/* * Copyright (c) 2003-2023, 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 #include "times.h" #if defined(_WIN32) || defined(__CYGWIN__) #include "strptime.h" #endif namespace ledger { optional epoch; date_time::weekdays start_of_week = gregorian::Sunday; namespace { template class temporal_io_t : public noncopyable { string fmt_str; public: date_traits_t traits; bool input; temporal_io_t(const char * _fmt_str, bool _input) : fmt_str(_fmt_str), traits(icontains(fmt_str, "%F") || icontains(fmt_str, "%y"), icontains(fmt_str, "%F") || icontains(fmt_str, "%m") || icontains(fmt_str, "%b"), icontains(fmt_str, "%F") || icontains(fmt_str, "%d")), input(_input) { } void set_format(const char * fmt) { fmt_str = fmt; traits = date_traits_t(icontains(fmt_str, "%F") || icontains(fmt_str, "%y"), icontains(fmt_str, "%F") || icontains(fmt_str, "%m") || icontains(fmt_str, "%b"), icontains(fmt_str, "%F") || icontains(fmt_str, "%d")); } T parse(const char *) {} std::string format(const T& when) { std::tm data(to_tm(when)); char buf[128]; std::strftime(buf, 127, fmt_str.c_str(), &data); return buf; } }; template <> datetime_t temporal_io_t ::parse(const char * str) { std::tm data; std::memset(&data, 0, sizeof(std::tm)); if (strptime(str, fmt_str.c_str(), &data)) return posix_time::ptime_from_tm(data); else return datetime_t(); } template <> date_t temporal_io_t ::parse(const char * str) { std::tm data; std::memset(&data, 0, sizeof(std::tm)); data.tm_year = CURRENT_DATE().year() - 1900; data.tm_mday = 1; // some formats have no day if (strptime(str, fmt_str.c_str(), &data)) return gregorian::date_from_tm(data); else return date_t(); } typedef temporal_io_t datetime_io_t; typedef temporal_io_t date_io_t; shared_ptr input_datetime_io; shared_ptr timelog_datetime_io; shared_ptr written_datetime_io; shared_ptr written_date_io; shared_ptr printed_datetime_io; shared_ptr printed_date_io; std::deque > readers; bool convert_separators_to_slashes = true; date_t parse_date_mask_routine(const char * date_str, date_io_t& io, date_traits_t * traits = NULL) { if (std::strlen(date_str) > 127) { throw_(date_error, _f("Invalid date: %1%") % date_str); } char buf[128]; std::strcpy(buf, date_str); if (convert_separators_to_slashes) { for (char * p = buf; *p; p++) if (*p == '.' || *p == '-') *p = '/'; } date_t when = io.parse(buf); if (! when.is_not_a_date()) { DEBUG("times.parse", "Passed date string: " << date_str); DEBUG("times.parse", "Parsed date string: " << buf); DEBUG("times.parse", "Parsed result is: " << when); DEBUG("times.parse", "Formatted result is: " << io.format(when)); string when_str = io.format(when); const char * p = when_str.c_str(); const char * q = buf; for (; *p && *q; p++, q++) { if (*p != *q && *p == '0') p++; if (! *p || *p != *q) break; } if (*p != '\0' || *q != '\0') throw_(date_error, _f("Invalid date: %1%") % date_str); if (traits) *traits = io.traits; if (! io.traits.has_year) { when = date_t(CURRENT_DATE().year(), when.month(), when.day()); if (when.month() > CURRENT_DATE().month()) when -= gregorian::years(1); } } return when; } date_t parse_date_mask(const char * date_str, date_traits_t * traits = NULL) { foreach (shared_ptr& reader, readers) { date_t when = parse_date_mask_routine(date_str, *reader.get(), traits); if (! when.is_not_a_date()) return when; } throw_(date_error, _f("Invalid date: %1%") % date_str); return date_t(); } } optional string_to_day_of_week(const std::string& str) { if (str == _("sun") || str == _("sunday") || str == "0") return gregorian::Sunday; else if (str == _("mon") || str == _("monday") || str == "1") return gregorian::Monday; else if (str == _("tue") || str == _("tuesday") || str == "2") return gregorian::Tuesday; else if (str == _("wed") || str == _("wednesday") || str == "3") return gregorian::Wednesday; else if (str == _("thu") || str == _("thursday") || str == "4") return gregorian::Thursday; else if (str == _("fri") || str == _("friday") || str == "5") return gregorian::Friday; else if (str == _("sat") || str == _("saturday") || str == "6") return gregorian::Saturday; else return none; } optional string_to_month_of_year(const std::string& str) { if (str == _("jan") || str == _("january") || str == "0") return gregorian::Jan; else if (str == _("feb") || str == _("february") || str == "1") return gregorian::Feb; else if (str == _("mar") || str == _("march") || str == "2") return gregorian::Mar; else if (str == _("apr") || str == _("april") || str == "3") return gregorian::Apr; else if (str == _("may") || str == _("may") || str == "4") return gregorian::May; else if (str == _("jun") || str == _("june") || str == "5") return gregorian::Jun; else if (str == _("jul") || str == _("july") || str == "6") return gregorian::Jul; else if (str == _("aug") || str == _("august") || str == "7") return gregorian::Aug; else if (str == _("sep") || str == _("september") || str == "8") return gregorian::Sep; else if (str == _("oct") || str == _("october") || str == "9") return gregorian::Oct; else if (str == _("nov") || str == _("november") || str == "10") return gregorian::Nov; else if (str == _("dec") || str == _("december") || str == "11") return gregorian::Dec; else return none; } datetime_t parse_datetime(const char * str) { if (std::strlen(str) > 127) { throw_(date_error, _f("Invalid date: %1%") % str); } char buf[128]; std::strcpy(buf, str); for (char * p = buf; *p; p++) if (*p == '.' || *p == '-') *p = '/'; datetime_t when = input_datetime_io->parse(buf); if (when.is_not_a_date_time()) { when = timelog_datetime_io->parse(buf); if (when.is_not_a_date_time()) { throw_(date_error, _f("Invalid date/time: %1%") % str); } } return when; } date_t parse_date(const char * str) { return parse_date_mask(str); } date_t date_specifier_t::begin() const { year_type the_year = year ? *year : year_type(CURRENT_DATE().year()); month_type the_month = month ? *month : date_t::month_type(1); day_type the_day = day ? *day : date_t::day_type(1); #if !NO_ASSERTS if (day) assert(! wday); else if (wday) assert(! day); #endif // jww (2009-11-16): Handle wday. If a month is set, find the most recent // wday in that month; if the year is set, then in that year. return gregorian::date(static_cast(the_year), static_cast(the_month), static_cast(the_day)); } date_t date_specifier_t::end() const { if (day || wday) return begin() + gregorian::days(1); else if (month) return begin() + gregorian::months(1); else if (year) return begin() + gregorian::years(1); else { assert(false); return date_t(); } } std::ostream& operator<<(std::ostream& out, const date_duration_t& duration) { if (duration.quantum == date_duration_t::DAYS) out << duration.length << " day(s)"; else if (duration.quantum == date_duration_t::WEEKS) out << duration.length << " week(s)"; else if (duration.quantum == date_duration_t::MONTHS) out << duration.length << " month(s)"; else if (duration.quantum == date_duration_t::QUARTERS) out << duration.length << " quarter(s)"; else { assert(duration.quantum == date_duration_t::YEARS); out << duration.length << " year(s)"; } return out; } class date_parser_t { friend void show_period_tokens(std::ostream& out, const string& arg); class lexer_t { friend class date_parser_t; string::const_iterator begin; string::const_iterator end; public: struct token_t { enum kind_t { UNKNOWN, TOK_DATE, TOK_INT, TOK_SLASH, TOK_DASH, TOK_DOT, TOK_A_MONTH, TOK_A_WDAY, TOK_AGO, TOK_HENCE, TOK_SINCE, TOK_UNTIL, TOK_IN, TOK_THIS, TOK_NEXT, TOK_LAST, TOK_EVERY, TOK_TODAY, TOK_TOMORROW, TOK_YESTERDAY, TOK_YEAR, TOK_QUARTER, TOK_MONTH, TOK_WEEK, TOK_DAY, TOK_YEARLY, TOK_QUARTERLY, TOK_BIMONTHLY, TOK_MONTHLY, TOK_BIWEEKLY, TOK_WEEKLY, TOK_DAILY, TOK_YEARS, TOK_QUARTERS, TOK_MONTHS, TOK_WEEKS, TOK_DAYS, END_REACHED } kind; typedef variant content_t; optional value; explicit token_t(kind_t _kind = UNKNOWN, const optional& _value = content_t(empty_string)) : kind(_kind), value(_value) { TRACE_CTOR(date_parser_t::lexer_t::token_t, ""); } token_t(const token_t& tok) : kind(tok.kind), value(tok.value) { TRACE_CTOR(date_parser_t::lexer_t::token_t, "copy"); } ~token_t() throw() { TRACE_DTOR(date_parser_t::lexer_t::token_t); } token_t& operator=(const token_t& tok) { if (this != &tok) { kind = tok.kind; value = tok.value; } return *this; } operator bool() const { return kind != END_REACHED; } string to_string() const { std::ostringstream out; switch (kind) { case UNKNOWN: out << boost::get(*value); break; case TOK_DATE: return boost::get(*value).to_string(); case TOK_INT: out << boost::get(*value); break; case TOK_SLASH: return "/"; case TOK_DASH: return "-"; case TOK_DOT: return "."; case TOK_A_MONTH: out << date_specifier_t::month_type (boost::get(*value)); break; case TOK_A_WDAY: out << date_specifier_t::day_of_week_type (boost::get(*value)); break; case TOK_AGO: return "ago"; case TOK_HENCE: return "hence"; case TOK_SINCE: return "since"; case TOK_UNTIL: return "until"; case TOK_IN: return "in"; case TOK_THIS: return "this"; case TOK_NEXT: return "next"; case TOK_LAST: return "last"; case TOK_EVERY: return "every"; case TOK_TODAY: return "today"; case TOK_TOMORROW: return "tomorrow"; case TOK_YESTERDAY: return "yesterday"; case TOK_YEAR: return "year"; case TOK_QUARTER: return "quarter"; case TOK_MONTH: return "month"; case TOK_WEEK: return "week"; case TOK_DAY: return "day"; case TOK_YEARLY: return "yearly"; case TOK_QUARTERLY: return "quarterly"; case TOK_BIMONTHLY: return "bimonthly"; case TOK_MONTHLY: return "monthly"; case TOK_BIWEEKLY: return "biweekly"; case TOK_WEEKLY: return "weekly"; case TOK_DAILY: return "daily"; case TOK_YEARS: return "years"; case TOK_QUARTERS: return "quarters"; case TOK_MONTHS: return "months"; case TOK_WEEKS: return "weeks"; case TOK_DAYS: return "days"; case END_REACHED: return ""; } return out.str(); } void dump(std::ostream& out) const { switch (kind) { case UNKNOWN: out << "UNKNOWN"; break; case TOK_DATE: out << "TOK_DATE"; break; case TOK_INT: out << "TOK_INT"; break; case TOK_SLASH: out << "TOK_SLASH"; break; case TOK_DASH: out << "TOK_DASH"; break; case TOK_DOT: out << "TOK_DOT"; break; case TOK_A_MONTH: out << "TOK_A_MONTH"; break; case TOK_A_WDAY: out << "TOK_A_WDAY"; break; case TOK_AGO: out << "TOK_AGO"; break; case TOK_HENCE: out << "TOK_HENCE"; break; case TOK_SINCE: out << "TOK_SINCE"; break; case TOK_UNTIL: out << "TOK_UNTIL"; break; case TOK_IN: out << "TOK_IN"; break; case TOK_THIS: out << "TOK_THIS"; break; case TOK_NEXT: out << "TOK_NEXT"; break; case TOK_LAST: out << "TOK_LAST"; break; case TOK_EVERY: out << "TOK_EVERY"; break; case TOK_TODAY: out << "TOK_TODAY"; break; case TOK_TOMORROW: out << "TOK_TOMORROW"; break; case TOK_YESTERDAY: out << "TOK_YESTERDAY"; break; case TOK_YEAR: out << "TOK_YEAR"; break; case TOK_QUARTER: out << "TOK_QUARTER"; break; case TOK_MONTH: out << "TOK_MONTH"; break; case TOK_WEEK: out << "TOK_WEEK"; break; case TOK_DAY: out << "TOK_DAY"; break; case TOK_YEARLY: out << "TOK_YEARLY"; break; case TOK_QUARTERLY: out << "TOK_QUARTERLY"; break; case TOK_BIMONTHLY: out << "TOK_BIMONTHLY"; break; case TOK_MONTHLY: out << "TOK_MONTHLY"; break; case TOK_BIWEEKLY: out << "TOK_BIWEEKLY"; break; case TOK_WEEKLY: out << "TOK_WEEKLY"; break; case TOK_DAILY: out << "TOK_DAILY"; break; case TOK_YEARS: out << "TOK_YEARS"; break; case TOK_QUARTERS: out << "TOK_QUARTERS"; break; case TOK_MONTHS: out << "TOK_MONTHS"; break; case TOK_WEEKS: out << "TOK_WEEKS"; break; case TOK_DAYS: out << "TOK_DAYS"; break; case END_REACHED: out << "END_REACHED"; break; } } void unexpected(); static void expected(char wanted, char c = '\0'); }; token_t token_cache; lexer_t(string::const_iterator _begin, string::const_iterator _end) : begin(_begin), end(_end) { TRACE_CTOR(date_parser_t::lexer_t, ""); } lexer_t(const lexer_t& other) : begin(other.begin), end(other.end), token_cache(other.token_cache) { TRACE_CTOR(date_parser_t::lexer_t, "copy"); } ~lexer_t() throw() { TRACE_DTOR(date_parser_t::lexer_t); } token_t next_token(); void push_token(token_t tok) { assert(token_cache.kind == token_t::UNKNOWN); token_cache = tok; } token_t peek_token() { if (token_cache.kind == token_t::UNKNOWN) token_cache = next_token(); return token_cache; } }; string arg; lexer_t lexer; public: date_parser_t(const string& _arg) : arg(_arg), lexer(arg.begin(), arg.end()) { TRACE_CTOR(date_parser_t, ""); } date_parser_t(const date_parser_t& parser) : arg(parser.arg), lexer(parser.lexer) { TRACE_CTOR(date_parser_t, "copy"); } ~date_parser_t() throw() { TRACE_DTOR(date_parser_t); } date_interval_t parse(); private: void determine_when(lexer_t::token_t& tok, date_specifier_t& specifier); }; void date_parser_t::determine_when(date_parser_t::lexer_t::token_t& tok, date_specifier_t& specifier) { date_t today = CURRENT_DATE(); switch (tok.kind) { case lexer_t::token_t::TOK_DATE: specifier = boost::get(*tok.value); break; case lexer_t::token_t::TOK_INT: { unsigned short amount = boost::get(*tok.value); int8_t adjust = 0; tok = lexer.peek_token(); lexer_t::token_t::kind_t kind = tok.kind; switch (kind) { case lexer_t::token_t::TOK_YEAR: case lexer_t::token_t::TOK_YEARS: case lexer_t::token_t::TOK_QUARTER: case lexer_t::token_t::TOK_QUARTERS: case lexer_t::token_t::TOK_MONTH: case lexer_t::token_t::TOK_MONTHS: case lexer_t::token_t::TOK_WEEK: case lexer_t::token_t::TOK_WEEKS: case lexer_t::token_t::TOK_DAY: case lexer_t::token_t::TOK_DAYS: lexer.next_token(); tok = lexer.next_token(); switch (tok.kind) { case lexer_t::token_t::TOK_AGO: adjust = -1; break; case lexer_t::token_t::TOK_HENCE: adjust = 1; break; default: tok.unexpected(); break; } break; default: break; } date_t when(today); switch (kind) { case lexer_t::token_t::TOK_YEAR: case lexer_t::token_t::TOK_YEARS: when += gregorian::years(amount * adjust); break; case lexer_t::token_t::TOK_QUARTER: case lexer_t::token_t::TOK_QUARTERS: when += gregorian::months(amount * 3 * adjust); break; case lexer_t::token_t::TOK_MONTH: case lexer_t::token_t::TOK_MONTHS: when += gregorian::months(amount * adjust); break; case lexer_t::token_t::TOK_WEEK: case lexer_t::token_t::TOK_WEEKS: when += gregorian::weeks(amount * adjust); break; case lexer_t::token_t::TOK_DAY: case lexer_t::token_t::TOK_DAYS: when += gregorian::days(amount * adjust); break; default: if (amount > 31) { specifier.year = date_specifier_t::year_type(amount); } else { specifier.day = date_specifier_t::day_type(amount); } break; } if (adjust) specifier = date_specifier_t(when); break; } case lexer_t::token_t::TOK_THIS: case lexer_t::token_t::TOK_NEXT: case lexer_t::token_t::TOK_LAST: { int8_t adjust = 0; if (tok.kind == lexer_t::token_t::TOK_NEXT) adjust = 1; else if (tok.kind == lexer_t::token_t::TOK_LAST) adjust = -1; tok = lexer.next_token(); switch (tok.kind) { case lexer_t::token_t::TOK_A_MONTH: { date_t temp(today.year(), boost::get(*tok.value), 1); temp += gregorian::years(adjust); specifier = date_specifier_t(static_cast(temp.year()), temp.month()); break; } case lexer_t::token_t::TOK_A_WDAY: { date_t temp = date_duration_t::find_nearest(today, date_duration_t::WEEKS); while (temp.day_of_week() != boost::get(*tok.value)) temp += gregorian::days(1); temp += gregorian::days(7 * adjust); specifier = date_specifier_t(temp); break; } case lexer_t::token_t::TOK_YEAR: { date_t temp(today); temp += gregorian::years(adjust); specifier = date_specifier_t(static_cast(temp.year())); break; } case lexer_t::token_t::TOK_QUARTER: { date_t base = date_duration_t::find_nearest(today, date_duration_t::QUARTERS); date_t temp; if (adjust < 0) { temp = base + gregorian::months(3 * adjust); } else if (adjust == 0) { temp = base + gregorian::months(3); } else if (adjust > 0) { base += gregorian::months(3 * adjust); temp = base + gregorian::months(3 * adjust); } specifier = date_specifier_t(adjust < 0 ? temp : base); break; } case lexer_t::token_t::TOK_WEEK: { date_t base = date_duration_t::find_nearest(today, date_duration_t::WEEKS); date_t temp; if (adjust < 0) { temp = base + gregorian::days(7 * adjust); } else if (adjust == 0) { temp = base + gregorian::days(7); } else if (adjust > 0) { base += gregorian::days(7 * adjust); temp = base + gregorian::days(7 * adjust); } specifier = date_specifier_t(adjust < 0 ? temp : base); break; } case lexer_t::token_t::TOK_DAY: { date_t temp(today); temp += gregorian::days(adjust); specifier = date_specifier_t(temp); break; } default: case lexer_t::token_t::TOK_MONTH: { date_t temp(today); temp += gregorian::months(adjust); specifier = date_specifier_t(static_cast(temp.year()), temp.month()); break; } } break; } case lexer_t::token_t::TOK_A_MONTH: specifier.month = date_specifier_t::month_type (boost::get(*tok.value)); tok = lexer.peek_token(); switch (tok.kind) { case lexer_t::token_t::TOK_INT: specifier.year = boost::get(*tok.value); break; case lexer_t::token_t::END_REACHED: break; default: break; } break; case lexer_t::token_t::TOK_A_WDAY: specifier.wday = date_specifier_t::day_of_week_type (boost::get(*tok.value)); break; case lexer_t::token_t::TOK_TODAY: specifier = date_specifier_t(today); break; case lexer_t::token_t::TOK_TOMORROW: specifier = date_specifier_t(today + gregorian::days(1)); break; case lexer_t::token_t::TOK_YESTERDAY: specifier = date_specifier_t(today - gregorian::days(1)); break; default: tok.unexpected(); break; } } date_interval_t date_parser_t::parse() { optional since_specifier; optional until_specifier; optional inclusion_specifier; date_interval_t period; date_t today = CURRENT_DATE(); bool end_inclusive = false; for (lexer_t::token_t tok = lexer.next_token(); tok.kind != lexer_t::token_t::END_REACHED; tok = lexer.next_token()) { switch (tok.kind) { case lexer_t::token_t::TOK_DATE: if (! inclusion_specifier) inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); break; case lexer_t::token_t::TOK_INT: if (! inclusion_specifier) inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); break; case lexer_t::token_t::TOK_A_MONTH: if (! inclusion_specifier) inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); break; case lexer_t::token_t::TOK_A_WDAY: if (! inclusion_specifier) inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); break; case lexer_t::token_t::TOK_DASH: if (inclusion_specifier) { since_specifier = inclusion_specifier; until_specifier = date_specifier_t(); inclusion_specifier = none; tok = lexer.next_token(); determine_when(tok, *until_specifier); // The dash operator is special: it has an _inclusive_ end. end_inclusive = true; } else { tok.unexpected(); } break; case lexer_t::token_t::TOK_SINCE: if (since_specifier) { tok.unexpected(); } else { since_specifier = date_specifier_t(); tok = lexer.next_token(); determine_when(tok, *since_specifier); } break; case lexer_t::token_t::TOK_UNTIL: if (until_specifier) { tok.unexpected(); } else { until_specifier = date_specifier_t(); tok = lexer.next_token(); determine_when(tok, *until_specifier); } break; case lexer_t::token_t::TOK_IN: if (inclusion_specifier) { tok.unexpected(); } else { inclusion_specifier = date_specifier_t(); tok = lexer.next_token(); determine_when(tok, *inclusion_specifier); } break; case lexer_t::token_t::TOK_THIS: case lexer_t::token_t::TOK_NEXT: case lexer_t::token_t::TOK_LAST: { int8_t adjust = 0; if (tok.kind == lexer_t::token_t::TOK_NEXT) adjust = 1; else if (tok.kind == lexer_t::token_t::TOK_LAST) adjust = -1; tok = lexer.next_token(); switch (tok.kind) { case lexer_t::token_t::TOK_INT: { unsigned short amount = boost::get(*tok.value); date_t base(today); date_t end(today); if (! adjust) adjust = 1; tok = lexer.next_token(); switch (tok.kind) { case lexer_t::token_t::TOK_YEARS: base += gregorian::years(amount * adjust); break; case lexer_t::token_t::TOK_QUARTERS: base += gregorian::months(amount * adjust * 3); break; case lexer_t::token_t::TOK_MONTHS: base += gregorian::months(amount * adjust); break; case lexer_t::token_t::TOK_WEEKS: base += gregorian::weeks(amount * adjust); break; case lexer_t::token_t::TOK_DAYS: base += gregorian::days(amount * adjust); break; default: tok.unexpected(); break; } if (adjust >= 0) { date_t temp = base; base = end; end = temp; } since_specifier = date_specifier_t(base); until_specifier = date_specifier_t(end); break; } case lexer_t::token_t::TOK_A_MONTH: { inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); date_t temp(today.year(), *inclusion_specifier->month, 1); temp += gregorian::years(adjust); inclusion_specifier = date_specifier_t(static_cast(temp.year()), temp.month()); break; } case lexer_t::token_t::TOK_A_WDAY: { inclusion_specifier = date_specifier_t(); determine_when(tok, *inclusion_specifier); date_t temp = date_duration_t::find_nearest(today, date_duration_t::WEEKS); while (temp.day_of_week() != inclusion_specifier->wday) temp += gregorian::days(1); temp += gregorian::days(7 * adjust); inclusion_specifier = date_specifier_t(temp); break; } case lexer_t::token_t::TOK_YEAR: { date_t temp(today); temp += gregorian::years(adjust); inclusion_specifier = date_specifier_t(static_cast(temp.year())); break; } case lexer_t::token_t::TOK_QUARTER: { date_t base = date_duration_t::find_nearest(today, date_duration_t::QUARTERS); date_t temp; if (adjust < 0) { temp = base + gregorian::months(3 * adjust); } else if (adjust == 0) { temp = base + gregorian::months(3); } else if (adjust > 0) { base += gregorian::months(3 * adjust); temp = base + gregorian::months(3 * adjust); } since_specifier = date_specifier_t(adjust < 0 ? temp : base); until_specifier = date_specifier_t(adjust < 0 ? base : temp); break; } case lexer_t::token_t::TOK_WEEK: { date_t base = date_duration_t::find_nearest(today, date_duration_t::WEEKS); date_t temp; if (adjust < 0) { temp = base + gregorian::days(7 * adjust); } else if (adjust == 0) { temp = base + gregorian::days(7); } else if (adjust > 0) { base += gregorian::days(7 * adjust); temp = base + gregorian::days(7 * adjust); } since_specifier = date_specifier_t(adjust < 0 ? temp : base); until_specifier = date_specifier_t(adjust < 0 ? base : temp); break; } case lexer_t::token_t::TOK_DAY: { date_t temp(today); temp += gregorian::days(adjust); inclusion_specifier = date_specifier_t(temp); break; } default: case lexer_t::token_t::TOK_MONTH: { date_t temp(today); temp += gregorian::months(adjust); inclusion_specifier = date_specifier_t(static_cast(temp.year()), temp.month()); break; } } break; } case lexer_t::token_t::TOK_TODAY: inclusion_specifier = date_specifier_t(today); break; case lexer_t::token_t::TOK_TOMORROW: inclusion_specifier = date_specifier_t(today + gregorian::days(1)); break; case lexer_t::token_t::TOK_YESTERDAY: inclusion_specifier = date_specifier_t(today - gregorian::days(1)); break; case lexer_t::token_t::TOK_EVERY: tok = lexer.next_token(); if (tok.kind == lexer_t::token_t::TOK_INT) { int quantity = boost::get(*tok.value); tok = lexer.next_token(); switch (tok.kind) { case lexer_t::token_t::TOK_YEARS: period.duration = date_duration_t(date_duration_t::YEARS, quantity); break; case lexer_t::token_t::TOK_QUARTERS: period.duration = date_duration_t(date_duration_t::QUARTERS, quantity); break; case lexer_t::token_t::TOK_MONTHS: period.duration = date_duration_t(date_duration_t::MONTHS, quantity); break; case lexer_t::token_t::TOK_WEEKS: period.duration = date_duration_t(date_duration_t::WEEKS, quantity); break; case lexer_t::token_t::TOK_DAYS: period.duration = date_duration_t(date_duration_t::DAYS, quantity); break; default: tok.unexpected(); break; } } else { switch (tok.kind) { case lexer_t::token_t::TOK_YEAR: period.duration = date_duration_t(date_duration_t::YEARS, 1); break; case lexer_t::token_t::TOK_QUARTER: period.duration = date_duration_t(date_duration_t::QUARTERS, 1); break; case lexer_t::token_t::TOK_MONTH: period.duration = date_duration_t(date_duration_t::MONTHS, 1); break; case lexer_t::token_t::TOK_WEEK: period.duration = date_duration_t(date_duration_t::WEEKS, 1); break; case lexer_t::token_t::TOK_DAY: period.duration = date_duration_t(date_duration_t::DAYS, 1); break; default: tok.unexpected(); break; } } break; case lexer_t::token_t::TOK_YEARLY: period.duration = date_duration_t(date_duration_t::YEARS, 1); break; case lexer_t::token_t::TOK_QUARTERLY: period.duration = date_duration_t(date_duration_t::QUARTERS, 1); break; case lexer_t::token_t::TOK_BIMONTHLY: period.duration = date_duration_t(date_duration_t::MONTHS, 2); break; case lexer_t::token_t::TOK_MONTHLY: period.duration = date_duration_t(date_duration_t::MONTHS, 1); break; case lexer_t::token_t::TOK_BIWEEKLY: period.duration = date_duration_t(date_duration_t::WEEKS, 2); break; case lexer_t::token_t::TOK_WEEKLY: period.duration = date_duration_t(date_duration_t::WEEKS, 1); break; case lexer_t::token_t::TOK_DAILY: period.duration = date_duration_t(date_duration_t::DAYS, 1); break; default: tok.unexpected(); break; } } #if 0 if (! period.duration && inclusion_specifier) period.duration = inclusion_specifier->implied_duration(); #endif if (since_specifier || until_specifier) { date_range_t range(since_specifier, until_specifier); range.end_inclusive = end_inclusive; period.range = date_specifier_or_range_t(range); } else if (inclusion_specifier) { period.range = date_specifier_or_range_t(*inclusion_specifier); } else { /* otherwise, it's something like "monthly", with no date reference */ } return period; } void date_interval_t::parse(const string& str) { date_parser_t parser(str); *this = parser.parse(); } void date_interval_t::resolve_end() { if (start && ! end_of_duration) { end_of_duration = duration->add(*start); DEBUG("times.interval", "stabilize: end_of_duration = " << *end_of_duration); } if (finish && *end_of_duration > *finish) { end_of_duration = finish; DEBUG("times.interval", "stabilize: end_of_duration reset to end: " << *end_of_duration); } if (start && ! next) { next = end_of_duration; DEBUG("times.interval", "stabilize: next set to: " << *next); } } date_t date_duration_t::find_nearest(const date_t& date, skip_quantum_t skip) { date_t result; switch (skip) { case date_duration_t::YEARS: result = date_t(date.year(), gregorian::Jan, 1); break; case date_duration_t::QUARTERS: result = date_t(date.year(), date.month(), 1); while (result.month() != gregorian::Jan && result.month() != gregorian::Apr && result.month() != gregorian::Jul && result.month() != gregorian::Oct) result -= gregorian::months(1); break; case date_duration_t::MONTHS: result = date_t(date.year(), date.month(), 1); break; case date_duration_t::WEEKS: result = date; while (result.day_of_week() != start_of_week) result -= gregorian::days(1); break; case date_duration_t::DAYS: result = date; break; } return result; } void date_interval_t::stabilize(const optional& date) { #if DEBUG_ON if (date) DEBUG("times.interval", "stabilize: with date = " << *date); #endif if (date && ! aligned) { DEBUG("times.interval", "stabilize: date passed, but not aligned"); if (duration) { DEBUG("times.interval", "stabilize: aligning with a duration: " << *duration); // The interval object has not been seeded with a start date yet, so // find the nearest period before or on date which fits, if possible. // // 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. optional initial_start = start ? start : begin(); optional initial_finish = finish ? finish : end(); #if DEBUG_ON if (initial_start) DEBUG("times.interval", "stabilize: initial_start = " << *initial_start); if (initial_finish) DEBUG("times.interval", "stabilize: initial_finish = " << *initial_finish); #endif date_t when = start ? *start : *date; switch (duration->quantum) { case date_duration_t::MONTHS: case date_duration_t::QUARTERS: case date_duration_t::YEARS: // These start on most recent period start quantum before when DEBUG("times.interval", "stabilize: monthly, quarterly or yearly duration"); start = date_duration_t::find_nearest(when, duration->quantum); break; case date_duration_t::WEEKS: // Weeks start on the beginning of week prior to 400 remainder period length // Either the first quanta of the period or the last quanta of the period seems more sensible // implies period is never less than 400 days not too unreasonable DEBUG("times.interval", "stabilize: weekly duration"); { int period = duration->length * 7; start = date_duration_t::find_nearest( when - gregorian::days(period + 400 % period), duration->quantum); } break; default: // multiples of days have a quanta of 1 day so should not have the start date adjusted to a quanta DEBUG("times.interval", "stabilize: daily duration - stable by definition"); start = when; break; } DEBUG("times.interval", "stabilize: beginning start date = " << *start); while (*start < *date) { date_interval_t next_interval(*this); ++next_interval; if (next_interval.start && *next_interval.start <= *date) { *this = next_interval; } else { end_of_duration = none; next = none; break; } } DEBUG("times.interval", "stabilize: proposed start date = " << *start); if (initial_start && (! start || *start < *initial_start)) { // Using the discovered start, find the end of the period resolve_end(); start = initial_start; DEBUG("times.interval", "stabilize: start reset to initial start"); } if (initial_finish && (! finish || *finish > *initial_finish)) { finish = initial_finish; DEBUG("times.interval", "stabilize: finish reset to initial finish"); } #if DEBUG_ON if (start) DEBUG("times.interval", "stabilize: final start = " << *start); if (finish) DEBUG("times.interval", "stabilize: final finish = " << *finish); #endif } else if (range) { start = range->begin(); finish = range->end(); } aligned = true; } // If there is no duration, then if we've reached here the date falls // between start and finish. if (! duration) { DEBUG("times.interval", "stabilize: there was no duration given"); if (! start && ! finish) throw_(date_error, _("Invalid date interval: neither start, nor finish, nor duration")); } else { resolve_end(); } } bool date_interval_t::find_period(const date_t& date, const bool allow_shift) { stabilize(date); if (finish && date > *finish) { DEBUG("times.interval", "false: date [" << date << "] > finish [" << *finish << "]"); return false; } if (! start) { throw_(std::runtime_error, _("Date interval is improperly initialized")); } else if (date < *start) { DEBUG("times.interval", "false: date [" << date << "] < start [" << *start << "]"); return false; } if (end_of_duration) { if (date < *end_of_duration) { DEBUG("times.interval", "true: date [" << date << "] < end_of_duration [" << *end_of_duration << "]"); return true; } } else { DEBUG("times.interval", "false: there is no end_of_duration"); return false; } // If we've reached here, it means the date does not fall into the current // interval, so we must seek another interval that does match -- unless we // pass by date in so doing, which means we shouldn't alter the current // period of the interval at all. date_t scan = *start; date_t end_of_scan = *end_of_duration; DEBUG("times.interval", "date = " << date); DEBUG("times.interval", "scan = " << scan); DEBUG("times.interval", "end_of_scan = " << end_of_scan); #if DEBUG_ON if (finish) DEBUG("times.interval", "finish = " << *finish); else DEBUG("times.interval", "finish is not set"); #endif while (date >= scan && (! finish || scan < *finish)) { if (date < end_of_scan) { start = scan; end_of_duration = end_of_scan; next = none; DEBUG("times.interval", "true: start = " << *start); DEBUG("times.interval", "true: end_of_duration = " << *end_of_duration); resolve_end(); return true; } else if (! allow_shift) { break; } scan = duration->add(scan); end_of_scan = duration->add(scan); DEBUG("times.interval", "scan = " << scan); DEBUG("times.interval", "end_of_scan = " << end_of_scan); } DEBUG("times.interval", "false: failed scan"); return false; } date_interval_t& date_interval_t::operator++() { if (! start) throw_(date_error, _("Cannot increment an unstarted date interval")); stabilize(); if (! duration) throw_(date_error, _("Cannot increment a date interval without a duration")); assert(next); if (finish && *next >= *finish) { start = none; } else { start = *next; end_of_duration = duration->add(*start); } next = none; resolve_end(); return *this; } void date_interval_t::dump(std::ostream& out) { out << _("--- Before stabilization ---") << std::endl; if (range) out << _(" range: ") << range->to_string() << std::endl; if (start) out << _(" start: ") << format_date(*start) << std::endl; if (finish) out << _(" finish: ") << format_date(*finish) << std::endl; if (duration) out << _("duration: ") << duration->to_string() << std::endl; optional when(begin()); if (! when) when = CURRENT_DATE(); stabilize(when); out << std::endl << _("--- After stabilization ---") << std::endl; if (range) out << _(" range: ") << range->to_string() << std::endl; if (start) out << _(" start: ") << format_date(*start) << std::endl; if (finish) out << _(" finish: ") << format_date(*finish) << std::endl; if (duration) out << _("duration: ") << duration->to_string() << std::endl; out << std::endl << _("--- Sample dates in range (max. 20) ---") << std::endl; date_t last_date; for (int i = 0; i < 20 && *this; ++i, ++*this) { out << std::right; out.width(2); if (! last_date.is_not_a_date() && last_date == *start) break; out << (i + 1) << ": " << format_date(*start); if (duration) out << " -- " << format_date(*inclusive_end()); out << std::endl; if (! duration) break; last_date = *start; } } date_parser_t::lexer_t::token_t date_parser_t::lexer_t::next_token() { if (token_cache.kind != token_t::UNKNOWN) { token_t tok = token_cache; token_cache = token_t(); return tok; } while (begin != end && std::isspace(*begin)) begin++; if (begin == end) return token_t(token_t::END_REACHED); switch (*begin) { case '/': ++begin; return token_t(token_t::TOK_SLASH); case '-': ++begin; return token_t(token_t::TOK_DASH); case '.': ++begin; return token_t(token_t::TOK_DOT); default: break; } string::const_iterator start = begin; // If the first character is a digit, try parsing the whole argument as a // date using the typical date formats. This allows not only dates like // "2009/08/01", but also dates that fit the user's --input-date-format, // assuming their format fits in one argument and begins with a digit. if (std::isdigit(*begin)) { string::const_iterator i = begin; for (i = begin; i != end && ! std::isspace(*i); i++) {} assert(i != begin); string possible_date(start, i); try { date_traits_t traits; date_t when = parse_date_mask(possible_date.c_str(), &traits); if (! when.is_not_a_date()) { begin = i; return token_t(token_t::TOK_DATE, token_t::content_t(date_specifier_t(when, traits))); } } catch (date_error&) { if (contains(possible_date, "/") || contains(possible_date, "-") || contains(possible_date, ".")) throw; } } start = begin; string term; bool alnum = std::isalnum(*begin); for (; (begin != end && ! std::isspace(*begin) && ((alnum && static_cast(std::isalnum(*begin))) || (! alnum && ! static_cast(std::isalnum(*begin))))); begin++) term.push_back(*begin); if (! term.empty()) { if (std::isdigit(term[0])) { return token_t(token_t::TOK_INT, token_t::content_t(lexical_cast(term))); } else if (std::isalpha(term[0])) { to_lower(term); if (optional month = string_to_month_of_year(term)) { return token_t(token_t::TOK_A_MONTH, token_t::content_t(*month)); } else if (optional wday = string_to_day_of_week(term)) { return token_t(token_t::TOK_A_WDAY, token_t::content_t(*wday)); } else if (term == _("ago")) return token_t(token_t::TOK_AGO); else if (term == _("hence")) return token_t(token_t::TOK_HENCE); else if (term == _("from") || term == _("since")) return token_t(token_t::TOK_SINCE); else if (term == _("to") || term == _("until")) return token_t(token_t::TOK_UNTIL); else if (term == _("in")) return token_t(token_t::TOK_IN); else if (term == _("this")) return token_t(token_t::TOK_THIS); else if (term == _("next")) return token_t(token_t::TOK_NEXT); else if (term == _("last")) return token_t(token_t::TOK_LAST); else if (term == _("every")) return token_t(token_t::TOK_EVERY); else if (term == _("today")) return token_t(token_t::TOK_TODAY); else if (term == _("tomorrow")) return token_t(token_t::TOK_TOMORROW); else if (term == _("yesterday")) return token_t(token_t::TOK_YESTERDAY); else if (term == _("year")) return token_t(token_t::TOK_YEAR); else if (term == _("quarter")) return token_t(token_t::TOK_QUARTER); else if (term == _("month")) return token_t(token_t::TOK_MONTH); else if (term == _("week")) return token_t(token_t::TOK_WEEK); else if (term == _("day")) return token_t(token_t::TOK_DAY); else if (term == _("yearly")) return token_t(token_t::TOK_YEARLY); else if (term == _("quarterly")) return token_t(token_t::TOK_QUARTERLY); else if (term == _("bimonthly")) return token_t(token_t::TOK_BIMONTHLY); else if (term == _("monthly")) return token_t(token_t::TOK_MONTHLY); else if (term == _("biweekly")) return token_t(token_t::TOK_BIWEEKLY); else if (term == _("weekly")) return token_t(token_t::TOK_WEEKLY); else if (term == _("daily")) return token_t(token_t::TOK_DAILY); else if (term == _("years")) return token_t(token_t::TOK_YEARS); else if (term == _("quarters")) return token_t(token_t::TOK_QUARTERS); else if (term == _("months")) return token_t(token_t::TOK_MONTHS); else if (term == _("weeks")) return token_t(token_t::TOK_WEEKS); else if (term == _("days")) return token_t(token_t::TOK_DAYS); } else { token_t::expected('\0', term[0]); begin = ++start; } } else { token_t::expected('\0', *begin); } return token_t(token_t::UNKNOWN, token_t::content_t(term)); } void date_parser_t::lexer_t::token_t::unexpected() { switch (kind) { case END_REACHED: kind = UNKNOWN; throw_(date_error, _("Unexpected end of expression")); default: { string desc = to_string(); kind = UNKNOWN; throw_(date_error, _f("Unexpected date period token '%1%'") % desc); } } } void date_parser_t::lexer_t::token_t::expected(char wanted, char c) { if (wanted == '\0') throw_(date_error, _f("Invalid char '%1%'") % c); else throw_(date_error, _f("Invalid char '%1%' (wanted '%2%')") % c % wanted); } namespace { typedef std::map datetime_io_map; typedef std::map date_io_map; datetime_io_map temp_datetime_io; date_io_map temp_date_io; } std::string format_datetime(const datetime_t& when, const format_type_t format_type, const optional& format) { if (format_type == FMT_WRITTEN) { return written_datetime_io->format(when); } else if (format_type == FMT_CUSTOM && format) { datetime_io_map::iterator i = temp_datetime_io.find(*format); if (i != temp_datetime_io.end()) { return (*i).second->format(when); } else { datetime_io_t * formatter = new datetime_io_t(*format, false); temp_datetime_io.insert(datetime_io_map::value_type(*format, formatter)); return formatter->format(when); } } else if (format_type == FMT_PRINTED) { return printed_datetime_io->format(when); } else { assert(false); return empty_string; } } std::string format_date(const date_t& when, const format_type_t format_type, const optional& format) { if (format_type == FMT_WRITTEN) { return written_date_io->format(when); } else if (format_type == FMT_CUSTOM && format) { date_io_map::iterator i = temp_date_io.find(*format); if (i != temp_date_io.end()) { return (*i).second->format(when); } else { date_io_t * formatter = new date_io_t(*format, false); temp_date_io.insert(date_io_map::value_type(*format, formatter)); return formatter->format(when); } } else if (format_type == FMT_PRINTED) { return printed_date_io->format(when); } else { assert(false); return empty_string; } } namespace { bool is_initialized = false; } void set_datetime_format(const char * format) { written_datetime_io->set_format(format); printed_datetime_io->set_format(format); } void set_date_format(const char * format) { written_date_io->set_format(format); printed_date_io->set_format(format); } void set_input_date_format(const char * format) { readers.push_front(shared_ptr(new date_io_t(format, true))); convert_separators_to_slashes = false; } void times_initialize() { if (! is_initialized) { input_datetime_io.reset(new datetime_io_t("%Y/%m/%d %H:%M:%S", true)); timelog_datetime_io.reset(new datetime_io_t("%m/%d/%Y %H:%M:%S", true)); written_datetime_io.reset(new datetime_io_t("%Y/%m/%d %H:%M:%S", false)); written_date_io.reset(new date_io_t("%Y/%m/%d", false)); printed_datetime_io.reset(new datetime_io_t("%y-%b-%d %H:%M:%S", false)); printed_date_io.reset(new date_io_t("%y-%b-%d", false)); readers.push_back(shared_ptr(new date_io_t("%m/%d", true))); readers.push_back(shared_ptr(new date_io_t("%Y/%m/%d", true))); readers.push_back(shared_ptr(new date_io_t("%Y/%m", true))); readers.push_back(shared_ptr(new date_io_t("%y/%m/%d", true))); readers.push_back(shared_ptr(new date_io_t("%Y-%m-%d", true))); is_initialized = true; } } void times_shutdown() { if (is_initialized) { input_datetime_io.reset(); timelog_datetime_io.reset(); written_datetime_io.reset(); written_date_io.reset(); printed_datetime_io.reset(); printed_date_io.reset(); readers.clear(); foreach (datetime_io_map::value_type& pair, temp_datetime_io) checked_delete(pair.second); temp_datetime_io.clear(); foreach (date_io_map::value_type& pair, temp_date_io) checked_delete(pair.second); temp_date_io.clear(); is_initialized = false; } } void show_period_tokens(std::ostream& out, const string& arg) { date_parser_t::lexer_t lexer(arg.begin(), arg.end()); out << _("--- Period expression tokens ---") << std::endl; date_parser_t::lexer_t::token_t token; do { token = lexer.next_token(); token.dump(out); out << ": " << token.to_string() << std::endl; } while (token.kind != date_parser_t::lexer_t::token_t::END_REACHED); } } // namespace ledger