TSTP Solution File: MGT057+1 by Bliksem---1.12
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- Process Solution
%------------------------------------------------------------------------------
% File : Bliksem---1.12
% Problem : MGT057+1 : TPTP v8.1.0. Released v2.4.0.
% Transfm : none
% Format : tptp:raw
% Command : bliksem %s
% Computer : n019.cluster.edu
% Model : x86_64 x86_64
% CPU : Intel(R) Xeon(R) CPU E5-2620 v4 2.10GHz
% Memory : 8042.1875MB
% OS : Linux 3.10.0-693.el7.x86_64
% CPULimit : 300s
% WCLimit : 0s
% DateTime : Sun Jul 17 21:57:57 EDT 2022
% Result : Theorem 0.86s 1.21s
% Output : Refutation 0.86s
% Verified :
% SZS Type : -
% Comments :
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.12 % Problem : MGT057+1 : TPTP v8.1.0. Released v2.4.0.
% 0.07/0.13 % Command : bliksem %s
% 0.12/0.34 % Computer : n019.cluster.edu
% 0.12/0.34 % Model : x86_64 x86_64
% 0.12/0.34 % CPU : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.12/0.34 % Memory : 8042.1875MB
% 0.12/0.34 % OS : Linux 3.10.0-693.el7.x86_64
% 0.12/0.34 % CPULimit : 300
% 0.12/0.34 % DateTime : Thu Jun 9 12:17:10 EDT 2022
% 0.12/0.34 % CPUTime :
% 0.86/1.21 *** allocated 10000 integers for termspace/termends
% 0.86/1.21 *** allocated 10000 integers for clauses
% 0.86/1.21 *** allocated 10000 integers for justifications
% 0.86/1.21 Bliksem 1.12
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Automatic Strategy Selection
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Clauses:
% 0.86/1.21
% 0.86/1.21 { ! smaller_or_equal( X, Y ), smaller( X, Y ), X = Y }.
% 0.86/1.21 { ! smaller( X, Y ), smaller_or_equal( X, Y ) }.
% 0.86/1.21 { ! X = Y, smaller_or_equal( X, Y ) }.
% 0.86/1.21 { ! greater_or_equal( X, Y ), greater( X, Y ), X = Y }.
% 0.86/1.21 { ! greater( X, Y ), greater_or_equal( X, Y ) }.
% 0.86/1.21 { ! X = Y, greater_or_equal( X, Y ) }.
% 0.86/1.21 { ! smaller( X, Y ), greater( Y, X ) }.
% 0.86/1.21 { ! greater( Y, X ), smaller( X, Y ) }.
% 0.86/1.21 { ! greater( X, Y ), ! greater( Y, X ) }.
% 0.86/1.21 { ! greater( X, Z ), ! greater( Z, Y ), greater( X, Y ) }.
% 0.86/1.21 { smaller( X, Y ), X = Y, greater( X, Y ) }.
% 0.86/1.21 { ! has_endowment( X ), organization( X ) }.
% 0.86/1.21 { ! has_endowment( X ), alpha1( X ) }.
% 0.86/1.21 { ! organization( X ), ! alpha1( X ), has_endowment( X ) }.
% 0.86/1.21 { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 { ! alpha2( X, skol1( X ) ), ! alpha3( X, skol1( X ) ), alpha1( X ) }.
% 0.86/1.21 { ! alpha3( X, Y ), ! greater( age( X, Y ), eta ), ! has_immunity( X, Y ) }
% 0.86/1.21 .
% 0.86/1.21 { greater( age( X, Y ), eta ), alpha3( X, Y ) }.
% 0.86/1.21 { has_immunity( X, Y ), alpha3( X, Y ) }.
% 0.86/1.21 { ! alpha2( X, Y ), ! smaller_or_equal( age( X, Y ), eta ), has_immunity( X
% 0.86/1.21 , Y ) }.
% 0.86/1.21 { smaller_or_equal( age( X, Y ), eta ), alpha2( X, Y ) }.
% 0.86/1.21 { ! has_immunity( X, Y ), alpha2( X, Y ) }.
% 0.86/1.21 { ! organization( X ), ! has_immunity( X, Y ), ! has_immunity( X, Z ),
% 0.86/1.21 hazard_of_mortality( X, Y ) = hazard_of_mortality( X, Z ) }.
% 0.86/1.21 { ! organization( X ), ! has_immunity( X, Y ), has_immunity( X, Z ),
% 0.86/1.21 greater( hazard_of_mortality( X, Z ), hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 { organization( skol2 ) }.
% 0.86/1.21 { has_endowment( skol2 ) }.
% 0.86/1.21 { age( skol2, skol3 ) = zero }.
% 0.86/1.21 { smaller_or_equal( age( skol2, skol4 ), eta ) }.
% 0.86/1.21 { greater( age( skol2, skol5 ), eta ) }.
% 0.86/1.21 { greater( eta, zero ) }.
% 0.86/1.21 { ! greater( hazard_of_mortality( skol2, skol5 ), hazard_of_mortality(
% 0.86/1.21 skol2, skol4 ) ), ! hazard_of_mortality( skol2, skol4 ) =
% 0.86/1.21 hazard_of_mortality( skol2, skol3 ) }.
% 0.86/1.21
% 0.86/1.21 percentage equality = 0.114286, percentage horn = 0.781250
% 0.86/1.21 This is a problem with some equality
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Options Used:
% 0.86/1.21
% 0.86/1.21 useres = 1
% 0.86/1.21 useparamod = 1
% 0.86/1.21 useeqrefl = 1
% 0.86/1.21 useeqfact = 1
% 0.86/1.21 usefactor = 1
% 0.86/1.21 usesimpsplitting = 0
% 0.86/1.21 usesimpdemod = 5
% 0.86/1.21 usesimpres = 3
% 0.86/1.21
% 0.86/1.21 resimpinuse = 1000
% 0.86/1.21 resimpclauses = 20000
% 0.86/1.21 substype = eqrewr
% 0.86/1.21 backwardsubs = 1
% 0.86/1.21 selectoldest = 5
% 0.86/1.21
% 0.86/1.21 litorderings [0] = split
% 0.86/1.21 litorderings [1] = extend the termordering, first sorting on arguments
% 0.86/1.21
% 0.86/1.21 termordering = kbo
% 0.86/1.21
% 0.86/1.21 litapriori = 0
% 0.86/1.21 termapriori = 1
% 0.86/1.21 litaposteriori = 0
% 0.86/1.21 termaposteriori = 0
% 0.86/1.21 demodaposteriori = 0
% 0.86/1.21 ordereqreflfact = 0
% 0.86/1.21
% 0.86/1.21 litselect = negord
% 0.86/1.21
% 0.86/1.21 maxweight = 15
% 0.86/1.21 maxdepth = 30000
% 0.86/1.21 maxlength = 115
% 0.86/1.21 maxnrvars = 195
% 0.86/1.21 excuselevel = 1
% 0.86/1.21 increasemaxweight = 1
% 0.86/1.21
% 0.86/1.21 maxselected = 10000000
% 0.86/1.21 maxnrclauses = 10000000
% 0.86/1.21
% 0.86/1.21 showgenerated = 0
% 0.86/1.21 showkept = 0
% 0.86/1.21 showselected = 0
% 0.86/1.21 showdeleted = 0
% 0.86/1.21 showresimp = 1
% 0.86/1.21 showstatus = 2000
% 0.86/1.21
% 0.86/1.21 prologoutput = 0
% 0.86/1.21 nrgoals = 5000000
% 0.86/1.21 totalproof = 1
% 0.86/1.21
% 0.86/1.21 Symbols occurring in the translation:
% 0.86/1.21
% 0.86/1.21 {} [0, 0] (w:1, o:2, a:1, s:1, b:0),
% 0.86/1.21 . [1, 2] (w:1, o:28, a:1, s:1, b:0),
% 0.86/1.21 ! [4, 1] (w:0, o:19, a:1, s:1, b:0),
% 0.86/1.21 = [13, 2] (w:1, o:0, a:0, s:1, b:0),
% 0.86/1.21 ==> [14, 2] (w:1, o:0, a:0, s:1, b:0),
% 0.86/1.21 smaller_or_equal [37, 2] (w:1, o:52, a:1, s:1, b:0),
% 0.86/1.21 smaller [38, 2] (w:1, o:53, a:1, s:1, b:0),
% 0.86/1.21 greater_or_equal [39, 2] (w:1, o:54, a:1, s:1, b:0),
% 0.86/1.21 greater [40, 2] (w:1, o:55, a:1, s:1, b:0),
% 0.86/1.21 has_endowment [42, 1] (w:1, o:24, a:1, s:1, b:0),
% 0.86/1.21 organization [44, 1] (w:1, o:25, a:1, s:1, b:0),
% 0.86/1.21 age [45, 2] (w:1, o:56, a:1, s:1, b:0),
% 0.86/1.21 eta [46, 0] (w:1, o:10, a:1, s:1, b:0),
% 0.86/1.21 has_immunity [47, 2] (w:1, o:57, a:1, s:1, b:0),
% 0.86/1.21 hazard_of_mortality [49, 2] (w:1, o:58, a:1, s:1, b:0),
% 0.86/1.21 zero [52, 0] (w:1, o:14, a:1, s:1, b:0),
% 0.86/1.21 alpha1 [53, 1] (w:1, o:26, a:1, s:1, b:1),
% 0.86/1.21 alpha2 [54, 2] (w:1, o:59, a:1, s:1, b:1),
% 0.86/1.21 alpha3 [55, 2] (w:1, o:60, a:1, s:1, b:1),
% 0.86/1.21 skol1 [56, 1] (w:1, o:27, a:1, s:1, b:1),
% 0.86/1.21 skol2 [57, 0] (w:1, o:15, a:1, s:1, b:1),
% 0.86/1.21 skol3 [58, 0] (w:1, o:16, a:1, s:1, b:1),
% 0.86/1.21 skol4 [59, 0] (w:1, o:17, a:1, s:1, b:1),
% 0.86/1.21 skol5 [60, 0] (w:1, o:18, a:1, s:1, b:1).
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Starting Search:
% 0.86/1.21
% 0.86/1.21 *** allocated 15000 integers for clauses
% 0.86/1.21 *** allocated 22500 integers for clauses
% 0.86/1.21 *** allocated 33750 integers for clauses
% 0.86/1.21 *** allocated 50625 integers for clauses
% 0.86/1.21 *** allocated 15000 integers for termspace/termends
% 0.86/1.21 Resimplifying inuse:
% 0.86/1.21 Done
% 0.86/1.21
% 0.86/1.21 *** allocated 75937 integers for clauses
% 0.86/1.21 *** allocated 22500 integers for termspace/termends
% 0.86/1.21 *** allocated 113905 integers for clauses
% 0.86/1.21 *** allocated 33750 integers for termspace/termends
% 0.86/1.21
% 0.86/1.21 Intermediate Status:
% 0.86/1.21 Generated: 4161
% 0.86/1.21 Kept: 2001
% 0.86/1.21 Inuse: 153
% 0.86/1.21 Deleted: 5
% 0.86/1.21 Deletedinuse: 0
% 0.86/1.21
% 0.86/1.21 Resimplifying inuse:
% 0.86/1.21 Done
% 0.86/1.21
% 0.86/1.21 *** allocated 50625 integers for termspace/termends
% 0.86/1.21 *** allocated 170857 integers for clauses
% 0.86/1.21
% 0.86/1.21 Bliksems!, er is een bewijs:
% 0.86/1.21 % SZS status Theorem
% 0.86/1.21 % SZS output start Refutation
% 0.86/1.21
% 0.86/1.21 (1) {G0,W6,D2,L2,V2,M2} I { ! smaller( X, Y ), smaller_or_equal( X, Y ) }.
% 0.86/1.21 (7) {G0,W6,D2,L2,V2,M2} I { ! greater( Y, X ), smaller( X, Y ) }.
% 0.86/1.21 (12) {G0,W4,D2,L2,V1,M2} I { ! has_endowment( X ), alpha1( X ) }.
% 0.86/1.21 (14) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 (15) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 (17) {G0,W11,D3,L3,V2,M3} I { ! alpha3( X, Y ), ! greater( age( X, Y ), eta
% 0.86/1.21 ), ! has_immunity( X, Y ) }.
% 0.86/1.21 (20) {G0,W11,D3,L3,V2,M3} I { ! alpha2( X, Y ), ! smaller_or_equal( age( X
% 0.86/1.21 , Y ), eta ), has_immunity( X, Y ) }.
% 0.86/1.21 (23) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), ! has_immunity( X, Y ),
% 0.86/1.21 ! has_immunity( X, Z ), hazard_of_mortality( X, Y ) = hazard_of_mortality
% 0.86/1.21 ( X, Z ) }.
% 0.86/1.21 (24) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), ! has_immunity( X, Y ),
% 0.86/1.21 has_immunity( X, Z ), greater( hazard_of_mortality( X, Z ),
% 0.86/1.21 hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 (25) {G0,W2,D2,L1,V0,M1} I { organization( skol2 ) }.
% 0.86/1.21 (26) {G0,W2,D2,L1,V0,M1} I { has_endowment( skol2 ) }.
% 0.86/1.21 (27) {G0,W5,D3,L1,V0,M1} I { age( skol2, skol3 ) ==> zero }.
% 0.86/1.21 (28) {G0,W5,D3,L1,V0,M1} I { smaller_or_equal( age( skol2, skol4 ), eta )
% 0.86/1.21 }.
% 0.86/1.21 (29) {G0,W5,D3,L1,V0,M1} I { greater( age( skol2, skol5 ), eta ) }.
% 0.86/1.21 (30) {G0,W3,D2,L1,V0,M1} I { greater( eta, zero ) }.
% 0.86/1.21 (31) {G0,W14,D3,L2,V0,M2} I { ! greater( hazard_of_mortality( skol2, skol5
% 0.86/1.21 ), hazard_of_mortality( skol2, skol4 ) ), ! hazard_of_mortality( skol2,
% 0.86/1.21 skol4 ) ==> hazard_of_mortality( skol2, skol3 ) }.
% 0.86/1.21 (43) {G1,W2,D2,L1,V0,M1} R(12,26) { alpha1( skol2 ) }.
% 0.86/1.21 (44) {G2,W3,D2,L1,V1,M1} R(15,43) { alpha3( skol2, X ) }.
% 0.86/1.21 (46) {G2,W3,D2,L1,V1,M1} R(14,43) { alpha2( skol2, X ) }.
% 0.86/1.21 (158) {G1,W3,D2,L1,V0,M1} R(7,30) { smaller( zero, eta ) }.
% 0.86/1.21 (159) {G2,W3,D2,L1,V0,M1} R(158,1) { smaller_or_equal( zero, eta ) }.
% 0.86/1.21 (474) {G3,W3,D2,L1,V0,M1} R(17,29);r(44) { ! has_immunity( skol2, skol5 )
% 0.86/1.21 }.
% 0.86/1.21 (663) {G3,W3,D2,L1,V0,M1} R(20,28);r(46) { has_immunity( skol2, skol4 ) }.
% 0.86/1.21 (943) {G4,W10,D3,L2,V1,M2} R(24,474);r(25) { ! has_immunity( skol2, X ),
% 0.86/1.21 greater( hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2
% 0.86/1.21 , X ) ) }.
% 0.86/1.21 (1033) {G5,W15,D3,L4,V1,M4} P(23,31);r(943) { ! hazard_of_mortality( skol2
% 0.86/1.21 , X ) = hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 0.86/1.21 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ) }.
% 0.86/1.21 (1069) {G6,W6,D2,L2,V0,M2} Q(1033);r(25) { ! has_immunity( skol2, skol4 ),
% 0.86/1.21 ! has_immunity( skol2, skol3 ) }.
% 0.86/1.21 (2972) {G7,W3,D2,L1,V0,M1} S(1069);r(663) { ! has_immunity( skol2, skol3 )
% 0.86/1.21 }.
% 0.86/1.21 (2974) {G8,W3,D2,L1,V0,M1} R(2972,20);d(27);r(46) { ! smaller_or_equal(
% 0.86/1.21 zero, eta ) }.
% 0.86/1.21 (2987) {G9,W0,D0,L0,V0,M0} S(2974);r(159) { }.
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 % SZS output end Refutation
% 0.86/1.21 found a proof!
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Unprocessed initial clauses:
% 0.86/1.21
% 0.86/1.21 (2989) {G0,W9,D2,L3,V2,M3} { ! smaller_or_equal( X, Y ), smaller( X, Y ),
% 0.86/1.21 X = Y }.
% 0.86/1.21 (2990) {G0,W6,D2,L2,V2,M2} { ! smaller( X, Y ), smaller_or_equal( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 (2991) {G0,W6,D2,L2,V2,M2} { ! X = Y, smaller_or_equal( X, Y ) }.
% 0.86/1.21 (2992) {G0,W9,D2,L3,V2,M3} { ! greater_or_equal( X, Y ), greater( X, Y ),
% 0.86/1.21 X = Y }.
% 0.86/1.21 (2993) {G0,W6,D2,L2,V2,M2} { ! greater( X, Y ), greater_or_equal( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 (2994) {G0,W6,D2,L2,V2,M2} { ! X = Y, greater_or_equal( X, Y ) }.
% 0.86/1.21 (2995) {G0,W6,D2,L2,V2,M2} { ! smaller( X, Y ), greater( Y, X ) }.
% 0.86/1.21 (2996) {G0,W6,D2,L2,V2,M2} { ! greater( Y, X ), smaller( X, Y ) }.
% 0.86/1.21 (2997) {G0,W6,D2,L2,V2,M2} { ! greater( X, Y ), ! greater( Y, X ) }.
% 0.86/1.21 (2998) {G0,W9,D2,L3,V3,M3} { ! greater( X, Z ), ! greater( Z, Y ), greater
% 0.86/1.21 ( X, Y ) }.
% 0.86/1.21 (2999) {G0,W9,D2,L3,V2,M3} { smaller( X, Y ), X = Y, greater( X, Y ) }.
% 0.86/1.21 (3000) {G0,W4,D2,L2,V1,M2} { ! has_endowment( X ), organization( X ) }.
% 0.86/1.21 (3001) {G0,W4,D2,L2,V1,M2} { ! has_endowment( X ), alpha1( X ) }.
% 0.86/1.21 (3002) {G0,W6,D2,L3,V1,M3} { ! organization( X ), ! alpha1( X ),
% 0.86/1.21 has_endowment( X ) }.
% 0.86/1.21 (3003) {G0,W5,D2,L2,V2,M2} { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 (3004) {G0,W5,D2,L2,V2,M2} { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 (3005) {G0,W10,D3,L3,V1,M3} { ! alpha2( X, skol1( X ) ), ! alpha3( X,
% 0.86/1.21 skol1( X ) ), alpha1( X ) }.
% 0.86/1.21 (3006) {G0,W11,D3,L3,V2,M3} { ! alpha3( X, Y ), ! greater( age( X, Y ),
% 0.86/1.21 eta ), ! has_immunity( X, Y ) }.
% 0.86/1.21 (3007) {G0,W8,D3,L2,V2,M2} { greater( age( X, Y ), eta ), alpha3( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 (3008) {G0,W6,D2,L2,V2,M2} { has_immunity( X, Y ), alpha3( X, Y ) }.
% 0.86/1.21 (3009) {G0,W11,D3,L3,V2,M3} { ! alpha2( X, Y ), ! smaller_or_equal( age( X
% 0.86/1.21 , Y ), eta ), has_immunity( X, Y ) }.
% 0.86/1.21 (3010) {G0,W8,D3,L2,V2,M2} { smaller_or_equal( age( X, Y ), eta ), alpha2
% 0.86/1.21 ( X, Y ) }.
% 0.86/1.21 (3011) {G0,W6,D2,L2,V2,M2} { ! has_immunity( X, Y ), alpha2( X, Y ) }.
% 0.86/1.21 (3012) {G0,W15,D3,L4,V3,M4} { ! organization( X ), ! has_immunity( X, Y )
% 0.86/1.21 , ! has_immunity( X, Z ), hazard_of_mortality( X, Y ) =
% 0.86/1.21 hazard_of_mortality( X, Z ) }.
% 0.86/1.21 (3013) {G0,W15,D3,L4,V3,M4} { ! organization( X ), ! has_immunity( X, Y )
% 0.86/1.21 , has_immunity( X, Z ), greater( hazard_of_mortality( X, Z ),
% 0.86/1.21 hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 (3014) {G0,W2,D2,L1,V0,M1} { organization( skol2 ) }.
% 0.86/1.21 (3015) {G0,W2,D2,L1,V0,M1} { has_endowment( skol2 ) }.
% 0.86/1.21 (3016) {G0,W5,D3,L1,V0,M1} { age( skol2, skol3 ) = zero }.
% 0.86/1.21 (3017) {G0,W5,D3,L1,V0,M1} { smaller_or_equal( age( skol2, skol4 ), eta )
% 0.86/1.21 }.
% 0.86/1.21 (3018) {G0,W5,D3,L1,V0,M1} { greater( age( skol2, skol5 ), eta ) }.
% 0.86/1.21 (3019) {G0,W3,D2,L1,V0,M1} { greater( eta, zero ) }.
% 0.86/1.21 (3020) {G0,W14,D3,L2,V0,M2} { ! greater( hazard_of_mortality( skol2, skol5
% 0.86/1.21 ), hazard_of_mortality( skol2, skol4 ) ), ! hazard_of_mortality( skol2,
% 0.86/1.21 skol4 ) = hazard_of_mortality( skol2, skol3 ) }.
% 0.86/1.21
% 0.86/1.21
% 0.86/1.21 Total Proof:
% 0.86/1.21
% 0.86/1.21 subsumption: (1) {G0,W6,D2,L2,V2,M2} I { ! smaller( X, Y ),
% 0.86/1.21 smaller_or_equal( X, Y ) }.
% 0.86/1.21 parent0: (2990) {G0,W6,D2,L2,V2,M2} { ! smaller( X, Y ), smaller_or_equal
% 0.86/1.21 ( X, Y ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (7) {G0,W6,D2,L2,V2,M2} I { ! greater( Y, X ), smaller( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 parent0: (2996) {G0,W6,D2,L2,V2,M2} { ! greater( Y, X ), smaller( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (12) {G0,W4,D2,L2,V1,M2} I { ! has_endowment( X ), alpha1( X )
% 0.86/1.21 }.
% 0.86/1.21 parent0: (3001) {G0,W4,D2,L2,V1,M2} { ! has_endowment( X ), alpha1( X )
% 0.86/1.21 }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (14) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 parent0: (3003) {G0,W5,D2,L2,V2,M2} { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (15) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 parent0: (3004) {G0,W5,D2,L2,V2,M2} { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (17) {G0,W11,D3,L3,V2,M3} I { ! alpha3( X, Y ), ! greater( age
% 0.86/1.21 ( X, Y ), eta ), ! has_immunity( X, Y ) }.
% 0.86/1.21 parent0: (3006) {G0,W11,D3,L3,V2,M3} { ! alpha3( X, Y ), ! greater( age( X
% 0.86/1.21 , Y ), eta ), ! has_immunity( X, Y ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 2 ==> 2
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (20) {G0,W11,D3,L3,V2,M3} I { ! alpha2( X, Y ), !
% 0.86/1.21 smaller_or_equal( age( X, Y ), eta ), has_immunity( X, Y ) }.
% 0.86/1.21 parent0: (3009) {G0,W11,D3,L3,V2,M3} { ! alpha2( X, Y ), !
% 0.86/1.21 smaller_or_equal( age( X, Y ), eta ), has_immunity( X, Y ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 2 ==> 2
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (23) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), !
% 0.86/1.21 has_immunity( X, Y ), ! has_immunity( X, Z ), hazard_of_mortality( X, Y )
% 0.86/1.21 = hazard_of_mortality( X, Z ) }.
% 0.86/1.21 parent0: (3012) {G0,W15,D3,L4,V3,M4} { ! organization( X ), ! has_immunity
% 0.86/1.21 ( X, Y ), ! has_immunity( X, Z ), hazard_of_mortality( X, Y ) =
% 0.86/1.21 hazard_of_mortality( X, Z ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 Z := Z
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 2 ==> 2
% 0.86/1.21 3 ==> 3
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (24) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), !
% 0.86/1.21 has_immunity( X, Y ), has_immunity( X, Z ), greater( hazard_of_mortality
% 0.86/1.21 ( X, Z ), hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 parent0: (3013) {G0,W15,D3,L4,V3,M4} { ! organization( X ), ! has_immunity
% 0.86/1.21 ( X, Y ), has_immunity( X, Z ), greater( hazard_of_mortality( X, Z ),
% 0.86/1.21 hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 Y := Y
% 0.86/1.21 Z := Z
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 2 ==> 2
% 0.86/1.21 3 ==> 3
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (25) {G0,W2,D2,L1,V0,M1} I { organization( skol2 ) }.
% 0.86/1.21 parent0: (3014) {G0,W2,D2,L1,V0,M1} { organization( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (26) {G0,W2,D2,L1,V0,M1} I { has_endowment( skol2 ) }.
% 0.86/1.21 parent0: (3015) {G0,W2,D2,L1,V0,M1} { has_endowment( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (27) {G0,W5,D3,L1,V0,M1} I { age( skol2, skol3 ) ==> zero }.
% 0.86/1.21 parent0: (3016) {G0,W5,D3,L1,V0,M1} { age( skol2, skol3 ) = zero }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (28) {G0,W5,D3,L1,V0,M1} I { smaller_or_equal( age( skol2,
% 0.86/1.21 skol4 ), eta ) }.
% 0.86/1.21 parent0: (3017) {G0,W5,D3,L1,V0,M1} { smaller_or_equal( age( skol2, skol4
% 0.86/1.21 ), eta ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (29) {G0,W5,D3,L1,V0,M1} I { greater( age( skol2, skol5 ), eta
% 0.86/1.21 ) }.
% 0.86/1.21 parent0: (3018) {G0,W5,D3,L1,V0,M1} { greater( age( skol2, skol5 ), eta )
% 0.86/1.21 }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (30) {G0,W3,D2,L1,V0,M1} I { greater( eta, zero ) }.
% 0.86/1.21 parent0: (3019) {G0,W3,D2,L1,V0,M1} { greater( eta, zero ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (31) {G0,W14,D3,L2,V0,M2} I { ! greater( hazard_of_mortality(
% 0.86/1.21 skol2, skol5 ), hazard_of_mortality( skol2, skol4 ) ), !
% 0.86/1.21 hazard_of_mortality( skol2, skol4 ) ==> hazard_of_mortality( skol2, skol3
% 0.86/1.21 ) }.
% 0.86/1.21 parent0: (3020) {G0,W14,D3,L2,V0,M2} { ! greater( hazard_of_mortality(
% 0.86/1.21 skol2, skol5 ), hazard_of_mortality( skol2, skol4 ) ), !
% 0.86/1.21 hazard_of_mortality( skol2, skol4 ) = hazard_of_mortality( skol2, skol3 )
% 0.86/1.21 }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 1 ==> 1
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3139) {G1,W2,D2,L1,V0,M1} { alpha1( skol2 ) }.
% 0.86/1.21 parent0[0]: (12) {G0,W4,D2,L2,V1,M2} I { ! has_endowment( X ), alpha1( X )
% 0.86/1.21 }.
% 0.86/1.21 parent1[0]: (26) {G0,W2,D2,L1,V0,M1} I { has_endowment( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := skol2
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (43) {G1,W2,D2,L1,V0,M1} R(12,26) { alpha1( skol2 ) }.
% 0.86/1.21 parent0: (3139) {G1,W2,D2,L1,V0,M1} { alpha1( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3140) {G1,W3,D2,L1,V1,M1} { alpha3( skol2, X ) }.
% 0.86/1.21 parent0[0]: (15) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha3( X, Y ) }.
% 0.86/1.21 parent1[0]: (43) {G1,W2,D2,L1,V0,M1} R(12,26) { alpha1( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := skol2
% 0.86/1.21 Y := X
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (44) {G2,W3,D2,L1,V1,M1} R(15,43) { alpha3( skol2, X ) }.
% 0.86/1.21 parent0: (3140) {G1,W3,D2,L1,V1,M1} { alpha3( skol2, X ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3141) {G1,W3,D2,L1,V1,M1} { alpha2( skol2, X ) }.
% 0.86/1.21 parent0[0]: (14) {G0,W5,D2,L2,V2,M2} I { ! alpha1( X ), alpha2( X, Y ) }.
% 0.86/1.21 parent1[0]: (43) {G1,W2,D2,L1,V0,M1} R(12,26) { alpha1( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := skol2
% 0.86/1.21 Y := X
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (46) {G2,W3,D2,L1,V1,M1} R(14,43) { alpha2( skol2, X ) }.
% 0.86/1.21 parent0: (3141) {G1,W3,D2,L1,V1,M1} { alpha2( skol2, X ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3142) {G1,W3,D2,L1,V0,M1} { smaller( zero, eta ) }.
% 0.86/1.21 parent0[0]: (7) {G0,W6,D2,L2,V2,M2} I { ! greater( Y, X ), smaller( X, Y )
% 0.86/1.21 }.
% 0.86/1.21 parent1[0]: (30) {G0,W3,D2,L1,V0,M1} I { greater( eta, zero ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := zero
% 0.86/1.21 Y := eta
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (158) {G1,W3,D2,L1,V0,M1} R(7,30) { smaller( zero, eta ) }.
% 0.86/1.21 parent0: (3142) {G1,W3,D2,L1,V0,M1} { smaller( zero, eta ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3143) {G1,W3,D2,L1,V0,M1} { smaller_or_equal( zero, eta ) }.
% 0.86/1.21 parent0[0]: (1) {G0,W6,D2,L2,V2,M2} I { ! smaller( X, Y ), smaller_or_equal
% 0.86/1.21 ( X, Y ) }.
% 0.86/1.21 parent1[0]: (158) {G1,W3,D2,L1,V0,M1} R(7,30) { smaller( zero, eta ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := zero
% 0.86/1.21 Y := eta
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (159) {G2,W3,D2,L1,V0,M1} R(158,1) { smaller_or_equal( zero,
% 0.86/1.21 eta ) }.
% 0.86/1.21 parent0: (3143) {G1,W3,D2,L1,V0,M1} { smaller_or_equal( zero, eta ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3144) {G1,W6,D2,L2,V0,M2} { ! alpha3( skol2, skol5 ), !
% 0.86/1.21 has_immunity( skol2, skol5 ) }.
% 0.86/1.21 parent0[1]: (17) {G0,W11,D3,L3,V2,M3} I { ! alpha3( X, Y ), ! greater( age
% 0.86/1.21 ( X, Y ), eta ), ! has_immunity( X, Y ) }.
% 0.86/1.21 parent1[0]: (29) {G0,W5,D3,L1,V0,M1} I { greater( age( skol2, skol5 ), eta
% 0.86/1.21 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := skol2
% 0.86/1.21 Y := skol5
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3145) {G2,W3,D2,L1,V0,M1} { ! has_immunity( skol2, skol5 )
% 0.86/1.21 }.
% 0.86/1.21 parent0[0]: (3144) {G1,W6,D2,L2,V0,M2} { ! alpha3( skol2, skol5 ), !
% 0.86/1.21 has_immunity( skol2, skol5 ) }.
% 0.86/1.21 parent1[0]: (44) {G2,W3,D2,L1,V1,M1} R(15,43) { alpha3( skol2, X ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 X := skol5
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (474) {G3,W3,D2,L1,V0,M1} R(17,29);r(44) { ! has_immunity(
% 0.86/1.21 skol2, skol5 ) }.
% 0.86/1.21 parent0: (3145) {G2,W3,D2,L1,V0,M1} { ! has_immunity( skol2, skol5 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3146) {G1,W6,D2,L2,V0,M2} { ! alpha2( skol2, skol4 ),
% 0.86/1.21 has_immunity( skol2, skol4 ) }.
% 0.86/1.21 parent0[1]: (20) {G0,W11,D3,L3,V2,M3} I { ! alpha2( X, Y ), !
% 0.86/1.21 smaller_or_equal( age( X, Y ), eta ), has_immunity( X, Y ) }.
% 0.86/1.21 parent1[0]: (28) {G0,W5,D3,L1,V0,M1} I { smaller_or_equal( age( skol2,
% 0.86/1.21 skol4 ), eta ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := skol2
% 0.86/1.21 Y := skol4
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3147) {G2,W3,D2,L1,V0,M1} { has_immunity( skol2, skol4 ) }.
% 0.86/1.21 parent0[0]: (3146) {G1,W6,D2,L2,V0,M2} { ! alpha2( skol2, skol4 ),
% 0.86/1.21 has_immunity( skol2, skol4 ) }.
% 0.86/1.21 parent1[0]: (46) {G2,W3,D2,L1,V1,M1} R(14,43) { alpha2( skol2, X ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 X := skol4
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (663) {G3,W3,D2,L1,V0,M1} R(20,28);r(46) { has_immunity( skol2
% 0.86/1.21 , skol4 ) }.
% 0.86/1.21 parent0: (3147) {G2,W3,D2,L1,V0,M1} { has_immunity( skol2, skol4 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 permutation0:
% 0.86/1.21 0 ==> 0
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3148) {G1,W12,D3,L3,V1,M3} { ! organization( skol2 ), !
% 0.86/1.21 has_immunity( skol2, X ), greater( hazard_of_mortality( skol2, skol5 ),
% 0.86/1.21 hazard_of_mortality( skol2, X ) ) }.
% 0.86/1.21 parent0[0]: (474) {G3,W3,D2,L1,V0,M1} R(17,29);r(44) { ! has_immunity(
% 0.86/1.21 skol2, skol5 ) }.
% 0.86/1.21 parent1[2]: (24) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), !
% 0.86/1.21 has_immunity( X, Y ), has_immunity( X, Z ), greater( hazard_of_mortality
% 0.86/1.21 ( X, Z ), hazard_of_mortality( X, Y ) ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 X := skol2
% 0.86/1.21 Y := X
% 0.86/1.21 Z := skol5
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 resolution: (3149) {G1,W10,D3,L2,V1,M2} { ! has_immunity( skol2, X ),
% 0.86/1.21 greater( hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2
% 0.86/1.21 , X ) ) }.
% 0.86/1.21 parent0[0]: (3148) {G1,W12,D3,L3,V1,M3} { ! organization( skol2 ), !
% 0.86/1.21 has_immunity( skol2, X ), greater( hazard_of_mortality( skol2, skol5 ),
% 0.86/1.21 hazard_of_mortality( skol2, X ) ) }.
% 0.86/1.21 parent1[0]: (25) {G0,W2,D2,L1,V0,M1} I { organization( skol2 ) }.
% 0.86/1.21 substitution0:
% 0.86/1.21 X := X
% 0.86/1.21 end
% 0.86/1.21 substitution1:
% 0.86/1.21 end
% 0.86/1.21
% 0.86/1.21 subsumption: (943) {G4,W10,D3,L2,V1,M2} R(24,474);r(25) { ! has_immunity(
% 0.86/1.21 skol2, X ), greater( hazard_of_mortality( skol2, skol5 ),
% 0.86/1.21 hazard_of_mortality( skol2, X ) ) }.
% 0.86/1.21 parent0: (3149) {G1,W10,D3,L2,V1,M2} { ! has_immunity( skol2, X ), greater
% 0.86/1.21 ( hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, X ) )
% 1.47/1.83 }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 0 ==> 0
% 1.47/1.83 1 ==> 1
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 *** allocated 75937 integers for termspace/termends
% 1.47/1.83 *** allocated 15000 integers for justifications
% 1.47/1.83 *** allocated 113905 integers for termspace/termends
% 1.47/1.83 *** allocated 22500 integers for justifications
% 1.47/1.83 *** allocated 256285 integers for clauses
% 1.47/1.83 *** allocated 170857 integers for termspace/termends
% 1.47/1.83 *** allocated 33750 integers for justifications
% 1.47/1.83 *** allocated 50625 integers for justifications
% 1.47/1.83 *** allocated 256285 integers for termspace/termends
% 1.47/1.83 eqswap: (3150) {G0,W14,D3,L2,V0,M2} { ! hazard_of_mortality( skol2, skol3
% 1.47/1.83 ) ==> hazard_of_mortality( skol2, skol4 ), ! greater(
% 1.47/1.83 hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, skol4 )
% 1.47/1.83 ) }.
% 1.47/1.83 parent0[1]: (31) {G0,W14,D3,L2,V0,M2} I { ! greater( hazard_of_mortality(
% 1.47/1.83 skol2, skol5 ), hazard_of_mortality( skol2, skol4 ) ), !
% 1.47/1.83 hazard_of_mortality( skol2, skol4 ) ==> hazard_of_mortality( skol2, skol3
% 1.47/1.83 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 paramod: (3154) {G1,W22,D3,L5,V1,M5} { ! greater( hazard_of_mortality(
% 1.47/1.83 skol2, skol5 ), hazard_of_mortality( skol2, X ) ), ! organization( skol2
% 1.47/1.83 ), ! has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), !
% 1.47/1.83 hazard_of_mortality( skol2, skol3 ) ==> hazard_of_mortality( skol2, skol4
% 1.47/1.83 ) }.
% 1.47/1.83 parent0[3]: (23) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), !
% 1.47/1.83 has_immunity( X, Y ), ! has_immunity( X, Z ), hazard_of_mortality( X, Y )
% 1.47/1.83 = hazard_of_mortality( X, Z ) }.
% 1.47/1.83 parent1[1; 5]: (3150) {G0,W14,D3,L2,V0,M2} { ! hazard_of_mortality( skol2
% 1.47/1.83 , skol3 ) ==> hazard_of_mortality( skol2, skol4 ), ! greater(
% 1.47/1.83 hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, skol4 )
% 1.47/1.83 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := skol2
% 1.47/1.83 Y := skol4
% 1.47/1.83 Z := X
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 paramod: (3158) {G1,W30,D3,L8,V2,M8} { ! hazard_of_mortality( skol2, skol3
% 1.47/1.83 ) ==> hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! greater(
% 1.47/1.83 hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, Y ) ), !
% 1.47/1.83 organization( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity(
% 1.47/1.83 skol2, Y ) }.
% 1.47/1.83 parent0[3]: (23) {G0,W15,D3,L4,V3,M4} I { ! organization( X ), !
% 1.47/1.83 has_immunity( X, Y ), ! has_immunity( X, Z ), hazard_of_mortality( X, Y )
% 1.47/1.83 = hazard_of_mortality( X, Z ) }.
% 1.47/1.83 parent1[4; 5]: (3154) {G1,W22,D3,L5,V1,M5} { ! greater(
% 1.47/1.83 hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, X ) ), !
% 1.47/1.83 organization( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity(
% 1.47/1.83 skol2, X ), ! hazard_of_mortality( skol2, skol3 ) ==> hazard_of_mortality
% 1.47/1.83 ( skol2, skol4 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := skol2
% 1.47/1.83 Y := skol4
% 1.47/1.83 Z := X
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 X := Y
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6716) {G2,W26,D3,L8,V2,M8} { ! hazard_of_mortality( skol2,
% 1.47/1.83 skol3 ) ==> hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity( skol2, Y ), !
% 1.47/1.83 has_immunity( skol2, Y ) }.
% 1.47/1.83 parent0[4]: (3158) {G1,W30,D3,L8,V2,M8} { ! hazard_of_mortality( skol2,
% 1.47/1.83 skol3 ) ==> hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! greater(
% 1.47/1.83 hazard_of_mortality( skol2, skol5 ), hazard_of_mortality( skol2, Y ) ), !
% 1.47/1.83 organization( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity(
% 1.47/1.83 skol2, Y ) }.
% 1.47/1.83 parent1[1]: (943) {G4,W10,D3,L2,V1,M2} R(24,474);r(25) { ! has_immunity(
% 1.47/1.83 skol2, X ), greater( hazard_of_mortality( skol2, skol5 ),
% 1.47/1.83 hazard_of_mortality( skol2, X ) ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 Y := Y
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 X := Y
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 eqswap: (6717) {G2,W26,D3,L8,V2,M8} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity( skol2, Y ), !
% 1.47/1.83 has_immunity( skol2, Y ) }.
% 1.47/1.83 parent0[0]: (6716) {G2,W26,D3,L8,V2,M8} { ! hazard_of_mortality( skol2,
% 1.47/1.83 skol3 ) ==> hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity( skol2, Y ), !
% 1.47/1.83 has_immunity( skol2, Y ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 Y := Y
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 factor: (6720) {G2,W23,D3,L7,V2,M7} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, Y ), ! has_immunity( skol2, Y ) }.
% 1.47/1.83 parent0[2, 5]: (6717) {G2,W26,D3,L8,V2,M8} { ! hazard_of_mortality( skol2
% 1.47/1.83 , X ) ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity( skol2, Y ), !
% 1.47/1.83 has_immunity( skol2, Y ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 Y := Y
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 factor: (6723) {G2,W20,D3,L6,V1,M6} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ) }.
% 1.47/1.83 parent0[2, 5]: (6720) {G2,W23,D3,L7,V2,M7} { ! hazard_of_mortality( skol2
% 1.47/1.83 , X ) ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, Y ), ! has_immunity( skol2, Y ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 Y := skol4
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 factor: (6726) {G2,W17,D3,L5,V1,M5} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ) }.
% 1.47/1.83 parent0[2, 5]: (6723) {G2,W20,D3,L6,V1,M6} { ! hazard_of_mortality( skol2
% 1.47/1.83 , X ) ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ), ! has_immunity( skol2, skol4 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 factor: (6727) {G2,W15,D3,L4,V1,M4} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ) }.
% 1.47/1.83 parent0[1, 4]: (6726) {G2,W17,D3,L5,V1,M5} { ! hazard_of_mortality( skol2
% 1.47/1.83 , X ) ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ), ! organization
% 1.47/1.83 ( skol2 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 subsumption: (1033) {G5,W15,D3,L4,V1,M4} P(23,31);r(943) { !
% 1.47/1.83 hazard_of_mortality( skol2, X ) = hazard_of_mortality( skol2, skol3 ), !
% 1.47/1.83 organization( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity(
% 1.47/1.83 skol2, X ) }.
% 1.47/1.83 parent0: (6727) {G2,W15,D3,L4,V1,M4} { ! hazard_of_mortality( skol2, X )
% 1.47/1.83 ==> hazard_of_mortality( skol2, skol3 ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 0 ==> 0
% 1.47/1.83 1 ==> 1
% 1.47/1.83 2 ==> 2
% 1.47/1.83 3 ==> 3
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 eqswap: (6742) {G5,W15,D3,L4,V1,M4} { ! hazard_of_mortality( skol2, skol3
% 1.47/1.83 ) = hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ) }.
% 1.47/1.83 parent0[0]: (1033) {G5,W15,D3,L4,V1,M4} P(23,31);r(943) { !
% 1.47/1.83 hazard_of_mortality( skol2, X ) = hazard_of_mortality( skol2, skol3 ), !
% 1.47/1.83 organization( skol2 ), ! has_immunity( skol2, skol4 ), ! has_immunity(
% 1.47/1.83 skol2, X ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := X
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 eqrefl: (6743) {G0,W8,D2,L3,V0,M3} { ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, skol3 ) }.
% 1.47/1.83 parent0[0]: (6742) {G5,W15,D3,L4,V1,M4} { ! hazard_of_mortality( skol2,
% 1.47/1.83 skol3 ) = hazard_of_mortality( skol2, X ), ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, X ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 X := skol3
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6744) {G1,W6,D2,L2,V0,M2} { ! has_immunity( skol2, skol4 ), !
% 1.47/1.83 has_immunity( skol2, skol3 ) }.
% 1.47/1.83 parent0[0]: (6743) {G0,W8,D2,L3,V0,M3} { ! organization( skol2 ), !
% 1.47/1.83 has_immunity( skol2, skol4 ), ! has_immunity( skol2, skol3 ) }.
% 1.47/1.83 parent1[0]: (25) {G0,W2,D2,L1,V0,M1} I { organization( skol2 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 subsumption: (1069) {G6,W6,D2,L2,V0,M2} Q(1033);r(25) { ! has_immunity(
% 1.47/1.83 skol2, skol4 ), ! has_immunity( skol2, skol3 ) }.
% 1.47/1.83 parent0: (6744) {G1,W6,D2,L2,V0,M2} { ! has_immunity( skol2, skol4 ), !
% 1.47/1.83 has_immunity( skol2, skol3 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 0 ==> 0
% 1.47/1.83 1 ==> 1
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6745) {G4,W3,D2,L1,V0,M1} { ! has_immunity( skol2, skol3 )
% 1.47/1.83 }.
% 1.47/1.83 parent0[0]: (1069) {G6,W6,D2,L2,V0,M2} Q(1033);r(25) { ! has_immunity(
% 1.47/1.83 skol2, skol4 ), ! has_immunity( skol2, skol3 ) }.
% 1.47/1.83 parent1[0]: (663) {G3,W3,D2,L1,V0,M1} R(20,28);r(46) { has_immunity( skol2
% 1.47/1.83 , skol4 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 subsumption: (2972) {G7,W3,D2,L1,V0,M1} S(1069);r(663) { ! has_immunity(
% 1.47/1.83 skol2, skol3 ) }.
% 1.47/1.83 parent0: (6745) {G4,W3,D2,L1,V0,M1} { ! has_immunity( skol2, skol3 ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 0 ==> 0
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6747) {G1,W8,D3,L2,V0,M2} { ! alpha2( skol2, skol3 ), !
% 1.47/1.83 smaller_or_equal( age( skol2, skol3 ), eta ) }.
% 1.47/1.83 parent0[0]: (2972) {G7,W3,D2,L1,V0,M1} S(1069);r(663) { ! has_immunity(
% 1.47/1.83 skol2, skol3 ) }.
% 1.47/1.83 parent1[2]: (20) {G0,W11,D3,L3,V2,M3} I { ! alpha2( X, Y ), !
% 1.47/1.83 smaller_or_equal( age( X, Y ), eta ), has_immunity( X, Y ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 X := skol2
% 1.47/1.83 Y := skol3
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 paramod: (6748) {G1,W6,D2,L2,V0,M2} { ! smaller_or_equal( zero, eta ), !
% 1.47/1.83 alpha2( skol2, skol3 ) }.
% 1.47/1.83 parent0[0]: (27) {G0,W5,D3,L1,V0,M1} I { age( skol2, skol3 ) ==> zero }.
% 1.47/1.83 parent1[1; 2]: (6747) {G1,W8,D3,L2,V0,M2} { ! alpha2( skol2, skol3 ), !
% 1.47/1.83 smaller_or_equal( age( skol2, skol3 ), eta ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6749) {G2,W3,D2,L1,V0,M1} { ! smaller_or_equal( zero, eta )
% 1.47/1.83 }.
% 1.47/1.83 parent0[1]: (6748) {G1,W6,D2,L2,V0,M2} { ! smaller_or_equal( zero, eta ),
% 1.47/1.83 ! alpha2( skol2, skol3 ) }.
% 1.47/1.83 parent1[0]: (46) {G2,W3,D2,L1,V1,M1} R(14,43) { alpha2( skol2, X ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 X := skol3
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 subsumption: (2974) {G8,W3,D2,L1,V0,M1} R(2972,20);d(27);r(46) { !
% 1.47/1.83 smaller_or_equal( zero, eta ) }.
% 1.47/1.83 parent0: (6749) {G2,W3,D2,L1,V0,M1} { ! smaller_or_equal( zero, eta ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 0 ==> 0
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 resolution: (6750) {G3,W0,D0,L0,V0,M0} { }.
% 1.47/1.83 parent0[0]: (2974) {G8,W3,D2,L1,V0,M1} R(2972,20);d(27);r(46) { !
% 1.47/1.83 smaller_or_equal( zero, eta ) }.
% 1.47/1.83 parent1[0]: (159) {G2,W3,D2,L1,V0,M1} R(158,1) { smaller_or_equal( zero,
% 1.47/1.83 eta ) }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 substitution1:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 subsumption: (2987) {G9,W0,D0,L0,V0,M0} S(2974);r(159) { }.
% 1.47/1.83 parent0: (6750) {G3,W0,D0,L0,V0,M0} { }.
% 1.47/1.83 substitution0:
% 1.47/1.83 end
% 1.47/1.83 permutation0:
% 1.47/1.83 end
% 1.47/1.83
% 1.47/1.83 Proof check complete!
% 1.47/1.83
% 1.47/1.83 Memory use:
% 1.47/1.83
% 1.47/1.83 space for terms: 38721
% 1.47/1.83 space for clauses: 121402
% 1.47/1.83
% 1.47/1.83
% 1.47/1.83 clauses generated: 8508
% 1.47/1.83 clauses kept: 2988
% 1.47/1.83 clauses selected: 239
% 1.47/1.83 clauses deleted: 17
% 1.47/1.83 clauses inuse deleted: 1
% 1.47/1.83
% 1.47/1.83 subsentry: 1716261
% 1.47/1.83 literals s-matched: 131646
% 1.47/1.83 literals matched: 108838
% 1.47/1.83 full subsumption: 64455
% 1.47/1.83
% 1.47/1.83 checksum: -401900795
% 1.47/1.83
% 1.47/1.83
% 1.47/1.83 Bliksem ended
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