// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use crate::tokio_util::create_basic_runtime; use deno_core::anyhow; use deno_core::anyhow::anyhow; use deno_core::futures::channel::mpsc; use deno_core::futures::channel::mpsc::UnboundedSender; use deno_core::futures::future::BoxFuture; use deno_core::futures::stream; use deno_core::futures::Stream; use deno_core::futures::StreamExt; use deno_core::op2; use deno_core::v8; use deno_core::OpState; use once_cell::sync::Lazy; use once_cell::sync::OnceCell; use opentelemetry::logs::AnyValue; use opentelemetry::logs::LogRecord as LogRecordTrait; use opentelemetry::logs::Severity; use opentelemetry::trace::SpanContext; use opentelemetry::trace::SpanId; use opentelemetry::trace::SpanKind; use opentelemetry::trace::Status as SpanStatus; use opentelemetry::trace::TraceFlags; use opentelemetry::trace::TraceId; use opentelemetry::Key; use opentelemetry::KeyValue; use opentelemetry::StringValue; use opentelemetry::Value; use opentelemetry_otlp::HttpExporterBuilder; use opentelemetry_otlp::Protocol; use opentelemetry_otlp::WithExportConfig; use opentelemetry_otlp::WithHttpConfig; use opentelemetry_sdk::export::trace::SpanData; use opentelemetry_sdk::logs::BatchLogProcessor; use opentelemetry_sdk::logs::LogProcessor as LogProcessorTrait; use opentelemetry_sdk::logs::LogRecord; use opentelemetry_sdk::trace::BatchSpanProcessor; use opentelemetry_sdk::trace::SpanProcessor as SpanProcessorTrait; use opentelemetry_sdk::Resource; use opentelemetry_semantic_conventions::resource::PROCESS_RUNTIME_NAME; use opentelemetry_semantic_conventions::resource::PROCESS_RUNTIME_VERSION; use opentelemetry_semantic_conventions::resource::TELEMETRY_SDK_LANGUAGE; use opentelemetry_semantic_conventions::resource::TELEMETRY_SDK_NAME; use opentelemetry_semantic_conventions::resource::TELEMETRY_SDK_VERSION; use serde::Deserialize; use serde::Serialize; use std::borrow::Cow; use std::env; use std::fmt::Debug; use std::pin::Pin; use std::task::Context; use std::task::Poll; use std::thread; use std::time::Duration; use std::time::SystemTime; type SpanProcessor = BatchSpanProcessor; type LogProcessor = BatchLogProcessor; deno_core::extension!( deno_otel, ops = [ op_otel_log, op_otel_instrumentation_scope_create_and_enter, op_otel_instrumentation_scope_enter, op_otel_instrumentation_scope_enter_builtin, op_otel_span_start, op_otel_span_continue, op_otel_span_attribute, op_otel_span_attribute2, op_otel_span_attribute3, op_otel_span_set_dropped, op_otel_span_flush, ], ); #[derive(Debug, Clone, Serialize, Deserialize)] pub struct OtelConfig { pub runtime_name: Cow<'static, str>, pub runtime_version: Cow<'static, str>, pub console: OtelConsoleConfig, pub deterministic: bool, } #[derive(Debug, Clone, Copy, Serialize, Deserialize)] #[repr(u8)] pub enum OtelConsoleConfig { Ignore = 0, Capture = 1, Replace = 2, } impl Default for OtelConfig { fn default() -> Self { Self { runtime_name: Cow::Borrowed(env!("CARGO_PKG_NAME")), runtime_version: Cow::Borrowed(env!("CARGO_PKG_VERSION")), console: OtelConsoleConfig::Capture, deterministic: false, } } } static OTEL_SHARED_RUNTIME_SPAWN_TASK_TX: Lazy< UnboundedSender>, > = Lazy::new(otel_create_shared_runtime); fn otel_create_shared_runtime() -> UnboundedSender> { let (spawn_task_tx, mut spawn_task_rx) = mpsc::unbounded::>(); thread::spawn(move || { let rt = create_basic_runtime(); rt.block_on(async move { while let Some(task) = spawn_task_rx.next().await { tokio::spawn(task); } }); }); spawn_task_tx } #[derive(Clone, Copy)] struct OtelSharedRuntime; impl hyper::rt::Executor> for OtelSharedRuntime { fn execute(&self, fut: BoxFuture<'static, ()>) { (*OTEL_SHARED_RUNTIME_SPAWN_TASK_TX) .unbounded_send(fut) .expect("failed to send task to shared OpenTelemetry runtime"); } } impl opentelemetry_sdk::runtime::Runtime for OtelSharedRuntime { type Interval = Pin + Send + 'static>>; type Delay = Pin>; fn interval(&self, period: Duration) -> Self::Interval { stream::repeat(()) .then(move |_| tokio::time::sleep(period)) .boxed() } fn spawn(&self, future: BoxFuture<'static, ()>) { (*OTEL_SHARED_RUNTIME_SPAWN_TASK_TX) .unbounded_send(future) .expect("failed to send task to shared OpenTelemetry runtime"); } fn delay(&self, duration: Duration) -> Self::Delay { Box::pin(tokio::time::sleep(duration)) } } impl opentelemetry_sdk::runtime::RuntimeChannel for OtelSharedRuntime { type Receiver = BatchMessageChannelReceiver; type Sender = BatchMessageChannelSender; fn batch_message_channel( &self, capacity: usize, ) -> (Self::Sender, Self::Receiver) { let (batch_tx, batch_rx) = tokio::sync::mpsc::channel::(capacity); (batch_tx.into(), batch_rx.into()) } } #[derive(Debug)] pub struct BatchMessageChannelSender { sender: tokio::sync::mpsc::Sender, } impl From> for BatchMessageChannelSender { fn from(sender: tokio::sync::mpsc::Sender) -> Self { Self { sender } } } impl opentelemetry_sdk::runtime::TrySend for BatchMessageChannelSender { type Message = T; fn try_send( &self, item: Self::Message, ) -> Result<(), opentelemetry_sdk::runtime::TrySendError> { self.sender.try_send(item).map_err(|err| match err { tokio::sync::mpsc::error::TrySendError::Full(_) => { opentelemetry_sdk::runtime::TrySendError::ChannelFull } tokio::sync::mpsc::error::TrySendError::Closed(_) => { opentelemetry_sdk::runtime::TrySendError::ChannelClosed } }) } } pub struct BatchMessageChannelReceiver { receiver: tokio::sync::mpsc::Receiver, } impl From> for BatchMessageChannelReceiver { fn from(receiver: tokio::sync::mpsc::Receiver) -> Self { Self { receiver } } } impl Stream for BatchMessageChannelReceiver { type Item = T; fn poll_next( mut self: Pin<&mut Self>, cx: &mut Context<'_>, ) -> Poll> { self.receiver.poll_recv(cx) } } mod hyper_client { use http_body_util::BodyExt; use http_body_util::Full; use hyper::body::Body as HttpBody; use hyper::body::Frame; use hyper_util::client::legacy::connect::HttpConnector; use hyper_util::client::legacy::Client; use opentelemetry_http::Bytes; use opentelemetry_http::HttpError; use opentelemetry_http::Request; use opentelemetry_http::Response; use opentelemetry_http::ResponseExt; use std::fmt::Debug; use std::pin::Pin; use std::task::Poll; use std::task::{self}; use super::OtelSharedRuntime; // same as opentelemetry_http::HyperClient except it uses OtelSharedRuntime #[derive(Debug, Clone)] pub struct HyperClient { inner: Client, } impl HyperClient { pub fn new() -> Self { Self { inner: Client::builder(OtelSharedRuntime).build(HttpConnector::new()), } } } #[async_trait::async_trait] impl opentelemetry_http::HttpClient for HyperClient { async fn send( &self, request: Request>, ) -> Result, HttpError> { let (parts, body) = request.into_parts(); let request = Request::from_parts(parts, Body(Full::from(body))); let mut response = self.inner.request(request).await?; let headers = std::mem::take(response.headers_mut()); let mut http_response = Response::builder() .status(response.status()) .body(response.into_body().collect().await?.to_bytes())?; *http_response.headers_mut() = headers; Ok(http_response.error_for_status()?) } } #[pin_project::pin_project] pub struct Body(#[pin] Full); impl HttpBody for Body { type Data = Bytes; type Error = Box; #[inline] fn poll_frame( self: Pin<&mut Self>, cx: &mut task::Context<'_>, ) -> Poll, Self::Error>>> { self.project().0.poll_frame(cx).map_err(Into::into) } #[inline] fn is_end_stream(&self) -> bool { self.0.is_end_stream() } #[inline] fn size_hint(&self) -> hyper::body::SizeHint { self.0.size_hint() } } } static OTEL_PROCESSORS: OnceCell<(SpanProcessor, LogProcessor)> = OnceCell::new(); static BUILT_IN_INSTRUMENTATION_SCOPE: OnceCell< opentelemetry::InstrumentationScope, > = OnceCell::new(); pub fn init(config: OtelConfig) -> anyhow::Result<()> { // Parse the `OTEL_EXPORTER_OTLP_PROTOCOL` variable. The opentelemetry_* // crates don't do this automatically. // TODO(piscisaureus): enable GRPC support. let protocol = match env::var("OTEL_EXPORTER_OTLP_PROTOCOL").as_deref() { Ok("http/protobuf") => Protocol::HttpBinary, Ok("http/json") => Protocol::HttpJson, Ok("") | Err(env::VarError::NotPresent) => { return Ok(()); } Ok(protocol) => { return Err(anyhow!( "Env var OTEL_EXPORTER_OTLP_PROTOCOL specifies an unsupported protocol: {}", protocol )); } Err(err) => { return Err(anyhow!( "Failed to read env var OTEL_EXPORTER_OTLP_PROTOCOL: {}", err )); } }; // Define the resource attributes that will be attached to all log records. // These attributes are sourced as follows (in order of precedence): // * The `service.name` attribute from the `OTEL_SERVICE_NAME` env var. // * Additional attributes from the `OTEL_RESOURCE_ATTRIBUTES` env var. // * Default attribute values defined here. // TODO(piscisaureus): add more default attributes (e.g. script path). let mut resource = Resource::default(); // Add the runtime name and version to the resource attributes. Also override // the `telemetry.sdk` attributes to include the Deno runtime. resource = resource.merge(&Resource::new(vec![ KeyValue::new(PROCESS_RUNTIME_NAME, config.runtime_name), KeyValue::new(PROCESS_RUNTIME_VERSION, config.runtime_version.clone()), KeyValue::new( TELEMETRY_SDK_LANGUAGE, format!( "deno-{}", resource.get(Key::new(TELEMETRY_SDK_LANGUAGE)).unwrap() ), ), KeyValue::new( TELEMETRY_SDK_NAME, format!( "deno-{}", resource.get(Key::new(TELEMETRY_SDK_NAME)).unwrap() ), ), KeyValue::new( TELEMETRY_SDK_VERSION, format!( "{}-{}", config.runtime_version, resource.get(Key::new(TELEMETRY_SDK_VERSION)).unwrap() ), ), ])); // The OTLP endpoint is automatically picked up from the // `OTEL_EXPORTER_OTLP_ENDPOINT` environment variable. Additional headers can // be specified using `OTEL_EXPORTER_OTLP_HEADERS`. let client = hyper_client::HyperClient::new(); let span_exporter = HttpExporterBuilder::default() .with_http_client(client.clone()) .with_protocol(protocol) .build_span_exporter()?; let mut span_processor = BatchSpanProcessor::builder(span_exporter, OtelSharedRuntime).build(); span_processor.set_resource(&resource); let log_exporter = HttpExporterBuilder::default() .with_http_client(client) .with_protocol(protocol) .build_log_exporter()?; let log_processor = BatchLogProcessor::builder(log_exporter, OtelSharedRuntime).build(); log_processor.set_resource(&resource); OTEL_PROCESSORS .set((span_processor, log_processor)) .map_err(|_| anyhow!("failed to init otel"))?; let builtin_instrumentation_scope = opentelemetry::InstrumentationScope::builder("deno") .with_version(config.runtime_version.clone()) .build(); BUILT_IN_INSTRUMENTATION_SCOPE .set(builtin_instrumentation_scope) .map_err(|_| anyhow!("failed to init otel"))?; Ok(()) } /// This function is called by the runtime whenever it is about to call /// `process::exit()`, to ensure that all OpenTelemetry logs are properly /// flushed before the process terminates. pub fn flush() { if let Some((span_processor, log_processor)) = OTEL_PROCESSORS.get() { let _ = span_processor.force_flush(); let _ = log_processor.force_flush(); } } pub fn handle_log(record: &log::Record) { use log::Level; let Some((_, log_processor)) = OTEL_PROCESSORS.get() else { return; }; let mut log_record = LogRecord::default(); log_record.set_observed_timestamp(SystemTime::now()); log_record.set_severity_number(match record.level() { Level::Error => Severity::Error, Level::Warn => Severity::Warn, Level::Info => Severity::Info, Level::Debug => Severity::Debug, Level::Trace => Severity::Trace, }); log_record.set_severity_text(record.level().as_str()); log_record.set_body(record.args().to_string().into()); log_record.set_target(record.metadata().target().to_string()); struct Visitor<'s>(&'s mut LogRecord); impl<'s, 'kvs> log::kv::VisitSource<'kvs> for Visitor<'s> { fn visit_pair( &mut self, key: log::kv::Key<'kvs>, value: log::kv::Value<'kvs>, ) -> Result<(), log::kv::Error> { #[allow(clippy::manual_map)] let value = if let Some(v) = value.to_bool() { Some(AnyValue::Boolean(v)) } else if let Some(v) = value.to_borrowed_str() { Some(AnyValue::String(v.to_owned().into())) } else if let Some(v) = value.to_f64() { Some(AnyValue::Double(v)) } else if let Some(v) = value.to_i64() { Some(AnyValue::Int(v)) } else { None }; if let Some(value) = value { let key = Key::from(key.as_str().to_owned()); self.0.add_attribute(key, value); } Ok(()) } } let _ = record.key_values().visit(&mut Visitor(&mut log_record)); log_processor.emit( &mut log_record, BUILT_IN_INSTRUMENTATION_SCOPE.get().unwrap(), ); } fn parse_trace_id( scope: &mut v8::HandleScope<'_>, trace_id: v8::Local<'_, v8::Value>, ) -> TraceId { if let Ok(string) = trace_id.try_cast() { let value_view = v8::ValueView::new(scope, string); match value_view.data() { v8::ValueViewData::OneByte(bytes) => { TraceId::from_hex(&String::from_utf8_lossy(bytes)) .unwrap_or(TraceId::INVALID) } _ => TraceId::INVALID, } } else if let Ok(uint8array) = trace_id.try_cast::() { let data = uint8array.data(); let byte_length = uint8array.byte_length(); if byte_length != 16 { return TraceId::INVALID; } // SAFETY: We have ensured that the byte length is 16, so it is safe to // cast the data to an array of 16 bytes. let bytes = unsafe { &*(data as *const u8 as *const [u8; 16]) }; TraceId::from_bytes(*bytes) } else { TraceId::INVALID } } fn parse_span_id( scope: &mut v8::HandleScope<'_>, span_id: v8::Local<'_, v8::Value>, ) -> SpanId { if let Ok(string) = span_id.try_cast() { let value_view = v8::ValueView::new(scope, string); match value_view.data() { v8::ValueViewData::OneByte(bytes) => { SpanId::from_hex(&String::from_utf8_lossy(bytes)) .unwrap_or(SpanId::INVALID) } _ => SpanId::INVALID, } } else if let Ok(uint8array) = span_id.try_cast::() { let data = uint8array.data(); let byte_length = uint8array.byte_length(); if byte_length != 8 { return SpanId::INVALID; } // SAFETY: We have ensured that the byte length is 8, so it is safe to // cast the data to an array of 8 bytes. let bytes = unsafe { &*(data as *const u8 as *const [u8; 8]) }; SpanId::from_bytes(*bytes) } else { SpanId::INVALID } } macro_rules! attr { ($scope:ident, $attributes:expr $(=> $dropped_attributes_count:expr)?, $name:expr, $value:expr) => { let name = if let Ok(name) = $name.try_cast() { let view = v8::ValueView::new($scope, name); match view.data() { v8::ValueViewData::OneByte(bytes) => { Some(String::from_utf8_lossy(bytes).into_owned()) } v8::ValueViewData::TwoByte(bytes) => { Some(String::from_utf16_lossy(bytes)) } } } else { None }; let value = if let Ok(string) = $value.try_cast::() { Some(Value::String(StringValue::from({ let x = v8::ValueView::new($scope, string); match x.data() { v8::ValueViewData::OneByte(bytes) => { String::from_utf8_lossy(bytes).into_owned() } v8::ValueViewData::TwoByte(bytes) => String::from_utf16_lossy(bytes), } }))) } else if let Ok(number) = $value.try_cast::() { Some(Value::F64(number.value())) } else if let Ok(boolean) = $value.try_cast::() { Some(Value::Bool(boolean.is_true())) } else if let Ok(bigint) = $value.try_cast::() { let (i64_value, _lossless) = bigint.i64_value(); Some(Value::I64(i64_value)) } else { None }; if let (Some(name), Some(value)) = (name, value) { $attributes.push(KeyValue::new(name, value)); } $( else { $dropped_attributes_count += 1; } )? }; } #[derive(Debug, Clone)] struct InstrumentationScope(opentelemetry::InstrumentationScope); impl deno_core::GarbageCollected for InstrumentationScope {} #[op2] #[cppgc] fn op_otel_instrumentation_scope_create_and_enter( state: &mut OpState, #[string] name: String, #[string] version: Option, #[string] schema_url: Option, ) -> InstrumentationScope { let mut builder = opentelemetry::InstrumentationScope::builder(name); if let Some(version) = version { builder = builder.with_version(version); } if let Some(schema_url) = schema_url { builder = builder.with_schema_url(schema_url); } let scope = InstrumentationScope(builder.build()); state.put(scope.clone()); scope } #[op2(fast)] fn op_otel_instrumentation_scope_enter( state: &mut OpState, #[cppgc] scope: &InstrumentationScope, ) { state.put(scope.clone()); } #[op2(fast)] fn op_otel_instrumentation_scope_enter_builtin(state: &mut OpState) { state.put(InstrumentationScope( BUILT_IN_INSTRUMENTATION_SCOPE.get().unwrap().clone(), )); } #[op2(fast)] fn op_otel_log( scope: &mut v8::HandleScope<'_>, #[string] message: String, #[smi] level: i32, trace_id: v8::Local<'_, v8::Value>, span_id: v8::Local<'_, v8::Value>, #[smi] trace_flags: u8, ) { let Some((_, log_processor)) = OTEL_PROCESSORS.get() else { return; }; // Convert the integer log level that ext/console uses to the corresponding // OpenTelemetry log severity. let severity = match level { ..=0 => Severity::Debug, 1 => Severity::Info, 2 => Severity::Warn, 3.. => Severity::Error, }; let trace_id = parse_trace_id(scope, trace_id); let span_id = parse_span_id(scope, span_id); let mut log_record = LogRecord::default(); log_record.set_observed_timestamp(SystemTime::now()); log_record.set_body(message.into()); log_record.set_severity_number(severity); log_record.set_severity_text(severity.name()); if trace_id != TraceId::INVALID && span_id != SpanId::INVALID { log_record.set_trace_context( trace_id, span_id, Some(TraceFlags::new(trace_flags)), ); } log_processor.emit( &mut log_record, BUILT_IN_INSTRUMENTATION_SCOPE.get().unwrap(), ); } struct TemporarySpan(SpanData); #[allow(clippy::too_many_arguments)] #[op2(fast)] fn op_otel_span_start<'s>( scope: &mut v8::HandleScope<'s>, state: &mut OpState, trace_id: v8::Local<'s, v8::Value>, span_id: v8::Local<'s, v8::Value>, parent_span_id: v8::Local<'s, v8::Value>, #[smi] span_kind: u8, name: v8::Local<'s, v8::Value>, start_time: f64, end_time: f64, ) -> Result<(), anyhow::Error> { if let Some(temporary_span) = state.try_take::() { let Some((span_processor, _)) = OTEL_PROCESSORS.get() else { return Ok(()); }; span_processor.on_end(temporary_span.0); }; let Some(InstrumentationScope(instrumentation_scope)) = state.try_borrow::() else { return Err(anyhow!("instrumentation scope not available")); }; let trace_id = parse_trace_id(scope, trace_id); if trace_id == TraceId::INVALID { return Err(anyhow!("invalid trace_id")); } let span_id = parse_span_id(scope, span_id); if span_id == SpanId::INVALID { return Err(anyhow!("invalid span_id")); } let parent_span_id = parse_span_id(scope, parent_span_id); let name = { let x = v8::ValueView::new(scope, name.try_cast()?); match x.data() { v8::ValueViewData::OneByte(bytes) => { String::from_utf8_lossy(bytes).into_owned() } v8::ValueViewData::TwoByte(bytes) => String::from_utf16_lossy(bytes), } }; let temporary_span = TemporarySpan(SpanData { span_context: SpanContext::new( trace_id, span_id, TraceFlags::SAMPLED, false, Default::default(), ), parent_span_id, span_kind: match span_kind { 0 => SpanKind::Internal, 1 => SpanKind::Server, 2 => SpanKind::Client, 3 => SpanKind::Producer, 4 => SpanKind::Consumer, _ => return Err(anyhow!("invalid span kind")), }, name: Cow::Owned(name), start_time: SystemTime::UNIX_EPOCH .checked_add(std::time::Duration::from_secs_f64(start_time)) .ok_or_else(|| anyhow!("invalid start time"))?, end_time: SystemTime::UNIX_EPOCH .checked_add(std::time::Duration::from_secs_f64(end_time)) .ok_or_else(|| anyhow!("invalid start time"))?, attributes: Vec::new(), dropped_attributes_count: 0, events: Default::default(), links: Default::default(), status: SpanStatus::Unset, instrumentation_scope: instrumentation_scope.clone(), }); state.put(temporary_span); Ok(()) } #[op2(fast)] fn op_otel_span_continue( state: &mut OpState, #[smi] status: u8, #[string] error_description: Cow<'_, str>, ) { if let Some(temporary_span) = state.try_borrow_mut::() { temporary_span.0.status = match status { 0 => SpanStatus::Unset, 1 => SpanStatus::Ok, 2 => SpanStatus::Error { description: Cow::Owned(error_description.into_owned()), }, _ => return, }; } } #[op2(fast)] fn op_otel_span_attribute<'s>( scope: &mut v8::HandleScope<'s>, state: &mut OpState, #[smi] capacity: u32, key: v8::Local<'s, v8::Value>, value: v8::Local<'s, v8::Value>, ) { if let Some(temporary_span) = state.try_borrow_mut::() { temporary_span.0.attributes.reserve_exact( (capacity as usize) - temporary_span.0.attributes.capacity(), ); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key, value); } } #[op2(fast)] fn op_otel_span_attribute2<'s>( scope: &mut v8::HandleScope<'s>, state: &mut OpState, #[smi] capacity: u32, key1: v8::Local<'s, v8::Value>, value1: v8::Local<'s, v8::Value>, key2: v8::Local<'s, v8::Value>, value2: v8::Local<'s, v8::Value>, ) { if let Some(temporary_span) = state.try_borrow_mut::() { temporary_span.0.attributes.reserve_exact( (capacity as usize) - temporary_span.0.attributes.capacity(), ); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key1, value1); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key2, value2); } } #[allow(clippy::too_many_arguments)] #[op2(fast)] fn op_otel_span_attribute3<'s>( scope: &mut v8::HandleScope<'s>, state: &mut OpState, #[smi] capacity: u32, key1: v8::Local<'s, v8::Value>, value1: v8::Local<'s, v8::Value>, key2: v8::Local<'s, v8::Value>, value2: v8::Local<'s, v8::Value>, key3: v8::Local<'s, v8::Value>, value3: v8::Local<'s, v8::Value>, ) { if let Some(temporary_span) = state.try_borrow_mut::() { temporary_span.0.attributes.reserve_exact( (capacity as usize) - temporary_span.0.attributes.capacity(), ); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key1, value1); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key2, value2); attr!(scope, temporary_span.0.attributes => temporary_span.0.dropped_attributes_count, key3, value3); } } #[op2(fast)] fn op_otel_span_set_dropped( state: &mut OpState, #[smi] dropped_attributes_count: u32, #[smi] dropped_links_count: u32, #[smi] dropped_events_count: u32, ) { if let Some(temporary_span) = state.try_borrow_mut::() { temporary_span.0.dropped_attributes_count += dropped_attributes_count; temporary_span.0.links.dropped_count += dropped_links_count; temporary_span.0.events.dropped_count += dropped_events_count; } } #[op2(fast)] fn op_otel_span_flush(state: &mut OpState) { let Some(temporary_span) = state.try_take::() else { return; }; let Some((span_processor, _)) = OTEL_PROCESSORS.get() else { return; }; span_processor.on_end(temporary_span.0); }