Expert skill for using MOSS-TTS-Nano, a 0.1B parameter multilingual real-time TTS model that runs on CPU with voice cloning support.
---
name: moss-tts-nano-speech
description: Expert skill for using MOSS-TTS-Nano, a 0.1B parameter multilingual real-time TTS model that runs on CPU with voice cloning support.
triggers:
- generate speech with MOSS TTS
- text to speech with voice cloning
- moss tts nano inference
- run MOSS-TTS-Nano locally
- multilingual TTS CPU inference
- clone voice with MOSS
- streaming audio generation python
- tiny TTS model deployment
---
# MOSS-TTS-Nano Speech Generation Skill
> Skill by [ara.so](https://ara.so) — Daily 2026 Skills collection.
MOSS-TTS-Nano is an open-source multilingual tiny TTS model (0.1B parameters) from MOSI.AI and the OpenMOSS team. It uses an Audio Tokenizer + LLM autoregressive pipeline to generate 48 kHz stereo speech in real time, supports 20 languages, voice cloning, streaming inference, and runs on CPU without a GPU.
## Installation
### Conda (recommended)
```bash
conda create -n moss-tts-nano python=3.12 -y
conda activate moss-tts-nano
git clone https://github.com/OpenMOSS/MOSS-TTS-Nano.git
cd MOSS-TTS-Nano
pip install -r requirements.txt
pip install -e .
```
### Fix WeTextProcessing if it fails
```bash
conda install -c conda-forge pynini=2.1.6.post1 -y
pip install git+https://github.com/WhizZest/WeTextProcessing.git
```
After `pip install -e .` the `moss-tts-nano` CLI command is available in the active environment.
## Model Weights
Models are auto-downloaded from Hugging Face on first run:
- TTS model: `OpenMOSS-Team/MOSS-TTS-Nano`
- Audio tokenizer: `OpenMOSS-Team/MOSS-Audio-Tokenizer-Nano`
ModelScope mirrors are available at `openmoss/MOSS-TTS-Nano` and `openmoss/MOSS-Audio-Tokenizer-Nano`.
## CLI Commands
### Generate speech (voice clone mode)
```bash
moss-tts-nano generate \
--prompt-speech assets/audio/zh_1.wav \
--text "欢迎关注模思智能、上海创智学院与复旦大学自然语言处理实验室。"
```
Output defaults to `generated_audio/moss_tts_nano_output.wav`.
### Generate from a text file (long-form)
```bash
moss-tts-nano generate \
--prompt-speech assets/audio/zh_1.wav \
--text-file my_script.txt \
--output output.wav
```
### Launch local web demo
```bash
moss-tts-nano serve
# or directly:
python app.py
```
Opens at `http://127.0.0.1:18083` — model stays loaded in memory for fast repeated requests.
### Direct Python entrypoint
```bash
python infer.py \
--prompt-audio-path assets/audio/zh_1.wav \
--text "Hello, this is a test of MOSS-TTS-Nano."
```
Output: `generated_audio/infer_output.wav`
## Python API Usage
### Basic voice clone inference
```python
from infer import MossTTSNanoInference
# Initialize once (downloads weights on first run)
tts = MossTTSNanoInference()
# Voice clone: synthesize text in the style of the reference audio
audio = tts.infer(
text="欢迎使用MOSS语音合成系统。",
prompt_audio_path="assets/audio/zh_1.wav",
)
# Save output
import soundfile as sf
sf.write("output.wav", audio, samplerate=48000)
```
### English voice clone
```python
from infer import MossTTSNanoInference
tts = MossTTSNanoInference()
audio = tts.infer(
text="Welcome to MOSS TTS Nano, a tiny but capable text to speech model.",
prompt_audio_path="assets/audio/en_sample.wav",
)
import soundfile as sf
sf.write("english_output.wav", audio, samplerate=48000)
```
### Streaming inference (low latency)
```python
from infer import MossTTSNanoInference
import soundfile as sf
import numpy as np
tts = MossTTSNanoInference()
chunks = []
for audio_chunk in tts.infer_stream(
text="This sentence is generated chunk by chunk for low latency playback.",
prompt_audio_path="assets/audio/en_sample.wav",
):
chunks.append(audio_chunk)
# process or play chunk in real time here
full_audio = np.concatenate(chunks)
sf.write("streamed_output.wav", full_audio, samplerate=48000)
```
### Long-text synthesis with chunked voice cloning
```python
from infer import MossTTSNanoInference
tts = MossTTSNanoInference()
long_text = """
MOSS-TTS-Nano supports long-form synthesis through automatic chunking.
Each chunk uses the same reference voice, producing consistent speaker identity
across the entire output even for multi-paragraph documents.
"""
audio = tts.infer(
text=long_text,
prompt_audio_path="assets/audio/en_sample.wav",
)
import soundfile as sf
sf.write("long_form_output.wav", audio, samplerate=48000)
```
### FastAPI HTTP endpoint usage
When the server is running (`moss-tts-nano serve` or `python app.py`):
```python
import requests
import base64
import soundfile as sf
import io
import numpy as np
# Read reference audio as base64
with open("assets/audio/zh_1.wav", "rb") as f:
ref_audio_b64 = base64.b64encode(f.read()).decode()
response = requests.post(
"http://127.0.0.1:18083/generate",
json={
"text": "你好,这是一个语音合成测试。",
"prompt_audio_base64": ref_audio_b64,
},
)
data = response.json()
audio_bytes = base64.b64decode(data["audio_base64"])
audio_array, sr = sf.read(io.BytesIO(audio_bytes))
sf.write("api_output.wav", audio_array, samplerate=sr)
```
### Streaming HTTP response (real-time web playback)
```python
import requests
with open("assets/audio/zh_1.wav", "rb") as f:
ref_audio_b64 = __import__("base64").b64encode(f.read()).decode()
with requests.post(
"http://127.0.0.1:18083/generate_stream",
json={
"text": "流式语音合成示例,适合实时播放场景。",
"prompt_audio_base64": ref_audio_b64,
},
stream=True,
) as resp:
with open("stream_output.wav", "wb") as out:
for chunk in resp.iter_content(chunk_size=4096):
out.write(chunk)
```
## Supported Languages
| Code | Language | Code | Language | Code | Language |
|------|-----------|------|-----------|------|----------|
| zh | Chinese | en | English | de | German |
| es | Spanish | fr | French | ja | Japanese |
| it | Italian | hu | Hungarian | ko | Korean |
| ru | Russian | fa | Persian | ar | Arabic |
| pl | Polish | pt | Portuguese| cs | Czech |
| da | Danish | sv | Swedish | el | Greek |
| tr | Turkish | | | | |
The language is inferred automatically from the input text and the reference audio. No explicit language code parameter is required for basic usage.
## Architecture Overview
- **Pipeline**: Audio Tokenizer + LLM (pure autoregressive)
- **Audio Tokenizer**: MOSS-Audio-Tokenizer-Nano (~20M params), CNN-free causal Transformer (Cat architecture)
- **Output**: 48 kHz, 2-channel (stereo)
- **Token rate**: 12.5 Hz token stream
- **Codebooks**: RVQ with 16 codebooks (0.125 kbps – 2 kbps)
- **LLM**: ~0.1B parameters total
## Key CLI Flags
| Flag | Alias | Description |
|------|-------|-------------|
| `--prompt-audio-path` | — | Path to reference WAV for voice cloning (`infer.py`) |
| `--prompt-speech` | — | Same purpose in `moss-tts-nano generate` CLI |
| `--text` | — | Input text string |
| `--text-file` | — | Path to plain text file for long-form synthesis |
| `--output` | — | Output WAV file path (default varies by entrypoint) |
## Common Patterns
### Pattern: Batch synthesis with one reference voice
```python
from infer import MossTTSNanoInference
import soundfile as sf
tts = MossTTSNanoInference()
ref = "assets/audio/zh_1.wav"
sentences = [
"第一句话,用于批量合成测试。",
"第二句话,保持相同的音色。",
"第三句话,输出独立的音频文件。",
]
for i, sentence in enumerate(sentences):
audio = tts.infer(text=sentence, prompt_audio_path=ref)
sf.write(f"output_{i:02d}.wav", audio, samplerate=48000)
print(f"Saved output_{i:02d}.wav")
```
### Pattern: Real-time playback with sounddevice
```python
import sounddevice as sd
import numpy as np
from infer import MossTTSNanoInference
tts = MossTTSNanoInference()
buffer = []
for chunk in tts.infer_stream(
text="Real-time playback example using sounddevice.",
prompt_audio_path="assets/audio/en_sample.wav",
):
buffer.append(chunk)
audio = np.concatenate(buffer)
sd.play(audio, samplerate=48000)
sd.wait()
```
### Pattern: Gradio integration
```python
import gradio as gr
import soundfile as sf
import numpy as np
import io
from infer import MossTTSNanoInference
tts = MossTTSNanoInference()
def synthesize(reference_audio_path: str, text: str):
audio = tts.infer(text=text, prompt_audio_path=reference_audio_path)
# Return as (sample_rate, numpy_array) tuple for Gradio Audio component
return (48000, audio)
demo = gr.Interface(
fn=synthesize,
inputs=[
gr.Audio(type="filepath", label="Reference Voice"),
gr.Textbox(label="Text to synthesize"),
],
outputs=gr.Audio(label="Generated Speech"),
title="MOSS-TTS-Nano Voice Clone",
)
demo.launch()
```
## Troubleshooting
### WeTextProcessing install fails
```bash
# Use conda to get pynini, then install from source
conda install -c conda-forge pynini=2.1.6.post1 -y
pip install git+https://github.com/WhizZest/WeTextProcessing.git
```
### Model download is slow or fails
Set `HF_ENDPOINT` to a mirror if Hugging Face is unreachable:
```bash
export HF_ENDPOINT=https://hf-mirror.com
python infer.py --prompt-audio-path assets/audio/zh_1.wav --text "测试"
```
Or use ModelScope:
```bash
pip install modelscope
```
Then point model paths to `openmoss/MOSS-TTS-Nano` and `openmoss/MOSS-Audio-Tokenizer-Nano`.
### Out of memory on CPU
- Use streaming inference (`infer_stream`) to reduce peak memory.
- Reduce chunk size for long text inputs — the model handles chunked voice cloning automatically.
- Close other applications; the model needs ~1–2 GB RAM.
### Audio output is silent or corrupt
- Ensure the reference WAV is a clean mono or stereo file, 16-bit or float32, any sample rate (it will be resampled).
- Minimum reference audio duration: ~3–5 seconds for reliable voice cloning.
- Avoid reference audio with heavy background noise.
### `moss-tts-nano` command not found
```bash
# Re-run editable install inside the active conda env
pip install -e .
which moss-tts-nano # should resolve now
```
### Port conflict for web demo
```bash
# Default port is 18083; check what occupies it
lsof -i :18083
# Kill if needed, then relaunch
moss-tts-nano serve
```
## Output Defaults
| Entrypoint | Default output path |
|---|---|
| `python infer.py` | `generated_audio/infer_output.wav` |
| `moss-tts-nano generate` | `generated_audio/moss_tts_nano_output.wav` |
| `python app.py` / `moss-tts-nano serve` | returned via HTTP response |
The `generated_audio/` directory is created automatically if it does not exist.
Creator's repository · aradotso/trending-skills