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% How to program an SPI flash chip with the BeagleBone Black or Teensy 3.1
This document exists as a guide for reading from or writing to an SPI
flash chip with the BeagleBone Black, using the
[flashrom](http://flashrom.org/Flashrom) software. A BeagleBone Black,
rev. C was used when creating this guide, but earlier revisions may also
work.
**NOTE: this documentation may be outdated, and discusses configuring
SPI flashing on the default Debian system that the BBB sometimes comes
with. If you want an easier time, just use [BBB
ScrewDriver](https://www.coreboot.org/BBB_screwdriver) which comes
pre-configured.**
**This guide is written for Debian Wheezy 7.5, which is what came on the
BBB at the time this guide was written. This one:
<https://debian.beagleboard.org/images/bone-debian-7.8-lxde-4gb-armhf-2015-03-01-4gb.img.xz>**
There was no justification for a further section for the Teensy. Simply
refer to [this page on
flashrom.org](https://www.flashrom.org/Teensy_3.1_SPI_%2B_LPC/FWH_Flasher#ISP_Usage)
for information about how to set it up, and correlate that with the pins
on the SPI flash chip as per other guides in the libreboot documentation
for each board. At the time of writing, the teensy is tested for
flashing on the ThinkPad X200, but it should work for other targets.
here is a photo of the setup for the teensy:
<http://h5ai.swiftgeek.net/IMG_20160601_120855.jpg>
Onto the Beaglebone black\...
[Back to previous index](./)
Hardware requirements
=====================
Shopping list (pictures of this hardware is shown later):
- A [Flashrom](http://flashrom.org)-compatible external SPI
programmer: **BeagleBone Black**, sometimes referred to as 'BBB',
(rev. C) is highly recommended. You can buy one from
[Adafruit](https://www.adafruit.com) (USA),
[ElectroKit](http://electrokit.com) (Sweden) or any of the
distributors listed [here](http://beagleboard.org/black) (look below
'Purchase'). We recommend this product because we know that it
works well for our purposes and doesn't require any non-free
software.
- Electrical/insulative tape: cover the entire bottom surface of the
BBB (the part that rests on a surface). This is important, when
placing the BBB on top of a board so that nothing shorts. Most
hardware/electronics stores have this. Optionally, you can use the
bottom half of a [hammond plastic
enclosure](http://www.hammondmfg.com/1593HAM.htm#BeagleBoneBlack).
- Clip for connecting to the flash chip: if you have a SOIC-16 flash
chip (16 pins), you will need the **Pomona 5252** or equivalent. For
SOIC-8 flash chips (8 pins), you will need the **Pomona 5250** or
equivalent. Do check which chip you have, before ordering a clip.
Also, you might as well buy two clips or more since they break
easily. [Farnell element 14](http://farnell.com/) sells these and
ships to many countries. Some people find these clips difficult to
get hold of, especially in South America. If you know of any good
suppliers, please contact the libreboot project with the relevant
information. **If you can't get hold of a pomona clip, some other
clips might work, e.g. 3M, but they are not always reliable. You can
also directly solder the wires to the chip, if that suits you; the
clip is just for convenience, really.**
- **External 3.3V DC power supply**, for powering the flash chip: an
ATX power supply / PSU (common on Intel/AMD desktop computers) will
work for this. A lab PSU (DC) will also work (adjusted to 3.3V).
- Getting a multimeter might be worthwhile, to verify that it's
supplying 3.3V.
- **External 5V DC power supply** (barrel connector), for powering the
BBB: the latter can have power supplied via USB, but a dedicated
power supply is recommended. These should be easy to find in most
places that sell electronics. **OPTIONAL. Only needed if not
powering with the USB cable, or if you want to use [EHCI
debug](../misc/bbb_ehci.html)**.
- **Pin header / jumper cables** (2.54mm / 0.1" headers): you should
get male\--male, male\--female and female\--female cables in 10cm
size. Just get a load of them. Other possible names for these
cables/wires/leads are as follows:
- flying leads
- breadboard cables (since they are often used on breadboards).
- You might also be able to make these cables yourself.
[Adafruit](https://www.adafruit.com) sell them, as do many others.
**Some people find them difficult to buy. Please contact the
libreboot project if you know of any good sellers.** You might also
be able to make these cables yourself. For PSU connections, using
long cables, e.g. 20cm, is fine, and you can extend them longer than
that if needed.
- **Mini USB A-B cable** (the BeagleBone probably already comes with
one.) - **OPTIONAL - only needed for [EHCI
debug](../misc/bbb_ehci.html) or for serial/ssh access without
ethernet cable (g\_multi kernel module)**
- **FTDI TTL cable or debug board**: used for accessing the serial
console on the BBB. [This
page](http://elinux.org/Beagleboard:BeagleBone_Black_Serial)
contains a list. **OPTIONAL\-\--only needed for serial console on
the BBB, if not using SSH via ethernet cable.**
[Back to top of page.](#pagetop)
Setting up the 3.3V DC PSU
==========================
ATX PSU pinouts can be read on [this Wikipedia
page](https://en.wikipedia.org/wiki/Power_supply_unit_%28computer%29#Wiring_diagrams).
You can use pin 1 or 2 (orange wire) on a 20-pin or 24-pin ATX PSU for
3.3V, and any of the ground/earth sources (black cables) for ground.
Short PS\_ON\# / Power on (green wire; pin 16 on 24-pin ATX PSU, or pin
14 on a 20-pin ATX PSU) to a ground (black; there is one right next to
it) using a wire/paperclip/jumper, then power on the PSU by grounding
PS\_ON\# (this is also how an ATX motherboard turns on a PSU).
**DO \*\*NOT\*\* use pin 4, 6, do \*\*NOT\*\* use pin 19 or 20 (on a
20-pin ATX PSU), and DO \*\*NOT\*\* use pin 21, 22 or 23 (on a 24-pin
ATX PSU). Those wires (the red ones) are 5V, and they \*\*WILL\*\* kill
your flash chip. \*\*\*NEVER\*\*\* supply more than 3.3V to your flash
chip (that is, if it's a 3.3V flash chip; 5V and 1.8V SPI flash chips
do exist, but they are rare. Always check what voltage your chip takes.
Most of them take 3.3V).**
You only need one 3.3V supply and one ground for the flash chip, after
grounding PS\_ON\#.
The male end of a 0.1" or 2.54mm header cable is not thick enough to
remain permanently connected to the ATX PSU on its own. When connecting
header cables to the connector on the ATX PSU, use a female end attached
to a thicker piece of wire (you could use a paper clip), or wedge the
male end of the jumper cable into the sides of the hole in the
connector, instead of going through the centre.
Here is an example set up:\
![](images/x200/psu33.jpg "Copyright © 2015 Patrick "P. J." McDermott <pj@pehjota.net> see license notice at the end of this document")
Accessing the operating system on the BBB
=========================================
The operating system on your BBB will probably have an SSH daemon
running where the root account has no password. Use SSH to access the
operating system and set a root password. By default, the OS on your BBB
will most likely use DHCP, so it should already have an IP address.
You will also be using the OS on your BBB for programming an SPI flash
chip.
Alternatives to SSH (in case SSH fails)
---------------------------------------
You can also use a serial FTDI debug board with GNU Screen, to access
the serial console.\
\# **screen /dev/ttyUSB0 115200**\
Here are some example photos:\
![](images/x200/ftdi.jpg) ![](images/x200/ftdi_port.jpg)\
You can also connect the USB cable from the BBB to another computer and
a new network interface will appear, with its own IP address. This is
directly accessible from SSH, or screen:\
\# **screen /dev/ttyACM0 115200**
You can also access the uboot console, using the serial method instead
of SSH.
Setting up spidev on the BBB
============================
Log on as root on the BBB, using either SSH or a serial console as
defined in [\#bbb\_access](#bbb_access). Make sure that you have
internet access on your BBB.
Follow the instructions at
<http://elinux.org/BeagleBone_Black_Enable_SPIDEV#SPI0> up to (and
excluding) the point where it tells you to modify uEnv.txt
You need to update the software on the BBB first. If you have an
element14 brand BBB (sold by Premier Farnell plc. stores like Farnell
element14, Newark element14, and Embest), you may need to [work around a
bug](https://groups.google.com/forum/?_escaped_fragment_=msg/beagleboard/LPjCn4LEY2I/alozBGsbTJMJ#!msg/beagleboard/LPjCn4LEY2I/alozBGsbTJMJ)
in the LED aging init script before you can update your software. If you
don't have a file named /etc/init.d/led\_aging.sh, you can skip this
step and update your software as described below. Otherwise, replace the
contents of this file with:
#!/bin/sh -e
### BEGIN INIT INFO
# Provides: led_aging.sh
# Required-Start: $local_fs
# Required-Stop: $local_fs
# Default-Start: 2 3 4 5
# Default-Stop: 0 1 6
# Short-Description: Start LED aging
# Description: Starts LED aging (whatever that is)
### END INIT INFO
x=$(/bin/ps -ef | /bin/grep "[l]ed_acc")
if [ ! -n "$x" -a -x /usr/bin/led_acc ]; then
/usr/bin/led_acc &
fi
Run **apt-get update** and **apt-get upgrade** then reboot the BBB,
before continuing.
Check that the firmware exists:\
\# **ls /lib/firmware/BB-SPI0-01-00A0.\***\
Output:
/lib/firmware/BB-SPI0-01-00A0.dtbo
Then:\
\# **echo BB-SPI0-01 > /sys/devices/bone\_capemgr.\*/slots**\
\# **cat /sys/devices/bone\_capemgr.\*/slots**\
Output:
0: 54:PF---
1: 55:PF---
2: 56:PF---
3: 57:PF---
4: ff:P-O-L Bone-LT-eMMC-2G,00A0,Texas Instrument,BB-BONE-EMMC-2G
5: ff:P-O-L Bone-Black-HDMI,00A0,Texas Instrument,BB-BONELT-HDMI
7: ff:P-O-L Override Board Name,00A0,Override Manuf,BB-SPI0-01
Verify that the spidev device now exists:\
\# **ls -al /dev/spid\***\
Output:
crw-rw---T 1 root spi 153, 0 Nov 19 21:07 /dev/spidev1.0
Now the BBB is ready to be used for flashing. Make this persist across
reboots:\
In /etc/default/capemgr add **CAPE=BB-SPI0-01** at the end (or change
the existing **CAPE=** entry to say that, if an entry already exists.
Get flashrom from the libreboot\_util release archive, or build it from
libreboot\_src/git if you need to. An ARM binary (statically compiled)
for flashrom exists in libreboot\_util releases. Put the flashrom binary
on your BBB.
You may also need ich9gen, if you will be flashing an ICH9-M laptop
(such as the X200). Get it from libreboot\_util, or build it from
libreboot\_src, and put the ARM binary for it on your BBB.
Finally, get the ROM image that you would like to flash and put that on
your BBB.
Now test flashrom:\
\# **./flashrom -p linux\_spi:dev=/dev/spidev1.0,spispeed=512**\
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).
Connecting the Pomona 5250/5252
===============================
Use this image for reference when connecting the pomona to the BBB:
<http://beagleboard.org/Support/bone101#headers> (D0 = MISO or connects
to MISO).
The following shows how to connect clip to the BBB (on the P9 header),
for SOIC-16 (clip: Pomona 5252):
NC - - 21
1 - - 17
NC - - NC
NC - - NC
NC - - NC
NC - - NC
18 - - 3.3V (PSU)
22 - - NC - this is pin 1 on the flash chip
This is how you will connect. Numbers refer to pin numbers on the BBB, on the plugs near the DC jack.
You may also need to connect pins 1 and 9 (tie to 3.3V supply). These are HOLD# and WP#.
On some systems they are held high, if the flash chip is attached to the board.
If you're flashing a chip that isn't connected to a board, you'll almost certainly
have to connect them.
SOIC16 pinout (more info available online, or in the datasheet for your flash chip):
HOLD 1-16 SCK
VDD 2-15 MOSI
N/C 3-14 N/C
N/C 4-13 N/C
N/C 5-12 N/C
N/C 6-11 N/C
SS 7-10 GND
MISO 8-9 WP
The following shows how to connect clip to the BBB (on the P9 header),
for SOIC-8 (clip: Pomona 5250):
18 - - 1
22 - - NC
NC - - 21
3.3V (PSU) - - 17 - this is pin 1 on the flash chip
This is how you will connect. Numbers refer to pin numbers on the BBB, on the plugs near the DC jack.
You may also need to connect pins 3 and 7 (tie to 3.3V supply). These are HOLD# and WP#.
On some systems they are held high, if the flash chip is attached to the board.
If you're flashing a chip that isn't connected to a board, you'll almost certainly
have to connect them.
SOIC8 pinout (more info available online, or in the datasheet for your flash chip):
SS 1-8 VDD
MISO 2-7 HOLD
WP 3-6 SCK
GND 4-5 MOSI
**NC = no connection**
**DO NOT connect 3.3V (PSU) yet. ONLY connect this once the pomona is
connected to the flash chip.**
**You also need to connect the BLACK wire (ground/earth) from the 3.3V
PSU to pin 2 on the BBB (P9 header). It is safe to install this now
(that is, before you connect the pomona to the flash chip); in fact, you
should.**
if you need to extend the 3.3v psu leads, just use the same colour M-F
leads, **but** keep all other leads short (10cm or less)
You should now have something that looks like this:\
![](images/x200/5252_bbb0.jpg) ![](images/x200/5252_bbb1.jpg)
[Back to top of page.](#pagetop)
Notes about stability {#stability}
=====================
<http://flashrom.org/ISP> is what we typically do in libreboot, though
not always. That page has some notes about using resistors to affect
stability. Currently, we use spispeed=512 (512kHz) but it is possible to
use higher speeds while maintaining stability.
tty0\_ in \#libreboot was able to get better flashing speeds with the
following configuration:
- "coax" with 0.1 mm core and aluminum foley (from my kitchen), add
100 Ohm resistors (serial)
- put heatshrink above the foley, for: CS, CLK, D0, D1
- Twisted pair used as core (in case more capacitors are needed)
- See this image: <http://i.imgur.com/qHGxKpj.jpg>
- He was able to flash at 50MHz (lower speeds are also fine).
Copyright © 2014, 2015 Leah Rowe <info@minifree.org>\
Copyright © 2015 Patrick "P. J." McDermott <pj@pehjota.net>\
Copyright © 2015 Albin Söderqvist\
Permission is granted to copy, distribute and/or modify this document
under the terms of the Creative Commons Attribution-ShareAlike 4.0
International license or any later version published by Creative
Commons; A copy of the license can be found at
[../cc-by-sa-4.0.txt](../cc-by-sa-4.0.txt)
Updated versions of the license (when available) can be found at
<https://creativecommons.org/licenses/by-sa/4.0/legalcode>
UNLESS OTHERWISE SEPARATELY UNDERTAKEN BY THE LICENSOR, TO THE EXTENT
POSSIBLE, THE LICENSOR OFFERS THE LICENSED MATERIAL AS-IS AND
AS-AVAILABLE, AND MAKES NO REPRESENTATIONS OR WARRANTIES OF ANY KIND
CONCERNING THE LICENSED MATERIAL, WHETHER EXPRESS, IMPLIED, STATUTORY,
OR OTHER. THIS INCLUDES, WITHOUT LIMITATION, WARRANTIES OF TITLE,
MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, NON-INFRINGEMENT,
ABSENCE OF LATENT OR OTHER DEFECTS, ACCURACY, OR THE PRESENCE OR ABSENCE
OF ERRORS, WHETHER OR NOT KNOWN OR DISCOVERABLE. WHERE DISCLAIMERS OF
WARRANTIES ARE NOT ALLOWED IN FULL OR IN PART, THIS DISCLAIMER MAY NOT
APPLY TO YOU.
TO THE EXTENT POSSIBLE, IN NO EVENT WILL THE LICENSOR BE LIABLE TO YOU
ON ANY LEGAL THEORY (INCLUDING, WITHOUT LIMITATION, NEGLIGENCE) OR
OTHERWISE FOR ANY DIRECT, SPECIAL, INDIRECT, INCIDENTAL, CONSEQUENTIAL,
PUNITIVE, EXEMPLARY, OR OTHER LOSSES, COSTS, EXPENSES, OR DAMAGES
ARISING OUT OF THIS PUBLIC LICENSE OR USE OF THE LICENSED MATERIAL, EVEN
IF THE LICENSOR HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH LOSSES,
COSTS, EXPENSES, OR DAMAGES. WHERE A LIMITATION OF LIABILITY IS NOT
ALLOWED IN FULL OR IN PART, THIS LIMITATION MAY NOT APPLY TO YOU.
The disclaimer of warranties and limitation of liability provided above
shall be interpreted in a manner that, to the extent possible, most
closely approximates an absolute disclaimer and waiver of all liability.
|