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I have two debian servers located on the same subnet. They are connected by a switch. I am aware the UDP is unreliable.

Question 1: I assume the link layer is ethernet. And MTU from a standard Ethernet is 1500 bytes. However, when I did a ping from one server to another, I found out that the maximum packet size can be sent is 65507. Shouldn't it be 1500 bytes? Can I say, because there's no router in between these two servers, therefore, the IP datagram will not be fragmented.

Question 2: Because two servers are directly connected with a switch, can I assume that all datagrams arrives in order and no loss on the path?

Question 3: How can I determine that the chances of datagram dropped at the server because of buffer overflow. What size to set the receive buffer so that datagram will not overflow receive buffer.

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This isn't a programming question. Perhaps you should check out serverfault.com –  Jim Miller Dec 17 '11 at 22:12
    
You can't 'prove it's reliable in [your] situation', because it isn't. –  EJP Dec 17 '11 at 23:39

4 Answers 4

up vote 4 down vote accepted

No. UDP is not even reliable between processes on the same machine. If packets are sent to a socket without giving the receiver process time to read them, the buffer will overflow and packets will be lost.

  1. You did your ping test with fragmentation enabled. Besides that, ping doesn't use UDP, but ICMP, so the results mean nothing. UDP packets smaller than the MTU will not be fragmented, but the MTU depends on more factors, such as IP options and VLAN headers, so it may not be greater than 1500.

  2. No. Switches perform buffering, and it's possible for the internal buffers to overflow. Consider a 24 port switch where 23 nodes are all transmitting as fast as possible to the last node. Clearly the connection to the last node cannot handle the aggregate traffic of 23 other links, the switch will try to buffer packets but eventually end up dropping them.

    Besides that, electrical noise can corrupt packets in transit, causing them to be discarded when the checksum fails.

  3. To analyze the chance of buffer overflow, you could employ queuing theory to find the probability that a packet arrives when the buffer is full. You'll need some assumptions regarding the probability distribution on the rate of packet transmission and the processing time. The number of packets in the buffer then form a finite chain, hopefully Markov, which you can solve for the steady-state probabilities of each state in the chain. Good search keywords to find out more would be "queuing theory", "Markov chain", "call capacity", "circuit capacity", "load factor".


EDIT: You changed the title of the question. The answer to your new question is: "You can't prove something that isn't true." If you want to make a reliable application using UDP, you should add your own acknowledgement and loss handling logic.

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Could you give me some reference by saying "UDP is not even reliable between processes on the same machine." And if I set the receiver a multiplier of the sender buffer, can I say the chances of end side buffer overflow is minimum. –  Kevin Q Dec 17 '11 at 23:03
    
@KevinQ (a) UDP is unreliable period. You don't need a reference saying it is unreliable in a specific stuation. (b) No. –  EJP Dec 17 '11 at 23:43

The 64 KB maximum packet size is the absolute limit of the protocol, as opposed to the 1500 byte MTU you may have configured (the MTU can be changed easily, the 64 KB limit cannot).

In practice you will probably never see reordered datagrams in your scenario. And you'll probably only lose them if the receiving side is not processing them fast enough (or is shut off completely).

The "chances" of a datagram being dropped by the receiver is not something we can really quantify without knowing a whole lot more about your situation. If the receiver processes datagrams faster than the sender sends them, you're fine, otherwise you may lose some--know how many and exactly when is a considerably finer point.

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64 KB is 64 kilobytes > 1500 byte. And where do you get the 64 KB from? –  Kevin Q Dec 17 '11 at 22:32
    
@Kevin: From IPv4, which has a fragment offset field that maxes out at 64k. –  Ben Voigt Dec 18 '11 at 2:30
    
@BenVoigt The maximum size of an IPv4 datagram is 65535-28=65507 bytes. –  EJP Dec 18 '11 at 8:53
    
@EJP: Are you sure? The last fragment should be able to get all the way to 64k (theoretically it could even go beyond, but I believe the spec forbids that). –  Ben Voigt Dec 18 '11 at 19:41
    
@BenVoigt You're forgetting about the IP header (20 bytes) and the UDP header (8 bytes). –  EJP Dec 18 '11 at 20:40
  1. The IP stack will fragment and defragment the packet for you. You can test this by setting the the no-fragment flag. The packet will be dropped.

  2. No. They will most likely come in order, and probably not dropped, but the network stack, in your sender, router and receiver, are free to drop the packet if it can't handle it when it arrives. Also remember that when a large packet is fragmented, one lost fragment means that the whole packet will be dropped by the stack.

  3. I guess you can probe by sending 1000 packets and measure loss, but historical values does not predict the future...

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Question 1: You are confusing the MTU with the tcp maximum packet size see here

Question 2: Two servers connected via a switch does not guarantee datagrams arriving in order. There will be other network transmissions occurring that will interfere with the udp stream potentially causing out of sequence frames

Question 3: Answered by Ben Voigt above.

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TCP has nothing to do with it. –  Ben Voigt Dec 18 '11 at 2:32

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