Power Sessions with Screen
Screen is a terminal multiplexer that allows you to manage many processes through one physical terminal. Each process gets its own virtual window, and you can bounce between virtual windows interacting with each process. The processes managed by screen continue to run when their window is not active.
Thus far, the screen features described aren't all that exciting or new. In fact, there already are X11 terminal applications that provide this functionality (konsole and multi-gnome-terminal). What differentiates screen from the others are some of the core features screen provides.
Screen offers the ability to detach from a session and then attach to it at a later time. When detached from a session, the processes screen is managing continue to run. You can then re-attach to the session at a later time, and your terminals are still there, the way you left them.
Screen also maintains individual, searchable scrollback buffers for each of the windows it manages. You can perform traditional “enter the search term and I'll find it for you” searches as well as incremental searches. This is such an obvious feature, it's surprising that more terminal emulators do not offer it.
Other notable features of screen are configurable key bindings, utf8 and multibyte charset support, multi-attach, configurable input and output translation, input and output filter, multi-user support with access control lists (ACLs) and logging.
Before actually running screen, it's important to understand how to interact with it. Screen sends all entered text to the current window, with the exception of the command character. The default command character is Ctrl-A (press the Ctrl and the A key at the same time). The screen man page uses C-, Emacs style, to mean Ctrl-.
The command character is used to notify screen that you'd like to control screen itself, rather than the application in the current window. The key pressed after the command character designates which screen command you would like to perform.
Some of the more useful commands and their key bindings are shown in Table 1.
For many of the commonly used commands, the control version of the key is also bound to the command. An example of this is Ctrl-A C and Ctrl-A Ctrl-C to create a window.
To send Ctrl-A to an application without screen intercepting it, you can press Ctrl-A A. The command character can be changed to an alternate key if you wish. Typically Emacs users change the command character to Ctrl-B by adding escape Bb to their .screenrc. The following examples use Ctrl-A because that is the default.
As you might expect, .screenrc is the per-user configuration file in your home directory, and /etc/screenrc is the system-wide configuration file that applies to all users.
Now that you understand the fundamentals of interacting with screen, we can step through screen fundamentals using a typical screen session as an example. Probably the most typical use of screen is to control terminals on a remote machine on which you have a shell login.
So, for those of you playing along at home, log in to a remote host that has screen installed. If you don't have a remote host to ssh to, you can install screen and ssh to localhost. Packages for screen are available for most distributions.
You're now sitting at the shell prompt on the remote machine. Type screen at the prompt. You should see a splash screen showing some information explaining that screen is under the GPL, where to report bugs and so on. You can press the spacebar to bypass this screen (you can disable this splash screen permanently with startup_message off in your .screenrc). Next, you should arrive at another shell prompt, this one running inside of screen.
The new shell running inside of screen should behave like your first shell would. If you do a printenv, you may notice a few new environment variables set. Screen sets TERM to screen—each screen window provides its own vt100-compatible virtual terminal. The variable WINDOW is set to the virtual window number, and the variable STY is set to your session name. I'll explain more about those last two later.
So far, this single shell works exactly like you're used to working on a remote machine. For the sake of this example, say we are downloading the current version of screen (as of this writing, screen 3.9.13) from the screen distribution site at ftp.uni-erlangen.de/pub/utilities/screen. While this file is downloading, you decide to use your spare time to clean up your home directory. If you weren't using screen, you'd have to open another xterm and ssh to the remote machine. With screen, a simple Ctrl-A C will create a new screen window with a new shell process.
Thus far, you have an FTP client and a shell busily tidying up your home directory. You can check on your download in the original FTP window by using Ctrl-A P to go to the previous window. You can get back to your shell with Ctrl-A N.
When you check on your download, it's not finished (screen doesn't take that long to download, but we'll pretend it does for this demonstration). Time to get back to your messy home directory, right? Before doing that, press Ctrl-A Shift-M to monitor the current window for output. Now screen will notify you when there is activity in the FTP window. Bouncing between windows to check on your download's progress is no longer necessary. This also works in the inverse case; use Ctrl-A _ to monitor for silence (30 seconds by default). Monitoring for silence is useful for long compile jobs or other things that spew information.
You can continue to spawn new shells and do things in parallel on the remote machine. After you open a few windows, it becomes difficult to keep track of which window is where. This is where the windowlist comes in to play. Press Ctrl-A “, and you will be presented with a list of the current open windows. Navigate the list with the J and K keys. Pressing Enter on an entry will make it the current window. By default, the window name isn't all that descriptive. You can remedy this by setting the window name yourself with Ctrl-A Shift-A. You can set these titles automatically, much as you would set titles in an xterm, by sending Esc-K, then the title, then Esc-\. Most likely you can adapt a shell-specific recipe for setting the xterm titlebar to the screen window name using the mentioned escape sequences.
To finish up our basic run-through of windowing, let's close your existing windows. If you exit the shell that screen has spawned, the window is deleted automatically. You can delete a window manually with the kill command (default Ctrl-A K). When you exit all of the screen windows, screen exits. You also can tell screen to exit and kill all of your windows by issuing the quit command (Ctrl-A \).
Practical Task Scheduling Deployment
One of the best things about the UNIX environment (aside from being stable and efficient) is the vast array of software tools available to help you do your job. Traditionally, a UNIX tool does only one thing, but does that one thing very well. For example, grep is very easy to use and can search vast amounts of data quickly. The find tool can find a particular file or files based on all kinds of criteria. It's pretty easy to string these tools together to build even more powerful tools, such as a tool that finds all of the .log files in the /home directory and searches each one for a particular entry. This erector-set mentality allows UNIX system administrators to seem to always have the right tool for the job.
Cron traditionally has been considered another such a tool for job scheduling, but is it enough? This webinar considers that very question. The first part builds on a previous Geek Guide, Beyond Cron, and briefly describes how to know when it might be time to consider upgrading your job scheduling infrastructure. The second part presents an actual planning and implementation framework.
Join Linux Journal's Mike Diehl and Pat Cameron of Help Systems.
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- Stunnel Security for Oracle
- The Firebird Project's Firebird Relational Database
- Murat Yener and Onur Dundar's Expert Android Studio (Wrox)
- SUSE LLC's SUSE Manager
- Managing Linux Using Puppet
- My +1 Sword of Productivity
- Non-Linux FOSS: Caffeine!
- Google's SwiftShader Released
- SuperTuxKart 0.9.2 Released
- Doing for User Space What We Did for Kernel Space
With all the industry talk about the benefits of Linux on Power and all the performance advantages offered by its open architecture, you may be considering a move in that direction. If you are thinking about analytics, big data and cloud computing, you would be right to evaluate Power. The idea of using commodity x86 hardware and replacing it every three years is an outdated cost model. It doesn’t consider the total cost of ownership, and it doesn’t consider the advantage of real processing power, high-availability and multithreading like a demon.
This ebook takes a look at some of the practical applications of the Linux on Power platform and ways you might bring all the performance power of this open architecture to bear for your organization. There are no smoke and mirrors here—just hard, cold, empirical evidence provided by independent sources. I also consider some innovative ways Linux on Power will be used in the future.Get the Guide