There is a nice graphic in Gödel, Escher, Bach that illustrates this issue: it displays the universe split into the true and the false, and elaborate structures covered with appendages illustrating “proof”. Of all valid programs¹, many are “typeable”, meaning that we can prove that they are sound, type-wise, with a particular type system; conversely, most invalid programs are not typeable.
However, you might imagine that the fingers stretch into the invalid space on occasion, and they don't cover the valid space entirely either; for any given type system, there are valid programs that are rejected, and there are invalid programs that are accepted.
Not so simple math
The goal of type system research is to both accept more valid programs and reject more invalid programs. Let's consider these three programs in three different languages, which implement one step of a divide-and-conquer list reduction strategy.def pm(x, y, z): # Python return x + y - z pm x y z = x + y - z -- Haskell -- inferred as Num a ⇒ a → a → a → a int pm(int x, int y, int z) { /* C */ return x + y - z; }First, the expressive problem in C is easy to spot: you can only add and subtract
int
s. You have to reimplement this for each
number type, even if the code stays the same.
The Haskell expressive problem is a little more obscure, but more obvious given the inferred type: all the numbers must be of the same type. You can see this with some partial application:
pm (1::Int) -- Int → Int → Int pm (1::Integer) -- Integer → Integer → Integer pm (1::Float) -- Float → Float → FloatThe Python version works on a numeric tower: once you introduce a float, it sticks. This may be good for you, or it may be bad. If you are reducing some data with
pm
and a float sneaks in there, you
won't see it until you get the final output. So with dynamic
promotion, pm
works with everything, even some things you
probably don't want.
There are adjustments you can make to get the Haskell version to be more general, but this all depends on the kind of generalization you mean. This is a matter of continued innovation, even in the standard library; many commonly used libraries provide alternative, more generic versions of built-in
Prelude
functions, such as
fmap
for functors, one of many, many generalizations
that work with lists, in this case replacing map
.
Footnotes
[1] Use whatever
meaning you like for “valid”, but if you want something more formal,
perhaps “it terminates” will suffice.
No comments:
Post a Comment