- : unit = () h : heuristic = - : unit = () APPLY CRITERIA (Marked dependency pairs) TRS termination of: [1] active(nats) -> mark(adx(zeros)) [2] active(zeros) -> mark(cons(0,zeros)) [3] active(incr(cons(X,Y))) -> mark(cons(s(X),incr(Y))) [4] active(adx(cons(X,Y))) -> mark(incr(cons(X,adx(Y)))) [5] active(hd(cons(X,Y))) -> mark(X) [6] active(tl(cons(X,Y))) -> mark(Y) [7] mark(nats) -> active(nats) [8] mark(adx(X)) -> active(adx(mark(X))) [9] mark(zeros) -> active(zeros) [10] mark(cons(X1,X2)) -> active(cons(X1,X2)) [11] mark(0) -> active(0) [12] mark(incr(X)) -> active(incr(mark(X))) [13] mark(s(X)) -> active(s(X)) [14] mark(hd(X)) -> active(hd(mark(X))) [15] mark(tl(X)) -> active(tl(mark(X))) [16] adx(mark(X)) -> adx(X) [17] adx(active(X)) -> adx(X) [18] cons(mark(X1),X2) -> cons(X1,X2) [19] cons(X1,mark(X2)) -> cons(X1,X2) [20] cons(active(X1),X2) -> cons(X1,X2) [21] cons(X1,active(X2)) -> cons(X1,X2) [22] incr(mark(X)) -> incr(X) [23] incr(active(X)) -> incr(X) [24] s(mark(X)) -> s(X) [25] s(active(X)) -> s(X) [26] hd(mark(X)) -> hd(X) [27] hd(active(X)) -> hd(X) [28] tl(mark(X)) -> tl(X) [29] tl(active(X)) -> tl(X) Sub problem: guided: DP termination of: END GUIDED APPLY CRITERIA (Graph splitting) Found 7 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } { --> --> --> --> } { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } { --> --> --> --> } { --> --> --> --> } { --> --> --> --> } { --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(nats) >= Marked_active(nats) ; Marked_mark(cons(X1,X2)) >= Marked_active(cons(X1,X2)) ; Marked_mark(s(X)) >= Marked_active(s(X)) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(hd(X)) >= Marked_mark(X) ; Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(nats) >= Marked_mark(adx(zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(hd(cons(X,Y))) >= Marked_mark(X) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(nats) > Marked_active(nats) ; } { Marked_mark(cons(X1,X2)) > Marked_active(cons(X1,X2)) ; } { Marked_mark(s(X)) > Marked_active(s(X)) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(hd(X)) > Marked_mark(X) ; } { Marked_mark(hd(X)) > Marked_active(hd(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(nats) > Marked_mark(adx(zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(hd(cons(X,Y))) > Marked_mark(X) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(nats) >= Marked_active(nats) constraint: Marked_mark(cons(X1,X2)) >= Marked_active(cons(X1,X2)) constraint: Marked_mark(s(X)) >= Marked_active(s(X)) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(hd(X)) >= Marked_mark(X) constraint: Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(nats) >= Marked_mark(adx(zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(hd(cons(X,Y))) >= Marked_mark(X) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_adx(mark(X)) >= Marked_adx(X) ; Marked_adx(active(X)) >= Marked_adx(X) ; } + Disjunctions:{ { Marked_adx(mark(X)) > Marked_adx(X) ; } { Marked_adx(active(X)) > Marked_adx(X) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_adx(mark(X)) >= Marked_adx(X) constraint: Marked_adx(active(X)) >= Marked_adx(X) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_cons(mark(X1),X2) >= Marked_cons(X1,X2) ; Marked_cons(active(X1),X2) >= Marked_cons(X1,X2) ; Marked_cons(X1,mark(X2)) >= Marked_cons(X1,X2) ; Marked_cons(X1,active(X2)) >= Marked_cons(X1,X2) ; } + Disjunctions:{ { Marked_cons(mark(X1),X2) > Marked_cons(X1,X2) ; } { Marked_cons(active(X1),X2) > Marked_cons(X1,X2) ; } { Marked_cons(X1,mark(X2)) > Marked_cons(X1,X2) ; } { Marked_cons(X1,active(X2)) > Marked_cons(X1,X2) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_cons(mark(X1),X2) >= Marked_cons(X1,X2) constraint: Marked_cons(active(X1),X2) >= Marked_cons(X1,X2) constraint: Marked_cons(X1,mark(X2)) >= Marked_cons(X1,X2) constraint: Marked_cons(X1,active(X2)) >= Marked_cons(X1,X2) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_incr(mark(X)) >= Marked_incr(X) ; Marked_incr(active(X)) >= Marked_incr(X) ; } + Disjunctions:{ { Marked_incr(mark(X)) > Marked_incr(X) ; } { Marked_incr(active(X)) > Marked_incr(X) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_incr(mark(X)) >= Marked_incr(X) constraint: Marked_incr(active(X)) >= Marked_incr(X) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_s(mark(X)) >= Marked_s(X) ; Marked_s(active(X)) >= Marked_s(X) ; } + Disjunctions:{ { Marked_s(mark(X)) > Marked_s(X) ; } { Marked_s(active(X)) > Marked_s(X) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_s(mark(X)) >= Marked_s(X) constraint: Marked_s(active(X)) >= Marked_s(X) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_hd(mark(X)) >= Marked_hd(X) ; Marked_hd(active(X)) >= Marked_hd(X) ; } + Disjunctions:{ { Marked_hd(mark(X)) > Marked_hd(X) ; } { Marked_hd(active(X)) > Marked_hd(X) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_hd(mark(X)) >= Marked_hd(X) constraint: Marked_hd(active(X)) >= Marked_hd(X) APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_tl(mark(X)) >= Marked_tl(X) ; Marked_tl(active(X)) >= Marked_tl(X) ; } + Disjunctions:{ { Marked_tl(mark(X)) > Marked_tl(X) ; } { Marked_tl(active(X)) > Marked_tl(X) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_tl(mark(X)) >= Marked_tl(X) constraint: Marked_tl(active(X)) >= Marked_tl(X) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(nats) >= Marked_active(nats) ; Marked_mark(s(X)) >= Marked_active(s(X)) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(hd(X)) >= Marked_mark(X) ; Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(nats) >= Marked_mark(adx(zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(hd(cons(X,Y))) >= Marked_mark(X) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(nats) > Marked_active(nats) ; } { Marked_mark(s(X)) > Marked_active(s(X)) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(hd(X)) > Marked_mark(X) ; } { Marked_mark(hd(X)) > Marked_active(hd(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(nats) > Marked_mark(adx(zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(hd(cons(X,Y))) > Marked_mark(X) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(nats) >= Marked_active(nats) constraint: Marked_mark(s(X)) >= Marked_active(s(X)) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(hd(X)) >= Marked_mark(X) constraint: Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(nats) >= Marked_mark(adx(zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(hd(cons(X,Y))) >= Marked_mark(X) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(nats) >= Marked_active(nats) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(hd(X)) >= Marked_mark(X) ; Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(nats) >= Marked_mark(adx(zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(hd(cons(X,Y))) >= Marked_mark(X) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(nats) > Marked_active(nats) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(hd(X)) > Marked_mark(X) ; } { Marked_mark(hd(X)) > Marked_active(hd(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(nats) > Marked_mark(adx(zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(hd(cons(X,Y))) > Marked_mark(X) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(nats) >= Marked_active(nats) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(hd(X)) >= Marked_mark(X) constraint: Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(nats) >= Marked_mark(adx(zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(hd(cons(X,Y))) >= Marked_mark(X) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(hd(X)) >= Marked_mark(X) ; Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(hd(cons(X,Y))) >= Marked_mark(X) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(hd(X)) > Marked_mark(X) ; } { Marked_mark(hd(X)) > Marked_active(hd(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(hd(cons(X,Y))) > Marked_mark(X) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(hd(X)) >= Marked_mark(X) constraint: Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(hd(cons(X,Y))) >= Marked_mark(X) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(hd(X)) > Marked_active(hd(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(hd(X)) >= Marked_active(hd(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(tl(X)) >= Marked_mark(X) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(tl(X)) > Marked_mark(X) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } { Marked_active(tl(cons(X,Y))) > Marked_mark(Y) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_mark(X) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) constraint: Marked_active(tl(cons(X,Y))) >= Marked_mark(Y) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_mark(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_mark(X) ; } { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_mark(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_mark(tl(X)) > Marked_active(tl(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_mark(tl(X)) >= Marked_active(tl(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(zeros) >= Marked_active(zeros) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(zeros) > Marked_active(zeros) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned === STOPING TIMER real === === STOPING TIMER virtual === No solution found for these parameters. Entering rpo_solver === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 15.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 15.000000 === === STOPING TIMER real === Sat solver returned === STOPING TIMER real === === STOPING TIMER virtual === No solution found for these parameters. === TIMER virtual : 50.000000 === trying sub matrices of size: 1 Matrix interpretation constraints generated. Search parameters: LINEAR MATRIX 3x3 (strict=1x1) ; time limit: 50.. Termination constraints generated. Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 50.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(zeros) >= Marked_active(zeros) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(zeros) >= Marked_mark(cons(0,zeros)) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(zeros) > Marked_mark(cons(0,zeros)) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned Sat solver result read === STOPING TIMER real === === STOPING TIMER virtual === constraint: mark(adx(X)) >= active(adx(mark(X))) constraint: mark(zeros) >= active(zeros) constraint: mark(nats) >= active(nats) constraint: mark(cons(X1,X2)) >= active(cons(X1,X2)) constraint: mark(0) >= active(0) constraint: mark(s(X)) >= active(s(X)) constraint: mark(incr(X)) >= active(incr(mark(X))) constraint: mark(hd(X)) >= active(hd(mark(X))) constraint: mark(tl(X)) >= active(tl(mark(X))) constraint: adx(mark(X)) >= adx(X) constraint: adx(active(X)) >= adx(X) constraint: active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) constraint: active(zeros) >= mark(cons(0,zeros)) constraint: active(nats) >= mark(adx(zeros)) constraint: active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) constraint: active(hd(cons(X,Y))) >= mark(X) constraint: active(tl(cons(X,Y))) >= mark(Y) constraint: cons(mark(X1),X2) >= cons(X1,X2) constraint: cons(active(X1),X2) >= cons(X1,X2) constraint: cons(X1,mark(X2)) >= cons(X1,X2) constraint: cons(X1,active(X2)) >= cons(X1,X2) constraint: s(mark(X)) >= s(X) constraint: s(active(X)) >= s(X) constraint: incr(mark(X)) >= incr(X) constraint: incr(active(X)) >= incr(X) constraint: hd(mark(X)) >= hd(X) constraint: hd(active(X)) >= hd(X) constraint: tl(mark(X)) >= tl(X) constraint: tl(active(X)) >= tl(X) constraint: Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) constraint: Marked_mark(incr(X)) >= Marked_mark(X) constraint: Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) constraint: Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) constraint: Marked_active(zeros) >= Marked_mark(cons(0,zeros)) constraint: Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) APPLY CRITERIA (Graph splitting) Found 1 components: { --> --> --> --> --> --> --> --> --> --> --> --> --> } APPLY CRITERIA (Choosing graph) Trying to solve the following constraints: { mark(adx(X)) >= active(adx(mark(X))) ; mark(zeros) >= active(zeros) ; mark(nats) >= active(nats) ; mark(cons(X1,X2)) >= active(cons(X1,X2)) ; mark(0) >= active(0) ; mark(s(X)) >= active(s(X)) ; mark(incr(X)) >= active(incr(mark(X))) ; mark(hd(X)) >= active(hd(mark(X))) ; mark(tl(X)) >= active(tl(mark(X))) ; adx(mark(X)) >= adx(X) ; adx(active(X)) >= adx(X) ; active(adx(cons(X,Y))) >= mark(incr(cons(X,adx(Y)))) ; active(zeros) >= mark(cons(0,zeros)) ; active(nats) >= mark(adx(zeros)) ; active(incr(cons(X,Y))) >= mark(cons(s(X),incr(Y))) ; active(hd(cons(X,Y))) >= mark(X) ; active(tl(cons(X,Y))) >= mark(Y) ; cons(mark(X1),X2) >= cons(X1,X2) ; cons(active(X1),X2) >= cons(X1,X2) ; cons(X1,mark(X2)) >= cons(X1,X2) ; cons(X1,active(X2)) >= cons(X1,X2) ; s(mark(X)) >= s(X) ; s(active(X)) >= s(X) ; incr(mark(X)) >= incr(X) ; incr(active(X)) >= incr(X) ; hd(mark(X)) >= hd(X) ; hd(active(X)) >= hd(X) ; tl(mark(X)) >= tl(X) ; tl(active(X)) >= tl(X) ; Marked_mark(adx(X)) >= Marked_active(adx(mark(X))) ; Marked_mark(incr(X)) >= Marked_mark(X) ; Marked_mark(incr(X)) >= Marked_active(incr(mark(X))) ; Marked_active(adx(cons(X,Y))) >= Marked_mark(incr(cons(X,adx(Y)))) ; Marked_active(incr(cons(X,Y))) >= Marked_mark(cons(s(X),incr(Y))) ; } + Disjunctions:{ { Marked_mark(adx(X)) > Marked_active(adx(mark(X))) ; } { Marked_mark(incr(X)) > Marked_mark(X) ; } { Marked_mark(incr(X)) > Marked_active(incr(mark(X))) ; } { Marked_active(adx(cons(X,Y))) > Marked_mark(incr(cons(X,adx(Y)))) ; } { Marked_active(incr(cons(X,Y))) > Marked_mark(cons(s(X),incr(Y))) ; } } === TIMER virtual : 10.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 10.000000 === === STOPING TIMER real === Sat solver returned === STOPING TIMER real === === STOPING TIMER virtual === No solution found for these parameters. Entering rpo_solver === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 25.000000 === Search parameters: AFS type: 2 ; time limit: 25.. === STOPING TIMER virtual === === TIMER virtual : 15.000000 === Entering poly_solver Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 15.000000 === === STOPING TIMER real === Sat solver returned === STOPING TIMER real === === STOPING TIMER virtual === No solution found for these parameters. === TIMER virtual : 50.000000 === trying sub matrices of size: 1 Matrix interpretation constraints generated. Search parameters: LINEAR MATRIX 3x3 (strict=1x1) ; time limit: 50.. Termination constraints generated. Starting Sat solver initialization Calling Sat solver... === STOPING TIMER virtual === === TIMER real : 50.000000 === === STOPING TIMER real === Sat timeout reached === STOPING TIMER virtual === No solution found for these parameters. No solution found for these constraints. APPLY CRITERIA (ID_CRIT) APPLY CRITERIA (Graph splitting) Found 0 components: APPLY CRITERIA (Graph splitting) Found 0 components: APPLY CRITERIA (Graph splitting) Found 0 components: APPLY CRITERIA (Graph splitting) Found 0 components: APPLY CRITERIA (Graph splitting) Found 0 components: APPLY CRITERIA (Graph splitting) Found 0 components: NOT SOLVED No proof found Cime worked for 60.776977 seconds (real time) Cime Exit Status: 0