go-two-tone-detector-wav/main.go

package main

import (
	"flag"
	"fmt"
	"log"
	"math"
	"os"
	"time"

	"github.com/go-audio/audio"
	"github.com/go-audio/wav"
)

// Command-line flags
var (
	wavFile     = flag.String("wav", "", "Path to mono 8kHz WAV file")
	minAms      = flag.Int("minA", 1000, "Minimum Tone A duration (ms)")
	minBms      = flag.Int("minB", 3000, "Minimum Tone B duration (ms)")
	gapMaxMs    = flag.Int("gap", 5000, "Max gap between A and B (ms)")
	winMs       = flag.Int("win", 100, "Window size (ms)")
	hopMs       = flag.Int("hop", 50, "Hop size (ms)")
	ratioThresh = flag.Float64("ratio", 0.65, "Power ratio threshold for tone detection")
	rmsThresh   = flag.Float64("rms", 300.0, "Minimum RMS for valid signal")
)

// Goertzel struct for frequency detection
type goertzel struct {
	N     int
	fs    float64
	k     int
	coeff float64
}

func newGoertzel(targetHz float64, fs float64, N int) *goertzel {
	g := &goertzel{N: N, fs: fs}
	g.k = int(0.5 + (float64(g.N)*targetHz)/fs)
	omega := (2.0 * math.Pi * float64(g.k)) / float64(g.N)
	g.coeff = 2.0 * math.Cos(omega)
	return g
}

func (g *goertzel) Power(x []float64) float64 {
	var s0, s1, s2 float64
	for i := 0; i < g.N; i++ {
		s0 = x[i] + g.coeff*s1 - s2
		s2 = s1
		s1 = s0
	}
	omega := (2.0 * math.Pi * float64(g.k)) / float64(g.N)
	real := s1 - s2*math.Cos(omega)
	imag := s2 * math.Sin(omega)
	return real*real + imag*imag
}

func windowHann(x []float64) {
	n := float64(len(x))
	for i := range x {
		x[i] *= 0.5 * (1.0 - math.Cos(2.0*math.Pi*float64(i)/(n-1.0)))
	}
}

func pcmToFloat(buf []int16, N int) []float64 {
	out := make([]float64, N)
	for i := 0; i < N && i < len(buf); i++ {
		out[i] = float64(buf[i])
	}
	return out
}

func rmsPCM(buf []int16) float64 {
	var s float64
	for _, v := range buf {
		f := float64(v)
		s += f * f
	}
	if len(buf) == 0 {
		return 0
	}
	return math.Sqrt(s / float64(len(buf)))
}

// twoToneDetector for detecting tone sequences
type twoToneDetector struct {
	fs          int
	winN        int
	hopN        int
	ratioThresh float64
	rmsThresh   float64
	minAms      int
	minBms      int
	gapMaxMs    int
	freqs       []float64
	gzBank      []*goertzel
	inA         bool
	aFreq       float64
	aAccumMs    int
	aStart      time.Time
	aEnd        time.Time
	waitingB    bool
	bFreq       float64
	bAccumMs    int
	bStart      time.Time
	bEnd        time.Time
	gapRemainMs int
}

func newTwoToneDetector(fs, winN, hopN int, ratioThresh, rmsThresh float64, minAms, minBms, gapMaxMs int) *twoToneDetector {
	freqs := make([]float64, 0)
	for f := 300.0; f <= 3000.0; f += 10.0 {
		freqs = append(freqs, f)
	}
	gzBank := make([]*goertzel, len(freqs))
	for i, f := range freqs {
		gzBank[i] = newGoertzel(f, float64(fs), winN)
	}
	return &twoToneDetector{
		fs:          fs,
		winN:        winN,
		hopN:        hopN,
		ratioThresh: ratioThresh,
		rmsThresh:   rmsThresh,
		minAms:      minAms,
		minBms:      minBms,
		gapMaxMs:    gapMaxMs,
		freqs:       freqs,
		gzBank:      gzBank,
	}
}

func (d *twoToneDetector) stepWindow(pcms []int16, t0 time.Time) (event string, aFreq, aDur, bFreq, bDur float64, timestamp time.Time) {
	xi := pcmToFloat(pcms, d.winN)
	windowHann(xi)

	var total float64
	for _, v := range xi {
		total += v * v
	}

	r := rmsPCM(pcms)
	hopDur := time.Millisecond * time.Duration(int(float64(d.hopN)*1000.0/float64(d.fs)))
	now := t0

	if r < d.rmsThresh {
		d.reset()
		return "", 0, 0, 0, 0, time.Time{}
	}

	// Find frequency with highest power
	bestIdx := -1
	bestPow := 0.0
	for i, gz := range d.gzBank {
		p := gz.Power(xi)
		if p > bestPow {
			bestPow = p
			bestIdx = i
		}
	}
	ratio := bestPow / (total + 1e-12)
	if ratio < d.ratioThresh {
		d.reset()
		return "", 0, 0, 0, 0, time.Time{}
	}
	freq := d.freqs[bestIdx]

	if !d.inA && !d.waitingB {
		// Looking for Tone A
		d.inA = true
		d.aFreq = freq
		d.aStart = now
	} else if d.inA && !d.waitingB {
		// Confirming Tone A
		if math.Abs(freq-d.aFreq) <= 10.0 {
			d.aAccumMs += int(hopDur.Milliseconds())
			d.aEnd = now.Add(hopDur)
			if d.aAccumMs >= d.minAms {
				d.inA = false
				d.waitingB = true
				d.gapRemainMs = d.gapMaxMs
			}
		} else {
			d.reset()
		}
	} else if d.waitingB {
		d.gapRemainMs -= int(hopDur.Milliseconds())
		if d.gapRemainMs <= 0 {
			d.reset()
		} else if math.Abs(freq-d.aFreq) > 10.0 {
			// Check for Tone B
			if d.bAccumMs == 0 {
				d.bFreq = freq
				d.bStart = now
			} else if math.Abs(freq-d.bFreq) > 10.0 {
				d.bFreq = freq
				d.bAccumMs = 0
				d.bStart = now
			}
			d.bAccumMs += int(hopDur.Milliseconds())
			d.bEnd = now.Add(hopDur)
			if d.bAccumMs >= d.minBms {
				event = "TWO_TONE_DETECTED"
				aDurMs := float64(d.aEnd.Sub(d.aStart).Milliseconds())
				bDurMs := float64(d.bEnd.Sub(d.bStart).Milliseconds())
				return event, d.aFreq, aDurMs, d.bFreq, bDurMs, now
			}
		}
	}
	return "", 0, 0, 0, 0, time.Time{}
}

func (d *twoToneDetector) reset() {
	d.inA = false
	d.aFreq = 0
	d.aAccumMs = 0
	d.aStart = time.Time{}
	d.aEnd = time.Time{}
	d.waitingB = false
	d.bFreq = 0
	d.bAccumMs = 0
	d.bStart = time.Time{}
	d.bEnd = time.Time{}
	d.gapRemainMs = 0
}

func main() {
	flag.Parse()
	if *wavFile == "" {
		log.Fatal("WAV file path is required (use -wav flag)")
	}

	file, err := os.Open(*wavFile)
	if err != nil {
		log.Fatalf("Failed to open WAV file: %v", err)
	}
	defer file.Close()

	decoder := wav.NewDecoder(file)
	if !decoder.IsValidFile() {
		log.Fatal("Invalid WAV file")
	}
	if decoder.Format().SampleRate != 8000 || decoder.Format().NumChannels != 1 {
		log.Fatalf("WAV file must be mono 8kHz, got %d Hz, %d channels",
			decoder.Format().SampleRate, decoder.Format().NumChannels)
	}

	const fs = 8000
	winN := int(float64(fs) * float64(*winMs) / 1000.0)
	hopN := int(float64(fs) * float64(*hopMs) / 1000.0)
	if winN <= 0 || hopN <= 0 || hopN > winN {
		log.Fatalf("Invalid window/hop: winN=%d, hopN=%d", winN, hopN)
	}

	det := newTwoToneDetector(fs, winN, hopN, *ratioThresh, *rmsThresh, *minAms, *minBms, *gapMaxMs)

	buf := &audio.IntBuffer{
		Format:         &audio.Format{SampleRate: fs, NumChannels: 1},
		Data:           make([]int, 8192),
		SourceBitDepth: 16,
	}
	sampleCount := 0
	startTime := time.Now()

	log.Println("Processing WAV file...")
	for {
		n, err := decoder.PCMBuffer(buf)
		if err != nil || n == 0 || len(buf.Data) == 0 {
			log.Printf("Finished processing %d samples (%.2f seconds)", sampleCount, float64(sampleCount)/float64(fs))
			break
		}

		pcm := make([]int16, n)
		for i, v := range buf.Data[:n] {
			pcm[i] = int16(v)
		}
		sampleCount += n

		for offset := 0; offset <= len(pcm)-winN; offset += hopN {
			win := pcm[offset:min(offset+winN, len(pcm))]
			t := startTime.Add(time.Duration(sampleCount-len(pcm)+offset) * time.Second / time.Duration(fs))
			event, aFreq, aDur, bFreq, bDur, timestamp := det.stepWindow(win, t)
			if event != "" {
				fmt.Printf("Detected two-tone sequence at %s:\n", timestamp.Format(time.RFC3339))
				fmt.Printf("  Tone A: %.1f Hz, duration %.0f ms\n", aFreq, aDur)
				fmt.Printf("  Tone B: %.1f Hz, duration %.0f ms\n", bFreq, bDur)
				det.reset()
			}
		}
	}
}

func min(a, b int) int {
	if a < b {
		return a
	}
	return b
}