# rerun command

## Syntax

    rerun file1 file2 ... keyword args ...

-   file1,file2,\... = dump file(s) to read

-   one or more keywords may be appended, keyword *dump* must appear and
    be last

        keyword = *first* or *last* or *every* or *skip* or *start* or *stop* or *post* or *dump*
         *first* args = Nfirst
           Nfirst = dump timestep to start on
         *last* args = Nlast
           Nlast = dumptimestep to stop on
         *every* args = Nevery
           Nevery = read snapshots matching every this many timesteps
         *skip* args = Nskip
           Nskip = read one out of every Nskip snapshots
         *start* args = Nstart
           Nstart = timestep on which pseudo run will start
         *stop* args = Nstop
           Nstop = timestep to which pseudo run will end
         *post* value = *yes* or *no*
         *dump* args = same as `read_dump <read_dump>`__ command starting with its field arguments

## Examples

``` LAMMPS
rerun dump.file dump x y z vx vy vz
rerun dump1.txt dump2.txt first 10000 every 1000 dump x y z
rerun dump.vels dump x y z vx vy vz box yes format molfile lammpstrj
rerun dump.dcd dump x y z box no format molfile dcd
rerun ../run7/dump.file.gz skip 2 dump x y z box yes
rerun dump.bp dump x y z box no format adios
rerun dump.bp dump x y z vx vy vz format adios timeout 10.0
```

## Description

Perform a pseudo simulation run where atom information is read one
snapshot at a time from a dump file(s), and energies and forces are
computed on the shapshot to produce thermodynamic or other output.

This can be useful in the following kinds of scenarios, after an initial
simulation produced the dump file:

-   Compute the energy and forces of snapshots using a different
    potential.
-   Calculate one or more diagnostic quantities on the snapshots that
    were not computed in the initial run. These can also be computed
    with settings not used in the initial run, e.g. computing an RDF via
    the [compute rdf](compute_rdf) command with a longer cutoff than was
    used initially.
-   Calculate the portion of per-atom forces resulting from a subset of
    the potential. E.g. compute only Coulombic forces. This can be done
    by only defining only a Coulombic pair style in the rerun script.
    Doing this in the original script would result in different (bad)
    dynamics.

Conceptually, using the rerun command is like running an input script
that has a loop in it (see the [next](next) and [jump](jump) commands).
Each iteration of the loop reads one snapshot from the dump file via the
[read_dump](read_dump) command, sets the timestep to the appropriate
value, and then invokes a [run](run) command for zero timesteps to
simply compute energy and forces, and any other [thermodynamic
output](thermo_style) or diagnostic info you have defined. This
computation also invokes any fixes you have defined that apply
constraints to the system, such as [fix shake](fix_shake) or [fix
indent](fix_indent).

Note that a simulation box must already be defined before using the
rerun command. This can be done by the [create_box](create_box),
[read_data](read_data), or [read_restart](read_restart) commands.

Also note that reading per-atom information from dump snapshots is
limited to the atom coordinates, velocities and image flags as explained
in the [read_dump](read_dump) command. Other atom properties, which may
be necessary to compute energies and forces, such as atom charge, or
bond topology information for a molecular system, are not read from (or
even contained in) dump files. Thus this auxiliary information should be
defined in the usual way, e.g. in a data file read in by a
[read_data](read_data) command, before using the rerun command.

Also note that the frequency of thermodynamic or dump output from the
rerun simulation will depend on settings made in the rerun script, the
same as for output from any LAMMPS simulation. See further info below as
to what that means if the timesteps for snapshots read from dump files
do not match the specified output frequency.

------------------------------------------------------------------------

If more than one dump file is specified, the dump files are read one
after the other in the order specified. It is assumed that snapshot
timesteps will be in ascending order. If a snapshot is encountered that
is not in ascending order, it will skip the snapshot until it reads one
that is. This allows skipping of a duplicate snapshot (same timestep),
e.g. that appeared at the end of one file and beginning of the next.
However if you specify a series of dump files in an incorrect order
(with respect to the timesteps they contain), you may skip large numbers
of snapshots.

Note that the dump files specified as part of the *dump* keyword can be
parallel files, i.e. written as multiple files either per processor
and/or per snapshot. If that is the case they will also be read in
parallel which can make the rerun command operate dramatically faster
for large systems. See the page for the [read_dump](read_dump) and
[dump](dump) commands which describe how to read and write parallel dump
files.

The *first*, *last*, *every*, *skip* keywords determine which snapshots
are read from the dump file(s). Snapshots are skipped until they have a
timestep \>= *Nfirst*. When a snapshot with a timestep \> *Nlast* is
encountered, the rerun command finishes. Note that the defaults for
*first* and *last* are to read all snapshots. If the *every* keyword is
set to a value \> 0, then only snapshots with timesteps that are a
multiple of *Nevery* are read (the first snapshot is always read). If
*Nevery* = 0, then this criterion is ignored, i.e. every snapshot is
read that meets the other criteria. If the *skip* keyword is used, then
after the first snapshot is read, every Nth snapshot is read, where N =
*Nskip*. E.g. if *Nskip* = 3, then only 1 out of every 3 snapshots is
read, assuming the snapshot timestep is also consistent with the other
criteria.

:::: note
::: title
Note
:::

Not all dump formats contain the timestep and not all dump readers
support reading it. In that case individual snapshots are assigned
consecutive timestep numbers starting at 1.
::::

The *start* and *stop* keywords do not affect which snapshots are read
from the dump file(s). Rather, they have the same meaning that they do
for the [run](run) command. They only need to be defined if (a) you are
using a [fix](fix) command that changes some value over time, and (b)
you want the reference point for elapsed time (from start to stop) to be
different than the *first* and *last* settings. See the page for
individual fixes to see which ones can be used with the *start/stop*
keywords. Note that if you define neither of the *start*/\*stop\* or
*first*/\*last\* keywords, then LAMMPS treats the pseudo run as going
from 0 to a huge value (effectively infinity). This means that any
quantity that a fix scales as a fraction of elapsed time in the run,
will essentially remain at its initial value. Also note that an error
will occur if you read a snapshot from the dump file with a timestep
value larger than the *stop* setting you have specified.

The *post* keyword can be used to minimize the output to the screen that
happens after a *rerun* command, similar to the post keyword of the [run
command](run). It is set to *no* by default.

The *dump* keyword is required and must be the last keyword specified.
Its arguments are passed internally to the [read_dump](read_dump)
command. The first argument following the *dump* keyword should be the
*field1* argument of the [read_dump](read_dump) command. See the
[read_dump](read_dump) page for details on the various options it allows
for extracting information from the dump file snapshots, and for using
that information to alter the LAMMPS simulation.

------------------------------------------------------------------------

In general, a LAMMPS input script that uses a rerun command can include
and perform all the usual operations of an input script that uses the
[run](run) command. There are a few exceptions and points to consider,
as discussed here.

Fixes that perform time integration, such as [fix nve](fix_nve) or [fix
npt](fix_nh) are not invoked, since no time integration is performed.
Fixes that perturb or constrain the forces on atoms will be invoked,
just as they would during a normal run. Examples are [fix
indent](fix_indent) and [fix langevin](fix_langevin). So you should
think carefully as to whether that makes sense for the manner in which
you are reprocessing the dump snapshots.

If you only want the rerun script to perform an analysis that does not
involve pair interactions, such as use compute msd to calculated
displacements over time, you do not need to define a [pair
style](pair_style), which may also mean neighbor lists will not need to
be calculated which saves time. The [comm_modify cutoff](comm_modify)
command can also be used to ensure ghost atoms are acquired from far
enough away for operations like bond and angle evaluations, if no pair
style is being used.

Every time a snapshot is read, the timestep for the simulation is reset,
as if the [reset_timestep](reset_timestep) command were used. This
command has some restrictions as to what fixes can be defined. See its
documentation page for details. For example, the [fix
deposit](fix_deposit) and [fix dt/reset](fix_dt_reset) fixes are in this
category. They also make no sense to use with a rerun command.

If time-averaging fixes like [fix ave/time](fix_ave_time) are used, they
are invoked on timesteps that are a function of their *Nevery*,
*Nrepeat*, and *Nfreq* settings. As an example, see the [fix
ave/time](fix_ave_time) page for details. You must ensure those settings
are consistent with the snapshot timestamps that are read from the dump
file(s). If an averaging fix is not invoked on a timestep it expects to
be, LAMMPS will flag an error.

The various forms of LAMMPS output, as defined by the
[thermo_style](thermo_style), [thermo](thermo), [dump](dump), and
[restart](restart) commands occur with specified frequency, e.g. every N
steps. If the timestep for a dump snapshot is not a multiple of N, then
it will be read and processed, but no output will be produced. If you
want output for every dump snapshot, you can simply use N=1 for an
output frequency, e.g. for thermodynamic output or new dump file output.

------------------------------------------------------------------------

## Restrictions

The *rerun* command is subject to all restrictions of the
[read_dump](read_dump) command.

## Related commands

[read_dump](read_dump)

## Default

The option defaults are first = 0, last = a huge value (effectively
infinity), start = same as first, stop = same as last, every = 0, skip =
1, post = no;