import * as ffmpeg from 'fluent-ffmpeg'
import { join } from 'path'
import { VideoResolution } from '../../shared/models/videos'
import { CONFIG, VIDEO_TRANSCODING_FPS, FFMPEG_NICE } from '../initializers'
import { unlinkPromise } from './core-utils'
import { processImage } from './image-utils'
import { logger } from './logger'
import { checkFFmpegEncoders } from '../initializers/checker'
async function getVideoFileResolution (path: string) {
const videoStream = await getVideoFileStream(path)
return {
videoFileResolution: Math.min(videoStream.height, videoStream.width),
isPortraitMode: videoStream.height > videoStream.width
}
}
async function getVideoFileFPS (path: string) {
const videoStream = await getVideoFileStream(path)
for (const key of [ 'r_frame_rate' , 'avg_frame_rate' ]) {
const valuesText: string = videoStream[key]
if (!valuesText) continue
const [ frames, seconds ] = valuesText.split('/')
if (!frames || !seconds) continue
const result = parseInt(frames, 10) / parseInt(seconds, 10)
if (result > 0) return Math.round(result)
}
return 0
}
function getDurationFromVideoFile (path: string) {
return new Promise<number>((res, rej) => {
ffmpeg.ffprobe(path, (err, metadata) => {
if (err) return rej(err)
return res(Math.floor(metadata.format.duration))
})
})
}
async function generateImageFromVideoFile (fromPath: string, folder: string, imageName: string, size: { width: number, height: number }) {
const pendingImageName = 'pending-' + imageName
const options = {
filename: pendingImageName,
count: 1,
folder
}
const pendingImagePath = join(folder, pendingImageName)
try {
await new Promise<string>((res, rej) => {
ffmpeg(fromPath, { 'niceness': FFMPEG_NICE.THUMBNAIL })
.on('error', rej)
.on('end', () => res(imageName))
.thumbnail(options)
})
const destination = join(folder, imageName)
await processImage({ path: pendingImagePath }, destination, size)
} catch (err) {
logger.error('Cannot generate image from video %s.', fromPath, { err })
try {
await unlinkPromise(pendingImagePath)
} catch (err) {
logger.debug('Cannot remove pending image path after generation error.', { err })
}
}
}
type TranscodeOptions = {
inputPath: string
outputPath: string
resolution?: VideoResolution
isPortraitMode?: boolean
}
function transcode (options: TranscodeOptions) {
return new Promise<void>(async (res, rej) => {
let command = ffmpeg(options.inputPath, { 'niceness': FFMPEG_NICE.TRANSCODING })
.output(options.outputPath)
.preset(standard)
if (CONFIG.TRANSCODING.THREADS > 0) {
command.outputOption('-threads ' + CONFIG.TRANSCODING.THREADS) // if we don't set any threads ffmpeg will chose automatically
}
let fps = await getVideoFileFPS(options.inputPath)
if (options.resolution !== undefined) {
// '?x720' or '720x?' for example
const size = options.isPortraitMode === true ? `${options.resolution}x?` : `?x${options.resolution}`
command = command.size(size)
// On small/medium resolutions, limit FPS
if (
options.resolution < VIDEO_TRANSCODING_FPS.KEEP_ORIGIN_FPS_RESOLUTION_MIN &&
fps > VIDEO_TRANSCODING_FPS.AVERAGE
) {
fps = VIDEO_TRANSCODING_FPS.AVERAGE
}
}
if (fps) {
// Hard FPS limits
if (fps > VIDEO_TRANSCODING_FPS.MAX) fps = VIDEO_TRANSCODING_FPS.MAX
else if (fps < VIDEO_TRANSCODING_FPS.MIN) fps = VIDEO_TRANSCODING_FPS.MIN
command = command.withFPS(fps)
}
command
.on('error', (err, stdout, stderr) => {
logger.error('Error in transcoding job.', { stdout, stderr })
return rej(err)
})
.on('end', res)
.run()
})
}
// ---------------------------------------------------------------------------
export {
getVideoFileResolution,
getDurationFromVideoFile,
generateImageFromVideoFile,
transcode,
getVideoFileFPS
}
// ---------------------------------------------------------------------------
function getVideoFileStream (path: string) {
return new Promise<any>((res, rej) => {
ffmpeg.ffprobe(path, (err, metadata) => {
if (err) return rej(err)
const videoStream = metadata.streams.find(s => s.codec_type === 'video')
if (!videoStream) throw new Error('Cannot find video stream of ' + path)
return res(videoStream)
})
})
}
/**
* A slightly customised version of the 'veryfast' x264 preset
*
* The veryfast preset is right in the sweet spot of performance
* and quality. Superfast and ultrafast will give you better
* performance, but then quality is noticeably worse.
*/
function veryfast (_ffmpeg) {
_ffmpeg
.preset(standard)
.outputOption('-preset:v veryfast')
.outputOption(['--aq-mode=2', '--aq-strength=1.3'])
/*
MAIN reference: https://slhck.info/video/2017/03/01/rate-control.html
Our target situation is closer to a livestream than a stream,
since we want to reduce as much a possible the encoding burden,
altough not to the point of a livestream where there is a hard
constraint on the frames per second to be encoded.
why '--aq-mode=2 --aq-strength=1.3' instead of '-profile:v main'?
Make up for most of the loss of grain and macroblocking
with less computing power.
*/
}
/**
* A preset optimised for a stillimage audio video
*/
function audio (_ffmpeg) {
_ffmpeg
.preset(veryfast)
.outputOption('-tune stillimage')
}
/**
* A toolbox to play with audio
*/
namespace audio {
export const get = (_ffmpeg, pos: number | string = 0) => {
// without position, ffprobe considers the last input only
// we make it consider the first input only
// if you pass a file path to pos, then ffprobe acts on that file directly
return new Promise<any>((res, rej) => {
_ffmpeg
.ffprobe(pos, (err,data) => {
if (err) return rej(err)
if ('streams' in data) {
return res(data['streams'].find(stream => stream['codec_type'] === 'audio'))
} else {
rej()
}
})
})
}
export namespace bitrate {
export const baseKbitrate = 384
const toBits = (kbits: number): number => { return kbits * 8000 }
export const aac = (bitrate: number): number => {
switch (true) {
case bitrate > toBits(384):
return baseKbitrate
default:
return -1 // we interpret it as a signal to copy the audio stream as is
}
}
export const mp3 = (bitrate: number): number => {
switch (true) {
case bitrate <= toBits(192):
return 128
case bitrate <= toBits(384):
return 256
default:
return baseKbitrate
}
}
}
}
/**
* Standard profile, with variable bitrate audio and faststart.
*
* As for the audio, quality '5' is the highest and ensures 96-112kbps/channel
* See https://trac.ffmpeg.org/wiki/Encode/AAC#fdk_vbr
*/
async function standard (_ffmpeg) {
let _bitrate = audio.bitrate.baseKbitrate
let localFfmpeg = _ffmpeg
.format('mp4')
.videoCodec('libx264')
.outputOption('-level 3.1') // 3.1 is the minimal ressource allocation for our highest supported resolution
.outputOption('-b_strategy 1') // NOTE: b-strategy 1 - heuristic algorythm, 16 is optimal B-frames for it
.outputOption('-bf 16') // NOTE: Why 16: https://github.com/Chocobozzz/PeerTube/pull/774. b-strategy 2 -> B-frames<16
.outputOption('-map_metadata -1') // strip all metadata
.outputOption('-movflags faststart')
let _audio = audio.get(localFfmpeg)
.then(res => res)
.catch(_ => undefined)
if (!_audio) return localFfmpeg.noAudio()
// we try to reduce the ceiling bitrate by making rough correspondances of bitrates
// of course this is far from perfect, but it might save some space in the end
if (audio.bitrate[_audio['codec_name']]) {
_bitrate = audio.bitrate[_audio['codec_name']](_audio['bit_rate'])
if (_bitrate === -1) {
return localFfmpeg.audioCodec('copy')
}
}
// we favor VBR, if a good AAC encoder is available
if ((await checkFFmpegEncoders()).get('libfdk_aac')) {
return localFfmpeg
.audioCodec('libfdk_aac')
.audioQuality(5)
}
return localFfmpeg.audioBitrate(_bitrate)
}