use std::{ cmp::max, collections::VecDeque, fmt::{Debug, Formatter}, vec, }; use hashbrown::HashMap; use rayon::iter::{IntoParallelIterator, IntoParallelRefIterator, ParallelIterator}; use rustc_hash::FxHashSet; use crate::{ FxIndexMap, bottom_up::build_bottom_up_graph, span::{Span, SpanEvent, SpanExtra, SpanGraphEvent, SpanIndex, SpanNames, SpanTimeData}, span_bottom_up_ref::SpanBottomUpRef, span_graph_ref::{SpanGraphEventRef, SpanGraphRef, event_map_to_list}, store::{SpanId, Store}, timestamp::Timestamp, }; pub type GroupNameToDirectAndRecusiveSpans<'l> = FxIndexMap<(&'l str, &'l str), (Vec, Vec)>; #[derive(Copy, Clone)] pub struct SpanRef<'a> { pub(crate) span: &'a Span, pub(crate) store: &'a Store, pub(crate) index: usize, } impl<'a> SpanRef<'a> { pub fn id(&self) -> SpanId { unsafe { SpanId::new_unchecked(self.index << 1) } } pub fn index(&self) -> SpanIndex { SpanIndex::new(self.index).unwrap() } pub fn parent(&self) -> Option> { self.span.parent.map(|index| SpanRef { span: &self.store.spans[index.get()], store: self.store, index: index.get(), }) } pub fn start(&self) -> Timestamp { self.span.start } pub fn time_data(&self) -> &'a SpanTimeData { self.span.time_data() } pub fn extra(&self) -> &'a SpanExtra { self.span.extra() } pub fn names(&self) -> &'a SpanNames { self.span.names() } pub fn end(&self) -> Timestamp { let time_data = self.time_data(); *time_data.end.get_or_init(|| { max( time_data.self_end, self.children() .map(|child| child.end()) .max() .unwrap_or_default(), ) }) } pub fn is_complete(&self) -> bool { self.span.is_complete } pub fn is_root(&self) -> bool { self.index == 0 } pub fn nice_name(&self) -> (&'a str, &'a str) { let (category, title) = self.names().nice_name.get_or_init(|| { if let Some(name) = self .span .args .iter() .find(|&(k, _)| k == "name") .map(|(_, v)| v.as_str()) { if matches!(self.span.name.as_str(), "turbo_tasks::function") { (self.span.name.clone(), name.to_string()) } else if matches!( self.span.name.as_str(), "turbo_tasks::resolve_call" | "turbo_tasks::resolve_trait_call" ) { (self.span.name.clone(), format!("*{name}")) } else { ( self.span.category.clone(), format!("{} {name}", self.span.name), ) } } else { (self.span.category.to_string(), self.span.name.to_string()) } }); (category, title) } pub fn group_name(&self) -> (&'a str, &'a str) { let (category, title) = self.names().group_name.get_or_init(|| { if matches!(self.span.name.as_str(), "turbo_tasks::function") { let name = self .span .args .iter() .find(|&(k, _)| k == "name") .map(|(_, v)| v.to_string()) .unwrap_or_else(|| self.span.name.to_string()); (self.span.name.clone(), name) } else if matches!( self.span.name.as_str(), "turbo_tasks::resolve_call" | "turbo_tasks::resolve_trait_call" ) { let name = self .span .args .iter() .find(|&(k, _)| k == "name") .map(|(_, v)| format!("*{v}")) .unwrap_or_else(|| self.span.name.to_string()); ( self.span.category.clone(), format!("{} {name}", self.span.name), ) } else { (self.span.category.clone(), self.span.name.clone()) } }); (category.as_str(), title.as_str()) } pub fn args(&self) -> impl Iterator { self.span.args.iter().map(|(k, v)| (k.as_str(), v.as_str())) } pub fn self_time(&self) -> Timestamp { self.time_data().self_time } pub fn self_allocations(&self) -> u64 { // 32 bytes for the tracing itself self.span.self_allocations.saturating_sub(32) } pub fn self_deallocations(&self) -> u64 { self.span.self_deallocations } pub fn self_persistent_allocations(&self) -> u64 { self.self_allocations() .saturating_sub(self.span.self_deallocations) } pub fn self_allocation_count(&self) -> u64 { // 4 allocations for the tracing itself self.span.self_allocation_count.saturating_sub(4) } pub fn self_span_count(&self) -> u64 { 1 } // TODO(sokra) use events instead of children for visualizing span graphs #[allow(dead_code)] pub fn events_count(&self) -> usize { self.span.events.len() } // TODO(sokra) use events instead of children for visualizing span graphs #[allow(dead_code)] pub fn events(&self) -> impl Iterator> { self.span.events.iter().map(|event| match event { &SpanEvent::SelfTime { start, end } => SpanEventRef::SelfTime { start, end }, SpanEvent::Child { index } => SpanEventRef::Child { span: SpanRef { span: &self.store.spans[index.get()], store: self.store, index: index.get(), }, }, }) } pub fn children(&self) -> impl DoubleEndedIterator> + 'a + use<'a> { self.span.events.iter().filter_map(|event| match event { SpanEvent::SelfTime { .. } => None, SpanEvent::Child { index } => Some(SpanRef { span: &self.store.spans[index.get()], store: self.store, index: index.get(), }), }) } pub fn children_par(&self) -> impl ParallelIterator> + 'a { self.span.events.par_iter().filter_map(|event| match event { SpanEvent::SelfTime { .. } => None, SpanEvent::Child { index } => Some(SpanRef { span: &self.store.spans[index.get()], store: self.store, index: index.get(), }), }) } pub fn total_time(&self) -> Timestamp { *self.time_data().total_time.get_or_init(|| { self.children() .map(|child| child.total_time()) .reduce(|a, b| a + b) .unwrap_or_default() + self.self_time() }) } pub fn total_allocations(&self) -> u64 { *self.span.total_allocations.get_or_init(|| { self.children() .map(|child| child.total_allocations()) .reduce(|a, b| a + b) .unwrap_or_default() + self.self_allocations() }) } pub fn total_deallocations(&self) -> u64 { *self.span.total_deallocations.get_or_init(|| { self.children() .map(|child| child.total_deallocations()) .reduce(|a, b| a + b) .unwrap_or_default() + self.self_deallocations() }) } pub fn total_persistent_allocations(&self) -> u64 { *self.span.total_persistent_allocations.get_or_init(|| { self.children() .map(|child| child.total_persistent_allocations()) .reduce(|a, b| a + b) .unwrap_or_default() + self.self_persistent_allocations() }) } pub fn total_allocation_count(&self) -> u64 { *self.span.total_allocation_count.get_or_init(|| { self.children() .map(|child| child.total_allocation_count()) .reduce(|a, b| a + b) .unwrap_or_default() + self.self_allocation_count() }) } pub fn total_span_count(&self) -> u64 { *self.span.total_span_count.get_or_init(|| { self.children() .map(|child| child.total_span_count()) .reduce(|a, b| a + b) .unwrap_or_default() + 1 }) } pub fn corrected_self_time(&self) -> Timestamp { let store = self.store; *self.time_data().corrected_self_time.get_or_init(|| { let mut self_time = self .span .events .par_iter() .filter_map(|event| { if let SpanEvent::SelfTime { start, end } = event { let duration = *end - *start; if !duration.is_zero() { store.set_max_self_time_lookup(*end); let corrected_time = store.self_time_tree.as_ref().map_or(duration, |tree| { tree.lookup_range_corrected_time(*start, *end) }); return Some(corrected_time); } } None }) .sum(); if self.children().next().is_none() { self_time = max(self_time, Timestamp::from_value(1)); } self_time }) } pub fn corrected_total_time(&self) -> Timestamp { *self.time_data().corrected_total_time.get_or_init(|| { self.children_par() .map(|child| child.corrected_total_time()) .sum::() + self.corrected_self_time() }) } pub fn max_depth(&self) -> u32 { *self.span.max_depth.get_or_init(|| { self.children() .map(|child| child.max_depth() + 1) .max() .unwrap_or_default() }) } pub fn graph(&self) -> impl Iterator> + '_ { self.extra() .graph .get_or_init(|| { struct Entry<'a> { span: SpanRef<'a>, recursive: Vec, } let entries = self .children_par() .map(|span| { let name = span.group_name(); let mut recursive = Vec::new(); let mut queue = VecDeque::with_capacity(0); for nested_child in span.children() { let nested_name = nested_child.group_name(); if name == nested_name { recursive.push(nested_child.index()); queue.push_back(nested_child); } } while let Some(child) = queue.pop_front() { for nested_child in child.children() { let nested_name = nested_child.group_name(); if name == nested_name { recursive.push(nested_child.index()); queue.push_back(nested_child); } } } Entry { span, recursive } }) .collect_vec_list(); let mut map: GroupNameToDirectAndRecusiveSpans = FxIndexMap::default(); for Entry { span, mut recursive, } in entries.into_iter().flatten() { let name = span.group_name(); let (list, recursive_list) = map.entry(name).or_default(); list.push(span.index()); recursive_list.append(&mut recursive); } event_map_to_list(map) }) .iter() .map(|event| match event { SpanGraphEvent::SelfTime { duration } => SpanGraphEventRef::SelfTime { duration: *duration, }, SpanGraphEvent::Child { child } => SpanGraphEventRef::Child { graph: SpanGraphRef { graph: child.clone(), store: self.store, }, }, }) } pub fn bottom_up(self) -> impl Iterator> { self.extra() .bottom_up .get_or_init(|| build_bottom_up_graph([self].into_iter())) .iter() .map(move |bottom_up| SpanBottomUpRef { bottom_up: bottom_up.clone(), store: self.store, }) } pub fn search(&self, query: &str) -> impl Iterator> { let mut query_items = query.split(",").map(str::trim); let index = self.search_index(); let mut result = FxHashSet::default(); let query = query_items.next().unwrap(); for (key, spans) in index { if key.contains(query) { result.extend(spans.iter().copied()); } } for query in query_items { let mut and_result = FxHashSet::default(); for (key, spans) in index { if key.contains(query) { and_result.extend(spans.iter().copied()); } } result.retain(|index| and_result.contains(index)); } let store = self.store; result.into_iter().map(move |index| SpanRef { span: &store.spans[index.get()], store, index: index.get(), }) } fn search_index(&self) -> &HashMap> { self.extra().search_index.get_or_init(|| { let mut all_spans = Vec::new(); all_spans.push(self.index); let mut i = 0; while i < all_spans.len() { let index = all_spans[i]; let span = SpanRef { span: &self.store.spans[index], store: self.store, index, }; for child in span.children() { all_spans.push(child.index); } i += 1; } enum SpanOrMap<'a> { Span(SpanRef<'a>), Map(HashMap>), } fn add_span_to_map<'a>(index: &mut HashMap>, span: SpanRef<'a>) { if !span.is_root() { let (cat, name) = span.nice_name(); if !cat.is_empty() { index .raw_entry_mut() .from_key(cat) .and_modify(|_, v| v.push(span.index())) .or_insert_with(|| (cat.to_string(), vec![span.index()])); } if !name.is_empty() { index .raw_entry_mut() .from_key(name) .and_modify(|_, v| v.push(span.index())) .or_insert_with(|| (format!("name={name}"), vec![span.index()])); } for (name, value) in span.span.args.iter() { index .raw_entry_mut() .from_key(value) .and_modify(|_, v| v.push(span.index())) .or_insert_with(|| (format!("{name}={value}"), vec![span.index()])); } if !span.is_complete() && !span.time_data().ignore_self_time { let name = "incomplete_span"; index .raw_entry_mut() .from_key(name) .and_modify(|_, v| v.push(span.index())) .or_insert_with(|| (name.to_string(), vec![span.index()])); } } } let result = all_spans .into_par_iter() .map(|index| { SpanOrMap::Span(SpanRef { span: &self.store.spans[index], store: self.store, index, }) }) .reduce( || SpanOrMap::Map(HashMap::default()), |a, b| { let mut map = match a { SpanOrMap::Span(span) => { let mut map = HashMap::default(); add_span_to_map(&mut map, span); map } SpanOrMap::Map(map) => map, }; match b { SpanOrMap::Span(span) => { add_span_to_map(&mut map, span); } SpanOrMap::Map(other_map) => { for (name, value) in other_map { map.entry(name).or_default().extend(value); } } } SpanOrMap::Map(map) }, ); match result { SpanOrMap::Span(span) => { let mut map = HashMap::default(); add_span_to_map(&mut map, span); map } SpanOrMap::Map(map) => map, } }) } } impl Debug for SpanRef<'_> { fn fmt(&self, f: &mut Formatter<'_>) -> std::fmt::Result { f.debug_struct("SpanRef") .field("id", &self.id()) .field("name", &self.nice_name()) .field("start", &self.start()) .field("end", &self.end()) .field("is_complete", &self.is_complete()) .field("self_time", &self.self_time()) .field("total_time", &self.total_time()) .field("max_depth", &self.max_depth()) .finish() } } #[allow(dead_code)] #[derive(Copy, Clone)] pub enum SpanEventRef<'a> { SelfTime { start: Timestamp, end: Timestamp }, Child { span: SpanRef<'a> }, }