#!/bin/bash
#This script needs to be edited for each run.
#Define PDB Filename & GROMACS Pameters
# reference: http://www.mdtutorials.com/gmx/lysozyme/
# NAME=1ao7 NSTEPS=50000000 ./md_gromacs.sh  
# 命令会临时设置 NAME 为 1ao7 和 NSTEPS 为 50000000（对应 100ns），然后运行 md_gromacs.sh 脚本
# Check if GMXRC_PATH is provided and source it
if [ -n "$GMXRC_PATH" ]; then
    source "$GMXRC_PATH" # source /home/lingyuzeng/software/gmx2023.2/bin/GMXRC
fi
NAME=${NAME:-"5sws_fixer"}
FORCEFIELD=${FORCEFIELD:-"amber99sb-ildn"}
WATERMODEL=${WATERMODEL:-"tip3p"}
WATERTOPFILE=${WATERTOPFILE:-"spc216.gro"}
BOXTYPE=${BOXTYPE:-"tric"}
BOXORIENTATION=${BOXORIENTATION:-"1.0"}
NSTEPS=${NSTEPS:-500000} # 50,000 steps for 1 ns
DT=${DT:-0.002} # 2 fs
#BOXSIZE="5.0"
#BOXCENTER="2.5"
# Define simulation name variable
MDRUN_NAME=${MDRUN_NAME:-"md"}
NDX_NAME=${NDX_NAME:-"index"}
# Define analysis parameters
# Define other filenames based on MDRUN_NAME
TPR_FILE="${MDRUN_NAME}.tpr"
XTC_FILE="${MDRUN_NAME}.xtc"
NDX_FILE="${NDX_NAME}.ndx"
NO_PBC_XTC_FILE="${MDRUN_NAME}_noPBC.xtc"
OUTPUT_FOLDER=${OUTPUT_FOLDER:-"frame_extraction_output"}
TEMP_FOLDER=${TEMP_FOLDER:-"temp"}
# Define variables for frame extraction
EXTRACT_EVERY_PS=${EXTRACT_EVERY_PS:-100} # Default to 100 ps if not set

# Print the current settings
echo "Current settings:"
echo "NAME: $NAME"
echo "FORCEFIELD: $FORCEFIELD"
echo "WATERMODEL: $WATERMODEL"
echo "WATERTOPFILE: $WATERTOPFILE"
echo "BOXTYPE: $BOXTYPE"
echo "BOXORIENTATION: $BOXORIENTATION"
echo "NSTEPS: $NSTEPS"
echo "DT: $DT"
echo "MDRUN_NAME: $MDRUN_NAME"
echo "TPR_FILE: $TPR_FILE"
echo "XTC_FILE: $XTC_FILE"
echo "NO_PBC_XTC_FILE: $NO_PBC_XTC_FILE"
echo "OUTPUT_FOLDER: $OUTPUT_FOLDER"
echo "EXTRACT_EVERY_PS: $EXTRACT_EVERY_PS"

# generate GROMACS .gro file
gmx_mpi pdb2gmx -f $NAME.pdb -o $NAME.gro -ff $FORCEFIELD -water $WATERMODEL -ignh -p topol.top
# define the box
gmx_mpi editconf -f $NAME.gro -o $NAME-box.gro -bt $BOXTYPE -c -d $BOXORIENTATION
# add solvate
gmx_mpi solvate -cp $NAME-box.gro -cs $WATERTOPFILE -o $NAME-solv.gro -p topol.top
# add icons # ! ions.mdp add by manual
# --- ions.mdp file content --- #
cat << EOF > ions.mdp
; ions.mdp - used as input into grompp to generate ions.tpr
; Parameters describing what to do, when to stop and what to save
integrator  = steep         ; Algorithm （steep = steepest descent minimization）
emtol       = 1000.0        ; Stop minimization when the maximum force < 1000.0 kJ/mol/nm
emstep      = 0.01          ; Minimization step size
nsteps      = 50000         ; Maximum number of （minimization） steps to perform
; Parameters describing how to find the neighbors of each atom and how to calculate the interactions
nstlist         = 1         ; Frequency to update the neighbor list and long range forces
cutoff-scheme  = Verlet    ; Buffered neighbor searching
ns_type         = grid      ; Method to determine neighbor list （simple, grid）
coulombtype     = cutoff    ; Treatment of long range electrostatic interactions
rcoulomb        = 1.0       ; Short-range electrostatic cut-off
rvdw            = 1.0       ; Short-range Van der Waals cut-off
pbc             = xyz       ; Periodic Boundary Conditions in all 3 dimensions
EOF
gmx_mpi grompp -f ions.mdp -c $NAME-solv.gro -p topol.top -o ions.tpr -maxwarn 1
echo SOL | gmx_mpi genion -s ions.tpr -o $NAME-solv-ions.gro -p topol.top -pname NA -nname CL -conc 0.125 -neutral
# energy minimization of the structure in solvate # ! minim.mdp add by manual
# --- minim.mdp file content --- #
cat << EOF > minim.mdp
; minim.mdp - used as input into grompp to generate em.tpr
; Parameters describing what to do, when to stop and what to save
integrator  = steep         ; Algorithm （steep = steepest descent minimization）
emtol       = 1000.0        ; Stop minimization when the maximum force < 1000.0 kJ/mol/nm
emstep      = 0.01          ; Minimization step size
nsteps      = 50000         ; Maximum number of （minimization） steps to perform
; Parameters describing how to find the neighbors of each atom and how to calculate the interactions
nstlist         = 1         ; Frequency to update the neighbor list and long range forces
cutoff-scheme   = Verlet    ; Buffered neighbor searching
ns_type         = grid      ; Method to determine neighbor list （simple, grid）
coulombtype     = PME       ; Treatment of long range electrostatic interactions
rcoulomb        = 1.0       ; Short-range electrostatic cut-off
rvdw            = 1.0       ; Short-range Van der Waals cut-off
pbc             = xyz       ; Periodic Boundary Conditions in all 3 dimensions
EOF
gmx_mpi grompp -f minim.mdp -c $NAME-solv-ions.gro -p topol.top -o em.tpr
gmx_mpi mdrun -v -deffnm em 
# optional em, you will need the Xmgrace plotting too
#gmx_mpi energy -f em.edr -o potential.xvg
#position restrain
# gmx_mpi grompp -f posre.mdp -c em.gro -p topol.top -o posre.tpr -r em.gro
# gmx_mpi mdrun -v -deffnm posre
# nvt
# gmx_mpi grompp -f nvt.mdp -c posre.gro -p topol.top -o nvt.tpr
# --- nvt.mdp file content --- #
cat << EOF > nvt.mdp
title                   = OPLS Lysozyme NVT equilibration
define                  = -DPOSRES  ; position restrain the protein
; Run parameters
integrator              = md        ; leap-frog integrator
nsteps                  = 50000     ; 2 * 50000 = 100 ps
dt                      = 0.002     ; 2 fs
; Output control
nstxout                 = 500       ; save coordinates every 1.0 ps
nstvout                 = 500       ; save velocities every 1.0 ps
nstenergy               = 500       ; save energies every 1.0 ps
nstlog                  = 500       ; update log file every 1.0 ps
; Bond parameters
continuation            = no        ; first dynamics run
constraint_algorithm    = lincs     ; holonomic constraints
constraints             = h-bonds   ; bonds involving H are constrained
lincs_iter              = 1         ; accuracy of LINCS
lincs_order             = 4         ; also related to accuracy
; Nonbonded settings
cutoff-scheme           = Verlet    ; Buffered neighbor searching
ns_type                 = grid      ; search neighboring grid cells
nstlist                 = 10        ; 20 fs, largely irrelevant with Verlet
rcoulomb                = 1.0       ; short-range electrostatic cutoff （in nm）
rvdw                    = 1.0       ; short-range van der Waals cutoff （in nm）
DispCorr                = EnerPres  ; account for cut-off vdW scheme
; Electrostatics
coulombtype             = PME       ; Particle Mesh Ewald for long-range electrostatics
pme_order               = 4         ; cubic interpolation
fourierspacing          = 0.16      ; grid spacing for FFT
; Temperature coupling is on
tcoupl                  = V-rescale             ; modified Berendsen thermostat
tc-grps                 = Protein Non-Protein   ; two coupling groups - more accurate
tau_t                   = 0.1     0.1           ; time constant, in ps
ref_t                   = 300     300           ; reference temperature, one for each group, in K
; Pressure coupling is off
pcoupl                  = no        ; no pressure coupling in NVT
; Periodic boundary conditions
pbc                     = xyz       ; 3-D PBC
; Velocity generation
gen_vel                 = yes       ; assign velocities from Maxwell distribution
gen_temp                = 300       ; temperature for Maxwell distribution
gen_seed                = -1        ; generate a random seed
EOF
gmx_mpi grompp -f nvt.mdp -c em.gro -r em.gro -p topol.top -o nvt.tpr
gmx_mpi mdrun -v -deffnm nvt
# optional : Let's analyze the temperature progression, again using energy:
# gmx_mpi energy -f nvt.edr -o temperature.xvg
# npt
# gmx_mpi grompp -f npt.mdp -c nvt.gro -t nvt.cpt -p topol.top -o npt.tpr
# --- npt.mdp file content --- #
cat << EOF > npt.mdp
title                   = OPLS Lysozyme NPT equilibration 
define                  = -DPOSRES  ; position restrain the protein
; Run parameters
integrator              = md        ; leap-frog integrator
nsteps                  = 50000     ; 2 * 50000 = 100 ps
dt                      = 0.002     ; 2 fs
; Output control
nstxout                 = 500       ; save coordinates every 1.0 ps
nstvout                 = 500       ; save velocities every 1.0 ps
nstenergy               = 500       ; save energies every 1.0 ps
nstlog                  = 500       ; update log file every 1.0 ps
; Bond parameters
continuation            = yes       ; Restarting after NVT 
constraint_algorithm    = lincs     ; holonomic constraints 
constraints             = h-bonds   ; bonds involving H are constrained
lincs_iter              = 1         ; accuracy of LINCS
lincs_order             = 4         ; also related to accuracy
; Nonbonded settings 
cutoff-scheme           = Verlet    ; Buffered neighbor searching
ns_type                 = grid      ; search neighboring grid cells
nstlist                 = 10        ; 20 fs, largely irrelevant with Verlet scheme
rcoulomb                = 1.0       ; short-range electrostatic cutoff (in nm)
rvdw                    = 1.0       ; short-range van der Waals cutoff (in nm)
DispCorr                = EnerPres  ; account for cut-off vdW scheme
; Electrostatics
coulombtype             = PME       ; Particle Mesh Ewald for long-range electrostatics
pme_order               = 4         ; cubic interpolation
fourierspacing          = 0.16      ; grid spacing for FFT
; Temperature coupling is on
tcoupl                  = V-rescale             ; modified Berendsen thermostat
tc-grps                 = Protein Non-Protein   ; two coupling groups - more accurate
tau_t                   = 0.1     0.1           ; time constant, in ps
ref_t                   = 300     300           ; reference temperature, one for each group, in K
; Pressure coupling is on
pcoupl                  = Parrinello-Rahman     ; Pressure coupling on in NPT
pcoupltype              = isotropic             ; uniform scaling of box vectors
tau_p                   = 2.0                   ; time constant, in ps
ref_p                   = 1.0                   ; reference pressure, in bar
compressibility         = 4.5e-5                ; isothermal compressibility of water, bar^-1
refcoord_scaling        = com
; Periodic boundary conditions
pbc                     = xyz       ; 3-D PBC
; Velocity generation
gen_vel                 = no        ; Velocity generation is off 
EOF
gmx_mpi grompp -f npt.mdp -c nvt.gro -r nvt.gro -t nvt.cpt -p topol.top -o npt.tpr
gmx_mpi mdrun -v -deffnm npt
# Optional: Let's analyze the pressure progression, again using energy: type 18 0
# gmx energy -f npt.edr -o pressure.xvg
# Optional: Let's take a look at density as well, this time using energy and entering "24 0" at the prompt.
# gmx energy -f npt.edr -o density.xvg
# md
# --- md.mdp file content --- #
cat << EOF > ${MDRUN_NAME}.mdp
title                   = OPLS Lysozyme NPT equilibration
; Run parameters
integrator              = md        ; leap-frog integrator
nsteps                  = ${NSTEPS}    ; steps for simulation
dt                      = ${DT}     ; time step in fs
; Output control
nstxout                 = 0         ; suppress bulky .trr file by specifying
nstvout                 = 0         ; 0 for output frequency of nstxout,
nstfout                 = 0         ; nstvout, and nstfout
nstenergy               = 5000      ; save energies every 10.0 ps
nstlog                  = 5000      ; update log file every 10.0 ps
nstxout-compressed      = 5000      ; save compressed coordinates every 10.0 ps
compressed-x-grps       = System    ; save the whole system
; Bond parameters
continuation            = yes       ; Restarting after NPT
constraint_algorithm    = lincs     ; holonomic constraints
constraints             = h-bonds   ; bonds involving H are constrained
lincs_iter              = 1         ; accuracy of LINCS
lincs_order             = 4         ; also related to accuracy
; Neighborsearching
cutoff-scheme           = Verlet    ; Buffered neighbor searching
ns_type                 = grid      ; search neighboring grid cells
nstlist                 = 10        ; 20 fs, largely irrelevant with Verlet scheme
rcoulomb                = 1.0       ; short-range electrostatic cutoff （in nm）
rvdw                    = 1.0       ; short-range van der Waals cutoff （in nm）
; Electrostatics
coulombtype             = PME       ; Particle Mesh Ewald for long-range electrostatics
pme_order               = 4         ; cubic interpolation
fourierspacing          = 0.16      ; grid spacing for FFT
; Temperature coupling is on
tcoupl                  = V-rescale             ; modified Berendsen thermostat
tc-grps                 = Protein Non-Protein   ; two coupling groups - more accurate
tau_t                   = 0.1     0.1           ; time constant, in ps
ref_t                   = 300     300           ; reference temperature, one for each group, in K
; Pressure coupling is on
pcoupl                  = Parrinello-Rahman     ; Pressure coupling on in NPT
pcoupltype              = isotropic             ; uniform scaling of box vectors
tau_p                   = 2.0                   ; time constant, in ps
ref_p                   = 1.0                   ; reference pressure, in bar
compressibility         = 4.5e-5                ; isothermal compressibility of water, bar^-1
; Periodic boundary conditions
pbc                     = xyz       ; 3-D PBC
; Dispersion correction
DispCorr                = EnerPres  ; account for cut-off vdW scheme
; Velocity generation
gen_vel                 = no        ; Velocity generation is off
EOF

# Generate GROMACS .tpr file for the simulation
gmx_mpi grompp -f ${MDRUN_NAME}.mdp -c npt.gro -t npt.cpt -p topol.top -o ${TPR_FILE}

# Run the simulation
gmx_mpi mdrun -deffnm ${MDRUN_NAME}
# mpirun -np $(ls | egrep "Scaled[0-9]+$" | wc -l) gmx_mpi mdrun -v --deffnm md -cpi Scaled.cpt -multidir $(ls -v | egrep "Scaled[0-9]+$") -plumed plumed.dat -hrex -replex 1000 >& run_$(date "+%H%M%S_%d%m%Y").log || { echo "mdrun failed at line ${LINENO} "; exit -1; }
# extra ndx file , select protein
echo -e "1\nq" | gmx_mpi make_ndx -f ${MDRUN_NAME}.gro -o ${NDX_FILE}
# echo -e "1\nq" | gmx_mpi make_ndx -f md.gro -o index.ndx

# Create extraction output directory
mkdir -p ${OUTPUT_FOLDER}

# Create temp output directory
mkdir -p ${TEMP_FOLDER}

echo -e "1\nq" | gmx_mpi trjconv -dt ${EXTRACT_EVERY_PS} -s ${TPR_FILE} -f ${XTC_FILE} -n ${NDX_FILE} -pbc mol -o ${TEMP_FOLDER}/temp.xtc

# echo -e "1\nq" | gmx_mpi trjconv -dt 100 -s md.tpr -f md.xtc -n index.ndx -pbc mol -o temp/temp.xtc

echo -e "1\n1\n1" | gmx_mpi trjconv -s ${TPR_FILE} -f ${TEMP_FOLDER}/temp.xtc -n ${NDX_FILE} -center -fit rot+trans -o ${TEMP_FOLDER}/traj_show.xtc

# echo -e "1\n1\n1" | gmx_mpi trjconv -s md.tpr -f temp/temp.xtc -n index.ndx -center -fit rot+trans -o temp/traj_show.xtc

echo -e "1\n1\n1" | gmx_mpi trjconv -s ${TPR_FILE} -f ${TEMP_FOLDER}/temp.xtc -n ${NDX_FILE} -center -fit rot+trans -b 0 -e 0 -o ${TEMP_FOLDER}/tarj_show.pdb

# echo -e "1\n1\n1" | gmx_mpi trjconv -s md.tpr -f temp/temp.xtc -n index.ndx -center -fit rot+trans -b 0 -e 0 -o temp/tarj_show.pdb

# Group     1 (        Protein) 

# ---
# Step 1: Extract frames every 1000 ps
gmx_mpi trjconv -s ${TPR_FILE} -f ${XTC_FILE} -o ${OUTPUT_FOLDER}/${NO_PBC_XTC_FILE} -dt ${EXTRACT_EVERY_PS} -pbc mol <<EOF
0
EOF

# Step 2: Center and fit the trajectory
# Centering the protein and fitting to the initial frame
gmx_mpi trjconv -s ${TPR_FILE} -f ${OUTPUT_FOLDER}/${NO_PBC_XTC_FILE} -o ${OUTPUT_FOLDER}/${NO_PBC_XTC_FILE} -pbc mol -center <<EOF
1
1
EOF

# Step 3: Output PDB format file
gmx_mpi trjconv -s ${TPR_FILE} -f ${OUTPUT_FOLDER}/${NO_PBC_XTC_FILE} -o ${OUTPUT_FOLDER}/${MDRUN_NAME}.pdb -pbc mol -center <<EOF
1
0
EOF

# Continue with further analysis like RMSD calculation...
# ... [other analysis commands] ...

# End of script

# command reference

# Command 1: 提取蛋白质
command_1 = f'echo "Protein" | gmx trjconv -dt 1000 -s {tpr_file} -f {xtc_file} -n {temp_folder}/tarj_show.ndx -pbc mol -o {temp_folder}/temp.xtc'
# echo "Protein": 选择蛋白质组，用于告诉 gmx trjconv 要处理哪个部分。
# -dt 1000: 指定时间间隔（这里是1000 picoseconds），用于从 .xtc 文件中抽取帧。
# -s {tpr_file}: 指定拓扑文件（.tpr），它包含了模拟系统的完整描述。
# -f {xtc_file}: 指定原始的 .xtc 轨迹文件。
# -n {temp_folder}/tarj_show.ndx: 指定索引文件，其中包含各种原子群的定义。
# -pbc mol: 处理周期性边界条件，确保分子不会被分割。
# -o {temp_folder}/temp.xtc: 指定输出文件名和位置。
# Command 2: 中心对齐蛋白质
command_2 = f'echo "Protein\nProtein\nProtein" | gmx trjconv -s {tpr_file} -f {temp_folder}/temp.xtc -n {temp_folder}/tarj_show.ndx -center -fit rot+trans -o {output_folder}/traj_show.xtc'
# echo "Protein\nProtein\nProtein": 三次选择蛋白质组，分别用于中心化、拟合和输出。
# -center: 将蛋白质移动到框架的中心。
# -fit rot+trans: 对齐蛋白质，通过旋转和平移来最佳拟合。
# -o {output_folder}/traj_show.xtc: 指定输出文件名和位置。
# Command 3: 抽取帧生成 .pdb 文件
command_3 = f'echo "Protein\nProtein\nProtein" | gmx trjconv -s {tpr_file} -f {temp_folder}/temp.xtc -n {temp_folder}/tarj_show.ndx -center -fit rot+trans -b 0 -e 0 -o {output_folder}/tarj_show.pdb'
# -b 0 -e 0: 指定开始和结束时间，这里设置为0表示只取第一帧。
# -o {output_folder}/tarj_show.pdb: 输出为 .pdb 格式，存储在指定的位置。