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I have several expressions I have generated in Mathematica that I would like to export into the source code of an external C program. "CForm" almost does what I want except that exponentiation is expressed as calls to Power(). My expressions involves only small powers so I would prefer that the expression in C use inlined multiplication rather than a call to Power().

For example CForm[2 hgt^2 k1inv^3 mx0 wid^2 + hgt^2 k1inv^3 wid^3] yields

2*Power(hgt,2)*Power(k1inv,3)*mx0*Power(wid,2) + Power(hgt,2)*Power(k1inv,3)*Power(wid,3)

..whereas what I would like to generate is:

2*hgt*hgt*k1inv*k1inv*k1inv*mx0*wid*wid + hgt*hgt*k1inv*k1inv*k1inv*wid*wid*wid

My initial attempts to pick out the internal Power[..] parts of the expression and remap it to a multiplication using x_Symbol^y_Integer /; y > 1 :> Fold[Times, 1, Table[#1, {#2}]] have been stymied by mathematica immediately converting my carefully generated sub expressions a*a*a right back into Power[a,3] ;-) I know it is only trying to help but I can't figure out how to ask it to stop, in this case...

As I have written this question it has occurred to me that I could capture the output of CForm into a string and then perform string pattern matching and manipulation on that, but is that a good way to go? I think I prefer to work on it as a Mathematica expression as I do my remapping and then output..?

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1 Answer 1

up vote 13 down vote accepted

For the case at hand, you may use something like the following:

Clear[getCFormNoPowers];
getCFormNoPowers[expr_] :=
  Module[{times},      
   Apply[Function[code, Hold[CForm[code]], HoldAll],
     Hold[#] &[expr /. x_Symbol^y_Integer /; y > 1 :> 
         times @@ Table[x, {y}]] /. times -> Times]];

For example,

In[52]:= getCFormNoPowers[2 hgt^2 k1inv^3 mx0 wid^2+hgt^2 k1inv^3 wid^3]

Out[52]= Hold[2*mx0*(hgt*hgt)*(wid*wid)*(k1inv*k1inv*k1inv) + 
hgt*hgt*(k1inv*k1inv*k1inv)* (wid*wid*wid)]

The result is wrapped in Hold, to prevent its evaluation back to Power-s. You can convert it to a string at any time, using something like ToString[HoldForm@@result]. Or you can manipulate is further.

Edit:

as an alternative, you can do this:

Clear[getCFormNoPowers];
getCFormNoPowers[expr_] :=
 Block[{Times},
   SetAttributes[Times, {Flat, OneIdentity}];
   Apply[Function[code, Hold[CForm[code]], HoldAll],
   Hold[#] &[expr /. x_Symbol^y_Integer /; y > 1 :> Times @@ Table[x, {y}]]]];

which will also keep the original order of your terms and will get rid of unnecessary parentheses, so this one seem to correspond precisely to your specs.

Generally, you may want to have a look at the new "symbolic C generation" capabilities of the version 8. Mapping your code to symbolic C expressions may be a more robust approach. In that way, you don't have to worry about evaluation all the time, and you may use the new functionality to generate entire C programs at the end.

Edit 2:

To illustrate how the problem can be solved with the SymbolicC:

Needs["SymbolicC`"];

Clear[getCFormNoPowersSymC];
getCFormNoPowersSymC[expr_] :=
  Block[{Times},
   SetAttributes[Times, {Flat, Orderless}];
   ToCCodeString[
     expr /. x_Symbol^y_Integer /; y > 1 :> Times @@ Table[x, {y}] //.     
       HoldPattern[(op : (Times | Plus))[args__]] :>  COperator[op, {args}]]];

In[53]:= getCFormNoPowersSymC[2 hgt^2 k1inv^3 mx0 wid^2+hgt^2 k1inv^3 wid^3]

Out[53]= 2 * hgt * hgt * k1inv * k1inv * k1inv * mx0 * wid * wid + 
    hgt * hgt * k1inv * k1inv * k1inv * wid * wid * wid

This method IMO has several advantages. Perhaps the two main ones being composability (one can nest such expressions in their symbolic form, building larger blocks of code from smaller ones), and the fact that one does not have to think much about evaluation (I didn't need any tricks with Hold here).

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Thanks for a nice meaty answer, I am still puzzling through many of its subtleties (e.g. why the HoldAll for CForm? Neatly using times but then changing to Times outside the Hold. And the undocumented(?) use of HoldAll as an argument to Apply) –  Daniel Chisholm Mar 25 '11 at 16:08
    
I actually removed the HoldAll, it is unnecessary. See also another solution with Block. The possibility of adding Attributes to pure functions is documented at the Function page, the last item under the "more information" section there. The undocumented use would be if I used Function[Null,Hold[CForm[#]],HoldAll]. What is IMO the most interesting part here is that CForm works inside Hold. So, like other forms, it is not the usual command but rather the special mode of representing the output. –  Leonid Shifrin Mar 25 '11 at 16:21
    
That is an interesting behaviour from CForm; if I copy the output and then paste into a notebook it seems to be a string value inside Hold e.g. Hold["2 hgt hgt k1inv k1inv k1inv mx0 wid wid + hgt hgt k1inv k1inv k1inv wid wid wid"] and yet pasting the same copy buffer into a text editor or doing a Fullform shows that it is being held Hold[CForm[2 hgt hgt k1inv k1inv k1inv mx0 wid wid + hgt hgt k1inv k1inv k1inv wid wid wid]]; odd, but the documentation of CForm does warn that it is a clever synatical sugarcoat only. BTW thank you very much for your help this has solved my problem. –  Daniel Chisholm Mar 25 '11 at 16:46
    
@Leonid Shifrin I have been looking at the "symbolic C generation" capabilities of 8, but other than the ability to represent a c program in Mathematica and perhaps to describe it parametrically, so that you can quickly generate many versions of the same program, I haven't got a clue how to use it in a sensible way. And, getting back to the question, I don't see how it can be used to replace CForm. I can imagine that you could write a replacement of CForm in terms of Symbolic C concepts, but that's work and I want Mathematica to do that for me. –  Sjoerd C. de Vries Mar 25 '11 at 18:07
    
@Sjoerd Frankly, I haven' t used it much yet. But in this particular case, it is not too difficult and the code size is about the same (see the edit to my post), while this can also serve as a building block for building larger programs, so one can accumulate one's own functions like this, eventually turning them into some mini-compiler to C for a small subset of Mathematica, suited to one's individual needs. –  Leonid Shifrin Mar 25 '11 at 18:32
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