Rustls is a modern TLS library written in Rust.
Rustls is used in production at many organizations and projects. We aim to maintain reasonable API surface stability but the API may evolve as we make changes to accomodate new features or performance improvements.
We have a roadmap for our future plans. We also have benchmarks to prevent performance regressions and to let you evaluate rustls on your target hardware.
If you'd like to help out, please see CONTRIBUTING.md.
The detailed list of changes in each release can be found at https://github.com/rustls/rustls/releases.
Rustls is a TLS library that aims to provide a good level of cryptographic security, requires no configuration to achieve that security, and provides no unsafe features or obsolete cryptography by default.
Rustls implements TLS1.2 and TLS1.3 for both clients and servers. See the full list of protocol features.
While Rustls itself is platform independent, by default it uses aws-lc-rs
for implementing
the cryptography in TLS. See the aws-lc-rs FAQ for more details of the
platform/architecture support constraints in aws-lc-rs.
ring
is also available via the ring
crate feature: see
the supported ring
target platforms.
By providing a custom instance of the crypto::CryptoProvider
struct, you
can replace all cryptography dependencies of rustls. This is a route to being portable
to a wider set of architectures and environments, or compliance requirements. See the
crypto::CryptoProvider
documentation for more details.
Specifying default-features = false
when depending on rustls will remove the
dependency on aws-lc-rs.
Rustls requires Rust 1.61 or later.
Since Rustls 0.22 it has been possible to choose the provider of the cryptographic primitives
that Rustls uses. This may be appealing if you have specific platform, compliance or feature
requirements that aren't met by the default provider, aws-lc-rs
.
Users that wish to customize the provider in use can do so when constructing ClientConfig
and ServerConfig
instances using the with_crypto_provider
method on the respective config
builder types. See the crypto::CryptoProvider
documentation for more details.
Rustls ships with two built-in providers controlled with associated feature flags:
aws-lc-rs
- enabled by default, available with theaws_lc_rs
feature flag enabled.ring
- available with thering
feature flag enabled.
See the documentation for crypto::CryptoProvider
for details on how providers are
selected.
The community has also started developing third-party providers for Rustls:
rustls-mbedtls-provider
- a provider that usesmbedtls
for cryptography.boring-rustls-provider
- a work-in-progress provider that usesboringssl
for cryptography.rustls-rustcrypto
- an experimental provider that uses the crypto primitives fromRustCrypto
for cryptography.rustls-post-quantum
: an experimental provider that adds support for post-quantum key exchange to the default aws-lc-rs provider.
We also provide a simple example of writing your own provider in the custom-provider
example. This example implements a minimal provider using parts of the RustCrypto
ecosystem.
See the Making a custom CryptoProvider section of the documentation for more information on this topic.
Our examples directory contains demos that show how to handle I/O using the
stream::Stream
helper, as well as more complex asynchronous I/O using mio
.
If you're already using Tokio for an async runtime you may prefer to use
tokio-rustls
instead of interacting with rustls directly.
The mio
based examples are the most complete, and discussed below. Users
new to Rustls may prefer to look at the simple client/server examples before
diving in to the more complex MIO examples.
The MIO client example program is named tlsclient-mio
. The interface looks like:
Connects to the TLS server at hostname:PORT. The default PORT
is 443. By default, this reads a request from stdin (to EOF)
before making the connection. --http replaces this with a
basic HTTP GET request for /.
If --cafile is not supplied, a built-in set of CA certificates
are used from the webpki-roots crate.
Usage:
tlsclient-mio [options] [--suite SUITE ...] [--proto PROTO ...] [--protover PROTOVER ...] <hostname>
tlsclient-mio (--version | -v)
tlsclient-mio (--help | -h)
Options:
-p, --port PORT Connect to PORT [default: 443].
--http Send a basic HTTP GET request for /.
--cafile CAFILE Read root certificates from CAFILE.
--auth-key KEY Read client authentication key from KEY.
--auth-certs CERTS Read client authentication certificates from CERTS.
CERTS must match up with KEY.
--protover VERSION Disable default TLS version list, and use
VERSION instead. May be used multiple times.
--suite SUITE Disable default cipher suite list, and use
SUITE instead. May be used multiple times.
--proto PROTOCOL Send ALPN extension containing PROTOCOL.
May be used multiple times to offer several protocols.
--no-tickets Disable session ticket support.
--no-sni Disable server name indication support.
--insecure Disable certificate verification.
--verbose Emit log output.
--max-frag-size M Limit outgoing messages to M bytes.
--version, -v Show tool version.
--help, -h Show this screen.
Some sample runs:
$ cargo run --bin tlsclient-mio -- --http mozilla-modern.badssl.com
HTTP/1.1 200 OK
Server: nginx/1.6.2 (Ubuntu)
Date: Wed, 01 Jun 2016 18:44:00 GMT
Content-Type: text/html
Content-Length: 644
(...)
or
$ cargo run --bin tlsclient-mio -- --http expired.badssl.com
TLS error: InvalidCertificate(Expired)
Connection closed
The MIO server example program is named tlsserver-mio
. The interface looks like:
Runs a TLS server on :PORT. The default PORT is 443.
`echo' mode means the server echoes received data on each connection.
`http' mode means the server blindly sends a HTTP response on each
connection.
`forward' means the server forwards plaintext to a connection made to
localhost:fport.
`--certs' names the full certificate chain, `--key' provides the
RSA private key.
Usage:
tlsserver-mio --certs CERTFILE --key KEYFILE [--suite SUITE ...] [--proto PROTO ...] [--protover PROTOVER ...] [options] echo
tlsserver-mio --certs CERTFILE --key KEYFILE [--suite SUITE ...] [--proto PROTO ...] [--protover PROTOVER ...] [options] http
tlsserver-mio --certs CERTFILE --key KEYFILE [--suite SUITE ...] [--proto PROTO ...] [--protover PROTOVER ...] [options] forward <fport>
tlsserver-mio (--version | -v)
tlsserver-mio (--help | -h)
Options:
-p, --port PORT Listen on PORT [default: 443].
--certs CERTFILE Read server certificates from CERTFILE.
This should contain PEM-format certificates
in the right order (the first certificate should
certify KEYFILE, the last should be a root CA).
--key KEYFILE Read private key from KEYFILE. This should be a RSA
private key or PKCS8-encoded private key, in PEM format.
--ocsp OCSPFILE Read DER-encoded OCSP response from OCSPFILE and staple
to certificate. Optional.
--auth CERTFILE Enable client authentication, and accept certificates
signed by those roots provided in CERTFILE.
--crl CRLFILE ... Perform client certificate revocation checking using the DER-encoded
CRLFILE. May be used multiple times.
--require-auth Send a fatal alert if the client does not complete client
authentication.
--resumption Support session resumption.
--tickets Support tickets.
--protover VERSION Disable default TLS version list, and use
VERSION instead. May be used multiple times.
--suite SUITE Disable default cipher suite list, and use
SUITE instead. May be used multiple times.
--proto PROTOCOL Negotiate PROTOCOL using ALPN.
May be used multiple times.
--verbose Emit log output.
--version, -v Show tool version.
--help, -h Show this screen.
Here's a sample run; we start a TLS echo server, then connect to it with
openssl
and tlsclient-mio
:
$ cargo run --bin tlsserver-mio -- --certs test-ca/rsa/end.fullchain --key test-ca/rsa/end.rsa -p 8443 echo &
$ echo hello world | openssl s_client -ign_eof -quiet -connect localhost:8443
depth=2 CN = ponytown RSA CA
verify error:num=19:self signed certificate in certificate chain
hello world
^C
$ echo hello world | cargo run --bin tlsclient-mio -- --cafile test-ca/rsa/ca.cert -p 8443 localhost
hello world
^C
Rustls is distributed under the following three licenses:
- Apache License version 2.0.
- MIT license.
- ISC license.
These are included as LICENSE-APACHE, LICENSE-MIT and LICENSE-ISC respectively. You may use this software under the terms of any of these licenses, at your option.
- Joe Birr-Pixton (@ctz, Project Founder - full-time funded by Prossimo)
- Dirkjan Ochtman (@djc, Co-maintainer)
- Daniel McCarney (@cpu, Co-maintainer - full-time funded by Prossimo)
- Josh Aas (@bdaehlie, Project Management)
This project adopts the Rust Code of Conduct. Please email [email protected] to report any instance of misconduct, or if you have any comments or questions on the Code of Conduct.