Difference between revisions of "Connect to a modified router"
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− | ====== | + | === Task One: Connect Serial (& Optionally Network) Cable(s) === |
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− | + | Ensure that the connection is going from UART0 (the first serial port--if you followed our instructions on [[HOWTO:Modify the Linksys hardware|modifying the router]] it will be the '''DB9 Female''' serial port on the left) as this is where the console will be running. If you are connecting a standard PC serial port (a DTE) to your router, use a straight serial cable. Other arrangements may require a [[Null Modem]]; check your transmit/receive line polarities to be sure. | |
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+ | Also, because the goal is to upload custom code to the router, it would be a good idea to connect the router to your network by wiring it up via one of the numbered LAN ports on the back of the router (NOT the Internet/WAN port). This is not necessary to simply connect and communicate with the router, but it is necessary if you want to try and boot the router running your own custom code (which is the point of this Xinu lab after all). | ||
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Install 1 Package(s) | Install 1 Package(s) |
Revision as of 16:57, 26 June 2008
Summary
This will explain how to connect to the serial ports on a modified LinkSys WRT54G using serial communication software. In our tutorial we will use Picocom for our serial communication software because it is free and easy to get with a front end or server running Linux.
Before Starting
Expose a serial port on the router
You must have successfully modified a LinkSys WRT54G to expose at least its first serial port in such a way that you can connect it to another machine with serial communications software. If you have not done so yet, please see HOWTO:Modify the Linksys hardware
Acquire serial communication software
There is a freely available software package for serial communication on almost every major platform. Picocom is one such piece of software that is easy to obtain on a machine running Linux. To get Picocom installed on your front end simply open a terminal and type yum install picocom
(or use your system's package install command if it does not support the yum
command). NOTE: you may need root access to your front end machine in order to install packages. We installed Picocom on a front end machine running Fedora 9 and got the following output:
[root@argolis ~]# yum install picocom Loaded plugins: refresh-packagekit Setting up Install Process Parsing package install arguments Resolving Dependencies --> Running transaction check ---> Package picocom.i386 0:1.4-4.fc9 set to be updated --> Finished Dependency Resolution Dependencies Resolved ============================================================================= Package Arch Version Repository Size === Task One: Connect Serial (& Optionally Network) Cable(s) === Ensure that the connection is going from UART0 (the first serial port--if you followed our instructions on [[HOWTO:Modify the Linksys hardware|modifying the router]] it will be the '''DB9 Female''' serial port on the left) as this is where the console will be running. If you are connecting a standard PC serial port (a DTE) to your router, use a straight serial cable. Other arrangements may require a [[Null Modem]]; check your transmit/receive line polarities to be sure. Also, because the goal is to upload custom code to the router, it would be a good idea to connect the router to your network by wiring it up via one of the numbered LAN ports on the back of the router (NOT the Internet/WAN port). This is not necessary to simply connect and communicate with the router, but it is necessary if you want to try and boot the router running your own custom code (which is the point of this Xinu lab after all). ============================================================================= Install 1 Package(s) Update 0 Package(s) Remove 0 Package(s) Total download size: 29 k Is this ok [y/N]: y Downloading Packages: (1/1): picocom-1.4-4.fc9.i386.rpm | 29 kB 00:00 Running rpm_check_debug Running Transaction Test Finished Transaction Test Transaction Test Succeeded Running Transaction Installing: picocom ######################### [1/1] Installed: picocom.i386 0:1.4-4.fc9 Complete! [root@argolis ~]#
Alternatively, if you are building multiple backends to be made available as a pool, our suite of XINU Console Tools includes a basic serial console utility called tty-connect. However it is recommended that you do not use the XINU Console Tools's tty-connect utility for directly connecting a single back end router to a front end machine because this utility does not allow the user to send a ctrl-C
command over the serial connection, which is necessary in the upcoming steps in order to properly communicate with your router.
Steps to Connect to the Router
Task One: Connect Serial (& Optionally Network) Cable(s)
Ensure that the connection is going from UART0 (the first serial port--if you followed our instructions on modifying the router it will be the DB9 Female serial port on the left) as this is where the console will be running. If you are connecting a standard PC serial port (a DTE) to your router, use a straight serial cable. Other arrangements may require a Null Modem; check your transmit/receive line polarities to be sure.
Also, because the goal is to upload custom code to the router, it would be a good idea to connect the router to your network by wiring it up via one of the numbered LAN ports on the back of the router (NOT the Internet/WAN port). This is not necessary to simply connect and communicate with the router, but it is necessary if you want to try and boot the router running your own custom code (which is the point of this XINU lab after all).
Task Two: Configure your Serial Communication Software
The connection used by the router's serial port is fairly standard: 115200bps, with 8 data bits, no parity bit, and 1 stop bit, or 8N1. Set your software to connect using these settings.
If you are following our tutorial and using Picocom as your serial connection software, the command to open Picocom with these settings is picocom -b 115200 /dev/ttyS0
(where /dev/ttyS0
is the name of your front end's serial communication device hooked up to the router). By default the other necessary settings are already set on picocom; it's default connection uses 8 data bits, no parity bits, and 1 stop bit. If you use picicom to set up a connection you should get output like the following:
[root@argolis ~]# picocom -b 115200 /dev/ttyS0 picocom v1.4 port is : /dev/ttyS0 flowcontrol : none baudrate is : 115200 parity is : none databits are : 8 escape is : C-a noinit is : no noreset is : no nolock is : no send_cmd is : ascii_xfr -s -v -l10 receive_cmd is : rz -vv Terminal ready
Task Three: Power up the Router
Yes, that means plug it in.
With serial communications software listening, you should see something like the following output:
CFE version 1.0.37 for BCM947XX (32bit,SP,LE) Build Date: Mon Nov 14 18:06:25 CST 2005 (root@localhost.localdomain) Copyright (C) 2000,2001,2002,2003 Broadcom Corporation. Initializing Arena Initializing Devices. No DPN et0: Broadcom BCM47xx 10/100 Mbps Ethernet Controller 3.90.37.0 CPU type 0x29008: 200MHz Total memory: 16384 KBytes Total memory used by CFE: 0x80300000 - 0x803A39C0 (670144) Initialized Data: 0x803398D0 - 0x8033BFE0 (10000) BSS Area: 0x8033BFE0 - 0x8033D9C0 (6624) Local Heap: 0x8033D9C0 - 0x803A19C0 (409600) Stack Area: 0x803A19C0 - 0x803A39C0 (8192) Text (code) segment: 0x80300000 - 0x803398D0 (235728) Boot area (physical): 0x003A4000 - 0x003E4000 Relocation Factor: I:00000000 - D:00000000 Boot version: v3.7 The boot is CFE mac_init(): Find mac [00:18:39:6F:78:15] in location 0 Nothing... eou_key_init(): Find key pair in location 0 The eou device id is same The eou public key is same The eou private key is same Device eth0: hwaddr 00-18-39-6F-78-15, ipaddr 192.168.1.1, mask 255.255.255.0 gateway not set, nameserver not set Loader:raw Filesys:raw Dev:flash0.os File: Options:(null) Loading: ...... 1601536 bytes read Entry at 0x80001000 Closing network. Starting program at 0x80001000 CPU revision is: 00029008 Primary instruction cache 16kb, linesize 16 bytes (2 ways) Primary data cache 8kb, linesize 16 bytes (2 ways) Linux version 2.4.20 (root@localhost.localdomain) (gcc version 3.2.3 with Broadcom modifications) ... (snip) ... Hit enter to continue...
Pressing enter will give you a root shell:
BusyBox v0.60.0 (2005.11.14-09:45+0000) Built-in shell (msh) Enter 'help' for a list of built-in commands. #
Task Four: Access the Common Firmware Environment CLI
If you reboot the router while holding CTRL+C on the serial console, you will get a CFE prompt.
CFE version 1.0.37 for BCM947XX (32bit,SP,LE) Build Date: Mon Nov 14 18:06:25 CST 2005 (root@localhost.localdomain) Copyright (C) 2000,2001,2002,2003 Broadcom Corporation. Initializing Arena Initializing Devices. No DPN et0: Broadcom BCM47xx 10/100 Mbps Ethernet Controller 3.90.37.0 CPU type 0x29008: 200MHz Total memory: 16384 KBytes Total memory used by CFE: 0x80300000 - 0x803A39C0 (670144) Initialized Data: 0x803398D0 - 0x8033BFE0 (10000) BSS Area: 0x8033BFE0 - 0x8033D9C0 (6624) Local Heap: 0x8033D9C0 - 0x803A19C0 (409600) Stack Area: 0x803A19C0 - 0x803A39C0 (8192) Text (code) segment: 0x80300000 - 0x803398D0 (235728) Boot area (physical): 0x003A4000 - 0x003E4000 Relocation Factor: I:00000000 - D:00000000 Boot version: v3.7 The boot is CFE mac_init(): Find mac [00:18:39:6F:78:15] in location 0 Nothing... eou_key_init(): Find key pair in location 0 The eou device id is same The eou public key is same The eou private key is same Device eth0: hwaddr 00-18-39-6F-78-15, ipaddr 192.168.1.1, mask 255.255.255.0 gateway not set, nameserver not set Automatic startup canceled via Ctrl-C CFE> ^C CFE> ^C CFE>
See the CFE page for more information about using this prompt.
What to do next?
Now that you have successfully modified and connected to your router, you are ready to Build and Deploy XINU.
This work is supported in part by NSF grant DUE-CCLI-0737476.