openwrtv4/target/linux/ramips/base-files/etc/board.d/02_network

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#!/bin/sh
. /lib/functions.sh
. /lib/functions/uci-defaults.sh
. /lib/functions/system.sh
ramips_setup_rt3x5x_vlans()
{
if [ ! -x /sbin/swconfig ]; then
# legacy default
ucidef_set_interfaces_lan_wan "eth0.1" "eth0.2"
return
fi
local wanports=""
local lanports=""
for port in 5 4 3 2 1 0; do
if [ `swconfig dev rt305x port $port get disable` = "1" ]; then
continue
fi
if [ `swconfig dev rt305x port $port get lan` = "0" ]; then
wanports="$port:wan $wanports"
else
lanports="$port:lan $lanports"
fi
done
ucidef_add_switch "rt305x" $lanports $wanports "6t@eth0"
}
ramips_setup_interfaces()
{
local board="$1"
case $board in
11acnas|\
w2914nsv2|\
zbt-we2026)
ucidef_add_switch "switch0" \
"0:lan:4" "1:lan:3" "2:lan:2" "3:lan:1" "4:wan:5" "6@eth0"
;;
3g150b|\
3g300m|\
a5-v11|\
all0256n-4M|\
all0256n-8M|\
all5002|\
all5003|\
bocco|\
broadway|\
dcs-930|\
dcs-930l-b1|\
ht-tm02|\
kimax,u35wf|\
linkits7688 | \
m2m|\
microwrt|\
ramips: add support for MikroTik RouterBOARD RBM11g This commit adds support for the MikroTik RouterBOARD RBM11g. =Hardware= The RBM11g is a mt7621 based device featuring one GbE port and one miniPCIe slot with a sim card socket and USB 2.0. ==Switch== The single onboard Ethernet port is connected the CPU directly. The internal switch of the mt7621 SoC is disabled. ==Flash== The device has one spi nor flash chip. It is a 128 Mbit winbond 25Q128FVS connected to CS0. ==PCIe== The board features a single miniPCIe slot. It has a dedicated mini SIM socket and a USB 2.0 port. Power to the miniPCIe slot is controlled via GPIO9. ==USB== There are no external USB ports. ==Power== The board can accept both, passive PoE and external power via a 2.1 mm barrel jack (center-positive). The input voltage range is 11-32 V. ==Serial port== The device does have an onboard UART on an unpopulated header next to the flash chip: GND: pin 2 TX: pin 7 RX: pin 6 Settings: 115200, 8N1 See below illustration for positioning of the header. 0 = screw hole * = some pin T = TX pin R = RX pin G = GND pin Pinout: +--------------- |O | __ | / \ | \__/ | | | | +---+ | |RAM| | +--+ | | | |**| <- unpopulated header with UART | |*T| +---+ | |R*| +--------+ | |**| | | | |G*| | CPU | | +--+ | | | +--+ | | | | | +--------+ | +--+ <- flash chip |O | +-----+ | | | |+--+ | | || | | | +--------------------- =Installation= To install an OpenWRT image to the device two components must be built: 1. A openwrt initramfs image 2. A openwrt sysupgrade image ===initramfs & sysupgrade image=== Select target devices "Mikrotik RBM11G" in openwrt menuconfig and build the images. This will create the images "openwrt-ramips-mt7621-mikrotik_rbm11g-initramfs-kernel.bin" and "openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" in the output directory. ==Installing== **Make sure to back up your RouterOS license in case you do ever want to go back to RouterOS using "/system license output" and back up the created license file.** When rebooted the board will try booting via ethernet first. If your board does not boot via ethernet automatically you will have to attach to the serial port and set ethernet as boot device within RouterBOOT. 1. Set up a dhcp server that points the bootfile to tftp server serving the "openwrt-ramips-mt7621-mikrotik_rbm11g-initramfs-kernel.bin" initramfs image 2. Connect to ethernet port on board 3. Power on the board 4. Wait for OpenWrt to boot Right now OpenWrt will be running with a SSH server listening. Now OpenWrt must be flashed to the devices flash: 1. Copy "openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" to the device using scp. 2. Write openwrt to flash using "sysupgrade openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" Once the flashing completes the board will reboot. Disconnect from the devices ethernet port or stop the DHCP/TFTP server to prevent the device from booting via ethernet again. The device should now boot straight to OpenWrt. Signed-off-by: Tobias Schramm <tobleminer@gmail.com>
2018-06-25 20:51:43 +00:00
mikrotik,rbm11g|\
mpr-a2|\
ncs601w|\
omega2 | \
omega2p | \
timecloud|\
tplink,tl-wa801nd-v5|\
w150m|\
widora,neo-16m|\
widora,neo-32m|\
wnce2001|\
zbt-cpe102|\
zorlik,zl5900v2|\
zte-q7)
ucidef_add_switch "switch0"
ucidef_add_switch_attr "switch0" "enable" "false"
ucidef_set_interface_lan "eth0"
;;
mlw221|\
mr-102n)
ucidef_set_interface_lan "eth0.2"
;;
3g-6200n|\
ai-br100|\
alfa-network,ac1200rm|\
mediatek,ap-mt7621a-v60|\
d240|\
db-wrt01|\
dir-300-b7|\
dir-320-b1|\
dir-610-a1|\
dir-615-h1|\
dir-810l|\
dlink,dwr-116-a1|\
dlink,dwr-921-c1|\
ew1200|\
firewrt|\
hc5661a|\
hc5962|\
hlk-rm04|\
k2p|\
kn|\
kn_rc|\
mac1200rv2|\
miwifi-mini|\
miwifi-nano|\
mt7621|\
mt7628|\
mzk-750dhp|\
mzk-w300nh2|\
d-team,newifi-d2|\
netgear,r6120|\
nixcore-x1-8M|\
nixcore-x1-16M|\
oy-0001|\
pbr-m1|\
psg1208|\
psg1218a|\
r6220|\
rt-n12p|\
sap-g3200u3|\
sk-wb8|\
ramips: add support for UniElec U7621-06 UniElec U7621-06 is a router platform board based on MediaTek MT7621AT. The device has the following specifications: - MT7621AT (880 MHz) - 256/512 MB of RAM (DDR3) - 8/16/32/64 MB of FLASH (SPI NOR) - 5x 1 Gbps Ethernet (MT7621 built-in switch) - 1x ASMedia ASM1061 (for mSATA and SATA) - 2x miniPCIe slots (PCIe bus only) - 1x mSATA slot (with USB 2.0 bus for modem) - 1x SATA - 1x miniSIM slot - 1x microSD slot - 1x USB 3.0 - 12x LEDs (3 GPIO-controlled) - 1x reset button - 1x UART header (4-pins) - 1x GPIO header (30-pins) - 1x FPC connector for LEDs (20-pin, 0.5 mm pitch) - 1x DC jack for main power (12 V) The following has been tested and is working: - Ethernet switch - miniPCIe slots (tested with Wi-Fi cards) - mSATA slot (tested with modem and mSATA drive) - miniSIM slot - sysupgrade - reset button - microSD slot Installation: This board might come with a different firmware versions (MediaTek SDK, PandoraBox, Padavan, etc.). If your board comes with PandoraBox, you can install LEDE using sysupgrade. Just SSH to the router and perform forced sysupgrade (due to a board name mismatch). The default IP of this board should be: 192.168.1.1 and username/password: root/admin. In case of a different firmware, you can use web based recovery described below. Use the following command to perform the sysupgrade (for the 256MB RAM/16MB flash version): sysupgrade -n -F lede-ramips-mt7621-u7621-06-256M-16M-squashfs-sysupgrade.bin Recovery: This board contains a Chinese, closed-source bootloader called Breed (Boot and Recovery Environment for Embedded Devices). Breed supports web recovery and to enter it, you keep the reset button pressed for around 5 seconds during boot. Your machine will be assigned an IP through DHCP and the router will use IP address 192.168.1.1. The recovery website is in Chinese, but is easy to use. Click on the second item in the list to access the recovery page, then the second item on the next page is where you select the firmware. In order to start the recovery, you click the button at the bottom. LEDs list (top row, left to right): - LED_WWAN# (connected with pin 42 in LTE/mSATA slot) - Power (connected directly to 3V3) - CTS2_N (GPIO10, configured as "status" LED) - TXD2 (GPIO11, configured as "led4", without default trigger) - RXD2 (GPIO12, configured as "led5", without default trigger) - LED_WLAN# (connected with pin 44 in wifi0 slot) LEDs list (bottom row, left to right): - ESW_P0_LED_0 - ESW_P1_LED_0 - ESW_P2_LED_0 - ESW_P3_LED_0 - ESW_P4_LED_0 - LED_WLAN# (connected with pin 44 in wifi1 slot) Other notes: 1. The board is available with different amounts of RAM and flash. We have only added support for the 256/16 MB configuration, as that seems to be the default. However, all the required infrastructure is in place for making support for the other configurations easy. 2. The manufacturer offers five different wireless cards with MediaTek chipsets, based on MT76x2, MT7603 and MT7615. Images of the board all show that the miniPCIe slots are dedicated to specific Wi-Fi cards. However, the slots are generic. 3. All boards we got access to had the same EEPROM content. The default firmware reads the Ethernet MAC from offset 0xe000 in factory partition. This offset only contains 0xffs, so a random MAC will be generated on every boot of the router. There is a valid MAC stored at offset 0xe006 and this MAC is shown as the WAN MAC in the bootloader. However, it is the same on all boards we have checked. Based on information provided by the vendor, all boards sold in small quantities are considered more as samples for development purposes. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com> Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-11-02 15:04:49 +00:00
u7621-06-256M-16M|\
vr500|\
wf-2881|\
whr-g300n|\
mqmaker,witi-256m|\
mqmaker,witi-512m|\
wl-wn575a3|\
wndr3700v5|\
youku-yk1|\
zbt-ape522ii|\
zbt-we1326|\
zbtlink,zbt-we3526|\
zbt-we826-16M|\
zbt-we826-32M|\
zbt-wg2626|\
zbt-wg3526-16M|\
zbt-wg3526-32M|\
zbt-wr8305rt)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "6@eth0"
;;
alfa-network,awusfree1|\
cs-qr10|\
d105|\
dlink,dap-1522-a1|\
dch-m225|\
ex2700|\
ex3700|\
hpm|\
mzk-ex300np|\
mzk-ex750np|\
na930|\
pbr-d1|\
ravpower,wd03|\
tama,w06|\
tplink,tl-mr3020-v3|\
u25awf-h1|\
wli-tx4-ag300n|\
wmdr-143n|\
wmr-300|\
wn3000rpv3|\
wrh-300cr)
ucidef_set_interface_lan "eth0"
;;
dlink,dwr-118-a2)
ucidef_add_switch "switch0" \
"1:lan:2" "2:lan:1" "3:lan:3" "4:lan" "0:wan" "6@eth0"
;;
mir3g)
ucidef_add_switch "switch0" \
ramips: improve Xiaomi Mi Router 3G support This commit improves support for the Xiaomi Mi Router 3G originally added in commit 6e283cdc0da25928f8148805ebef7f8f2b769ee8 Improvements: - Remove software watchdog as hardware watchdog now working as per commit 3fbf3ab44f5cebb22e30a4c8681b13341feed6a6 for all mt7621 devices. - Reset button polarity corrected - length of press determines reboot (short press) vs. reset to defaults (long press) behaviour. - Enable GPIO amber switch port LEDs on board rear - lit indicates 1Gbit link and blink on activity. Green LEDs driven directly by switch indicating any link speed and tx activity. - USB port power on/off GPIO exposed as 'usbpower' - Add access to uboot environment settings for checking/setting uboot boot order preference from user space. Changes: - Front LED indicator is physically made of independent Yellow/Amber, Red & Blue LEDs combined via a plastic 'lightpipe' to a front panel indicator, hence the colour behaviour is similar to an RGB LED. RGB LEDs are not supported at this time because they produce colour results that do not then match colour labels, e.g. enabling 'mir3g:red' and 'mir3g:blue' would result in a purple indicator and we have no such label for purple. The yellow, red & blue LEDs have been split out as individual yellow, red & blue status LEDs, with yellow being the default status LED as before and with red's WAN and blue's USB default associations removed. - Swapped order of vlan interfaces (eth0.1 & eth0.2) to match stock vlan layout. eth0.1 is LAN, eth0.2 is WAN - Add 'lwlll' vlan layout to mt7530 switch driver to prevent packet leakage between kernel switch init and uci swconfig uboot behaviour & system 'recovery' uboot expects to find bootable kernels at nand addresses 0x200000 & 0x600000 known by uboot as "system 1" and "system 2" respectively. uboot chooses which system to hand control to based on 3 environment variables: flag_last_success, flag_try_sys1_failed & flag_try_sys2_failed last_success represents a preference for a particular system and is set to 0 for system 1, set to 1 for system 2. last_success is considered *if* and only if both try_sys'n'_failed flags are 0 (ie. unset) If *either* failed flags are set then uboot will attempt to hand control to the non failed system. If both failed flags are set then uboot will check the uImage CRC of system 1 and hand control to it if ok. If the uImage CRC of system is not ok, uboot will hand control to system 2 irrespective of system 2's uImage CRC. NOTE: uboot only ever sets failed flags, it *never* clears them. uboot sets a system's failed flag if that system's was selected for boot but the uImage CRC is incorrect. Fortunately with serial console access, uboot provides the ability to boot an initramfs image transferred via tftp, similarly an image may be flashed to nand however it will flash to *both* kernels so a backup of stock kernel image is suggested. Note that the suggested install procedure below set's system 1's failed flag (stock) thus uboot ignores the last_success preference and boots LEDE located in system 2. Considerable thought has gone into whether LEDE should replace both kernels, only one (and which one) etc. LEDE kernels do not include a minimal rootfs and thus unlike the stock kernel cannot include a method of controlling uboot environment variables in the event of rootfs mount failure. Similarly uboot fails to provide an external mechanism for indicating boot system failure. Installation - from stock. Installation through telnet/ssh: - copy lede-ramips-mt7621-mir3g-squashfs-kernel1.bin and lede-ramips-mt7621-mir3g-squashfs-rootfs0.bin to usb disk or wget it from LEDE download site to /tmp - switch to /extdisks/sda1/ (if copied to USB drive) or to /tmp if wgetted from LEDE download site - run: mtd write lede-ramips-mt7621-mir3g-squashfs-kernel1.bin kernel1 - run: mtd write lede-ramips-mt7621-mir3g-squashfs-rootfs0.bin rootfs0 - run: nvram set flag_try_sys1_failed=1 - run: nvram commit - run: reboot Recovery - to stock. Assuming you used the above installation instructions you will have a stock kernel image in system 1. If it can be booted then it may be used to perform a stock firmware recovery, thus erasing LEDE completely. From a 'working' LEDE state (even failsafe) Failsafe only: - run: mount_root - run: sh /etc/uci-defaults/30_uboot-envtools Then do the steps for 'All' All: - run: fw_setenv flag_try_sys2_failed 1 - run: reboot The board will reboot into system 1 (stock basic kernel) and wait with system red light slowly blinking for a FAT formatted usb stick with a recovery image to be inserted. Press and hold the reset button for around 1 second. Status LED will turn yellow during recovery and blue when recovery complete. Signed-off-by: Kevin Darbyshire-Bryant <ldir@darbyshire-bryant.me.uk>
2017-09-25 19:41:13 +00:00
"2:lan:2" "3:lan:1" "1:wan" "6t@eth0"
;;
psg1218b)
ucidef_add_switch "switch0" \
"0:lan:3" "1:lan:2" "2:lan:1" "3:wan" "6@eth0"
;;
whr-300hp2|\
whr-600d|\
wsr-1166|\
wsr-600)
ucidef_add_switch "switch0" \
"0:lan:1" "1:lan:2" "2:lan:3" "3:lan:4" "4:wan:5" "6@eth0"
;;
ar670w|\
ar725w|\
rt-ac51u)
ucidef_add_switch "switch0" \
"0:wan" "1:lan" "2:lan" "3:lan" "4:lan" "6t@eth0"
;;
rt-n15|\
wl-351)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "5@eth0"
;;
asl26555-8M|\
asl26555-16M|\
rp-n53)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "6t@eth0"
;;
atp-52b|\
awm002-evb-4M|\
awm002-evb-8M|\
c20i|\
dir-645|\
f5d8235-v2|\
gl-mt300a|\
gl-mt300n|\
gl-mt750|\
hg255d|\
hiwifi,hc5861b|\
jhr-n805r|\
jhr-n825r|\
jhr-n926r|\
ramips: Add support for Mikrotik RouterBOARD RBM33g This commit adds support for the Mikrotik RouterBOARD RBM33g. =Hardware= The RBM33g is a mt7621 based device featuring three gigabit ports, 2 miniPCIe slots with sim card sockets, 1 M.2 slot, 1 USB 3.0 port and a male onboard RS-232 serial port. Additionally there are a lot of accessible GPIO ports and additional buses like i2c, mdio, spi and uart. ==Switch== The three Ethernet ports are all connected to the internal switch of the mt7621 SoC: port 0: Ethernet Port next to barrel jack with PoE printed on it port 1: Innermost Ethernet Port on opposite side of RS-232 port port 2: Outermost Ethernet Port on opposite side of RS-232 port port 6: CPU ==Flash== The device has two spi flash chips. The first flash chips is rather small (512 kB), connected to CS0 by default and contains only the RouterBOOT bootloader and some factory information (e.g. mac address). The second chip has a size of 16 MB, is by default connected to CS1 and contains the firmware image. ==PCIe== The board features three PCIe-enabled slots. Two of them are miniPCIe slots (PCIe0, PCIe1) and one is a M.2 (Key M) slot (PCIe2). Each of the miniPCIe slots is connected to a dedicated mini SIM socket on the back of the board. Power to all three PCIe-enabled slots is controlled via GPIOs on the mt7621 SoC: PCIe0: GPIO9 PCIe1: GPIO10 PCIe2: GPIO11 ==USB== The board has one external USB 3.0 port at the rear. Additionally PCIe port 0 has a permanently enabled USB interface. PCIe slot 1 shares its USB interface with the rear USB port. Thus only either the rear USB port or the USB interface of PCIe slot 1 can be active at the same time. The jumper next to the rear USB port controls which one is active: open: USB on PCIe 1 is active closed: USB on rear USB port is active ==Power== The board can accept both, passive PoE and external power via a 2.1 mm barrel jack. The input voltage range is 11-32 V. =Installation= ==Prerequisites== A USB -> RS-232 Adapter and a null modem cable are required for installation. To install an OpenWRT image to the device two components must be built: 1. A openwrt initramfs image 2. A openwrt sysupgrade image ===initramfs & sysupgrade image=== Select target devices "Mikrotik RBM33G" in openwrt menuconfig and build the images. This will create the images "openwrt-ramips-mt7621-mikrotik_rbm33g-initramfs-kernel.bin" and "openwrt-ramips-mt7621-mikrotik_rbm33g-squashfs-sysupgrade.bin" in the output directory. ==Installing== **Make sure to back up your RouterOS license in case you do ever want to go back to RouterOS using "/system license output" and back up the created license file.** Serial settings: 115200 8N1 The installation is a two-step process. First the "openwrt-ramips-mt7621-mikrotik_rbm33g-initramfs-kernel.bin" must be booted via tftp: 1. Set up a dhcp server that points the bootfile to tftp server serving the "openwrt-ramips-mt7621-mikrotik_rbm33g-initramfs-kernel.bin" initramfs image 2. Connect to WAN port (left side, next to sys-LED and power indicator) 3. Connect to serial port of board 4. Power on board and enter RouterBOOT setup menu 5. Set boot device to "boot over ethernet" 6. Set boot protocol to "dhcp protocol" (can be omitted if DHCP server allows dynamic bootp) 6. Save config 7. Wait for board to boot via Ethernet On the serial port you should now be presented with the OpenWRT boot log. The next steps will install OpenWRT persistently. 1. Copy "openwrt-ramips-mt7621-mikrotik_rbm33g-squashfs-sysupgrade.bin" to the device using scp. 2. Write openwrt to flash using "sysupgrade openwrt-ramips-mt7621-mikrotik_rbm33g-squashfs-sysupgrade.bin" Once the flashing completes reboot the router and let it boot from flash. It should boot straight to OpenWRT. Signed-off-by: Tobias Schramm <tobleminer@gmail.com>
2018-05-04 01:47:23 +00:00
mikrotik,rbm33g|\
mzk-wdpr|\
rb750gr3|\
rt-n14u|\
tplink,c20-v4|\
tplink,c50-v3|\
tplink,tl-mr3420-v5|\
tplink,tl-wr842n-v5|\
ramips: add support for TP-Link TL-WR840N v4 and TL-WR841N v13 TP-Link TL-WR840N v4 and TL-WR841N v13 are simple N300 routers with 5-port FE switch and non-detachable antennas. Both are very similar and are based on MediaTek MT7628NN (aka MT7628N) WiSoC. The difference between these two models is in number of available LEDs, buttons and power input switch. This work is partially based on GitHub PR#974. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 8 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - TL-WR840N v4: 5x LED (GPIO-controlled), 1x button - TL-WR841N v13: 8x LED (GPIO-controlled*), 2x button, power input switch * WAN LED in TL-WR841N v13 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Factory image notes: These devices use version 3 of TP-Link header, fortunately without RSA signature (at least in case of devices sold in Europe). The difference lays in the requirement for a non-zero value in "Additional Hardware Version" field. Ideally, it should match the value stored in vendor firmware header on device ("0x4"/"0x13" for these devices) but it seems that anything other than "0" is correct. We are able to prepare factory firwmare file which is accepted and (almost) correctly flashed from the vendor GUI. As it turned out, it accepts files without U-Boot image with second header at the beginning but due to some kind of bug in upgrade routine, flashed image gets corrupted before it's written to flash. Tests showed that the GUI upgrade routine copies value of "Additional Hardware Version" from existing firmware into offset "0x2023c" in provided file, _before_ storing it in flash. In case of vendor firmware upgrade files (which all include U-Boot image and two headers), this offset points to the matching field in kernel+rootfs firmware part header. Unfortunately, in case of LEDE factory image file which contains only one header, it points to the offset "0x2023c" in kernel image. This leads to a corrupted kernel and ends up with a "soft-bricked" device. The good news is that U-Boot in these devices contains well known tftp recovery mode, which can be triggered with "reset" button. What's more, in comparison to some of older MediaTek based TP-Link devices, this recovery mode doesn't write whole file at offset "0x0" in flash, without verifying provided file in advance. In case of recovery mode in these devices, first "0x20000" bytes are always skipped and "0x7a0000" bytes from rest of the file are stored in flash at offset "0x20000". Flash instruction: Until (if at all) TP-Link fixes described problem, the only way to flash LEDE image in these devices is to use tftp recovery mode in U-Boot: 1. Configure PC with static IP 192.168.0.66/24 and tftp server. 2. Rename "lede-ramips-mt7628-tl-wr84...-squashfs-tftp-recovery.bin" to "tp_recovery.bin" and place it in tftp server directory. 3. Connect PC with one of LAN ports, press the reset button, power up the router and keep button pressed for around 6-7 seconds, until device starts downloading the file. 4. Router will download file from server, write it to flash and reboot. To access U-Boot CLI, keep pressed "4" key during boot. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
2017-06-21 12:16:15 +00:00
tl-wr840n-v4|\
ramips: add support for TP-Link TL-WR840N v5 TP-Link TL-WR840N v5 is simple N300 router with 5-port FE switch and non-detachable antennas, based on MediaTek MT7628NN (aka MT7628N) WiSoC. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 4 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - 1x LED (GPIO-controlled), 1x button * LED in TL-WR840N v5 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Orange LED is registered so you can later use it for your own purposes. Flash instruction: Unlike TL-WR840N v4 flashing through WEB UI works in v5. 1. Download lede-ramips-mt76x8-tl-wr840n-v5-squashfs-sysupgrade.bin image. 2. Go to 192.168.0.1 3. Flash the sysupgrade image through Firmware upgrade section of WEB UI. 4. Wait until green LED stops flashing and use the router. Notes: TFTP recovery is broken since TP-Link reused bootloader code for v4 and that does not take into account only 4 MB of flash and bricks the device. So do not use TFTP Recovery or you will have to rewrite SPI flash. They fixed it in later GPL code,but it is unknown which version of bootloader you have. After manually compiling and flashing bootloader from GPL sources TFTP recovery works properly. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-08 13:00:06 +00:00
tl-wr840n-v5|\
ramips: add support for TP-Link TL-WR840N v4 and TL-WR841N v13 TP-Link TL-WR840N v4 and TL-WR841N v13 are simple N300 routers with 5-port FE switch and non-detachable antennas. Both are very similar and are based on MediaTek MT7628NN (aka MT7628N) WiSoC. The difference between these two models is in number of available LEDs, buttons and power input switch. This work is partially based on GitHub PR#974. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 8 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - TL-WR840N v4: 5x LED (GPIO-controlled), 1x button - TL-WR841N v13: 8x LED (GPIO-controlled*), 2x button, power input switch * WAN LED in TL-WR841N v13 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Factory image notes: These devices use version 3 of TP-Link header, fortunately without RSA signature (at least in case of devices sold in Europe). The difference lays in the requirement for a non-zero value in "Additional Hardware Version" field. Ideally, it should match the value stored in vendor firmware header on device ("0x4"/"0x13" for these devices) but it seems that anything other than "0" is correct. We are able to prepare factory firwmare file which is accepted and (almost) correctly flashed from the vendor GUI. As it turned out, it accepts files without U-Boot image with second header at the beginning but due to some kind of bug in upgrade routine, flashed image gets corrupted before it's written to flash. Tests showed that the GUI upgrade routine copies value of "Additional Hardware Version" from existing firmware into offset "0x2023c" in provided file, _before_ storing it in flash. In case of vendor firmware upgrade files (which all include U-Boot image and two headers), this offset points to the matching field in kernel+rootfs firmware part header. Unfortunately, in case of LEDE factory image file which contains only one header, it points to the offset "0x2023c" in kernel image. This leads to a corrupted kernel and ends up with a "soft-bricked" device. The good news is that U-Boot in these devices contains well known tftp recovery mode, which can be triggered with "reset" button. What's more, in comparison to some of older MediaTek based TP-Link devices, this recovery mode doesn't write whole file at offset "0x0" in flash, without verifying provided file in advance. In case of recovery mode in these devices, first "0x20000" bytes are always skipped and "0x7a0000" bytes from rest of the file are stored in flash at offset "0x20000". Flash instruction: Until (if at all) TP-Link fixes described problem, the only way to flash LEDE image in these devices is to use tftp recovery mode in U-Boot: 1. Configure PC with static IP 192.168.0.66/24 and tftp server. 2. Rename "lede-ramips-mt7628-tl-wr84...-squashfs-tftp-recovery.bin" to "tp_recovery.bin" and place it in tftp server directory. 3. Connect PC with one of LAN ports, press the reset button, power up the router and keep button pressed for around 6-7 seconds, until device starts downloading the file. 4. Router will download file from server, write it to flash and reboot. To access U-Boot CLI, keep pressed "4" key during boot. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
2017-06-21 12:16:15 +00:00
tl-wr841n-v13|\
ramips: add support for UniElec U7628-01 UniElec U7628-01 is a router platform board based on MediaTek MT7628AN. The device has the following specifications: - MT7628AN (580MHz) - 64/128/256 MB of RAM (DDR2) - 8/16 MB of flash (SPI NOR) - 5x 10/100 Mbps Ethernet (MT7628 built-in switch) - 1x 2T2R 2.4 GHz Wi-Fi (MT7628) - 1x miniPCIe slot (with PCIe and USB 2.0 buses) - 1x miniSIM slot - 1x microSD slot - 1x USB 2.0 port - 7x single-color LEDs (GPIO-controlled) - 1x bi-color LED (green GPIO-controlled, red -> LED_WLAN# in miniPCIe) - 1x reset button - 1x UART header (4-pins) - 1x SDXC/GPIO header (10-pins, connected with microSD slot) - 1x DC jack for main power (12 V) The following has been tested and is working: - Ethernet switch - miniPCIe slot (tested with modem and Wi-Fi card) - miniSIM slot - sysupgrade - reset button - USB 2.0 port* Due to a missing driver (MMC over GPIO) this is not supported: - microSD card reader * Warning: USB buses in miniPCIe and regular A-type socket are connected together, without any proper analog switch or USB HUB. Installation: This board might come with a different firmware versions (MediaTek SDK, PandoraBox, Padavan, etc.). If your board comes with PandoraBox, you can install LEDE using sysupgrade. Just SSH to the router and perform forced sysupgrade (due to a board name mismatch). The default IP of this board should be: 192.168.1.1 and username/password: root/admin. In case of a different firmware, you can use web based recovery described below. Use the following command to perform the sysupgrade (for the 128MB RAM/16MB flash version): sysupgrade -n -F lede-ramips-mt76x8-u7628-01-128M-16M-squashfs-sysupgrade.bin Recovery: This board contains a Chinese, closed-source bootloader called Breed (Boot and Recovery Environment for Embedded Devices). Breed supports web recovery and to enter it, you keep the reset button pressed for around 5 seconds during boot. Your machine will be assigned an IP through DHCP and the router will use IP address 192.168.1.1. The recovery website is in Chinese, but is easy to use. Click on the second item in the list to access the recovery page, then the second item on the next page is where you select the firmware. In order to start the recovery, you click the button at the bottom. SDXC/GPIO header (J3): 1. SDXC_D3 / I2C_SCLK 2. SDXC_D2 / I2C_SD 3. SDXC_D1 / I2S_DI 4. SDXC_D0 / I2S_WS 5. SDXC_CMD / I2S_CLK 6. SDXC_CLK / GPIO0 7. SDXC_CD / UART_RXD1 8. UART_TXD1 9. 3V3 10. GND Other notes: 1. The board is available with different amounts of RAM and flash. We have only added support for the 128/16 MB configuration, as that seems to be the default. However, all the required infrastructure is in place for making support for the other configurations easy. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com> Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-11-03 20:12:49 +00:00
u7628-01-128M-16M|\
ramips: add support for Ubiquiti EdgeRouter X (UBNT-ERX) This router is based on MT7621 SoC, no wifi, no usb, nand. Works: * Boots. * Ethernet. * Switch. * Button (reset). * Flashing OpenWrt from stock firmware. * Upgrading OpenWrt. Doesn't work: * No GPIO leds. All leds are controlled by switch, but stock firmware was able to control them. * SoC has crypto engine but no open driver. * SoC has nat acceleration, but no open driver. * This router has 2MB spi flash soldered in but MT nand/spi drivers do not support pin sharing, so it is not accessable and disabled. Stock firmware could read it and it was empty. * PoE out. Router has serial pins populated. If looking at the top of the router, then counting from Eth sockets pins go as: 'GND, RX, TX, GND'. 3.3v, 57600. U-boot bootloader supports tftpboot, controlled from serial. This router has two kernel partitions: 'live' and 'backup'. They are swapped during flashing (on both stock and OpenWrt). Active partition is controlled by a flag in a factory partition. U-boot has custom command to switch active kernel partition. Kernel partitions are 'bare flash' 3MB. Stock bootloader has no UBI support. Stock rootfs is UBIFS. Flashing procedure. Stock firmware uses custom kernel patch to mount squashfs from a file that is located on UBIFS volume. This makes wiping out this volume from within stock firmware difficult. Instead this patch builds image that is flashable by stock firmware and contains initrams image (with minimal set of packages to fit into kernel partition). Once this is flashed one can reboot into initramfs OpenWrt and use sysupgrade to flash OpenWrt including rootfs into nand. Note: factory image is only built if initramfs image is enabled. Signed-off-by: Nikolay Martynov <mar.kolya@gmail.com> SVN-Revision: 47881
2015-12-12 07:38:06 +00:00
ubnt-erx|\
ubnt-erx-sfp|\
ur-326n4g|\
wrtnode|\
wrtnode2p | \
wrtnode2r | \
youhua,wr1200js|\
zbt-wa05|\
zyxel,keenetic-extra-ii)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "0:wan" "6@eth0"
;;
c50|\
tplink,c20-v1)
ucidef_add_switch "switch0" \
"1:lan:3" "2:lan:4" "3:lan:1" "4:lan:2" "0:wan" "6@eth0"
;;
dir-860l-b1|\
elecom,wrc-1167ghbk2-s|\
elecom,wrc-2533gst|\
elecom,wrc-1900gst|\
ramips: add support for I-O DATA WN-AX1167GR I-O DATA WN-AX1167GR is a 2.4/5 GHz band 11ac router, based on MediaTek MT7621A. Specification: - MT7621A (2-Cores, 4-Threads) - 64 MB of RAM (DDR2) - 16 MB of Flash (SPI) - 2T2R 2.4/5 GHz - 5x 10/100/1000 Mbps Ethernet - 2x LEDs, 4x keys (2x buttons, 1x slide switch) - UART header on PCB - Vcc, GND, TX, RX from ethernet port side - baudrate: 115200 bps (U-Boot, OpenWrt) Stock firmware: In the stock firmware, WN-AX1167GR has two os images each composed of Linux kernel and rootfs. These images are stored in "Kernel" and "app" partition of the following partitions, respectively. (excerpt from dmesg): MX25L12805D(c2 2018c220) (16384 Kbytes) mtd .name = raspi, .size = 0x01000000 (16M) .erasesize = 0x00010000 (64K) .numeraseregions = 0 Creating 10 MTD partitions on "raspi": 0x000000000000-0x000001000000 : "ALL" 0x000000000000-0x000000030000 : "Bootloader" 0x000000030000-0x000000040000 : "Config " 0x000000040000-0x000000050000 : "Factory" 0x000000050000-0x000000060000 : "iNIC_rf" 0x000000060000-0x0000007e0000 : "Kernel" 0x000000800000-0x000000f80000 : "app" 0x000000f90000-0x000000fa0000 : "Key" 0x000000fa0000-0x000000fb0000 : "backup" 0x000000fb0000-0x000001000000 : "storage" The flag for boot partition is stored in "Key" partition, and U-Boot reads this and determines the partition to boot. If the image that U-Boot first reads according to the flag is "Bad Magic Number", U-Boot then tries to boot from the other image. If the second image is correct, change the flag to the number corresponding to that image and boot from that image. (example): ## Booting image at bc800000 ... Bad Magic Number,FFFFFFFF Boot from KERNEL 1 !! ## Booting image at bc060000 ... Image Name: MIPS OpenWrt Linux-4.14.50 Image Type: MIPS Linux kernel Image (lzma compressed) Data Size: 1865917 Bytes = 1.8 MB Load Address: 80001000 Entry Point: 80001000 Verifying Checksum ... OK Uncompressing Kernel Image ... OK raspi_erase_write: offs:f90000, count:34 . . Done! Starting kernel ... Flash instruction using factory image: 1. Connect the computer to the LAN port of WN-AX1167GR 2. Connect power cable to WN-AX1167GR and turn on it 3. Access to "192.168.0.1" on the web browser and open firmware update page ("ファームウェア") 4. Select the OpenWrt factory image and perform firmware update 5. On the initramfs image, execute "mtd erase firmware" to erase stock firmware and execute sysupgrade with sysupgrade image for WN-AX1167GR 6. Wait ~180 seconds to complete flasing Signed-off-by: INAGAKI Hiroshi <musashino.open@gmail.com>
2018-06-27 13:47:13 +00:00
iodata,wn-ax1167gr|\
iodata,wn-gx300gr)
ucidef_add_switch "switch0" \
"1:lan:4" "2:lan:3" "3:lan:2" "4:lan:1" "0:wan" "6@eth0"
;;
gnubee,gb-pc1|\
gnubee,gb-pc2)
ucidef_add_switch "switch0" \
"0:lan" "4:lan" "6@eth0"
;;
gl-mt300n-v2)
ucidef_add_switch "switch0" \
"1:lan" "0:wan" "6@eth0"
;;
awapn2403)
ucidef_add_switch "switch0" \
"0:lan" "1:wan" "6@eth0"
;;
b2c|\
nw718|\
psr-680w|\
sl-r7205|\
ur-336un|\
w502u|\
wr6202)
ucidef_set_interfaces_lan_wan "eth0.1" "eth0.2"
;;
br-6475nd)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "0:wan" "9@eth0"
;;
ramips: add support for the HNET C108 The HNET C108 (http://www.szhwtech88.com/Product-product-cid-100-id-4374.html) is a mifi based on MT7602A, which has the following specifications: * CPU: MT7620A * 1x 10/100Mbps Ethernet. * 16 MB Flash. * 64 MB RAM. * 1x USB 2.0 port. Only power is connected, this port is meant for charging other devices. * 1x mini-PCIe slots. * 1x SIM slots. * 1x 2.4Ghz WIFI. * 1x button. * 6000 mAh battery. * 5x controllable LEDs. Works: * Wifi. * Switch. * mini-PCIe slot. Only tested with a USB device (a modem). * SIM slot. * Sysupgrade. * Button (reset). Not working (also applies to the factory firmware): * Wifi LED. It is always switched on, there is no relation to the up/down state or activity of the wireless interface. Not tested: * SD card reader. Notes: * The C108 has no dedicated status LED. I therefore set the LAN LED as status LED. Installation: The router comes pre-installed with OpenWRT, including a variant of Luci. The initial firmware install can be done through this UI, following normal procedure. I.e., access the UI and update the firmware using the sysupgrade-image. Remember to select that you do not want to keep existing settings. Recovery: If you brick the device, the C108 supports recovery using TFTP. Keep the reset button pressed for ~5sec when booting to trigger TFTP. Set the address of the network interface on your machine to 10.10.10.3/24, and rename your image file to Kernal.bin. Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-09-06 09:14:16 +00:00
c108|\
cf-wr800n)
ucidef_add_switch "switch0" \
"4:lan" "6t@eth0"
;;
cy-swr1100)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "9@eth0"
;;
duzun-dm06)
ucidef_add_switch "switch0" \
"1:lan" "0:wan" "6@eth0"
;;
e1700|\
mt7620a_mt7530)
ucidef_add_switch "switch1" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "6@eth0"
;;
edimax,br-6478ac-v2|\
tplink,c2-v1)
ucidef_add_switch "switch1" \
"1:lan" "2:lan" "3:lan" "4:lan" "0:wan" "6@eth0"
;;
hc5*61|\
y1s)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "5:lan" "0:wan" "6@eth0"
;;
kn_rf)
ucidef_add_switch "switch0" \
"0:wan" "1:lan" "2:lan" "3:lan" "4:lan" "6@eth0"
;;
kng_rc)
ucidef_add_switch "switch1" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "7t@eth0"
;;
mlwg2|\
wizard8800|\
wl-330n)
ucidef_set_interface_lan "eth0.1"
;;
mr200)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "6t@eth0"
ucidef_set_interface_wan "usb0"
;;
mzk-dp150n|\
vocore-8M|\
vocore-16M)
ucidef_add_switch "switch0" \
"0:lan" "4:lan" "6t@eth0"
;;
newifi-d1)
ucidef_add_switch "switch0" \
"1:lan:2" "2:lan:1" "4:wan" "6@eth0"
;;
phicomm,k2g)
ucidef_add_switch "switch0" \
"0:lan:4" "1:lan:3" "2:lan:2" "3:lan:1" "5:wan" "6@eth0"
;;
re350-v1)
ucidef_add_switch "switch0" \
"0:lan" "6@eth0"
;;
re6500)
ucidef_add_switch "switch0" \
"0:lan:1" "1:lan:2" "2:lan:3" "3:lan:4" "6@eth0"
;;
rt-n56u)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "4:wan" "8@eth0"
;;
tew-638apb-v2)
ucidef_add_switch "switch0" \
"4:lan" "6@eth0"
;;
tew-691gr|\
ramips: add support for Sitecom WLR-6000 The Sitecom firmware upgrade file has SENAO_FIRMWARE_TYPE 2 set. This looks rather wrong since SENAO_FIRMWARE_TYPE 2 is kernel only but the file is way to big for only including a kernel. The factory image need to have the dlf file extension. Otherwise the Sitecom firmware rejects the file. The stock firmware uses the following mac addresses: LAN: 00:0C:F6:AA:BB:D8 (u-boot env: ethaddr) 2,4: 00:0C:F6:AA:BB:D8 (EEPROM) 5: 00:0C:F6:AA:BB:DC (EEPROM) WAN: 00:0C:F6:AA:C8:43 (u-boot env: wanaddr) Assuming the mac address range :D8 to :DC is reserved for this device, the MAC addresses were reorder to have a unique MAC address for each interface: 2.4GHz: 00:0C:F6:AA:BB:D8 LAN: 00:0C:F6:AA:BB:D9 WAN: 00:0C:F6:AA:BB:DA 5 GHz: 00:0C:F6:AA:BB:DC The first MAC is assigned to the 2.4GHz WiFi interface to keep compatibility with the SSIDs printed on the case, which have the last three sextets of the MAC address appended. There are still issues with the rt2x00 driver. It is not possible to use both wireless interfaces at the same time. The 2.4 GHz wireless (PCIe) only works if the internal 5GHz wireless is/has been enabled or used for scanning. The internal 5GHz wireless only works if the 2.4GHz wireless (PCIe) was never enabled. Disabling the 2.4Ghz after it was enabled will result in stations seeing the 5Ghz AP but are unable to connect. Due to the not optimal working wifi the manufacture, backup and storage partitions of the OEM firmware are kept for now to allow an easy switch back to the Sitecom firmware. Signed-off-by: Jasper Scholte <NightNL@outlook.com> Signed-off-by: Mathias Kresin <dev@kresin.me>
2016-08-14 21:30:44 +00:00
tew-692gr|\
wlr-6000)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "5:wan" "0@eth0"
;;
tplink,tl-wr902ac-v3)
ucidef_add_switch "switch0" \
"4:lan" "6@eth0"
;;
vonets,var11n-300|\
wt1520-4M|\
wt1520-8M)
ramips: add support for Vonets VAR11N-300 The VAR11N-300 is a tiny wireless-N device with a hardwired Ethernet cable, one extra Ethernet port, and an internal antenna, based on the MediaTek MT7620n chipset. Specs: - MT7620n WiSoC @ 600MHz - 32 MB SDRAM - 4 MB SPI flash - 2T2R 2.4GHz WiFi-N - 1 attached 10/100 Ethernet cable (LAN) - 1 10/100 Ethernet port (WAN) - 1 attached USB / barrel 5vdc power cable - 5 LEDs (see notes below) - 1 reset button - 1 UART (3 pads on board) Installation: The stock firmware does not support uploading new firmware directly, only checking the manufacturer's site for updates. This process may be possible to spoof, but the update check uses some kind of homebrew encryption that I didn't investigate. Instead, you can install via a backdoor: 1. Set up a TFTP server to serve the firmware binary (lede-ramips-mt7620-var11n-300-squashfs-sysupgrade.bin) 2. Factory reset the device by holding the reset button for a few seconds. 3. Open the web interface (default IP: 192.168.253.254) 4. Log in with the "super admin" credentials: username `vonets`, password `vonets26642519`. 5. On the "Operative Status" page, click the text "System Uptime", then quickly click the uptime value. 6. If successful, an alert dialog will appear reading "Ated start", and the device will now accept telnet connections. If the alert does not appear, repeat step 5 until it works (the timing is a bit tricky). 7. Telnet to the device using credentials "admin / admin" 8. Retrieve the firmware binary from the tftp server: `tftp -l lede.bin -r lede-ramips-mt7620-var11n-300-squashfs-sysupgrade.bin -g <tftp-server-ip>` 9. Write the firmware to flash: `mtd_write write lede.bin /dev/mtd4` 10. Reboot Tested: - LAN / WAN ethernet - WiFi - LAN / WAN / status LED GPIOs (see notes below) - Reset button - Sysupgrade Notes: LEDs: The board has 5 LEDs - two green LEDs for LAN / WAN activity, one blue LED for WiFi, and a pair of "status" LEDs connected to the same GPIO (the blue LED lights when the GPIO is low, and the green when it's high). I was unable to determine how to operate the WiFi LED, as it does not appear to be controlled by a GPIO directly. Recovery: The default U-boot installation will only boot from flash due to a missing environment block. I generated a valid 4KB env block using U-boot's `fw_setenv` tool and wrote it to flash at 0x30000 using an external programmer. After this, it was possible to enter the U-boot commandline interface and download a new image via TFTP (`tftpboot 81b00000 <image-filename>`), but while I could boot this image sucessfully (`bootm`), writing it to flash (`cp.linux`) just corrupted the flash chip. The sysupgrade file can be written to flash at 0x50000 using an external programmer. Signed-off-by: Andrew Crawley <acrawley@gmail.com>
2017-11-23 23:52:13 +00:00
ucidef_add_switch "switch0" \
"0:lan" "4:wan" "6@eth0"
;;
vocore2|\
vocore2lite)
ucidef_add_switch "switch0" \
"0:lan" "2:lan" "6t@eth0"
;;
f5d8235-v1|\
tew-714tru|\
v11st-fe|\
wzr-agl300nh)
ucidef_add_switch "switch0" \
"1:lan" "2:lan" "3:lan" "4:lan" "0:wan" "5@eth0"
;;
wcr-1166ds)
ucidef_add_switch "switch0" \
"3:lan" "4:wan" "6@eth0"
;;
ramips: Add support for ZBT WE1026-5G The ZBT WE1026-5G (http://www.zbtlink.com/products/router/WE1026-5G.html) is the follow-up to the ZBT WE1026 and is based on MT7620. For the previous WE1026, the ZBT WE826 image could be used. However, as the name implies, the -5G comes equipped with a 5GHz wifi radio. As the WE826 only has a 2.4GHz radio, the addition of 5GHz means that a separate image is needed for the WE1026-5G. I suspect that this image will also work on the previous WE1026, but I don't have a device to test with. The WE1026-5G has following specifications: * CPU: MT7620A * 1x 10/100Mbps Ethernet. * 16 MB Flash. * 64 MB RAM. * 1x USB 2.0 port. * 1x mini-PCIe slots. * 1x SIM slots. * 1x 2.4Ghz WIFI. * 1x 5GHz wifi (MT7612) * 1x button. * 3x controllable LEDs. Works: * Wifi. * Switch. * mini-PCIe slot. Only tested with a USB device (a modem). * SIM slot. * Sysupgrade. * Button (reset). Not working: * The 5GHz WIFI LED is completely dead. I suspect the issue is the same as on other devices with Mediatek 5Ghz wifi-cards/chips. The LED is controlled by the driver, and mt76 (currently) does not support this. Not tested: * SD card reader. Notes: * The modem (labeled 3G/4G) and power LEDs are controlled by the hardware. * There is a 32MB version of this device available, but I do not have access to it. I have therefor only added support for the 16MB version, but added all the required infrastructure to make adding support for the 32MB version easy. Installation: The router comes pre-installed with OpenWRT, including a variant of Luci. The initial firmware install can be done through this UI, following normal procedure. I.e., access the UI and update the firmware using the sysupgrade-image. Remember to select that you do not want to keep existing settings. Recovery: If you brick the device, the WE1026-5G supports recovery using HTTP. Keep the reset button pressed for ~5sec when booting to start the web server. Set the address of the network interface on your machine to 192.168.1.2/24, and point your browser to 192.168.1.1 to access the recovery UI. From the recovery UI you can upload a firmware image. Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-09-10 12:44:47 +00:00
wcr-150gn|\
we1026-5g-16m)
ucidef_add_switch "switch0" \
"0:lan" "6t@eth0"
;;
whr-1166d)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:lan" "3:lan" "5:wan" "6@eth0"
;;
wizfi630a)
ucidef_add_switch "switch0" \
"0:lan" "1:lan" "2:wan" "6@eth0"
;;
wt3020-4M|\
wt3020-8M)
ucidef_add_switch "switch0" \
"4:lan" "0:wan" "6@eth0"
;;
zbtlink,zbt-we1226|\
y1)
ucidef_add_switch "switch0" \
"0:lan:2" "1:lan:1" "4:wan" "6@eth0"
;;
*)
RT3X5X=`cat /proc/cpuinfo | egrep "(RT3.5|RT5350)"`
if [ -n "${RT3X5X}" ]; then
ramips_setup_rt3x5x_vlans
else
ucidef_set_interfaces_lan_wan "eth0.1" "eth0.2"
fi
;;
esac
}
ramips_setup_macs()
{
local board="$1"
local lan_mac=""
local wan_mac=""
case $board in
a5-v11|\
ht-tm02|\
wmdr-143n)
lan_mac=$(cat /sys/class/net/eth0/address)
;;
all0239-3g|\
carambola|\
freestation5|\
w502u|\
wnce2001)
wan_mac=$(mtd_get_mac_binary factory 46)
;;
bc2|\
broadway|\
d105|\
dir-300-b7|\
dir-320-b1|\
dir-620-a1|\
esr-9753|\
freestation5|\
hlk-rm04|\
mpr-a1|\
psr-680w|\
sl-r7205|\
y1|\
y1s)
lan_mac=$(cat /sys/class/net/eth0/address)
lan_mac=$(macaddr_setbit_la "$lan_mac")
wan_mac=$(macaddr_add "$lan_mac" 1)
;;
br-6475nd)
lan_mac=$(cat /sys/class/net/eth0/address)
wan_mac=$(mtd_get_mac_binary devdata 7)
;;
cy-swr1100|\
dch-m225)
lan_mac=$(mtd_get_mac_ascii factory lanmac)
;;
dir-645)
lan_mac=$(mtd_get_mac_ascii nvram lanmac)
wan_mac=$(mtd_get_mac_ascii nvram wanmac)
;;
dir-860l-b1)
lan_mac=$(mtd_get_mac_ascii factory lanmac)
wan_mac=$(mtd_get_mac_ascii factory wanmac)
;;
dlink,dwr-116-a1|\
dlink,dwr-118-a2|\
dlink,dwr-921-c1)
wan_mac=$(jboot_config_read -m -i $(find_mtd_part "config") -o 0xE000)
lan_mac=$(macaddr_add "$wan_mac" 1)
;;
e1700)
wan_mac=$(mtd_get_mac_ascii config WAN_MAC_ADDR)
;;
edimax,br-6478ac-v2)
lan_mac=$(cat /sys/class/net/eth0/address)
wan_mac=$(macaddr_add "$lan_mac" 2)
;;
elecom,wrc-1167ghbk2-s|\
elecom,wrc-2533gst|\
elecom,wrc-1900gst|\
sk-wb8)
wan_mac=$(mtd_get_mac_binary factory 57350)
;;
gl-mt300n-v2|\
whr-g300n)
wan_mac=$(mtd_get_mac_binary factory 4)
;;
hc5*61|\
hc5661a|\
hc5962|\
hiwifi,hc5861b)
lan_mac=`mtd_get_mac_ascii bdinfo "Vfac_mac "`
[ -n "$lan_mac" ] || lan_mac=$(cat /sys/class/net/eth0/address)
wan_mac=$(macaddr_add "$lan_mac" 1)
;;
ramips: add support for I-O DATA WN-AX1167GR I-O DATA WN-AX1167GR is a 2.4/5 GHz band 11ac router, based on MediaTek MT7621A. Specification: - MT7621A (2-Cores, 4-Threads) - 64 MB of RAM (DDR2) - 16 MB of Flash (SPI) - 2T2R 2.4/5 GHz - 5x 10/100/1000 Mbps Ethernet - 2x LEDs, 4x keys (2x buttons, 1x slide switch) - UART header on PCB - Vcc, GND, TX, RX from ethernet port side - baudrate: 115200 bps (U-Boot, OpenWrt) Stock firmware: In the stock firmware, WN-AX1167GR has two os images each composed of Linux kernel and rootfs. These images are stored in "Kernel" and "app" partition of the following partitions, respectively. (excerpt from dmesg): MX25L12805D(c2 2018c220) (16384 Kbytes) mtd .name = raspi, .size = 0x01000000 (16M) .erasesize = 0x00010000 (64K) .numeraseregions = 0 Creating 10 MTD partitions on "raspi": 0x000000000000-0x000001000000 : "ALL" 0x000000000000-0x000000030000 : "Bootloader" 0x000000030000-0x000000040000 : "Config " 0x000000040000-0x000000050000 : "Factory" 0x000000050000-0x000000060000 : "iNIC_rf" 0x000000060000-0x0000007e0000 : "Kernel" 0x000000800000-0x000000f80000 : "app" 0x000000f90000-0x000000fa0000 : "Key" 0x000000fa0000-0x000000fb0000 : "backup" 0x000000fb0000-0x000001000000 : "storage" The flag for boot partition is stored in "Key" partition, and U-Boot reads this and determines the partition to boot. If the image that U-Boot first reads according to the flag is "Bad Magic Number", U-Boot then tries to boot from the other image. If the second image is correct, change the flag to the number corresponding to that image and boot from that image. (example): ## Booting image at bc800000 ... Bad Magic Number,FFFFFFFF Boot from KERNEL 1 !! ## Booting image at bc060000 ... Image Name: MIPS OpenWrt Linux-4.14.50 Image Type: MIPS Linux kernel Image (lzma compressed) Data Size: 1865917 Bytes = 1.8 MB Load Address: 80001000 Entry Point: 80001000 Verifying Checksum ... OK Uncompressing Kernel Image ... OK raspi_erase_write: offs:f90000, count:34 . . Done! Starting kernel ... Flash instruction using factory image: 1. Connect the computer to the LAN port of WN-AX1167GR 2. Connect power cable to WN-AX1167GR and turn on it 3. Access to "192.168.0.1" on the web browser and open firmware update page ("ファームウェア") 4. Select the OpenWrt factory image and perform firmware update 5. On the initramfs image, execute "mtd erase firmware" to erase stock firmware and execute sysupgrade with sysupgrade image for WN-AX1167GR 6. Wait ~180 seconds to complete flasing Signed-off-by: INAGAKI Hiroshi <musashino.open@gmail.com>
2018-06-27 13:47:13 +00:00
iodata,wn-ax1167gr|\
iodata,wn-gx300gr)
wan_mac=$(macaddr_add "$(mtd_get_mac_binary Factory 4)" 1)
;;
kn_rc|\
kn_rf|\
kng_rc)
wan_mac=$(mtd_get_mac_binary factory 40)
;;
linkits7688)
wan_mac=$(mtd_get_mac_binary factory 4)
lan_mac=$(mtd_get_mac_binary factory 46)
;;
mac1200rv2)
lan_mac=$(mtd_get_mac_binary factory_info 13)
wan_mac=$(macaddr_add "$lan_mac" 1)
;;
mir3g)
ramips: improve Xiaomi Mi Router 3G support This commit improves support for the Xiaomi Mi Router 3G originally added in commit 6e283cdc0da25928f8148805ebef7f8f2b769ee8 Improvements: - Remove software watchdog as hardware watchdog now working as per commit 3fbf3ab44f5cebb22e30a4c8681b13341feed6a6 for all mt7621 devices. - Reset button polarity corrected - length of press determines reboot (short press) vs. reset to defaults (long press) behaviour. - Enable GPIO amber switch port LEDs on board rear - lit indicates 1Gbit link and blink on activity. Green LEDs driven directly by switch indicating any link speed and tx activity. - USB port power on/off GPIO exposed as 'usbpower' - Add access to uboot environment settings for checking/setting uboot boot order preference from user space. Changes: - Front LED indicator is physically made of independent Yellow/Amber, Red & Blue LEDs combined via a plastic 'lightpipe' to a front panel indicator, hence the colour behaviour is similar to an RGB LED. RGB LEDs are not supported at this time because they produce colour results that do not then match colour labels, e.g. enabling 'mir3g:red' and 'mir3g:blue' would result in a purple indicator and we have no such label for purple. The yellow, red & blue LEDs have been split out as individual yellow, red & blue status LEDs, with yellow being the default status LED as before and with red's WAN and blue's USB default associations removed. - Swapped order of vlan interfaces (eth0.1 & eth0.2) to match stock vlan layout. eth0.1 is LAN, eth0.2 is WAN - Add 'lwlll' vlan layout to mt7530 switch driver to prevent packet leakage between kernel switch init and uci swconfig uboot behaviour & system 'recovery' uboot expects to find bootable kernels at nand addresses 0x200000 & 0x600000 known by uboot as "system 1" and "system 2" respectively. uboot chooses which system to hand control to based on 3 environment variables: flag_last_success, flag_try_sys1_failed & flag_try_sys2_failed last_success represents a preference for a particular system and is set to 0 for system 1, set to 1 for system 2. last_success is considered *if* and only if both try_sys'n'_failed flags are 0 (ie. unset) If *either* failed flags are set then uboot will attempt to hand control to the non failed system. If both failed flags are set then uboot will check the uImage CRC of system 1 and hand control to it if ok. If the uImage CRC of system is not ok, uboot will hand control to system 2 irrespective of system 2's uImage CRC. NOTE: uboot only ever sets failed flags, it *never* clears them. uboot sets a system's failed flag if that system's was selected for boot but the uImage CRC is incorrect. Fortunately with serial console access, uboot provides the ability to boot an initramfs image transferred via tftp, similarly an image may be flashed to nand however it will flash to *both* kernels so a backup of stock kernel image is suggested. Note that the suggested install procedure below set's system 1's failed flag (stock) thus uboot ignores the last_success preference and boots LEDE located in system 2. Considerable thought has gone into whether LEDE should replace both kernels, only one (and which one) etc. LEDE kernels do not include a minimal rootfs and thus unlike the stock kernel cannot include a method of controlling uboot environment variables in the event of rootfs mount failure. Similarly uboot fails to provide an external mechanism for indicating boot system failure. Installation - from stock. Installation through telnet/ssh: - copy lede-ramips-mt7621-mir3g-squashfs-kernel1.bin and lede-ramips-mt7621-mir3g-squashfs-rootfs0.bin to usb disk or wget it from LEDE download site to /tmp - switch to /extdisks/sda1/ (if copied to USB drive) or to /tmp if wgetted from LEDE download site - run: mtd write lede-ramips-mt7621-mir3g-squashfs-kernel1.bin kernel1 - run: mtd write lede-ramips-mt7621-mir3g-squashfs-rootfs0.bin rootfs0 - run: nvram set flag_try_sys1_failed=1 - run: nvram commit - run: reboot Recovery - to stock. Assuming you used the above installation instructions you will have a stock kernel image in system 1. If it can be booted then it may be used to perform a stock firmware recovery, thus erasing LEDE completely. From a 'working' LEDE state (even failsafe) Failsafe only: - run: mount_root - run: sh /etc/uci-defaults/30_uboot-envtools Then do the steps for 'All' All: - run: fw_setenv flag_try_sys2_failed 1 - run: reboot The board will reboot into system 1 (stock basic kernel) and wait with system red light slowly blinking for a FAT formatted usb stick with a recovery image to be inserted. Press and hold the reset button for around 1 second. Status LED will turn yellow during recovery and blue when recovery complete. Signed-off-by: Kevin Darbyshire-Bryant <ldir@darbyshire-bryant.me.uk>
2017-09-25 19:41:13 +00:00
lan_mac=$(mtd_get_mac_binary Factory 0xe006)
;;
miwifi-mini)
wan_mac=$(cat /sys/class/net/eth0/address)
lan_mac=$(macaddr_setbit_la "$wan_mac")
;;
m3|\
m4-4M|\
m4-8M|\
x5|\
x8)
lan_mac=$(cat /sys/class/net/eth0/address)
lan_mac=$(macaddr_add "$lan_mac" -2)
;;
newifi-d1)
lan_mac=$(cat /sys/class/net/eth0/address)
lan_mac=$(macaddr_add "$lan_mac" 2)
;;
omega2|\
omega2p)
wan_mac=$(mtd_get_mac_binary factory 4)
lan_mac=$(mtd_get_mac_binary factory 46)
;;
oy-0001|\
phicomm,k2g)
lan_mac=$(mtd_get_mac_binary factory 40)
wan_mac=$(mtd_get_mac_binary factory 46)
;;
r6220)
wan_mac=$(mtd_get_mac_binary factory 4)
lan_mac=$(macaddr_add "$wan_mac" 1)
;;
rt-n56u)
lan_mac=$(cat /sys/class/net/eth0/address)
lan_mac=$(macaddr_setbit_la "$lan_mac")
wan_mac=$(mtd_get_mac_binary factory 32772)
;;
tew-691gr)
wan_mac=$(macaddr_add "$(mtd_get_mac_binary factory 4)" 3)
;;
tew-692gr)
wan_mac=$(macaddr_add "$(mtd_get_mac_binary factory 4)" 1)
;;
tiny-ac)
lan_mac=$(mtd_get_mac_ascii u-boot-env LAN_MAC_ADDR)
wan_mac=$(mtd_get_mac_ascii u-boot-env WAN_MAC_ADDR)
;;
vr500)
lan_mac=$(mtd_get_mac_binary factory 57344)
wan_mac=$(mtd_get_mac_binary factory 57350)
;;
w306r-v20)
lan_mac=$(cat /sys/class/net/eth0/address)
wan_mac=$(macaddr_add "$lan_mac" 5)
;;
wcr-1166ds|\
wsr-1166)
local index="$(find_mtd_index "board_data")"
wan_mac="$(grep -m1 mac= "/dev/mtd${index}" | cut -d= -f2)"
lan_mac=$wan_mac
;;
wcr-150gn)
wan_mac=$(mtd_get_mac_binary factory 40)
;;
whr-1166d|\
whr-300hp2|\
whr-600d|\
wsr-600)
wan_mac=$(mtd_get_mac_binary factory 4)
lan_mac=$wan_mac
;;
wizfi630a)
lan_mac=$(mtd_get_mac_binary factory 4)
wan_mac=$(mtd_get_mac_binary factory 40)
;;
ramips: add support for Sitecom WLR-6000 The Sitecom firmware upgrade file has SENAO_FIRMWARE_TYPE 2 set. This looks rather wrong since SENAO_FIRMWARE_TYPE 2 is kernel only but the file is way to big for only including a kernel. The factory image need to have the dlf file extension. Otherwise the Sitecom firmware rejects the file. The stock firmware uses the following mac addresses: LAN: 00:0C:F6:AA:BB:D8 (u-boot env: ethaddr) 2,4: 00:0C:F6:AA:BB:D8 (EEPROM) 5: 00:0C:F6:AA:BB:DC (EEPROM) WAN: 00:0C:F6:AA:C8:43 (u-boot env: wanaddr) Assuming the mac address range :D8 to :DC is reserved for this device, the MAC addresses were reorder to have a unique MAC address for each interface: 2.4GHz: 00:0C:F6:AA:BB:D8 LAN: 00:0C:F6:AA:BB:D9 WAN: 00:0C:F6:AA:BB:DA 5 GHz: 00:0C:F6:AA:BB:DC The first MAC is assigned to the 2.4GHz WiFi interface to keep compatibility with the SSIDs printed on the case, which have the last three sextets of the MAC address appended. There are still issues with the rt2x00 driver. It is not possible to use both wireless interfaces at the same time. The 2.4 GHz wireless (PCIe) only works if the internal 5GHz wireless is/has been enabled or used for scanning. The internal 5GHz wireless only works if the 2.4GHz wireless (PCIe) was never enabled. Disabling the 2.4Ghz after it was enabled will result in stations seeing the 5Ghz AP but are unable to connect. Due to the not optimal working wifi the manufacture, backup and storage partitions of the OEM firmware are kept for now to allow an easy switch back to the Sitecom firmware. Signed-off-by: Jasper Scholte <NightNL@outlook.com> Signed-off-by: Mathias Kresin <dev@kresin.me>
2016-08-14 21:30:44 +00:00
wlr-6000)
wan_mac=$(macaddr_add "$(mtd_get_mac_binary factory 32772)" 2)
;;
*)
lan_mac=$(cat /sys/class/net/eth0/address)
wan_mac=$(macaddr_add "$lan_mac" 1)
;;
esac
[ -n "$lan_mac" ] && ucidef_set_interface_macaddr "lan" $lan_mac
[ -n "$wan_mac" ] && ucidef_set_interface_macaddr "wan" $wan_mac
}
board_config_update
board=$(board_name)
ramips_setup_interfaces $board
ramips_setup_macs $board
board_config_flush
exit 0