C++20 update to new answer for old question
3rd party libraries no longer required.
Assuming one wants to measure "physical seconds". I.e. if a daylight saving adjustment has been made since midnight, this computation takes that into account. This code is very similar to the code below, but shortened to just the version that throws an exception if there is no local midnight, or if there are two local midnights.
#include <chrono>
#include <iostream>
std::chrono::milliseconds
since_local_midnight(std::chrono::system_clock::time_point t = std::chrono::system_clock::now(),
std::chrono::time_zone const* zone = std::chrono::current_zone())
{
using namespace std::chrono;
zoned_time zt{zone, t};
zt = floor<days>(zt.get_local_time());
return floor<milliseconds>(t - zt.get_sys_time());
}
int
main()
{
std::cout << since_local_midnight() << '\n';
}
Demo.
Explanation:
- Combine the
time_zone
and the time_point
into a zoned_time
. A zoned_time
is nothing more than a pairing of these two pieces of information. It makes it convenient to retrieve either the local time, or the UTC (sys
) time.
- Retrieve the local time and floor that to days precision to get the local midnight. Assign this new local time back into the
zoned_time
. This assignment will throw an exception if there is not a single midnight on this date in this time zone.
- Retrieve the UTC equivalent of the local midnight and subtract that from the input
time_point
. Truncate the answer to milliseconds precision as requested in the OP.
See the more extended answer below for ways to deal with or work around the case where there are 0 or 2 local midnights.
New answer for old question.
Rationale for new answer: We have better tools now.
I'm assuming the desired result is "actual" milliseconds since the local midnight (getting the correct answer when there has been a UTC offset change since midnight).
A modern answer based on <chrono>
and using this free, open-source library is very easy. This library has been ported to VS-2013, VS-2015, clang/libc++, macOS, and linux/gcc.
In order to make the code testable, I'm going to enable an API to get the time since midnight (in milliseconds) from any std::chrono::system_clock::time_point
in any IANA time zone.
std::chrono::milliseconds
since_local_midnight(std::chrono::system_clock::time_point t,
const date::time_zone* zone);
And then to get the current time since midnight in the local time zone is easy to write on top of this testable primitive:
inline
std::chrono::milliseconds
since_local_midnight()
{
return since_local_midnight(std::chrono::system_clock::now(),
date::current_zone());
}
Writing the meat of the matter is relatively straight-forward:
std::chrono::milliseconds
since_local_midnight(std::chrono::system_clock::time_point t,
const date::time_zone* zone)
{
using namespace date;
using namespace std::chrono;
auto zt = make_zoned(zone, t);
zt = floor<days>(zt.get_local_time());
return floor<milliseconds>(t - zt.get_sys_time());
}
The first thing to do is create a zoned_time
which really does nothing at all but pair zone
and t
. This pairing is mainly just to make the syntax nicer. It actually doesn't do any computation.
The next step is to get the local time associated with t
. That is what zt.get_local_time()
does. This will have whatever precision t
has, unless t
is coarser than seconds, in which case the local time will have a precision of seconds.
The call to floor<days>
truncates the local time to a precision of days
. This effectively creates a local_time
equal to the local midnight. By assigning this local_time
back to zt
, we don't change the time zone of zt
at all, but we change the local_time
of zt
to midnight (and thus change its sys_time
as well).
We can get the corresponding sys_time
out of zt
with zt.get_sys_time()
. This is the UTC time which corresponds to the local midnight. It is then an easy process to subtract this from the input t
and truncate the results to the desired precision.
If the local midnight is non-existent, or ambiguous (there are two of them), this code will throw an exception derived from std::exception
with a very informative what()
.
The current time since the local midnight can be printed out with simply:
std::cout << since_local_midnight().count() << "ms\n";
To ensure that our function is working, it is worthwhile to output a few example dates. This is most easily done by specifying a time zone (I'll use "America/New_York"), and some local date/times where I know the right answer. To facilitate nice syntax in the test, another since_local_midnight
helps:
inline
std::chrono::milliseconds
since_local_midnight(const date::zoned_seconds& zt)
{
return since_local_midnight(zt.get_sys_time(), zt.get_time_zone());
}
This simply extracts the system_clock::time_point
and time zone from a zoned_time
(with seconds precision), and forwards it on to our implementation.
auto zt = make_zoned(locate_zone("America/New_York"), local_days{jan/15/2016} + 3h);
std::cout << zt << " is "
<< since_local_midnight(zt).count() << "ms after midnight\n";
This is 3am in the middle of the Winter which outputs:
2016-01-15 03:00:00 EST is 10800000ms after midnight
and is correct (10800000ms == 3h).
I can run the test again just by assigning a new local time to zt
. The following is 3am just after the "spring forward" daylight saving transition (2nd Sunday in March):
zt = local_days{sun[2]/mar/2016} + 3h;
std::cout << zt << " is "
<< since_local_midnight(zt).count() << "ms after midnight\n";
This outputs:
2016-03-13 03:00:00 EDT is 7200000ms after midnight
Because the local time from 2am to 3am was skipped, this correctly outputs 2 hours since midnight.
An example from the middle of Summer gets us back to 3 hours after midnight:
zt = local_days{jul/15/2016} + 3h;
std::cout << zt << " is "
<< since_local_midnight(zt).count() << "ms after midnight\n";
2016-07-15 03:00:00 EDT is 10800000ms after midnight
And finally an example just after the Fall transition from daylight saving back to standard gives us 4 hours:
zt = local_days{sun[1]/nov/2016} + 3h;
std::cout << zt << " is "
<< since_local_midnight(zt).count() << "ms after midnight\n";
2016-11-06 03:00:00 EST is 14400000ms after midnight
If you want, you can avoid an exception in the case that midnight is non-existent or ambiguous. You have to decide before hand in the ambiguous case: Do you want to measure from the first midnight or the second?
Here is how you would measure from the first:
std::chrono::milliseconds
since_local_midnight(std::chrono::system_clock::time_point t,
const date::time_zone* zone)
{
using namespace date;
using namespace std::chrono;
auto zt = make_zoned(zone, t);
zt = make_zoned(zt.get_time_zone(), floor<days>(zt.get_local_time()),
choose::earliest);
return floor<milliseconds>(t - zt.get_sys_time());
}
If you want to measure from the second midnight, use choose::latest
instead. If midnight is non-existent, you can use either choose
, and it will measure from the single UTC time point that borders the local time gap that midnight is in. This can all be very confusing, and that's why the default behavior is to just throw an exception with a very informative what()
:
zt = make_zoned(locate_zone("America/Asuncion"), local_days{sun[1]/oct/2016} + 3h);
std::cout << zt << " is "
<< since_local_midnight(zt).count() << "ms after midnight\n";
what():
2016-10-02 00:00:00.000000 is in a gap between
2016-10-02 00:00:00 PYT and
2016-10-02 01:00:00 PYST which are both equivalent to
2016-10-02 04:00:00 UTC
If you use the choose::earliest/latest
formula, instead of an exception with the above what()
, you get:
2016-10-02 03:00:00 PYST is 7200000ms after midnight
If you want to do something really tricky like use choose
for non-existent midnights, but throw an exception for ambiguous midnights, that too is possible:
auto zt = make_zoned(zone, t);
try
{
zt = floor<days>(zt.get_local_time());
}
catch (const date::nonexistent_local_time&)
{
zt = make_zoned(zt.get_time_zone(), floor<days>(zt.get_local_time()),
choose::latest);
}
return floor<milliseconds>(t - zt.get_sys_time());
Because hitting such a condition is truly rare (exceptional), the use of try/catch
is justified. However if you want to do it without throwing at all, there exists a low-level API within this library to achieve that.
Finally note that this long winded answer is really about 3 lines of code, and everything else is about testing, and taking care of rare exceptional cases.