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	# IDLSave - a python module to read IDL 'save' files
	# Copyright (c) 2010 Thomas P. Robitaille

	# Many thanks to Craig Markwardt for publishing the Unofficial Format
	# Specification for IDL .sav files, without which this Python module would not
	# exist (http://cow.physics.wisc.edu/~craigm/idl/savefmt).

	# This code was developed by with permission from ITT Visual Information
	# Systems. IDL(r) is a registered trademark of ITT Visual Information Systems,
	# Inc. for their Interactive Data Language software.

	# Permission is hereby granted, free of charge, to any person obtaining a
	# copy of this software and associated documentation files (the "Software"),
	# to deal in the Software without restriction, including without limitation
	# the rights to use, copy, modify, merge, publish, distribute, sublicense,
	# and/or sell copies of the Software, and to permit persons to whom the
	# Software is furnished to do so, subject to the following conditions:

	# The above copyright notice and this permission notice shall be included in
	# all copies or substantial portions of the Software.

	# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
	# FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
	# DEALINGS IN THE SOFTWARE.

	__all__ = ['readsav']

	import struct
	import numpy as np
	import tempfile
	import zlib
	import warnings

	# Define the different data types that can be found in an IDL save file
	DTYPE_DICT = {1: '>u1',
	2: '>i2',
	3: '>i4',
	4: '>f4',
	5: '>f8',
	6: '>c8',
	7: '\|O',
	8: '\|O',
	9: '>c16',
	10: '\|O',
	11: '\|O',
	12: '>u2',
	13: '>u4',
	14: '>i8',
	15: '>u8'}

	# Define the different record types that can be found in an IDL save file
	RECTYPE_DICT = {0: "START_MARKER",
	1: "COMMON_VARIABLE",
	2: "VARIABLE",
	3: "SYSTEM_VARIABLE",
	6: "END_MARKER",
	10: "TIMESTAMP",
	12: "COMPILED",
	13: "IDENTIFICATION",
	14: "VERSION",
	15: "HEAP_HEADER",
	16: "HEAP_DATA",
	17: "PROMOTE64",
	19: "NOTICE",
	20: "DESCRIPTION"}

	# Define a dictionary to contain structure definitions
	STRUCT_DICT = {}


	def _align_32(f):
	'''Align to the next 32-bit position in a file'''

	pos = f.tell()
	if pos % 4 != 0:
	f.seek(pos + 4 - pos % 4)
	return


	def _skip_bytes(f, n):
	'''Skip `n` bytes'''
	f.read(n)
	return


	def _read_bytes(f, n):
	'''Read the next `n` bytes'''
	return f.read(n)


	def _read_byte(f):
	'''Read a single byte'''
	return np.uint8(struct.unpack('>B', f.read(4)[:1])[0])


	def _read_long(f):
	'''Read a signed 32-bit integer'''
	return np.int32(struct.unpack('>l', f.read(4))[0])


	def _read_int16(f):
	'''Read a signed 16-bit integer'''
	return np.int16(struct.unpack('>h', f.read(4)[2:4])[0])


	def _read_int32(f):
	'''Read a signed 32-bit integer'''
	return np.int32(struct.unpack('>i', f.read(4))[0])


	def _read_int64(f):
	'''Read a signed 64-bit integer'''
	return np.int64(struct.unpack('>q', f.read(8))[0])


	def _read_uint16(f):
	'''Read an unsigned 16-bit integer'''
	return np.uint16(struct.unpack('>H', f.read(4)[2:4])[0])


	def _read_uint32(f):
	'''Read an unsigned 32-bit integer'''
	return np.uint32(struct.unpack('>I', f.read(4))[0])


	def _read_uint64(f):
	'''Read an unsigned 64-bit integer'''
	return np.uint64(struct.unpack('>Q', f.read(8))[0])


	def _read_float32(f):
	'''Read a 32-bit float'''
	return np.float32(struct.unpack('>f', f.read(4))[0])


	def _read_float64(f):
	'''Read a 64-bit float'''
	return np.float64(struct.unpack('>d', f.read(8))[0])


	class Pointer:
	'''Class used to define pointers'''

	def __init__(self, index):
	self.index = index
	return


	class ObjectPointer(Pointer):
	'''Class used to define object pointers'''
	pass


	def _read_string(f):
	'''Read a string'''
	length = _read_long(f)
	if length > 0:
	chars = _read_bytes(f, length).decode('latin1')
	_align_32(f)
	else:
	chars = ''
	return chars


	def _read_string_data(f):
	'''Read a data string (length is specified twice)'''
	length = _read_long(f)
	if length > 0:
	length = _read_long(f)
	string_data = _read_bytes(f, length)
	_align_32(f)
	else:
	string_data = ''
	return string_data


	def _read_data(f, dtype):
	'''Read a variable with a specified data type'''
	if dtype == 1:
	if _read_int32(f) != 1:
	raise Exception("Error occurred while reading byte variable")
	return _read_byte(f)
	elif dtype == 2:
	return _read_int16(f)
	elif dtype == 3:
	return _read_int32(f)
	elif dtype == 4:
	return _read_float32(f)
	elif dtype == 5:
	return _read_float64(f)
	elif dtype == 6:
	real = _read_float32(f)
	imag = _read_float32(f)
	return np.complex64(real + imag * 1j)
	elif dtype == 7:
	return _read_string_data(f)
	elif dtype == 8:
	raise Exception("Should not be here - please report this")
	elif dtype == 9:
	real = _read_float64(f)
	imag = _read_float64(f)
	return np.complex128(real + imag * 1j)
	elif dtype == 10:
	return Pointer(_read_int32(f))
	elif dtype == 11:
	return ObjectPointer(_read_int32(f))
	elif dtype == 12:
	return _read_uint16(f)
	elif dtype == 13:
	return _read_uint32(f)
	elif dtype == 14:
	return _read_int64(f)
	elif dtype == 15:
	return _read_uint64(f)
	else:
	raise Exception("Unknown IDL type: %i - please report this" % dtype)


	def _read_structure(f, array_desc, struct_desc):
	'''
	Read a structure, with the array and structure descriptors given as
	`array_desc` and `structure_desc` respectively.
	'''

	nrows = array_desc['nelements']
	columns = struct_desc['tagtable']

	dtype = []
	for col in columns:
	if col['structure'] or col['array']:
	dtype.append(((col['name'].lower(), col['name']), np.object_))
	else:
	if col['typecode'] in DTYPE_DICT:
	dtype.append(((col['name'].lower(), col['name']),
	DTYPE_DICT[col['typecode']]))
	else:
	raise Exception("Variable type %i not implemented" %
	col['typecode'])

	structure = np.rec.recarray((nrows, ), dtype=dtype)

	for i in range(nrows):
	for col in columns:
	dtype = col['typecode']
	if col['structure']:
	structure[col['name']][i] = _read_structure(f,
	struct_desc['arrtable'][col['name']],
	struct_desc['structtable'][col['name']])
	elif col['array']:
	structure[col['name']][i] = _read_array(f, dtype,
	struct_desc['arrtable'][col['name']])
	else:
	structure[col['name']][i] = _read_data(f, dtype)

	# Reshape structure if needed
	if array_desc['ndims'] > 1:
	dims = array_desc['dims'][:int(array_desc['ndims'])]
	dims.reverse()
	structure = structure.reshape(dims)

	return structure


	def _read_array(f, typecode, array_desc):
	'''
	Read an array of type `typecode`, with the array descriptor given as
	`array_desc`.
	'''

	if typecode in [1, 3, 4, 5, 6, 9, 13, 14, 15]:

	if typecode == 1:
	nbytes = _read_int32(f)
	if nbytes != array_desc['nbytes']:
	warnings.warn("Not able to verify number of bytes from header",
	stacklevel=3)

	# Read bytes as numpy array
	array = np.frombuffer(f.read(array_desc['nbytes']),
	dtype=DTYPE_DICT[typecode])

	elif typecode in [2, 12]:

	# These are 2 byte types, need to skip every two as they are not packed

	array = np.frombuffer(f.read(array_desc['nbytes']*2),
	dtype=DTYPE_DICT[typecode])[1::2]

	else:

	# Read bytes into list
	array = []
	for i in range(array_desc['nelements']):
	dtype = typecode
	data = _read_data(f, dtype)
	array.append(data)

	array = np.array(array, dtype=np.object_)

	# Reshape array if needed
	if array_desc['ndims'] > 1:
	dims = array_desc['dims'][:int(array_desc['ndims'])]
	dims.reverse()
	array = array.reshape(dims)

	# Go to next alignment position
	_align_32(f)

	return array


	def _read_record(f):
	'''Function to read in a full record'''

	record = {'rectype': _read_long(f)}

	nextrec = _read_uint32(f)
	nextrec += _read_uint32(f).astype(np.int64) * 2**32

	_skip_bytes(f, 4)

	if record['rectype'] not in RECTYPE_DICT:
	raise Exception("Unknown RECTYPE: %i" % record['rectype'])

	record['rectype'] = RECTYPE_DICT[record['rectype']]

	if record['rectype'] in ["VARIABLE", "HEAP_DATA"]:

	if record['rectype'] == "VARIABLE":
	record['varname'] = _read_string(f)
	else:
	record['heap_index'] = _read_long(f)
	_skip_bytes(f, 4)

	rectypedesc = _read_typedesc(f)

	if rectypedesc['typecode'] == 0:

	if nextrec == f.tell():
	record['data'] = None # Indicates NULL value
	else:
	raise ValueError("Unexpected type code: 0")

	else:

	varstart = _read_long(f)
	if varstart != 7:
	raise Exception("VARSTART is not 7")

	if rectypedesc['structure']:
	record['data'] = _read_structure(f, rectypedesc['array_desc'],
	rectypedesc['struct_desc'])
	elif rectypedesc['array']:
	record['data'] = _read_array(f, rectypedesc['typecode'],
	rectypedesc['array_desc'])
	else:
	dtype = rectypedesc['typecode']
	record['data'] = _read_data(f, dtype)

	elif record['rectype'] == "TIMESTAMP":

	_skip_bytes(f, 4*256)
	record['date'] = _read_string(f)
	record['user'] = _read_string(f)
	record['host'] = _read_string(f)

	elif record['rectype'] == "VERSION":

	record['format'] = _read_long(f)
	record['arch'] = _read_string(f)
	record['os'] = _read_string(f)
	record['release'] = _read_string(f)

	elif record['rectype'] == "IDENTIFICATON":

	record['author'] = _read_string(f)
	record['title'] = _read_string(f)
	record['idcode'] = _read_string(f)

	elif record['rectype'] == "NOTICE":

	record['notice'] = _read_string(f)

	elif record['rectype'] == "DESCRIPTION":

	record['description'] = _read_string_data(f)

	elif record['rectype'] == "HEAP_HEADER":

	record['nvalues'] = _read_long(f)
	record['indices'] = [_read_long(f) for _ in range(record['nvalues'])]

	elif record['rectype'] == "COMMONBLOCK":

	record['nvars'] = _read_long(f)
	record['name'] = _read_string(f)
	record['varnames'] = [_read_string(f) for _ in range(record['nvars'])]

	elif record['rectype'] == "END_MARKER":

	record['end'] = True

	elif record['rectype'] == "UNKNOWN":

	warnings.warn("Skipping UNKNOWN record", stacklevel=3)

	elif record['rectype'] == "SYSTEM_VARIABLE":

	warnings.warn("Skipping SYSTEM_VARIABLE record", stacklevel=3)

	else:

	raise Exception(f"record['rectype']={record['rectype']} not implemented")

	f.seek(nextrec)

	return record


	def _read_typedesc(f):
	'''Function to read in a type descriptor'''

	typedesc = {'typecode': _read_long(f), 'varflags': _read_long(f)}

	if typedesc['varflags'] & 2 == 2:
	raise Exception("System variables not implemented")

	typedesc['array'] = typedesc['varflags'] & 4 == 4
	typedesc['structure'] = typedesc['varflags'] & 32 == 32

	if typedesc['structure']:
	typedesc['array_desc'] = _read_arraydesc(f)
	typedesc['struct_desc'] = _read_structdesc(f)
	elif typedesc['array']:
	typedesc['array_desc'] = _read_arraydesc(f)

	return typedesc


	def _read_arraydesc(f):
	'''Function to read in an array descriptor'''

	arraydesc = {'arrstart': _read_long(f)}

	if arraydesc['arrstart'] == 8:

	_skip_bytes(f, 4)

	arraydesc['nbytes'] = _read_long(f)
	arraydesc['nelements'] = _read_long(f)
	arraydesc['ndims'] = _read_long(f)

	_skip_bytes(f, 8)

	arraydesc['nmax'] = _read_long(f)

	arraydesc['dims'] = [_read_long(f) for _ in range(arraydesc['nmax'])]

	elif arraydesc['arrstart'] == 18:

	warnings.warn("Using experimental 64-bit array read", stacklevel=3)

	_skip_bytes(f, 8)

	arraydesc['nbytes'] = _read_uint64(f)
	arraydesc['nelements'] = _read_uint64(f)
	arraydesc['ndims'] = _read_long(f)

	_skip_bytes(f, 8)

	arraydesc['nmax'] = 8

	arraydesc['dims'] = []
	for d in range(arraydesc['nmax']):
	v = _read_long(f)
	if v != 0:
	raise Exception("Expected a zero in ARRAY_DESC")
	arraydesc['dims'].append(_read_long(f))

	else:

	raise Exception("Unknown ARRSTART: %i" % arraydesc['arrstart'])

	return arraydesc


	def _read_structdesc(f):
	'''Function to read in a structure descriptor'''

	structdesc = {}

	structstart = _read_long(f)
	if structstart != 9:
	raise Exception("STRUCTSTART should be 9")

	structdesc['name'] = _read_string(f)
	predef = _read_long(f)
	structdesc['ntags'] = _read_long(f)
	structdesc['nbytes'] = _read_long(f)

	structdesc['predef'] = predef & 1
	structdesc['inherits'] = predef & 2
	structdesc['is_super'] = predef & 4

	if not structdesc['predef']:

	structdesc['tagtable'] = [_read_tagdesc(f)
	for _ in range(structdesc['ntags'])]

	for tag in structdesc['tagtable']:
	tag['name'] = _read_string(f)

	structdesc['arrtable'] = {tag['name']: _read_arraydesc(f)
	for tag in structdesc['tagtable']
	if tag['array']}

	structdesc['structtable'] = {tag['name']: _read_structdesc(f)
	for tag in structdesc['tagtable']
	if tag['structure']}

	if structdesc['inherits'] or structdesc['is_super']:
	structdesc['classname'] = _read_string(f)
	structdesc['nsupclasses'] = _read_long(f)
	structdesc['supclassnames'] = [
	_read_string(f) for _ in range(structdesc['nsupclasses'])]
	structdesc['supclasstable'] = [
	_read_structdesc(f) for _ in range(structdesc['nsupclasses'])]

	STRUCT_DICT[structdesc['name']] = structdesc

	else:

	if structdesc['name'] not in STRUCT_DICT:
	raise Exception("PREDEF=1 but can't find definition")

	structdesc = STRUCT_DICT[structdesc['name']]

	return structdesc


	def _read_tagdesc(f):
	'''Function to read in a tag descriptor'''

	tagdesc = {'offset': _read_long(f)}

	if tagdesc['offset'] == -1:
	tagdesc['offset'] = _read_uint64(f)

	tagdesc['typecode'] = _read_long(f)
	tagflags = _read_long(f)

	tagdesc['array'] = tagflags & 4 == 4
	tagdesc['structure'] = tagflags & 32 == 32
	tagdesc['scalar'] = tagdesc['typecode'] in DTYPE_DICT
	# Assume '10'x is scalar

	return tagdesc


	def _replace_heap(variable, heap):

	if isinstance(variable, Pointer):

	while isinstance(variable, Pointer):

	if variable.index == 0:
	variable = None
	else:
	if variable.index in heap:
	variable = heap[variable.index]
	else:
	warnings.warn("Variable referenced by pointer not found "
	"in heap: variable will be set to None",
	stacklevel=3)
	variable = None

	replace, new = _replace_heap(variable, heap)

	if replace:
	variable = new

	return True, variable

	elif isinstance(variable, np.rec.recarray):

	# Loop over records
	for ir, record in enumerate(variable):

	replace, new = _replace_heap(record, heap)

	if replace:
	variable[ir] = new

	return False, variable

	elif isinstance(variable, np.record):

	# Loop over values
	for iv, value in enumerate(variable):

	replace, new = _replace_heap(value, heap)

	if replace:
	variable[iv] = new

	return False, variable

	elif isinstance(variable, np.ndarray):

	# Loop over values if type is np.object_
	if variable.dtype.type is np.object_:

	for iv in range(variable.size):

	replace, new = _replace_heap(variable.item(iv), heap)

	if replace:
	variable.reshape(-1)[iv] = new

	return False, variable

	else:

	return False, variable


	class AttrDict(dict):
	'''
	A case-insensitive dictionary with access via item, attribute, and call
	notations:

	>>> from scipy.io._idl import AttrDict
	>>> d = AttrDict()
	>>> d['Variable'] = 123
	>>> d['Variable']
	123
	>>> d.Variable
	123
	>>> d.variable
	123
	>>> d('VARIABLE')
	123
	>>> d['missing']
	Traceback (most recent error last):
	...
	KeyError: 'missing'
	>>> d.missing
	Traceback (most recent error last):
	...
	AttributeError: 'AttrDict' object has no attribute 'missing'
	'''

	def __init__(self, init={}):
	dict.__init__(self, init)

	def __getitem__(self, name):
	return super().__getitem__(name.lower())

	def __setitem__(self, key, value):
	return super().__setitem__(key.lower(), value)

	def __getattr__(self, name):
	try:
	return self.__getitem__(name)
	except KeyError:
	raise AttributeError(
	f"'{type(self)}' object has no attribute '{name}'") from None

	__setattr__ = __setitem__
	__call__ = __getitem__


	def readsav(file_name, idict=None, python_dict=False,
	uncompressed_file_name=None, verbose=False):
	"""
	Read an IDL .sav file.

	Parameters
	----------
	file_name : str
	Name of the IDL save file.
	idict : dict, optional
	Dictionary in which to insert .sav file variables.
	python_dict : bool, optional
	By default, the object return is not a Python dictionary, but a
	case-insensitive dictionary with item, attribute, and call access
	to variables. To get a standard Python dictionary, set this option
	to True.
	uncompressed_file_name : str, optional
	This option only has an effect for .sav files written with the
	/compress option. If a file name is specified, compressed .sav
	files are uncompressed to this file. Otherwise, readsav will use
	the `tempfile` module to determine a temporary filename
	automatically, and will remove the temporary file upon successfully
	reading it in.
	verbose : bool, optional
	Whether to print out information about the save file, including
	the records read, and available variables.

	Returns
	-------
	idl_dict : AttrDict or dict
	If `python_dict` is set to False (default), this function returns a
	case-insensitive dictionary with item, attribute, and call access
	to variables. If `python_dict` is set to True, this function
	returns a Python dictionary with all variable names in lowercase.
	If `idict` was specified, then variables are written to the
	dictionary specified, and the updated dictionary is returned.

	Examples
	--------
	>>> from os.path import dirname, join as pjoin
	>>> import scipy.io as sio
	>>> from scipy.io import readsav

	Get the filename for an example .sav file from the tests/data directory.

	>>> data_dir = pjoin(dirname(sio.__file__), 'tests', 'data')
	>>> sav_fname = pjoin(data_dir, 'array_float32_1d.sav')

	Load the .sav file contents.

	>>> sav_data = readsav(sav_fname)

	Get keys of the .sav file contents.

	>>> print(sav_data.keys())
	dict_keys(['array1d'])

	Access a content with a key.

	>>> print(sav_data['array1d'])
	[0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.
	0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.
	0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.
	0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.
	0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.
	0. 0. 0.]

	"""

	# Initialize record and variable holders
	records = []
	if python_dict or idict:
	variables = {}
	else:
	variables = AttrDict()

	# Open the IDL file
	f = open(file_name, 'rb')

	# Read the signature, which should be 'SR'
	signature = _read_bytes(f, 2)
	if signature != b'SR':
	raise Exception("Invalid SIGNATURE: %s" % signature)

	# Next, the record format, which is '\x00\x04' for normal .sav
	# files, and '\x00\x06' for compressed .sav files.
	recfmt = _read_bytes(f, 2)

	if recfmt == b'\x00\x04':
	pass

	elif recfmt == b'\x00\x06':

	if verbose:
	print("IDL Save file is compressed")

	if uncompressed_file_name:
	fout = open(uncompressed_file_name, 'w+b')
	else:
	fout = tempfile.NamedTemporaryFile(suffix='.sav')

	if verbose:
	print(" -> expanding to %s" % fout.name)

	# Write header
	fout.write(b'SR\x00\x04')

	# Cycle through records
	while True:

	# Read record type
	rectype = _read_long(f)
	fout.write(struct.pack('>l', int(rectype)))

	# Read position of next record and return as int
	nextrec = _read_uint32(f)
	nextrec += _read_uint32(f).astype(np.int64) * 2**32

	# Read the unknown 4 bytes
	unknown = f.read(4)

	# Check if the end of the file has been reached
	if RECTYPE_DICT[rectype] == 'END_MARKER':
	modval = np.int64(2**32)
	fout.write(struct.pack('>I', int(nextrec) % modval))
	fout.write(
	struct.pack('>I', int((nextrec - (nextrec % modval)) / modval))
	)
	fout.write(unknown)
	break

	# Find current position
	pos = f.tell()

	# Decompress record
	rec_string = zlib.decompress(f.read(nextrec-pos))

	# Find new position of next record
	nextrec = fout.tell() + len(rec_string) + 12

	# Write out record
	fout.write(struct.pack('>I', int(nextrec % 2**32)))
	fout.write(struct.pack('>I', int((nextrec - (nextrec % 232)) / 232)))
	fout.write(unknown)
	fout.write(rec_string)

	# Close the original compressed file
	f.close()

	# Set f to be the decompressed file, and skip the first four bytes
	f = fout
	f.seek(4)

	else:
	raise Exception("Invalid RECFMT: %s" % recfmt)

	# Loop through records, and add them to the list
	while True:
	r = _read_record(f)
	records.append(r)
	if 'end' in r:
	if r['end']:
	break

	# Close the file
	f.close()

	# Find heap data variables
	heap = {}
	for r in records:
	if r['rectype'] == "HEAP_DATA":
	heap[r['heap_index']] = r['data']

	# Find all variables
	for r in records:
	if r['rectype'] == "VARIABLE":
	replace, new = _replace_heap(r['data'], heap)
	if replace:
	r['data'] = new
	variables[r['varname'].lower()] = r['data']

	if verbose:

	# Print out timestamp info about the file
	for record in records:
	if record['rectype'] == "TIMESTAMP":
	print("-"*50)
	print("Date: %s" % record['date'])
	print("User: %s" % record['user'])
	print("Host: %s" % record['host'])
	break

	# Print out version info about the file
	for record in records:
	if record['rectype'] == "VERSION":
	print("-"*50)
	print("Format: %s" % record['format'])
	print("Architecture: %s" % record['arch'])
	print("Operating System: %s" % record['os'])
	print("IDL Version: %s" % record['release'])
	break

	# Print out identification info about the file
	for record in records:
	if record['rectype'] == "IDENTIFICATON":
	print("-"*50)
	print("Author: %s" % record['author'])
	print("Title: %s" % record['title'])
	print("ID Code: %s" % record['idcode'])
	break

	# Print out descriptions saved with the file
	for record in records:
	if record['rectype'] == "DESCRIPTION":
	print("-"*50)
	print("Description: %s" % record['description'])
	break

	print("-"*50)
	print("Successfully read %i records of which:" %
	(len(records)))

	# Create convenience list of record types
	rectypes = [r['rectype'] for r in records]

	for rt in set(rectypes):
	if rt != 'END_MARKER':
	print(" - %i are of type %s" % (rectypes.count(rt), rt))
	print("-"*50)

	if 'VARIABLE' in rectypes:
	print("Available variables:")
	for var in variables:
	print(f" - {var} [{type(variables[var])}]")
	print("-"*50)

	if idict:
	for var in variables:
	idict[var] = variables[var]
	return idict
	else:
	return variables