Would sending lots a small packets by UDP take more resources (cpu, compression by zlib, etc...). I read here that sending one big packet of ~65kBYTEs by UDP would probably fail so I'm thought that sending lots of smaller packets would succeed more often, but then comes the computational overhead of using more processing power (or at least thats what I'm assuming). The question is basically this; what is the best scenario for sending the maximum successful packets and keeping computation down to a minimum? Is there a specific size that works most of the time? I'm using Erlang for a server and Enet for the client (written in c++). Using Zlib compression also and I send the same packets to every client (broadcasting is the term I guess).

4 Answers 4


The maximum size of UDP payload that, most of the time, will not cause ip fragmentation is

MTU size of the host handling the PDU (most of the case it will be 1500) -
size of the IP header (20 bytes) -
size of UDP header (8 bytes)

1500 MTU - 20 IP hdr - 8 UDP hdr  = 1472 bytes

@EJP talked about 534 bytes but I would fix it to 508. This is the number of bytes that FOR SURE will not cause fragmentation, because the minimum MTU size that an host can set is 576 and IP header max size can be 60 bytes (508 = 576 MTU - 60 IP - 8 UDP)

By the way i'd try to go with 1472 bytes because 1500 is a standard-enough value.

Use 1492 instead of 1500 for calculation if you're passing through a PPPoE connection.

  • The minimum IP MTU is 576. It doesn't include Ethernet headers, so that would give 548 actually.
    – user207421
    Feb 22, 2013 at 2:05
  • You're right... i fixed the calculation considering also that IP header max size can reach 60 bytes Feb 22, 2013 at 8:17
  • Where does the number 1500 come from?
    – Evorlor
    Mar 30, 2021 at 23:59
  • these are the numbers for IPv4 ? Feb 20, 2023 at 19:28
  • Don't we need to account for ETH header?
    – Simao
    Feb 14 at 17:23

Would sending lots a small packets by UDP take more resources ?

Yes, it would, definitely! I just did an experiment with a streaming app. The app sends 2000 frames of data each second, precisely timed. The data payload for each frame is 24 bytes. I used UDP with sendto() to send this data to a listener app on another node.

What I found was interesting. This level of activity took my sending CPU to its knees! I went from having about 64% free CPU time, to having about 5%! That was disastrous for my application, so I had to fix that. I decided to experiment with variations.

First, I simply commented out the sendto() call, to see what the packet assembly overhead looked like. About a 1% hit on CPU time. Not bad. OK... must be the sendto() call!

Then, I did a quick fakeout test... I called the sendto() API only once in every 10 iterations, but I padded the data record to 10 times its previous length, to simulate the effect of assembling a collection of smaller records into a larger one, sent less often. The results were quite satisfactory: 7% CPU hit, as compared to 59% previously. It would seem that, at least on my *NIX-like system, the operation of sending a packet is costly just in the overhead of making the call.

Just in case anyone doubts whether the test was working properly, I verified all the results with Wireshark observation of the actual UDP transmissions to confirm all was working as it should.

Conclusion: it uses MUCH less CPU time to send larger packets less often, then the same amount of data in the form of smaller packets sent more frequently. Admittedly, I do not know what happens if UDP starts fragging your overly-large UDP datagram... I mean, I don't know how much CPU overhead this adds. I will try to find out (I'd like to know myself) and update this answer.

  • 1
    I've read that using sento instead of using a connected udp socket can produce some overhead because the kernel temporarily connects the socket during sendto. If you are in a unicast scenario this should not be a problem at all. Didn't tested it by myself though but would be interesting to test your scenario with a connected udp socket. Source: stackoverflow.com/a/638306/2298490
    – grill2010
    Jul 13, 2018 at 16:23

534 bytes. That is required to be transmitted without fragmentation. It can still be lost altogether of course. The overheads due to retransmission of lost packets and the network overheads themselves are several orders of magnitude more significant than any CPU cost.

  • I wonder what the direct effect on packet of fragmentation is. In my application, when I go from 508 to 509, it seems that a '\0' is appended at the end of the 2nd packet. I wonder whether it depenmds on my particular implementation or it is a trule?
    – user2881553
    Oct 29, 2013 at 6:58
  • 1
    @mavErick The trailing null comes from, or is incorrectly observed by, your code. UDP doesn't do that.
    – user207421
    Dec 16, 2013 at 11:29

You're probably using the wrong protocol. UDP is almost always a poor choice for data you care about transmitting. You wind up layering sequencing, retry, and integrity logic atop it, and then you have TCP.

  • 4
    "retry"? But I thought that was what tcp about...resending packets to get the job done. I'm doing this for an online game so tcp will most likely be too slow, or thats what everyone else says. Feb 21, 2013 at 12:58
  • 1
    "Everyone" is often wrong. If you're concerned that data might not arrive, you need TCP. Feb 21, 2013 at 15:59
  • 1
    For TCP, you don't choose the packet size. You just write bytes into one end of the socket and they come out the other. Feb 22, 2013 at 0:13
  • 19
    If on the other hand you don't care whether or not the packets arrive or what order they arrive in (i.e. most streaming data protocols) then UDP is the perfect choice. Dec 12, 2013 at 14:47
  • 5
    I used UDP for a view finder in my camera app. UDP is perfect in this case. TCP is unnecessary and slow. How many times you use TCP directly in a real life project? Not many either. HTTP is probably mostly used.
    – jack
    Jan 19, 2015 at 0:26

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