aMCatNLO: Generation ttbb jobs did not terminate correctly
Hello,
I am trying to generate p p -> t t~ b b~ [QCD] events on parton level with aMC@NLO /Madgraph5 Version 2.0_0_0_beta_3 on a pbs cluster.
I retried this event generation a few times: All jobs seem to run correctly in the beginning, but at the end I get the following error:
-----
ERROR: not all jobs terminated correctly
-----
I paste the log from aMC@NLO here:
-------
ERROR: not all jobs terminated correctly
INFO: Return code of the event collection: None
INFO: Output of the event collection:
N of directories: 98
Determining the number of unweighted events per channel
35 jobs did not terminate correctly
P0_gg_tbbxtx/GV1
P0_gg_tbbxtx/GV10
P0_gg_tbbxtx/GV11
P0_gg_tbbxtx/GV12
P0_gg_tbbxtx/GV13
P0_gg_tbbxtx/GV14
P0_gg_tbbxtx/GV15
P0_gg_tbbxtx/GV16
P0_gg_tbbxtx/GV17
P0_gg_tbbxtx/GV18
P0_gg_tbbxtx/GV19
P0_gg_tbbxtx/GV2
P0_gg_tbbxtx/GV20
P0_gg_tbbxtx/GV21
P0_gg_tbbxtx/GV22
P0_gg_tbbxtx/GV23
P0_gg_tbbxtx/GV24
P0_gg_tbbxtx/GV25
P0_gg_tbbxtx/GV26
P0_gg_tbbxtx/GV27
P0_gg_tbbxtx/GV28
P0_gg_tbbxtx/GV29
P0_gg_tbbxtx/GV3
P0_gg_tbbxtx/GV30
P0_gg_tbbxtx/GV31
P0_gg_tbbxtx/GV32
P0_gg_tbbxtx/GV33
P0_gg_tbbxtx/GV35
P0_gg_tbbxtx/GV36
P0_gg_tbbxtx/GV4
P0_gg_tbbxtx/GV5
P0_gg_tbbxtx/GV6
P0_gg_tbbxtx/GV7
P0_gg_tbbxtx/GV8
P0_gg_tbbxtx/GV9
Found 63 correctly terminated jobs
63 98
Integrated abs(cross-section)
P0_uxu_
35 jobs did not terminate correctly
P0_gg_tbbxtx/GV1
P0_gg_tbbxtx/GV10
P0_gg_tbbxtx/GV11
P0_gg_tbbxtx/GV12
P0_gg_tbbxtx/GV13
P0_gg_tbbxtx/GV14
P0_gg_tbbxtx/GV15
P0_gg_tbbxtx/GV16
P0_gg_tbbxtx/GV17
P0_gg_tbbxtx/GV18
P0_gg_tbbxtx/GV19
P0_gg_tbbxtx/GV2
P0_gg_tbbxtx/GV20
P0_gg_tbbxtx/GV21
P0_gg_tbbxtx/GV22
P0_gg_tbbxtx/GV23
P0_gg_tbbxtx/GV24
P0_gg_tbbxtx/GV25
P0_gg_tbbxtx/GV26
P0_gg_tbbxtx/GV27
P0_gg_tbbxtx/GV28
P0_gg_tbbxtx/GV29
P0_gg_tbbxtx/GV3
P0_gg_tbbxtx/GV30
P0_gg_tbbxtx/GV31
P0_gg_tbbxtx/GV32
P0_gg_tbbxtx/GV33
P0_gg_tbbxtx/GV35
P0_gg_tbbxtx/GV36
P0_gg_tbbxtx/GV4
P0_gg_tbbxtx/GV5
P0_gg_tbbxtx/GV6
P0_gg_tbbxtx/GV7
P0_gg_tbbxtx/GV8
P0_gg_tbbxtx/GV9
Found 63 correctly terminated jobs
63 98
Integrated cross-section
P0_uxu_
Error detected in "launch -c"
write debug file /scratch/
If you need help with this issue please contact us on https:/
aMCatNLOError : An error occurred during the collection of results
-------
Here you find the debug log:
-------
#******
#* MadGraph/aMC@NLO 5 *
#* *
#* * * *
#* * * * * *
#* * * * * 5 * * * * *
#* * * * * *
#* * * *
#* *
#* *
#* VERSION 2.0.0.beta3 2013-02-14 *
#* *
#* The MadGraph Development Team - Please visit us at *
#* https:/
#* *
#******
#* *
#* Command File for aMCatNLO *
#* *
#* run as ./bin/madevent.py filename *
#* *
#******
launch -c
Traceback (most recent call last):
File "/afs/naf.
File "/afs/naf.
File "/afs/naf.
File "/afs/naf.
File "/afs/naf.
aMCatNLOError: An error occurred during the collection of results
Value of current Options:
ignore_
loop_
cluster_
automatic_
MCatNLO-
exrootana
complex_
-------
I also looked in the Subprocess folders of the failing Subprocesses to look for some speficic error messages in the debug logs there. But I do not find any special errors.
But I paste here also the log SubProcesses/
-------
Process in group number 0
A PDF is used, so alpha_s(MZ) is going to be modified
Old value of alpha_s from param_card: 0.11799999999999999
New value of alpha_s from PDF cteq6_m: 0.11799999999999999
WARNING: the value of maxjetflavor specified in the run_card is inconsistent with the number of light flavours in the model.
Hence it will be set to 4
******
* MadGraph/MadEvent *
* -------
* http://
* http://
* http://
* -------
* *
* PARAMETER AND COUPLING VALUES *
* *
******
External Params
-----
MU_R = 91.188000000000002
aEWM1 = 132.50700000000001
Gf = 1.1663900000000
aS = 0.11799999999999999
ymb = 4.7000000000000002
ymt = 173.00000000000000
ymtau = 1.7769999999999999
MT = 173.00000000000000
MB = 4.7000000000000002
MZ = 91.188000000000002
MH = 125.00000000000000
MTA = 1.7769999999999999
WT = 0.0000000000000000
WZ = 2.4414039999999999
WW = 2.0476000000000001
WH = 5.7530879999999
Internal Params
-----
CKM3x3 = 1.0000000000000000
conjg__CKM3x3 = 1.0000000000000000
CKM22 = 1.0000000000000000
lhv = 1.0000000000000000
conjg__CKM22 = 1.0000000000000000
conjg__CKM33 = 1.0000000000000000
Ncol = 3.0000000000000000
CA = 3.0000000000000000
TF = 0.50000000000000000
CF = 1.3333333333333333
complexi = ( 0.0000000000000000 , 1.0000000000000000 )
MZ__exp__2 = 8315.2513440000002
MZ__exp__4 = 69143404.913893804
sqrt__2 = 1.4142135623730951
MH__exp__2 = 15625.000000000000
Ncol__exp__2_m_1 = 8.0000000000000000
MH__exp__2 = 15625.000000000000
Ncol__exp__2_m_1 = 8.0000000000000000
MB__exp__2 = 22.090000000000003
MT__exp__2 = 29929.000000000000
Ncol__exp__2_m_1_0 = 8.0000000000000000
aEW = 7.5467711139788
MW = 80.419002445756163
sqrt__aEW = 8.6872153846781
ee = 0.30795376724436879
MW__exp__2 = 6467.2159543705357
sw2 = 0.22224648578577766
cw = 0.88190334743339216
sqrt__sw2 = 0.47143025548407230
sw = 0.47143025548407230
g1 = 0.34919219678733299
gw = 0.65323293034757990
v = 246.21845810181637
v__exp__2 = 60623.529110035903
lam = 0.12886910601690263
yb = 2.6995554250465
yt = 0.99366614581500623
ytau = 1.0206617000654
muH = 88.388347648318430
AxialZUp = -0.185177018617
AxialZDown = 0.18517701861793787
VectorZUp = 7.5430507588273
VectorZDown = -0.130303763103
VectorAUp = 0.20530251149624587
VectorADown = -0.102651255748
VectorWmDxU = 0.23095271737156670
AxialWmDxU = -0.230952717371
VectorWpUxD = 0.23095271737156670
AxialWpUxD = -0.230952717371
I1x33 = ( 2.6995554250465
I2x33 = ( 0.99366614581500623 , 0.0000000000000000 )
I3x33 = ( 0.99366614581500623 , 0.0000000000000000 )
I4x33 = ( 2.6995554250465
Vector_tbGp = (-0.96667059156
Axial_tbGp = ( -1.0206617000654716 , -0.0000000000000000 )
Vector_tbGm = ( 0.96667059156454072 , 0.0000000000000000 )
Axial_tbGm = ( -1.0206617000654716 , -0.0000000000000000 )
gw__exp__2 = 0.42671326129048615
cw__exp__2 = 0.77775351421422245
ee__exp__2 = 9.4835522759998
sw__exp__2 = 0.22224648578577769
yb__exp__2 = 7.2875994928982
yt__exp__2 = 0.98737240933884918
Internal Params evaluated point by point
-----
MU_R__exp__2 = 8315.2513440000002
sqrt__aS = 0.34351128074635334
G__exp__2 = 1.4828317324943823
G__exp__3 = 1.8056676068262196
G__exp__4 = 2.1987899468922913
Couplings of loop_sm
G__exp__4 = 2.1987899468922913
Couplings of loop_sm
-----
UV_3Gb = -0.22605E-01 -0.00000E+00
UV_3Gt = 0.48815E-02 0.00000E+00
UV_4Gb = 0.00000E+00 0.55053E-01
UV_4Ggt = 0.00000E+00 -0.11889E-01
UV_GQQb = 0.00000E+00 0.22605E-01
UV_GQQt = 0.00000E+00 -0.48815E-02
UV_bMass = 0.00000E+00 0.12824E+01
UV_tMass = 0.00000E+00 0.34177E+00
UVWfct_b_0 = -0.13642E+00 -0.00000E+00
UVWfct_t_0 = -0.98778E-03 -0.00000E+00
UVWfct_G_2 = 0.40088E-02 0.00000E+00
UVWfct_G_1 = -0.18563E-01 0.00000E+00
GC_4 = -0.12177E+01 0.00000E+00
GC_5 = 0.00000E+00 0.12177E+01
GC_6 = 0.00000E+00 0.14828E+01
R2_3Gq = 0.76230E-02 0.00000E+00
R2_3Gg = 0.31445E-01 0.00000E+00
R2GC_137_43 = 0.00000E+00 0.11603E-02
R2GC_137_44 = -0.00000E+00 -0.34810E-02
R2GC_138_45 = -0.00000E+00 -0.11603E-02
R2GC_138_46 = 0.00000E+00 0.34810E-02
R2GC_139_47 = -0.00000E+00 -0.46413E-02
R2GC_140_48 = 0.00000E+00 0.77356E-03
R2GC_140_49 = -0.00000E+00 -0.69620E-02
R2GC_141_50 = -0.00000E+00 -0.13924E-01
R2GC_141_51 = -0.00000E+00 -0.48734E-01
R2GC_142_52 = 0.00000E+00 0.13924E-01
R2GC_142_53 = 0.00000E+00 0.48734E-01
R2GC_143_54 = 0.00000E+00 0.12764E-01
R2GC_143_55 = 0.00000E+00 0.52215E-01
R2GC_144_56 = -0.00000E+00 -0.10443E-01
R2GC_144_57 = -0.00000E+00 -0.59177E-01
R2GC_145_58 = -0.11603E-02 0.00000E+00
R2GC_145_59 = 0.34810E-02 0.00000E+00
R2_GQQ = -0.00000E+00 -0.30492E-01
R2_GGq = 0.00000E+00 0.62601E-02
R2_GGb = -0.00000E+00 -0.82971E+00
R2_GGt = -0.00000E+00 -0.11242E+04
R2_GGg_1 = 0.00000E+00 0.28170E-01
R2_GGg_2 = -0.00000E+00 -0.18780E-01
R2_QQq = 0.00000E+00 0.12520E-01
R2_QQb = 0.00000E+00 0.11769E+00
R2_QQt = 0.00000E+00 0.43320E+01
UV_3Gg_1eps = 0.62890E-01 0.00000E+00
UV_3Gb_1eps = -0.38115E-02 0.00000E+00
UV_4Gg_1eps = 0.00000E+00 -0.15316E+00
UV_4Gb_1eps = 0.00000E+00 0.92827E-02
UV_GQQg_1eps = 0.00000E+00 -0.62890E-01
UV_GQQq_1eps = 0.00000E+00 0.38115E-02
UV_bMass_1eps = 0.00000E+00 0.17653E+00
UV_tMass_1eps = 0.00000E+00 0.64980E+01
UVWfct_b_0_1eps -0.18780E-01 0.00000E+00
UV_tMass_1eps = 0.00000E+00 0.64980E+01
UVWfct_b_0_1eps -0.18780E-01 0.00000E+00
UVWfct_G_2_1eps -0.31300E-02 0.00000E+00
Collider parameters:
------
Running at P P machine @ 8000.0000000000000 GeV
PDF set = cteq6_m
alpha_s(Mz)= 0.1180 running at 2 loops.
alpha_s(Mz)= 0.1180 running at 2 loops.
Renormalization scale set on event-by-event basis
Factorization scale set on event-by-event basis
getting user params
Enter number of events and iterations:
Number of events and iterations -1 12
Enter desired fractional accuracy:
Desired fractional accuracy: 5.0000000000000
Enter alpha, beta for G_soft
Enter alpha<0 to set G_soft=1 (no ME soft)
for G_soft: alpha= 1.0000000000000000 , beta= -0.100000000000
Enter alpha, beta for G_azi
Enter alpha>0 to set G_azi=0 (no azi corr)
for G_azi: alpha= -1.0000000000000000 , beta= -0.100000000000
Doing the S and H events together
Suppress amplitude (0 no, 1 yes)?
Using suppressed amplitude.
Exact helicity sum (0 yes, n = number/event)?
Explicitly summing over helicities
Enter Configuration Number:
Running Configuration Number: 1
Enter running mode for MINT:
0 to set-up grids, 1 to integrate, 2 to generate events
MINT running mode: 0
Set the three folding parameters for MINT
xi_i, phi_i, y_ij
1 1 1
'all ', 'born', 'real', 'virt', 'novi' or 'grid'?
Enter 'born0' or 'virt0' to perform
a pure n-body integration (no S functions)
doing the viSB of this channel
Normal integration (Sfunction != 1)
Not subdividing B.W.
about to integrate 13 -1 12 1
imode is 0
#------
# FastJet release 3.0.5
# M. Cacciari, G.P. Salam and G. Soyez
# A software package for jet finding and analysis at colliders
# http://
#
# Please cite EPJC72(2012)1896 [arXiv:1111.6097] if you use this package
# for scientific work and optionally PLB641(2006)57 [hep-ph/0512210].
#
# for scientific work and optionally PLB641(2006)57 [hep-ph/0512210].
#
# FastJet is provided without warranty under the terms of the GNU GPLv2.
# It uses T. Chan's closest pair algorithm, S. Fortune's Voronoi code
# and 3rd party plugin jet algorithms. See COPYING file for details.
#------
------- iteration 1
Update # PS points (even): 1040 --> 1040
Using random seed offsets: 1 , 1 , 0
with seed 36
Ranmar initialization seeds 15606 9411
Total number of FKS directories is 10
For the Born we use nFKSprocesses # 2 6
FKS process map (sum= 3 ) :
1 --> 3 : 1 7 8
2 --> 3 : 2 9 10
3 --> 1 : 3
4 --> 1 : 4
5 --> 1 : 5
6 --> 1 : 6
nFKSprocess: 1. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 1. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 1. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 2. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 2. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 2. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 3. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 3. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 4. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 4. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 5. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 5. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 6. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 6. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 7. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 7. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 7. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 8. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 8. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 8. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 9. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 9. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 9. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 10. Absolute lower bound for tau at the Born is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 10. Lower bound for tau is 0.19736E-02 0.35540E+03 0.80000E+04
nFKSprocess: 10. Lower bound for tau is (taking resonances into account) 0.19736E-02 0.35540E+03 0.80000E+04
bpower is 4.0000000000000000
======
From cuts.f
Jets are defined with the kT algorithm
with a mimumal pT of 10.000000000000000 GeV
and no maximal pseudo-rapidity.
Charged leptons are required to have at least 0.0000000000000000 GeV of transverse momentum and
pseudo rapidity of maximum 100.00000000000000 .
Opposite charged lepton pairs need to be separated by at least 0.0000000000000000
and have an invariant mass of 30.000000000000000 GeV
Opposite charged lepton pairs need to be separated by at least 0.0000000000000000
and have an invariant mass of 30.000000000000000 GeV
======
Scale values (may change event by event):
muR, muR_reference: 0.585740D+03 0.585740D+03 1.00
muF1, muF1_reference: 0.585740D+03 0.585740D+03 1.00
muF2, muF2_reference: 0.585740D+03 0.585740D+03 1.00
QES, QES_reference: 0.585740D+03 0.585740D+03 1.00
muR_reference [functional form]:
sum_i mT(i), i=final state
muF1_reference [functional form]:
sum_i mT(i), i=final state
muF2_reference [functional form]:
sum_i mT(i), i=final state
QES_reference [functional form]:
sum_i mT(i), i=final state
alpha_s= 9.2260725592062
alpha_s value used for the virtuals is (for the first PS point): 9.2260725592062
======
INFO: MadLoop read these parameters from MadLoopParams.dat
======
> CTModeRun = -1
> MLStabThres = 1.0000000000000
> NRotations_DP = 1
> NRotations_QP = 0
> CTStabThres = 1.0000000000000
> CTLoopLibrary = 2
> CTModeInit = 0
> CheckCycle = 3
> MaxAttempts = 10
> UseLoopFilter = F
> ImprovePSPoint = T
> DoubleCheckHeli
> LoopInitStartOver = F
> HelInitStartOver = F
> ZeroThres = 1.0000000000000
======
-------
| You are using CutTools - Version 1.8.7 |
| Authors: G. Ossola, C. Papadopoulos, R. Pittau |
| Published in JHEP 0803:042,2008 |
| http://
| |
| Compiler with 34 significant digits detetected |
------
#######
# #
# You are using OneLOop-3.2 #
# #
# for the evaluation of 1-loop scalar 1-, 2-, 3- and 4-point functions #
# #
# author: Andreas van Hameren <email address hidden> #
# #
# author: Andreas van Hameren <email address hidden> #
# date: 19-07-2012 #
# #
# Please cite #
# A. van Hameren, #
# Comput.Phys.Commun. 182 (2011) 2427-2438, arXiv:1007.4716 #
# A. van Hameren, C.G. Papadopoulos and R. Pittau, #
# JHEP 0909:106,2009, arXiv:0903.4665 #
# in publications with results obtained with the help of this program. #
# #
#######
======
process combination map (specified per FKS dir):
1 map 1
1 inv. map 1
2 map 1
2 inv. map 1
3 map 1
3 inv. map 1
4 map 1
4 inv. map 1
5 map 1
5 inv. map 1
6 map 1
6 inv. map 1
7 map 1 1 1 1
7 inv. map 4
8 map 1 1 1 1
8 inv. map 4
9 map 1 1 1 1
9 inv. map 4
10 map 1 1 1 1
10 inv. map 4
======
alpha_s value used for the virtuals is (for the first PS point): 8.8021980786292
---- POLES CANCELLED ----
|int|= 1.2134123604182
int = 1.2134123604182
Chi^2 per d.o.f. 0.0000000000000000
accumulated result |int|= 1.2134123604182
accumulated result int = 1.2134123604182
accumulated result Chi^2 per DoF = 0.0000000000000000
1: 0 1 2 3 4 5 6
------- iteration 2
Update # PS points (even): 2080 --> 2080
|int|= 1.8725447341931
int = 1.8725447341931
Chi^2= 3.2807096117158436
accumulated result |int|= 1.6220147238959
accumulated result int = 1.6220147238959
accumulated result Chi^2 per DoF = 3.2807096117158436
1: 0 1 2 3 4 5 6
------- iteration 3
Update # PS points (even): 4160 --> 4160
|int|= 1.8222975138106
Update # PS points (even): 4160 --> 4160
|int|= 1.8222975138106
int = 1.8222964195992
Chi^2= 1.4797765733635537
accumulated result |int|= 1.7654560501705
accumulated result int = 1.7654552620344
accumulated result Chi^2 per DoF = 2.3802430925396987
1: 0 1 2 3 4 5 6
Time in seconds: 173798
-------
I would be glad, if you could give some hints how to solve this error.
Thank you in advance.
Best regards
Question information
- Language:
- English Edit question
- Status:
- Solved
- Assignee:
- marco zaro Edit question
- Solved by:
- Marco A. Harrendorf
- Solved:
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