CSC/ECE 517 Fall 2011/ch1 1c cm: Difference between revisions

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==== Basic Algorithms ====
==== Basic Algorithms ====
The C++ proposal makes light of the fact that closures provide the ability to inject code into generic routines without the programmer having to provide adapters. "The lack of a syntactically light-weight way to define simple function objects is a hindrance to the effective use of several generic algorithms in the Standard Library [C++]
The C++ proposal makes light of the fact that closures provide the ability to inject code into generic routines without the programmer having to provide adapters. "The lack of a syntactically light-weight way to define simple function objects is a hindrance to the effective use of several generic algorithms in the Standard Library" [C++]


The classic for_each template algorithm in C++ is called using the following syntax:
The classic for_each template algorithm in C++ is called using the following syntax:

Revision as of 00:16, 6 September 2011

Introduction

Previous 517 classes have written about closures as implemented in several o-o languages, but this topic asks you to identify practical advantages of using closures over using methods. Give examples of programming problems that can be solved more concisely, more extensibly, or more elegantly using closures than using methods. Make sure the examples are organized into a coherent progression.

Definitions

Closures

"A closure is a function that captures the bindings of free variables in its lexical context."[gafter] In other words, a closure is a block of executable code together with a reference to the variables in scope at the site of its creation. These free variables are captured by the closure, and their lifetime is extended throughout the lifetime of the closure.

Closures can be created by defining a function within the body of another function as the following example illustrates. Note that the scope of the parameter n is limited to the inside of the addGen function. However, because addGen returns a closure, that closure has access to n whenever it is evoked.

def addGen(n)
    Proc.new { |x| x + n }
end

add5 = addGen(5)
add10 = addGen(10)

puts add5(6)      # 11
puts add10(6)     # 16

First-class functions

Closures are typically implemented as first-class functions. A first-class function is a function that can appear anywhere in a program that other first-class values (such as a number or a string) can appear. Namely, a first-class function can be assigned to a variable, passed as an argument to another function, and returned as the return value from a function.

Execution-time environment contains free variables

Early functional programming languages such as LISP relied upon dynamic scoping in which free variables are bound at run-time to the first matching variable name in the call stack. First the compiler would look inside the function for a definition of each variable. If none was found, it would next look at the calling function, and so on.

An example of dynamic scoping in a JavaScript-like language:

function alertX() {
    alert(x);           // Note that with dynamic scoping, x need not be defined at the site of the function declaration
}

function fun1() {
    var x = 10;
    alertX();           // 10
}

function fun2() {
    var x = "hello";
    alertX();           // hello
}

Closures, on the other hand, capture variables that are in scope at the time they are created, and the lifetime of those captured variables is extended throughout the lifetime of the closure. This is called lexical or static scoping. Free variables must be defined at compile time -- hence the name static scoping as opposed to dynamic scoping, where the values of free variables can only be known at run time. Closures were first implemented in the Scheme programming language in the 1960s.

The following example illustrates the fact that free variables inside of a closure are in fact bound to the variables defined at the site of the closure's definition. Here we have a function multipleClosures that returns two closures that both act on the variable i. Both are able to act on i though it is not in scope at the site where they are called but rather at the site where they were defined.

def multipleClosures
i = 0
[ Proc.new { i = i + 1 }, Proc.new { i = i - 1 } ]
end

closures = multipleClosures

puts closures[0].call    # 1
puts closures[0].call    # 2
puts closures[1].call    # 1

Methods

Object-oriented programming dates back to at least the middle 1960's. One of the fundamental principals of objects is the notion of encapsulation. One of the earliest descriptions of the methodology, dates back to a 1966 paper describing the SIMULA, a language designed to ease simulation of large systems. The SIMULA language used classes to encapsulate coupled procedures and data into an object, “an object is a self-contained program (block instance) having its own local data and actions defined by a 'class declaration'” [pg 6, Simula]. This 50 year-old concept of fields and procedures is central to the design of today's object-oriented languages such as Smalltalk, Java and C++. The method will be defined using the following criteria:

  • An object as first-class data which allows binding of
  1. finite set of static or instance data (commonly referred to as fields) created by the programmer which hold the state of the object referenced in the method call with implicit this or self
  2. procedures or actions modifying the data to change the state of the object

Instance or static class functions

Our definition of a method requires functions which can be bound to a first-class object. All object-oriented languages provide this construct. We can create objects and pass those objects around to be executed by other objects or in the global environment. Methods receive an implicit 'this' pointer which givens the execution context access to fields of the object.

Execution-time environment contains instance or static variables

The second point of the method definition is that the we can bind static or instance data to our first-class data object. All object-oriented language also provide this construct.

Closures vs. Methods - Benefits of Closures

Where the benefits of methods have been demonstrated in object-oriented systems, closures are finding their way into languages which haven't had them in the past, like C++ and Java. The C++ proposal for extending the language lists some of the benefits of supporting closures in the traditionally OO language, including notational simplicity, code sharing of common algorithms, and generality [Lamba]. The IBM developerWorks site article lists the some common usages of closures as customization, iterating across collections, and managing resources and enforcing policy.

We will broadly break these down into examples where Closure provide a clean implementation.

  • Generic algorithms - iterating across collections
  • Callbacks - customizing behavior
  • Managing resources and enforcing policy (this is new)

Generic Algorithms

We can break the generic algorithms down further into the follow examples.

  • basic algorithm syntax
  • parallel programming (e.g. the MapReduce problem)

Basic Algorithms

The C++ proposal makes light of the fact that closures provide the ability to inject code into generic routines without the programmer having to provide adapters. "The lack of a syntactically light-weight way to define simple function objects is a hindrance to the effective use of several generic algorithms in the Standard Library" [C++]

The classic for_each template algorithm in C++ is called using the following syntax:

template <class InputIterator, class OutputIterator, class UnaryFunction>
OutputIterator transform(InputIterator first, InputIterator last,
                         OutputIterator result, UnaryFunction op);
{
   for ( ; first != last; ++first, ++result ) *result = op(*first);
   return result;
}

Because C++ does not have Closures, the fourth parameter requires either a named function or an object which supports "operator ()".

// static function
int multiply_2(int x) 
{
   return x * 2;
}
class multiply_it
{
   int multiplier;
   multiple_it(int x) : multiplier(x) {}
   int operator()(int x) const { return x * multiplier }
}

std::vect test(3,10);
std::vect output(3);

std::transform( test.begin(), test.end(), output.begin(), multiply )
std::transform( test.begin(), test.end(), output.begin(), multiply_it(2) )

If we use the static function and we want to change the multiply function, we either have to create a new named function or create a global variable and make sure the global variable is set correctly before the function is executed. Using the function object, we have can easily change the multiplier, but we were forced to create and manage a new class specifically for the integer multiply.

Consider the same code using Ruby and a Closure where the each function where the developer can pass a code block.

test = [10,10,10]
output = test.collect { |x| x * 2 }

The Closure is syntactically much cleaner.

Parallel Programming - Map Reduce

Google popularized the technique of Map Reduction with its search algorithm that simultaneously runs the same search algorithm on multiple threads and combines the results to produce a single answer. Within a programming environment Closures allow parallelized reduction.

The following Ruby example is taken from [pg 382, Ruby] as an example of performing a multi-threaded concurrent map and reduce using a thread per Closure.

module Enumerable
  def con_map(&block)
    threads = []
    self.each do |item|
        threads << Thread.new { block.call(item) }
    end
    threads.map { |t| t.value }
  end
end

input = ['file1.txt','file2.txt','file3.txt']
lines = {}
total_lines = 0
output = input.con_map { 
  |file| 
  lines[file] = 0
  IO.foreach(file) { 
    |in_line| lines[file] += 1
    puts "adding #{file} #{lines[file]} #{in_line}\n"
  }
  lines[file]
}.reduce {
  |total, val| total+=val
}

The example counts

Callbacks

Callbacks are often cited as the most desirable application of Closures because the environment around the callback is initialized without programmer intervention. In languages that don't provide Closures, interfaces, fields, or even parameters may have to be added to provide thunking and state information to object being called.

There are several forms of callbacks that can demonstrate this capability.

  • GUI behavior injection
  • generic exception handling

GUI behavior Injection

Behavior injection is used heavily in Javascript libraries where they allow the creation of generic libraries which can be easily extended using a provided function.

Below is an example using the JQuery bind method to provide some capability to an event framework.

$("p").bind("mouseenter", 
   function(event) {
     $(this).toggleClass('someclass');
   }
)

The Closure is created in the context of each selected DOM object (in this case those objects with type of "p"). The anonymous function is then called when the "mouseenter" event fires. The context of the this pointer is unique to each DOM object because the Closure captured the environment (object) at the time of function creation.

Consider the same callback behavior in a language like Java which does not provide Closures.

public class MouseClick implements MouseListener {
  [... class implementation ...]
  public void mousePressed(MouseEvent e) {
   this.toggleClass;
  }
}
window.addMouseListener( [instance of MouseClick class] );

We must first define the interface or function which will provide the callback. It must provide the context under which the callback will execute. If we want access to more of the environment we must make provisions in the MouseClick class by adding state variables or pointers to the environment under which it was instanced.

Generic Exception Handling

It can be useful in exception handling because the context of the executing is maintained in the Closure. We had a guarantee that the objects referenced will still be in scope when the exception is taken.

Resource Management / Policy Enforcement

Closures allow the creation of policies within an application or class. Closures allow injection of user specified code within the generic policy.

  • maintaining resources
  • resource policy

Maintaining Resources - Simple

This often cited example shows the encapsulation of file base policy using a Closure.

file = fopen(local_filename, 'w')
fwrite(file, doc);
fclose(file)
File.open(local_filename, 'w') { |f| f.write(doc) }

The Closure is passed to the open method call along with the environment that contains the doc variable.

Resource Policy

The IBM developerWorks site gives an excellent example of a database policy in Ruby.

def do_transaction
   begin
      setup_transaction
      yield
      commit_transaction
   rescue
      roll_back_transaction
   end
end

The user of this policy would be able to call the do_transaction method, providing a Closure that will execute between steps of setup and commit.

Topical References

External Links

[Ruby] Flanagan, David and Yukihiro Matsumoto, The Ruby Programming Language. Sebastopol: O'Reilly Media, Inc., 2008. http://oreilly.com/catalog/9780596516178

http://martinfowler.com/bliki/Closure.html

http://gafter.blogspot.com/2007/01/definition-of-closures.html

http://jibbering.com/faq/notes/closures/

http://onestepback.org/articles/invitationtoruby/reason4.html

http://www.skorks.com/2010/05/closures-a-simple-explanation-using-ruby/

http://www.ibm.com/developerworks/java/library/j-cb01097/index.html

http://samdanielson.com/2007/9/6/an-introduction-to-closures-in-ruby

http://csharpindepth.com/Articles/Chapter5/Closures.aspx

http://en.wikipedia.org/wiki/Closure_(computer_science)

http://ynniv.com/blog/2007/08/closures-in-python.html