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dir: /man/2/asn1/

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.TH ASN1 2
.SH NAME
asn1: decode, encode \- ASN.1 (X.208), BER (X.209) encoding
.SH SYNOPSIS
.EX
include "asn1.m";
asn1 := load ASN1 ASN1->PATH;
asn1->init();

Elem: adt {
    tag: Tag;
    val: ref Value;

    is_seq:         fn(e: self ref Elem): (int, list of ref Elem);
    is_set:         fn(e: self ref Elem): (int, list of ref Elem);
    is_int:         fn(e: self ref Elem): (int, int);
    is_bigint:      fn(e: self ref Elem): (int, array of byte);
    is_bitstring:   fn(e: self ref Elem): (int, int, array of byte);
    is_octetstring: fn(e: self ref Elem): (int, array of byte);
    is_oid:         fn(e: self ref Elem): (int, ref Oid);
    is_string:      fn(e: self ref Elem): (int, string);
    is_time:        fn(e: self ref Elem): (int, string);
    tostring:       fn(e: self ref Elem): string;
};

Tag: adt {
    class: int;
    num: int;
    constr: int;

    tostring: fn(t: self Tag): string;
};

Value: adt {
    pick {
        Bool or Int =>
            v: int;
        Octets or BigInt or Real or Other =>
            bytes: array of byte;
        BitString =>
            unusedbits: int;
            bits: array of byte;
        Null or EOC =>
            ;
        ObjId =>
            id: ref Oid;
        String =>
            s: string;
        Seq or Set =>
            l: list of ref Elem;
    }

    tostring: fn(v: self ref Value): string;
};

Oid: adt {
    nums: array of int;
    tostring: fn(o: self ref Oid): string;
};

init: fn();
decode:       fn(a: array of byte): (string, ref Elem);
decode_seq:   fn(a: array of byte): (string, list of ref Elem);
decode_value: fn(a: array of byte, kind, constr: int):
              (string, ref Value);
encode:       fn(e: ref Elem): (string, array of byte);
oid_lookup:   fn(o: ref Oid, tab: array of Oid): int;
print_elem:   fn(e: ref Elem);

.EE
.SH DESCRIPTION
.B ASN1
supports decoding and encoding of the ASN.1 Basic Encoding Rules
(BER, ITU-T Recommendation X.209).
Despite its name, the module is not a parser for Abstract Syntax Notation One
(ASN.1, ITU-T Recommendation X.208).
.PP
.B ASN1
handles the BER encodings of all types from the ASN.1 Universal class, and
provides a simple OBJECT IDENTIFIER comparison facility.
.PP
For simplicity,
.B ASN1
does not take a description of the ASN.1 module of the data being
processed.
Consequently, the (de)composition of tagged types must be performed by the
application.
.B ASN1
does not know the
context of tagged values and so cannot determine the underlying Universal type
to be able to encode or decode the value automatically.
See the section on Tagging for details on how the application
should handle both implicit and explicit tagging.
.TP
.B init()
The module must be initialised by calling this function
before any other module functions or associated adt member functions are called.
.TP
.BI decode( a )
Convert the BER encoding given by the byte array
.I a
into an
.B Elem
representing the ASN.1 value.
The byte array must contain
the entire BER encoding of the value and any component values.
.IP
Item values not tagged as a Universal type are converted to an
.B Elem
comprised of the decoded
.B Tag
and a
value given by the
.B Value.Octets
variant, which contains
the original encoding of the value
stripped of the BER tag and length header.
.IP
The function returns a tuple composed of an error string and
the decoded
.BR Elem .
If no errors are encountered the error string is nil.
.TP
.BI decode_seq( a )
Like
.B decode
except that the data in
.I a
is the encoding of an item of type SEQUENCE, SEQUENCE OF, SET or SET OF
which has been stripped of its tag and length header.
The function decodes all of the items in the SEQUENCE or SET.
.IP
The return value is a tuple composed of an error string and the list of
.BR Elem s
forming the SEQUENCE or SET.
.HP
.BI decode_value( a ,
.IB kind ,
.IB constr )
.br
Convert the encoding of a single item value to a
.B Value
data structure.
.IP
The array
.I a
does not include the tag and length header.
Instead, the value's Universal type is given by the
.I kind
argument and length is given by that of the array.
The
.B constr
argument indicates if the encoding is in the BER
constructed form or not.
A value of 0 indicates that the primitive encoding is used, all other values
indicate the constructed encoding.
.IP
The function returns a tuple composed of an error string and a
.B Value
reference.
.TP
.BI encode( e )
Convert the
.B Elem
.I e
to a BER encoding of the element.
If the element is of a structured type, such as SEQUENCE or SET,
then all component values are also exhaustively encoded.
.IP
The encoding can fail if the
.B Tag
and
.B Value
of the element are not compatible.
The
.I constr
field of the
.B Tag
is currently ignored.
.IP
The function returns a tuple comprising an error string and
the BER encoding.  
If no errors are encountered the error string is nil and the
second part of the returned tuple is a byte array of the
BER encoding.
.TP
.BI oid_lookup( o ", " tab )
Lookup an OBJECT IDENTIFIER value in an array of such values.
Returns the index of the first exact match of
.I o
in the
.I tab
array.
Returns -1 if no match is found.
.TP
.BI print_elem( e )
Print a textual representation of the element to standard output.
The output is that given by
.BR Elem.tostring() ,
followed by a newline character.
.SS "Elem adt"
This is the principal data structure, representing the value of an ASN.1 item.
The adt couples a data representation, the
.BR Value ,
with its type specifier, the
.BR Tag .
.TP
.B "Elem.tag"
Specifies the ASN.1 type of the element value.
See the description of the
.B Tag
adt for more details.
.TP
.B "Elem.val"
The value of the element.
See the description of the
.B Value
adt for more details.
.PP
All of the
.IB e .is_ Type
member functions test whether the specific
.B Value
pick variant of
.B Elem.val
and the ASN.1 Universal type, given by
the tag, match and are of the requested form.
A successful match yields the type specific data from the
.B Value
pick variant.
The association of Universal types to
.B Value
pick variants is given in the section on the 
.B Value
adt.
.PP
The function
.IB e .is_int
succeeds for BOOLEAN and INTEGER ASN.1 types.
The function
.IB e .is_string
succeeds for all of the ASN.1 Universal string types.
.PP
Except for
.BR is_bitstring ,
each function returns a tuple of two values.
The first tuple item is an integer, 1 for success, 0 for failure.
The second item is the type specific data from the
.B Value
pick variant.
.PP
.TP
.IB e ".is_bitstring()"
Like the
.BI is_ Type
functions described above.
Tests that the element is a BIT STRING and returns its data.
.IP
The return value is a tuple comprised of two integers and an array of bytes.
The byte array represents the bit string.
The first integer is 1 for success, 0 for failure.
The second integer is the number of unused bits in the last byte of the data
array.
See the description of the
.B Value.BitString
variant for more information.
.TP
.IB e ".tostring()"
returns a textual representation of the element formed by joining
the strings returned from
.IB e ".tag.tostring()"
and
.IB e ".val.tostring()" .
.PP
.SS "Tag adt"
The
.B Tag
adt denotes the ASN.1 type of a
.B Value
instance.
.TP
.B "Tag.class"
Specifies the class of the type and can take one of the values:
.BR ASN1->Universal ,
.BR ASN1->Application ,
.B ASN1->Context
or
.BR ASN1->Private .
.TP
.B "Tag.num"
Identifies the particular type, or tag, within the specified class.
Tag numbers for the Universal class are given in the
.B asn1.m
header file.
The inconsistent use of upper-case and mixed-case identifiers comes
straight from the ITU-T Recommendation.
.TP
.B "Tag.constr"
This flag is set by the
.B ASN1
decode functions to mark if the BER
.I constructed
encoding was used for the value.
A zero value indicates the BER primitive encoding, non-zero indicates
the constructed encoding.
.TP
.IB t ".tostring()"
Returns a string representation of the
.BR Tag .
For Universal class tags the function returns
the string
.RB `` UNIVERSAL
.IR "Name" '',
where
.I Name
is the standard name of the specified Universal type.
For other classes the function returns the class name, in upper-case,
followed by the tag number.
.SS "Value adt"
This pick adt provides the representation for values of each of the various
Universal class types.
Values of all other classes are represented by the
.B Value.Octets
branch of the pick.
.TP
.IB v ".tostring()"
Returns a string representation of the
.BR Value .
.PP
The following table lists
each variant of the pick, indicating the ASN.1 Universal type values
it represents, followed by a brief description.
For each variant of the pick,
.I v
is taken to be of that particular type.
.TP
.B Value.Bool
BOOLEAN
.IP
.IB v .v
equals zero for FALSE, non-zero values represent TRUE.
.TP
.B Value.Int
INTEGER, ENUMERATED
.IP
The value is given by
.IB v .v
.TP
.B Value.BigInt
Used for INTEGER values too large to fit a Limbo int.
.IP
The array
.IB v .bytes
contains the encoding of the value.
The array does not include the tag and length prefix.
.TP
.B Value.Octets
OCTET_STRING, ObjectDescriptor
.IP
The octet string is given by the
.IB v .bytes
array.
.TP
.B Value.Null
NULL
.TP
.B Value.ObjId
OBJECT_ID
.IP
The OBJECT_ID value is represented by the
.B Oid
adt given by
.IB v .id .
.TP
.B Value.Real
REAL
.IP
.B ASN1
does not convert the value into the Limbo
.B real
data type.
The encoding of the value is given by the
.IB v .bytes
array, which does not include the tag and length prefix.
.TP
.B Value.Other
EXTERNAL, EMBEDDED_PDV and Unknown Universal types
.IP
The raw bytes of the value, excluding the tag nad length header,
are given by the
.IB v .bytes
array.
.TP
.B Value.BitString
BIT_STRING
.IP
The number of bits in the BIT_STRING value does not have to be
a multiple of 8.
Bits are packed into bytes MSB first.
The bytes representing the BIT_STRING value, including the potentially
incomplete last byte, are given by the
.IB v .bits
array.
The number of unused bits in the last byte of the array is given by
.IB v .unused ,
counting from the LSB.
.IP
The BER constructed encoding of values other than zero-length is not implemented.
.TP
.B Value.EOC
End of Contents octets marker.
.IP
This value is not normally returned to the application; it is used
privately by BER to support indefinite length value encodings.
.TP
.B Value.String
NumericString, PrintableString, TeletexString,
VideotexString, IA5String, UTCTime,
GeneralizedTime, GraphicString, VisibleString,
GeneralString, UniversalString or BMPString.
.IP
The text is given by the
.IB v .s
Limbo string.
Currently no character-set conversion is performed between
the ASN.1 string byte codes and the Unicode code-points of the Limbo string.
.TP
.B Value.Seq
SEQUENCE, SEQUENCE OF
.IP
ASN.1 assigns both constructs the same type tag.
The difference between them is that, within the
ASN.1 notation, the elements
of a SEQUENCE OF structure are constrained to be of the same type.
BER and, consequently,
.B ASN1
do not directly enforce the restriction.
.IP
The elements of the sequence are given by the
.IB v .l
list.
.TP
.B Value.Set
SET, SET OF
.IP
ASN.1 assigns both constructs the same type tag.
The difference between them is that, within the ASN.1 notation,
SET items are formed from an unordered list of distinct types, whereas
SET OF items are formed from an unordered list of the same type.
BER and
.B ASN1
do not enforce these constraints.
.IP
The elements of the set are given by the
.IB v .l
list.
.SS "Oid adt"
The
.B Oid
adt provides the value representation for OBJECT IDENTIFERs.
Within the ASN.1 notation OBJECT IDENTIFIERs ultimately map
to an ordered list of INTEGERs.
.TP
.B Oid.nums
The value of the OBJECT IDENTIFIER, given as an
.BR "array of int" .
.TP
.IB o .tostring()
Returns a textual representation of the OBJECT IDENTIFIER in the
form of a `.' separated list of numbers.
.SS Tagging
Tagging is an ASN.1 mechanism for disambiguating values.
It is usually applied to component types, where several components
of a structured type have the same underlying Universal class type.
Tagging allows the client application to determine to which item of the
structured type a value instance belongs.
.PP
There are two types of tagging, implicit and explicit, defining
the manner in which the values are encoded.
.PP
Implicitly tagged values are encoded in the same way as the underlying type,
but with the tag class and number replaced by that specified.
.PP
Explicitly tagged values are encoded in a nested fashion.
The outermost item bears the specified tag and its contents is the
full encoding of the original value using the tag of its underlying type.
.PP
The following examples of how to decode and encode simple tagged types
should make the distinction clear.
.SS "Decoding Tagged Values"
Consider the following ASN.1 type definitions:
.PP
.EX
    Type1 ::= INTEGER
    Type2 ::= [Application 2] Type1     -- Explicitly tagged
    Type3 ::= [3] IMPLICIT Type1        -- Implicitly tagged

.EE
For each of the types
the value 16r55 will be decoded as follows:
.PP
.EX
	(error, elem) := asn1->decode(data);
.EE
.TP
.BR Type1 " (primitive type)"
.EX
elem.tag.class == Universal
elem.tag.num == INTEGER
tagof elem.val == tagof Value.Int
elem.is_int() == (1, 16r55)
.EE
.TP
.BR Type2 " (explicitly tagged)"
.EX
elem.tag.class == Application
elem.tag.num == 2
tagof elem.val == tagof Value.Octets

.EE
The
.B bytes
array of the
.B Value.Octets
value contains the complete encoding of the
.B Type1
value.
The actual value can be obtained as follows:
.IP
.EX
pick v := elem.val {
Octets =>
	(err2, e2) := asn1->decode(v.bytes);
}
.EE
with
.B e2
having exactly the same properties as
.B elem
in the
.B Type1
case above.
.TP
.BR Type3 " (implicitly tagged)"
.EX
elem.tag.class == Context
elem.tag.num == 3
tagof elem.val == tagof Value.Octets

.EE
In this case the
.B bytes
array of the
.B Value.Octets
value contains the encoding of just the value part of the Type1 value,
not the complete encoding.
The actual value can be obtained as follows:
.IP
.EX
pick v := e.val {
Octets =>
    constr := e.tag.constr;
    (err, val) := asn1->decode_value(v.bytes, INTEGER, constr);
}

.EE
Note that the application has to infer the type of the value from
the context in which it occurs.
The resultant
.B val
is of the type
.B Value.Int
with the value 16r55 stored in the
.B v
member variable.
.SS "Encoding Tagged Values"
To encode the value 16r55 in each of the above types, the following
data structures are required.
.TP
.BR Type1 "(primitive type)"
.EX
tag := Tag(Universal, INTEGER, 0);
val := Value.Int(16r55);
elem := ref Elem(tag, val);
(err, data) := asn1->encode(elem);
.EE
.TP
.BR Type2 "(explicitly tagged)"
.EX
tag1          := Tag(Universal, INTEGER, 0);
val1          := Value.Int(16r55);
elem1         := ref Elem(tag1, val1);
(err1, data1) := asn1->encode(elem1);
tag2          := Tag(Application, 2, 0);
val2          := Value.Octets(data1);
elem2         := ref Elem(tag2, val2);
(err, data)   := asn1->encode(elem2);
.EE
.TP
.BR Type3 "(implicitly tagged)"
.EX
tag         := Tag(Context, 3, 0);
val         := Value.Int(16r55);
elem        := ref Elem(tag, val);
(err, data) := asn1->encode(elem);
.EE
.SH SOURCE
.B /appl/lib/asn1.b
.SH BUGS
It is irritating that REAL values are not converted by the module.
This forces the application to do the conversion to and from the
raw BER encoding.  Fortunately they are rarely used.
.PP
String encodings are converted as UTF-8 byte sequences.
This will result in strings comprising any character codes above 127
being incorrectly converted.
.PP
There is a particular form of BER encoding that the module will
handle incorrectly, resulting in a decoding error.
The error occurs when a tagged value is encoded using the
indefinite length specifier and the constructed representation.