forked from lijiext/lammps
260 lines
11 KiB
Plaintext
260 lines
11 KiB
Plaintext
"LAMMPS WWW Site"_lws - "LAMMPS Documentation"_ld - "LAMMPS Commands"_lc :c
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:link(lws,http://lammps.sandia.gov)
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:link(ld,Manual.html)
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:link(lc,Section_commands.html#comm)
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:line
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fix balance command :h3
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[Syntax:]
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fix ID group-ID balance Nfreq dimstr Niter thresh keyword value ... :pre
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ID, group-ID are documented in "fix"_fix.html command :ulb,l
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balance = style name of this fix command :l
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Nfreq = perform dynamic load balancing every this many steps :l
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dimstr = sequence of letters containing "x" or "y" or "z", each not more than once :l
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Niter = # of times to iterate within each dimension of dimstr sequence :l
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thresh = stop balancing when this imbalance threshhold is reached :l
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zero or more keyword/arg pairs may be appended :ule,l
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keyword = {out} :l
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{out} arg = filename
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filename = output file to write each processor's sub-domain to :pre
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:ule
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[Examples:]
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fix 2 all balance 1000 x 10 1.05
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fix 2 all balance 0 xy 20 1.1 out tmp.balance :pre
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[Description:]
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This command adjusts the size of processor sub-domains within the
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simulation box dynamically as a simulation runs, to attempt to balance
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the number of particles and thus the computational cost (load) evenly
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across processors. The load balancing is "dynamic" in the sense that
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rebalancing is performed periodically during the simulation. To
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perform "static" balancing, before of between runs, see the
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"balance"_balance.html command.
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Load-balancing is only useful if the particles in the simulation box
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have a spatially-varying density distribution. E.g. a model of a
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vapor/liquid interface, or a solid with an irregular-shaped geometry
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containing void regions. In this case, the LAMMPS default of dividing
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the simulation box volume into a regular-spaced grid of processor
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sub-domain, with one equal-volume sub-domain per procesor, may assign
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very different numbers of particles per processor. This can lead to
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poor performance in a scalability sense, when the simulation is run in
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parallel.
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Note that the "processors"_processors.html command gives you some
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control over how the box volume is split across
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processors. Specifically, for a Px by Py by Pz grid of processors, it
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lets you choose Px, Py, and Pz, subject to the constraint that Px * Py
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* Pz = P, the total number of processors. This can be sufficient to
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achieve good load-balance for some models on some processor
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counts. However, all the processor sub-domains will still be the same
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shape and have the same volume.
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This command does not alter the topology of the Px by Py by Pz grid or
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processors. But it shifts the cutting planes between processors (in
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3d, or lines in 2d), which adjusts the volume (area in 2d) assigned to
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each processor, as in the following 2d diagram. The left diagram is
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the default partitioning of the simulation box across processors (one
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sub-box for each of 16 processors); the right diagram is after
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balancing.
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:c,image(JPG/balance.jpg)
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IMPORTANT NOTE: This command attempts to minimize the imbalance
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factor, as defined above. But because of the topology constraint that
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only the cutting planes (lines) between processors are moved, there
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are many irregular distributions of particles, where this factor
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cannot be shrunk to 1.0, particuarly in 3d. Also, computational cost
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is not strictly proportional to particle count, and changing the
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relative size and shape of processor sub-domains may lead to
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additional computational and communication overheads, e.g. in the PPPM
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solver used via the "kspace_style"_kspace_style.html command. Thus
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you should benchmark the run times of your simulation with and without
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balancing.
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:line
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The {group-ID} is currently ignored. In the future it may be used to
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determine what particles are considered for balancing. Normally it
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would only makes sense to use the {all} group. But in some cases it
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may be useful to balance on a subset of the particles, e.g. when
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modeling large nanoparticles in a background of small solvent
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particles.
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The {Nfreq} setting determines how often a rebalance is performed. If
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{Nfreq} > 0, then rebalancing will occur every {Nfreq} steps. Each
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time a rebalance occurs, a reneighboring is triggered, so you should
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not make {Nfreq} too small. If {Nfreq} = 0, then rebalancing will be
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done every time reneighboring normally occurs, as determined by the
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the "neighbor"_neighbor.html and "neigh_modify"_neigh_modify.html
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command settings.
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On rebalance steps, rebalancing will only be attempted if the current
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imbalance factor, as defined above, exceeds the {thresh} setting.
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The {dimstr} argument is a string of characters, each of which must be
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an "x" or "y" or "z". Eacn character can appear zero or one time,
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since there is no advantage to balancing on a dimension more than
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once. You should normally only list dimensions where you expect there
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to be a density variation in the particles.
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Balancing proceeds by adjusting the cutting planes in each of the
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dimensions listed in {dimstr}, one dimension at a time. For a single
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dimension, the balancing operation (described below) is iterated on up
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to {Niter} times. After each dimension finishes, the imbalance factor
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is re-computed, and the balancing operation halts if the {thresh}
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criterion is met.
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A rebalance operation in a single dimension is performed using a
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density-dependent recursive multisectioning algorithm, where the
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position of each cutting plane (line in 2d) in the dimension is
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adjusted independently. This is similar to a recursive bisectioning
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(RCB) for a single value, except that the bounds used for each
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bisectioning take advantage of information from neighboring cuts if
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possible, as well as counts of particles at the bounds on either side
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of each cuts, which themselves were cuts in previous iterations. The
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latter is used to infer a density of pariticles near each of the
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current cuts. At each iteration, the count of particles on either
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side of each plane is tallied. If the counts do not match the target
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value for the plane, the position of the cut is adjusted based on the
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local density. The low and high bounds are adjusted on each
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iteration, using new count information, so that they become closer
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together over time. Thus as the recustion progresses, the count of
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particles on either side of the plane gets closer to the target value.
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The density-dependent part of this algorithm is often an advantage
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when you rebalance a system that is already nearly balanced. It
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typically converges more quickly than the geometric bisectioning
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algorithm used by the "balance"_balance.html command. However, if can
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be a disadvants if you attempt to rebalance a system that is far from
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balanced, and converge more slowly. In this case you probably want to
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use the "balance"_balance.html command before starting a run, so that
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you begin the run with a balanced system.
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Once the rebalancing is complete and final processor sub-domains
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assigned, particles migrate to their new owning processor as part of
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the normal reneighboring procedure.
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IMPORTANT NOTE: At each rebalance operation, the RCB operation for
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each cutting plane (line in 2d) typcially starts with low and high
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bounds separated by the extent of a processor's sub-domain in one
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dimension. The size of this bracketing region shrinks based on the
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local density, as described above, which should typically be 1/2 or
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more every iteration. Thus if {Niter} is specified as 10, the cutting
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plane will typically be positioned to better than 1 part in 1000
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accuracy (relative to the perfect target position). For {Niter} = 20,
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it will be accurate to better than 1 part in a million. Thus there is
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no need to set {Niter} to a large value. This is especially true if
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you are rebalancing often enough that each time you expect only an
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incremental adjustement in the cutting planes is necessary. LAMMPS
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will check if the threshold accuracy is reached (in a dimension) is
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less iterations than {Niter} and exit early.
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IMPORTANT NOTE: If a portion of your system is a perfect lattice,
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e.g. a frozen substrate, then the balancer may be unable to achieve
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exact balance. I.e. entire lattice planes will be owned or not owned
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by a single processor. So you you should not expect to achieve
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perfect balance in this case. Nor will it be helpful to use a large
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value for {Niter}, since it will simply cause the balancer to iterate
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until {Niter} is reached, without improving the imbalance factor.
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:line
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The {out} keyword writes a text file to the specified {filename} with
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the results of each rebalancing operation. The file contains the
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bounds of the sub-domain for each processor after the balancing
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operation completes. The format of the file is compatible with the
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"Pizza.py"_pizza {mdump} tool which has support for manipulating and
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visualizing mesh files. An example is shown here for a balancing by 4
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processors for a 2d problem:
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ITEM: TIMESTEP
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1000
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ITEM: NUMBER OF SQUARES
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4
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ITEM: SQUARES
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1 1 1 2 7 6
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2 2 2 3 8 7
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3 3 3 4 9 8
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4 4 4 5 10 9
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ITEM: TIMESTEP
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1000
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ITEM: NUMBER OF NODES
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10
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ITEM: BOX BOUNDS
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-153.919 184.703
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0 15.3919
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-0.769595 0.769595
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ITEM: NODES
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1 1 -153.919 0 0
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2 1 7.45545 0 0
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3 1 14.7305 0 0
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4 1 22.667 0 0
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5 1 184.703 0 0
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6 1 -153.919 15.3919 0
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7 1 7.45545 15.3919 0
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8 1 14.7305 15.3919 0
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9 1 22.667 15.3919 0
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10 1 184.703 15.3919 0 :pre
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The "SQUARES" lists the node IDs of the 4 vertices in a rectangle for
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each processor (1 to 4). The first SQUARE 1 (for processor 0) is a
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rectangle of type 1 (equal to SQUARE ID) and contains vertices
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1,2,7,6. The coordinates of all the vertices are listed in the NODES
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section. Note that the 4 sub-domains share vertices, so there are
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only 10 unique vertices in total.
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For a 3d problem, the syntax is similar with "SQUARES" replaced by
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"CUBES", and 8 vertices listed for each processor, instead of 4.
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Each time rebalancing is performed a new timestamp is written with new
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NODES values. The SQUARES of CUBES sections are not repeated, since
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they do not change.
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:line
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[Restart, fix_modify, output, run start/stop, minimize info:]
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No information about this fix is written to "binary restart
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files"_restart.html. None of the "fix_modify"_fix_modify.html options
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are relevant to this fix.
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This fix computes a global scalar which is the imbalance factor
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after the most recent rebalance and a global vector of length 3 with
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additional information about the most recent rebalancing. The 3
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values in the vector are as follows:
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1 = max # of particles per processor
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2 = total # iterations performed in last rebalance
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3 = imbalance factor right before the last rebalance was performed :ul
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As explained above, the imbalance factor is the ratio of the maximum
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number of particles on any processor to the average number of
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particles per processor.
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These quantities can be accessed by various "output
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commands"_Section_howto.html#howto_15. The scalar and vector values
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calculated by this fix are "intensive".
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No parameter of this fix can be used with the {start/stop} keywords of
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the "run"_run.html command. This fix is not invoked during "energy
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minimization"_minimize.html.
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:line
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[Restrictions:] none
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[Related commands:]
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"processors"_processors.html, "balance"_balance.html
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[Default:] none
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