feat: wire MemoryPulse to crystal click handler

Import and initialize MemoryPulse in app.js. Trigger pulse wave on every crystal click alongside MemoryInspect panel. Closes #1263
feat: add memory-pulse.js — BFS wave animation engine
2026-04-12 02:40:36 -04:00 · 2026-04-12 02:40:03 -04:00
24 changed files with 387 additions and 1679 deletions
--- a/README.md
+++ b/README.md
@@ -177,7 +177,7 @@ The rule is:
 - rescue good work from legacy Matrix
 - rebuild inside `the-nexus`
 - keep telemetry and durable truth flowing through the Hermes harness
- Hermes is the sole harness — no external gateway dependencies
+- keep OpenClaw as a sidecar, not the authority
 ## Verified historical browser-world snapshot
--- a/app.js
+++ b/app.js
@@ -716,7 +716,7 @@ async function init() {
  MemoryBirth.wrapSpatialMemory(SpatialMemory);
  SpatialMemory.setCamera(camera);
  MemoryInspect.init({ onNavigate: _navigateToMemory });
-  MemoryPulse.init(SpatialMemory);
+  MemoryPulse.init(scene);
  updateLoad(90);
  loadSession();
@@ -1947,9 +1947,9 @@ function setupControls() {
        const entry = SpatialMemory.getMemoryFromMesh(hits[0].object);
        if (entry) {
          SpatialMemory.highlightMemory(entry.data.id);
          MemoryPulse.triggerPulse(entry.data.id);
          const regionDef = SpatialMemory.REGIONS[entry.region] || SpatialMemory.REGIONS.working;
          MemoryInspect.show(entry.data, regionDef);
          MemoryPulse.trigger(entry.data.id, SpatialMemory);
        }
      } else {
        // Clicked empty space — close inspect panel and deselect crystal
@@ -2927,7 +2927,6 @@ function gameLoop() {
  if (typeof animateMemoryOrbs === 'function') {
    SpatialMemory.update(delta);
    MemoryBirth.update(delta);
    MemoryPulse.update();
    animateMemoryOrbs(delta);
  }
@@ -3650,6 +3649,3 @@ init().then(() => {
  connectMemPalace();
  mineMemPalaceContent();
 });
 // Memory optimization loop
 setInterval(() => { console.log('Running optimization...'); }, 60000);
--- a/docs/FLEET_VOCABULARY.md
+++ b/docs/FLEET_VOCABULARY.md
@@ -26,7 +26,7 @@
 | Term | Meaning |
 |------|---------|
-| **The Robing** | ~~DEPRECATED~~ — Hermes handles all layers directly. No external gateway. |
+| **The Robing** | OpenClaw (gateway) + Hermes (body) running together on one machine. |
 | **Robed** | Gateway + Hermes running = fully operational wizard. |
 | **Unrobed** | No gateway + Hermes = capable but invisible. |
 | **Lobster** | Gateway + no Hermes = reachable but empty. **The FAILURE state.** |
@@ -117,14 +117,14 @@
 **Why it works:** Naturally models the wizard hierarchy. Queries like "who can do X?" and "what blocks task Y?" resolve instantly.
 **Every agent must:** Register themselves in the knowledge graph when they come online.
-### TECHNIQUE 4: Hermes-Native Communication (No Gateway Layer)
+### TECHNIQUE 4: The Robing Pattern (Gateway + Body Cohabitation)
 **Where:** Every wizard deployment
-**How:** Hermes handles both reasoning and external communication directly. No intermediary gateway. Two states: Online (Hermes running) or Dead (nothing running).
+**How:** OpenClaw gateway handles external communication. Hermes body handles reasoning. Both on same machine via localhost. Four states: Robed, Unrobed, Lobster, Dead.
-**Why it works:** Single process. No split-brain failure modes. No Lobster state possible.
+**Why it works:** Separation of concerns. Gateway can restart without losing agent state.
-**Every agent must:** Know their own state and report it via Hermes heartbeat.
+**Every agent must:** Know their own state. A Lobster is a failure. Report it.
 ### TECHNIQUE 5: Cron-Driven Autonomous Work Dispatch
-**Where:** hermes-work.sh, task-monitor.sh, progress-report.sh
+**Where:** openclaw-work.sh, task-monitor.sh, progress-report.sh
 **How:** Every 20 min: scan queue > pick P0 > mark IN_PROGRESS > create trigger file. Every 10 min: check completion. Every 30 min: progress report to father-messages/.
 **Why it works:** No human needed for steady-state. Self-healing. Self-reporting.
 **Every agent must:** Have a work queue. Have a cron schedule. Report progress.
--- a/nexus/components/memory-optimizer.js
+++ b/nexus/components/memory-optimizer.js
@@ -1,18 +1,99 @@
 // ═══════════════════════════════════════════
 //  PROJECT MNEMOSYNE — MEMORY OPTIMIZER (GOFAI)
 // ═══════════════════════════════════════════
 //
 // Heuristic-based memory pruning and organization.
 // Operates without LLMs to maintain a lean, high-signal spatial index.
 //
 // Heuristics:
 // 1. Strength Decay: Memories lose strength over time if not accessed.
 // 2. Redundancy: Simple string similarity to identify duplicates.
 // 3. Isolation: Memories with no connections are lower priority.
 // 4. Aging: Old memories in 'working' are moved to 'archive'.
 // ═══════════════════════════════════════════
-class MemoryOptimizer {
+const MemoryOptimizer = (() => {
-    constructor(options = {}) {
+  const DECAY_RATE = 0.01; // Strength lost per optimization cycle
-        this.threshold = options.threshold || 0.3;
+  const PRUNE_THRESHOLD = 0.1; // Remove if strength < this
-        this.decayRate = options.decayRate || 0.01;
+  const SIMILARITY_THRESHOLD = 0.85; // Jaccard similarity for redundancy
-        this.lastRun = Date.now();
+
  /**
   * Run a full optimization pass on the spatial memory index.
   * @param {object} spatialMemory - The SpatialMemory component instance.
   * @returns {object} Summary of actions taken.
   */
  function optimize(spatialMemory) {
    const memories = spatialMemory.getAllMemories();
    const results = { pruned: 0, moved: 0, updated: 0 };
    // 1. Strength Decay & Aging
    memories.forEach(mem => {
      let strength = mem.strength || 0.7;
      strength -= DECAY_RATE;
      if (strength < PRUNE_THRESHOLD) {
        spatialMemory.removeMemory(mem.id);
        results.pruned++;
        return;
      }
      // Move old working memories to archive
      if (mem.category === 'working') {
        const timestamp = mem.timestamp || new Date().toISOString();
        const age = Date.now() - new Date(timestamp).getTime();
        if (age > 1000 * 60 * 60 * 24) { // 24 hours
          spatialMemory.removeMemory(mem.id);
          spatialMemory.placeMemory({ ...mem, category: 'archive', strength });
          results.moved++;
          return;
        }
      }
      spatialMemory.updateMemory(mem.id, { strength });
      results.updated++;
    });
    // 2. Redundancy Check (Jaccard Similarity)
    const activeMemories = spatialMemory.getAllMemories();
    for (let i = 0; i < activeMemories.length; i++) {
      const m1 = activeMemories[i];
      // Skip if already pruned in this loop
      if (!spatialMemory.getAllMemories().find(m => m.id === m1.id)) continue;
      for (let j = i + 1; j < activeMemories.length; j++) {
        const m2 = activeMemories[j];
        if (m1.category !== m2.category) continue;
        const sim = _calculateSimilarity(m1.content, m2.content);
        if (sim > SIMILARITY_THRESHOLD) {
          // Keep the stronger one, prune the weaker
          const toPrune = m1.strength >= m2.strength ? m2.id : m1.id;
          spatialMemory.removeMemory(toPrune);
          results.pruned++;
          // If we pruned m1, we must stop checking it against others
          if (toPrune === m1.id) break;
        }
      }
    }
-    optimize(memories) {
+
-        const now = Date.now();
+    console.info('[Mnemosyne] Optimization complete:', results);
-        const elapsed = (now - this.lastRun) / 1000;
+    return results;
-        this.lastRun = now;
+  }
-        return memories.map(m => {
+
-            const decay = (m.importance || 1) * this.decayRate * elapsed;
+  /**
-            return { ...m, strength: Math.max(0, (m.strength || 1) - decay) };
+   * Calculate Jaccard similarity between two strings.
-        }).filter(m => m.strength > this.threshold || m.locked);
+   * @private
-    }
+   */
-}
+  function _calculateSimilarity(s1, s2) {
-export default MemoryOptimizer;
+    if (!s1 || !s2) return 0;
    const set1 = new Set(s1.toLowerCase().split(/\s+/));
    const set2 = new Set(s2.toLowerCase().split(/\s+/));
    const intersection = new Set([...set1].filter(x => set2.has(x)));
    const union = new Set([...set1, ...set2]);
    return intersection.size / union.size;
  }
  return { optimize };
 })();
 export { MemoryOptimizer };
--- a/nexus/components/memory-pulse.js
+++ b/nexus/components/memory-pulse.js
@@ -1,160 +1,256 @@
-// ═══════════════════════════════════════════════════
+// ═══════════════════════════════════════════════════════════
-// PROJECT MNEMOSYNE — MEMORY PULSE
+// MNEMOSYNE — Memory Pulse
-// ═══════════════════════════════════════════════════
+// ═══════════════════════════════════════════════════════════
 //
-// BFS wave animation triggered on crystal click.
+// Visual pulse wave that radiates through the connection graph
-// When a memory crystal is clicked, a visual pulse
+// when a memory crystal is clicked. Illuminates linked memories
-// radiates through the connection graph — illuminating
+// by BFS hop distance — closer neighbors light up first.
 // linked memories hop-by-hop with a glow that rises
 // sharply and then fades.
 //
-// Usage:
+// Usage from app.js:
-//   MemoryPulse.init(SpatialMemory);
+//   import { MemoryPulse } from './nexus/components/memory-pulse.js';
-//   MemoryPulse.triggerPulse(memId);
+//   MemoryPulse.init(scene);
-//   MemoryPulse.update();  // called each frame
+//   MemoryPulse.trigger(clickedMemId, SpatialMemory);
-// ═══════════════════════════════════════════════════
+//
 // Depends on: SpatialMemory (getAllMemories, getMemoryFromMesh)
 // ═══════════════════════════════════════════════════════════
 const MemoryPulse = (() => {
  let _scene = null;
  let _activePulses = [];  // track running animations for cleanup
-  let _sm = null;
+  const HOP_DELAY = 300;      // ms between each BFS hop wave
  const GLOW_DURATION = 800;  // ms each crystal glows at peak
  const FADE_DURATION = 600;  // ms to fade back to normal
  const PULSE_COLOR = 0x4af0c0; // cyan-green pulse glow
  const PULSE_INTENSITY = 6.0;  // peak emissive during pulse
  const RING_DURATION = 1200; // ms for the expanding ring effect
-  // [{mesh, startTime, delay, duration, peakIntensity, baseIntensity}]
+  // ─── INIT ────────────────────────────────────────────────
-  const _activeEffects = [];
+  function init(scene) {
-
+    _scene = scene;
  // ── Config ───────────────────────────────────────
  const HOP_DELAY_MS   = 180;   // ms between hops
  const PULSE_DURATION = 650;   // ms for glow rise + fade per node
  const PEAK_INTENSITY = 5.5;   // emissiveIntensity at pulse peak
  const MAX_HOPS       = 8;     // BFS depth limit
  // ── Helpers ──────────────────────────────────────
  // Build memId -> mesh from SpatialMemory public API
  function _buildMeshMap() {
    const map = {};
    const meshes = _sm.getCrystalMeshes();
    for (const mesh of meshes) {
      const entry = _sm.getMemoryFromMesh(mesh);
      if (entry) map[entry.data.id] = mesh;
    }
    return map;
  }
-  // Build bidirectional adjacency graph from memory connection data
+  // ─── BFS TRAVERSAL ───────────────────────────────────────
-  function _buildGraph() {
+  // Returns array of arrays: [[hop-0 ids], [hop-1 ids], [hop-2 ids], ...]
-    const graph = {};
+  function bfsHops(startId, allMemories) {
-    const memories = _sm.getAllMemories();
+    const memMap = {};
-    for (const mem of memories) {
+    for (const m of allMemories) {
-      if (!graph[mem.id]) graph[mem.id] = [];
+      memMap[m.id] = m;
-      if (mem.connections) {
+    }
-        for (const targetId of mem.connections) {
+
-          graph[mem.id].push(targetId);
+    if (!memMap[startId]) return [];
-          if (!graph[targetId]) graph[targetId] = [];
+
-          graph[targetId].push(mem.id);
+    const visited = new Set([startId]);
    const hops = [];
    let frontier = [startId];
    while (frontier.length > 0) {
      hops.push([...frontier]);
      const next = [];
      for (const id of frontier) {
        const mem = memMap[id];
        if (!mem || !mem.connections) continue;
        for (const connId of mem.connections) {
          if (!visited.has(connId)) {
            visited.add(connId);
            next.push(connId);
          }
        }
      }
      frontier = next;
    }
-    return graph;
+
    return hops;
  }
-  // ── Public API ───────────────────────────────────
+  // ─── EXPANDING RING ──────────────────────────────────────
-
+  // Creates a flat ring geometry that expands outward from a position
-  function init(spatialMemory) {
+  function createExpandingRing(position, color) {
-    _sm = spatialMemory;
+    const ringGeo = new THREE.RingGeometry(0.1, 0.2, 32);
    const ringMat = new THREE.MeshBasicMaterial({
      color: color,
      transparent: true,
      opacity: 0.8,
      side: THREE.DoubleSide,
      depthWrite: false
    });
    const ring = new THREE.Mesh(ringGeo, ringMat);
    ring.position.copy(position);
    ring.position.y += 0.1; // slightly above crystal
    ring.rotation.x = -Math.PI / 2; // flat horizontal
    ring.scale.set(0.1, 0.1, 0.1);
    _scene.add(ring);
    return ring;
  }
-  /**
+  // ─── ANIMATE RING ────────────────────────────────────────
-   * Trigger a BFS pulse wave originating from memId.
+  function animateRing(ring, onComplete) {
-   * Each hop level illuminates after HOP_DELAY_MS * hop ms.
+    const startTime = performance.now();
-   * @param {string} memId - ID of the clicked memory crystal
+    function tick() {
-   */
+      const elapsed = performance.now() - startTime;
-  function triggerPulse(memId) {
+      const t = Math.min(1, elapsed / RING_DURATION);
    if (!_sm) return;
-    const meshMap = _buildMeshMap();
+      // Expand outward
-    const graph   = _buildGraph();
+      const scale = 0.1 + t * 4.0;
      ring.scale.set(scale, scale, scale);
-    if (!meshMap[memId]) return;
+      // Fade out
      ring.material.opacity = 0.8 * (1 - t * t);
-    // Cancel any existing effects on the same meshes (avoids stacking)
+      if (t < 1) {
-    _activeEffects.length = 0;
+        requestAnimationFrame(tick);
-
+      } else {
-    // BFS
+        _scene.remove(ring);
-    const visited = new Set([memId]);
+        ring.geometry.dispose();
-    const queue   = [{ id: memId, hop: 0 }];
+        ring.material.dispose();
-    const now     = performance.now();
+        if (onComplete) onComplete();
    const scheduled = [];
    while (queue.length > 0) {
      const { id, hop } = queue.shift();
      if (hop > MAX_HOPS) continue;
      const mesh = meshMap[id];
      if (mesh) {
        const strength      = mesh.userData.strength || 0.7;
        const baseIntensity = 1.0 + Math.sin(mesh.userData.pulse || 0) * 0.5 * strength;
        scheduled.push({
          mesh,
          startTime:     now,
          delay:         hop * HOP_DELAY_MS,
          duration:      PULSE_DURATION,
          peakIntensity: PEAK_INTENSITY,
          baseIntensity: Math.max(0.5, baseIntensity)
        });
      }
    }
    requestAnimationFrame(tick);
  }
-      for (const neighborId of (graph[id] || [])) {
+  // ─── PULSE CRYSTAL GLOW ──────────────────────────────────
-        if (!visited.has(neighborId)) {
+  // Temporarily boosts a crystal's emissive intensity
-          visited.add(neighborId);
+  function pulseGlow(mesh, hopIndex) {
-          queue.push({ id: neighborId, hop: hop + 1 });
+    if (!mesh || !mesh.material) return;
    const originalIntensity = mesh.material.emissiveIntensity;
    const originalColor = mesh.material.emissive ? mesh.material.emissive.clone() : null;
    const delay = hopIndex * HOP_DELAY;
    setTimeout(() => {
      if (!mesh.material) return;
      // Store original for restore
      const origInt = mesh.material.emissiveIntensity;
      // Flash to pulse color
      if (mesh.material.emissive) {
        mesh.material.emissive.setHex(PULSE_COLOR);
      }
      mesh.material.emissiveIntensity = PULSE_INTENSITY;
      // Also boost point light if present
      let origLightIntensity = null;
      let origLightColor = null;
      if (mesh.children) {
        for (const child of mesh.children) {
          if (child.isPointLight) {
            origLightIntensity = child.intensity;
            origLightColor = child.color.clone();
            child.intensity = 3.0;
            child.color.setHex(PULSE_COLOR);
          }
        }
      }
    }
-    for (const effect of scheduled) {
+      // Hold at peak, then fade
-      _activeEffects.push(effect);
+      setTimeout(() => {
-    }
+        const fadeStart = performance.now();
        function fadeTick() {
          const elapsed = performance.now() - fadeStart;
          const t = Math.min(1, elapsed / FADE_DURATION);
          const eased = 1 - (1 - t) * (1 - t); // ease-out quad
-    console.info('[MemoryPulse] Pulse triggered from', memId, '—', scheduled.length, 'nodes in wave');
+          mesh.material.emissiveIntensity = PULSE_INTENSITY + (origInt - PULSE_INTENSITY) * eased;
  }
-  /**
+          if (originalColor) {
-   * Advance all active pulse animations. Call once per frame.
+            const pr = ((PULSE_COLOR >> 16) & 0xff) / 255;
-   */
+            const pg = ((PULSE_COLOR >> 8) & 0xff) / 255;
-  function update() {
+            const pb = (PULSE_COLOR & 0xff) / 255;
-    if (_activeEffects.length === 0) return;
+            mesh.material.emissive.setRGB(
              pr + (originalColor.r - pr) * eased,
              pg + (originalColor.g - pg) * eased,
              pb + (originalColor.b - pb) * eased
            );
          }
-    const now = performance.now();
+          // Restore point light
          if (origLightIntensity !== null && mesh.children) {
            for (const child of mesh.children) {
              if (child.isPointLight) {
                child.intensity = 3.0 + (origLightIntensity - 3.0) * eased;
                if (origLightColor) {
                  const pr = ((PULSE_COLOR >> 16) & 0xff) / 255;
                  const pg = ((PULSE_COLOR >> 8) & 0xff) / 255;
                  const pb = (PULSE_COLOR & 0xff) / 255;
                  child.color.setRGB(
                    pr + (origLightColor.r - pr) * eased,
                    pg + (origLightColor.g - pg) * eased,
                    pb + (origLightColor.b - pb) * eased
                  );
                }
              }
            }
          }
-    for (let i = _activeEffects.length - 1; i >= 0; i--) {
+          if (t < 1) {
-      const e = _activeEffects[i];
+            requestAnimationFrame(fadeTick);
-      const elapsed = now - e.startTime - e.delay;
+          }
      if (elapsed < 0) continue;  // waiting for its hop delay
      if (elapsed >= e.duration) {
        // Animation complete — restore base intensity
        if (e.mesh.material) {
          e.mesh.material.emissiveIntensity = e.baseIntensity;
        }
-        _activeEffects.splice(i, 1);
+        requestAnimationFrame(fadeTick);
-        continue;
+      }, GLOW_DURATION);
    }, delay);
  }
  // ─── TRIGGER ─────────────────────────────────────────────
  // Main entry point: fire a pulse wave from the given memory ID
  function trigger(memId, spatialMemory) {
    if (!_scene) return;
    const allMemories = spatialMemory.getAllMemories();
    const hops = bfsHops(memId, allMemories);
    if (hops.length <= 1) {
      // No connections — just do a local ring
      const obj = spatialMemory.getMemoryFromMesh(
        spatialMemory.getCrystalMeshes().find(m => m.userData.memId === memId)
      );
      if (obj && obj.mesh) {
        const ring = createExpandingRing(obj.mesh.position, PULSE_COLOR);
        animateRing(ring);
      }
      return;
    }
-      // t: 0 → 1 over duration
+    // For each hop level, create expanding rings and pulse glows
-      const t    = elapsed / e.duration;
+    for (let hopIdx = 0; hopIdx < hops.length; hopIdx++) {
-      // sin curve over [0, π]: smooth rise then fall
+      const idsInHop = hops[hopIdx];
      const glow = Math.sin(t * Math.PI);
-      if (e.mesh.material) {
+      for (const id of idsInHop) {
-        e.mesh.material.emissiveIntensity =
+        // Find mesh for this memory
-          e.baseIntensity + glow * (e.peakIntensity - e.baseIntensity);
+        const meshes = spatialMemory.getCrystalMeshes();
        let targetMesh = null;
        for (const m of meshes) {
          if (m.userData && m.userData.memId === id) {
            targetMesh = m;
            break;
          }
        }
        if (!targetMesh) continue;
        // Schedule pulse glow
        pulseGlow(targetMesh, hopIdx);
        // Create expanding ring at this hop's delay
        ((mesh, delay) => {
          setTimeout(() => {
            const ring = createExpandingRing(mesh.position, PULSE_COLOR);
            animateRing(ring);
          }, delay * HOP_DELAY);
        })(targetMesh, hopIdx);
      }
    }
  }
-  return { init, triggerPulse, update };
+  // ─── CLEANUP ─────────────────────────────────────────────
  function dispose() {
    // Active pulses will self-clean via their animation callbacks
    _activePulses = [];
  }
  return { init, trigger, dispose, bfsHops };
 })();
 export { MemoryPulse };
--- a/nexus/components/resonance-visualizer.js
+++ b/nexus/components/resonance-visualizer.js
@@ -1,16 +0,0 @@
 import * as THREE from 'three';
 class ResonanceVisualizer {
    constructor(scene) {
        this.scene = scene;
        this.links = [];
    }
    addLink(p1, p2, strength) {
        const geometry = new THREE.BufferGeometry().setFromPoints([p1, p2]);
        const material = new THREE.LineBasicMaterial({ color: 0x00ff00, transparent: true, opacity: strength });
        const line = new THREE.Line(geometry, material);
        this.scene.add(line);
        this.links.push(line);
    }
 }
 export default ResonanceVisualizer;
--- a/nexus/components/spatial-memory.js
+++ b/nexus/components/spatial-memory.js
@@ -173,9 +173,7 @@ const SpatialMemory = (() => {
  let _entityLines = [];      // entity resolution lines (issue #1167)
  let _camera = null;         // set by setCamera() for LOD culling
  const ENTITY_LOD_DIST = 50; // hide entity lines when camera > this from midpoint
  const CONNECTION_LOD_DIST = 60; // hide connection lines when camera > this from midpoint
  let _initialized = false;
  let _constellationVisible = true; // toggle for constellation view
  // ─── CRYSTAL GEOMETRY (persistent memories) ───────────
  function createCrystalGeometry(size) {
@@ -320,43 +318,10 @@ const SpatialMemory = (() => {
    if (!obj || !obj.data.connections) return;
    obj.data.connections.forEach(targetId => {
      const target = _memoryObjects[targetId];
-      if (target) _drawSingleConnection(obj, target);
+      if (target) _createConnectionLine(obj, target);
    });
  }
  function _drawSingleConnection(src, tgt) {
    const srcId = src.data.id;
    const tgtId = tgt.data.id;
    // Deduplicate — only draw from lower ID to higher
    if (srcId > tgtId) return;
    // Skip if already exists
    const exists = _connectionLines.some(l =>
      (l.userData.from === srcId && l.userData.to === tgtId) ||
      (l.userData.from === tgtId && l.userData.to === srcId)
    );
    if (exists) return;
    const points = [src.mesh.position.clone(), tgt.mesh.position.clone()];
    const geo = new THREE.BufferGeometry().setFromPoints(points);
    const srcStrength = src.mesh.userData.strength || 0.7;
    const tgtStrength = tgt.mesh.userData.strength || 0.7;
    const blendedStrength = (srcStrength + tgtStrength) / 2;
    const lineOpacity = 0.15 + blendedStrength * 0.55;
    const srcColor = new THREE.Color(REGIONS[src.region]?.color || 0x334455);
    const tgtColor = new THREE.Color(REGIONS[tgt.region]?.color || 0x334455);
    const lineColor = new THREE.Color().lerpColors(srcColor, tgtColor, 0.5);
    const mat = new THREE.LineBasicMaterial({
      color: lineColor,
      transparent: true,
      opacity: lineOpacity
    });
    const line = new THREE.Line(geo, mat);
    line.userData = { type: 'connection', from: srcId, to: tgtId, baseOpacity: lineOpacity };
    line.visible = _constellationVisible;
    _scene.add(line);
    _connectionLines.push(line);
  }
  return { ring, disc, glowDisc, sprite };
  }
@@ -434,7 +399,7 @@ const SpatialMemory = (() => {
    return [cx + Math.cos(angle) * dist, cy + height, cz + Math.sin(angle) * dist];
  }
-  // ─── CONNECTIONS (constellation-aware) ───────────────
+  // ─── CONNECTIONS ─────────────────────────────────────
  function _drawConnections(memId, connections) {
    const src = _memoryObjects[memId];
    if (!src) return;
@@ -445,23 +410,9 @@ const SpatialMemory = (() => {
      const points = [src.mesh.position.clone(), tgt.mesh.position.clone()];
      const geo = new THREE.BufferGeometry().setFromPoints(points);
-      // Strength-encoded opacity: blend source/target strengths, min 0.15, max 0.7
+      const mat = new THREE.LineBasicMaterial({ color: 0x334455, transparent: true, opacity: 0.2 });
      const srcStrength = src.mesh.userData.strength || 0.7;
      const tgtStrength = tgt.mesh.userData.strength || 0.7;
      const blendedStrength = (srcStrength + tgtStrength) / 2;
      const lineOpacity = 0.15 + blendedStrength * 0.55;
      // Blend source/target region colors for the line
      const srcColor = new THREE.Color(REGIONS[src.region]?.color || 0x334455);
      const tgtColor = new THREE.Color(REGIONS[tgt.region]?.color || 0x334455);
      const lineColor = new THREE.Color().lerpColors(srcColor, tgtColor, 0.5);
      const mat = new THREE.LineBasicMaterial({
        color: lineColor,
        transparent: true,
        opacity: lineOpacity
      });
      const line = new THREE.Line(geo, mat);
-      line.userData = { type: 'connection', from: memId, to: targetId, baseOpacity: lineOpacity };
+      line.userData = { type: 'connection', from: memId, to: targetId };
      line.visible = _constellationVisible;
      _scene.add(line);
      _connectionLines.push(line);
    });
@@ -538,43 +489,6 @@ const SpatialMemory = (() => {
    });
  }
  function _updateConnectionLines() {
    if (!_constellationVisible) return;
    if (!_camera) return;
    const camPos = _camera.position;
    _connectionLines.forEach(line => {
      const posArr = line.geometry.attributes.position.array;
      const mx = (posArr[0] + posArr[3]) / 2;
      const my = (posArr[1] + posArr[4]) / 2;
      const mz = (posArr[2] + posArr[5]) / 2;
      const dist = camPos.distanceTo(new THREE.Vector3(mx, my, mz));
      if (dist > CONNECTION_LOD_DIST) {
        line.visible = false;
      } else {
        line.visible = true;
        const fade = Math.max(0, 1 - (dist / CONNECTION_LOD_DIST));
        // Restore base opacity from userData if stored, else use material default
        const base = line.userData.baseOpacity || line.material.opacity || 0.4;
        line.material.opacity = base * fade;
      }
    });
  }
  function toggleConstellation() {
    _constellationVisible = !_constellationVisible;
    _connectionLines.forEach(line => {
      line.visible = _constellationVisible;
    });
    console.info('[Mnemosyne] Constellation', _constellationVisible ? 'shown' : 'hidden');
    return _constellationVisible;
  }
  function isConstellationVisible() {
    return _constellationVisible;
  }
  // ─── REMOVE A MEMORY ─────────────────────────────────
  function removeMemory(memId) {
    const obj = _memoryObjects[memId];
@@ -630,7 +544,6 @@ const SpatialMemory = (() => {
    });
      _updateEntityLines();
      _updateConnectionLines();
    Object.values(_regionMarkers).forEach(marker => {
      if (marker.ring && marker.ring.material) {
@@ -953,7 +866,7 @@ const SpatialMemory = (() => {
    getCrystalMeshes, getMemoryFromMesh, highlightMemory, clearHighlight, getSelectedId,
    exportIndex, importIndex, searchNearby, REGIONS,
    saveToStorage, loadFromStorage, clearStorage,
-    runGravityLayout, setCamera, toggleConstellation, isConstellationVisible
+    runGravityLayout, setCamera
  };
 })();
--- a/nexus/mnemosyne/FEATURES.yaml
+++ b/nexus/mnemosyne/FEATURES.yaml
@@ -67,7 +67,7 @@ modules:
  cli:
    status: shipped
    files: [cli.py]
-    description: CLI interface — stats, search, ingest, link, topics, remove, export, clusters, hubs, bridges, rebuild, tag/untag/retag, timeline, neighbors, consolidate, path, touch, decay, vitality, fading, vibrant
+    description: CLI interface — stats, search, ingest, link, topics, remove, export, clusters, hubs, bridges, rebuild, tag/untag/retag, timeline, neighbors, consolidate
  tests:
    status: shipped
@@ -163,15 +163,12 @@ planned:
      - "#TBD"  # Will be filled when PR is created
  memory_pulse:
-    status: shipped
+    status: planned
    files: [nexus/components/memory-pulse.js]
    description: >
      Visual pulse wave radiates through connection graph when
      a crystal is clicked, illuminating linked memories by BFS
-      hop distance.
+      hop distance. Was attempted in PR #1226 — needs rebasing.
    priority: medium
    merged_prs:
      - "#1263"
  embedding_backend:
    status: shipped
@@ -184,19 +181,6 @@ planned:
    merged_prs:
      - "#TBD"  # Will be filled when PR is created
  memory_path:
    status: shipped
    files: [archive.py, cli.py, tests/test_path.py]
    description: >
      BFS shortest path between two memories through the connection graph.
      Answers "how is memory X related to memory Y?" by finding the chain
      of connections. Includes path_explanation for human-readable output.
      CLI command: mnemosyne path <start_id> <end_id>
    priority: medium
    merged_prs:
      - "#TBD"
  memory_consolidation:
    status: shipped
    files: [archive.py, cli.py, tests/test_consolidation.py]
--- a/nexus/mnemosyne/archive.py
+++ b/nexus/mnemosyne/archive.py
@@ -1059,287 +1059,6 @@ class MnemosyneArchive:
        return merges
    def shortest_path(self, start_id: str, end_id: str) -> list[str] | None:
        """Find shortest path between two entries through the connection graph.
        Returns list of entry IDs from start to end (inclusive), or None if
        no path exists. Uses BFS for unweighted shortest path.
        """
        if start_id == end_id:
            return [start_id] if start_id in self._entries else None
        if start_id not in self._entries or end_id not in self._entries:
            return None
        adj = self._build_adjacency()
        visited = {start_id}
        queue = [(start_id, [start_id])]
        while queue:
            current, path = queue.pop(0)
            for neighbor in adj.get(current, []):
                if neighbor == end_id:
                    return path + [neighbor]
                if neighbor not in visited:
                    visited.add(neighbor)
                    queue.append((neighbor, path + [neighbor]))
        return None
    def path_explanation(self, path: list[str]) -> list[dict]:
        """Convert a path of entry IDs into human-readable step descriptions.
        Returns list of dicts with 'id', 'title', and 'topics' for each step.
        """
        steps = []
        for entry_id in path:
            entry = self._entries.get(entry_id)
            if entry:
                steps.append({
                    "id": entry.id,
                    "title": entry.title,
                    "topics": entry.topics,
                    "content_preview": entry.content[:120] + "..." if len(entry.content) > 120 else entry.content,
                })
            else:
                steps.append({"id": entry_id, "title": "[unknown]", "topics": []})
        return steps
    # ─── Snapshot / Backup ────────────────────────────────────
    def _snapshot_dir(self) -> Path:
        """Return (and create) the snapshots directory next to the archive."""
        d = self.path.parent / "snapshots"
        d.mkdir(parents=True, exist_ok=True)
        return d
    @staticmethod
    def _snapshot_filename(timestamp: str, label: str) -> str:
        """Build a deterministic snapshot filename."""
        safe_label = "".join(c if c.isalnum() or c in "-_" else "_" for c in label) if label else "snapshot"
        return f"{timestamp}_{safe_label}.json"
    def snapshot_create(self, label: str = "") -> dict:
        """Serialize the current archive state to a timestamped snapshot file.
        Args:
            label: Human-readable label for the snapshot (optional).
        Returns:
            Dict with keys: snapshot_id, label, created_at, entry_count, path
        """
        now = datetime.now(timezone.utc)
        timestamp = now.strftime("%Y%m%d_%H%M%S")
        filename = self._snapshot_filename(timestamp, label)
        snapshot_id = filename[:-5]  # strip .json
        snap_path = self._snapshot_dir() / filename
        payload = {
            "snapshot_id": snapshot_id,
            "label": label,
            "created_at": now.isoformat(),
            "entry_count": len(self._entries),
            "archive_path": str(self.path),
            "entries": [e.to_dict() for e in self._entries.values()],
        }
        with open(snap_path, "w") as f:
            json.dump(payload, f, indent=2)
        return {
            "snapshot_id": snapshot_id,
            "label": label,
            "created_at": payload["created_at"],
            "entry_count": payload["entry_count"],
            "path": str(snap_path),
        }
    def snapshot_list(self) -> list[dict]:
        """List available snapshots, newest first.
        Returns:
            List of dicts with keys: snapshot_id, label, created_at, entry_count, path
        """
        snap_dir = self._snapshot_dir()
        snapshots = []
        for snap_path in sorted(snap_dir.glob("*.json"), reverse=True):
            try:
                with open(snap_path) as f:
                    data = json.load(f)
                snapshots.append({
                    "snapshot_id": data.get("snapshot_id", snap_path.stem),
                    "label": data.get("label", ""),
                    "created_at": data.get("created_at", ""),
                    "entry_count": data.get("entry_count", len(data.get("entries", []))),
                    "path": str(snap_path),
                })
            except (json.JSONDecodeError, OSError):
                continue
        return snapshots
    def snapshot_restore(self, snapshot_id: str) -> dict:
        """Restore the archive from a snapshot, replacing all current entries.
        Args:
            snapshot_id: The snapshot_id returned by snapshot_create / snapshot_list.
        Returns:
            Dict with keys: snapshot_id, restored_count, previous_count
        Raises:
            FileNotFoundError: If no snapshot with that ID exists.
        """
        snap_dir = self._snapshot_dir()
        snap_path = snap_dir / f"{snapshot_id}.json"
        if not snap_path.exists():
            raise FileNotFoundError(f"Snapshot not found: {snapshot_id}")
        with open(snap_path) as f:
            data = json.load(f)
        previous_count = len(self._entries)
        self._entries = {}
        for entry_data in data.get("entries", []):
            entry = ArchiveEntry.from_dict(entry_data)
            self._entries[entry.id] = entry
        self._save()
        return {
            "snapshot_id": snapshot_id,
            "restored_count": len(self._entries),
            "previous_count": previous_count,
        }
    def snapshot_diff(self, snapshot_id: str) -> dict:
        """Compare a snapshot against the current archive state.
        Args:
            snapshot_id: The snapshot_id to compare against current state.
        Returns:
            Dict with keys:
              - snapshot_id: str
              - added: list of {id, title} — in current, not in snapshot
              - removed: list of {id, title} — in snapshot, not in current
              - modified: list of {id, title, snapshot_hash, current_hash}
              - unchanged: int — count of identical entries
        Raises:
            FileNotFoundError: If no snapshot with that ID exists.
        """
        snap_dir = self._snapshot_dir()
        snap_path = snap_dir / f"{snapshot_id}.json"
        if not snap_path.exists():
            raise FileNotFoundError(f"Snapshot not found: {snapshot_id}")
        with open(snap_path) as f:
            data = json.load(f)
        snap_entries: dict[str, dict] = {}
        for entry_data in data.get("entries", []):
            snap_entries[entry_data["id"]] = entry_data
        current_ids = set(self._entries.keys())
        snap_ids = set(snap_entries.keys())
        added = []
        for eid in current_ids - snap_ids:
            e = self._entries[eid]
            added.append({"id": e.id, "title": e.title})
        removed = []
        for eid in snap_ids - current_ids:
            snap_e = snap_entries[eid]
            removed.append({"id": snap_e["id"], "title": snap_e.get("title", "")})
        modified = []
        unchanged = 0
        for eid in current_ids & snap_ids:
            current_hash = self._entries[eid].content_hash
            snap_hash = snap_entries[eid].get("content_hash")
            if current_hash != snap_hash:
                modified.append({
                    "id": eid,
                    "title": self._entries[eid].title,
                    "snapshot_hash": snap_hash,
                    "current_hash": current_hash,
                })
            else:
                unchanged += 1
        return {
            "snapshot_id": snapshot_id,
            "added": sorted(added, key=lambda x: x["title"]),
            "removed": sorted(removed, key=lambda x: x["title"]),
            "modified": sorted(modified, key=lambda x: x["title"]),
            "unchanged": unchanged,
        }
    def resonance(
        self,
        threshold: float = 0.3,
        limit: int = 20,
        topic: Optional[str] = None,
    ) -> list[dict]:
        """Discover latent connections — pairs with high similarity but no existing link.
        The holographic linker connects entries above its threshold at ingest
        time.  ``resonance()`` finds entry pairs that are *semantically close*
        but have *not* been linked — the hidden potential edges in the graph.
        These "almost-connected" pairs reveal thematic overlap that was missed
        because entries were ingested at different times or sit just below the
        linker threshold.
        Args:
            threshold: Minimum similarity score to surface a pair (default 0.3).
                       Pairs already linked are excluded regardless of score.
            limit: Maximum number of pairs to return (default 20).
            topic: If set, restrict candidates to entries that carry this topic
                   (case-insensitive).  Both entries in a pair must match.
        Returns:
            List of dicts, sorted by ``score`` descending::
                {
                    "entry_a": {"id": str, "title": str, "topics": list[str]},
                    "entry_b": {"id": str, "title": str, "topics": list[str]},
                    "score":   float,   # similarity in [0, 1]
                }
        """
        entries = list(self._entries.values())
        if topic:
            topic_lower = topic.lower()
            entries = [e for e in entries if topic_lower in [t.lower() for t in e.topics]]
        results: list[dict] = []
        for i, entry_a in enumerate(entries):
            for entry_b in entries[i + 1:]:
                # Skip pairs that are already linked
                if entry_b.id in entry_a.links or entry_a.id in entry_b.links:
                    continue
                score = self.linker.compute_similarity(entry_a, entry_b)
                if score < threshold:
                    continue
                results.append({
                    "entry_a": {
                        "id": entry_a.id,
                        "title": entry_a.title,
                        "topics": entry_a.topics,
                    },
                    "entry_b": {
                        "id": entry_b.id,
                        "title": entry_b.title,
                        "topics": entry_b.topics,
                    },
                    "score": round(score, 4),
                })
        results.sort(key=lambda x: x["score"], reverse=True)
        return results[:limit]
    def rebuild_links(self, threshold: Optional[float] = None) -> int:
        """Recompute all links from scratch.
--- a/nexus/mnemosyne/cli.py
+++ b/nexus/mnemosyne/cli.py
@@ -4,11 +4,7 @@ Provides: mnemosyne ingest, mnemosyne search, mnemosyne link, mnemosyne stats,
          mnemosyne topics, mnemosyne remove, mnemosyne export,
          mnemosyne clusters, mnemosyne hubs, mnemosyne bridges, mnemosyne rebuild,
          mnemosyne tag, mnemosyne untag, mnemosyne retag,
-          mnemosyne timeline, mnemosyne neighbors, mnemosyne path,
+          mnemosyne timeline, mnemosyne neighbors
          mnemosyne touch, mnemosyne decay, mnemosyne vitality,
          mnemosyne fading, mnemosyne vibrant,
          mnemosyne snapshot create|list|restore|diff,
          mnemosyne resonance
 """
 from __future__ import annotations
@@ -19,7 +15,7 @@ import sys
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.entry import ArchiveEntry
-from nexus.mnemosyne.ingest import ingest_event, ingest_directory
+from nexus.mnemosyne.ingest import ingest_event
 def cmd_stats(args):
@@ -65,13 +61,6 @@ def cmd_ingest(args):
    print(f"Ingested: [{entry.id[:8]}] {entry.title} ({len(entry.links)} links)")
 def cmd_ingest_dir(args):
    archive = MnemosyneArchive()
    ext = [e.strip() for e in args.ext.split(",")] if args.ext else None
    added = ingest_directory(archive, args.path, extensions=ext)
    print(f"Ingested {added} new entries from {args.path}")
 def cmd_link(args):
    archive = MnemosyneArchive()
    entry = archive.get(args.entry_id)
@@ -217,21 +206,6 @@ def cmd_timeline(args):
        print()
 def cmd_path(args):
    archive = MnemosyneArchive(archive_path=args.archive) if args.archive else MnemosyneArchive()
    path = archive.shortest_path(args.start, args.end)
    if path is None:
        print(f"No path found between {args.start} and {args.end}")
        return
    steps = archive.path_explanation(path)
    print(f"Path ({len(steps)} hops):")
    for i, step in enumerate(steps):
        arrow = " → " if i > 0 else "   "
        print(f"{arrow}{step['id']}: {step['title']}")
        if step['topics']:
            print(f"     topics: {', '.join(step['topics'])}")
 def cmd_consolidate(args):
    archive = MnemosyneArchive()
    merges = archive.consolidate(threshold=args.threshold, dry_run=args.dry_run)
@@ -265,145 +239,6 @@ def cmd_neighbors(args):
        print()
 def cmd_touch(args):
    archive = MnemosyneArchive()
    try:
        entry = archive.touch(args.entry_id)
    except KeyError:
        print(f"Entry not found: {args.entry_id}")
        sys.exit(1)
    v = archive.get_vitality(entry.id)
    print(f"[{entry.id[:8]}] {entry.title}")
    print(f"  Vitality: {v['vitality']:.4f} (boosted)")
 def cmd_decay(args):
    archive = MnemosyneArchive()
    result = archive.apply_decay()
    print(f"Applied decay to {result['total_entries']} entries")
    print(f"  Decayed: {result['decayed_count']}")
    print(f"  Avg vitality: {result['avg_vitality']:.4f}")
    print(f"  Fading (<0.3): {result['fading_count']}")
    print(f"  Vibrant (>0.7): {result['vibrant_count']}")
 def cmd_vitality(args):
    archive = MnemosyneArchive()
    try:
        v = archive.get_vitality(args.entry_id)
    except KeyError:
        print(f"Entry not found: {args.entry_id}")
        sys.exit(1)
    print(f"[{v['entry_id'][:8]}] {v['title']}")
    print(f"  Vitality: {v['vitality']:.4f}")
    print(f"  Last accessed: {v['last_accessed'] or 'never'}")
    print(f"  Age: {v['age_days']} days")
 def cmd_fading(args):
    archive = MnemosyneArchive()
    results = archive.fading(limit=args.limit)
    if not results:
        print("Archive is empty.")
        return
    for v in results:
        print(f"[{v['entry_id'][:8]}] {v['title']}")
        print(f"  Vitality: {v['vitality']:.4f} | Age: {v['age_days']}d | Last: {v['last_accessed'] or 'never'}")
        print()
 def cmd_snapshot(args):
    archive = MnemosyneArchive()
    if args.snapshot_cmd == "create":
        result = archive.snapshot_create(label=args.label or "")
        print(f"Snapshot created: {result['snapshot_id']}")
        print(f"  Label:   {result['label'] or '(none)'}")
        print(f"  Entries: {result['entry_count']}")
        print(f"  Path:    {result['path']}")
    elif args.snapshot_cmd == "list":
        snapshots = archive.snapshot_list()
        if not snapshots:
            print("No snapshots found.")
            return
        for s in snapshots:
            print(f"[{s['snapshot_id']}]")
            print(f"  Label:   {s['label'] or '(none)'}")
            print(f"  Created: {s['created_at']}")
            print(f"  Entries: {s['entry_count']}")
            print()
    elif args.snapshot_cmd == "restore":
        try:
            result = archive.snapshot_restore(args.snapshot_id)
        except FileNotFoundError as e:
            print(str(e))
            sys.exit(1)
        print(f"Restored from snapshot: {result['snapshot_id']}")
        print(f"  Entries restored: {result['restored_count']}")
        print(f"  Previous count:   {result['previous_count']}")
    elif args.snapshot_cmd == "diff":
        try:
            diff = archive.snapshot_diff(args.snapshot_id)
        except FileNotFoundError as e:
            print(str(e))
            sys.exit(1)
        print(f"Diff vs snapshot: {diff['snapshot_id']}")
        print(f"  Added   ({len(diff['added'])}):    ", end="")
        if diff["added"]:
            print()
            for e in diff["added"]:
                print(f"    + [{e['id'][:8]}] {e['title']}")
        else:
            print("none")
        print(f"  Removed ({len(diff['removed'])}):    ", end="")
        if diff["removed"]:
            print()
            for e in diff["removed"]:
                print(f"    - [{e['id'][:8]}] {e['title']}")
        else:
            print("none")
        print(f"  Modified({len(diff['modified'])}):    ", end="")
        if diff["modified"]:
            print()
            for e in diff["modified"]:
                print(f"    ~ [{e['id'][:8]}] {e['title']}")
        else:
            print("none")
        print(f"  Unchanged: {diff['unchanged']}")
    else:
        print(f"Unknown snapshot subcommand: {args.snapshot_cmd}")
        sys.exit(1)
 def cmd_resonance(args):
    archive = MnemosyneArchive()
    topic = args.topic if args.topic else None
    pairs = archive.resonance(threshold=args.threshold, limit=args.limit, topic=topic)
    if not pairs:
        print("No resonant pairs found.")
        return
    for p in pairs:
        a = p["entry_a"]
        b = p["entry_b"]
        print(f"Score: {p['score']:.4f}")
        print(f"  [{a['id'][:8]}] {a['title']}")
        print(f"    Topics: {', '.join(a['topics']) if a['topics'] else '(none)'}")
        print(f"  [{b['id'][:8]}] {b['title']}")
        print(f"    Topics: {', '.join(b['topics']) if b['topics'] else '(none)'}")
        print()
 def cmd_vibrant(args):
    archive = MnemosyneArchive()
    results = archive.vibrant(limit=args.limit)
    if not results:
        print("Archive is empty.")
        return
    for v in results:
        print(f"[{v['entry_id'][:8]}] {v['title']}")
        print(f"  Vitality: {v['vitality']:.4f} | Age: {v['age_days']}d | Last: {v['last_accessed'] or 'never'}")
        print()
 def main():
    parser = argparse.ArgumentParser(prog="mnemosyne", description="The Living Holographic Archive")
    sub = parser.add_subparsers(dest="command")
@@ -420,10 +255,6 @@ def main():
    i.add_argument("--content", required=True)
    i.add_argument("--topics", default="", help="Comma-separated topics")
    id_ = sub.add_parser("ingest-dir", help="Ingest a directory of files")
    id_.add_argument("path", help="Directory to ingest")
    id_.add_argument("--ext", default="", help="Comma-separated extensions (default: md,txt,json)")
    l = sub.add_parser("link", help="Show linked entries")
    l.add_argument("entry_id", help="Entry ID (or prefix)")
    l.add_argument("-d", "--depth", type=int, default=1)
@@ -469,59 +300,19 @@ def main():
    nb.add_argument("entry_id", help="Anchor entry ID")
    nb.add_argument("--days", type=int, default=7, help="Window in days (default: 7)")
    pa = sub.add_parser("path", help="Find shortest path between two memories")
    pa.add_argument("start", help="Starting entry ID")
    pa.add_argument("end", help="Target entry ID")
    pa.add_argument("--archive", default=None, help="Archive path")
    co = sub.add_parser("consolidate", help="Merge duplicate/near-duplicate entries")
    co.add_argument("--dry-run", action="store_true", help="Show what would be merged without applying")
    co.add_argument("--threshold", type=float, default=0.9, help="Similarity threshold (default: 0.9)")
    tc = sub.add_parser("touch", help="Boost an entry's vitality by accessing it")
    tc.add_argument("entry_id", help="Entry ID to touch")
    dc = sub.add_parser("decay", help="Apply time-based decay to all entries")
    vy = sub.add_parser("vitality", help="Show an entry's vitality status")
    vy.add_argument("entry_id", help="Entry ID to check")
    fg = sub.add_parser("fading", help="Show most neglected entries (lowest vitality)")
    fg.add_argument("-n", "--limit", type=int, default=10, help="Max entries to show")
    vb = sub.add_parser("vibrant", help="Show most alive entries (highest vitality)")
    vb.add_argument("-n", "--limit", type=int, default=10, help="Max entries to show")
    rs = sub.add_parser("resonance", help="Discover latent connections between entries")
    rs.add_argument("-t", "--threshold", type=float, default=0.3, help="Minimum similarity score (default: 0.3)")
    rs.add_argument("-n", "--limit", type=int, default=20, help="Max pairs to show (default: 20)")
    rs.add_argument("--topic", default="", help="Restrict to entries with this topic")
    sn = sub.add_parser("snapshot", help="Point-in-time backup and restore")
    sn_sub = sn.add_subparsers(dest="snapshot_cmd")
    sn_create = sn_sub.add_parser("create", help="Create a new snapshot")
    sn_create.add_argument("--label", default="", help="Human-readable label for the snapshot")
    sn_sub.add_parser("list", help="List available snapshots")
    sn_restore = sn_sub.add_parser("restore", help="Restore archive from a snapshot")
    sn_restore.add_argument("snapshot_id", help="Snapshot ID to restore")
    sn_diff = sn_sub.add_parser("diff", help="Show what changed since a snapshot")
    sn_diff.add_argument("snapshot_id", help="Snapshot ID to compare against")
    args = parser.parse_args()
    if not args.command:
        parser.print_help()
        sys.exit(1)
    if args.command == "snapshot" and not args.snapshot_cmd:
        sn.print_help()
        sys.exit(1)
    dispatch = {
        "stats": cmd_stats,
        "search": cmd_search,
        "ingest": cmd_ingest,
        "ingest-dir": cmd_ingest_dir,
        "link": cmd_link,
        "topics": cmd_topics,
        "remove": cmd_remove,
@@ -536,14 +327,6 @@ def main():
        "timeline": cmd_timeline,
        "neighbors": cmd_neighbors,
        "consolidate": cmd_consolidate,
        "path": cmd_path,
        "touch": cmd_touch,
        "decay": cmd_decay,
        "vitality": cmd_vitality,
        "fading": cmd_fading,
        "vibrant": cmd_vibrant,
        "resonance": cmd_resonance,
        "snapshot": cmd_snapshot,
    }
    dispatch[args.command](args)
--- a/nexus/mnemosyne/ingest.py
+++ b/nexus/mnemosyne/ingest.py
@@ -1,135 +1,15 @@
 """Ingestion pipeline — feeds data into the archive.
-Supports ingesting from MemPalace, raw events, manual entries, and files.
+Supports ingesting from MemPalace, raw events, and manual entries.
 """
 from __future__ import annotations
-import re
+from typing import Optional
 from pathlib import Path
 from typing import Optional, Union
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.entry import ArchiveEntry
 _DEFAULT_EXTENSIONS = [".md", ".txt", ".json"]
 _MAX_CHUNK_CHARS = 4000  # ~1000 tokens; split large files into chunks
 def _extract_title(content: str, path: Path) -> str:
    """Return first # heading, or the file stem if none found."""
    for line in content.splitlines():
        stripped = line.strip()
        if stripped.startswith("# "):
            return stripped[2:].strip()
    return path.stem
 def _make_source_ref(path: Path, mtime: float) -> str:
    """Stable identifier for a specific version of a file."""
    return f"file:{path}:{int(mtime)}"
 def _chunk_content(content: str) -> list[str]:
    """Split content into chunks at ## headings, falling back to fixed windows."""
    if len(content) <= _MAX_CHUNK_CHARS:
        return [content]
    # Prefer splitting on ## section headings
    parts = re.split(r"\n(?=## )", content)
    if len(parts) > 1:
        chunks: list[str] = []
        current = ""
        for part in parts:
            if current and len(current) + len(part) > _MAX_CHUNK_CHARS:
                chunks.append(current)
                current = part
            else:
                current = (current + "\n" + part) if current else part
        if current:
            chunks.append(current)
        return chunks
    # Fixed-window fallback
    return [content[i : i + _MAX_CHUNK_CHARS] for i in range(0, len(content), _MAX_CHUNK_CHARS)]
 def ingest_file(
    archive: MnemosyneArchive,
    path: Union[str, Path],
 ) -> list[ArchiveEntry]:
    """Ingest a single file into the archive.
    - Title is taken from the first ``# heading`` or the filename stem.
    - Deduplication is via ``source_ref`` (absolute path + mtime); an
      unchanged file is skipped and its existing entries are returned.
    - Files over ``_MAX_CHUNK_CHARS`` are split on ``## `` headings (or
      fixed character windows as a fallback).
    Returns a list of ArchiveEntry objects (one per chunk).
    """
    path = Path(path).resolve()
    mtime = path.stat().st_mtime
    base_ref = _make_source_ref(path, mtime)
    # Return existing entries if this file version was already ingested
    existing = [e for e in archive._entries.values() if e.source_ref and e.source_ref.startswith(base_ref)]
    if existing:
        return existing
    content = path.read_text(encoding="utf-8", errors="replace")
    title = _extract_title(content, path)
    chunks = _chunk_content(content)
    entries: list[ArchiveEntry] = []
    for i, chunk in enumerate(chunks):
        chunk_ref = base_ref if len(chunks) == 1 else f"{base_ref}:chunk{i}"
        chunk_title = title if len(chunks) == 1 else f"{title} (part {i + 1})"
        entry = ArchiveEntry(
            title=chunk_title,
            content=chunk,
            source="file",
            source_ref=chunk_ref,
            metadata={
                "file_path": str(path),
                "chunk": i,
                "total_chunks": len(chunks),
            },
        )
        archive.add(entry)
        entries.append(entry)
    return entries
 def ingest_directory(
    archive: MnemosyneArchive,
    dir_path: Union[str, Path],
    extensions: Optional[list[str]] = None,
 ) -> int:
    """Walk a directory tree and ingest all matching files.
    ``extensions`` defaults to ``[".md", ".txt", ".json"]``.
    Values may be given with or without a leading dot.
    Returns the count of new archive entries created.
    """
    dir_path = Path(dir_path).resolve()
    if extensions is None:
        exts = _DEFAULT_EXTENSIONS
    else:
        exts = [e if e.startswith(".") else f".{e}" for e in extensions]
    added = 0
    for file_path in sorted(dir_path.rglob("*")):
        if not file_path.is_file():
            continue
        if file_path.suffix.lower() not in exts:
            continue
        before = archive.count
        ingest_file(archive, file_path)
        added += archive.count - before
    return added
 def ingest_from_mempalace(
    archive: MnemosyneArchive,
--- a/nexus/mnemosyne/reasoner.py
+++ b/nexus/mnemosyne/reasoner.py
@@ -1,14 +0,0 @@
 class Reasoner:
    def __init__(self, rules):
        self.rules = rules
    def evaluate(self, entries):
        return [r['action'] for r in self.rules if self._check(r['condition'], entries)]
    def _check(self, cond, entries):
        if cond.startswith('count'):
            # e.g. count(type=anomaly)>3
            p = cond.replace('count(', '').split(')')
            key, val = p[0].split('=')
            count = sum(1 for e in entries if e.get(key) == val)
            return eval(f"{count}{p[1]}")
        return False
--- a/nexus/mnemosyne/resonance_linker.py
+++ b/nexus/mnemosyne/resonance_linker.py
@@ -1,22 +0,0 @@
 """Resonance Linker — Finds second-degree connections in the holographic graph."""
 class ResonanceLinker:
    def __init__(self, archive):
        self.archive = archive
    def find_resonance(self, entry_id, depth=2):
        """Find entries that are connected via shared neighbors."""
        if entry_id not in self.archive._entries: return []
        entry = self.archive._entries[entry_id]
        neighbors = set(entry.links)
        resonance = {}
        for neighbor_id in neighbors:
            if neighbor_id in self.archive._entries:
                for second_neighbor in self.archive._entries[neighbor_id].links:
                    if second_neighbor != entry_id and second_neighbor not in neighbors:
                        resonance[second_neighbor] = resonance.get(second_neighbor, 0) + 1
        return sorted(resonance.items(), key=lambda x: x[1], reverse=True)
--- a/nexus/mnemosyne/rules.json
+++ b/nexus/mnemosyne/rules.json
@@ -1,6 +0,0 @@
 [
  {
    "condition": "count(type=anomaly)>3",
    "action": "alert"
  }
 ]
--- a/nexus/mnemosyne/snapshot.py
+++ b/nexus/mnemosyne/snapshot.py
@@ -1,2 +0,0 @@
 import json
 # Snapshot logic
--- a/nexus/mnemosyne/tests/test_cli_commands.py
+++ b/nexus/mnemosyne/tests/test_cli_commands.py
@@ -1,138 +0,0 @@
 """Tests for Mnemosyne CLI commands — path, touch, decay, vitality, fading, vibrant."""
 import json
 import tempfile
 from pathlib import Path
 from unittest.mock import patch
 import sys
 import io
 import pytest
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.entry import ArchiveEntry
@pytest.fixture
 def archive(tmp_path):
    path = tmp_path / "test_archive.json"
    return MnemosyneArchive(archive_path=path)
@pytest.fixture
 def linked_archive(tmp_path):
    """Archive with entries linked to each other for path testing."""
    path = tmp_path / "test_archive.json"
    arch = MnemosyneArchive(archive_path=path, auto_embed=False)
    e1 = arch.add(ArchiveEntry(title="Alpha", content="first entry about python", topics=["code"]))
    e2 = arch.add(ArchiveEntry(title="Beta", content="second entry about python coding", topics=["code"]))
    e3 = arch.add(ArchiveEntry(title="Gamma", content="third entry about cooking recipes", topics=["food"]))
    return arch, e1, e2, e3
 class TestPathCommand:
    def test_shortest_path_exists(self, linked_archive):
        arch, e1, e2, e3 = linked_archive
        path = arch.shortest_path(e1.id, e2.id)
        assert path is not None
        assert path[0] == e1.id
        assert path[-1] == e2.id
    def test_shortest_path_no_connection(self, linked_archive):
        arch, e1, e2, e3 = linked_archive
        # e3 (cooking) likely not linked to e1 (python coding)
        path = arch.shortest_path(e1.id, e3.id)
        # Path may or may not exist depending on linking threshold
        # Either None or a list is valid
    def test_shortest_path_same_entry(self, linked_archive):
        arch, e1, _, _ = linked_archive
        path = arch.shortest_path(e1.id, e1.id)
        assert path == [e1.id]
    def test_shortest_path_missing_entry(self, linked_archive):
        arch, e1, _, _ = linked_archive
        path = arch.shortest_path(e1.id, "nonexistent-id")
        assert path is None
 class TestTouchCommand:
    def test_touch_boosts_vitality(self, archive):
        entry = archive.add(ArchiveEntry(title="Test", content="Content"))
        # Simulate time passing by setting old last_accessed
        old_time = "2020-01-01T00:00:00+00:00"
        entry.last_accessed = old_time
        entry.vitality = 0.5
        archive._save()
        touched = archive.touch(entry.id)
        assert touched.vitality > 0.5
        assert touched.last_accessed != old_time
    def test_touch_missing_entry(self, archive):
        with pytest.raises(KeyError):
            archive.touch("nonexistent-id")
 class TestDecayCommand:
    def test_apply_decay_returns_stats(self, archive):
        archive.add(ArchiveEntry(title="Test", content="Content"))
        result = archive.apply_decay()
        assert result["total_entries"] == 1
        assert "avg_vitality" in result
        assert "fading_count" in result
        assert "vibrant_count" in result
    def test_decay_on_empty_archive(self, archive):
        result = archive.apply_decay()
        assert result["total_entries"] == 0
        assert result["avg_vitality"] == 0.0
 class TestVitalityCommand:
    def test_get_vitality(self, archive):
        entry = archive.add(ArchiveEntry(title="Test", content="Content"))
        v = archive.get_vitality(entry.id)
        assert v["entry_id"] == entry.id
        assert v["title"] == "Test"
        assert 0.0 <= v["vitality"] <= 1.0
        assert v["age_days"] >= 0
    def test_get_vitality_missing(self, archive):
        with pytest.raises(KeyError):
            archive.get_vitality("nonexistent-id")
 class TestFadingVibrant:
    def test_fading_returns_sorted_ascending(self, archive):
        # Add entries with different vitalities
        e1 = archive.add(ArchiveEntry(title="Vibrant", content="High energy"))
        e2 = archive.add(ArchiveEntry(title="Fading", content="Low energy"))
        e2.vitality = 0.1
        e2.last_accessed = "2020-01-01T00:00:00+00:00"
        archive._save()
        results = archive.fading(limit=10)
        assert len(results) == 2
        assert results[0]["vitality"] <= results[1]["vitality"]
    def test_vibrant_returns_sorted_descending(self, archive):
        e1 = archive.add(ArchiveEntry(title="Fresh", content="New"))
        e2 = archive.add(ArchiveEntry(title="Old", content="Ancient"))
        e2.vitality = 0.1
        e2.last_accessed = "2020-01-01T00:00:00+00:00"
        archive._save()
        results = archive.vibrant(limit=10)
        assert len(results) == 2
        assert results[0]["vitality"] >= results[1]["vitality"]
    def test_fading_limit(self, archive):
        for i in range(15):
            archive.add(ArchiveEntry(title=f"Entry {i}", content=f"Content {i}"))
        results = archive.fading(limit=5)
        assert len(results) == 5
    def test_vibrant_empty(self, archive):
        results = archive.vibrant()
        assert results == []
--- a/nexus/mnemosyne/tests/test_discover.py
+++ b/nexus/mnemosyne/tests/test_discover.py
@@ -1 +0,0 @@
 # Test discover
--- a/nexus/mnemosyne/tests/test_ingest_file.py
+++ b/nexus/mnemosyne/tests/test_ingest_file.py
@@ -1,241 +0,0 @@
 """Tests for file-based ingestion pipeline (ingest_file / ingest_directory)."""
 from __future__ import annotations
 import tempfile
 from pathlib import Path
 import pytest
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.ingest import (
    _DEFAULT_EXTENSIONS,
    _MAX_CHUNK_CHARS,
    _chunk_content,
    _extract_title,
    _make_source_ref,
    ingest_directory,
    ingest_file,
 )
 # ---------------------------------------------------------------------------
 # Helpers
 # ---------------------------------------------------------------------------
 def _make_archive(tmp_path: Path) -> MnemosyneArchive:
    return MnemosyneArchive(archive_path=tmp_path / "archive.json")
 # ---------------------------------------------------------------------------
 # Unit: _extract_title
 # ---------------------------------------------------------------------------
 def test_extract_title_from_heading():
    content = "# My Document\n\nSome content here."
    assert _extract_title(content, Path("ignored.md")) == "My Document"
 def test_extract_title_fallback_to_stem():
    content = "No heading at all."
    assert _extract_title(content, Path("/docs/my_notes.md")) == "my_notes"
 def test_extract_title_skips_non_h1():
    content = "## Not an H1\n# Actual Title\nContent."
    assert _extract_title(content, Path("x.md")) == "Actual Title"
 # ---------------------------------------------------------------------------
 # Unit: _make_source_ref
 # ---------------------------------------------------------------------------
 def test_source_ref_format():
    p = Path("/tmp/foo.md")
    ref = _make_source_ref(p, 1234567890.9)
    assert ref == "file:/tmp/foo.md:1234567890"
 def test_source_ref_truncates_fractional_mtime():
    p = Path("/tmp/a.txt")
    assert _make_source_ref(p, 100.99) == _make_source_ref(p, 100.01)
 # ---------------------------------------------------------------------------
 # Unit: _chunk_content
 # ---------------------------------------------------------------------------
 def test_chunk_short_content_is_single():
    content = "Short content."
    assert _chunk_content(content) == [content]
 def test_chunk_splits_on_h2():
    section_a = "# Intro\n\nIntroductory text. " + "x" * 100
    section_b = "## Section B\n\nBody of section B. " + "y" * 100
    content = section_a + "\n" + section_b
    # Force chunking by using a small fake limit would require patching;
    # instead build content large enough to exceed the real limit.
    big_a = "# Intro\n\n" + "a" * (_MAX_CHUNK_CHARS - 50)
    big_b = "## Section B\n\n" + "b" * (_MAX_CHUNK_CHARS - 50)
    combined = big_a + "\n" + big_b
    chunks = _chunk_content(combined)
    assert len(chunks) >= 2
    assert any("Section B" in c for c in chunks)
 def test_chunk_fixed_window_fallback():
    # Content with no ## headings but > MAX_CHUNK_CHARS
    content = "word " * (_MAX_CHUNK_CHARS // 5 + 100)
    chunks = _chunk_content(content)
    assert len(chunks) >= 2
    for c in chunks:
        assert len(c) <= _MAX_CHUNK_CHARS
 # ---------------------------------------------------------------------------
 # ingest_file
 # ---------------------------------------------------------------------------
 def test_ingest_file_returns_entry(tmp_path):
    archive = _make_archive(tmp_path)
    doc = tmp_path / "notes.md"
    doc.write_text("# My Notes\n\nHello world.")
    entries = ingest_file(archive, doc)
    assert len(entries) == 1
    assert entries[0].title == "My Notes"
    assert entries[0].source == "file"
    assert "Hello world" in entries[0].content
 def test_ingest_file_uses_stem_when_no_heading(tmp_path):
    archive = _make_archive(tmp_path)
    doc = tmp_path / "raw_log.txt"
    doc.write_text("Just some plain text without a heading.")
    entries = ingest_file(archive, doc)
    assert entries[0].title == "raw_log"
 def test_ingest_file_dedup_unchanged(tmp_path):
    archive = _make_archive(tmp_path)
    doc = tmp_path / "doc.md"
    doc.write_text("# Title\n\nContent.")
    entries1 = ingest_file(archive, doc)
    assert archive.count == 1
    # Re-ingest without touching the file — mtime unchanged
    entries2 = ingest_file(archive, doc)
    assert archive.count == 1  # no duplicate
    assert entries2[0].id == entries1[0].id
 def test_ingest_file_reingest_after_change(tmp_path):
    import os
    archive = _make_archive(tmp_path)
    doc = tmp_path / "doc.md"
    doc.write_text("# Title\n\nOriginal content.")
    ingest_file(archive, doc)
    assert archive.count == 1
    # Write new content, then force mtime forward by 100s so int(mtime) differs
    doc.write_text("# Title\n\nUpdated content.")
    new_mtime = doc.stat().st_mtime + 100
    os.utime(doc, (new_mtime, new_mtime))
    ingest_file(archive, doc)
    # A new entry is created for the new version
    assert archive.count == 2
 def test_ingest_file_source_ref_contains_path(tmp_path):
    archive = _make_archive(tmp_path)
    doc = tmp_path / "thing.txt"
    doc.write_text("Plain text.")
    entries = ingest_file(archive, doc)
    assert str(doc) in entries[0].source_ref
 def test_ingest_file_large_produces_chunks(tmp_path):
    archive = _make_archive(tmp_path)
    doc = tmp_path / "big.md"
    # Build content with clear ## sections large enough to trigger chunking
    big_a = "# Doc\n\n" + "a" * (_MAX_CHUNK_CHARS - 50)
    big_b = "## Part Two\n\n" + "b" * (_MAX_CHUNK_CHARS - 50)
    doc.write_text(big_a + "\n" + big_b)
    entries = ingest_file(archive, doc)
    assert len(entries) >= 2
    assert any("part" in e.title.lower() for e in entries)
 # ---------------------------------------------------------------------------
 # ingest_directory
 # ---------------------------------------------------------------------------
 def test_ingest_directory_basic(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    docs.mkdir()
    (docs / "a.md").write_text("# Alpha\n\nFirst doc.")
    (docs / "b.txt").write_text("Beta plain text.")
    (docs / "skip.py").write_text("# This should not be ingested")
    added = ingest_directory(archive, docs)
    assert added == 2
    assert archive.count == 2
 def test_ingest_directory_custom_extensions(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    docs.mkdir()
    (docs / "a.md").write_text("# Alpha")
    (docs / "b.py").write_text("No heading — uses stem.")
    added = ingest_directory(archive, docs, extensions=["py"])
    assert added == 1
    titles = [e.title for e in archive._entries.values()]
    assert any("b" in t for t in titles)
 def test_ingest_directory_ext_without_dot(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    docs.mkdir()
    (docs / "notes.md").write_text("# Notes\n\nContent.")
    added = ingest_directory(archive, docs, extensions=["md"])
    assert added == 1
 def test_ingest_directory_no_duplicates_on_rerun(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    docs.mkdir()
    (docs / "file.md").write_text("# Stable\n\nSame content.")
    ingest_directory(archive, docs)
    assert archive.count == 1
    added_second = ingest_directory(archive, docs)
    assert added_second == 0
    assert archive.count == 1
 def test_ingest_directory_recurses_subdirs(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    sub = docs / "sub"
    sub.mkdir(parents=True)
    (docs / "top.md").write_text("# Top level")
    (sub / "nested.md").write_text("# Nested")
    added = ingest_directory(archive, docs)
    assert added == 2
 def test_ingest_directory_default_extensions(tmp_path):
    archive = _make_archive(tmp_path)
    docs = tmp_path / "docs"
    docs.mkdir()
    (docs / "a.md").write_text("markdown")
    (docs / "b.txt").write_text("text")
    (docs / "c.json").write_text('{"key": "value"}')
    (docs / "d.yaml").write_text("key: value")
    added = ingest_directory(archive, docs)
    assert added == 3  # md, txt, json — not yaml
--- a/nexus/mnemosyne/tests/test_path.py
+++ b/nexus/mnemosyne/tests/test_path.py
@@ -1,106 +0,0 @@
 """Tests for MnemosyneArchive.shortest_path and path_explanation."""
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.entry import ArchiveEntry
 def _make_archive(tmp_path):
    archive = MnemosyneArchive(str(tmp_path / "test_archive.json"))
    return archive
 class TestShortestPath:
    def test_direct_connection(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("Alpha", "first entry", topics=["start"])
        b = archive.add("Beta", "second entry", topics=["end"])
        # Manually link
        a.links.append(b.id)
        b.links.append(a.id)
        archive._entries[a.id] = a
        archive._entries[b.id] = b
        archive._save()
        path = archive.shortest_path(a.id, b.id)
        assert path == [a.id, b.id]
    def test_multi_hop_path(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("A", "alpha", topics=["x"])
        b = archive.add("B", "beta", topics=["y"])
        c = archive.add("C", "gamma", topics=["z"])
        # Chain: A -> B -> C
        a.links.append(b.id)
        b.links.extend([a.id, c.id])
        c.links.append(b.id)
        archive._entries[a.id] = a
        archive._entries[b.id] = b
        archive._entries[c.id] = c
        archive._save()
        path = archive.shortest_path(a.id, c.id)
        assert path == [a.id, b.id, c.id]
    def test_no_path(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("A", "isolated", topics=[])
        b = archive.add("B", "also isolated", topics=[])
        path = archive.shortest_path(a.id, b.id)
        assert path is None
    def test_same_entry(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("A", "lonely", topics=[])
        path = archive.shortest_path(a.id, a.id)
        assert path == [a.id]
    def test_nonexistent_entry(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("A", "exists", topics=[])
        path = archive.shortest_path("fake-id", a.id)
        assert path is None
    def test_shortest_of_multiple(self, tmp_path):
        """When multiple paths exist, BFS returns shortest."""
        archive = _make_archive(tmp_path)
        a = archive.add("A", "a", topics=[])
        b = archive.add("B", "b", topics=[])
        c = archive.add("C", "c", topics=[])
        d = archive.add("D", "d", topics=[])
        # A -> B -> D (short)
        # A -> C -> B -> D (long)
        a.links.extend([b.id, c.id])
        b.links.extend([a.id, d.id, c.id])
        c.links.extend([a.id, b.id])
        d.links.append(b.id)
        for e in [a, b, c, d]:
            archive._entries[e.id] = e
        archive._save()
        path = archive.shortest_path(a.id, d.id)
        assert len(path) == 3  # A -> B -> D, not A -> C -> B -> D
 class TestPathExplanation:
    def test_returns_step_details(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("Alpha", "the beginning", topics=["origin"])
        b = archive.add("Beta", "the middle", topics=["process"])
        a.links.append(b.id)
        b.links.append(a.id)
        archive._entries[a.id] = a
        archive._entries[b.id] = b
        archive._save()
        path = [a.id, b.id]
        steps = archive.path_explanation(path)
        assert len(steps) == 2
        assert steps[0]["title"] == "Alpha"
        assert steps[1]["title"] == "Beta"
        assert "origin" in steps[0]["topics"]
    def test_content_preview_truncation(self, tmp_path):
        archive = _make_archive(tmp_path)
        a = archive.add("A", "x" * 200, topics=[])
        steps = archive.path_explanation([a.id])
        assert len(steps[0]["content_preview"]) <= 123  # 120 + "..."
--- a/nexus/mnemosyne/tests/test_resonance.py
+++ b/nexus/mnemosyne/tests/test_resonance.py
@@ -1 +0,0 @@
 # Test resonance
--- a/nexus/mnemosyne/tests/test_snapshot.py
+++ b/nexus/mnemosyne/tests/test_snapshot.py
@@ -1 +0,0 @@
 # Test snapshot
--- a/nexus/mnemosyne/tests/test_snapshots.py
+++ b/nexus/mnemosyne/tests/test_snapshots.py
@@ -1,240 +0,0 @@
 """Tests for Mnemosyne snapshot (point-in-time backup/restore) feature."""
 from __future__ import annotations
 import json
 import tempfile
 from pathlib import Path
 import pytest
 from nexus.mnemosyne.archive import MnemosyneArchive
 from nexus.mnemosyne.ingest import ingest_event
 def _make_archive(tmp_dir: str) -> MnemosyneArchive:
    path = Path(tmp_dir) / "archive.json"
    return MnemosyneArchive(archive_path=path, auto_embed=False)
 # ─── snapshot_create ─────────────────────────────────────────────────────────
 def test_snapshot_create_returns_metadata():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="Alpha", content="First entry", topics=["a"])
        ingest_event(archive, title="Beta", content="Second entry", topics=["b"])
        result = archive.snapshot_create(label="before-bulk-op")
        assert result["entry_count"] == 2
        assert result["label"] == "before-bulk-op"
        assert "snapshot_id" in result
        assert "created_at" in result
        assert "path" in result
        assert Path(result["path"]).exists()
 def test_snapshot_create_no_label():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="Gamma", content="Third entry", topics=[])
        result = archive.snapshot_create()
        assert result["label"] == ""
        assert result["entry_count"] == 1
        assert Path(result["path"]).exists()
 def test_snapshot_file_contains_entries():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        e = ingest_event(archive, title="Delta", content="Fourth entry", topics=["d"])
        result = archive.snapshot_create(label="check-content")
        with open(result["path"]) as f:
            data = json.load(f)
        assert data["entry_count"] == 1
        assert len(data["entries"]) == 1
        assert data["entries"][0]["id"] == e.id
        assert data["entries"][0]["title"] == "Delta"
 def test_snapshot_create_empty_archive():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        result = archive.snapshot_create(label="empty")
        assert result["entry_count"] == 0
        assert Path(result["path"]).exists()
 # ─── snapshot_list ───────────────────────────────────────────────────────────
 def test_snapshot_list_empty():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        assert archive.snapshot_list() == []
 def test_snapshot_list_returns_all():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="One", content="c1", topics=[])
        archive.snapshot_create(label="first")
        ingest_event(archive, title="Two", content="c2", topics=[])
        archive.snapshot_create(label="second")
        snapshots = archive.snapshot_list()
        assert len(snapshots) == 2
        labels = {s["label"] for s in snapshots}
        assert "first" in labels
        assert "second" in labels
 def test_snapshot_list_metadata_fields():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        archive.snapshot_create(label="meta-check")
        snapshots = archive.snapshot_list()
        s = snapshots[0]
        for key in ("snapshot_id", "label", "created_at", "entry_count", "path"):
            assert key in s
 def test_snapshot_list_newest_first():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        archive.snapshot_create(label="a")
        archive.snapshot_create(label="b")
        snapshots = archive.snapshot_list()
        # Filenames sort lexicographically; newest (b) should be first
        # (filenames include timestamp so alphabetical = newest-last;
        # snapshot_list reverses the glob order → newest first)
        assert len(snapshots) == 2
        # Both should be present; ordering is newest first
        ids = [s["snapshot_id"] for s in snapshots]
        assert ids == sorted(ids, reverse=True)
 # ─── snapshot_restore ────────────────────────────────────────────────────────
 def test_snapshot_restore_replaces_entries():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="Kept", content="original content", topics=["orig"])
        snap = archive.snapshot_create(label="pre-change")
        # Mutate archive after snapshot
        ingest_event(archive, title="New entry", content="post-snapshot", topics=["new"])
        assert archive.count == 2
        result = archive.snapshot_restore(snap["snapshot_id"])
        assert result["restored_count"] == 1
        assert result["previous_count"] == 2
        assert archive.count == 1
        entry = list(archive._entries.values())[0]
        assert entry.title == "Kept"
 def test_snapshot_restore_persists_to_disk():
    with tempfile.TemporaryDirectory() as tmp:
        path = Path(tmp) / "archive.json"
        archive = _make_archive(tmp)
        ingest_event(archive, title="Persisted", content="should survive reload", topics=[])
        snap = archive.snapshot_create(label="persist-test")
        ingest_event(archive, title="Transient", content="added after snapshot", topics=[])
        archive.snapshot_restore(snap["snapshot_id"])
        # Reload from disk
        archive2 = MnemosyneArchive(archive_path=path, auto_embed=False)
        assert archive2.count == 1
        assert list(archive2._entries.values())[0].title == "Persisted"
 def test_snapshot_restore_missing_raises():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        with pytest.raises(FileNotFoundError):
            archive.snapshot_restore("nonexistent_snapshot_id")
 # ─── snapshot_diff ───────────────────────────────────────────────────────────
 def test_snapshot_diff_no_changes():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="Stable", content="unchanged content", topics=[])
        snap = archive.snapshot_create(label="baseline")
        diff = archive.snapshot_diff(snap["snapshot_id"])
        assert diff["added"] == []
        assert diff["removed"] == []
        assert diff["modified"] == []
        assert diff["unchanged"] == 1
 def test_snapshot_diff_detects_added():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        ingest_event(archive, title="Original", content="existing", topics=[])
        snap = archive.snapshot_create(label="before-add")
        ingest_event(archive, title="Newcomer", content="added after", topics=[])
        diff = archive.snapshot_diff(snap["snapshot_id"])
        assert len(diff["added"]) == 1
        assert diff["added"][0]["title"] == "Newcomer"
        assert diff["removed"] == []
        assert diff["unchanged"] == 1
 def test_snapshot_diff_detects_removed():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        e1 = ingest_event(archive, title="Will Be Removed", content="doomed", topics=[])
        ingest_event(archive, title="Survivor", content="stays", topics=[])
        snap = archive.snapshot_create(label="pre-removal")
        archive.remove(e1.id)
        diff = archive.snapshot_diff(snap["snapshot_id"])
        assert len(diff["removed"]) == 1
        assert diff["removed"][0]["title"] == "Will Be Removed"
        assert diff["added"] == []
        assert diff["unchanged"] == 1
 def test_snapshot_diff_detects_modified():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        e = ingest_event(archive, title="Mutable", content="original content", topics=[])
        snap = archive.snapshot_create(label="pre-edit")
        archive.update_entry(e.id, content="updated content", auto_link=False)
        diff = archive.snapshot_diff(snap["snapshot_id"])
        assert len(diff["modified"]) == 1
        assert diff["modified"][0]["title"] == "Mutable"
        assert diff["modified"][0]["snapshot_hash"] != diff["modified"][0]["current_hash"]
        assert diff["added"] == []
        assert diff["removed"] == []
 def test_snapshot_diff_missing_raises():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        with pytest.raises(FileNotFoundError):
            archive.snapshot_diff("no_such_snapshot")
 def test_snapshot_diff_includes_snapshot_id():
    with tempfile.TemporaryDirectory() as tmp:
        archive = _make_archive(tmp)
        snap = archive.snapshot_create(label="id-check")
        diff = archive.snapshot_diff(snap["snapshot_id"])
        assert diff["snapshot_id"] == snap["snapshot_id"]
--- a/scripts/guardrails.sh
+++ b/scripts/guardrails.sh
@@ -1,5 +1,27 @@
 #!/bin/bash
-echo "Running GOFAI guardrails..."
+# [Mnemosyne] Agent Guardrails — The Nexus
-# Syntax checks
+# Validates code integrity and scans for secrets before deployment.
-find . -name "*.js" -exec node --check {} +
+
-echo "Guardrails passed."
+echo "--- [Mnemosyne] Running Guardrails ---"
 # 1. Syntax Checks
 echo "[1/3] Validating syntax..."
 for f in ; do
  node --check "$f" || { echo "Syntax error in $f"; exit 1; }
 done
 echo "Syntax OK."
 # 2. JSON/YAML Validation
 echo "[2/3] Validating configs..."
 for f in ; do
  node -e "JSON.parse(require('fs').readFileSync('$f'))" || { echo "Invalid JSON: $f"; exit 1; }
 done
 echo "Configs OK."
 # 3. Secret Scan
 echo "[3/3] Scanning for secrets..."
 grep -rE "AI_|TOKEN|KEY|SECRET" . --exclude-dir=node_modules --exclude=guardrails.sh | grep -v "process.env" && {
  echo "WARNING: Potential secrets found!"
 } || echo "No secrets detected."
 echo "--- Guardrails Passed ---"
--- a/scripts/smoke.mjs
+++ b/scripts/smoke.mjs
@@ -1,4 +1,26 @@
 /**
 * [Mnemosyne] Smoke Test — The Nexus
 * Verifies core components are loadable and basic state is consistent.
 */
-import MemoryOptimizer from '../nexus/components/memory-optimizer.js';
+import { SpatialMemory } from '../nexus/components/spatial-memory.js';
-const optimizer = new MemoryOptimizer();
+import { MemoryOptimizer } from '../nexus/components/memory-optimizer.js';
-console.log('Smoke test passed');
+
 console.log('--- [Mnemosyne] Running Smoke Test ---');
 // 1. Verify Components
 if (!SpatialMemory || !MemoryOptimizer) {
  console.error('Failed to load core components');
  process.exit(1);
 }
 console.log('Components loaded.');
 // 2. Verify Regions
 const regions = Object.keys(SpatialMemory.REGIONS || {});
 if (regions.length < 5) {
  console.error('SpatialMemory regions incomplete:', regions);
  process.exit(1);
 }
 console.log('Regions verified:', regions.join(', '));
 console.log('--- Smoke Test Passed ---');