4432

I'm trying to create globally-unique identifiers in JavaScript. I'm not sure what routines are available on all browsers, how "random" and seeded the built-in random number generator is, etc.

The GUID / UUID should be at least 32 characters and should stay in the ASCII range to avoid trouble when passing them around.

  • 15
    GUIDs when repesented as as strings are at least 36 and no more than 38 characters in length and match the pattern ^\{?[a-zA-Z0-9]{36}?\}$ and hence are always ascii. – AnthonyWJones Sep 19 '08 at 20:35
  • 2
    David Bau provides a much better, seedable random number generator at davidbau.com/archives/2010/01/30/… I wrote up a slightly different approach to generating UUIDs at blogs.cozi.com/tech/2010/04/generating-uuids-in-javascript.html – George V. Reilly May 4 '10 at 23:09
  • Weird that no one has mentioned this yet but for completeness, there's a plethora of guid generators on npm I'm willing to bet most of them work in browser too. – George Mauer Feb 3 '14 at 15:54
  • If anyone wants more options like different versions of the uuid and non standard guid support, REST based uuid generation services like these [fungenerators.com/api/uuid ] are an attractive option too. – dors Dec 15 '20 at 16:20
  • Some 12 years later with BigInt and ES6 classes, other techniques that yield rates of 500,000 uuid/sec can be done. See reference – smallscript Dec 30 '20 at 6:34

57 Answers 57

1
2
6

It is important that to use well tested code that is maintained by more than 1 contributors instead of whipping your own stuff for this. This is one of the places where you probably want to prefer most stable code than shortest possible clever version that works in X browser but doesn't take in to account idiosyncrasies of Y which would often lead to very hard to investigate bugs than manifests only randomly for some users. Personally I use uuid-js at https://github.com/aurigadl/uuid-js which bower enabled so I can take updates easily.

5

You could use the npm package guid, a guid generator and validator.

https://www.npmjs.com/package/guid

Example:

Guid.raw();
// -> '6fdf6ffc-ed77-94fa-407e-a7b86ed9e59d'

UPDATE: This package has been deprecated. Use uuid instead.

https://www.npmjs.com/package/uuid

Example:

const uuidv4 = require('uuid/v4');
uuidv4(); // ⇨ '10ba038e-48da-487b-96e8-8d3b99b6d18a'
5

I couldn't find any answer that uses a single 16-octet TypedArray and a DataView, so I think the following solution for generating a version 4 UUID per the RFC will stand on its own here:

function uuid4() {
    const ho = (n, p) => n.toString(16).padStart(p, 0); /// Return the hexadecimal text representation of number `n`, padded with zeroes to be of length `p`
    const view = new DataView(new ArrayBuffer(16)); /// Create a view backed by a 16-byte buffer
    crypto.getRandomValues(new Uint8Array(view.buffer)); /// Fill the buffer with random data
    view.setUint8(6, (view.getUint8(6) & 0xf) | 0x40); /// Patch the 6th byte to reflect a version 4 UUID
    view.setUint8(8, (view.getUint8(8) & 0x3f) | 0x80); /// Patch the 8th byte to reflect a variant 1 UUID (version 4 UUIDs are)
    return `${ho(view.getUint32(0), 8)}-${ho(view.getUint16(4), 4)}-${ho(view.getUint16(6), 4)}-${ho(view.getUint16(8), 4)}-${ho(view.getUint32(10), 8)}${ho(view.getUint16(14), 4)}`; /// Compile the canonical textual form from the array data
}

I prefer it because it only relies on functions available to the standard ECMAScript platform.

Take note of the fact that at the time of writing this, getRandomValues is not something implemented for the crypto object in Node.js. However, it has the equivalent randomBytes function which may be used instead.

4

I'm using this below function, hope it may be useful.

    function NewGuid()
         {
           var sGuid="";
           for (var i=0; i<32; i++)
            {
              sGuid+=Math.floor(Math.random()*0xF).toString(0xF);
            }
           return sGuid;
         }
4

A simple solution to generate unique identification is to use time token and add random number to it. I prefer to prefix it with "uuid-".

Below function will generate random string of type: uuid-14d93eb1b9b4533e6. One doesn't need to generate 32 chars random string. 16 char random string is more than sufficient in this case to provide the unique UUIDs in javascript.

var createUUID = function() {
  return"uuid-"+((new Date).getTime().toString(16)+Math.floor(1E7*Math.random()).toString(16));
}
4

Because i can, i thought i should share my solution, since it is a very fascinating problem and it has so many solutions.

It works for nodejs too, if you replace let buffer = new Uint8Array(); crypto.getRandomValues with let buffer = crypto.randomBytes(16)

I hope it helps somebody. It should beat most regex solutions in performance.

const hex = '0123456789ABCDEF'

let generateToken = function() {
    let buffer = new Uint8Array(16)
    
    crypto.getRandomValues(buffer)

    buffer[6] = 0x40 | (buffer[6] & 0xF)
    buffer[8] = 0x80 | (buffer[8] & 0xF)

    let segments = []

    for (let i = 0; i < 16; ++i) {
        segments.push(hex[(buffer[i] >> 4 & 0xF)])
        segments.push(hex[(buffer[i] >> 0 & 0xF)])

        if (i == 3 || i == 5 || i == 7 || i == 9) {
            segments.push('-')
        }
    }

    return segments.join('')
}

for (let i = 0; i < 100; ++i) {
  console.log(generateToken())
}

Performance charts, everybody loves them: jsbench

Have fun and thank you for all the other solutions, some served my quite long.

3

I found this script useful for creating GUIDs in JavaScript

https://github.com/addui/GUIDJS

var myGuid = GUID();
  • This uses Math.random under the hood. Therefore broken and likely to suffer collisions in browsers with bad Math.random implementations. Prefer uuid since it uses the crypto API where available. – Mark Amery Sep 23 '19 at 23:06
3

Here you can find a very small function that generates uuids https://gist.github.com/jed/982883

One of the final versions is:

function b(
  a                  // placeholder
){
  var cryptoObj = window.crypto || window.msCrypto; // for IE 11
  return a           // if the placeholder was passed, return
    ? (              // a random number from 0 to 15
      a ^            // unless b is 8,
      cryptoObj.getRandomValues(new Uint8Array(1))[0]  // in which case
      % 16           // a random number from
      >> a/4         // 8 to 11
      ).toString(16) // in hexadecimal
    : (              // or otherwise a concatenated string:
      [1e7] +        // 10000000 +
      -1e3 +         // -1000 +
      -4e3 +         // -4000 +
      -8e3 +         // -80000000 +
      -1e11          // -100000000000,
      ).replace(     // replacing
        /[018]/g,    // zeroes, ones, and eights with
        b            // random hex digits
      )
}
3

For those who are using Javascript on Windows (e.g. WScript / CScript / MSHTA). One can use ActiveX. Specifically, the Scriptlet.Typelib object:

WScript.Echo((new ActiveXObject("Scriptlet.TypeLib")).Guid)

Note that this answer only works on the technologies I listed, it will not work any browser, not even Microsoft Edge! So, your mileage will vary with this answer.

  • 5
    Such approach is still a thing in 2018? Wow :-) – alek kowalczyk Apr 21 '18 at 1:01
3

Old question, so this might never float to the top, but I've built on everything mentioned here to produce something twice as fast, portable all environments, including node, and upgraded from Math.random() to crypto-strength randomness. You might not think uuid needs crypto strength, but what that means is even less chance of a collision, which is the entire point of a uuid.

function random() {
    const
        fourBytesOn = 0xffffffff, // 4 bytes, all 32 bits on: 4294967295
        c = typeof crypto === "object"
            ? crypto // node or most browsers
            : typeof msCrypto === "object" // stinky non-standard IE
                ? msCrypto // eslint-disable-line no-undef
                : null; // what old or bad environment are we running in?
        return c
            ? c.randomBytes
                ? parseInt(c.randomBytes(4).toString("hex"), 16) / (fourBytesOn + 1) - Number.EPSILON // node
                : c.getRandomValues(new Uint32Array(1))[0] / (fourBytesOn + 1) - Number.EPSILON // browsers
            : Math.random();
}

function uuidV4() { // eslint-disable-line complexity
    // if possible, generate a single random value, 128 bits (16 bytes) in length
    // in an environment where that is not possible, generate and make use of 4 32-bit (4-byte) random values
    // use crypto-grade randomness when available, else Math.random()
    const
        c = typeof crypto === "object"
            ? crypto // node or most browsers
            : typeof msCrypto === "object" // stinky non-standard IE
                ? msCrypto // eslint-disable-line no-undef
            : null; // what old or bad environment are we running in?
    let
        byteArray = c
            ? c.randomBytes
                ? c.randomBytes(16) // node
                : c.getRandomValues(new Uint8Array(16)) // browsers
            : null,
        uuid = [ ];

    /* eslint-disable no-bitwise */
    if ( ! byteArray) { // no support for generating 16 random bytes in one shot -- this will be slower
        const
            int = [
                random() * 0xffffffff | 0,
                random() * 0xffffffff | 0,
                random() * 0xffffffff | 0,
                random() * 0xffffffff | 0
            ];
        byteArray = [ ];
        for (let i = 0; i < 256; i++) {
            byteArray[i] = int[i < 4 ? 0 : i < 8 ? 1 : i < 12 ? 2 : 3] >> i % 4 * 8 & 0xff;
        }
    }
    byteArray[6] = byteArray[6] & 0x0f | 0x40; // always 4, per RFC, indicating the version
    byteArray[8] = byteArray[8] & 0x3f | 0x80; // constrained to [89ab], per RFC for version 4
    for (let i = 0; i < 16; ++i) {
        uuid[i] = (byteArray[i] < 16 ? "0" : "") + byteArray[i].toString(16);
    }
    uuid =
        uuid[ 0] + uuid[ 1] + uuid[ 2] + uuid[ 3] + "-" +
        uuid[ 4] + uuid[ 5]                       + "-" +
        uuid[ 6] + uuid[ 7]                       + "-" +
        uuid[ 8] + uuid[ 9]                       + "-" +
        uuid[10] + uuid[11] + uuid[12] + uuid[13] + uuid[14] + uuid[15];
    return uuid;
    /* eslint-enable no-bitwise */
}
3

Based on the work of broofa, I've added some more randomness by adding the timestamp to math.random()

Hope it might help

function uuidv4() {
    return 'xxxxxxxx-xxxx-4xxx-yxxx-xxxxxxxxxxxx'.replace(/[xy]/g, function (c) {
        var r = parseFloat('0.' + Math.random().toString().replace('0.', '') + new Date().getTime()) * 16 | 0,
            v = c == 'x' ? r : (r & 0x3 | 0x8);
        return v.toString(16);
    });
}
2

For my use-case, I required id generation that was guaranteed to be unique globally; without exception. I struggled with the problem for a while, and came up with a solution called tuid (Truly Unique ID). It generates an id with the first 32 characters being system-generated and the remaining digits representing milliseconds since epoch. In situations where I need to generate id's on client-side javascript, it works well. Have a look:

https://github.com/mongoh/tuid

  • 2
    This literally calls AWS S3 to get a random ID. If calling a server is okay, you can just have the server generate a UUID. – Kasey Speakman Nov 23 '18 at 8:50
2

Just in case anyone dropping by google is seeking a small utility library, ShortId (https://www.npmjs.com/package/shortid) meets all the requirements of this question. It allows specifying allowed characters and length, and guarantees non-sequential, non-repeating strings.

To make this more of a real answer, the core of that library uses the following logic to produce its short ids:

function encode(lookup, number) {
    var loopCounter = 0;
    var done;

    var str = '';

    while (!done) {
        str = str + lookup( ( (number >> (4 * loopCounter)) & 0x0f ) | randomByte() );
        done = number < (Math.pow(16, loopCounter + 1 ) );
        loopCounter++;
    }
    return str;
}

/** Generates the short id */
function generate() {

    var str = '';

    var seconds = Math.floor((Date.now() - REDUCE_TIME) * 0.001);

    if (seconds === previousSeconds) {
        counter++;
    } else {
        counter = 0;
        previousSeconds = seconds;
    }

    str = str + encode(alphabet.lookup, version);
    str = str + encode(alphabet.lookup, clusterWorkerId);
    if (counter > 0) {
        str = str + encode(alphabet.lookup, counter);
    }
    str = str + encode(alphabet.lookup, seconds);

    return str;
}

I have not edited this to reflect only the most basic parts of this approach, so the above code includes some additional logic from the library. If you are curious about everything it is doing, take a look at the source: https://github.com/dylang/shortid/tree/master/lib

2

Hi here is an working example it generates 32-digit Unique UUID.

function generateUUID() {
      var d = new Date();
      var k = d.getTime();
     var str = k.toString(16).slice(1)
    var UUID= 'xxxx-xxxx-4xxx-yxxx-xzx'.replace(/[xy]/g, function (c)
      {
        var r = Math.random() * 16 | 0;
        v = c == 'x' ? r : (r & 3 | 8);
        return v.toString(16);
      });
      var newString = UUID.replace(/[z]/, str)
      return newString;
    }
    var x = generateUUID()
    console.log(x,x.length)
2

We can use replace and crypto.getRandomValues to get an output like this :

xxxxxxxx-xxxx-4xxx-xxxx-xxxxxxxxxxxx

enter image description here

If we are looking for an opti solution, we have to replace crypto.getRandomValues(new Uint8Array(1))[0] by an array(32).

const uuidv4 = () =>
  ([1e7] + -1e3 + -4e3 + -8e3 + -1e11).replace(/[018]/g, c =>
    (c ^ crypto.getRandomValues(new Uint8Array(1))[0] & 15 >> c / 4).toString(16)
  );

console.log(uuidv4());

To get this code :

function uuidv4() {
  let bytes = window.crypto.getRandomValues(new Uint8Array(32));
  const randomBytes = () => (bytes = bytes.slice(1)) && bytes[0];

  return ([1e7] + -1e3 + -4e3 + -8e3 + -1e11).replace(/[018]/g, c => 
      (c ^ randomBytes() & 15 >> c / 4).toString(16)
    );
}


for (var i = 0; i < 10; i++)
  console.log(uuidv4());

Collision :

We can do like google analytics and add a timestamp with : uuidv4() + "." + (+new Date()).

2

The UUID currently has a proposal for addition to the standard library and can be supported here https://github.com/tc39/proposal-uuid

The proposal encompasses having UUID as the following:

// We're not yet certain as to how the API will be accessed (whether it's in the global, or a
// future built-in module), and this will be part of the investigative process as we continue
// working on the proposal.
uuid(); // "52e6953d-edbe-4953-be2e-65ed3836b2f0"

This implemtation follows the same layout as the V4 random uuid generation found here: https://www.npmjs.com/package/uuid

const uuidv4 = require('uuid/v4');
uuidv4(); // ⇨ '1b9d6bcd-bbfd-4b2d-9b5d-ab8dfbbd4bed'

I think it's noteworthy to understand how much bandwidth could be saved by this having an official implementation in the standard library. The authors of the proposal have also noted:

The 12 kb uuid module is downloaded from npm > 62,000,000 times a month (June 2019); making it available in the standard library eventually saves TBs of bandwidth globally. If we continue to address user needs, such as uuid, with the standard library, bandwidth savings add up.

2

A typescript version of broofa's update from 2017-06-28, based on crypto API:

function genUUID() {
        // Reference: https://stackoverflow.com/a/2117523/709884
        return ("10000000-1000-4000-8000-100000000000").replace(/[018]/g, s => {
            const c = Number.parseInt(s, 10)
            return (c ^ crypto.getRandomValues(new Uint8Array(1))[0] & 15 >> c / 4).toString(16)
        })
}

Reasons:

  • Use of + between number[] and number isn't valid
  • The conversion from string to number has to be explicit
1

Don't use Math.random in anycase since it generated a non-cryptographic source of random numbers

Solution below using crypto.getRandomValues

function uuidv4() {
  return "xxxxxxxx-xxxx-4xxx-yxxx-xxxxxxxxxxxx".replace(/[xy]/g, (c) => {
    // tslint:disable-next-line: no-bitwise
    const r =
      (window.crypto.getRandomValues(new Uint32Array(1))[0] *
        Math.pow(2, -32) * 16) |
      0;
    // tslint:disable-next-line: no-bitwise
    const v = c === "x" ? r : (r & 0x3) | 0x8;
    return v.toString(16);
  });
}

This link helps your to understand the Insecure Randomness thrown by Fortify Scanner

1

UUID with timestamp built in (emitter/parser)
I will also post my simple approach to generating a valid UUID v4 with very strong uniqueness and fast runtime. The basic idea is not new, but approach is different. I use a timestamp in milliseconds from the date.now() (in Node.js library, which I'll point later, I use nanoseconds timestamp from process.hrtime.bigint()), and then add a random 5 digit number (10000-90000) to the end of the timestamp string. After merging the strings, I just form a valid UUID from digits and a pair of special characters, so that my UUID consists only of digits and a few non-numeric characters. Please check it out below:

/*
 * uuid-timestamp (emitter)
 * UUID v4 based on timestamp
 *
 * Created by tarkh
 * tarkh.com (C) 2020
 */
const uuidEmit = () => {
  // Get now time
  const n = Date.now();
  // Generate random
  const r = Math.random();
  // Stringify now time and generate additional random number
  const s = String(n) + String(~~(r*9e4)+1e4);
  // Form UUID and return it
  return `${s.slice(0,8)}-${s.slice(8,12)}-4${s.slice(12,15)}-${[8,9,'a','b'][~~(r*3)]}${s.slice(15,18)}-${s.slice(s.length-12)}`;
};

// Generate 5 UUIDs
console.log(`${uuidEmit()}
${uuidEmit()}
${uuidEmit()}
${uuidEmit()}
${uuidEmit()}`);

Looking at the results, you obviously see that the first part of UUIDs is the same, and then comes randomness. This is because I inserted the timestamp into the UUID linearly. The code will produce a new UUID every millisecond (nanosecond in Node.js library) + add a random 5-digit number to the end, so we end up with very approximate collision probability around 1 in 10 million per second. If we use Node.js library, our very approximate collision probability goes to 1 in 10 billion per second.

Timestamp built into the UUID
Since we insert a timestamp into the UUID linearly, we get a feature (good or bad - depends on the task) - ability to easily extract this timestamp back from the UUID. This way we can understand when UUID was released:

/*
 * uuid-timestamp (parser)
 * UUID v4 based on timestamp
 *
 * Created by tarkh
 * tarkh.com (C) 2020
 */
const uuidParse = (uuid) => {
  // Get current timestamp string length
  let tl = String(Date.now()).length;
  // Strip out timestamp from UUID
  let ts = '';
  let i = -1;
  while(tl--) {
    i++;
    if(i===8||i===13||i===14||i===18||i===19||i===23) {
      tl++;
      continue;
    }
    ts += uuid[i];
  }
  return Number(ts);
};

// Get the timestamp when UUID was emitted
const time = uuidParse('15970688-7109-4530-8114-887109530114');

// Covert timestamp to date and print it
console.log(new Date(time).toUTCString());

Node.js
NPM version of my code above available as Node.js module. This version is even more powerful in generating unique values, because instead of millisecond timestamp it uses nanoseconds from combination of system time and process.hrtime.bigint() diff.

Benchmarks
At the end of my post, I want to do some performance tests based on some of the answers from this topic. Of course, my decision is not the fastest, but it certainly takes the top positions.
Check jsBench here

  • This is technically not a compliant UUID4. It's neat that it has the timestamp, but you are better off using a UUID1 at that point. With this scheme, there's a 1 in 10,000 chance of a collision every time there is a millisecond collision, which if you emit events every second, that's 1/1000, or 1 in 10 million, every second. That's pretty much guaranteed to occur in any production bigger than basically hobby scale. Semantically, UUIDs shouldn't be timestamp fields. That's what timestamp fields are for. They are meant for "give me an ID which will NEVER collide". – DeusXMachina Sep 8 '20 at 19:30
  • 1
    @DeusXMachina thanks for commenting, I 100% agree. That's why in NodeJS library, which I've pointed at the end of my post, I use process.hrtime.bigint() for timestamps, which gives me nanosecond scale (1 million chance in a second) + random number from 10000 to 90000 at the end. So finally it goes to multi-billion chance in 1 sec, if my calculations is right. Anyway this is non-standard approach with specific use case, as I've mentioned above. – tarkh Sep 8 '20 at 23:04
  • 1
    Ah, I missed that. Perhaps edit your explanation so that it's a bit more obvious you are using ns resolution. "...produce a new UUID every millisecond + add a random 5-digit number". Still, why not use uuid1? That provides 0.1 µs resolution plus another 48 bits of entropy. en.wikipedia.org/wiki/… – DeusXMachina Sep 9 '20 at 14:12
  • Invalid should be xxxxxxxx-xxxx-Mxxx-Nxxx-xxxxxxxxxxxx – NVRM Nov 24 '20 at 6:13
  • @NVRM It IS valid, you can check result in any online UUID validators, i.e. here: freecodeformat.com/validate-uuid-guid.php – tarkh Nov 24 '20 at 9:51
1

Necromancing.

Effectively, a Guid, or UUID as it is called in non-microsoft-circles, is just a 128-Bit cryptographic random number, with the uuid version number (1-5) being at a fixed location byte.

So when you just generate a bunch of random numbers betwween 0 and 65535 and hex-encode them, like this:

function guid()
{
    function s4()
    {
        return Math.floor(Math.random() * 65536).toString(16).padStart(4, '0')
    } // End Function s4 

    return s4() + s4() + '-' + s4() + '-' + "4" + s4().substr(1) + '-' + s4() + '-' + s4() + s4() + s4();
} // End Function guid 

you get a valid GUID, but due to the random-implementation, it's not cryptographically secure.

To generate a cryptographically secure GUID, you need to use window.crypto (or window.msCrypto for Internet Exploder).

That goes like this:

function cryptGuid()
{ 
    var array = new Uint16Array(8);
    (window.crypto || window.msCrypto).getRandomValues(array);
    var dataView = new DataView(array.buffer);
    
    var parts = [];

    for(var i = 0; i < array.length; ++i)
    {
        // 0&1,2,3,4,5-7 dataView.getUint16(0-7)
        if(i>1 && i<6) parts.push("-");
        parts.push(dataView.getUint16(i).toString(16).padStart(4, '0'));
    }

    parts[5] = "4" + parts[5].substr(1);
    // console.log(parts);
    return parts.join('').toUpperCase();// .toLowerCase();
}

cryptGuid();

Plus you have to decide, if you return the number as lower-or upper-case character string. Certain software require lowercase characters (e.g. Reporting Service), while others generate uppercase characters (SQL-Server).

1

There are many correct answers here, but sadly, included code samples are quite cryptic and difficult to understand. This is how I create version 4 (random) UUIDs.

Note that following pieces of code make use of binary literals for improved readability, thus require ECMAScript 6.

Node version

function uuid4() {
  let array = new Uint8Array(16)
  crypto.randomFillSync(array)

  // manipulate 9th byte
  array[8] &= 0b00111111 // clear first two bits
  array[8] |= 0b10000000 // set first two bits to 10

  // manipulate 7th byte
  array[6] &= 0b00001111 // clear first four bits
  array[6] |= 0b01000000 // set first four bits to 0100

  const pattern = "XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX"
  let idx = 0

  return pattern.replace(
    /XX/g,
    () => array[idx++].toString(16).padStart(2, "0"), // padStart ensures leading zero, if needed
  )
}

Browser version

Only the 2nd line is different.

function uuid4() {
  let array = new Uint8Array(16)
  crypto.getRandomValues(array)

  // manipulate 9th byte
  array[8] &= 0b00111111 // clear first two bits
  array[8] |= 0b10000000 // set first two bits to 10

  // manipulate 7th byte
  array[6] &= 0b00001111 // clear first four bits
  array[6] |= 0b01000000 // set first four bits to 0100

  const pattern = "XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX"
  let idx = 0

  return pattern.replace(
    /XX/g,
    () => array[idx++].toString(16).padStart(2, "0"), // padStart ensures leading zero, if needed
  )
}

Tests

And finally, corresponding tests (Jasmine).

describe(".uuid4()", function() {
  it("returns a UUIDv4 string", function() {
    const uuidPattern = "XXXXXXXX-XXXX-4XXX-YXXX-XXXXXXXXXXXX"
    const uuidPatternRx = new RegExp(uuidPattern.
      replaceAll("X", "[0-9a-f]").
      replaceAll("Y", "[89ab]"))

    for (let attempt = 0; attempt < 1000; attempt++) {
      let retval = uuid4()
      expect(retval.length).toEqual(36)
      expect(retval).toMatch(uuidPatternRx)
    }
  })
})

UUID v4 explained

A very good explanation of UUID version 4 is here: https://www.cryptosys.net/pki/uuid-rfc4122.html.

Final notes

Also, there are plenty of third-party packages. However, as long as you have just basic needs, I don't recommend them. Really, there is not much to win and pretty much to lose. Authors may pursue for tiniest bits of performance, "fix" things which aren't supposed to be fixed, and when it comes to security, it is a risky idea. Similarly, they may introduce other bugs or incompatibilities. Careful updates require time.

0

Just thought I'd post yet another way of doing the same thing.

function guid() {
  var chars = ["0","1","2","3","4","5","6","7","8","9","A","B","C","D","E","F"];
  var str = "";
  for(var i=0;i<36;i++) {
    var str = str + ((i == 8 || i == 13 || i == 18 || i == 23) ? "-" : chars[Math.floor(Math.random()*chars.length)]);
  };
  return str;
}
0

This may be of use to someone...

var d = new Date().valueOf();
var n = d.toString();
var result = '';
var length = 32;
var p = 0;
var chars = '0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ';

for (var i = length; i > 0; --i){
    result += ((i & 1) && n.charAt(p) ? '<b>' + n.charAt(p) + '</b>' : chars[Math.floor(Math.random() * chars.length)]);
    if(i & 1) p++;
};

https://jsfiddle.net/j0evrdf1/1/

0
function randomHex(length) {
    var random_string = '';
    if(!length){
        length = 1;
    }
    for(var i=0; i<length; i+=1){
        random_string += Math.floor(Math.random() * 15).toString(16);
    }
    return random_string;
}

function guid() {
    return randomHex(8);
}
0

For science. I haven't seen anyone do this yet... its not v4 compliant, but could easily be altered to be. Its just an example of extending the Uint8Array type, and using crypto.getRandomValues() to generate the uuid byte values.

class uuid extends Uint8Array {
        constructor() {
            super(16)
            /* not v4, just some random bytes */
            window.crypto.getRandomValues(this)
        }
        toString() {
            let id = new String()
            for (let i = 0; i < this.length; i++) {
                /*convert uint8 to hex string */
                let hex = this[i].toString(16).toUpperCase()

                /*add zero padding*/
                while (hex.length < 2) {
                    hex = String(0).concat(hex)
                }
                id += hex

                /* add dashes */
                if (i == 4 || i == 6 || i == 8 || i == 10 || i == 16){
                    id += '-'
                }
            }
            return id
        }
    }
0
var guid = createMyGuid();

function createMyGuid()  
{  
   return 'xxxxxxxx-xxxx-4xxx-yxxx-xxxxxxxxxxxx'.replace(/[xy]/g, function(c) {  
      var r = Math.random()*16|0, v = c === 'x' ? r : (r&0x3|0x8);  
      return v.toString(16);  
   });  
}
  • 1
    What's the difference to this post? – fcdt Aug 8 '20 at 10:19
  • @fcdt - the difference is c === 'x' instead of c == 'x'. – dbc Aug 8 '20 at 22:30
0

The following uuid implementation offers a different ES6 2020 solution using BigInt and focuses on "Use case intent for a uuid design pattern"; especially for use with indexedDb primaryKey scenarios where unifying sequencing in time and collation are valuable.

So, noting that this post has over 30 answers, here goes...

This post has:

  1. a "TL;DR" code section w/self-contained es6 class Xuid
  2. a use-case and motivations discussion section regarding the es6 class Xuid provided code.

TL;DR class Xuid solution for generic v4 uuid using a monotonic clock

The code-below is extracted from Smallscript's EdgeS web-client library that I wrote and own and is provided here, freely MIT licensed. A github version will be available once EdgeS web-client toolset is released.

Usage example:

eval: console.log(Xuid.v4New)
emits: {1eb4a659-8bdc-4ce0-c002-b1d505d38ea8}

class Xuid {
  //@ edges.sm.st, ess.dev: MIT license Smallscript/David Simmons 2020
  //! Can't use `static const field = const` xbrowser (thus, const's duped)
  static get v4New() {
    const ns7Now = this.ns7Now, xnode48 = this.xnode48; let clock_seq13
    // monotonic `clock_seq` guarantee (13-bits/time-quantum)
    if(ns7Now <= this.ns7Now_prevSeq && this.ns7Now_prevSeq)
      clock_seq13 = ((this.ns7Now_prevSeq += 1n) - ns7Now) & 0b1_1111_1111_1111n
    else
      clock_seq13 = 0n, this.ns7Now_prevSeq = ns7Now
    const time60 = ((ns7Now << 4n) & 0xFFFF_FFFF_FFFF_0000n) |
                           (ns7Now & 0x0000_0000_0000_0FFFn),
              v4 = 0x1_00000000_0000_0000_0000_000000000000n |
      (time60 << 64n) | (0x00000000_0000_4000_0000_000000000000n) | // M: V4
      (0b110n << 61n) | (clock_seq13 << 48n) | // N: Variant-2 time-seq collation
      xnode48, s = v4.toString(16)//.substr(1)
    return `{${s.substr(1,8)}-${s.substr(9,4)}-${s.substr(13,4)}-${
      s.substr(17,4)}-${s.substr(21,12)}}`
  }
  static get xnode48()/*:<BigInt#48>*/{
    if(this.xnode48_) return this.xnode48_
    let clockSeqNode; if(typeof URL !== 'undefined' && URL.createObjectURL) {
      const url = URL.createObjectURL(new Blob())
      const id = (url.toString().split('/').reverse()[0]).split('-')
      URL.revokeObjectURL(url)
      clockSeqNode = BigInt('0x'+id[3]+id[4])
    }
    else {
      const a4 = this.a4; this.getRandomValues(this.a4);
      clockSeqNode = (BigInt(a4[2]) << 32n) | BigInt(a4[3])
    }
    // simulate the 48-bit node-id and 13-bit clock-seq
    // to combine with 3-bit uuid-variant
    return this.xnode48_ = clockSeqNode & 0xFFFF_FFFF_FFFFn;
  }
  static get jdNow()/*:<double#ns7>*/{
    // return 2440587.5+Date.now()/864e5 // <- Date-quantum-ms form (7ns form below)
    return this.jdFromNs7(this.ns7Now)
  }
  static get ns7Now()/*:<BigInt#60>*/{
    if(typeof performance !== 'undefined' && performance.now)
      Reflect.defineProperty(this, 'ns7Now',
        Reflect.getOwnPropertyDescriptor(this,'ns7Now_performance'))
    else
      Reflect.defineProperty(this, 'ns7Now',
        Reflect.getOwnPropertyDescriptor(this,'ns7Now_Date'))
    return this.ns7Now
  }
  static get ns7Now_Date()/*:<BigInt#60>*/{
    // const epoch1582Ns7_bias = 0x1b2_1dd2_1381_4000  // V1 1582 Oct 15
    // const epoch1601Ns7_bias = 0x19d_b1de_d53e_8000n // FILETIME base
    const epoch1970Ns7 = BigInt(Date.now() * 1000_0.0)
    return epoch1970Ns7 + 0x1b2_1dd2_1381_4000n
  }
  static get ns7Now_performance()/*:<BigInt#60>*/{
    const epochPgNs7 = BigInt(performance.now()*/*15*/1000_0.0|/*17*/0)
    if(!this.epoch1970PgNs7) // performance.timing.navigationStart
      this.epoch1970PgNs7 = this.ns7Now_Date - epochPgNs7
    return epochPgNs7 + this.epoch1970PgNs7
  }
  static dateFromJd(jd) {return new Date((jd - 2440587.5) * 864e5)}
  static dateFromNs7(ns7) {
    return new Date(Number(ns7 - 0x1b2_1dd2_1381_4000n) / 1000_0.0)}
  static jdFromNs7(ns7) {   // atomic-clock leap-seconds (ignored)
    return 2440587.5 + (Number(ns7 - 0x1b2_1dd2_1381_4000n) / 864e9)
  }
  static ns7FromJd(jd) {
    return BigInt((jd - 2440587.5) * 864e9) + 0x1b2_1dd2_1381_4000n
  }
  static getRandomValues(va/*:<Uint32Array>*/) {
    if(typeof crypto !== 'undefined' && crypto.getRandomValues)
      crypto.getRandomValues(va)
    else for(let i = 0, n = va.length; i < n; i += 1)
      va[i] = Math.random() * 0x1_0000_0000 >>> 0
  }
  static get a4() {return this.a4_ || (this.a4_ = new Uint32Array(4))}
  static ntohl(v)/*:<BigInt>*/{
    let r = '0x', sign = 1n, s = BigInt(v).toString(16)
    if(s[0] == '-') s = s.substr(1), sign = -1n
    for(let i = s.length; i > 0; i -= 2)
      r += (i == 1) ? ('0' + s[i-1]) : s[i-2] + s[i-1]
    return sign*BigInt(r)
  }
  static ntohl32(v)/*:<Number>*/{return Number(this.ntohl(v))}
}

Motivation

While v4 uuid defines a basically random uuid, it is desirable to have a uuid implementation that can support some additional characteristics.

  • creates new uuid values quickly and efficiently (using BigInt)
  • implemented as standalone code with a nominal 80 loc readable class w/comments
  • incorporates uuid uniqueness using monotonic time within a context
  • stringifies such that the string form:
    • collates based on time and then context (using uuid Variant-2)
    • converts back to a binary form that correctly identifies and recovers the time
  • incorporates JavaScript micro-second clock accuracy where available
  • supports cross-environment quantum of 100 nano-second units based on julian-day epoch year 1582 Oct 15, V1 compatibility. Choices that enable unified time behavior across a spectrum of environments and use cases consistent with EdgeS and ESS language model.

    Especially suited for database use with facilities like SqLite.

  • uses es6 class design to simplify extensibility for nominal work to extend it to provide other uuid variants
  • for this posting, unified and incorporated basic time and related eswc library APIs.
    • Julian Day api
    • ns7 (100 nano-second quantum) api
    • ntohl api for endian convenience re-ordering BigInt string representations
  • derived from QKS Smalltalk 1991, AOS® [Agile Object System;Agents Object System] engine family technology for language, framework and runtimes it preserves use case compatibility across a wide range of current and historical host OS models.
    • specifically where the Xuid curly-brace quoted scalar string format supports guid, uuid, and uid (git, fossil, SqLite repo-id) representations, FILETIME etc.

      as in: {1eb4a659-8bdc-4ce0-c002-b1d505d38ea8}

  • last, but not least, it provides a desirable solution to working with indexedDb object stores where using a uuid as the primaryKey becomes desireable.
    • enabling auto-sequencing capabilities
    • natural string collation
      • note the subtle use of uuid Variant-2 to reverse time value of the LHS in its stringified form.
    • natural and simple put updating
    • natural pattern for efs (EdgeS virtual file-system auto-names)
    • service-worker and cloud-server sync and replicate actions

Summary

Although terse, hopefully that is sufficient explanation for now; try it

And, please feel free to comment, submit feedback or suggestions.

When released as part of the EdgeS web-client eswc library on github the indexedDb usage patterns with efs will serve as examples of its design intentions which include addressing efficiencies and usability with indexedDb and related PWA sync and replicate scenarios.

Related

Benchmarking uuids/sec

const start = Xuid.ns7Now
for(let i = 100000; i; i -=1)
  Xuid.v4New
const end = Xuid.ns7Now
console.log(`Delta 7ns: ${(end-start)/100000n}`)

Resulted in: values of 16..20 => ~2 micro-seconds => 500,000 uuids/sec

1
2

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