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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at
http://mozilla.org/MPL/2.0/. */
const hashBits = 48;
const hashLength = hashBits / 4; // each hexadecimal digit represents 4 bits
const hashMultiplier = Math.pow(2, hashBits) - 1;
export var Sampling = {
/**
* Map from the range [0, 1] to [0, 2^48].
* @param {number} frac A float from 0.0 to 1.0.
* @return {string} A 48 bit number represented in hex, padded to 12 characters.
*/
fractionToKey(frac) {
if (frac < 0 || frac > 1) {
throw new Error(`frac must be between 0 and 1 inclusive (got ${frac})`);
}
return Math.floor(frac * hashMultiplier)
.toString(16)
.padStart(hashLength, "0");
},
/**
* @param {ArrayBuffer} buffer Data to convert
* @returns {String} `buffer`'s content, converted to a hexadecimal string.
*/
bufferToHex(buffer) {
const hexCodes = [];
const view = new DataView(buffer);
for (let i = 0; i < view.byteLength; i += 4) {
// Using getUint32 reduces the number of iterations needed (we process 4 bytes each time)
const value = view.getUint32(i);
// toString(16) will give the hex representation of the number without padding
hexCodes.push(value.toString(16).padStart(8, "0"));
}
// Join all the hex strings into one
return hexCodes.join("");
},
/**
* Check if an input hash is contained in a bucket range.
*
* isHashInBucket(fractionToKey(0.5), 3, 6, 10) -> returns true
*
* minBucket
* | hash
* v v
* [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
* ^
* maxBucket
*
* @param inputHash {String}
* @param minBucket {int} The lower boundary, inclusive, of the range to check.
* @param maxBucket {int} The upper boundary, exclusive, of the range to check.
* @param bucketCount {int} The total number of buckets. Should be greater than
* or equal to maxBucket.
*/
isHashInBucket(inputHash, minBucket, maxBucket, bucketCount) {
const minHash = Sampling.fractionToKey(minBucket / bucketCount);
const maxHash = Sampling.fractionToKey(maxBucket / bucketCount);
return minHash <= inputHash && inputHash < maxHash;
},
/**
* @promise A hash of `data`, truncated to the 12 most significant characters.
*/
async truncatedHash(data) {
const hasher = crypto.subtle;
const input = new TextEncoder().encode(JSON.stringify(data));
const hash = await hasher.digest("SHA-256", input);
// truncate hash to 12 characters (2^48), because the full hash is larger
// than JS can meaningfully represent as a number.
return Sampling.bufferToHex(hash).slice(0, 12);
},
/**
* Sample by splitting the input into two buckets, one with a size (rate) and
* another with a size (1.0 - rate), and then check if the input's hash falls
* into the first bucket.
*
* @param {object} input Input to hash to determine the sample.
* @param {Number} rate Number between 0.0 and 1.0 to sample at. A value of
* 0.25 returns true 25% of the time.
* @promises {boolean} True if the input is in the sample.
*/
async stableSample(input, rate) {
const inputHash = await Sampling.truncatedHash(input);
const samplePoint = Sampling.fractionToKey(rate);
return inputHash < samplePoint;
},
/**
* Sample by splitting the input space into a series of buckets, and checking
* if the given input is in a range of buckets.
*
* The range to check is defined by a start point and length, and can wrap
* around the input space. For example, if there are 100 buckets, and we ask to
* check 50 buckets starting from bucket 70, then buckets 70-99 and 0-19 will
* be checked.
*
* @param {object} input Input to hash to determine the matching bucket.
* @param {integer} start Index of the bucket to start checking.
* @param {integer} count Number of buckets to check.
* @param {integer} total Total number of buckets to group inputs into.
* @promises {boolean} True if the given input is within the range of buckets
* we're checking. */
async bucketSample(input, start, count, total) {
const inputHash = await Sampling.truncatedHash(input);
const wrappedStart = start % total;
const end = wrappedStart + count;
// If the range we're testing wraps, we have to check two ranges: from start
// to max, and from min to end.
if (end > total) {
return (
Sampling.isHashInBucket(inputHash, 0, end % total, total) ||
Sampling.isHashInBucket(inputHash, wrappedStart, total, total)
);
}
return Sampling.isHashInBucket(inputHash, wrappedStart, end, total);
},
/**
* Sample over a list of ratios such that, over the input space, each ratio
* has a number of matches in correct proportion to the other ratios.
*
* For example, given the ratios:
*
* [1, 2, 3, 4]
*
* 10% of all inputs will return 0, 20% of all inputs will return 1, 30% will
* return 2, and 40% will return 3. You can determine the percent of inputs
* that will return an index by dividing the ratio by the sum of all ratios
* passed in. In the case above, 4 / (1 + 2 + 3 + 4) == 0.4, or 40% of the
* inputs.
*
* @param {object} input
* @param {Array<integer>} ratios
* @promises {integer}
* Index of the ratio that matched the input
* @rejects {Error}
* If the list of ratios doesn't have at least one element
*/
async ratioSample(input, ratios) {
if (ratios.length < 1) {
throw new Error(
`ratios must be at least 1 element long (got length: ${ratios.length})`
);
}
const inputHash = await Sampling.truncatedHash(input);
const ratioTotal = ratios.reduce((acc, ratio) => acc + ratio);
let samplePoint = 0;
for (let k = 0; k < ratios.length - 1; k++) {
samplePoint += ratios[k];
if (inputHash <= Sampling.fractionToKey(samplePoint / ratioTotal)) {
return k;
}
}
// No need to check the last bucket if the others didn't match.
return ratios.length - 1;
},
};
