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rms_analysis.f90
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program rms_analysis
!Lei20230819 implicit none
!Lei20230819 real(kind=8) :: a, b, c, d, e, f, g, h, o, p, q, r, s, t, u, v, w, x, y, z
!Lei20230819 integer(kind=8) :: i, j, k, l, m, n
implicit real(kind=8) (a-h, o-z) !Lei20230821
implicit integer(kind=8) (i-n) !Lei20230821
integer(kind=8) :: n_file, n_event_per_file, n_event_total
character(len=50) :: name_file, prefix, suffix
real(kind=8) :: distr_h(40,4,2), sum_distr_h(40,4,2), mult_h(2), sum_mult_h(2) !Lei20230820 mult_h. sum_mult_h
!Lei20230819B---
integer(kind=8) :: i_sim_mode, n_current_date_and_time(8)
real(kind=8) :: Ncoll_in_coll_list, Npart_in_coll_list, Ncoll_max_in_coll_list, &
Ncoll_call_PYTHIA, Ncoll_not_call_PYTHIA, Npart_real, &
Ncoll_over_Npart_Optical_Glauber_multi_string, Ncoll_Optical_Glauber, &
Npart_call_PYTHIA, Ncoll_nn_call_PYTHIA, Ncoll_pp_call_PYTHIA, &
Ncoll_np_call_PYTHIA, Ncoll_call_PYTHIA_2, Ncoll_lp_call_PYTHIA, &
Npart_Optical_Glauber_proj, Npart_Optical_Glauber_targ, &
Overlap_function_Optical_Glauber, Ncoll_Optical_Glauber_2, &
n_coll_parton_rescattering_success, n_coll_parton_rescattering_block, &
n_coll_parton_rescattering_total, n_coll_parton_rescattering, &
n_coll_hadron_rescattering_elastic, n_coll_hadron_rescattering_inelastic, &
n_coll_hadron_rescattering_total, n_gluon_in_a_string_single_multi_string, &
n_string_single_string, n_q_thrown, n_qbar_thrown, &
multiplicity_minus_partial, multiplicity_plus_partial, multiplicity_total_partial, &
multiplicity_minus_full, multiplicity_plus_full, multiplicity_total_full, &
multiplicity_quark_partial, multiplicity_qbar_partial, &
multiplicity_q_qbar_total_partial, multiplicity_gluon_partial, &
multiplicity_quark_full, multiplicity_qbar_full, &
multiplicity_q_qbar_total_full, multiplicity_gluon_full, &
kapa_effective
real(kind=8) :: n_process_parton_rescattering(9), sum_n_process_parton_rescattering(9), &
n_process_hadron_rescattering(10,60), sum_n_process_hadron_rescattering(10,60), &
multiplicity_specie_partial(21), sum_multiplicity_specie_partial(21), &
multiplicity_specie_full(21), sum_multiplicity_specie_full(21), &
multiplicity_parton_partial(14), sum_multiplicity_parton_partial(14), &
multiplicity_parton_full(14), sum_multiplicity_parton_full(14)
real(kind=8) :: x_coor(40,6)
real(kind=8) :: distr_hadron_partial(21,40,6), sum_distr_hadron_partial(21,40,6), &
distr_hadron_full(21,40,6), sum_distr_hadron_full(21,40,6), &
distr_parton_partial(14,40,6), sum_distr_parton_partial(14,40,6), &
distr_parton_full(14,40,6), sum_distr_parton_full(14,40,6)
character(len=200) :: comment_line(400)
character(len=26) :: name_specie(21), shebang_sign
character(len=4) :: c_date_and_time(8)
character(len=4) :: id_abscissa(6)
data id_abscissa / "y", "pT", "eta", "mT", "mult", "pT" /
!Lei20230819E---
open(98,file="input_rms_analysis.dat",status="unknown")
read(98,*) n_file, n_event_per_file !Lei20230820
read(98,*) i_sim_mode, i_b_sampling_method !Lei20230819
close(98)
n_event_total = n_file * n_event_per_file
! Initialization.
sum_distr_h = 0D0
!Lei2230819B---
comment_line = ""
name_specie = ""
sum_Ncoll_in_coll_list = 0D0
sum_Npart_in_coll_list = 0D0
sum_Ncoll_max_in_coll_list = 0D0
sum_Ncoll_call_PYTHIA = 0D0
sum_Ncoll_not_call_PYTHIA = 0D0
sum_Npart_real = 0D0
sum_Ncoll_over_Npart_Optical_Glauber_multi_string = 0D0
sum_Ncoll_optical_Glauber = 0D0
sum_Npart_call_PYTHIA = 0D0
sum_Ncoll_nn_call_PYTHIA = 0D0
sum_Ncoll_pp_call_PYTHIA = 0D0
sum_Ncoll_np_call_PYTHIA = 0D0
sum_Ncoll_call_PYTHIA_2 = 0D0
sum_Ncoll_lp_call_PYTHIA = 0D0
sum_ave_b_param = 0D0
sum_avneu = 0D0
sum_Npart_Optical_Glauber_proj = 0D0
sum_Npart_Optical_Glauber_targ = 0D0
sum_Overlap_function_Optical_Glauber = 0D0
sum_Ncoll_Optical_Glauber_2 = 0D0
sum_E_gamma_1 = 0D0
sum_E_gamma_2 = 0D0
sum_E_gamma_3 = 0D0
sum_E_gamma_4 = 0D0
sum_n_coll_parton_rescattering_success = 0D0
sum_n_coll_parton_rescattering_block = 0D0
sum_n_coll_parton_rescattering_total = 0D0
sum_n_process_parton_rescattering = 0D0
sum_n_coll_hadron_rescattering_elastic = 0D0
sum_n_coll_hadron_rescattering_inelastic = 0D0
sum_n_coll_hadron_rescattering_total = 0D0
sum_parj1_effective = 0D0
sum_parj2_effective = 0D0
sum_parj3_effective = 0D0
sum_parj4_effective = 0D0
sum_parj21_effective = 0D0
sum_kapa_effective = 0D0
sum_n_gluon_in_a_string_single_multi_string = 0D0
sum_xi_factor_single_string = 0D0
sum_pT_hardest_gluon_single_string = 0D0
sum_n_string_single_string = 0D0
sum_time_NN_collision = 0D0
sum_time_parton_rescattering = 0D0
sum_time_hadron_rescattering = 0D0
sum_n_q_thrown = 0D0
sum_n_qbar_thrown = 0D0
sum_charge_thrown = 0D0
sum_px_thrown = 0D0
sum_py_thrown = 0D0
sum_pz_thrown = 0D0
sum_E_thrown = 0D0
sum_multiplicity_minus_partial = 0D0
sum_multiplicity_plus_partial = 0D0
sum_multiplicity_minus_full = 0D0
sum_multiplicity_plus_full = 0D0
sum_multiplicity_specie_partial = 0D0
sum_multiplicity_specie_full = 0D0
sum_distr_hadron_partial = 0D0
sum_distr_hadron_full = 0D0
sum_distr_parton_partial = 0D0
sum_distr_parton_full = 0D0
sum_multiplicity_quark_partial = 0D0
sum_multiplicity_qbar_partial = 0D0
sum_multiplicity_gluon_partial = 0D0
sum_multiplicity_quark_full = 0D0
sum_multiplicity_qbar_full = 0D0
sum_multiplicity_gluon_full = 0D0
sum_n_process_hadron_rescattering = 0D0
!Lei2230819E---
! Cycle over all of the "rms_i.out" files.
loop_file: do i_file=1,n_file,1
! Opens one of the "rms_i.out" files.
write(suffix,*) i_file
name_file = "rms_" // TRIM(ADJUSTL(suffix)) // ".out"
open(99,file=name_file,status="old")
!Lei20230819B----------
! Reecords comment line.
!1 #!***************************************************************************!#
!2 #!*********************| PACIAE Analysis Output |********************!#
!3 #!***************************************************************************!#
!4
!5 #! Now is HH:MM:SS DD/MM/YYYY
!6 #! Seed (PYTHIA default=19780503) = xxxxxxxxx
!7
!8 #!-----------------------------------------------------------------------------
!9 #! parp81, parp82, bp, mstp82 =
do j=1,9,1
read(99,"(A200)") comment_line(j)
end do
!10
read(99,*) PARP81, PARP82, b_param_current, MSTP82
!11 #!-----------------------------------------------------------------------------
!12 #! MC Glauber-like <N_coll>, <N_part> =
do j=11,12,1
read(99,"(A200)") comment_line(j)
end do
!13
read(99,*) Ncoll_in_coll_list, Npart_in_coll_list
sum_Ncoll_in_coll_list = sum_Ncoll_in_coll_list + Ncoll_in_coll_list
sum_Npart_in_coll_list = sum_Npart_in_coll_list + Npart_in_coll_list
!14 #! largest ave. # of NN collision pairs =
read(99,"(A200)") comment_line(14)
!15
read(99,*) Ncoll_max_in_coll_list
sum_Ncoll_max_in_coll_list = sum_Ncoll_max_in_coll_list + Ncoll_max_in_coll_list
!16 #! ave. # of NN collision pairs calling PYTHIA, not calling PYTHIA =
read(99,"(A200)") comment_line(16)
!17
read(99,*) Ncoll_call_PYTHIA, Ncoll_not_call_PYTHIA
sum_Ncoll_call_PYTHIA = sum_Ncoll_call_PYTHIA + Ncoll_call_PYTHIA
sum_Ncoll_not_call_PYTHIA = sum_Ncoll_not_call_PYTHIA + Ncoll_not_call_PYTHIA
!18 #! ave. # of wounded nucleons in parini =
read(99,"(A200)") comment_line(18)
!19
read(99,*) Npart_real
sum_Npart_real = sum_Npart_real + Npart_real
!20 #! colli. # suffered by projectile nucleon in target nucleus
read(99,"(A200)") comment_line(20)
!21
read(99,*) Ncoll_over_Npart_Optical_Glauber_multi_string
sum_Ncoll_over_Npart_Optical_Glauber_multi_string = &
sum_Ncoll_over_Npart_Optical_Glauber_multi_string + &
Ncoll_over_Npart_Optical_Glauber_multi_string
!22 #! event averaged N_bin
read(99,"(A200)") comment_line(22)
!23
read(99,*) Ncoll_Optical_Glauber
sum_Ncoll_Optical_Glauber = sum_Ncoll_Optical_Glauber + Ncoll_Optical_Glauber
!24 #! (Npart)mini-jet, Nnn, Npp=
read(99,"(A200)") comment_line(24)
!25
read(99,*) Npart_call_PYTHIA, Ncoll_nn_call_PYTHIA, Ncoll_pp_call_PYTHIA
sum_Npart_call_PYTHIA = sum_Npart_call_PYTHIA + Npart_call_PYTHIA
sum_Ncoll_nn_call_PYTHIA = sum_Ncoll_nn_call_PYTHIA + Ncoll_nn_call_PYTHIA
sum_Ncoll_pp_call_PYTHIA = sum_Ncoll_pp_call_PYTHIA + Ncoll_pp_call_PYTHIA
!26 #! Nnp, Ntot, Nep=
read(99,"(A200)") comment_line(26)
!27
read(99,*) Ncoll_np_call_PYTHIA, Ncoll_call_PYTHIA_2, Ncoll_lp_call_PYTHIA
sum_Ncoll_np_call_PYTHIA = sum_Ncoll_np_call_PYTHIA + Ncoll_np_call_PYTHIA
sum_Ncoll_call_PYTHIA_2 = sum_Ncoll_call_PYTHIA_2 + Ncoll_call_PYTHIA_2
sum_Ncoll_lp_call_PYTHIA = sum_Ncoll_lp_call_PYTHIA + Ncoll_lp_call_PYTHIA
!28-29
! For the case of fixed impact-parameter (b).
! if( i_b_sampling_method == 0 ) then
if( .true. ) then
read(99,*)
read(99,*)
! For the case of random impact-parameter (b) sampling method.
else if( i_b_sampling_method == 1 ) then
!28 #! event averaged b, avneu, Npart_p, Npart_t, T_pt=
read(99,"(A200)") comment_line(28)
!29
read(99,*) ave_b_param, avneu, &
Npart_Optical_Glauber_proj, Npart_Optical_Glauber_targ, &
Overlap_function_Optical_Glauber
sum_ave_b_param = sum_ave_b_param + ave_b_param
sum_avneu = sum_avneu + avneu ! TODO(Lei20230819): ???
sum_Npart_Optical_Glauber_proj = sum_Npart_Optical_Glauber_proj + &
Npart_Optical_Glauber_proj
sum_Npart_Optical_Glauber_targ = sum_Npart_Optical_Glauber_targ + &
Npart_Optical_Glauber_targ
sum_Overlap_function_Optical_Glauber = &
sum_Overlap_function_Optical_Glauber + &
Overlap_function_Optical_Glauber
! For the case of random impact-parameter (b) sampling method.
else if( i_b_sampling_method == 2 ) then
!28 #! psno, ave. b, N_part and N_bin =
read(99,"(A200)") comment_line(28)
!29
read(99,*) b_sampling_method, ave_b_param, &
Npart_Optical_Glauber_proj, Npart_Optical_Glauber_targ, &
Ncoll_Optical_Glauber_2
sum_ave_b_param = sum_ave_b_param + ave_b_param
sum_Npart_Optical_Glauber_proj = sum_Npart_Optical_Glauber_proj + &
Npart_Optical_Glauber_proj
sum_Npart_Optical_Glauber_targ = sum_Npart_Optical_Glauber_targ + &
Npart_Optical_Glauber_targ
sum_Ncoll_Optical_Glauber_2 = sum_Ncoll_Optical_Glauber_2 + &
Ncoll_Optical_Glauber_2
end if
!30 #!-----------------------------------------------------------------------------
!31 #! event averaged energy of gamma after partonic initiation, partonic cascade,
!32 #! hadronization and end of event =
do j=30,32,1
read(99,"(A200)") comment_line(j)
end do
!33
read(99,*) E_gamma_1, E_gamma_2, E_gamma_3, E_gamma_4
sum_E_gamma_1 = sum_E_gamma_1 + E_gamma_1
sum_E_gamma_2 = sum_E_gamma_2 + E_gamma_2
sum_E_gamma_3 = sum_E_gamma_3 + E_gamma_3
sum_E_gamma_4 = sum_E_gamma_4 + E_gamma_4
!34 #!-----------------------------------------------------------------------------
!35 #! # of successful, blocked and all collision in parton cascade =
do j=34,35,1
read(99,"(A200)") comment_line(j)
end do
!36
read(99,*) n_coll_parton_rescattering_success, &
n_coll_parton_rescattering_block, &
n_coll_parton_rescattering_total
sum_n_coll_parton_rescattering_success = &
sum_n_coll_parton_rescattering_success + &
n_coll_parton_rescattering_success
sum_n_coll_parton_rescattering_block = &
sum_n_coll_parton_rescattering_block + &
n_coll_parton_rescattering_block
sum_n_coll_parton_rescattering_total = &
sum_n_coll_parton_rescattering_total + &
n_coll_parton_rescattering_total
!37 #! average collision # in parton cascade =
read(99,"(A200)") comment_line(37)
!38
read(99,*) n_coll_parton_rescattering
sum_n_coll_parton_rescattering = sum_n_coll_parton_rescattering + &
n_coll_parton_rescattering
!39 #! # of scaterring processes in parton cascade
read(99,"(A200)") comment_line(39)
!40-42
read(99,*) ( n_process_parton_rescattering(k), k=1,3,1 )
read(99,*) ( n_process_parton_rescattering(k), k=4,6,1 )
read(99,*) ( n_process_parton_rescattering(k), k=7,9,1 )
sum_n_process_parton_rescattering = sum_n_process_parton_rescattering + &
n_process_parton_rescattering
!43 #! average frequency of the occurring of each inela. in hadron cascade (at the end of the file)
!44 #! el. and inel. coll. # and sum in hadron cascade=
do j=43,44,1
read(99,"(A200)") comment_line(j)
end do
!45
read(99,*) n_coll_hadron_rescattering_elastic, &
n_coll_hadron_rescattering_inelastic, &
n_coll_hadron_rescattering_total
sum_n_coll_hadron_rescattering_elastic = &
sum_n_coll_hadron_rescattering_elastic + &
n_coll_hadron_rescattering_elastic
sum_n_coll_hadron_rescattering_inelastic = &
sum_n_coll_hadron_rescattering_inelastic + &
n_coll_hadron_rescattering_inelastic
sum_n_coll_hadron_rescattering_total = &
sum_n_coll_hadron_rescattering_total + &
n_coll_hadron_rescattering_total
!46 #!-----------------------------------------------------------------------------
!47 #! default parj1, parj2, parj3, parj4, parj21 =
do j=46,47,1
read(99,"(A200)") comment_line(j)
end do
!48
read(99,*) parj1_default, parj2_default, parj3_default, parj4_default, parj21_default
!49 #! Eff-parj1, parj2, parj3, parj4, parj21, keff =
read(99,"(A200)") comment_line(49)
!50
read(99,*) parj1_effective, parj2_effective, parj3_effective, &
parj4_effective, parj21_effective, kapa_effective
sum_parj1_effective = sum_parj1_effective + parj1_effective
sum_parj2_effective = sum_parj2_effective + parj2_effective
sum_parj3_effective = sum_parj3_effective + parj3_effective
sum_parj4_effective = sum_parj4_effective + parj4_effective
sum_parj21_effective = sum_parj21_effective + parj21_effective
sum_kapa_effective = sum_kapa_effective + kapa_effective
!51 #! averaged # of gluon in a string when kjp22=1,3
read(99,"(A200)") comment_line(51)
!52
read(99,*) n_gluon_in_a_string_single_multi_string
sum_n_gluon_in_a_string_single_multi_string = &
sum_n_gluon_in_a_string_single_multi_string + &
n_gluon_in_a_string_single_multi_string
!53 #! event averaged value of the factor related to #
!54 #! of gluons and hardest gluon in a string, event
!55 #! averaged transverse momentum of hardest gluon,
!56 #! event averaged # strings when kjp22=1,3 =
do j=53,56,1
read(99,"(A200)") comment_line(j)
end do
!57
read(99,*) xi_factor_single_string, pT_hardest_gluon_single_string, n_string_single_string
sum_xi_factor_single_string = sum_xi_factor_single_string + &
xi_factor_single_string
sum_pT_hardest_gluon_single_string = sum_pT_hardest_gluon_single_string + &
pT_hardest_gluon_single_string
sum_n_string_single_string = sum_n_string_single_string + &
n_string_single_string
!58 #!-----------------------------------------------------------------------------
!59 #! times & sum=
do j=58,59,1
read(99,"(A200)") comment_line(j)
end do
!60
read(99,*) time_NN_collision, time_parton_rescattering, time_hadron_rescattering
sum_time_NN_collision = sum_time_NN_collision + time_NN_collision
sum_time_parton_rescattering = sum_time_parton_rescattering + time_parton_rescattering
sum_time_hadron_rescattering = sum_time_hadron_rescattering + time_hadron_rescattering
!61 #!-----------------------------------------------------------------------------
!62 #! q, qbar, charge thrown away =
do j=61,62,1
read(99,"(A200)") comment_line(j)
end do
!63
read(99,*) n_q_thrown, n_qbar_thrown, charge_thrown
sum_n_q_thrown = sum_n_q_thrown + n_q_thrown
sum_n_qbar_thrown = sum_n_qbar_thrown + n_qbar_thrown
sum_charge_thrown = sum_charge_thrown + charge_thrown
!64 #! 3-momentum and energy thrown away =
read(99,"(A200)") comment_line(64)
!65
read(99,*) px_thrown, py_thrown, pz_thrown, E_thrown
sum_px_thrown = sum_px_thrown + px_thrown
sum_py_thrown = sum_py_thrown + py_thrown
sum_pz_thrown = sum_pz_thrown + pz_thrown
sum_E_thrown = sum_E_thrown + E_thrown
!66 Null line.
!67 #!-----------------------------------------------------------------------------
!68 #! multiplicity of negative, positive particles and sums, partial & full =
do j=66,68,1
read(99,"(A200)") comment_line(j)
end do
!69-70
read(99,*) multiplicity_minus_partial, multiplicity_plus_partial, multiplicity_total_partial
read(99,*) multiplicity_minus_full, multiplicity_plus_full, multiplicity_total_full
sum_multiplicity_minus_partial = sum_multiplicity_minus_partial + multiplicity_minus_partial
sum_multiplicity_plus_partial = sum_multiplicity_plus_partial + multiplicity_plus_partial
sum_multiplicity_minus_full = sum_multiplicity_minus_full + multiplicity_minus_full
sum_multiplicity_plus_full = sum_multiplicity_plus_full + multiplicity_plus_full
!71 #!-----------------------------------------------------------------------------
!72 #! particle multiplicity, partial =
do j=71,72,1
read(99,"(A200)") comment_line(j)
end do
!73 pi+K+p name_1 ... name_20
read(99,*) shebang_sign, ( name_specie(j), j=1,21,1 )
!74
read(99,*) ( multiplicity_specie_partial(j), j=1,21,1 )
sum_multiplicity_specie_partial = sum_multiplicity_specie_partial + multiplicity_specie_partial
!75 #! particle multiplicity, full =
read(99,"(A200)") comment_line(75)
!76
read(99,*) ( multiplicity_specie_full(j), j=1,21,1 )
sum_multiplicity_specie_full = sum_multiplicity_specie_full + multiplicity_specie_full
!77-79 Null line.
do j=1,3,1
read(99,*)
end do
! Read out the data of 6 distributions, both hadrons and partons in
! the partial and full phase-spaces.
! For hadrons:
! #!*******************| Hadron Distribution Output |******************!#
read(99,"(A200)") comment_line(200)
i_line = 200
distr_hadron_partial = 0D0
distr_hadron_full = 0D0
loop_hadron: do i_distr=1,6,1
! Partial phase-space.
! #!-----------------------------------------------------------------------------
! #! ID of distribution m2= x xxxx
! #! partial phase-space, x.xx < pT < x.xx (nominal cuts of 1-st setting in usu.dat)
do j=1,3,1
i_line = i_line + 1
read(99,"(A200)") comment_line(i_line)
end do
! #! x pi+K+p name_1 ... name_20
read(99,*) ! Jumps out this line.
! Reads out data of partial phase-space.
do i_bin=1,40,1
read(99,*) x_coor(i_bin,i_distr), &
( distr_hadron_partial(i_specie,i_bin,i_distr), i_specie=1,21,1 )
end do
! Full phase-space.
! #! ID of distribution m2= x xxxx
! #! full phase-space
! #! x pi+K+p name_1 ... name_20
do j=1,2,1
i_line = i_line + 1
read(99,"(A200)") comment_line(i_line)
end do
! #! x pi+K+p name_1 ... name_20
read(99,*) ! Jumps out this line.
do i_bin=1,40,1
read(99,*) x_coor(i_bin,i_distr), &
( distr_hadron_full(i_specie,i_bin,i_distr), i_specie=1,21,1 )
end do
end do loop_hadron
sum_distr_hadron_partial = sum_distr_hadron_partial + distr_hadron_partial
sum_distr_hadron_full = sum_distr_hadron_full + distr_hadron_full
! For partons:
! Jumps out 3 null lines and 2 comment lines.
! #!-----------------------------------------------------------------------------
! #! multiplicity of negative, positive quark, sums and gluon, partial & full =
do j=1,5,1
read(99,*)
end do
read(99,*) multiplicity_quark_partial, multiplicity_qbar_partial, &
multiplicity_q_qbar_total_partial, multiplicity_gluon_partial
read(99,*) multiplicity_quark_full, multiplicity_qbar_full, &
multiplicity_q_qbar_total_full, multiplicity_gluon_full
sum_multiplicity_quark_partial = sum_multiplicity_quark_partial + multiplicity_quark_partial
sum_multiplicity_qbar_partial = sum_multiplicity_qbar_partial + multiplicity_qbar_partial
sum_multiplicity_gluon_partial = sum_multiplicity_gluon_partial + multiplicity_gluon_partial
sum_multiplicity_quark_full = sum_multiplicity_quark_full + multiplicity_quark_full
sum_multiplicity_qbar_full = sum_multiplicity_qbar_full + multiplicity_qbar_full
sum_multiplicity_gluon_full = sum_multiplicity_gluon_full + multiplicity_gluon_full
! #!-----------------------------------------------------------------------------
! #! particle multiplicity, partial =
! #! g u+d+s + anti- ... u, d, s, ...
read(99,*) ! Jumps out this line.
read(99,*)
read(99,*)
read(99,*) ( multiplicity_parton_partial(j), j=1,14,1 )
sum_multiplicity_parton_partial = sum_multiplicity_parton_partial + multiplicity_parton_partial
! #! particle multiplicity, full =
read(99,*) ! Jumps out this line.
read(99,*) ( multiplicity_parton_full(j), j=1,14,1 )
sum_multiplicity_parton_full = sum_multiplicity_parton_full + multiplicity_parton_full
! Null lines.
read(99,*) ! Jumps out this line.
read(99,*)
read(99,*)
! #!*******************| Parton Distribution Output |******************!#
read(99,"(A200)") comment_line(300)
i_line = 300
distr_parton_partial = 0D0
distr_parton_full = 0D0
loop_parton: do i_distr=1,6,1
! Partial phase-space.
! #!-----------------------------------------------------------------------------
! #! ID of distribution m2= x xxxx
! #! partial phase-space, x.xx < pT < x.xx (nominal cuts of 1-st setting in usu.dat)
do j=1,3,1
i_line = i_line + 1
read(99,"(A200)") comment_line(i_line)
end do
! #! x g u+d+s + anti- u, d, s, ...
read(99,*) ! Jumps out this line.
! Reads out data of partial phase-space.
do i_bin=1,40,1
read(99,*) x_coor(i_bin,i_distr), &
( distr_parton_partial(i_specie,i_bin,i_distr), i_specie=1,14,1 )
end do
! Full phase-space.
! #! ID of distribution m2= x xxxx
! #! full phase-space
do j=1,2,1
i_line = i_line + 1
read(99,"(A200)") comment_line(i_line)
end do
! #! x g u+d+s + anti- u, d, s, ...
read(99,*) ! Jumps out this line.
do i_bin=1,40,1
read(99,*) x_coor(i_bin,i_distr), &
( distr_parton_full(i_specie,i_bin,i_distr), i_specie=1,14,1 )
end do
end do loop_parton
sum_distr_parton_partial = sum_distr_parton_partial + distr_parton_partial
sum_distr_parton_full = sum_distr_parton_full + distr_parton_full
! 3 null lines.
! #! average frequency of the occurring of each inela. in hadron cascade =
do j=1,4,1
read(99,*)
end do
! Reads out data.
n_process_hadron_rescattering = 0D0
do j=1,60,1
read(99,*) ( n_process_hadron_rescattering(k,j), k=1,10,1 )
end do
sum_n_process_hadron_rescattering = sum_n_process_hadron_rescattering + &
n_process_hadron_rescattering
!Lei20230819E----------
!Lei20230820 3 null lines and 1 comment line.
! #! Inv. dN/dpT, dN/dpT, dN/dy, dN/deta of h+-, p and f
IF(.FALSE.)THEN
read(99,"(3/)")
distr_h = 0D0
do j=1,40,1
read(99,*) distr_h(j,1,1), distr_h(j,1,2), &
distr_h(j,2,1), distr_h(j,2,2), &
distr_h(j,3,1), distr_h(j,3,2), &
distr_h(j,4,1), distr_h(j,4,2)
end do
sum_distr_h = sum_distr_h + distr_h
!Lei20230820B-
! #! partial/full multiplicity of h+-:
read(99,"(1/)")
read(99,*) mult_h(1), mult_h(2)
sum_mult_h = sum_mult_h + mult_h
!Lei20230820E-
ENDIF
close(99)
end do loop_file
!Lei20230820 Event-(file-) averaging.
sum_Ncoll_in_coll_list = sum_Ncoll_in_coll_list / n_file
sum_Npart_in_coll_list = sum_Npart_in_coll_list / n_file
sum_Ncoll_max_in_coll_list = sum_Ncoll_max_in_coll_list / n_file
sum_Ncoll_call_PYTHIA = sum_Ncoll_call_PYTHIA / n_file
sum_Ncoll_not_call_PYTHIA = sum_Ncoll_not_call_PYTHIA / n_file
sum_Npart_real = sum_Npart_real / n_file
sum_Ncoll_over_Npart_Optical_Glauber_multi_string = &
sum_Ncoll_over_Npart_Optical_Glauber_multi_string / n_file
sum_Ncoll_Optical_Glauber = sum_Ncoll_Optical_Glauber / n_file
sum_Npart_call_PYTHIA = sum_Npart_call_PYTHIA / n_file
sum_Ncoll_nn_call_PYTHIA = sum_Ncoll_nn_call_PYTHIA / n_file
sum_Ncoll_pp_call_PYTHIA = sum_Ncoll_pp_call_PYTHIA / n_file
sum_Ncoll_np_call_PYTHIA = sum_Ncoll_np_call_PYTHIA / n_file
sum_Ncoll_call_PYTHIA_2 = sum_Ncoll_call_PYTHIA_2 / n_file
sum_Ncoll_lp_call_PYTHIA = sum_Ncoll_lp_call_PYTHIA / n_file
sum_ave_b_param = sum_ave_b_param / n_file
sum_avneu = sum_avneu / n_file
sum_Npart_Optical_Glauber_proj = sum_Npart_Optical_Glauber_proj / n_file
sum_Npart_Optical_Glauber_targ = sum_Npart_Optical_Glauber_targ / n_file
sum_Overlap_function_Optical_Glauber = &
sum_Overlap_function_Optical_Glauber / n_file
sum_Ncoll_Optical_Glauber_2 = sum_Ncoll_Optical_Glauber_2 / n_file
sum_E_gamma_1 = sum_E_gamma_1 / n_file
sum_E_gamma_2 = sum_E_gamma_2 / n_file
sum_E_gamma_3 = sum_E_gamma_3 / n_file
sum_E_gamma_4 = sum_E_gamma_4 / n_file
sum_n_coll_parton_rescattering_success = sum_n_coll_parton_rescattering_success / n_file
sum_n_coll_parton_rescattering_block = sum_n_coll_parton_rescattering_block / n_file
sum_n_coll_parton_rescattering_total = sum_n_coll_parton_rescattering_total / n_file
sum_n_coll_parton_rescattering = sum_n_coll_parton_rescattering / n_file
sum_n_process_parton_rescattering = sum_n_process_parton_rescattering / n_file
sum_n_coll_hadron_rescattering_elastic = sum_n_coll_hadron_rescattering_elastic / n_file
sum_n_coll_hadron_rescattering_inelastic = sum_n_coll_hadron_rescattering_inelastic / n_file
sum_n_coll_hadron_rescattering_total = sum_n_coll_hadron_rescattering_total / n_file
sum_parj1_effective = sum_parj1_effective / n_file
sum_parj2_effective = sum_parj2_effective / n_file
sum_parj3_effective = sum_parj3_effective / n_file
sum_parj4_effective = sum_parj4_effective / n_file
sum_parj21_effective = sum_parj21_effective / n_file
sum_kapa_effective = sum_kapa_effective / n_file
sum_n_gluon_in_a_string_single_multi_string = sum_n_gluon_in_a_string_single_multi_string / n_file
sum_xi_factor_single_string = sum_xi_factor_single_string / n_file
sum_pT_hardest_gluon_single_string = sum_pT_hardest_gluon_single_string / n_file
sum_n_string_single_string = sum_n_string_single_string / n_file
sum_time_NN_collision = sum_time_NN_collision / n_file
sum_time_parton_rescattering = sum_time_parton_rescattering / n_file
sum_time_hadron_rescattering = sum_time_hadron_rescattering / n_file
sum_n_q_thrown = sum_n_q_thrown / n_file
sum_n_qbar_thrown = sum_n_qbar_thrown / n_file
sum_charge_thrown = sum_charge_thrown / n_file
sum_px_thrown = sum_px_thrown / n_file
sum_py_thrown = sum_py_thrown / n_file
sum_pz_thrown = sum_pz_thrown / n_file
sum_E_thrown = sum_E_thrown / n_file
sum_multiplicity_minus_partial = sum_multiplicity_minus_partial / n_file
sum_multiplicity_plus_partial = sum_multiplicity_plus_partial / n_file
sum_multiplicity_minus_full = sum_multiplicity_minus_full / n_file
sum_multiplicity_plus_full = sum_multiplicity_plus_full / n_file
sum_multiplicity_specie_partial = sum_multiplicity_specie_partial / n_file
sum_multiplicity_specie_full = sum_multiplicity_specie_full / n_file
sum_distr_hadron_partial = sum_distr_hadron_partial / n_file
sum_distr_hadron_full = sum_distr_hadron_full / n_file
sum_multiplicity_quark_partial = sum_multiplicity_quark_partial / n_file
sum_multiplicity_qbar_partial = sum_multiplicity_qbar_partial / n_file
sum_multiplicity_gluon_partial = sum_multiplicity_gluon_partial / n_file
sum_multiplicity_quark_full = sum_multiplicity_quark_full / n_file
sum_multiplicity_qbar_full = sum_multiplicity_qbar_full / n_file
sum_multiplicity_gluon_full = sum_multiplicity_gluon_full / n_file
sum_multiplicity_parton_partial = sum_multiplicity_parton_partial / n_file
sum_multiplicity_parton_full = sum_multiplicity_parton_full / n_file
sum_distr_parton_partial = sum_distr_parton_partial / n_file
sum_distr_parton_full = sum_distr_parton_full / n_file
sum_n_process_hadron_rescattering = sum_n_process_hadron_rescattering / n_file
sum_distr_h = sum_distr_h / n_file
sum_mult_h = sum_mult_h / n_file
!Lei20230820 output.
open(100,file="ave_rms.out",status="unknown")
! Header.
!1 #!***************************************************************************!#
!2 #!*********************| PACIAE Analysis Output |********************!#
!3 #!***************************************************************************!#
!4
do j=1,4,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
! Records the current real date and time.
!5 #! Now is HH:MM:SS DD/MM/YYYY
call DATE_AND_TIME(VALUES=n_current_date_and_time)
do i=1,8,1
write(c_date_and_time(i),"(I4)") n_current_date_and_time(i)
enddo
write(100,*) "#! Now is " //TRIM(ADJUSTL( c_date_and_time(5) )) // &
":" //TRIM(ADJUSTL( c_date_and_time(6) )) // &
":" //TRIM(ADJUSTL( c_date_and_time(7) )) // &
" " //TRIM(ADJUSTL( c_date_and_time(3) )) // &
"/" //TRIM(ADJUSTL( c_date_and_time(2) )) // &
"/" //TRIM(ADJUSTL( c_date_and_time(1) ))
!6 #! Seed (PYTHIA default=19780503) = xxxxxxxxx
!7
!8 #!-----------------------------------------------------------------------------
!9 #! parp81, parp82, bp, mstp82 =
do j=6,9,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!10
write(100,*) PARP81, PARP82, b_param_current, MSTP82
!11 #!-----------------------------------------------------------------------------
!12 #! MC Glauber-like <N_coll>, <N_part> =
do j=11,12,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!13
write(100,*) sum_Ncoll_in_coll_list, sum_Npart_in_coll_list
!14 #! largest ave. # of NN collision pairs =
write(100,*) TRIM(ADJUSTL( comment_line(14) ))
!15
write(100,*) sum_Ncoll_max_in_coll_list
!16 #! ave. # of NN collision pairs calling PYTHIA, not calling PYTHIA =
write(100,*) TRIM(ADJUSTL( comment_line(16) ))
!17
write(100,*) sum_Ncoll_call_PYTHIA, sum_Ncoll_not_call_PYTHIA
!18 #! ave. # of wounded nucleons in parini =
write(100,*) TRIM(ADJUSTL( comment_line(18) ))
!19
write(100,*) sum_Npart_real
!20 #! colli. # suffered by projectile nucleon in target nucleus
write(100,*) TRIM(ADJUSTL( comment_line(20) ))
!21
write(100,*) sum_Ncoll_over_Npart_Optical_Glauber_multi_string
!22 #! event averaged N_bin
write(100,*) TRIM(ADJUSTL( comment_line(22) ))
!23
write(100,*) sum_Ncoll_Optical_Glauber
!24 #! (Npart)mini-jet, Nnn, Npp=
write(100,*) TRIM(ADJUSTL( comment_line(24) ))
!25
write(100,*) sum_Npart_call_PYTHIA, sum_Ncoll_nn_call_PYTHIA, sum_Ncoll_pp_call_PYTHIA
!26 #! Nnp, Ntot, Nep=
write(100,*) TRIM(ADJUSTL( comment_line(26) ))
!27
write(100,*) sum_Ncoll_np_call_PYTHIA, sum_Ncoll_call_PYTHIA_2, sum_Ncoll_lp_call_PYTHIA
!28-29
! For the case of fixed impact-parameter (b).
! if( i_b_sampling_method == 0 ) then
if( .true. ) then
write(100,*)
write(100,*)
! For the case of random impact-parameter (b) sampling method.
else if( i_b_sampling_method == 1 ) then
!28 #! event averaged b, avneu, Npart_p, Npart_t, T_pt=
write(100,*) TRIM(ADJUSTL( comment_line(28) ))
!29
write(100,*) sum_ave_b_param, sum_avneu, &
sum_Npart_Optical_Glauber_proj, sum_Npart_Optical_Glauber_targ, &
sum_Overlap_function_Optical_Glauber
! For the case of random impact-parameter (b) sampling method.
else if( i_b_sampling_method == 2 ) then
!28 #! psno, ave. b, N_part and N_bin =
write(100,*) TRIM(ADJUSTL( comment_line(28) ))
!29
write(100,*) INT(i_b_sampling_method), sum_ave_b_param, &
sum_Npart_Optical_Glauber_proj, sum_Npart_Optical_Glauber_targ, &
sum_Ncoll_Optical_Glauber_2
end if
!30 #!-----------------------------------------------------------------------------
!31 #! event averaged energy of gamma after partonic initiation, partonic cascade,
!32 #! hadronization and end of event =
do j=30,32,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!33
write(100,*) sum_E_gamma_1, sum_E_gamma_2, sum_E_gamma_3, sum_E_gamma_4
!34 #!-----------------------------------------------------------------------------
!35 #! # of successful, blocked and all collision in parton cascade =
do j=34,35,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!36
write(100,*) sum_n_coll_parton_rescattering_success, &
sum_n_coll_parton_rescattering_block, &
sum_n_coll_parton_rescattering_total
!37 #! average collision # in parton cascade =
write(100,*) TRIM(ADJUSTL( comment_line(37) ))
!38
write(100,*) sum_n_coll_parton_rescattering
!39 #! # of scaterring processes in parton cascade
write(100,*) TRIM(ADJUSTL( comment_line(39) ))
!40-42
write(100,*) ( sum_n_process_parton_rescattering(k), k=1,3,1 )
write(100,*) ( sum_n_process_parton_rescattering(k), k=4,6,1 )
write(100,*) ( sum_n_process_parton_rescattering(k), k=7,9,1 )
!43 #! average frequency of the occurring of each inela. in hadron cascade (at the end of the file)
!44 #! el. and inel. coll. # and sum in hadron cascade=
do j=43,44,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!45
write(100,*) sum_n_coll_hadron_rescattering_elastic, &
sum_n_coll_hadron_rescattering_inelastic, &
sum_n_coll_hadron_rescattering_total
!46 #!-----------------------------------------------------------------------------
!47 #! default parj1, parj2, parj3, parj4, parj21 =
do j=46,47,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!48
write(100,*) parj1_default, parj2_default, parj3_default, parj4_default, parj21_default
!49 #! Eff-parj1, parj2, parj3, parj4, parj21, keff =
write(100,*) TRIM(ADJUSTL( comment_line(49) ))
!50
write(100,*) sum_parj1_effective, sum_parj2_effective, sum_parj3_effective, &
sum_parj4_effective, sum_parj21_effective, sum_kapa_effective
!51 #! averaged # of gluon in a string when kjp22=1,3
write(100,*) TRIM(ADJUSTL( comment_line(51) ))
!52
write(100,*) sum_n_gluon_in_a_string_single_multi_string
!53 #! event averaged value of the factor related to #
!54 #! of gluons and hardest gluon in a string, event
!55 #! averaged transverse momentum of hardest gluon,
!56 #! event averaged # strings when kjp22=1,3 =
do j=53,56,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!57
write(100,*) sum_xi_factor_single_string, sum_pT_hardest_gluon_single_string, sum_n_string_single_string
!58 #!-----------------------------------------------------------------------------
!59 #! times & sum=
do j=58,59,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!60
write(100,*) sum_time_NN_collision, sum_time_parton_rescattering, sum_time_hadron_rescattering, &
sum_time_NN_collision + sum_time_parton_rescattering + sum_time_hadron_rescattering
!61 #!-----------------------------------------------------------------------------
!62 #! q, qbar, charge thrown away =
do j=61,62,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!63
write(100,*) sum_n_q_thrown, sum_n_qbar_thrown, sum_charge_thrown
!64 #! 3-momentum and energy thrown away =
write(100,*) TRIM(ADJUSTL( comment_line(64) ))
!65
write(100,*) sum_px_thrown, sum_py_thrown, sum_pz_thrown, sum_E_thrown
!66 Null line.
!67 #!-----------------------------------------------------------------------------
!68 #! multiplicity of negative, positive particles and sums, partial & full =
do j=66,68,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!69-70
write(100,*) sum_multiplicity_minus_partial, sum_multiplicity_plus_partial, &
sum_multiplicity_minus_partial + sum_multiplicity_plus_partial
write(100,*) sum_multiplicity_minus_full, sum_multiplicity_plus_full, &
sum_multiplicity_minus_full + sum_multiplicity_plus_full
!71 #!-----------------------------------------------------------------------------
!72 #! particle multiplicity, partial =
do j=71,72,1
write(100,*) TRIM(ADJUSTL( comment_line(j) ))
end do
!73 pi+K+p name_1 ... name_20
write(100,*) "#! ", ( name_specie(j), j=1,21,1 )
!74
write(100,*) ( sum_multiplicity_specie_partial(j), j=1,21,1 )
!75 #! particle multiplicity, full =
write(100,*) TRIM(ADJUSTL( comment_line(75) ))
!76
write(100,*) ( sum_multiplicity_specie_full(j), j=1,21,1 )
!77-79 Null line.
do j=1,3,1
write(100,*)
end do
! Outputs the data of 6 distributions, both hadrons and partons in
! the partial and full phase-spaces.
! For hadrons:
! #!*******************| Hadron Distribution Output |******************!#
i_line = 200
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
loop_hadron_output: do i_distr=1,6,1
! Partial phase-space.
! #!-----------------------------------------------------------------------------
! #! ID of distribution m2= x xxxx
! #! partial phase-space, x.xx < pT < x.xx (nominal cuts of 1-st setting in usu.dat)
do j=1,3,1
i_line = i_line + 1
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
end do
! #! x pi+K+p name_1 ... name_20
write(100,*) "#! " // id_abscissa(i_distr) // " ", (name_specie(j),j=1,21,1)
! Outputs data of partial phase-space.
do i_bin=1,40,1
write(100,*) x_coor(i_bin,i_distr), &
( sum_distr_hadron_partial(i_specie,i_bin,i_distr), i_specie=1,21,1 )
end do
! Full phase-space.
! #! ID of distribution m2= x xxxx
! #! full phase-space
! #! x pi+K+p name_1 ... name_20
do j=1,2,1
i_line = i_line + 1
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
end do
! #! x pi+K+p name_1 ... name_20
write(100,*) "#! " // id_abscissa(i_distr) // " ", (name_specie(j),j=1,21,1)
do i_bin=1,40,1
write(100,*) x_coor(i_bin,i_distr), &
( sum_distr_hadron_full(i_specie,i_bin,i_distr), i_specie=1,21,1 )
end do
end do loop_hadron_output
! For partons:
! 3 null lines.
do j=1,3,1
write(100,*)
end do
write(100,*) "#!-----------------------------------------------------------------------------"
write(100,*) "#! multiplicity of negative, positive quark, sums and gluon, partial & full ="
write(100,*) sum_multiplicity_quark_partial, sum_multiplicity_qbar_partial, &
sum_multiplicity_quark_partial + sum_multiplicity_qbar_partial, &
sum_multiplicity_gluon_partial
write(100,*) sum_multiplicity_quark_full, sum_multiplicity_qbar_full, &
sum_multiplicity_quark_full + sum_multiplicity_qbar_full, &
sum_multiplicity_gluon_full
write(100,*) "#!-----------------------------------------------------------------------------"
write(100,*) "#! particle multiplicity, partial ="
write(100,*) "#! g u+d+s + anti- " // &
"u ubar " // &
"d dbar " // &
"s sbar " // &
"c cbar " // &
"b bbar " // &
"t tbar"
write(100,*) ( sum_multiplicity_parton_partial(j), j=1,14,1 )
write(100,*) "#! particle multiplicity, full ="
write(100,*) ( sum_multiplicity_parton_full(j), j=1,14,1 )
! 3 null lines.
do j=1,3,1
write(100,*)
end do
! #!*******************| Parton Distribution Output |******************!#
i_line = 300
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
loop_parton_output: do i_distr=1,6,1
! Partial phase-space.
! #!-----------------------------------------------------------------------------
! #! ID of distribution m2= x xxxx
! #! partial phase-space, x.xx < pT < x.xx (nominal cuts of 1-st setting in usu.dat)
do j=1,3,1
i_line = i_line + 1
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
end do
! #! x g u+d+s + anti- u, d, s, ...
write(100,*) "#! " // id_abscissa(i_distr) // " " // &
"g u+d+s + anti- " // &
"u ubar " // &
"d dbar " // &
"s sbar " // &
"c cbar " // &
"b bbar " // &
"t tbar"
! Outputs data of partial phase-space.
do i_bin=1,40,1
write(100,*) x_coor(i_bin,i_distr), &
( sum_distr_parton_partial(i_specie,i_bin,i_distr), i_specie=1,14,1 )
end do
! Full phase-space.
! #! ID of distribution m2= x xxxx
! #! full phase-space
do j=1,2,1
i_line = i_line + 1
write(100,*) TRIM(ADJUSTL( comment_line(i_line) ))
end do
! #! x g u+d+s + anti- u, d, s, ...
write(100,*) "#! " // id_abscissa(i_distr) // " " // &
"g u+d+s + anti- " // &
"u ubar " // &
"d dbar " // &
"s sbar " // &
"c cbar " // &
"b bbar " // &
"t tbar"
do i_bin=1,40,1
write(100,*) x_coor(i_bin,i_distr), &
( sum_distr_parton_full(i_specie,i_bin,i_distr), i_specie=1,14,1 )
end do
end do loop_parton_output
! 3 null lines.
do j=1,3,1
write(100,*)
end do
write(100,*) "#! average frequency of the occurring of each inela. in hadron cascade ="
! Outputs data.
do j=1,60,1
write(100,*) ( sum_n_process_hadron_rescattering(k,j), k=1,10,1 )
end do
!Lei20230819E----------
!Lei20230821B---
stop !Lei20230912
! 3 null lines.
do j=1,3,1
write(100,*)
end do
write(100,*) "#! Inv. dN/dpT, dN/dpT, dN/dy, dN/deta of h+-, p and f"
do j=1,40,1
write(100,*) sum_distr_h(j,1,1), sum_distr_h(j,1,2), &
sum_distr_h(j,2,1), sum_distr_h(j,2,2), &
sum_distr_h(j,3,1), sum_distr_h(j,3,2), &
sum_distr_h(j,4,1), sum_distr_h(j,4,2)
end do
! #! partial/full multiplicity of h+-:
write(100,*)
write(100,*) "#! partial/full multiplicity of h+-:"
write(100,*) sum_mult_h(1), sum_mult_h(2)
!Lei20230821B---
close(100)
stop
end program