/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: arith.yap * * Last rev: * * mods: * * comments: arithmetical optimization * * * *************************************************************************/ % the default mode is on :- system_module( '$_arith', [compile_expressions/0, expand_exprs/2, plus/3, succ/2], ['$c_built_in'/3]). :- private( [do_c_built_in/3, do_c_built_metacall/3, expand_expr/3, expand_expr/5, expand_expr/6] ). :- use_system_module( '$_errors', ['$do_error'/2]). :- use_system_module( '$_modules', ['$clean_cuts'/2]). /** @defgroup CompilerAnalysis Internal Clause Rewriting @ingroup YAPCompilerSettings YAP supports several clause optimisation mechanisms, that are designed to improve execution of arithmetic and term construction built-ins. In other words, during the compilation process a clause is rewritten twice: 1. first, perform user-defined goal_expansion as described in the predicates goal_expansion/1 and goal_expansion/2. 2. Perform expansion of some built-ins like: + pruning operators, like ->/2 and *->/2 + arithmetic, including early evaluation of constant expressions + specialise versions for some built-ins, if we are aware of the run-time execution mode The user has some control over this process, through some built-ins and through execution flsgs. */ %% @{ /** @pred expand_exprs(- _O_,+ _N_) Control term expansion during compilation. Enables low-level optimizations. It reports the current state by unifying _O_ with the previous state. It then puts YAP in state _N_ (`on` or `off`)/ _On_ is equivalent to compile_expressions/0 and `off` is equivalent to do_not_compile_expressions/0. This predicate is useful when debugging, to ensure execution close to the original source. */ expand_exprs(Old,New) :- (get_value('$c_arith',true) -> Old = on ; Old = off ), '$set_arith_expan'(New). '$set_arith_expan'(on) :- set_value('$c_arith',true). '$set_arith_expan'(off) :- set_value('$c_arith',[]). /** @pred compile_expressions After a call to this predicate, arithmetical expressions will be compiled. (see example below). This is the default behavior. */ compile_expressions :- set_value('$c_arith',true). /** @pred do_not_compile_expressions After a call to this predicate, arithmetical expressions will not be compiled. ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ?- source, do_not_compile_expressions. yes ?- [user]. | p(X) :- X is 2 * (3 + 8). | :- end_of_file. ?- compile_expressions. yes ?- [user]. | q(X) :- X is 2 * (3 + 8). | :- end_of_file. :- listing. p(A):- A is 2 * (3 + 8). q(A):- A is 22. ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ w*/ do_not_compile_expressions :- set_value('$c_arith',[]). '$c_built_in'(IN, M, H, OUT) :- get_value('$c_arith',true), !, do_c_built_in(IN, M, H, OUT). '$c_built_in'(IN, _, _H, IN). do_c_built_in(G, M, H, OUT) :- var(G), !, do_c_built_metacall(G, M, H, OUT). do_c_built_in(Mod:G, _, H, OUT) :- '$yap_strip_module'(Mod:G, M1, G1), var(G1), !, do_c_built_metacall(G1, M1, H, OUT). do_c_built_in('C'(A,B,C), _, _, (A=[B|C])) :- !. do_c_built_in('$do_error'( Error, Goal), M, Head, (clause_location(Call, Caller), strip_module(M:Goal,M1,NGoal), throw(error(Error, [[g|g(M1:NGoal)],[p|Call],[e|Caller],[h|g(Head)]] ) ) ) ) :- !. do_c_built_in(X is Y, M, H, P) :- primitive(X), !, do_c_built_in(X =:= Y, M, H, P). do_c_built_in(X is Y, M, H, (P,A=X)) :- nonvar(X), !, do_c_built_in(A is Y, M, H, P). do_c_built_in(X is Y, _, _, P) :- nonvar(Y), % Don't rewrite variables !, ( number(Y) -> P = ( X = Y); % This case reduces to an unification expand_expr(Y, P0, X0), '$drop_is'(X0, X, P0, P) ). do_c_built_in(phrase(NT,Xs), Mod, H, NTXsNil) :- '$_arith':do_c_built_in(phrase(NT,Xs,[]), Mod, H, NTXsNil). do_c_built_in(phrase(NT,Xs0,Xs), Mod, _, NewGoal) :- '$c_built_in_phrase'(NT, Xs0, Xs, Mod, NewGoal ). do_c_built_in(Comp0, _, _, R) :- % now, do it for comparisons '$compop'(Comp0, Op, E, F), !, '$compop'(Comp, Op, U, V), expand_expr(E, P, U), expand_expr(F, Q, V), '$do_and'(P, Q, R0), '$do_and'(R0, Comp, R). do_c_built_in(P, _M, _H, P). do_c_built_metacall(G1, Mod, _, '$execute_wo_mod'(G1,Mod)) :- var(Mod), !. do_c_built_metacall(G1, Mod, _, '$execute_in_mod'(G1,Mod)) :- atom(Mod), !. do_c_built_metacall(G1, Mod, _, call(Mod:G1)). '$do_and'(true, P, P) :- !. '$do_and'(P, true, P) :- !. '$do_and'(P, Q, (P,Q)). % V is the result of the simplification, % X the result of the initial expression % and the last argument is how we are writing this result '$drop_is'(V, V1, P0, G) :- var(V), !, % usual case V = V1, P0 = G. '$drop_is'(V, X, P0, P) :- % atoms '$do_and'(P0, X is V, P). % Table of arithmetic comparisons '$compop'(X < Y, < , X, Y). '$compop'(X > Y, > , X, Y). '$compop'(X=< Y,=< , X, Y). '$compop'(X >=Y, >=, X, Y). '$compop'(X=:=Y,=:=, X, Y). '$compop'(X=\=Y,=\=, X, Y). '$composed_built_in'(V) :- var(V), !, fail. '$composed_built_in'(('$current_choice_point'(_),NG,'$$cut_by'(_))) :- !, '$composed_built_in'(NG). '$composed_built_in'((_,_)). '$composed_built_in'((_;_)). '$composed_built_in'((_|_)). '$composed_built_in'((_->_)). '$composed_built_in'(_:G) :- '$composed_built_in'(G). '$composed_built_in'(\+G) :- '$composed_built_in'(G). '$composed_built_in'(not(G)) :- '$composed_built_in'(G). % expanding an expression: % first argument is the expression not expanded, % second argument the expanded expression % third argument unifies with the result from the expression expand_expr(V, true, V) :- var(V), !. expand_expr([T], E, V) :- !, expand_expr(T, E, V). expand_expr(String, _E, V) :- string( String ), !, string_codes(String, [V]). expand_expr(A, true, A) :- atomic(A), !. expand_expr(T, E, V) :- T =.. [O, A], !, expand_expr(A, Q, X), expand_expr(O, X, V, Q, E). expand_expr(T, E, V) :- T =.. [O, A, B], !, expand_expr(A, Q, X), expand_expr(B, R, Y), expand_expr(O, X, Y, V, Q, S), '$do_and'(R, S, E). % expanding an expression of the form: % O is Op(X), % after having expanded into Q % and giving as result P (the last argument) expand_expr(Op, X, O, Q, Q) :- number(X), catch(is( O, Op, X),_,fail), !. % do not do error handling at compile time expand_expr(Op, X, O, Q, P) :- '$unary_op_as_integer'(Op,IOp), '$do_and'(Q, is( O, IOp, X), P). % expanding an expression of the form: % O is Op(X,Y), % after having expanded into Q % and giving as result P (the last argument) % included is some optimization for: % incrementing and decrementing, % the elementar arithmetic operations [+,-,*,//] expand_expr(Op, X, Y, O, Q, Q) :- number(X), number(Y), catch(is( O, Op, X, Y),_,fail), !. expand_expr(+, X, Y, O, Q, P) :- !, '$preprocess_args_for_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$plus'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(-, X, Y, O, Q, P) :- var(X), number(Y), Z is -Y, !, expand_expr(+, Z, X, O, Q, P). expand_expr(-, X, Y, O, Q, P) :- !, '$preprocess_args_for_non_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$minus'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(*, X, Y, O, Q, P) :- !, '$preprocess_args_for_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$times'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(//, X, Y, O, Q, P) :- nonvar(Y), Y == 0, !, '$binary_op_as_integer'(//,IOp), '$do_and'(Q, is(O,IOp,X,Y), P). expand_expr(//, X, Y, O, Q, P) :- !, '$preprocess_args_for_non_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$div'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(/\, X, Y, O, Q, P) :- !, '$preprocess_args_for_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$and'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(\/, X, Y, O, Q, P) :- !, '$preprocess_args_for_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$or'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(<<, X, Y, O, Q, P) :- var(X), number(Y), Y < 0, Z is -Y, !, expand_expr(>>, X, Z, O, Q, P). expand_expr(<<, X, Y, O, Q, P) :- !, '$preprocess_args_for_non_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$sll'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(>>, X, Y, O, Q, P) :- var(X), number(Y), Y < 0, Z is -Y, !, expand_expr(<<, X, Z, O, Q, P). expand_expr(>>, X, Y, O, Q, P) :- !, '$preprocess_args_for_non_commutative'(X, Y, X1, Y1, E), '$do_and'(E, '$slr'(X1,Y1,O), F), '$do_and'(Q, F, P). expand_expr(Op, X, Y, O, Q, P) :- '$binary_op_as_integer'(Op,IOp), '$do_and'(Q, is(O,IOp,X,Y), P). '$preprocess_args_for_commutative'(X, Y, X, Y, true) :- var(X), var(Y), !. '$preprocess_args_for_commutative'(X, Y, X, Y, true) :- var(X), integer(Y), \+ '$bignum'(Y), !. '$preprocess_args_for_commutative'(X, Y, X, Z, Z = Y) :- var(X), !. '$preprocess_args_for_commutative'(X, Y, Y, X, true) :- integer(X), \+ '$bignum'(X), var(Y), !. '$preprocess_args_for_commutative'(X, Y, Z, X, Z = Y) :- integer(X), \+ '$bignum'(X), !. '$preprocess_args_for_commutative'(X, Y, Z, W, E) :- '$do_and'(Z = X, Y = W, E). '$preprocess_args_for_non_commutative'(X, Y, X, Y, true) :- var(X), var(Y), !. '$preprocess_args_for_non_commutative'(X, Y, X, Y, true) :- var(X), integer(Y), \+ '$bignum'(Y), !. '$preprocess_args_for_non_commutative'(X, Y, X, Z, Z = Y) :- var(X), !. '$preprocess_args_for_non_commutative'(X, Y, X, Y, true) :- integer(X), \+ '$bignum'(X), var(Y), !. '$preprocess_args_for_non_commutative'(X, Y, X, Z, Z = Y) :- integer(X), \+ '$bignum'(X), !. '$preprocess_args_for_non_commutative'(X, Y, Z, W, E) :- '$do_and'(Z = X, Y = W, E). '$goal_expansion_allowed'(phrase(NT,_Xs0,_Xs), Mod). %% contains_illegal_dcgnt(+Term) is semidet. % % True if Term contains a non-terminal we cannot deal with using % goal-expansion. The test is too general approximation, but safe. '$contains_illegal_dcgnt'(NT) :- functor(NT, _, A), between(1, A, I), arg(I, NT, AI), nonvar(AI), ( AI = ! ; AI = phrase(_,_,_) ), !. % write(contains_illegal_nt(NT)), % JW: we do not want to write % nl. '$harmless_dcgexception'(instantiation_error). % ex: phrase(([1],x:X,[3]),L) '$harmless_dcgexception'(type_error(callable,_)). % ex: phrase(27,L) :- set_value('$c_arith',true). /** @} */