Friday, July 23, 2010

Convert .DAA files to .ISO in Linux with Poweriso

SkyHi @ Friday, July 23, 2010

PowerISO for Linux is a free utility which can extract, list, and convert image files (including ISO, BIN, DAA, and other formats).


You can download Poweriso from this link. You can also download and extract Poweriso via command line, to do that open terminal and copy the commands bellow :

wget http://www.poweriso.com/poweriso-1.3.tar.gz

Now extract the file

tar -zxvf poweriso-1.3.tar.gz

you can copy the extracted file "poweriso"; to /usr/bin to help all users of a computer to user it.

Now if you want to convert for example a .daa file to .iso use this command:

./poweriso convert /path/to/source.daa -o /path/to/target.iso -ot iso

(Change source.daa and target.iso to the name of your file you want to convert)

there is more useful commands of poweriso

Task: list all files and directories in home direcory of /media/file.iso

$ ./poweriso list /media/file.iso /
$ ./poweriso list /media/file.iso / -r

Fore more commands please type

Thursday, July 22, 2010

Iperf measure the bandwidth

SkyHi @ Thursday, July 22, 2010




Iperf is a
tool to measure the bandwidth and the quality of a network link.
Jperf can be associated
with Iperf to provide a graphical frontend written in Java.



The network link is delimited by two hosts running Iperf.




The quality of a link can be tested as follows:

- Latency (response time or RTT): can be measured with the Ping command.

- Jitter (latency variation): can be measured with an Iperf UDP test.

- Datagram loss: can be measured with an Iperf UDP test.





The bandwidth is measured through TCP tests.



To be clear, the difference between TCP (Transmission Control Protocol) and UDP (User Datagram Protocol)
is that TCP use processes to check that the packets are correctly sent to the receiver whereas with
UDP the packets are sent without any checks but with the advantage of being quicker than TCP.

Iperf uses the different capacities of TCP and UDP to provide statistics about network links.





Finally, Iperf can be installed very easily on any UNIX/Linux or Microsoft Windows system. One host must be set as
client, the other one as server.










Here is a diagram where Iperf is installed on a Linux and Microsoft Windows machine.

Linux is used as the Iperf client and Windows as the Iperf server. Of course, it is also possible to use two Linux boxes.









screenshot Iperf bandwidth measure client server






Iperf tests:














no arg.

-b

-r

-d

-w



Default settings

Data format

Bi-directional bandwidth

Simultaneous bi-directional bandwidth

TCP Window size





-p, -t, -i

-u, -b

-m

-M

-P

-h

Port, timing and interval

UDP tests, bandwidth settings

Maximum Segment Size display

Maximum Segment Size settings

Parallel tests

help


Jperf:

















no arg.

-d

-u, -b


Default settings

Simultaneous bi-directional bandwidth

UDP tests, bandwidth settings











Default Iperf settings:

Also check "
Jperf section.



By default, the Iperf client connects to the Iperf server on the TCP port 5001 and

the bandwidth displayed by Iperf is the bandwidth from the client to the server.

If you want to use UDP tests, use the -u argument.

The -d and -r Iperf client arguments measure the bi-directional bandwidths. (See further
on this tutorial)



Client side:






#iperf -c 10.1.1.1


------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16384 Byte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 33453 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.2 sec 1.26 MBytes 1.05 Mbits/sec




Server side:





#iperf -s



------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[852] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 33453

[ ID] Interval Transfer Bandwidth

[852] 0.0-10.6 sec 1.26 MBytes 1.03 Mbits/sec











Data formatting: (-f argument)



The -f argument can display the results in the desired format:
bits(b), bytes(B), kilobits(k), kilobytes(K), megabits(m),
megabytes(M), gigabits(g) or gigabytes(G).

Generally the bandwidth measures are displayed in bits (or Kilobits, etc ...) and an amount of data
is displayed in bytes (or Kilobytes, etc ...).

As a reminder, 1 byte is equal to 8 bits and, in the computer science world, 1 kilo is equal to 1024 (2^10).

For example: 100'000'000 bytes is not equal to 100 Mbytes but to 100'000'000/1024/1024 = 95.37 Mbytes.



Client side:






#iperf -c 10.1.1.1 -f b


------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16384 Byte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 54953 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.2 sec 1359872 Bytes 1064272 bits/sec



Server side:






#iperf -s



------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[852] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 33453

[ ID] Interval Transfer Bandwidth

[852] 0.0-10.6 sec 920 KBytes 711 Kbits/sec




Top of the page







Bi-directional bandwidth measurement: (-r argument)




The Iperf server connects back to the client allowing the bi-directional bandwidth measurement.
By default, only the bandwidth from the client to the server is measured.

If you want to measure the bi-directional bandwidth simultaneously, use the -d keyword. (See next test.)




Client side:





#iperf -c 10.1.1.1 -r



------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 85.3 KByte (default)

------------------------------------------------------------

------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 5] local 10.6.2.5 port 35726 connected with 10.1.1.1 port 5001

[ 5] 0.0-10.0 sec 1.12 MBytes 936 Kbits/sec

[ 4] local 10.6.2.5 port 5001 connected with 10.1.1.1 port 1640

[ 4] 0.0-10.1 sec 74.2 MBytes 61.7 Mbits/sec





Server side:





#iperf -s


------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[852] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 54355

[ ID] Interval Transfer Bandwidth

[852] 0.0-10.1 sec 1.15 MBytes 956 Kbits/sec

------------------------------------------------------------

Client connecting to 10.6.2.5, TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[824] local 10.1.1.1 port 1646 connected with 10.6.2.5 port 5001

[ ID] Interval Transfer Bandwidth

[824] 0.0-10.0 sec 73.3 MBytes 61.4 Mbits/sec



Top of the page







Simultaneous bi-directional bandwidth measurement: (-d argument)


Also check the "
Jperf" section.


To measure the bi-directional bandwidths simultaneousely, use the -d argument.
If you want to test the bandwidths sequentially, use the -r argument (see previous test).

By default (ie: without the -r or -d arguments), only the bandwidth from the client to the server is measured.



Client side:






#iperf -c 10.1.1.1 -d


------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 85.3 KByte (default)

------------------------------------------------------------

------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 5] local 10.6.2.5 port 60270 connected with 10.1.1.1 port 5001

[ 4] local 10.6.2.5 port 5001 connected with 10.1.1.1 port 2643

[ 4] 0.0-10.0 sec 76.3 MBytes 63.9 Mbits/sec

[ 5] 0.0-10.1 sec 1.55 MBytes 1.29 Mbits/sec










Server side:






#iperf -s


------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[852] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 60270

------------------------------------------------------------

Client connecting to 10.6.2.5, TCP port 5001

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[800] local 10.1.1.1 port 2643 connected with 10.6.2.5 port 5001

[ ID] Interval Transfer Bandwidth

[800] 0.0-10.0 sec 76.3 MBytes 63.9 Mbits/sec

[852] 0.0-10.1 sec 1.55 MBytes 1.29 Mbits/sec




Top of the page







TCP Window size: (-w argument)



The TCP window size is the amount of data that
can be buffered during a connection without a validation from the receiver.

It can be between 2 and 65,535 bytes.

On Linux systems, when specifying a TCP buffer size with the -w argument,
the kernel allocates double as much as indicated.




Client side:






#iperf -c 10.1.1.1 -w 2000


WARNING: TCP window size set to 2000 bytes. A small window size

will give poor performance. See the Iperf documentation.

------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 3.91 KByte (WARNING: requested 1.95 KByte)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 51400 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.1 sec 704 KBytes 572 Kbits/sec





Server side:





#iperf -s -w 4000

------------------------------------------------------------

Server listening on TCP port 5001

TCP window size: 3.91 KByte

------------------------------------------------------------

[852] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 51400

[ ID] Interval Transfer Bandwidth

[852] 0.0-10.1 sec 704 KBytes 570 Kbits/sec










Top of the page








Communication port (-p), timing (-t) and interval (-i):



The Iperf server communication port can be changed with the -p argument. It must be configured
on the client and the server with the same value, default is TCP port 5001.



The -t argument specifies the test duration time in seconds, default is 10 secs.


The -i argument indicates the interval in seconds between periodic bandwidth reports.





Client side:






#iperf -c 10.1.1.1 -p 12000 -t 20 -i 2


------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 12000

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 58316 connected with 10.1.1.1 port 12000

[ 3] 0.0- 2.0 sec 224 KBytes 918 Kbits/sec

[ 3] 2.0- 4.0 sec 368 KBytes 1.51 Mbits/sec

[ 3] 4.0- 6.0 sec 704 KBytes 2.88 Mbits/sec

[ 3] 6.0- 8.0 sec 280 KBytes 1.15 Mbits/sec

[ 3] 8.0-10.0 sec 208 KBytes 852 Kbits/sec

[ 3] 10.0-12.0 sec 344 KBytes 1.41 Mbits/sec

[ 3] 12.0-14.0 sec 208 KBytes 852 Kbits/sec

[ 3] 14.0-16.0 sec 232 KBytes 950 Kbits/sec

[ 3] 16.0-18.0 sec 232 KBytes 950 Kbits/sec

[ 3] 18.0-20.0 sec 264 KBytes 1.08 Mbits/sec

[ 3] 0.0-20.1 sec 3.00 MBytes 1.25 Mbits/sec




Server side:





#iperf -s -p 12000


------------------------------------------------------------

Server listening on TCP port 12000

TCP window size: 8.00 KByte (default)

------------------------------------------------------------

[852] local 10.1.1.1 port 12000 connected with 10.6.2.5 port 58316

[ ID] Interval Transfer Bandwidth

[852] 0.0-20.1 sec 3.00 MBytes 1.25 Mbits/sec





Top of the page






UDP tests: (-u), bandwidth settings (-b)

Also check the "
Jperf" section.



The UDP tests with the -u argument will give invaluable information about the
jitter and the packet loss.
If you don't specify the -u argument, Iperf uses TCP.


To keep a good link quality, the packet loss should not go over 1 %. A high packet
loss rate will generate a lot of
TCP segment retransmissions which will affect the bandwidth.


The jitter is basically the latency variation and does not
depend on the latency. You can have high response
times and a very low jitter. The jitter value is particularly important
on network links supporting voice over IP (VoIP) because a high jitter can break a call.

The -b argument allows the allocation if the desired bandwidth.



Client side:





#iperf -c 10.1.1.1 -u -b 10m


------------------------------------------------------------

Client connecting to 10.1.1.1, UDP port 5001

Sending 1470 byte datagrams

UDP buffer size: 108 KByte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 32781 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.0 sec 11.8 MBytes 9.89 Mbits/sec

[ 3] Sent 8409 datagrams

[ 3] Server Report:

[ 3] 0.0-10.0 sec 11.8 MBytes 9.86 Mbits/sec 2.617 ms 9/ 8409 (0.11%)



Server side:





#iperf -s -u -i 1


------------------------------------------------------------

Server listening on UDP port 5001

Receiving 1470 byte datagrams

UDP buffer size: 8.00 KByte (default)

------------------------------------------------------------

[904] local 10.1.1.1 port 5001 connected with 10.6.2.5 port 32781

[ ID] Interval Transfer Bandwidth Jitter Lost/Total Datagrams

[904] 0.0- 1.0 sec 1.17 MBytes 9.84 Mbits/sec 1.830 ms 0/ 837 (0%)

[904] 1.0- 2.0 sec 1.18 MBytes 9.94 Mbits/sec 1.846 ms 5/ 850 (0.59%)

[904] 2.0- 3.0 sec 1.19 MBytes 9.98 Mbits/sec 1.802 ms 2/ 851 (0.24%)

[904] 3.0- 4.0 sec 1.19 MBytes 10.0 Mbits/sec 1.830 ms 0/ 850 (0%)

[904] 4.0- 5.0 sec 1.19 MBytes 9.98 Mbits/sec 1.846 ms 1/ 850 (0.12%)

[904] 5.0- 6.0 sec 1.19 MBytes 10.0 Mbits/sec 1.806 ms 0/ 851 (0%)

[904] 6.0- 7.0 sec 1.06 MBytes 8.87 Mbits/sec 1.803 ms 1/ 755 (0.13%)

[904] 7.0- 8.0 sec 1.19 MBytes 10.0 Mbits/sec 1.831 ms 0/ 850 (0%)

[904] 8.0- 9.0 sec 1.19 MBytes 10.0 Mbits/sec 1.841 ms 0/ 850 (0%)

[904] 9.0-10.0 sec 1.19 MBytes 10.0 Mbits/sec 1.801 ms 0/ 851 (0%)

[904] 0.0-10.0 sec 11.8 MBytes 9.86 Mbits/sec 2.618 ms 9/ 8409 (0.11%)



Top of the page






Maximum Segment Size (-m argument) display:



The Maximum Segment Size (MSS) is the largest
amount of data, in bytes, that a computer can support in a single, unfragmented TCP segment.

It can be calculated as follows:

MSS = MTU - TCP & IP headers

The TCP & IP headers are equal to 40 bytes.

The MTU or Maximum Transmission Unit is the greatest amount of data that can
be transferred in a frame.

Here are some default MTU size for different network topology:

Ethernet - 1500 bytes: used in a LAN.

PPPoE - 1492 bytes: used on ADSL links.

Token Ring (16Mb/sec) - 17914 bytes: old technology developed by IBM.

Dial-up - 576 bytes




Generally, a higher MTU (and MSS) brings higher bandwidth efficiency




Client side:






#iperf -c 10.1.1.1 -m



------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 41532 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.2 sec 1.27 MBytes 1.04 Mbits/sec

[ 3] MSS size 1448 bytes (MTU 1500 bytes, ethernet)



Here the MSS is not equal to 1500 - 40 but to 1500 - 40 - 12 (Timestamps option) = 1448



Server side:





#iperf -s

Top of the page







Maximum Segment Size (-M argument) settings:



Use the -M argument to change the MSS. (See the previous test for more explanations about the MSS)





#iperf -c 10.1.1.1 -M 1300 -m


WARNING: attempt to set TCP maximum segment size to 1300, but got 536

------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 41533 connected with 10.1.1.1 port 5001

[ 3] 0.0-10.1 sec 4.29 MBytes 3.58 Mbits/sec

[ 3] MSS size 1288 bytes (MTU 1328 bytes, unknown interface)



Server side:





#iperf -s

Top of the page








Parallel tests (-P argument):



Use the -P argument to run parallel tests.



Client side:





#iperf -c 10.1.1.1 -P 2



------------------------------------------------------------

Client connecting to 10.1.1.1, TCP port 5001

TCP window size: 16.0 KByte (default)

------------------------------------------------------------

[ 3] local 10.6.2.5 port 41534 connected with 10.1.1.1 port 5001

[ 4] local 10.6.2.5 port 41535 connected with 10.1.1.1 port 5001

[ 4] 0.0-10.1 sec 1.35 MBytes 1.12 Mbits/sec

[ 3] 0.0-10.1 sec 1.35 MBytes 1.12 Mbits/sec

[SUM] 0.0-10.1 sec 2.70 MBytes 2.24 Mbits/sec




Server side:





#iperf -s

Top of the page






Iperf help:







#iperf -h



Usage: iperf [-s|-c host] [options]

iperf [-h|--help] [-v|--version]



Client/Server:













-f
-i
-l
-m
-p
-u
-w
-B
-C
-M
-N
-V


--format

--interval

--len

--print_mss

--port

--udp

--window

--bind

--compatibility

--mss

--nodelay

--IPv6Version
[kmKM]


#

#[KM]



#



#[KM]

"host"



#





format to report: Kbits, Mbits, KBytes, MBytes

seconds between periodic bandwidth reports

length of buffer to read or write (default 8 KB)

print TCP maximum segment size (MTU - TCP/IP header)

server port to listen on/connect to

use UDP rather than TCP

TCP window size (socket buffer size)

bind to "host", an interface or multicast address

for use with older versions does not sent extra msgs

set TCP maximum segment size (MTU - 40 bytes)

set TCP no delay, disabling Nagle's Algorithm

Set the domain to IPv6





Server specific:













-s
-U
-D


--server

--single_udp

--daemon









run in server mode

run in single threaded UDP mode

run the server as a daemon






Client specific:
















-b
-c
-d
-n
-r
-t
-F
-I
-L
-P
-T


--bandwidth

--client

--dualtest

--num

--tradeoff

--time

--fileinput

--stdin

--listenport

--parallel

--ttl



#[KM]

"host"



#[KM]



#

"name"



#

#

#






for UDP, bandwidth to send at in bits/sec (default 1 Mbit/sec, implies -u)

run in client mode, connecting to "host"

Do a bidirectional test simultaneously

number of bytes to transmit (instead of -t)

Do a bidirectional test individually

time in seconds to transmit for (default 10 secs)

input the data to be transmitted from a file

input the data to be transmitted from stdin

port to recieve bidirectional tests back on

number of parallel client threads to run

time-to-live, for multicast (default 1)






Miscellaneous:













-h
-v


--help

--version









print this message and quit

print version information and quit






Top of the page








JPERF



Jperf is a graphical frontend for Iperf written in Java.






1. Installation:



Download Jperf.



Linux


Uncompress the downloaded file:






#tar -xvf jperf2.0.0.zip

Launch Jperf.






#cd jperf2.0.0

#./jperf.sh


If you have the following message, it means that you need to install Iperf with:
"apt-get install iperf"




Iperf is probably not in your Path!

Please download it here 'http://dast.nlanr.net/Projects/Iperf/'

and put the executable in your PATH environment variable.










jperf default settings









Microsoft Windows


Uncompress the downloaded file with your favorite program.


Access the uncompressed folder called by default "jperf2.0.0"
and double-click on "jperf.bat".




Note that the iperf utility is already present in the /bin folder.






2. Examples:



Default settings, bandwidth measurement:

Also check "Iperf" section for more details.




- Linux client:







jperf default settings



- Windows server:







jperf default settings



Top of the page
Jperf



Simultaneous bi-directional bandwidth measurement:

Also check "Iperf" section for more details.



- Linux client:







jperf bidirectionnal bandwidth measurement



- Windows server:







jperf bidirectionnal bandwidth measurement



Top of the page
Jperf



Jitter measurement:

Also check "Iperf" section for more details.



- Linux client:








jperf jitter measurement



- Windows server:







jperf jitter measurement



REFERENCES
http://openmaniak.com/iperf.php
http://www.soopertutorials.com/technology/networks/397-397.html
http://trepullins.net/05-17-2008/testing-network-throughput-with-iperf