import os import torch import gradio as gr from transformers import AutoModelForCausalLM, AutoTokenizer from huggingface_hub import snapshot_download from dotenv import load_dotenv # Load environment variables load_dotenv() # Device and torch dtype selection device = "cuda" if torch.cuda.is_available() else "cpu" torch_dtype = torch.bfloat16 if device == "cuda" else torch.float32 # Define a no-op decorator for CPU if needed def gpu_decorator(func): return func # If you are on GPU and have the spaces module, you could replace gpu_decorator with spaces.GPU # For CPU usage we simply use a no-op # Example: from snac import spaces; gpu_decorator = spaces.GPU() # Import SNAC after setting device from snac import SNAC print("Loading SNAC model...") snac_model = SNAC.from_pretrained("hubertsiuzdak/snac_24khz") snac_model = snac_model.to(device) snac_model.eval() # set SNAC to eval mode model_name = "canopylabs/orpheus-3b-0.1-ft" # Download only model config and safetensors files snapshot_download( repo_id=model_name, allow_patterns=[ "config.json", "*.safetensors", "model.safetensors.index.json", ], ignore_patterns=[ "optimizer.pt", "pytorch_model.bin", "training_args.bin", "scheduler.pt", "tokenizer.json", "tokenizer_config.json", "special_tokens_map.json", "vocab.json", "merges.txt", "tokenizer.*" ] ) print("Loading Orpheus model...") model = AutoModelForCausalLM.from_pretrained(model_name, torch_dtype=torch_dtype) model.to(device) model.eval() # set Orpheus to eval mode tokenizer = AutoTokenizer.from_pretrained(model_name) print(f"Orpheus model loaded to {device}") # Process text prompt into tokens with start/end markers def process_prompt(prompt, voice, tokenizer, device): prompt = f"{voice}: {prompt}" input_ids = tokenizer(prompt, return_tensors="pt").input_ids start_token = torch.tensor([[128259]], dtype=torch.int64) # Start token end_tokens = torch.tensor([[128009, 128260]], dtype=torch.int64) # End tokens modified_input_ids = torch.cat([start_token, input_ids, end_tokens], dim=1) attention_mask = torch.ones_like(modified_input_ids) return modified_input_ids.to(device), attention_mask.to(device) # Parse output tokens to extract audio codes def parse_output(generated_ids): token_to_find = 128257 token_to_remove = 128258 token_indices = (generated_ids == token_to_find).nonzero(as_tuple=True) if len(token_indices[1]) > 0: last_occurrence_idx = token_indices[1][-1].item() cropped_tensor = generated_ids[:, last_occurrence_idx + 1:] else: cropped_tensor = generated_ids processed_rows = [] for row in cropped_tensor: masked_row = row[row != token_to_remove] processed_rows.append(masked_row) code_lists = [] for row in processed_rows: row_length = row.size(0) new_length = (row_length // 7) * 7 trimmed_row = row[:new_length] trimmed_row = [t - 128266 for t in trimmed_row] code_lists.append(trimmed_row) return code_lists[0] # Return first sample # Redistribute codes for audio generation using SNAC def redistribute_codes(code_list, snac_model): snac_device = next(snac_model.parameters()).device layer_1, layer_2, layer_3 = [], [], [] for i in range((len(code_list) + 1) // 7): layer_1.append(code_list[7 * i]) layer_2.append(code_list[7 * i + 1] - 4096) layer_3.append(code_list[7 * i + 2] - (2 * 4096)) layer_3.append(code_list[7 * i + 3] - (3 * 4096)) layer_2.append(code_list[7 * i + 4] - (4 * 4096)) layer_3.append(code_list[7 * i + 5] - (5 * 4096)) layer_3.append(code_list[7 * i + 6] - (6 * 4096)) codes = [ torch.tensor(layer_1, device=snac_device).unsqueeze(0), torch.tensor(layer_2, device=snac_device).unsqueeze(0), torch.tensor(layer_3, device=snac_device).unsqueeze(0) ] audio_hat = snac_model.decode(codes) return audio_hat.detach().squeeze().cpu().numpy() # Main generation function with CPU optimizations @gpu_decorator def generate_speech(text, voice, temperature, top_p, repetition_penalty, max_new_tokens, progress=gr.Progress()): if not text.strip(): return None try: progress(0.1, "Processing text...") input_ids, attention_mask = process_prompt(text, voice, tokenizer, device) progress(0.3, "Generating speech tokens...") with torch.inference_mode(): generated_ids = model.generate( input_ids=input_ids, attention_mask=attention_mask, max_new_tokens=max_new_tokens, do_sample=True, temperature=temperature, top_p=top_p, repetition_penalty=repetition_penalty, num_return_sequences=1, eos_token_id=128258, ) progress(0.6, "Processing speech tokens...") code_list = parse_output(generated_ids) progress(0.8, "Converting tokens to audio...") audio_samples = redistribute_codes(code_list, snac_model) return (24000, audio_samples) # Return sample rate and numpy array audio except Exception as e: print(f"Error generating speech: {e}") return None # Example inputs for the Gradio UI examples = [ ["Hey there my name is Tara, and I'm a speech generation model that can sound like a person.", "tara", 0.6, 0.95, 1.1, 1200], ["I've also been taught to understand and produce paralinguistic things like sighing, or chuckling, or yawning!", "dan", 0.7, 0.95, 1.1, 1200], ["I live in San Francisco, and have, uhm let's see, 3 billion 7 hundred ... well, let's just say a lot of parameters.", "emma", 0.6, 0.9, 1.2, 1200] ] VOICES = ["tara", "dan", "josh", "emma"] # Create Gradio interface with gr.Blocks(title="Orpheus Text-to-Speech") as demo: gr.Markdown(""" # 🎵 Orpheus Text-to-Speech Enter your text below and hear it converted to natural-sounding speech. **Tips for better prompts:** - Include paralinguistic elements like ``, ``, or `uhm` for more human-like speech. - Longer prompts often produce more natural results. - Adjust the temperature slider to control variation in speech patterns. """) with gr.Row(): with gr.Column(scale=3): text_input = gr.Textbox( label="Text to speak", placeholder="Enter your text here...", lines=5 ) voice = gr.Dropdown( choices=VOICES, value="tara", label="Voice" ) with gr.Accordion("Advanced Settings", open=False): temperature = gr.Slider( minimum=0.1, maximum=1.5, value=0.6, step=0.05, label="Temperature", info="Higher values (0.7-1.0) create more expressive but less stable speech" ) top_p = gr.Slider( minimum=0.1, maximum=1.0, value=0.95, step=0.05, label="Top P", info="Nucleus sampling threshold" ) repetition_penalty = gr.Slider( minimum=1.0, maximum=2.0, value=1.1, step=0.05, label="Repetition Penalty", info="Higher values discourage repetitive patterns" ) max_new_tokens = gr.Slider( minimum=100, maximum=2000, value=1200, step=100, label="Max Length", info="Maximum length of generated audio (in tokens)" ) with gr.Row(): submit_btn = gr.Button("Generate Speech", variant="primary") clear_btn = gr.Button("Clear") with gr.Column(scale=2): audio_output = gr.Audio(label="Generated Speech", type="numpy") gr.Examples( examples=examples, inputs=[text_input, voice, temperature, top_p, repetition_penalty, max_new_tokens], outputs=audio_output, fn=generate_speech, cache_examples=True, ) submit_btn.click( fn=generate_speech, inputs=[text_input, voice, temperature, top_p, repetition_penalty, max_new_tokens], outputs=audio_output ) clear_btn.click( fn=lambda: (None, None), inputs=[], outputs=[text_input, audio_output] ) # Launch the Gradio app if __name__ == "__main__": demo.queue().launch(share=False, ssr_mode=False)