view sim.xml @ 4:cdaed42b4223 draft

"planemo upload for repository https://github.com/galaxycomputationalchemistry/galaxy-tools-compchem/tools/gromacs commit d75a4b4a47d2a74aacb6d3ff90755f9a5289cfb1"
author chemteam
date Wed, 18 Dec 2019 15:25:39 -0500
parents 4dba9a5b74fc
children 171ce1253b19
line wrap: on
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<tool id="gmx_sim" name="GROMACS simulation" version="@VERSION@">
    <description>for system equilibration or data collection</description>
    <macros>
        <import>macros.xml</import>
    </macros>
    <expand macro="requirements" />
    <command detect_errors="exit_code"><![CDATA[
        #if $sets.mdp.mdpfile == "custom":
            ln -s '$sets.mdp.mdp_input' ./md.mdp &&
        #end if
        #if $sets.mdp.mdpfile == "default":
            ln -s '$md' ./md.mdp &&
        #end if

        ln -s '$gro_input' ./inp.gro &&
        ln -s '$top_input' ./top_input.top &&

        #if $inps.itp_in:
            ln -s '$inps.itp_in' ./posres.itp &&
        #end if

        #if $inps.cpt_in:
            ln -s '$inps.cpt_in' ./inp.cpt &&
        #end if

        #if $inps.ndx_in:
            ln -s '$inps.ndx_in' ./index.ndx &&
        #end if

        gmx grompp 
            -f ./md.mdp 
            -c ./inp.gro 
            #if $inps.cpt_in:
                -t ./inp.cpt
            #end if
            #if $inps.itp_in:
                -r ./inp.gro
            #end if
            #if $inps.ndx_in:
                -n ./index.ndx
            #end if
            -p ./top_input.top 
            -o outp.tpr &>> verbose.txt &&


        gmx mdrun -nt "\${GALAXY_SLOTS:-4}" -deffnm outp &>> verbose.txt
 
        #if $outps.str == 'pdb' or $outps.str == 'both'
            && gmx editconf -f outp.gro -o outp.pdb &>> verbose.txt
        #end if

        && cat md.mdp &>> verbose.txt

    ]]></command>
        <configfiles>
            <!-- .mdp file for the gromacs simulation -->
            <configfile name="md">
                #if $sets.mdp.mdpfile == 'default':
                    title    = OPLS Lysozyme MD simulation 
                    ; Run parameters
                    integrator  = $sets.mdp.integrator    ; leap-frog integrator
                    nsteps    = $sets.mdp.md_steps  ; 2 * 500000 = 1000 ps (1 ns)
                    dt        = $sets.mdp.step_length    ; 2 fs
                    ; Output control
                    nstxout            = $sets.mdp.write_freq    ; save coordinates every 10.0 ps
                    nstvout            = $sets.mdp.write_freq    ; save velocities every 10.0 ps
                    nstenergy          = $sets.mdp.write_freq    ; save energies every 10.0 ps
                    nstlog            = $sets.mdp.write_freq    ; update log file every 10.0 ps
                    nstxout-compressed  = $sets.mdp.write_freq      ; save compressed coordinates every 10.0 ps
                                                    ; nstxout-compressed replaces nstxtcout
                    compressed-x-grps   = System    ; group(s) to write to the compressed trajectory file
                    ; Bond parameters
                    #if $inps.cpt_in:
                    continuation          = yes    ; Restarting after NPT 
                    #end if
                    constraint_algorithm    = lincs      ; holonomic constraints 
                    constraints              = $sets.mdp.constraints  ; all bonds (even heavy atom-H bonds) constrained
                    lincs_iter              = 1        ; accuracy of LINCS
                    lincs_order              = 4        ; also related to accuracy
                    ; Neighborsearching
                    cutoff-scheme   = $sets.mdp.cutoffscheme
                    ns_type        = grid    ; search neighboring grid cells
                    nstlist        = 10      ; 20 fs, largely irrelevant with Verlet scheme
                    rcoulomb      = $sets.mdp.rcoulomb    ; Short-range electrostatic cut-off
                    rlist       = $sets.mdp.rlist ; Cut-off distance for the short-range neighbor list.
                    rvdw        = $sets.mdp.rvdw    ; Short-range Van der Waals cut-off
                    ; Electrostatics
                    coulombtype      = $sets.mdp.coulombtype    ; method for electrostatics calculations e.g. PME
                    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    = $sets.mdp.temperature $sets.mdp.temperature           ; reference temperature, one for each group, in K
                    ; 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
                #end if
                #if $inps.itp_in:
                    define    = -DPOSRES  ; position restrain the protein
                    refcoord_scaling  = com
                #end if
                #if $sets.ensemble == "nvt":
                    pcoupl    = no     ; no pressure coupling in NVT
                #else: 
                    ; 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
                #end if

            </configfile>

        </configfiles>
    <inputs>
        <param argument="gro_input" type="data" format='gro' label="GRO structure file"/>
        <param argument="top_input" type="data" format='top' label="Topology (TOP) file"/>

        <section name="inps" title="Inputs" expanded="false">
        
            <!-- CPT inp -->
            <!-- <conditional name="cpt_inp">
                <param name="cpt_bool" type="select" label="Use a checkpoint (CPT) file" help="CPT file from a previous MD run">
                    <option value="yes">Continue simulation from a CPT file</option>
                    <option value="no" selected="true">No CPT input</option>
                </param>
                <when value="yes">
                    <param argument="cpt_in" type="data" format='cpt' label="Checkpoint file"/>
                </when>
                <when value="no"/>
            </conditional> -->
            
            <param argument="cpt_in" type="data" format='cpt' label="Checkpoint (CPT) file" optional="true" help="CPT file from a previous MD run. Leave empty if no checkpoint should be used."/>

            <!-- ITP inp -->
            <!-- <conditional name="posres">
                <param name="posres_bool" type="select" label="Apply position restraints" help="Used e.g. for equilibration of solvent around a protein" value="false">
                    <option value="true">Apply position restraints</option>
                    <option value="false" selected="true">No position restraints</option>
                </param>
                <when value="true">
                    <param argument="itp_in" type="data" format='itp' label="Position restraint (ITP) file"/>
                </when>
                <when value="false"/>
            </conditional> -->

            <param argument="itp_in" type="data" format='itp' label="Position restraint (ITP) file" optional="true" help="Apply position restraints using a ITP file. Leave empty if no position restraints should be used."/>

            <!-- NDX inp -->
            <!-- <conditional name="ndx_inp">
                <param name="ndx_bool" type="select" label="Use a custom index (ndx) file" help="Use an index file specifying custom atom groups.">
                    <option value="true">Use custom index file</option>
                    <option value="false" selected="true">Use default generated group</option>
                </param>
                <when value="true">
                    <param argument="ndx_in" type="data" format='ndx' label="Index file"/>
                </when>
                <when value="false"/>
            </conditional> -->

            <param argument="ndx_in" type="data" format='ndx' label="Index (ndx) file" optional="true" help="Use an index file specifying custom atom groups. Leave empty to use default generated group"/>

        </section>

        <section name="outps" title="Outputs" expanded="false">
            <!-- TRAJ out -->
            <param argument="traj" type="select" label="Trajectory output">
                <option value='none'>Return no trajectory output</option>
                <option value='xtc'>Return .xtc file (reduced precision)</option>
                <option value='trr'>Return .trr file (full precision)</option>
                <option value='both'>Return both .xtc and .trr files</option>
            </param>

            <!-- STR out -->
            <param argument="str" type="select" label="Structure output">
                <option value='none'>Return no structure output</option>
                <option value='gro'>Return .gro file</option>
                <option value='pdb'>Return .pdb file</option>
                <option value='both'>Return both .gro and .pdb files</option>
            </param>
            
            <!-- CPT out -->
            <param name="cpt_out" type="select" label="Produce a checkpoint (CPT) file" help="Produce CPT file for a subsequent MD run">
                <option value="true">Produce CPT output</option>
                <option value="false" selected="true">No CPT output</option>
            </param>

            <!-- EDR out -->
            <param name="edr_out" type="select" label="Produce an energy (EDR) file" help="Produce file containing energies associated with the simulation">
                <option value="true">Produce EDR output</option>
                <option value="false" selected="true">No EDR output</option>
            </param>

            <!-- XVG out -->
            <param name="xvg_out" type="select" label="Produce XVG output" help="Produce tabular XVG file (e.g. forces from pulling simulations)" >
                <option value="true">Produce XVG output</option>
                <option value="false" selected="true">No XVG output</option>
            </param>

            <!-- TPR out -->
            <param name="tpr_out" type="select" label="Produce TPR output" help="Produce TPR binary file" >
                <option value="true">Produce TPR output</option>
                <option value="false" selected="true">No TPR output</option>
            </param>
        
        </section>

        <section name="sets" title="Settings" expanded="false">
            <!-- other ... -->
            <param name="ensemble" label="Ensemble" type="select" help="NVT ensemble (constant number of particles, volume and temperature) or NPT ensemble (constant number of particles, pressure and temperature)">
                <option value="nvt">Isothermal-isochoric ensemble (NVT)</option>
                <option value="npt">Isothermal-isobaric ensemble (NPT)</option>
            </param>

            <expand macro="md_inputs"/>
        </section>

        <expand macro="log" />

    </inputs>
    <outputs>
        <data name="output1" format="gro" from_work_dir="outp.gro">
            <filter>outps["str"] == 'gro' or outps["str"] == 'both'</filter>
        </data>
        <data name="output2" format="pdb" from_work_dir="outp.pdb">
            <filter>outps["str"] == 'pdb' or outps["str"] == 'both'</filter>
        </data>
        <data name="output3" format="trr" from_work_dir="outp.trr">
            <filter>outps["traj"] == 'trr' or outps["traj"] == 'both'</filter>
        </data>
        <data name="output4" format="xtc" from_work_dir="outp.xtc">
            <filter>outps["traj"] == 'xtc' or outps["traj"] == 'both'</filter>
        </data>
        <data name="output5" format="cpt" from_work_dir="outp.cpt">
            <filter>outps["cpt_out"] == 'true'</filter>
        </data>
        <data name="output6" format="edr" from_work_dir="outp.edr">
            <filter>outps["edr_out"] == 'true'</filter>
        </data>
        <collection name="output7" type="list">
            <discover_datasets pattern="(?P&lt;designation&gt;.*)\.xvg" visible="true" directory="." />
            <filter>outps["xvg_out"] == 'true'</filter>
        </collection>
        <data name="output8" format="binary" from_work_dir="outp.tpr">
            <filter>outps["tpr_out"] == 'true'</filter>
        </data>

        <expand macro="log_outputs" />
    </outputs>

    <tests>
        <test expect_num_outputs="3">
            <param name="gro_input" value="npt.gro" />
            <param name="top_input" value="topol_solv.top" />
            <!-- <param name="cpt_bool" value="yes" /> -->
            <param name="cpt_in" value="npt.cpt" />
            <param name="mdpfile" value="custom" />
            <param name="mdp_input" value="md.mdp" />
            <!-- <param name="ndx_bool" value="false" /> -->
            <param name="traj" value="trr"/>
            <param name="str" value="gro"/>
            <param name="tpr_out" value="true"/>
            <param name="ensemble" value="npt" />
            <!-- <param name="posres_bool" value="false" /> -->
            <output name="output1" file="md_0_1.gro" ftype="gro" compare="sim_size"/>
            <output name="output3" file="md_0_1.trr" ftype="trr" compare="sim_size"/>
            <output name="output8" file="md_0_1.tpr" ftype="binary" compare="sim_size"/>
            <!-- <output name="output1" ftype="gro">
                <assert_contents>
                    <has_size value="2647999" />
                </assert_contents>
            </output>
            <output name="output3" ftype="trr">
                <assert_contents>
                    <has_size value="10132584" />
                </assert_contents>
            </output> -->
        </test>

        <test expect_num_outputs="3">
            <param name="gro_input" value="npt.gro" />
            <param name="top_input" value="topol_solv.top" />
            <!-- <param name="cpt_bool" value="yes" /> -->
            <param name="cpt_in" value="npt.cpt" />
            <!-- <param name="ndx_bool" value="false" /> -->
            <param name="traj" value="trr"/>
            <param name="str" value="both"/>
            <expand macro="test_params"/>
            <param name="ensemble" value="npt" />
            <!-- <param name="posres_bool" value="false" /> -->
            <output name="output1" file="md_0_1.gro" ftype="gro" compare="sim_size"/>
            <output name="output2" file="md_0_1.pdb" ftype="pdb" compare="sim_size"/>
            <output name="output3" file="md_0_1.trr" ftype="trr" compare="sim_size"/>
        </test>

        <test expect_num_outputs="3">
            <param name="gro_input" value="npt.gro" />
            <param name="top_input" value="topol_solv.top" />
            <!-- <param name="cpt_bool" value="yes" /> -->
            <param name="cpt_in" value="npt.cpt" />
            <!-- <param name="ndx_bool" value="true" /> -->
            <param name="ndx_in" value="index.ndx" />
            <param name="traj" value="trr"/>
            <param name="str" value="both"/>
            <expand macro="test_params"/>
            <param name="ensemble" value="npt" />
            <!-- <param name="posres_bool" value="false" /> -->
            <output name="output1" file="md_0_1.gro" ftype="gro" compare="sim_size"/>
            <output name="output2" file="md_0_1.pdb" ftype="pdb" compare="sim_size"/>
            <output name="output3" file="md_0_1.trr" ftype="trr" compare="sim_size"/>
        </test>

        <test expect_num_outputs="3">
            <param name="gro_input" value="em.gro" />
            <param name="top_input" value="topol_solv.top" />
            <!-- <param name="posres_bool" value="true" /> -->
            <param name="itp_in" value="posres.itp" />
            <!-- <param name="cpt_bool" value="no" /> -->
            <param name="cpt_out" value="true" />
            <!-- <param name="ndx_bool" value="false" /> -->
            <param name="traj" value="xtc"/>
            <param name="str" value="pdb"/>
            <param name="ensemble" value="nvt" />
            <expand macro="test_params"/>
            
            <output name="output2" file="nvt.pdb" ftype="pdb" compare="sim_size"/>
            <output name="output4" file="nvt.xtc" ftype="xtc" compare="sim_size"/>
            <output name="output5" file="nvt.cpt" ftype="cpt" compare="sim_size"/>
        </test>
    </tests>
    
    <help><![CDATA[

.. class:: infomark

**What it does**

This tool performs a molecular dynamics simulation with GROMACS.

_____

.. class:: infomark

**Input**

       - GRO structure file.
       - Topology (TOP) file.

A variety of other options can also be specified:
       - MDP parameter file to take advantage of all GROMACS features. Otherwise, choose parameters through the Galaxy interface. See the `manual`_ for more information on the options.
       - Accepting and producing checkpoint (CPT) input/output files, which allows sequential MD simulations, e.g. when performing NVT and NPT equilibration followed by a production simulation.
       - Position restraint (ITP) file, useful for equilibrating solvent around a protein.
       - Choice of ensemble: NVT or NPT.
       - Whether to return trajectory (XTC or TRR) and/or structure (GRO or PDB) files.

.. _`manual`: http://manual.gromacs.org/documentation/2018/user-guide/mdp-options.html

_____

        
.. class:: infomark

**Output**

       - Structure and/or trajectory files as specified in the input.

    ]]></help>

    <expand macro="citations" />
</tool>