To protect our apps from man-in-the-middle attacks one of the first things that usually springs to mind is certificate pinning. However, the issues of certificate pinning are numerous. Firstly deciding on a reliable set of keys to pin against is tough. Once you made that decision if your expectations don't match reality your users suffer from not being able to access your app or website. Smashing Magazine learnt about this the hard way in late 2016 when they blocked users access for up to a year because of a mismatch between the pins and the certificates. On mobile fixing an invalid pin means pushing out a new version of an app which can still take a while to reach every user.
So with certificate pinning falling out of favour, what should you do? The new kid in town is certificate transparency.
Certificate Transparency helps eliminate these flaws by providing an open framework for monitoring and auditing SSL certificates in nearly real time. Specifically, Certificate Transparency makes it possible to detect SSL certificates that have been mistakenly issued by a certificate authority or maliciously acquired from an otherwise unimpeachable certificate authority. It also makes it possible to identify certificate authorities that have gone rogue and are maliciously issuing certificates. https://www.certificate-transparency.org
Certificate transparency works by having a network of publicly accessible log servers that provide cryptographic evidence when a certificate authority issues new certificates for any domain. These log servers can then be monitored to look out for suspicious certificates as well as audited to prove the logs are working as expected.
These log servers help achieve the three main goals:
- Make it hard to issue certificates without the domain owners knowledge
- Provide auditing and monitoring to spot mis-issued certificates
- Protect users from mis-issued certificates
When you submit a certificate to a log server, the server responds with a signed certificate timestamp (SCT), which is a promise that the certificate will be added to the logs within 24 hours (the maximum merge delay). User agents, such as web browsers and mobile apps, use this SCT to verify the validity of a domain.
For a more detailed overview of certificate transparency, please watch the excellent video The Very Best of Certificate Transparency (2011-) from Networking @Scale 2017.
More details about how the verification works in the library can be found at Android Security: Certificate Transparency
We are open about the security of our library and provide a threat model in the source code, created using OWASP Threat Dragon. If you feel there is something we have missed please reach out so we can keep this up to date.
For Android modules include the android dependency in your build.gradle file which ensures the necessary ProGuard rules are present:
implementation 'com.babylon.certificatetransparency:certificatetransparency-android:<latest-version>'For Java library modules include the dependency as follows:
implementation 'com.babylon.certificatetransparency:certificatetransparency:<latest-version>'The library allows you to create a network interceptor for use with OkHttp where you specify which hosts to perform certificate transparency checks on. Wildcards are accepted but note that *.babylonhealth.com will match any sub-domain but not "babylonhealth.com" with no subdomain.
val interceptor = certificateTransparencyInterceptor {
// Enable for the provided hosts
+"*.babylonhealth.com"
// Exclude specific hosts
-"legacy.babylonhealth.com"
}
val client = OkHttpClient.Builder().apply {
addNetworkInterceptor(interceptor)
}.build()In Java, you can create the network interceptor through CTInterceptorBuilder.
With Retrofit built on top of OkHttp, configuring it for certificate transparency is as simple as setting up an OkHttpClient as shown above and supplying that to your Retrofit.Builder.
val retrofit = Retrofit.Builder()
.baseUrl("https://babylonhealth.com")
.addConverterFactory(GsonConverterFactory.create())
.client(okHttpClient)
.build()Firstly if you are still using HttpURLConnection consider upgrading to OkHttp. The version built into Android, naturally, is a fixed version so you won't get any security updates or bug fixes.
To use with HttpURLConnection you wrap the original hostname verifier before calling connect() on the connection:
val connection = URL("https://www.babylonhealth.com").openConnection()
if (connection is HttpsURLConnection) {
connection.hostnameVerifier = certificateTransparencyHostnameVerifier(connection.hostnameVerifier) {
// Enable for the provided hosts
+"*.babylonhealth.com"
// Exclude specific hosts
-"legacy.babylonhealth.com"
}
}In Java, you can create the hostname verifier through CTHostnameVerifierBuilder.
Overriding the HostnameVerifier can be achieved by overriding
createConnection when creating the RequestQueue:
val requestQueue = Volley.newRequestQueue(applicationContext, object : HurlStack() {
override fun createConnection(url: URL): HttpURLConnection {
val connection = super.createConnection(url)
if (connection is HttpsURLConnection) {
connection.hostnameVerifier = certificateTransparencyHostnameVerifier(connection.hostnameVerifier) {
// Enable for the provided hosts
+"*.babylonhealth.com"
// Exclude specific hosts
-"legacy.babylonhealth.com"
}
}
return connection
}
})Currently, there is no support in the library for Apache HttpClient. However, adding the functionality would be relatively easy to add if there is enough demand.
With WebViews on Android now being provided by Chrome, hopefully in the long-term certificate transparency support will come for free. There is a proposal to add an Expect-CT header to instruct user agents to expect valid SCTs which would help enforce this.
Assuming that never happens, WebViews are tricky, not least because there is no perfect way to implement certificate transparency in them. The best you can do is override shouldInterceptRequest and implement the network calls yourself using one of the above methods. However, you can only intercept GET requests so if your WebViews use POST requests then you are out of luck.
The network interceptor allows you to configure the following properties:
Trust Manager X509TrustManager
used to clean the certificate chain
Default: Platform default X509TrustManager
created through TrustManagerFactory
Log List Data Source A DataSource
providing a list of LogServer
Default: In memory cached log list loaded from https://www.gstatic.com/ct/log_list/log_list.json
Policy CTPolicy
which will verify correct number of SCTs are present
Default: Policy which follows rules of Chromium CT Policy
Fail On Error Determine if a failure to pass certificate
transparency results in the connection being closed. A value of true
ensures the connection is closed on errors
Default: true
Logger CTLogger
which will be called with all results.
On Android you can use the provided BasicAndroidCTLogger
which logs with the tag CertificateTransparency by setting
logger = BasicAndroidCRLogger(BuildConfig.DEBUG) using your apps
BuildConfig.
Default: none
Hosts Verify certificate transparency for hosts that match a
pattern which is a lower-case host name or wildcard pattern such as
*.example.com.
In addition to all of the properties above the hostname verifier ensures you provide a delegate hostname verifier which is used to first verify the hostname before the certificate transparency checks occur.
Please read CONTRIBUTING.md for details on our code of conduct, and the process for submitting pull requests to us.
We use SemVer for versioning. For the versions available, see the tags on this repository.
This project is licensed under the Apache License, Version 2.0 - see the LICENSE.md file for details