NaïveProxy uses Chrome's network stack to camouflage traffic with stronger censorship resistence and less detectablility than custom-made network stacks (Shadowsocks and variants, V2Ray suite, handmade Golang stacks). Reusing Chrome's stack also ensures NaïveProxy has the best practices in performance and security.
The following traffic attacks are mitigated in NaïveProxy:
- Website fingerprinting / traffic classification: mitigated by traffic multiplexing in HTTP/2.
- TLS parameter fingerprinting: defeated by reusing Chrome's network stack.
- Active probing: defeated by application fronting, i.e. hiding proxy servers behind a commonly used frontend with application-layer routing.
- Length-based traffic analysis: mitigated by length padding.
[Browser → Naïve (client)] ⟶ Censor ⟶ [Frontend → Naïve (server)] ⟶ Internet
NaïveProxy uses Chrome's network stack. The traffic behavior intercepted by the censor is identical to regular HTTP/2 traffic between Chrome and standard Frontend (e.g. Caddy, HAProxy).
Frontend also reroutes unauthenticated users and active probes to a backend HTTP server, making it impossible to detect the existence of a proxy, like this: Probe ⟶ Frontend ⟶ index.html
See latest release.
Note: On Linux libnss3 must be installed before using the prebuilt binary.
On the server, download Caddy (from https://caddyserver.com/download with plugin: http.forwardproxy):
curl -OJ 'https://caddyserver.com/download/linux/amd64?plugins=http.forwardproxy&license=personal'
tar xf ./caddy_*.tar.gz
sudo setcap cap_net_bind_service=+ep caddy
Run ./caddy with the following Caddyfile (replace the example values accordingly):
domain.example
root /var/www/html
tls myemail@example.com
forwardproxy {
basicauth user pass
hide_ip
hide_via
probe_resistance secret.localhost
upstream http://127.0.0.1:8080
}
and ./naive with the following config.json:
{
"listen": "http://127.0.0.1:8080",
"padding": true
}Locally run ./naive with config.json:
{
"listen": "socks://127.0.0.1:1080",
"proxy": "https://user:pass@domain.example",
"padding": true
}to get a SOCKS5 proxy at local port 1080.
See USAGE.txt on how to configure config.json. See also Parameter Tuning to improve client-side performance.
It's possible to run Caddy without Naive server, but you need to remove padding from config.json and upstream from Caddyfile.
If you don't like to download binaries, you can build NaïveProxy.
Prerequisites:
- Ubuntu (apt-get install): git, python2, ninja-build (>= 1.7), pkg-config, libnss3-dev, curl, unzip, ccache (optional)
- MacOS (brew install): git, ninja, ccache (optional)
- Windows (choco install): git, python2, ninja, visualstudio2017community. See Chromium's page for detail on Visual Studio setup requirements.
Build (output to ./out/Release/naive):
git clone --depth 1 https://github.com/klzgrad/naiveproxy.git
cd naiveproxy/src
./get-clang.sh
./build.sh
The scripts download tools from Google servers with curl. You may need to set a proxy environment variable for curl, e.g. export ALL_PROXY=socks5h://127.0.0.1:1080.
Their TLS stacks have distinct features that can be easily detected. TLS parameters are generally very informative and distinguishable. Most client-originated traffic comes from browsers, putting the custom network stacks in the minority.
Previously, Tor tried to mimic Firefox's TLS signature and still got identified and blocked by firewalls, because that signature was of an outdated version of Firefox and the firewall determined the rate of collateral damage would be acceptable. If we use the signature of the most commonly used browser the collateral damage of blocking it would be unacceptable.
Any languages can be used for high performance architectures, but not all architectures have high performance.
Go, Node, etc. make it easy to implement a 1:1 connection proxy model, i.e. creating one upstream connection for every user connection. Then under this model the goal of performance is to reduce overhead in setting up each upstream connection. Toward that goal people start to reinvent their own 0-RTT cryptographic protocols (badly) as TLS goes out of the window because it either spends take several round trips in handshakes or makes it a pain to set up 0-RTT properly. Then people also start to look at low level optimization such as TCP Fast Open.
Meanwhile, Google has removed the code for TCP Fast Open in Chromium all together (they authored the RFC of TCP Fast Open in 2014). The literal reason given for this reversal was
We never enabled it by default, and have no plans to, so we should just remove it. QUIC also makes it less useful, and TLS 1.2 0-RTT session restore means it potentially mutates state.
And the real reason Google never enabled TCP Fast Open by default is that it was dragged down by middleboxes and never really worked. In Linux kernel there is a sysctl called tcp_fastopen_blackhole_timeout_sec, and whenever a SYN packet is dropped, TCP Fast Open is blackholed for this much time, starting at one hour and increasing exponentially, rendering it practically useless. Today TCP Fast Open accounts for 0.1% of the Internet traffic, so using it actually makes you highly detectable!
It was obvious to Google then and is obvious to us now that the road to zero latency at the cost of compromising security and interoperability is a dead end under the 1:1 connection model, which is why Google pursued connection persistence and 1:N connection multiplexing in HTTP/2 and more radical overhaul of HTTP/TLS/TCP in QUIC. In a 1:N connection model, the cost of setting up the first connection is amortized, and the following connections cost nothing to set up without any security or stability compromises, and the race to zero connection latency becomes irrelevant.
Complex, battle-tested logic for connection management was implemented in Chromium. The same thing is not so easy to do again from scratch with the aforementioned languages.
Because the first rule of cryptography is: Don't roll your own cryptos.
If you do roll your own cryptos, see what happened with Shadowsocks. (Spoiler: it encrypts, but doesn't authenticate, leading to active probing exploits, and more exploits after duct-tape fixes.)
You may have wondered why not use Chrome directly if NaïveProxy reuses Chrome's network stack. The answer is yes, you can. You will get 80% of what NaïveProxy does (TLS, connection multiplexing, application fronting) without NaïveProxy, which is also what makes NaïveProxy indistinguishable from normal traffic. Simply point your browser to Caddy as an HTTP/2 or HTTP/3 forward proxy directly.
But this setup is prone to basic traffic analysis due to lack of obfuscation and predictable packet sizes in TLS handshakes. The bane of "TLS-in-TLS" tunnels is that this combination is just so different from any normal protocols (nobody does 3-way handshakes twice in a row) and the record sizes of TLS handshakes are so predictable that no machine learning is needed to detect it.
The browser will introduce an extra 1RTT delay during proxied connection setup because of interpretation of HTTP RFCs. The browser will wait for a 200 response after a CONNECT request, incuring 1RTT which is not necessary. NaïveProxy does HTTP Fast CONNECT similar to TCP Fast Open, i.e. send subsequent data immediately after CONNECT. Also, you may have to type in the password for the proxy everytime you open the browser. NaïveProxy sends the password automatically.
Thus, traffic obfuscation, HTTP Fast CONNECT, and auto-authentication are the crucial last 20% provided by NaïveProxy. These can't be really achieved inside Chrome as extensions/apps because they don't have access to sockets. NaïveProxy extracts Chromium's network stack without all the other baggage to build a small binary (4% of a full Chrome build).
But if you don't need the best performance, and unobfuscated TLS-in-TLS somehow still works for you, you can just keep using Caddy proxy with your browser.