Provided by: flashrom_1.3.0-2ubuntu1_amd64 bug

NAME

       flashrom - detect, read, write, verify and erase flash chips

SYNOPSIS

       flashrom [-h|-R|-L|-z|
                 -p <programmername>[:<parameters>] [-c <chipname>]
                   (--flash-name|--flash-size|
                    [-E|-x|-r <file>|-w <file>|-v <file>]
                    [(-l <file>|--ifd| --fmap|--fmap-file <file>)
                      [-i <include>[:<file>]]]
                    [--wp-status] [--wp-list] [--wp-enable|--wp-disable]
                    [--wp-range <start>,<length>|--wp-region <region>]
                    [-n] [-N] [-f])]
                [-V[V[V]]] [-o <logfile>]

DESCRIPTION

       flashrom  is a utility for detecting, reading, writing, verifying and erasing flash chips.
       It's often used to flash BIOS/EFI/coreboot/firmware images  in-system  using  a  supported
       mainboard.  However,  it  also supports various external PCI/USB/parallel-port/serial-port
       based devices which can program flash chips, including some network cards (NICs), SATA/IDE
       controller    cards,    graphics    cards,   the   Bus   Pirate   device,   various   FTDI
       FT2232/FT4232H/FT232H based USB devices, and more.

       It supports a wide range of DIP32, PLCC32, DIP8, SO8/SOIC8, TSOP32,  TSOP40,  TSOP48,  and
       BGA chips, which use various protocols such as LPC, FWH, parallel flash, or SPI.

OPTIONS

       You can specify one of -h, -R, -L, -z, -E, -r, -w, -v or no operation.  If no operation is
       specified, flashrom will only probe for flash chips. It is recommended  that  if  you  try
       flashrom  the  first time on a system, you run it in probe-only mode and check the output.
       Also you are advised to make a backup of your current ROM contents with -r before you  try
       to  write  a  new  image.  All operations involving any chip access (probe/read/write/...)
       require the -p/--programmer option to be used (please see below).

       -r, --read <file>
              Read flash ROM contents and save them into the given <file>.  If the  file  already
              exists, it will be overwritten.

       -w, --write (<file>|-)
              Write  <file>  into flash ROM. If - is provided instead, contents will be read from
              stdin. This will first automatically
               B erase the chip, then write to it.

              In the process the chip is also read several times. First an  in-memory  backup  is
              made for disaster recovery and to be able to skip regions that are already equal to
              the image file. This copy is updated along with the write  operation.  In  case  of
              erase  errors  it  is  even  re-read  completely. After writing has finished and if
              verification is enabled, the whole flash chip is read out  and  compared  with  the
              input image.

       -n, --noverify
              Skip  the  automatic  verification  of flash ROM contents after writing. Using this
              option is not recommended, you should only use it if you know what  you  are  doing
              and if you feel that the time for verification takes too long.

              Typical usage is: flashrom -p prog -n -w <file>

              This option is only useful in combination with --write.

       -N, --noverify-all
              Skip  not included regions during automatic verification after writing (cf.  -l and
              -i).  You should only use this option if you are sure that communication  with  the
              flash  chip is reliable (e.g. when using the internal programmer). Even if flashrom
              is instructed not to touch parts of the flash chip, their contents could be damaged
              (e.g. due to misunderstood erase commands).

              This  option is required to flash an Intel system with locked ME flash region using
              the internal programmer. It may be enabled by default in this case in the future.

       -v, --verify (<file>|-)
              Verify the flash ROM contents against the given <file>.  If - is provided  instead,
              contents will be written to the stdout.

       -E, --erase
              Erase the flash ROM chip.

       -x, --extract
              Extract  every  region defined on the layout from flash ROM chip to a file with the
              same name as the extracted region (replacing spaces with underscores).

       -V, --verbose
              More verbose output. This option can be supplied multiple times (max. 3 times, i.e.
              -VVV) for even more debug output.

       -c, --chip <chipname>
              Probe  only  for  the  specified flash ROM chip. This option takes the chip name as
              printed by flashrom -L without the vendor name as parameter. Please note  that  the
              chip name is case sensitive.

       -f, --force
              Force one or more of the following actions:

              * Force chip read and pretend the chip is there.

              *  Force chip access even if the chip is bigger than the maximum supported size for
              the flash bus.

              * Force erase even if erase is known bad.

              * Force write even if write is known bad.

       -l, --layout <file>
              Read ROM layout from <file>.

              flashrom supports ROM layouts. This allows you to flash certain parts of the  flash
              chip only. A ROM layout file contains multiple lines with the following syntax:

                startaddr:endaddr imagename

              startaddr  and  endaddr  are  hexadecimal  addresses within the ROM file and do not
              refer to any physical address. Please  note  that  using  a  0x  prefix  for  those
              hexadecimal  numbers is not necessary, but you can't specify decimal/octal numbers.
              imagename is an arbitrary name for the region/image  from    startaddr  to  endaddr
              (both addresses included).

              Example:

                00000000:00008fff gfxrom
                00009000:0003ffff normal
                00040000:0007ffff fallback

              If  you  only  want  to  update the image named normal in a ROM based on the layout
              above, run

                flashrom -p prog --layout rom.layout --image normal -w some.rom

              To update only the images named normal and fallback, run:

                flashrom -p prog -l rom.layout -i normal -i fallback -w some.rom

              Overlapping sections are not supported.

       --fmap Read layout from fmap in flash chip.

              flashrom supports the fmap binary format which is commonly  used  by  coreboot  for
              partitioning  a  flash chip. The on-chip fmap will be read and used to generate the
              layout.

              If you only want to update the COREBOOT region defined in the fmap, run

               flashrom -p prog --fmap --image COREBOOT -w some.rom

       --fmap-file <file>
              Read layout from a <file> containing binary fmap (e.g. coreboot roms).

              flashrom supports the fmap binary format which is commonly  used  by  coreboot  for
              partitioning  a flash chip. The fmap in the specified file will be read and used to
              generate the layout.

              If you only want to update the COREBOOT region defined in the binary fmap file, run

                flashrom -p prog --fmap-file some.rom --image COREBOOT -w some.rom

       --ifd  Read ROM layout from Intel Firmware Descriptor.

              flashrom supports ROM layouts given by an Intel Firmware Descriptor (IFD). The  on-
              chip descriptor will be read and used to generate the layout. If you need to change
              the layout, you have to update the IFD only first.

              The following ROM images may be present in an IFD:

                fd    the IFD itself
                bios  the host firmware aka. BIOS
                me    Intel Management Engine firmware
                gbe   gigabit ethernet firmware
                pd    platform specific data

       -i, --include <region>[:<file>]
              Read or write only <region> to or from ROM.  The -i option  may  be  used  multiple
              times if the user wishes to read or write multiple regions using a single command.

              The  user may optionally specify a corresponding <file> for any region they wish to
              read or write. A read operation will read the corresponding regions  from  ROM  and
              write  individual files for each one. A write option will read file(s) and write to
              the corresponding region(s) in ROM.

              For write operations, files specified using -i take precedence  over  content  from
              the argument to -w.

              Examples:

                To read regions named foo and bar in layout file <layout> into region-sized files
              foo.bin and bar.bin, run:

                  flashrom -p prog -l <layout> -i foo:foo.bin -i bar:bar.bin -r rom.bin

                To write files foo.bin and bar.bin into regions named foo and bar in layout  file
              <layout> to the ROM, run:

                  flashrom -p prog -l <layout> -i foo:foo.bin -i bar:bar.bin -w rom.bin

       --wp-status
              Prints  the  flash's  current  status register protection mode and write protection
              range.

       --wp-list
              Prints a list of all protection ranges that the flash supports.

       --wp-enable
              Enables hardware status register protection (SRP) if the flash supports  it.   Once
              SRP  is  enabled,  operations  that  change the flash's status registers (including
              --wp-disable and --wp-range) can only be performed if the flash's #WP pin is at  an
              inactive logic level.

       --wp-disable
              Disables status register protection if the flash allows it.

       --wp-range <start>,<length>
              Configures  the  flash  to  protect a range of addresses from <start> to (<start> +
              <length> - 1), bounds inclusive. The range must be  supported  by  the  flash,  see
              --wp-list.

       --wp-region <region>
              Same as --wp-range but protects the range occupied by an image region.  This option
              requires a image layout to be specified, see --layout. The region must be supported
              by the flash, see --wp-list.

       --flash-name
              Prints out the detected flash chip's name.

       --flash-size
              Prints out the detected flash chip's size.

       --flash-contents <ref-file>
              The  file  contents  of  <ref-file> will be used to decide which parts of the flash
              need to be written. Providing this saves an initial read of the full flash chip. Be
              careful,  if  the  provided data doesn't actually match the flash contents, results
              are undefined.

       -L, --list-supported
              List the flash chips, chipsets, mainboards,  and  external  programmers  (including
              PCI, USB, parallel port, and serial port based devices) supported by flashrom.

              There  are  many  unlisted  boards  which will work out of the box, without special
              support in flashrom. Please let us know if you can verify that other boards work or
              do not work out of the box.

              IMPORTANT:  For  verification  you have to test an ERASE and/or WRITE operation, so
              make sure you only do that if you have proper means to recover from failure!

       -z, --list-supported-wiki
              Same as --list-supported, but outputs the supported hardware in  MediaWiki  syntax,
              so   that   it  can  be  easily  pasted  into  the  supported  hardware  wiki  page
              ⟨https://flashrom.org/Supported_hardware⟩.  Please note that  MediaWiki  output  is
              not compiled in by default.

       -p, --programmer <name>[:parameter[,parameter[,parameter]]]
              Specify  the  programmer device. This is mandatory for all operations involving any
              chip access (probe/read/write/...). Currently supported are:

              * internal (for in-system flashing in the mainboard)

              * dummy (virtual programmer for testing flashrom)

              * nic3com (for flash ROMs on 3COM network cards)

              * nicrealtek (for flash ROMs on Realtek and SMC 1211 network cards)

              * nicnatsemi (for flash ROMs on National Semiconductor DP838* network cards)

              * nicintel (for parallel flash ROMs on Intel 10/100Mbit network cards)

              * gfxnvidia (for flash ROMs on NVIDIA graphics cards)

              * drkaiser (for flash ROMs on Dr. Kaiser PC-Waechter PCI cards)

              * satasii (for flash ROMs on Silicon Image SATA/IDE controllers)

              * satamv (for flash ROMs on Marvell SATA controllers)

              * atahpt (for flash ROMs on Highpoint ATA/RAID controllers)

              * atavia (for flash ROMs on VIA VT6421A SATA controllers)

              * atapromise (for flash ROMs on Promise PDC2026x ATA/RAID controllers)

              * it8212 (for flash ROMs on ITE IT8212F ATA/RAID controller)

              * ft2232_spi (for SPI flash ROMs attached to an FT2232/FT4232H/FT232H family  based
              USB SPI programmer).

              * serprog (for flash ROMs attached to a programmer speaking serprog, including some
              Arduino-based devices).

              * buspirate_spi (for SPI flash ROMs attached to a Bus Pirate)

              * dediprog (for SPI flash ROMs attached to a Dediprog SF100)

              * rayer_spi (for SPI flash ROMs attached to a parallel port by one of various cable
              types)

              *  raiden_debug_spi  (For Chrome EC based debug tools - SuzyQable, Servo V4, C2D2 &
              uServo)

              * pony_spi (for SPI flash  ROMs  attached  to  a  SI-Prog  serial  port  bitbanging
              adapter)

              * nicintel_spi (for SPI flash ROMs on Intel Gigabit network cards)

              * ogp_spi (for SPI flash ROMs on Open Graphics Project graphics card)

              * linux_mtd (for SPI flash ROMs accessible via /dev/mtdX on Linux)

              * linux_spi (for SPI flash ROMs accessible via /dev/spidevX.Y on Linux)

              *  usbblaster_spi  (for SPI flash ROMs attached to an Altera USB-Blaster compatible
              cable)

              * nicintel_eeprom (for SPI EEPROMs on Intel Gigabit network cards)

              * mstarddc_spi (for  SPI  flash  ROMs  accessible  through  DDC  in  MSTAR-equipped
              displays)

              * pickit2_spi (for SPI flash ROMs accessible via Microchip PICkit2)

              * ch341a_spi (for SPI flash ROMs attached to WCH CH341A)

              * digilent_spi (for SPI flash ROMs attached to iCEblink40 development boards)

              * jlink_spi (for SPI flash ROMs attached to SEGGER J-Link and compatible devices)

              *  ni845x_spi  (for  SPI  flash  ROMs  attached to National Instruments USB-8451 or
              USB-8452)

              * stlinkv3_spi (for  SPI  flash  ROMs  attached  to  STMicroelectronics  STLINK  V3
              devices)

              *  realtek_mst_i2c_spi  (for  SPI  flash  ROMs attached to Realtek DisplayPort hubs
              accessible through I2C)

              * parade_lspcon (for  SPI  flash  ROMs  attached  to  Parade  Technologies  LSPCONs
              (PS175))

              *  mediatek_i2c_spi  (for  SPI flash ROMs attached to some Mediatek display devices
              accessible over I2C)

              * dirtyjtag_spi (for SPI flash ROMs attached to DirtyJTAG-compatible devices)

              Some programmers have optional or  mandatory  parameters  which  are  described  in
              detail in the PROGRAMMER-SPECIFIC INFORMATION section. Support for some programmers
              can be disabled at compile time.  flashrom -h lists all supported programmers.

       -h, --help
              Show a help text and exit.

       -o, --output <logfile>
              Save the full debug log to <logfile>.  If the  file  already  exists,  it  will  be
              overwritten.  This is the recommended way to gather logs from flashrom because they
              will be verbose even if the on-screen messages are not verbose  and  don't  require
              output redirection.

       -R, --version
              Show version information and exit.

PROGRAMMER-SPECIFIC INFORMATION

       Some  programmer  drivers accept further parameters to set programmer-specific parameters.
       These parameters are separated from the programmer name by a colon. While some programmers
       take  arguments  at  fixed positions, other programmers use a key/value interface in which
       the key and value is separated by an equal sign and different pairs  are  separated  by  a
       comma or a colon.

   internal programmer
       Board Enables

              Some  mainboards  require  to run mainboard specific code to enable flash erase and
              write support (and  probe  support  on  old  systems  with  parallel  flash).   The
              mainboard  brand  and  model (if it requires specific code) is usually autodetected
              using one of the following mechanisms: If your  system  is  running  coreboot,  the
              mainboard  type is determined from the coreboot table.  Otherwise, the mainboard is
              detected by examining the onboard PCI devices and possibly DMI info. If PCI and DMI
              do  not  contain  information  to  uniquely  identify  the  mainboard (which is the
              exception), or if you want to  override  the  detected  mainboard  model,  you  can
              specify the mainboard using the

                flashrom -p internal:mainboard=<vendor>:<board> syntax.

              See  the  'Known  boards' or 'Known laptops' section in the output of 'flashrom -L'
              for a list of boards which require the specification  of  the  board  name,  if  no
              coreboot table is found.

              Some  of  these  board-specific  flash enabling functions (called board enables) in
              flashrom have not yet been  tested.  If  your  mainboard  is  detected  needing  an
              untested  board  enable function, a warning message is printed and the board enable
              is not executed, because a wrong board enable function might cause  the  system  to
              behave  erratically,  as  board enable functions touch the low-level internals of a
              mainboard. Not executing a board enable function (if one  is  needed)  might  cause
              detection  or  erasing  failure.  If  your  board  protects  only part of the flash
              (commonly the top end, called boot block), flashrom might encounter an  error  only
              after  erasing  the  unprotected part, so running without the board-enable function
              might be dangerous for erase and write (which includes erase).

              The suggested procedure for a mainboard with untested board  specific  code  is  to
              first  try  to  probe  the ROM (just invoke flashrom and check that it detects your
              flash chip  type)  without  running  the  board  enable  code  (i.e.   without  any
              parameters).  If  it finds your chip, fine. Otherwise, retry probing your chip with
              the board-enable code running, using

                flashrom -p internal:boardenable=force

              If your chip is still not detected, the board enable code seems to be broken or the
              flash  chip  unsupported.  Otherwise,  make  a  backup of your current ROM contents
              (using -r) and store it to a medium outside of your computer, like a USB drive or a
              network  share. If you needed to run the board enable code already for probing, use
              it for reading too.  If reading succeeds and the contents of  the  read  file  look
              legit  you can try to write the new image.  You should enable the board enable code
              in any case now, as it has been written because it is  known  that  writing/erasing
              without the board enable is going to fail. In any case (success or failure), please
              report to the flashrom mailing list, see below.

       Coreboot

              On systems running coreboot, flashrom checks whether the desired image matches your
              mainboard.  This  needs  some  special  board  ID  to  be present in the image.  If
              flashrom detects that the image you want to write and  the  current  board  do  not
              match, it will refuse to write the image unless you specify

                flashrom -p internal:boardmismatch=force

       ITE IT87 Super I/O

              If  your  mainboard  is  manufactured  by GIGABYTE and supports DualBIOS it is very
              likely that it uses an ITE IT87 series Super I/O to switch between  the  two  flash
              chips. Only one of them can be accessed at a time and you can manually select which
              one to use with the

                flashrom -p internal:dualbiosindex=chip

              syntax where chip is the index of the chip to use (0 = main, 1 = backup).  You  can
              check which one is currently selected by leaving out the chip parameter.

              If  your  mainboard  uses  an  ITE  IT87  series  Super I/O for LPC<->SPI flash bus
              translation, flashrom should autodetect that configuration. If you want to set  the
              I/O base port of the IT87 series SPI controller manually instead of using the value
              provided by the BIOS, use the

                flashrom -p internal:it87spiport=portnum

              syntax where portnum is the I/O port number (must be  a  multiple  of  8).  In  the
              unlikely  case flashrom doesn't detect an active IT87 LPC<->SPI bridge, please send
              a bug report so we can diagnose the problem.

       AMD chipsets

              Beginning with the SB700 chipset there is an integrated microcontroller (IMC) based
              on  the  8051  embedded  in every AMD southbridge. Its firmware resides in the same
              flash chip as the host's which makes writing to the  flash  risky  if  the  IMC  is
              active.  Flashrom  tries  to temporarily disable the IMC but even then changing the
              contents of the flash can have unwanted effects: when the  IMC  continues  (at  the
              latest  after a reboot) it will continue executing code from the flash. If the code
              was removed or changed in an unfortunate way it is unpredictable what the IMC  will
              do.  Therefore,  if  flashrom  detects  an active IMC it will disable write support
              unless the user forces it with the

                flashrom -p internal:amd_imc_force=yes

              syntax. The user is responsible for supplying a suitable image or leaving  out  the
              IMC  region with the help of a layout file. This limitation might be removed in the
              future when we understand the details better and have received enough feedback from
              users. Please report the outcome if you had to use this option to write a chip.

              An  optional  spispeed  parameter  specifies  the  frequency  of  the SPI bus where
              applicable (i.e. SB600 or later with an SPI flash chip  directly  attached  to  the
              chipset).  Syntax is

                flashrom -p internal:spispeed=frequency

              where  frequency  can  be  '16.5 MHz',  '22 MHz', '33 MHz', '66 MHz', '100 MHZ', or
              '800 kHz'.  Support of individual frequencies depends  on  the  generation  of  the
              chipset:

              * SB6xx, SB7xx, SP5xxx: from 16.5 MHz up to and including 33 MHz

              -The default is to use 16.5 MHz and disable Fast Reads.

              * SB8xx, SB9xx, Hudson: from 16.5 MHz up to and including 66 MHz

              -The default is to use 16.5 MHz and disable Fast Reads.

              * Yangtze (with SPI 100 engine as found in Kabini and Tamesh): all of them

              -The default is to use the frequency that is currently configured.

              An  optional  spireadmode  parameter  specifies  the read mode of the SPI bus where
              applicable (Bolton or later).  Syntax is

                flashrom -p internal:spireadmode=mode

              where   mode   can   be   'Normal (up to 33   MHz)',    'Normal (up to 66    MHz)',
              'Dual IO (1-1-2)',   'Quad IO (1-1-4)',  'Dual IO (1-2-2)',  'Quad IO (1-4-4)',  or
              'Fast Read'.

              The default is to use the read mode that is currently configured.

       Intel chipsets

              If you have an Intel chipset with an ICH8  or  later  southbridge  with  SPI  flash
              attached,  and  if  a  valid descriptor was written to it (e.g. by the vendor), the
              chipset provides an alternative way to access  the  flash  chip(s)  named  Hardware
              Sequencing.   It  is  much  simpler  than the normal access method (called Software
              Sequencing), but does not allow the software to choose the SPI commands to be sent.
              You can use the

                flashrom -p internal:ich_spi_mode=value

              syntax  where  value  can  be  auto,  swseq  or hwseq.  By default (or when setting
              ich_spi_mode=auto) the module tries to use swseq and only activates hwseq  if  need
              be (e.g. if important opcodes are inaccessible due to lockdown; or if more than one
              flash chip is attached). The other options (swseq,  hwseq)  select  the  respective
              mode (if possible).

              ICH8  and later southbridges may also have locked address ranges of different kinds
              if a valid  descriptor  was  written  to  it.  The  flash  address  space  is  then
              partitioned in multiple so called "Flash Regions" containing the host firmware, the
              ME firmware and so on respectively. The flash descriptor can also specify up  to  5
              so  called  "Protected Regions", which are freely chosen address ranges independent
              from the aforementioned "Flash Regions". All of  them  can  be  write  and/or  read
              protected individually.

              If  you  have an Intel chipset with an ICH2 or later southbridge and if you want to
              set specific IDSEL values for a non-default flash chip or  an  embedded  controller
              (EC), you can use the

                flashrom -p internal:fwh_idsel=value

              syntax  where  value is the 48-bit hexadecimal raw value to be written in the IDSEL
              registers of the Intel southbridge. The upper 32 bits use one hex  digit  each  per
              512  kB  range between 0xffc00000 and 0xffffffff, and the lower 16 bits use one hex
              digit each per 1024 kB range between 0xff400000 and 0xff7fffff.  The rightmost  hex
              digit  corresponds  with  the  lowest  address  range.  All  address  ranges have a
              corresponding sister range 4 MB below with identical IDSEL  settings.  The  default
              value for ICH7 is given in the example below.

              Example: flashrom -p internal:fwh_idsel=0x001122334567

       Laptops

              Using  flashrom  on older laptops that don't boot from the SPI bus is dangerous and
              may easily make your hardware unusable (see also the BUGS  section).  The  embedded
              controller   (EC)  in  some  machines  may  interact  badly  with  flashing.   More
              information is in the wiki ⟨https://flashrom.org/Laptops⟩.  Problems occur when the
              flash  chip  is shared between BIOS and EC firmware, and the latter does not expect
              flashrom to access the chip. While flashrom tries to change the  contents  of  that
              memory  the  EC might need to fetch new instructions or data from it and could stop
              working correctly. Probing for and reading from the chip may also irritate your  EC
              and cause fan failure, backlight failure, sudden poweroff, and other nasty effects.
              flashrom will attempt to detect if it is running on such a laptop and limit probing
              to SPI buses. If you want to probe the LPC bus anyway at your own risk, use

                flashrom -p internal:laptop=force_I_want_a_brick

              We  will  not  help  you if you force flashing on a laptop because this is a really
              dumb idea.

              You have been warned.

              Currently we rely on the chassis type encoded in  the  DMI/SMBIOS  data  to  detect
              laptops. Some vendors did not implement those bits correctly or set them to generic
              and/or dummy values. flashrom will then issue a warning  and  restrict  buses  like
              above. In this case you can use

                flashrom -p internal:laptop=this_is_not_a_laptop

              to tell flashrom (at your own risk) that it is not running on a laptop.

   dummy programmer
              The  dummy  programmer  operates on a buffer in memory only. It provides a safe and
              fast way to test various aspects of flashrom and is mainly used in development  and
              while  debugging.   It  is  able  to  emulate some chips to a certain degree (basic
              identify/read/erase/write operations work).

              An optional parameter specifies the bus types it should support. For that you  have
              to use the

                flashrom -p dummy:bus=[type[+type[+type]]]

              syntax  where  type can be parallel, lpc, fwh, spi in any order. If you specify bus
              without type, all buses will be disabled.  If you do not  specify  bus,  all  buses
              will be enabled.

              Example: flashrom -p dummy:bus=lpc+fwh

              The dummy programmer supports flash chip emulation for automated self-tests without
              hardware access. If you want to emulate a flash chip, use the

                flashrom -p dummy:emulate=chip

              syntax where chip is one of the following chips (please specify only the chip name,
              not the vendor):

              * ST M25P10.RES SPI flash chip (128 kB, RES, page write)

              * SST SST25VF040.REMS SPI flash chip (512 kB, REMS, byte write)

              * SST SST25VF032B SPI flash chip (4096 kB, RDID, AAI write)

              * Macronix MX25L6436 SPI flash chip (8192 kB, RDID, SFDP)

              * Winbond W25Q128FV SPI flash chip (16384 kB, RDID)

              * Spansion S25FL128L SPI flash chip (16384 kB, RDID)

              * Dummy vendor VARIABLE_SIZE SPI flash chip (configurable size, page write)

              Example: flashrom -p dummy:emulate=SST25VF040.REMS

              To  use  VARIABLE_SIZE  chip,  size  must be specified to configure the size of the
              flash chip as a power of two.

              Example: flashrom -p dummy:emulate=VARIABLE_SIZE,size=16777216,image=dummy.bin

       Persistent images

              If you use flash chip emulation, flash image persistence is available  as  well  by
              using the

                flashrom -p dummy:emulate=chip,image=image.rom

              syntax  where  image.rom  is the file where the simulated chip contents are read on
              flashrom startup and where the chip contents on flashrom shutdown are written to.

              Example: flashrom -p dummy:emulate=M25P10.RES,image=dummy.bin

       SPI write chunk size

              If you use SPI flash chip emulation for a chip which supports SPI page  write  with
              the default opcode, you can set the maximum allowed write chunk size with the

                flashrom -p dummy:emulate=chip,spi_write_256_chunksize=size

              syntax where size is the number of bytes (min. 1, max. 256).

              Example:

                flashrom -p dummy:emulate=M25P10.RES,spi_write_256_chunksize=5

       SPI blacklist

              To  simulate  a  programmer which refuses to send certain SPI commands to the flash
              chip, you can specify a blacklist of SPI commands with the

                flashrom -p dummy:spi_blacklist=commandlist

              syntax where commandlist is a list of two-digit hexadecimal representations of  SPI
              commands.  If  commandlist  is  e.g.  0302,  flashrom  will  behave  as  if the SPI
              controller  refuses  to  run  command  0x03  (READ)  and  command   0x02   (WRITE).
              commandlist  may be up to 512 characters (256 commands) long.  Implementation note:
              flashrom will detect an error during command execution.

       SPI ignorelist

              To simulate a flash chip which ignores (doesn't support) certain SPI commands,  you
              can specify an ignorelist of SPI commands with the

                flashrom -p dummy:spi_ignorelist=commandlist

              syntax  where commandlist is a list of two-digit hexadecimal representations of SPI
              commands. If commandlist is e.g. 0302, the emulated flash chip will ignore  command
              0x03 (READ) and command 0x02 (WRITE).  commandlist may be up to 512 characters (256
              commands) long.  Implementation note: flashrom won't detect an error during command
              execution.

       SPI status register

              You can specify the initial content of the chip's status register with the

                flashrom -p dummy:spi_status=content

              syntax where content is a hexadecimal value of up to 24 bits. For example, 0x332211
              assigns 0x11 to SR1, 0x22 to SR2 and 0x33 to SR3. Shorter value  is  padded  to  24
              bits  with  zeroes on the left. See datasheet for chosen chip for details about the
              registers content.

       Write protection

              Chips with emulated WP: W25Q128FV, S25FL128L.

              You can simulate state of hardware protection pin (WP) with the

                flashrom -p dummy:hwwp=state

              syntax where state is "yes" or "no" (default value). "yes" means  active  state  of
              the  pin  implies that chip is write-protected (on real hardware the pin is usually
              negated, but not here).

   nic3com, nicrealtek, nicnatsemi, nicintel, nicintel_eeprom, nicintel_spi, gfxnvidia,  ogp_spi,
       drkaiser, satasii, satamv, atahpt, atavia , atapromise and it8212 programmers
              These  programmers  have an option to specify the PCI address of the card your want
              to use, which must be specified if more than one card  supported  by  the  selected
              programmer is installed in your system. The syntax is

                flashrom -p xxxx:pci=bb:dd.f,

              where  xxxx  is the name of the programmer, bb is the PCI bus number, dd is the PCI
              device number, and f is the PCI function number of the desired device.

              Example: flashrom -p nic3com:pci=05:04.0

   atavia programmer
              Due to the mysterious address handling of the VIA VT6421A controller the  user  can
              specify an offset with the

                flashrom -p atavia:offset=addr

              syntax  where  addr  will  be  interpreted as usual (leading 0x (0) for hexadecimal
              (octal) values, or else decimal).  For more information please see  its  wiki  page
              ⟨https://flashrom.org/VT6421A⟩.

   atapromise programmer
              This programmer is currently limited to 32 kB, regardless of the actual size of the
              flash chip. This stems from  the  fact  that,  on  the  tested  device  (a  Promise
              Ultra100), not all of the chip's address lines were actually connected. You may use
              this programmer to flash firmware updates, since these  are  only  16  kB  in  size
              (padding to 32 kB is required).

   nicintel_eeprom programmer
              This is the first programmer module in flashrom that does not provide access to NOR
              flash chips but EEPROMs mounted on gigabit Ethernet cards based  on  Intel's  82580
              NIC. Because EEPROMs normally do not announce their size nor allow themselves to be
              identified, the controller relies on correct  size  values  written  to  predefined
              addresses  within  the  chip.  Flashrom follows this scheme but assumes the minimum
              size of 16 kB (128 kb) if an unprogrammed EEPROM/card is detected. Intel  specifies
              following  EEPROMs  to  be  compatible: Atmel AT25128, AT25256, Micron (ST) M95128,
              M95256 and OnSemi (Catalyst) CAT25CS128.

   ft2232_spi programmer
              This module supports various programmers based on FTDI FT2232/FT4232H/FT232H  chips
              including  the  DLP Design DLP-USB1232H, openbiosprog-spi, Amontec JTAGkey/JTAGkey-
              tiny/JTAGkey-2, Dangerous Prototypes Bus Blaster,  Olimex  ARM-USB-TINY/-H,  Olimex
              ARM-USB-OCD/-H,  OpenMoko  Neo1973  Debug  board  (V2+),  TIAO/DIYGADGET USB Multi-
              Protocol Adapter (TUMPA), TUMPA Lite, GOEPEL PicoTAP, Google Servo v1/v2,  Tin  Can
              Tools Flyswatter/Flyswatter 2 and Kristech KT-LINK.

              An  optional  parameter  specifies  the  controller type, channel/interface/port it
              should support. For that you have to use the

                flashrom -p ft2232_spi:type=model,port=interface

              syntax where model can be 2232H, 4232H, 232H, jtagkey, busblaster,  openmoko,  arm-
              usb-tiny,  arm-usb-tiny-h,  arm-usb-ocd,  arm-usb-ocd-h, tumpa, tumpalite, picotap,
              google-servo, google-servo-v2, google-servo-v2-legacy or kt-link interface  can  be
              A,  B,  C, or D.  The default model is 4232H the default interface is A and GPIO is
              not used by default.

              If there is more than one ft2232_spi-compatible device connected,  you  can  select
              which one should be used by specifying its serial number with the

                flashrom -p ft2232_spi:serial=number

              syntax  where  number  is  the  serial number of the device (which can be found for
              example in the output of lsusb -v).

              All models supported by the ft2232_spi driver can configure the SPI clock  rate  by
              setting a divisor. The expressible divisors are all even numbers between 2 and 2^17
              (=131072) resulting in SPI clock frequencies of 6 MHz down to about 92  Hz  for  12
              MHz  inputs.  The  default  divisor  is  set  to  2, but you can use another one by
              specifying the optional divisor parameter with the

                flashrom -p ft2232_spi:divisor=div

              syntax.

              Using the parameter csgpiol (DEPRECATED - use gpiol instead) an additional CS#  pin
              can  be  chosen,  where  the  value  can  be  a  number  between  0 and 3, denoting
              GPIOL0-GPIOL3 correspondingly. Example:

                flashrom -p ft2232_spi:csgpiol=3

              The parameter gpiolX=[HLC] allows use of the GPIOL pins  either  as  generic  gpios
              with  a  fixed  value during flashing or as additional CS# signal, where X can be a
              number between 0 and 3, denoting GPIOL0-GPIOL3 correspondingly. The  parameter  may
              be  specified multiple times, one time per GPIOL pin.  Valid values are H , L and C
              :
                H - Set GPIOL output high
                L - Set GPIOL output low
                C - Use GPIOL as additional CS# output

              Example:

                flashrom -p ft2232_spi:gpiol0=H

              Note that not all GPIOL pins are freely usable with all programmers  as  some  have
              special functionality.

   serprog programmer
              This  module  supports all programmers speaking the serprog protocol. This includes
              some Arduino-based devices as well as various programmers by Urja Rannikko,  Juhana
              Helovuo, Stefan Tauner, Chi Zhang and many others.

              A  mandatory  parameter  specifies  either  a  serial  device (and baud rate) or an
              IP/port  combination  for  communicating  with  the  programmer.   The  device/baud
              combination  has  to  start  with  dev=  and separate the optional baud rate with a
              colon.  For example

                flashrom -p serprog:dev=/dev/ttyS0:115200

              If no baud rate is given the default values by the operating  system/hardware  will
              be used.  For IP connections you have to use the

                flashrom -p serprog:ip=ipaddr:port

              syntax.   In  case the device supports it, you can set the SPI clock frequency with
              the optional spispeed parameter. The frequency is parsed as hertz, unless an M,  or
              k suffix is given, then megahertz or kilohertz are used respectively.  Example that
              sets the frequency to 2 MHz:

                flashrom -p serprog:dev=/dev/device:baud,spispeed=2M

              More information about serprog is available in serprog-protocol.txt in  the  source
              distribution.

   buspirate_spi programmer
              A  required  dev  parameter  specifies  the  Bus Pirate device node and an optional
              spispeed parameter specifies the frequency of the SPI bus. The parameter  delimiter
              is a comma. Syntax is

                flashrom -p buspirate_spi:dev=/dev/device,spispeed=frequency

              where frequency can be 30k, 125k, 250k, 1M, 2M, 2.6M, 4M or 8M (in Hz). The default
              is the maximum frequency of 8 MHz.

              The baud rate for communication  between  the  host  and  the  Bus  Pirate  can  be
              specified with the optional serialspeed parameter. Syntax is

                flashrom -p buspirate_spi:serialspeed=baud

              where  baud  can be 115200, 230400, 250000 or 2000000 (2M).  The default is 2M baud
              for Bus Pirate hardware version 3.0 and greater, and 115200 otherwise.

              An optional pullups parameter specifies the use of the Bus Pirate internal  pull-up
              resistors.  This  may  be  needed if you are working with a flash ROM chip that you
              have physically removed from the board. Syntax is

                flashrom -p buspirate_spi:pullups=state

              where state can be on or off.   More  information  about  the  Bus  Pirate  pull-up
              resistors  and  their  purpose  is  available  in  a  guide  by dangerousprototypes
              ⟨http://dangerousprototypes.com/docs/Practical_guide_to_Bus_Pirate_pull-
              up_resistors⟩.

              The  state  of the Bus Pirate power supply pins is controllable through an optional
              psus parameter. Syntax is

                flashrom -p buspirate_spi:psus=state

              where state can be on or off.  This allows the bus pirate to  power  the  ROM  chip
              directly.  This may also be used to provide the required pullup voltage (when using
              the pullups option), by connecting the Bus Pirate's Vpu input  to  the  appropriate
              Vcc pin.

   pickit2_spi programmer
              An  optional  voltage  parameter  specifies the voltage the PICkit2 should use. The
              default unit is Volt if no unit is specified.  You can use mV, millivolt, V or Volt
              as unit specifier. Syntax is

                flashrom -p pickit2_spi:voltage=value

              where value can be 0V, 1.8V, 2.5V, 3.5V or the equivalent in mV.

              An optional spispeed parameter specifies the frequency of the SPI bus. Syntax is

                flashrom -p pickit2_spi:spispeed=frequency

              where  frequency  can be 250k, 333k, 500k or 1M (in Hz). The default is a frequency
              of 1 MHz.

   dediprog programmer
              An optional voltage parameter specifies the voltage the Dediprog  should  use.  The
              default  unit is Volt if no unit is specified. You can use mV, milliVolt, V or Volt
              as unit specifier. Syntax is

                flashrom -p dediprog:voltage=value

              where value can be 0V, 1.8V, 2.5V, 3.5V or the equivalent in mV.

              An optional device parameter specifies which of multiple connected Dediprog devices
              should   be   used.    Please   be   aware  that  the  order  depends  on  libusb's
              usb_get_busses() function and that the numbering starts at  0.   Usage  example  to
              select the second device:

                flashrom -p dediprog:device=1

              An optional spispeed parameter specifies the frequency of the SPI bus. The firmware
              on the device needs to be 5.0.0 or newer.  Syntax is

                flashrom -p dediprog:spispeed=frequency

              where frequency can be 375k, 750k, 1.5M, 2.18M, 3M, 8M, 12M or  24M  (in  Hz).  The
              default is a frequency of 12 MHz.

              An optional target parameter specifies which target chip should be used. Syntax is

                flashrom -p dediprog:target=value

              where value can be 1 or 2 to select target chip 1 or 2 respectively. The default is
              target chip 1.

   rayer_spi programmer
              The default I/O base address used for the parallel port is 0x378 and  you  can  use
              the optional iobase parameter to specify an alternate base I/O address with the

                flashrom -p rayer_spi:iobase=baseaddr

              syntax  where baseaddr is base I/O port address of the parallel port, which must be
              a multiple of four. Make sure to not forget the "0x" prefix  for  hexadecimal  port
              addresses.

              The  default cable type is the RayeR cable. You can use the optional type parameter
              to specify the cable type with the

                flashrom -p rayer_spi:type=model

              syntax where model can be rayer for the RayeR cable, byteblastermv for  the  Altera
              ByteBlasterMV,  stk200 for the Atmel STK200/300, wiggler for the Macraigor Wiggler,
              xilinx for the Xilinx Parallel Cable III (DLC 5), or spi_tt  for  SPI  Tiny  Tools-
              compatible hardware.

              More  information  about  the  RayeR  hardware  is  available  at  RayeR's  website
              ⟨http://rayer.g6.cz/elektro/spipgm.htm⟩.  The Altera ByteBlasterMV datasheet can be
              obtained  from  Altera  ⟨http://www.altera.co.jp/literature/ds/dsbytemv.pdf⟩.   For
              more  information  about  the  Macraigor  Wiggler  see   their   company   homepage
              ⟨http://www.macraigor.com/wiggler.htm⟩.   The  schematic  of  the  Xilinx DLC 5 was
              published           in           a           Xilinx           user            guide
              ⟨http://www.xilinx.com/support/documentation/user_guides/xtp029.pdf⟩.

   raiden_debug_spi programmer
              The target of the SPI flashing mux must be specified with the target parameter with
              the

                flashrom -p raiden_debug_spi:target=chip

              syntax, where chip is either the ap or ec to flash, otherwise a unspecified  target
              terminates at the end-point.

              The  default  is  to use the first available servo. You can use the optional serial
              parameter to specify the servo USB device serial number to use specifically with

                flashrom -p raiden_debug_spi:serial=XXX

              The servo device serial number can be found via lsusb.

              Raiden will poll the ap target waiting for the system power to settle on the AP and
              EC flash devices.

              The optional custom_rst=true parameter changes the timeout value from 3ms to 10ms.

                flashrom -p raiden_debug_spi:custom_rst=<true|false>

              syntax, where custom_rst=false is the implicit default timeout of 3ms.

              More  information about the ChromiumOS servo hardware is available at servo website
              ⟨https://chromium.googlesource.com/chromiumos/third_party/hdctools/+/HEAD/docs/servo_v4.md⟩.

   pony_spi programmer
              The  serial  port  (like  /dev/ttyS0,  /dev/ttyUSB0 on Linux or COM3 on windows) is
              specified using the mandatory dev parameter. The adapter type is selectable between
              SI-Prog  (used  for  SPI  devices  with  PonyProg  2000)  or  a  custom made serial
              bitbanging programmer named "serbang". The  optional  type  parameter  accepts  the
              values "si_prog" (default) or "serbang".

              Information   about   the   SI-Prog   adapter   can   be   found   at  its  website
              ⟨http://www.lancos.com/siprogsch.html⟩.

              An example call to flashrom is

                flashrom -p pony_spi:dev=/dev/ttyS0,type=serbang

              Please note that while USB-to-serial adapters  work  under  certain  circumstances,
              this slows down operation considerably.

   ogp_spi programmer
              The flash ROM chip to access must be specified with the rom parameter.

                flashrom -p ogp_spi:rom=name

              Where  name  is  either cprom or s3 for the configuration ROM and bprom or bios for
              the BIOS ROM. If more  than  one  card  supported  by  the  ogp_spi  programmer  is
              installed  in your system, you have to specify the PCI address of the card you want
              to use with the pci= parameter as explained in the nic3com et al. section above.

   linux_mtd programmer
              You may specify the MTD device to use with the

                flashrom -p linux_mtd:dev=/dev/mtdX

              syntax where /dev/mtdX is the Linux device  node  for  your  MTD  device.  If  left
              unspecified the first MTD device found (e.g. /dev/mtd0) will be used by default.

              Please note that the linux_mtd driver only works on Linux.

   linux_spi programmer
              You have to specify the SPI controller to use with the

                flashrom -p linux_spi:dev=/dev/spidevX.Y

              syntax where /dev/spidevX.Y is the Linux device node for your SPI controller.

              In  case  the  device  supports  it,  you  can set the SPI clock frequency with the
              optional spispeed parameter. The frequency is parsed as  kilohertz.   Example  that
              sets the frequency to 8 MHz:

                flashrom -p linux_spi:dev=/dev/spidevX.Y,spispeed=8000

              Please note that the linux_spi driver only works on Linux.

   mstarddc_spi programmer
              The  Display  Data  Channel  (DDC) is an I2C bus present on VGA and DVI connectors,
              that allows exchanging information between a computer and  attached  displays.  Its
              most  common  uses  are  getting  display capabilities through EDID (at I2C address
              0x50) and sending commands to the display using the  DDC/CI  protocol  (at  address
              0x37).  On  displays  driven  by  MSTAR SoCs, it is also possible to access the SoC
              firmware flash (connected to the Soc through another SPI bus)  using  an  In-System
              Programming  (ISP)  port, usually at address 0x49.  This flashrom module allows the
              latter via Linux's I2C driver.

              IMPORTANT: Before using this programmer, the display MUST be in standby  mode,  and
              only  connected  to  the  computer  that will run flashrom using a VGA cable, to an
              inactive VGA output. It absolutely MUST  NOT  be  used  as  a  display  during  the
              procedure!

              You have to specify the DDC/I2C controller and I2C address to use with the

                flashrom -p mstarddc_spi:dev=/dev/i2c-X:YY

              syntax  where /dev/i2c-X is the Linux device node for your I2C controller connected
              to the display's DDC channel, and YY is the (hexadecimal) address of the MSTAR  ISP
              port  (address  0x49 is usually used).  Example that uses I2C controller /dev/i2c-1
              and address 0x49:

                flashrom -p mstarddc_spi:dev=/dev/i2c-1:49

              It is also possible to inhibit the reset command  that  is  normally  sent  to  the
              display  once  the  flashrom  operation  is  completed  using  the optional noreset
              parameter. A value of 1 prevents flashrom from sending the reset command.   Example
              that does not reset the display at the end of the operation:

                flashrom -p mstarddc_spi:dev=/dev/i2c-1:49,noreset=1

              Please  note  that sending the reset command is also inhibited if an error occurred
              during the operation.  To send the reset command afterwards,  you  can  simply  run
              flashrom  once  more, in chip probe mode (not specifying an operation), without the
              noreset parameter, once the flash read/write operation you intended to perform  has
              completed successfully.

              Please also note that the mstarddc_spi driver only works on Linux.

   ch341a_spi programmer
       The  WCH  CH341A  programmer  does  not support any parameters currently. SPI frequency is
       fixed at 2 MHz, and CS0 is used as per the device.

   ni845x_spi programmer
              An optional voltage parameter could  be  used  to  specify  the  IO  voltage.  This
              parameter  is available for the NI USB-8452 device.  The default unit is Volt if no
              unit is specified. You can use mV, milliVolt, V or Volt as unit specifier.   Syntax
              is

                flashrom -p ni845x_spi:voltage=value

              where value can be 1.2V, 1.5V, 1.8V, 2.5V, 3.3V or the equivalent in mV.

              In  the  case  if  none  of  the  programmer's  supported  IO voltage is within the
              supported voltage range of the detected flash chip  the  flashrom  will  abort  the
              operation (to prevent damaging the flash chip).  You can override this behaviour by
              passing "yes" to the ignore_io_voltage_limits parameter (for e.g. if you are  using
              an external voltage translator circuit).  Syntax is

                flashrom -p ni845x_spi:ignore_io_voltage_limits=yes

              You  can use the serial parameter to explicitly specify which connected NI USB-845x
              device should be used.  You should use your device's  7  digit  hexadecimal  serial
              number.  Usage example to select the device with 1230A12 serial number:

                flashrom -p ni845x_spi:serial=1230A12

              An optional spispeed parameter specifies the frequency of the SPI bus.  Syntax is

                flashrom -p ni845x_spi:spispeed=frequency

              where frequency should a number corresponding to the desired frequency in kHz.  The
              maximum frequency is 12 MHz (12000 kHz) for the USB-8451 and 50 MHz (50000 kHz) for
              the USB-8452.  The default is a frequency of 1 MHz (1000 kHz).

              An  optional  cs  parameter specifies which target chip select line should be used.
              Syntax is

                flashrom -p ni845x_spi:csnumber=value

              where value should be between 0 and 7 By default the CS0 is used.

   digilent_spi programmer
              An optional spispeed parameter specifies the frequency of the SPI bus.  Syntax is

                flashrom -p digilent_spi:spispeed=frequency

              where frequency can be 62.5k, 125k, 250k, 500k, 1M, 2M or 4M (in Hz).  The  default
              is a frequency of 4 MHz.

              dirtyjtag_spi programmer

              An optional freq parameter specifies the frequency of the SPI bus.  Syntax is

                flashrom -p dirtyjtag_spi:spispeed=frequency

              where    spispeed    can    be   anyvalueinhertz,kilohertzormegahertzsupportedbythe
              programmer. The default is a frequency of 100 KHz.

   jlink_spi programmer
              This module supports SEGGER J-Link and compatible devices.

              The MOSI signal of the flash chip must be attached to TDI pin  of  the  programmer,
              MISO  to  TDO and SCK to TCK.  The chip select (CS) signal of the flash chip can be
              attached to different pins of the programmer which can be selected with the

                flashrom -p jlink_spi:cs=pin

              syntax where pin can be either TRST or RESET.  The default pin for chip  select  is
              RESET.   Note  that,  when  using RESET, it is normal that the indicator LED blinks
              orange or red.
              Additionally, the VTref pin of the programmer must be attached to the  logic  level
              of  the  flash chip.  The programmer measures the voltage on this pin and generates
              the reference voltage for its input comparators and adapts its output  voltages  to
              it.

              Pinout for devices with 20-pin JTAG connector:

                  +-------+
                  |  1  2 |     1: VTref     2:
                  |  3  4 |     3: TRST      4: GND
                  |  5  6 |     5: TDI       6: GND
                +-+  7  8 |     7:           8: GND
                |    9 10 |     9: TCK      10: GND
                |   11 12 |    11:          12: GND
                +-+ 13 14 |    13: TDO      14:
                  | 15 16 |    15: RESET    16:
                  | 17 18 |    17:          18:
                  | 19 20 |    19: PWR_5V   20:
                  +-------+

              If  there  is  more  than one compatible device connected, you can select which one
              should be used by specifying its serial number with the

                flashrom -p jlink_spi:serial=number

              syntax where number is the serial number of the device  (which  can  be  found  for
              example in the output of lsusb -v).

              The SPI speed can be selected by using the

                flashrom -p jlink_spi:spispeed=frequency

              syntax  where  frequency  is  the  SPI  clock  frequency in kHz.  The maximum speed
              depends on the device in use.

              The power=on option can be used to activate the 5 V power supply (PWR_5V) of the J-
              Link during a flash operation.

   stlinkv3_spi programmer
              This module supports SPI flash programming through the STMicroelectronics STLINK V3
              programmer/debugger's SPI bridge interface

                flashrom -p stlinkv3_spi

              If there is more than one compatible device connected, you  can  select  which  one
              should be used by specifying its serial number with the

                flashrom -p stlinkv3_spi:serial=number

              syntax  where  number  is  the  serial number of the device (which can be found for
              example in the output of lsusb -v).

              The SPI speed can be selected by using the

                flashrom -p stlinkv3_spi:spispeed=frequency

              syntax where frequency is the SPI clock frequency in kHz.  If the passed  frequency
              is not supported by the adapter the nearest lower supported frequency will be used.

   realtek_mst_i2c_spi , parade_lspcon ,and mediatek_i2c_spi programmers
              These  programmers  tunnel  SPI commands through I2C-connected devices. The I2C bus
              over which communication occurs must be specified either by device  path  with  the
              devpath option:

                flashrom -p realtek_mst_i2c_spi:devpath=/dev/i2c-8

              or by a bus number with the bus option, which implies a device path like /dev/i2c-N
              where N is the specified bus number:

                flashrom -p parade_lspcon:bus=8

   realtek_mst_i2c_spi programmer
              This programmer supports SPI  flash  programming  for  chips  attached  to  Realtek
              DisplayPort MST hubs, themselves accessed through I2C (tunneling SPI flash commands
              through the MST hub's I2C connection with the host).

       In-system programming (ISP) mode

              The reset_mcu and enter_isp options provide control over device mode changes, where
              each can be set to 0 or 1 to enable or disable the corresponding mode transition.

              enter_isp  defaults  to  1,  and if enabled will issue commands to the MST hub when
              beginning operation to put it into ISP mode.

              reset_mcu defaults to 0, and if enabled will issue a reset command to the  MST  hub
              on  programming  completion,  causing  it  to  exit  ISP mode and to reload its own
              firmware from flash.

              allow_brick defaults to no, however must be set explicitly to "yes"  to  allow  the
              driver to run if you are sure you have a MST chip.

              The  hub  must be in ISP mode for SPI flash access to be possible, so it is usually
              only useful to disable enter_isp if an earlier invocation avoided resetting  it  on
              completion.  For instance, to erase the flash and rewrite it with the contents of a
              file  without  resetting  in  between  (which  could  render  it  nonfunctional  if
              attempting to load firmware from a blank flash):

                flashrom -p realtek_mst_i2c_spi:bus=0,enter_isp=1,reset_mcu=0 -E
                flashrom -p realtek_mst_i2c_spi:bus=0,enter_isp=0,reset_mcu=1 -w new.bin

   parade_lspcon programmer
              This  programmer  supports  SPI  flash  programming  for  chips  attached to Parade
              Technologies DisplayPort-to-HDMI level shifter/protocol converters (LSPCONs),  e.g.
              the PS175. Communication to the SPI flash is tunneled through the LSPCON over I2C.

   mediatek_i2c_spi programmer
              This  programmer supports SPI flash programming for chips attached to some Mediatek
              display controllers, themselves accessed through I2C (tunneling SPI flash  commands
              through an I2C connection with the host).

              The programmer is designed to support the TSUMOP82JUQ integrated display driver and
              scaler as used in the Google Meet Series One Desk  27  (which  runs  a  version  of
              ChromeOS  and  uses  flashrom in its tsum-scaler-updater scripts that ship with the
              OS). Other chips may use compatible protocols but have not been  tested  with  this
              programmer,  and  external  chip  IOs  may need to be controlled through other non-
              flashrom means to configure the chip in order for it to operate as expected.

              devpath and bus options select  the  I2C  bus  to  use,  as  described  previously.
              allow_brick  defaults  to  no, and must explicitly be set to "yes" in order for the
              programmer to operate. This is required because there is no mechanism in the driver
              to  positively  identify  that a given I2C bus is actually connected to a supported
              device.

EXAMPLES

       To back up and update your BIOS, run

       flashrom -p internal -r backup.rom -o backuplog.txt
       flashrom -p internal -w newbios.rom -o writelog.txt

       Please make sure to copy backup.rom to some external media before you try to  write.  That
       makes offline recovery easier.
       If  writing fails and flashrom complains about the chip being in an unknown state, you can
       try to restore the backup by running

       flashrom -p internal -w backup.rom -o restorelog.txt

       If you encounter any problems, please contact us and  supply  backuplog.txt,  writelog.txt
       and restorelog.txt. See section BUGS for contact info.

EXIT STATUS

       flashrom exits with 0 on success, 1 on most failures but with 3 if a call to mmap() fails.

REQUIREMENTS

       flashrom needs different access permissions for different programmers.

       internal  needs  raw  memory  access,  PCI configuration space access, raw I/O port access
       (x86) and MSR access (x86).

       atavia needs PCI configuration space access.

       nic3com, nicrealtek and nicnatsemi need PCI configuration space read access  and  raw  I/O
       port access.

       atahpt needs PCI configuration space access and raw I/O port access.

       gfxnvidia, drkaiser and it8212 need PCI configuration space access and raw memory access.

       rayer_spi needs raw I/O port access.

       raiden_debug_spi need access to the respective USB device via libusb API version 1.0.

       satasii,  nicintel,  nicintel_eeprom  and  nicintel_spi  need PCI configuration space read
       access and raw memory access.

       satamv and atapromise need PCI configuration space read access, raw I/O  port  access  and
       raw memory access.

       serprog needs TCP access to the network or userspace access to a serial port.

       buspirate_spi needs userspace access to a serial port.

       ft2232_spi,  usbblaster_spi  and  pickit2_spi need access to the respective USB device via
       libusb API version 0.1.

       ch341a_spi and dediprog need access to the respective USB device via  libusb  API  version
       1.0.

       dummy needs no access permissions at all.

       internal,  nic3com,  nicrealtek, nicnatsemi, gfxnvidia, drkaiser, satasii, satamv, atahpt,
       atavia and atapromise have to be run as superuser/root, and  need  additional  raw  access
       permission.

       serprog,  buspirate_spi,  dediprog,  usbblaster_spi,  ft2232_spi, pickit2_spi, ch341a_spi,
       digilent_spi and dirtyjtag_spi can be run as normal user  on  most  operating  systems  if
       appropriate device permissions are set.

       ogp needs PCI configuration space read access and raw memory access.

       realtek_mst_i2c_spi and parade_lspcon need userspace access to the selected I2C bus.

       On   OpenBSD,   you  can  obtain  raw  access  permission  by  setting  securelevel=-1  in
       /etc/rc.securelevel and rebooting, or rebooting into single user mode.

BUGS

       You can report bugs, ask us questions  or  send  success  reports  via  our  communication
       channels listed here: https://www.flashrom.org/Contact.

       Also,  we  provide  a pastebin service ⟨https://paste.flashrom.org⟩ that is very useful to
       share logs without spamming the communication channels.

   Laptops
       Using flashrom on older laptops is dangerous and may easily make your  hardware  unusable.
       flashrom  will  attempt  to  detect  if it is running on a susceptible laptop and restrict
       flash-chip probing for safety reasons. Please see the detailed discussion  of  this  topic
       and  associated  flashrom  options  in  the  Laptops  paragraph in the internal programmer
       subsection of the PROGRAMMER-SPECIFIC INFORMATION section and the information in our  wiki
       ⟨https://flashrom.org/Laptops⟩.

   One-time programmable (OTP) memory and unique IDs
       Some  flash  chips contain OTP memory often denoted as "security registers".  They usually
       have a capacity in the range of some bytes to a few hundred bytes and can be used to  give
       devices  unique  IDs  etc.   flashrom  is not able to read or write these memories and may
       therefore not be able to duplicate a chip completely. For chip types known to include  OTP
       memories a warning is printed when they are detected.

       Similar  to  OTP  memories  are unique, factory programmed, unforgeable IDs.  They are not
       modifiable by the user at all.

LICENSE

       flashrom is covered by the GNU General Public License (GPL), version  2.  Some  files  are
       additionally available under any later version of the GPL.

COPYRIGHT

       Please see the individual files.

AUTHORS

       Andrew Morgan
       Anastasia Klimchuk
       Carl-Daniel Hailfinger
       Claus Gindhart
       David Borg
       David Hendricks
       Dominik Geyer
       Edward O'Callaghan
       Eric Biederman
       Giampiero Giancipoli
       Helge Wagner
       Idwer Vollering
       Joe Bao
       Joerg Fischer
       Joshua Roys
       Kyösti Mälkki
       Luc Verhaegen
       Li-Ta Lo
       Mark Marshall
       Markus Boas
       Mattias Mattsson
       Michael Karcher
       Nikolay Petukhov
       Patrick Georgi
       Peter Lemenkov
       Peter Stuge
       Reinder E.N. de Haan
       Ronald G. Minnich
       Ronald Hoogenboom
       Sean Nelson
       Stefan Reinauer
       Stefan Tauner
       Stefan Wildemann
       Stephan Guilloux
       Steven James
       Urja Rannikko
       Uwe Hermann
       Wang Qingpei
       Yinghai Lu
       some others, please see the flashrom git history for details.
       All still active authors can be reached via the mailing list ⟨flashrom@flashrom.org⟩.

       This  manual page was written by Uwe Hermann ⟨uwe@hermann-uwe.de⟩, Carl-Daniel Hailfinger,
       Stefan Tauner and others.  It is licensed under the terms of the GNU  GPL  (version  2  or
       later).