So after a few hours of workaround the limitation of Reflection being currently disabled on the Google App Engine, I was wondering if someone could help me understand why object reflection can be a threat. Is it because I can inspect the private variables of a class or are there any other deeper reasons?
1 - Reflection (as a concept) is indeed orthogonal to safety/security.
There was a big emphasis in the design of java to make it a safe platform, with static typing, security manager, disciplined usage of class loader, and no way to screw pointers/memory. You can read the interview of James Gosling in Masterming of programming, which is interesting about that.
But the more reflective power you have the harder it is to ensure things are safe as they should. Reflection defeat notably static typing and can lead to run-time errors.
But more subtle things can happen as well. For instance class loaders -- which can be considered as reflective hook in the system -- were not designed properly in the early version of Java leading to potential type replacement. The article Dynamic class loading in the JVM, by Gilad Bracha, is insightful on such issues.
Reflection can not be turned off altogether; it's always possible to reflect on its own public fields/methods. Reflection on private structures with
Finally there are other mechanism that put security in jeopardy, notably
2 - Now, the question is whether reflection (in practice) leads to that many risks.
I've read the link pointed by @dbyrne but it's mostly about .net. Also I don't know exactly what is disabled for Google App. Is it the
The problem of access to private data and breaking encapsulation can be argued in practice. Writing secure code is indeed extremely hard, and even without changing the access modifier you can subclass classes in an inappropriate way -- unless they are
Type-safety is also anyway threatened by run-time error because of downcast, so this point can also be argued.
In a shared/hosted environment, the security is relative. At the language level, you can for instance not prevent a module form consuming 100% of CPU or consuming all memory up to a
So my personal answer, would be: reflection is a security risk, but not that big in practice if compared to other potential attack vectors.
GAE is a shared hosting environment, and hosts WAR files from multiple users. It is highly likely that multiple WAR files are hosted in the same JVM, because spawning a process per WAR is just ridiculous. So, the only way to sandbox each war file is via a custom classloader for each WAR file.
Now, assume that reflection was allowed. You could then walk the classloader hierarchy and enumerate classes/methods from WAR files belonging to different users. Obviously, that is a big concern.
First off, if you've not installed a
Secondly, reflection doesn't open up significant holes unless the
Note also that writing a secure security manager and class loader is non-trivial. Best to leave those to others if you're not aspiring to mega-guru-dom (or, more likely, embarrassing levels of failure).
A theory of mine is that Google is trying to hide something. By disabling Reflection Google could hide Variable names, function calls and an even a full API. If Google is hiding something like an API, then they certainty aren't going to tell you about it.
I know for a fact that Reflection plays a very important role in security testing. For instance you can automatically generate Fuzz tests using reflection. AxMan uses TypeLib to identify all of the classes and their method calls that make up a COM object. Using this information AxMan will then instantiate each class and call every method with permutations of long strings and large numbers. Similar testing is conducted by SOAP Fuzzers using the WSDL file for reflection.
An application can use the Java reflection APIs to access and update fields, and execute methods that are forbidden by normal Java access / visibility rules. With a bit of ingenuity, this is sufficient to:
Under certain circumstances, it might even allow the injection of malicious native code.