"""
Module to read / write Fortran unformatted sequential files.
This is in the spirit of code written by Neil Martinsen-Burrell and Joe Zuntz.
"""
from __future__ import division, print_function, absolute_import
import warnings
import numpy as np
__all__ = ['FortranFile']
class FortranFile(object):
"""
A file object for unformatted sequential files from Fortran code.
Parameters
----------
filename : file or str
Open file object or filename.
mode : {'r', 'w'}, optional
Read-write mode, default is 'r'.
header_dtype : dtype, optional
Data type of the header. Size and endiness must match the input/output file.
Notes
-----
These files are broken up into records of unspecified types. The size of
each record is given at the start (although the size of this header is not
standard) and the data is written onto disk without any formatting. Fortran
compilers supporting the BACKSPACE statement will write a second copy of
the size to facilitate backwards seeking.
This class only supports files written with both sizes for the record.
It also does not support the subrecords used in Intel and gfortran compilers
for records which are greater than 2GB with a 4-byte header.
An example of an unformatted sequential file in Fortran would be written as::
OPEN(1, FILE=myfilename, FORM='unformatted')
WRITE(1) myvariable
Since this is a non-standard file format, whose contents depend on the
compiler and the endianness of the machine, caution is advised. Files from
gfortran 4.8.0 and gfortran 4.1.2 on x86_64 are known to work.
Consider using Fortran direct-access files or files from the newer Stream
I/O, which can be easily read by `numpy.fromfile`.
Examples
--------
To create an unformatted sequential Fortran file:
>>> from scipy.io import FortranFile
>>> f = FortranFile('test.unf', 'w')
>>> f.write_record(np.array([1,2,3,4,5], dtype=np.int32))
>>> f.write_record(np.linspace(0,1,20).reshape((5,4)).T)
>>> f.close()
To read this file:
>>> f = FortranFile('test.unf', 'r')
>>> print(f.read_ints(np.int32))
[1 2 3 4 5]
>>> print(f.read_reals(float).reshape((5,4), order="F"))
[[0. 0.05263158 0.10526316 0.15789474]
[0.21052632 0.26315789 0.31578947 0.36842105]
[0.42105263 0.47368421 0.52631579 0.57894737]
[0.63157895 0.68421053 0.73684211 0.78947368]
[0.84210526 0.89473684 0.94736842 1. ]]
>>> f.close()
Or, in Fortran::
integer :: a(5), i
double precision :: b(5,4)
open(1, file='test.unf', form='unformatted')
read(1) a
read(1) b
close(1)
write(*,*) a
do i = 1, 5
write(*,*) b(i,:)
end do
"""
def __init__(self, filename, mode='r', header_dtype=np.uint32):
if header_dtype is None:
raise ValueError('Must specify dtype')
header_dtype = np.dtype(header_dtype)
if header_dtype.kind != 'u':
warnings.warn("Given a dtype which is not unsigned.")
if mode not in 'rw' or len(mode) != 1:
raise ValueError('mode must be either r or w')
if hasattr(filename, 'seek'):
self._fp = filename
else:
self._fp = open(filename, '%sb' % mode)
self._header_dtype = header_dtype
def _read_size(self):
return int(np.fromfile(self._fp, dtype=self._header_dtype, count=1))
def write_record(self, *items):
"""
Write a record (including sizes) to the file.
Parameters
----------
*items : array_like
The data arrays to write.
Notes
-----
Writes data items to a file::
write_record(a.T, b.T, c.T, ...)
write(1) a, b, c, ...
Note that data in multidimensional arrays is written in
row-major order --- to make them read correctly by Fortran
programs, you need to transpose the arrays yourself when
writing them.
"""
items = tuple(np.asarray(item) for item in items)
total_size = sum(item.nbytes for item in items)
nb = np.array([total_size], dtype=self._header_dtype)
nb.tofile(self._fp)
for item in items:
item.tofile(self._fp)
nb.tofile(self._fp)
def read_record(self, *dtypes, **kwargs):
"""
Reads a record of a given type from the file.
Parameters
----------
*dtypes : dtypes, optional
Data type(s) specifying the size and endiness of the data.
Returns
-------
data : ndarray
A one-dimensional array object.
Notes
-----
If the record contains a multi-dimensional array, you can specify
the size in the dtype. For example::
INTEGER var(5,4)
can be read with::
read_record('(4,5)i4').T
Note that this function does **not** assume the file data is in Fortran
column major order, so you need to (i) swap the order of dimensions
when reading and (ii) transpose the resulting array.
Alternatively, you can read the data as a 1D array and handle the
ordering yourself. For example::
read_record('i4').reshape(5, 4, order='F')
For records that contain several variables or mixed types (as opposed
to single scalar or array types), give them as separate arguments::
double precision :: a
integer :: b
write(1) a, b
record = f.read_record('<f4', '<i4')
a = record[0] # first number
b = record[1] # second number
and if any of the variables are arrays, the shape can be specified as
the third item in the relevant dtype::
double precision :: a
integer :: b(3,4)
write(1) a, b
record = f.read_record('<f4', np.dtype(('<i4', (4, 3))))
a = record[0]
b = record[1].T
Numpy also supports a short syntax for this kind of type::
record = f.read_record('<f4', '(3,3)<i4')
See Also
--------
read_reals
read_ints
"""
dtype = kwargs.pop('dtype', None)
if kwargs:
raise ValueError("Unknown keyword arguments {}".format(tuple(kwargs.keys())))
if dtype is not None:
dtypes = dtypes + (dtype,)
elif not dtypes:
raise ValueError('Must specify at least one dtype')
first_size = self._read_size()
dtypes = tuple(np.dtype(dtype) for dtype in dtypes)
block_size = sum(dtype.itemsize for dtype in dtypes)
num_blocks, remainder = divmod(first_size, block_size)
if remainder != 0:
raise ValueError('Size obtained ({0}) is not a multiple of the '
'dtypes given ({1}).'.format(first_size, block_size))
if len(dtypes) != 1 and first_size != block_size:
# Fortran does not write mixed type array items in interleaved order,
# and it's not possible to guess the sizes of the arrays that were written.
# The user must specify the exact sizes of each of the arrays.
raise ValueError('Size obtained ({0}) does not match with the expected '
'size ({1}) of multi-item record'.format(first_size, block_size))
data = []
for dtype in dtypes:
r = np.fromfile(self._fp, dtype=dtype, count=num_blocks)
if dtype.shape != ():
# Squeeze outmost block dimension for array items
if num_blocks == 1:
assert r.shape == (1,) + dtype.shape
r = r[0]
data.append(r)
second_size = self._read_size()
if first_size != second_size:
raise IOError('Sizes do not agree in the header and footer for '
'this record - check header dtype')
# Unpack result
if len(dtypes) == 1:
return data[0]
else:
return tuple(data)
def read_ints(self, dtype='i4'):
"""
Reads a record of a given type from the file, defaulting to an integer
type (``INTEGER*4`` in Fortran).
Parameters
----------
dtype : dtype, optional
Data type specifying the size and endiness of the data.
Returns
-------
data : ndarray
A one-dimensional array object.
See Also
--------
read_reals
read_record
"""
return self.read_record(dtype)
def read_reals(self, dtype='f8'):
"""
Reads a record of a given type from the file, defaulting to a floating
point number (``real*8`` in Fortran).
Parameters
----------
dtype : dtype, optional
Data type specifying the size and endiness of the data.
Returns
-------
data : ndarray
A one-dimensional array object.
See Also
--------
read_ints
read_record
"""
return self.read_record(dtype)
def close(self):
"""
Closes the file. It is unsupported to call any other methods off this
object after closing it. Note that this class supports the 'with'
statement in modern versions of Python, to call this automatically
"""
self._fp.close()
def __enter__(self):
return self
def __exit__(self, type, value, tb):
self.close()