What you request is tricky. This is a job for macros, as already exposed by the others. I will explore a different possibility - to use the same symbols but put some wrappers around the code you want to write. The advantage of this technique is that the code is transformed "lexically" and at "compile-time", rather than at run-time (as in the other answers). This is generally both faster and easier to debug.

So, here is a function which would transform the `With`

with your proposed syntax:

```
Clear[expandWith];
expandWith[heldCode_Hold] :=
Module[{with},
heldCode /. With -> with //. {
HoldPattern[with[{{} = {}, rest___}, body_]] :>
with[{rest}, body],
HoldPattern[
with[{
Set[{var_Symbol, otherVars___Symbol}, {val_, otherVals___}], rest___},
body_]] :>
with[{{otherVars} = {otherVals}, var = val, rest}, body]
} /. with -> With]
```

Note that this operates on held code. This has the advantage that we don't have to worry about possible evaluation o the code neither at the start nor when `expandWith`

is finished. Here is how it works:

```
In[46]:= expandWith@Hold[With[{{x1,x2,x3}={a,b,c}},x+x1+x2+x3]]
Out[46]= Hold[With[{x3=c,x2=b,x1=a},x+x1+x2+x3]]
```

This is, however, not very convenient to use. Here is a convenience function to simplify this:

```
ew = Function[code, ReleaseHold@expandWith@Hold@code, HoldAll]
```

We can use it now as:

```
In[47]:= ew@With[{{x1,x2}={a,b}},x+x1+x2]
Out[47]= a+b+x
```

So, to make the expansion happen in the code, simply wrap `ew`

around it. Here is your case for the function's definition:

```
Remove[f];
ew[f[x_] := With[{{x1, x2} = {a, b}}, x + x1 + x2]]
```

We now check and see that what we get is an expanded definition:

```
?f
Global`f
f[x_]:=With[{x2=b,x1=a},x+x1+x2]
```

The advantage of this approach is that you can wrap `ew`

around an arbitrarily large chunk of your code. What happens is that first, expanded code is generated from it, as if you would write it yourself, and then that code gets executed. For the case of function's definitions, like `f`

above, we cansay that the code generation happens at "compile-time", so you avoid any run-time overhead when usin the function later, which may be substantial if the function is called often.

Another advantage of this approach is its composability: you can come up with many syntax extensions, and for each of them write a function similar to `ew`

. Then, provided that these custom code-transforming functions don't conlict with each other, you can simply compose (nest) them, to get a cumulative effect. In a sense, in this way you create a custom code generator which generates valid Mathematica code from some Mathematica expressions representing programs in your custom languuage, that you may create within Mathematica using these means.

*EDIT*

In writing `expandWith`

, I used iterative rule application to avoid dealing with evaluation control, which can be a mess. However, for those interested, here is a version which does some explicit work with unevaluated pieces of code.

```
Clear[expandWithAlt];
expandWithAlt[heldCode_Hold] :=
Module[{myHold},
SetAttributes[myHold, HoldAll];
heldCode //. HoldPattern[With[{Set[{vars__}, {vals__}]}, body_]] :>
With[{eval =
(Thread[Unevaluated[Hold[vars] = Hold[vals]], Hold] /.
Hold[decl___] :> myHold[With[{decl}, body]])},
eval /; True] //. myHold[x_] :> x]
```

I find it considerably more complicated than the first one though.

`Set`

in the first argument of these isn't actually performing the`Set`

operation but instead is syntax. – Mr.Wizard Dec 4 '11 at 6:53