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//------------------------------------------------------------------------
// Scilab ( http://www.scilab.org/ ) - This file is part of Scilab
// Copyright (C) INRIA - Pierre MARECHAL
//
// This file must be used under the terms of the CeCILL.
// This source file is licensed as described in the file COPYING, which
// you should have received as part of this distribution. The terms
// are also available at
// http://www.cecill.info/licences/Licence_CeCILL_V2.1-en.txt
// Copyright INRIA
// Date : 28 Dec 2005
//------------------------------------------------------------------------
function [Y,M,D,h,m,s] = datevec(N)
lhs=argn(1);
rhs=argn(2);
common_year = [0,31,59,90,120,151,181,212,243,273,304,334,365];
leap_year = [0,31,60,91,121,152,182,213,244,274,305,335,366];
if rhs<>1 then
error(msprintf(gettext("%s: Wrong number of input argument: %d expected.\n"),"datevec",1));
end
if type(N) <> 1 then
error(msprintf(gettext("%s: Wrong type for input argument #%d: Real matrix expected.\n"),"datevec",1));
end
[nr,nc] = size(N);
if nc == 1 then
common_year = common_year';
leap_year = leap_year';
end
// for the moment : hour, minute, second
// =========================================================================
second = 86400*(N-floor(N));
hour = floor(second/3600);
second = second - 3600*hour;
minute = floor(second/60);
second = second - 60*minute;
// Now, the year
// =========================================================================
N = floor(N);
Year = floor(N/365.2425);
temp = N - (365.0*Year + ceil(0.25*Year)- ceil(0.01*Year) + ceil(0.0025*Year));
// On retranche 1 si la valeur est inferieur à 0
mask = (temp <= 0);
Year(mask) = Year(mask)-1;
N(mask) = N(mask) - (365.0*Year(mask) + ceil(0.25*Year(mask)) - ceil(0.01*Year(mask)) + ceil(0.0025*Year(mask)));
N(~mask) = temp(~mask);
// ... and the month
// =========================================================================
Month = int (N/29);
// construction de la matrice
month_day_mat = ones(nr,nc);
month_day_mat(isLeapYear(Year)) = leap_year(Month(isLeapYear(Year))+1);
month_day_mat(~isLeapYear(Year)) = common_year(Month(~isLeapYear(Year))+1);
Month( N>month_day_mat ) = Month( N>month_day_mat )+1;
Day = ones(nr,nc);
month_day_mat(isLeapYear(Year)) = leap_year(Month(isLeapYear(Year)));
month_day_mat(~isLeapYear(Year)) = common_year(Month(~isLeapYear(Year)));
Day = N - month_day_mat;
if (lhs==1) then
Y(:,1) = matrix(Year ,nr*nc , 1);
Y(:,2) = matrix(Month ,nr*nc , 1);
Y(:,3) = matrix(Day ,nr*nc , 1);
Y(:,4) = matrix(hour ,nr*nc , 1);
Y(:,5) = matrix(minute,nr*nc , 1);
Y(:,6) = matrix(second,nr*nc , 1);
else
Y = Year;
M = Month;
D = Day;
h = hour;
m = minute;
s = second;
end
endfunction
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