d16645c952
* Update mattermost library * Fix linting |
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doc.go | ||
eastasianwidth.go | ||
emojipresentation.go | ||
gen_breaktest.go | ||
gen_properties.go | ||
grapheme.go | ||
graphemeproperties.go | ||
graphemerules.go | ||
LICENSE.txt | ||
line.go | ||
lineproperties.go | ||
linerules.go | ||
properties.go | ||
README.md | ||
sentence.go | ||
sentenceproperties.go | ||
sentencerules.go | ||
step.go | ||
width.go | ||
word.go | ||
wordproperties.go | ||
wordrules.go |
Unicode Text Segmentation for Go
This Go package implements Unicode Text Segmentation according to Unicode Standard Annex #29, Unicode Line Breaking according to Unicode Standard Annex #14 (Unicode version 15.0.0), and monospace font string width calculation similar to wcwidth.
Background
Grapheme Clusters
In Go, strings are read-only
slices of bytes. They can be turned into Unicode code points using
the for
loop or by casting: []rune(str)
.
However, multiple code points may be combined into one user-perceived
character or what the Unicode specification calls “grapheme cluster”.
Here are some examples:
String | Bytes (UTF-8) | Code points (runes) | Grapheme clusters |
---|---|---|---|
Käse | 6 bytes: 4b 61 cc 88 73 65 |
5 code points: 4b 61 308 73 65 |
4 clusters: [4b],[61 308],[73],[65] |
🏳️🌈 | 14 bytes:
f0 9f 8f b3 ef b8 8f e2 80 8d f0 9f 8c 88 |
4 code points: 1f3f3 fe0f 200d 1f308 |
1 cluster: [1f3f3 fe0f 200d 1f308] |
🇩🇪 | 8 bytes: f0 9f 87 a9 f0 9f 87 aa |
2 code points: 1f1e9 1f1ea |
1 cluster: [1f1e9 1f1ea] |
This package provides tools to iterate over these grapheme clusters. This may be used to determine the number of user-perceived characters, to split strings in their intended places, or to extract individual characters which form a unit.
Word Boundaries
Word boundaries are used in a number of different contexts. The most familiar ones are selection (double-click mouse selection), cursor movement (“move to next word” control-arrow keys), and the dialog option “Whole Word Search” for search and replace. They are also used in database queries, to determine whether elements are within a certain number of words of one another. Searching may also use word boundaries in determining matching items. This package provides tools to determine word boundaries within strings.
Sentence Boundaries
Sentence boundaries are often used for triple-click or some other method of selecting or iterating through blocks of text that are larger than single words. They are also used to determine whether words occur within the same sentence in database queries. This package provides tools to determine sentence boundaries within strings.
Line Breaking
Line breaking, also known as word wrapping, is the process of breaking a section of text into lines such that it will fit in the available width of a page, window or other display area. This package provides tools to determine where a string may or may not be broken and where it must be broken (for example after newline characters).
Monospace Width
Most terminals or text displays / text editors using a monospace font (for example source code editors) use a fixed width for each character. Some characters such as emojis or characters found in Asian and other languages may take up more than one character cell. This package provides tools to determine the number of cells a string will take up when displayed in a monospace font. See here for more information.
Installation
go get github.com/rivo/uniseg
Examples
Counting Characters in a String
:= uniseg.GraphemeClusterCount("🇩🇪🏳️🌈")
n .Println(n)
fmt// 2
Calculating the Monospace String Width
:= uniseg.StringWidth("🇩🇪🏳️🌈!")
width .Println(width)
fmt// 5
Using the Graphemes
Class
This is the most convenient method of iterating over grapheme clusters:
:= uniseg.NewGraphemes("👍🏼!")
gr for gr.Next() {
.Printf("%x ", gr.Runes())
fmt}
// [1f44d 1f3fc] [21]
Using the Step
or StepString
Function
This avoids allocating a new Graphemes
object but it
requires the handling of states and boundaries:
:= "🇩🇪🏳️🌈"
str := -1
state var c string
for len(str) > 0 {
, str, _, state = uniseg.StepString(str, state)
c.Printf("%x ", []rune(c))
fmt}
// [1f1e9 1f1ea] [1f3f3 fe0f 200d 1f308]
Advanced Examples
The Graphemes
class offers the most convenient way to access all functionality of this
package. But in some cases, it may be better to use the specialized
functions directly. For example, if you’re only interested in word
segmentation, use FirstWord
or FirstWordInString
:
:= "Hello, world!"
str := -1
state var c string
for len(str) > 0 {
, str, state = uniseg.FirstWordInString(str, state)
c.Printf("(%s)\n", c)
fmt}
// (Hello)
// (,)
// ( )
// (world)
// (!)
Similarly, use
FirstGraphemeCluster
orFirstGraphemeClusterInString
for grapheme cluster determination only,FirstSentence
orFirstSentenceInString
for sentence segmentation only, andFirstLineSegment
orFirstLineSegmentInString
for line breaking / word wrapping (although usingStep
orStepString
is preferred as it will observe grapheme cluster boundaries).
If you’re only interested in the width of characters, use FirstGraphemeCluster
or FirstGraphemeClusterInString
.
It is much faster than using Step
,
StepString
,
or the Graphemes
class because it does not include the logic for word / sentence / line
boundaries.
Finally, if you need to reverse a string while preserving grapheme
clusters, use ReverseString
:
.Println(uniseg.ReverseString("🇩🇪🏳️🌈"))
fmt// 🏳️🌈🇩🇪
Documentation
Refer to https://pkg.go.dev/github.com/rivo/uniseg for the package’s documentation.
Dependencies
This package does not depend on any packages outside the standard library.
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Add your issue here on GitHub, preferably before submitting any PR’s. Feel free to get in touch if you have any questions.