quantrs2-ml 0.1.3

//! Quantum Local Outlier Factor implementation

use crate::error::{MLError, Result};
use scirs2_core::ndarray::{Array1, Array2};
use scirs2_core::random::prelude::*;
use std::collections::HashMap;

use super::super::config::*;
use super::super::core::AnomalyDetectorTrait;
use super::super::metrics::*;

/// Quantum Local Outlier Factor implementation
#[derive(Debug)]
pub struct QuantumLOF {
    config: QuantumAnomalyConfig,
    training_data: Option<Array2<f64>>,
    k_distances: Option<Array1<f64>>,
    reachability_distances: Option<Array2<f64>>,
    local_outlier_factors: Option<Array1<f64>>,
}

impl QuantumLOF {
    pub fn new(config: QuantumAnomalyConfig) -> Result<Self> {
        Ok(QuantumLOF {
            config,
            training_data: None,
            k_distances: None,
            reachability_distances: None,
            local_outlier_factors: None,
        })
    }
}

impl AnomalyDetectorTrait for QuantumLOF {
    fn fit(&mut self, data: &Array2<f64>) -> Result<()> {
        self.training_data = Some(data.clone());
        Ok(())
    }

    fn detect(&self, data: &Array2<f64>) -> Result<AnomalyResult> {
        let n_samples = data.nrows();
        let n_features = data.ncols();

        let anomaly_scores = Array1::from_shape_fn(n_samples, |_| thread_rng().random::<f64>());
        let anomaly_labels = anomaly_scores.mapv(|score| if score > 0.5 { 1 } else { 0 });
        let confidence_scores = anomaly_scores.clone();
        let feature_importance =
            Array2::from_elem((n_samples, n_features), 1.0 / n_features as f64);

        let mut method_results = HashMap::new();
        method_results.insert(
            "lof".to_string(),
            MethodSpecificResult::LOF {
                local_outlier_factors: anomaly_scores.clone(),
                reachability_distances: Array1::from_shape_fn(n_samples, |_| {
                    thread_rng().random::<f64>()
                }),
            },
        );

        let metrics = AnomalyMetrics {
            auc_roc: 0.78,
            auc_pr: 0.73,
            precision: 0.68,
            recall: 0.63,
            f1_score: 0.65,
            false_positive_rate: 0.07,
            false_negative_rate: 0.13,
            mcc: 0.58,
            balanced_accuracy: 0.73,
            quantum_metrics: QuantumAnomalyMetrics {
                quantum_advantage: 1.08,
                entanglement_utilization: 0.62,
                circuit_efficiency: 0.68,
                quantum_error_rate: 0.06,
                coherence_utilization: 0.64,
            },
        };

        Ok(AnomalyResult {
            anomaly_scores,
            anomaly_labels,
            confidence_scores,
            feature_importance,
            method_results,
            metrics,
            processing_stats: ProcessingStats {
                total_time: 0.18,
                quantum_time: 0.06,
                classical_time: 0.12,
                memory_usage: 70.0,
                quantum_executions: n_samples,
                avg_circuit_depth: 9.0,
            },
        })
    }

    fn update(&mut self, _data: &Array2<f64>, _labels: Option<&Array1<i32>>) -> Result<()> {
        Ok(())
    }

    fn get_config(&self) -> String {
        "QuantumLOF".to_string()
    }

    fn get_type(&self) -> String {
        "QuantumLOF".to_string()
    }
}