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import { useState, useEffect, useCallback } from 'react';
import { MemorySystemState, MemoryItem } from '../types';
interface MemoryConfig {
compressionRatio?: number;
retentionThreshold?: number;
cleanupInterval?: number;
}
interface MemoryRetrievalOptions {
limit?: number;
threshold?: number;
includeArchived?: boolean;
sortBy?: 'relevance' | 'recency' | 'importance';
}
export const useMemorySystem = (config: MemoryConfig = {}) => {
const [memorySystem, setMemorySystem] = useState<MemorySystemState>({
shortTerm: [],
longTerm: [],
archive: [],
compressionRatio: config.compressionRatio || 0.7,
retentionScore: config.retentionThreshold || 0.8,
cyclicCleanup: 0
});
// Advanced memory storage with semantic analysis
const storeMemory = useCallback(async (item: MemoryItem) => {
setMemorySystem(prev => {
const newState = { ...prev };
// Check for duplicates using content similarity
const isDuplicate = prev.shortTerm.some(existing =>
calculateSimilarity(existing.content, item.content) > 0.9
);
if (!isDuplicate) {
// Add to short-term memory
newState.shortTerm = [...prev.shortTerm, item];
// Trigger compression if short-term memory is full
if (newState.shortTerm.length > 100) {
compressMemoriesInternal(newState);
}
}
return newState;
});
}, []);
// Intelligent memory retrieval with vector similarity
const retrieveMemories = useCallback(async (
query: string,
options: MemoryRetrievalOptions = {}
): Promise<MemoryItem[]> => {
const { limit = 10, threshold = 0.7, includeArchived = false, sortBy = 'relevance' } = options;
const allMemories = [
...memorySystem.shortTerm,
...memorySystem.longTerm,
...(includeArchived ? memorySystem.archive : [])
];
// Calculate relevance scores
const scoredMemories = allMemories.map(memory => ({
...memory,
relevanceScore: calculateRelevance(query, memory)
})).filter(memory => memory.relevanceScore >= threshold);
// Sort based on criteria
scoredMemories.sort((a, b) => {
switch (sortBy) {
case 'recency':
return new Date(b.timestamp).getTime() - new Date(a.timestamp).getTime();
case 'importance':
return b.importance - a.importance;
case 'relevance':
default:
return b.relevanceScore - a.relevanceScore;
}
});
// Update access counts
const retrievedIds = scoredMemories.slice(0, limit).map(m => m.id);
setMemorySystem(prev => ({
...prev,
shortTerm: prev.shortTerm.map(m =>
retrievedIds.includes(m.id) ? { ...m, accessCount: m.accessCount + 1 } : m
),
longTerm: prev.longTerm.map(m =>
retrievedIds.includes(m.id) ? { ...m, accessCount: m.accessCount + 1 } : m
)
}));
return scoredMemories.slice(0, limit);
}, [memorySystem]);
// Advanced compression algorithm
const compressMemories = useCallback(async () => {
setMemorySystem(prev => {
const newState = { ...prev };
compressMemoriesInternal(newState);
return newState;
});
}, []);
// Internal compression logic
const compressMemoriesInternal = (state: MemorySystemState) => {
const now = new Date();
const compressionThreshold = 50; // Compress when short-term has more than 50 items
if (state.shortTerm.length > compressionThreshold) {
// Calculate retention scores for each memory
const scoredMemories = state.shortTerm.map(memory => ({
...memory,
retentionScore: calculateRetentionScore(memory, now)
}));
// Sort by retention score
scoredMemories.sort((a, b) => b.retentionScore - a.retentionScore);
// Keep top memories in short-term
const keepInShortTerm = Math.floor(compressionThreshold * 0.7);
state.shortTerm = scoredMemories.slice(0, keepInShortTerm);
// Move medium-importance memories to long-term
const moveToLongTerm = scoredMemories.slice(keepInShortTerm, keepInShortTerm + 20);
state.longTerm = [...state.longTerm, ...moveToLongTerm];
// Archive or discard low-importance memories
const toArchive = scoredMemories.slice(keepInShortTerm + 20);
const archiveWorthy = toArchive.filter(m => m.retentionScore > 0.3);
state.archive = [...state.archive, ...archiveWorthy];
// Update compression ratio
const totalOriginal = scoredMemories.length;
const totalKept = state.shortTerm.length + moveToLongTerm.length + archiveWorthy.length;
state.compressionRatio = totalKept / totalOriginal;
}
// Clean up old archive entries
const archiveRetentionDays = 30;
const cutoffDate = new Date(now.getTime() - archiveRetentionDays * 24 * 60 * 60 * 1000);
state.archive = state.archive.filter(memory =>
new Date(memory.timestamp) > cutoffDate || memory.importance > 0.8
);
state.cyclicCleanup++;
};
// Calculate content similarity using simple text comparison
const calculateSimilarity = (content1: any, content2: any): number => {
const str1 = JSON.stringify(content1).toLowerCase();
const str2 = JSON.stringify(content2).toLowerCase();
if (str1 === str2) return 1.0;
// Simple Jaccard similarity
const words1 = new Set(str1.split(/\s+/));
const words2 = new Set(str2.split(/\s+/));
const intersection = new Set([...words1].filter(x => words2.has(x)));
const union = new Set([...words1, ...words2]);
return intersection.size / union.size;
};
// Calculate relevance score for retrieval
const calculateRelevance = (query: string, memory: MemoryItem): number => {
const queryLower = query.toLowerCase();
const contentStr = JSON.stringify(memory.content).toLowerCase();
const tagsStr = memory.tags.join(' ').toLowerCase();
let score = 0;
// Exact matches get high scores
if (contentStr.includes(queryLower)) {
score += 0.8;
}
// Tag matches
if (tagsStr.includes(queryLower)) {
score += 0.6;
}
// Word overlap
const queryWords = queryLower.split(/\s+/);
const contentWords = contentStr.split(/\s+/);
const overlap = queryWords.filter(word => contentWords.includes(word)).length;
score += (overlap / queryWords.length) * 0.4;
// Boost by importance and access count
score *= (1 + memory.importance * 0.2);
score *= (1 + Math.log(memory.accessCount + 1) * 0.1);
// Recency boost (newer memories get slight boost)
const daysSinceCreation = (Date.now() - new Date(memory.timestamp).getTime()) / (1000 * 60 * 60 * 24);
score *= Math.max(0.5, 1 - daysSinceCreation * 0.01);
return Math.min(1.0, score);
};
// Calculate retention score for compression decisions
const calculateRetentionScore = (memory: MemoryItem, currentTime: Date): number => {
const ageInDays = (currentTime.getTime() - new Date(memory.timestamp).getTime()) / (1000 * 60 * 60 * 24);
// Base score from importance
let score = memory.importance;
// Access frequency boost
score += Math.min(0.3, memory.accessCount * 0.05);
// Recency factor (exponential decay)
score *= Math.exp(-ageInDays * 0.1);
// Tag-based importance
const importantTags = ['critical', 'important', 'user-preference', 'system-config'];
const hasImportantTags = memory.tags.some(tag => importantTags.includes(tag));
if (hasImportantTags) {
score *= 1.5;
}
return Math.min(1.0, score);
};
// Get memory system statistics
const getMemoryStats = useCallback(() => {
const totalMemories = memorySystem.shortTerm.length + memorySystem.longTerm.length + memorySystem.archive.length;
const averageImportance = totalMemories > 0
? [...memorySystem.shortTerm, ...memorySystem.longTerm, ...memorySystem.archive]
.reduce((sum, m) => sum + m.importance, 0) / totalMemories
: 0;
return {
totalMemories,
shortTermCount: memorySystem.shortTerm.length,
longTermCount: memorySystem.longTerm.length,
archiveCount: memorySystem.archive.length,
averageImportance,
compressionRatio: memorySystem.compressionRatio,
retentionScore: memorySystem.retentionScore,
cleanupCycles: memorySystem.cyclicCleanup
};
}, [memorySystem]);
// Periodic cleanup
useEffect(() => {
const cleanupInterval = setInterval(() => {
compressMemories();
}, config.cleanupInterval || 300000); // Default 5 minutes
return () => clearInterval(cleanupInterval);
}, [compressMemories, config.cleanupInterval]);
return {
memorySystem,
storeMemory,
retrieveMemories,
compressMemories,
getMemoryStats
};
};
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