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mentedb_index/
manager.rs

1//! Composite index manager that owns and coordinates all index types.
2
3use std::collections::{HashMap, HashSet};
4use std::path::Path;
5
6use mentedb_core::MemoryNode;
7use mentedb_core::error::MenteResult;
8use mentedb_core::types::{MemoryId, Timestamp};
9
10use crate::bitmap::BitmapIndex;
11use crate::bm25::Bm25Index;
12use crate::hnsw::{HnswConfig, HnswIndex};
13use crate::salience::SalienceIndex;
14use crate::temporal::TemporalIndex;
15
16/// Configuration for the composite index manager.
17#[derive(Default)]
18pub struct IndexManagerConfig {
19    /// HNSW configuration parameters.
20    pub hnsw: HnswConfig,
21}
22
23/// Owns all index types and provides unified indexing and hybrid search.
24pub struct IndexManager {
25    /// Vector similarity index.
26    pub hnsw: HnswIndex,
27    /// BM25 full-text index for keyword search.
28    pub bm25: Bm25Index,
29    /// Tag and attribute bitmap index.
30    pub bitmap: BitmapIndex,
31    /// Timestamp range index.
32    pub temporal: TemporalIndex,
33    /// Importance score index.
34    pub salience: SalienceIndex,
35}
36
37impl IndexManager {
38    /// Create a new index manager with the given configuration.
39    pub fn new(config: IndexManagerConfig) -> Self {
40        Self {
41            hnsw: HnswIndex::new(config.hnsw),
42            bm25: Bm25Index::new(),
43            bitmap: BitmapIndex::new(),
44            temporal: TemporalIndex::new(),
45            salience: SalienceIndex::new(),
46        }
47    }
48
49    /// Save all indexes to the given directory (bincode format).
50    pub fn save(&self, dir: &Path) -> MenteResult<()> {
51        std::fs::create_dir_all(dir)?;
52        self.hnsw.save(&dir.join("hnsw.bin"))?;
53        self.bm25.save(&dir.join("bm25.bin"))?;
54        self.bitmap.save(&dir.join("bitmap.bin"))?;
55        self.temporal.save(&dir.join("temporal.bin"))?;
56        self.salience.save(&dir.join("salience.bin"))?;
57        Ok(())
58    }
59
60    /// Load all indexes from the given directory. Tries `.bin` first, falls back to `.json`.
61    pub fn load(dir: &Path) -> MenteResult<Self> {
62        let hnsw_path = Self::resolve_path(dir, "hnsw");
63        let hnsw = HnswIndex::load(&hnsw_path, HnswConfig::default().ef_search)?;
64
65        let bm25_bin = dir.join("bm25.bin");
66        let bm25_json = dir.join("bm25.json");
67        let bm25 = if bm25_bin.exists() {
68            Bm25Index::load(&bm25_bin)?
69        } else if bm25_json.exists() {
70            Bm25Index::load(&bm25_json)?
71        } else {
72            Bm25Index::new()
73        };
74
75        let bitmap = BitmapIndex::load(&Self::resolve_path(dir, "bitmap"))?;
76        let temporal = TemporalIndex::load(&Self::resolve_path(dir, "temporal"))?;
77        let salience = SalienceIndex::load(&Self::resolve_path(dir, "salience"))?;
78        Ok(Self {
79            hnsw,
80            bm25,
81            bitmap,
82            temporal,
83            salience,
84        })
85    }
86
87    /// Resolve index file path: prefer `.bin`, fall back to `.json`.
88    fn resolve_path(dir: &Path, name: &str) -> std::path::PathBuf {
89        let bin = dir.join(format!("{name}.bin"));
90        if bin.exists() {
91            bin
92        } else {
93            dir.join(format!("{name}.json"))
94        }
95    }
96
97    /// Index a memory node across all indexes.
98    pub fn index_memory(&self, node: &MemoryNode) {
99        // Vector index
100        if !node.embedding.is_empty() {
101            let _ = self.hnsw.insert(node.id, &node.embedding);
102        }
103
104        // BM25 full-text index
105        if !node.content.is_empty() {
106            self.bm25.insert(node.id, &node.content);
107        }
108
109        // Tag bitmap index
110        for tag in &node.tags {
111            self.bitmap.add_tag(node.id, tag);
112        }
113
114        // Temporal index
115        self.temporal.insert(node.id, node.created_at);
116
117        // Salience index
118        self.salience.insert(node.id, node.salience);
119    }
120
121    /// Remove a memory from all indexes.
122    pub fn remove_memory(&self, id: MemoryId, node: &MemoryNode) {
123        let _ = self.hnsw.remove(id);
124        self.bm25.remove(id);
125        self.bitmap.remove_all(id);
126        self.temporal.remove(id, node.created_at);
127        self.salience.remove(id, node.salience);
128    }
129
130    /// Hybrid search combining vector similarity, BM25 keyword matching,
131    /// tag filtering, time range, and salience.
132    ///
133    /// Strategy:
134    /// 1. Vector search (HNSW) for top candidates
135    /// 2. BM25 keyword search for top candidates
136    /// 3. Merge via Reciprocal Rank Fusion (RRF)
137    /// 4. Filter by tags and time range
138    /// 5. Boost by salience and recency
139    /// 6. Return top k results
140    pub fn hybrid_search(
141        &self,
142        query_embedding: &[f32],
143        tags: Option<&[&str]>,
144        time_range: Option<(Timestamp, Timestamp)>,
145        k: usize,
146    ) -> Vec<(MemoryId, f32)> {
147        self.hybrid_search_with_query(query_embedding, None, tags, time_range, k)
148    }
149
150    /// Hybrid search with an optional text query for BM25 matching.
151    ///
152    /// When `query_text` is provided, BM25 results are merged with vector
153    /// results via RRF. When None, behaves like vector-only search.
154    pub fn hybrid_search_with_query(
155        &self,
156        query_embedding: &[f32],
157        query_text: Option<&str>,
158        tags: Option<&[&str]>,
159        time_range: Option<(Timestamp, Timestamp)>,
160        k: usize,
161    ) -> Vec<(MemoryId, f32)> {
162        self.hybrid_search_with_query_mode(query_embedding, query_text, tags, false, time_range, k)
163    }
164
165    /// Hybrid search with configurable tag mode (AND vs OR).
166    pub fn hybrid_search_with_query_mode(
167        &self,
168        query_embedding: &[f32],
169        query_text: Option<&str>,
170        tags: Option<&[&str]>,
171        tags_or: bool,
172        time_range: Option<(Timestamp, Timestamp)>,
173        k: usize,
174    ) -> Vec<(MemoryId, f32)> {
175        if k == 0 {
176            return Vec::new();
177        }
178
179        // Build tag filter set (if tags are specified)
180        let tag_filter: Option<HashSet<MemoryId>> = tags.map(|t| {
181            if t.is_empty() {
182                HashSet::new()
183            } else if tags_or {
184                self.bitmap.query_tags_or(t).into_iter().collect()
185            } else {
186                self.bitmap.query_tags_and(t).into_iter().collect()
187            }
188        });
189
190        // Build time-range filter set
191        let time_filter: Option<HashSet<MemoryId>> =
192            time_range.map(|(start, end)| self.temporal.range(start, end).into_iter().collect());
193
194        // Combine filters into a single candidate set
195        let candidate_set: Option<HashSet<MemoryId>> = match (&tag_filter, &time_filter) {
196            (Some(tf), Some(trf)) => Some(tf.intersection(trf).copied().collect()),
197            (Some(tf), None) => Some(tf.clone()),
198            (None, Some(trf)) => Some(trf.clone()),
199            (None, None) => None,
200        };
201
202        // Pre-filtered path: when we have a candidate set and it's reasonably sized,
203        // do brute-force search directly over the candidates instead of global search + post-filter.
204        // This is critical for OR-tag queries with many tags where global top-k misses most matches.
205        let use_prefilter = candidate_set.as_ref().is_some_and(|cs| {
206            let cs_len = cs.len();
207            // Use pre-filter when candidate set is non-trivial but manageable for brute-force
208            // (up to 500K is fine — brute-force cosine on 384-dim vectors is fast)
209            cs_len > 0 && cs_len <= 500_000
210        });
211
212        let fetch_k = k * 4;
213        let rrf_k: f32 = 60.0;
214
215        let (vector_candidates, bm25_candidates) = if use_prefilter {
216            let cs = candidate_set.as_ref().unwrap();
217            let vc = self.hnsw.search_filtered(query_embedding, cs, fetch_k);
218            let bc = match query_text {
219                Some(qt) if !self.bm25.is_empty() => self.bm25.search_filtered(qt, fetch_k, cs),
220                _ => Vec::new(),
221            };
222            (vc, bc)
223        } else {
224            let vc = self.hnsw.search(query_embedding, fetch_k);
225            let bc = match query_text {
226                Some(qt) if !self.bm25.is_empty() => self.bm25.search(qt, fetch_k),
227                _ => Vec::new(),
228            };
229            (vc, bc)
230        };
231
232        if vector_candidates.is_empty() && bm25_candidates.is_empty() {
233            return Vec::new();
234        }
235
236        // Merge via RRF
237        let mut rrf_scores: HashMap<MemoryId, f32> = HashMap::new();
238
239        for (rank, (id, _)) in vector_candidates.iter().enumerate() {
240            *rrf_scores.entry(*id).or_insert(0.0) += 1.0 / (rrf_k + rank as f32);
241        }
242        for (rank, (id, _)) in bm25_candidates.iter().enumerate() {
243            *rrf_scores.entry(*id).or_insert(0.0) += 1.0 / (rrf_k + rank as f32);
244        }
245
246        // Post-filter only needed when NOT using pre-filter path
247        let mut scored: Vec<(MemoryId, f32)> = rrf_scores
248            .into_iter()
249            .filter(|(id, _)| {
250                if !use_prefilter {
251                    if let Some(ref tf) = tag_filter
252                        && !tf.contains(id)
253                    {
254                        return false;
255                    }
256                    if let Some(ref trf) = time_filter
257                        && !trf.contains(id)
258                    {
259                        return false;
260                    }
261                }
262                true
263            })
264            .map(|(id, rrf_score)| {
265                let salience = self.salience.get_salience(id).unwrap_or(0.5);
266                let recency = 0.5f32;
267
268                let combined = rrf_score * 0.7 + salience * 0.05 + recency * 0.02;
269                (id, combined)
270            })
271            .collect();
272
273        scored.sort_unstable_by(|a, b| b.1.partial_cmp(&a.1).unwrap_or(std::cmp::Ordering::Equal));
274        scored.truncate(k);
275        scored
276    }
277}
278
279impl Default for IndexManager {
280    fn default() -> Self {
281        Self::new(IndexManagerConfig::default())
282    }
283}
284
285#[cfg(test)]
286mod tests {
287    use super::*;
288    use mentedb_core::memory::MemoryType;
289    use mentedb_core::types::AgentId;
290
291    fn make_node(
292        embedding: Vec<f32>,
293        tags: Vec<String>,
294        salience: f32,
295        created_at: u64,
296    ) -> MemoryNode {
297        let mut node = MemoryNode::new(
298            AgentId::new(),
299            MemoryType::Episodic,
300            "test".into(),
301            embedding,
302        );
303        node.tags = tags;
304        node.salience = salience;
305        node.created_at = created_at;
306        node
307    }
308
309    #[test]
310    fn test_index_and_search() {
311        let mgr = IndexManager::default();
312        let node = make_node(vec![1.0, 0.0, 0.0, 0.0], vec!["test".into()], 0.8, 1000);
313        mgr.index_memory(&node);
314
315        let results = mgr.hybrid_search(&[1.0, 0.0, 0.0, 0.0], None, None, 1);
316        assert_eq!(results.len(), 1);
317        assert_eq!(results[0].0, node.id);
318    }
319
320    #[test]
321    fn test_tag_filter() {
322        let mgr = IndexManager::default();
323        let a = make_node(vec![1.0, 0.0, 0.0, 0.0], vec!["alpha".into()], 0.8, 1000);
324        let b = make_node(vec![0.9, 0.1, 0.0, 0.0], vec!["beta".into()], 0.8, 1000);
325        mgr.index_memory(&a);
326        mgr.index_memory(&b);
327
328        let results = mgr.hybrid_search(&[1.0, 0.0, 0.0, 0.0], Some(&["alpha"]), None, 10);
329        assert_eq!(results.len(), 1);
330        assert_eq!(results[0].0, a.id);
331    }
332
333    #[test]
334    fn test_time_filter() {
335        let mgr = IndexManager::default();
336        let a = make_node(vec![1.0, 0.0, 0.0, 0.0], vec![], 0.8, 100);
337        let b = make_node(vec![0.9, 0.1, 0.0, 0.0], vec![], 0.8, 500);
338        mgr.index_memory(&a);
339        mgr.index_memory(&b);
340
341        let results = mgr.hybrid_search(&[1.0, 0.0, 0.0, 0.0], None, Some((400, 600)), 10);
342        assert_eq!(results.len(), 1);
343        assert_eq!(results[0].0, b.id);
344    }
345
346    #[test]
347    fn test_remove_memory() {
348        let mgr = IndexManager::default();
349        let node = make_node(vec![1.0, 0.0, 0.0, 0.0], vec!["t".into()], 0.5, 100);
350        let id = node.id;
351        mgr.index_memory(&node);
352        mgr.remove_memory(id, &node);
353
354        let results = mgr.hybrid_search(&[1.0, 0.0, 0.0, 0.0], None, None, 10);
355        assert!(results.is_empty());
356    }
357
358    #[test]
359    fn test_empty_search() {
360        let mgr = IndexManager::default();
361        let results = mgr.hybrid_search(&[1.0, 0.0], None, None, 5);
362        assert!(results.is_empty());
363    }
364}