Where does Android store the root certificates on the device?
It moves around. With the advent of Ice Cream Sandwich (ICS), there are three stores used. The three stores are
/data/misc/keychain (supplied by Android),
/data/misc/keychain/cacerts-added (CAs added by users), and
/data/misc/keychain/cacerts-removed (CAs removed by users or updates).
Prior to ICS, they used a BouncyCastle store located at
/system/etc/security/cacerts.bks. It was a static store, and it could not be modified. If it needed to be changed, then you needed to update the firmware or image.
For an explanation of the stores, see ICS Trust Store Implementation. Its Nikolay Elenkov's blog, and he does a great job of discussing the system, and not just where the stores are located.
How can I point OpenSSL to them?
You can't really do it because what OpenSSL expects and what Android presents are two different presentation/storage formats. OpenSSL expects a collection of trust anchors in PEM format concatenated together. But an Android trust store is not in that format.
Often what happens is you download
cacert.pem. Then, you load them with a call to
SSL_CTX_load_verify_locations by specifying
cacert.pem as the
Even though you download
cacert.pem from a trusted source, like Mozilla or cURL, you should still go through it and ensure you are satisfied with the collection of trust anchors. There are 155 potential trust anchors in the pack:
$ cat cacert.pem | grep BEGIN | wc -l
But like I said in the comment, its implicitly using the Browser Security Model, and its not a particularly good way to do things in many instances.
when attempting to establish an HTTPS connection to a well-known host (such as https://google.com), I always receive the error "The SSL certificate is invalid."
To answer this, just use Google Internet Authority or GeoTrust Global CA with
SSL_CTX_load_verify_locations. Its probably best to use Google Internet Authority because it limits the net cast.
Google Internet Authority:
GeoTrust Global CA:
In the ideal world, you run a private PKI, and you only trust your PKI's root to certify sites and services. You don't confer trust a public CA to certify anything because they don't make any warranties to the relying party. Essentially, a public CA tells you their warez are no good, even for the purpose they are selling them to sites.
In the next best world, you only use the public CA that certified the site. That means you use Google Internet Authority or GeoTrust Global CA to certify Google properties; and not, say Diginotar.
There's other not-so-readily-apparent problems. The Google Internet Authority is an unconstrained subordinate CA certified by GeoTrust. Google is allowed to issue certificates for any site, and not just Google properties. Usually, this is caught by the RA, which is effectively an independent auditor that validates the signing request to the CA before issuance. But in this model, the organization making the request (Google) is the same organization that validates the request (Google), and the same organization that issues the certificate (Google). Browsers, CAs and PKI is the only instance I am aware the independent auditor was completely removed as a check-and-balance because it was too inconvenient.
If you think a subordinate would not do such a thing, then you'd be sadly mistaken. CNICC was just removed from a few browser trust stores because one of its unconstrained subordinates was caught issuing certificates for sites and services it was not authorized.
Where the browser security model really breaks down is ability for the wrong CA to certify a site. And it includes successful phishing attempts on the user. That is, a browser will happily allow a connection to be intercepted because a user was phished.
If you think the upcoming Public Key Pinning with Overrides will help, then you'd be sadly mistaken. Though they barely mention the overrides, an attacker can break a known good pinset. And worse, the reporting feature is disabled for a broken pinset with a MUST NOT Report, so the browser is complicit in the cover up.
There's a lot more reading available on the subject. For starters, try Peter Gutmann's Engineering Security and Audun Jøsang's Trust Extortion on the Internet.