e100boot - Network and serial port bootloader for the ETRAX100 CPU.
e100boot [--device devicename] [--file filename|- addr [size]] [--flash ram-source flash-offset size] [--pause iter] [--memtest addr addr] [--memclear addr addr] [--memdump addr addr] [--setreg addr|regname val] [--getreg addr|regname] [--verify addr val] [--label label] [--loop addr label] [--5400] [--5600] [--testcard] [--devboard] [--testcardlx] [--network] [--serial] [--baudrate baudrate] [--bootfile file] [--jump addr] [--tofiles] [--cmdsonly] [--images] [--noleds] [--help]
This boot loader facilitates loading of files over the network or a serial port to an ETRAX100. It can also be used for fairly extensive hardware debugging as you can read and write to any memory addresses, including the ETRAX100 registers. You can also perform memory checks and dumps and copy data to flash memories.
The first packet (or the first 784 bytes in the case of serial boot) sent to Etrax100 is loaded into the cache. The code in this packet is executed and loads the rest of the boot loader into the cache. The cache is the only thing we can be sure of exists on all ETRAX100 products, so the boot loader is limited to the size of the cache, 8KB. If further boot loading code is needed you have to set up external memory and load another boot loader into it, but this is rarely needed.
Two programs are involved in this boot loading, one is the program on your workstation that sends the packets to ETRAX100, this is called the server boot loader or SBL. The other program is the one in ETRAX100 that receives packets from the SBL and acts upon the data therein, this is called the client boot loader or CBL.
We don't want to edit and recompile the CBL each time we want to load level two to different parts of memory, like we do on different products. We also want to change things like the setup of external memory before we load data into it. To make the boot loading as flexible as possible and separate the CBL from level two we send a configuration packet to it. After this packet we load other files, if we want to.
The configuration packet can contain information to the CBL which lets you: initialize external memory, read and write to all ETRAX100 registers, read and write to any part of memory, load as many other files as you like to any part of memory you like, etc. The configuration packet is generated on the fly by the SBL.
Since the CBL is unaware of which product it will be loaded on, it doesn't do product specific initialization like setting up the memory. This must be done with the configuration packet.
When doing network boot the debugging printout from the CBL in ETRAX is transmitted back over the network and printed by e100boot. When doing serial boot that interface will be used. So in either case you will not need any other software or hardware to receive the debugging printout.
The files containing code to be loaded on the ETRAX100 must be stripped using the standard GCC binutils.
ack, timeout bla, bla... RTFS.
Noteworthy is that two separate ETRAX100 binaries are created, one for network boot and one for serial boot. They actually contain exactly the same code, but linked in different order. This is because the code to load the rest of the bootloader over a specific interface must be contained in the first data sent to the ETRAX100 and it is too difficult to cram the code for both interfaces in the beginning of the same binary. Hence two files.
Other stuff you don't want to know is that the cache is mapped from 0x380000f0 to 0x380020f0. Code starts at the first address followed by data up to the symbol Ebss. At the other end is the buffer for boot commands (addresses defined by IO_BUF_START and IO_BUF_END below which the stack lies and hopefully the stack and Ebss will never meet...
The serial data is loaded from 0x380000f0 to 0x380003ff before execution starts.
The options are done in the order specified on the command line, so you probably want to do any memory setup before loading a file to the memory, and you probably do not want to perform a memory test after you have loaded a file to that memory.
All addresses and sizes must be in hex with optional '0x' prefix, or a ETRAX100 register name. Since the --setreg and --getreg options only can be performed on dword aligned dwords only the registers that conform to this can be named.
Note also that all addresses must be in uncached memory (bit 31 set), as the bootloader lies in the cache. If you access any uncached address during boot, the bootloader will be destroyed without warning.
It is also possible to specify an address as +address, in which case it is considered to be relative to IO_BUF_START. This is especially useful in combination with the --loop option below.
Set baudrate for files loaded after the boot loader.
Which boot image to send to ETRAX instead of the default ones.
Write the commands to file e100boot.cmds.
Sets registers for the developer board.
Which device to send packets on. For network boot the default is eth0. For serial boot it is ttyS0.
The file to load and the address to load it to. If file is loaded on stdin, specify filename '-' followed by a size. Size need only be given in this case. You can load as many files as you want, each specified with a --file.
Copies the specified RAM area to the flash.
Print value of memory location. Must be uncached address.
Print the help information.
Print information about the internal boot images, then exit.
Jump to specified address.
Define a label to be used as target by the --loop command. This command is only used by the SBL to calculate the address for the --loop and does not take up any space in the configuration packet.
If the contents of check-address is nonzero it is decremented and the command parser continues parsing at the label.
If no external memory is initialized yet it can be convenient to use an address in the area occupied by the configuration packet. Run e100boot with --help to see which addresses the commands are stored at. The size of the commands are four bytes for each command plus four bytes per argument to the command.
Clears the specified memory area.
Prints the contents of the specified memory area.
Does a fairly extensive test of the specified memory area. Not only catches defect memories but also catches things like wrong memory setups where memory addresses are mirrored onto each other.
Perform a network boot.
When using the internal images use a version that does not toggle general port PA or PB in ETRAX during the boot procedure.
How many iterations to do of an empty loop.
Do a serial boot.
Load dword to dword aligned memory location.
Configures the memories for the ETRAX 100 testcard.
Configures the memories for the ETRAX100 LX testcard.
Write packets to files e100boot.seq[0..]. Does not transmit the data.
Verify that memory contains dword. If not loader will stop. This is to avoid booting the wrong unit. If you have the units ethernet address in the flash memory you can check for that.
Sets R_WAITSTATES, R_DRAM_TIMING and R_DRAM_CONFIG for the 5400 printserver.
Sets R_WAITSTATES, R_DRAM_TIMING and R_DRAM_CONFIG for the 5600 printserver.
If you have a stripped binary (file.ima) linked to 0x08000000 that you want to boot via the network, do this:
e100boot --file file.ima 88000000 --jump 08000000
Or something like this. Sets waitstates to zero and loads two files, the first from stdin:
cat file.ima | e100boot --memtest 88000000 8801ffff --memclear 88000000 8801ffff --setreg b0000000 0 --getreg b0000000 --file - 88000000 a000 --file file2.ima 88010000 --memdump 88000000 880000ff --jump 08000000
Or this, enables 16 bit parallel port and flashes the led on PA0:
e100boot --testcardlx --setreg R_PORT_PA_SET 0x00000000 --setreg R_GEN_CONFIG 0x80000004 --setreg R_PAR0_CONFIG 0x00000200 --setreg R_PORT_G_DATA 0x00000000 --pause 0x02000000 --setreg R_PORT_G_DATA 0xffffffff --pause 0x02000000 --setreg R_PORT_G_DATA 0x00000000 --loop 0x38001e0b 0x38001e60
Setup the memory, test the SRAM, print the contents of the first 256 bytes of SRAM, clear SRAM, test the DRAM, print R_DMA_CH0_CMD, load a file to SRAM, load another file to SRAM, load file to DRAM, jump to code in SRAM.
e100boot --setreg b0000000 1000 --setreg b0000008 00006543 --setreg b000000c 12966060 --memtest 88000000 80000 --memdump 88000000 880000ff --memclear 88000000 80000 --memtest c0000000 400000 --getreg b00001d0 --file file1.ima 88000000 --file file2.ima 88010000 --file file3.ima c0000000 --jump 88000000
Boot Linux on the testcard.
e100boot --setreg b0000000 1000 --setreg b0000008 6557 --setreg b000000c 1b988080 --file timage c0000500 --jump 40000500
Booting over serial port and using labels to flash the leds on port PA.
e100boot --serial --device /dev/ttyS1 --baudrate 9600 --label first --setreg 0x380020e0 00000001 --setreg R_PORT_PA_SET 0x0000ff00 --pause 0x02000000 --setreg R_PORT_PA_SET 0x0000ffff --pause 0x02000000 --loop 0x380020e0 first
You're kidding, right? Check AUTHOR below. The only thing would be the hubris of the author, but that I consider a feature. If you find any other 'features' report them to technology@axis.com. Don't bother the author directly, he is busy playing PlayStation2.
Copyright © 1996-2002 Axis Communications AB.
Written by Ronny Ranerup.
The fine source, which you can get at http://developer.axis.com.