This patch adds support for Cisco Meraki MR33
hardware highlights:
SOC: IPQ4029 Quad-Core ARMv7 Processor rev 5 (v7l) Cortex-A7
DRAM: 256 MiB DDR3L-1600 @ 627 MHz Micron MT41K128M16JT-125IT
NAND: 128 MiB SLC NAND Spansion S34ML01G200TFV00 (106 MiB usable)
ETH: Qualcomm Atheros AR8035 Gigabit PHY (1 x LAN/WAN) + PoE
WLAN1: QCA9887 (168c:0050) PCIe 1x1:1 802.11abgn ac Dualband VHT80
WLAN2: Qualcomm Atheros QCA4029 2.4GHz 802.11bgn 2:2x2
WLAN3: Qualcomm Atheros QCA4029 5GHz 802.11a/n/ac 2:2x2 VHT80
LEDS: 1 x Programmable RGB+White Status LED (driven by Ti LP5562 on i2c-1)
1 x Orange LED Fault Indicator (shared with LP5562)
2 x LAN Activity / Speed LEDs (On the RJ45 Port)
BUTTON: one Reset button
MISC: Bluetooth LE Ti cc2650 PG2.3 4x4mm - BL_CONFIG at 0x0001FFD8
AT24C64 8KiB EEPROM
Kensington Lock
Serial:
WARNING: The serial port needs a TTL/RS-232 3V3 level converter!
The Serial setting is 115200-8-N-1. The board has a populated
1x4 0.1" header with half-height/low profile pins.
The pinout is: VCC (little white arrow), RX, TX, GND.
Flashing needs a serial adaptor, as well as patched ubootwrite utility
(needs Little-Endian support). And a modified u-boot (enabled Ethernet).
Meraki's original u-boot source can be found in:
<https://github.com/riptidewave93/meraki-uboot/tree/mr33-20170427>
Add images to do an installation via bootloader:
0. open up the MR33 and connect the serial console.
1. start the 2nd stage bootloader transfer from client pc:
# ubootwrite.py --write=mr33-uboot.bin
(The ubootwrite tool will interrupt the boot-process and hence
it needs to listen for cues. If the connection is bad (due to
the low-profile pins), the tool can fail multiple times and in
weird ways. If you are not sure, just use a terminal program
and see what the device is doing there.
2. power on the MR33 (with ethernet + serial cables attached)
Warning: Make sure you do this in a private LAN that has
no connection to the internet.
- let it upload the u-boot this can take 250-300 seconds -
3. use a tftp client (in binary mode!) on your PC to upload the sysupgrade.bin
(the u-boot is listening on 192.168.1.1)
# tftp 192.168.1.1
binary
put openwrt-ipq40xx-meraki_mr33-squashfs-sysupgrade.bin
4. wait for it to reboot
5. connect to your MR33 via ssh on 192.168.1.1
For more detailed instructions, please take a look at the:
"Flashing Instructions for the MR33" PDF. This can be found
on the wiki: <https://openwrt.org/toh/meraki/mr33>
(A link to the mr33-uboot.bin + the modified ubootwrite is
also there)
Thanks to Jerome C. for sending an MR33 to Chris.
Signed-off-by: Chris Blake <chrisrblake93@gmail.com>
Signed-off-by: Mathias Kresin <dev@kresin.me>
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
This patch adds support for ASUS RT-AC58U/RT-ACRH13.
hardware highlights:
SOC: IPQ4018 / QCA Dakota
CPU: Quad-Core ARMv7 Processor rev 5 (v7l) Cortex-A7
DRAM: 128 MiB DDR3L-1066 @ 537 MHz (1074?) NT5CC64M16GP-DI
NOR: 2 MiB Macronix MX25L1606E (for boot, QSEE)
NAND: 128 MiB Winbond W25NO1GVZE1G (cal + kernel + root, UBI)
ETH: Qualcomm Atheros QCA8075 Gigabit Switch (4 x LAN, 1 x WAN)
USB: 1 x 3.0 (via Synopsys DesignWare DWC3 controller in the SoC)
WLAN1: Qualcomm Atheros QCA4018 2.4GHz 802.11bgn 2:2x2
WLAN2: Qualcomm Atheros QCA4018 5GHz 802.11a/n/ac 2:2x2
INPUT: one Reset and one WPS button
LEDS: Status, WAN, WIFI1/2, USB and LAN (one blue LED for each)
Serial:
WARNING: The serial port needs a TTL/RS-232 3V3 level converter!
The Serial setting is 115200-8-N-1. The board has an unpopulated
1x4 0.1" header. The pinout (VDD, RX, GND, TX) is printed on the
PCB right next to the connector.
U-Boot Note: The ethernet driver isn't always reliable and can sometime
time out... Don't worry, just retry.
Access via the serial console is required. As well as a working
TFTP-server setup and the initramfs image. (If not provided, it
has to be built from the OpenWrt source. Make sure to enable
LZMA as the compression for the INITRAMFS!)
To install the image permanently, you have to do the following
steps in the listed order.
1. Open up the router.
There are four phillips screws hiding behind the four plastic
feets on the underside.
2. Connect the serial cable (See notes above)
3. Connect your router via one of the four LAN-ports (yellow)
to a PC which can set the IP-Address and ssh and scp from.
If possible set your PC's IPv4 Address to 192.168.1.70
(As this is the IP-Address the Router's bootloader expects
for the tftp server)
4. power up the router and enter the u-boot
choose option 1 to upload the initramfs image. And follow
through the ipv4 setup.
Wait for your router's status LED to stop blinking rapidly and
glow just blue. (The LAN LED should also be glowing blue).
3. Connect to the OpenWrt running in RAM
The default IPv4-Address of your router will be 192.168.1.1.
1. Copy over the openwrt-sysupgrade.bin image to your router's
temporary directory
# scp openwrt-sysupgrade.bin root@192.168.1.1:/tmp
2. ssh from your PC into your router as root.
# ssh root@192.168.1.1
The default OpenWrt-Image won't ask for a password. Simply hit the Enter-Key.
Once connected...: run the following commands on your temporary installation
3. delete the "jffs2" ubi partition to make room for your new root partition
# ubirmvol /dev/ubi0 --name=jffs2
4. install OpenWrt on the NAND Flash.
# sysupgrade -v /tmp/openwrt-sysupgrade.bin
- This will will automatically reboot the router -
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
Rename the dts file to match the used SoC type and drop the unnecessary
KERNEL_INSTALL from the image build code.
Remove the fixed rootfs and kernel partitions and create an image with
rootfs appended after kernel.
Setup a switch portmap matching the hardware and a default network/switch
configuration to make make the second lan port working. Use eth0 as lan
to have it consistent accross the target.
Use the power LED to indicate the boot status.
Sort the SoC entries within the dts by address and use dtc labels
whenever possible.
Signed-off-by: Mathias Kresin <dev@kresin.me>
Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
This removes the block- and pagesize from the FritzBox 4040
image description, fixing incorrectly working sysupgrade.
With this commit, the default values for block- and pagesize are
used.
Signed-off-by: David Bauer <mail@david-bauer.net>
[chunkeey@gmail.com: removed 105-mtd-nor-add-mx25l25635f.patch as well]
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
Sort the soc entries in the dts by address and use dtc labels whenever
possible.
Adjust the DTS files, the OpenMesh A42 is actually an IPQ4018 and not an
IPQ4019.
Signed-off-by: Sven Eckelmann <sven.eckelmann@openmesh.com>
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>
There's an interaction issue between the clk changes:"
clk: qcom: ipq4019: Add the apss cpu pll divider clock node
clk: qcom: ipq4019: remove fixed clocks and add pll clocks
" and the cpufreq-dt.
cpufreq-dt is now spamming the kernel-log with the following:
[ 1099.190658] cpu cpu0: dev_pm_opp_set_rate: failed to find current OPP
for freq 761142857 (-34)
This only happens on certain devices like the Compex WPJ428
and AVM FritzBox!4040. However, other devices like the Asus
RT-AC58U and Meraki MR33 work just fine.
The issue stem from the fact that all higher CPU-Clocks
are achieved by switching the clock-parent to the P_DDRPLLAPSS
(ddrpllapss). Which is set by Qualcomm's proprietary bootcode
as part of the DDR calibration.
For example, the FB4040 uses 256 MiB Nanya NT5CC128M16IP clocked
at round 533 MHz (ddrpllsdcc = 190285714 Hz).
whereas the 128 MiB Nanya NT5CC64M16GP-DI in the ASUS RT-AC58U is
clocked at a slightly higher 537 MHz ( ddrpllsdcc = 192000000 Hz).
Signed-off-by: Christian Lamparter <chunkeey@gmail.com>