const BinarySearchTree = require('@seald-io/binary-search-tree').BinarySearchTree const model = require('./model.js') const { uniq, isDate } = require('./utils.js') /** * Two indexed pointers are equal iif they point to the same place */ const checkValueEquality = (a, b) => a === b /** * Type-aware projection */ function projectForUnique (elt) { if (elt === null) return '$null' if (typeof elt === 'string') return '$string' + elt if (typeof elt === 'boolean') return '$boolean' + elt if (typeof elt === 'number') return '$number' + elt if (isDate(elt)) return '$date' + elt.getTime() return elt // Arrays and objects, will check for pointer equality } class Index { /** * Create a new index * All methods on an index guarantee that either the whole operation was successful and the index changed * or the operation was unsuccessful and an error is thrown while the index is unchanged * @param {String} options.fieldName On which field should the index apply (can use dot notation to index on sub fields) * @param {Boolean} options.unique Optional, enforce a unique constraint (default: false) * @param {Boolean} options.sparse Optional, allow a sparse index (we can have documents for which fieldName is undefined) (default: false) */ constructor (options) { this.fieldName = options.fieldName this.unique = options.unique || false this.sparse = options.sparse || false this.treeOptions = { unique: this.unique, compareKeys: model.compareThings, checkValueEquality: checkValueEquality } this.reset() // No data in the beginning } /** * Reset an index * @param {Document or Array of documents} newData Optional, data to initialize the index with * If an error is thrown during insertion, the index is not modified */ reset (newData) { this.tree = new BinarySearchTree(this.treeOptions) if (newData) this.insert(newData) } /** * Insert a new document in the index * If an array is passed, we insert all its elements (if one insertion fails the index is not modified) * O(log(n)) */ insert (doc) { let keys let failingIndex let error if (Array.isArray(doc)) { this.insertMultipleDocs(doc) return } const key = model.getDotValue(doc, this.fieldName) // We don't index documents that don't contain the field if the index is sparse if (key === undefined && this.sparse) return if (!Array.isArray(key)) this.tree.insert(key, doc) else { // If an insert fails due to a unique constraint, roll back all inserts before it keys = uniq(key, projectForUnique) for (let i = 0; i < keys.length; i += 1) { try { this.tree.insert(keys[i], doc) } catch (e) { error = e failingIndex = i break } } if (error) { for (let i = 0; i < failingIndex; i += 1) { this.tree.delete(keys[i], doc) } throw error } } } /** * Insert an array of documents in the index * If a constraint is violated, the changes should be rolled back and an error thrown * * @API private */ insertMultipleDocs (docs) { let error let failingIndex for (let i = 0; i < docs.length; i += 1) { try { this.insert(docs[i]) } catch (e) { error = e failingIndex = i break } } if (error) { for (let i = 0; i < failingIndex; i += 1) { this.remove(docs[i]) } throw error } } /** * Remove a document from the index * If an array is passed, we remove all its elements * The remove operation is safe with regards to the 'unique' constraint * O(log(n)) */ remove (doc) { if (Array.isArray(doc)) { doc.forEach(d => { this.remove(d) }) return } const key = model.getDotValue(doc, this.fieldName) if (key === undefined && this.sparse) return if (!Array.isArray(key)) { this.tree.delete(key, doc) } else { uniq(key, projectForUnique).forEach(_key => { this.tree.delete(_key, doc) }) } } /** * Update a document in the index * If a constraint is violated, changes are rolled back and an error thrown * Naive implementation, still in O(log(n)) */ update (oldDoc, newDoc) { if (Array.isArray(oldDoc)) { this.updateMultipleDocs(oldDoc) return } this.remove(oldDoc) try { this.insert(newDoc) } catch (e) { this.insert(oldDoc) throw e } } /** * Update multiple documents in the index * If a constraint is violated, the changes need to be rolled back * and an error thrown * @param {Array of oldDoc, newDoc pairs} pairs * * @API private */ updateMultipleDocs (pairs) { let failingIndex let error for (let i = 0; i < pairs.length; i += 1) { this.remove(pairs[i].oldDoc) } for (let i = 0; i < pairs.length; i += 1) { try { this.insert(pairs[i].newDoc) } catch (e) { error = e failingIndex = i break } } // If an error was raised, roll back changes in the inverse order if (error) { for (let i = 0; i < failingIndex; i += 1) { this.remove(pairs[i].newDoc) } for (let i = 0; i < pairs.length; i += 1) { this.insert(pairs[i].oldDoc) } throw error } } /** * Revert an update */ revertUpdate (oldDoc, newDoc) { const revert = [] if (!Array.isArray(oldDoc)) this.update(newDoc, oldDoc) else { oldDoc.forEach(pair => { revert.push({ oldDoc: pair.newDoc, newDoc: pair.oldDoc }) }) this.update(revert) } } /** * Get all documents in index whose key match value (if it is a Thing) or one of the elements of value (if it is an array of Things) * @param {Thing} value Value to match the key against * @return {Array of documents} */ getMatching (value) { if (!Array.isArray(value)) return this.tree.search(value) else { const _res = {} const res = [] value.forEach(v => { this.getMatching(v).forEach(doc => { _res[doc._id] = doc }) }) Object.keys(_res).forEach(_id => { res.push(_res[_id]) }) return res } } /** * Get all documents in index whose key is between bounds are they are defined by query * Documents are sorted by key * @param {Query} query * @return {Array of documents} */ getBetweenBounds (query) { return this.tree.betweenBounds(query) } /** * Get all elements in the index * @return {Array of documents} */ getAll () { const res = [] this.tree.executeOnEveryNode(node => { res.push(...node.data) }) return res } } // Interface module.exports = Index