// Copyright 2008 the V8 project authors. All rights reserved. // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "v8.h" #include "dateparser.h" namespace v8 { namespace internal { bool DateParser::Parse(String* str, FixedArray* out) { ASSERT(out->length() == OUTPUT_SIZE); InputReader in(str); TimeZoneComposer tz; TimeComposer time; DayComposer day; while (!in.IsEnd()) { if (in.IsAsciiDigit()) { // Parse a number (possibly with 1 or 2 trailing colons). int n = in.ReadUnsignedNumber(); if (in.Skip(':')) { if (in.Skip(':')) { // n + "::" if (!time.IsEmpty()) return false; time.Add(n); time.Add(0); } else { // n + ":" if (!time.Add(n)) return false; } } else if (tz.IsExpecting(n)) { tz.SetAbsoluteMinute(n); } else if (time.IsExpecting(n)) { time.AddFinal(n); // Require end or white space immediately after finalizing time. if (!in.IsEnd() && !in.SkipWhiteSpace()) return false; } else { if (!day.Add(n)) return false; in.Skip('-'); // Ignore suffix '-' for year, month, or day. } } else if (in.IsAsciiAlphaOrAbove()) { // Parse a "word" (sequence of chars. >= 'A'). uint32_t pre[KeywordTable::kPrefixLength]; int len = in.ReadWord(pre, KeywordTable::kPrefixLength); int index = KeywordTable::Lookup(pre, len); KeywordType type = KeywordTable::GetType(index); if (type == AM_PM && !time.IsEmpty()) { time.SetHourOffset(KeywordTable::GetValue(index)); } else if (type == MONTH_NAME) { day.SetNamedMonth(KeywordTable::GetValue(index)); in.Skip('-'); // Ignore suffix '-' for month names } else if (type == TIME_ZONE_NAME && in.HasReadNumber()) { tz.Set(KeywordTable::GetValue(index)); } else { // Garbage words are illegal if no number read yet. if (in.HasReadNumber()) return false; } } else if (in.IsAsciiSign() && (tz.IsUTC() || !time.IsEmpty())) { // Parse UTC offset (only after UTC or time). tz.SetSign(in.GetAsciiSignValue()); in.Next(); int n = in.ReadUnsignedNumber(); if (in.Skip(':')) { tz.SetAbsoluteHour(n); tz.SetAbsoluteMinute(kNone); } else { tz.SetAbsoluteHour(n / 100); tz.SetAbsoluteMinute(n % 100); } } else if (in.Is('(')) { // Ignore anything from '(' to a matching ')' or end of string. in.SkipParentheses(); } else if ((in.IsAsciiSign() || in.Is(')')) && in.HasReadNumber()) { // Extra sign or ')' is illegal if no number read yet. return false; } else { // Ignore other characters. in.Next(); } } return day.Write(out) && time.Write(out) && tz.Write(out); } bool DateParser::DayComposer::Write(FixedArray* output) { int year = 0; // Default year is 0 (=> 2000) for KJS compatibility. int month = kNone; int day = kNone; if (named_month_ == kNone) { if (index_ < 2) return false; if (index_ == 3 && !IsDay(comp_[0])) { // YMD year = comp_[0]; month = comp_[1]; day = comp_[2]; } else { // MD(Y) month = comp_[0]; day = comp_[1]; if (index_ == 3) year = comp_[2]; } } else { month = named_month_; if (index_ < 1) return false; if (index_ == 1) { // MD or DM day = comp_[0]; } else if (!IsDay(comp_[0])) { // YMD, MYD, or YDM year = comp_[0]; day = comp_[1]; } else { // DMY, MDY, or DYM day = comp_[0]; year = comp_[1]; } } if (Between(year, 0, 49)) year += 2000; else if (Between(year, 50, 99)) year += 1900; if (!Smi::IsValid(year) || !IsMonth(month) || !IsDay(day)) return false; output->set(YEAR, Smi::FromInt(year), SKIP_WRITE_BARRIER); output->set(MONTH, Smi::FromInt(month - 1), SKIP_WRITE_BARRIER); // 0-based output->set(DAY, Smi::FromInt(day), SKIP_WRITE_BARRIER); return true; } bool DateParser::TimeComposer::Write(FixedArray* output) { // All time slots default to 0 while (index_ < kSize) { comp_[index_++] = 0; } int& hour = comp_[0]; int& minute = comp_[1]; int& second = comp_[2]; if (hour_offset_ != kNone) { if (!IsHour12(hour)) return false; hour %= 12; hour += hour_offset_; } if (!IsHour(hour) || !IsMinute(minute) || !IsSecond(second)) return false; output->set(HOUR, Smi::FromInt(hour), SKIP_WRITE_BARRIER); output->set(MINUTE, Smi::FromInt(minute), SKIP_WRITE_BARRIER); output->set(SECOND, Smi::FromInt(second), SKIP_WRITE_BARRIER); return true; } bool DateParser::TimeZoneComposer::Write(FixedArray* output) { if (sign_ != kNone) { if (hour_ == kNone) hour_ = 0; if (minute_ == kNone) minute_ = 0; int total_seconds = sign_ * (hour_ * 3600 + minute_ * 60); if (!Smi::IsValid(total_seconds)) return false; output->set(UTC_OFFSET, Smi::FromInt(total_seconds), SKIP_WRITE_BARRIER); } else { output->set(UTC_OFFSET, Heap::null_value(), SKIP_WRITE_BARRIER); } return true; } const int8_t DateParser::KeywordTable::array[][DateParser::KeywordTable::kEntrySize] = { {'j', 'a', 'n', DateParser::MONTH_NAME, 1}, {'f', 'e', 'b', DateParser::MONTH_NAME, 2}, {'m', 'a', 'r', DateParser::MONTH_NAME, 3}, {'a', 'p', 'r', DateParser::MONTH_NAME, 4}, {'m', 'a', 'y', DateParser::MONTH_NAME, 5}, {'j', 'u', 'n', DateParser::MONTH_NAME, 6}, {'j', 'u', 'l', DateParser::MONTH_NAME, 7}, {'a', 'u', 'g', DateParser::MONTH_NAME, 8}, {'s', 'e', 'p', DateParser::MONTH_NAME, 9}, {'o', 'c', 't', DateParser::MONTH_NAME, 10}, {'n', 'o', 'v', DateParser::MONTH_NAME, 11}, {'d', 'e', 'c', DateParser::MONTH_NAME, 12}, {'a', 'm', '\0', DateParser::AM_PM, 0}, {'p', 'm', '\0', DateParser::AM_PM, 12}, {'u', 't', '\0', DateParser::TIME_ZONE_NAME, 0}, {'u', 't', 'c', DateParser::TIME_ZONE_NAME, 0}, {'g', 'm', 't', DateParser::TIME_ZONE_NAME, 0}, {'c', 'd', 't', DateParser::TIME_ZONE_NAME, -5}, {'c', 's', 't', DateParser::TIME_ZONE_NAME, -6}, {'e', 'd', 't', DateParser::TIME_ZONE_NAME, -4}, {'e', 's', 't', DateParser::TIME_ZONE_NAME, -5}, {'m', 'd', 't', DateParser::TIME_ZONE_NAME, -6}, {'m', 's', 't', DateParser::TIME_ZONE_NAME, -7}, {'p', 'd', 't', DateParser::TIME_ZONE_NAME, -7}, {'p', 's', 't', DateParser::TIME_ZONE_NAME, -8}, {'\0', '\0', '\0', DateParser::INVALID, 0}, }; // We could use perfect hashing here, but this is not a bottleneck. int DateParser::KeywordTable::Lookup(const uint32_t* pre, int len) { int i; for (i = 0; array[i][kTypeOffset] != INVALID; i++) { int j = 0; while (j < kPrefixLength && pre[j] == static_cast(array[i][j])) { j++; } // Check if we have a match and the length is legal. // Word longer than keyword is only allowed for month names. if (j == kPrefixLength && (len <= kPrefixLength || array[i][kTypeOffset] == MONTH_NAME)) { return i; } } return i; } } } // namespace v8::internal