diff --git a/resum/resconst.C b/resum/resconst.C
index 86c668a..8aa092b 100644
--- a/resum/resconst.C
+++ b/resum/resconst.C
@@ -1,81 +1,80 @@
 #include "resconst.h"
-#include "interface.h"
 #include <math.h>
 
 // constants.f
 const int resconst::NF = 5;
 
 const double resconst::CA = 3.;
 const double resconst::Cf = 4./3.;
 
 const double resconst::Euler = 0.57721566;
 const double resconst::Z2 = 1.64493406685; //1.644934;
 const double resconst::Z3 = 1.20205690316;// 1.202057;
 //higher precision
 /*
 const double resconst::Euler = 0.57721566490153286;
 const double resconst::Z2 = M_PI*M_PI/6.;
 const double resconst::Z3 = 1.2020569031595942853;
 */
 
 double resconst::b0;
 double resconst::beta0, resconst::beta1, resconst::beta2, resconst::Kappa;
 double resconst::A1g, resconst::A2g, resconst::A3g, resconst::B1g, resconst::B2g, resconst::C1ggn;
 double resconst::A1q, resconst::A2q, resconst::A3q, resconst::B1q, resconst::B2q, resconst::C1qqn;
 double resconst::C1qqdelta, resconst::Delta2qq;
 double resconst::D0qqqq, resconst::D1qqqq;
 double resconst::Deltaqqqq;
 double resconst::H2qqdelta;
 double resconst::H2qqD0;
 
 void resconst::init()
 {
   double pi2 = M_PI*M_PI;
   double pi4 = pi2*pi2;
   double nf2 = NF*NF;
 
   b0=2*exp(-Euler);
 
   //Resummation coefficients
   beta0=(33.-2.*NF)/12.;
   beta1=(153.-19.*NF)/24.;
   beta2=2857./128.-5033.*NF/1152.+325.*nf2/3456.;
   Kappa=67./6.-pi2/2.-5./9.*NF;
 
   //gluon coefficients
   A1g=CA;
   A2g=CA/2.*(67./6.-pi2/2.-5./9.*NF); //CA/2.*Kappa;
   A3g=CA*(13.81-2.15*NF-nf2/108.);
   B1g=-(11.*CA-2.*NF)/6.;
   B2g=CA*CA*(23./24.+(11.*pi2)/18.-3.*Z3/2.)+Cf*NF/2.-CA*NF*(1./12.+pi2/9.)-11./8.*Cf*CA;
   C1ggn=(pi2/2.+11./2.+pi2)/2.;
 
   //quark coefficients
   A1q=Cf; //4./3;
   A2q=Cf/2.*Kappa; //(67./6.-pi2/2.-5./9.*NF);
   A3q=Cf*(13.81-2.15*NF-nf2/108.)+Cf*(CA*(29.9259-28.*Z3)-8.2963*NF/2.)*2.*(beta0*4.)/64.; //A3 from Becher & Neubert
   B1q=-(3.*Cf)/2.; //-2;
   B2q=Cf*Cf*(pi2/4.-3./16.-3.*Z3)+CA*Cf*(11*pi2/36.-193./48.+3.*Z3/2.)+Cf*NF*(17./24.-pi2/18.);
   //B2q=4./9.*(pi2-3./4.-12.*Z3)+(11./9.*pi2-193./12.+6.*Z3)+NF/6.*(17./3.-4./9.*pi2);
   C1qqn=Cf/2.*(pi2/2.-4.);          // Only delta(1-z) part, i.e. N independent part
 
   // Delta term in c1qq coefficient
   C1qqdelta=(pi2-8.)/3.;
 
   // Delta term in P2qq splitting function (as/M_PI normalization)
   Delta2qq=16./9.*(3./8.-pi2/2.+6.*Z3)+4.*(17./24.+11.*pi2/18.-3.*Z3)-2./3.*NF*(1./6.+2.*pi2/9.);
   Delta2qq=Delta2qq/4.;
 
   // Coefficients of D0 and D1 in P*P (as/M_PI normalization)
   D0qqqq=8./3.;
   D1qqqq=32./9.;
 
   // Coefficients of delta(1-z) in P*P
   Deltaqqqq=4./9.*(9./4.-2.*pi2/3.);
 
   // H2qq contribution: coefficient of delta(1-z)
   H2qqdelta=-2561./144.+127.*NF/72.+3.*pi2/2.-19.*NF*pi2/81.+49.*pi4/324.+58.*Z3/9.+8.*NF*Z3/27.;
 
   // H2qq contribution: coefficient of D0(z)
   H2qqD0=-404./27.+(56.*NF)/81.+14.*Z3;
 }