TSTP Solution File: MGT037+2 by Etableau---0.67

View Problem - Process Solution 
%------------------------------------------------------------------------------
% File     : Etableau---0.67
% Problem  : MGT037+2 : TPTP v8.1.0. Released v2.0.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : etableau --auto --tsmdo --quicksat=10000 --tableau=1 --tableau-saturation=1 -s -p --tableau-cores=8 --cpu-limit=%d %s

% Computer : n032.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  : 600s
% DateTime : Sun Jul 17 22:10:34 EDT 2022

% Result   : CounterSatisfiable 0.12s 0.29s
% Output   : CNFRefutation 0.12s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.02/0.07  % Problem  : MGT037+2 : TPTP v8.1.0. Released v2.0.0.
% 0.02/0.08  % Command  : etableau --auto --tsmdo --quicksat=10000 --tableau=1 --tableau-saturation=1 -s -p --tableau-cores=8 --cpu-limit=%d %s
% 0.08/0.27  % Computer : n032.cluster.edu
% 0.08/0.27  % Model    : x86_64 x86_64
% 0.08/0.27  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.08/0.27  % Memory   : 8042.1875MB
% 0.08/0.27  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.08/0.27  % CPULimit : 300
% 0.08/0.27  % WCLimit  : 600
% 0.08/0.27  % DateTime : Thu Jun  9 10:55:07 EDT 2022
% 0.08/0.27  % CPUTime  : 
% 0.12/0.29  # No SInE strategy applied
% 0.12/0.29  # Auto-Mode selected heuristic G_E___107_C36_F1_PI_AE_Q4_CS_SP_PS_S0Y
% 0.12/0.29  # and selection function SelectMaxLComplexAvoidPosPred.
% 0.12/0.29  #
% 0.12/0.29  # Presaturation interreduction done
% 0.12/0.29  # Number of axioms: 27 Number of unprocessed: 27
% 0.12/0.29  # Tableaux proof search.
% 0.12/0.29  # APR header successfully linked.
% 0.12/0.29  # Hello from C++
% 0.12/0.29  # The folding up rule is enabled...
% 0.12/0.29  # Local unification is enabled...
% 0.12/0.29  # Any saturation attempts will use folding labels...
% 0.12/0.29  # 27 beginning clauses after preprocessing and clausification
% 0.12/0.29  # Creating start rules for all 4 conjectures.
% 0.12/0.29  # There are 4 start rule candidates:
% 0.12/0.29  # Found 5 unit axioms.
% 0.12/0.29  # Unsuccessfully attempted saturation on 1 start tableaux, moving on.
% 0.12/0.29  # 4 start rule tableaux created.
% 0.12/0.29  # 22 extension rule candidate clauses
% 0.12/0.29  # 5 unit axiom clauses
% 0.12/0.29  
% 0.12/0.29  # Requested 8, 32 cores available to the main process.
% 0.12/0.29  # There are not enough tableaux to fork, creating more from the initial 4
% 0.12/0.29  # Returning from population with 21 new_tableaux and 0 remaining starting tableaux.
% 0.12/0.29  # We now have 21 tableaux to operate on
% 0.12/0.29  # 19806 Satisfiable branch
% 0.12/0.29  # 19807 Satisfiable branch
% 0.12/0.29  # 19805 Satisfiable branch
% 0.12/0.29  # Satisfiable branch found.
% 0.12/0.29  # 19808 Satisfiable branch
% 0.12/0.29  # There were 1 total branch saturation attempts.
% 0.12/0.29  # There were 0 of these attempts blocked.
% 0.12/0.29  # There were 0 deferred branch saturation attempts.
% 0.12/0.29  # There were 0 free duplicated saturations.
% 0.12/0.29  # There were 0 total successful branch saturations.
% 0.12/0.29  # There were 0 successful branch saturations in interreduction.
% 0.12/0.29  # There were 0 successful branch saturations on the branch.
% 0.12/0.29  # There were 0 successful branch saturations after the branch.
% 0.12/0.29  # SZS status CounterSatisfiable for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # SZS output start for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # Begin clausification derivation
% 0.12/0.29  
% 0.12/0.29  # End clausification derivation
% 0.12/0.29  # Begin listing active clauses obtained from FOF to CNF conversion
% 0.12/0.29  cnf(i_0_27, negated_conjecture, (environment(esk3_0))).
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0))).
% 0.12/0.29  cnf(i_0_25, negated_conjecture, (greater_or_equal(esk4_0,appear(efficient_producers,esk3_0)))).
% 0.12/0.29  cnf(i_0_17, hypothesis, (greater(resilience(efficient_producers),resilience(first_movers)))).
% 0.12/0.29  cnf(i_0_24, negated_conjecture, (~greater(cardinality_at_time(efficient_producers,esk4_0),zero))).
% 0.12/0.29  cnf(i_0_10, plain, (subpopulation(efficient_producers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_11, plain, (subpopulation(first_movers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_14, plain, (~constant(X1)|~decreases(X1))).
% 0.12/0.29  cnf(i_0_13, plain, (cardinality_at_time(efficient_producers,X1)=zero|greater(cardinality_at_time(efficient_producers,X1),zero)|~in_environment(X2,X1)|~environment(X2))).
% 0.12/0.29  cnf(i_0_12, plain, (cardinality_at_time(X1,X2)!=zero|~greater(zero,growth_rate(X1,X2)))).
% 0.12/0.29  cnf(i_0_5, plain, (number_of_organizations(X1,X2)=zero|~in_environment(X1,X2)|~greater(appear(an_organisation,X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_20, hypothesis, (constant(number_of_organizations(X1,X2))|~constant(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_21, hypothesis, (~decreases(number_of_organizations(X1,X2))|~decreases(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_15, plain, (greater(appear(an_organisation,X1),X2)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_16, hypothesis, (greater(number_of_organizations(X1,X2),zero)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_4, plain, (greater(esk1_2(X1,X2),appear(efficient_producers,X1))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_8, plain, (subpopulation(esk2_2(X1,X2),X1,X2)|decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_2, plain, (greater(X1,esk1_2(X2,X1))|cardinality_at_time(efficient_producers,X1)!=zero|~greater_or_equal(X1,appear(efficient_producers,X2))|~environment(X2))).
% 0.12/0.29  cnf(i_0_3, plain, (in_environment(X1,esk1_2(X1,X2))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_1, plain, (greater(zero,growth_rate(efficient_producers,esk1_2(X1,X2)))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_22, hypothesis, (X1=first_movers|X1=efficient_producers|~subpopulation(X1,X2,X3)|~greater(cardinality_at_time(X1,X3),zero)|~environment(X2))).
% 0.12/0.29  cnf(i_0_7, plain, (decreases(number_of_organizations(X1,X2))|greater(cardinality_at_time(esk2_2(X1,X2),X2),zero)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_18, hypothesis, (constant(resources(X1,X2))|greater(equilibrium(X1),X2)|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~environment(X1))).
% 0.12/0.29  cnf(i_0_19, hypothesis, (decreases(resources(X1,X2))|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~greater(equilibrium(X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_9, plain, (cardinality_at_time(X1,X2)=zero|number_of_organizations(X3,X2)!=zero|~subpopulation(X1,X3,X2)|~in_environment(X3,X2)|~environment(X3))).
% 0.12/0.29  cnf(i_0_6, plain, (decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~greater(zero,growth_rate(esk2_2(X1,X2),X2))|~environment(X1))).
% 0.12/0.29  cnf(i_0_23, hypothesis, (greater(zero,growth_rate(X1,X2))|~in_environment(X3,X2)|~greater(zero,growth_rate(X4,X2))|~greater(resilience(X4),resilience(X1))|~environment(X3))).
% 0.12/0.29  # End listing active clauses.  There is an equivalent clause to each of these in the clausification!
% 0.12/0.29  # Begin printing tableau
% 0.12/0.29  # Found 4 steps
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0)), inference(start_rule)).
% 0.12/0.29  cnf(i_0_30, plain, (in_environment(esk3_0,esk4_0)), inference(extension_rule, [i_0_9])).
% 0.12/0.29  cnf(i_0_283, plain, (~environment(esk3_0)), inference(closure_rule, [i_0_27])).
% 0.12/0.29  cnf(i_0_279, plain, (cardinality_at_time(X3,esk4_0)=zero), inference(extension_rule, [i_0_12])).
% 0.12/0.29  # End printing tableau
% 0.12/0.29  # SZS output end
% 0.12/0.29  # Branches closed with saturation will be marked with an "s"
% 0.12/0.29  # Satisfiable branch found.
% 0.12/0.29  # There were 1 total branch saturation attempts.
% 0.12/0.29  # There were 0 of these attempts blocked.
% 0.12/0.29  # There were 0 deferred branch saturation attempts.
% 0.12/0.29  # There were 0 free duplicated saturations.
% 0.12/0.29  # There were 0 total successful branch saturations.
% 0.12/0.29  # There were 0 successful branch saturations in interreduction.
% 0.12/0.29  # There were 0 successful branch saturations on the branch.
% 0.12/0.29  # There were 0 successful branch saturations after the branch.
% 0.12/0.29  # SZS status CounterSatisfiable for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # SZS output start for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # Begin clausification derivation
% 0.12/0.29  
% 0.12/0.29  # End clausification derivation
% 0.12/0.29  # Begin listing active clauses obtained from FOF to CNF conversion
% 0.12/0.29  cnf(i_0_27, negated_conjecture, (environment(esk3_0))).
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0))).
% 0.12/0.29  cnf(i_0_25, negated_conjecture, (greater_or_equal(esk4_0,appear(efficient_producers,esk3_0)))).
% 0.12/0.29  cnf(i_0_17, hypothesis, (greater(resilience(efficient_producers),resilience(first_movers)))).
% 0.12/0.29  cnf(i_0_24, negated_conjecture, (~greater(cardinality_at_time(efficient_producers,esk4_0),zero))).
% 0.12/0.29  cnf(i_0_10, plain, (subpopulation(efficient_producers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_11, plain, (subpopulation(first_movers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_14, plain, (~constant(X1)|~decreases(X1))).
% 0.12/0.29  cnf(i_0_13, plain, (cardinality_at_time(efficient_producers,X1)=zero|greater(cardinality_at_time(efficient_producers,X1),zero)|~in_environment(X2,X1)|~environment(X2))).
% 0.12/0.29  cnf(i_0_12, plain, (cardinality_at_time(X1,X2)!=zero|~greater(zero,growth_rate(X1,X2)))).
% 0.12/0.29  cnf(i_0_5, plain, (number_of_organizations(X1,X2)=zero|~in_environment(X1,X2)|~greater(appear(an_organisation,X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_20, hypothesis, (constant(number_of_organizations(X1,X2))|~constant(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_21, hypothesis, (~decreases(number_of_organizations(X1,X2))|~decreases(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_15, plain, (greater(appear(an_organisation,X1),X2)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_16, hypothesis, (greater(number_of_organizations(X1,X2),zero)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_4, plain, (greater(esk1_2(X1,X2),appear(efficient_producers,X1))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_8, plain, (subpopulation(esk2_2(X1,X2),X1,X2)|decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_2, plain, (greater(X1,esk1_2(X2,X1))|cardinality_at_time(efficient_producers,X1)!=zero|~greater_or_equal(X1,appear(efficient_producers,X2))|~environment(X2))).
% 0.12/0.29  cnf(i_0_3, plain, (in_environment(X1,esk1_2(X1,X2))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_1, plain, (greater(zero,growth_rate(efficient_producers,esk1_2(X1,X2)))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_22, hypothesis, (X1=first_movers|X1=efficient_producers|~subpopulation(X1,X2,X3)|~greater(cardinality_at_time(X1,X3),zero)|~environment(X2))).
% 0.12/0.29  cnf(i_0_7, plain, (decreases(number_of_organizations(X1,X2))|greater(cardinality_at_time(esk2_2(X1,X2),X2),zero)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_18, hypothesis, (constant(resources(X1,X2))|greater(equilibrium(X1),X2)|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~environment(X1))).
% 0.12/0.29  cnf(i_0_19, hypothesis, (decreases(resources(X1,X2))|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~greater(equilibrium(X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_9, plain, (cardinality_at_time(X1,X2)=zero|number_of_organizations(X3,X2)!=zero|~subpopulation(X1,X3,X2)|~in_environment(X3,X2)|~environment(X3))).
% 0.12/0.29  cnf(i_0_6, plain, (decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~greater(zero,growth_rate(esk2_2(X1,X2),X2))|~environment(X1))).
% 0.12/0.29  cnf(i_0_23, hypothesis, (greater(zero,growth_rate(X1,X2))|~in_environment(X3,X2)|~greater(zero,growth_rate(X4,X2))|~greater(resilience(X4),resilience(X1))|~environment(X3))).
% 0.12/0.29  # End listing active clauses.  There is an equivalent clause to each of these in the clausification!
% 0.12/0.29  # Begin printing tableau
% 0.12/0.29  # Found 4 steps# Satisfiable branch found.
% 0.12/0.29  # Satisfiable branch found.
% 0.12/0.29  # There were 1 total branch saturation attempts.
% 0.12/0.29  # There were 0 of these attempts blocked.
% 0.12/0.29  # There were 0 deferred branch saturation attempts.
% 0.12/0.29  # There were 0 free duplicated saturations.
% 0.12/0.29  # There were 0 total successful branch saturations.
% 0.12/0.29  # There were 0 successful branch saturations in interreduction.
% 0.12/0.29  # There were 0 successful branch saturations on the branch.
% 0.12/0.29  # There were 0 successful branch saturations after the branch.
% 0.12/0.29  # There were 1 total branch saturation attempts.
% 0.12/0.29  # There were 0 of these attempts blocked.
% 0.12/0.29  # There were 0 deferred branch saturation attempts.
% 0.12/0.29  # There were 0 free duplicated saturations.
% 0.12/0.29  # There were 0 total successful branch saturations.
% 0.12/0.29  # There were 0 successful branch saturations in interreduction.
% 0.12/0.29  # There were 0 successful branch saturations on the branch.
% 0.12/0.29  # There were 0 successful branch saturations after the branch.
% 0.12/0.29  
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0)), inference(start_rule)).
% 0.12/0.29  cnf(i_0_30, plain, (in_environment(esk3_0,esk4_0)), inference(extension_rule, [i_0_19])).
% 0.12/0.29  cnf(i_0_278, plain, (~environment(esk3_0)), inference(closure_rule, [i_0_27])).
% 0.12/0.29  cnf(i_0_274, plain, (decreases(resources(esk3_0,esk4_0))), inference(extension_rule, [i_0_14])).
% 0.12/0.29  # End printing tableau
% 0.12/0.29  # SZS output end
% 0.12/0.29  # Branches closed with saturation will be marked with an "s"
% 0.12/0.29  # SZS status CounterSatisfiable for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # SZS output start for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # Begin clausification derivation
% 0.12/0.29  
% 0.12/0.29  # End clausification derivation
% 0.12/0.29  # Begin listing active clauses obtained from FOF to CNF conversion
% 0.12/0.29  cnf(i_0_27, negated_conjecture, (environment(esk3_0))).
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0))).
% 0.12/0.29  cnf(i_0_25, negated_conjecture, (greater_or_equal(esk4_0,appear(efficient_producers,esk3_0)))).
% 0.12/0.29  cnf(i_0_17, hypothesis, (greater(resilience(efficient_producers),resilience(first_movers)))).
% 0.12/0.29  cnf(i_0_24, negated_conjecture, (~greater(cardinality_at_time(efficient_producers,esk4_0),zero))).
% 0.12/0.29  cnf(i_0_10, plain, (subpopulation(efficient_producers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_11, plain, (subpopulation(first_movers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_14, plain, (~constant(X1)|~decreases(X1))).
% 0.12/0.29  cnf(i_0_13, plain, (cardinality_at_time(efficient_producers,X1)=zero|greater(cardinality_at_time(efficient_producers,X1),zero)|~in_environment(X2,X1)|~environment(X2))).
% 0.12/0.29  cnf(i_0_12, plain, (cardinality_at_time(X1,X2)!=zero|~greater(zero,growth_rate(X1,X2)))).
% 0.12/0.29  cnf(i_0_5, plain, (number_of_organizations(X1,X2)=zero|~in_environment(X1,X2)|~greater(appear(an_organisation,X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_20, hypothesis, (constant(number_of_organizations(X1,X2))|~constant(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_21, hypothesis, (~decreases(number_of_organizations(X1,X2))|~decreases(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_15, plain, (greater(appear(an_organisation,X1),X2)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_16, hypothesis, (greater(number_of_organizations(X1,X2),zero)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_4, plain, (greater(esk1_2(X1,X2),appear(efficient_producers,X1))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_8, plain, (subpopulation(esk2_2(X1,X2),X1,X2)|decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_2, plain, (greater(X1,esk1_2(X2,X1))|cardinality_at_time(efficient_producers,X1)!=zero|~greater_or_equal(X1,appear(efficient_producers,X2))|~environment(X2))).
% 0.12/0.29  cnf(i_0_3, plain, (in_environment(X1,esk1_2(X1,X2))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_1, plain, (greater(zero,growth_rate(efficient_producers,esk1_2(X1,X2)))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_22, hypothesis, (X1=first_movers|X1=efficient_producers|~subpopulation(X1,X2,X3)|~greater(cardinality_at_time(X1,X3),zero)|~environment(X2))).
% 0.12/0.29  cnf(i_0_7, plain, (decreases(number_of_organizations(X1,X2))|greater(cardinality_at_time(esk2_2(X1,X2),X2),zero)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_18, hypothesis, (constant(resources(X1,X2))|greater(equilibrium(X1),X2)|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~environment(X1))).
% 0.12/0.29  cnf(i_0_19, hypothesis, (decreases(resources(X1,X2))|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~greater(equilibrium(X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_9, plain, (cardinality_at_time(X1,X2)=zero|number_of_organizations(X3,X2)!=zero|~subpopulation(X1,X3,X2)|~in_environment(X3,X2)|~environment(X3))).
% 0.12/0.29  cnf(i_0_6, plain, (decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~greater(zero,growth_rate(esk2_2(X1,X2),X2))|~environment(X1))).
% 0.12/0.29  cnf(i_0_23, hypothesis, (greater(zero,growth_rate(X1,X2))|~in_environment(X3,X2)|~greater(zero,growth_rate(X4,X2))|~greater(resilience(X4),resilience(X1))|~environment(X3))).
% 0.12/0.29  # End listing active clauses.  There is an equivalent clause to each of these in the clausification!
% 0.12/0.29  # Begin printing tableau
% 0.12/0.29  # Found 4 steps# SZS status CounterSatisfiable for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # SZS output start for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.12/0.29  # Begin clausification derivation
% 0.12/0.29  
% 0.12/0.29  # End clausification derivation
% 0.12/0.29  # Begin listing active clauses obtained from FOF to CNF conversion
% 0.12/0.29  cnf(i_0_27, negated_conjecture, (environment(esk3_0))).
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0))).
% 0.12/0.29  cnf(i_0_25, negated_conjecture, (greater_or_equal(esk4_0,appear(efficient_producers,esk3_0)))).
% 0.12/0.29  cnf(i_0_17, hypothesis, (greater(resilience(efficient_producers),resilience(first_movers)))).
% 0.12/0.29  cnf(i_0_24, negated_conjecture, (~greater(cardinality_at_time(efficient_producers,esk4_0),zero))).
% 0.12/0.29  cnf(i_0_10, plain, (subpopulation(efficient_producers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_11, plain, (subpopulation(first_movers,X1,X2)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_14, plain, (~constant(X1)|~decreases(X1))).
% 0.12/0.29  cnf(i_0_13, plain, (cardinality_at_time(efficient_producers,X1)=zero|greater(cardinality_at_time(efficient_producers,X1),zero)|~in_environment(X2,X1)|~environment(X2))).
% 0.12/0.29  cnf(i_0_12, plain, (cardinality_at_time(X1,X2)!=zero|~greater(zero,growth_rate(X1,X2)))).
% 0.12/0.29  cnf(i_0_5, plain, (number_of_organizations(X1,X2)=zero|~in_environment(X1,X2)|~greater(appear(an_organisation,X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_20, hypothesis, (constant(number_of_organizations(X1,X2))|~constant(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_21, hypothesis, (~decreases(number_of_organizations(X1,X2))|~decreases(resources(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_15, plain, (greater(appear(an_organisation,X1),X2)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_16, hypothesis, (greater(number_of_organizations(X1,X2),zero)|~in_environment(X1,X2)|~greater_or_equal(X2,appear(an_organisation,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_4, plain, (greater(esk1_2(X1,X2),appear(efficient_producers,X1))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_8, plain, (subpopulation(esk2_2(X1,X2),X1,X2)|decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_2, plain, (greater(X1,esk1_2(X2,X1))|cardinality_at_time(efficient_producers,X1)!=zero|~greater_or_equal(X1,appear(efficient_producers,X2))|~environment(X2))).
% 0.12/0.29  cnf(i_0_3, plain, (in_environment(X1,esk1_2(X1,X2))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_1, plain, (greater(zero,growth_rate(efficient_producers,esk1_2(X1,X2)))|cardinality_at_time(efficient_producers,X2)!=zero|~greater_or_equal(X2,appear(efficient_producers,X1))|~environment(X1))).
% 0.12/0.29  cnf(i_0_22, hypothesis, (X1=first_movers|X1=efficient_producers|~subpopulation(X1,X2,X3)|~greater(cardinality_at_time(X1,X3),zero)|~environment(X2))).
% 0.12/0.29  cnf(i_0_7, plain, (decreases(number_of_organizations(X1,X2))|greater(cardinality_at_time(esk2_2(X1,X2),X2),zero)|~in_environment(X1,X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_18, hypothesis, (constant(resources(X1,X2))|greater(equilibrium(X1),X2)|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~environment(X1))).
% 0.12/0.29  cnf(i_0_19, hypothesis, (decreases(resources(X1,X2))|~in_environment(X1,X2)|~greater(number_of_organizations(X1,X2),zero)|~greater(equilibrium(X1),X2)|~environment(X1))).
% 0.12/0.29  cnf(i_0_9, plain, (cardinality_at_time(X1,X2)=zero|number_of_organizations(X3,X2)!=zero|~subpopulation(X1,X3,X2)|~in_environment(X3,X2)|~environment(X3))).
% 0.12/0.29  cnf(i_0_6, plain, (decreases(number_of_organizations(X1,X2))|~in_environment(X1,X2)|~greater(zero,growth_rate(esk2_2(X1,X2),X2))|~environment(X1))).
% 0.12/0.29  cnf(i_0_23, hypothesis, (greater(zero,growth_rate(X1,X2))|~in_environment(X3,X2)|~greater(zero,growth_rate(X4,X2))|~greater(resilience(X4),resilience(X1))|~environment(X3))).
% 0.12/0.29  # End listing active clauses.  There is an equivalent clause to each of these in the clausification!
% 0.12/0.29  # Begin printing tableau
% 0.12/0.29  # Found 4 steps
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0)), inference(start_rule)).
% 0.12/0.29  cnf(i_0_30, plain, (in_environment(esk3_0,esk4_0)), inference(extension_rule, [i_0_18])).
% 0.12/0.29  cnf(i_0_273, plain, (~environment(esk3_0)), inference(closure_rule, [i_0_27])).
% 0.12/0.29  cnf(i_0_269, plain, (constant(resources(esk3_0,esk4_0))), inference(extension_rule, [i_0_14])).
% 0.12/0.29  # End printing tableau
% 0.12/0.29  # SZS output end
% 0.12/0.29  # Branches closed with saturation will be marked with an "s"
% 0.12/0.29  
% 0.12/0.29  cnf(i_0_26, negated_conjecture, (in_environment(esk3_0,esk4_0)), inference(start_rule)).
% 0.12/0.29  cnf(i_0_30, plain, (in_environment(esk3_0,esk4_0)), inference(extension_rule, [i_0_6])).
% 0.12/0.29  cnf(i_0_287, plain, (~environment(esk3_0)), inference(closure_rule, [i_0_27])).
% 0.12/0.29  cnf(i_0_284, plain, (decreases(number_of_organizations(esk3_0,esk4_0))), inference(extension_rule, [i_0_14])).
% 0.12/0.29  # End printing tableau
% 0.12/0.29  # SZS output end
% 0.12/0.29  # Branches closed with saturation will be marked with an "s"
% 0.12/0.29  # Child (19806) has found a proof.
% 0.12/0.29  
% 0.12/0.30  # Proof search is over...
% 0.12/0.30  # Freeing feature tree
%------------------------------------------------------------------------------