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An example of doing the Roman numerals kata with property-based test-driven development.

The Roman numerals kata is a simple programming exercise. You should implement conversion to and from Roman numerals. This always struck me as the ultimate case for example-driven development, but I must also admit that I've managed to get stuck on the exercise doing exactly that: throwing more and more examples at the problem. Prompted by previous successes with property-based testing, I wondered whether the problem would be more tractable if approached with property-based testing. This turned out to be the case.

Single values #

When modelling a problem with property-based testing, you should attempt to express it in terms of general rules, but even so, the fundamental rule of Roman numerals is that there are certain singular symbols that have particular numeric values. There are no overall principles guiding these relationships; they simply are. Therefore, you'll still need to express these singular values as particular values. This is best done with a simple parametrised test, here using xUnit.net 2.1:

[<Theory>]
[<InlineData("I",    1)>]
[<InlineData("V",    5)>]
[<InlineData("X",   10)>]
[<InlineData("L",   50)>]
[<InlineData("C",  100)>]
[<InlineData("D",  500)>]
[<InlineData("M", 1000)>]
let ``elemental symbols have correct values`` (symbol : string) expected =
    Some expected =! Numeral.tryParseRoman symbol

The =! operator is a custom operator defined by Unquote (3.1.1), an assertion library. You can read it as must equal; that is, you can read this particular assertion as some expected must equal tryParseRoman symbol.

As you can see, this simple test expresses the relationship between the singular Roman numeral values and their decimal counterparts. You might still consider this automated test as example-driven, but I more think about it as establishing the ground rules for how Roman numerals work. If you look at the Wikipedia article, for instance, it also starts explaining the system by listing the values of these seven symbols.

Round-tripping #

A common technique when applying property-based testing to parsing problems is to require that values can round-trip. This should also be the case here:

let romanRange = Gen.elements [1..3999] |> Arb.fromGen
 
[<Property(QuietOnSuccess = true)>]
let ``tryParse is the inverse of toRoman`` () =
    Prop.forAll romanRange <| fun i ->
        test <@ Some i = (i |> Numeral.toRoman
                            |> Option.bind Numeral.tryParseRoman) @>

This property uses FsCheck (2.2.4). First, it expresses a range of relevant integers. For various reasons (that we'll return to) we're only going to attempt conversion of the integers between 1 and 3,999. The value romanRange has the type Arbitrary<int>, where Arbitrary<'a> is a type defined by FsCheck. You can think of it as a generator of random values. In this case, romanRange generates random integers between 1 and 3,999.

When used with Prop.forAll, the property states that for all values drawn from romanRange, the anonymous function should succeed. The i argument within that anonymous function is populated by romanRange, and the function is executed 100 times (by default).

The test function is another Unquote function. It evaluates and reports on the quoted boolean expression; if it evaluates to true, nothing happens, but it throws an exception if it evaluates to false.

The particular expression states that if you call toRoman with i, and then call tryParseRoman with the return value of that function call, the result should be equal to i. Both sides should be wrapped in a Some case, though, since both toRoman and tryParseRoman might also return None. For the values in romanRange, however, you'd expect that the round-trip always succeeds.

Additivity #

The fundamental idea about Roman numerals is that they are additive: I means 1, II means (1 + 1 =) 2, XXX means (10 + 10 + 10 =) 30, and MLXVI means (1000 + 50 + 10 + 5 + 1 =) 1066. You simply count and add. Yes, there are special rules for subtractive shorthand, but forget about those for a moment. If you have a Roman numeral with symbols in strictly descending order, you can simply add the symbol values together.

You can express this with FsCheck. It looks a little daunting, but actually isn't that bad. I'll show it first, and then walk you through it:

[<Property(QuietOnSuccess = true)>]
let ``symbols in descending order are additive`` () =
    let stringRepeat char count = String (char, count)
    let genSymbols count symbol =
        [0..count] |> List.map (stringRepeat symbol) |> Gen.elements
    let thousands =    genSymbols 3 'M'
    let fiveHundreds = genSymbols 1 'D'
    let hundreds =     genSymbols 3 'C'
    let fifties =      genSymbols 1 'L'
    let tens =         genSymbols 3 'X'
    let fives =        genSymbols 1 'V'
    let ones =         genSymbols 3 'I'
    let symbols = 
        [thousands; fiveHundreds; hundreds; fifties; tens; fives; ones]
        |> Gen.sequence
        |> Gen.map String.Concat
        |> Arb.fromGen
    Prop.forAll symbols <| fun s ->
 
        let actual = Numeral.tryParseRoman s
        
        let expected =
            s
            |> Seq.map (string >> Numeral.tryParseRoman)
            |> Seq.choose id
            |> Seq.sum
            |> Some            
        expected =! actual

The first two lines are two utility functions. The function stringRepeat has the type char -> int -> string. It simply provides a curried form of the String constructor overload that enables you to repeat a particular char value. As an example, stringRepeat 'I' 0 is "", stringRepeat 'X' 2 is "XX", and so on.

The function genSymbols has the type int -> char -> Gen<string>. It returns a generator that produces a repeated string no longer than the specified length. Thus, genSymbols 3 'M' is a generator that draws random values from the set [""; "M"; "MM"; "MMM"], genSymbols 1 'D' is a generator that draws random values from the set [""; "D"], and so on. Notice that the empty string is one of the values that the generator may use. This is by design.

Using genSymbols, you can define generators for all the symbols: up to three thousands, up to one five hundreds, up to three hundreds, etc. thousands, fiveHundreds, hundreds, and so on, are all values of the type Gen<string>.

You can combine all these string generators to a single generator using Gen.sequence, which takes a seq<Gen<'a>> as input and returns a Gen<'a list>. In this case, the input is [thousands; fiveHundreds; hundreds; fifties; tens; fives; ones], which has the type Gen<string> list, so the output is a Gen<string list> value. Values generated could include ["MM"; ""; ""; ""; "X"; ""; ""], [""; "D"; "CC"; "L"; "X"; "V"; ""], and so on.

Instead of lists of strings, you need single string values. These are easy to create using the built-in method String.Concat. You have to do it within a Gen value, though, so it's Gen.map String.Concat. Finally, you can convert the resulting Gen<string> to an Arbitrary using Arb.fromGen. The final symbols value has the type Arbitrary<string>. It'll generate values such as "MMX" and "DCCLXV".

This is a bit of work to ensure that proper Roman numerals are generated, but the rest of the property is tractable. You can use FsCheck's Prop.forAll to express the property that when tryParseRoman is called with any of the generated numerals, the return value is equal to the expected value.

The expected value is the sum of the value of each of the symbols in the input string, s. The string type implements the interface char seq, so you can map each of the characters by invoking tryParseRoman. That gives you a seq<int option>, because tryParseRoman returns int option values. You can use Seq.choose id to throw away any None values there may be, and then Seq.sum to calculate the sum of the integers. Finally, you can pipe the sum into the Some case constructor to turn expected into an int option, which matches the type of actual.

Now that you have expected and actual values, you can assert that these two values must be equal to each other. This property states that for all strictly descending numerals, the return value must be the sum of the constituent symbols.

Subtractiveness #

The principal rule for Roman numerals is that of additivity, but if you only apply the above rules, you'd allow numerals such as IIII for 4, LXXXX for 90, etc. While there's historical precedent for such notation, it's not allowed in 'modern' Roman numerals. If there are more than three repeated characters, you should instead prefer subtractive notation: IV for 4, XC for 90, and so on.

Subtractive notation is, however, only allowed within adjacent groups. Logically, you could write 1999 as MIM, but this isn't allowed. The symbol I can only be used to subtract from V and X, X can only subtract from L and C, and C can only subtract from D and M.

Within these constraints, you have to describe the property of subtractive notation. Here's one way to do it:

type OptionBuilder() =
    member this.Bind(v, f) = Option.bind f v
    member this.Return v = Some v
 
let opt = OptionBuilder()
 
[<Property(QuietOnSuccess = true)>]
let ``certain symbols in ascending are subtractive`` () =
    let subtractive (subtrahend : char) (minuends : string) = gen {
        let! minuend = Gen.elements minuends
        return subtrahend, minuend }
    let symbols = 
        Gen.oneof [
            subtractive 'I' "VX"
            subtractive 'X' "LC"
            subtractive 'C' "DM" ]
        |> Arb.fromGen
    Prop.forAll symbols <| fun (subtrahend, minuend) ->
        let originalRoman = String [| subtrahend; minuend |]
 
        let actual = Numeral.tryParseRoman originalRoman
        let roundTrippedRoman = actual |> Option.bind Numeral.toRoman
 
        let expected = opt {
            let! m = Numeral.tryParseRoman (string minuend)
            let! s = Numeral.tryParseRoman (string subtrahend)
            return m - s }
        expected =! actual
        Some originalRoman =! roundTrippedRoman

Like the previous property, this looks like a mouthful, but isn't too bad. I'll walk you through it.

Initially, ignore the OptionBuilder type and the opt value; we'll return to them shortly. The property itself starts by defining a function called subtractive, which has the type char -> string -> Gen<char * char>. The first argument is a symbol representing the subtrahend; that is: the number being subtracted. The next argument is a sequence of minuends; that is: numbers from which the subtrahend will be subtracted.

The subtractive function is implemented with a gen computation expression. It first uses a let! binding to define that a singular minuend is a random value drawn from minuends. As usual, Gen.elements is the workhorse: it defines a generator that randomly draws from a sequence of values, and because minuends is a string, and the string type implements char seq, it can be used with Gen.elements to define a generator of char values. While Gen.elements minuends returns a Gen<char> value, the use of a let! binding within a computation expression causes minuend to have the type char.

The second line of code in subtractive returns a tuple of two char values: the subtrahend first, and the minuend second. Normally, when subtracting with the arithmetic minus operator, you'd write a difference as minuend - subtrahend; the minuends comes first, followed by the subtrahend. The Roman subtractive notation, however, is written with the subtrahend before the minuend, which is the reason that the subtractive function returns the symbols in that order. It's easier to think about that way.

The subtractive function enables you to define generators of Roman numerals using subtractive notation. Since I can only be used before V and X, you can define a generator using subtractive 'I' "VX". This is a Gen<char * char> value. Likewise, you can define subtractive 'X' "LC" and subtractive 'C' "DM" and use Gen.oneOf to define a generator that randomly selects one of these generators, and uses the selected generator to produce a value. As always, the last step is to convert the generator into an Arbitrary with Arb.fromGen, so that symbols has the type Arbitrary<char * char>.

Equipped with an Arbitrary, you can again use Prop.forAll to express the desired property. First, originalRoman is created from the subtrahend and minuend. Due to the way symbols is defined, originalRoman will have values like "IV", "XC", and so on.

The property then proceeds to invoke tryParseRoman. It also uses the actual value to produce a round-tripped value. Not only should the parser correctly understand subtractive notation, but the integer-to-Roman conversion should also prefer this notation.

The last part of the property is the assertion. Here, you need opt, which is a computation builder for option values.

In the assertion, you need to calculate the expected value. Both minuend and subtrahend are char values; in order to find their corresponding decimal values, you'll need to call tryParseRoman. The problem is that tryParseRoman returns an int option. For example, tryParseRoman "I" returns Some 1, so you may need to subtract Some 1 from Some 5. The most readable way I've found is to use a computation expression. Using let! bindings, both m and s are int values, which you can easily subtract using the normal - operator.

expected and actual are both int option values, so can be compared using Unquote's must equal operator.

Finally, the property also asserts that the original value must be equal to the round-tripped value. If not, you could have an implementation that correctly parses "IV" as 4, but converts 4 to "IIII".

Limited repetition #

The previous property only ensures that subtractive notation is used in simple cases, like IX or CD. It doesn't verify that composite numerals are correctly written. As an example, the converter should convert 1893 to MDCCCXCIII, not MDCCCLXXXXIII. The second alternative is incorrect because it uses LXXXX to represent 90, instead of XC.

The underlying property is that any given symbol can only be repeated at most three times. A symbol can appear more than thrice in total, as demonstrated by the valid numeral MDCCCXCIII, in which C appears four times. For any group of repeated characters, however, a character must only be repeated once, twice, or thrice.

This also explain why the maximum Roman numeral is MMMCMXCIX, or 3,999.

In order to express this property in code, you first need a function to group characters. Here, I've chosen to reuse one of my own creation:

// seq<'a> -> 'a list list when 'a : equality
let group xs =
    let folder x = function
        | [] -> [[x]]
        | (h::t)::ta when h = x -> (x::h::t)::ta
        | acc -> [x]::acc
    Seq.foldBack folder xs []

This function will, for example, group "MDCCCXCIII" like this:

> "MDCCCXCIII" |> group;;
val it : char list list =
  [['M']; ['D']; ['C'; 'C'; 'C']; ['X']; ['C']; ['I'; 'I'; 'I']]

All you need to do is to find the length of all such sub-lists, and assert that the maximum is at most 3:

[<Property(QuietOnSuccess = true)>]
let ``there can be no more than three identical symbols in a row`` () =
    Prop.forAll romanRange <| fun i ->
 
        let actual = Numeral.toRoman i
        
        test <@ actual
                |> Option.map (group >> (List.map List.length) >> List.max)
                |> Option.exists (fun x -> x <= 3) @>

Since actual is a string option, you need to express the assertion within the Maybe (Option) monad. First, you can use Option.map to map any value (should there be one) to find the maximum length of any repeated character group. This returns an int option.

Finally, you can pipe that int option into Option.exists, which will evaluate to false if there's no value, or if the boolean expression x <= 3 evaluates to false.

Input range #

At this point, you're almost done. The only remaining properties you'll need to specify is that the maximum value is 3,999, and the minimum value is 1. Negative numbers, or zero, are not allowed:

[<Property(QuietOnSuccess = true)>]
let ``negative numbers and zero are not supported`` i =
    let i = -(abs i)
    let actual = Numeral.toRoman i
    test <@ Option.isNone actual @>

In this property, the function argument i can be any number, but calling abs ensures that it's positive (or zero), and the unary - operator then converts that positive value to a negative value.

Notice that the new i value shadows the input argument of the same name. This is a common trick when writing properties. It prevents me from accidentally using the input value provided by FsCheck. While the input argument is useful as a seed value, it isn't guaranteed to model the particular circumstances of this property. Here, you only care to assert what happens if the input is negative or zero. Specifically, you always want the return value to be None.

Likewise for too large input values:

[<Property(QuietOnSuccess = true)>]
let ``numbers too big are not supported`` () =
    Gen.choose (4000, Int32.MaxValue) |> Arb.fromGen |> Prop.forAll <| fun i ->
        let actual = Numeral.toRoman i
        test <@ Option.isNone actual @>

Here, Gen.choose is used to define an Arbitrary<int> that only produces numbers between 4000 and Int32.MaxValue (including both boundary values).

This test is similar to the one that exercises negative values, so you could combine them to a single function if you'd like. I'll leave this as an exercise, though.

Implementation #

The interesting part of this exercise is, I think, how to define the properties. There are many ways you can implement the functions to pass all properties. Here's one of them:

open System
 
let tryParseRoman candidate = 
    let add x = Option.map ((+) x)
    let rec imp acc = function
        | 'I'::'X'::xs -> imp (acc |> add    9) xs
        | 'I'::'V'::xs -> imp (acc |> add    4) xs        
        | 'I'::xs      -> imp (acc |> add    1) xs
        | 'V'::xs      -> imp (acc |> add    5) xs
        | 'X'::'C'::xs -> imp (acc |> add   90) xs
        | 'X'::'L'::xs -> imp (acc |> add   40) xs        
        | 'X'::xs      -> imp (acc |> add   10) xs
        | 'L'::xs      -> imp (acc |> add   50) xs
        | 'C'::'M'::xs -> imp (acc |> add  900) xs
        | 'C'::'D'::xs -> imp (acc |> add  400) xs        
        | 'C'::xs      -> imp (acc |> add  100) xs
        | 'D'::xs      -> imp (acc |> add  500) xs
        | 'M'::xs      -> imp (acc |> add 1000) xs
        | []           -> acc
        | _            -> None
    candidate |> Seq.toList |> imp (Some 0)
 
let toRoman i =
    let rec imp acc = function
        | x when x >= 1000 -> imp ('M'::     acc) (x - 1000)
        | x when x >=  900 -> imp ('M'::'C'::acc) (x -  900)
        | x when x >=  500 -> imp ('D'::     acc) (x -  500)
        | x when x >=  400 -> imp ('D'::'C'::acc) (x -  400)
        | x when x >=  100 -> imp ('C'::     acc) (x -  100)
        | x when x >=   90 -> imp ('C'::'X'::acc) (x -   90)
        | x when x >=   50 -> imp ('L'::     acc) (x -   50)
        | x when x >=   40 -> imp ('L'::'X'::acc) (x -   40)
        | x when x >=   10 -> imp ('X'::     acc) (x -   10)
        | x when x >=    9 -> imp ('X'::'I'::acc) (x -    9)
        | x when x >=    5 -> imp ('V'::     acc) (x -    5)
        | x when x >=    4 -> imp ('V'::'I'::acc) (x -    4)
        | x when x >=    1 -> imp ('I'::     acc) (x -    1)
        | _                -> acc
    if 0 < i && i < 4000
    then imp [] i |> List.rev |> List.toArray |> String |> Some
    else None

Both functions use tail-recursive inner imp functions in order to accumulate the appropriate answer.

One of the nice properties (that I didn't test for) of this implementation is that the tryParseRoman function is a Tolerant Reader. While toRoman would never create such a numeral, tryParseRoman correctly understands some alternative renderings:

> "MDCCCLXXXXIII" |> tryParseRoman;;
val it : int option = Some 1893
> 1893 |> toRoman;;
val it : String option = Some "MDCCCXCIII"

In other words, the implementation follows Postel's law. tryParseRoman is liberal in what it accepts, while toRoman is conservative in what it returns.

Summary #

Some problems look, at first glance, as obvious candidates for example-driven development. In my experience, this particularly happen when obvious examples abound. It's not difficult to come up with examples of Roman numerals, so it seems intuitive that you should just start writing some test cases with various examples. In my experience, though, that doesn't guarantee that you're led towards a good implementation.

The more a problem description is based on examples, the harder it can be to identify the underlying properties. Still, they're often there, once you start looking. As I've previously reported, using property-based test-driven development enables you to proceed in a more incremental fashion, because properties describe only parts of the desired solution.

If you're interested in learning more about Property-Based Testing, you can watch my introduction to Property-based Testing with F# Pluralsight course.

While it's possible to rely on Extract and Override for unit testing, Dependency Injection can make code and tests simpler and easier to maintain.

In object-oriented programming, many people still struggle with the intersection of design and testability. If a unit test is an automated test of a unit in isolation of its dependencies, then how do you isolate an object from its dependencies, most notably databases, web services, and the like?

One technique, described in The Art of Unit Testing, is called Extract and Override. The idea is that you write a class, but use a Template Method, Factory Method, or other sort of virtual class method to expose extensibility points that a unit test can use to achieve the desired isolation.

People sometimes ask me whether that isn't good enough, and why I advocate the (ostensibly) more complex technique of Dependency Injection?

It's easiest to understand the advantages and disadvantages if we have an example to discuss.

Example: Extract and Override #

Imagine that you're creating a reservation system for a restaurant. Clients (web sites, smart phone apps, etcetera) display a user interface where you can fill in details about your reservation: your name, email address, the number of guests, and the date of your reservation. When you submit your reservation request, the client POSTs a JSON document to a web service.

In this example, the web service is implemented by a Controller class, and the Post method handles the incoming request:

public int Capacity { get; }
 
public IHttpActionResult Post(ReservationDto reservationDto)
{
    DateTime requestedDate;
    if(!DateTime.TryParse(reservationDto.Date, out requestedDate))
        return this.BadRequest("Invalid date.");
 
    var reservedSeats = this.ReadReservedSeats(requestedDate);
    if(this.Capacity < reservationDto.Quantity + reservedSeats)
        return this.StatusCode(HttpStatusCode.Forbidden);
 
    this.SaveReservation(requestedDate, reservationDto);
 
    return this.Ok();
}

The implementation is simple: It first attempts to validate the incoming document, and returns an error message if the document is invalid. Second, it reads the number of already reserved seats via a helper method, and rejects the request if the remaining capacity is insufficient. On the other hand, if the remaining capacity is sufficient, it saves the reservation and returns 200 OK.

The Post method relies on two helper methods that handles communication with the database:

public virtual int ReadReservedSeats(DateTime date)
{
    const string sql = @"
        SELECT COALESCE(SUM([Quantity]), 0) FROM [dbo].[Reservations]
        WHERE YEAR([Date]) = YEAR(@Date)
        AND MONTH([Date]) = MONTH(@Date)
        AND DAY([Date]) = DAY(@Date)";
 
    var connStr = ConfigurationManager.ConnectionStrings["booking"]
        .ConnectionString;
 
    using (var conn = new SqlConnection(connStr))
    using (var cmd = new SqlCommand(sql, conn))
    {
        cmd.Parameters.Add(new SqlParameter("@Date", date));
 
        conn.Open();
        return (int)cmd.ExecuteScalar();
    }
}
 
public virtual void SaveReservation(
    DateTime dateTime,
    ReservationDto reservationDto)
{
    const string sql = @"
        INSERT INTO [dbo].[Reservations] ([Date], [Name], [Email], [Quantity])
        VALUES (@Date, @Name, @Email, @Quantity)";
 
    var connStr = ConfigurationManager.ConnectionStrings["booking"]
        .ConnectionString;
 
    using (var conn = new SqlConnection(connStr))
    using (var cmd = new SqlCommand(sql, conn))
    {
        cmd.Parameters.Add(
            new SqlParameter("@Date", reservationDto.Date));
        cmd.Parameters.Add(
            new SqlParameter("@Name", reservationDto.Name));
        cmd.Parameters.Add(
            new SqlParameter("@Email", reservationDto.Email));
        cmd.Parameters.Add(
            new SqlParameter("@Quantity", reservationDto.Quantity));
 
        conn.Open();
        cmd.ExecuteNonQuery();
    }
}

In this example, both helper methods are public, but they could have been protected without changing any conclusions; by being public, though, they're easier to override using Moq. The important detail is that both of these methods are overridable. In C#, you declare that with the virtual keyword; in Java, methods are overridable by default.

Both of these methods use elemental ADO.NET to communicate with the database. You can also use an ORM, or any other database access technique you prefer - it doesn't matter for this discussion. What matters is that the methods can be overridden by unit tests.

Here's a unit test of the happy path:

[Fact]
public void PostReturnsCorrectResultAndHasCorrectStateOnAcceptableRequest()
{
    var json =
            new ReservationDto
            {
                Date = "2016-05-31",
                Name = "Mark Seemann",
                Email = "mark@example.com",
                Quantity = 1
            };
    var sut = new Mock<ReservationsController> { CallBase = true };
    sut
        .Setup(s => s.ReadReservedSeats(new DateTime(2016, 5, 31)))
        .Returns(0);
    sut
        .Setup(s => s.SaveReservation(new DateTime(2016, 5, 31), json))
        .Verifiable();
            
    var actual = sut.Object.Post(json);
 
    Assert.IsAssignableFrom<OkResult>(actual);
    sut.Verify();
}

This example uses the Extract and Override technique, but instead of creating a test-specific class that derives from ReservationsController, it uses Moq to create a dynamic Test Double for the System Under Test (SUT) - a SUT Double.

Since both ReadReservedSeats and SaveReservation are virtual, Moq can override them with test-specific behaviour. In this test, it defines the behaviour of ReadReservedSeats in such a way that it returns 0 when the input is a particular date.

While the test is simple, it has a single blemish. It ought to follow the Arrange Act Assert pattern, so it shouldn't have to configure the SaveReservation method before it calls the Post method. After all, the SaveReservation method is a Command, and you should use Mocks for Commands. In other words, the test ought to verify the interaction with the SaveReservation method in the Assert phase; not configure it in the Arrange phase.

Unfortunately, if you don't configure the SaveReservation method before calling Post, Moq will use the base implementation, which will attempt to interact with the database. The database isn't available in the unit test context, so without that override, the base method will throw an exception, causing the test to fail.

Still, that's a minor issue. In general, the test is easy to follow, and the design of the ReservationsController class itself is also straightforward. Are there any downsides?

Example: shared connection #

From a design perspective, the above version is fine, but you may find it inefficient that ReadReservedSeats and SaveReservation both open and close a connection to the database. Wouldn't it be more efficient if they could share a single connection?

If (by measuring) you decide that you'd like to refactor the ReservationsController class to use a shared connection, your first attempt might look like this:

public IHttpActionResult Post(ReservationDto reservationDto)
{
    DateTime requestedDate;
    if (!DateTime.TryParse(reservationDto.Date, out requestedDate))
        return this.BadRequest("Invalid date.");
 
    using (var conn = this.OpenDbConnection())
    {
        var reservedSeats = this.ReadReservedSeats(conn, requestedDate);
        if (this.Capacity < reservationDto.Quantity + reservedSeats)
            return this.StatusCode(HttpStatusCode.Forbidden);
 
        this.SaveReservation(conn, requestedDate, reservationDto);
 
        return this.Ok();
    }
}
 
public virtual SqlConnection OpenDbConnection()
{
    var connStr = ConfigurationManager.ConnectionStrings["booking"]
        .ConnectionString;
 
    var conn = new SqlConnection(connStr);
    try
    {
        conn.Open();
    }
    catch
    {
        conn.Dispose();
        throw;
    }
    return conn;
}
 
public virtual int ReadReservedSeats(SqlConnection conn, DateTime date)
{
    const string sql = @"
        SELECT COALESCE(SUM([Quantity]), 0) FROM [dbo].[Reservations]
        WHERE YEAR([Date]) = YEAR(@Date)
        AND MONTH([Date]) = MONTH(@Date)
        AND DAY([Date]) = DAY(@Date)";
 
    using (var cmd = new SqlCommand(sql, conn))
    {
        cmd.Parameters.Add(new SqlParameter("@Date", date));
 
        return (int)cmd.ExecuteScalar();
    }
}
 
public virtual void SaveReservation(
    SqlConnection conn,
    DateTime dateTime,
    ReservationDto reservationDto)
{
    const string sql = @"
        INSERT INTO [dbo].[Reservations] ([Date], [Name], [Email], [Quantity])
        VALUES (@Date, @Name, @Email, @Quantity)";
 
    using (var cmd = new SqlCommand(sql, conn))
    {
        cmd.Parameters.Add(
            new SqlParameter("@Date", reservationDto.Date));
        cmd.Parameters.Add(
            new SqlParameter("@Name", reservationDto.Name));
        cmd.Parameters.Add(
            new SqlParameter("@Email", reservationDto.Email));
        cmd.Parameters.Add(
            new SqlParameter("@Quantity", reservationDto.Quantity));
 
        cmd.ExecuteNonQuery();
    }
}

You've changed both ReadReservedSeats and SaveReservation to take an extra parameter: the connection to the database. That connection is created by the OpenDbConnection method, but you also have to make that method overridable, because otherwise, it'd attempt to connect to a database during unit testing, and thereby causing the tests to fail.

You can still unit test using the Extract and Overide technique, but the test becomes more complicated:

[Fact]
public void PostReturnsCorrectResultAndHasCorrectStateOnAcceptableRequest()
{
    var json =
            new ReservationDto
            {
                Date = "2016-05-31",
                Name = "Mark Seemann",
                Email = "mark@example.com",
                Quantity = 1
            };
    var sut = new Mock<ReservationsController> { CallBase = true };
    sut.Setup(s => s.OpenDbConnection()).Returns((SqlConnection)null);
    sut
        .Setup(s => s.ReadReservedSeats(
            It.IsAny<SqlConnection>(),
            new DateTime(2016, 5, 31)))
        .Returns(0);
    sut
        .Setup(s => s.SaveReservation(
            It.IsAny<SqlConnection>(),
            new DateTime(2016, 5, 31), json))
        .Verifiable();
            
    var actual = sut.Object.Post(json);
 
    Assert.IsAssignableFrom<OkResult>(actual);
    sut.Verify();
}

Not only must you override ReadReservedSeats and SaveReservation, but you must also supply a Dummy Object for the connection object, as well as override OpenDbConnection. Still manageable, perhaps, but the design indisputably deteriorated.

You can summarise the flaw by a single design smell: Feature Envy. Both the ReadReservedSeats and the SaveReservation methods take an argument of the type SqlConnection. On the other hand, they don't use any instance members of the ReservationsController class that currently hosts them. These methods seem like they ought to belong to SqlConnection instead of ReservationsController. That's not possible, however, since SqlConnection is a class from the Base Class Library, but you can, instead, create a new Repository class.

Example: Repository #

A common design pattern is the Repository pattern, although the way it's commonly implemented today has diverged somewhat from the original description in PoEAA. Here, I'm going to apply it like people often do. You start by defining a new class:

public class SqlReservationsRepository : IDisposable
{
    private readonly Lazy<SqlConnection> lazyConn;
 
    public SqlReservationsRepository()
    {
        this.lazyConn = new Lazy<SqlConnection>(this.OpenSqlConnection);
    }
 
    private SqlConnection OpenSqlConnection()
    {
        var connStr = ConfigurationManager.ConnectionStrings["booking"]
            .ConnectionString;
 
        var conn = new SqlConnection(connStr);
        try
        {
            conn.Open();
        }
        catch
        {
            conn.Dispose();
            throw;
        }
        return conn;
    }
 
    public virtual int ReadReservedSeats(DateTime date)
    {
        const string sql = @"
            SELECT COALESCE(SUM([Quantity]), 0) FROM [dbo].[Reservations]
            WHERE YEAR([Date]) = YEAR(@Date)
            AND MONTH([Date]) = MONTH(@Date)
            AND DAY([Date]) = DAY(@Date)";
 
        using (var cmd = new SqlCommand(sql, this.lazyConn.Value))
        {
            cmd.Parameters.Add(new SqlParameter("@Date", date));
 
            return (int)cmd.ExecuteScalar();
        }
    }
 
    public virtual void SaveReservation(
        DateTime dateTime,
        ReservationDto reservationDto)
    {
        const string sql = @"
            INSERT INTO [dbo].[Reservations] ([Date], [Name], [Email], [Quantity])
            VALUES (@Date, @Name, @Email, @Quantity)";
 
        using (var cmd = new SqlCommand(sql, this.lazyConn.Value))
        {
            cmd.Parameters.Add(
                new SqlParameter("@Date", reservationDto.Date));
            cmd.Parameters.Add(
                new SqlParameter("@Name", reservationDto.Name));
            cmd.Parameters.Add(
                new SqlParameter("@Email", reservationDto.Email));
            cmd.Parameters.Add(
                new SqlParameter("@Quantity", reservationDto.Quantity));
 
            cmd.ExecuteNonQuery();
        }
    }
 
    public void Dispose()
    {
        this.Dispose(true);
        GC.SuppressFinalize(this);
    }
 
    protected virtual void Dispose(bool disposing)
    {
        if (disposing)
            this.lazyConn.Value.Dispose();
    }
}

The new SqlReservationsRepository class contains the two ReadReservedSeats and SaveReservation methods, and because you've now moved them to a class that contains a shared database connection, the methods don't need the connection as a parameter.

The ReservationsController can use the new SqlReservationsRepository class to do its work, while keeping connection management efficient. In order to make it testable, however, you must make it overridable. The SqlReservationsRepository class' methods are already virtual, but that's not the class you're testing. The System Under Test is the ReservationsController class, and you have to make its use of SqlReservationsRepository overridable as well.

If you wish to avoid Dependency Injection, you can use a Factory Method:

public IHttpActionResult Post(ReservationDto reservationDto)
{
    DateTime requestedDate;
    if (!DateTime.TryParse(reservationDto.Date, out requestedDate))
        return this.BadRequest("Invalid date.");
 
    using (var repo = this.CreateRepository())
    {
        var reservedSeats = repo.ReadReservedSeats(requestedDate);
        if (this.Capacity < reservationDto.Quantity + reservedSeats)
            return this.StatusCode(HttpStatusCode.Forbidden);
 
        repo.SaveReservation(requestedDate, reservationDto);
 
        return this.Ok();
    }
}
        
public virtual SqlReservationsRepository CreateRepository()
{
    return new SqlReservationsRepository();
}

The Factory Method in the above example is the CreateRepository method, which is virtual, and thereby overridable. You can override it in a unit test like this:

[Fact]
public void PostReturnsCorrectResultAndHasCorrectStateOnAcceptableRequest()
{
    var json =
            new ReservationDto
            {
                Date = "2016-05-31",
                Name = "Mark Seemann",
                Email = "mark@example.com",
                Quantity = 1
            };
    var repo = new Mock<SqlReservationsRepository>();
    repo
        .Setup(r => r.ReadReservedSeats(new DateTime(2016, 5, 31)))
        .Returns(0);
    repo
        .Setup(r => r.SaveReservation(new DateTime(2016, 5, 31), json))
        .Verifiable();
    var sut = new Mock<ReservationsController> { CallBase = true };
    sut.Setup(s => s.CreateRepository()).Returns(repo.Object);
 
    var actual = sut.Object.Post(json);
 
    Assert.IsAssignableFrom<OkResult>(actual);
    repo.Verify();
}

You'll notice that not only did the complexity increase of the System Under Test, but the test itself became more complicated as well. In the previous version, at least you only needed to create a single Mock<T>, but now you have to create two different test doubles and connect them. This is a typical example demonstrating the shortcomings of the Extract and Override technique. It doesn't scale well as complexity increases.

Example: Dependency Injection #

In 1994 we we were taught to favor object composition over class inheritance. You can do that, and still keep your code loosely coupled with Dependency Injection. Instead of relying on virtual methods, inject a polymorphic object into the class:

public class ReservationsController : ApiController
{
    public ReservationsController(IReservationsRepository repository)
    {
        if (repository == null)
            throw new ArgumentNullException(nameof(repository));
 
        this.Capacity = 12;
        this.Repository = repository;
    }
 
    public int Capacity { get; }
 
    public IReservationsRepository Repository { get; }
 
    public IHttpActionResult Post(ReservationDto reservationDto)
    {
        DateTime requestedDate;
        if (!DateTime.TryParse(reservationDto.Date, out requestedDate))
            return this.BadRequest("Invalid date.");
 
        var reservedSeats =
            this.Repository.ReadReservedSeats(requestedDate);
        if (this.Capacity < reservationDto.Quantity + reservedSeats)
            return this.StatusCode(HttpStatusCode.Forbidden);
 
        this.Repository.SaveReservation(requestedDate, reservationDto);
 
        return this.Ok();
    }
}

In this version of ReservationsController, an IReservationsRepository object is injected into the object via the constructor and saved in a class field for later use. When the Post method executes, it calls Repository.ReadReservedSeats and Repository.SaveReservation without further ado.

The IReservationsRepository interface is defined like this:

public interface IReservationsRepository
{
    int ReadReservedSeats(DateTime date);
    void SaveReservation(DateTime dateTime, ReservationDto reservationDto);
}

Perhaps you're surprised to see that it merely defines the two ReadReservedSeats and SaveReservation methods, but makes no attempt at making the interface disposable.

Not only is IDisposable an implementation detail, but it also keeps the implementation of ReservationsController simple. Notice how it doesn't attempt to control the lifetime of the injected repository, which may or may not be disposable. In a few paragraphs, we'll return to this matter, but first, witness how the unit test became simpler as well:

[Fact]
public void PostReturnsCorrectResultAndHasCorrectStateOnAcceptableRequest()
{
    var json =
            new ReservationDto
            {
                Date = "2016-05-31",
                Name = "Mark Seemann",
                Email = "mark@example.com",
                Quantity = 1
            };
    var repo = new Mock<IReservationsRepository>();
    repo
        .Setup(r => r.ReadReservedSeats(new DateTime(2016, 5, 31)))
        .Returns(0);
    var sut = new ReservationsController(repo.Object);
 
    var actual = sut.Post(json);
 
    Assert.IsAssignableFrom<OkResult>(actual);
    repo.Verify(
        r => r.SaveReservation(new DateTime(2016, 5, 31), json));
}

With this test, you can finally use the Arrange Act Assert structure, instead of having to configure the SaveReservation method call in the Arrange phase. This test arranges the Test Fixture by creating a Test Double for the IReservationsRepository interface and injecting it into the ReservationsController. You only need to configure the ReadReservedSeats method, because there's no default behaviour that you need to suppress.

You may be wondering about the potential memory leak when the SqlReservationsRepository is in use. After all, ReservationsController doesn't dispose of the injected repository.

You address this concern when you compose the dependency graph. This example uses ASP.NET Web API, which has an extensibility point for this exact purpose:

public class PureCompositionRoot : IHttpControllerActivator
{
    public IHttpController Create(
        HttpRequestMessage request,
        HttpControllerDescriptor controllerDescriptor,
        Type controllerType)
    {
        if(controllerType == typeof(ReservationsController))
        {
            var repo = new SqlReservationsRepository();
            request.RegisterForDispose(repo);
            return new ReservationsController(repo);
        }
 
        throw new ArgumentException(
            "Unexpected controller type: " + controllerType,
            nameof(controllerType));
    }
}

The call to request.RegisterForDispose tells the ASP.NET Web API framework to dispose of the concrete repo object once it has handled the request and served the response.

Conclusion #

At first glance, it seems like the overall design would be easier if you make your SUT testable via inheritance, but once things become more complex, favouring composition over inheritance gives you more freedom to design according to well-known design patterns.

In case you want to dive into the details of the code presented here, it's available on GitHub. You can follow the progression of the code in the repository's commit history.

If you're interested in learning more about advanced unit testing techniques, you can watch my popular Pluralsight course.

Use the F# TIE fighter operator combination to eliminate a hard-to-name intermediary value.

A doctrine of Clean Code is the Boy Scout Rule: leave the code cleaner than you found it. Attempting to live by that rule, I'm always looking for ways to improve my code.

Writing properties with FsCheck is enjoyable, but I've been struggling with expressing ad-hoc Arbitraries in a clean style. Although I've already twice written about this, I've recently found another improvement.

Cleaner, but not clean enough #

Previously, I've described how you can use the backward pipe operator to avoid enclosing a multi-line expression in brackets:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    let nc = Gen.elements [4..8] |> Arb.fromGen
    Prop.forAll nc <| fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual

This property uses the custom Arbitrary nc to express a property about Conway's Game of Life. The value nc is a Arbitrary<int>, which is a generator of integer values between 4 and 8 (both included).

There's a problem with that code, though: I don't care about nc; I care about the values it creates. That's the important value in my property, and this is the reason I reserved the descriptive name neighborCount for that role. The property cares about the neighbour count: for any neighbour count in the range 4-8, it should hold that blah blah blah, and so on...

Unfortunately, I was still left with the need to pass an Arbitrary<'a> to Prop.forAll, so I named it the best I could: nc (short for Neighbour Count). Following Clean Code's heuristics for short symbol scope, I considered it an acceptable name, albeit a bit cryptic.

TIE Fighters to the rescue! #

One day, I was looking at a property like the one above, and I thought: if you consider the expression Prop.forAll nc in isolation, you could also write it nc |> Prop.forAll. Does it work in this context? Yes it does:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    let nc = Gen.elements [4..8] |> Arb.fromGen
    (nc |> Prop.forAll) <| fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual

This code compiles, and is equivalent to the first example. I deliberately put the expression nc |> Prop.forAll in brackets to be sure that I'd made a correct replacement. Pipes are left-associative, though, so in this case, the brackets are redundant:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    let nc = Gen.elements [4..8] |> Arb.fromGen
    nc |> Prop.forAll <| fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual

This still works (and fails if the system under test has a defect).

Due to referential transparency, though, the value nc is equal to the expression Gen.elements [4..8] |> Arb.fromGen, so you can replace it:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    Gen.elements [4..8]
    |> Arb.fromGen
    |> Prop.forAll <| fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual

In the above example, I've also slightly reformatted the expression, so that each expression composed with a forward pipe is on a separate line. That's not required, but I find it more readable.

Notice how Prop.forAll is now surrounded by pipes: |> Prop.forAll <|. This is humorously called TIE fighter infix.

Summary #

Sometimes, giving an intermediary value a descriptive name can improve code readability, but in other cases, such a value is only in the way. This was the case with the nc value in the first example above. Using TIE fighter infix notation enables you to get rid of a redundant, hard-to-name symbol. In my opinion, because nc didn't add any information to the code, I find the refactored version easier to read. I've left the code base cleaner than I found it.

Is it a violation of Command Query Separation to update an ID property when saving an Entity to a database?

In my Encapsulation and SOLID course on Pluralsight, I explain how the elusive object-oriented quality encapsulation can be approximated by the actionable principles of Command Query Separation (CQS) and Postel's law.

One of the questions that invariably arise when people first learn about CQS is how to deal with (database) server-generated IDs. While I've already covered that question, I recently came upon a variation of the question:

"The Create method is a command, then if the object passed to this method have some changes in their property, does it violate any rule? I mean that we can always get the new id from the object itself, so we don't need to return another integer. Is it good or bad practice?"

Returning an ID by mutating input #

I interpret the question like this: an Entity (as described in DDD) can have a mutable Id property. A Create method could save the Entity in a database, and then update the input value's Id property with the newly created record's ID.

As an example, consider this User class:

public class User
{
    public int Id { get; set; }
 
    public string FirstName { get; set; }
 
    public string LastName { get; set; }
}

In order to create a new User in your database, you could define an API like this:

public interface IUserRepository
{
    void Create(User user);
}

An implementation of IUserRepository based on a relational database could perform an INSERT into the appropriate database, get the ID of the created record, and update the User object's Id property.

This test snippet demonstrates that behaviour:

var u = new User { FirstName = "Jane", LastName = "Doe" };
Assert.Equal(0, u.Id);
 
repository.Create(u);
Assert.NotEqual(0, u.Id);

When you create the u object, by not assigning a value to the Id property, it will have the default value of 0. Only after the Create method returns does Id hold a proper value.

Evaluation #

Does this design adhere to CQS? Yes, it does. The Create method doesn't return a value, but rather changes the state of the system. Not only does it create a record in your database, but it also changes the state of the u object. Nowhere does CQS state that an operation can't change more than a single part of the system.

Is it good design, then? I don't think that it is.

First, the design violates another part of encapsulation: protection of invariants. The invariants of any Entity is that is has an ID. It is the single defining feature of Entities that they have enduring and stable identities. When you change the identity of an Entity, it's no longer the same Entity. Yet this design allows exactly that:

u.Id = 42;
// ...
u.Id = 1337;

Second, such a design puts considerable trust in the implicit protocol between any client and the implementation of IUserRepository. Not only must the Create method save the User object in a data store, but it must also update the Id.

What happens, though, if you replay the method call:

repository.Create(new User { FirstName = "Ada", LastName = "Poe" });
repository.Create(new User { FirstName = "Ada", LastName = "Poe" });

This will result in duplicated entries, because the repository can't detect whether this is a replay, or simply two new users with the same name. You may find this example contrived, but in these days of cloud-based storage, it's common to apply retry strategies to clients.

If you use one of the alternatives I previously outlined, you will not have this problem.

Invariants #

Even if you don't care about replays or duplicates, you should still consider the invariants of Entities. As a minimum, you shouldn't be able to change the ID of an Entity. For a class like User, it'll also make client developers' job easier if it can provide some useful guarantees. This is part of Postel's law applied: be conservative in what you send. In this case, at least guarantee that no values will be null. Thus, a better (but by no means perfect) User class could be:

public class User
{
    public User(int id)
    {
        if (id <= 0)
            throw new ArgumentOutOfRangeException(
                nameof(id),
                "The ID must be a (unique) positive value.");;
 
        this.Id = id;
        this.firstName = "";
        this.lastName = "";
    }
 
    public int Id { get; }
 
    private string firstName;        
    public string FirstName
    {
        get { return this.firstName; }
        set
        {
            if (value == null)
                throw new ArgumentNullException(nameof(value));
            this.firstName = value;
        }
    }
 
    private string lastName;
    public string LastName
    {
        get { return this.lastName; }
        set
        {
            if (value == null)
                throw new ArgumentNullException(nameof(value));
            this.lastName = value;
        }
    }
}

The constructor initialises all class fields, and ensure that Id is a positive integer. It can't ensure that the ID is unique, though - at least, not without querying the database, which would introduce other problems.

How do you create a new User object and save it in the database, then?

One option is this:

public interface IUserRepository
{
    void Create(string firstName, string lastName);
 
    User Read(int id);
 
    void Update(User user);
 
    void Delete(int id);
}

The Create method doesn't use the User class at all, because at this time, the Entity doesn't yet exist. It only exists once it has an ID, and in this scenario, this only happens once the database has stored it and assigned it an ID.

Other methods can still use the User class as either input or output, because once the Entity has an ID, its invariants are satisfied.

There are other problems with this design, though, so I still prefer the alternatives I originally sketched.

Conclusion #

Proper object-oriented design should, as a bare minimum, consider encapsulation. This includes protecting the invariants of objects. For Entities, it means that an Entity must always have a stable and enduring identity. Well-designed Entities guarantee that identity values are always present and immutable. This requirement tend to be at odds with most popular Object-Relational Mappers (ORM), which require that ID fields are externally assignable. In order to use ORMs, most programmers compromise on encapsulation, ending up with systems that are relational in nature, but far from object-oriented.

Comments

public interface IRepository<T>
{
    void Create(T item);
}

Haskell defines IO as an explicit context for handling effects. In F#, you can experiment with using Async as a surrogate.

As a reaction to my article on the relationship between Functional architecture and Ports and Adapters, Szymon Pobiega suggested on Twitter:

random idea: in c# “IO Int” translates to “Task<int>”. By consistently using this we can make type system help you even in c#

Async as an IO surrogate #

Functions in Haskell are, by default, pure. Whenever you need to do something impure, like querying a database or sending an email, you need to explicitly do this in an impure context: IO. Don't let the name IO mislead you: it's not only for input and output, but for all impure actions. As an example, random number generation is impure as well, because a function that returns a new value every time isn't pure. (There are ways to model random number generation with pure functions, but let's forget about that for now.)

F#, on the other hand, doesn't make the distinction between pure and impure functions in its type system, so nothing 'translates' from IO in Haskell into an equivalent type in F#. Still, it's worth looking into Szymon's suggestion.

In 2013, C# finally caught up with F#'s support for asynchronous work-flows, and since then, many IO-bound .NET APIs have gotten asynchronous versions. The underlying API for C#'s async/await support is the Task Parallel Library, which isn't particularly constrained to IO-bound operations. The use of async/await, however, makes most sense for IO-bound operations. It improves resource utilisation because it can free up threads while waiting for IO-bound operations to complete.

It seems to be a frequent observation that once you start using asynchronous operations, they tend to be 'infectious'. A common rule of thumb is async all the way. You can easily call synchronous methods from asynchronous methods, but it's harder the other way around.

This is similar to the distinction between pure and impure functions. You can call pure functions from impure functions, but not the other way around. If you call an impure function from a 'pure' function in F#, the caller also automatically becomes impure. In Haskell, it's not even possible; you can call a pure function from an IO context, but not the other way around.

In F#, Async<'a> is more idiomatic than using Task<T>. While Async<'a> doesn't translate directly to Haskell's IO either, it's worth experimenting with the analogy.

Async I/O #

In the previous Haskell example, communication with the database was implemented by functions returning IO:

getReservedSeatsFromDB :: ConnectionString -> ZonedTime -> IO Int

saveReservation :: ConnectionString -> Reservation -> IO ()

By applying the analogy of IO to Async<'a>, you can implement your F# data access module to return Async work-flows:

module SqlGateway =
    // string -> DateTimeOffset -> Async<int>
    let getReservedSeats connectionString (date : DateTimeOffset) =
        // ...
 
    // string -> Reservation -> Async<unit>
    let saveReservation connectionString (reservation : Reservation) =
        // ...

This makes it harder to compose the desired imp function, because you need to deal with both asynchronous work-flows and the Either monad. In Haskell, the building blocks are already there in the shape of the EitherT monad transformer. F# doesn't have monad transformers, but in the spirit of the previous article, you can define a computation expression that combines Either and Async:

type AsyncEitherBuilder () =
    // Async<Result<'a,'c>> * ('a -> Async<Result<'b,'c>>)
    // -> Async<Result<'b,'c>>
    member this.Bind(x, f) =
        async {
            let! x' = x
            match x' with
            | Success s -> return! f s
            | Failure f -> return Failure f }
    // 'a -> 'a
    member this.ReturnFrom x = x
 
let asyncEither = AsyncEitherBuilder ()

This is the minimal implementation required for the following composition. A more complete implementation would also define a Return method, as well as other useful methods.

In the Haskell example, you saw how I had to use hoistEither and liftIO to 'extract' the values within the do block. This is necessary because sometimes you need to pull a value out of an Either value, and sometimes you need to get the value inside an IO context.

In an asyncEither expression, you need similar functions:

// Async<'a> -> Async<Result<'a,'b>>
let liftAsync x = async {
    let! x' = x
    return Success x' }
 
// 'a -> Async<'a>
let asyncReturn x = async { return x }

I chose to name the first one liftAsync as a counterpart to Haskell's liftIO, since I'm using Async<'a> as a surrogate for IO. The other function I named asyncReturn because it returns a pure value wrapped in an asynchronous work-flow.

You can now compose the desired imp function from the above building blocks:

let imp candidate = asyncEither {
    let! r = Validate.reservation candidate |> asyncReturn
    let! i =
        SqlGateway.getReservedSeats connectionString r.Date
        |> liftAsync
    let! r = Capacity.check 10 i r |> asyncReturn
    return! SqlGateway.saveReservation connectionString r
            |> liftAsync }

Notice how, in contrast with the previous example, this expression uses let! and return! throughout, but that you have to compose each line with asyncReturn or liftAsync in order to pull out the appropriate values.

As an example, the original, unmodified Validate.reservation function has the type ReservationRendition -> Result<Reservation, Error>. Inside an asyncEither expression, however, all let!-bound values must be of the type Async<Result<'a, 'b>>, so you need to wrap the return value Result<Reservation, Error> in Async. That's what asyncReturn does. Since this expression is let!-bound, the r value has the type Reservation. It's 'double-unwrapped', if you will.

Likewise, SqlGateway.getReservedSeats returns a value of the type Async<int>, so you need to pipe it into liftAsync in order to turn it into an Async<Result<int, Error>>. When that value is let!-bound, then, i has the type int.

There's one change compared to the previous examples: the type of imp changed. It's now ReservationRendition -> Async<Result<unit, Error>>. While you could write an adapter function that executes this function synchronously, it's better to recall the mantra: async all the way!

Async Controller #

Instead of coercing the imp function to be synchronous, you can change the ReservationsController that uses it to be asynchronous as well:

// ReservationRendition -> Task<IHttpActionResult>
member this.Post(rendition : ReservationRendition) =
    async {
        let! res = imp rendition
        match res with
        | Failure (ValidationError msg) ->
            return this.BadRequest msg
        | Failure CapacityExceeded ->
            return this.StatusCode HttpStatusCode.Forbidden
        | Success () -> return this.Ok () }
    |> Async.StartAsTask

Notice that the method body uses an async computation expression, instead of the new asyncEither. This is because, when returning a result, you finally need to explicitly deal with the error cases as well as the success case. Using a standard async expression enables you to let!-bind res to the result of invoking the asynchronous imp function, and pattern match against it.

Since ASP.NET Web API support asynchronous controllers, this works when you convert the async work-flow to a Task with Async.StartAsTask. Async all the way.

In order to get this to work, I had to overload the BadRequest, StatusCode, and Ok methods, because they are protected, and you can't use protected methods from within a closure. Here's the entire code for the Controller, including the above Post method for completeness sake:

type ReservationsController(imp) =
    inherit ApiController()
 
    member private this.BadRequest (msg : string) =
        base.BadRequest msg :> IHttpActionResult
    member private this.StatusCode statusCode =
        base.StatusCode statusCode :> IHttpActionResult
    member private this.Ok () = base.Ok () :> IHttpActionResult
 
    // ReservationRendition -> Task<IHttpActionResult>
    member this.Post(rendition : ReservationRendition) =
        async {
            let! res = imp rendition
            match res with
            | Failure (ValidationError msg) ->
                return this.BadRequest msg
            | Failure CapacityExceeded ->
                return this.StatusCode HttpStatusCode.Forbidden
            | Success () -> return this.Ok () }
        |> Async.StartAsTask

As you can see, apart from the overloaded methods, the Post method is all there is. It uses the injected imp function to perform the actual work, asynchronously translates the result into a proper HTTP response, and returns it as a Task<IHttpActionResult>.

Summary #

The initial idea was to experiment with using Async as a surrogate for IO. If you want to derive any value from this convention, you'll need to be disciplined and make all impure functions return Async<'a> - even those not IO-bound, but impure for other reasons (like random number generators).

I'm not sure I'm entirely convinced that this would be a useful strategy to adopt, but on the other hand, I'm not deterred either. At least, the outcome of this experiment demonstrates that you can combine asynchronous work-flows with the Either monad, and that the code is still manageable, with good separation of concerns. Since it is a good idea to access IO-bound resources using asynchronous work-flows, it's nice to know that they can be combined with sane error handling.

Comments

let aprintfn fmt = async { return printfn fmt }

let explicitSeq = seq { yield aprintfn "hello"; yield aprintfn "hello" }
let replicatedSeq = Seq.replicate 2 <| aprintfn "hello"

// seq<Async<'a>> -> Async<seq<'a>>
let asequence xs = async { return Seq.map Async.RunSynchronously xs }

> asequence explicitSeq |> Async.RunSynchronously;;
hello
hello
val it : seq = seq [null; null]
> asequence replicatedSeq |> Async.RunSynchronously;;
hello
hello
val it : seq = seq [null; null]

A simple example of a composition using an F# computation expression.

In a previous article, you saw how to compose an application feature from functions:

let imp =
    Validate.reservation
    >> map (fun r ->
        SqlGateway.getReservedSeats connectionString r.Date, r)
    >> bind (fun (i, r) -> Capacity.check 10 i r)
    >> map (SqlGateway.saveReservation connectionString)

This is awkward because of the need to carry the result of Validate.reservation (r) on to Capacity.check, while also needing it for SqlGateway.getReservedSeats. In this article, you'll see a neater, alternative syntax.

Building blocks #

To recapitulate the context, you have this Result discriminated union from Scott Wlaschin's article about railway-oriented programming:

type Result<'TSuccess,'TFailure> = 
    | Success of 'TSuccess
    | Failure of 'TFailure

A type with this structure is also sometimes known as Either, because the result can be either a success or a failure.

The above example also uses bind and map functions, which are implemented this way:

// ('a -> Result<'b,'c>) -> Result<'a,'c> -> Result<'b,'c>
let bind f x = 
    match x with
    | Success s -> f s
    | Failure f -> Failure f
 
// ('a -> 'b) -> Result<'a,'c> -> Result<'b,'c>
let map f x = 
    match x with
    | Success s -> Success(f s)
    | Failure f -> Failure f

With these building blocks, it's trivial to implement a computation expression for the type:

type EitherBuilder () =
    member this.Bind(x, f) = bind f x
    member this.ReturnFrom x = x

You can add more members to EitherBuilder if you need support for more advanced syntax, but this is the minimal implementation required for the following example.

You also need a value of the EitherBuilder type:

let either = EitherBuilder ()

All this code is entirely generic, so you could put it (or a more comprehensive version) in a reusable library.

Composition using the Either computation expression #

Since this Either computation expression is for general-purpose use, you can also use it to compose the above imp function:

let imp candidate = either {
    let! r = Validate.reservation candidate
    let i = SqlGateway.getReservedSeats connectionString r.Date
    return! Capacity.check 10 i r
        |> map (SqlGateway.saveReservation connectionString) }

Notice how the r value can be used by both the SqlGateway.getReservedSeats and Capacity.check functions, because they are all within the same scope.

This example looks more like the Haskell composition in my previous article. It even looks cleaner in F#, but to be fair to Haskell, in F# you don't have to explicitly deal with IO as a monadic context, so that in itself makes things look simpler.

A variation using shadowing #

You may wonder why I chose to use return! with an expression using the map function. One reason was that I wanted to avoid having to bind a named value to the result of calling Capacity.check. Naming is always difficult, and while I find the names r and i acceptable because the scope is so small, I prefer composing functions without having to declare intermediary values.

Another reason was that I wanted to show you an example that resembles the previous Haskell example as closely as possible.

You may, however, find the following variation more readable. In order to use return instead of return!, you need to furnish a Return method on your computation builder:

type EitherBuilder () =
    member this.Bind(x, f) = bind f x
    member this.Return x = Success x

Nothing prevents you from adding both Return and ReturnFrom (as well as other) methods to the EitherBuilder class, but I'm showing you the minimal implementation required for the example to work.

Using this variation of EitherBuilder, you can alternatively write the imp function like this:

let imp candidate = either {
    let! r = Validate.reservation candidate
    let i = SqlGateway.getReservedSeats connectionString r.Date
    let! r = Capacity.check 10 i r
    return SqlGateway.saveReservation connectionString r }

In such an alternative, you can use a let!-bound value to capture the result of calling Capacity.check, but that obligates you to devise a name for the value. You'll often see names like r', but I always feel uneasy when I resort to such naming. Here, I circumvented the problem by shadowing the original r value with a new value also called r. This is possible, and even desirable, because once the reservation has been checked, you should use that new, checked value, and not the original value. That's what the original composition, above, does, so shadowing is both equivalent and appropriate.

Summary #

Computation expressions give you an opportunity to compose functions in a readable way. It's an alternative to using the underlying bind and map functions. Whether you prefer one over the other is partly subjective, but I tend to favour the underlying functions until they become inconvenient. The initial version of the imp function in this article is an example of map and bind becoming unwieldy, and where a computation expression affords a cleaner, more readable syntax.

The disadvantage of computation expressions is that you need to use return or return! to return a value. That forces you to write an extra line of code that isn't necessary with a simple bind or map.

Functional architecture tends to fall into a pit of success that looks a lot like Ports and Adapters.

In object-oriented architecture, we often struggle towards the ideal of the Ports and Adapters architecture, although we often call it something else: layered architecture, onion architecture, hexagonal architecture, and so on. The goal is to decouple the business logic from technical implementation details, so that we can vary each independently.

This creates value because it enables us to manoeuvre nimbly, responding to changes in business or technology.

Ports and Adapters #

The idea behind the Ports and Adapters architecture is that ports make up the boundaries of an application. A port is something that interacts with the outside world: user interfaces, message queues, databases, files, command-line prompts, etcetera. While the ports constitute the interface to the rest of the world, adapters translate between the ports and the application model.

The word adapter is aptly chosen, because the role of the Adapter design pattern is exactly to translate between two different interfaces.

You ought to arrive at some sort of variation of Ports and Adapters if you apply Dependency Injection, as I've previously attempted to explain.

The problem with this architecture, however, is that it seems to take a lot of explaining:

• My book about Dependency Injection is 500 pages long.
• Robert C. Martin's book about the SOLID principles, package and component design, and so on is 700 pages long.
• Domain-Driven Design is 500 pages long.
• and so on...

It's possible to implement a Ports and Adapters architecture with object-oriented programming, but it takes so much effort. Does it have to be that difficult?

Haskell as a learning aid #

Someone recently asked me: how do I know I'm being sufficiently Functional?

I was wondering that myself, so I decided to learn Haskell. Not that Haskell is the only Functional language out there, but it enforces purity in a way that neither F#, Clojure, nor Scala does. In Haskell, a function must be pure, unless its type indicates otherwise. This forces you to be deliberate in your design, and to separate pure functions from functions with (side) effects.

If you don't know Haskell, code with side effects can only happen inside of a particular 'context' called IO. It's a monadic type, but that's not the most important point. The point is that you can tell by a function's type whether or not it's pure. A function with the type ReservationRendition -> Either Error Reservation is pure, because IO appears nowhere in the type. On the other hand, a function with the type ConnectionString -> ZonedTime -> IO Int is impure because its return type is IO Int. This means that the return value is an integer, but that this integer originates from a context where it could change between function calls.

There's a fundamental distinction between a function that returns Int, and one that returns IO Int. Any function that returns Int is, in Haskell, referentially transparent. This means that you're guaranteed that the function will always return the same value given the same input. On the other hand, a function returning IO Int doesn't provide such a guarantee.

In Haskell programming, you should strive towards maximising the amount of pure functions you write, pushing the impure code to the edges of the system. A good Haskell program has a big core of pure functions, and a shell of IO code. Does that sound familiar?

It basically means that Haskell's type system enforces the Ports and Adapters architecture. The ports are all your IO code. The application's core is all your pure functions. The type system automatically creates a pit of success.

Haskell is a great learning aid, because it forces you to explicitly make the distinction between pure and impure functions. You can even use it as a verification step to figure out whether your F# code is 'sufficiently Functional'. F# is a Functional first language, but it also allows you to write object-oriented or imperative code. If you write your F# code in a Functional manner, though, it's easy to translate to Haskell. If your F# code is difficult to translate to Haskell, it's probably because it isn't Functional.

Here's an example.

Accepting reservations in F#, first attempt #

In my Test-Driven Development with F# Pluralsight course (a free, condensed version is also available), I demonstrate how to implement an HTTP API that accepts reservation requests for an on-line restaurant booking system. One of the steps when handling the reservation request is to check whether the restaurant has enough remaining capacity to accept the reservation. The function looks like this:

// int
// -> (DateTimeOffset -> int)
// -> Reservation
// -> Result<Reservation,Error>
let check capacity getReservedSeats reservation =
    let reservedSeats = getReservedSeats reservation.Date
    if capacity < reservation.Quantity + reservedSeats
    then Failure CapacityExceeded
    else Success reservation

As the comment suggests, the second argument, getReservedSeats, is a function of the type DateTimeOffset -> int. The check function calls this function to retrieve the number of already reserved seats on the requested date.

When unit testing, you can supply a pure function as a Stub; for example:

let getReservedSeats _ = 0
 
let actual = Capacity.check capacity getReservedSeats reservation

When finally composing the application, instead of using a pure function with a hard-coded return value, you can compose with an impure function that queries a database for the desired information:

let imp =
    Validate.reservation
    >> bind (Capacity.check 10 (SqlGateway.getReservedSeats connectionString))
    >> map (SqlGateway.saveReservation connectionString)

Here, SqlGateway.getReservedSeats connectionString is a partially applied function, the type of which is DateTimeOffset -> int. In F#, you can't tell by its type that it's impure, but I know that this is the case because I wrote it. It queries a database, so isn't referentially transparent.

This works well in F#, where it's up to you whether a particular function is pure or impure. Since that imp function is composed in the application's Composition Root, the impure functions SqlGateway.getReservedSeats and SqlGateway.saveReservation are only pulled in at the edge of the system. The rest of the system is nicely protected against side-effects.

It feels Functional, but is it?

Feedback from Haskell #

In order to answer that question, I decided to re-implement the central parts of this application in Haskell. My first attempt to check the capacity was this direct translation:

checkCapacity :: Int
              -> (ZonedTime -> Int)
              -> Reservation
              -> Either Error Reservation
checkCapacity capacity getReservedSeats reservation =
  let reservedSeats = getReservedSeats $ date reservation
  in if capacity < quantity reservation + reservedSeats
      then Left CapacityExceeded
      else Right reservation

This compiles, and at first glance seems promising. The type of the getReservedSeats function is ZonedTime -> Int. Since IO appears nowhere in this type, Haskell guarantees that it's pure.

On the other hand, when you need to implement the function to retrieve the number of reserved seats from a database, this function must, by its very nature, be impure, because the return value could change between two function calls. In order to enable that in Haskell, the function must have this type:

getReservedSeatsFromDB :: ConnectionString -> ZonedTime -> IO Int

While you can partially apply the first ConnectionString argument, the return value is IO Int, not Int.

A function with the type ZonedTime -> IO Int isn't the same as ZonedTime -> Int. Even when executing inside of an IO context, you can't convert ZonedTime -> IO Int to ZonedTime -> Int.

You can, on the other hand, call the impure function inside of an IO context, and extract the Int from the IO Int. That doesn't quite fit with the above checkCapacity function, so you'll need to reconsider the design. While it was 'Functional enough' for F#, it turns out that this design isn't really Functional.

If you consider the above checkCapacity function, though, you may wonder why it's necessary to pass in a function in order to determine the number of reserved seats. Why not simply pass in this number instead?

checkCapacity :: Int -> Int -> Reservation -> Either Error Reservation
checkCapacity capacity reservedSeats reservation =
    if capacity < quantity reservation + reservedSeats
    then Left CapacityExceeded
    else Right reservation

That's much simpler. At the edge of the system, the application executes in an IO context, and that enables you to compose the pure and impure functions:

import Control.Monad.Trans (liftIO)
import Control.Monad.Trans.Either (EitherT(..), hoistEither)

postReservation :: ReservationRendition -> IO (HttpResult ())
postReservation candidate = fmap toHttpResult $ runEitherT $ do
  r <- hoistEither $ validateReservation candidate
  i <- liftIO $ getReservedSeatsFromDB connStr $ date r
  hoistEither $ checkCapacity 10 i r
  >>= liftIO . saveReservation connStr

(Complete source code is available here.)

Don't worry if you don't understand all the details of this composition. The highlights are these:

The postReservation function takes a ReservationRendition (think of it as a JSON document) as input, and returns an IO (HttpResult ()) as output. The use of IO informs you that this entire function is executing within the IO monad. In other words: it's impure. This shouldn't be surprising, since this is the edge of the system.

Furthermore, notice that the function liftIO is called twice. You don't have to understand exactly what it does, but it's necessary to use in order to 'pull out' a value from an IO type; for example pulling out the Int from an IO Int. This makes it clear where the pure code is, and where the impure code is: the liftIO function is applied to the functions getReservedSeatsFromDB and saveReservation. This tells you that these two functions are impure. By exclusion, the rest of the functions (validateReservation, checkCapacity, and toHttpResult) are pure.

It's interesting to observe how you can interleave pure and impure functions. If you squint, you can almost see how the data flows from the pure validateReservation function, to the impure getReservedSeatsFromDB function, and then both output values (r and i) are passed to the pure checkCapacity function, and finally to the impure saveReservation function. All of this happens within an (EitherT Error IO) () do block, so if any of these functions return Left, the function short-circuits right there and returns the resulting error. See e.g. Scott Wlaschin's excellent article on railway-oriented programming for an exceptional, lucid, clear, and visual introduction to the Either monad.

The value from this expression is composed with the built-in runEitherT function, and again with this pure function:

toHttpResult :: Either Error () -> HttpResult ()
toHttpResult (Left (ValidationError msg)) = BadRequest msg
toHttpResult (Left CapacityExceeded) = StatusCode Forbidden
toHttpResult (Right ()) = OK ()

The entire postReservation function is impure, and sits at the edge of the system, since it handles IO. The same is the case of the getReservedSeatsFromDB and saveReservation functions. I deliberately put the two database functions in the bottom of the below diagram, in order to make it look more familiar to readers used to looking at layered architecture diagrams. You can imagine that there's a cylinder-shaped figure below the circles, representing a database.

You can think of the validateReservation and toHttpResult functions as belonging to the application model. While pure functions, they translate between the external and internal representation of data. Finally, the checkCapacity function is part of the application's Domain Model, if you will.

Most of the design from my first F# attempt survived, apart from the Capacity.check function. Re-implementing the design in Haskell has taught me an important lesson that I can now go back and apply to my F# code.

Accepting reservations in F#, even more Functionally #

Since the required change is so little, it's easy to apply the lesson learned from Haskell to the F# code base. The culprit was the Capacity.check function, which ought to instead be implemented like this:

let check capacity reservedSeats reservation =
    if capacity < reservation.Quantity + reservedSeats
    then Failure CapacityExceeded
    else Success reservation

This simplifies the implementation, but makes the composition slightly more involved:

let imp =
    Validate.reservation
    >> map (fun r ->
        SqlGateway.getReservedSeats connectionString r.Date, r)
    >> bind (fun (i, r) -> Capacity.check 10 i r)
    >> map (SqlGateway.saveReservation connectionString)

This almost looks more complicated than the Haskell function. Haskell has the advantage that you can automatically use any type that implements the Monad typeclass inside of a do block, and since (EitherT Error IO) () is a Monad instance, the do syntax is available for free.

You could do something similar in F#, but then you'd have to implement a custom computation expression builder for the Result type. Perhaps I'll do this in a later blog post...

Summary #

Good Functional design is equivalent to the Ports and Adapters architecture. If you use Haskell as a yardstick for 'ideal' Functional architecture, you'll see how its explicit distinction between pure and impure functions creates a pit of success. Unless you write your entire application to execute within the IO monad, Haskell will automatically enforce the distinction, and push all communication with the external world to the edges of the system.

Some Functional languages, like F#, don't explicitly enforce this distinction. Still, in F#, it's easy to informally make the distinction and compose applications with impure functions pushed to the edges of the system. While this isn't enforced by the type system, it still feels natural.

Comments

let internal makeReservation' getReservedSeats saveReservation check r =
    (getReservedSeats r.Date, r)
    |> bind (fun (i, r) -> check 10 i r)
    |> map saveReservation

let makeReservation = makeReservation' SqlGateway.getReservedSeats SqlGateway.saveReservation Capacity.check

// In module SqlGateway:
let getReservedSeats connectionString (date : DateTimeOffset) =
    let min = DateTimeOffset(date.Date           , date.Offset)
    let max = DateTimeOffset(date.Date.AddDays 1., date.Offset)
 
    let sql = "
        SELECT ISNULL(SUM(Quantity), 0)
        FROM [dbo].[Reservations]
        WHERE @min <= Date AND Date < @max"
    use conn = new SqlConnection(connectionString)
    use cmd = new SqlCommand(sql, conn)
    cmd.Parameters.AddWithValue("@min", min) |> ignore
    cmd.Parameters.AddWithValue("@max", max) |> ignore
    conn.Open()
    cmd.ExecuteScalar() :?> int

// In module SqlGateway:
let saveReservation connectionString (reservation : Reservation) =
    let sql = "
        INSERT INTO Reservations(Date, Name, Email, Quantity)
        VALUES(@Date, @Name, @Email, @Quantity)"
    use conn = new SqlConnection(connectionString)
    use cmd = new SqlCommand(sql, conn)
    cmd.Parameters.AddWithValue("@Date", reservation.Date) |> ignore
    cmd.Parameters.AddWithValue("@Name", reservation.Name) |> ignore
    cmd.Parameters.AddWithValue("@Email", reservation.Email) |> ignore
    cmd.Parameters.AddWithValue("@Quantity", reservation.Quantity) |> ignore
    conn.Open()
    cmd.ExecuteNonQuery() |> ignore

let imp =
	Validate.reservation
	>> map (fun r ->
		SqlGateway.getReservedSeats connectionString r.Date, r)
	>> bind (fun (i, r) -> Capacity.check 10 i r)
	>> map (SqlGateway.saveReservation connectionString)

findCaravan :: Int -> ZoneTime -> IO (Maybe Caravan)
findCaravan minimumCapacity date = ... -- database stuff
        

checkCapacity :: Monad m => Int
                            -> (ZonedTime -> m Int)
                            -> Reservation
                            -> EitherT Error m Reservation
checkCapacity capacity getReservedSeats reservation = EitherT $ do
    reservedSeats <- getReservedSeats $ date reservation
    if capacity < quantity reservation + reservedSeats
    then return $ Left CapacityExceeded
    else return $ Right reservation
                

postReservation :: ReservationRendition -> IO (HttpResult ())
postReservation candidate = fmap toHttpResult $ runEitherT $
  hoistEither $ validateReservation candidate
  >>= checkCapacity 10 (getReservedSeatsFromDB connStr)
  >>= liftIO . saveReservation connStr

stubGetReservedSeats :: ZonedTime -> Identity Int
stubGetReservedSeats date = return 8
        

int foo(boolean condition, IntSupplier io1, IntSupplier io2) {
    if (condition) {
        return io1.getAsInt();
    } else {
        return io2.getAsInt();
    }
}

Slightly improved syntax for defining ad-hoc, in-line Arbitraries for FsCheck.Xunit.

Last year, I described how to define and use ad-hoc, in-line Arbitraries with FsCheck.Xunit. The final example code looked like this:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    let nc = Gen.elements [4..8] |> Arb.fromGen
    Prop.forAll nc (fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual)

There's one tiny problem with this way of expressing properties using Prop.forAll: the use of brackets to demarcate the anonymous multi-line function. Notice how the opening bracket appears to the left of the fun keyword, while the closing bracket appears eleven lines down, after the end of the expression Dead =! actual.

While it isn't pretty, I haven't found it that bad for readability, either. When you're writing the property, however, this syntax is cumbersome.

Issues writing the code #

After having written Prop.forAll nc, you start writing (fun neighborCount -> ). After you've typed the closing bracket, you have to move your cursor one place to the left. When entering new lines, you have to keep diligent, making sure that the closing bracket is always to the right of your cursor.

If you ever need to use a nested level of brackets within that anonymous function, your vigilance will be tested to its utmost. When I wrote the above property, for example, when I reached the point where I wanted to call the calculateNextState function, I wrote:

let actual : State =
    calculateNextState (

The editor detects that I'm writing an opening bracket, but since I have the closing bracket to the immediate right of the cursor, this is what happens:

let actual : State =
    calculateNextState ()

What normally happens when you type an opening bracket is that the editor automatically inserts a closing bracket to the right of your cursor, but in this case, it doesn't do that. There's already a closing bracket immediately to the right of the cursor, and the editor assumes that this bracket belongs to the opening bracket I just typed. What it really should have done was this:

let actual : State =
    calculateNextState ())

The editor doesn't have a chance, though, because at this point, I'm still typing, and the code doesn't compile. None of the alternatives compile at this point. You can't really blame the editor.

To make a long story short, enclosing a multi-line anonymous function in brackets is a source of errors. If only there was a better alternative.

Backward pipe #

The solution started to dawn on me because I've been learning Haskell for the last half year, and in Haskell, you often use the $ operator to get rid of unwanted brackets. F# has an equivalent operator: <|, the backward pipe operator.

I rarely use the <| operator in F#, but in this case, it works really well:

[<Property(QuietOnSuccess = true)>]
let ``Any live cell with > 3 live neighbors dies`` (cell : int * int) =
    let nc = Gen.elements [4..8] |> Arb.fromGen
    Prop.forAll nc <| fun neighborCount ->
        let liveNeighbors =
            cell
            |> findNeighbors
            |> shuffle
            |> Seq.take neighborCount
            |> Seq.toList
        
        let actual : State =
            calculateNextState (cell :: liveNeighbors |> shuffle |> set) cell
 
        Dead =! actual

Notice that there's no longer any need for a closing bracket after Dead =! actual.

Summary #

When the last argument passed to a function is another function, you can replace the brackets with a single application of the <| operator. I only use this operator sparingly, but in the case of in-line ad-hoc FsCheck Arbitraries, I find it useful.

Addendum 2016-05-17: You can get rid of the nc value with TIE fighter infix notation.

Even simple functions may have properties that can be expressed independently of the implementation.

This article is the eighth in a series of articles that demonstrate how to develop software using types and properties. In previous articles, you've seen an extensive example of how to solve the Tennis Kata with type design and Property-Based Testing. Specifically, in the third article, you saw the introduction of a function called other. In that article we didn't cover that function with automatic tests, but this article rectifies that omission.

The source code for this article series is available on GitHub.

Implementation duplication #

The other function is used to find the opponent of a player. The implementation is trivial:

let other = function PlayerOne -> PlayerTwo | PlayerTwo -> PlayerOne

Unless you're developing software where lives, or extraordinary amounts of money, are at stake, you probably need not test such a trivial function. I'm still going to show you how you could do this, mostly because it's a good example of how Property-Based Testing can sometimes help you test the behaviour of a function, instead of the implementation.

Before I show you that, however, I'll show you why example-based unit tests are inadequate for testing this function.

You could test this function using examples, and because the space of possible input is so small, you can even cover it in its entirety:

[<Fact>]
let ``other than playerOne returns correct result`` () =
    PlayerTwo =! other PlayerOne
 
[<Fact>]
let ``other than playerTwo returns correct result`` () =
    PlayerOne =! other PlayerTwo

The =! operator is a custom operator defined by Unquote, an assertion library. You can read the first expression as player two must equal other than player one.

The problem with these tests, however, is that they don't state anything not already stated by the implementation itself. Basically, what these tests state is that if the input is PlayerOne, the output is PlayerTwo, and if the input is PlayerTwo, the output is PlayerOne.

That's exactly what the implementation does.

The only important difference is that the implementation of other states this relationship more succinctly than the tests.

It's as though the tests duplicate the information already in the implementation. How does that add value?

Sometimes, this can be the only way to cover functionality with tests, but in this case, there's an alternative.

Behaviour instead of implementation #

Property-Based Testing inspires you to think about the observable behaviour of a system, rather than the implementation. Which properties do the other function have?

If you call it with a Player value, you'd expect it to return a Player value that's not the input value:

[<Property>]
let ``other returns a different player`` player = player <>! other player

The <>! operator is another custom operator defined by Unquote. You can read the expression as player must not equal other player.

This property alone doesn't completely define the behaviour of other, but combined with the next property, it does:

[<Property>]
let ``other other returns same player`` player = player =! other (other player)

If you call other, and then you take the output of that call and use it as input to call other again, you should get the original Player value. This property is an excellent example of what Scott Wlaschin calls there and back again.

These two properties, together, describe the behaviour of the other function, without going into details about the implementation.

Summary #

You've seen a simple example of how to describe the properties of a function without resorting to duplicating the implementation in the tests. You may not always be able to do this, but it always feels right when you can.

If you're interested in learning more about Property-Based Testing, you can watch my introduction to Property-based Testing with F# Pluralsight course.

How to compose the tennis game code into a finite state machine.

This article is the seventh in a series of articles that demonstrate how to develop software using types and properties. In the previous article, you saw how to define the initial state of a tennis game. In this article, you'll see how to define the tennis game as a finite state machine.

The source code for this article series is available on GitHub.

Scoring a sequence of balls #

Previously, you saw how to score a game in an ad-hoc fashion:

> let firstBall = score newGame PlayerTwo;;
val firstBall : Score = Points {PlayerOnePoint = Love;
                                PlayerTwoPoint = Fifteen;}

> let secondBall = score firstBall PlayerOne;;
val secondBall : Score = Points {PlayerOnePoint = Fifteen;
                                 PlayerTwoPoint = Fifteen;}

You'll quickly get tired of that, so you may think that you can do something like this instead:

> newGame |> (fun s -> score s PlayerOne) |> (fun s -> score s PlayerTwo);;
val it : Score = Points {PlayerOnePoint = Fifteen;
                         PlayerTwoPoint = Fifteen;}

That does seem a little clumsy, though, but it's not really what you need to be able to do either. What you'd probably appreciate more is to be able to calculate the score given a sequence of wins. A sequence of wins is a list of Player values; for instance, [PlayerOne; PlayerOne; PlayerTwo] means that player one won the first two balls, and then player two won the third ball.

Since we already know the initial state of a game, and how to calculate the score for each ball, it's a one-liner to calculate the score for a sequence of balls:

let scoreSeq wins = Seq.fold score newGame wins

This function has the type Player seq -> Score. It uses newGame as the initial state of a left fold over the wins. The aggregator function is the score function.

You can use it with a sequence of wins, like this:

> scoreSeq [PlayerOne; PlayerOne; PlayerTwo];;
val it : Score = Points {PlayerOnePoint = Thirty;
                         PlayerTwoPoint = Fifteen;}

Since player one won the first two balls, and player two then won the third ball, the score at that point is thirty-fifteen.

Properties for the state machine #

Can you think of any properties for the scoreSeq function?

There are quite a few, it turns out. It may be a good exercise if you pause reading for a couple of minutes, and try to think of some properties.

If you have a list of properties, you can compare them with the ones I though of.

Before we start, you may find the following helper functions useful:

let isPoints =    function Points _    -> true | _ -> false
let isForty =     function Forty  _    -> true | _ -> false
let isDeuce =     function Deuce       -> true | _ -> false
let isAdvantage = function Advantage _ -> true | _ -> false
let isGame =      function Game _      -> true | _ -> false

These can be useful to express some properties, but I don't think that they are generally useful, so I put them together with the test code.

Limited win sequences #

If you look at short win sequences, you can already say something about them. For instance, it takes at least four balls to finish a game, so you know that if you have fewer wins than four, the game must still be on-going:

[<Property>]
let ``A game with less then four balls isn't over`` (wins : Player list) =
    let actual : Score = wins |> Seq.truncate 3 |> scoreSeq
    test <@ actual |> (not << isGame) @>

The built-in function Seq.truncate returns only the n (in this case: 3) first elements of a sequence. If the sequence is shorter than that, then the entire sequence is returned. The use of Seq.truncate 3 guarantees that the sequence passed to scoreSeq is no longer than three elements long, no matter what FsCheck originally generated.

Likewise, you can't reach deuce in less than six balls:

[<Property>]
let ``A game with less than six balls can't be Deuce`` (wins : Player list) =
    let actual = wins |> Seq.truncate 5 |> scoreSeq
    test <@ actual |> (not << isDeuce) @>

This is similar to the previous property. There's one more in that family:

[<Property>]
let ``A game with less than seven balls can't have any player with advantage``
    (wins : Player list) =
 
    let actual = wins |> Seq.truncate 6 |> scoreSeq
    test <@ actual |> (not << isAdvantage) @>

It takes at least seven balls before the score can reach a state where one of the players have the advantage.

Longer win sequences #

Conversely, you can also express some properties related to win sequences of a minimum size. This one is more intricate to express with FsCheck, though. You'll need a sequence of Player values, but the sequence should be guaranteed to have a minimum length. There's no built-in in function for that in FsCheck, so you need to define it yourself:

// int -> Gen<Player list>
let genListLongerThan n =
    let playerGen = Arb.generate<Player>
    let nPlayers = playerGen |> Gen.listOfLength (n + 1)
    let morePlayers = playerGen |> Gen.listOf
    Gen.map2 (@) nPlayers morePlayers

This function takes an exclusive minimum size, and returns an FsCheck generator that will generate Player lists longer than n. It does that by combining two of FsCheck's built-in generators. Gen.listOfLength generates lists of the requested length, and Gen.listOf generates all sorts of lists, including the empty list.

Both nPlayers and morePlayers are values of the type Gen<Player list>. Using Gen.map2, you can concatenate these two list generators using F#'s built-in list concatenation operator @. (All operators in F# are also functions. The (@) function has the type 'a list -> 'a list -> 'a list.)

With the genListLongerThan function, you can now express properties related to longer win sequences. As an example, if the players have played more than four balls, the score can't be a Points case:

[<Property>]
let ``A game with more than four balls can't be Points`` () =
    let moreThanFourBalls = genListLongerThan 4 |> Arb.fromGen
    Prop.forAll moreThanFourBalls (fun wins ->
 
        let actual = scoreSeq wins
 
        test <@ actual |> (not << isPoints) @>)

As previously explained, Prop.forAll expresses a property that must hold for all lists generated by moreThanFourBalls.

Correspondingly, if the players have played more than five balls, the score can't be a Forty case:

[<Property>]
let ``A game with more than five balls can't be Forty`` () =
    let moreThanFiveBalls = genListLongerThan 5 |> Arb.fromGen
    Prop.forAll moreThanFiveBalls (fun wins ->
 
        let actual = scoreSeq wins
 
        test <@ actual |> (not << isForty) @>)

This property is, as you can see, similar to the previous example.

Shortest completed game #

Do you still have your list of tennis game properties? Let's see if you thought of this one. The shortest possible way to complete a tennis game is when one of the players wins four balls in a row. This property should hold for all (two) players:

[<Property>]
let ``A game where one player wins all balls is over in four balls`` (player) =
    let fourWins = Seq.init 4 (fun _ -> player)
    
    let actual = scoreSeq fourWins
 
    let expected = Game player
    expected =! actual

This test first defines fourWins, of the type Player seq. It does that by using the player argument created by FsCheck, and repeating it four times, using Seq.init.

The =! operator is a custom operator defined by Unquote, an assertion library. You can read the expression as expected must equal actual.

Infinite games #

The tennis scoring system turns out to be a rich domain. There are still more properties. We'll look at a final one, because it showcases another way to use FsCheck's API, and then we'll call it a day.

An interesting property of the tennis scoring system is that a game isn't guaranteed to end. It may, theoretically, continue forever, if players alternate winning balls:

[<Property>]
let ``A game where players alternate never ends`` firstWinner =
    let alternateWins = 
        firstWinner
        |> Gen.constant
        |> Gen.map (fun p -> [p; other p])
        |> Gen.listOf
        |> Gen.map List.concat
        |> Arb.fromGen
    Prop.forAll alternateWins (fun wins ->
        
        let actual = scoreSeq wins
        
        test <@ actual |> (not << isGame) @>)

This property starts by creating alternateWins, an Arbitrary<Player list>. It creates lists with alternating players, like [PlayerOne; PlayerTwo], or [PlayerTwo; PlayerOne; PlayerTwo; PlayerOne; PlayerTwo; PlayerOne]. It does that by using the firstWinner argument (of the type Player) as a constant starting value. It's only constant within each test, because firstWinner itself varies.

Using that initial Player value, it then proceeds to map that value to a list with two elements: the player, and the other player, using the other function. This creates a Gen<Player list>, but piped into Gen.listOf, it becomes a Gen<Player list list>. An example of the sort of list that would generate could be [[PlayerTwo; PlayerOne]; [PlayerTwo; PlayerOne]]. Obviously, you need to flatten such lists, which you can do with List.concat; you have to do it inside of a Gen, though, so it's Gen.map List.concat. That gives you a Gen<Player list>, which you can finally turn into an Arbitrary<Player list> with Arb.fromGen.

This enables you to use Prop.forAll with alternateWins to express that regardless of the size of such alternating win lists, the game never reaches a Game state.

Summary #

In this article, you saw how to implement a finite state machine for calculating tennis scores. It's a left fold over the score function, always starting in the initial state where both players are at love. You also saw how you can express various properties that hold for a game of tennis.

In this article series, you've seen an extensive example of how to design with types and properties. You may have noticed that out of the six example articles so far, only the first one was about designing with types, and the next five articles were about Property-Based Testing. It looks as though not much is gained from designing with types.

On the contrary, much is gained by designing with types, but you don't see it, exactly because it's efficient. If you don't design with types in order to make illegal states unrepresentable, you'd have to write even more automated tests in order to test what happens when input is invalid. Also, if illegal states are representable, it would have been much harder to write Property-Based Tests. Instead of trusting that FsCheck generates only valid values based exclusively on the types, you'd have to write custom Generators or Arbitraries for each type of input. That would have been even more work than you've seen in this articles series.

Designing with types makes Property-Based Testing a comfortable undertaking. Together, they enable you to develop software that you can trust.

If you're interested in learning more about Property-Based Testing, you can watch my introduction to Property-based Testing with F# Pluralsight course.