#![deny(clippy::print_stdout, clippy::print_stderr)] use codex_common::CliConfigOverrides; use codex_core::config::Config; use codex_core::config::ConfigOverrides; use opentelemetry_appender_tracing::layer::OpenTelemetryTracingBridge; use std::io::ErrorKind; use std::io::Result as IoResult; use std::path::PathBuf; use crate::message_processor::MessageProcessor; use crate::outgoing_message::OutgoingMessage; use crate::outgoing_message::OutgoingMessageSender; use codex_app_server_protocol::JSONRPCMessage; use codex_feedback::CodexFeedback; use tokio::io::AsyncBufReadExt; use tokio::io::AsyncWriteExt; use tokio::io::BufReader; use tokio::io::{self}; use tokio::sync::mpsc; use tracing::Level; use tracing::debug; use tracing::error; use tracing::info; use tracing_subscriber::EnvFilter; use tracing_subscriber::Layer; use tracing_subscriber::filter::Targets; use tracing_subscriber::layer::SubscriberExt; use tracing_subscriber::util::SubscriberInitExt; mod codex_message_processor; mod error_code; mod fuzzy_file_search; mod message_processor; mod models; mod outgoing_message; /// Size of the bounded channels used to communicate between tasks. The value /// is a balance between throughput and memory usage – 128 messages should be /// plenty for an interactive CLI. const CHANNEL_CAPACITY: usize = 128; pub async fn run_main( codex_linux_sandbox_exe: Option, cli_config_overrides: CliConfigOverrides, ) -> IoResult<()> { // Set up channels. let (incoming_tx, mut incoming_rx) = mpsc::channel::(CHANNEL_CAPACITY); let (outgoing_tx, mut outgoing_rx) = mpsc::unbounded_channel::(); // Task: read from stdin, push to `incoming_tx`. let stdin_reader_handle = tokio::spawn({ async move { let stdin = io::stdin(); let reader = BufReader::new(stdin); let mut lines = reader.lines(); while let Some(line) = lines.next_line().await.unwrap_or_default() { match serde_json::from_str::(&line) { Ok(msg) => { if incoming_tx.send(msg).await.is_err() { // Receiver gone – nothing left to do. break; } } Err(e) => error!("Failed to deserialize JSONRPCMessage: {e}"), } } debug!("stdin reader finished (EOF)"); } }); // Parse CLI overrides once and derive the base Config eagerly so later // components do not need to work with raw TOML values. let cli_kv_overrides = cli_config_overrides.parse_overrides().map_err(|e| { std::io::Error::new( ErrorKind::InvalidInput, format!("error parsing -c overrides: {e}"), ) })?; let config = Config::load_with_cli_overrides(cli_kv_overrides, ConfigOverrides::default()) .await .map_err(|e| { std::io::Error::new(ErrorKind::InvalidData, format!("error loading config: {e}")) })?; let feedback = CodexFeedback::new(); let otel = codex_core::otel_init::build_provider(&config, env!("CARGO_PKG_VERSION")).map_err(|e| { std::io::Error::new( ErrorKind::InvalidData, format!("error loading otel config: {e}"), ) })?; // Install a simple subscriber so `tracing` output is visible. Users can // control the log level with `RUST_LOG`. let stderr_fmt = tracing_subscriber::fmt::layer() .with_writer(std::io::stderr) .with_filter(EnvFilter::from_default_env()); let feedback_layer = tracing_subscriber::fmt::layer() .with_writer(feedback.make_writer()) .with_ansi(false) .with_target(false) .with_filter(Targets::new().with_default(Level::TRACE)); let _ = tracing_subscriber::registry() .with(stderr_fmt) .with(feedback_layer) .with(otel.as_ref().map(|provider| { OpenTelemetryTracingBridge::new(&provider.logger).with_filter( tracing_subscriber::filter::filter_fn(codex_core::otel_init::codex_export_filter), ) })) .try_init(); // Task: process incoming messages. let processor_handle = tokio::spawn({ let outgoing_message_sender = OutgoingMessageSender::new(outgoing_tx); let mut processor = MessageProcessor::new( outgoing_message_sender, codex_linux_sandbox_exe, std::sync::Arc::new(config), feedback.clone(), ); async move { while let Some(msg) = incoming_rx.recv().await { match msg { JSONRPCMessage::Request(r) => processor.process_request(r).await, JSONRPCMessage::Response(r) => processor.process_response(r).await, JSONRPCMessage::Notification(n) => processor.process_notification(n).await, JSONRPCMessage::Error(e) => processor.process_error(e), } } info!("processor task exited (channel closed)"); } }); // Task: write outgoing messages to stdout. let stdout_writer_handle = tokio::spawn(async move { let mut stdout = io::stdout(); while let Some(outgoing_message) = outgoing_rx.recv().await { let Ok(value) = serde_json::to_value(outgoing_message) else { error!("Failed to convert OutgoingMessage to JSON value"); continue; }; match serde_json::to_string(&value) { Ok(mut json) => { json.push('\n'); if let Err(e) = stdout.write_all(json.as_bytes()).await { error!("Failed to write to stdout: {e}"); break; } } Err(e) => error!("Failed to serialize JSONRPCMessage: {e}"), } } info!("stdout writer exited (channel closed)"); }); // Wait for all tasks to finish. The typical exit path is the stdin reader // hitting EOF which, once it drops `incoming_tx`, propagates shutdown to // the processor and then to the stdout task. let _ = tokio::join!(stdin_reader_handle, processor_handle, stdout_writer_handle); Ok(()) }