# How is a 1s complement checksum useful for error detection?

A checksum can be generated simply by adding bits. How is the extra step of taking the 1s complement useful?

I understand the theory. I know how to calculate 1s complement and I know about how adding the complements makes the result all 1s.

I would like to see a simple example of how an error is detected.

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C program implimentation to demonstrate Checksum bit for finding error –  ARJUN Sep 19 at 12:44

I believe the example you're looking for can be found here.

http://en.wikibooks.org/wiki/Computer_Networks/UDP#Checksum_Calculation

The reason we do 1's complement is that when the 1's complement is added to the sum of all the values, and the result is trimmed to the bit-length of the machine (16 bits in the example above), it is all 1's. CPUs have a feature to take 1's complement of numbers, and taking the 1's complement of all-1 is all-0.

The reason: CPUs hate to work with bits except in chunks of however many it normally use. So adding two 64-bit numbers may take 1 cycle, but checking all the bits of that number individually will take many more (in a naive loop, perhaps as high as 8x64 cycles). CPUs also have capability to trivially take 1's complements, and detect that the result of the last calculation was zero without inspecting individual bits and branch based on that. So basically, it's an optimization that lets us check checksums really fast. Since most packets are just fine, this lets us check the checksum on the fly and get the data to the destination much faster.

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Using mod-65535 has a couple of other advantages: (1) changes in the upper bits of some input terms can percolate into the lower bits of the checksum; (2) such calculations are byte-order independent. For example, 0xFF00 + 0xFF00 + 0x01FE sum correctly, as do 0x00FF, 0xFF, and 0xFE01 (swapping the upper and lower bytes of each word). –  supercat Aug 26 '11 at 17:41

By "adding bits" I assume you mean calculating parity bits. According to this Wikipedia entry on checksums, for a parity checksum "the probability of a two-bit error being undetected is 1/n" while with a modular sum (such as 1s complement) "the probability that a two-bit error will go undetected is a little less than 1/n."

This "Ask Dr. Math" column discusses how to calculate 1s complement (most commonly for TCP/IP).

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I know about 1s complement and how adding the complement makes everything 1s, and that's how errors are detected. However, I don't understand how it's helpful because you're just manipulating numbers. Can you show an actual example? –  node ninja Apr 9 '11 at 23:10

Checksum is very important for networking as partickmdnet mentioned. Basically, for every datagram transmitted in the IP protocol, there is a checksum that was computed ahead of time and transmitted. If even one bit is corrupted and sent incorrectly in the data portion of the datagram, then the checksum computed at the receiving router will be different than that provided with the datagram. This tells the router that the datagram is corrupted (either the data or the checksum portion itself) and the router will discard the datagram.

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