[1XA Generalities[0X Here we describe some functions which are not specific for numerical semigroups but are used to do computations with them. As they may have interest by themselves, we decribe them here. [1XA.1 Bézout sequences[0X A sequence of positive rational numbers a_1/b_1 < cdots < a_n/b_n with a_i,b_i positive integers is a [13XBézout sequence[0m if a_i+1b_i - a_i b_i+1=1 for all iin {1,...,n-1}. The following function uses an algorithm presented in [BR08]. [1XA.1-1 BezoutSequence[0m [2X> BezoutSequence( [0X[3Xarg[0X[2X ) ____________________________________________[0Xfunction [3Xarg[0m consits of two rational numbers or a list of two rational numbers. The output is a Bézout sequence with ends the two rational numbers given. (Warning: rational numbers are silently transformed into irreducible fractions.) [4X--------------------------- Example ----------------------------[0X [4Xgap> BezoutSequence(4/5,53/27);[0X [4X[ 4/5, 1, 3/2, 5/3, 7/4, 9/5, 11/6, 13/7, 15/8, 17/9, 19/10, 21/11, 23/12,[0X [4X 25/13, 27/14, 29/15, 31/16, 33/17, 35/18, 37/19, 39/20, 41/21, 43/22,[0X [4X 45/23, 47/24, 49/25, 51/26, 53/27 ][0X [4X[0X [4X------------------------------------------------------------------[0X [1XA.1-2 IsBezoutSequence[0m [2X> IsBezoutSequence( [0X[3XL[0X[2X ) ____________________________________________[0Xfunction [3XL[0m is a list of rational numbers. [10XIsBezoutSequence[0m returns [9Xtrue[0m or [9Xfalse[0m according to whether [3XL[0m is a Bézout sequence or not. [4X--------------------------- Example ----------------------------[0X [4Xgap> IsBezoutSequence([ 4/5, 1, 3/2, 5/3, 7/4, 9/5, 11/6]);[0X [4Xtrue[0X [4Xgap> IsBezoutSequence([ 4/5, 1, 3/2, 5/3, 7/4, 9/5, 11/3]);[0X [4XTake the 6 and the 7 elements of the sequence[0X [4Xfalse[0X [4X------------------------------------------------------------------[0X [1XA.1-3 CeilingOfRational[0m [2X> CeilingOfRational( [0X[3Xr[0X[2X ) ___________________________________________[0Xfunction Returns the smallest integer greater than or equal to the rational [3Xr[0m. [4X--------------------------- Example ----------------------------[0X [4Xgap> CeilingOfRational(3/5);[0X [4X1[0X [4X------------------------------------------------------------------[0X [1XA.2 Periodic subadditive functions[0X A periodic function f of period m from the set N of natural numbers into itself may be specified through a list of m natural numbers. The function f is said to be [13Xsubadditive[0m if f(i+j)<= f(i)+f(j) and f(0)=0. [1XA.2-1 RepresentsPeriodicSubAdditiveFunction[0m [2X> RepresentsPeriodicSubAdditiveFunction( [0X[3XL[0X[2X ) _______________________[0Xfunction [3XL[0m is a list of integers. [10XRepresentsPeriodicSubAdditiveFunction[0m returns [9Xtrue[0m or [9Xfalse[0m according to whether [3XL[0m represents a periodic subAdditive function f periodic of period m or not. To avoid defining f(0) (which we assume to be 0) we define f(m)=0 and so the last element of the list must be 0. This technical need is due to the fact that positions in a list must be positive (not a 0). [4X--------------------------- Example ----------------------------[0X [4Xgap> RepresentsPeriodicSubAdditiveFunction([1,2,3,4,0]);[0X [4Xtrue[0X [4X------------------------------------------------------------------[0X