TCP/IP and Other Transports for High Bandwidth Applications
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Transcript TCP/IP and Other Transports for High Bandwidth Applications
TCP/IP and Other Transports for
High Bandwidth Applications
Back to Basics
Richard Hughes-Jones
The University of Manchester
www.hep.man.ac.uk/~rich/ then “Talks” then look for “Brasov”
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
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Structure of the Talks
The aim is to give you a picture of how researchers are using high performance
networks to support their work.
Back to Basics
Simple Introduction to Networking
TCP/IP on High Bandwidth Long Distance Networks
But TCP/IP works !
The effect of packet loss
Advanced TCP Stacks
Fairness
Real Applications on Real Networks
Disk-2-disk applications on real networks
Memory-2-memory tests
Transatlantic disk-2-disk at Gigabit speeds
Remote Computing Farms
The effect of distance
Radio Astronomy e-VLBI
Thanks for allowing me to use their slides to:
Sylvain Ravot CERN, Les Cottrell SLAC, Brian Tierney LBL, Robin Tasker DL
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
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Simple Introduction to Networking
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What is a Protocol Stack ?
ISO OSI (Open Systems Interconnection) Seven Layer Model defines a
framework allowing development of real network protocols
A layer…
performs unique and specific tasks
only has knowledge of those layers immediately above and below
uses services of layer below, and provides services to layer above
the services defined by a layer are implementation independent –
it’s a definition of how things work
conceptually communicates with its peer in the remote system
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Encapsulation:
The Layering Principle
Each protocol layer N adds a Header to the data unit from layer N+1
Header contains control information
App data
Layer 7: Application
user processes
Layer 6: Presentation
data interpretation, code transformation
SH
Layer 5: Session
Connection, negotiation control
Layer 4: Transport
End-2-end data transfer & integrity
Packet sequencing, flow control
Layer 3: Network
Addressing, Routing
Packet sequencing, flow control
Layer 2: Data Link
Packet assembly/disassembly
Transmission control, Error checking
Layer 1: Physical
Electrical, Optical, Mechanical
PH
App data
PH
App data
Segment
TH
SH
PH
App data
Packet
NH TH
SH
PH
App data
Frame
DH NH TH
SH
PH
App data FCS
Bits on the “wire”
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What do the Layers do?
Transport Layer: acts as a go-between for the user and network
Provides end-to-end data movement & control
Gives the level of reliability/integrity need by the application
Can ensure a reliable service (which network layer cannot),
e.g. assigns sequence numbers to identify “lost” packets
Network Layer: deals with logical addressing & the transmission of
packets, mechanism for routing.
Data Link Layer: provides the synchronization and error checking for
the data transmitted over a single physical link
(may ensure correct delivery of frames)
Going down: fits packets from the network layer above into
frames.
Going up: Groups bits from the physical layer into frames.
Physical Layer: concerned with the transmission of individual bits.
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How do the “IP” Protocols fit together?
Application
File
Transfer
Protocol
(FTP) RFC 559
TELNET
RFC 854
Simple Mail
Transfer
Protocol
( Presentation
(SMTP) RFC 821
Session)
DNS
traceroute
NFS
RFC 1024, 1057
and 1094
User Datagram
Protocol (UDP)
RFC 768
Transmission Control
Protocol (TCP)
RFC 793
Internet Control
Message Protocol
(ICMP) RFC 792
Routing
OSPF, BGP
Address
Resolution
Protocols
ARP: RFC 826
RARP: RFC 903
Internet Protocol
IP
RFC 791
Network
Data Link
ping
SNMP
RFC 1157
DNS
POP3/IMAP
HTTP
Transport
TFTP RFC 783
ssh
Ethernet
Token Ring
Network Interface Cards
ISDN
FDDI
SMDS
ATM
SDH/SONET xDSL
Transmission Mode
Physical
TP Copper
Fibre Optic
Satellite
Microwave DWDM CWDM etc
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Some of the “IP” Protocols
Transmission Control Protocol. TCP provides application programs
access to the network using a reliable, connection-oriented
transport layer service.
User Datagram Protocol. UDP provides unreliable, connectionless delivery service using the IP protocol to transport messages
between machines. It adds the ability to distinguish among multiple
destinations on a single host computer.
Internet Protocol. IP receives datagrams from the upper-layer
software and transmits it to the destination host based upon a best
effort, connection-less delivery service.
Internet Control Message Protocol. ICMP allows internet routers to
transmit error messages and test messages.
Internet Group Message Protocol. IGMP is used with multicast to
send UDP datagrams to multiple hosts.
Address Resolution Protocol. ARP translates between the 32 bit IP
address and a 48 bit LAN address.
Reverse Address Resolution Protocol. RARP translates between
the 48 bit LAN address and the 32 bit IP address.
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
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The Physical Layer 1: Ethernet
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The Link Layer 2: Ethernet Frame
Frame header
IP Datagram
FCS
12 bytes
Inter Frame Gap
Preamble, which is comprised of 56 bits of alternating 0s and 1s. The
preamble provides all the nodes on the network a signal against
which to synchronize.
Start Frame delimiter, which marks the start of a frame. The start frame delimiter is 8
bits long with the pattern10101011
Media Access Control (MAC) Address
Every Ethernet network card has, built into its hardware, a unique six-octet (48-bit)
hexadecimal number that differentiates it from all other Ethernet cards in the
universe. The DA and SA define the path across the link
Length/Type field two octets long.
If the value =< 1500 (0x05dc hex) indicates the length of data
If the value > 1500 indicates network-layer protocol : “Ethernet Types”
Data, the reason the frame exists.
MTU Maximum Transport Unit
Frame Check Sequence to protect the frame
contents
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Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
The Link Layer: Ethernet VLANs
VLANS are logical networks built over the
same physical cable plant.
Distinguishes Ethernet frames between
their logical networks using VLAN
header
VLAN is defined by the use of value 0x8100 in the Type field location.
The next two octets are composed of the following three fields:
User Priority field
This field is 3 bits in length and is used to define the priority of the Ethernet frame.
This is utilized to define and deliver a class of service
Canonical format indicator
This is 1 bit in length. Just **don’t** ask!!!
VLAN Identifier field
This field is 12 bits in length and contains the VLAN identifier (VID)
of this frame.
The original Length/Type field will then follow the inserted VLAN tag.
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The Network Layer 3: IP
IP Layer properties:
Provides best effort delivery
It is unreliable
Packet may be lost
Duplicated
Out of order
Connection less
Provides logical addresses
Provides routing
Demultiplex data on protocol number
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The Internet datagram
Frame header IP header
0
4
Vers Hlen
8
16
Type of serv.
Transport
FCS
24
19
Total length
31
Identification
Flags Fragment offset
TTL
Protocol
Header Checksum
Source IP address
Destination IP address
IP Options (if any)
20 Bytes
Padding
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IP Datagram Format (cont.)
Vers
Hlen
TOS.
Total length
Identification
Flags Fragment offset
Type of Service – TOS:
TTL
Protocol
Header Checksum
now being used for QoS
Source IP address
Destination IP address
Total length: length of datagram
IP Options (if any)
Padding
in bytes, includes header and data
Time to live – TTL: specifies how long datagram is
allowed to remain in internet
Routers decrement by 1
When TTL = 0 router discards datagram
Prevents infinite loops
Protocol: specifies the format of the data area
Protocol numbers administered by central authority to guarantee
agreement, e.g. ICMP=1, TCP=6, UDP=17 …
Source & destination IP address: (32 bits each) contain
IP address of sender and intended recipient
Options: (variable length) Mainly used to record a route,
or timestamps, or specify routing
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Internet Class-based addresses
An Address looks like 192.168.22.123
Class A: large number of hosts, few networks
0nnnnnnn hhhhhhhh hhhhhhhh hhhhhhhh
7 network bits (0 and 127 reserved, so 126 networks),
24 host bits (> 16M hosts/net)
Initial byte 1-127 (decimal)
Class B: medium number of hosts and networks
10nnnnnn nnnnnnnn hhhhhhhh hhhhhhhh
16,384 class B networks, 65,534 hosts/network
Initial byte 128-191 (decimal)
Class C: large number of small networks
110nnnnn nnnnnnnn nnnnnnnn hhhhhhhh
2,097,152 networks, 254 hosts/network
Initial byte 192-223 (decimal)
Class D: Multicast (See RFC 1112)
1110nnnn nnnnnnnn nnnnnnnn hhhhhhhh
Initial byte 224-239 (decimal)
Class E: Reserved
Initial byte 248-255 (decimal)
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The Transport Layer 4: UDP
UDP Provides :
Connection less service over IP
No setup teardown
One packet at a time
Minimal overhead – high performance
Provides best effort delivery
It is unreliable:
Packet may be lost
Duplicated
Out of order
Application is responsible for
Data reliability
Flow control
Error handling
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UDP Datagram format
Frame header IP header
0
8
Source port
UDP header
16
Application data
24
Destination port
FCS
31
8 Bytes
UDP message len Checksum (opt.)
Source/destination port: port numbers identify sending & receiving processes
Port number & IP address allow any application on Internet to be uniquely identified
Ports can be static or dynamic
Static (< 1024) assigned centrally, known as well known ports
Dynamic
Message length: in bytes includes the UDP header and data (min 8 max 65,535)
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The Transport Layer 4: TCP
TCP RFC 768 RFC 1122 Provides :
Connection orientated service over IP
During setup the two ends agree on details
Explicit teardown
Multiple connections allowed
Reliable end-to-end Byte Stream delivery over unreliable network
It takes care of:
Lost packets
Duplicated packets
Out of order packets
TCP provides
Data buffering
Flow control
Error detection & handling
Limits network congestion
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The TCP Segment Format
Frame header IP header
0
4
8
10
Source port
TCP header
Application data
24
16
FCS
31
Destination port
Sequence number
Acknowledgement number
Hlen Resv Code
Window
Checksum
Urgent ptr
Options (if any)
20 Bytes
Padding
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TCP Segment Format – cont.
Source/Dest port: TCP port numbers to ID applications
at both ends of connection
Sequence number: First byte in segment from sender’s
byte stream
Acknowledgement: identifies the number of the byte the
sender of this segment expects to receive next
Code: used to determine segment purpose, e.g. SYN,
ACK, FIN, URG
Window: Advertises how much data this station is willing
to accept. Can depend on buffer space remaining.
Source port
Destination port
Options: used for window scaling,
Sequence number
SACK, timestamps,
Acknowledgement number
maximum segment size etc.
Hlen
Resv
Code
Checksum
Options (if any)
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
Window
Urgent ptr
Padding
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The RTP Header Format
Frame header IP header UDP header RTP header Application data FCS
0
4
8
12
Ver P X CSRC M I S T VPT
16
24
31
Sequence Num.
RTP Time Stamp
12 Bytes
Synchronization Source Identifier
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
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0
4
Vers Hlen
8
16
Type of serv.
24
19
Total length
31
Identification
Flags Fragment offset
TTL
Protocol
Header Checksum
Source IP address
Destination IP address
IP Options (if any)
Padding
Summer School, Brasov, Romania, July 2005, R. Hughes-Jones Manchester
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More Information
Lectures, tutorials etc. on TCP/IP:
www.nv.cc.va.us/home/joney/tcp_ip.htm
www.cs.pdx.edu/~jrb/tcpip.lectures.html
www.raleigh.ibm.com/cgi-bin/bookmgr/BOOKS/EZ306200/CCONTENTS
www.cisco.com/univercd/cc/td/doc/product/iaabu/centri4/user/scf4ap1.htm
www.cis.ohio-state.edu/htbin/rfc/rfc1180.html
www.jbmelectronics.com/tcp.htm
Encylopaedia
http://www.freesoft.org/CIE/index.htm
TCP/IP Resources
www.private.org.il/tcpip_rl.html
Understanding IP addresses
http://www.3com.com/solutions/en_US/ncs/501302.html
Configuring TCP (RFC 1122)
ftp://nic.merit.edu/internet/documents/rfc/rfc1122.txt
Assigned protocols, ports etc (RFC 1010)
http://www.es.net/pub/rfcs/rfc1010.txt & /etc/protocols
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Any Questions?
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Backup Slides
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More Information Some URLs
UKLight web site: http://www.uklight.ac.uk
MB-NG project web site: http://www.mb-ng.net/
DataTAG project web site: http://www.datatag.org/
UDPmon / TCPmon kit + writeup:
http://www.hep.man.ac.uk/~rich/net
Motherboard and NIC Tests:
http://www.hep.man.ac.uk/~rich/net/nic/GigEth_tests_Boston.ppt
& http://datatag.web.cern.ch/datatag/pfldnet2003/
“Performance of 1 and 10 Gigabit Ethernet Cards with Server
Quality Motherboards” FGCS Special issue 2004
http:// www.hep.man.ac.uk/~rich/
TCP tuning information may be found at:
http://www.ncne.nlanr.net/documentation/faq/performance.html
& http://www.psc.edu/networking/perf_tune.html
TCP stack comparisons:
“Evaluation of Advanced TCP Stacks on Fast Long-Distance
Production Networks” Journal of Grid Computing 2004
PFLDnet http://www.ens-lyon.fr/LIP/RESO/pfldnet2005/
Dante PERT http://www.geant2.net/server/show/nav.00d00h002
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tcpdump / tcptrace
tcpdump: dump all TCP header information for a specified
source/destination
ftp://ftp.ee.lbl.gov/
tcptrace: format tcpdump output for analysis using xplot
http://www.tcptrace.org/
NLANR TCP Testrig : Nice wrapper for tcpdump and tcptrace tools
http://www.ncne.nlanr.net/TCP/testrig/
Sample use:
tcpdump -s 100 -w /tmp/tcpdump.out host hostname
tcptrace -Sl /tmp/tcpdump.out
xplot /tmp/a2b_tsg.xpl
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