trader-ml/tests/unit/test_ml/test_regime_detector.py

"""
Tests Unitaires - RegimeDetector.

Tests de la détection de régimes de marché avec HMM.
"""

import pytest
import pandas as pd
import numpy as np
from datetime import datetime, timedelta

from src.ml.regime_detector import RegimeDetector


class TestRegimeDetectorInitialization:
    """Tests d'initialisation du RegimeDetector."""
    
    def test_initialization_default(self):
        """Test initialisation avec paramètres par défaut."""
        detector = RegimeDetector()
        
        assert detector.n_regimes == 4
        assert detector.random_state == 42
        assert detector.is_fitted is False
        assert len(detector.feature_names) == 0
    
    def test_initialization_custom_regimes(self):
        """Test initialisation avec nombre de régimes personnalisé."""
        detector = RegimeDetector(n_regimes=3)
        
        assert detector.n_regimes == 3
    
    def test_regime_names_defined(self):
        """Test que les noms de régimes sont définis."""
        detector = RegimeDetector()
        
        assert len(detector.REGIME_NAMES) == 4
        assert 'Trending Up' in detector.REGIME_NAMES.values()
        assert 'Trending Down' in detector.REGIME_NAMES.values()
        assert 'Ranging' in detector.REGIME_NAMES.values()
        assert 'High Volatility' in detector.REGIME_NAMES.values()


class TestRegimeDetectorFitting:
    """Tests d'entraînement du modèle."""
    
    @pytest.fixture
    def sample_data(self):
        """Génère des données de test."""
        dates = pd.date_range(start='2024-01-01', periods=200, freq='1H')
        
        np.random.seed(42)
        returns = np.random.normal(0.0001, 0.01, 200)
        prices = 1.1000 * np.exp(np.cumsum(returns))
        
        df = pd.DataFrame(index=dates)
        df['close'] = prices
        df['open'] = df['close'].shift(1).fillna(df['close'].iloc[0])
        df['high'] = df[['open', 'close']].max(axis=1) * 1.001
        df['low'] = df[['open', 'close']].min(axis=1) * 0.999
        df['volume'] = np.random.randint(1000, 10000, 200)
        
        return df
    
    def test_fit_success(self, sample_data):
        """Test entraînement réussi."""
        detector = RegimeDetector()
        
        detector.fit(sample_data)
        
        assert detector.is_fitted is True
        assert len(detector.feature_names) > 0
    
    def test_fit_creates_features(self, sample_data):
        """Test que fit crée les features."""
        detector = RegimeDetector()
        
        detector.fit(sample_data)
        
        # Vérifier que les features attendues sont créées
        expected_features = ['returns', 'volatility', 'trend', 'range', 'volume_change', 'momentum']
        
        for feature in expected_features:
            assert feature in detector.feature_names
    
    def test_fit_with_insufficient_data(self):
        """Test avec données insuffisantes."""
        detector = RegimeDetector()
        
        # Données trop courtes
        dates = pd.date_range(start='2024-01-01', periods=10, freq='1H')
        df = pd.DataFrame({
            'close': np.random.randn(10),
            'open': np.random.randn(10),
            'high': np.random.randn(10),
            'low': np.random.randn(10),
            'volume': np.random.randint(1000, 10000, 10)
        }, index=dates)
        
        # Devrait lever une erreur ou gérer gracieusement
        try:
            detector.fit(df)
            # Si pas d'erreur, vérifier que le modèle n'est pas fitted
            # ou qu'il y a un warning
        except Exception as e:
            # Acceptable
            pass


class TestRegimeDetectorPrediction:
    """Tests de prédiction des régimes."""
    
    @pytest.fixture
    def fitted_detector(self, sample_data):
        """Retourne un détecteur entraîné."""
        detector = RegimeDetector()
        detector.fit(sample_data)
        return detector
    
    @pytest.fixture
    def sample_data(self):
        """Génère des données de test."""
        dates = pd.date_range(start='2024-01-01', periods=200, freq='1H')
        
        np.random.seed(42)
        returns = np.random.normal(0.0001, 0.01, 200)
        prices = 1.1000 * np.exp(np.cumsum(returns))
        
        df = pd.DataFrame(index=dates)
        df['close'] = prices
        df['open'] = df['close'].shift(1).fillna(df['close'].iloc[0])
        df['high'] = df[['open', 'close']].max(axis=1) * 1.001
        df['low'] = df[['open', 'close']].min(axis=1) * 0.999
        df['volume'] = np.random.randint(1000, 10000, 200)
        
        return df
    
    def test_predict_regime_returns_array(self, fitted_detector, sample_data):
        """Test que predict_regime retourne un array."""
        regimes = fitted_detector.predict_regime(sample_data)
        
        assert isinstance(regimes, np.ndarray)
        assert len(regimes) > 0
    
    def test_predict_regime_values_valid(self, fitted_detector, sample_data):
        """Test que les régimes prédits sont valides."""
        regimes = fitted_detector.predict_regime(sample_data)
        
        # Tous les régimes doivent être entre 0 et n_regimes-1
        assert (regimes >= 0).all()
        assert (regimes < fitted_detector.n_regimes).all()
    
    def test_predict_current_regime(self, fitted_detector, sample_data):
        """Test prédiction du régime actuel."""
        current_regime = fitted_detector.predict_current_regime(sample_data)
        
        assert isinstance(current_regime, (int, np.integer))
        assert 0 <= current_regime < fitted_detector.n_regimes
    
    def test_predict_without_fitting(self, sample_data):
        """Test prédiction sans entraînement préalable."""
        detector = RegimeDetector()
        
        with pytest.raises(ValueError, match="not fitted"):
            detector.predict_regime(sample_data)
    
    def test_get_regime_probabilities(self, fitted_detector, sample_data):
        """Test obtention des probabilités."""
        probabilities = fitted_detector.get_regime_probabilities(sample_data)
        
        assert isinstance(probabilities, np.ndarray)
        assert probabilities.shape[1] == fitted_detector.n_regimes
        
        # Vérifier que les probabilités somment à 1
        prob_sums = probabilities.sum(axis=1)
        np.testing.assert_array_almost_equal(prob_sums, np.ones(len(prob_sums)), decimal=5)


class TestRegimeDetectorStatistics:
    """Tests des statistiques de régimes."""
    
    @pytest.fixture
    def fitted_detector(self, sample_data):
        """Retourne un détecteur entraîné."""
        detector = RegimeDetector()
        detector.fit(sample_data)
        return detector
    
    @pytest.fixture
    def sample_data(self):
        """Génère des données de test."""
        dates = pd.date_range(start='2024-01-01', periods=200, freq='1H')
        
        np.random.seed(42)
        returns = np.random.normal(0.0001, 0.01, 200)
        prices = 1.1000 * np.exp(np.cumsum(returns))
        
        df = pd.DataFrame(index=dates)
        df['close'] = prices
        df['open'] = df['close'].shift(1).fillna(df['close'].iloc[0])
        df['high'] = df[['open', 'close']].max(axis=1) * 1.001
        df['low'] = df[['open', 'close']].min(axis=1) * 0.999
        df['volume'] = np.random.randint(1000, 10000, 200)
        
        return df
    
    def test_get_regime_name(self, fitted_detector):
        """Test récupération du nom d'un régime."""
        for regime in range(fitted_detector.n_regimes):
            name = fitted_detector.get_regime_name(regime)
            assert isinstance(name, str)
            assert len(name) > 0
    
    def test_get_regime_statistics(self, fitted_detector, sample_data):
        """Test calcul des statistiques."""
        stats = fitted_detector.get_regime_statistics(sample_data)
        
        assert 'regime_counts' in stats
        assert 'regime_percentages' in stats
        assert 'current_regime' in stats
        assert 'current_regime_name' in stats
        
        # Vérifier que les pourcentages somment à 1
        total_pct = sum(stats['regime_percentages'].values())
        assert abs(total_pct - 1.0) < 0.01


class TestRegimeDetectorAdaptation:
    """Tests d'adaptation des paramètres."""
    
    def test_adapt_strategy_parameters(self):
        """Test adaptation des paramètres selon le régime."""
        detector = RegimeDetector()
        
        base_params = {
            'min_confidence': 0.6,
            'risk_per_trade': 0.02
        }
        
        # Tester pour chaque régime
        for regime in range(4):
            adapted = detector.adapt_strategy_parameters(regime, base_params)
            
            assert 'min_confidence' in adapted
            assert 'risk_per_trade' in adapted
            
            # Les paramètres doivent être modifiés
            assert adapted != base_params
    
    def test_adapt_trending_up(self):
        """Test adaptation pour régime Trending Up."""
        detector = RegimeDetector()
        
        base_params = {
            'min_confidence': 0.6,
            'risk_per_trade': 0.02
        }
        
        adapted = detector.adapt_strategy_parameters(0, base_params)  # 0 = Trending Up
        
        # Devrait être plus agressif
        assert adapted['min_confidence'] < base_params['min_confidence']
        assert adapted['risk_per_trade'] > base_params['risk_per_trade']
    
    def test_adapt_high_volatility(self):
        """Test adaptation pour régime High Volatility."""
        detector = RegimeDetector()
        
        base_params = {
            'min_confidence': 0.6,
            'risk_per_trade': 0.02
        }
        
        adapted = detector.adapt_strategy_parameters(3, base_params)  # 3 = High Volatility
        
        # Devrait être plus conservateur
        assert adapted['min_confidence'] > base_params['min_confidence']
        assert adapted['risk_per_trade'] < base_params['risk_per_trade']
    
    def test_should_trade_in_regime(self):
        """Test décision de trading selon régime."""
        detector = RegimeDetector()
        
        # Scalping devrait trader en Ranging
        assert detector.should_trade_in_regime(2, 'scalping') is True
        
        # Scalping ne devrait pas trader en High Volatility
        assert detector.should_trade_in_regime(3, 'scalping') is False
        
        # Intraday devrait trader en Trending
        assert detector.should_trade_in_regime(0, 'intraday') is True
        assert detector.should_trade_in_regime(1, 'intraday') is True
        
        # Intraday ne devrait pas trader en Ranging
        assert detector.should_trade_in_regime(2, 'intraday') is False


class TestRegimeDetectorFeatures:
    """Tests de calcul des features."""
    
    @pytest.fixture
    def sample_data(self):
        """Génère des données de test."""
        dates = pd.date_range(start='2024-01-01', periods=200, freq='1H')
        
        np.random.seed(42)
        returns = np.random.normal(0.0001, 0.01, 200)
        prices = 1.1000 * np.exp(np.cumsum(returns))
        
        df = pd.DataFrame(index=dates)
        df['close'] = prices
        df['open'] = df['close'].shift(1).fillna(df['close'].iloc[0])
        df['high'] = df[['open', 'close']].max(axis=1) * 1.001
        df['low'] = df[['open', 'close']].min(axis=1) * 0.999
        df['volume'] = np.random.randint(1000, 10000, 200)
        
        return df
    
    def test_calculate_features(self, sample_data):
        """Test calcul des features."""
        detector = RegimeDetector()
        
        features = detector._calculate_features(sample_data)
        
        assert isinstance(features, pd.DataFrame)
        assert len(features) > 0
        
        # Vérifier présence des features
        expected_features = ['returns', 'volatility', 'trend', 'range', 'volume_change', 'momentum']
        
        for feature in expected_features:
            assert feature in features.columns
    
    def test_features_no_nan(self, sample_data):
        """Test que les features n'ont pas de NaN après nettoyage."""
        detector = RegimeDetector()
        
        features = detector._calculate_features(sample_data)
        
        # Après dropna, ne devrait pas y avoir de NaN
        assert features.isna().sum().sum() == 0
    
    def test_normalize_features(self):
        """Test normalisation des features."""
        detector = RegimeDetector()
        
        # Créer features test
        X = np.random.randn(100, 6)
        
        X_normalized = detector._normalize_features(X)
        
        # Vérifier que la moyenne est proche de 0 et std proche de 1
        assert abs(X_normalized.mean()) < 0.1
        assert abs(X_normalized.std() - 1.0) < 0.1


class TestRegimeDetectorEdgeCases:
    """Tests des cas limites."""
    
    def test_with_missing_columns(self):
        """Test avec colonnes manquantes."""
        detector = RegimeDetector()
        
        # DataFrame incomplet
        df = pd.DataFrame({
            'close': np.random.randn(100)
            # Manque open, high, low, volume
        })
        
        with pytest.raises(KeyError):
            detector.fit(df)
    
    def test_with_constant_prices(self):
        """Test avec prix constants."""
        detector = RegimeDetector()
        
        dates = pd.date_range(start='2024-01-01', periods=200, freq='1H')
        
        df = pd.DataFrame(index=dates)
        df['close'] = 1.1000  # Prix constant
        df['open'] = 1.1000
        df['high'] = 1.1000
        df['low'] = 1.1000
        df['volume'] = 1000
        
        # Devrait gérer gracieusement (ou lever erreur appropriée)
        try:
            detector.fit(df)
            # Si réussit, vérifier que le modèle est fitted
            assert detector.is_fitted
        except Exception:
            # Acceptable si erreur appropriée
            pass
    
    def test_regime_name_invalid(self):
        """Test avec numéro de régime invalide."""
        detector = RegimeDetector()
        
        # Régime hors limites
        name = detector.get_regime_name(999)
        
        # Devrait retourner un nom par défaut
        assert 'Regime' in name


class TestRegimeDetectorIntegration:
    """Tests d'intégration."""
    
    @pytest.fixture
    def sample_data(self):
        """Génère des données de test."""
        dates = pd.date_range(start='2024-01-01', periods=500, freq='1H')
        
        np.random.seed(42)
        
        # Créer différents régimes
        regimes = []
        prices = []
        base_price = 1.1000
        
        for i in range(500):
            if i < 125:  # Trending Up
                regime = 0
                price = base_price * (1 + i * 0.0001)
            elif i < 250:  # Trending Down
                regime = 1
                price = base_price * (1 - (i - 125) * 0.0001)
            elif i < 375:  # Ranging
                regime = 2
                price = base_price + 0.001 * np.sin(i / 10)
            else:  # High Volatility
                regime = 3
                price = base_price + 0.01 * np.random.randn()
            
            regimes.append(regime)
            prices.append(price)
        
        df = pd.DataFrame(index=dates)
        df['close'] = prices
        df['open'] = df['close'].shift(1).fillna(df['close'].iloc[0])
        df['high'] = df[['open', 'close']].max(axis=1) * 1.001
        df['low'] = df[['open', 'close']].min(axis=1) * 0.999
        df['volume'] = np.random.randint(1000, 10000, 500)
        
        return df
    
    def test_full_workflow(self, sample_data):
        """Test workflow complet."""
        detector = RegimeDetector(n_regimes=4)
        
        # 1. Fit
        detector.fit(sample_data)
        assert detector.is_fitted
        
        # 2. Predict
        regimes = detector.predict_regime(sample_data)
        assert len(regimes) > 0
        
        # 3. Current regime
        current = detector.predict_current_regime(sample_data)
        assert 0 <= current < 4
        
        # 4. Statistics
        stats = detector.get_regime_statistics(sample_data)
        assert 'current_regime' in stats
        
        # 5. Adaptation
        adapted = detector.adapt_strategy_parameters(current, {'min_confidence': 0.6})
        assert 'min_confidence' in adapted
        
        # 6. Should trade
        should_trade = detector.should_trade_in_regime(current, 'intraday')
        assert isinstance(should_trade, bool)