Currently the best installation instructions and software are here:

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DebianOn is an effort to document how to install, configure and use Debian on some specific hardware. Therefore potential buyers would know if that hardware is supported and owners would know how get the best out of that hardware.

The purpose is not to duplicate the Debian Official Documentation, but to document how to install Debian on some specific hardware.

If you need help to get Debian running on your hardware, please have a look at our user support channels where you may find specific channels (mailing list, IRC channel) dedicated to certain types of hardware.

Models covered
Toshiba AC100

- Video card NVidia (adapt this list to actually match options available. Common features are listed below)
- Screen size: 10" wide
- Wireless card
- Disk and Ram size, optical device
- Other options, like fingerprint reader, bluetooth... -~

Overall Status

Core Components


Boot Standard Kernel:

[-] (Needs kernel from external repository)

LAN network card:


Detect CD/DVD:


Detect hard drives:


Extra Features

CPU Frequency Scaling




Sleep / Suspend




- OpenGL


- Resize-and-Rotate(randr)


Switch to External Screen



- Built-in (Trackpoint)


- Built-in (Touchpad)

/!\ Works at random times





Keyboard's Hotkeys


Legend :
{OK} = OK ; {X} Unsupported(No Driver) ; /!\ = Error (Couldn't get it working); [?] Unknown, Not Test ; [-] Not-applicable
{i} = Configuration Required; X-( = Only works with a non-free driver and or firmware

Important Note

{X} This describes installing Debian on SD card. In order to boot Debian you will need overwrite your Android boot image (but we will make a backup so you can restore it later). Android OS itself and its configuration should stay intact, but you are strongly advised to make a backup of the internal eMMC flash before starting.

Debian armhf installation HOWTO

This describes the steps required to install Debian armhf (arm hard float) on SD card. I believe that similar steps would be sufficient to install armel, but I didn't try.

You will need:

Having a WiFi network with Internet access will help you during last steps of installation.

Toshiba AC100 boot process

(This may be inaccurate in certain details, but should be accurate enough to understand the installation process.)

  1. When you press Power the bootloader from the Tegra ROM starts.
  2. If this bootloader detects that Ctrl-ESC is pressed, the device is put into recovery mode (black screen, but you can manipulate the data from your PC with nvflash utility).
  3. ... the bootloader reads fuse bits, reads and starts next bootloader from eMMC, ...
  4. At least we are at the point where some bootloader has read the partition table. LNX (number 6) partition is read. It should contain an Android-style boot image that consists of a kernel and initramfs along with boot parameters (kernel load addresses and kernel boot parameters).
  5. The kernel is started. Kernel starts initramfs scripts that find and mount root file system.

(This description is based on

The most important (for us) part of boot process is the boot image.


nvflash is a proprietary, closed-source tool that allows you to read and write to the internal eMMC flash on the AC100 in recovery mode. You can download the nvflash tool along with other tools from nVidia here:

Make a backup

Before proceeding with the Debian installation, it is wise to make a back up of the current OS. See


Sosboot is a boot image (goes to the LNX partition) with a minimalistic kernel and initramfs that includes an interactive shell. Download prebuilt image from: It can be used to mount your SD card and chroot into its file system to fix anything.

To write SOSBOOT to LNX partition boot AC100 in recovery mode and run on your PC:

root@pc# LD_LIBRARY_PATH=. ./nvflash --bl fastboot.stock.bin --download 6 sosboot-r3.img --go

After that hold Power until AC100 shuts down. Boot and verify that SOSBOOT works.

Bootstrap Debian armhf on PC

The goal of this step is to create a directory on our local machine that will contain all files for the root directory of the AC100.

root@pc# apt-get install debootstrap qemu-user-static binfmt-support qemu
root@pc# mkdir armhf_root
root@pc# debootstrap --foreign --arch=armhf sid armhf_root $MIRROR

Where $MIRROR is a debian-ports mirror, for example use main site or select from

Presumably the processor in your PC is an x86, this means it cannot run binaries that are compiled for another architecture, like ARM. The AC100 has an ARM chip so we'll have to use the "foreign" mode with debootstrap. From the debootstrap man page; "foreign mode just does the initial unpack phase of bootstrapping only. A copy of debootstrap sufficient for completing the bootstrap process will be installed as /debootstrap/debootstrap in the target filesystem." The second stage runs the configuration scripts:

root@pc# cp /usr/bin/qemu-arm-static armhf_root/usr/bin
root@pc# chroot armhf_root /debootstrap/debootstrap --second-stage

Now add /etc/apt/sources.list and install a kernel to the chroot:

root@pc# cat > armhf_root/etc/apt/sources.list
deb sid main non-free contrib

deb unreleased main non-free
#deb-src unreleased main non-free
root@pc# chroot armhf_root apt-get update
root@pc# chroot armhf_root apt-get install abootimg flash-kernel linux-image-ac100

Also install the driver and tools to make the network card work:

root@pc# chroot armhf_root apt-get install firmware-ralink wireless-tools wpasupplicant

Add bootimg.cfg to create a proper boot image:

root@pc# cat > armhf_root/boot/bootimg.cfg
bootsize = 0x800000
pagesize = 0x800
kerneladdr = 0x10008000
ramdiskaddr = 0x11000000
secondaddr = 0x10f00000
tagsaddr = 0x10000100
name = jak-ac100
cmdline = root=/dev/mmcblk1p1 mem=448M@0M nvmem=64M@448M vmalloc=320M video=tegrafb console=tty0 usbcore.old_scheme_first=1 tegraboot=sdmmc tegrapart=recovery:700:a00:800,boot:1100:1000:800,mbr:2100:200:800,system:2300:25800:800,cache:27b00:32000:800,misc:59b00:400:800,userdata:5a000:9a600:800

Kernel command line shown above works for my AC100-117 (8 Gb internal flash). It should work for other models apart from the tegrapart= option that specifies the partition table for internal flash. See for command lines for other models.

Edit /etc/initramfs-tools/initramfs.conf to make initrd images smaller (to fit into LNX partition):

root@pc# vim armhf_root/etc/initramfs-tools/initramfs.conf

Populate /etc/fstab (change filesystem and mount options as appropriate):

root@pc# cat >> armhf_root/etc/fstab
/dev/mmcblk1p1 / ext4 rw,noatime,commit=30,barrier=1,data=ordered 0 0

Populate /etc/network/interfaces:

root@pc# cat >> armhf_root/etc/network/interfaces
auto lo
iface lo inet loopback

Partition SD card

Create a root partition and run mkfs (separate /boot is not needed). It is recommended to align the partition to SD card erase block. The simplest way to do this is to use GPT partition table (instead of MSDOS-style partition table) and let gdisk (GPT fdisk) do the alignment for you: gdisk creates partitions aligned to 1 Mb boundary by default. Detailed instructions are available here:

Create ext4 filesystem with:

# mkfs -t ext4 -v -b 4096 -E stride=32,stripe-width=32,resize=32G /dev/sdX1

ext4 block size is set to 4K. 4K * 32 = 128K, which is a common SD erase block size.

See also:

Copy prepared files to root partition

root@pc# cp -ax armhf_root/* /media/sdcard/

Write kernel to internal flash (LNX partition)

Boot into SOSBOOT. (See also SOSBOOT section above.)

root@(none)# mount /dev/mmcblk1p1 /mnt
root@(none)# mount --bind /dev /mnt/dev
root@(none)# mount --bind /proc /mnt/proc
root@(none)# mount --bind /sys /mnt/sys
root@(none)# chroot /mnt /bin/bash

Regenerate initramfs and verify that it is small (should be less than 2 Mb)

root@host# update-initramfs -u
root@host# ls -lh /boot/initrd*
-rw-r--r-- 1 root root 1.7M Aug 13 05:02 /boot/initrd.img-2.6.38-ac1-ac100

Write boot image to internal flash:

root@host# flash-kernel

Exit chroot and umount fs:

root@host# exit
root@(none)# umount /mnt/sys
root@(none)# umount /mnt/proc
root@(none)# umount /mnt/dev
root@(none)# umount /mnt

Reboot. Debian should boot.


Run dpkg-reconfigure locales to set locale, dpkg-reconfigure tzdata to choose timezone, dpkg-reconfigure console-setup to set console font.

If it didn't work...

If the kernel didn't boot you can write SOSBOOT with nvflash again and examine SD card contents, read logs etc.





Power Management


Bring the interface up:

root@host# ip link set dev wlan0 up

and then configure the wifi as explained at WiFi/HowToUse.


System Summary


Toshiba AC100-117

cat /proc/cpuinfo

Processor       : ARMv7 Processor rev 0 (v7l)
processor       : 0
BogoMIPS        : 1998.84

processor       : 1
BogoMIPS        : 19.45

Features        : swp half thumb fastmult vfp edsp thumbee vfpv3 vfpv3d16 
CPU implementer : 0x41
CPU architecture: 7
CPU variant     : 0x1
CPU part        : 0xc09
CPU revision    : 0

Hardware        : Toshiba AC100 / Dynabook AZ
Revision        : 0000
Serial          : 0000000000000000


No PCI (?)


Toshiba AC100-117

lsusb -v | grep -E '\<(Bus|iProduct|bDeviceClass|bDeviceProtocol)' 2>/dev/null

Bus 001 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub
  bDeviceClass            9 Hub
  bDeviceProtocol         1 Single TT
  iProduct                2 Tegra EHCI Host Controller
Bus 002 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub
  bDeviceClass            9 Hub
  bDeviceProtocol         1 Single TT
  iProduct                2 Tegra EHCI Host Controller
Bus 001 Device 002: ID 0424:2512 Standard Microsystems Corp. USB 2.0 Hub
  bDeviceClass            9 Hub
  bDeviceProtocol         2 TT per port
  iProduct                0 
  bDeviceClass            9 Hub
  bDeviceProtocol         0 Full speed (or root) hub
Bus 002 Device 002: ID 0424:2513 Standard Microsystems Corp. 
  bDeviceClass            9 Hub
  bDeviceProtocol         2 TT per port
  iProduct                0 
  bDeviceClass            9 Hub
  bDeviceProtocol         0 Full speed (or root) hub
Bus 001 Device 003: ID 0db0:3871 Micro Star International 
  bDeviceClass            0 (Defined at Interface level)
  bDeviceProtocol         0 
  iProduct                2 802.11 n WLAN
      (Bus Powered)
  bDeviceClass            0 (Defined at Interface level)
  bDeviceProtocol         0 
  (Bus Powered)
Bus 001 Device 004: ID 0db0:a871 Micro Star International 
  bDeviceClass          224 Wireless
  bDeviceProtocol         1 Bluetooth
  iProduct                0 
Bus 002 Device 003: ID 0bda:58f2 Realtek Semiconductor Corp. 
  bDeviceClass          239 Miscellaneous Device
  bDeviceProtocol         1 Interface Association
  iProduct                1 USB Camera
      (Bus Powered)
  bDeviceClass          239 Miscellaneous Device
  bDeviceProtocol         1 Interface Association
  (Bus Powered)

USB Host controllers entries (without OHCI, UHCI, EHCI) are removed too.



Some configuration files and sample outputs.


Julian Andres Klode wrote

Installation guide (all on the device itself):

  1. Bootstrap Debian on USB stick, SD, or eMMC
  2. Install busybox and initramfs-tools
  3. Set MODULES=dep in /etc/initramfs-tools/initramfs.conf
  4. Copy /boot/bootimg.cfg to Debian and configure cmdline
  5. (bind) mount /proc and /dev
  6. Install abootimg flash-kernel linux-image-ac100

Alternatively, you can also do all steps on another machine, reboot with the Ubuntu kernel into the Debian system and then run flash-kernel manually to install the Debian kernel.

It's a bit complicated currently, because there's no boot.img available that you could nvflash to the target device. But that's actually the most complicated part, the rest is fairly easy.