/* * Copyright (c) 2003-2007, John Wiegley. 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 New Artisans LLC 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 "utils.h" namespace ledger { #ifdef BOOST_DATE_TIME_HAS_HIGH_PRECISION_CLOCK const ptime time_now = boost::posix_time::microsec_clock::universal_time(); #else const ptime time_now = boost::posix_time::second_clock::universal_time(); #endif const date date_now = boost::gregorian::day_clock::universal_day(); #ifdef SUPPORT_DATE_AND_TIME const datetime_t& current_moment(time_now); #else const datetime_t& current_moment(date_now); #endif int current_year(current_moment.date().year()); string input_time_format; string output_time_format = "%Y/%m/%d"; #if 0 static const char * formats[] = { "%y/%m/%d", "%Y/%m/%d", "%m/%d", "%y.%m.%d", "%Y.%m.%d", "%m.%d", "%y-%m-%d", "%Y-%m-%d", "%m-%d", "%a", "%A", "%b", "%B", "%Y", NULL }; #endif bool day_before_month = false; static bool day_before_month_initialized = false; #if 0 datetime_t datetime_t::now(std::time(NULL)); namespace { static std::time_t base = -1; static int base_year = -1; static const int month_days[12] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }; bool parse_date_mask(const char * date_str, struct std::tm * result); bool parse_date(const char * date_str, std::time_t * result, const int year = -1); bool quick_parse_date(const char * date_str, std::time_t * result); } #endif datetime_t parse_datetime(const char * str) { if (! day_before_month_initialized) { #ifdef HAVE_NL_LANGINFO const char * d_fmt = nl_langinfo(D_FMT); if (d_fmt && std::strlen(d_fmt) > 1 && d_fmt[1] == 'd') day_before_month = true; day_before_month_initialized = true; #endif } #if 0 return parse_abs_datetime(in); #else int year = ((str[0] - '0') * 1000 + (str[1] - '0') * 100 + (str[2] - '0') * 10 + (str[3] - '0')); int mon = ((str[5] - '0') * 10 + (str[6] - '0')); int day = ((str[8] - '0') * 10 + (str[9] - '0')); return datetime_t(boost::gregorian::date(year, mon, day)); #endif } datetime_t interval_t::first(const datetime_t& moment) const { datetime_t quant(begin); if (! advanced) advanced = true; #if 0 if (is_valid(moment) && moment > quant) { // Find an efficient starting point for the upcoming while loop. // We want a date early enough that the range will be correct, but // late enough that we don't spend hundreds of thousands of loops // skipping through time. struct std::tm * desc = std::localtime(&moment.when); if (years) desc->tm_mon = 0; desc->tm_mday = 1; desc->tm_hour = 0; desc->tm_min = 0; desc->tm_sec = 0; desc->tm_isdst = -1; quant = std::mktime(desc); datetime_t temp; while (moment >= (temp = increment(quant))) { if (quant == temp) break; quant = temp; } } #endif return quant; } datetime_t interval_t::increment(const datetime_t& moment) const { #if 0 struct std::tm * desc = std::localtime(&moment.when); if (years) desc->tm_year += years; if (months) desc->tm_mon += months; if (days) desc->tm_mday += days; desc->tm_hour += hours; desc->tm_min += minutes; desc->tm_sec += seconds; desc->tm_isdst = -1; return std::mktime(desc); #else return datetime_t(); #endif } namespace { void parse_inclusion_specifier(const string& word, datetime_t * begin, datetime_t * end) { #if 0 // jww (2008-05-08): Implement! struct std::tm when; if (! parse_date_mask(word.c_str(), &when)) throw new datetime_error(string("Could not parse date mask: ") + word); when.tm_hour = 0; when.tm_min = 0; when.tm_sec = 0; when.tm_isdst = -1; bool saw_year = true; bool saw_mon = true; bool saw_day = true; if (when.tm_year == -1) { when.tm_year = date_t::current_year - 1900; saw_year = false; } if (when.tm_mon == -1) { when.tm_mon = 0; saw_mon = false; } else { saw_year = false; // don't increment by year if month used } if (when.tm_mday == -1) { when.tm_mday = 1; saw_day = false; } else { saw_mon = false; // don't increment by month if day used saw_year = false; // don't increment by year if day used } if (begin) { *begin = std::mktime(&when); assert(int(*begin) != -1); if (end) { *end = interval_t(saw_day ? 1 : 0, saw_mon ? 1 : 0, saw_year ? 1 : 0).increment(*begin); assert(int(*end) != -1); } } else if (end) { *end = std::mktime(&when); assert(int(*end) != -1); } #endif } inline void read_lower_word(std::istream& in, string& word) { in >> word; for (int i = 0, l = word.length(); i < l; i++) word[i] = std::tolower(word[i]); } void parse_date_words(std::istream& in, string& word, datetime_t * begin, datetime_t * end) { string type; bool mon_spec = false; char buf[32]; if (word == "this" || word == "last" || word == "next") { type = word; if (! in.eof()) read_lower_word(in, word); else word = "month"; } else { type = "this"; } if (word == "month") { #if 0 // jww (2008-05-08): std::strftime(buf, 31, "%B", datetime_t::now.localtime()); #endif word = buf; mon_spec = true; } else if (word == "year") { #if 0 // jww (2008-05-08): std::strftime(buf, 31, "%Y", datetime_t::now.localtime()); #endif word = buf; } parse_inclusion_specifier(word, begin, end); if (type == "last") { if (mon_spec) { if (begin) *begin = interval_t(0, -1, 0).increment(*begin); if (end) *end = interval_t(0, -1, 0).increment(*end); } else { if (begin) *begin = interval_t(0, 0, -1).increment(*begin); if (end) *end = interval_t(0, 0, -1).increment(*end); } } else if (type == "next") { if (mon_spec) { if (begin) *begin = interval_t(0, 1, 0).increment(*begin); if (end) *end = interval_t(0, 1, 0).increment(*end); } else { if (begin) *begin = interval_t(0, 0, 1).increment(*begin); if (end) *end = interval_t(0, 0, 1).increment(*end); } } } } void interval_t::parse(std::istream& in) { string word; while (! in.eof()) { read_lower_word(in, word); if (word == "every") { read_lower_word(in, word); if (std::isdigit(word[0])) { int quantity = std::atol(word.c_str()); read_lower_word(in, word); if (word == "days") days = quantity; else if (word == "weeks") days = 7 * quantity; else if (word == "months") months = quantity; else if (word == "quarters") months = 3 * quantity; else if (word == "years") years = quantity; else if (word == "hours") hours = quantity; else if (word == "minutes") minutes = quantity; else if (word == "seconds") seconds = quantity; } else if (word == "day") days = 1; else if (word == "week") days = 7; else if (word == "month") months = 1; else if (word == "quarter") months = 3; else if (word == "year") years = 1; else if (word == "hour") hours = 1; else if (word == "minute") minutes = 1; else if (word == "second") seconds = 1; } else if (word == "daily") days = 1; else if (word == "weekly") days = 7; else if (word == "biweekly") days = 14; else if (word == "monthly") months = 1; else if (word == "bimonthly") months = 2; else if (word == "quarterly") months = 3; else if (word == "yearly") years = 1; else if (word == "hourly") hours = 1; else if (word == "this" || word == "last" || word == "next") { parse_date_words(in, word, &begin, &end); } else if (word == "in") { read_lower_word(in, word); parse_date_words(in, word, &begin, &end); } else if (word == "from" || word == "since") { read_lower_word(in, word); parse_date_words(in, word, &begin, NULL); } else if (word == "to" || word == "until") { read_lower_word(in, word); parse_date_words(in, word, NULL, &end); } else { parse_inclusion_specifier(word, &begin, &end); } } } namespace { bool parse_date_mask(const char * date_str, struct std::tm * result) { #if 0 // jww (2008-05-08): if (! date_t::input_format.empty()) { std::memset(result, -1, sizeof(struct std::tm)); if (strptime(date_str, date_t::input_format.c_str(), result)) return true; } for (const char ** f = formats; *f; f++) { std::memset(result, INT_MAX, sizeof(struct std::tm)); if (strptime(date_str, *f, result)) return true; } #endif return false; } bool parse_date(const char * date_str, std::time_t * result, const int year) { #if 0 // jww (2008-05-08): struct std::tm when; if (! parse_date_mask(date_str, &when)) return false; when.tm_hour = 0; when.tm_min = 0; when.tm_sec = 0; if (when.tm_year == -1) when.tm_year = ((year == -1) ? date_t::current_year : year) - 1900; if (when.tm_mon == -1) when.tm_mon = 0; if (when.tm_mday == -1) when.tm_mday = 1; *result = std::mktime(&when); #endif return true; } bool quick_parse_date(const char * date_str, std::time_t * result) { #if 0 // jww (2008-05-08): return parse_date(date_str, result, date_t::current_year); #else return false; #endif } } } // namespace ledger