Skip to main content

llm_kernel/graph/
backend.rs

1//! Backend-agnostic graph trait and SQLite implementation.
2//!
3//! [`GraphBackend`] is a sync, object-safe trait covering the primitive node/edge
4//! operations every graph backend must support. It deliberately exposes **no
5//! `rusqlite` types**, so a PostgreSQL or in-memory backend can implement it
6//! (see the v0.8.0 roadmap). [`SqliteGraph`] is the bundled implementation: it
7//! wraps a single mutex-guarded connection and delegates to the existing
8//! free-function graph API in [`crate::graph`].
9//!
10//! The existing free functions (`upsert_node(&conn, …)`, `search_nodes(&conn, …)`,
11//! …) are unchanged — callers that already own a `Connection` keep using them.
12//! [`SqliteGraph`] simply packages a connection behind the trait for users who
13//! want backend-agnostic graph access.
14
15use std::path::Path;
16use std::sync::Mutex;
17
18use rusqlite::Connection;
19
20use crate::error::Result;
21use crate::graph::recall::smart_recall;
22use crate::graph::schema::{init_graph_schema, migrate_graph, schema_version};
23use crate::graph::search::{query_nodes, search_nodes};
24use crate::graph::store::{
25    append_edge, delete_edge, delete_node, edges_for_node, remove_edges_for_node, upsert_node,
26};
27use crate::graph::traversal::related_nodes;
28use crate::graph::types::{EdgeDirection, GraphEdge, GraphNode, ScoredNode};
29
30/// Sync, object-safe trait for graph backends.
31///
32/// Methods cover node/edge CRUD, FTS search, filtered query, and schema
33/// migration. No method exposes `rusqlite` types, so the trait is implementable
34/// by any backend. `dyn GraphBackend` is usable.
35pub trait GraphBackend: Send + Sync {
36    /// Insert or replace a node.
37    fn upsert_node(&self, node: &GraphNode) -> Result<()>;
38    /// Read a single node by ID (`None` if absent).
39    fn read_node(&self, id: &str) -> Result<Option<GraphNode>>;
40    /// Delete a node by ID. Returns `true` if a row was removed.
41    fn delete_node(&self, id: &str) -> Result<bool>;
42    /// FTS5 full-text search, ranked by importance DESC.
43    fn search_nodes(&self, query: &str, limit: usize) -> Result<Vec<GraphNode>>;
44    /// Dynamic filter by tag / node_type / project.
45    #[allow(clippy::too_many_arguments)]
46    fn query_nodes(
47        &self,
48        tag: Option<&str>,
49        node_type: Option<&str>,
50        project: Option<&str>,
51        limit: usize,
52    ) -> Result<Vec<GraphNode>>;
53    /// Composite recall — rank nodes by recency, importance, access, FTS, and
54    /// graph boost. The canonical high-level read path for "what's relevant".
55    fn smart_recall(
56        &self,
57        project: Option<&str>,
58        hint: Option<&str>,
59        limit: usize,
60    ) -> Result<Vec<ScoredNode>>;
61    /// BFS-traverse up to `depth` hops from `start_id`, returning related node
62    /// IDs (excluding the start).
63    fn related_nodes(&self, start_id: &str, depth: usize) -> Result<Vec<String>>;
64    /// Append an edge (duplicates by edge ID are ignored).
65    fn append_edge(&self, edge: &GraphEdge) -> Result<()>;
66    /// Append many edges in one call.
67    ///
68    /// Duplicates by edge ID *or* by the `(source, target, relation)` unique
69    /// index are ignored. The default implementation loops [`Self::append_edge`];
70    /// backends with a batch path override it for throughput (citation graphs
71    /// built during indexing can reach hundreds of thousands of edges).
72    fn append_edges(&self, edges: &[GraphEdge]) -> Result<()> {
73        for edge in edges {
74            self.append_edge(edge)?;
75        }
76        Ok(())
77    }
78    /// Read edges touching `node_id`, filtered by direction and an optional
79    /// relation. The default implementation reads both directions via
80    /// [`Self::edges_for_node`] and filters in Rust; backends with directional
81    /// indexes override for efficiency.
82    fn edges_for_node_dir(
83        &self,
84        node_id: &str,
85        dir: EdgeDirection,
86        relation: Option<&str>,
87    ) -> Result<Vec<GraphEdge>> {
88        Ok(self
89            .edges_for_node(node_id)?
90            .into_iter()
91            .filter(|e| match dir {
92                EdgeDirection::Out => e.source == node_id,
93                EdgeDirection::In => e.target == node_id,
94                EdgeDirection::Both => true,
95            })
96            .filter(|e| relation.is_none_or(|r| e.relation == r))
97            .collect())
98    }
99    /// 1-hop neighbors of `seed_ids` (weighted sum), restricted by direction
100    /// and an optional relation. Seed nodes are excluded. The default
101    /// implementation walks each seed via [`Self::edges_for_node_dir`].
102    fn neighbors_weighted(
103        &self,
104        seed_ids: &[String],
105        dir: EdgeDirection,
106        relation: Option<&str>,
107    ) -> Result<Vec<(String, f64)>> {
108        let mut weights: std::collections::HashMap<String, f64> = std::collections::HashMap::new();
109        let seed_set: std::collections::HashSet<&str> =
110            seed_ids.iter().map(String::as_str).collect();
111        for seed in seed_ids {
112            for e in self.edges_for_node_dir(seed, dir, relation)? {
113                let other = if e.source == *seed {
114                    &e.target
115                } else {
116                    &e.source
117                };
118                if !seed_set.contains(other.as_str()) {
119                    *weights.entry(other.clone()).or_default() += e.weight;
120                }
121            }
122        }
123        let mut result: Vec<(String, f64)> = weights.into_iter().collect();
124        result.sort_by(|a, b| b.1.partial_cmp(&a.1).unwrap_or(std::cmp::Ordering::Equal));
125        Ok(result)
126    }
127    /// BFS-traverse up to `depth` hops from `start_id`, returning related node
128    /// IDs (excluding the start), restricted by direction and an optional
129    /// relation. The default implementation hops via [`Self::neighbors_weighted`].
130    fn related_nodes_filtered(
131        &self,
132        start_id: &str,
133        depth: usize,
134        dir: EdgeDirection,
135        relation: Option<&str>,
136    ) -> Result<Vec<String>> {
137        if depth == 0 {
138            return Ok(vec![]);
139        }
140        let mut visited: std::collections::HashSet<String> = std::collections::HashSet::new();
141        visited.insert(start_id.to_string());
142        let mut frontier: Vec<String> = vec![start_id.to_string()];
143        for _ in 0..depth {
144            let mut next: Vec<String> = Vec::new();
145            for node in &frontier {
146                for (nb, _) in self.neighbors_weighted(std::slice::from_ref(node), dir, relation)? {
147                    if visited.insert(nb.clone()) {
148                        next.push(nb);
149                    }
150                }
151            }
152            if next.is_empty() {
153                break;
154            }
155            frontier = next;
156        }
157        visited.remove(start_id);
158        Ok(visited.into_iter().collect())
159    }
160    /// Read edges where the given node is source or target.
161    fn edges_for_node(&self, node_id: &str) -> Result<Vec<GraphEdge>>;
162    /// Delete an edge by ID. Returns `true` if a row was removed.
163    fn delete_edge(&self, id: &str) -> Result<bool>;
164    /// Remove every edge connected to a node.
165    fn remove_edges_for_node(&self, node_id: &str) -> Result<()>;
166
167    /// Recorded schema version for this backend.
168    fn current_version(&self) -> Result<u32>;
169    /// Apply pending migrations up to the backend's latest schema version.
170    /// Returns the resulting version.
171    fn migrate(&self) -> Result<u32>;
172}
173
174/// SQLite-backed [`GraphBackend`] over one mutex-guarded connection.
175///
176/// Opening applies the schema and runs any pending migrations, so a database
177/// created by an older `llm-kernel` is upgraded transparently on open.
178pub struct SqliteGraph {
179    conn: Mutex<Connection>,
180}
181
182impl SqliteGraph {
183    /// Open (or create) a graph database at `path`, applying schema + migrations.
184    pub fn open(path: impl AsRef<Path>) -> Result<Self> {
185        let conn = open_with_schema(path.as_ref())?;
186        Ok(Self {
187            conn: Mutex::new(conn),
188        })
189    }
190
191    /// Create an in-memory graph (useful for tests and ephemeral stores).
192    pub fn open_in_memory() -> Result<Self> {
193        let conn = Connection::open_in_memory().map_err(store_err)?;
194        init_graph_schema(&conn)?;
195        let current = schema_version(&conn)?;
196        migrate_graph(&conn, current)?;
197        Ok(Self {
198            conn: Mutex::new(conn),
199        })
200    }
201
202    /// Lock helper: recover the guard even if a previous holder panicked.
203    fn lock(&self) -> std::sync::MutexGuard<'_, Connection> {
204        self.conn.lock().unwrap_or_else(|e| e.into_inner())
205    }
206}
207
208/// Open a file-backed connection, apply the schema, then run pending migrations.
209fn open_with_schema(path: &Path) -> Result<Connection> {
210    let conn = Connection::open(path).map_err(store_err)?;
211    init_graph_schema(&conn)?;
212    let current = schema_version(&conn)?;
213    migrate_graph(&conn, current)?;
214    Ok(conn)
215}
216
217fn store_err(e: rusqlite::Error) -> crate::error::KernelError {
218    crate::error::KernelError::Store(e.to_string())
219}
220
221impl GraphBackend for SqliteGraph {
222    fn upsert_node(&self, node: &GraphNode) -> Result<()> {
223        let c = self.lock();
224        upsert_node(&c, node)
225    }
226
227    fn read_node(&self, id: &str) -> Result<Option<GraphNode>> {
228        let c = self.lock();
229        crate::graph::store::read_node(&c, id)
230    }
231
232    fn delete_node(&self, id: &str) -> Result<bool> {
233        let c = self.lock();
234        delete_node(&c, id)
235    }
236
237    fn search_nodes(&self, query: &str, limit: usize) -> Result<Vec<GraphNode>> {
238        let c = self.lock();
239        search_nodes(&c, query, limit)
240    }
241
242    fn query_nodes(
243        &self,
244        tag: Option<&str>,
245        node_type: Option<&str>,
246        project: Option<&str>,
247        limit: usize,
248    ) -> Result<Vec<GraphNode>> {
249        let c = self.lock();
250        query_nodes(&c, tag, node_type, project, limit)
251    }
252
253    fn smart_recall(
254        &self,
255        project: Option<&str>,
256        hint: Option<&str>,
257        limit: usize,
258    ) -> Result<Vec<ScoredNode>> {
259        let c = self.lock();
260        smart_recall(&c, project, hint, limit)
261    }
262
263    fn related_nodes(&self, start_id: &str, depth: usize) -> Result<Vec<String>> {
264        let c = self.lock();
265        Ok(related_nodes(&c, start_id, depth))
266    }
267
268    fn append_edge(&self, edge: &GraphEdge) -> Result<()> {
269        let c = self.lock();
270        append_edge(&c, edge)
271    }
272
273    fn append_edges(&self, edges: &[GraphEdge]) -> Result<()> {
274        let c = self.lock();
275        crate::graph::store::append_edges(&c, edges)
276    }
277
278    fn edges_for_node_dir(
279        &self,
280        node_id: &str,
281        dir: EdgeDirection,
282        relation: Option<&str>,
283    ) -> Result<Vec<GraphEdge>> {
284        let c = self.lock();
285        crate::graph::store::edges_for_node_dir(&c, node_id, dir, relation)
286    }
287
288    fn neighbors_weighted(
289        &self,
290        seed_ids: &[String],
291        dir: EdgeDirection,
292        relation: Option<&str>,
293    ) -> Result<Vec<(String, f64)>> {
294        let c = self.lock();
295        Ok(crate::graph::traversal::neighbors_weighted(
296            &c, seed_ids, dir, relation,
297        ))
298    }
299
300    fn edges_for_node(&self, node_id: &str) -> Result<Vec<GraphEdge>> {
301        let c = self.lock();
302        edges_for_node(&c, node_id)
303    }
304
305    fn delete_edge(&self, id: &str) -> Result<bool> {
306        let c = self.lock();
307        delete_edge(&c, id)
308    }
309
310    fn remove_edges_for_node(&self, node_id: &str) -> Result<()> {
311        let c = self.lock();
312        remove_edges_for_node(&c, node_id)
313    }
314
315    fn current_version(&self) -> Result<u32> {
316        let c = self.lock();
317        schema_version(&c)
318    }
319
320    fn migrate(&self) -> Result<u32> {
321        let c = self.lock();
322        let current = schema_version(&c)?;
323        migrate_graph(&c, current)
324    }
325}
326
327/// CJK-aware convenience methods (available with the `graph-cjk` feature).
328#[cfg(feature = "graph-cjk")]
329impl SqliteGraph {
330    /// CJK (or mixed) search via contiguous substring matching.
331    ///
332    /// Delegates to [`crate::graph::cjk::search_nodes_cjk`]; see its docs for
333    /// the matching semantics.
334    pub fn search_nodes_cjk(&self, query: &str, limit: usize) -> Result<Vec<GraphNode>> {
335        let c = self.lock();
336        crate::graph::cjk::search_nodes_cjk(&c, query, limit)
337    }
338
339    /// Segment a string for CJK tokenization (exposed for callers that want to
340    /// pre-process queries or inspect tokenization).
341    pub fn segment_cjk(text: &str) -> String {
342        crate::graph::cjk::segment_cjk(text)
343    }
344}
345
346#[cfg(test)]
347mod tests {
348    use super::*;
349
350    fn sample_node(id: &str) -> GraphNode {
351        GraphNode {
352            id: id.to_string(),
353            node_type: "concept".to_string(),
354            title: format!("Node {id}"),
355            body: "graph backend test body".to_string(),
356            tags: vec!["backend".to_string()],
357            projects: vec![],
358            agents: vec![],
359            created: "2026-01-01T00:00:00Z".to_string(),
360            updated: "2026-01-01T00:00:00Z".to_string(),
361            importance: 0.5,
362            access_count: 0,
363            accessed_at: String::new(),
364        }
365    }
366
367    /// AC4: a node round-trips through the trait, and the trait is usable as
368    /// `dyn GraphBackend` (object-safety) with no `rusqlite` in the surface.
369    #[test]
370    fn dyn_backend_round_trips_node() {
371        let backend: Box<dyn GraphBackend> = Box::new(SqliteGraph::open_in_memory().unwrap());
372        assert!(backend.read_node("n1").unwrap().is_none());
373        backend.upsert_node(&sample_node("n1")).unwrap();
374        let loaded = backend.read_node("n1").unwrap().unwrap();
375        assert_eq!(loaded.title, "Node n1");
376        assert_eq!(loaded.tags, vec!["backend".to_string()]);
377        assert!(backend.delete_node("n1").unwrap());
378        assert!(backend.read_node("n1").unwrap().is_none());
379    }
380
381    /// AC5: a fresh backend reports the current schema version.
382    #[test]
383    fn fresh_backend_reports_current_version() {
384        let backend = SqliteGraph::open_in_memory().unwrap();
385        assert_eq!(
386            backend.current_version().unwrap(),
387            crate::graph::schema::GRAPH_SCHEMA_VERSION
388        );
389    }
390
391    /// AC5: search through the trait finds an inserted node by title.
392    #[test]
393    fn backend_search_finds_node() {
394        let backend = SqliteGraph::open_in_memory().unwrap();
395        backend.upsert_node(&sample_node("rust")).unwrap();
396        let hits = backend.search_nodes("graph backend", 10).unwrap();
397        assert_eq!(hits.len(), 1);
398        assert_eq!(hits[0].id, "rust");
399    }
400
401    /// The composite recall path is reachable through the trait.
402    #[test]
403    fn backend_smart_recall_finds_relevant() {
404        let backend = SqliteGraph::open_in_memory().unwrap();
405        let mut n = sample_node("rust");
406        n.body = "rust ownership borrow checker".to_string();
407        backend.upsert_node(&n).unwrap();
408        let recalled = backend.smart_recall(None, Some("ownership"), 5).unwrap();
409        assert!(recalled.iter().any(|s| s.node.id == "rust"));
410    }
411
412    /// The composite traversal path is reachable through the trait.
413    #[test]
414    fn backend_related_nodes_traverses_edges() {
415        let backend = SqliteGraph::open_in_memory().unwrap();
416        backend.upsert_node(&sample_node("a")).unwrap();
417        backend.upsert_node(&sample_node("b")).unwrap();
418        backend
419            .append_edge(&GraphEdge {
420                id: "e1".into(),
421                source: "a".into(),
422                target: "b".into(),
423                relation: "related".into(),
424                weight: 1.0,
425                ts: "2026-01-01T00:00:00Z".into(),
426            })
427            .unwrap();
428        let related = backend.related_nodes("a", 2).unwrap();
429        assert!(related.contains(&"b".to_string()));
430    }
431
432    /// Batch edge append + directional/relation-filtered lookups through the
433    /// trait (object-safe path), including the BFS `related_nodes_filtered`.
434    #[test]
435    fn dyn_backend_batch_and_filtered_edges() {
436        let backend: Box<dyn GraphBackend> = Box::new(SqliteGraph::open_in_memory().unwrap());
437        backend
438            .append_edges(&[
439                GraphEdge {
440                    id: "e1".into(),
441                    source: "a".into(),
442                    target: "b".into(),
443                    relation: "cites".into(),
444                    weight: 1.0,
445                    ts: "t".into(),
446                },
447                GraphEdge {
448                    id: "e2".into(),
449                    source: "c".into(),
450                    target: "a".into(),
451                    relation: "cites".into(),
452                    weight: 1.0,
453                    ts: "t".into(),
454                },
455                GraphEdge {
456                    id: "e3".into(),
457                    source: "a".into(),
458                    target: "d".into(),
459                    relation: "see_also".into(),
460                    weight: 1.0,
461                    ts: "t".into(),
462                },
463            ])
464            .unwrap();
465        // Out-edges of `a`: b, d.
466        assert_eq!(
467            backend
468                .edges_for_node_dir("a", EdgeDirection::Out, None)
469                .unwrap()
470                .len(),
471            2
472        );
473        // Out-only neighbors of `a` filtered to `cites`: only b (not c, which is in-edge).
474        let nbs = backend
475            .neighbors_weighted(&["a".to_string()], EdgeDirection::Out, Some("cites"))
476            .unwrap();
477        let ids: Vec<&str> = nbs.iter().map(|(id, _)| id.as_str()).collect();
478        assert_eq!(ids, vec!["b"]);
479        // BFS out-only depth 2 from `a`: reaches b and d.
480        let rel = backend
481            .related_nodes_filtered("a", 2, EdgeDirection::Out, None)
482            .unwrap();
483        assert!(rel.contains(&"b".to_string()));
484        assert!(rel.contains(&"d".to_string()));
485    }
486}