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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-27 10:05:51 +0000
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+=====================================
+MTD NAND Driver Programming Interface
+=====================================
+
+:Author: Thomas Gleixner
+
+Introduction
+============
+
+The generic NAND driver supports almost all NAND and AG-AND based chips
+and connects them to the Memory Technology Devices (MTD) subsystem of
+the Linux Kernel.
+
+This documentation is provided for developers who want to implement
+board drivers or filesystem drivers suitable for NAND devices.
+
+Known Bugs And Assumptions
+==========================
+
+None.
+
+Documentation hints
+===================
+
+The function and structure docs are autogenerated. Each function and
+struct member has a short description which is marked with an [XXX]
+identifier. The following chapters explain the meaning of those
+identifiers.
+
+Function identifiers [XXX]
+--------------------------
+
+The functions are marked with [XXX] identifiers in the short comment.
+The identifiers explain the usage and scope of the functions. Following
+identifiers are used:
+
+- [MTD Interface]
+
+ These functions provide the interface to the MTD kernel API. They are
+ not replaceable and provide functionality which is complete hardware
+ independent.
+
+- [NAND Interface]
+
+ These functions are exported and provide the interface to the NAND
+ kernel API.
+
+- [GENERIC]
+
+ Generic functions are not replaceable and provide functionality which
+ is complete hardware independent.
+
+- [DEFAULT]
+
+ Default functions provide hardware related functionality which is
+ suitable for most of the implementations. These functions can be
+ replaced by the board driver if necessary. Those functions are called
+ via pointers in the NAND chip description structure. The board driver
+ can set the functions which should be replaced by board dependent
+ functions before calling nand_scan(). If the function pointer is
+ NULL on entry to nand_scan() then the pointer is set to the default
+ function which is suitable for the detected chip type.
+
+Struct member identifiers [XXX]
+-------------------------------
+
+The struct members are marked with [XXX] identifiers in the comment. The
+identifiers explain the usage and scope of the members. Following
+identifiers are used:
+
+- [INTERN]
+
+ These members are for NAND driver internal use only and must not be
+ modified. Most of these values are calculated from the chip geometry
+ information which is evaluated during nand_scan().
+
+- [REPLACEABLE]
+
+ Replaceable members hold hardware related functions which can be
+ provided by the board driver. The board driver can set the functions
+ which should be replaced by board dependent functions before calling
+ nand_scan(). If the function pointer is NULL on entry to
+ nand_scan() then the pointer is set to the default function which is
+ suitable for the detected chip type.
+
+- [BOARDSPECIFIC]
+
+ Board specific members hold hardware related information which must
+ be provided by the board driver. The board driver must set the
+ function pointers and datafields before calling nand_scan().
+
+- [OPTIONAL]
+
+ Optional members can hold information relevant for the board driver.
+ The generic NAND driver code does not use this information.
+
+Basic board driver
+==================
+
+For most boards it will be sufficient to provide just the basic
+functions and fill out some really board dependent members in the nand
+chip description structure.
+
+Basic defines
+-------------
+
+At least you have to provide a nand_chip structure and a storage for
+the ioremap'ed chip address. You can allocate the nand_chip structure
+using kmalloc or you can allocate it statically. The NAND chip structure
+embeds an mtd structure which will be registered to the MTD subsystem.
+You can extract a pointer to the mtd structure from a nand_chip pointer
+using the nand_to_mtd() helper.
+
+Kmalloc based example
+
+::
+
+ static struct mtd_info *board_mtd;
+ static void __iomem *baseaddr;
+
+
+Static example
+
+::
+
+ static struct nand_chip board_chip;
+ static void __iomem *baseaddr;
+
+
+Partition defines
+-----------------
+
+If you want to divide your device into partitions, then define a
+partitioning scheme suitable to your board.
+
+::
+
+ #define NUM_PARTITIONS 2
+ static struct mtd_partition partition_info[] = {
+ { .name = "Flash partition 1",
+ .offset = 0,
+ .size = 8 * 1024 * 1024 },
+ { .name = "Flash partition 2",
+ .offset = MTDPART_OFS_NEXT,
+ .size = MTDPART_SIZ_FULL },
+ };
+
+
+Hardware control function
+-------------------------
+
+The hardware control function provides access to the control pins of the
+NAND chip(s). The access can be done by GPIO pins or by address lines.
+If you use address lines, make sure that the timing requirements are
+met.
+
+*GPIO based example*
+
+::
+
+ static void board_hwcontrol(struct mtd_info *mtd, int cmd)
+ {
+ switch(cmd){
+ case NAND_CTL_SETCLE: /* Set CLE pin high */ break;
+ case NAND_CTL_CLRCLE: /* Set CLE pin low */ break;
+ case NAND_CTL_SETALE: /* Set ALE pin high */ break;
+ case NAND_CTL_CLRALE: /* Set ALE pin low */ break;
+ case NAND_CTL_SETNCE: /* Set nCE pin low */ break;
+ case NAND_CTL_CLRNCE: /* Set nCE pin high */ break;
+ }
+ }
+
+
+*Address lines based example.* It's assumed that the nCE pin is driven
+by a chip select decoder.
+
+::
+
+ static void board_hwcontrol(struct mtd_info *mtd, int cmd)
+ {
+ struct nand_chip *this = mtd_to_nand(mtd);
+ switch(cmd){
+ case NAND_CTL_SETCLE: this->legacy.IO_ADDR_W |= CLE_ADRR_BIT; break;
+ case NAND_CTL_CLRCLE: this->legacy.IO_ADDR_W &= ~CLE_ADRR_BIT; break;
+ case NAND_CTL_SETALE: this->legacy.IO_ADDR_W |= ALE_ADRR_BIT; break;
+ case NAND_CTL_CLRALE: this->legacy.IO_ADDR_W &= ~ALE_ADRR_BIT; break;
+ }
+ }
+
+
+Device ready function
+---------------------
+
+If the hardware interface has the ready busy pin of the NAND chip
+connected to a GPIO or other accessible I/O pin, this function is used
+to read back the state of the pin. The function has no arguments and
+should return 0, if the device is busy (R/B pin is low) and 1, if the
+device is ready (R/B pin is high). If the hardware interface does not
+give access to the ready busy pin, then the function must not be defined
+and the function pointer this->legacy.dev_ready is set to NULL.
+
+Init function
+-------------
+
+The init function allocates memory and sets up all the board specific
+parameters and function pointers. When everything is set up nand_scan()
+is called. This function tries to detect and identify then chip. If a
+chip is found all the internal data fields are initialized accordingly.
+The structure(s) have to be zeroed out first and then filled with the
+necessary information about the device.
+
+::
+
+ static int __init board_init (void)
+ {
+ struct nand_chip *this;
+ int err = 0;
+
+ /* Allocate memory for MTD device structure and private data */
+ this = kzalloc(sizeof(struct nand_chip), GFP_KERNEL);
+ if (!this) {
+ printk ("Unable to allocate NAND MTD device structure.\n");
+ err = -ENOMEM;
+ goto out;
+ }
+
+ board_mtd = nand_to_mtd(this);
+
+ /* map physical address */
+ baseaddr = ioremap(CHIP_PHYSICAL_ADDRESS, 1024);
+ if (!baseaddr) {
+ printk("Ioremap to access NAND chip failed\n");
+ err = -EIO;
+ goto out_mtd;
+ }
+
+ /* Set address of NAND IO lines */
+ this->legacy.IO_ADDR_R = baseaddr;
+ this->legacy.IO_ADDR_W = baseaddr;
+ /* Reference hardware control function */
+ this->hwcontrol = board_hwcontrol;
+ /* Set command delay time, see datasheet for correct value */
+ this->legacy.chip_delay = CHIP_DEPENDEND_COMMAND_DELAY;
+ /* Assign the device ready function, if available */
+ this->legacy.dev_ready = board_dev_ready;
+ this->eccmode = NAND_ECC_SOFT;
+
+ /* Scan to find existence of the device */
+ if (nand_scan (this, 1)) {
+ err = -ENXIO;
+ goto out_ior;
+ }
+
+ add_mtd_partitions(board_mtd, partition_info, NUM_PARTITIONS);
+ goto out;
+
+ out_ior:
+ iounmap(baseaddr);
+ out_mtd:
+ kfree (this);
+ out:
+ return err;
+ }
+ module_init(board_init);
+
+
+Exit function
+-------------
+
+The exit function is only necessary if the driver is compiled as a
+module. It releases all resources which are held by the chip driver and
+unregisters the partitions in the MTD layer.
+
+::
+
+ #ifdef MODULE
+ static void __exit board_cleanup (void)
+ {
+ /* Unregister device */
+ WARN_ON(mtd_device_unregister(board_mtd));
+ /* Release resources */
+ nand_cleanup(mtd_to_nand(board_mtd));
+
+ /* unmap physical address */
+ iounmap(baseaddr);
+
+ /* Free the MTD device structure */
+ kfree (mtd_to_nand(board_mtd));
+ }
+ module_exit(board_cleanup);
+ #endif
+
+
+Advanced board driver functions
+===============================
+
+This chapter describes the advanced functionality of the NAND driver.
+For a list of functions which can be overridden by the board driver see
+the documentation of the nand_chip structure.
+
+Multiple chip control
+---------------------
+
+The nand driver can control chip arrays. Therefore the board driver must
+provide an own select_chip function. This function must (de)select the
+requested chip. The function pointer in the nand_chip structure must be
+set before calling nand_scan(). The maxchip parameter of nand_scan()
+defines the maximum number of chips to scan for. Make sure that the
+select_chip function can handle the requested number of chips.
+
+The nand driver concatenates the chips to one virtual chip and provides
+this virtual chip to the MTD layer.
+
+*Note: The driver can only handle linear chip arrays of equally sized
+chips. There is no support for parallel arrays which extend the
+buswidth.*
+
+*GPIO based example*
+
+::
+
+ static void board_select_chip (struct mtd_info *mtd, int chip)
+ {
+ /* Deselect all chips, set all nCE pins high */
+ GPIO(BOARD_NAND_NCE) |= 0xff;
+ if (chip >= 0)
+ GPIO(BOARD_NAND_NCE) &= ~ (1 << chip);
+ }
+
+
+*Address lines based example.* Its assumed that the nCE pins are
+connected to an address decoder.
+
+::
+
+ static void board_select_chip (struct mtd_info *mtd, int chip)
+ {
+ struct nand_chip *this = mtd_to_nand(mtd);
+
+ /* Deselect all chips */
+ this->legacy.IO_ADDR_R &= ~BOARD_NAND_ADDR_MASK;
+ this->legacy.IO_ADDR_W &= ~BOARD_NAND_ADDR_MASK;
+ switch (chip) {
+ case 0:
+ this->legacy.IO_ADDR_R |= BOARD_NAND_ADDR_CHIP0;
+ this->legacy.IO_ADDR_W |= BOARD_NAND_ADDR_CHIP0;
+ break;
+ ....
+ case n:
+ this->legacy.IO_ADDR_R |= BOARD_NAND_ADDR_CHIPn;
+ this->legacy.IO_ADDR_W |= BOARD_NAND_ADDR_CHIPn;
+ break;
+ }
+ }
+
+
+Hardware ECC support
+--------------------
+
+Functions and constants
+~~~~~~~~~~~~~~~~~~~~~~~
+
+The nand driver supports three different types of hardware ECC.
+
+- NAND_ECC_HW3_256
+
+ Hardware ECC generator providing 3 bytes ECC per 256 byte.
+
+- NAND_ECC_HW3_512
+
+ Hardware ECC generator providing 3 bytes ECC per 512 byte.
+
+- NAND_ECC_HW6_512
+
+ Hardware ECC generator providing 6 bytes ECC per 512 byte.
+
+- NAND_ECC_HW8_512
+
+ Hardware ECC generator providing 8 bytes ECC per 512 byte.
+
+If your hardware generator has a different functionality add it at the
+appropriate place in nand_base.c
+
+The board driver must provide following functions:
+
+- enable_hwecc
+
+ This function is called before reading / writing to the chip. Reset
+ or initialize the hardware generator in this function. The function
+ is called with an argument which let you distinguish between read and
+ write operations.
+
+- calculate_ecc
+
+ This function is called after read / write from / to the chip.
+ Transfer the ECC from the hardware to the buffer. If the option
+ NAND_HWECC_SYNDROME is set then the function is only called on
+ write. See below.
+
+- correct_data
+
+ In case of an ECC error this function is called for error detection
+ and correction. Return 1 respectively 2 in case the error can be
+ corrected. If the error is not correctable return -1. If your
+ hardware generator matches the default algorithm of the nand_ecc
+ software generator then use the correction function provided by
+ nand_ecc instead of implementing duplicated code.
+
+Hardware ECC with syndrome calculation
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Many hardware ECC implementations provide Reed-Solomon codes and
+calculate an error syndrome on read. The syndrome must be converted to a
+standard Reed-Solomon syndrome before calling the error correction code
+in the generic Reed-Solomon library.
+
+The ECC bytes must be placed immediately after the data bytes in order
+to make the syndrome generator work. This is contrary to the usual
+layout used by software ECC. The separation of data and out of band area
+is not longer possible. The nand driver code handles this layout and the
+remaining free bytes in the oob area are managed by the autoplacement
+code. Provide a matching oob-layout in this case. See rts_from4.c and
+diskonchip.c for implementation reference. In those cases we must also
+use bad block tables on FLASH, because the ECC layout is interfering
+with the bad block marker positions. See bad block table support for
+details.
+
+Bad block table support
+-----------------------
+
+Most NAND chips mark the bad blocks at a defined position in the spare
+area. Those blocks must not be erased under any circumstances as the bad
+block information would be lost. It is possible to check the bad block
+mark each time when the blocks are accessed by reading the spare area of
+the first page in the block. This is time consuming so a bad block table
+is used.
+
+The nand driver supports various types of bad block tables.
+
+- Per device
+
+ The bad block table contains all bad block information of the device
+ which can consist of multiple chips.
+
+- Per chip
+
+ A bad block table is used per chip and contains the bad block
+ information for this particular chip.
+
+- Fixed offset
+
+ The bad block table is located at a fixed offset in the chip
+ (device). This applies to various DiskOnChip devices.
+
+- Automatic placed
+
+ The bad block table is automatically placed and detected either at
+ the end or at the beginning of a chip (device)
+
+- Mirrored tables
+
+ The bad block table is mirrored on the chip (device) to allow updates
+ of the bad block table without data loss.
+
+nand_scan() calls the function nand_default_bbt().
+nand_default_bbt() selects appropriate default bad block table
+descriptors depending on the chip information which was retrieved by
+nand_scan().
+
+The standard policy is scanning the device for bad blocks and build a
+ram based bad block table which allows faster access than always
+checking the bad block information on the flash chip itself.
+
+Flash based tables
+~~~~~~~~~~~~~~~~~~
+
+It may be desired or necessary to keep a bad block table in FLASH. For
+AG-AND chips this is mandatory, as they have no factory marked bad
+blocks. They have factory marked good blocks. The marker pattern is
+erased when the block is erased to be reused. So in case of powerloss
+before writing the pattern back to the chip this block would be lost and
+added to the bad blocks. Therefore we scan the chip(s) when we detect
+them the first time for good blocks and store this information in a bad
+block table before erasing any of the blocks.
+
+The blocks in which the tables are stored are protected against
+accidental access by marking them bad in the memory bad block table. The
+bad block table management functions are allowed to circumvent this
+protection.
+
+The simplest way to activate the FLASH based bad block table support is
+to set the option NAND_BBT_USE_FLASH in the bbt_option field of the
+nand chip structure before calling nand_scan(). For AG-AND chips is
+this done by default. This activates the default FLASH based bad block
+table functionality of the NAND driver. The default bad block table
+options are
+
+- Store bad block table per chip
+
+- Use 2 bits per block
+
+- Automatic placement at the end of the chip
+
+- Use mirrored tables with version numbers
+
+- Reserve 4 blocks at the end of the chip
+
+User defined tables
+~~~~~~~~~~~~~~~~~~~
+
+User defined tables are created by filling out a nand_bbt_descr
+structure and storing the pointer in the nand_chip structure member
+bbt_td before calling nand_scan(). If a mirror table is necessary a
+second structure must be created and a pointer to this structure must be
+stored in bbt_md inside the nand_chip structure. If the bbt_md member
+is set to NULL then only the main table is used and no scan for the
+mirrored table is performed.
+
+The most important field in the nand_bbt_descr structure is the
+options field. The options define most of the table properties. Use the
+predefined constants from rawnand.h to define the options.
+
+- Number of bits per block
+
+ The supported number of bits is 1, 2, 4, 8.
+
+- Table per chip
+
+ Setting the constant NAND_BBT_PERCHIP selects that a bad block
+ table is managed for each chip in a chip array. If this option is not
+ set then a per device bad block table is used.
+
+- Table location is absolute
+
+ Use the option constant NAND_BBT_ABSPAGE and define the absolute
+ page number where the bad block table starts in the field pages. If
+ you have selected bad block tables per chip and you have a multi chip
+ array then the start page must be given for each chip in the chip
+ array. Note: there is no scan for a table ident pattern performed, so
+ the fields pattern, veroffs, offs, len can be left uninitialized
+
+- Table location is automatically detected
+
+ The table can either be located in the first or the last good blocks
+ of the chip (device). Set NAND_BBT_LASTBLOCK to place the bad block
+ table at the end of the chip (device). The bad block tables are
+ marked and identified by a pattern which is stored in the spare area
+ of the first page in the block which holds the bad block table. Store
+ a pointer to the pattern in the pattern field. Further the length of
+ the pattern has to be stored in len and the offset in the spare area
+ must be given in the offs member of the nand_bbt_descr structure.
+ For mirrored bad block tables different patterns are mandatory.
+
+- Table creation
+
+ Set the option NAND_BBT_CREATE to enable the table creation if no
+ table can be found during the scan. Usually this is done only once if
+ a new chip is found.
+
+- Table write support
+
+ Set the option NAND_BBT_WRITE to enable the table write support.
+ This allows the update of the bad block table(s) in case a block has
+ to be marked bad due to wear. The MTD interface function
+ block_markbad is calling the update function of the bad block table.
+ If the write support is enabled then the table is updated on FLASH.
+
+ Note: Write support should only be enabled for mirrored tables with
+ version control.
+
+- Table version control
+
+ Set the option NAND_BBT_VERSION to enable the table version
+ control. It's highly recommended to enable this for mirrored tables
+ with write support. It makes sure that the risk of losing the bad
+ block table information is reduced to the loss of the information
+ about the one worn out block which should be marked bad. The version
+ is stored in 4 consecutive bytes in the spare area of the device. The
+ position of the version number is defined by the member veroffs in
+ the bad block table descriptor.
+
+- Save block contents on write
+
+ In case that the block which holds the bad block table does contain
+ other useful information, set the option NAND_BBT_SAVECONTENT. When
+ the bad block table is written then the whole block is read the bad
+ block table is updated and the block is erased and everything is
+ written back. If this option is not set only the bad block table is
+ written and everything else in the block is ignored and erased.
+
+- Number of reserved blocks
+
+ For automatic placement some blocks must be reserved for bad block
+ table storage. The number of reserved blocks is defined in the
+ maxblocks member of the bad block table description structure.
+ Reserving 4 blocks for mirrored tables should be a reasonable number.
+ This also limits the number of blocks which are scanned for the bad
+ block table ident pattern.
+
+Spare area (auto)placement
+--------------------------
+
+The nand driver implements different possibilities for placement of
+filesystem data in the spare area,
+
+- Placement defined by fs driver
+
+- Automatic placement
+
+The default placement function is automatic placement. The nand driver
+has built in default placement schemes for the various chiptypes. If due
+to hardware ECC functionality the default placement does not fit then
+the board driver can provide a own placement scheme.
+
+File system drivers can provide a own placement scheme which is used
+instead of the default placement scheme.
+
+Placement schemes are defined by a nand_oobinfo structure
+
+::
+
+ struct nand_oobinfo {
+ int useecc;
+ int eccbytes;
+ int eccpos[24];
+ int oobfree[8][2];
+ };
+
+
+- useecc
+
+ The useecc member controls the ecc and placement function. The header
+ file include/mtd/mtd-abi.h contains constants to select ecc and
+ placement. MTD_NANDECC_OFF switches off the ecc complete. This is
+ not recommended and available for testing and diagnosis only.
+ MTD_NANDECC_PLACE selects caller defined placement,
+ MTD_NANDECC_AUTOPLACE selects automatic placement.
+
+- eccbytes
+
+ The eccbytes member defines the number of ecc bytes per page.
+
+- eccpos
+
+ The eccpos array holds the byte offsets in the spare area where the
+ ecc codes are placed.
+
+- oobfree
+
+ The oobfree array defines the areas in the spare area which can be
+ used for automatic placement. The information is given in the format
+ {offset, size}. offset defines the start of the usable area, size the
+ length in bytes. More than one area can be defined. The list is
+ terminated by an {0, 0} entry.
+
+Placement defined by fs driver
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The calling function provides a pointer to a nand_oobinfo structure
+which defines the ecc placement. For writes the caller must provide a
+spare area buffer along with the data buffer. The spare area buffer size
+is (number of pages) \* (size of spare area). For reads the buffer size
+is (number of pages) \* ((size of spare area) + (number of ecc steps per
+page) \* sizeof (int)). The driver stores the result of the ecc check
+for each tuple in the spare buffer. The storage sequence is::
+
+ <spare data page 0><ecc result 0>...<ecc result n>
+
+ ...
+
+ <spare data page n><ecc result 0>...<ecc result n>
+
+This is a legacy mode used by YAFFS1.
+
+If the spare area buffer is NULL then only the ECC placement is done
+according to the given scheme in the nand_oobinfo structure.
+
+Automatic placement
+~~~~~~~~~~~~~~~~~~~
+
+Automatic placement uses the built in defaults to place the ecc bytes in
+the spare area. If filesystem data have to be stored / read into the
+spare area then the calling function must provide a buffer. The buffer
+size per page is determined by the oobfree array in the nand_oobinfo
+structure.
+
+If the spare area buffer is NULL then only the ECC placement is done
+according to the default builtin scheme.
+
+Spare area autoplacement default schemes
+----------------------------------------
+
+256 byte pagesize
+~~~~~~~~~~~~~~~~~
+
+======== ================== ===================================================
+Offset Content Comment
+======== ================== ===================================================
+0x00 ECC byte 0 Error correction code byte 0
+0x01 ECC byte 1 Error correction code byte 1
+0x02 ECC byte 2 Error correction code byte 2
+0x03 Autoplace 0
+0x04 Autoplace 1
+0x05 Bad block marker If any bit in this byte is zero, then this
+ block is bad. This applies only to the first
+ page in a block. In the remaining pages this
+ byte is reserved
+0x06 Autoplace 2
+0x07 Autoplace 3
+======== ================== ===================================================
+
+512 byte pagesize
+~~~~~~~~~~~~~~~~~
+
+
+============= ================== ==============================================
+Offset Content Comment
+============= ================== ==============================================
+0x00 ECC byte 0 Error correction code byte 0 of the lower
+ 256 Byte data in this page
+0x01 ECC byte 1 Error correction code byte 1 of the lower
+ 256 Bytes of data in this page
+0x02 ECC byte 2 Error correction code byte 2 of the lower
+ 256 Bytes of data in this page
+0x03 ECC byte 3 Error correction code byte 0 of the upper
+ 256 Bytes of data in this page
+0x04 reserved reserved
+0x05 Bad block marker If any bit in this byte is zero, then this
+ block is bad. This applies only to the first
+ page in a block. In the remaining pages this
+ byte is reserved
+0x06 ECC byte 4 Error correction code byte 1 of the upper
+ 256 Bytes of data in this page
+0x07 ECC byte 5 Error correction code byte 2 of the upper
+ 256 Bytes of data in this page
+0x08 - 0x0F Autoplace 0 - 7
+============= ================== ==============================================
+
+2048 byte pagesize
+~~~~~~~~~~~~~~~~~~
+
+=========== ================== ================================================
+Offset Content Comment
+=========== ================== ================================================
+0x00 Bad block marker If any bit in this byte is zero, then this block
+ is bad. This applies only to the first page in a
+ block. In the remaining pages this byte is
+ reserved
+0x01 Reserved Reserved
+0x02-0x27 Autoplace 0 - 37
+0x28 ECC byte 0 Error correction code byte 0 of the first
+ 256 Byte data in this page
+0x29 ECC byte 1 Error correction code byte 1 of the first
+ 256 Bytes of data in this page
+0x2A ECC byte 2 Error correction code byte 2 of the first
+ 256 Bytes data in this page
+0x2B ECC byte 3 Error correction code byte 0 of the second
+ 256 Bytes of data in this page
+0x2C ECC byte 4 Error correction code byte 1 of the second
+ 256 Bytes of data in this page
+0x2D ECC byte 5 Error correction code byte 2 of the second
+ 256 Bytes of data in this page
+0x2E ECC byte 6 Error correction code byte 0 of the third
+ 256 Bytes of data in this page
+0x2F ECC byte 7 Error correction code byte 1 of the third
+ 256 Bytes of data in this page
+0x30 ECC byte 8 Error correction code byte 2 of the third
+ 256 Bytes of data in this page
+0x31 ECC byte 9 Error correction code byte 0 of the fourth
+ 256 Bytes of data in this page
+0x32 ECC byte 10 Error correction code byte 1 of the fourth
+ 256 Bytes of data in this page
+0x33 ECC byte 11 Error correction code byte 2 of the fourth
+ 256 Bytes of data in this page
+0x34 ECC byte 12 Error correction code byte 0 of the fifth
+ 256 Bytes of data in this page
+0x35 ECC byte 13 Error correction code byte 1 of the fifth
+ 256 Bytes of data in this page
+0x36 ECC byte 14 Error correction code byte 2 of the fifth
+ 256 Bytes of data in this page
+0x37 ECC byte 15 Error correction code byte 0 of the sixth
+ 256 Bytes of data in this page
+0x38 ECC byte 16 Error correction code byte 1 of the sixth
+ 256 Bytes of data in this page
+0x39 ECC byte 17 Error correction code byte 2 of the sixth
+ 256 Bytes of data in this page
+0x3A ECC byte 18 Error correction code byte 0 of the seventh
+ 256 Bytes of data in this page
+0x3B ECC byte 19 Error correction code byte 1 of the seventh
+ 256 Bytes of data in this page
+0x3C ECC byte 20 Error correction code byte 2 of the seventh
+ 256 Bytes of data in this page
+0x3D ECC byte 21 Error correction code byte 0 of the eighth
+ 256 Bytes of data in this page
+0x3E ECC byte 22 Error correction code byte 1 of the eighth
+ 256 Bytes of data in this page
+0x3F ECC byte 23 Error correction code byte 2 of the eighth
+ 256 Bytes of data in this page
+=========== ================== ================================================
+
+Filesystem support
+==================
+
+The NAND driver provides all necessary functions for a filesystem via
+the MTD interface.
+
+Filesystems must be aware of the NAND peculiarities and restrictions.
+One major restrictions of NAND Flash is, that you cannot write as often
+as you want to a page. The consecutive writes to a page, before erasing
+it again, are restricted to 1-3 writes, depending on the manufacturers
+specifications. This applies similar to the spare area.
+
+Therefore NAND aware filesystems must either write in page size chunks
+or hold a writebuffer to collect smaller writes until they sum up to
+pagesize. Available NAND aware filesystems: JFFS2, YAFFS.
+
+The spare area usage to store filesystem data is controlled by the spare
+area placement functionality which is described in one of the earlier
+chapters.
+
+Tools
+=====
+
+The MTD project provides a couple of helpful tools to handle NAND Flash.
+
+- flasherase, flasheraseall: Erase and format FLASH partitions
+
+- nandwrite: write filesystem images to NAND FLASH
+
+- nanddump: dump the contents of a NAND FLASH partitions
+
+These tools are aware of the NAND restrictions. Please use those tools
+instead of complaining about errors which are caused by non NAND aware
+access methods.
+
+Constants
+=========
+
+This chapter describes the constants which might be relevant for a
+driver developer.
+
+Chip option constants
+---------------------
+
+Constants for chip id table
+~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+These constants are defined in rawnand.h. They are OR-ed together to
+describe the chip functionality::
+
+ /* Buswitdh is 16 bit */
+ #define NAND_BUSWIDTH_16 0x00000002
+ /* Device supports partial programming without padding */
+ #define NAND_NO_PADDING 0x00000004
+ /* Chip has cache program function */
+ #define NAND_CACHEPRG 0x00000008
+ /* Chip has copy back function */
+ #define NAND_COPYBACK 0x00000010
+ /* AND Chip which has 4 banks and a confusing page / block
+ * assignment. See Renesas datasheet for further information */
+ #define NAND_IS_AND 0x00000020
+ /* Chip has a array of 4 pages which can be read without
+ * additional ready /busy waits */
+ #define NAND_4PAGE_ARRAY 0x00000040
+
+
+Constants for runtime options
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+These constants are defined in rawnand.h. They are OR-ed together to
+describe the functionality::
+
+ /* The hw ecc generator provides a syndrome instead a ecc value on read
+ * This can only work if we have the ecc bytes directly behind the
+ * data bytes. Applies for DOC and AG-AND Renesas HW Reed Solomon generators */
+ #define NAND_HWECC_SYNDROME 0x00020000
+
+
+ECC selection constants
+-----------------------
+
+Use these constants to select the ECC algorithm::
+
+ /* No ECC. Usage is not recommended ! */
+ #define NAND_ECC_NONE 0
+ /* Software ECC 3 byte ECC per 256 Byte data */
+ #define NAND_ECC_SOFT 1
+ /* Hardware ECC 3 byte ECC per 256 Byte data */
+ #define NAND_ECC_HW3_256 2
+ /* Hardware ECC 3 byte ECC per 512 Byte data */
+ #define NAND_ECC_HW3_512 3
+ /* Hardware ECC 6 byte ECC per 512 Byte data */
+ #define NAND_ECC_HW6_512 4
+ /* Hardware ECC 8 byte ECC per 512 Byte data */
+ #define NAND_ECC_HW8_512 6
+
+
+Hardware control related constants
+----------------------------------
+
+These constants describe the requested hardware access function when the
+boardspecific hardware control function is called::
+
+ /* Select the chip by setting nCE to low */
+ #define NAND_CTL_SETNCE 1
+ /* Deselect the chip by setting nCE to high */
+ #define NAND_CTL_CLRNCE 2
+ /* Select the command latch by setting CLE to high */
+ #define NAND_CTL_SETCLE 3
+ /* Deselect the command latch by setting CLE to low */
+ #define NAND_CTL_CLRCLE 4
+ /* Select the address latch by setting ALE to high */
+ #define NAND_CTL_SETALE 5
+ /* Deselect the address latch by setting ALE to low */
+ #define NAND_CTL_CLRALE 6
+ /* Set write protection by setting WP to high. Not used! */
+ #define NAND_CTL_SETWP 7
+ /* Clear write protection by setting WP to low. Not used! */
+ #define NAND_CTL_CLRWP 8
+
+
+Bad block table related constants
+---------------------------------
+
+These constants describe the options used for bad block table
+descriptors::
+
+ /* Options for the bad block table descriptors */
+
+ /* The number of bits used per block in the bbt on the device */
+ #define NAND_BBT_NRBITS_MSK 0x0000000F
+ #define NAND_BBT_1BIT 0x00000001
+ #define NAND_BBT_2BIT 0x00000002
+ #define NAND_BBT_4BIT 0x00000004
+ #define NAND_BBT_8BIT 0x00000008
+ /* The bad block table is in the last good block of the device */
+ #define NAND_BBT_LASTBLOCK 0x00000010
+ /* The bbt is at the given page, else we must scan for the bbt */
+ #define NAND_BBT_ABSPAGE 0x00000020
+ /* bbt is stored per chip on multichip devices */
+ #define NAND_BBT_PERCHIP 0x00000080
+ /* bbt has a version counter at offset veroffs */
+ #define NAND_BBT_VERSION 0x00000100
+ /* Create a bbt if none axists */
+ #define NAND_BBT_CREATE 0x00000200
+ /* Write bbt if necessary */
+ #define NAND_BBT_WRITE 0x00001000
+ /* Read and write back block contents when writing bbt */
+ #define NAND_BBT_SAVECONTENT 0x00002000
+
+
+Structures
+==========
+
+This chapter contains the autogenerated documentation of the structures
+which are used in the NAND driver and might be relevant for a driver
+developer. Each struct member has a short description which is marked
+with an [XXX] identifier. See the chapter "Documentation hints" for an
+explanation.
+
+.. kernel-doc:: include/linux/mtd/rawnand.h
+ :internal:
+
+Public Functions Provided
+=========================
+
+This chapter contains the autogenerated documentation of the NAND kernel
+API functions which are exported. Each function has a short description
+which is marked with an [XXX] identifier. See the chapter "Documentation
+hints" for an explanation.
+
+.. kernel-doc:: drivers/mtd/nand/raw/nand_base.c
+ :export:
+
+.. kernel-doc:: drivers/mtd/nand/raw/nand_ecc.c
+ :export:
+
+Internal Functions Provided
+===========================
+
+This chapter contains the autogenerated documentation of the NAND driver
+internal functions. Each function has a short description which is
+marked with an [XXX] identifier. See the chapter "Documentation hints"
+for an explanation. The functions marked with [DEFAULT] might be
+relevant for a board driver developer.
+
+.. kernel-doc:: drivers/mtd/nand/raw/nand_base.c
+ :internal:
+
+.. kernel-doc:: drivers/mtd/nand/raw/nand_bbt.c
+ :internal:
+
+Credits
+=======
+
+The following people have contributed to the NAND driver:
+
+1. Steven J. Hill\ sjhill@realitydiluted.com
+
+2. David Woodhouse\ dwmw2@infradead.org
+
+3. Thomas Gleixner\ tglx@linutronix.de
+
+A lot of users have provided bugfixes, improvements and helping hands
+for testing. Thanks a lot.
+
+The following people have contributed to this document:
+
+1. Thomas Gleixner\ tglx@linutronix.de