Flash memory

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Like other memory mapped hardware devices on the MIPS platform, Flash memory has an address range in KSEG1. This means that the memory is unmapped and uncached. An interesting, and important, piece of information is that all 4 megabytes of Flash memory is mapped 1-1 into the address range between 0xBC00 0000 and 0xBC3F FFFF. This allows for random read-access without using an interface to load the data a fixed amount of registers.


Contents

Data Locations

Stored on Flash memory are several important parts to make a backend work properly, some of these data points are listed below.

  • 0xBC00 1000 has backup NVRAM settings. If the "proper" settings become corrupt, CFE will replace the proper settings with these.
  • 0xBC00 1E00 holds the "true" MAC address of device. During CFE boot, this is the address that will be used. Once a full kernel has been loaded the MAC address may be different.
  • 0xBC00 1F00 holds the current CFE boot version (should be "v3.7" for WRT54GLs).
  • 0xBC00 2000 is the beginning of CFE code.
  • 0xBC03 F400 is a unique device ID (should match the NVRAM setting for eou_device_id).
  • 0xBC03 F408 is a unique private key for device (should match the NVRAM setting for eou_private_key).
  • 0xBC03 F508 is a unique public key for device (should match the NVRAM setting for eou_public_key).
  • 0xBC04 0000 is the beginning of the operating system kernel (Embedded Xinu or some Linux variant). Typically, this will be a gzipped version of the raw kernel code prefixed with a TRX header.
  • 0xBC3F 8000 is the location of proper NVRAM settings.

This is not a comprehensive list of memory locations within Flash memory, but a guide of where some values may be stored when trying to interface with a new system.

Writing Flash

Writing data to Flash memory is not simply a matter of writing data to the memory address. For the WRT54GL backends the common NOR type of Flash memory is used. As with all Flash memories there are certain properties that must be followed when storing data.

An important property of NOR based Flash memory is that each bit on Flash can only be changed from a 1 to a 0 and not the other way around. So if a byte has the pattern 1001 1101 only the high bits can be written. This presents an interesting challenge for efficient file system structures. Once a bit has been set to 0 and the operating system wishes to reset the bit to 1 a special erase command must be sent to the device. Because of this Flash memory is broken down into several distinct segments called erase blocks. These erase blocks can vary in size between Flash memory chips and even within the same chip. After sending the command to erase an erase block, the entire erase block will be set to 1s, allowing any data to be written. The specific method of erasing and writing data depends on the manufacturer of the underlying hardware. In general it is a matter of writing a sequence of values to a certain location to prepare the device, then writing the new data to the correct position. These operations are more detailed on the Flash driver page under physical layer.

Common Flash Interface

Luckily for software authors, the manufacturers of Flash memory have developed a standard for discovering information about a Flash device, called the Common Flash Interface (CFI). By implementing a CFI query routine, the operating system can discover what command set the chip implements (Intel, AMD, and Mitsubishi all have a standard command set and extended command set). Other information that can be queried is voltages, timeouts for writing and erasing, access mode (word or byte), device size (as 2^n), and information about up-to four erase block regions. The information about each erase block region will consist of the size of an erase block in the region and the number of equally sized erase blocks that exist in the regions.

NVRAM

While technically a misnomer, NVRAM (non-volatile random access memory) refers specifically to the platform settings stored across power cycles of the device. These settings will always begin 8 pages (32 kilobytes) away from the end of Flash memory. In the case of the WRT54GL, this means NVRAM settings are stored beginning at 0xBC3F 8000. At this point there is a 20 byte header which is laid out as follows:

 0                   1                   2                   3   
 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 
+---------------------------------------------------------------+
|                     magic number ('FLSH')                     |
+---------------------------------------------------------------+
|                length (header size + variables)               |
+---------------+---------------+-------------------------------+
|      CRC      |    version    |         SDRAM Init (?)        |
+---------------+---------------+-------------------------------+
|       SDRAM config (?)        |       SDRAM refresh (?)       |
+-------------------------------+-------------------------------+
|                        NCDL value (?)                         |
+---------------------------------------------------------------+

Several of the values are not used by Embedded Xinu as the values represent something that is not fully understood (all the SDRAM values and the NCDL value).

Immediately after the header begins the NVRAM settings as NULL delimited name=value tuples stored as plain text. It is possible that after the final tuple the settings are NULL character padded to the nearest 4 byte word.

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