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repdstr (c48b1)
The Parallel Distributed Replica
By Paul Maragakis and Milan Hodoscek, 2005
Parallel distributed replica allows independent replicated systems
over specified number of processors. Although previously REPDSTR mainly
worked with CMPI, it can (and should) now be compiled without it.
REPDSTR also now works with DOMDEC turned on.
REPDSTR is still not the default pref.dat keyword so the recommended way
to compile CHARMM is the following:
$ ./configure --with-repdstr ...
$ make -C build/cmake install
MSCALE is not really needed for pure REPDSTR runs, but it is
needed for triple parallel CHARMM (» mscale ).
Recently, the dependency of REPDSTR on CMPI has become a liability
because it makes REPDSTR incompatible with some newer portions of
For one of the examples of REPDSTR usage see this reference:
Jiang, W; Hodoscek, M; Roux, B; "Computation of Absolute Hydration and
Binding Free Energy with Free Energy Perturbation Distributed
Replica-Exchange Molecular Dynamics", J. Chem. Theo. and Comp., 2009,
Vol. 5, 2583-2588.
For the reservoir replica exchange code, please cite the following
references:
Boltzmann reservoir REX--
Okur A., Roe D., Cui G., Hornak V., Simmerling C. J. Chem Theo. Comput.
3, 557-568 (2007).
Non-boltzmann reservoir REX--
Roitberg A., Okur. A., Simmerling C. J. Phys. Chem. B. 111, 2415-2418
(2007).
Okur A., Miller B. T, Joo K., Lee J., Brooks B. R. J. Chem Theo. Comput.
9, 1115-1124 (2013).
* Syntax | Syntax of the REPD command
* I/O | Input and output functionality
* FAST | Usage of FAST replica exchange
* Examples | Examples to show the possibilities
* Output | Explanation of the replica exchange printout
By Paul Maragakis and Milan Hodoscek, 2005
Parallel distributed replica allows independent replicated systems
over specified number of processors. Although previously REPDSTR mainly
worked with CMPI, it can (and should) now be compiled without it.
REPDSTR also now works with DOMDEC turned on.
REPDSTR is still not the default pref.dat keyword so the recommended way
to compile CHARMM is the following:
$ ./configure --with-repdstr ...
$ make -C build/cmake install
MSCALE is not really needed for pure REPDSTR runs, but it is
needed for triple parallel CHARMM (» mscale ).
Recently, the dependency of REPDSTR on CMPI has become a liability
because it makes REPDSTR incompatible with some newer portions of
For one of the examples of REPDSTR usage see this reference:
Jiang, W; Hodoscek, M; Roux, B; "Computation of Absolute Hydration and
Binding Free Energy with Free Energy Perturbation Distributed
Replica-Exchange Molecular Dynamics", J. Chem. Theo. and Comp., 2009,
Vol. 5, 2583-2588.
For the reservoir replica exchange code, please cite the following
references:
Boltzmann reservoir REX--
Okur A., Roe D., Cui G., Hornak V., Simmerling C. J. Chem Theo. Comput.
3, 557-568 (2007).
Non-boltzmann reservoir REX--
Roitberg A., Okur. A., Simmerling C. J. Phys. Chem. B. 111, 2415-2418
(2007).
Okur A., Miller B. T, Joo K., Lee J., Brooks B. R. J. Chem Theo. Comput.
9, 1115-1124 (2013).
* Syntax | Syntax of the REPD command
* I/O | Input and output functionality
* FAST | Usage of FAST replica exchange
* Examples | Examples to show the possibilities
* Output | Explanation of the replica exchange printout
Top
REPDstr [ FAST ] NREP <int> [ NATRep <int> ]
Replicates the system <int> times. Optional NATRep limits the
number of atoms to be included in the path calculations (RPATH
commands). It also reduces the size of arrays that need to be
transfered between replicas in the RPATH calculations.
REPDstr NREP <int> [REPEat <int> [ LOGLevel <int> ] { EXCHange replica-exchange-spec }
{ PHREx ph-replica-exchange-spec }
replica-exchange-spec::= FREQuency <int> temperature-spec
[UNIT <int>] [SUMP]
[NREP <int>]
[SGLD] sgld-replica-exchange-spec
[TIGEr] tiger-spec
[RSRV] reservoir-spec
[TWOD] twod-spec
[NDIM] ndim-spec
[EWRU <int>]
[NOPV]
temperature-spec::= [ [ TEMP <real> ] TEMP <real> ... ]
[STEMperature <real> DTEMperature <real> MTEMperature <real>]
tiger-spec::= [ITER <int> ] [NEQU <int>] [NMIN <int>] [TOLG <real>]
ph-replica-exchange-spec ::= FREQuency <int> ph-spec [UNIT <int>] [ RSVR reservoir-spec ]
reservoir-spec ::= RESHigh { BOLTzmann } RHTEmp <real> RHUNit <int> RHSZ <int> [ RHEN <int> ]
RESLow { NOBOltzmann } RLTEmp <real> RLUNit <int> RLSZ <int> [ RLEN <int> ]
[ ECOR ] [ FHEN <int> ] [ FLEN <int> ]
ph-spec ::= [ [PHVAlue <real>] PHVAlue <real> ... ]
sgld-replica-exchange-spec::= [ [ SGTT <real> ] SGTT <real> ... ]
[SGTE <real> DSGT <real> MSGT <real>]
[SGFT <real> ] DSGF <real> ... ]
twod-spec::= DIM1 <int> D1CR criteria-spec D1FRequency <int>
DIM2 <int> D2CR criteria-spec D2FRequency <int>
multi-spec
ndim-spec::= DIMSize <int> DCRIteria criteria-spec DFREquency <int> ...
multi-spec
criteria-spec::= { TEMPerature }
{ HAM }
{ PH }
{ SGLD }
multi-spec::= [HTEMperature <real>] [temp-spec] [ph-spec] [sgld-replica-exchange-spec]
[MULTiple]
This is for the replica exchange method (see details in
c34test/rexc.inp, c36test/rexcpt.inp, c36test/rexsgld.inp) Currently
it works so that when exchange occurs all the coordinates and
velocities are exchanged, thus the lowest temperature is always on the
first replica. This also implies that the number of atoms in the
replicas have to be the same. The other method which exchange only the
temperature will be implemented later. With just temperature exchange
the replicas do not need to be the same anymore.
Current implementation of replica exchange methods has its own
temperature control independent of the CHARMM's one. So in the case of
exchanging the coordinates and velocities also the appropriate
temperature scaling is perfomed. Perhaps it is best to turn CHARMM's
own temperature controls off, but one can also combine the two. To get
both temperature control mechanisms at the same time one need to define
different temperature for each replica. This can be accomplished by
the following commands in the CHARMM input script:
set st 300
set dt 10
repd nrep @nreps EXCHange FREQuency 50 STEMp @st DTEMp @dt sump unit 17
mult dt by ?myrep
incr st by @dt
dyna cpt start nstep 1000 timestep 0.001 -
....
hoover reft @st tmass 2000.0 tbath @st -
....
As of CHARMM version c37a2, replica exchange in pH space is also
supported. This uses the formalism described in the reference given in
consph.info. The CONSPH key word must be in pref.dat along with REPDSTR
to activate this functionality.
Details about each keyword:
UNIT <int> - Optional keyword for exchange output file. Default for
int is OUTU. Must be opened after repd: each replica
writes to its own file. If no open statement all
replicas write to the same file with the default
fortran file name for this unit. Open before the repd
command is not very useful. Can be also the same unit
as on the OUTU command so exchange info is written to
the same output files.
SUMPrint - Summary printout. On replica zero the summary from
all other replicas is printed to UNIT, and on the
rest of the repicas just their own data. This is
flaged since it requires extra communication just for
printouts.
FREQuency - when to exchange
REPEat - Number of times to repeat an exchange attempt every FREQ
steps.
STEM - Starting-temperature.
DTEM - temperature-increase
MTEM - Top temperature. When MTEM>0, DTEM is ignored and temperatures
of replicas are expoenentially spaced.
TEMPerature - Temperature of each replica if STEM is not set. It must be
repeated NREP times.
PHVAl - pH value of each replica when replica exchange in pH space is
used.
SGLD - Flag to do RXSGLD with the self-guiding
temperature. It maybe used with the standard replica
exchange or one can specify all the temperature the
same, most convenient with the STEM <temp> DTEM 0.0.
SGTE 0 - The self-guiding temperature for the first replica.
DSGT 0 - Increment for the self-guiding temperature
MSGT 0 - The top self-guiding temperature. If MSGT>0, DSGT is ignored and
the guiding temperatures of replicas are expoenentially spaced.
SGTT - Self-guiding temperature of each replica if SGTE is not set.
It must be repeated NREP times.
SGFT 0 - The guiding factor of the first replica. When the self-guiding
temperatures are set with SGTE..., SGFT will be adjusted
automatically during simulation.
DSGF 0 - Guiding factor increment.
EWRU <int> - Energy write out unit - this parameter is only active with
Hamiltonian replica exchange. It writes a log of the energies
for the replica and its partner at each exchange attempt. These
energies can be read into the FREN command to calculate overlap
between replicas (» fren for details). If this keyword
is not specified, this information is written out to the unit
given by the UNIT keyword, if greater than 0.
NOPV - Disable pressure/volume correction to exchange criterion.
TIGEr - Flag to start TIGER replica exchange.
ITER - number of iteration steps for minimization and
equlibration procedures before the exchange.
Default: 1
NEQU - number of steps in the equlibration process.
Default: 1000
NMIN - number of steps in the minimization process.
Default: 100
TOLG - gradient tolerance in the minimization step.
Default:0.0
PHMD - Flag to allow exchange of theta variables from CPHMD
along with spatial coordinates. Thus, replicas can be run
at different pH (Hamiltonian replica exchange) or temperture.
It is also possible to couple the top or bottom replicas (or
both) to a reservoir of structures. To do so, the RSVR keyword is
used. When RSVR is used, at least one of the following keywords
must also be used with the corresponding unit numbers to tell CHARMM
which replica(s) should be coupled to the reservoir.
RESH - couple the top replica to a reservoir. RHUN must
be specified.
RESL - couple the bottom replica to a reservoir. RLUN
must be specified.
RHSZ - The number of elements in the top reservoir.
RLSZ - The number of elements in the bottom reservoir.
RHEN - A unit number pointing to a data file listing the
potential energies of each reservoir structure in
the top reservoir. The data file should be formatted
in order with one energy per line. This is ONLY
required for Hamiltonian reservoir replica exchange.
RLEN - Identical to RHEN, but for the bottom reservoir.
RHUN and RLUN must be units that point to open files in a simplified
trajectory format. This format is a standard CHARMM binary trajectory
file, but has the header and crystal information stripped out. A utility,
simpletraj.py, is provided in the support/programs directory to convert a standard
files musrt be opened in DIREct mode with a record size specified (which
is four times the number of atoms except for pH reservoirs).
Two exchange schemes have been implemented to govern coupling of the
reservoir with its neighboring replica.
BOLTzmann - The standard Boltzmann temperature replica exchange
criterion is used. Use of this keyword implies that
the reservoir is a sample from a Boltzmann distribution.
If this option is used, RHTEmp and/or RLTEmp must
be used to specify the temperatures of the high and
low reservoirs, respectively.
NOBOltzmann - This option allows for a non-Boltzmann weighted
reservoir, using a slightly different exchange
criterion.
The RHUNit and RLUNit key-words tell CHARMM how many structures are in the
high and low reservoirs. If FHEN or FLEN are used, then the energies of
the high and low structures are read from the given unit, one floating
point number per line. The number of lines in the file must match the number
of structures in the reservoir, and the order of the lines must correspond
to the order of the structures in the reservoirs. If these options are
omitted, the energy of each structure is calculated by CHARMM. If the ECOR
key word is specified, 0.5*kT of energy is added to the structure energy
for each degree of freedom in the system, which provides a quick and dirty
way of adjust the structure energy to the desired temperature.
As of CHARMM c40a1, the reservoir replica exchange scheme has been
extended to Hamiltonian and discrete-state (CONSPH key-word) pH replica
exchange. It does NOT work with the continuous-state pH replica exchange
code (PHMD key word). Hamiltonian and pH reservoir replica exchange are
only implemented for BOLTzmann reservoir replica exchange; use of the
NOBOltzmann exchange criteria will throw an error.
REPDstr RESEt [ SYNC ] [ PONE ]
Resets the run to a normal parallel run. SYNC does the global
sync before that. PONE is making for everybody NUMNOD=1. As of March
2010 RESET is still not fully supported.
REPDstr IORES
Sometimes within the REPDstr run one wants to access the files
created by other replicas. After this command is executed the names in
the open command do not get _myrep appended!
REPDstr IOSET
Sets the appending of the replica number back to original nameing
scheme in REPEDstr.
REPDstr NREP <int> EXLM [EXPT NRPT <int>] FREQuency <int>
This is for Hamiltonian exchange method. Currently it works so that
when exchange occurs all the coordinates are exchanged and new nonbond list
are generated. To guarantee stable md run after exchange, velocities also
are exchanged once an exchange attempt is accepted. The present Hamiltonian-
exchange scheme works for all integrators, including VV2 integrator for
Drude oscillator model.
EXLM - Keyword invoking Hamiltonian exchange. Currently it can be used
in Free Energy perturbation and umbrella sampling.
EXPT NRPT <int> - Optional keyword introducing parallel tempering into
Hamiltonian exchange. With this keyword, the replica-exchange
consists of two alternative stages: parallel tempering and Halmiltonian
exchange. In parallel tempering stage, the number of replicas
participating exchange is NREP, while in Hamiltonian exchange stage,
the number of replica is NREP/NRPT. Currently it can be used to
accelerate the relaxation of internal degrees of freedom, such as
sidechain dynamics and backbone dynamics
REPD NREP <int> EXLM EX2D NRPX <int> FREQ <int>
This is a new 2 Dimensional Hamiltonian Replica exchange scheme.
Hamiltonian-Exchange is extended to PBC systems for either NVT and NPT
simulation. This new feature is especially useful to enhance samplings of
umbrella sampling that involve multiple reaction coordinates.
EX2D NRPX <int> - Optional keyword introducing 2D replica exchange.
With this keyword, the number of replicas along X (one reaction coordinate)
is NREPX, then the number of replicas along the other reaction coordinate
is NREP/NREPX.
REPD TWOD DIM1 <int> DIM2 <int> D1FR <int> D2FR <int> -
D1CR <string> D2CR <string> [HTEMperature <real>] -
[temp-spec] [ph-spec] [sgld-replica-exchange-spec] -
[MULT]
This is a alternate 2D replica exchange implementation that allows
each dimension to be temperature, Hamiltonian, pH, or self-guided
Langevin replica exchange. This is set by the two dimension criteria
D1CR and D2CR, each of which may be TEMP, HAM, PH, or SGLD. Note that
only one TEMP, PH, or SGLD dimension may be used. However, two
Hamiltonian dimensions can be used. If no temperature dimension is
specified the exchange temperature needs to be specified with HTEM. The
number of replicas in each dimension is set by DIM1 and DIM2. The exchange
frequency for each dimension is set by D1FR and D2FR. D1FR should be
set smaller than D2FR. The default behavior is that if D2FR is a multiple
of D1FR, then no dimension 1 exchange will occur on the same step as an
exchange in dimension 2. If the MULT keyword is specified, multiple dimensions
can exchange in the same exchange attempt.
REPD NDIM DIMSize <int> DCRIteria criteria-spec DFREquency <int> ... -
[HTEMperature <real>] [MULT] -
[temp-spec] [ph-spec] [sgld-replica-exchange-spec]
This is the N-dimensional replica exchange implementation, which is essentially
TWOD generalized to N dimensions. For each desired dimension DIMS, DCRI,
and DFRE must be specified. The remaining keywords function as they do for
TWOD.
After this command has been executed, the following substitution
valriables become available:
?nrep - number of replicas overall
?myrep - global index of the current replica
?nrepd<X> - number of replicas in dimension <X>, where <X> is an integer.
?myrepd<X> - current replica's position in dimension <X>
REPDstr [ FAST ] NREP <int> [ NATRep <int> ]
Replicates the system <int> times. Optional NATRep limits the
number of atoms to be included in the path calculations (RPATH
commands). It also reduces the size of arrays that need to be
transfered between replicas in the RPATH calculations.
REPDstr NREP <int> [REPEat <int> [ LOGLevel <int> ] { EXCHange replica-exchange-spec }
{ PHREx ph-replica-exchange-spec }
replica-exchange-spec::= FREQuency <int> temperature-spec
[UNIT <int>] [SUMP]
[NREP <int>]
[SGLD] sgld-replica-exchange-spec
[TIGEr] tiger-spec
[RSRV] reservoir-spec
[TWOD] twod-spec
[NDIM] ndim-spec
[EWRU <int>]
[NOPV]
temperature-spec::= [ [ TEMP <real> ] TEMP <real> ... ]
[STEMperature <real> DTEMperature <real> MTEMperature <real>]
tiger-spec::= [ITER <int> ] [NEQU <int>] [NMIN <int>] [TOLG <real>]
ph-replica-exchange-spec ::= FREQuency <int> ph-spec [UNIT <int>] [ RSVR reservoir-spec ]
reservoir-spec ::= RESHigh { BOLTzmann } RHTEmp <real> RHUNit <int> RHSZ <int> [ RHEN <int> ]
RESLow { NOBOltzmann } RLTEmp <real> RLUNit <int> RLSZ <int> [ RLEN <int> ]
[ ECOR ] [ FHEN <int> ] [ FLEN <int> ]
ph-spec ::= [ [PHVAlue <real>] PHVAlue <real> ... ]
sgld-replica-exchange-spec::= [ [ SGTT <real> ] SGTT <real> ... ]
[SGTE <real> DSGT <real> MSGT <real>]
[SGFT <real> ] DSGF <real> ... ]
twod-spec::= DIM1 <int> D1CR criteria-spec D1FRequency <int>
DIM2 <int> D2CR criteria-spec D2FRequency <int>
multi-spec
ndim-spec::= DIMSize <int> DCRIteria criteria-spec DFREquency <int> ...
multi-spec
criteria-spec::= { TEMPerature }
{ HAM }
{ PH }
{ SGLD }
multi-spec::= [HTEMperature <real>] [temp-spec] [ph-spec] [sgld-replica-exchange-spec]
[MULTiple]
This is for the replica exchange method (see details in
c34test/rexc.inp, c36test/rexcpt.inp, c36test/rexsgld.inp) Currently
it works so that when exchange occurs all the coordinates and
velocities are exchanged, thus the lowest temperature is always on the
first replica. This also implies that the number of atoms in the
replicas have to be the same. The other method which exchange only the
temperature will be implemented later. With just temperature exchange
the replicas do not need to be the same anymore.
Current implementation of replica exchange methods has its own
temperature control independent of the CHARMM's one. So in the case of
exchanging the coordinates and velocities also the appropriate
temperature scaling is perfomed. Perhaps it is best to turn CHARMM's
own temperature controls off, but one can also combine the two. To get
both temperature control mechanisms at the same time one need to define
different temperature for each replica. This can be accomplished by
the following commands in the CHARMM input script:
set st 300
set dt 10
repd nrep @nreps EXCHange FREQuency 50 STEMp @st DTEMp @dt sump unit 17
mult dt by ?myrep
incr st by @dt
dyna cpt start nstep 1000 timestep 0.001 -
....
hoover reft @st tmass 2000.0 tbath @st -
....
As of CHARMM version c37a2, replica exchange in pH space is also
supported. This uses the formalism described in the reference given in
consph.info. The CONSPH key word must be in pref.dat along with REPDSTR
to activate this functionality.
Details about each keyword:
UNIT <int> - Optional keyword for exchange output file. Default for
int is OUTU. Must be opened after repd: each replica
writes to its own file. If no open statement all
replicas write to the same file with the default
fortran file name for this unit. Open before the repd
command is not very useful. Can be also the same unit
as on the OUTU command so exchange info is written to
the same output files.
SUMPrint - Summary printout. On replica zero the summary from
all other replicas is printed to UNIT, and on the
rest of the repicas just their own data. This is
flaged since it requires extra communication just for
printouts.
FREQuency - when to exchange
REPEat - Number of times to repeat an exchange attempt every FREQ
steps.
STEM - Starting-temperature.
DTEM - temperature-increase
MTEM - Top temperature. When MTEM>0, DTEM is ignored and temperatures
of replicas are expoenentially spaced.
TEMPerature - Temperature of each replica if STEM is not set. It must be
repeated NREP times.
PHVAl - pH value of each replica when replica exchange in pH space is
used.
SGLD - Flag to do RXSGLD with the self-guiding
temperature. It maybe used with the standard replica
exchange or one can specify all the temperature the
same, most convenient with the STEM <temp> DTEM 0.0.
SGTE 0 - The self-guiding temperature for the first replica.
DSGT 0 - Increment for the self-guiding temperature
MSGT 0 - The top self-guiding temperature. If MSGT>0, DSGT is ignored and
the guiding temperatures of replicas are expoenentially spaced.
SGTT - Self-guiding temperature of each replica if SGTE is not set.
It must be repeated NREP times.
SGFT 0 - The guiding factor of the first replica. When the self-guiding
temperatures are set with SGTE..., SGFT will be adjusted
automatically during simulation.
DSGF 0 - Guiding factor increment.
EWRU <int> - Energy write out unit - this parameter is only active with
Hamiltonian replica exchange. It writes a log of the energies
for the replica and its partner at each exchange attempt. These
energies can be read into the FREN command to calculate overlap
between replicas (» fren for details). If this keyword
is not specified, this information is written out to the unit
given by the UNIT keyword, if greater than 0.
NOPV - Disable pressure/volume correction to exchange criterion.
TIGEr - Flag to start TIGER replica exchange.
ITER - number of iteration steps for minimization and
equlibration procedures before the exchange.
Default: 1
NEQU - number of steps in the equlibration process.
Default: 1000
NMIN - number of steps in the minimization process.
Default: 100
TOLG - gradient tolerance in the minimization step.
Default:0.0
PHMD - Flag to allow exchange of theta variables from CPHMD
along with spatial coordinates. Thus, replicas can be run
at different pH (Hamiltonian replica exchange) or temperture.
It is also possible to couple the top or bottom replicas (or
both) to a reservoir of structures. To do so, the RSVR keyword is
used. When RSVR is used, at least one of the following keywords
must also be used with the corresponding unit numbers to tell CHARMM
which replica(s) should be coupled to the reservoir.
RESH - couple the top replica to a reservoir. RHUN must
be specified.
RESL - couple the bottom replica to a reservoir. RLUN
must be specified.
RHSZ - The number of elements in the top reservoir.
RLSZ - The number of elements in the bottom reservoir.
RHEN - A unit number pointing to a data file listing the
potential energies of each reservoir structure in
the top reservoir. The data file should be formatted
in order with one energy per line. This is ONLY
required for Hamiltonian reservoir replica exchange.
RLEN - Identical to RHEN, but for the bottom reservoir.
RHUN and RLUN must be units that point to open files in a simplified
trajectory format. This format is a standard CHARMM binary trajectory
file, but has the header and crystal information stripped out. A utility,
simpletraj.py, is provided in the support/programs directory to convert a standard
files musrt be opened in DIREct mode with a record size specified (which
is four times the number of atoms except for pH reservoirs).
Two exchange schemes have been implemented to govern coupling of the
reservoir with its neighboring replica.
BOLTzmann - The standard Boltzmann temperature replica exchange
criterion is used. Use of this keyword implies that
the reservoir is a sample from a Boltzmann distribution.
If this option is used, RHTEmp and/or RLTEmp must
be used to specify the temperatures of the high and
low reservoirs, respectively.
NOBOltzmann - This option allows for a non-Boltzmann weighted
reservoir, using a slightly different exchange
criterion.
The RHUNit and RLUNit key-words tell CHARMM how many structures are in the
high and low reservoirs. If FHEN or FLEN are used, then the energies of
the high and low structures are read from the given unit, one floating
point number per line. The number of lines in the file must match the number
of structures in the reservoir, and the order of the lines must correspond
to the order of the structures in the reservoirs. If these options are
omitted, the energy of each structure is calculated by CHARMM. If the ECOR
key word is specified, 0.5*kT of energy is added to the structure energy
for each degree of freedom in the system, which provides a quick and dirty
way of adjust the structure energy to the desired temperature.
As of CHARMM c40a1, the reservoir replica exchange scheme has been
extended to Hamiltonian and discrete-state (CONSPH key-word) pH replica
exchange. It does NOT work with the continuous-state pH replica exchange
code (PHMD key word). Hamiltonian and pH reservoir replica exchange are
only implemented for BOLTzmann reservoir replica exchange; use of the
NOBOltzmann exchange criteria will throw an error.
REPDstr RESEt [ SYNC ] [ PONE ]
Resets the run to a normal parallel run. SYNC does the global
sync before that. PONE is making for everybody NUMNOD=1. As of March
2010 RESET is still not fully supported.
REPDstr IORES
Sometimes within the REPDstr run one wants to access the files
created by other replicas. After this command is executed the names in
the open command do not get _myrep appended!
REPDstr IOSET
Sets the appending of the replica number back to original nameing
scheme in REPEDstr.
REPDstr NREP <int> EXLM [EXPT NRPT <int>] FREQuency <int>
This is for Hamiltonian exchange method. Currently it works so that
when exchange occurs all the coordinates are exchanged and new nonbond list
are generated. To guarantee stable md run after exchange, velocities also
are exchanged once an exchange attempt is accepted. The present Hamiltonian-
exchange scheme works for all integrators, including VV2 integrator for
Drude oscillator model.
EXLM - Keyword invoking Hamiltonian exchange. Currently it can be used
in Free Energy perturbation and umbrella sampling.
EXPT NRPT <int> - Optional keyword introducing parallel tempering into
Hamiltonian exchange. With this keyword, the replica-exchange
consists of two alternative stages: parallel tempering and Halmiltonian
exchange. In parallel tempering stage, the number of replicas
participating exchange is NREP, while in Hamiltonian exchange stage,
the number of replica is NREP/NRPT. Currently it can be used to
accelerate the relaxation of internal degrees of freedom, such as
sidechain dynamics and backbone dynamics
REPD NREP <int> EXLM EX2D NRPX <int> FREQ <int>
This is a new 2 Dimensional Hamiltonian Replica exchange scheme.
Hamiltonian-Exchange is extended to PBC systems for either NVT and NPT
simulation. This new feature is especially useful to enhance samplings of
umbrella sampling that involve multiple reaction coordinates.
EX2D NRPX <int> - Optional keyword introducing 2D replica exchange.
With this keyword, the number of replicas along X (one reaction coordinate)
is NREPX, then the number of replicas along the other reaction coordinate
is NREP/NREPX.
REPD TWOD DIM1 <int> DIM2 <int> D1FR <int> D2FR <int> -
D1CR <string> D2CR <string> [HTEMperature <real>] -
[temp-spec] [ph-spec] [sgld-replica-exchange-spec] -
[MULT]
This is a alternate 2D replica exchange implementation that allows
each dimension to be temperature, Hamiltonian, pH, or self-guided
Langevin replica exchange. This is set by the two dimension criteria
D1CR and D2CR, each of which may be TEMP, HAM, PH, or SGLD. Note that
only one TEMP, PH, or SGLD dimension may be used. However, two
Hamiltonian dimensions can be used. If no temperature dimension is
specified the exchange temperature needs to be specified with HTEM. The
number of replicas in each dimension is set by DIM1 and DIM2. The exchange
frequency for each dimension is set by D1FR and D2FR. D1FR should be
set smaller than D2FR. The default behavior is that if D2FR is a multiple
of D1FR, then no dimension 1 exchange will occur on the same step as an
exchange in dimension 2. If the MULT keyword is specified, multiple dimensions
can exchange in the same exchange attempt.
REPD NDIM DIMSize <int> DCRIteria criteria-spec DFREquency <int> ... -
[HTEMperature <real>] [MULT] -
[temp-spec] [ph-spec] [sgld-replica-exchange-spec]
This is the N-dimensional replica exchange implementation, which is essentially
TWOD generalized to N dimensions. For each desired dimension DIMS, DCRI,
and DFRE must be specified. The remaining keywords function as they do for
TWOD.
After this command has been executed, the following substitution
valriables become available:
?nrep - number of replicas overall
?myrep - global index of the current replica
?nrepd<X> - number of replicas in dimension <X>, where <X> is an integer.
?myrepd<X> - current replica's position in dimension <X>
Top
Once REPDstr command is activated the I/O capabilities of CHARMM
are expanded. In standard parallel mode CHARMM deals with I/O only on
the first process. The rest of processes get their data through
network or memory communication. So all I/O statements that are in the
script before REPDstr command are valid only on first process. In
distributed replica mode each replica needs its own and independent
I/O which is enabled after the REPDstr keyword in the input script.
Two substitution parameters are defined after the REPD command is
specified in the input script: ?NREP (number of replicas) and ?MYREP
(current executing replica).
As of May 2009 the following is working:
1. OPEN
The command open read|write unit 1 card name somefile will open
somefile_0 for replica 0, somefile_1 for replica 1, etc
2. READ/WRITE
writes to individual files one for each replica. It works for all
I/O operations.
3. STRE stream
This will open stream_0 for replica 0, stream_1 for replica 1, etc
It allows CHARMM to run different input files for each replica (or
group of processors)
4. OUTU unit
Will stream output to individual files as specified in the open
command for particular unit. This command should precede STRE
command if one wants both input and output files for each group of
processors
5. IF ?MYREP .EQ. n THEN ....
Works, too. Output only for the processor zero, unless OUTU is
specified.
6. All the above works in parallel/parallel mode, ie each replica can
be a parallel job in itself. The numeration of input and output
files follows the replica numbers.
The output is written only on a local process 0 for each replica,
and similar is true also for stream command. The limitation is
that the number of replicas must divide the number of processes
allocated for parallel. Otherwise it bombs out with the level -5.
Once REPDstr command is activated the I/O capabilities of CHARMM
are expanded. In standard parallel mode CHARMM deals with I/O only on
the first process. The rest of processes get their data through
network or memory communication. So all I/O statements that are in the
script before REPDstr command are valid only on first process. In
distributed replica mode each replica needs its own and independent
I/O which is enabled after the REPDstr keyword in the input script.
Two substitution parameters are defined after the REPD command is
specified in the input script: ?NREP (number of replicas) and ?MYREP
(current executing replica).
As of May 2009 the following is working:
1. OPEN
The command open read|write unit 1 card name somefile will open
somefile_0 for replica 0, somefile_1 for replica 1, etc
2. READ/WRITE
writes to individual files one for each replica. It works for all
I/O operations.
3. STRE stream
This will open stream_0 for replica 0, stream_1 for replica 1, etc
It allows CHARMM to run different input files for each replica (or
group of processors)
4. OUTU unit
Will stream output to individual files as specified in the open
command for particular unit. This command should precede STRE
command if one wants both input and output files for each group of
processors
5. IF ?MYREP .EQ. n THEN ....
Works, too. Output only for the processor zero, unless OUTU is
specified.
6. All the above works in parallel/parallel mode, ie each replica can
be a parallel job in itself. The numeration of input and output
files follows the replica numbers.
The output is written only on a local process 0 for each replica,
and similar is true also for stream command. The limitation is
that the number of replicas must divide the number of processes
allocated for parallel. Otherwise it bombs out with the level -5.
Top
The FAST keyword turns on "fast" replica exchange (1D, temperature exchange
only). When this option is activated, all exchange decisions are made on
processor 0, and new temperatures are sent to each individual replica,
as opposed to sending coordinates and velocities between replicas.
This method requires substantially less communication, especially when
the REPEat keyword is used. The drawback is that the outputs are per-replica
rather than per-temperature. Additional functionality has been added to the
MERGE command (» dynamc ) to convert per-replica trajectories
to per-temperature.
Additionally, since all decisions are made on processor 0, only a single
exchange file is written out, showing the results of ALL exchanges at
a particular timestep. If REPEat is used the LOGLevel may be specified
to limit the number of exchanges written to this file. If LOGLevel is set
to N, every Nth exchange at a given step is written, however, the first
and last exchange is always written. NB, this only applies when the
REPEat key word is used, and at least one exchange at each time step
is always written.
Currently, FAST is only compatible with temperature replica exchange
without the use of a reservoir.
The FAST keyword turns on "fast" replica exchange (1D, temperature exchange
only). When this option is activated, all exchange decisions are made on
processor 0, and new temperatures are sent to each individual replica,
as opposed to sending coordinates and velocities between replicas.
This method requires substantially less communication, especially when
the REPEat keyword is used. The drawback is that the outputs are per-replica
rather than per-temperature. Additional functionality has been added to the
MERGE command (» dynamc ) to convert per-replica trajectories
to per-temperature.
Additionally, since all decisions are made on processor 0, only a single
exchange file is written out, showing the results of ALL exchanges at
a particular timestep. If REPEat is used the LOGLevel may be specified
to limit the number of exchanges written to this file. If LOGLevel is set
to N, every Nth exchange at a given step is written, however, the first
and last exchange is always written. NB, this only applies when the
REPEat key word is used, and at least one exchange at each time step
is always written.
Currently, FAST is only compatible with temperature replica exchange
without the use of a reservoir.
Top
NOTE: If you are using mpich-1.2.X then you need to use -p4wd with the
absolute path or -p4wd `pwd`
Example 1:
==========
read psf
read coor
repd nrep 4
This will replicate PSF and coordinates, so after nrep 4 there are
four independent runs with the same coordinates
Example 2:
==========
read psf
repd nrep 4
read coor name system.crd
This will replicate PSF but the coordinates will be read from 4
separate files: system.crd_0, system.crd_1, etc
Example 3:
==========
repd nrep 4
stre inp
This will run for independent CHARMM jobs. Each inp_0, inp_1, inp_3,
and inp_4 can be different input files, with different PSFs,
parameters, etc
Example 4:
==========
open write unit 1 card name out
repd nrep 4
outu 1
stre inp
The same as example 3 but now also output files out_0, out_1, ... will
be written. Note that OUTU must precede STREam command.
Example 5: RXSGLD
==========
read psf
read coor name system.crd
!All stages have the same temperature of 300 K but have TEMPSG from 300 K to 500 K.
repd nrep 8 EXCHange FREQuency 1000 STEMp 300 DTEMp 0 -
SGLD SGTE 300 MSGT 500 DSGF 0.2
SCAL FBETA SET 1.0 SELE ALL END
!Perform SGLD with SGFT set to 0 to allow above RXSGLD setting in control
DYNA LANG SGLD SGFT 0
NOTE: If you are using mpich-1.2.X then you need to use -p4wd with the
absolute path or -p4wd `pwd`
Example 1:
==========
read psf
read coor
repd nrep 4
This will replicate PSF and coordinates, so after nrep 4 there are
four independent runs with the same coordinates
Example 2:
==========
read psf
repd nrep 4
read coor name system.crd
This will replicate PSF but the coordinates will be read from 4
separate files: system.crd_0, system.crd_1, etc
Example 3:
==========
repd nrep 4
stre inp
This will run for independent CHARMM jobs. Each inp_0, inp_1, inp_3,
and inp_4 can be different input files, with different PSFs,
parameters, etc
Example 4:
==========
open write unit 1 card name out
repd nrep 4
outu 1
stre inp
The same as example 3 but now also output files out_0, out_1, ... will
be written. Note that OUTU must precede STREam command.
Example 5: RXSGLD
==========
read psf
read coor name system.crd
!All stages have the same temperature of 300 K but have TEMPSG from 300 K to 500 K.
repd nrep 8 EXCHange FREQuency 1000 STEMp 300 DTEMp 0 -
SGLD SGTE 300 MSGT 500 DSGF 0.2
SCAL FBETA SET 1.0 SELE ALL END
!Perform SGLD with SGFT set to 0 to allow above RXSGLD setting in control
DYNA LANG SGLD SGFT 0
Top
The replica exchange printout is written to the unit specified in
the command after the UNIT keyword. The output of the current results
is labeled by either REX> for temperature based replica exchange or
RXSG> for self-guding replica exchange (RXSGLD). The RXSG> line contains the
following fields:
RXSG> Exchanges DynSteps StagID NeighborID ReplicaID Ep EpNeighbor
TempScale TSGScale AcceptRatio Acceptance
A summary from all other
replicas is labeled by REXSUM>. The labels in the output are
shortened, end the meaning of some of them is as the following:
Epot - potential energy (current)
Tscale - temperature scaling for exchange [Tscale=sqrt(Temp/NewTemp)]
Sratio - success ratio [Srate=#-of-successful-exchanges/#-of-tried-exchanges]
NewTemp - new temperature after the exchange
CurrTemp - current temperature
PROB - probability to perform exchange P=exp(-Delta(1/kT)*Delta(Epot))
Rand - random number used for exchange condition PROB>Rand => Success=T
NEIGHBOR - current neighbor with which the exchange occurs (or not)
The replica exchange printout is written to the unit specified in
the command after the UNIT keyword. The output of the current results
is labeled by either REX> for temperature based replica exchange or
RXSG> for self-guding replica exchange (RXSGLD). The RXSG> line contains the
following fields:
RXSG> Exchanges DynSteps StagID NeighborID ReplicaID Ep EpNeighbor
TempScale TSGScale AcceptRatio Acceptance
A summary from all other
replicas is labeled by REXSUM>. The labels in the output are
shortened, end the meaning of some of them is as the following:
Epot - potential energy (current)
Tscale - temperature scaling for exchange [Tscale=sqrt(Temp/NewTemp)]
Sratio - success ratio [Srate=#-of-successful-exchanges/#-of-tried-exchanges]
NewTemp - new temperature after the exchange
CurrTemp - current temperature
PROB - probability to perform exchange P=exp(-Delta(1/kT)*Delta(Epot))
Rand - random number used for exchange condition PROB>Rand => Success=T
NEIGHBOR - current neighbor with which the exchange occurs (or not)