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| import gradio as gr | |
| import torch | |
| import joblib | |
| import numpy as np | |
| from itertools import product | |
| import torch.nn as nn | |
| class VirusClassifier(nn.Module): | |
| def __init__(self, input_shape: int): | |
| super(VirusClassifier, self).__init__() | |
| self.network = nn.Sequential( | |
| nn.Linear(input_shape, 64), | |
| nn.GELU(), | |
| nn.BatchNorm1d(64), | |
| nn.Dropout(0.3), | |
| nn.Linear(64, 32), | |
| nn.GELU(), | |
| nn.BatchNorm1d(32), | |
| nn.Dropout(0.3), | |
| nn.Linear(32, 32), | |
| nn.GELU(), | |
| nn.Linear(32, 2) | |
| ) | |
| def forward(self, x): | |
| return self.network(x) | |
| def get_feature_importance(self, x): | |
| """Calculate feature importance using gradient-based method""" | |
| x.requires_grad_(True) | |
| output = self.network(x) | |
| importance = torch.zeros_like(x) | |
| for i in range(output.shape[1]): | |
| if x.grad is not None: | |
| x.grad.zero_() | |
| output[..., i].sum().backward(retain_graph=True) | |
| importance += torch.abs(x.grad) | |
| return importance | |
| def sequence_to_kmer_vector(sequence: str, k: int = 4) -> np.ndarray: | |
| """Convert sequence to k-mer frequency vector""" | |
| # Generate all possible k-mers | |
| kmers = [''.join(p) for p in product("ACGT", repeat=k)] | |
| kmer_dict = {km: i for i, km in enumerate(kmers)} | |
| # Initialize vector | |
| vec = np.zeros(len(kmers), dtype=np.float32) | |
| # Count k-mers | |
| for i in range(len(sequence) - k + 1): | |
| kmer = sequence[i:i+k] | |
| if kmer in kmer_dict: | |
| vec[kmer_dict[kmer]] += 1 | |
| # Convert to frequencies | |
| total_kmers = len(sequence) - k + 1 | |
| if total_kmers > 0: | |
| vec = vec / total_kmers | |
| return vec | |
| def parse_fasta(text): | |
| sequences = [] | |
| current_header = None | |
| current_sequence = [] | |
| for line in text.split('\n'): | |
| line = line.strip() | |
| if not line: | |
| continue | |
| if line.startswith('>'): | |
| if current_header: | |
| sequences.append((current_header, ''.join(current_sequence))) | |
| current_header = line[1:] | |
| current_sequence = [] | |
| else: | |
| current_sequence.append(line.upper()) | |
| if current_header: | |
| sequences.append((current_header, ''.join(current_sequence))) | |
| return sequences | |
| def predict(file_obj): | |
| if file_obj is None: | |
| return "Please upload a FASTA file" | |
| # Read the file content | |
| try: | |
| if isinstance(file_obj, str): | |
| text = file_obj | |
| else: | |
| text = file_obj.decode('utf-8') | |
| except Exception as e: | |
| return f"Error reading file: {str(e)}" | |
| # Generate k-mer dictionary | |
| k = 4 # k-mer size | |
| kmers = [''.join(p) for p in product("ACGT", repeat=k)] | |
| kmer_dict = {km: i for i, km in enumerate(kmers)} | |
| # Load model and scaler | |
| try: | |
| device = 'cuda' if torch.cuda.is_available() else 'cpu' | |
| model = VirusClassifier(256).to(device) # k=4 -> 4^4 = 256 features | |
| # Load model with explicit map_location | |
| state_dict = torch.load('model.pt', map_location=device) | |
| model.load_state_dict(state_dict) | |
| # Load scaler | |
| scaler = joblib.load('scaler.pkl') | |
| # Set model to evaluation mode | |
| model.eval() | |
| except Exception as e: | |
| return f"Error loading model: {str(e)}\nFull traceback: {str(e.__traceback__)}" | |
| # Get predictions | |
| results = [] | |
| try: | |
| sequences = parse_fasta(text) | |
| for header, seq in sequences: | |
| # Get k-mer vector | |
| kmer_vector = sequence_to_kmer_vector(seq) | |
| kmer_vector = scaler.transform(kmer_vector.reshape(1, -1)) | |
| X_tensor = torch.FloatTensor(kmer_vector).to(device) | |
| # Get raw frequency vector before scaling | |
| raw_freq_vector = sequence_to_kmer_vector(seq) | |
| # Get predictions and feature importance | |
| with torch.no_grad(): | |
| output = model(X_tensor) | |
| probs = torch.softmax(output, dim=1) | |
| # Calculate feature importance | |
| importance = model.get_feature_importance(X_tensor) | |
| kmer_importance = importance[0].cpu().numpy() | |
| # Normalize importance scores to match original scale | |
| kmer_importance = kmer_importance / np.max(np.abs(kmer_importance)) * 0.002 | |
| # Get top 10 k-mers | |
| top_k = 10 | |
| top_indices = np.argsort(np.abs(kmer_importance))[-top_k:][::-1] | |
| important_kmers = [ | |
| { | |
| 'kmer': list(kmer_dict.keys())[list(kmer_dict.values()).index(i)], | |
| 'importance': float(kmer_importance[i]), | |
| 'frequency': float(raw_freq_vector[i]) | |
| } | |
| for i in top_indices | |
| ] | |
| # Format results | |
| pred_class = 1 if probs[0][1] > probs[0][0] else 0 | |
| pred_label = 'human' if pred_class == 1 else 'non-human' | |
| result = f"""Sequence: {header} | |
| Prediction: {pred_label} | |
| Confidence: {float(max(probs[0])):0.4f} | |
| Human probability: {float(probs[0][1]):0.4f} | |
| Non-human probability: {float(probs[0][0]):0.4f} | |
| Most influential k-mers:""" | |
| for kmer in important_kmers: | |
| result += f"\n {kmer['kmer']}: importance={kmer['importance']:.4f}, raw_freq={kmer['raw_freq']:.4f} ({kmer['raw_freq']*100:.2f}%), scaled_freq={kmer['scaled_freq']:.4f}" | |
| results.append(result) | |
| except Exception as e: | |
| return f"Error processing sequences: {str(e)}" | |
| return "\n\n".join(results) | |
| # Create the interface | |
| iface = gr.Interface( | |
| fn=predict, | |
| inputs=gr.File(label="Upload FASTA file", type="binary"), | |
| outputs=gr.Textbox(label="Results"), | |
| title="Virus Host Classifier" | |
| ) | |
| # Launch the interface | |
| if __name__ == "__main__": | |
| iface.launch() |