parcoursup/node_modules/nanoid/async/index.browser.js

let random = bytes =>
  Promise.resolve(crypto.getRandomValues(new Uint8Array(bytes)))

let customAlphabet = (alphabet, size) => {
  // First, a bitmask is necessary to generate the ID. The bitmask makes bytes
  // values closer to the alphabet size. The bitmask calculates the closest
  // `2^31 - 1` number, which exceeds the alphabet size.
  // For example, the bitmask for the alphabet size 30 is 31 (00011111).
  // `Math.clz32` is not used, because it is not available in browsers.
  let mask = (2 << (Math.log(alphabet.length - 1) / Math.LN2)) - 1
  // Though, the bitmask solution is not perfect since the bytes exceeding
  // the alphabet size are refused. Therefore, to reliably generate the ID,
  // the random bytes redundancy has to be satisfied.

  // Note: every hardware random generator call is performance expensive,
  // because the system call for entropy collection takes a lot of time.
  // So, to avoid additional system calls, extra bytes are requested in advance.

  // Next, a step determines how many random bytes to generate.
  // The number of random bytes gets decided upon the ID size, mask,
  // alphabet size, and magic number 1.6 (using 1.6 peaks at performance
  // according to benchmarks).

  // `-~f => Math.ceil(f)` if f is a float
  // `-~i => i + 1` if i is an integer
  let step = -~((1.6 * mask * size) / alphabet.length)

  return () => {
    let id = ''
    while (true) {
      let bytes = crypto.getRandomValues(new Uint8Array(step))
      // A compact alternative for `for (var i = 0; i < step; i++)`.
      let i = step
      while (i--) {
        // Adding `|| ''` refuses a random byte that exceeds the alphabet size.
        id += alphabet[bytes[i] & mask] || ''
        if (id.length === size) return Promise.resolve(id)
      }
    }
  }
}

let nanoid = (size = 21) => {
  let id = ''
  let bytes = crypto.getRandomValues(new Uint8Array(size))

  // A compact alternative for `for (var i = 0; i < step; i++)`.
  while (size--) {
    // It is incorrect to use bytes exceeding the alphabet size.
    // The following mask reduces the random byte in the 0-255 value
    // range to the 0-63 value range. Therefore, adding hacks, such
    // as empty string fallback or magic numbers, is unneccessary because
    // the bitmask trims bytes down to the alphabet size.
    let byte = bytes[size] & 63
    if (byte < 36) {
      // `0-9a-z`
      id += byte.toString(36)
    } else if (byte < 62) {
      // `A-Z`
      id += (byte - 26).toString(36).toUpperCase()
    } else if (byte < 63) {
      id += '_'
    } else {
      id += '-'
    }
  }
  return Promise.resolve(id)
}

export { nanoid, customAlphabet, random }
$ 2023-03-05 13:23:23 +01:00			`let random = bytes =>`
			`Promise.resolve(crypto.getRandomValues(new Uint8Array(bytes)))`

			`let customAlphabet = (alphabet, size) => {`
			`// First, a bitmask is necessary to generate the ID. The bitmask makes bytes`
			`// values closer to the alphabet size. The bitmask calculates the closest`
			// `2^31 - 1` number, which exceeds the alphabet size.
			`// For example, the bitmask for the alphabet size 30 is 31 (00011111).`
			// `Math.clz32` is not used, because it is not available in browsers.
			`let mask = (2 << (Math.log(alphabet.length - 1) / Math.LN2)) - 1`
			`// Though, the bitmask solution is not perfect since the bytes exceeding`
			`// the alphabet size are refused. Therefore, to reliably generate the ID,`
			`// the random bytes redundancy has to be satisfied.`

			`// Note: every hardware random generator call is performance expensive,`
			`// because the system call for entropy collection takes a lot of time.`
			`// So, to avoid additional system calls, extra bytes are requested in advance.`

			`// Next, a step determines how many random bytes to generate.`
			`// The number of random bytes gets decided upon the ID size, mask,`
			`// alphabet size, and magic number 1.6 (using 1.6 peaks at performance`
			`// according to benchmarks).`

			// `-~f => Math.ceil(f)` if f is a float
			// `-~i => i + 1` if i is an integer
			`let step = -~((1.6 * mask * size) / alphabet.length)`

			`return () => {`
			`let id = ''`
			`while (true) {`
			`let bytes = crypto.getRandomValues(new Uint8Array(step))`
			// A compact alternative for `for (var i = 0; i < step; i++)`.
			`let i = step`
			`while (i--) {`
			// Adding `\|\| ''` refuses a random byte that exceeds the alphabet size.
			`id += alphabet[bytes[i] & mask] \|\| ''`
			`if (id.length === size) return Promise.resolve(id)`
			`}`
			`}`
			`}`
			`}`

			`let nanoid = (size = 21) => {`
			`let id = ''`
			`let bytes = crypto.getRandomValues(new Uint8Array(size))`

			// A compact alternative for `for (var i = 0; i < step; i++)`.
			`while (size--) {`
			`// It is incorrect to use bytes exceeding the alphabet size.`
			`// The following mask reduces the random byte in the 0-255 value`
			`// range to the 0-63 value range. Therefore, adding hacks, such`
			`// as empty string fallback or magic numbers, is unneccessary because`
			`// the bitmask trims bytes down to the alphabet size.`
			`let byte = bytes[size] & 63`
			`if (byte < 36) {`
			// `0-9a-z`
			`id += byte.toString(36)`
			`} else if (byte < 62) {`
			// `A-Z`
			`id += (byte - 26).toString(36).toUpperCase()`
			`} else if (byte < 63) {`
			`id += '_'`
			`} else {`
			`id += '-'`
			`}`
			`}`
			`return Promise.resolve(id)`
			`}`

			`export { nanoid, customAlphabet, random }`