third_party/llvm-16.0/llvm/lib/Support/UnicodeNameToCodepoint.cpp - SwiftShader - Git at Google

 //===- llvm/Support/UnicodeNameToCodepoint.cpp - Unicode character properties
 //-*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements functions to map the name or alias of a unicode
 // character to its codepoint.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Unicode.h"

 namespace llvm {
 namespace sys {
 namespace unicode {

 extern const char *UnicodeNameToCodepointDict;
 extern const uint8_t *UnicodeNameToCodepointIndex;
 extern const std::size_t UnicodeNameToCodepointIndexSize;
 extern const std::size_t UnicodeNameToCodepointLargestNameSize;

 using BufferType = SmallString<64>;

 struct Node {
   bool IsRoot = false;
   char32_t Value = 0xFFFFFFFF;
   uint32_t ChildrenOffset = 0;
   bool HasSibling = false;
   uint32_t Size = 0;
   StringRef Name;
   const Node *Parent = nullptr;

   constexpr bool isValid() const {
     return !Name.empty() || Value == 0xFFFFFFFF;
   }
   constexpr bool hasChildren() const { return ChildrenOffset != 0 || IsRoot; }

   std::string fullName() const {
     std::string S;
     // Reserve enough space for most unicode code points.
     // The chosen value represent the 99th percentile of name size as of
     // Unicode 15.0.
     S.reserve(46);
     const Node *N = this;
     while (N) {
       std::reverse_copy(N->Name.begin(), N->Name.end(), std::back_inserter(S));
       N = N->Parent;
     }
     std::reverse(S.begin(), S.end());
     return S;
   }
 };

 static Node createRoot() {
   Node N;
   N.IsRoot = true;
   N.ChildrenOffset = 1;
   N.Size = 1;
   return N;
 }

 static Node readNode(uint32_t Offset, const Node *Parent = nullptr) {
   if (Offset == 0)
     return createRoot();

   uint32_t Origin = Offset;
   Node N;
   N.Parent = Parent;
   uint8_t NameInfo = UnicodeNameToCodepointIndex[Offset++];
   if (Offset + 6 >= UnicodeNameToCodepointIndexSize)
     return N;

   bool LongName = NameInfo & 0x40;
   bool HasValue = NameInfo & 0x80;
   std::size_t Size = NameInfo & ~0xC0;
   if (LongName) {
     uint32_t NameOffset = (UnicodeNameToCodepointIndex[Offset++] << 8);
     NameOffset |= UnicodeNameToCodepointIndex[Offset++];
     N.Name = StringRef(UnicodeNameToCodepointDict + NameOffset, Size);
   } else {
     N.Name = StringRef(UnicodeNameToCodepointDict + Size, 1);
   }
   if (HasValue) {
     uint8_t H = UnicodeNameToCodepointIndex[Offset++];
     uint8_t M = UnicodeNameToCodepointIndex[Offset++];
     uint8_t L = UnicodeNameToCodepointIndex[Offset++];
     N.Value = ((H << 16) | (M << 8) | L) >> 3;

     bool HasChildren = L & 0x02;
     N.HasSibling = L & 0x01;

     if (HasChildren) {
       N.ChildrenOffset = UnicodeNameToCodepointIndex[Offset++] << 16;
       N.ChildrenOffset |= UnicodeNameToCodepointIndex[Offset++] << 8;
       N.ChildrenOffset |= UnicodeNameToCodepointIndex[Offset++];
     }
   } else {
     uint8_t H = UnicodeNameToCodepointIndex[Offset++];
     N.HasSibling = H & 0x80;
     bool HasChildren = H & 0x40;
     H &= uint8_t(~0xC0);
     if (HasChildren) {
       N.ChildrenOffset = (H << 16);
       N.ChildrenOffset |=
           (uint32_t(UnicodeNameToCodepointIndex[Offset++]) << 8);
       N.ChildrenOffset |= UnicodeNameToCodepointIndex[Offset++];
     }
   }
   N.Size = Offset - Origin;
   return N;
 }

 static bool startsWith(StringRef Name, StringRef Needle, bool Strict,
                        std::size_t &Consummed, char &PreviousCharInName,
                        char &PreviousCharInNeedle, bool IsPrefix = false) {

   Consummed = 0;
   if (Strict) {
     if (!Name.startswith(Needle))
       return false;
     Consummed = Needle.size();
     return true;
   }
   if (Needle.empty())
     return true;

   auto NamePos = Name.begin();
   auto NeedlePos = Needle.begin();

   char PreviousCharInNameOrigin = PreviousCharInName;
   char PreviousCharInNeedleOrigin = PreviousCharInNeedle;

   auto IgnoreSpaces = [](auto It, auto End, char &PreviousChar,
                          bool IgnoreEnd = false) {
     while (It != End) {
       const auto Next = std::next(It);
       // Ignore spaces, underscore, medial hyphens
       // https://unicode.org/reports/tr44/#UAX44-LM2.
       bool Ignore =
           *It == ' ' || *It == '_' ||
           (*It == '-' && isAlnum(PreviousChar) &&
            ((Next != End && isAlnum(*Next)) || (Next == End && IgnoreEnd)));
       PreviousChar = *It;
       if (!Ignore)
         break;
       ++It;
     }
     return It;
   };

   while (true) {
     NamePos = IgnoreSpaces(NamePos, Name.end(), PreviousCharInName);
     NeedlePos =
         IgnoreSpaces(NeedlePos, Needle.end(), PreviousCharInNeedle, IsPrefix);
     if (NeedlePos == Needle.end())
       break;
     if (NamePos == Name.end())
       break;
     if (toUpper(*NeedlePos) != toUpper(*NamePos))
       break;
     NeedlePos++;
     NamePos++;
   }
   Consummed = std::distance(Name.begin(), NamePos);
   if (NeedlePos != Needle.end()) {
     PreviousCharInName = PreviousCharInNameOrigin;
     PreviousCharInNeedle = PreviousCharInNeedleOrigin;
   }
   return NeedlePos == Needle.end();
 }

 static std::tuple<Node, bool, uint32_t>
 compareNode(uint32_t Offset, StringRef Name, bool Strict,
             char PreviousCharInName, char PreviousCharInNeedle,
             BufferType &Buffer, const Node *Parent = nullptr) {
   Node N = readNode(Offset, Parent);
   std::size_t Consummed = 0;
   bool DoesStartWith =
       N.IsRoot || startsWith(Name, N.Name, Strict, Consummed,
                              PreviousCharInName, PreviousCharInNeedle);
   if (!DoesStartWith)
     return std::make_tuple(N, false, 0);

   if (Name.size() - Consummed == 0 && N.Value != 0xFFFFFFFF)
     return std::make_tuple(N, true, N.Value);

   if (N.hasChildren()) {
     uint32_t ChildOffset = N.ChildrenOffset;
     for (;;) {
       Node C;
       bool Matches;
       uint32_t Value;
       std::tie(C, Matches, Value) =
           compareNode(ChildOffset, Name.substr(Consummed), Strict,
                       PreviousCharInName, PreviousCharInNeedle, Buffer, &N);
       if (Matches) {
         std::reverse_copy(C.Name.begin(), C.Name.end(),
                           std::back_inserter(Buffer));
         return std::make_tuple(N, true, Value);
       }
       ChildOffset += C.Size;
       if (!C.HasSibling)
         break;
     }
   }
   return std::make_tuple(N, false, 0);
 }

 static std::tuple<Node, bool, uint32_t>
 compareNode(uint32_t Offset, StringRef Name, bool Strict, BufferType &Buffer) {
   return compareNode(Offset, Name, Strict, 0, 0, Buffer);
 }

 // clang-format off
 constexpr const char *const HangulSyllables[][3] = {
     { "G",  "A",   ""   },
     { "GG", "AE",  "G"  },
     { "N",  "YA",  "GG" },
     { "D",  "YAE", "GS" },
     { "DD", "EO",  "N", },
     { "R",  "E",   "NJ" },
     { "M",  "YEO", "NH" },
     { "B",  "YE",  "D"  },
     { "BB", "O",   "L"  },
     { "S",  "WA",  "LG" },
     { "SS", "WAE", "LM" },
     { "",   "OE",  "LB" },
     { "J",  "YO",  "LS" },
     { "JJ", "U",   "LT" },
     { "C",  "WEO", "LP" },
     { "K",  "WE",  "LH" },
     { "T",  "WI",  "M"  },
     { "P",  "YU",  "B"  },
     { "H",  "EU",  "BS" },
     { 0,    "YI",  "S"  },
     { 0,    "I",   "SS" },
     { 0,    0,     "NG" },
     { 0,    0,     "J"  },
     { 0,    0,     "C"  },
     { 0,    0,     "K"  },
     { 0,    0,     "T"  },
     { 0,    0,     "P"  },
     { 0,    0,     "H"  }
     };
 // clang-format on

 // Unicode 15.0
 // 3.12 Conjoining Jamo Behavior Common constants
 constexpr const char32_t SBase = 0xAC00;
 constexpr const uint32_t LCount = 19;
 constexpr const uint32_t VCount = 21;
 constexpr const uint32_t TCount = 28;

 static std::size_t findSyllable(StringRef Name, bool Strict,
                                 char &PreviousInName, int &Pos, int Column) {
   assert(Column == 0 || Column == 1 || Column == 2);
   static std::size_t CountPerColumn[] = {LCount, VCount, TCount};
   char NeedleStart = 0;
   int Len = -1;
   int Prev = PreviousInName;
   for (std::size_t I = 0; I < CountPerColumn[Column]; I++) {
     StringRef Syllable(HangulSyllables[I][Column]);
     if (int(Syllable.size()) <= Len)
       continue;
     std::size_t Consummed = 0;
     char PreviousInNameCopy = PreviousInName;
     bool DoesStartWith = startsWith(Name, Syllable, Strict, Consummed,
                                     PreviousInNameCopy, NeedleStart);
     if (!DoesStartWith)
       continue;
     Len = Consummed;
     Pos = I;
     Prev = PreviousInNameCopy;
   }
   if (Len == -1)
     return 0;
   PreviousInName = Prev;
   return size_t(Len);
 }

 static std::optional<char32_t>
 nameToHangulCodePoint(StringRef Name, bool Strict, BufferType &Buffer) {
   Buffer.clear();
   // Hangul Syllable Decomposition
   std::size_t Consummed = 0;
   char NameStart = 0, NeedleStart = 0;
   bool DoesStartWith = startsWith(Name, "HANGUL SYLLABLE ", Strict, Consummed,
                                   NameStart, NeedleStart);
   if (!DoesStartWith)
     return std::nullopt;
   Name = Name.substr(Consummed);
   int L = -1, V = -1, T = -1;
   Name = Name.substr(findSyllable(Name, Strict, NameStart, L, 0));
   Name = Name.substr(findSyllable(Name, Strict, NameStart, V, 1));
   Name = Name.substr(findSyllable(Name, Strict, NameStart, T, 2));
   if (L != -1 && V != -1 && T != -1 && Name.empty()) {
     if (!Strict) {
       Buffer.append("HANGUL SYLLABLE ");
       if (L != -1)
         Buffer.append(HangulSyllables[L][0]);
       if (V != -1)
         Buffer.append(HangulSyllables[V][1]);
       if (T != -1)
         Buffer.append(HangulSyllables[T][2]);
     }
     return SBase + (std::uint32_t(L) * VCount + std::uint32_t(V)) * TCount +
            std::uint32_t(T);
   }
   // Otherwise, it's an illegal syllable name.
   return std::nullopt;
 }

 struct GeneratedNamesData {
   StringRef Prefix;
   uint32_t Start;
   uint32_t End;
 };

 // Unicode 15.0 Table 4-8. Name Derivation Rule Prefix Strings
 static const GeneratedNamesData GeneratedNamesDataTable[] = {
     {"CJK UNIFIED IDEOGRAPH-", 0x3400, 0x4DBF},
     {"CJK UNIFIED IDEOGRAPH-", 0x4E00, 0x9FFF},
     {"CJK UNIFIED IDEOGRAPH-", 0x20000, 0x2A6DF},
     {"CJK UNIFIED IDEOGRAPH-", 0x2A700, 0x2B739},
     {"CJK UNIFIED IDEOGRAPH-", 0x2B740, 0x2B81D},
     {"CJK UNIFIED IDEOGRAPH-", 0x2B820, 0x2CEA1},
     {"CJK UNIFIED IDEOGRAPH-", 0x2CEB0, 0x2EBE0},
     {"CJK UNIFIED IDEOGRAPH-", 0x30000, 0x3134A},
     {"CJK UNIFIED IDEOGRAPH-", 0x31350, 0x323AF},
     {"TANGUT IDEOGRAPH-", 0x17000, 0x187F7},
     {"TANGUT IDEOGRAPH-", 0x18D00, 0x18D08},
     {"KHITAN SMALL SCRIPT CHARACTER-", 0x18B00, 0x18CD5},
     {"NUSHU CHARACTER-", 0x1B170, 0x1B2FB},
     {"CJK COMPATIBILITY IDEOGRAPH-", 0xF900, 0xFA6D},
     {"CJK COMPATIBILITY IDEOGRAPH-", 0xFA70, 0xFAD9},
     {"CJK COMPATIBILITY IDEOGRAPH-", 0x2F800, 0x2FA1D},
 };

 static std::optional<char32_t>
 nameToGeneratedCodePoint(StringRef Name, bool Strict, BufferType &Buffer) {
   for (auto &&Item : GeneratedNamesDataTable) {
     Buffer.clear();
     std::size_t Consummed = 0;
     char NameStart = 0, NeedleStart = 0;
     bool DoesStartWith = startsWith(Name, Item.Prefix, Strict, Consummed,
                                     NameStart, NeedleStart, /*isPrefix*/ true);
     if (!DoesStartWith)
       continue;
     auto Number = Name.substr(Consummed);
     unsigned long long V = 0;
     // Be consistent about mandating upper casing.
     if (Strict &&
         llvm::any_of(Number, [](char C) { return C >= 'a' && C <= 'f'; }))
       return {};
     if (getAsUnsignedInteger(Number, 16, V) || V < Item.Start || V > Item.End)
       continue;
     if (!Strict) {
       Buffer.append(Item.Prefix);
       Buffer.append(utohexstr(V, true));
     }
     return V;
   }
   return std::nullopt;
 }

 static std::optional<char32_t> nameToCodepoint(StringRef Name, bool Strict,
                                                BufferType &Buffer) {
   if (Name.empty())
     return std::nullopt;

   std::optional<char32_t> Res = nameToHangulCodePoint(Name, Strict, Buffer);
   if (!Res)
     Res = nameToGeneratedCodePoint(Name, Strict, Buffer);
   if (Res)
     return *Res;

   Buffer.clear();
   Node Node;
   bool Matches;
   uint32_t Value;
   std::tie(Node, Matches, Value) = compareNode(0, Name, Strict, Buffer);
   if (Matches) {
     std::reverse(Buffer.begin(), Buffer.end());
     // UAX44-LM2. Ignore case, whitespace, underscore ('_'), and all medial
     // hyphens except the hyphen in U+1180 HANGUL JUNGSEONG O-E.
     if (!Strict && Value == 0x116c &&
         Name.find_insensitive("O-E") != StringRef::npos) {
       Buffer = "HANGUL JUNGSEONG O-E";
       Value = 0x1180;
     }
     return Value;
   }
   return std::nullopt;
 }

 std::optional<char32_t> nameToCodepointStrict(StringRef Name) {

   BufferType Buffer;
   auto Opt = nameToCodepoint(Name, true, Buffer);
   return Opt;
 }

 std::optional<LooseMatchingResult>
 nameToCodepointLooseMatching(StringRef Name) {
   BufferType Buffer;
   auto Opt = nameToCodepoint(Name, false, Buffer);
   if (!Opt)
     return std::nullopt;
   return LooseMatchingResult{*Opt, Buffer};
 }

 // Find the unicode character whose editing distance to Pattern
 // is shortest, using the Wagner–Fischer algorithm.
 llvm::SmallVector<MatchForCodepointName>
 nearestMatchesForCodepointName(StringRef Pattern, std::size_t MaxMatchesCount) {
   // We maintain a fixed size vector of matches,
   // sorted by distance
   // The worst match (with the biggest distance) are discarded when new elements
   // are added.
   std::size_t LargestEditDistance = 0;
   llvm::SmallVector<MatchForCodepointName> Matches;
   Matches.reserve(MaxMatchesCount + 1);

   auto Insert = [&](const Node &Node, uint32_t Distance,
                     char32_t Value) -> bool {
     if (Distance > LargestEditDistance) {
       if (Matches.size() == MaxMatchesCount)
         return false;
       LargestEditDistance = Distance;
     }
     // To avoid allocations, the creation of the name is delayed
     // as much as possible.
     std::string Name;
     auto GetName = [&] {
       if (Name.empty())
         Name = Node.fullName();
       return Name;
     };

     auto It = llvm::lower_bound(
         Matches, Distance,
         [&](const MatchForCodepointName &a, std::size_t Distance) {
           if (Distance == a.Distance)
             return a.Name < GetName();
           return a.Distance < Distance;
         });
     if (It == Matches.end() && Matches.size() == MaxMatchesCount)
       return false;

     MatchForCodepointName M{GetName(), Distance, Value};
     Matches.insert(It, std::move(M));
     if (Matches.size() > MaxMatchesCount)
       Matches.pop_back();
     return true;
   };

   // We ignore case, space, hyphens, etc,
   // in both the search pattern and the prospective names.
   auto Normalize = [](StringRef Name) {
     std::string Out;
     Out.reserve(Name.size());
     for (char C : Name) {
       if (isAlnum(C))
         Out.push_back(toUpper(C));
     }
     return Out;
   };
   std::string NormalizedName = Normalize(Pattern);

   // Allocate a matrix big enough for longest names.
   const std::size_t Columns =
       std::min(NormalizedName.size(), UnicodeNameToCodepointLargestNameSize) +
       1;

   LLVM_ATTRIBUTE_UNUSED static std::size_t Rows =
       UnicodeNameToCodepointLargestNameSize + 1;

   std::vector<char> Distances(
       Columns * (UnicodeNameToCodepointLargestNameSize + 1), 0);

   auto Get = [&Distances, Columns](size_t Column, std::size_t Row) -> char & {
     assert(Column < Columns);
     assert(Row < Rows);
     return Distances[Row * Columns + Column];
   };

   for (std::size_t I = 0; I < Columns; I++)
     Get(I, 0) = I;

   // Visit the childrens,
   // Filling (and overriding) the matrix for the name fragment of each node
   // iteratively. CompleteName is used to collect the actual name of potential
   // match, respecting case and spacing.
   auto VisitNode = [&](const Node &N, std::size_t Row,
                        auto &VisitNode) -> void {
     std::size_t J = 0;
     for (; J < N.Name.size(); J++) {
       if (!isAlnum(N.Name[J]))
         continue;

       Get(0, Row) = Row;

       for (std::size_t I = 1; I < Columns; I++) {
         const int Delete = Get(I - 1, Row) + 1;
         const int Insert = Get(I, Row - 1) + 1;

         const int Replace =
             Get(I - 1, Row - 1) + (NormalizedName[I - 1] != N.Name[J] ? 1 : 0);

         Get(I, Row) = std::min(Insert, std::min(Delete, Replace));
       }

       Row++;
     }

     unsigned Cost = Get(Columns - 1, Row - 1);
     if (N.Value != 0xFFFFFFFF) {
       Insert(N, Cost, N.Value);
     }

     if (N.hasChildren()) {
       auto ChildOffset = N.ChildrenOffset;
       for (;;) {
         Node C = readNode(ChildOffset, &N);
         ChildOffset += C.Size;
         if (!C.isValid())
           break;
         VisitNode(C, Row, VisitNode);
         if (!C.HasSibling)
           break;
       }
     }
   };

   Node Root = createRoot();
   VisitNode(Root, 1, VisitNode);
   return Matches;
 }

 } // namespace unicode

 } // namespace sys
 } // namespace llvm
	//===- llvm/Support/UnicodeNameToCodepoint.cpp - Unicode character properties
	//-- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements functions to map the name or alias of a unicode
	// character to its codepoint.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Unicode.h"

	namespace llvm {
	namespace sys {
	namespace unicode {

	extern const char *UnicodeNameToCodepointDict;
	extern const uint8_t *UnicodeNameToCodepointIndex;
	extern const std::size_t UnicodeNameToCodepointIndexSize;
	extern const std::size_t UnicodeNameToCodepointLargestNameSize;

	using BufferType = SmallString<64>;

	struct Node {
	bool IsRoot = false;
	char32_t Value = 0xFFFFFFFF;
	uint32_t ChildrenOffset = 0;
	bool HasSibling = false;
	uint32_t Size = 0;
	StringRef Name;
	const Node *Parent = nullptr;

	constexpr bool isValid() const {
	return !Name.empty() \|\| Value == 0xFFFFFFFF;
	}
	constexpr bool hasChildren() const { return ChildrenOffset != 0 \|\| IsRoot; }

	std::string fullName() const {
	std::string S;
	// Reserve enough space for most unicode code points.
	// The chosen value represent the 99th percentile of name size as of
	// Unicode 15.0.
	S.reserve(46);
	const Node *N = this;
	while (N) {
	std::reverse_copy(N->Name.begin(), N->Name.end(), std::back_inserter(S));
	N = N->Parent;
	}
	std::reverse(S.begin(), S.end());
	return S;
	}
	};

	static Node createRoot() {
	Node N;
	N.IsRoot = true;
	N.ChildrenOffset = 1;
	N.Size = 1;
	return N;
	}

	static Node readNode(uint32_t Offset, const Node *Parent = nullptr) {
	if (Offset == 0)
	return createRoot();

	uint32_t Origin = Offset;
	Node N;
	N.Parent = Parent;
	uint8_t NameInfo = UnicodeNameToCodepointIndex[Offset++];
	if (Offset + 6 >= UnicodeNameToCodepointIndexSize)
	return N;

	bool LongName = NameInfo & 0x40;
	bool HasValue = NameInfo & 0x80;
	std::size_t Size = NameInfo & ~0xC0;
	if (LongName) {
	uint32_t NameOffset = (UnicodeNameToCodepointIndex[Offset++] << 8);
	NameOffset \|= UnicodeNameToCodepointIndex[Offset++];
	N.Name = StringRef(UnicodeNameToCodepointDict + NameOffset, Size);
	} else {
	N.Name = StringRef(UnicodeNameToCodepointDict + Size, 1);
	}
	if (HasValue) {
	uint8_t H = UnicodeNameToCodepointIndex[Offset++];
	uint8_t M = UnicodeNameToCodepointIndex[Offset++];
	uint8_t L = UnicodeNameToCodepointIndex[Offset++];
	N.Value = ((H << 16) \| (M << 8) \| L) >> 3;

	bool HasChildren = L & 0x02;
	N.HasSibling = L & 0x01;

	if (HasChildren) {
	N.ChildrenOffset = UnicodeNameToCodepointIndex[Offset++] << 16;
	N.ChildrenOffset \|= UnicodeNameToCodepointIndex[Offset++] << 8;
	N.ChildrenOffset \|= UnicodeNameToCodepointIndex[Offset++];
	}
	} else {
	uint8_t H = UnicodeNameToCodepointIndex[Offset++];
	N.HasSibling = H & 0x80;
	bool HasChildren = H & 0x40;
	H &= uint8_t(~0xC0);
	if (HasChildren) {
	N.ChildrenOffset = (H << 16);
	N.ChildrenOffset \|=
	(uint32_t(UnicodeNameToCodepointIndex[Offset++]) << 8);
	N.ChildrenOffset \|= UnicodeNameToCodepointIndex[Offset++];
	}
	}
	N.Size = Offset - Origin;
	return N;
	}

	static bool startsWith(StringRef Name, StringRef Needle, bool Strict,
	std::size_t &Consummed, char &PreviousCharInName,
	char &PreviousCharInNeedle, bool IsPrefix = false) {

	Consummed = 0;
	if (Strict) {
	if (!Name.startswith(Needle))
	return false;
	Consummed = Needle.size();
	return true;
	}
	if (Needle.empty())
	return true;

	auto NamePos = Name.begin();
	auto NeedlePos = Needle.begin();

	char PreviousCharInNameOrigin = PreviousCharInName;
	char PreviousCharInNeedleOrigin = PreviousCharInNeedle;

	auto IgnoreSpaces = [](auto It, auto End, char &PreviousChar,
	bool IgnoreEnd = false) {
	while (It != End) {
	const auto Next = std::next(It);
	// Ignore spaces, underscore, medial hyphens
	// https://unicode.org/reports/tr44/#UAX44-LM2.
	bool Ignore =
	It == ' ' \|\| It == '_' \|\|
	(*It == '-' && isAlnum(PreviousChar) &&
	((Next != End && isAlnum(*Next)) \|\| (Next == End && IgnoreEnd)));
	PreviousChar = *It;
	if (!Ignore)
	break;
	++It;
	}
	return It;
	};

	while (true) {
	NamePos = IgnoreSpaces(NamePos, Name.end(), PreviousCharInName);
	NeedlePos =
	IgnoreSpaces(NeedlePos, Needle.end(), PreviousCharInNeedle, IsPrefix);
	if (NeedlePos == Needle.end())
	break;
	if (NamePos == Name.end())
	break;
	if (toUpper(NeedlePos) != toUpper(NamePos))
	break;
	NeedlePos++;
	NamePos++;
	}
	Consummed = std::distance(Name.begin(), NamePos);
	if (NeedlePos != Needle.end()) {
	PreviousCharInName = PreviousCharInNameOrigin;
	PreviousCharInNeedle = PreviousCharInNeedleOrigin;
	}
	return NeedlePos == Needle.end();
	}

	static std::tuple<Node, bool, uint32_t>
	compareNode(uint32_t Offset, StringRef Name, bool Strict,
	char PreviousCharInName, char PreviousCharInNeedle,
	BufferType &Buffer, const Node *Parent = nullptr) {
	Node N = readNode(Offset, Parent);
	std::size_t Consummed = 0;
	bool DoesStartWith =
	N.IsRoot \|\| startsWith(Name, N.Name, Strict, Consummed,
	PreviousCharInName, PreviousCharInNeedle);
	if (!DoesStartWith)
	return std::make_tuple(N, false, 0);

	if (Name.size() - Consummed == 0 && N.Value != 0xFFFFFFFF)
	return std::make_tuple(N, true, N.Value);

	if (N.hasChildren()) {
	uint32_t ChildOffset = N.ChildrenOffset;
	for (;;) {
	Node C;
	bool Matches;
	uint32_t Value;
	std::tie(C, Matches, Value) =
	compareNode(ChildOffset, Name.substr(Consummed), Strict,
	PreviousCharInName, PreviousCharInNeedle, Buffer, &N);
	if (Matches) {
	std::reverse_copy(C.Name.begin(), C.Name.end(),
	std::back_inserter(Buffer));
	return std::make_tuple(N, true, Value);
	}
	ChildOffset += C.Size;
	if (!C.HasSibling)
	break;
	}
	}
	return std::make_tuple(N, false, 0);
	}

	static std::tuple<Node, bool, uint32_t>
	compareNode(uint32_t Offset, StringRef Name, bool Strict, BufferType &Buffer) {
	return compareNode(Offset, Name, Strict, 0, 0, Buffer);
	}

	// clang-format off
	constexpr const char *const HangulSyllables[][3] = {
	{ "G", "A", "" },
	{ "GG", "AE", "G" },
	{ "N", "YA", "GG" },
	{ "D", "YAE", "GS" },
	{ "DD", "EO", "N", },
	{ "R", "E", "NJ" },
	{ "M", "YEO", "NH" },
	{ "B", "YE", "D" },
	{ "BB", "O", "L" },
	{ "S", "WA", "LG" },
	{ "SS", "WAE", "LM" },
	{ "", "OE", "LB" },
	{ "J", "YO", "LS" },
	{ "JJ", "U", "LT" },
	{ "C", "WEO", "LP" },
	{ "K", "WE", "LH" },
	{ "T", "WI", "M" },
	{ "P", "YU", "B" },
	{ "H", "EU", "BS" },
	{ 0, "YI", "S" },
	{ 0, "I", "SS" },
	{ 0, 0, "NG" },
	{ 0, 0, "J" },
	{ 0, 0, "C" },
	{ 0, 0, "K" },
	{ 0, 0, "T" },
	{ 0, 0, "P" },
	{ 0, 0, "H" }
	};
	// clang-format on

	// Unicode 15.0
	// 3.12 Conjoining Jamo Behavior Common constants
	constexpr const char32_t SBase = 0xAC00;
	constexpr const uint32_t LCount = 19;
	constexpr const uint32_t VCount = 21;
	constexpr const uint32_t TCount = 28;

	static std::size_t findSyllable(StringRef Name, bool Strict,
	char &PreviousInName, int &Pos, int Column) {
	assert(Column == 0 \|\| Column == 1 \|\| Column == 2);
	static std::size_t CountPerColumn[] = {LCount, VCount, TCount};
	char NeedleStart = 0;
	int Len = -1;
	int Prev = PreviousInName;
	for (std::size_t I = 0; I < CountPerColumn[Column]; I++) {
	StringRef Syllable(HangulSyllables[I][Column]);
	if (int(Syllable.size()) <= Len)
	continue;
	std::size_t Consummed = 0;
	char PreviousInNameCopy = PreviousInName;
	bool DoesStartWith = startsWith(Name, Syllable, Strict, Consummed,
	PreviousInNameCopy, NeedleStart);
	if (!DoesStartWith)
	continue;
	Len = Consummed;
	Pos = I;
	Prev = PreviousInNameCopy;
	}
	if (Len == -1)
	return 0;
	PreviousInName = Prev;
	return size_t(Len);
	}

	static std::optional<char32_t>
	nameToHangulCodePoint(StringRef Name, bool Strict, BufferType &Buffer) {
	Buffer.clear();
	// Hangul Syllable Decomposition
	std::size_t Consummed = 0;
	char NameStart = 0, NeedleStart = 0;
	bool DoesStartWith = startsWith(Name, "HANGUL SYLLABLE ", Strict, Consummed,
	NameStart, NeedleStart);
	if (!DoesStartWith)
	return std::nullopt;
	Name = Name.substr(Consummed);
	int L = -1, V = -1, T = -1;
	Name = Name.substr(findSyllable(Name, Strict, NameStart, L, 0));
	Name = Name.substr(findSyllable(Name, Strict, NameStart, V, 1));
	Name = Name.substr(findSyllable(Name, Strict, NameStart, T, 2));
	if (L != -1 && V != -1 && T != -1 && Name.empty()) {
	if (!Strict) {
	Buffer.append("HANGUL SYLLABLE ");
	if (L != -1)
	Buffer.append(HangulSyllables[L][0]);
	if (V != -1)
	Buffer.append(HangulSyllables[V][1]);
	if (T != -1)
	Buffer.append(HangulSyllables[T][2]);
	}
	return SBase + (std::uint32_t(L) * VCount + std::uint32_t(V)) * TCount +
	std::uint32_t(T);
	}
	// Otherwise, it's an illegal syllable name.
	return std::nullopt;
	}

	struct GeneratedNamesData {
	StringRef Prefix;
	uint32_t Start;
	uint32_t End;
	};

	// Unicode 15.0 Table 4-8. Name Derivation Rule Prefix Strings
	static const GeneratedNamesData GeneratedNamesDataTable[] = {
	{"CJK UNIFIED IDEOGRAPH-", 0x3400, 0x4DBF},
	{"CJK UNIFIED IDEOGRAPH-", 0x4E00, 0x9FFF},
	{"CJK UNIFIED IDEOGRAPH-", 0x20000, 0x2A6DF},
	{"CJK UNIFIED IDEOGRAPH-", 0x2A700, 0x2B739},
	{"CJK UNIFIED IDEOGRAPH-", 0x2B740, 0x2B81D},
	{"CJK UNIFIED IDEOGRAPH-", 0x2B820, 0x2CEA1},
	{"CJK UNIFIED IDEOGRAPH-", 0x2CEB0, 0x2EBE0},
	{"CJK UNIFIED IDEOGRAPH-", 0x30000, 0x3134A},
	{"CJK UNIFIED IDEOGRAPH-", 0x31350, 0x323AF},
	{"TANGUT IDEOGRAPH-", 0x17000, 0x187F7},
	{"TANGUT IDEOGRAPH-", 0x18D00, 0x18D08},
	{"KHITAN SMALL SCRIPT CHARACTER-", 0x18B00, 0x18CD5},
	{"NUSHU CHARACTER-", 0x1B170, 0x1B2FB},
	{"CJK COMPATIBILITY IDEOGRAPH-", 0xF900, 0xFA6D},
	{"CJK COMPATIBILITY IDEOGRAPH-", 0xFA70, 0xFAD9},
	{"CJK COMPATIBILITY IDEOGRAPH-", 0x2F800, 0x2FA1D},
	};

	static std::optional<char32_t>
	nameToGeneratedCodePoint(StringRef Name, bool Strict, BufferType &Buffer) {
	for (auto &&Item : GeneratedNamesDataTable) {
	Buffer.clear();
	std::size_t Consummed = 0;
	char NameStart = 0, NeedleStart = 0;
	bool DoesStartWith = startsWith(Name, Item.Prefix, Strict, Consummed,
	NameStart, NeedleStart, /isPrefix/ true);
	if (!DoesStartWith)
	continue;
	auto Number = Name.substr(Consummed);
	unsigned long long V = 0;
	// Be consistent about mandating upper casing.
	if (Strict &&
	llvm::any_of(Number, [](char C) { return C >= 'a' && C <= 'f'; }))
	return {};
	if (getAsUnsignedInteger(Number, 16, V) \|\| V < Item.Start \|\| V > Item.End)
	continue;
	if (!Strict) {
	Buffer.append(Item.Prefix);
	Buffer.append(utohexstr(V, true));
	}
	return V;
	}
	return std::nullopt;
	}

	static std::optional<char32_t> nameToCodepoint(StringRef Name, bool Strict,
	BufferType &Buffer) {
	if (Name.empty())
	return std::nullopt;

	std::optional<char32_t> Res = nameToHangulCodePoint(Name, Strict, Buffer);
	if (!Res)
	Res = nameToGeneratedCodePoint(Name, Strict, Buffer);
	if (Res)
	return *Res;

	Buffer.clear();
	Node Node;
	bool Matches;
	uint32_t Value;
	std::tie(Node, Matches, Value) = compareNode(0, Name, Strict, Buffer);
	if (Matches) {
	std::reverse(Buffer.begin(), Buffer.end());
	// UAX44-LM2. Ignore case, whitespace, underscore ('_'), and all medial
	// hyphens except the hyphen in U+1180 HANGUL JUNGSEONG O-E.
	if (!Strict && Value == 0x116c &&
	Name.find_insensitive("O-E") != StringRef::npos) {
	Buffer = "HANGUL JUNGSEONG O-E";
	Value = 0x1180;
	}
	return Value;
	}
	return std::nullopt;
	}

	std::optional<char32_t> nameToCodepointStrict(StringRef Name) {

	BufferType Buffer;
	auto Opt = nameToCodepoint(Name, true, Buffer);
	return Opt;
	}

	std::optional<LooseMatchingResult>
	nameToCodepointLooseMatching(StringRef Name) {
	BufferType Buffer;
	auto Opt = nameToCodepoint(Name, false, Buffer);
	if (!Opt)
	return std::nullopt;
	return LooseMatchingResult{*Opt, Buffer};
	}

	// Find the unicode character whose editing distance to Pattern
	// is shortest, using the Wagner–Fischer algorithm.
	llvm::SmallVector<MatchForCodepointName>
	nearestMatchesForCodepointName(StringRef Pattern, std::size_t MaxMatchesCount) {
	// We maintain a fixed size vector of matches,
	// sorted by distance
	// The worst match (with the biggest distance) are discarded when new elements
	// are added.
	std::size_t LargestEditDistance = 0;
	llvm::SmallVector<MatchForCodepointName> Matches;
	Matches.reserve(MaxMatchesCount + 1);

	auto Insert = [&](const Node &Node, uint32_t Distance,
	char32_t Value) -> bool {
	if (Distance > LargestEditDistance) {
	if (Matches.size() == MaxMatchesCount)
	return false;
	LargestEditDistance = Distance;
	}
	// To avoid allocations, the creation of the name is delayed
	// as much as possible.
	std::string Name;
	auto GetName = [&] {
	if (Name.empty())
	Name = Node.fullName();
	return Name;
	};

	auto It = llvm::lower_bound(
	Matches, Distance,
	[&](const MatchForCodepointName &a, std::size_t Distance) {
	if (Distance == a.Distance)
	return a.Name < GetName();
	return a.Distance < Distance;
	});
	if (It == Matches.end() && Matches.size() == MaxMatchesCount)
	return false;

	MatchForCodepointName M{GetName(), Distance, Value};
	Matches.insert(It, std::move(M));
	if (Matches.size() > MaxMatchesCount)
	Matches.pop_back();
	return true;
	};

	// We ignore case, space, hyphens, etc,
	// in both the search pattern and the prospective names.
	auto Normalize = [](StringRef Name) {
	std::string Out;
	Out.reserve(Name.size());
	for (char C : Name) {
	if (isAlnum(C))
	Out.push_back(toUpper(C));
	}
	return Out;
	};
	std::string NormalizedName = Normalize(Pattern);

	// Allocate a matrix big enough for longest names.
	const std::size_t Columns =
	std::min(NormalizedName.size(), UnicodeNameToCodepointLargestNameSize) +
	1;

	LLVM_ATTRIBUTE_UNUSED static std::size_t Rows =
	UnicodeNameToCodepointLargestNameSize + 1;

	std::vector<char> Distances(
	Columns * (UnicodeNameToCodepointLargestNameSize + 1), 0);

	auto Get = [&Distances, Columns](size_t Column, std::size_t Row) -> char & {
	assert(Column < Columns);
	assert(Row < Rows);
	return Distances[Row * Columns + Column];
	};

	for (std::size_t I = 0; I < Columns; I++)
	Get(I, 0) = I;

	// Visit the childrens,
	// Filling (and overriding) the matrix for the name fragment of each node
	// iteratively. CompleteName is used to collect the actual name of potential
	// match, respecting case and spacing.
	auto VisitNode = [&](const Node &N, std::size_t Row,
	auto &VisitNode) -> void {
	std::size_t J = 0;
	for (; J < N.Name.size(); J++) {
	if (!isAlnum(N.Name[J]))
	continue;

	Get(0, Row) = Row;

	for (std::size_t I = 1; I < Columns; I++) {
	const int Delete = Get(I - 1, Row) + 1;
	const int Insert = Get(I, Row - 1) + 1;

	const int Replace =
	Get(I - 1, Row - 1) + (NormalizedName[I - 1] != N.Name[J] ? 1 : 0);

	Get(I, Row) = std::min(Insert, std::min(Delete, Replace));
	}

	Row++;
	}

	unsigned Cost = Get(Columns - 1, Row - 1);
	if (N.Value != 0xFFFFFFFF) {
	Insert(N, Cost, N.Value);
	}

	if (N.hasChildren()) {
	auto ChildOffset = N.ChildrenOffset;
	for (;;) {
	Node C = readNode(ChildOffset, &N);
	ChildOffset += C.Size;
	if (!C.isValid())
	break;
	VisitNode(C, Row, VisitNode);
	if (!C.HasSibling)
	break;
	}
	}
	};

	Node Root = createRoot();
	VisitNode(Root, 1, VisitNode);
	return Matches;
	}

	} // namespace unicode

	} // namespace sys
	} // namespace llvm