# How does rendezvous work?

I am studying for an exam and am having a difficult time understanding Rendezvous. Here's an example I'm looking a

``````While(1) {
select{
when a == TRUE :
accept A() {f1; b=FALSE}
when b == TRUE :
accept B() {f2; a=FALSE}
else {a=true; b=true}
}
}
``````

The following calls arrive in the given order: A(), B(), B(), A(), A(), B()

In which order will the calls be accepted? And can caller of A or B starve?

I'd really appreciate any help. Thanks in advance.

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Even if this were Ada code (it is not. Ada doesn't use curly braces, or a `==` operator, and the language is case-insensitive, so `a` and `A` would be the same thing), the way I'm reading it I don't think the question could be answered without knowing the initial state of your two boolean flags (guards, I'm guessing). Are you sure this isn't something like Concurrent C? – T.E.D. Jan 26 '11 at 15:26

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Going with the logic of your problem rather than the syntax, I think the answer is 'it all depends'.

The task that's running this loop (call it `Server`) is in a busy loop (most times round the loop, it'll end up setting `A := True; B := True;`). This could use up all your CPU and starve the other tasks out.

Assuming that doesn't happen and you have 2 client tasks `A_Caller` and `B_Caller` which have higher priority than `Server` and call their entries relatively infrequently, then you might get

1. `A_Caller` and `B_Caller` both run and call their respective entries.
2. `Server` enters the `select` and finds both guards open and the entries called; it chooses to accept `A` (it could have chosen `B`). The guard `B` is closed.
3. Next time round the loop, guard `A` is open but there is no caller; guard `B` is closed; the `else` part is chosen, so guard `B` is opened.
4. Next time round the loop, `Server` accepts `B`; guard `A` is closed.
5. Next time round the loop, guard `B` is open but there is no caller; the `else` part is chosen, so guard `A` is opened.
6. Next time round the loop, both guards are open but there is no caller, so the `else` part is chosen again and away we spin.

Obviously the exact sequence followed will depend on when the entry calls arrive with respect to `Server`'s loop. Assuming the entry calls in your question happen a second apart, the entries will be accepted in the order called.

I don't think you can get starvation unless one of the callers is running sufficiently frequently that it's called its entry again before `Server` has got back round its loop. It would be hard to get this to happen under a general-purpose OS.

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