# Complete, efficient NumericLiteral module implementation

Building on a discussion in this question, could anyone provide code, or a link to code, showing a complete implementation of a `NumericLiteralX` module (such as this one)? I'm especially interested in an efficient implementation of `FromInt32`/`64` for a `NumericLiteralX` module that facilitates generic numeric operations. Here's a perhaps inefficient implementation taken from the aforementioned question:

``````module NumericLiteralG =
let inline FromZero() = LanguagePrimitives.GenericZero
let inline FromOne() = LanguagePrimitives.GenericOne
let inline FromInt32 (n:int) =
let one : ^a = FromOne()
let zero : ^a = FromZero()
let n_incr = if n > 0 then 1 else -1
let g_incr = if n > 0 then one else (zero - one)
let rec loop i g =
if i = n then g
else loop (i + n_incr) (g + g_incr)
loop 0 zero
``````

How could this be improved and completed?

-

I'll just address `FromInt32`. In an ideal world, we could define it as simply as

``````let inline FromInt32 i =
((^t or int) : (static member op_Explicit : int -> ^t) i)
``````

which would use static constraints to ensure that we could inline an explicit conversion from `int`. Unfortunately, there are two problems with this. The first is that the syntax is invalid - you can't have a concrete type (like `int`) in the "static-typars" portion of a member constraint. We can work around this by defining a helper function

``````let inline cvt i = ((^t or ^u) : (static member op_Explicit : ^u -> ^t) i)
let inline FromInt32 (i:int) = cvt i
``````

Since both of these functions are inlined, this isn't any less efficient than the first attempt, it's just wordier.

Here's where we run into the second problem: this will work for real `op_Explicit` definitions (or `op_Implicit`, which is treated specially by the compiler so that it is subsumed by `op_Explicit`). So `(10G : bigint)` will be inlined as if you had written `System.Numerics.BigInt.op_Implicit 10`, which is as efficient as we can hope for. However, F# also simulates `op_Explicit` for many primitive types (e.g. for conversions from `int` to `float`, `byte`, etc.), and since the definition of `FromInt32` relies on the existence of these members it will fail at runtime (that is, `(10G : float)` and even `(10G : int)` will compile but will throw an exception when executed). Ideally a future version of F# might enable this to work as-is, but as of F# 2.0, we'll need to come up with a workaround.

It would be nice if we could use a similar approach to how the F# core library handles this kind of problem, which would require special casing all of the implied operators but would result in everything being inlined with perfect efficiency:

``````let inline FromInt32 (i : int) : ^t =
cvt i
when ^t : int   = int i
when ^t : float = float i
when ^t : byte  = byte i
...
``````

However, the F# compiler rejects this with a `"Static optimization conditionals are only for use within the F# library"` message (and compiling with the secret `--compiling-fslib` flag only makes things worse :)).

Instead, we need to use a few additional layers of indirection to achieve something similar at runtime. First, we'll create a runtime mapping of types to conversion functions by using a static member of a generic type:

``````type IntConverterDynamicImplTable<'t>() =
static let result : int -> 't =
let ty = typeof< 't> //'
if   ty.Equals(typeof<sbyte>)      then sbyte      |> box |> unbox
elif ty.Equals(typeof<int16>)      then int16      |> box |> unbox
elif ty.Equals(typeof<int32>)      then int        |> box |> unbox
elif ty.Equals(typeof<int64>)      then int64      |> box |> unbox
elif ty.Equals(typeof<nativeint>)  then nativeint  |> box |> unbox
elif ty.Equals(typeof<byte>)       then byte       |> box |> unbox
elif ty.Equals(typeof<uint16>)     then uint16     |> box |> unbox
elif ty.Equals(typeof<char>)       then char       |> box |> unbox
elif ty.Equals(typeof<uint32>)     then uint32     |> box |> unbox
elif ty.Equals(typeof<uint64>)     then uint64     |> box |> unbox
elif ty.Equals(typeof<unativeint>) then unativeint |> box |> unbox
elif ty.Equals(typeof<decimal>)    then decimal    |> box |> unbox
elif ty.Equals(typeof<float>)      then float      |> box |> unbox
elif ty.Equals(typeof<float32>)    then float32    |> box |> unbox
else
let m =
try ty.GetMethod("op_Implicit", [| typeof<int> |])
with _ -> ty.GetMethod("op_Explicit", [| typeof<int> |])
let del =
System.Delegate.CreateDelegate(typeof<System.Func<int,'t>>, m)
:?> System.Func<int,'t>
del.Invoke |> box |> unbox
static member Result = result
``````

This is similar to what we were trying to achieve with the static optimization conditionals in the previous attempt, but it's deferred to runtime instead of everything being evaluated at compile time. Now we just need to define a few values to use this type:

``````let inline constrain< ^t, ^u when (^t or ^u) : (static member op_Explicit : ^t -> ^u)> () = ()
let inline FromInt32 i : ^t =
constrain<int, ^t>()
IntConverterDynamicImplTable.Result i
``````

Here, the `constrain` function is just used to make sure that `FromInt32` can only be applied to types where there's an explicit conversion from int (or one simulated by the compiler). The actual call to `constrain()` within `FromInt32` should get optimized away during compilation.

With this approach, `(10G : bigint)` will get compiled to something like `IntConverterDynamicImplTable<bigint>.Result 10`, and `IntConverterDynamicTable<bigint>.Result` will have a value equivalent to `(System.Func<int,bigint>(bigint.op_Implicit)).Invoke` (but cached, so that the delegate is only created once). Similarly, `(10G : int64)` will compile to `IntConverterDynamicImplTable<int64>.Result 10`, and `IntConverterDynamicTable<int64>.Result` will have a value equivalent to the conversion function `(int64 : int -> int64)`, so there are overheads of a few method calls, but the overall performance should be very good.

EDIT

However, if you're just looking for something more efficient than a naive implementations of `FromInt32` and `FromInt64` taking time O(n), here's a version which is still relatively simple and only takes O(log n) time:

``````module SymmetricOps =
let inline (~-) (x:'a) : 'a = -x
let inline (+) (x:'a) (y:'a) : 'a = x + y
let inline (-) (x:'a) (y:'a) : 'a = x - y
let inline (*) (x:'a) (y:'a) : 'a = x * y
let inline (/) (x:'a) (y:'a) : 'a = x / y
let inline (%) (x:'a) (y:'a) : 'a = x % y

module NumericLiteralG =
open SymmetricOps
let inline FromOne() = LanguagePrimitives.GenericOne
let inline FromZero() = LanguagePrimitives.GenericZero
let rec compute zero one two (/) (%) Two (+) (-) (*) pow2 rest n =
if n = zero then rest
else
let rest' =
let nmod2 = n % two
if nmod2 = zero then rest
elif nmod2 = one then rest + pow2
else rest - pow2
compute zero one two (/) (%) Two (+) (-) (*) (Two * pow2) rest' (n / two)
let inline FromInt32 i = compute 0  1  2  (/) (%) (FromOne() + FromOne()) (+) (-) (*) (FromOne()) (FromZero()) i
let inline FromInt64 i = compute 0L 1L 2L (/) (%) (FromOne() + FromOne()) (+) (-) (*) (FromOne()) (FromZero()) i
``````
-
Wow. Thanks for the great explanation. –  Daniel Jan 19 '11 at 23:11
Granting for the moment that no mere mortal is likely to implement this, is there an easier way to express an arbitrary generic number? `GenericZero` and `GenericOne` are given, but what about `GenericN`? It's essential for generic numeric operations...and awkward to compute using `GenericOne`/`Zero`. –  Daniel Jan 19 '11 at 23:16
@Daniel - Well, I guess it depends on how efficient you need it to be. There's nothing wrong with the more straightforward approach to `FromInt32` used in your question, it's just that it will result in more overhead. –  kvb Jan 19 '11 at 23:30
@kvb - Doesn't it have linear cost? To calculate 1 million is it going to loop a million times? If so, I'm hoping for a better way to go about it. –  Daniel Jan 19 '11 at 23:36
+1: <3 all of your answers, kvb :) –  Juliet Jan 20 '11 at 22:29