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In order to find leap years, why must the year be indivisible by 100 and divisible by 400? I understand why it must be divisible by 4. Please explain the algorithm.

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For what it's worth, calendar calculations are surprisingly hard, especially if you have to get into leap seconds. If you're building a library, consider acquiring one instead. Good luck! :) – Greg D Apr 7 '09 at 11:30
It is not an algorithm, it is astronomical facts, adapted to human granularity... – PhiLho Apr 7 '09 at 11:42

17 Answers 17

In general terms the algorithm for calculating a leap year is as follows...

A year will be a leap year if it is divisible by 4 but not by 100. If a year is divisible by 4 and by 100, it is not a leap year unless it is also divisible by 400.

Thus years such as 1996, 1992, 1988 and so on are leap years because they are divisible by 4 but not by 100. For century years, the 400 rule is important. Thus, century years 1900, 1800 and 1700 while all still divisible by 4 are also exactly divisible by 100. As they are not further divisible by 400, they are not leap years

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There's an algorithm on wikipedia to determine leap years:

function isLeapYear (year):
    if ((year modulo 4 is 0) and (year modulo 100 is not 0))
    or (year modulo 400 is 0)
        then true
    else false

There's a lot of information about this topic on the wikipedia page about leap years, inclusive information about different calendars.

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I just tested this and it correctly determines leap and non-leap years 1900-2200 from the list of leap years at – GlenPeterson Jun 16 '14 at 19:13
Your algorithm is way more easy to understand than wikipedia's. I really like it. – benvds Apr 5 '15 at 21:36

I'm sure Wikipedia can explain it better than I can, but it is basically to do with the fact that if you added an extra day every four years we'd get ahead of the sun as its time to orbit the sun is less than 365.25 days so we compensate for this by not adding leap days on years that are not divisible by 400 eg 1900.

Hope that helps

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You really should try to google first.

Wikipedia has a explanation of leap years. The algorithm your describing is for the Proleptic Gregorian calendar.

More about the math around it can be found in the article Calendar Algorithms.

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That "Calendar Algorithms" link no longer works :( – Peter M Feb 1 '14 at 16:10

A quick Google for "calculating leap years" came up with this page, which describes the problem clearly and gives an (admitedly VB) implementation, as the first hit.

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Leap years are arbitrary, and the system used to describe them is a man made construct. There is no why.

What I mean is there could have been a leap year every 28 years and we would have an extra week in those leap years ... but the powers that be decided to make it a day every 4 years to catch up.

It also has to do with the earth taking a pesky 365.25 days to go round the sun etc. Of course it isn't really 365.25 is it slightly less (365.242222...), so to correct for this discrepancy they decided drop the leap years that are divisible by 100.

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If you're interested in the reasons for these rules, it's because the time it takes the earth to make exactly one orbit around the sun is a long imprecise decimal value. It's not exactly 365.25. It's slightly less than 365.25, so every 100 years, one leap day must be eliminated (365.25 - 0.01 = 365.24). But that's not exactly correct either. The value is slightly larger than 365.24. So only 3 out of 4 times will the 100 year rule apply (or in other words, add back in 1 day every 400 years; 365.25 - 0.01 + 0.0025 = 365.2425).

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The length of a year is (more or less) 365.242196 days. So we have to subtract, more or less, a quarter of a day to make it fit :

365.242196 - 0.25 = 364.992196 (by adding 1 day in 4 years) : but oops, now it's too small!! lets add a hundreth of a day (by not adding that day once in a hundred year :-))

364.992196 + 0,01 = 365.002196 (oops, a bit too big, let's add that day anyway one time in about 400 years)

365.002196 - 1/400 = 364.999696

Almost there now, just play with leapseconds now and then, and you're set.

(Note : the reason no more corrections are applied after this step is because a year also CHANGES IN LENGTH!!, that's why leapseconds are the most flexible solution, see for examlple here)

That's why i guess

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++ Good explanation, and entertaining! – Mike Dunlavey Apr 7 '09 at 11:34
tx, and tx for correcting the typo – Peter Apr 7 '09 at 11:48
You may want to mention that the small differences really do matter since the old Julian calendar did not have these corrections and by the 16th century the calendar was over 10 days off for astronomical events like solstices and (more importantly) the date of easter. – Michael Borgwardt Apr 13 '09 at 21:33
For interest, the original source of the present leap-year calculation system is a document entitled "Inter gravissimas" issued by Pope Gregory XIII in 1582. – Nick Moore Mar 2 '10 at 19:43
Bery Bery Nice Explanation – Tarun Sep 23 '12 at 7:55

There are on average, roughly 365.2425 days in a year at the moment (the Earth is slowing down but let's ignore that for now).

The reason we have leap years every 4 years is because that gets us to 365.25 on average [(365+365+365+366) / 4 = 365.25, 1461 days in 4 years].

The reason we don't have leap years on the 100-multiples is to get us to 365.24 `[(1461 x 25 - 1) / 100 = 365.24, 36,524 days in 100 years.

Then the reason we once again have a leap year on 400-multiples is to get us to 365.2425 [(36,524 x 4 + 1) / 400 = 365.2425, 146,097 days in 400 years].

I believe there may be another rule at 3600-multiples but I've never coded for it (Y2K was one thing but planning for one and a half thousand years into the future is not necessary in my opinion - keep in mind I've been wrong before).

So, the rules are, in decreasing priority:

  • multiple of 400 is a leap year.
  • multiple of 100 is not a leap year.
  • multiple of 4 is a leap year.
  • anything else is not a leap year.
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just wrote this in Coffee-Script:

is_leap_year = ( year ) ->
  assert isa_integer year
  return true   if year % 400 == 0
  return false  if year % 100 == 0
  return true   if year %   4 == 0
  return false

# parseInt? that's not even a word. 
# Let's rewrite that using real language:
integer = parseInt 

isa_number = ( x ) ->
  return x ) == '[object Number]' and not isNaN( x )

isa_integer = ( x ) ->
  return ( isa_number x ) and ( x == integer( x ) )

of course, the validity checking done here goes a little further than what was asked for, but i find it a necessary thing to do in good programming.

note that the return values of this function indicate leap years in the so-called proleptic gregorian calendar, so for the year 1400 it indicates false, whereas in fact that year was a leap year, according to the then-used julian calendar. i will still leave it as such in the datetime library i'm writing because writing correct code to deal with dates quickly gets surprisingly involved, so i will only ever support the gregorian calendar (or get paid for another one).

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Will it not be much better if we make one step further. Assuming every 3200 year as no leap year, the length of the year will come

364.999696 + 1/3200 = 364.999696 + .0003125 = 365.0000085

and after this the adjustment will be required after around 120000 years.

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by Sandeep Agrawal, again A little modification in my above suggestion:- In place of 3000, take 3200 years as no leap year(because 3000 year itself is not a leap year as it is not divisible by 400) By taking 3200 year as no leap year the calculation will be :- 364.999696 +1/3200 = 364.999696 + .0003125 = 365.0000085 and now will hardly need any further adjustment.( after around 12000 years) – Sandeep Agrawal Dec 28 '11 at 16:27
after 12000 years( taking 12000 as no leap year) the calculation will be:- – Sandeep Agrawal Dec 28 '11 at 16:30
you can edit your answer – Nimit Dudani Nov 3 '12 at 6:49

Here comes a rather obsqure idea. When every year dividable with 100 gets 365 days, what shall be done at this time? In the far future, when even years dividable with 400 only can get 365 days.

Then there is a possibility or reason to make corrections in years dividable with 80. Normal years will have 365 day and those dividable with 400 can get 366 days. Or is this a loose-loose situation.

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The next time a year is divisible by 400 would be in the year 2400. And we just don't care what happens if and when we get there. – Bo Persson Apr 22 '13 at 16:21

Return true if the input year is a leap year

Basic modern day code:

  If year mod 4 = 0, then leap year
  if year mod 100 then normal year
  if year mod 400 then leap year
  else normal year

Todays rule started 1582 AD Julian calendar rule with every 4th year started 46BC but is not coherent before 10 AD as declared by Cesar. They did however add some leap years every 3rd year now and then in the years before: Leap years were therefore 45 BC, 42 BC, 39 BC, 36 BC, 33 BC, 30 BC, 27 BC, 24 BC, 21 BC, 18 BC, 15 BC, 12 BC, 9 BC, 8 AD, 12 AD Before year 45BC leap year was not added.

The year 0 do not exist as it is ...2BC 1BC 1AD 2AD... for some calculation this can be an issue.

function isLeapYear(year: Integer): Boolean;
  result := false;
  if year > 1582 then // Todays calendar rule was started in year 1582 
    result := ((year mod 4 = 0) and (not(year mod 100 = 0))) or (year mod 400 = 0)
  else if year > 10 then // Between year 10 and year 1582 every 4th year was a leap year 
    result := year mod 4 = 0
  else //Between year -45 and year 10 only certain years was leap year, every 3rd year but the entire time
    case year of
      -45, -42, -39, -36, -33, -30, -27, -24, -21, -18, -15, -12, -9:
        result := true;
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You could just check if the Year number is divisible by both 4 and 400. You dont really need to check if it is indivisible by 100. The reason 400 comes into question is because according to the Gregorian Calendar, our "day length" is slightly off, and thus to compensate that, we have 303 regular years (365 days each) and 97 leap years (366 days each). The difference of those 3 extra years that are not leap years is to stay in cycle with the Gregorian calendar, which repeats every 400 years. Look up Christian Zeller's congruence equation. It will help understanding the real reason. Hope this helps :)

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this is enough to check if a year is a leap year.

if( (year%400==0 || year%100!=0) &&(year%4==0))
    cout<<"It is a leap year";
    cout<<"It is not a leap year";
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In the Gregorian calendar 3 criteria must be taken into account to identify leap years:

  1. The year is evenly divisible by 4;
  2. If the year can be evenly divided by 100, it is NOT a leap year, unless;
  3. The year is also evenly divisible by 400. Then it is a leap year. Why the year divided by 100 is not leap year
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a) The year is 365.242199 days.

b)If every year was 365 days, in 100 years we would lose 24.2199 days. That's why we add 24 days per century (every 4 years EXCEPT when divisable by 100)

c)But still we lose 0.21299 days/century. So in 4 centuries we lose 0.8796 days. That's why we add 1 day per 4 centuries (every fourth century we DO count a leap year).

d)But that means we lose -0.1204 days (we go forward) per quadricentenial (4 centuries). So in 8 quadricentenials (3200 years) we DO NOT count a leap year.

e)But that means we lose 0.0368 days per 3200 years. So in 24x3200 years (=76800years) we lose 0.8832 days. That's why we DO count a leap year.

and so on... (by then we will have destroyed the planet, so it doesn't matter)

What I cannot understand though, is why we don't count a leap year every 500 years instead of 400. In that way we would converge more rapidly to the correct time (we would lose 2.3 hours/500 years).

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