Rasn
Welcome to rasn
(pronounced "raisin"), a safe #[no_std]
ASN.1 codec framework.
That enables you to safely create, share, and handle ASN.1 data types from and to different encoding rules. If you are unfamiliar with ASN.1 and encoding formats like BER/DER, I would recommend reading "A Warm Welcome to ASN.1 and DER" by Let's Encrypt as a quick introduction before continuing. In short it is an "Interface Description Language" (and data model) with a set of encoding formats (called rules) for that model. It was originally designed in the late 1980s and is used throughout the industry especially in telecommunications and cryptography.
Features
Abstract Codec Data Model
There are quite a few existing ASN.1 related Rust crates already, however they are currently specific to a single format or even a single standard, this makes it hard to share and re-use standards that are specified in ASN.1. Now with rasn
's abstract model you can build and share ASN.1 data types as crates that work with any encoder or decoder regardless of the underlying encoding rules, whether it's BER, CER, DER, or your own custom encoding.
#[no_std]
Support
Rasn is entirely #[no_std]
, so you can share the same ASN.1 implementation on any Rust target platform that can support alloc
.
Rich Data Types
Rasn currently has support for nearly all of ASN.1's data types. rasn
uses popular community libraries such as bitvec
, bytes
, and chrono
for some of its data types as well as providing a couple of its own. Check out the types
module for what's currently available.
Safe Codecs
The encoder and decoder have been written in 100% safe Rust and fuzzed with American Fuzzy Lop Plus Plus to ensure that the decoder correctly handles random input, and if valid that the encoder can correctly re-encode that value.
Supported Codecs
- Basic Encoding Rules (BER)
- Canonical Encoding Rules (CER)
- Distinguished Encoding Rules (DER)
- Aligned Packed Encoding Rules (APER)
- Unaligned Packed Encoding Rules (UPER)
- JSON Encoding Rules (JER)
- Octet Encoding Rules (OER)
- Canonical Octet Encoding Rules (COER)
RFC implementations
Rasn also provides implementations for a number of IETF RFCs using the rasn
framework for use out of the box. These crates provide strongly typed
definitions for the necessary data types. Like rasn
they are #[no_std]
,
as well as being transport layer and encoding rule agnostic.
- CMS: Cryptographic Message Syntax
- Kerberos Authentication Framework
- LDAP: Lightweight Directory Access Protocol
- MIB-II: Management of Information Base
- OCSP: Online Certificate Status Protocol
- PKIX: Public Key Infrastructure
- SMI: Structure of Management Information
- SNMP: Simple Network Management Protocol
- S/MIME: Secure/Multipurpose Internet Mail Extensions
Powerful Derive Macros
Easily model your structs and enums with derive equivalents of all of the traits. These macros provide a automatic implementation that ensures your model is a valid ASN.1 type at compile-time. To explain that though, first we have to explain…
How It Works
The codec API has been designed for ease of use, safety, and being hard to misuse. The most common mistakes are around handling the length and ensuring it's correctly encoded and decoded. In rasn
this is completely abstracted away letting you focus on the abstract model. Let's look at what decoding a simple custom SEQUENCE
type looks like.
Person ::= SEQUENCE {
age INTEGER,
name UTF8String
}
Which we want to map to the following equivalent Rust code.
Implementing The Traits
When modelling an ASN.1 data type, there are three traits we'll need to implement. Decode
and Encode
for converting to and from encoding rules, and the shared AsnType
trait; which defines some associated data needed to be given to the encoder and decoder. Currently the only thing we have define is the tag to use to identify our type.
# ;
use ;
Next is the Decode
and Encode
traits. These are mirrors of each other and both have one provided method (decode
/encode
) and one required method (decode_with_tag
/encode_with_tag
). Since in ASN.1 nearly every type can be implicitly tagged allowing anyone to override the tag associated with the type, having *_with_tag
as a required method requires the implementer to correctly handle this case, and the provided methods simply calls *_with_tag
with the type's associated AsnType::TAG
. Let's look at what the codec implementation of Person
looks like.
# use ;
#
#
#
use ;
That's it! We've just created a new ASN.1 that can be encoded and decoded to BER, CER, and DER; and nowhere did we have to check the tag, the length, or whether the string was primitive or constructed encoded. All those nasty encoding rules details are completely abstracted away so your type only has handle how to map to and from ASN.1's data model.
With all the actual conversion code isolated to the codec implementations you can know that your model is always safe to use. The API has also been designed to prevent you from making common logic errors that can lead to invalid encoding. For example; if we look back at our Encode
implementation, what if we forgot to use the encoder we were given in encode_sequence
and tried to use the parent instead?
error[E0501]: cannot borrow `*encoder` as mutable because previous closure requires unique access
--> tests/derive.rs:122:9
|
122 | encoder.encode_sequence(tag, |sequence| {
| ^ --------------- ---------- closure construction occurs here
| | |
| _________| first borrow later used by call
| |
123 | | self.age.encode(encoder)?;
| | ------- first borrow occurs due to use of `encoder` in closure
124 | | self.name.encode(sequence)?;
125 | | Ok(())
126 | | })?;
| |__________^ second borrow occurs here
error[E0500]: closure requires unique access to `encoder` but it is already borrowed
--> tests/derive.rs:122:38
|
122 | encoder.encode_sequence(tag, |sequence| {
| ------- --------------- ^^^^^^^^^^ closure construction occurs here
| | |
| | first borrow later used by call
| borrow occurs here
123 | self.age.encode(encoder)?;
| ------- second borrow occurs due to use of `encoder` in closure
Our code fails to compile! Which, in this case is great, there's no chance that our contents will accidentally be encoded in the wrong sequence because we forgot to change the name of a variable. These ownership semantics also mean that an Encoder
can't accidentally encode the contents of a sequence multiple times in their implementation. Let's see how we can try to take this even further.
Compile-Safe ASN.1 With Macros
So far we've shown how rasn's API takes steps to be safe and protect from accidentally creating an invalid model. However, it's often hard to cover everything in an imperative API. Something that is important to understand about ASN.1 that isn't obvious in the above examples is that; in ASN.1, all types can be identified by a tag (essentially two numbers e.g. INTEGER
's tag is 0, 2
). Field and variant names are not transmitted in most encoding rules, so this tag is also used to identify fields or variants in a SEQUENCE
or CHOICE
. This means that in a ASN.1 struct or enum every field and variant must have a distinct tag for the whole type to be considered valid. For example ; If we changed age
in Person
to be a String
like below it would be invalid ASN.1 even though it compiles and runs correctly, we have to either use a different type or override age
's tag to be distinct from name
's. When implementing the AsnType
trait yourself this requirement must be checked manually, however as we'll see you generally won't need to do that.
Included with rasn is a set of derive macros that enable you to have your ASN.1 model implementation implemented declaratively. The Encode
and Decode
macros will essentially auto-generate the implementations we showed earlier, but the real magic is the AsnType
derive macro. Thanks to the static-assertations
crate and recent developments in const fn
; the AsnType
derive will not only generate your AsnType
implementation, it will also generate a check that asserts that every field or variant has a distinct tag at compile-time. This means now if for some reason we made a change to one of the types in person, we don't have re-check that our model is still valid, the compiler takes care of that for us.
// Invalid
#[derive(rasn::AsnType)]
struct Person {
age: Option<String>,
name: Option<String>,
}
We'll now get the following error trying to compile the above definition.
error[E0080]: evaluation of constant value failed
--> tests/derive.rs:146:10
|
146 | #[derive(rasn::AsnType)]
| ^^^^^^^^^^^^^ the evaluated program panicked at 'Person's fields is not a valid order of ASN.1 tags, ensure that your field's tags and OPTIONAL
s are correct.', tests/derive.rs:146:10
|
= note: this error originates in the macro `$crate::panic::panic_2015` (in Nightly builds, run with -Z macro-backtrace for more info)
Validating your model at compile-time enables you to work on ASN.1 code without fear that you're unintentionally changing something in the background. I bet you're wondering now though, how we are supposed to have a struct with two strings for fields? The answer is thankfully pretty simple, you just add #[rasn(tag)]
attribute to override the tags of one or more of the types. However we can actually go further, because in ASN.1 there's the concept of having AUTOMATIC TAGS
which essentially tells your ASN.1 compiler to automatically generate distinct tags for your ASN.1 definition. Now with rasn you can do that in Rust! Applying #[rasn(automatic_tags)]
to the container will apply the same automatic tagging transformation you'd expect from an ASN.1 compiler.
use AsnType;
// Valid
// Also valid
Reference
The following table provides a range of examples showing how to declare data types with rasn
.
Test-type-b ::= BOOLEAN
Test-type-a ::= Test-type-b
// either
use *;
type TestTypeB = bool;
type TestTypeA = TestTypeB;
// or
use *;
;
/// or
;
Test-type-a ::= BOOLEAN
// either
use *;
;
// or
use *;
type TestTypeA = bool;
Test-type-a ::= NULL
// either
use *;
;
// or
use *;
);
// or
use *;
type TestTypeA = ;
Test-type-a ::= INTEGER
use *;
// either
;
// or
use *;
;
// or
use *;
type TestTypeA = Integer;
// or
use *;
type TestTypeA = u8; // or any other rust integer type
Test-type-a ::= INTEGER (8)
// either
use *;
;
// or
use *;
;
Test-type-a ::= INTEGER (-8..360)
Test-type-b ::= INTEGER (MIN..360)
Test-type-c ::= INTEGER (42..MAX)
use *;
/// of course a primitive rust integer would still work in these examples
;
;
;
Test-type-a ::= INTEGER (42,...)
Test-type-b ::= INTEGER (1..360,...)
use *;
/// of course a primitive rust integer would still work in these examples
;
;
Test-type-a ::= ENUMERATED { seed, grape, raisin }
use *;
/// See below
Test-type-a ::= ENUMERATED { seed, grape, ..., raisin }
use *;
/// See below
TestModule DEFINITIONS AUTOMATIC TAGS ::=
BEGIN
Test-type-a ::= ENUMERATED { seed, grape, raisin }
Test-type-b ::= ENUMERATED { juice, wine, grappa }
END
use *;
/// The tagging encironment has to be declared for every rasn-annotated struct or enum
/// There is no implicit extensibility
TestModule DEFINITIONS EXPLICIT TAGS ::=
BEGIN
Test-type-a ::= [APPLICATION 1] ENUMERATED { seed, grape, raisin }
Test-type-b ::= [APPLICATION 2] ENUMERATED { juice, wine, grappa }
END
use *;
/// The tagging encironment has to be declared for every rasn-annotated struct or enum
/// There is no implicit extensibility
TestModule DEFINITIONS IMPLICIT TAGS ::=
BEGIN
Test-type-a ::= [APPLICATION 1] ENUMERATED { seed, grape, raisin }
Test-type-b ::= [APPLICATION 2] ENUMERATED { juice, wine, grappa }
END
use *;
/// The tagging encironment has to be declared for every rasn-annotated struct or enum
/// There is no implicit extensibility
Test-type-a ::= CHOICE {
seed BOOLEAN,
grape BIT STRING SIZE(1,...),
raisin OCTET STRING
}
Test-type-b ::= CHOICE {
juice INTEGER (0..3,...),
wine OCTET STRING,
...,
grappa INTEGER
}
use *;
Test-type-a ::= SEQUENCE {
juice INTEGER (0..3,...),
wine OCTET STRING,
...,
grappa INTEGER OPTIONAL,
water BIT STRING (SIZE(1)) OPTIONAL
}
use *;
Test-type-a ::= SET {
seed NULL,
grape BOOLEAN,
raisin INTEGER
}
use *;
/// the SET declaration is basically identical to a SEQUENCE declaration,
/// except for the `set` annotation
Test-type-a ::= SEQUENCE {
notQuiteRustCase INTEGER
}
use *;
Test-type-a ::= SEQUENCE {
seed BOOLEAN DEFAULT TRUE,
grape INTEGER OPTIONAL,
raisin INTEGER DEFAULT 1
}
use *;
/// DEFAULTs are provided via linked helper functions
Test-type-a ::= SEQUENCE OF BOOLEAN
Test-type-b ::= SEQUENCE OF INTEGER(1,...)
use *;
;
/// Constrained inner primitive types need to be wrapped in a helper newtype
;
;
Test-type-a ::= UTF8String
use *;
/// the other charater types supported by rasn behave exactly the same:
/// NumericString, VisibleString, Ia5String, TeletexString, GeneralString, BmpString, PrintableString
/// (and also for BIT STRING and OCTET STRING)
;
Test-type-a ::= BIT STRING
use *;
;
Test-type-a ::= OCTET STRING
use *;
;
Test-type-a ::= UTF8String (SIZE (42,...))
Test-type-b ::= SEQUENCE (SIZE (1..8)) OF BOOLEAN
use *;
/// The size constraint definition behaves similar to the value definition (see above)
;
;
Test-type-a ::= UTF8String (FROM ("A".."Z"))
use *;
;
Sponsorship
This project was funded through the NGI Assure Fund, a fund established by NLnet with financial support from the European Commission's Next Generation Internet programme, under the aegis of DG Communications Networks, Content and Technology under grant agreement No 957073.
Disclaimer
The software is provided "as is" and the authors disclaim all warranties with regard to this software including all implied warranties of merchant-ability and fitness. In no event shall the authors be liable for any special, direct, indirect, or consequential damages or any damages whatsoever resulting from loss of use, data or profits, whether in an action of contract, negligence or other tortuous action, arising out of or in connection with the use or performance of this software.