| # Strings, bytes, runes and characters in Go |
| 23 Oct 2013 |
| Tags: strings, bytes, runes, characters |
| Summary: The [previous blog post](https://blog.golang.org/slices) explained how slices work in Go, using a number of examples to illustrate the mechanism behind their implementation. Building on that background, this post discusses strings in Go. At first, strings might seem too simple a topic for a blog post, but to use them well requires understanding not only how they work, but also the difference between a byte, a character, and a rune, the difference between Unicode and UTF-8, the difference between a string and a string literal, and other even more subtle distinctions. |
| |
| Rob Pike |
| |
| ## Introduction |
| |
| The [previous blog post](https://blog.golang.org/slices) explained how slices |
| work in Go, using a number of examples to illustrate the mechanism behind |
| their implementation. |
| Building on that background, this post discusses strings in Go. |
| At first, strings might seem too simple a topic for a blog post, but to use |
| them well requires understanding not only how they work, |
| but also the difference between a byte, a character, and a rune, |
| the difference between Unicode and UTF-8, |
| the difference between a string and a string literal, |
| and other even more subtle distinctions. |
| |
| One way to approach this topic is to think of it as an answer to the frequently |
| asked question, "When I index a Go string at position _n_, why don't I get the |
| _nth_ character?" |
| As you'll see, this question leads us to many details about how text works |
| in the modern world. |
| |
| An excellent introduction to some of these issues, independent of Go, |
| is Joel Spolsky's famous blog post, |
| [The Absolute Minimum Every Software Developer Absolutely, Positively Must Know About Unicode and Character Sets (No Excuses!)](http://www.joelonsoftware.com/articles/Unicode.html). |
| Many of the points he raises will be echoed here. |
| |
| ## What is a string? |
| |
| Let's start with some basics. |
| |
| In Go, a string is in effect a read-only slice of bytes. |
| If you're at all uncertain about what a slice of bytes is or how it works, |
| please read the [previous blog post](https://blog.golang.org/slices); |
| we'll assume here that you have. |
| |
| It's important to state right up front that a string holds _arbitrary_ bytes. |
| It is not required to hold Unicode text, UTF-8 text, or any other predefined format. |
| As far as the content of a string is concerned, it is exactly equivalent to a |
| slice of bytes. |
| |
| Here is a string literal (more about those soon) that uses the |
| `\xNN` notation to define a string constant holding some peculiar byte values. |
| (Of course, bytes range from hexadecimal values 00 through FF, inclusive.) |
| |
| .code strings/basic.go /const sample/ |
| |
| ## Printing strings |
| |
| Because some of the bytes in our sample string are not valid ASCII, not even |
| valid UTF-8, printing the string directly will produce ugly output. |
| The simple print statement |
| |
| .code strings/basic.go /println/,/println/ |
| |
| produces this mess (whose exact appearance varies with the environment): |
| |
| ��=� ⌘ |
| |
| To find out what that string really holds, we need to take it apart and examine the pieces. |
| There are several ways to do this. |
| The most obvious is to loop over its contents and pull out the bytes |
| individually, as in this `for` loop: |
| |
| .code strings/basic.go /byte loop/,/byte loop/ |
| |
| As implied up front, indexing a string accesses individual bytes, not |
| characters. We'll return to that topic in detail below. For now, let's |
| stick with just the bytes. |
| This is the output from the byte-by-byte loop: |
| |
| bd b2 3d bc 20 e2 8c 98 |
| |
| Notice how the individual bytes match the |
| hexadecimal escapes that defined the string. |
| |
| A shorter way to generate presentable output for a messy string |
| is to use the `%x` (hexadecimal) format verb of `fmt.Printf`. |
| It just dumps out the sequential bytes of the string as hexadecimal |
| digits, two per byte. |
| |
| .code strings/basic.go /percent x/,/percent x/ |
| |
| Compare its output to that above: |
| |
| bdb23dbc20e28c98 |
| |
| A nice trick is to use the "space" flag in that format, putting a |
| space between the `%` and the `x`. Compare the format string |
| used here to the one above, |
| |
| .code strings/basic.go /percent space x/,/percent space x/ |
| |
| and notice how the bytes come |
| out with spaces between, making the result a little less imposing: |
| |
| bd b2 3d bc 20 e2 8c 98 |
| |
| There's more. The `%q` (quoted) verb will escape any non-printable |
| byte sequences in a string so the output is unambiguous. |
| |
| .code strings/basic.go /percent q/,/percent q/ |
| |
| This technique is handy when much of the string is |
| intelligible as text but there are peculiarities to root out; it produces: |
| |
| "\xbd\xb2=\xbc ⌘" |
| |
| If we squint at that, we can see that buried in the noise is one ASCII equals sign, |
| along with a regular space, and at the end appears the well-known Swedish "Place of Interest" |
| symbol. |
| That symbol has Unicode value U+2318, encoded as UTF-8 by the bytes |
| after the space (hex value `20`): `e2` `8c` `98`. |
| |
| If we are unfamiliar or confused by strange values in the string, |
| we can use the "plus" flag to the `%q` verb. This flag causes the output to escape |
| not only non-printable sequences, but also any non-ASCII bytes, all |
| while interpreting UTF-8. |
| The result is that it exposes the Unicode values of properly formatted UTF-8 |
| that represents non-ASCII data in the string: |
| |
| .code strings/basic.go /percent plus q/,/percent plus q/ |
| |
| With that format, the Unicode value of the Swedish symbol shows up as a |
| `\u` escape: |
| |
| "\xbd\xb2=\xbc \u2318" |
| |
| These printing techiques are good to know when debugging |
| the contents of strings, and will be handy in the discussion that follows. |
| It's worth pointing out as well that all these methods behave exactly the |
| same for byte slices as they do for strings. |
| |
| Here's the full set of printing options we've listed, presented as |
| a complete program you can run (and edit) right in the browser: |
| |
| .play -edit strings/basic.go /package/,/^}/ |
| |
| [Exercise: Modify the examples above to use a slice of bytes |
| instead of a string. Hint: Use a conversion to create the slice.] |
| |
| [Exercise: Loop over the string using the `%q` format on each byte. |
| What does the output tell you?] |
| |
| ## UTF-8 and string literals |
| |
| As we saw, indexing a string yields its bytes, not its characters: a string is just a |
| bunch of bytes. |
| That means that when we store a character value in a string, |
| we store its byte-at-a-time representation. |
| Let's look at a more controlled example to see how that happens. |
| |
| Here's a simple program that prints a string constant with a single character |
| three different ways, once as a plain string, once as an ASCII-only quoted |
| string, and once as individual bytes in hexadecimal. |
| To avoid any confusion, we create a "raw string", enclosed by back quotes, |
| so it can contain only literal text. (Regular strings, enclosed by double |
| quotes, can contain escape sequences as we showed above.) |
| |
| .play -edit strings/utf8.go /^func/,/^}/ |
| |
| The output is: |
| |
| plain string: ⌘ |
| quoted string: "\u2318" |
| hex bytes: e2 8c 98 |
| |
| which reminds us that the Unicode character value U+2318, the "Place |
| of Interest" symbol ⌘, is represented by the bytes `e2` `8c` `98`, and |
| that those bytes are the UTF-8 encoding of the hexadecimal |
| value 2318. |
| |
| It may be obvious or it may be subtle, depending on your familiarity with |
| UTF-8, but it's worth taking a moment to explain how the UTF-8 representation |
| of the string was created. |
| The simple fact is: it was created when the source code was written. |
| |
| Source code in Go is _defined_ to be UTF-8 text; no other representation is |
| allowed. That implies that when, in the source code, we write the text |
| |
| `⌘` |
| |
| the text editor used to create the program places the UTF-8 encoding |
| of the symbol ⌘ into the source text. |
| When we print out the hexadecimal bytes, we're just dumping the |
| data the editor placed in the file. |
| |
| In short, Go source code is UTF-8, so |
| _the source code for the string literal is UTF-8 text_. |
| If that string literal contains no escape sequences, which a raw |
| string cannot, the constructed string will hold exactly the |
| source text between the quotes. |
| Thus by definition and |
| by construction the raw string will always contain a valid UTF-8 |
| representation of its contents. |
| Similarly, unless it contains UTF-8-breaking escapes like those |
| from the previous section, a regular string literal will also always |
| contain valid UTF-8. |
| |
| Some people think Go strings are always UTF-8, but they |
| are not: only string literals are UTF-8. |
| As we showed in the previous section, string _values_ can contain arbitrary |
| bytes; |
| as we showed in this one, string _literals_ always contain UTF-8 text |
| as long as they have no byte-level escapes. |
| |
| To summarize, strings can contain arbitrary bytes, but when constructed |
| from string literals, those bytes are (almost always) UTF-8. |
| |
| ## Code points, characters, and runes |
| |
| We've been very careful so far in how we use the words "byte" and "character". |
| That's partly because strings hold bytes, and partly because the idea of "character" |
| is a little hard to define. |
| The Unicode standard uses the term "code point" to refer to the item represented |
| by a single value. |
| The code point U+2318, with hexadecimal value 2318, represents the symbol ⌘. |
| (For lots more information about that code point, see |
| [its Unicode page](http://unicode.org/cldr/utility/character.jsp?a=2318).) |
| |
| To pick a more prosaic example, the Unicode code point U+0061 is the lower |
| case Latin letter 'A': a. |
| |
| But what about the lower case grave-accented letter 'A', à? |
| That's a character, and it's also a code point (U+00E0), but it has other |
| representations. |
| For example we can use the "combining" grave accent code point, U+0300, |
| and attach it to the lower case letter a, U+0061, to create the same character à. |
| In general, a character may be represented by a number of different |
| sequences of code points, and therefore different sequences of UTF-8 bytes. |
| |
| The concept of character in computing is therefore ambiguous, or at least |
| confusing, so we use it with care. |
| To make things dependable, there are _normalization_ techniques that guarantee that |
| a given character is always represented by the same code points, but that |
| subject takes us too far off the topic for now. |
| A later blog post will explain how the Go libraries address normalization. |
| |
| "Code point" is a bit of a mouthful, so Go introduces a shorter term for the |
| concept: _rune_. |
| The term appears in the libraries and source code, and means exactly |
| the same as "code point", with one interesting addition. |
| |
| The Go language defines the word `rune` as an alias for the type `int32`, so |
| programs can be clear when an integer value represents a code point. |
| Moreover, what you might think of as a character constant is called a |
| _rune constant_ in Go. |
| The type and value of the expression |
| |
| '⌘' |
| |
| is `rune` with integer value `0x2318`. |
| |
| To summarize, here are the salient points: |
| |
| - Go source code is always UTF-8. |
| - A string holds arbitrary bytes. |
| - A string literal, absent byte-level escapes, always holds valid UTF-8 sequences. |
| - Those sequences represent Unicode code points, called runes. |
| - No guarantee is made in Go that characters in strings are normalized. |
| |
| ## Range loops |
| |
| Besides the axiomatic detail that Go source code is UTF-8, |
| there's really only one way that Go treats UTF-8 specially, and that is when using |
| a `for` `range` loop on a string. |
| |
| We've seen what happens with a regular `for` loop. |
| A `for` `range` loop, by contrast, decodes one UTF-8-encoded rune on each |
| iteration. |
| Each time around the loop, the index of the loop is the starting position of the |
| current rune, measured in bytes, and the code point is its value. |
| Here's an example using yet another handy `Printf` format, `%#U`, which shows |
| the code point's Unicode value and its printed representation: |
| |
| .play -edit strings/range.go /const/,/}/ |
| |
| The output shows how each code point occupies multiple bytes: |
| |
| U+65E5 '日' starts at byte position 0 |
| U+672C '本' starts at byte position 3 |
| U+8A9E '語' starts at byte position 6 |
| |
| [Exercise: Put an invalid UTF-8 byte sequence into the string. (How?) |
| What happens to the iterations of the loop?] |
| |
| ## Libraries |
| |
| Go's standard library provides strong support for interpreting UTF-8 text. |
| If a `for` `range` loop isn't sufficient for your purposes, |
| chances are the facility you need is provided by a package in the library. |
| |
| The most important such package is |
| [`unicode/utf8`](https://golang.org/pkg/unicode/utf8/), |
| which contains |
| helper routines to validate, disassemble, and reassemble UTF-8 strings. |
| Here is a program equivalent to the `for` `range` example above, |
| but using the `DecodeRuneInString` function from that package to |
| do the work. |
| The return values from the function are the rune and its width in |
| UTF-8-encoded bytes. |
| |
| .play -edit strings/encoding.go /const/,/}/ |
| |
| Run it to see that it performs the same. |
| The `for` `range` loop and `DecodeRuneInString` are defined to produce |
| exactly the same iteration sequence. |
| |
| Look at the |
| [documentation](https://golang.org/pkg/unicode/utf8/) |
| for the `unicode/utf8` package to see what |
| other facilities it provides. |
| |
| ## Conclusion |
| |
| To answer the question posed at the beginning: Strings are built from bytes |
| so indexing them yields bytes, not characters. |
| A string might not even hold characters. |
| In fact, the definition of "character" is ambiguous and it would |
| be a mistake to try to resolve the ambiguity by defining that strings are made |
| of characters. |
| |
| There's much more to say about Unicode, UTF-8, and the world of multilingual |
| text processing, but it can wait for another post. |
| For now, we hope you have a better understanding of how Go strings behave |
| and that, although they may contain arbitrary bytes, UTF-8 is a central part |
| of their design. |