About the Execution of Marcie for Kanban-PT-0050
Execution Summary | |||||
Max Memory Used (MB) |
Time wait (ms) | CPU Usage (ms) | I/O Wait (ms) | Computed Result | Execution Status |
4150.350 | 15286.00 | 15030.00 | 10.00 | FFFFFFFFFFFFFFFF | normal |
Execution Chart
We display below the execution chart for this examination (boot time has been removed).
Trace from the execution
Waiting for the VM to be ready (probing ssh)
.............................................
=====================================================================
Generated by BenchKit 2-2265
Executing tool marcie
Input is Kanban-PT-0050, examination is ReachabilityBounds
Time confinement is 3600 seconds
Memory confinement is 16384 MBytes
Number of cores is 1
Run identifier is r050kn-ebro-143236503800476
=====================================================================
--------------------
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 Kanban-PT-0050-ReachabilityBounds-0
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-1
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-10
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-11
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-12
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-13
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-14
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-15
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-2
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-3
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-4
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-5
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-6
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-7
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-8
FORMULA_NAME Kanban-PT-0050-ReachabilityBounds-9
=== Now, execution of the tool begins
BK_START 1432542041589
Model: Kanban-PT-0050
reachability algorithm:
Saturation-based algorithm
variable ordering algorithm:
Calculated like in [Noa99]
--memory=6 --suppress --rs-algorithm=3 --place-order=5
Marcie rev. 1429:1432M (built: crohr on 2014-10-22)
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: marcie --net-file=model.pnml --mcc-file=ReachabilityBounds.xml --memory=6 --suppress --rs-algorithm=3 --place-order=5
parse successfull
net created successfully
(NrP: 16 NrTr: 16 NrArc: 40)
net check time: 0m0sec
parse formulas successfull
formulas created successfully
place and transition orderings generation:0m0sec
init dd package: 0m5sec
RS generation: 0m6sec
-> reachability set: #nodes 13466 (1.3e+04) #states 10,425,941,194,901,336 (16)
starting MCC model checker
--------------------------
checking: [maxVal(Pback3)<=2 & maxVal(P4)<=3]
normalized: [maxVal(Pback3)<=2 & maxVal(P4)<=3]
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-0 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [maxVal(Pout2)<=3 & [maxVal(P4)<=2 & [[[[maxVal(P3)<=2 & maxVal(P4)<=2] & maxVal(Pout1)<=3] & maxVal(Pm1)<=1] & maxVal(Pm1)<=2]]]
normalized: [maxVal(Pout2)<=3 & [maxVal(P4)<=2 & [maxVal(Pm1)<=2 & [maxVal(Pm1)<=1 & [maxVal(Pout1)<=3 & [maxVal(P3)<=2 & maxVal(P4)<=2]]]]]]
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-1 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [[[[maxVal(Pback1)<=1 & [[maxVal(Pm3)<=3 & maxVal(Pm1)<=1] & maxVal(Pback4)<=2]] & maxVal(P2)<=2] & [maxVal(Pm2)<=3 & maxVal(Pout4)<=3]] & maxVal(Pm1)<=1]
normalized: [maxVal(Pm1)<=1 & [[maxVal(Pm2)<=3 & maxVal(Pout4)<=3] & [maxVal(P2)<=2 & [maxVal(Pback1)<=1 & [maxVal(Pback4)<=2 & [maxVal(Pm3)<=3 & maxVal(Pm1)<=1]]]]]]
abstracting: (50<=1) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-2 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm4)<=1
normalized: maxVal(Pm4)<=1
abstracting: (50<=1) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-3 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [maxVal(Pout2)<=1 & maxVal(Pback3)<=3]
normalized: [maxVal(Pout2)<=1 & maxVal(Pback3)<=3]
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-4 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [[[[[maxVal(Pout1)<=3 & [maxVal(Pm3)<=3 & maxVal(Pback4)<=3]] & maxVal(P2)<=2] & [maxVal(P3)<=2 & [maxVal(Pm2)<=1 & [maxVal(Pm2)<=3 & maxVal(P4)<=2]]]] & maxVal(Pback3)<=2] & maxVal(Pback3)<=3]
normalized: [maxVal(Pback3)<=3 & [maxVal(Pback3)<=2 & [[maxVal(P3)<=2 & [maxVal(Pm2)<=1 & [maxVal(Pm2)<=3 & maxVal(P4)<=2]]] & [maxVal(P2)<=2 & [maxVal(Pout1)<=3 & [maxVal(Pm3)<=3 & maxVal(Pback4)<=3]]]]]]
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-5 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm2)<=2
normalized: maxVal(Pm2)<=2
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-6 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm1)<=3
normalized: maxVal(Pm1)<=3
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-7 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm1)<=2
normalized: maxVal(Pm1)<=2
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-8 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm1)<=2
normalized: maxVal(Pm1)<=2
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-9 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [maxVal(Pback2)<=3 & maxVal(Pout3)<=3]
normalized: [maxVal(Pback2)<=3 & maxVal(Pout3)<=3]
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-10 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [[maxVal(Pback3)<=1 & [[maxVal(Pback4)<=1 & [maxVal(P3)<=2 & [maxVal(Pout1)<=3 & maxVal(Pback4)<=2]]] & maxVal(P4)<=2]] & maxVal(P2)<=3]
normalized: [maxVal(P2)<=3 & [maxVal(Pback3)<=1 & [maxVal(P4)<=2 & [maxVal(Pback4)<=1 & [maxVal(P3)<=2 & [maxVal(Pout1)<=3 & maxVal(Pback4)<=2]]]]]]
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-11 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [maxVal(Pm1)<=2 & [maxVal(Pm1)<=1 & [[[[maxVal(Pm3)<=2 & maxVal(P4)<=1] & [maxVal(Pm1)<=2 & maxVal(P3)<=2]] & [[maxVal(P1)<=3 & maxVal(Pout1)<=3] & [maxVal(Pback4)<=3 & maxVal(Pout1)<=2]]] & [[[maxVal(Pout2)<=1 & maxVal(P2)<=3] & maxVal(P3)<=3] & maxVal(Pm4)<=3]]]]
normalized: [maxVal(Pm1)<=2 & [maxVal(Pm1)<=1 & [[maxVal(Pm4)<=3 & [maxVal(P3)<=3 & [maxVal(Pout2)<=1 & maxVal(P2)<=3]]] & [[[maxVal(Pback4)<=3 & maxVal(Pout1)<=2] & [maxVal(P1)<=3 & maxVal(Pout1)<=3]] & [[maxVal(Pm1)<=2 & maxVal(P3)<=2] & [maxVal(Pm3)<=2 & maxVal(P4)<=1]]]]]]
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-12 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [[maxVal(Pback3)<=1 & [maxVal(Pm3)<=1 & maxVal(P1)<=2]] & [maxVal(Pback2)<=3 & maxVal(Pm1)<=2]]
normalized: [[maxVal(Pback2)<=3 & maxVal(Pm1)<=2] & [maxVal(Pback3)<=1 & [maxVal(Pm3)<=1 & maxVal(P1)<=2]]]
abstracting: (50<=2) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-13 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: [[[[[[maxVal(Pout3)<=2 & maxVal(P4)<=3] & maxVal(Pout2)<=1] & maxVal(Pback3)<=1] & [maxVal(Pout3)<=2 & maxVal(P3)<=1]] & maxVal(Pback3)<=3] & maxVal(P3)<=2]
normalized: [maxVal(P3)<=2 & [maxVal(Pback3)<=3 & [[maxVal(Pout3)<=2 & maxVal(P3)<=1] & [maxVal(Pback3)<=1 & [maxVal(Pout2)<=1 & [maxVal(Pout3)<=2 & maxVal(P4)<=3]]]]]]
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=1) states: 0
abstracting: (50<=2) states: 0
abstracting: (50<=3) states: 0
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-14 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
checking: maxVal(Pm1)<=2
normalized: maxVal(Pm1)<=2
abstracting: (50<=2) states: 0
-> the formula is FALSE
FORMULA Kanban-PT-0050-ReachabilityBounds-15 FALSE TECHNIQUES SEQUENTIAL_PROCESSING DECISION_DIAGRAMS UNFOLDING_TO_PT
MC time: 0m0sec
Total processing time: 0m15sec
BK_STOP 1432542056875
--------------------
content from stderr:
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: 0m0sec
80627 18638 13708
iterations count:3516 (219), effective:1050 (65)
initing FirstDep: 0m0sec
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="Kanban-PT-0050"
export BK_EXAMINATION="ReachabilityBounds"
export BK_TOOL="marcie"
export BK_RESULT_DIR="/users/gast00/fkordon/BK_RESULTS/OUTPUTS"
export BK_TIME_CONFINEMENT="3600"
export BK_MEMORY_CONFINEMENT="16384"
# 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
tar xzf /home/mcc/BenchKit/INPUTS/Kanban-PT-0050.tgz
mv Kanban-PT-0050 execution
# this is for BenchKit: explicit launching of the test
cd execution
echo "====================================================================="
echo " Generated by BenchKit 2-2265"
echo " Executing tool marcie"
echo " Input is Kanban-PT-0050, examination is ReachabilityBounds"
echo " Time confinement is $BK_TIME_CONFINEMENT seconds"
echo " Memory confinement is 16384 MBytes"
echo " Number of cores is 1"
echo " Run identifier is r050kn-ebro-143236503800476"
echo "====================================================================="
echo
echo "--------------------"
echo "content from stdout:"
echo
echo "=== Data for post analysis generated by BenchKit (invocation template)"
echo
if [ "ReachabilityBounds" = "ReachabilityComputeBounds" ] ; then
echo "The expected result is a vector of positive values"
echo NUM_VECTOR
elif [ "ReachabilityBounds" != "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 "ReachabilityBounds.txt" ] ; then
echo "here is the order used to build the result vector(from text file)"
for x in $(grep Property ReachabilityBounds.txt | cut -d ' ' -f 2 | sort -u) ; do
echo "FORMULA_NAME $x"
done
elif [ -f "ReachabilityBounds.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 '
echo "FORMULA_NAME $x"
done
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 ;