--- /dev/null
+* $Id$
+
+C*********************************************************************
+
+ SUBROUTINE LUX3JT_HIJING(NJET,CUT,KFL,ECM,X1,X2)
+
+C...Purpose: to select the kinematical variables of three-jet events.
+#include "ludat1_hijing.inc"
+ DIMENSION ZHUP(5,12)
+
+C...Coefficients of Zhu second order parametrization.
+ DATA ((ZHUP(IC1,IC2),IC2=1,12),IC1=1,5)/
+ & 18.29, 89.56, 4.541, -52.09, -109.8, 24.90,
+ & 11.63, 3.683, 17.50, 0.002440, -1.362, -0.3537,
+ & 11.42, 6.299, -22.55, -8.915, 59.25, -5.855,
+ & -32.85, -1.054, -16.90, 0.006489, -0.8156, 0.01095,
+ & 7.847, -3.964, -35.83, 1.178, 29.39, 0.2806,
+ & 47.82, -12.36, -56.72, 0.04054, -0.4365, 0.6062,
+ & 5.441, -56.89, -50.27, 15.13, 114.3, -18.19,
+ & 97.05, -1.890, -139.9, 0.08153, -0.4984, 0.9439,
+ & -17.65, 51.44, -58.32, 70.95, -255.7, -78.99,
+ & 476.9, 29.65, -239.3, 0.4745, -1.174, 6.081/
+
+C...Dilogarithm of x for x<0.5 (x>0.5 obtained by analytic trick).
+ DILOG(X)=X+X**2/4.+X**3/9.+X**4/16.+X**5/25.+X**6/36.+X**7/49.
+
+C...Event type. Mass effect factors and other common constants.
+ MSTJ(120)=2
+ MSTJ(121)=0
+ PMQ=ULMASS_HIJING(KFL)
+ QME=(2.*PMQ/ECM)**2
+ IF(MSTJ(109).NE.1) THEN
+ CUTL=LOG(CUT)
+ CUTD=LOG(1./CUT-2.)
+ IF(MSTJ(109).EQ.0) THEN
+ CF=4./3.
+ CN=3.
+ TR=2.
+ WTMX=MIN(20.,37.-6.*CUTD)
+ IF(MSTJ(110).EQ.2) WTMX=2.*(7.5+80.*CUT)
+ ELSE
+ CF=1.
+ CN=0.
+ TR=12.
+ WTMX=0.
+ ENDIF
+
+C...Alpha_strong and effects of optimized Q^2 scale. Maximum weight.
+ ALS2PI=PARU(118)/PARU(2)
+ WTOPT=0.
+ IF(MSTJ(111).EQ.1) WTOPT=(33.-2.*MSTU(112))/6.*LOG(PARJ(169))*
+ & ALS2PI
+ WTMAX=MAX(0.,1.+WTOPT+ALS2PI*WTMX)
+
+C...Choose three-jet events in allowed region.
+ 100 NJET=3
+ 110 Y13L=CUTL+CUTD*RLU_HIJING(0)
+ Y23L=CUTL+CUTD*RLU_HIJING(0)
+ Y13=EXP(Y13L)
+ Y23=EXP(Y23L)
+ Y12=1.-Y13-Y23
+ IF(Y12.LE.CUT) GOTO 110
+ IF(Y13**2+Y23**2+2.*Y12.LE.2.*RLU_HIJING(0)) GOTO 110
+
+C...Second order corrections.
+ IF(MSTJ(101).EQ.2.AND.MSTJ(110).LE.1) THEN
+ Y12L=LOG(Y12)
+ Y13M=LOG(1.-Y13)
+ Y23M=LOG(1.-Y23)
+ Y12M=LOG(1.-Y12)
+ IF(Y13.LE.0.5) Y13I=DILOG(Y13)
+ IF(Y13.GE.0.5) Y13I=1.644934-Y13L*Y13M-DILOG(1.-Y13)
+ IF(Y23.LE.0.5) Y23I=DILOG(Y23)
+ IF(Y23.GE.0.5) Y23I=1.644934-Y23L*Y23M-DILOG(1.-Y23)
+ IF(Y12.LE.0.5) Y12I=DILOG(Y12)
+ IF(Y12.GE.0.5) Y12I=1.644934-Y12L*Y12M-DILOG(1.-Y12)
+ WT1=(Y13**2+Y23**2+2.*Y12)/(Y13*Y23)
+ WT2=CF*(-2.*(CUTL-Y12L)**2-3.*CUTL-1.+3.289868+
+ & 2.*(2.*CUTL-Y12L)*CUT/Y12)+
+ & CN*((CUTL-Y12L)**2-(CUTL-Y13L)**2-(CUTL-Y23L)**2-11.*CUTL/6.+
+ & 67./18.+1.644934-(2.*CUTL-Y12L)*CUT/Y12+(2.*CUTL-Y13L)*
+ & CUT/Y13+(2.*CUTL-Y23L)*CUT/Y23)+
+ & TR*(2.*CUTL/3.-10./9.)+
+ & CF*(Y12/(Y12+Y13)+Y12/(Y12+Y23)+(Y12+Y23)/Y13+(Y12+Y13)/Y23+
+ & Y13L*(4.*Y12**2+2.*Y12*Y13+4.*Y12*Y23+Y13*Y23)/(Y12+Y23)**2+
+ & Y23L*(4.*Y12**2+2.*Y12*Y23+4.*Y12*Y13+Y13*Y23)/(Y12+Y13)**2)/
+ & WT1+
+ & CN*(Y13L*Y13/(Y12+Y23)+Y23L*Y23/(Y12+Y13))/WT1+
+ & (CN-2.*CF)*((Y12**2+(Y12+Y13)**2)*(Y12L*Y23L-Y12L*Y12M-Y23L*
+ & Y23M+1.644934-Y12I-Y23I)/(Y13*Y23)+(Y12**2+(Y12+Y23)**2)*
+ & (Y12L*Y13L-Y12L*Y12M-Y13L*Y13M+1.644934-Y12I-Y13I)/
+ & (Y13*Y23)+(Y13**2+Y23**2)/(Y13*Y23*(Y13+Y23))-
+ & 2.*Y12L*Y12**2/(Y13+Y23)**2-4.*Y12L*Y12/(Y13+Y23))/WT1-
+ & CN*(Y13L*Y23L-Y13L*Y13M-Y23L*Y23M+1.644934-Y13I-Y23I)
+ IF(1.+WTOPT+ALS2PI*WT2.LE.0.) MSTJ(121)=1
+ IF(1.+WTOPT+ALS2PI*WT2.LE.WTMAX*RLU_HIJING(0)) GOTO 110
+ PARJ(156)=(WTOPT+ALS2PI*WT2)/(1.+WTOPT+ALS2PI*WT2)
+
+ ELSEIF(MSTJ(101).EQ.2.AND.MSTJ(110).EQ.2) THEN
+C...Second order corrections; Zhu parametrization of ERT.
+ ZX=(Y23-Y13)**2
+ ZY=1.-Y12
+ IZA=0
+ DO 120 IY=1,5
+ 120 IF(ABS(CUT-0.01*IY).LT.0.0001) IZA=IY
+ IF(IZA.NE.0) THEN
+ IZ=IZA
+ WT2=ZHUP(IZ,1)+ZHUP(IZ,2)*ZX+ZHUP(IZ,3)*ZX**2+(ZHUP(IZ,4)+
+ & ZHUP(IZ,5)*ZX)*ZY+(ZHUP(IZ,6)+ZHUP(IZ,7)*ZX)*ZY**2+
+ & (ZHUP(IZ,8)+ZHUP(IZ,9)*ZX)*ZY**3+ZHUP(IZ,10)/(ZX-ZY**2)+
+ & ZHUP(IZ,11)/(1.-ZY)+ZHUP(IZ,12)/ZY
+ ELSE
+ IZ=100.*CUT
+ WTL=ZHUP(IZ,1)+ZHUP(IZ,2)*ZX+ZHUP(IZ,3)*ZX**2+(ZHUP(IZ,4)+
+ & ZHUP(IZ,5)*ZX)*ZY+(ZHUP(IZ,6)+ZHUP(IZ,7)*ZX)*ZY**2+
+ & (ZHUP(IZ,8)+ZHUP(IZ,9)*ZX)*ZY**3+ZHUP(IZ,10)/(ZX-ZY**2)+
+ & ZHUP(IZ,11)/(1.-ZY)+ZHUP(IZ,12)/ZY
+ IZ=IZ+1
+ WTU=ZHUP(IZ,1)+ZHUP(IZ,2)*ZX+ZHUP(IZ,3)*ZX**2+(ZHUP(IZ,4)+
+ & ZHUP(IZ,5)*ZX)*ZY+(ZHUP(IZ,6)+ZHUP(IZ,7)*ZX)*ZY**2+
+ & (ZHUP(IZ,8)+ZHUP(IZ,9)*ZX)*ZY**3+ZHUP(IZ,10)/(ZX-ZY**2)+
+ & ZHUP(IZ,11)/(1.-ZY)+ZHUP(IZ,12)/ZY
+ WT2=WTL+(WTU-WTL)*(100.*CUT+1.-IZ)
+ ENDIF
+ IF(1.+WTOPT+2.*ALS2PI*WT2.LE.0.) MSTJ(121)=1
+ IF(1.+WTOPT+2.*ALS2PI*WT2.LE.WTMAX*RLU_HIJING(0)) GOTO 110
+ PARJ(156)=(WTOPT+2.*ALS2PI*WT2)/(1.+WTOPT+2.*ALS2PI*WT2)
+ ENDIF
+
+C...Impose mass cuts (gives two jets). For fixed jet number new try.
+ X1=1.-Y23
+ X2=1.-Y13
+ X3=1.-Y12
+ IF(4.*Y23*Y13*Y12/X3**2.LE.QME) NJET=2
+ IF(MOD(MSTJ(103),4).GE.2.AND.IABS(MSTJ(101)).LE.1.AND.QME*X3+
+ & 0.5*QME**2+(0.5*QME+0.25*QME**2)*((1.-X2)/(1.-X1)+
+ & (1.-X1)/(1.-X2)).GT.(X1**2+X2**2)*RLU_HIJING(0)) NJET=2
+ IF(MSTJ(101).EQ.-1.AND.NJET.EQ.2) GOTO 100
+
+C...Scalar gluon model (first order only, no mass effects).
+ ELSE
+ 130 NJET=3
+ 140 Y12=SQRT(4.*CUT**2+RLU_HIJING(0)*((1.-CUT)**2-4.*CUT**2))
+ IF(LOG((Y12-CUT)/CUT).LE.RLU_HIJING(0)*LOG((1.-2.*CUT)/CUT))
+ $ GOTO 140
+ YD=SIGN(2.*CUT*((Y12-CUT)/CUT)**RLU_HIJING(0)-Y12,RLU_HIJING(0)
+ $ -0.5)
+ X1=1.-0.5*(Y12+YD)
+ X2=1.-0.5*(Y12-YD)
+ IF(4.*(1.-X1)*(1.-X2)*Y12/(1.-Y12)**2.LE.QME) NJET=2
+ IF(MSTJ(101).EQ.-1.AND.NJET.EQ.2) GOTO 130
+ ENDIF
+
+ RETURN
+ END