pyemma.coordinates.data._base.transformer.StreamingTransformer¶

class pyemma.coordinates.data._base.transformer.StreamingTransformer(chunksize=None)¶

Basis class for pipelined Transformers.

This class derives from DataSource, so follow up pipeline elements can stream the output of this class.

Parameters: chunksize (int (optional)) – the chunksize used to batch process underlying data.

__init__(chunksize=None)¶: Initialize self. See help(type(self)) for accurate signature.

Methods

`__init__`([chunksize])	Initialize self.
`describe`()	Get a descriptive string representation of this class.
`dimension`()
`fit_transform`(X[, y])	Fit to data, then transform it.
`get_output`([dimensions, stride, skip, chunk])	Maps all input data of this transformer and returns it as an array or list of arrays
`iterator`([stride, lag, chunk, …])	creates an iterator to stream over the (transformed) data.
`n_chunks`(chunksize[, stride, skip])	how many chunks an iterator of this sourcde will output, starting (eg.
`n_frames_total`([stride, skip])	Returns total number of frames.
`number_of_trajectories`([stride])	Returns the number of trajectories.
`output_type`()	By default transformers return single precision floats.
`trajectory_length`(itraj[, stride, skip])	Returns the length of trajectory of the requested index.
`trajectory_lengths`([stride, skip])	Returns the length of each trajectory.
`transform`(X)	Maps the input data through the transformer to correspondingly shaped output data array/list.
`write_to_csv`([filename, extension, …])	write all data to csv with numpy.savetxt
`write_to_hdf5`(filename[, group, …])	writes all data of this Iterable to a given HDF5 file.

Attributes

`chunksize`	chunksize defines how much data is being processed at once.
`data_producer`	The data producer for this data source object (can be another data source object).
`default_chunksize`	How much data will be processed at once, in case no chunksize has been provided.
`filenames`	list of file names the data is originally being read from.
`in_memory`	are results stored in memory?
`is_random_accessible`	Check if self._is_random_accessible is set to true and if all the random access strategies are implemented.
`is_reader`	Property telling if this data source is a reader or not.
`logger`	The logger for this class instance
`name`	The name of this instance
`ndim`
`ntraj`
`ra_itraj_cuboid`	Implementation of random access with slicing that can be up to 3-dimensional, where the first dimension corresponds to the trajectory index, the second dimension corresponds to the frames and the third dimension corresponds to the dimensions of the frames.
`ra_itraj_jagged`	Behaves like ra_itraj_cuboid just that the trajectories are not truncated and returned as a list.
`ra_itraj_linear`	Implementation of random access that takes arguments as the default random access (i.e., up to three dimensions with trajs, frames and dims, respectively), but which considers the frame indexing to be contiguous.
`ra_linear`	Implementation of random access that takes a (maximal) two-dimensional slice where the first component corresponds to the frames and the second component corresponds to the dimensions.

chunksize¶: chunksize defines how much data is being processed at once.

data_producer¶: The data producer for this data source object (can be another data source object). :returns: :rtype: This data source’s data producer.

default_chunksize¶

How much data will be processed at once, in case no chunksize has been provided.

Notes

This variable respects your setting for maximum memory in pyemma.config.default_chunksize

describe()¶: Get a descriptive string representation of this class.

filenames¶

list of file names the data is originally being read from.

Returns: names – list of file names at the beginning of the input chain.
Return type: list of str

fit_transform(X, y=None, **fit_params)¶

Fit to data, then transform it. Fits transformer to X and y with optional parameters fit_params and returns a transformed version of X. :param X: Training set. :type X: numpy array of shape [n_samples, n_features] :param y: Target values. :type y: numpy array of shape [n_samples]

Returns: X_new – Transformed array.
Return type: numpy array of shape [n_samples, n_features_new]

get_output(dimensions=slice(0, None, None), stride=1, skip=0, chunk=None)¶

Maps all input data of this transformer and returns it as an array or list of arrays

Parameters

dimensions (list-like of indexes or slice, default=all) – indices of dimensions you like to keep.
stride (int, default=1) – only take every n’th frame.
skip (int, default=0) – initially skip n frames of each file.
chunk (int, default=None) – How many frames to process at once. If not given obtain the chunk size from the source.

Returns

output – the mapped data, where T is the number of time steps of the input data, or if stride > 1, floor(T_in / stride). d is the output dimension of this transformer. If the input consists of a list of trajectories, Y will also be a corresponding list of trajectories

Return type

list of ndarray(T_i, d)

in_memory¶: are results stored in memory?

is_random_accessible¶: Check if self._is_random_accessible is set to true and if all the random access strategies are implemented. :returns: bool :rtype: Returns True if random accessible via strategies and False otherwise.

is_reader¶: Property telling if this data source is a reader or not. :returns: bool :rtype: True if this data source is a reader and False otherwise

iterator(stride=1, lag=0, chunk=None, return_trajindex=True, cols=None, skip=0)¶

creates an iterator to stream over the (transformed) data.

If your data is too large to fit into memory and you want to incrementally compute some quantities on it, you can create an iterator on a reader or transformer (eg. TICA) to avoid memory overflows.

Parameters

stride (int, default=1) – Take only every stride’th frame.
lag (int, default=0) – how many frame to omit for each file.
chunk (int, default=None) – How many frames to process at once. If not given obtain the chunk size from the source.
return_trajindex (boolean, default=True) – a chunk of data if return_trajindex is False, otherwise a tuple of (trajindex, data).
cols (array like, default=None) – return only the given columns.
skip (int, default=0) – skip ‘n’ first frames of each trajectory.

Returns

iter – a implementation of a DataSourceIterator to stream over the data

Return type

instance of DataSourceIterator

Examples

>>> from pyemma.coordinates import source; import numpy as np
>>> data = [np.arange(3), np.arange(4, 7)]
>>> reader = source(data)
>>> iterator = reader.iterator(chunk=1)
>>> for array_index, chunk in iterator:
...     print(array_index, chunk)
0 [[0]]
0 [[1]]
0 [[2]]
1 [[4]]
1 [[5]]
1 [[6]]

logger¶: The logger for this class instance

n_chunks(chunksize, stride=1, skip=0)¶

how many chunks an iterator of this sourcde will output, starting (eg. after calling reset())

Parameters

chunksize –
stride –
skip –

n_frames_total(stride=1, skip=0)¶

Returns total number of frames.

Parameters

stride (int) – return value is the number of frames in trajectories when running through them with a step size of stride.
skip (int, default=0) – skip the first initial n frames per trajectory.

Returns

n_frames_total – total number of frames.

Return type

int

name¶: The name of this instance

number_of_trajectories(stride=1)¶

Returns the number of trajectories.

Parameters: stride (None (default) or np.ndarray) –
Returns: int
Return type: number of trajectories

output_type()¶: By default transformers return single precision floats.

ra_itraj_cuboid¶

Implementation of random access with slicing that can be up to 3-dimensional, where the first dimension corresponds to the trajectory index, the second dimension corresponds to the frames and the third dimension corresponds to the dimensions of the frames.

The with the frame slice selected frames will be loaded from each in the trajectory-slice selected trajectories and then sliced with the dimension slice. For example: The data consists out of three trajectories with length 10, 20, 10, respectively. The slice data[:, :15, :3] returns a 3D array of shape (3, 10, 3), where the first component corresponds to the three trajectories, the second component corresponds to 10 frames (note that the last 5 frames are being truncated as the other two trajectories only have 10 frames) and the third component corresponds to the selected first three dimensions.

Returns: Returns an object that allows access by slices in the described manner.

ra_itraj_jagged¶

Behaves like ra_itraj_cuboid just that the trajectories are not truncated and returned as a list.

Returns: Returns an object that allows access by slices in the described manner.

ra_itraj_linear¶

Implementation of random access that takes arguments as the default random access (i.e., up to three dimensions with trajs, frames and dims, respectively), but which considers the frame indexing to be contiguous. Therefore, it returns a simple 2D array.

Returns: A 2D array of the sliced data containing [frames, dims].

ra_linear¶

Implementation of random access that takes a (maximal) two-dimensional slice where the first component corresponds to the frames and the second component corresponds to the dimensions. Here it is assumed that the frame indexing is contiguous, i.e., the first frame of the second trajectory has the index of the last frame of the first trajectory plus one.

Returns: Returns an object that allows access by slices in the described manner.

trajectory_length(itraj, stride=1, skip=0)¶

Returns the length of trajectory of the requested index.

Parameters

itraj (int) – trajectory index
stride (int) – return value is the number of frames in the trajectory when running through it with a step size of stride.
skip (int or None) – skip n frames.

Returns

int

Return type

length of trajectory

trajectory_lengths(stride=1, skip=0)¶

Returns the length of each trajectory.

Parameters

stride (int) – return value is the number of frames of the trajectories when running through them with a step size of stride.
skip (int) – skip parameter

Returns

array(dtype=int)

Return type

containing length of each trajectory

transform(X)¶

Maps the input data through the transformer to correspondingly shaped output data array/list.

Parameters: X (ndarray(T, n) or list of ndarray(T_i, n)) – The input data, where T is the number of time steps and n is the number of dimensions. If a list is provided, the number of time steps is allowed to vary, but the number of dimensions are required to be to be consistent.
Returns: Y – The mapped data, where T is the number of time steps of the input data and d is the output dimension of this transformer. If called with a list of trajectories, Y will also be a corresponding list of trajectories
Return type: ndarray(T, d) or list of ndarray(T_i, d)

write_to_csv(filename=None, extension='.dat', overwrite=False, stride=1, chunksize=None, **kw)¶

write all data to csv with numpy.savetxt

Parameters

filename (str, optional) –
filename string, which may contain placeholders {itraj} and {stride}:
- itraj will be replaced by trajetory index
- stride is stride argument of this method
If filename is not given, it is being tried to obtain the filenames from the data source of this iterator.
extension (str, optional, default='.dat') – filename extension of created files
overwrite (bool, optional, default=False) – shall existing files be overwritten? If a file exists, this method will raise.
stride (int) – omit every n’th frame
chunksize (int, default=None) – how many frames to process at once
kw (dict, optional) – named arguments passed into numpy.savetxt (header, seperator etc.)

Example

Assume you want to save features calculated by some FeatureReader to ASCII:

>>> import numpy as np, pyemma
>>> import os
>>> from pyemma.util.files import TemporaryDirectory
>>> from pyemma.util.contexts import settings
>>> data = [np.random.random((10,3))] * 3
>>> reader = pyemma.coordinates.source(data)
>>> filename = "distances_{itraj}.dat"
>>> with TemporaryDirectory() as td, settings(show_progress_bars=False):
...    out = os.path.join(td, filename)
...    reader.write_to_csv(out, header='', delimiter=';')
...    print(sorted(os.listdir(td)))
['distances_0.dat', 'distances_1.dat', 'distances_2.dat']

write_to_hdf5(filename, group='/', data_set_prefix='', overwrite=False, stride=1, chunksize=None, h5_opt=None)¶

writes all data of this Iterable to a given HDF5 file. This is equivalent of writing the result of func:pyemma.coordinates.data._base.DataSource.get_output to a file.

Parameters

filename (str) – file name of output HDF5 file
group (str, default='/') – write all trajectories to this HDF5 group. The group name may not already exist in the file.
data_set_prefix (str, default=None) – data set name prefix, will postfixed with the index of the trajectory.
overwrite (bool, default=False) – if group and data sets already exist, shall we overwrite data?
stride (int, default=1) – stride argument to iterator
chunksize (int, default=None) – how many frames to process at once
h5_opt (dict) – optional parameters for h5py.create_dataset

Notes

You can pass the following via h5_opt to enable compression/filters/shuffling etc:

chunks: (Tuple) Chunk shape, or True to enable auto-chunking.
maxshape: (Tuple) Make the dataset resizable up to this shape. Use None for axes you want to be unlimited.
compression: (String or int) Compression strategy. Legal values are ‘gzip’, ‘szip’, ‘lzf’. If an integer in range(10), this indicates gzip compression level. Otherwise, an integer indicates the number of a dynamically loaded compression filter.
compression_opts: Compression settings. This is an integer for gzip, 2-tuple for szip, etc. If specifying a dynamically loaded compression filter number, this must be a tuple of values.
scaleoffset: (Integer) Enable scale/offset filter for (usually) lossy compression of integer or floating-point data. For integer data, the value of scaleoffset is the number of bits to retain (pass 0 to let HDF5 determine the minimum number of bits necessary for lossless compression). For floating point data, scaleoffset is the number of digits after the decimal place to retain; stored values thus have absolute error less than 0.5*10**(-scaleoffset).
shuffle: (T/F) Enable shuffle filter. Only effective in combination with chunks.
fletcher32: (T/F) Enable fletcher32 error detection. Not permitted in conjunction with the scale/offset filter.
fillvalue: (Scalar) Use this value for uninitialized parts of the dataset.
track_times: (T/F) Enable dataset creation timestamps.