Yes, what you are trying to do is impossible in Haskell, and in general: deciding whether two functions are equal for all possible inputs (without just checking every input value, if that is even possible) is equivalent to solving the Halting problem.
However, in your specific case, you can get around it, using a custom type that simulates a
Double (i.e. has the same instances, and so can be used in place of it) but instead of evaluating to a number, it constructs an abstract representation of the operations the functions does.
Expr represents the right-hand side of a mathematical function definition
f(x) = ....
data Expr = X | Const Double |
Add Expr Expr | Mult Expr Expr |
Negate Expr | Inverse Expr |
Exp Expr | Log Expr | Sin Expr | ...
deriving (Show, Eq)
instance Num Expr where
(+) = Add
(*) = Mult
instance Fractional Expr where
recip = Inverse
instance Floating Expr where
pi = Const pi
exp = Exp
log = Log
sin = Sin
Then, you can define conversion functions that convert between functions and
fromFunction :: Floating a => (a -> a) -> Expr
fromFunction f = f X
toFunction :: Expr -> (Double -> Double)
toFunction X = \x -> x
toFunction (Const a) = const a
toFunction (Plus a b) = \x -> (toFunction a x) + (toFunction b x)
You can also define a function
diff :: Expr -> Expr that differentiates the expression:
diff X = Const 1
diff (Const _) = Const 0
diff (Plus a b) = Plus (diff a) (diff b)
diff (Exp a) = Mult (diff a) (Exp a)
Having all these parts should mean that you can differentiate (some) functions, e.g.
f x = sin x + cos x * exp x
f' = toFunction . diff . fromFunction $ f
- this won't work in general,
- defining a complete
Eq instance for
Expr is tricky (it is equivalent to the Halting problem, since it is basically asking if two functions are equal),
- I haven't actually tested any of this code,
- the differentiation and reconstruction are done at runtime, so the resulting function is highly likely to be very slow.