tl;dr

// For regular arrays: var max = Math.max(...arrayOfNumbers); // For arrays with tens of thousands of items: let max = testArray[0]; for (let i = 1; i < testArrayLength; ++i) { if (testArray[i] > max) { max = testArray[i]; } }

MDN solution

The official MDN docs on Math.max() already covers this issue:

The following function uses Function.prototype.apply() to find the maximum element in a numeric array. getMaxOfArray([1, 2, 3]) is equivalent to Math.max(1, 2, 3) , but you can use getMaxOfArray() on programmatically constructed arrays of any size. function getMaxOfArray(numArray) { return Math.max.apply(null, numArray); } Or with the new spread operator, getting the maximum of an array becomes a lot easier. var arr = [1, 2, 3]; var max = Math.max(...arr);

Maximum size of an array

According to MDN the apply and spread solutions had a limitation of 65536 that came from the limit of the maximum number of arguments:

But beware: in using apply this way, you run the risk of exceeding the JavaScript engine's argument length limit. The consequences of applying a function with too many arguments (think more than tens of thousands of arguments) vary across engines (JavaScriptCore has hard-coded argument limit of 65536), because the limit (indeed even the nature of any excessively-large-stack behavior) is unspecified. Some engines will throw an exception. More perniciously, others will arbitrarily limit the number of arguments actually passed to the applied function. To illustrate this latter case: if such an engine had a limit of four arguments (actual limits are of course significantly higher), it would be as if the arguments 5, 6, 2, 3 had been passed to apply in the examples above, rather than the full array.

They even provide a hybrid solution which doesn't really have good performance compared to other solutions. See performance test below for more.

In 2019 the actual limit is the maximum size of the call stack. For modern Chromium based desktop browsers this means that when it comes to finding min/max with apply or spread, practically the maximum size for numbers only arrays is ~120000. Above this, there will be a stack overflow and the following error will be thrown:

RangeError: Maximum call stack size exceeded

With the script below (based on this blog post), by catching that error you can calculate the limit for your specific environment.

Warning! Running this script takes time and depending on the performance of your system it might slow or crash your browser/system!

let testArray = Array.from({length: 10000}, () => Math.floor(Math.random() * 2000000)); for (i = 10000; i < 1000000; ++i) { testArray.push(Math.floor(Math.random() * 2000000)); try { Math.max.apply(null, testArray); } catch (e) { console.log(i); break; } }

Performance on large arrays

Based on the test in EscapeNetscape's comment I created some benchmarks that tests 5 different methods on a random number only array with 100000 items.

In 2019, the results show that the standard loop (which BTW doesn't have the size limitation) is the fastest everywhere. apply and spread comes closely after it, then much later MDN's hybrid solution then reduce as the slowest.

Almost all tests gave the same results, except for one where spread somewhy ended up being the slowest.

If you step up your array to have 1 million items, things start to break and you are left with the standard loop as a fast solution and reduce as a slower.

Benchmark source code