Selection syntax and usage¶
Selections are used to select atoms/molecules/residues for analysis. In contrast to traditional index files, selections can be dynamic, i.e., select different atoms for different trajectory frames. The GROMACS manual contains a short introductory section to selections in the Analysis chapter, including suggestions on how to get familiar with selections if you are new to the concept. The subtopics listed below provide more details on the technical and syntactic aspects of selections.
Each analysis tool requires a different number of selections and the selections are interpreted differently. The general idea is still the same: each selection evaluates to a set of positions, where a position can be an atom position or center-of-mass or center-of-geometry of a set of atoms. The tool then uses these positions for its analysis to allow very flexible processing. Some analysis tools may have limitations on the types of selections allowed.
Specifying selections from command line¶
If no selections are provided on the command line, you are prompted to type the selections interactively (a pipe can also be used to provide the selections in this case for most tools). While this works well for testing, it is easier to provide the selections from the command line if they are complex or for scripting.
Each tool has different command-line arguments for specifying selections (see the help for the individual tools). You can either pass a single string containing all selections (separated by semicolons), or multiple strings, each containing one selection. Note that you need to quote the selections to protect them from the shell.
If you set a selection command-line argument, but do not provide any selections, you are prompted to type the selections for that argument interactively. This is useful if that selection argument is optional, in which case it is not normally prompted for.
To provide selections from a file, use -sf file.dat
in the place
of the selection for a selection argument (e.g.,
-select -sf file.dat
). In general, the -sf
argument reads
selections from the provided file and assigns them to selection arguments
that have been specified up to that point, but for which no selections
have been provided.
As a special case, -sf
provided on its own, without preceding
selection arguments, assigns the selections to all (yet unset) required
selections (i.e., those that would be prompted interactively if no
selections are provided on the command line).
To use groups from a traditional index file, use argument -n
to provide a file. See the “syntax” subtopic for how to use them.
If this option is not provided, default groups are generated.
The default groups are generated with the same logic as for
non-selection tools.
Depending on the tool, two additional command-line arguments may be available to control the behavior:
-seltype
can be used to specify the default type of positions to calculate for each selection.-selrpos
can be used to specify the default type of positions used in selecting atoms by coordinates.
See the “positions” subtopic for more information on these options.
Tools that take selections apply them to a structure/topology and/or
a trajectory file. If the tool takes both (typically as -s
for structure/topology and -f
for trajectory), then the
trajectory file is only used for coordinate information, and all other
information, such as atom names and residue information, is read from
the structure/topology file. If the tool only takes a structure file,
or if only that input parameter is provided, then also the coordinates
are taken from that file.
For example, to select atoms from a .pdb
/.gro
file in
a tool that provides both options, pass it as -s
(only).
There is no warning if the trajectory file specifies, e.g., different
atom names than the structure file. Only the number of atoms is checked.
Many selection-enabled tools also provide an -fgroup
option
to specify the atom indices that are present in the trajectory for cases
where the trajectory only has a subset of atoms from the
topology/structure file.
Selection syntax¶
A set of selections consists of one or more selections, separated by semicolons. Each selection defines a set of positions for the analysis. Each selection can also be preceded by a string that gives a name for the selection for use in, e.g., graph legends. If no name is provided, the string used for the selection is used automatically as the name.
For interactive input, the syntax is slightly altered: line breaks can also be used to separate selections. followed by a line break can be used to continue a line if necessary. Notice that the above only applies to real interactive input, not if you provide the selections, e.g., from a pipe.
It is possible to use variables to store selection expressions. A variable is defined with the following syntax:
VARNAME = EXPR ;
where EXPR
is any valid selection expression.
After this, VARNAME
can be used anywhere where EXPR
would be valid.
Selections are composed of three main types of expressions, those that
define atoms (ATOM_EXPR
), those that define positions
(POS_EXPR
), and those that evaluate to numeric values
(NUM_EXPR
). Each selection should be a POS_EXPR
or a ATOM_EXPR
(the latter is automatically converted to
positions). The basic rules are as follows:
An expression like
NUM_EXPR1 < NUM_EXPR2
evaluates to anATOM_EXPR
that selects all the atoms for which the comparison is true.Atom expressions can be combined with boolean operations such as
not ATOM_EXPR
,ATOM_EXPR and ATOM_EXPR
, orATOM_EXPR or ATOM_EXPR
. Parentheses can be used to alter the evaluation order.ATOM_EXPR
expressions can be converted intoPOS_EXPR
expressions in various ways, see the “positions” subtopic for more details.POS_EXPR
can be converted intoNUM_EXPR
using syntax like “x of POS_EXPR
”. Currently, this is only supported for single positions like in expression “x of cog of ATOM_EXPR
”.
Some keywords select atoms based on string values such as the atom name.
For these keywords, it is possible to use wildcards (name "C*"
)
or regular expressions (e.g., resname "R[AB]"
).
The match type is automatically guessed from the string: if it contains
other characters than letters, numbers, ‘*’, or ‘?’, it is interpreted
as a regular expression.
To force the matching to use literal string matching, use
name = "C*"
to match a literal C*.
To force other type of matching, use ‘?’ or ‘~’ in place of ‘=’ to force
wildcard or regular expression matching, respectively.
Strings that contain non-alphanumeric characters should be enclosed in double quotes as in the examples. For other strings, the quotes are optional, but if the value conflicts with a reserved keyword, a syntax error will occur. If your strings contain uppercase letters, this should not happen.
Index groups provided with the -n
command-line option or
generated by default can be accessed with group NR
or
group NAME
, where NR
is a zero-based index of the group
and NAME
is part of the name of the desired group.
The keyword group
is optional if the whole selection is
provided from an index group.
To see a list of available groups in the interactive mode, press enter
in the beginning of a line.
Specifying positions in selections¶
Possible ways of specifying positions in selections are:
A constant position can be defined as
[XX, YY, ZZ]
, whereXX
,YY
andZZ
are real numbers.com of ATOM_EXPR [pbc]
orcog of ATOM_EXPR [pbc]
calculate the center of mass/geometry ofATOM_EXPR
. Ifpbc
is specified, the center is calculated iteratively to try to deal with cases whereATOM_EXPR
wraps around periodic boundary conditions.POSTYPE of ATOM_EXPR
calculates the specified positions for the atoms inATOM_EXPR
.POSTYPE
can beatom
,res_com
,res_cog
,mol_com
ormol_cog
, with an optional prefixwhole_
part_
ordyn_
.whole_
calculates the centers for the whole residue/molecule, even if only part of it is selected.part_
prefix calculates the centers for the selected atoms, but uses always the same atoms for the same residue/molecule. The used atoms are determined from the largest group allowed by the selection.dyn_
calculates the centers strictly only for the selected atoms. If no prefix is specified, whole selections default topart_
and other places default towhole_
. The latter is often desirable to select the same molecules in different tools, while the first is a compromise between speed (dyn_
positions can be slower to evaluate thanpart_
) and intuitive behavior.ATOM_EXPR
, when given for whole selections, is handled as 3. above, using the position type from the command-line argument-seltype
.
Selection keywords that select atoms based on their positions, such as
dist from
, use by default the positions defined by the
-selrpos
command-line option.
This can be overridden by prepending a POSTYPE
specifier to the
keyword. For example, res_com dist from POS
evaluates the
residue center of mass distances. In the example, all atoms of a residue
are either selected or not, based on the single distance calculated.
Arithmetic expressions in selections¶
Basic arithmetic evaluation is supported for numeric expressions. Supported operations are addition, subtraction, negation, multiplication, division, and exponentiation (using ^). Result of a division by zero or other illegal operations is undefined.
Selection keywords¶
The following selection keywords are currently available. For keywords marked with a plus, additional help is available through a subtopic KEYWORD, where KEYWORD is the name of the keyword.
Keywords that select atoms by an integer property:
atomnr mol (synonym for molindex) molecule (synonym for molindex) molindex resid (synonym for resnr) residue (synonym for resindex) resindex resnr
(use in expressions or like “atomnr 1 to 5 7 9”)
Keywords that select atoms by a numeric property:
beta (synonym for betafactor) betafactor charge distance from POS [cutoff REAL] distance from POS [cutoff REAL] mass mindistance from POS_EXPR [cutoff REAL] mindistance from POS_EXPR [cutoff REAL] occupancy x y z
(use in expressions or like “occupancy 0.5 to 1”)
Keywords that select atoms by a string property:
altloc atomname atomtype chain insertcode name (synonym for atomname) pdbatomname pdbname (synonym for pdbatomname) resname type (synonym for atomtype)
(use like “name PATTERN [PATTERN] …”)
Additional keywords that directly select atoms:
all insolidangle center POS span POS_EXPR [cutoff REAL] none same KEYWORD as ATOM_EXPR within REAL of POS_EXPR
Keywords that directly evaluate to positions:
cog of ATOM_EXPR [pbc] com of ATOM_EXPR [pbc]
(see also “positions” subtopic)
Additional keywords:
merge POSEXPR POSEXPR permute P1 ... PN plus POSEXPR
Selecting atoms by name - atomname, name, pdbatomname, pdbname¶
name
pdbname
atomname
pdbatomname
These keywords select atoms by name. name
selects atoms using
the GROMACS atom naming convention.
For input formats other than PDB, the atom names are matched exactly
as they appear in the input file. For PDB files, 4 character atom names
that start with a digit are matched after moving the digit to the end
(e.g., to match 3HG2 from a PDB file, use name HG23
).
pdbname
can only be used with a PDB input file, and selects
atoms based on the exact name given in the input file, without the
transformation described above.
atomname
and pdbatomname
are synonyms for the above two
keywords.
Selecting based on distance - dist, distance, mindist, mindistance, within¶
distance from POS [cutoff REAL]
mindistance from POS_EXPR [cutoff REAL]
within REAL of POS_EXPR
distance
and mindistance
calculate the distance from the
given position(s), the only difference being in that distance
only accepts a single position, while any number of positions can be
given for mindistance
, which then calculates the distance to the
closest position.
within
directly selects atoms that are within REAL
of
POS_EXPR
.
For the first two keywords, it is possible to specify a cutoff to speed up the evaluation: all distances above the specified cutoff are returned as equal to the cutoff.
Selecting atoms in a solid angle - insolidangle¶
insolidangle center POS span POS_EXPR [cutoff REAL]
This keyword selects atoms that are within REAL
degrees
(default=5) of any position in POS_EXPR
as seen from POS
a position expression that evaluates to a single position), i.e., atoms
in the solid angle spanned by the positions in POS_EXPR
and
centered at POS
.
Technically, the solid angle is constructed as a union of small cones
whose tip is at POS
and the axis goes through a point in
POS_EXPR
. There is such a cone for each position in
POS_EXPR
, and point is in the solid angle if it lies within any
of these cones. The cutoff determines the width of the cones.
Merging selections - merge, plus¶
POSEXPR merge POSEXPR [stride INT]
POSEXPR merge POSEXPR [merge POSEXPR ...]
POSEXPR plus POSEXPR [plus POSEXPR ...]
Basic selection keywords can only create selections where each atom
occurs at most once. The merge
and plus
selection
keywords can be used to work around this limitation. Both create
a selection that contains the positions from all the given position
expressions, even if they contain duplicates.
The difference between the two is that merge
expects two or more
selections with the same number of positions, and the output contains
the input positions selected from each expression in turn, i.e.,
the output is like A1 B1 A2 B2 and so on. It is also possible to merge
selections of unequal size as long as the size of the first is a
multiple of the second one. The stride
parameter can be used
to explicitly provide this multiplicity.
plus
simply concatenates the positions after each other, and
can work also with selections of different sizes.
These keywords are valid only at the selection level, not in any
subexpressions.
Permuting selections - permute¶
permute P1 ... PN
By default, all selections are evaluated such that the atom indices are
returned in ascending order. This can be changed by appending
permute P1 P2 ... PN
to an expression.
The Pi
should form a permutation of the numbers 1 to N.
This keyword permutes each N-position block in the selection such that
the i’th position in the block becomes Pi’th.
Note that it is the positions that are permuted, not individual atoms.
A fatal error occurs if the size of the selection is not a multiple of n.
It is only possible to permute the whole selection expression, not any
subexpressions, i.e., the permute
keyword should appear last in
a selection.
Selecting atoms by residue number - resid, residue, resindex, resnr¶
resnr
resid
resindex
residue
resnr
selects atoms using the residue numbering in the input
file. resid
is synonym for this keyword for VMD compatibility.
resindex N
selects the N
th residue starting from the
beginning of the input file. This is useful for uniquely identifying
residues if there are duplicate numbers in the input file (e.g., in
multiple chains).
residue
is a synonym for resindex
. This allows
same residue as
to work as expected.
Extending selections - same¶
same KEYWORD as ATOM_EXPR
The keyword same
can be used to select all atoms for which
the given KEYWORD
matches any of the atoms in ATOM_EXPR
.
Keywords that evaluate to integer or string values are supported.
Selection evaluation and optimization¶
Boolean evaluation proceeds from left to right and is short-circuiting i.e., as soon as it is known whether an atom will be selected, the remaining expressions are not evaluated at all. This can be used to optimize the selections: you should write the most restrictive and/or the most inexpensive expressions first in boolean expressions. The relative ordering between dynamic and static expressions does not matter: all static expressions are evaluated only once, before the first frame, and the result becomes the leftmost expression.
Another point for optimization is in common subexpressions: they are not automatically recognized, but can be manually optimized by the use of variables. This can have a big impact on the performance of complex selections, in particular if you define several index groups like this:
rdist = distance from com of resnr 1 to 5;
resname RES and rdist < 2;
resname RES and rdist < 4;
resname RES and rdist < 6;
Without the variable assignment, the distances would be evaluated three times, although they are exactly the same within each selection. Anything assigned into a variable becomes a common subexpression that is evaluated only once during a frame. Currently, in some cases the use of variables can actually lead to a small performance loss because of the checks necessary to determine for which atoms the expression has already been evaluated, but this should not be a major problem.
Selection limitations¶
Some analysis programs may require a special structure for the input selections (e.g., some options of
gmx gangle
require the index group to be made of groups of three or four atoms). For such programs, it is up to the user to provide a proper selection expression that always returns such positions.All selection keywords select atoms in increasing order, i.e., you can consider them as set operations that in the end return the atoms in sorted numerical order. For example, the following selections select the same atoms in the same order:
resname RA RB RC resname RB RC RA
atomnr 10 11 12 13 atomnr 12 13 10 11 atomnr 10 to 13 atomnr 13 to 10
If you need atoms/positions in a different order, you can:
use external index groups (for some static selections),
use the
permute
keyword to change the final order, oruse the
merge
orplus
keywords to compose the final selection from multiple distinct selections.
Due to technical reasons, having a negative value as the first value in expressions like
charge -1 to -0.7
result in a syntax error. A workaround is to write
charge {-1 to -0.7}
instead.
When
name
selection keyword is used together with PDB input files, the behavior may be unintuitive. When GROMACS reads in a PDB file, 4 character atom names that start with a digit are transformed such that, e.g., 1HG2 becomes HG21, and the latter is what is matched by thename
keyword. Usepdbname
to match the atom name as it appears in the input PDB file.
Selection examples¶
Below, examples of different types of selections are given.
Selection of all water oxygens:
resname SOL and name OW
Centers of mass of residues 1 to 5 and 10:
res_com of resnr 1 to 5 10
All atoms farther than 1 nm of a fixed position:
not within 1 of [1.2, 3.1, 2.4]
All atoms of a residue LIG within 0.5 nm of a protein (with a custom name):
"Close to protein" resname LIG and within 0.5 of group "Protein"
All protein residues that have at least one atom within 0.5 nm of a residue LIG:
group "Protein" and same residue as within 0.5 of resname LIG
All RES residues whose COM is between 2 and 4 nm from the COM of all of them:
rdist = res_com distance from com of resname RES resname RES and rdist >= 2 and rdist <= 4
Selection like with duplicate atoms like C1 C2 C2 C3 C3 C4 … C8 C9:
name "C[1-8]" merge name "C[2-9]"
This can be used with
gmx distance
to compute C1-C2, C2-C3 etc. distances.Selection with atoms in order C2 C1:
name C1 C2 permute 2 1
This can be used with
gmx gangle
to get C2->C1 vectors instead of C1->C2.Selection with COMs of two index groups:
com of group 1 plus com of group 2
This can be used with
gmx distance
to compute the distance between these two COMs.Fixed vector along x (can be used as a reference with
gmx gangle
):[0, 0, 0] plus [1, 0, 0]
The following examples explain the difference between the various position types. This selection selects a position for each residue where any of the three atoms C[123] has
x < 2
. The positions are computed as the COM of all three atoms. This is the default behavior if you just writeres_com of
.part_res_com of name C1 C2 C3 and x < 2
This selection does the same, but the positions are computed as COM positions of whole residues:
whole_res_com of name C1 C2 C3 and x < 2
Finally, this selection selects the same residues, but the positions are computed as COM of exactly those atoms atoms that match the
x < 2
criterion:dyn_res_com of name C1 C2 C3 and x < 2
Without the
of
keyword, the default behavior is different from above, but otherwise the rules are the same:name C1 C2 C3 and res_com x < 2
works as if
whole_res_com
was specified, and selects the three atoms from residues whose COM satisfiexx < 2
. Usingname C1 C2 C3 and part_res_com x < 2
instead selects residues based on the COM computed from the C[123] atoms.