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SUBROUTINE SMATRIX3(P,ANS)
C
C Generated by MadGraph 5 v. 2.0.0.beta3, 2013-02-14
C By the MadGraph Development Team
C Please visit us at https://launchpad.net/madgraph5
C
C MadGraph for Madevent Version
C
C Returns amplitude squared summed/avg over colors
C and helicities
C for the point in phase space P(0:3,NEXTERNAL)
C
C Process: u~ u~ > u u~ u~ u~ WEIGHTED=4
C Process: s~ s~ > s s~ s~ s~ WEIGHTED=4
C
IMPLICIT NONE
C
C CONSTANTS
C
INCLUDE 'genps.inc'
INCLUDE 'maxconfigs.inc'
INCLUDE 'nexternal.inc'
INCLUDE 'maxamps.inc'
INTEGER NCOMB
PARAMETER ( NCOMB=64)
INTEGER NGRAPHS
PARAMETER (NGRAPHS=42)
INTEGER NDIAGS
PARAMETER (NDIAGS=42)
INTEGER THEL
PARAMETER (THEL=2*NCOMB)
C
C ARGUMENTS
C
REAL*8 P(0:3,NEXTERNAL),ANS
C
C LOCAL VARIABLES
C
INTEGER NHEL(NEXTERNAL,NCOMB),NTRY(2)
INTEGER ISHEL(2)
REAL*8 T,MATRIX3
REAL*8 R,SUMHEL,TS(NCOMB)
INTEGER I,IDEN
INTEGER JC(NEXTERNAL),II
LOGICAL GOODHEL(NCOMB,2)
REAL*8 HWGT, XTOT, XTRY, XREJ, XR, YFRAC(0:NCOMB)
INTEGER NGOOD(2), IGOOD(NCOMB,2)
INTEGER JHEL(2), J, JJ
C
C GLOBAL VARIABLES
C
DOUBLE PRECISION AMP2(MAXAMPS), JAMP2(0:MAXFLOW)
COMMON/TO_AMPS/ AMP2, JAMP2
CHARACTER*101 HEL_BUFF
COMMON/TO_HELICITY/ HEL_BUFF
INTEGER IMIRROR
COMMON/TO_MIRROR/ IMIRROR
REAL*8 POL(2)
COMMON/TO_POLARIZATION/ POL
INTEGER ISUM_HEL
LOGICAL MULTI_CHANNEL
COMMON/TO_MATRIX/ISUM_HEL, MULTI_CHANNEL
INTEGER MAPCONFIG(0:LMAXCONFIGS), ICONFIG
COMMON/TO_MCONFIGS/MAPCONFIG, ICONFIG
INTEGER SUBDIAG(MAXSPROC),IB(2)
COMMON/TO_SUB_DIAG/SUBDIAG,IB
DATA XTRY, XREJ /0,0/
DATA NTRY /0,0/
DATA NGOOD /0,0/
DATA ISHEL/0,0/
SAVE YFRAC, IGOOD, JHEL
DATA GOODHEL/THEL*.FALSE./
DATA (NHEL(I, 1),I=1,6) /-1,-1,-1,-1,-1,-1/
DATA (NHEL(I, 2),I=1,6) /-1,-1,-1,-1,-1, 1/
DATA (NHEL(I, 3),I=1,6) /-1,-1,-1,-1, 1,-1/
DATA (NHEL(I, 4),I=1,6) /-1,-1,-1,-1, 1, 1/
DATA (NHEL(I, 5),I=1,6) /-1,-1,-1, 1,-1,-1/
DATA (NHEL(I, 6),I=1,6) /-1,-1,-1, 1,-1, 1/
DATA (NHEL(I, 7),I=1,6) /-1,-1,-1, 1, 1,-1/
DATA (NHEL(I, 8),I=1,6) /-1,-1,-1, 1, 1, 1/
DATA (NHEL(I, 9),I=1,6) /-1,-1, 1,-1,-1,-1/
DATA (NHEL(I, 10),I=1,6) /-1,-1, 1,-1,-1, 1/
DATA (NHEL(I, 11),I=1,6) /-1,-1, 1,-1, 1,-1/
DATA (NHEL(I, 12),I=1,6) /-1,-1, 1,-1, 1, 1/
DATA (NHEL(I, 13),I=1,6) /-1,-1, 1, 1,-1,-1/
DATA (NHEL(I, 14),I=1,6) /-1,-1, 1, 1,-1, 1/
DATA (NHEL(I, 15),I=1,6) /-1,-1, 1, 1, 1,-1/
DATA (NHEL(I, 16),I=1,6) /-1,-1, 1, 1, 1, 1/
DATA (NHEL(I, 17),I=1,6) /-1, 1,-1,-1,-1,-1/
DATA (NHEL(I, 18),I=1,6) /-1, 1,-1,-1,-1, 1/
DATA (NHEL(I, 19),I=1,6) /-1, 1,-1,-1, 1,-1/
DATA (NHEL(I, 20),I=1,6) /-1, 1,-1,-1, 1, 1/
DATA (NHEL(I, 21),I=1,6) /-1, 1,-1, 1,-1,-1/
DATA (NHEL(I, 22),I=1,6) /-1, 1,-1, 1,-1, 1/
DATA (NHEL(I, 23),I=1,6) /-1, 1,-1, 1, 1,-1/
DATA (NHEL(I, 24),I=1,6) /-1, 1,-1, 1, 1, 1/
DATA (NHEL(I, 25),I=1,6) /-1, 1, 1,-1,-1,-1/
DATA (NHEL(I, 26),I=1,6) /-1, 1, 1,-1,-1, 1/
DATA (NHEL(I, 27),I=1,6) /-1, 1, 1,-1, 1,-1/
DATA (NHEL(I, 28),I=1,6) /-1, 1, 1,-1, 1, 1/
DATA (NHEL(I, 29),I=1,6) /-1, 1, 1, 1,-1,-1/
DATA (NHEL(I, 30),I=1,6) /-1, 1, 1, 1,-1, 1/
DATA (NHEL(I, 31),I=1,6) /-1, 1, 1, 1, 1,-1/
DATA (NHEL(I, 32),I=1,6) /-1, 1, 1, 1, 1, 1/
DATA (NHEL(I, 33),I=1,6) / 1,-1,-1,-1,-1,-1/
DATA (NHEL(I, 34),I=1,6) / 1,-1,-1,-1,-1, 1/
DATA (NHEL(I, 35),I=1,6) / 1,-1,-1,-1, 1,-1/
DATA (NHEL(I, 36),I=1,6) / 1,-1,-1,-1, 1, 1/
DATA (NHEL(I, 37),I=1,6) / 1,-1,-1, 1,-1,-1/
DATA (NHEL(I, 38),I=1,6) / 1,-1,-1, 1,-1, 1/
DATA (NHEL(I, 39),I=1,6) / 1,-1,-1, 1, 1,-1/
DATA (NHEL(I, 40),I=1,6) / 1,-1,-1, 1, 1, 1/
DATA (NHEL(I, 41),I=1,6) / 1,-1, 1,-1,-1,-1/
DATA (NHEL(I, 42),I=1,6) / 1,-1, 1,-1,-1, 1/
DATA (NHEL(I, 43),I=1,6) / 1,-1, 1,-1, 1,-1/
DATA (NHEL(I, 44),I=1,6) / 1,-1, 1,-1, 1, 1/
DATA (NHEL(I, 45),I=1,6) / 1,-1, 1, 1,-1,-1/
DATA (NHEL(I, 46),I=1,6) / 1,-1, 1, 1,-1, 1/
DATA (NHEL(I, 47),I=1,6) / 1,-1, 1, 1, 1,-1/
DATA (NHEL(I, 48),I=1,6) / 1,-1, 1, 1, 1, 1/
DATA (NHEL(I, 49),I=1,6) / 1, 1,-1,-1,-1,-1/
DATA (NHEL(I, 50),I=1,6) / 1, 1,-1,-1,-1, 1/
DATA (NHEL(I, 51),I=1,6) / 1, 1,-1,-1, 1,-1/
DATA (NHEL(I, 52),I=1,6) / 1, 1,-1,-1, 1, 1/
DATA (NHEL(I, 53),I=1,6) / 1, 1,-1, 1,-1,-1/
DATA (NHEL(I, 54),I=1,6) / 1, 1,-1, 1,-1, 1/
DATA (NHEL(I, 55),I=1,6) / 1, 1,-1, 1, 1,-1/
DATA (NHEL(I, 56),I=1,6) / 1, 1,-1, 1, 1, 1/
DATA (NHEL(I, 57),I=1,6) / 1, 1, 1,-1,-1,-1/
DATA (NHEL(I, 58),I=1,6) / 1, 1, 1,-1,-1, 1/
DATA (NHEL(I, 59),I=1,6) / 1, 1, 1,-1, 1,-1/
DATA (NHEL(I, 60),I=1,6) / 1, 1, 1,-1, 1, 1/
DATA (NHEL(I, 61),I=1,6) / 1, 1, 1, 1,-1,-1/
DATA (NHEL(I, 62),I=1,6) / 1, 1, 1, 1,-1, 1/
DATA (NHEL(I, 63),I=1,6) / 1, 1, 1, 1, 1,-1/
DATA (NHEL(I, 64),I=1,6) / 1, 1, 1, 1, 1, 1/
DATA IDEN/216/
C ----------
C BEGIN CODE
C ----------
NTRY(IMIRROR)=NTRY(IMIRROR)+1
DO I=1,NEXTERNAL
JC(I) = +1
ENDDO
IF (MULTI_CHANNEL) THEN
DO I=1,NDIAGS
AMP2(I)=0D0
ENDDO
JAMP2(0)=6
DO I=1,INT(JAMP2(0))
JAMP2(I)=0D0
ENDDO
ENDIF
ANS = 0D0
WRITE(HEL_BUFF,'(20I5)') (0,I=1,NEXTERNAL)
DO I=1,NCOMB
TS(I)=0D0
ENDDO
IF (ISHEL(IMIRROR) .EQ. 0 .OR. NTRY(IMIRROR) .LE. MAXTRIES) THEN
DO I=1,NCOMB
IF (GOODHEL(I,IMIRROR) .OR. NTRY(IMIRROR).LE.MAXTRIES) THEN
T=MATRIX3(P ,NHEL(1,I),JC(1))
DO JJ=1,NINCOMING
IF(POL(JJ).NE.1D0.AND.NHEL(JJ,I).EQ.INT(SIGN(1D0
$ ,POL(JJ)))) THEN
T=T*ABS(POL(JJ))
ELSE IF(POL(JJ).NE.1D0)THEN
T=T*(2D0-ABS(POL(JJ)))
ENDIF
ENDDO
ANS=ANS+DABS(T)
TS(I)=T
ENDIF
ENDDO
JHEL(IMIRROR) = 1
IF(NTRY(IMIRROR).LE.MAXTRIES)THEN
DO I=1,NCOMB
IF (.NOT.GOODHEL(I,IMIRROR) .AND. (DABS(TS(I)).GT.ANS
$ *LIMHEL/NCOMB)) THEN
GOODHEL(I,IMIRROR)=.TRUE.
NGOOD(IMIRROR) = NGOOD(IMIRROR) +1
IGOOD(NGOOD(IMIRROR),IMIRROR) = I
PRINT *,'Added good helicity ',I,TS(I)*NCOMB/ANS
$ ,' in event ',NTRY(IMIRROR)
ENDIF
ENDDO
ENDIF
IF(NTRY(IMIRROR).EQ.MAXTRIES)THEN
ISHEL(IMIRROR)=MIN(ISUM_HEL,NGOOD(IMIRROR))
ENDIF
ELSE !LOOP OVER GOOD HELICITIES
DO J=1,ISHEL(IMIRROR)
JHEL(IMIRROR)=JHEL(IMIRROR)+1
IF (JHEL(IMIRROR) .GT. NGOOD(IMIRROR)) JHEL(IMIRROR)=1
HWGT = REAL(NGOOD(IMIRROR))/REAL(ISHEL(IMIRROR))
I = IGOOD(JHEL(IMIRROR),IMIRROR)
T=MATRIX3(P ,NHEL(1,I),JC(1))
DO JJ=1,NINCOMING
IF(POL(JJ).NE.1D0.AND.NHEL(JJ,I).EQ.INT(SIGN(1D0,POL(JJ)))
$ ) THEN
T=T*ABS(POL(JJ))
ELSE IF(POL(JJ).NE.1D0)THEN
T=T*(2D0-ABS(POL(JJ)))
ENDIF
ENDDO
ANS=ANS+DABS(T)*HWGT
TS(I)=T*HWGT
ENDDO
IF (ISHEL(IMIRROR) .EQ. 1) THEN
WRITE(HEL_BUFF,'(20i5)')(NHEL(II,I),II=1,NEXTERNAL)
C Set right sign for ANS, based on sign of chosen helicity
ANS=DSIGN(ANS,TS(I))
ENDIF
ENDIF
IF (ISHEL(IMIRROR) .NE. 1) THEN
CALL RANMAR(R)
SUMHEL=0D0
DO I=1,NCOMB
SUMHEL=SUMHEL+DABS(TS(I))/ANS
IF(R.LT.SUMHEL)THEN
WRITE(HEL_BUFF,'(20i5)')(NHEL(II,I),II=1,NEXTERNAL)
C Set right sign for ANS, based on sign of chosen helicity
ANS=DSIGN(ANS,TS(I))
GOTO 10
ENDIF
ENDDO
10 CONTINUE
ENDIF
IF (MULTI_CHANNEL) THEN
XTOT=0D0
DO I=1,NDIAGS
XTOT=XTOT+AMP2(I)
ENDDO
IF (XTOT.NE.0D0) THEN
ANS=ANS*AMP2(SUBDIAG(3))/XTOT
ELSE
ANS=0D0
ENDIF
ENDIF
ANS=ANS/DBLE(IDEN)
END
REAL*8 FUNCTION MATRIX3(P,NHEL,IC)
C
C Generated by MadGraph 5 v. 2.0.0.beta3, 2013-02-14
C By the MadGraph Development Team
C Please visit us at https://launchpad.net/madgraph5
C
C Returns amplitude squared summed/avg over colors
C for the point with external lines W(0:6,NEXTERNAL)
C
C Process: u~ u~ > u u~ u~ u~ WEIGHTED=4
C Process: s~ s~ > s s~ s~ s~ WEIGHTED=4
C
IMPLICIT NONE
C
C CONSTANTS
C
INTEGER NGRAPHS
PARAMETER (NGRAPHS=42)
INCLUDE 'genps.inc'
INCLUDE 'nexternal.inc'
INCLUDE 'maxamps.inc'
INTEGER NWAVEFUNCS, NCOLOR
PARAMETER (NWAVEFUNCS=16, NCOLOR=6)
REAL*8 ZERO
PARAMETER (ZERO=0D0)
COMPLEX*16 IMAG1
PARAMETER (IMAG1=(0D0,1D0))
C
C ARGUMENTS
C
REAL*8 P(0:3,NEXTERNAL)
INTEGER NHEL(NEXTERNAL), IC(NEXTERNAL)
C
C LOCAL VARIABLES
C
INTEGER I,J
COMPLEX*16 ZTEMP
REAL*8 DENOM(NCOLOR), CF(NCOLOR,NCOLOR)
COMPLEX*16 AMP(NGRAPHS), JAMP(NCOLOR)
COMPLEX*16 W(6,NWAVEFUNCS)
C Needed for v4 models
COMPLEX*16 DUM0,DUM1
DATA DUM0, DUM1/(0D0, 0D0), (1D0, 0D0)/
C
C GLOBAL VARIABLES
C
DOUBLE PRECISION AMP2(MAXAMPS), JAMP2(0:MAXFLOW)
COMMON/TO_AMPS/ AMP2, JAMP2
INCLUDE 'coupl.inc'
C
C COLOR DATA
C
DATA DENOM(1)/1/
DATA (CF(I, 1),I= 1, 6) / 27, 9, 9, 3, 3, 9/
C 1 T(1,4) T(2,5) T(3,6)
DATA DENOM(2)/1/
DATA (CF(I, 2),I= 1, 6) / 9, 27, 3, 9, 9, 3/
C 1 T(1,4) T(2,6) T(3,5)
DATA DENOM(3)/1/
DATA (CF(I, 3),I= 1, 6) / 9, 3, 27, 9, 9, 3/
C 1 T(1,5) T(2,4) T(3,6)
DATA DENOM(4)/1/
DATA (CF(I, 4),I= 1, 6) / 3, 9, 9, 27, 3, 9/
C 1 T(1,5) T(2,6) T(3,4)
DATA DENOM(5)/1/
DATA (CF(I, 5),I= 1, 6) / 3, 9, 9, 3, 27, 9/
C 1 T(1,6) T(2,4) T(3,5)
DATA DENOM(6)/1/
DATA (CF(I, 6),I= 1, 6) / 9, 3, 3, 9, 9, 27/
C 1 T(1,6) T(2,5) T(3,4)
C ----------
C BEGIN CODE
C ----------
CALL OXXXXX(P(0,1),ZERO,NHEL(1),-1*IC(1),W(1,1))
CALL OXXXXX(P(0,2),ZERO,NHEL(2),-1*IC(2),W(1,2))
CALL OXXXXX(P(0,3),ZERO,NHEL(3),+1*IC(3),W(1,3))
CALL IXXXXX(P(0,4),ZERO,NHEL(4),-1*IC(4),W(1,4))
CALL IXXXXX(P(0,5),ZERO,NHEL(5),-1*IC(5),W(1,5))
CALL IXXXXX(P(0,6),ZERO,NHEL(6),-1*IC(6),W(1,6))
CALL FFV1_3(W(1,4),W(1,1),GC_11,ZERO,ZERO,W(1,7))
CALL FFV1_3(W(1,5),W(1,2),GC_11,ZERO,ZERO,W(1,8))
CALL FFV1_1(W(1,3),W(1,7),GC_11,ZERO,ZERO,W(1,9))
C Amplitude(s) for diagram number 1
CALL FFV1_0(W(1,6),W(1,9),W(1,8),GC_11,AMP(1))
CALL FFV1_2(W(1,6),W(1,7),GC_11,ZERO,ZERO,W(1,10))
C Amplitude(s) for diagram number 2
CALL FFV1_0(W(1,10),W(1,3),W(1,8),GC_11,AMP(2))
CALL FFV1_3(W(1,6),W(1,3),GC_11,ZERO,ZERO,W(1,11))
C Amplitude(s) for diagram number 3
CALL VVV1_0(W(1,7),W(1,8),W(1,11),GC_10,AMP(3))
CALL FFV1_3(W(1,5),W(1,3),GC_11,ZERO,ZERO,W(1,12))
CALL FFV1_1(W(1,2),W(1,7),GC_11,ZERO,ZERO,W(1,13))
C Amplitude(s) for diagram number 4
CALL FFV1_0(W(1,6),W(1,13),W(1,12),GC_11,AMP(4))
C Amplitude(s) for diagram number 5
CALL FFV1_0(W(1,10),W(1,2),W(1,12),GC_11,AMP(5))
CALL FFV1_3(W(1,6),W(1,2),GC_11,ZERO,ZERO,W(1,10))
C Amplitude(s) for diagram number 6
CALL VVV1_0(W(1,7),W(1,12),W(1,10),GC_10,AMP(6))
CALL FFV1_2(W(1,5),W(1,7),GC_11,ZERO,ZERO,W(1,14))
C Amplitude(s) for diagram number 7
CALL FFV1_0(W(1,14),W(1,3),W(1,10),GC_11,AMP(7))
C Amplitude(s) for diagram number 8
CALL FFV1_0(W(1,5),W(1,9),W(1,10),GC_11,AMP(8))
C Amplitude(s) for diagram number 9
CALL FFV1_0(W(1,14),W(1,2),W(1,11),GC_11,AMP(9))
C Amplitude(s) for diagram number 10
CALL FFV1_0(W(1,5),W(1,13),W(1,11),GC_11,AMP(10))
CALL FFV1_3(W(1,4),W(1,2),GC_11,ZERO,ZERO,W(1,13))
CALL FFV1_3(W(1,5),W(1,1),GC_11,ZERO,ZERO,W(1,14))
CALL FFV1_1(W(1,3),W(1,13),GC_11,ZERO,ZERO,W(1,9))
C Amplitude(s) for diagram number 11
CALL FFV1_0(W(1,6),W(1,9),W(1,14),GC_11,AMP(11))
CALL FFV1_2(W(1,6),W(1,13),GC_11,ZERO,ZERO,W(1,7))
C Amplitude(s) for diagram number 12
CALL FFV1_0(W(1,7),W(1,3),W(1,14),GC_11,AMP(12))
C Amplitude(s) for diagram number 13
CALL VVV1_0(W(1,13),W(1,14),W(1,11),GC_10,AMP(13))
CALL FFV1_1(W(1,1),W(1,13),GC_11,ZERO,ZERO,W(1,15))
C Amplitude(s) for diagram number 14
CALL FFV1_0(W(1,6),W(1,15),W(1,12),GC_11,AMP(14))
C Amplitude(s) for diagram number 15
CALL FFV1_0(W(1,7),W(1,1),W(1,12),GC_11,AMP(15))
CALL FFV1_3(W(1,6),W(1,1),GC_11,ZERO,ZERO,W(1,7))
C Amplitude(s) for diagram number 16
CALL VVV1_0(W(1,13),W(1,12),W(1,7),GC_10,AMP(16))
CALL FFV1_2(W(1,5),W(1,13),GC_11,ZERO,ZERO,W(1,16))
C Amplitude(s) for diagram number 17
CALL FFV1_0(W(1,16),W(1,3),W(1,7),GC_11,AMP(17))
C Amplitude(s) for diagram number 18
CALL FFV1_0(W(1,5),W(1,9),W(1,7),GC_11,AMP(18))
C Amplitude(s) for diagram number 19
CALL FFV1_0(W(1,16),W(1,1),W(1,11),GC_11,AMP(19))
C Amplitude(s) for diagram number 20
CALL FFV1_0(W(1,5),W(1,15),W(1,11),GC_11,AMP(20))
CALL FFV1_3(W(1,4),W(1,3),GC_11,ZERO,ZERO,W(1,15))
CALL FFV1_1(W(1,2),W(1,15),GC_11,ZERO,ZERO,W(1,16))
C Amplitude(s) for diagram number 21
CALL FFV1_0(W(1,6),W(1,16),W(1,14),GC_11,AMP(21))
CALL FFV1_2(W(1,6),W(1,15),GC_11,ZERO,ZERO,W(1,9))
C Amplitude(s) for diagram number 22
CALL FFV1_0(W(1,9),W(1,2),W(1,14),GC_11,AMP(22))
C Amplitude(s) for diagram number 23
CALL VVV1_0(W(1,15),W(1,14),W(1,10),GC_10,AMP(23))
CALL FFV1_1(W(1,1),W(1,15),GC_11,ZERO,ZERO,W(1,13))
C Amplitude(s) for diagram number 24
CALL FFV1_0(W(1,6),W(1,13),W(1,8),GC_11,AMP(24))
C Amplitude(s) for diagram number 25
CALL FFV1_0(W(1,9),W(1,1),W(1,8),GC_11,AMP(25))
C Amplitude(s) for diagram number 26
CALL VVV1_0(W(1,15),W(1,8),W(1,7),GC_10,AMP(26))
CALL FFV1_2(W(1,5),W(1,15),GC_11,ZERO,ZERO,W(1,9))
C Amplitude(s) for diagram number 27
CALL FFV1_0(W(1,9),W(1,2),W(1,7),GC_11,AMP(27))
C Amplitude(s) for diagram number 28
CALL FFV1_0(W(1,5),W(1,16),W(1,7),GC_11,AMP(28))
C Amplitude(s) for diagram number 29
CALL FFV1_0(W(1,9),W(1,1),W(1,10),GC_11,AMP(29))
C Amplitude(s) for diagram number 30
CALL FFV1_0(W(1,5),W(1,13),W(1,10),GC_11,AMP(30))
CALL FFV1_2(W(1,4),W(1,14),GC_11,ZERO,ZERO,W(1,13))
C Amplitude(s) for diagram number 31
CALL FFV1_0(W(1,13),W(1,3),W(1,10),GC_11,AMP(31))
CALL FFV1_2(W(1,4),W(1,10),GC_11,ZERO,ZERO,W(1,5))
C Amplitude(s) for diagram number 32
CALL FFV1_0(W(1,5),W(1,3),W(1,14),GC_11,AMP(32))
C Amplitude(s) for diagram number 33
CALL FFV1_0(W(1,13),W(1,2),W(1,11),GC_11,AMP(33))
CALL FFV1_2(W(1,4),W(1,11),GC_11,ZERO,ZERO,W(1,13))
C Amplitude(s) for diagram number 34
CALL FFV1_0(W(1,13),W(1,2),W(1,14),GC_11,AMP(34))
CALL FFV1_2(W(1,4),W(1,8),GC_11,ZERO,ZERO,W(1,14))
C Amplitude(s) for diagram number 35
CALL FFV1_0(W(1,14),W(1,3),W(1,7),GC_11,AMP(35))
CALL FFV1_2(W(1,4),W(1,7),GC_11,ZERO,ZERO,W(1,9))
C Amplitude(s) for diagram number 36
CALL FFV1_0(W(1,9),W(1,3),W(1,8),GC_11,AMP(36))
C Amplitude(s) for diagram number 37
CALL FFV1_0(W(1,14),W(1,1),W(1,11),GC_11,AMP(37))
C Amplitude(s) for diagram number 38
CALL FFV1_0(W(1,13),W(1,1),W(1,8),GC_11,AMP(38))
CALL FFV1_2(W(1,4),W(1,12),GC_11,ZERO,ZERO,W(1,13))
C Amplitude(s) for diagram number 39
CALL FFV1_0(W(1,13),W(1,2),W(1,7),GC_11,AMP(39))
C Amplitude(s) for diagram number 40
CALL FFV1_0(W(1,9),W(1,2),W(1,12),GC_11,AMP(40))
C Amplitude(s) for diagram number 41
CALL FFV1_0(W(1,13),W(1,1),W(1,10),GC_11,AMP(41))
C Amplitude(s) for diagram number 42
CALL FFV1_0(W(1,5),W(1,1),W(1,12),GC_11,AMP(42))
JAMP(1)=+1D0/4D0*(+1D0/9D0*AMP(1)+1D0/9D0*AMP(2)+1D0/3D0*AMP(4)
$ +1D0/3D0*AMP(5)+1D0/3D0*AMP(7)+1D0/3D0*AMP(8)+1D0/9D0*AMP(9)
$ +1D0/9D0*AMP(10)+AMP(14)-IMAG1*AMP(16)+AMP(17)+1D0/3D0*AMP(19)
$ +1D0/3D0*AMP(20)+AMP(22)+IMAG1*AMP(23)+1D0/3D0*AMP(24)
$ +1D0/3D0*AMP(25)+AMP(30)+AMP(31)+1D0/3D0*AMP(33)+1D0/3D0
$ *AMP(34)+1D0/3D0*AMP(35)+1D0/3D0*AMP(36)+1D0/9D0*AMP(37)
$ +1D0/9D0*AMP(38)+AMP(40))
JAMP(2)=+1D0/4D0*(-1D0/3D0*AMP(1)-1D0/3D0*AMP(2)-1D0/9D0*AMP(4)
$ -1D0/9D0*AMP(5)-1D0/9D0*AMP(7)-1D0/9D0*AMP(8)-1D0/3D0*AMP(9)
$ -1D0/3D0*AMP(10)-AMP(12)-IMAG1*AMP(13)-1D0/3D0*AMP(14)
$ -1D0/3D0*AMP(15)-AMP(20)-AMP(24)+IMAG1*AMP(26)-AMP(27)
$ -1D0/3D0*AMP(29)-1D0/3D0*AMP(30)-1D0/3D0*AMP(31)-1D0/3D0
$ *AMP(32)-AMP(33)-AMP(36)-1D0/3D0*AMP(39)-1D0/3D0*AMP(40)
$ -1D0/9D0*AMP(41)-1D0/9D0*AMP(42))
JAMP(3)=+1D0/4D0*(-AMP(4)+IMAG1*AMP(6)-AMP(7)-1D0/3D0*AMP(9)
$ -1D0/3D0*AMP(10)-1D0/9D0*AMP(11)-1D0/9D0*AMP(12)-1D0/3D0
$ *AMP(14)-1D0/3D0*AMP(15)-1D0/3D0*AMP(17)-1D0/3D0*AMP(18)
$ -1D0/9D0*AMP(19)-1D0/9D0*AMP(20)-1D0/3D0*AMP(21)-1D0/3D0
$ *AMP(22)-AMP(25)-IMAG1*AMP(26)-AMP(28)-1D0/3D0*AMP(31)
$ -1D0/3D0*AMP(32)-1D0/9D0*AMP(33)-1D0/9D0*AMP(34)-AMP(35)
$ -1D0/3D0*AMP(37)-1D0/3D0*AMP(38)-AMP(42))
JAMP(4)=+1D0/4D0*(+AMP(1)-IMAG1*AMP(3)+1D0/3D0*AMP(7)+1D0/3D0
$ *AMP(8)+AMP(9)+1D0/3D0*AMP(11)+1D0/3D0*AMP(12)+AMP(15)
$ +IMAG1*AMP(16)+AMP(18)+1D0/9D0*AMP(21)+1D0/9D0*AMP(22)
$ +1D0/3D0*AMP(24)+1D0/3D0*AMP(25)+1D0/3D0*AMP(27)+1D0/3D0
$ *AMP(28)+1D0/9D0*AMP(29)+1D0/9D0*AMP(30)+1D0/9D0*AMP(31)
$ +1D0/9D0*AMP(32)+1D0/3D0*AMP(33)+1D0/3D0*AMP(34)+AMP(38)
$ +AMP(39)+1D0/3D0*AMP(41)+1D0/3D0*AMP(42))
JAMP(5)=+1D0/4D0*(+AMP(2)+IMAG1*AMP(3)+1D0/3D0*AMP(4)+1D0/3D0
$ *AMP(5)+AMP(10)+1D0/3D0*AMP(11)+1D0/3D0*AMP(12)+1D0/9D0*AMP(14)
$ +1D0/9D0*AMP(15)+1D0/9D0*AMP(17)+1D0/9D0*AMP(18)+1D0/3D0
$ *AMP(19)+1D0/3D0*AMP(20)+AMP(21)-IMAG1*AMP(23)+1D0/3D0*AMP(27)
$ +1D0/3D0*AMP(28)+AMP(29)+AMP(32)+1D0/3D0*AMP(35)+1D0/3D0
$ *AMP(36)+AMP(37)+1D0/9D0*AMP(39)+1D0/9D0*AMP(40)+1D0/3D0
$ *AMP(41)+1D0/3D0*AMP(42))
JAMP(6)=+1D0/4D0*(-1D0/3D0*AMP(1)-1D0/3D0*AMP(2)-AMP(5)
$ -IMAG1*AMP(6)-AMP(8)-AMP(11)+IMAG1*AMP(13)-1D0/3D0*AMP(17)
$ -1D0/3D0*AMP(18)-AMP(19)-1D0/3D0*AMP(21)-1D0/3D0*AMP(22)
$ -1D0/9D0*AMP(24)-1D0/9D0*AMP(25)-1D0/9D0*AMP(27)-1D0/9D0
$ *AMP(28)-1D0/3D0*AMP(29)-1D0/3D0*AMP(30)-AMP(34)-1D0/9D0
$ *AMP(35)-1D0/9D0*AMP(36)-1D0/3D0*AMP(37)-1D0/3D0*AMP(38)
$ -1D0/3D0*AMP(39)-1D0/3D0*AMP(40)-AMP(41))
MATRIX3 = 0.D0
DO I = 1, NCOLOR
ZTEMP = (0.D0,0.D0)
DO J = 1, NCOLOR
ZTEMP = ZTEMP + CF(J,I)*JAMP(J)
ENDDO
MATRIX3=MATRIX3+ZTEMP*DCONJG(JAMP(I))/DENOM(I)
ENDDO
AMP2(1)=AMP2(1)+AMP(1)*DCONJG(AMP(1))
AMP2(2)=AMP2(2)+AMP(2)*DCONJG(AMP(2))
AMP2(3)=AMP2(3)+AMP(3)*DCONJG(AMP(3))
AMP2(10)=AMP2(10)+AMP(10)*DCONJG(AMP(10))
AMP2(9)=AMP2(9)+AMP(9)*DCONJG(AMP(9))
AMP2(12)=AMP2(12)+AMP(12)*DCONJG(AMP(12))
AMP2(11)=AMP2(11)+AMP(11)*DCONJG(AMP(11))
AMP2(13)=AMP2(13)+AMP(13)*DCONJG(AMP(13))
AMP2(34)=AMP2(34)+AMP(34)*DCONJG(AMP(34))
AMP2(33)=AMP2(33)+AMP(33)*DCONJG(AMP(33))
AMP2(20)=AMP2(20)+AMP(20)*DCONJG(AMP(20))
AMP2(19)=AMP2(19)+AMP(19)*DCONJG(AMP(19))
AMP2(38)=AMP2(38)+AMP(38)*DCONJG(AMP(38))
AMP2(37)=AMP2(37)+AMP(37)*DCONJG(AMP(37))
AMP2(4)=AMP2(4)+AMP(4)*DCONJG(AMP(4))
AMP2(5)=AMP2(5)+AMP(5)*DCONJG(AMP(5))
AMP2(6)=AMP2(6)+AMP(6)*DCONJG(AMP(6))
AMP2(7)=AMP2(7)+AMP(7)*DCONJG(AMP(7))
AMP2(8)=AMP2(8)+AMP(8)*DCONJG(AMP(8))
AMP2(42)=AMP2(42)+AMP(42)*DCONJG(AMP(42))
AMP2(41)=AMP2(41)+AMP(41)*DCONJG(AMP(41))
AMP2(14)=AMP2(14)+AMP(14)*DCONJG(AMP(14))
AMP2(15)=AMP2(15)+AMP(15)*DCONJG(AMP(15))
AMP2(16)=AMP2(16)+AMP(16)*DCONJG(AMP(16))
AMP2(17)=AMP2(17)+AMP(17)*DCONJG(AMP(17))
AMP2(18)=AMP2(18)+AMP(18)*DCONJG(AMP(18))
AMP2(21)=AMP2(21)+AMP(21)*DCONJG(AMP(21))
AMP2(22)=AMP2(22)+AMP(22)*DCONJG(AMP(22))
AMP2(23)=AMP2(23)+AMP(23)*DCONJG(AMP(23))
AMP2(24)=AMP2(24)+AMP(24)*DCONJG(AMP(24))
AMP2(25)=AMP2(25)+AMP(25)*DCONJG(AMP(25))
AMP2(26)=AMP2(26)+AMP(26)*DCONJG(AMP(26))
AMP2(27)=AMP2(27)+AMP(27)*DCONJG(AMP(27))
AMP2(28)=AMP2(28)+AMP(28)*DCONJG(AMP(28))
AMP2(29)=AMP2(29)+AMP(29)*DCONJG(AMP(29))
AMP2(30)=AMP2(30)+AMP(30)*DCONJG(AMP(30))
AMP2(31)=AMP2(31)+AMP(31)*DCONJG(AMP(31))
AMP2(32)=AMP2(32)+AMP(32)*DCONJG(AMP(32))
AMP2(35)=AMP2(35)+AMP(35)*DCONJG(AMP(35))
AMP2(36)=AMP2(36)+AMP(36)*DCONJG(AMP(36))
AMP2(39)=AMP2(39)+AMP(39)*DCONJG(AMP(39))
AMP2(40)=AMP2(40)+AMP(40)*DCONJG(AMP(40))
DO I = 1, NCOLOR
JAMP2(I)=JAMP2(I)+JAMP(I)*DCONJG(JAMP(I))
ENDDO
END
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