fond
Model Checking Contest 2023
13th edition, Paris, France, April 26, 2023 (at TOOLympics II)
Execution of r225-tall-167856407000041
Last Updated
May 14, 2023

About the Execution of Marcie for HypertorusGrid-PT-d2k3p2b04

Execution Summary
Max Memory
Used (MB)
Time wait (ms) CPU Usage (ms) I/O Wait (ms) Computed Result Execution
Status
13176.039 3600000.00 3600080.00 50.00 ??????????FTT??? normal

Execution Chart

We display below the execution chart for this examination (boot time has been removed).

Trace from the execution

Formatting '/data/fkordon/mcc2023-input.r225-tall-167856407000041.qcow2', fmt=qcow2 size=4294967296 backing_file=/data/fkordon/mcc2023-input.qcow2 cluster_size=65536 lazy_refcounts=off refcount_bits=16
Waiting for the VM to be ready (probing ssh)
.................
=====================================================================
Generated by BenchKit 2-5348
Executing tool marcie
Input is HypertorusGrid-PT-d2k3p2b04, examination is CTLCardinality
Time confinement is 3600 seconds
Memory confinement is 16384 MBytes
Number of cores is 1
Run identifier is r225-tall-167856407000041
=====================================================================

--------------------
preparation of the directory to be used:
/home/mcc/execution
total 560K
-rw-r--r-- 1 mcc users 7.9K Feb 26 11:08 CTLCardinality.txt
-rw-r--r-- 1 mcc users 72K Feb 26 11:08 CTLCardinality.xml
-rw-r--r-- 1 mcc users 6.0K Feb 26 10:57 CTLFireability.txt
-rw-r--r-- 1 mcc users 41K Feb 26 10:57 CTLFireability.xml
-rw-r--r-- 1 mcc users 4.2K Jan 29 11:40 GenericPropertiesDefinition.xml
-rw-r--r-- 1 mcc users 6.3K Jan 29 11:40 GenericPropertiesVerdict.xml
-rw-r--r-- 1 mcc users 4.3K Feb 25 16:17 LTLCardinality.txt
-rw-r--r-- 1 mcc users 26K Feb 25 16:17 LTLCardinality.xml
-rw-r--r-- 1 mcc users 2.9K Feb 25 16:17 LTLFireability.txt
-rw-r--r-- 1 mcc users 16K Feb 25 16:17 LTLFireability.xml
-rw-r--r-- 1 mcc users 11K Feb 26 11:18 ReachabilityCardinality.txt
-rw-r--r-- 1 mcc users 89K Feb 26 11:18 ReachabilityCardinality.xml
-rw-r--r-- 1 mcc users 19K Feb 26 11:13 ReachabilityFireability.txt
-rw-r--r-- 1 mcc users 132K Feb 26 11:13 ReachabilityFireability.xml
-rw-r--r-- 1 mcc users 1.9K Feb 25 16:17 UpperBounds.txt
-rw-r--r-- 1 mcc users 3.9K Feb 25 16:17 UpperBounds.xml
-rw-r--r-- 1 mcc users 6 Mar 5 18:22 equiv_col
-rw-r--r-- 1 mcc users 10 Mar 5 18:22 instance
-rw-r--r-- 1 mcc users 6 Mar 5 18:22 iscolored
-rwxr-xr-x 1 mcc users 79K Mar 5 18:22 model.pnml

--------------------
content from stdout:

=== Data for post analysis generated by BenchKit (invocation template)

The expected result is a vector of booleans
BOOL_VECTOR

here is the order used to build the result vector(from text file)
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-00
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-01
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-02
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-03
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-04
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-05
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-06
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-07
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-08
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-09
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-10
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-11
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-12
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-13
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-14
FORMULA_NAME HypertorusGrid-PT-d2k3p2b04-CTLCardinality-15

=== Now, execution of the tool begins

BK_START 1678602395642

bash -c /home/mcc/BenchKit/BenchKit_head.sh 2> STDERR ; echo ; echo -n "BK_STOP " ; date -u +%s%3N
Invoking MCC driver with
BK_TOOL=marcie
BK_EXAMINATION=CTLCardinality
BK_BIN_PATH=/home/mcc/BenchKit/bin/
BK_TIME_CONFINEMENT=3600
BK_INPUT=HypertorusGrid-PT-d2k3p2b04
Not applying reductions.
Model is PT
CTLCardinality PT
timeout --kill-after=10s --signal=SIGINT 1m for testing only

Marcie built on Linux at 2019-11-18.
A model checker for Generalized Stochastic Petri nets

authors: Alex Tovchigrechko (IDD package and CTL model checking)

Martin Schwarick (Symbolic numerical analysis and CSL model checking)

Christian Rohr (Simulative and approximative numerical model checking)

marcie@informatik.tu-cottbus.de

called as: /home/mcc/BenchKit/bin//../marcie/bin/marcie --net-file=model.pnml --mcc-file=CTLCardinality.xml --memory=6 --mcc-mode

parse successfull
net created successfully

Net: HypertorusGrid_PT_d2k3p2b04
(NrP: 117 NrTr: 144 NrArc: 576)

parse formulas
formulas created successfully
place and transition orderings generation:0m 0.001sec

net check time: 0m 0.000sec

init dd package: 0m 2.869sec


before gc: list nodes free: 85694

after gc: idd nodes used:42398, unused:63957602; list nodes free:452671872

RS generation: 14m 7.058sec


-> reachability set: #nodes 27808 (2.8e+04) #states 547,584,122,014,766,883,484,149,027,370,223,872 (35)



starting MCC model checker
--------------------------

checking: AG [EF [4<=po_d1_n1_3_1]]
normalized: ~ [E [true U ~ [E [true U 4<=po_d1_n1_3_1]]]]

abstracting: (4<=po_d1_n1_3_1)
states: 0
-> the formula is FALSE

FORMULA HypertorusGrid-PT-d2k3p2b04-CTLCardinality-10 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT

MC time: 0m15.254sec

checking: EG [pb_d2_n2_1_1<=2]
normalized: EG [pb_d2_n2_1_1<=2]

abstracting: (pb_d2_n2_1_1<=2)
states: 414,056,897,615,382,018,906,435,531,019,430,672 (35)
MC time: 3m 6.481sec

checking: EG [pol_d2_n1_1_1<=4]
normalized: EG [pol_d2_n1_1_1<=4]

abstracting: (pol_d2_n1_1_1<=4)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)

EG iterations: 0
-> the formula is TRUE

FORMULA HypertorusGrid-PT-d2k3p2b04-CTLCardinality-12 TRUE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT

MC time: 0m 0.137sec

checking: ~ [AG [EF [A [[AG [pil_d1_n1_3_1<=pil_d1_n1_3_1] & [pol_d2_n1_3_1<=4 | 2<=pb_d1_n2_1_3]] U pil_d1_n1_3_3<=pb_d2_n2_1_1]]]]
normalized: E [true U ~ [E [true U [~ [EG [~ [pil_d1_n1_3_3<=pb_d2_n2_1_1]]] & ~ [E [~ [pil_d1_n1_3_3<=pb_d2_n2_1_1] U [~ [[[pol_d2_n1_3_1<=4 | 2<=pb_d1_n2_1_3] & ~ [E [true U ~ [pil_d1_n1_3_1<=pil_d1_n1_3_1]]]]] & ~ [pil_d1_n1_3_3<=pb_d2_n2_1_1]]]]]]]]

abstracting: (pil_d1_n1_3_3<=pb_d2_n2_1_1)
states: 429,424,056,826,193,669,721,510,254,010,036,212 (35)
abstracting: (pil_d1_n1_3_1<=pil_d1_n1_3_1)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (2<=pb_d1_n2_1_3)
states: 218,424,933,743,865,155,613,441,949,721,114,176 (35)
abstracting: (pol_d2_n1_3_1<=4)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (pil_d1_n1_3_3<=pb_d2_n2_1_1)
states: 429,424,056,826,193,669,721,510,254,010,036,212 (35)
abstracting: (pil_d1_n1_3_3<=pb_d2_n2_1_1)
states: 429,424,056,826,193,669,721,510,254,010,036,212 (35)
MC time: 3m53.635sec

checking: A [AF [4<=po_d1_n1_3_1] U ~ [AF [[E [EF [1<=po_d1_n1_3_2] U [pb_d1_n2_3_2<=pb_d2_n2_2_2 | pil_d2_n1_3_2<=pol_d2_n1_2_1]] & AX [EF [3<=pol_d2_n1_1_3]]]]]]
normalized: [~ [EG [~ [EG [~ [[E [E [true U 1<=po_d1_n1_3_2] U [pb_d1_n2_3_2<=pb_d2_n2_2_2 | pil_d2_n1_3_2<=pol_d2_n1_2_1]] & ~ [EX [~ [E [true U 3<=pol_d2_n1_1_3]]]]]]]]]] & ~ [E [~ [EG [~ [[E [E [true U 1<=po_d1_n1_3_2] U [pb_d1_n2_3_2<=pb_d2_n2_2_2 | pil_d2_n1_3_2<=pol_d2_n1_2_1]] & ~ [EX [~ [E [true U 3<=pol_d2_n1_1_3]]]]]]]] U [~ [EG [~ [[E [E [true U 1<=po_d1_n1_3_2] U [pb_d1_n2_3_2<=pb_d2_n2_2_2 | pil_d2_n1_3_2<=pol_d2_n1_2_1]] & ~ [EX [~ [E [true U 3<=pol_d2_n1_1_3]]]]]]]] & EG [~ [4<=po_d1_n1_3_1]]]]]]

abstracting: (4<=po_d1_n1_3_1)
states: 0

EG iterations: 0
abstracting: (3<=pol_d2_n1_1_3)
states: 0
MC time: 3m38.226sec

checking: [~ [EG [EF [pi_d2_n1_2_1<=pi_d1_n1_3_1]]] | [AF [A [AF [EF [pb_d1_n1_3_2<=pb_d1_n2_3_2]] U AX [[pb_d1_n2_3_1<=2 | pb_d1_n1_1_2<=1]]]] & EX [~ [[pb_d1_n1_2_3<=4 | ~ [po_d2_n1_3_1<=0]]]]]]
normalized: [~ [EG [E [true U pi_d2_n1_2_1<=pi_d1_n1_3_1]]] | [EX [~ [[pb_d1_n1_2_3<=4 | ~ [po_d2_n1_3_1<=0]]]] & ~ [EG [~ [[~ [EG [EX [~ [[pb_d1_n2_3_1<=2 | pb_d1_n1_1_2<=1]]]]] & ~ [E [EX [~ [[pb_d1_n2_3_1<=2 | pb_d1_n1_1_2<=1]]] U [EG [~ [E [true U pb_d1_n1_3_2<=pb_d1_n2_3_2]]] & EX [~ [[pb_d1_n2_3_1<=2 | pb_d1_n1_1_2<=1]]]]]]]]]]]]

abstracting: (pb_d1_n1_1_2<=1)
states: 329,159,188,270,901,727,870,707,077,649,109,696 (35)
abstracting: (pb_d1_n2_3_1<=2)
states: 414,056,897,615,382,018,906,435,531,019,430,672 (35)

before gc: list nodes free: 1186440

after gc: idd nodes used:3260078, unused:60739922; list nodes free:461050679
.abstracting: (pb_d1_n1_3_2<=pb_d1_n2_3_2)
states: 333,413,612,673,421,459,713,954,687,968,784,326 (35)
MC time: 2m30.018sec

checking: AG [EF [~ [[pb_d1_n2_1_3<=pol_d1_n1_2_1 & [[A [pol_d2_n1_1_3<=3 U pb_d1_n1_1_2<=pi_d2_n1_2_1] & E [pil_d2_n1_1_3<=po_d2_n1_2_1 U 3<=pol_d2_n1_1_2]] & pi_d2_n1_1_2<=3]]]]]
normalized: ~ [E [true U ~ [E [true U ~ [[pb_d1_n2_1_3<=pol_d1_n1_2_1 & [pi_d2_n1_1_2<=3 & [E [pil_d2_n1_1_3<=po_d2_n1_2_1 U 3<=pol_d2_n1_1_2] & [~ [EG [~ [pb_d1_n1_1_2<=pi_d2_n1_2_1]]] & ~ [E [~ [pb_d1_n1_1_2<=pi_d2_n1_2_1] U [~ [pol_d2_n1_1_3<=3] & ~ [pb_d1_n1_1_2<=pi_d2_n1_2_1]]]]]]]]]]]]]

abstracting: (pb_d1_n1_1_2<=pi_d2_n1_2_1)
states: 250,978,967,973,337,203,512,061,130,671,118,876 (35)
abstracting: (pol_d2_n1_1_3<=3)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (pb_d1_n1_1_2<=pi_d2_n1_2_1)
states: 250,978,967,973,337,203,512,061,130,671,118,876 (35)
abstracting: (pb_d1_n1_1_2<=pi_d2_n1_2_1)
states: 250,978,967,973,337,203,512,061,130,671,118,876 (35)
MC time: 2m37.184sec

checking: [E [~ [[~ [pb_d1_n2_2_3<=pb_d1_n2_1_3] & AX [~ [4<=pbl_2_2]]]] U [~ [A [~ [E [pil_d2_n1_2_1<=po_d1_n1_1_1 U 2<=pi_d2_n1_3_3]] U AG [po_d2_n1_1_2<=2]]] & ~ [A [2<=pi_d1_n1_2_3 U pb_d2_n1_1_3<=3]]]] & EG [po_d2_n1_3_1<=1]]
normalized: [E [~ [[~ [EX [4<=pbl_2_2]] & ~ [pb_d1_n2_2_3<=pb_d1_n2_1_3]]] U [~ [[~ [EG [~ [pb_d2_n1_1_3<=3]]] & ~ [E [~ [pb_d2_n1_1_3<=3] U [~ [2<=pi_d1_n1_2_3] & ~ [pb_d2_n1_1_3<=3]]]]]] & ~ [[~ [EG [E [true U ~ [po_d2_n1_1_2<=2]]]] & ~ [E [E [true U ~ [po_d2_n1_1_2<=2]] U [E [pil_d2_n1_2_1<=po_d1_n1_1_1 U 2<=pi_d2_n1_3_3] & E [true U ~ [po_d2_n1_1_2<=2]]]]]]]]] & EG [po_d2_n1_3_1<=1]]

abstracting: (po_d2_n1_3_1<=1)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)

EG iterations: 0
abstracting: (po_d2_n1_1_2<=2)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (2<=pi_d2_n1_3_3)
states: 0
abstracting: (pil_d2_n1_2_1<=po_d1_n1_1_1)
states: 351,620,606,256,164,238,954,776,550,146,471,882 (35)
abstracting: (po_d2_n1_1_2<=2)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (po_d2_n1_1_2<=2)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
.MC time: 2m 8.518sec

checking: AF [[E [~ [pol_d1_n1_1_2<=pil_d1_n1_3_1] U pil_d2_n1_2_3<=pb_d2_n1_3_2] & [4<=pb_d2_n2_3_3 | ~ [A [[[pi_d2_n1_2_3<=0 | pi_d2_n1_3_3<=4] | E [pb_d2_n1_1_3<=4 U pb_d2_n2_1_2<=1]] U AF [pbl_1_1<=2]]]]]]
normalized: ~ [EG [~ [[[4<=pb_d2_n2_3_3 | ~ [[~ [EG [EG [~ [pbl_1_1<=2]]]] & ~ [E [EG [~ [pbl_1_1<=2]] U [~ [[E [pb_d2_n1_1_3<=4 U pb_d2_n2_1_2<=1] | [pi_d2_n1_2_3<=0 | pi_d2_n1_3_3<=4]]] & EG [~ [pbl_1_1<=2]]]]]]]] & E [~ [pol_d1_n1_1_2<=pil_d1_n1_3_1] U pil_d2_n1_2_3<=pb_d2_n1_3_2]]]]]

abstracting: (pil_d2_n1_2_3<=pb_d2_n1_3_2)
states: 429,424,056,826,193,669,721,510,254,010,036,212 (35)
abstracting: (pol_d1_n1_1_2<=pil_d1_n1_3_1)
states: 415,703,935,552,248,296,659,620,631,976,285,296 (35)
MC time: 1m59.316sec

checking: AF [[AG [[[[AF [pil_d2_n1_1_3<=2] | A [3<=pol_d2_n1_2_2 U pi_d1_n1_1_1<=0]] & AG [2<=pb_d2_n2_2_2]] | [~ [AG [po_d2_n1_3_1<=pi_d1_n1_1_1]] & ~ [po_d1_n1_1_2<=1]]]] & [pol_d1_n1_1_1<=3 | pb_d1_n2_3_2<=pol_d1_n1_2_3]]]
normalized: ~ [EG [~ [[[pol_d1_n1_1_1<=3 | pb_d1_n2_3_2<=pol_d1_n1_2_3] & ~ [E [true U ~ [[[~ [po_d1_n1_1_2<=1] & E [true U ~ [po_d2_n1_3_1<=pi_d1_n1_1_1]]] | [~ [E [true U ~ [2<=pb_d2_n2_2_2]]] & [[~ [EG [~ [pi_d1_n1_1_1<=0]]] & ~ [E [~ [pi_d1_n1_1_1<=0] U [~ [3<=pol_d2_n1_2_2] & ~ [pi_d1_n1_1_1<=0]]]]] | ~ [EG [~ [pil_d2_n1_1_3<=2]]]]]]]]]]]]]

abstracting: (pil_d2_n1_1_3<=2)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
.MC time: 2m12.291sec

checking: EX [~ [AX [[[E [pil_d2_n1_2_2<=pil_d1_n1_2_2 U 4<=po_d1_n1_1_1] & [[pi_d2_n1_3_3<=2 | po_d1_n1_2_1<=1] & E [po_d2_n1_2_1<=1 U pil_d1_n1_2_2<=pil_d2_n1_2_1]]] | pi_d2_n1_3_3<=pil_d1_n1_2_1]]]]
normalized: EX [EX [~ [[pi_d2_n1_3_3<=pil_d1_n1_2_1 | [[E [po_d2_n1_2_1<=1 U pil_d1_n1_2_2<=pil_d2_n1_2_1] & [pi_d2_n1_3_3<=2 | po_d1_n1_2_1<=1]] & E [pil_d2_n1_2_2<=pil_d1_n1_2_2 U 4<=po_d1_n1_1_1]]]]]]

abstracting: (4<=po_d1_n1_1_1)
states: 0
abstracting: (pil_d2_n1_2_2<=pil_d1_n1_2_2)
states: 415,703,935,552,248,296,659,620,631,976,285,296 (35)
abstracting: (po_d1_n1_2_1<=1)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (pi_d2_n1_3_3<=2)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (pil_d1_n1_2_2<=pil_d2_n1_2_1)
states: 415,703,935,552,248,296,659,620,631,976,285,296 (35)
abstracting: (po_d2_n1_2_1<=1)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
MC time: 1m41.101sec

checking: EF [~ [[~ [AX [~ [A [3<=pi_d1_n1_3_2 U pi_d2_n1_2_1<=pb_d2_n1_3_3]]]] & [~ [E [pb_d2_n1_2_1<=pol_d1_n1_2_2 U AF [2<=po_d2_n1_2_2]]] | [4<=pol_d1_n1_3_1 & [~ [E [pb_d1_n1_3_3<=pil_d1_n1_1_1 U 4<=po_d2_n1_2_1]] | pil_d1_n1_3_2<=1]]]]]]
normalized: E [true U ~ [[[[4<=pol_d1_n1_3_1 & [pil_d1_n1_3_2<=1 | ~ [E [pb_d1_n1_3_3<=pil_d1_n1_1_1 U 4<=po_d2_n1_2_1]]]] | ~ [E [pb_d2_n1_2_1<=pol_d1_n1_2_2 U ~ [EG [~ [2<=po_d2_n1_2_2]]]]]] & EX [[~ [EG [~ [pi_d2_n1_2_1<=pb_d2_n1_3_3]]] & ~ [E [~ [pi_d2_n1_2_1<=pb_d2_n1_3_3] U [~ [3<=pi_d1_n1_3_2] & ~ [pi_d2_n1_2_1<=pb_d2_n1_3_3]]]]]]]]]

abstracting: (pi_d2_n1_2_1<=pb_d2_n1_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
abstracting: (3<=pi_d1_n1_3_2)
states: 0
abstracting: (pi_d2_n1_2_1<=pb_d2_n1_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
abstracting: (pi_d2_n1_2_1<=pb_d2_n1_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
MC time: 1m43.372sec

checking: [EG [[[pol_d2_n1_1_1<=pi_d1_n1_2_1 & 3<=po_d1_n1_2_2] | AF [EG [[2<=pol_d1_n1_2_1 | 3<=po_d1_n1_3_1]]]]] & [[~ [[EX [~ [AF [4<=pil_d2_n1_2_1]]] & AG [EG [3<=pb_d1_n1_1_2]]]] | ~ [AX [[pol_d2_n1_3_2<=4 & pi_d2_n1_1_3<=pb_d2_n1_1_1]]]] & EF [AF [[pbl_2_1<=3 & EF [3<=pol_d1_n1_1_3]]]]]]
normalized: [[E [true U ~ [EG [~ [[pbl_2_1<=3 & E [true U 3<=pol_d1_n1_1_3]]]]]] & [EX [~ [[pol_d2_n1_3_2<=4 & pi_d2_n1_1_3<=pb_d2_n1_1_1]]] | ~ [[~ [E [true U ~ [EG [3<=pb_d1_n1_1_2]]]] & EX [EG [~ [4<=pil_d2_n1_2_1]]]]]]] & EG [[~ [EG [~ [EG [[2<=pol_d1_n1_2_1 | 3<=po_d1_n1_3_1]]]]] | [pol_d2_n1_1_1<=pi_d1_n1_2_1 & 3<=po_d1_n1_2_2]]]]

abstracting: (3<=po_d1_n1_2_2)
states: 0
abstracting: (pol_d2_n1_1_1<=pi_d1_n1_2_1)
states: 351,620,606,256,164,238,954,776,550,146,471,882 (35)
abstracting: (3<=po_d1_n1_3_1)
states: 0
abstracting: (2<=pol_d1_n1_2_1)
states: 0
.MC time: 1m47.140sec

checking: AX [[[[[AX [EG [pol_d1_n1_1_3<=0]] & ~ [AF [pbl_1_1<=pb_d2_n1_3_2]]] | AX [~ [AG [pb_d1_n2_1_3<=po_d2_n1_1_1]]]] & EG [pb_d2_n2_2_1<=pbl_3_3]] | [~ [AF [[[pil_d1_n1_3_2<=4 & pb_d2_n2_2_1<=4] | [pb_d2_n1_3_3<=0 | 3<=pol_d1_n1_1_1]]]] & ~ [EF [EF [pb_d1_n1_1_1<=0]]]]]]
normalized: ~ [EX [~ [[[~ [E [true U E [true U pb_d1_n1_1_1<=0]]] & EG [~ [[[pb_d2_n1_3_3<=0 | 3<=pol_d1_n1_1_1] | [pil_d1_n1_3_2<=4 & pb_d2_n2_2_1<=4]]]]] | [EG [pb_d2_n2_2_1<=pbl_3_3] & [~ [EX [~ [E [true U ~ [pb_d1_n2_1_3<=po_d2_n1_1_1]]]]] | [EG [~ [pbl_1_1<=pb_d2_n1_3_2]] & ~ [EX [~ [EG [pol_d1_n1_1_3<=0]]]]]]]]]]]

abstracting: (pol_d1_n1_1_3<=0)
states: 219,740,419,793,645,652,130,248,154,752,533,306 (35)
.MC time: 1m19.877sec

checking: [[[[EF [~ [A [pol_d2_n1_3_2<=3 U po_d1_n1_3_1<=pb_d1_n2_3_3]]] | ~ [E [po_d1_n1_2_3<=pbl_3_3 U ~ [pol_d1_n1_3_3<=0]]]] & A [~ [EG [[2<=pb_d1_n1_2_1 | pil_d1_n1_1_2<=po_d2_n1_3_3]]] U 2<=pb_d2_n2_3_1]] | AX [~ [pil_d2_n1_1_2<=1]]] & EF [2<=po_d2_n1_2_3]]
normalized: [E [true U 2<=po_d2_n1_2_3] & [~ [EX [pil_d2_n1_1_2<=1]] | [[~ [EG [~ [2<=pb_d2_n2_3_1]]] & ~ [E [~ [2<=pb_d2_n2_3_1] U [EG [[2<=pb_d1_n1_2_1 | pil_d1_n1_1_2<=po_d2_n1_3_3]] & ~ [2<=pb_d2_n2_3_1]]]]] & [~ [E [po_d1_n1_2_3<=pbl_3_3 U ~ [pol_d1_n1_3_3<=0]]] | E [true U ~ [[~ [EG [~ [po_d1_n1_3_1<=pb_d1_n2_3_3]]] & ~ [E [~ [po_d1_n1_3_1<=pb_d1_n2_3_3] U [~ [pol_d2_n1_3_2<=3] & ~ [po_d1_n1_3_1<=pb_d1_n2_3_3]]]]]]]]]]]

abstracting: (po_d1_n1_3_1<=pb_d1_n2_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
abstracting: (pol_d2_n1_3_2<=3)
states: 547,584,122,014,766,883,484,149,027,370,223,872 (35)
abstracting: (po_d1_n1_3_1<=pb_d1_n2_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
abstracting: (po_d1_n1_3_1<=pb_d1_n2_3_3)
states: 467,392,545,164,982,832,217,705,869,293,226,972 (35)
MC time: 1m19.119sec

checking: AF [[~ [[A [~ [A [pb_d2_n2_2_3<=2 U 3<=pi_d2_n1_1_3]] U [AG [1<=pol_d1_n1_2_1] & A [4<=pol_d1_n1_2_2 U 4<=pol_d2_n1_2_3]]] | [[~ [EX [pil_d2_n1_2_2<=pol_d2_n1_3_3]] & [[pil_d1_n1_1_1<=4 & pbl_2_3<=1] | E [pol_d1_n1_1_1<=2 U pi_d1_n1_2_3<=pil_d1_n1_3_3]]] & ~ [[EF [pb_d2_n2_2_1<=0] | [3<=pb_d1_n2_2_3 & pil_d2_n1_1_2<=pi_d2_n1_1_3]]]]]] | AX [[[[[pb_d2_n2_2_2<=2 | 3<=pb_d2_n1_2_2] | [4<=pi_d1_n1_3_3 | 4<=pil_d2_n1_2_3]] | AG [1<=pbl_3_3]] & [EG [pil_d2_n1_2_2<=1] | [~ [pbl_3_3<=pbl_3_3] | [2<=pi_d1_n1_2_1 | 4<=po_d2_n1_2_2]]]]]]]
normalized: ~ [EG [~ [[~ [EX [~ [[[[[2<=pi_d1_n1_2_1 | 4<=po_d2_n1_2_2] | ~ [pbl_3_3<=pbl_3_3]] | EG [pil_d2_n1_2_2<=1]] & [~ [E [true U ~ [1<=pbl_3_3]]] | [[4<=pi_d1_n1_3_3 | 4<=pil_d2_n1_2_3] | [pb_d2_n2_2_2<=2 | 3<=pb_d2_n1_2_2]]]]]]] | ~ [[[~ [[[3<=pb_d1_n2_2_3 & pil_d2_n1_1_2<=pi_d2_n1_1_3] | E [true U pb_d2_n2_2_1<=0]]] & [[E [pol_d1_n1_1_1<=2 U pi_d1_n1_2_3<=pil_d1_n1_3_3] | [pil_d1_n1_1_1<=4 & pbl_2_3<=1]] & ~ [EX [pil_d2_n1_2_2<=pol_d2_n1_3_3]]]] | [~ [EG [~ [[[~ [EG [~ [4<=pol_d2_n1_2_3]]] & ~ [E [~ [4<=pol_d2_n1_2_3] U [~ [4<=pol_d1_n1_2_2] & ~ [4<=pol_d2_n1_2_3]]]]] & ~ [E [true U ~ [1<=pol_d1_n1_2_1]]]]]]] & ~ [E [~ [[[~ [EG [~ [4<=pol_d2_n1_2_3]]] & ~ [E [~ [4<=pol_d2_n1_2_3] U [~ [4<=pol_d1_n1_2_2] & ~ [4<=pol_d2_n1_2_3]]]]] & ~ [E [true U ~ [1<=pol_d1_n1_2_1]]]]] U [[~ [EG [~ [3<=pi_d2_n1_1_3]]] & ~ [E [~ [3<=pi_d2_n1_1_3] U [~ [pb_d2_n2_2_3<=2] & ~ [3<=pi_d2_n1_1_3]]]]] & ~ [[[~ [EG [~ [4<=pol_d2_n1_2_3]]] & ~ [E [~ [4<=pol_d2_n1_2_3] U [~ [4<=pol_d1_n1_2_2] & ~ [4<=pol_d2_n1_2_3]]]]] & ~ [E [true U ~ [1<=pol_d1_n1_2_1]]]]]]]]]]]]]]]

abstracting: (1<=pol_d1_n1_2_1)
states: 327,843,702,221,121,231,353,900,872,617,690,566 (35)
MC time: 1m 8.006sec

checking: EG [pb_d2_n2_1_1<=2]
normalized: EG [pb_d2_n2_1_1<=2]

abstracting: (pb_d2_n2_1_1<=2)
states: 414,056,897,615,382,018,906,435,531,019,430,672 (35)

before gc: list nodes free: 1272387

after gc: idd nodes used:2572781, unused:61427219; list nodes free:475058048
.
EG iterations: 1
-> the formula is TRUE

FORMULA HypertorusGrid-PT-d2k3p2b04-CTLCardinality-11 TRUE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT

TIME LIMIT: Killed by timeout after 3600 seconds
MemTotal: 16393916 kB
MemFree: 3050268 kB
After kill :
MemTotal: 16393916 kB
MemFree: 16182192 kB

BK_TIME_CONFINEMENT_REACHED

--------------------
content from stderr:

check for maximal unmarked siphon
ok
check for constant places
ok
check if there are places and transitions
ok
check if there are transitions without pre-places
ok
check if at least one transition is enabled in m0
ok
check if there are transitions that can never fire
ok


initing FirstDep: 0m 0.002sec

57670 21119 64358 22045 38521 38631 27295
iterations count:794875 (5519), effective:64725 (449)

initing FirstDep: 0m 0.000sec


iterations count:144 (1), effective:0 (0)

net_ddint.h:600: Timeout: after 182 sec


net_ddint.h:600: Timeout: after 182 sec


net_ddint.h:600: Timeout: after 165 sec


sat_reach.icc:155: Timeout: after 149 sec


net_ddint.h:600: Timeout: after 139 sec


net_ddint.h:442: Timeout: after 127 sec


sat_reach.icc:155: Timeout: after 118 sec


net_ddint.h:442: Timeout: after 110 sec


sat_reach.icc:155: Timeout: after 100 sec


iterations count:144 (1), effective:0 (0)

net_ddint.h:600: Timeout: after 93 sec


net_ddint.h:442: Timeout: after 86 sec


net_ddint.h:442: Timeout: after 78 sec


net_ddint.h:600: Timeout: after 72 sec


sat_reach.icc:155: Timeout: after 67 sec

Sequence of Actions to be Executed by the VM

This is useful if one wants to reexecute the tool in the VM from the submitted image disk.

set -x
# this is for BenchKit: configuration of major elements for the test
export BK_INPUT="HypertorusGrid-PT-d2k3p2b04"
export BK_EXAMINATION="CTLCardinality"
export BK_TOOL="marcie"
export BK_RESULT_DIR="/tmp/BK_RESULTS/OUTPUTS"
export BK_TIME_CONFINEMENT="3600"
export BK_MEMORY_CONFINEMENT="16384"
export BK_BIN_PATH="/home/mcc/BenchKit/bin/"

# this is specific to your benchmark or test

export BIN_DIR="$HOME/BenchKit/bin"

# remove the execution directoty if it exists (to avoid increse of .vmdk images)
if [ -d execution ] ; then
rm -rf execution
fi

# this is for BenchKit: explicit launching of the test
echo "====================================================================="
echo " Generated by BenchKit 2-5348"
echo " Executing tool marcie"
echo " Input is HypertorusGrid-PT-d2k3p2b04, examination is CTLCardinality"
echo " Time confinement is $BK_TIME_CONFINEMENT seconds"
echo " Memory confinement is 16384 MBytes"
echo " Number of cores is 1"
echo " Run identifier is r225-tall-167856407000041"
echo "====================================================================="
echo
echo "--------------------"
echo "preparation of the directory to be used:"

tar xzf /home/mcc/BenchKit/INPUTS/HypertorusGrid-PT-d2k3p2b04.tgz
mv HypertorusGrid-PT-d2k3p2b04 execution
cd execution
if [ "CTLCardinality" = "ReachabilityDeadlock" ] || [ "CTLCardinality" = "UpperBounds" ] || [ "CTLCardinality" = "QuasiLiveness" ] || [ "CTLCardinality" = "StableMarking" ] || [ "CTLCardinality" = "Liveness" ] || [ "CTLCardinality" = "OneSafe" ] || [ "CTLCardinality" = "StateSpace" ]; then
rm -f GenericPropertiesVerdict.xml
fi
pwd
ls -lh

echo
echo "--------------------"
echo "content from stdout:"
echo
echo "=== Data for post analysis generated by BenchKit (invocation template)"
echo
if [ "CTLCardinality" = "UpperBounds" ] ; then
echo "The expected result is a vector of positive values"
echo NUM_VECTOR
elif [ "CTLCardinality" != "StateSpace" ] ; then
echo "The expected result is a vector of booleans"
echo BOOL_VECTOR
else
echo "no data necessary for post analysis"
fi
echo
if [ -f "CTLCardinality.txt" ] ; then
echo "here is the order used to build the result vector(from text file)"
for x in $(grep Property CTLCardinality.txt | cut -d ' ' -f 2 | sort -u) ; do
echo "FORMULA_NAME $x"
done
elif [ -f "CTLCardinality.xml" ] ; then # for cunf (txt files deleted;-)
echo echo "here is the order used to build the result vector(from xml file)"
for x in $(grep '' CTLCardinality.xml | cut -d '>' -f 2 | cut -d '<' -f 1 | sort -u) ; do
echo "FORMULA_NAME $x"
done
elif [ "CTLCardinality" = "ReachabilityDeadlock" ] || [ "CTLCardinality" = "QuasiLiveness" ] || [ "CTLCardinality" = "StableMarking" ] || [ "CTLCardinality" = "Liveness" ] || [ "CTLCardinality" = "OneSafe" ] ; then
echo "FORMULA_NAME CTLCardinality"
fi
echo
echo "=== Now, execution of the tool begins"
echo
echo -n "BK_START "
date -u +%s%3N
echo
timeout -s 9 $BK_TIME_CONFINEMENT bash -c "/home/mcc/BenchKit/BenchKit_head.sh 2> STDERR ; echo ; echo -n \"BK_STOP \" ; date -u +%s%3N"
if [ $? -eq 137 ] ; then
echo
echo "BK_TIME_CONFINEMENT_REACHED"
fi
echo
echo "--------------------"
echo "content from stderr:"
echo
cat STDERR ;