Crates.io | ece |
lib.rs | ece |
version | 2.3.1 |
source | src |
created_at | 2019-01-22 04:08:15.601101 |
updated_at | 2024-01-22 16:55:26.084328 |
description | Encrypted Content-Encoding for HTTP Rust implementation. |
homepage | |
repository | https://github.com/mozilla/rust-ece |
max_upload_size | |
id | 109924 |
size | 112,543 |
This crate has not been security reviewed yet, use at your own risk (tracking issue).
The ece crate is a Rust implementation of Message Encryption for Web Push (RFC8291) and the HTTP Encrypted Content-Encoding scheme (RFC8188) on which it is based.
It provides low-level cryptographic "plumbing" and is destined to be used by higher-level Web Push libraries, both on the server and the client side. It is a port of the ecec C library.
This crate implements both the published Web Push Encryption scheme, and a legacy scheme from earlier drafts that is still widely used in the wild:
aes128gcm
: the scheme described in RFC8291 and
RFC8188aesgcm
: the draft scheme described in
draft-ietf-webpush-encryption-04 and
draft-ietf-httpbis-encryption-encoding-03It does not support, and we have no plans to ever support, the obsolete aesgcm128
scheme
from earlier drafts.
To receive messages via WebPush, the receiver must generate an EC keypair and a symmetric authentication secret, then distribute the public key and authentication secret to the sender:
let (keypair, auth_secret) = ece::generate_keypair_and_auth_secret()?;
let pubkey = keypair.pub_as_raw();
// Base64-encode the `pubkey` and `auth_secret` bytes and distribute them to the sender.
The sender can encrypt a Web Push message to the receiver's public key:
let ciphertext = ece::encrypt(&pubkey, &auth_secret, b"payload")?;
And the receiver can decrypt it using their private key:
let plaintext = ece::decrypt(&keypair, &auth_secret, &ciphertext)?;
That's pretty much all there is to it! It's up to the higher-level library to manage distributing the encrypted payload,
typically by arranging for it to be included in a HTTP response with Content-Encoding: aes128gcm
header.
aesgcm
encryptionThe legacy aesgcm
scheme is more complicated, because it communicates some encryption parameters in HTTP header fields
rather than as part of the encrypted payload. When used for encryption, the sender must deal with Encryption
and
Crypto-Key
headers in addition to the ciphertext:
let encrypted_block = ece::legacy::encrypt_aesgcm(pubkey, auth_secret, b"payload")?;
for (header, &value) in encrypted_block.headers().iter() {
// Set header to corresponding value
}
// Send encrypted_block.body() as the body
When receiving an aesgcm
message, the receiver needs to parse encryption parameters from the Encryption
and Crypto-Key
fields:
// Parse `rs`, `salt` and `dh` from the `Encryption` and `Crypto-Key` headers.
// You'll need to consult the spec for how to do this; we might add some helpers one day.
let encrypted_block = ece::AesGcmEncryptedBlock::new(dh, rs, salt, ciphertext);
let plaintext = ece::legacy::decrypt_aesgcm(keypair, auth_secret, encrypted_block)?;
aes128gcm
; messages using the
legacy aesgcm
scheme must fit in a single record.These restrictions might be lifted in future, if it turns out that we need them.
This crate is designed to use pluggable backend implementations of low-level crypto primitives. different crypto backends. At the moment only openssl is supported.
We use cargo-release
to manage releases. To cut a new release,
make sure you have it installed and then:
git checkout -b release-vX.Y.Z
git push -u origin release-vX.Y.Z
cargo release --dry-run -vv [major|minor|patch]
and check that the things
it's proposing to do seem sensible.cargo release [major|minor|patch]
to prepare, commit, tag and publish the release.release-vX.Y.Z
branch to request it be merged to the main branch.