package offline import ( "context" "encoding/binary" "fmt" "path/filepath" "time" "github.com/jan/fm-rds-tx/internal/audio" cfgpkg "github.com/jan/fm-rds-tx/internal/config" "github.com/jan/fm-rds-tx/internal/dsp" "github.com/jan/fm-rds-tx/internal/mpx" "github.com/jan/fm-rds-tx/internal/output" "github.com/jan/fm-rds-tx/internal/rds" "github.com/jan/fm-rds-tx/internal/stereo" ) type frameSource interface { NextFrame() audio.Frame } type SourceInfo struct { Kind string SampleRate float64 Detail string } type Generator struct { cfg cfgpkg.Config } func NewGenerator(cfg cfgpkg.Config) *Generator { return &Generator{cfg: cfg} } func (g *Generator) sourceFor(sampleRate float64) (frameSource, SourceInfo) { if g.cfg.Audio.InputPath != "" { if src, err := audio.LoadWAVSource(g.cfg.Audio.InputPath); err == nil { return audio.NewResampledSource(src, sampleRate), SourceInfo{Kind: "wav", SampleRate: float64(src.SampleRate), Detail: g.cfg.Audio.InputPath} } return audio.NewConfiguredToneSource(sampleRate, g.cfg.Audio.ToneLeftHz, g.cfg.Audio.ToneRightHz, g.cfg.Audio.ToneAmplitude), SourceInfo{Kind: "tone-fallback", SampleRate: sampleRate, Detail: g.cfg.Audio.InputPath} } return audio.NewConfiguredToneSource(sampleRate, g.cfg.Audio.ToneLeftHz, g.cfg.Audio.ToneRightHz, g.cfg.Audio.ToneAmplitude), SourceInfo{Kind: "tones", SampleRate: sampleRate, Detail: "generated"} } func (g *Generator) GenerateFrame(duration time.Duration) *output.CompositeFrame { sampleRate := float64(g.cfg.FM.CompositeRateHz) if sampleRate <= 0 { sampleRate = 228000 } samples := int(duration.Seconds() * sampleRate) if samples <= 0 { samples = int(sampleRate / 10) } frame := &output.CompositeFrame{ Samples: make([]output.IQSample, samples), SampleRateHz: sampleRate, Timestamp: time.Now().UTC(), Sequence: 1, } // --- DSP chain --- // Pre-emphasis filters for L and R channels var preL, preR *dsp.PreEmphasis if g.cfg.FM.PreEmphasisUS > 0 { preL = dsp.NewPreEmphasis(g.cfg.FM.PreEmphasisUS, sampleRate) preR = dsp.NewPreEmphasis(g.cfg.FM.PreEmphasisUS, sampleRate) } // Stereo encoder (includes stateful 19kHz pilot and 38kHz subcarrier) stereoEncoder := stereo.NewStereoEncoder(sampleRate) // MPX combiner combiner := mpx.NewDefaultCombiner() combiner.PilotGain = g.cfg.FM.PilotLevel / 0.1 // normalize: pilot generator has 0.1 level built-in combiner.RDSGain = g.cfg.FM.RDSInjection / 0.05 // normalize: RDS encoder has 0.05 amplitude built-in // RDS encoder (standards-grade group framing + CRC + diff encoding) rdsEnc, _ := rds.NewEncoder(rds.RDSConfig{ PI: 0x1234, PS: g.cfg.RDS.PS, RT: g.cfg.RDS.RadioText, PTY: uint8(g.cfg.RDS.PTY), SampleRate: sampleRate, }) // MPX limiter var limiter *dsp.MPXLimiter ceiling := g.cfg.FM.LimiterCeiling if ceiling <= 0 { ceiling = 1.0 } if g.cfg.FM.LimiterEnabled { limiter = dsp.NewMPXLimiter(ceiling, 0.1, 50, sampleRate) } // FM modulator for IQ output var fmMod *dsp.FMModulator if g.cfg.FM.FMModulationEnabled { fmMod = dsp.NewFMModulator(sampleRate) if g.cfg.FM.MaxDeviationHz > 0 { fmMod.MaxDeviation = g.cfg.FM.MaxDeviationHz } } // Audio source source, _ := g.sourceFor(sampleRate) // --- Sample loop --- for i := 0; i < samples; i++ { in := source.NextFrame() // Apply gain inL := float64(in.L) * g.cfg.Audio.Gain inR := float64(in.R) * g.cfg.Audio.Gain // Pre-emphasis if preL != nil { inL = preL.Process(inL) inR = preR.Process(inR) } // Stereo encode (produces mono, DSB-SC stereo, pilot) preFrame := audio.NewFrame(audio.Sample(inL), audio.Sample(inR)) comps := stereoEncoder.Encode(preFrame) // RDS rdsValue := 0.0 if g.cfg.RDS.Enabled { rdsBuf := rdsEnc.Generate(1) rdsValue = rdsBuf[0] } // Combine MPX composite := combiner.Combine(comps.Mono, comps.Stereo, comps.Pilot, rdsValue) // Apply output drive composite *= g.cfg.FM.OutputDrive // Limiter if limiter != nil { composite = limiter.Process(composite) } // Hard clip safety net composite = dsp.HardClip(composite, ceiling) // Output: FM modulated IQ or raw composite if fmMod != nil { iq_i, iq_q := fmMod.Modulate(composite) frame.Samples[i] = output.IQSample{I: float32(iq_i), Q: float32(iq_q)} } else { frame.Samples[i] = output.IQSample{I: float32(composite), Q: 0} } } return frame } func (g *Generator) WriteFile(path string, duration time.Duration) error { if path == "" { path = g.cfg.Backend.OutputPath } if path == "" { path = filepath.Join("build", "offline", "composite.iqf32") } backend, err := output.NewFileBackend(path, binary.LittleEndian, output.BackendInfo{ Name: "offline-file", Description: "offline composite file backend", }) if err != nil { return err } defer backend.Close(context.Background()) if err := backend.Configure(context.Background(), output.BackendConfig{ SampleRateHz: float64(g.cfg.FM.CompositeRateHz), Channels: 2, IQLevel: float32(g.cfg.FM.OutputDrive), }); err != nil { return err } frame := g.GenerateFrame(duration) if _, err := backend.Write(context.Background(), frame); err != nil { return err } if err := backend.Flush(context.Background()); err != nil { return err } return nil } func (g *Generator) Summary(duration time.Duration) string { sampleRate := float64(g.cfg.FM.CompositeRateHz) if sampleRate <= 0 { sampleRate = 228000 } _, info := g.sourceFor(sampleRate) preemph := "off" if g.cfg.FM.PreEmphasisUS > 0 { preemph = fmt.Sprintf("%.0fµs", g.cfg.FM.PreEmphasisUS) } modMode := "composite" if g.cfg.FM.FMModulationEnabled { modMode = fmt.Sprintf("FM-IQ(±%.0fHz)", g.cfg.FM.MaxDeviationHz) } return fmt.Sprintf("offline frame: freq=%.1fMHz rate=%d duration=%s drive=%.2f stereo=%t rds=%t preemph=%s limiter=%t output=%s source=%s detail=%s", g.cfg.FM.FrequencyMHz, g.cfg.FM.CompositeRateHz, duration.String(), g.cfg.FM.OutputDrive, g.cfg.FM.StereoEnabled, g.cfg.RDS.Enabled, preemph, g.cfg.FM.LimiterEnabled, modMode, info.Kind, info.Detail) }