From "Signed Types" on Encoding - Protocol Buffers - Google Code:

ZigZag encoding maps signed integers to unsigned integers so that numbers with a small absolute value (for instance, -1) have a small varint encoded value too. It does this in a way that "zig-zags" back and forth through the positive and negative integers, so that -1 is encoded as 1, 1 is encoded as 2, -2 is encoded as 3, and so on, as you can see in the following table:

`Signed Original Encoded As 0 0 -1 1 1 2 -2 3 2147483647 4294967294 -2147483648 4294967295`

In other words, each value n is encoded using

`(n << 1) ^ (n >> 31)`

for sint32s, or

`(n << 1) ^ (n >> 63)`

for the 64-bit version.

How does `(n << 1) ^ (n >> 31)`

equal whats in the table? I understand that would work for positives, but how does that work for say, -1? Wouldn't -1 be `1111 1111`

, and `(n << 1)`

be `1111 1110`

? (Is bit-shifting on negatives well formed in any language?)

Nonetheless, using the fomula and doing `(-1 << 1) ^ (-1 >> 31)`

, assuming a 32-bit int, I get `1111 1111`

, which is 4 billion, whereas the table thinks I should have 1.