0x00000008) << 10) + \ 168 (((x) & 0x00040040) << 8) + \ 169 (((x) & 0x00000001) << 4) + \ 170 (((x) & 0x12200104) << 3) + \ 171 (((x) & 0x08820020) << 2) + \ 172 ((x) & 0x40000400) + \ 173 (((x) & 0x00080080) >> 1) + \ 174 (((x) & 0x01100000) >> 4) + \ 175 (((x) & 0x04402000) >> 5) + \ 176 (((x) & 0x20008200) >> 6) + \ 177 (((x) & 0x80000800) >> 9) + \ 178 (((x) & 0x00001000) >> 12) + \ 179 (((x) & 0x00004000) >> 13) \ 180 ) 181 182/* 183 * The address line mapping on LART is as follows: 184 * 185 * U3 CPU | U2 CPU 186 * ------------------- 187 * 0 2 | 0 2 188 * 1 3 | 1 3 189 * 2 9 | 2 9 190 * 3 13 | 3 8 191 * 4 8 | 4 7 192 * 5 12 | 5 6 193 * 6 11 | 6 5 194 * 7 10 | 7 4 195 * 8 4 | 8 10 196 * 9 5 | 9 11 197 * 10 6 | 10 12 198 * 11 7 | 11 13 199 * 200 * BOOT BLOCK BOUNDARY 201 * 202 * 12 15 | 12 15 203 * 13 14 | 13 14 204 * 14 16 | 14 16 205 * 206 * MAIN BLOCK BOUNDARY 207 * 208 * 15 17 | 15 18 209 * 16 18 | 16 17 210 * 17 20 | 17 20 211 * 18 19 | 18 19 212 * 19 21 | 19 21 213 * 214 * As we can see from above, the addresses aren't mangled across 215 * block boundaries, so we don't need to worry about address 216 * translations except for sending/reading commands during 217 * initialization 218 */ 219 220/* Mangle address (x) on chip U2 */ 221#define ADDR_TO_FLASH_U2(x) \ 222 ( \ 223 (((x) & 0x00000f00) >> 4) + \ 224 (((x) & 0x00042000) << 1) + \ 225 (((x) & 0x0009c003) << 2) + \ 226 (((x) & 0x00021080) << 3) + \ 227 (((x) & 0x00000010) << 4) + \ 228 (((x) & 0x00000040) << 5) + \ 229 (((x) & 0x00000024) << 7) + \ 230 (((x) & 0x00000008) << 10) \ 231 ) 232 233/* Unmangle address (x) on chip U2 */ 234#define FLASH_U2_TO_ADDR(x) \ 235 ( \ 236 (((x) << 4) & 0x00000f00) + \ 237 (((x) >> 1) & 0x00042000) + \ 238 (((x) >> 2) & 0x0009c003) + \ 239 (((x) >> 3) & 0x00021080) + \ 240 (((x) >> 4) & 0x00000010) + \ 241 (((x) >> 5) & 0x00000040) + \ 242 (((x) >> 7) & 0x00000024) + \ 243 (((x) >> 10) & 0x00000008) \ 244 ) 245 246/* Mangle address (x) on chip U3 */ 247#define ADDR_TO_FLASH_U3(x) \ 248 ( \ 249 (((x) & 0x00000080) >> 3) + \ 250 (((x) & 0x00000040) >> 1) + \ 251 (((x) & 0x00052020) << 1) + \ 252 (((x) & 0x00084f03) << 2) + \ 253 (((x) & 0x00029010) << 3) + \ 254 (((x) & 0x00000008) << 5) + \ 255 (((x) & 0x00000004) << 7) \ 256 ) 257 258/* Unmangle address (x) on chip U3 */ 259#define FLASH_U3_TO_ADDR(x) \ 260 ( \ 261 (((x) << 3) & 0x00000080) + \ 262 (((x) << 1) & 0x00000040) + \ 263 (((x) >> 1) & 0x00052020) + \ 264 (((x) >> 2) & 0x00084f03) + \ 265 (((x) >> 3) & 0x00029010) + \ 266 (((x) >> 5) & 0x00000008) + \ 267 (((x) >> 7) & 0x00000004) \ 268 ) 269 270/***************************************************************************************************/ 271 272static __u8 read8 (__u32 offset) 273{ 274 volatile __u8 *data = (__u8 *) (FLASH_OFFSET + offset); 275#ifdef LART_DEBUG 276 printk (KERN_DEBUG "%s(): 0x%.8x -> 0x%.2x\n", __func__, offset, *data); 277#endif 278 return (*data); 279} 280 281static __u32 read32 (__u32 offset) 282{ 283 volatile __u32 *data = (__u32 *) (FLASH_OFFSET + offset); 284#ifdef LART_DEBUG 285 printk (KERN_DEBUG "%s(): 0x%.8x -> 0x%.8x\n", __func__, offset, *data); 286#endif 287 return (*data); 288} 289 290static void write32 (__u32 x,__u32 offset) 291{ 292 volatile __u32 *data = (__u32 *) (FLASH_OFFSET + offset); 293 *data = x; 294#ifdef LART_DEBUG 295 printk (KERN_DEBUG "%s(): 0x%.8x <- 0x%.8x\n", __func__, offset, *data); 296#endif 297} 298 299/***************************************************************************************************/ 300 301/* 302 * Probe for 16mbit flash memory on a LART board without doing 303 * too much damage. Since we need to write 1 dword to memory, 304 * we're f**cked if this happens to be DRAM since we can't 305 * restore the memory (otherwise we might exit Read Array mode). 306 * 307 * Returns 1 if we found 16mbit flash memory on LART, 0 otherwise. 308 */ 309static int flash_probe (void) 310{ 311 __u32 manufacturer,devtype; 312 313 /* setup "Read Identifier Codes" mode */ 314 write32 (DATA_TO_FLASH (READ_ID_CODES),0x00000000); 315 316 /* probe U2. U2/U3 returns the same data since the first 3 317 * address lines is mangled in the same way */ 318 manufacturer = FLASH_TO_DATA (read32 (ADDR_TO_FLASH_U2 (0x00000000))); 319 devtype = FLASH_TO_DATA (read32 (ADDR_TO_FLASH_U2 (0x00000001))); 320 321 /* put the flash back into command mode */ 322 write32 (DATA_TO_FLASH (READ_ARRAY),0x00000000); 323 324 return (manufacturer == FLASH_MANUFACTURER && (devtype == FLASH_DEVICE_16mbit_TOP || devtype == FLASH_DEVICE_16mbit_BOTTOM)); 325} 326 327/* 328 * Erase one block of flash memory at offset ``offset'' which is any 329 * address within the block which should be erased. 330 * 331 * Returns 1 if successful, 0 otherwise. 332 */ 333static inline int erase_block (__u32 offset) 334{ 335 __u32 status; 336 337#ifdef LART_DEBUG 338 printk (KERN_DEBUG "%s(): 0x%.8x\n", __func__, offset); 339#endif 340 341 /* erase and confirm */ 342 write32 (DATA_TO_FLASH (ERASE_SETUP),offset); 343 write32 (DATA_TO_FLASH (ERASE_CONFIRM),offset); 344 345 /* wait for block erase to finish */ 346 do 347 { 348 write32 (DATA_TO_FLASH (STATUS_READ),offset); 349 status = FLASH_TO_DATA (read32 (offset)); 350 } 351 while ((~status & STATUS_BUSY) != 0); 352 353 /* put the flash back into command mode */ 354 write32 (DATA_TO_FLASH (READ_ARRAY),offset); 355 356 /* was the erase successfull? */ 357 if ((status & STATUS_ERASE_ERR)) 358 { 359 printk (KERN_WARNING "%s: erase error at address 0x%.8x.\n",module_name,offset); 360 return (0); 361 } 362 363 return (1); 364} 365 366static int flash_erase (struct mtd_info *mtd,struct erase_info *instr) 367{ 368 __u32 addr,len; 369 int i,first; 370 371#ifdef LART_DEBUG 372 printk (KERN_DEBUG "%s(addr = 0x%.8x, len = %d)\n", __func__, instr->addr, instr->len); 373#endif 374 375 /* sanity checks */ 376 if (instr->addr + instr->len > mtd->size) return (-EINVAL); 377 378 /* 379 * check that both start and end of the requested erase are 380 * aligned with the erasesize at the appropriate addresses. 381 * 382 * skip all erase regions which are ended before the start of 383 * the requested erase. Actually, to save on the calculations, 384 * we skip to the first erase region which starts after the 385 * start of the requested erase, and then go back one. 386 */ 387 for (i = 0; i < mtd->numeraseregions && instr->addr >= mtd->eraseregions[i].offset; i++) ; 388 i--; 389 390 /* 391 * ok, now i is pointing at the erase region in which this 392 * erase request starts. Check the start of the requested 393 * erase range is aligned with the erase size which is in 394 * effect here. 395 */ 396 if (i < 0 || (instr->addr & (mtd->eraseregions[i].erasesize - 1))) 397 return -EINVAL; 398 399 /* Remember the erase region we start on */ 400 first = i; 401 402 /* 403 * next, check that the end of the requested erase is aligned 404 * with the erase region at that address. 405 * 406 * as before, drop back one to point at the region in which 407 * the address actually falls 408 */ 409 for (; i < mtd->numeraseregions && instr->addr + instr->len >= mtd->eraseregions[i].offset; i++) ; 410 i--; 411 412 /* is the end aligned on a block boundary? */ 413 if (i < 0 || ((instr->addr + instr->len) & (mtd->eraseregions[i].erasesize - 1))) 414 return -EINVAL; 415 416 addr = instr->addr; 417 len = instr->len; 418 419 i = first; 420 421 /* now erase those blocks */ 422 while (len) 423 { 424 if (!erase_block (addr)) 425 { 426 instr->state = MTD_ERASE_FAILED; 427 return (-EIO); 428 } 429 430 addr += mtd->eraseregions[i].erasesize; 431 len -= mtd->eraseregions[i].erasesize; 432 433 if (addr == mtd->eraseregions[i].offset + (mtd->eraseregions[i].erasesize * mtd->eraseregions[i].numblocks)) i++; 434 } 435 436 instr->state = MTD_ERASE_DONE; 437 mtd_erase_callback(instr); 438 439 return (0); 440} 441 442static int flash_read (struct mtd_info *mtd,loff_t from,size_t len,size_t *retlen,u_char *buf) 443{ 444#ifdef LART_DEBUG 445 printk (KERN_DEBUG "%s(from = 0x%.8x, len = %d)\n", __func__, (__u32)from, len); 446#endif 447 448 /* sanity checks */ 449 if (!len) return (0); 450 if (from + len > mtd->size) return (-EINVAL); 451 452 /* we always read len bytes */ 453 *retlen = len; 454 455 /* first, we read bytes until we reach a dword boundary */ 456 if (from & (BUSWIDTH - 1)) 457 { 458 int gap = BUSWIDTH - (from & (BUSWIDTH - 1)); 459 460 while (len && gap--) *buf++ = read8 (from++), len--; 461 } 462 463 /* now we read dwords until we reach a non-dword boundary */ 464 while (len >= BUSWIDTH) 465 { 466 *((__u32 *) buf) = read32 (from); 467 468 buf += BUSWIDTH; 469 from += BUSWIDTH; 470 len -= BUSWIDTH; 471 } 472 473 /* top up the last unaligned bytes */ 474 if (len & (BUSWIDTH - 1)) 475 while (len--) *buf++ = read8 (from++); 476 477 return (0); 478} 479 480/* 481 * Write one dword ``x'' to flash memory at offset ``offset''. ``offset'' 482 * must be 32 bits, i.e. it must be on a dword boundary. 483 * 484 * Returns 1 if successful, 0 otherwise. 485 */ 486static inline int write_dword (__u32 offset,__u32 x) 487{ 488 __u32 status; 489 490#ifdef LART_DEBUG 491 printk (KERN_DEBUG "%s(): 0x%.8x <- 0x%.8x\n", __func__, offset, x); 492#endif 493 494 /* setup writing */ 495 write32 (DATA_TO_FLASH (PGM_SETUP),offset); 496 497 /* write the data */ 498 write32 (x,offset); 499 500 /* wait for the write to finish */ 501 do 502 { 503 write32 (DATA_TO_FLASH (STATUS_READ),offset); 504 status = FLASH_TO_DATA (read32 (offset)); 505 } 506 while ((~status & STATUS_BUSY) != 0); 507 508 /* put the flash back into command mode */ 509 write32 (DATA_TO_FLASH (READ_ARRAY),offset); 510 511 /* was the write successfull? */ 512 if ((status & STATUS_PGM_ERR) || read32 (offset) != x) 513 { 514 printk (KERN_WARNING "%s: write error at address 0x%.8x.\n",module_name,offset); 515 return (0); 516 } 517 518 return (1); 519} 520 521static int flash_write (struct mtd_info *mtd,loff_t to,size_t len,size_t *retlen,const u_char *buf) 522{ 523 __u8 tmp[4]; 524 int i,n; 525 526#ifdef LART_DEBUG 527 printk (KERN_DEBUG "%s(to = 0x%.8x, len = %d)\n", __func__, (__u32)to, len); 528#endif 529 530 *retlen = 0; 531 532 /* sanity checks */ 533 if (!len) return (0); 534 if (to + len > mtd->size) return (-EINVAL); 535 536 /* first, we write a 0xFF.... padded byte until we reach a dword boundary */ 537 if (to & (BUSWIDTH - 1)) 538 { 539 __u32 aligned = to & ~(BUSWIDTH - 1); 540 int gap = to - aligned; 541 542 i = n = 0; 543 544 while (gap--) tmp[i++] = 0xFF; 545 while (len && i < BUSWIDTH) tmp[i++] = buf[n++], len--; 546 while (i < BUSWIDTH) tmp[i++] = 0xFF; 547 548 if (!write_dword (aligned,*((__u32 *) tmp))) return (-EIO); 549 550 to += n; 551 buf += n; 552 *retlen += n; 553 } 554 555 /* now we write dwords until we reach a non-dword boundary */ 556 while (len >= BUSWIDTH) 557 { 558 if (!write_dword (to,*((__u32 *) buf))) return (-EIO); 559 560 to += BUSWIDTH; 561 buf += BUSWIDTH; 562 *retlen += BUSWIDTH; 563 len -= BUSWIDTH; 564 } 565 566 /* top up the last unaligned bytes, padded with 0xFF.... */ 567 if (len & (BUSWIDTH - 1)) 568 { 569 i = n = 0; 570 571 while (len--) tmp[i++] = buf[n++]; 572 while (i < BUSWIDTH) tmp[i++] = 0xFF; 573 574 if (!write_dword (to,*((__u32 *) tmp))) return (-EIO); 575 576 *retlen += n; 577 } 578 579 return (0); 580} 581 582/***************************************************************************************************/ 583 584static struct mtd_info mtd; 585 586static struct mtd_erase_region_info erase_regions[] = { 587 /* parameter blocks */ 588 { 589 .offset = 0x00000000, 590 .erasesize = FLASH_BLOCKSIZE_PARAM, 591 .numblocks = FLASH_NUMBLOCKS_16m_PARAM, 592 }, 593 /* main blocks */ 594 { 595 .offset = FLASH_BLOCKSIZE_PARAM * FLASH_NUMBLOCKS_16m_PARAM, 596 .erasesize = FLASH_BLOCKSIZE_MAIN, 597 .numblocks = FLASH_NUMBLOCKS_16m_MAIN, 598 } 599}; 600 601#ifdef HAVE_PARTITIONS 602static struct mtd_partition lart_partitions[] = { 603 /* blob */ 604 { 605 .name = "blob", 606 .offset = BLOB_START, 607 .size = BLOB_LEN, 608 }, 609 /* kernel */ 610 { 611 .name = "kernel", 612 .offset = KERNEL_START, /* MTDPART_OFS_APPEND */ 613 .size = KERNEL_LEN, 614 }, 615 /* initial ramdisk / file system */ 616 { 617 .name = "file system", 618 .offset = INITRD_START, /* MTDPART_OFS_APPEND */ 619 .size = INITRD_LEN, /* MTDPART_SIZ_FULL */ 620 } 621}; 622#endif 623 624static int __init lart_flash_init (void) 625{ 626 int result; 627 memset (&mtd,0,sizeof (mtd)); 628 printk ("MTD driver for LART. Written by Abraham vd Merwe <abraham@2d3d.co.za>\n"); 629 printk ("%s: Probing for 28F160x3 flash on LART...\n",module_name); 630 if (!flash_probe ()) 631 { 632 printk (KERN_WARNING "%s: Found no LART compatible flash device\n",module_name); 633 return (-ENXIO); 634 } 635 printk ("%s: This looks like a LART board to me.\n",module_name); 636 mtd.name = module_name; 637 mtd.type = MTD_NORFLASH; 638 mtd.writesize = 1; 639 mtd.flags = MTD_CAP_NORFLASH; 640 mtd.size = FLASH_BLOCKSIZE_PARAM * FLASH_NUMBLOCKS_16m_PARAM + FLASH_BLOCKSIZE_MAIN * FLASH_NUMBLOCKS_16m_MAIN; 641 mtd.erasesize = FLASH_BLOCKSIZE_MAIN; 642 mtd.numeraseregions = ARRAY_SIZE(erase_regions); 643 mtd.eraseregions = erase_regions; 644 mtd.erase = flash_erase; 645 mtd.read = flash_read; 646 mtd.write = flash_write; 647 mtd.owner = THIS_MODULE; 648 649#ifdef LART_DEBUG 650 printk (KERN_DEBUG 651 "mtd.name = %s\n" 652 "mtd.size = 0x%.8x (%uM)\n" 653 "mtd.erasesize = 0x%.8x (%uK)\n" 654 "mtd.numeraseregions = %d\n", 655 mtd.name, 656 mtd.size,mtd.size / (1024*1024), 657 mtd.erasesize,mtd.erasesize / 1024, 658 mtd.numeraseregions); 659 660 if (mtd.numeraseregions) 661 for (result = 0; result < mtd.numeraseregions; result++) 662 printk (KERN_DEBUG 663 "\n\n" 664 "mtd.eraseregions[%d].offset = 0x%.8x\n" 665 "mtd.eraseregions[%d].erasesize = 0x%.8x (%uK)\n" 666 "mtd.eraseregions[%d].numblocks = %d\n", 667 result,mtd.eraseregions[result].offset, 668 result,mtd.eraseregions[result].erasesize,mtd.eraseregions[result].erasesize / 1024, 669 result,mtd.eraseregions[result].numblocks); 670 671#ifdef HAVE_PARTITIONS 672 printk ("\npartitions = %d\n", ARRAY_SIZE(lart_partitions)); 673 674 for (result = 0; result < ARRAY_SIZE(lart_partitions); result++) 675 printk (KERN_DEBUG 676 "\n\n" 677 "lart_partitions[%d].name = %s\n" 678 "lart_partitions[%d].offset = 0x%.8x\n" 679 "lart_partitions[%d].size = 0x%.8x (%uK)\n", 680 result,lart_partitions[result].name, 681 result,lart_partitions[result].offset, 682 result,lart_partitions[result].size,lart_partitions[result].size / 1024); 683#endif 684#endif 685 686#ifndef HAVE_PARTITIONS 687 result = add_mtd_device (&mtd); 688#else 689 result = add_mtd_partitions (&mtd,lart_partitions, ARRAY_SIZE(lart_partitions)); 690#endif 691 692 return (result); 693} 694 695static void __exit lart_flash_exit (void) 696{ 697#ifndef HAVE_PARTITIONS 698 del_mtd_device (&mtd); 699#else 700 del_mtd_partitions (&mtd); 701#endif 702} 703 704module_init (lart_flash_init); 705module_exit (lart_flash_exit); 706 707MODULE_LICENSE("GPL"); 708MODULE_AUTHOR("Abraham vd Merwe <abraham@2d3d.co.za>"); 709MODULE_DESCRIPTION("MTD driver for Intel 28F160F3 on LART board"); 710