view transformations/filetensor.py @ 41:fdb0e0870fb4

Beaucoup de modifications à pipeline.py pour généraliser et un début de visualisation, et créé un wrapper (run_pipeline.py) pour appeler avec GIMP. - Modifications à pipeline.py - Wrappé la boucle du pipeline dans une classe - Isolé le problème de itérer sur les batches et les complexités dans des itérateurs - Permet d'avoir des ordres compliqués de batch (plusieurs sources), de complexités - Maintenant regenerate_parameters() est appelé pour chaque image. - Command line arguments avec getopt(). On pourra rajouter des options ainsi. - run_pipeline.py - Le but est de permettre de passer des arguments. Pas facile (pas trouvé comment de façon simple) avec la command line pour appeler GIMP en mode batch. C'est un hack ici. - Le but ultime est de permettre de lancer les jobs sur les clusters avec dbidispatch en précisant les options (diff. pour chaque job) sur la ligne de commande.
author fsavard
date Wed, 03 Feb 2010 17:08:27 -0500
parents faacc76d21c2
children
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"""
Read and write the matrix file format described at
U{http://www.cs.nyu.edu/~ylclab/data/norb-v1.0/index.html}

The format is for dense tensors:

    - magic number indicating type and endianness - 4bytes
    - rank of tensor - int32
    - dimensions - int32, int32, int32, ...
    - <data>

The number of dimensions and rank is slightly tricky: 
    - for scalar: rank=0, dimensions = [1, 1, 1]
    - for vector: rank=1, dimensions = [?, 1, 1]
    - for matrix: rank=2, dimensions = [?, ?, 1]

For rank >= 3, the number of dimensions matches the rank exactly.


@todo: add complex type support

"""
import sys
import numpy

def _prod(lst):
    p = 1
    for l in lst:
        p *= l
    return p

_magic_dtype = {
        0x1E3D4C51 : ('float32', 4),
        #0x1E3D4C52 : ('packed matrix', 0), #what is a packed matrix?
        0x1E3D4C53 : ('float64', 8),
        0x1E3D4C54 : ('int32', 4),
        0x1E3D4C55 : ('uint8', 1),
        0x1E3D4C56 : ('int16', 2),
        }
_dtype_magic = {
        'float32': 0x1E3D4C51,
        #'packed matrix': 0x1E3D4C52,
        'float64': 0x1E3D4C53,
        'int32': 0x1E3D4C54,
        'uint8': 0x1E3D4C55,
        'int16': 0x1E3D4C56
        }

def _read_int32(f):
    """unpack a 4-byte integer from the current position in file f"""
    s = f.read(4)
    s_array = numpy.fromstring(s, dtype='int32')
    return s_array.item()

def _read_header(f, debug=False):
    """
    :returns: data type, element size, rank, shape, size
    """
    #what is the data type of this matrix?
    #magic_s = f.read(4)
    #magic = numpy.fromstring(magic_s, dtype='int32')
    magic = _read_int32(f)
    magic_t, elsize = _magic_dtype[magic]
    if debug: 
        print 'header magic', magic, magic_t, elsize
    if magic_t == 'packed matrix':
        raise NotImplementedError('packed matrix not supported')

    #what is the rank of the tensor?
    ndim = _read_int32(f)
    if debug: print 'header ndim', ndim

    #what are the dimensions of the tensor?
    dim = numpy.fromfile(f, dtype='int32', count=max(ndim,3))[:ndim]
    dim_size = _prod(dim)
    if debug: print 'header dim', dim, dim_size

    return magic_t, elsize, ndim, dim, dim_size

class arraylike(object):
    """Provide an array-like interface to the filetensor in f.

    The rank parameter to __init__ controls how this object interprets the underlying tensor.
    Its behaviour should be clear from the following example.
    Suppose the underlying tensor is MxNxK.

    - If rank is 0, self[i] will be a scalar and len(self) == M*N*K.

    - If rank is 1, self[i] is a vector of length K, and len(self) == M*N.

    - If rank is 3, self[i] is a 3D tensor of size MxNxK, and len(self)==1.

    - If rank is 5, self[i] is a 5D tensor of size 1x1xMxNxK, and len(self) == 1.


    :note: Objects of this class generally require exclusive use of the underlying file handle, because
    they call seek() every time you access an element.
    """

    f = None 
    """File-like object"""

    magic_t = None
    """numpy data type of array"""

    elsize = None
    """number of bytes per scalar element"""

    ndim = None
    """Rank of underlying tensor"""

    dim = None
    """tuple of array dimensions (aka shape)"""

    dim_size = None
    """number of scalars in the tensor (prod of dim)"""

    f_start = None
    """The file position of the first element of the tensor"""

    readshape = None
    """tuple of array dimensions of the block that we read"""

    readsize = None
    """number of elements we must read for each block"""
    
    def __init__(self, f, rank=0, debug=False):
        self.f = f
        self.magic_t, self.elsize, self.ndim, self.dim, self.dim_size = _read_header(f,debug)
        self.f_start = f.tell()

        if rank <= self.ndim:
          self.readshape = tuple(self.dim[self.ndim-rank:])
        else:
          self.readshape = tuple(self.dim)

        #self.readshape = tuple(self.dim[self.ndim-rank:]) if rank <= self.ndim else tuple(self.dim)

        if rank <= self.ndim:
          padding = tuple()
        else:
          padding = (1,) * (rank - self.ndim)

        #padding = tuple() if rank <= self.ndim else (1,) * (rank - self.ndim)
        self.returnshape = padding + self.readshape
        self.readsize = _prod(self.readshape)
        if debug: print 'READ PARAM', self.readshape, self.returnshape, self.readsize

    def __len__(self):
        return _prod(self.dim[:self.ndim-len(self.readshape)])

    def __getitem__(self, idx):
        if idx >= len(self):
            raise IndexError(idx)
        self.f.seek(self.f_start + idx * self.elsize * self.readsize)
        return numpy.fromfile(self.f, 
                dtype=self.magic_t, 
                count=self.readsize).reshape(self.returnshape)


#
# TODO: implement item selection:
#  e.g. load('some mat', subtensor=(:6, 2:5))
#
#  This function should be memory efficient by:
#  - allocating an output matrix at the beginning
#  - seeking through the file, reading subtensors from multiple places
def read(f, subtensor=None, debug=False):
    """Load all or part of file 'f' into a numpy ndarray

    @param f: file from which to read
    @type f: file-like object

    If subtensor is not None, it should be like the argument to
    numpy.ndarray.__getitem__.  The following two expressions should return
    equivalent ndarray objects, but the one on the left may be faster and more
    memory efficient if the underlying file f is big.

        read(f, subtensor) <===> read(f)[*subtensor]
    
    Support for subtensors is currently spotty, so check the code to see if your
    particular type of subtensor is supported.

    """
    magic_t, elsize, ndim, dim, dim_size = _read_header(f,debug)
    f_start = f.tell()

    rval = None
    if subtensor is None:
        rval = numpy.fromfile(f, dtype=magic_t, count=_prod(dim)).reshape(dim)
    elif isinstance(subtensor, slice):
        if subtensor.step not in (None, 1):
            raise NotImplementedError('slice with step', subtensor.step)
        if subtensor.start not in (None, 0):
            bytes_per_row = _prod(dim[1:]) * elsize
            f.seek(f_start + subtensor.start * bytes_per_row)
        dim[0] = min(dim[0], subtensor.stop) - subtensor.start
        rval = numpy.fromfile(f, dtype=magic_t, count=_prod(dim)).reshape(dim)
    else:
        raise NotImplementedError('subtensor access not written yet:', subtensor) 

    return rval

def write(f, mat):
    """Write a numpy.ndarray to file.

    @param f: file into which to write
    @type f: file-like object

    @param mat: array to write to file
    @type mat: numpy ndarray or compatible

    """
    def _write_int32(f, i):
        i_array = numpy.asarray(i, dtype='int32')
        if 0: print 'writing int32', i, i_array
        i_array.tofile(f)

    try:
        _write_int32(f, _dtype_magic[str(mat.dtype)])
    except KeyError:
        raise TypeError('Invalid ndarray dtype for filetensor format', mat.dtype)

    _write_int32(f, len(mat.shape))
    shape = mat.shape
    if len(shape) < 3:
        shape = list(shape) + [1] * (3 - len(shape))
    if 0: print 'writing shape =', shape
    for sh in shape:
        _write_int32(f, sh)
    mat.tofile(f)