Encapsulation vs Business Rules

No Naked Primitives is a Coderetreat constraint which trains our object orientation skills. No primitive values, e.g. booleans, numbers or strings, must be visible at object boundaries, i.e. public methods. Arrays and other containers like lists or hash-tables are primitives, too. I love this constraint, as it pushes people right out of their comfort zone. ;-) (I wrote about No Naked Primitives in combination with other constraints and included it in the expert level Brutal Coding Constraints.)

Value Objects
The usual designs to avoid naked primitives are Value Objects and First Class Collections. Value Objects, by design, expose the values they wrap with a getter because some other objects will want to use these values. What happens if I go extreme and do not allow any primitives at object boundaries? (Of course this is crazy, a clear case of Primitive Obsession Obsession. Still when Coderetreat facilitators get together to practice, things end up like that.) Let us take the Game of Life as an example. (If you do not know the Game of Life, read the description and implement it right away.) In the game, for evolving a generation, I need to count the living neighbours of each cell. The number of living neighbours is an integer and its value object in C# could look like

public class NeighbourCount {
    private int count;
    
    public NeighbourCount(int count) {
        this.count = count;
    }

    // ... code to manage the count

}

Now any code which depends on the data (i.e. the count) will have to be moved into the value object to be able to access the data. Following the rules of the game, if there are two or three living neighbours, a living cell lives on. The method Apply​Rules​OnLiving​Cell implements this rule.

public class NeighbourCount {

    // ...

    public GridSpace ApplyRulesOnLivingCell() {
        if (this.count == 2 || this.count == 3) {
            return new AliveCell();   
        }
        return new EmptySpace();
    }
}

public interface GridSpace {}
public class EmptySpace : GridSpace {}
public class AliveCell : GridSpace {}

Grouping the data (count) and the logic which is based on the data, uses or modifies it (Apply​Rules​OnLiving​Cell) together is a core principle of object orientation. Further all data is strongly encapsulated.

Polymorphism
The next method Apply​Rules​OnEmpty​Space is similar. The decision which of the two methods to call depends on the state of the cell, which is either alive or dead/non existing. This boolean state has to be encapsulated inside a class, e.g. class GridSpace. This class behaves differently for the values of the boolean state, which makes the boolean a simple type code. The object oriented way to work with type codes is to use polymorphism:

public interface GridSpace {
    public GridSpace ApplyRulesWith(NeighbourCount count);
}
public class AliveCell : GridSpace {
    public GridSpace ApplyRulesWith(NeighbourCount count) {
        return count.ApplyRulesOnLivingCell();
    }
}
public class EmptySpace : GridSpace {
    public GridSpace ApplyRulesWith(NeighbourCount count) {
        return count.ApplyRulesOnEmptySpace();
    }
}

The code looks weird and it is not my usual implementation of the game's rules. It has an issue: The rules of the game are distributed among three classes. This is Shotgun Surgery - when a single change is made to multiple classes simultaneously: If I need to change the rules, or even want to read and understand the logic of cell evolution, I have to go to three places.

Business Rules
On the other hand, a basic implementation of the rules using primitives (e.g. in Ruby because polyglot programming is cool),

def alive_in_next_generation(alive, living_neighbours)
  (alive and living_neighbours == 2) or 
  living_neighbours == 3
end

is one line of code and easy to understand. The game's rules - the business rules - are boolean expressions describing certain situations, which "the business" needs to act on. Typical examples of such situations are when an item is out of stock or a client qualifies for a discount. Business related conditions are called policies. (And there are predicates, which are boolean expressions, too. These have their origins in formal logic.) Boolean expression are functional in nature. So a functional design, i.e. functions operating on primitive data, could be more appropriate. Even in object oriented design there are use cases for objects containing only logic and no (mutable) data.

Conclusion
What is the point of my discussion? In the case of Game of Life, there is a tension between keeping data and its logic together versus keeping related logic together. This is particularly true for boolean expressions and code depending on them, as boolean values usually end up in conditionals. I like to keep "decisions" and the logic depending on them close together but I want to keep my business rules in one place even more. I am wondering if this is true for most design situations, besides Game of Life. Boolean logic is interesting because if allows variation in the automation. Code without any booleans is still useful, e.g. pure calculations or uniform transformations in a pipeline style of operations.

Taking it further?
While boolean is a primitive, it is different from other primitives. What happens if I do not allow any primitives besides boolean at object boundaries? The data of class NeighbourCount would still be encapsulated when I add relevant queries (in Python because I love programming languages):

class NeighbourCount:

  def __init__(self, count):
    self._count = count

  # ... code to manage the count

  def isTwoOrThree(self):
    return self._count == 2 or self._count == 3

  def isThree(self):
    return self._count == 3

Using these small methods, I get a concise implementation of the rules,

class Rules:
  def cellInNextGeneration(self, cell, count):
    if (cell.isAlive() and count.isTwoOrThree()) or count.isThree():
      return AliveCell()
    return EmptySpace()

Is this better? I am not sure. At least the (business) rules of the Game of Life are in one place now. They could be replaced with different rules if needed, making the design extensible. At the same time different rules would most likely require different queries in NeighbourCount. For example in Hex Life, I need a weighted sum of first and second tier living neighbours to decide the state of the next generation. This is not possible without adding new queries to NeighbourCount. The Open Closed Principle is not satisfied. (Then maybe Hex Life is too much of a change for any design to "survive".) My rules logic keeps calling into the encapsulated value object repeatedly, which looks much like Feature Envy. I feel like I am going in circles here ;-)

39 Years of Coding

Last week was my 39th anniversary of coding. I got a Commodore 64 as a present for Easter Sunday from my mother. I own an old image to prove that. The exact date is tricky: There are no time stamps on my files, I do not know how old my oldest programs are. I wish I had added comments with time stamps back then. I was able to pin down some programs, like demos, to the year they were created by investigating file names and scrolling messages. On of these attributes to Easter 1986, so my start must have been in 1985. One of my neighbours had made fun of people using the Commodore only to play games, and I had bought a book about coding BASIC even before I owned the machine. It was a nice book with exercises to write pieces of code into gaps in the text. I imagine I wrote some silly Hello World program right away on that Easter Sunday, which would have been 8th of April 1985.

BASIC
I spent a large part of my teens fiddling with the Commodore 64 and its BASIC. It will always have a special place in my heart. I never really left BASIC behind. From time to time, I code a little kata in the emulator, e.g. Prime Factors, Game of Life or several years later Roman Numerals. When learning a new programming language, my usual exercise is to create a Scheme (Lisp) interpreter, but I have also played with BASIC as a Scala DSL and even turned it upside down creating a BASIC parser in Scheme, using TDD, unit tests and a file watcher to run my tests for all modified files. It was a fun project and I stopped after parsing most of the BASIC code I was able to find on my old disks.

Monkeys Everywhere
So what did I do on the evening of my anniversary? I opened a can of energy drink and had a look at a new programming language. I went for Garmin Connect IQ, a platform by Garmin to build applications for their watches. While I did not own a Garmin device, I wanted to support a developer at my client who wanted to create her own specialised app for her watch.

Connect IQ reminds me a lot of Android: There is an SDK, support for various devices, an emulator, an API for different kinds of apps, an app store with review process and so on. It has manifests, permissions, storage, intents etc. Someone at Garmin had some humour, as the programming language is called Monkey C (with extension .mc), the build system is called Jungles (.jungle) and the system libraries use the Toybox namespace. They even have their own domain-specific property language for managing style elements, derived from CSS. The whole thing is branded with monkeys all over the place.

Using a small, proprietary language has disadvantages: There are only few public code samples to copy from and ChatGPT is unable to create any working code in Monkey C. Still I found everything I needed during that first evening: a minimalist Unit Testing framework and CLI commands to build and test my code. Piping the test output through a small shell script added ANSI colours, i.e. Red and Green respectively, to the test output. Perfection! In my tradition of learning new languages, I TDD'ed the Prime Factors code kata as first exercise:

import Toybox.Lang;

class PrimeFactors {

  static function generate(n as Integer) as Array<Integer> {
    var factors = [] as Array<Integer>;
    
    for (var candidate = 2; candidate <= n; candidate++) {
      while (n % candidate == 0) {
        factors.add(candidate);
        n = n / candidate;
      }
    }

    return factors;
  }

}

The language itself is object oriented and looks a lot like JavaScript with optional types, the as ... clauses. It is a compiled language and all type declarations are optional but can be forced with a compiler flag. I felt at home immediately. What a happy anniversary ;-)

Programming with Nothing

I like extreme coding constraints. A constraint, also known as an activity, is a challenge during a kata, coding dojo or code retreat designed to help participants think about writing code differently than they would otherwise. Every constraint has a specific learning goal in mind, for example Verbs instead of Nouns. After playing with basic constraints for a long time now, I need more challenging tasks. Combining existing constraints makes things harder: For example Object Callisthenics or my very own Brutal Coding Constraints are way harder than their parts applied individually.

Missing Feature Group of Constraints
There is a another group of extreme constraints which I call the Programming With Nothing constraints. They are a subgroup of the Only Use <placeholder> constraints. All of these belong to the Missing Feature group. The well known No If and No Naked Primitives constraints are good examples of Missing Features because we take away a single element that we are so very much used to. Only Use <placeholder> constraints force you to use new constructs instead of something else. For example, Alexandru Bolboaca, the pioneer of Coderetreat in Europe, once mentioned the following constraints to me: Only Bit Operations replaces all arithmetic operations, like plus or multiply, with bit operations and Only Regular Expressions asks you to use Regular Expressions as much as possible. You can get pretty far with Regular Expressions in exercises like Balanced Brackets, Coin Change, Snake or Word Wrap. (Look for the Bonus Round at the bottom of the Word Wrap page.)

Programming With Nothing
But let us get back to Programming With Nothing. The first one of this group, which I came across ten years ago, was presented by Tom Stuart in his 2011 Ru3y Manor talk Programming With Nothing. Tom is taking functional programming to the extreme, only allowing the declaration of lambda expressions and calling them. The exact rules he is following are:

• Create functions with one argument.
• Call functions and return a result.
• Assign functions to names (abbreviate them as constants).

Basically he is using the Lambda Calculus and this constraint is also referred to as Lambda Calculus. His talk is using Ruby, using only Proc.new, no booleans, numbers or strings, no assignments, control flow constructs or standard library. Clearly he is programming with nothing. (Here is the recording of the talk, his slides and the code.) Over the years I have seen similar presentations, even using Java.

The Fizz Buzz Kata
The goal is to implement the Fizz Buzz kata. While Fizz Buzz is very simple, it needs looping integer numbers up to 100, conditionals on integer comparison, integer division and strings. It is very small but not simple. Some people even use it during job interviews - which is controversial. The whole Fizz Buzz is:

for (i = 1; i <= 100; i++) {
  if (i % 3*5 == 0) 
    print("FizzBuzz");
  else if (i % 3 == 0) 
    print("Fizz");
  else if (i % 5 == 0) 
    print("Buzz");
  else 
    print(i);
}

And this is quite a lot if all you have is a lambda. I maintain a starting point for TypeScript, to be used in my workshops. This kind of exercise is fun, at least for me ;-). If you follow the assignment, i.e. work on numbers, then booleans, then pairs etc., you can use Git branches to jump to the next milestone - or take a sneak peak how it could be done.

Extreme Object-Orientation
In 2015 I watched John Cinnamond's Extreme Object-Oriented Ruby, which is like Tom Stuart's Programming with Nothing. This version only allowed you to define objects which contain other objects and call the nested object's methods or return them. In his starter repository he described how to simulate booleans, numbers and so on.

Nothing but NAND
Then I tried to write Fizz Buzz only using NAND. This is Programming With Nothing the hardware way. How so? A NAND gate is a logic gate which produces an output which is false only if all its inputs are true; thus its output is complement to that of an AND says Wikipedia. More importantly, the NAND gate is significant because any Boolean function can be implemented by using a combination of NAND gates. This property is called functional completeness.. Because of its functional completeness it should be possible to create arbitrary programs. I started out with a Bit class which had its nand() function implemented and all other code was built on top of this. Numbers, i.e. arrays of bits,

class Numbers {

  static final Byt ZERO = new Byt(OFF, OFF, OFF, OFF, OFF, OFF, OFF, OFF);

  // ...

  static final Byt FIFTEEN = new Byt(ON, ON, ON, ON, OFF, OFF, OFF, OFF);
  static final Byt HUNDRED = new Byt(OFF, OFF, ON, OFF, OFF, ON, ON, OFF);
}

and bitwise logic,

class Logic {

  static Bit eq(Bit a, Bit b) {
    return not(xor(a, b));
  }

  // ...

  static Byt and(Byt a, Byt b) {
    return not(nand(a, b));
  }

  // ...

  static Byt ifThenElse(Bit b, Byt theThen, Byt theElse) {
    Byt condition = Byt.from(b);
    return or(and(condition, theThen), 
              and(not(condition), theElse));
  }
}

were straight forward. Arithmetic was cumbersome due to possible over- and underflows.

class Arithmetic {

  static BitOverflow inc(Bit b) {
    return new BitOverflow(not(b), b);
  }

  static BitOverflow add(Bit a, Bit b) {
    return new BitOverflow(xor(a, b), and(a, b));
  }

  // ...

  static Byt inc(Byt a) {
    BitOverflow r0 = add(a.b0, Bit.ON);
    BitOverflow r1 = add(a.b1, r0.overflow);
    BitOverflow r2 = add(a.b2, r1.overflow);
    BitOverflow r3 = add(a.b3, r2.overflow);
    BitOverflow r4 = add(a.b4, r3.overflow);
    BitOverflow r5 = add(a.b5, r4.overflow);
    BitOverflow r6 = add(a.b6, r5.overflow);
    BitOverflow r7 = add(a.b7, r6.overflow);
    return new Byt(r0.b,r1.b,r2.b,r3.b,r4.b,r5.b,r6.b,r7.b);
  }
}

For loops I added a sequence of bits which worked as the Instruction Pointer. Using the IP and the existing arithmetic operations I implemented goto which I used to jump back during loops. The final code did not look much different than your regular structural code, using functions and mutable data. The exact list of things I used was:

• Data structures for a single bit, a byte (8 bits) and a series of bytes i.e. memory.
• Bit nand(Bit other) as the only logic provided.
• Getting and setting the values of the data structures.
• Defining functions with multiple statements to create and modify data and call other functions.
• A map to associate statements with memory addresses indexed by the IP. Was this cheating?

I had played with assembly in the past, which helped me to build my program from NANDs alone. It is a great learning exercise to understand computers' logical components and CPUs. There is even an educational game based on the idea of NAND.

What is Next?
I cannot remember how I ended up there, but next I tried to write Fizz Buzz using a Touring Machine. But this is a story for another time...