Three main options:

1. for (var i = 0; i < xs.length; i++) { console.log(xs[i]); }
2. xs.forEach((x, i) => console.log(x));
3. for (const x of xs) { console.log(x); }

Detailed examples are below.

1. Sequential for loop:

var myStringArray = ["Hello","World"];
var arrayLength = myStringArray.length;
for (var i = 0; i < arrayLength; i++) {
    console.log(myStringArray[i]);
    //Do something
}

Pros

• Works on every environment
• You can use break and continue flow control statements

Cons

• Too verbose
• Imperative
• Easy to have off-by-one errors (sometimes also called a fence post error)

2. Array.prototype.forEach:

The ES5 specification introduced a lot of beneficial array methods. One of them, the Array.prototype.forEach, gave us a concise way to iterate over an array:

const array = ["one", "two", "three"]
array.forEach(function (item, index) {
  console.log(item, index);
});

Being almost ten years as the time of writing that the ES5 specification was released (Dec. 2009), it has been implemented by nearly all modern engines in the desktop, server, and mobile environments, so it's safe to use them.

And with the ES6 arrow function syntax, it's even more succinct:

array.forEach(item => console.log(item));

Arrow functions are also widely implemented unless you plan to support ancient platforms (e.g., Internet Explorer 11); you are also safe to go.

Pros

• Very short and succinct.
• Declarative

Cons

• Cannot use break / continue

Normally, you can replace the need to break out of imperative loops by filtering the array elements before iterating them, for example:

array.filter(item => item.condition < 10)
     .forEach(item => console.log(item))

Keep in mind if you are iterating an array to build another array from it, you should use map. I've seen this anti-pattern so many times.

Anti-pattern:

const numbers = [1,2,3,4,5], doubled = [];

numbers.forEach((n, i) => { doubled[i] = n * 2 });

Proper use case of map:

const numbers = [1,2,3,4,5];
const doubled = numbers.map(n => n * 2);

console.log(doubled);

Also, if you are trying to reduce the array to a value, for example, you want to sum an array of numbers, you should use the reduce method.

Anti-pattern:

const numbers = [1,2,3,4,5];
const sum = 0;
numbers.forEach(num => { sum += num });

Proper use of reduce:

const numbers = [1,2,3,4,5];
const sum = numbers.reduce((total, n) => total + n, 0);

console.log(sum);

3. ES6 for-of statement:

The ES6 standard introduces the concept of iterable objects and defines a new construct for traversing data, the for...of statement.

This statement works for any kind of iterable object and also for generators (any object that has a \[Symbol.iterator\] property).

Array objects are by definition built-in iterables in ES6, so you can use this statement on them:

let colors = ['red', 'green', 'blue'];
for (const color of colors){
    console.log(color);
}

Pros

• It can iterate over a large variety of objects.
• Can use normal flow control statements (break / continue).
• Useful to iterate serially asynchronous values.

Cons

• If you are targeting older browsers, the transpiled output might surprise you.

Do not use for...in

@zipcodeman suggests the use of the for...in statement, but for iterating arrays for-in should be avoided, that statement is meant to enumerate object properties.

It shouldn't be used for array-like objects because:

• The order of iteration is not guaranteed; the array indexes may not be visited in numeric order.
• Inherited properties are also enumerated.

The second point is that it can give you a lot of problems, for example, if you extend the Array.prototype object to include a method there, that property will also be enumerated.

For example:

Array.prototype.foo = "foo!";
var array = ['a', 'b', 'c'];

for (var i in array) {
    console.log(array[i]);
}

The above code will console log "a", "b", "c", and "foo!".

That can be particularly a problem if you use some library that relies heavily on native prototypes augmentation (such as MooTools).

The for-in statement, as I said before, is there to enumerate object properties, for example:

var obj = {
    "a": 1,
    "b": 2,
    "c": 3
};

for (var prop in obj) {
    if (obj.hasOwnProperty(prop)) {
        // or if (Object.prototype.hasOwnProperty.call(obj,prop)) for safety...
        console.log("prop: " + prop + " value: " + obj[prop])
    }
}

In the above example, the hasOwnProperty method allows you to enumerate only own properties. That's it, only the properties that the object physically has, no inherited properties.

I would recommend you to read the following article:

• Enumeration VS Iteration

TL;DR

• Your best bets are usually

  • a for-of loop (ES2015+ only; spec | MDN) - simple and async-friendly

    for (const element of theArray) {
        // ...use `element`...
    }
    

  • forEach (ES5+ only; spec | MDN) (or its relatives some and such) - not async-friendly (but see details)

    theArray.forEach(element => {
        // ...use `element`...
    });
    

  • a simple old-fashioned for loop - async-friendly

    for (let index = 0; index < theArray.length; ++index) {
        const element = theArray[index];
        // ...use `element`...
    }
    

  • (rarely) for-in with safeguards - async-friendly

    for (const propertyName in theArray) {
        if (/*...is an array element property (see below)...*/) {
            const element = theArray[propertyName];
            // ...use `element`...
        }
    }
    

• Some quick "don't"s:

  • Don't use for-in unless you use it with safeguards or are at least aware of why it might bite you.
  • Don't use map if you're not using its return value.
    (There's sadly someone out there teaching map [spec / MDN] as though it were forEach — but as I write on my blog, that's not what it's for. If you aren't using the array it creates, don't use map.)
  • Don't use forEach if the callback does asynchronous work and you want the forEach to wait until that work is done (because it won't).

But there's lots more to explore, read on...

JavaScript has powerful semantics for looping through arrays and array-like objects. I've split the answer into two parts: Options for genuine arrays, and options for things that are just array-like, such as the arguments object, other iterable objects (ES2015+), DOM collections, and so on.

Okay, let's look at our options:

For Actual Arrays

You have five options (two supported basically forever, another added by ECMAScript 5 ["ES5"], and two more added in ECMAScript 2015 ("ES2015", aka "ES6"):

1. Use for-of (use an iterator implicitly) (ES2015+)
2. Use forEach and related (ES5+)
3. Use a simple for loop
4. Use for-in correctly
5. Use an iterator explicitly (ES2015+)

(You can see those old specs here: ES5, ES2015, but both have been superceded; the current editor's draft is always here.)

Details:

1. Use for-of (use an iterator implicitly) (ES2015+)

ES2015 added iterators and iterables to JavaScript. Arrays are iterable (so are strings, Maps, and Sets, as well as DOM collections and lists, as you'll see later). Iterable objects provide iterators for their values. The new for-of statement loops through the values returned by an iterator:

const a = ["a", "b", "c"];
for (const element of a) { // You can use `let` instead of `const` if you like
    console.log(element);
}
// a
// b
// c

It doesn't get simpler than that! Under the covers, that gets an iterator from the array and loops through the values the iterator returns. The iterator provided by arrays provides the values of the array elements, in order beginning to end.

Notice how element is scoped to each loop iteration; trying to use element after the end of the loop would fail because it doesn't exist outside the loop body.

In theory, a for-of loop involves several function calls (one to get the iterator, then one to get each value from it). Even when that's true, it's nothing to worry about, function calls are very cheap in modern JavaScript engines (it bothered me for forEach [below] until I looked into it; details). But additionally, JavaScript engines optimize those calls away (in performance-critical code) when dealing with native iterators for things like arrays.

for-of is entirely async-friendly. If you need the work in a loop body to be done in series (not in parallel), an await in the loop body will wait for the promise to settle before continuing. Here's a silly example:

function delay(ms) {
    return new Promise(resolve => {
        setTimeout(resolve, ms);
    });
}

async function showSlowly(messages) {
    for (const message of messages) {
        await delay(400);
        console.log(message);
    }
}

showSlowly([
    "So", "long", "and", "thanks", "for", "all", "the", "fish!"
]);
// `.catch` omitted because we know it never rejects

Note how the words appear with a delay before each one.

It's a matter of coding style, but for-of is the first thing I reach for when looping through anything iterable.

2. Use forEach and related

In any even vaguely-modern environment (so, not IE8) where you have access to the Array features added by ES5, you can use forEach (spec | MDN) if you're only dealing with synchronous code (or you don't need to wait for an asynchronous process to finish during the loop):

const a = ["a", "b", "c"];
a.forEach((element) => {
    console.log(element);
});

forEach accepts a callback function and, optionally, a value to use as this when calling that callback (not used above). The callback is called for each element in the array, in order, skipping non-existent elements in sparse arrays. Although I only used one parameter above, the callback is called with three arguments: The element for that iteration, the index of that element, and a reference to the array you're iterating over (in case your function doesn't already have it handy).

Like for-of, forEach has the advantage that you don't have to declare indexing and value variables in the containing scope; in this case, they're supplied as arguments to the iteration function, and so nicely scoped to just that iteration.

Unlike for-of, forEach has the disadvantage that it doesn't understand async functions and await. If you use an async function as the callback, forEach does not wait for that function's promise to settle before continuing. Here's the async example from for-of using forEach instead — notice how there's an initial delay, but then all the text appears right away instead of waiting:

function delay(ms) {
    return new Promise(resolve => {
        setTimeout(resolve, ms);
    });
}

async function showSlowly(messages) {
    // INCORRECT, doesn't wait before continuing,
    // doesn't handle promise rejections
    messages.forEach(async message => {
        await delay(400);
        console.log(message);
    });
}

showSlowly([
    "So", "long", "and", "thanks", "for", "all", "the", "fish!"
]);
// `.catch` omitted because we know it never rejects

forEach is the "loop through them all" function, but ES5 defined several other useful "work your way through the array and do things" functions, including:

• every (spec | MDN) - stops looping the first time the callback returns a falsy value
• some (spec | MDN) - stops looping the first time the callback returns a truthy value
• filter (spec | MDN) - creates a new array including elements where the callback returns a truthy value, omitting the ones where it doesn't
• map (spec | MDN) - creates a new array from the values returned by the callback
• reduce (spec | MDN) - builds up a value by repeatedly calling the callback, passing in previous values; see the spec for the details
• reduceRight (spec | MDN) - like reduce, but works in descending rather than ascending order

As with forEach, if you use an async function as your callback, none of those waits for the function's promise to settle. That means:

• Using an async function callback is never appropriate with every, some, and filter since they will treat the returned promise as though it were a truthy value; they don't wait for the promise to settle and then use the fulfillment value.
• Using an async function callback is often appropriate with map, if the goal is to turn an array of something into an array of promises, perhaps for passing to one of the promise combinator functions (Promise.all, Promise.race, promise.allSettled, or Promise.any).
• Using an async function callback is rarely appropriate with reduce or reduceRight, because (again) the callback will always return a promise. But there is an idiom of building a chain of promises from an array that uses reduce (const promise = array.reduce((p, element) => p.then(/*...something using `element`...*/));), but usually in those cases a for-of or for loop in an async function will be clearer and easier to debug.

3. Use a simple for loop

Sometimes the old ways are the best:

const a = ["a", "b", "c"];
for (let index = 0; index < a.length; ++index) {
    const element = a[index];
    console.log(element);
}

If the length of the array won't change during the loop, and it's in highly performance-sensitive code, a slightly more complicated version grabbing the length up front might be a tiny bit faster:

const a = ["a", "b", "c"];
for (let index = 0, len = a.length; index < len; ++index) {
    const element = a[index];
    console.log(element);
}

And/or counting backward:

const a = ["a", "b", "c"];
for (let index = a.length - 1; index >= 0; --index) {
    const element = a[index];
    console.log(element);
}

But with modern JavaScript engines, it's rare you need to eke out that last bit of juice.

Before ES2015, the loop variable had to exist in the containing scope, because var only has function-level scope, not block-level scope. But as you saw in the examples above, you can use let within the for to scope the variables to just the loop. And when you do that, the index variable is recreated for each loop iteration, meaning closures created in the loop body keep a reference to the index for that specific iteration, which solves the old "closures in loops" problem:

// (The `NodeList` from `querySelectorAll` is array-like)
const divs = document.querySelectorAll("div");
for (let index = 0; index < divs.length; ++index) {
    divs[index].addEventListener('click', e => {
        console.log("Index is: " + index);
    });
}

<div>zero</div>
<div>one</div>
<div>two</div>
<div>three</div>
<div>four</div>

In the above, you get "Index is: 0" if you click the first and "Index is: 4" if you click the last. This does not work if you use var instead of let (you'd always see "Index is: 5").

Like for-of, for loops work well in async functions. Here's the earlier example using a for loop:

function delay(ms) {
    return new Promise(resolve => {
        setTimeout(resolve, ms);
    });
}

async function showSlowly(messages) {
    for (let i = 0; i < messages.length; ++i) {
        const message = messages[i];
        await delay(400);
        console.log(message);
    }
}

showSlowly([
    "So", "long", "and", "thanks", "for", "all", "the", "fish!"
]);
// `.catch` omitted because we know it never rejects

4. Use for-in correctly

for-in isn't for looping through arrays, it's for looping through the names of an object's properties. It does often seem to work for looping through arrays as a by-product of the fact that arrays are objects, but it doesn't just loop through the array indexes, it loops through all enumerable properties of the object (including inherited ones). (It also used to be that the order wasn't specified; it is now [details in this other answer], but even though the order is specified now, the rules are complex, there are exceptions, and relying on the order is not best practice.)

The only real use cases for for-in on an array are:

• It's a sparse array with massive gaps in it, or
• You're using non-element properties on the array object and you want to include them in the loop

Looking only at that first example: You can use for-in to visit those sparse array elements if you use appropriate safeguards:

// `a` is a sparse array
const a = [];
a[0] = "a";
a[10] = "b";
a[10000] = "c";
for (const name in a) {
    if (Object.hasOwn(a, name) &&       // These checks are
        /^0$|^[1-9]\d*$/.test(name) &&  // explained
        name <= 4294967294              // below
       ) {
        const element = a[name];
        console.log(a[name]);
    }
}

Note the three checks:

1. That the object has its own property by that name (not one it inherits from its prototype; this check is also often written as a.hasOwnProperty(name) but ES2022 adds Object.hasOwn which can be more reliable), and

2. That the name is all decimal digits (e.g., normal string form, not scientific notation), and

3. That the name's value when coerced to a number is <= 2^32 - 2 (which is 4,294,967,294). Where does that number come from? It's part of the definition of an array index in the specification. Other numbers (non-integers, negative numbers, numbers greater than 2^32 - 2) are not array indexes. The reason it's 2^32 - 2 is that that makes the greatest index value one lower than 2^32 - 1, which is the maximum value an array's length can have. (E.g., an array's length fits in a 32-bit unsigned integer.)

...although with that said, most code only does the hasOwnProperty check.

You wouldn't do that in inline code, of course. You'd write a utility function. Perhaps:

// Utility function for antiquated environments without `forEach`
const hasOwn = Object.prototype.hasOwnProperty.call.bind(Object.prototype.hasOwnProperty);
const rexNum = /^0$|^[1-9]\d*$/;
function sparseEach(array, callback, thisArg) {
    for (const name in array) {
        const index = +name;
        if (hasOwn(a, name) &&
            rexNum.test(name) &&
            index <= 4294967294
           ) {
            callback.call(thisArg, array[name], index, array);
        }
    }
}

const a = [];
a[5] = "five";
a[10] = "ten";
a[100000] = "one hundred thousand";
a.b = "bee";

sparseEach(a, (value, index) => {
    console.log("Value at " + index + " is " + value);
});

Like for, for-in works well in asynchronous functions if the work within it needs to be done in series.

function delay(ms) {
    return new Promise(resolve => {
        setTimeout(resolve, ms);
    });
}

async function showSlowly(messages) {
    for (const name in messages) {
        if (messages.hasOwnProperty(name)) { // Almost always this is the only check people do
            const message = messages[name];
            await delay(400);
            console.log(message);
        }
    }
}

showSlowly([
    "So", "long", "and", "thanks", "for", "all", "the", "fish!"
]);
// `.catch` omitted because we know it never rejects

5. Use an iterator explicitly (ES2015+)

for-of uses an iterator implicitly, doing all the scut work for you. Sometimes, you might want to use an iterator explicitly. It looks like this:

const a = ["a", "b", "c"];
const it = a.values(); // Or `const it = a[Symbol.iterator]();` if you like
let entry;
while (!(entry = it.next()).done) {
    const element = entry.value;
    console.log(element);
}

An iterator is an object matching the Iterator definition in the specification. Its next method returns a new result object each time you call it. The result object has a property, done, telling us whether it's done, and a property value with the value for that iteration. (done is optional if it would be false, value is optional if it would be undefined.)

What you get for value varies depending on the iterator. On arrays, the default iterator provides the value of each array element ("a", "b", and "c" in the example earlier). Arrays also have three other methods that return iterators:

• values(): This is an alias for the [Symbol.iterator] method that returns the default iterator.
• keys(): Returns an iterator that provides each key (index) in the array. In the example above, it would provide 0, then 1, then 2 (as numbers, not strings). (Also note that in a sparse array, it will include indexes for elements that don't exist.)
• entries(): Returns an iterator that provides [key, value] arrays.

Since iterator objects don't advance until you call next, they work well in async function loops. Here's the earlier for-of example using the iterator explicitly:

function delay(ms) {
    return new Promise(resolve => {
        setTimeout(resolve, ms);
    });
}

async function showSlowly(messages) {
    const it = messages.values()
    while (!(entry = it.next()).done) {
        await delay(400);
        const element = entry.value;
        console.log(element);
    }
}

showSlowly([
    "So", "long", "and", "thanks", "for", "all", "the", "fish!"
]);
// `.catch` omitted because we know it never rejects

For Array-Like Objects

Aside from true arrays, there are also array-like objects that have a length property and properties with all-digits names: NodeList instances, HTMLCollection instances, the arguments object, etc. How do we loop through their contents?

Use most of the options above

At least some, and possibly most or even all, of the array approaches above apply equally well to array-like objects:

1. Use for-of (use an iterator implicitly) (ES2015+)

   for-of uses the iterator provided by the object (if any). That includes host-provided objects (like DOM collections and lists). For instance, HTMLCollection instances from getElementsByXYZ methods and NodeLists instances from querySelectorAll both support iteration. (This is defined quite subtly by the HTML and DOM specifications. Basically, any object with length and indexed access is automatically iterable. It doesn't have to be marked iterable; that is used only for collections that, in addition to being iterable, support forEach, values, keys, and entries methods. NodeList does; HTMLCollection doesn't, but both are iterable.)

   Here's an example of looping through div elements:

const divs = document.querySelectorAll("div");
for (const div of divs) {
    div.textContent = Math.random();
}

<div>zero</div>
<div>one</div>
<div>two</div>
<div>three</div>
<div>four</div>

2. Use forEach and related (ES5+)

   The various functions on Array.prototype are "intentionally generic" and can be used on array-like objects via Function#call (spec | MDN) or Function#apply (spec | …

Use forEach its a built-in array function. Array.forEach():

yourArray.forEach(function (arrayItem) {
    var x = arrayItem.prop1 + 2;
    console.log(x);
});