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arithmetic.pl
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arithmetic.pl
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/** Arithmetic predicates
These predicates are additions to standard the arithmetic functions provided by `is/2`.
*/
:- module(arithmetic, [expmod/4, lcm/3, lsb/2, msb/2, number_to_rational/2,
number_to_rational/3, popcount/2,
rational_numerator_denominator/3]).
:- use_module(library(charsio), [write_term_to_chars/3]).
:- use_module(library(error)).
:- use_module(library(lists), [append/3, member/2]).
%% expmod(+Base, +Expo, +Mod, -R).
%
% Modular exponentiation. Base, Expo and Mod must be integers.
expmod(Base, Expo, Mod, R) :-
( member(N, [Base, Expo, Mod]), var(N) -> instantiation_error(expmod/4)
; member(N, [Base, Expo, Mod]), \+ integer(N) ->
type_error(integer, N, expmod/4)
; Expo < 0 -> domain_error(not_less_than_zero, Expo, expmod/4)
; expmod_(Base, Expo, Mod, 1, R)
).
expmod_(_, _, 1, _, 0) :- !.
expmod_(_, 0, _, R, R) :- !.
expmod_(Base0, Expo0, Mod, C0, R) :-
Expo0 /\ 1 =:= 1,
C is (C0 * Base0) mod Mod,
!,
Expo is Expo0 >> 1,
Base is (Base0 * Base0) mod Mod,
expmod_(Base, Expo, Mod, C, R).
expmod_(Base0, Expo0, Mod, C, R) :-
Expo is Expo0 >> 1,
Base is (Base0 * Base0) mod Mod,
expmod_(Base, Expo, Mod, C, R).
%% lcm(+A, +B, -Lcm) is det.
%
% Calculates the Least common multiple for A and B: the smallest positive integer
% that is divisible by both A and B.
%
% A and B need to be integers.
lcm(A, B, X) :-
builtins:must_be_number(A, lcm/2),
builtins:must_be_number(B, lcm/2),
( \+ integer(A) -> type_error(integer, A, lcm/2)
; \+ integer(B) -> type_error(integer, B, lcm/2)
; (A = 0, B = 0) -> X = 0
; builtins:can_be_number(X, lcm/2),
X is abs(B) // gcd(A,B) * abs(A)
).
%% lsb(+X, -N).
%
% True iff N is the least significat bit of integer X
lsb(X, N) :-
builtins:must_be_number(X, lsb/2),
( \+ integer(X) -> type_error(integer, X, lsb/2)
; X < 1 -> domain_error(not_less_than_one, X, lsb/2)
; builtins:can_be_number(N, lsb/2),
X1 is X /\ (-X),
msb_(X1, -1, N)
).
%% msb(+X, -N).
%
% True iff N is the most significant bit of integer X
msb(X, N) :-
builtins:must_be_number(X, msb/2),
( \+ integer(X) -> type_error(integer, X, msb/2)
; X < 1 -> domain_error(not_less_than_one, X, msb/2)
; builtins:can_be_number(N, msb/2),
X1 is X >> 1,
msb_(X1, 0, N)
).
msb_(0, N, N) :- !.
msb_(X, M, N) :-
X1 is X >> 1,
M1 is M + 1,
msb_(X1, M1, N).
%% number_to_rational(+Real, -Fraction).
%
% True iff given a number Real, Fraction is the same number represented as a fraction.
number_to_rational(Real, Fraction) :-
( var(Real) -> instantiation_error(number_to_rational/2)
; integer(Real) -> Fraction is Real rdiv 1
; (rational(Real) ; float(Real)) ->
number_to_rational(1.0e-6, Real, Fraction)
; type_error(number, Real, number_to_rational/2)
).
% If 0 <= Eps0 <= 1e-16 then the search is for "infinite" precision.
number_to_rational(Eps0, Real0, Fraction) :-
( var(Eps0) -> instantiation_error(number_to_rational/3)
; \+ number(Eps0) -> type_error(number, Eps0, number_to_rational/3)
; Eps0 < 0 -> domain_error(not_less_than_zero, Eps0, number_to_rational/3)
; Eps_ is Eps0 rdiv 1,
rational_numerator_denominator(Eps_, EpsN, EpsD),
Eps = EpsN/EpsD
),
( var(Real0) -> instantiation_error(number_to_rational/3)
; \+ number(Real0) -> type_error(number, Eps0, number_to_rational/3)
; Real_ is Real0 rdiv 1,
rational_numerator_denominator(Real_, RealN, RealD),
Real = RealN/RealD
),
E0/E1 = Eps,
P0/Q0 = Real,
( P0 < 0 -> I1 is -1 + P0 // Q0
; I1 is P0 // Q0
),
P1 is P0 mod Q0,
Q1 = Q0,
( P1 =:= 0 -> Fraction is I1 + 0 rdiv 1
; Qn1n is max(P1 * E1 - Q1 * E0, 0),
Qn1d is Q1 * E1,
Qn1 = Qn1n/Qn1d,
Qp1n is P1 * E1 + Q1 * E0,
Qp1d = Qn1d,
Qp1 = Qp1n/Qp1d,
stern_brocot_(Qn1, Qp1, 0/1, 1/0, P2/Q2),
Fraction is I1 + P2 rdiv Q2
),
!.
stern_brocot_(Qnn/Qnd, Qpn/Qpd, A/B, C/D, Fraction) :-
Fn1 is A + C,
Fd1 is B + D,
simplify_fraction(Fn1/Fd1, Fn/Fd),
S1 is sign(Fn * Qnd - Fd * Qnn),
S2 is sign(Fn * Qpd - Fd * Qpn),
( S1 < 0 -> stern_brocot_(Qnn/Qnd, Qpn/Qpd, Fn/Fd, C/D, Fraction)
; S2 > 0 -> stern_brocot_(Qnn/Qnd, Qpn/Qpd, A/B, Fn/Fd, Fraction)
; Fraction = Fn/Fd
).
simplify_fraction(A0/B0, A/B) :-
G is gcd(A0, B0),
A is A0 // G,
B is B0 // G.
%% rational_numerator_denominator(+Fraction, -Numerator, -Denominator).
%
% True iff given a fraction Fraction, Numerator is the numerator of that fraction
% and Denominator the denominator.
rational_numerator_denominator(R, N, D) :-
write_term_to_chars(R, [], Cs),
append(Ns, [' ', r, d, i, v, ' '|Ds], Cs),
number_chars(N, Ns),
number_chars(D, Ds).
%% popcount(+Number, -Bits1).
%
% True iff given an integer Number, Bits1 is the amount of 1 bits the binary representation
% of that number has.
popcount(X, N) :-
must_be(integer, X),
'$popcount'(X, N).