Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
David Woodhouse | 5522 | 39.52% | 9 | 9.57% |
Christian Riesch | 1873 | 13.40% | 5 | 5.32% |
Todd Android Poynor | 1053 | 7.54% | 2 | 2.13% |
Stefan Roese | 982 | 7.03% | 1 | 1.06% |
Ira W. Snyder | 975 | 6.98% | 1 | 1.06% |
Håvard Skinnemoen | 676 | 4.84% | 5 | 5.32% |
Linus Torvalds (pre-git) | 508 | 3.64% | 2 | 2.13% |
Guillaume LECERF | 501 | 3.59% | 11 | 11.70% |
Linus Torvalds | 325 | 2.33% | 4 | 4.26% |
Kevin Cernekee | 238 | 1.70% | 1 | 1.06% |
Trent Piepho | 161 | 1.15% | 1 | 1.06% |
Gerlando Falauto | 151 | 1.08% | 1 | 1.06% |
Eric W. Biedermann | 125 | 0.89% | 1 | 1.06% |
Stefani Seibold | 112 | 0.80% | 1 | 1.06% |
Christopher Moore | 95 | 0.68% | 1 | 1.06% |
Bean Huo | 82 | 0.59% | 1 | 1.06% |
Joakim Tjernlund | 82 | 0.59% | 6 | 6.38% |
Tokunori Ikegami | 76 | 0.54% | 5 | 5.32% |
Harald Nordgard-Hansen | 59 | 0.42% | 1 | 1.06% |
Javier Martin | 56 | 0.40% | 1 | 1.06% |
Wolfgang Grandegger | 44 | 0.31% | 1 | 1.06% |
Konstantin Baydarov | 36 | 0.26% | 1 | 1.06% |
Brian Norris | 32 | 0.23% | 3 | 3.19% |
Vijay Sampath | 26 | 0.19% | 1 | 1.06% |
Anatolij Gustschin | 25 | 0.18% | 2 | 2.13% |
Hans-Christian Noren Egtvedt | 25 | 0.18% | 1 | 1.06% |
Paul Parsons | 20 | 0.14% | 1 | 1.06% |
Artem B. Bityutskiy | 19 | 0.14% | 2 | 2.13% |
Ryan Jackson | 10 | 0.07% | 1 | 1.06% |
Steffen Sledz | 8 | 0.06% | 1 | 1.06% |
Wolfram Sang | 8 | 0.06% | 1 | 1.06% |
Art Haas | 8 | 0.06% | 1 | 1.06% |
Kees Cook | 7 | 0.05% | 2 | 2.13% |
Thomas Gleixner | 7 | 0.05% | 2 | 2.13% |
Boris Brezillon | 7 | 0.05% | 1 | 1.06% |
Paulius Zaleckas | 6 | 0.04% | 1 | 1.06% |
Dmitry Adamushko | 5 | 0.04% | 1 | 1.06% |
Adrian Hunter | 4 | 0.03% | 1 | 1.06% |
Joe Perches | 4 | 0.03% | 1 | 1.06% |
Huang Shijie | 3 | 0.02% | 1 | 1.06% |
Tadashi Abe | 3 | 0.02% | 1 | 1.06% |
Lucas De Marchi | 3 | 0.02% | 1 | 1.06% |
David Vrabel | 3 | 0.02% | 1 | 1.06% |
Fabian Frederick | 3 | 0.02% | 1 | 1.06% |
Gernot Hoyler | 2 | 0.01% | 1 | 1.06% |
Ben Dooks | 1 | 0.01% | 1 | 1.06% |
Justin Treon | 1 | 0.01% | 1 | 1.06% |
Burman Yan | 1 | 0.01% | 1 | 1.06% |
Total | 13973 | 94 |
/* * Common Flash Interface support: * AMD & Fujitsu Standard Vendor Command Set (ID 0x0002) * * Copyright (C) 2000 Crossnet Co. <info@crossnet.co.jp> * Copyright (C) 2004 Arcom Control Systems Ltd <linux@arcom.com> * Copyright (C) 2005 MontaVista Software Inc. <source@mvista.com> * * 2_by_8 routines added by Simon Munton * * 4_by_16 work by Carolyn J. Smith * * XIP support hooks by Vitaly Wool (based on code for Intel flash * by Nicolas Pitre) * * 25/09/2008 Christopher Moore: TopBottom fixup for many Macronix with CFI V1.0 * * Occasionally maintained by Thayne Harbaugh tharbaugh at lnxi dot com * * This code is GPL */ #include <linux/module.h> #include <linux/types.h> #include <linux/kernel.h> #include <linux/sched.h> #include <asm/io.h> #include <asm/byteorder.h> #include <linux/errno.h> #include <linux/slab.h> #include <linux/delay.h> #include <linux/interrupt.h> #include <linux/reboot.h> #include <linux/of.h> #include <linux/of_platform.h> #include <linux/mtd/map.h> #include <linux/mtd/mtd.h> #include <linux/mtd/cfi.h> #include <linux/mtd/xip.h> #define AMD_BOOTLOC_BUG #define FORCE_WORD_WRITE 0 #define MAX_RETRIES 3 #define SST49LF004B 0x0060 #define SST49LF040B 0x0050 #define SST49LF008A 0x005a #define AT49BV6416 0x00d6 static int cfi_amdstd_read (struct mtd_info *, loff_t, size_t, size_t *, u_char *); static int cfi_amdstd_write_words(struct mtd_info *, loff_t, size_t, size_t *, const u_char *); static int cfi_amdstd_write_buffers(struct mtd_info *, loff_t, size_t, size_t *, const u_char *); static int cfi_amdstd_erase_chip(struct mtd_info *, struct erase_info *); static int cfi_amdstd_erase_varsize(struct mtd_info *, struct erase_info *); static void cfi_amdstd_sync (struct mtd_info *); static int cfi_amdstd_suspend (struct mtd_info *); static void cfi_amdstd_resume (struct mtd_info *); static int cfi_amdstd_reboot(struct notifier_block *, unsigned long, void *); static int cfi_amdstd_get_fact_prot_info(struct mtd_info *, size_t, size_t *, struct otp_info *); static int cfi_amdstd_get_user_prot_info(struct mtd_info *, size_t, size_t *, struct otp_info *); static int cfi_amdstd_secsi_read (struct mtd_info *, loff_t, size_t, size_t *, u_char *); static int cfi_amdstd_read_fact_prot_reg(struct mtd_info *, loff_t, size_t, size_t *, u_char *); static int cfi_amdstd_read_user_prot_reg(struct mtd_info *, loff_t, size_t, size_t *, u_char *); static int cfi_amdstd_write_user_prot_reg(struct mtd_info *, loff_t, size_t, size_t *, u_char *); static int cfi_amdstd_lock_user_prot_reg(struct mtd_info *, loff_t, size_t); static int cfi_amdstd_panic_write(struct mtd_info *mtd, loff_t to, size_t len, size_t *retlen, const u_char *buf); static void cfi_amdstd_destroy(struct mtd_info *); struct mtd_info *cfi_cmdset_0002(struct map_info *, int); static struct mtd_info *cfi_amdstd_setup (struct mtd_info *); static int get_chip(struct map_info *map, struct flchip *chip, unsigned long adr, int mode); static void put_chip(struct map_info *map, struct flchip *chip, unsigned long adr); #include "fwh_lock.h" static int cfi_atmel_lock(struct mtd_info *mtd, loff_t ofs, uint64_t len); static int cfi_atmel_unlock(struct mtd_info *mtd, loff_t ofs, uint64_t len); static int cfi_ppb_lock(struct mtd_info *mtd, loff_t ofs, uint64_t len); static int cfi_ppb_unlock(struct mtd_info *mtd, loff_t ofs, uint64_t len); static int cfi_ppb_is_locked(struct mtd_info *mtd, loff_t ofs, uint64_t len); static struct mtd_chip_driver cfi_amdstd_chipdrv = { .probe = NULL, /* Not usable directly */ .destroy = cfi_amdstd_destroy, .name = "cfi_cmdset_0002", .module = THIS_MODULE }; /* #define DEBUG_CFI_FEATURES */ #ifdef DEBUG_CFI_FEATURES static void cfi_tell_features(struct cfi_pri_amdstd *extp) { const char* erase_suspend[3] = { "Not supported", "Read only", "Read/write" }; const char* top_bottom[6] = { "No WP", "8x8KiB sectors at top & bottom, no WP", "Bottom boot", "Top boot", "Uniform, Bottom WP", "Uniform, Top WP" }; printk(" Silicon revision: %d\n", extp->SiliconRevision >> 1); printk(" Address sensitive unlock: %s\n", (extp->SiliconRevision & 1) ? "Not required" : "Required"); if (extp->EraseSuspend < ARRAY_SIZE(erase_suspend)) printk(" Erase Suspend: %s\n", erase_suspend[extp->EraseSuspend]); else printk(" Erase Suspend: Unknown value %d\n", extp->EraseSuspend); if (extp->BlkProt == 0) printk(" Block protection: Not supported\n"); else printk(" Block protection: %d sectors per group\n", extp->BlkProt); printk(" Temporary block unprotect: %s\n", extp->TmpBlkUnprotect ? "Supported" : "Not supported"); printk(" Block protect/unprotect scheme: %d\n", extp->BlkProtUnprot); printk(" Number of simultaneous operations: %d\n", extp->SimultaneousOps); printk(" Burst mode: %s\n", extp->BurstMode ? "Supported" : "Not supported"); if (extp->PageMode == 0) printk(" Page mode: Not supported\n"); else printk(" Page mode: %d word page\n", extp->PageMode << 2); printk(" Vpp Supply Minimum Program/Erase Voltage: %d.%d V\n", extp->VppMin >> 4, extp->VppMin & 0xf); printk(" Vpp Supply Maximum Program/Erase Voltage: %d.%d V\n", extp->VppMax >> 4, extp->VppMax & 0xf); if (extp->TopBottom < ARRAY_SIZE(top_bottom)) printk(" Top/Bottom Boot Block: %s\n", top_bottom[extp->TopBottom]); else printk(" Top/Bottom Boot Block: Unknown value %d\n", extp->TopBottom); } #endif #ifdef AMD_BOOTLOC_BUG /* Wheee. Bring me the head of someone at AMD. */ static void fixup_amd_bootblock(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; struct cfi_pri_amdstd *extp = cfi->cmdset_priv; __u8 major = extp->MajorVersion; __u8 minor = extp->MinorVersion; if (((major << 8) | minor) < 0x3131) { /* CFI version 1.0 => don't trust bootloc */ pr_debug("%s: JEDEC Vendor ID is 0x%02X Device ID is 0x%02X\n", map->name, cfi->mfr, cfi->id); /* AFAICS all 29LV400 with a bottom boot block have a device ID * of 0x22BA in 16-bit mode and 0xBA in 8-bit mode. * These were badly detected as they have the 0x80 bit set * so treat them as a special case. */ if (((cfi->id == 0xBA) || (cfi->id == 0x22BA)) && /* Macronix added CFI to their 2nd generation * MX29LV400C B/T but AFAICS no other 29LV400 (AMD, * Fujitsu, Spansion, EON, ESI and older Macronix) * has CFI. * * Therefore also check the manufacturer. * This reduces the risk of false detection due to * the 8-bit device ID. */ (cfi->mfr == CFI_MFR_MACRONIX)) { pr_debug("%s: Macronix MX29LV400C with bottom boot block" " detected\n", map->name); extp->TopBottom = 2; /* bottom boot */ } else if (cfi->id & 0x80) { printk(KERN_WARNING "%s: JEDEC Device ID is 0x%02X. Assuming broken CFI table.\n", map->name, cfi->id); extp->TopBottom = 3; /* top boot */ } else { extp->TopBottom = 2; /* bottom boot */ } pr_debug("%s: AMD CFI PRI V%c.%c has no boot block field;" " deduced %s from Device ID\n", map->name, major, minor, extp->TopBottom == 2 ? "bottom" : "top"); } } #endif static void fixup_use_write_buffers(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; if (cfi->cfiq->BufWriteTimeoutTyp) { pr_debug("Using buffer write method\n"); mtd->_write = cfi_amdstd_write_buffers; } } /* Atmel chips don't use the same PRI format as AMD chips */ static void fixup_convert_atmel_pri(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; struct cfi_pri_amdstd *extp = cfi->cmdset_priv; struct cfi_pri_atmel atmel_pri; memcpy(&atmel_pri, extp, sizeof(atmel_pri)); memset((char *)extp + 5, 0, sizeof(*extp) - 5); if (atmel_pri.Features & 0x02) extp->EraseSuspend = 2; /* Some chips got it backwards... */ if (cfi->id == AT49BV6416) { if (atmel_pri.BottomBoot) extp->TopBottom = 3; else extp->TopBottom = 2; } else { if (atmel_pri.BottomBoot) extp->TopBottom = 2; else extp->TopBottom = 3; } /* burst write mode not supported */ cfi->cfiq->BufWriteTimeoutTyp = 0; cfi->cfiq->BufWriteTimeoutMax = 0; } static void fixup_use_secsi(struct mtd_info *mtd) { /* Setup for chips with a secsi area */ mtd->_read_user_prot_reg = cfi_amdstd_secsi_read; mtd->_read_fact_prot_reg = cfi_amdstd_secsi_read; } static void fixup_use_erase_chip(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; if ((cfi->cfiq->NumEraseRegions == 1) && ((cfi->cfiq->EraseRegionInfo[0] & 0xffff) == 0)) { mtd->_erase = cfi_amdstd_erase_chip; } } /* * Some Atmel chips (e.g. the AT49BV6416) power-up with all sectors * locked by default. */ static void fixup_use_atmel_lock(struct mtd_info *mtd) { mtd->_lock = cfi_atmel_lock; mtd->_unlock = cfi_atmel_unlock; mtd->flags |= MTD_POWERUP_LOCK; } static void fixup_old_sst_eraseregion(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; /* * These flashes report two separate eraseblock regions based on the * sector_erase-size and block_erase-size, although they both operate on the * same memory. This is not allowed according to CFI, so we just pick the * sector_erase-size. */ cfi->cfiq->NumEraseRegions = 1; } static void fixup_sst39vf(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; fixup_old_sst_eraseregion(mtd); cfi->addr_unlock1 = 0x5555; cfi->addr_unlock2 = 0x2AAA; } static void fixup_sst39vf_rev_b(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; fixup_old_sst_eraseregion(mtd); cfi->addr_unlock1 = 0x555; cfi->addr_unlock2 = 0x2AA; cfi->sector_erase_cmd = CMD(0x50); } static void fixup_sst38vf640x_sectorsize(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; fixup_sst39vf_rev_b(mtd); /* * CFI reports 1024 sectors (0x03ff+1) of 64KBytes (0x0100*256) where * it should report a size of 8KBytes (0x0020*256). */ cfi->cfiq->EraseRegionInfo[0] = 0x002003ff; pr_warn("%s: Bad 38VF640x CFI data; adjusting sector size from 64 to 8KiB\n", mtd->name); } static void fixup_s29gl064n_sectors(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; if ((cfi->cfiq->EraseRegionInfo[0] & 0xffff) == 0x003f) { cfi->cfiq->EraseRegionInfo[0] |= 0x0040; pr_warn("%s: Bad S29GL064N CFI data; adjust from 64 to 128 sectors\n", mtd->name); } } static void fixup_s29gl032n_sectors(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; if ((cfi->cfiq->EraseRegionInfo[1] & 0xffff) == 0x007e) { cfi->cfiq->EraseRegionInfo[1] &= ~0x0040; pr_warn("%s: Bad S29GL032N CFI data; adjust from 127 to 63 sectors\n", mtd->name); } } static void fixup_s29ns512p_sectors(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; /* * S29NS512P flash uses more than 8bits to report number of sectors, * which is not permitted by CFI. */ cfi->cfiq->EraseRegionInfo[0] = 0x020001ff; pr_warn("%s: Bad S29NS512P CFI data; adjust to 512 sectors\n", mtd->name); } /* Used to fix CFI-Tables of chips without Extended Query Tables */ static struct cfi_fixup cfi_nopri_fixup_table[] = { { CFI_MFR_SST, 0x234a, fixup_sst39vf }, /* SST39VF1602 */ { CFI_MFR_SST, 0x234b, fixup_sst39vf }, /* SST39VF1601 */ { CFI_MFR_SST, 0x235a, fixup_sst39vf }, /* SST39VF3202 */ { CFI_MFR_SST, 0x235b, fixup_sst39vf }, /* SST39VF3201 */ { CFI_MFR_SST, 0x235c, fixup_sst39vf_rev_b }, /* SST39VF3202B */ { CFI_MFR_SST, 0x235d, fixup_sst39vf_rev_b }, /* SST39VF3201B */ { CFI_MFR_SST, 0x236c, fixup_sst39vf_rev_b }, /* SST39VF6402B */ { CFI_MFR_SST, 0x236d, fixup_sst39vf_rev_b }, /* SST39VF6401B */ { 0, 0, NULL } }; static struct cfi_fixup cfi_fixup_table[] = { { CFI_MFR_ATMEL, CFI_ID_ANY, fixup_convert_atmel_pri }, #ifdef AMD_BOOTLOC_BUG { CFI_MFR_AMD, CFI_ID_ANY, fixup_amd_bootblock }, { CFI_MFR_AMIC, CFI_ID_ANY, fixup_amd_bootblock }, { CFI_MFR_MACRONIX, CFI_ID_ANY, fixup_amd_bootblock }, #endif { CFI_MFR_AMD, 0x0050, fixup_use_secsi }, { CFI_MFR_AMD, 0x0053, fixup_use_secsi }, { CFI_MFR_AMD, 0x0055, fixup_use_secsi }, { CFI_MFR_AMD, 0x0056, fixup_use_secsi }, { CFI_MFR_AMD, 0x005C, fixup_use_secsi }, { CFI_MFR_AMD, 0x005F, fixup_use_secsi }, { CFI_MFR_AMD, 0x0c01, fixup_s29gl064n_sectors }, { CFI_MFR_AMD, 0x1301, fixup_s29gl064n_sectors }, { CFI_MFR_AMD, 0x1a00, fixup_s29gl032n_sectors }, { CFI_MFR_AMD, 0x1a01, fixup_s29gl032n_sectors }, { CFI_MFR_AMD, 0x3f00, fixup_s29ns512p_sectors }, { CFI_MFR_SST, 0x536a, fixup_sst38vf640x_sectorsize }, /* SST38VF6402 */ { CFI_MFR_SST, 0x536b, fixup_sst38vf640x_sectorsize }, /* SST38VF6401 */ { CFI_MFR_SST, 0x536c, fixup_sst38vf640x_sectorsize }, /* SST38VF6404 */ { CFI_MFR_SST, 0x536d, fixup_sst38vf640x_sectorsize }, /* SST38VF6403 */ #if !FORCE_WORD_WRITE { CFI_MFR_ANY, CFI_ID_ANY, fixup_use_write_buffers }, #endif { 0, 0, NULL } }; static struct cfi_fixup jedec_fixup_table[] = { { CFI_MFR_SST, SST49LF004B, fixup_use_fwh_lock }, { CFI_MFR_SST, SST49LF040B, fixup_use_fwh_lock }, { CFI_MFR_SST, SST49LF008A, fixup_use_fwh_lock }, { 0, 0, NULL } }; static struct cfi_fixup fixup_table[] = { /* The CFI vendor ids and the JEDEC vendor IDs appear * to be common. It is like the devices id's are as * well. This table is to pick all cases where * we know that is the case. */ { CFI_MFR_ANY, CFI_ID_ANY, fixup_use_erase_chip }, { CFI_MFR_ATMEL, AT49BV6416, fixup_use_atmel_lock }, { 0, 0, NULL } }; static void cfi_fixup_major_minor(struct cfi_private *cfi, struct cfi_pri_amdstd *extp) { if (cfi->mfr == CFI_MFR_SAMSUNG) { if ((extp->MajorVersion == '0' && extp->MinorVersion == '0') || (extp->MajorVersion == '3' && extp->MinorVersion == '3')) { /* * Samsung K8P2815UQB and K8D6x16UxM chips * report major=0 / minor=0. * K8D3x16UxC chips report major=3 / minor=3. */ printk(KERN_NOTICE " Fixing Samsung's Amd/Fujitsu" " Extended Query version to 1.%c\n", extp->MinorVersion); extp->MajorVersion = '1'; } } /* * SST 38VF640x chips report major=0xFF / minor=0xFF. */ if (cfi->mfr == CFI_MFR_SST && (cfi->id >> 4) == 0x0536) { extp->MajorVersion = '1'; extp->MinorVersion = '0'; } } static int is_m29ew(struct cfi_private *cfi) { if (cfi->mfr == CFI_MFR_INTEL && ((cfi->device_type == CFI_DEVICETYPE_X8 && (cfi->id & 0xff) == 0x7e) || (cfi->device_type == CFI_DEVICETYPE_X16 && cfi->id == 0x227e))) return 1; return 0; } /* * From TN-13-07: Patching the Linux Kernel and U-Boot for M29 Flash, page 20: * Some revisions of the M29EW suffer from erase suspend hang ups. In * particular, it can occur when the sequence * Erase Confirm -> Suspend -> Program -> Resume * causes a lockup due to internal timing issues. The consequence is that the * erase cannot be resumed without inserting a dummy command after programming * and prior to resuming. [...] The work-around is to issue a dummy write cycle * that writes an F0 command code before the RESUME command. */ static void cfi_fixup_m29ew_erase_suspend(struct map_info *map, unsigned long adr) { struct cfi_private *cfi = map->fldrv_priv; /* before resume, insert a dummy 0xF0 cycle for Micron M29EW devices */ if (is_m29ew(cfi)) map_write(map, CMD(0xF0), adr); } /* * From TN-13-07: Patching the Linux Kernel and U-Boot for M29 Flash, page 22: * * Some revisions of the M29EW (for example, A1 and A2 step revisions) * are affected by a problem that could cause a hang up when an ERASE SUSPEND * command is issued after an ERASE RESUME operation without waiting for a * minimum delay. The result is that once the ERASE seems to be completed * (no bits are toggling), the contents of the Flash memory block on which * the erase was ongoing could be inconsistent with the expected values * (typically, the array value is stuck to the 0xC0, 0xC4, 0x80, or 0x84 * values), causing a consequent failure of the ERASE operation. * The occurrence of this issue could be high, especially when file system * operations on the Flash are intensive. As a result, it is recommended * that a patch be applied. Intensive file system operations can cause many * calls to the garbage routine to free Flash space (also by erasing physical * Flash blocks) and as a result, many consecutive SUSPEND and RESUME * commands can occur. The problem disappears when a delay is inserted after * the RESUME command by using the udelay() function available in Linux. * The DELAY value must be tuned based on the customer's platform. * The maximum value that fixes the problem in all cases is 500us. * But, in our experience, a delay of 30 µs to 50 µs is sufficient * in most cases. * We have chosen 500µs because this latency is acceptable. */ static void cfi_fixup_m29ew_delay_after_resume(struct cfi_private *cfi) { /* * Resolving the Delay After Resume Issue see Micron TN-13-07 * Worst case delay must be 500µs but 30-50µs should be ok as well */ if (is_m29ew(cfi)) cfi_udelay(500); } struct mtd_info *cfi_cmdset_0002(struct map_info *map, int primary) { struct cfi_private *cfi = map->fldrv_priv; struct device_node __maybe_unused *np = map->device_node; struct mtd_info *mtd; int i; mtd = kzalloc(sizeof(*mtd), GFP_KERNEL); if (!mtd) return NULL; mtd->priv = map; mtd->type = MTD_NORFLASH; /* Fill in the default mtd operations */ mtd->_erase = cfi_amdstd_erase_varsize; mtd->_write = cfi_amdstd_write_words; mtd->_read = cfi_amdstd_read; mtd->_sync = cfi_amdstd_sync; mtd->_suspend = cfi_amdstd_suspend; mtd->_resume = cfi_amdstd_resume; mtd->_read_user_prot_reg = cfi_amdstd_read_user_prot_reg; mtd->_read_fact_prot_reg = cfi_amdstd_read_fact_prot_reg; mtd->_get_fact_prot_info = cfi_amdstd_get_fact_prot_info; mtd->_get_user_prot_info = cfi_amdstd_get_user_prot_info; mtd->_write_user_prot_reg = cfi_amdstd_write_user_prot_reg; mtd->_lock_user_prot_reg = cfi_amdstd_lock_user_prot_reg; mtd->flags = MTD_CAP_NORFLASH; mtd->name = map->name; mtd->writesize = 1; mtd->writebufsize = cfi_interleave(cfi) << cfi->cfiq->MaxBufWriteSize; pr_debug("MTD %s(): write buffer size %d\n", __func__, mtd->writebufsize); mtd->_panic_write = cfi_amdstd_panic_write; mtd->reboot_notifier.notifier_call = cfi_amdstd_reboot; if (cfi->cfi_mode==CFI_MODE_CFI){ unsigned char bootloc; __u16 adr = primary?cfi->cfiq->P_ADR:cfi->cfiq->A_ADR; struct cfi_pri_amdstd *extp; extp = (struct cfi_pri_amdstd*)cfi_read_pri(map, adr, sizeof(*extp), "Amd/Fujitsu"); if (extp) { /* * It's a real CFI chip, not one for which the probe * routine faked a CFI structure. */ cfi_fixup_major_minor(cfi, extp); /* * Valid primary extension versions are: 1.0, 1.1, 1.2, 1.3, 1.4, 1.5 * see: http://cs.ozerki.net/zap/pub/axim-x5/docs/cfi_r20.pdf, page 19 * http://www.spansion.com/Support/AppNotes/cfi_100_20011201.pdf * http://www.spansion.com/Support/Datasheets/s29ws-p_00_a12_e.pdf * http://www.spansion.com/Support/Datasheets/S29GL_128S_01GS_00_02_e.pdf */ if (extp->MajorVersion != '1' || (extp->MajorVersion == '1' && (extp->MinorVersion < '0' || extp->MinorVersion > '5'))) { printk(KERN_ERR " Unknown Amd/Fujitsu Extended Query " "version %c.%c (%#02x/%#02x).\n", extp->MajorVersion, extp->MinorVersion, extp->MajorVersion, extp->MinorVersion); kfree(extp); kfree(mtd); return NULL; } printk(KERN_INFO " Amd/Fujitsu Extended Query version %c.%c.\n", extp->MajorVersion, extp->MinorVersion); /* Install our own private info structure */ cfi->cmdset_priv = extp; /* Apply cfi device specific fixups */ cfi_fixup(mtd, cfi_fixup_table); #ifdef DEBUG_CFI_FEATURES /* Tell the user about it in lots of lovely detail */ cfi_tell_features(extp); #endif #ifdef CONFIG_OF if (np && of_property_read_bool( np, "use-advanced-sector-protection") && extp->BlkProtUnprot == 8) { printk(KERN_INFO " Advanced Sector Protection (PPB Locking) supported\n"); mtd->_lock = cfi_ppb_lock; mtd->_unlock = cfi_ppb_unlock; mtd->_is_locked = cfi_ppb_is_locked; } #endif bootloc = extp->TopBottom; if ((bootloc < 2) || (bootloc > 5)) { printk(KERN_WARNING "%s: CFI contains unrecognised boot " "bank location (%d). Assuming bottom.\n", map->name, bootloc); bootloc = 2; } if (bootloc == 3 && cfi->cfiq->NumEraseRegions > 1) { printk(KERN_WARNING "%s: Swapping erase regions for top-boot CFI table.\n", map->name); for (i=0; i<cfi->cfiq->NumEraseRegions / 2; i++) { int j = (cfi->cfiq->NumEraseRegions-1)-i; swap(cfi->cfiq->EraseRegionInfo[i], cfi->cfiq->EraseRegionInfo[j]); } } /* Set the default CFI lock/unlock addresses */ cfi->addr_unlock1 = 0x555; cfi->addr_unlock2 = 0x2aa; } cfi_fixup(mtd, cfi_nopri_fixup_table); if (!cfi->addr_unlock1 || !cfi->addr_unlock2) { kfree(mtd); return NULL; } } /* CFI mode */ else if (cfi->cfi_mode == CFI_MODE_JEDEC) { /* Apply jedec specific fixups */ cfi_fixup(mtd, jedec_fixup_table); } /* Apply generic fixups */ cfi_fixup(mtd, fixup_table); for (i=0; i< cfi->numchips; i++) { cfi->chips[i].word_write_time = 1<<cfi->cfiq->WordWriteTimeoutTyp; cfi->chips[i].buffer_write_time = 1<<cfi->cfiq->BufWriteTimeoutTyp; cfi->chips[i].erase_time = 1<<cfi->cfiq->BlockEraseTimeoutTyp; /* * First calculate the timeout max according to timeout field * of struct cfi_ident that probed from chip's CFI aera, if * available. Specify a minimum of 2000us, in case the CFI data * is wrong. */ if (cfi->cfiq->BufWriteTimeoutTyp && cfi->cfiq->BufWriteTimeoutMax) cfi->chips[i].buffer_write_time_max = 1 << (cfi->cfiq->BufWriteTimeoutTyp + cfi->cfiq->BufWriteTimeoutMax); else cfi->chips[i].buffer_write_time_max = 0; cfi->chips[i].buffer_write_time_max = max(cfi->chips[i].buffer_write_time_max, 2000); cfi->chips[i].ref_point_counter = 0; init_waitqueue_head(&(cfi->chips[i].wq)); } map->fldrv = &cfi_amdstd_chipdrv; return cfi_amdstd_setup(mtd); } struct mtd_info *cfi_cmdset_0006(struct map_info *map, int primary) __attribute__((alias("cfi_cmdset_0002"))); struct mtd_info *cfi_cmdset_0701(struct map_info *map, int primary) __attribute__((alias("cfi_cmdset_0002"))); EXPORT_SYMBOL_GPL(cfi_cmdset_0002); EXPORT_SYMBOL_GPL(cfi_cmdset_0006); EXPORT_SYMBOL_GPL(cfi_cmdset_0701); static struct mtd_info *cfi_amdstd_setup(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; unsigned long devsize = (1<<cfi->cfiq->DevSize) * cfi->interleave; unsigned long offset = 0; int i,j; printk(KERN_NOTICE "number of %s chips: %d\n", (cfi->cfi_mode == CFI_MODE_CFI)?"CFI":"JEDEC",cfi->numchips); /* Select the correct geometry setup */ mtd->size = devsize * cfi->numchips; mtd->numeraseregions = cfi->cfiq->NumEraseRegions * cfi->numchips; mtd->eraseregions = kmalloc_array(mtd->numeraseregions, sizeof(struct mtd_erase_region_info), GFP_KERNEL); if (!mtd->eraseregions) goto setup_err; for (i=0; i<cfi->cfiq->NumEraseRegions; i++) { unsigned long ernum, ersize; ersize = ((cfi->cfiq->EraseRegionInfo[i] >> 8) & ~0xff) * cfi->interleave; ernum = (cfi->cfiq->EraseRegionInfo[i] & 0xffff) + 1; if (mtd->erasesize < ersize) { mtd->erasesize = ersize; } for (j=0; j<cfi->numchips; j++) { mtd->eraseregions[(j*cfi->cfiq->NumEraseRegions)+i].offset = (j*devsize)+offset; mtd->eraseregions[(j*cfi->cfiq->NumEraseRegions)+i].erasesize = ersize; mtd->eraseregions[(j*cfi->cfiq->NumEraseRegions)+i].numblocks = ernum; } offset += (ersize * ernum); } if (offset != devsize) { /* Argh */ printk(KERN_WARNING "Sum of regions (%lx) != total size of set of interleaved chips (%lx)\n", offset, devsize); goto setup_err; } __module_get(THIS_MODULE); register_reboot_notifier(&mtd->reboot_notifier); return mtd; setup_err: kfree(mtd->eraseregions); kfree(mtd); kfree(cfi->cmdset_priv); kfree(cfi->cfiq); return NULL; } /* * Return true if the chip is ready. * * Ready is one of: read mode, query mode, erase-suspend-read mode (in any * non-suspended sector) and is indicated by no toggle bits toggling. * * Note that anything more complicated than checking if no bits are toggling * (including checking DQ5 for an error status) is tricky to get working * correctly and is therefore not done (particularly with interleaved chips * as each chip must be checked independently of the others). */ static int __xipram chip_ready(struct map_info *map, unsigned long addr) { map_word d, t; d = map_read(map, addr); t = map_read(map, addr); return map_word_equal(map, d, t); } /* * Return true if the chip is ready and has the correct value. * * Ready is one of: read mode, query mode, erase-suspend-read mode (in any * non-suspended sector) and it is indicated by no bits toggling. * * Error are indicated by toggling bits or bits held with the wrong value, * or with bits toggling. * * Note that anything more complicated than checking if no bits are toggling * (including checking DQ5 for an error status) is tricky to get working * correctly and is therefore not done (particularly with interleaved chips * as each chip must be checked independently of the others). * */ static int __xipram chip_good(struct map_info *map, unsigned long addr, map_word expected) { map_word oldd, curd; oldd = map_read(map, addr); curd = map_read(map, addr); return map_word_equal(map, oldd, curd) && map_word_equal(map, curd, expected); } static int get_chip(struct map_info *map, struct flchip *chip, unsigned long adr, int mode) { DECLARE_WAITQUEUE(wait, current); struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo; struct cfi_pri_amdstd *cfip = (struct cfi_pri_amdstd *)cfi->cmdset_priv; resettime: timeo = jiffies + HZ; retry: switch (chip->state) { case FL_STATUS: for (;;) { if (chip_ready(map, adr)) break; if (time_after(jiffies, timeo)) { printk(KERN_ERR "Waiting for chip to be ready timed out.\n"); return -EIO; } mutex_unlock(&chip->mutex); cfi_udelay(1); mutex_lock(&chip->mutex); /* Someone else might have been playing with it. */ goto retry; } case FL_READY: case FL_CFI_QUERY: case FL_JEDEC_QUERY: return 0; case FL_ERASING: if (!cfip || !(cfip->EraseSuspend & (0x1|0x2)) || !(mode == FL_READY || mode == FL_POINT || (mode == FL_WRITING && (cfip->EraseSuspend & 0x2)))) goto sleep; /* Do not allow suspend iff read/write to EB address */ if ((adr & chip->in_progress_block_mask) == chip->in_progress_block_addr) goto sleep; /* Erase suspend */ /* It's harmless to issue the Erase-Suspend and Erase-Resume * commands when the erase algorithm isn't in progress. */ map_write(map, CMD(0xB0), chip->in_progress_block_addr); chip->oldstate = FL_ERASING; chip->state = FL_ERASE_SUSPENDING; chip->erase_suspended = 1; for (;;) { if (chip_ready(map, adr)) break; if (time_after(jiffies, timeo)) { /* Should have suspended the erase by now. * Send an Erase-Resume command as either * there was an error (so leave the erase * routine to recover from it) or we trying to * use the erase-in-progress sector. */ put_chip(map, chip, adr); printk(KERN_ERR "MTD %s(): chip not ready after erase suspend\n", __func__); return -EIO; } mutex_unlock(&chip->mutex); cfi_udelay(1); mutex_lock(&chip->mutex); /* Nobody will touch it while it's in state FL_ERASE_SUSPENDING. So we can just loop here. */ } chip->state = FL_READY; return 0; case FL_XIP_WHILE_ERASING: if (mode != FL_READY && mode != FL_POINT && (!cfip || !(cfip->EraseSuspend&2))) goto sleep; chip->oldstate = chip->state; chip->state = FL_READY; return 0; case FL_SHUTDOWN: /* The machine is rebooting */ return -EIO; case FL_POINT: /* Only if there's no operation suspended... */ if (mode == FL_READY && chip->oldstate == FL_READY) return 0; default: sleep: set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); mutex_lock(&chip->mutex); goto resettime; } } static void put_chip(struct map_info *map, struct flchip *chip, unsigned long adr) { struct cfi_private *cfi = map->fldrv_priv; switch(chip->oldstate) { case FL_ERASING: cfi_fixup_m29ew_erase_suspend(map, chip->in_progress_block_addr); map_write(map, cfi->sector_erase_cmd, chip->in_progress_block_addr); cfi_fixup_m29ew_delay_after_resume(cfi); chip->oldstate = FL_READY; chip->state = FL_ERASING; break; case FL_XIP_WHILE_ERASING: chip->state = chip->oldstate; chip->oldstate = FL_READY; break; case FL_READY: case FL_STATUS: break; default: printk(KERN_ERR "MTD: put_chip() called with oldstate %d!!\n", chip->oldstate); } wake_up(&chip->wq); } #ifdef CONFIG_MTD_XIP /* * No interrupt what so ever can be serviced while the flash isn't in array * mode. This is ensured by the xip_disable() and xip_enable() functions * enclosing any code path where the flash is known not to be in array mode. * And within a XIP disabled code path, only functions marked with __xipram * may be called and nothing else (it's a good thing to inspect generated * assembly to make sure inline functions were actually inlined and that gcc * didn't emit calls to its own support functions). Also configuring MTD CFI * support to a single buswidth and a single interleave is also recommended. */ static void xip_disable(struct map_info *map, struct flchip *chip, unsigned long adr) { /* TODO: chips with no XIP use should ignore and return */ (void) map_read(map, adr); /* ensure mmu mapping is up to date */ local_irq_disable(); } static void __xipram xip_enable(struct map_info *map, struct flchip *chip, unsigned long adr) { struct cfi_private *cfi = map->fldrv_priv; if (chip->state != FL_POINT && chip->state != FL_READY) { map_write(map, CMD(0xf0), adr); chip->state = FL_READY; } (void) map_read(map, adr); xip_iprefetch(); local_irq_enable(); } /* * When a delay is required for the flash operation to complete, the * xip_udelay() function is polling for both the given timeout and pending * (but still masked) hardware interrupts. Whenever there is an interrupt * pending then the flash erase operation is suspended, array mode restored * and interrupts unmasked. Task scheduling might also happen at that * point. The CPU eventually returns from the interrupt or the call to * schedule() and the suspended flash operation is resumed for the remaining * of the delay period. * * Warning: this function _will_ fool interrupt latency tracing tools. */ static void __xipram xip_udelay(struct map_info *map, struct flchip *chip, unsigned long adr, int usec) { struct cfi_private *cfi = map->fldrv_priv; struct cfi_pri_amdstd *extp = cfi->cmdset_priv; map_word status, OK = CMD(0x80); unsigned long suspended, start = xip_currtime(); flstate_t oldstate; do { cpu_relax(); if (xip_irqpending() && extp && ((chip->state == FL_ERASING && (extp->EraseSuspend & 2))) && (cfi_interleave_is_1(cfi) || chip->oldstate == FL_READY)) { /* * Let's suspend the erase operation when supported. * Note that we currently don't try to suspend * interleaved chips if there is already another * operation suspended (imagine what happens * when one chip was already done with the current * operation while another chip suspended it, then * we resume the whole thing at once). Yes, it * can happen! */ map_write(map, CMD(0xb0), adr); usec -= xip_elapsed_since(start); suspended = xip_currtime(); do { if (xip_elapsed_since(suspended) > 100000) { /* * The chip doesn't want to suspend * after waiting for 100 msecs. * This is a critical error but there * is not much we can do here. */ return; } status = map_read(map, adr); } while (!map_word_andequal(map, status, OK, OK)); /* Suspend succeeded */ oldstate = chip->state; if (!map_word_bitsset(map, status, CMD(0x40))) break; chip->state = FL_XIP_WHILE_ERASING; chip->erase_suspended = 1; map_write(map, CMD(0xf0), adr); (void) map_read(map, adr); xip_iprefetch(); local_irq_enable(); mutex_unlock(&chip->mutex); xip_iprefetch(); cond_resched(); /* * We're back. However someone else might have * decided to go write to the chip if we are in * a suspended erase state. If so let's wait * until it's done. */ mutex_lock(&chip->mutex); while (chip->state != FL_XIP_WHILE_ERASING) { DECLARE_WAITQUEUE(wait, current); set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); mutex_lock(&chip->mutex); } /* Disallow XIP again */ local_irq_disable(); /* Correct Erase Suspend Hangups for M29EW */ cfi_fixup_m29ew_erase_suspend(map, adr); /* Resume the write or erase operation */ map_write(map, cfi->sector_erase_cmd, adr); chip->state = oldstate; start = xip_currtime(); } else if (usec >= 1000000/HZ) { /* * Try to save on CPU power when waiting delay * is at least a system timer tick period. * No need to be extremely accurate here. */ xip_cpu_idle(); } status = map_read(map, adr); } while (!map_word_andequal(map, status, OK, OK) && xip_elapsed_since(start) < usec); } #define UDELAY(map, chip, adr, usec) xip_udelay(map, chip, adr, usec) /* * The INVALIDATE_CACHED_RANGE() macro is normally used in parallel while * the flash is actively programming or erasing since we have to poll for * the operation to complete anyway. We can't do that in a generic way with * a XIP setup so do it before the actual flash operation in this case * and stub it out from INVALIDATE_CACHE_UDELAY. */ #define XIP_INVAL_CACHED_RANGE(map, from, size) \ INVALIDATE_CACHED_RANGE(map, from, size) #define INVALIDATE_CACHE_UDELAY(map, chip, adr, len, usec) \ UDELAY(map, chip, adr, usec) /* * Extra notes: * * Activating this XIP support changes the way the code works a bit. For * example the code to suspend the current process when concurrent access * happens is never executed because xip_udelay() will always return with the * same chip state as it was entered with. This is why there is no care for * the presence of add_wait_queue() or schedule() calls from within a couple * xip_disable()'d areas of code, like in do_erase_oneblock for example. * The queueing and scheduling are always happening within xip_udelay(). * * Similarly, get_chip() and put_chip() just happen to always be executed * with chip->state set to FL_READY (or FL_XIP_WHILE_*) where flash state * is in array mode, therefore never executing many cases therein and not * causing any problem with XIP. */ #else #define xip_disable(map, chip, adr) #define xip_enable(map, chip, adr) #define XIP_INVAL_CACHED_RANGE(x...) #define UDELAY(map, chip, adr, usec) \ do { \ mutex_unlock(&chip->mutex); \ cfi_udelay(usec); \ mutex_lock(&chip->mutex); \ } while (0) #define INVALIDATE_CACHE_UDELAY(map, chip, adr, len, usec) \ do { \ mutex_unlock(&chip->mutex); \ INVALIDATE_CACHED_RANGE(map, adr, len); \ cfi_udelay(usec); \ mutex_lock(&chip->mutex); \ } while (0) #endif static inline int do_read_onechip(struct map_info *map, struct flchip *chip, loff_t adr, size_t len, u_char *buf) { unsigned long cmd_addr; struct cfi_private *cfi = map->fldrv_priv; int ret; adr += chip->start; /* Ensure cmd read/writes are aligned. */ cmd_addr = adr & ~(map_bankwidth(map)-1); mutex_lock(&chip->mutex); ret = get_chip(map, chip, cmd_addr, FL_READY); if (ret) { mutex_unlock(&chip->mutex); return ret; } if (chip->state != FL_POINT && chip->state != FL_READY) { map_write(map, CMD(0xf0), cmd_addr); chip->state = FL_READY; } map_copy_from(map, buf, adr, len); put_chip(map, chip, cmd_addr); mutex_unlock(&chip->mutex); return 0; } static int cfi_amdstd_read (struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; unsigned long ofs; int chipnum; int ret = 0; /* ofs: offset within the first chip that the first read should start */ chipnum = (from >> cfi->chipshift); ofs = from - (chipnum << cfi->chipshift); while (len) { unsigned long thislen; if (chipnum >= cfi->numchips) break; if ((len + ofs -1) >> cfi->chipshift) thislen = (1<<cfi->chipshift) - ofs; else thislen = len; ret = do_read_onechip(map, &cfi->chips[chipnum], ofs, thislen, buf); if (ret) break; *retlen += thislen; len -= thislen; buf += thislen; ofs = 0; chipnum++; } return ret; } typedef int (*otp_op_t)(struct map_info *map, struct flchip *chip, loff_t adr, size_t len, u_char *buf, size_t grouplen); static inline void otp_enter(struct map_info *map, struct flchip *chip, loff_t adr, size_t len) { struct cfi_private *cfi = map->fldrv_priv; cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x88, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); INVALIDATE_CACHED_RANGE(map, chip->start + adr, len); } static inline void otp_exit(struct map_info *map, struct flchip *chip, loff_t adr, size_t len) { struct cfi_private *cfi = map->fldrv_priv; cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x90, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x00, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); INVALIDATE_CACHED_RANGE(map, chip->start + adr, len); } static inline int do_read_secsi_onechip(struct map_info *map, struct flchip *chip, loff_t adr, size_t len, u_char *buf, size_t grouplen) { DECLARE_WAITQUEUE(wait, current); retry: mutex_lock(&chip->mutex); if (chip->state != FL_READY){ set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); goto retry; } adr += chip->start; chip->state = FL_READY; otp_enter(map, chip, adr, len); map_copy_from(map, buf, adr, len); otp_exit(map, chip, adr, len); wake_up(&chip->wq); mutex_unlock(&chip->mutex); return 0; } static int cfi_amdstd_secsi_read (struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; unsigned long ofs; int chipnum; int ret = 0; /* ofs: offset within the first chip that the first read should start */ /* 8 secsi bytes per chip */ chipnum=from>>3; ofs=from & 7; while (len) { unsigned long thislen; if (chipnum >= cfi->numchips) break; if ((len + ofs -1) >> 3) thislen = (1<<3) - ofs; else thislen = len; ret = do_read_secsi_onechip(map, &cfi->chips[chipnum], ofs, thislen, buf, 0); if (ret) break; *retlen += thislen; len -= thislen; buf += thislen; ofs = 0; chipnum++; } return ret; } static int __xipram do_write_oneword(struct map_info *map, struct flchip *chip, unsigned long adr, map_word datum, int mode); static int do_otp_write(struct map_info *map, struct flchip *chip, loff_t adr, size_t len, u_char *buf, size_t grouplen) { int ret; while (len) { unsigned long bus_ofs = adr & ~(map_bankwidth(map)-1); int gap = adr - bus_ofs; int n = min_t(int, len, map_bankwidth(map) - gap); map_word datum = map_word_ff(map); if (n != map_bankwidth(map)) { /* partial write of a word, load old contents */ otp_enter(map, chip, bus_ofs, map_bankwidth(map)); datum = map_read(map, bus_ofs); otp_exit(map, chip, bus_ofs, map_bankwidth(map)); } datum = map_word_load_partial(map, datum, buf, gap, n); ret = do_write_oneword(map, chip, bus_ofs, datum, FL_OTP_WRITE); if (ret) return ret; adr += n; buf += n; len -= n; } return 0; } static int do_otp_lock(struct map_info *map, struct flchip *chip, loff_t adr, size_t len, u_char *buf, size_t grouplen) { struct cfi_private *cfi = map->fldrv_priv; uint8_t lockreg; unsigned long timeo; int ret; /* make sure area matches group boundaries */ if ((adr != 0) || (len != grouplen)) return -EINVAL; mutex_lock(&chip->mutex); ret = get_chip(map, chip, chip->start, FL_LOCKING); if (ret) { mutex_unlock(&chip->mutex); return ret; } chip->state = FL_LOCKING; /* Enter lock register command */ cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x40, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); /* read lock register */ lockreg = cfi_read_query(map, 0); /* set bit 0 to protect extended memory block */ lockreg &= ~0x01; /* set bit 0 to protect extended memory block */ /* write lock register */ map_write(map, CMD(0xA0), chip->start); map_write(map, CMD(lockreg), chip->start); /* wait for chip to become ready */ timeo = jiffies + msecs_to_jiffies(2); for (;;) { if (chip_ready(map, adr)) break; if (time_after(jiffies, timeo)) { pr_err("Waiting for chip to be ready timed out.\n"); ret = -EIO; break; } UDELAY(map, chip, 0, 1); } /* exit protection commands */ map_write(map, CMD(0x90), chip->start); map_write(map, CMD(0x00), chip->start); chip->state = FL_READY; put_chip(map, chip, chip->start); mutex_unlock(&chip->mutex); return ret; } static int cfi_amdstd_otp_walk(struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf, otp_op_t action, int user_regs) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int ofs_factor = cfi->interleave * cfi->device_type; unsigned long base; int chipnum; struct flchip *chip; uint8_t otp, lockreg; int ret; size_t user_size, factory_size, otpsize; loff_t user_offset, factory_offset, otpoffset; int user_locked = 0, otplocked; *retlen = 0; for (chipnum = 0; chipnum < cfi->numchips; chipnum++) { chip = &cfi->chips[chipnum]; factory_size = 0; user_size = 0; /* Micron M29EW family */ if (is_m29ew(cfi)) { base = chip->start; /* check whether secsi area is factory locked or user lockable */ mutex_lock(&chip->mutex); ret = get_chip(map, chip, base, FL_CFI_QUERY); if (ret) { mutex_unlock(&chip->mutex); return ret; } cfi_qry_mode_on(base, map, cfi); otp = cfi_read_query(map, base + 0x3 * ofs_factor); cfi_qry_mode_off(base, map, cfi); put_chip(map, chip, base); mutex_unlock(&chip->mutex); if (otp & 0x80) { /* factory locked */ factory_offset = 0; factory_size = 0x100; } else { /* customer lockable */ user_offset = 0; user_size = 0x100; mutex_lock(&chip->mutex); ret = get_chip(map, chip, base, FL_LOCKING); if (ret) { mutex_unlock(&chip->mutex); return ret; } /* Enter lock register command */ cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x40, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); /* read lock register */ lockreg = cfi_read_query(map, 0); /* exit protection commands */ map_write(map, CMD(0x90), chip->start); map_write(map, CMD(0x00), chip->start); put_chip(map, chip, chip->start); mutex_unlock(&chip->mutex); user_locked = ((lockreg & 0x01) == 0x00); } } otpsize = user_regs ? user_size : factory_size; if (!otpsize) continue; otpoffset = user_regs ? user_offset : factory_offset; otplocked = user_regs ? user_locked : 1; if (!action) { /* return otpinfo */ struct otp_info *otpinfo; len -= sizeof(*otpinfo); if (len <= 0) return -ENOSPC; otpinfo = (struct otp_info *)buf; otpinfo->start = from; otpinfo->length = otpsize; otpinfo->locked = otplocked; buf += sizeof(*otpinfo); *retlen += sizeof(*otpinfo); from += otpsize; } else if ((from < otpsize) && (len > 0)) { size_t size; size = (len < otpsize - from) ? len : otpsize - from; ret = action(map, chip, otpoffset + from, size, buf, otpsize); if (ret < 0) return ret; buf += size; len -= size; *retlen += size; from = 0; } else { from -= otpsize; } } return 0; } static int cfi_amdstd_get_fact_prot_info(struct mtd_info *mtd, size_t len, size_t *retlen, struct otp_info *buf) { return cfi_amdstd_otp_walk(mtd, 0, len, retlen, (u_char *)buf, NULL, 0); } static int cfi_amdstd_get_user_prot_info(struct mtd_info *mtd, size_t len, size_t *retlen, struct otp_info *buf) { return cfi_amdstd_otp_walk(mtd, 0, len, retlen, (u_char *)buf, NULL, 1); } static int cfi_amdstd_read_fact_prot_reg(struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf) { return cfi_amdstd_otp_walk(mtd, from, len, retlen, buf, do_read_secsi_onechip, 0); } static int cfi_amdstd_read_user_prot_reg(struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf) { return cfi_amdstd_otp_walk(mtd, from, len, retlen, buf, do_read_secsi_onechip, 1); } static int cfi_amdstd_write_user_prot_reg(struct mtd_info *mtd, loff_t from, size_t len, size_t *retlen, u_char *buf) { return cfi_amdstd_otp_walk(mtd, from, len, retlen, buf, do_otp_write, 1); } static int cfi_amdstd_lock_user_prot_reg(struct mtd_info *mtd, loff_t from, size_t len) { size_t retlen; return cfi_amdstd_otp_walk(mtd, from, len, &retlen, NULL, do_otp_lock, 1); } static int __xipram do_write_oneword(struct map_info *map, struct flchip *chip, unsigned long adr, map_word datum, int mode) { struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo = jiffies + HZ; /* * We use a 1ms + 1 jiffies generic timeout for writes (most devices * have a max write time of a few hundreds usec). However, we should * use the maximum timeout value given by the chip at probe time * instead. Unfortunately, struct flchip does have a field for * maximum timeout, only for typical which can be far too short * depending of the conditions. The ' + 1' is to avoid having a * timeout of 0 jiffies if HZ is smaller than 1000. */ unsigned long uWriteTimeout = (HZ / 1000) + 1; int ret = 0; map_word oldd; int retry_cnt = 0; adr += chip->start; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr, mode); if (ret) { mutex_unlock(&chip->mutex); return ret; } pr_debug("MTD %s(): WRITE 0x%.8lx(0x%.8lx)\n", __func__, adr, datum.x[0]); if (mode == FL_OTP_WRITE) otp_enter(map, chip, adr, map_bankwidth(map)); /* * Check for a NOP for the case when the datum to write is already * present - it saves time and works around buggy chips that corrupt * data at other locations when 0xff is written to a location that * already contains 0xff. */ oldd = map_read(map, adr); if (map_word_equal(map, oldd, datum)) { pr_debug("MTD %s(): NOP\n", __func__); goto op_done; } XIP_INVAL_CACHED_RANGE(map, adr, map_bankwidth(map)); ENABLE_VPP(map); xip_disable(map, chip, adr); retry: cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xA0, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); map_write(map, datum, adr); chip->state = mode; INVALIDATE_CACHE_UDELAY(map, chip, adr, map_bankwidth(map), chip->word_write_time); /* See comment above for timeout value. */ timeo = jiffies + uWriteTimeout; for (;;) { if (chip->state != mode) { /* Someone's suspended the write. Sleep */ DECLARE_WAITQUEUE(wait, current); set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); timeo = jiffies + (HZ / 2); /* FIXME */ mutex_lock(&chip->mutex); continue; } if (time_after(jiffies, timeo) && !chip_ready(map, adr)){ xip_enable(map, chip, adr); printk(KERN_WARNING "MTD %s(): software timeout\n", __func__); xip_disable(map, chip, adr); break; } if (chip_ready(map, adr)) break; /* Latency issues. Drop the lock, wait a while and retry */ UDELAY(map, chip, adr, 1); } /* Did we succeed? */ if (!chip_good(map, adr, datum)) { /* reset on all failures. */ map_write(map, CMD(0xF0), chip->start); /* FIXME - should have reset delay before continuing */ if (++retry_cnt <= MAX_RETRIES) goto retry; ret = -EIO; } xip_enable(map, chip, adr); op_done: if (mode == FL_OTP_WRITE) otp_exit(map, chip, adr, map_bankwidth(map)); chip->state = FL_READY; DISABLE_VPP(map); put_chip(map, chip, adr); mutex_unlock(&chip->mutex); return ret; } static int cfi_amdstd_write_words(struct mtd_info *mtd, loff_t to, size_t len, size_t *retlen, const u_char *buf) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int ret = 0; int chipnum; unsigned long ofs, chipstart; DECLARE_WAITQUEUE(wait, current); chipnum = to >> cfi->chipshift; ofs = to - (chipnum << cfi->chipshift); chipstart = cfi->chips[chipnum].start; /* If it's not bus-aligned, do the first byte write */ if (ofs & (map_bankwidth(map)-1)) { unsigned long bus_ofs = ofs & ~(map_bankwidth(map)-1); int i = ofs - bus_ofs; int n = 0; map_word tmp_buf; retry: mutex_lock(&cfi->chips[chipnum].mutex); if (cfi->chips[chipnum].state != FL_READY) { set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&cfi->chips[chipnum].wq, &wait); mutex_unlock(&cfi->chips[chipnum].mutex); schedule(); remove_wait_queue(&cfi->chips[chipnum].wq, &wait); goto retry; } /* Load 'tmp_buf' with old contents of flash */ tmp_buf = map_read(map, bus_ofs+chipstart); mutex_unlock(&cfi->chips[chipnum].mutex); /* Number of bytes to copy from buffer */ n = min_t(int, len, map_bankwidth(map)-i); tmp_buf = map_word_load_partial(map, tmp_buf, buf, i, n); ret = do_write_oneword(map, &cfi->chips[chipnum], bus_ofs, tmp_buf, FL_WRITING); if (ret) return ret; ofs += n; buf += n; (*retlen) += n; len -= n; if (ofs >> cfi->chipshift) { chipnum ++; ofs = 0; if (chipnum == cfi->numchips) return 0; } } /* We are now aligned, write as much as possible */ while(len >= map_bankwidth(map)) { map_word datum; datum = map_word_load(map, buf); ret = do_write_oneword(map, &cfi->chips[chipnum], ofs, datum, FL_WRITING); if (ret) return ret; ofs += map_bankwidth(map); buf += map_bankwidth(map); (*retlen) += map_bankwidth(map); len -= map_bankwidth(map); if (ofs >> cfi->chipshift) { chipnum ++; ofs = 0; if (chipnum == cfi->numchips) return 0; chipstart = cfi->chips[chipnum].start; } } /* Write the trailing bytes if any */ if (len & (map_bankwidth(map)-1)) { map_word tmp_buf; retry1: mutex_lock(&cfi->chips[chipnum].mutex); if (cfi->chips[chipnum].state != FL_READY) { set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&cfi->chips[chipnum].wq, &wait); mutex_unlock(&cfi->chips[chipnum].mutex); schedule(); remove_wait_queue(&cfi->chips[chipnum].wq, &wait); goto retry1; } tmp_buf = map_read(map, ofs + chipstart); mutex_unlock(&cfi->chips[chipnum].mutex); tmp_buf = map_word_load_partial(map, tmp_buf, buf, 0, len); ret = do_write_oneword(map, &cfi->chips[chipnum], ofs, tmp_buf, FL_WRITING); if (ret) return ret; (*retlen) += len; } return 0; } /* * FIXME: interleaved mode not tested, and probably not supported! */ static int __xipram do_write_buffer(struct map_info *map, struct flchip *chip, unsigned long adr, const u_char *buf, int len) { struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo = jiffies + HZ; /* * Timeout is calculated according to CFI data, if available. * See more comments in cfi_cmdset_0002(). */ unsigned long uWriteTimeout = usecs_to_jiffies(chip->buffer_write_time_max); int ret = -EIO; unsigned long cmd_adr; int z, words; map_word datum; adr += chip->start; cmd_adr = adr; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr, FL_WRITING); if (ret) { mutex_unlock(&chip->mutex); return ret; } datum = map_word_load(map, buf); pr_debug("MTD %s(): WRITE 0x%.8lx(0x%.8lx)\n", __func__, adr, datum.x[0]); XIP_INVAL_CACHED_RANGE(map, adr, len); ENABLE_VPP(map); xip_disable(map, chip, cmd_adr); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); /* Write Buffer Load */ map_write(map, CMD(0x25), cmd_adr); chip->state = FL_WRITING_TO_BUFFER; /* Write length of data to come */ words = len / map_bankwidth(map); map_write(map, CMD(words - 1), cmd_adr); /* Write data */ z = 0; while(z < words * map_bankwidth(map)) { datum = map_word_load(map, buf); map_write(map, datum, adr + z); z += map_bankwidth(map); buf += map_bankwidth(map); } z -= map_bankwidth(map); adr += z; /* Write Buffer Program Confirm: GO GO GO */ map_write(map, CMD(0x29), cmd_adr); chip->state = FL_WRITING; INVALIDATE_CACHE_UDELAY(map, chip, adr, map_bankwidth(map), chip->word_write_time); timeo = jiffies + uWriteTimeout; for (;;) { if (chip->state != FL_WRITING) { /* Someone's suspended the write. Sleep */ DECLARE_WAITQUEUE(wait, current); set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); timeo = jiffies + (HZ / 2); /* FIXME */ mutex_lock(&chip->mutex); continue; } if (time_after(jiffies, timeo) && !chip_ready(map, adr)) break; if (chip_good(map, adr, datum)) { xip_enable(map, chip, adr); goto op_done; } /* Latency issues. Drop the lock, wait a while and retry */ UDELAY(map, chip, adr, 1); } /* * Recovery from write-buffer programming failures requires * the write-to-buffer-reset sequence. Since the last part * of the sequence also works as a normal reset, we can run * the same commands regardless of why we are here. * See e.g. * http://www.spansion.com/Support/Application%20Notes/MirrorBit_Write_Buffer_Prog_Page_Buffer_Read_AN.pdf */ cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xF0, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); xip_enable(map, chip, adr); /* FIXME - should have reset delay before continuing */ printk(KERN_WARNING "MTD %s(): software timeout, address:0x%.8lx.\n", __func__, adr); ret = -EIO; op_done: chip->state = FL_READY; DISABLE_VPP(map); put_chip(map, chip, adr); mutex_unlock(&chip->mutex); return ret; } static int cfi_amdstd_write_buffers(struct mtd_info *mtd, loff_t to, size_t len, size_t *retlen, const u_char *buf) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int wbufsize = cfi_interleave(cfi) << cfi->cfiq->MaxBufWriteSize; int ret = 0; int chipnum; unsigned long ofs; chipnum = to >> cfi->chipshift; ofs = to - (chipnum << cfi->chipshift); /* If it's not bus-aligned, do the first word write */ if (ofs & (map_bankwidth(map)-1)) { size_t local_len = (-ofs)&(map_bankwidth(map)-1); if (local_len > len) local_len = len; ret = cfi_amdstd_write_words(mtd, ofs + (chipnum<<cfi->chipshift), local_len, retlen, buf); if (ret) return ret; ofs += local_len; buf += local_len; len -= local_len; if (ofs >> cfi->chipshift) { chipnum ++; ofs = 0; if (chipnum == cfi->numchips) return 0; } } /* Write buffer is worth it only if more than one word to write... */ while (len >= map_bankwidth(map) * 2) { /* We must not cross write block boundaries */ int size = wbufsize - (ofs & (wbufsize-1)); if (size > len) size = len; if (size % map_bankwidth(map)) size -= size % map_bankwidth(map); ret = do_write_buffer(map, &cfi->chips[chipnum], ofs, buf, size); if (ret) return ret; ofs += size; buf += size; (*retlen) += size; len -= size; if (ofs >> cfi->chipshift) { chipnum ++; ofs = 0; if (chipnum == cfi->numchips) return 0; } } if (len) { size_t retlen_dregs = 0; ret = cfi_amdstd_write_words(mtd, ofs + (chipnum<<cfi->chipshift), len, &retlen_dregs, buf); *retlen += retlen_dregs; return ret; } return 0; } /* * Wait for the flash chip to become ready to write data * * This is only called during the panic_write() path. When panic_write() * is called, the kernel is in the process of a panic, and will soon be * dead. Therefore we don't take any locks, and attempt to get access * to the chip as soon as possible. */ static int cfi_amdstd_panic_wait(struct map_info *map, struct flchip *chip, unsigned long adr) { struct cfi_private *cfi = map->fldrv_priv; int retries = 10; int i; /* * If the driver thinks the chip is idle, and no toggle bits * are changing, then the chip is actually idle for sure. */ if (chip->state == FL_READY && chip_ready(map, adr)) return 0; /* * Try several times to reset the chip and then wait for it * to become idle. The upper limit of a few milliseconds of * delay isn't a big problem: the kernel is dying anyway. It * is more important to save the messages. */ while (retries > 0) { const unsigned long timeo = (HZ / 1000) + 1; /* send the reset command */ map_write(map, CMD(0xF0), chip->start); /* wait for the chip to become ready */ for (i = 0; i < jiffies_to_usecs(timeo); i++) { if (chip_ready(map, adr)) return 0; udelay(1); } retries--; } /* the chip never became ready */ return -EBUSY; } /* * Write out one word of data to a single flash chip during a kernel panic * * This is only called during the panic_write() path. When panic_write() * is called, the kernel is in the process of a panic, and will soon be * dead. Therefore we don't take any locks, and attempt to get access * to the chip as soon as possible. * * The implementation of this routine is intentionally similar to * do_write_oneword(), in order to ease code maintenance. */ static int do_panic_write_oneword(struct map_info *map, struct flchip *chip, unsigned long adr, map_word datum) { const unsigned long uWriteTimeout = (HZ / 1000) + 1; struct cfi_private *cfi = map->fldrv_priv; int retry_cnt = 0; map_word oldd; int ret = 0; int i; adr += chip->start; ret = cfi_amdstd_panic_wait(map, chip, adr); if (ret) return ret; pr_debug("MTD %s(): PANIC WRITE 0x%.8lx(0x%.8lx)\n", __func__, adr, datum.x[0]); /* * Check for a NOP for the case when the datum to write is already * present - it saves time and works around buggy chips that corrupt * data at other locations when 0xff is written to a location that * already contains 0xff. */ oldd = map_read(map, adr); if (map_word_equal(map, oldd, datum)) { pr_debug("MTD %s(): NOP\n", __func__); goto op_done; } ENABLE_VPP(map); retry: cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xA0, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); map_write(map, datum, adr); for (i = 0; i < jiffies_to_usecs(uWriteTimeout); i++) { if (chip_ready(map, adr)) break; udelay(1); } if (!chip_good(map, adr, datum)) { /* reset on all failures. */ map_write(map, CMD(0xF0), chip->start); /* FIXME - should have reset delay before continuing */ if (++retry_cnt <= MAX_RETRIES) goto retry; ret = -EIO; } op_done: DISABLE_VPP(map); return ret; } /* * Write out some data during a kernel panic * * This is used by the mtdoops driver to save the dying messages from a * kernel which has panic'd. * * This routine ignores all of the locking used throughout the rest of the * driver, in order to ensure that the data gets written out no matter what * state this driver (and the flash chip itself) was in when the kernel crashed. * * The implementation of this routine is intentionally similar to * cfi_amdstd_write_words(), in order to ease code maintenance. */ static int cfi_amdstd_panic_write(struct mtd_info *mtd, loff_t to, size_t len, size_t *retlen, const u_char *buf) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; unsigned long ofs, chipstart; int ret = 0; int chipnum; chipnum = to >> cfi->chipshift; ofs = to - (chipnum << cfi->chipshift); chipstart = cfi->chips[chipnum].start; /* If it's not bus aligned, do the first byte write */ if (ofs & (map_bankwidth(map) - 1)) { unsigned long bus_ofs = ofs & ~(map_bankwidth(map) - 1); int i = ofs - bus_ofs; int n = 0; map_word tmp_buf; ret = cfi_amdstd_panic_wait(map, &cfi->chips[chipnum], bus_ofs); if (ret) return ret; /* Load 'tmp_buf' with old contents of flash */ tmp_buf = map_read(map, bus_ofs + chipstart); /* Number of bytes to copy from buffer */ n = min_t(int, len, map_bankwidth(map) - i); tmp_buf = map_word_load_partial(map, tmp_buf, buf, i, n); ret = do_panic_write_oneword(map, &cfi->chips[chipnum], bus_ofs, tmp_buf); if (ret) return ret; ofs += n; buf += n; (*retlen) += n; len -= n; if (ofs >> cfi->chipshift) { chipnum++; ofs = 0; if (chipnum == cfi->numchips) return 0; } } /* We are now aligned, write as much as possible */ while (len >= map_bankwidth(map)) { map_word datum; datum = map_word_load(map, buf); ret = do_panic_write_oneword(map, &cfi->chips[chipnum], ofs, datum); if (ret) return ret; ofs += map_bankwidth(map); buf += map_bankwidth(map); (*retlen) += map_bankwidth(map); len -= map_bankwidth(map); if (ofs >> cfi->chipshift) { chipnum++; ofs = 0; if (chipnum == cfi->numchips) return 0; chipstart = cfi->chips[chipnum].start; } } /* Write the trailing bytes if any */ if (len & (map_bankwidth(map) - 1)) { map_word tmp_buf; ret = cfi_amdstd_panic_wait(map, &cfi->chips[chipnum], ofs); if (ret) return ret; tmp_buf = map_read(map, ofs + chipstart); tmp_buf = map_word_load_partial(map, tmp_buf, buf, 0, len); ret = do_panic_write_oneword(map, &cfi->chips[chipnum], ofs, tmp_buf); if (ret) return ret; (*retlen) += len; } return 0; } /* * Handle devices with one erase region, that only implement * the chip erase command. */ static int __xipram do_erase_chip(struct map_info *map, struct flchip *chip) { struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo = jiffies + HZ; unsigned long int adr; DECLARE_WAITQUEUE(wait, current); int ret = 0; int retry_cnt = 0; adr = cfi->addr_unlock1; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr, FL_WRITING); if (ret) { mutex_unlock(&chip->mutex); return ret; } pr_debug("MTD %s(): ERASE 0x%.8lx\n", __func__, chip->start); XIP_INVAL_CACHED_RANGE(map, adr, map->size); ENABLE_VPP(map); xip_disable(map, chip, adr); retry: cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x80, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x10, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); chip->state = FL_ERASING; chip->erase_suspended = 0; chip->in_progress_block_addr = adr; chip->in_progress_block_mask = ~(map->size - 1); INVALIDATE_CACHE_UDELAY(map, chip, adr, map->size, chip->erase_time*500); timeo = jiffies + (HZ*20); for (;;) { if (chip->state != FL_ERASING) { /* Someone's suspended the erase. Sleep */ set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); mutex_lock(&chip->mutex); continue; } if (chip->erase_suspended) { /* This erase was suspended and resumed. Adjust the timeout */ timeo = jiffies + (HZ*20); /* FIXME */ chip->erase_suspended = 0; } if (chip_good(map, adr, map_word_ff(map))) break; if (time_after(jiffies, timeo)) { printk(KERN_WARNING "MTD %s(): software timeout\n", __func__); ret = -EIO; break; } /* Latency issues. Drop the lock, wait a while and retry */ UDELAY(map, chip, adr, 1000000/HZ); } /* Did we succeed? */ if (ret) { /* reset on all failures. */ map_write(map, CMD(0xF0), chip->start); /* FIXME - should have reset delay before continuing */ if (++retry_cnt <= MAX_RETRIES) { ret = 0; goto retry; } } chip->state = FL_READY; xip_enable(map, chip, adr); DISABLE_VPP(map); put_chip(map, chip, adr); mutex_unlock(&chip->mutex); return ret; } static int __xipram do_erase_oneblock(struct map_info *map, struct flchip *chip, unsigned long adr, int len, void *thunk) { struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo = jiffies + HZ; DECLARE_WAITQUEUE(wait, current); int ret = 0; int retry_cnt = 0; adr += chip->start; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr, FL_ERASING); if (ret) { mutex_unlock(&chip->mutex); return ret; } pr_debug("MTD %s(): ERASE 0x%.8lx\n", __func__, adr); XIP_INVAL_CACHED_RANGE(map, adr, len); ENABLE_VPP(map); xip_disable(map, chip, adr); retry: cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x80, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); map_write(map, cfi->sector_erase_cmd, adr); chip->state = FL_ERASING; chip->erase_suspended = 0; chip->in_progress_block_addr = adr; chip->in_progress_block_mask = ~(len - 1); INVALIDATE_CACHE_UDELAY(map, chip, adr, len, chip->erase_time*500); timeo = jiffies + (HZ*20); for (;;) { if (chip->state != FL_ERASING) { /* Someone's suspended the erase. Sleep */ set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); mutex_lock(&chip->mutex); continue; } if (chip->erase_suspended) { /* This erase was suspended and resumed. Adjust the timeout */ timeo = jiffies + (HZ*20); /* FIXME */ chip->erase_suspended = 0; } if (chip_good(map, adr, map_word_ff(map))) break; if (time_after(jiffies, timeo)) { printk(KERN_WARNING "MTD %s(): software timeout\n", __func__); ret = -EIO; break; } /* Latency issues. Drop the lock, wait a while and retry */ UDELAY(map, chip, adr, 1000000/HZ); } /* Did we succeed? */ if (ret) { /* reset on all failures. */ map_write(map, CMD(0xF0), chip->start); /* FIXME - should have reset delay before continuing */ if (++retry_cnt <= MAX_RETRIES) { ret = 0; goto retry; } } chip->state = FL_READY; xip_enable(map, chip, adr); DISABLE_VPP(map); put_chip(map, chip, adr); mutex_unlock(&chip->mutex); return ret; } static int cfi_amdstd_erase_varsize(struct mtd_info *mtd, struct erase_info *instr) { return cfi_varsize_frob(mtd, do_erase_oneblock, instr->addr, instr->len, NULL); } static int cfi_amdstd_erase_chip(struct mtd_info *mtd, struct erase_info *instr) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; if (instr->addr != 0) return -EINVAL; if (instr->len != mtd->size) return -EINVAL; return do_erase_chip(map, &cfi->chips[0]); } static int do_atmel_lock(struct map_info *map, struct flchip *chip, unsigned long adr, int len, void *thunk) { struct cfi_private *cfi = map->fldrv_priv; int ret; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr + chip->start, FL_LOCKING); if (ret) goto out_unlock; chip->state = FL_LOCKING; pr_debug("MTD %s(): LOCK 0x%08lx len %d\n", __func__, adr, len); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x80, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); map_write(map, CMD(0x40), chip->start + adr); chip->state = FL_READY; put_chip(map, chip, adr + chip->start); ret = 0; out_unlock: mutex_unlock(&chip->mutex); return ret; } static int do_atmel_unlock(struct map_info *map, struct flchip *chip, unsigned long adr, int len, void *thunk) { struct cfi_private *cfi = map->fldrv_priv; int ret; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr + chip->start, FL_UNLOCKING); if (ret) goto out_unlock; chip->state = FL_UNLOCKING; pr_debug("MTD %s(): LOCK 0x%08lx len %d\n", __func__, adr, len); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); map_write(map, CMD(0x70), adr); chip->state = FL_READY; put_chip(map, chip, adr + chip->start); ret = 0; out_unlock: mutex_unlock(&chip->mutex); return ret; } static int cfi_atmel_lock(struct mtd_info *mtd, loff_t ofs, uint64_t len) { return cfi_varsize_frob(mtd, do_atmel_lock, ofs, len, NULL); } static int cfi_atmel_unlock(struct mtd_info *mtd, loff_t ofs, uint64_t len) { return cfi_varsize_frob(mtd, do_atmel_unlock, ofs, len, NULL); } /* * Advanced Sector Protection - PPB (Persistent Protection Bit) locking */ struct ppb_lock { struct flchip *chip; unsigned long adr; int locked; }; #define MAX_SECTORS 512 #define DO_XXLOCK_ONEBLOCK_LOCK ((void *)1) #define DO_XXLOCK_ONEBLOCK_UNLOCK ((void *)2) #define DO_XXLOCK_ONEBLOCK_GETLOCK ((void *)3) static int __maybe_unused do_ppb_xxlock(struct map_info *map, struct flchip *chip, unsigned long adr, int len, void *thunk) { struct cfi_private *cfi = map->fldrv_priv; unsigned long timeo; int ret; adr += chip->start; mutex_lock(&chip->mutex); ret = get_chip(map, chip, adr, FL_LOCKING); if (ret) { mutex_unlock(&chip->mutex); return ret; } pr_debug("MTD %s(): XXLOCK 0x%08lx len %d\n", __func__, adr, len); cfi_send_gen_cmd(0xAA, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); cfi_send_gen_cmd(0x55, cfi->addr_unlock2, chip->start, map, cfi, cfi->device_type, NULL); /* PPB entry command */ cfi_send_gen_cmd(0xC0, cfi->addr_unlock1, chip->start, map, cfi, cfi->device_type, NULL); if (thunk == DO_XXLOCK_ONEBLOCK_LOCK) { chip->state = FL_LOCKING; map_write(map, CMD(0xA0), adr); map_write(map, CMD(0x00), adr); } else if (thunk == DO_XXLOCK_ONEBLOCK_UNLOCK) { /* * Unlocking of one specific sector is not supported, so we * have to unlock all sectors of this device instead */ chip->state = FL_UNLOCKING; map_write(map, CMD(0x80), chip->start); map_write(map, CMD(0x30), chip->start); } else if (thunk == DO_XXLOCK_ONEBLOCK_GETLOCK) { chip->state = FL_JEDEC_QUERY; /* Return locked status: 0->locked, 1->unlocked */ ret = !cfi_read_query(map, adr); } else BUG(); /* * Wait for some time as unlocking of all sectors takes quite long */ timeo = jiffies + msecs_to_jiffies(2000); /* 2s max (un)locking */ for (;;) { if (chip_ready(map, adr)) break; if (time_after(jiffies, timeo)) { printk(KERN_ERR "Waiting for chip to be ready timed out.\n"); ret = -EIO; break; } UDELAY(map, chip, adr, 1); } /* Exit BC commands */ map_write(map, CMD(0x90), chip->start); map_write(map, CMD(0x00), chip->start); chip->state = FL_READY; put_chip(map, chip, adr); mutex_unlock(&chip->mutex); return ret; } static int __maybe_unused cfi_ppb_lock(struct mtd_info *mtd, loff_t ofs, uint64_t len) { return cfi_varsize_frob(mtd, do_ppb_xxlock, ofs, len, DO_XXLOCK_ONEBLOCK_LOCK); } static int __maybe_unused cfi_ppb_unlock(struct mtd_info *mtd, loff_t ofs, uint64_t len) { struct mtd_erase_region_info *regions = mtd->eraseregions; struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; struct ppb_lock *sect; unsigned long adr; loff_t offset; uint64_t length; int chipnum; int i; int sectors; int ret; /* * PPB unlocking always unlocks all sectors of the flash chip. * We need to re-lock all previously locked sectors. So lets * first check the locking status of all sectors and save * it for future use. */ sect = kcalloc(MAX_SECTORS, sizeof(struct ppb_lock), GFP_KERNEL); if (!sect) return -ENOMEM; /* * This code to walk all sectors is a slightly modified version * of the cfi_varsize_frob() code. */ i = 0; chipnum = 0; adr = 0; sectors = 0; offset = 0; length = mtd->size; while (length) { int size = regions[i].erasesize; /* * Only test sectors that shall not be unlocked. The other * sectors shall be unlocked, so lets keep their locking * status at "unlocked" (locked=0) for the final re-locking. */ if ((offset < ofs) || (offset >= (ofs + len))) { sect[sectors].chip = &cfi->chips[chipnum]; sect[sectors].adr = adr; sect[sectors].locked = do_ppb_xxlock( map, &cfi->chips[chipnum], adr, 0, DO_XXLOCK_ONEBLOCK_GETLOCK); } adr += size; offset += size; length -= size; if (offset == regions[i].offset + size * regions[i].numblocks) i++; if (adr >> cfi->chipshift) { if (offset >= (ofs + len)) break; adr = 0; chipnum++; if (chipnum >= cfi->numchips) break; } sectors++; if (sectors >= MAX_SECTORS) { printk(KERN_ERR "Only %d sectors for PPB locking supported!\n", MAX_SECTORS); kfree(sect); return -EINVAL; } } /* Now unlock the whole chip */ ret = cfi_varsize_frob(mtd, do_ppb_xxlock, ofs, len, DO_XXLOCK_ONEBLOCK_UNLOCK); if (ret) { kfree(sect); return ret; } /* * PPB unlocking always unlocks all sectors of the flash chip. * We need to re-lock all previously locked sectors. */ for (i = 0; i < sectors; i++) { if (sect[i].locked) do_ppb_xxlock(map, sect[i].chip, sect[i].adr, 0, DO_XXLOCK_ONEBLOCK_LOCK); } kfree(sect); return ret; } static int __maybe_unused cfi_ppb_is_locked(struct mtd_info *mtd, loff_t ofs, uint64_t len) { return cfi_varsize_frob(mtd, do_ppb_xxlock, ofs, len, DO_XXLOCK_ONEBLOCK_GETLOCK) ? 1 : 0; } static void cfi_amdstd_sync (struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int i; struct flchip *chip; int ret = 0; DECLARE_WAITQUEUE(wait, current); for (i=0; !ret && i<cfi->numchips; i++) { chip = &cfi->chips[i]; retry: mutex_lock(&chip->mutex); switch(chip->state) { case FL_READY: case FL_STATUS: case FL_CFI_QUERY: case FL_JEDEC_QUERY: chip->oldstate = chip->state; chip->state = FL_SYNCING; /* No need to wake_up() on this state change - * as the whole point is that nobody can do anything * with the chip now anyway. */ case FL_SYNCING: mutex_unlock(&chip->mutex); break; default: /* Not an idle state */ set_current_state(TASK_UNINTERRUPTIBLE); add_wait_queue(&chip->wq, &wait); mutex_unlock(&chip->mutex); schedule(); remove_wait_queue(&chip->wq, &wait); goto retry; } } /* Unlock the chips again */ for (i--; i >=0; i--) { chip = &cfi->chips[i]; mutex_lock(&chip->mutex); if (chip->state == FL_SYNCING) { chip->state = chip->oldstate; wake_up(&chip->wq); } mutex_unlock(&chip->mutex); } } static int cfi_amdstd_suspend(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int i; struct flchip *chip; int ret = 0; for (i=0; !ret && i<cfi->numchips; i++) { chip = &cfi->chips[i]; mutex_lock(&chip->mutex); switch(chip->state) { case FL_READY: case FL_STATUS: case FL_CFI_QUERY: case FL_JEDEC_QUERY: chip->oldstate = chip->state; chip->state = FL_PM_SUSPENDED; /* No need to wake_up() on this state change - * as the whole point is that nobody can do anything * with the chip now anyway. */ case FL_PM_SUSPENDED: break; default: ret = -EAGAIN; break; } mutex_unlock(&chip->mutex); } /* Unlock the chips again */ if (ret) { for (i--; i >=0; i--) { chip = &cfi->chips[i]; mutex_lock(&chip->mutex); if (chip->state == FL_PM_SUSPENDED) { chip->state = chip->oldstate; wake_up(&chip->wq); } mutex_unlock(&chip->mutex); } } return ret; } static void cfi_amdstd_resume(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int i; struct flchip *chip; for (i=0; i<cfi->numchips; i++) { chip = &cfi->chips[i]; mutex_lock(&chip->mutex); if (chip->state == FL_PM_SUSPENDED) { chip->state = FL_READY; map_write(map, CMD(0xF0), chip->start); wake_up(&chip->wq); } else printk(KERN_ERR "Argh. Chip not in PM_SUSPENDED state upon resume()\n"); mutex_unlock(&chip->mutex); } } /* * Ensure that the flash device is put back into read array mode before * unloading the driver or rebooting. On some systems, rebooting while * the flash is in query/program/erase mode will prevent the CPU from * fetching the bootloader code, requiring a hard reset or power cycle. */ static int cfi_amdstd_reset(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; int i, ret; struct flchip *chip; for (i = 0; i < cfi->numchips; i++) { chip = &cfi->chips[i]; mutex_lock(&chip->mutex); ret = get_chip(map, chip, chip->start, FL_SHUTDOWN); if (!ret) { map_write(map, CMD(0xF0), chip->start); chip->state = FL_SHUTDOWN; put_chip(map, chip, chip->start); } mutex_unlock(&chip->mutex); } return 0; } static int cfi_amdstd_reboot(struct notifier_block *nb, unsigned long val, void *v) { struct mtd_info *mtd; mtd = container_of(nb, struct mtd_info, reboot_notifier); cfi_amdstd_reset(mtd); return NOTIFY_DONE; } static void cfi_amdstd_destroy(struct mtd_info *mtd) { struct map_info *map = mtd->priv; struct cfi_private *cfi = map->fldrv_priv; cfi_amdstd_reset(mtd); unregister_reboot_notifier(&mtd->reboot_notifier); kfree(cfi->cmdset_priv); kfree(cfi->cfiq); kfree(cfi); kfree(mtd->eraseregions); } MODULE_LICENSE("GPL"); MODULE_AUTHOR("Crossnet Co. <info@crossnet.co.jp> et al."); MODULE_DESCRIPTION("MTD chip driver for AMD/Fujitsu flash chips"); MODULE_ALIAS("cfi_cmdset_0006"); MODULE_ALIAS("cfi_cmdset_0701");
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