As far as I can tell (and this has been mentioned by other answerers already), `Condition`

should not be thought of as a standalone function, but as a wrapper used in forming larger expressions involving patterns. But I want to stress that part of the subtlety here comes from the fact that `Rule`

and `RuleDelayed`

are scoping constructs. In general, scoping constructs must have a variable-binding stage, where they resolve possible conflicts in variable names and actually bind variables to their occurrences in the body of the scoping construct (or, in the r.h.s. of the rule for `Rule`

and `RuleDelayed`

). This may be considered a part of the inner workings of the scoping constructs, but, because Mathematica allows top-level manipulations through attributes and things like `Evaluate`

, scoping constructs are not as black-box as they may seem - we may change the bindings by forcing the variable declarations, or the body, or both, to evaluate before the binding happens - for example, by removing some of the `Hold*`

- attributes. I discussed these things here in somewhat more detail, although, not knowing the exact implementation details for the scoping constructs, I had to mostly guess.

Returning back to the case of `Rule`

, `RuleDelayed`

and `Condition`

, it is instructive to `Trace`

one of the examples discussed:

```
In[28]:= Trace[Cases[{3,3.},a_:>Print[a]/;(Print["!"];IntegerQ[a])],RuleCondition,TraceAbove->All]
During evaluation of In[28]:= !
During evaluation of In[28]:= !
During evaluation of In[28]:= 3
Out[28]= {Cases[{3,3.},a_:>Print[a]/;(Print[!];IntegerQ[a])],
{RuleCondition[$ConditionHold[$ConditionHold[Print[3]]],True],
$ConditionHold[$ConditionHold[Print[3]]]},
{RuleCondition[$ConditionHold[$ConditionHold[Print[3.]]],False],Fail},
{Print[3]},{Null}}
```

What you see is that there are special internal heads `RuleCondition`

and `$ConditionHold`

, which appear when `Condition`

is used with `Rule`

or `RuleDelayed`

. My guess is that these implement the mechanism to incorporate conditions on pattern variables, including the variable binding. When you use `Condition`

as a standalone function, these don't appear. These heads are crucial for condition mechanism to really work.
You can look at how they work in `Rule`

and `RuleDelayed`

:

```
In[31]:= RuleCondition[$ConditionHold[$ConditionHold[Print[3.`]]],True]
Out[31]= $ConditionHold[$ConditionHold[Print[3.]]]
In[32]:= RuleCondition[$ConditionHold[$ConditionHold[Print[3.`]]],False]
Out[32]= Fail
```

You can see that, say, `Cases`

picks up only elements of the form `$ConditionHold[$ConditionHold[something]]`

, and ignore those where `RuleCondition`

results in `Fail`

. Now, what happens when you use `Condition`

as a stand-alone function is different - thus the difference in results.

One good example I am aware of, which illustrates the above points very well, is in this thread, where possible implementations of a version of `With`

which binds sequentially, are discussed. I will repeat a part of that discussion here, since it is instructive. The idea was to make a version of With, where previous declarations can be used for declarations further down the declaration list. If we call it `Let`

, then, for example, for code like

```
Clear[h, xl, yl];
xl = 1;
yl = 2;
h[x_, y_] := Let[{xl = x, yl = y + xl + 1}, xl^2 + yl^2];
h[a, b]
```

we should get

```
a^2+(1+a+b)^2
```

One of the implementations which was suggested, and gives this result, is:

```
ClearAll[Let];
SetAttributes[Let, HoldAll];
Let /: (lhs_ := Let[vars_, expr_ /; cond_]) :=
Let[vars, lhs := expr /; cond]
Let[{}, expr_] := expr;
Let[{head_}, expr_] := With[{head}, expr]
Let[{head_, tail__}, expr_] := With[{head}, Let[{tail}, expr]]
```

(this is due to Bastian Erdnuess). What happens here is that this `Let`

performs bindings at run-time, rather than at the time when function is being defined. And as soon as we want to use shared local variables, it fails:

```
Clear[f];
f[x_,y_]:=Let[{xl=x,yl=y+xl+1},xl^2+yl^2/;(xl+yl<15)];
f[x_,y_]:=x+y;
?f
Global`f
f[x_,y_]:=x+y
```

Had it worked correctly, and we should have ended up with 2 distinct definitions. And here we come to the crux of the matter: since this `Let`

acts at run-time, `SetDelayed`

does not perceive the `Condition`

as a part of the pattern - it would do that for `With`

, `Block`

, `Module`

, but not some unknown `Let`

. So, both definitions look for Mathematica the same (in terms of patterns), and therefore, the second replaces the first. But this is not all. Now we only create the first definition, and try to execute:

```
Clear[f];
f[x_, y_] := Let[{xl = x, yl = y + xl + 1}, xl^2 + yl^2 /; (xl + yl < 15)];
In[121]:= f[3, 4]
Out[121]= 73 /; 3 + 8 < 15
```

If you trace the last execution, it would be very unclear why the `Condition`

did not fire here. The reason is that we messed up the binding stage. Here is my improved version, which is free from these flaws:

```
ClearAll[LetL];
SetAttributes[LetL, HoldAll];
LetL /: Verbatim[SetDelayed][lhs_, rhs : HoldPattern[LetL[{__}, _]]] :=
Block[{With}, Attributes[With] = {HoldAll};
lhs := Evaluate[rhs]];
LetL[{}, expr_] := expr;
LetL[{head_}, expr_] := With[{head}, expr];
LetL[{head_, tail__}, expr_] :=
Block[{With}, Attributes[With] = {HoldAll};
With[{head}, Evaluate[LetL[{tail}, expr]]]];
```

What is does is that it expands `LetL`

into nested `With`

at definition-time, not run-time, and that happens *before* the binding stage. Now, let us see:

```
In[122]:=
Clear[ff];
ff[x_,y_]:=LetL[{xl=x,yl=y+xl+1},xl^2+yl^2/;(xl+yl<15)];
Trace[ff[3,4]]
Out[124]= {ff[3,4],
{With[{xl$=3},With[{yl$=4+xl$+1},RuleCondition[$ConditionHold[$ConditionHold[xl$^2+yl$^2]],
xl$+yl$<15]]],With[{yl$=4+3+1},RuleCondition[$ConditionHold[$ConditionHold[3^2+yl$^2]],3+yl$<15]],
{4+3+1,8},RuleCondition[$ConditionHold[$ConditionHold[3^2+8^2]],3+8<15],
{{3+8,11},11<15,True},RuleCondition[$ConditionHold[$ConditionHold[3^2+8^2]],True],
$ConditionHold[$ConditionHold[3^2+8^2]]},3^2+8^2,{3^2,9},{8^2,64},9+64,73}
```

This works fine, and you can see the heads `RuleCondition`

and `$ConditionHold`

showing up all right. It is instructive to look at the resulting definition for `ff`

:

```
?ff
Global`ff
ff[x_,y_]:=With[{xl=x},With[{yl=y+xl+1},xl^2+yl^2/;xl+yl<15]]
```

You can see that `LetL`

has expanded at definition-time, as advertised. And since pattern variable binding happened after that, things work fine. Also, if we add another definition:

```
ff[x_,y_]:=x+y;
?ff
Global`ff
ff[x_,y_]:=With[{xl=x},With[{yl=y+xl+1},xl^2+yl^2/;xl+yl<15]]
ff[x_,y_]:=x+y
```

We see that the patterns are now perceived as different by Mathematica.

The final question was why `Unevaluated`

does not restore the behavior of `RuleDelayed`

broken by the removal of its `HoldRest`

attribute. I can only guess that this is related to the unusual behavior of `RuleDelayed`

(it eats up any number of `Unevaluated`

wrappers around the r.h.s.), noted in the comments to this question.

To summarize: one of the most frequent intended uses of `Condition`

is closely tied to the enclosing scoping constructs (`Rule`

and `RuleDelayed`

), and one should take into account the variable binding stage in scoping constructs, when analyzing their behavior.

Mathematicaall the functions are supposed to be working in a very general way.`Condition`

(and a use of`Update`

). The reply of Carl Woll to an old Mathgroup question from David Park might also be of general interest.