Crate jwt_compact
source ·Expand description
Minimalistic JSON web token (JWT) implementation with focus on type safety and secure cryptographic primitives.
Design choices
- JWT signature algorithms (i.e., cryptographic algorithms providing JWT integrity)
are expressed via the
Algorithm
trait, which uses fully typed keys and signatures. - JWT header is represented by the
Header
struct. Notably,Header
does not expose thealg
field. Instead,alg
is filled automatically during token creation, and is compared to the expected value during verification. (If you do not know the JWT signature algorithm during verification, you’re doing something wrong.) This eliminates the possibility of algorithm switching attacks.
Additional features
- The crate supports more compact CBOR encoding of the claims. This feature is enabled
via the
ciborium
feature. - The crate supports
EdDSA
algorithm with the Ed25519 elliptic curve, andES256K
algorithm with the secp256k1 elliptic curve. - Supports basic JSON Web Key functionality, e.g., for converting keys to / from JSON or computing a key thumbprint.
Supported algorithms
Algorithm(s) | Feature | Description |
---|---|---|
HS256 , HS384 , HS512 | - | Uses pure Rust sha2 crate |
EdDSA (Ed25519) | exonum-crypto | libsodium binding |
EdDSA (Ed25519) | ed25519-dalek | Pure Rust implementation |
EdDSA (Ed25519) | ed25519-compact | Compact pure Rust implementation, WASM-compatible |
ES256K | es256k | Rust binding for libsecp256k1 |
ES256K | k256 | Pure Rust implementation |
ES256 | p256 | Pure Rust implementation |
RS* , PS* (RSA) | rsa | Uses pure Rust rsa crate with blinding |
EdDSA
and ES256K
algorithms are somewhat less frequently supported by JWT implementations
than others since they are recent additions to the JSON Web Algorithms (JWA) suit.
They both work with elliptic curves
(Curve25519 and secp256k1; both are widely used in crypto community and believed to be
securely generated). These algs have 128-bit security, making them an alternative
to ES256
.
RSA support requires a system-wide RNG retrieved via the getrandom
crate.
In case of a compilation failure in the getrandom
crate, you may want
to include it as a direct dependency and specify one of its features
to assist getrandom
with choosing an appropriate RNG implementation; consult getrandom
docs
for more details. See also WASM and bare-metal E2E tests included
in the source code repository of this crate.
CBOR support
If the ciborium
crate feature is enabled (and it is enabled by default), token claims can
be encoded using CBOR with the AlgorithmExt::compact_token()
method.
The compactly encoded JWTs have the cty
field (content type) in their header
set to "CBOR"
. Tokens with such encoding can be verified in the same way as ordinary tokens;
see examples below.
If the ciborium
feature is disabled, AlgorithmExt::compact_token()
is not available.
Verifying CBOR-encoded tokens in this case is not supported either;
a ParseError::UnsupportedContentType
will be returned when creating an UntrustedToken
from the token string.
no_std
support
The crate supports a no_std
compilation mode. This is controlled by two features:
clock
and std
; both are on by default.
- The
clock
feature enables getting the current time usingUtc::now()
fromchrono
. Without it, someTimeOptions
constructors, such as theDefault
impl, are not available. It is still possible to createTimeOptions
with an explicitly specified clock function, or to set / verify time-relatedClaims
fields manually. - The
std
feature is propagated to the core dependencies and enablesstd
-specific functionality (such as error types implementing the standardError
trait).
Some alloc
types are still used in the no_std
mode, such as String
, Vec
and Cow
.
Note that not all crypto backends are no_std
-compatible.
Examples
Basic JWT lifecycle:
use chrono::{Duration, Utc};
use jwt_compact::{prelude::*, alg::{Hs256, Hs256Key}};
use serde::{Serialize, Deserialize};
/// Custom claims encoded in the token.
#[derive(Debug, PartialEq, Serialize, Deserialize)]
struct CustomClaims {
/// `sub` is a standard claim which denotes claim subject:
/// https://tools.ietf.org/html/rfc7519#section-4.1.2
#[serde(rename = "sub")]
subject: String,
}
// Choose time-related options for token creation / validation.
let time_options = TimeOptions::default();
// Create a symmetric HMAC key, which will be used both to create and verify tokens.
let key = Hs256Key::new(b"super_secret_key_donut_steel");
// Create a token.
let header = Header::empty().with_key_id("my-key");
let claims = Claims::new(CustomClaims { subject: "alice".to_owned() })
.set_duration_and_issuance(&time_options, Duration::days(7))
.set_not_before(Utc::now() - Duration::hours(1));
let token_string = Hs256.token(&header, &claims, &key)?;
println!("token: {token_string}");
// Parse the token.
let token = UntrustedToken::new(&token_string)?;
// Before verifying the token, we might find the key which has signed the token
// using the `Header.key_id` field.
assert_eq!(token.header().key_id, Some("my-key".to_owned()));
// Validate the token integrity.
let token: Token<CustomClaims> = Hs256.validator(&key).validate(&token)?;
// Validate additional conditions.
token.claims()
.validate_expiration(&time_options)?
.validate_maturity(&time_options)?;
// Now, we can extract information from the token (e.g., its subject).
let subject = &token.claims().custom.subject;
assert_eq!(subject, "alice");
Compact JWT
/// Custom claims encoded in the token.
#[derive(Debug, PartialEq, Serialize, Deserialize)]
struct CustomClaims {
/// `sub` is a standard claim which denotes claim subject:
/// https://tools.ietf.org/html/rfc7519#section-4.1.2
/// The custom serializer we use allows to efficiently
/// encode the subject in CBOR.
#[serde(rename = "sub", with = "HexForm")]
subject: [u8; 32],
}
let time_options = TimeOptions::default();
let key = Hs256Key::new(b"super_secret_key_donut_steel");
let claims = Claims::new(CustomClaims { subject: [111; 32] })
.set_duration_and_issuance(&time_options, Duration::days(7));
let token = Hs256.token(&Header::empty(), &claims, &key)?;
println!("token: {token}");
let compact_token = Hs256.compact_token(&Header::empty(), &claims, &key)?;
println!("compact token: {compact_token}");
// The compact token should be ~40 chars shorter.
// Parse the compact token.
let token = UntrustedToken::new(&compact_token)?;
let token: Token<CustomClaims> = Hs256.validator(&key).validate(&token)?;
token.claims().validate_expiration(&time_options)?;
// Now, we can extract information from the token (e.g., its subject).
assert_eq!(token.claims().custom.subject, [111; 32]);
JWT with custom header fields
#[derive(Debug, PartialEq, Serialize, Deserialize)]
struct CustomClaims { subject: [u8; 32] }
/// Additional fields in the token header.
#[derive(Debug, Clone, Serialize, Deserialize)]
struct HeaderExtensions { custom: bool }
let time_options = TimeOptions::default();
let key = Hs256Key::new(b"super_secret_key_donut_steel");
let claims = Claims::new(CustomClaims { subject: [111; 32] })
.set_duration_and_issuance(&time_options, Duration::days(7));
let header = Header::new(HeaderExtensions { custom: true })
.with_key_id("my-key");
let token = Hs256.token(&header, &claims, &key)?;
print!("token: {token}");
// Parse the token.
let token: UntrustedToken<HeaderExtensions> =
token.as_str().try_into()?;
// Token header (incl. custom fields) can be accessed right away.
assert_eq!(token.header().key_id.as_deref(), Some("my-key"));
assert!(token.header().other_fields.custom);
// Token can then be validated as usual.
let token = Hs256.validator::<CustomClaims>(&key).validate(&token)?;
assert_eq!(token.claims().custom.subject, [111; 32]);
Modules
- Implementations of JWT signing / verification algorithms. Also contains generic traits for signing and verifying keys.
- Basic support of JSON Web Keys (JWK).
- Prelude to neatly import all necessary stuff from the crate.
Structs
- Claims encoded in a token.
- A structure with no fields that can be used as a type parameter to
Claims
. - JWT header.
- Algorithm that uses a custom name when creating and validating tokens.
Token
together with the validated token signature.- Time-related options for token creation and validation.
- Token with validated integrity.
- Parsed, but unvalidated token.
- Validator for a certain signing
Algorithm
associated with a specific verifying key and a claims type. Produced by theAlgorithmExt::validator()
method.
Enums
- Identifier of a claim in
Claims
. - Errors that can occur during token creation.
- Errors that may occur during token parsing.
- Errors that can occur during token validation.
Traits
- JWT signing algorithm.
- Automatically implemented extensions of the
Algorithm
trait. - Signature for a certain JWT signing
Algorithm
.