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  • django, mod_wsgi, MySQL High CPU - Problems

    - by Red Rover
    I am having a problem with an OSQA site. It is Django/Apache/mod_wsgi configured site. Every hour, the CPU spikes to 164% (Average) for task HTTPD. After 10 minutes, it frees back up. I have reviewed the logs, cron tables, made many config changes, but cannot track this problem down. Can someone please look at the information below and let me know if it is a configuration problem, or if anyone else has experienced this issue. Running TOP shows HTTPD using 165% of CPU VMware performance monitor also displays spikes. This happens every hour for 10 minutes. I have the following information from server status Server Version: Apache/2.2.15 (Unix) DAV/2 mod_wsgi/3.2 Python/2.6.6 Server Built: Feb 7 2012 09:50:15 Current Time: Sunday, 10-Jun-2012 21:44:29 EDT Restart Time: Sunday, 10-Jun-2012 19:44:51 EDT Parent Server Generation: 0 Server uptime: 1 hour 59 minutes 37 seconds Total accesses: 1088 - Total Traffic: 11.5 MB CPU Usage: u80.26 s243.8 cu0 cs0 - 4.52% CPU load .152 requests/sec - 1682 B/second - 10.8 kB/request 4 requests currently being processed, 11 idle workers ....._..........__......W....................................... ...................................C._..._....._L__._L_._....... ...................... Scoreboard Key: "_" Waiting for Connection, "S" Starting up, "R" Reading Request, "W" Sending Reply, "K" Keepalive (read), "D" DNS Lookup, "C" Closing connection, "L" Logging, "G" Gracefully finishing, "I" Idle cleanup of worker, "." Open slot with no current process Srv PID Acc M CPU SS Req Conn Child Slot Client VHost Request 0-0 - 0/0/34 . 0.42 327 17 0.0 0.00 0.67 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 1-0 - 0/0/22 . 0.31 339 32 0.0 0.00 0.26 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 2-0 - 0/0/22 . 0.65 358 10 0.0 0.00 0.31 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 3-0 - 0/0/31 . 1.03 378 31 0.0 0.00 0.60 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 4-0 - 0/0/20 . 0.45 356 9 0.0 0.00 0.31 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 5-0 18852 0/16/34 _ 0.98 27 18120 0.0 0.37 0.62 69.180.250.36 osqa.informs.org GET /questions/289/what-is-the-difference-between-operations-re 6-0 - 0/0/32 . 0.94 309 29 0.0 0.00 0.64 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 7-0 - 0/0/31 . 1.15 382 32 0.0 0.00 0.75 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 8-0 - 0/0/21 . 0.28 403 19 0.0 0.00 0.20 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 9-0 - 0/0/32 . 1.37 288 16 0.0 0.00 0.60 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 10-0 - 0/0/33 . 1.72 383 16 0.0 0.00 0.40 127.0.0.1 osqa.informs.org OPTIONS * HTTP/1.0 I am running Django 1.3 This is a mod_wsgi configuration and copied is the wsgi.conf file: <IfModule !python_module> <IfModule !wsgi_module> LoadModule wsgi_module modules/mod_wsgi.so <IfModule wsgi_module> <Directory /var/www/osqa> Order allow,deny Allow from all #Deny from all </Directory> WSGISocketPrefix /var/run/wsgi WSGIPythonEggs /var/tmp WSGIDaemonProcess OSQA maximum-requests=10000 WSGIProcessGroup OSQA Alias /admin_media/ /usr/lib/python2.6/site-packages/Django-1.2.5-py2.6.egg/django/contrib/admin/media/ Alias /m/ /var/www/osqa/forum/skins/ Alias /upfiles/ /var/www/osqa/forum/upfiles/ <Directory /var/www/osqa/forum/skins> Order allow,deny Allow from all </Directory> WSGIScriptAlias / /var/www/osqa/osqa.wsgi </IfModule> </IfModule> </IfModule> This is the httpd.conf file Timeout 120 KeepAlive Off MaxKeepAliveRequests 100 MaxKeepAliveRequests 400 KeepAliveTimeout 3 <IfModule prefork.c> Startservers 15 MinSpareServers 10 MaxSpareServers 20 ServerLimit 50 MaxClients 50 MaxRequestsPerChild 0 </IfModule> <IfModule worker.c> StartServers 4 MaxClients 150 MinSpareThreads 25 MaxSpareThreads 75 ThreadsPerChild 25 MaxRequestsPerChild 0 </IfModule> We are using MySQL The server is an ESX4i, configured for the VM to use 4 CPUs and 8 GB Ram. Hyper threading is enabled, 2 physical CPU's, with 4 Logical. the CPU are Intel Xeon 2.8 GHz. Total memory is 12GB

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  • Online Multiplayer Game Architecture [on hold]

    - by Eric
    I am just starting to research online multiplayer game development and I have a high-level architectural question regarding how online multiple games function. I have server-side and client-side programming experience, and I understand how AJAX-esque transfer protocol operates. What I don't understand yet is how online multiple fits into all of that. For example, an online Tetris multiplayer game. Would both players have the entire Tetris game built out on their client-side and then get pushed "moves" from the other player via some AJAX-esque mechanism, in which case each client would have to be constantly listening via JavaScript for inbound "moves" and update the client appropriately? Or would each client build out the aesthetics and run a virtual server per game to which each client connects and thus pull and push commands in real-time via something like web sockets? I apologize if this question is too high-level and general, but I couldn't find anything online that offered this high-level of a perspective on the topic.

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  • SOA Suite HealthCare Integration Architecture

    - by Nitesh Jain
    Oracle SOA Suite for HealthCare integration is an integrated, best-of-breed suite that helps HealthCare organizations rapidly design and assemble, deploy and manage, highly agile and adaptable business applications.It  will help healthcare industry to  reduce operating costs and speeds time-to-market by delivering a consistent user interface, management console and monitoring environment, as well as healthcare libraries and templates for healthcare customer projects.Oracle SOA Suite for healthcare integration is fully configurable and extensible, providing a highly flexible platform for collaboration across all healthcare domains.Healthcare message standards support:    Messaging standards - HL7, HIPAA, Custom , X12N    Exchange standards - MLLP (v1.0, v2.0), TCP/IP, File, FTP, SFTP, JMSSimplified dashboards and customized reports helps users to advanced monitoring capabilities that support end-to-end healthcare message tracking.A toolkit for rapid HIPAA 5010 upgrade and compliance provides pre-defined healthcare integration mapping for HIPAA standards that is fully customizable and extensible.MLLP-HA helps easily failover and disaster recovery which makes system running on the long time without any issue.Audit keeps track of all the system changes. Alert and notification (SMS,Email etc) helps user to take the fast action and gives tracking on the real-time.

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  • UDP Code client server architecture

    - by GameBuilder
    Hi I have developed a game on android.Now I want to play it on wifi or 3G. I have game packets which i want to send it form client(mobile) to server then to another client2(mobile). I don't know how to write code in Java to send the playPackets continuously to server and receive the playPacket continuously from the server to the clients. I guess i have to use two thread one for sending and one for receiving. Can someone help me with the code, or the procedure to write code for it. Thanks in advance.

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  • EPM 11.1.2.2 Architecture: Essbase

    - by Marc Schumacher
    Since a lot of components exist to access or administer Essbase, there are also a couple of client tools available. End users typically use the Excel Add-In or SmartView nowadays. While the Excel Add-In talks to the Essbase server directly using various ports, SmartView connects to Essbase through Provider Services using HTTP protocol. The ability to communicate using a single port is one of the major advantages from SmartView over Excel Add-In. If you consider using Excel Add-In going forward, please make sure you are aware of the Statement of Direction for this component. The Administration Services Console, Integration Services Console and Essbase Studio are clients, which are mainly used by Essbase administrators or application designers. While Integration Services and Essbase Studio are used to setup Essbase applications by loading metadata or simply for data loads, Administration Services are utilized for all kind of Essbase administration. All clients are using only one or two ports to talk to their server counterparts, which makes them work through firewalls easily. Although clients for Provider Services (SmartView) and Administration Services (Administration Services Console) are only using a single port to communicate to their backend services, the backend services itself need the Essbase configured port range to talk to the Essbase server. Any communication to repository databases is done using JDBC connections. Essbase Studio and Integration Services are using different technologies to talk to the Essbase server, Integration Services uses CAPI, Essbase Studio uses JAPI. However, both are using the configured port range on the Essbase server to talk to Essbase. Connections to data sources are either based on ODBC (Integration Service, Essbase) or JDBC (Essbase Studio). As for all other components discussed previously, when setting up firewall rules, be aware of the fact that all services may need to talk to the external authentication sources, this is not only needed for Shared Services.

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  • SNMP - Value of CPU processor load not reflecting reality

    - by Ovesh
    Trying to plot CPU load on my server, with the following hardware: ProLiant DL360p Gen8 (same behavior on ProLiant DL360 G7). The machine is running VMWare ESXi5.1 To create a CPU spike I run dd if=/dev/zero of=/dev/null, and I know the CPU is overloaded, because I can see a correlating spike in the graphs displayed on vCenter. However, running this snmpwalk: snmpwalk -v 1 -c ******** 192.168.MY_IP 1.3.6.1.2.1.25.3.3.1.2 Shows the following results: iso.3.6.1.2.1.25.3.3.1.2.1 = INTEGER: 3 iso.3.6.1.2.1.25.3.3.1.2.2 = INTEGER: 2 iso.3.6.1.2.1.25.3.3.1.2.3 = INTEGER: 2 iso.3.6.1.2.1.25.3.3.1.2.4 = INTEGER: 3 Am I not looking into the right MIB? Should I be multiplying these by a constant? By the way, using HP Agentless Monitoring I was able to get some cpu stats, but not what I'm looking for, at least nothing I could find wading through these MIBs.

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  • Vue d'ensemble de l'architecture modulaire de Qt 5, un billet de Guillaume Belz

    La sortie de Qt 5 se précise de jour en jour. L'une des principales évolutions de Qt 5 est la réorganisation des différents modules. Certaines fonctionnalités sont séparées dans des modules indépendants, comme le transfert des widgets depuis QtGui vers QtWidget, ou déplacées dans des modules existants, comme l'intégration des fonctionnalités d'OpenGL depuis QtOpenGL vers QtGui. Ce billet de blog présente l'ensemble des modules de Qt 5 et les principaux changement que l'on y trouvera. Les modules de Qt 5

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  • WCF/webservice architecture question

    - by M.R.
    I have a requirement to create a webservice to expose certain items from a CMS as a web service, and I need some suggestions - the structure of the items is as such: item - field 1 - field 2 - field 3 - field 4 So, one would think that the class for this will be: public class MyItem { public string ItemName { get; set; } public List<MyField> Fields { get; set; } } public class MyField { public string FieldName { get; set; } public string FieldValue { get; set; } //they are always string (except - see below) } This works for when its always one level deep, but sometimes, one of the fields is actually a point to ANOTHER item (MyItem) or multiple MyItem (List<MyItem>), so I thought I would change the structure of MyField as follows, to make FieldValue as object; public class MyField { public string FieldName { get; set; } public object FieldValue { get; set; } //changed to object } So, now, I can put whatever I want in there. This is great in theory, but how will clients consume this? I suspect that when users make a reference to this web service, they won't know which object is being returned in that field? This seems like a not-so-good design. Is there a better approach to this?

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  • Dell whitepaper on PowerEdge R810 R910 and M910 Memory Architecture

    - by jchang
    The Dell PowerEdge 11 th Generation Servers: R810, R910 and M910 Memory Guidance whitepaper seems to have caused some confusion. I believe the source is an error in the paper. In the section on FlexMem Bridge Technology, the Dell whitepaper says this applies to the R810 and the M910. The Dell M910 is a 4-way blade server for the Xeon 7500 series processor line. First a breif recap. The R810 is a 2-way server, by which I mean it has two sockets regardless of the number of cores on each processor....(read more)

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  • CPU-adaptive compression

    - by liori
    Hello, Let assume I need to send some data from one computer to another, over a pretty fast network... for example standard 100Mbit connection (~10MB/s). My disk drives are standard HDD, so their speed is somewhere between 30MB/s and 100MB/s. So I guess that compressing the data on the fly could help. But... I don't want to be limited by CPU. If I choose an algorithm that is intensive on CPU, the transfer will actually go slower than without compression. This is difficult with compressors like GZIP and BZIP2 because you usually set the compression strength once for the whole transfer, and my data streams are sometimes easy, sometimes hard to compress--this makes the process suboptimal because sometimes I do not use full CPU, and sometimes the bandwidth is underutilized. Is there a compression program that would adapt to current CPU/bandwidth and hit the sweet spot so that the transfer will be optimal? Ideally for Linux, but I am still curious about all solutions. I'd love to see something compatible with GZIP/BZIP2 decompressors, but this is not necessary. So I'd like to optimize total transfer time, not simply amount of bytes to send. Also I don't need real time decompression... real time compression is enough. The destination host can process the data later in its spare time. I know this doesn't change much (compression is usually much more CPU-intensive than decompression), but if there's a solution that could use this fact, all the better. Each time I am transferring different data, and I really want to make these one-time transfers as quick as possible. So I won't benefit from getting multiple transfers faster due to stronger compression. Thanks,

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  • Intermittent temporary GUI freeze in Ubuntu 11.10

    - by Oscar
    I've been using Ubuntu 11.10 for a month or so. In the last week it's started freezing randomly (every few hours or minutes). I can still move the mouse and switch to other terminals with ctrl+alt. I thought this was purely a gui issue as I could continue entering commands (mouse clicks and keys) which seem to be processed once the system resumes (generally 30 seconds to a few minutes). I'm using gnome and metacity. I can't identify anything in particular that triggers the freezes. Saving a file in LibreOffice causes the system to hang. I tried disabling most of the services I've installed (dropbox, autokey, etc.) but doesn't help. Switching to another terminal and running top, the CPU column is shared equally among all of my processes (i.e. non-root). I have no idea what that signifies. My PC is unusable in this state. CPU model name : Pentium(R) Dual-Core CPU E6700 @ 3.20GHz [7m PID USER PR NI VIRT RES SHR S %CPU %MEM TIME+ COMMAND [0;10m[39;49m[K [0;10m[0;10m 1499 ogga 20 0 404m 32m 13m R 10 0.8 0:28.19 python [0;10m[39;49m [0;10m[0;10m 1501 ogga 20 0 216m 13m 6224 R 10 0.3 0:18.28 ibus-x11 [0;10m[39;49m [0;10m[0;10m 1679 ogga 20 0 449m 34m 15m R 10 0.9 0:41.10 gnome-panel [0;10m[39;49m [0;10m[0;10m 1710 ogga 20 0 350m 15m 8324 R 10 0.4 0:18.25 bluetooth-apple [0;10m[39;49m [0;10m[0;10m 1752 ogga 20 0 458m 37m 13m R 10 0.9 0:22.62 autokey-gtk [0;10m[39;49m [0;10m[0;10m 2081 ogga 20 0 354m 17m 9800 R 10 0.5 0:16.36 update-notifier [0;10m[39;49m [0;10m[0;10m 5439 ogga 20 0 640m 104m 38m R 10 2.6 0:45.17 chromium-browse [0;10m[39;49m [0;10m[0;10m 5586 ogga 20 0 381m 42m 21m R 10 1.1 0:20.17 chromium-browse [0;10m[39;49m [0;10m[0;10m 6422 ogga 20 0 529m 59m 18m R 10 1.5 0:28.15 sublime_text [0;10m[39;49m [0;10m[0;10m 1362 ogga 20 0 264m 14m 7884 R 8 0.4 0:18.29 gnome-session [0;10m[39;49m [0;10m[0;10m 1673 ogga 20 0 351m 17m 9768 R 8 0.4 0:21.78 metacity [0;10m[39;49m [0;10m[0;10m 1708 ogga 20 0 249m 13m 7156 R 8 0.3 0:18.23 gnome-fallback- [0;10m[39;49m [0;10m[0;10m 1709 ogga 20 0 572m 28m 15m R 8 0.7 0:18.37 nautilus [0;10m[39;49m [0;10m[0;10m 1722 ogga 20 0 467m 18m 9m R 8 0.5 0:18.43 nm-applet [0;10m[39;49m [0;10m[0;10m 1727 ogga 20 0 225m 12m 6304 R 8 0.3 0:18.24 polkit-gnome-au [0;10m[39;49m [0;10m[0;10m 1731 ogga 20 0 422m 19m 10m R 8 0.5 0:26.62 gnome-sound-app [0;10m[39;49m [0;10m[0;10m 1735 ogga 20 0 306m 31m 13m R 8 0.8 0:18.37 python [0;10m[39;49m [0;10m[0;10m 1754 ogga 20 0 286m 16m 8912 R 8 0.4 0:18.90 vino-server [0;10m[39;49m [0;10m[0;10m 1798 ogga 20 0 246m 15m 7476 R 8 0.4 0:18.25 gnome-screensav [0;10m[39;49m [0;10m[0;10m 1851 ogga 20 0 185m 14m 7256 R 8 0.4 0:18.18 gdu-notificatio [0;10m[39;49m [0;10m[0;10m 1923 ogga 20 0 251m 28m 11m R 8 0.7 0:17.96 applet.py [0;10m[39;49m [0;10m[0;10m 4085 ogga 20 0 378m 22m 11m R 8 0.6 0:18.19 gnome-terminal [0;10m[39;49m [0;10m 4213 ogga 20 0 263m 73m 15m S 2 1.9 3:57.44 skype [0;10m[39;49m [0;10m 1 root 20 0 24188 1492 1320 S 0 0.0 0:00.45 init [0;10m[39;49m [0;10m 2 root 20 0 0 0 0 S 0 0.0 0:00.00 kthreadd [0;10m[39;49m [0;10m 3 root 20 0 0 0 0 S 0 0.0 0:02.27 ksoftirqd/0 [0;10m[39;49m [0;10m 6 root RT 0 0 0 0 S 0 0.0 0:00.00 migration/0 [0;10m[39;49m [0;10m 7 root RT 0 0 0 0 S 0 0.0 0:00.00 migration/1 [0;10m[39;49m [0;10m 9 root 20 0 0 0 0 S 0 0.0 0:01.97 ksoftirqd/1 [0;10m[39;49m [0;10m 10 root 20 0 0 0 0 S 0 0.0 0:01.16 kworker/0:1 [0;10m[39;49m [0;10m 11 root 0 -20 0 0 0 S 0 0.0 0:00.00 cpuset [0;10m[39;49m [0;10m 12 root 0 -20 0 0 0 S 0 0.0 0:00.00 khelper [0;10m[39;49m [0;10m 13 root 0 -20 0 0 0 S 0 0.0 0:00.00 netns [0;10m[39;49m [0;10m 15 root 20 0 0 0 0 S 0 0.0 0:00.00 sync_supers [0;10m[39;49m [0;10m 16 root 20 0 0 0 0 S 0 0.0 0:00.00 bdi-default [0;10m[39;49m [0;10m 17 root 0 -20 0 0 0 S 0 0.0 0:00.00 kintegrityd [0;10m[39;49m [0;10m 18 root 0 -20 0 0 0 S 0 0.0 0:00.00 kblockd [0;10m[39;49m [0;10m 19 root 0 -20 0 0 0 S 0 0.0 0:00.00 ata_sff [0;10m[39;49m [0;10m 20 root 20 0 0 0 0 S 0 0.0 0:00.00 khubd [0;10m[39;49m [0;10m 21 root 0 -20 0 0 0 S 0 0.0 0:00.00 md [0;10m[39;49m [0;10m 23 root 20 0 0 0 0 S 0 0.0 0:00.00 khungtaskd [0;10m[39;49m [0;10m 24 root 20 0 0 0 0 S 0 0.0 0:00.14 kswapd0 [0;10m[39;49m [0;10m 25 root 25 5 0 0 0 S 0 0.0 0:00.00 ksmd [0;10m[39;49m [0;10m 26 root 39 19 0 0 0 S 0 0.0 0:00.00 khugepaged [0;10m[39;49m [0;10m 27 root 20 0 0 0 0 S 0 0.0 0:00.00 fsnotify_mark [0;10m[39;49m [0;10m 28 root 20 0 0 0 0 S 0 0.0 0:00.00 ecryptfs-kthrea [0;10m[39;49m [0;10m 29 root 0 -20 0 0 0 S 0 0.0 0:00.00 crypto [0;10m[39;49m [0;10m 37 root 0 -20 0 0 0 S 0 0.0 0:00.00 kthrotld [0;10m[39;49m [0;10m 38 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_0 [0;10m[39;49m [0;10m 39 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_1 [0;10m[39;49m [0;10m 41 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_2 [0;10m[39;49m [0;10m 42 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_3 [0;10m[39;49m [0;10m 64 root 20 0 0 0 0 S 0 0.0 0:02.98 kworker/0:2 [0;10m[39;49m [0;10m 242 root 20 0 0 0 0 S 0 0.0 0:00.39 jbd2/sdb1-8 [0;10m[39;49m [0;10m 243 root 0 -20 0 0 0 S 0 0.0 0:00.00 ext4-dio-unwrit [0;10m[39;49m [0;10m 288 root 20 0 17236 448 448 S 0 0.0 0:00.04 upstart-udev-br [0;10m[39;49m [0;10m 295 root 20 0 21752 884 796 S 0 0.0 0:00.06 udevd And at another time: [7m PID USER PR NI VIRT RES SHR S %CPU %MEM TIME+ COMMAND [0;10m[39;49m[K [0;10m[0;10m 1757 ogga 20 0 222m 9932 6300 R 13 0.2 0:05.69 polkit-gnome-au [0;10m[39;49m [0;10m[0;10m 1559 ogga 20 0 152m 9764 6112 R 13 0.2 0:05.77 ibus-x11 [0;10m[39;49m [0;10m[0;10m 1786 ogga 20 0 457m 33m 13m R 13 0.9 0:06.10 autokey-gtk [0;10m[39;49m [0;10m[0;10m 1395 ogga 20 0 262m 12m 7880 R 12 0.3 0:05.88 gnome-session [0;10m[39;49m [0;10m[0;10m 1557 ogga 20 0 403m 31m 13m R 12 0.8 0:14.95 python [0;10m[39;49m [0;10m[0;10m 1745 ogga 20 0 247m 11m 7196 R 12 0.3 0:05.69 gnome-fallback- [0;10m[39;49m [0;10m[0;10m 1767 ogga 20 0 237m 26m 11m R 12 0.7 0:05.87 python [0;10m[39;49m [0;10m[0;10m 1713 ogga 20 0 440m 25m 13m R 12 0.6 0:13.76 gnome-panel [0;10m[39;49m [0;10m[0;10m 1747 ogga 20 0 348m 13m 8328 R 11 0.3 0:05.22 bluetooth-apple [0;10m[39;49m [0;10m[0;10m 1754 ogga 20 0 465m 16m 10m R 11 0.4 0:05.21 nm-applet [0;10m[39;49m [0;10m[0;10m 1710 ogga 20 0 167m 11m 7564 R 11 0.3 0:05.21 metacity [0;10m[39;49m [0;10m[0;10m 1761 ogga 20 0 406m 17m 9928 R 11 0.4 0:12.71 gnome-sound-app [0;10m[39;49m [0;10m[0;10m 1789 ogga 20 0 283m 13m 8852 R 11 0.3 0:05.55 vino-server [0;10m[39;49m [0;10m[0;10m 1815 ogga 20 0 243m 11m 7452 R 11 0.3 0:05.17 gnome-screensav [0;10m[39;49m [0;10m[0;10m 1885 ogga 20 0 182m 11m 7256 R 11 0.3 0:05.18 gdu-notificatio [0;10m[39;49m [0;10m[0;10m 1957 ogga 20 0 249m 25m 11m R 11 0.7 0:05.32 applet.py [0;10m[39;49m [0;10m[0;10m 2067 ogga 20 0 260m 12m 7828 R 11 0.3 0:05.21 update-notifier [0;10m[39;49m [0;10m 1975 ogga 20 0 292m 48m 11m S 0 1.2 0:08.28 ubuntuone-syncd [0;10m[39;49m [0;10m[0;10m 2363 ogga 20 0 21468 1384 988 R 0 0.0 0:00.01 top [0;10m[39;49m [0;10m 1 root 20 0 24284 2296 1320 S 0 0.1 0:00.46 init [0;10m[39;49m [0;10m 2 root 20 0 0 0 0 S 0 0.0 0:00.00 kthreadd [0;10m[39;49m [0;10m 3 root 20 0 0 0 0 S 0 0.0 0:00.05 ksoftirqd/0 [0;10m[39;49m [0;10m 4 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/0:0 [0;10m[39;49m [0;10m 5 root 20 0 0 0 0 S 0 0.0 0:00.19 kworker/u:0 [0;10m[39;49m [0;10m 6 root RT 0 0 0 0 S 0 0.0 0:00.00 migration/0 [0;10m[39;49m [0;10m 7 root RT 0 0 0 0 S 0 0.0 0:00.00 migration/1 [0;10m[39;49m [0;10m 8 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/1:0 [0;10m[39;49m [0;10m 9 root 20 0 0 0 0 S 0 0.0 0:00.06 ksoftirqd/1 [0;10m[39;49m [0;10m 10 root 20 0 0 0 0 S 0 0.0 0:00.09 kworker/0:1 [0;10m[39;49m [0;10m 11 root 0 -20 0 0 0 S 0 0.0 0:00.00 cpuset [0;10m[39;49m [0;10m 12 root 0 -20 0 0 0 S 0 0.0 0:00.00 khelper [0;10m[39;49m [0;10m 13 root 0 -20 0 0 0 S 0 0.0 0:00.00 netns [0;10m[39;49m [0;10m 14 root 20 0 0 0 0 S 0 0.0 0:00.25 kworker/u:1 [0;10m[39;49m [0;10m 15 root 20 0 0 0 0 S 0 0.0 0:00.00 sync_supers [0;10m[39;49m [0;10m 16 root 20 0 0 0 0 S 0 0.0 0:00.00 bdi-default [0;10m[39;49m [0;10m 17 root 0 -20 0 0 0 S 0 0.0 0:00.00 kintegrityd [0;10m[39;49m [0;10m 18 root 0 -20 0 0 0 S 0 0.0 0:00.00 kblockd [0;10m[39;49m [0;10m 19 root 0 -20 0 0 0 S 0 0.0 0:00.00 ata_sff [0;10m[39;49m [0;10m 20 root 20 0 0 0 0 S 0 0.0 0:00.00 khubd [0;10m[39;49m [0;10m 21 root 0 -20 0 0 0 S 0 0.0 0:00.00 md [0;10m[39;49m [0;10m 22 root 20 0 0 0 0 S 0 0.0 0:00.22 kworker/1:1 [0;10m[39;49m [0;10m 23 root 20 0 0 0 0 S 0 0.0 0:00.00 khungtaskd [0;10m[39;49m [0;10m 24 root 20 0 0 0 0 S 0 0.0 0:00.00 kswapd0 [0;10m[39;49m [0;10m 25 root 25 5 0 0 0 S 0 0.0 0:00.00 ksmd [0;10m[39;49m [0;10m 26 root 39 19 0 0 0 S 0 0.0 0:00.00 khugepaged [0;10m[39;49m [0;10m 27 root 20 0 0 0 0 S 0 0.0 0:00.00 fsnotify_mark [0;10m[39;49m [0;10m 28 root 20 0 0 0 0 S 0 0.0 0:00.00 ecryptfs-kthrea [0;10m[39;49m [0;10m 29 root 0 -20 0 0 0 S 0 0.0 0:00.00 crypto [0;10m[39;49m [0;10m 37 root 0 -20 0 0 0 S 0 0.0 0:00.00 kthrotld [0;10m[39;49m [0;10m 38 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_0 [0;10m[39;49m [0;10m 39 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_1 [0;10m[39;49m [0;10m 40 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/u:2 [0;10m[39;49m [0;10m 41 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_2 [0;10m[39;49m [0;10m 42 root 20 0 0 0 0 S 0 0.0 0:00.00 scsi_eh_3 [0;10m[39;49m [0;10m 43 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/u:3 [0;10m[39;49m [0;10m 44 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/u:4 [0;10m[39;49m [0;10m 45 root 20 0 0 0 0 S 0 0.0 0:00.00 kworker/u:5 [0;10m[39;49m[6;1H[K Sorry about the horrible formatting. Thanks for any suggestions... Edit: I notice that my virtual computer (win7 64 on virtualbox) continues to respond most of the time during these 'freezes' Edit2: I suspect this is something to do with UI priority being too low... but I don't know enough about linux to know how to address that.

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  • Regarding compatibility of Intel Pentium D 805 CPU with new motherboard

    - by aniruddhabhide
    I currently have an old configuration with Intel Pentium D 805 CPU and Intel D101GGC chipset. Now I am planning to upgrade my system except CPU and hard disk since it doesn't fit in the budget. QUESTION: I am planning to get Gigabyte GA-B75M-D3H Motherboard which has LGA1155 socket. But my processor has PLGA775 socket type. Will my CPU fit in thee new motherboard's socket? LINKS: CPU specs (Intel site): http://ark.intel.com/products/27511/Intel-Pentium-D-Processor-805-2M-Cache-2_66-GHz-533-MHz-FSB New Motherboard specs (Vendor site): http://www.flipkart.com/gigabyte-ga-b75m-d3h-motherboard/p/itmdacp36gegyeqt?pid=MBDDACP2GUBGFPFM

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  • PASS Data Architecture VC presents Neil Hambly on Improve Data Quality & Integrity using Constraints

    On Tuesday June 19th 12PM noon Central, Neil Hambly will discuss "Leveraging the power of constraints to improve both data quality and performance of your databases." What are your servers really trying to tell you? Find out with new SQL Monitor 3.0, an easy-to-use tool built for no-nonsense database professionals.For effortless insights into SQL Server, download a free trial today.

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  • Subsumption architecture vs. perceptual control theory

    - by Yasir G.
    I'm a new person to AI field and I have to research and compare 2 different architectures for a thesis I'm writing. Before you scream (homework thread), I've been reading on these 2 topics only to find that I'm confusing myself more.. let me first start with stating briefly what I know so far. Subsumption is based on the fact that targets of a system are different in sophistication, thus that requires them to be added as layers, each layer can suppress (modify) the command of the layers below it, and there are inhibitors to stop signals from execution lets say. PCT stresses on the fact that there are nodes to handle environmental changes (negative feedback), so the inputs coming from an environment go through a comparator node and then an action is generated by that node, HPCT or (Hierarchical PCT) is based on nesting these cycles inside each other so a small cycle to avoid crashing would be nested in a more sophisticated cycle that targets a certain location for example. My questions, am I getting this the right way? am I missing any critical understanding about these 2 models? also any idea where I can find simplified explanations for each theory (so far been struggling trying to understand the papers from Google scholar :< ) /Y

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  • Getting a per thread cpu stats

    - by viraptor
    I'm interested in the current usage of cpu - precisely cpu% and wait% - for each thread in a specific application. Is it possible to get that information from somewhere? I know that top can split information per real thread (ones with pid), but it doesn't show the system/user/wait cpu usage split for each of them. I would also like some way to log that info. Do you know any apps (or apis) that can do that?

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  • UDP Code client server architecture

    - by GameBuilder
    Hi I have developed a game on android.Now I want to play it on wifi or 3G. I have game packets which i want to send it form client(mobile) to server then to another client2(mobile). I don't know how to write code in Java to send the playPackets continuously to server and receive the playPacket continuously from the server to the clients. I guess i have to use two thread one for sending and one for receiving. Can someone help me with the code, or the procedure to write code for it. Thanks in advance.

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  • 4.5 Load average on single CPU

    - by Webnet
    I'm currently looking at... top - 16:27:37 up 27 min, 1 user, load average: 4.96, 3.75, 2.87 Tasks: 141 total, 6 running, 135 sleeping, 0 stopped, 0 zombie Cpu(s): 91.4%us, 6.9%sy, 0.0%ni, 0.0%id, 0.0%wa, 0.3%hi, 1.3%si, 0.0%st Mem: 514952k total, 507500k used, 7452k free, 5652k buffers Swap: 1044184k total, 281400k used, 762784k free, 89164k cached This is a single 2.0 Ghz CPU with 2 GB RAM Is it time for an upgrade? I'm watching and it seems to stick around 50% CPU "us" which I assume means usage.

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  • Diving into OpenStack Network Architecture - Part 2 - Basic Use Cases

    - by Ronen Kofman
      rkofman Normal rkofman 4 138 2014-06-05T03:38:00Z 2014-06-05T05:04:00Z 3 2735 15596 Oracle Corporation 129 36 18295 12.00 Clean Clean false false false false EN-US X-NONE HE /* Style Definitions */ table.MsoNormalTable {mso-style-name:"Table Normal"; mso-tstyle-rowband-size:0; mso-tstyle-colband-size:0; mso-style-noshow:yes; mso-style-priority:99; mso-style-qformat:yes; mso-style-parent:""; mso-padding-alt:0in 5.4pt 0in 5.4pt; mso-para-margin-top:0in; mso-para-margin-right:0in; mso-para-margin-bottom:10.0pt; mso-para-margin-left:0in; line-height:115%; mso-pagination:widow-orphan; font-size:11.0pt; font-family:"Calibri","sans-serif"; mso-ascii-font-family:Calibri; mso-ascii-theme-font:minor-latin; mso-hansi-font-family:Calibri; mso-hansi-theme-font:minor-latin; mso-bidi-font-family:Arial; mso-bidi-theme-font:minor-bidi; mso-bidi-language:AR-SA;} In the previous post we reviewed several network components including Open vSwitch, Network Namespaces, Linux Bridges and veth pairs. In this post we will take three simple use cases and see how those basic components come together to create a complete SDN solution in OpenStack. With those three use cases we will review almost the entire network setup and see how all the pieces work together. The use cases we will use are: 1.       Create network – what happens when we create network and how can we create multiple isolated networks 2.       Launch a VM – once we have networks we can launch VMs and connect them to networks. 3.       DHCP request from a VM – OpenStack can automatically assign IP addresses to VMs. This is done through local DHCP service controlled by OpenStack Neutron. We will see how this service runs and how does a DHCP request and response look like. In this post we will show connectivity, we will see how packets get from point A to point B. We first focus on how a configured deployment looks like and only later we will discuss how and when the configuration is created. Personally I found it very valuable to see the actual interfaces and how they connect to each other through examples and hands on experiments. After the end game is clear and we know how the connectivity works, in a later post, we will take a step back and explain how Neutron configures the components to be able to provide such connectivity.  We are going to get pretty technical shortly and I recommend trying these examples on your own deployment or using the Oracle OpenStack Tech Preview. Understanding these three use cases thoroughly and how to look at them will be very helpful when trying to debug a deployment in case something does not work. Use case #1: Create Network Create network is a simple operation it can be performed from the GUI or command line. When we create a network in OpenStack the network is only available to the tenant who created it or it could be defined as “shared” and then it can be used by all tenants. A network can have multiple subnets but for this demonstration purpose and for simplicity we will assume that each network has exactly one subnet. Creating a network from the command line will look like this: # neutron net-create net1 Created a new network: +---------------------------+--------------------------------------+ | Field                     | Value                                | +---------------------------+--------------------------------------+ | admin_state_up            | True                                 | | id                        | 5f833617-6179-4797-b7c0-7d420d84040c | | name                      | net1                                 | | provider:network_type     | vlan                                 | | provider:physical_network | default                              | | provider:segmentation_id  | 1000                                 | | shared                    | False                                | | status                    | ACTIVE                               | | subnets                   |                                      | | tenant_id                 | 9796e5145ee546508939cd49ad59d51f     | +---------------------------+--------------------------------------+ Creating a subnet for this network will look like this: # neutron subnet-create net1 10.10.10.0/24 Created a new subnet: +------------------+------------------------------------------------+ | Field            | Value                                          | +------------------+------------------------------------------------+ | allocation_pools | {"start": "10.10.10.2", "end": "10.10.10.254"} | | cidr             | 10.10.10.0/24                                  | | dns_nameservers  |                                                | | enable_dhcp      | True                                           | | gateway_ip       | 10.10.10.1                                     | | host_routes      |                                                | | id               | 2d7a0a58-0674-439a-ad23-d6471aaae9bc           | | ip_version       | 4                                              | | name             |                                                | | network_id       | 5f833617-6179-4797-b7c0-7d420d84040c           | | tenant_id        | 9796e5145ee546508939cd49ad59d51f               | +------------------+------------------------------------------------+ We now have a network and a subnet, on the network topology view this looks like this: Now let’s dive in and see what happened under the hood. Looking at the control node we will discover that a new namespace was created: # ip netns list qdhcp-5f833617-6179-4797-b7c0-7d420d84040c   The name of the namespace is qdhcp-<network id> (see above), let’s look into the namespace and see what’s in it: # ip netns exec qdhcp-5f833617-6179-4797-b7c0-7d420d84040c ip addr 1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN     link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00     inet 127.0.0.1/8 scope host lo     inet6 ::1/128 scope host        valid_lft forever preferred_lft forever 12: tap26c9b807-7c: <BROADCAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UNKNOWN     link/ether fa:16:3e:1d:5c:81 brd ff:ff:ff:ff:ff:ff     inet 10.10.10.3/24 brd 10.10.10.255 scope global tap26c9b807-7c     inet6 fe80::f816:3eff:fe1d:5c81/64 scope link        valid_lft forever preferred_lft forever   We see two interfaces in the namespace, one is the loopback and the other one is an interface called “tap26c9b807-7c”. This interface has the IP address of 10.10.10.3 and it will also serve dhcp requests in a way we will see later. Let’s trace the connectivity of the “tap26c9b807-7c” interface from the namespace.  First stop is OVS, we see that the interface connects to bridge  “br-int” on OVS: # ovs-vsctl show 8a069c7c-ea05-4375-93e2-b9fc9e4b3ca1     Bridge "br-eth2"         Port "br-eth2"             Interface "br-eth2"                 type: internal         Port "eth2"             Interface "eth2"         Port "phy-br-eth2"             Interface "phy-br-eth2"     Bridge br-ex         Port br-ex             Interface br-ex                 type: internal     Bridge br-int         Port "int-br-eth2"             Interface "int-br-eth2"         Port "tap26c9b807-7c"             tag: 1             Interface "tap26c9b807-7c"                 type: internal         Port br-int             Interface br-int                 type: internal     ovs_version: "1.11.0"   In the picture above we have a veth pair which has two ends called “int-br-eth2” and "phy-br-eth2", this veth pair is used to connect two bridge in OVS "br-eth2" and "br-int". In the previous post we explained how to check the veth connectivity using the ethtool command. It shows that the two are indeed a pair: # ethtool -S int-br-eth2 NIC statistics:      peer_ifindex: 10 . .   #ip link . . 10: phy-br-eth2: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP qlen 1000 . . Note that “phy-br-eth2” is connected to a bridge called "br-eth2" and one of this bridge's interfaces is the physical link eth2. This means that the network which we have just created has created a namespace which is connected to the physical interface eth2. eth2 is the “VM network” the physical interface where all the virtual machines connect to where all the VMs are connected. About network isolation: OpenStack supports creation of multiple isolated networks and can use several mechanisms to isolate the networks from one another. The isolation mechanism can be VLANs, VxLANs or GRE tunnels, this is configured as part of the initial setup in our deployment we use VLANs. When using VLAN tagging as an isolation mechanism a VLAN tag is allocated by Neutron from a pre-defined VLAN tags pool and assigned to the newly created network. By provisioning VLAN tags to the networks Neutron allows creation of multiple isolated networks on the same physical link.  The big difference between this and other platforms is that the user does not have to deal with allocating and managing VLANs to networks. The VLAN allocation and provisioning is handled by Neutron which keeps track of the VLAN tags, and responsible for allocating and reclaiming VLAN tags. In the example above net1 has the VLAN tag 1000, this means that whenever a VM is created and connected to this network the packets from that VM will have to be tagged with VLAN tag 1000 to go on this particular network. This is true for namespace as well, if we would like to connect a namespace to a particular network we have to make sure that the packets to and from the namespace are correctly tagged when they reach the VM network. In the example above we see that the namespace interface “tap26c9b807-7c” has vlan tag 1 assigned to it, if we examine OVS we see that it has flows which modify VLAN tag 1 to VLAN tag 1000 when a packet goes to the VM network on eth2 and vice versa. We can see this using the dump-flows command on OVS for packets going to the VM network we see the modification done on br-eth2: #  ovs-ofctl dump-flows br-eth2 NXST_FLOW reply (xid=0x4):  cookie=0x0, duration=18669.401s, table=0, n_packets=857, n_bytes=163350, idle_age=25, priority=4,in_port=2,dl_vlan=1 actions=mod_vlan_vid:1000,NORMAL  cookie=0x0, duration=165108.226s, table=0, n_packets=14, n_bytes=1000, idle_age=5343, hard_age=65534, priority=2,in_port=2 actions=drop  cookie=0x0, duration=165109.813s, table=0, n_packets=1671, n_bytes=213304, idle_age=25, hard_age=65534, priority=1 actions=NORMAL   For packets coming from the interface to the namespace we see the following modification: #  ovs-ofctl dump-flows br-int NXST_FLOW reply (xid=0x4):  cookie=0x0, duration=18690.876s, table=0, n_packets=1610, n_bytes=210752, idle_age=1, priority=3,in_port=1,dl_vlan=1000 actions=mod_vlan_vid:1,NORMAL  cookie=0x0, duration=165130.01s, table=0, n_packets=75, n_bytes=3686, idle_age=4212, hard_age=65534, priority=2,in_port=1 actions=drop  cookie=0x0, duration=165131.96s, table=0, n_packets=863, n_bytes=160727, idle_age=1, hard_age=65534, priority=1 actions=NORMAL   To summarize we can see that when a user creates a network Neutron creates a namespace and this namespace is connected through OVS to the “VM network”. OVS also takes care of tagging the packets from the namespace to the VM network with the correct VLAN tag and knows to modify the VLAN for packets coming from VM network to the namespace. Now let’s see what happens when a VM is launched and how it is connected to the “VM network”. Use case #2: Launch a VM Launching a VM can be done from Horizon or from the command line this is how we do it from Horizon: Attach the network: And Launch Once the virtual machine is up and running we can see the associated IP using the nova list command : # nova list +--------------------------------------+--------------+--------+------------+-------------+-----------------+ | ID                                   | Name         | Status | Task State | Power State | Networks        | +--------------------------------------+--------------+--------+------------+-------------+-----------------+ | 3707ac87-4f5d-4349-b7ed-3a673f55e5e1 | Oracle Linux | ACTIVE | None       | Running     | net1=10.10.10.2 | +--------------------------------------+--------------+--------+------------+-------------+-----------------+ The nova list command shows us that the VM is running and that the IP 10.10.10.2 is assigned to this VM. Let’s trace the connectivity from the VM to VM network on eth2 starting with the VM definition file. The configuration files of the VM including the virtual disk(s), in case of ephemeral storage, are stored on the compute node at/var/lib/nova/instances/<instance-id>/. Looking into the VM definition file ,libvirt.xml,  we see that the VM is connected to an interface called “tap53903a95-82” which is connected to a Linux bridge called “qbr53903a95-82”: <interface type="bridge">       <mac address="fa:16:3e:fe:c7:87"/>       <source bridge="qbr53903a95-82"/>       <target dev="tap53903a95-82"/>     </interface>   Looking at the bridge using the brctl show command we see this: # brctl show bridge name     bridge id               STP enabled     interfaces qbr53903a95-82          8000.7e7f3282b836       no              qvb53903a95-82                                                         tap53903a95-82    The bridge has two interfaces, one connected to the VM (“tap53903a95-82 “) and another one ( “qvb53903a95-82”) connected to “br-int” bridge on OVS: # ovs-vsctl show 83c42f80-77e9-46c8-8560-7697d76de51c     Bridge "br-eth2"         Port "br-eth2"             Interface "br-eth2"                 type: internal         Port "eth2"             Interface "eth2"         Port "phy-br-eth2"             Interface "phy-br-eth2"     Bridge br-int         Port br-int             Interface br-int                 type: internal         Port "int-br-eth2"             Interface "int-br-eth2"         Port "qvo53903a95-82"             tag: 3             Interface "qvo53903a95-82"     ovs_version: "1.11.0"   As we showed earlier “br-int” is connected to “br-eth2” on OVS using the veth pair int-br-eth2,phy-br-eth2 and br-eth2 is connected to the physical interface eth2. The whole flow end to end looks like this: VM è tap53903a95-82 (virtual interface)è qbr53903a95-82 (Linux bridge) è qvb53903a95-82 (interface connected from Linux bridge to OVS bridge br-int) è int-br-eth2 (veth one end) è phy-br-eth2 (veth the other end) è eth2 physical interface. The purpose of the Linux Bridge connecting to the VM is to allow security group enforcement with iptables. Security groups are enforced at the edge point which are the interface of the VM, since iptables nnot be applied to OVS bridges we use Linux bridge to apply them. In the future we hope to see this Linux Bridge going away rules.  VLAN tags: As we discussed in the first use case net1 is using VLAN tag 1000, looking at OVS above we see that qvo41f1ebcf-7c is tagged with VLAN tag 3. The modification from VLAN tag 3 to 1000 as we go to the physical network is done by OVS  as part of the packet flow of br-eth2 in the same way we showed before. To summarize, when a VM is launched it is connected to the VM network through a chain of elements as described here. During the packet from VM to the network and back the VLAN tag is modified. Use case #3: Serving a DHCP request coming from the virtual machine In the previous use cases we have shown that both the namespace called dhcp-<some id> and the VM end up connecting to the physical interface eth2  on their respective nodes, both will tag their packets with VLAN tag 1000.We saw that the namespace has an interface with IP of 10.10.10.3. Since the VM and the namespace are connected to each other and have interfaces on the same subnet they can ping each other, in this picture we see a ping from the VM which was assigned 10.10.10.2 to the namespace: The fact that they are connected and can ping each other can become very handy when something doesn’t work right and we need to isolate the problem. In such case knowing that we should be able to ping from the VM to the namespace and back can be used to trace the disconnect using tcpdump or other monitoring tools. To serve DHCP requests coming from VMs on the network Neutron uses a Linux tool called “dnsmasq”,this is a lightweight DNS and DHCP service you can read more about it here. If we look at the dnsmasq on the control node with the ps command we see this: dnsmasq --no-hosts --no-resolv --strict-order --bind-interfaces --interface=tap26c9b807-7c --except-interface=lo --pid-file=/var/lib/neutron/dhcp/5f833617-6179-4797-b7c0-7d420d84040c/pid --dhcp-hostsfile=/var/lib/neutron/dhcp/5f833617-6179-4797-b7c0-7d420d84040c/host --dhcp-optsfile=/var/lib/neutron/dhcp/5f833617-6179-4797-b7c0-7d420d84040c/opts --leasefile-ro --dhcp-range=tag0,10.10.10.0,static,120s --dhcp-lease-max=256 --conf-file= --domain=openstacklocal The service connects to the tap interface in the namespace (“--interface=tap26c9b807-7c”), If we look at the hosts file we see this: # cat  /var/lib/neutron/dhcp/5f833617-6179-4797-b7c0-7d420d84040c/host fa:16:3e:fe:c7:87,host-10-10-10-2.openstacklocal,10.10.10.2   If you look at the console output above you can see the MAC address fa:16:3e:fe:c7:87 which is the VM MAC. This MAC address is mapped to IP 10.10.10.2 and so when a DHCP request comes with this MAC dnsmasq will return the 10.10.10.2.If we look into the namespace at the time we initiate a DHCP request from the VM (this can be done by simply restarting the network service in the VM) we see the following: # ip netns exec qdhcp-5f833617-6179-4797-b7c0-7d420d84040c tcpdump -n 19:27:12.191280 IP 0.0.0.0.bootpc > 255.255.255.255.bootps: BOOTP/DHCP, Request from fa:16:3e:fe:c7:87, length 310 19:27:12.191666 IP 10.10.10.3.bootps > 10.10.10.2.bootpc: BOOTP/DHCP, Reply, length 325   To summarize, the DHCP service is handled by dnsmasq which is configured by Neutron to listen to the interface in the DHCP namespace. Neutron also configures dnsmasq with the combination of MAC and IP so when a DHCP request comes along it will receive the assigned IP. Summary In this post we relied on the components described in the previous post and saw how network connectivity is achieved using three simple use cases. These use cases gave a good view of the entire network stack and helped understand how an end to end connection is being made between a VM on a compute node and the DHCP namespace on the control node. One conclusion we can draw from what we saw here is that if we launch a VM and it is able to perform a DHCP request and receive a correct IP then there is reason to believe that the network is working as expected. We saw that a packet has to travel through a long list of components before reaching its destination and if it has done so successfully this means that many components are functioning properly. In the next post we will look at some more sophisticated services Neutron supports and see how they work. We will see that while there are some more components involved for the most part the concepts are the same. @RonenKofman

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  • 0% CPU in top for all processes, but load average > 1

    - by chrisdew
    On two different servers (with Ubuntu 12.04LTS AMD64) I have seen the following behaviour: op - 10:50:05 up 305 days, 21:17, 1 user, load average: 1.94, 2.52, 2.97 Tasks: 141 total, 2 running, 139 sleeping, 0 stopped, 0 zombie Cpu(s): 41.5%us, 6.5%sy, 0.0%ni, 51.8%id, 0.0%wa, 0.2%hi, 0.1%si, 0.0%st Mem: 8178432k total, 5753740k used, 2424692k free, 159480k buffers Swap: 15625208k total, 0k used, 15625208k free, 4905292k cached PID USER PR NI VIRT RES SHR S %CPU %MEM TIME+ COMMAND 1 root 20 0 23928 2072 1216 S 0 0.0 0:56.42 init 2 root 20 0 0 0 0 S 0 0.0 0:00.01 kthreadd 3 root RT 0 0 0 0 S 0 0.0 0:01.23 migration/0 4 root 20 0 0 0 0 S 0 0.0 2:39.82 ksoftirqd/0 5 root RT 0 0 0 0 S 0 0.0 0:00.00 watchdog/0 6 root RT 0 0 0 0 S 0 0.0 0:02.99 migration/1 7 root 20 0 0 0 0 S 0 0.0 2:32.15 ksoftirqd/1 8 root RT 0 0 0 0 S 0 0.0 0:00.00 watchdog/1 9 root RT 0 0 0 0 S 0 0.0 0:11.67 migration/2 10 root 20 0 0 0 0 S 0 0.0 29:00.34 ksoftirqd/2 The server is working fine, but top shows all processes as using 0% CPU. A reboot fixed this on an earlier machine, but I haven't yet tried it on this one. I have tried top several times, and so am sure that I haven't accidentally pressed '<' or '' to sort by a different column. Sorting the process list by all of the available columns, stills shows 0% CPU for all displayed processes. What is going on? If this a kernel bug? Update: If I use top -p <PID> for a know, busy process, top still displays 0% CPU for that process.

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  • Overheating on Dell Studio XPS 1645

    - by pjtatlow
    So I was wondering if anyone else has come upon this problem, and/or has come up with a solution. When I use my Ubuntu partition, my computer becomes extremely hot, and the fan runs very noisily for a very long time. If I reboot into windows while this is happening, my computer actually begins to cool down while doing the exact same tasks. Thinking this might just be a bug with Ubuntu, I installed fedora on another partition, and the same problem occurs. Is this a problem with the kernel? Cpufreq tells me that my CPU is running at 933 MHz out of a possible 1.6 GHz from my Intel Core i7 CPU Q70. For anyone who wants more information, I have 8 GB of memory, and an ATI Mobility Raedon HD 5730 Graphics Card. I'm open to any ideas anyone might have. Thanks in advance!

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  • How to create and administer multi-architecture PPAs?

    - by maxschlepzig
    I have a program that needs to be recompiled for every ubuntu version. Currently I am packaging it using Ubuntu's PPA just for the current distribution. Eventually, I have to provide packages for the previous ubuntu version. I am not sure how to accomplish this. How does the Ubuntu PPA build server works - does it just look at the distribution field in the most current changelog entry (in the debian/changelog file) to determine for what distribution the package should be build? The debian specification allows to add multiple distributions into the distribution field. But this does not seam to help me. Some ubuntu documents talk about encoding the distribution name into the version number (in the debian changelog file). But how does this work in practice? A new version of the program is available, then what? Do I add for each distribution a new changelog entry and the PPA buildserver builds automatically for each distribution new packages after dput'ing it up? Or does the PPA buildserver just looks at the first changelog entry?

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