cfi.c revision 1.1
1/* $NetBSD: cfi.c,v 1.1 2011/07/15 19:19:57 cliff Exp $ */ 2 3#include "opt_nor.h" 4#include "opt_flash.h" 5 6#include <sys/cdefs.h> 7__KERNEL_RCSID(0, "$NetBSD: cfi.c,v 1.1 2011/07/15 19:19:57 cliff Exp $"); 8 9#include <sys/param.h> 10#include <sys/systm.h> 11#include <sys/cdefs.h> 12#include <sys/device.h> 13#include <sys/endian.h> 14 15#include <machine/bus.h> 16 17#include <dev/nor/nor.h> 18#include <dev/nor/cfi.h> 19#include <dev/nor/cfi_0002.h> 20 21 22static bool cfi_chip_query(struct cfi * const); 23static int cfi_scan_media(device_t self, struct nor_chip *chip); 24static void cfi_init(device_t); 25static void cfi_select(device_t, bool); 26static void cfi_read_1(device_t, flash_off_t, uint8_t *); 27static void cfi_read_2(device_t, flash_off_t, uint16_t *); 28static void cfi_read_4(device_t, flash_off_t, uint32_t *); 29static void cfi_read_buf_1(device_t, flash_off_t, uint8_t *, size_t); 30static void cfi_read_buf_2(device_t, flash_off_t, uint16_t *, size_t); 31static void cfi_read_buf_4(device_t, flash_off_t, uint32_t *, size_t); 32static void cfi_write_1(device_t, flash_off_t, uint8_t); 33static void cfi_write_2(device_t, flash_off_t, uint16_t); 34static void cfi_write_4(device_t, flash_off_t, uint32_t); 35static void cfi_write_buf_1(device_t, flash_off_t, const uint8_t *, size_t); 36static void cfi_write_buf_2(device_t, flash_off_t, const uint16_t *, size_t); 37static void cfi_write_buf_4(device_t, flash_off_t, const uint32_t *, size_t); 38static bool cfi_jedec_id(struct cfi * const); 39 40 41/* 42 * NOTE these opmode tables are informed by "Table 1. CFI Query Read" 43 * in Intel "Common Flash Interface (CFI) and Command Sets" 44 * Application Note 646, April 2000 45 * 46 * The byte ordering of the signature string here varies from that table 47 * because of discrepancy in observed behavior, for the case: 48 * - x16 device operating in 16-bit mode 49 * Similar discrepancy is expected (but not verified) for the case: 50 * - x32 device operating in 32-bit mode 51 * so the ordering is changed here for that case also. 52 * 53 * XXX down-sized, interleaved & multi-chip opmodes not yet supported 54 */ 55 56/* 1-byte access */ 57static const struct cfi_opmodes cfi_opmodes_1[] = { 58 { 0, 0, 0, 0x10, 3, "QRY", "x8 device operating in 8-bit mode" }, 59}; 60 61/* 2-byte access */ 62static const struct cfi_opmodes cfi_opmodes_2[] = { 63 { 1, 1, 0, 0x20, 6, "\0Q\0R\0Y", 64 "x16 device operating in 16-bit mode" }, 65}; 66 67/* 4-byte access */ 68static const struct cfi_opmodes cfi_opmodes_4[] = { 69 { 2, 2, 0, 0x40, 12, "\0\0\0Q\0\0\0R\0\0\0Y", 70 "x32 device operating in 32-bit mode" }, 71}; 72 73 74const struct nor_interface nor_interface_cfi = { 75 .scan_media = cfi_scan_media, 76 .init = cfi_init, 77 .select = cfi_select, 78 .read_1 = cfi_read_1, 79 .read_2 = cfi_read_2, 80 .read_4 = cfi_read_4, 81 .read_buf_1 = cfi_read_buf_1, 82 .read_buf_2 = cfi_read_buf_2, 83 .read_buf_4 = cfi_read_buf_4, 84 .write_1 = cfi_write_1, 85 .write_2 = cfi_write_2, 86 .write_4 = cfi_write_4, 87 .write_buf_1 = cfi_write_buf_1, 88 .write_buf_2 = cfi_write_buf_2, 89 .write_buf_4 = cfi_write_buf_4, 90 .read_page = NULL, /* cmdset */ 91 .program_page = NULL, /* cmdset */ 92 .busy = NULL, 93 .private = NULL, 94 .access_width = -1, 95 .part_info = NULL, 96 .part_num = -1, 97}; 98 99 100/* only data[7..0] are used regardless of chip width */ 101#define cfi_unpack_1(n) ((n) & 0xff) 102 103/* construct (arbitrarily big endian) uint16_t */ 104#define cfi_unpack_2(b0, b1) \ 105 ((cfi_unpack_1(b1) << 8) | cfi_unpack_1(b0)) 106 107/* construct (arbitrarily) big endian uint32_t */ 108#define cfi_unpack_4(b0, b1, b2, b3) \ 109 ((cfi_unpack_1(b3) << 24) | \ 110 (cfi_unpack_1(b2) << 16) | \ 111 (cfi_unpack_1(b1) << 8) | \ 112 (cfi_unpack_1(b0))) 113 114#define cfi_unpack_qry(qryp, data) \ 115 do { \ 116 (qryp)->qry[0] = cfi_unpack_1(data[0x10]); \ 117 (qryp)->qry[1] = cfi_unpack_1(data[0x11]); \ 118 (qryp)->qry[2] = cfi_unpack_1(data[0x12]); \ 119 (qryp)->id_pri = be16toh(cfi_unpack_2(data[0x13], data[0x14])); \ 120 (qryp)->addr_pri = \ 121 be16toh(cfi_unpack_2(data[0x15], data[0x16])); \ 122 (qryp)->id_alt = be16toh(cfi_unpack_2(data[0x17], data[0x18])); \ 123 (qryp)->addr_alt = \ 124 be16toh(cfi_unpack_2(data[0x19], data[0x1a])); \ 125 (qryp)->vcc_min = cfi_unpack_1(data[0x1b]); \ 126 (qryp)->vcc_max = cfi_unpack_1(data[0x1c]); \ 127 (qryp)->vpp_min = cfi_unpack_1(data[0x1d]); \ 128 (qryp)->vpp_max = cfi_unpack_1(data[0x1e]); \ 129 (qryp)->write_word_time_typ = cfi_unpack_1(data[0x1f]); \ 130 (qryp)->write_nbyte_time_typ = cfi_unpack_1(data[0x20]); \ 131 (qryp)->erase_blk_time_typ = cfi_unpack_1(data[0x21]); \ 132 (qryp)->erase_chiptime_typ = cfi_unpack_1(data[0x22]); \ 133 (qryp)->write_word_time_max = cfi_unpack_1(data[0x23]); \ 134 (qryp)->write_nbyte_time_max = cfi_unpack_1(data[0x24]); \ 135 (qryp)->erase_blk_time_max = cfi_unpack_1(data[0x25]); \ 136 (qryp)->erase_chiptime_max = cfi_unpack_1(data[0x26]); \ 137 (qryp)->device_size = cfi_unpack_1(data[0x27]); \ 138 (qryp)->interface_code_desc = \ 139 be16toh(cfi_unpack_2(data[0x28], data[0x29])); \ 140 (qryp)->write_nbyte_size_max = \ 141 be16toh(cfi_unpack_2(data[0x2a], data[0x2b])); \ 142 (qryp)->erase_blk_regions = cfi_unpack_1(data[0x2c]); \ 143 u_int _i = 0x2d; \ 144 const u_int _n = (qryp)->erase_blk_regions; \ 145 KASSERT(_n <= 4); \ 146 for (u_int _r = 0; _r < _n; _r++, _i+=4) { \ 147 (qryp)->erase_blk_info[_r].y = \ 148 be32toh(cfi_unpack_2(data[_i+0], data[_i+1])); \ 149 (qryp)->erase_blk_info[_r].z = \ 150 be32toh(cfi_unpack_2(data[_i+2], data[_i+3])); \ 151 } \ 152 } while (0) 153 154#define cfi_unpack_pri_0002(qryp, data) \ 155 do { \ 156 (qryp)->pri.cmd_0002.pri[0] = cfi_unpack_1(data[0x00]); \ 157 (qryp)->pri.cmd_0002.pri[1] = cfi_unpack_1(data[0x01]); \ 158 (qryp)->pri.cmd_0002.pri[2] = cfi_unpack_1(data[0x02]); \ 159 (qryp)->pri.cmd_0002.version_maj = cfi_unpack_1(data[0x03]); \ 160 (qryp)->pri.cmd_0002.version_min = cfi_unpack_1(data[0x04]); \ 161 (qryp)->pri.cmd_0002.asupt = cfi_unpack_1(data[0x05]); \ 162 (qryp)->pri.cmd_0002.erase_susp = cfi_unpack_1(data[0x06]); \ 163 (qryp)->pri.cmd_0002.sector_prot = cfi_unpack_1(data[0x07]); \ 164 (qryp)->pri.cmd_0002.tmp_sector_unprot = \ 165 cfi_unpack_1(data[0x08]); \ 166 (qryp)->pri.cmd_0002.sector_prot_scheme = \ 167 cfi_unpack_1(data[0x09]); \ 168 (qryp)->pri.cmd_0002.simul_op = cfi_unpack_1(data[0x0a]); \ 169 (qryp)->pri.cmd_0002.burst_mode_type = cfi_unpack_1(data[0x0b]);\ 170 (qryp)->pri.cmd_0002.page_mode_type = cfi_unpack_1(data[0x0c]); \ 171 (qryp)->pri.cmd_0002.acc_min = cfi_unpack_1(data[0x0d]); \ 172 (qryp)->pri.cmd_0002.acc_max = cfi_unpack_1(data[0x0e]); \ 173 (qryp)->pri.cmd_0002.wp_prot = cfi_unpack_1(data[0x0f]); \ 174 /* XXX 1.3 stops here */ \ 175 (qryp)->pri.cmd_0002.prog_susp = cfi_unpack_1(data[0x10]); \ 176 (qryp)->pri.cmd_0002.unlock_bypass = cfi_unpack_1(data[0x11]); \ 177 (qryp)->pri.cmd_0002.sss_size = cfi_unpack_1(data[0x12]); \ 178 (qryp)->pri.cmd_0002.soft_feat = cfi_unpack_1(data[0x13]); \ 179 (qryp)->pri.cmd_0002.page_size = cfi_unpack_1(data[0x14]); \ 180 (qryp)->pri.cmd_0002.erase_susp_time_max = \ 181 cfi_unpack_1(data[0x15]); \ 182 (qryp)->pri.cmd_0002.prog_susp_time_max = \ 183 cfi_unpack_1(data[0x16]); \ 184 (qryp)->pri.cmd_0002.embhwrst_time_max = \ 185 cfi_unpack_1(data[0x38]); \ 186 (qryp)->pri.cmd_0002.hwrst_time_max = \ 187 cfi_unpack_1(data[0x39]); \ 188 } while (0) 189 190#define CFI_QRY_UNPACK_COMMON(cfi, data, type, found) \ 191 do { \ 192 struct cfi_query_data * const qryp = &cfi->cfi_qry_data; \ 193 \ 194 memset(qryp, 0, sizeof(*qryp)); \ 195 cfi_unpack_qry(qryp, data); \ 196 \ 197 switch (qryp->id_pri) { \ 198 case 0x0002: \ 199 if ((cfi_unpack_1(data[qryp->addr_pri + 0]) == 'P') && \ 200 (cfi_unpack_1(data[qryp->addr_pri + 1]) == 'R') && \ 201 (cfi_unpack_1(data[qryp->addr_pri + 2]) == 'I')) { \ 202 type *pri_data = &data[qryp->addr_pri]; \ 203 cfi_unpack_pri_0002(qryp, pri_data); \ 204 found = true; \ 205 break; \ 206 } \ 207 default: \ 208 printf("%s: unsupported id_pri=%#x\n", \ 209 __func__, qryp->id_pri); \ 210 break; /* unknown command set */ \ 211 } \ 212 } while (0) 213 214/* 215 * cfi_chip_query_opmode - determine operational mode based on QRY signature 216 */ 217static bool 218cfi_chip_query_opmode(struct cfi *cfi, uint8_t *data, 219 const struct cfi_opmodes *tab, u_int nentries) 220{ 221 for (u_int i=0; i < nentries; i++) { 222 if (memcmp(&data[tab[i].qsa], tab[i].sig, tab[i].len) == 0) { 223 cfi->cfi_opmode = &tab[i]; 224 return true; 225 } 226 } 227 return false; 228} 229 230static bool 231cfi_chip_query_1(struct cfi * const cfi) 232{ 233 uint8_t data[0x80]; 234 235 bus_space_read_region_1(cfi->cfi_bst, cfi->cfi_bsh, 0, data, 236 __arraycount(data)); 237 238 bool found = cfi_chip_query_opmode(cfi, data, cfi_opmodes_1, 239 __arraycount(cfi_opmodes_1)); 240 241 if (found) { 242 CFI_QRY_UNPACK_COMMON(cfi, data, uint8_t, found); 243 } 244 245 return found; 246} 247 248static bool 249cfi_chip_query_2(struct cfi * const cfi) 250{ 251 uint16_t data[0x80]; 252 253 bus_space_read_region_2(cfi->cfi_bst, cfi->cfi_bsh, 0, data, 254 __arraycount(data)); 255 256 bool found = cfi_chip_query_opmode(cfi, (uint8_t *)data, 257 cfi_opmodes_2, __arraycount(cfi_opmodes_2)); 258 259 if (found) { 260 CFI_QRY_UNPACK_COMMON(cfi, data, uint16_t, found); 261 } 262 263 return found; 264} 265 266static bool 267cfi_chip_query_4(struct cfi * const cfi) 268{ 269 uint32_t data[0x80]; 270 271 bus_space_read_region_4(cfi->cfi_bst, cfi->cfi_bsh, 0, data, 272 __arraycount(data)); 273 274 bool found = cfi_chip_query_opmode(cfi, (uint8_t *)data, 275 cfi_opmodes_4, __arraycount(cfi_opmodes_4)); 276 277 if (found) { 278 CFI_QRY_UNPACK_COMMON(cfi, data, uint32_t, found); 279 } 280 281 return found; 282} 283 284static bool 285cfi_chip_query_8(struct cfi * const cfi) 286{ 287#ifdef NOTYET 288 uint64_t data[0x80]; 289 290 bus_space_read_region_8(cfi->cfi_bst, cfi->cfi_bsh, 0, data, 291 __arraycount(data)); 292 293 bool found = cfi_chip_query_opmode(cfi, (uint8_t *)data, 294 cfi_opmodes_8, __arraycount(cfi_opmodes_8)); 295 296 if (found) { 297 CFI_QRY_UNPACK_COMMON(cfi, data, uint64_t, found); 298 } 299 300 return found; 301#else 302 return false; 303#endif 304} 305 306/* 307 * cfi_chip_query - detect a CFI chip 308 * 309 * fill in the struct cfi as we discover what's there 310 */ 311static bool 312cfi_chip_query(struct cfi * const cfi) 313{ 314 bool found = false; 315 const bus_size_t cfi_query_offset[] = { 316 CFI_QUERY_MODE_ADDRESS, 317 CFI_QUERY_MODE_ALT_ADDRESS 318 }; 319 320 KASSERT(cfi != NULL); 321 KASSERT(cfi->cfi_bst != NULL); 322 323 for (int j=0; !found && j < __arraycount(cfi_query_offset); j++) { 324 325 cfi_reset_default(cfi); 326 cfi_cmd(cfi, cfi_query_offset[j], CFI_QUERY_DATA); 327 328 switch(cfi->cfi_portwidth) { 329 case 0: 330 found = cfi_chip_query_1(cfi); 331 break; 332 case 1: 333 found = cfi_chip_query_2(cfi); 334 break; 335 case 2: 336 found = cfi_chip_query_4(cfi); 337 break; 338 case 3: 339 found = cfi_chip_query_8(cfi); 340 break; 341 default: 342 panic("%s: bad portwidth %d\n", 343 __func__, cfi->cfi_portwidth); 344 } 345 } 346 347 return found; 348} 349 350/* 351 * cfi_probe - search for a CFI NOR trying various port & chip widths 352 * 353 * NOTE: 354 * striped NOR chips design not supported yet, 355 * so force portwidth=chipwidth for now 356 * eventually permute portwidth seperately 357 */ 358bool 359cfi_probe(struct cfi * const cfi) 360{ 361 bool found; 362 363 KASSERT(cfi != NULL); 364 365 for (u_int cw = 0; cw < 3; cw++) { 366 cfi->cfi_portwidth = /* XXX */ 367 cfi->cfi_chipwidth = cw; 368 found = cfi_chip_query(cfi); 369 if (found) 370 goto out; 371 } 372 out: 373 cfi_reset_default(cfi); /* exit QRY mode */ 374 return found; 375} 376 377bool 378cfi_identify(struct cfi * const cfi) 379{ 380 const bus_space_tag_t bst = cfi->cfi_bst; 381 const bus_space_handle_t bsh = cfi->cfi_bsh; 382 bool found = true; 383 384 KASSERT(cfi != NULL); 385 KASSERT(bst != NULL); 386 387 memset(cfi, 0, sizeof(struct cfi)); /* XXX clean slate */ 388 cfi->cfi_bst = bst; /* restore bus space */ 389 cfi->cfi_bsh = bsh; /* " " " */ 390 391 /* gather CFI PRQ and PRI data */ 392 if (! cfi_probe(cfi)) { 393 aprint_debug("%s: cfi_probe failed\n", __func__); 394 found = false; 395 goto out; 396 } 397 398 /* gather ID data if possible */ 399 if (! cfi_jedec_id(cfi)) { 400 aprint_debug("%s: cfi_jedec_id failed\n", __func__); 401 goto out; 402 } 403 404 out: 405 cfi_reset_default(cfi); /* exit QRY mode */ 406 407 return found; 408} 409 410static int 411cfi_scan_media(device_t self, struct nor_chip *chip) 412{ 413 struct nor_softc *sc = device_private(self); 414 KASSERT(sc != NULL); 415 KASSERT(sc->sc_nor_if != NULL); 416 struct cfi * const cfi = (struct cfi * const)sc->sc_nor_if->private; 417 KASSERT(cfi != NULL); 418 419 sc->sc_nor_if->access_width = cfi->cfi_portwidth; 420 421 chip->nc_manf_id = cfi->cfi_id_data.id_mid; 422 chip->nc_dev_id = cfi->cfi_id_data.id_did[0]; /* XXX 3 words */ 423 chip->nc_size = 1 << cfi->cfi_qry_data.device_size; 424 425 /* size of line for Read Buf command */ 426 chip->nc_line_size = 1 << cfi->cfi_qry_data.pri.cmd_0002.page_size; 427 428 /* 429 * size of erase block 430 * XXX depends on erase region 431 */ 432 chip->nc_num_luns = 1; 433 chip->nc_lun_blocks = cfi->cfi_qry_data.erase_blk_info[0].y + 1; 434 chip->nc_block_size = cfi->cfi_qry_data.erase_blk_info[0].z * 256; 435 436 switch (cfi->cfi_qry_data.id_pri) { 437 case 0x0002: 438 cfi_0002_init(sc, cfi, chip); 439 break; 440 default: 441 return -1; 442 } 443 444 return 0; 445} 446 447void 448cfi_init(device_t self) 449{ 450 /* nothing */ 451} 452 453static void 454cfi_select(device_t self, bool select) 455{ 456 /* nothing */ 457} 458 459static void 460cfi_read_1(device_t self, flash_off_t offset, uint8_t *datap) 461{ 462} 463 464static void 465cfi_read_2(device_t self, flash_off_t offset, uint16_t *datap) 466{ 467} 468 469static void 470cfi_read_4(device_t self, flash_off_t offset, uint32_t *datap) 471{ 472} 473 474static void 475cfi_read_buf_1(device_t self, flash_off_t offset, uint8_t *datap, size_t size) 476{ 477} 478 479static void 480cfi_read_buf_2(device_t self, flash_off_t offset, uint16_t *datap, size_t size) 481{ 482} 483 484static void 485cfi_read_buf_4(device_t self, flash_off_t offset, uint32_t *datap, size_t size) 486{ 487} 488 489static void 490cfi_write_1(device_t self, flash_off_t offset, uint8_t data) 491{ 492} 493 494static void 495cfi_write_2(device_t self, flash_off_t offset, uint16_t data) 496{ 497} 498 499static void 500cfi_write_4(device_t self, flash_off_t offset, uint32_t data) 501{ 502} 503 504static void 505cfi_write_buf_1(device_t self, flash_off_t offset, const uint8_t *datap, 506 size_t size) 507{ 508} 509 510static void 511cfi_write_buf_2(device_t self, flash_off_t offset, const uint16_t *datap, 512 size_t size) 513{ 514} 515 516static void 517cfi_write_buf_4(device_t self, flash_off_t offset, const uint32_t *datap, 518 size_t size) 519{ 520} 521 522void 523cfi_cmd(struct cfi * const cfi, bus_size_t off, uint32_t val) 524{ 525 const bus_space_tag_t bst = cfi->cfi_bst; 526 bus_space_handle_t bsh = cfi->cfi_bsh; 527 528 off <<= cfi->cfi_portwidth; 529 530 DPRINTF(("%s: %p %x %x %x\n", __func__, bst, bsh, off, val)); 531 532 switch(cfi->cfi_portwidth) { 533 case 0: 534 bus_space_write_1(bst, bsh, off, (uint8_t)val); 535 break; 536 case 1: 537 bus_space_write_2(bst, bsh, off, val); 538 break; 539 case 2: 540 bus_space_write_4(bst, bsh, off, (uint32_t)val); 541 break; 542#ifdef NOTYET 543 case 3: 544 bus_space_write_4(bst, bsh, off, (uint64_t)val); 545 break; 546#endif 547 default: 548 panic("%s: bad portwidth %d bytes\n", 549 __func__, 1 << cfi->cfi_portwidth); 550 } 551} 552 553/* 554 * cfi_reset_default - when we don't know which command will work, use both 555 */ 556void 557cfi_reset_default(struct cfi * const cfi) 558{ 559 cfi_cmd(cfi, CFI_ADDRESS_ANY, CFI_RESET_DATA); 560 cfi_cmd(cfi, CFI_ADDRESS_ANY, CFI_ALT_RESET_DATA); 561} 562 563/* 564 * cfi_reset_std - use standard reset command 565 */ 566void 567cfi_reset_std(struct cfi * const cfi) 568{ 569 cfi_cmd(cfi, CFI_ADDRESS_ANY, CFI_RESET_DATA); 570} 571 572/* 573 * cfi_reset_alt - use "alternate" reset command 574 */ 575void 576cfi_reset_alt(struct cfi * const cfi) 577{ 578 cfi_cmd(cfi, CFI_ADDRESS_ANY, CFI_ALT_RESET_DATA); 579} 580 581static void 582cfi_jedec_id_2(struct cfi * const cfi) 583{ 584 struct cfi_jedec_id_data *idp = &cfi->cfi_id_data; 585 uint16_t data[0x10]; 586 587 bus_space_read_region_2(cfi->cfi_bst, cfi->cfi_bsh, 0, data, 588 __arraycount(data)); 589 590 idp->id_mid = data[0]; 591 idp->id_did[0] = data[1]; 592 idp->id_did[1] = data[0xe]; 593 idp->id_did[2] = data[0xf]; 594 idp->id_prot_state = data[2]; 595 idp->id_indicators = data[3]; 596 597 /* software bits, upper and lower 598 * - undefined on S29GL-P 599 * - defined on S29GL-S 600 */ 601 idp->id_swb_lo = data[0xc]; 602 idp->id_swb_hi = data[0xd]; 603} 604 605/* 606 * cfi_jedec_id - get JEDEC ID info 607 * 608 * this should be ignored altogether for CFI chips? 609 * JEDEC ID is superceded by CFI info except CFI is not 610 * a true superset of the JEDEC, so some info provided 611 * by JEDEC is not available via CFI QRY. 612 * But the JEDEC info is unreliable: 613 * - different chips not distinguishaable by IDs 614 * - some fields undefined (read as 0xff) on some chips 615 */ 616static bool 617cfi_jedec_id(struct cfi * const cfi) 618{ 619 DPRINTF(("%s\n", __func__)); 620 621 cfi_cmd(cfi, 0x555, 0xaa); 622 cfi_cmd(cfi, 0x2aa, 0x55); 623 cfi_cmd(cfi, 0x555, 0x90); 624 625 switch(cfi->cfi_portwidth) { 626 case 1: 627 cfi_jedec_id_2(cfi); 628 break; 629#ifdef NOTYET 630 case 0: 631 cfi_jedec_id_1(cfi); 632 break; 633 case 2: 634 cfi_jedec_id_4(cfi); 635 break; 636 case 3: 637 cfi_jedec_id_8(cfi); 638 break; 639#endif 640 default: 641 panic("%s: bad portwidth %d bytes\n", 642 __func__, 1 << cfi->cfi_portwidth); 643 } 644 645 return true; 646} 647 648void 649cfi_print(device_t self, struct cfi * const cfi) 650{ 651 char pbuf[sizeof("XXXX MB")]; 652 struct cfi_query_data * const qryp = &cfi->cfi_qry_data; 653 654 format_bytes(pbuf, sizeof(pbuf), 1 << qryp->device_size); 655 aprint_normal_dev(self, "CFI NOR flash %s %s\n", pbuf, 656 cfi_interface_desc_str(qryp->interface_code_desc)); 657#ifdef NOR_VERBOSE 658 aprint_normal_dev(self, "manufacturer id %#x, device id %#x %#x %#x\n", 659 cfi->cfi_id_data.id_mid, 660 cfi->cfi_id_data.id_did[0], 661 cfi->cfi_id_data.id_did[1], 662 cfi->cfi_id_data.id_did[2]); 663 aprint_normal_dev(self, "%s\n", cfi->cfi_opmode->str); 664 aprint_normal_dev(self, "sw bits lo=%#x hi=%#x\n", 665 cfi->cfi_id_data.id_swb_lo, 666 cfi->cfi_id_data.id_swb_hi); 667 aprint_normal_dev(self, "max multibyte write size %d\n", 668 1 << qryp->write_nbyte_size_max); 669 aprint_normal_dev(self, "%d Erase Block Region(s)\n", 670 qryp->erase_blk_regions); 671 for (u_int r=0; r < qryp->erase_blk_regions; r++) { 672 size_t sz = qryp->erase_blk_info[r].z * 256; 673 format_bytes(pbuf, sizeof(pbuf), sz); 674 aprint_normal(" %d: %d blocks, size %s\n", r, 675 qryp->erase_blk_info[r].y + 1, pbuf); 676 } 677#endif 678 679 switch (cfi->cfi_qry_data.id_pri) { 680 case 0x0002: 681 cfi_0002_print(self, cfi); 682 break; 683 } 684} 685