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- .TH FLASH 3
- .SH NAME
- flash \- flash memory
- .SH SYNOPSYS
- .nf
- .BI "bind -a #F" \fR[\fPn\fR]\fP " /dev"
- .sp 0.3v
- .B /dev/flash
- .BI /dev/flash/ part
- .BI /dev/flash/ part ctl
- .fi
- .SH DESCRIPTION
- The flash memory device serves a two-level directory,
- giving access to files representing part or all of a bank of flash memory.
- A platform might have more than one bank of flash, numbered starting from 0.
- The attach specifier
- .I n
- is a decimal integer that selects a particular bank of flash (default: 0).
- Both NOR and NAND flash is supported.
- For both types of flash,
- the driver gives a read/write/erase interface to the raw flash device,
- which can impose constraints on operations beyond those imposed by the driver.
- Other drivers such as
- .IR ftl (3)
- or
- .IR logfs (3)
- implement any higher-level format required,
- including ECC for NAND flash, for instance.
- .PP
- The top level directory contains a single directory named
- .B flash
- for bank 0, and
- .BI flash n
- for each other bank
- .IR n .
- It contains two files for each partition:
- a data file
- .I part
- and an associated control file
- .IB part ctl ,
- where
- .I part
- is the name of the partition.
- Each partition represents a region of flash memory that starts and ends
- on a flash segment (erase unit) boundary.
- The system initially creates a single standard partition
- .B flash
- representing the whole of flash memory, and the corresponding control file
- .BR flashctl .
- Other partitions can be created by writing to
- .B flashctl
- as described below.
- .PP
- The data file
- .I part
- provides read and write access to the bytes on the system's flash memory.
- Bytes can be read and written on any byte boundary:
- the interface hides any alignment restrictions.
- A read returns the value of the bytes at the current file offset,
- where zero is the start of the partition.
- A write reprograms the flash to the given byte values, at the current
- file offset (relative to the start of the partition), using the physical
- device's reprogramming algorithm.
- An erased flash byte is logically
- .B 0xFF
- (regardless of the conventions of the physical flash device).
- A write can change a bit with value 1 to a 0,
- but cannot change a 0 bit to 1;
- that can only be done by erasing one or more flash segments.
- NAND flash typically has restrictions on the number of writes
- allowed to a page before requiring a block erase.
- .\" bad idea:
- .\" Reads and writes are unbuffered.
- .PP
- The control file
- .IB part ctl
- can be read and written.
- A read returns several lines containing decimal and hexadecimal numbers
- (separated by white space)
- revealing the characteristics of memory within the partition.
- The first line gives the
- the manufacturer ID, the flash device ID, the memory width in bytes,
- and a string giving the flash type
- (currently either
- .B nor
- or
- .BR nand ).
- Subsequent lines give characteristics of each group of erase units
- within the partition,
- where the erase units within a group have the same properties.
- Each line gives the start and end (as byte addresses)
- of the erase units in the region
- that lie within the partition,
- followed by the size in bytes of each erase unit, which is followed
- for NAND flash by the size in bytes of a page.
- The sizes for NAND flash include the extra bytes per page
- typically used to hold an ECC and block status.
- A write contains one of the following textual commands:
- .TF "erase al"
- .TP
- .BI add " name start end"
- Create a new partition that ranges from
- .I start
- to
- .I end
- within the current partition.
- Each value must be numeric (decimal, octal or hexadecimal)
- and a multiple of the erase unit size.
- .I Name
- must not be the name of an existing partition.
- On success, new files
- .I name
- and
- .IB name ctl
- will appear in the parent
- .B flash
- directory.
- .TP
- .B erase all
- Erase the whole flash partition, setting all bytes to
- .BR 0xFF ,
- except those that are hardware write-protected.
- .TP
- .BI erase " offset"
- Erase the segment that begins at the given
- .I offset
- within the partition,
- setting all bytes to
- .BR 0xFF ,
- except those that are hardware write-protected.
- The
- .I offset
- is given in bytes, but must be a multiple
- of the segment (erase unit) size.
- .TP
- .BR protectboot " [ " off " ]"
- By default the system prevents erase unit 0 of the flash from being
- erased or written, assuming it
- contains the primary bootstrap.
- Writing this command with parameter
- .B off
- removes that protection.
- Writing
- .B protectboot
- with any other parameter (or none) restores the protection.
- Note that a manufacturer might also have locked the flash in hardware,
- and that protection must be removed in a device-dependent way.
- .TP
- .B sync
- If the underlying device must buffer or cache (current devices do not),
- flush the buffer(s).
- .PD
- .PP
- The syntax of all numbers is that of
- .I strtoul
- (in
- .IR atof (2));
- the default base is 10.
- .SH SOURCE
- .B /sys/src/*/devflash.c
- .br
- .B /sys/src/*/flash*.c
- .SH SEE ALSO
- .IR flashfs (4),
- .IR paqfs (4)
- .SH DIAGNOSTICS
- A write will return an error if
- an attempt is made to change a 0 bit to 1,
- or if the flash memory fails to be programmed correctly.
- .SH BUGS
- The flash cannot be written if the kernel is executing directly from flash,
- because the physical flash cannot be read during programming,
- and the driver does not copy the programming code to DRAM.
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