metrics.rs

// SPDX-FileCopyrightText: Copyright (c) 2024-2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
// SPDX-License-Identifier: Apache-2.0

use axum::{
    Router,
    extract::State,
    http::StatusCode,
    response::{IntoResponse, sse::Event},
    routing::get,
};
use dynamo_runtime::metrics::prometheus_names::{
    frontend_service, name_prefix, sanitize_frontend_prometheus_prefix,
};
use prometheus::{Encoder, HistogramOpts, HistogramVec, IntCounterVec, IntGaugeVec, Opts};
use serde::Serialize;
use std::{
    sync::Arc,
    time::{Duration, Instant},
};

use crate::discovery::ModelEntry;
use crate::local_model::runtime_config::ModelRuntimeConfig;
use crate::model_card::{ModelDeploymentCard, ROOT_PATH as MDC_ROOT_PATH};
use dynamo_runtime::metrics::prometheus_names::clamp_u64_to_i64;
use dynamo_runtime::slug::Slug;
use dynamo_runtime::storage::key_value_store::{EtcdStorage, KeyValueStore, KeyValueStoreManager};

pub use prometheus::Registry;

use super::RouteDoc;

pub struct Metrics {
    request_counter: IntCounterVec,
    inflight_gauge: IntGaugeVec,
    client_disconnect_gauge: prometheus::IntGauge,
    http_queue_gauge: IntGaugeVec,
    request_duration: HistogramVec,
    input_sequence_length: HistogramVec,
    output_sequence_length: HistogramVec,
    time_to_first_token: HistogramVec,
    inter_token_latency: HistogramVec,

    // Runtime configuration metrics. Note: Some of these metrics represent counter-like values from
    // source systems, but are implemented as gauges because they are copied/synchronized from upstream
    // counter values rather than being directly incremented.
    model_total_kv_blocks: IntGaugeVec,
    model_max_num_seqs: IntGaugeVec,
    model_max_num_batched_tokens: IntGaugeVec,
    model_context_length: IntGaugeVec,
    model_kv_cache_block_size: IntGaugeVec,
    model_migration_limit: IntGaugeVec,
}

// Inflight tracks requests from HTTP handler start until complete response is finished.
// HTTP queue tracks requests from HTTP handler start until first token generation begins (including prefill time).
// HTTP queue time is a subset of inflight time. For detailed explanation, see:
// deploy/metrics/README.md - "Request Processing Flow" section

/// RAII object for HTTP queue gauge
/// Tracks requests from HTTP handler start until metrics processing begins
pub struct HttpQueueGuard {
    metrics: Arc<Metrics>,
    model: String,
}

/// RAII object for inflight gauge and request counters
/// If this object is dropped without calling `mark_ok`, then the request will increment
/// the request counter with the `status` label with [`frontend_service::status::ERROR`]; otherwise, it will increment
/// the counter with `status` label [`frontend_service::status::SUCCESS`]
pub struct InflightGuard {
    metrics: Arc<Metrics>,
    model: String,
    endpoint: Endpoint,
    request_type: RequestType,
    status: Status,
    timer: Instant,
}

/// Requests will be logged by the type of endpoint hit
/// This will include llamastack in the future
pub enum Endpoint {
    /// OAI Completions
    Completions,

    /// OAI Chat Completions
    ChatCompletions,

    /// OAI Embeddings
    Embeddings,

    /// OAI Responses
    Responses,

    /// Tensor
    Tensor,
}

/// Metrics for the HTTP service
pub enum RequestType {
    /// SingleIn / SingleOut
    Unary,

    /// SingleIn / ManyOut
    Stream,
}

/// Status
#[derive(PartialEq)]
pub enum Status {
    Success,
    Error,
}

/// Track response-specific metrics
pub struct ResponseMetricCollector {
    metrics: Arc<Metrics>,
    model: String,
    start_time: Instant,
    // we use is_first_token to distinguish TTFT from ITL. It is true by default and
    // flipped to false when the first token is returned and TTFT is published.
    is_first_token: bool,
    // we track the last response time so that ITL for the newly returned tokens can
    // be computed.
    last_response_time: Option<Duration>,
    osl: usize,
}

impl Default for Metrics {
    fn default() -> Self {
        Self::new()
    }
}

impl Metrics {
    /// Create Metrics with the standard prefix defined by [`name_prefix::FRONTEND`] or specify custom prefix via the following environment variable:
    /// - `DYN_METRICS_PREFIX`: Override the default metrics prefix
    ///
    /// The following metrics will be created with the configured prefix:
    /// - `{prefix}_requests_total` - IntCounterVec for the total number of requests processed
    /// - `{prefix}_inflight_requests` - IntGaugeVec for the number of inflight requests
    /// - `{prefix}_request_duration_seconds` - HistogramVec for the duration of requests
    /// - `{prefix}_input_sequence_tokens` - HistogramVec for input sequence length in tokens
    /// - `{prefix}_output_sequence_tokens` - HistogramVec for output sequence length in tokens
    /// - `{prefix}_time_to_first_token_seconds` - HistogramVec for time to first token in seconds
    /// - `{prefix}_inter_token_latency_seconds` - HistogramVec for inter-token latency in seconds
    ///
    /// ## Model Configuration Metrics
    ///
    /// Runtime config metrics (from ModelRuntimeConfig):
    /// - `{prefix}_model_total_kv_blocks` - IntGaugeVec for total KV cache blocks available for a worker serving the model
    /// - `{prefix}_model_max_num_seqs` - IntGaugeVec for maximum sequences for a worker serving the model
    /// - `{prefix}_model_max_num_batched_tokens` - IntGaugeVec for maximum batched tokens for a worker serving the model
    ///
    /// MDC metrics (from ModelDeploymentCard):
    /// - `{prefix}_model_context_length` - IntGaugeVec for maximum context length for a worker serving the model
    /// - `{prefix}_model_kv_cache_block_size` - IntGaugeVec for KV cache block size for a worker serving the model
    /// - `{prefix}_model_migration_limit` - IntGaugeVec for request migration limit for a worker serving the model
    ///
    /// ## Runtime Config Polling Configuration
    ///
    /// The polling behavior can be configured via environment variables:
    /// - `DYN_HTTP_SVC_CONFIG_METRICS_POLL_INTERVAL_SECS`: Poll interval in seconds (must be > 0, supports fractional seconds, defaults to 8)
    ///
    /// Metrics are never removed to preserve historical data. Runtime config and MDC
    /// metrics are updated when models are discovered and their configurations are available.
    pub fn new() -> Self {
        let raw_prefix = std::env::var(frontend_service::METRICS_PREFIX_ENV)
            .unwrap_or_else(|_| name_prefix::FRONTEND.to_string());
        let prefix = sanitize_frontend_prometheus_prefix(&raw_prefix);
        if prefix != raw_prefix {
            tracing::warn!(
                raw=%raw_prefix,
                sanitized=%prefix,
                env=%frontend_service::METRICS_PREFIX_ENV,
                "Sanitized HTTP metrics prefix"
            );
        }
        let frontend_metric_name = |suffix: &str| format!("{}_{}", &prefix, suffix);

        let request_counter = IntCounterVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::REQUESTS_TOTAL),
                "Total number of LLM requests processed",
            ),
            &["model", "endpoint", "request_type", "status"],
        )
        .unwrap();

        let inflight_gauge = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::INFLIGHT_REQUESTS_TOTAL),
                "Number of inflight requests",
            ),
            &["model"],
        )
        .unwrap();

        let client_disconnect_gauge = prometheus::IntGauge::new(
            frontend_metric_name("client_disconnects"),
            "Number of connections dropped by clients",
        )
        .unwrap();

        let http_queue_gauge = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::QUEUED_REQUESTS_TOTAL),
                "Number of requests in HTTP processing queue",
            ),
            &["model"],
        )
        .unwrap();

        let buckets = vec![0.0, 1.0, 2.0, 4.0, 8.0, 16.0, 32.0, 64.0, 128.0, 256.0];

        let request_duration = HistogramVec::new(
            HistogramOpts::new(
                frontend_metric_name(frontend_service::REQUEST_DURATION_SECONDS),
                "Duration of LLM requests",
            )
            .buckets(buckets),
            &["model"],
        )
        .unwrap();

        let input_sequence_length = HistogramVec::new(
            HistogramOpts::new(
                frontend_metric_name(frontend_service::INPUT_SEQUENCE_TOKENS),
                "Input sequence length in tokens",
            )
            .buckets(vec![
                0.0, 50.0, 100.0, 500.0, 1000.0, 2000.0, 4000.0, 8000.0, 16000.0, 32000.0, 64000.0,
                128000.0,
            ]),
            &["model"],
        )
        .unwrap();

        let output_sequence_length = HistogramVec::new(
            HistogramOpts::new(
                frontend_metric_name(frontend_service::OUTPUT_SEQUENCE_TOKENS),
                "Output sequence length in tokens",
            )
            .buckets(vec![
                0.0, 50.0, 100.0, 500.0, 1000.0, 2000.0, 4000.0, 8000.0, 16000.0, 32000.0,
            ]),
            &["model"],
        )
        .unwrap();

        let time_to_first_token = HistogramVec::new(
            HistogramOpts::new(
                frontend_metric_name(frontend_service::TIME_TO_FIRST_TOKEN_SECONDS),
                "Time to first token in seconds",
            )
            .buckets(vec![
                0.0, 0.001, 0.005, 0.01, 0.025, 0.05, 0.1, 0.25, 0.5, 1.0, 2.0, 5.0, 10.0, 30.0,
                60.0, 120.0, 240.0, 480.0,
            ]),
            &["model"],
        )
        .unwrap();

        let inter_token_latency = HistogramVec::new(
            HistogramOpts::new(
                frontend_metric_name(frontend_service::INTER_TOKEN_LATENCY_SECONDS),
                "Inter-token latency in seconds",
            )
            .buckets(vec![
                0.0, 0.001, 0.005, 0.01, 0.015, 0.02, 0.025, 0.05, 0.1, 0.25, 0.5, 1.0, 2.0,
            ]),
            &["model"],
        )
        .unwrap();

        // Runtime configuration metrics
        // Note: Some of these metrics represent counter-like values from source systems,
        // but are implemented as gauges because they are copied/synchronized from upstream
        // counter values rather than being directly incremented.
        let model_total_kv_blocks = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_TOTAL_KV_BLOCKS),
                "Total KV cache blocks available for a worker serving the model",
            ),
            &["model"],
        )
        .unwrap();

        let model_max_num_seqs = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_MAX_NUM_SEQS),
                "Maximum number of sequences for a worker serving the model",
            ),
            &["model"],
        )
        .unwrap();

        let model_max_num_batched_tokens = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_MAX_NUM_BATCHED_TOKENS),
                "Maximum number of batched tokens for a worker serving the model",
            ),
            &["model"],
        )
        .unwrap();

        let model_context_length = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_CONTEXT_LENGTH),
                "Maximum context length in tokens for a worker serving the model",
            ),
            &["model"],
        )
        .unwrap();

        let model_kv_cache_block_size = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_KV_CACHE_BLOCK_SIZE),
                "KV cache block size in tokens for a worker serving the model",
            ),
            &["model"],
        )
        .unwrap();

        let model_migration_limit = IntGaugeVec::new(
            Opts::new(
                frontend_metric_name(frontend_service::MODEL_MIGRATION_LIMIT),
                "Maximum number of request migrations allowed for the model",
            ),
            &["model"],
        )
        .unwrap();

        Metrics {
            request_counter,
            inflight_gauge,
            client_disconnect_gauge,
            http_queue_gauge,
            request_duration,
            input_sequence_length,
            output_sequence_length,
            time_to_first_token,
            inter_token_latency,
            model_total_kv_blocks,
            model_max_num_seqs,
            model_max_num_batched_tokens,
            model_context_length,
            model_kv_cache_block_size,
            model_migration_limit,
        }
    }

    /// Get the number of successful requests for the given dimensions:
    /// - model
    /// - endpoint (completions/chat_completions)
    /// - request type (unary/stream)
    /// - status (success/error)
    pub fn get_request_counter(
        &self,
        model: &str,
        endpoint: &Endpoint,
        request_type: &RequestType,
        status: &Status,
    ) -> u64 {
        self.request_counter
            .with_label_values(&[
                model,
                endpoint.as_str(),
                request_type.as_str(),
                status.as_str(),
            ])
            .get()
    }

    /// Increment the counter for requests for the given dimensions:
    /// - model
    /// - endpoint (completions/chat_completions)
    /// - request type (unary/stream)
    /// - status (success/error)
    fn inc_request_counter(
        &self,
        model: &str,
        endpoint: &Endpoint,
        request_type: &RequestType,
        status: &Status,
    ) {
        self.request_counter
            .with_label_values(&[
                model,
                endpoint.as_str(),
                request_type.as_str(),
                status.as_str(),
            ])
            .inc()
    }

    /// Get the number if inflight requests for the given model
    pub fn get_inflight_count(&self, model: &str) -> i64 {
        self.inflight_gauge.with_label_values(&[model]).get()
    }

    fn inc_inflight_gauge(&self, model: &str) {
        self.inflight_gauge.with_label_values(&[model]).inc()
    }

    fn dec_inflight_gauge(&self, model: &str) {
        self.inflight_gauge.with_label_values(&[model]).dec()
    }

    /// Increment the gauge for client disconnections
    pub fn inc_client_disconnect(&self) {
        self.client_disconnect_gauge.inc();
    }

    /// Get the count of client disconnections
    pub fn get_client_disconnect_count(&self) -> i64 {
        self.client_disconnect_gauge.get()
    }

    fn inc_http_queue_gauge(&self, model: &str) {
        self.http_queue_gauge.with_label_values(&[model]).inc()
    }

    fn dec_http_queue_gauge(&self, model: &str) {
        self.http_queue_gauge.with_label_values(&[model]).dec()
    }

    pub fn register(&self, registry: &Registry) -> Result<(), prometheus::Error> {
        registry.register(Box::new(self.request_counter.clone()))?;
        registry.register(Box::new(self.inflight_gauge.clone()))?;
        registry.register(Box::new(self.client_disconnect_gauge.clone()))?;
        registry.register(Box::new(self.http_queue_gauge.clone()))?;
        registry.register(Box::new(self.request_duration.clone()))?;
        registry.register(Box::new(self.input_sequence_length.clone()))?;
        registry.register(Box::new(self.output_sequence_length.clone()))?;
        registry.register(Box::new(self.time_to_first_token.clone()))?;
        registry.register(Box::new(self.inter_token_latency.clone()))?;

        // Register runtime configuration metrics
        registry.register(Box::new(self.model_total_kv_blocks.clone()))?;
        registry.register(Box::new(self.model_max_num_seqs.clone()))?;
        registry.register(Box::new(self.model_max_num_batched_tokens.clone()))?;
        registry.register(Box::new(self.model_context_length.clone()))?;
        registry.register(Box::new(self.model_kv_cache_block_size.clone()))?;
        registry.register(Box::new(self.model_migration_limit.clone()))?;

        Ok(())
    }

    /// Update runtime configuration metrics for a model
    /// This should be called when model runtime configuration is available or updated
    pub fn update_runtime_config_metrics(
        &self,
        model_name: &str,
        runtime_config: &ModelRuntimeConfig,
    ) {
        if let Some(total_kv_blocks) = runtime_config.total_kv_blocks {
            self.model_total_kv_blocks
                .with_label_values(&[model_name])
                .set(clamp_u64_to_i64(total_kv_blocks));
        }

        if let Some(max_num_seqs) = runtime_config.max_num_seqs {
            self.model_max_num_seqs
                .with_label_values(&[model_name])
                .set(clamp_u64_to_i64(max_num_seqs));
        }

        if let Some(max_batched_tokens) = runtime_config.max_num_batched_tokens {
            self.model_max_num_batched_tokens
                .with_label_values(&[model_name])
                .set(clamp_u64_to_i64(max_batched_tokens));
        }
    }

    /// Update metrics from a ModelEntry and its ModelDeploymentCard
    /// This updates both runtime config metrics and MDC-specific metrics
    pub async fn update_metrics_from_model_entry_with_mdc(
        &self,
        model_entry: &ModelEntry,
        etcd_client: &dynamo_runtime::transports::etcd::Client,
    ) -> anyhow::Result<()> {
        // Update runtime config metrics
        if let Some(runtime_config) = &model_entry.runtime_config {
            self.update_runtime_config_metrics(&model_entry.name, runtime_config);
        }

        // Load and update MDC metrics
        let model_slug = Slug::from_string(&model_entry.name);
        let store: Box<dyn KeyValueStore> = Box::new(EtcdStorage::new(etcd_client.clone()));
        let card_store = Arc::new(KeyValueStoreManager::new(store));

        match card_store
            .load::<ModelDeploymentCard>(MDC_ROOT_PATH, &model_slug)
            .await
        {
            Ok(Some(mdc)) => {
                // Inline MDC metrics update
                self.model_context_length
                    .with_label_values(&[&model_entry.name])
                    .set(mdc.context_length as i64);

                self.model_kv_cache_block_size
                    .with_label_values(&[&model_entry.name])
                    .set(mdc.kv_cache_block_size as i64);

                self.model_migration_limit
                    .with_label_values(&[&model_entry.name])
                    .set(mdc.migration_limit as i64);

                tracing::debug!(
                    model = %model_entry.name,
                    "Successfully updated MDC metrics"
                );
            }
            Ok(None) => {
                tracing::debug!(
                    model = %model_entry.name,
                    "No MDC found in storage, skipping MDC metrics"
                );
            }
            Err(e) => {
                tracing::debug!(
                    model = %model_entry.name,
                    error = %e,
                    "Failed to load MDC for metrics update"
                );
            }
        }

        Ok(())
    }

    /// Create a new [`InflightGuard`] for the given model and annotate if its a streaming request,
    /// and the kind of endpoint that was hit
    ///
    /// The [`InflightGuard`] is an RAII object will handle incrementing the inflight gauge and
    /// request counters.
    ///
    /// # Metrics Distinction
    ///
    /// This method creates an inflight guard  t tracks requests actively being processed by the LLM engine.
    /// This is distinct from [`HttpQueueGuard`] which tracks requests from HTTP handler start until
    /// first token generation (including prefill time). The separation allows monitoring both HTTP processing queue time
    /// and actual LLM processing time.
    pub fn create_inflight_guard(
        self: Arc<Self>,
        model: &str,
        endpoint: Endpoint,
        streaming: bool,
    ) -> InflightGuard {
        let request_type = if streaming {
            RequestType::Stream
        } else {
            RequestType::Unary
        };

        InflightGuard::new(
            self.clone(),
            model.to_string().to_lowercase(),
            endpoint,
            request_type,
        )
    }

    /// Create a new [`ResponseMetricCollector`] for collecting per-response metrics (i.e., TTFT, ITL)
    pub fn create_response_collector(self: Arc<Self>, model: &str) -> ResponseMetricCollector {
        ResponseMetricCollector::new(self, model.to_string().to_lowercase())
    }

    /// Create a new [`HttpQueueGuard`] for tracking HTTP processing queue
    ///
    /// This guard tracks requests from HTTP handler start until first token generation,
    /// providing visibility into HTTP processing queue time before actual LLM processing begins.
    pub fn create_http_queue_guard(self: Arc<Self>, model: &str) -> HttpQueueGuard {
        HttpQueueGuard::new(self, model.to_string().to_lowercase())
    }
}

impl HttpQueueGuard {
    fn new(metrics: Arc<Metrics>, model: String) -> Self {
        // Increment the HTTP queue gauge when the guard is created
        metrics.inc_http_queue_gauge(&model);

        HttpQueueGuard { metrics, model }
    }
}

impl Drop for HttpQueueGuard {
    fn drop(&mut self) {
        // Decrement the HTTP queue gauge when the guard is dropped
        self.metrics.dec_http_queue_gauge(&self.model);
    }
}

impl InflightGuard {
    fn new(
        metrics: Arc<Metrics>,
        model: String,
        endpoint: Endpoint,
        request_type: RequestType,
    ) -> Self {
        // Start the timer
        let timer = Instant::now();

        // Increment the inflight gauge when the guard is created
        metrics.inc_inflight_gauge(&model);

        // Return the RAII Guard
        InflightGuard {
            metrics,
            model,
            endpoint,
            request_type,
            status: Status::Error,
            timer,
        }
    }

    pub(crate) fn mark_ok(&mut self) {
        self.status = Status::Success;
    }
}

impl Drop for InflightGuard {
    fn drop(&mut self) {
        let duration = self.timer.elapsed().as_secs_f64();

        // Decrement the gauge when the guard is dropped
        self.metrics.dec_inflight_gauge(&self.model);

        // the frequency on incrementing the full request counter is relatively low
        // if we were incrementing the counter on every forward pass, we'd use static CounterVec or
        // discrete counter object without the more costly lookup required for the following calls
        self.metrics.inc_request_counter(
            &self.model,
            &self.endpoint,
            &self.request_type,
            &self.status,
        );

        // Record the duration of the request
        self.metrics
            .request_duration
            .with_label_values(&[&self.model])
            .observe(duration);
    }
}

impl std::fmt::Display for Endpoint {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        match self {
            Endpoint::Completions => write!(f, "completions"),
            Endpoint::ChatCompletions => write!(f, "chat_completions"),
            Endpoint::Embeddings => write!(f, "embeddings"),
            Endpoint::Responses => write!(f, "responses"),
            Endpoint::Tensor => write!(f, "tensor"),
        }
    }
}

impl Endpoint {
    pub fn as_str(&self) -> &'static str {
        match self {
            Endpoint::Completions => "completions",
            Endpoint::ChatCompletions => "chat_completions",
            Endpoint::Embeddings => "embeddings",
            Endpoint::Responses => "responses",
            Endpoint::Tensor => "tensor",
        }
    }
}

impl RequestType {
    pub fn as_str(&self) -> &'static str {
        match self {
            RequestType::Unary => frontend_service::request_type::UNARY,
            RequestType::Stream => frontend_service::request_type::STREAM,
        }
    }
}

impl Status {
    pub fn as_str(&self) -> &'static str {
        match self {
            Status::Success => frontend_service::status::SUCCESS,
            Status::Error => frontend_service::status::ERROR,
        }
    }
}

impl ResponseMetricCollector {
    fn new(metrics: Arc<Metrics>, model: String) -> Self {
        ResponseMetricCollector {
            metrics,
            model,
            is_first_token: true,
            last_response_time: None,
            start_time: Instant::now(),
            osl: 0,
        }
    }

    /// Observe the current output sequence length
    pub fn observe_current_osl(&mut self, osl: usize) {
        self.osl = osl;
    }

    /// Check if this will be the first token (before calling observe_response)
    pub fn is_first_token(&self) -> bool {
        self.is_first_token
    }

    /// Observe a response with input sequence length and number of new tokens
    pub fn observe_response(&mut self, isl: usize, num_tokens: usize) {
        if num_tokens == 0 {
            return;
        }

        if self.is_first_token {
            // NOTE: when there are multiple tokens in the first response,
            // we use the full response time as TTFT and ignore the ITL
            self.is_first_token = false;

            // Publish TTFT
            let ttft = self.start_time.elapsed().as_secs_f64();
            self.metrics
                .time_to_first_token
                .with_label_values(&[&self.model])
                .observe(ttft);

            // Publish ISL
            // TODO: publish ISL as soon as the tokenization process completes
            self.metrics
                .input_sequence_length
                .with_label_values(&[&self.model])
                .observe(isl as f64);
        }

        let current_duration = self.start_time.elapsed();

        if let Some(last_response_time) = self.last_response_time {
            let response_duration = current_duration - last_response_time;
            let itl = response_duration.as_secs_f64() / num_tokens as f64;
            for _ in 0..num_tokens {
                self.metrics
                    .inter_token_latency
                    .with_label_values(&[&self.model])
                    .observe(itl);
            }
        }

        self.last_response_time = Some(current_duration);
    }
}

impl Drop for ResponseMetricCollector {
    fn drop(&mut self) {
        // Publish final OSL when the collector is dropped
        self.metrics
            .output_sequence_length
            .with_label_values(&[&self.model])
            .observe(self.osl as f64);
    }
}

/// Process streaming metrics for annotated responses
///
/// This function handles metrics collection and http_queue_guard management for streaming responses.
/// It observes the current output sequence length, drops the http_queue_guard on the first token,
/// and records response metrics.
pub fn process_response_and_observe_metrics<T>(
    annotated: &crate::types::Annotated<T>,
    response_collector: &mut ResponseMetricCollector,
    http_queue_guard: &mut Option<HttpQueueGuard>,
) {
    use crate::preprocessor::LLMMetricAnnotation;

    // update metrics
    if let Ok(Some(metrics)) = LLMMetricAnnotation::from_annotation(annotated) {
        response_collector.observe_current_osl(metrics.output_tokens);

        // Drop http_queue_guard on first token for non-streaming (same as streaming)
        if response_collector.is_first_token()
            && metrics.chunk_tokens > 0
            && let Some(guard) = http_queue_guard.take()
        {
            drop(guard);
        }

        response_collector.observe_response(metrics.input_tokens, metrics.chunk_tokens);
    }
}

/// Event converter wrapper for streaming responses
pub struct EventConverter<T>(pub crate::types::Annotated<T>);

impl<T> From<crate::types::Annotated<T>> for EventConverter<T> {
    fn from(annotated: crate::types::Annotated<T>) -> Self {
        EventConverter(annotated)
    }
}

/// Process streaming response with event conversion for SSE
///
/// This function handles metrics collection, http_queue_guard management, and converts
/// annotated responses to SSE events for streaming responses.
pub fn process_response_using_event_converter_and_observe_metrics<T: Serialize>(
    annotated: EventConverter<T>,
    response_collector: &mut ResponseMetricCollector,
    http_queue_guard: &mut Option<HttpQueueGuard>,
) -> Result<Event, axum::Error> {
    use crate::preprocessor::LLMMetricAnnotation;

    let mut annotated = annotated.0;

    // update metrics
    if let Ok(Some(metrics)) = LLMMetricAnnotation::from_annotation(&annotated) {
        response_collector.observe_current_osl(metrics.output_tokens);

        // Drop http_queue_guard on first token for streaming
        if response_collector.is_first_token()
            && metrics.chunk_tokens > 0
            && let Some(guard) = http_queue_guard.take()
        {
            drop(guard);
        }

        response_collector.observe_response(metrics.input_tokens, metrics.chunk_tokens);

        // Chomp the LLMMetricAnnotation so it's not returned in the response stream
        // TODO: add a flag to control what is returned in the SSE stream
        if annotated.event.as_deref() == Some(crate::preprocessor::ANNOTATION_LLM_METRICS) {
            annotated.event = None;
            annotated.comment = None;
        }
    }

    let mut event = Event::default();

    if let Some(data) = annotated.data {
        event = event.json_data(data)?;
    }

    if let Some(msg) = annotated.event {
        if msg == "error" {
            let msgs = annotated
                .comment
                .unwrap_or_else(|| vec!["unspecified error".to_string()]);
            return Err(axum::Error::new(msgs.join(" -- ")));
        }
        event = event.event(msg);
    }

    if let Some(comments) = annotated.comment {
        for comment in comments {
            event = event.comment(comment);
        }
    }

    Ok(event)
}

/// Create a new router with the given path
pub fn router(registry: Registry, path: Option<String>) -> (Vec<RouteDoc>, Router) {
    let registry = Arc::new(registry);
    let path = path.unwrap_or_else(|| "/metrics".to_string());
    let doc = RouteDoc::new(axum::http::Method::GET, &path);
    let route = Router::new()
        .route(&path, get(handler_metrics))
        .with_state(registry);
    (vec![doc], route)
}

/// Metrics Handler
async fn handler_metrics(State(registry): State<Arc<Registry>>) -> impl IntoResponse {
    let encoder = prometheus::TextEncoder::new();
    let metric_families = registry.gather();
    let mut buffer = vec![];
    if encoder.encode(&metric_families, &mut buffer).is_err() {
        return (
            StatusCode::INTERNAL_SERVER_ERROR,
            "Failed to encode metrics",
        )
            .into_response();
    }

    let metrics = match String::from_utf8(buffer) {
        Ok(metrics) => metrics,
        Err(_) => {
            return (
                StatusCode::INTERNAL_SERVER_ERROR,
                "Failed to encode metrics",
            )
                .into_response();
        }
    };

    (StatusCode::OK, metrics).into_response()
}