class OpenSSL::ASN1::ASN1Data
The top-level class representing any ASN.1 object. When parsed by ASN1.decode
, tagged values are always represented by an instance of ASN1Data
.
The role of ASN1Data
for parsing tagged values
When encoding an ASN.1 type it is inherently clear what original type (e.g. INTEGER, OCTET STRING etc.) this value has, regardless of its tagging. But opposed to the time an ASN.1 type is to be encoded, when parsing them it is not possible to deduce the “real type” of tagged values. This is why tagged values are generally parsed into ASN1Data
instances, but with a different outcome for implicit and explicit tagging.
Example of a parsed implicitly tagged value
An implicitly 1-tagged INTEGER value will be parsed as an ASN1Data
with
-
tag equal to 1
-
tag_class equal to
:CONTEXT_SPECIFIC
-
value equal to a
String
that carries the raw encoding of the INTEGER.
This implies that a subsequent decoding step is required to completely decode implicitly tagged values.
Example of a parsed explicitly tagged value
An explicitly 1-tagged INTEGER value will be parsed as an ASN1Data
with
-
tag equal to 1
-
tag_class equal to
:CONTEXT_SPECIFIC
-
value equal to an
Array
with one single element, an instance of OpenSSL::ASN1::Integer, i.e. the inner element is the non-tagged primitive value, and the tagging is represented in the outerASN1Data
Example - Decoding an implicitly tagged INTEGER
int = OpenSSL::ASN1::Integer.new(1, 0, :IMPLICIT) # implicit 0-tagged seq = OpenSSL::ASN1::Sequence.new( [int] ) der = seq.to_der asn1 = OpenSSL::ASN1.decode(der) # pp asn1 => #<OpenSSL::ASN1::Sequence:0x87326e0 # @indefinite_length=false, # @tag=16, # @tag_class=:UNIVERSAL, # @tagging=nil, # @value= # [#<OpenSSL::ASN1::ASN1Data:0x87326f4 # @indefinite_length=false, # @tag=0, # @tag_class=:CONTEXT_SPECIFIC, # @value="\x01">]> raw_int = asn1.value[0] # manually rewrite tag and tag class to make it an UNIVERSAL value raw_int.tag = OpenSSL::ASN1::INTEGER raw_int.tag_class = :UNIVERSAL int2 = OpenSSL::ASN1.decode(raw_int) puts int2.value # => 1
Example - Decoding an explicitly tagged INTEGER
int = OpenSSL::ASN1::Integer.new(1, 0, :EXPLICIT) # explicit 0-tagged seq = OpenSSL::ASN1::Sequence.new( [int] ) der = seq.to_der asn1 = OpenSSL::ASN1.decode(der) # pp asn1 => #<OpenSSL::ASN1::Sequence:0x87326e0 # @indefinite_length=false, # @tag=16, # @tag_class=:UNIVERSAL, # @tagging=nil, # @value= # [#<OpenSSL::ASN1::ASN1Data:0x87326f4 # @indefinite_length=false, # @tag=0, # @tag_class=:CONTEXT_SPECIFIC, # @value= # [#<OpenSSL::ASN1::Integer:0x85bf308 # @indefinite_length=false, # @tag=2, # @tag_class=:UNIVERSAL # @tagging=nil, # @value=1>]>]> int2 = asn1.value[0].value[0] puts int2.value # => 1
Attributes
Never nil
. A boolean value indicating whether the encoding uses indefinite length (in the case of parsing) or whether an indefinite length form shall be used (in the encoding case). In DER, every value uses definite length form. But in scenarios where large amounts of data need to be transferred it might be desirable to have some kind of streaming support available. For example, huge OCTET STRINGs are preferably sent in smaller-sized chunks, each at a time. This is possible in BER by setting the length bytes of an encoding to zero and by this indicating that the following value will be sent in chunks. Indefinite length encodings are always constructed. The end of such a stream of chunks is indicated by sending a EOC (End of Content) tag. SETs and SEQUENCEs may use an indefinite length encoding, but also primitive types such as e.g. OCTET STRINGS or BIT STRINGS may leverage this functionality (cf. ITU-T X.690).
Never nil
. A boolean value indicating whether the encoding uses indefinite length (in the case of parsing) or whether an indefinite length form shall be used (in the encoding case). In DER, every value uses definite length form. But in scenarios where large amounts of data need to be transferred it might be desirable to have some kind of streaming support available. For example, huge OCTET STRINGs are preferably sent in smaller-sized chunks, each at a time. This is possible in BER by setting the length bytes of an encoding to zero and by this indicating that the following value will be sent in chunks. Indefinite length encodings are always constructed. The end of such a stream of chunks is indicated by sending a EOC (End of Content) tag. SETs and SEQUENCEs may use an indefinite length encoding, but also primitive types such as e.g. OCTET STRINGS or BIT STRINGS may leverage this functionality (cf. ITU-T X.690).
Carries the value of a ASN.1 type. Please confer Constructive
and Primitive
for the mappings between ASN.1 data types and Ruby classes.
Public Class Methods
static VALUE ossl_asn1data_initialize(VALUE self, VALUE value, VALUE tag, VALUE tag_class) { if(!SYMBOL_P(tag_class)) ossl_raise(eASN1Error, "invalid tag class"); ossl_asn1_set_tag(self, tag); ossl_asn1_set_value(self, value); ossl_asn1_set_tag_class(self, tag_class); ossl_asn1_set_indefinite_length(self, Qfalse); return self; }
value: Please have a look at Constructive
and Primitive
to see how Ruby types are mapped to ASN.1 types and vice versa.
tag: An Integer
indicating the tag number.
tag_class: A Symbol
indicating the tag class. Please cf. ASN1
for possible values.
Example
asn1_int = OpenSSL::ASN1Data.new(42, 2, :UNIVERSAL) # => Same as OpenSSL::ASN1::Integer.new(42) tagged_int = OpenSSL::ASN1Data.new(42, 0, :CONTEXT_SPECIFIC) # implicitly 0-tagged INTEGER
Public Instance Methods
static VALUE ossl_asn1data_to_der(VALUE self) { VALUE value = ossl_asn1_get_value(self); if (rb_obj_is_kind_of(value, rb_cArray)) return ossl_asn1cons_to_der(self); else { if (RTEST(ossl_asn1_get_indefinite_length(self))) ossl_raise(eASN1Error, "indefinite length form cannot be used " \ "with primitive encoding"); return ossl_asn1prim_to_der(self); } }
Encodes this ASN1Data
into a DER-encoded String
value. The result is DER-encoded except for the possibility of indefinite length forms. Indefinite length forms are not allowed in strict DER, so strictly speaking the result of such an encoding would be a BER-encoding.
Ruby Core © 1993–2020 Yukihiro Matsumoto
Licensed under the Ruby License.
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Licensed under their own licenses.