Spaces
Explore
Communities
Statistics
Reports
Cluster
Status
Help
Logic_Programming 2019-04-02 08.22 pair #434324621
details
property
value
status
complete
benchmark
d.pl
ran by
Akihisa Yamada
cpu timeout
1200 seconds
wallclock timeout
300 seconds
memory limit
137438953472 bytes
execution host
n111.star.cs.uiowa.edu
space
SGST06
run statistics
property
value
solver
AProVE
configuration
standard
runtime (wallclock)
3.66337 seconds
cpu usage
10.8987
user time
10.3286
system time
0.570132
max virtual memory
1.9877672E7
max residence set size
1312776.0
stage attributes
key
value
starexec-result
YES
output
10.22/3.54 YES 10.61/3.58 proof of /export/starexec/sandbox/benchmark/theBenchmark.pl 10.61/3.58 # AProVE Commit ID: 48fb2092695e11cc9f56e44b17a92a5f88ffb256 marcel 20180622 unpublished dirty 10.61/3.58 10.61/3.58 10.61/3.58 Left Termination of the query pattern 10.61/3.58 10.61/3.58 d(g,g,a) 10.61/3.58 10.61/3.58 w.r.t. the given Prolog program could successfully be proven: 10.61/3.58 10.61/3.58 (0) Prolog 10.61/3.58 (1) PrologToPiTRSProof [SOUND, 0 ms] 10.61/3.58 (2) PiTRS 10.61/3.58 (3) DependencyPairsProof [EQUIVALENT, 5 ms] 10.61/3.58 (4) PiDP 10.61/3.58 (5) DependencyGraphProof [EQUIVALENT, 1 ms] 10.61/3.58 (6) AND 10.61/3.58 (7) PiDP 10.61/3.58 (8) UsableRulesProof [EQUIVALENT, 0 ms] 10.61/3.58 (9) PiDP 10.61/3.58 (10) PiDPToQDPProof [EQUIVALENT, 0 ms] 10.61/3.58 (11) QDP 10.61/3.58 (12) QDPSizeChangeProof [EQUIVALENT, 0 ms] 10.61/3.58 (13) YES 10.61/3.58 (14) PiDP 10.61/3.58 (15) PiDPToQDPProof [SOUND, 0 ms] 10.61/3.58 (16) QDP 10.61/3.58 (17) QDPQMonotonicMRRProof [EQUIVALENT, 122 ms] 10.61/3.58 (18) QDP 10.61/3.58 (19) QDPQMonotonicMRRProof [EQUIVALENT, 44 ms] 10.61/3.58 (20) QDP 10.61/3.58 (21) QDPSizeChangeProof [EQUIVALENT, 0 ms] 10.61/3.58 (22) YES 10.61/3.58 10.61/3.58 10.61/3.58 ---------------------------------------- 10.61/3.58 10.61/3.58 (0) 10.61/3.58 Obligation: 10.61/3.58 Clauses: 10.61/3.58 10.61/3.58 d(X, X, 1). 10.61/3.58 d(T, X1, 0) :- isnumber(T). 10.61/3.58 d(times(U, V), X, +(times(B, U), times(A, V))) :- ','(d(U, X, A), d(V, X, B)). 10.61/3.58 d(div(U, V), X, W) :- d(times(U, power(V, p(0))), X, W). 10.61/3.58 d(power(U, V), X, times(V, times(W, power(U, p(V))))) :- ','(isnumber(V), d(U, X, W)). 10.61/3.58 isnumber(0). 10.61/3.58 isnumber(s(X)) :- isnumber(X). 10.61/3.58 isnumber(p(X)) :- isnumber(X). 10.61/3.58 10.61/3.58 10.61/3.58 Query: d(g,g,a) 10.61/3.58 ---------------------------------------- 10.61/3.58 10.61/3.58 (1) PrologToPiTRSProof (SOUND) 10.61/3.58 We use the technique of [TOCL09]. With regard to the inferred argument filtering the predicates were used in the following modes: 10.61/3.58 10.61/3.58 d_in_3: (b,b,f) 10.61/3.58 10.61/3.58 isnumber_in_1: (b) 10.61/3.58 10.61/3.58 Transforming Prolog into the following Term Rewriting System: 10.61/3.58 10.61/3.58 Pi-finite rewrite system: 10.61/3.58 The TRS R consists of the following rules: 10.61/3.58 10.61/3.58 d_in_gga(X, X, 1) -> d_out_gga(X, X, 1) 10.61/3.58 d_in_gga(T, X1, 0) -> U1_gga(T, X1, isnumber_in_g(T)) 10.61/3.58 isnumber_in_g(0) -> isnumber_out_g(0) 10.61/3.58 isnumber_in_g(s(X)) -> U7_g(X, isnumber_in_g(X)) 10.61/3.58 isnumber_in_g(p(X)) -> U8_g(X, isnumber_in_g(X)) 10.61/3.58 U8_g(X, isnumber_out_g(X)) -> isnumber_out_g(p(X)) 10.61/3.58 U7_g(X, isnumber_out_g(X)) -> isnumber_out_g(s(X)) 10.61/3.58 U1_gga(T, X1, isnumber_out_g(T)) -> d_out_gga(T, X1, 0) 10.61/3.58 d_in_gga(times(U, V), X, +(times(B, U), times(A, V))) -> U2_gga(U, V, X, B, A, d_in_gga(U, X, A)) 10.61/3.58 d_in_gga(div(U, V), X, W) -> U4_gga(U, V, X, W, d_in_gga(times(U, power(V, p(0))), X, W)) 10.61/3.58 d_in_gga(power(U, V), X, times(V, times(W, power(U, p(V))))) -> U5_gga(U, V, X, W, isnumber_in_g(V)) 10.61/3.58 U5_gga(U, V, X, W, isnumber_out_g(V)) -> U6_gga(U, V, X, W, d_in_gga(U, X, W)) 10.61/3.58 U6_gga(U, V, X, W, d_out_gga(U, X, W)) -> d_out_gga(power(U, V), X, times(V, times(W, power(U, p(V))))) 10.61/3.58 U4_gga(U, V, X, W, d_out_gga(times(U, power(V, p(0))), X, W)) -> d_out_gga(div(U, V), X, W) 10.61/3.58 U2_gga(U, V, X, B, A, d_out_gga(U, X, A)) -> U3_gga(U, V, X, B, A, d_in_gga(V, X, B)) 10.61/3.58 U3_gga(U, V, X, B, A, d_out_gga(V, X, B)) -> d_out_gga(times(U, V), X, +(times(B, U), times(A, V))) 10.61/3.58 10.61/3.58 The argument filtering Pi contains the following mapping: 10.61/3.58 d_in_gga(x1, x2, x3) = d_in_gga(x1, x2) 10.61/3.58 10.61/3.58 d_out_gga(x1, x2, x3) = d_out_gga(x1, x2, x3) 10.61/3.58 10.61/3.58 U1_gga(x1, x2, x3) = U1_gga(x1, x2, x3) 10.61/3.58 10.61/3.58 isnumber_in_g(x1) = isnumber_in_g(x1) 10.61/3.58 10.61/3.58 0 = 0 10.61/3.58 10.61/3.58 isnumber_out_g(x1) = isnumber_out_g(x1) 10.61/3.58 10.61/3.58 s(x1) = s(x1) 10.61/3.58 10.61/3.58 U7_g(x1, x2) = U7_g(x1, x2)
popout
output may be truncated. 'popout' for the full output.
job log
popout
actions
all output
return to Logic_Programming 2019-04-02 08.22