When calling A(x) x is guaranteed to be kept alive to the end of A - because B uses the same parameter.
This statement is false. Suppose method A always throws an exception. The jitter could know that B will never be reached, and therefore x can be released immediately. Suppose method A goes into an unconditional infinite loop after its last reference to x; again, the jitter could know that via static analysis, determine that x will never be referenced again, and schedule it to be cleaned up. I do not know if the jitter actually performs these optimization; they seem dodgy, but they are legal.
Can this optimization (namely, doing early cleanup of a reference that is not used anywhere) actually be done by the JITter?
Yes, and in practice, it is done. That is not an observable side effect.
This is justified by section 3.9 of the specification, which I quote for your convenience:
If the object, or any part of it, cannot be accessed by any possible continuation of execution, other than the running of destructors, the object is considered no longer in use, and it becomes eligible for destruction. The C# compiler and the garbage collector may choose to analyze code to determine which references to an object may be used in the future. For instance, if a local variable that is in scope is the only existing reference to an object, but that local variable is never referred to in any possible continuation of execution from the current execution point in the procedure, the garbage collector may (but is not required to) treat the object as no longer in use.
Can optimizations done by the C# compiler or the JITter have visible side effects?
Your question is answered in section 3.10 of the specification, which I quote here for your convenience:
Execution of a C# program proceeds
such that the side effects of each
executing thread are preserved at
critical execution points.
effect is defined as a read or write
of a volatile field, a write to a
non-volatile variable, a write to an
external resource, and the throwing of
The critical execution
points at which the order of these
side effects must be preserved are
references to volatile fields, lock statements,
and thread creation and termination.
The execution environment is free to
change the order of execution of a C#
program, subject to the following
Data dependence is
preserved within a thread of
execution. That is, the value of each
variable is computed as if all
statements in the thread were executed
in original program order.
Initialization ordering rules are
ordering of side effects is preserved
with respect to volatile reads and
execution environment need not
evaluate part of an expression if it
can deduce that that expression’s
value is not used and that no needed
side effects are produced (including
any caused by calling a method or
accessing a volatile field).
program execution is interrupted by an
asynchronous event (such as an
exception thrown by another thread),
it is not guaranteed that the
observable side effects are visible in
the original program order.
The second-to-last paragraph is I believe the one you are most concerned about; that is, what optimizations is the runtime allowed to perform with respect to affecting observable side effects? The runtime is permitted to perform any optimization which does not affect an observable side effect.
Note that in particular data dependence is only preserved within a thread of execution. Data dependence is not guaranteed to be preserved when observed from another thread of execution.
If that doesn't answer your question, ask a more specific question. In particular, a careful and precise definition of "observable side effect" will be necessary to answer your question in more detail, if you do not consider the definition given above to match your definition of "observable side effect".