While studying the Unicode and utf-8 encoding,
I noticed that the 129th Unicode encoded by the utf-8 starts with 0xc2.
I checked the last letter of 0xcf.
No Unicode was 0xc1 encoded as 0xc1.
Why 129th unicode is start at 0xc2 instead of 0xc1?
The octet values C0, C1, F5 to FF never appear.
The reason for this is that a 1-byte UTF-8 sequence consists of the 8-bit binary pattern
0xxxxxxx (a zero followed by seven bits) and can represent Unicode code points that fit in seven bits (U+0000 to U+007F).
A 2-byte UTF-8 sequence consists of the 16-bit binary pattern
110xxxxx 10xxxxxx and can represent Unicode code points that fit in eight to eleven bits (U+0080 to U+07FF).
It is not legal in UTF-8 encoding to use more bytes that the minimum required, so while U+007F can be represented in two bytes as
11000001 10111111 (
C1 BF hex) it is more compact and therefore follows specification as the 1-byte
The first valid two-byte value is the encoding of U+0080, which is
1100010 10000000 (
C2 80 hex), so
C1 will never appear.
See section 3 UTF-8 definition in the standard. The last paragraph states:
Implementations of the decoding algorithm above MUST protect against decoding invalid sequences. For instance, a naive implementation may decode the overlong UTF-8 sequence C0 80 into the character U+0000....
UTF-8 starting with 0xc1 would be a Unicode code point in the range 0x40 to 0x7f. 0xc0 would be a Unicode code point in the range 0x00 to 0x3f.
There is an iron rule that every code point is represented in UTF-8 in the shortest possible way. Since all these code points can be stored in a single UTF-8 byte, they are not allowed to be stored using two bytes.
For the same reason you will find that there are no 4-byte codes starting with 0xf0 0x80 to 0xf0 0x8f because they are stored using fewer bytes instead.