 enter npoints,number_propagators,rank,scaloop,muscale,    thrs
     
 scaloop= 1 -> looptools 1-loop 
 scaloop= 2 -> avh 1-loop (massive with complex masses)
 scaloop= 3 -> qcdloop   1-loop (Ellis and Zanderighi)
 muscale (dimension of energy) is the scale
 for the 1-loop integrals
     
  
 ----------------------------------------------------- 
 |  You are using CutTools - Version 1.6.5           | 
 |  Authors: G. Ossola, C. Papadopoulos, R. Pittau   | 
 |  Published in JHEP 0803:042,2008                  | 
 |  http://www.ugr.es/~pittau/CutTools               | 
 ----------------------------------------------------- 
   
########################################################################
#                                                                      #
#                      You are using OneLOop 1.1                       #
#                                                                      #
# for the evaluation of 1-loop scalar 1-, 2-, 3- and 4-point functions #
#                                                                      #
# author: Andreas van Hameren <hamerenREMOVETHIS@ifj.edu.pl>           #
#   date: 09-09-2010                                                   #
#                                                                      #
# Please cite                                                          #
#    A. van Hameren, arXiv:1007.4716 [hep-ph]                          #
#    A. van Hameren, C.G. Papadopoulos and R. Pittau,                  #
#    JHEP 0909:106,2009, arXiv:0903.4665 [hep-ph]                      #
# in publications with results obtained with the help of this program. #
#                                                                      #
########################################################################
 MESSAGE from avh_olo_mu_set: scale (mu, not mu^2) set to:   1.0000000000000000     
 MESSAGE from avh_olo_prec: precision set to  2.22044604925031308E-016
 MESSAGE from avh_olo_onshell: threshold set to:  9.99999999999999955E-007
                
   iter=            1
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-6.14414287617328205E-005, 2.68796945675523491E-005)
  coeff of 1/eps   pole amp(1)= ( 1.72788878854191854E-005,-3.50247591047628493E-006)
  coeff of 1/eps^2 pole amp(2)= (-2.22974541685034994E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-6.14414287617328205E-005, 2.68796945675523491E-005)
                        stable= T
                
                
   iter=            2
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-6.18970305854200681E-005, 2.70817374763685206E-005)
  coeff of 1/eps   pole amp(1)= ( 1.74186377819000514E-005,-3.53276641988525333E-006)
  coeff of 1/eps^2 pole amp(2)= (-2.24902895405518566E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-6.18970305854200681E-005, 2.70817374763685206E-005)
                        stable= T
                
                
   iter=            3
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-1.01091658005325992E-003, 4.77805322672677298E-004)
  coeff of 1/eps   pole amp(1)= ( 4.35961116389186492E-004,-1.13982831464560011E-004)
  coeff of 1/eps^2 pole amp(2)= (-7.25637242207805846E-005,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-1.01091658005325992E-003, 4.77805322672677298E-004)
                        stable= T
                
                
   iter=            4
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-1.78331419446036712E-004, 7.94184387884404010E-005)
  coeff of 1/eps   pole amp(1)= ( 5.61298712204248273E-005,-1.23872932431771638E-005)
  coeff of 1/eps^2 pole amp(2)= (-7.88599580472192363E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-1.78331419446036712E-004, 7.94184387884404010E-005)
                        stable= T
                
                
   iter=            5
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-5.78086790278832847E-005, 2.52696884074355092E-005)
  coeff of 1/eps   pole amp(1)= ( 1.61687999682418042E-005,-3.26251849167770338E-006)
  coeff of 1/eps^2 pole amp(2)= (-2.07698377951688439E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-5.78086790278832847E-005, 2.52696884074355092E-005)
                        stable= T
                
                
   iter=            6
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-2.04744015964614535E-004, 9.14487935916586108E-005)
  coeff of 1/eps   pole amp(1)= ( 6.55855859235043929E-005,-1.46464375551982862E-005)
  coeff of 1/eps^2 pole amp(2)= (-9.32421174238632754E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-2.04744015964614535E-004, 9.14487935916586108E-005)
                        stable= T
                
                
   iter=            7
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-9.03639125694515911E-004, 4.24425579559954040E-004)
  coeff of 1/eps   pole amp(1)= ( 3.78281151449825017E-004,-9.76450938256549729E-005)
  coeff of 1/eps^2 pole amp(2)= (-6.21627974040995840E-005,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-9.03639125694515911E-004, 4.24425579559954040E-004)
                        stable= T
                
                
   iter=            8
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-6.25155275100655323E-004, 2.88635124727871508E-004)
  coeff of 1/eps   pole amp(1)= ( 2.40406950941506070E-004,-5.96399338110252801E-005)
  coeff of 1/eps^2 pole amp(2)= (-3.79679610867925317E-005,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-6.25155275100655323E-004, 2.88635124727871508E-004)
                        stable= T
                
                
   iter=            9
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-2.58250038523982197E-004, 1.15968447920779011E-004)
  coeff of 1/eps   pole amp(1)= ( 8.53758474472424681E-005,-1.94589457938039746E-005)
  coeff of 1/eps^2 pole amp(2)= (-1.23879496417645899E-005,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-2.58250038523982197E-004, 1.15968447920779011E-004)
                        stable= T
                
                
   iter=           10
                
                
  Complete Amplitude (without r2):     
                
                
  finite part           amp(0)= (-1.73083957574840909E-004, 7.70344734138706406E-005)
  coeff of 1/eps   pole amp(1)= ( 5.42774678586871445E-005,-1.19481941615276758E-005)
  coeff of 1/eps^2 pole amp(2)= (-7.60645664731541295E-006,  0.0000000000000000     )
                           R_1= (  0.0000000000000000     ,  0.0000000000000000     )
                    amp(0)+R_1= (-1.73083957574840909E-004, 7.70344734138706406E-005)
                        stable= T
                
 n_mp  =           0
 n_disc=           0
