Assembly Language for Beginners

(Jeff_L) #1

3.4. FIBONACCI NUMBERS


Let’s investigate the stack more closely. The author has again added his comments:


0029FC14 00E0103A RETURN to fib2.00E0103A from fib2.00E01000
0029FC18 00000008 1st argument: a
0029FC1C 0000000D 2nd argument: b
0029FC20 00000014 3rd argument: limit
0029FC24 0000000D "next" variable
0029FC28 /0029FC40 saved EBP register
0029FC2C |00E0103A RETURN to fib2.00E0103A from fib2.00E01000
0029FC30 |00000005 1st argument: a
0029FC34 |00000008 2nd argument: b
0029FC38 |00000014 3rd argument: limit
0029FC3C |00000008 "next" variable
0029FC40 ]0029FC58 saved EBP register
0029FC44 |00E0103A RETURN to fib2.00E0103A from fib2.00E01000
0029FC48 |00000003 1st argument: a
0029FC4C |00000005 2nd argument: b
0029FC50 |00000014 3rd argument: limit
0029FC54 |00000005 "next" variable
0029FC58 ]0029FC70 saved EBP register
0029FC5C |00E0103A RETURN to fib2.00E0103A from fib2.00E01000
0029FC60 |00000002 1st argument: a
0029FC64 |00000003 2nd argument: b
0029FC68 |00000014 3rd argument: limit
0029FC6C |00000003 "next" variable
0029FC70 ]0029FC88 saved EBP register
0029FC74 |00E0103A RETURN to fib2.00E0103A from fib2.00E01000
0029FC78 |00000001 1st argument: a \
0029FC7C |00000002 2nd argument: b | prepared in f1() for next f1() call
0029FC80 |00000014 3rd argument: limit /
0029FC84 |00000002 "next" variable
0029FC88 ]0029FC9C saved EBP register
0029FC8C |00E0106C RETURN to fib2.00E0106C from fib2.00E01000
0029FC90 |00000001 1st argument: a \
0029FC94 |00000001 2nd argument: b | prepared in main() for f1()
0029FC98 |00000014 3rd argument: limit /
0029FC9C ]0029FCE0 saved EBP register
0029FCA0 |00E011E0 RETURN to fib2.00E011E0 from fib2.00E01050
0029FCA4 |00000001 main() 1st argument: argc \
0029FCA8 |000812C8 main() 2nd argument: argv | prepared in CRT for main()
0029FCAC |00082940 main() 3rd argument: envp /


Here we see it: thenextvalue is calculated in each function incarnation, then passed as argumentbto
the next incarnation.


3.4.3 Summary


Recursive functions are æsthetically nice, but technically may degrade performance because of their
heavy stack usage. Everyone who writes performance critical code probably should avoid recursion.


For example, the author of this book once wrote a function to seek a particular node in a binary tree. As a
recursive function it looked quite stylish but since additional time was spent at each function call for the
prologue/epilogue, it was working a couple of times slower than an iterative (recursion-free) implementa-
tion.


By the way, that is the reason that some functionalPL^6 compilers (where recursion is used heavily) use
tail call. We talk about tail call when a function has only one single call to itself located at the end of it,
like:


Listing 3.6: Scheme, example is copypasted from Wikipedia

;; factorial : number -> number
;; to calculate the product of all positive
;; integers less than or equal to n.
(define (factorial n)
(if (= n 1)
1


(^6) LISP, Python, Lua, etc.

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