// PicoClaw - Ultra-lightweight personal AI agent // Inspired by and based on nanobot: https://github.com/HKUDS/nanobot // License: MIT // // Copyright (c) 2026 PicoClaw contributors package agent import ( "context" "encoding/json" "fmt" "strings" "sync" "sync/atomic" "time" "unicode/utf8" "github.com/sipeed/picoclaw/pkg/bus" "github.com/sipeed/picoclaw/pkg/channels" "github.com/sipeed/picoclaw/pkg/config" "github.com/sipeed/picoclaw/pkg/constants" "github.com/sipeed/picoclaw/pkg/logger" "github.com/sipeed/picoclaw/pkg/providers" "github.com/sipeed/picoclaw/pkg/routing" "github.com/sipeed/picoclaw/pkg/state" "github.com/sipeed/picoclaw/pkg/tools" "github.com/sipeed/picoclaw/pkg/utils" ) type AgentLoop struct { bus *bus.MessageBus cfg *config.Config registry *AgentRegistry state *state.Manager running atomic.Bool summarizing sync.Map fallback *providers.FallbackChain channelManager *channels.Manager } // processOptions configures how a message is processed type processOptions struct { SessionKey string // Session identifier for history/context Channel string // Target channel for tool execution ChatID string // Target chat ID for tool execution UserMessage string // User message content (may include prefix) DefaultResponse string // Response when LLM returns empty EnableSummary bool // Whether to trigger summarization SendResponse bool // Whether to send response via bus NoHistory bool // If true, don't load session history (for heartbeat) } func NewAgentLoop(cfg *config.Config, msgBus *bus.MessageBus, provider providers.LLMProvider) *AgentLoop { registry := NewAgentRegistry(cfg, provider) // Register shared tools to all agents registerSharedTools(cfg, msgBus, registry, provider) // Set up shared fallback chain cooldown := providers.NewCooldownTracker() fallbackChain := providers.NewFallbackChain(cooldown) // Create state manager using default agent's workspace for channel recording defaultAgent := registry.GetDefaultAgent() var stateManager *state.Manager if defaultAgent != nil { stateManager = state.NewManager(defaultAgent.Workspace) } return &AgentLoop{ bus: msgBus, cfg: cfg, registry: registry, state: stateManager, summarizing: sync.Map{}, fallback: fallbackChain, } } // registerSharedTools registers tools that are shared across all agents (web, message, spawn). func registerSharedTools(cfg *config.Config, msgBus *bus.MessageBus, registry *AgentRegistry, provider providers.LLMProvider) { for _, agentID := range registry.ListAgentIDs() { agent, ok := registry.GetAgent(agentID) if !ok { continue } // Web tools if searchTool := tools.NewWebSearchTool(tools.WebSearchToolOptions{ BraveAPIKey: cfg.Tools.Web.Brave.APIKey, BraveMaxResults: cfg.Tools.Web.Brave.MaxResults, BraveEnabled: cfg.Tools.Web.Brave.Enabled, DuckDuckGoMaxResults: cfg.Tools.Web.DuckDuckGo.MaxResults, DuckDuckGoEnabled: cfg.Tools.Web.DuckDuckGo.Enabled, PerplexityAPIKey: cfg.Tools.Web.Perplexity.APIKey, PerplexityMaxResults: cfg.Tools.Web.Perplexity.MaxResults, PerplexityEnabled: cfg.Tools.Web.Perplexity.Enabled, }); searchTool != nil { agent.Tools.Register(searchTool) } agent.Tools.Register(tools.NewWebFetchTool(50000)) // Hardware tools (I2C, SPI) - Linux only, returns error on other platforms agent.Tools.Register(tools.NewI2CTool()) agent.Tools.Register(tools.NewSPITool()) // Message tool messageTool := tools.NewMessageTool() messageTool.SetSendCallback(func(channel, chatID, content string) error { msgBus.PublishOutbound(bus.OutboundMessage{ Channel: channel, ChatID: chatID, Content: content, }) return nil }) agent.Tools.Register(messageTool) // Spawn tool with allowlist checker subagentManager := tools.NewSubagentManager(provider, agent.Model, agent.Workspace, msgBus) spawnTool := tools.NewSpawnTool(subagentManager) currentAgentID := agentID spawnTool.SetAllowlistChecker(func(targetAgentID string) bool { return registry.CanSpawnSubagent(currentAgentID, targetAgentID) }) agent.Tools.Register(spawnTool) // Update context builder with the complete tools registry agent.ContextBuilder.SetToolsRegistry(agent.Tools) } } func (al *AgentLoop) Run(ctx context.Context) error { al.running.Store(true) for al.running.Load() { select { case <-ctx.Done(): return nil default: msg, ok := al.bus.ConsumeInbound(ctx) if !ok { continue } response, err := al.processMessage(ctx, msg) if err != nil { response = fmt.Sprintf("Error processing message: %v", err) } if response != "" { // Check if the message tool already sent a response during this round. // If so, skip publishing to avoid duplicate messages to the user. // Use default agent's tools to check (message tool is shared). alreadySent := false defaultAgent := al.registry.GetDefaultAgent() if defaultAgent != nil { if tool, ok := defaultAgent.Tools.Get("message"); ok { if mt, ok := tool.(*tools.MessageTool); ok { alreadySent = mt.HasSentInRound() } } } if !alreadySent { al.bus.PublishOutbound(bus.OutboundMessage{ Channel: msg.Channel, ChatID: msg.ChatID, Content: response, }) } } } } return nil } func (al *AgentLoop) Stop() { al.running.Store(false) } func (al *AgentLoop) RegisterTool(tool tools.Tool) { for _, agentID := range al.registry.ListAgentIDs() { if agent, ok := al.registry.GetAgent(agentID); ok { agent.Tools.Register(tool) } } } func (al *AgentLoop) SetChannelManager(cm *channels.Manager) { al.channelManager = cm } // RecordLastChannel records the last active channel for this workspace. // This uses the atomic state save mechanism to prevent data loss on crash. func (al *AgentLoop) RecordLastChannel(channel string) error { if al.state == nil { return nil } return al.state.SetLastChannel(channel) } // RecordLastChatID records the last active chat ID for this workspace. // This uses the atomic state save mechanism to prevent data loss on crash. func (al *AgentLoop) RecordLastChatID(chatID string) error { if al.state == nil { return nil } return al.state.SetLastChatID(chatID) } func (al *AgentLoop) ProcessDirect(ctx context.Context, content, sessionKey string) (string, error) { return al.ProcessDirectWithChannel(ctx, content, sessionKey, "cli", "direct") } func (al *AgentLoop) ProcessDirectWithChannel(ctx context.Context, content, sessionKey, channel, chatID string) (string, error) { msg := bus.InboundMessage{ Channel: channel, SenderID: "cron", ChatID: chatID, Content: content, SessionKey: sessionKey, } return al.processMessage(ctx, msg) } // ProcessHeartbeat processes a heartbeat request without session history. // Each heartbeat is independent and doesn't accumulate context. func (al *AgentLoop) ProcessHeartbeat(ctx context.Context, content, channel, chatID string) (string, error) { agent := al.registry.GetDefaultAgent() return al.runAgentLoop(ctx, agent, processOptions{ SessionKey: "heartbeat", Channel: channel, ChatID: chatID, UserMessage: content, DefaultResponse: "I've completed processing but have no response to give.", EnableSummary: false, SendResponse: false, NoHistory: true, // Don't load session history for heartbeat }) } func (al *AgentLoop) processMessage(ctx context.Context, msg bus.InboundMessage) (string, error) { // Add message preview to log (show full content for error messages) var logContent string if strings.Contains(msg.Content, "Error:") || strings.Contains(msg.Content, "error") { logContent = msg.Content // Full content for errors } else { logContent = utils.Truncate(msg.Content, 80) } logger.InfoCF("agent", fmt.Sprintf("Processing message from %s:%s: %s", msg.Channel, msg.SenderID, logContent), map[string]interface{}{ "channel": msg.Channel, "chat_id": msg.ChatID, "sender_id": msg.SenderID, "session_key": msg.SessionKey, }) // Route system messages to processSystemMessage if msg.Channel == "system" { return al.processSystemMessage(ctx, msg) } // Check for commands if response, handled := al.handleCommand(ctx, msg); handled { return response, nil } // Route to determine agent and session key route := al.registry.ResolveRoute(routing.RouteInput{ Channel: msg.Channel, AccountID: msg.Metadata["account_id"], Peer: extractPeer(msg), ParentPeer: extractParentPeer(msg), GuildID: msg.Metadata["guild_id"], TeamID: msg.Metadata["team_id"], }) agent, ok := al.registry.GetAgent(route.AgentID) if !ok { agent = al.registry.GetDefaultAgent() } // Use routed session key, but honor pre-set agent-scoped keys (for ProcessDirect/cron) sessionKey := route.SessionKey if msg.SessionKey != "" && strings.HasPrefix(msg.SessionKey, "agent:") { sessionKey = msg.SessionKey } logger.InfoCF("agent", "Routed message", map[string]interface{}{ "agent_id": agent.ID, "session_key": sessionKey, "matched_by": route.MatchedBy, }) return al.runAgentLoop(ctx, agent, processOptions{ SessionKey: sessionKey, Channel: msg.Channel, ChatID: msg.ChatID, UserMessage: msg.Content, DefaultResponse: "I've completed processing but have no response to give.", EnableSummary: true, SendResponse: false, }) } func (al *AgentLoop) processSystemMessage(ctx context.Context, msg bus.InboundMessage) (string, error) { if msg.Channel != "system" { return "", fmt.Errorf("processSystemMessage called with non-system message channel: %s", msg.Channel) } logger.InfoCF("agent", "Processing system message", map[string]interface{}{ "sender_id": msg.SenderID, "chat_id": msg.ChatID, }) // Parse origin channel from chat_id (format: "channel:chat_id") var originChannel, originChatID string if idx := strings.Index(msg.ChatID, ":"); idx > 0 { originChannel = msg.ChatID[:idx] originChatID = msg.ChatID[idx+1:] } else { originChannel = "cli" originChatID = msg.ChatID } // Extract subagent result from message content // Format: "Task 'label' completed.\n\nResult:\n" content := msg.Content if idx := strings.Index(content, "Result:\n"); idx >= 0 { content = content[idx+8:] // Extract just the result part } // Skip internal channels - only log, don't send to user if constants.IsInternalChannel(originChannel) { logger.InfoCF("agent", "Subagent completed (internal channel)", map[string]interface{}{ "sender_id": msg.SenderID, "content_len": len(content), "channel": originChannel, }) return "", nil } // Use default agent for system messages agent := al.registry.GetDefaultAgent() // Use the origin session for context sessionKey := routing.BuildAgentMainSessionKey(agent.ID) return al.runAgentLoop(ctx, agent, processOptions{ SessionKey: sessionKey, Channel: originChannel, ChatID: originChatID, UserMessage: fmt.Sprintf("[System: %s] %s", msg.SenderID, msg.Content), DefaultResponse: "Background task completed.", EnableSummary: false, SendResponse: true, }) } // runAgentLoop is the core message processing logic. func (al *AgentLoop) runAgentLoop(ctx context.Context, agent *AgentInstance, opts processOptions) (string, error) { // 0. Record last channel for heartbeat notifications (skip internal channels) if opts.Channel != "" && opts.ChatID != "" { // Don't record internal channels (cli, system, subagent) if !constants.IsInternalChannel(opts.Channel) { channelKey := fmt.Sprintf("%s:%s", opts.Channel, opts.ChatID) if err := al.RecordLastChannel(channelKey); err != nil { logger.WarnCF("agent", "Failed to record last channel", map[string]interface{}{"error": err.Error()}) } } } // 1. Update tool contexts al.updateToolContexts(agent, opts.Channel, opts.ChatID) // 2. Build messages (skip history for heartbeat) var history []providers.Message var summary string if !opts.NoHistory { history = agent.Sessions.GetHistory(opts.SessionKey) summary = agent.Sessions.GetSummary(opts.SessionKey) } messages := agent.ContextBuilder.BuildMessages( history, summary, opts.UserMessage, nil, opts.Channel, opts.ChatID, ) // 3. Save user message to session agent.Sessions.AddMessage(opts.SessionKey, "user", opts.UserMessage) // 4. Run LLM iteration loop finalContent, iteration, err := al.runLLMIteration(ctx, agent, messages, opts) if err != nil { return "", err } // If last tool had ForUser content and we already sent it, we might not need to send final response // This is controlled by the tool's Silent flag and ForUser content // 5. Handle empty response if finalContent == "" { finalContent = opts.DefaultResponse } // 6. Save final assistant message to session agent.Sessions.AddMessage(opts.SessionKey, "assistant", finalContent) agent.Sessions.Save(opts.SessionKey) // 7. Optional: summarization if opts.EnableSummary { al.maybeSummarize(agent, opts.SessionKey, opts.Channel, opts.ChatID) } // 8. Optional: send response via bus if opts.SendResponse { al.bus.PublishOutbound(bus.OutboundMessage{ Channel: opts.Channel, ChatID: opts.ChatID, Content: finalContent, }) } // 9. Log response responsePreview := utils.Truncate(finalContent, 120) logger.InfoCF("agent", fmt.Sprintf("Response: %s", responsePreview), map[string]interface{}{ "agent_id": agent.ID, "session_key": opts.SessionKey, "iterations": iteration, "final_length": len(finalContent), }) return finalContent, nil } // runLLMIteration executes the LLM call loop with tool handling. func (al *AgentLoop) runLLMIteration(ctx context.Context, agent *AgentInstance, messages []providers.Message, opts processOptions) (string, int, error) { iteration := 0 var finalContent string for iteration < agent.MaxIterations { iteration++ logger.DebugCF("agent", "LLM iteration", map[string]interface{}{ "agent_id": agent.ID, "iteration": iteration, "max": agent.MaxIterations, }) // Build tool definitions providerToolDefs := agent.Tools.ToProviderDefs() // Log LLM request details logger.DebugCF("agent", "LLM request", map[string]interface{}{ "agent_id": agent.ID, "iteration": iteration, "model": agent.Model, "messages_count": len(messages), "tools_count": len(providerToolDefs), "max_tokens": 8192, "temperature": 0.7, "system_prompt_len": len(messages[0].Content), }) // Log full messages (detailed) logger.DebugCF("agent", "Full LLM request", map[string]interface{}{ "iteration": iteration, "messages_json": formatMessagesForLog(messages), "tools_json": formatToolsForLog(providerToolDefs), }) // Call LLM with fallback chain if candidates are configured. var response *providers.LLMResponse var err error callLLM := func() (*providers.LLMResponse, error) { if len(agent.Candidates) > 1 && al.fallback != nil { fbResult, fbErr := al.fallback.Execute(ctx, agent.Candidates, func(ctx context.Context, provider, model string) (*providers.LLMResponse, error) { return agent.Provider.Chat(ctx, messages, providerToolDefs, model, map[string]interface{}{ "max_tokens": 8192, "temperature": 0.7, }) }, ) if fbErr != nil { return nil, fbErr } if fbResult.Provider != "" && len(fbResult.Attempts) > 0 { logger.InfoCF("agent", fmt.Sprintf("Fallback: succeeded with %s/%s after %d attempts", fbResult.Provider, fbResult.Model, len(fbResult.Attempts)+1), map[string]interface{}{"agent_id": agent.ID, "iteration": iteration}) } return fbResult.Response, nil } return agent.Provider.Chat(ctx, messages, providerToolDefs, agent.Model, map[string]interface{}{ "max_tokens": 8192, "temperature": 0.7, }) } // Retry loop for context/token errors maxRetries := 2 for retry := 0; retry <= maxRetries; retry++ { response, err = callLLM() if err == nil { break } errMsg := strings.ToLower(err.Error()) isContextError := strings.Contains(errMsg, "token") || strings.Contains(errMsg, "context") || strings.Contains(errMsg, "invalidparameter") || strings.Contains(errMsg, "length") if isContextError && retry < maxRetries { logger.WarnCF("agent", "Context window error detected, attempting compression", map[string]interface{}{ "error": err.Error(), "retry": retry, }) if retry == 0 && !constants.IsInternalChannel(opts.Channel) { al.bus.PublishOutbound(bus.OutboundMessage{ Channel: opts.Channel, ChatID: opts.ChatID, Content: "Context window exceeded. Compressing history and retrying...", }) } al.forceCompression(agent, opts.SessionKey) newHistory := agent.Sessions.GetHistory(opts.SessionKey) newSummary := agent.Sessions.GetSummary(opts.SessionKey) messages = agent.ContextBuilder.BuildMessages( newHistory, newSummary, "", nil, opts.Channel, opts.ChatID, ) continue } break } if err != nil { logger.ErrorCF("agent", "LLM call failed", map[string]interface{}{ "agent_id": agent.ID, "iteration": iteration, "error": err.Error(), }) return "", iteration, fmt.Errorf("LLM call failed after retries: %w", err) } // Check if no tool calls - we're done if len(response.ToolCalls) == 0 { finalContent = response.Content logger.InfoCF("agent", "LLM response without tool calls (direct answer)", map[string]interface{}{ "agent_id": agent.ID, "iteration": iteration, "content_chars": len(finalContent), }) break } normalizedToolCalls := make([]providers.ToolCall, 0, len(response.ToolCalls)) for _, tc := range response.ToolCalls { normalizedToolCalls = append(normalizedToolCalls, providers.NormalizeToolCall(tc)) } // Log tool calls toolNames := make([]string, 0, len(normalizedToolCalls)) for _, tc := range normalizedToolCalls { toolNames = append(toolNames, tc.Name) } logger.InfoCF("agent", "LLM requested tool calls", map[string]interface{}{ "agent_id": agent.ID, "tools": toolNames, "count": len(normalizedToolCalls), "iteration": iteration, }) // Build assistant message with tool calls assistantMsg := providers.Message{ Role: "assistant", Content: response.Content, } for _, tc := range normalizedToolCalls { argumentsJSON, _ := json.Marshal(tc.Arguments) // Copy ExtraContent to ensure thought_signature is persisted for Gemini 3 extraContent := tc.ExtraContent thoughtSignature := "" if tc.Function != nil { thoughtSignature = tc.Function.ThoughtSignature } assistantMsg.ToolCalls = append(assistantMsg.ToolCalls, providers.ToolCall{ ID: tc.ID, Type: "function", Name: tc.Name, Function: &providers.FunctionCall{ Name: tc.Name, Arguments: string(argumentsJSON), ThoughtSignature: thoughtSignature, }, ExtraContent: extraContent, ThoughtSignature: thoughtSignature, }) } messages = append(messages, assistantMsg) // Save assistant message with tool calls to session agent.Sessions.AddFullMessage(opts.SessionKey, assistantMsg) // Execute tool calls for _, tc := range normalizedToolCalls { argsJSON, _ := json.Marshal(tc.Arguments) argsPreview := utils.Truncate(string(argsJSON), 200) logger.InfoCF("agent", fmt.Sprintf("Tool call: %s(%s)", tc.Name, argsPreview), map[string]interface{}{ "agent_id": agent.ID, "tool": tc.Name, "iteration": iteration, }) // Create async callback for tools that implement AsyncTool // NOTE: Following openclaw's design, async tools do NOT send results directly to users. // Instead, they notify the agent via PublishInbound, and the agent decides // whether to forward the result to the user (in processSystemMessage). asyncCallback := func(callbackCtx context.Context, result *tools.ToolResult) { // Log the async completion but don't send directly to user // The agent will handle user notification via processSystemMessage if !result.Silent && result.ForUser != "" { logger.InfoCF("agent", "Async tool completed, agent will handle notification", map[string]interface{}{ "tool": tc.Name, "content_len": len(result.ForUser), }) } } toolResult := agent.Tools.ExecuteWithContext(ctx, tc.Name, tc.Arguments, opts.Channel, opts.ChatID, asyncCallback) // Send ForUser content to user immediately if not Silent if !toolResult.Silent && toolResult.ForUser != "" && opts.SendResponse { al.bus.PublishOutbound(bus.OutboundMessage{ Channel: opts.Channel, ChatID: opts.ChatID, Content: toolResult.ForUser, }) logger.DebugCF("agent", "Sent tool result to user", map[string]interface{}{ "tool": tc.Name, "content_len": len(toolResult.ForUser), }) } // Determine content for LLM based on tool result contentForLLM := toolResult.ForLLM if contentForLLM == "" && toolResult.Err != nil { contentForLLM = toolResult.Err.Error() } toolResultMsg := providers.Message{ Role: "tool", Content: contentForLLM, ToolCallID: tc.ID, } messages = append(messages, toolResultMsg) // Save tool result message to session agent.Sessions.AddFullMessage(opts.SessionKey, toolResultMsg) } } return finalContent, iteration, nil } // updateToolContexts updates the context for tools that need channel/chatID info. func (al *AgentLoop) updateToolContexts(agent *AgentInstance, channel, chatID string) { // Use ContextualTool interface instead of type assertions if tool, ok := agent.Tools.Get("message"); ok { if mt, ok := tool.(tools.ContextualTool); ok { mt.SetContext(channel, chatID) } } if tool, ok := agent.Tools.Get("spawn"); ok { if st, ok := tool.(tools.ContextualTool); ok { st.SetContext(channel, chatID) } } if tool, ok := agent.Tools.Get("subagent"); ok { if st, ok := tool.(tools.ContextualTool); ok { st.SetContext(channel, chatID) } } } // maybeSummarize triggers summarization if the session history exceeds thresholds. func (al *AgentLoop) maybeSummarize(agent *AgentInstance, sessionKey, channel, chatID string) { newHistory := agent.Sessions.GetHistory(sessionKey) tokenEstimate := al.estimateTokens(newHistory) threshold := agent.ContextWindow * 75 / 100 if len(newHistory) > 20 || tokenEstimate > threshold { summarizeKey := agent.ID + ":" + sessionKey if _, loading := al.summarizing.LoadOrStore(summarizeKey, true); !loading { go func() { defer al.summarizing.Delete(summarizeKey) if !constants.IsInternalChannel(channel) { al.bus.PublishOutbound(bus.OutboundMessage{ Channel: channel, ChatID: chatID, Content: "Memory threshold reached. Optimizing conversation history...", }) } al.summarizeSession(agent, sessionKey) }() } } } // forceCompression aggressively reduces context when the limit is hit. // It drops the oldest 50% of messages (keeping system prompt and last user message). func (al *AgentLoop) forceCompression(agent *AgentInstance, sessionKey string) { history := agent.Sessions.GetHistory(sessionKey) if len(history) <= 4 { return } // Keep system prompt (usually [0]) and the very last message (user's trigger) // We want to drop the oldest half of the *conversation* // Assuming [0] is system, [1:] is conversation conversation := history[1 : len(history)-1] if len(conversation) == 0 { return } // Helper to find the mid-point of the conversation mid := len(conversation) / 2 // New history structure: // 1. System Prompt (with compression note appended) // 2. Second half of conversation // 3. Last message droppedCount := mid keptConversation := conversation[mid:] newHistory := make([]providers.Message, 0) // Append compression note to the original system prompt instead of adding a new system message // This avoids having two consecutive system messages which some APIs (like Zhipu) reject compressionNote := fmt.Sprintf("\n\n[System Note: Emergency compression dropped %d oldest messages due to context limit]", droppedCount) enhancedSystemPrompt := history[0] enhancedSystemPrompt.Content = enhancedSystemPrompt.Content + compressionNote newHistory = append(newHistory, enhancedSystemPrompt) newHistory = append(newHistory, keptConversation...) newHistory = append(newHistory, history[len(history)-1]) // Last message // Update session agent.Sessions.SetHistory(sessionKey, newHistory) agent.Sessions.Save(sessionKey) logger.WarnCF("agent", "Forced compression executed", map[string]interface{}{ "session_key": sessionKey, "dropped_msgs": droppedCount, "new_count": len(newHistory), }) } // GetStartupInfo returns information about loaded tools and skills for logging. func (al *AgentLoop) GetStartupInfo() map[string]interface{} { info := make(map[string]interface{}) agent := al.registry.GetDefaultAgent() if agent == nil { return info } // Tools info toolsList := agent.Tools.List() info["tools"] = map[string]interface{}{ "count": len(toolsList), "names": toolsList, } // Skills info info["skills"] = agent.ContextBuilder.GetSkillsInfo() // Agents info info["agents"] = map[string]interface{}{ "count": len(al.registry.ListAgentIDs()), "ids": al.registry.ListAgentIDs(), } return info } // formatMessagesForLog formats messages for logging func formatMessagesForLog(messages []providers.Message) string { if len(messages) == 0 { return "[]" } var result string result += "[\n" for i, msg := range messages { result += fmt.Sprintf(" [%d] Role: %s\n", i, msg.Role) if len(msg.ToolCalls) > 0 { result += " ToolCalls:\n" for _, tc := range msg.ToolCalls { result += fmt.Sprintf(" - ID: %s, Type: %s, Name: %s\n", tc.ID, tc.Type, tc.Name) if tc.Function != nil { result += fmt.Sprintf(" Arguments: %s\n", utils.Truncate(tc.Function.Arguments, 200)) } } } if msg.Content != "" { content := utils.Truncate(msg.Content, 200) result += fmt.Sprintf(" Content: %s\n", content) } if msg.ToolCallID != "" { result += fmt.Sprintf(" ToolCallID: %s\n", msg.ToolCallID) } result += "\n" } result += "]" return result } // formatToolsForLog formats tool definitions for logging func formatToolsForLog(tools []providers.ToolDefinition) string { if len(tools) == 0 { return "[]" } var result string result += "[\n" for i, tool := range tools { result += fmt.Sprintf(" [%d] Type: %s, Name: %s\n", i, tool.Type, tool.Function.Name) result += fmt.Sprintf(" Description: %s\n", tool.Function.Description) if len(tool.Function.Parameters) > 0 { result += fmt.Sprintf(" Parameters: %s\n", utils.Truncate(fmt.Sprintf("%v", tool.Function.Parameters), 200)) } } result += "]" return result } // summarizeSession summarizes the conversation history for a session. func (al *AgentLoop) summarizeSession(agent *AgentInstance, sessionKey string) { ctx, cancel := context.WithTimeout(context.Background(), 120*time.Second) defer cancel() history := agent.Sessions.GetHistory(sessionKey) summary := agent.Sessions.GetSummary(sessionKey) // Keep last 4 messages for continuity if len(history) <= 4 { return } toSummarize := history[:len(history)-4] // Oversized Message Guard maxMessageTokens := agent.ContextWindow / 2 validMessages := make([]providers.Message, 0) omitted := false for _, m := range toSummarize { if m.Role != "user" && m.Role != "assistant" { continue } msgTokens := len(m.Content) / 2 if msgTokens > maxMessageTokens { omitted = true continue } validMessages = append(validMessages, m) } if len(validMessages) == 0 { return } // Multi-Part Summarization var finalSummary string if len(validMessages) > 10 { mid := len(validMessages) / 2 part1 := validMessages[:mid] part2 := validMessages[mid:] s1, _ := al.summarizeBatch(ctx, agent, part1, "") s2, _ := al.summarizeBatch(ctx, agent, part2, "") mergePrompt := fmt.Sprintf("Merge these two conversation summaries into one cohesive summary:\n\n1: %s\n\n2: %s", s1, s2) resp, err := agent.Provider.Chat(ctx, []providers.Message{{Role: "user", Content: mergePrompt}}, nil, agent.Model, map[string]interface{}{ "max_tokens": 1024, "temperature": 0.3, }) if err == nil { finalSummary = resp.Content } else { finalSummary = s1 + " " + s2 } } else { finalSummary, _ = al.summarizeBatch(ctx, agent, validMessages, summary) } if omitted && finalSummary != "" { finalSummary += "\n[Note: Some oversized messages were omitted from this summary for efficiency.]" } if finalSummary != "" { agent.Sessions.SetSummary(sessionKey, finalSummary) agent.Sessions.TruncateHistory(sessionKey, 4) agent.Sessions.Save(sessionKey) } } // summarizeBatch summarizes a batch of messages. func (al *AgentLoop) summarizeBatch(ctx context.Context, agent *AgentInstance, batch []providers.Message, existingSummary string) (string, error) { prompt := "Provide a concise summary of this conversation segment, preserving core context and key points.\n" if existingSummary != "" { prompt += "Existing context: " + existingSummary + "\n" } prompt += "\nCONVERSATION:\n" for _, m := range batch { prompt += fmt.Sprintf("%s: %s\n", m.Role, m.Content) } response, err := agent.Provider.Chat(ctx, []providers.Message{{Role: "user", Content: prompt}}, nil, agent.Model, map[string]interface{}{ "max_tokens": 1024, "temperature": 0.3, }) if err != nil { return "", err } return response.Content, nil } // estimateTokens estimates the number of tokens in a message list. // Uses a safe heuristic of 2.5 characters per token to account for CJK and other // overheads better than the previous 3 chars/token. func (al *AgentLoop) estimateTokens(messages []providers.Message) int { totalChars := 0 for _, m := range messages { totalChars += utf8.RuneCountInString(m.Content) } // 2.5 chars per token = totalChars * 2 / 5 return totalChars * 2 / 5 } func (al *AgentLoop) handleCommand(ctx context.Context, msg bus.InboundMessage) (string, bool) { content := strings.TrimSpace(msg.Content) if !strings.HasPrefix(content, "/") { return "", false } parts := strings.Fields(content) if len(parts) == 0 { return "", false } cmd := parts[0] args := parts[1:] switch cmd { case "/show": if len(args) < 1 { return "Usage: /show [model|channel|agents]", true } switch args[0] { case "model": defaultAgent := al.registry.GetDefaultAgent() if defaultAgent == nil { return "No default agent configured", true } return fmt.Sprintf("Current model: %s", defaultAgent.Model), true case "channel": return fmt.Sprintf("Current channel: %s", msg.Channel), true case "agents": agentIDs := al.registry.ListAgentIDs() return fmt.Sprintf("Registered agents: %s", strings.Join(agentIDs, ", ")), true default: return fmt.Sprintf("Unknown show target: %s", args[0]), true } case "/list": if len(args) < 1 { return "Usage: /list [models|channels|agents]", true } switch args[0] { case "models": return "Available models: configured in config.json per agent", true case "channels": if al.channelManager == nil { return "Channel manager not initialized", true } channels := al.channelManager.GetEnabledChannels() if len(channels) == 0 { return "No channels enabled", true } return fmt.Sprintf("Enabled channels: %s", strings.Join(channels, ", ")), true case "agents": agentIDs := al.registry.ListAgentIDs() return fmt.Sprintf("Registered agents: %s", strings.Join(agentIDs, ", ")), true default: return fmt.Sprintf("Unknown list target: %s", args[0]), true } case "/switch": if len(args) < 3 || args[1] != "to" { return "Usage: /switch [model|channel] to ", true } target := args[0] value := args[2] switch target { case "model": defaultAgent := al.registry.GetDefaultAgent() if defaultAgent == nil { return "No default agent configured", true } oldModel := defaultAgent.Model defaultAgent.Model = value return fmt.Sprintf("Switched model from %s to %s", oldModel, value), true case "channel": if al.channelManager == nil { return "Channel manager not initialized", true } if _, exists := al.channelManager.GetChannel(value); !exists && value != "cli" { return fmt.Sprintf("Channel '%s' not found or not enabled", value), true } return fmt.Sprintf("Switched target channel to %s", value), true default: return fmt.Sprintf("Unknown switch target: %s", target), true } } return "", false } // extractPeer extracts the routing peer from inbound message metadata. func extractPeer(msg bus.InboundMessage) *routing.RoutePeer { peerKind := msg.Metadata["peer_kind"] if peerKind == "" { return nil } peerID := msg.Metadata["peer_id"] if peerID == "" { if peerKind == "direct" { peerID = msg.SenderID } else { peerID = msg.ChatID } } return &routing.RoutePeer{Kind: peerKind, ID: peerID} } // extractParentPeer extracts the parent peer (reply-to) from inbound message metadata. func extractParentPeer(msg bus.InboundMessage) *routing.RoutePeer { parentKind := msg.Metadata["parent_peer_kind"] parentID := msg.Metadata["parent_peer_id"] if parentKind == "" || parentID == "" { return nil } return &routing.RoutePeer{Kind: parentKind, ID: parentID} }