/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: utils.yap * * Last rev: 8/2/88 * * mods: * * comments: Some utility predicates available in yap * * * *************************************************************************/ :- system_module( '$_utils', [callable/1, current_op/3, nb_current/2, nth_instance/3, nth_instance/4, op/3, prolog/0, recordaifnot/3, recordzifnot/3, simple/1, subsumes_term/2], ['$getval_exception'/3]). :- use_system_module( '$_boot', ['$live'/0]). :- use_system_module( '$_errors', ['$do_error'/2]). /** @pred op(+ _P_,+ _T_,+ _A_) is iso Defines the operator _A_ or the list of operators _A_ with type _T_ (which must be one of `xfx`, `xfy`,`yfx`, `xf`, `yf`, `fx` or `fy`) and precedence _P_ (see appendix iv for a list of predefined operators). Note that if there is a preexisting operator with the same name and type, this operator will be discarded. Also, `,` may not be defined as an operator, and it is not allowed to have the same for an infix and a postfix operator. */ op(P,T,V) :- '$check_op'(P,T,V,op(P,T,V)), '$op'(P, T, V). % just check the operator declarations for correctness. '$check_op'(P,T,Op,G) :- ( var(P) ; var(T); var(Op)), !, '$do_error'(instantiation_error,G). '$check_op'(P,_,_,G) :- \+ integer(P), !, '$do_error'(type_error(integer,P),G). '$check_op'(P,_,_,G) :- P < 0, !, '$do_error'(domain_error(operator_priority,P),G). '$check_op'(_,T,_,G) :- \+ atom(T), !, '$do_error'(type_error(atom,T),G). '$check_op'(_,T,_,G) :- \+ '$associativity'(T), !, '$do_error'(domain_error(operator_specifier,T),G). '$check_op'(P,T,V,G) :- '$check_module_for_op'(V, G, NV), '$check_top_op'(P, T, NV, G). '$check_top_op'(_, _, [], _) :- !. '$check_top_op'(P, T, [Op|NV], G) :- !, '$check_ops'(P, T, [Op|NV], G). '$check_top_op'(P, T, V, G) :- atom(V), !, '$check_op_name'(P, T, V, G). '$check_top_op'(_P, _T, V, G) :- '$do_error'(type_error(atom,V),G). '$associativity'(xfx). '$associativity'(xfy). '$associativity'(yfx). '$associativity'(yfy). '$associativity'(xf). '$associativity'(yf). '$associativity'(fx). '$associativity'(fy). '$check_module_for_op'(MOp, G, _) :- var(MOp), !, '$do_error'(instantiation_error,G). '$check_module_for_op'(M:_V, G, _) :- var(M), !, '$do_error'(instantiation_error,G). '$check_module_for_op'(M:V, G, NV) :- atom(M), !, '$check_module_for_op'(V, G, NV). '$check_module_for_op'(M:_V, G, _) :- !, '$do_error'(type_error(atom,M),G). '$check_module_for_op'(V, _G, V). '$check_ops'(_P, _T, [], _G) :- !. '$check_ops'(P, T, [Op|NV], G) :- !, ( var(NV) -> '$do_error'(instantiation_error,G) ; '$check_module_for_op'(Op, G, NOp), '$check_op_name'(P, T, NOp, G), '$check_ops'(P, T, NV, G) ). '$check_ops'(_P, _T, Ops, G) :- '$do_error'(type_error(list,Ops),G). '$check_op_name'(_,_,V,G) :- var(V), !, '$do_error'(instantiation_error,G). '$check_op_name'(_,_,',',G) :- !, '$do_error'(permission_error(modify,operator,','),G). '$check_op_name'(_,_,'[]',G) :- T \= yf, T\= xf, !, '$do_error'(permission_error(create,operator,'[]'),G). '$check_op_name'(_,_,'{}',G) :- T \= yf, T\= xf, !, '$do_error'(permission_error(create,operator,'{}'),G). '$check_op_name'(P,T,'|',G) :- ( integer(P), P < 1001, P > 0 ; atom_codes(T,[_,_]) ), !, '$do_error'(permission_error(create,operator,'|'),G). '$check_op_name'(_,_,V,_) :- atom(V), !. '$check_op_name'(_,_,A,G) :- '$do_error'(type_error(atom,A),G). '$op'(P, T, ML) :- strip_module(ML, M, [A|As]), !, '$opl'(P, T, M, [A|As]). '$op'(P, T, A) :- '$op2'(P,T,A). '$opl'(_P, _T, _, []). '$opl'(P, T, M, [A|As]) :- '$op2'(P, T, M:A), '$opl'(P, T, M, As). '$op2'(P,T,A) :- atom(A), !, '$opdec'(P,T,A,prolog). '$op2'(P,T,A) :- strip_module(A,M,N), '$opdec'(P,T,N,M). /** @pred current_op( _P_, _T_, _F_) is iso Defines the relation: _P_ is a currently defined operator of type _T_ and precedence _P_. */ current_op(X,Y,V) :- var(V), !, '$current_module'(M), '$do_current_op'(X,Y,V,M). current_op(X,Y,M:Z) :- !, '$current_opm'(X,Y,Z,M). current_op(X,Y,Z) :- '$current_module'(M), '$do_current_op'(X,Y,Z,M). '$current_opm'(X,Y,Z,M) :- nonvar(Y), \+ '$associativity'(Y), '$do_error'(domain_error(operator_specifier,Y),current_op(X,Y,M:Z)). '$current_opm'(X,Y,Z,M) :- var(Z), !, '$do_current_op'(X,Y,Z,M). '$current_opm'(X,Y,M:Z,_) :- !, '$current_opm'(X,Y,Z,M). '$current_opm'(X,Y,Z,M) :- '$do_current_op'(X,Y,Z,M). '$do_current_op'(X,Y,Z,M) :- nonvar(Y), \+ '$associativity'(Y), '$do_error'(domain_error(operator_specifier,Y),current_op(X,Y,M:Z)). '$do_current_op'(X,Y,Z,M) :- atom(Z), !, '$current_atom_op'(Z, M1, Prefix, Infix, Posfix), ( M1 = prolog -> true ; M1 = M ), ( '$get_prefix'(Prefix, X, Y) ; '$get_infix'(Infix, X, Y) ; '$get_posfix'(Posfix, X, Y) ). '$do_current_op'(X,Y,Z,M) :- '$current_op'(Z, M1, Prefix, Infix, Posfix), ( M1 = prolog -> true ; M1 = M ), ( '$get_prefix'(Prefix, X, Y) ; '$get_infix'(Infix, X, Y) ; '$get_posfix'(Posfix, X, Y) ). '$get_prefix'(Prefix, X, Y) :- Prefix > 0, X is Prefix /\ 0xfff, ( 0x2000 /\ Prefix =:= 0x2000 -> Y = fx ; Y = fy ). '$get_infix'(Infix, X, Y) :- Infix > 0, X is Infix /\ 0xfff, ( 0x3000 /\ Infix =:= 0x3000 -> Y = xfx ; 0x1000 /\ Infix =:= 0x1000 -> Y = xfy ; Y = yfx ). '$get_posfix'(Posfix, X, Y) :- Posfix > 0, X is Posfix /\ 0xfff, ( 0x1000 /\ Posfix =:= 0x1000 -> Y = xf ; Y = yf ). prolog :- '$live'. %%% current .... /** @pred callable( _T_) is iso Checks whether _T_ is a callable term, that is, an atom or a compound term. */ callable(A) :- ( var(A) -> fail ; number(A) -> fail ; true ). /** @pred simple( _T_) Checks whether _T_ is unbound, an atom, or a number. */ simple(V) :- var(V), !. simple(A) :- atom(A), !. simple(N) :- number(N). /** @pred nth_instance(? _Key_,? _Index_,? _R_) Fetches the _Index_nth entry in the internal database under the key _Key_. Entries are numbered from one. If the key _Key_ or the _Index_ are bound, a reference is unified with _R_. Otherwise, the reference _R_ must be given, and YAP will find the matching key and index. */ nth_instance(Key,Index,Ref) :- nonvar(Key), var(Index), var(Ref), !, recorded(Key,_,Ref), '$nth_instance'(_,Index,Ref). nth_instance(Key,Index,Ref) :- '$nth_instance'(Key,Index,Ref). /** @pred nth_instance(? _Key_,? _Index_, _T_,? _R_) Fetches the _Index_nth entry in the internal database under the key _Key_. Entries are numbered from one. If the key _Key_ or the _Index_ are bound, a reference is unified with _R_. Otherwise, the reference _R_ must be given, and YAP will find the matching key and index. */ nth_instance(Key,Index,T,Ref) :- nonvar(Key), var(Index), var(Ref), !, recorded(Key,T,Ref), '$nth_instance'(_,Index,Ref). nth_instance(Key,Index,T,Ref) :- '$nth_instance'(Key,Index,Ref), instance(Ref,T). /** @pred nb_current(? _Name_, ? _Value_) Enumerate all defined variables with their value. The order of enumeration is undefined. */ /** @pred nb_current(? _Name_,? _Value_) Enumerate all defined variables with their value. The order of enumeration is undefined. */ nb_current(GlobalVariable, Val) :- '$nb_current'(GlobalVariable), '$nb_getval'(GlobalVariable, Val, _). '$getval_exception'(GlobalVariable, _Val, Caller) :- user:exception(undefined_global_variable, GlobalVariable, Action), !, ( Action == fail -> fail ; Action == retry -> true ; Action == error -> '$do_error'(existence_error(variable, GlobalVariable),Caller) ; '$do_error'(type_error(atom, Action),Caller) ). /** @pred subsumes_term(? _Subsumer_, ? _Subsumed_) Succeed if _Submuser_ subsumes _Subsuned_ but does not bind any variable in _Subsumer_. */ subsumes_term(A,B) :- \+ \+ terms:subsumes(A,B). term_string( T, S, Opts) :- var( T ), !, memory_file:open_mem_read_stream( S, Stream ), read_term( Stream, T, Opts ), close( Stream ). term_string( T, S, _Opts) :- format(string(S), '~q.~n', [T]).