CSC/ECE 517 Fall 2007/wiki1 3 c1: Difference between revisions

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= Currying =
== Currying ==
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Languages like ML, Haskell and Ruby support currying by providing built in support. These languages have functionalities which allow certain multi-argument functions getting expanded to their curried form. In general, languages that support closures can be used to write curried functions.
Languages like ML, Haskell and Ruby support currying by providing built in support. These languages have functionalities which allow certain multi-argument functions getting expanded to their curried form. In general, languages that support closures can be used to write curried functions.


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== The Mathematical Concept of Currying ==
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The concept of currying has been borrowed from mathematics. We have simple mathematical concept which says that all the functions below are equivalent.
The concept of currying has been borrowed from mathematics. We have simple mathematical concept which says that all the functions below are equivalent.


<code><pre>
lambda { |a, b, c| ... }
lambda { |a, b, c| ... }
lambda { |a| lambda { |b| lambda { |c| ... } } } or
lambda { |a| lambda { |b| lambda { |c| ... } } } or
lambda { |a| lambda { |b, c| ... } }
lambda { |a| lambda { |b, c| ... } }
</pre></code>


In other words, a function’s arguments can be broken down the way liked by the programmer. We can apply a three-argument function to two arguments to get a one-argument function back and so on. Currying can be done explicitly with lambdas—say we want to curry two arguments into a three-argument function.
In other words, a function’s arguments can be broken down the way liked by the programmer. We can apply a three-argument function to two arguments to get a one-argument function back and so on. Currying can be done explicitly with lambdas—say we want to curry two arguments into a three-argument function.
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= Illustrations =
== Illustrations ==
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Let us illustrate this concept further with the help of two examples.  
Let us illustrate this concept further with the help of two examples.  
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== Example 1 ==
=== Example 1 ===
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'''
Let us consider a site which allows us to play music files. Now, for each music file we play,  
Let us consider a site which allows us to play music files. Now, for each music file we play,  
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== Example 2 ==
=== Example 2 ===
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The following program illustrates the concept of Currying using a simple example of a basic calculator.  
The following program illustrates the concept of Currying using a simple example of a basic calculator.  
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</pre></code>  
</pre></code>  
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= Features of Currying =
== Features of Currying ==
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= See Also =
== See Also ==
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= References =
== References ==
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Revision as of 00:53, 19 September 2007

Currying

Currying is a transformational technique in functional programming. It helps us to reduce the number of dangling arguments that are passed to a function, if we have some prior knowledge of the usage of that function. It helps to write code which is productive and elegant, though there is hardly any instance when it’s absolutely required. Christopher Strachey had coined the term "currying" in 1967 in reference to logician Haskell Curry.

In ordinary words, currying says that”if we fix some arguments of a function, we get a new function of the remaining arguments". For example, if function 'power(x, y)' stands for the calculating 'x raised to the power of y' then, square(x), cube(x) are other functions that implicitly fix one argument of y to either 2 or 3 for square and cube functions respectively. Thus we have reduced the number of arguments in the function on the cost of making it a more specific one.

Languages like ML, Haskell and Ruby support currying by providing built in support. These languages have functionalities which allow certain multi-argument functions getting expanded to their curried form. In general, languages that support closures can be used to write curried functions.

The Mathematical Concept of Currying

The concept of currying has been borrowed from mathematics. We have simple mathematical concept which says that all the functions below are equivalent.

lambda { |a, b, c| ... }
lambda { |a| lambda { |b| lambda { |c| ... } } } or
lambda { |a| lambda { |b, c| ... } }

In other words, a function’s arguments can be broken down the way liked by the programmer. We can apply a three-argument function to two arguments to get a one-argument function back and so on. Currying can be done explicitly with lambdas—say we want to curry two arguments into a three-argument function.

lambda { |c| oneArgFunc( 1, 2, c ) }

Two arguments curried in, one argument still dangling.

Illustrations

Currying in Ruby is pretty straight forward. Typically we use the 'lambda' method to curry the basic function to create new functions.

Let us illustrate this concept further with the help of two examples.

Example 1

Let us consider a site which allows us to play music files. Now, for each music file we play, the relevant information to be passed to play the system is Album Name, Track Number and Player to be used by that site. Let’s consider a scenario where a music site uses only one type of player every time. Let’s say the sites and player is – Mp3 Site (Jukebox Player). Instead of passing the same Player Name every time to the site, we can curry the player Name in the function Play and thus we’ll be sending the only minimum necessary parameters required to play the file while the site-specific information, i.e. the player name will be curried.

 def play(albumname,songname,player)
      @albumname = albumname
      @Trackname = songname
      @player = player
      puts "The album is #{@albumname} Track is #{@Trackname} and Player is #{@player}"
  end

#Using Curying
 
 mp3site = lambda{|albumname,songname| play(albumname,songname,"Jukebox")}

#Input Without Using Currying
 
 play("The Best of Bryan Adams", "Track 7", "Jukebox")
 play("MLTR", "Track 1"," Jukebox ")
 play("MLTR", "Track 11"," Jukebox ")

#Input Using Currying
 
 mp3site.call("The Best of Bryan Adams", "Track 7")
 mp3site.call("MLTR", "Track 1")
 mp3site.call("MLTR", "Track 11")

In real time scenario, we can put in the actual code which plays the requested file in the function 'play'. The primary purpose of the code is to show that we have all the values required to play the file.

Example 2

The following program illustrates the concept of Currying using a simple example of a basic calculator. The method calculator accepts two operands var1 & var2 performs the operation specified by 'op' on the two operands and returns the result. The method 'calculate' thus accepts 3 arguments. Now, calling this method again and again would lead to poor readbility. Instead by implementing currying we can improve the readability of the code. In the following code we have made use of the 'calculate' method with currying as well as without using curring. Places where 'calculate' is called using calculate(3,+,4) are instances where currying is not used.Places where either of 'add','sub','mul','div' have been used implements currying.


#definition of 'calculate' method

 def calculate(var1,op,var2)     
   if op == '+'
     return puts "The Result of addition is      : #{var1+var2}"
   elsif op == '-'
     return puts "The Result of subtraction is   : #{var1-var2}"
   elsif op == '*'
     return puts "The Result of multiplication is: #{var1*var2}"
   elsif op == '/'
     return puts "The Result of division is      : #{var1/var2}"
   else
     return puts "wrong choice ! "
   end
 end 
  
#Following 'calculate' method calls are without using currying 
 
  calculate(3,'+',4)
  calculate(4,'-',5)
  calculate(4,'*',2)
  calculate(4,'/',2)
 
#Currying Implementation using 'lambda' 
 
  add = lambda {|x , y| calculate(x,'+',y)}
  sub = lambda {|x , y| calculate(x,'-',y)}
  mul = lambda {|x , y| calculate(x,'*',y)}
  div = lambda {|x , y| calculate(x,'/',y)} 

#Following method calls are by using currying 
 
  add.call(3,4)
  sub.call(4,5)
  mul.call(4,2)
  div.call(4,2)

Features of Currying

1. The above examples illustrate that currying helps improve readability of code as it allows us to pass lesser number of arguments to the functions thus making the code easier to understand.

2. The reliability of the code, which is very essential for the reliability of th whole software application increases. This is because a major contributing factor of Software Reliability problems is the complexity of the underlying code. Currying tries to reduce this complexity by fixing the variables which will only take a fixed value and thus should not be left dangling for that particular function. For large applications, involving a lot of functions and variables - currying will be helpful.

3. The output of the code does not changes with currying. By fixing the parameters, we are only trying to avoid passing constant or redundant information every time with the function call. By using currying, the results of the code is not modified.

See Also

References