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As constexpr
will not be supported
by some compilers, it is replaced in the code by BOOST_CONSTEXPR
for constexpr
functions and BOOST_STATIC_CONSTEXPR
for struct/class static
fields. The same applies to noexecpt
which is replaced by noexcept
in the code.
The documentation doesn't use these macros.
Include all the chrono header files.
#include <boost/chrono/chrono.hpp> #include <boost/chrono/chrono_io.hpp> #include <boost/chrono/process_cpu_clocks.hpp> #include <boost/chrono/thread_clocks.hpp> #include <boost/chrono/ceil.hpp> #include <boost/chrono/floor.hpp> #include <boost/chrono/round.hpp>
<boost/chrono.hpp>
<boost/chrono/chrono.hpp>
<boost/chrono/duration.hpp>
Clock
RequirementsTrivialClock
RequirementsEcClock
Requirements<boost/chrono/time_point.hpp>
<boost/chrono/system_clocks.hpp>
<boost/chrono/clock_strings.hpp>
<boost/chrono/typeof/boost/chrono/chrono.hpp>
Include only the standard files.
#include <boost/chrono/duration.hpp> #include <boost/chrono/time_point.hpp> #include <boost/chrono/system_clocks.hpp> #include <boost/chrono/typeof/boost/chrono/chrono.hpp>
At present, there is no know limitation respect to the C++11 standard.
The current implementation provides in addition:
When BOOST_NO_CXX11_STATIC_ASSERT
is defined, the user can select the way static assertions are reported.
Define
BOOST_CHRONO_USES_STATIC_ASSERT
:
define it if you want to use Boost.StaticAssert.
BOOST_CHRONO_USES_MPL_ASSERT
:
define it if you want to use Boost.MPL static assertions.
BOOST_CHRONO_USES_ARRAY_ASSERT
:
define it if you want to use internal static assertions.
The default behavior is as BOOST_CHRONO_USES_ARRAY_ASSERT
was defined.
When BOOST_CHRONO_USES_MPL_ASSERT
is not defined the following symbols are defined as
#define BOOST_CHRONO_A_DURATION_REPRESENTATION_CAN_NOT_BE_A_DURATION \ "A duration representation can not be a duration" #define BOOST_CHRONO_SECOND_TEMPLATE_PARAMETER_OF_DURATION_MUST_BE_A_STD_RATIO \ "Second template parameter of duration must be a boost::ratio" #define BOOST_CHRONO_DURATION_PERIOD_MUST_BE_POSITIVE \ "duration period must be positive" #define BOOST_CHRONO_SECOND_TEMPLATE_PARAMETER_OF_TIME_POINT_MUST_BE_A_BOOST_CHRONO_DURATION \ "Second template parameter of time_point must be a boost::chrono::duration"
Depending on the static assertion used system you will have an hint of the failing assertion either through the symbol or through the text.
When BOOST_CHRONO_DONT_PROVIDE_HYBRID_ERROR_HANDLING
is defined the lib don't provides the hybrid error handling prototypes:
Clock::time_point Clock::now(system::error_code&ec=boost::throws());
This allow to be closer to the standard and to avoid the Boost.System dependency, making possible to have Boost.Chrono as a header-only library.
By default BOOST_CHRONO_PROVIDE_HYBRID_ERROR_HANDLING
is defined.
When BOOST_CHRONO_HEADER_ONLY
is defined the lib is header-only.
If in addition BOOST_USE_WINDOWS_H
is defined <windows.h>
is included, otherwise files in
boost/detail/win
are used to reduce the impact
of including <windows.h>
.
However, you will either need to define BOOST_CHRONO_DONT_PROVIDE_HYBRID_ERROR_HANDLING
or link with Boost.System.
Version 2.0.0 deprecates the preceding IO features.
However the default version is always version 1. If you don't want
to include the deprecated features you could define BOOST_CHRONO_DONT_PROVIDES_DEPRECATED_IO_SINCE_V2_0_0
.
BOOST_CHRONO_VERSION
defines the Boost.Chrono version. The default version is 1. In this
case the following breaking or extending macros are defined if the
opposite is not requested:
BOOST_CHRONO_PROVIDES_DEPRECATED_IO_SINCE_V2_0_0
The user can request the version 2 by defining BOOST_CHRONO_VERSION
to 2. In this case the following breaking or extending macros are defined
if the opposite is not requested:
BOOST_CHRONO_DONT_PROVIDES_DEPRECATED_IO_SINCE_V2_0_0
The default value for BOOST_CHRONO_VERSION
will be changed to 2 since Boost 1.55.
This file contains duration specific classes and non-member functions.
namespace boost { namespace chrono { template <class Rep, class Period =ratio
<1> > classduration
; } template <class Rep1, class Period1, class Rep2, class Period2> structcommon_type
<duration<Rep1, Period1>, duration<Rep2, Period2> >; namespace chrono { // customization traits template <class Rep> structtreat_as_floating_point
; template <class Rep> structduration_values
; // duration arithmetic template <class Rep1, class Period1, class Rep2, class Period2> constexpr typename common_type<duration<Rep1, Period1>, duration<Rep2, Period2> >::typeoperator+
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr typename common_type<duration<Rep1, Period1>, duration<Rep2, Period2> >::typeoperator-
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period, class Rep2> constexpr duration<typename common_type<Rep1, Rep2>::type, Period>operator*
( const duration<Rep1, Period>& d, const Rep2& s); template <class Rep1, class Period, class Rep2> constexpr duration<typename common_type<Rep1, Rep2>::type, Period>operator*
( const Rep1& s, const duration<Rep2, Period>& d); template <class Rep1, class Period, class Rep2> constexpr duration<typename common_type<Rep1, Rep2>::type, Period>operator/
( const duration<Rep1, Period>& d, const Rep2& s); template <class Rep1, class Period1, class Rep2, class Period2> constexpr typename common_type<Rep1, Rep2>::typeoperator/
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); #ifdef BOOST_CHRONO_EXTENSIONS // Used to get frequency of events template <class Rep1, class Rep2, class Period> constexpr doubleoperator/
( const Rep1& s, const duration<Rep2, Period>& d); #endif // duration comparisons template <class Rep1, class Period1, class Rep2, class Period2> constexpr booloperator==
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr booloperator!=
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr bool __duration__op_le_1( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr booloperator<=
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr booloperator>
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, class Rep2, class Period2> constexpr booloperator>=
( const duration<Rep1, Period1>& lhs, const duration<Rep2, Period2>& rhs); // duration_cast template <class ToDuration, class Rep, class Period> constexpr ToDurationduration_cast
(const duration<Rep, Period>& d); // convenience typedefs typedef duration<boost::int_least64_t, nano>nanoseconds
; // at least 64 bits needed typedef duration<boost::int_least64_t, micro>microseconds
; // at least 55 bits needed typedef duration<boost::int_least64_t, milli>milliseconds
; // at least 45 bits needed typedef duration<boost::int_least64_t>seconds
; // at least 35 bits needed typedef duration<boost::int_least32_t, ratio< 60> >minutes
; // at least 29 bits needed typedef duration<boost::int_least32_t, ratio<3600> >hours
; // at least 23 bits needed } }
template <class Rep> struct treat_as_floating_point : boost::is_floating_point<Rep> {};
The duration
template uses the
treat_as_floating_point
trait
to help determine if a duration
with one tick period
can be converted to another duration
with a different
tick period. If treat_as_floating_point<Rep>::value
is true
, then Rep
is a floating-point type and
implicit conversions are allowed among duration
s. Otherwise, the
implicit convertibility depends on the tick periods of the duration
s. If Rep
is a class type which emulates
a floating-point type, the author of Rep
can specialize treat_as_floating_point
so
that duration
will treat this
Rep
as if it were a
floating-point type. Otherwise Rep
is assumed to be an integral type, or a class emulating an integral
type.
template <class Rep> struct duration_values { public: static constexpr Repzero
(); static constexpr Repmax
(); static constexpr Repmin
(); };
The duration
template uses the
duration_values
trait to construct
special values of the duration
's representation
(Rep
). This is done
because the representation might be a class type with behavior which
requires some other implementation to return these special values.
In that case, the author of that class type should specialize duration_values
to return
the indicated values.
static constexpr Rep zero();
Returns: Rep(0)
. Note:
Rep(0)
is specified instead of Rep()
since Rep()
may have some other meaning, such
as an uninitialized value.
Remarks: The value returned corresponds to the additive identity.
static constexpr Rep max();
Returns: numeric_limits<Rep>::max()
.
Remarks: The value returned compares greater than zero().
static constexpr Rep min();
Returns: numeric_limits<Rep>::lowest()
.
Remarks: The value returned compares
less than or equal to zero()
.
template <class Rep1, class Period1, class Rep2, class Period2> structcommon_type
<chrono::duration
<Rep1, Period1>, chrono::duration
<Rep2, Period2> > { typedef chrono::duration
<typenamecommon_type
<Rep1, Rep2>::type, see bellow> type; };
The period of the duration
indicated by this specialization
of common_type
is the
greatest common divisor of Period1
and Period2
. This can
be computed by forming a ratio
of the greatest common divisor of Period1::num
and Period2::num
, and the least common multiple
of Period1::den
and Period2::den
.
Note: The typedef type is the duration
with the largest tick
period possible where both duration
arguments will convert
to it without requiring a division operation. The representation of this
type is intended to be able to hold any value resulting from this conversion,
with the possible exception of round-off error when floating-point duration
s are involved (but
not truncation error).
A duration
measures time between
two points in time (time_point
). A duration
has a representation
which holds a count of ticks, and a tick period. The tick period is the
amount of time which occurs from one tick to another in units of a second.
It is expressed as a rational constant using ratio
.
namespace boost { namespace chrono { template <class Rep, class Period> class duration { public: typedef Rep rep; typedef Period period; private: rep rep_; // exposition only public: constexprduration
(); template <class Rep2> constexpr explicitduration
(const Rep2& r); template <class Rep2, class Period2> constexprduration
(const duration<Rep2, Period2>& d); duration& operator=(const duration&) = default; constexpr repcount
() const; constexpr duration __duration__op_plus(); constexpr duration __duration__op_minus(); duration&operator++
(); durationoperator++
(int); duration&operator--
(); durationoperator--
(int); duration&operator+=
(const duration& d); duration&operator-=
(const duration& d); duration&operator*=
(const rep& rhs); duration&operator/=
(const rep& rhs); duration&operator%=
(const rep& rhs); duration&operator%=
(const duration& rhs); static constexpr durationzero
(); static constexpr durationmin
(); static constexpr durationmax
(); }; }}
Rep
must be an arithmetic
type, or a class emulating an arithmetic type, compile diagnostic otherwise.
If duration
is instantiated with
the type of Rep
being
a duration
, compile diagnostic
is issued.
Period
must be an instantiation
of ratio
, compile diagnostic
otherwise.
Period::num
must be positive, compile diagnostic
otherwise.
Examples:
The following members of duration
do not throw an exception
unless the indicated operations on the representations throw an exception.
constexpr duration();
Effects: Constructs an object of type
duration
initialized from
duration_values<rep>::zero()
in C++98 or BOOST_CHRONO_DURATION_DEFAULTS_TO_ZERO
is defined, otherwise the duration is uninitialized.
template <class Rep2> constexpr explicit duration(const Rep2& r);
Remarks: Rep2
is implicitly convertible to rep
,
and
treat_as_floating_point<rep>::value
is true
, or
!treat_as_floating_point<rep>::value
&& !treat_as_floating_point<Rep2>::value
is true
.
If these constraints are not met, this constructor will not participate
in overload resolution. Note: This
requirement prevents construction of an integral-based duration
with a floating-point
representation. Such a construction could easily lead to confusion
about the value of the duration
.
Example:
duration
<int, milli> d(3.5); // do not compileduration
<int, milli> d(3); // ok
Effects: Constructs an object of type
duration
.
Post Conditions: count() == static_cast<rep>(r)
.
template <class Rep2, class Period2> constexprduration
(constduration
<Rep2, Period2>& d);
Remarks: treat_as_floating_point<rep>::value
,
or ratio_divide<Period2,
period>::type::den ==
1
, else this constructor will
not participate in overload resolution. note
This requirement prevents implicit truncation error when converting
between integral-based duration
s. Such a construction
could easily lead to confusion about the value of the duration
.
Example:
duration
<int, milli> ms(3);duration
<int, micro> us = ms; // okduration
<int, milli> ms2 = us; // do not compile
Effects: Constructs an object of type
duration
, constructing rep_
from duration_cast<
.
duration
>(d).count()
static constexpr duration
zero();
Returns:
.
duration
(duration_values
<rep>::zero())
static constexpr duration
min();
Returns: duration
(duration_values
<rep>::min()).
static constexpr duration
max();
Returns:
.
duration
(duration_values
<rep>::max())
template <class Rep1, class Period1, class Rep2, class Period2> constexpr typenamecommon_type
<duration
<Rep1, Period1>,duration
<Rep2, Period2> >::type operator+(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: CD(CD(lhs).count() + CD(rhs).count())
where CD
is the type
of the return value.
template <class Rep1, class Period1, class Rep2, class Period2> constexpr typenamecommon_type
<duration
<Rep1, Period1>,duration
<Rep2, Period2> >::type operator-(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: CD(CD(lhs).count() - CD(rhs).count())
where CD
is the type
of the return value.
template <class Rep1, class Period, class Rep2> constexprduration
<typenamecommon_type
<Rep1, Rep2>::type, Period> operator*(constduration
<Rep1, Period>& d, const Rep2& s);
Requires: Let CR
represent the common_type
of Rep1
and Rep2
. This function will not participate
in overload resolution unless both Rep1
and Rep2
are implicitly
convertible to CR
.
Returns: CD(CD(d).count() * s)
where CD
is the type
of the return value.
template <class Rep1, class Period, class Rep2> constexprduration
<typenamecommon_type
<Rep1, Rep2>::type, Period> operator*(const Rep1& s, constduration
<Rep2, Period>& d);
Requires: Let CR
represent the common_type
of Rep1
and Rep2
. This function will not participate
in overload resolution unless both Rep1
and Rep2
are implicitly
convertible to CR
.
Returns: d
* s
.
template <class Rep1, class Period, class Rep2> constexprduration
<typenamecommon_type
<Rep1, Rep2>::type, Period> operator/(constduration
<Rep1, Period>& d, const Rep2& s);
Requires: Let CR
represent the common_type
of Rep1
and Rep2
. This function will not participate
in overload resolution unless both Rep1
and Rep2
are implicitly
convertible to CR
,
and Rep2
is not an
instantiation of duration
.
Returns: CD(CD(d).count() / s)
where CD
is the type
of the return value.
template <class Rep1, class Period1, class Rep2, class Period2> constexpr typenamecommon_type
<Rep1, Rep2>::type operator/(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Remarks: Let CD
represent the common_type
of the two duration
arguments. Returns: Returns CD(lhs).count() / CD(rhs).count()
.
Included only if BOOST_CHRONO_EXTENSIONS is defined.
This overloading could be used to get the frequency of an event counted
by Rep1
.
template <class Rep1, class Rep2, class Period>
constexpr
double operator/(const Rep1& s, const duration
<Rep2, Period>& d);
Remarks: Let CR
represent the common_type
of Rep1
and Rep2
. This function will not participate
in overload resolution unless both Rep1
and Rep2
are implicitly
convertible to CR
,
and Rep1
is not an
instantiation of duration
. Let CD
represent duration
<CR,Period>.
Returns: CR(s)/CD(d).count()
where CD
is the type of the return value.
template <class Rep1, class Period, class Rep2> constexprduration
<typenamecommon_type
<Rep1, Rep2>::type, Period> operator%(constduration
<Rep1, Period>& d, const Rep2& s);
Remarks: Let CR
represent the common_type
of Rep1
and Rep2
. This function will not participate
in overload resolution unless Rep2 must be implicitly convertible to
CR and Rep2 must not be an instantiation of duration
.
Returns: CD(CD(d).count() % s) where
CD
is the type of the
return value.
template <class Rep1, class Period1, class Rep2, class Period2> constexpr typenamecommon_type
<duration
<Rep1, Period1>,duration
<Rep2, Period2> >::type operator%(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Remarks: This function will not participate in overload resolution unless
Returns: CD(CD(lhs).count() % CD(rhs).count())
where CD
is the type
of the return value.
template <class Rep1, class Period1, class Rep2, class Period2> bool operator==(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: Let CD
represent the common_type
of the two duration
arguments.
Returns: Returns CD(lhs).count() == CD(rhs).count()
template <class Rep1, class Period1, class Rep2, class Period2> bool operator!=(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: !(lhs ==
rhs)
.
template <class Rep1, class Period1, class Rep2, class Period2> bool operator< (constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: Let CD
represent the common_type
of the two duration
arguments. Returns
CD(lhs).count()
< CD(rhs).count()
template <class Rep1, class Period1, class Rep2, class Period2> bool operator<=(constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: !(rhs <
lhs)
.
template <class Rep1, class Period1, class Rep2, class Period2> bool operator> (constduration
<Rep1, Period1>& lhs, constduration
<Rep2, Period2>& rhs);
Returns: rhs
< lhs
.
template <classToDuration
, class Rep, class Period>ToDuration
duration_cast(constduration
<Rep, Period>& d);
Requires: This function will not participate
in overload resolution unless ToDuration
is an instantiation of duration
.
Returns: Forms CF
which is a ratio
resulting
from ratio_divide<Period, typename ToDuration::period>::type
.
Let CR
be the common_type
of ToDuration::rep
,
Rep
, and intmax_t
.
CF::num ==
1
and CF::den
== 1
,
then returns ToDuration(static_cast<typename
ToDuration::rep>(d.count()))
CF::num !=
1
and CF::den
== 1
,
then returns ToDuration(static_cast<typename
ToDuration::rep>(static_cast<CR>(d.count())
* static_cast<CR>(CF::num)))
CF::num ==
1
and CF::den
!= 1
,
then returns ToDuration(static_cast<typename
ToDuration::rep>(static_cast<CR>(d.count())
/ static_cast<CR>(CF::den)))
ToDuration(static_cast<typename
ToDuration::rep>(static_cast<CR>(d.count())
* static_cast<CR>(CF::num) / static_cast<CR>(CF::den)))
Remarks: This function does not rely
on any implicit conversions. All conversions must be accomplished through
static_cast
. The implementation
avoids all multiplications or divisions when it is known at compile-time
that it can be avoided because one or more arguments are 1
. All intermediate computations are carried
out in the widest possible representation and only converted to the destination
representation at the final step.
// convenience typedefs typedefduration
<boost::int_least64_t, nano> nanoseconds; // at least 64 bits needed typedefduration
<boost::int_least64_t, micro> microseconds; // at least 55 bits needed typedefduration
<boost::int_least64_t, milli> milliseconds; // at least 45 bits needed typedefduration
<boost::int_least64_t> seconds; // at least 35 bits needed typedefduration
<boost::int_least32_t,ratio
< 60> > minutes; // at least 29 bits needed typedefduration
<boost::int_least32_t,ratio
<3600> > hours; // at least 23 bits needed
A clock represents a bundle consisting of a duration
, a time_point
, and a function now()
to get the current time_point
. A clock must meet
the requirements in the following Table.
In this table C1
and C2
denote Clock
types. t1
and t2
are values returned from C1::now()
where the call returning t1
happens before the call returning t2
and both of these calls occur before C1::time_point::max()
. (note This means C1 did not wrap around
between t1 and t2.).
Table 7.1. Clock Requirements
expression |
return type |
operational semantics |
---|---|---|
|
An arithmetic type or class emulating an arithmetic type. |
The representation type of the |
|
|
The tick period of the clock in seconds. |
|
|
The |
|
|
The |
|
|
|
|
|
Returns a |
Models of Clock
:
A type TC
meets the TrivialClock
requirements if:
TC
satisfies the Clock
requirements,
TC::rep
, TC::duration
,
and TC::time_point
satisfy the requirements
of EqualityComparable
,
LessThanComparable
,
DefaultConstructible
,
CopyConstructible
,
CopyAssignable
, Destructible
, and the requirements
of numeric types.
Note | |
---|---|
This means, in particular, that operations on these types will not throw exceptions. |
TC::rep
,
TC::duration
, and TC::time_point
are swappable,
TC::now()
does not throw exceptions and it is thread-safe, and
TC::time_point::clock
meets the TrivialClock
requirements, recursively.
Models of TrivialClock
:
A type EcC
meets the EcClock
requirements if
TC
satisfies the TrivialClock
requirements, and
now()
interfaces allowing to recover internal error codes as described in
the following table.
In this table C1
denotes
a EcClock
type and ec
is an instance of a boost::system::error_code
.
Table 7.2. Clock Requirements
expression |
return type |
operational semantics |
---|---|---|
|
|
Returns a |
|
|
Returns a |
Models of Clock
:
This file contains time_point
specific classes and
non-member functions.
namespace boost { namespace chrono { template <classClock
, classDuration
= typename Clock::duration> classtime_point
; } template <classClock
, classDuration1
, classDuration2
> structcommon_type
<time_point<Clock, Duration1>, time_point<Clock, Duration2> >; namespace chrono { // time_point arithmetic template <classClock
, classDuration1
, class Rep2, class Period2> constexpr time_point<Clock, typename common_type<Duration1, duration<Rep2, Period2> >::type>operator+
(const time_point<Clock, Duration1>& lhs, const duration<Rep2, Period2>& rhs); template <class Rep1, class Period1, classClock
, classDuration2
> constexpr time_point<Clock, typename common_type<duration<Rep1, Period1>, Duration2>::type>operator+
(const duration<Rep1, Period1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, class Rep2, class Period2> constexpr time_point<Clock, typename common_type<Duration1, duration<Rep2, Period2> >::type>operator-
(const time_point<Clock, Duration1>& lhs, const duration<Rep2, Period2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr typename common_type<Duration1, Duration2>::typeoperator-
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); // time_point comparisons template <classClock
, classDuration1
, classDuration2
> constexpr booloperator==
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr booloperator!=
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr booloperator<
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr booloperator<=
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr booloperator>
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); template <classClock
, classDuration1
, classDuration2
> constexpr booloperator>=
(const time_point<Clock, Duration1>& lhs, const time_point<Clock, Duration2>& rhs); // time_point_cast template <classToDuration
, classClock
, classDuration
> constexpr time_point<Clock, ToDuration>time_point_cast
(const time_point<Clock, Duration>& t); } }
template <classClock
, classDuration1
, classDuration2
> structcommon_type
<chrono::time_point
<Clock
,Duration1
>, chrono::time_point
<Clock
,Duration2
> > { typedef chrono::time_point
<Clock
, typenamecommon_type
<Duration1,Duration2
>::type> type; };
The common_type
of two
time_point
s is a time_point
with the same Clock
(both have the same Clock
), and the common_type
of the two duration
s.
A time_point
represents a point
in time with respect to a specific clock.
template <classClock
, classDuration
> class time_point { public: typedef Clock clock; typedef Duration duration; typedef typename duration::rep rep; typedef typename duration::period period; private: duration d_; // exposition only public: constexprtime_point
(); constexpr explicittime_point
(const duration& d); // conversions template <classDuration2
> constexprtime_point
(const time_point<clock,Duration2
>& t); // observer constexpr durationtime_since_epoch
() const; // arithmetic #ifdef BOOST_CHRONO_EXTENSIONS constexpr time_pointoperator+
(); constexpr time_pointoperator-
(); time_point&operator++
(); time_pointoperator++
(int); time_point&operator--
(); time_pointoperator--
(int); time_point& __time_point__op_plus_eq_1(const rep& d); time_point&operator-=
(const rep& d); #endif time_point& __time_point__op_plus_eq_2(const duration& d); time_point&operator-=
(const duration& d); // special values static constexpr time_pointmin
(); static constexpr time_pointmax
(); };
Clock must meet the Clock
requirements.
Duration must be an instantiation of duration
, compile diagnostic
otherwise.
constexpr time_point();
Effects: Constructs an object of
time_point
, initializing
d_
with duration::zero()
.
This time_point
represents the
epoch.
constexpr time_point(const duration& d);
Effects: Constructs an object of
time_point
, initializing
d_
with d
. This time_point
represents the
epoch + d
.
template <classDuration2
> constexpr time_point(consttime_point
<clock,Duration2
>& t);
Requires: This function will not participate
in overload resolution unless Duration2
is implicitly convertible to duration
.
Effects: Constructs an object of
time_point
, initializing
d_
with t.time_since_epoch()
.
time_point& operator+=(const duration& d);
Effects: d_
+= d
.
Returns: *this
.
time_point& operator-=(const duration& d);
Effects: d_
-= d
Returns: *this
.
template <classClock
, classDuration1
, class Rep2, class Period2> constexprtime_point
<Clock
, typenamecommon_type
<Duration1, duration<Rep2, Period2> >::type> operator+(consttime_point
<Clock
,Duration1
>& lhs, const duration<Rep2, Period2>& rhs);
Returns: CT(lhs.time_since_epoch() + rhs)
where CT
is the type
of the return value.
template <class Rep1, class Period1, classClock
, classDuration2
> constexprtime_point
<Clock
, typenamecommon_type
<duration<Rep1, Period1>,Duration2
>::type> operator+(const duration<Rep1, Period1>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: rhs
+ lhs
.
template <classClock
, classDuration1
, class Rep2, class Period2> constexprtime_point
<Clock
, typenamecommon_type
<Duration1, duration<Rep2, Period2> >::type> operator-(consttime_point
<Clock
,Duration1
>& lhs, const duration<Rep2, Period2>& rhs);
Returns: lhs
+ (-rhs)
.
template <classClock
, classDuration1
, classDuration2
> constexpr typenamecommon_type
<Duration1,Duration2
>::type operator-(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: lhs.time_since_epoch() - rhs.time_since_epoch()
.
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator==(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: lhs.time_since_epoch() == rhs.time_since_epoch()
.
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator!=(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: !(lhs ==
rhs)
.
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator< (consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: lhs.time_since_epoch() < rhs.time_since_epoch().
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator<=(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: !(rhs <
lhs)
.
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator>(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: rhs
< lhs
.
template <classClock
, classDuration1
, classDuration2
> constexpr bool operator>=(consttime_point
<Clock
,Duration1
>& lhs, consttime_point
<Clock
,Duration2
>& rhs);
Returns: !(lhs <
rhs)
.
template <classToDuration
, classClock
, classDuration
> constexprtime_point
<Clock
, ToDuration>time_point_cast
(consttime_point
<Clock
,Duration
>& t);
Requires: This function will not participate
in overload resolution unless ToDuration
is an instantiation of duration
.
Returns:
.
time_point
<Clock
, ToDuration>(duration_cast
<ToDuration>(t.time_since_epoch()))
This file contains the standard clock classes. The types defined in this
section satisfy the TrivialClock
requirements
namespace boost { namespace chrono { // Clocks classsystem_clock
; classsteady_clock
; classhigh_resolution_clock
; template <class CharT> struct clock_string<system_clock, CharT>; template <class CharT> struct clock_string<steady_clock, CharT>; } }
The system_clock
class provides
a means of obtaining the current wall-clock time from the system-wide
real-time clock. The current time can be obtained by calling system_clock::now()
.
Instances of system_clock::time_point
can be converted to and from time_t with the system_clock::to_time_t()
and system_clock::from_time_t()
functions. If system clock is not steady,
a subsequent call to system_clock::now()
may return an earlier time than a previous
call (e.g. if the operating system clock is manually adjusted, or synchronized
with an external clock).
The current implementation of system_clock
is related an epoch
(midnight UTC of January 1, 1970), but this is not in the contract. You
need to use the static function static
std::time_t to_time_t(const time_point& t);
which returns a time_t
type that is based on midnight UTC of January 1, 1970.
class system_clock {
public:
typedef see bellow duration;
typedef duration::rep rep;
typedef duration::period period;
typedef chrono::time_point
<system_clock> time_point;
static constexpr bool is_steady = false;
static time_point now() noexcept;
static time_point now(system::error_code & ec);
// Map to C API
static std::time_t to_time_t(const time_point& t) noexcept;
static time_point from_time_t(std::time_t t) noexcept;
};
system_clock
satisfy the Clock
requirements:
system_clock::duration::min()
< system_clock::duration::zero()
is true
.
duration
typedef has a resolution that depends on the one provided by the
platform.
time_t to_time_t(const time_point& t) noexcept;
Returns: A time_t
such that the time_t
and t
represent the
same point in time, truncated to the coarser of the precisions among
time_t
and time_point
.
time_point from_time_t(time_t t) noexcept;
Returns: A time_point
such that the
time_point
and t
represent the same point in time,
truncated to the coarser of the precisions among time_point
and time_t
.
Defined if the platform support steady clocks.
steady_clock
satisfy the Clock
requirements.
steady_clock
class provides
access to the system-wide steady clock. The current time can be obtained
by calling steady_clock::now()
. There is no fixed relationship between
values returned by steady_clock::now()
and wall-clock time.
#ifdef BOOST_HAS_CLOCK_STEADY class steady_clock { public: typedefnanoseconds
duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<steady_clock> time_point; static constexpr bool is_steady = true; static time_point now() noexcept; static time_point now(system::error_code & ec); }; #endif
high_resolution_clock
satisfy
the Clock
requirements.
#ifdefBOOST_CHRONO_HAS_CLOCK_STEADY
typedefsteady_clock
high_resolution_clock; // as permitted by [time.clock.hires] #else typedefsystem_clock
high_resolution_clock; // as permitted by [time.clock.hires] #endif
template <class CharT> struct clock_string<system_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); };
clock_string<>::name()
returns "system_clock".
clock_string<>::since()
returns " since Jan 1, 1970"
#ifdef BOOST_CHRONO_HAS_CLOCK_STEADY template <class CharT> struct clock_string<steady_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); }; #endif
clock_string<>::name()
returns "steady_clock".
clock_string<>::since()
returns " since boot"
namespace boost {
namespace chrono {
template <class Clock
, class CharT>
struct clock_string;
}
}
template <class Clock
, class CharT>
struct clock_string;
This template must be specialized for specific clocks. The specialization must define the following functions
static std::basic_string<CharT> name(); static std::basic_string<CharT> since();
clock_string<>::name()
return the clock name, which usually corresponds to the class name.
clock_string<>::since()
return the textual format of the clock epoch.
Register duration
<>
and time_point
<>
class templates to Boost.Typeof.
namespace boost { namespace chrono { template <class CharT> class duration_punct; template <class CharT, class Traits> std::basic_ostream<CharT, Traits>& duration_short(std::basic_ostream<CharT, Traits>& os); template <class CharT, class Traits> std::basic_ostream<CharT, Traits>& duration_long(std::basic_ostream<CharT, Traits>& os); template <class CharT, class Traits, class Rep, class Period> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const duration<Rep, Period>& d); template <class CharT, class Traits, class Rep, class Period> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, duration<Rep, Period>& d) template <class CharT, class Traits, class Clock, class Duration> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const time_point<Clock, Duration>& tp); template <class CharT, class Traits, class Clock, class Duration> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, time_point<Clock, Duration>& tp); } }
The duration
unit names can be customized
through the facet: duration_punct
. duration
unit names come in
two varieties: long and short. The default constructed duration_punct
provides names
in the long format. These names are English descriptions. Other languages
are supported by constructing a duration_punct
with the proper
spellings for "hours", "minutes" and "seconds",
and their abbreviations (for the short format).
template <class CharT> class duration_punct : public std::locale::facet { public: typedef std::basic_string<CharT> string_type; enum {use_long, use_short}; static std::locale::id id; explicit duration_punct(int use = use_long); duration_punct(int use, const string_type& long_seconds, const string_type& long_minutes, const string_type& long_hours, const string_type& short_seconds, const string_type& short_minutes, const string_type& short_hours); duration_punct(int use, const duration_punct& d); template <class Period> string_type short_name() const; template <class Period> string_type long_name() const; template <class Period> string_type name() const; bool is_short_name() const; bool is_long_name() const; };
The short or long format can be easily chosen by streaming a duration_short
or duration_long
manipulator respectively.
template <class CharT, class Traits> std::basic_ostream<CharT, Traits>& duration_short(std::basic_ostream<CharT, Traits>& os);
Effects: Set the duration_punct
facet to stream
duration
s and time_point
s as abbreviations.
Returns: the output stream
template <class CharT, class Traits> std::basic_ostream<CharT, Traits>& duration_long(std::basic_ostream<CharT, Traits>& os);
Effects: Set the duration_punct
facet to stream
durations and time_points as long text.
Returns: the output stream
Any duration
can be streamed out
to a basic_ostream
. The
run-time value of the duration
is formatted according
to the rules and current format settings for duration
::rep
. This is followed by a single space
and then the compile-time unit name of the duration
. This unit name is
built on the string returned from ratio_string<>
and the data used to construct
the duration_punct
which was inserted
into the stream's locale. If a duration_punct
has not been
inserted into the stream's locale, a default constructed duration_punct
will be added
to the stream's locale.
A time_point
is formatted by outputting
its internal duration
followed by a string
that describes the time_point
::clock
epoch. This string will vary
for each distinct clock, and for each implementation of the supplied
clocks.
template <class CharT, class Traits, class Rep, class Period> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const duration<Rep, Period>& d);
Effects: outputs the duration
as an abbreviated or
long text format depending on the state of the duration_punct
facet.
Returns: the output stream
template <class CharT, class Traits, class Rep, class Period> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, duration<Rep, Period>& d)
Effects: reads a duration
from the input stream.
If a format error is found, the input stream state will be set to failbit
.
Returns: the input stream
template <class CharT, class Traits, class Clock, class Duration> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const time_point<Clock, Duration>& tp);
Effects: outputs the time_point
as an abbreviated
or long text format depending on the state of the duration_punct
facet.
Returns: the output stream
template <class CharT, class Traits, class Clock, class Duration> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, time_point<Clock, Duration>& tp);
Effects: reads a time_point
from the input stream.
If a format error is found, the input stream state will be set to failbit
.
Returns: the input stream
<boost/chrono/chrono_io.hpp>
<boost/chrono/io/duration_style.hpp>
<boost/chrono/io/timezone.hpp>
<boost/chrono/io/ios_base_state.hpp>
<boost/chrono/io/duration_get.hpp>
<boost/chrono/io/duration_put.hpp>
<boost/chrono/io/duration_units.hpp>
<boost/chrono/io/duration_io.hpp>
<boost/chrono/io/time_point_get.hpp>
<boost/chrono/io/time_point_put.hpp>
<boost/chrono/io/time_point_units.hpp>
<boost/chrono/io/time_point_io.hpp>
This file includes the i/o of the two major components, duration and time_point.
#include <boost/chrono/io/duration_style.hpp> #include <boost/chrono/io/timezone.hpp> #include <boost/chrono/io/ios_base_state.hpp> #include <boost/chrono/io/duration_get.hpp> #include <boost/chrono/io/duration_put.hpp> #include <boost/chrono/io/duration_units.hpp> #include <boost/chrono/io/duration_io.hpp> #include <boost/chrono/io/time_point_get.hpp> #include <boost/chrono/io/time_point_put.hpp> #include <boost/chrono/io/time_point_units.hpp> #include <boost/chrono/io/time_point_io.hpp>
namespace boost { namespace chrono { // typedefs enum classduration_style
{prefix
,symbol
}; } }
enum class duration_style { prefix, symbol };
duration
unit names come in
two varieties: prefix and symbol.
namespace boost { namespace chrono { structtimezone
{ enum type {utc
,local
}; }; } }
enum class timezone { utc, local };
namespace boost { namespace chrono { // setters and getters duration_styleget_duration_style
(std::ios_base & ios); voidset_duration_style
(std::ios_base& ios, duration_style style); timezoneget_timezone
(std::ios_base & ios); voidset_timezone
(std::ios_base& ios, timezone tz); template<typename CharT> std::basic_string<CharT>get_time_fmt
(std::ios_base & ios); template<typename CharT> voidset_time_fmt
(std::ios_base& ios, std::basic_string<CharT> const& fmt); // i/o state savers structduration_style_io_saver
; template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtimezone_io_saver
; template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtime_fmt_io_saver
; } }
duration_style get_duration_style(std::ios_base & ios);
Returns: The stream's duration_style
attribute associated
to ios
.
void set_duration_style(std::ios_base& ios, duration_style style);
Effects: Set the stream's duration_style
attribute associated
to ios
with the style
parameter.
timezone get_timezone(std::ios_base & ios);
Returns: The stream's timezone
attribute associated
to ios
.
void set_timezone(std::ios_base& ios, timezone tz);
Effects: Set the stream's timezone
attribute associated
to ios
with the tz
parameter.
template<typename CharT> std::basic_string<CharT> get_time_fmt(std::ios_base & ios);
Returns: The stream's time format
attribute associated to ios
.
template<typename CharT> void set_time_fmt(std::ios_base& ios, std::basic_string<CharT> const& fmt);
Effects: Set the stream's time format
attribute associated to ios
with the fmt
parameter.
The format is composed of zero or more directives. Each directive is composed of one of the following:
* one or more white-space characters (as specified by isspace()); * an ordinary character (neither '%' nor a white-space character); * or a conversion specification.
Each conversion specification is composed of a '%' character followed by a conversion character which specifies the replacement required. The application shall ensure that there is white-space or other non-alphanumeric characters between any two conversion specifications. The following conversion specifications are supported:
Table 7.3. Format tags
Format Specifier |
Description |
Example |
---|---|---|
|
Replaced by |
. |
|
The day of the week, using the locale's weekday names; either the abbreviated or full name may be specified. |
"Monday". |
|
The month, using the locale's month names; either the abbreviated or full name may be specified. |
"February". |
|
Not supported. |
. |
|
The day of the month |
. |
|
The date as |
. |
|
The date as |
. |
|
The hour (24-hour clock) |
. |
|
The hour (12-hour clock) |
. |
|
The day number of the year |
"060" => Feb-29. |
|
The month number |
"01" => January. |
|
The minute |
. |
|
Any white space.. |
. |
|
Not supported. |
. |
|
Not supported. |
. |
|
The time as |
. |
|
The seconds |
. |
|
The time as |
. |
|
Not supported. |
. |
|
The weekday as a decimal number |
"0" => Sunday. |
|
Not supported. |
. |
|
The date, using the locale's date format.. |
. |
|
Not supported. |
. |
|
Not supported. |
"2005". |
|
The year, including the century (for example, 1988). |
. |
// i/o state savers struct duration_style_io_saver { typedef std::ios_base state_type; // the state type is ios_base typedefduration_style
aspect_type; // the aspect type is the __duration_style explicitduration_style_io_saver
(state_type &s);duration_style_io_saver
(state_type &s, aspect_type new_value);~duration_style_io_saver
(); voidrestore
(); };
The state_type
is a
version of the IOStreams base class std::ios_base
.
This constructor takes a stream object and saves a reference to the stream and the current value of a particular stream attribute.
explicit duration_style_io_saver(state_type &s);
Effects: Constructs a duration_style_io_saver
by storing s
.
This constructor works like the previous one, and in addition uses
its second argument to change the stream's attribute to the new
aspect_type
value
given.
explicit duration_style_io_saver(state_type &s, aspect_type new_value);
Effects: Constructs a duration_style_io_saver
by storing s
. Sets
the state_type
aspect_type
with the value new_value
.
The destructor restores the stream's attribute to the saved value.
~duration_style_io_saver();
Effects: As if restore
().
The restoration can be activated early (and often) with the restore member function.
void restore();
Effects: Restores the stream's
duration_style
attribute
to the saved value.
template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtimezone_io_saver
{ typedef std::basic_ios<CharT, Traits> state_type; typedeftimezone
aspect_type; explicittimezone_io_saver
(state_type &s);timezone_io_saver
(state_type &s, aspect_type new_value);~timezone_io_saver
(); void timezone_io_saver__restore(); };
The state_type
is a
version of the IOStreams base class template std::basic_ios<CharT, Traits>
, where CharT
is a character type and Traits
is a character traits class. The user would usually place an actual
input, output, or combined stream object for the state-type parameter,
and not a base class object.
This constructor takes a stream object and saves a reference to the stream and the current value of a particular stream attribute.
explicit timezone_io_saver(state_type &s);
Effects: Constructs a timezone_io_saver
by storing
s
.
This constructor works like the previous one, and uses its second argument to change the stream's attribute to the new aspect_type value given.
explicit timezone_io_saver(state_type &s, aspect_type new_value);
Effects: Constructs a timezone_io_saver
by storing
s
. Sets the state_type
aspect_type
with the value new_value
.
The destructor restores the stream's attribute to the saved value.
~timezone_io_saver();
Effects: As if restore
().
The restoration can be activated early (and often) with the restore member function.
void restore();
Effects: Restores the stream's
timezone
attribute to the
saved value.
template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtime_fmt_io_saver
{ typedef std::basic_ios<CharT, Traits> state_type; explicittime_fmt_io_saver
(state_type &s);time_fmt_io_saver
(state_type &s, basic_string<CharT> const& new_value);~time_fmt_io_saver
(); voidrestore
(); };
The state_type
is a
version of the IOStreams base class template std::basic_ios<CharT, Traits>
, where CharT
is a character type and Traits
is a character traits class. The user would usually place an actual
input, output, or combined stream object for the state-type parameter,
and not a base class object.
This constructor takes a stream object and saves a reference to the stream and the current value of a particular stream attribute.
explicit time_fmt_io_saver(state_type &s);
Effects: Constructs a time_fmt_io_saver
by storing
s
.
This constructor works like the previous one, and uses its second argument to change the stream's attribute to the new aspect_type value given.
explicit time_fmt_io_saver(state_type &s, aspect_type new_value);
Effects: Constructs a time_fmt_io_saver
by storing
s
. Sets the state_type
aspect_type
with the value new_value
.
The destructor restores the stream's attribute to the saved value.
~time_fmt_io_saver();
Effects: As if restore
().
The restoration can be activated early (and often) with the restore member function.
void restore();
Effects: Restores the stream's time format attribute to the saved value.
namespace boost {
namespace chrono {
template <class CharT, class InputIterator = std::istreambuf_iterator<CharT> >
class duration_get
;
}
}
template <class CharT, class InputIterator = std::istreambuf_iterator<CharT> > class duration_get: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on typedef std::basic_string<CharT> string_type; // Type of character string passed to member functions. typedef InputIterator iter_type; // Type of iterator used to scan the character buffer. explicitduration_get
(size_t refs = 0); template <typename Rep, typename Period> iter_typeget
( iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, duration<Rep, Period>& d, const char_type* pattern, const char_type* pat_end ) const; template <typename Rep, typename Period> iter_typeget
( iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, duration<Rep, Period>& d ) const; template <typename Rep> iter_typeget_value
( iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, Rep& r ) const; iter_typeget_unit
( iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err, detail::rt_ratio &rt ) const static std::locale::id id; // Unique identifier for this type of facet.~duration_get
() { } };
The duration_get
facet extracts
duration from a character string and stores the resulting value in a
class duration d argument. The facet parses the string using a specific
format as a guide. If the string does not fit the format, then the facet
will indicate an error by setting the err argument to iosbase::failbit.
In other words, user confirmation is required for reliable parsing of
user-entered durations, but machine-generated formats can be parsed reliably.
This allows parsers to be aggressive about interpreting user variations
on standard formats.
explicit duration_get(size_t refs);
Constructs a duration_get
facet.
Parameters:
Effects: Constructs a duration_get
facet. If the
refs
argument is 0
then destruction of the object is delegated
to the locale, or locales, containing it. This allows the user to ignore
lifetime management issues. On the other had, if refs
is 1
then the object must
be explicitly deleted; locale
will not do so. In this case, the object can be maintained across the
lifetime of multiple locales.
template <typename Rep, typename Period> iter_type get(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, duration<Rep, Period> &d, const char_type *pattern, const char_type *pat_end) const;
Extracts a duration from the range [s,end)
following the pattern [pattern,pat_end)
.
Parameters:
Requires: [s, end) and [pattern,
pat_end)
shall be valid ranges.
Effects: The function starts by evaluating
err =
std::ios_base::goodbit
.
Then it computes an intermediate representation based on Rep
according to the following rules:
Rep
is a floating
point type, the intermediate representation is long
double
.
Rep
is
a signed integral type, the intermediate representation is long long
.
Rep
is
an unsigned integral type, the intermediate representation is unsigned
long long.
Rep
.
Next the following local variable r
of type intermediate representation and rt
of type rt_ratio
are
default constructed.
It then enters a loop, reading zero or more characters from s
at each iteration. Unless otherwise
specified below, the loop terminates when the first of the following
conditions holds:
pattern
== pat_end
evaluates to true
.
err == std::ios_base::goodbit
evaluates to false.
s == end
evaluates to true
,
in which case the function evaluates err
= std::ios_base::eofbit
| std::ios_base::failbit
.
'%'
,
followed by a conversion specifier character, format. If the number
of elements in the range [pattern,pat_end)
is not sufficient to unambiguously determine whether the conversion
specification is complete and valid, the function evaluates err =
std::ios_base::failbit
. Otherwise, the function
evaluates s =
get_value(s,
end,
ios,
err,
r)
when the conversion specification is 'v' and s
= get_value(s, end, ios, err, rt)
when the conversion specification
is 'u'. If err == std::ios_base::goodbit
holds after the evaluation of the expression, the function increments
pattern to point just past the end of the conversion specification
and continues looping.
isspace(*pattern, ios.getloc())
evaluates to true
,
in which case the function first increments pattern until pattern ==
pat_end ||
!isspace(*pattern, ios.getloc())
evaluates to true
,
then advances s
until s ==
end ||
!isspace(*s, ios.getloc())
is true
,
and finally resumes looping.
s
matches the element pointed to by pattern in a case-insensitive
comparison, in which case the function evaluates ++pattern, ++s
and continues looping. Otherwise,
the function evaluates err
= std::ios_base::failbit
.
If a duration representation value and a unit specifier have successfully
been parsed, compute (rt.num/rt.den)/(Period::num/Period::den)
reduced to lowest terms. If this ratio can not be stored without overflow,
evaluates err =
std::ios_base::failbit
. Otherwise store the result
of this division in num
and den
.
If the division did not result in overflow, then compute r * num / den
in such a way as to avoid intermediate
overflow. If r
has
integral type and this computation would not be exact, evaluates err = std::ios_base::failbit
. If the result of the computation
would overflow Rep
,
evaluates err =
std::ios_base::failbit
. Otherwise the result of
r *
num /
den
is used to construct
a duration<Rep, Period>
which is assigned to d
.
Returns: s
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid duration.
template <typename Rep, typename Period> iter_type get( iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, duration<Rep, Period>& d ) const;
Extracts a duration from the range [s,end)
following the default pattern.
Parameters:
Effects: Stores the duration pattern
from the __duration_unit facet associated to 'ios in
let say
str`. Last as if
return get(s, end, ios, err, ios, d, str.data(), str.data() + str.size());
Returns: s
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid duration.
template <typename Rep> iter_type get_value(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, Rep& r) const;
Extracts a duration representation from the range [s,end)
.
Parameters:
Effects: As if
return std::use_facet<std::num_get<char_type, iter_type>>(ios.getloc()).get(s, end, ios, err, r);
Returns: s
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid Rep
value.
iter_type get_unit(iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err, detail::rt_ratio &rt) const;
Extracts a duration unit from the range [s,end)
.
Parameters:
Effects:
'['
,
an attempt is made to consume a pattern of the form "[N/D]"
where N
and D
have type unsigned long long
.
N
and D
, otherwise
evaluates err = std::ios_base::failbit
and return i
.
"[N/D]"
, as if
return do_get_n_d_prefix_unit(facet, i, e, is, err);
'['
.
Return the parse the longest string possible matching one of the
durations units, as if
return do_get_prefix_unit(facet, i, e, is, err, rt);
Returns: i
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid duration unit.
virtual iter_type do_get_n_d_prefix_unit( duration_units<CharT> const &facet, iter_type i, iter_type e, std::ios_base&, std::ios_base::iostate& err ) const;
Extracts the run-time ratio associated to the duration when it is given in [N/D] form.
This is an extension point of this facet so that we can take in account other periods that can have a useful translation in other contexts, as e.g. days and weeks.
Parameters:
Effects: Scan s
for the longest of all the plural forms associated with the duration
units. If successful, sets the matched ratio in rt
.
Otherwise evaluates err = std::ios_base::failbit
.
Returns: s
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid name.
virtual iter_type do_get_prefix_unit( duration_units<CharT> const &facet, iter_type i, iter_type e, std::ios_base&, std::ios_base::iostate& err, detail::rt_ratio &rt ) const;
Extracts the run-time ratio associated to the duration when it is given in prefix form.
This is an extension point of this facet so that we can take in account other periods that can have a useful translation in other contexts, as e.g. days and weeks.
Parameters:
Effects: Scan s
for the longest of all the plural forms associated with the duration
units. If successful, sets the matched ratio in rt
.
Otherwise evaluates err = std::ios_base::failbit
.
Returns: s
,
an iterator pointing just beyond the last character that can be determined
to be part of a valid name.
namespace boost {
namespace chrono {
template <class CharT, class OutputIterator = std::ostreambuf_iterator<CharT> >
class duration_put
;
}
}
template <class CharT, class OutputIterator = std::ostreambuf_iterator<CharT> > class duration_put: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef std::basic_string<CharT> string_type; // Type of character string passed to member functions. typedef OutputIterator iter_type; // Type of iterator used to write in the character buffer. explicitduration_put
(size_t refs = 0); template <typename Rep, typename Period> iter_typeput
(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d, const CharT* pattern, const CharT* pat_end) const; template <typename Rep, typename Period> iter_typeput
(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const; template <typename Rep, typename Period> iter_typeput_value
(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const; template <typename Rep, typename Period> iter_typeput_unit
(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const; static std::locale::id id; // Unique identifier for this type of facet.~duration_put
(); };
explicit duration_put(size_t refs);
Constructs a duration_put
facet.
Parameters:
Effects: Constructs a duration_put
facet. If the
refs
argument is 0
then destruction of the object is delegated
to the locale, or locales, containing it. This allows the user to ignore
lifetime management issues. On the other had, if refs
is 1
then the object must
be explicitly deleted; locale
will not do so. In this case, the object can be maintained across the
lifetime of multiple locales.
template <typename Rep, typename Period> iter_type put(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d, const CharT* pattern, const CharT* pat_end) const;
Parameters:
Effects: Steps through the sequence
from pattern
to pat_end
, identifying characters that
are part of a pattern sequence. Each character that is not part of
a pattern sequence is written to s
immediately, and each pattern sequence, as it is identified, results
in a call to put_value
or put_unit
; thus,
pattern elements and other characters are interleaved in the output
in the order in which they appear in the pattern. Pattern sequences
are identified by converting each character c
to a char
value as if
by ct.narrow(c,0)
, where
ct
is a reference to
ctype<charT>
obtained from ios.getloc()
.
The first character of each sequence is equal to '%'
,
followed by a pattern specifier character specifier, which can be
'v'
for the duration value
or 'u'
for the duration unit.
. For each valid pattern sequence identified, calls put_value(s, ios, d)
or put_unit(s, ios, d)
.
Returns: An iterator pointing immediately after the last character produced.
template <typename Rep, typename Period> iter_type put(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const;
Parameters:
Retrieves Stores the duration pattern from the __duration_unit facet
in let say str
. Last
as if
return put(s, ios, d, str.data(), str.data() + str.size());
Returns: An iterator pointing immediately after the last character produced.
template <typename Rep, typename Period> iter_type put_value(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const;
Parameters:
Effects: As if std::use_facet<std::num_put<CharT, iter_type> >(ios.getloc()).put(s, ios, ' ', static_cast<long int> (d.count())).
Returns: An iterator pointing immediately after the last character produced.
template <typename Rep, typename Period> iter_type put_unit(iter_type s, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const;
Parameters:
Effects: Let facet
be the duration_units<CharT>
facet associated to ios
. If the associated unit is named,
as if
string_type str = facet.get_unit(get_duration_style(ios), d); s=std::copy(str.begin(), str.end(), s);
Otherwise, format the unit as "[Period::num/Period::den]"
followed by the unit associated to [N/D] obtained using facet.get_n_d_unit(get_duration_style(ios), d)
.
Returns: s, iterator pointing immediately after the last character produced.
namespace boost { namespace chrono { class rt_ratio; template <typename CharT = char> class duration_units; } }
class rt_ratio { public: template <typename Period> rt_ratio(Period const&) : num(Period::type::num), den(Period::type::den) { } rt_ratio(intmax_t n = 0, intmax_t d = 1) : num(n), den(d) { } intmax_t num; intmax_t den; };
template <typename CharT = char> class duration_units: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef std::basic_string<CharT> string_type; // Type of character string passed to member functions. static std::locale::id id; // Unique identifier for this type of facet. explicitduration_units
(size_t refs = 0); virtual const string_type*get_n_d_valid_units_start
() const =0; virtual const string_type*get_n_d_valid_units_end
() const=0; virtual const string_type*get_valid_units_start
() const=0; virtual const string_type*get_valid_units_end
() const=0; virtual boolmatch_n_d_valid_unit
(const string_type* k) const = 0; virtual boolmatch_valid_unit
(const string_type* k, rt_ratio& rt) const = 0; virtual string_typeget_pattern
() const=0; template <typename Rep, typename Period> string_typeget_unit
(duration_style style, duration<Rep, Period> const& d) const; template <typename Rep, typename Period> string_typeget_n_d_unit
(duration_style style, duration<Rep, Period> const& d) const; template <typename Period> boolis_named_unit
() const; protected: virtual~duration_units
(); virtual string_typedo_get_n_d_unit
(duration_style style, rt_ratio rt, intmax_t v) const = 0; virtual string_typedo_get_unit
(duration_style style,rt_ratio rt, intmax_t v) const = 0; virtual booldo_is_named_unit
(rt_ratio rt) const =0; };
duration_units
facet gives useful
information about the duration units, as the number of plural forms,
the plural form associated to a duration, the text associated to a plural
form and a duration's period,
explicit duration_units(size_t refs = 0);
Construct a duration_units
facet.
Parameters:
Effects: Construct a duration_units
facet. If the
refs
argument is 0
then destruction of the object is delegated
to the locale, or locales, containing it. This allows the user to ignore
lifetime management issues. On the other had, if refs
is 1
then the object must
be explicitly deleted; the locale will not do so. In this case, the
object can be maintained across the lifetime of multiple locales.
virtual const string_type* get_n_d_valid_units_start() const =0;
Returns: pointer to the start of valid [N/D] units.
virtual const string_type* get_n_d_valid_units_end() const=0;
Returns: pointer to the end of valid [N/D] units.
virtual const string_type* get_valid_units_start() const=0;
Returns: pointer to the start of valid units, symbol or prefix with its different plural forms.
virtual const string_type* get_valid_units_end() const=0;
Returns: pointer to the end of valid units.
virtual bool match_n_d_valid_unit(const string_type* k) const = 0;
Parameters:
Returns: true
if k
matches a valid
unit.
virtual bool match_valid_unit(const string_type* k, rt_ratio& rt) const = 0;
Parameters:
Effects: rt
is set to the valid Period when the k
matches a valid unit. Returns: true
if k
matches a valid unit.
virtual string_type get_pattern() const=0;
Returns: the pattern to be used by default.
template <typename Rep, typename Period> string_type get_unit(duration_style style, duration<Rep, Period> const& d) const;
Returns: get_unit(style, d.count(), rt_ratio(Period()))
, the unit associated to this duration.
template <typename Rep, typename Period> string_type get_n_d_unit(duration_style style, duration<Rep, Period> const& d) const;
Returns: get_n_d_unit(style, d.count(), rt_ratio(Period())), i.e. the [N/D] suffix unit associated to this duration.
template <typename Period> bool is_named_unit() const;
Returns: do_is_named_unit(rt_ratio(Period()))
, true if the unit associated to
the given Period is named, false otherwise.
virtual string_type do_get_n_d_unit(duration_style style, rt_ratio rt, intmax_t v) const = 0;
Returns: the [N/D] suffix unit associated to this duration.
virtual string_type do_get_unit(duration_style style,rt_ratio rt, intmax_t v) const = 0;
Returns: the unit associated to this duration.
virtual bool do_is_named_unit(rt_ratio rt) const =0;
Returns: true if the unit associated to the given Period is named, false otherwise.
template <typename CharT = char> class duration_units_default: public duration_units<CharT> { protected: static const std::size_t pfs_ = 2; // The default English facet has two plural forms. public: typedef CharT char_type; typedef std::basic_string<CharT> string_type; explicit duration_units_default(size_t refs = 0); ~duration_units_default(); bool match_n_d_valid_unit(const string_type* k) const; bool match_valid_unit(const string_type* k, rt_ratio& rt) const; const string_type* get_n_d_valid_units_start()const; const string_type* get_n_d_valid_units_end()const; string_type* get_valid_units_start() const; string_type* get_valid_units_end() const; string_type get_pattern() const; protected: bool do_is_named_unit(rt_ratio rt) const; string_type do_get_n_d_unit(duration_style style, rt_ratio, intmax_t v) const; string_type do_get_unit(duration_style style, rt_ratio rt, intmax_t v) const; virtual std::size_t do_get_plural_forms() const; virtual std::size_t do_get_plural_form(int_least64_t value) const; virtual string_type do_get_unit(duration_style style, ratio<1> u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, ratio<60> u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, ratio<3600> u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, atto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, femto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, pico u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, nano u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, micro u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, milli u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, centi u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, deci u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, deca u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, hecto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, kilo u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, mega u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, giga u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, tera u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, peta u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, exa u, std::size_t pf) const; virtual string_type do_get_ratio_prefix(duration_style style, atto u) const; virtual string_type do_get_ratio_prefix(duration_style style, femto u) const; virtual string_type do_get_ratio_prefix(duration_style style, pico u) const; virtual string_type do_get_ratio_prefix(duration_style style, nano u) const; virtual string_type do_get_ratio_prefix(duration_style style, micro u) const; virtual string_type do_get_ratio_prefix(duration_style style, milli u) const; virtual string_type do_get_ratio_prefix(duration_style style, centi u) const; virtual string_type do_get_ratio_prefix(duration_style style, deci u) const; virtual string_type do_get_ratio_prefix(duration_style style, deca u) const; virtual string_type do_get_ratio_prefix(duration_style style, hecto u) const; virtual string_type do_get_ratio_prefix(duration_style style, kilo u) const; virtual string_type do_get_ratio_prefix(duration_style style, mega u) const; virtual string_type do_get_ratio_prefix(duration_style style, giga u) const; virtual string_type do_get_ratio_prefix(duration_style style, tera u) const; virtual string_type do_get_ratio_prefix(duration_style style, peta u) const; virtual string_type do_get_ratio_prefix(duration_style style, exa u) const; };
This class is used to define the strings for the default English. This facet names the units associated to the following periods:
atto
,
femto
,
pico
,
nano
,
micro
,
milli
,
centi
,
deci
,
deca
,
hecto
,
kilo
,
mega
,
giga
,
tera
,
peta
,
exa
,
explicit duration_units_default(size_t refs = 0);
Construct a duration_units_default facet.
Parameters:
Effects: Construct a duration_units_default
facet. If the refs
argument is 0
then destruction
of the object is delegated to the locale, or locales, containing it.
This allows the user to ignore lifetime management issues. On the other
had, if refs
is 1
then the object must be explicitly
deleted; the locale will not do so. In this case, the object can be
maintained across the lifetime of multiple locales.
virtual ~duration_units_default();
Effects: Destroys the facet.
virtual const string_type* get_n_d_valid_units_start() const;
Returns: pointer to the start of valid [N/D] units.
virtual const string_type* get_n_d_valid_units_end() const;
Returns: pointer to the end of valid [N/D] units.
virtual const string_type* get_valid_units_start() const;
Returns: pointer to the start of valid units, symbol or prefix with its different plural forms.
virtual const string_type* get_valid_units_end() const;
Returns: pointer to the end of valid units.
virtual bool match_n_d_valid_unit(const string_type* k) const;
Parameters:
Returns: true
if k
matches a valid
unit.
virtual bool match_valid_unit(const string_type* k, rt_ratio& rt) const;
Parameters:
Effects: rt
is set to the valid Period when the k
matches a valid unit. Returns: true
if k
matches a valid unit.
virtual string_type get_pattern() const;
Returns: the pattern to be used by default.
virtual string_type do_get_n_d_unit(duration_style style, rt_ratio rt, intmax_t v) const;
Returns: the [N/D] suffix unit associated to this duration.
virtual string_type do_get_unit(duration_style style,rt_ratio rt, intmax_t v) const;
Returns: the unit associated to this duration.
virtual bool do_is_named_unit(rt_ratio rt) const;
Returns: true if the unit associated to the given Period is named, false otherwise.
virtual std::size_t do_get_plural_forms() const;
Returns: the number of associated plural forms this facet manages.
virtual std::size_t do_get_plural_form(int_least64_t value) const;
Gets the associated plural form.
Parameters:
value: the duration representation
Returns: the plural form associated
to the value
parameter.
In English there are 2 plural forms
virtual string_type do_get_unit(duration_style style, ratio<1> u, std::size_t pf) const;
Parameters:
Returns: if style is symbol returns "s", otherwise if pf is 0 return "second", if pf is 1 "seconds"
virtual string_type do_get_unit(duration_style style, ratio<60> u, std::size_t pf) const;
Parameters:
Returns: if style is symbol returns "min", otherwise if pf is 0 return "minute", if pf is 1 "minutes"
virtual string_type do_get_unit(duration_style style, ratio<3600> u, std::size_t pf) const;
Parameters:
Returns: if style is symbol returns "h", otherwise if pf is 0 return "hour", if pf is 1 "hours"
virtual string_type do_get_unit(duration_style style, atto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, femto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, pico u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, nano u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, micro u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, milli u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, centi u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, deci u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, deca u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, hecto u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, kilo u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, mega u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, giga u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, tera u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, peta u, std::size_t pf) const; virtual string_type do_get_unit(duration_style style, exa u, std::size_t pf) const;
Parameters:
Returns: the concatenation of the
prefix associated to period u
+ the one associated to seconds.
virtual string_type do_get_ratio_prefix(duration_style style, atto u) const; virtual string_type do_get_ratio_prefix(duration_style style, femto u) const; virtual string_type do_get_ratio_prefix(duration_style style, pico u) const; virtual string_type do_get_ratio_prefix(duration_style style, nano u) const; virtual string_type do_get_ratio_prefix(duration_style style, micro u) const; virtual string_type do_get_ratio_prefix(duration_style style, milli u) const; virtual string_type do_get_ratio_prefix(duration_style style, centi u) const; virtual string_type do_get_ratio_prefix(duration_style style, deci u) const; virtual string_type do_get_ratio_prefix(duration_style style, deca u) const; virtual string_type do_get_ratio_prefix(duration_style style, hecto u) const; virtual string_type do_get_ratio_prefix(duration_style style, kilo u) const; virtual string_type do_get_ratio_prefix(duration_style style, mega u) const; virtual string_type do_get_ratio_prefix(duration_style style, giga u) const; virtual string_type do_get_ratio_prefix(duration_style style, tera u) const; virtual string_type do_get_ratio_prefix(duration_style style, peta u) const; virtual string_type do_get_ratio_prefix(duration_style style, exa u) const;
Parameters:
Returns: depending on the value of
style
return the ratio_string
symbol or prefix.
namespace boost { namespace chrono { // manipulators std::ios_base&symbol_format
(ios_base& ios); std::ios_base&name_format
(ios_base& ios); classduration_fmt
; template<class CharT, class Traits> std::basic_ostream<CharT, Traits>&operator <<
(std::basic_ostream<CharT, Traits>& os, duration_fmt d); template<class CharT, class Traits> std::basic_istream<CharT, Traits>&operator >>
(std::basic_istream<CharT, Traits>& is, duration_fmt d); // duration I/O template <class CharT, class Traits, class Rep, class Period> std::basic_ostream<CharT, Traits>&operator <<
(std::basic_ostream<CharT, Traits>& os, constduration
<Rep, Period>& d); template <class CharT, class Traits, class Rep, class Period> std::basic_istream<CharT, Traits>&operator >>
(std::basic_istream<CharT, Traits>& is,duration
<Rep, Period>& d) } }
There is a parameterized manipulator that takes the duration_style as
parameter. The symbol or name format can be easily chosen by streaming
a symbol_format
or name_format
manipulators respectively.
class duration_fmt { public: explicitduration_fmt
(duration_style
style) noexcept; #ifndef BOOST_NO_CXX11_EXPLICIT_CONVERSION_OPERATORS explicitoperator duration_style
() const noexcept; #endifduration_style
get_duration_style
() const noexcept; }; template<class CharT, class Traits> std::basic_ostream<CharT, Traits>&operator <<
(std::basic_ostream<CharT, Traits>& os, duration_fmt d); template<class CharT, class Traits> std::basic_istream<CharT, Traits>&operator >>
(std::basic_istream<CharT, Traits>& is, duration_fmt d);
explicit duration_fmt(duration_style f) noexcept;
Effects: Constructs a duration_fmt
by storing
f
.
Post Conditions: static_cast<duration_style>(*this) == f
.
explicit operator duration_style() const noexcept; duration_style get_duration_style() const noexcept;
Returns:: The stored duration_fmt
f
.
template<class CharT, class Traits> basic_ostream<CharT, Traits>& operator<<(basic_ostream<CharT, Traits>& s, duration_fmt d);
Effects::
.
set_duration_style
(s, static_cast<duration_style
>(d))))
Returns:: s
.
template<class CharT, class Traits> basic_istream<CharT, Traits>& operator>>(basic_istream<CharT, Traits>& s, duration_fmt d);
Effects::
.
set_duration_style
(s, static_cast<duration_style
>(d))))
Returns:: s
.
std::ios_base& symbol_format
(ios_base& ios);
Effects::
.
set_duration_style
(s, duration_style
::symbol)
Returns: ios
std::ios_base& name_format
(ios_base& ios);
Effects::
.
set_duration_style
(s, duration_style
::prefix)
Returns: ios
Any duration
can be streamed out
to a basic_ostream
.
The run-time value of the duration
is formatted according
to the rules and current format settings for duration
::rep
and the duration_units
facet.
template <class CharT, class Traits, class Rep, class Period> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const duration<Rep, Period>& d);
Effects: Behaves as a formatted output
function. After constructing a sentry object, if the sentry converts
to true, calls to facet.
where put
(os,os,os.fill(),d)facet
is the
facet associated to duration_put
<CharT>os
or a new created instance of the default
facet.
duration_put
<CharT>
Returns: os
.
template <class CharT, class Traits, class Rep, class Period> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, duration<Rep, Period>& d)
Effects: Behaves as a formatted input
function. After constructing a sentry
object, if the sentry
converts to true
, calls
to facet.
where get
(is,std::istreambuf_iterator<CharT,
Traits>(),
is,
err,
d)facet
is the
facet associated to duration_get
<CharT>is
or a new created instance of the default
facet.
duration_get
<CharT>
If any step fails, calls os.setstate(std::ios_base::failbit
| std::ios_base::badbit)
.
Returns: is
namespace boost { namespace chrono { template <class CharT, class InputIterator = std::istreambuf_iterator<CharT> > class time_point_get; } }
template <class CharT, class InputIterator = std::istreambuf_iterator<CharT> > class time_point_get: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef InputIterator iter_type; // Type of iterator used to scan the character buffer. explicit __time_point_get_c(size_t refs = 0); template <class Clock, class Duration> iter_type __time_point_get_get(iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err, time_point<Clock, Duration> &tp, const char_type *pattern, const char_type *pat_end) const; template <class Clock, class Duration> iter_type __time_point_get_get2(iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err, time_point<Clock, Duration> &tp) const; template <typename Rep, typename Period> iter_type __time_point_get_get_duration(iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err, duration<Rep, Period>& d) const; template <class Clock> iter_type __time_point_get_get_epoch(iter_type i, iter_type e, std::ios_base& is, std::ios_base::iostate& err) const; static std::locale::id id; // Unique identifier for this type of facet. __time_point_get_d(); };
time_point_get
is used
to parse a character sequence, extracting the duration and the epoch
into a class time_point
.
The pattern can contain the format specifiers %d
and %e
in any order.
User confirmation is required for reliable parsing of user-entered durations, but machine-generated formats can be parsed reliably. This allows parsers to be aggressive about interpreting user variations on standard formats.
If the end iterator is reached during parsing the member function sets
std::ios_base::eofbit
in err
.
explicit time_point_get(size_t refs);
Constructs a __time_point_get facet.
Parameters:
Effects: Constructs a duration_put
facet. If the
refs
argument is 0
then destruction of the object is delegated
to the locale, or locales, containing it. This allows the user to ignore
lifetime management issues. On the other had, if refs
is 1
then the object must
be explicitly deleted; locale
will not do so. In this case, the object can be maintained across the
lifetime of multiple locales.
template <class Clock, class Duration> iter_type get(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, time_point<Clock, Duration> &tp, const char_type *pattern, const char_type *pat_end) const;
Parameters:
ios_base
ios_base::iostate
time_point
Requires: [pattern,pat_end)
must be a valid range.
Effects:: The function starts by evaluating
err =
std::ios_base::goodbit
. It then enters a loop, reading
zero or more characters from s
at each iteration. Unless otherwise specified below, the loop terminates
when the first of the following conditions holds:
pattern
== pat_end
evaluates to true
.
err == std::ios_base::goodbit
evaluates to false
.
s == end
evaluates to true
,
in which case the function evaluates err
= std::ios_base::eofbit
| std::ios_base::failbit
.
'%'
,
followed by a conversion specifier character, the functions get_duration
or get_epoch
are called depending
on whether the format is 'd'
or 'e'
. If the number
of elements in the range [pattern,pat_end)
is not sufficient to unambiguously determine whether the conversion
specification is complete and valid, the function evaluates err |=
std::ios_base::failbit
. Otherwise, the function
evaluates s =
do_get(s,
end,
ios,
err,
d)
.
If err ==
std::ios_base::goodbit
holds after the evaluation
of the expression, the function increments pattern to point just
past the end of the conversion specification and continues looping.
isspace(*pattern, ios.getloc())
evaluates to true
,
in which case the function first increments pattern
until pattern == pat_end
|| !isspace(*pattern,
ios.getloc())
evaluates to true
,
then advances s
until s ==
end ||
!isspace(*s, ios.getloc())
is true
,
and finally resumes looping.
s
matches the element pointed to by pattern in a case-insensitive
comparison, in which case the function evaluates ++pattern
,
++s
and continues looping. Otherwise, the function evaluates err =
std::ios_base::failbit
.
Returns: An iterator pointing just beyond the last character that can be determined to be part of a valid time_point.
template <class Clock, class Duration> iter_type get(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, time_point<Clock, Duration> &tp) const;
Parameters:
ios_base
ios_base::iostate
time_point
Effects: Stores the duration pattern
from the duration_unit
facet in let say str
.
Last as if
return get(s, end, ios, err, ios, d, str.data(), str.data() + str.size());
Returns: An iterator pointing just beyond the last character that can be determined to be part of a valid name.
template <typename Rep, typename Period> iter_type get_duration(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err, duration<Rep, Period>& d) const;
Effects: As if
return facet.get(s, end, ios, err, d);
where facet
is either
the duration_get
facet
associated to the ios
or an instance of the default duration_get
facet.
Returns: An iterator pointing just beyond the last character that can be determined to be part of a valid duration.
template <class Clock> iter_type get_epoch(iter_type s, iter_type end, std::ios_base& ios, std::ios_base::iostate& err) const;
Effects: Let facet
be the time_point_units
facet associated
to ios
or a new instance
of the default __time_point_units_default facet. Let epoch
be the epoch string associated
to the Clock
using
this facet. Scans s
to match epoch
or
end
is reached.
If not match before the end
is reached std::ios_base::failbit
is set in err
.
If end
is reached
std::ios_base::failbit
is set in err
.
Returns: An iterator pointing just beyond the last character that can be determined to be part of a epoch.
namespace boost { namespace chrono { template <class CharT, class OutputIterator = std::ostreambuf_iterator<CharT> > class time_point_put; } }
The __time_point_put facet provides facilities for formatted output of
time_point
values. The member
function of __time_point_put take a time_point
and format it into
character string representation.
tparam ChatT a character type tparam OutputIterator a model of OutputIterator
template <class CharT, class OutputIterator = std::ostreambuf_iterator<CharT> > class time_point_put: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef std::basic_string<CharT> string_type; // Type of character string passed to member functions. typedef OutputIterator iter_type; // Type of iterator used to write in the character buffer. explicit time_point_put(size_t refs = 0); ~time_point_put(); template <class Clock, class Duration> iter_type put(iter_type i, std::ios_base& ios, char_type fill, time_point<Clock, Duration> const& tp, const CharT* pattern, const CharT* pat_end) const; template <class Clock, class Duration> iter_type put(iter_type i, std::ios_base& ios, char_type fill, time_point<Clock, Duration> const& tp) const; template <typename Rep, typename Period> iter_type put_duration(iter_type i, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const; template <typename Clock> iter_type put_epoch(iter_type i, std::ios_base& os) const; static std::locale::id id; // Unique identifier for this type of facet. };
explicit time_point_put(size_t refs = 0);
Construct a time_point_put facet.
Effects: Construct a time_point_put
facet. If the refs
argument is 0
then destruction
of the object is delegated to the locale, or locales, containing it.
This allows the user to ignore lifetime management issues. On the other
had, if refs
is 1
then the object must be explicitly
deleted; the locale will not do so. In this case, the object can be
maintained across the lifetime of multiple locales.
Parameters:
template <class Clock, class Duration> iter_type put(iter_type i, std::ios_base& ios, char_type fill, time_point<Clock, Duration> const& tp, const CharT* pattern, const CharT* pat_end) const;
Parameters:
time_point
Effects: Steps through the sequence
from pattern
to pat_end
, identifying characters that
are part of a pattern sequence. Each character that is not part of
a pattern sequence is written to s
immediately, and each pattern sequence, as it is identified, results
in a call to __put_duration or __put_epoch; thus, pattern elements
and other characters are interleaved in the output in the order in
which they appear in the pattern. Pattern sequences are identified
by converting each character c
to a char
value as if
by ct.narrow(c,0)
, where
ct
is a reference to
ctype<charT>
obtained from ios.getloc()
.
The first character of each sequence is equal to '%'
,
followed by a pattern specifier character spec, which can be 'd'
for the duration value or 'e'
for the epoch. For each valid pattern
sequence identified, calls put_duration(s, ios, fill, tp.time_since_epoch())
or put_epoch(s, ios)
.
Returns: An iterator pointing immediately after the last character produced.
template <class Clock, class Duration> iter_type put(iter_type i, std::ios_base& ios, char_type fill, time_point<Clock, Duration> const& tp) const;
Parameters:
time_point
Effects: Stores the time_point pattern
from the __time_point_unit facet in let say str
.
Last as if
return put(s, ios, fill, tp, str.data(), str.data() + str.size());
Returns: An iterator pointing immediately after the last character produced.
template <typename Rep, typename Period> iter_type put_duration(iter_type i, std::ios_base& ios, char_type fill, duration<Rep, Period> const& d) const;
Parameters:
duration
Effects: As if facet.put(s, ios, fill, d)
where facet is the
facet associated to the duration_put
<CharT>ios
or a new instance of
.
duration_put
<CharT>
Returns: An iterator pointing immediately after the last character produced.
template <typename Clock> iter_type put_epoch(iter_type i, std::ios_base& os) const;
Parameters:
Effects: As if
string_type str = facet.template get_epoch<Clock>(); s=std::copy(str.begin(), str.end(), s);
where facet is the
facet associated to the time_point_units
<CharT>ios
or a new instance of __time_point_units_default<CharT>
.
Returns: s, iterator pointing immediately after the last character produced.
namespace boost { namespace chrono { template <typename CharT, typename Clock, typename TPUFacet> std::basic_string<CharT> get_epoch_custom(Clock, TPUFacet& f); template <typename CharT=char> class time_point_units; template <typename CharT=char> class time_point_units_default, } }
template <typename CharT, typename Clock, typename TPUFacet> std::basic_string<CharT> get_epoch_custom(Clock, TPUFacet& f);
Customization point to the epoch associated to the clock Clock
The default calls f.do_get_epoch(Clock())
.
The user can overload this function.
Returns: Forwards the call to the facet as if
return f.do_get_epoch(Clock());
time_point_units
facet gives
useful information about the time_point pattern, the text associated
to a time_point's epoch,
template <typename CharT=char> class time_point_units: public std::locale::facet { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef std::basic_string<char_type> string_type; // Type of character string used by member functions. static std::locale::id id; // Unique identifier for this type of facet. explicit time_point_units(size_t refs = 0); virtual string_type get_pattern() const =0; template <typename Clock> string_type get_epoch() const; protected: virtual ~time_point_units(); virtual string_type do_get_epoch(system_clock) const=0; virtual string_type do_get_epoch(steady_clock) const=0; #if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) virtual string_type do_get_epoch(process_real_cpu_clock) const=0; virtual string_type do_get_epoch(process_user_cpu_clock) const=0; virtual string_type do_get_epoch(process_system_cpu_clock) const=0; virtual string_type do_get_epoch(process_cpu_clock) const=0; #endif #if defined(BOOST_CHRONO_HAS_THREAD_CLOCK) virtual string_type do_get_epoch(thread_clock) const=0; #endif };
explicit time_point_units(size_t refs = 0);
Construct a time_point_units
facet.
Parameters:
Effects: Construct a time_point_units
facet. If
the refs
argument is
0
then destruction of the
object is delegated to the locale, or locales, containing it. This
allows the user to ignore lifetime management issues. On the other
had, if refsv is
1` then the object must be explicitly deleted; the locale will
not do so. In this case, the object can be maintained across the lifetime
of multiple locales.
virtual string_type get_pattern() const =0;
Returns: the pattern to be used by default.
template <typename Clock> string_type get_epoch() const;
Returns: the epoch associated to the
clock Clock
as if
return get_epoch_custom<CharT>(Clock(), *this);
virtual string_type do_get_epoch(system_clock) const=0;
Parameters:
system_clock
.
Returns: The epoch string associated
to the system_clock
.
virtual string_type do_get_epoch(steady_clock) const=0;
Parameters:
steady_clock
.
Returns: The epoch string associated
to the steady_clock
.
#if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) virtual string_type do_get_epoch(process_real_cpu_clock) const=0; #endif
Parameters:
process_real_cpu_clock
.
Returns: The epoch string associated
to the process_real_cpu_clock
.
#if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) virtual string_type do_get_epoch(process_user_cpu_clock) const=0; #endif
Parameters:
process_real_cpu_clock
.
Returns: The epoch string associated to the process_user_cpu_clock.
#if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) virtual string_type do_get_epoch(process_system_cpu_clock) const=0; #endif
Parameters:
process_system_cpu_clock
.
Returns: The epoch string associated to the process_user_cpu_clock.
#if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) virtual string_type do_get_epoch(process_cpu_clock) const=0; #endif
Parameters:
process_cpu_clock
.
Returns: The epoch string associated to the process_cpu_clock.
#if defined(BOOST_CHRONO_HAS_THREAD_CLOCK) virtual string_type do_get_epoch(thread_clock) const=0; #endif
Parameters:
thread_clock
.
Returns: The epoch string associated
to the thread_clock
.
// This class is used to define the strings for the default English template <typename CharT=char> class time_point_units_default: public time_point_units<CharT> { public: typedef CharT char_type; // Type of character the facet is instantiated on. typedef std::basic_string<char_type> string_type; // Type of character string used by member functions. explicit time_point_units_default(size_t refs = 0); ~time_point_units_default(); /** * __returns the default pattern "%d%e". */ string_type get_pattern() const; protected: /** * [param c a dummy instance of __system_clock. * __returns The epoch string returned by `clock_string<system_clock,CharT>::since()`. */ string_type do_get_epoch(system_clock ) const; /** * [param c a dummy instance of __steady_clock. * __returns The epoch string returned by `clock_string<steady_clock,CharT>::since()`. */ string_type do_get_epoch(steady_clock ) const; #if defined(BOOST_CHRONO_HAS_PROCESS_CLOCKS) /** * [param c a dummy instance of __process_real_cpu_clock. * __returns The epoch string returned by `clock_string<process_real_cpu_clock,CharT>::since()`. */ string_type do_get_epoch(process_real_cpu_clock ) const; /** * [param c a dummy instance of __process_user_cpu_clock. * __returns The epoch string returned by `clock_string<process_user_cpu_clock,CharT>::since()`. */ string_type do_get_epoch(process_user_cpu_clock ) const; /** * [param c a dummy instance of __process_system_cpu_clock. * __returns The epoch string returned by `clock_string<process_system_cpu_clock,CharT>::since()`. */ string_type do_get_epoch(process_system_cpu_clock ) const; /** * [param c a dummy instance of __process_cpu_clock. * __returns The epoch string returned by `clock_string<process_cpu_clock,CharT>::since()`. */ string_type do_get_epoch(process_cpu_clock ) const; #endif #if defined(BOOST_CHRONO_HAS_THREAD_CLOCK) /** * [param c a dummy instance of __thread_clock. * __returns The epoch string returned by `clock_string<thread_clock,CharT>::since()`. */ string_type do_get_epoch(thread_clock ) const; #endif };
namespace boost { namespace chrono { // manipulators unspecifiedtime_fmt
(timezone tz); template<class CharT> unspecifiedtime_fmt
(timezone tz, basic_string<CharT> f); template<class CharT> unspecifiedtime_fmt
(timezone tz, const CharT* f); // i/o state savers template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtimezone_io_saver
{ typedef std::basic_ios<CharT, Traits> state_type; typedef timezone aspect_type; explicittimezone_io_saver
(state_type &s);timezone_io_saver
(state_type &s, aspect_type new_value);~timezone_io_saver
(); void timezone_io_saver__restore(); }; template<typename CharT = char, typename Traits = std::char_traits<CharT> > structtime_fmt_io_saver
{ typedef std::basic_ios<CharT, Traits> state_type; explicit time_fmt_io_saver(state_type &s); time_fmt_io_saver(state_type &s, basic_string<CharT> const& new_value); ~ time_fmt_io_saver(); void restore(); }; // system_clock I/O template <class CharT, class Traits, classDuration
> basic_ostream<CharT, Traits>& operator<<(basic_ostream<CharT, Traits>& os, const time_point<system_clock,Duration
>& tp); template <class CharT, class Traits, classDuration
> basic_istream<CharT, Traits>& operator>>(basic_istream<CharT, Traits>& is, time_point<system_clock,Duration
>& tp); // Other Clocks I/O template <class CharT, class Traits, classClock
, classDuration
> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const time_point<Clock
,Duration
>& tp); template <class CharT, class Traits, classClock
, classDuration
> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, time_point<Clock
,Duration
>& tp); } }
time_fmt(timezone
)
unspecified time_fmt(timezone
tz);
Returns:: An unspecified object that
when streamed to a basic_ostream<CharT, Traits>
or basic_istream<CharT, Traits>
s
will have the effects of:
set_timezone
(s, tz);
time_fmt(timezone
,
string)
template<class CharT> unspecified time_fmt(timezone tz, basic_string<CharT> f); template<class CharT> unspecified time_fmt(timezone tz, const CharT* f);
Returns:: An unspecified object that
when streamed to a basic_ostream<CharT, Traits>
or basic_istream<CharT, Traits>
s
will have the effects of:
set_timezone
(s, tz);set_time_fmt
<CharT>(s, f);
template <class CharT, class Traits, classDuration
> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const time_point<system_clock,Duration
>& tp);
Effects: Behaves as a formatted
output function. After constructing a sentry
object, if the sentry
converts to true
, sets
a local variable tz
of type timezone
to get_timezone(os)
.
Additionally the format string obtained with
is recorded as a pair of get_time_fmt
()const
CharT*
.
If the stream has no time_punct facet, then this pair of const CharT*
that represent an empty range.
Next tp
is converted
to a time_t
, and
this time_t
is converted
to a tm
. The conversion
to tm
use gmtime
(when available) if the
timezone is utc
, else it use localtime
(if available).
Using the std::time_put
facet stored in os
, this inserter writes characters
to the stream using the tm
and the formatting string stored in the time_punct
facet, unless that facet was missing, or unless it provided an empty
string.
If the formatting string is empty, then output as follows:
First output tm
using
"%F %H:%M:"
Next output a double
representing the number of seconds stored in the tm
plus the fractional seconds represented in tp
.
The format shall be ios::fixed
and the precision shall be sufficient to represent system_clock::duration
exactly (e.g. if system_clock::period
is micro, the precision
should be sufficient to output six digits following the decimal point).
If the number of seconds is less than 10
,
the output shall be prefixed by '0'
.
Finally if tz
is
local
, output the tm
using the pattern " %z".
Else append the sequence " +0000" to the stream.
If any step fails, calls os.setstate(ios_base::failbit
| ios_base::badbit)
.
Returns: os
template <class CharT, class Traits, classDuration
> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, time_point<system_clock,Duration
>& tp);
Effects: Behaves as a formatted
input function. After constructing a sentry object, if the sentry
converts to true, obtains a std::time_get
facet from is
, and
obtains a formatting string in the same manner as described for insertion
operator. Extract a tm
using the supplied formatting string, or if empty, defaulted as described
for the insertion operator. Note that extraction does not use the
timezone
data stored in
the is
for the defaulted
string as the timezone
information is
stored in the stream.
Any time_point<system_clock,
inserted, and then extracted should result in an equal Duration
>time_point<system_clock,
,
excepting any precision that did not get inserted.
Duration
>
Example:
void test(std::chrono::system_clock::time_point tp) { std::stringstream s; s << tp; boost::chrono::system_clock::time_point tp2; s >> tp2; assert(tp == tp2); }
Returns: is
template <class CharT, class Traits, classClock
, classDuration
> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, const time_point<Clock
,Duration
>& tp);
Effects: Behaves as a formatted
output function. After constructing a sentry
object, if the sentry
converts to true
, calls
to facet.put(os,os,os.fill(),tp)
where facet
is the
time_point_put<CharT>
facet associated to os
or a new created instance of the default time_point_put<CharT>
facet.
Returns: os
.
Example:
22644271279698 nanoseconds since boot
template <class CharT, class Traits, classClock
, classDuration
> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, time_point<Clock
,Duration
>& tp);
Extracts tp
from
the stream is
.
Effects: Behaves as a formatted
input function. After constructing a sentry
object, if the sentry
converts to true
, calls
to facet.get(is,std::istreambuf_iterator<CharT,
Traits>(),
is,
err,
tp)
where facet
is the
time_point_get<CharT>
facet associated to is
or a new created instance of the default time_point_get<CharT>
facet.
If any step fails, calls os.setstate(std::ios_base::failbit
| std::ios_base::badbit)
.
Returns: is
.
namespace boost { namespace chrono { template <class To, class Rep, class Period> To floor(const duration<Rep, Period>& d); } }
This function round down the given parameter.
namespace boost { namespace chrono { template <class To, class Rep, class Period> To round(const duration<Rep, Period>& d); } }
This function round to nearest, to even on tie the given parameter.
namespace boost { namespace chrono { template <class To, class Rep, class Period> To ceil(const duration<Rep, Period>& d); } }
This function round up the given parameter.
BOOST_CHRONO_HAS_PROCESS_CLOCKS
process_real_cpu_clock
process_user_cpu_clock
process_system_cpu_clock
process_cpu_clock
process_times
process_times
Input/Outputduration_values
Specialization for process_times<>
clock_string<process_real_cpu_clock>
Specializationclock_string<process_user_cpu_clock>
Specializationclock_string<process_system_cpu_clock>
Specializationclock_string<process_cpu_clock>
Specializationnumeric_limits
Specialization for process_times<>
Knowing how long a program takes to execute is useful in both test and production environments. It is also helpful if such timing information is broken down into real (wall clock) time, CPU time spent by the user, and CPU time spent by the operating system servicing user requests.
Process clocks don't include the time spent by the child process.
#define BOOST_CHRONO_HAS_PROCESS_CLOCKS namespace boost { namespace chrono { class process_real_cpu_clock; class process_user_cpu_clock; class process_system_cpu_clock; class process_cpu_clock; template <typename Rep> struct process_times; template <class CharT, class Traits, class Rep> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, process_times<Rep> const& rhs); template <class CharT, class Traits, class Rep> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, process_times<Rep> const& rhs); template <class Rep> struct duration_values<process_times<Rep> >; template <class CharT> struct clock_string<process_real_cpu_clock, CharT>; struct clock_string<process_user_cpu_clock, CharT>; struct clock_string<process_system_cpu_clock, CharT>; struct clock_string<process_cpu_clock, CharT>; } } namespace std { template <class Rep> class numeric_limits<boost::chrono::process_times<Rep> >; }
This macro is defined if the platform supports process clocks.
process_real_cpu_clock
satisfy
the Clock
requirements.
process_real_cpu_clock
class
provides access to the real process wall-clock steady clock, i.e. the
real CPU-time clock of the calling process. The process relative current
time can be obtained by calling process_real_cpu_clock::now()
.
class process_real_cpu_clock { public: typedefnanoseconds
duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<process_real_cpu_clock> time_point; static constexpr bool is_steady = true; static time_point now( ) noexcept; static time_point now( system::error_code & ec ); };
process_user_cpu_clock
satisfy
the Clock
requirements.
process_user_cpu_clock
class
provides access to the user CPU-time steady clock of the calling process.
The process relative user current time can be obtained by calling process_user_cpu_clock::now()
.
class process_user_cpu_clock { public: typedefnanoseconds
duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<process_user_cpu_clock> time_point; static constexpr bool is_steady = true; static time_point now( ) noexcept; static time_point now( system::error_code & ec ); };
process_system_cpu_clock
satisfy
the Clock
requirements.
process_system_cpu_clock
class
provides access to the system CPU-time steady clock of the calling process.
The process relative system current time can be obtained by calling
process_system_cpu_clock::now()
.
class process_system_cpu_clock { public: typedefnanoseconds
duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<process_system_cpu_clock> time_point; static constexpr bool is_steady = true; static time_point now( ) noexcept; static time_point now( system::error_code & ec ); };
process_cpu_clock
can
be considered as a tuple<process_real_cpu_clock, process_user_cpu_clock, process_system_cpu_clock>
.
process_cpu_clock
provides
a thin wrapper around the operating system's process time API. For POSIX-like
systems, that's the times() function, while for Windows, it's the GetProcessTimes()
function.
The process relative real, user and system current time can be obtained
at once by calling process_clocks::now()
.
class process_cpu_clock { public: typedef process_times<nanoseconds::rep> times ; typedefduration
<times, nano> duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<process_cpu_clock> time_point; static constexpr bool is_steady = true; static time_point now( ) noexcept; static time_point now( system::error_code & ec ); };
This class is the representation of the process_cpu_clock::duration
class. As such it needs to implements the arithmetic operators.
template <typename Rep> struct process_times : arithmetic<process_times<Rep>, multiplicative<process_times<Rep>, Rep, less_than_comparable<process_times<Rep> > > > { Rep real; // real (i.e wall clock) time Rep user; // user cpu time Rep system; // system cpu time times(); times( process_real_cpu_clock::rep r, process_user_cpu_clock::rep u, process_system_cpu_clock::rep s); template <typename Rep2> explicit process_times( Rep2 r); template <typename Rep2> explicit process_times( process_times<Rep2> const& rhs); operator rep() const; bool operator==(process_times const& rhs); template <typename Rep2> bool operator==(process_times<Rep2> const& rhs); times operator+=(process_times const& rhs); times operator-=(process_times const& rhs); times operator*=(process_times const& rhs); times operator/=(process_times const& rhs); bool operator<(process_times const & rhs) const; };
template <class CharT, class Traits, class Rep> std::basic_ostream<CharT, Traits>& operator<<(std::basic_ostream<CharT, Traits>& os, process_times<Rep> const& rhs);
Effects: Output each part separated by ';' and surrounded by '{', '}'.
Throws: None.
template <class CharT, class Traits, class Rep> std::basic_istream<CharT, Traits>& operator>>(std::basic_istream<CharT, Traits>& is, process_times<Rep> const& rhs);
Effects: overrides the value of rhs if the input stream has the format "{r;u;s}". Otherwise, set the input stream state as failbit | eofbit.
Throws: None.
template <class Rep>
struct duration_values
<process_times<Rep> >
{
static process_times<Rep> zero();
static process_times<Rep> max();
static process_times<Rep> min();
};
The times
specific functions
zero()
,
max()
and min()
uses the relative functions on the representation of each component.
template <class CharT> struct clock_string<process_real_cpu_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); };
clock_string<>::name()
returns "process_real_cpu_clock".
clock_string<>::since()
returns " since process start-up"
template <class CharT> struct clock_string<process_user_cpu_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); };
clock_string<>::name()
returns "process_user_cpu_clock".
clock_string<>::since()
returns " since process start-up"
template <class CharT> struct clock_string<process_system_cpu_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); };
clock_string<>::name()
returns "process_system_cpu_clock".
clock_string<>::since()
returns " since process start-up"
template <class CharT> struct clock_string<process_cpu_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); };
clock_string<>::name()
returns "process_cpu_clock".
clock_string<>::since()
returns " since process start-up"
namespace std { template <> class numeric_limits<boost::chrono::process_times<Rep>> { typedef boost::chrono::process_times<Rep> Res; public: static const bool is_specialized = true; static Res min(); static Res max(); static Res lowest(); static const int digits; static const int digits10; static const bool is_signed = false; static const bool is_integer = true; static const bool is_exact = true; static const int radix = 0; }; }
The process_times<Rep>
specialization functions min()
, max()
and lowest()
uses the relative functions on the
representation of each component.
Notes
min()
returns the tuple of mins.
max()
returns the tuple of maxs.
lowest()
returns the tuple of lowests.
digits
is the sum
of (binary) digits.
digits10
is the sum
of digits10s.
Knowing the time a thread takes to execute is useful in both test and production environments.
#define BOOST_CHRONO_HAS_THREAD_CLOCK #define BOOST_CHRONO_THREAD_CLOCK_IS_STEADY namespace boost { namespace chrono { class thread_clock; template <class CharT> struct clock_string<thread_clock, CharT>; } }
This macro is defined if the platform supports thread clocks.
This macro is defined if the platform has a thread clock. Its value is true if it is steady and false otherwise.
thread_clock
satisfy the Clock
requirements.
thread_clock
class provides
access to the real thread wall-clock, i.e. the real CPU-time clock of
the calling thread. The thread relative current time can be obtained
by calling thread_clock::now()
.
class thread_clock { public: typedefnanoseconds
duration; typedef duration::rep rep; typedef duration::period period; typedef chrono::time_point
<thread_clock> time_point; static constexpr bool is_steady = BOOST_CHRONO_THREAD_CLOCK_IS_STEADY; static time_point now( ) noexcept; static time_point now( system::error_code & ec ); };
#if defined(BOOST_CHRONO_HAS_THREAD_CLOCK) template <class CharT> struct clock_string<thread_clock, CharT> { static std::basic_string<CharT> name(); static std::basic_string<CharT> since(); }; #endif
clock_string<>::name()
returns "thread_clock".
clock_string<>::since()
returns " since thread start-up"