# Can a TCP checksum produce a false positive? If yes, how is this dealt with?

If a TCP payload gets corrupted in transit the recomputed checksum won't match the transmitted checksum. Great, all fine so far.

If a TCP checksum gets corrupted in transit the recomputed checksum won't match the now corrupted checksum. Great, all fine so far.

What happens when both the payload and checksum get corrupted and the recomputed checksum, whilst different to what it should be, just happens to match the now corrupted checksum?

I can see with a good checksum algorithm (and additional checksums at lower levels) this might be very, very unlikely but isn't TCP meant to be 100% reliable? How does it resolve these false positives?

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Something that should be noted here, and that most people overlook completely, is the fact, that the TCP checksum is actually a very poor checksum.

The TCP checksum is a 16-bit ones-complement sum of the data. This sum will catch any burst error of 15 bits or less, and all 16-bit burst errors except for those which replace one 1’s complement zero with another (i.e., 16 adjacent 1 bits replaced by 16 zero bits, or vice-versa). Over uniformly distributed data, it is expected to detect other types of errors at a rate proportional to 1 in 2^16. The checksum also has a major limitation: the sum of a set of 16-bit values is the same, regardless of the order in which the values appear.

So if you randomly flip any number bits anywhere in the data part of the packet, the chances are 1 to 65536 that this error is not detected, even if you don't touch the checksum at all, as the new data, even though totally corrupt, has in fact the same checksum as the old one. If you just swap two 16 bit values in the data part, regardless which ones and regardless how often, the chances are even 100% that this error is not detected, since the order in which the 16 bit values appear in the data part of the packet is totally irrelevant to the value of the calculated checksum.

What I'm trying to say here is that you don't have to worry too much about the rather unlikely case that data and checksum both get corrupted and this error is not detected because the corrupted checksum matches the corrupted data, the truth is that every day millions of TCP packets on the Internet have only the data corrupted and this error is not detected because the uncorrupted checksum still matches the corrupted data.

If you need to transfer data and you want to be sure the data didn't get corrupted, the TCP checksum alone is certainly not enough for this task. I would even dare to say that a CRC checksum is not enough for this task, since a CRC32 may not detect an error where more than 32 bits in a row are affected (these errors can "cancel out" each other). The minimum checksum you'd need for ensuring flawless data transfer is the MD5 value of the data. Of course anything better than that (SHA-1, SHA-256, SHA-384, SHA-512, Whirlpool, and so on) will work even better, yet MD5 is sufficient. MD5 may not be secure enough for cryptographic security any longer (since it has been broken multiple times in the past), but as a data checksum MD5 is still absolutely sufficient.

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Assume

packet checksum: 2 byte

probability of packet with double error, one of wchich in checksum (assume P very small, less than 1/10^5):

``````A = 8P*(1000*8P) = 6*10^4 * P^2
``````

probability of exact checksum:

``````B = 1/2^16 = 6/10^4
``````

probability of false positive:

``````A * B = 40 * P^2
``````

The probability is low (P=1/10^6, then the probability of false positive A*B=4/10^11) but in any case with any crc algorithm it can't be zero. The probability of a random 1000 byte packet to appear as another random 1000 byte packet is P^8000, as if all bytes contain errors.

If P is high, for example from 1/10^3 to 1, the calculations above does not apply. In that case A=1 (all packets contain double errors) and the probability of false positive is just A*B = 6/10^4. It's not a very relevant case because more than 99% of received packets will contain errors in crc.

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No it can't be 100% reliable: this paper mentions 1 in 16 million to 10 billion packets not caught by the error control system. I'll let you calculate the occurences per day/week :)

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World traffic is about 10 to the 15 packets per day: so the chance of its happening to some of other people's packets (though not to yours) is pretty high, therefore. –  ChrisW Sep 30 '10 at 12:03
I think the only metric as to how probable it is for one person to experience it is packet-related; you're as liable to have this problem as somebody else that uses the same amount of packets. OTOH, to be noticeable you'd have to experience the failure in a critical packet; if your html or your js is mangled you frown and just reload the page, you don't whip out the post-mortem tools :) By the way, where did you find your stat? I looked around but couldn't find data about the number of packets... –  samy Sep 30 '10 at 12:16
I was just pointing out that if the error rate is one in 10 billion then it probably won't happen to you (because you don't send that many packets): but it probably will happen to someone else (because they do, collectively, send more than many packets). The first stats I found were World 7,500-12,000 PB (PetaByte = 10^15 bytes), which I divided by my guesstimate of 500 bytes per packet. –  ChrisW Sep 30 '10 at 12:22
@ChrisW Thanks for the link :) You're more conservative than i would have been regarding the packet size, though, but even by taking the max size of the packet, errors happen daily –  samy Sep 30 '10 at 12:22
Actually your number includes checks on lower levels in combination with TCP (e.g. Ethernet CRC). The TCP checksum alone has a probability of 1 in 65536 errors not being detected. That is very high. Considering that there are trillion of packets every day, the error rate of TCP all alone would still cause millions of corrupted packets a day that are not detected as the corrupted data still has the same checksum as the original one. –  Mecki Mar 27 '13 at 0:31

Can a TCP checksum produce a false positive?

Yes. The checksum is considerably smaller than the packet, so many different packets can match a given checksum.

If yes, how is this dealt with?

In TCP, not at all. However, most data corruptions will be noticeable at a higher level, e.g. your XML is no longer well-formed; your email is no longer English, etc.

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I would imagine the probability is one in a billion million zillion kajillion, because if the TCP data is corrupted, which is the transport layer, it will also mean the other layers (datalink and network) will also be corrupted. I believe at least the datalink layer has a checksum for integrity, so you'd have to have both checksums fail.

Corrupting in such a way that at least two separate checksums fail, is astronomically unlikely, maybe even impossible.

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Not all datalink layers have integrity checking though do they? –  Mr Question McQuestion Sep 30 '10 at 12:00
No, they don't. The paper i linked to above mentions the use of application-level checks in some cases –  samy Sep 30 '10 at 12:02
See academic.research.microsoft.com/Paper/22436.aspx , lower level crc might not be as reliable as you think. –  nos Sep 30 '10 at 12:13
RAM can introduce errors too. Not all problems occur in the wire (or the ether). –  curiousguy Dec 8 '11 at 20:03

and additional checksums at lower levels

Some of these are stricter than checksums, e.g. Ethernet uses a CRC instead of a checksum.

this might be very, very unlikely but isn't TCP meant to be 100% reliable? How does it resolve these false positives?

I don't think it can. Even if it sent a duplicate via hard copy and carrier pigeon, a cosmic ray or quantum effects might theoreticaly mangle the duplicate too in exactly the same way. It's just very, very unlikely.

You can also implement arbitrarily strong integrity chcking at the application layer (above TCP), e.g. using cryptographic signing.

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Whilst Ethernet has good integrity checking what about other forms of network? –  Mr Question McQuestion Sep 30 '10 at 12:01
I expect you'd want to engineer the integrity checking to match the error rate of your data link. For example PPP uses a CRC as well. –  ChrisW Sep 30 '10 at 12:06
That makes sense. For a long connection over many different data link types (ethernet, ppp, atm) I guess you'll be at the mercy of the worse component link (which might not have integrity checking at all). –  Mr Question McQuestion Sep 30 '10 at 12:15
Good point, and the use of your Data Link matters too. If it's critical, go for another layer of protection; you'll only delay the inevitable, though. If it's just transmitting throw-away data, why bother since people won't notice or refresh their query... –  samy Sep 30 '10 at 12:18
"Ethernet uses a CRC instead of a checksum." how is a CRC not a "checksum"? –  curiousguy Dec 8 '11 at 20:02