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yap-6.3/GPL/clpqr/clpr/nf_r.pl

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/*
Part of CLP(R) (Constraint Logic Programming over Reals)
Author: Leslie De Koninck
E-mail: Leslie.DeKoninck@cs.kuleuven.be
WWW: http://www.swi-prolog.org
http://www.ai.univie.ac.at/cgi-bin/tr-online?number+95-09
Copyright (C): 2004, K.U. Leuven and
1992-1995, Austrian Research Institute for
Artificial Intelligence (OFAI),
Vienna, Austria
This software is part of Leslie De Koninck's master thesis, supervised
by Bart Demoen and daily advisor Tom Schrijvers. It is based on CLP(Q,R)
by Christian Holzbaur for SICStus Prolog and distributed under the
license details below with permission from all mentioned authors.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
As a special exception, if you link this library with other files,
compiled with a Free Software compiler, to produce an executable, this
library does not by itself cause the resulting executable to be covered
by the GNU General Public License. This exception does not however
invalidate any other reasons why the executable file might be covered by
the GNU General Public License.
*/
:- module(nf_r,
[
{}/1,
nf/2,
entailed/1,
split/3,
repair/2,
nf_constant/2,
wait_linear/3,
nf2term/2
]).
:- use_module('../clpqr/geler',
[
geler/3
]).
:- use_module(bv_r,
[
export_binding/2,
log_deref/4,
solve/1,
'solve_<'/1,
'solve_=<'/1,
'solve_=\\='/1
]).
:- use_module(ineq_r,
[
ineq_one/4,
ineq_one_s_p_0/1,
ineq_one_s_n_0/1,
ineq_one_n_p_0/1,
ineq_one_n_n_0/1
]).
:- use_module(store_r,
[
add_linear_11/3,
normalize_scalar/2
]).
goal_expansion(geler(X,Y),geler(clpr,X,Y)).
% -------------------------------------------------------------------------
% {Constraint}
%
% Adds the constraint Constraint to the constraint store.
%
% First rule is to prevent binding with other rules when a variable is input
% Constraints are converted to normal form and if necessary, submitted to the linear
% equality/inequality solver (bv + ineq) or to the non-linear store (geler)
{Rel} :-
var(Rel),
!,
throw(instantiation_error({Rel},1)).
{R,Rs} :-
!,
{R},{Rs}.
{R;Rs} :-
!,
({R};{Rs}). % for entailment checking
{L < R} :-
!,
nf(L-R,Nf),
submit_lt(Nf).
{L > R} :-
!,
nf(R-L,Nf),
submit_lt(Nf).
{L =< R} :-
!,
nf(L-R,Nf),
submit_le( Nf).
{<=(L,R)} :-
!,
nf(L-R,Nf),
submit_le(Nf).
{L >= R} :-
!,
nf(R-L,Nf),
submit_le(Nf).
{L =\= R} :-
!,
nf(L-R,Nf),
submit_ne(Nf).
{L =:= R} :-
!,
nf(L-R,Nf),
submit_eq(Nf).
{L = R} :-
!,
nf(L-R,Nf),
submit_eq(Nf).
{Rel} :- throw(type_error({Rel},1,'a constraint',Rel)).
% entailed(C)
%
% s -> c = ~s v c = ~(s /\ ~c)
% where s is the store and c is the constraint for which
% we want to know whether it is entailed.
% C is negated and added to the store. If this fails, then c is entailed by s
entailed(C) :-
negate(C,Cn),
\+ {Cn}.
% negate(C,Res).
%
% Res is the negation of constraint C
% first rule is to prevent binding with other rules when a variable is input
negate(Rel,_) :-
var(Rel),
!,
throw(instantiation_error(entailed(Rel),1)).
negate((A,B),(Na;Nb)) :-
!,
negate(A,Na),
negate(B,Nb).
negate((A;B),(Na,Nb)) :-
!,
negate(A,Na),
negate(B,Nb).
negate(A<B,A>=B) :- !.
negate(A>B,A=<B) :- !.
negate(A=<B,A>B) :- !.
negate(A>=B,A<B) :- !.
negate(A=:=B,A=\=B) :- !.
negate(A=B,A=\=B) :- !.
negate(A=\=B,A=:=B) :- !.
negate(Rel,_) :- throw( type_error(entailed(Rel),1,'a constraint',Rel)).
% submit_eq(Nf)
%
% Submits the equality Nf = 0 to the constraint store, where Nf is in normal form.
% The following cases may apply:
% a) Nf = []
% b) Nf = [A]
% b1) A = k
% b2) invertible(A)
% b3) linear -> A = 0
% b4) nonlinear -> geler
% c) Nf=[A,B|Rest]
% c1) A=k
% c11) (B=c*X^+1 or B=c*X^-1), Rest=[] -> B=-k/c or B=-c/k
% c12) invertible(A,B)
% c13) linear(B|Rest)
% c14) geler
% c2) linear(Nf)
% c3) nonlinear -> geler
submit_eq([]). % trivial success: case a
submit_eq([T|Ts]) :-
submit_eq(Ts,T).
submit_eq([],A) :- submit_eq_b(A). % case b
submit_eq([B|Bs],A) :- submit_eq_c(A,B,Bs). % case c
% submit_eq_b(A)
%
% Handles case b of submit_eq/1
% case b1: A is a constant (non-zero)
submit_eq_b(v(_,[])) :-
!,
fail.
% case b2/b3: A is n*X^P => X = 0
submit_eq_b(v(_,[X^P])) :-
var(X),
P > 0,
!,
export_binding(X,0.0).
% case b2: non-linear is invertible: NL(X) = 0 => X - inv(NL)(0) = 0
submit_eq_b(v(_,[NL^1])) :-
nonvar(NL),
nl_invertible(NL,X,0.0,Inv),
!,
nf(-Inv,S),
nf_add(X,S,New),
submit_eq(New).
% case b4: A is non-linear and not invertible => submit equality to geler
submit_eq_b(Term) :-
term_variables(Term,Vs),
geler(Vs,nf_r:resubmit_eq([Term])).
% submit_eq_c(A,B,Rest)
%
% Handles case c of submit_eq/1
% case c1: A is a constant
submit_eq_c(v(I,[]),B,Rest) :-
!,
submit_eq_c1(Rest,B,I).
% case c2: A,B and Rest are linear
submit_eq_c(A,B,Rest) :- % c2
A = v(_,[X^1]),
var(X),
B = v(_,[Y^1]),
var(Y),
linear(Rest),
!,
Hom = [A,B|Rest],
% 'solve_='(Hom).
nf_length(Hom,0,Len),
log_deref(Len,Hom,[],HomD),
solve(HomD).
% case c3: A, B or Rest is non-linear => geler
submit_eq_c(A,B,Rest) :-
Norm = [A,B|Rest],
term_variables(Norm,Vs),
geler(Vs,nf_r:resubmit_eq(Norm)).
% submit_eq_c1(Rest,B,K)
%
% Handles case c1 of submit_eq/1
% case c11: k+cX^1=0 or k+cX^-1=0
submit_eq_c1([],v(K,[X^P]),I) :-
var(X),
( P =:= 1,
!,
Val is -I/K,
export_binding(X,Val)
; P =:= -1,
!,
Val is -K/I,
export_binding(X,Val)
).
% case c12: non-linear, invertible: cNL(X)^1+k=0 => inv(NL)(-k/c) = 0 ;
% cNL(X)^-1+k=0 => inv(NL)(-c/k) = 0
submit_eq_c1([],v(K,[NL^P]),I) :-
nonvar(NL),
( P =:= 1,
Y is -I/K
; P =:= -1,
Y is -K/I
),
nl_invertible(NL,X,Y,Inv),
!,
nf(-Inv,S),
nf_add(X,S,New),
submit_eq(New).
% case c13: linear: X + Y + Z + c = 0 =>
submit_eq_c1(Rest,B,I) :-
B = v(_,[Y^1]),
var(Y),
linear(Rest),
!,
% 'solve_='( [v(I,[]),B|Rest]).
Hom = [B|Rest],
nf_length(Hom,0,Len),
normalize_scalar(I,Nonvar),
log_deref(Len,Hom,[],HomD),
add_linear_11(Nonvar,HomD,LinD),
solve(LinD).
% case c14: other cases => geler
submit_eq_c1(Rest,B,I) :-
Norm = [v(I,[]),B|Rest],
term_variables(Norm,Vs),
geler(Vs,nf_r:resubmit_eq(Norm)).
% -----------------------------------------------------------------------
% submit_lt(Nf)
%
% Submits the inequality Nf<0 to the constraint store, where Nf is in normal form.
% 0 < 0 => fail
submit_lt([]) :- fail.
% A + B < 0
submit_lt([A|As]) :- submit_lt(As,A).
% submit_lt(As,A)
%
% Does what submit_lt/1 does where Nf = [A|As]
% v(K,P) < 0
submit_lt([],v(K,P)) :- submit_lt_b(P,K).
% A + B + Bs < 0
submit_lt([B|Bs],A) :- submit_lt_c(Bs,A,B).
% submit_lt_b(P,K)
%
% Does what submit_lt/2 does where A = [v(K,P)] and As = []
% c < 0
submit_lt_b([],I) :-
!,
I < -1.0e-10.
% cX^1 < 0 : if c < 0 then X > 0, else X < 0
submit_lt_b([X^1],K) :-
var(X),
!,
( K > 1.0e-10
-> ineq_one_s_p_0(X) % X is strictly negative
; ineq_one_s_n_0(X) % X is strictly positive
).
% non-linear => geler
submit_lt_b(P,K) :-
term_variables(P,Vs),
geler(Vs,nf_r:resubmit_lt([v(K,P)])).
% submit_lt_c(Bs,A,B)
%
% Does what submit_lt/2 does where As = [B|Bs].
% c + kX < 0 => kX < c
submit_lt_c([],A,B) :-
A = v(I,[]),
B = v(K,[Y^1]),
var(Y),
!,
ineq_one(strict,Y,K,I).
% linear < 0 => solve, non-linear < 0 => geler
submit_lt_c(Rest,A,B) :-
Norm = [A,B|Rest],
( linear(Norm)
-> 'solve_<'(Norm)
; term_variables(Norm,Vs),
geler(Vs,nf_r:resubmit_lt(Norm))
).
% submit_le(Nf)
%
% Submits the inequality Nf =< 0 to the constraint store, where Nf is in normal form.
% See also submit_lt/1
% 0 =< 0 => success
submit_le([]).
% A + B =< 0
submit_le([A|As]) :- submit_le(As,A).
% submit_le(As,A)
%
% See submit_lt/2. This handles less or equal.
% v(K,P) =< 0
submit_le([],v(K,P)) :- submit_le_b(P,K).
% A + B + Bs =< 0
submit_le([B|Bs],A) :- submit_le_c(Bs,A,B).
% submit_le_b(P,K)
%
% See submit_lt_b/2. This handles less or equal.
% c =< 0
submit_le_b([],I) :-
!,
I < 1.0e-10.
% cX^1 =< 0: if c < 0 then X >= 0, else X =< 0
submit_le_b([X^1],K) :-
var(X),
!,
( K > 1.0e-10
-> ineq_one_n_p_0(X) % X is non-strictly negative
; ineq_one_n_n_0(X) % X is non-strictly positive
).
% cX^P =< 0 => geler
submit_le_b(P,K) :-
term_variables(P,Vs),
geler(Vs,nf_r:resubmit_le([v(K,P)])).
% submit_le_c(Bs,A,B)
%
% See submit_lt_c/3. This handles less or equal.
% c + kX^1 =< 0 => kX =< 0
submit_le_c([],A,B) :-
A = v(I,[]),
B = v(K,[Y^1]),
var(Y),
!,
ineq_one(nonstrict,Y,K,I).
% A, B & Rest are linear => solve, otherwise => geler
submit_le_c(Rest,A,B) :-
Norm = [A,B|Rest],
( linear(Norm)
-> 'solve_=<'(Norm)
; term_variables(Norm,Vs),
geler(Vs,nf_r:resubmit_le(Norm))
).
% submit_ne(Nf)
%
% Submits the inequality Nf =\= 0 to the constraint store, where Nf is in normal form.
% if Nf is a constant => check constant = 0, else if Nf is linear => solve else => geler
submit_ne(Norm1) :-
( nf_constant(Norm1,K)
-> \+ (K >= -1.0e-10, K =< 1.0e-10) % K =\= 0
; linear(Norm1)
-> 'solve_=\\='(Norm1)
; term_variables(Norm1,Vs),
geler(Vs,nf_r:resubmit_ne(Norm1))
).
% linear(A)
%
% succeeds when A is linear: all elements are of the form v(_,[]) or v(_,[X^1])
linear([]).
linear(v(_,Ps)) :- linear_ps(Ps).
linear([A|As]) :-
linear(A),
linear(As).
% linear_ps(A)
%
% Succeeds when A = V^1 with V a variable.
% This reflects the linearity of v(_,A).
linear_ps([]).
linear_ps([V^1]) :- var(V). % excludes sin(_), ...
%
% Goal delays until Term gets linear.
% At this time, Var will be bound to the normalform of Term.
%
:- meta_predicate wait_linear( ?, ?, :).
%
wait_linear(Term,Var,Goal) :-
nf(Term,Nf),
( linear(Nf)
-> Var = Nf,
call(Goal)
; term_variables(Nf,Vars),
geler(Vars,nf_r:wait_linear_retry(Nf,Var,Goal))
).
%
% geler clients
%
resubmit_eq(N) :-
repair(N,Norm),
submit_eq(Norm).
resubmit_lt(N) :-
repair(N,Norm),
submit_lt(Norm).
resubmit_le(N) :-
repair(N,Norm),
submit_le(Norm).
resubmit_ne(N) :-
repair(N,Norm),
submit_ne(Norm).
wait_linear_retry(Nf0,Var,Goal) :-
repair(Nf0,Nf),
( linear(Nf)
-> Var = Nf,
call(Goal)
; term_variables(Nf,Vars),
geler(Vars,nf_r:wait_linear_retry(Nf,Var,Goal))
).
% -----------------------------------------------------------------------
% nl_invertible(F,X,Y,Res)
%
% Res is the evaluation of the inverse of nonlinear function F in variable X
% where X is Y
nl_invertible(sin(X),X,Y,Res) :- Res is asin(Y).
nl_invertible(cos(X),X,Y,Res) :- Res is acos(Y).
nl_invertible(tan(X),X,Y,Res) :- Res is atan(Y).
nl_invertible(exp(B,C),X,A,Res) :-
( nf_constant(B,Kb)
-> A > 1.0e-10,
Kb > 1.0e-10,
TestKb is Kb - 1.0, % Kb =\= 1.0
\+ (TestKb >= -1.0e-10, TestKb =< 1.0e-10),
X = C, % note delayed unification
Res is log(A)/log(Kb)
; nf_constant(C,Kc),
\+ (A >= -1.0e-10, A =< 1.0e-10), % A =\= 0
Kc > 1.0e-10, % Kc > 0
X = B, % note delayed unification
Res is A**(1.0/Kc)
).
% -----------------------------------------------------------------------
% nf(Exp,Nf)
%
% Returns in Nf, the normal form of expression Exp
%
% v(A,[B^C,D^E|...]) means A*B^C*D^E*... where A is a scalar (number)
% v(A,[]) means scalar A
% variable X => 1*X^1
nf(X,Norm) :-
var(X),
!,
Norm = [v(1.0,[X^1])].
nf(X,Norm) :-
number(X),
!,
nf_number(X,Norm).
%
nf(#(Const),Norm) :-
monash_constant(Const,Value),
!,
Norm = [v(Value,[])].
%
nf(-A,Norm) :-
!,
nf(A,An),
nf_mul_factor(v(-1.0,[]),An,Norm).
nf(+A,Norm) :-
!,
nf(A,Norm).
%
nf(A+B,Norm) :-
!,
nf(A,An),
nf(B,Bn),
nf_add(An,Bn,Norm).
nf(A-B,Norm) :-
!,
nf(A,An),
nf(-B,Bn),
nf_add(An,Bn,Norm).
%
nf(A*B,Norm) :-
!,
nf(A,An),
nf(B,Bn),
nf_mul(An,Bn,Norm).
nf(A/B,Norm) :-
!,
nf(A,An),
nf(B,Bn),
nf_div(Bn,An,Norm).
% non-linear function, one argument: Term = f(Arg) equals f'(Sa1) = Skel
nf(Term,Norm) :-
nonlin_1(Term,Arg,Skel,Sa1),
!,
nf(Arg,An),
nf_nonlin_1(Skel,An,Sa1,Norm).
% non-linear function, two arguments: Term = f(A1,A2) equals f'(Sa1,Sa2) = Skel
nf(Term,Norm) :-
nonlin_2(Term,A1,A2,Skel,Sa1,Sa2),
!,
nf(A1,A1n),
nf(A2,A2n),
nf_nonlin_2(Skel,A1n,A2n,Sa1,Sa2,Norm).
%
nf(Term,_) :-
throw(type_error(nf(Term,_),1,'a numeric expression',Term)).
% nf_number(N,Res)
%
% If N is a number, N is normalized
nf_number(N,Res) :-
number(N),
( (N >= -1.0e-10, N =< 1.0e-10) % N =:= 0
-> Res = []
; Res = [v(N,[])]
).
nonlin_1(abs(X),X,abs(Y),Y).
nonlin_1(sin(X),X,sin(Y),Y).
nonlin_1(cos(X),X,cos(Y),Y).
nonlin_1(tan(X),X,tan(Y),Y).
nonlin_2(min(A,B),A,B,min(X,Y),X,Y).
nonlin_2(max(A,B),A,B,max(X,Y),X,Y).
nonlin_2(exp(A,B),A,B,exp(X,Y),X,Y).
nonlin_2(pow(A,B),A,B,exp(X,Y),X,Y). % pow->exp
nonlin_2(A^B,A,B,exp(X,Y),X,Y).
nf_nonlin_1(Skel,An,S1,Norm) :-
( nf_constant(An,S1)
-> nl_eval(Skel,Res),
nf_number(Res,Norm)
; S1 = An,
Norm = [v(1.0,[Skel^1])]).
nf_nonlin_2(Skel,A1n,A2n,S1,S2,Norm) :-
( nf_constant(A1n,S1),
nf_constant(A2n,S2)
-> nl_eval(Skel,Res),
nf_number(Res,Norm)
; Skel=exp(_,_),
nf_constant(A2n,Exp),
integerp(Exp,I)
-> nf_power(I,A1n,Norm)
; S1 = A1n,
S2 = A2n,
Norm = [v(1.0,[Skel^1])]
).
% evaluates non-linear functions in one variable where the variable is bound
nl_eval(abs(X),R) :- R is abs(X).
nl_eval(sin(X),R) :- R is sin(X).
nl_eval(cos(X),R) :- R is cos(X).
nl_eval(tan(X),R) :- R is tan(X).
% evaluates non-linear functions in two variables where both variables are
% bound
nl_eval(min(X,Y),R) :- R is min(X,Y).
nl_eval(max(X,Y),R) :- R is max(X,Y).
nl_eval(exp(X,Y),R) :- R is X**Y.
monash_constant(X,_) :-
var(X),
!,
fail.
monash_constant(p,3.14259265).
monash_constant(pi,3.14259265).
monash_constant(e,2.71828182).
monash_constant(zero,1.0e-10).
%
% check if a Nf consists of just a constant
%
nf_constant([],0.0).
nf_constant([v(K,[])],K).
% split(NF,SNF,C)
%
% splits a normalform expression NF into two parts:
% - a constant term C (which might be 0)
% - the homogene part of the expression
%
% this method depends on the polynf ordering, i.e. [] < [X^1] ...
split([],[],0.0).
split([First|T],H,I) :-
( First = v(I,[])
-> H = T
; I = 0.0,
H = [First|T]
).
% nf_add(A,B,C): merges two normalized additions into a new normalized addition
%
% a normalized addition is one where the terms are ordered, e.g. X^1 < Y^1, X^1 < X^2 etc.
% terms in the same variable with the same exponent are added,
% e.g. when A contains v(5,[X^1]) and B contains v(4,[X^1]) then C contains v(9,[X^1]).
nf_add([],Bs,Bs).
nf_add([A|As],Bs,Cs) :- nf_add(Bs,A,As,Cs).
nf_add([],A,As,Cs) :- Cs = [A|As].
nf_add([B|Bs],A,As,Cs) :-
A = v(Ka,Pa),
B = v(Kb,Pb),
compare(Rel,Pa,Pb),
nf_add_case(Rel,A,As,Cs,B,Bs,Ka,Kb,Pa).
% nf_add_case(Rel,A,As,Cs,B,Bs,Ka,Kb,Pa)
%
% merges sorted lists [A|As] and [B|Bs] into new sorted list Cs
% A = v(Ka,Pa) and B = v(Kb,_)
% Rel is the ordering relation (<, > or =) between A and B.
% when Rel is =, Ka and Kb are added to form a new scalar for Pa
nf_add_case(<,A,As,Cs,B,Bs,_,_,_) :-
Cs = [A|Rest],
nf_add(As,B,Bs,Rest).
nf_add_case(>,A,As,Cs,B,Bs,_,_,_) :-
Cs = [B|Rest],
nf_add(Bs,A,As,Rest).
nf_add_case(=,_,As,Cs,_,Bs,Ka,Kb,Pa) :-
Kc is Ka + Kb,
( (Kc >= -1.0e-10, Kc =< 1.0e-10) % Kc =:= 0.0
-> nf_add(As,Bs,Cs)
; Cs = [v(Kc,Pa)|Rest],
nf_add(As,Bs,Rest)
).
nf_mul(A,B,Res) :-
nf_length(A,0,LenA),
nf_length(B,0,LenB),
nf_mul_log(LenA,A,[],LenB,B,Res).
nf_mul_log(0,As,As,_,_,[]) :- !.
nf_mul_log(1,[A|As],As,Lb,B,R) :-
!,
nf_mul_factor_log(Lb,B,[],A,R).
nf_mul_log(2,[A1,A2|As],As,Lb,B,R) :-
!,
nf_mul_factor_log(Lb,B,[],A1,A1b),
nf_mul_factor_log(Lb,B,[],A2,A2b),
nf_add(A1b,A2b,R).
nf_mul_log(N,A0,A2,Lb,B,R) :-
P is N>>1,
Q is N-P,
nf_mul_log(P,A0,A1,Lb,B,Rp),
nf_mul_log(Q,A1,A2,Lb,B,Rq),
nf_add(Rp,Rq,R).
% nf_add_2: does the same thing as nf_add, but only has 2 elements to combine.
nf_add_2(Af,Bf,Res) :- % unfold: nf_add([Af],[Bf],Res).
Af = v(Ka,Pa),
Bf = v(Kb,Pb),
compare(Rel,Pa,Pb),
nf_add_2_case(Rel,Af,Bf,Res,Ka,Kb,Pa).
nf_add_2_case(<,Af,Bf,[Af,Bf],_,_,_).
nf_add_2_case(>,Af,Bf,[Bf,Af],_,_,_).
nf_add_2_case(=,_, _,Res,Ka,Kb,Pa) :-
Kc is Ka + Kb,
( (Kc >= -1.0e-10, Kc =< 1.0e-10) % Kc =:= 0
-> Res = []
; Res = [v(Kc,Pa)]
).
% nf_mul_k(A,B,C)
%
% C is the result of the multiplication of each element of A (of the form v(_,_)) with scalar B (which shouldn't be 0)
nf_mul_k([],_,[]).
nf_mul_k([v(I,P)|Vs],K,[v(Ki,P)|Vks]) :-
Ki is K*I,
nf_mul_k(Vs,K,Vks).
% nf_mul_factor(A,Sum,Res)
%
% multiplies each element of the list Sum with factor A which is of the form v(_,_)
% and puts the result in the sorted list Res.
nf_mul_factor(v(K,[]),Sum,Res) :-
!,
nf_mul_k(Sum,K,Res).
nf_mul_factor(F,Sum,Res) :-
nf_length(Sum,0,Len),
nf_mul_factor_log(Len,Sum,[],F,Res).
% nf_mul_factor_log(Len,[Sum|SumTail],SumTail,F,Res)
%
% multiplies each element of Sum with F and puts the result in the sorted list Res
% Len is the length of Sum
% Sum is split logarithmically each step
nf_mul_factor_log(0,As,As,_,[]) :- !.
nf_mul_factor_log(1,[A|As],As,F,[R]) :-
!,
mult(A,F,R).
nf_mul_factor_log(2,[A,B|As],As,F,Res) :-
!,
mult(A,F,Af),
mult(B,F,Bf),
nf_add_2(Af,Bf,Res).
nf_mul_factor_log(N,A0,A2,F,R) :-
P is N>>1, % P is rounded(N/2)
Q is N-P,
nf_mul_factor_log(P,A0,A1,F,Rp),
nf_mul_factor_log(Q,A1,A2,F,Rq),
nf_add(Rp,Rq,R).
% mult(A,B,C)
%
% multiplies A and B into C each of the form v(_,_)
mult(v(Ka,La),v(Kb,Lb),v(Kc,Lc)) :-
Kc is Ka*Kb,
pmerge(La,Lb,Lc).
% pmerge(A,B,C)
%
% multiplies A and B into sorted C, where each is of the form of the second argument of v(_,_)
pmerge([],Bs,Bs).
pmerge([A|As],Bs,Cs) :- pmerge(Bs,A,As,Cs).
pmerge([],A,As,Res) :- Res = [A|As].
pmerge([B|Bs],A,As,Res) :-
A = Xa^Ka,
B = Xb^Kb,
compare(R,Xa,Xb),
pmerge_case(R,A,As,Res,B,Bs,Ka,Kb,Xa).
% pmerge_case(Rel,A,As,Res,B,Bs,Ka,Kb,Xa)
%
% multiplies and sorts [A|As] with [B|Bs] into Res where each is of the form of
% the second argument of v(_,_)
%
% A is Xa^Ka and B is Xb^Kb, Rel is ordening relation between Xa and Xb
pmerge_case(<,A,As,Res,B,Bs,_,_,_) :-
Res = [A|Tail],
pmerge(As,B,Bs,Tail).
pmerge_case(>,A,As,Res,B,Bs,_,_,_) :-
Res = [B|Tail],
pmerge(Bs,A,As,Tail).
pmerge_case(=,_,As,Res,_,Bs,Ka,Kb,Xa) :-
Kc is Ka + Kb,
( Kc =:= 0
-> pmerge(As,Bs,Res)
; Res = [Xa^Kc|Tail],
pmerge(As,Bs,Tail)
).
% nf_div(Factor,In,Out)
%
% Out is the result of the division of each element in In (which is of the form v(_,_)) by Factor.
% division by zero
nf_div([],_,_) :-
!,
zero_division.
% division by v(K,P) => multiplication by v(1/K,P^-1)
nf_div([v(K,P)],Sum,Res) :-
!,
Ki is 1.0/K,
mult_exp(P,-1,Pi),
nf_mul_factor(v(Ki,Pi),Sum,Res).
nf_div(D,A,[v(1.0,[(A/D)^1])]).
% zero_division
%
% called when a division by zero is performed
zero_division :- fail. % raise_exception(_) ?
% mult_exp(In,Factor,Out)
%
% Out is the result of the multiplication of the exponents of the elements in In
% (which are of the form X^Exp by Factor.
mult_exp([],_,[]).
mult_exp([X^P|Xs],K,[X^I|Tail]) :-
I is K*P,
mult_exp(Xs,K,Tail).
%
% raise to integer powers
%
% | ?- time({(1+X+Y+Z)^15=0}). (sicstus, try with SWI)
% Timing 00:00:02.610 2.610 iterative
% Timing 00:00:00.660 0.660 binomial
nf_power(N,Sum,Norm) :-
integer(N),
compare(Rel,N,0),
( Rel = (<)
-> Pn is -N,
% nf_power_pos(Pn,Sum,Inorm),
binom(Sum,Pn,Inorm),
nf_div(Inorm,[v(1.0,[])],Norm)
; Rel = (>)
-> % nf_power_pos(N,Sum,Norm)
binom(Sum,N,Norm)
; Rel = (=)
-> % 0^0 is indeterminate but we say 1
Norm = [v(1.0,[])]
).
%
% N>0
%
% iterative method: X^N = X*(X^N-1)
nf_power_pos(1,Sum,Norm) :-
!,
Sum = Norm.
nf_power_pos(N,Sum,Norm) :-
N1 is N-1,
nf_power_pos(N1,Sum,Pn1),
nf_mul(Sum,Pn1,Norm).
%
% N>0
%
% binomial method
binom(Sum,1,Power) :-
!,
Power = Sum.
binom([],_,[]).
binom([A|Bs],N,Power) :-
( Bs = []
-> nf_power_factor(A,N,Ap),
Power = [Ap]
; Bs = [_|_]
-> factor_powers(N,A,v(1.0,[]),Pas),
sum_powers(N,Bs,[v(1.0,[])],Pbs,[]),
combine_powers(Pas,Pbs,0,N,1,[],Power)
).
combine_powers([],[],_,_,_,Pi,Pi).
combine_powers([A|As],[B|Bs],L,R,C,Pi,Po) :-
nf_mul(A,B,Ab),
nf_mul_k(Ab,C,Abc),
nf_add(Abc,Pi,Pii),
L1 is L+1,
R1 is R-1,
C1 is C*R//L1,
combine_powers(As,Bs,L1,R1,C1,Pii,Po).
nf_power_factor(v(K,P),N,v(Kn,Pn)) :-
Kn is K**N,
mult_exp(P,N,Pn).
factor_powers(0,_,Prev,[[Prev]]) :- !.
factor_powers(N,F,Prev,[[Prev]|Ps]) :-
N1 is N-1,
mult(Prev,F,Next),
factor_powers(N1,F,Next,Ps).
sum_powers(0,_,Prev,[Prev|Lt],Lt) :- !.
sum_powers(N,S,Prev,L0,Lt) :-
N1 is N-1,
nf_mul(S,Prev,Next),
sum_powers(N1,S,Next,L0,[Prev|Lt]).
% ------------------------------------------------------------------------------
repair(Sum,Norm) :-
nf_length(Sum,0,Len),
repair_log(Len,Sum,[],Norm).
repair_log(0,As,As,[]) :- !.
repair_log(1,[v(Ka,Pa)|As],As,R) :-
!,
repair_term(Ka,Pa,R).
repair_log(2,[v(Ka,Pa),v(Kb,Pb)|As],As,R) :-
!,
repair_term(Ka,Pa,Ar),
repair_term(Kb,Pb,Br),
nf_add(Ar,Br,R).
repair_log(N,A0,A2,R) :-
P is N>>1,
Q is N-P,
repair_log(P,A0,A1,Rp),
repair_log(Q,A1,A2,Rq),
nf_add(Rp,Rq,R).
repair_term(K,P,Norm) :-
length(P,Len),
repair_p_log(Len,P,[],Pr,[v(1.0,[])],Sum),
nf_mul_factor(v(K,Pr),Sum,Norm).
repair_p_log(0,Ps,Ps,[],L0,L0) :- !.
repair_p_log(1,[X^P|Ps],Ps,R,L0,L1) :-
!,
repair_p(X,P,R,L0,L1).
repair_p_log(2,[X^Px,Y^Py|Ps],Ps,R,L0,L2) :-
!,
repair_p(X,Px,Rx,L0,L1),
repair_p(Y,Py,Ry,L1,L2),
pmerge(Rx,Ry,R).
repair_p_log(N,P0,P2,R,L0,L2) :-
P is N>>1,
Q is N-P,
repair_p_log(P,P0,P1,Rp,L0,L1),
repair_p_log(Q,P1,P2,Rq,L1,L2),
pmerge(Rp,Rq,R).
repair_p(Term,P,[Term^P],L0,L0) :- var(Term).
repair_p(Term,P,[],L0,L1) :-
nonvar(Term),
repair_p_one(Term,TermN),
nf_power(P,TermN,TermNP),
nf_mul(TermNP,L0,L1).
%
% An undigested term a/b is distinguished from an
% digested one by the fact that its arguments are
% digested -> cuts after repair of args!
%
repair_p_one(Term,TermN) :-
nf_number(Term,TermN), % freq. shortcut for nf/2 case below
!.
repair_p_one(A1/A2,TermN) :-
repair(A1,A1n),
repair(A2,A2n),
!,
nf_div(A2n,A1n,TermN).
repair_p_one(Term,TermN) :-
nonlin_1(Term,Arg,Skel,Sa),
repair(Arg,An),
!,
nf_nonlin_1(Skel,An,Sa,TermN).
repair_p_one(Term,TermN) :-
nonlin_2(Term,A1,A2,Skel,Sa1,Sa2),
repair(A1,A1n),
repair(A2,A2n),
!,
nf_nonlin_2(Skel,A1n,A2n,Sa1,Sa2,TermN).
repair_p_one(Term,TermN) :-
nf(Term,TermN).
nf_length([],Li,Li).
nf_length([_|R],Li,Lo) :-
Lii is Li+1,
nf_length(R,Lii,Lo).
% ------------------------------------------------------------------------------
% nf2term(NF,Term)
%
% transforms a normal form into a readable term
% empty normal form = 0
nf2term([],0.0).
% term is first element (+ next elements)
nf2term([F|Fs],T) :-
f02t(F,T0), % first element
yfx(Fs,T0,T). % next elements
yfx([],T0,T0).
yfx([F|Fs],T0,TN) :-
fn2t(F,Ft,Op),
T1 =.. [Op,T0,Ft],
yfx(Fs,T1,TN).
% f02t(v(K,P),T)
%
% transforms the first element of the normal form (something of the form v(K,P))
% into a readable term
f02t(v(K,P),T) :-
( % just a constant
P = []
-> T = K
; TestK is K - 1.0, % K =:= 1
(TestK >= -1.0e-10, TestK =< 1.0e-10)
-> p2term(P,T)
; TestK is K + 1.0, % K =:= -1
(TestK >= -1.0e-10, TestK =< 1.0e-10)
-> T = -Pt,
p2term(P,Pt)
; T = K*Pt,
p2term(P,Pt)
).
% f02t(v(K,P),T,Op)
%
% transforms a next element of the normal form (something of the form v(K,P))
% into a readable term
fn2t(v(K,P),Term,Op) :-
( TestK is K - 1.0, % K =:= 1
(TestK >= -1.0e-10, TestK =< 1.0e-10)
-> Term = Pt,
Op = +
; TestK is K + 1.0, % K =:= -1
(TestK >= -1.0e-10, TestK =< 1.0e-10)
-> Term = Pt,
Op = -
; K < -1.0e-10 % K < 0
-> Kf is -K,
Term = Kf*Pt,
Op = -
; % K > 0
Term = K*Pt,
Op = +
),
p2term(P,Pt).
% transforms the P part in v(_,P) into a readable term
p2term([X^P|Xs],Term) :-
( Xs = []
-> pe2term(X,Xt),
exp2term(P,Xt,Term)
; Xs = [_|_]
-> Term = Xst*Xtp,
pe2term(X,Xt),
exp2term(P,Xt,Xtp),
p2term(Xs,Xst)
).
%
exp2term(1,X,X) :- !.
exp2term(-1,X,1.0/X) :- !.
exp2term(P,X,Term) :-
% Term = exp(X,Pn)
Term = X^P.
pe2term(X,Term) :-
var(X),
Term = X.
pe2term(X,Term) :-
nonvar(X),
X =.. [F|Args],
pe2term_args(Args,Argst),
Term =.. [F|Argst].
pe2term_args([],[]).
pe2term_args([A|As],[T|Ts]) :-
nf2term(A,T),
pe2term_args(As,Ts).
% transg(Goal,[OutList|OutListTail],OutListTail)
%
% puts the equalities and inequalities that are implied by the elements in Goal
% in the difference list OutList
%
% called by geler.pl for project.pl
transg(resubmit_eq(Nf)) -->
{
nf2term([],Z),
nf2term(Nf,Term)
},
[clpr:{Term=Z}].
transg(resubmit_lt(Nf)) -->
{
nf2term([],Z),
nf2term(Nf,Term)
},
[clpr:{Term<Z}].
transg(resubmit_le(Nf)) -->
{
nf2term([],Z),
nf2term(Nf,Term)
},
[clpr:{Term=<Z}].
transg(resubmit_ne(Nf)) -->
{
nf2term([],Z),
nf2term(Nf,Term)
},
[clpr:{Term=\=Z}].
transg(wait_linear_retry(Nf,Res,Goal)) -->
{
nf2term(Nf,Term)
},
[clpr:{Term=Res},Goal].
integerp(X) :-
floor(X)=:=X.
integerp(X,I) :-
floor(X)=:=X,
I is integer(X).