gnuboot/site/docs/install/spi.md

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---
title: Read/write 25XX NOR flash via SPI protocol
x-unreviewed: true
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...
This guide will teach you how to use various tools for externally reprogramming
a 25xx NOR flash via SPI protocol. This is the most common type of flash IC for
computers that coreboot runs on. Almost every system currently supported by
Libreboot uses this type of boot flash; the only exception is ASUS KFSN4-DRE,
which uses LPC flash in a PLCC32 socket, which you can simply hot-swap after
booting the vendor firmware, and then flash internally. Simple!
We will be using
the [flashrom](https://flashrom.org/Flashrom) software which is written to
dump, erase and rewrite these flash chips.
Libreboot currently documents how to use these SPI programmers:
* Raspberry Pi (RPi)
* BeagleBone Black (BBB)
Many other SPI programmers exist. More of them will be documented on this page,
at a date in the future.
Most systems in Libreboot have to be re-flashed externally, using instructions
on this and similar guides, the first time you flash. However, on all currently
supported systems, it's possible that you can re-flash *internally* when
Libreboot is running.
*Internal* flashing means that the host CPU on your system can re-program the
SPI flash, using an on-board SPI programmer (which all boards have). You do this
from GNU+Linux, with flashrom.
*This* guide that you're reading now is for using an *external* programmer. It
is called *external* because it's not the *internal* one on your mainboard.
Do not use CH341A!
==================
NOR flashes on Libreboot systems run on 3.3V DC, and this includes data lines.
CH341A has 5V logic levels on data lines, which will damage your SPI flash and
also the southbridge that it's connected to, plus anything else that it's
connected to.
These ch341a programmers are unfortunately very popular. DO NOT use it unless
you have fixed the issue. You CAN fix it so that the data lines are 3.3v, if
you follow the notes here:
<https://www.eevblog.com/forum/repair/ch341a-serial-memory-programmer-power-supply-fix/>
In practise, most people will not fix their ch341a and instead just risk it,
so no documentation will be provided for ch341a on this website. It is best
to discourage use of that device.
**Not covered on that eevblog page: the WP/HOLD pins (pins 3 and 7) must be held high via pull-up resistors, but on CH341A dongles, they are directly connected to 3.3V DC (continuity with pin 8). It is advisable to cut these two connections, to the WP and HOLD pins, and jump the cuts using pull-up resistors instead. A value between 1k to 10k (ohms) should be fine.**
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In case it's not clear:
Please do not buy the ch341a! It is incorrectly engineered for the purpose of
ROM flashing on systems with 3.3v SPI (which is most coreboot systems). DO NOT
USE IT! This issue still isn't fixed by the manufacturer, and it doesn't look
like they will ever fix it.
If you see someone talking about CH341A, please direct them to this page and
tell them why the CH341A is bad.
Identify which flash type you have
==================================
In all of them, a dot or marking shows pin 1 (in the case of WSON8, pad 1).
Use the following photos and then look at your board. When you've figured out
what type of chip you have, use that knowledge and the rest of this guide, to
accomplish your goal, which is to read from and/or write to the boot flash.
SOIC8
-----
![](/software/gnuboot/web/img/chip/soic8.jpg)
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SOIC16
------
![](/software/gnuboot/web/img/chip/soic16.jpg)
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SOIC8 and SOIC16 are the most common types, but there are others:
WSON8
-----
It will be like this on an X200S or X200 Tablet:\
![](/software/gnuboot/web/img/x200t_flash/X200T-flashchip-location.jpg)
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On T400S, it is in this location near the RAM:\
![](/software/gnuboot/web/img/t400s/soic8.jpg)\
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NOTE: in this photo, the chip has been replaced with SOIC8
DIP8
----
![](/software/gnuboot/web/img/dip8/dip8.jpg)
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Software configuration
======================
BeagleBone Black (BBB)
----------------------
SSH into your BeagleBone Black. It is assumed that you are running Debian 9 on
your BBB. You will run `flashrom` from your BBB.
NOTE: This section is out of date, because it is written for Debian 9 (running
on the BBB)
Run the following commands as root to enable spidev:
config-pin P9.17 spi_cs
config-pin P9.18 spi
config-pin P9.21 spi
config-pin P9.22 spi_sclk
Verify that the spidev devices now exist:
ls /dev/spidev*
Output:
/dev/spidev1.0 /dev/spidev1.1 /dev/spidev2.0 /dev/spidev2.1
Now the BBB is ready to be used for flashing. The following systemd service
file can optionally be enabled to make this persistent across reboots.
```
[Unit]
Description=Enable SPI function on pins
[Service]
Type=oneshot
ExecStart=config-pin P9.17 spi_cs
ExecStart=config-pin P9.18 spi
ExecStart=config-pin P9.21 spi
ExecStart=config-pin P9.22 spi_sclk
RemainAfterExit=yes
[Install]
WantedBy=multi-user.target
```
Now test flashrom:
./flashrom -p linux_spi:dev=/dev/spidev1.0,spispeed=512
It is important to use `spispeed=512` or a lower number such as 256 or 128,
because otherwise the BBB will be quite unstable.
Example output:
Calibrating delay loop... OK.
No EEPROM/flash device found.
Note: flashrom can never write if the flash chip isn't found automatically.
This means that it's working (the clip isn't connected to any flash
chip, so the error is fine).
Caution about BBB
-----------------
BeagleBone Black is not recommended, because it's very slow and unstable for
SPI flashing, and nowadays much better options exist. We used to mainly
recommend the BBB, because of the fact that it can be used with entirely Free
Software on it, but nowadays there are superior options.
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TODO: document other SPI flashers
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Rasberry Pi (RPi)
-----------------
SSH into your Raspberry Pi. You will run `flashrom` from your Raspberry Pi.
You must configure `spidev` on your Raspberry Pi. This is a special driver in
the Linux kernel; technically, the driver name is `spi-bcm2835`.
This page has info:\
<https://www.raspberrypi.org/documentation/hardware/raspberrypi/spi/README.md>
In your Raspberry Pi, which we assume you're running the latest Raspbian version
on, do this:
sudo raspi-config
Under the Interface section, you can enable SPI.
The device for communicating via SPI as at `/dev/spidev0.0`
Caution about RPi
-----------------
Basically, the Raspbian project, now called Raspberry Pi OS, put in their repo
an update that added a new "trusted" repository, which just so happened to be
a Microsoft software repository. They seem to have done this for VS Code, but
the problem here is that it gave Microsoft free reign to define whatever
dependencies they liked (as per apt-get rules), and every time you updated,
you would be pinging Microsoft servers. Do you think that is strange?
Microsoft shouldn't have *any* access to your GNU+Linux system! This was the
commit that Raspbian added to their distro, which added this what should rightly
be called a security vulnerability, intentionally:
* <https://github.com/RPi-Distro/raspberrypi-sys-mods/commit/655cad5aee6457b94fc2336b1ff3c1104ccb4351>
They then removed it, after a public backlash, via the following commits:
* <https://github.com/RPi-Distro/raspberrypi-sys-mods/commit/ed96790e6de281bc393b575c38aa8071ce39b555>
* <https://github.com/RPi-Distro/raspberrypi-sys-mods/commit/4d1afece91008f3787495b520ac03b53fef754c6>
For now, Raspbian / Raspberry Pi OS (which is based on Debian) should be safe,
but this whole episode proves that the distro can no longer be trusted to
respect its users. Therefore, it's now on the [tasks page](../../tasks/)
a TODO entry for recommending and documenting alternative GNU+Linux distros
on the Raspberry Pi, for the purposes of SPI flashing.
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Install flashrom
----------------
If you're using a BBB or RPi, you will do this while SSH'd into those.
Flashrom is the software that you will use, for dumping, erasing and rewriting
the contents of your NOR flash.
In the Libreboot build system, from the Git repository, you can download and
install flashrom. Do this after downloading the
[lbmk Git repository](https://git.sr.ht/~libreboot/lbmk):
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cd lbmk
sudo ./build install dependencies
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NOTE: debian, arch or void can be written instead of trisquel-10. the debian
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script is also applicable to newer ubuntu versions
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./download flashrom
./build module flashrom
If the script complains about missing dependencies, just modify the
resources/dependencies/trisquel-10 script and remove those dependencies.
The script is written for Ubuntu 20.04, but it should work fine in other
GNU/Linux distributions that use the `apt-get` package manager.
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A `flashrom/` directory will be present, with a `flashrom` executable inside
of it. If you got an error about missing package when running the dependencies
command above, tweak `resources/dependencies/trisquel-10`. That
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script downloads and installs build dependencies in apt-get and it is intended
for use on x86-64 systems running Ubuntu 20.04, but it should work in Raspbian
on the Raspberry Pi.
Alternatively, you may download flashrom directly from upstream
at <https://flashrom.org/Flashrom>
If you're flashing a Macronix flashchip on a ThinkPad X200, you will want to
use a special patched version of flashrom, which you can download here:
<https://vimuser.org/hackrom.tar.xz> - patched source code is available, and a
binary is also available that you can simply run. Pass the `--workaround-mx`
argument in flashrom. This mitigates stability issues.
If you downloaded the flashrom source code directly, you can go into the
directory and simply type `make`. In the Libreboot build system, build
dependencies are documented in scripts located in `resources/dependencies/`
which you can install using the `apt-get` software.
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How to use flashrom
===================
Read past these sections, further down this page, to learn about specific chip
types and how to wire them.
Reading
-------
Before flashing a new ROM image, it is highly advisable that you dump the
current chip contents to a file.
Run this command to see if 25xx flash is detected, with your RPi properly
wired.
sudo ./flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=32768
For BBB, you must use a lower speed and a different device path:
sudo ./flashrom -p linux_spi:dev=/dev/spidev1.0,spispeed=512
On BBB, never use a speed higher than `spispeed=512`. In some cases, you may
even need to go as low as `spispeed=128`. The BBB is highly unstable and
unreliable for SPI flashing. When you're reading, take multiple dumps and
verify that the checksums match, before you flash. You may have to flash your
chip several times!
NOTE: On some systems, higher speeds will be unstable. On those systems, try
lower speed like `spispeed=4096` or even `spispeed=2048` which should, in most
cases, work just fine but it will obviously be slower. The `spispeed=32768`
setting works just fine on most setups if you use short wires, within 10cm.
If flash chip is detected you may try reading (dumping) the flash contents now,
or you can try flashing it with a new ROM.
Dump it like so (RPi):
sudo ./flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=32768 -r dump.bin
For BBB, do this:
sudo ./flashrom -p linux_spi:dev=/dev/spidev1.0,spispeed=512 -r dump.bin
It is advisable to take a *2nd* dump, e.g. `dump2.bin`, and then check sha1sum:
sha1sum dump*.bin
If the checksums match, it indicates that you have a good dump. If they do not,
check your wiring. Wires should be within 10cm length for best stability, and
they should all be the same length (3.3V VCC and GND wires can be longer).
This advice is *especially* applicable to the BBB, which is highly unreliable.
Writing
-------
Next, run this command (RPi):
sudo ./flashrom -p linux_spi:dev=/dev/spidev0.0,spispeed=32768 -w /path/to/libreboot.rom
If using BBB:
sudo ./flashrom -p linux_spi:dev=/dev/spidev1.0,spispeed=512 -w /path/to/libreboot.rom
If using BBB, you may have to use a lower speed than 512. You may also have to
re-flash several times before it works fully.
Again, use a lower `spispeed` value if you need to, for stability.
Once that command outputs the following, the flash has completed
successfully. If not, just flash again.
Reading old flash chip contents... done.
Erasing and writing flash chip... Erase/write done.
Verifying flash... VERIFIED.
If it says "VERIFIED" or says that the chip contents are identical to the
requested image, then the chip is properly flashed.
Hardware configuration
======================
Refer to the above guidance about software configuration. The following advice
will teach you how to wire each type of flash chip.
WARNINGS
--------
Do not connect a 3.3V DC power source until your chip is otherwise properly
wired. For instance, do not connect a test clip that has 3.3V DC attached.
Do not *disconnect* your chip from the flasher until you've disconnected or
turned off the 3.3V DC power source.
BE CAREFUL that you are indeed supplying 3.3V DC to the chip. All SPI flashes
on all currently supported Libreboot hardware run on 3.3V DC and logic at that
level too.
It is important to CHECK that you are running on the correct voltage, when you
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do anything with these chips. Lower than 3.3V won't damage anything, but higher
will fry your chip (on most chips, the tolerated voltage range is between 2.7V
and 3.6V, but 3.3V is the most ideal level).
DO NOT connect more than 1 DC power source to your flash chip either!
Mixing voltages like that can easily cause damage to your equipment, and to
your chip/mainboard.
MISO/MOSI/CS/CLK lines
----------------------
You may want to add 47ohm series resistors on these lines, when flashing the
chips. Only do it on those lines (NOT the 3.3V or GND lines). This provides
some protection from over-current. On Intel platforms, the SPI flash is usually
connected via such resistors, directly to the Southbridge chipset.
ISP programming and VCC diode
-----------------------------
ISP means in-system programming. It's when you flash a chip that is already
mounted to the mainboard of your computer that you wish to install Libreboot
on.
It may be beneficial to modify the mainboard so that the SPI flash is powered
(on the VCC pin) through a diode, but please note: a diode will cause a voltage
drop. The tolerated range for VCC on these chips is 2.7V to 3.6V DC. If you do
this, please also ensure that the WP and HOLD pins are still held to a high
logic state; each via their own resistor (1K to 10K ohms) connected to the
*same* 3.3V DC source going through the diode.
The reason is simple: on most systems, the flash shares a common 3.3V DC rail
with many other components on the board, which draw a lot of current. Further,
if you accidentally provide too much voltage or cause an overcurrent, you could
fry those other components but if there is diode protection, you'll only fry
the boot flash (and it is very easy to replace, if you have good soldering
skills).
When you've placed the diode, ensure that VCC on the chip is isolated from all
other components on that board, which share the same 3.3V DC rail. Further,
ensure that the pull-up resistors for WP/HOLD are *only* connected to the side
of the diode that has continuity with the VCC pin (this is important because if
they're not, they won't be held high while doing ISP flashing, even if they're
still held high when the mainboard is fully powered on).
Furthermore: ensure that the SPI flash is operating at 2.7 to 3.6V when fully
powered on, after installing the diode.
If it's a desktop/workstation/server board (not a laptop), you could de-solder
the SOIC8/WSON8 if it uses that, and replace with an IC socket (for SOIC8,
WSON8 or DIP8, whatever you want), because then you could easily just insert
the flash into a breadboard when flashing.
TODO: Make a page on libreboot.srht.site, showing how to do this on all mainboards
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supported by Libreboot.
GPIO pins on BeagleBone Black (BBB)
-----------------------------------
Use this image for reference when connecting the pomona to the BBB:
<https://beagleboard.org/Support/bone101#headers> (D0 = MISO or connects
to MISO).
On that page, look at the *P9 header*. It is what you will use to wire up your
chip for flashing.
GPIO pins on Raspberry Pi (RPi)
-------------------------------
Diagram of the 26 GPIO Pins of the Raspberry Pi Model B (for the Model
B+ with 40 pins, start counting from the right and leave 14 pins):
![](/software/gnuboot/web/img/rpi/0012.png) ![](/software/gnuboot/web/img/rpi/0013.png)
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Use this as a reference for the other sections in this page, seen below:
SOIC8/DIP8/WSON8 wiring diagram
-------------------------------
Refer to this diagram:
Pin \# 25xx signal RPi(GPIO) BBB(P9 header)
------ ----------- ---------- --------------
1 CS 24 17
2 MISO 21 21
3 *not used* *not used* *not used*
4 GND 25 1
5 MOSI 19 18
6 CLK 23 22
7 *not used* *not used* *not used*
8 3.3V 1 3
On your SOIC8, there will be a dot in one of the corners. The dot is pin 1.
NOTE: pins 3 and 7 are WP/HOLD pins. If flashing a chip on a breadboard, please
use pull-up resistors on those (see notes below), and decoupling capacitor on
pin 8 (VCC).
NOTE: On X60/T60 thinkpads, don't connect pin 8. Instead, plug in your the PSU
to the charging port on your mainboard, but do not power on the mainboard. This
will provide a stable 3.3V voltage, with adequate current levels. On those
laptops, this is necessary because the flash shares a common 3.3V DC rail with
many other ICs that all draw quite a lot of current.
SOIC16 wiring diagram (Raspberry Pi)
------------------------------------
RPi GPIO header:\
![](/software/gnuboot/web/img/rpi/0009.png)
![](/software/gnuboot/web/img/rpi/0010.png)
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BBB P9 header:\
<https://beagleboard.org/static/images/cape-headers.png>
Refer to this diagram:
Pin \# 25xx signal RPi(GPIO) BBB(P9 header)
-------- -------------- ----------- --------------
1 *not used* *not used* *not used*
2 3.3V 1 3
3 *not used* *not used* *not used*
4 *not used* *not used* *not used*
5 *not used* *not used* *not used*
6 *not used* *not used* *not used*
7 CS\# 24 17
8 MISO 21 21
9 *not used* *not used* *not used*
10 GND 25 1
11 *not used* *not used* *not used*
12 *not used* *not used* *not used*
13 *not used* *not used* *not used*
14 *not used* *not used* *not used*
15 MOSI 19 18
16 SCLK 23 22
Refer to the RPi GPIO guide above, on this page.
On your SOIC16, there will be a dot in one of the corners. The dot is pin 1.
NOTE: pins 1 and 9 are WP/HOLD pins. If flashing a chip on a breadboard, please
use pull-up resistors on those (see notes below), and decoupling capacitor on
pin 2 (VCC).
Pull-up resistors and decoupling capacitors
-------------------------------------------
**Do this for chips mounted to a breadboard. Ignore this section if you're
flashing a chip that is already soldered to a mainboard.**
This section is only relevant if you're flashing a new chip that is not yet
mounted to a mainboard. You need pull-up resistors on the WP and HOLD pins,
and decoupling capacitors on the VCC pin. If the chip is already mounted to a
board, whether soldered or in a socket, these capacitors and resistors will
probably already exist on the board and you can just flash it without pulling
WP/HOLD high, and without capacitors(just connect your external 3.3V DC power
source).
The best way is as follows:
* Insert the DIP8 IC into a breadboard (2.54mm holes), if it's DIP8
* Insert WSON8 into a WSON8 socket and put on a breadboard, if WSON8
* Insert SOIC8 into a SOIC8 socket and put on a broadboard, if SOIN8
* Wire an SPI flasher, using 2.54mm dupont leads, to the breadboard, using
the correct wiring (see link to SPI flashing guides below)
SOIC8/WSON8/DIP8: pin 3 and 7 must be held to a high logic state, which means
that each pin
has its own pull-up resistor to VCC (from the 3.3v voltage plane that pin 8
connects to); anything from 1Kohm to 10Kohm will do. When you're flashing a chip
that's already on a laptop/desktop/server mainboard, pin 3 and 7 are likely
already held high, so you don't need to bother.
SOIC8/WSON8/DIP8: pin 8, which is 3.3v VCC, will already have decoupling capacitors on it
if the chip is on a mainboard, but lone chip flashing means that these capacitors
do not exist. A capacitor passes AC but blocks DC. Due to electromagnetic
indunctance, and RF noise from high-speed switching ICs, a DC voltage line isn't
actually straight (when viewed on an oscilloscope), but actually has low voltage
AC mixed in; on a particularly noisy line under high load, noise of around 300mV
or more is common. To smooth out that noise, you wire capacitors from the DC
line to ground, with the side of the capacitor on VCC as close to the IC's VCC
pin as possible. We recommend that you use ceramic capacitors for this purpose.
The recommended capacitors for this are: 100nF and 4.7uF ceramic capacitors.
Electrolytic capacitors are inferior for this, because they have higher ESR
(ceramic capacitors have super low ESR, which is very good for decoupling).
The result of using a decoupling capacitor is that some of the noise on the DC
line is filtered to ground, making the DC signal much cleaner/straighter (when
seen on an oscilloscope).
SOIC16: same as above, but use a SOIC16 socked on a breadboard. On SOIC16,
WP/HOLD are not pin 3/7 like above, but instead pins 1 and 9, so wire your
pull-up resistors on those. 3.3v VCC on SOIC16 is pin 2, so wire your
decoupling capacitors up on that.
SOIC8/WSON8/DIP8/SOIC16 not mounted to a mainboard
--------------------------------------------------
If your system has lower capacity SPI flash, you can upgrade. On *most* systems,
SPI flash is memory mapped and the maximum (in practise) that you can use is a
16MiB chip. For example, KGPE-D16 and KCMA-D8 mainboards in Libreboot have
2MiB flash by default, but you can easily upgrade these. Another example is the
ThinkPad X200S, X200 Tablet and T400S, all of which have WSON8 where the best
course of action is to replace it with a SOIC8 flash chip.
In all such cases, flashing a new chip should be done using a breadboard, not
a test clip. You will use 2.54mm dupont leads to connect your Raspberry Pi.
For data lines, make sure that all wires are the same length, and about 10cm
in length (don't use longer lengths than this).
Some advice:
* DIP8: Strong choice is Winbond W25Q128FVIQ. It is a direct drop-in replacement
* SOIC8 is possible: Winbond W25Q128FVSIG is a strong choice.
* DIP8 using adapter and SOIC8 is also possible. Use a 208-mil 1.27mm SOP8/SOIC8
to DIP8 adapter PCB with a
2.54mm 4-pin header on each side (square pins), then you can slot that in as
though it were a normal P-DIP 8 IC. This page shows a perfect example:
<https://coolcomponents.co.uk/products/soic-to-dip-adapter-8-pin>
* The above SOP8/DIP8 adapter is actually what we recommend, if you're going
that route. It's made by Sparkfun and widely available; you don't have to buy
from that particular website. The part number is: BOB-13655
* If you use a SOP/DIP adapter with a SOIC8 IC, you'll have to solder it
obviously. K tip is a nice choice for soldering ICs like these. Use good
flux and 60/40 leaded solder (or 63/37), none of that Rohs lead-free crap.
If you go for a SOIC8, mounted it to the SOP to DIP adapter (208mil 1.27mm one)
and solder 2.54mm headers to it. You could put the 2.54mm pins in a breadboard,
then solder the chip to the adapter PCB and mount that to the pins on the
breadboard, to keep it aligned, and solder that. Whith the PCB on the pins, and
the pins in the breadboard, push the pins inwards a little bit.
This is for a new SOIC8 chip, but you can get sockets similar to the one in the
video, but for WSON8. Sometimes they are called DFN8 or QFN8 sockets. Get one
that is 1.27mm pitch.
If you're flashing/dumping a lone WSON8, get a WSON8/QFN8/DFN8 socket (1.27mm
pitch) and mount it to a breadboard for flashing. If your mainboard's landing
pads for the flash IC can take a SOIC8, we recommend that you use a SOIC8
instead because a test clip is possible later on when you wish to re-flash it,
however you may be dealing with a board where replacing existing WSON8 with
SOIC8 is desirable; in that case, you might still want to dump the contents of
the original WSON8.
Here is a SOIC8 in a socket, mounted to a breadboard, for flashing:\
![](/software/gnuboot/web/img/rpi/soic8_socket.jpg)
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Here is a photo of a DIP8 IC:\
![](/software/gnuboot/web/img/dip8/dip8.jpg)
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Here is a photo of a SOIC8 in 1.27mm 208mil SOP to DIP adapter:\
![](/software/gnuboot/web/img/dip8/sop8todip8.jpg)
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NOTE: DIP8 and WSON8-in-socket, and SOIC16-in-socket, are basically the same,
just adapt accordingly.
If you're replacing a DIP8 but using SOIC8 on an adapter, solder it to the
adapter first, then insert 2.54mm headers (square pins) into a breadboard to
keep them aligned. Put the SOIC8 on the PCB, onto the pins, and push the pins
inwards a little bit, and solder that. Alternatively to the breadboard, you
can just put the 2.54mm pins directly in the DIP8 socket and mount the SOIC8 +
adapter onto that, and solder that. Use quality rosin flux (not acid based)
and good 60/40 or 63/37 leaded solder (don't use lead-free):
![](/software/gnuboot/web/img/dip8/adapter_breadboard.jpg)
![](/software/gnuboot/web/img/dip8/adapter.jpg)
![](/software/gnuboot/web/img/dip8/sop8todip8.jpg)
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SOIC8/SOIC16 soldered to a mainboard
------------------------------------
This is an example of *in-system programming* or *ISP* for short.
SOIC8:\
Pomona 5250 is a SOIC8 test clip. There are others available, but this is the
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best one. Use that. Use the SOIC8 diagram (see above) to wire up your Raspberry
Pi.
Your mainboard likely already pulls WP/HOLD (pins 3 and 7) high, so don't
connect these. 3.3v VCC on SOIC8's pin 8 probably already has decoupling
capacitors on the mainboard, so just hook that up without using a capacitor.
SOIC16:\
Pomona 5252 is a SOIC16 test clip. There are others available, but this is the
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best one. Use that. Use the SOIC16 diagram (see above) to wire up your Raspberry
Pi. WP/HOLD pins are pins 1 and 9, and likely already held high, so no pull-up
resistors needed. You do not need a decoupling capacitor for pin 2 (VCC) either
because the mainboard will already have one.
Here is an example of a test clip connected for SOIC16:\
![](/software/gnuboot/web/img/rpi/0002.jpg)
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And here is an example photo for SOIC8:\
![](/software/gnuboot/web/img/x60/th_bbb_flashing.jpg)
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DIP8 soldered to the mainboard
------------------------------
It is extremely cursed for DIP8 to be soldered directly to the mainboard. It is
usually mounted to a socket.
The pins are large enough that you can just use test hooks to wire up your chip
for flashing. You might want to de-solder the chip, using a solder vacuum
(extractor) tool, and then you can install a socket in its place. You can then
insert the DIP8 IC into the socket.
In the Libreboot project, we have never heard of a board where the DIP8 is
directly soldered. It is almost always mounted in a socket.
Your DIP8 IC has the same pinout as a SOIC8 IC.
Replace WSON8 IC with SOIC8
---------------------------
You *can* connect a SOIC8 test clip, but you will struggle to get good
connections and it will be extremely unreliable. DO NOT solder to the pads of
the WSON8 directly; some people do this, but you shouldn't do it, because you
can easily damage the pads that way.
WSON8 has the same pinout as SOIC8, but it's a ball mounted QFN (quad flat
pack, no leads). There are no clips for it. Sometimes referred to as QFN8
On all currently supported Libreboot hardware, boards that have WSON8 can also
have a SOIC8 because the pads are long enough to accomodate either type of
chip.
A good choice of soldering iron would be a T12-D08 or T12-K tip, on a T12
soldering station. KSGER makes nice soldering stations:\
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<https://vid.puffyan.us/watch?v=w0nZCK7B-0U>
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The case on that KSGER station is not grounded by default, so you should
modify it to ground the case, in case of an electrical fault. This is for your
safety. This video shows how to do it:\
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<https://vid.puffyan.us/watch?v=-6IZ_sBgw8I>
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Use quality 60/40 or 63/37 lead+tin solder. Do not use lead-free! Lead-free is
not suitable for hobbyist use such as this. Use quality *rosin* flux. Fluxes
with an acid base should never be used. Amtech and MG Chemicals make good flux
pastes. Use it in a dispenser tube. Some of these fluxes will contain adapic
acid which has a low pH level, and it is simply used as a mild activator. So
long as you clean the flux afterwards, you should be fine.
Make sure to have a copper wire brush and a wet sponge handy. You wipe the iron
on the wire brush and tap it on the wet sponge(to remove oxides) to keep it
clean. Always clean your tip constantly. Also, after cleaning it, always re-tin
the tip with fresh solder, to prevent the tip from oxidizing!
Make sure to buy 99.9% isopropyl alcohol. Don't buy weaker solutions because
they contain water, and don't use other chemicals because most other chemicals
are corrosive. You use the isopropyl to clean the area you're soldering, before
soldering it, and then soak up the wet alcohol with a cloth. You will also use
it to clean off any flux that you used.
Use of flux is very important, to get a good solder joint, because it removes
oxides and prevents further oxidation during soldering, ensuring that the solder
flows properly, otherwise the solder will ball up and you won't get a good
joint.
In case you're not comfortable with soldering, we have some excellent videos
linked on the [FAQ page](../../faq.md) which you can watch.
WSON8 IC:\
![](/software/gnuboot/web/img/rpi/wson8/0001.jpg)
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Surround a large area around the chip with layers of kapton tape, and then
aluminium foil. This will act as a heat shield, to reduce the risk of re-flowing
other solder joints (which can make them turn into cold joints, and you risk
knocking them off of the board):\
![](/software/gnuboot/web/img/rpi/wson8/0002.jpg)\
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Notice that the kapton+foil does not cover the chip itself, or the solder pads.
It's important that these are exposed to the heat.
Use a hot air rework station, set to about 330-340C. The reason for the higher
temperature is because air doesn't conduct heat as efficiently as an iron, so
you must use a higher temperature. You should put lots of rosin flux above the
IC. Do not hold the nozel too close to the board. The diameter of the nozel
should be slightly higher than the length of the chip. Apply even heat, at high
air flow.
While blasting the chip with hot air, hold the chip with tweezers but do not
use any real force. Do not try to forcefully pry off the chip. Simply hold the
chip with your tweezers, gently nudging it until it feels like the chip can
move freely. While in this state, the solder is fully melted and the chip can
be lifted off with ease.
If you're doing it correctly, the chip will come off within 1 minute, like so:\
![](/software/gnuboot/web/img/rpi/wson8/0003.jpg)
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Add fresh solder to the pads, including the thermal pad:\
![](/software/gnuboot/web/img/rpi/wson8/0004.jpg)
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Now wick it out using a copper braid, dunked in rosin flux:\
![](/software/gnuboot/web/img/rpi/wson8/0005.jpg)
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Ensure that all of the solder is removed:\
![](/software/gnuboot/web/img/rpi/wson8/0006.jpg)\
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You will notice that one of the pads doesn't have all of the solder removed.
The pad on the top-left in this photo. This is intentional, to show you a
comparison for reference. The other pads are free of solder.
You *can* simply solder the chip unflashed, and flash it using a test clip.
Alternatively, you can put the SOIC8 in a socket on a breadboard, and flash it
before soldering it. If you wish to dump the contents of the WSON8, you can
put the removed WSON8 in a socket on a breadboard and dump it using your
SPI flasher.
Align the new SOIC8, and tack it in the corner pins. Then solder it fully. Use
lots of flux!\
![](/software/gnuboot/web/img/rpi/wson8/0007.jpg)\
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A T12-D08 tip is being used in this photo, but a mini chisel, mini hoof or
knife (e.g. T12-K) tip would be ideal.
Ensure that all the joints are perfect. A good solder joint is shiny, and with
concave fillets where the solder has flowed. Observe:\
![](/software/gnuboot/web/img/rpi/wson8/0008.jpg)
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After you're done, use a soft bristle brush and 99.9% isopropyl alcohol to
break up the remaining flux, then soak up the flux using a cloth, while the
alcohol is still wet. 99.9% isopropyl is the best liquid to use, because it
evaporates quickly and it does not leave a corrosive residue.
-------------------------------------------------------------------------------
LICENSING
=========
This page is released under different copyright terms than most other pages
on this website.
This page and the photos on it are available under
[CC BY SA 4.0](https://creativecommons.org/licenses/by-sa/4.0/legalcode.txt)
Check the Git repository for history of who owns what part of the document.
Photos showing a BeagleBone Black are under the normal GNU Free Documentation
license like other pages and images on this website, or you can use them under
the CC-BY-SA 4.0 license if you wish (I, Leah Rowe, own all BBB photos shown
on this page, except for the one on the beaglebone website, and that one is
merely linked here, instead of being hosted on the libreboot.srht.site/img server).
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This version of the page is hosted in the `lbwww` git repository, with images
for it hosted in the `lbwww-img` repository. Images and this page were both
forked from the *old* Libreboot git repository, which was available here:
<https://notabug.org/libreboot/libreboot/> (you can still download it but this
repository is no longer worked on. You can find both the website and images
under the `www/` and/or `docs/` directory, in that repository)