Base32
Base32 is one of several base 32 transfer encodings using a 32-character subset of the twenty-six letters A–Z and six digits 2–7.
Primarily Base32 is used to encode binary data, but is able to encode binary text like ASCII.
Software
Base32 is a notation for encoding arbitrary byte data using a restricted set of symbols that can be conveniently used by humans and processed by computers.
Base32 consists of a symbol set made up of 32 different characters, as well as an algorithm for encoding arbitrary sequences of 8-bit bytes into the Base32 alphabet. Because more than one 5-bit Base32 symbol is needed to represent each 8-bit input byte, it also specifies requirements on the allowed lengths of Base32 strings (which must be multiples of 40 bits). The closely related Base64 system, in contrast, uses a set of 64 symbols.
Base32 implementations in C/C++,[1] Perl,[2] Java,[3] Python[4] and Ruby[5] are available.
Advantages
Base32 has a number of advantages over Base64:
- The resulting character set is all one case, which can often be beneficial when using a case-insensitive filesystem, spoken language, or human memory.
- The result can be used as a file name because it can not possibly contain the '/' symbol, which is the Unix path separator.
- The alphabet can be selected to avoid similar-looking pairs of different symbols, so the strings can be accurately transcribed by hand. (For example, the RFC 4648 symbol set omits the digits for one, eight and zero, since they could be confused with the letters 'I', 'B', and 'O'.)
- A result excluding padding can be included in a URL without encoding any characters.
Base32 also has advantages over hexadecimal/Base16:
- Base32 representation takes roughly 20% less space. (1000 bits takes 200 characters, compared to 250 for Base16)
Disadvantages
Base32 representation takes roughly 20% more space than Base64. Also, because it encodes 5 bytes to 8 characters (rather than 3 bytes to 4 characters), padding to an 8-character boundary is a greater burden on short messages.
Base64 | Base32 | |
---|---|---|
8-bit | 133% | 160% |
7-bit | 117% | 140% |
RFC 4648 Base32 alphabet
The most widely used Base32 alphabet is defined in RFC 4648. It uses an alphabet of A–Z, followed by 2–7. 0 and 1 are skipped due to their similarity with the letters O and I (thus "2" actually has a decimal value of 26).
In some circumstances padding is not required or used (the padding can be inferred from the length of the string modulo 8). RFC 4648 states that padding must be used unless the specification of the standard referring to the RFC explicitly states otherwise. Excluding padding is useful when using base32 encoded data in URL tokens or file names where the padding character could pose a problem.
Value | Symbol | Value | Symbol | Value | Symbol | Value | Symbol | |||
---|---|---|---|---|---|---|---|---|---|---|
0 | A | 9 | J | 18 | S | 27 | 3 | |||
1 | B | 10 | K | 19 | T | 28 | 4 | |||
2 | C | 11 | L | 20 | U | 29 | 5 | |||
3 | D | 12 | M | 21 | V | 30 | 6 | |||
4 | E | 13 | N | 22 | W | 31 | 7 | |||
5 | F | 14 | O | 23 | X | |||||
6 | G | 15 | P | 24 | Y | |||||
7 | H | 16 | Q | 25 | Z | |||||
8 | I | 17 | R | 26 | 2 | pad | = |
Alternative versions
z-base-32
z-base-32 is a Base32 encoding designed to be easier for human use and more compact. It includes 1, 8 and 9 but excludes l, v and 2. It also permutes the alphabet so that the easier characters are the ones that occur more frequently. It compactly encodes bitstrings whose length in bits is not a multiple of 8, and omits trailing padding characters. z-base-32 was used in the Mnet open source project, and is currently used in Phil Zimmermann's ZRTP protocol, and in the Tahoe-LAFS open source project.
Value | Symbol | Value | Symbol | Value | Symbol | Value | Symbol | |||
---|---|---|---|---|---|---|---|---|---|---|
0 | y | 8 | e | 16 | o | 24 | a | |||
1 | b | 9 | j | 17 | t | 25 | 3 | |||
2 | n | 10 | k | 18 | 1 | 26 | 4 | |||
3 | d | 11 | m | 19 | u | 27 | 5 | |||
4 | r | 12 | c | 20 | w | 28 | h | |||
5 | f | 13 | p | 21 | i | 29 | 7 | |||
6 | g | 14 | q | 22 | s | 30 | 6 | |||
7 | 8 | 15 | x | 23 | z | 31 | 9 |
Crockford's Base32
Another alternative design for Base32 is created by Douglas Crockford, who proposes using additional characters for a checksum.[1] It excludes the letters I, L, and O to avoid confusion with digits. It also excludes the letter U to reduce the likelihood of accidental obscenity.
Libraries to encode binary data in Crockford's Base32 are available in a variety of languages.[6][7][8][9][10]
Value | Encode Digit | Decode Digit | Value | Encode Digit | Decode Digit | |
---|---|---|---|---|---|---|
0 | 0 | 0 o O | 16 | G | g G | |
1 | 1 | 1 i I l L | 17 | H | h H | |
2 | 2 | 2 | 18 | J | j J | |
3 | 3 | 3 | 19 | K | k K | |
4 | 4 | 4 | 20 | M | m M | |
5 | 5 | 5 | 21 | N | n N | |
6 | 6 | 6 | 22 | P | p P | |
7 | 7 | 7 | 23 | Q | q Q | |
8 | 8 | 8 | 24 | R | r R | |
9 | 9 | 9 | 25 | S | s S | |
10 | A | a A | 26 | T | t T | |
11 | B | b B | 27 | V | v V | |
12 | C | c C | 28 | W | w W | |
13 | D | d D | 29 | X | x X | |
14 | E | e E | 30 | Y | y Y | |
15 | F | f F | 31 | Z | z Z |
Electrologica
An earlier form of base 32 notation was used by programmers working on the Electrologica X1 to represent machine addresses. The "digits" were represented as decimal numbers from 0 to 31. For example, 12-16 would represent the machine address 400 (= 12*32 + 16).
base32hex
Triacontakaidecimal is another alternative design for Base 32, that extends hexadecimal in a more natural way. First proposed by Christian Lanctot, a programmer working at Sage software, in a letter to Dr. Dobb's magazine in March 1999 as a proposed solution for solving the Y2K bug and referred to as "Double Hex". RFC 4648 uses base32hex as name for this encoding deployed in RFC 2938.
Unlike many other base 32 notation systems, triacontakaidecimal is contiguous and includes characters that may visually conflict. With the right font it is possible to visually distinguish between 0, O and 1, I. Other fonts are unsuitable because the context that English usually provides is not provided by a notation system that is expressing numbers. However, the choice of font is not controlled by notation or encoding which is why it's risky to assume a distinguishable font will be used.
Value | Symbol | Value | Symbol | Value | Symbol | Value | Symbol | |||
---|---|---|---|---|---|---|---|---|---|---|
0 | 0 | 9 | 9 | 18 | I | 27 | R | |||
1 | 1 | 10 | A | 19 | J | 28 | S | |||
2 | 2 | 11 | B | 20 | K | 29 | T | |||
3 | 3 | 12 | C | 21 | L | 30 | U | |||
4 | 4 | 13 | D | 22 | M | 31 | V | |||
5 | 5 | 14 | E | 23 | N | |||||
6 | 6 | 15 | F | 24 | O | |||||
7 | 7 | 16 | G | 25 | P | |||||
8 | 8 | 17 | H | 26 | Q | pad | = |
Video games
Before NVRAM became universal, several video games for Nintendo platforms used base 32 numbers for passwords. These systems, like Natural Area Code, omit vowels to prevent the game from accidentally giving a profane password. Thus, the characters are generally some minor variation of the following set: 0–9, B, C, D, F, G, H, J, K, L, M, N, P, Q, R, S, T, V, W, X, Y, Z, and some punctuation marks. Games known to use such a system include Mario Is Missing!, Mario's Time Machine, Tetris Blast, and The Lord of the Rings (Super NES).
See also
- Ascii85 (also called Base85)
- Base64
- Base58
- Base16
- Binary-to-text encoding for a comparison of various encoding algorithms
- Geohash
References
- ^ http://sourceforge.net/projects/cyoencode/
- ^ "Archived copy". Archived from the original on 2015-11-17. Retrieved 2015-11-13.
{{cite web}}
: Unknown parameter|deadurl=
ignored (|url-status=
suggested) (help)CS1 maint: archived copy as title (link) - ^ https://commons.apache.org/proper/commons-codec/apidocs/org/apache/commons/codec/binary/Base32.html
- ^ https://docs.python.org/2/library/base64.html
- ^ https://rubygems.org/gems/base32
- ^ "Crockford Base32 Encoder".
- ^ "Base32::Crockford"[permanent dead link]
- ^ "The crockford package"
- ^ "A Python implementation of Douglas Crockford's base32 encoding scheme".
- ^ "Python base32-crockford"
- RFC 4648