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I have bumped into this problem several times on the type of input data declarations mathematica understands for functions.

It Seems Mathematica understands the following types declarations: _Integer, _List, _?MatrixQ, _?VectorQ

However: _Real,_Complex declarations for instance cause the function sometimes not to compute. Any idea why?

What's the general rule here?

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It is not clean what is being asked. Please give example code and/or further explanation. –  Mr.Wizard Apr 10 '11 at 3:17
    
@ Mr. Wizard: I've silghtly edited, but I think the question is clear enough and the answers provided below have helped address the problem I had. For instance I did not understand why when inputting an integer number with Real type restriction, it would return false. Anyway the answers below really help me get to the bottom of this issue and usefully expand beyond... –  Phil Apr 10 '11 at 16:36

3 Answers 3

up vote 10 down vote accepted

When you do something like f[x_]:=Sin[x], what you are doing is defining a pattern replacement rule. If you instead say f[x_smth]:=5 (if you try both, do Clear[f] before the second example), you are really saying "wherever you see f[x], check if the head of x is smth and, if it is, replace by 5". Try, for instance,

Clear[f]
f[x_smth]:=5
f[5]
f[smth[5]]

So, to answer your question, the rule is that in f[x_hd]:=1;, hd can be anything and is matched to the head of x.

One can also have more complicated definitions, such as f[x_] := Sin[x] /; x > 12, which will match if x>12 (of course this can be made arbitrarily complicated).

Edit: I forgot about the Real part. You can certainly define Clear[f];f[x_Real]=Sin[x] and it works for eg f[12.]. But you have to keep in mind that, while Head[12.] is Real, Head[12] is Integer, so that your definition won't match.

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Just a quick note since no one else has mentioned it. You can pattern match for multiple Heads - and this is quicker than using the conditional matching of ? or /;.

f[x:(_Integer|_Real)] := True (* function definition goes here *)

For simple functions acting on Real or Integer arguments, it runs in about 75% of the time as the similar definition

g[x_] /; Element[x, Reals] := True (* function definition goes here *)

(which as WReach pointed out, runs in 75% of the time
as g[x_?(Element[#, Reals]&)] := True).

The advantage of the latter form is that it works with Symbolic constants such as Pi - although if you want a purely numeric function, this can be fixed in the former form with the use of N.

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5  
Matching for multiple heads like this is very fragile. It's so easy to forget about one type of expression, as you forgot about Rational here, or something like Sqrt[2] (not only Pi). If you need to check if the expression is numeric only (and not whether it has an imaginary part), x_?NumericQ is best. –  Szabolcs Apr 10 '11 at 0:42
    
@Szabolcs: I originally thought about Rational, because I checked that it doesn't include complex rationals, then I forgot to include it! And yeah... all sorts of numeric functions acting on Reals or Rationals will break the head checking. So you're right, NumericQ combined with an optional check to see if it's in the Reals is probably best / the most robust. –  Simon Apr 10 '11 at 2:43

The most likely problem is the input your using to test the the functions. For instance,

f[x_Complex]:= Conjugate[x]
f[x + I y]
f[3 + I 4]

returns

f[x + I y]
3 - I 4

The reason the second one works while the first one doesn't is revealed when looking at their FullForms

x + I y // FullForm == Plus[x, Times[ Complex[0,1], y]]
3 + I 4 // FullForm == Complex[3,4]

Internally, Mathematica transforms 3 + I 4 into a Complex object because each of the terms is numeric, but x + I y does not get the same treatment as x and y are Symbols. Similarly, if we define

g[x_Real] := -x

and using them

g[ 5 ]  == g[ 5 ]
g[ 5. ] == -5.

The key here is that 5 is an Integer which is not recognized as a subset of Real, but by adding the decimal point it becomes Real.

As acl pointed out, the pattern _Something means match to anything with Head === Something, and both the _Real and _Complex cases are very restrictive in what is given those Heads.

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Why doesn't mma recognize Integer as a subset of Real when it is perfectly valid mathematically? –  r.m. Apr 9 '11 at 16:57
4  
@RM, I think its because of how the pattern matching mechanism works, in that it only looks at the Head of the expression. So, when you type 5 vs. 5. you get an Integer expression vs. a Real expression. Then the pattern matcher only sees that the heads don't match. If you want to match both use _?NumericQ. You run across this problem all the time when matching patterns when an internal alters the expression just enough to no longer match. For me, the most infamous is collecting the imaginary part of a complex expression ... –  rcollyer Apr 9 '11 at 17:08
6  
@R. M. Head matching, and pattern matching in general, have no notion of mathematical validity -- the only concern is the structural form of expressions. Notions of mathematical validity need to be programmed explicitly. For example, if one wanted a function that applied to any real number in the mathematical sense, one would write f[x_ /; x \[Element] Reals] := .... –  WReach Apr 9 '11 at 18:10
4  
@rcollyer: Just for laughs I tried a microbenchmark: Timing[Do[f[10], {10000000}]] for both variants. /; ran in 75% of the time required by ?. I wouldn't read too much into this result. In Mathematica, expressiveness and clarity are generally more important than performance. I would just go ahead and write whichever form was clearest in the context. There is also personal preference at work -- I happen to use '/;' a lot. YMMV. When performance is a big deal, then one is likely to look for a different algorithm or, failing that, using Compile or symbolic C or something. –  WReach Apr 9 '11 at 18:57
3  
@WReach The reason probably is that FullForm of Condition is substantially simpler that FullForm of PatternTest with Function: f[x_ /; x \[Element] Reals] // FullForm and f[x_?(Element[#, Reals] &)] // FullForm. Without Function PatternTest is slightly faster: ClearAll[f]; f[x_?NumericQ] := x; Timing[Do[f[10], {20000000}]] and ClearAll[f]; f[x_ /; NumericQ[x]] := x; Timing[Do[f[10], {20000000}]]. This confirm your insight that we should write whichever form is clearest in the context. –  Alexey Popkov Apr 9 '11 at 23:30

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