Difference between revisions of "Recursion"
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A '''''recursive''''' function is a function that calls itself within its definition. This is often a convenient way to define a function, and sometimes the only way. As an example, consider this definition of factorial: | A '''''recursive''''' function is a function that calls itself within its definition. This is often a convenient way to define a function, and sometimes the only way. As an example, consider this definition of factorial: | ||
| − | <code>Function Factorial2(n: Positive Atom)</code> | + | :<code>Function Factorial2(n: Positive Atom)</code> |
| − | <code>Definition: IF n > 1 THEN N*Factorial2(n-1) ELSE 1</code> | + | :<code>Definition: IF n > 1 THEN N*Factorial2(n-1) ELSE 1</code> |
If its parameter, <code>n</code>, is greater than 1, <code>Factorial2</code> calls itself with the actual parameter value <code>n-1</code>. Otherwise, it simply returns 1. Like any normal recursive function, it has a termination condition under which the recursion stops — when <code>n <= 1</code>. | If its parameter, <code>n</code>, is greater than 1, <code>Factorial2</code> calls itself with the actual parameter value <code>n-1</code>. Otherwise, it simply returns 1. Like any normal recursive function, it has a termination condition under which the recursion stops — when <code>n <= 1</code>. | ||
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As another example, consider this recursive function to compute a list of the prime factors of an integer, <code>x</code>, equal to or greater than <code>y</code>: | As another example, consider this recursive function to compute a list of the prime factors of an integer, <code>x</code>, equal to or greater than <code>y</code>: | ||
| − | <code>Function Prime_factors(x, y: Positive Atom)</code> | + | :<code>Function Prime_factors(x, y: Positive Atom)</code> |
| − | <code>Definition:</code> | + | :<code>Definition:</code> |
| − | <code>Var n := Floor(x/y);</code> | + | ::<code>Var n := Floor(x/y);</code> |
| − | <code>IF n<y THEN [x]</code> | + | ::<code>IF n<y THEN [x]</code> |
| − | <code>ELSE IF x = n*y THEN Concat([y], Factors(n, y))</code> | + | ::<code>ELSE IF x = n*y THEN Concat([y], Factors(n, y))</code> |
| − | <code>ELSE Prime_factors(x, y+1)</code> | + | ::<code>ELSE Prime_factors(x, y+1)</code> |
| − | <code>Factors(60, 2) → [2, 2, 3, 5]</code> | + | ::<code>Factors(60, 2) → [2, 2, 3, 5]</code> |
In essence, <code>Prime_factors</code> says to compute <code>n</code> as <code>x</code> divided by <code>y</code>, rounded down. If <code>y</code> is greater than <code>n</code>, then <code>x</code> is the last factor, so return <code>x</code> as a list. If <code>x</code> is an exact factor of <code>y</code>, then concatenate <code>x</code> with any factors of <code>n</code>, equal or greater than <code>n</code>. Otherwise, try <code>y+1</code> as a factor. | In essence, <code>Prime_factors</code> says to compute <code>n</code> as <code>x</code> divided by <code>y</code>, rounded down. If <code>y</code> is greater than <code>n</code>, then <code>x</code> is the last factor, so return <code>x</code> as a list. If <code>x</code> is an exact factor of <code>y</code>, then concatenate <code>x</code> with any factors of <code>n</code>, equal or greater than <code>n</code>. Otherwise, try <code>y+1</code> as a factor. | ||
Revision as of 13:52, 20 December 2015
A recursive function is a function that calls itself within its definition. This is often a convenient way to define a function, and sometimes the only way. As an example, consider this definition of factorial:
Function Factorial2(n: Positive Atom)
Definition: IF n > 1 THEN N*Factorial2(n-1) ELSE 1
If its parameter, n, is greater than 1, Factorial2 calls itself with the actual parameter value n-1. Otherwise, it simply returns 1. Like any normal recursive function, it has a termination condition under which the recursion stops — when n <= 1.
Normally, if you try to use a function in its own definition, it complains about a cyclic dependency loop. To enable recursion, you must display and set the Recursive attribute:
- Select Attributes from the Object menu.
- Select Functions from the Class menu.
- Scroll down the list of attributes and click Recursive twice, so that it shows √, meaning that the recursive attribute is displayed for each function in its Object window and the Attribute panel.
- Check OK to close Attributes dialog.
For each function for which you wish to enable recursion:
- Open the Object Window for the function by double-clicking its node (or selecting the node and clicking the Object button).
- Type
1into its Recursive field.
As another example, consider this recursive function to compute a list of the prime factors of an integer, x, equal to or greater than y:
Function Prime_factors(x, y: Positive Atom)
Definition:
Var n := Floor(x/y);
IF n<y THEN [x]
ELSE IF x = n*y THEN Concat([y], Factors(n, y))
ELSE Prime_factors(x, y+1)
Factors(60, 2) → [2, 2, 3, 5]
In essence, Prime_factors says to compute n as x divided by y, rounded down. If y is greater than n, then x is the last factor, so return x as a list. If x is an exact factor of y, then concatenate x with any factors of n, equal or greater than n. Otherwise, try y+1 as a factor.
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