5d6b2021f8
- Agent identity injection: prepend core-personality to all agent prompts so agents dream as me, not as generic graph workers. Include instructions to walk the graph and connect new nodes to core concepts. - Parallel agent scheduling: sequential within type, parallel across types. Different agent types (linker, organize, replay) run concurrently. - Linker prompt: graph walking instead of keyword search for connections. "Explore the local topology and walk the graph until you find the best connections." - memory-search fixes: format_results no longer truncates to 5 results, pipeline default raised to 50, returned file cleared on compaction, --seen and --seen-full merged, compaction timestamp in --seen output, max_entries=3 per prompt for steady memory drip. - Stemmer optimization: strip_suffix now works in-place on a single String buffer instead of allocating 18 new Strings per word. Note for future: reversed-suffix trie for O(suffix_len) instead of O(n_rules). - Transcript: add compaction_timestamp() for --seen display. - Agent budget configurable (default 4000 from config). Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
140 lines
4.7 KiB
Rust
140 lines
4.7 KiB
Rust
// Text similarity: Porter stemming + BM25
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//
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// Used for interference detection (similar content, different communities)
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// and schema fit scoring. Intentionally simple — ~100 lines, no
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// external dependencies.
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use std::collections::HashMap;
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/// Minimal Porter stemmer — handles the most common English suffixes.
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/// Not linguistically complete but good enough for similarity matching.
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/// Single allocation: works on one String buffer throughout.
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///
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/// If this is still a hot spot, replace the sequential suffix checks
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/// with a reversed-suffix trie: single pass from the end of the word
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/// matches the longest applicable suffix in O(suffix_len) instead of
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/// O(n_rules).
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pub fn stem(word: &str) -> String {
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let mut w = word.to_lowercase();
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if w.len() <= 3 { return w; }
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strip_suffix_inplace(&mut w, "ation", "ate");
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strip_suffix_inplace(&mut w, "ness", "");
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strip_suffix_inplace(&mut w, "ment", "");
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strip_suffix_inplace(&mut w, "ting", "t");
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strip_suffix_inplace(&mut w, "ling", "l");
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strip_suffix_inplace(&mut w, "ring", "r");
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strip_suffix_inplace(&mut w, "ning", "n");
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strip_suffix_inplace(&mut w, "ding", "d");
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strip_suffix_inplace(&mut w, "ping", "p");
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strip_suffix_inplace(&mut w, "ging", "g");
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strip_suffix_inplace(&mut w, "ying", "y");
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strip_suffix_inplace(&mut w, "ied", "y");
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strip_suffix_inplace(&mut w, "ies", "y");
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strip_suffix_inplace(&mut w, "ing", "");
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strip_suffix_inplace(&mut w, "ed", "");
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strip_suffix_inplace(&mut w, "ly", "");
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strip_suffix_inplace(&mut w, "er", "");
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strip_suffix_inplace(&mut w, "al", "");
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strip_suffix_inplace(&mut w, "s", "");
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w
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}
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fn strip_suffix_inplace(word: &mut String, suffix: &str, replacement: &str) {
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if word.len() > suffix.len() + 2 && word.ends_with(suffix) {
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word.truncate(word.len() - suffix.len());
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word.push_str(replacement);
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}
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}
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/// Tokenize and stem a text into a term frequency map
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pub fn term_frequencies(text: &str) -> HashMap<String, u32> {
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let mut tf = HashMap::new();
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for word in text.split(|c: char| !c.is_alphanumeric()) {
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if word.len() > 2 {
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let stemmed = stem(word);
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*tf.entry(stemmed).or_default() += 1;
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}
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}
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tf
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}
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/// Cosine similarity between two documents using stemmed term frequencies.
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/// Returns 0.0 for disjoint vocabularies, 1.0 for identical content.
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pub fn cosine_similarity(doc_a: &str, doc_b: &str) -> f32 {
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let tf_a = term_frequencies(doc_a);
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let tf_b = term_frequencies(doc_b);
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if tf_a.is_empty() || tf_b.is_empty() {
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return 0.0;
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}
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// Dot product
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let mut dot = 0.0f64;
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for (term, &freq_a) in &tf_a {
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if let Some(&freq_b) = tf_b.get(term) {
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dot += freq_a as f64 * freq_b as f64;
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}
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}
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// Magnitudes
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let mag_a: f64 = tf_a.values().map(|&f| (f as f64).powi(2)).sum::<f64>().sqrt();
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let mag_b: f64 = tf_b.values().map(|&f| (f as f64).powi(2)).sum::<f64>().sqrt();
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if mag_a < 1e-10 || mag_b < 1e-10 {
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return 0.0;
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}
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(dot / (mag_a * mag_b)) as f32
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}
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/// Compute pairwise similarity for a set of documents.
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/// Returns pairs with similarity above threshold.
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pub fn pairwise_similar(
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docs: &[(String, String)], // (key, content)
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threshold: f32,
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) -> Vec<(String, String, f32)> {
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let mut results = Vec::new();
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for i in 0..docs.len() {
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for j in (i + 1)..docs.len() {
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let sim = cosine_similarity(&docs[i].1, &docs[j].1);
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if sim >= threshold {
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results.push((docs[i].0.clone(), docs[j].0.clone(), sim));
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}
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}
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}
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results.sort_by(|a, b| b.2.total_cmp(&a.2));
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results
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}
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#[cfg(test)]
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mod tests {
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use super::*;
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#[test]
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fn test_stem() {
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assert_eq!(stem("running"), "runn"); // -ning → n
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assert_eq!(stem("talking"), "talk"); // not matched by specific consonant rules
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assert_eq!(stem("slowly"), "slow"); // -ly
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// The stemmer is minimal — it doesn't need to be perfect,
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// just consistent enough that related words collide.
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assert_eq!(stem("observations"), "observation"); // -s stripped, -ation stays (word too short after)
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}
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#[test]
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fn test_cosine_identical() {
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let text = "the quick brown fox jumps over the lazy dog";
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let sim = cosine_similarity(text, text);
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assert!((sim - 1.0).abs() < 0.01, "identical docs should have sim ~1.0, got {}", sim);
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}
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#[test]
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fn test_cosine_different() {
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let a = "kernel filesystem transaction restart handling";
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let b = "cooking recipe chocolate cake baking temperature";
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let sim = cosine_similarity(a, b);
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assert!(sim < 0.1, "unrelated docs should have low sim, got {}", sim);
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}
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}
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