'use strict' const { kState, kError, kResult, kAborted, kLastProgressEventFired } = require('./symbols') const { ProgressEvent } = require('./progressevent') const { getEncoding } = require('./encoding') const { serializeAMimeType, parseMIMEType } = require('../fetch/dataURL') const { types } = require('util') const { StringDecoder } = require('string_decoder') const { btoa } = require('buffer') /** @type {PropertyDescriptor} */ const staticPropertyDescriptors = { enumerable: true, writable: false, configurable: false } /** * @see https://w3c.github.io/FileAPI/#readOperation * @param {import('./filereader').FileReader} fr * @param {import('buffer').Blob} blob * @param {string} type * @param {string?} encodingName */ function readOperation (fr, blob, type, encodingName) { // 1. If fr’s state is "loading", throw an InvalidStateError // DOMException. if (fr[kState] === 'loading') { throw new DOMException('Invalid state', 'InvalidStateError') } // 2. Set fr’s state to "loading". fr[kState] = 'loading' // 3. Set fr’s result to null. fr[kResult] = null // 4. Set fr’s error to null. fr[kError] = null // 5. Let stream be the result of calling get stream on blob. /** @type {import('stream/web').ReadableStream} */ const stream = blob.stream() // 6. Let reader be the result of getting a reader from stream. const reader = stream.getReader() // 7. Let bytes be an empty byte sequence. /** @type {Uint8Array[]} */ const bytes = [] // 8. Let chunkPromise be the result of reading a chunk from // stream with reader. let chunkPromise = reader.read() // 9. Let isFirstChunk be true. let isFirstChunk = true // 10. In parallel, while true: // Note: "In parallel" just means non-blocking // Note 2: readOperation itself cannot be async as double // reading the body would then reject the promise, instead // of throwing an error. ;(async () => { while (!fr[kAborted]) { // 1. Wait for chunkPromise to be fulfilled or rejected. try { const { done, value } = await chunkPromise // 2. If chunkPromise is fulfilled, and isFirstChunk is // true, queue a task to fire a progress event called // loadstart at fr. if (isFirstChunk && !fr[kAborted]) { queueMicrotask(() => { fireAProgressEvent('loadstart', fr) }) } // 3. Set isFirstChunk to false. isFirstChunk = false // 4. If chunkPromise is fulfilled with an object whose // done property is false and whose value property is // a Uint8Array object, run these steps: if (!done && types.isUint8Array(value)) { // 1. Let bs be the byte sequence represented by the // Uint8Array object. // 2. Append bs to bytes. bytes.push(value) // 3. If roughly 50ms have passed since these steps // were last invoked, queue a task to fire a // progress event called progress at fr. if ( ( fr[kLastProgressEventFired] === undefined || Date.now() - fr[kLastProgressEventFired] >= 50 ) && !fr[kAborted] ) { fr[kLastProgressEventFired] = Date.now() queueMicrotask(() => { fireAProgressEvent('progress', fr) }) } // 4. Set chunkPromise to the result of reading a // chunk from stream with reader. chunkPromise = reader.read() } else if (done) { // 5. Otherwise, if chunkPromise is fulfilled with an // object whose done property is true, queue a task // to run the following steps and abort this algorithm: queueMicrotask(() => { // 1. Set fr’s state to "done". fr[kState] = 'done' // 2. Let result be the result of package data given // bytes, type, blob’s type, and encodingName. try { const result = packageData(bytes, type, blob.type, encodingName) // 4. Else: if (fr[kAborted]) { return } // 1. Set fr’s result to result. fr[kResult] = result // 2. Fire a progress event called load at the fr. fireAProgressEvent('load', fr) } catch (error) { // 3. If package data threw an exception error: // 1. Set fr’s error to error. fr[kError] = error // 2. Fire a progress event called error at fr. fireAProgressEvent('error', fr) } // 5. If fr’s state is not "loading", fire a progress // event called loadend at the fr. if (fr[kState] !== 'loading') { fireAProgressEvent('loadend', fr) } }) break } } catch (error) { if (fr[kAborted]) { return } // 6. Otherwise, if chunkPromise is rejected with an // error error, queue a task to run the following // steps and abort this algorithm: queueMicrotask(() => { // 1. Set fr’s state to "done". fr[kState] = 'done' // 2. Set fr’s error to error. fr[kError] = error // 3. Fire a progress event called error at fr. fireAProgressEvent('error', fr) // 4. If fr’s state is not "loading", fire a progress // event called loadend at fr. if (fr[kState] !== 'loading') { fireAProgressEvent('loadend', fr) } }) break } } })() } /** * @see https://w3c.github.io/FileAPI/#fire-a-progress-event * @see https://dom.spec.whatwg.org/#concept-event-fire * @param {string} e The name of the event * @param {import('./filereader').FileReader} reader */ function fireAProgressEvent (e, reader) { // The progress event e does not bubble. e.bubbles must be false // The progress event e is NOT cancelable. e.cancelable must be false const event = new ProgressEvent(e, { bubbles: false, cancelable: false }) reader.dispatchEvent(event) } /** * @see https://w3c.github.io/FileAPI/#blob-package-data * @param {Uint8Array[]} bytes * @param {string} type * @param {string?} mimeType * @param {string?} encodingName */ function packageData (bytes, type, mimeType, encodingName) { // 1. A Blob has an associated package data algorithm, given // bytes, a type, a optional mimeType, and a optional // encodingName, which switches on type and runs the // associated steps: switch (type) { case 'DataURL': { // 1. Return bytes as a DataURL [RFC2397] subject to // the considerations below: // * Use mimeType as part of the Data URL if it is // available in keeping with the Data URL // specification [RFC2397]. // * If mimeType is not available return a Data URL // without a media-type. [RFC2397]. // https://datatracker.ietf.org/doc/html/rfc2397#section-3 // dataurl := "data:" [ mediatype ] [ ";base64" ] "," data // mediatype := [ type "/" subtype ] *( ";" parameter ) // data := *urlchar // parameter := attribute "=" value let dataURL = 'data:' const parsed = parseMIMEType(mimeType || 'application/octet-stream') if (parsed !== 'failure') { dataURL += serializeAMimeType(parsed) } dataURL += ';base64,' const decoder = new StringDecoder('latin1') for (const chunk of bytes) { dataURL += btoa(decoder.write(chunk)) } dataURL += btoa(decoder.end()) return dataURL } case 'Text': { // 1. Let encoding be failure let encoding = 'failure' // 2. If the encodingName is present, set encoding to the // result of getting an encoding from encodingName. if (encodingName) { encoding = getEncoding(encodingName) } // 3. If encoding is failure, and mimeType is present: if (encoding === 'failure' && mimeType) { // 1. Let type be the result of parse a MIME type // given mimeType. const type = parseMIMEType(mimeType) // 2. If type is not failure, set encoding to the result // of getting an encoding from type’s parameters["charset"]. if (type !== 'failure') { encoding = getEncoding(type.parameters.get('charset')) } } // 4. If encoding is failure, then set encoding to UTF-8. if (encoding === 'failure') { encoding = 'UTF-8' } // 5. Decode bytes using fallback encoding encoding, and // return the result. return decode(bytes, encoding) } case 'ArrayBuffer': { // Return a new ArrayBuffer whose contents are bytes. const sequence = combineByteSequences(bytes) return sequence.buffer } case 'BinaryString': { // Return bytes as a binary string, in which every byte // is represented by a code unit of equal value [0..255]. let binaryString = '' const decoder = new StringDecoder('latin1') for (const chunk of bytes) { binaryString += decoder.write(chunk) } binaryString += decoder.end() return binaryString } } } /** * @see https://encoding.spec.whatwg.org/#decode * @param {Uint8Array[]} ioQueue * @param {string} encoding */ function decode (ioQueue, encoding) { const bytes = combineByteSequences(ioQueue) // 1. Let BOMEncoding be the result of BOM sniffing ioQueue. const BOMEncoding = BOMSniffing(bytes) let slice = 0 // 2. If BOMEncoding is non-null: if (BOMEncoding !== null) { // 1. Set encoding to BOMEncoding. encoding = BOMEncoding // 2. Read three bytes from ioQueue, if BOMEncoding is // UTF-8; otherwise read two bytes. // (Do nothing with those bytes.) slice = BOMEncoding === 'UTF-8' ? 3 : 2 } // 3. Process a queue with an instance of encoding’s // decoder, ioQueue, output, and "replacement". // 4. Return output. const sliced = bytes.slice(slice) return new TextDecoder(encoding).decode(sliced) } /** * @see https://encoding.spec.whatwg.org/#bom-sniff * @param {Uint8Array} ioQueue */ function BOMSniffing (ioQueue) { // 1. Let BOM be the result of peeking 3 bytes from ioQueue, // converted to a byte sequence. const [a, b, c] = ioQueue // 2. For each of the rows in the table below, starting with // the first one and going down, if BOM starts with the // bytes given in the first column, then return the // encoding given in the cell in the second column of that // row. Otherwise, return null. if (a === 0xEF && b === 0xBB && c === 0xBF) { return 'UTF-8' } else if (a === 0xFE && b === 0xFF) { return 'UTF-16BE' } else if (a === 0xFF && b === 0xFE) { return 'UTF-16LE' } return null } /** * @param {Uint8Array[]} sequences */ function combineByteSequences (sequences) { const size = sequences.reduce((a, b) => { return a + b.byteLength }, 0) let offset = 0 return sequences.reduce((a, b) => { a.set(b, offset) offset += b.byteLength return a }, new Uint8Array(size)) } module.exports = { staticPropertyDescriptors, readOperation, fireAProgressEvent }