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encoder.py
# # This file is part of pyasn1 software. # # Copyright (c) 2005-2017, Ilya Etingof <etingof@gmail.com> # License: http://pyasn1.sf.net/license.html # from pyasn1.type import univ from pyasn1.type import useful from pyasn1.codec.ber import encoder from pyasn1.compat.octets import str2octs, null from pyasn1 import error __all__ = ['encode'] class BooleanEncoder(encoder.IntegerEncoder): def encodeValue(self, value, encodeFun, **options): if value == 0: substrate = (0,) else: substrate = (255,) return substrate, False, False class RealEncoder(encoder.RealEncoder): def _chooseEncBase(self, value): m, b, e = value return self._dropFloatingPoint(m, b, e) # specialized GeneralStringEncoder here class TimeEncoderMixIn(object): zchar, = str2octs('Z') pluschar, = str2octs('+') minuschar, = str2octs('-') commachar, = str2octs(',') minLength = 12 maxLength = 19 def encodeValue(self, value, encodeFun, **options): # Encoding constraints: # - minutes are mandatory, seconds are optional # - subseconds must NOT be zero # - no hanging fraction dot # - time in UTC (Z) # - only dot is allowed for fractions octets = value.asOctets() if not self.minLength < len(octets) < self.maxLength: raise error.PyAsn1Error('Length constraint violated: %r' % value) if self.pluschar in octets or self.minuschar in octets: raise error.PyAsn1Error('Must be UTC time: %r' % octets) if octets[-1] != self.zchar: raise error.PyAsn1Error('Missing "Z" time zone specifier: %r' % octets) if self.commachar in octets: raise error.PyAsn1Error('Comma in fractions disallowed: %r' % value) options.update(maxChunkSize=1000) return encoder.OctetStringEncoder.encodeValue( self, value, encodeFun, **options ) class GeneralizedTimeEncoder(TimeEncoderMixIn, encoder.OctetStringEncoder): minLength = 12 maxLength = 19 class UTCTimeEncoder(TimeEncoderMixIn, encoder.OctetStringEncoder): minLength = 10 maxLength = 14 class SetOfEncoder(encoder.SequenceOfEncoder): @staticmethod def _sortComponents(components): # sort by tags regardless of the Choice value (static sort) return sorted(components, key=lambda x: isinstance(x, univ.Choice) and x.minTagSet or x.tagSet) def encodeValue(self, value, encodeFun, **options): value.verifySizeSpec() substrate = null idx = len(value) if value.typeId == univ.Set.typeId: namedTypes = value.componentType comps = [] compsMap = {} while idx > 0: idx -= 1 if namedTypes: if namedTypes[idx].isOptional and not value[idx].isValue: continue if namedTypes[idx].isDefaulted and value[idx] == namedTypes[idx].asn1Object: continue comps.append(value[idx]) compsMap[id(value[idx])] = namedTypes and namedTypes[idx].isOptional for comp in self._sortComponents(comps): options.update(ifNotEmpty=compsMap[id(comp)]) substrate += encodeFun(comp, **options) else: components = [encodeFun(x, **options) for x in value] # sort by serialized and padded components if len(components) > 1: zero = str2octs('\x00') maxLen = max(map(len, components)) paddedComponents = [ (x.ljust(maxLen, zero), x) for x in components ] paddedComponents.sort(key=lambda x: x[0]) components = [x[1] for x in paddedComponents] substrate = null.join(components) return substrate, True, True class SequenceEncoder(encoder.SequenceEncoder): def encodeValue(self, value, encodeFun, **options): value.verifySizeSpec() namedTypes = value.componentType substrate = null idx = len(value) while idx > 0: idx -= 1 if namedTypes: if namedTypes[idx].isOptional and not value[idx].isValue: continue if namedTypes[idx].isDefaulted and value[idx] == namedTypes[idx].asn1Object: continue options.update(ifNotEmpty=namedTypes and namedTypes[idx].isOptional) substrate = encodeFun(value[idx], **options) + substrate return substrate, True, True class SequenceOfEncoder(encoder.SequenceOfEncoder): def encodeValue(self, value, encodeFun, **options): substrate = null idx = len(value) if options.get('ifNotEmpty', False) and not idx: return substrate, True, True value.verifySizeSpec() while idx > 0: idx -= 1 substrate = encodeFun(value[idx], **options) + substrate return substrate, True, True tagMap = encoder.tagMap.copy() tagMap.update({ univ.Boolean.tagSet: BooleanEncoder(), univ.Real.tagSet: RealEncoder(), useful.GeneralizedTime.tagSet: GeneralizedTimeEncoder(), useful.UTCTime.tagSet: UTCTimeEncoder(), # Sequence & Set have same tags as SequenceOf & SetOf univ.SetOf.tagSet: SetOfEncoder(), univ.Sequence.typeId: SequenceEncoder() }) typeMap = encoder.typeMap.copy() typeMap.update({ univ.Boolean.typeId: BooleanEncoder(), univ.Real.typeId: RealEncoder(), useful.GeneralizedTime.typeId: GeneralizedTimeEncoder(), useful.UTCTime.typeId: UTCTimeEncoder(), # Sequence & Set have same tags as SequenceOf & SetOf univ.Set.typeId: SetOfEncoder(), univ.SetOf.typeId: SetOfEncoder(), univ.Sequence.typeId: SequenceEncoder(), univ.SequenceOf.typeId: SequenceOfEncoder() }) class Encoder(encoder.Encoder): fixedDefLengthMode = False fixedChunkSize = 1000 #: Turns ASN.1 object into CER octet stream. #: #: Takes any ASN.1 object (e.g. :py:class:`~pyasn1.type.base.PyAsn1Item` derivative) #: walks all its components recursively and produces a CER octet stream. #: #: Parameters #: ---------- # value: any pyasn1 object (e.g. :py:class:`~pyasn1.type.base.PyAsn1Item` derivative) #: A pyasn1 object to encode #: #: defMode: :py:class:`bool` #: If `False`, produces indefinite length encoding #: #: maxChunkSize: :py:class:`int` #: Maximum chunk size in chunked encoding mode (0 denotes unlimited chunk size) #: #: Returns #: ------- #: : :py:class:`bytes` (Python 3) or :py:class:`str` (Python 2) #: Given ASN.1 object encoded into BER octetstream #: #: Raises #: ------ #: : :py:class:`pyasn1.error.PyAsn1Error` #: On encoding errors encode = Encoder(tagMap, typeMap) # EncoderFactory queries class instance and builds a map of tags -> encoders
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