Hardware
--------
CPU: Qualcomm IPQ4019
RAM: 256M (NANYA NT5CC128M16JR-EK)
FLASH: 128M NAND (Macronix MX30LF1G18AC-XKI)
ETH: Qualcomm QCA8072
WiFi2: IPQ4019 2T2R 2SS b/g/n
WiFi5: IPQ4019 2T2R 2SS n/ac
WiFi5: QCA9984 4T4R 4SS n/ac
LED: - Connect green/blue/red
- Power green
BTN: WPS/Connect
UART: 115200n8 3.3V
VCC - RX - TX - GND (Square is VCC)
Installation
------------
1. Grab the uboot for the Device from the 'u-boot-fritz3000'
subdirectory. Place it in the same directory as the 'eva_ramboot.py'
script. It is located in the 'scripts/flashing' subdirectory of the
OpenWRT tree.
2. Assign yourself the IP address 192.168.178.10/24. Connect your
Computer to one of the boxes LAN ports.
3. Connect Power to the Box. As soon as the LAN port of your computer
shows link, load the U-Boot to the box using following command.
> ./eva_ramboot.py --offset 0x85000000 192.168.178.1 uboot-fritz3000.bin
4. The U-Boot will now start. Now assign yourself the IP address
192.168.1.70/24. Copy the OpenWRT initramfs (!) image to a TFTP
server root directory and rename it to 'FRITZ3000.bin'.
5. The Box will now boot OpenWRT from RAM. This can take up to two
minutes.
6. Copy the U-Boot and the OpenWRT sysupgrade (!) image to the Box using
scp. SSH into the Box and first write the Bootloader to both previous
kernel partitions.
> mtd write /path/to/uboot-fritz3000.bin uboot0
> mtd write /path/to/uboot-fritz3000.bin uboot1
7. Remove the AVM filesystem partitions to make room for our kernel +
rootfs + overlayfs.
> ubirmvol /dev/ubi0 --name=avm_filesys_0
> ubirmvol /dev/ubi0 --name=avm_filesys_1
8. Flash OpenWRT peristently using sysupgrade.
> sysupgrade -n /path/to/openwrt-sysupgrade.bin
Signed-off-by: David Bauer <mail@david-bauer.net>
Hardware:
CPU: MediaTek MT7621AT (2x880MHz)
RAM: 512MB DDR3
FLASH: 256MB NAND
WiFi: 2.4GHz 4x4 MT7615 b/g/n (Needs driver, See Issues!)
WiFI: 5GHz 4x4 MT7615 a/n/ac (Needs driver, See Issues!)
USB: 1x 3.0
ETH: 1x WAN 10/100/1000 3x LAN 10/100/1000
LED: Power/Status
BTN: RESET
UART: 115200 8n1
Partition layout and boot:
Stock Xiaomi firmware has the MTD split into (among others)
- kernel0 (@0x200000)
- kernel1 (@0x600000)
- rootfs0
- rootfs1
- overlay (ubi)
Xiaomi uboot expects to find kernels at 0x200000 & 0x600000
referred to as system 1 & system 2 respectively.
a kernel is considered suitable for handing control over
if its linux magic number exists & uImage CRC are correct.
If either of those conditions fail, a matching sys'n'_fail flag
is set in uboot env & a restart performed in the hope that the
alternate kernel is okay.
If neither kernel checksums ok and both are marked failed, system 2
is booted anyway.
Note uboot's tftp flash install writes the transferred
image to both kernel partitions.
Installation:
Similar to the Xiaomi MIR3G, we keep stock Xiaomi firmware in
kernel0 for ease of recovery, and install OpenWRT into kernel1 and
after.
The installation file for OpenWRT is a *squashfs-factory.bin file that
contains the kernel and a ubi partition. This is flashed as follows:
nvram set flag_try_sys1_failed=1
nvram set flag_try_sys2_failed=0
nvram commit
dd if=factory.bin bs=1M count=4 | mtd write - kernel1
dd if=factory.bin bs=1M skip=4 | mtd write - rootfs0
reboot
Reverting to stock:
The part of stock firmware we've kept in kernel0 allows us to run stock
recovery, which will re-flash stock firmware from a *.bin file on a USB.
For this we do the following:
fw_setenv flag_try_sys1_failed 0
fw_setenv flag_try_sys2_failed 1
reboot
After reboot the LED status light will blink red, at which point pressing
the 'reset' button will cause stock firmware to be installed from USB.
Issues:
OpenWRT currently does not have support for the MT7615 wifi chips. There is
ongoing work to add mt7615 support to the open source mt76 driver. Until that
support is in place, there are closed-source kernel modules that can be used.
See: https://forum.openwrt.org/t/support-for-xiaomi-wifi-r3p-pro/20290/170
Signed-off-by: Ozgur Can Leonard <ozgurcan@gmail.com>
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
[02_network remaps, Added link to notes]
Hardware
--------
SOC: QCA9558
RAM: 128M DDR2
Flash: 16MiB SPI-NOR
ETH: QCA8337N: 2x 10/100/1000 PoE and PoE pass-through
WiFi2: QCA9558 (bgn) 2T2R
WiFi5: 2x mPCIE with AR9582 (an) 2T2R
BTN: 1x Reset
GPIO: multiple GPIO on header, PoE passthrough enable
UART: 3.3V 115200 8N1 header on the board
WDG: ATTiny13 watchdog
JTAG: header on the board
USB: 1x connector and 1x header on the board
PoE: 10-32V input in ETH port 1, passthrough in port 2
mPCIE: 2x populated with radios (but replaceable)
OpenWrt is preinstalled from factory. To install use <your-image>-sysupgade.bin
using the web interface or with sysupgrade -n.
Flash from bootloader (in case failsafe does not work)
1. Connect the LibreRouter with a serial adapter (TTL voltage) to the UART
header in the board.
2. Connect an ETH cable and configure static ip addres 192.168.1.10/24
3. Turn on the device and stop the bootloader sending any key through the serial
interface.
4. Use a TFTP server to serve <your image>-sysupgrade.bin file.
5. Execute the following commands at the bootloader prompt:
ath> tftp 82000000 <your image>-sysupgrade.bin
ath> erase 0x9f050000 +$filesize
ath> cp.b 0x82000000 0x9f050000 $filesize
ath> bootm 0x9f050000
More docs
* Bootloader https://github.com/librerouterorg/u-boot
* Board details (schematics, gerbers): https://github.com/librerouterorg/board
Signed-off-by: Santiago Piccinini <spiccinini@altermundi.net>
Use tested values on shuttle,kd20 and assumed values for
mitrastar,stg-212 and cloudengines,pogoplug*.
akitio users have yet to report back stock flash layout to support
vendor bootloader environment there as well.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Hardware
--------
CPU: Qualcomm IPQ4019
RAM: 256M
FLASH: 128M NAND
ETH: QCA8075
VDSL: Intel/Lantiq VRX518 PCIe attached
currently not supported
DECT: Dialog SC14448
currently not supported
WiFi2: IPQ4019 2T2R 2SS b/g/n
WiFi5: IPQ4019 2T2R 2SS n/ac
LED: - Power/DSL green
- WLAN green
- FON/DECT green
- Connect/WPS green
- Info green
- Info red
BTN: - WLAN
- FON
- WPS/Connect
UART: 115200n8 3.3V (located under the Dialog chip)
VCC - RX - TX - GND (Square is VCC)
Installation
------------
1. Grab the uboot for the Device from the 'u-boot-fritz7530'
subdirectory. Place it in the same directory as the 'eva_ramboot.py'
script. It is located in the 'scripts/flashing' subdirectory of the
OpenWRT tree.
2. Assign yourself the IP address 192.168.178.10/24. Connect your
Computer to one of the boxes LAN ports.
3. Connect Power to the Box. As soon as the LAN port of your computer
shows link, load the U-Boot to the box using following command.
> ./eva_ramboot.py --offset 0x85000000 192.168.178.1 uboot-fritz7530.bin
4. The U-Boot will now start. Now assign yourself the IP address
192.168.1.70/24. Copy the OpenWRT initramfs (!) image to a TFTP
server root directory and rename it to 'FRITZ7530.bin'.
5. The Box will now boot OpenWRT from RAM. This can take up to two
minutes.
6. Copy the U-Boot and the OpenWRT sysupgrade (!) image to the Box using
scp. SSH into the Box and first write the Bootloader to both previous
kernel partitions.
> mtd write /path/to/uboot-fritz7530.bin uboot0
> mtd write /path/to/uboot-fritz7530.bin uboot1
7. Remove the AVM filesystem partitions to make room for our kernel +
rootfs + overlayfs.
> ubirmvol /dev/ubi0 --name=avm_filesys_0
> ubirmvol /dev/ubi0 --name=avm_filesys_1
8. Flash OpenWRT peristently using sysupgrade.
> sysupgrade -n /path/to/openwrt-sysupgrade.bin
Signed-off-by: David Bauer <mail@david-bauer.net>
[removed pcie-dts range node, refreshed on top of AP120-AC/E2600AC]
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
Adds support for the AVM FRITZ!Box 7530.
Signed-off-by: David Bauer <mail@david-bauer.net>
Signed-off-by: Christian Lamparter <chunkeey@gmail.com> [PKG_RELEASE]
VBoxManage is not used and the image is created with proper permisions:
0f5d0f6 image: use internal qemu-img for vmdk and vdi images drop host
dependencies on qemu-utils and VirtualBox
Unreachable config symbols:
9e0759e x86: merge all geode based subtargets into one
No need to define those symbols since x86_64 is subtarget of x86:
196fb76 x86: make x86_64 a subtarget instead of a standalone target
Unreachable config symbols, so remove GRUB_ROOT:
371b382 x86: remove the xen_domu subtarget
Signed-off-by: Tomasz Maciej Nowak <tomek_n@o2.pl>
This commit adds support for the Linksys EA6350v3 device in the ipq40xx
target.
This is needed for uboot-envtools to access the environment. Without this
patch, the Linksys EA6350v3 will not be able to access the uboot
environment. As a side effect, the feature auto_recovery will make the
device unstable by switching between the latest and the current firmware.
Signed-off-by: Ryan Pannell <ryan@osukl.com>
Signed-off-by: Oever González <notengobattery@gmail.com>
CPU: FSL P1020 (2x 800MHz E500 PPC)
RAM: 1GB DDR3
FLASH: 256MiB NAND
WiFi: 2x Atheros AR9382 2x2:2 abgn
ETH: 2x BCM54616S - 1x BCM53128 8-port switch
LED: 5x LEDs (Power, WiFi1, WiFi2, N/D, SYS)
BTN: 1x RESET
Installation
------------
1. Download initrams kernel image, dtb binary and sysupgrade image.
2. Place initramfs kernel into tftp root directory. Rename to
"panda-uimage-factory".
3. Place dtb binary into tftp root directory. Rename to "panda.fdt".
4. Start tftp server on 192.168.100.8/24.
5. Power up the device with the reset button pressed. It will download
the initrams and dtb via tftp and boot into OpenWRT in RAM.
6. SSH into the device and remove the factory partitions.
> ubirmvol /dev/ubi0 --name=kernel1
> ubirmvol /dev/ubi0 --name=rootfs1
> ubirmvol /dev/ubi0 --name=devicetree1
You will have around 60 MiB of free space with that.
You can also delete "kernel2", "devicetree2", "rootfs2" and "storage"
respectively in case you do not want to go back to the vendor firmware.
7. Modify the U-Boot bootcmd to allow for booting OpenWRT
> fw_setenv bootcmd_owrt "ubi part ubi && ubi read 0x1000000 kernel
&& bootm 0x1000000"
> fw_setenv bootargs_owrt "setenv bootargs console=ttyS0,115200
ubi.mtd=3,2048"
> fw_setenv bootcmd "run bootargs_owrt; run bootcmd_owrt"
8. Transfer the sysupgrade image via scp into the /tmp directory.
9. Upgrade the device
> sysupgrade -n /tmp/<imagename>
Signed-off-by: David Bauer <mail@david-bauer.net>
On musl based distributions, u-boot 2010.03 fails to build with:
u-boot-2010.03/include/u-boot/crc.h:29:50: error: unknown type name 'uint'
uint32_t crc32 (uint32_t, const unsigned char *, uint);
The issue was fixed in the newer u-boot-2018.03 version, this commit
backports the change to the older version used by ar71xx/ath79.
Signed-off-by: Andy Walsh <andy.walsh44+github@gmail.com>
[add commit message from PR description]
Signed-off-by: Jo-Philipp Wich <jo@mein.io>
The Detection pin is at PF6 and not at PH13 like defined before. I
checked the schematics and now I am am not seeing this error message any
more:
Loading Environment from FAT... Card did not respond to voltage select!
Signed-off-by: Hauke Mehrtens <hauke@hauke-m.de>
Disable the PMIC on Olimex A13 Olinuxino, as the SPL cannot set the
core voltage correctly, which causes the board to freeze later at
kernel if CPU throttling is enabled (see below). This will almost
certainly kill the VGA output (which requires LDO3 to be set), but
this is still a better option than to disable CPU throttling for
all Cortex-A8 based devices.
[ 2.485632] cpufreq: cpufreq_online: CPU0: Running at unlisted freq: 384000 KHz
[ 2.525698] cpufreq: cpufreq_online: CPU0: Unlisted initial frequency changed to: 432000 KHz
Signed-off-by: Zoltan HERPAI <wigyori@uid0.hu>
Instead of using a fork of the ARM trusted firmware specifically for the
Allwinner SoCs, use the official version from ARM now, this version
supports the Allwinner SoCs now and the older ATF repository is
deprecated.
Signed-off-by: Hauke Mehrtens <hauke@hauke-m.de>
This updates the uboot for the sunxi target to version 2018.11
The removed patches are applied upstream and not needed any more.
Signed-off-by: Hauke Mehrtens <hauke@hauke-m.de>
Copy U-Boot to STAGING_DIR_IMAGE (and append it to the EVA-image from
there) to fix image generation using the image-builder.
Also remove the bootloader from DEVICE_PACKAGES and instead use the
BUILD_DEVICES directive from within the U-Boot makefile.
This fixes eva-image generation using the OpenWRT image-builder.
Signed-off-by: David Bauer <mail@david-bauer.net>
This commit adds the nescessary settings to allow reading the uboot environment variables on the GL.iNet GL-B1300 board.
Signed-off-by: Ibrahim Tachijian <barhom@netsat.se>
This device is called GL-AR300M, therefore rename the board(s)
to 'gl-ar300m-nor' and 'gl-ar300m-nand'
Signed-off-by: Paul Wassi <p.wassi@gmx.at>
[change boardname in uboot envtools as well, don't use wildcards for
boardname]
Signed-off-by: Mathias Kresin <dev@kresin.me>
The LS1021A-IoT gateway reference design based on the
QorIQ LS1021A processor is a purpose-built, small
footprint hardware platform with a wide array of
high-speed connectivity and low-speed serial interfaces
to support secure delivery of IoT services for home,
business or other commercial location.
- Combines standards-based, open source software with a
feature-rich IoT gateway design to establish a common,
open framework for secured IoT service delivery and
management.
- Provides a wide assortment of high-speed and serial-based
connectivity in a compact, highly secure design.
- High efficiency through the use of the Arm-based QorIQ
LS1021A embedded processor.
Signed-off-by: Yangbo Lu <yangbo.lu@nxp.com>
Signed-off-by: Biwen Li <biwen.li@nxp.com>
After changing board names to DT compat string, we also need to
adjust the script which generates uboot-env configuration files.
Fixes: e880a30549 ("mxs: use generic sysinfo board detection")
Signed-off-by: Michael Heimpold <mhei@heimpold.de>
According to https://github.com/openwrt/openwrt/pull/1527, support
for the Buffalo BHR-4GRV2 in ath79 requires repartitioning from
an initramfs image, make this easier by supporting uboot-envtools
support out of the box.
Build tested, but not runtime tested.
Signed-off-by: Stefan Lippers-Hollmann <s.l-h@gmx.de>
Port support for the Buffalo WZR-HP-AG300H from the ar71xx target to
ath79 as well.
Build- and runtime tested on the Buffalo WZR-HP-AG300H.
Signed-off-by: Stefan Lippers-Hollmann <s.l-h@gmx.de>
Beside one exception, no one took care of these two remaining boards
still using the legacy image build code during the last two years.
Since OpenWrt 14.07 the ALLNET ALL0239-3G image building is broken.
The Sitecom WL-341 v3 image build code looks pretty hackish and broken.
It's questionable if the legacy image works as all.
Signed-off-by: Mathias Kresin <dev@kresin.me>
This patch updates the uboot-fritz4040 package to the latest version.
The portability and private-libgcc patches, as well as the
upload-to-f4040.sh script have been added to the upstream repository.
Furthermore, the upload-to-f4040 has been updated to take the first
parameter as the file it is supposed to flash, otherwise it defaults
to the previous "uboot-fritz4040.bin". Furthermore the error messages
have been improved and ftp will now dump some "progress information"
to the user's console.
Also included is support for gcc 8+ and a fix for the obnoxous error
that currently breaks the builders:
| fritz/src/lzma2eva.c:23:30: fatal error: zlib.h: No such file or directory
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
This patch adds support for the Netgear WNDAP620 and WNDAP660,
they are similar devices, but due to the LAN LED configuration,
the switch setup and WIFI configuration each gets a different
device target.
Hardware Highlights WNDAP620:
CPU: AMCC PowerPC APM82181 at 1000 MHz
DRAM: 128 MB, 2 x 64 MiB DDR2 Hynix H5PS5162GF
CPU: AMCC PowerPC APM82181 at 1000 MHz
FLASH: 32 MiB, NAND SLC, Hynix HY27US08561A
Ethernet: RealTek RTL8363SB 2x2-Port Switch PHY - Only 1 GBit Port (POE)
Wifi: Atheros AR9380 minipcie - Dual-Band - 3x3:3
Serial: console port with RJ45 Interface (9600-N-8-1)
LEDS: Power, LAN-Activity, dual color LAN-Linkspeed, 2.4GHz, 5GHz LEDs
Button: Soft Reset Button
Antennae: 3 internal dual-band antennae + 3 x RSMA for external antennaes
Hardware Highlights WNDAP660:
CPU: AMCC PowerPC APM82181 at 1000 MHz + 2 Heatsinks
DRAM: 256 MB, 2 x 128 MiB DDR2
FLASH: 32 MiB, NAND SLC, Hynix HY27US08561A
Ethernet: RealTek RTL8363SB 2x2-Port Switch PHY (POE)
Wifi1: Atheros AR9380 minipcie - Dual-Band - 3x3:3
Wifi2: Atheros AR9380 minipcie - Dual-Band - 3x3:3
Serial: console port with RJ45 Interface (9600-N-8-1)
LEDS: Power, LAN-Activity, 2x dual color LAN-Linkspeed, 2.4GHz, 5GHz LEDs
Button: Soft Reset Button
Antennae: 6 internal dual-band antennae + 3 x RSMA for external antennaes
Flashing requirements:
- needs a tftp server at 192.168.1.10/serverip.
- special 8P8C(aka RJ45)<->D-SUB9 Console Cable
("Cisco Console Cable"). Note: Both WNDAP6x0 have
a MAX3232 transceivers, hence no need for any separate
CMOS/TTL level shifters.
External Antenna:
The antennae mux is controlled by GPIO 11 and GPIO14. Valid Configurations:
= Config# = | = GPIO 11 = | = GPIO 14 = | ===== Description =====
1. | 1 / High | 0 / Low | Use the internal antennae (default)
2. | 0 / Low | 1 / High | Use the external antennae
The external antennaes are only meant for the 2.4 GHz band.
One-way Flashing instructions via u-boot:
0. connect the serial cable to the RJ45 Console Port
Note: This requires a poper RS232 and not a TTL/USB adaptor.
1. power up the AP and interrupt the u-boot process at
'Hit any key to stop autoboot'
2. setup serverip and ipaddr env settings
Enter the following commands into the u-boot shell
# setenv ipaddr 192.168.1.1
# setenv serverip 192.168.1.10
3. download the factory.img image to the AP
Enter the following commands into the u-boot shell
# tftp ${kernel_addr_r} openwrt-apm821xx-nand-netgear_wndap660-squashfs-factory.img
4. verfiy image integrity
Enter the following commands into the u-boot shell
# crc32 $fileaddr $filesize
If the calculated crc32 checksum does not match, go back to step 3.
5. flash the image
Enter the following commands into the u-boot shell
# nand erase 0x110000 0x1bd0000
# nand write ${kernel_addr_r} 0x110000 ${filesize}
6. setup uboot environment
Enter the following commands into the u-boot shell
# setenv bootargs
# setenv fileaddr
# setenv filesize
# setenv addroot 'setenv bootargs ${bootargs} root=/dev/ubiblock0_0'
# setenv owrt_boot 'nboot ${kernel_addr_r} nand0 0x110000; run addroot; run addtty; bootm ${kernel_addr_r}'
# setenv bootcmd 'run owrt_boot'
# saveenv
7. boot
# run bootcmd
Booting initramfs instructions via u-boot:
Follow steps 0 - 2 from above.
3. boot initramfs
Enter the following commands into the u-boot shell
# tftp ${kernel_addr_r} openwrt-apm821xx-nand-netgear_wndap660-initramfs-kernel.bin
# run addtty
# bootm ${kernel_addr_r}
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
This patch adds u-boot environment access to the MX60(W) target.
"The environment size is one NAND block (128KiB on Buckminster).
We allocate four NAND blocks to deal with bad blocks which may
exist in the saved environment"
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
All apm821xx devices use u-boot and most of them have
an accessible u-boot environment. This patch adds the
necessary template file, but does not add the
uboot-envtools package to any of the targets.
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
Also update the U-Boot BSP patch for I2SE Duckbill devices
and remove upstreamed patch for LibreSSL support.
Signed-off-by: Michael Heimpold <mhei@heimpold.de>
In dtc version 1.4.6 the macro names in header include guards changed,
but the build relies on them matching in order to replace selected
headers. This is a horrible hack to work around this.
Signed-off-by: Thomas Nixon <tom@tomn.co.uk>
ls1012afrdm was no longer supported in NXP Layerscape SDK.
Instead a new board ls1012afrwy was introduced in LSDK.
This patch is to drop ls1012afrdm and add ls1012afrwy support.
Since only 2MB NOR flash could be used, we just put u-boot
and firmware on NOR flash, and put kernel/dtb/rootfs on SD
card.
The Layerscape FRWY-LS1012A board is an ultra-low-cost
development platform for LS1012A Series Communication
Processors built on Arm Cortex-A53. This tool refines the
FRDM-LS1012A with more features for a better hands-on experience
for IoT, edge computing, and various advanced embedded
applications. Features include easy access to processor I/O,
low-power operation, micro SD card storage, an M2 connector, a
small form factor, and expansion board options via mikroBUS Click
Module. The MicroBUS Module provides easy expansion via hundreds
of powerful modules supporting sensors, actuators, memories,
and displays.
Signed-off-by: Yangbo Lu <yangbo.lu@nxp.com>