I've taken it as a challenge to perform this computation using `chrono`

-Compatible Low-Level Date Algorithms, `<chrono>`

Utilities, and the C++11 `<chrono>`

facilities.

From `chrono`

-Compatible Low-Level Date Algorithms we need:

```
template <class Int>
constexpr
Int
days_from_civil(Int y, unsigned m, unsigned d) noexcept;
```

which converts a y/m/d triple into a number of days before/since 1970-01-01, and:

```
template <class Int>
constexpr
std::tuple<Int, unsigned, unsigned>
civil_from_days(Int z) noexcept;
```

which converts a number of days before/since 1970-01-01 to a y/m/d triple.

From `<chrono>`

Utilities we need:

```
template <class To, class Rep, class Period>
To
floor(const std::chrono::duration<Rep, Period>& d);
```

which is very similar to `std::chrono::duration_cast`

, except that it rounds towards negative infinity, instead of towards zero (makes a difference for rounding negative values).

First we need a datetime object to hold all of the info we want:

```
struct datetime
{
int year;
int month;
int day;
int hour;
int minute;
int second;
int nanoseconds;
};
```

And a printing facility is convenient for demonstration purposes (which should be customized to whatever format is desired):

```
std::ostream&
operator<<(std::ostream& os, const datetime& dt)
{
char fill = os.fill();
os.fill('0');
os << dt.year << '-';
os << std::setw(2) << dt.month << '-';
os << std::setw(2) << dt.day << " T ";
os << std::setw(2) << dt.hour << ':';
os << std::setw(2) << dt.minute << ':';
os << std::setw(2) << dt.second << '.';
os << std::setw(9) << dt.nanoseconds;
os.fill(fill);
return os;
}
```

I've chosen units of `nanoseconds`

as the precision of `datetime`

, which is slightly overkill. You can easily set this to whatever is desired.

Next it is convenient to declare two custom `std::chrono::duration`

's:

One to represent days (exactly 24 hours):

```
typedef std::chrono::duration
<
int,
std::ratio_multiply<std::ratio<24>, std::chrono::hours::period>
> days;
```

And one to represent the 100 nanosecond interval from the problem statement:

```
typedef std::chrono::duration
<
std::int64_t, std::ratio_multiply<std::ratio<100>, std::nano>
> wtick;
```

Now we have all the tools necessary to convert a `std::uint64_t`

to a `datetime`

, (the subject of this question):

```
datetime
datetime_from_wtick(wtick t)
{
// Get the number of days between 1601-01-01 and 1970-01-01
constexpr days epoch{days_from_civil(1601, 1, 1)};
// eppoch is a negative number of days, so add it to get time since 1970-01-01
wtick utc_time = t + epoch;
days d = floor<days>(utc_time); // Get #days before/since 1970-01-01
datetime r;
// Split #days into year/month/day
std::tie(r.year, r.month, r.day) = civil_from_days(d.count());
utc_time -= d; // Subtract off #days to leave hours:minutes:seconds.fractional
auto h = floor<std::chrono::hours>(utc_time); // Get hours
r.hour = h.count();
utc_time -= h; // Subtract off hours to leave minutes:seconds.fractional
auto m = floor<std::chrono::minutes>(utc_time); // Get minutes
r.minute = m.count();
utc_time -= m; // Subtract off minutes to leave seconds.fractional
auto s = floor<std::chrono::seconds>(utc_time); // Get seconds
r.second = s.count();
utc_time -= s; // Subtract off seconds to leave fractional seconds
std::chrono::nanoseconds ns = utc_time; // Get nanoseconds
r.nanoseconds = ns.count();
return r;
}
```

This solution works by simply shifting the epoch to 1970-01-01, then truncating off the number of days, then the number of hours, then the number of minutes, etc., until we get down to fractions of a second. The number of days is further split into a triple: y/m/d.

The only reason to shift the epoch is to take advantage of the fully-debugged, high-performance, and extremely-robust formulas in `chrono`

-Compatible Low-Level Date Algorithms.

This solution ignores the existence of leap seconds. My guess is that Windows FILETIME does too. However if it does not, you can take leap seconds into account by building a table that maps `datetime`

to #seconds to add. For example if the `datetime`

extends beyond the current leap seconds table, you add 25 seconds to get the "true" difference between now and 1601-01-01. My experience is that computers are using Unix Time, which just glosses over leap seconds.

Testing it all out with:

```
int
main()
{
std::cout << datetime_from_wtick(wtick(130330211760000005)) << '\n';
}
```

Which should give:

```
2014-01-01 T 03:39:36.000000500
```

Which is intended to represent a `datetime`

in the UTC timezone.

There are two primary points to this post:

Used correctly, `<chrono>`

can be used to virtually eliminate all conversion constants. This example introduces just a few conversion constants which are used to define custom `std::chrono:duration`

s, and an epoch shift. After that, the machinery just works, eliminating common errors.

`chrono`

-Compatible Low-Level Date Algorithms has some really useful and efficient algorithms.

**Update**

Working with unsigned durations is really error prone, and 63 bits of `wtick`

s is plenty of range. Changed `wtick::rep`

to `int64_t`

. This gives much better results:

```
int
main()
{
std::cout << datetime_from_wtick(wtick(0)) << '\n';
std::cout << datetime_from_wtick(wtick(864000000000)) << '\n';
std::cout << datetime_from_wtick(wtick(130330211760000005)) << '\n';
std::cout << datetime_from_wtick(wtick(0x7FFFFFFFFFFFFFFF)) << '\n';
}
1601-01-01 T 00:00:00.000000000
1601-01-02 T 00:00:00.000000000
2014-01-01 T 03:39:36.000000500
30828-09-14 T 02:48:05.477580700
```