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I am having a problem getting Automatic Differentiation to work between C# and F#.

In C# I have a function that takes a double and returns a double, say:

private double Price(double yield)
{
    double price;

    price = 0;

    for (int index = 1; index <= _maturity * _frequency; index++)
    {
        price += (_coupon / _frequency) * _nominal / Math.Pow(1 + (yield / _frequency), index);
    }

    price += _nominal / Math.Pow(1 + (yield / _frequency), _maturity * _frequency);

    return price;
}

I picked this function specifically, as the Math.pow is very prohibitive, and only allows a double's or int's for its parameters.

I would like to differentiate this function using Automatic Differentiation. I have written the method for this in F#:

type Diff(d : double, df : Lazy<Diff>) = class
    member x.d = d
    member x.df = df
    static member (+) (x : Diff, y : Diff) = 
        Diff(x.d + y.d, lazy (x.df.Value + y.df.Value)) 
    static member (-) (x : Diff, y : Diff) = 
        Diff(x.d - y.d, lazy (x.df.Value - y.df.Value))
    static member (*) (x : Diff, a : double) = 
        Diff(x.d * a, lazy (x.df.Value * a))
    static member (*) (x : Diff, y : Diff) = 
        Diff(x.d * y.d, lazy ((x.df.Value * y) + (y.df.Value * x)))
    override x.ToString() =
        x.d.ToString()
end

let rec dZero = Diff(0.0, lazy dZero)

let dConst x = Diff(x, lazy dZero)

let dId x = Diff(x, lazy dConst 1.0)

let Differentiate (x:Diff) = x.df.Value

// Example function
let f (x:Diff) = x*x*x;

// Example usage:
// (f (dId 5)).ToString = "125"
// (Differentiate (f (dId 5))).ToString = "75"
// (Differentiate (Differentate (f (dId 5)))).ToString = "30"

Unfortunately, I need to feed a type Diff into my Price(..) function to produce a type Diff, which then gets fed into my Differente(..) function to return another type Diff.

My C# function however works solely on doubles (and I would like it to stay this way, as it is used in other places in my C# program).

The only way I can think to solve this is to write every function twice, which is obviously awful as:

1) I may as well just write a differentiated version each time 2) This isn't a very expandable model

So is there any way I can get around this, or perhaps coerce my double functions into Diff functions (preferably in F#). Ideally I would just like to throw a (double -> double) function in and get a Diff.ToString() out.

Sorry if this totally vague or impossible to understand. I will answer any questions in comments if this is unclear.

I hope there is a solution for this! Thanks in advance,

Ashley

share|improve this question
    
I'm not sure I understand what you're asking here. If I read your question correctly, it seems you want to be able to use your Price method (unmodified) as you use your example function f. But f uses your custom operators, while a C# method operating on doubles will always use the double operators. –  dtb Sep 8 '10 at 20:09
    
Note that if you're only interested in the numerical value of the derivative and no symbolic term, just use an approximation formula: f'(x) = (f(x+h)-f(x))/h for some small h –  Dario Sep 8 '10 at 20:23
    
@dtb Yes, you are exactly correct. Ideally I would like to use a transform/coerce on the functions parameters to get them from double to Diff. –  Ash Sep 8 '10 at 21:10
    
@Dario Yes, I am only interested in the numerical derivative. However, using the approximation has two problems. 1) It is very inaccurate (for a price), 2) h needs to change from function to function and with variable x to optimize the method, hence I would prefer a more general one. –  Ash Sep 8 '10 at 21:12
    
With maturity=5, frequency=10, coupon=11 and nominal=13 I get Price(Id(2))==71.493, Differentiate(Price(Id(2)))==-423.782 and Differentiate(Differentiate(Price(Id(2))))==5039.610. Is that correct? –  dtb Sep 9 '10 at 19:36

2 Answers 2

up vote 2 down vote accepted

You can re-invent Haskell Type Classes:

interface Eq<T>
{
    bool Equal(T a, T b);
    bool NotEqual(T a, T b);
}

interface Num<T> : Eq<T>
{
    T Zero { get; }
    T Add(T a, T b);
    T Subtract(T a, T b);
    T Multiply(T a, T b);
    T Negate(T a);
}

sealed class Int : Num<int>
{
    public static readonly Int Instance = new Int();
    private Int() { }
    public bool Equal(int a, int b) { return a == b; }
    public bool NotEqual(int a, int b) { return a != b; }
    public int Zero { get { return 0; } }
    public int Add(int a, int b) { return a + b; }
    public int Subtract(int a, int b) { return a - b; }
    public int Multiply(int a, int b) { return a * b; }
    public int Negate(int a) { return -a; }
}

Then you can do:

static T F<M, T>(M m, T x) where M : Num<T>
{
    return m.Multiply(x, m.Multiply(x, x));
}

static void Main(string[] args)
{
    Console.WriteLine(F(Int.Instance, 5));  // prints "125"
}

And then with:

class Diff
{
    public readonly double d;
    public readonly Lazy<Diff> df;

    public Diff(double d, Lazy<Diff> df)
    {
        this.d = d;
        this.df = df;
    }
}

class DiffClass : Floating<Diff>
{
    public static readonly DiffClass Instance = new DiffClass();
    private static readonly Diff zero = new Diff(0.0, new Lazy<Diff>(() => DiffClass.zero));
    private DiffClass() { }
    public Diff Zero { get { return zero; } }
    public Diff Add(Diff a, Diff b) { return new Diff(a.d + b.d, new Lazy<Diff>(() => Add(a.df.Value, b.df.Value))); }
    public Diff Subtract(Diff a, Diff b) { return new Diff(a.d - b.d, new Lazy<Diff>(() => Subtract(a.df.Value, b.df.Value))); }
    public Diff Multiply(Diff a, Diff b) { return new Diff(a.d * b.d, new Lazy<Diff>(() => Add(Multiply(a.df.Value, b), Multiply(b.df.Value, a)))); }
    ...
}

You can do this:

static T Price<M, T>(M m, T _maturity, T _frequency, T _coupon, T _nominal, T yield) where M : Floating<T>
{
    T price;

    price = m.Zero;

    for (T index = m.Succ(m.Zero); m.Compare(index, m.Multiply(_maturity, _frequency)) <= 0; index = m.Succ(index))
    {
        price = m.Add(price, m.Divide(m.Multiply(m.Divide(_coupon, _frequency), _nominal), m.Power(m.Add(m.Succ(m.Zero), m.Divide(yield, _frequency)), index)));
    }

    price = m.Add(price, m.Divide(_nominal, m.Power(m.Add(m.Succ(m.Zero), m.Divide(yield, _frequency)), m.Multiply(_maturity, _frequency))));

    return price;
}

But that's not really pretty.

In fact, it almost reads like code that creates a LINQ Expression Tree. Maybe you can use Source code Expression tree transformation instead of Operator overloading to achieve Automatic differentiation?

share|improve this answer

There's no way to use your existing C# function, nor is there any easy way to lift it to a function that could operate on members of type Diff. Once the function has been compiled it is opaque and the internal structure is unavaliable; all you can do is call the function with a double argument and get a double result. Furthermore, your Price method uses operations which you haven't even defined on your Diff class anyway ((\) and Pow).

I'm not sure if it would be acceptable for your purposes, but one possible alternative would be to write a generic inline version of your Price function in F#, which could then operate on either doubles or Diffs (assuming that you add the (\) and Pow operators).

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