|
|
Sponsored Content
Operating Systems
Solaris
interface ce1 up-down
Post 302304740 by incredible on Tuesday 7th of April 2009 08:23:09 AM
04-07-2009
|
|
9 More Discussions You Might Find Interesting
1. Solaris
i have ce0 and ce1 online, on 2 different networks. im getting a message that says one nic is trying to assume the others IP or something to thta effect.
I do ifconfig -a and i see they have the same mac.
How do i deal with this?
Solaris 9 i beleive 04/04
Thanks,
Brian (2 Replies)
Discussion started by: BG_JrAdmin
2 Replies
2. Solaris
Dear ALL,
my server give me messages like below:
Apr 20 21:33:09 TAISERVER in.routed: interface bge3 to 192.168.11.22 turned off
I check with ifconfig,but nothing error that,how can make it solve...thanks for your help. (7 Replies)
Discussion started by: fredginting
7 Replies
3. Solaris
Hi there. My first time posting so apologies for any indescretions in advance. :o I've got two SunFire V440 servers running Solaris 5v10. Both have a quad Gigabit ethernet card fitted, both have the same symptom; that is, I can't get the first port ce1 to run Gigabit. Motherboard ports are ce0 and... (10 Replies)
Discussion started by: fixit9660
10 Replies
4. Solaris
Dear all,
I am a newbie in solaris and I need your advice.
I have a Solaris version 5.9 installed on Sunfire V240.
I am able to ssh the machine from putty remotely.
My problem is that I cannot see the display from KVM switch I have connected to it. I need also to be able to see the GUI... (2 Replies)
Discussion started by: mbouster
2 Replies
5. SCO
Hi all
I have installed a demo version of SCO OpenServer 5.0.2, I finally found it is Desktop Interface, I would like to know how to change its interface to dos based interface?
If you have any ideas, please tell me then. Thank you (2 Replies)
Discussion started by: TinhNhi
2 Replies
6. IP Networking
This is my situation
DOS pc serial cable (sl0) Linux Pc eth1
192.168.0.10 <-------------------->192.168.0.2 <------------>192.168.0.1 (router)
I connected the linux pc and the dos pc with a SLIP (serial line internet protocol), so they can communicate in the sl0 interface.
... (3 Replies)
Discussion started by: mghis
3 Replies
7. UNIX for Dummies Questions & Answers
Hi All,
How to check whether a Interface has a single port or dual port.Thanks in advance. (5 Replies)
Discussion started by: rama krishna
5 Replies
8. UNIX for Dummies Questions & Answers
Just wanted to understand what is the logic being used by Solaris(kernel) to transmit data/traffic on physical interfaces.
I have seen most of the time traffic is being sent to interface ce0 and sometime to ce1.
I have removed ip address from below command for some reason.
netstat -rn
... (3 Replies)
Discussion started by: nadeemahmed
3 Replies
9. UNIX for Dummies Questions & Answers
I have a RHEL 5 system with a bonded interface configure using only one network port (eth0). So I have config file for ifcfg-bond0 and ifcfg-eth. I'd like to configure eth5 to be the second SLAVE in the bond. My question is, after I modify ifcfg-eth5, can I add eth5 to the bond0 interface without... (1 Reply)
Discussion started by: westmoreland
1 Replies
LEARN ABOUT SUNOS
bootup
BOOTUP(7) bootup BOOTUP(7) NAME
bootup - System bootup process DESCRIPTION
A number of different components are involved in the system boot. Immediately after power-up, the system BIOS will do minimal hardware initialization, and hand control over to a boot loader stored on a persistent storage device. This boot loader will then invoke an OS kernel from disk (or the network). In the Linux case, this kernel (optionally) extracts and executes an initial RAM disk image (initrd), such as generated by dracut(8), which looks for the root file system (possibly using systemd(1) for this). After the root file system is found and mounted, the initrd hands over control to the host's system manager (such as systemd(1)) stored on the OS image, which is then responsible for probing all remaining hardware, mounting all necessary file systems and spawning all configured services. On shutdown, the system manager stops all services, unmounts all file systems (detaching the storage technologies backing them), and then (optionally) jumps back into the initrd code which unmounts/detaches the root file system and the storage it resides on. As a last step, the system is powered down. Additional information about the system boot process may be found in boot(7). SYSTEM MANAGER BOOTUP
At boot, the system manager on the OS image is responsible for initializing the required file systems, services and drivers that are necessary for operation of the system. On systemd(1) systems, this process is split up in various discrete steps which are exposed as target units. (See systemd.target(5) for detailed information about target units.) The boot-up process is highly parallelized so that the order in which specific target units are reached is not deterministic, but still adheres to a limited amount of ordering structure. When systemd starts up the system, it will activate all units that are dependencies of default.target (as well as recursively all dependencies of these dependencies). Usually, default.target is simply an alias of graphical.target or multi-user.target, depending on whether the system is configured for a graphical UI or only for a text console. To enforce minimal ordering between the units pulled in, a number of well-known target units are available, as listed on systemd.special(7). The following chart is a structural overview of these well-known units and their position in the boot-up logic. The arrows describe which units are pulled in and ordered before which other units. Units near the top are started before units nearer to the bottom of the chart. local-fs-pre.target | v (various mounts and (various swap (various cryptsetup fsck services...) devices...) devices...) (various low-level (various low-level | | | services: udevd, API VFS mounts: v v v tmpfiles, random mqueue, configfs, local-fs.target swap.target cryptsetup.target seed, sysctl, ...) debugfs, ...) | | | | | \__________________|_________________ | ___________________|____________________/ |/ v sysinit.target | ____________________________________/|\________________________________________ / | | | | | | | | v v | v v (various (various | (various rescue.service timers...) paths...) | sockets...) | | | | | v v v | v rescue.target timers.target paths.target | sockets.target | | | | v \_________________ | ___________________/ |/ v basic.target | ____________________________________/| emergency.service / | | | | | | v v v v emergency.target display- (various system (various system manager.service services services) | required for | | graphical UIs) v | | multi-user.target | | | \_________________ | _________________/ |/ v graphical.target Target units that are commonly used as boot targets are emphasized. These units are good choices as goal targets, for example by passing them to the systemd.unit= kernel command line option (see systemd(1)) or by symlinking default.target to them. timers.target is pulled-in by basic.target asynchronously. This allows timers units to depend on services which become only available later in boot. BOOTUP IN THE INITIAL RAM DISK (INITRD) The initial RAM disk implementation (initrd) can be set up using systemd as well. In this case, boot up inside the initrd follows the following structure. The default target in the initrd is initrd.target. The bootup process begins identical to the system manager bootup (see above) until it reaches basic.target. From there, systemd approaches the special target initrd.target. Before any file systems are mounted, it must be determined whether the system will resume from hibernation or proceed with normal boot. This is accomplished by systemd-hibernate-resume@.service which must be finished before local-fs-pre.target, so no filesystems can be mounted before the check is complete. When the root device becomes available, initd-root-device.target is reached. If the root device can be mounted at /sysroot, the sysroot.mount unit becomes active and initrd-root-fs.target is reached. The service initrd-parse-etc.service scans /sysroot/etc/fstab for a possible /usr mount point and additional entries marked with the x-initrd.mount option. All entries found are mounted below /sysroot, and initrd-fs.target is reached. The service initrd-cleanup.service isolates to the initrd-switch-root.target, where cleanup services can run. As the very last step, the initrd-switch-root.service is activated, which will cause the system to switch its root to /sysroot. : (beginning identical to above) : v basic.target | emergency.service ______________________/| | / | v | initrd-root-device.target emergency.target | | | v | sysroot.mount | | | v | initrd-root-fs.target | | | v v initrd-parse-etc.service (custom initrd | services...) v | (sysroot-usr.mount and | various mounts marked | with fstab option | x-initrd.mount...) | | | v | initrd-fs.target \______________________ | | v initrd.target | v initrd-cleanup.service isolates to initrd-switch-root.target | v ______________________/| / v | initrd-udevadm-cleanup-db.service v | (custom initrd | services...) | \______________________ | | v initrd-switch-root.target | v initrd-switch-root.service | v Transition to Host OS SYSTEM MANAGER SHUTDOWN
System shutdown with systemd also consists of various target units with some minimal ordering structure applied: (conflicts with (conflicts with all system all file system services) mounts, swaps, | cryptsetup | devices, ...) | | v v shutdown.target umount.target | | \_______ ______/ / v (various low-level services) | v final.target | _____________________________________/ \_________________________________ / | | | | | | v v v v systemd-reboot.service systemd-poweroff.service systemd-halt.service systemd-kexec.service | | | | v v v v reboot.target poweroff.target halt.target kexec.target Commonly used system shutdown targets are emphasized. SEE ALSO
systemd(1), boot(7), systemd.special(7), systemd.target(5), dracut(8) systemd 237 BOOTUP(7)