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Posix Time

Ptime
Time Duration
Time Period
Time Iterators

Posix Time System

Introduction -- Usage Examples

Introduction

Defines a non-adjusted time system with nano-second/micro-second resolution and stable calculation properties. The nano-second resolution option uses 96 bits of underlying storage for each ptime while the micro-second resolution uses 64 bits per ptime (see Build Options for details). This time system uses the Gregorian calendar to implement the date portion of the time representation.

Usage Examples

Example Description
Time Math A few simple calculations using ptime and time_durations.
Print Hours Retrieve time from clock, use a time_iterator.
Local to UTC Conversion Demonstrates a couple different ways to convert a local to UTC time including daylight savings rules.
Time Periods Some simple examples of intersection and display of time periods.

Ptime

Introduction -- Header -- Construction -- Construct from String -- Construct from Clock -- Construct using Conversion functions -- Accessors -- Conversion To String -- Operators -- Struct tm, time_t, and FILETIME Functions

Introduction

The class boost::posix_time::ptime is the primary interface for time point manipulation. In general, the ptime class is immutable once constructed although it does allow assignment.

Class ptime is dependent on gregorian::date for the interface to the date portion of a time point.

Other techniques for creating times include time iterators.

Header

#include "boost/date_time/posix_time/posix_time.hpp" //include all types plus i/o
or
#include "boost/date_time/posix_time/posix_time_types.hpp" //no i/o just types

Construction

Syntax Description
Example
ptime(date,time_duration)
Construct from a date and offset
ptime t1(date(2002,Jan,10), 
         time_duration(1,2,3));
ptime t2(date(2002,Jan,10), 
         hours(1)+nanosec(5));
ptime(ptime)
Copy constructor
ptime t3(t1)
ptime(special_values sv)
Constructor for infinities, not-a-date-time, max_date_time, and min_date_time
ptime d1(neg_infin);
ptime d2(pos_infin);
ptime d3(not_a_date_time);
ptime d4(max_date_time);
ptime d5(min_date_time);
ptime;
Default constructor. Creates a ptime object initialized to not_a_date_time. NOTE: this constructor can be disabled by defining DATE_TIME_NO_DEFAULT_CONSTRUCTOR (see compiler_config.hpp)
ptime p; // p => not_a_date_time

Construct from String

Syntax Description
Example
ptime time_from_string(std::string)
From delimited string. NOTE: Excess digits in fractional seconds will be dropped. Ex: "1:02:03.123456999" => 1:02:03.123456. This behavior is affected by the precision the library is compiled with (see Build-Compiler Information.
std::string ts("2002-01-20 23:59:59.000");
ptime t(time_from_string(ts))
ptime from_iso_string(std::string)
From non delimited ISO 8601 form string.
std::string ts("20020131T235959");
ptime t(from_iso_string(ts))
ptime from_iso_extended_string(std::string)
From delimited ISO 8601 form string.
std::string ts("2020-01-31T23:59:59.123");
ptime t(from_iso_extended_string(ts))

Construct from Clock

Syntax Description
Example
ptime second_clock::local_time()
Get the local time, second level resolution, based on the time zone settings of the computer.
ptime t(second_clock::local_time());
ptime second_clock::universal_time()
Get the UTC time.
ptime t(second_clock::universal_time())
ptime microsec_clock::local_time()
Get the local time using a sub second resolution clock. On Unix systems this is implemented using gettimeofday. On most Win32 platforms it is implemented using ftime. Win32 systems often do not achieve microsecond resolution via this API. If higher resolution is critical to your application test your platform to see the achieved resolution.
ptime t(microsec_clock::local_time());
ptime microsec_clock::universal_time()
Get the UTC time using a sub second resolution clock. On Unix systems this is implemented using gettimeofday. On most Win32 platforms it is implemented using ftime. Win32 systems often do not achieve microsecond resolution via this API. If higher resolution is critical to your application test your platform to see the achieved resolution.
ptime t(microsec_clock::universal_time());

Construct using Conversion Functions

Syntax Description
Example
ptime from_time_t(time_t t);
Converts a time_t into a ptime.
ptime t = from_time_t(tt);
ptime from_ftime<ptime>(FILETIME ft);
Creates a ptime object from a FILETIME structure.
ptime t = from_ftime<ptime>(ft);

Accessors

Syntax Description
Example
date date()
Get the date part of a time.
date d(2002,Jan,10);
ptime t(d, hour(1));
t.date() --> 2002-Jan-10;
time_duration time_of_day()
Get the time offset in the day.
date d(2002,Jan,10);
ptime t(d, hour(1));
t.time_of_day() --> 01:00:00;
bool is_infinity() const
Returns true if ptime is either positive or negative infinity
ptime pt(pos_infin); 
pt.is_infinity(); // --> true
bool is_neg_infinity() const
Returns true if ptime is negative infinity
ptime pt(neg_infin);
pt.is_neg_infinity(); // --> true
bool is_pos_infinity() const
Returns true if ptime is positive infinity
ptime pt(neg_infin); 
pt.is_pos_infinity(); // --> true
bool is_not_a_date_time() const
Returns true if value is not a ptime
ptime pt(not_a_date_time);
pt.is_not_a_date_time(); // --> true
bool is_special() const
Returns true if ptime is any special_value
ptime pt(pos_infin); 
ptime pt2(not_a_date_time); 
ptime pt3(date(2005,Mar,1), hours(10));
pt.is_special(); // --> true
pt2.is_special(); // --> true
pt3.is_special(); // --> false

Conversion to String

Syntax Description
Example
std::string to_simple_string(ptime)
To YYYY-mmm-DD HH:MM:SS.fffffffff string where mmm 3 char month name and the fractional seconds are only included if non-zero.
2002-Jan-01 10:00:01.123456789
std::string to_iso_string(ptime)
Convert to form YYYYMMDDTHHMMSS.fffffffff where T is the date-time separator and the fractional seconds are only included if non-zero.
20020131T100001.123456789
std::string to_iso_extended_string(ptime)
Convert to form YYYY-MM-DDTHH:MM:SS.fffffffff where T is the date-time separator and the fractional seconds are only included if non-zero.
2002-01-31T10:00:01.123456789

Operators

Syntax Description
Example
operator<<, operator>>
Streaming operators. Note: As of version 1.33, streaming operations have been greatly improved. See Date Time IO System for more details (including exceptions and error conditions).
ptime pt(not_a_date_time);
stringstream ss("2002-Jan-01 14:23:11");
ss >> pt; 
std::cout << pt; // "2002-Jan-01 14:23:11"
  
operator==, operator!=,
operator>, operator<,
operator>=, operator<=
A full complement of comparison operators
t1 == t2, etc
ptime operator+(days)
Return a ptime adding a day offset
date d(2002,Jan,1);
ptime t(d,minutes(5));
days dd(1);
ptime t2 = t + dd;
ptime operator-(days)
Return a ptime subtracting a day offset
date d(2002,Jan,1);
ptime t(d,minutes(5));
days dd(1);
ptime t2 = t - dd;
ptime operator+(time_duration)
Return a ptime adding a time duration
date d(2002,Jan,1);
ptime t(d,minutes(5));
ptime t2 = t + hours(1) + minutes(2);
ptime operator-(time_duration)
Return a ptime subtracting a time duration
date d(2002,Jan,1);
ptime t(d,minutes(5));
ptime t2 = t - minutes(2);
time_duration operator-(ptime)
Take the difference between two times.
date d(2002,Jan,1);
ptime t1(d,minutes(5));
ptime t2(d,seconds(5));
time_duration t3 = t2 - t1;//negative result

Struct tm, time_t, and FILETIME Functions

Functions for converting posix_time objects to, and from, tm structs are provided as well as conversion from time_t and FILETIME.

Syntax Description
Example
tm to_tm(ptime)
A function for converting a ptime object to a tm struct. The tm_isdst field is set to -1.
ptime pt(date(2005,Jan,1), time_duration(1,2,3));
tm pt_tm = to_tm(pt);
/* tm_year => 105
   tm_mon  => 0
   tm_mday => 1
   tm_wday => 6 (Saturday)
   tm_yday => 0
   tm_hour => 1
   tm_min  => 2
   tm_sec  => 3
   tm_isdst => -1 */
ptime ptime_from_tm(tm timetm)
A function for converting a tm struct to a ptime object. The fields: tm_wday , tm_yday , and tm_isdst are ignored.
tm pt_tm;
pt_tm.tm_year = 105;
pt_tm.tm_mon  = 0;
pt_tm.tm_mday = 1;
pt_tm.tm_hour = 1;
pt_tm.tm_min  = 2;
pt_tm.tm_sec  = 3;
ptime pt = ptime_from_tm(pt_tm);
// pt => 2005-Jan-01 01:02:03
tm to_tm(time_duration)
A function for converting a time_duration object to a tm struct. The fields: tm_year, tm_mon, tm_mday, tm_wday, tm_yday are set to zero. The tm_isdst field is set to -1.
time_duration td(1,2,3);
tm td_tm = to_tm(td);
/* tm_year => 0
   tm_mon  => 0
   tm_mday => 0
   tm_wday => 0
   tm_yday => 0
   tm_hour => 1
   tm_min  => 2
   tm_sec  => 3
   tm_isdst => -1 */
ptime from_time_t(std::time_t)
Creates a ptime from the time_t parameter. The seconds held in the time_t are added to a time point of 1970-Jan-01.
ptime pt(not_a_date_time);
std::time_t t;
t = 1118158776;
pt = from_time_t(t);
// pt => 2005-Jun-07 15:39:36
ptime from_ftime<ptime>(FILETIME)
A template function that constructs a ptime from a FILETIME struct.
FILETIME ft;
ft.dwHighDateTime = 29715317;
ft.dwLowDateTime = 3865122988UL;
ptime pt = from_ftime<ptime>(ft);
// pt => 2005-Jun-07 15:30:57.039582000

Time Duration

Introduction -- Header -- Construction -- Count Based Construction -- Construct from String -- Accessors -- Conversion To String -- Operators -- Struct tm Functions

Introduction

The class boost::posix_time::time_duration the base type responsible for representing a length of time. A duration can be either positive or negative. The general time_duration class provides a constructor that takes a count of the number of hours, minutes, seconds, and fractional seconds count as shown in the code fragment below. The resolution of the time_duration is configure able at compile time. See Build-Compiler Information for more information.

using namespace boost::posix_time;
time_duration td(1,2,3,4); //01:02:03.000000004 when resolution is nano seconds
time_duration td(1,2,3,4); //01:02:03.000004 when resolution is micro seconds

Several small helper classes that derive from a base time_duration, as shown below, to adjust for different resolutions. These classes can shorten code and make the intent clearer.

As an example:

using namespace boost::posix_time;
      
time_duration td = hours(1) + seconds(10); //01:00:10
td = hours(1) + nanoseconds(5); //01:00:00.000000005

Note that the existence of the higher resolution classes (eg: nanoseconds) depends on the installation of the library. See Build-Compiler Information for more information.

Another way to handle this is to utilize the ticks_per_second() method of time_duration to write code that is portable no matter how the library is compiled. The general equation for calculating a resolution independent count is as follows:

count*(time_duration_ticks_per_second / count_ticks_per_second)
    

For example, let's suppose we want to construct using a count that represents tenths of a second. That is, each tick is 0.1 second.

int number_of_tenths = 5;
//create a resolution independent count -- divide by 10 since there are 
//10 tenths in a second.  
int count = number_of_tenths*(time_duration::ticks_per_second()/10);
time_duration td(1,2,3,count); //01:02:03.5 //no matter the resolution settings
    

Header

#include "boost/date_time/posix_time/posix_time.hpp" //include all types plus i/o
or
#include "boost/date_time/posix_time/posix_time_types.hpp" //no i/o just types

Construction

Syntax Description
Example
time_duration(hours,
              minutes,
              seconds,
              fractional_seconds)
Construct a duration from the counts. The fractional_second parameter is a number of units and is therefore affected by the resolution the application is compiled with (see Build-Compiler Information). If the fractional_seconds argument exceeds the limit of the compiled precision, the excess value will be "carried over" into the seconds field. See above for techniques to creating a resolution independent count.
time_duration td(1,2,3,9);
//1 hr 2 min 3 sec 9 nanoseconds
time_duration td2(1,2,3,123456789);
time_duration td3(1,2,3,1000);
// with microsecond resolution (6 digits)
// td2 => "01:04:06.456789"
// td3 => "01:02:03.001000"
// with nanosecond resolution (9 digits)
// td2 => "01:02:03.123456789"
// td3 => "01:02:03.000001000"
time_duration(special_value sv)
Special values constructor. Important note: When a time_duration is a special value, either by construction or other means, the following accessor functions will give unpredictable results:
hours(), minutes(), seconds(), ticks(), 
fractional_seconds(), total_nanoseconds(),
total_microseconds(), total_milliseconds(),
total_seconds()
The remaining accessor functions will work as expected.

Count Based Construction

Syntax Description
Example
hours(long)
Number of hours
time_duration td = hours(3);
minutes(long)
Number of minutes
time_duration td = minutes(3);
seconds(long)
Number of seconds
time_duration td = seconds(3);
milliseconds(long)
Number of milliseconds.
time_duration td = milliseconds(3);
microseconds(long)
Number of microseconds.
time_duration td = microseconds(3);
nanoseconds(long)
Number of nanoseconds.
time_duration td = nanoseconds(3);

Construct from String

Syntax Description
Example
time_duration duration_from_string(std::string)
From delimited string. NOTE: Excess digits in fractional seconds will be dropped. Ex: "1:02:03.123456999" => 1:02:03.123456. This behavior is affected by the precision the library is compiled with (see Build-Compiler Information.
std::string ts("23:59:59.000");
time_duration td(duration_from_string(ts));

Accessors

Syntax Description
Example
boost::int64_t hours()
Get the number of normalized hours (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3); 
time_duration neg_td(-1,2,3);
td.hours(); // --> 1
neg_td.hours(); // --> -1
boost::int64_t minutes()
Get the number of minutes normalized +/-(0..59) (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3);
time_duration neg_td(-1,2,3);
td.minutes(); // --> 2
neg_td.minutes(); // --> -2
boost::int64_t seconds() const
Get the normalized number of second +/-(0..59) (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3); 
time_duration neg_td(-1,2,3);
td.seconds(); // --> 3
neg_td.seconds(); // --> -3
boost::int64_t total_seconds() const
Get the total number of seconds truncating any fractional seconds (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3,10);
td.total_seconds(); 
// --> (1*3600) + (2*60) + 3 == 3723
boost::int64_t total_milliseconds() const
Get the total number of milliseconds truncating any remaining digits (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3,123456789);
td.total_milliseconds(); 
// HMS --> (1*3600) + (2*60) + 3 == 3723 seconds
// milliseconds is 3 decimal places
// (3723 * 1000) + 123 == 3723123
boost::int64_t total_microseconds() const
Get the total number of microseconds truncating any remaining digits (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3,123456789);
td.total_microseconds(); 
// HMS --> (1*3600) + (2*60) + 3 == 3723 seconds
// microseconds is 6 decimal places
// (3723 * 1000000) + 123456 == 3723123456
boost::int64_t total_nanoseconds() const
Get the total number of nanoseconds truncating any remaining digits (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3,123456789);
td.total_nanoseconds(); 
// HMS --> (1*3600) + (2*60) + 3 == 3723 seconds
// nanoseconds is 9 decimal places
// (3723 * 1000000000) + 123456789
//                              == 3723123456789
boost::int64_t fractional_seconds() const
Get the number of fractional seconds (will give unpredictable results if calling time_duration is a special_value).
time_duration td(1,2,3, 1000);
td.fractional_seconds(); // --> 1000
bool is_negative() const
True if and only if duration is negative.
time_duration td(-1,0,0); 
td.is_negative(); // --> true
bool is_zero() const
True if and only if duration is zero.
time_duration td(0,0,0);
td.is_zero(); // --> true
bool is_positive() const
True if and only if duration is positive.
time_duration td(1,0,0);
td.is_positive(); // --> true
time_duration invert_sign() const
Generate a new duration with the sign inverted.
time_duration td(-1,0,0);
td.invert_sign(); // --> 01:00:00
time_duration abs() const
Generate a new duration with the absolute value of the time duration.
time_duration td(-1,0,0);
td.abs(); // --> 01:00:00
time_duration td(+1,0,0);
td.abs(); // --> 01:00:00
date_time::time_resolutions time_duration::resolution()
Describes the resolution capability of the time_duration class. time_resolutions is an enum of resolution possibilities ranging from seconds to nanoseconds.  
time_duration::resolution() --> nano
 
unsigned short time_duration::num_fractional_digits()
Returns the number of fractional digits the time resolution has.  
unsigned short secs;
secs = time_duration::num_fractional_digits();
// 9 for nano, 6 for micro, etc.
 
boost::int64_t time_duration::ticks_per_second()
Return the number of ticks in a second. For example, if the duration supports nanoseconds then the returned result will be 1,000,000,000 (1e+9).  
std::cout << time_duration::ticks_per_second();
 
boost::int64_t ticks()
Return the raw count of the duration type (will give unpredictable results if calling time_duration is a special_value).  
time_duration td(0,0,0, 1000);
td.ticks() // --> 1000
 
time_duration time_duration::unit()
Return smallest possible unit of duration type (1 nanosecond).  
time_duration::unit() --> time_duration(0,0,0,1)
 
bool is_neg_infinity() const
Returns true if time_duration is negative infinity  
time_duration td(neg_infin);
td.is_neg_infinity(); // --> true
 
bool is_pos_infinity() const
Returns true if time_duration is positive infinity  
time_duration td(pos_infin); 
td.is_pos_infinity(); // --> true
 
bool is_not_a_date_time() const
Returns true if value is not a time  
time_duration td(not_a_date_time);
td.is_not_a_date_time(); // --> true
 
bool is_special() const
Returns true if time_duration is any special_value  
time_duration td(pos_infin); 
time_duration td2(not_a_date_time); 
time_duration td3(2,5,10);
td.is_special(); // --> true
td2.is_special(); // --> true
td3.is_special(); // --> false
 

Conversion To String

Syntax Description
Example
std::string to_simple_string(time_duration)
To HH:MM:SS.fffffffff where fffffffff is fractional seconds that are only included if non-zero.
10:00:01.123456789
std::string to_iso_string(time_duration)
Convert to form HHMMSS.fffffffff where the fractional seconds are only included if non-zero.
100001.123456789

Operators

Syntax Description
Example
operator<<, operator>>
Streaming operators. Note: As of version 1.33, streaming operations have been greatly improved. See Date Time IO System for more details (including exceptions and error conditions).
time_duration td(0,0,0);
stringstream ss("14:23:11.345678");
ss >> td; 
std::cout << td; // "14:23:11.345678"
  
operator==, operator!=,
operator>, operator<,
operator>=, operator<=
A full complement of comparison operators
dd1 == dd2, etc
time_duration operator+(time_duration)
Add durations.
time_duration td1(hours(1)+minutes(2));
time_duration td2(seconds(10));
time_duration td3 = td1 + td2;
time_duration operator-(time_duration)
Subtract durations.
time_duration td1(hours(1)+nanoseconds(2));
time_duration td2 = td1 - minutes(1);
time_duration operator/(int)
Divide the length of a duration by an integer value. Discards any remainder.
hours(3)/2 == time_duration(1,30,0);
nanosecond(3)/2 == nanosecond(1);
time_duration operator*(int)
Multiply the length of a duration by an integer value.
hours(3)*2 == hours(6);

Struct tm, time_t, and FILETIME Functions

Function for converting a time_duration to a tm struct is provided.

Syntax Description
Example
tm to_tm(time_duration)
A function for converting a time_duration object to a tm struct. The fields: tm_year, tm_mon, tm_mday, tm_wday, tm_yday are set to zero. The tm_isdst field is set to -1.
time_duration td(1,2,3);
tm td_tm = to_tm(td);
/* tm_year => 0
   tm_mon  => 0
   tm_mday => 0
   tm_wday => 0
   tm_yday => 0
   tm_hour => 1
   tm_min  => 2
   tm_sec  => 3
   tm_isdst => -1 */

Time Period

Introduction -- Header -- Construction -- Mutators -- Accessors -- Conversion To String -- Operators

Introduction

The class boost::posix_time::time_period provides direct representation for ranges between two times. Periods provide the ability to simplify some types of calculations by simplifying the conditional logic of the program.

A period that is created with beginning and end points being equal, or with a duration of zero, is known as a zero length period. Zero length periods are considered invalid (it is perfectly legal to construct an invalid period). For these periods, the last point will always be one unit less that the begin point.

The time periods example provides an example of using time periods.

Header

#include "boost/date_time/posix_time/posix_time.hpp" //include all types plus i/o
or
#include "boost/date_time/posix_time/posix_time_types.hpp" //no i/o just types

Construction

Syntax Description
Example
time_period(ptime,
            ptime)
Create a period as [begin, end). If end is <= begin then the period will be defined as invalid.
date d(2002,Jan,01);
ptime t1(d, seconds(10)); //10 sec after midnight
ptime t2(d, hours(10)); //10 hours after midnight
time_period tp(t1, t2);
time_period(ptime, 
            time_duration)
Create a period as [begin, begin+len) where end would be begin+len. If len is <= zero then the period will be defined as invalid.
date d(2002,Jan,01);
ptime t(d, seconds(10)); //10 sec after midnight
time_period tp(t, hours(3));
time_period(time_period rhs)
Copy constructor
time_period tp1(tp);

Mutators

Syntax Description
Example
time_period shift(time_duration)
Add duration to both begin and end.
time_period tp(ptime(date(2005,Jan,1),hours(1)), hours(2));
tp.shift(minutes(5)); 
// tp == 2005-Jan-01 01:05:00 to 2005-Jan-01 03:05:00
             
time_period expand(days)
Subtract duration from begin and add duration to end.
time_period tp(ptime(date(2005,Jan,1),hours(1)), hours(2));
tp.expand(minutes(5)); 
// tp == 2005-Jan-01 00:55:00 to 2005-Jan-01 03:05:00
             

Accessors

Syntax Description
Example
ptime begin()
Return first time of period.
date d(2002,Jan,01);
ptime t1(d, seconds(10)); //10 sec after midnight
ptime t2(d, hours(10)); //10 hours after midnight
time_period tp(t1, t2);
tp.begin(); // --> 2002-Jan-01 00:00:10
ptime last()
Return last time in the period
date d(2002,Jan,01);
ptime t1(d, seconds(10)); //10 sec after midnight
ptime t2(d, hours(10)); //10 hours after midnight
time_period tp(t1, t2);
tp.last();// --> 2002-Jan-01 09:59:59.999999999
ptime end()
Return one past the last in period
date d(2002,Jan,01);
ptime t1(d, seconds(10)); //10 sec after midnight
ptime t2(d, hours(10)); //10 hours after midnight
time_period tp(t1, t2);
tp.end(); // --> 2002-Jan-01 10:00:00
time_duration length()
Return the length of the time period.
date d(2002,Jan,01);
ptime t1(d); //midnight
time_period tp(t1, hours(1));
tp.length() --> 1 hour
bool is_null()
True if period is not well formed. eg: end is less than or equal to begin.
date d(2002,Jan,01);
ptime t1(d, hours(12)); // noon on Jan 1st
ptime t2(d, hours(9)); // 9am on Jan 1st
time_period tp(t1, t2);
tp.is_null(); // true
bool contains(ptime)
True if ptime is within the period. Zero length periods cannot contain any points.
date d(2002,Jan,01);
ptime t1(d, seconds(10)); //10 sec after midnight
ptime t2(d, hours(10)); //10 hours after midnight
ptime t3(d, hours(2)); //2 hours after midnight
time_period tp(t1, t2); 
tp.contains(t3); // true
time_period tp2(t1, t1);
tp2.contains(t1); // false
bool contains(time_period)
True if period is within the period
time_period tp1(ptime(d,hours(1)), 
                ptime(d,hours(12)));
time_period tp2(ptime(d,hours(2)), 
                ptime(d,hours(4)));
tp1.contains(tp2); // --> true
tp2.contains(tp1); // --> false
bool intersects(time_period)
True if periods overlap
time_period tp1(ptime(d,hours(1)),
                ptime(d,hours(12)));
time_period tp2(ptime(d,hours(2)), 
                ptime(d,hours(4)));
tp2.intersects(tp1); // --> true
time_period intersection(time_period)
Calculate the intersection of 2 periods. Null if no intersection.
 
time_period merge(time_period)
Returns union of two periods. Null if no intersection.
 
time_period span(time_period)
Combines two periods and any gap between them such that begin = min(p1.begin, p2.begin) and end = max(p1.end , p2.end).
 

Conversion To String

Syntax Description
Example
std::string 
  to_simple_string(time_period dp)
To [YYYY-mmm-DD hh:mm:ss.fffffffff/YYYY-mmm-DD hh:mm:ss.fffffffff] string where mmm is 3 char month name and the fractional seconds are only included if non-zero.
[2002-Jan-01 01:25:10.000000001/
                2002-Jan-31 01:25:10.123456789]
// string occupies one line

Operators

Syntax Description
Example
operator<<
Output streaming operator for time duration. Uses facet to output [date time_of_day/date time_of_day]. The default is format is [YYYY-mmm-DD hh:mm:ss.fffffffff/YYYY-mmm-DD hh:mm:ss.fffffffff] string where mmm is 3 char month name and the fractional seconds are only included if non-zero.
[2002-Jan-01 01:25:10.000000001/ \
    2002-Jan-31 01:25:10.123456789]
operator>>
Input streaming operator for time duration. Uses facet to read [date time_of_day/date time_of_day]. The default is format is [YYYY-mmm-DD hh:mm:ss.fffffffff/YYYY-mmm-DD hh:mm:ss.fffffffff] string where mmm is 3 char month name and the fractional seconds are only included if non-zero.
[2002-Jan-01 01:25:10.000000001/ \
    2002-Jan-31 01:25:10.123456789]
operator==, operator!=
Equality operators. Periods are equal if p1.begin == p2.begin && p1.last == p2.last
if (tp1 == tp2) {...
operator<
Ordering with no overlap. True if tp1.end() less than tp2.begin()
if (tp1 < tp2) {...
operator>
Ordering with no overlap. True if tp1.begin() greater than tp2.end()
if (tp1 > tp2) {... etc
operator<=, operator>=
Defined in terms of the other operators.
 

Time Iterators

Introduction -- Header -- Overview -- Operators

Introduction

Time iterators provide a mechanism for iteration through times. Time iterators are similar to Bidirectional Iterators. However, time_iterators are different than standard iterators in that there is no underlying sequence, just a calculation function. In addition, time_iterators are directly comparable against instances of class ptime. Thus a second iterator for the end point of the iteration is not required, but rather a point in time can be used directly. For example, the following code iterates using a 15 minute iteration interval. The print hours example also illustrates the use of the time_iterator.

      
	#include "boost/date_time/posix_time/posix_time.hpp"
	#include <iostream>


	int
	main()
	{
	  using namespace boost::gregorian;
	  using namespace boost::posix_time;
	  date d(2000,Jan,20);
	  ptime start(d);
	  ptime end = start + hours(1);
	  time_iterator titr(start,minutes(15)); //increment by 15 minutes
	  //produces 00:00:00, 00:15:00, 00:30:00, 00:45:00
	  while (titr < end) {
	    std::cout << to_simple_string(*titr) << std::endl;
	    ++titr;
	  }
	  std::cout << "Now backward" << std::endl;
	  //produces 01:00:00, 00:45:00, 00:30:00, 00:15:00
	  while (titr > start) {
	    std::cout << to_simple_string(*titr) << std::endl;
	    --titr;
	  }
	}
      
    

Header

#include "boost/date_time/posix_time/posix_time.hpp" //include all types plus i/o
or
#include "boost/date_time/posix_time/posix_time_types.hpp" //no i/o just types

Overview

Class Description
Construction Parameters
time_iterator
Iterate incrementing by the specified duration.
ptime start_time, time_duration increment

Operators

Syntax Description
Example
operator==(const ptime& rhs),
operator!=(const ptime& rhs),
operator>, operator<,
operator>=, operator<=
A full complement of comparison operators
date d(2002,Jan,1);
ptime start_time(d, hours(1));
//increment by 10 minutes
time_iterator titr(start_time, minutes(10));
ptime end_time = start_time + hours(2);
if (titr == end_time) // false
if (titr != end_time) // true
if (titr >= end_time) // false
if (titr <= end_time) // true
prefix increment
Increment the iterator by the specified duration.
//increment by 10 milli seconds
time_iterator titr(start_time, milliseconds(10));
++titr; // == start_time + 10 milliseconds
prefix decrement
Decrement the iterator by the specified time duration.
time_duration td(1,2,3);
time_iterator titr(start_time, td);
--titr; // == start_time - 01:02:03


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