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DIDComm Rust + JavaScript/TypeScript + Swift

License Unit Tests Rust Package

The repository consists of the following main components:

The docs below are provided for the main DIDComm Rust.

See wasm/README.md for DIDComm JavaScript/TypeScript docs.

See wrappers/swift/README.md for DIDComm Swift docs.

Usage

To use didcomm, add this to your Cargo.toml:

[dependencies]
didcomm = "0.4"

Run examples

Use cargo run --example {example-name} for example cargo run --example basic.

Assumptions and Limitations

  • Rust 2018 edition is required.
  • In order to use the library, SecretsResolver and DIDResolver traits must be implemented on the application level. Implementation of that traits is out of DIDComm library scope, but we provide 2 simple implementation ExampleDIDResolver and ExampleSecretsResolver that allows resolve locally known DID docs and secrets for tests/demo purposes.
    • Verification materials are expected in JWK, Base58 and Multibase (internally Base58 only) formats.
      • In Base58 and Multibase formats, keys using only X25519 and Ed25519 curves are supported.
      • For private keys in Base58 and Multibase formats, the verification material value contains both private and public parts (concatenated bytes).
      • In Multibase format, bytes of the verification material value is prefixed with the corresponding Multicodec code.
    • Key IDs (kids) used in SecretsResolver must match the corresponding key IDs from DID Doc verification methods.
    • Key IDs (kids) in DID Doc verification methods and secrets must be a full DID Fragment, that is did#key-id.
    • Verification methods referencing another DID Document are not supported (see Referring to Verification Methods).
  • The following curves and algorithms are supported:
    • Encryption:
      • Curves: X25519, P-256
      • Content encryption algorithms:
        • XC20P (to be used with ECDH-ES only, default for anoncrypt),
        • A256GCM (to be used with ECDH-ES only),
        • A256CBC-HS512 (default for authcrypt)
      • Key wrapping algorithms: ECDH-ES+A256KW, ECDH-1PU+A256KW
    • Signing:
      • Curves: Ed25519, Secp256k1, P-256
      • Algorithms: EdDSA (with crv=Ed25519), ES256, ES256K
  • Forward protocol is implemented and used by default.
  • DID rotation (fromPrior field) is supported.
  • DIDComm has been implemented under the following Assumptions

Examples

See examples for details.

A general usage of the API is the following:

  • Sender Side:
    • Build a Message (plaintext, payload).
    • Convert a message to a DIDComm Message for further transporting by calling one of the following:
      • Message::pack_encrypted to build an Encrypted DIDComm message
      • Message::pack_signed to build a Signed DIDComm message
      • Message::pack_plaintext to build a Plaintext DIDComm message
  • Receiver side:
    • Call Message::unpack on receiver side that will decrypt the message, verify signature if needed and return a Message for further processing on the application level.

1. Build an Encrypted DIDComm message for the given recipient

This is the most common DIDComm message to be used in most of the applications.

A DIDComm encrypted message is an encrypted JWM (JSON Web Messages) that

  • hides its content from all but authorized recipients
  • (optionally) discloses and proves the sender to only those recipients
  • provides message integrity guarantees

It is important in privacy-preserving routing. It is what normally moves over network transports in DIDComm applications, and is the safest format for storing DIDComm data at rest.

See Message::pack_encrypted documentation for more details.

Authentication encryption example (most common case):

// --- Build message from ALICE to BOB ---
let msg = Message::build(
    "example-1".to_owned(),
    "example/v1".to_owned(),
    json!("example-body"),
)
.to(ALICE_DID.to_owned())
.from(BOB_DID.to_owned())
.finalize();

// --- Pack encrypted and authenticated message ---
let did_resolver = ExampleDIDResolver::new(vec![ALICE_DID_DOC.clone(), BOB_DID_DOC.clone()]);
let secrets_resolver = ExampleSecretsResolver::new(ALICE_SECRETS.clone());

let (msg, metadata) = msg
    .pack_encrypted(
        BOB_DID,
        Some(ALICE_DID),
        None,
        &did_resolver,
        &secrets_resolver,
        &PackEncryptedOptions::default(),
    )
    .await
    .expect("Unable pack_encrypted");

println!("Encryption metadata is\n{:?}\n", metadata);

// --- Send message ---
println!("Sending message \n{}\n", msg);

// --- Unpacking message ---
let did_resolver = ExampleDIDResolver::new(vec![ALICE_DID_DOC.clone(), BOB_DID_DOC.clone()]);
let secrets_resolver = ExampleSecretsResolver::new(BOB_SECRETS.clone());

let (msg, metadata) = Message::unpack(
    &msg,
    &did_resolver,
    &secrets_resolver,
    &UnpackOptions::default(),
)
.await
.expect("Unable unpack");

println!("Receved message is \n{:?}\n", msg);
println!("Receved message unpack metadata is \n{:?}\n", metadata);

Anonymous encryption example:

let (msg, metadata) = msg
    .pack_encrypted(
        BOB_DID,
        None, // Keep sender as None here
        None,
        &did_resolver,
        &secrets_resolver,
        &PackEncryptedOptions::default(),
    )
    .await
    .expect("Unable pack_encrypted");

Encryption with non-repudiation example:

let (msg, metadata) = msg
    .pack_encrypted(
        BOB_DID,
        Some(ALICE_DID),
        Some(ALICE_DID), // Provide information about signer here
        &did_resolver,
        &secrets_resolver,
        &PackEncryptedOptions::default(),
    )
    .await
    .expect("Unable pack_encrypted");

2. Build an unencrypted but Signed DIDComm message

Signed messages are only necessary when

  • the origin of plaintext must be provable to third parties
  • or the sender can’t be proven to the recipient by authenticated encryption because the recipient is not known in advance (e.g., in a broadcast scenario).

Adding a signature when one is not needed can degrade rather than enhance security because it relinquishes the sender’s ability to speak off the record.

See Message::pack_signed documentation for more details.

// ALICE
let msg = Message::build(
    "example-1".to_owned(),
    "example/v1".to_owned(),
    json!("example-body"),
)
.to(ALICE_DID.to_owned())
.from(BOB_DID.to_owned())
.finalize();

let (msg, metadata) = msg
    .pack_signed(ALICE_DID, &did_resolver, &secrets_resolver)
    .await
    .expect("Unable pack_signed");

// BOB
let (msg, metadata) = Message::unpack(
    &msg,
    &did_resolver,
    &secrets_resolver,
    &UnpackOptions::default(),
)
.await
.expect("Unable unpack");

3. Build a Plaintext DIDComm message

A DIDComm message in its plaintext form that

  • is not packaged into any protective envelope
  • lacks confidentiality and integrity guarantees
  • repudiable

They are therefore not normally transported across security boundaries.

// ALICE
let msg = Message::build(
    "example-1".to_owned(),
    "example/v1".to_owned(),
    json!("example-body"),
)
.to(ALICE_DID.to_owned())
.from(BOB_DID.to_owned())
.finalize();

let msg = msg
    .pack_plaintext(&did_resolver)
    .expect("Unable pack_plaintext");

// BOB
let (msg, metadata) = Message::unpack(
    &msg,
    &did_resolver,
    &secrets_resolver,
    &UnpackOptions::default(),
)
.await
.expect("Unable unpack");

Contribution

PRs are welcome!

The following CI checks are run against every PR:

  • No warnings from cargo check --all-targets
  • All tests must pass with cargo tests
  • Code must be formatted by cargo fmt --all

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  • Rust 77.2%
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  • TypeScript 7.9%
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