Merge branch 'master' into m3u-reduc

This commit is contained in:
Trek H 2020-01-24 15:17:51 +10:30
commit 4e4eaf95d4
10 changed files with 107 additions and 53 deletions

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@ -1,12 +1,9 @@
/*
NAME
lex-mjpeg.js
AUTHOR
Trek Hopton <trek@ausocean.org>
LICENSE
This file is Copyright (C) 2019 the Australian Ocean Lab (AusOcean)
This file is Copyright (C) 2020 the Australian Ocean Lab (AusOcean)
It is free software: you can redistribute it and/or modify them
under the terms of the GNU General Public License as published by the
@ -24,11 +21,14 @@ LICENSE
// MJPEGLexer lexes a byte array containing MJPEG into individual JPEGs.
class MJPEGLexer {
constructor(src) {
this.src = src;
constructor() {
this.off = 0;
}
append(data) {
this.src = new Uint8Array(data);
}
// read returns the next single frame.
read() {
// Check if the src can contain at least the start and end flags (4B).

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@ -66,7 +66,7 @@ func Lex(dst io.Writer, src io.Reader, delay time.Duration) error {
buf := make([]byte, len(h264Prefix), bufSize)
copy(buf, h264Prefix[:])
writeOut := false
outer:
for {
var b byte
var err error
@ -75,7 +75,10 @@ outer:
if err != io.EOF {
return err
}
break
if len(buf) != 0 {
return io.ErrUnexpectedEOF
}
return io.EOF
}
for n := 1; b == 0x0 && n < 4; n++ {
@ -84,7 +87,7 @@ outer:
if err != io.EOF {
return err
}
break outer
return io.ErrUnexpectedEOF
}
buf = append(buf, b)
@ -109,7 +112,7 @@ outer:
if err != io.EOF {
return err
}
break outer
return io.ErrUnexpectedEOF
}
buf = append(buf, b)
@ -127,10 +130,4 @@ outer:
}
}
}
if len(buf) == len(h264Prefix) {
return nil
}
<-tick
_, err := dst.Write(buf)
return err
}

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@ -76,10 +76,14 @@ func (l *Lexer) Lex(dst io.Writer, src io.Reader, delay time.Duration) error {
n, err := src.Read(buf)
switch err {
case nil: // Do nothing.
case io.EOF:
return nil
default:
return fmt.Errorf("source read error: %w\n", err)
if err == io.EOF {
if l.buf.Len() == 0 {
return io.EOF
}
return io.ErrUnexpectedEOF
}
return err
}
// Get payload from RTP packet.
@ -181,7 +185,7 @@ func (l *Lexer) handleFragmentation(d []byte) {
}
}
// handlePACI will handl PACI packets
// handlePACI will handle PACI packets
//
// TODO: complete this
func (l *Lexer) handlePACI(d []byte) {

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@ -247,7 +247,9 @@ func TestLex(t *testing.T) {
r := &rtpReader{packets: test.packets}
d := &destination{}
err := NewLexer(test.donl).Lex(d, r, 0)
if err != nil {
switch err {
case nil, io.EOF: // Do nothing
default:
t.Fatalf("error lexing: %v\n", err)
}

View File

@ -60,12 +60,9 @@ func Lex(dst io.Writer, src io.Reader, delay time.Duration) error {
buf := make([]byte, 2, 4<<10)
n, err := r.Read(buf)
if n < 2 {
return nil
return io.ErrUnexpectedEOF
}
if err != nil {
if err == io.EOF {
return nil
}
return err
}
if !bytes.Equal(buf, []byte{0xff, 0xd8}) {
@ -76,7 +73,7 @@ func Lex(dst io.Writer, src io.Reader, delay time.Duration) error {
b, err := r.ReadByte()
if err != nil {
if err == io.EOF {
return nil
return io.ErrUnexpectedEOF
}
return err
}

View File

@ -32,10 +32,10 @@ import (
)
// NewMOGFilter returns a pointer to a new NoOp struct for testing purposes only.
func NewMOGFilter(dst io.WriteCloser, area, threshold float64, history int, debug bool) *NoOp {
func NewMOGFilter(dst io.WriteCloser, area, threshold float64, history int, debug bool, hf int) *NoOp {
return &NoOp{dst: dst}
}
func NewKNNFilter(dst io.WriteCloser, area, threshold float64, history, kernelSize int, debug bool) *NoOp {
func NewKNNFilter(dst io.WriteCloser, area, threshold float64, history, kernelSize int, debug bool, hf int) *NoOp {
return &NoOp{dst: dst}
}

View File

@ -40,23 +40,26 @@ import (
// KNNFilter is a filter that provides basic motion detection. KNN is short for
// K-Nearest Neighbours method.
type KNNFilter struct {
dst io.WriteCloser
area float64
bs *gocv.BackgroundSubtractorKNN
knl gocv.Mat
debug bool
windows []*gocv.Window
dst io.WriteCloser // Destination to which motion containing frames go.
area float64 // The minimum area that a contour can be found in.
bs *gocv.BackgroundSubtractorKNN // Uses the KNN algorithm to find the difference between the current and background frame.
knl gocv.Mat // Matrix that is used for calculations.
debug bool // If true then debug windows with the bounding boxes and difference will be shown on the screen.
windows []*gocv.Window // Holds debug windows.
hold [][]byte // Will hold all frames up to hf (so only every hf frame is motion detected).
hf int // The number of frames to be held.
hfCount int // Counter for the hold array.
}
// NewKNNFilter returns a pointer to a new KNNFilter.
func NewKNNFilter(dst io.WriteCloser, area, threshold float64, history, kernelSize int, debug bool) *KNNFilter {
func NewKNNFilter(dst io.WriteCloser, area, threshold float64, history, kernelSize int, debug bool, hf int) *KNNFilter {
bs := gocv.NewBackgroundSubtractorKNNWithParams(history, threshold, false)
k := gocv.GetStructuringElement(gocv.MorphRect, image.Pt(kernelSize, kernelSize))
var windows []*gocv.Window
if debug {
windows = []*gocv.Window{gocv.NewWindow("KNN: Bounding boxes"), gocv.NewWindow("KNN: Motion")}
}
return &KNNFilter{dst, area, &bs, k, debug, windows}
return &KNNFilter{dst, area, &bs, k, debug, windows, make([][]byte, hf-1), hf, 0}
}
// Implements io.Closer.
@ -75,6 +78,13 @@ func (m *KNNFilter) Close() error {
// Write applies the motion filter to the video stream. Only frames with motion
// are written to the destination encoder, frames without are discarded.
func (m *KNNFilter) Write(f []byte) (int, error) {
if m.hfCount < (m.hf - 1) {
m.hold[m.hfCount] = f
m.hfCount++
return len(f), nil
}
m.hfCount = 0
img, err := gocv.IMDecode(f, gocv.IMReadColor)
if err != nil {
return 0, fmt.Errorf("can't decode image: %w", err)
@ -125,9 +135,16 @@ func (m *KNNFilter) Write(f []byte) (int, error) {
// Don't write to destination if there is no motion.
if len(contours) == 0 {
return -1, nil
return len(f), nil
}
// Write to destination.
// Write to destination, past 4 frames then current frame.
for i, h := range m.hold {
_, err := m.dst.Write(h)
m.hold[i] = nil
if err != nil {
return len(f), fmt.Errorf("could not write previous frames: %w", err)
}
}
return m.dst.Write(f)
}

View File

@ -40,23 +40,26 @@ import (
// MOGFilter is a filter that provides basic motion detection. MoG is short for
// Mixture of Gaussians method.
type MOGFilter struct {
dst io.WriteCloser
area float64
bs *gocv.BackgroundSubtractorMOG2
knl gocv.Mat
debug bool
windows []*gocv.Window
dst io.WriteCloser // Destination to which motion containing frames go.
area float64 // The minimum area that a contour can be found in.
bs *gocv.BackgroundSubtractorMOG2 // Uses the MOG algorithm to find the difference between the current and background frame.
knl gocv.Mat // Matrix that is used for calculations.
debug bool // If true then debug windows with the bounding boxes and difference will be shown on the screen.
windows []*gocv.Window // Holds debug windows.
hold [][]byte // Will hold all frames up to hf (so only every hf frame is motion detected).
hf int // The number of frames to be held.
hfCount int // Counter for the hold array.
}
// NewMOGFilter returns a pointer to a new MOGFilter struct.
func NewMOGFilter(dst io.WriteCloser, area, threshold float64, history int, debug bool) *MOGFilter {
func NewMOGFilter(dst io.WriteCloser, area, threshold float64, history int, debug bool, hf int) *MOGFilter {
bs := gocv.NewBackgroundSubtractorMOG2WithParams(history, threshold, false)
k := gocv.GetStructuringElement(gocv.MorphRect, image.Pt(3, 3))
var windows []*gocv.Window
if debug {
windows = []*gocv.Window{gocv.NewWindow("MOG: Bounding boxes"), gocv.NewWindow("MOG: Motion")}
}
return &MOGFilter{dst, area, &bs, k, debug, windows}
return &MOGFilter{dst, area, &bs, k, debug, windows, make([][]byte, hf-1), hf, 0}
}
// Implements io.Closer.
@ -75,6 +78,13 @@ func (m *MOGFilter) Close() error {
// Write applies the motion filter to the video stream. Only frames with motion
// are written to the destination encoder, frames without are discarded.
func (m *MOGFilter) Write(f []byte) (int, error) {
if m.hfCount < (m.hf - 1) {
m.hold[m.hfCount] = f
m.hfCount++
return len(f), nil
}
m.hfCount = 0
img, err := gocv.IMDecode(f, gocv.IMReadColor)
if err != nil {
return 0, fmt.Errorf("image can't be decoded: %w", err)
@ -125,9 +135,16 @@ func (m *MOGFilter) Write(f []byte) (int, error) {
// Don't write to destination if there is no motion.
if len(contours) == 0 {
return 0, nil
return len(f), nil
}
// Write to destination.
// Write to destination, past 4 frames then current frame.
for i, h := range m.hold {
_, err := m.dst.Write(h)
m.hold[i] = nil
if err != nil {
return len(f), fmt.Errorf("could not write previous frames: %w", err)
}
}
return m.dst.Write(f)
}

View File

@ -85,6 +85,7 @@ const (
defaultClipDuration = 0
defaultAudioInputCodec = codecutil.ADPCM
defaultPSITime = 2
defaultMotionInterval = 5
// Ring buffer defaults.
defaultRBMaxElements = 10000
@ -275,6 +276,7 @@ type Config struct {
HorizontalFlip bool // HorizontalFlip flips video horizontally for Raspivid input.
VerticalFlip bool // VerticalFlip flips video vertically for Raspivid input.
Filters []int // Defines the methods of filtering to be used in between lexing and encoding.
MotionInterval int // Sets the number of frames that are held before the filter is used (on the nth frame)
PSITime int // Sets the time between a packet being sent.
// Ring buffer parameters.
@ -328,6 +330,7 @@ var TypeData = map[string]string{
"MOGHistory": "uint",
"MOGMinArea": "float",
"MOGThreshold": "float",
"MotionInterval": "int",
"RBCapacity": "uint",
"RBMaxElements": "uint",
"RBWriteTimeout": "uint",
@ -462,6 +465,10 @@ func (c *Config) Validate() error {
c.Logger.Log(logger.Info, pkg+"PSITime bad or unset, defaulting", "PSITime", defaultPSITime)
c.PSITime = defaultPSITime
}
if c.MotionInterval <= 0 {
c.Logger.Log(logger.Info, pkg+"MotionInterval bad or unset, defaulting", "MotionInterval", defaultMotionInterval)
c.MotionInterval = defaultMotionInterval
}
if c.MinFPS <= 0 {
c.Logger.Log(logger.Info, pkg+"MinFPS bad or unset, defaulting", "MinFPS", defaultMinFPS)

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@ -337,11 +337,11 @@ func (r *Revid) setupPipeline(mtsEnc func(dst io.WriteCloser, rate float64) (io.
case config.FilterNoOp:
r.filters[i] = filter.NewNoOp(dst)
case config.FilterMOG:
r.filters[i] = filter.NewMOGFilter(dst, r.cfg.MOGMinArea, r.cfg.MOGThreshold, int(r.cfg.MOGHistory), r.cfg.ShowWindows)
r.filters[i] = filter.NewMOGFilter(dst, r.cfg.MOGMinArea, r.cfg.MOGThreshold, int(r.cfg.MOGHistory), r.cfg.ShowWindows, r.cfg.MotionInterval)
case config.FilterVariableFPS:
r.filters[i] = filter.NewVariableFPSFilter(dst, r.cfg.MinFPS, filter.NewMOGFilter(dst, r.cfg.MOGMinArea, r.cfg.MOGThreshold, int(r.cfg.MOGHistory), r.cfg.ShowWindows))
r.filters[i] = filter.NewVariableFPSFilter(dst, r.cfg.MinFPS, filter.NewMOGFilter(dst, r.cfg.MOGMinArea, r.cfg.MOGThreshold, int(r.cfg.MOGHistory), r.cfg.ShowWindows, r.cfg.MotionInterval))
case config.FilterKNN:
r.filters[i] = filter.NewKNNFilter(dst, r.cfg.KNNMinArea, r.cfg.KNNThreshold, int(r.cfg.KNNHistory), int(r.cfg.KNNKernel), r.cfg.ShowWindows)
r.filters[i] = filter.NewKNNFilter(dst, r.cfg.KNNMinArea, r.cfg.KNNThreshold, int(r.cfg.KNNHistory), int(r.cfg.KNNKernel), r.cfg.ShowWindows, r.cfg.MotionInterval)
default:
panic("Undefined Filter")
}
@ -671,6 +671,13 @@ func (r *Revid) Update(vars map[string]string) error {
}
r.cfg.Filters[i] = v
}
case "MotionInterval":
v, err := strconv.Atoi(value)
if err != nil || v < 0 {
r.cfg.Logger.Log(logger.Warning, pkg+"invalid MotionInterval var", "value", value)
break
}
r.cfg.MotionInterval = v
case "PSITime":
v, err := strconv.Atoi(value)
if err != nil || v < 0 {
@ -847,7 +854,13 @@ func (r *Revid) Update(vars map[string]string) error {
// processFrom is run as a routine to read from a input data source, lex and
// then send individual access units to revid's encoders.
func (r *Revid) processFrom(read io.Reader, delay time.Duration) {
r.err <- r.lexTo(r.filters[0], read, delay)
r.cfg.Logger.Log(logger.Info, pkg+"finished lexing")
err := r.lexTo(r.filters[0], read, delay)
r.cfg.Logger.Log(logger.Debug, pkg+"finished lexing")
switch err {
case nil: // Do nothing.
case io.EOF: // TODO: handle this depending on loop mode.
default:
r.err <- err
}
r.wg.Done()
}