I'm using WebGL to render a binary encoded mesh file. The binary file is written out in big-endian format (I can verify this by opening the file in a hex editor, or viewing the network traffic using fiddler). When I try to read the binary response using a Float32Array or Int32Array, the binary is interpreted as little-endian and my values are wrong:

// Interpret first 32bits in buffer as an int
var wrongValue = new Int32Array(binaryArrayBuffer)[0];

I can't find any references to the default endianness of typed arrays in http://www.khronos.org/registry/typedarray/specs/latest/ so I'm wondering what's the deal? Should I assume that all binary data should be little-endian when reading using typed arrays?

To get around the problem I can use a DataView object (discussed in the previous link) and call:

// Interpret first 32bits in buffer as an int
var correctValue = new DataView(binaryArrayBuffer).getInt32(0);

The DataView functions such as "getInt32" read big-endian values by default.

(Note: I've tested using Google Chrome 15 and Firefox 8 and they both behave the same way)

  • In case anyone is wondering, I think the answer is that I should have written my file using little-endian. – Bob Oct 23 '11 at 23:25
  • 3
    That's called avoiding the issue instead of addressing it. – Pacerier Jul 27 '15 at 4:59

The current behaviour, somewhat sadly, is that the endianness is that of the underlying hardware. As almost all desktop computers are x86, this means little-endian. Most ARM OSes use little-endian mode (ARM processors are bi-endian and thus can operate in either).

The reason why this is somewhat sad is the fact that it means almost nobody will test whether their code works on big-endian hardware, hurting what does, and the fact that the entire web platform was designed around code working uniformly across implementations and platforms, which this breaks.

  • 7
    Somehow I thought that would be the case. – Bob Nov 12 '11 at 2:30
  • 2
    It's not unfortunate at all. Typed arrays follow the platform's endianness because we use them to interoperate with with native APIs, which work in the platform's endianness. If typed arrays had a set endianness, we'd lose a huge amount of the benefit of using them (on platforms that didn't happen to match the endianness that was chosen). For situations like the OP's, where there's a file involved (or for interacting with various protocols that define a specific endian order, such as TCP; etc.), that's what DataView is for. – T.J. Crowder Sep 13 '18 at 15:56
  • @T.J.Crowder There's definitely a use for machine-endianness, but the bigger problem is the majority of use we're seeing of typed arrays on the web don't need to worry about the underlying machine endianness, and if you do rely on machine endianness it's highly likely to broken on big endian systems (given approximately nobody will have tested their JS on one). (Note I was working at Opera at the time I wrote the above, who probably to this day account for the majority of browsers shipped on big-endian systems.) – gsnedders Sep 13 '18 at 19:11
  • Well, I can't claim deep familiarity with the issue, but the claim of those working on this from the early development of this stuff through implementation was that using machine endianness in typed arrays was important for interop with native APIs, which sounds solid to me. I'm going to trust that the many and varied people involved who have that deep familiarity didn't just collectively get it wrong. :-) – T.J. Crowder Sep 13 '18 at 19:48
  • @T.J.Crowder Remember typed arrays grew out of WebGL (where yes, machine endianness is useful), rather than a separate proposal. By the time it started getting used outside of WebGL, almost entirely in places where endianness doesn't matter, the cat was out of the bag with defaulting to machine endianness. Basically, given nobody tests on big-endian systems, you either break most WebGL cases (or swap endianness when passing to the GL implementation, which I believe is what browsers actually do), or break most non-WebGL cases. – gsnedders Sep 13 '18 at 22:49

Taken from here http://www.khronos.org/registry/typedarray/specs/latest/ (when that spec is fully implemented) you can use:

new DataView(binaryArrayBuffer).getInt32(0, true) // For little endian
new DataView(binaryArrayBuffer).getInt32(0, false) // For big endian

However, if you can't use those method because they aren't implemented, you can always check the file's magic value (almost every format has a magic value) on the header to see if you need to invert it according to your endiannes.

Also, you can save endiannes-specific files on your server and use them accordingly to the detected host endiannes.

  • Hm that's a good idea! I was using DataView before, but only Chrome supports it at the moment. – Bob Nov 12 '11 at 2:26
  • Just as a follow up, i'm implementing my own binary writer on JavaScript, and it seems to be working on both firefox and chrome. – Chiguireitor Dec 13 '11 at 20:29

FYI you can use the following javascript function to determine the endianness of the machine, after which you can pass an appropriately formatted file to the client (you can store two versions of the file on server, big endian and little endian):

function checkEndian() {
    var arrayBuffer = new ArrayBuffer(2);
    var uint8Array = new Uint8Array(arrayBuffer);
    var uint16array = new Uint16Array(arrayBuffer);
    uint8Array[0] = 0xAA; // set first byte
    uint8Array[1] = 0xBB; // set second byte
    if(uint16array[0] === 0xBBAA) return "little endian";
    if(uint16array[0] === 0xAABB) return "big endian";
    else throw new Error("Something crazy just happened");

In your case you will probably have to either recreate the file in little endian, or run through the entire data structure to make it little endian. Using a twist of the above method you can swap endianness on the fly (not really recommended and only makes sense if the entire structure is the same tightly packed types, in reality you can create a stub function that swaps bytes as needed):

function swapBytes(buf, size) {
    var bytes = new Uint8Array(buf);
    var len = bytes.length;
    var holder;

    if (size == 'WORD') {
        // 16 bit
        for (var i = 0; i<len; i+=2) {
            holder = bytes[i];
            bytes[i] = bytes[i+1];
            bytes[i+1] = holder;
    } else if (size == 'DWORD') {
        // 32 bit
        for (var i = 0; i<len; i+=4) {
            holder = bytes[i];
            bytes[i] = bytes[i+3];
            bytes[i+3] = holder;
            holder = bytes[i+1];
            bytes[i+1] = bytes[i+2];
            bytes[i+2] = holder;
  • Nice one! I have just added new and return bytes; to your code. These helped make the code run for me. Thanks. – Theo Mar 21 '14 at 21:14
  • Actually the return was not necessary as the buffer itself is swapped. – Theo Mar 21 '14 at 21:47
  • filler text just to do this: :-D – Ryan Mar 24 '14 at 11:05
  • @Ryan, why do you use 4 bytes instead of 2? – Max Koretskyi aka Wizard Sep 30 '16 at 9:08
  • @Maximus this is due to 32bit, for example an Uint32ArrayBuffer – Stefan Rein Dec 7 '16 at 20:44

The other answers seem a bit outdated to me, so here's a link to the latest spec:


In particular:

The typed array view types operate with the endianness of the host computer.

The DataView type operates upon data with a specified endianness (big-endian or little-endian).

So if you want to read/write data in Big Endian (Network Byte Order), see: http://www.khronos.org/registry/typedarray/specs/latest/#DATAVIEW

// For multi-byte values, the optional littleEndian argument
// indicates whether a big-endian or little-endian value should be
// read. If false or undefined, a big-endian value is read.
  • 4
    "If false or undefined, a big-endian value is read." - just cost me a few hours or my life. – Meirion Hughes Mar 6 '17 at 12:13

Quick way to check endianness

/** @returns {Boolean} true if system is big endian */
function isBigEndian() {
    const array = new Uint8Array(4);
    const view = new Uint32Array(array.buffer);
    return !((view[0] = 1) & array[0]);

How it works:

  • an array of 4 bytes is created;
  • a 32-bit view wraps that array;
  • view[0] = 1 sets the array to hold 32-bit value 1;
  • now comes the important part: if system is big endian, that 1 is being hold by the rightmost byte (little comes last); if it is little endian, it is the leftmost byte that stores it (little comes first). So doing a bitwise AND with the leftmost byte returns false if the machine is big endian;
  • the function finally converts it to a boolean by applying the ! operator to the result of the & operation, while also inverting it so that it returns true for big endian.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.