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memory-orchestration

分析代理框架中的上下文管理、内存系统和状态连续性。当(1)理解提示是如何组合的,(2)评估上下文溢出时的淘汰策略,(3)映射内存层级(短期/长期),(4)分析令牌预算管理,或(5)比较不同框架之间的上下文策略时使用。

person作者: jakexiaohubgithub

Memory Orchestration

Analyzes context management and memory systems.

Process

  1. Trace context assembly — How prompts are built from components
  2. Identify eviction policies — How context overflow is handled
  3. Map memory tiers — Short-term (RAM) to long-term (DB)
  4. Analyze token management — Counting, budgeting, truncation

Context Assembly Analysis

Standard Assembly Order

┌─────────────────────────────────────────┐
│ 1. System Prompt                        │
│    - Role definition                    │
│    - Behavioral guidelines              │
│    - Output format instructions         │
├─────────────────────────────────────────┤
│ 2. Retrieved Context / Memory           │
│    - Relevant past interactions         │
│    - Retrieved documents (RAG)          │
│    - User preferences                   │
├─────────────────────────────────────────┤
│ 3. Tool Definitions                     │
│    - Available tools and schemas        │
│    - Usage examples                     │
├─────────────────────────────────────────┤
│ 4. Conversation History                 │
│    - Previous turns (user/assistant)    │
│    - Prior tool calls and results       │
├─────────────────────────────────────────┤
│ 5. Current Input                        │
│    - User's current message             │
│    - Any attachments/context            │
├─────────────────────────────────────────┤
│ 6. Agent Scratchpad (Optional)          │
│    - Current thinking/planning          │
│    - Intermediate results               │
└─────────────────────────────────────────┘

Assembly Patterns

Template-Based

PROMPT_TEMPLATE = """
{system_prompt}

## Available Tools
{tool_descriptions}

## Conversation
{history}

## Current Request
{user_input}
"""

prompt = PROMPT_TEMPLATE.format(
    system_prompt=self.system_prompt,
    tool_descriptions=self._format_tools(),
    history=self._format_history(),
    user_input=message
)

Message List (Chat API)

messages = [
    {"role": "system", "content": system_prompt},
    *self._get_history_messages(),
    {"role": "user", "content": user_input}
]

Programmatic Assembly

def build_prompt(self, input):
    builder = PromptBuilder()
    builder.add_system(self.system_prompt)
    builder.add_context(self.memory.retrieve(input))
    builder.add_tools(self.tools)
    builder.add_history(self.history, max_tokens=2000)
    builder.add_user(input)
    return builder.build()

Eviction Policies

FIFO (First In, First Out)

def trim_history(self, max_messages: int):
    while len(self.history) > max_messages:
        self.history.pop(0)  # Remove oldest

Pros: Simple, predictable Cons: May lose important early context

Sliding Window

def get_context_window(self, max_tokens: int):
    window = []
    token_count = 0
    for msg in reversed(self.history):
        msg_tokens = count_tokens(msg)
        if token_count + msg_tokens > max_tokens:
            break
        window.insert(0, msg)
        token_count += msg_tokens
    return window

Pros: Token-aware, keeps recent Cons: Still loses old context

Summarization

def summarize_and_trim(self, max_tokens: int):
    if self.total_tokens < max_tokens:
        return
    
    # Summarize oldest messages
    old_messages = self.history[:len(self.history)//2]
    summary = self.llm.summarize(old_messages)
    
    # Replace with summary
    self.history = [
        {"role": "system", "content": f"Previous conversation summary: {summary}"},
        *self.history[len(self.history)//2:]
    ]

Pros: Preserves context semantically Cons: Expensive (LLM call), lossy

Vector Store Swapping

def manage_context(self, current_input: str, max_tokens: int):
    # Move old messages to vector store
    if self.total_tokens > max_tokens:
        to_archive = self.history[:-10]
        self.vector_store.add(to_archive)
        self.history = self.history[-10:]
    
    # Retrieve relevant context
    relevant = self.vector_store.search(current_input, k=5)
    return self._build_prompt(relevant, self.history)

Pros: Scalable, relevance-based Cons: Complex, retrieval quality matters

Importance Scoring

def score_and_trim(self, max_tokens: int):
    scored = []
    for msg in self.history:
        score = self._compute_importance(msg)
        scored.append((score, msg))
    
    # Keep highest scoring until budget
    scored.sort(reverse=True)
    kept = []
    tokens = 0
    for score, msg in scored:
        if tokens + count_tokens(msg) > max_tokens:
            break
        kept.append(msg)
        tokens += count_tokens(msg)
    
    # Restore chronological order
    self.history = sorted(kept, key=lambda m: m['timestamp'])

Pros: Keeps important context Cons: Expensive to compute

Memory Tier Mapping

┌─────────────────────────────────────────────────────┐
│                  MEMORY TIERS                        │
├─────────────────────────────────────────────────────┤
│ Tier 1: Working Memory (In-Prompt)                  │
│ ├── Current conversation turns                      │
│ ├── Active tool results                             │
│ └── Immediate scratchpad                            │
│ Latency: 0ms | Capacity: Context window             │
├─────────────────────────────────────────────────────┤
│ Tier 2: Session Memory (RAM)                        │
│ ├── Full conversation history                       │
│ ├── Session state                                   │
│ └── Cached retrievals                               │
│ Latency: <1ms | Capacity: GB                        │
├─────────────────────────────────────────────────────┤
│ Tier 3: Persistent Memory (Database)                │
│ ├── Vector store (semantic search)                  │
│ ├── SQL/Document store (structured)                 │
│ └── User profiles and preferences                   │
│ Latency: 10-100ms | Capacity: TB+                   │
└─────────────────────────────────────────────────────┘

Tier Promotion/Demotion

class MemoryManager:
    def on_turn_end(self, turn):
        # Tier 1 → Tier 2: Move from prompt to session
        self.session_memory.add(turn)
        
        # Tier 2 → Tier 3: Persist important turns
        if self.should_persist(turn):
            self.persistent_memory.add(turn)
    
    def on_session_end(self):
        # Tier 2 → Tier 3: Archive session
        summary = self.summarize_session()
        self.persistent_memory.add(summary)

Token Management

Counting Strategies

| Method | Accuracy | Speed | |--------|----------|-------| | tiktoken | Exact | Fast | | len(text) / 4 | Rough estimate | Instant | | API response | Post-hoc | After call | | Tokenizer model | Exact | Medium |

Budget Allocation

class TokenBudget:
    def __init__(self, total: int = 8000):
        self.total = total
        self.allocations = {
            'system': 1000,
            'tools': 1500,
            'history': 4000,
            'input': 1000,
            'output_reserve': 500
        }
    
    def remaining_for_history(self, used: dict) -> int:
        fixed = used.get('system', 0) + used.get('tools', 0)
        return self.total - fixed - self.allocations['output_reserve']

Output Template

## Memory Orchestration Analysis: [Framework Name]

### Context Assembly
- **Order**: [System → Memory → Tools → History → Input]
- **Method**: [Template/Message List/Programmatic]
- **Location**: `path/to/prompt_builder.py`

### Eviction Policy
- **Strategy**: [FIFO/Window/Summarization/Vector/Importance]
- **Trigger**: [Token count/Message count/Explicit]
- **Location**: `path/to/memory.py:L45`

### Memory Tiers

| Tier | Storage | Capacity | Retrieval |
|------|---------|----------|-----------|
| Working | In-prompt | ~4K tokens | Immediate |
| Session | Dict/List | Unlimited | Direct |
| Persistent | [Chroma/Pinecone/SQL] | Unlimited | Semantic |

### Token Management
- **Counting**: [tiktoken/estimate/API]
- **Budget Allocation**: [Description]
- **Overflow Handling**: [Truncate/Summarize/Error]

Integration

  • Prerequisite: codebase-mapping to identify memory files
  • Feeds into: comparative-matrix for context strategies
  • Related: control-loop-extraction for scratchpad usage