I have defined a binary tree:

```
data Tree = Null | Node Tree Int Tree
```

and have implemented a function that'll yield the sum of the values of all its nodes:

```
sumOfValues :: Tree -> Int
sumOfValues Null = 0
sumOfValues (Node Null v Null) = v
sumOfValues (Node Null v t2) = v + (sumOfValues t2)
sumOfValues (Node t1 v Null) = v + (sumOfValues t1)
sumOfValues (Node t1 v t2) = v + (sumOfValues t1) + (sumOfValues t2)
```

It works as expected. I had the idea of also trying to implement it using guards:

```
sumOfValues2 :: Tree -> Int
sumOfValues2 Null = 0
sumOfValues2 (Node t1 v t2)
| t1 == Null && t2 == Null = v
| t1 == Null = v + (sumOfValues2 t2)
| t2 == Null = v + (sumOfValues2 t1)
| otherwise = v + (sumOfValues2 t1) + (sumOfValues2 t2)
```

but this one doesn't work because I haven't implemented `Eq`

, I believe:

`No instance for (Eq Tree) arising from a use of `==' at zzz3.hs:13:3-12 Possible fix: add an instance declaration for (Eq Tree) In the first argument of `(&&)', namely `t1 == Null' In the expression: t1 == Null && t2 == Null In a stmt of a pattern guard for the definition of `sumOfValues2': t1 == Null && t2 == Null`

The question that has to be made, then, is how can Haskell make pattern matching without knowing when a passed argument matches, without resorting to `Eq`

?

## Edit

Your arguments seem to revolve around the fact that Haskell is not indeed comparing the arguments of the function, but instead on the "form" and types of signature to know which sub-function to match. But how about this?

```
f :: Int -> Int -> Int
f 1 _ = 666
f 2 _ = 777
f _ 1 = 888
f _ _ = 999
```

When running `f 2 9`

, won't it have to use `Eq`

to know which one of the subfunctions is the right one? All of them are equal (contrary to my initial Tree example when we had Tree/Node/Null). Or is the actual definition of an `Int`

something like

```
data Int = -2^32 | -109212 ... | 0 | ... +2^32
```

?

`Eq`

class. Numeric literals are not constructors. If they were, they couldn't have the type`Num a => a`

. Note that`Num`

requires`Eq`

. If you define a`Num`

instance with a funky`Eq`

instance, pattern matching will behave accordingly (i.e. if`(fromInteger 42 :: MyInt) == fromInteger 23`

is true, the pattern`23`

will also match the value`42 :: MyInt`

). – sepp2k Jan 17 '11 at 23:35`maxBound :: Int`

returns 2147483647, 2^31 - 1. – Wei Hu Jan 18 '11 at 0:28`Eq`

for pattern-matching, it would be rather hard to define`Eq`

instances in the first place yourself... ;-) – hvr Jan 18 '11 at 11:07