10 lessons learnt from the Ruby Refactoring Kata - Tennis Game

Over the last ~2 months, I’ve been scheduling some time to work on a specific Ruby code which is designed to be a good starting point for a refactoring.

Those exercises are called Refactoring Katas. The one I picked up is called Tennis Game.

I’ve had around 20 coding sessions with this specific kata and I have recorded all the session on our Arkency YouTube channel. There’s a whole playlist of all the videos for this kata.

This blogpost is a written summary of my lessons, thoughts, observations after those 20 coding/refactoring sessions.

Introduction

The responsibility of this code is to return a string with a Tennis game result. The input comes as sequential calls to the won_point method. The result is returned via score method. Those 2 methods create the public API of the TennisGame1 object.

Initial code

class TennisGame1 def initialize ( player1Name , player2Name ) @player1Name = player1Name @player2Name = player2Name @p1points = 0 @p2points = 0 end def won_point ( playerName ) if playerName == "player1" @p1points += 1 else @p2points += 1 end end def score result = "" tempScore = 0 if ( @p1points == @p2points ) result = { 0 => "Love-All" , 1 => "Fifteen-All" , 2 => "Thirty-All" , }. fetch ( @p1points , "Deuce" ) elsif ( @p1points >= 4 or @p2points >= 4 ) minusResult = @p1points - @p2points if ( minusResult == 1 ) result = "Advantage player1" elsif ( minusResult ==- 1 ) result = "Advantage player2" elsif ( minusResult >= 2 ) result = "Win for player1" else result = "Win for player2" end else ( 1 ... 3 ). each do | i | if ( i == 1 ) tempScore = @p1points else result += "-" tempScore = @p2points end result += { 0 => "Love" , 1 => "Fifteen" , 2 => "Thirty" , 3 => "Forty" , }[ tempScore ] end end result end end

Initial tests

At the first glance the tests look quite cool - the code is declarative, you should be able to see the expectations. However, while working on this code for longer I came to the conclusion that those tests are not really that perfect.

TEST_CASES = [ [ 0 , 0 , "Love-All" , 'player1' , 'player2' ], [ 1 , 1 , "Fifteen-All" , 'player1' , 'player2' ], [ 2 , 2 , "Thirty-All" , 'player1' , 'player2' ], [ 3 , 3 , "Deuce" , 'player1' , 'player2' ], [ 4 , 4 , "Deuce" , 'player1' , 'player2' ], [ 1 , 0 , "Fifteen-Love" , 'player1' , 'player2' ], [ 0 , 1 , "Love-Fifteen" , 'player1' , 'player2' ], [ 2 , 0 , "Thirty-Love" , 'player1' , 'player2' ], [ 0 , 2 , "Love-Thirty" , 'player1' , 'player2' ], [ 3 , 0 , "Forty-Love" , 'player1' , 'player2' ], [ 0 , 3 , "Love-Forty" , 'player1' , 'player2' ], [ 4 , 0 , "Win for player1" , 'player1' , 'player2' ], [ 0 , 4 , "Win for player2" , 'player1' , 'player2' ], [ 2 , 1 , "Thirty-Fifteen" , 'player1' , 'player2' ], [ 1 , 2 , "Fifteen-Thirty" , 'player1' , 'player2' ], [ 3 , 1 , "Forty-Fifteen" , 'player1' , 'player2' ], [ 1 , 3 , "Fifteen-Forty" , 'player1' , 'player2' ], [ 4 , 1 , "Win for player1" , 'player1' , 'player2' ], [ 1 , 4 , "Win for player2" , 'player1' , 'player2' ], [ 3 , 2 , "Forty-Thirty" , 'player1' , 'player2' ], [ 2 , 3 , "Thirty-Forty" , 'player1' , 'player2' ], [ 4 , 2 , "Win for player1" , 'player1' , 'player2' ], [ 2 , 4 , "Win for player2" , 'player1' , 'player2' ], [ 4 , 3 , "Advantage player1" , 'player1' , 'player2' ], [ 3 , 4 , "Advantage player2" , 'player1' , 'player2' ], [ 5 , 4 , "Advantage player1" , 'player1' , 'player2' ], [ 4 , 5 , "Advantage player2" , 'player1' , 'player2' ], [ 15 , 14 , "Advantage player1" , 'player1' , 'player2' ], [ 14 , 15 , "Advantage player2" , 'player1' , 'player2' ], [ 6 , 4 , 'Win for player1' , 'player1' , 'player2' ], [ 4 , 6 , 'Win for player2' , 'player1' , 'player2' ], [ 16 , 14 , 'Win for player1' , 'player1' , 'player2' ], [ 14 , 16 , 'Win for player2' , 'player1' , 'player2' ], [ 6 , 4 , 'Win for player1' , 'player1' , 'player2' ], [ 4 , 6 , 'Win for player2' , 'player1' , 'player2' ], [ 6 , 5 , 'Advantage player1' , 'player1' , 'player2' ], [ 5 , 6 , 'Advantage player2' , 'player1' , 'player2' ] ] class TestTennis < Test :: Unit :: TestCase def play_game ( tennisGameClass , p1Points , p2Points , p1Name , p2Name ) game = tennisGameClass . new ( p1Name , p2Name ) ( 0 .. [ p1Points , p2Points ]. max ). each do | i | if i < p1Points game . won_point ( p1Name ) end if i < p2Points game . won_point ( p2Name ) end end game end def test_Score_Game1 TEST_CASES . each do | testcase | ( p1Points , p2Points , score , p1Name , p2Name ) = testcase game = play_game ( TennisGame1 , p1Points , p2Points , p1Name , p2Name ) assert_equal ( score , game . score ()) end end end

Lessons learnt

1. Merciless refactoring can be a nice learning technique

Let me quote the extreme programming definition of what I mean here:

Refactor mercilessly to keep the design simple as you go and to avoid needless clutter and complexity. Keep your code clean and concise so it is easier to understand, modify, and extend. Make sure everything is expressed once and only once. In the end it takes less time to produce a system that is well groomed. ￼ There is a certain amount of Zen to refactoring. It is hard at first because you must be able to let go of that perfect design you have envisioned and accept the design that was serendipitously discovered for you by refactoring. You must realize that the design you envisioned was a good guide post, but is now obsolete.

The above definition makes most sense when applied to a situation when you think you know what is the perfect design and then you try to apply it. Usually, the code would tell you why your vision may not be so perfect. The solution is to follow the code.

In this Refactoring Kata, you can see my initial attempts to actually understand what the code does, by changing the code.

Even though, I don’t understand the domain yet - I’m following the typical code smells to restructure the code. It’s purely technical at this stage. I have no idea what the code really does (I’m trying to guess) but I know that certain technical transformations will keep the behaviour the same, while allow me to look at the code from a different angle.

2. After Red/Green comes the Refactor phase

Another refactoring lesson was the reminder that TDD (which I try to practice) is not only Red/Green, it’s also Refactor after the Green part.

3. Don’t trust the tests

At first, I thought that the tests give me enough coverage, that I can do the initial refactoring safely. However, it’s only over time that I learnt what are the drawbacks of the current tests design. The main problem is this code:

def play_game ( tennisGameClass , p1Points , p2Points , p1Name , p2Name ) game = tennisGameClass . new ( p1Name , p2Name ) ( 0 .. [ p1Points , p2Points ]. max ). each do | i | if i < p1Points game . won_point ( p1Name ) end if i < p2Points game . won_point ( p2Name ) end end game end

You see, this code plays through the game always in the same manner — first add all possible points to player1 and only later add player2 points. For certain implementations this might be a correct suite of tests, but if we switch to more stateful implementations, we’re lacking the coverage.

I consider refactoring a process of learning. It’s learning of the domain, of the code and of the tests. When you look at it this way, maybe it was alright - I started refactoring and through this process I learnt about the problems with tests. However, this is only valid, if I don’t push my changes before I learn the lessons. If I do, I risk introducing breaking changes.

4. Learn at least some basics of the domain

I’m not a big fan of tennis, but I thought I knew enough about it to work on this code.

In practice, this was hard. I kept forgetting what’s the meaning of Love , I had to constantly look up the possible results.

I think this led me to overgeneralising the code sometimes. The names I used for method names, for object names - they were not really names that would appear in a conversation among the real fans of the game.

That’s something what I’m trying to be more professional in my commercial projects. When I worked on accounting project, I took an online class on accounting. When I worked on a publishing project, I have studied the publishing industry, including the possible business models, what publishers struggle with, how publishers cooperate with authors. I talked to certain publishers.

In this kata, I clearly failed at it. I wasted some time, because I couldn’t visualise the domain well enough.

My domain vocabulary was very poor here - I kept using the words: game , score , result without learning some more.

5. Extract method is a no-brainer refactoring with a good IDE support

As you can see in the initial videos, I’m very aggressive in using the extract method technique. There are several reasons but the main one is to make the main algorithm, the main scenario as concise and clear as possible. This way I have the main method which represents the algorithm in an abstract way, but everything stays at the same level of abstraction. All the details are left to the other methods or even classes to be extracted.

I use RubyMine and I learnt to trust its Extract Method tooling. It’s just an alt-cmd-m keystroke, type the new name and it’s done.

6. Preserve the public API if you have no control on the client calls

I like to use modules to package my code. Sometimes, I don’t have control on the client calls, though. In such cases, I leave the public API untouched, but then delegate everything to the code behind modules. This is like building a facade/wall in front of my “well-packaged” code.

The name TennisGame1 remained untouched in my initial commits, even though it’s a terrible name. However, over time, I moved more code into the Tennis module.

class TennisGame1 def initialize ( player1Name , player2Name ) @player1Name = player1Name @player2Name = player2Name @p1points = 0 @p2points = 0 end def won_point ( playerName ) if playerName == "player1" @p1points += 1 else @p2points += 1 end end def score return draw_result if ( @p1points == @p2points ) return advantage_or_win_result if ( @p1points >= 4 or @p2points >= 4 ) return ongoing_result end private def ongoing_result Tennis :: OngoingResult . new ( @p1points , @p2points ). score end def draw_result Tennis :: DrawResult . new ( @p1points ). score end end

7. Extracting new classes helped my encapsulate concepts like Draw or Win

Similarly as Extract Method, I found Extract Class useful. I usually follow the same pattern, where I create a constructor method which sets the state and then 1 or 2 public methods to retrieve the data. In a way, this is a function and can be implemented as a function too. However, what I learnt is that often those objects are just a temporary thing. They’re not the final result of the refactoring, more like a step in-between.

module Tennis class DrawResult def initialize ( points ) @points = points end def score { 0 => "Love-All" , 1 => "Fifteen-All" , 2 => "Thirty-All" , }. fetch ( @points , "Deuce" ) end end class OngoingResult def initialize ( points_1 , points_2 ) @points_1 = points_1 @points_2 = points_2 end def score " #{ ongoing_result_names [ @points_1 ] } - #{ ongoing_result_names [ @points_2 ] } " end private def ongoing_result_names { 0 => "Love" , 1 => "Fifteen" , 2 => "Thirty" , 3 => "Forty" , } end end end

8. Simplify if conditions with Guards

There’s something about if conditions that I dislike. They often hide some important logic and I feel like ifs are sometimes a too primitive way of encapsulating this logic (often some state machines).

The most dangerous code I usually see are the nested if statements.

“No one ever got fired for adding the n+1 if statement, right”?

When I saw this initial code, trying to simplify it was my main goal:

def score result = "" tempScore = 0 if ( @p1points == @p2points ) result = { 0 => "Love-All" , 1 => "Fifteen-All" , 2 => "Thirty-All" , }. fetch ( @p1points , "Deuce" ) elsif ( @p1points >= 4 or @p2points >= 4 ) minusResult = @p1points - @p2points if ( minusResult == 1 ) result = "Advantage player1" elsif ( minusResult ==- 1 ) result = "Advantage player2" elsif ( minusResult >= 2 ) result = "Win for player1" else result = "Win for player2" end else ( 1 ... 3 ). each do | i | if ( i == 1 ) tempScore = @p1points else result += "-" tempScore = @p2points end result += { 0 => "Love" , 1 => "Fifteen" , 2 => "Thirty" , 3 => "Forty" , }[ tempScore ] end end result end

Here is the result after Extract Method, Extract Class and Replace If with Guard:

def score return draw_result if ( @p1points == @p2points ) return advantage_or_win_result if ( @p1points >= 4 or @p2points >= 4 ) return ongoing_result end

Obviously the ugliness of nested ifs didn’t disappear, but starting from the top-level code allowed me to make the main algorithm more clear and let me deal with other nested ifs in more localized methods/objects.

9. Code as data sounded more exciting in theory than in practice

I’ve been always excited by the idea of treating code as data. What I mean here is that some code doesn’t need to be code, because it’s actually data. In the video above you can see that I started refactoring some of the code (state machine transitions between possible results) into “code like data” direction. However, I never really finished it. It felt very “primitive” to represent those concepts as pure data without any behaviour.

This is a topic I need to think more about. Maybe this example wasn’t a good fit. Or maybe the idea isn’t as good as I thought. Maybe I’m just missing some skills here.

10. Mutation testing

This lesson came too late ;)

In my next refactoring kata I will try to “hire” mutant to check my tests earlier than I did here. Somehow, I connect mutant with some “big deal”, while in fact it’s very easy to start with, especially in such katas. Mutant shows very nicely that the tests are far from perfect and that my merciless refactoring attempts might be too brave sometimes.

The “final” code

The final code is not really that final. It’s more like a result of the most recent code experiment and I don’t consider it perfect in any way. Far from that.

The last experiment was treating the tennis game as a state machine. Each state is another object (data structure maybe?). Each state knows which is the next state, depending on who won the next point.

The nodes in the state machine don’t track the actual points count, instead it’s part of their identity/name to know what is the result.

Each state does know (possible a smell?) what is their String representation, but the actual formatting (plus interpolation) happens at the TennisGame1#score method.

class TennisGame1 def initialize ( player1Name , player2Name ) @player_1_name = player1Name @player_2_name = player2Name @game = Tennis :: LoveAll . new end def won_point ( playerName ) if playerName == @player_1_name @game = @game . player_1_score else @game = @game . player_2_score end end def score @game . score % { player_1: @player_1_name , player_2: @player_2_name } end end module Tennis class LoveAll def score ; "Love-All" end def player_1_score ; FifteenLove . new end def player_2_score ; LoveFifteen . new end end class FifteenLove def score ; "Fifteen-Love" end def player_1_score ; ThirtyLove . new end def player_2_score ; FifteenAll . new end end class ThirtyLove def score ; "Thirty-Love" end def player_1_score ; FortyLove . new end def player_2_score ; ThirtyFifteen . new end end class FortyLove def score ; "Forty-Love" end def player_1_score ; WinPlayer_1 . new end def player_2_score ; FortyFifteen . new end end class LoveFifteen def score ; "Love-Fifteen" end def player_1_score ; FifteenAll . new end def player_2_score ; LoveThirty . new end end class LoveThirty def score ; "Love-Thirty" end def player_1_score ; FifteenThirty . new end def player_2_score ; LoveForty . new end end class LoveForty def score ; "Love-Forty" end def player_1_score ; FifteenForty . new end def player_2_score ; WinPlayer_2 . new end end class FifteenAll def score ; "Fifteen-All" end def player_1_score ; ThirtyFifteen . new end def player_2_score ; FifteenThirty . new end end class ThirtyFifteen def score ; "Thirty-Fifteen" end def player_2_score ; ThirtyAll . new end def player_1_score ; FortyFifteen . new end end class FortyFifteen def score ; "Forty-Fifteen" end def player_1_score ; WinPlayer_1 . new end def player_2_score ; FortyThirty . new end end class ThirtyAll def score ; "Thirty-All" end def player_1_score ; FortyThirty . new end def player_2_score ; ThirtyForty . new end end class FortyThirty def score ; "Forty-Thirty" end def player_1_score ; WinPlayer_1 . new end def player_2_score ; Deuce . new end end class WinPlayer_1 def score ; "Win for %{player_1}" end end class WinPlayer_2 def score ; "Win for %{player_2}" end end class Deuce def score ; "Deuce" end def player_1_score ; AdvantagePlayer_1 . new end def player_2_score ; AdvantagePlayer_2 . new end end class AdvantagePlayer_1 def score ; "Advantage %{player_1}" end def player_1_score ; WinPlayer_1 . new end def player_2_score ; Deuce . new end end class AdvantagePlayer_2 def score ; "Advantage %{player_2}" end def player_1_score ; Deuce . new end def player_2_score ; WinPlayer_2 . new end end class FifteenThirty def score ; "Fifteen-Thirty" end def player_1_score ; ThirtyAll . new end def player_2_score ; FifteenForty . new end end class FifteenForty def score ; "Fifteen-Forty" end def player_2_score ; WinPlayer_2 . new end end class ThirtyForty def score ; "Thirty-Forty" end def player_1_score ; Deuce . new end def player_2_score ; WinPlayer_2 . new end end end

Summary

Those lessons are not all, I just picked the ones I thought were the most important.

It was a nice experience overall and I learnt a lot from doing the kata. I have recorded the YouTube videos along the way and it was nice to receive feedback from the audience which of my changes could be better (thank you everyone!).

The sad thing is that I’m still not satisfied with the end result code, but on the more optimistic side is that I like the current solution better than the initial one.

Such katas are a wonderful way of practicing outside of our commercial projects, while the lessons can be incorporated into our daily coding sessions.

If you’d like to follow my next such coding sessions and/or watch my other software/Ruby/DDD/TDD-related thoughts, follow us on the Arkency YouTube channel, thank you!!