.. currentmodule:: asdf
Saving arrays
-------------
Beyond the basic data types of dictionaries, lists, strings and numbers, the
most important thing ASDF can save is arrays. It's as simple as putting a
:mod:`numpy` array somewhere in the tree. Here, we save an 8x8 array of random
floating-point numbers (using `numpy.random.rand`). Note that the resulting
YAML output contains information about the structure (size and data type) of
the array, but the actual array content is in a binary block.
.. runcode::
from asdf import AsdfFile
import numpy as np
tree = {'my_array': np.random.rand(8, 8)}
ff = AsdfFile(tree)
ff.write_to("test.asdf")
.. note::
In the file examples below, the first YAML part appears as it
appears in the file. The ``BLOCK`` sections are stored as binary
data in the file, but are presented in human-readable form on this
page.
.. asdf:: test.asdf
Sharing of data
---------------
Arrays that are views on the same data automatically share the same
data in the file. In this example an array and a subview on that same
array are saved to the same file, resulting in only a single block of
data being saved.
.. runcode::
from asdf import AsdfFile
import numpy as np
my_array = np.random.rand(8, 8)
subset = my_array[2:4,3:6]
tree = {
'my_array': my_array,
'subset': subset
}
ff = AsdfFile(tree)
ff.write_to("test.asdf")
.. asdf:: test.asdf
Saving inline arrays
--------------------
For small arrays, you may not care about the efficiency of a binary
representation and just want to save the array contents directly in the YAML
tree. The `~asdf.AsdfFile.set_array_storage` method can be used to set the
storage type of the associated data. The allowed values are ``internal``,
``external``, and ``inline``.
- ``internal``: The default. The array data will be
stored in a binary block in the same ASDF file.
- ``external``: Store the data in a binary block in a separate ASDF file (also
known as "exploded" format, which discussed below in :ref:`exploded`).
- ``inline``: Store the data as YAML inline in the tree.
.. runcode::
from asdf import AsdfFile
import numpy as np
my_array = np.random.rand(8, 8)
tree = {'my_array': my_array}
ff = AsdfFile(tree)
ff.set_array_storage(my_array, 'inline')
ff.write_to("test.asdf")
.. asdf:: test.asdf
Alternatively, it is possible to use the ``all_array_storage`` parameter of
`AsdfFile.write_to` and `AsdfFile.update` to control the storage
format of all arrays in the file.
.. code::
# This controls the output format of all arrays in the file
ff.write_to("test.asdf", all_array_storage='inline')
For automatic management of the array storage type based on number of elements,
see :ref:`config_options_array_inline_threshold`.
.. _exploded:
Saving external arrays
----------------------
ASDF files may also be saved in "exploded form", which creats multiple files
corresponding to the following data items:
- One ASDF file containing only the header and tree.
- *n* ASDF files, each containing a single array data block.
Exploded form is useful in the following scenarios:
- Over a network protocol, such as HTTP, a client may only need to
access some of the blocks. While reading a subset of the file can
be done using HTTP ``Range`` headers, it still requires one (small)
request per block to "jump" through the file to determine the start
location of each block. This can become time-consuming over a
high-latency network if there are many blocks. Exploded form allows
each block to be requested directly by a specific URI.
- An ASDF writer may stream a table to disk, when the size of the table
is not known at the outset. Using exploded form simplifies this,
since a standalone file containing a single table can be iteratively
appended to without worrying about any blocks that may follow it.
To save a block in an external file, set its block type to
``'external'``.
.. runcode::
from asdf import AsdfFile
import numpy as np
my_array = np.random.rand(8, 8)
tree = {'my_array': my_array}
ff = AsdfFile(tree)
# On an individual block basis:
ff.set_array_storage(my_array, 'external')
ff.write_to("test.asdf")
# Or for every block:
ff.write_to("test.asdf", all_array_storage='external')
.. asdf:: test.asdf
.. asdf:: test0000.asdf
Streaming array data
--------------------
In certain scenarios, you may want to stream data to disk, rather than
writing an entire array of data at once. For example, it may not be
possible to fit the entire array in memory, or you may want to save
data from a device as it comes in to prevent data loss. The ASDF
Standard allows exactly one streaming block per file where the size of
the block isn't included in the block header, but instead is
implicitly determined to include all of the remaining contents of the
file. By definition, it must be the last block in the file.
To use streaming, rather than including a Numpy array object in the
tree, you include a `asdf.Stream` object which sets up the structure
of the streamed data, but will not write out the actual content. The
file handle's `write` method is then used to manually write out the
binary data.
.. runcode::
from asdf import AsdfFile, Stream
import numpy as np
tree = {
# Each "row" of data will have 128 entries.
'my_stream': Stream([128], np.float64)
}
ff = AsdfFile(tree)
with open('test.asdf', 'wb') as fd:
ff.write_to(fd)
# Write 100 rows of data, one row at a time. ``write``
# expects the raw binary bytes, not an array, so we use
# ``tobytes()``.
for i in range(100):
fd.write(np.array([i] * 128, np.float64).tobytes())
.. asdf:: test.asdf
A case where streaming may be useful is when converting large data sets from a
different format into ASDF. In these cases it would be impractical to hold all
of the data in memory as an intermediate step. Consider the following example
that streams a large CSV file containing rows of integer data and converts it
to numpy arrays stored in ASDF:
.. doctest-skip::
import csv
import numpy as np
from asdf import AsdfFile, Stream
tree = {
# We happen to know in advance that each row in the CSV has 100 ints
'data': Stream([100], np.int64)
}
ff = AsdfFile(tree)
# open the output file handle
with open('new_file.asdf', 'wb') as fd:
ff.write_to(fd)
# open the CSV file to be converted
with open('large_file.csv', 'r') as cfd:
# read each line of the CSV file
reader = csv.reader(cfd)
for row in reader:
# convert each row to a numpy array
array = np.array([int(x) for x in row], np.int64)
# write the array to the output file handle
fd.write(array.tobytes())
Compression
-----------
Individual blocks in an ASDF file may be compressed.
You can easily `zlib `__ or `bzip2
`__ compress all blocks:
.. runcode::
from asdf import AsdfFile
import numpy as np
tree = {
'a': np.random.rand(32, 32),
'b': np.random.rand(64, 64)
}
target = AsdfFile(tree)
target.write_to('target.asdf', all_array_compression='zlib')
target.write_to('target.asdf', all_array_compression='bzp2')
.. asdf:: target.asdf
The `lz4 `__ compression algorithm is also
supported, but requires the optional
`lz4 `__ package in order to work.
When reading a file with compressed blocks, the blocks will be automatically
decompressed when accessed. If a file with compressed blocks is read and then
written out again, by default the new file will use the same compression as the
original file. This behavior can be overridden by explicitly providing a
different compression algorithm when writing the file out again.
.. code::
import asdf
# Open a file with some compression
af = asdf.open('compressed.asdf')
# Use the same compression when writing out a new file
af.write_to('same.asdf')
# Or specify the (possibly different) algorithm to use when writing out
af.write_to('different.asdf', all_array_compression='lz4')
Memory mapping
--------------
By default, all internal array data is memory mapped using `numpy.memmap`. This
allows for the efficient use of memory even when reading files with very large
arrays. The use of memory mapping means that the following usage pattern is not
permitted:
.. code::
import asdf
with asdf.open('my_data.asdf') as af:
...
af.tree
Specifically, if an ASDF file has been opened using a `with` context, it is not
possible to access the file contents outside of the scope of that context,
because any memory mapped arrays will no longer be available.
It may sometimes be useful to copy array data into memory instead of using
memory maps. This can be controlled by passing the `copy_arrays` parameter to
either the `AsdfFile` constructor or `asdf.open`. By default,
`copy_arrays=False`.