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Multiplication of two numbers can be algorithmically defined like so: 'add the first number to itself a number of times equal to the value of the second number'. Exponentiation of two numbers can be algorithmically defined like so: 'multiply the first number by itself a number of times equal to the value of the second number'. Thinking about those definitions for multiplication and exponentiation raises a few questions...

Firstly, can a class of arithmetic operations be defined by starting with addition as the fundamental operation? I wrote up some haskell code to test that idea:

order1 x y = x + y
order2 x y = foldl (order1) x (replicate (y - 1) x)
order3 x y = foldl (order2) x (replicate (y - 1) x)
order4 x y = foldl (order3) x (replicate (y - 1) x)
order5 x y = foldl (order4) x (replicate (y - 1) x)

Sure enough, the meaning of 'order2' is multiplication and the meaning of 'order3' is exponentiation. The english language, as far as I know, lacks words for 'orderN' where N > 3. Does the mathematical community have anything interesting to say about these operations?

Also, given the recursive appearance of those 'order' functions, how might one write a function like this:

generalArithmetic :: Int -> Int -> Int -> Int
generalArithmetic n x y =   --Comment: what to put here?

that means multiplication when n equals 2, means exponentiation when n equals 3 ...?

Also, how might one generalize these arithmetic functions so that they could operate on all real numbers? The type of 'replicate' is, after all, Int -> a -> [a].

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en.wikipedia.org/wiki/Tetration –  Matt Bryant Aug 5 '13 at 22:15
The general expression is hyperoperation. –  leftaroundabout Aug 5 '13 at 22:16
Multiplication/exponentiation of natural numbers can be defined as repeated applications of a "lower order" operation. It's harder to say what it means to interpret "x ^ -7.6" as "multiply x by itself -7.6 times". –  Ben Aug 6 '13 at 2:36

2 Answers 2

Yes. You can start with peano arithmetic as the first order (increment)

Brainf*ck only has increment, decrement, and checks for non-zero value. Even with this it can do any computation any other computer program can do as long as it always has enough memory and you are not in a hurry to get the answer.

Such property is called Turing completeness and Brainf*ck is such even without input and output. Thus with <, >, +, -, [, and ] you can make a program to solve all math problems solvable by other programming languages.

So far I have made programs that do addition, subtraction, averages, multiplication, division, modulus and square root with it.

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In case anybody cares about a definition for what I earlier called 'generalArithmetic', here it is:

arithmetic n x y = if n == 0
                   then (x + y)
                   else foldl (arithmetic (n - 1)) x (replicate (y - 1) x)
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If this were some real-world-thing and you'd care about efficiency at all, you'd also want to handle n == 1 and n == 2 as special cases and use builtin multiplication and exponentiation there. –  Mike Hartl Aug 6 '13 at 4:30

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