Documentation/fmc/fmc-write-eeprom.txt - pub/scm/linux/kernel/git/davem/net-next - Git at Google

 fmc-write-eeprom
 ================

 This module is designed to load a binary file from /lib/firmware and to
 write it to the internal EEPROM of the mezzanine card. This driver uses
 the `busid' generic parameter.

 Overwriting the EEPROM is not something you should do daily, and it is
 expected to only happen during manufacturing. For this reason, the
 module makes it unlikely for the random user to change a working EEPROM.

 However, since the EEPROM may include application-specific information
 other than the identification, later versions of this packages added
 write-support through sysfs. See *note Accessing the EEPROM::.

 To avoid damaging the EEPROM content, the module takes the following
 measures:

    * It accepts a `file=' argument (within /lib/firmware) and if no
      such argument is received, it doesn't write anything to EEPROM
      (i.e. there is no default file name).

    * If the file name ends with `.bin' it is written verbatim starting
      at offset 0.

    * If the file name ends with `.tlv' it is interpreted as
      type-length-value (i.e., it allows writev(2)-like operation).

    * If the file name doesn't match any of the patterns above, it is
      ignored and no write is performed.

    * Only cards listed with `busid=' are written to. If no busid is
      specified, no programming is done (and the probe function of the
      driver will fail).


 Each TLV tuple is formatted in this way: the header is 5 bytes,
 followed by data. The first byte is `w' for write, the next two bytes
 represent the address, in little-endian byte order, and the next two
 represent the data length, in little-endian order. The length does not
 include the header (it is the actual number of bytes to be written).

 This is a real example: that writes 5 bytes at position 0x110:

         spusa.root# od -t x1 -Ax /lib/firmware/try.tlv
         000000 77 10 01 05 00 30 31 32 33 34
         00000a
         spusa.root# insmod /tmp/fmc-write-eeprom.ko busid=0x0200 file=try.tlv
         [19983.391498] spec 0000:03:00.0: write 5 bytes at 0x0110
         [19983.414615] spec 0000:03:00.0: write_eeprom: success

 Please note that you'll most likely want to use SDBFS to build your
 EEPROM image, at least if your mezzanines are being used in the White
 Rabbit environment. For this reason the TLV format is not expected to
 be used much and is not expected to be developed further.

 If you want to try reflashing fake EEPROM devices, you can use the
 fmc-fakedev.ko module (see *note fmc-fakedev::).  Whenever you change
 the image starting at offset 0, it will deregister and register again
 after two seconds.  Please note, however, that if fmc-write-eeprom is
 still loaded, the system will associate it to the new device, which
 will be reprogrammed and thus will be unloaded after two seconds.  The
 following example removes the module after it reflashed fakedev the
 first time.

      spusa.root# insmod fmc-fakedev.ko
         [   72.984733]  fake-fmc: Manufacturer: fake-vendor
         [   72.989434]  fake-fmc: Product name: fake-design-for-testing
         spusa.root# insmod fmc-write-eeprom.ko busid=0 file=fdelay-eeprom.bin; \
             rmmod fmc-write-eeprom
         [  130.874098]  fake-fmc: Matching a generic driver (no ID)
         [  130.887845]  fake-fmc: programming 6155 bytes
         [  130.894567]  fake-fmc: write_eeprom: success
         [  132.895794]  fake-fmc: Manufacturer: CERN
         [  132.899872]  fake-fmc: Product name: FmcDelay1ns4cha


 Accessing the EEPROM
 =====================

 The bus creates a sysfs binary file called eeprom for each mezzanine it
 knows about:

         spusa.root# cd /sys/bus/fmc/devices; ls -l */eeprom
         -r--r--r-- 1 root root 8192 Feb 21 12:30 FmcAdc100m14b4cha-0800/eeprom
         -r--r--r-- 1 root root 8192 Feb 21 12:30 FmcDelay1ns4cha-0200/eeprom
         -r--r--r-- 1 root root 8192 Feb 21 12:30 FmcDio5cha-0400/eeprom

 Everybody can read the files and the superuser can also modify it, but
 the operation may on the carrier driver, if the carrier is unable to
 access the I2C bus.  For example, the spec driver can access the bus
 only with its golden gateware: after a mezzanine driver reprogrammed
 the FPGA with a custom circuit, the carrier is unable to access the
 EEPROM and returns ENOTSUPP.

 An alternative way to write the EEPROM is the mezzanine driver
 fmc-write-eeprom (See *note fmc-write-eeprom::), but the procedure is
 more complex.
	fmc-write-eeprom
	================

	This module is designed to load a binary file from /lib/firmware and to
	write it to the internal EEPROM of the mezzanine card. This driver uses
	the `busid' generic parameter.

	Overwriting the EEPROM is not something you should do daily, and it is
	expected to only happen during manufacturing. For this reason, the
	module makes it unlikely for the random user to change a working EEPROM.

	However, since the EEPROM may include application-specific information
	other than the identification, later versions of this packages added
	write-support through sysfs. See *note Accessing the EEPROM::.

	To avoid damaging the EEPROM content, the module takes the following
	measures:

	* It accepts a `file=' argument (within /lib/firmware) and if no
	such argument is received, it doesn't write anything to EEPROM
	(i.e. there is no default file name).

	* If the file name ends with `.bin' it is written verbatim starting
	at offset 0.

	* If the file name ends with `.tlv' it is interpreted as
	type-length-value (i.e., it allows writev(2)-like operation).

	* If the file name doesn't match any of the patterns above, it is
	ignored and no write is performed.

	* Only cards listed with `busid=' are written to. If no busid is
	specified, no programming is done (and the probe function of the
	driver will fail).


	Each TLV tuple is formatted in this way: the header is 5 bytes,
	followed by data. The first byte is `w' for write, the next two bytes
	represent the address, in little-endian byte order, and the next two
	represent the data length, in little-endian order. The length does not
	include the header (it is the actual number of bytes to be written).

	This is a real example: that writes 5 bytes at position 0x110:

	spusa.root# od -t x1 -Ax /lib/firmware/try.tlv
	000000 77 10 01 05 00 30 31 32 33 34
	00000a
	spusa.root# insmod /tmp/fmc-write-eeprom.ko busid=0x0200 file=try.tlv
	[19983.391498] spec 0000:03:00.0: write 5 bytes at 0x0110
	[19983.414615] spec 0000:03:00.0: write_eeprom: success

	Please note that you'll most likely want to use SDBFS to build your
	EEPROM image, at least if your mezzanines are being used in the White
	Rabbit environment. For this reason the TLV format is not expected to
	be used much and is not expected to be developed further.

	If you want to try reflashing fake EEPROM devices, you can use the
	fmc-fakedev.ko module (see *note fmc-fakedev::). Whenever you change
	the image starting at offset 0, it will deregister and register again
	after two seconds. Please note, however, that if fmc-write-eeprom is
	still loaded, the system will associate it to the new device, which
	will be reprogrammed and thus will be unloaded after two seconds. The
	following example removes the module after it reflashed fakedev the
	first time.

	spusa.root# insmod fmc-fakedev.ko
	[ 72.984733] fake-fmc: Manufacturer: fake-vendor
	[ 72.989434] fake-fmc: Product name: fake-design-for-testing
	spusa.root# insmod fmc-write-eeprom.ko busid=0 file=fdelay-eeprom.bin; \
	rmmod fmc-write-eeprom
	[ 130.874098] fake-fmc: Matching a generic driver (no ID)
	[ 130.887845] fake-fmc: programming 6155 bytes
	[ 130.894567] fake-fmc: write_eeprom: success
	[ 132.895794] fake-fmc: Manufacturer: CERN
	[ 132.899872] fake-fmc: Product name: FmcDelay1ns4cha


	Accessing the EEPROM
	=====================

	The bus creates a sysfs binary file called eeprom for each mezzanine it
	knows about:

	spusa.root# cd /sys/bus/fmc/devices; ls -l */eeprom
	-r--r--r-- 1 root root 8192 Feb 21 12:30 FmcAdc100m14b4cha-0800/eeprom
	-r--r--r-- 1 root root 8192 Feb 21 12:30 FmcDelay1ns4cha-0200/eeprom
	-r--r--r-- 1 root root 8192 Feb 21 12:30 FmcDio5cha-0400/eeprom

	Everybody can read the files and the superuser can also modify it, but
	the operation may on the carrier driver, if the carrier is unable to
	access the I2C bus. For example, the spec driver can access the bus
	only with its golden gateware: after a mezzanine driver reprogrammed
	the FPGA with a custom circuit, the carrier is unable to access the
	EEPROM and returns ENOTSUPP.

	An alternative way to write the EEPROM is the mezzanine driver
	fmc-write-eeprom (See *note fmc-write-eeprom::), but the procedure is
	more complex.