You can certainly do this. Here is one way:

```
exportCode[fname_String] :=
Function[code,
Export[fname, ToString@HoldForm@FullForm@code, "String"],
HoldAllComplete]
```

For example:

```
fn = exportCode["C:\\Temp\\mmacode.m"];
fn[
Clear[getWordsIndices];
getWordsIndices[sym_, words : {__String}] :=
Developer`ToPackedArray[words /. sym["Direct"]];
];
```

And importing this as a string:

```
In[623]:= Import["C:\\Temp\\mmacode.m","String"]//InputForm
Out[623]//InputForm=
"CompoundExpression[Clear[getWordsIndices], SetDelayed[getWordsIndices[Pattern[sym, Blank[]], \
Pattern[words, List[BlankSequence[String]]]], Developer`ToPackedArray[ReplaceAll[words, \
sym[\"Direct\"]]]], Null]"
```

However, going to other language to do metaprogramming for Mathematica sounds ridiculous to me, given that Mathematica is very well suited for that. There are many techniques available in Mathematica to do meta-programming and avoid premature evaluation. One that comes to my mind I described in this answer, but there are many others. Since you can operate on parsed code and use the pattern-matching in Mathematica, you save *a lot*. You can browse the SO Mathematica tags (past questions) and find lots of examples of meta-programming and evaluation control.

*EDIT*

To ease your pain with auto-evaluating symbols (there are only a few actually, `Infinity`

being one of them).If you just need to get a symbol name for a given symbol, then this function will help:

```
unevaluatedSymbolName = Function[sym, SymbolName@Unevaluated@sym, HoldAllComplete]
```

You use it as

```
In[638]:= unevaluatedSymbolName[Infinity]//InputForm
Out[638]//InputForm="Infinity"
```

Alternatively, you can simply add `HoldFirst`

attribute to `SymbolName`

function via `SetAttributes`

. One way is to do that globally:

SetAttributes[SymbolName,HoldFirst];
SymbolName[Infinity]//InputForm

Modifying built-in functions globally is however dangerous since it may have unpredictable effects for such a large system as Mathematica:

```
ClearAttributes[SymbolName, HoldFirst];
```

Here is a macro to use that locally:

```
ClearAll[withUnevaluatedSymbolName];
SetAttributes[withUnevaluatedSymbolName, HoldFirst];
withUnevaluatedSymbolName[code_] :=
Internal`InheritedBlock[{SymbolName},
SetAttributes[SymbolName, HoldFirst];
code]
```

Now,

```
In[649]:=
withUnevaluatedSymbolName[
{#,StringLength[#]}&[SymbolName[Infinity]]]//InputForm
Out[649]//InputForm= {"Infinity", 8}
```

You may also wish to do some replacements in a piece of code, say, replace a given symbol by its name. Here is an example code (which I wrap in `Hold`

to prevent it from evaluation):

```
c = Hold[Integrate[Exp[-x^2], {x, -Infinity, Infinity}]]
```

The general way to do replacements in such cases is using Hold-attributes (see this answer) and replacements inside held expressions (see this question). For the case at hand:

```
In[652]:=
withUnevaluatedSymbolName[
c/.HoldPattern[Infinity]:>RuleCondition[SymbolName[Infinity],True]
]//InputForm
Out[652]//InputForm=
Hold[Integrate[Exp[-x^2], {x, -"Infinity", "Infinity"}]]
```

, although this is not the only way to do this. Instead of using the above macro, we can also encode the modification to `SymbolName`

into the rule itself (here I am using a more wordy form ( Trott - Strzebonski trick) of in-place evaluation, but you can use `RuleCondition`

as well:

```
ClearAll[replaceSymbolUnevaluatedRule];
SetAttributes[replaceSymbolUnevaluatedRule, HoldFirst];
replaceSymbolUnevaluatedRule[sym_Symbol] :=
HoldPattern[sym] :> With[{eval = SymbolName@Unevaluated@sym}, eval /; True];
```

Now, for example:

```
In[629]:=
Hold[Integrate[Exp[-x^2],{x,-Infinity,Infinity}]]/.
replaceSymbolUnevaluatedRule[Infinity]//InputForm
Out[629]//InputForm=
Hold[Integrate[Exp[-x^2], {x, -"Infinity", "Infinity"}]]
```

Actually, this entire answer is a good demonstration of various meta-programming techniques. From my own experiences, I can direct you to this, this, this, this and this answers of mine, where meta-programming was essential to solve problem I was addressing. You can also judge by the fraction of functions in Mathematica carrying Hold-attributes to all functions - it is about 10-15 percents if memory serves me well. All those functions are effectively macros, operating on code. To me, this is a very indicative fact, telling me that Mathematica jeavily builds on its meta-programming facilities.