/* * Copyright (C) 1999-2000 Harri Porten (porten@kde.org) * Copyright (C) 2004, 2005, 2006, 2007, 2008, 2009 Apple Inc. All rights reserved. * Copyright (C) 2007 Cameron Zwarich (cwzwarich@uwaterloo.ca) * Copyright (C) 2009 Google Inc. All rights reserved. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include "config.h" #include "UString.h" #include "JSGlobalObjectFunctions.h" #include "Collector.h" #include "dtoa.h" #include "Identifier.h" #include "Operations.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if HAVE(STRINGS_H) #include #endif using namespace WTF; using namespace WTF::Unicode; using namespace std; namespace JSC { extern const double NaN; extern const double Inf; CString::CString(const char* c) : m_length(strlen(c)) , m_data(new char[m_length + 1]) { memcpy(m_data, c, m_length + 1); } CString::CString(const char* c, size_t length) : m_length(length) , m_data(new char[length + 1]) { memcpy(m_data, c, m_length); m_data[m_length] = 0; } CString::CString(const CString& b) { m_length = b.m_length; if (b.m_data) { m_data = new char[m_length + 1]; memcpy(m_data, b.m_data, m_length + 1); } else m_data = 0; } CString::~CString() { delete [] m_data; } CString CString::adopt(char* c, size_t length) { CString s; s.m_data = c; s.m_length = length; return s; } CString& CString::append(const CString& t) { char* n; n = new char[m_length + t.m_length + 1]; if (m_length) memcpy(n, m_data, m_length); if (t.m_length) memcpy(n + m_length, t.m_data, t.m_length); m_length += t.m_length; n[m_length] = 0; delete [] m_data; m_data = n; return *this; } CString& CString::operator=(const char* c) { if (m_data) delete [] m_data; m_length = strlen(c); m_data = new char[m_length + 1]; memcpy(m_data, c, m_length + 1); return *this; } CString& CString::operator=(const CString& str) { if (this == &str) return *this; if (m_data) delete [] m_data; m_length = str.m_length; if (str.m_data) { m_data = new char[m_length + 1]; memcpy(m_data, str.m_data, m_length + 1); } else m_data = 0; return *this; } bool operator==(const CString& c1, const CString& c2) { size_t len = c1.size(); return len == c2.size() && (len == 0 || memcmp(c1.c_str(), c2.c_str(), len) == 0); } // These static strings are immutable, except for rc, whose initial value is chosen to // reduce the possibility of it becoming zero due to ref/deref not being thread-safe. static UChar sharedEmptyChar; UStringImpl* UStringImpl::s_empty; UString::Rep* UString::s_nullRep; UString* UString::s_nullUString; void initializeUString() { UStringImpl::s_empty = new UStringImpl(&sharedEmptyChar, 0, UStringImpl::ConstructStaticString); UString::s_nullRep = new UStringImpl(0, 0, UStringImpl::ConstructStaticString); UString::s_nullUString = new UString; } UString::UString(const char* c) : m_rep(Rep::create(c)) { } UString::UString(const char* c, int length) : m_rep(Rep::create(c, length)) { } UString::UString(const UChar* c, int length) { if (length == 0) m_rep = &Rep::empty(); else m_rep = Rep::create(c, length); } UString UString::from(int i) { UChar buf[1 + sizeof(i) * 3]; UChar* end = buf + sizeof(buf) / sizeof(UChar); UChar* p = end; if (i == 0) *--p = '0'; else if (i == INT_MIN) { char minBuf[1 + sizeof(i) * 3]; sprintf(minBuf, "%d", INT_MIN); return UString(minBuf); } else { bool negative = false; if (i < 0) { negative = true; i = -i; } while (i) { *--p = static_cast((i % 10) + '0'); i /= 10; } if (negative) *--p = '-'; } return UString(p, static_cast(end - p)); } UString UString::from(long long i) { UChar buf[1 + sizeof(i) * 3]; UChar* end = buf + sizeof(buf) / sizeof(UChar); UChar* p = end; if (i == 0) *--p = '0'; else if (i == std::numeric_limits::min()) { char minBuf[1 + sizeof(i) * 3]; #if OS(WINDOWS) snprintf(minBuf, sizeof(minBuf) - 1, "%I64d", std::numeric_limits::min()); #else snprintf(minBuf, sizeof(minBuf) - 1, "%lld", std::numeric_limits::min()); #endif return UString(minBuf); } else { bool negative = false; if (i < 0) { negative = true; i = -i; } while (i) { *--p = static_cast((i % 10) + '0'); i /= 10; } if (negative) *--p = '-'; } return UString(p, static_cast(end - p)); } UString UString::from(unsigned int u) { UChar buf[sizeof(u) * 3]; UChar* end = buf + sizeof(buf) / sizeof(UChar); UChar* p = end; if (u == 0) *--p = '0'; else { while (u) { *--p = static_cast((u % 10) + '0'); u /= 10; } } return UString(p, static_cast(end - p)); } UString UString::from(long l) { UChar buf[1 + sizeof(l) * 3]; UChar* end = buf + sizeof(buf) / sizeof(UChar); UChar* p = end; if (l == 0) *--p = '0'; else if (l == LONG_MIN) { char minBuf[1 + sizeof(l) * 3]; sprintf(minBuf, "%ld", LONG_MIN); return UString(minBuf); } else { bool negative = false; if (l < 0) { negative = true; l = -l; } while (l) { *--p = static_cast((l % 10) + '0'); l /= 10; } if (negative) *--p = '-'; } return UString(p, static_cast(end - p)); } UString UString::from(double d) { DtoaBuffer buffer; unsigned length; doubleToStringInJavaScriptFormat(d, buffer, &length); return UString(buffer, length); } bool UString::getCString(CStringBuffer& buffer) const { int length = size(); int neededSize = length + 1; buffer.resize(neededSize); char* buf = buffer.data(); UChar ored = 0; const UChar* p = data(); char* q = buf; const UChar* limit = p + length; while (p != limit) { UChar c = p[0]; ored |= c; *q = static_cast(c); ++p; ++q; } *q = '\0'; return !(ored & 0xFF00); } char* UString::ascii() const { static char* asciiBuffer = 0; int length = size(); int neededSize = length + 1; delete[] asciiBuffer; asciiBuffer = new char[neededSize]; const UChar* p = data(); char* q = asciiBuffer; const UChar* limit = p + length; while (p != limit) { *q = static_cast(p[0]); ++p; ++q; } *q = '\0'; return asciiBuffer; } bool UString::is8Bit() const { const UChar* u = data(); const UChar* limit = u + size(); while (u < limit) { if (u[0] > 0xFF) return false; ++u; } return true; } UChar UString::operator[](int pos) const { if (pos >= size()) return '\0'; return data()[pos]; } double UString::toDouble(bool tolerateTrailingJunk, bool tolerateEmptyString) const { if (size() == 1) { UChar c = data()[0]; if (isASCIIDigit(c)) return c - '0'; if (isASCIISpace(c) && tolerateEmptyString) return 0; return NaN; } // FIXME: If tolerateTrailingJunk is true, then we want to tolerate non-8-bit junk // after the number, so this is too strict a check. CStringBuffer s; if (!getCString(s)) return NaN; const char* c = s.data(); // skip leading white space while (isASCIISpace(*c)) c++; // empty string ? if (*c == '\0') return tolerateEmptyString ? 0.0 : NaN; double d; // hex number ? if (*c == '0' && (*(c + 1) == 'x' || *(c + 1) == 'X')) { const char* firstDigitPosition = c + 2; c++; d = 0.0; while (*(++c)) { if (*c >= '0' && *c <= '9') d = d * 16.0 + *c - '0'; else if ((*c >= 'A' && *c <= 'F') || (*c >= 'a' && *c <= 'f')) d = d * 16.0 + (*c & 0xdf) - 'A' + 10.0; else break; } if (d >= mantissaOverflowLowerBound) d = parseIntOverflow(firstDigitPosition, c - firstDigitPosition, 16); } else { // regular number ? char* end; d = WTF::strtod(c, &end); if ((d != 0.0 || end != c) && d != Inf && d != -Inf) { c = end; } else { double sign = 1.0; if (*c == '+') c++; else if (*c == '-') { sign = -1.0; c++; } // We used strtod() to do the conversion. However, strtod() handles // infinite values slightly differently than JavaScript in that it // converts the string "inf" with any capitalization to infinity, // whereas the ECMA spec requires that it be converted to NaN. if (c[0] == 'I' && c[1] == 'n' && c[2] == 'f' && c[3] == 'i' && c[4] == 'n' && c[5] == 'i' && c[6] == 't' && c[7] == 'y') { d = sign * Inf; c += 8; } else if ((d == Inf || d == -Inf) && *c != 'I' && *c != 'i') c = end; else return NaN; } } // allow trailing white space while (isASCIISpace(*c)) c++; // don't allow anything after - unless tolerant=true if (!tolerateTrailingJunk && *c != '\0') d = NaN; return d; } double UString::toDouble(bool tolerateTrailingJunk) const { return toDouble(tolerateTrailingJunk, true); } double UString::toDouble() const { return toDouble(false, true); } uint32_t UString::toUInt32(bool* ok) const { double d = toDouble(); bool b = true; if (d != static_cast(d)) { b = false; d = 0; } if (ok) *ok = b; return static_cast(d); } uint32_t UString::toUInt32(bool* ok, bool tolerateEmptyString) const { double d = toDouble(false, tolerateEmptyString); bool b = true; if (d != static_cast(d)) { b = false; d = 0; } if (ok) *ok = b; return static_cast(d); } uint32_t UString::toStrictUInt32(bool* ok) const { if (ok) *ok = false; // Empty string is not OK. int len = m_rep->size(); if (len == 0) return 0; const UChar* p = m_rep->data(); unsigned short c = p[0]; // If the first digit is 0, only 0 itself is OK. if (c == '0') { if (len == 1 && ok) *ok = true; return 0; } // Convert to UInt32, checking for overflow. uint32_t i = 0; while (1) { // Process character, turning it into a digit. if (c < '0' || c > '9') return 0; const unsigned d = c - '0'; // Multiply by 10, checking for overflow out of 32 bits. if (i > 0xFFFFFFFFU / 10) return 0; i *= 10; // Add in the digit, checking for overflow out of 32 bits. const unsigned max = 0xFFFFFFFFU - d; if (i > max) return 0; i += d; // Handle end of string. if (--len == 0) { if (ok) *ok = true; return i; } // Get next character. c = *(++p); } } int UString::find(const UString& f, int pos) const { int fsz = f.size(); if (pos < 0) pos = 0; if (fsz == 1) { UChar ch = f[0]; const UChar* end = data() + size(); for (const UChar* c = data() + pos; c < end; c++) { if (*c == ch) return static_cast(c - data()); } return -1; } int sz = size(); if (sz < fsz) return -1; if (fsz == 0) return pos; const UChar* end = data() + sz - fsz; int fsizeminusone = (fsz - 1) * sizeof(UChar); const UChar* fdata = f.data(); unsigned short fchar = fdata[0]; ++fdata; for (const UChar* c = data() + pos; c <= end; c++) { if (c[0] == fchar && !memcmp(c + 1, fdata, fsizeminusone)) return static_cast(c - data()); } return -1; } int UString::find(UChar ch, int pos) const { if (pos < 0) pos = 0; const UChar* end = data() + size(); for (const UChar* c = data() + pos; c < end; c++) { if (*c == ch) return static_cast(c - data()); } return -1; } int UString::rfind(const UString& f, int pos) const { int sz = size(); int fsz = f.size(); if (sz < fsz) return -1; if (pos < 0) pos = 0; if (pos > sz - fsz) pos = sz - fsz; if (fsz == 0) return pos; int fsizeminusone = (fsz - 1) * sizeof(UChar); const UChar* fdata = f.data(); for (const UChar* c = data() + pos; c >= data(); c--) { if (*c == *fdata && !memcmp(c + 1, fdata + 1, fsizeminusone)) return static_cast(c - data()); } return -1; } int UString::rfind(UChar ch, int pos) const { if (isEmpty()) return -1; if (pos + 1 >= size()) pos = size() - 1; for (const UChar* c = data() + pos; c >= data(); c--) { if (*c == ch) return static_cast(c - data()); } return -1; } UString UString::substr(int pos, int len) const { int s = size(); if (pos < 0) pos = 0; else if (pos >= s) pos = s; if (len < 0) len = s; if (pos + len >= s) len = s - pos; if (pos == 0 && len == s) return *this; return UString(Rep::create(m_rep, pos, len)); } bool operator==(const UString& s1, const char *s2) { if (s2 == 0) return s1.isEmpty(); const UChar* u = s1.data(); const UChar* uend = u + s1.size(); while (u != uend && *s2) { if (u[0] != (unsigned char)*s2) return false; s2++; u++; } return u == uend && *s2 == 0; } bool operator<(const UString& s1, const UString& s2) { const int l1 = s1.size(); const int l2 = s2.size(); const int lmin = l1 < l2 ? l1 : l2; const UChar* c1 = s1.data(); const UChar* c2 = s2.data(); int l = 0; while (l < lmin && *c1 == *c2) { c1++; c2++; l++; } if (l < lmin) return (c1[0] < c2[0]); return (l1 < l2); } bool operator>(const UString& s1, const UString& s2) { const int l1 = s1.size(); const int l2 = s2.size(); const int lmin = l1 < l2 ? l1 : l2; const UChar* c1 = s1.data(); const UChar* c2 = s2.data(); int l = 0; while (l < lmin && *c1 == *c2) { c1++; c2++; l++; } if (l < lmin) return (c1[0] > c2[0]); return (l1 > l2); } int compare(const UString& s1, const UString& s2) { const int l1 = s1.size(); const int l2 = s2.size(); const int lmin = l1 < l2 ? l1 : l2; const UChar* c1 = s1.data(); const UChar* c2 = s2.data(); int l = 0; while (l < lmin && *c1 == *c2) { c1++; c2++; l++; } if (l < lmin) return (c1[0] > c2[0]) ? 1 : -1; if (l1 == l2) return 0; return (l1 > l2) ? 1 : -1; } bool equal(const UString::Rep* r, const UString::Rep* b) { int length = r->size(); if (length != b->size()) return false; const UChar* d = r->data(); const UChar* s = b->data(); for (int i = 0; i != length; ++i) { if (d[i] != s[i]) return false; } return true; } CString UString::UTF8String(bool strict) const { // Allocate a buffer big enough to hold all the characters. const int length = size(); Vector buffer(length * 3); // Convert to runs of 8-bit characters. char* p = buffer.data(); const UChar* d = reinterpret_cast(&data()[0]); ConversionResult result = convertUTF16ToUTF8(&d, d + length, &p, p + buffer.size(), strict); if (result != conversionOK) return CString(); return CString(buffer.data(), p - buffer.data()); } } // namespace JSC