Answer updated with better algorithms, link to detailed description of the algorithms, and complete conversion to `std::tm`

.

I would like to print or extract year/month/day values.
Is there a simple way to convert from time_point to tm (preferably
without boost)?

The first thing to note is that `std::chrono::time_point`

is templated not only on `duration`

, but also on the clock. The clock implies an epoch. And different clocks can have different epochs.

For example, on my system, `std::chrono::high_resolution_clock`

and `std::chrono::steady_clock`

have an epoch of: whenever the computer booted up. If you don't know what time the computer booted up, there is no way to convert that `time_point`

to any calendar system.

That being said, you were probably talking just about `std::chrono::system_clock::time_point`

, as this `time_point`

, and only this `time_point`

, is required to have a deterministic relationship with the civil (gregorian) calendar.

As it turns out, every implementation of `std::chrono::system_clock`

I'm aware of is using unix time. This has an epoch of New Years 1970 neglecting leap seconds.

This isn't guaranteed by the standard. However you can take advantage of this fact if you want to with the following formulas found at:

chrono-Compatible Low-Level Date Algorithms

First off, warning, I'm using the latest C++1y draft, which includes great new `constexpr`

tools. If you need to back off some of the `constexpr`

attributes for your compiler, just do so.

Given the algorithms found at the above link, you can can convert a `std::chrono::time_point<std::chrono::system_clock, Duration>`

to a `std::tm`

, without using `time_t`

with the following function:

```
template <class Duration>
std::tm
make_utc_tm(std::chrono::time_point<std::chrono::system_clock, Duration> tp)
{
using namespace std;
using namespace std::chrono;
typedef duration<int, ratio_multiply<hours::period, ratio<24>>> days;
// t is time duration since 1970-01-01
Duration t = tp.time_since_epoch();
// d is days since 1970-01-01
days d = round_down<days>(t);
// t is now time duration since midnight of day d
t -= d;
// break d down into year/month/day
int year;
unsigned month;
unsigned day;
std::tie(year, month, day) = civil_from_days(d.count());
// start filling in the tm with calendar info
std::tm tm = {0};
tm.tm_year = year - 1900;
tm.tm_mon = month - 1;
tm.tm_mday = day;
tm.tm_wday = weekday_from_days(d.count());
tm.tm_yday = d.count() - days_from_civil(year, 1, 1);
// Fill in the time
tm.tm_hour = duration_cast<hours>(t).count();
t -= hours(tm.tm_hour);
tm.tm_min = duration_cast<minutes>(t).count();
t -= minutes(tm.tm_min);
tm.tm_sec = duration_cast<seconds>(t).count();
return tm;
}
```

Also note that the `std::chrono::system_clock::time_point`

on all existing implementations is a duration in the UTC (neglecting leap seconds) time zone. If you want to convert the `time_point`

using another timezone, you will need to add/subtract the duration offset of the timezone to the `std::chrono::system_clock::time_point`

prior to converting it to a precision of `days`

. And if you further want to take leap seconds into account, then adjust by the appropriate number of seconds prior to truncation to `days`

using this table, and the knowledge that unix time is aligned with UTC *now*.

This function can be verified with:

```
#include <iostream>
#include <iomanip>
void
print_tm(const std::tm& tm)
{
using namespace std;
cout << tm.tm_year+1900;
char fill = cout.fill();
cout << setfill('0');
cout << '-' << setw(2) << tm.tm_mon+1;
cout << '-' << setw(2) << tm.tm_mday;
cout << ' ';
switch (tm.tm_wday)
{
case 0:
cout << "Sun";
break;
case 1:
cout << "Mon";
break;
case 2:
cout << "Tue";
break;
case 3:
cout << "Wed";
break;
case 4:
cout << "Thu";
break;
case 5:
cout << "Fri";
break;
case 6:
cout << "Sat";
break;
}
cout << ' ';
cout << ' ' << setw(2) << tm.tm_hour;
cout << ':' << setw(2) << tm.tm_min;
cout << ':' << setw(2) << tm.tm_sec << " UTC.";
cout << setfill(fill);
cout << " This is " << tm.tm_yday << " days since Jan 1\n";
}
int
main()
{
print_tm(make_utc_tm(std::chrono::system_clock::now()));
}
```

Which for me currently prints out:

2013-09-15 Sun 18:16:50 UTC. This is 257 days since Jan 1

In case chrono-Compatible Low-Level Date Algorithms goes offline, or gets moved, here are the algorithms used in `make_utc_tm`

. There are in-depth explanations of these algorithms at the above link. They are well-tested, and have an extraordinarily large range of validity.

```
// Returns number of days since civil 1970-01-01. Negative values indicate
// days prior to 1970-01-01.
// Preconditions: y-m-d represents a date in the civil (Gregorian) calendar
// m is in [1, 12]
// d is in [1, last_day_of_month(y, m)]
// y is "approximately" in
// [numeric_limits<Int>::min()/366, numeric_limits<Int>::max()/366]
// Exact range of validity is:
// [civil_from_days(numeric_limits<Int>::min()),
// civil_from_days(numeric_limits<Int>::max()-719468)]
template <class Int>
constexpr
Int
days_from_civil(Int y, unsigned m, unsigned d) noexcept
{
static_assert(std::numeric_limits<unsigned>::digits >= 18,
"This algorithm has not been ported to a 16 bit unsigned integer");
static_assert(std::numeric_limits<Int>::digits >= 20,
"This algorithm has not been ported to a 16 bit signed integer");
y -= m <= 2;
const Int era = (y >= 0 ? y : y-399) / 400;
const unsigned yoe = static_cast<unsigned>(y - era * 400); // [0, 399]
const unsigned doy = (153*(m + (m > 2 ? -3 : 9)) + 2)/5 + d-1; // [0, 365]
const unsigned doe = yoe * 365 + yoe/4 - yoe/100 + doy; // [0, 146096]
return era * 146097 + static_cast<Int>(doe) - 719468;
}
// Returns year/month/day triple in civil calendar
// Preconditions: z is number of days since 1970-01-01 and is in the range:
// [numeric_limits<Int>::min(), numeric_limits<Int>::max()-719468].
template <class Int>
constexpr
std::tuple<Int, unsigned, unsigned>
civil_from_days(Int z) noexcept
{
static_assert(std::numeric_limits<unsigned>::digits >= 18,
"This algorithm has not been ported to a 16 bit unsigned integer");
static_assert(std::numeric_limits<Int>::digits >= 20,
"This algorithm has not been ported to a 16 bit signed integer");
z += 719468;
const Int era = (z >= 0 ? z : z - 146096) / 146097;
const unsigned doe = static_cast<unsigned>(z - era * 146097); // [0, 146096]
const unsigned yoe = (doe - doe/1460 + doe/36524 - doe/146096) / 365; // [0, 399]
const Int y = static_cast<Int>(yoe) + era * 400;
const unsigned doy = doe - (365*yoe + yoe/4 - yoe/100); // [0, 365]
const unsigned mp = (5*doy + 2)/153; // [0, 11]
const unsigned d = doy - (153*mp+2)/5 + 1; // [1, 31]
const unsigned m = mp + (mp < 10 ? 3 : -9); // [1, 12]
return std::tuple<Int, unsigned, unsigned>(y + (m <= 2), m, d);
}
template <class Int>
constexpr
unsigned
weekday_from_days(Int z) noexcept
{
return static_cast<unsigned>(z >= -4 ? (z+4) % 7 : (z+5) % 7 + 6);
}
template <class To, class Rep, class Period>
To
round_down(const std::chrono::duration<Rep, Period>& d)
{
To t = std::chrono::duration_cast<To>(d);
if (t > d)
--t;
return t;
}
```