/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2021 Aidan MacDonald * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "nand-x1000.h" #include "sfc-x1000.h" #include "system.h" #include "logf.h" #include static void winbond_setup_chip(struct nand_drv* drv); static const struct nand_chip chip_ato25d1ga = { .log2_ppb = 6, /* 64 pages */ .page_size = 2048, .oob_size = 64, .nr_blocks = 1024, .bbm_pos = 2048, .clock_freq = 150000000, .dev_conf = jz_orf(SFC_DEV_CONF, CE_DL(1), HOLD_DL(1), WP_DL(1), CPHA(0), CPOL(0), TSH(7), TSETUP(0), THOLD(0), STA_TYPE_V(1BYTE), CMD_TYPE_V(8BITS), SMP_DELAY(1)), .flags = NAND_CHIPFLAG_QUAD | NAND_CHIPFLAG_HAS_QE_BIT, .cmd_page_read = NANDCMD_PAGE_READ, .cmd_program_execute = NANDCMD_PROGRAM_EXECUTE, .cmd_block_erase = NANDCMD_BLOCK_ERASE, .cmd_read_cache = NANDCMD_READ_CACHE_x4, .cmd_program_load = NANDCMD_PROGRAM_LOAD_x4, }; static const struct nand_chip chip_w25n01gvxx = { .log2_ppb = 6, /* 64 pages */ .page_size = 2048, .oob_size = 64, .nr_blocks = 1024, .bbm_pos = 2048, .clock_freq = 150000000, .dev_conf = jz_orf(SFC_DEV_CONF, CE_DL(1), HOLD_DL(1), WP_DL(1), CPHA(0), CPOL(0), TSH(11), TSETUP(0), THOLD(0), STA_TYPE_V(1BYTE), CMD_TYPE_V(8BITS), SMP_DELAY(1)), .flags = NAND_CHIPFLAG_ON_DIE_ECC, /* TODO: quad mode? */ .cmd_page_read = NANDCMD_PAGE_READ, .cmd_program_execute = NANDCMD_PROGRAM_EXECUTE, .cmd_block_erase = NANDCMD_BLOCK_ERASE, .cmd_read_cache = NANDCMD_READ_CACHE_SLOW, .cmd_program_load = NANDCMD_PROGRAM_LOAD, .setup_chip = winbond_setup_chip, }; static const struct nand_chip chip_gd5f1gq4xexx = { .log2_ppb = 6, /* 64 pages */ .page_size = 2048, .oob_size = 64, /* 128B when hardware ECC is disabled */ .nr_blocks = 1024, .bbm_pos = 2048, .clock_freq = 150000000, .dev_conf = jz_orf(SFC_DEV_CONF, CE_DL(1), HOLD_DL(1), WP_DL(1), CPHA(0), CPOL(0), TSH(7), TSETUP(0), THOLD(0), STA_TYPE_V(1BYTE), CMD_TYPE_V(8BITS), SMP_DELAY(1)), .flags = NAND_CHIPFLAG_QUAD | NAND_CHIPFLAG_HAS_QE_BIT | NAND_CHIPFLAG_ON_DIE_ECC, .cmd_page_read = NANDCMD_PAGE_READ, .cmd_program_execute = NANDCMD_PROGRAM_EXECUTE, .cmd_block_erase = NANDCMD_BLOCK_ERASE, .cmd_read_cache = NANDCMD_READ_CACHE_x4, .cmd_program_load = NANDCMD_PROGRAM_LOAD_x4, }; #define chip_ds35x1gaxxx chip_gd5f1gq4xexx const struct nand_chip_id supported_nand_chips[] = { NAND_CHIP_ID(&chip_ato25d1ga, NAND_READID_ADDR, 0x9b, 0x12), NAND_CHIP_ID(&chip_w25n01gvxx, NAND_READID_ADDR, 0xef, 0xaa, 0x21), NAND_CHIP_ID(&chip_gd5f1gq4xexx, NAND_READID_ADDR, 0xc8, 0xd1), NAND_CHIP_ID(&chip_gd5f1gq4xexx, NAND_READID_ADDR, 0xc8, 0xc1), NAND_CHIP_ID(&chip_ds35x1gaxxx, NAND_READID_ADDR, 0xe5, 0x71), /* 3.3 V */ NAND_CHIP_ID(&chip_ds35x1gaxxx, NAND_READID_ADDR, 0xe5, 0x21), /* 1.8 V */ }; const size_t nr_supported_nand_chips = ARRAYLEN(supported_nand_chips); static struct nand_drv static_nand_drv; static uint8_t static_scratch_buf[NAND_DRV_SCRATCHSIZE] CACHEALIGN_ATTR; static uint8_t static_page_buf[NAND_DRV_MAXPAGESIZE] CACHEALIGN_ATTR; struct nand_drv* nand_init(void) { static bool inited = false; if(!inited) { mutex_init(&static_nand_drv.mutex); static_nand_drv.scratch_buf = static_scratch_buf; static_nand_drv.page_buf = static_page_buf; static_nand_drv.refcount = 0; } return &static_nand_drv; } static uint8_t nand_get_reg(struct nand_drv* drv, uint8_t reg) { sfc_exec(NANDCMD_GET_FEATURE, reg, drv->scratch_buf, 1|SFC_READ); return drv->scratch_buf[0]; } static void nand_set_reg(struct nand_drv* drv, uint8_t reg, uint8_t val) { drv->scratch_buf[0] = val; sfc_exec(NANDCMD_SET_FEATURE, reg, drv->scratch_buf, 1|SFC_WRITE); } static void nand_upd_reg(struct nand_drv* drv, uint8_t reg, uint8_t msk, uint8_t val) { uint8_t x = nand_get_reg(drv, reg); x &= ~msk; x |= val; nand_set_reg(drv, reg, x); } static const struct nand_chip* identify_chip_method(uint8_t method, const uint8_t* id_buf) { for (size_t i = 0; i < nr_supported_nand_chips; ++i) { const struct nand_chip_id* chip_id = &supported_nand_chips[i]; if (chip_id->method == method && !memcmp(chip_id->id_bytes, id_buf, chip_id->num_id_bytes)) return chip_id->chip; } return NULL; } static bool identify_chip(struct nand_drv* drv) { /* Read ID command has some variations; Linux handles these 3: * - no address or dummy bytes * - 1 byte address, no dummy byte * - no address byte, 1 byte dummy * * Currently we use the 2nd method, aka. address read ID, the * other methods can be added when needed. */ sfc_exec(NANDCMD_READID_ADDR, 0, drv->scratch_buf, 4|SFC_READ); drv->chip = identify_chip_method(NAND_READID_ADDR, drv->scratch_buf); if (drv->chip) return true; return false; } static void setup_chip_data(struct nand_drv* drv) { drv->ppb = 1 << drv->chip->log2_ppb; drv->fpage_size = drv->chip->page_size + drv->chip->oob_size; } static void winbond_setup_chip(struct nand_drv* drv) { /* Ensure we are in buffered read mode. */ nand_upd_reg(drv, FREG_CFG, FREG_CFG_WINBOND_BUF, FREG_CFG_WINBOND_BUF); } static void setup_chip_registers(struct nand_drv* drv) { /* Set chip registers to enter normal operation */ if(drv->chip->flags & NAND_CHIPFLAG_HAS_QE_BIT) { bool en = (drv->chip->flags & NAND_CHIPFLAG_QUAD) != 0; nand_upd_reg(drv, FREG_CFG, FREG_CFG_QUAD_ENABLE, en ? FREG_CFG_QUAD_ENABLE : 0); } if(drv->chip->flags & NAND_CHIPFLAG_ON_DIE_ECC) { /* Enable on-die ECC */ nand_upd_reg(drv, FREG_CFG, FREG_CFG_ECC_ENABLE, FREG_CFG_ECC_ENABLE); } /* Clear OTP bit to access the main data array */ nand_upd_reg(drv, FREG_CFG, FREG_CFG_OTP_ENABLE, 0); /* Clear write protection bits */ nand_set_reg(drv, FREG_PROT, FREG_PROT_UNLOCK); /* Call any chip-specific hooks */ if(drv->chip->setup_chip) drv->chip->setup_chip(drv); } int nand_open(struct nand_drv* drv) { if(drv->refcount > 0) { drv->refcount++; return NAND_SUCCESS; } /* Initialize the controller */ sfc_open(); sfc_set_dev_conf(jz_orf(SFC_DEV_CONF, CE_DL(1), HOLD_DL(1), WP_DL(1), CPHA(0), CPOL(0), TSH(15), TSETUP(0), THOLD(0), STA_TYPE_V(1BYTE), CMD_TYPE_V(8BITS), SMP_DELAY(0))); sfc_set_clock(X1000_EXCLK_FREQ); /* Send the software reset command */ sfc_exec(NANDCMD_RESET, 0, NULL, 0); mdelay(10); /* Chip identification and setup */ if(!identify_chip(drv)) return NAND_ERR_UNKNOWN_CHIP; setup_chip_data(drv); /* Set new SFC parameters */ sfc_set_dev_conf(drv->chip->dev_conf); sfc_set_clock(drv->chip->clock_freq); /* Enter normal operating mode */ setup_chip_registers(drv); drv->refcount++; return NAND_SUCCESS; } void nand_close(struct nand_drv* drv) { --drv->refcount; if(drv->refcount > 0) return; /* Let's reset the chip... the idea is to restore the registers * to whatever they should "normally" be */ sfc_exec(NANDCMD_RESET, 0, NULL, 0); mdelay(10); sfc_close(); } void nand_enable_otp(struct nand_drv* drv, bool enable) { nand_upd_reg(drv, FREG_CFG, FREG_CFG_OTP_ENABLE, enable ? FREG_CFG_OTP_ENABLE : 0); } static uint8_t nand_wait_busy(struct nand_drv* drv) { uint8_t reg; do { reg = nand_get_reg(drv, FREG_STATUS); } while(reg & FREG_STATUS_BUSY); return reg; } int nand_block_erase(struct nand_drv* drv, nand_block_t block) { sfc_exec(NANDCMD_WR_EN, 0, NULL, 0); sfc_exec(drv->chip->cmd_block_erase, block, NULL, 0); uint8_t status = nand_wait_busy(drv); if(status & FREG_STATUS_EFAIL) return NAND_ERR_ERASE_FAIL; else return NAND_SUCCESS; } int nand_page_program(struct nand_drv* drv, nand_page_t page, const void* buffer) { sfc_exec(NANDCMD_WR_EN, 0, NULL, 0); sfc_exec(drv->chip->cmd_program_load, 0, (void*)buffer, drv->fpage_size|SFC_WRITE); sfc_exec(drv->chip->cmd_program_execute, page, NULL, 0); uint8_t status = nand_wait_busy(drv); if(status & FREG_STATUS_PFAIL) return NAND_ERR_PROGRAM_FAIL; else return NAND_SUCCESS; } int nand_page_read(struct nand_drv* drv, nand_page_t page, void* buffer) { sfc_exec(drv->chip->cmd_page_read, page, NULL, 0); nand_wait_busy(drv); sfc_exec(drv->chip->cmd_read_cache, 0, buffer, drv->fpage_size|SFC_READ); if(drv->chip->flags & NAND_CHIPFLAG_ON_DIE_ECC) { uint8_t status = nand_get_reg(drv, FREG_STATUS); if(status & FREG_STATUS_ECC_UNCOR_ERR) { logf("ecc uncorrectable error on page %08lx", (unsigned long)page); return NAND_ERR_ECC_FAIL; } if(status & FREG_STATUS_ECC_HAS_FLIPS) { logf("ecc corrected bitflips on page %08lx", (unsigned long)page); } } return NAND_SUCCESS; } int nand_read_bytes(struct nand_drv* drv, uint32_t byte_addr, uint32_t byte_len, void* buffer) { if(byte_len == 0) return NAND_SUCCESS; int rc; unsigned pg_size = drv->chip->page_size; nand_page_t page = byte_addr / pg_size; unsigned offset = byte_addr % pg_size; while(1) { rc = nand_page_read(drv, page, drv->page_buf); if(rc < 0) return rc; memcpy(buffer, &drv->page_buf[offset], MIN(pg_size - offset, byte_len)); if(byte_len <= pg_size - offset) break; byte_len -= pg_size - offset; buffer += pg_size - offset; offset = 0; page++; } return NAND_SUCCESS; } int nand_write_bytes(struct nand_drv* drv, uint32_t byte_addr, uint32_t byte_len, const void* buffer) { if(byte_len == 0) return NAND_SUCCESS; int rc; unsigned pg_size = drv->chip->page_size; unsigned blk_size = pg_size << drv->chip->log2_ppb; if(byte_addr % blk_size != 0) return NAND_ERR_UNALIGNED; if(byte_len % blk_size != 0) return NAND_ERR_UNALIGNED; nand_page_t page = byte_addr / pg_size; nand_page_t end_page = page + (byte_len / pg_size); for(nand_block_t blk = page; blk < end_page; blk += drv->ppb) { rc = nand_block_erase(drv, blk); if(rc < 0) return rc; } for(; page != end_page; ++page) { memcpy(drv->page_buf, buffer, pg_size); memset(&drv->page_buf[pg_size], 0xff, drv->chip->oob_size); buffer += pg_size; rc = nand_page_program(drv, page, drv->page_buf); if(rc < 0) return rc; } return NAND_SUCCESS; } /* TODO - NAND driver future improvements * * 1. Support sofware or on-die ECC transparently. Support debug ECC bypass. * * It's probably best to add an API call to turn ECC on or off. Software * ECC and most or all on-die ECC implementations require some OOB bytes * to function; which leads us to the next problem... * * 2. Allow safe access to OOB areas * * The OOB data area is not fully available to users; it is also occupied * by ECC data and bad block markings. The NAND driver needs to provide a * mapping which allows OOB data users to map around those reserved areas, * otherwise it's not really possible to use OOB data. * * 3. Support partial page programming. * * This might already work. My understanding of NAND flash is that bits are * represented by charge deposited on flash cells. In the case of SLC flash, * cells are one bit. For MLC flash, cells can store more than one bit; but * MLC flash is much less reliable than SLC. We probably don't have to be * concerned about MLC flash, and its does not support partial programming * anyway due to the cell characteristics, so I will only consider SLC here. * * For SLC there are two cell states -- an uncharged cell represents a "1" * and a charged cell represents "0". Programming can only deposit charge * on a cell and erasing can only remove charge. Therefore, "programming" a * cell to 1 is actually a no-op. * * So, there's no datasheet which spells this out, but I suspect you just * set the areas you're not interested in programming to 0xff. Programming * can never change a written 0 back to a 1, so programming a 1 bit works * more like a "don't care" (= keep whatever value is already there). * * What _is_ given by the datasheets is limits on how many times you can * reprogram the same page without erasing it. This is an overall limit * called NOP (number of programs) in many datasheets. In addition to this, * sub-regions of the page have further limits: it's common for a 2048+64 * byte page to be split into 8 regions, with four 512-byte main areas and * four 16-byte OOB areas. Usually, each subregion can only be programmed * once. However, you can write multiple subregions with a single program. * * Violating programming constraints could cause data loss, so we need to * communicate to upper layers what the limitations are here if they want * to use partial programming safely. * * Programming the same page more than once increases the overall stress * on the flash cells and can cause bitflips. For this reason, it's best * to keep the number of programs as low as possible. Some sources suggest * that programming the pages in a block in linear order is also better to * reduce stress, although I don't know why this would be. * * These program/read stresses can flip bits, but it's only due to residual * charge building up on uncharged cells; cells are not permanently damaged * by these kind of stresses. Erasing the block will remove the charge and * restore all the cells to a clean state. * * These slides are fairly informative on this subject: * - https://cushychicken.github.io/assets/cooke_inconvenient_truths.pdf * * 4. Bad block management * * This probably doesn't belong in the NAND layer but it seems wise to keep * at least a bad block table at the level of the NAND driver. Factory bad * block marks are usually some non-0xFF byte in the OOB area, but bad blocks * which develop over the device lifetime usually won't be marked; after all * they are unreliable, so we can't program a marking on them and expect it * to stick. So, most FTL systems keep a bad block table somewhere in flash * and update it whenever a block goes bad. * * So, in addition to a bad block marker scan, we should try to gather bad * block information from such tables. */