// context.rs — Context window management // // Token counting, conversation trimming, and error classification. // Journal entries are loaded from the memory graph store, not from // a flat file — the parse functions are gone. use crate::agent::types::*; use chrono::{DateTime, Utc}; use tiktoken_rs::CoreBPE; /// A single journal entry with its timestamp and content. #[derive(Debug, Clone)] pub struct JournalEntry { pub timestamp: DateTime, pub content: String, } /// Context window size in tokens (from config). pub fn context_window() -> usize { crate::config::get().api_context_window } /// Context budget in tokens: 60% of the model's context window. fn context_budget_tokens() -> usize { context_window() * 60 / 100 } /// Dedup and trim conversation entries to fit within the context budget. /// /// 1. Dedup: if the same memory key appears multiple times, keep only /// the latest render (drop the earlier Memory entry and its /// corresponding assistant tool_call message). /// 2. Trim: drop oldest entries until the conversation fits, snapping /// to user message boundaries. pub fn trim_entries( context: &ContextState, entries: &[ConversationEntry], tokenizer: &CoreBPE, ) -> Vec { let count = |s: &str| tokenizer.encode_with_special_tokens(s).len(); // --- Phase 1: dedup memory entries by key (keep last) --- let mut seen_keys: std::collections::HashMap<&str, usize> = std::collections::HashMap::new(); let mut drop_indices: std::collections::HashSet = std::collections::HashSet::new(); for (i, entry) in entries.iter().enumerate() { if let ConversationEntry::Memory { key, .. } = entry { if let Some(prev) = seen_keys.insert(key.as_str(), i) { drop_indices.insert(prev); } } } let deduped: Vec = entries.iter().enumerate() .filter(|(i, _)| !drop_indices.contains(i)) .map(|(_, e)| e.clone()) .collect(); // --- Phase 2: trim to fit context budget --- let max_tokens = context_budget_tokens(); let identity_cost = count(&context.system_prompt) + context.personality.iter().map(|(_, c)| count(c)).sum::(); let journal_cost: usize = context.journal.iter().map(|e| count(&e.content)).sum(); let reserve = max_tokens / 4; let available = max_tokens .saturating_sub(identity_cost) .saturating_sub(journal_cost) .saturating_sub(reserve); let msg_costs: Vec = deduped.iter() .map(|e| msg_token_count(tokenizer, e.message())).collect(); let total: usize = msg_costs.iter().sum(); let mut skip = 0; let mut trimmed = total; while trimmed > available && skip < deduped.len() { trimmed -= msg_costs[skip]; skip += 1; } // Walk forward to user message boundary while skip < deduped.len() && deduped[skip].message().role != Role::User { skip += 1; } deduped[skip..].to_vec() } /// Count the token footprint of a message using BPE tokenization. pub fn msg_token_count(tokenizer: &CoreBPE, msg: &Message) -> usize { let count = |s: &str| tokenizer.encode_with_special_tokens(s).len(); let content = msg.content.as_ref().map_or(0, |c| match c { MessageContent::Text(s) => count(s), MessageContent::Parts(parts) => parts.iter() .map(|p| match p { ContentPart::Text { text } => count(text), ContentPart::ImageUrl { .. } => 85, }) .sum(), }); let tools = msg.tool_calls.as_ref().map_or(0, |calls| { calls.iter() .map(|c| count(&c.function.arguments) + count(&c.function.name)) .sum() }); content + tools } /// Detect context window overflow errors from the API. pub fn is_context_overflow(err: &anyhow::Error) -> bool { let msg = err.to_string().to_lowercase(); msg.contains("context length") || msg.contains("token limit") || msg.contains("too many tokens") || msg.contains("maximum context") || msg.contains("prompt is too long") || msg.contains("request too large") || msg.contains("input validation error") || msg.contains("content length limit") || (msg.contains("400") && msg.contains("tokens")) } /// Detect model/provider errors delivered inside the SSE stream. pub fn is_stream_error(err: &anyhow::Error) -> bool { err.to_string().contains("model stream error") }