In an Apple paper about Object Oriented Programming, it depicts objects sending messages to each other. So
Appliance can send a message to
Valve, saying requesting for water, and the
Valve object can then send a message to the
Appliance, for "giving the water".
(to send a message is actually calling the method of the other object)
So I wonder, won't this cause subtle infinite loop in some way that even the programmer did not anticipate? For example, one is if we program two objects, each one of them pulling each other by gravity, so one is sending to the other object, that there is a "pull" force, and the other object's method got called, and in turn sends a message to the first object, and they will go into an infinite loop. So if the computer program only has 1 process or 1 thread, it will simply go into an infinite loop, and never run anything else in that program (even if the two object finally collide together, they still continue to pull each other). How does this programming paradigm work in reality to prevent this?
Update: this is the Apple paper: http://developer.apple.com/library/mac/documentation/cocoa/conceptual/OOP_ObjC/OOP_ObjC.pdf
Update: for all the people who just look at this obvious example and say "You are wrong! Programs should be finite, blah blah blah", well, what I am aiming at is, what if there are hundreds or thousands of objects, and they send each other messages, and when getting a message, they might in turn send other messages to other objects. Then, how can you be sure there can't be infinite loop and the program cannot go any further.
On the other hand, for people who said, "a program must be finite", well, what about a simple GUI program? It has the event loop, and it is an infinite loop, running UNTIL the user explicitly asks the program to stop. And what about a program that keep on looking for prime numbers? It can keep looking (with BigNum such as in Ruby so that there can be any number of digits for an integer), so the program is just written to keep on running, and write the next larger prime number into the hard disk (or write to hard disk once every million time it find greater prime number -- so it find 1 million prime number and write that 1 millionth to the hard drive and then keep on looking for the next million prime numbers and write the 2 millionth number to hard drive (write only 1 number, not 1 million of them). Well, for a computer with 12GB or RAM and 2TB of hard drive, maybe you can say it can take 20 years for the program to exceed the capability of the computer, when hard disk is full or when the 12GB of RAM cannot fit all the variables (it might be billion of years that an integer cannot fit in 1GB of RAM), but as far as the program is concerned, it just keep running, unless the memory manager cannot allocate another BigNum, or the hard drive is full, that the exception is raised and the program is forced to stop, but the program is written to run indefinitely. So not all programs HAS TO BE written to be finite.