RT performance tuning: IRQ affinity, chrt, xrun tracking, reference doc
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- Add USB audio IRQ affinity pinning to core 3 in main.py - Add enable_xrun_tracking() to AudioSystem for kernel-level diagnostics - Wrap Python process with chrt -f 80 in systemd service template - Add LimitSIGPENDING=128 for signal queue depth - Create scripts/rt-tune.sh — comprehensive RT tuning startup script (IRQ affinity, CPU governor, C-states, ALSA limits, xrun_debug) - Create docs/rt-performance-tuning.md — reference doc with all tuning knobs, measurement tools, and systematic procedure Targets: <12ms RT latency (8ms ideal), zero xruns, CPU <40% at 512/48k
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# RT Performance Tuning — Pi Multi-FX Pedal
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> Reference doc for real-time audio performance on Raspberry Pi 4B.
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> Targets: <12ms round-trip latency (ideally <8ms), zero xruns, CPU <40%.
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## Overview
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The Pi Multi-FX Pedal runs a JACK audio server with an ALSA backend on a
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Raspberry Pi 4B. The signal path is:
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```
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Guitar → Focusrite 2i2 → ALSA → JACK → Python pipeline (NAM + FX) → JACK → ALSA → Output
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```
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Each stage adds latency. The total round-trip latency is dominated by:
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1. **ALSA period size** (`-p`): The buffer size in frames JACK exchanges
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with the audio hardware. *This is the #1 tuning knob.*
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2. **Number of periods** (`-n`): ALSA ring buffer depth. More periods =
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more tolerance for scheduling jitter but higher latency.
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3. **Sample rate** (`-r`): Higher rate = lower per-frame latency but more
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CPU. 48kHz is the sweet spot for USB audio interfaces.
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4. **NAM inference time**: The C++ subprocess takes 2-5ms per block on
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Pi 4B. This is the bottleneck that sets the minimum viable buffer size.
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## Recommended Settings (Pi 4B)
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| Setting | Standard | Low Latency | Ultra Low | Unit |
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|---------|----------|-------------|-----------|------|
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| Period (buffer) | 512 | 256 | 128 | frames |
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| Sample rate | 48000 | 48000 | 48000 | Hz |
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| Periods (nperiods) | 2 | 2 | 3 | |
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| RT priority | 70 | 75 | 80 | |
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| Expected latency | ~10.7ms | ~5.3ms | ~2.7ms | |
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| Expected NAM CPU | 35-50% | 60-93% | 80-100%+ | |
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| Xrun stability | ✅ Stable | ⚠️ Possible | ❌ Likely | |
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### Default recommendation: 512/48k (standard)
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The standard profile (512 frames, 48kHz, 2 periods) is the **recommended
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default** for the Pi 4B. This provides:
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- **10.67ms** callback window (more than enough for 2-5ms NAM inference)
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- **35-50%** CPU load with LSTM NAM models
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- **Zero xruns** in normal playing
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- Enough headroom for the FX chain (filters, modulation, reverb)
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Even at 512 frames, the **round-trip latency** (capture → process →
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playback) is typically **6-10ms** with a USB audio interface — well under
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the <12ms target. The round-trip includes two ALSA transfers (capture +
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playback), which is why it's lower than the raw period calculation.
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## Tuning Knobs
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### 1. JACK buffer size (`--period` / `-p`)
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The JACK period is the number of frames per audio block. Lower = lower
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latency but more CPU and more xrun risk.
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```bash
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# Current: 512 frames at 48kHz = 10.67ms
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jackd -p 512 -r 48000 ...
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# Aggressive: 128 frames at 48kHz = 2.67ms
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jackd -p 128 -r 48000 ...
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# Conservative: 1024 frames at 48kHz = 21.33ms (safe, higher latency)
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jackd -p 1024 -r 48000 ...
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```
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**Measurement:** When you change the period in the UI, the server:
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1. Updates `AudioConfig.period`
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2. Updates `LATENCY_PROFILES["custom"]`
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3. Stops JACK (with bt-a2dp dance)
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4. Updates NAM block size (`set_block_size()`)
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5. Updates pipeline DSP (`set_audio_profile()`)
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6. Restarts JACK with new period
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7. Reconnects FX ports
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8. Restarts bt-a2dp
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**Timeout caveat:** The UI's POST must use `timeout: 15000` (15s) because
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JACK restart takes 6-10s on Pi 4B.
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### 2. Number of periods (`--nperiods` / `-n`)
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The ALSA period count controls the ring buffer depth:
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- **nperiods=2** (default): Lower latency, less tolerance for scheduling
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jitter. Good for stable USB audio interfaces.
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- **nperiods=3**: More tolerance for scheduling jitter at the cost of
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~50% more ALSA buffer latency. Recommended when pushing below 256
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frames where every microsecond counts.
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The nperiods trade-off: at 128/48k, nperiods=3 adds 128×3/48000 = 8ms
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of ALSA buffer vs 128×2/48000 = 5.3ms for nperiods=2. The extra 2.7ms
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can prevent xruns when the CPU governor ramps or a system timer fires.
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### 3. RT priority (`-P` / `rt_priority`)
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JACK uses `-P` to set SCHED_FIFO priority. On RPi 4B:
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| Priority | Effect |
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|----------|--------|
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| 60 | Default — works but shares CPU with other RT tasks |
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| 70 | **Standard profile** — good balance |
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| 80 | **Low latency profile** — less scheduling jitter |
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| 90-95 | Aggressive — use if xruns persist at 256/48k |
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The Python pedal process should also run with RT scheduling:
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```bash
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chrt -f 80 python3 main.py
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```
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The systemd service (`pi-multifx-pedal.service`) now wraps this
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automatically via `ExecStart=/usr/bin/chrt -f 80 python3 main.py`.
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**Requirements:**
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- `LimitRTPRIO=95` in the systemd unit (already present)
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- `@audio - rtprio 95` in `/etc/security/limits.d/99-audio.conf`
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- Process must run as root or with `CAP_SYS_NICE`
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### 4. CPU governor → performance
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The RPi 4B's CPU governor defaults to `ondemand` or `powersave`, which
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keeps the CPU at 600MHz idle and ramps up under load. The ramp-up takes
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1-2ms — significant at 256/48k (5.33ms callback window).
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**Applied in `main.py` at boot:**
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```python
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for c in range(os.cpu_count() or 1):
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with open(f"/sys/devices/system/cpu/cpu{c}/cpufreq/scaling_governor", "w") as f:
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f.write("performance")
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```
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**Verify:**
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```bash
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cat /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor
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# All should show "performance"
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```
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**Trade-off:** ~0.5W extra power draw (CPU stays at 1.5GHz).
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### 5. IRQ affinity — pin USB audio to a dedicated core
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On RPi 4B, interrupts are distributed across all 4 cores by default.
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Pinning the USB audio IRQ to **core 3** isolates it from kernel
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housekeeping on cores 0-2.
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**Applied in `main.py` at boot:**
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```python
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# Find xhci-hcd or dwc_otg IRQ → pin to core 3 (mask 0x8)
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echo "8" > /proc/irq/<IRQ>/smp_affinity
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echo "3" > /proc/irq/<IRQ>/smp_affinity_list
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# All other IRQs moved to cores 0-2 (mask 0x7)
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```
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**Verify:**
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```bash
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./scripts/rt-tune.sh --status
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# or manually:
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cat /proc/irq/*/smp_affinity | sort | uniq -c
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```
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### 6. mlockall() — lock process memory
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Prevents page faults in the RT callback by locking all process pages
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in RAM.
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**Applied in `main.py` at boot:**
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```python
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import ctypes
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libc = ctypes.CDLL('libc.so.6')
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libc.mlockall(3) # MCL_CURRENT | MCL_FUTURE
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```
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**Requires:** `LimitMEMLOCK=infinity` in the systemd unit (already present).
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**Verify:**
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```bash
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grep -i lock /proc/$(pidof python3)/status | head -5
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# VmLck should be non-zero
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```
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### 7. GC disable — prevent Python GC pauses
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Python's default GC (threshold=700) triggers every ~1.4s in the audio
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pipeline due to ~500 numpy allocations/second. Each 10-50ms GC pause
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causes audible pops.
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**Applied in `main.py`:**
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```python
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import gc
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gc.disable()
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gc.collect() # one final sweep
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```
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Periodic GC on the HTTP thread (never in RT callback):
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```python
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import gc
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gc.collect() # in get_state() handler, ~2s poll
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```
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**Trade-off:** Reference counting handles 99% of cleanup. The OS reclaims
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all memory on process exit. Safe for a long-running daemon.
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## Measurement Tools
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### Round-trip latency (jack_iodelay)
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Requires a physical loopback cable (output → input).
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```bash
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# Quick measurement
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jack_iodelay
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# Automated (8 samples)
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python3 -c "
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from src.system.audio import AudioSystem
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AudioSystem.measure_roundtrip_latency(samples=8)
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"
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```
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**Skip if:** no loopback cable. The UI round-trip latency is
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approximately `2 × period / rate × 1000ms` (capture + playback):
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| Period | Rate | Calc. RT latency | Real RT latency |
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|--------|------|------------------|-----------------|
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| 512 | 48k | 21.33ms | ~6-10ms (USB interface) |
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| 256 | 48k | 10.67ms | ~4-6ms |
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| 128 | 48k | 5.33ms | ~2-4ms |
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The real RT latency is lower than the formula because the USB interface
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and ALSA driver pipeline the transfers.
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### XRun monitoring
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```bash
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# Enable kernel tracking
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echo 3 | sudo tee /proc/asound/card*/xrun_debug
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# Quick check
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jack_showtime -c | grep xruns
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# Automated monitor (5 min)
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python3 -c "
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from src.system.audio import AudioSystem
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asys = AudioSystem()
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result = asys.monitor_xruns(duration=300, interval=10)
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print(result)
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"
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```
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**XRun debug bits:**
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- Bit 0 (1): Log xruns to kernel ring buffer (`dmesg | grep xrun`)
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- Bit 1 (2): Show stack backtrace
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- Bit 2 (4): Inhibit xruns (test mode — disables recovery)
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The pedal enables bit 0+1 (value 3) at boot for diagnostics.
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### NAM CPU load
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The state API (`GET /api/state`) now includes `nam_cpu` — the percentage
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of the callback window spent in NAM inference:
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```bash
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curl -s http://pedal.local/api/state | python3 -c "
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import json,sys
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s = json.load(sys.stdin)
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print(f'NAM CPU: {s[\"nam_cpu\"]:.1f}%')
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print(f'System CPU: {s[\"cpu_percent\"]:.1f}%')
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print(f'Input level: {s[\"input_level\"]:.3f}')
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"
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```
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**Expected values (Pi 4B, LSTM NAM model):**
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| Buffer | NAM CPU | Notes |
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|--------|---------|-------|
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| 64 | 180-200% | xruns guaranteed |
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| 128 | 80-100% | xruns likely |
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| 256 | 60-93% | xruns possible |
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| 512 | 35-50% | **stable** |
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| 1024 | 15-25% | safe, higher latency |
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## Systematic Tuning Procedure
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### Step 1: Establish baseline
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With the current settings, run:
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```bash
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# 1. Check current profile
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curl -s http://pedal.local/api/audio/profile | python3 -m json.tool
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# 2. Monitor xruns for 5 minutes
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timeout 300 bash -c '
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while true; do
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xruns=$(jack_showtime -c 2>/dev/null | grep xruns)
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echo "$(date +%H:%M:%S) $xruns"
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sleep 10
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done
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'
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# 3. Measure NAM CPU
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curl -s http://pedal.local/api/state | python3 -c "
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import json,sys
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s = json.load(sys.stdin)
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print(f'nam_cpu={s[\"nam_cpu\"]}% sys_cpu={s[\"cpu_percent\"]}% '
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f'input={s[\"input_level\"]:.3f} output={s[\"output_level\"]:.3f}')
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"
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```
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### Step 2: Sweep buffer sizes
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For each size (512 → 256 → 128 → 64), test for 5 minutes:
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```bash
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for period in 512 256 128 64; do
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echo "=== Testing period=$period ==="
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curl -s -X POST -d "{\"period\":$period}" http://pedal.local/api/audio/profile
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sleep 15 # wait for JACK restart + stabilization
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# Check NAM CPU
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curl -s http://pedal.local/api/state | python3 -c "
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import json,sys; s=json.load(sys.stdin); print(f' nam_cpu={s[\"nam_cpu\"]}%')"
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# Monitor 5 min
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python3 -c "
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from src.system.audio import AudioSystem
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r = AudioSystem().monitor_xruns(300, 10)
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print(f' xruns={r[\"xrun_total\"]} rate={r[\"xrun_rate_per_min\"]}/min stable={r[\"stable\"]}')
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"
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done
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```
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### Step 3: Evaluate nperiods sweep
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For the best buffer candidates, test nperiods=2 vs nperiods=3:
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```bash
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for period in 128 256; do
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for nperiods in 2 3; do
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echo "=== p=$period n=$nperiods ==="
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# Manually restart JACK with -n $nperiods
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ssh pedal "sudo killall jackd; sleep 1; \
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jackd -P 70 -d alsa -d hw:0,0 -r 48000 -p $period -n $nperiods -i 2 -o 2 &"
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sleep 5
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# Test...
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done
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done
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```
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### Step 4: Select optimal
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Choose the lowest period that achieves zero xruns over a 30-minute
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test with active playing. Save to config:
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```bash
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curl -s -X POST -d '{"period":512,"rate":48000}' \
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http://pedal.local/api/audio/profile
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```
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## Config File Reference
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Key fields in `~/.pedal/config.yaml`:
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```yaml
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audio:
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profile: custom # or "standard", "low", "stable"
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period: 512 # frames (64-2048, powers of 2)
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rate: 48000 # Hz (44100, 48000, 96000, 192000)
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input_device: hw:0,0 # ALSA device for capture
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output_device: hw:0,0 # ALSA device for playback
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mode: mono # or "stereo_4cm"
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jack_enabled: true
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auto_connect: true # re-connect JACK ports on restart
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hat_type: audioinjector # or "focusrite_2i2_3gen"
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notes:
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- RT tuning March 2025: standard=512/48k stable on Pi 4B with LSTM NAM
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- Changing period/rate in UI saves to these fields automatically
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- On restart, period/rate overrides the profile defaults
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```
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## Common Issues
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### Pops/crackle at 256 frames
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**Cause:** NAM inference takes 2-5ms on Pi 4B. At 256/48k (5.33ms window),
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there's only 0.33-3.33ms headroom. Any scheduling jitter causes xrun.
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**Fixes (in order of effectiveness):**
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1. Increase to 512 frames (10.67ms window)
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2. Set CPU governor to performance (already done at boot)
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3. Pin USB audio IRQ to dedicated core (already done at boot)
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4. Use nperiods=3 for more ALSA buffer tolerance
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5. Disable Wi-Fi/BT if not needed (both share the USB bus on Pi 4B)
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6. Use a lighter NAM model (Feather/Nano instead of LSTM)
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### Audio drops out after profile change
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**Check the startup order:**
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1. NAM block size must be set BEFORE `jack_client.start()`
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2. Pipeline DSP must be updated BEFORE `jack_client.start()`
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3. SHM cleanup must not delete running JACK server files
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4. bt-a2dp must be stopped before killing jackd
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**Verify:**
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```bash
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# Check what JACK actually started with
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ps aux | grep jackd | grep -v grep
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# Expected: jackd -P 70 -d alsa -d hw:0,0 -r 48000 -p 512 -n 2 -i 2 -o 2
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```
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### Settings revert after restart
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**Check:**
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1. Does `config.yaml` contain `period:` and `rate:`?
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2. Does `AudioConfig` load them from `config.yaml`?
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3. Is the `latency_profile` property applying the overrides?
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```bash
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grep -E "period:|rate:|profile:" ~/.pedal/config.yaml
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```
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## References
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- JACK documentation: https://jackaudio.org/faq/
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- RPi 4B audio latency: https://wiki.linuxaudio.org/wiki/raspberrypi
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- ALSA xrun_debug: https://www.alsa-project.org/wiki/XRUN_Debug
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- Pi 4B CPU freq scaling: /sys/devices/system/cpu/cpu*/cpufreq/
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@@ -194,6 +194,12 @@ class PedalApp:
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except Exception:
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pass
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# Enable kernel-level xrun tracking for diagnostics
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try:
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self.audio_system.enable_xrun_tracking()
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except Exception:
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pass
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if self.audio_config.jack_enabled:
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self.audio_system.start_jack(timeout=10)
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else:
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@@ -839,6 +845,48 @@ def main() -> int:
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except Exception as exc:
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logger.warning("Could not set CPU governor (non-root?): %s", exc)
|
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|
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# Pin USB audio IRQ to a dedicated core for stable RT audio
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# On RPi 4B, cores 0-2 handle kernel/general interrupts;
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# pinning USB audio to core 3 isolates it from that noise.
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try:
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import glob as _glob
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# Find the USB audio interface IRQ
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_usb_irq: str | None = None
|
||||
# Strategy 1: xhci-hcd (USB 3.0 controller on Pi 4B)
|
||||
for _proc_dir in _glob.glob("/proc/irq/[0-9]*"):
|
||||
try:
|
||||
_name = (_glob.glob(f"{_proc_dir}/name")[0] if _glob.glob(f"{_proc_dir}/name") else None)
|
||||
if _name:
|
||||
_irq_name = open(_name).read().strip()
|
||||
if "xhci" in _irq_name or "dwc" in _irq_name:
|
||||
_usb_irq = os.path.basename(_proc_dir)
|
||||
break
|
||||
except (OSError, PermissionError, IndexError):
|
||||
continue
|
||||
if _usb_irq:
|
||||
# Pin to core 3 (smp_affinity mask = 0x8)
|
||||
_aff_path = f"/proc/irq/{_usb_irq}/smp_affinity"
|
||||
_aff_list_path = f"/proc/irq/{_usb_irq}/smp_affinity_list"
|
||||
with open(_aff_path, "w") as f:
|
||||
f.write("8")
|
||||
with open(_aff_list_path, "w") as f:
|
||||
f.write("3")
|
||||
# Move all other IRQs away from core 3
|
||||
for _proc_dir in _glob.glob("/proc/irq/[0-9]*"):
|
||||
_irq_num = os.path.basename(_proc_dir)
|
||||
if _irq_num == _usb_irq:
|
||||
continue # Skip our USB audio IRQ
|
||||
try:
|
||||
with open(f"{_proc_dir}/smp_affinity", "w") as f:
|
||||
f.write("7") # cores 0,1,2
|
||||
except (OSError, PermissionError):
|
||||
continue
|
||||
logger.info("USB audio IRQ %s pinned to core 3 for RT stability", _usb_irq)
|
||||
else:
|
||||
logger.info("No USB audio IRQ found — skipping IRQ affinity (non-critical)")
|
||||
except Exception as exc:
|
||||
logger.warning("Could not set IRQ affinity (non-root?): %s", exc)
|
||||
|
||||
# Disable Python garbage collector to prevent 10-50ms GC pauses in
|
||||
# the real-time audio callback. At ~500 numpy allocs/sec in the
|
||||
# pipeline, default GC (threshold=700) triggers every ~1.4s,
|
||||
|
||||
Executable
+387
@@ -0,0 +1,387 @@
|
||||
#!/usr/bin/env bash
|
||||
# ────────────────────────────────────────────────────────────────────
|
||||
# Pi Multi-FX Pedal — RT Performance Tuning Script
|
||||
#
|
||||
# Applies real-time audio optimizations for stable guitar playing on
|
||||
# RPi 4B. Designed to run at boot (via systemd or main.py) and on
|
||||
# every JACK/audio profile change.
|
||||
#
|
||||
# Targets:
|
||||
# - Round-trip latency: <12ms (ideally <8ms)
|
||||
# - Zero xruns during playing
|
||||
# - CPU <40% on Pi 4B at recommended settings (512/48k)
|
||||
#
|
||||
# Usage:
|
||||
# sudo ./rt-tune.sh # apply all optimizations
|
||||
# sudo ./rt-tune.sh --status # check current settings
|
||||
# sudo ./rt-tune.sh --irq-only # just IRQ affinity
|
||||
# sudo ./rt-tune.sh --usb-audio-irq # find + pin USB audio IRQ
|
||||
# ────────────────────────────────────────────────────────────────────
|
||||
|
||||
set -euo pipefail
|
||||
|
||||
# ── Colour helpers ──────────────────────────────────────────────────
|
||||
info() { printf "\\e[34m[INFO] %s\\e[0m\\n" "$*"; }
|
||||
ok() { printf "\\e[32m[ OK ] %s\\e[0m\\n" "$*"; }
|
||||
warn() { printf "\\e[33m[WARN] %s\\e[0m\\n" "$*"; }
|
||||
err() { printf "\\e[31m[FAIL] %s\\e[0m\\n" "$*"; }
|
||||
|
||||
# ── Config ─────────────────────────────────────────────────────────
|
||||
# Which CPU core to dedicate to audio IRQ handling
|
||||
# RPi 4B has 4 cores (0-3). Core 3 is largely unused by Linux housekeeping.
|
||||
# Core 0 = most interrupts + kernel, Core 1-2 = general, Core 3 = isolated
|
||||
IRQ_CORE=3
|
||||
|
||||
# Default JACK parameters (will be overridden by main.py dynamically)
|
||||
JACK_PERIOD=512
|
||||
JACK_RATE=48000
|
||||
|
||||
# ── Helpers ─────────────────────────────────────────────────────────
|
||||
|
||||
# Find the USB audio interface IRQ number
|
||||
find_usb_audio_irq() {
|
||||
# Look for the USB audio device in /proc/interrupts
|
||||
# On RPi 4B, the USB controller is on a PCIe bridge (xhci-hcd) or
|
||||
# directly on the BCM2711's DWC2/dwc_otg USB controller.
|
||||
# Focusrite Scarlett 2i2 shows up as a USB interrupt tied to xhci-hcd.
|
||||
|
||||
# Strategy 1: Look for xhci-hcd (USB 3.0 controller on Pi 4B)
|
||||
local irq
|
||||
irq=$(awk '/xhci-hcd/ {gsub(":","",$1); print $1}' /proc/interrupts 2>/dev/null | head -1)
|
||||
|
||||
# Strategy 2: Look for dwc_otg/dwc2 (USB 2.0 controller)
|
||||
if [[ -z "$irq" ]]; then
|
||||
irq=$(awk '/dwc_otg|dwc2/ {gsub(":","",$1); print $1}' /proc/interrupts 2>/dev/null | head -1)
|
||||
fi
|
||||
|
||||
# Strategy 3: Find the USB controller from sysfs for the audio device
|
||||
if [[ -z "$irq" ]]; then
|
||||
# Try to find the USB device that's our audio interface
|
||||
# Look for USB audio class devices
|
||||
local usb_dev
|
||||
usb_dev=$(grep -l "audio" /sys/bus/usb/devices/*/bInterfaceClass 2>/dev/null | head -1)
|
||||
if [[ -n "$usb_dev" ]]; then
|
||||
local usb_path
|
||||
usb_path=$(dirname "$usb_dev")
|
||||
# Walk up to find the parent USB controller
|
||||
while [[ "$usb_path" != "/sys/bus/usb/devices" && "$usb_path" != "/" ]]; do
|
||||
if [[ -f "$usb_path/irq" ]]; then
|
||||
irq=$(cat "$usb_path/irq" 2>/dev/null)
|
||||
break
|
||||
fi
|
||||
usb_path=$(dirname "$usb_path" 2>/dev/null)
|
||||
done
|
||||
fi
|
||||
fi
|
||||
|
||||
echo "$irq"
|
||||
}
|
||||
|
||||
# ── Apply IRQ affinity ──────────────────────────────────────────────
|
||||
|
||||
apply_irq_affinity() {
|
||||
local irq="$1"
|
||||
local core="$2"
|
||||
local smp_affinity
|
||||
|
||||
if [[ -z "$irq" || "$irq" == "0" ]]; then
|
||||
warn "No USB audio IRQ found — cannot set affinity"
|
||||
return 1
|
||||
fi
|
||||
|
||||
# Convert core number to hex mask for /proc/irq/*/smp_affinity
|
||||
# Core 0 = 1, Core 1 = 2, Core 2 = 4, Core 3 = 8
|
||||
smp_affinity=$(printf "%x" $((1 << core)))
|
||||
|
||||
local irq_dir="/proc/irq/$irq"
|
||||
if [[ ! -d "$irq_dir" ]]; then
|
||||
warn "IRQ $irq directory not found at $irq_dir"
|
||||
return 1
|
||||
fi
|
||||
|
||||
echo "$smp_affinity" > "$irq_dir/smp_affinity" 2>/dev/null || true
|
||||
local effective
|
||||
effective=$(cat "$irq_dir/smp_affinity" 2>/dev/null || echo "unknown")
|
||||
|
||||
# Also set smp_affinity_list for convenience
|
||||
echo "$core" > "$irq_dir/smp_affinity_list" 2>/dev/null || true
|
||||
|
||||
info "IRQ $irq pinned to core $core (smp_affinity=0x$smp_affinity, effective=0x$effective)"
|
||||
return 0
|
||||
}
|
||||
|
||||
# ── Set RT priority for the current process ──────────────────────────
|
||||
|
||||
set_self_rt_priority() {
|
||||
local prio="$1"
|
||||
# Set SCHED_FIFO with the given priority for our process group
|
||||
# Note: This only works if called from the target process or with CAP_SYS_NICE
|
||||
chrt -f -p "$prio" $$ 2>/dev/null || warn "Cannot set self RT priority (not running as root?)"
|
||||
}
|
||||
|
||||
# ── CPU isolation ───────────────────────────────────────────────────
|
||||
|
||||
# Move all non-critical interrupts away from the IRQ core
|
||||
isolate_core_from_housekeeping() {
|
||||
local core="$1"
|
||||
local exclude_irqs="$2" # comma-separated IRQs to keep on the isolated core
|
||||
|
||||
# For each IRQ, move it away from our dedicated audio core
|
||||
# unless it's one we explicitly want to keep there
|
||||
for irq_dir in /proc/irq/[0-9]*/; do
|
||||
local irq_num
|
||||
irq_num=$(basename "$irq_dir")
|
||||
local irq_name
|
||||
irq_name=$(cat "${irq_dir}affinity_hint" 2>/dev/null || echo "")
|
||||
|
||||
# Skip if this is the USB audio IRQ we want to keep pinned
|
||||
if [[ ",$exclude_irqs," == *",$irq_num,"* ]]; then
|
||||
continue
|
||||
fi
|
||||
|
||||
# Move to other cores (0-2, leaving core 3 free)
|
||||
# Affinity = 0x7 (cores 0,1,2)
|
||||
echo "7" > "${irq_dir}smp_affinity" 2>/dev/null || true
|
||||
done
|
||||
info "Non-audio IRQs moved away from core $core"
|
||||
}
|
||||
|
||||
# ── Status check ────────────────────────────────────────────────────
|
||||
|
||||
show_status() {
|
||||
echo ""
|
||||
info "========== RT Performance Status =========="
|
||||
echo ""
|
||||
|
||||
# CPU governor
|
||||
echo "── CPU Governor ──"
|
||||
for c in /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor; do
|
||||
local cpu
|
||||
cpu=$(basename "$(dirname "$c")")
|
||||
echo " $cpu: $(cat "$c" 2>/dev/null || echo 'N/A')"
|
||||
done
|
||||
|
||||
# Current frequency
|
||||
echo ""
|
||||
echo "── CPU Frequency ──"
|
||||
for c in /sys/devices/system/cpu/cpu*/cpufreq/scaling_cur_freq; do
|
||||
local cpu
|
||||
cpu=$(basename "$(dirname "$c")")
|
||||
local freq_khz
|
||||
freq_khz=$(cat "$c" 2>/dev/null || echo 'N/A')
|
||||
echo " $cpu: $((freq_khz / 1000)) MHz"
|
||||
done
|
||||
|
||||
# IRQ affinity
|
||||
echo ""
|
||||
echo "── IRQ Affinity ──"
|
||||
local irq
|
||||
irq=$(find_usb_audio_irq)
|
||||
if [[ -n "$irq" && "$irq" != "0" ]]; then
|
||||
local aff
|
||||
aff=$(cat "/proc/irq/$irq/smp_affinity" 2>/dev/null || echo "N/A")
|
||||
local name
|
||||
name=$(cat "/proc/irq/$irq/name" 2>/dev/null || echo "unknown")
|
||||
echo " USB Audio IRQ $irq ($name): smp_affinity=0x$aff"
|
||||
else
|
||||
echo " No USB audio IRQ found"
|
||||
fi
|
||||
|
||||
# All IRQs
|
||||
echo ""
|
||||
echo "── All Interrupts (affinity) ──"
|
||||
for irq_dir in /proc/irq/[0-9]*/; do
|
||||
local i
|
||||
i=$(basename "$irq_dir")
|
||||
local aff
|
||||
aff=$(cat "${irq_dir}smp_affinity" 2>/dev/null || echo "?")
|
||||
local name
|
||||
name=$(cat "${irq_dir}name" 2>/dev/null || echo "?")
|
||||
printf " IRQ %-4s 0x%-4s %s\\n" "$i" "$aff" "$name"
|
||||
done
|
||||
|
||||
# JACK status
|
||||
echo ""
|
||||
echo "── JACK Status ──"
|
||||
if pidof jackd >/dev/null 2>&1; then
|
||||
echo " jackd: RUNNING"
|
||||
# Show JACK command line
|
||||
ps aux | grep jackd | grep -v grep | head -1 | awk '{$1=$2=$3=$4=$5=$6=$7=$8=$9=$10=""; print " Args:" $0}'
|
||||
else
|
||||
echo " jackd: NOT RUNNING"
|
||||
fi
|
||||
|
||||
# RT priority of processes
|
||||
echo ""
|
||||
echo "── RT Priority ──"
|
||||
for proc in jackd python3; do
|
||||
pidof "$proc" 2>/dev/null | tr ' ' '\\n' | while read -r pid; do
|
||||
local policy
|
||||
policy=$(chrt -p "$pid" 2>/dev/null | head -1 || echo "N/A")
|
||||
echo " $proc (PID $pid): $policy"
|
||||
done
|
||||
done
|
||||
|
||||
# Memory locking
|
||||
echo ""
|
||||
echo "── Memory Locking ──"
|
||||
if [[ -f /proc/self/status ]]; then
|
||||
grep -i "lock" /proc/self/status 2>/dev/null | head -5 | while read -r line; do
|
||||
echo " $line"
|
||||
done
|
||||
fi
|
||||
|
||||
# XRun debug
|
||||
echo ""
|
||||
echo "── XRun Debug ──"
|
||||
for card in /proc/asound/card*/xrun_debug; do
|
||||
echo " $card: $(cat "$card" 2>/dev/null || echo 'N/A')"
|
||||
done
|
||||
|
||||
echo ""
|
||||
ok "Status check complete"
|
||||
}
|
||||
|
||||
# ═══════════════════════════════════════════════════════════════════
|
||||
# Main
|
||||
# ═══════════════════════════════════════════════════════════════════
|
||||
|
||||
if [[ $EUID -ne 0 ]]; then
|
||||
err "This script must be run as root"
|
||||
exit 1
|
||||
fi
|
||||
|
||||
MODE="${1:-all}"
|
||||
|
||||
case "$MODE" in
|
||||
--status|-s)
|
||||
show_status
|
||||
exit 0
|
||||
;;
|
||||
|
||||
--irq-only|-i)
|
||||
IRQ=$(find_usb_audio_irq)
|
||||
if [[ -n "$IRQ" && "$IRQ" != "0" ]]; then
|
||||
apply_irq_affinity "$IRQ" "$IRQ_CORE" && ok "IRQ affinity applied"
|
||||
else
|
||||
warn "No USB audio IRQ found — checking /proc/interrupts..."
|
||||
grep -E "xhci|dwc|usb|audio" /proc/interrupts | head -10
|
||||
echo ""
|
||||
info "To find the right IRQ manually:"
|
||||
info " cat /proc/interrupts | grep xhci"
|
||||
info " cat /sys/bus/usb/devices/*/irq 2>/dev/null"
|
||||
fi
|
||||
exit 0
|
||||
;;
|
||||
|
||||
--usb-audio-irq|-u)
|
||||
IRQ=$(find_usb_audio_irq)
|
||||
if [[ -n "$IRQ" && "$IRQ" != "0" ]]; then
|
||||
local name
|
||||
name=$(cat "/proc/irq/$IRQ/name" 2>/dev/null || echo "unknown")
|
||||
info "USB Audio IRQ = $IRQ ($name)"
|
||||
else
|
||||
warn "No USB audio IRQ found"
|
||||
echo "── /proc/interrupts (USB/audio lines) ──"
|
||||
grep -E "xhci|dwc|usb|audio|snd" /proc/interrupts | head -10
|
||||
fi
|
||||
exit 0
|
||||
;;
|
||||
|
||||
all|*)
|
||||
# Full tuning
|
||||
info "========== Pi Multi-FX Pedal — RT Tuning =========="
|
||||
echo ""
|
||||
|
||||
# ── 1. Find and pin USB audio IRQ ────────────────────────
|
||||
info "Step 1: USB audio IRQ affinity..."
|
||||
IRQ=$(find_usb_audio_irq)
|
||||
if [[ -n "$IRQ" && "$IRQ" != "0" ]]; then
|
||||
apply_irq_affinity "$IRQ" "$IRQ_CORE"
|
||||
# Isolate core 3 from housekeeping interrupts
|
||||
isolate_core_from_housekeeping "$IRQ_CORE" "$IRQ"
|
||||
else
|
||||
warn "USB audio IRQ not found — audio may work but without dedicated IRQ core"
|
||||
fi
|
||||
|
||||
# ── 2. CPU governor (already done in main.py, but belt-and-braces) ──
|
||||
info "Step 2: CPU governor → performance..."
|
||||
echo performance | tee /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor >/dev/null 2>&1 || \
|
||||
warn "Could not set CPU governor (may need cpufrequtils)"
|
||||
|
||||
# ── 3. Disable CPU idle states (C-states) for lower latency ──
|
||||
# This prevents the CPU from entering deep sleep that adds latency
|
||||
# on wake. Trade-off: ~0.5W extra power draw.
|
||||
info "Step 3: Disabling deep CPU idle states..."
|
||||
if [[ -f /sys/module/processor/parameters/max_cstate ]]; then
|
||||
echo 1 > /sys/module/processor/parameters/max_cstate 2>/dev/null || true
|
||||
fi
|
||||
if [[ -f /dev/cpu_dma_latency ]]; then
|
||||
# Write 0 to request minimum DMA latency (blocks deep C-states)
|
||||
# The file stays open while the process lives — we do it briefly
|
||||
echo 0 > /dev/cpu_dma_latency 2>/dev/null || true
|
||||
fi
|
||||
|
||||
# ── 4. Set JACK's ALSA buffer sizes for low latency ───────────
|
||||
# These are advisory — main.py overrides them via jackd arguments
|
||||
info "Step 4: ALSA buffer constraints (advisory)..."
|
||||
cat > /etc/security/limits.d/99-audio.conf <<'LIMITS'
|
||||
# Pi Multi-FX Pedal — Real-time audio limits
|
||||
# Applied by rt-tune.sh
|
||||
@audio - rtprio 95
|
||||
@audio - memlock unlimited
|
||||
@audio - nice -20
|
||||
LIMITS
|
||||
ok "Audio limits written to /etc/security/limits.d/99-audio.conf"
|
||||
|
||||
# ── 5. Set xrun_debug for diagnostics ─────────────────────────
|
||||
info "Step 5: Enable xrun tracking..."
|
||||
for card in /proc/asound/card*/xrun_debug; do
|
||||
if [[ -w "$card" ]]; then
|
||||
# Bit 0 = enable xrun logging
|
||||
# Bit 1 = show stack backtrace on xrun
|
||||
# Bit 2 = inhibit xrun (test mode)
|
||||
# Value 3 = log xruns with backtrace (diagnostic)
|
||||
echo 3 > "$card" 2>/dev/null || true
|
||||
ok "Set xrun_debug on $(dirname "$card" | xargs basename)"
|
||||
fi
|
||||
done
|
||||
|
||||
# ── 6. Process RT priority (for the calling process) ──────────
|
||||
info "Step 6: Setting RT priority..."
|
||||
# This is primarily done by main.py (mlockall, GC disable)
|
||||
# and the systemd service (LimitRTPRIO). We set it here too
|
||||
# so the script works in all contexts.
|
||||
set_self_rt_priority 80 || true
|
||||
|
||||
# ── 7. Systemd service check ──────────────────────────────────
|
||||
info "Step 7: Verifying systemd RT limits..."
|
||||
if systemctl is-active pi-multifx-pedal.service &>/dev/null; then
|
||||
local rtprio
|
||||
rtprio=$(systemctl show pi-multifx-pedal.service -p LimitRTPRIO --value 2>/dev/null || echo "?")
|
||||
local memlock
|
||||
memlock=$(systemctl show pi-multifx-pedal.service -p LimitMEMLOCK --value 2>/dev/null || echo "?")
|
||||
local nice
|
||||
nice=$(systemctl show pi-multifx-pedal.service -p LimitNICE --value 2>/dev/null || echo "?")
|
||||
info " LimitRTPRIO=$rtprio LimitMEMLOCK=$memlock LimitNICE=$nice"
|
||||
if [[ "$rtprio" != "95" ]]; then
|
||||
warn "LimitRTPRIO should be 95 — check pi-multifx-pedal.service"
|
||||
fi
|
||||
if [[ "$memlock" != "infinity" ]]; then
|
||||
warn "LimitMEMLOCK should be infinity — check pi-multifx-pedal.service"
|
||||
fi
|
||||
else
|
||||
warn "pi-multifx-pedal.service not running — check after deployment"
|
||||
fi
|
||||
|
||||
echo ""
|
||||
ok "========== RT Tuning Complete =========="
|
||||
echo ""
|
||||
info "Recommended next steps:"
|
||||
info " 1. Start pedal: sudo systemctl start pi-multifx-pedal.service"
|
||||
info " 2. Check logs: journalctl -fu pi-multifx-pedal.service"
|
||||
info " 3. Test latency: jack_iodelay (needs loopback cable)"
|
||||
info " 4. Check xruns: cat /proc/asound/card*/xrun_debug"
|
||||
info " 5. Full status: sudo ./rt-tune.sh --status"
|
||||
;;
|
||||
esac
|
||||
+27
-1
@@ -587,9 +587,35 @@ class AudioSystem:
|
||||
return devices
|
||||
|
||||
# ──────────────────────────────────────────────────────────────
|
||||
# XRun monitoring
|
||||
# XRun monitoring and tracking
|
||||
# ──────────────────────────────────────────────────────────────
|
||||
|
||||
def enable_xrun_tracking(self) -> bool:
|
||||
"""Enable kernel-level xrun tracking via ALSA xrun_debug.
|
||||
|
||||
Sets xrun_debug to value 3 on all ALSA cards:
|
||||
- Bit 0 (1): log xruns to kernel ring buffer
|
||||
- Bit 1 (2): show stack backtrace on xrun
|
||||
|
||||
Returns True if at least one card was configured.
|
||||
|
||||
Requires root. Non-fatal if unavailable.
|
||||
"""
|
||||
import glob as _glob
|
||||
configured = 0
|
||||
for card_path in _glob.glob("/proc/asound/card*/xrun_debug"):
|
||||
try:
|
||||
with open(card_path, "w") as f:
|
||||
f.write("3")
|
||||
configured += 1
|
||||
except (OSError, PermissionError):
|
||||
continue
|
||||
if configured:
|
||||
logger.info("XRun tracking enabled on %d ALSA card(s)", configured)
|
||||
else:
|
||||
logger.info("XRun tracking not available (non-root or no ALSA cards)")
|
||||
return configured > 0
|
||||
|
||||
@staticmethod
|
||||
def read_xrun_count() -> Optional[int]:
|
||||
"""Read JACK xrun counter from jack_showtime.
|
||||
|
||||
@@ -62,7 +62,7 @@ User={user}
|
||||
Group={group}
|
||||
WorkingDirectory={install_dir}
|
||||
ExecStartPre={python_bin} -c "from src.system.audio import _jack_is_running; import sys; sys.exit(0 if _jack_is_running() else 2)"
|
||||
ExecStart={python_bin} {main_script}
|
||||
ExecStart=/usr/bin/chrt -f 80 {python_bin} {main_script}
|
||||
ExecStop={python_bin} -c "import sys; sys.path.insert(0, '{install_dir}'); from main import PedalApp; PedalApp().shutdown()" 2>/dev/null || true
|
||||
Restart=on-failure
|
||||
RestartSec=3
|
||||
@@ -74,6 +74,7 @@ KillMode=process
|
||||
LimitRTPRIO=95
|
||||
LimitMEMLOCK=infinity
|
||||
LimitNICE=-20
|
||||
LimitSIGPENDING=128
|
||||
|
||||
# Environment
|
||||
Environment=PYTHONUNBUFFERED=1
|
||||
|
||||
Reference in New Issue
Block a user