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LSTM-based stock price forecaster.
Uses historical OHLCV data to predict future closing prices.
"""
import torch
import torch.nn as nn
import numpy as np
import pickle
import json
import os
from datetime import datetime
from typing import Dict, List, Optional, Tuple
import logging
logger = logging.getLogger(__name__)
class LSTMModel(nn.Module):
"""LSTM neural network for time series forecasting."""
def __init__(self, input_size: int = 5, hidden_size: int = 128,
num_layers: int = 2, output_size: int = 30, dropout: float = 0.2):
super(LSTMModel, self).__init__()
self.hidden_size = hidden_size
self.num_layers = num_layers
self.lstm = nn.LSTM(
input_size=input_size,
hidden_size=hidden_size,
num_layers=num_layers,
batch_first=True,
dropout=dropout if num_layers > 1 else 0
)
self.fc = nn.Sequential(
nn.Linear(hidden_size, 64),
nn.ReLU(),
nn.Dropout(dropout),
nn.Linear(64, output_size)
)
def forward(self, x: torch.Tensor) -> torch.Tensor:
# x shape: (batch, seq_len, input_size)
lstm_out, _ = self.lstm(x)
# Take the last output
last_output = lstm_out[:, -1, :]
# Predict future prices
predictions = self.fc(last_output)
return predictions
class MinMaxScaler:
"""Simple MinMax scaler for normalization."""
def __init__(self):
self.min_vals = None
self.max_vals = None
self.fitted = False
def fit(self, data: np.ndarray) -> 'MinMaxScaler':
self.min_vals = data.min(axis=0)
self.max_vals = data.max(axis=0)
# Avoid division by zero
self.range_vals = self.max_vals - self.min_vals
self.range_vals[self.range_vals == 0] = 1
self.fitted = True
return self
def transform(self, data: np.ndarray) -> np.ndarray:
if not self.fitted:
raise ValueError("Scaler not fitted. Call fit() first.")
return (data - self.min_vals) / self.range_vals
def fit_transform(self, data: np.ndarray) -> np.ndarray:
self.fit(data)
return self.transform(data)
def inverse_transform(self, data: np.ndarray, col_idx: int = 0) -> np.ndarray:
"""Inverse transform for a single column (default: close price at index 0)."""
if not self.fitted:
raise ValueError("Scaler not fitted. Call fit() first.")
return data * self.range_vals[col_idx] + self.min_vals[col_idx]
class StockForecaster:
"""
Stock price forecaster using LSTM neural network.
The model is lazy-loaded on first use to avoid slow startup times.
Supports training on historical OHLCV data and predicting future prices.
"""
MODEL_DIR = os.path.join(os.path.dirname(__file__), 'forecast_models')
def __init__(self, sequence_length: int = 60, forecast_horizon: int = 30):
self._models: Dict[str, LSTMModel] = {}
self._scalers: Dict[str, MinMaxScaler] = {}
self._device = "cuda" if torch.cuda.is_available() else "cpu"
self.sequence_length = sequence_length
self.forecast_horizon = forecast_horizon
# Ensure model directory exists
os.makedirs(self.MODEL_DIR, exist_ok=True)
def _get_ticker_dir(self, ticker: str) -> str:
"""Get the directory path for a ticker's model files."""
return os.path.join(self.MODEL_DIR, ticker.upper())
def _load_model(self, ticker: str) -> bool:
"""
Load a trained model for a ticker from disk.
Returns:
True if model was loaded successfully, False otherwise.
"""
ticker = ticker.upper()
if ticker in self._models:
return True
ticker_dir = self._get_ticker_dir(ticker)
model_path = os.path.join(ticker_dir, 'model.pt')
scaler_path = os.path.join(ticker_dir, 'scaler.pkl')
if not os.path.exists(model_path) or not os.path.exists(scaler_path):
return False
try:
logger.info(f"Loading forecast model for {ticker}...")
# Load scaler
with open(scaler_path, 'rb') as f:
self._scalers[ticker] = pickle.load(f)
# Build and load model
model = LSTMModel(output_size=self.forecast_horizon)
model.load_state_dict(torch.load(model_path, map_location=self._device, weights_only=True))
model.to(self._device)
model.eval()
self._models[ticker] = model
logger.info(f"Forecast model for {ticker} loaded successfully on {self._device}")
return True
except Exception as e:
logger.error(f"Failed to load forecast model for {ticker}: {e}")
return False
def _save_model(self, ticker: str, metadata: Dict) -> None:
"""Save trained model and scaler to disk."""
ticker = ticker.upper()
ticker_dir = self._get_ticker_dir(ticker)
os.makedirs(ticker_dir, exist_ok=True)
model_path = os.path.join(ticker_dir, 'model.pt')
scaler_path = os.path.join(ticker_dir, 'scaler.pkl')
metadata_path = os.path.join(ticker_dir, 'metadata.json')
# Save model weights
torch.save(self._models[ticker].state_dict(), model_path)
# Save scaler
with open(scaler_path, 'wb') as f:
pickle.dump(self._scalers[ticker], f)
# Save metadata
with open(metadata_path, 'w') as f:
json.dump(metadata, f, indent=2)
logger.info(f"Forecast model for {ticker} saved to {ticker_dir}")
def _prepare_data(self, data: List[Dict]) -> Tuple[np.ndarray, np.ndarray]:
"""
Prepare OHLCV data for training.
Args:
data: List of dicts with keys: o, h, l, c, v (open, high, low, close, volume)
Returns:
Tuple of (X, y) numpy arrays for training
"""
# Extract OHLCV features - close first for easy inverse transform
features = np.array([[d['c'], d['o'], d['h'], d['l'], d['v']] for d in data], dtype=np.float32)
# Create sequences
X, y = [], []
for i in range(len(features) - self.sequence_length - self.forecast_horizon + 1):
X.append(features[i:i + self.sequence_length])
# Target: next forecast_horizon closing prices
y.append(features[i + self.sequence_length:i + self.sequence_length + self.forecast_horizon, 0])
return np.array(X), np.array(y)
def train(self, ticker: str, data: List[Dict], epochs: int = 50,
learning_rate: float = 0.001, batch_size: int = 32) -> Dict:
"""
Train the LSTM model on historical price data.
Args:
ticker: Stock ticker symbol
data: List of OHLCV dicts (must have at least sequence_length + forecast_horizon entries)
epochs: Number of training epochs
learning_rate: Learning rate for optimizer
batch_size: Training batch size
Returns:
Dict with training results (loss, metadata)
"""
ticker = ticker.upper()
if len(data) < self.sequence_length + self.forecast_horizon:
raise ValueError(f"Insufficient data: need at least {self.sequence_length + self.forecast_horizon} data points")
logger.info(f"Training forecast model for {ticker} with {len(data)} data points...")
# Prepare data
X, y = self._prepare_data(data)
# Normalize features
scaler = MinMaxScaler()
X_flat = X.reshape(-1, X.shape[-1])
scaler.fit(X_flat)
X_scaled = np.array([scaler.transform(seq) for seq in X])
# Normalize targets using close price stats
y_scaled = (y - scaler.min_vals[0]) / scaler.range_vals[0]
self._scalers[ticker] = scaler
# Convert to tensors
X_tensor = torch.FloatTensor(X_scaled).to(self._device)
y_tensor = torch.FloatTensor(y_scaled).to(self._device)
# Split train/validation (80/20)
split_idx = int(len(X_tensor) * 0.8)
X_train, X_val = X_tensor[:split_idx], X_tensor[split_idx:]
y_train, y_val = y_tensor[:split_idx], y_tensor[split_idx:]
# Build model
model = LSTMModel(output_size=self.forecast_horizon)
model.to(self._device)
criterion = nn.MSELoss()
optimizer = torch.optim.Adam(model.parameters(), lr=learning_rate)
# Training loop
best_val_loss = float('inf')
train_losses = []
for epoch in range(epochs):
model.train()
epoch_loss = 0
# Mini-batch training
for i in range(0, len(X_train), batch_size):
batch_X = X_train[i:i + batch_size]
batch_y = y_train[i:i + batch_size]
optimizer.zero_grad()
outputs = model(batch_X)
loss = criterion(outputs, batch_y)
loss.backward()
optimizer.step()
epoch_loss += loss.item()
avg_train_loss = epoch_loss / (len(X_train) // batch_size + 1)
train_losses.append(avg_train_loss)
# Validation
model.eval()
with torch.no_grad():
val_outputs = model(X_val)
val_loss = criterion(val_outputs, y_val).item()
if val_loss < best_val_loss:
best_val_loss = val_loss
if (epoch + 1) % 10 == 0:
logger.info(f"Epoch {epoch + 1}/{epochs} - Train Loss: {avg_train_loss:.6f}, Val Loss: {val_loss:.6f}")
self._models[ticker] = model
# Save model and metadata
metadata = {
"ticker": ticker,
"trained_at": datetime.utcnow().isoformat() + "Z",
"training_epochs": epochs,
"final_train_loss": float(train_losses[-1]),
"final_val_loss": float(best_val_loss),
"data_points": len(data),
"sequence_length": self.sequence_length,
"forecast_horizon": self.forecast_horizon,
"model_version": "1.0"
}
self._save_model(ticker, metadata)
logger.info(f"Training complete for {ticker}. Final val loss: {best_val_loss:.6f}")
return {
"status": "training_complete",
"ticker": ticker,
"epochs": epochs,
"final_loss": float(train_losses[-1]),
"validation_loss": float(best_val_loss),
"data_points": len(data)
}
def predict(self, ticker: str, recent_data: List[Dict]) -> Dict:
"""
Generate price forecast using trained model.
Args:
ticker: Stock ticker symbol
recent_data: Most recent OHLCV data (at least sequence_length entries)
Returns:
Dict with predictions and confidence bounds
"""
ticker = ticker.upper()
# Load model if not in memory
if ticker not in self._models:
if not self._load_model(ticker):
raise ValueError(f"No trained model found for {ticker}. Train the model first.")
if len(recent_data) < self.sequence_length:
raise ValueError(f"Need at least {self.sequence_length} data points for prediction")
# Use last sequence_length data points
data = recent_data[-self.sequence_length:]
features = np.array([[d['c'], d['o'], d['h'], d['l'], d['v']] for d in data], dtype=np.float32)
# Normalize
scaler = self._scalers[ticker]
features_scaled = scaler.transform(features)
# Predict
model = self._models[ticker]
model.eval()
X = torch.FloatTensor(features_scaled).unsqueeze(0).to(self._device)
with torch.no_grad():
predictions_scaled = model(X).cpu().numpy()[0]
# Inverse transform predictions
predictions = scaler.inverse_transform(predictions_scaled, col_idx=0)
# Calculate confidence bounds (simple approach: +/- percentage based on historical volatility)
recent_closes = [d['c'] for d in recent_data[-30:]]
volatility = np.std(recent_closes) / np.mean(recent_closes)
confidence_pct = max(0.02, min(0.10, volatility * 2)) # 2-10% bounds
upper_bound = predictions * (1 + confidence_pct)
lower_bound = predictions * (1 - confidence_pct)
# Get last date from data for generating forecast dates
last_timestamp = recent_data[-1].get('t', 0)
return {
"predictions": predictions.tolist(),
"upper_bound": upper_bound.tolist(),
"lower_bound": lower_bound.tolist(),
"last_timestamp": last_timestamp,
"forecast_horizon": self.forecast_horizon
}
def has_model(self, ticker: str) -> bool:
"""Check if a trained model exists for the ticker."""
ticker = ticker.upper()
if ticker in self._models:
return True
ticker_dir = self._get_ticker_dir(ticker)
return os.path.exists(os.path.join(ticker_dir, 'model.pt'))
def get_model_metadata(self, ticker: str) -> Optional[Dict]:
"""Get metadata for a trained model."""
ticker = ticker.upper()
metadata_path = os.path.join(self._get_ticker_dir(ticker), 'metadata.json')
if not os.path.exists(metadata_path):
return None
with open(metadata_path, 'r') as f:
return json.load(f)
def unload_model(self, ticker: str) -> None:
"""Unload a model from memory to free resources."""
ticker = ticker.upper()
if ticker in self._models:
del self._models[ticker]
del self._scalers[ticker]
if torch.cuda.is_available():
torch.cuda.empty_cache()
logger.info(f"Forecast model for {ticker} unloaded")
# Singleton instance
_forecaster_instance: Optional[StockForecaster] = None
def get_stock_forecaster() -> StockForecaster:
"""Get or create the singleton stock forecaster instance."""
global _forecaster_instance
if _forecaster_instance is None:
_forecaster_instance = StockForecaster()
return _forecaster_instance
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