% examples-thom1.math --------------------------------------------------------
% thom fruehwirth 1991-93
% examples for *math* constraint handlers compiled from various sources
% results shown are from old obsolete versions

:- op(1200,fx,'example').	
:- dynamic (example)/1.

% Equation Examples

example    X1+X2=<4, 2*X1+3*X2>=18, X1>=0,X2>=0.
%NO 

example    Y1>=0,Y2>=0,X1>=0,X2>=0,Y1=:=X1-X2,Y2=:=X2-X1.
%YES Y1 = 0 , Y2 = 0,
%    X2 =:= slack(_2),
%    X1 =:= slack(_2),
%    slack(_1) =:= slack(_2)

example 3*X+2*Y-4*(3+Z)=:=2*(X-3)+(Y+Z)*7,
        2*(X+Y+Z)=:=3*(X-Y-Z),
        5*(X+Y)-7*X-Z=:=(2+1+X)*6.
%YES Y = 0.657143 , Z = -1 , X = -1.71429

example 3*X+2*Y-4*(3+Z)=:=2*(X-3)+(Y+Z)*7,
        2*(X+Y+Z)=:=3*(X-Y-Z).
%YES Z = -1,
%    X =:= 5 * -1 + 5 * Y

example    3*X+2*Y-4*(3+Z)=:=2*(X-3)+(Y+Z)*7,
        2*(X+Y+Z)=:=3*(X-Y-Z),
        5*(X+Y)-7*X-Z=:=(2+1+X)*6               ,
        2*(X-Y+Z)=:=Y+X-7.
%Failure, test = 0.0799999
%NO 

example 3*X+2*Y-4*(3+Z)=:=2*(X-3)+(Y+Z)*7,
        2*(X+Y+Z)=:=3*(X-Y-Z),
        5*(X+Y)-7*X-Z >= (2+1+X)*6               ,
        2*(X-Y+Z)=:=Y+X-7.
%Success, test = 0.0666666
%YES Z = -1 , Y = 0 , X = -5

example    X>=Y,Y>=X.
%Success, test = 0.0216667
%YES ,
%    X =:= slack(0) + Y

example     X>=Y+1,Y>=X+1.
%Failure, test = 0.0133333
%NO 

example     X>=Y+1,Y>=X-1.

example     X>=Y+1,Y>=X-2.
%Success, test = 0.0199999
%YES ,
%    X =:= slack(0) + Y + 1

example     X*Y=:=6,X+Y=:=5,X-Y=:=1.
%Success, test = 0.0200001
%YES X = 3.0 , Y = 2.0

example    X*Y=:=6,X+Y=:=5,X>=Y.
%Success, test = 0.04
%YES ,
%    6 =:= X * Y,
%    X =:= 0.5 * slack(_1) + 2.5,
%    Y =:= -0.5 * slack(_1) + 2.5

example	 X>=Y+Z,Z>=X+1,Y>=Z.		
%Success, test = 0.0883333
%YES ,
%    Z =:= -(slack(_1)) - slack(_3) - slack(_2) - 1,
%    X =:= -(slack(_1)) - 2 * slack(_3) - slack(_2) - 2,
%    Y =:= -(slack(_3)) - slack(_2) - 1



% men_and_horses

mh(Men,Horses,Heads,Legs):-
	Men >= 0, Horses >= 0,
        Heads =:= Men + Horses,
        Legs =:= 2*Men + 4*Horses.


% fibonacci 
 % loops for  first argument var !
 % works if multi-headed rules are evaluated eagerly as soon as a var is bound

fib(N, X):-
	N =:= 0, X =:= 1.
fib(N, X):-
	N =:= 1, X =:= 1.
fib(N, X):-
	N >= 2, X >= N,
	X =:= X1 + X2,
	%N1 =:= N - 1,
	%N2 =:= N - 2,
	fib(N-1, X1), 
	fib(N-2, X2).


% prove of paralellogram in arbitrary polygon with 4 corners

:- op(31,xfx,#).

mid(AX#AY,BX#BY,CX#CY):-
	AX+CX =:= 2*BX,
	AY+CY =:= 2*BY.

para(AX#AY,BX#BY,CX#CY,DX#DY):-			% nonlinear part
	(AX-BX)*(CY-DY) =:= (AY-BY)*(CX-DX).

pp(P0,P1,P2,P3,[P4,P5,P6,P7]):-
	mid(P0,P4,P1),
	mid(P1,P5,P2),
	mid(P2,P6,P3),
	mid(P3,P7,P0),
	para(P4,P5,P7,P6),
	para(P4,P7,P5,P6).

% for solution, 4 points must be given

example    pp(1#5,2#3,3#1,5#2,L).
%Success, test = 0.025
%YES L = [1.5 # 4.0, 2.5 # 2.0, 4.0 # 1.5, 3.0 # 3.5]

example     pp(A,B,C,D,[1.5 # 4.0, 2.5 # 2.0, 4.0 # 1.5, 3.0 # 3.5]).
/*
YES A = _2 # _4 , B = _1 # _3 , C = _5 # _7 , D = _6 # _8,
    _1 =:= _6 - 3.0,
    _2 =:= -(_6) + 6.0,
    _3 =:= _8 + 1.0,
    _4 =:= -(_8) + 7.0,
    _5 =:= -(_6) + 8.0,
    _7 =:= -(_8) + 3.0
*/

example     L = [1.5 # 4.0, 2.5 # 2.0, 4.0 # 1.5, 3.0 # 3.5],pp(A,B,1#1,D,L).
%Success, test = 0.0333328
%YES A = -1 # 5.0 , B = 4.0 # 3.0 , D = 7.0 # 2.0 , L = [1.5 # 4.0, 2.5 # 2.0, 4.0 # 1.5, 3.0 # 3.5]



% CLP(R) Version 1.0 - Example Programs
% Standard mortgage relationship between:
%     P: Principal
%     T: Life of loan in months
%     I: Fixed (but compounded) monthly interest rate 
%     B: Outstanding balance at the end
%     M: Monthly payment
 % doesn't run in CHIP because of nonlinear constraints ?

mg(P, T, I, B, MP) :-
  T =:= 1,
  B =:= P + P*I - MP.
mg(P, T, I, B, MP) :-
  T > 1, 
  T1 =:= T - 1,
  P1 =:= P + P*I - MP,
  mg(P1, T1, I, B, MP).

mg1(P, T, I, B, MP) :-
  T =:= 1,
  B =:= P + P*I - MP.
mg1(P, T, I, B, MP) :-
  T > 1, 
  mg1(P + P*I - MP, T-1, I, B, MP).

% code in CLP9R) language and system ACM TPLS paper 1992
mg2(P, T, I, B, MP) :-
  T>0,T=<1,
  Int =:= T*(P*I/1200),  
  B =:= P + Int - (T*MP).
mg2(P, T, I, B, MP) :-
  T > 1, 
  Int =:= P*I/1200,
  mg2(P+Int-MP, T-1, I, B, MP).

mg1(M):- mg(999999, 6, 0.01, 0, M). % 6 was 360

mg2(P,B,M):- mg(P, 6, 0.01, B, M).  % 6 was 720

example    mg(999999, 6, 0.01, 0, M).
%YES M = 172548.2

example     mg(P, 6, 0.01, B, M).
/*
YES ,
    _1 =:= -0.990099 * B + 1.9901 * _5,
    M =:= -(B) + 1.01 * _5,
    P =:= -4.85343 * B + 5.85343 * _5,
    _2 =:= -2.94098 * B + 3.94098 * _5,
    _3 =:= -3.90197 * B + 4.90196 * _5,
    _4 =:= -1.97039 * B + 2.97039 * _5
*/

example B=0, P=999999,
    _1 =:= -0.990099 * B + 1.9901 * _5,
    M =:= -(B) + 1.01 * _5,
    P =:= -4.85343 * B + 5.85343 * _5,
    _2 =:= -2.94098 * B + 3.94098 * _5,
    _3 =:= -3.90197 * B + 4.90196 * _5,
    _4 =:= -1.97039 * B + 2.97039 * _5.
%Success, test = 0.0199997
%YES _1 = 339988.4 , M = 172548.2 , P = 999999 , _2 = 673276.4 , _3 = 837450.1 , _4 = 507461.0 , B = 0 , _5 = 170839.8

example    B=0, P=999999,
        M =:= -(B) + 1.01 * _5,
    	P =:= -4.85343 * B + 5.85343 * _5.
%Success, test = 0.0116669
%YES M = 172548.2 , P = 999999 , B = 0 , _5 = 170839.8

example mg(P, 6,I,B,M).
/*
YES ,
    _1 =:= P * I,
    M =:= _11 - B + _9,
    P =:= -(_3) + _4 + 2 * M - _1,
    _10 =:= _6 * I,
    _11 =:= _9 * I,
    _2 =:= 2 * _8 - 2 * _6 - _5 + 3 * _7 - _3,
    _3 =:= _2 * I,
    _4 =:= 2 * _10 - 2 * _9 - _8 + 3 * _6 - _5,
    _5 =:= _4 * I,
    _6 =:= _11 - B - _10 + 2 * _9,
    _7 =:= 2 * _11 - 2 * B - _10 + 3 * _9 - _8,
    _8 =:= _7 * I
*/

% CLP(R) Version 1.0 - Example Programs
% (Slow implementation of) The classic cryptarithmetic puzzle:
%
%       S E N D
%     + M O R E
%     ---------
%     M O N E Y
 % works, but very slow


example    sendmory([9, 5, 6, 7, 1, 0, 8, 2]).
%Success, test = 0.00999908
%YES (was no before because floats don't unify bit/1)

sendmory([S, E, N, D, M, O, R, Y]) :-
	constraints([S, E, N, D, M, O, R, Y]),
	gen_diff_digits([S, E, N, D, M, O, R, Y]).

constraints([S, E, N, D, M, O, R, Y]) :- 
%	S >= 0, E >= 0, N >= 0, D >= 0, M >= 0, O >= 0, R >= 0, Y >= 0,
%	S =< 9, E =< 9, N =< 9, D =< 9, M =< 9, O =< 9, R =< 9, Y =< 9,
%	S >= 1, 
	M >= 1,
%	C1 >= 0, C2 >= 0, C3 >= 0, C4 >= 0,
%	C1 =< 1, C2 =< 1, C3 =< 1, C4 =< 1,
	M = C1,
	S + M + C2 =:= O + 10 * C1,
	E + O + C3 =:= N + 10 * C2,
	N + R + C4 =:= E + 10 * C3,
	D + E      =:= Y + 10 * C4,
	bit(C1), bit(C2), bit(C3), bit(C4).

bit(0).
bit(1).

gen_diff_digits(L) :- 
	gen_diff_digits(L, [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]).
gen_diff_digits([], _).
gen_diff_digits([H | T], L) :- 
	delete(H, L, L2), gen_diff_digits(T, L2).



% CLP(R) Version 1.0 - Example Programs
% Algebraic combinations of options transactions
 % very slow if Stockprice not given, because of
 % backtracking caused by h/3, r/3

% heaviside function
h(X, Y, Z) :- Y < X, Z =:= 0.
h(X, Y, Z) :- Y >= X, Z =:= 1. 

% ramp function
r(X, Y, Z) :- Y < X , Z =:= 0.
r(X, Y, Z) :- Y >= X, Z =:= Y - X.

% option valuation
 % changed order of subgoals
value(Type,Buy_or_Sell,S,C,P,I,X,B,Value) :-
	lookup_option(Type,S,C,P,I,X,B,B1,B2,H1,H2,R1,R2),
	check_param(S,C,P,I,X,B),
	get_sign(Buy_or_Sell,Sign),
	h(B1,S,T1),h(B2,S,T2),r(B1,S,T3),r(B2,S,T4),
	Value =:= Sign*(H1*T1 + H2*T2 + R1*T3 + R2*T4).

% safety check
check_param(S,C,P,I,X,B) :-
	S >= 0, C >= 0, P >= 0,
	I >= 0, X >= 0, B >= 0 .

% Buy or sell are just opposite
get_sign(buy,(-1)).
get_sign(sell,1).

% lookup option vector
lookup_option(Type,S,C,P,I,X,B,B1,B2,H1,H2,R1,R2) :- 
	table(Type,S,C,P,I,X,B,B1,B2,H1,H2,R1,R2).
%	table(Type,S,C,P,I,X,B,B11,B21,H11,H21,R11,R21),
%	B1 =:= B11, B2 =:= B21, H1 =:= H11, H2 =:= H21, R1 =:= R11, R2 =:= R21.

% Table of values for B1,B2,H1,H2,R1,R2
% generic format - lookup_table(Type,Pos_neg,S,C,P,I,X,B,B1,B2,H1,H2,R1,R2).
% where K to R2 are obtained from the table
% M is a multiplier which is -1 or 1 depending on whether one
% is buying or selling the option
table(	stock,		S,	C,	P,	I,	X,	B,	0,	0,	S*(1+I),	0,	-1,	0).
table(	call,		S,	C,	P,	I,	X,	B,	0,	X,	C*(1+I),	0,	0,	-1).
table(	put,		S,	C,	P,	I,	X,	B,	0,	X,	P*(1+I)-X,	0,	1,	-1).
table(	bond,		S,	C,	P,	I,	X,	B,	0,	0,	B*(1+I),	0,	0,	0).


stocks1(Wealth, Stockprice) :-
	Wealth =:= Wealth1 + Wealth2,
	X = 99,
	P = 10, C = 10,
	I = 0,
	value(put, buy, Stockprice, _, P, I, X, _, Wealth1), 
	value(call, buy, Stockprice, C, _, I, X, _, Wealth2).

stocks2(Wealth, Stockprice) :-
	I = 0.1, P1 = 10, X1 = 20, 
	value(put, sell, Stockprice, _, P1, I, X1, _, Wealth1), 
	P2 = 18, X2 = 40, 
	value(put, buy, Stockprice, _, P2, I, X2, _, Wealth2), 
	C3 = 15, X3 = 60, 
	value(call, buy, Stockprice, C3, _, I, X3, _, Wealth3), 
	C4 = 10, X4 = 80, 
	value(call, sell, Stockprice, C4, _, I, X4, _, Wealth4), 
	Wealth =:= Wealth1 + Wealth2 + Wealth3 + Wealth4.

example stocks1(W,10).
/*
Success, test = 0.075
YES W = 69,
    _1 =:= slack(_2),
    _3 =:= slack(_4),
    _5 =:= slack(_6),
    _7 =:= slack(_8)
*/

example stocks2(W,10).
/*
YES W = 5.7,
    _1 =:= slack(_2),
    _11 =:= slack(_12),
    _13 =:= slack(_14),
    _15 =:= slack(_16),
    _3 =:= slack(_4),
    _5 =:= slack(_6),
    _7 =:= slack(_8),
    _9 =:= slack(_10)
*/



% Hoon Hong EXAMPLES

% electric circuit (from clp(r))

resistor(V,I,R):-
	V =:= I*R, R>0.

par_circuit(V,I,R1,R2):-
	I=:=I1+I2,
	resistor(V,I1,R1),
	resistor(V,I2,R2).

example par_circuit(A,B,2,2).
%Success, test = 0.0566666
%YES ,
%    _1 =:= 0.5 * A,
%    B =:= A,
%    _2 =:= 0.5 * A

example    par_circuit(2,A,2,B).
%Success, test = 0.0300003
%YES ,
%    nonzero(B - 0),
%    2 =:= _1 * B,
%    A =:= _1 + 1,
%    B =:= slack(_2)


% complex number arithmetic ((from clp(r))

zmul(R1#I1,R2#I2,R3#I3):-
	R3 =:= R1*R2-I1*I2,
	I3 =:= R1*I2+R2*I1.

example    zmul(1#2,3#4,C).
%Success, test = 0.00333405
%YES C = -5 # 10

example    zmul(A,B,(-5)#10).
/*
Success, test = 0.0483337
YES A = _1 # _4 , B = _3 # _2,
    _5 =:= _1 * _3,
    _5 =:= _6 - 5,
    _6 =:= _4 * _2,
    _7 =:= _1 * _2,
    _7 =:= -(_8) + 10,
    _8 =:= _3 * _4
*/

example    zmul(1#2,B,(-5)#10).
%Success, test = 0.0183334
%YES B = 3.0 # 4.0


% pythagorean numbers
 % loops, see fib for explaination
 % changed order of subgoals

nat(X):- X=:=1.
nat(X):- X>1,nat(Y),X=:=Y+1.

% loops immediately
pyth(X,Y,Z):-
	X*X+Y*Y=:=Z*Z,nat(X),nat(Y),nat(Z).

/*
%From lim@scorpio Fri Jan 31 17:09:44 1992

minimize x1 - 2x2
subject to
 x1 + x2 >= 2,
-x1 + x2 >= 1,
 x2      <= 3.
chr: X+Y>=2,Y-X>=1,Y=<3,X-2*Y=:=M,minimize(M),X=< -1.

Y = 3
M = -7
X = -1

% does not work
chr: X+Y>=2,Y-X>=1,Y=<3,X-2*Y=:=M,minimize(M).

X = X_m176
Y = Y_m196
M = M_m2048
 
yes if
eq0([slack(X_g7001_m242) * 1, slack(X_g7001_m470) * 1, slack(X_g7602_m1106) * 2], -3)
eq0([X_m176 * 1, Y_m196 * -2, M_m2048 * -1], 0)
eq0([Y_m196 * 1, M_m2048 * 1, slack(X_g7001_m470) * 1], 1)
eq0([M_m2048 * -1, slack(X_g7001_m470) * -1, slack(X_g7602_m1106) * 1], -4)
minimize(M_m2048)


Delayed goals:
        X_g7001_m242 >= 0
        X_g7001_m470 >= 0
        X_g7602_m1106 >= 0

minimize -3x1 + 4x2
subject to
x1 + x2 <= 4,
2x1 + 3x2 >= 18.

chr: X+Y =<4,2*X+3*Y>=18,M=:=4*Y-3*X,minimize(M).

Y = 10
X = -6
M = 58
chr: X+Y =<4,2*X+3*Y>=18,M=:=4*Y-3*X,M<58.

no (more) solution.

minimize -x1 + 2x2 -3x3
subject to
x1 + x2 + x3 = 6,
-x1 + x2 + 2x3 = 4,
2x2 + 3x3 = 10,
x3 <= 2.

chr: X+Y+Z=:=6,Y+2*Z-X=:=4,2*Y+3*Z=:=10,Z=<2,M=:=2*Y-3*Z-X,minimize(M).

Y = 2
Z = 2
X = 2
M = -4
yes.
chr: X+Y+Z=:=6,Y+2*Z-X=:=4,2*Y+3*Z=:=10,Z=<2,M=:=2*Y-3*Z-X,M< -4.

no (more) solution.

*/


% from CACM May 91 34(5) p. 59
% given solution is wrong because last inequation is wrong - replace 26 by 19
%I1=3,I2=2,I3=3,I4=0,I5=4,I6=2,I7=5,I8=0,I9=3,I10=5,I11=(-2),I12=3,I13=4,I14=3,
example I8+I7+I6+I5+I4+I3+I2+6=:=22, I9+I8+I7+I6+I5+I4+I3+I2+6=:=25,
	I1=:=3, I2>=2, I3>=3, I4+I3+I2+1>=4, I5+I4+1>=5,
	I6+I5+1>=7, I6>=2, I7>=5, I10+I9+1>=2, I11+I10+1>=4,
	I12+I11+2=<3, I12+1=<4, I12+I11+1>=2, I12>=3, I13>=4,
	I14>=3, I14+I13+I12+I11+4=<22, I14+I13+I12+I11+3=<25, 
	I14+I13+I12+I11+I10+I9+7>=23, I14+I13+I12+I11+I10+6>=26.
/*
YES I1 = 3 , I9 = 3 , I12 = 3 , I11 = -2,
    I7 =:= slack(_1) + 5,
    I10 =:= slack(_14) + slack(_13) - 9,
    I13 =:= -(slack(_10)) - slack(_9) + 14,
    I14 =:= slack(_9) + 3,
    I2 =:= -(slack(_7)) + slack(_6) - slack(_5) + slack(_4) - slack(_3),
    I3 =:= slack(_3) + 3,
    I4 =:= slack(_7) - slack(_6) + slack(_5),
    I5 =:= -(slack(_7)) + slack(_6) + 4,
    I6 =:= slack(_7) + 2,
    I8 =:= -(slack(_1)) - slack(_6) - slack(_4) + 2,
    slack(_10) =:= slack(_13) - 4,
    slack(_11) =:= slack(_14) + slack(_13) - 7,
    slack(_12) =:= slack(_14) + slack(_13) - 14,
    slack(_14) =:= slack(_15) + 7,
    slack(_2) =:= -(slack(_7)) + slack(_6) - slack(_5) + slack(_4) - slack(_3) - 2,
    slack(_8) =:= -(slack(_10)) - slack(_9) + 10
*/

/*

% Examples that take longer --------------------------------------------------

example    sendmory(L). % too slow maybe
%YES L = [9, 5, 6, 7, 1, 0, 8, 2] 

example stocks1(69,S).  % takes long!
/*
YES S = 10,
    _1 =:= slack(_2),
    _3 =:= slack(_4),
    _5 =:= slack(_6),
    _7 =:= slack(_8)
;
YES S = 188,
    _A =:= slack(_B),
    _C =:= slack(_D),
    _E =:= slack(_F),
    _G =:= slack(_H)
*/


%------------------------------------------------------------------------------

chr: X+Y>=2,Y-X>=1,3>=Y.

X = X_m208
Y = Y_m228
 
yes if
eq0([X_m208 * 1, Y_m228 * -1, slack(X_g7001_m4754) * 1], 1)
eq0([Y_m228 * 1, slack(X_g7001_m13874) * 1], -3)
eq0([slack(X_g7001_m802) * 1, slack(X_g7001_m4754) * 1, slack(X_g7001_m13874) * 2], -3)


Delayed goals:
        X_g7001_m802 >= 0
        X_g7001_m4754 >= 0
        X_g7001_m13874 >= 0
yes.
chr: X+2*Y=<3,-X-Y=<1.

X = X_m206
Y = Y_m226
 
yes if
eq0([X_m206 * -1, Y_m226 * -1, slack(X_g7602_m5512) * 1], -1)
eq0([Y_m226 * 1, slack(X_g7602_m808) * 1, slack(X_g7602_m5512) * 1], -4)
 

Delayed goals:
        X_g7602_m808 >= 0
        X_g7602_m5512 >= 0
yes.
chr: X+Y-Z=:=0,-Y+3*Z=:=0.

X = X_m222
Y = Y_m242
Z = Z_m262
 
yes if
eq0([X_m222 * 1, Y_m242 * 1, Z_m262 * -1], 0)
eq0([Y_m242 * -1, Z_m262 * 3], 0)

yes.
chr: 2*X-3*Y+4*Z=:=5,X+2*Y-Z=:=6,-3*X+Y+3*Z=:=1.

X = 2.5714285714285712
Y = 2.714285714285714
Z = 2
*/

% end of file examples-thom1.math ============================================