//===-- StringRef.cpp - Lightweight String References ---------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "llvm/ADT/StringRef.h" #include "llvm/ADT/APInt.h" #include "llvm/ADT/OwningPtr.h" #include <bitset> using namespace llvm; // MSVC emits references to this into the translation units which reference it. #ifndef _MSC_VER const size_t StringRef::npos; #endif static char ascii_tolower(char x) { if (x >= 'A' && x <= 'Z') return x - 'A' + 'a'; return x; } static bool ascii_isdigit(char x) { return x >= '0' && x <= '9'; } /// compare_lower - Compare strings, ignoring case. int StringRef::compare_lower(StringRef RHS) const { for (size_t I = 0, E = min(Length, RHS.Length); I != E; ++I) { unsigned char LHC = ascii_tolower(Data[I]); unsigned char RHC = ascii_tolower(RHS.Data[I]); if (LHC != RHC) return LHC < RHC ? -1 : 1; } if (Length == RHS.Length) return 0; return Length < RHS.Length ? -1 : 1; } /// compare_numeric - Compare strings, handle embedded numbers. int StringRef::compare_numeric(StringRef RHS) const { for (size_t I = 0, E = min(Length, RHS.Length); I != E; ++I) { // Check for sequences of digits. if (ascii_isdigit(Data[I]) && ascii_isdigit(RHS.Data[I])) { // The longer sequence of numbers is considered larger. // This doesn't really handle prefixed zeros well. size_t J; for (J = I + 1; J != E + 1; ++J) { bool ld = J < Length && ascii_isdigit(Data[J]); bool rd = J < RHS.Length && ascii_isdigit(RHS.Data[J]); if (ld != rd) return rd ? -1 : 1; if (!rd) break; } // The two number sequences have the same length (J-I), just memcmp them. if (int Res = compareMemory(Data + I, RHS.Data + I, J - I)) return Res < 0 ? -1 : 1; // Identical number sequences, continue search after the numbers. I = J - 1; continue; } if (Data[I] != RHS.Data[I]) return (unsigned char)Data[I] < (unsigned char)RHS.Data[I] ? -1 : 1; } if (Length == RHS.Length) return 0; return Length < RHS.Length ? -1 : 1; } // Compute the edit distance between the two given strings. unsigned StringRef::edit_distance(llvm::StringRef Other, bool AllowReplacements, unsigned MaxEditDistance) { // The algorithm implemented below is the "classic" // dynamic-programming algorithm for computing the Levenshtein // distance, which is described here: // // http://en.wikipedia.org/wiki/Levenshtein_distance // // Although the algorithm is typically described using an m x n // array, only two rows are used at a time, so this implemenation // just keeps two separate vectors for those two rows. size_type m = size(); size_type n = Other.size(); const unsigned SmallBufferSize = 64; unsigned SmallBuffer[SmallBufferSize]; llvm::OwningArrayPtr<unsigned> Allocated; unsigned *previous = SmallBuffer; if (2*(n + 1) > SmallBufferSize) { previous = new unsigned [2*(n+1)]; Allocated.reset(previous); } unsigned *current = previous + (n + 1); for (unsigned i = 0; i <= n; ++i) previous[i] = i; for (size_type y = 1; y <= m; ++y) { current[0] = y; unsigned BestThisRow = current[0]; for (size_type x = 1; x <= n; ++x) { if (AllowReplacements) { current[x] = min(previous[x-1] + ((*this)[y-1] == Other[x-1]? 0u:1u), min(current[x-1], previous[x])+1); } else { if ((*this)[y-1] == Other[x-1]) current[x] = previous[x-1]; else current[x] = min(current[x-1], previous[x]) + 1; } BestThisRow = min(BestThisRow, current[x]); } if (MaxEditDistance && BestThisRow > MaxEditDistance) return MaxEditDistance + 1; unsigned *tmp = current; current = previous; previous = tmp; } unsigned Result = previous[n]; return Result; } //===----------------------------------------------------------------------===// // String Searching //===----------------------------------------------------------------------===// /// find - Search for the first string \arg Str in the string. /// /// \return - The index of the first occurrence of \arg Str, or npos if not /// found. size_t StringRef::find(StringRef Str, size_t From) const { size_t N = Str.size(); if (N > Length) return npos; for (size_t e = Length - N + 1, i = min(From, e); i != e; ++i) if (substr(i, N).equals(Str)) return i; return npos; } /// rfind - Search for the last string \arg Str in the string. /// /// \return - The index of the last occurrence of \arg Str, or npos if not /// found. size_t StringRef::rfind(StringRef Str) const { size_t N = Str.size(); if (N > Length) return npos; for (size_t i = Length - N + 1, e = 0; i != e;) { --i; if (substr(i, N).equals(Str)) return i; } return npos; } /// find_first_of - Find the first character in the string that is in \arg /// Chars, or npos if not found. /// /// Note: O(size() + Chars.size()) StringRef::size_type StringRef::find_first_of(StringRef Chars, size_t From) const { std::bitset<1 << CHAR_BIT> CharBits; for (size_type i = 0; i != Chars.size(); ++i) CharBits.set((unsigned char)Chars[i]); for (size_type i = min(From, Length), e = Length; i != e; ++i) if (CharBits.test((unsigned char)Data[i])) return i; return npos; } /// find_first_not_of - Find the first character in the string that is not /// \arg C or npos if not found. StringRef::size_type StringRef::find_first_not_of(char C, size_t From) const { for (size_type i = min(From, Length), e = Length; i != e; ++i) if (Data[i] != C) return i; return npos; } /// find_first_not_of - Find the first character in the string that is not /// in the string \arg Chars, or npos if not found. /// /// Note: O(size() + Chars.size()) StringRef::size_type StringRef::find_first_not_of(StringRef Chars, size_t From) const { std::bitset<1 << CHAR_BIT> CharBits; for (size_type i = 0; i != Chars.size(); ++i) CharBits.set((unsigned char)Chars[i]); for (size_type i = min(From, Length), e = Length; i != e; ++i) if (!CharBits.test((unsigned char)Data[i])) return i; return npos; } /// find_last_of - Find the last character in the string that is in \arg C, /// or npos if not found. /// /// Note: O(size() + Chars.size()) StringRef::size_type StringRef::find_last_of(StringRef Chars, size_t From) const { std::bitset<1 << CHAR_BIT> CharBits; for (size_type i = 0; i != Chars.size(); ++i) CharBits.set((unsigned char)Chars[i]); for (size_type i = min(From, Length) - 1, e = -1; i != e; --i) if (CharBits.test((unsigned char)Data[i])) return i; return npos; } //===----------------------------------------------------------------------===// // Helpful Algorithms //===----------------------------------------------------------------------===// /// count - Return the number of non-overlapped occurrences of \arg Str in /// the string. size_t StringRef::count(StringRef Str) const { size_t Count = 0; size_t N = Str.size(); if (N > Length) return 0; for (size_t i = 0, e = Length - N + 1; i != e; ++i) if (substr(i, N).equals(Str)) ++Count; return Count; } static unsigned GetAutoSenseRadix(StringRef &Str) { if (Str.startswith("0x")) { Str = Str.substr(2); return 16; } else if (Str.startswith("0b")) { Str = Str.substr(2); return 2; } else if (Str.startswith("0")) { return 8; } else { return 10; } } /// GetAsUnsignedInteger - Workhorse method that converts a integer character /// sequence of radix up to 36 to an unsigned long long value. static bool GetAsUnsignedInteger(StringRef Str, unsigned Radix, unsigned long long &Result) { // Autosense radix if not specified. if (Radix == 0) Radix = GetAutoSenseRadix(Str); // Empty strings (after the radix autosense) are invalid. if (Str.empty()) return true; // Parse all the bytes of the string given this radix. Watch for overflow. Result = 0; while (!Str.empty()) { unsigned CharVal; if (Str[0] >= '0' && Str[0] <= '9') CharVal = Str[0]-'0'; else if (Str[0] >= 'a' && Str[0] <= 'z') CharVal = Str[0]-'a'+10; else if (Str[0] >= 'A' && Str[0] <= 'Z') CharVal = Str[0]-'A'+10; else return true; // If the parsed value is larger than the integer radix, the string is // invalid. if (CharVal >= Radix) return true; // Add in this character. unsigned long long PrevResult = Result; Result = Result*Radix+CharVal; // Check for overflow. if (Result < PrevResult) return true; Str = Str.substr(1); } return false; } bool StringRef::getAsInteger(unsigned Radix, unsigned long long &Result) const { return GetAsUnsignedInteger(*this, Radix, Result); } bool StringRef::getAsInteger(unsigned Radix, long long &Result) const { unsigned long long ULLVal; // Handle positive strings first. if (empty() || front() != '-') { if (GetAsUnsignedInteger(*this, Radix, ULLVal) || // Check for value so large it overflows a signed value. (long long)ULLVal < 0) return true; Result = ULLVal; return false; } // Get the positive part of the value. if (GetAsUnsignedInteger(substr(1), Radix, ULLVal) || // Reject values so large they'd overflow as negative signed, but allow // "-0". This negates the unsigned so that the negative isn't undefined // on signed overflow. (long long)-ULLVal > 0) return true; Result = -ULLVal; return false; } bool StringRef::getAsInteger(unsigned Radix, int &Result) const { long long Val; if (getAsInteger(Radix, Val) || (int)Val != Val) return true; Result = Val; return false; } bool StringRef::getAsInteger(unsigned Radix, unsigned &Result) const { unsigned long long Val; if (getAsInteger(Radix, Val) || (unsigned)Val != Val) return true; Result = Val; return false; } bool StringRef::getAsInteger(unsigned Radix, APInt &Result) const { StringRef Str = *this; // Autosense radix if not specified. if (Radix == 0) Radix = GetAutoSenseRadix(Str); assert(Radix > 1 && Radix <= 36); // Empty strings (after the radix autosense) are invalid. if (Str.empty()) return true; // Skip leading zeroes. This can be a significant improvement if // it means we don't need > 64 bits. while (!Str.empty() && Str.front() == '0') Str = Str.substr(1); // If it was nothing but zeroes.... if (Str.empty()) { Result = APInt(64, 0); return false; } // (Over-)estimate the required number of bits. unsigned Log2Radix = 0; while ((1U << Log2Radix) < Radix) Log2Radix++; bool IsPowerOf2Radix = ((1U << Log2Radix) == Radix); unsigned BitWidth = Log2Radix * Str.size(); if (BitWidth < Result.getBitWidth()) BitWidth = Result.getBitWidth(); // don't shrink the result else Result = Result.zext(BitWidth); APInt RadixAP, CharAP; // unused unless !IsPowerOf2Radix if (!IsPowerOf2Radix) { // These must have the same bit-width as Result. RadixAP = APInt(BitWidth, Radix); CharAP = APInt(BitWidth, 0); } // Parse all the bytes of the string given this radix. Result = 0; while (!Str.empty()) { unsigned CharVal; if (Str[0] >= '0' && Str[0] <= '9') CharVal = Str[0]-'0'; else if (Str[0] >= 'a' && Str[0] <= 'z') CharVal = Str[0]-'a'+10; else if (Str[0] >= 'A' && Str[0] <= 'Z') CharVal = Str[0]-'A'+10; else return true; // If the parsed value is larger than the integer radix, the string is // invalid. if (CharVal >= Radix) return true; // Add in this character. if (IsPowerOf2Radix) { Result <<= Log2Radix; Result |= CharVal; } else { Result *= RadixAP; CharAP = CharVal; Result += CharAP; } Str = Str.substr(1); } return false; }