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#ifndef DATE_TIME_TIME_SYSTEM_COUNTED_HPP
#define DATE_TIME_TIME_SYSTEM_COUNTED_HPP
/* Copyright (c) 2002,2003 CrystalClear Software, Inc.
* Use, modification and distribution is subject to the
* Boost Software License, Version 1.0. (See accompanying
* file LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)
* Author: Jeff Garland, Bart Garst
* $Date: 2008-02-27 15:00:24 -0500 (Wed, 27 Feb 2008) $
*/
#include "boost/date_time/time_defs.hpp"
#include <string>
namespace boost {
namespace date_time {
//! Time representation that uses a single integer count
template<class config>
struct counted_time_rep
{
typedef typename config::int_type int_type;
typedef typename config::date_type date_type;
typedef typename config::impl_type impl_type;
typedef typename date_type::duration_type date_duration_type;
typedef typename date_type::calendar_type calendar_type;
typedef typename date_type::ymd_type ymd_type;
typedef typename config::time_duration_type time_duration_type;
typedef typename config::resolution_traits resolution_traits;
counted_time_rep(const date_type& d, const time_duration_type& time_of_day)
: time_count_(1)
{
if(d.is_infinity() || d.is_not_a_date() || time_of_day.is_special()) {
time_count_ = time_of_day.get_rep() + d.day_count();
//std::cout << time_count_ << std::endl;
}
else {
time_count_ = (d.day_number() * frac_sec_per_day()) + time_of_day.ticks();
}
}
explicit counted_time_rep(int_type count) :
time_count_(count)
{}
explicit counted_time_rep(impl_type count) :
time_count_(count)
{}
date_type date() const
{
if(time_count_.is_special()) {
return date_type(time_count_.as_special());
}
else {
typename calendar_type::date_int_type dc = day_count();
//std::cout << "time_rep here:" << dc << std::endl;
ymd_type ymd = calendar_type::from_day_number(dc);
return date_type(ymd);
}
}
//int_type day_count() const
unsigned long day_count() const
{
/* resolution_traits::as_number returns a boost::int64_t &
* frac_sec_per_day is also a boost::int64_t so, naturally,
* the division operation returns a boost::int64_t.
* The static_cast to an unsigned long is ok (results in no data loss)
* because frac_sec_per_day is either the number of
* microseconds per day, or the number of nanoseconds per day.
* Worst case scenario: resolution_traits::as_number returns the
* maximum value an int64_t can hold and frac_sec_per_day
* is microseconds per day (lowest possible value).
* The division operation will then return a value of 106751991 -
* easily fitting in an unsigned long.
*/
return static_cast<unsigned long>(resolution_traits::as_number(time_count_) / frac_sec_per_day());
}
int_type time_count() const
{
return resolution_traits::as_number(time_count_);
}
int_type tod() const
{
return resolution_traits::as_number(time_count_) % frac_sec_per_day();
}
static int_type frac_sec_per_day()
{
int_type seconds_per_day = 60*60*24;
int_type fractional_sec_per_sec(resolution_traits::res_adjust());
return seconds_per_day*fractional_sec_per_sec;
}
bool is_pos_infinity()const
{
return impl_type::is_pos_inf(time_count_.as_number());
}
bool is_neg_infinity()const
{
return impl_type::is_neg_inf(time_count_.as_number());
}
bool is_not_a_date_time()const
{
return impl_type::is_not_a_number(time_count_.as_number());
}
bool is_special()const
{
return time_count_.is_special();
}
impl_type get_rep()const
{
return time_count_;
}
private:
impl_type time_count_;
};
//! An unadjusted time system implementation.
template<class time_rep>
class counted_time_system
{
public:
typedef time_rep time_rep_type;
typedef typename time_rep_type::impl_type impl_type;
typedef typename time_rep_type::time_duration_type time_duration_type;
typedef typename time_duration_type::fractional_seconds_type fractional_seconds_type;
typedef typename time_rep_type::date_type date_type;
typedef typename time_rep_type::date_duration_type date_duration_type;
template<class T> static void unused_var(const T&) {}
static time_rep_type get_time_rep(const date_type& day,
const time_duration_type& tod,
date_time::dst_flags dst=not_dst)
{
unused_var(dst);
return time_rep_type(day, tod);
}
static time_rep_type get_time_rep(special_values sv)
{
switch (sv) {
case not_a_date_time:
return time_rep_type(date_type(not_a_date_time),
time_duration_type(not_a_date_time));
case pos_infin:
return time_rep_type(date_type(pos_infin),
time_duration_type(pos_infin));
case neg_infin:
return time_rep_type(date_type(neg_infin),
time_duration_type(neg_infin));
case max_date_time: {
time_duration_type td = time_duration_type(24,0,0,0) - time_duration_type(0,0,0,1);
return time_rep_type(date_type(max_date_time), td);
}
case min_date_time:
return time_rep_type(date_type(min_date_time), time_duration_type(0,0,0,0));
default:
return time_rep_type(date_type(not_a_date_time),
time_duration_type(not_a_date_time));
}
}
static date_type get_date(const time_rep_type& val)
{
return val.date();
}
static time_duration_type get_time_of_day(const time_rep_type& val)
{
if(val.is_special()) {
return time_duration_type(val.get_rep().as_special());
}
else{
return time_duration_type(0,0,0,val.tod());
}
}
static std::string zone_name(const time_rep_type&)
{
return "";
}
static bool is_equal(const time_rep_type& lhs, const time_rep_type& rhs)
{
return (lhs.time_count() == rhs.time_count());
}
static bool is_less(const time_rep_type& lhs, const time_rep_type& rhs)
{
return (lhs.time_count() < rhs.time_count());
}
static time_rep_type add_days(const time_rep_type& base,
const date_duration_type& dd)
{
if(base.is_special() || dd.is_special()) {
return(time_rep_type(base.get_rep() + dd.get_rep()));
}
else {
return time_rep_type(base.time_count() + (dd.days() * time_rep_type::frac_sec_per_day()));
}
}
static time_rep_type subtract_days(const time_rep_type& base,
const date_duration_type& dd)
{
if(base.is_special() || dd.is_special()) {
return(time_rep_type(base.get_rep() - dd.get_rep()));
}
else{
return time_rep_type(base.time_count() - (dd.days() * time_rep_type::frac_sec_per_day()));
}
}
static time_rep_type subtract_time_duration(const time_rep_type& base,
const time_duration_type& td)
{
if(base.is_special() || td.is_special()) {
return(time_rep_type(base.get_rep() - td.get_rep()));
}
else {
return time_rep_type(base.time_count() - td.ticks());
}
}
static time_rep_type add_time_duration(const time_rep_type& base,
time_duration_type td)
{
if(base.is_special() || td.is_special()) {
return(time_rep_type(base.get_rep() + td.get_rep()));
}
else {
return time_rep_type(base.time_count() + td.ticks());
}
}
static time_duration_type subtract_times(const time_rep_type& lhs,
const time_rep_type& rhs)
{
if(lhs.is_special() || rhs.is_special()) {
return(time_duration_type(
impl_type::to_special((lhs.get_rep() - rhs.get_rep()).as_number())));
}
else {
fractional_seconds_type fs = lhs.time_count() - rhs.time_count();
return time_duration_type(0,0,0,fs);
}
}
};
} } //namespace date_time
#endif
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