//go:build !nocv // +build !nocv /* DESCRIPTION Provides the methods for the turbidity probe using GoCV. Turbidity probe will collect the most recent frames in a buffer and write the latest sharpness and contrast scores to the probe. AUTHORS Russell Stanley LICENSE Copyright (C) 2021-2022 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 Free Software Foundation, either version 3 of the License, or (at your option) any later version. It is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License in gpl.txt. If not, see http://www.gnu.org/licenses. */ package main import ( "bytes" "os" "time" "gocv.io/x/gocv" "gonum.org/v1/gonum/stat" "bitbucket.org/ausocean/av/codec/h264" "bitbucket.org/ausocean/av/turbidity" "bitbucket.org/ausocean/utils/logger" ) // Misc constants. const ( maxImages = 1 // Max number of images read when evaluating turbidity. bufferLimit = 20000 // 20KB ) // Turbidity sensor constants. const ( k1, k2 = 4, 4 // Block size, must be divisible by the size template with no remainder. filterSize = 3 // Sobel filter size. scale = 1.0 // Amount of scale applied to sobel filter values. alpha = 1.0 // Paramater for contrast equation. ) // turbidityProbe will hold the latest video data and calculate the sharpness and contrast scores. // These scores will be sent to netreceiver based on the given delay. type turbidityProbe struct { sharpness, contrast float64 delay time.Duration ticker time.Ticker ts *turbidity.TurbiditySensor log logger.Logger buffer *bytes.Buffer } // NewTurbidityProbe returns a new turbidity probe. func NewTurbidityProbe(log logger.Logger, delay time.Duration) (*turbidityProbe, error) { tp := new(turbidityProbe) tp.log = log tp.delay = delay tp.ticker = *time.NewTicker(delay) tp.buffer = bytes.NewBuffer(*new([]byte)) // Create the turbidity sensor. standard := gocv.IMRead("../../turbidity/images/default.jpg", gocv.IMReadGrayScale) template := gocv.IMRead("../../turbidity/images/template.jpg", gocv.IMReadGrayScale) ts, err := turbidity.NewTurbiditySensor(template, standard, k1, k2, filterSize, scale, alpha, log) if err != nil { log.Error("failed create turbidity sensor", "error", err.Error()) } tp.ts = ts return tp, nil } // Write, reads input h264 frames in the form of a byte stream and writes the the sharpness and contrast // scores of a video to the the turbidity probe. func (tp *turbidityProbe) Write(p []byte) (int, error) { out := len(p) if tp.buffer.Len() == 0 { // The first entry in the buffer must be a keyframe to speed up decoding. video, err := h264.Trim(p) if err != nil { tp.log.Log(logger.Debug, "no key frame detected", "error", err.Error()) return 0, nil } n, err := tp.buffer.Write(video) if err != nil { tp.log.Log(logger.Error, "could not write trimmed video to buffer", "error", err.Error()) tp.buffer.Reset() return 0, nil } tp.log.Log(logger.Debug, "video trimmed, write keyframe complete", "size(bytes)", n) } else if tp.buffer.Len() < bufferLimit { // Buffer is limited to speed up decoding. n, err := tp.buffer.Write(p) if err != nil { tp.log.Log(logger.Error, "could not write to buffer, reseting", "error", err.Error()) tp.buffer.Reset() return 0, nil } tp.log.Log(logger.Debug, "write to video buffer complete", "size(bytes)", n) } else { out = 0 } select { case <-tp.ticker.C: tp.log.Log(logger.Debug, "beginning turbidity calculation") startTime := time.Now() tp.turbidityCalculation() tp.log.Log(logger.Debug, "finished turbidity calculation", "total duration (sec)", time.Since(startTime).Seconds()) default: } return out, nil } func (tp *turbidityProbe) Close() error { return nil } func (tp *turbidityProbe) turbidityCalculation() { var imgs []gocv.Mat img := gocv.NewMat() // Write byte array to a temp file. file, err := os.CreateTemp("temp", "video*.h264") if err != nil { tp.log.Error("failed to create temp file", "error", err.Error()) return } tp.log.Log(logger.Debug, "writing to file", "buffer size(bytes)", tp.buffer.Len()) _, err = file.Write(tp.buffer.Bytes()) if err != nil { tp.log.Error("failed to write to temporary file", "error", err.Error()) return } tp.log.Log(logger.Debug, "write to file success", "buffer size(bytes)", tp.buffer.Len()) tp.buffer.Reset() // Open the video file. startTime := time.Now() vc, err := gocv.VideoCaptureFile(file.Name()) if err != nil { tp.log.Error("failed to open video file", "error", err.Error()) return } tp.log.Log(logger.Debug, "video capture open", "total duration (sec)", time.Since(startTime).Seconds()) // Store each frame untill max. startTime = time.Now() for vc.Read(&img) && len(imgs) < maxImages { imgs = append(imgs, img.Clone()) } if len(imgs) <= 0 { tp.log.Log(logger.Warning, "no frames found") return } tp.log.Log(logger.Debug, "read time", "total duration (sec)", time.Since(startTime).Seconds()) // Process video data to get saturation and contrast scores. res, err := tp.ts.Evaluate(imgs) if err != nil { tp.log.Error("evaluate failed", "error", err.Error()) } else { tp.contrast = stat.Mean(res.Contrast, nil) tp.sharpness = stat.Mean(res.Sharpness, nil) } err = os.Remove(file.Name()) if err != nil { tp.log.Error("could not remove file", "error", err.Error()) } err = vc.Close() if err != nil { tp.log.Error("could not close video capture", "error", err.Error()) } }