So, my question is, have there been
any statistical studies done on the
effects of immutability in real-world
I'd argue that your professor is just being obtuse -- not necessarily intentionally or even a bad thing. Its just that the question is too vague. Two real problems with the question:
- "Statistical studies on the effect of [x]" doesn't really mean anything if you don't specify what kind of measurements you're looking for.
- "Real-world code" doesn't really mean anything unless you state a specific domain. Real world code includes scientific computing, game development, blog engines, automated proof generators, stored procedures, operating system kernals, etc
For what its worth, the ability for the compiler to optimize immutable objects is well-documented. Off the top of my head:
- The Haskell compiler performs deforestation (also called short-cut fusion), where Haskell will transform the expression
map f . map g to
map f . g. Since Haskell functions are immutable, these expressions are guaranteed to produce equivalent output, but the second function runs twice as fast since we don't need to create an intermediate list.
- Common subexpression elimination where we could convert
x = foo(12); y = foo(12) to
temp = foo(12); x = temp; y = temp; is only possible if the compiler can guarantee
foo is a pure function. To my knowledge, the D compiler can perform substitutions like this using the
immutable keywords. If I remember correctly, some C and C++ compilers will aggressively optimize calls to these functions marked "pure" (or whatever the equivalent keyword is).
- So long as we don't have mutable state, a sufficiently smart compiler can execute linear blocks of code multiple threads with a guarantee that we won't corrupt the state of variables in another thread.
Regarding concurrency, the pitfalls of concurrency using mutable state are well-documented and don't need to be restated.
Sure, this is all anecdotal evidence, but that's pretty much the best you'll get. The immutable vs mutable debate is largely a pissing match, and you are not going to find a paper making a sweeping generalization like "functional programming is superior to imperative programming".
At most, you'll probably find that you can summarize the benefits of immutable vs mutable in a set of best practices rather than as codified studies and statistics. For example, mutable state is the enemy of multithreaded programming; on the other hand, mutable queues and arrays are often easier to write and more efficient in practice than their immutable variants.
It takes practice, but eventually you learn to use the right tool for the job, rather than shoehorning your favorite pet paradigm into project.