This contains nvmmac, a tool for modifying MAC addresses on Intel PHY NVM ("GbE") images, for use on coreboot machines where an Intel Flash Descriptor is present, defining a GbE region.
Leah Rowe 27a8fc3034 deprecation | 2 лет назад | |
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src | 2 лет назад | |
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README.md | 2 лет назад | |
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The nvmutils
project is now discontinued. Newer development is now
done in nvmutil
. Not to be confused. New project:
The nvmutils
project shall be preserved, for reference, but all new
development should go in nvmutil
instead.
This manual was last updated for nvmmac version 20220307, released on 2022-03-07. These programs allow you to manipulate Intel PHY NVM images, extracted from coreboot ROM images on Intel machines with an Intel PHY and IFD (Intel Flash Descriptor).
Below, you will find instructions that teach you how to compile the source code and make use of these programs. However, the first sections will go into some detail about exactly what this program is for, providing some background information about Intel PHY NVM images used on Intel machines.
You can find newer versions of nvmutils
by downloading it
from the official Git repository, like so:
git clone https://notabug.org/osboot/nvmutils
Releases of nvmutils are tagged, so you can use git tag
to find
which versions are officially available. You can switch to any
version, using git reset
. More information about Git is available
on the Git homepage:
The nvmutils
software is an official project within osboot:
On many Intel systems with an IFD (Intel Flash Descriptor), the Intel PHY (Gigabit Ethernet) stores its configuration, binary encoded, into a special region of the main boot flash, alongside other flash regions such as: IFD, ME, BIOS.
This includes many configurations, such as your MAC address.
The purpose of nvmmac
, supplied by the nvmutils project, is
precisely to allow you to change your MAC address. Many other
useful programs are also provided.
Intel defines this as the Gigabit Ethernet Non-Volative Memory or just NVM for short. It is a 128-byte section, consisting of 64 words that are 2 bytes, stored in little-endian byte order.
Newer Intel PHYs define an extended area, which starts
immediately after the main one, but the nvmutils
programs
do not modify or manipulate these in any way.
The final word in the NVM section is the checksum; all words
must add up, truncated, to the value 0xBABA
. The hardware
itself does not calculate or validate this, and will in
fact work nicely, but software such as Linux will check
that this is correct. If the checksum is invalid, your
kernel will refuse to make use of the NIC.
This NVM section is the first 128 bytes of a 4KB region in flash.
This 4KB region is then repeated, to make an 8KB region in
flash, known as the GbE region. In nvmutils
, the first part
is referred to as part 0 and the second part as part 1.
TODO: write here what actual PHYs are known to work.
This software is targeted at coreboot users, and users of coreboot distributions such as osboot, but this is a universal tool that is applicable to many Intel platforms, regardless of whether the user has coreboot or not.
You can learn about coreboot and osboot on these websites:
Coreboot is a free and open source firmware project, which has support for many different kinds of computers. The osboot project provides an easy-to-use automated build system and friendly instructions for installing coreboot, for non-technical users who may otherwise find coreboot quite daunting.
The chip containing your BIOS/UEFI firmware (or coreboot) has it, if you have an Intel PHY for gigabit ethernet.
The sections below will teach you how to obtain the GbE file, containing your NIC's configuration. This is the part that many people will struggle with, so we will dedicated an entire next section to it:
If you wish to operate on the GbE section that's already flashed, you should dump the current full ROM image. If you already have a ROM image, you do not need to dump it, so you can skip this section.
Download flashrom here:
Using recent flashrom versions, you can extract this region. If your regions are unlocked, you can run flashrom on the target system, like so:
flashrom -p internal -r rom.bin
If your system has two flash chips, the GbE region is usually
stored on SPI1 (not SPI2). Otherwise, it may be that you have
a single-flash setup. In that case, it's recommended to dump
both chips, as spi1.rom
and spi2.rom
; you can then cat
them together:
cat spi1.rom spi2.rom > rom.bin
If your GbE region is locked (per IFD settings), you can dump
and flash it using external flashing equipment. The osboot
project has a handy guide for this; it can be used for reading
from and writing to the chip. See:
If you're using an external programmer, the -p internal
option should be changed accordingly. Read flashrom
documentation, and make sure you have everything
properly configured.
The ifdtool
program is a powerful tool, allowing you to
manipulate Intel Flash Descriptors. It's part of coreboot,
available in the coreboot.git
repository
under util/ifdtool/
. Just go in there and build it
with make
, to get an ifdtool binary.
To make internal flashing possible later on, you might do:
ifdtool --unlock rom.bin
Running this command will create a modified image,
named rom.bin.new
. This file will have all regions set
to read-write, per configuration in the Intel Flash Descriptor.
In addition to unlocked regions, you may wish to neuter the
Intel Management Engine, removing all the nasty spying features
from it, using me_cleaner
. See:
coreboot.git
, undir util/
The me_cleaner
program is outside the scope of this
article, so you should read their documentation.
Now run this:
ifdtool -x rom.bin
Several files will be created, and the one you need to
operate on is named flashregion_3_gbe.bin
so please
ensure that you have this file.
Read the notes below about how to use nvmutils
programs,
operating on this file. When you're done, you can insert the
modified GbE file back into your ROM image, like so:
ifdtool -i gbe:flashregion_3_gbe.bin rom.bin
This will create the file rom.bin.new
, which contains
your modified GbE section with the NVM images inside; this
includes your MAC address.
Refer to flashrom documentation. You may flash the new ROM like so, if running on the same system and the regions are read-write:
flashrom -p internal -w rom.bin.new
Newer versions of flashrom support flashing just the specified region, like so:
flashrom -p internal --ifd -i gbe -w rom.bin.new
If you're running flashrom from host CPU on the target
system, and it's dual flash, you can just flash the
concatenated image, which you created earlier by running
the cat
program; dual-IC flash configurations appear to
your operating system as one large flash area, as though
it were a single chip.
If you're using an external programmer, you should change
the -p internal
parameter to something else. In this
situation, you should re-split the file accordingly, if
you have a dual-IC flash set, like so:
dd if=rom.bin.new of=spi2.rom bs=1M skip=8
dd if=rom.bin.new of=spi1.rom bs=1M count=8
These files would then be flashed externally, separately, using an external programmer.
The above example (using dd
) is for setups with 12MB
flash, where you have 8MB as SPI1 and 4MB as SPI2. SPI1
would contain the IFD, and SPI2 is the upper flash area
containing your bootblock; GbE is probably located in
SPI1. You should adjust the above parameters, according
to your configuration.
The nvmutils programs will work just fine, on any BSD operating system, or unix-like system such as GNU+Linux, Chimera Linux or Alpine Linux. You must be sure to have toolchains installed, for building; a normal libc, C compiler and linker should be enough. GCC and LLVM have all these things included, so use whichever one you want.
GCC and Clang both work quite well, and nvmutils
programs only
use standard C libraries. As such, you do not need to install any
third party header files.
First, ensure that the current working directory is your copy of the nvmutils source code!
You may run this in your terminal:
make
You can re-run make
to re-build the software, if you've
made modifications. Patches welcome!
The programs in nvmutils
have been written with portability
in mind. The code is endian-independent, so it should work on
any system. Furthermore, portable C99 integer types are used
extensively.
The code is cleanly written, and modular. It is written precisely with the Unix philosophy in mind: write one program that performs one task in the most efficient manner possible.
Thus, specific tasks are implemented by single-use programs within nvmutils. These programs share common code with each other. If you see some code in nvmutils that you think could be improved, patches are very welcome!
Use of non-portable data structures is avoided entirely.
Here, you may learn how to use each program:
The nvmmac
program lets you change the MAC address. It sets
a valid checksum, after changing the MAC address. This program
operates on both NVM parts, but it will only modify a given
part if the existing checksum is correct. It will exit with zero
status if at least one part is modified; otherwise, it will
exit with non-zero status (one).
How to use (the MAC address in just an example):
nvmmac gbe.bin 00:de:ad:be:ef:00
The reason nvmmac doesn't alter a part with an existing
invalid checksum, is precisely so that if the algorithm
changes in future Intel PHYs, nvmmac will just fail and
not modify your file. This is because the checksum would
then be invalid, at all times. However, correct NVM parts
with otherwise invalid checksums do exist, and can be
correct if you use the nvmfix
program as defined in
this document.
The nvmcheck
program shows a hexdump of both NVM parts, and
tells you whether each one is valid (as per checksum calculation).
How to use:
nvmcheck gbe.bin
The nvmcp
program copies one NVM part to another. It copies
the entire 4KB part, within the 8KB file.
Overwrite part 0 with the contents of part 1:
nvmcp gbe.bin 1
Overwrite part 1 with the contents of part 0:
nvmcp gbe.bin 0
The nvmswap
program simply swaps both 4KB parts in the GbE
file. It does this, via simple XOR swaps.
How to use:
nvmswap gbe.bin
The nvmfix
program calculates and sets a valid checksum, on
the desired NVM part. Usage:
Fix part 0:
nvmfix gbe.bin 0
Fix part 1:
nvmfix gbe.bin 1
The nvmbrick
program intentionally sets an invalid checksum, on
the desired NVM part. Usage:
Invalidate part 0:
nvmbrick gbe.bin 0
Invalidate part 1:
nvmbrick gbe.bin 1
That is all.
The nvmutils software and documentation are released under the following terms (Expat license):
Copyright 2022 Leah Rowe
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.