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Lua - Iterators
Iterator is a construct that enables you to traverse through the elements of the so called collection or container. In Lua, these collections often refer to tables, which are used to create various data structures like array.
Example - Generic For Iterator
A generic for iterator provides the key value pairs of each element in the collection. A simple example is given below.
main.lua
-- Initialize an array
array = {"Lua", "Tutorial"}
-- loop through array elements and print them
for key,value in ipairs(array)
do
print(key, value)
end
Output
When we run the above code, we will get the following output −
1 Lua 2 Tutorial
The above example uses the default ipairs iterator function provided by Lua.
In Lua we use functions to represent iterators. Based on the state maintenance in these iterator functions, we have two main types −
- Stateless Iterators
- Stateful Iterators
Example - Stateless Iterators
By the name itself we can understand that this type of iterator function does not retain any state.
Let us now see an example of creating our own iterator using a simple function that prints the squares of n numbers.
main.lua
-- define a function to get squre of an element
function square(iteratorMaxCount,currentNumber)
if currentNumber<iteratorMaxCount
then
currentNumber = currentNumber+1
return currentNumber, currentNumber*currentNumber
end
end
-- iterate from 1 to n and get square
for i,n in square,3,0
do
print(i,n)
end
Output
When we run the above program, we will get the following output−
1 1 2 4 3 9
Example - Custom Iterator
The above code can be modified slightly to mimic the way ipairs function of iterators work. It is shown below.
main.lua
-- define a function to get squre of an element
function square(iteratorMaxCount,currentNumber)
if currentNumber<iteratorMaxCount
then
currentNumber = currentNumber+1
return currentNumber, currentNumber*currentNumber
end
end
function squares(iteratorMaxCount)
return square,iteratorMaxCount,0
end
-- iterate from 1 to n and get square
for i,n in squares(3)
do
print(i,n)
end
Output
When we run the above program, we will get the following output−
1 1 2 4 3 9
Example - Stateful Iterators
The previous example of iteration using function does not retain the state. Each time the function is called, it returns the next element of the collection based on a second variable sent to the function. To hold the state of the current element, closures are used. Closure retain variables values across functions calls. To create a new closure, we create two functions including the closure itself and a factory, the function that creates the closure.
Let us now see an example of creating our own iterator in which we will be using closures.
main.lua
-- Initialize an array
array = {"Lua", "Tutorial"}
-- return a stateful iterator to get values of collection passed
function elementIterator (collection)
local index = 0
local count = #collection
-- The closure function is returned
return function ()
index = index + 1
if index <= count
then
-- return the current element of the iterator
return collection[index]
end
end
end
for element in elementIterator(array)
do
print(element)
end
Output
When we run the above program, we will get the following output−
Lua Tutorial
In the above example, we can see that elementIterator has another method inside that uses the local external variables index and count to return each of the element in the collection by incrementing the index each time the function is called.
We can create our own function iterators using closure as shown above and it can return multiple elements for each of the time we iterate through the collection.