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- "use strict";
-
- // Simulations show these probabilities for a single change
- // 93.1% that one group is invalidated
- // 4.8% that two groups are invalidated
- // 1.1% that 3 groups are invalidated
- // 0.1% that 4 or more groups are invalidated
- //
- // And these for removing/adding 10 lexically adjacent files
- // 64.5% that one group is invalidated
- // 24.8% that two groups are invalidated
- // 7.8% that 3 groups are invalidated
- // 2.7% that 4 or more groups are invalidated
- //
- // And these for removing/adding 3 random files
- // 0% that one group is invalidated
- // 3.7% that two groups are invalidated
- // 80.8% that 3 groups are invalidated
- // 12.3% that 4 groups are invalidated
- // 3.2% that 5 or more groups are invalidated
-
- /**
- *
- * @param {string} a key
- * @param {string} b key
- * @returns {number} the similarity as number
- */
- const similarity = (a, b) => {
- const l = Math.min(a.length, b.length);
- let dist = 0;
- for (let i = 0; i < l; i++) {
- const ca = a.charCodeAt(i);
- const cb = b.charCodeAt(i);
- dist += Math.max(0, 10 - Math.abs(ca - cb));
- }
- return dist;
- };
-
- /**
- * @param {string} a key
- * @param {string} b key
- * @returns {string} the common part and a single char for the difference
- */
- const getName = (a, b) => {
- const l = Math.min(a.length, b.length);
- let r = "";
- for (let i = 0; i < l; i++) {
- const ca = a.charAt(i);
- const cb = b.charAt(i);
- r += ca;
- if (ca === cb) {
- continue;
- }
- return r;
- }
- return a;
- };
-
- /**
- * @template T
- */
- class Node {
- /**
- * @param {T} item item
- * @param {string} key key
- * @param {number} size size
- */
- constructor(item, key, size) {
- this.item = item;
- this.key = key;
- this.size = size;
- }
- }
-
- /**
- * @template T
- */
- class Group {
- /**
- * @param {Node<T>[]} nodes nodes
- * @param {number[]} similarities similarities between the nodes (length = nodes.length - 1)
- */
- constructor(nodes, similarities) {
- this.nodes = nodes;
- this.similarities = similarities;
- this.size = nodes.reduce((size, node) => size + node.size, 0);
- /** @type {string} */
- this.key = undefined;
- }
- }
-
- /**
- * @template T
- * @typedef {Object} GroupedItems<T>
- * @property {string} key
- * @property {T[]} items
- * @property {number} size
- */
-
- /**
- * @template T
- * @typedef {Object} Options
- * @property {number} maxSize maximum size of a group
- * @property {number} minSize minimum size of a group (preferred over maximum size)
- * @property {Iterable<T>} items a list of items
- * @property {function(T): number} getSize function to get size of an item
- * @property {function(T): string} getKey function to get the key of an item
- */
-
- /**
- * @template T
- * @param {Options<T>} options options object
- * @returns {GroupedItems<T>[]} grouped items
- */
- module.exports = ({ maxSize, minSize, items, getSize, getKey }) => {
- /** @type {Group<T>[]} */
- const result = [];
-
- const nodes = Array.from(
- items,
- item => new Node(item, getKey(item), getSize(item))
- );
-
- /** @type {Node<T>[]} */
- const initialNodes = [];
-
- // lexically ordering of keys
- nodes.sort((a, b) => {
- if (a.key < b.key) return -1;
- if (a.key > b.key) return 1;
- return 0;
- });
-
- // return nodes bigger than maxSize directly as group
- for (const node of nodes) {
- if (node.size >= maxSize) {
- result.push(new Group([node], []));
- } else {
- initialNodes.push(node);
- }
- }
-
- if (initialNodes.length > 0) {
- // calculate similarities between lexically adjacent nodes
- /** @type {number[]} */
- const similarities = [];
- for (let i = 1; i < initialNodes.length; i++) {
- const a = initialNodes[i - 1];
- const b = initialNodes[i];
- similarities.push(similarity(a.key, b.key));
- }
-
- const initialGroup = new Group(initialNodes, similarities);
-
- if (initialGroup.size < minSize) {
- // We hit an edgecase where the working set is already smaller than minSize
- // We merge it with the smallest result node to keep minSize intact
- if (result.length > 0) {
- const smallestGroup = result.reduce((min, group) =>
- min.size > group.size ? group : min
- );
- for (const node of initialGroup.nodes) smallestGroup.nodes.push(node);
- smallestGroup.nodes.sort((a, b) => {
- if (a.key < b.key) return -1;
- if (a.key > b.key) return 1;
- return 0;
- });
- } else {
- // There are no other nodes
- // We use all nodes and have to accept that it's smaller than minSize
- result.push(initialGroup);
- }
- } else {
- const queue = [initialGroup];
-
- while (queue.length) {
- const group = queue.pop();
- // only groups bigger than maxSize need to be splitted
- if (group.size < maxSize) {
- result.push(group);
- continue;
- }
-
- // find unsplittable area from left and right
- // going minSize from left and right
- // at least one node need to be included otherwise we get stuck
- let left = 0;
- let leftSize = 0;
- while (leftSize <= minSize) {
- leftSize += group.nodes[left].size;
- left++;
- }
- let right = group.nodes.length - 1;
- let rightSize = 0;
- while (rightSize <= minSize) {
- rightSize += group.nodes[right].size;
- right--;
- }
-
- if (left - 1 > right) {
- // can't split group while holding minSize
- // because minSize is preferred of maxSize we return
- // the group here even while it's too big
- // To avoid this make sure maxSize > minSize * 3
- result.push(group);
- continue;
- }
- if (left <= right) {
- // when there is a area between left and right
- // we look for best split point
- // we split at the minimum similarity
- // here key space is separated the most
- let best = left - 1;
- let bestSimilarity = group.similarities[best];
- for (let i = left; i <= right; i++) {
- const similarity = group.similarities[i];
- if (similarity < bestSimilarity) {
- best = i;
- bestSimilarity = similarity;
- }
- }
- left = best + 1;
- right = best;
- }
-
- // create two new groups for left and right area
- // and queue them up
- const rightNodes = [group.nodes[right + 1]];
- /** @type {number[]} */
- const rightSimilaries = [];
- for (let i = right + 2; i < group.nodes.length; i++) {
- rightSimilaries.push(group.similarities[i - 1]);
- rightNodes.push(group.nodes[i]);
- }
- queue.push(new Group(rightNodes, rightSimilaries));
-
- const leftNodes = [group.nodes[0]];
- /** @type {number[]} */
- const leftSimilaries = [];
- for (let i = 1; i < left; i++) {
- leftSimilaries.push(group.similarities[i - 1]);
- leftNodes.push(group.nodes[i]);
- }
- queue.push(new Group(leftNodes, leftSimilaries));
- }
- }
- }
-
- // lexically ordering
- result.sort((a, b) => {
- if (a.nodes[0].key < b.nodes[0].key) return -1;
- if (a.nodes[0].key > b.nodes[0].key) return 1;
- return 0;
- });
-
- // give every group a name
- for (let i = 0; i < result.length; i++) {
- const group = result[i];
- const first = group.nodes[0];
- const last = group.nodes[group.nodes.length - 1];
- let name = getName(first.key, last.key);
- group.key = name;
- }
-
- // return the results
- return result.map(group => {
- /** @type {GroupedItems} */
- return {
- key: group.key,
- items: group.nodes.map(node => node.item),
- size: group.size
- };
- });
- };
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