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std.uni

The std.uni module provides an implementation of fundamental Unicode algorithms and data structures. This doesn't include UTF encoding and decoding primitives, see std.utf.decode and std.utf.encode in std.utf for this functionality.

Category Functions
Decode byCodePoint byGrapheme decodeGrapheme graphemeStride
Comparison icmp sicmp
Classification isAlpha isAlphaNum isCodepointSet isControl isFormat isGraphical isIntegralPair isMark isNonCharacter isNumber isPrivateUse isPunctuation isSpace isSurrogate isSurrogateHi isSurrogateLo isSymbol isWhite
Normalization NFC NFD NFKD NormalizationForm normalize
Decompose decompose decomposeHangul UnicodeDecomposition
Compose compose composeJamo
Sets CodepointInterval CodepointSet InversionList unicode
Trie codepointSetTrie CodepointSetTrie codepointTrie CodepointTrie toTrie toDelegate
Casing asCapitalized asLowerCase asUpperCase isLower isUpper toLower toLowerInPlace toUpper toUpperInPlace
Utf8Matcher isUtfMatcher MatcherConcept utfMatcher
Separators lineSep nelSep paraSep
Building blocks allowedIn combiningClass Grapheme

All primitives listed operate on Unicode characters and sets of characters. For functions which operate on ASCII characters and ignore Unicode characters, see std.ascii. For definitions of Unicode character, code point and other terms used throughout this module see the terminology section below.

The focus of this module is the core needs of developing Unicode-aware applications. To that effect it provides the following optimized primitives:

It's recognized that an application may need further enhancements and extensions, such as less commonly known algorithms, or tailoring existing ones for region specific needs. To help users with building any extra functionality beyond the core primitives, the module provides:

  • CodepointSet, a type for easy manipulation of sets of characters. Besides the typical set algebra it provides an unusual feature: a D source code generator for detection of code points in this set. This is a boon for meta-programming parser frameworks, and is used internally to power classification in small sets like isWhite.
  • A way to construct optimal packed multi-stage tables also known as a special case of Trie. The functions codepointTrie, codepointSetTrie construct custom tries that map dchar to value. The end result is a fast and predictable Ο(1) lookup that powers functions like isAlpha and combiningClass, but for user-defined data sets.
  • A useful technique for Unicode-aware parsers that perform character classification of encoded code points is to avoid unnecassary decoding at all costs. utfMatcher provides an improvement over the usual workflow of decode-classify-process, combining the decoding and classification steps. By extracting necessary bits directly from encoded code units matchers achieve significant performance improvements. See MatcherConcept for the common interface of UTF matchers.
  • Generally useful building blocks for customized normalization: combiningClass for querying combining class and allowedIn for testing the Quick_Check property of a given normalization form.
  • Access to a large selection of commonly used sets of code points. Supported sets include Script, Block and General Category. The exact contents of a set can be observed in the CLDR utility, on the property index page of the Unicode website. See unicode for easy and (optionally) compile-time checked set queries.

Synopsis

import std.uni;
void main()
{
    // initialize code point sets using script/block or property name
    // now 'set' contains code points from both scripts.
    auto set = unicode("Cyrillic") | unicode("Armenian");
    // same thing but simpler and checked at compile-time
    auto ascii = unicode.ASCII;
    auto currency = unicode.Currency_Symbol;

    // easy set ops
    auto a = set & ascii;
    assert(a.empty); // as it has no intersection with ascii
    a = set | ascii;
    auto b = currency - a; // subtract all ASCII, Cyrillic and Armenian

    // some properties of code point sets
    assert(b.length > 45); // 46 items in Unicode 6.1, even more in 6.2
    // testing presence of a code point in a set
    // is just fine, it is O(logN)
    assert(!b['$']);
    assert(!b['\u058F']); // Armenian dram sign
    assert(b['¥']);

    // building fast lookup tables, these guarantee O(1) complexity
    // 1-level Trie lookup table essentially a huge bit-set ~262Kb
    auto oneTrie = toTrie!1(b);
    // 2-level far more compact but typically slightly slower
    auto twoTrie = toTrie!2(b);
    // 3-level even smaller, and a bit slower yet
    auto threeTrie = toTrie!3(b);
    assert(oneTrie['£']);
    assert(twoTrie['£']);
    assert(threeTrie['£']);

    // build the trie with the most sensible trie level
    // and bind it as a functor
    auto cyrillicOrArmenian = toDelegate(set);
    auto balance = find!(cyrillicOrArmenian)("Hello ընկեր!");
    assert(balance == "ընկեր!");
    // compatible with bool delegate(dchar)
    bool delegate(dchar) bindIt = cyrillicOrArmenian;

    // Normalization
    string s = "Plain ascii (and not only), is always normalized!";
    assert(s is normalize(s));// is the same string

    string nonS = "A\u0308ffin"; // A ligature
    auto nS = normalize(nonS); // to NFC, the W3C endorsed standard
    assert(nS == "Äffin");
    assert(nS != nonS);
    string composed = "Äffin";

    assert(normalize!NFD(composed) == "A\u0308ffin");
    // to NFKD, compatibility decomposition useful for fuzzy matching/searching
    assert(normalize!NFKD("2¹⁰") == "210");
}

Terminology

The following is a list of important Unicode notions and definitions. Any conventions used specifically in this module alone are marked as such. The descriptions are based on the formal definition as found in chapter three of The Unicode Standard Core Specification.

Abstract character
A unit of information used for the organization, control, or representation of textual data. Note that:
  • When representing data, the nature of that data is generally symbolic as opposed to some other kind of data (for example, visual).
  • An abstract character has no concrete form and should not be confused with a glyph.
  • An abstract character does not necessarily correspond to what a user thinks of as a “character” and should not be confused with a Grapheme.
  • The abstract characters encoded (see Encoded character) are known as Unicode abstract characters.
  • Abstract characters not directly encoded by the Unicode Standard can often be represented by the use of combining character sequences.

Canonical decomposition
The decomposition of a character or character sequence that results from recursively applying the canonical mappings found in the Unicode Character Database and these described in Conjoining Jamo Behavior (section 12 of Unicode Conformance).

Canonical composition
The precise definition of the Canonical composition is the algorithm as specified in Unicode Conformance section 11. Informally it's the process that does the reverse of the canonical decomposition with the addition of certain rules that e.g. prevent legacy characters from appearing in the composed result.

Canonical equivalent
Two character sequences are said to be canonical equivalents if their full canonical decompositions are identical.

Character
Typically differs by context. For the purpose of this documentation the term character implies encoded character, that is, a code point having an assigned abstract character (a symbolic meaning).

Code point
Any value in the Unicode codespace; that is, the range of integers from 0 to 10FFFF (hex). Not all code points are assigned to encoded characters.

Code unit
The minimal bit combination that can represent a unit of encoded text for processing or interchange. Depending on the encoding this could be: 8-bit code units in the UTF-8 (char), 16-bit code units in the UTF-16 (wchar), and 32-bit code units in the UTF-32 (dchar). Note that in UTF-32, a code unit is a code point and is represented by the D dchar type.

Combining character
A character with the General Category of Combining Mark(M).
  • All characters with non-zero canonical combining class are combining characters, but the reverse is not the case: there are combining characters with a zero combining class.
  • These characters are not normally used in isolation unless they are being described. They include such characters as accents, diacritics, Hebrew points, Arabic vowel signs, and Indic matras.

Combining class
A numerical value used by the Unicode Canonical Ordering Algorithm to determine which sequences of combining marks are to be considered canonically equivalent and which are not.

Compatibility decomposition
The decomposition of a character or character sequence that results from recursively applying both the compatibility mappings and the canonical mappings found in the Unicode Character Database, and those described in Conjoining Jamo Behavior no characters can be further decomposed.

Compatibility equivalent
Two character sequences are said to be compatibility equivalents if their full compatibility decompositions are identical.

Encoded character
An association (or mapping) between an abstract character and a code point.

Glyph
The actual, concrete image of a glyph representation having been rasterized or otherwise imaged onto some display surface.

Grapheme base
A character with the property Grapheme_Base, or any standard Korean syllable block.

Grapheme cluster
Defined as the text between grapheme boundaries as specified by Unicode Standard Annex #29, Unicode text segmentation. Important general properties of a grapheme:
  • The grapheme cluster represents a horizontally segmentable unit of text, consisting of some grapheme base (which may consist of a Korean syllable) together with any number of nonspacing marks applied to it.
  • A grapheme cluster typically starts with a grapheme base and then extends across any subsequent sequence of nonspacing marks. A grapheme cluster is most directly relevant to text rendering and processes such as cursor placement and text selection in editing, but may also be relevant to comparison and searching.
  • For many processes, a grapheme cluster behaves as if it was a single character with the same properties as its grapheme base. Effectively, nonspacing marks apply graphically to the base, but do not change its properties.

This module defines a number of primitives that work with graphemes: Grapheme, decodeGrapheme and graphemeStride. All of them are using extended grapheme boundaries as defined in the aforementioned standard annex.

Nonspacing mark
A combining character with the General Category of Nonspacing Mark (Mn) or Enclosing Mark (Me).

Spacing mark
A combining character that is not a nonspacing mark.

Normalization

The concepts of canonical equivalent or compatibility equivalent characters in the Unicode Standard make it necessary to have a full, formal definition of equivalence for Unicode strings. String equivalence is determined by a process called normalization, whereby strings are converted into forms which are compared directly for identity. This is the primary goal of the normalization process, see the function normalize to convert into any of the four defined forms.

A very important attribute of the Unicode Normalization Forms is that they must remain stable between versions of the Unicode Standard. A Unicode string normalized to a particular Unicode Normalization Form in one version of the standard is guaranteed to remain in that Normalization Form for implementations of future versions of the standard.

The Unicode Standard specifies four normalization forms. Informally, two of these forms are defined by maximal decomposition of equivalent sequences, and two of these forms are defined by maximal composition of equivalent sequences.

The choice of the normalization form depends on the particular use case. NFC is the best form for general text, since it's more compatible with strings converted from legacy encodings. NFKC is the preferred form for identifiers, especially where there are security concerns. NFD and NFKD are the most useful for internal processing.

Construction of lookup tables

The Unicode standard describes a set of algorithms that depend on having the ability to quickly look up various properties of a code point. Given the the codespace of about 1 million code points, it is not a trivial task to provide a space-efficient solution for the multitude of properties.

Common approaches such as hash-tables or binary search over sorted code point intervals (as in InversionList) are insufficient. Hash-tables have enormous memory footprint and binary search over intervals is not fast enough for some heavy-duty algorithms.

The recommended solution (see Unicode Implementation Guidelines) is using multi-stage tables that are an implementation of the Trie data structure with integer keys and a fixed number of stages. For the remainder of the section this will be called a fixed trie. The following describes a particular implementation that is aimed for the speed of access at the expense of ideal size savings.

Taking a 2-level Trie as an example the principle of operation is as follows. Split the number of bits in a key (code point, 21 bits) into 2 components (e.g. 15 and 8). The first is the number of bits in the index of the trie and the other is number of bits in each page of the trie. The layout of the trie is then an array of size 2^^bits-of-index followed an array of memory chunks of size 2^^bits-of-page/bits-per-element.

The number of pages is variable (but not less then 1) unlike the number of entries in the index. The slots of the index all have to contain a number of a page that is present. The lookup is then just a couple of operations - slice the upper bits, lookup an index for these, take a page at this index and use the lower bits as an offset within this page.

Assuming that pages are laid out consequently in one array at pages, the pseudo-code is:

auto elemsPerPage = (2 ^^ bits_per_page) / Value.sizeOfInBits;
pages[index[n >> bits_per_page]][n & (elemsPerPage - 1)];

Where if elemsPerPage is a power of 2 the whole process is a handful of simple instructions and 2 array reads. Subsequent levels of the trie are introduced by recursing on this notion - the index array is treated as values. The number of bits in index is then again split into 2 parts, with pages over 'current-index' and the new 'upper-index'.

For completeness a level 1 trie is simply an array. The current implementation takes advantage of bit-packing values when the range is known to be limited in advance (such as bool). See also BitPacked for enforcing it manually. The major size advantage however comes from the fact that multiple identical pages on every level are merged by construction.

The process of constructing a trie is more involved and is hidden from the user in a form of the convenience functions codepointTrie, codepointSetTrie and the even more convenient toTrie. In general a set or built-in AA with dchar type can be turned into a trie. The trie object in this module is read-only (immutable); it's effectively frozen after construction.

Unicode properties

This is a full list of Unicode properties accessible through unicode with specific helpers per category nested within. Consult the CLDR utility when in doubt about the contents of a particular set.

General category sets listed below are only accessible with the unicode shorthand accessor.

General category
Abb. Long form Abb. Long formAbb. Long form
L Letter Cn Unassigned Po Other_Punctuation
Ll Lowercase_Letter Co Private_Use Ps Open_Punctuation
Lm Modifier_Letter Cs Surrogate S Symbol
Lo Other_Letter N Number Sc Currency_Symbol
Lt Titlecase_Letter Nd Decimal_Number Sk Modifier_Symbol
Lu Uppercase_Letter Nl Letter_Number Sm Math_Symbol
M Mark No Other_Number So Other_Symbol
Mc Spacing_Mark P Punctuation Z Separator
Me Enclosing_Mark Pc Connector_Punctuation Zl Line_Separator
Mn Nonspacing_Mark Pd Dash_Punctuation Zp Paragraph_Separator
C Other Pe Close_Punctuation Zs Space_Separator
Cc Control Pf Final_Punctuation - Any
Cf Format Pi Initial_Punctuation - ASCII

Sets for other commonly useful properties that are accessible with unicode:

Common binary properties
Name Name Name
Alphabetic Ideographic Other_Uppercase
ASCII_Hex_Digit IDS_Binary_Operator Pattern_Syntax
Bidi_Control ID_Start Pattern_White_Space
Cased IDS_Trinary_Operator Quotation_Mark
Case_Ignorable Join_Control Radical
Dash Logical_Order_Exception Soft_Dotted
Default_Ignorable_Code_Point Lowercase STerm
Deprecated Math Terminal_Punctuation
Diacritic Noncharacter_Code_Point Unified_Ideograph
Extender Other_Alphabetic Uppercase
Grapheme_Base Other_Default_Ignorable_Code_Point Variation_Selector
Grapheme_Extend Other_Grapheme_Extend White_Space
Grapheme_Link Other_ID_Continue XID_Continue
Hex_Digit Other_ID_Start XID_Start
Hyphen Other_Lowercase
ID_Continue Other_Math

Below is the table with block names accepted by unicode.block. Note that the shorthand version unicode requires "In" to be prepended to the names of blocks so as to disambiguate scripts and blocks.

Blocks
Aegean Numbers Ethiopic Extended Mongolian
Alchemical Symbols Ethiopic Extended-A Musical Symbols
Alphabetic Presentation Forms Ethiopic Supplement Myanmar
Ancient Greek Musical Notation General Punctuation Myanmar Extended-A
Ancient Greek Numbers Geometric Shapes New Tai Lue
Ancient Symbols Georgian NKo
Arabic Georgian Supplement Number Forms
Arabic Extended-A Glagolitic Ogham
Arabic Mathematical Alphabetic Symbols Gothic Ol Chiki
Arabic Presentation Forms-A Greek and Coptic Old Italic
Arabic Presentation Forms-B Greek Extended Old Persian
Arabic Supplement Gujarati Old South Arabian
Armenian Gurmukhi Old Turkic
Arrows Halfwidth and Fullwidth Forms Optical Character Recognition
Avestan Hangul Compatibility Jamo Oriya
Balinese Hangul Jamo Osmanya
Bamum Hangul Jamo Extended-A Phags-pa
Bamum Supplement Hangul Jamo Extended-B Phaistos Disc
Basic Latin Hangul Syllables Phoenician
Batak Hanunoo Phonetic Extensions
Bengali Hebrew Phonetic Extensions Supplement
Block Elements High Private Use Surrogates Playing Cards
Bopomofo High Surrogates Private Use Area
Bopomofo Extended Hiragana Rejang
Box Drawing Ideographic Description Characters Rumi Numeral Symbols
Brahmi Imperial Aramaic Runic
Braille Patterns Inscriptional Pahlavi Samaritan
Buginese Inscriptional Parthian Saurashtra
Buhid IPA Extensions Sharada
Byzantine Musical Symbols Javanese Shavian
Carian Kaithi Sinhala
Chakma Kana Supplement Small Form Variants
Cham Kanbun Sora Sompeng
Cherokee Kangxi Radicals Spacing Modifier Letters
CJK Compatibility Kannada Specials
CJK Compatibility Forms Katakana Sundanese
CJK Compatibility Ideographs Katakana Phonetic Extensions Sundanese Supplement
CJK Compatibility Ideographs Supplement Kayah Li Superscripts and Subscripts
CJK Radicals Supplement Kharoshthi Supplemental Arrows-A
CJK Strokes Khmer Supplemental Arrows-B
CJK Symbols and Punctuation Khmer Symbols Supplemental Mathematical Operators
CJK Unified Ideographs Lao Supplemental Punctuation
CJK Unified Ideographs Extension A Latin-1 Supplement Supplementary Private Use Area-A
CJK Unified Ideographs Extension B Latin Extended-A Supplementary Private Use Area-B
CJK Unified Ideographs Extension C Latin Extended Additional Syloti Nagri
CJK Unified Ideographs Extension D Latin Extended-B Syriac
Combining Diacritical Marks Latin Extended-C Tagalog
Combining Diacritical Marks for Symbols Latin Extended-D Tagbanwa
Combining Diacritical Marks Supplement Lepcha Tags
Combining Half Marks Letterlike Symbols Tai Le
Common Indic Number Forms Limbu Tai Tham
Control Pictures Linear B Ideograms Tai Viet
Coptic Linear B Syllabary Tai Xuan Jing Symbols
Counting Rod Numerals Lisu Takri
Cuneiform Low Surrogates Tamil
Cuneiform Numbers and Punctuation Lycian Telugu
Currency Symbols Lydian Thaana
Cypriot Syllabary Mahjong Tiles Thai
Cyrillic Malayalam Tibetan
Cyrillic Extended-A Mandaic Tifinagh
Cyrillic Extended-B Mathematical Alphanumeric Symbols Transport And Map Symbols
Cyrillic Supplement Mathematical Operators Ugaritic
Deseret Meetei Mayek Unified Canadian Aboriginal Syllabics
Devanagari Meetei Mayek Extensions Unified Canadian Aboriginal Syllabics Extended
Devanagari Extended Meroitic Cursive Vai
Dingbats Meroitic Hieroglyphs Variation Selectors
Domino Tiles Miao Variation Selectors Supplement
Egyptian Hieroglyphs Miscellaneous Mathematical Symbols-A Vedic Extensions
Emoticons Miscellaneous Mathematical Symbols-B Vertical Forms
Enclosed Alphanumerics Miscellaneous Symbols Yijing Hexagram Symbols
Enclosed Alphanumeric Supplement Miscellaneous Symbols and Arrows Yi Radicals
Enclosed CJK Letters and Months Miscellaneous Symbols And Pictographs Yi Syllables
Enclosed Ideographic Supplement Miscellaneous Technical
Ethiopic Modifier Tone Letters

Below is the table with script names accepted by unicode.script and by the shorthand version unicode:

Scripts
Arabic Hanunoo Old_Italic
Armenian Hebrew Old_Persian
Avestan Hiragana Old_South_Arabian
Balinese Imperial_Aramaic Old_Turkic
Bamum Inherited Oriya
Batak Inscriptional_Pahlavi Osmanya
Bengali Inscriptional_Parthian Phags_Pa
Bopomofo Javanese Phoenician
Brahmi Kaithi Rejang
Braille Kannada Runic
Buginese Katakana Samaritan
Buhid Kayah_Li Saurashtra
Canadian_Aboriginal Kharoshthi Sharada
Carian Khmer Shavian
Chakma Lao Sinhala
Cham Latin Sora_Sompeng
Cherokee Lepcha Sundanese
Common Limbu Syloti_Nagri
Coptic Linear_B Syriac
Cuneiform Lisu Tagalog
Cypriot Lycian Tagbanwa
Cyrillic Lydian Tai_Le
Deseret Malayalam Tai_Tham
Devanagari Mandaic Tai_Viet
Egyptian_Hieroglyphs Meetei_Mayek Takri
Ethiopic Meroitic_Cursive Tamil
Georgian Meroitic_Hieroglyphs Telugu
Glagolitic Miao Thaana
Gothic Mongolian Thai
Greek Myanmar Tibetan
Gujarati New_Tai_Lue Tifinagh
Gurmukhi Nko Ugaritic
Han Ogham Vai
Hangul Ol_Chiki Yi

Below is the table of names accepted by unicode.hangulSyllableType.

Hangul syllable type
Abb. Long form
L Leading_Jamo
LV LV_Syllable
LVT LVT_Syllable
T Trailing_Jamo
V Vowel_Jamo

Trademarks: Unicode(tm) is a trademark of Unicode, Inc.

Authors:
Dmitry Olshansky

Source: std/uni.d

Standards:
enum dchar lineSep;
Constant code point (0x2028) - line separator.
enum dchar paraSep;
Constant code point (0x2029) - paragraph separator.
enum dchar nelSep;
Constant code point (0x0085) - next line.
template isCodepointSet(T)
Tests if T is some kind a set of code points. Intended for template constraints.
enum auto isIntegralPair(T, V = uint);
Tests if T is a pair of integers that implicitly convert to V. The following code must compile for any pair T:
(T x){ V a = x[0]; V b = x[1];}
The following must not compile:
(T x){ V c = x[2];}
alias CodepointSet = InversionList!(GcPolicy).InversionList;
The recommended default type for set of code points. For details, see the current implementation: InversionList.
struct CodepointInterval;
The recommended type of std.typecons.Tuple to represent [a, b) intervals of code points. As used in InversionList. Any interval type should pass isIntegralPair trait.
struct InversionList(SP = GcPolicy);

InversionList is a set of code points represented as an array of open-right [a, b) intervals (see CodepointInterval above). The name comes from the way the representation reads left to right. For instance a set of all values [10, 50), [80, 90), plus a singular value 60 looks like this:

10, 50, 60, 61, 80, 90

The way to read this is: start with negative meaning that all numbers smaller then the next one are not present in this set (and positive - the contrary). Then switch positive/negative after each number passed from left to right.

This way negative spans until 10, then positive until 50, then negative until 60, then positive until 61, and so on. As seen this provides a space-efficient storage of highly redundant data that comes in long runs. A description which Unicode character properties fit nicely. The technique itself could be seen as a variation on RLE encoding.

Sets are value types (just like int is) thus they are never aliased.

Example:

auto a = CodepointSet('a', 'z'+1);
auto b = CodepointSet('A', 'Z'+1);
auto c = a;
a = a | b;
assert(a == CodepointSet('A', 'Z'+1, 'a', 'z'+1));
assert(a != c);

See also unicode for simpler construction of sets from predefined ones.

Memory usage is 8 bytes per each contiguous interval in a set. The value semantics are achieved by using the COW technique and thus it's not safe to cast this type to shared.

Note:

It's not recommended to rely on the template parameters or the exact type of a current code point set in std.uni. The type and parameters may change when the standard allocators design is finalized. Use isCodepointSet with templates or just stick with the default alias CodepointSet throughout the whole code base.

pure this(Set)(Set set)
if (isCodepointSet!Set);
Construct from another code point set of any type.
pure this(Range)(Range intervals)
if (isForwardRange!Range && isIntegralPair!(ElementType!Range));
Construct a set from a forward range of code point intervals.
this()(uint[] intervals...);
Construct a set from plain values of code point intervals.
Examples:
import std.algorithm.comparison : equal;

auto set = CodepointSet('a', 'z'+1, 'а', 'я'+1);
foreach (v; 'a'..'z'+1)
    assert(set[v]);
// Cyrillic lowercase interval
foreach (v; 'а'..'я'+1)
    assert(set[v]);
//specific order is not required, intervals may interesect
auto set2 = CodepointSet('а', 'я'+1, 'a', 'd', 'b', 'z'+1);
//the same end result
assert(set2.byInterval.equal(set.byInterval));
@property auto byInterval();
Get range that spans all of the code point intervals in this InversionList.

Example:

import std.algorithm.comparison : equal;
import std.typecons : tuple;

auto set = CodepointSet('A', 'D'+1, 'a', 'd'+1);

assert(set.byInterval.equal([tuple('A','E'), tuple('a','e')]));

const bool opIndex(uint val);
Tests the presence of code point val in this set.
Examples:
auto gothic = unicode.Gothic;
// Gothic letter ahsa
assert(gothic['\U00010330']);
// no ascii in Gothic obviously
assert(!gothic['$']);
@property size_t length();
Number of code points in this set
This opBinary(string op, U)(U rhs)
if (isCodepointSet!U || is(U : dchar));

Sets support natural syntax for set algebra, namely:

Operator Math notation Description
& a ∩ b intersection
| a ∪ b union
- a ∖ b subtraction
~ a ~ b symmetric set difference i.e. (a ∪ b) \ (a ∩ b)
Examples:
import std.algorithm.comparison : equal;
import std.range : iota;

auto lower = unicode.LowerCase;
auto upper = unicode.UpperCase;
auto ascii = unicode.ASCII;

assert((lower & upper).empty); // no intersection
auto lowerASCII = lower & ascii;
assert(lowerASCII.byCodepoint.equal(iota('a', 'z'+1)));
// throw away all of the lowercase ASCII
writeln((ascii - lower).length); // 128 - 26

auto onlyOneOf = lower ~ ascii;
assert(!onlyOneOf['Δ']); // not ASCII and not lowercase
assert(onlyOneOf['$']); // ASCII and not lowercase
assert(!onlyOneOf['a']); // ASCII and lowercase
assert(onlyOneOf['я']); // not ASCII but lowercase

// throw away all cased letters from ASCII
auto noLetters = ascii - (lower | upper);
writeln(noLetters.length); // 128 - 26 * 2
ref This opOpAssign(string op, U)(U rhs)
if (isCodepointSet!U || is(U : dchar));
The 'op=' versions of the above overloaded operators.
const bool opBinaryRight(string op : "in", U)(U ch)
if (is(U : dchar));
Tests the presence of codepoint ch in this set, the same as opIndex.
Examples:
assert('я' in unicode.Cyrillic);
assert(!('z' in unicode.Cyrillic));
auto opUnary(string op : "!")();
Obtains a set that is the inversion of this set.
See Also:
@property auto byCodepoint();
A range that spans each code point in this set.
Examples:
import std.algorithm.comparison : equal;
import std.range : iota;

auto set = unicode.ASCII;
set.byCodepoint.equal(iota(0, 0x80));
void toString(Writer)(scope Writer sink, FormatSpec!char fmt);
Obtain a textual representation of this InversionList in form of open-right intervals.
The formatting flag is applied individually to each value, for example:
  • %s and %d format the intervals as a [low .. high) range of integrals
  • %x formats the intervals as a [low .. high) range of lowercase hex characters
  • %X formats the intervals as a [low .. high) range of uppercase hex characters
  • Examples:
    import std.conv : to;
    import std.format : format;
    import std.uni : unicode;
    
    assert(unicode.Cyrillic.to!string ==
        "[1024..1157) [1159..1320) [7467..7468) [7544..7545) [11744..11776) [42560..42648) [42655..42656)");
    
    // The specs '%s' and '%d' are equivalent to the to!string call above.
    writeln(format("%d", unicode.Cyrillic)); // unicode.Cyrillic.to!string
    
    assert(format("%#x", unicode.Cyrillic) ==
        "[0x400..0x485) [0x487..0x528) [0x1d2b..0x1d2c) [0x1d78..0x1d79) [0x2de0..0x2e00) "
        ~"[0xa640..0xa698) [0xa69f..0xa6a0)");
    
    assert(format("%#X", unicode.Cyrillic) ==
        "[0X400..0X485) [0X487..0X528) [0X1D2B..0X1D2C) [0X1D78..0X1D79) [0X2DE0..0X2E00) "
        ~"[0XA640..0XA698) [0XA69F..0XA6A0)");
    
    ref auto add()(uint a, uint b);
    Add an interval [a, b) to this set.
    Examples:
    CodepointSet someSet;
    someSet.add('0', '5').add('A','Z'+1);
    someSet.add('5', '9'+1);
    assert(someSet['0']);
    assert(someSet['5']);
    assert(someSet['9']);
    assert(someSet['Z']);
    
    @property auto inverted();
    Obtains a set that is the inversion of this set.
    See the '!' opUnary for the same but using operators.
    Examples:
    auto set = unicode.ASCII;
    // union with the inverse gets all of the code points in the Unicode
    writeln((set | set.inverted).length); // 0x110000
    // no intersection with the inverse
    assert((set & set.inverted).empty);
    
    string toSourceCode(string funcName = "");
    Generates string with D source code of unary function with name of funcName taking a single dchar argument. If funcName is empty the code is adjusted to be a lambda function.
    The function generated tests if the code point passed belongs to this set or not. The result is to be used with string mixin. The intended usage area is aggressive optimization via meta programming in parser generators and the like.

    Note: Use with care for relatively small or regular sets. It could end up being slower then just using multi-staged tables.

    Example:

    import std.stdio;
    
    // construct set directly from [a, b$RPAREN intervals
    auto set = CodepointSet(10, 12, 45, 65, 100, 200);
    writeln(set);
    writeln(set.toSourceCode("func"));
    
    The above outputs something along the lines of:
    bool func(dchar ch)  @safe pure nothrow @nogc
    {
        if (ch < 45)
        {
            if (ch == 10 || ch == 11) return true;
            return false;
        }
        else if (ch < 65) return true;
        else
        {
            if (ch < 100) return false;
            if (ch < 200) return true;
            return false;
        }
    }
    

    const @property bool empty();
    True if this set doesn't contain any code points.
    Examples:
    CodepointSet emptySet;
    writeln(emptySet.length); // 0
    assert(emptySet.empty);
    
    template codepointSetTrie(sizes...) if (sumOfIntegerTuple!sizes == 21)
    A shorthand for creating a custom multi-level fixed Trie from a CodepointSet. sizes are numbers of bits per level, with the most significant bits used first.

    Note: The sum of sizes must be equal 21.

    See Also:
    toTrie, which is even simpler.

    Example:

    {
        import std.stdio;
        auto set = unicode("Number");
        auto trie = codepointSetTrie!(8, 5, 8)(set);
        writeln("Input code points to test:");
        foreach (line; stdin.byLine)
        {
            int count=0;
            foreach (dchar ch; line)
                if (trie[ch])// is number
                    count++;
            writefln("Contains %d number code points.", count);
        }
    }
    

    template CodepointSetTrie(sizes...) if (sumOfIntegerTuple!sizes == 21)
    Type of Trie generated by codepointSetTrie function.
    template codepointTrie(T, sizes...) if (sumOfIntegerTuple!sizes == 21)
    A slightly more general tool for building fixed Trie for the Unicode data.
    Specifically unlike codepointSetTrie it's allows creating mappings of dchar to an arbitrary type T.

    Note: Overload taking CodepointSets will naturally convert only to bool mapping Tries.

    template CodepointTrie(T, sizes...) if (sumOfIntegerTuple!sizes == 21)
    Type of Trie as generated by codepointTrie function.
    struct MatcherConcept;
    Conceptual type that outlines the common properties of all UTF Matchers.

    Note: For illustration purposes only, every method call results in assertion failure. Use utfMatcher to obtain a concrete matcher for UTF-8 or UTF-16 encodings.

    bool match(Range)(ref Range inp)
    if (isRandomAccessRange!Range && is(ElementType!Range : char));

    bool skip(Range)(ref Range inp)
    if (isRandomAccessRange!Range && is(ElementType!Range : char));

    bool test(Range)(ref Range inp)
    if (isRandomAccessRange!Range && is(ElementType!Range : char));

    Perform a semantic equivalent 2 operations: decoding a code point at front of inp and testing if it belongs to the set of code points of this matcher.

    The effect on inp depends on the kind of function called:

    Match. If the codepoint is found in the set then range inp is advanced by its size in code units, otherwise the range is not modifed.

    Skip. The range is always advanced by the size of the tested code point regardless of the result of test.

    Test. The range is left unaffected regardless of the result of test.

    Examples:
    string truth = "2² = 4";
    auto m = utfMatcher!char(unicode.Number);
    assert(m.match(truth)); // '2' is a number all right
    assert(truth == "² = 4"); // skips on match
    assert(m.match(truth)); // so is the superscript '2'
    assert(!m.match(truth)); // space is not a number
    assert(truth == " = 4"); // unaffected on no match
    assert(!m.skip(truth)); // same test ...
    assert(truth == "= 4"); // but skips a codepoint regardless
    assert(!m.test(truth)); // '=' is not a number
    assert(truth == "= 4"); // test never affects argument
    
    @property auto subMatcher(Lengths...)();
    Advanced feature - provide direct access to a subset of matcher based a set of known encoding lengths. Lengths are provided in code units. The sub-matcher then may do less operations per any test/match.
    Use with care as the sub-matcher won't match any code points that have encoded length that doesn't belong to the selected set of lengths. Also the sub-matcher object references the parent matcher and must not be used past the liftetime of the latter.
    Another caveat of using sub-matcher is that skip is not available preciesly because sub-matcher doesn't detect all lengths.
    Examples:
    auto m = utfMatcher!char(unicode.Number);
    string square = "2²";
    // about sub-matchers
    assert(!m.subMatcher!(2,3,4).test(square)); // ASCII no covered
    assert(m.subMatcher!1.match(square)); // ASCII-only, works
    assert(!m.subMatcher!1.test(square)); // unicode '²'
    assert(m.subMatcher!(2,3,4).match(square));  //
    writeln(square); // ""
    wstring wsquare = "2²";
    auto m16 = utfMatcher!wchar(unicode.Number);
    // may keep ref, but the orignal (m16) must be kept alive
    auto bmp = m16.subMatcher!1;
    assert(bmp.match(wsquare)); // Okay, in basic multilingual plan
    assert(bmp.match(wsquare)); // And '²' too
    
    enum auto isUtfMatcher(M, C);
    Test if M is an UTF Matcher for ranges of Char.
    @trusted auto utfMatcher(Char, Set)(Set set)
    if (isCodepointSet!Set);
    Constructs a matcher object to classify code points from the set for encoding that has Char as code unit.
    See MatcherConcept for API outline.
    auto toTrie(size_t level, Set)(Set set)
    if (isCodepointSet!Set);
    Convenience function to construct optimal configurations for packed Trie from any set of code points.
    The parameter level indicates the number of trie levels to use, allowed values are: 1, 2, 3 or 4. Levels represent different trade-offs speed-size wise.

    Level 1 is fastest and the most memory hungry (a bit array).

    Level 4 is the slowest and has the smallest footprint.

    See the Synopsis section for example.

    Note: Level 4 stays very practical (being faster and more predictable) compared to using direct lookup on the set itself.

    auto toDelegate(Set)(Set set)
    if (isCodepointSet!Set);

    Builds a Trie with typically optimal speed-size trade-off and wraps it into a delegate of the following type: bool delegate(dchar ch).

    Effectively this creates a 'tester' lambda suitable for algorithms like std.algorithm.find that take unary predicates.

    See the Synopsis section for example.
    struct unicode;
    A single entry point to lookup Unicode code point sets by name or alias of a block, script or general category.
    It uses well defined standard rules of property name lookup. This includes fuzzy matching of names, so that 'White_Space', 'white-SpAce' and 'whitespace' are all considered equal and yield the same set of white space characters.
    pure @property auto opDispatch(string name)();
    Performs the lookup of set of code points with compile-time correctness checking. This short-cut version combines 3 searches: across blocks, scripts, and common binary properties.
    Note that since scripts and blocks overlap the usual trick to disambiguate is used - to get a block use unicode.InBlockName, to search a script use unicode.ScriptName.
    See Also:
    block, script and (not included in this search) hangulSyllableType.
    auto opCall(C)(in C[] name)
    if (is(C : dchar));
    The same lookup across blocks, scripts, or binary properties, but performed at run-time. This version is provided for cases where name is not known beforehand; otherwise compile-time checked opDispatch is typically a better choice.
    See the table of properties for available sets.
    struct block;
    Narrows down the search for sets of code points to all Unicode blocks.

    Note: Here block names are unambiguous as no scripts are searched and thus to search use simply unicode.block.BlockName notation.

    See table of properties for available sets.

    Examples:
    // use .block for explicitness
    writeln(unicode.block.Greek_and_Coptic); // unicode.InGreek_and_Coptic
    
    struct script;
    Narrows down the search for sets of code points to all Unicode scripts.
    See the table of properties for available sets.
    Examples:
    auto arabicScript = unicode.script.arabic;
    auto arabicBlock = unicode.block.arabic;
    // there is an intersection between script and block
    assert(arabicBlock['؁']);
    assert(arabicScript['؁']);
    // but they are different
    assert(arabicBlock != arabicScript);
    writeln(arabicBlock); // unicode.inArabic
    writeln(arabicScript); // unicode.arabic
    
    struct hangulSyllableType;
    Fetch a set of code points that have the given hangul syllable type.
    Other non-binary properties (once supported) follow the same notation - unicode.propertyName.propertyValue for compile-time checked access and unicode.propertyName(propertyValue) for run-time checked one.
    See the table of properties for available sets.
    Examples:
    // L here is syllable type not Letter as in unicode.L short-cut
    auto leadingVowel = unicode.hangulSyllableType("L");
    // check that some leading vowels are present
    foreach (vowel; '\u1110'..'\u115F')
        assert(leadingVowel[vowel]);
    writeln(leadingVowel); // unicode.hangulSyllableType.L
    
    size_t graphemeStride(C)(in C[] input, size_t index)
    if (is(C : dchar));
    Computes the length of grapheme cluster starting at index. Both the resulting length and the index are measured in code units.
    Parameters:
    C type that is implicitly convertible to dchars
    C[] input array of grapheme clusters
    size_t index starting index into input[]
    Returns:
    length of grapheme cluster
    Examples:
    writeln(graphemeStride("  ", 1)); // 1
    // A + combing ring above
    string city = "A\u030Arhus";
    size_t first = graphemeStride(city, 0);
    assert(first == 3); //\u030A has 2 UTF-8 code units
    writeln(city[0 .. first]); // "A\u030A"
    writeln(city[first .. $]); // "rhus"
    
    Grapheme decodeGrapheme(Input)(ref Input inp)
    if (isInputRange!Input && is(Unqual!(ElementType!Input) == dchar));
    Reads one full grapheme cluster from an input range of dchar inp.
    For examples see the Grapheme below.

    Note: This function modifies inp and thus inp must be an L-value.

    auto byGrapheme(Range)(Range range)
    if (isInputRange!Range && is(Unqual!(ElementType!Range) == dchar));

    Iterate a string by grapheme.

    Useful for doing string manipulation that needs to be aware of graphemes.

    See Also:
    Examples:
    import std.algorithm.comparison : equal;
    import std.range.primitives : walkLength;
    import std.range : take, drop;
    auto text = "noe\u0308l"; // noël using e + combining diaeresis
    assert(text.walkLength == 5); // 5 code points
    
    auto gText = text.byGrapheme;
    assert(gText.walkLength == 4); // 4 graphemes
    
    assert(gText.take(3).equal("noe\u0308".byGrapheme));
    assert(gText.drop(3).equal("l".byGrapheme));
    
    auto byCodePoint(Range)(Range range)
    if (isInputRange!Range && is(Unqual!(ElementType!Range) == Grapheme));

    Range byCodePoint(Range)(Range range)
    if (isInputRange!Range && is(Unqual!(ElementType!Range) == dchar));

    Lazily transform a range of Graphemes to a range of code points.

    Useful for converting the result to a string after doing operations on graphemes.

    Acts as the identity function when given a range of code points.

    Examples:
    import std.array : array;
    import std.conv : text;
    import std.range : retro;
    
    string s = "noe\u0308l"; // noël
    
    // reverse it and convert the result to a string
    string reverse = s.byGrapheme
        .array
        .retro
        .byCodePoint
        .text;
    
    assert(reverse == "le\u0308on"); // lëon
    
    struct Grapheme;

    A structure designed to effectively pack characters of a grapheme cluster.

    Grapheme has value semantics so 2 copies of a Grapheme always refer to distinct objects. In most actual scenarios a Grapheme fits on the stack and avoids memory allocation overhead for all but quite long clusters.

    this(C)(in C[] chars...)
    if (is(C : dchar));

    this(Input)(Input seq)
    if (!isDynamicArray!Input && isInputRange!Input && is(ElementType!Input : dchar));
    Ctor
    const pure nothrow @nogc @trusted dchar opIndex(size_t index);
    Gets a code point at the given index in this cluster.
    pure nothrow @nogc @trusted void opIndexAssign(dchar ch, size_t index);
    Writes a code point ch at given index in this cluster.

    Warning: Use of this facility may invalidate grapheme cluster, see also Grapheme.valid.

    Examples:
    auto g = Grapheme("A\u0302");
    writeln(g[0]); // 'A'
    assert(g.valid);
    g[1] = '~'; // ASCII tilda is not a combining mark
    writeln(g[1]); // '~'
    assert(!g.valid);
    
    pure nothrow @nogc @system SliceOverIndexed!Grapheme opSlice(size_t a, size_t b);

    pure nothrow @nogc @system SliceOverIndexed!Grapheme opSlice();
    Random-access range over Grapheme's characters.

    Warning: Invalidates when this Grapheme leaves the scope, attempts to use it then would lead to memory corruption.

    const pure nothrow @nogc @property @trusted size_t length();
    Grapheme cluster length in code points.
    ref auto opOpAssign(string op)(dchar ch);
    Append character ch to this grapheme.

    Warning: Use of this facility may invalidate grapheme cluster, see also valid.

    See Also:
    Examples:
    import std.algorithm.comparison : equal;
    auto g = Grapheme("A");
    assert(g.valid);
    g ~= '\u0301';
    assert(g[].equal("A\u0301"));
    assert(g.valid);
    g ~= "B";
    // not a valid grapheme cluster anymore
    assert(!g.valid);
    // still could be useful though
    assert(g[].equal("A\u0301B"));
    
    ref auto opOpAssign(string op, Input)(Input inp)
    if (isInputRange!Input && is(ElementType!Input : dchar));
    Append all characters from the input range inp to this Grapheme.
    @property bool valid()();
    True if this object contains valid extended grapheme cluster. Decoding primitives of this module always return a valid Grapheme.
    Appending to and direct manipulation of grapheme's characters may render it no longer valid. Certain applications may chose to use Grapheme as a "small string" of any code points and ignore this property entirely.
    int sicmp(S1, S2)(S1 r1, S2 r2)
    if (isInputRange!S1 && isSomeChar!(ElementEncodingType!S1) && isInputRange!S2 && isSomeChar!(ElementEncodingType!S2));

    Does basic case-insensitive comparison of r1 and r2. This function uses simpler comparison rule thus achieving better performance than icmp. However keep in mind the warning below.

    Parameters:
    S1 r1 an input range of characters
    S2 r2 an input range of characters
    Returns:
    An int that is 0 if the strings match, <0 if r1 is lexicographically "less" than r2, >0 if r1 is lexicographically "greater" than r2

    Warning: This function only handles 1:1 code point mapping and thus is not sufficient for certain alphabets like German, Greek and few others.

    Examples:
    writeln(sicmp("Август", "авгусТ")); // 0
    // Greek also works as long as there is no 1:M mapping in sight
    writeln(sicmp("ΌΎ", "όύ")); // 0
    // things like the following won't get matched as equal
    // Greek small letter iota with dialytika and tonos
    assert(sicmp("ΐ", "\u03B9\u0308\u0301") != 0);
    
    // while icmp has no problem with that
    writeln(icmp("ΐ", "\u03B9\u0308\u0301")); // 0
    writeln(icmp("ΌΎ", "όύ")); // 0
    
    int icmp(S1, S2)(S1 r1, S2 r2)
    if (isForwardRange!S1 && isSomeChar!(ElementEncodingType!S1) && isForwardRange!S2 && isSomeChar!(ElementEncodingType!S2));
    Does case insensitive comparison of r1 and r2. Follows the rules of full case-folding mapping. This includes matching as equal german ß with "ss" and other 1:M code point mappings unlike sicmp. The cost of icmp being pedantically correct is slightly worse performance.
    Parameters:
    S1 r1 a forward range of characters
    S2 r2 a forward range of characters
    Returns:
    An int that is 0 if the strings match, <0 if str1 is lexicographically "less" than str2, >0 if str1 is lexicographically "greater" than str2
    Examples:
    writeln(icmp("Rußland", "Russland")); // 0
    writeln(icmp("ᾩ -> \u1F70\u03B9", "\u1F61\u03B9 -> ᾲ")); // 0
    
    Examples:
    By using std.utf.byUTF and its aliases, GC allocations via auto-decoding and thrown exceptions can be avoided, making icmp @safe @nogc nothrow pure.
    import std.utf : byDchar;
    
    writeln(icmp("Rußland".byDchar, "Russland".byDchar)); // 0
    writeln(icmp("ᾩ -> \u1F70\u03B9".byDchar, "\u1F61\u03B9 -> ᾲ".byDchar)); // 0
    
    pure nothrow @nogc @safe ubyte combiningClass(dchar ch);

    Returns the combining class of ch.

    Examples:
    // shorten the code
    alias CC = combiningClass;
    
    // combining tilda
    writeln(CC('\u0303')); // 230
    // combining ring below
    writeln(CC('\u0325')); // 220
    // the simple consequence is that  "tilda" should be
    // placed after a "ring below" in a sequence
    
    enum UnicodeDecomposition: int;
    Unicode character decomposition type.
    Canonical
    Canonical decomposition. The result is canonically equivalent sequence.
    Compatibility
    Compatibility decomposition. The result is compatibility equivalent sequence.

    Note: Compatibility decomposition is a lossy conversion, typically suitable only for fuzzy matching and internal processing.

    pure nothrow @safe dchar compose(dchar first, dchar second);
    Try to canonically compose 2 characters. Returns the composed character if they do compose and dchar.init otherwise.
    The assumption is that first comes before second in the original text, usually meaning that the first is a starter.

    Note: Hangul syllables are not covered by this function. See composeJamo below.

    Examples:
    writeln(compose('A', '\u0308')); // '\u00C4'
    writeln(compose('A', 'B')); // dchar.init
    writeln(compose('C', '\u0301')); // '\u0106'
    // note that the starter is the first one
    // thus the following doesn't compose
    writeln(compose('\u0308', 'A')); // dchar.init
    
    @safe Grapheme decompose(UnicodeDecomposition decompType = Canonical)(dchar ch);
    Returns a full Canonical (by default) or Compatibility decomposition of character ch. If no decomposition is available returns a Grapheme with the ch itself.

    Note: This function also decomposes hangul syllables as prescribed by the standard.

    See Also:
    decomposeHangul for a restricted version that takes into account only hangul syllables but no other decompositions.
    Examples:
    import std.algorithm.comparison : equal;
    
    writeln(compose('A', '\u0308')); // '\u00C4'
    writeln(compose('A', 'B')); // dchar.init
    writeln(compose('C', '\u0301')); // '\u0106'
    // note that the starter is the first one
    // thus the following doesn't compose
    writeln(compose('\u0308', 'A')); // dchar.init
    
    assert(decompose('Ĉ')[].equal("C\u0302"));
    assert(decompose('D')[].equal("D"));
    assert(decompose('\uD4DC')[].equal("\u1111\u1171\u11B7"));
    assert(decompose!Compatibility('¹')[].equal("1"));
    
    @safe Grapheme decomposeHangul(dchar ch);
    Decomposes a Hangul syllable. If ch is not a composed syllable then this function returns Grapheme containing only ch as is.
    Examples:
    import std.algorithm.comparison : equal;
    assert(decomposeHangul('\uD4DB')[].equal("\u1111\u1171\u11B6"));
    
    pure nothrow @nogc @safe dchar composeJamo(dchar lead, dchar vowel, dchar trailing = (dchar).init);
    Try to compose hangul syllable out of a leading consonant (lead), a vowel and optional trailing consonant jamos.
    On success returns the composed LV or LVT hangul syllable.
    If any of lead and vowel are not a valid hangul jamo of the respective character class returns dchar.init.
    Examples:
    writeln(composeJamo('\u1111', '\u1171', '\u11B6')); // '\uD4DB'
    // leaving out T-vowel, or passing any codepoint
    // that is not trailing consonant composes an LV-syllable
    writeln(composeJamo('\u1111', '\u1171')); // '\uD4CC'
    writeln(composeJamo('\u1111', '\u1171', ' ')); // '\uD4CC'
    writeln(composeJamo('\u1111', 'A')); // dchar.init
    writeln(composeJamo('A', '\u1171')); // dchar.init
    
    enum NormalizationForm: int;
    Enumeration type for normalization forms, passed as template parameter for functions like normalize.
    NFC

    NFD

    NFKC

    NFKD
    Shorthand aliases from values indicating normalization forms.
    inout(C)[] normalize(NormalizationForm norm = NFC, C)(inout(C)[] input);
    Returns input string normalized to the chosen form. Form C is used by default.
    For more information on normalization forms see the normalization section.

    Note: In cases where the string in question is already normalized, it is returned unmodified and no memory allocation happens.

    Examples:
    // any encoding works
    wstring greet = "Hello world";
    assert(normalize(greet) is greet); // the same exact slice
    
    // An example of a character with all 4 forms being different:
    // Greek upsilon with acute and hook symbol (code point 0x03D3)
    writeln(normalize!NFC("ϓ")); // "\u03D3"
    writeln(normalize!NFD("ϓ")); // "\u03D2\u0301"
    writeln(normalize!NFKC("ϓ")); // "\u038E"
    writeln(normalize!NFKD("ϓ")); // "\u03A5\u0301"
    
    bool allowedIn(NormalizationForm norm)(dchar ch);
    Tests if dchar ch is always allowed (Quick_Check=YES) in normalization form norm.
    Examples:
    // e.g. Cyrillic is always allowed, so is ASCII
    assert(allowedIn!NFC('я'));
    assert(allowedIn!NFD('я'));
    assert(allowedIn!NFKC('я'));
    assert(allowedIn!NFKD('я'));
    assert(allowedIn!NFC('Z'));
    
    pure nothrow @nogc @safe bool isWhite(dchar c);
    Whether or not c is a Unicode whitespace character. (general Unicode category: Part of C0(tab, vertical tab, form feed, carriage return, and linefeed characters), Zs, Zl, Zp, and NEL(U+0085))
    pure nothrow @nogc @safe bool isLower(dchar c);
    Return whether c is a Unicode lowercase character.
    pure nothrow @nogc @safe bool isUpper(dchar c);
    Return whether c is a Unicode uppercase character.
    auto asLowerCase(Range)(Range str)
    if (isInputRange!Range && isSomeChar!(ElementEncodingType!Range) && !isConvertibleToString!Range);

    auto asUpperCase(Range)(Range str)
    if (isInputRange!Range && isSomeChar!(ElementEncodingType!Range) && !isConvertibleToString!Range);
    Convert input range or string to upper or lower case.
    Does not allocate memory. Characters in UTF-8 or UTF-16 format that cannot be decoded are treated as std.utf.replacementDchar.
    Parameters:
    Range str string or range of characters
    Returns:
    an InputRange of dchars
    See Also:
    Examples:
    import std.algorithm.comparison : equal;
    
    assert("hEllo".asUpperCase.equal("HELLO"));
    
    auto asCapitalized(Range)(Range str)
    if (isInputRange!Range && isSomeChar!(ElementEncodingType!Range) && !isConvertibleToString!Range);
    Capitalize input range or string, meaning convert the first character to upper case and subsequent characters to lower case.
    Does not allocate memory. Characters in UTF-8 or UTF-16 format that cannot be decoded are treated as std.utf.replacementDchar.
    Parameters:
    Range str string or range of characters
    Returns:
    an InputRange of dchars
    Examples:
    import std.algorithm.comparison : equal;
    
    assert("hEllo".asCapitalized.equal("Hello"));
    
    pure @trusted void toLowerInPlace(C)(ref C[] s)
    if (is(C == char) || is(C == wchar) || is(C == dchar));
    Converts s to lowercase (by performing Unicode lowercase mapping) in place. For a few characters string length may increase after the transformation, in such a case the function reallocates exactly once. If s does not have any uppercase characters, then s is unaltered.
    pure @trusted void toUpperInPlace(C)(ref C[] s)
    if (is(C == char) || is(C == wchar) || is(C == dchar));
    Converts s to uppercase (by performing Unicode uppercase mapping) in place. For a few characters string length may increase after the transformation, in such a case the function reallocates exactly once. If s does not have any lowercase characters, then s is unaltered.
    pure nothrow @nogc @safe dchar toLower(dchar c);
    If c is a Unicode uppercase character, then its lowercase equivalent is returned. Otherwise c is returned.

    Warning: certain alphabets like German and Greek have no 1:1 upper-lower mapping. Use overload of toLower which takes full string instead.

    pure @trusted S toLower(S)(S s)
    if (isSomeString!S);
    Returns a string which is identical to s except that all of its characters are converted to lowercase (by preforming Unicode lowercase mapping). If none of s characters were affected, then s itself is returned.
    pure nothrow @nogc @safe dchar toUpper(dchar c);
    If c is a Unicode lowercase character, then its uppercase equivalent is returned. Otherwise c is returned.

    Warning: Certain alphabets like German and Greek have no 1:1 upper-lower mapping. Use overload of toUpper which takes full string instead.

    toUpper can be used as an argument to std.algorithm.iteration.map to produce an algorithm that can convert a range of characters to upper case without allocating memory. A string can then be produced by using std.algorithm.mutation.copy to send it to an std.array.appender.

    Examples:
    import std.algorithm.iteration : map;
    import std.algorithm.mutation : copy;
    import std.array : appender;
    
    auto abuf = appender!(char[])();
    "hello".map!toUpper.copy(&abuf);
    writeln(abuf.data); // "HELLO"
    
    pure @trusted S toUpper(S)(S s)
    if (isSomeString!S);
    Returns a string which is identical to s except that all of its characters are converted to uppercase (by preforming Unicode uppercase mapping). If none of s characters were affected, then s itself is returned.
    pure nothrow @nogc @safe bool isAlpha(dchar c);
    Returns whether c is a Unicode alphabetic character (general Unicode category: Alphabetic).
    pure nothrow @nogc @safe bool isMark(dchar c);
    Returns whether c is a Unicode mark (general Unicode category: Mn, Me, Mc).
    pure nothrow @nogc @safe bool isNumber(dchar c);
    Returns whether c is a Unicode numerical character (general Unicode category: Nd, Nl, No).
    pure nothrow @nogc @safe bool isAlphaNum(dchar c);
    Returns whether c is a Unicode alphabetic character or number. (general Unicode category: Alphabetic, Nd, Nl, No).
    Parameters:
    dchar c any Unicode character
    Returns:
    true if the character is in the Alphabetic, Nd, Nl, or No Unicode categories
    pure nothrow @nogc @safe bool isPunctuation(dchar c);
    Returns whether c is a Unicode punctuation character (general Unicode category: Pd, Ps, Pe, Pc, Po, Pi, Pf).
    pure nothrow @nogc @safe bool isSymbol(dchar c);
    Returns whether c is a Unicode symbol character (general Unicode category: Sm, Sc, Sk, So).
    pure nothrow @nogc @safe bool isSpace(dchar c);
    Returns whether c is a Unicode space character (general Unicode category: Zs)

    Note: This doesn't include '\n', '\r', \t' and other non-space character. For commonly used less strict semantics see isWhite.

    pure nothrow @nogc @safe bool isGraphical(dchar c);
    Returns whether c is a Unicode graphical character (general Unicode category: L, M, N, P, S, Zs).
    pure nothrow @nogc @safe bool isControl(dchar c);
    Returns whether c is a Unicode control character (general Unicode category: Cc).
    pure nothrow @nogc @safe bool isFormat(dchar c);
    Returns whether c is a Unicode formatting character (general Unicode category: Cf).
    pure nothrow @nogc @safe bool isPrivateUse(dchar c);
    Returns whether c is a Unicode Private Use code point (general Unicode category: Co).
    pure nothrow @nogc @safe bool isSurrogate(dchar c);
    Returns whether c is a Unicode surrogate code point (general Unicode category: Cs).
    pure nothrow @nogc @safe bool isSurrogateHi(dchar c);
    Returns whether c is a Unicode high surrogate (lead surrogate).
    pure nothrow @nogc @safe bool isSurrogateLo(dchar c);
    Returns whether c is a Unicode low surrogate (trail surrogate).
    pure nothrow @nogc @safe bool isNonCharacter(dchar c);
    Returns whether c is a Unicode non-character i.e. a code point with no assigned abstract character. (general Unicode category: Cn)