"I still can't detect a non-existing index using the above code."
If the goal is purely to validate the existence of an index in an array, then the ideal approach would be to use a function like the following:
function isValidIndex(arr, index) {
/*
Validates given index by checking if it is:
1. An integer,
2. Non-negative (0 or positive),
3. Within the bounds of the given array.
*/
return Number.isInteger(index) && index >= 0 && index < arr.length;
}
This function accurately evaluates the existence of the given index
in the specified arr
efficiently and avoids some potential issues that could arise if using some of the other mentioned techniques, such as...
1. Dependency on the Element Value (Using typeof
or Optional Chaining):
Whether or not an array has a valid index of the specified value should not depend on the value of the element at that index.
Using if (typeof array[index] === 'undefined')
, the condition is...
"If the element, if any, of this array at the specified index is undefined
...",
which is not the same as...
"If this array has an element at the specified index...".
It's possible for the array to have an element at that index with an empty slot or undefined
value, which would result in a false negative from the check.
JavaScript arrays are technically a predefined object with methods and properties rather than an explicit data type. Array
elements are actually stored as object properties with the index as the property name. length
is a special Array
property that's automatically updated to reflect the highest index + 1.
Because of this, an array can be instantiated with a given length, but containing no elements, and the value of the array's length
property will reflect the length specified upon instantiation.
For example:
const arr = new Array(5); // arr.length === 5
console.log(arr); // [ <5 empty items> ]
This results in a "sparse array", which contains empty slots, despite having valid indices.
Similar to the typeof`` technique, using
arr?.[index]has value dependency and will return
undefinedfor an index that ***does*** exist but has an empty slot or an
undefined` value.
Additionally, these techniques lack inherent type and range checking for the index itself, which could cause unexpected results if a non-integer or out-of-range value is somehow passed to the function.
2. Value not Index Checking (The includes()
Method):
Using the includes()
method doesn't validate the existence of an index, but rather the existence of a value within the array.
For example:
const arr = [1, 3, 5];
console.log(arr.includes(3)); // true
The method checks if the value 3
exists within the array, not if the array has index 3
.
In this case, the method would return true
because the array contains the value 3
, which would be a false positive for checking if the index 3
exists, as the array only has the indices 0
, 1
, and 2
.
In any case, the value could exist at multiple indices, or not at all, and it would still return true
or false
respectively.
3. Performance Hit Using the in
Operator:
The in
operator is used to check if a property exists in an object and is a valid way to check if an index exists in an array. However, it isn't the most efficient way to verify an index's existence because:
1) It checks if the property exists in the object OR its prototype chain, which is unecessary for arrays
and can also potentially result in false positives if the property is inherited from the object's prototype.
2) It doesn't inherently check the type or range of the index, meaning additional checks would be necessary to ensure the index is a valid integer within the bounds of the array, adding complexity and possibly impacting performance.
&&
) between the individual conditions.