dev/nand/nand.c

1.8  ahoka /*	$NetBSD: nand.c,v 1.8 2011/04/10 12:48:09 ahoka Exp $	*/
1.1  ahoka
1.1  ahoka /*-
1.1  ahoka  * Copyright (c) 2010 Department of Software Engineering,
1.1  ahoka  *		      University of Szeged, Hungary
1.1  ahoka  * Copyright (c) 2010 Adam Hoka <ahoka (at) NetBSD.org>
1.1  ahoka  * All rights reserved.
1.1  ahoka  *
1.1  ahoka  * This code is derived from software contributed to The NetBSD Foundation
1.1  ahoka  * by the Department of Software Engineering, University of Szeged, Hungary
1.1  ahoka  *
1.1  ahoka  * Redistribution and use in source and binary forms, with or without
1.1  ahoka  * modification, are permitted provided that the following conditions
1.1  ahoka  * are met:
1.1  ahoka  * 1. Redistributions of source code must retain the above copyright
1.1  ahoka  *    notice, this list of conditions and the following disclaimer.
1.1  ahoka  * 2. Redistributions in binary form must reproduce the above copyright
1.1  ahoka  *    notice, this list of conditions and the following disclaimer in the
1.1  ahoka  *    documentation and/or other materials provided with the distribution.
1.1  ahoka  *
1.1  ahoka  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1  ahoka  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1  ahoka  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1  ahoka  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1  ahoka  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
1.1  ahoka  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
1.1  ahoka  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
1.1  ahoka  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
1.1  ahoka  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  ahoka  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  ahoka  * SUCH DAMAGE.
1.1  ahoka  */
1.1  ahoka
1.1  ahoka /* Common driver for NAND chips implementing the ONFI 2.2 specification */
1.1  ahoka
1.1  ahoka #include <sys/cdefs.h>
1.8  ahoka __KERNEL_RCSID(0, "$NetBSD: nand.c,v 1.8 2011/04/10 12:48:09 ahoka Exp $");
1.1  ahoka
1.1  ahoka #include "locators.h"
1.1  ahoka
1.1  ahoka #include <sys/param.h>
1.1  ahoka #include <sys/types.h>
1.1  ahoka #include <sys/device.h>
1.1  ahoka #include <sys/kmem.h>
1.1  ahoka #include <sys/sysctl.h>
1.1  ahoka
1.1  ahoka #include <dev/flash/flash.h>
1.1  ahoka #include <dev/nand/nand.h>
1.1  ahoka #include <dev/nand/onfi.h>
1.1  ahoka #include <dev/nand/hamming.h>
1.1  ahoka #include <dev/nand/nand_bbt.h>
1.1  ahoka #include <dev/nand/nand_crc.h>
1.1  ahoka
1.1  ahoka #include "opt_nand.h"
1.1  ahoka
1.2  ahoka int nand_match(device_t, cfdata_t, void *);
1.2  ahoka void nand_attach(device_t, device_t, void *);
1.2  ahoka int nand_detach(device_t, int);
1.2  ahoka bool nand_shutdown(device_t, int);
1.2  ahoka
1.2  ahoka int nand_print(void *, const char *);
1.2  ahoka
1.2  ahoka static int nand_search(device_t, cfdata_t, const int *, void *);
1.2  ahoka static void nand_address_row(device_t, size_t);
1.2  ahoka static void nand_address_column(device_t, size_t, size_t);
1.6  ahoka static int nand_fill_chip_structure(device_t, struct nand_chip *);
1.2  ahoka static int nand_scan_media(device_t, struct nand_chip *);
1.2  ahoka static bool nand_check_wp(device_t);
1.1  ahoka
1.1  ahoka CFATTACH_DECL_NEW(nand, sizeof(struct nand_softc),
1.1  ahoka     nand_match, nand_attach, nand_detach, NULL);
1.1  ahoka
1.1  ahoka #ifdef NAND_DEBUG
1.1  ahoka int	nanddebug = NAND_DEBUG;
1.1  ahoka #endif
1.1  ahoka
1.1  ahoka int nand_cachesync_timeout = 1;
1.1  ahoka int nand_cachesync_nodenum;
1.1  ahoka
1.6  ahoka #ifdef NAND_VERBOSE
1.1  ahoka const struct nand_manufacturer nand_mfrs[] = {
1.1  ahoka 	{ NAND_MFR_AMD,		"AMD" },
1.1  ahoka 	{ NAND_MFR_FUJITSU,	"Fujitsu" },
1.1  ahoka 	{ NAND_MFR_RENESAS,	"Renesas" },
1.1  ahoka 	{ NAND_MFR_STMICRO,	"ST Micro" },
1.1  ahoka 	{ NAND_MFR_MICRON,	"Micron" },
1.1  ahoka 	{ NAND_MFR_NATIONAL,	"National" },
1.1  ahoka 	{ NAND_MFR_TOSHIBA,	"Toshiba" },
1.1  ahoka 	{ NAND_MFR_HYNIX,	"Hynix" },
1.1  ahoka 	{ NAND_MFR_SAMSUNG,	"Samsung" },
1.1  ahoka 	{ NAND_MFR_UNKNOWN,	"Unknown" }
1.1  ahoka };
1.1  ahoka
1.6  ahoka static const char *
1.6  ahoka nand_midtoname(int id)
1.6  ahoka {
1.6  ahoka 	int i;
1.6  ahoka
1.6  ahoka 	for (i = 0; nand_mfrs[i].id != 0; i++) {
1.6  ahoka 		if (nand_mfrs[i].id == id)
1.6  ahoka 			return nand_mfrs[i].name;
1.6  ahoka 	}
1.6  ahoka
1.6  ahoka 	KASSERT(nand_mfrs[i].id == 0);
1.6  ahoka
1.6  ahoka 	return nand_mfrs[i].name;
1.6  ahoka }
1.6  ahoka #endif
1.6  ahoka
1.1  ahoka /* ARGSUSED */
1.1  ahoka int
1.1  ahoka nand_match(device_t parent, cfdata_t match, void *aux)
1.1  ahoka {
1.1  ahoka 	/* pseudo device, always attaches */
1.1  ahoka 	return 1;
1.1  ahoka }
1.1  ahoka
1.1  ahoka void
1.1  ahoka nand_attach(device_t parent, device_t self, void *aux)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_attach_args *naa = aux;
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka
1.1  ahoka 	sc->sc_dev = self;
1.6  ahoka 	sc->controller_dev = parent;
1.1  ahoka 	sc->nand_if = naa->naa_nand_if;
1.1  ahoka
1.1  ahoka 	aprint_naive("\n");
1.1  ahoka
1.1  ahoka 	if (nand_check_wp(self)) {
1.1  ahoka 		aprint_error("NAND chip is write protected!\n");
1.1  ahoka 		return;
1.1  ahoka 	}
1.3  ahoka
1.3  ahoka 	if (nand_scan_media(self, chip)) {
1.1  ahoka 		return;
1.3  ahoka 	}
1.1  ahoka
1.1  ahoka 	/* allocate cache */
1.1  ahoka 	chip->nc_oob_cache = kmem_alloc(chip->nc_spare_size, KM_SLEEP);
1.1  ahoka 	chip->nc_page_cache = kmem_alloc(chip->nc_page_size, KM_SLEEP);
1.1  ahoka
1.1  ahoka 	mutex_init(&sc->sc_device_lock, MUTEX_DEFAULT, IPL_NONE);
1.1  ahoka
1.1  ahoka 	if (nand_sync_thread_start(self)) {
1.1  ahoka 		goto error;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (!pmf_device_register1(sc->sc_dev, NULL, NULL, nand_shutdown))
1.1  ahoka 		aprint_error_dev(sc->sc_dev,
1.1  ahoka 		    "couldn't establish power handler\n");
1.1  ahoka
1.1  ahoka #ifdef NAND_BBT
1.1  ahoka 	nand_bbt_init(self);
1.1  ahoka 	nand_bbt_scan(self);
1.1  ahoka #endif
1.1  ahoka
1.1  ahoka 	/*
1.1  ahoka 	 * Attach all our devices
1.1  ahoka 	 */
1.1  ahoka 	config_search_ia(nand_search, self, NULL, NULL);
1.1  ahoka
1.1  ahoka 	return;
1.1  ahoka error:
1.1  ahoka 	kmem_free(chip->nc_oob_cache, chip->nc_spare_size);
1.1  ahoka 	kmem_free(chip->nc_page_cache, chip->nc_page_size);
1.1  ahoka 	mutex_destroy(&sc->sc_device_lock);
1.1  ahoka }
1.1  ahoka
1.1  ahoka static int
1.1  ahoka nand_search(device_t parent, cfdata_t cf, const int *ldesc, void *aux)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(parent);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	struct flash_interface *flash_if;
1.1  ahoka 	struct flash_attach_args faa;
1.1  ahoka
1.1  ahoka 	flash_if = kmem_alloc(sizeof(*flash_if), KM_SLEEP);
1.1  ahoka
1.1  ahoka 	flash_if->type = FLASH_TYPE_NAND;
1.1  ahoka
1.1  ahoka 	flash_if->read = nand_flash_read;
1.1  ahoka 	flash_if->write = nand_flash_write;
1.1  ahoka 	flash_if->erase = nand_flash_erase;
1.1  ahoka 	flash_if->block_isbad = nand_flash_isbad;
1.1  ahoka 	flash_if->block_markbad = nand_flash_markbad;
1.1  ahoka
1.1  ahoka 	flash_if->submit = nand_io_submit;
1.1  ahoka
1.1  ahoka 	flash_if->erasesize = chip->nc_block_size;
1.1  ahoka 	flash_if->page_size = chip->nc_page_size;
1.1  ahoka 	flash_if->writesize = chip->nc_page_size;
1.1  ahoka
1.1  ahoka 	flash_if->partition.part_offset = cf->cf_loc[FLASHBUSCF_OFFSET];
1.1  ahoka
1.1  ahoka 	if (cf->cf_loc[FLASHBUSCF_SIZE] == 0) {
1.1  ahoka 		flash_if->size = chip->nc_size -
1.1  ahoka 		    flash_if->partition.part_offset;
1.1  ahoka 		flash_if->partition.part_size = flash_if->size;
1.1  ahoka 	} else {
1.1  ahoka 		flash_if->size = cf->cf_loc[FLASHBUSCF_SIZE];
1.1  ahoka 		flash_if->partition.part_size = cf->cf_loc[FLASHBUSCF_SIZE];
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (cf->cf_loc[FLASHBUSCF_READONLY])
1.1  ahoka 		flash_if->partition.part_flags = FLASH_PART_READONLY;
1.1  ahoka 	else
1.1  ahoka 		flash_if->partition.part_flags = 0;
1.1  ahoka
1.1  ahoka 	faa.flash_if = flash_if;
1.1  ahoka
1.1  ahoka 	if (config_match(parent, cf, &faa)) {
1.1  ahoka 		config_attach(parent, cf, &faa, nand_print);
1.1  ahoka 		return 0;
1.1  ahoka 	} else {
1.1  ahoka 		kmem_free(flash_if, sizeof(*flash_if));
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return 1;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.1  ahoka nand_detach(device_t self, int flags)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	int ret = 0;
1.1  ahoka
1.1  ahoka #ifdef NAND_BBT
1.1  ahoka 	nand_bbt_detach(self);
1.1  ahoka #endif
1.1  ahoka 	nand_sync_thread_stop(self);
1.1  ahoka
1.1  ahoka 	/* free oob cache */
1.1  ahoka 	kmem_free(chip->nc_oob_cache, chip->nc_spare_size);
1.1  ahoka 	kmem_free(chip->nc_page_cache, chip->nc_page_size);
1.1  ahoka 	kmem_free(chip->nc_ecc_cache, chip->nc_ecc->necc_size);
1.1  ahoka
1.1  ahoka 	mutex_destroy(&sc->sc_device_lock);
1.1  ahoka
1.1  ahoka 	pmf_device_deregister(sc->sc_dev);
1.1  ahoka
1.1  ahoka 	return ret;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.1  ahoka nand_print(void *aux, const char *pnp)
1.1  ahoka {
1.1  ahoka 	if (pnp != NULL)
1.1  ahoka 		aprint_normal("nand at %s\n", pnp);
1.1  ahoka
1.1  ahoka 	return UNCONF;
1.1  ahoka }
1.1  ahoka
1.6  ahoka /* ask for a nand driver to attach to the controller */
1.1  ahoka device_t
1.1  ahoka nand_attach_mi(struct nand_interface *nand_if, device_t parent)
1.1  ahoka {
1.1  ahoka 	struct nand_attach_args arg;
1.1  ahoka
1.1  ahoka 	KASSERT(nand_if != NULL);
1.1  ahoka
1.6  ahoka 	/* fill the defaults if we have null pointers */
1.6  ahoka 	if (nand_if->program_page == NULL) {
1.6  ahoka 		nand_if->program_page = &nand_default_program_page;
1.6  ahoka 	}
1.6  ahoka
1.6  ahoka 	if (nand_if->read_page == NULL) {
1.6  ahoka 		nand_if->read_page = &nand_default_read_page;
1.6  ahoka 	}
1.6  ahoka
1.1  ahoka 	arg.naa_nand_if = nand_if;
1.1  ahoka 	return config_found_ia(parent, "nandbus", &arg, nand_print);
1.1  ahoka }
1.1  ahoka
1.6  ahoka /* default everything to reasonable values, to ease future api changes */
1.6  ahoka void
1.6  ahoka nand_init_interface(struct nand_interface *interface)
1.1  ahoka {
1.6  ahoka 	interface->select = &nand_default_select;
1.6  ahoka 	interface->command = NULL;
1.6  ahoka 	interface->address = NULL;
1.6  ahoka 	interface->read_buf_byte = NULL;
1.6  ahoka 	interface->read_buf_word = NULL;
1.6  ahoka 	interface->read_byte = NULL;
1.6  ahoka 	interface->read_word = NULL;
1.6  ahoka 	interface->write_buf_byte = NULL;
1.6  ahoka 	interface->write_buf_word = NULL;
1.6  ahoka 	interface->write_byte = NULL;
1.6  ahoka 	interface->write_word = NULL;
1.6  ahoka 	interface->busy = NULL;
1.6  ahoka
1.6  ahoka 	/*-
1.6  ahoka 	 * most drivers dont want to change this, but some implement
1.6  ahoka 	 * read/program in one step
1.6  ahoka 	 */
1.6  ahoka 	interface->program_page = &nand_default_program_page;
1.6  ahoka 	interface->read_page = &nand_default_read_page;
1.1  ahoka
1.6  ahoka 	/* default to soft ecc, that should work everywhere */
1.6  ahoka 	interface->ecc_compute = &nand_default_ecc_compute;
1.6  ahoka 	interface->ecc_correct = &nand_default_ecc_correct;
1.6  ahoka 	interface->ecc_prepare = NULL;
1.6  ahoka 	interface->ecc.necc_code_size = 3;
1.6  ahoka 	interface->ecc.necc_block_size = 256;
1.6  ahoka 	interface->ecc.necc_type = NAND_ECC_TYPE_SW;
1.1  ahoka }
1.1  ahoka
1.1  ahoka #if 0
1.1  ahoka /* handle quirks here */
1.1  ahoka static void
1.1  ahoka nand_quirks(device_t self, struct nand_chip *chip)
1.1  ahoka {
1.1  ahoka 	/* this is an example only! */
1.1  ahoka 	switch (chip->nc_manf_id) {
1.1  ahoka 	case NAND_MFR_SAMSUNG:
1.1  ahoka 		if (chip->nc_dev_id == 0x00) {
1.1  ahoka 			/* do something only samsung chips need */
1.1  ahoka 			/* or */
1.1  ahoka 			/* chip->nc_quirks |= NC_QUIRK_NO_READ_START */
1.1  ahoka 		}
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return;
1.1  ahoka }
1.1  ahoka #endif
1.1  ahoka
1.3  ahoka static int
1.6  ahoka nand_fill_chip_structure_legacy(device_t self, struct nand_chip *chip)
1.3  ahoka {
1.3  ahoka 	switch (chip->nc_manf_id) {
1.3  ahoka 	case NAND_MFR_MICRON:
1.3  ahoka 		return nand_read_parameters_micron(self, chip);
1.3  ahoka 	default:
1.3  ahoka 		return 1;
1.3  ahoka 	}
1.3  ahoka
1.3  ahoka 	return 0;
1.3  ahoka }
1.3  ahoka
1.1  ahoka /**
1.1  ahoka  * scan media to determine the chip's properties
1.1  ahoka  * this function resets the device
1.1  ahoka  */
1.1  ahoka static int
1.1  ahoka nand_scan_media(device_t self, struct nand_chip *chip)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_ecc *ecc;
1.1  ahoka 	uint8_t onfi_signature[4];
1.1  ahoka
1.1  ahoka 	nand_select(self, true);
1.1  ahoka 	nand_command(self, ONFI_RESET);
1.1  ahoka 	nand_select(self, false);
1.1  ahoka
1.3  ahoka 	/* check if the device implements the ONFI standard */
1.1  ahoka 	nand_select(self, true);
1.1  ahoka 	nand_command(self, ONFI_READ_ID);
1.1  ahoka 	nand_address(self, 0x20);
1.1  ahoka 	nand_read_byte(self, &onfi_signature[0]);
1.1  ahoka 	nand_read_byte(self, &onfi_signature[1]);
1.1  ahoka 	nand_read_byte(self, &onfi_signature[2]);
1.1  ahoka 	nand_read_byte(self, &onfi_signature[3]);
1.1  ahoka 	nand_select(self, false);
1.1  ahoka
1.1  ahoka 	if (onfi_signature[0] != 'O' || onfi_signature[1] != 'N' ||
1.1  ahoka 	    onfi_signature[2] != 'F' || onfi_signature[3] != 'I') {
1.3  ahoka 		chip->nc_isonfi = false;
1.3  ahoka
1.3  ahoka 		aprint_normal(": Legacy NAND Flash\n");
1.3  ahoka
1.6  ahoka 		nand_read_id(self, &chip->nc_manf_id, &chip->nc_dev_id);
1.1  ahoka
1.6  ahoka 		if (nand_fill_chip_structure_legacy(self, chip)) {
1.3  ahoka 			aprint_error_dev(self,
1.3  ahoka 			    "can't read device parameters for legacy chip\n");
1.3  ahoka 			return 1;
1.3  ahoka 		}
1.3  ahoka 	} else {
1.3  ahoka 		chip->nc_isonfi = true;
1.1  ahoka
1.3  ahoka 		aprint_normal(": ONFI NAND Flash\n");
1.1  ahoka
1.6  ahoka 		nand_read_id(self, &chip->nc_manf_id, &chip->nc_dev_id);
1.6  ahoka
1.6  ahoka 		if (nand_fill_chip_structure(self, chip)) {
1.6  ahoka 			aprint_error_dev(self,
1.6  ahoka 			    "can't read device parameters\n");
1.6  ahoka
1.6  ahoka 			return 1;
1.6  ahoka 		}
1.3  ahoka 	}
1.1  ahoka
1.3  ahoka #ifdef NAND_VERBOSE
1.3  ahoka 	aprint_normal_dev(self,
1.1  ahoka 	    "manufacturer id: 0x%.2x (%s), device id: 0x%.2x\n",
1.1  ahoka 	    chip->nc_manf_id,
1.1  ahoka 	    nand_midtoname(chip->nc_manf_id),
1.1  ahoka 	    chip->nc_dev_id);
1.3  ahoka #endif
1.1  ahoka
1.3  ahoka 	aprint_normal_dev(self,
1.5  ahoka 	    "page size: %zu bytes, spare size: %zu bytes, "
1.5  ahoka 	    "block size: %zu bytes\n",
1.3  ahoka 	    chip->nc_page_size, chip->nc_spare_size, chip->nc_block_size);
1.3  ahoka
1.3  ahoka 	aprint_normal_dev(self,
1.5  ahoka 	    "LUN size: %" PRIu32 " blocks, LUNs: %" PRIu8
1.5  ahoka 	    ", total storage size: %zu MB\n",
1.3  ahoka 	    chip->nc_lun_blocks, chip->nc_num_luns,
1.3  ahoka 	    chip->nc_size / 1024 / 1024);
1.1  ahoka
1.3  ahoka #ifdef NAND_VERBOSE
1.5  ahoka 	aprint_normal_dev(self, "column cycles: %" PRIu8 ", row cycles: %"
1.5  ahoka 	    PRIu8 "\n",
1.3  ahoka 	    chip->nc_addr_cycles_column, chip->nc_addr_cycles_row);
1.3  ahoka #endif
1.3  ahoka
1.1  ahoka 	ecc = chip->nc_ecc = &sc->nand_if->ecc;
1.1  ahoka
1.1  ahoka 	/*
1.1  ahoka 	 * calculate the place of ecc data in oob
1.1  ahoka 	 * we try to be compatible with Linux here
1.1  ahoka 	 */
1.1  ahoka 	switch (chip->nc_spare_size) {
1.1  ahoka 	case 8:
1.1  ahoka 		ecc->necc_offset = 0;
1.1  ahoka 		break;
1.1  ahoka 	case 16:
1.1  ahoka 		ecc->necc_offset = 0;
1.1  ahoka 		break;
1.1  ahoka 	case 64:
1.1  ahoka 		ecc->necc_offset = 40;
1.1  ahoka 		break;
1.1  ahoka 	case 128:
1.1  ahoka 		ecc->necc_offset = 80;
1.1  ahoka 		break;
1.1  ahoka 	default:
1.1  ahoka 		panic("OOB size is unexpected");
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	ecc->necc_steps = chip->nc_page_size / ecc->necc_block_size;
1.1  ahoka 	ecc->necc_size = ecc->necc_steps * ecc->necc_code_size;
1.1  ahoka
1.1  ahoka 	/* check if we fit in oob */
1.1  ahoka 	if (ecc->necc_offset + ecc->necc_size > chip->nc_spare_size) {
1.1  ahoka 		panic("NAND ECC bits dont fit in OOB");
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	/* TODO: mark free oob area available for file systems */
1.1  ahoka
1.1  ahoka 	chip->nc_ecc_cache = kmem_zalloc(ecc->necc_size, KM_SLEEP);
1.1  ahoka
1.1  ahoka 	/*
1.1  ahoka 	 * calculate badblock marker offset in oob
1.1  ahoka 	 * we try to be compatible with linux here
1.1  ahoka 	 */
1.1  ahoka 	if (chip->nc_page_size > 512)
1.1  ahoka 		chip->nc_badmarker_offs = 0;
1.1  ahoka 	else
1.1  ahoka 		chip->nc_badmarker_offs = 5;
1.1  ahoka
1.1  ahoka 	/* Calculate page shift and mask */
1.1  ahoka 	chip->nc_page_shift = ffs(chip->nc_page_size) - 1;
1.1  ahoka 	chip->nc_page_mask = ~(chip->nc_page_size - 1);
1.1  ahoka 	/* same for block */
1.1  ahoka 	chip->nc_block_shift = ffs(chip->nc_block_size) - 1;
1.1  ahoka 	chip->nc_block_mask = ~(chip->nc_block_size - 1);
1.1  ahoka
1.1  ahoka 	/* look for quirks here if needed in future */
1.1  ahoka 	/* nand_quirks(self, chip); */
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.6  ahoka void
1.6  ahoka nand_read_id(device_t self, uint8_t *manf, uint8_t *dev)
1.1  ahoka {
1.1  ahoka 	nand_select(self, true);
1.1  ahoka 	nand_command(self, ONFI_READ_ID);
1.1  ahoka 	nand_address(self, 0x00);
1.3  ahoka
1.6  ahoka 	nand_read_byte(self, manf);
1.6  ahoka 	nand_read_byte(self, dev);
1.3  ahoka
1.1  ahoka 	nand_select(self, false);
1.1  ahoka }
1.1  ahoka
1.6  ahoka int
1.6  ahoka nand_read_parameter_page(device_t self, struct onfi_parameter_page *params)
1.1  ahoka {
1.1  ahoka 	uint8_t *bufp;
1.1  ahoka 	uint16_t crc;
1.6  ahoka 	int i;//, tries = 0;
1.1  ahoka
1.6  ahoka 	KASSERT(sizeof(*params) == 256);
1.1  ahoka
1.6  ahoka //read_params:
1.6  ahoka //	tries++;
1.6  ahoka
1.1  ahoka 	nand_select(self, true);
1.1  ahoka 	nand_command(self, ONFI_READ_PARAMETER_PAGE);
1.1  ahoka 	nand_address(self, 0x00);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka
1.6  ahoka 	/* TODO check the signature if it contains at least 2 letters */
1.6  ahoka
1.6  ahoka 	bufp = (uint8_t *)params;
1.6  ahoka 	/* XXX why i am not using read_buf? */
1.1  ahoka 	for (i = 0; i < 256; i++) {
1.1  ahoka 		nand_read_byte(self, &bufp[i]);
1.1  ahoka 	}
1.1  ahoka 	nand_select(self, false);
1.1  ahoka
1.1  ahoka 	/* validate the parameter page with the crc */
1.1  ahoka 	crc = nand_crc16(bufp, 254);
1.1  ahoka
1.6  ahoka 	if (crc != params->param_integrity_crc) {
1.1  ahoka 		aprint_error_dev(self, "parameter page crc check failed\n");
1.1  ahoka 		/* TODO: we should read the next parameter page copy */
1.6  ahoka 		return 1;
1.6  ahoka 	}
1.6  ahoka
1.6  ahoka 	return 0;
1.6  ahoka }
1.6  ahoka
1.6  ahoka static int
1.6  ahoka nand_fill_chip_structure(device_t self, struct nand_chip *chip)
1.6  ahoka {
1.6  ahoka 	struct onfi_parameter_page params;
1.6  ahoka 	uint8_t	vendor[13], model[21];
1.6  ahoka 	int i;
1.6  ahoka
1.6  ahoka 	if (nand_read_parameter_page(self, &params)) {
1.6  ahoka 		return 1;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	/* strip manufacturer and model string */
1.1  ahoka 	strlcpy(vendor, params.param_manufacturer, sizeof(vendor));
1.1  ahoka 	for (i = 11; i > 0 && vendor[i] == ' '; i--)
1.1  ahoka 		vendor[i] = 0;
1.1  ahoka 	strlcpy(model, params.param_model, sizeof(model));
1.1  ahoka 	for (i = 19; i > 0 && model[i] == ' '; i--)
1.1  ahoka 		model[i] = 0;
1.1  ahoka
1.1  ahoka 	aprint_normal_dev(self, "vendor: %s, model: %s\n", vendor, model);
1.1  ahoka
1.1  ahoka 	/* XXX TODO multiple LUNs */
1.6  ahoka 	if (params.param_numluns != 1) {
1.6  ahoka 		aprint_error_dev(self,
1.6  ahoka 		    "more than one LUNs are not supported yet!\n");
1.6  ahoka
1.6  ahoka 		return 1;
1.3  ahoka 	}
1.1  ahoka
1.1  ahoka 	chip->nc_size = params.param_pagesize * params.param_blocksize *
1.1  ahoka 	    params.param_lunsize * params.param_numluns;
1.1  ahoka
1.1  ahoka 	chip->nc_page_size = params.param_pagesize;
1.1  ahoka 	chip->nc_block_pages = params.param_blocksize;
1.1  ahoka 	chip->nc_block_size = params.param_blocksize * params.param_pagesize;
1.1  ahoka 	chip->nc_spare_size = params.param_sparesize;
1.3  ahoka 	chip->nc_lun_blocks = params.param_lunsize;
1.3  ahoka 	chip->nc_num_luns = params.param_numluns;
1.1  ahoka
1.1  ahoka 	/* the lower 4 bits contain the row address cycles */
1.1  ahoka 	chip->nc_addr_cycles_row = params.param_addr_cycles & 0x07;
1.1  ahoka 	/* the upper 4 bits contain the column address cycles */
1.1  ahoka 	chip->nc_addr_cycles_column = (params.param_addr_cycles & ~0x07) >> 4;
1.1  ahoka
1.1  ahoka 	if (params.param_features & ONFI_FEATURE_16BIT)
1.1  ahoka 		chip->nc_flags |= NC_BUSWIDTH_16;
1.1  ahoka
1.1  ahoka 	if (params.param_features & ONFI_FEATURE_EXTENDED_PARAM)
1.1  ahoka 		chip->nc_flags |= NC_EXTENDED_PARAM;
1.6  ahoka
1.6  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka /* ARGSUSED */
1.1  ahoka bool
1.1  ahoka nand_shutdown(device_t self, int howto)
1.1  ahoka {
1.1  ahoka 	return true;
1.1  ahoka }
1.1  ahoka
1.1  ahoka static void
1.1  ahoka nand_address_column(device_t self, size_t row, size_t column)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	uint8_t i;
1.1  ahoka
1.1  ahoka 	DPRINTF(("addressing row: 0x%jx column: %zu\n",
1.1  ahoka 		(uintmax_t )row, column));
1.1  ahoka
1.1  ahoka 	/* XXX TODO */
1.1  ahoka 	row >>= chip->nc_page_shift;
1.1  ahoka
1.1  ahoka 	/* Write the column (subpage) address */
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16)
1.1  ahoka 		column >>= 1;
1.1  ahoka 	for (i = 0; i < chip->nc_addr_cycles_column; i++, column >>= 8)
1.1  ahoka 		nand_address(self, column & 0xff);
1.1  ahoka
1.1  ahoka 	/* Write the row (page) address */
1.1  ahoka 	for (i = 0; i < chip->nc_addr_cycles_row; i++, row >>= 8)
1.1  ahoka 		nand_address(self, row & 0xff);
1.1  ahoka }
1.1  ahoka
1.1  ahoka static void
1.1  ahoka nand_address_row(device_t self, size_t row)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	int i;
1.1  ahoka
1.1  ahoka 	/* XXX TODO */
1.1  ahoka 	row >>= chip->nc_page_shift;
1.1  ahoka
1.1  ahoka 	/* Write the row (page) address */
1.1  ahoka 	for (i = 0; i < chip->nc_addr_cycles_row; i++, row >>= 8)
1.1  ahoka 		nand_address(self, row & 0xff);
1.1  ahoka }
1.1  ahoka
1.1  ahoka static inline uint8_t
1.1  ahoka nand_get_status(device_t self)
1.1  ahoka {
1.1  ahoka 	uint8_t status;
1.1  ahoka
1.1  ahoka 	nand_command(self, ONFI_READ_STATUS);
1.1  ahoka 	nand_busy(self);
1.1  ahoka 	nand_read_byte(self, &status);
1.1  ahoka
1.1  ahoka 	return status;
1.1  ahoka }
1.1  ahoka
1.1  ahoka static bool
1.1  ahoka nand_check_wp(device_t self)
1.1  ahoka {
1.1  ahoka 	if (nand_get_status(self) & 0x80)
1.1  ahoka 		return false;
1.1  ahoka 	else
1.1  ahoka 		return true;
1.1  ahoka }
1.1  ahoka
1.1  ahoka static void
1.7  ahoka nand_prepare_read(device_t self, flash_off_t row, flash_off_t column)
1.1  ahoka {
1.1  ahoka 	nand_command(self, ONFI_READ);
1.1  ahoka 	nand_address_column(self, row, column);
1.1  ahoka 	nand_command(self, ONFI_READ_START);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka }
1.1  ahoka
1.6  ahoka /* read a page with ecc correction, default implementation */
1.1  ahoka int
1.6  ahoka nand_default_read_page(device_t self, size_t offset, uint8_t *data)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	size_t b, bs, e, cs;
1.1  ahoka 	uint8_t *ecc;
1.1  ahoka 	int result;
1.1  ahoka
1.1  ahoka 	nand_prepare_read(self, offset, 0);
1.1  ahoka
1.1  ahoka 	bs = chip->nc_ecc->necc_block_size;
1.1  ahoka 	cs = chip->nc_ecc->necc_code_size;
1.1  ahoka
1.1  ahoka 	/* decide if we access by 8 or 16 bits */
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16) {
1.1  ahoka 		for (b = 0, e = 0; b < chip->nc_page_size; b += bs, e += cs) {
1.1  ahoka 			nand_ecc_prepare(self, NAND_ECC_READ);
1.1  ahoka 			nand_read_buf_word(self, data + b, bs);
1.1  ahoka 			nand_ecc_compute(self, data + b,
1.1  ahoka 			    chip->nc_ecc_cache + e);
1.1  ahoka 		}
1.1  ahoka 	} else {
1.1  ahoka 		for (b = 0, e = 0; b < chip->nc_page_size; b += bs, e += cs) {
1.1  ahoka 			nand_ecc_prepare(self, NAND_ECC_READ);
1.1  ahoka 			nand_read_buf_byte(self, data + b, bs);
1.1  ahoka 			nand_ecc_compute(self, data + b,
1.1  ahoka 			    chip->nc_ecc_cache + e);
1.1  ahoka 		}
1.1  ahoka 	}
1.1  ahoka
1.2  ahoka 	/* for debugging new drivers */
1.2  ahoka #if 0
1.2  ahoka 	nand_dump_data("page", data, chip->nc_page_size);
1.2  ahoka #endif
1.1  ahoka
1.1  ahoka 	nand_read_oob(self, offset, chip->nc_oob_cache);
1.1  ahoka 	ecc = chip->nc_oob_cache + chip->nc_ecc->necc_offset;
1.1  ahoka
1.1  ahoka 	/* useful for debugging new ecc drivers */
1.1  ahoka #if 0
1.1  ahoka 	printf("dumping ecc %d\n--------------\n", chip->nc_ecc->necc_steps);
1.1  ahoka 	for (e = 0; e < chip->nc_ecc->necc_steps; e++) {
1.1  ahoka 		printf("0x");
1.1  ahoka 		for (b = 0; b < cs; b++) {
1.1  ahoka 			printf("%.2hhx", ecc[e+b]);
1.1  ahoka 		}
1.1  ahoka 		printf(" 0x");
1.1  ahoka 		for (b = 0; b < cs; b++) {
1.1  ahoka 			printf("%.2hhx", chip->nc_ecc_cache[e+b]);
1.1  ahoka 		}
1.1  ahoka 		printf("\n");
1.1  ahoka 	}
1.1  ahoka 	printf("--------------\n");
1.1  ahoka #endif
1.1  ahoka
1.1  ahoka 	for (b = 0, e = 0; b < chip->nc_page_size; b += bs, e += cs) {
1.1  ahoka 		result = nand_ecc_correct(self, data + b, ecc + e,
1.1  ahoka 		    chip->nc_ecc_cache + e);
1.1  ahoka
1.1  ahoka 		switch (result) {
1.1  ahoka 		case NAND_ECC_OK:
1.1  ahoka 			break;
1.1  ahoka 		case NAND_ECC_CORRECTED:
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "data corrected with ECC at page offset 0x%jx "
1.1  ahoka 			    "block %zu\n", (uintmax_t)offset, b);
1.1  ahoka 			break;
1.1  ahoka 		case NAND_ECC_TWOBIT:
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "uncorrectable ECC error at page offset 0x%jx "
1.1  ahoka 			    "block %zu\n", (uintmax_t)offset, b);
1.1  ahoka 			return EIO;
1.1  ahoka 			break;
1.1  ahoka 		case NAND_ECC_INVALID:
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "invalid ECC in oob at page offset 0x%jx "
1.1  ahoka 			    "block %zu\n", (uintmax_t)offset, b);
1.1  ahoka 			return EIO;
1.1  ahoka 			break;
1.1  ahoka 		default:
1.1  ahoka 			panic("invalid ECC correction errno");
1.1  ahoka 		}
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.6  ahoka int
1.6  ahoka nand_default_program_page(device_t self, size_t page, const uint8_t *data)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	size_t bs, cs, e, b;
1.1  ahoka 	uint8_t status;
1.1  ahoka 	uint8_t *ecc;
1.1  ahoka
1.1  ahoka 	nand_command(self, ONFI_PAGE_PROGRAM);
1.1  ahoka 	nand_address_column(self, page, 0);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka
1.1  ahoka 	bs = chip->nc_ecc->necc_block_size;
1.1  ahoka 	cs = chip->nc_ecc->necc_code_size;
1.1  ahoka 	ecc = chip->nc_oob_cache + chip->nc_ecc->necc_offset;
1.1  ahoka
1.1  ahoka 	/* XXX code duplication */
1.1  ahoka 	/* decide if we access by 8 or 16 bits */
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16) {
1.1  ahoka 		for (b = 0, e = 0; b < chip->nc_page_size; b += bs, e += cs) {
1.1  ahoka 			nand_ecc_prepare(self, NAND_ECC_WRITE);
1.1  ahoka 			nand_write_buf_word(self, data + b, bs);
1.1  ahoka 			nand_ecc_compute(self, data + b, ecc + e);
1.1  ahoka 		}
1.1  ahoka 		/* write oob with ecc correction code */
1.1  ahoka 		nand_write_buf_word(self, chip->nc_oob_cache,
1.1  ahoka 		    chip->nc_spare_size);
1.1  ahoka 	} else {
1.1  ahoka 		for (b = 0, e = 0; b < chip->nc_page_size; b += bs, e += cs) {
1.1  ahoka 			nand_ecc_prepare(self, NAND_ECC_WRITE);
1.1  ahoka 			nand_write_buf_byte(self, data + b, bs);
1.1  ahoka 			nand_ecc_compute(self, data + b, ecc + e);
1.1  ahoka 		}
1.1  ahoka 		/* write oob with ecc correction code */
1.1  ahoka 		nand_write_buf_byte(self, chip->nc_oob_cache,
1.1  ahoka 		    chip->nc_spare_size);
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	nand_command(self, ONFI_PAGE_PROGRAM_START);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka
1.2  ahoka 	/* for debugging ecc */
1.1  ahoka #if 0
1.1  ahoka 	printf("dumping ecc %d\n--------------\n", chip->nc_ecc->necc_steps);
1.1  ahoka 	for (e = 0; e < chip->nc_ecc->necc_steps; e++) {
1.1  ahoka 		printf("0x");
1.1  ahoka 		for (b = 0; b < cs; b++) {
1.1  ahoka 			printf("%.2hhx", ecc[e+b]);
1.1  ahoka 		}
1.1  ahoka 		printf("\n");
1.1  ahoka 	}
1.1  ahoka 	printf("--------------\n");
1.1  ahoka #endif
1.1  ahoka
1.1  ahoka 	status = nand_get_status(self);
1.1  ahoka 	KASSERT(status & ONFI_STATUS_RDY);
1.1  ahoka 	if (status & ONFI_STATUS_FAIL) {
1.1  ahoka 		aprint_error_dev(self, "page program failed!\n");
1.1  ahoka 		return EIO;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.6  ahoka /* read the OOB of a page */
1.1  ahoka int
1.6  ahoka nand_read_oob(device_t self, size_t page, uint8_t *oob)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka
1.1  ahoka 	nand_prepare_read(self, page, chip->nc_page_size);
1.1  ahoka
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16)
1.1  ahoka 		nand_read_buf_word(self, oob, chip->nc_spare_size);
1.1  ahoka 	else
1.1  ahoka 		nand_read_buf_byte(self, oob, chip->nc_spare_size);
1.1  ahoka
1.2  ahoka 	/* for debugging drivers */
1.2  ahoka #if 0
1.2  ahoka 	nand_dump_data("oob", oob, chip->nc_spare_size);
1.2  ahoka #endif
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka static int
1.1  ahoka nand_write_oob(device_t self, size_t offset, const void *oob)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	uint8_t status;
1.1  ahoka
1.1  ahoka 	nand_command(self, ONFI_PAGE_PROGRAM);
1.1  ahoka 	nand_address_column(self, offset, chip->nc_page_size);
1.1  ahoka 	nand_command(self, ONFI_PAGE_PROGRAM_START);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16)
1.1  ahoka 		nand_write_buf_word(self, oob, chip->nc_spare_size);
1.1  ahoka 	else
1.1  ahoka 		nand_write_buf_byte(self, oob, chip->nc_spare_size);
1.1  ahoka
1.1  ahoka 	status = nand_get_status(self);
1.1  ahoka 	KASSERT(status & ONFI_STATUS_RDY);
1.1  ahoka 	if (status & ONFI_STATUS_FAIL)
1.1  ahoka 		return EIO;
1.1  ahoka 	else
1.1  ahoka 		return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka void
1.1  ahoka nand_markbad(device_t self, size_t offset)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t blockoffset, marker;
1.1  ahoka #ifdef NAND_BBT
1.7  ahoka 	flash_off_t block;
1.1  ahoka
1.1  ahoka 	block = offset / chip->nc_block_size;
1.1  ahoka
1.1  ahoka 	nand_bbt_block_markbad(self, block);
1.1  ahoka #endif
1.1  ahoka 	blockoffset = offset & chip->nc_block_mask;
1.1  ahoka 	marker = chip->nc_badmarker_offs & ~0x01;
1.1  ahoka
1.1  ahoka 	/* check if it is already marked bad */
1.1  ahoka 	if (nand_isbad(self, blockoffset))
1.1  ahoka 		return;
1.1  ahoka
1.1  ahoka 	nand_read_oob(self, blockoffset, chip->nc_oob_cache);
1.1  ahoka
1.1  ahoka 	chip->nc_oob_cache[chip->nc_badmarker_offs] = 0x00;
1.1  ahoka 	chip->nc_oob_cache[chip->nc_badmarker_offs + 1] = 0x00;
1.1  ahoka
1.1  ahoka 	nand_write_oob(self, blockoffset, chip->nc_oob_cache);
1.1  ahoka }
1.1  ahoka
1.1  ahoka bool
1.7  ahoka nand_isfactorybad(device_t self, flash_off_t offset)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t block, first_page, last_page, page;
1.1  ahoka 	int i;
1.1  ahoka
1.1  ahoka 	/* Check for factory bad blocks first
1.1  ahoka 	 * Factory bad blocks are marked in the first or last
1.1  ahoka 	 * page of the blocks, see: ONFI 2.2, 3.2.2.
1.1  ahoka 	 */
1.1  ahoka 	block = offset / chip->nc_block_size;
1.1  ahoka 	first_page = block * chip->nc_block_size;
1.1  ahoka 	last_page = (block + 1) * chip->nc_block_size
1.1  ahoka 	    - chip->nc_page_size;
1.1  ahoka
1.1  ahoka 	for (i = 0, page = first_page; i < 2; i++, page = last_page) {
1.1  ahoka 		/* address OOB */
1.1  ahoka 		nand_prepare_read(self, page, chip->nc_page_size);
1.1  ahoka
1.1  ahoka 		if (chip->nc_flags & NC_BUSWIDTH_16) {
1.1  ahoka 			uint16_t word;
1.1  ahoka 			nand_read_word(self, &word);
1.1  ahoka 			if (word == 0x0000)
1.1  ahoka 				return true;
1.1  ahoka 		} else {
1.1  ahoka 			uint8_t byte;
1.1  ahoka 			nand_read_byte(self, &byte);
1.1  ahoka 			if (byte == 0x00)
1.1  ahoka 				return true;
1.1  ahoka 		}
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return false;
1.1  ahoka }
1.1  ahoka
1.1  ahoka bool
1.7  ahoka nand_iswornoutbad(device_t self, flash_off_t offset)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t block;
1.1  ahoka
1.1  ahoka 	/* we inspect the first page of the block */
1.1  ahoka 	block = offset & chip->nc_block_mask;
1.1  ahoka
1.1  ahoka 	/* Linux/u-boot compatible badblock handling */
1.1  ahoka 	if (chip->nc_flags & NC_BUSWIDTH_16) {
1.1  ahoka 		uint16_t word, mark;
1.1  ahoka
1.1  ahoka 		nand_prepare_read(self, block,
1.1  ahoka 		    chip->nc_page_size + (chip->nc_badmarker_offs & 0xfe));
1.1  ahoka
1.1  ahoka 		nand_read_word(self, &word);
1.1  ahoka 		mark = htole16(word);
1.1  ahoka 		if (chip->nc_badmarker_offs & 0x01)
1.1  ahoka 			mark >>= 8;
1.1  ahoka 		if ((mark & 0xff) != 0xff)
1.1  ahoka 			return true;
1.1  ahoka 	} else {
1.1  ahoka 		uint8_t byte;
1.1  ahoka
1.1  ahoka 		nand_prepare_read(self, block,
1.1  ahoka 		    chip->nc_page_size + chip->nc_badmarker_offs);
1.1  ahoka
1.1  ahoka 		nand_read_byte(self, &byte);
1.1  ahoka 		if (byte != 0xff)
1.1  ahoka 			return true;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	return false;
1.1  ahoka }
1.1  ahoka
1.1  ahoka bool
1.7  ahoka nand_isbad(device_t self, flash_off_t offset)
1.1  ahoka {
1.1  ahoka #ifdef NAND_BBT
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t block;
1.1  ahoka
1.1  ahoka 	block = offset / chip->nc_block_size;
1.1  ahoka
1.1  ahoka 	return nand_bbt_block_isbad(self, block);
1.1  ahoka #else
1.1  ahoka 	/* ONFI host requirement */
1.1  ahoka 	if (nand_isfactorybad(self, offset))
1.1  ahoka 		return true;
1.1  ahoka
1.1  ahoka 	/* Look for Linux/U-Boot compatible bad marker */
1.1  ahoka 	if (nand_iswornoutbad(self, offset))
1.1  ahoka 		return true;
1.1  ahoka
1.1  ahoka 	return false;
1.1  ahoka #endif
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.1  ahoka nand_erase_block(device_t self, size_t offset)
1.1  ahoka {
1.1  ahoka 	uint8_t status;
1.1  ahoka
1.1  ahoka 	/* xxx calculate first page of block for address? */
1.1  ahoka
1.1  ahoka 	nand_command(self, ONFI_BLOCK_ERASE);
1.1  ahoka 	nand_address_row(self, offset);
1.1  ahoka 	nand_command(self, ONFI_BLOCK_ERASE_START);
1.1  ahoka
1.1  ahoka 	nand_busy(self);
1.1  ahoka
1.1  ahoka 	status = nand_get_status(self);
1.1  ahoka 	KASSERT(status & ONFI_STATUS_RDY);
1.1  ahoka 	if (status & ONFI_STATUS_FAIL) {
1.1  ahoka 		aprint_error_dev(self, "block erase failed!\n");
1.1  ahoka 		nand_markbad(self, offset);
1.1  ahoka 		return EIO;
1.1  ahoka 	} else {
1.1  ahoka 		return 0;
1.1  ahoka 	}
1.1  ahoka }
1.1  ahoka
1.1  ahoka /* default functions for driver development */
1.1  ahoka
1.1  ahoka /* default ECC using hamming code of 256 byte chunks */
1.1  ahoka int
1.1  ahoka nand_default_ecc_compute(device_t self, const uint8_t *data, uint8_t *code)
1.1  ahoka {
1.1  ahoka 	hamming_compute_256(data, code);
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.1  ahoka nand_default_ecc_correct(device_t self, uint8_t *data, const uint8_t *origcode,
1.1  ahoka 	const uint8_t *compcode)
1.1  ahoka {
1.1  ahoka 	return hamming_correct_256(data, origcode, compcode);
1.1  ahoka }
1.1  ahoka
1.1  ahoka void
1.1  ahoka nand_default_select(device_t self, bool enable)
1.1  ahoka {
1.1  ahoka 	/* do nothing */
1.1  ahoka 	return;
1.1  ahoka }
1.1  ahoka
1.1  ahoka /* implementation of the block device API */
1.1  ahoka
1.1  ahoka /*
1.1  ahoka  * handle (page) unaligned write to nand
1.1  ahoka  */
1.1  ahoka static int
1.7  ahoka nand_flash_write_unaligned(device_t self, flash_off_t offset, size_t len,
1.1  ahoka     size_t *retlen, const uint8_t *buf)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t first, last, firstoff;
1.1  ahoka 	const uint8_t *bufp;
1.7  ahoka 	flash_off_t addr;
1.1  ahoka 	size_t left, count;
1.8  ahoka 	int error = 0, i;
1.1  ahoka
1.1  ahoka 	first = offset & chip->nc_page_mask;
1.1  ahoka 	firstoff = offset & ~chip->nc_page_mask;
1.1  ahoka 	/* XXX check if this should be len - 1 */
1.1  ahoka 	last = (offset + len) & chip->nc_page_mask;
1.1  ahoka 	count = last - first + 1;
1.1  ahoka
1.1  ahoka 	addr = first;
1.1  ahoka 	*retlen = 0;
1.1  ahoka
1.8  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	if (count == 1) {
1.1  ahoka 		if (nand_isbad(self, addr)) {
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "nand_flash_write_unaligned: "
1.1  ahoka 			    "bad block encountered\n");
1.8  ahoka 			error = EIO;
1.8  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		error = nand_read_page(self, addr, chip->nc_page_cache);
1.8  ahoka 		if (error) {
1.8  ahoka 			goto out;
1.8  ahoka 		}
1.1  ahoka
1.1  ahoka 		memcpy(chip->nc_page_cache + firstoff, buf, len);
1.1  ahoka
1.1  ahoka 		error = nand_program_page(self, addr, chip->nc_page_cache);
1.8  ahoka 		if (error) {
1.8  ahoka 			goto out;
1.8  ahoka 		}
1.1  ahoka
1.1  ahoka 		*retlen = len;
1.8  ahoka 		goto out;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	bufp = buf;
1.1  ahoka 	left = len;
1.1  ahoka
1.1  ahoka 	for (i = 0; i < count && left != 0; i++) {
1.1  ahoka 		if (nand_isbad(self, addr)) {
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "nand_flash_write_unaligned: "
1.1  ahoka 			    "bad block encountered\n");
1.8  ahoka 			error = EIO;
1.8  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		if (i == 0) {
1.1  ahoka 			error = nand_read_page(self,
1.1  ahoka 			    addr, chip->nc_page_cache);
1.8  ahoka 			if (error) {
1.8  ahoka 				goto out;
1.8  ahoka 			}
1.1  ahoka
1.1  ahoka 			memcpy(chip->nc_page_cache + firstoff,
1.1  ahoka 			    bufp, chip->nc_page_size - firstoff);
1.1  ahoka
1.1  ahoka 			printf("program page: %s: %d\n", __FILE__, __LINE__);
1.1  ahoka 			error = nand_program_page(self,
1.1  ahoka 			    addr, chip->nc_page_cache);
1.8  ahoka 			if (error) {
1.8  ahoka 				goto out;
1.8  ahoka 			}
1.1  ahoka
1.1  ahoka 			bufp += chip->nc_page_size - firstoff;
1.1  ahoka 			left -= chip->nc_page_size - firstoff;
1.1  ahoka 			*retlen += chip->nc_page_size - firstoff;
1.1  ahoka
1.1  ahoka 		} else if (i == count - 1) {
1.1  ahoka 			error = nand_read_page(self,
1.1  ahoka 			    addr, chip->nc_page_cache);
1.8  ahoka 			if (error) {
1.8  ahoka 				goto out;
1.8  ahoka 			}
1.1  ahoka
1.1  ahoka 			memcpy(chip->nc_page_cache, bufp, left);
1.1  ahoka
1.1  ahoka 			error = nand_program_page(self,
1.1  ahoka 			    addr, chip->nc_page_cache);
1.8  ahoka 			if (error) {
1.8  ahoka 				goto out;
1.8  ahoka 			}
1.1  ahoka
1.1  ahoka 			*retlen += left;
1.1  ahoka 			KASSERT(left < chip->nc_page_size);
1.1  ahoka
1.1  ahoka 		} else {
1.1  ahoka 			/* XXX debug */
1.1  ahoka 			if (left > chip->nc_page_size) {
1.1  ahoka 				printf("left: %zu, i: %d, count: %zu\n",
1.1  ahoka 				    (size_t )left, i, count);
1.1  ahoka 			}
1.1  ahoka 			KASSERT(left > chip->nc_page_size);
1.1  ahoka
1.1  ahoka 			error = nand_program_page(self, addr, bufp);
1.8  ahoka 			if (error) {
1.8  ahoka 				goto out;
1.8  ahoka 			}
1.1  ahoka
1.1  ahoka 			bufp += chip->nc_page_size;
1.1  ahoka 			left -= chip->nc_page_size;
1.1  ahoka 			*retlen += chip->nc_page_size;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		addr += chip->nc_page_size;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	KASSERT(*retlen == len);
1.8  ahoka out:
1.8  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.8  ahoka 	return error;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.7  ahoka nand_flash_write(device_t self, flash_off_t offset, size_t len, size_t *retlen,
1.1  ahoka     const uint8_t *buf)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	const uint8_t *bufp;
1.1  ahoka 	size_t pages, page;
1.1  ahoka 	daddr_t addr;
1.1  ahoka 	int error = 0;
1.1  ahoka
1.1  ahoka 	if ((offset + len) > chip->nc_size) {
1.1  ahoka 		DPRINTF(("nand_flash_write: write (off: 0x%jx, len: %ju),"
1.1  ahoka 			" is over device size (0x%jx)\n",
1.1  ahoka 			(uintmax_t)offset, (uintmax_t)len,
1.1  ahoka 			(uintmax_t)chip->nc_size));
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (len % chip->nc_page_size != 0 ||
1.1  ahoka 	    offset % chip->nc_page_size != 0) {
1.1  ahoka 		return nand_flash_write_unaligned(self,
1.1  ahoka 		    offset, len, retlen, buf);
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	pages = len / chip->nc_page_size;
1.1  ahoka 	KASSERT(pages != 0);
1.1  ahoka 	*retlen = 0;
1.1  ahoka
1.1  ahoka 	addr = offset;
1.1  ahoka 	bufp = buf;
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	for (page = 0; page < pages; page++) {
1.1  ahoka 		/* do we need this check here? */
1.1  ahoka 		if (nand_isbad(self, addr)) {
1.1  ahoka 			aprint_error_dev(self,
1.1  ahoka 			    "nand_flash_write: bad block encountered\n");
1.1  ahoka
1.1  ahoka 			error = EIO;
1.1  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		error = nand_program_page(self, addr, bufp);
1.8  ahoka 		if (error) {
1.1  ahoka 			goto out;
1.8  ahoka 		}
1.1  ahoka
1.1  ahoka 		addr += chip->nc_page_size;
1.1  ahoka 		bufp += chip->nc_page_size;
1.1  ahoka 		*retlen += chip->nc_page_size;
1.1  ahoka 	}
1.1  ahoka out:
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka 	DPRINTF(("page programming: retlen: %zu, len: %zu\n", *retlen, len));
1.1  ahoka
1.1  ahoka 	return error;
1.1  ahoka }
1.1  ahoka
1.1  ahoka /*
1.1  ahoka  * handle (page) unaligned read from nand
1.1  ahoka  */
1.1  ahoka static int
1.1  ahoka nand_flash_read_unaligned(device_t self, size_t offset,
1.1  ahoka     size_t len, size_t *retlen, uint8_t *buf)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	daddr_t first, last, count, firstoff;
1.1  ahoka 	uint8_t *bufp;
1.1  ahoka 	daddr_t addr;
1.1  ahoka 	size_t left;
1.1  ahoka 	int error = 0, i;
1.1  ahoka
1.1  ahoka 	first = offset & chip->nc_page_mask;
1.1  ahoka 	firstoff = offset & ~chip->nc_page_mask;
1.1  ahoka 	last = (offset + len) & chip->nc_page_mask;
1.1  ahoka 	count = (last - first) / chip->nc_page_size + 1;
1.1  ahoka
1.1  ahoka 	addr = first;
1.1  ahoka 	bufp = buf;
1.1  ahoka 	left = len;
1.1  ahoka 	*retlen = 0;
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	if (count == 1) {
1.1  ahoka 		error = nand_read_page(self, addr, chip->nc_page_cache);
1.8  ahoka 		if (error) {
1.1  ahoka 			goto out;
1.8  ahoka 		}
1.1  ahoka
1.1  ahoka 		memcpy(bufp, chip->nc_page_cache + firstoff, len);
1.1  ahoka
1.1  ahoka 		*retlen = len;
1.1  ahoka 		goto out;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	for (i = 0; i < count && left != 0; i++) {
1.1  ahoka 		error = nand_read_page(self, addr, chip->nc_page_cache);
1.8  ahoka 		if (error) {
1.1  ahoka 			goto out;
1.8  ahoka 		}
1.1  ahoka
1.1  ahoka 		if (i == 0) {
1.1  ahoka 			memcpy(bufp, chip->nc_page_cache + firstoff,
1.1  ahoka 			    chip->nc_page_size - firstoff);
1.1  ahoka
1.1  ahoka 			bufp += chip->nc_page_size - firstoff;
1.1  ahoka 			left -= chip->nc_page_size - firstoff;
1.1  ahoka 			*retlen += chip->nc_page_size - firstoff;
1.1  ahoka
1.1  ahoka 		} else if (i == count - 1) {
1.1  ahoka 			memcpy(bufp, chip->nc_page_cache, left);
1.1  ahoka 			*retlen += left;
1.1  ahoka 			KASSERT(left < chip->nc_page_size);
1.1  ahoka
1.1  ahoka 		} else {
1.1  ahoka 			memcpy(bufp, chip->nc_page_cache, chip->nc_page_size);
1.1  ahoka
1.1  ahoka 			bufp += chip->nc_page_size;
1.1  ahoka 			left -= chip->nc_page_size;
1.1  ahoka 			*retlen += chip->nc_page_size;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		addr += chip->nc_page_size;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	KASSERT(*retlen == len);
1.1  ahoka
1.1  ahoka out:
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.1  ahoka 	return error;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.7  ahoka nand_flash_read(device_t self, flash_off_t offset, size_t len, size_t *retlen,
1.1  ahoka     uint8_t *buf)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	uint8_t *bufp;
1.1  ahoka 	size_t addr;
1.1  ahoka 	size_t i, pages;
1.1  ahoka 	int error = 0;
1.1  ahoka
1.1  ahoka 	*retlen = 0;
1.1  ahoka
1.1  ahoka 	DPRINTF(("nand_flash_read: off: 0x%jx, len: %zu\n",
1.1  ahoka 		(uintmax_t)offset, len));
1.1  ahoka
1.1  ahoka 	if (__predict_false((offset + len) > chip->nc_size)) {
1.1  ahoka 		DPRINTF(("nand_flash_read: read (off: 0x%jx, len: %zu),"
1.1  ahoka 			" is over device size (%ju)\n", (uintmax_t)offset,
1.1  ahoka 			len, (uintmax_t)chip->nc_size));
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	/* Handle unaligned access, shouldnt be needed when using the
1.1  ahoka 	 * block device, as strategy handles it, so only low level
1.1  ahoka 	 * accesses will use this path
1.1  ahoka 	 */
1.2  ahoka 	/* XXX^2 */
1.2  ahoka #if 0
1.2  ahoka 	if (len < chip->nc_page_size)
1.2  ahoka 		panic("TODO page size is larger than read size");
1.2  ahoka #endif
1.2  ahoka
1.1  ahoka
1.1  ahoka 	if (len % chip->nc_page_size != 0 ||
1.1  ahoka 	    offset % chip->nc_page_size != 0) {
1.1  ahoka 		return nand_flash_read_unaligned(self,
1.1  ahoka 		    offset, len, retlen, buf);
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	bufp = buf;
1.1  ahoka 	addr = offset;
1.1  ahoka 	pages = len / chip->nc_page_size;
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	for (i = 0; i < pages; i++) {
1.2  ahoka 		/* XXX do we need this check here? */
1.1  ahoka 		if (nand_isbad(self, addr)) {
1.1  ahoka 			aprint_error_dev(self, "bad block encountered\n");
1.1  ahoka 			error = EIO;
1.1  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka 		error = nand_read_page(self, addr, bufp);
1.1  ahoka 		if (error)
1.1  ahoka 			goto out;
1.1  ahoka
1.1  ahoka 		bufp += chip->nc_page_size;
1.1  ahoka 		addr += chip->nc_page_size;
1.1  ahoka 		*retlen += chip->nc_page_size;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka out:
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.1  ahoka 	return error;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.7  ahoka nand_flash_isbad(device_t self, flash_off_t ofs, bool *isbad)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka 	bool result;
1.1  ahoka
1.1  ahoka 	if (ofs > chip->nc_size) {
1.1  ahoka 		DPRINTF(("nand_flash_isbad: offset 0x%jx is larger than"
1.1  ahoka 			" device size (0x%jx)\n", (uintmax_t)ofs,
1.1  ahoka 			(uintmax_t)chip->nc_size));
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (ofs % chip->nc_block_size != 0) {
1.7  ahoka 		DPRINTF(("offset (0x%jx) is not the multiple of block size "
1.7  ahoka 			"(%ju)",
1.7  ahoka 			(uintmax_t)ofs, (uintmax_t)chip->nc_block_size));
1.7  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	result = nand_isbad(self, ofs);
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.7  ahoka 	*isbad = result;
1.7  ahoka
1.7  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.7  ahoka nand_flash_markbad(device_t self, flash_off_t ofs)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.1  ahoka
1.1  ahoka 	if (ofs > chip->nc_size) {
1.1  ahoka 		DPRINTF(("nand_flash_markbad: offset 0x%jx is larger than"
1.1  ahoka 			" device size (0x%jx)\n", ofs,
1.1  ahoka 			(uintmax_t)chip->nc_size));
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (ofs % chip->nc_block_size != 0) {
1.1  ahoka 		panic("offset (%ju) is not the multiple of block size (%ju)",
1.1  ahoka 		    (uintmax_t)ofs, (uintmax_t)chip->nc_block_size);
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	nand_markbad(self, ofs);
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka int
1.1  ahoka nand_flash_erase(device_t self,
1.1  ahoka     struct flash_erase_instruction *ei)
1.1  ahoka {
1.1  ahoka 	struct nand_softc *sc = device_private(self);
1.1  ahoka 	struct nand_chip *chip = &sc->sc_chip;
1.7  ahoka 	flash_off_t addr;
1.8  ahoka 	int error = 0;
1.1  ahoka
1.1  ahoka 	if (ei->ei_addr < 0 || ei->ei_len < chip->nc_block_size)
1.1  ahoka 		return EINVAL;
1.1  ahoka
1.1  ahoka 	if (ei->ei_addr + ei->ei_len > chip->nc_size) {
1.1  ahoka 		DPRINTF(("nand_flash_erase: erase address is over the end"
1.1  ahoka 			" of the device\n"));
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (ei->ei_addr % chip->nc_block_size != 0) {
1.1  ahoka 		aprint_error_dev(self,
1.1  ahoka 		    "nand_flash_erase: ei_addr (%ju) is not"
1.1  ahoka 		    "the multiple of block size (%ju)",
1.1  ahoka 		    (uintmax_t)ei->ei_addr,
1.1  ahoka 		    (uintmax_t)chip->nc_block_size);
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if (ei->ei_len % chip->nc_block_size != 0) {
1.1  ahoka 		aprint_error_dev(self,
1.1  ahoka 		    "nand_flash_erase: ei_len (%ju) is not"
1.1  ahoka 		    "the multiple of block size (%ju)",
1.1  ahoka 		    (uintmax_t)ei->ei_addr,
1.1  ahoka 		    (uintmax_t)chip->nc_block_size);
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	mutex_enter(&sc->sc_device_lock);
1.1  ahoka 	addr = ei->ei_addr;
1.1  ahoka 	while (addr < ei->ei_addr + ei->ei_len) {
1.1  ahoka 		if (nand_isbad(self, addr)) {
1.1  ahoka 			aprint_error_dev(self, "bad block encountered\n");
1.1  ahoka 			ei->ei_state = FLASH_ERASE_FAILED;
1.8  ahoka
1.8  ahoka 			error = EIO;
1.8  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		error = nand_erase_block(self, addr);
1.1  ahoka 		if (error) {
1.1  ahoka 			ei->ei_state = FLASH_ERASE_FAILED;
1.8  ahoka
1.8  ahoka 			goto out;
1.1  ahoka 		}
1.1  ahoka
1.1  ahoka 		addr += chip->nc_block_size;
1.1  ahoka 	}
1.1  ahoka 	mutex_exit(&sc->sc_device_lock);
1.1  ahoka
1.1  ahoka 	ei->ei_state = FLASH_ERASE_DONE;
1.8  ahoka 	if (ei->ei_callback != NULL) {
1.1  ahoka 		ei->ei_callback(ei);
1.8  ahoka 	}
1.1  ahoka
1.1  ahoka 	return 0;
1.8  ahoka out:
1.8  ahoka 	mutex_exit(&sc->sc_device_lock);
1.8  ahoka
1.8  ahoka 	return error;
1.1  ahoka }
1.1  ahoka
1.1  ahoka static int
1.1  ahoka sysctl_nand_verify(SYSCTLFN_ARGS)
1.1  ahoka {
1.1  ahoka 	int error, t;
1.1  ahoka 	struct sysctlnode node;
1.1  ahoka
1.1  ahoka 	node = *rnode;
1.1  ahoka 	t = *(int *)rnode->sysctl_data;
1.1  ahoka 	node.sysctl_data = &t;
1.1  ahoka 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
1.1  ahoka 	if (error || newp == NULL)
1.1  ahoka 		return error;
1.1  ahoka
1.1  ahoka 	if (node.sysctl_num == nand_cachesync_nodenum) {
1.1  ahoka 		if (t <= 0 || t > 60)
1.1  ahoka 			return EINVAL;
1.1  ahoka 	} else {
1.1  ahoka 		return EINVAL;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	*(int *)rnode->sysctl_data = t;
1.1  ahoka
1.1  ahoka 	return 0;
1.1  ahoka }
1.1  ahoka
1.1  ahoka SYSCTL_SETUP(sysctl_nand, "sysctl nand subtree setup")
1.1  ahoka {
1.1  ahoka 	int rc, nand_root_num;
1.1  ahoka 	const struct sysctlnode *node;
1.1  ahoka
1.1  ahoka 	if ((rc = sysctl_createv(clog, 0, NULL, NULL,
1.1  ahoka 	    CTLFLAG_PERMANENT, CTLTYPE_NODE, "hw", NULL,
1.1  ahoka 	    NULL, 0, NULL, 0, CTL_HW, CTL_EOL)) != 0) {
1.1  ahoka 		goto error;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	if ((rc = sysctl_createv(clog, 0, NULL, &node,
1.1  ahoka 	    CTLFLAG_PERMANENT, CTLTYPE_NODE, "nand",
1.1  ahoka 	    SYSCTL_DESCR("NAND driver controls"),
1.1  ahoka 	    NULL, 0, NULL, 0, CTL_HW, CTL_CREATE, CTL_EOL)) != 0) {
1.1  ahoka 		goto error;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	nand_root_num = node->sysctl_num;
1.1  ahoka
1.1  ahoka 	if ((rc = sysctl_createv(clog, 0, NULL, &node,
1.1  ahoka 	    CTLFLAG_PERMANENT|CTLFLAG_READWRITE,
1.1  ahoka 	    CTLTYPE_INT, "cache_sync_timeout",
1.1  ahoka 	    SYSCTL_DESCR("NAND write cache sync timeout in seconds"),
1.1  ahoka 	    sysctl_nand_verify, 0, &nand_cachesync_timeout,
1.1  ahoka 	    0, CTL_HW, nand_root_num, CTL_CREATE,
1.1  ahoka 	    CTL_EOL)) != 0) {
1.1  ahoka 		goto error;
1.1  ahoka 	}
1.1  ahoka
1.1  ahoka 	nand_cachesync_nodenum = node->sysctl_num;
1.1  ahoka
1.1  ahoka 	return;
1.1  ahoka
1.1  ahoka error:
1.1  ahoka 	aprint_error("%s: sysctl_createv failed (rc = %d)\n", __func__, rc);
1.1  ahoka }
1.1  ahoka
1.1  ahoka MODULE(MODULE_CLASS_DRIVER, nand, "flash");
1.1  ahoka
1.1  ahoka #ifdef _MODULE
1.1  ahoka #include "ioconf.c"
1.1  ahoka #endif
1.1  ahoka
1.1  ahoka static int
1.1  ahoka nand_modcmd(modcmd_t cmd, void *opaque)
1.1  ahoka {
1.1  ahoka 	switch (cmd) {
1.1  ahoka 	case MODULE_CMD_INIT:
1.1  ahoka #ifdef _MODULE
1.1  ahoka 		return config_init_component(cfdriver_ioconf_nand,
1.1  ahoka 		    cfattach_ioconf_nand, cfdata_ioconf_nand);
1.1  ahoka #else
1.1  ahoka 		return 0;
1.1  ahoka #endif
1.1  ahoka 	case MODULE_CMD_FINI:
1.1  ahoka #ifdef _MODULE
1.1  ahoka 		return config_fini_component(cfdriver_ioconf_nand,
1.1  ahoka 		    cfattach_ioconf_nand, cfdata_ioconf_nand);
1.1  ahoka #else
1.1  ahoka 		return 0;
1.1  ahoka #endif
1.1  ahoka 	default:
1.1  ahoka 		return ENOTTY;
1.1  ahoka 	}
1.1  ahoka }