The asn1crypto library is a combination of universal type classes that implement BER/DER decoding and DER encoding, a PEM encoder and decoder, and a number of pre-built cryptographic type classes. This document covers the universal type classes.
For a general overview of ASN.1 as used in cryptography, please see A Layman's Guide to a Subset of ASN.1, BER, and DER.
This page contains the following sections:
- Universal Types
- Basic Usage
- Sequence
- Set
- SequenceOf
- SetOf
- Integer
- Enumerated
- ObjectIdentifier
- BitString
- Strings
- UTCTime
- GeneralizedTime
- Choice
- Any
- Specification via OID
- Explicit and Implicit Tagging
For general purpose ASN.1 parsing, the asn1crypto.core
module is used. It
contains the following classes, that parse, represent and serialize all of the
ASN.1 universal types:
Class | Native Type | Implementation Notes |
---|---|---|
Boolean |
bool |
|
Integer |
int |
may be long on Python 2 |
BitString |
tuple of int or set of unicode |
set used if _map present |
OctetString |
bytes (str ) |
|
Null |
None |
|
ObjectIdentifier |
str (unicode ) |
string is dotted integer format |
ObjectDescriptor |
no native conversion | |
InstanceOf |
no native conversion | |
Real |
no native conversion | |
Enumerated |
str (unicode ) |
_map must be set |
UTF8String |
str (unicode ) |
|
RelativeOid |
str (unicode ) |
string is dotted integer format |
Sequence |
OrderedDict |
|
SequenceOf |
list |
|
Set |
OrderedDict |
|
SetOf |
list |
|
EmbeddedPdv |
OrderedDict |
no named field parsing |
NumericString |
str (unicode ) |
no charset limitations |
PrintableString |
str (unicode ) |
no charset limitations |
TeletexString |
str (unicode ) |
|
VideotexString |
bytes (str ) |
no unicode conversion |
IA5String |
str (unicode ) |
|
UTCTime |
datetime.datetime |
|
GeneralizedTime |
datetime.datetime |
treated as UTC when no timezone |
GraphicString |
str (unicode ) |
unicode conversion as latin1 |
VisibleString |
str (unicode ) |
no charset limitations |
GeneralString |
str (unicode ) |
unicode conversion as latin1 |
UniversalString |
str (unicode ) |
|
CharacterString |
str (unicode ) |
unicode conversion as latin1 |
BMPString |
str (unicode ) |
For Native Type, the Python 3 type is listed first, with the Python 2 type in parentheses.
As mentioned next to some of the types, value parsing may not be implemented
for types not currently used in cryptography (such as ObjectDescriptor
,
InstanceOf
and Real
). Additionally some of the string classes don't
enforce character set limitations, and for some string types that accept all
different encodings, the default encoding is set to latin1.
In addition, there are a few overridden types where various specifications use
a BitString
or OctetString
type to represent a different type. These
include:
Class | Native Type | Implementation Notes |
---|---|---|
OctetBitString |
bytes (str ) |
|
IntegerBitString |
int |
may be long on Python 2 |
IntegerOctetString |
int |
may be long on Python 2 |
For situations where the DER encoded bytes from one type is embedded in another,
the ParsableOctetString
and ParsableOctetBitString
classes exist. These
function the same as OctetString
and OctetBitString
, however they also
have an attribute .parsed
and a method .parse()
that allows for
parsing the content as ASN.1 structures.
All of these overrides can be used with the cast()
method to convert between
them. The only requirement is that the class being casted to has the same tag
as the original class. No re-encoding is done, rather the contents are simply
re-interpreted.
from asn1crypto.core import BitString, OctetBitString, IntegerBitString
bit = BitString((
0, 0, 0, 0, 0, 0, 0, 1,
0, 0, 0, 0, 0, 0, 1, 0,
))
# Will print (0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 1, 0)
print(bit.native)
octet = bit.cast(OctetBitString)
# Will print b'\x01\x02'
print(octet.native)
i = bit.cast(IntegerBitString)
# Will print 258
print(i.native)
All of the universal types implement four methods, a class method .load()
and
the instance methods .dump()
, .copy()
and .debug()
.
.load()
accepts a byte string of DER or BER encoded data and returns an
object of the class it was called on. .dump()
returns the serialization of
an object into DER encoding.
from asn1crypto.core import Sequence
parsed = Sequence.load(der_byte_string)
serialized = parsed.dump()
By default, asn1crypto tries to be efficient and caches serialized data for
better performance. If the input data is possibly BER encoded, but the output
must be DER encoded, the force
parameter may be used with .dump()
.
from asn1crypto.core import Sequence
parsed = Sequence.load(der_byte_string)
der_serialized = parsed.dump(force=True)
The .copy()
method creates a deep copy of an object, allowing child fields to
be modified without affecting the original.
from asn1crypto.core import Sequence
seq1 = Sequence.load(der_byte_string)
seq2 = seq1.copy()
seq2[0] = seq1[0] + 1
if seq1[0] != seq2[0]:
print('Copies have distinct contents')
The .debug()
method is available to help in situations where interaction with
another ASN.1 serializer or parsing is not functioning as expected. Calling
this method will print a tree structure with information about the header bytes,
class, method, tag, special tagging, content bytes, native Python value, child
fields and any sub-parsed values.
from asn1crypto.core import Sequence
parsed = Sequence.load(der_byte_string)
parsed.debug()
In addition to the available methods, every instance has a .native
property
that converts the data into a native Python data type.
import pprint
from asn1crypto.core import Sequence
parsed = Sequence.load(der_byte_string)
pprint(parsed.native)
One of the core structures when dealing with ASN.1 is the Sequence type. The
Sequence
class can handle field with universal data types, however in most
situations the _fields
property will need to be set with the expected
definition of each field in the Sequence.
The _fields
property must be set to a list
of 2-3 element tuple
s. The
first element in the tuple must be a unicode string of the field name. The
second must be a type class - either a universal type, or a custom type. The
third, and optional, element is a dict
with parameters to pass to the type
class for things like default values, marking the field as optional, or
implicit/explicit tagging.
from asn1crypto.core import Sequence, Integer, OctetString, IA5String
class MySequence(Sequence):
_fields = [
('field_one', Integer),
('field_two', OctetString),
('field_three', IA5String, {'optional': True}),
]
Implicit and explicit tagging will be covered in more detail later, however the following are options that can be set for each field type class:
{'default: 1}
sets the field's default value to1
, allowing it to be omitted from the serialized form{'optional': True}
set the field to be optional, allowing it to be omitted
To access values of the sequence, use dict-like access via []
and use the
name of the field:
seq = MySequence.load(der_byte_string)
print(seq['field_two'].native)
The values of fields can be set by assigning via []
. If the value assigned is
of the correct type class, it will be used as-is. If the value is not of the
correct type class, a new instance of that type class will be created and the
value will be passed to the constructor.
seq = MySequence.load(der_byte_string)
# These statements will result in the same state
seq['field_one'] = Integer(5)
seq['field_one'] = 5
When fields are complex types such as Sequence
or SequenceOf
, there is no
way to construct the value out of a native Python data type.
When a field is configured via the optional
parameter, not present in the
Sequence
, but accessed, the VOID
object will be returned. This is an object
that is serialized to an empty byte string and returns None
when .native
is
accessed.
The Set
class is configured in the same was as Sequence
, however it allows
serialized fields to be in any order, per the ASN.1 standard.
from asn1crypto.core import Set, Integer, OctetString, IA5String
class MySet(Set):
_fields = [
('field_one', Integer),
('field_two', OctetString),
('field_three', IA5String, {'optional': True}),
]
The SequenceOf
class is used to allow for zero or more instances of a type.
The class uses the _child_spec
property to define the instance class type.
from asn1crypto.core import SequenceOf, Integer
class Integers(SequenceOf):
_child_spec = Integer
Values in the SequenceOf
can be accessed via []
with an integer key. The
length of the SequenceOf
is determined via len()
.
values = Integers.load(der_byte_string)
for i in range(0, len(values)):
print(values[i].native)
The SetOf
class is an exact duplicate of SequenceOf
. According to the ASN.1
standard, the difference is that a SequenceOf
is explicitly ordered, however
SetOf
may be in any order. This is an equivalent comparison of a Python list
and set
.
from asn1crypto.core import SetOf, Integer
class Integers(SetOf):
_child_spec = Integer
The Integer
class allows values to be named. An Integer
with named values
may contain any integer, however special values with named will be represented
as those names when .native
is called.
Named values are configured via the _map
property, which must be a dict
with the keys being integers and the values being unicode strings.
from asn1crypto.core import Integer
class Version(Integer):
_map = {
1: 'v1',
2: 'v2',
}
# Will print: "v1"
print(Version(1).native)
# Will print: 4
print(Version(4).native)
The Enumerated
class is almost identical to Integer
, however only values in
the _map
property are valid.
from asn1crypto.core import Enumerated
class Version(Enumerated):
_map = {
1: 'v1',
2: 'v2',
}
# Will print: "v1"
print(Version(1).native)
# Will raise a ValueError exception
print(Version(4).native)
The ObjectIdentifier
class represents values of the ASN.1 type of the same
name. ObjectIdentifier
instances are converted to a unicode string in a
dotted-integer format when .native
is accessed.
While this standard conversion is a reasonable baseline, in most situations it will be more maintainable to map the OID strings to a unicode string containing a description of what the OID repesents.
The mapping of OID strings to name strings is configured via the _map
property, which is a dict
object with keys being unicode OID string and the
values being a unicode string.
The .dotted
attribute will always return a unicode string of the dotted
integer form of the OID.
The class methods .map()
and .unmap()
will convert a dotted integer unicode
string to the user-friendly name, and vice-versa.
from asn1crypto.core import ObjectIdentifier
class MyType(ObjectIdentifier):
_map = {
'1.8.2.1.23': 'value_name',
'1.8.2.1.24': 'other_value',
}
# Will print: "value_name"
print(MyType('1.8.2.1.23').native)
# Will print: "1.8.2.1.23"
print(MyType('1.8.2.1.23').dotted)
# Will print: "1.8.2.1.25"
print(MyType('1.8.2.1.25').native)
# Will print "value_name"
print(MyType.map('1.8.2.1.23'))
# Will print "1.8.2.1.23"
print(MyType.unmap('value_name'))
When no _map
is set for a BitString
class, the native representation is a
tuple
of int
s (being either 1
or 0
).
from asn1crypto.core import BitString
b1 = BitString((1, 0, 1))
Additionally, it is possible to set the _map
property to a dict where the
keys are bit indexes and the values are unicode string names. This allows
checking the value of a given bit by item access, and the native representation
becomes a set
of unicode strings.
from asn1crypto.core import BitString
class MyFlags(BitString):
_map = {
0: 'edit',
1: 'delete',
2: 'manage_users',
}
permissions = MyFlags({'edit', 'delete'})
# This will be printed
if permissions['edit'] and permissions['delete']:
print('Can edit and delete')
# This will not
if 'manage_users' in permissions.native:
print('Is admin')
ASN.1 contains quite a number of string types:
Type | Standard Encoding | Implementation Encoding | Notes |
---|---|---|---|
UTF8String |
UTF-8 | UTF-8 | |
NumericString |
ASCII [0-9 ] |
ISO 8859-1 | The implementation is a superset of supported characters |
PrintableString |
ASCII [a-zA-Z0-9 '()+,\\-./:=?] |
ISO 8859-1 | The implementation is a superset of supported characters |
TeletexString |
ITU T.61 | Custom | The implementation is based off of https://en.wikipedia.org/wiki/ITU_T.61 |
VideotexString |
? | None | This has no set encoding, and it not used in cryptography |
IA5String |
ITU T.50 (very similar to ASCII) | ISO 8859-1 | The implementation is a superset of supported characters |
GraphicString |
* | ISO 8859-1 | This has not set encoding, but seems to often contain ISO 8859-1 |
VisibleString |
ASCII (printable) | ISO 8859-1 | The implementation is a superset of supported characters |
GeneralString |
* | ISO 8859-1 | This has not set encoding, but seems to often contain ISO 8859-1 |
UniversalString |
UTF-32 | UTF-32 | |
CharacterString |
* | ISO 8859-1 | This has not set encoding, but seems to often contain ISO 8859-1 |
BMPString |
UTF-16 | UTF-16 |
As noted in the table above, many of the implementations are supersets of the
supported characters. This simplifies parsing, but puts the onus of using valid
characters on the developer. However, in general UTF8String
, BMPString
or
UniversalString
should be preferred when a choice is given.
All string types other than VideotexString
are created from unicode strings.
from asn1crypto.core import IA5String
print(IA5String('Testing!').native)
The class UTCTime
accepts a unicode string in one of the formats:
%y%m%d%H%MZ
%y%m%d%H%M%SZ
%y%m%d%H%M%z
%y%m%d%H%M%S%z
or a datetime.datetime
instance. See the
Python datetime strptime() reference
for details of the formats.
When .native
is accessed, it returns a datetime.datetime
object with a
tzinfo
of asn1crypto.util.timezone.utc
.
The class GeneralizedTime
accepts a unicode string in one of the formats:
%Y%m%d%H
%Y%m%d%H%M
%Y%m%d%H%M%S
%Y%m%d%H%M%S.%f
%Y%m%d%HZ
%Y%m%d%H%MZ
%Y%m%d%H%M%SZ
%Y%m%d%H%M%S.%fZ
%Y%m%d%H%z
%Y%m%d%H%M%z
%Y%m%d%H%M%S%z
%Y%m%d%H%M%S.%f%z
or a datetime.datetime
instance. See the
Python datetime strptime() reference
for details of the formats.
When .native
is accessed, it returns a datetime.datetime
object with a
tzinfo
of asn1crypto.util.timezone.utc
. For formats where the time has a
timezone offset is specified ([+-]\d{4}
), the time is converted to UTC. For
times without a timezone, the time is assumed to be in UTC.
The Choice
class allows handling ASN.1 Choice structures. The _alternatives
property must be set to a list
containing 2-3 element tuple
s. The first
element in the tuple is the alternative name. The second element is the type
class for the alternative. The, optional, third element is a dict
of
parameters to pass to the type class constructor. This is used primarily for
implicit and explicit tagging.
from asn1crypto.core import Choice, Integer, OctetString, IA5String
class MyChoice(Choice):
_alternatives = [
('option_one', Integer),
('option_two', OctetString),
('option_three', IA5String),
]
Choice
objects has two extra properties, .name
and .chosen
. The .name
property contains the name of the chosen alternative. The .chosen
property
contains the instance of the chosen type class.
parsed = MyChoice.load(der_bytes)
print(parsed.name)
print(type(parsed.chosen))
The .native
property and .dump()
method work as with the universal type
classes. Under the hood they just proxy the calls to the .chosen
object.
The Any
class implements the ASN.1 Any type, which allows any data type. By
default objects of this class do not perform any parsing. However, the
.parse()
instance method allows parsing the contents of the Any
object,
either into a universal type, or to a specification pass in via the spec
parameter.
This type is not used as a top-level structure, but instead allows Sequence
and Set
objects to accept varying contents, usually based on some sort of
ObjectIdentifier
.
from asn1crypto.core import Sequence, ObjectIdentifier, Any, Integer, OctetString
class MySequence(Sequence):
_fields = [
('type', ObjectIdentifier),
('value', Any),
]
Throughout the usage of ASN.1 in cryptography, a pattern is present where an
ObjectIdenfitier
is used to determine what specification should be used to
interpret another field in a Sequence
. Usually the other field is an instance
of Any
, however occasionally it is an OctetString
or OctetBitString
.
asn1crypto provides the _oid_pair
and _oid_specs
properties of the
Sequence
class to allow handling these situations.
The _oid_pair
is a tuple with two unicode string elements. The first is the
name of the field that is an ObjectIdentifier
and the second if the name of
the field that has a variable specification based on the first field. In
situations where the value field should be an OctetString
or OctetBitString
,
ParsableOctetString
and ParsableOctetBitString
will need to be used instead
to allow for the sub-parsing of the contents.
The _oid_specs
property is a dict
object with ObjectIdentifier
values as
the keys (either dotted or mapped notation) and a type class as the value. When
the first field in _oid_pair
has a value equal to one of the keys in
_oid_specs
, then the corresponding type class will be used as the
specification for the second field of _oid_pair
.
from asn1crypto.core import Sequence, ObjectIdentifier, Any, OctetString, Integer
class MyId(ObjectIdentifier):
_map = {
'1.2.3.4': 'initialization_vector',
'1.2.3.5': 'iterations',
}
class MySequence(Sequence):
_fields = [
('type', MyId),
('value', Any),
]
_oid_pair = ('type', 'value')
_oid_specs = {
'initialization_vector': OctetString,
'iterations': Integer,
}
When working with Sequence
, Set
and Choice
it is often necessary to
disambiguate between fields because of a number of factors:
- In
Sequence
the presence of an optional field must be determined by tag number - In
Set
, each field must have a different tag number since they can be in any order - In
Choice
, each alternative must have a different tag number to determine which is present
The universal types all have unique tag numbers. However, if a Sequence
, Set
or Choice
has more than one field with the same universal type, tagging allows
a way to keep the semantics of the original type, but with a different tag
number.
Implicit tagging simply changes the tag number of a type to a different value. However, Explicit tagging wraps the existing type in another tag with the specified tag number.
In general, most situations allow for implicit tagging, with the notable
exception than a field that is a Choice
type must always be explicitly tagged.
Otherwise, using implicit tagging would modify the tag of the chosen
alternative, breaking the mechanism by which Choice
works.
Here is an example of implicit and explicit tagging where explicit tagging on
the Sequence
allows a Choice
type field to be optional, and where implicit
tagging in the Choice
structure allows disambiguating between two string of
the same type.
from asn1crypto.core import Sequence, Choice, IA5String, UTCTime, ObjectIdentifier
class Person(Choice):
_alternatives = [
('name', IA5String),
('email', IA5String, {'implicit': 0}),
]
class Record(Sequence):
_fields = [
('id', ObjectIdentifier),
('created', UTCTime),
('creator', Person, {'explicit': 0, 'optional': True}),
]
As is shown above, the keys implicit
and explicit
are used for tagging,
and are passed to a type class constructor via the optional third element of
a field or alternative tuple. Both parameters may be an integer tag number, or
a 2-element tuple of string class name and integer tag.
If a tagging value needs its tagging changed, the .untag()
method can be used
to create a copy of the object without explicit/implicit tagging. The .retag()
method can be used to change the tagging. This method accepts one parameter, a
dict with either or both of the keys implicit
and explicit
.
person = Person(name='email', value='[email protected]')
# Will display True
print(person.implicit)
# Will display False
print(person.untag().implicit)
# Will display 0
print(person.tag)
# Will display 1
print(person.retag({'implicit': 1}).tag)