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In object-oriented programming, the iterator pattern is a design pattern in which an iterator is used to traverse a container and access the container's elements. The iterator pattern decouples algorithms from containers; in some cases, algorithms are necessarily container-specific and thus cannot be decoupled.
Contents
For example, the hypothetical algorithm SearchForElement can be implemented generally using a specified type of iterator rather than implementing it as a container-specific algorithm. This allows SearchForElement to be used on any container that supports the required type of iterator.
Definition
The essence of the Iterator Factory method Pattern is to "Provide a way to access the elements of an aggregate object sequentially without exposing its underlying representation.".
Language-specific implementation
Some languages standardize syntax. C++ and Python are notable examples.
C#
.NET Framework has special interfaces that support a simple iteration: System.Collections.IEnumerator over a non-generic collection and System.Collections.Generic.IEnumerator<T> over a generic collection.
C# statement foreach is designed to easily iterate through the collection that implements System.Collections.IEnumerator and/or System.Collections.Generic.IEnumerator<T> interface.
Example of using foreach statement:
C++
C++ implements iterators with the semantics of pointers in that language. In C++, a class can overload all of the pointer operations, so an iterator can be implemented that acts more or less like a pointer, complete with dereference, increment, and decrement. This has the advantage that C++ algorithms such as std::sort can immediately be applied to plain old memory buffers, and that there is no new syntax to learn. However, it requires an "end" iterator to test for equality, rather than allowing an iterator to know that it has reached the end. In C++ language, we say that an iterator models the iterator concept.
Java
Java has the Iterator interface.
As of Java 5, objects implementing the Iterable interface, which returns an Iterator from its only method, can be traversed using the enhanced for loop syntax. The Collection interface from the Java collections framework extends Iterable.
JavaScript
JavaScript, as part of ECMAScript 6, supports the iterator pattern with any object that provides a next() method, which returns an object with two specific properties: done and value. Here's an example that shows a reverse array iterator:
Most of the time, though, what you want is to provide Iterator semantics on objects so that they can be iterated automatically via for...of loops. Some of JavaScript's built-in types such as Array, Map, or Set already define their own iteration behavior. You can achieve the same effect by defining an object's meta @@iterator method, also referred to by Symbol.iterator. This creates an Iterable object.
Here's an example of a range function that generates a list of values starting from start to end, exclusive, using a regular for loop to generate the numbers:
The iteration mechanism of built-in types, like strings, can also be manipulated:
PHP
PHP supports the iterator pattern via the Iterator interface, as part of the standard distribution. Objects that implement the interface can be iterated over with the foreach language construct.
Example of patterns using PHP:
OUTPUT
string(15) "Design Patterns" string(16) "PHP7 is the best" string(13) "Laravel Rules" string(9) "DHH Rules"Python
Python prescribes a syntax for iterators as part of the language itself, so that language keywords such as for work with what Python calls sequences. A sequence has an __iter__() method that returns an iterator object. The "iterator protocol" requires next() return the next element or raise a StopIteration exception upon reaching the end of the sequence. Iterators also provide an __iter__() method returning themselves so that they can also be iterated over e.g., using a for loop. Generators are available since 2.2.
In Python 3, next() was renamed __next__().