linux_dsm_epyc7002/drivers/mtd/nand/qcom_nandc.c
Linus Torvalds 2382dc9a3e dma mapping changes for Linux 4.16:
This pull requests contains a consolidation of the generic no-IOMMU code,
 a well as the glue code for swiotlb.  All the code is based on the x86
 implementation with hooks to allow all architectures that aren't cache
 coherent to use it.  The x86 conversion itself has been deferred because
 the x86 maintainers were a little busy in the last months.
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Merge tag 'dma-mapping-4.16' of git://git.infradead.org/users/hch/dma-mapping

Pull dma mapping updates from Christoph Hellwig:
 "Except for a runtime warning fix from Christian this is all about
  consolidation of the generic no-IOMMU code, a well as the glue code
  for swiotlb.

  All the code is based on the x86 implementation with hooks to allow
  all architectures that aren't cache coherent to use it.

  The x86 conversion itself has been deferred because the x86
  maintainers were a little busy in the last months"

* tag 'dma-mapping-4.16' of git://git.infradead.org/users/hch/dma-mapping: (57 commits)
  MAINTAINERS: add the iommu list for swiotlb and xen-swiotlb
  arm64: use swiotlb_alloc and swiotlb_free
  arm64: replace ZONE_DMA with ZONE_DMA32
  mips: use swiotlb_{alloc,free}
  mips/netlogic: remove swiotlb support
  tile: use generic swiotlb_ops
  tile: replace ZONE_DMA with ZONE_DMA32
  unicore32: use generic swiotlb_ops
  ia64: remove an ifdef around the content of pci-dma.c
  ia64: clean up swiotlb support
  ia64: use generic swiotlb_ops
  ia64: replace ZONE_DMA with ZONE_DMA32
  swiotlb: remove various exports
  swiotlb: refactor coherent buffer allocation
  swiotlb: refactor coherent buffer freeing
  swiotlb: wire up ->dma_supported in swiotlb_dma_ops
  swiotlb: add common swiotlb_map_ops
  swiotlb: rename swiotlb_free to swiotlb_exit
  x86: rename swiotlb_dma_ops
  powerpc: rename swiotlb_dma_ops
  ...
2018-01-31 11:32:27 -08:00

2922 lines
78 KiB
C

/*
* Copyright (c) 2016, The Linux Foundation. All rights reserved.
*
* This software is licensed under the terms of the GNU General Public
* License version 2, as published by the Free Software Foundation, and
* may be copied, distributed, and modified under those terms.
*
* 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/clk.h>
#include <linux/slab.h>
#include <linux/bitops.h>
#include <linux/dma-mapping.h>
#include <linux/dmaengine.h>
#include <linux/module.h>
#include <linux/mtd/rawnand.h>
#include <linux/mtd/partitions.h>
#include <linux/of.h>
#include <linux/of_device.h>
#include <linux/delay.h>
#include <linux/dma/qcom_bam_dma.h>
#include <linux/dma-direct.h> /* XXX: drivers shall never use this directly! */
/* NANDc reg offsets */
#define NAND_FLASH_CMD 0x00
#define NAND_ADDR0 0x04
#define NAND_ADDR1 0x08
#define NAND_FLASH_CHIP_SELECT 0x0c
#define NAND_EXEC_CMD 0x10
#define NAND_FLASH_STATUS 0x14
#define NAND_BUFFER_STATUS 0x18
#define NAND_DEV0_CFG0 0x20
#define NAND_DEV0_CFG1 0x24
#define NAND_DEV0_ECC_CFG 0x28
#define NAND_DEV1_ECC_CFG 0x2c
#define NAND_DEV1_CFG0 0x30
#define NAND_DEV1_CFG1 0x34
#define NAND_READ_ID 0x40
#define NAND_READ_STATUS 0x44
#define NAND_DEV_CMD0 0xa0
#define NAND_DEV_CMD1 0xa4
#define NAND_DEV_CMD2 0xa8
#define NAND_DEV_CMD_VLD 0xac
#define SFLASHC_BURST_CFG 0xe0
#define NAND_ERASED_CW_DETECT_CFG 0xe8
#define NAND_ERASED_CW_DETECT_STATUS 0xec
#define NAND_EBI2_ECC_BUF_CFG 0xf0
#define FLASH_BUF_ACC 0x100
#define NAND_CTRL 0xf00
#define NAND_VERSION 0xf08
#define NAND_READ_LOCATION_0 0xf20
#define NAND_READ_LOCATION_1 0xf24
#define NAND_READ_LOCATION_2 0xf28
#define NAND_READ_LOCATION_3 0xf2c
/* dummy register offsets, used by write_reg_dma */
#define NAND_DEV_CMD1_RESTORE 0xdead
#define NAND_DEV_CMD_VLD_RESTORE 0xbeef
/* NAND_FLASH_CMD bits */
#define PAGE_ACC BIT(4)
#define LAST_PAGE BIT(5)
/* NAND_FLASH_CHIP_SELECT bits */
#define NAND_DEV_SEL 0
#define DM_EN BIT(2)
/* NAND_FLASH_STATUS bits */
#define FS_OP_ERR BIT(4)
#define FS_READY_BSY_N BIT(5)
#define FS_MPU_ERR BIT(8)
#define FS_DEVICE_STS_ERR BIT(16)
#define FS_DEVICE_WP BIT(23)
/* NAND_BUFFER_STATUS bits */
#define BS_UNCORRECTABLE_BIT BIT(8)
#define BS_CORRECTABLE_ERR_MSK 0x1f
/* NAND_DEVn_CFG0 bits */
#define DISABLE_STATUS_AFTER_WRITE 4
#define CW_PER_PAGE 6
#define UD_SIZE_BYTES 9
#define ECC_PARITY_SIZE_BYTES_RS 19
#define SPARE_SIZE_BYTES 23
#define NUM_ADDR_CYCLES 27
#define STATUS_BFR_READ 30
#define SET_RD_MODE_AFTER_STATUS 31
/* NAND_DEVn_CFG0 bits */
#define DEV0_CFG1_ECC_DISABLE 0
#define WIDE_FLASH 1
#define NAND_RECOVERY_CYCLES 2
#define CS_ACTIVE_BSY 5
#define BAD_BLOCK_BYTE_NUM 6
#define BAD_BLOCK_IN_SPARE_AREA 16
#define WR_RD_BSY_GAP 17
#define ENABLE_BCH_ECC 27
/* NAND_DEV0_ECC_CFG bits */
#define ECC_CFG_ECC_DISABLE 0
#define ECC_SW_RESET 1
#define ECC_MODE 4
#define ECC_PARITY_SIZE_BYTES_BCH 8
#define ECC_NUM_DATA_BYTES 16
#define ECC_FORCE_CLK_OPEN 30
/* NAND_DEV_CMD1 bits */
#define READ_ADDR 0
/* NAND_DEV_CMD_VLD bits */
#define READ_START_VLD BIT(0)
#define READ_STOP_VLD BIT(1)
#define WRITE_START_VLD BIT(2)
#define ERASE_START_VLD BIT(3)
#define SEQ_READ_START_VLD BIT(4)
/* NAND_EBI2_ECC_BUF_CFG bits */
#define NUM_STEPS 0
/* NAND_ERASED_CW_DETECT_CFG bits */
#define ERASED_CW_ECC_MASK 1
#define AUTO_DETECT_RES 0
#define MASK_ECC (1 << ERASED_CW_ECC_MASK)
#define RESET_ERASED_DET (1 << AUTO_DETECT_RES)
#define ACTIVE_ERASED_DET (0 << AUTO_DETECT_RES)
#define CLR_ERASED_PAGE_DET (RESET_ERASED_DET | MASK_ECC)
#define SET_ERASED_PAGE_DET (ACTIVE_ERASED_DET | MASK_ECC)
/* NAND_ERASED_CW_DETECT_STATUS bits */
#define PAGE_ALL_ERASED BIT(7)
#define CODEWORD_ALL_ERASED BIT(6)
#define PAGE_ERASED BIT(5)
#define CODEWORD_ERASED BIT(4)
#define ERASED_PAGE (PAGE_ALL_ERASED | PAGE_ERASED)
#define ERASED_CW (CODEWORD_ALL_ERASED | CODEWORD_ERASED)
/* NAND_READ_LOCATION_n bits */
#define READ_LOCATION_OFFSET 0
#define READ_LOCATION_SIZE 16
#define READ_LOCATION_LAST 31
/* Version Mask */
#define NAND_VERSION_MAJOR_MASK 0xf0000000
#define NAND_VERSION_MAJOR_SHIFT 28
#define NAND_VERSION_MINOR_MASK 0x0fff0000
#define NAND_VERSION_MINOR_SHIFT 16
/* NAND OP_CMDs */
#define PAGE_READ 0x2
#define PAGE_READ_WITH_ECC 0x3
#define PAGE_READ_WITH_ECC_SPARE 0x4
#define PROGRAM_PAGE 0x6
#define PAGE_PROGRAM_WITH_ECC 0x7
#define PROGRAM_PAGE_SPARE 0x9
#define BLOCK_ERASE 0xa
#define FETCH_ID 0xb
#define RESET_DEVICE 0xd
/* Default Value for NAND_DEV_CMD_VLD */
#define NAND_DEV_CMD_VLD_VAL (READ_START_VLD | WRITE_START_VLD | \
ERASE_START_VLD | SEQ_READ_START_VLD)
/* NAND_CTRL bits */
#define BAM_MODE_EN BIT(0)
/*
* the NAND controller performs reads/writes with ECC in 516 byte chunks.
* the driver calls the chunks 'step' or 'codeword' interchangeably
*/
#define NANDC_STEP_SIZE 512
/*
* the largest page size we support is 8K, this will have 16 steps/codewords
* of 512 bytes each
*/
#define MAX_NUM_STEPS (SZ_8K / NANDC_STEP_SIZE)
/* we read at most 3 registers per codeword scan */
#define MAX_REG_RD (3 * MAX_NUM_STEPS)
/* ECC modes supported by the controller */
#define ECC_NONE BIT(0)
#define ECC_RS_4BIT BIT(1)
#define ECC_BCH_4BIT BIT(2)
#define ECC_BCH_8BIT BIT(3)
#define nandc_set_read_loc(nandc, reg, offset, size, is_last) \
nandc_set_reg(nandc, NAND_READ_LOCATION_##reg, \
((offset) << READ_LOCATION_OFFSET) | \
((size) << READ_LOCATION_SIZE) | \
((is_last) << READ_LOCATION_LAST))
/*
* Returns the actual register address for all NAND_DEV_ registers
* (i.e. NAND_DEV_CMD0, NAND_DEV_CMD1, NAND_DEV_CMD2 and NAND_DEV_CMD_VLD)
*/
#define dev_cmd_reg_addr(nandc, reg) ((nandc)->props->dev_cmd_reg_start + (reg))
/* Returns the NAND register physical address */
#define nandc_reg_phys(chip, offset) ((chip)->base_phys + (offset))
/* Returns the dma address for reg read buffer */
#define reg_buf_dma_addr(chip, vaddr) \
((chip)->reg_read_dma + \
((uint8_t *)(vaddr) - (uint8_t *)(chip)->reg_read_buf))
#define QPIC_PER_CW_CMD_ELEMENTS 32
#define QPIC_PER_CW_CMD_SGL 32
#define QPIC_PER_CW_DATA_SGL 8
/*
* Flags used in DMA descriptor preparation helper functions
* (i.e. read_reg_dma/write_reg_dma/read_data_dma/write_data_dma)
*/
/* Don't set the EOT in current tx BAM sgl */
#define NAND_BAM_NO_EOT BIT(0)
/* Set the NWD flag in current BAM sgl */
#define NAND_BAM_NWD BIT(1)
/* Finish writing in the current BAM sgl and start writing in another BAM sgl */
#define NAND_BAM_NEXT_SGL BIT(2)
/*
* Erased codeword status is being used two times in single transfer so this
* flag will determine the current value of erased codeword status register
*/
#define NAND_ERASED_CW_SET BIT(4)
/*
* This data type corresponds to the BAM transaction which will be used for all
* NAND transfers.
* @bam_ce - the array of BAM command elements
* @cmd_sgl - sgl for NAND BAM command pipe
* @data_sgl - sgl for NAND BAM consumer/producer pipe
* @bam_ce_pos - the index in bam_ce which is available for next sgl
* @bam_ce_start - the index in bam_ce which marks the start position ce
* for current sgl. It will be used for size calculation
* for current sgl
* @cmd_sgl_pos - current index in command sgl.
* @cmd_sgl_start - start index in command sgl.
* @tx_sgl_pos - current index in data sgl for tx.
* @tx_sgl_start - start index in data sgl for tx.
* @rx_sgl_pos - current index in data sgl for rx.
* @rx_sgl_start - start index in data sgl for rx.
*/
struct bam_transaction {
struct bam_cmd_element *bam_ce;
struct scatterlist *cmd_sgl;
struct scatterlist *data_sgl;
u32 bam_ce_pos;
u32 bam_ce_start;
u32 cmd_sgl_pos;
u32 cmd_sgl_start;
u32 tx_sgl_pos;
u32 tx_sgl_start;
u32 rx_sgl_pos;
u32 rx_sgl_start;
};
/*
* This data type corresponds to the nand dma descriptor
* @list - list for desc_info
* @dir - DMA transfer direction
* @adm_sgl - sgl which will be used for single sgl dma descriptor. Only used by
* ADM
* @bam_sgl - sgl which will be used for dma descriptor. Only used by BAM
* @sgl_cnt - number of SGL in bam_sgl. Only used by BAM
* @dma_desc - low level DMA engine descriptor
*/
struct desc_info {
struct list_head node;
enum dma_data_direction dir;
union {
struct scatterlist adm_sgl;
struct {
struct scatterlist *bam_sgl;
int sgl_cnt;
};
};
struct dma_async_tx_descriptor *dma_desc;
};
/*
* holds the current register values that we want to write. acts as a contiguous
* chunk of memory which we use to write the controller registers through DMA.
*/
struct nandc_regs {
__le32 cmd;
__le32 addr0;
__le32 addr1;
__le32 chip_sel;
__le32 exec;
__le32 cfg0;
__le32 cfg1;
__le32 ecc_bch_cfg;
__le32 clrflashstatus;
__le32 clrreadstatus;
__le32 cmd1;
__le32 vld;
__le32 orig_cmd1;
__le32 orig_vld;
__le32 ecc_buf_cfg;
__le32 read_location0;
__le32 read_location1;
__le32 read_location2;
__le32 read_location3;
__le32 erased_cw_detect_cfg_clr;
__le32 erased_cw_detect_cfg_set;
};
/*
* NAND controller data struct
*
* @controller: base controller structure
* @host_list: list containing all the chips attached to the
* controller
* @dev: parent device
* @base: MMIO base
* @base_phys: physical base address of controller registers
* @base_dma: dma base address of controller registers
* @core_clk: controller clock
* @aon_clk: another controller clock
*
* @chan: dma channel
* @cmd_crci: ADM DMA CRCI for command flow control
* @data_crci: ADM DMA CRCI for data flow control
* @desc_list: DMA descriptor list (list of desc_infos)
*
* @data_buffer: our local DMA buffer for page read/writes,
* used when we can't use the buffer provided
* by upper layers directly
* @buf_size/count/start: markers for chip->read_buf/write_buf functions
* @reg_read_buf: local buffer for reading back registers via DMA
* @reg_read_dma: contains dma address for register read buffer
* @reg_read_pos: marker for data read in reg_read_buf
*
* @regs: a contiguous chunk of memory for DMA register
* writes. contains the register values to be
* written to controller
* @cmd1/vld: some fixed controller register values
* @props: properties of current NAND controller,
* initialized via DT match data
* @max_cwperpage: maximum QPIC codewords required. calculated
* from all connected NAND devices pagesize
*/
struct qcom_nand_controller {
struct nand_hw_control controller;
struct list_head host_list;
struct device *dev;
void __iomem *base;
phys_addr_t base_phys;
dma_addr_t base_dma;
struct clk *core_clk;
struct clk *aon_clk;
union {
/* will be used only by QPIC for BAM DMA */
struct {
struct dma_chan *tx_chan;
struct dma_chan *rx_chan;
struct dma_chan *cmd_chan;
};
/* will be used only by EBI2 for ADM DMA */
struct {
struct dma_chan *chan;
unsigned int cmd_crci;
unsigned int data_crci;
};
};
struct list_head desc_list;
struct bam_transaction *bam_txn;
u8 *data_buffer;
int buf_size;
int buf_count;
int buf_start;
unsigned int max_cwperpage;
__le32 *reg_read_buf;
dma_addr_t reg_read_dma;
int reg_read_pos;
struct nandc_regs *regs;
u32 cmd1, vld;
const struct qcom_nandc_props *props;
};
/*
* NAND chip structure
*
* @chip: base NAND chip structure
* @node: list node to add itself to host_list in
* qcom_nand_controller
*
* @cs: chip select value for this chip
* @cw_size: the number of bytes in a single step/codeword
* of a page, consisting of all data, ecc, spare
* and reserved bytes
* @cw_data: the number of bytes within a codeword protected
* by ECC
* @use_ecc: request the controller to use ECC for the
* upcoming read/write
* @bch_enabled: flag to tell whether BCH ECC mode is used
* @ecc_bytes_hw: ECC bytes used by controller hardware for this
* chip
* @status: value to be returned if NAND_CMD_STATUS command
* is executed
* @last_command: keeps track of last command on this chip. used
* for reading correct status
*
* @cfg0, cfg1, cfg0_raw..: NANDc register configurations needed for
* ecc/non-ecc mode for the current nand flash
* device
*/
struct qcom_nand_host {
struct nand_chip chip;
struct list_head node;
int cs;
int cw_size;
int cw_data;
bool use_ecc;
bool bch_enabled;
int ecc_bytes_hw;
int spare_bytes;
int bbm_size;
u8 status;
int last_command;
u32 cfg0, cfg1;
u32 cfg0_raw, cfg1_raw;
u32 ecc_buf_cfg;
u32 ecc_bch_cfg;
u32 clrflashstatus;
u32 clrreadstatus;
};
/*
* This data type corresponds to the NAND controller properties which varies
* among different NAND controllers.
* @ecc_modes - ecc mode for NAND
* @is_bam - whether NAND controller is using BAM
* @dev_cmd_reg_start - NAND_DEV_CMD_* registers starting offset
*/
struct qcom_nandc_props {
u32 ecc_modes;
bool is_bam;
u32 dev_cmd_reg_start;
};
/* Frees the BAM transaction memory */
static void free_bam_transaction(struct qcom_nand_controller *nandc)
{
struct bam_transaction *bam_txn = nandc->bam_txn;
devm_kfree(nandc->dev, bam_txn);
}
/* Allocates and Initializes the BAM transaction */
static struct bam_transaction *
alloc_bam_transaction(struct qcom_nand_controller *nandc)
{
struct bam_transaction *bam_txn;
size_t bam_txn_size;
unsigned int num_cw = nandc->max_cwperpage;
void *bam_txn_buf;
bam_txn_size =
sizeof(*bam_txn) + num_cw *
((sizeof(*bam_txn->bam_ce) * QPIC_PER_CW_CMD_ELEMENTS) +
(sizeof(*bam_txn->cmd_sgl) * QPIC_PER_CW_CMD_SGL) +
(sizeof(*bam_txn->data_sgl) * QPIC_PER_CW_DATA_SGL));
bam_txn_buf = devm_kzalloc(nandc->dev, bam_txn_size, GFP_KERNEL);
if (!bam_txn_buf)
return NULL;
bam_txn = bam_txn_buf;
bam_txn_buf += sizeof(*bam_txn);
bam_txn->bam_ce = bam_txn_buf;
bam_txn_buf +=
sizeof(*bam_txn->bam_ce) * QPIC_PER_CW_CMD_ELEMENTS * num_cw;
bam_txn->cmd_sgl = bam_txn_buf;
bam_txn_buf +=
sizeof(*bam_txn->cmd_sgl) * QPIC_PER_CW_CMD_SGL * num_cw;
bam_txn->data_sgl = bam_txn_buf;
return bam_txn;
}
/* Clears the BAM transaction indexes */
static void clear_bam_transaction(struct qcom_nand_controller *nandc)
{
struct bam_transaction *bam_txn = nandc->bam_txn;
if (!nandc->props->is_bam)
return;
bam_txn->bam_ce_pos = 0;
bam_txn->bam_ce_start = 0;
bam_txn->cmd_sgl_pos = 0;
bam_txn->cmd_sgl_start = 0;
bam_txn->tx_sgl_pos = 0;
bam_txn->tx_sgl_start = 0;
bam_txn->rx_sgl_pos = 0;
bam_txn->rx_sgl_start = 0;
sg_init_table(bam_txn->cmd_sgl, nandc->max_cwperpage *
QPIC_PER_CW_CMD_SGL);
sg_init_table(bam_txn->data_sgl, nandc->max_cwperpage *
QPIC_PER_CW_DATA_SGL);
}
static inline struct qcom_nand_host *to_qcom_nand_host(struct nand_chip *chip)
{
return container_of(chip, struct qcom_nand_host, chip);
}
static inline struct qcom_nand_controller *
get_qcom_nand_controller(struct nand_chip *chip)
{
return container_of(chip->controller, struct qcom_nand_controller,
controller);
}
static inline u32 nandc_read(struct qcom_nand_controller *nandc, int offset)
{
return ioread32(nandc->base + offset);
}
static inline void nandc_write(struct qcom_nand_controller *nandc, int offset,
u32 val)
{
iowrite32(val, nandc->base + offset);
}
static inline void nandc_read_buffer_sync(struct qcom_nand_controller *nandc,
bool is_cpu)
{
if (!nandc->props->is_bam)
return;
if (is_cpu)
dma_sync_single_for_cpu(nandc->dev, nandc->reg_read_dma,
MAX_REG_RD *
sizeof(*nandc->reg_read_buf),
DMA_FROM_DEVICE);
else
dma_sync_single_for_device(nandc->dev, nandc->reg_read_dma,
MAX_REG_RD *
sizeof(*nandc->reg_read_buf),
DMA_FROM_DEVICE);
}
static __le32 *offset_to_nandc_reg(struct nandc_regs *regs, int offset)
{
switch (offset) {
case NAND_FLASH_CMD:
return &regs->cmd;
case NAND_ADDR0:
return &regs->addr0;
case NAND_ADDR1:
return &regs->addr1;
case NAND_FLASH_CHIP_SELECT:
return &regs->chip_sel;
case NAND_EXEC_CMD:
return &regs->exec;
case NAND_FLASH_STATUS:
return &regs->clrflashstatus;
case NAND_DEV0_CFG0:
return &regs->cfg0;
case NAND_DEV0_CFG1:
return &regs->cfg1;
case NAND_DEV0_ECC_CFG:
return &regs->ecc_bch_cfg;
case NAND_READ_STATUS:
return &regs->clrreadstatus;
case NAND_DEV_CMD1:
return &regs->cmd1;
case NAND_DEV_CMD1_RESTORE:
return &regs->orig_cmd1;
case NAND_DEV_CMD_VLD:
return &regs->vld;
case NAND_DEV_CMD_VLD_RESTORE:
return &regs->orig_vld;
case NAND_EBI2_ECC_BUF_CFG:
return &regs->ecc_buf_cfg;
case NAND_READ_LOCATION_0:
return &regs->read_location0;
case NAND_READ_LOCATION_1:
return &regs->read_location1;
case NAND_READ_LOCATION_2:
return &regs->read_location2;
case NAND_READ_LOCATION_3:
return &regs->read_location3;
default:
return NULL;
}
}
static void nandc_set_reg(struct qcom_nand_controller *nandc, int offset,
u32 val)
{
struct nandc_regs *regs = nandc->regs;
__le32 *reg;
reg = offset_to_nandc_reg(regs, offset);
if (reg)
*reg = cpu_to_le32(val);
}
/* helper to configure address register values */
static void set_address(struct qcom_nand_host *host, u16 column, int page)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
if (chip->options & NAND_BUSWIDTH_16)
column >>= 1;
nandc_set_reg(nandc, NAND_ADDR0, page << 16 | column);
nandc_set_reg(nandc, NAND_ADDR1, page >> 16 & 0xff);
}
/*
* update_rw_regs: set up read/write register values, these will be
* written to the NAND controller registers via DMA
*
* @num_cw: number of steps for the read/write operation
* @read: read or write operation
*/
static void update_rw_regs(struct qcom_nand_host *host, int num_cw, bool read)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
u32 cmd, cfg0, cfg1, ecc_bch_cfg;
if (read) {
if (host->use_ecc)
cmd = PAGE_READ_WITH_ECC | PAGE_ACC | LAST_PAGE;
else
cmd = PAGE_READ | PAGE_ACC | LAST_PAGE;
} else {
cmd = PROGRAM_PAGE | PAGE_ACC | LAST_PAGE;
}
if (host->use_ecc) {
cfg0 = (host->cfg0 & ~(7U << CW_PER_PAGE)) |
(num_cw - 1) << CW_PER_PAGE;
cfg1 = host->cfg1;
ecc_bch_cfg = host->ecc_bch_cfg;
} else {
cfg0 = (host->cfg0_raw & ~(7U << CW_PER_PAGE)) |
(num_cw - 1) << CW_PER_PAGE;
cfg1 = host->cfg1_raw;
ecc_bch_cfg = 1 << ECC_CFG_ECC_DISABLE;
}
nandc_set_reg(nandc, NAND_FLASH_CMD, cmd);
nandc_set_reg(nandc, NAND_DEV0_CFG0, cfg0);
nandc_set_reg(nandc, NAND_DEV0_CFG1, cfg1);
nandc_set_reg(nandc, NAND_DEV0_ECC_CFG, ecc_bch_cfg);
nandc_set_reg(nandc, NAND_EBI2_ECC_BUF_CFG, host->ecc_buf_cfg);
nandc_set_reg(nandc, NAND_FLASH_STATUS, host->clrflashstatus);
nandc_set_reg(nandc, NAND_READ_STATUS, host->clrreadstatus);
nandc_set_reg(nandc, NAND_EXEC_CMD, 1);
if (read)
nandc_set_read_loc(nandc, 0, 0, host->use_ecc ?
host->cw_data : host->cw_size, 1);
}
/*
* Maps the scatter gather list for DMA transfer and forms the DMA descriptor
* for BAM. This descriptor will be added in the NAND DMA descriptor queue
* which will be submitted to DMA engine.
*/
static int prepare_bam_async_desc(struct qcom_nand_controller *nandc,
struct dma_chan *chan,
unsigned long flags)
{
struct desc_info *desc;
struct scatterlist *sgl;
unsigned int sgl_cnt;
int ret;
struct bam_transaction *bam_txn = nandc->bam_txn;
enum dma_transfer_direction dir_eng;
struct dma_async_tx_descriptor *dma_desc;
desc = kzalloc(sizeof(*desc), GFP_KERNEL);
if (!desc)
return -ENOMEM;
if (chan == nandc->cmd_chan) {
sgl = &bam_txn->cmd_sgl[bam_txn->cmd_sgl_start];
sgl_cnt = bam_txn->cmd_sgl_pos - bam_txn->cmd_sgl_start;
bam_txn->cmd_sgl_start = bam_txn->cmd_sgl_pos;
dir_eng = DMA_MEM_TO_DEV;
desc->dir = DMA_TO_DEVICE;
} else if (chan == nandc->tx_chan) {
sgl = &bam_txn->data_sgl[bam_txn->tx_sgl_start];
sgl_cnt = bam_txn->tx_sgl_pos - bam_txn->tx_sgl_start;
bam_txn->tx_sgl_start = bam_txn->tx_sgl_pos;
dir_eng = DMA_MEM_TO_DEV;
desc->dir = DMA_TO_DEVICE;
} else {
sgl = &bam_txn->data_sgl[bam_txn->rx_sgl_start];
sgl_cnt = bam_txn->rx_sgl_pos - bam_txn->rx_sgl_start;
bam_txn->rx_sgl_start = bam_txn->rx_sgl_pos;
dir_eng = DMA_DEV_TO_MEM;
desc->dir = DMA_FROM_DEVICE;
}
sg_mark_end(sgl + sgl_cnt - 1);
ret = dma_map_sg(nandc->dev, sgl, sgl_cnt, desc->dir);
if (ret == 0) {
dev_err(nandc->dev, "failure in mapping desc\n");
kfree(desc);
return -ENOMEM;
}
desc->sgl_cnt = sgl_cnt;
desc->bam_sgl = sgl;
dma_desc = dmaengine_prep_slave_sg(chan, sgl, sgl_cnt, dir_eng,
flags);
if (!dma_desc) {
dev_err(nandc->dev, "failure in prep desc\n");
dma_unmap_sg(nandc->dev, sgl, sgl_cnt, desc->dir);
kfree(desc);
return -EINVAL;
}
desc->dma_desc = dma_desc;
list_add_tail(&desc->node, &nandc->desc_list);
return 0;
}
/*
* Prepares the command descriptor for BAM DMA which will be used for NAND
* register reads and writes. The command descriptor requires the command
* to be formed in command element type so this function uses the command
* element from bam transaction ce array and fills the same with required
* data. A single SGL can contain multiple command elements so
* NAND_BAM_NEXT_SGL will be used for starting the separate SGL
* after the current command element.
*/
static int prep_bam_dma_desc_cmd(struct qcom_nand_controller *nandc, bool read,
int reg_off, const void *vaddr,
int size, unsigned int flags)
{
int bam_ce_size;
int i, ret;
struct bam_cmd_element *bam_ce_buffer;
struct bam_transaction *bam_txn = nandc->bam_txn;
bam_ce_buffer = &bam_txn->bam_ce[bam_txn->bam_ce_pos];
/* fill the command desc */
for (i = 0; i < size; i++) {
if (read)
bam_prep_ce(&bam_ce_buffer[i],
nandc_reg_phys(nandc, reg_off + 4 * i),
BAM_READ_COMMAND,
reg_buf_dma_addr(nandc,
(__le32 *)vaddr + i));
else
bam_prep_ce_le32(&bam_ce_buffer[i],
nandc_reg_phys(nandc, reg_off + 4 * i),
BAM_WRITE_COMMAND,
*((__le32 *)vaddr + i));
}
bam_txn->bam_ce_pos += size;
/* use the separate sgl after this command */
if (flags & NAND_BAM_NEXT_SGL) {
bam_ce_buffer = &bam_txn->bam_ce[bam_txn->bam_ce_start];
bam_ce_size = (bam_txn->bam_ce_pos -
bam_txn->bam_ce_start) *
sizeof(struct bam_cmd_element);
sg_set_buf(&bam_txn->cmd_sgl[bam_txn->cmd_sgl_pos],
bam_ce_buffer, bam_ce_size);
bam_txn->cmd_sgl_pos++;
bam_txn->bam_ce_start = bam_txn->bam_ce_pos;
if (flags & NAND_BAM_NWD) {
ret = prepare_bam_async_desc(nandc, nandc->cmd_chan,
DMA_PREP_FENCE |
DMA_PREP_CMD);
if (ret)
return ret;
}
}
return 0;
}
/*
* Prepares the data descriptor for BAM DMA which will be used for NAND
* data reads and writes.
*/
static int prep_bam_dma_desc_data(struct qcom_nand_controller *nandc, bool read,
const void *vaddr,
int size, unsigned int flags)
{
int ret;
struct bam_transaction *bam_txn = nandc->bam_txn;
if (read) {
sg_set_buf(&bam_txn->data_sgl[bam_txn->rx_sgl_pos],
vaddr, size);
bam_txn->rx_sgl_pos++;
} else {
sg_set_buf(&bam_txn->data_sgl[bam_txn->tx_sgl_pos],
vaddr, size);
bam_txn->tx_sgl_pos++;
/*
* BAM will only set EOT for DMA_PREP_INTERRUPT so if this flag
* is not set, form the DMA descriptor
*/
if (!(flags & NAND_BAM_NO_EOT)) {
ret = prepare_bam_async_desc(nandc, nandc->tx_chan,
DMA_PREP_INTERRUPT);
if (ret)
return ret;
}
}
return 0;
}
static int prep_adm_dma_desc(struct qcom_nand_controller *nandc, bool read,
int reg_off, const void *vaddr, int size,
bool flow_control)
{
struct desc_info *desc;
struct dma_async_tx_descriptor *dma_desc;
struct scatterlist *sgl;
struct dma_slave_config slave_conf;
enum dma_transfer_direction dir_eng;
int ret;
desc = kzalloc(sizeof(*desc), GFP_KERNEL);
if (!desc)
return -ENOMEM;
sgl = &desc->adm_sgl;
sg_init_one(sgl, vaddr, size);
if (read) {
dir_eng = DMA_DEV_TO_MEM;
desc->dir = DMA_FROM_DEVICE;
} else {
dir_eng = DMA_MEM_TO_DEV;
desc->dir = DMA_TO_DEVICE;
}
ret = dma_map_sg(nandc->dev, sgl, 1, desc->dir);
if (ret == 0) {
ret = -ENOMEM;
goto err;
}
memset(&slave_conf, 0x00, sizeof(slave_conf));
slave_conf.device_fc = flow_control;
if (read) {
slave_conf.src_maxburst = 16;
slave_conf.src_addr = nandc->base_dma + reg_off;
slave_conf.slave_id = nandc->data_crci;
} else {
slave_conf.dst_maxburst = 16;
slave_conf.dst_addr = nandc->base_dma + reg_off;
slave_conf.slave_id = nandc->cmd_crci;
}
ret = dmaengine_slave_config(nandc->chan, &slave_conf);
if (ret) {
dev_err(nandc->dev, "failed to configure dma channel\n");
goto err;
}
dma_desc = dmaengine_prep_slave_sg(nandc->chan, sgl, 1, dir_eng, 0);
if (!dma_desc) {
dev_err(nandc->dev, "failed to prepare desc\n");
ret = -EINVAL;
goto err;
}
desc->dma_desc = dma_desc;
list_add_tail(&desc->node, &nandc->desc_list);
return 0;
err:
kfree(desc);
return ret;
}
/*
* read_reg_dma: prepares a descriptor to read a given number of
* contiguous registers to the reg_read_buf pointer
*
* @first: offset of the first register in the contiguous block
* @num_regs: number of registers to read
* @flags: flags to control DMA descriptor preparation
*/
static int read_reg_dma(struct qcom_nand_controller *nandc, int first,
int num_regs, unsigned int flags)
{
bool flow_control = false;
void *vaddr;
vaddr = nandc->reg_read_buf + nandc->reg_read_pos;
nandc->reg_read_pos += num_regs;
if (first == NAND_DEV_CMD_VLD || first == NAND_DEV_CMD1)
first = dev_cmd_reg_addr(nandc, first);
if (nandc->props->is_bam)
return prep_bam_dma_desc_cmd(nandc, true, first, vaddr,
num_regs, flags);
if (first == NAND_READ_ID || first == NAND_FLASH_STATUS)
flow_control = true;
return prep_adm_dma_desc(nandc, true, first, vaddr,
num_regs * sizeof(u32), flow_control);
}
/*
* write_reg_dma: prepares a descriptor to write a given number of
* contiguous registers
*
* @first: offset of the first register in the contiguous block
* @num_regs: number of registers to write
* @flags: flags to control DMA descriptor preparation
*/
static int write_reg_dma(struct qcom_nand_controller *nandc, int first,
int num_regs, unsigned int flags)
{
bool flow_control = false;
struct nandc_regs *regs = nandc->regs;
void *vaddr;
vaddr = offset_to_nandc_reg(regs, first);
if (first == NAND_ERASED_CW_DETECT_CFG) {
if (flags & NAND_ERASED_CW_SET)
vaddr = &regs->erased_cw_detect_cfg_set;
else
vaddr = &regs->erased_cw_detect_cfg_clr;
}
if (first == NAND_EXEC_CMD)
flags |= NAND_BAM_NWD;
if (first == NAND_DEV_CMD1_RESTORE || first == NAND_DEV_CMD1)
first = dev_cmd_reg_addr(nandc, NAND_DEV_CMD1);
if (first == NAND_DEV_CMD_VLD_RESTORE || first == NAND_DEV_CMD_VLD)
first = dev_cmd_reg_addr(nandc, NAND_DEV_CMD_VLD);
if (nandc->props->is_bam)
return prep_bam_dma_desc_cmd(nandc, false, first, vaddr,
num_regs, flags);
if (first == NAND_FLASH_CMD)
flow_control = true;
return prep_adm_dma_desc(nandc, false, first, vaddr,
num_regs * sizeof(u32), flow_control);
}
/*
* read_data_dma: prepares a DMA descriptor to transfer data from the
* controller's internal buffer to the buffer 'vaddr'
*
* @reg_off: offset within the controller's data buffer
* @vaddr: virtual address of the buffer we want to write to
* @size: DMA transaction size in bytes
* @flags: flags to control DMA descriptor preparation
*/
static int read_data_dma(struct qcom_nand_controller *nandc, int reg_off,
const u8 *vaddr, int size, unsigned int flags)
{
if (nandc->props->is_bam)
return prep_bam_dma_desc_data(nandc, true, vaddr, size, flags);
return prep_adm_dma_desc(nandc, true, reg_off, vaddr, size, false);
}
/*
* write_data_dma: prepares a DMA descriptor to transfer data from
* 'vaddr' to the controller's internal buffer
*
* @reg_off: offset within the controller's data buffer
* @vaddr: virtual address of the buffer we want to read from
* @size: DMA transaction size in bytes
* @flags: flags to control DMA descriptor preparation
*/
static int write_data_dma(struct qcom_nand_controller *nandc, int reg_off,
const u8 *vaddr, int size, unsigned int flags)
{
if (nandc->props->is_bam)
return prep_bam_dma_desc_data(nandc, false, vaddr, size, flags);
return prep_adm_dma_desc(nandc, false, reg_off, vaddr, size, false);
}
/*
* Helper to prepare DMA descriptors for configuring registers
* before reading a NAND page.
*/
static void config_nand_page_read(struct qcom_nand_controller *nandc)
{
write_reg_dma(nandc, NAND_ADDR0, 2, 0);
write_reg_dma(nandc, NAND_DEV0_CFG0, 3, 0);
write_reg_dma(nandc, NAND_EBI2_ECC_BUF_CFG, 1, 0);
write_reg_dma(nandc, NAND_ERASED_CW_DETECT_CFG, 1, 0);
write_reg_dma(nandc, NAND_ERASED_CW_DETECT_CFG, 1,
NAND_ERASED_CW_SET | NAND_BAM_NEXT_SGL);
}
/*
* Helper to prepare DMA descriptors for configuring registers
* before reading each codeword in NAND page.
*/
static void config_nand_cw_read(struct qcom_nand_controller *nandc)
{
if (nandc->props->is_bam)
write_reg_dma(nandc, NAND_READ_LOCATION_0, 4,
NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_FLASH_CMD, 1, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_EXEC_CMD, 1, NAND_BAM_NEXT_SGL);
read_reg_dma(nandc, NAND_FLASH_STATUS, 2, 0);
read_reg_dma(nandc, NAND_ERASED_CW_DETECT_STATUS, 1,
NAND_BAM_NEXT_SGL);
}
/*
* Helper to prepare dma descriptors to configure registers needed for reading a
* single codeword in page
*/
static void config_nand_single_cw_page_read(struct qcom_nand_controller *nandc)
{
config_nand_page_read(nandc);
config_nand_cw_read(nandc);
}
/*
* Helper to prepare DMA descriptors used to configure registers needed for
* before writing a NAND page.
*/
static void config_nand_page_write(struct qcom_nand_controller *nandc)
{
write_reg_dma(nandc, NAND_ADDR0, 2, 0);
write_reg_dma(nandc, NAND_DEV0_CFG0, 3, 0);
write_reg_dma(nandc, NAND_EBI2_ECC_BUF_CFG, 1,
NAND_BAM_NEXT_SGL);
}
/*
* Helper to prepare DMA descriptors for configuring registers
* before writing each codeword in NAND page.
*/
static void config_nand_cw_write(struct qcom_nand_controller *nandc)
{
write_reg_dma(nandc, NAND_FLASH_CMD, 1, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_EXEC_CMD, 1, NAND_BAM_NEXT_SGL);
read_reg_dma(nandc, NAND_FLASH_STATUS, 1, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_FLASH_STATUS, 1, 0);
write_reg_dma(nandc, NAND_READ_STATUS, 1, NAND_BAM_NEXT_SGL);
}
/*
* the following functions are used within chip->cmdfunc() to perform different
* NAND_CMD_* commands
*/
/* sets up descriptors for NAND_CMD_PARAM */
static int nandc_param(struct qcom_nand_host *host)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
/*
* NAND_CMD_PARAM is called before we know much about the FLASH chip
* in use. we configure the controller to perform a raw read of 512
* bytes to read onfi params
*/
nandc_set_reg(nandc, NAND_FLASH_CMD, PAGE_READ | PAGE_ACC | LAST_PAGE);
nandc_set_reg(nandc, NAND_ADDR0, 0);
nandc_set_reg(nandc, NAND_ADDR1, 0);
nandc_set_reg(nandc, NAND_DEV0_CFG0, 0 << CW_PER_PAGE
| 512 << UD_SIZE_BYTES
| 5 << NUM_ADDR_CYCLES
| 0 << SPARE_SIZE_BYTES);
nandc_set_reg(nandc, NAND_DEV0_CFG1, 7 << NAND_RECOVERY_CYCLES
| 0 << CS_ACTIVE_BSY
| 17 << BAD_BLOCK_BYTE_NUM
| 1 << BAD_BLOCK_IN_SPARE_AREA
| 2 << WR_RD_BSY_GAP
| 0 << WIDE_FLASH
| 1 << DEV0_CFG1_ECC_DISABLE);
nandc_set_reg(nandc, NAND_EBI2_ECC_BUF_CFG, 1 << ECC_CFG_ECC_DISABLE);
/* configure CMD1 and VLD for ONFI param probing */
nandc_set_reg(nandc, NAND_DEV_CMD_VLD,
(nandc->vld & ~READ_START_VLD));
nandc_set_reg(nandc, NAND_DEV_CMD1,
(nandc->cmd1 & ~(0xFF << READ_ADDR))
| NAND_CMD_PARAM << READ_ADDR);
nandc_set_reg(nandc, NAND_EXEC_CMD, 1);
nandc_set_reg(nandc, NAND_DEV_CMD1_RESTORE, nandc->cmd1);
nandc_set_reg(nandc, NAND_DEV_CMD_VLD_RESTORE, nandc->vld);
nandc_set_read_loc(nandc, 0, 0, 512, 1);
write_reg_dma(nandc, NAND_DEV_CMD_VLD, 1, 0);
write_reg_dma(nandc, NAND_DEV_CMD1, 1, NAND_BAM_NEXT_SGL);
nandc->buf_count = 512;
memset(nandc->data_buffer, 0xff, nandc->buf_count);
config_nand_single_cw_page_read(nandc);
read_data_dma(nandc, FLASH_BUF_ACC, nandc->data_buffer,
nandc->buf_count, 0);
/* restore CMD1 and VLD regs */
write_reg_dma(nandc, NAND_DEV_CMD1_RESTORE, 1, 0);
write_reg_dma(nandc, NAND_DEV_CMD_VLD_RESTORE, 1, NAND_BAM_NEXT_SGL);
return 0;
}
/* sets up descriptors for NAND_CMD_ERASE1 */
static int erase_block(struct qcom_nand_host *host, int page_addr)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
nandc_set_reg(nandc, NAND_FLASH_CMD,
BLOCK_ERASE | PAGE_ACC | LAST_PAGE);
nandc_set_reg(nandc, NAND_ADDR0, page_addr);
nandc_set_reg(nandc, NAND_ADDR1, 0);
nandc_set_reg(nandc, NAND_DEV0_CFG0,
host->cfg0_raw & ~(7 << CW_PER_PAGE));
nandc_set_reg(nandc, NAND_DEV0_CFG1, host->cfg1_raw);
nandc_set_reg(nandc, NAND_EXEC_CMD, 1);
nandc_set_reg(nandc, NAND_FLASH_STATUS, host->clrflashstatus);
nandc_set_reg(nandc, NAND_READ_STATUS, host->clrreadstatus);
write_reg_dma(nandc, NAND_FLASH_CMD, 3, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_DEV0_CFG0, 2, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_EXEC_CMD, 1, NAND_BAM_NEXT_SGL);
read_reg_dma(nandc, NAND_FLASH_STATUS, 1, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_FLASH_STATUS, 1, 0);
write_reg_dma(nandc, NAND_READ_STATUS, 1, NAND_BAM_NEXT_SGL);
return 0;
}
/* sets up descriptors for NAND_CMD_READID */
static int read_id(struct qcom_nand_host *host, int column)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
if (column == -1)
return 0;
nandc_set_reg(nandc, NAND_FLASH_CMD, FETCH_ID);
nandc_set_reg(nandc, NAND_ADDR0, column);
nandc_set_reg(nandc, NAND_ADDR1, 0);
nandc_set_reg(nandc, NAND_FLASH_CHIP_SELECT,
nandc->props->is_bam ? 0 : DM_EN);
nandc_set_reg(nandc, NAND_EXEC_CMD, 1);
write_reg_dma(nandc, NAND_FLASH_CMD, 4, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_EXEC_CMD, 1, NAND_BAM_NEXT_SGL);
read_reg_dma(nandc, NAND_READ_ID, 1, NAND_BAM_NEXT_SGL);
return 0;
}
/* sets up descriptors for NAND_CMD_RESET */
static int reset(struct qcom_nand_host *host)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
nandc_set_reg(nandc, NAND_FLASH_CMD, RESET_DEVICE);
nandc_set_reg(nandc, NAND_EXEC_CMD, 1);
write_reg_dma(nandc, NAND_FLASH_CMD, 1, NAND_BAM_NEXT_SGL);
write_reg_dma(nandc, NAND_EXEC_CMD, 1, NAND_BAM_NEXT_SGL);
read_reg_dma(nandc, NAND_FLASH_STATUS, 1, NAND_BAM_NEXT_SGL);
return 0;
}
/* helpers to submit/free our list of dma descriptors */
static int submit_descs(struct qcom_nand_controller *nandc)
{
struct desc_info *desc;
dma_cookie_t cookie = 0;
struct bam_transaction *bam_txn = nandc->bam_txn;
int r;
if (nandc->props->is_bam) {
if (bam_txn->rx_sgl_pos > bam_txn->rx_sgl_start) {
r = prepare_bam_async_desc(nandc, nandc->rx_chan, 0);
if (r)
return r;
}
if (bam_txn->tx_sgl_pos > bam_txn->tx_sgl_start) {
r = prepare_bam_async_desc(nandc, nandc->tx_chan,
DMA_PREP_INTERRUPT);
if (r)
return r;
}
if (bam_txn->cmd_sgl_pos > bam_txn->cmd_sgl_start) {
r = prepare_bam_async_desc(nandc, nandc->cmd_chan,
DMA_PREP_CMD);
if (r)
return r;
}
}
list_for_each_entry(desc, &nandc->desc_list, node)
cookie = dmaengine_submit(desc->dma_desc);
if (nandc->props->is_bam) {
dma_async_issue_pending(nandc->tx_chan);
dma_async_issue_pending(nandc->rx_chan);
if (dma_sync_wait(nandc->cmd_chan, cookie) != DMA_COMPLETE)
return -ETIMEDOUT;
} else {
if (dma_sync_wait(nandc->chan, cookie) != DMA_COMPLETE)
return -ETIMEDOUT;
}
return 0;
}
static void free_descs(struct qcom_nand_controller *nandc)
{
struct desc_info *desc, *n;
list_for_each_entry_safe(desc, n, &nandc->desc_list, node) {
list_del(&desc->node);
if (nandc->props->is_bam)
dma_unmap_sg(nandc->dev, desc->bam_sgl,
desc->sgl_cnt, desc->dir);
else
dma_unmap_sg(nandc->dev, &desc->adm_sgl, 1,
desc->dir);
kfree(desc);
}
}
/* reset the register read buffer for next NAND operation */
static void clear_read_regs(struct qcom_nand_controller *nandc)
{
nandc->reg_read_pos = 0;
nandc_read_buffer_sync(nandc, false);
}
static void pre_command(struct qcom_nand_host *host, int command)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
nandc->buf_count = 0;
nandc->buf_start = 0;
host->use_ecc = false;
host->last_command = command;
clear_read_regs(nandc);
if (command == NAND_CMD_RESET || command == NAND_CMD_READID ||
command == NAND_CMD_PARAM || command == NAND_CMD_ERASE1)
clear_bam_transaction(nandc);
}
/*
* this is called after NAND_CMD_PAGEPROG and NAND_CMD_ERASE1 to set our
* privately maintained status byte, this status byte can be read after
* NAND_CMD_STATUS is called
*/
static void parse_erase_write_errors(struct qcom_nand_host *host, int command)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int num_cw;
int i;
num_cw = command == NAND_CMD_PAGEPROG ? ecc->steps : 1;
nandc_read_buffer_sync(nandc, true);
for (i = 0; i < num_cw; i++) {
u32 flash_status = le32_to_cpu(nandc->reg_read_buf[i]);
if (flash_status & FS_MPU_ERR)
host->status &= ~NAND_STATUS_WP;
if (flash_status & FS_OP_ERR || (i == (num_cw - 1) &&
(flash_status &
FS_DEVICE_STS_ERR)))
host->status |= NAND_STATUS_FAIL;
}
}
static void post_command(struct qcom_nand_host *host, int command)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
switch (command) {
case NAND_CMD_READID:
nandc_read_buffer_sync(nandc, true);
memcpy(nandc->data_buffer, nandc->reg_read_buf,
nandc->buf_count);
break;
case NAND_CMD_PAGEPROG:
case NAND_CMD_ERASE1:
parse_erase_write_errors(host, command);
break;
default:
break;
}
}
/*
* Implements chip->cmdfunc. It's only used for a limited set of commands.
* The rest of the commands wouldn't be called by upper layers. For example,
* NAND_CMD_READOOB would never be called because we have our own versions
* of read_oob ops for nand_ecc_ctrl.
*/
static void qcom_nandc_command(struct mtd_info *mtd, unsigned int command,
int column, int page_addr)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
bool wait = false;
int ret = 0;
pre_command(host, command);
switch (command) {
case NAND_CMD_RESET:
ret = reset(host);
wait = true;
break;
case NAND_CMD_READID:
nandc->buf_count = 4;
ret = read_id(host, column);
wait = true;
break;
case NAND_CMD_PARAM:
ret = nandc_param(host);
wait = true;
break;
case NAND_CMD_ERASE1:
ret = erase_block(host, page_addr);
wait = true;
break;
case NAND_CMD_READ0:
/* we read the entire page for now */
WARN_ON(column != 0);
host->use_ecc = true;
set_address(host, 0, page_addr);
update_rw_regs(host, ecc->steps, true);
break;
case NAND_CMD_SEQIN:
WARN_ON(column != 0);
set_address(host, 0, page_addr);
break;
case NAND_CMD_PAGEPROG:
case NAND_CMD_STATUS:
case NAND_CMD_NONE:
default:
break;
}
if (ret) {
dev_err(nandc->dev, "failure executing command %d\n",
command);
free_descs(nandc);
return;
}
if (wait) {
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev,
"failure submitting descs for command %d\n",
command);
}
free_descs(nandc);
post_command(host, command);
}
/*
* when using BCH ECC, the HW flags an error in NAND_FLASH_STATUS if it read
* an erased CW, and reports an erased CW in NAND_ERASED_CW_DETECT_STATUS.
*
* when using RS ECC, the HW reports the same erros when reading an erased CW,
* but it notifies that it is an erased CW by placing special characters at
* certain offsets in the buffer.
*
* verify if the page is erased or not, and fix up the page for RS ECC by
* replacing the special characters with 0xff.
*/
static bool erased_chunk_check_and_fixup(u8 *data_buf, int data_len)
{
u8 empty1, empty2;
/*
* an erased page flags an error in NAND_FLASH_STATUS, check if the page
* is erased by looking for 0x54s at offsets 3 and 175 from the
* beginning of each codeword
*/
empty1 = data_buf[3];
empty2 = data_buf[175];
/*
* if the erased codework markers, if they exist override them with
* 0xffs
*/
if ((empty1 == 0x54 && empty2 == 0xff) ||
(empty1 == 0xff && empty2 == 0x54)) {
data_buf[3] = 0xff;
data_buf[175] = 0xff;
}
/*
* check if the entire chunk contains 0xffs or not. if it doesn't, then
* restore the original values at the special offsets
*/
if (memchr_inv(data_buf, 0xff, data_len)) {
data_buf[3] = empty1;
data_buf[175] = empty2;
return false;
}
return true;
}
struct read_stats {
__le32 flash;
__le32 buffer;
__le32 erased_cw;
};
/*
* reads back status registers set by the controller to notify page read
* errors. this is equivalent to what 'ecc->correct()' would do.
*/
static int parse_read_errors(struct qcom_nand_host *host, u8 *data_buf,
u8 *oob_buf)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct mtd_info *mtd = nand_to_mtd(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
unsigned int max_bitflips = 0;
struct read_stats *buf;
int i;
buf = (struct read_stats *)nandc->reg_read_buf;
nandc_read_buffer_sync(nandc, true);
for (i = 0; i < ecc->steps; i++, buf++) {
u32 flash, buffer, erased_cw;
int data_len, oob_len;
if (i == (ecc->steps - 1)) {
data_len = ecc->size - ((ecc->steps - 1) << 2);
oob_len = ecc->steps << 2;
} else {
data_len = host->cw_data;
oob_len = 0;
}
flash = le32_to_cpu(buf->flash);
buffer = le32_to_cpu(buf->buffer);
erased_cw = le32_to_cpu(buf->erased_cw);
if (flash & (FS_OP_ERR | FS_MPU_ERR)) {
bool erased;
/* ignore erased codeword errors */
if (host->bch_enabled) {
erased = (erased_cw & ERASED_CW) == ERASED_CW ?
true : false;
} else {
erased = erased_chunk_check_and_fixup(data_buf,
data_len);
}
if (erased) {
data_buf += data_len;
if (oob_buf)
oob_buf += oob_len + ecc->bytes;
continue;
}
if (buffer & BS_UNCORRECTABLE_BIT) {
int ret, ecclen, extraooblen;
void *eccbuf;
eccbuf = oob_buf ? oob_buf + oob_len : NULL;
ecclen = oob_buf ? host->ecc_bytes_hw : 0;
extraooblen = oob_buf ? oob_len : 0;
/*
* make sure it isn't an erased page reported
* as not-erased by HW because of a few bitflips
*/
ret = nand_check_erased_ecc_chunk(data_buf,
data_len, eccbuf, ecclen, oob_buf,
extraooblen, ecc->strength);
if (ret < 0) {
mtd->ecc_stats.failed++;
} else {
mtd->ecc_stats.corrected += ret;
max_bitflips =
max_t(unsigned int, max_bitflips, ret);
}
}
} else {
unsigned int stat;
stat = buffer & BS_CORRECTABLE_ERR_MSK;
mtd->ecc_stats.corrected += stat;
max_bitflips = max(max_bitflips, stat);
}
data_buf += data_len;
if (oob_buf)
oob_buf += oob_len + ecc->bytes;
}
return max_bitflips;
}
/*
* helper to perform the actual page read operation, used by ecc->read_page(),
* ecc->read_oob()
*/
static int read_page_ecc(struct qcom_nand_host *host, u8 *data_buf,
u8 *oob_buf)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int i, ret;
config_nand_page_read(nandc);
/* queue cmd descs for each codeword */
for (i = 0; i < ecc->steps; i++) {
int data_size, oob_size;
if (i == (ecc->steps - 1)) {
data_size = ecc->size - ((ecc->steps - 1) << 2);
oob_size = (ecc->steps << 2) + host->ecc_bytes_hw +
host->spare_bytes;
} else {
data_size = host->cw_data;
oob_size = host->ecc_bytes_hw + host->spare_bytes;
}
if (nandc->props->is_bam) {
if (data_buf && oob_buf) {
nandc_set_read_loc(nandc, 0, 0, data_size, 0);
nandc_set_read_loc(nandc, 1, data_size,
oob_size, 1);
} else if (data_buf) {
nandc_set_read_loc(nandc, 0, 0, data_size, 1);
} else {
nandc_set_read_loc(nandc, 0, data_size,
oob_size, 1);
}
}
config_nand_cw_read(nandc);
if (data_buf)
read_data_dma(nandc, FLASH_BUF_ACC, data_buf,
data_size, 0);
/*
* when ecc is enabled, the controller doesn't read the real
* or dummy bad block markers in each chunk. To maintain a
* consistent layout across RAW and ECC reads, we just
* leave the real/dummy BBM offsets empty (i.e, filled with
* 0xffs)
*/
if (oob_buf) {
int j;
for (j = 0; j < host->bbm_size; j++)
*oob_buf++ = 0xff;
read_data_dma(nandc, FLASH_BUF_ACC + data_size,
oob_buf, oob_size, 0);
}
if (data_buf)
data_buf += data_size;
if (oob_buf)
oob_buf += oob_size;
}
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev, "failure to read page/oob\n");
free_descs(nandc);
return ret;
}
/*
* a helper that copies the last step/codeword of a page (containing free oob)
* into our local buffer
*/
static int copy_last_cw(struct qcom_nand_host *host, int page)
{
struct nand_chip *chip = &host->chip;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int size;
int ret;
clear_read_regs(nandc);
size = host->use_ecc ? host->cw_data : host->cw_size;
/* prepare a clean read buffer */
memset(nandc->data_buffer, 0xff, size);
set_address(host, host->cw_size * (ecc->steps - 1), page);
update_rw_regs(host, 1, true);
config_nand_single_cw_page_read(nandc);
read_data_dma(nandc, FLASH_BUF_ACC, nandc->data_buffer, size, 0);
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev, "failed to copy last codeword\n");
free_descs(nandc);
return ret;
}
/* implements ecc->read_page() */
static int qcom_nandc_read_page(struct mtd_info *mtd, struct nand_chip *chip,
uint8_t *buf, int oob_required, int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
u8 *data_buf, *oob_buf = NULL;
int ret;
nand_read_page_op(chip, page, 0, NULL, 0);
data_buf = buf;
oob_buf = oob_required ? chip->oob_poi : NULL;
clear_bam_transaction(nandc);
ret = read_page_ecc(host, data_buf, oob_buf);
if (ret) {
dev_err(nandc->dev, "failure to read page\n");
return ret;
}
return parse_read_errors(host, data_buf, oob_buf);
}
/* implements ecc->read_page_raw() */
static int qcom_nandc_read_page_raw(struct mtd_info *mtd,
struct nand_chip *chip, uint8_t *buf,
int oob_required, int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
u8 *data_buf, *oob_buf;
struct nand_ecc_ctrl *ecc = &chip->ecc;
int i, ret;
int read_loc;
nand_read_page_op(chip, page, 0, NULL, 0);
data_buf = buf;
oob_buf = chip->oob_poi;
host->use_ecc = false;
clear_bam_transaction(nandc);
update_rw_regs(host, ecc->steps, true);
config_nand_page_read(nandc);
for (i = 0; i < ecc->steps; i++) {
int data_size1, data_size2, oob_size1, oob_size2;
int reg_off = FLASH_BUF_ACC;
data_size1 = mtd->writesize - host->cw_size * (ecc->steps - 1);
oob_size1 = host->bbm_size;
if (i == (ecc->steps - 1)) {
data_size2 = ecc->size - data_size1 -
((ecc->steps - 1) << 2);
oob_size2 = (ecc->steps << 2) + host->ecc_bytes_hw +
host->spare_bytes;
} else {
data_size2 = host->cw_data - data_size1;
oob_size2 = host->ecc_bytes_hw + host->spare_bytes;
}
if (nandc->props->is_bam) {
read_loc = 0;
nandc_set_read_loc(nandc, 0, read_loc, data_size1, 0);
read_loc += data_size1;
nandc_set_read_loc(nandc, 1, read_loc, oob_size1, 0);
read_loc += oob_size1;
nandc_set_read_loc(nandc, 2, read_loc, data_size2, 0);
read_loc += data_size2;
nandc_set_read_loc(nandc, 3, read_loc, oob_size2, 1);
}
config_nand_cw_read(nandc);
read_data_dma(nandc, reg_off, data_buf, data_size1, 0);
reg_off += data_size1;
data_buf += data_size1;
read_data_dma(nandc, reg_off, oob_buf, oob_size1, 0);
reg_off += oob_size1;
oob_buf += oob_size1;
read_data_dma(nandc, reg_off, data_buf, data_size2, 0);
reg_off += data_size2;
data_buf += data_size2;
read_data_dma(nandc, reg_off, oob_buf, oob_size2, 0);
oob_buf += oob_size2;
}
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev, "failure to read raw page\n");
free_descs(nandc);
return 0;
}
/* implements ecc->read_oob() */
static int qcom_nandc_read_oob(struct mtd_info *mtd, struct nand_chip *chip,
int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int ret;
clear_read_regs(nandc);
clear_bam_transaction(nandc);
host->use_ecc = true;
set_address(host, 0, page);
update_rw_regs(host, ecc->steps, true);
ret = read_page_ecc(host, NULL, chip->oob_poi);
if (ret)
dev_err(nandc->dev, "failure to read oob\n");
return ret;
}
/* implements ecc->write_page() */
static int qcom_nandc_write_page(struct mtd_info *mtd, struct nand_chip *chip,
const uint8_t *buf, int oob_required, int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
u8 *data_buf, *oob_buf;
int i, ret;
nand_prog_page_begin_op(chip, page, 0, NULL, 0);
clear_read_regs(nandc);
clear_bam_transaction(nandc);
data_buf = (u8 *)buf;
oob_buf = chip->oob_poi;
host->use_ecc = true;
update_rw_regs(host, ecc->steps, false);
config_nand_page_write(nandc);
for (i = 0; i < ecc->steps; i++) {
int data_size, oob_size;
if (i == (ecc->steps - 1)) {
data_size = ecc->size - ((ecc->steps - 1) << 2);
oob_size = (ecc->steps << 2) + host->ecc_bytes_hw +
host->spare_bytes;
} else {
data_size = host->cw_data;
oob_size = ecc->bytes;
}
write_data_dma(nandc, FLASH_BUF_ACC, data_buf, data_size,
i == (ecc->steps - 1) ? NAND_BAM_NO_EOT : 0);
/*
* when ECC is enabled, we don't really need to write anything
* to oob for the first n - 1 codewords since these oob regions
* just contain ECC bytes that's written by the controller
* itself. For the last codeword, we skip the bbm positions and
* write to the free oob area.
*/
if (i == (ecc->steps - 1)) {
oob_buf += host->bbm_size;
write_data_dma(nandc, FLASH_BUF_ACC + data_size,
oob_buf, oob_size, 0);
}
config_nand_cw_write(nandc);
data_buf += data_size;
oob_buf += oob_size;
}
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev, "failure to write page\n");
free_descs(nandc);
if (!ret)
ret = nand_prog_page_end_op(chip);
return ret;
}
/* implements ecc->write_page_raw() */
static int qcom_nandc_write_page_raw(struct mtd_info *mtd,
struct nand_chip *chip, const uint8_t *buf,
int oob_required, int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
u8 *data_buf, *oob_buf;
int i, ret;
nand_prog_page_begin_op(chip, page, 0, NULL, 0);
clear_read_regs(nandc);
clear_bam_transaction(nandc);
data_buf = (u8 *)buf;
oob_buf = chip->oob_poi;
host->use_ecc = false;
update_rw_regs(host, ecc->steps, false);
config_nand_page_write(nandc);
for (i = 0; i < ecc->steps; i++) {
int data_size1, data_size2, oob_size1, oob_size2;
int reg_off = FLASH_BUF_ACC;
data_size1 = mtd->writesize - host->cw_size * (ecc->steps - 1);
oob_size1 = host->bbm_size;
if (i == (ecc->steps - 1)) {
data_size2 = ecc->size - data_size1 -
((ecc->steps - 1) << 2);
oob_size2 = (ecc->steps << 2) + host->ecc_bytes_hw +
host->spare_bytes;
} else {
data_size2 = host->cw_data - data_size1;
oob_size2 = host->ecc_bytes_hw + host->spare_bytes;
}
write_data_dma(nandc, reg_off, data_buf, data_size1,
NAND_BAM_NO_EOT);
reg_off += data_size1;
data_buf += data_size1;
write_data_dma(nandc, reg_off, oob_buf, oob_size1,
NAND_BAM_NO_EOT);
reg_off += oob_size1;
oob_buf += oob_size1;
write_data_dma(nandc, reg_off, data_buf, data_size2,
NAND_BAM_NO_EOT);
reg_off += data_size2;
data_buf += data_size2;
write_data_dma(nandc, reg_off, oob_buf, oob_size2, 0);
oob_buf += oob_size2;
config_nand_cw_write(nandc);
}
ret = submit_descs(nandc);
if (ret)
dev_err(nandc->dev, "failure to write raw page\n");
free_descs(nandc);
if (!ret)
ret = nand_prog_page_end_op(chip);
return ret;
}
/*
* implements ecc->write_oob()
*
* the NAND controller cannot write only data or only oob within a codeword,
* since ecc is calculated for the combined codeword. we first copy the
* entire contents for the last codeword(data + oob), replace the old oob
* with the new one in chip->oob_poi, and then write the entire codeword.
* this read-copy-write operation results in a slight performance loss.
*/
static int qcom_nandc_write_oob(struct mtd_info *mtd, struct nand_chip *chip,
int page)
{
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
u8 *oob = chip->oob_poi;
int data_size, oob_size;
int ret;
host->use_ecc = true;
clear_bam_transaction(nandc);
ret = copy_last_cw(host, page);
if (ret)
return ret;
clear_read_regs(nandc);
clear_bam_transaction(nandc);
/* calculate the data and oob size for the last codeword/step */
data_size = ecc->size - ((ecc->steps - 1) << 2);
oob_size = mtd->oobavail;
/* override new oob content to last codeword */
mtd_ooblayout_get_databytes(mtd, nandc->data_buffer + data_size, oob,
0, mtd->oobavail);
set_address(host, host->cw_size * (ecc->steps - 1), page);
update_rw_regs(host, 1, false);
config_nand_page_write(nandc);
write_data_dma(nandc, FLASH_BUF_ACC,
nandc->data_buffer, data_size + oob_size, 0);
config_nand_cw_write(nandc);
ret = submit_descs(nandc);
free_descs(nandc);
if (ret) {
dev_err(nandc->dev, "failure to write oob\n");
return -EIO;
}
return nand_prog_page_end_op(chip);
}
static int qcom_nandc_block_bad(struct mtd_info *mtd, loff_t ofs)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int page, ret, bbpos, bad = 0;
u32 flash_status;
page = (int)(ofs >> chip->page_shift) & chip->pagemask;
/*
* configure registers for a raw sub page read, the address is set to
* the beginning of the last codeword, we don't care about reading ecc
* portion of oob. we just want the first few bytes from this codeword
* that contains the BBM
*/
host->use_ecc = false;
clear_bam_transaction(nandc);
ret = copy_last_cw(host, page);
if (ret)
goto err;
flash_status = le32_to_cpu(nandc->reg_read_buf[0]);
if (flash_status & (FS_OP_ERR | FS_MPU_ERR)) {
dev_warn(nandc->dev, "error when trying to read BBM\n");
goto err;
}
bbpos = mtd->writesize - host->cw_size * (ecc->steps - 1);
bad = nandc->data_buffer[bbpos] != 0xff;
if (chip->options & NAND_BUSWIDTH_16)
bad = bad || (nandc->data_buffer[bbpos + 1] != 0xff);
err:
return bad;
}
static int qcom_nandc_block_markbad(struct mtd_info *mtd, loff_t ofs)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
int page, ret;
clear_read_regs(nandc);
clear_bam_transaction(nandc);
/*
* to mark the BBM as bad, we flash the entire last codeword with 0s.
* we don't care about the rest of the content in the codeword since
* we aren't going to use this block again
*/
memset(nandc->data_buffer, 0x00, host->cw_size);
page = (int)(ofs >> chip->page_shift) & chip->pagemask;
/* prepare write */
host->use_ecc = false;
set_address(host, host->cw_size * (ecc->steps - 1), page);
update_rw_regs(host, 1, false);
config_nand_page_write(nandc);
write_data_dma(nandc, FLASH_BUF_ACC,
nandc->data_buffer, host->cw_size, 0);
config_nand_cw_write(nandc);
ret = submit_descs(nandc);
free_descs(nandc);
if (ret) {
dev_err(nandc->dev, "failure to update BBM\n");
return -EIO;
}
return nand_prog_page_end_op(chip);
}
/*
* the three functions below implement chip->read_byte(), chip->read_buf()
* and chip->write_buf() respectively. these aren't used for
* reading/writing page data, they are used for smaller data like reading
* id, status etc
*/
static uint8_t qcom_nandc_read_byte(struct mtd_info *mtd)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
u8 *buf = nandc->data_buffer;
u8 ret = 0x0;
if (host->last_command == NAND_CMD_STATUS) {
ret = host->status;
host->status = NAND_STATUS_READY | NAND_STATUS_WP;
return ret;
}
if (nandc->buf_start < nandc->buf_count)
ret = buf[nandc->buf_start++];
return ret;
}
static void qcom_nandc_read_buf(struct mtd_info *mtd, uint8_t *buf, int len)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
int real_len = min_t(size_t, len, nandc->buf_count - nandc->buf_start);
memcpy(buf, nandc->data_buffer + nandc->buf_start, real_len);
nandc->buf_start += real_len;
}
static void qcom_nandc_write_buf(struct mtd_info *mtd, const uint8_t *buf,
int len)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
int real_len = min_t(size_t, len, nandc->buf_count - nandc->buf_start);
memcpy(nandc->data_buffer + nandc->buf_start, buf, real_len);
nandc->buf_start += real_len;
}
/* we support only one external chip for now */
static void qcom_nandc_select_chip(struct mtd_info *mtd, int chipnr)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
if (chipnr <= 0)
return;
dev_warn(nandc->dev, "invalid chip select\n");
}
/*
* NAND controller page layout info
*
* Layout with ECC enabled:
*
* |----------------------| |---------------------------------|
* | xx.......yy| | *********xx.......yy|
* | DATA xx..ECC..yy| | DATA **SPARE**xx..ECC..yy|
* | (516) xx.......yy| | (516-n*4) **(n*4)**xx.......yy|
* | xx.......yy| | *********xx.......yy|
* |----------------------| |---------------------------------|
* codeword 1,2..n-1 codeword n
* <---(528/532 Bytes)--> <-------(528/532 Bytes)--------->
*
* n = Number of codewords in the page
* . = ECC bytes
* * = Spare/free bytes
* x = Unused byte(s)
* y = Reserved byte(s)
*
* 2K page: n = 4, spare = 16 bytes
* 4K page: n = 8, spare = 32 bytes
* 8K page: n = 16, spare = 64 bytes
*
* the qcom nand controller operates at a sub page/codeword level. each
* codeword is 528 and 532 bytes for 4 bit and 8 bit ECC modes respectively.
* the number of ECC bytes vary based on the ECC strength and the bus width.
*
* the first n - 1 codewords contains 516 bytes of user data, the remaining
* 12/16 bytes consist of ECC and reserved data. The nth codeword contains
* both user data and spare(oobavail) bytes that sum up to 516 bytes.
*
* When we access a page with ECC enabled, the reserved bytes(s) are not
* accessible at all. When reading, we fill up these unreadable positions
* with 0xffs. When writing, the controller skips writing the inaccessible
* bytes.
*
* Layout with ECC disabled:
*
* |------------------------------| |---------------------------------------|
* | yy xx.......| | bb *********xx.......|
* | DATA1 yy DATA2 xx..ECC..| | DATA1 bb DATA2 **SPARE**xx..ECC..|
* | (size1) yy (size2) xx.......| | (size1) bb (size2) **(n*4)**xx.......|
* | yy xx.......| | bb *********xx.......|
* |------------------------------| |---------------------------------------|
* codeword 1,2..n-1 codeword n
* <-------(528/532 Bytes)------> <-----------(528/532 Bytes)----------->
*
* n = Number of codewords in the page
* . = ECC bytes
* * = Spare/free bytes
* x = Unused byte(s)
* y = Dummy Bad Bock byte(s)
* b = Real Bad Block byte(s)
* size1/size2 = function of codeword size and 'n'
*
* when the ECC block is disabled, one reserved byte (or two for 16 bit bus
* width) is now accessible. For the first n - 1 codewords, these are dummy Bad
* Block Markers. In the last codeword, this position contains the real BBM
*
* In order to have a consistent layout between RAW and ECC modes, we assume
* the following OOB layout arrangement:
*
* |-----------| |--------------------|
* |yyxx.......| |bb*********xx.......|
* |yyxx..ECC..| |bb*FREEOOB*xx..ECC..|
* |yyxx.......| |bb*********xx.......|
* |yyxx.......| |bb*********xx.......|
* |-----------| |--------------------|
* first n - 1 nth OOB region
* OOB regions
*
* n = Number of codewords in the page
* . = ECC bytes
* * = FREE OOB bytes
* y = Dummy bad block byte(s) (inaccessible when ECC enabled)
* x = Unused byte(s)
* b = Real bad block byte(s) (inaccessible when ECC enabled)
*
* This layout is read as is when ECC is disabled. When ECC is enabled, the
* inaccessible Bad Block byte(s) are ignored when we write to a page/oob,
* and assumed as 0xffs when we read a page/oob. The ECC, unused and
* dummy/real bad block bytes are grouped as ecc bytes (i.e, ecc->bytes is
* the sum of the three).
*/
static int qcom_nand_ooblayout_ecc(struct mtd_info *mtd, int section,
struct mtd_oob_region *oobregion)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
if (section > 1)
return -ERANGE;
if (!section) {
oobregion->length = (ecc->bytes * (ecc->steps - 1)) +
host->bbm_size;
oobregion->offset = 0;
} else {
oobregion->length = host->ecc_bytes_hw + host->spare_bytes;
oobregion->offset = mtd->oobsize - oobregion->length;
}
return 0;
}
static int qcom_nand_ooblayout_free(struct mtd_info *mtd, int section,
struct mtd_oob_region *oobregion)
{
struct nand_chip *chip = mtd_to_nand(mtd);
struct qcom_nand_host *host = to_qcom_nand_host(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
if (section)
return -ERANGE;
oobregion->length = ecc->steps * 4;
oobregion->offset = ((ecc->steps - 1) * ecc->bytes) + host->bbm_size;
return 0;
}
static const struct mtd_ooblayout_ops qcom_nand_ooblayout_ops = {
.ecc = qcom_nand_ooblayout_ecc,
.free = qcom_nand_ooblayout_free,
};
static int qcom_nand_host_setup(struct qcom_nand_host *host)
{
struct nand_chip *chip = &host->chip;
struct mtd_info *mtd = nand_to_mtd(chip);
struct nand_ecc_ctrl *ecc = &chip->ecc;
struct qcom_nand_controller *nandc = get_qcom_nand_controller(chip);
int cwperpage, bad_block_byte;
bool wide_bus;
int ecc_mode = 1;
/*
* the controller requires each step consists of 512 bytes of data.
* bail out if DT has populated a wrong step size.
*/
if (ecc->size != NANDC_STEP_SIZE) {
dev_err(nandc->dev, "invalid ecc size\n");
return -EINVAL;
}
wide_bus = chip->options & NAND_BUSWIDTH_16 ? true : false;
if (ecc->strength >= 8) {
/* 8 bit ECC defaults to BCH ECC on all platforms */
host->bch_enabled = true;
ecc_mode = 1;
if (wide_bus) {
host->ecc_bytes_hw = 14;
host->spare_bytes = 0;
host->bbm_size = 2;
} else {
host->ecc_bytes_hw = 13;
host->spare_bytes = 2;
host->bbm_size = 1;
}
} else {
/*
* if the controller supports BCH for 4 bit ECC, the controller
* uses lesser bytes for ECC. If RS is used, the ECC bytes is
* always 10 bytes
*/
if (nandc->props->ecc_modes & ECC_BCH_4BIT) {
/* BCH */
host->bch_enabled = true;
ecc_mode = 0;
if (wide_bus) {
host->ecc_bytes_hw = 8;
host->spare_bytes = 2;
host->bbm_size = 2;
} else {
host->ecc_bytes_hw = 7;
host->spare_bytes = 4;
host->bbm_size = 1;
}
} else {
/* RS */
host->ecc_bytes_hw = 10;
if (wide_bus) {
host->spare_bytes = 0;
host->bbm_size = 2;
} else {
host->spare_bytes = 1;
host->bbm_size = 1;
}
}
}
/*
* we consider ecc->bytes as the sum of all the non-data content in a
* step. It gives us a clean representation of the oob area (even if
* all the bytes aren't used for ECC).It is always 16 bytes for 8 bit
* ECC and 12 bytes for 4 bit ECC
*/
ecc->bytes = host->ecc_bytes_hw + host->spare_bytes + host->bbm_size;
ecc->read_page = qcom_nandc_read_page;
ecc->read_page_raw = qcom_nandc_read_page_raw;
ecc->read_oob = qcom_nandc_read_oob;
ecc->write_page = qcom_nandc_write_page;
ecc->write_page_raw = qcom_nandc_write_page_raw;
ecc->write_oob = qcom_nandc_write_oob;
ecc->mode = NAND_ECC_HW;
mtd_set_ooblayout(mtd, &qcom_nand_ooblayout_ops);
cwperpage = mtd->writesize / ecc->size;
nandc->max_cwperpage = max_t(unsigned int, nandc->max_cwperpage,
cwperpage);
/*
* DATA_UD_BYTES varies based on whether the read/write command protects
* spare data with ECC too. We protect spare data by default, so we set
* it to main + spare data, which are 512 and 4 bytes respectively.
*/
host->cw_data = 516;
/*
* total bytes in a step, either 528 bytes for 4 bit ECC, or 532 bytes
* for 8 bit ECC
*/
host->cw_size = host->cw_data + ecc->bytes;
if (ecc->bytes * (mtd->writesize / ecc->size) > mtd->oobsize) {
dev_err(nandc->dev, "ecc data doesn't fit in OOB area\n");
return -EINVAL;
}
bad_block_byte = mtd->writesize - host->cw_size * (cwperpage - 1) + 1;
host->cfg0 = (cwperpage - 1) << CW_PER_PAGE
| host->cw_data << UD_SIZE_BYTES
| 0 << DISABLE_STATUS_AFTER_WRITE
| 5 << NUM_ADDR_CYCLES
| host->ecc_bytes_hw << ECC_PARITY_SIZE_BYTES_RS
| 0 << STATUS_BFR_READ
| 1 << SET_RD_MODE_AFTER_STATUS
| host->spare_bytes << SPARE_SIZE_BYTES;
host->cfg1 = 7 << NAND_RECOVERY_CYCLES
| 0 << CS_ACTIVE_BSY
| bad_block_byte << BAD_BLOCK_BYTE_NUM
| 0 << BAD_BLOCK_IN_SPARE_AREA
| 2 << WR_RD_BSY_GAP
| wide_bus << WIDE_FLASH
| host->bch_enabled << ENABLE_BCH_ECC;
host->cfg0_raw = (cwperpage - 1) << CW_PER_PAGE
| host->cw_size << UD_SIZE_BYTES
| 5 << NUM_ADDR_CYCLES
| 0 << SPARE_SIZE_BYTES;
host->cfg1_raw = 7 << NAND_RECOVERY_CYCLES
| 0 << CS_ACTIVE_BSY
| 17 << BAD_BLOCK_BYTE_NUM
| 1 << BAD_BLOCK_IN_SPARE_AREA
| 2 << WR_RD_BSY_GAP
| wide_bus << WIDE_FLASH
| 1 << DEV0_CFG1_ECC_DISABLE;
host->ecc_bch_cfg = !host->bch_enabled << ECC_CFG_ECC_DISABLE
| 0 << ECC_SW_RESET
| host->cw_data << ECC_NUM_DATA_BYTES
| 1 << ECC_FORCE_CLK_OPEN
| ecc_mode << ECC_MODE
| host->ecc_bytes_hw << ECC_PARITY_SIZE_BYTES_BCH;
host->ecc_buf_cfg = 0x203 << NUM_STEPS;
host->clrflashstatus = FS_READY_BSY_N;
host->clrreadstatus = 0xc0;
nandc->regs->erased_cw_detect_cfg_clr =
cpu_to_le32(CLR_ERASED_PAGE_DET);
nandc->regs->erased_cw_detect_cfg_set =
cpu_to_le32(SET_ERASED_PAGE_DET);
dev_dbg(nandc->dev,
"cfg0 %x cfg1 %x ecc_buf_cfg %x ecc_bch cfg %x cw_size %d cw_data %d strength %d parity_bytes %d steps %d\n",
host->cfg0, host->cfg1, host->ecc_buf_cfg, host->ecc_bch_cfg,
host->cw_size, host->cw_data, ecc->strength, ecc->bytes,
cwperpage);
return 0;
}
static int qcom_nandc_alloc(struct qcom_nand_controller *nandc)
{
int ret;
ret = dma_set_coherent_mask(nandc->dev, DMA_BIT_MASK(32));
if (ret) {
dev_err(nandc->dev, "failed to set DMA mask\n");
return ret;
}
/*
* we use the internal buffer for reading ONFI params, reading small
* data like ID and status, and preforming read-copy-write operations
* when writing to a codeword partially. 532 is the maximum possible
* size of a codeword for our nand controller
*/
nandc->buf_size = 532;
nandc->data_buffer = devm_kzalloc(nandc->dev, nandc->buf_size,
GFP_KERNEL);
if (!nandc->data_buffer)
return -ENOMEM;
nandc->regs = devm_kzalloc(nandc->dev, sizeof(*nandc->regs),
GFP_KERNEL);
if (!nandc->regs)
return -ENOMEM;
nandc->reg_read_buf = devm_kzalloc(nandc->dev,
MAX_REG_RD * sizeof(*nandc->reg_read_buf),
GFP_KERNEL);
if (!nandc->reg_read_buf)
return -ENOMEM;
if (nandc->props->is_bam) {
nandc->reg_read_dma =
dma_map_single(nandc->dev, nandc->reg_read_buf,
MAX_REG_RD *
sizeof(*nandc->reg_read_buf),
DMA_FROM_DEVICE);
if (dma_mapping_error(nandc->dev, nandc->reg_read_dma)) {
dev_err(nandc->dev, "failed to DMA MAP reg buffer\n");
return -EIO;
}
nandc->tx_chan = dma_request_slave_channel(nandc->dev, "tx");
if (!nandc->tx_chan) {
dev_err(nandc->dev, "failed to request tx channel\n");
return -ENODEV;
}
nandc->rx_chan = dma_request_slave_channel(nandc->dev, "rx");
if (!nandc->rx_chan) {
dev_err(nandc->dev, "failed to request rx channel\n");
return -ENODEV;
}
nandc->cmd_chan = dma_request_slave_channel(nandc->dev, "cmd");
if (!nandc->cmd_chan) {
dev_err(nandc->dev, "failed to request cmd channel\n");
return -ENODEV;
}
/*
* Initially allocate BAM transaction to read ONFI param page.
* After detecting all the devices, this BAM transaction will
* be freed and the next BAM tranasction will be allocated with
* maximum codeword size
*/
nandc->max_cwperpage = 1;
nandc->bam_txn = alloc_bam_transaction(nandc);
if (!nandc->bam_txn) {
dev_err(nandc->dev,
"failed to allocate bam transaction\n");
return -ENOMEM;
}
} else {
nandc->chan = dma_request_slave_channel(nandc->dev, "rxtx");
if (!nandc->chan) {
dev_err(nandc->dev,
"failed to request slave channel\n");
return -ENODEV;
}
}
INIT_LIST_HEAD(&nandc->desc_list);
INIT_LIST_HEAD(&nandc->host_list);
nand_hw_control_init(&nandc->controller);
return 0;
}
static void qcom_nandc_unalloc(struct qcom_nand_controller *nandc)
{
if (nandc->props->is_bam) {
if (!dma_mapping_error(nandc->dev, nandc->reg_read_dma))
dma_unmap_single(nandc->dev, nandc->reg_read_dma,
MAX_REG_RD *
sizeof(*nandc->reg_read_buf),
DMA_FROM_DEVICE);
if (nandc->tx_chan)
dma_release_channel(nandc->tx_chan);
if (nandc->rx_chan)
dma_release_channel(nandc->rx_chan);
if (nandc->cmd_chan)
dma_release_channel(nandc->cmd_chan);
} else {
if (nandc->chan)
dma_release_channel(nandc->chan);
}
}
/* one time setup of a few nand controller registers */
static int qcom_nandc_setup(struct qcom_nand_controller *nandc)
{
u32 nand_ctrl;
/* kill onenand */
nandc_write(nandc, SFLASHC_BURST_CFG, 0);
nandc_write(nandc, dev_cmd_reg_addr(nandc, NAND_DEV_CMD_VLD),
NAND_DEV_CMD_VLD_VAL);
/* enable ADM or BAM DMA */
if (nandc->props->is_bam) {
nand_ctrl = nandc_read(nandc, NAND_CTRL);
nandc_write(nandc, NAND_CTRL, nand_ctrl | BAM_MODE_EN);
} else {
nandc_write(nandc, NAND_FLASH_CHIP_SELECT, DM_EN);
}
/* save the original values of these registers */
nandc->cmd1 = nandc_read(nandc, dev_cmd_reg_addr(nandc, NAND_DEV_CMD1));
nandc->vld = NAND_DEV_CMD_VLD_VAL;
return 0;
}
static int qcom_nand_host_init(struct qcom_nand_controller *nandc,
struct qcom_nand_host *host,
struct device_node *dn)
{
struct nand_chip *chip = &host->chip;
struct mtd_info *mtd = nand_to_mtd(chip);
struct device *dev = nandc->dev;
int ret;
ret = of_property_read_u32(dn, "reg", &host->cs);
if (ret) {
dev_err(dev, "can't get chip-select\n");
return -ENXIO;
}
nand_set_flash_node(chip, dn);
mtd->name = devm_kasprintf(dev, GFP_KERNEL, "qcom_nand.%d", host->cs);
if (!mtd->name)
return -ENOMEM;
mtd->owner = THIS_MODULE;
mtd->dev.parent = dev;
chip->cmdfunc = qcom_nandc_command;
chip->select_chip = qcom_nandc_select_chip;
chip->read_byte = qcom_nandc_read_byte;
chip->read_buf = qcom_nandc_read_buf;
chip->write_buf = qcom_nandc_write_buf;
chip->onfi_set_features = nand_onfi_get_set_features_notsupp;
chip->onfi_get_features = nand_onfi_get_set_features_notsupp;
/*
* the bad block marker is readable only when we read the last codeword
* of a page with ECC disabled. currently, the nand_base and nand_bbt
* helpers don't allow us to read BB from a nand chip with ECC
* disabled (MTD_OPS_PLACE_OOB is set by default). use the block_bad
* and block_markbad helpers until we permanently switch to using
* MTD_OPS_RAW for all drivers (with the help of badblockbits)
*/
chip->block_bad = qcom_nandc_block_bad;
chip->block_markbad = qcom_nandc_block_markbad;
chip->controller = &nandc->controller;
chip->options |= NAND_NO_SUBPAGE_WRITE | NAND_USE_BOUNCE_BUFFER |
NAND_SKIP_BBTSCAN;
/* set up initial status value */
host->status = NAND_STATUS_READY | NAND_STATUS_WP;
ret = nand_scan_ident(mtd, 1, NULL);
if (ret)
return ret;
ret = qcom_nand_host_setup(host);
return ret;
}
static int qcom_nand_mtd_register(struct qcom_nand_controller *nandc,
struct qcom_nand_host *host,
struct device_node *dn)
{
struct nand_chip *chip = &host->chip;
struct mtd_info *mtd = nand_to_mtd(chip);
int ret;
ret = nand_scan_tail(mtd);
if (ret)
return ret;
ret = mtd_device_register(mtd, NULL, 0);
if (ret)
nand_cleanup(mtd_to_nand(mtd));
return ret;
}
static int qcom_probe_nand_devices(struct qcom_nand_controller *nandc)
{
struct device *dev = nandc->dev;
struct device_node *dn = dev->of_node, *child;
struct qcom_nand_host *host, *tmp;
int ret;
for_each_available_child_of_node(dn, child) {
host = devm_kzalloc(dev, sizeof(*host), GFP_KERNEL);
if (!host) {
of_node_put(child);
return -ENOMEM;
}
ret = qcom_nand_host_init(nandc, host, child);
if (ret) {
devm_kfree(dev, host);
continue;
}
list_add_tail(&host->node, &nandc->host_list);
}
if (list_empty(&nandc->host_list))
return -ENODEV;
if (nandc->props->is_bam) {
free_bam_transaction(nandc);
nandc->bam_txn = alloc_bam_transaction(nandc);
if (!nandc->bam_txn) {
dev_err(nandc->dev,
"failed to allocate bam transaction\n");
return -ENOMEM;
}
}
list_for_each_entry_safe(host, tmp, &nandc->host_list, node) {
ret = qcom_nand_mtd_register(nandc, host, child);
if (ret) {
list_del(&host->node);
devm_kfree(dev, host);
}
}
if (list_empty(&nandc->host_list))
return -ENODEV;
return 0;
}
/* parse custom DT properties here */
static int qcom_nandc_parse_dt(struct platform_device *pdev)
{
struct qcom_nand_controller *nandc = platform_get_drvdata(pdev);
struct device_node *np = nandc->dev->of_node;
int ret;
if (!nandc->props->is_bam) {
ret = of_property_read_u32(np, "qcom,cmd-crci",
&nandc->cmd_crci);
if (ret) {
dev_err(nandc->dev, "command CRCI unspecified\n");
return ret;
}
ret = of_property_read_u32(np, "qcom,data-crci",
&nandc->data_crci);
if (ret) {
dev_err(nandc->dev, "data CRCI unspecified\n");
return ret;
}
}
return 0;
}
static int qcom_nandc_probe(struct platform_device *pdev)
{
struct qcom_nand_controller *nandc;
const void *dev_data;
struct device *dev = &pdev->dev;
struct resource *res;
int ret;
nandc = devm_kzalloc(&pdev->dev, sizeof(*nandc), GFP_KERNEL);
if (!nandc)
return -ENOMEM;
platform_set_drvdata(pdev, nandc);
nandc->dev = dev;
dev_data = of_device_get_match_data(dev);
if (!dev_data) {
dev_err(&pdev->dev, "failed to get device data\n");
return -ENODEV;
}
nandc->props = dev_data;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
nandc->base = devm_ioremap_resource(dev, res);
if (IS_ERR(nandc->base))
return PTR_ERR(nandc->base);
nandc->base_phys = res->start;
nandc->base_dma = phys_to_dma(dev, (phys_addr_t)res->start);
nandc->core_clk = devm_clk_get(dev, "core");
if (IS_ERR(nandc->core_clk))
return PTR_ERR(nandc->core_clk);
nandc->aon_clk = devm_clk_get(dev, "aon");
if (IS_ERR(nandc->aon_clk))
return PTR_ERR(nandc->aon_clk);
ret = qcom_nandc_parse_dt(pdev);
if (ret)
return ret;
ret = qcom_nandc_alloc(nandc);
if (ret)
goto err_core_clk;
ret = clk_prepare_enable(nandc->core_clk);
if (ret)
goto err_core_clk;
ret = clk_prepare_enable(nandc->aon_clk);
if (ret)
goto err_aon_clk;
ret = qcom_nandc_setup(nandc);
if (ret)
goto err_setup;
ret = qcom_probe_nand_devices(nandc);
if (ret)
goto err_setup;
return 0;
err_setup:
clk_disable_unprepare(nandc->aon_clk);
err_aon_clk:
clk_disable_unprepare(nandc->core_clk);
err_core_clk:
qcom_nandc_unalloc(nandc);
return ret;
}
static int qcom_nandc_remove(struct platform_device *pdev)
{
struct qcom_nand_controller *nandc = platform_get_drvdata(pdev);
struct qcom_nand_host *host;
list_for_each_entry(host, &nandc->host_list, node)
nand_release(nand_to_mtd(&host->chip));
qcom_nandc_unalloc(nandc);
clk_disable_unprepare(nandc->aon_clk);
clk_disable_unprepare(nandc->core_clk);
return 0;
}
static const struct qcom_nandc_props ipq806x_nandc_props = {
.ecc_modes = (ECC_RS_4BIT | ECC_BCH_8BIT),
.is_bam = false,
.dev_cmd_reg_start = 0x0,
};
static const struct qcom_nandc_props ipq4019_nandc_props = {
.ecc_modes = (ECC_BCH_4BIT | ECC_BCH_8BIT),
.is_bam = true,
.dev_cmd_reg_start = 0x0,
};
static const struct qcom_nandc_props ipq8074_nandc_props = {
.ecc_modes = (ECC_BCH_4BIT | ECC_BCH_8BIT),
.is_bam = true,
.dev_cmd_reg_start = 0x7000,
};
/*
* data will hold a struct pointer containing more differences once we support
* more controller variants
*/
static const struct of_device_id qcom_nandc_of_match[] = {
{
.compatible = "qcom,ipq806x-nand",
.data = &ipq806x_nandc_props,
},
{
.compatible = "qcom,ipq4019-nand",
.data = &ipq4019_nandc_props,
},
{
.compatible = "qcom,ipq8074-nand",
.data = &ipq8074_nandc_props,
},
{}
};
MODULE_DEVICE_TABLE(of, qcom_nandc_of_match);
static struct platform_driver qcom_nandc_driver = {
.driver = {
.name = "qcom-nandc",
.of_match_table = qcom_nandc_of_match,
},
.probe = qcom_nandc_probe,
.remove = qcom_nandc_remove,
};
module_platform_driver(qcom_nandc_driver);
MODULE_AUTHOR("Archit Taneja <architt@codeaurora.org>");
MODULE_DESCRIPTION("Qualcomm NAND Controller driver");
MODULE_LICENSE("GPL v2");