At work, we use monads to control IO in our C# code on our most important pieces of business logic. Two examples are our financial code and code that finds solutions to an optimization problem for our customers.

In our financial code, we use a monad to control IO writing to and reading from our database. It essentially consists of a small set of operations and an abstract syntax tree for the monad operations. You could imagine it's something like this (not actual code):

```
interface IFinancialOperationVisitor<T, out R> : IMonadicActionVisitor<T, R> {
R GetTransactions(GetTransactions op);
R PostTransaction(PostTransaction op);
}
interface IFinancialOperation<T> {
R Accept<R>(IFinancialOperationVisitor<T, R> visitor);
}
class GetTransactions : IFinancialOperation<IError<IEnumerable<Transaction>>> {
Account Account {get; set;};
public R Accept<R>(IFinancialOperationVisitor<R> visitor) {
return visitor.Accept(this);
}
}
class PostTransaction : IFinancialOperation<IError<Unit>> {
Transaction Transaction {get; set;};
public R Accept<R>(IFinancialOperationVisitor<R> visitor) {
return visitor.Accept(this);
}
}
```

which is essentially the Haskell code

```
data FinancialOperation a where
GetTransactions :: Account -> FinancialOperation (Either Error [Transaction])
PostTransaction :: Transaction -> FinancialOperation (Either Error Unit)
```

along with an abstract syntax tree for the construction of actions in a monad, essentially the free monad:

```
interface IMonadicActionVisitor<in T, out R> {
R Return(T value);
R Bind<TIn>(IMonadicAction<TIn> input, Func<TIn, IMonadicAction<T>> projection);
R Fail(Errors errors);
}
// Objects to remember the arguments, and pass them to the visitor, just like above
// Hopefully I got the variance right on everything for doing this without higher order types, which is how we used to do this. We now use higher order types in c#, more on that below. Here, to avoid a higher-order type, the AST for monadic actions is included by inheritance in
```

In the real code, there are more of these so we can remember that something was built by `.Select()`

instead of `.SelectMany()`

for efficiency. A financial operation, including intermediary computations still has type `IFinancialOperation<T>`

. The actual performance of the operations is done by an interpreter, which wraps all the database operations in a transaction and deals with how to roll that transaction back if any component is unsuccessful. We also use a interpreter for unit testing the code.

In our optimization code, we use a monad for controlling IO to get external data for optimization. This allows us to write code that is ignorant of how computations are composed, which lets us use exactly the same business code in multiple settings:

- synchronous IO and computations for computations done on demand
- asynchronous IO and computations for many computations done in parallel
- mocked IO for unit tests

Since the code needs to be passed which monad to use, we need an explicit definition of a monad. Here's one. `IEncapsulated<TClass,T>`

essentially means `TClass<T>`

. This lets the c# compiler keep track of all three pieces of the type of monads simultaneously, overcoming the need to cast when dealing with monads themselves.

```
public interface IEncapsulated<TClass,out T>
{
TClass Class { get; }
}
public interface IFunctor<F> where F : IFunctor<F>
{
// Map
IEncapsulated<F, B> Select<A, B>(IEncapsulated<F, A> initial, Func<A, B> projection);
}
public interface IApplicativeFunctor<F> : IFunctor<F> where F : IApplicativeFunctor<F>
{
// Return / Pure
IEncapsulated<F, A> Return<A>(A value);
IEncapsulated<F, B> Apply<A, B>(IEncapsulated<F, Func<A, B>> projection, IEncapsulated<F, A> initial);
}
public interface IMonad<M> : IApplicativeFunctor<M> where M : IMonad<M>
{
// Bind
IEncapsulated<M, B> SelectMany<A, B>(IEncapsulated<M, A> initial, Func<A, IEncapsulated<M, B>> binding);
// Bind and project
IEncapsulated<M, C> SelectMany<A, B, C>(IEncapsulated<M, A> initial, Func<A, IEncapsulated<M, B>> binding, Func<A, B, C> projection);
}
public interface IMonadFail<M,TError> : IMonad<M> {
// Fail
IEncapsulated<M, A> Fail<A>(TError error);
}
```

Now we could imagine making another class of monad for the portion of IO our computations need to be able to see:

```
public interface IMonadGetSomething<M> : IMonadFail<Error> {
IEncapsulated<M, Something> GetSomething();
}
```

Then we can write code that doesn't know about how computations are put together

```
public class Computations {
public IEncapsulated<M, IEnumerable<Something>> GetSomethings<M>(IMonadGetSomething<M> monad, int number) {
var result = monad.Return(Enumerable.Empty<Something>());
// Our developers might still like writing imperative code
for (int i = 0; i < number; i++) {
result = from existing in r1
from something in monad.GetSomething()
select r1.Concat(new []{something});
}
return result.Select(x => x.ToList());
}
}
```

This can be reused in both a synchronous and asynchronous implementation of an `IMonadGetSomething<>`

. Note that in this code, the `GetSomething()`

s will happen one after another until there's an error, even in an asynchronous setting. (No this is not how we build lists in real life)