Abstract Syntax Notation One (or ASN.1) is a notation syntax to describe data structures and is defined in ITU-T X.680. ASN.1 itself does not mandate any encoding or parsing rules, but usually ASN.1 data structures are encoded using the Distinguished Encoding
Rules (DER) or less often the Basic Encoding
Rules (BER) described in ITU-T X.690. DER and BER encodings are binary Tag-Length-Value (TLV) encodings that are quite concise compared to other popular data description formats such as XML
, JSON
etc. ASN.1 data structures are very common in cryptographic applications, e.g. X.509 public key certificates or certificate revocation lists (CRLs) are all defined in ASN.1 and DER-encoded. ASN.1, DER and BER are the building blocks of applied cryptography. The ASN1
module provides the necessary classes that allow generation of ASN.1 data structures and the methods to encode them using a DER encoding. The decode method allows parsing arbitrary BER-/DER-encoded data to a Ruby object that can then be modified and re-encoded at will.
ASN.1 class hierarchy
The base class representing ASN.1 structures is ASN1Data
. ASN1Data
offers attributes to read and set the tag, the tag_class and finally the value of a particular ASN.1 item. Upon parsing, any tagged values (implicit or explicit) will be represented by ASN1Data
instances because their “real type” can only be determined using out-of-band information from the ASN.1 type declaration. Since this information is normally known when encoding a type, all sub-classes of ASN1Data
offer an additional attribute tagging that allows to encode a value implicitly (:IMPLICIT
) or explicitly (:EXPLICIT
).
Constructive
Constructive
is, as its name implies, the base class for all constructed encodings, i.e. those that consist of several values, opposed to “primitive” encodings with just one single value. The value of an Constructive
is always an Array.
ASN1::Set
and ASN1::Sequence
The most common constructive encodings are SETs and SEQUENCEs, which is why there are two sub-classes of Constructive
representing each of them.
Primitive
This is the super class of all primitive values. Primitive
itself is not used when parsing ASN.1 data, all values are either instances of a corresponding sub-class of Primitive
or they are instances of ASN1Data
if the value was tagged implicitly or explicitly. Please cf. Primitive
documentation for details on sub-classes and their respective mappings of ASN.1 data types to Ruby objects.
Possible values for tagging
When constructing an ASN1Data
object the ASN.1 type definition may require certain elements to be either implicitly or explicitly tagged. This can be achieved by setting the tagging attribute manually for sub-classes of ASN1Data
. Use the symbol :IMPLICIT
for implicit tagging and :EXPLICIT
if the element requires explicit tagging.
Possible values for tag_class
It is possible to create arbitrary ASN1Data
objects that also support a PRIVATE or APPLICATION tag class. Possible values for the tag_class attribute are:
-
:UNIVERSAL
(the default for untagged values) -
:CONTEXT_SPECIFIC
(the default for tagged values) -
:APPLICATION
-
:PRIVATE
Tag constants
There is a constant defined for each universal tag:
-
OpenSSL::ASN1::EOC (0)
-
OpenSSL::ASN1::BOOLEAN (1)
-
OpenSSL::ASN1::INTEGER (2)
-
OpenSSL::ASN1::BIT_STRING (3)
-
OpenSSL::ASN1::OCTET_STRING (4)
-
OpenSSL::ASN1::NULL (5)
-
OpenSSL::ASN1::OBJECT (6)
-
OpenSSL::ASN1::ENUMERATED (10)
-
OpenSSL::ASN1::UTF8STRING (12)
-
OpenSSL::ASN1::SEQUENCE (16)
-
OpenSSL::ASN1::SET (17)
-
OpenSSL::ASN1::NUMERICSTRING (18)
-
OpenSSL::ASN1::PRINTABLESTRING (19)
-
OpenSSL::ASN1::T61STRING (20)
-
OpenSSL::ASN1::VIDEOTEXSTRING (21)
-
OpenSSL::ASN1::IA5STRING (22)
-
OpenSSL::ASN1::UTCTIME (23)
-
OpenSSL::ASN1::GENERALIZEDTIME (24)
-
OpenSSL::ASN1::GRAPHICSTRING (25)
-
OpenSSL::ASN1::ISO64STRING (26)
-
OpenSSL::ASN1::GENERALSTRING (27)
-
OpenSSL::ASN1::UNIVERSALSTRING (28)
-
OpenSSL::ASN1::BMPSTRING (30)
UNIVERSAL_TAG_NAME
constant
An Array that stores the name of a given tag number. These names are the same as the name of the tag constant that is additionally defined, e.g. UNIVERSAL_TAG_NAME = “INTEGER” and OpenSSL::ASN1::INTEGER = 2.
Example usage
Decoding and viewing a DER-encoded file
require 'openssl' require 'pp' der = File.binread('data.der') asn1 = OpenSSL::ASN1.decode(der) pp der
Creating an ASN.1 structure and DER-encoding it
require 'openssl' version = OpenSSL::ASN1::Integer.new(1) # Explicitly 0-tagged implies context-specific tag class serial = OpenSSL::ASN1::Integer.new(12345, 0, :EXPLICIT, :CONTEXT_SPECIFIC) name = OpenSSL::ASN1::PrintableString.new('Data 1') sequence = OpenSSL::ASN1::Sequence.new( [ version, serial, name ] ) der = sequence.to_der
Array storing tag names at the tag’s index.
static VALUE
ossl_asn1_decode(VALUE self, VALUE obj)
{
VALUE ret;
unsigned char *p;
VALUE tmp;
long len, read = 0, offset = 0;
obj = ossl_to_der_if_possible(obj);
tmp = rb_str_new4(StringValue(obj));
p = (unsigned char *)RSTRING_PTR(tmp);
len = RSTRING_LEN(tmp);
ret = ossl_asn1_decode0(&p, len, &offset, 0, 0, &read);
RB_GC_GUARD(tmp);
int_ossl_decode_sanity_check(len, read, offset);
return ret;
}
Decodes a BER- or DER-encoded value and creates an ASN1Data
instance. der may be a String or any object that features a .to_der
method transforming it into a BER-/DER-encoded String+
Example
der = File.binread('asn1data') asn1 = OpenSSL::ASN1.decode(der)
static VALUE
ossl_asn1_decode_all(VALUE self, VALUE obj)
{
VALUE ary, val;
unsigned char *p;
long len, tmp_len = 0, read = 0, offset = 0;
VALUE tmp;
obj = ossl_to_der_if_possible(obj);
tmp = rb_str_new4(StringValue(obj));
p = (unsigned char *)RSTRING_PTR(tmp);
len = RSTRING_LEN(tmp);
tmp_len = len;
ary = rb_ary_new();
while (tmp_len > 0) {
long tmp_read = 0;
val = ossl_asn1_decode0(&p, tmp_len, &offset, 0, 0, &tmp_read);
rb_ary_push(ary, val);
read += tmp_read;
tmp_len -= tmp_read;
}
RB_GC_GUARD(tmp);
int_ossl_decode_sanity_check(len, read, offset);
return ary;
}
Similar to decode with the difference that decode expects one distinct value represented in der. decode_all on the contrary decodes a sequence of sequential BER/DER values lined up in der and returns them as an array.
Example
ders = File.binread('asn1data_seq') asn1_ary = OpenSSL::ASN1.decode_all(ders)
static VALUE
ossl_asn1_traverse(VALUE self, VALUE obj)
{
unsigned char *p;
VALUE tmp;
long len, read = 0, offset = 0;
obj = ossl_to_der_if_possible(obj);
tmp = rb_str_new4(StringValue(obj));
p = (unsigned char *)RSTRING_PTR(tmp);
len = RSTRING_LEN(tmp);
ossl_asn1_decode0(&p, len, &offset, 0, 1, &read);
RB_GC_GUARD(tmp);
int_ossl_decode_sanity_check(len, read, offset);
return Qnil;
}
If a block is given, it prints out each of the elements encountered. Block parameters are (in that order):
-
depth: The recursion depth, plus one with each constructed value being encountered (
Integer
) -
offset: Current byte offset (
Integer
) -
header length: Combined length in bytes of the Tag and Length headers. (
Integer
) -
length: The overall remaining length of the entire data (
Integer
) -
constructed: Whether this value is constructed or not (Boolean)
-
tag_class: Current tag class (
Symbol
) -
tag: The current tag number (
Integer
)
Example
der = File.binread('asn1data.der') OpenSSL::ASN1.traverse(der) do | depth, offset, header_len, length, constructed, tag_class, tag| puts "Depth: #{depth} Offset: #{offset} Length: #{length}" puts "Header length: #{header_len} Tag: #{tag} Tag class: #{tag_class} Constructed: #{constructed}" end