# -*- Mode: python; tab-width: 4; indent-tabs-mode:nil; coding:utf-8 -*-
# vim: tabstop=4 expandtab shiftwidth=4 softtabstop=4
#
# MDAnalysis --- https://www.mdanalysis.org
# Copyright (c) 2006-2017 The MDAnalysis Development Team and contributors
# (see the file AUTHORS for the full list of names)
#
# Released under the GNU Public Licence, v2 or any higher version
#
# Please cite your use of MDAnalysis in published work:
#
# R. J. Gowers, M. Linke, J. Barnoud, T. J. E. Reddy, M. N. Melo, S. L. Seyler,
# D. L. Dotson, J. Domanski, S. Buchoux, I. M. Kenney, and O. Beckstein.
# MDAnalysis: A Python package for the rapid analysis of molecular dynamics
# simulations. In S. Benthall and S. Rostrup editors, Proceedings of the 15th
# Python in Science Conference, pages 102-109, Austin, TX, 2016. SciPy.
# doi: 10.25080/majora-629e541a-00e
#
# N. Michaud-Agrawal, E. J. Denning, T. B. Woolf, and O. Beckstein.
# MDAnalysis: A Toolkit for the Analysis of Molecular Dynamics Simulations.
# J. Comput. Chem. 32 (2011), 2319--2327, doi:10.1002/jcc.21787
#
"""
Helper functions --- :mod:`MDAnalysis.lib.util`
====================================================
Small helper functions that don't fit anywhere else.
.. versionchanged:: 0.11.0
Moved mathematical functions into lib.mdamath
Files and directories
---------------------
.. autofunction:: filename
.. autofunction:: openany
.. autofunction:: anyopen
.. autofunction:: greedy_splitext
.. autofunction:: which
.. autofunction:: realpath
.. autofunction:: get_ext
.. autofunction:: check_compressed_format
.. autofunction:: format_from_filename_extension
.. autofunction:: guess_format
Streams
-------
Many of the readers are not restricted to just reading files. They can
also use gzip-compressed or bzip2-compressed files (through the
internal use of :func:`openany`). It is also possible to provide more
general streams as inputs, such as a :func:`cStringIO.StringIO`
instances (essentially, a memory buffer) by wrapping these instances
into a :class:`NamedStream`. This :class:`NamedStream` can then be
used in place of an ordinary file name (typically, with a
class:`~MDAnalysis.core.universe.Universe` but it is also possible to
*write* to such a stream using :func:`MDAnalysis.Writer`).
.. rubric: Examples
In the following example, we use a PDB stored as a string ``pdb_s``::
import MDAnalysis
from MDAnalysis.lib.util import NamedStream
import cStringIO
pdb_s = "TITLE Lonely Ion\\nATOM 1 NA NA+ 1 81.260 64.982 10.926 1.00 0.00\\n"
u = MDAnalysis.Universe(NamedStream(cStringIO.StringIO(pdb_s), "ion.pdb"))
print(u)
# <Universe with 1 atoms>
print(u.atoms.positions)
# [[ 81.26000214 64.98200226 10.92599964]]
It is important to provide a proper pseudo file name with the correct extension
(".pdb") to :class:`NamedStream` because the file type recognition uses the
extension of the file name to determine the file format or alternatively
provide the ``format="pdb"`` keyword argument to the
:class:`~MDAnalysis.core.universe.Universe`.
The use of streams becomes more interesting when MDAnalysis is used as glue
between different analysis packages and when one can arrange things so that
intermediate frames (typically in the PDB format) are not written to disk but
remain in memory via e.g. :mod:`cStringIO` buffers.
.. The following does *not* work because most readers need to
.. reopen files, which is not possible with http streams. Might
.. need to implement a buffer.
..
.. Read a test LAMMPS data file from the MDAnalysis repository::
..
.. import MDAnalysis
.. from MDAnalysis.lib.util import NamedStream
.. import urllib2
.. URI = "https://mdanalysis.googlecode.com/git-history/develop/testsuite/MDAnalysisTests/data/mini.data"
.. urldata = NamedStream(urllib2.urlopen(URI), "mini.data")
.. u = MDAnalysis.Universe(urldata)
.. Note:: A remote connection created by :func:`urllib2.urlopen` is not seekable
and therefore will often not work as an input. But try it...
.. autoclass:: NamedStream
:members:
.. autofunction:: isstream
Containers and lists
--------------------
.. autofunction:: iterable
.. autofunction:: asiterable
.. autofunction:: hasmethod
.. autoclass:: Namespace
Arrays
------
.. autofunction:: unique_int_1d(values)
.. autofunction:: unique_rows
.. autofunction:: blocks_of
File parsing
------------
.. autoclass:: FORTRANReader
:members:
.. autodata:: FORTRAN_format_regex
Data manipulation and handling
------------------------------
.. autofunction:: fixedwidth_bins
.. autofunction:: get_weights
.. autofunction:: ltruncate_int
.. autofunction:: flatten_dict
Strings
-------
.. autofunction:: convert_aa_code
.. autofunction:: parse_residue
.. autofunction:: conv_float
Class decorators
----------------
.. autofunction:: cached
Function decorators
-------------------
.. autofunction:: static_variables
.. autofunction:: warn_if_not_unique
.. autofunction:: check_coords
Code management
---------------
.. autofunction:: deprecate
.. autoclass:: _Deprecate
.. autofunction:: dedent_docstring
Data format checks
------------------
.. autofunction:: check_box
.. Rubric:: Footnotes
.. [#NamedStreamClose] The reason why :meth:`NamedStream.close` does
not close a stream by default (but just rewinds it to the
beginning) is so that one can use the class :class:`NamedStream` as
a drop-in replacement for file names, which are often re-opened
(e.g. when the same file is used as a topology and coordinate file
or when repeatedly iterating through a trajectory in some
implementations). The ``close=True`` keyword can be supplied in
order to make :meth:`NamedStream.close` actually close the
underlying stream and ``NamedStream.close(force=True)`` will also
close it.
"""
from __future__ import division, absolute_import
import six
from six.moves import range, map
import sys
__docformat__ = "restructuredtext en"
import os
import os.path
import errno
from contextlib import contextmanager
import bz2
import gzip
import re
import io
import warnings
import functools
from functools import wraps
import textwrap
import mmtf
import numpy as np
from numpy.testing import assert_equal
import inspect
from ..exceptions import StreamWarning, DuplicateWarning
try:
from ._cutil import unique_int_1d
except ImportError:
raise ImportError("MDAnalysis not installed properly. "
"This can happen if your C extensions "
"have not been built.")
# Python 3.0, 3.1 do not have the builtin callable()
try:
callable(list)
except NameError:
# http://bugs.python.org/issue10518
import collections
def callable(obj):
return isinstance(obj, collections.Callable)
try:
from os import PathLike
except ImportError:
class PathLike(object):
pass
[docs]def filename(name, ext=None, keep=False):
"""Return a new name that has suffix attached; replaces other extensions.
Parameters
----------
name : str or NamedStream
filename; extension is replaced unless ``keep=True``;
`name` can also be a :class:`NamedStream` (and its
:attr:`NamedStream.name` will be changed accordingly)
ext : None or str
extension to use in the new filename
keep : bool
- ``False``: replace existing extension with `ext`;
- ``True``: keep old extension if one existed
.. versionchanged:: 0.9.0
Also permits :class:`NamedStream` to pass through.
"""
if ext is not None:
ext = ext.lower()
if not ext.startswith(os.path.extsep):
ext = os.path.extsep + ext
root, origext = os.path.splitext(name)
if not keep or len(origext) == 0:
newname = root + ext
if isstream(name):
name.name = newname
else:
name = newname
return name if isstream(name) else str(name)
[docs]@contextmanager
def openany(datasource, mode='rt', reset=True):
"""Context manager for :func:`anyopen`.
Open the `datasource` and close it when the context of the :keyword:`with`
statement exits.
`datasource` can be a filename or a stream (see :func:`isstream`). A stream
is reset to its start if possible (via :meth:`~io.IOBase.seek` or
:meth:`~cString.StringIO.reset`).
The advantage of this function is that very different input sources
("streams") can be used for a "file", ranging from files on disk (including
compressed files) to open file objects to sockets and strings---as long as
they have a file-like interface.
Parameters
----------
datasource : a file or a stream
mode : {'r', 'w'} (optional)
open in r(ead) or w(rite) mode
reset : bool (optional)
try to read (`mode` 'r') the stream from the start [``True``]
Examples
--------
Open a gzipped file and process it line by line::
with openany("input.pdb.gz") as pdb:
for line in pdb:
if line.startswith('ATOM'):
print(line)
Open a URL and read it::
import urllib2
with openany(urllib2.urlopen("https://www.mdanalysis.org/")) as html:
print(html.read())
See Also
--------
:func:`anyopen`
"""
stream = anyopen(datasource, mode=mode, reset=reset)
try:
yield stream
finally:
stream.close()
# On python 3, we want to use bz2.open to open and uncompress bz2 files. That
# function allows to specify the type of the uncompressed file (bytes ot text).
# The function does not exist in python 2, thus we must use bz2.BZFile to
# which we cannot tell if the uncompressed file contains bytes or text.
# Therefore, on python 2 we use a proxy function that removes the type of the
# uncompressed file from the `mode` argument.
try:
bz2.open
except AttributeError:
# We are on python 2 and bz2.open is not available
def bz2_open(filename, mode):
"""Open and uncompress a BZ2 file"""
mode = mode.replace('t', '').replace('b', '')
return bz2.BZ2File(filename, mode)
else:
# We are on python 3 so we can use bz2.open
bz2_open = bz2.open
[docs]def anyopen(datasource, mode='rt', reset=True):
"""Open datasource (gzipped, bzipped, uncompressed) and return a stream.
`datasource` can be a filename or a stream (see :func:`isstream`). By
default, a stream is reset to its start if possible (via
:meth:`~io.IOBase.seek` or :meth:`~cString.StringIO.reset`).
If possible, the attribute ``stream.name`` is set to the filename or
"<stream>" if no filename could be associated with the *datasource*.
Parameters
----------
datasource
a file (from :class:`file` or :func:`open`) or a stream (e.g. from
:func:`urllib2.urlopen` or :class:`cStringIO.StringIO`)
mode: {'r', 'w', 'a'} (optional)
Open in r(ead), w(rite) or a(ppen) mode. More complicated
modes ('r+', 'w+', ...) are not supported; only the first letter of
`mode` is used and thus any additional modifiers are silently ignored.
reset: bool (optional)
try to read (`mode` 'r') the stream from the start
Returns
-------
file-like object
See Also
--------
:func:`openany`
to be used with the :keyword:`with` statement.
.. versionchanged:: 0.9.0
Only returns the ``stream`` and tries to set ``stream.name = filename`` instead of the previous
behavior to return a tuple ``(stream, filename)``.
"""
handlers = {'bz2': bz2_open, 'gz': gzip.open, '': open}
if mode.startswith('r'):
if isstream(datasource):
stream = datasource
try:
filename = str(stream.name) # maybe that does not always work?
except AttributeError:
filename = "<stream>"
if reset:
try:
stream.reset()
except (AttributeError, IOError):
try:
stream.seek(0)
except (AttributeError, IOError):
warnings.warn("Stream {0}: not guaranteed to be at the beginning."
"".format(filename),
category=StreamWarning)
else:
stream = None
filename = datasource
for ext in ('bz2', 'gz', ''): # file == '' should be last
openfunc = handlers[ext]
stream = _get_stream(datasource, openfunc, mode=mode)
if stream is not None:
break
if stream is None:
raise IOError(errno.EIO, "Cannot open file or stream in mode={mode!r}.".format(**vars()), repr(filename))
elif mode.startswith('w') or mode.startswith('a'): # append 'a' not tested...
if isstream(datasource):
stream = datasource
try:
filename = str(stream.name) # maybe that does not always work?
except AttributeError:
filename = "<stream>"
else:
stream = None
filename = datasource
name, ext = os.path.splitext(filename)
if ext.startswith('.'):
ext = ext[1:]
if not ext in ('bz2', 'gz'):
ext = '' # anything else but bz2 or gz is just a normal file
openfunc = handlers[ext]
stream = openfunc(datasource, mode=mode)
if stream is None:
raise IOError(errno.EIO, "Cannot open file or stream in mode={mode!r}.".format(**vars()), repr(filename))
else:
raise NotImplementedError("Sorry, mode={mode!r} is not implemented for {datasource!r}".format(**vars()))
try:
stream.name = filename
except (AttributeError, TypeError):
pass # can't set name (e.g. cStringIO.StringIO)
return stream
def _get_stream(filename, openfunction=open, mode='r'):
"""Return open stream if *filename* can be opened with *openfunction* or else ``None``."""
try:
stream = openfunction(filename, mode=mode)
except (IOError, OSError) as err:
# An exception might be raised due to two reasons, first the openfunction is unable to open the file, in this
# case we have to ignore the error and return None. Second is when openfunction can't open the file because
# either the file isn't there or the permissions don't allow access.
if errno.errorcode[err.errno] in ['ENOENT', 'EACCES']:
six.reraise(*sys.exc_info())
return None
if mode.startswith('r'):
# additional check for reading (eg can we uncompress) --- is this needed?
try:
stream.readline()
except IOError:
stream.close()
stream = None
except:
stream.close()
raise
else:
stream.close()
stream = openfunction(filename, mode=mode)
return stream
[docs]def greedy_splitext(p):
"""Split extension in path *p* at the left-most separator.
Extensions are taken to be separated from the filename with the
separator :data:`os.extsep` (as used by :func:`os.path.splitext`).
Arguments
---------
p : str
path
Returns
-------
(root, extension) : tuple
where ``root`` is the full path and filename with all
extensions removed whereas ``extension`` is the string of
all extensions.
Example
-------
>>> greedy_splitext("/home/joe/protein.pdb.bz2")
('/home/joe/protein', '.pdb.bz2')
"""
path, root = os.path.split(p)
extension = ''
while True:
root, ext = os.path.splitext(root)
extension = ext + extension
if not ext:
break
return os.path.join(path, root), extension
[docs]def hasmethod(obj, m):
"""Return ``True`` if object *obj* contains the method *m*."""
return hasattr(obj, m) and callable(getattr(obj, m))
[docs]def isstream(obj):
"""Detect if `obj` is a stream.
We consider anything a stream that has the methods
- ``close()``
and either set of the following
- ``read()``, ``readline()``, ``readlines()``
- ``write()``, ``writeline()``, ``writelines()``
Parameters
----------
obj : stream or str
Returns
-------
bool
``True`` if `obj` is a stream, ``False`` otherwise
See Also
--------
:mod:`io`
.. versionadded:: 0.9.0
"""
signature_methods = ("close",)
alternative_methods = (
("read", "readline", "readlines"),
("write", "writeline", "writelines"))
# Must have ALL the signature methods
for m in signature_methods:
if not hasmethod(obj, m):
return False
# Must have at least one complete set of alternative_methods
alternative_results = [
np.all([hasmethod(obj, m) for m in alternatives])
for alternatives in alternative_methods]
return np.any(alternative_results)
[docs]def which(program):
"""Determine full path of executable `program` on :envvar:`PATH`.
(Jay at http://stackoverflow.com/questions/377017/test-if-executable-exists-in-python)
Parameters
----------
programe : str
name of the executable
Returns
-------
path : str or None
absolute path to the executable if it can be found, else ``None``
"""
def is_exe(fpath):
return os.path.isfile(fpath) and os.access(fpath, os.X_OK)
fpath, fname = os.path.split(program)
if fpath:
real_program = realpath(program)
if is_exe(real_program):
return real_program
else:
for path in os.environ["PATH"].split(os.pathsep):
exe_file = os.path.join(path, program)
if is_exe(exe_file):
return exe_file
return None
[docs]@functools.total_ordering
class NamedStream(io.IOBase, PathLike):
"""Stream that also provides a (fake) name.
By wrapping a stream `stream` in this class, it can be passed to
code that uses inspection of the filename to make decisions. For
instance. :func:`os.path.split` will work correctly on a
:class:`NamedStream`.
The class can be used as a context manager.
:class:`NamedStream` is derived from :class:`io.IOBase` (to indicate that
it is a stream). Many operations that normally expect a string will also
work with a :class:`NamedStream`; for instance, most of the functions in
:mod:`os.path` will work with the exception of :func:`os.path.expandvars`
and :func:`os.path.expanduser`, which will return the :class:`NamedStream`
itself instead of a string if no substitutions were made.
Example
-------
Wrap a :func:`cStringIO.StringIO` instance to write to::
import cStringIO
import os.path
stream = cStringIO.StringIO()
f = NamedStream(stream, "output.pdb")
print(os.path.splitext(f))
Wrap a :class:`file` instance to read from::
stream = open("input.pdb")
f = NamedStream(stream, stream.name)
Use as a context manager (closes stream automatically when the
:keyword:`with` block is left)::
with NamedStream(open("input.pdb"), "input.pdb") as f:
# use f
print f.closed # --> False
# ...
print f.closed # --> True
Note
----
This class uses its own :meth:`__getitem__` method so if `stream`
implements :meth:`stream.__getitem__` then that will be masked and
this class should not be used.
Warning
-------
By default, :meth:`NamedStream.close` will **not close the
stream** but instead :meth:`~NamedStream.reset` it to the
beginning. [#NamedStreamClose]_ Provide the ``force=True`` keyword
to :meth:`NamedStream.close` to always close the stream.
"""
def __init__(self, stream, filename, reset=True, close=False):
"""Initialize the :class:`NamedStream` from a `stream` and give it a `name`.
The constructor attempts to rewind the stream to the beginning unless
the keyword `reset` is set to ``False``. If rewinding fails, a
:class:`MDAnalysis.StreamWarning` is issued.
Parameters
----------
stream : stream
an open stream (e.g. :class:`file` or :func:`cStringIO.StringIO`)
filename : str
the filename that should be associated with the stream
reset : bool (optional)
start the stream from the beginning (either :meth:`reset` or :meth:`seek`)
when the class instance is constructed
close : bool (optional)
close the stream when a :keyword:`with` block exits or when
:meth:`close` is called; note that the default is **not to close
the stream**
Notes
-----
By default, this stream will *not* be closed by :keyword:`with` and
:meth:`close` (see there) unless the `close` keyword is set to
``True``.
.. versionadded:: 0.9.0
"""
# constructing the class from an instance of itself has weird behavior
# on __del__ and super on python 3. Let's warn the user and ensure the
# class works normally.
if isinstance(stream, NamedStream):
warnings.warn("Constructed NamedStream from a NamedStream",
RuntimeWarning)
stream = stream.stream
self.stream = stream
self.name = filename
self.close_stream = close
if reset:
self.reset()
[docs] def reset(self):
"""Move to the beginning of the stream"""
# try to rewind
try:
self.stream.reset() # e.g. StreamIO
except (AttributeError, IOError):
try:
self.stream.seek(0) # typical file objects
except (AttributeError, IOError):
warnings.warn("NamedStream {0}: not guaranteed to be at the beginning."
"".format(self.name),
category=StreamWarning)
# access the stream
def __getattr__(self, x):
try:
return getattr(self.stream, x)
except AttributeError:
return getattr(self.name, x)
def __iter__(self):
return iter(self.stream)
def __next__(self):
return self.stream.__next__()
def __enter__(self):
# do not call the stream's __enter__ because the stream is already open
return self
def __exit__(self, *args):
# NOTE: By default (close=False) we only reset the stream and NOT close it; this makes
# it easier to use it as a drop-in replacement for a filename that might
# be opened repeatedly (at least in MDAnalysis)
#try:
# return self.stream.__exit__(*args)
#except AttributeError:
# super(NamedStream, self).__exit__(*args)
self.close()
def __fspath__(self):
return self.name
# override more IOBase methods, as these are provided by IOBase and are not
# caught with __getattr__ (ugly...)
[docs] def close(self, force=False):
"""Reset or close the stream.
If :attr:`NamedStream.close_stream` is set to ``False`` (the default)
then this method will *not close the stream* and only :meth:`reset` it.
If the *force* = ``True`` keyword is provided, the stream will be
closed.
.. Note:: This ``close()`` method is non-standard. ``del NamedStream``
always closes the underlying stream.
"""
if self.close_stream or force:
try:
return self.stream.close()
except AttributeError:
return super(NamedStream, self).close()
else:
self.flush()
self.reset()
def __del__(self):
"""Always closes the stream."""
self.close(force=True)
@property
def closed(self):
"""``True`` if stream is closed."""
try:
return self.stream.closed
except AttributeError:
return super(NamedStream, self).closed
[docs] def seek(self, offset, whence=os.SEEK_SET):
"""Change the stream position to the given byte `offset` .
Parameters
----------
offset : int
`offset` is interpreted relative to the position
indicated by `whence`.
whence : {0, 1, 2} (optional)
Values for `whence` are:
- :data:`io.SEEK_SET` or 0 – start of the stream (the default); `offset`
should be zero or positive
- :data:`io.SEEK_CUR` or 1 – current stream position; `offset` may be
negative
- :data:`io.SEEK_END` or 2 – end of the stream; `offset` is usually
negative
Returns
-------
int
the new absolute position in bytes.
"""
try:
return self.stream.seek(offset, whence) # file.seek: no kw
except AttributeError:
return super(NamedStream, self).seek(offset, whence)
[docs] def tell(self):
"""Return the current stream position."""
try:
return self.stream.tell()
except AttributeError:
return super(NamedStream, self).tell()
[docs] def truncate(self, *size):
"""Truncate the stream's size to `size`.
Parameters
----------
size : int (optional)
The `size` defaults to the current position (if no `size` argument
is supplied). The current file position is not changed.
"""
try:
return self.stream.truncate(*size)
except AttributeError:
return super(NamedStream, self).truncate(*size)
[docs] def seekable(self):
"""Return ``True`` if the stream supports random access.
If ``False``, :meth:`seek`, :meth:`tell` and :meth:`truncate` will
raise :exc:`IOError`.
"""
try:
return self.stream.seekable()
except AttributeError:
return super(NamedStream, self).seekable()
[docs] def readable(self):
"""Return ``True`` if the stream can be read from.
If ``False``, :meth:`read` will raise :exc:`IOError`.
"""
try:
return self.stream.readable()
except AttributeError:
return super(NamedStream, self).readable()
[docs] def writable(self):
"""Return ``True`` if the stream can be written to.
If ``False``, :meth:`write` will raise :exc:`IOError`.
"""
try:
return self.stream.writable()
except AttributeError:
return super(NamedStream, self).writable()
[docs] def flush(self):
"""Flush the write buffers of the stream if applicable.
This does nothing for read-only and non-blocking streams. For file
objects one also needs to call :func:`os.fsync` to write contents to
disk.
"""
try:
return self.stream.flush()
except AttributeError:
return super(NamedStream, self).flush()
[docs] def fileno(self):
"""Return the underlying file descriptor (an integer) of the stream if it exists.
An :exc:`IOError` is raised if the IO object does not use a file descriptor.
"""
try:
return self.stream.fileno()
except AttributeError:
# IOBase.fileno does not raise IOError as advertised so we do this here
six.raise_from(
IOError("This NamedStream does not use a file descriptor."),
None)
[docs] def readline(self):
try:
return self.stream.readline()
except AttributeError:
return super(NamedStream, self).readline()
# fake the important parts of the string API
# (other methods such as rfind() are automatically dealt with via __getattr__)
def __getitem__(self, x):
return self.name[x]
def __eq__(self, x):
return self.name == x
def __ne__(self, x):
return not self == x
def __lt__(self, x):
return self.name < x
def __len__(self):
return len(self.name)
def __add__(self, x):
return self.name + x
def __radd__(self, x):
return x + self.name
def __mul__(self, x):
return self.name * x
__rmul__ = __mul__
def __format__(self, format_spec):
return self.name.format(format_spec)
def __str__(self):
return self.name
def __repr__(self):
return "<NamedStream({0}, {1})>".format(self.stream, self.name)
[docs]def realpath(*args):
"""Join all args and return the real path, rooted at ``/``.
Expands '~', '~user', and environment variables such as :envvar:`$HOME`.
Returns ``None`` if any of the args is ``None``.
"""
if None in args:
return None
return os.path.realpath(os.path.expanduser(os.path.expandvars(os.path.join(*args))))
[docs]def get_ext(filename):
"""Return the lower-cased extension of `filename` without a leading dot.
Parameters
----------
filename : str
Returns
-------
root : str
ext : str
"""
root, ext = os.path.splitext(filename)
if ext.startswith(os.extsep):
ext = ext[1:]
return root, ext.lower()
[docs]def iterable(obj):
"""Returns ``True`` if `obj` can be iterated over and is *not* a string
nor a :class:`NamedStream`"""
if isinstance(obj, (six.string_types, NamedStream)):
return False # avoid iterating over characters of a string
if hasattr(obj, 'next'):
return True # any iterator will do
try:
len(obj) # anything else that might work
except (TypeError, AttributeError):
return False
return True
[docs]def asiterable(obj):
"""Returns `obj` so that it can be iterated over.
A string is *not* detected as and iterable and is wrapped into a :class:`list`
with a single element.
See Also
--------
iterable
"""
if not iterable(obj):
obj = [obj]
return obj
#: Regular expresssion (see :mod:`re`) to parse a simple `FORTRAN edit descriptor`_.
#: ``(?P<repeat>\d?)(?P<format>[IFELAX])(?P<numfmt>(?P<length>\d+)(\.(?P<decimals>\d+))?)?``
#:
#: .. _FORTRAN edit descriptor: http://www.cs.mtu.edu/~shene/COURSES/cs201/NOTES/chap05/format.html
FORTRAN_format_regex = "(?P<repeat>\d+?)(?P<format>[IFEAX])(?P<numfmt>(?P<length>\d+)(\.(?P<decimals>\d+))?)?"
_FORTRAN_format_pattern = re.compile(FORTRAN_format_regex)
def strip(s):
"""Convert `s` to a string and return it white-space stripped."""
return str(s).strip()
class FixedcolumnEntry(object):
"""Represent an entry at specific fixed columns.
Reads from line[start:stop] and converts according to
typespecifier.
"""
convertors = {'I': int, 'F': float, 'E': float, 'A': strip}
def __init__(self, start, stop, typespecifier):
"""
Parameters
----------
start : int
first column
stop : int
last column + 1
typespecifier : str
'I': int, 'F': float, 'E': float, 'A': stripped string
The start/stop arguments follow standard Python convention in that
they are 0-based and that the *stop* argument is not included.
"""
self.start = start
self.stop = stop
self.typespecifier = typespecifier
self.convertor = self.convertors[typespecifier]
def read(self, line):
"""Read the entry from `line` and convert to appropriate type."""
try:
return self.convertor(line[self.start:self.stop])
except ValueError:
six.raise_from(
ValueError(
"{0!r}: Failed to read&convert {1!r}".format(
self, line[self.start:self.stop])),
None)
def __len__(self):
"""Length of the field in columns (stop - start)"""
return self.stop - self.start
def __repr__(self):
return "FixedcolumnEntry({0:d},{1:d},{2!r})".format(self.start, self.stop, self.typespecifier)
[docs]class FORTRANReader(object):
"""FORTRANReader provides a method to parse FORTRAN formatted lines in a file.
The contents of lines in a file can be parsed according to FORTRAN format
edit descriptors (see `Fortran Formats`_ for the syntax).
Only simple one-character specifiers supported here: *I F E A X* (see
:data:`FORTRAN_format_regex`).
Strings are stripped of leading and trailing white space.
.. _`Fortran Formats`: http://www.webcitation.org/5xbaWMV2x
.. _`Fortran Formats (URL)`:
http://www.cs.mtu.edu/~shene/COURSES/cs201/NOTES/chap05/format.html
"""
def __init__(self, fmt):
"""Set up the reader with the FORTRAN format string.
The string `fmt` should look like '2I10,2X,A8,2X,A8,3F20.10,2X,A8,2X,A8,F20.10'.
Parameters
----------
fmt : str
FORTRAN format edit descriptor for a line as described in `Fortran
Formats`_
Example
-------
Parsing of a standard CRD file::
atomformat = FORTRANReader('2I10,2X,A8,2X,A8,3F20.10,2X,A8,2X,A8,F20.10')
for line in open('coordinates.crd'):
serial,TotRes,resName,name,x,y,z,chainID,resSeq,tempFactor = atomformat.read(line)
"""
self.fmt = fmt.split(',')
descriptors = [self.parse_FORTRAN_format(descriptor) for descriptor in self.fmt]
start = 0
self.entries = []
for d in descriptors:
if d['format'] != 'X':
for x in range(d['repeat']):
stop = start + d['length']
self.entries.append(FixedcolumnEntry(start, stop, d['format']))
start = stop
else:
start += d['totallength']
[docs] def read(self, line):
"""Parse `line` according to the format string and return list of values.
Values are converted to Python types according to the format specifier.
Parameters
----------
line : str
Returns
-------
list
list of entries with appropriate types
Raises
------
ValueError
Any of the conversions cannot be made (e.g. space for an int)
See Also
--------
:meth:`FORTRANReader.number_of_matches`
"""
return [e.read(line) for e in self.entries]
[docs] def number_of_matches(self, line):
"""Return how many format entries could be populated with legal values."""
# not optimal, I suppose...
matches = 0
for e in self.entries:
try:
e.read(line)
matches += 1
except ValueError:
pass
return matches
def __len__(self):
"""Returns number of entries."""
return len(self.entries)
def __repr__(self):
return self.__class__.__name__ + "(" + ",".join(self.fmt) + ")"
[docs]def fixedwidth_bins(delta, xmin, xmax):
"""Return bins of width `delta` that cover `xmin`, `xmax` (or a larger range).
The bin parameters are computed such that the bin size `delta` is
guaranteed. In order to achieve this, the range `[xmin, xmax]` can be
increased.
Bins can be calculated for 1D data (then all parameters are simple floats)
or nD data (then parameters are supplied as arrays, with each entry
correpsonding to one dimension).
Parameters
----------
delta : float or array_like
desired spacing of the bins
xmin : float or array_like
lower bound (left boundary of first bin)
xmax : float or array_like
upper bound (right boundary of last bin)
Returns
-------
dict
The dict contains 'Nbins', 'delta', 'min', and 'max'; these are either
floats or arrays, depending on the input.
Example
-------
Use with :func:`numpy.histogram`::
B = fixedwidth_bins(delta, xmin, xmax)
h, e = np.histogram(data, bins=B['Nbins'], range=(B['min'], B['max']))
"""
if not np.all(xmin < xmax):
raise ValueError('Boundaries are not sane: should be xmin < xmax.')
_delta = np.asarray(delta, dtype=np.float_)
_xmin = np.asarray(xmin, dtype=np.float_)
_xmax = np.asarray(xmax, dtype=np.float_)
_length = _xmax - _xmin
N = np.ceil(_length / _delta).astype(np.int_) # number of bins
dx = 0.5 * (N * _delta - _length) # add half of the excess to each end
return {'Nbins': N, 'delta': _delta, 'min': _xmin - dx, 'max': _xmax + dx}
[docs]def get_weights(atoms, weights):
"""Check that a `weights` argument is compatible with `atoms`.
Parameters
----------
atoms : AtomGroup or array_like
The atoms that the `weights` should be applied to. Typically this
is a :class:`AtomGroup` but because only the length is compared,
any sequence for which ``len(atoms)`` is defined is acceptable.
weights : {"mass", None} or array_like
All MDAnalysis functions or classes understand "mass" and will then
use ``atoms.masses``. ``None`` indicates equal weights for all atoms.
Using an ``array_like`` assigns a custom weight to each element of
`atoms`.
Returns
-------
weights : array_like or None
If "mass" was selected, ``atoms.masses`` is returned, otherwise the
value of `weights` (which can be ``None``).
Raises
------
TypeError
If `weights` is not one of the allowed values or if "mass" is
selected but ``atoms.masses`` is not available.
ValueError
If `weights` is not a 1D array with the same length as
`atoms`, then the exception is raised. :exc:`TypeError` is
also raised if ``atoms.masses`` is not defined.
"""
if not iterable(weights) and weights == "mass":
try:
weights = atoms.masses
except AttributeError:
six.raise_from(
TypeError("weights='mass' selected but atoms.masses is missing"),
None)
if iterable(weights):
if len(np.asarray(weights, dtype=object).shape) != 1:
raise ValueError("weights must be a 1D array, not with shape "
"{0}".format(
np.asarray(weights, dtype=object).shape))
elif len(weights) != len(atoms):
raise ValueError("weights (length {0}) must be of same length as "
"the atoms ({1})".format(
len(weights), len(atoms)))
elif weights is not None:
raise ValueError("weights must be {'mass', None} or an iterable of the "
"same size as the atomgroup.")
return weights
# String functions
# ----------------
#: translation table for 3-letter codes --> 1-letter codes
#: .. SeeAlso:: :data:`alternative_inverse_aa_codes`
canonical_inverse_aa_codes = {
'ALA': 'A', 'CYS': 'C', 'ASP': 'D', 'GLU': 'E',
'PHE': 'F', 'GLY': 'G', 'HIS': 'H', 'ILE': 'I',
'LYS': 'K', 'LEU': 'L', 'MET': 'M', 'ASN': 'N',
'PRO': 'P', 'GLN': 'Q', 'ARG': 'R', 'SER': 'S',
'THR': 'T', 'VAL': 'V', 'TRP': 'W', 'TYR': 'Y'}
#: translation table for 1-letter codes --> *canonical* 3-letter codes.
#: The table is used for :func:`convert_aa_code`.
amino_acid_codes = {one: three for three, one in canonical_inverse_aa_codes.items()}
#: non-default charge state amino acids or special charge state descriptions
#: (Not fully synchronized with :class:`MDAnalysis.core.selection.ProteinSelection`.)
alternative_inverse_aa_codes = {
'HISA': 'H', 'HISB': 'H', 'HSE': 'H', 'HSD': 'H', 'HID': 'H', 'HIE': 'H', 'HIS1': 'H',
'HIS2': 'H',
'ASPH': 'D', 'ASH': 'D',
'GLUH': 'E', 'GLH': 'E',
'LYSH': 'K', 'LYN': 'K',
'ARGN': 'R',
'CYSH': 'C', 'CYS1': 'C', 'CYS2': 'C'}
#: lookup table from 3/4 letter resnames to 1-letter codes. Note that non-standard residue names
#: for tautomers or different protonation states such as HSE are converted to canonical 1-letter codes ("H").
#: The table is used for :func:`convert_aa_code`.
#: .. SeeAlso:: :data:`canonical_inverse_aa_codes` and :data:`alternative_inverse_aa_codes`
inverse_aa_codes = {}
inverse_aa_codes.update(canonical_inverse_aa_codes)
inverse_aa_codes.update(alternative_inverse_aa_codes)
[docs]def convert_aa_code(x):
"""Converts between 3-letter and 1-letter amino acid codes.
Parameters
----------
x : str
1-letter or 3-letter amino acid code
Returns
-------
str
3-letter or 1-letter amino acid code
Raises
------
ValueError
No conversion can be made; the amino acid code is not defined.
Note
----
Data are defined in :data:`amino_acid_codes` and :data:`inverse_aa_codes`.
"""
if len(x) == 1:
d = amino_acid_codes
else:
d = inverse_aa_codes
try:
return d[x.upper()]
except KeyError:
six.raise_from(
ValueError(
"No conversion for {0} found (1 letter -> 3 letter or 3/4 letter -> 1 letter)".format(x)
),
None)
#: Regular expression to match and parse a residue-atom selection; will match
#: "LYS300:HZ1" or "K300:HZ1" or "K300" or "4GB300:H6O" or "4GB300" or "YaA300".
RESIDUE = re.compile("""
(?P<aa>([ACDEFGHIKLMNPQRSTVWY]) # 1-letter amino acid
| # or
([0-9A-Z][a-zA-Z][A-Z][A-Z]?) # 3-letter or 4-letter residue name
)
\s* # white space allowed
(?P<resid>\d+) # resid
\s*
(: # separator ':'
\s*
(?P<atom>\w+) # atom name
)? # possibly one
""", re.VERBOSE | re.IGNORECASE)
# from GromacsWrapper cbook.IndexBuilder
[docs]def parse_residue(residue):
"""Process residue string.
Parameters
----------
residue: str
The *residue* must contain a 1-letter or 3-letter or
4-letter residue string, a number (the resid) and
optionally an atom identifier, which must be separate
from the residue with a colon (":"). White space is
allowed in between.
Returns
-------
tuple
`(3-letter aa string, resid, atomname)`; known 1-letter
aa codes are converted to 3-letter codes
Examples
--------
- "LYS300:HZ1" --> ("LYS", 300, "HZ1")
- "K300:HZ1" --> ("LYS", 300, "HZ1")
- "K300" --> ("LYS", 300, None)
- "4GB300:H6O" --> ("4GB", 300, "H6O")
- "4GB300" --> ("4GB", 300, None)
"""
# XXX: use _translate_residue() ....
m = RESIDUE.match(residue)
if not m:
raise ValueError("Selection {residue!r} is not valid (only 1/3/4 letter resnames, resid required).".format(**vars()))
resid = int(m.group('resid'))
residue = m.group('aa')
if len(residue) == 1:
resname = convert_aa_code(residue) # only works for AA
else:
resname = residue # use 3-letter for any resname
atomname = m.group('atom')
return (resname, resid, atomname)
[docs]def conv_float(s):
"""Convert an object `s` to float if possible.
Function to be passed into :func:`map` or a list comprehension. If
the argument can be interpreted as a float it is converted,
otherwise the original object is passed back.
"""
try:
return float(s)
except ValueError:
return s
[docs]def cached(key):
"""Cache a property within a class.
Requires the Class to have a cache dict called ``_cache``.
Example
-------
How to add a cache for a variable to a class by using the `@cached`
decorator::
class A(object):
def__init__(self):
self._cache = dict()
@property
@cached('keyname')
def size(self):
# This code gets ran only if the lookup of keyname fails
# After this code has been ran once, the result is stored in
# _cache with the key: 'keyname'
size = 10.0
.. versionadded:: 0.9.0
"""
def cached_lookup(func):
@wraps(func)
def wrapper(self, *args, **kwargs):
try:
return self._cache[key]
except KeyError:
self._cache[key] = ret = func(self, *args, **kwargs)
return ret
return wrapper
return cached_lookup
[docs]def unique_rows(arr, return_index=False):
"""Return the unique rows of an array.
Arguments
---------
arr : numpy.ndarray
Array of shape ``(n1, m)``.
return_index : bool, optional
If ``True``, returns indices of array that formed answer (see
:func:`numpy.unique`)
Returns
-------
unique_rows : numpy.ndarray
Array of shape ``(n2, m)`` containing only the unique rows of `arr`.
r_idx : numpy.ndarray (optional)
Array containing the corresponding row indices (if `return_index`
is ``True``).
Examples
--------
Remove dupicate rows from an array:
>>> a = np.array([[0, 1], [1, 2], [1, 2], [0, 1], [2, 3]])
>>> b = unique_rows(a)
>>> b
array([[0, 1], [1, 2], [2, 3]])
See Also
--------
numpy.unique
"""
# From here, but adapted to handle any size rows
# https://mail.scipy.org/pipermail/scipy-user/2011-December/031200.html
# This seems to fail if arr.flags['OWNDATA'] is False
# this can occur when second dimension was created through broadcasting
# eg: idx = np.array([1, 2])[None, :]
if not arr.flags['OWNDATA']:
arr = arr.copy()
m = arr.shape[1]
if return_index:
u, r_idx = np.unique(arr.view(dtype=np.dtype([(str(i), arr.dtype)
for i in range(m)])),
return_index=True)
return u.view(arr.dtype).reshape(-1, m), r_idx
else:
u = np.unique(arr.view(
dtype=np.dtype([(str(i), arr.dtype) for i in range(m)])
))
return u.view(arr.dtype).reshape(-1, m)
[docs]def blocks_of(a, n, m):
"""Extract a view of ``(n, m)`` blocks along the diagonal of the array `a`.
Parameters
----------
a : numpy.ndarray
Input array, must be C contiguous and at least 2D.
n : int
Size of block in first dimension.
m : int
Size of block in second dimension.
Returns
-------
view : numpy.ndarray
A view of the original array with shape ``(nblocks, n, m)``, where
``nblocks`` is the number of times the miniblocks of shape ``(n, m)``
fit in the original.
Raises
------
ValueError
If the supplied `n` and `m` don't divide `a` into an integer number
of blocks or if `a` is not C contiguous.
Examples
--------
>>> arr = np.arange(16).reshape(4, 4)
>>> view = blocks_of(arr, 2, 2)
>>> view[:] = 100
>>> arr
array([[100, 100, 2, 3],
[100, 100, 6, 7],
[ 8, 9, 100, 100],
[ 12, 13, 100, 100]])
Notes
-----
`n`, `m` must divide `a` into an identical integer number of blocks. Please
note that if the block size is larger than the input array, this number will
be zero, resulting in an empty view!
Uses strides and therefore requires that the array is C contiguous.
Returns a view, so editing this modifies the original array.
.. versionadded:: 0.12.0
"""
# based on:
# http://stackoverflow.com/a/10862636
# but generalised to handle non square blocks.
if not a.flags['C_CONTIGUOUS']:
raise ValueError("Input array is not C contiguous.")
nblocks = a.shape[0] // n
nblocks2 = a.shape[1] // m
if not nblocks == nblocks2:
raise ValueError("Must divide into same number of blocks in both"
" directions. Got {} by {}"
"".format(nblocks, nblocks2))
new_shape = (nblocks, n, m)
new_strides = (n * a.strides[0] + m * a.strides[1],
a.strides[0], a.strides[1])
return np.lib.stride_tricks.as_strided(a, new_shape, new_strides)
[docs]class Namespace(dict):
"""Class to allow storing attributes in new namespace. """
def __getattr__(self, key):
# a.this causes a __getattr__ call for key = 'this'
try:
return dict.__getitem__(self, key)
except KeyError:
six.raise_from(AttributeError('"{}" is not known in the namespace.'
.format(key)), None)
def __setattr__(self, key, value):
dict.__setitem__(self, key, value)
def __delattr__(self, key):
try:
dict.__delitem__(self, key)
except KeyError:
six.raise_from(
AttributeError('"{}" is not known in the namespace.'
.format(key)),
None)
def __eq__(self, other):
try:
# this'll allow us to compare if we're storing arrays
assert_equal(self, other)
except AssertionError:
return False
return True
[docs]def ltruncate_int(value, ndigits):
"""Truncate an integer, retaining least significant digits
Parameters
----------
value : int
value to truncate
ndigits : int
number of digits to keep
Returns
-------
truncated : int
only the `ndigits` least significant digits from `value`
Examples
--------
>>> ltruncate_int(123, 2)
23
>>> ltruncate_int(1234, 5)
1234
"""
return int(str(value)[-ndigits:])
[docs]def flatten_dict(d, parent_key=tuple()):
"""Flatten a nested dict `d` into a shallow dict with tuples as keys.
Parameters
----------
d : dict
Returns
-------
dict
Note
-----
Based on https://stackoverflow.com/a/6027615/
by user https://stackoverflow.com/users/1897/imran
.. versionadded:: 0.18.0
"""
items = []
for k, v in d.items():
if type(k) != tuple:
new_key = parent_key + (k, )
else:
new_key = parent_key + k
if isinstance(v, dict):
items.extend(flatten_dict(v, new_key).items())
else:
items.append((new_key, v))
return dict(items)
[docs]def static_variables(**kwargs):
"""Decorator equipping functions or methods with static variables.
Static variables are declared and initialized by supplying keyword arguments
and initial values to the decorator.
Example
-------
>>> @static_variables(msg='foo calls', calls=0)
... def foo():
... foo.calls += 1
... print("{}: {}".format(foo.msg, foo.calls))
...
>>> foo()
foo calls: 1
>>> foo()
foo calls: 2
.. note:: Based on https://stackoverflow.com/a/279586
by `Claudiu <https://stackoverflow.com/users/15055/claudiu>`_
.. versionadded:: 0.19.0
"""
def static_decorator(func):
for kwarg in kwargs:
setattr(func, kwarg, kwargs[kwarg])
return func
return static_decorator
# In a lot of Atom/Residue/SegmentGroup methods such as center_of_geometry() and
# the like, results are biased if the calling group is not unique, i.e., if it
# contains duplicates.
# We therefore raise a `DuplicateWarning` whenever an affected method is called
# from a non-unique group. Since several of the affected methods involve calls
# to other affected methods, simply raising a warning in every affected method
# would potentially lead to a massive amount of warnings. This is exactly where
# the `warn_if_unique` decorator below comes into play. It ensures that a
# warning is only raised once for a method using this decorator, and suppresses
# all such warnings that would potentially be raised in methods called by that
# method. Of course, as it is generally the case with Python warnings, this is
# *not threadsafe*.
[docs]@static_variables(warned=False)
def warn_if_not_unique(groupmethod):
"""Decorator triggering a :class:`~MDAnalysis.exceptions.DuplicateWarning`
if the underlying group is not unique.
Assures that during execution of the decorated method only the first of
potentially multiple warnings concerning the uniqueness of groups is shown.
Raises
------
:class:`~MDAnalysis.exceptions.DuplicateWarning`
If the :class:`~MDAnalysis.core.groups.AtomGroup`,
:class:`~MDAnalysis.core.groups.ResidueGroup`, or
:class:`~MDAnalysis.core.groups.SegmentGroup` of which the decorated
method is a member contains duplicates.
.. versionadded:: 0.19.0
"""
@wraps(groupmethod)
def wrapper(group, *args, **kwargs):
# Proceed as usual if the calling group is unique or a DuplicateWarning
# has already been thrown:
if group.isunique or warn_if_not_unique.warned:
return groupmethod(group, *args, **kwargs)
# Otherwise, throw a DuplicateWarning and execute the method.
method_name = ".".join((group.__class__.__name__, groupmethod.__name__))
# Try to get the group's variable name(s):
caller_locals = inspect.currentframe().f_back.f_locals.items()
group_names = []
for name, obj in caller_locals:
try:
if obj is group:
group_names.append("'{}'".format(name))
except:
pass
if not group_names:
group_name = "'unnamed {}'".format(group.__class__.__name__)
elif len(group_names) == 1:
group_name = group_names[0]
else:
group_name = " a.k.a. ".join(sorted(group_names))
group_repr = repr(group)
msg = ("{}(): {} {} contains duplicates. Results might be biased!"
"".format(method_name, group_name, group_repr))
warnings.warn(message=msg, category=DuplicateWarning, stacklevel=2)
warn_if_not_unique.warned = True
try:
result = groupmethod(group, *args, **kwargs)
finally:
warn_if_not_unique.warned = False
return result
return wrapper
[docs]def check_coords(*coord_names, **options):
"""Decorator for automated coordinate array checking.
This decorator is intended for use especially in
:mod:`MDAnalysis.lib.distances`.
It takes an arbitrary number of positional arguments which must correspond
to names of positional arguments of the decorated function.
It then checks if the corresponding values are valid coordinate arrays.
If all these arrays are single coordinates (i.e., their shape is ``(3,)``),
the decorated function can optionally return a single coordinate (or angle)
instead of an array of coordinates (or angles). This can be used to enable
computations of single observables using functions originally designed to
accept only 2-d coordinate arrays.
The checks performed on each individual coordinate array are:
* Check that coordinate arrays are of type :class:`numpy.ndarray`.
* Check that coordinate arrays have a shape of ``(n, 3)`` (or ``(3,)`` if
single coordinates are allowed; see keyword argument `allow_single`).
* Automatic dtype conversion to ``numpy.float32``.
* Optional replacement by a copy; see keyword argument `enforce_copy` .
* If coordinate arrays aren't C-contiguous, they will be automatically
replaced by a C-contiguous copy.
* Optional check for equal length of all coordinate arrays; see optional
keyword argument `check_lengths_match`.
Parameters
----------
*coord_names : tuple
Arbitrary number of strings corresponding to names of positional
arguments of the decorated function.
**options : dict, optional
* **enforce_copy** (:class:`bool`, optional) -- Enforce working on a
copy of the coordinate arrays. This is useful to ensure that the input
arrays are left unchanged. Default: ``True``
* **allow_single** (:class:`bool`, optional) -- Allow the input
coordinate array to be a single coordinate with shape ``(3,)``.
* **convert_single** (:class:`bool`, optional) -- If ``True``, single
coordinate arrays will be converted to have a shape of ``(1, 3)``.
Only has an effect if `allow_single` is ``True``. Default: ``True``
* **reduce_result_if_single** (:class:`bool`, optional) -- If ``True``
and *all* input coordinates are single, a decorated function ``func``
will return ``func()[0]`` instead of ``func()``. Only has an effect if
`allow_single` is ``True``. Default: ``True``
* **check_lengths_match** (:class:`bool`, optional) -- If ``True``, a
:class:`ValueError` is raised if not all coordinate arrays contain the
same number of coordinates. Default: ``True``
Raises
------
ValueError
If the decorator is used without positional arguments (for development
purposes only).
If any of the positional arguments supplied to the decorator doesn't
correspond to a name of any of the decorated function's positional
arguments.
If any of the coordinate arrays has a wrong shape.
TypeError
If any of the coordinate arrays is not a :class:`numpy.ndarray`.
If the dtype of any of the coordinate arrays is not convertible to
``numpy.float32``.
Example
-------
>>> @check_coords('coords1', 'coords2')
... def coordsum(coords1, coords2):
... assert coords1.dtype == np.float32
... assert coords2.flags['C_CONTIGUOUS']
... return coords1 + coords2
...
>>> # automatic dtype conversion:
>>> coordsum(np.zeros(3, dtype=np.int64), np.ones(3))
array([1., 1., 1.], dtype=float32)
>>>
>>> # automatic handling of non-contiguous arrays:
>>> coordsum(np.zeros(3), np.ones(6)[::2])
array([1., 1., 1.], dtype=float32)
>>>
>>> # automatic shape checking:
>>> coordsum(np.zeros(3), np.ones(6))
ValueError: coordsum(): coords2.shape must be (3,) or (n, 3), got (6,).
.. versionadded:: 0.19.0
"""
enforce_copy = options.get('enforce_copy', True)
allow_single = options.get('allow_single', True)
convert_single = options.get('convert_single', True)
reduce_result_if_single = options.get('reduce_result_if_single', True)
check_lengths_match = options.get('check_lengths_match',
len(coord_names) > 1)
if not coord_names:
raise ValueError("Decorator check_coords() cannot be used without "
"positional arguments.")
def check_coords_decorator(func):
fname = func.__name__
code = func.__code__
argnames = code.co_varnames
nargs = len(code.co_varnames)
ndefaults = len(func.__defaults__) if func.__defaults__ else 0
# Create a tuple of positional argument names:
nposargs = code.co_argcount - ndefaults
posargnames = argnames[:nposargs]
# The check_coords() decorator is designed to work only for positional
# arguments:
for name in coord_names:
if name not in posargnames:
raise ValueError("In decorator check_coords(): Name '{}' "
"doesn't correspond to any positional "
"argument of the decorated function {}()."
"".format(name, func.__name__))
def _check_coords(coords, argname):
if not isinstance(coords, np.ndarray):
raise TypeError("{}(): Parameter '{}' must be a numpy.ndarray, "
"got {}.".format(fname, argname, type(coords)))
is_single = False
if allow_single:
if (coords.ndim not in (1, 2)) or (coords.shape[-1] != 3):
raise ValueError("{}(): {}.shape must be (3,) or (n, 3), "
"got {}.".format(fname, argname,
coords.shape))
if coords.ndim == 1:
is_single = True
if convert_single:
coords = coords[None, :]
else:
if (coords.ndim != 2) or (coords.shape[1] != 3):
raise ValueError("{}(): {}.shape must be (n, 3), got {}."
"".format(fname, argname, coords.shape))
try:
coords = coords.astype(np.float32, order='C', copy=enforce_copy)
except ValueError:
six.raise_from(
TypeError(
"{}(): {}.dtype must be convertible to float32,"
" got {}.".format(fname, argname, coords.dtype)),
None)
return coords, is_single
@wraps(func)
def wrapper(*args, **kwargs):
# Check for invalid function call:
if len(args) != nposargs:
# set marker for testing purposes:
wrapper._invalid_call = True
if len(args) > nargs:
# too many arguments, invoke call:
return func(*args, **kwargs)
for name in posargnames[:len(args)]:
if name in kwargs:
# duplicate argument, invoke call:
return func(*args, **kwargs)
for name in posargnames[len(args):]:
if name not in kwargs:
# missing argument, invoke call:
return func(*args, **kwargs)
for name in kwargs:
if name not in argnames:
# unexpected kwarg, invoke call:
return func(*args, **kwargs)
# call is valid, unset test marker:
wrapper._invalid_call = False
args = list(args)
ncoords = []
all_single = allow_single
for name in coord_names:
idx = posargnames.index(name)
if idx < len(args):
args[idx], is_single = _check_coords(args[idx], name)
all_single &= is_single
ncoords.append(args[idx].shape[0])
else:
kwargs[name], is_single = _check_coords(kwargs[name],
name)
all_single &= is_single
ncoords.append(kwargs[name].shape[0])
if check_lengths_match and ncoords:
if ncoords.count(ncoords[0]) != len(ncoords):
raise ValueError("{}(): {} must contain the same number of "
"coordinates, got {}."
"".format(fname, ", ".join(coord_names),
ncoords))
# If all input coordinate arrays were 1-d, so should be the output:
if all_single and reduce_result_if_single:
return func(*args, **kwargs)[0]
return func(*args, **kwargs)
return wrapper
return check_coords_decorator
#------------------------------------------------------------------
#
# our own deprecate function, derived from numpy (see
# https://github.com/MDAnalysis/mdanalysis/pull/1763#issuecomment-403231136)
#
# From numpy/lib/utils.py 1.14.5 (used under the BSD 3-clause licence,
# https://www.numpy.org/license.html#license) and modified
def _set_function_name(func, name):
func.__name__ = name
return func
[docs]class _Deprecate(object):
"""
Decorator class to deprecate old functions.
Refer to `deprecate` for details.
See Also
--------
deprecate
.. versionadded:: 0.19.0
"""
def __init__(self, old_name=None, new_name=None,
release=None, remove=None, message=None):
self.old_name = old_name
self.new_name = new_name
if release is None:
raise ValueError("deprecate: provide release in which "
"feature was deprecated.")
self.release = str(release)
self.remove = str(remove) if remove is not None else remove
self.message = message
def __call__(self, func, *args, **kwargs):
"""
Decorator call. Refer to ``decorate``.
"""
old_name = self.old_name
new_name = self.new_name
message = self.message
release = self.release
remove = self.remove
if old_name is None:
try:
old_name = func.__name__
except AttributeError:
old_name = func.__name__
if new_name is None:
depdoc = "`{0}` is deprecated!".format(old_name)
else:
depdoc = "`{0}` is deprecated, use `{1}` instead!".format(
old_name, new_name)
warn_message = depdoc
remove_text = ""
if remove is not None:
remove_text = "`{0}` will be removed in release {1}.".format(
old_name, remove)
warn_message += "\n" + remove_text
if message is not None:
warn_message += "\n" + message
def newfunc(*args, **kwds):
"""This function is deprecated."""
warnings.warn(warn_message, DeprecationWarning, stacklevel=2)
return func(*args, **kwds)
newfunc = _set_function_name(newfunc, old_name)
# Build the doc string
# First line: func is deprecated, use newfunc instead!
# Normal docs follows.
# Last: .. deprecated::
# make sure that we do not mess up indentation, otherwise sphinx
# docs do not build properly
try:
doc = dedent_docstring(func.__doc__)
except TypeError:
doc = ""
deprecation_text = dedent_docstring("""\n\n
.. deprecated:: {0}
{1}
{2}
""".format(release,
message if message else depdoc,
remove_text))
doc = "{0}\n\n{1}\n{2}\n".format(depdoc, doc, deprecation_text)
newfunc.__doc__ = doc
try:
d = func.__dict__
except AttributeError:
pass
else:
newfunc.__dict__.update(d)
return newfunc
[docs]def deprecate(*args, **kwargs):
"""Issues a DeprecationWarning, adds warning to `old_name`'s
docstring, rebinds ``old_name.__name__`` and returns the new
function object.
This function may also be used as a decorator.
It adds a restructured text ``.. deprecated:: release`` block with
the sphinx deprecated role to the end of the docs. The `message`
is added under the deprecation block and contains the `release` in
which the function was deprecated.
Parameters
----------
func : function
The function to be deprecated.
old_name : str, optional
The name of the function to be deprecated. Default is None, in
which case the name of `func` is used.
new_name : str, optional
The new name for the function. Default is None, in which case the
deprecation message is that `old_name` is deprecated. If given, the
deprecation message is that `old_name` is deprecated and `new_name`
should be used instead.
release : str
Release in which the function was deprecated. This is given as
a keyword argument for technical reasons but is required; a
:exc:`ValueError` is raised if it is missing.
remove : str, optional
Release for which removal of the feature is planned.
message : str, optional
Additional explanation of the deprecation. Displayed in the
docstring after the warning.
Returns
-------
old_func : function
The deprecated function.
Examples
--------
When :func:`deprecate` is used as a function as in the following
example,
.. code-block:: python
oldfunc = deprecate(func, release="0.19.0", remove="1.0",
message="Do it yourself instead.")
then ``oldfunc`` will return a value after printing
:exc:`DeprecationWarning`; ``func`` is still available as it was
before.
When used as a decorator, ``func`` will be changed and issue the
warning and contain the deprecation note in the do string.
.. code-block:: python
@deprecate(release="0.19.0", remove="1.0",
message="Do it yourself instead.")
def func():
\"\"\"Just pass\"\"\"
pass
The resulting doc string (``help(func)``) will look like:
.. code-block:: reST
`func` is deprecated!
Just pass.
.. deprecated:: 0.19.0
Do it yourself instead.
`func` will be removed in 1.0.
(It is possible but confusing to change the name of ``func`` with
the decorator so it is not recommended to use the `new_func`
keyword argument with the decorator.)
.. versionadded:: 0.19.0
"""
# Deprecate may be run as a function or as a decorator
# If run as a function, we initialise the decorator class
# and execute its __call__ method.
if args:
fn = args[0]
args = args[1:]
return _Deprecate(*args, **kwargs)(fn)
else:
return _Deprecate(*args, **kwargs)
#
#------------------------------------------------------------------
[docs]def dedent_docstring(text):
"""Dedent typical python doc string.
Parameters
----------
text : str
string, typically something like ``func.__doc__``.
Returns
-------
str
string with the leading common whitespace removed from each
line
See Also
--------
textwrap.dedent
.. versionadded:: 0.19.0
"""
lines = text.splitlines()
if len(lines) < 2:
return text.lstrip()
# treat first line as special (typically no leading whitespace!) which messes up dedent
return lines[0].lstrip() + "\n" + textwrap.dedent("\n".join(lines[1:]))
[docs]def check_box(box):
"""Take a box input and deduce what type of system it represents based on
the shape of the array and whether all angles are 90 degrees.
Parameters
----------
box : array_like
The unitcell dimensions of the system, which can be orthogonal or
triclinic and must be provided in the same format as returned by
:attr:`MDAnalysis.coordinates.base.Timestep.dimensions`:\n
``[lx, ly, lz, alpha, beta, gamma]``.
Returns
-------
boxtype : {``'ortho'``, ``'tri_vecs'``}
String indicating the box type (orthogonal or triclinic).
checked_box : numpy.ndarray
Array of dtype ``numpy.float32`` containing box information:
* If `boxtype` is ``'ortho'``, `cecked_box` will have the shape ``(3,)``
containing the x-, y-, and z-dimensions of the orthogonal box.
* If `boxtype` is ``'tri_vecs'``, `cecked_box` will have the shape
``(3, 3)`` containing the triclinic box vectors in a lower triangular
matrix as returned by
:meth:`~MDAnalysis.lib.mdamath.triclinic_vectors`.
Raises
------
ValueError
If `box` is not of the form ``[lx, ly, lz, alpha, beta, gamma]``
or contains data that is not convertible to ``numpy.float32``.
See Also
--------
MDAnalysis.lib.mdamath.triclinic_vectors
.. versionchanged: 0.19.0
* Enforced correspondence of `box` with specified format.
* Added automatic conversion of input to :class:`numpy.ndarray` with
dtype ``numpy.float32``.
* Now also returns the box in the format expected by low-level functions
in :mod:`~MDAnalysis.lib.c_distances`.
* Removed obsolete box types ``tri_box`` and ``tri_vecs_bad``.
"""
from .mdamath import triclinic_vectors # avoid circular import
box = np.asarray(box, dtype=np.float32, order='C')
if box.shape != (6,):
raise ValueError("Invalid box information. Must be of the form "
"[lx, ly, lz, alpha, beta, gamma].")
if np.all(box[3:] == 90.):
return 'ortho', box[:3]
return 'tri_vecs', triclinic_vectors(box)