%------------------------------------------------------------------------------
% File     : SRASS---0.1
% Problem  : KRS235+1 : TPTP v5.3.0. Bugfixed v5.4.0.
% Transfm  : none
% Format   : tptp
% Command  : SRASS -q2 -a 0 10 10 10 -i3 -n60 %s

% Computer : manassas.cs.miami.edu
% Model    : x86_64 x86_64
% CPU      : Intel(R) Core(TM)2 CPU          6600  @ 2.40GHz @ 2400MHz
% Memory   : 1003MB
% OS       : Linux 2.6.32.26-175.fc12.x86_64
% CPULimit : 300s
% DateTime : Fri Jun 15 10:53:25 EDT 2012

% Result   : Theorem 26.77s
% Output   : Solution 26.77s
% Verified : 
% SZS Type : None (Parsing solution fails)
% Syntax   : Number of formulae    : 0

% Comments : 
%------------------------------------------------------------------------------
%----ERROR: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% Reading problem from /tmp/SystemOnTPTP22387/KRS235+1.tptp
% Adding relevance values
% Extracting the conjecture
% Sorting axioms by relevance
% Looking for THM       ... 
% found
% SZS status THM for /tmp/SystemOnTPTP22387/KRS235+1.tptp
% SZS output start Solution for /tmp/SystemOnTPTP22387/KRS235+1.tptp
% TreeLimitedRun: ----------------------------------------------------------
% TreeLimitedRun: /home/graph/tptp/Systems/EP---1.5/eproof_ram --print-statistics -xAuto -tAuto --cpu-limit=60 --memory-limit=Auto --tstp-format /tmp/SRASS.s.p 
% TreeLimitedRun: CPU time limit is 60s
% TreeLimitedRun: WC  time limit is 120s
% TreeLimitedRun: PID is 22485
% TreeLimitedRun: ----------------------------------------------------------
% PrfWatch: 0.00 CPU 0.01 WC
% PrfWatch: 3.36 CPU 2.01 WC
% PrfWatch: 7.01 CPU 4.02 WC
% PrfWatch: 10.27 CPU 6.02 WC
% PrfWatch: 13.39 CPU 8.03 WC
% PrfWatch: 16.43 CPU 10.04 WC
% PrfWatch: 19.57 CPU 12.05 WC
% PrfWatch: 22.50 CPU 14.06 WC
% PrfWatch: 25.63 CPU 16.07 WC
% # Auto-Ordering is analysing problem.
% # Problem is type GHNFNFFMM21LS
% # Auto-mode selected ordering type KBO6
% # Auto-mode selected ordering precedence scheme <invfreq>
% # Auto-mode selected weight ordering scheme <invfreqrank>
% #
% # Auto-Heuristic is analysing problem.
% # Problem is type GHNFNFFMM21LS
% # Auto-Mode selected heuristic G_E___006_C18_F1_PI_AE_Q4_CS_SP_S2S
% # and selection function SelectNewComplexAHP.
% #
% # No equality, disabling AC handling.
% #
% # Initializing proof state
% # Proof found!
% # SZS status Theorem
% # Parsed axioms                      : 33
% # Removed by relevancy pruning       : 0
% # Initial clauses                    : 109
% # Removed in clause preprocessing    : 0
% # Initial clauses in saturation      : 109
% # Processed clauses                  : 35398
% # ...of these trivial                : 3103
% # ...subsumed                        : 20722
% # ...remaining for further processing: 11573
% # Other redundant clauses eliminated : 0
% # Clauses deleted for lack of memory : 0
% # Backward-subsumed                  : 524
% # Backward-rewritten                 : 253
% # Generated clauses                  : 1055188
% # ...of the previous two non-trivial : 781641
% # Contextual simplify-reflections    : 9533
% # Paramodulations                    : 1054618
% # Factorizations                     : 570
% # Equation resolutions               : 0
% # Current number of processed clauses: 10796
% #    Positive orientable unit clauses: 1184
% #    Positive unorientable unit clauses: 0
% #    Negative unit clauses           : 1174
% #    Non-unit-clauses                : 8438
% # Current number of unprocessed clauses: 699709
% # ...number of literals in the above : 2746498
% # Clause-clause subsumption calls (NU) : 9894884
% # Rec. Clause-clause subsumption calls : 6142422
% # Non-unit clause-clause subsumptions: 28856
% # Unit Clause-clause subsumption calls : 814698
% # Rewrite failures with RHS unbound  : 0
% # BW rewrite match attempts          : 1363
% # BW rewrite match successes         : 221
% # Backwards rewriting index : 18031 nodes,  4640 leaves,   2.08+/-3.923 terms/leaf
% # Paramod-from index      :  8168 nodes,  2310 leaves,   1.38+/-1.970 terms/leaf
% # Paramod-into index      : 14321 nodes,  3642 leaves,   1.29+/-1.602 terms/leaf
% # Paramod-neg-atom index  :  3932 nodes,  1048 leaves,   2.99+/-4.134 terms/leaf
% # SZS output start CNFRefutation.
% fof(1, axiom,![X1]:![X2]:(![X3]:![X4]:(status(X3,X4,X1)=>~(status(X3,X4,X2)))<=>nevera(X1,X2)),file('/tmp/SRASS.s.p', nevera)).
% fof(2, axiom,![X3]:![X4]:(![X5]:(model(X5,X3)=>model(X5,X4))<=>status(X3,X4,thm)),file('/tmp/SRASS.s.p', thm)).
% fof(3, axiom,![X6]:![X7]:(model(X6,X7)<~>model(X6,not(X7))),file('/tmp/SRASS.s.p', completeness)).
% fof(11, axiom,![X3]:![X4]:((?[X5]:(model(X5,X3)&model(X5,X4))&?[X8]:(model(X8,X3)&model(X8,not(X4))))<=>status(X3,X4,noc)),file('/tmp/SRASS.s.p', noc)).
% fof(33, conjecture,nevera(noc,thm),file('/tmp/SRASS.s.p', nevera_noc_thm)).
% fof(34, negated_conjecture,~(nevera(noc,thm)),inference(assume_negation,[status(cth)],[33])).
% fof(35, plain,![X1]:![X2]:(![X3]:![X4]:(status(X3,X4,X1)=>~(status(X3,X4,X2)))<=>nevera(X1,X2)),inference(fof_simplification,[status(thm)],[1,theory(equality)])).
% fof(36, plain,![X6]:![X7]:~((model(X6,X7)<=>model(X6,not(X7)))),inference(fof_simplification,[status(thm)],[3,theory(equality)])).
% fof(50, negated_conjecture,~(nevera(noc,thm)),inference(fof_simplification,[status(thm)],[34,theory(equality)])).
% fof(51, plain,![X1]:![X2]:((?[X3]:?[X4]:(status(X3,X4,X1)&status(X3,X4,X2))|nevera(X1,X2))&(~(nevera(X1,X2))|![X3]:![X4]:(~(status(X3,X4,X1))|~(status(X3,X4,X2))))),inference(fof_nnf,[status(thm)],[35])).
% fof(52, plain,(![X1]:![X2]:(?[X3]:?[X4]:(status(X3,X4,X1)&status(X3,X4,X2))|nevera(X1,X2))&![X1]:![X2]:(~(nevera(X1,X2))|![X3]:![X4]:(~(status(X3,X4,X1))|~(status(X3,X4,X2))))),inference(shift_quantors,[status(thm)],[51])).
% fof(53, plain,(![X5]:![X6]:(?[X7]:?[X8]:(status(X7,X8,X5)&status(X7,X8,X6))|nevera(X5,X6))&![X9]:![X10]:(~(nevera(X9,X10))|![X11]:![X12]:(~(status(X11,X12,X9))|~(status(X11,X12,X10))))),inference(variable_rename,[status(thm)],[52])).
% fof(54, plain,(![X5]:![X6]:((status(esk1_2(X5,X6),esk2_2(X5,X6),X5)&status(esk1_2(X5,X6),esk2_2(X5,X6),X6))|nevera(X5,X6))&![X9]:![X10]:(~(nevera(X9,X10))|![X11]:![X12]:(~(status(X11,X12,X9))|~(status(X11,X12,X10))))),inference(skolemize,[status(esa)],[53])).
% fof(55, plain,![X5]:![X6]:![X9]:![X10]:![X11]:![X12]:(((status(esk1_2(X5,X6),esk2_2(X5,X6),X5)&status(esk1_2(X5,X6),esk2_2(X5,X6),X6))|nevera(X5,X6))&(~(nevera(X9,X10))|(~(status(X11,X12,X9))|~(status(X11,X12,X10))))),inference(shift_quantors,[status(thm)],[54])).
% fof(56, plain,![X5]:![X6]:![X9]:![X10]:![X11]:![X12]:(((status(esk1_2(X5,X6),esk2_2(X5,X6),X5)|nevera(X5,X6))&(status(esk1_2(X5,X6),esk2_2(X5,X6),X6)|nevera(X5,X6)))&(~(nevera(X9,X10))|(~(status(X11,X12,X9))|~(status(X11,X12,X10))))),inference(distribute,[status(thm)],[55])).
% cnf(57,plain,(~status(X1,X2,X3)|~status(X1,X2,X4)|~nevera(X4,X3)),inference(split_conjunct,[status(thm)],[56])).
% cnf(58,plain,(nevera(X1,X2)|status(esk1_2(X1,X2),esk2_2(X1,X2),X2)),inference(split_conjunct,[status(thm)],[56])).
% cnf(59,plain,(nevera(X1,X2)|status(esk1_2(X1,X2),esk2_2(X1,X2),X1)),inference(split_conjunct,[status(thm)],[56])).
% fof(60, plain,![X3]:![X4]:((?[X5]:(model(X5,X3)&~(model(X5,X4)))|status(X3,X4,thm))&(~(status(X3,X4,thm))|![X5]:(~(model(X5,X3))|model(X5,X4)))),inference(fof_nnf,[status(thm)],[2])).
% fof(61, plain,(![X3]:![X4]:(?[X5]:(model(X5,X3)&~(model(X5,X4)))|status(X3,X4,thm))&![X3]:![X4]:(~(status(X3,X4,thm))|![X5]:(~(model(X5,X3))|model(X5,X4)))),inference(shift_quantors,[status(thm)],[60])).
% fof(62, plain,(![X6]:![X7]:(?[X8]:(model(X8,X6)&~(model(X8,X7)))|status(X6,X7,thm))&![X9]:![X10]:(~(status(X9,X10,thm))|![X11]:(~(model(X11,X9))|model(X11,X10)))),inference(variable_rename,[status(thm)],[61])).
% fof(63, plain,(![X6]:![X7]:((model(esk3_2(X6,X7),X6)&~(model(esk3_2(X6,X7),X7)))|status(X6,X7,thm))&![X9]:![X10]:(~(status(X9,X10,thm))|![X11]:(~(model(X11,X9))|model(X11,X10)))),inference(skolemize,[status(esa)],[62])).
% fof(64, plain,![X6]:![X7]:![X9]:![X10]:![X11]:(((model(esk3_2(X6,X7),X6)&~(model(esk3_2(X6,X7),X7)))|status(X6,X7,thm))&(~(status(X9,X10,thm))|(~(model(X11,X9))|model(X11,X10)))),inference(shift_quantors,[status(thm)],[63])).
% fof(65, plain,![X6]:![X7]:![X9]:![X10]:![X11]:(((model(esk3_2(X6,X7),X6)|status(X6,X7,thm))&(~(model(esk3_2(X6,X7),X7))|status(X6,X7,thm)))&(~(status(X9,X10,thm))|(~(model(X11,X9))|model(X11,X10)))),inference(distribute,[status(thm)],[64])).
% cnf(66,plain,(model(X1,X2)|~model(X1,X3)|~status(X3,X2,thm)),inference(split_conjunct,[status(thm)],[65])).
% fof(69, plain,![X6]:![X7]:((~(model(X6,X7))|~(model(X6,not(X7))))&(model(X6,X7)|model(X6,not(X7)))),inference(fof_nnf,[status(thm)],[36])).
% fof(70, plain,(![X6]:![X7]:(~(model(X6,X7))|~(model(X6,not(X7))))&![X6]:![X7]:(model(X6,X7)|model(X6,not(X7)))),inference(shift_quantors,[status(thm)],[69])).
% fof(71, plain,(![X8]:![X9]:(~(model(X8,X9))|~(model(X8,not(X9))))&![X10]:![X11]:(model(X10,X11)|model(X10,not(X11)))),inference(variable_rename,[status(thm)],[70])).
% fof(72, plain,![X8]:![X9]:![X10]:![X11]:((~(model(X8,X9))|~(model(X8,not(X9))))&(model(X10,X11)|model(X10,not(X11)))),inference(shift_quantors,[status(thm)],[71])).
% cnf(74,plain,(~model(X1,not(X2))|~model(X1,X2)),inference(split_conjunct,[status(thm)],[72])).
% fof(111, plain,![X3]:![X4]:(((![X5]:(~(model(X5,X3))|~(model(X5,X4)))|![X8]:(~(model(X8,X3))|~(model(X8,not(X4)))))|status(X3,X4,noc))&(~(status(X3,X4,noc))|(?[X5]:(model(X5,X3)&model(X5,X4))&?[X8]:(model(X8,X3)&model(X8,not(X4)))))),inference(fof_nnf,[status(thm)],[11])).
% fof(112, plain,(![X3]:![X4]:((![X5]:(~(model(X5,X3))|~(model(X5,X4)))|![X8]:(~(model(X8,X3))|~(model(X8,not(X4)))))|status(X3,X4,noc))&![X3]:![X4]:(~(status(X3,X4,noc))|(?[X5]:(model(X5,X3)&model(X5,X4))&?[X8]:(model(X8,X3)&model(X8,not(X4)))))),inference(shift_quantors,[status(thm)],[111])).
% fof(113, plain,(![X9]:![X10]:((![X11]:(~(model(X11,X9))|~(model(X11,X10)))|![X12]:(~(model(X12,X9))|~(model(X12,not(X10)))))|status(X9,X10,noc))&![X13]:![X14]:(~(status(X13,X14,noc))|(?[X15]:(model(X15,X13)&model(X15,X14))&?[X16]:(model(X16,X13)&model(X16,not(X14)))))),inference(variable_rename,[status(thm)],[112])).
% fof(114, plain,(![X9]:![X10]:((![X11]:(~(model(X11,X9))|~(model(X11,X10)))|![X12]:(~(model(X12,X9))|~(model(X12,not(X10)))))|status(X9,X10,noc))&![X13]:![X14]:(~(status(X13,X14,noc))|((model(esk23_2(X13,X14),X13)&model(esk23_2(X13,X14),X14))&(model(esk24_2(X13,X14),X13)&model(esk24_2(X13,X14),not(X14)))))),inference(skolemize,[status(esa)],[113])).
% fof(115, plain,![X9]:![X10]:![X11]:![X12]:![X13]:![X14]:((((~(model(X11,X9))|~(model(X11,X10)))|(~(model(X12,X9))|~(model(X12,not(X10)))))|status(X9,X10,noc))&(~(status(X13,X14,noc))|((model(esk23_2(X13,X14),X13)&model(esk23_2(X13,X14),X14))&(model(esk24_2(X13,X14),X13)&model(esk24_2(X13,X14),not(X14)))))),inference(shift_quantors,[status(thm)],[114])).
% fof(116, plain,![X9]:![X10]:![X11]:![X12]:![X13]:![X14]:((((~(model(X11,X9))|~(model(X11,X10)))|(~(model(X12,X9))|~(model(X12,not(X10)))))|status(X9,X10,noc))&(((model(esk23_2(X13,X14),X13)|~(status(X13,X14,noc)))&(model(esk23_2(X13,X14),X14)|~(status(X13,X14,noc))))&((model(esk24_2(X13,X14),X13)|~(status(X13,X14,noc)))&(model(esk24_2(X13,X14),not(X14))|~(status(X13,X14,noc)))))),inference(distribute,[status(thm)],[115])).
% cnf(117,plain,(model(esk24_2(X1,X2),not(X2))|~status(X1,X2,noc)),inference(split_conjunct,[status(thm)],[116])).
% cnf(118,plain,(model(esk24_2(X1,X2),X1)|~status(X1,X2,noc)),inference(split_conjunct,[status(thm)],[116])).
% cnf(325,negated_conjecture,(~nevera(noc,thm)),inference(split_conjunct,[status(thm)],[50])).
% cnf(430,plain,(model(esk24_2(esk1_2(X1,noc),esk2_2(X1,noc)),esk1_2(X1,noc))|nevera(X1,noc)),inference(spm,[status(thm)],[118,58,theory(equality)])).
% cnf(431,plain,(model(esk24_2(esk1_2(X1,noc),esk2_2(X1,noc)),not(esk2_2(X1,noc)))|nevera(X1,noc)),inference(spm,[status(thm)],[117,58,theory(equality)])).
% cnf(434,plain,(nevera(X3,X1)|~nevera(X1,X2)|~status(esk1_2(X3,X1),esk2_2(X3,X1),X2)),inference(spm,[status(thm)],[57,58,theory(equality)])).
% cnf(477,plain,(model(X1,esk2_2(thm,X2))|nevera(thm,X2)|~model(X1,esk1_2(thm,X2))),inference(spm,[status(thm)],[66,59,theory(equality)])).
% cnf(7844,plain,(nevera(X1,noc)|~model(esk24_2(esk1_2(X1,noc),esk2_2(X1,noc)),esk2_2(X1,noc))),inference(spm,[status(thm)],[74,431,theory(equality)])).
% cnf(8504,plain,(nevera(X1,X2)|~nevera(X2,X1)),inference(spm,[status(thm)],[434,59,theory(equality)])).
% cnf(13377,plain,(model(esk24_2(esk1_2(thm,noc),esk2_2(thm,noc)),esk2_2(thm,noc))|nevera(thm,noc)),inference(spm,[status(thm)],[477,430,theory(equality)])).
% cnf(1404721,plain,(nevera(thm,noc)),inference(csr,[status(thm)],[13377,7844])).
% cnf(1404727,plain,(nevera(noc,thm)),inference(spm,[status(thm)],[8504,1404721,theory(equality)])).
% cnf(1404868,plain,($false),inference(sr,[status(thm)],[1404727,325,theory(equality)])).
% cnf(1404869,plain,($false),1404868,['proof']).
% # SZS output end CNFRefutation
% PrfWatch: 26.45 CPU 16.63 WC
% FINAL PrfWatch: 26.45 CPU 16.63 WC
% SZS output end Solution for /tmp/SystemOnTPTP22387/KRS235+1.tptp
% 
%------------------------------------------------------------------------------