//===- StringTableBuilder.cpp - String table building utility -------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "llvm/MC/StringTableBuilder.h" #include "llvm/ADT/CachedHashString.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringRef.h" #include "llvm/BinaryFormat/COFF.h" #include "llvm/Support/Endian.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include #include #include using namespace llvm; StringTableBuilder::~StringTableBuilder() = default; void StringTableBuilder::initSize() { // Account for leading bytes in table so that offsets returned from add are // correct. switch (K) { case RAW: case DWARF: Size = 0; break; case MachO: case ELF: // Start the table with a NUL byte. Size = 1; break; case WinCOFF: // Make room to write the table size later. Size = 4; break; } } StringTableBuilder::StringTableBuilder(Kind K, unsigned Alignment) : K(K), Alignment(Alignment) { initSize(); } void StringTableBuilder::write(raw_ostream &OS) const { assert(isFinalized()); SmallString<0> Data; Data.resize(getSize()); write((uint8_t *)Data.data()); OS << Data; } using StringPair = std::pair; void StringTableBuilder::write(uint8_t *Buf) const { assert(isFinalized()); for (const StringPair &P : StringIndexMap) { StringRef Data = P.first.val(); if (!Data.empty()) memcpy(Buf + P.second, Data.data(), Data.size()); } if (K != WinCOFF) return; support::endian::write32le(Buf, Size); } // Returns the character at Pos from end of a string. static int charTailAt(StringPair *P, size_t Pos) { StringRef S = P->first.val(); if (Pos >= S.size()) return -1; return (unsigned char)S[S.size() - Pos - 1]; } // Three-way radix quicksort. This is much faster than std::sort with strcmp // because it does not compare characters that we already know the same. static void multikeySort(MutableArrayRef Vec, int Pos) { tailcall: if (Vec.size() <= 1) return; // Partition items so that items in [0, I) are greater than the pivot, // [I, J) are the same as the pivot, and [J, Vec.size()) are less than // the pivot. int Pivot = charTailAt(Vec[0], Pos); size_t I = 0; size_t J = Vec.size(); for (size_t K = 1; K < J;) { int C = charTailAt(Vec[K], Pos); if (C > Pivot) std::swap(Vec[I++], Vec[K++]); else if (C < Pivot) std::swap(Vec[--J], Vec[K]); else K++; } multikeySort(Vec.slice(0, I), Pos); multikeySort(Vec.slice(J), Pos); // multikeySort(Vec.slice(I, J - I), Pos + 1), but with // tail call optimization. if (Pivot != -1) { Vec = Vec.slice(I, J - I); ++Pos; goto tailcall; } } void StringTableBuilder::finalize() { assert(K != DWARF); finalizeStringTable(/*Optimize=*/true); } void StringTableBuilder::finalizeInOrder() { finalizeStringTable(/*Optimize=*/false); } void StringTableBuilder::finalizeStringTable(bool Optimize) { Finalized = true; if (Optimize) { std::vector Strings; Strings.reserve(StringIndexMap.size()); for (StringPair &P : StringIndexMap) Strings.push_back(&P); multikeySort(Strings, 0); initSize(); StringRef Previous; for (StringPair *P : Strings) { StringRef S = P->first.val(); if (Previous.endswith(S)) { size_t Pos = Size - S.size() - (K != RAW); if (!(Pos & (Alignment - 1))) { P->second = Pos; continue; } } Size = alignTo(Size, Alignment); P->second = Size; Size += S.size(); if (K != RAW) ++Size; Previous = S; } } if (K == MachO) Size = alignTo(Size, 4); // Pad to multiple of 4. } void StringTableBuilder::clear() { Finalized = false; StringIndexMap.clear(); } size_t StringTableBuilder::getOffset(CachedHashStringRef S) const { assert(isFinalized()); auto I = StringIndexMap.find(S); assert(I != StringIndexMap.end() && "String is not in table!"); return I->second; } size_t StringTableBuilder::add(CachedHashStringRef S) { if (K == WinCOFF) assert(S.size() > COFF::NameSize && "Short string in COFF string table!"); assert(!isFinalized()); auto P = StringIndexMap.insert(std::make_pair(S, 0)); if (P.second) { size_t Start = alignTo(Size, Alignment); P.first->second = Start; Size = Start + S.size() + (K != RAW); } return P.first->second; }