//===- xray-stacks.cpp: XRay Function Call Stack Accounting ---------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements stack-based accounting. It takes XRay traces, and // collates statistics across these traces to show a breakdown of time spent // at various points of the stack to provide insight into which functions // spend the most time in terms of a call stack. We provide a few // sorting/filtering options for zero'ing in on the useful stacks. // //===----------------------------------------------------------------------===// #include #include #include "func-id-helper.h" #include "trie-node.h" #include "xray-registry.h" #include "llvm/ADT/StringExtras.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Errc.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FormatAdapters.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/XRay/Graph.h" #include "llvm/XRay/InstrumentationMap.h" #include "llvm/XRay/Trace.h" using namespace llvm; using namespace llvm::xray; static cl::SubCommand Stack("stack", "Call stack accounting"); static cl::list StackInputs(cl::Positional, cl::desc(""), cl::Required, cl::sub(Stack), cl::OneOrMore); static cl::opt StackKeepGoing("keep-going", cl::desc("Keep going on errors encountered"), cl::sub(Stack), cl::init(false)); static cl::alias StackKeepGoing2("k", cl::aliasopt(StackKeepGoing), cl::desc("Alias for -keep-going")); // TODO: Does there need to be an option to deduce tail or sibling calls? static cl::opt StacksInstrMap( "instr_map", cl::desc("instrumentation map used to identify function ids. " "Currently supports elf file instrumentation maps."), cl::sub(Stack), cl::init("")); static cl::alias StacksInstrMap2("m", cl::aliasopt(StacksInstrMap), cl::desc("Alias for -instr_map")); static cl::opt SeparateThreadStacks("per-thread-stacks", cl::desc("Report top stacks within each thread id"), cl::sub(Stack), cl::init(false)); static cl::opt AggregateThreads("aggregate-threads", cl::desc("Aggregate stack times across threads"), cl::sub(Stack), cl::init(false)); static cl::opt DumpAllStacks("all-stacks", cl::desc("Dump sum of timings for all stacks. " "By default separates stacks per-thread."), cl::sub(Stack), cl::init(false)); static cl::alias DumpAllStacksShort("all", cl::aliasopt(DumpAllStacks), cl::desc("Alias for -all-stacks")); // TODO(kpw): Add other interesting formats. Perhaps chrome trace viewer format // possibly with aggregations or just a linear trace of timings. enum StackOutputFormat { HUMAN, FLAMETOOL }; static cl::opt StacksOutputFormat( "stack-format", cl::desc("The format that output stacks should be " "output in. Only applies with all-stacks."), cl::values( clEnumValN(HUMAN, "human", "Human readable output. Only valid without -all-stacks."), clEnumValN(FLAMETOOL, "flame", "Format consumable by Brendan Gregg's FlameGraph tool. " "Only valid with -all-stacks.")), cl::sub(Stack), cl::init(HUMAN)); // Types of values for each stack in a CallTrie. enum class AggregationType { TOTAL_TIME, // The total time spent in a stack and its callees. INVOCATION_COUNT // The number of times the stack was invoked. }; static cl::opt RequestedAggregation( "aggregation-type", cl::desc("The type of aggregation to do on call stacks."), cl::values( clEnumValN( AggregationType::TOTAL_TIME, "time", "Capture the total time spent in an all invocations of a stack."), clEnumValN(AggregationType::INVOCATION_COUNT, "count", "Capture the number of times a stack was invoked. " "In flamegraph mode, this count also includes invocations " "of all callees.")), cl::sub(Stack), cl::init(AggregationType::TOTAL_TIME)); /// A helper struct to work with formatv and XRayRecords. Makes it easier to /// use instrumentation map names or addresses in formatted output. struct format_xray_record : public FormatAdapter { explicit format_xray_record(XRayRecord record, const FuncIdConversionHelper &conv) : FormatAdapter(std::move(record)), Converter(&conv) {} void format(raw_ostream &Stream, StringRef Style) override { Stream << formatv( "{FuncId: \"{0}\", ThreadId: \"{1}\", RecordType: \"{2}\"}", Converter->SymbolOrNumber(Item.FuncId), Item.TId, DecodeRecordType(Item.RecordType)); } private: Twine DecodeRecordType(uint16_t recordType) { switch (recordType) { case 0: return Twine("Fn Entry"); case 1: return Twine("Fn Exit"); default: // TODO: Add Tail exit when it is added to llvm/XRay/XRayRecord.h return Twine("Unknown"); } } const FuncIdConversionHelper *Converter; }; /// The stack command will take a set of XRay traces as arguments, and collects /// information about the stacks of instrumented functions that appear in the /// traces. We track the following pieces of information: /// /// - Total time: amount of time/cycles accounted for in the traces. /// - Stack count: number of times a specific stack appears in the /// traces. Only instrumented functions show up in stacks. /// - Cumulative stack time: amount of time spent in a stack accumulated /// across the invocations in the traces. /// - Cumulative local time: amount of time spent in each instrumented /// function showing up in a specific stack, accumulated across the traces. /// /// Example output for the kind of data we'd like to provide looks like the /// following: /// /// Total time: 3.33234 s /// Stack ID: ... /// Stack Count: 2093 /// # Function Local Time (%) Stack Time (%) /// 0 main 2.34 ms 0.07% 3.33234 s 100% /// 1 foo() 3.30000 s 99.02% 3.33 s 99.92% /// 2 bar() 30 ms 0.90% 30 ms 0.90% /// /// We can also show distributions of the function call durations with /// statistics at each level of the stack. This works by doing the following /// algorithm: /// /// 1. When unwinding, record the duration of each unwound function associated /// with the path up to which the unwinding stops. For example: /// /// Step Duration (? means has start time) /// /// push a a = ? /// push b a = ?, a->b = ? /// push c a = ?, a->b = ?, a->b->c = ? /// pop c a = ?, a->b = ?, emit duration(a->b->c) /// pop b a = ?, emit duration(a->b) /// push c a = ?, a->c = ? /// pop c a = ?, emit duration(a->c) /// pop a emit duration(a) /// /// 2. We then account for the various stacks we've collected, and for each of /// them will have measurements that look like the following (continuing /// with the above simple example): /// /// c : [b->c"), [durations]>, c"), [durations]>] /// b : [b"), [durations]>] /// a : [] /// /// This allows us to compute, for each stack id, and each function that /// shows up in the stack, some important statistics like: /// /// - median /// - 99th percentile /// - mean + stddev /// - count /// /// 3. For cases where we don't have durations for some of the higher levels /// of the stack (perhaps instrumentation wasn't activated when the stack was /// entered), we can mark them appropriately. /// /// Computing this data also allows us to implement lookup by call stack nodes, /// so that we can find functions that show up in multiple stack traces and /// show the statistical properties of that function in various contexts. We /// can compute information similar to the following: /// /// Function: 'c' /// Stacks: 2 / 2 /// Stack ID: ... /// Stack Count: ... /// # Function ... /// 0 a ... /// 1 b ... /// 2 c ... /// /// Stack ID: ... /// Stack Count: ... /// # Function ... /// 0 a ... /// 1 c ... /// ----------------... /// /// Function: 'b' /// Stacks: 1 / 2 /// Stack ID: ... /// Stack Count: ... /// # Function ... /// 0 a ... /// 1 b ... /// 2 c ... /// /// /// To do this we require a Trie data structure that will allow us to represent /// all the call stacks of instrumented functions in an easily traversible /// manner when we do the aggregations and lookups. For instrumented call /// sequences like the following: /// /// a() /// b() /// c() /// d() /// c() /// /// We will have a representation like so: /// /// a -> b -> c /// | | /// | +--> d /// | /// +--> c /// /// We maintain a sequence of durations on the leaves and in the internal nodes /// as we go through and process every record from the XRay trace. We also /// maintain an index of unique functions, and provide a means of iterating /// through all the instrumented call stacks which we know about. struct StackDuration { llvm::SmallVector TerminalDurations; llvm::SmallVector IntermediateDurations; }; StackDuration mergeStackDuration(const StackDuration &Left, const StackDuration &Right) { StackDuration Data{}; Data.TerminalDurations.reserve(Left.TerminalDurations.size() + Right.TerminalDurations.size()); Data.IntermediateDurations.reserve(Left.IntermediateDurations.size() + Right.IntermediateDurations.size()); // Aggregate the durations. for (auto duration : Left.TerminalDurations) Data.TerminalDurations.push_back(duration); for (auto duration : Right.TerminalDurations) Data.TerminalDurations.push_back(duration); for (auto duration : Left.IntermediateDurations) Data.IntermediateDurations.push_back(duration); for (auto duration : Right.IntermediateDurations) Data.IntermediateDurations.push_back(duration); return Data; } using StackTrieNode = TrieNode; template std::size_t GetValueForStack(const StackTrieNode *Node); // When computing total time spent in a stack, we're adding the timings from // its callees and the timings from when it was a leaf. template <> std::size_t GetValueForStack(const StackTrieNode *Node) { auto TopSum = std::accumulate(Node->ExtraData.TerminalDurations.begin(), Node->ExtraData.TerminalDurations.end(), 0uLL); return std::accumulate(Node->ExtraData.IntermediateDurations.begin(), Node->ExtraData.IntermediateDurations.end(), TopSum); } // Calculates how many times a function was invoked. // TODO: Hook up option to produce stacks template <> std::size_t GetValueForStack(const StackTrieNode *Node) { return Node->ExtraData.TerminalDurations.size() + Node->ExtraData.IntermediateDurations.size(); } // Make sure there are implementations for each enum value. template struct DependentFalseType : std::false_type {}; template std::size_t GetValueForStack(const StackTrieNode *Node) { static_assert(DependentFalseType::value, "No implementation found for aggregation type provided."); return 0; } class StackTrie { // Avoid the magic number of 4 propagated through the code with an alias. // We use this SmallVector to track the root nodes in a call graph. using RootVector = SmallVector; // We maintain pointers to the roots of the tries we see. DenseMap Roots; // We make sure all the nodes are accounted for in this list. std::forward_list NodeStore; // A map of thread ids to pairs call stack trie nodes and their start times. DenseMap, 8>> ThreadStackMap; StackTrieNode *createTrieNode(uint32_t ThreadId, int32_t FuncId, StackTrieNode *Parent) { NodeStore.push_front(StackTrieNode{FuncId, Parent, {}, {{}, {}}}); auto I = NodeStore.begin(); auto *Node = &*I; if (!Parent) Roots[ThreadId].push_back(Node); return Node; } StackTrieNode *findRootNode(uint32_t ThreadId, int32_t FuncId) { const auto &RootsByThread = Roots[ThreadId]; auto I = find_if(RootsByThread, [&](StackTrieNode *N) { return N->FuncId == FuncId; }); return (I == RootsByThread.end()) ? nullptr : *I; } public: enum class AccountRecordStatus { OK, // Successfully processed ENTRY_NOT_FOUND, // An exit record had no matching call stack entry UNKNOWN_RECORD_TYPE }; struct AccountRecordState { // We keep track of whether the call stack is currently unwinding. bool wasLastRecordExit; static AccountRecordState CreateInitialState() { return {false}; } }; AccountRecordStatus accountRecord(const XRayRecord &R, AccountRecordState *state) { auto &TS = ThreadStackMap[R.TId]; switch (R.Type) { case RecordTypes::CUSTOM_EVENT: case RecordTypes::TYPED_EVENT: return AccountRecordStatus::OK; case RecordTypes::ENTER: case RecordTypes::ENTER_ARG: { state->wasLastRecordExit = false; // When we encounter a new function entry, we want to record the TSC for // that entry, and the function id. Before doing so we check the top of // the stack to see if there are callees that already represent this // function. if (TS.empty()) { auto *Root = findRootNode(R.TId, R.FuncId); TS.emplace_back(Root ? Root : createTrieNode(R.TId, R.FuncId, nullptr), R.TSC); return AccountRecordStatus::OK; } auto &Top = TS.back(); auto I = find_if(Top.first->Callees, [&](StackTrieNode *N) { return N->FuncId == R.FuncId; }); if (I == Top.first->Callees.end()) { // We didn't find the callee in the stack trie, so we're going to // add to the stack then set up the pointers properly. auto N = createTrieNode(R.TId, R.FuncId, Top.first); Top.first->Callees.emplace_back(N); // Top may be invalidated after this statement. TS.emplace_back(N, R.TSC); } else { // We found the callee in the stack trie, so we'll use that pointer // instead, add it to the stack associated with the TSC. TS.emplace_back(*I, R.TSC); } return AccountRecordStatus::OK; } case RecordTypes::EXIT: case RecordTypes::TAIL_EXIT: { bool wasLastRecordExit = state->wasLastRecordExit; state->wasLastRecordExit = true; // The exit case is more interesting, since we want to be able to deduce // missing exit records. To do that properly, we need to look up the stack // and see whether the exit record matches any of the entry records. If it // does match, we attempt to record the durations as we pop the stack to // where we see the parent. if (TS.empty()) { // Short circuit, and say we can't find it. return AccountRecordStatus::ENTRY_NOT_FOUND; } auto FunctionEntryMatch = find_if( reverse(TS), [&](const std::pair &E) { return E.first->FuncId == R.FuncId; }); auto status = AccountRecordStatus::OK; if (FunctionEntryMatch == TS.rend()) { status = AccountRecordStatus::ENTRY_NOT_FOUND; } else { // Account for offset of 1 between reverse and forward iterators. We // want the forward iterator to include the function that is exited. ++FunctionEntryMatch; } auto I = FunctionEntryMatch.base(); for (auto &E : make_range(I, TS.end() - 1)) E.first->ExtraData.IntermediateDurations.push_back( std::max(E.second, R.TSC) - std::min(E.second, R.TSC)); auto &Deepest = TS.back(); if (wasLastRecordExit) Deepest.first->ExtraData.IntermediateDurations.push_back( std::max(Deepest.second, R.TSC) - std::min(Deepest.second, R.TSC)); else Deepest.first->ExtraData.TerminalDurations.push_back( std::max(Deepest.second, R.TSC) - std::min(Deepest.second, R.TSC)); TS.erase(I, TS.end()); return status; } } return AccountRecordStatus::UNKNOWN_RECORD_TYPE; } bool isEmpty() const { return Roots.empty(); } void printStack(raw_ostream &OS, const StackTrieNode *Top, FuncIdConversionHelper &FN) { // Traverse the pointers up to the parent, noting the sums, then print // in reverse order (callers at top, callees down bottom). SmallVector CurrentStack; for (auto *F = Top; F != nullptr; F = F->Parent) CurrentStack.push_back(F); int Level = 0; OS << formatv("{0,-5} {1,-60} {2,+12} {3,+16}\n", "lvl", "function", "count", "sum"); for (auto *F : reverse(make_range(CurrentStack.begin() + 1, CurrentStack.end()))) { auto Sum = std::accumulate(F->ExtraData.IntermediateDurations.begin(), F->ExtraData.IntermediateDurations.end(), 0LL); auto FuncId = FN.SymbolOrNumber(F->FuncId); OS << formatv("#{0,-4} {1,-60} {2,+12} {3,+16}\n", Level++, FuncId.size() > 60 ? FuncId.substr(0, 57) + "..." : FuncId, F->ExtraData.IntermediateDurations.size(), Sum); } auto *Leaf = *CurrentStack.begin(); auto LeafSum = std::accumulate(Leaf->ExtraData.TerminalDurations.begin(), Leaf->ExtraData.TerminalDurations.end(), 0LL); auto LeafFuncId = FN.SymbolOrNumber(Leaf->FuncId); OS << formatv("#{0,-4} {1,-60} {2,+12} {3,+16}\n", Level++, LeafFuncId.size() > 60 ? LeafFuncId.substr(0, 57) + "..." : LeafFuncId, Leaf->ExtraData.TerminalDurations.size(), LeafSum); OS << "\n"; } /// Prints top stacks for each thread. void printPerThread(raw_ostream &OS, FuncIdConversionHelper &FN) { for (auto iter : Roots) { OS << "Thread " << iter.first << ":\n"; print(OS, FN, iter.second); OS << "\n"; } } /// Prints timing sums for each stack in each threads. template void printAllPerThread(raw_ostream &OS, FuncIdConversionHelper &FN, StackOutputFormat format) { for (auto iter : Roots) { uint32_t threadId = iter.first; RootVector &perThreadRoots = iter.second; bool reportThreadId = true; printAll(OS, FN, perThreadRoots, threadId, reportThreadId); } } /// Prints top stacks from looking at all the leaves and ignoring thread IDs. /// Stacks that consist of the same function IDs but were called in different /// thread IDs are not considered unique in this printout. void printIgnoringThreads(raw_ostream &OS, FuncIdConversionHelper &FN) { RootVector RootValues; // Function to pull the values out of a map iterator. using RootsType = decltype(Roots.begin())::value_type; auto MapValueFn = [](const RootsType &Value) { return Value.second; }; for (const auto &RootNodeRange : make_range(map_iterator(Roots.begin(), MapValueFn), map_iterator(Roots.end(), MapValueFn))) { for (auto *RootNode : RootNodeRange) RootValues.push_back(RootNode); } print(OS, FN, RootValues); } /// Creates a merged list of Tries for unique stacks that disregards their /// thread IDs. RootVector mergeAcrossThreads(std::forward_list &NodeStore) { RootVector MergedByThreadRoots; for (auto MapIter : Roots) { const auto &RootNodeVector = MapIter.second; for (auto *Node : RootNodeVector) { auto MaybeFoundIter = find_if(MergedByThreadRoots, [Node](StackTrieNode *elem) { return Node->FuncId == elem->FuncId; }); if (MaybeFoundIter == MergedByThreadRoots.end()) { MergedByThreadRoots.push_back(Node); } else { MergedByThreadRoots.push_back(mergeTrieNodes( **MaybeFoundIter, *Node, nullptr, NodeStore, mergeStackDuration)); MergedByThreadRoots.erase(MaybeFoundIter); } } } return MergedByThreadRoots; } /// Print timing sums for all stacks merged by Thread ID. template void printAllAggregatingThreads(raw_ostream &OS, FuncIdConversionHelper &FN, StackOutputFormat format) { std::forward_list AggregatedNodeStore; RootVector MergedByThreadRoots = mergeAcrossThreads(AggregatedNodeStore); bool reportThreadId = false; printAll(OS, FN, MergedByThreadRoots, /*threadId*/ 0, reportThreadId); } /// Merges the trie by thread id before printing top stacks. void printAggregatingThreads(raw_ostream &OS, FuncIdConversionHelper &FN) { std::forward_list AggregatedNodeStore; RootVector MergedByThreadRoots = mergeAcrossThreads(AggregatedNodeStore); print(OS, FN, MergedByThreadRoots); } // TODO: Add a format option when more than one are supported. template void printAll(raw_ostream &OS, FuncIdConversionHelper &FN, RootVector RootValues, uint32_t ThreadId, bool ReportThread) { SmallVector S; for (const auto *N : RootValues) { S.clear(); S.push_back(N); while (!S.empty()) { auto *Top = S.pop_back_val(); printSingleStack(OS, FN, ReportThread, ThreadId, Top); for (const auto *C : Top->Callees) S.push_back(C); } } } /// Prints values for stacks in a format consumable for the flamegraph.pl /// tool. This is a line based format that lists each level in the stack /// hierarchy in a semicolon delimited form followed by a space and a numeric /// value. If breaking down by thread, the thread ID will be added as the /// root level of the stack. template void printSingleStack(raw_ostream &OS, FuncIdConversionHelper &Converter, bool ReportThread, uint32_t ThreadId, const StackTrieNode *Node) { if (ReportThread) OS << "thread_" << ThreadId << ";"; SmallVector lineage{}; lineage.push_back(Node); while (lineage.back()->Parent != nullptr) lineage.push_back(lineage.back()->Parent); while (!lineage.empty()) { OS << Converter.SymbolOrNumber(lineage.back()->FuncId) << ";"; lineage.pop_back(); } OS << " " << GetValueForStack(Node) << "\n"; } void print(raw_ostream &OS, FuncIdConversionHelper &FN, RootVector RootValues) { // Go through each of the roots, and traverse the call stack, producing the // aggregates as you go along. Remember these aggregates and stacks, and // show summary statistics about: // // - Total number of unique stacks // - Top 10 stacks by count // - Top 10 stacks by aggregate duration SmallVector, 11> TopStacksByCount; SmallVector, 11> TopStacksBySum; auto greater_second = [](const std::pair &A, const std::pair &B) { return A.second > B.second; }; uint64_t UniqueStacks = 0; for (const auto *N : RootValues) { SmallVector S; S.emplace_back(N); while (!S.empty()) { auto *Top = S.pop_back_val(); // We only start printing the stack (by walking up the parent pointers) // when we get to a leaf function. if (!Top->ExtraData.TerminalDurations.empty()) { ++UniqueStacks; auto TopSum = std::accumulate(Top->ExtraData.TerminalDurations.begin(), Top->ExtraData.TerminalDurations.end(), 0uLL); { auto E = std::make_pair(Top, TopSum); TopStacksBySum.insert( llvm::lower_bound(TopStacksBySum, E, greater_second), E); if (TopStacksBySum.size() == 11) TopStacksBySum.pop_back(); } { auto E = std::make_pair(Top, Top->ExtraData.TerminalDurations.size()); TopStacksByCount.insert(std::lower_bound(TopStacksByCount.begin(), TopStacksByCount.end(), E, greater_second), E); if (TopStacksByCount.size() == 11) TopStacksByCount.pop_back(); } } for (const auto *C : Top->Callees) S.push_back(C); } } // Now print the statistics in the end. OS << "\n"; OS << "Unique Stacks: " << UniqueStacks << "\n"; OS << "Top 10 Stacks by leaf sum:\n\n"; for (const auto &P : TopStacksBySum) { OS << "Sum: " << P.second << "\n"; printStack(OS, P.first, FN); } OS << "\n"; OS << "Top 10 Stacks by leaf count:\n\n"; for (const auto &P : TopStacksByCount) { OS << "Count: " << P.second << "\n"; printStack(OS, P.first, FN); } OS << "\n"; } }; std::string CreateErrorMessage(StackTrie::AccountRecordStatus Error, const XRayRecord &Record, const FuncIdConversionHelper &Converter) { switch (Error) { case StackTrie::AccountRecordStatus::ENTRY_NOT_FOUND: return std::string( formatv("Found record {0} with no matching function entry\n", format_xray_record(Record, Converter))); default: return std::string(formatv("Unknown error type for record {0}\n", format_xray_record(Record, Converter))); } } static CommandRegistration Unused(&Stack, []() -> Error { // Load each file provided as a command-line argument. For each one of them // account to a single StackTrie, and just print the whole trie for now. StackTrie ST; InstrumentationMap Map; if (!StacksInstrMap.empty()) { auto InstrumentationMapOrError = loadInstrumentationMap(StacksInstrMap); if (!InstrumentationMapOrError) return joinErrors( make_error( Twine("Cannot open instrumentation map: ") + StacksInstrMap, std::make_error_code(std::errc::invalid_argument)), InstrumentationMapOrError.takeError()); Map = std::move(*InstrumentationMapOrError); } if (SeparateThreadStacks && AggregateThreads) return make_error( Twine("Can't specify options for per thread reporting and reporting " "that aggregates threads."), std::make_error_code(std::errc::invalid_argument)); if (!DumpAllStacks && StacksOutputFormat != HUMAN) return make_error( Twine("Can't specify a non-human format without -all-stacks."), std::make_error_code(std::errc::invalid_argument)); if (DumpAllStacks && StacksOutputFormat == HUMAN) return make_error( Twine("You must specify a non-human format when reporting with " "-all-stacks."), std::make_error_code(std::errc::invalid_argument)); symbolize::LLVMSymbolizer Symbolizer; FuncIdConversionHelper FuncIdHelper(StacksInstrMap, Symbolizer, Map.getFunctionAddresses()); // TODO: Someday, support output to files instead of just directly to // standard output. for (const auto &Filename : StackInputs) { auto TraceOrErr = loadTraceFile(Filename); if (!TraceOrErr) { if (!StackKeepGoing) return joinErrors( make_error( Twine("Failed loading input file '") + Filename + "'", std::make_error_code(std::errc::invalid_argument)), TraceOrErr.takeError()); logAllUnhandledErrors(TraceOrErr.takeError(), errs()); continue; } auto &T = *TraceOrErr; StackTrie::AccountRecordState AccountRecordState = StackTrie::AccountRecordState::CreateInitialState(); for (const auto &Record : T) { auto error = ST.accountRecord(Record, &AccountRecordState); if (error != StackTrie::AccountRecordStatus::OK) { if (!StackKeepGoing) return make_error( CreateErrorMessage(error, Record, FuncIdHelper), make_error_code(errc::illegal_byte_sequence)); errs() << CreateErrorMessage(error, Record, FuncIdHelper); } } } if (ST.isEmpty()) { return make_error( "No instrumented calls were accounted in the input file.", make_error_code(errc::result_out_of_range)); } // Report the stacks in a long form mode for another tool to analyze. if (DumpAllStacks) { if (AggregateThreads) { switch (RequestedAggregation) { case AggregationType::TOTAL_TIME: ST.printAllAggregatingThreads( outs(), FuncIdHelper, StacksOutputFormat); break; case AggregationType::INVOCATION_COUNT: ST.printAllAggregatingThreads( outs(), FuncIdHelper, StacksOutputFormat); break; } } else { switch (RequestedAggregation) { case AggregationType::TOTAL_TIME: ST.printAllPerThread(outs(), FuncIdHelper, StacksOutputFormat); break; case AggregationType::INVOCATION_COUNT: ST.printAllPerThread( outs(), FuncIdHelper, StacksOutputFormat); break; } } return Error::success(); } // We're only outputting top stacks. if (AggregateThreads) { ST.printAggregatingThreads(outs(), FuncIdHelper); } else if (SeparateThreadStacks) { ST.printPerThread(outs(), FuncIdHelper); } else { ST.printIgnoringThreads(outs(), FuncIdHelper); } return Error::success(); });