drivers/mtd/nand/raw/nand_hynix.c - third_party/kernel - Git at Google

 /*
  * Copyright (C) 2017 Free Electrons
  * Copyright (C) 2017 NextThing Co
  *
  * Author: Boris Brezillon <boris.brezillon@free-electrons.com>
  *
  * 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 program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  */

 #include <linux/mtd/rawnand.h>
 #include <linux/sizes.h>
 #include <linux/slab.h>

 #define NAND_HYNIX_CMD_SET_PARAMS	0x36
 #define NAND_HYNIX_CMD_APPLY_PARAMS	0x16

 #define NAND_HYNIX_1XNM_RR_REPEAT	8

 /**
  * struct hynix_read_retry - read-retry data
  * @nregs: number of register to set when applying a new read-retry mode
  * @regs: register offsets (NAND chip dependent)
  * @values: array of values to set in registers. The array size is equal to
  *	    (nregs * nmodes)
  */
 struct hynix_read_retry {
 	int nregs;
 	const u8 *regs;
 	u8 values[0];
 };

 /**
  * struct hynix_nand - private Hynix NAND struct
  * @nand_technology: manufacturing process expressed in picometer
  * @read_retry: read-retry information
  */
 struct hynix_nand {
 	const struct hynix_read_retry *read_retry;
 };

 /**
  * struct hynix_read_retry_otp - structure describing how the read-retry OTP
  *				 area
  * @nregs: number of hynix private registers to set before reading the reading
  *	   the OTP area
  * @regs: registers that should be configured
  * @values: values that should be set in regs
  * @page: the address to pass to the READ_PAGE command. Depends on the NAND
  *	  chip
  * @size: size of the read-retry OTP section
  */
 struct hynix_read_retry_otp {
 	int nregs;
 	const u8 *regs;
 	const u8 *values;
 	int page;
 	int size;
 };

 static bool hynix_nand_has_valid_jedecid(struct nand_chip *chip)
 {
 	u8 jedecid[5] = { };
 	int ret;

 	ret = nand_readid_op(chip, 0x40, jedecid, sizeof(jedecid));
 	if (ret)
 		return false;

 	return !strncmp("JEDEC", jedecid, sizeof(jedecid));
 }

 static int hynix_nand_cmd_op(struct nand_chip *chip, u8 cmd)
 {
 	struct mtd_info *mtd = nand_to_mtd(chip);

 	if (chip->exec_op) {
 		struct nand_op_instr instrs[] = {
 			NAND_OP_CMD(cmd, 0),
 		};
 		struct nand_operation op = NAND_OPERATION(instrs);

 		return nand_exec_op(chip, &op);
 	}

 	chip->cmdfunc(mtd, cmd, -1, -1);

 	return 0;
 }

 static int hynix_nand_reg_write_op(struct nand_chip *chip, u8 addr, u8 val)
 {
 	struct mtd_info *mtd = nand_to_mtd(chip);
 	u16 column = ((u16)addr << 8) | addr;

 	if (chip->exec_op) {
 		struct nand_op_instr instrs[] = {
 			NAND_OP_ADDR(1, &addr, 0),
 			NAND_OP_8BIT_DATA_OUT(1, &val, 0),
 		};
 		struct nand_operation op = NAND_OPERATION(instrs);

 		return nand_exec_op(chip, &op);
 	}

 	chip->cmdfunc(mtd, NAND_CMD_NONE, column, -1);
 	chip->write_byte(mtd, val);

 	return 0;
 }

 static int hynix_nand_setup_read_retry(struct mtd_info *mtd, int retry_mode)
 {
 	struct nand_chip *chip = mtd_to_nand(mtd);
 	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);
 	const u8 *values;
 	int i, ret;

 	values = hynix->read_retry->values +
 		 (retry_mode * hynix->read_retry->nregs);

 	/* Enter 'Set Hynix Parameters' mode */
 	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
 	if (ret)
 		return ret;

 	/*
 	 * Configure the NAND in the requested read-retry mode.
 	 * This is done by setting pre-defined values in internal NAND
 	 * registers.
 	 *
 	 * The set of registers is NAND specific, and the values are either
 	 * predefined or extracted from an OTP area on the NAND (values are
 	 * probably tweaked at production in this case).
 	 */
 	for (i = 0; i < hynix->read_retry->nregs; i++) {
 		ret = hynix_nand_reg_write_op(chip, hynix->read_retry->regs[i],
 					      values[i]);
 		if (ret)
 			return ret;
 	}

 	/* Apply the new settings. */
 	return hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
 }

 /**
  * hynix_get_majority - get the value that is occurring the most in a given
  *			set of values
  * @in: the array of values to test
  * @repeat: the size of the in array
  * @out: pointer used to store the output value
  *
  * This function implements the 'majority check' logic that is supposed to
  * overcome the unreliability of MLC NANDs when reading the OTP area storing
  * the read-retry parameters.
  *
  * It's based on a pretty simple assumption: if we repeat the same value
  * several times and then take the one that is occurring the most, we should
  * find the correct value.
  * Let's hope this dummy algorithm prevents us from losing the read-retry
  * parameters.
  */
 static int hynix_get_majority(const u8 *in, int repeat, u8 *out)
 {
 	int i, j, half = repeat / 2;

 	/*
 	 * We only test the first half of the in array because we must ensure
 	 * that the value is at least occurring repeat / 2 times.
 	 *
 	 * This loop is suboptimal since we may count the occurrences of the
 	 * same value several time, but we are doing that on small sets, which
 	 * makes it acceptable.
 	 */
 	for (i = 0; i < half; i++) {
 		int cnt = 0;
 		u8 val = in[i];

 		/* Count all values that are matching the one at index i. */
 		for (j = i + 1; j < repeat; j++) {
 			if (in[j] == val)
 				cnt++;
 		}

 		/* We found a value occurring more than repeat / 2. */
 		if (cnt > half) {
 			*out = val;
 			return 0;
 		}
 	}

 	return -EIO;
 }

 static int hynix_read_rr_otp(struct nand_chip *chip,
 			     const struct hynix_read_retry_otp *info,
 			     void *buf)
 {
 	int i, ret;

 	ret = nand_reset_op(chip);
 	if (ret)
 		return ret;

 	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
 	if (ret)
 		return ret;

 	for (i = 0; i < info->nregs; i++) {
 		ret = hynix_nand_reg_write_op(chip, info->regs[i],
 					      info->values[i]);
 		if (ret)
 			return ret;
 	}

 	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
 	if (ret)
 		return ret;

 	/* Sequence to enter OTP mode? */
 	ret = hynix_nand_cmd_op(chip, 0x17);
 	if (ret)
 		return ret;

 	ret = hynix_nand_cmd_op(chip, 0x4);
 	if (ret)
 		return ret;

 	ret = hynix_nand_cmd_op(chip, 0x19);
 	if (ret)
 		return ret;

 	/* Now read the page */
 	ret = nand_read_page_op(chip, info->page, 0, buf, info->size);
 	if (ret)
 		return ret;

 	/* Put everything back to normal */
 	ret = nand_reset_op(chip);
 	if (ret)
 		return ret;

 	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
 	if (ret)
 		return ret;

 	ret = hynix_nand_reg_write_op(chip, 0x38, 0);
 	if (ret)
 		return ret;

 	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
 	if (ret)
 		return ret;

 	return nand_read_page_op(chip, 0, 0, NULL, 0);
 }

 #define NAND_HYNIX_1XNM_RR_COUNT_OFFS				0
 #define NAND_HYNIX_1XNM_RR_REG_COUNT_OFFS			8
 #define NAND_HYNIX_1XNM_RR_SET_OFFS(x, setsize, inv)		\
 	(16 + ((((x) * 2) + ((inv) ? 1 : 0)) * (setsize)))

 static int hynix_mlc_1xnm_rr_value(const u8 *buf, int nmodes, int nregs,
 				   int mode, int reg, bool inv, u8 *val)
 {
 	u8 tmp[NAND_HYNIX_1XNM_RR_REPEAT];
 	int val_offs = (mode * nregs) + reg;
 	int set_size = nmodes * nregs;
 	int i, ret;

 	for (i = 0; i < NAND_HYNIX_1XNM_RR_REPEAT; i++) {
 		int set_offs = NAND_HYNIX_1XNM_RR_SET_OFFS(i, set_size, inv);

 		tmp[i] = buf[val_offs + set_offs];
 	}

 	ret = hynix_get_majority(tmp, NAND_HYNIX_1XNM_RR_REPEAT, val);
 	if (ret)
 		return ret;

 	if (inv)
 		*val = ~*val;

 	return 0;
 }

 static u8 hynix_1xnm_mlc_read_retry_regs[] = {
 	0xcc, 0xbf, 0xaa, 0xab, 0xcd, 0xad, 0xae, 0xaf
 };

 static int hynix_mlc_1xnm_rr_init(struct nand_chip *chip,
 				  const struct hynix_read_retry_otp *info)
 {
 	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);
 	struct hynix_read_retry *rr = NULL;
 	int ret, i, j;
 	u8 nregs, nmodes;
 	u8 *buf;

 	buf = kmalloc(info->size, GFP_KERNEL);
 	if (!buf)
 		return -ENOMEM;

 	ret = hynix_read_rr_otp(chip, info, buf);
 	if (ret)
 		goto out;

 	ret = hynix_get_majority(buf, NAND_HYNIX_1XNM_RR_REPEAT,
 				 &nmodes);
 	if (ret)
 		goto out;

 	ret = hynix_get_majority(buf + NAND_HYNIX_1XNM_RR_REPEAT,
 				 NAND_HYNIX_1XNM_RR_REPEAT,
 				 &nregs);
 	if (ret)
 		goto out;

 	rr = kzalloc(sizeof(*rr) + (nregs * nmodes), GFP_KERNEL);
 	if (!rr) {
 		ret = -ENOMEM;
 		goto out;
 	}

 	for (i = 0; i < nmodes; i++) {
 		for (j = 0; j < nregs; j++) {
 			u8 *val = rr->values + (i * nregs);

 			ret = hynix_mlc_1xnm_rr_value(buf, nmodes, nregs, i, j,
 						      false, val);
 			if (!ret)
 				continue;

 			ret = hynix_mlc_1xnm_rr_value(buf, nmodes, nregs, i, j,
 						      true, val);
 			if (ret)
 				goto out;
 		}
 	}

 	rr->nregs = nregs;
 	rr->regs = hynix_1xnm_mlc_read_retry_regs;
 	hynix->read_retry = rr;
 	chip->setup_read_retry = hynix_nand_setup_read_retry;
 	chip->read_retries = nmodes;

 out:
 	kfree(buf);

 	if (ret)
 		kfree(rr);

 	return ret;
 }

 static const u8 hynix_mlc_1xnm_rr_otp_regs[] = { 0x38 };
 static const u8 hynix_mlc_1xnm_rr_otp_values[] = { 0x52 };

 static const struct hynix_read_retry_otp hynix_mlc_1xnm_rr_otps[] = {
 	{
 		.nregs = ARRAY_SIZE(hynix_mlc_1xnm_rr_otp_regs),
 		.regs = hynix_mlc_1xnm_rr_otp_regs,
 		.values = hynix_mlc_1xnm_rr_otp_values,
 		.page = 0x21f,
 		.size = 784
 	},
 	{
 		.nregs = ARRAY_SIZE(hynix_mlc_1xnm_rr_otp_regs),
 		.regs = hynix_mlc_1xnm_rr_otp_regs,
 		.values = hynix_mlc_1xnm_rr_otp_values,
 		.page = 0x200,
 		.size = 528,
 	},
 };

 static int hynix_nand_rr_init(struct nand_chip *chip)
 {
 	int i, ret = 0;
 	bool valid_jedecid;

 	valid_jedecid = hynix_nand_has_valid_jedecid(chip);

 	/*
 	 * We only support read-retry for 1xnm NANDs, and those NANDs all
 	 * expose a valid JEDEC ID.
 	 */
 	if (valid_jedecid) {
 		u8 nand_tech = chip->id.data[5] >> 4;

 		/* 1xnm technology */
 		if (nand_tech == 4) {
 			for (i = 0; i < ARRAY_SIZE(hynix_mlc_1xnm_rr_otps);
 			     i++) {
 				/*
 				 * FIXME: Hynix recommend to copy the
 				 * read-retry OTP area into a normal page.
 				 */
 				ret = hynix_mlc_1xnm_rr_init(chip,
 						hynix_mlc_1xnm_rr_otps);
 				if (!ret)
 					break;
 			}
 		}
 	}

 	if (ret)
 		pr_warn("failed to initialize read-retry infrastructure");

 	return 0;
 }

 static void hynix_nand_extract_oobsize(struct nand_chip *chip,
 				       bool valid_jedecid)
 {
 	struct mtd_info *mtd = nand_to_mtd(chip);
 	u8 oobsize;

 	oobsize = ((chip->id.data[3] >> 2) & 0x3) |
 		  ((chip->id.data[3] >> 4) & 0x4);

 	if (valid_jedecid) {
 		switch (oobsize) {
 		case 0:
 			mtd->oobsize = 2048;
 			break;
 		case 1:
 			mtd->oobsize = 1664;
 			break;
 		case 2:
 			mtd->oobsize = 1024;
 			break;
 		case 3:
 			mtd->oobsize = 640;
 			break;
 		default:
 			/*
 			 * We should never reach this case, but if that
 			 * happens, this probably means Hynix decided to use
 			 * a different extended ID format, and we should find
 			 * a way to support it.
 			 */
 			WARN(1, "Invalid OOB size");
 			break;
 		}
 	} else {
 		switch (oobsize) {
 		case 0:
 			mtd->oobsize = 128;
 			break;
 		case 1:
 			mtd->oobsize = 224;
 			break;
 		case 2:
 			mtd->oobsize = 448;
 			break;
 		case 3:
 			mtd->oobsize = 64;
 			break;
 		case 4:
 			mtd->oobsize = 32;
 			break;
 		case 5:
 			mtd->oobsize = 16;
 			break;
 		case 6:
 			mtd->oobsize = 640;
 			break;
 		default:
 			/*
 			 * We should never reach this case, but if that
 			 * happens, this probably means Hynix decided to use
 			 * a different extended ID format, and we should find
 			 * a way to support it.
 			 */
 			WARN(1, "Invalid OOB size");
 			break;
 		}

 		/*
 		 * The datasheet of H27UCG8T2BTR mentions that the "Redundant
 		 * Area Size" is encoded "per 8KB" (page size). This chip uses
 		 * a page size of 16KiB. The datasheet mentions an OOB size of
 		 * 1.280 bytes, but the OOB size encoded in the ID bytes (using
 		 * the existing logic above) is 640 bytes.
 		 * Update the OOB size for this chip by taking the value
 		 * determined above and scaling it to the actual page size (so
 		 * the actual OOB size for this chip is: 640 * 16k / 8k).
 		 */
 		if (chip->id.data[1] == 0xde)
 			mtd->oobsize *= mtd->writesize / SZ_8K;
 	}
 }

 static void hynix_nand_extract_ecc_requirements(struct nand_chip *chip,
 						bool valid_jedecid)
 {
 	u8 ecc_level = (chip->id.data[4] >> 4) & 0x7;

 	if (valid_jedecid) {
 		/* Reference: H27UCG8T2E datasheet */
 		chip->ecc_step_ds = 1024;

 		switch (ecc_level) {
 		case 0:
 			chip->ecc_step_ds = 0;
 			chip->ecc_strength_ds = 0;
 			break;
 		case 1:
 			chip->ecc_strength_ds = 4;
 			break;
 		case 2:
 			chip->ecc_strength_ds = 24;
 			break;
 		case 3:
 			chip->ecc_strength_ds = 32;
 			break;
 		case 4:
 			chip->ecc_strength_ds = 40;
 			break;
 		case 5:
 			chip->ecc_strength_ds = 50;
 			break;
 		case 6:
 			chip->ecc_strength_ds = 60;
 			break;
 		default:
 			/*
 			 * We should never reach this case, but if that
 			 * happens, this probably means Hynix decided to use
 			 * a different extended ID format, and we should find
 			 * a way to support it.
 			 */
 			WARN(1, "Invalid ECC requirements");
 		}
 	} else {
 		/*
 		 * The ECC requirements field meaning depends on the
 		 * NAND technology.
 		 */
 		u8 nand_tech = chip->id.data[5] & 0x7;

 		if (nand_tech < 3) {
 			/* > 26nm, reference: H27UBG8T2A datasheet */
 			if (ecc_level < 5) {
 				chip->ecc_step_ds = 512;
 				chip->ecc_strength_ds = 1 << ecc_level;
 			} else if (ecc_level < 7) {
 				if (ecc_level == 5)
 					chip->ecc_step_ds = 2048;
 				else
 					chip->ecc_step_ds = 1024;
 				chip->ecc_strength_ds = 24;
 			} else {
 				/*
 				 * We should never reach this case, but if that
 				 * happens, this probably means Hynix decided
 				 * to use a different extended ID format, and
 				 * we should find a way to support it.
 				 */
 				WARN(1, "Invalid ECC requirements");
 			}
 		} else {
 			/* <= 26nm, reference: H27UBG8T2B datasheet */
 			if (!ecc_level) {
 				chip->ecc_step_ds = 0;
 				chip->ecc_strength_ds = 0;
 			} else if (ecc_level < 5) {
 				chip->ecc_step_ds = 512;
 				chip->ecc_strength_ds = 1 << (ecc_level - 1);
 			} else {
 				chip->ecc_step_ds = 1024;
 				chip->ecc_strength_ds = 24 +
 							(8 * (ecc_level - 5));
 			}
 		}
 	}
 }

 static void hynix_nand_extract_scrambling_requirements(struct nand_chip *chip,
 						       bool valid_jedecid)
 {
 	u8 nand_tech;

 	/* We need scrambling on all TLC NANDs*/
 	if (chip->bits_per_cell > 2)
 		chip->options |= NAND_NEED_SCRAMBLING;

 	/* And on MLC NANDs with sub-3xnm process */
 	if (valid_jedecid) {
 		nand_tech = chip->id.data[5] >> 4;

 		/* < 3xnm */
 		if (nand_tech > 0)
 			chip->options |= NAND_NEED_SCRAMBLING;
 	} else {
 		nand_tech = chip->id.data[5] & 0x7;

 		/* < 32nm */
 		if (nand_tech > 2)
 			chip->options |= NAND_NEED_SCRAMBLING;
 	}
 }

 static void hynix_nand_decode_id(struct nand_chip *chip)
 {
 	struct mtd_info *mtd = nand_to_mtd(chip);
 	bool valid_jedecid;
 	u8 tmp;

 	/*
 	 * Exclude all SLC NANDs from this advanced detection scheme.
 	 * According to the ranges defined in several datasheets, it might
 	 * appear that even SLC NANDs could fall in this extended ID scheme.
 	 * If that the case rework the test to let SLC NANDs go through the
 	 * detection process.
 	 */
 	if (chip->id.len < 6 || nand_is_slc(chip)) {
 		nand_decode_ext_id(chip);
 		return;
 	}

 	/* Extract pagesize */
 	mtd->writesize = 2048 << (chip->id.data[3] & 0x03);

 	tmp = (chip->id.data[3] >> 4) & 0x3;
 	/*
 	 * When bit7 is set that means we start counting at 1MiB, otherwise
 	 * we start counting at 128KiB and shift this value the content of
 	 * ID[3][4:5].
 	 * The only exception is when ID[3][4:5] == 3 and ID[3][7] == 0, in
 	 * this case the erasesize is set to 768KiB.
 	 */
 	if (chip->id.data[3] & 0x80)
 		mtd->erasesize = SZ_1M << tmp;
 	else if (tmp == 3)
 		mtd->erasesize = SZ_512K + SZ_256K;
 	else
 		mtd->erasesize = SZ_128K << tmp;

 	/*
 	 * Modern Toggle DDR NANDs have a valid JEDECID even though they are
 	 * not exposing a valid JEDEC parameter table.
 	 * These NANDs use a different NAND ID scheme.
 	 */
 	valid_jedecid = hynix_nand_has_valid_jedecid(chip);

 	hynix_nand_extract_oobsize(chip, valid_jedecid);
 	hynix_nand_extract_ecc_requirements(chip, valid_jedecid);
 	hynix_nand_extract_scrambling_requirements(chip, valid_jedecid);
 }

 static void hynix_nand_cleanup(struct nand_chip *chip)
 {
 	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);

 	if (!hynix)
 		return;

 	kfree(hynix->read_retry);
 	kfree(hynix);
 	nand_set_manufacturer_data(chip, NULL);
 }

 static int hynix_nand_init(struct nand_chip *chip)
 {
 	struct hynix_nand *hynix;
 	int ret;

 	if (!nand_is_slc(chip))
 		chip->bbt_options |= NAND_BBT_SCANLASTPAGE;
 	else
 		chip->bbt_options |= NAND_BBT_SCAN2NDPAGE;

 	hynix = kzalloc(sizeof(*hynix), GFP_KERNEL);
 	if (!hynix)
 		return -ENOMEM;

 	nand_set_manufacturer_data(chip, hynix);

 	ret = hynix_nand_rr_init(chip);
 	if (ret)
 		hynix_nand_cleanup(chip);

 	return ret;
 }

 const struct nand_manufacturer_ops hynix_nand_manuf_ops = {
 	.detect = hynix_nand_decode_id,
 	.init = hynix_nand_init,
 	.cleanup = hynix_nand_cleanup,
 };
	/*
	* Copyright (C) 2017 Free Electrons
	* Copyright (C) 2017 NextThing Co
	*
	* Author: Boris Brezillon <boris.brezillon@free-electrons.com>
	*
	* 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 program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*/

	#include <linux/mtd/rawnand.h>
	#include <linux/sizes.h>
	#include <linux/slab.h>

	#define NAND_HYNIX_CMD_SET_PARAMS 0x36
	#define NAND_HYNIX_CMD_APPLY_PARAMS 0x16

	#define NAND_HYNIX_1XNM_RR_REPEAT 8

	/**
	* struct hynix_read_retry - read-retry data
	* @nregs: number of register to set when applying a new read-retry mode
	* @regs: register offsets (NAND chip dependent)
	* @values: array of values to set in registers. The array size is equal to
	* (nregs * nmodes)
	*/
	struct hynix_read_retry {
	int nregs;
	const u8 *regs;
	u8 values[0];
	};

	/**
	* struct hynix_nand - private Hynix NAND struct
	* @nand_technology: manufacturing process expressed in picometer
	* @read_retry: read-retry information
	*/
	struct hynix_nand {
	const struct hynix_read_retry *read_retry;
	};

	/**
	* struct hynix_read_retry_otp - structure describing how the read-retry OTP
	* area
	* @nregs: number of hynix private registers to set before reading the reading
	* the OTP area
	* @regs: registers that should be configured
	* @values: values that should be set in regs
	* @page: the address to pass to the READ_PAGE command. Depends on the NAND
	* chip
	* @size: size of the read-retry OTP section
	*/
	struct hynix_read_retry_otp {
	int nregs;
	const u8 *regs;
	const u8 *values;
	int page;
	int size;
	};

	static bool hynix_nand_has_valid_jedecid(struct nand_chip *chip)
	{
	u8 jedecid[5] = { };
	int ret;

	ret = nand_readid_op(chip, 0x40, jedecid, sizeof(jedecid));
	if (ret)
	return false;

	return !strncmp("JEDEC", jedecid, sizeof(jedecid));
	}

	static int hynix_nand_cmd_op(struct nand_chip *chip, u8 cmd)
	{
	struct mtd_info *mtd = nand_to_mtd(chip);

	if (chip->exec_op) {
	struct nand_op_instr instrs[] = {
	NAND_OP_CMD(cmd, 0),
	};
	struct nand_operation op = NAND_OPERATION(instrs);

	return nand_exec_op(chip, &op);
	}

	chip->cmdfunc(mtd, cmd, -1, -1);

	return 0;
	}

	static int hynix_nand_reg_write_op(struct nand_chip *chip, u8 addr, u8 val)
	{
	struct mtd_info *mtd = nand_to_mtd(chip);
	u16 column = ((u16)addr << 8) \| addr;

	if (chip->exec_op) {
	struct nand_op_instr instrs[] = {
	NAND_OP_ADDR(1, &addr, 0),
	NAND_OP_8BIT_DATA_OUT(1, &val, 0),
	};
	struct nand_operation op = NAND_OPERATION(instrs);

	return nand_exec_op(chip, &op);
	}

	chip->cmdfunc(mtd, NAND_CMD_NONE, column, -1);
	chip->write_byte(mtd, val);

	return 0;
	}

	static int hynix_nand_setup_read_retry(struct mtd_info *mtd, int retry_mode)
	{
	struct nand_chip *chip = mtd_to_nand(mtd);
	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);
	const u8 *values;
	int i, ret;

	values = hynix->read_retry->values +
	(retry_mode * hynix->read_retry->nregs);

	/* Enter 'Set Hynix Parameters' mode */
	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
	if (ret)
	return ret;

	/*
	* Configure the NAND in the requested read-retry mode.
	* This is done by setting pre-defined values in internal NAND
	* registers.
	*
	* The set of registers is NAND specific, and the values are either
	* predefined or extracted from an OTP area on the NAND (values are
	* probably tweaked at production in this case).
	*/
	for (i = 0; i < hynix->read_retry->nregs; i++) {
	ret = hynix_nand_reg_write_op(chip, hynix->read_retry->regs[i],
	values[i]);
	if (ret)
	return ret;
	}

	/* Apply the new settings. */
	return hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
	}

	/**
	* hynix_get_majority - get the value that is occurring the most in a given
	* set of values
	* @in: the array of values to test
	* @repeat: the size of the in array
	* @out: pointer used to store the output value
	*
	* This function implements the 'majority check' logic that is supposed to
	* overcome the unreliability of MLC NANDs when reading the OTP area storing
	* the read-retry parameters.
	*
	* It's based on a pretty simple assumption: if we repeat the same value
	* several times and then take the one that is occurring the most, we should
	* find the correct value.
	* Let's hope this dummy algorithm prevents us from losing the read-retry
	* parameters.
	*/
	static int hynix_get_majority(const u8 in, int repeat, u8 out)
	{
	int i, j, half = repeat / 2;

	/*
	* We only test the first half of the in array because we must ensure
	* that the value is at least occurring repeat / 2 times.
	*
	* This loop is suboptimal since we may count the occurrences of the
	* same value several time, but we are doing that on small sets, which
	* makes it acceptable.
	*/
	for (i = 0; i < half; i++) {
	int cnt = 0;
	u8 val = in[i];

	/* Count all values that are matching the one at index i. */
	for (j = i + 1; j < repeat; j++) {
	if (in[j] == val)
	cnt++;
	}

	/* We found a value occurring more than repeat / 2. */
	if (cnt > half) {
	*out = val;
	return 0;
	}
	}

	return -EIO;
	}

	static int hynix_read_rr_otp(struct nand_chip *chip,
	const struct hynix_read_retry_otp *info,
	void *buf)
	{
	int i, ret;

	ret = nand_reset_op(chip);
	if (ret)
	return ret;

	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
	if (ret)
	return ret;

	for (i = 0; i < info->nregs; i++) {
	ret = hynix_nand_reg_write_op(chip, info->regs[i],
	info->values[i]);
	if (ret)
	return ret;
	}

	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
	if (ret)
	return ret;

	/* Sequence to enter OTP mode? */
	ret = hynix_nand_cmd_op(chip, 0x17);
	if (ret)
	return ret;

	ret = hynix_nand_cmd_op(chip, 0x4);
	if (ret)
	return ret;

	ret = hynix_nand_cmd_op(chip, 0x19);
	if (ret)
	return ret;

	/* Now read the page */
	ret = nand_read_page_op(chip, info->page, 0, buf, info->size);
	if (ret)
	return ret;

	/* Put everything back to normal */
	ret = nand_reset_op(chip);
	if (ret)
	return ret;

	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_SET_PARAMS);
	if (ret)
	return ret;

	ret = hynix_nand_reg_write_op(chip, 0x38, 0);
	if (ret)
	return ret;

	ret = hynix_nand_cmd_op(chip, NAND_HYNIX_CMD_APPLY_PARAMS);
	if (ret)
	return ret;

	return nand_read_page_op(chip, 0, 0, NULL, 0);
	}

	#define NAND_HYNIX_1XNM_RR_COUNT_OFFS 0
	#define NAND_HYNIX_1XNM_RR_REG_COUNT_OFFS 8
	#define NAND_HYNIX_1XNM_RR_SET_OFFS(x, setsize, inv) \
	(16 + ((((x) * 2) + ((inv) ? 1 : 0)) * (setsize)))

	static int hynix_mlc_1xnm_rr_value(const u8 *buf, int nmodes, int nregs,
	int mode, int reg, bool inv, u8 *val)
	{
	u8 tmp[NAND_HYNIX_1XNM_RR_REPEAT];
	int val_offs = (mode * nregs) + reg;
	int set_size = nmodes * nregs;
	int i, ret;

	for (i = 0; i < NAND_HYNIX_1XNM_RR_REPEAT; i++) {
	int set_offs = NAND_HYNIX_1XNM_RR_SET_OFFS(i, set_size, inv);

	tmp[i] = buf[val_offs + set_offs];
	}

	ret = hynix_get_majority(tmp, NAND_HYNIX_1XNM_RR_REPEAT, val);
	if (ret)
	return ret;

	if (inv)
	val = ~val;

	return 0;
	}

	static u8 hynix_1xnm_mlc_read_retry_regs[] = {
	0xcc, 0xbf, 0xaa, 0xab, 0xcd, 0xad, 0xae, 0xaf
	};

	static int hynix_mlc_1xnm_rr_init(struct nand_chip *chip,
	const struct hynix_read_retry_otp *info)
	{
	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);
	struct hynix_read_retry *rr = NULL;
	int ret, i, j;
	u8 nregs, nmodes;
	u8 *buf;

	buf = kmalloc(info->size, GFP_KERNEL);
	if (!buf)
	return -ENOMEM;

	ret = hynix_read_rr_otp(chip, info, buf);
	if (ret)
	goto out;

	ret = hynix_get_majority(buf, NAND_HYNIX_1XNM_RR_REPEAT,
	&nmodes);
	if (ret)
	goto out;

	ret = hynix_get_majority(buf + NAND_HYNIX_1XNM_RR_REPEAT,
	NAND_HYNIX_1XNM_RR_REPEAT,
	&nregs);
	if (ret)
	goto out;

	rr = kzalloc(sizeof(rr) + (nregs nmodes), GFP_KERNEL);
	if (!rr) {
	ret = -ENOMEM;
	goto out;
	}

	for (i = 0; i < nmodes; i++) {
	for (j = 0; j < nregs; j++) {
	u8 val = rr->values + (i nregs);

	ret = hynix_mlc_1xnm_rr_value(buf, nmodes, nregs, i, j,
	false, val);
	if (!ret)
	continue;

	ret = hynix_mlc_1xnm_rr_value(buf, nmodes, nregs, i, j,
	true, val);
	if (ret)
	goto out;
	}
	}

	rr->nregs = nregs;
	rr->regs = hynix_1xnm_mlc_read_retry_regs;
	hynix->read_retry = rr;
	chip->setup_read_retry = hynix_nand_setup_read_retry;
	chip->read_retries = nmodes;

	out:
	kfree(buf);

	if (ret)
	kfree(rr);

	return ret;
	}

	static const u8 hynix_mlc_1xnm_rr_otp_regs[] = { 0x38 };
	static const u8 hynix_mlc_1xnm_rr_otp_values[] = { 0x52 };

	static const struct hynix_read_retry_otp hynix_mlc_1xnm_rr_otps[] = {
	{
	.nregs = ARRAY_SIZE(hynix_mlc_1xnm_rr_otp_regs),
	.regs = hynix_mlc_1xnm_rr_otp_regs,
	.values = hynix_mlc_1xnm_rr_otp_values,
	.page = 0x21f,
	.size = 784
	},
	{
	.nregs = ARRAY_SIZE(hynix_mlc_1xnm_rr_otp_regs),
	.regs = hynix_mlc_1xnm_rr_otp_regs,
	.values = hynix_mlc_1xnm_rr_otp_values,
	.page = 0x200,
	.size = 528,
	},
	};

	static int hynix_nand_rr_init(struct nand_chip *chip)
	{
	int i, ret = 0;
	bool valid_jedecid;

	valid_jedecid = hynix_nand_has_valid_jedecid(chip);

	/*
	* We only support read-retry for 1xnm NANDs, and those NANDs all
	* expose a valid JEDEC ID.
	*/
	if (valid_jedecid) {
	u8 nand_tech = chip->id.data[5] >> 4;

	/* 1xnm technology */
	if (nand_tech == 4) {
	for (i = 0; i < ARRAY_SIZE(hynix_mlc_1xnm_rr_otps);
	i++) {
	/*
	* FIXME: Hynix recommend to copy the
	* read-retry OTP area into a normal page.
	*/
	ret = hynix_mlc_1xnm_rr_init(chip,
	hynix_mlc_1xnm_rr_otps);
	if (!ret)
	break;
	}
	}
	}

	if (ret)
	pr_warn("failed to initialize read-retry infrastructure");

	return 0;
	}

	static void hynix_nand_extract_oobsize(struct nand_chip *chip,
	bool valid_jedecid)
	{
	struct mtd_info *mtd = nand_to_mtd(chip);
	u8 oobsize;

	oobsize = ((chip->id.data[3] >> 2) & 0x3) \|
	((chip->id.data[3] >> 4) & 0x4);

	if (valid_jedecid) {
	switch (oobsize) {
	case 0:
	mtd->oobsize = 2048;
	break;
	case 1:
	mtd->oobsize = 1664;
	break;
	case 2:
	mtd->oobsize = 1024;
	break;
	case 3:
	mtd->oobsize = 640;
	break;
	default:
	/*
	* We should never reach this case, but if that
	* happens, this probably means Hynix decided to use
	* a different extended ID format, and we should find
	* a way to support it.
	*/
	WARN(1, "Invalid OOB size");
	break;
	}
	} else {
	switch (oobsize) {
	case 0:
	mtd->oobsize = 128;
	break;
	case 1:
	mtd->oobsize = 224;
	break;
	case 2:
	mtd->oobsize = 448;
	break;
	case 3:
	mtd->oobsize = 64;
	break;
	case 4:
	mtd->oobsize = 32;
	break;
	case 5:
	mtd->oobsize = 16;
	break;
	case 6:
	mtd->oobsize = 640;
	break;
	default:
	/*
	* We should never reach this case, but if that
	* happens, this probably means Hynix decided to use
	* a different extended ID format, and we should find
	* a way to support it.
	*/
	WARN(1, "Invalid OOB size");
	break;
	}

	/*
	* The datasheet of H27UCG8T2BTR mentions that the "Redundant
	* Area Size" is encoded "per 8KB" (page size). This chip uses
	* a page size of 16KiB. The datasheet mentions an OOB size of
	* 1.280 bytes, but the OOB size encoded in the ID bytes (using
	* the existing logic above) is 640 bytes.
	* Update the OOB size for this chip by taking the value
	* determined above and scaling it to the actual page size (so
	* the actual OOB size for this chip is: 640 * 16k / 8k).
	*/
	if (chip->id.data[1] == 0xde)
	mtd->oobsize *= mtd->writesize / SZ_8K;
	}
	}

	static void hynix_nand_extract_ecc_requirements(struct nand_chip *chip,
	bool valid_jedecid)
	{
	u8 ecc_level = (chip->id.data[4] >> 4) & 0x7;

	if (valid_jedecid) {
	/* Reference: H27UCG8T2E datasheet */
	chip->ecc_step_ds = 1024;

	switch (ecc_level) {
	case 0:
	chip->ecc_step_ds = 0;
	chip->ecc_strength_ds = 0;
	break;
	case 1:
	chip->ecc_strength_ds = 4;
	break;
	case 2:
	chip->ecc_strength_ds = 24;
	break;
	case 3:
	chip->ecc_strength_ds = 32;
	break;
	case 4:
	chip->ecc_strength_ds = 40;
	break;
	case 5:
	chip->ecc_strength_ds = 50;
	break;
	case 6:
	chip->ecc_strength_ds = 60;
	break;
	default:
	/*
	* We should never reach this case, but if that
	* happens, this probably means Hynix decided to use
	* a different extended ID format, and we should find
	* a way to support it.
	*/
	WARN(1, "Invalid ECC requirements");
	}
	} else {
	/*
	* The ECC requirements field meaning depends on the
	* NAND technology.
	*/
	u8 nand_tech = chip->id.data[5] & 0x7;

	if (nand_tech < 3) {
	/* > 26nm, reference: H27UBG8T2A datasheet */
	if (ecc_level < 5) {
	chip->ecc_step_ds = 512;
	chip->ecc_strength_ds = 1 << ecc_level;
	} else if (ecc_level < 7) {
	if (ecc_level == 5)
	chip->ecc_step_ds = 2048;
	else
	chip->ecc_step_ds = 1024;
	chip->ecc_strength_ds = 24;
	} else {
	/*
	* We should never reach this case, but if that
	* happens, this probably means Hynix decided
	* to use a different extended ID format, and
	* we should find a way to support it.
	*/
	WARN(1, "Invalid ECC requirements");
	}
	} else {
	/* <= 26nm, reference: H27UBG8T2B datasheet */
	if (!ecc_level) {
	chip->ecc_step_ds = 0;
	chip->ecc_strength_ds = 0;
	} else if (ecc_level < 5) {
	chip->ecc_step_ds = 512;
	chip->ecc_strength_ds = 1 << (ecc_level - 1);
	} else {
	chip->ecc_step_ds = 1024;
	chip->ecc_strength_ds = 24 +
	(8 * (ecc_level - 5));
	}
	}
	}
	}

	static void hynix_nand_extract_scrambling_requirements(struct nand_chip *chip,
	bool valid_jedecid)
	{
	u8 nand_tech;

	/* We need scrambling on all TLC NANDs*/
	if (chip->bits_per_cell > 2)
	chip->options \|= NAND_NEED_SCRAMBLING;

	/* And on MLC NANDs with sub-3xnm process */
	if (valid_jedecid) {
	nand_tech = chip->id.data[5] >> 4;

	/* < 3xnm */
	if (nand_tech > 0)
	chip->options \|= NAND_NEED_SCRAMBLING;
	} else {
	nand_tech = chip->id.data[5] & 0x7;

	/* < 32nm */
	if (nand_tech > 2)
	chip->options \|= NAND_NEED_SCRAMBLING;
	}
	}

	static void hynix_nand_decode_id(struct nand_chip *chip)
	{
	struct mtd_info *mtd = nand_to_mtd(chip);
	bool valid_jedecid;
	u8 tmp;

	/*
	* Exclude all SLC NANDs from this advanced detection scheme.
	* According to the ranges defined in several datasheets, it might
	* appear that even SLC NANDs could fall in this extended ID scheme.
	* If that the case rework the test to let SLC NANDs go through the
	* detection process.
	*/
	if (chip->id.len < 6 \|\| nand_is_slc(chip)) {
	nand_decode_ext_id(chip);
	return;
	}

	/* Extract pagesize */
	mtd->writesize = 2048 << (chip->id.data[3] & 0x03);

	tmp = (chip->id.data[3] >> 4) & 0x3;
	/*
	* When bit7 is set that means we start counting at 1MiB, otherwise
	* we start counting at 128KiB and shift this value the content of
	* ID[3][4:5].
	* The only exception is when ID[3][4:5] == 3 and ID[3][7] == 0, in
	* this case the erasesize is set to 768KiB.
	*/
	if (chip->id.data[3] & 0x80)
	mtd->erasesize = SZ_1M << tmp;
	else if (tmp == 3)
	mtd->erasesize = SZ_512K + SZ_256K;
	else
	mtd->erasesize = SZ_128K << tmp;

	/*
	* Modern Toggle DDR NANDs have a valid JEDECID even though they are
	* not exposing a valid JEDEC parameter table.
	* These NANDs use a different NAND ID scheme.
	*/
	valid_jedecid = hynix_nand_has_valid_jedecid(chip);

	hynix_nand_extract_oobsize(chip, valid_jedecid);
	hynix_nand_extract_ecc_requirements(chip, valid_jedecid);
	hynix_nand_extract_scrambling_requirements(chip, valid_jedecid);
	}

	static void hynix_nand_cleanup(struct nand_chip *chip)
	{
	struct hynix_nand *hynix = nand_get_manufacturer_data(chip);

	if (!hynix)
	return;

	kfree(hynix->read_retry);
	kfree(hynix);
	nand_set_manufacturer_data(chip, NULL);
	}

	static int hynix_nand_init(struct nand_chip *chip)
	{
	struct hynix_nand *hynix;
	int ret;

	if (!nand_is_slc(chip))
	chip->bbt_options \|= NAND_BBT_SCANLASTPAGE;
	else
	chip->bbt_options \|= NAND_BBT_SCAN2NDPAGE;

	hynix = kzalloc(sizeof(*hynix), GFP_KERNEL);
	if (!hynix)
	return -ENOMEM;

	nand_set_manufacturer_data(chip, hynix);

	ret = hynix_nand_rr_init(chip);
	if (ret)
	hynix_nand_cleanup(chip);

	return ret;
	}

	const struct nand_manufacturer_ops hynix_nand_manuf_ops = {
	.detect = hynix_nand_decode_id,
	.init = hynix_nand_init,
	.cleanup = hynix_nand_cleanup,
	};