Disclaimer: It is hard to tell for sure since I never read an explicit Oracle statement about this, but I pretty much think this is the reason:
When you look at Java byte code, you could ask the same question about other instructions. Why would the verifier stop you when pushing two
ints on the stack and treating them as a single
long right after? (Try it, it will stop you.) You could argue that by allowing this, you could express the same logic with a smaller instruction set. (To go further with this argument, a byte cannot express too many instructions, the Java byte code set should therefore cut down wherever possible.)
Of course, in theory you would not need a byte code instruction for pushing
longs to the stack and you are right about the fact that you would not need two instructions for
INVOKESTATIC in order to express method invocations. A method is uniquely identified by its method descriptor (name and raw argument types) and you could not define both a static and a non-static method with an identical description within the same class. And in order to validate the byte code, the Java compiler must check whether the target method is
Remark: This contradicts the answer of v6ak. However, a methods descriptor of a non-static method is not altered to include a reference to
this.getClass(). The Java runtime could therefore always infer the appropriate method binding from the method descriptor for a hypothetical
INVOKESMART instruction. See JVMS §4.3.3.
So much for the theory. However, the intentions that are expressed by both invocation types are quite different. And remember that Java byte code is supposed to be used by other tools than javac to create JVM applications, as well. With byte code, these tools produce something that is more similar to machine code than your Java source code. But it is still rather high level. For example, byte code still is verified and the byte code is automatically optimized when compiled to machine code. However, the byte code is an abstraction that intentionally contains some redundancy in order to make the meaning of the byte code more explicit. And just like the Java language uses different names for similar things to make the language more readable, the byte code instruction set contains some redundancy as well. And as another benefit, verification and byte code interpretation/compilation can speed up since a method's invocation type does not always need to be inferred but is explicitly stated in the byte code. This is desirable because verification, interpretation and compilation are done at runtime.
As a final anecdote, I should mention that a class's static initializer
<clinit> was not flagged
static before Java 5. In this context, the static invocation could also be inferred by the method's name but this would cause even more run time overhead.