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According to this article

Due to the differences in information between Java code and bytecode (bytecode does not contain the types of local variables), the verifier does not need to check subtypes for assignments to local variables, or to parameters.

My question: Why does the bytecode not contain type information for local variables, whilst it does indeed contain type information for the parameters and return value?

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I suspect that type values were checked at compile-time resulting in code that no longer needs to have type value information, just binary data. The method parameters & return values, however are called at run-time and require information for type checking – Apr 14 '13 at 17:01
thanks, that makes sense! – JB2 Apr 14 '13 at 17:53
Because that's the way it is. The JDK verifier uses dataflow analysis to find out what type "reaches" each data use. Parameters and instance/static vars need to have types declared to feed into dataflow. The type of calculation results, OTOH, can be determined by rules. Besides which, local vars often disappear into stack values when compiled. – Hot Licks Apr 14 '13 at 18:35

3 Answers 3

up vote 5 down vote accepted

First off, there are several different notions of type. There are the compile time types, which include generics. However, generics don't exist after compile time.

There is the verification inferred static type of a variable, which can be int, float, long, double, returnaddress, or an object reference. Object references are additionally typed with an upper bound, so that all references are subtypes of java/lang/String for instance. Fields can additionally have one of the short types: byte, short, char, or boolean. These are treated identically to ints for execution purposes but have different storage.

Finally, there is the runtime type, which is the same as the verified static type, but in the case of object references, represents the actual type of the instance being referenced. Note that due to verifier laziness, there are some cases where the runtime type may not actually be a subtype of the verified type. For instance, a variable of declared type Comparable can actually hold any object in Hotspot because the VM doesn't check interfaces at verification time.

Compile time information is not preserved except through optional attributes for reflection and debugging. This is because there's no reason to keep it.

Local variables have no explicit type information (except for the new StackMapTable attribute, but that's a technicality). Instead, when the class is loaded, the bytecode verifier infers a type for each value by running a static dataflow analysis. The purpose of this is not to catch bugs like compile time type checking might, because it is assumed that the bytecode already went through such checking at compile time.

Instead, the purpose of verification is to ensure that the instructions are not dangerous to the VM itself. For example, it needs to make sure that you aren't taking an integer and interperting it as an object reference, because that could lead to arbitrary memory access and hacking the VM.

So while bytecode values don't have explicit type information, they do have an implicit type which is the result of static type inference. The details of this vary based on the internal implementation details of each VM, though they are supposed to follow the JVM standard. But you'll only have to worry about that in handwritten bytecode.

Fields have an explicit type since the VM needs to know which type of data is being stored in it. Method parameters and return types are encoded in what is known as a method descriptor, also used in type checking. They're impossible to infer automatically because these values can come from or go anywhere, while type checking is done on a per class basis.

P.S. I left out a few minor details when talking about the verification types. Object types additionally track whether they have been initialized or not, and which instruction created them if uninitialized. Address types track the target of the jsr that created them.

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It may be worth noting that the returnAddress type is only used in concert with the jsr and jsr_w opcodes, which were banned in Java 6. Values manipulated by modern bytecode will never include a returnAddress. – Tom Anderson Apr 14 '13 at 18:56
@Tom They can't be used in a classfile with major version above 49. But you can still run classfiles with lower version numbers on modern VMs. You can set the version as low as 45.0 if you want to, and doing so will enable some interesting undocumented behaviors in Hotspot. If you're only considering Java compiled bytecode, there are quite a few things that javac generated bytecode will never do. But it's still of interest to bytecode hackers. – Antimony Apr 14 '13 at 19:00
True! It's a bit of a shame that we have to keep this cruft around, because it makes explaining how bytecode works a lot more complicated. – Tom Anderson Apr 14 '13 at 19:03
@Tom Even funnier is that if you look at the source code, there is some code that appears to be left over from before Java was even called Java. Even the Hotspot devs aren't sure why it's still there. – Antimony Apr 14 '13 at 19:06
@Antimony very useful, enjoyed reading! A few references would make this answer more perfect! – GaborSch Apr 16 '13 at 14:40

Java bytecode retains type information about fields, method returns and parameters but it does not, as you asked, contain type information for local variables.

The type information in the Java class file renders the task of decompilation of bytecode easier than decompilation of machine code. Decompiling Java bytecode, thus, requires analysis of most local variable types, flattening of stack based instructions and structuring of loops and conditionals. The task of bytecode decompilation, however, is much harder than compilation. You would see often decompilers cannot fully perform their intended function

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That's a pretty old paper. Current class files do include types for local and stack variables. The types aren't stored in the method bytecode, but are stored in a StackMapTable attribute attached to the method.

It is (and always was) possible to reconstruct the types of all local variables and stack elements by dataflow analysis without a StackMapTable, but it is computationally expensive. Code with StackMapTables can be verified much faster. Although i have to confess that i don't see how verifying the StackMapTables can be faster than doing the analysis, but then i know almost nothing about this.

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I admire your expertise. To me, bytecode is like magic ... and no less arcane. – scottb Apr 14 '13 at 19:00
I don't really have expertise - i've read the specifications, but that's about it. – Tom Anderson Apr 14 '13 at 19:04
StackMapTables only supply a type for values at the start of each basic block, so dataflow analysis is required to reconstruct the types of all values. In particular, linear code may not even have a StackMapTable attribute. It's only faster because the dataflow no longer has to do multiple passes in the case of loops or branches. – Antimony Apr 14 '13 at 19:04
Ah, it's only per basic block, is it? In that case, indeed, there will be variables whose types are not covered. – Tom Anderson Apr 14 '13 at 19:12

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