// PD (Prefill-Decode) Router Implementation // This module handles routing for disaggregated prefill-decode systems use super::pd_types::{api_path, PDRouterError}; use crate::config::types::RetryConfig; use crate::core::{HealthChecker, Worker, WorkerFactory, WorkerLoadGuard}; use crate::metrics::RouterMetrics; use crate::openai_api_types::{ChatCompletionRequest, CompletionRequest, GenerateRequest}; use crate::policies::LoadBalancingPolicy; use crate::routers::{RouterTrait, WorkerManagement}; use crate::tree::Tree; use async_trait::async_trait; use axum::{ body::Body, extract::Request, http::{header::CONTENT_TYPE, HeaderMap, HeaderValue, StatusCode}, response::{IntoResponse, Response}, Json, }; use futures_util::StreamExt; use reqwest::Client; use serde_json::Value; use std::collections::HashMap; use std::sync::{Arc, Mutex, RwLock}; use std::time::{Duration, Instant}; use tokio_stream::wrappers::UnboundedReceiverStream; use tracing::{debug, error, info, warn}; #[derive(Debug)] pub struct PDRouter { pub prefill_workers: Arc>>>, pub decode_workers: Arc>>>, pub prefill_policy: Arc, pub decode_policy: Arc, pub prefill_tree: Option>>, pub decode_tree: Option>>, pub timeout_secs: u64, pub interval_secs: u64, pub worker_loads: Arc>>, pub load_monitor_handle: Option>>, pub client: Client, pub retry_config: RetryConfig, _prefill_health_checker: Option, _decode_health_checker: Option, } impl PDRouter { // Dynamic worker management methods for service discovery // Private helper method to perform health check on a new server async fn wait_for_server_health(&self, url: &str) -> Result<(), PDRouterError> { crate::routers::router::Router::wait_for_healthy_workers( &[url.to_string()], self.timeout_secs, self.interval_secs, ) .map_err(|_| PDRouterError::HealthCheckFailed { url: url.to_string(), }) } pub async fn add_prefill_server( &self, url: String, bootstrap_port: Option, ) -> Result { // Wait for the new server to be healthy self.wait_for_server_health(&url).await?; // Create Worker for the new prefill server let worker = WorkerFactory::create_prefill(url.clone(), bootstrap_port); // Add to prefill workers list let mut workers = self .prefill_workers .write() .map_err(|_| PDRouterError::LockError { operation: "prefill_workers write".to_string(), })?; // Check if already exists if workers.iter().any(|w| w.url() == &url) { return Err(PDRouterError::WorkerAlreadyExists { url: url.clone() }); } workers.push(worker); // Add to cache tree if using cache-aware policy for prefill if let Some(ref tree) = self.prefill_tree { tree.lock().unwrap().insert("", &url); } info!("Added prefill server: {}", url); Ok(format!("Successfully added prefill server: {}", url)) } pub async fn add_decode_server(&self, url: String) -> Result { // Wait for the new server to be healthy self.wait_for_server_health(&url).await?; // Create Worker for the new decode server let worker = WorkerFactory::create_decode(url.clone()); // Add to decode workers list let mut workers = self .decode_workers .write() .map_err(|_| PDRouterError::LockError { operation: "decode_workers write".to_string(), })?; // Check if already exists if workers.iter().any(|w| w.url() == &url) { return Err(PDRouterError::WorkerAlreadyExists { url: url.clone() }); } workers.push(worker); // Add to cache tree if using cache-aware policy for decode if let Some(ref tree) = self.decode_tree { tree.lock().unwrap().insert("", &url); } info!("Added decode server: {}", url); Ok(format!("Successfully added decode server: {}", url)) } pub async fn remove_prefill_server(&self, url: &str) -> Result { let mut workers = self .prefill_workers .write() .map_err(|_| PDRouterError::LockError { operation: "prefill_workers write".to_string(), })?; // Find and remove the server let initial_len = workers.len(); workers.retain(|w| w.url() != url); if workers.len() == initial_len { return Err(PDRouterError::WorkerNotFound { url: url.to_string(), }); } // Remove from cache tree if using cache-aware policy if let Some(ref tree) = self.prefill_tree { tree.lock().unwrap().remove_tenant(url); } info!("Removed prefill server: {}", url); Ok(format!("Successfully removed prefill server: {}", url)) } pub async fn remove_decode_server(&self, url: &str) -> Result { let mut workers = self .decode_workers .write() .map_err(|_| PDRouterError::LockError { operation: "decode_workers write".to_string(), })?; // Find and remove the server let initial_len = workers.len(); workers.retain(|w| w.url() != url); if workers.len() == initial_len { return Err(PDRouterError::WorkerNotFound { url: url.to_string(), }); } // Remove from the cache tree if using cache-aware policy for decode if let Some(ref tree) = self.decode_tree { tree.lock().unwrap().remove_tenant(url); } info!("Removed decode server: {}", url); Ok(format!("Successfully removed decode server: {}", url)) } pub fn new( prefill_urls: Vec<(String, Option)>, decode_urls: Vec, prefill_policy: Arc, decode_policy: Arc, client: Client, timeout_secs: u64, interval_secs: u64, retry_config: RetryConfig, ) -> Result { // Convert URLs to Worker trait objects let prefill_workers: Vec> = prefill_urls .into_iter() .map(|(url, port)| WorkerFactory::create_prefill(url, port)) .collect(); let decode_workers: Vec> = decode_urls .into_iter() .map(WorkerFactory::create_decode) .collect(); // Wait for PD workers to be healthy (skip if empty - for service discovery mode) let all_urls: Vec = prefill_workers .iter() .chain(decode_workers.iter()) .map(|worker| worker.url().to_string()) .collect(); if !all_urls.is_empty() { crate::routers::router::Router::wait_for_healthy_workers( &all_urls, timeout_secs, interval_secs, )?; } // Initialize cache-aware components if needed for prefill policy let prefill_tree = Self::initialize_radix_tree(&prefill_policy, &prefill_workers)?; // Initialize cache-aware components if needed for decode policy let decode_tree = Self::initialize_radix_tree(&decode_policy, &decode_workers)?; // Set up background load monitoring for power-of-two selection let (tx, rx) = tokio::sync::watch::channel(HashMap::new()); let worker_loads = Arc::new(rx); let load_monitor_handle = if prefill_policy.name() == "power_of_two" || decode_policy.name() == "power_of_two" { let monitor_urls = all_urls.clone(); let monitor_interval = interval_secs; let monitor_client = client.clone(); let prefill_policy_clone = Arc::clone(&prefill_policy); let decode_policy_clone = Arc::clone(&decode_policy); Some(Arc::new(tokio::spawn(async move { Self::monitor_worker_loads_with_client( monitor_urls, tx, monitor_interval, monitor_client, prefill_policy_clone, decode_policy_clone, ) .await; }))) } else { None }; let prefill_workers = Arc::new(RwLock::new(prefill_workers)); let decode_workers = Arc::new(RwLock::new(decode_workers)); // Start health checkers for both worker pools let prefill_health_checker = crate::core::start_health_checker(Arc::clone(&prefill_workers), interval_secs); let decode_health_checker = crate::core::start_health_checker(Arc::clone(&decode_workers), interval_secs); Ok(PDRouter { prefill_workers, decode_workers, prefill_policy, decode_policy, prefill_tree, decode_tree, timeout_secs, interval_secs, worker_loads, load_monitor_handle, client, retry_config, _prefill_health_checker: Some(prefill_health_checker), _decode_health_checker: Some(decode_health_checker), }) } // Helper function to initialize radix tree for cache-aware policies fn initialize_radix_tree( policy: &Arc, workers: &[Box], ) -> Result>>, String> { if let Some(cache_policy) = policy .as_any() .downcast_ref::() { // Initialize the policy's internal tree with workers cache_policy.init_workers(workers); let tree = Arc::new(Mutex::new(Tree::new())); { let tree_guard = tree .lock() .map_err(|e| format!("Failed to lock tree: {}", e))?; for worker in workers { tree_guard.insert("", worker.url()); } } Ok(Some(tree)) } else { Ok(None) } } // Helper to handle server selection errors fn handle_server_selection_error(error: String) -> Response { error!("Failed to select PD pair error={}", error); RouterMetrics::record_pd_error("server_selection"); ( StatusCode::SERVICE_UNAVAILABLE, format!("No available servers: {}", error), ) .into_response() } // Helper to handle serialization errors fn handle_serialization_error(error: impl std::fmt::Display) -> Response { error!("Failed to serialize request error={}", error); ( StatusCode::INTERNAL_SERVER_ERROR, "Failed to serialize request", ) .into_response() } // Helper to determine batch size from a GenerateRequest fn get_generate_batch_size(req: &GenerateRequest) -> Option { // Check prompt array if let Some(prompt) = &req.prompt { if let crate::openai_api_types::StringOrArray::Array(arr) = prompt { if !arr.is_empty() { return Some(arr.len()); } } } // Check text array if let Some(text) = &req.text { if text.contains("[") && text.contains("]") { // This is a simplified check - in reality we'd need to parse JSON return None; // For now, fall back to non-batch } } None } // Helper to determine batch size from a ChatCompletionRequest fn get_chat_batch_size(req: &ChatCompletionRequest) -> Option { // Check 'n' parameter for multiple responses if let Some(n) = req.n { if n > 1 { return Some(n as usize); } } None } // Helper to determine batch size from a CompletionRequest fn get_completion_batch_size(req: &CompletionRequest) -> Option { // Check prompt array if let crate::openai_api_types::StringOrArray::Array(arr) = &req.prompt { if !arr.is_empty() { return Some(arr.len()); } } None } // Helper to create request with bootstrap fields fn create_request_with_bootstrap( request: &T, prefill_worker: &dyn Worker, batch_size: Option, ) -> Result { // Get bootstrap port from prefill worker let bootstrap_port = match prefill_worker.worker_type() { crate::core::WorkerType::Prefill { bootstrap_port } => bootstrap_port, _ => None, }; let hostname = super::pd_types::get_hostname(prefill_worker.url()); // Create optimized request with bootstrap fields if let Some(batch_size) = batch_size { // Batch request let request_with_bootstrap = super::pd_types::BatchRequestWithBootstrap { original: request, bootstrap_host: vec![hostname; batch_size], bootstrap_port: vec![bootstrap_port; batch_size], bootstrap_room: (0..batch_size) .map(|_| super::pd_types::generate_room_id()) .collect(), }; serde_json::to_value(&request_with_bootstrap) } else { // Single request let request_with_bootstrap = super::pd_types::RequestWithBootstrap { original: request, bootstrap_host: hostname, bootstrap_port, bootstrap_room: super::pd_types::generate_room_id(), }; serde_json::to_value(&request_with_bootstrap) } } // Execute the dual dispatch to prefill and decode servers async fn execute_dual_dispatch( &self, headers: Option<&HeaderMap>, json_request: Value, route: &str, prefill: &dyn Worker, decode: &dyn Worker, is_stream: bool, return_logprob: bool, start_time: Instant, ) -> Response { // Update load tracking for both workers let _guard = WorkerLoadGuard::new_multi(vec![prefill, decode]); // Build requests with headers let prefill_request = self.build_request_with_headers(prefill.url(), route, &json_request, headers); let decode_request = self.build_request_with_headers(decode.url(), route, &json_request, headers); // Send both requests concurrently debug!( "Sending concurrent requests to prefill={} decode={}", prefill.url(), decode.url() ); if return_logprob { // When we need logprobs, wait for both responses let (prefill_result, decode_result) = tokio::join!(prefill_request.send(), decode_request.send()); debug!("Received responses from both servers"); // Update metrics let duration = start_time.elapsed(); RouterMetrics::record_pd_request_duration(route, duration); RouterMetrics::record_pd_request(route); RouterMetrics::record_pd_prefill_request(prefill.url()); RouterMetrics::record_pd_decode_request(decode.url()); // Process decode response with prefill for logprobs debug!("Processing decode response with logprobs"); match decode_result { Ok(res) => { let status = StatusCode::from_u16(res.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); debug!("Decode response status: {}", status); if !status.is_success() { RouterMetrics::record_pd_decode_error(decode.url()); error!( "Decode server returned error status decode_url={} status={}", decode.url(), status ); // Return the error response from decode server match res.bytes().await { Ok(error_body) => { return (status, error_body).into_response(); } Err(e) => { return (status, format!("Decode server error: {}", e)) .into_response(); } } } // Process prefill response for logprobs let prefill_body = match self .process_prefill_response(prefill_result, prefill.url(), return_logprob) .await { Ok((_, body)) => body, Err(error_response) => return error_response, }; if is_stream { // Streaming response with logprobs let prefill_logprobs = prefill_body .as_ref() .and_then(|body| serde_json::from_slice::(body).ok()) .and_then(|json| { json.pointer("/meta_info/input_token_logprobs").cloned() }); Self::create_streaming_response( res.bytes_stream(), status, prefill_logprobs, return_logprob, None, ) } else { // Non-streaming response with logprobs self.process_non_streaming_response( res, status, return_logprob, prefill_body, ) .await } } Err(e) => { error!( decode_url = %decode.url(), error = %e, "Decode request failed" ); RouterMetrics::record_pd_decode_error(decode.url()); ( StatusCode::BAD_GATEWAY, format!("Decode server error: {}", e), ) .into_response() } } } else { // When we don't need logprobs, only wait for decode response // Send both requests concurrently but don't wait for prefill // Add headers to minimize response size when we don't need the body let prefill_future = prefill_request.header("Connection", "close").send(); let decode_future = decode_request.send(); tokio::spawn(async move { if let Ok(response) = prefill_future.await { // Consume with a short timeout to free connection quickly let consume_future = async { let _ = response.bytes().await; }; // Give it 100ms to consume, then abandon let _ = tokio::time::timeout(Duration::from_millis(100), consume_future).await; } }); // Wait only for decode response let decode_result = decode_future.await; debug!("Received decode response"); // Update metrics let duration = start_time.elapsed(); RouterMetrics::record_pd_request_duration(route, duration); RouterMetrics::record_pd_request(route); RouterMetrics::record_pd_prefill_request(prefill.url()); RouterMetrics::record_pd_decode_request(decode.url()); // Process decode response immediately debug!("Processing decode response (no logprobs)"); match decode_result { Ok(res) => { let status = StatusCode::from_u16(res.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); debug!("Decode response status: {}", status); if !status.is_success() { RouterMetrics::record_pd_decode_error(decode.url()); error!( "Decode server returned error status decode_url={} status={}", decode.url(), status ); // Return the error response from decode server match res.bytes().await { Ok(error_body) => (status, error_body).into_response(), Err(e) => { (status, format!("Decode server error: {}", e)).into_response() } } } else if is_stream { // Streaming response without logprobs - direct passthrough let decode_url = decode.url().to_string(); Self::create_streaming_response( res.bytes_stream(), status, None, false, Some(decode_url), ) } else { // Non-streaming response without logprobs - direct passthrough like fast version match res.bytes().await { Ok(decode_body) => (status, decode_body).into_response(), Err(e) => { error!("Failed to read decode response: {}", e); (StatusCode::INTERNAL_SERVER_ERROR, "Failed to read response") .into_response() } } } } Err(e) => { error!( decode_url = %decode.url(), error = %e, "Decode request failed" ); RouterMetrics::record_pd_decode_error(decode.url()); ( StatusCode::BAD_GATEWAY, format!("Decode server error: {}", e), ) .into_response() } } } } // Check if either prefill or decode policy needs request text fn policies_need_request_text(&self) -> bool { self.prefill_policy.needs_request_text() || self.decode_policy.needs_request_text() } // Select a pair of prefill and decode servers async fn select_pd_pair( &self, request_text: Option<&str>, ) -> Result<(Box, Box), String> { // Get read locks for both worker lists let prefill_workers = self .prefill_workers .read() .map_err(|e| format!("Failed to acquire prefill workers lock: {}", e))?; let decode_workers = self .decode_workers .read() .map_err(|e| format!("Failed to acquire decode workers lock: {}", e))?; // Check we have workers if prefill_workers.is_empty() { return Err("No prefill workers available. Please check if prefill servers are configured and healthy.".to_string()); } if decode_workers.is_empty() { return Err("No decode workers available. Please check if decode servers are configured and healthy.".to_string()); } // Select prefill worker using prefill policy let prefill_idx = self .prefill_policy .select_worker(&prefill_workers, request_text) .ok_or("Failed to select prefill worker")?; // Select decode worker using decode policy let decode_idx = self .decode_policy .select_worker(&decode_workers, request_text) .ok_or("Failed to select decode worker")?; let prefill = prefill_workers[prefill_idx].clone_worker(); let decode = decode_workers[decode_idx].clone_worker(); Ok((prefill, decode)) } // Background task to monitor worker loads with shared client async fn monitor_worker_loads_with_client( worker_urls: Vec, tx: tokio::sync::watch::Sender>, interval_secs: u64, client: Client, prefill_policy: Arc, decode_policy: Arc, ) { loop { let mut loads = HashMap::new(); let futures: Vec<_> = worker_urls .iter() .map(|url| { let client = client.clone(); let url = url.clone(); async move { let load = get_worker_load(&client, &url).await.unwrap_or(0); (url, load) } }) .collect(); let results = futures_util::future::join_all(futures).await; for (url, load) in results { loads.insert(url, load); } debug!("Worker loads updated: {:?}", loads); // Update both policies with current loads prefill_policy.update_loads(&loads); decode_policy.update_loads(&loads); // Check if receiver is still active if tx.send(loads).is_err() { info!("Load monitor receiver dropped, shutting down monitor task"); break; } tokio::time::sleep(Duration::from_secs(interval_secs)).await; } } // Helper to create a streaming response fn create_streaming_response( stream: impl futures_util::Stream> + Send + 'static, status: StatusCode, prefill_logprobs: Option, return_logprob: bool, decode_url: Option, ) -> Response { let (tx, rx) = tokio::sync::mpsc::unbounded_channel(); tokio::spawn(async move { futures_util::pin_mut!(stream); while let Some(chunk_result) = stream.next().await { match chunk_result { Ok(chunk) => { let result = if return_logprob && prefill_logprobs.is_some() { // Try to merge logprobs Self::merge_streaming_logprobs(prefill_logprobs.clone(), &chunk) .unwrap_or(chunk) } else { chunk }; if tx.send(Ok(result)).is_err() { break; } } Err(e) => { if let Some(ref url) = decode_url { error!("Stream error from decode server {}: {}", url, e); RouterMetrics::record_pd_stream_error(url); } let _ = tx.send(Err(format!("Stream error: {}", e))); break; } } } }); let stream = UnboundedReceiverStream::new(rx); let body = Body::from_stream(stream); let mut response = Response::new(body); *response.status_mut() = status; response .headers_mut() .insert(CONTENT_TYPE, HeaderValue::from_static("text/event-stream")); response } // Helper to process non-streaming decode response with logprob merging async fn process_non_streaming_response( &self, res: reqwest::Response, status: StatusCode, return_logprob: bool, prefill_body: Option, ) -> Response { match res.bytes().await { Ok(decode_body) => { if return_logprob && prefill_body.is_some() { // Merge logprobs from prefill and decode let prefill_body = prefill_body.as_ref().unwrap(); match ( serde_json::from_slice::(prefill_body), serde_json::from_slice::(&decode_body), ) { (Ok(prefill_json), Ok(mut decode_json)) => { // Use helper to merge logprobs Self::merge_logprobs_in_json(&prefill_json, &mut decode_json); // Return merged response match serde_json::to_vec(&decode_json) { Ok(body) => (status, body).into_response(), Err(e) => { error!("Failed to serialize merged response: {}", e); (status, decode_body).into_response() } } } _ => { // If parsing fails, just return decode response warn!("Failed to parse responses for logprob merging"); (status, decode_body).into_response() } } } else { (status, decode_body).into_response() } } Err(e) => { error!("Failed to read decode response: {}", e); (StatusCode::INTERNAL_SERVER_ERROR, "Failed to read response").into_response() } } } // Helper to process prefill response and extract body if needed for logprobs async fn process_prefill_response( &self, prefill_result: Result, prefill_url: &str, return_logprob: bool, ) -> Result<(StatusCode, Option), Response> { // Check prefill result first - it's critical for disaggregated mode let prefill_response = match prefill_result { Ok(response) => response, Err(e) => { RouterMetrics::record_pd_prefill_error(prefill_url); error!( "Prefill server failed (CRITICAL) prefill_url={} error={}. Decode will timeout without prefill KV cache.", prefill_url, e ); // Return error immediately - don't wait for decode to timeout return Err(( StatusCode::BAD_GATEWAY, format!( "Prefill server error: {}. This will cause decode timeout.", e ), ) .into_response()); } }; let prefill_status = StatusCode::from_u16(prefill_response.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); // Check if prefill succeeded if !prefill_status.is_success() { RouterMetrics::record_pd_prefill_error(prefill_url); // Get error body from prefill let error_msg = prefill_response .text() .await .unwrap_or_else(|_| "Unknown prefill error".to_string()); error!( "Prefill server returned error status prefill_url={} status={} body={}", prefill_url, prefill_status, error_msg ); return Err(( prefill_status, format!("Prefill server error ({}): {}", prefill_status, error_msg), ) .into_response()); } // Read prefill body if needed for logprob merging let prefill_body = if return_logprob { match prefill_response.bytes().await { Ok(body) => Some(body), Err(e) => { warn!("Failed to read prefill response body for logprobs: {}", e); None } } } else { // For non-logprob requests, just consume the response without storing debug!("Consuming prefill response body (non-logprob request)"); match prefill_response.bytes().await { Ok(_) => debug!("Prefill response consumed successfully"), Err(e) => warn!("Error consuming prefill response: {}", e), } None }; Ok((prefill_status, prefill_body)) } // Helper to build a request with headers copied from the original request fn build_request_with_headers( &self, url: &str, route: &str, json_request: &Value, headers: Option<&HeaderMap>, ) -> reqwest::RequestBuilder { let mut request = self.client.post(api_path(url, route)).json(json_request); // Copy headers from original request (excluding content-type and content-length which are set by .json()) if let Some(headers) = headers { for (name, value) in headers.iter() { let name_str = name.as_str(); if name_str != "content-type" && name_str != "content-length" { // Skip headers with non-ASCII values if value.to_str().is_ok() { request = request.header(name, value); } } } } request } // Helper to merge logprobs from prefill and decode responses fn merge_logprobs_in_json(prefill_json: &Value, decode_json: &mut Value) -> bool { if let (Some(prefill_meta), Some(decode_meta)) = ( prefill_json.get("meta_info"), decode_json.get_mut("meta_info"), ) { if let (Some(prefill_logprobs), Some(decode_logprobs)) = ( prefill_meta.get("input_token_logprobs"), decode_meta.get_mut("input_token_logprobs"), ) { if let (Some(prefill_arr), Some(decode_arr)) = (prefill_logprobs.as_array(), decode_logprobs.as_array_mut()) { let mut merged = prefill_arr.clone(); merged.extend(decode_arr.clone()); decode_meta["input_token_logprobs"] = Value::Array(merged); return true; } } } false } // Simple helper to merge logprobs in streaming responses fn merge_streaming_logprobs( prefill_logprobs: Option, decode_chunk: &[u8], ) -> Result { // Skip non-data chunks let chunk_str = std::str::from_utf8(decode_chunk).map_err(|_| ())?; if !chunk_str.starts_with("data: ") || chunk_str.contains("[DONE]") { return Err(()); } // Parse JSON from chunk let json_str = chunk_str.trim_start_matches("data: ").trim(); let mut decode_json: Value = serde_json::from_str(json_str).map_err(|_| ())?; // Merge prefill logprobs if available if let Some(ref p_logprobs) = prefill_logprobs { if let Some(meta) = decode_json.get_mut("meta_info") { if let Some(d_logprobs) = meta.get_mut("input_token_logprobs") { if let (Some(p_arr), Some(d_arr)) = (p_logprobs.as_array(), d_logprobs.as_array()) { let mut merged = p_arr.clone(); merged.extend(d_arr.clone()); *d_logprobs = Value::Array(merged); } } } } // Re-serialize let merged_str = format!( "data: {}\n\n", serde_json::to_string(&decode_json).unwrap_or_default() ); Ok(bytes::Bytes::from(merged_str)) } } // Helper functions async fn get_worker_load(client: &Client, worker_url: &str) -> Option { match client.get(format!("{}/get_load", worker_url)).send().await { Ok(res) if res.status().is_success() => match res.bytes().await { Ok(bytes) => match serde_json::from_slice::(&bytes) { Ok(data) => data .get("load") .and_then(|v| v.as_i64()) .map(|v| v as isize), Err(e) => { debug!("Failed to parse load response from {}: {}", worker_url, e); None } }, Err(e) => { debug!("Failed to read load response from {}: {}", worker_url, e); None } }, Ok(res) => { debug!( "Worker {} returned non-success status: {}", worker_url, res.status() ); None } Err(e) => { debug!("Failed to get load from {}: {}", worker_url, e); None } } } #[async_trait] impl WorkerManagement for PDRouter { async fn add_worker(&self, _worker_url: &str) -> Result { // For PD router, we don't support adding workers via this generic method Err( "PD router requires specific add_prefill_server or add_decode_server methods" .to_string(), ) } fn remove_worker(&self, worker_url: &str) { // For PD router, we would need to know if it's a prefill or decode server // For now, try both if let Ok(mut workers) = self.prefill_workers.write() { if let Some(index) = workers.iter().position(|w| w.url() == worker_url) { workers.remove(index); info!("Removed prefill worker: {}", worker_url); return; } } if let Ok(mut workers) = self.decode_workers.write() { if let Some(index) = workers.iter().position(|w| w.url() == worker_url) { workers.remove(index); info!("Removed decode worker: {}", worker_url); } } } fn get_worker_urls(&self) -> Vec { let mut urls = Vec::new(); // Add prefill worker URLs if let Ok(workers) = self.prefill_workers.read() { for worker in workers.iter() { urls.push(worker.url().to_string()); } } // Add decode worker URLs if let Ok(workers) = self.decode_workers.read() { for worker in workers.iter() { urls.push(worker.url().to_string()); } } urls } } #[async_trait] impl RouterTrait for PDRouter { fn as_any(&self) -> &dyn std::any::Any { self } async fn health(&self, _req: Request) -> Response { // This is a server readiness check - checking if we have healthy workers // Workers handle their own health checks in the background let mut all_healthy = true; let mut unhealthy_servers = Vec::new(); // Check prefill servers for worker in self.prefill_workers.read().unwrap().iter() { if !worker.is_healthy() { all_healthy = false; unhealthy_servers.push(format!("Prefill: {}", worker.url())); } } // Check decode servers for worker in self.decode_workers.read().unwrap().iter() { if !worker.is_healthy() { all_healthy = false; unhealthy_servers.push(format!("Decode: {}", worker.url())); } } if all_healthy { (StatusCode::OK, "All servers healthy").into_response() } else { ( StatusCode::SERVICE_UNAVAILABLE, format!("Unhealthy servers: {:?}", unhealthy_servers), ) .into_response() } } async fn health_generate(&self, _req: Request) -> Response { // Test model generation capability by selecting a random pair and testing them // Note: This endpoint actually causes the model to generate tokens, so we only test one pair // Select a random worker pair using the policy let (prefill, decode) = match self.select_pd_pair(None).await { Ok(pair) => pair, Err(e) => { return ( StatusCode::SERVICE_UNAVAILABLE, format!("No healthy worker pair available: {}", e), ) .into_response(); } }; // Test prefill server's health_generate let prefill_url = format!("{}/health_generate", prefill.url()); let prefill_result = self.client.get(&prefill_url).send().await; // Test decode server's health_generate let decode_url = format!("{}/health_generate", decode.url()); let decode_result = self.client.get(&decode_url).send().await; // Check results let mut errors = Vec::new(); match prefill_result { Ok(res) if res.status().is_success() => { debug!( "Health generate passed for prefill server: {}", prefill.url() ); } Ok(res) => { errors.push(format!( "Prefill {} returned status {}", prefill.url(), res.status() )); } Err(e) => { errors.push(format!("Prefill {} error: {}", prefill.url(), e)); } } match decode_result { Ok(res) if res.status().is_success() => { debug!("Health generate passed for decode server: {}", decode.url()); } Ok(res) => { errors.push(format!( "Decode {} returned status {}", decode.url(), res.status() )); } Err(e) => { errors.push(format!("Decode {} error: {}", decode.url(), e)); } } if errors.is_empty() { ( StatusCode::OK, format!( "Health generate passed on selected pair: prefill={}, decode={}", prefill.url(), decode.url() ), ) .into_response() } else { ( StatusCode::SERVICE_UNAVAILABLE, format!("Health generate failed: {:?}", errors), ) .into_response() } } async fn get_server_info(&self, _req: Request) -> Response { // Get info from the first decode server to match sglang's server info format let first_decode_url = if let Ok(workers) = self.decode_workers.read() { workers.first().map(|w| w.url().to_string()) } else { return ( StatusCode::INTERNAL_SERVER_ERROR, "Failed to access decode workers", ) .into_response(); }; if let Some(worker_url) = first_decode_url { match self .client .get(format!("{}/get_server_info", worker_url)) .send() .await { Ok(res) if res.status().is_success() => { match res.json::().await { Ok(info) => { // The decode server should already return the proper format // with tokenizer_path and other fields that bench_one_batch_server.py expects Json(info).into_response() } Err(e) => { error!("Failed to parse server info: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to parse server info: {}", e), ) .into_response() } } } Ok(res) => { let status = StatusCode::from_u16(res.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); ( status, format!("Decode server returned status: {}", res.status()), ) .into_response() } Err(e) => { error!("Failed to get server info: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to get server info: {}", e), ) .into_response() } } } else { ( StatusCode::SERVICE_UNAVAILABLE, "No decode servers available", ) .into_response() } } async fn get_models(&self, req: Request) -> Response { // Extract headers first to avoid Send issues let headers = crate::routers::router::copy_request_headers(&req); // Get first prefill worker URL to avoid holding lock across await let first_worker_url = if let Ok(workers) = self.prefill_workers.read() { workers.first().map(|w| w.url().to_string()) } else { return ( StatusCode::INTERNAL_SERVER_ERROR, "Failed to access prefill workers", ) .into_response(); }; if let Some(worker_url) = first_worker_url { let url = format!("{}/v1/models", worker_url); let mut request_builder = self.client.get(&url); // Add headers for (name, value) in headers { request_builder = request_builder.header(name, value); } match request_builder.send().await { Ok(res) if res.status().is_success() => match res.bytes().await { Ok(body) => (StatusCode::OK, body).into_response(), Err(e) => { error!("Failed to read response body: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to read response body: {}", e), ) .into_response() } }, Ok(res) => { let status = StatusCode::from_u16(res.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); ( status, format!("Prefill server returned status: {}", res.status()), ) .into_response() } Err(e) => { error!("Failed to get models: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to get models: {}", e), ) .into_response() } } } else { ( StatusCode::SERVICE_UNAVAILABLE, "No prefill servers available", ) .into_response() } } async fn get_model_info(&self, req: Request) -> Response { // Extract headers first to avoid Send issues let headers = crate::routers::router::copy_request_headers(&req); // Get first prefill worker URL to avoid holding lock across await let first_worker_url = if let Ok(workers) = self.prefill_workers.read() { workers.first().map(|w| w.url().to_string()) } else { return ( StatusCode::INTERNAL_SERVER_ERROR, "Failed to access prefill workers", ) .into_response(); }; if let Some(worker_url) = first_worker_url { let url = format!("{}/get_model_info", worker_url); let mut request_builder = self.client.get(&url); // Add headers for (name, value) in headers { request_builder = request_builder.header(name, value); } match request_builder.send().await { Ok(res) if res.status().is_success() => match res.bytes().await { Ok(body) => (StatusCode::OK, body).into_response(), Err(e) => { error!("Failed to read response body: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to read response body: {}", e), ) .into_response() } }, Ok(res) => { let status = StatusCode::from_u16(res.status().as_u16()) .unwrap_or(StatusCode::INTERNAL_SERVER_ERROR); ( status, format!("Prefill server returned status: {}", res.status()), ) .into_response() } Err(e) => { error!("Failed to get model info: {}", e); ( StatusCode::INTERNAL_SERVER_ERROR, format!("Failed to get model info: {}", e), ) .into_response() } } } else { ( StatusCode::SERVICE_UNAVAILABLE, "No prefill servers available", ) .into_response() } } async fn route_generate( &self, headers: Option<&HeaderMap>, body: &GenerateRequest, ) -> Response { let start = Instant::now(); // Extract flags for routing logic let is_stream = body.stream; let return_logprob = body.return_logprob; // Extract text for cache-aware routing only if needed let request_text = if self.policies_need_request_text() { body.text.as_deref().or_else(|| { body.prompt.as_ref().and_then(|p| match p { crate::openai_api_types::StringOrArray::String(s) => Some(s.as_str()), crate::openai_api_types::StringOrArray::Array(v) => { v.first().map(|s| s.as_str()) } }) }) } else { None }; // Select servers let (prefill, decode) = match self.select_pd_pair(request_text).await { Ok(pair) => pair, Err(e) => return Self::handle_server_selection_error(e), }; // Log routing decision info!( "PD routing decision route=/generate prefill_url={} decode_url={}", prefill.url(), decode.url() ); // Create optimized request with bootstrap fields let batch_size = Self::get_generate_batch_size(body); let json = match Self::create_request_with_bootstrap(body, prefill.as_ref(), batch_size) { Ok(json) => json, Err(e) => return Self::handle_serialization_error(e), }; // Execute dual dispatch self.execute_dual_dispatch( headers, json, "/generate", prefill.as_ref(), decode.as_ref(), is_stream, return_logprob, start, ) .await } async fn route_chat( &self, headers: Option<&HeaderMap>, body: &ChatCompletionRequest, ) -> Response { let start = Instant::now(); // Extract flags for routing logic let is_stream = body.stream; let return_logprob = body.logprobs; // Extract text for cache-aware routing from chat messages only if needed let request_text = if self.policies_need_request_text() { body.messages.first().and_then(|msg| match msg { crate::openai_api_types::ChatMessage::User { content, .. } => { match content { crate::openai_api_types::UserMessageContent::Text(text) => { Some(text.as_str()) } crate::openai_api_types::UserMessageContent::Parts(_) => None, // Skip complex content } } crate::openai_api_types::ChatMessage::System { content, .. } => { Some(content.as_str()) } _ => None, }) } else { None }; // Select servers let (prefill, decode) = match self.select_pd_pair(request_text).await { Ok(pair) => pair, Err(e) => return Self::handle_server_selection_error(e), }; // Log routing decision info!( "PD routing decision route=/v1/chat/completions prefill_url={} decode_url={}", prefill.url(), decode.url() ); // Create optimized request with bootstrap fields let batch_size = Self::get_chat_batch_size(body); let json = match Self::create_request_with_bootstrap(body, prefill.as_ref(), batch_size) { Ok(json) => json, Err(e) => return Self::handle_serialization_error(e), }; // Execute dual dispatch self.execute_dual_dispatch( headers, json, "/v1/chat/completions", prefill.as_ref(), decode.as_ref(), is_stream, return_logprob, start, ) .await } async fn route_completion( &self, headers: Option<&HeaderMap>, body: &CompletionRequest, ) -> Response { let start = Instant::now(); // Extract flags for routing logic let is_stream = body.stream; let return_logprob = body.logprobs.is_some(); // Extract text for cache-aware routing only if needed let request_text = if self.policies_need_request_text() { match &body.prompt { crate::openai_api_types::StringOrArray::String(s) => Some(s.as_str()), crate::openai_api_types::StringOrArray::Array(v) => v.first().map(|s| s.as_str()), } } else { None }; // Select servers let (prefill, decode) = match self.select_pd_pair(request_text).await { Ok(pair) => pair, Err(e) => return Self::handle_server_selection_error(e), }; // Log routing decision info!( "PD routing decision route=/v1/completions prefill_url={} decode_url={}", prefill.url(), decode.url() ); // Create optimized request with bootstrap fields let batch_size = Self::get_completion_batch_size(body); let json = match Self::create_request_with_bootstrap(body, prefill.as_ref(), batch_size) { Ok(json) => json, Err(e) => return Self::handle_serialization_error(e), }; // Execute dual dispatch self.execute_dual_dispatch( headers, json, "/v1/completions", prefill.as_ref(), decode.as_ref(), is_stream, return_logprob, start, ) .await } async fn flush_cache(&self) -> Response { let mut results = Vec::new(); let mut errors = Vec::new(); // Get prefill worker URLs first to avoid holding lock across await let prefill_urls = if let Ok(workers) = self.prefill_workers.read() { workers .iter() .map(|w| w.url().to_string()) .collect::>() } else { errors.push("Failed to access prefill workers".to_string()); Vec::new() }; // Flush prefill workers for worker_url in prefill_urls { let url = format!("{}/flush_cache", worker_url); match self.client.post(&url).send().await { Ok(res) if res.status().is_success() => { results.push(format!("Prefill {}: OK", worker_url)); } Ok(res) => { errors.push(format!( "Prefill {} returned status: {}", worker_url, res.status() )); } Err(e) => { errors.push(format!("Prefill {} error: {}", worker_url, e)); } } } // Get decode worker URLs first to avoid holding lock across await let decode_urls = if let Ok(workers) = self.decode_workers.read() { workers .iter() .map(|w| w.url().to_string()) .collect::>() } else { errors.push("Failed to access decode workers".to_string()); Vec::new() }; // Flush decode workers for worker_url in decode_urls { let url = format!("{}/flush_cache", worker_url); match self.client.post(&url).send().await { Ok(res) if res.status().is_success() => { results.push(format!("Decode {}: OK", worker_url)); } Ok(res) => { errors.push(format!( "Decode {} returned status: {}", worker_url, res.status() )); } Err(e) => { errors.push(format!("Decode {} error: {}", worker_url, e)); } } } if errors.is_empty() { ( StatusCode::OK, format!("Cache flushed successfully: {:?}", results), ) .into_response() } else { ( StatusCode::PARTIAL_CONTENT, format!( "Partial success. Results: {:?}, Errors: {:?}", results, errors ), ) .into_response() } } async fn get_worker_loads(&self) -> Response { let mut loads = HashMap::new(); let mut errors = Vec::new(); // Get prefill worker URLs first to avoid holding lock across await let prefill_urls = if let Ok(workers) = self.prefill_workers.read() { workers .iter() .map(|w| w.url().to_string()) .collect::>() } else { errors.push("Failed to access prefill workers".to_string()); Vec::new() }; // Get loads from prefill workers for worker_url in prefill_urls { match get_worker_load(&self.client, &worker_url).await { Some(load) => { loads.insert(format!("prefill_{}", worker_url), load); } None => { errors.push(format!("Failed to get load from prefill {}", worker_url)); } } } // Get decode worker URLs first to avoid holding lock across await let decode_urls = if let Ok(workers) = self.decode_workers.read() { workers .iter() .map(|w| w.url().to_string()) .collect::>() } else { errors.push("Failed to access decode workers".to_string()); Vec::new() }; // Get loads from decode workers for worker_url in decode_urls { match get_worker_load(&self.client, &worker_url).await { Some(load) => { loads.insert(format!("decode_{}", worker_url), load); } None => { errors.push(format!("Failed to get load from decode {}", worker_url)); } } } let response_data = serde_json::json!({ "loads": loads, "errors": errors }); (StatusCode::OK, Json(response_data)).into_response() } fn router_type(&self) -> &'static str { "pd" } fn readiness(&self) -> Response { // PD router is ready if it has at least one healthy prefill AND one healthy decode worker let healthy_prefill_count = self .prefill_workers .read() .unwrap() .iter() .filter(|w| w.is_healthy()) .count(); let healthy_decode_count = self .decode_workers .read() .unwrap() .iter() .filter(|w| w.is_healthy()) .count(); let total_prefill = self.prefill_workers.read().unwrap().len(); let total_decode = self.decode_workers.read().unwrap().len(); if healthy_prefill_count > 0 && healthy_decode_count > 0 { Json(serde_json::json!({ "status": "ready", "prefill": { "healthy": healthy_prefill_count, "total": total_prefill }, "decode": { "healthy": healthy_decode_count, "total": total_decode } })) .into_response() } else { let mut reasons = Vec::new(); if healthy_prefill_count == 0 { reasons.push("no healthy prefill workers"); } if healthy_decode_count == 0 { reasons.push("no healthy decode workers"); } ( StatusCode::SERVICE_UNAVAILABLE, Json(serde_json::json!({ "status": "not_ready", "reason": reasons.join(", "), "prefill": { "healthy": healthy_prefill_count, "total": total_prefill }, "decode": { "healthy": healthy_decode_count, "total": total_decode } })), ) .into_response() } } } #[cfg(test)] mod tests { use super::*; use crate::core::{BasicWorker, WorkerType}; use crate::policies::{CacheAwarePolicy, RandomPolicy}; fn create_test_pd_router() -> PDRouter { let prefill_policy = Arc::new(RandomPolicy::new()); let decode_policy = Arc::new(RandomPolicy::new()); PDRouter { prefill_workers: Arc::new(RwLock::new(vec![])), decode_workers: Arc::new(RwLock::new(vec![])), prefill_policy, decode_policy, prefill_tree: None, decode_tree: None, timeout_secs: 5, interval_secs: 1, worker_loads: Arc::new(tokio::sync::watch::channel(HashMap::new()).1), load_monitor_handle: None, client: Client::new(), retry_config: RetryConfig::default(), _prefill_health_checker: None, _decode_health_checker: None, } } fn create_test_worker(url: String, worker_type: WorkerType, healthy: bool) -> Box { let worker = BasicWorker::new(url, worker_type); worker.set_healthy(healthy); Box::new(worker) } // ============= Worker Management Tests ============= #[tokio::test] async fn test_add_prefill_server_already_exists() { let router = create_test_pd_router(); // Add a worker first let worker = create_test_worker( "http://localhost:8000".to_string(), WorkerType::Prefill { bootstrap_port: Some(8080), }, true, ); router.prefill_workers.write().unwrap().push(worker); // Try to add the same URL again - this would fail during health check in real scenario // For unit test, we test the duplicate check logic let workers = router.prefill_workers.read().unwrap(); let exists = workers.iter().any(|w| w.url() == "http://localhost:8000"); assert!(exists); } #[tokio::test] async fn test_remove_prefill_server_success() { let router = create_test_pd_router(); // Add servers first let worker1 = create_test_worker( "http://worker1".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); let worker2 = create_test_worker( "http://worker2".to_string(), WorkerType::Prefill { bootstrap_port: Some(8080), }, true, ); router.prefill_workers.write().unwrap().push(worker1); router.prefill_workers.write().unwrap().push(worker2); // Remove one let result = router.remove_prefill_server("http://worker1").await; assert!(result.is_ok()); assert!(result.unwrap().contains("Successfully removed")); let workers = router.prefill_workers.read().unwrap(); assert_eq!(workers.len(), 1); assert_eq!(workers[0].url(), "http://worker2"); } #[tokio::test] async fn test_remove_prefill_server_not_found() { let router = create_test_pd_router(); let result = router.remove_prefill_server("http://nonexistent").await; assert!(result.is_err()); match result.unwrap_err() { PDRouterError::WorkerNotFound { url } => { assert_eq!(url, "http://nonexistent"); } _ => panic!("Expected WorkerNotFound error"), } } #[tokio::test] async fn test_remove_decode_server_success() { let router = create_test_pd_router(); // Add server first let worker = create_test_worker("http://decode1".to_string(), WorkerType::Decode, true); router.decode_workers.write().unwrap().push(worker); let result = router.remove_decode_server("http://decode1").await; assert!(result.is_ok()); assert!(result.unwrap().contains("Successfully removed")); let workers = router.decode_workers.read().unwrap(); assert_eq!(workers.len(), 0); } // ============= Lock Error Handling Tests ============= #[test] fn test_lock_operations() { let router = create_test_pd_router(); // Test read/write locks work correctly { let read_guard = router.prefill_workers.read().unwrap(); assert_eq!(read_guard.len(), 0); } { let mut write_guard = router.prefill_workers.write().unwrap(); write_guard.push(create_test_worker( "http://test".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, )); } { let read_guard = router.prefill_workers.read().unwrap(); assert_eq!(read_guard.len(), 1); } } // ============= Cache Tree Integration Tests ============= #[tokio::test] async fn test_cache_tree_operations() { let cache_policy = Arc::new(CacheAwarePolicy::new()); let mut router = create_test_pd_router(); router.prefill_policy = cache_policy; // Initialize cache tree let tree = Arc::new(Mutex::new(Tree::new())); router.prefill_tree = Some(Arc::clone(&tree)); // Manually add worker and update tree let worker = create_test_worker( "http://worker1".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); router.prefill_workers.write().unwrap().push(worker); // Update tree tree.lock().unwrap().insert("", "http://worker1"); // Verify tree contains the worker let tree_guard = tree.lock().unwrap(); let (_matched_text, tenant) = tree_guard.prefix_match(""); // Since we inserted with empty prefix, we should get a match assert_eq!(tenant, "http://worker1"); } #[tokio::test] async fn test_cache_tree_rebuild_on_remove() { let cache_policy = Arc::new(CacheAwarePolicy::new()); let mut router = create_test_pd_router(); router.prefill_policy = cache_policy; // Initialize cache tree let tree = Arc::new(Mutex::new(Tree::new())); router.prefill_tree = Some(Arc::clone(&tree)); // Add multiple workers let worker1 = create_test_worker( "http://worker1".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); let worker2 = create_test_worker( "http://worker2".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); router.prefill_workers.write().unwrap().push(worker1); router.prefill_workers.write().unwrap().push(worker2); // Initialize tree with both workers { let tree_guard = tree.lock().unwrap(); tree_guard.insert("", "http://worker1"); tree_guard.insert("", "http://worker2"); } // Remove one worker let result = router.remove_prefill_server("http://worker1").await; assert!(result.is_ok()); // Verify tree only contains remaining worker let tree_guard = tree.lock().unwrap(); let (_matched_text, tenant) = tree_guard.prefix_match(""); // After rebuild, tree should only have worker2 assert_eq!(tenant, "http://worker2"); } #[tokio::test] async fn test_no_cache_tree_operations() { let router = create_test_pd_router(); assert!(router.prefill_tree.is_none()); // Add a worker without cache tree let worker = create_test_worker( "http://worker1".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); router.prefill_workers.write().unwrap().push(worker); // Remove should work without tree let result = router.remove_prefill_server("http://worker1").await; assert!(result.is_ok()); } // ============= Bootstrap Injection Tests ============= // Note: These tests are commented out as we've moved to the optimized bootstrap injection // approach that doesn't use the Bootstrap trait on GenerateReqInput anymore. // TODO: Add new tests for the optimized bootstrap injection approach using // RequestWithBootstrap and BatchRequestWithBootstrap wrappers // ============= Worker Selection Tests ============= #[tokio::test] async fn test_select_healthy_prefill_worker() { let router = create_test_pd_router(); // Add mix of healthy and unhealthy workers let healthy_worker = create_test_worker( "http://healthy".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); let unhealthy_worker = create_test_worker( "http://unhealthy".to_string(), WorkerType::Prefill { bootstrap_port: None, }, false, ); let decode_worker = create_test_worker("http://decode".to_string(), WorkerType::Decode, true); router .prefill_workers .write() .unwrap() .push(unhealthy_worker); router.prefill_workers.write().unwrap().push(healthy_worker); router.decode_workers.write().unwrap().push(decode_worker); let result = router.select_pd_pair(None).await; assert!(result.is_ok()); let (prefill, _decode) = result.unwrap(); // Should select the healthy worker assert_eq!(prefill.url(), "http://healthy"); assert!(prefill.is_healthy()); } #[tokio::test] async fn test_empty_worker_lists() { let router = create_test_pd_router(); let result = router.select_pd_pair(None).await; assert!(result.is_err()); assert!(result.unwrap_err().contains("No prefill workers available")); } // ============= Health Endpoints Tests ============= #[tokio::test] async fn test_health_endpoints() { let router = create_test_pd_router(); // Add healthy workers let prefill_worker = create_test_worker( "http://localhost:8000".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); let decode_worker = create_test_worker( "http://localhost:8001".to_string(), WorkerType::Decode, true, ); router.prefill_workers.write().unwrap().push(prefill_worker); router.decode_workers.write().unwrap().push(decode_worker); // Test health endpoint let http_req = axum::http::Request::builder() .body(axum::body::Body::empty()) .unwrap(); let response = router.health(http_req).await; assert_eq!(response.status(), 200); // Test readiness endpoint let response = router.readiness(); assert_eq!(response.status(), 200); } // ============= Load Monitoring Tests ============= #[tokio::test] async fn test_load_monitor_updates() { let power_of_two_policy = Arc::new(crate::policies::PowerOfTwoPolicy::new()); let mut router = create_test_pd_router(); router.prefill_policy = power_of_two_policy.clone(); router.decode_policy = power_of_two_policy; // Create load channel let (tx, rx) = tokio::sync::watch::channel(HashMap::new()); router.worker_loads = Arc::new(rx); // Simulate load updates let mut loads = HashMap::new(); loads.insert("http://worker1".to_string(), 10); loads.insert("http://worker2".to_string(), 5); let _ = tx.send(loads.clone()); // Router should receive updates let received = router.worker_loads.borrow().clone(); assert_eq!(received.get("http://worker1"), Some(&10)); assert_eq!(received.get("http://worker2"), Some(&5)); } // ============= Worker Load Tests ============= #[test] fn test_worker_load_metrics() { let prefill_worker = create_test_worker( "http://prefill".to_string(), WorkerType::Prefill { bootstrap_port: None, }, true, ); let decode_worker = create_test_worker("http://decode".to_string(), WorkerType::Decode, true); // Create load guard for both workers let _guard = WorkerLoadGuard::new_multi(vec![prefill_worker.as_ref(), decode_worker.as_ref()]); // Load should be incremented assert_eq!(prefill_worker.load(), 1); assert_eq!(decode_worker.load(), 1); // Drop guard - load should decrement drop(_guard); assert_eq!(prefill_worker.load(), 0); assert_eq!(decode_worker.load(), 0); } // ============= Concurrent Operations Tests ============= #[tokio::test] async fn test_concurrent_worker_operations() { let router = Arc::new(create_test_pd_router()); let mut handles = vec![]; // Spawn tasks to add workers for i in 0..5 { let router_clone = Arc::clone(&router); let url = format!("http://worker{}", i); let handle = tokio::spawn(async move { let worker = create_test_worker( url, WorkerType::Prefill { bootstrap_port: None, }, true, ); router_clone.prefill_workers.write().unwrap().push(worker); }); handles.push(handle); } // Wait for all tasks for handle in handles { let _ = handle.await; } // Check final state let workers = router.prefill_workers.read().unwrap(); assert_eq!(workers.len(), 5); } }