//===- xray-account.h - XRay Function Call Accounting ---------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements basic function call accounting from an XRay trace. // //===----------------------------------------------------------------------===// #include #include #include #include #include #include "xray-account.h" #include "xray-registry.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/XRay/InstrumentationMap.h" #include "llvm/XRay/Trace.h" using namespace llvm; using namespace llvm::xray; static cl::SubCommand Account("account", "Function call accounting"); static cl::opt AccountInput(cl::Positional, cl::desc(""), cl::Required, cl::sub(Account)); static cl::opt AccountKeepGoing("keep-going", cl::desc("Keep going on errors encountered"), cl::sub(Account), cl::init(false)); static cl::alias AccountKeepGoing2("k", cl::aliasopt(AccountKeepGoing), cl::desc("Alias for -keep_going"), cl::sub(Account)); static cl::opt AccountDeduceSiblingCalls( "deduce-sibling-calls", cl::desc("Deduce sibling calls when unrolling function call stacks"), cl::sub(Account), cl::init(false)); static cl::alias AccountDeduceSiblingCalls2("d", cl::aliasopt(AccountDeduceSiblingCalls), cl::desc("Alias for -deduce_sibling_calls"), cl::sub(Account)); static cl::opt AccountOutput("output", cl::value_desc("output file"), cl::init("-"), cl::desc("output file; use '-' for stdout"), cl::sub(Account)); static cl::alias AccountOutput2("o", cl::aliasopt(AccountOutput), cl::desc("Alias for -output"), cl::sub(Account)); enum class AccountOutputFormats { TEXT, CSV }; static cl::opt AccountOutputFormat("format", cl::desc("output format"), cl::values(clEnumValN(AccountOutputFormats::TEXT, "text", "report stats in text"), clEnumValN(AccountOutputFormats::CSV, "csv", "report stats in csv")), cl::sub(Account)); static cl::alias AccountOutputFormat2("f", cl::desc("Alias of -format"), cl::aliasopt(AccountOutputFormat), cl::sub(Account)); enum class SortField { FUNCID, COUNT, MIN, MED, PCT90, PCT99, MAX, SUM, FUNC, }; static cl::opt AccountSortOutput( "sort", cl::desc("sort output by this field"), cl::value_desc("field"), cl::sub(Account), cl::init(SortField::FUNCID), cl::values(clEnumValN(SortField::FUNCID, "funcid", "function id"), clEnumValN(SortField::COUNT, "count", "funciton call counts"), clEnumValN(SortField::MIN, "min", "minimum function durations"), clEnumValN(SortField::MED, "med", "median function durations"), clEnumValN(SortField::PCT90, "90p", "90th percentile durations"), clEnumValN(SortField::PCT99, "99p", "99th percentile durations"), clEnumValN(SortField::MAX, "max", "maximum function durations"), clEnumValN(SortField::SUM, "sum", "sum of call durations"), clEnumValN(SortField::FUNC, "func", "function names"))); static cl::alias AccountSortOutput2("s", cl::aliasopt(AccountSortOutput), cl::desc("Alias for -sort"), cl::sub(Account)); enum class SortDirection { ASCENDING, DESCENDING, }; static cl::opt AccountSortOrder( "sortorder", cl::desc("sort ordering"), cl::init(SortDirection::ASCENDING), cl::values(clEnumValN(SortDirection::ASCENDING, "asc", "ascending"), clEnumValN(SortDirection::DESCENDING, "dsc", "descending")), cl::sub(Account)); static cl::alias AccountSortOrder2("r", cl::aliasopt(AccountSortOrder), cl::desc("Alias for -sortorder"), cl::sub(Account)); static cl::opt AccountTop("top", cl::desc("only show the top N results"), cl::value_desc("N"), cl::sub(Account), cl::init(-1)); static cl::alias AccountTop2("p", cl::desc("Alias for -top"), cl::aliasopt(AccountTop), cl::sub(Account)); static cl::opt AccountInstrMap("instr_map", cl::desc("binary with the instrumentation map, or " "a separate instrumentation map"), cl::value_desc("binary with xray_instr_map"), cl::sub(Account), cl::init("")); static cl::alias AccountInstrMap2("m", cl::aliasopt(AccountInstrMap), cl::desc("Alias for -instr_map"), cl::sub(Account)); namespace { template void setMinMax(std::pair &MM, U &&V) { if (MM.first == 0 || MM.second == 0) MM = std::make_pair(std::forward(V), std::forward(V)); else MM = std::make_pair(std::min(MM.first, V), std::max(MM.second, V)); } template T diff(T L, T R) { return std::max(L, R) - std::min(L, R); } } // namespace bool LatencyAccountant::accountRecord(const XRayRecord &Record) { setMinMax(PerThreadMinMaxTSC[Record.TId], Record.TSC); setMinMax(PerCPUMinMaxTSC[Record.CPU], Record.TSC); if (CurrentMaxTSC == 0) CurrentMaxTSC = Record.TSC; if (Record.TSC < CurrentMaxTSC) return false; auto &ThreadStack = PerThreadFunctionStack[Record.TId]; switch (Record.Type) { case RecordTypes::ENTER: case RecordTypes::ENTER_ARG: { ThreadStack.emplace_back(Record.FuncId, Record.TSC); break; } case RecordTypes::EXIT: case RecordTypes::TAIL_EXIT: { if (ThreadStack.empty()) return false; if (ThreadStack.back().first == Record.FuncId) { const auto &Top = ThreadStack.back(); recordLatency(Top.first, diff(Top.second, Record.TSC)); ThreadStack.pop_back(); break; } if (!DeduceSiblingCalls) return false; // Look for the parent up the stack. auto Parent = std::find_if(ThreadStack.rbegin(), ThreadStack.rend(), [&](const std::pair &E) { return E.first == Record.FuncId; }); if (Parent == ThreadStack.rend()) return false; // Account time for this apparently sibling call exit up the stack. // Considering the following case: // // f() // g() // h() // // We might only ever see the following entries: // // -> f() // -> g() // -> h() // <- h() // <- f() // // Now we don't see the exit to g() because some older version of the XRay // runtime wasn't instrumenting tail exits. If we don't deduce tail calls, // we may potentially never account time for g() -- and this code would have // already bailed out, because `<- f()` doesn't match the current "top" of // stack where we're waiting for the exit to `g()` instead. This is not // ideal and brittle -- so instead we provide a potentially inaccurate // accounting of g() instead, computing it from the exit of f(). // // While it might be better that we account the time between `-> g()` and // `-> h()` as the proper accounting of time for g() here, this introduces // complexity to do correctly (need to backtrack, etc.). // // FIXME: Potentially implement the more complex deduction algorithm? auto I = std::next(Parent).base(); for (auto &E : make_range(I, ThreadStack.end())) { recordLatency(E.first, diff(E.second, Record.TSC)); } ThreadStack.erase(I, ThreadStack.end()); break; } } return true; } namespace { // We consolidate the data into a struct which we can output in various forms. struct ResultRow { uint64_t Count; double Min; double Median; double Pct90; double Pct99; double Max; double Sum; std::string DebugInfo; std::string Function; }; ResultRow getStats(std::vector &Timings) { assert(!Timings.empty()); ResultRow R; R.Sum = std::accumulate(Timings.begin(), Timings.end(), 0.0); auto MinMax = std::minmax_element(Timings.begin(), Timings.end()); R.Min = *MinMax.first; R.Max = *MinMax.second; R.Count = Timings.size(); auto MedianOff = Timings.size() / 2; std::nth_element(Timings.begin(), Timings.begin() + MedianOff, Timings.end()); R.Median = Timings[MedianOff]; auto Pct90Off = std::floor(Timings.size() * 0.9); std::nth_element(Timings.begin(), Timings.begin() + Pct90Off, Timings.end()); R.Pct90 = Timings[Pct90Off]; auto Pct99Off = std::floor(Timings.size() * 0.99); std::nth_element(Timings.begin(), Timings.begin() + Pct99Off, Timings.end()); R.Pct99 = Timings[Pct99Off]; return R; } } // namespace template void LatencyAccountant::exportStats(const XRayFileHeader &Header, F Fn) const { using TupleType = std::tuple; std::vector Results; Results.reserve(FunctionLatencies.size()); for (auto FT : FunctionLatencies) { const auto &FuncId = FT.first; auto &Timings = FT.second; Results.emplace_back(FuncId, Timings.size(), getStats(Timings)); auto &Row = std::get<2>(Results.back()); if (Header.CycleFrequency) { double CycleFrequency = Header.CycleFrequency; Row.Min /= CycleFrequency; Row.Median /= CycleFrequency; Row.Pct90 /= CycleFrequency; Row.Pct99 /= CycleFrequency; Row.Max /= CycleFrequency; Row.Sum /= CycleFrequency; } Row.Function = FuncIdHelper.SymbolOrNumber(FuncId); Row.DebugInfo = FuncIdHelper.FileLineAndColumn(FuncId); } // Sort the data according to user-provided flags. switch (AccountSortOutput) { case SortField::FUNCID: llvm::sort(Results.begin(), Results.end(), [](const TupleType &L, const TupleType &R) { if (AccountSortOrder == SortDirection::ASCENDING) return std::get<0>(L) < std::get<0>(R); if (AccountSortOrder == SortDirection::DESCENDING) return std::get<0>(L) > std::get<0>(R); llvm_unreachable("Unknown sort direction"); }); break; case SortField::COUNT: llvm::sort(Results.begin(), Results.end(), [](const TupleType &L, const TupleType &R) { if (AccountSortOrder == SortDirection::ASCENDING) return std::get<1>(L) < std::get<1>(R); if (AccountSortOrder == SortDirection::DESCENDING) return std::get<1>(L) > std::get<1>(R); llvm_unreachable("Unknown sort direction"); }); break; default: // Here we need to look into the ResultRow for the rest of the data that // we want to sort by. llvm::sort(Results.begin(), Results.end(), [&](const TupleType &L, const TupleType &R) { auto &LR = std::get<2>(L); auto &RR = std::get<2>(R); switch (AccountSortOutput) { case SortField::COUNT: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Count < RR.Count; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Count > RR.Count; llvm_unreachable("Unknown sort direction"); case SortField::MIN: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Min < RR.Min; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Min > RR.Min; llvm_unreachable("Unknown sort direction"); case SortField::MED: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Median < RR.Median; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Median > RR.Median; llvm_unreachable("Unknown sort direction"); case SortField::PCT90: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Pct90 < RR.Pct90; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Pct90 > RR.Pct90; llvm_unreachable("Unknown sort direction"); case SortField::PCT99: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Pct99 < RR.Pct99; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Pct99 > RR.Pct99; llvm_unreachable("Unknown sort direction"); case SortField::MAX: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Max < RR.Max; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Max > RR.Max; llvm_unreachable("Unknown sort direction"); case SortField::SUM: if (AccountSortOrder == SortDirection::ASCENDING) return LR.Sum < RR.Sum; if (AccountSortOrder == SortDirection::DESCENDING) return LR.Sum > RR.Sum; llvm_unreachable("Unknown sort direction"); default: llvm_unreachable("Unsupported sort order"); } }); break; } if (AccountTop > 0) { auto MaxTop = std::min(AccountTop.getValue(), static_cast(Results.size())); Results.erase(Results.begin() + MaxTop, Results.end()); } for (const auto &R : Results) Fn(std::get<0>(R), std::get<1>(R), std::get<2>(R)); } void LatencyAccountant::exportStatsAsText(raw_ostream &OS, const XRayFileHeader &Header) const { OS << "Functions with latencies: " << FunctionLatencies.size() << "\n"; // We spend some effort to make the text output more readable, so we do the // following formatting decisions for each of the fields: // // - funcid: 32-bit, but we can determine the largest number and be // between // a minimum of 5 characters, up to 9 characters, right aligned. // - count: 64-bit, but we can determine the largest number and be // between // a minimum of 5 characters, up to 9 characters, right aligned. // - min, median, 90pct, 99pct, max: double precision, but we want to keep // the values in seconds, with microsecond precision (0.000'001), so we // have at most 6 significant digits, with the whole number part to be // at // least 1 character. For readability we'll right-align, with full 9 // characters each. // - debug info, function name: we format this as a concatenation of the // debug info and the function name. // static constexpr char StatsHeaderFormat[] = "{0,+9} {1,+10} [{2,+9}, {3,+9}, {4,+9}, {5,+9}, {6,+9}] {7,+9}"; static constexpr char StatsFormat[] = R"({0,+9} {1,+10} [{2,+9:f6}, {3,+9:f6}, {4,+9:f6}, {5,+9:f6}, {6,+9:f6}] {7,+9:f6})"; OS << llvm::formatv(StatsHeaderFormat, "funcid", "count", "min", "med", "90p", "99p", "max", "sum") << llvm::formatv(" {0,-12}\n", "function"); exportStats(Header, [&](int32_t FuncId, size_t Count, const ResultRow &Row) { OS << llvm::formatv(StatsFormat, FuncId, Count, Row.Min, Row.Median, Row.Pct90, Row.Pct99, Row.Max, Row.Sum) << " " << Row.DebugInfo << ": " << Row.Function << "\n"; }); } void LatencyAccountant::exportStatsAsCSV(raw_ostream &OS, const XRayFileHeader &Header) const { OS << "funcid,count,min,median,90%ile,99%ile,max,sum,debug,function\n"; exportStats(Header, [&](int32_t FuncId, size_t Count, const ResultRow &Row) { OS << FuncId << ',' << Count << ',' << Row.Min << ',' << Row.Median << ',' << Row.Pct90 << ',' << Row.Pct99 << ',' << Row.Max << "," << Row.Sum << ",\"" << Row.DebugInfo << "\",\"" << Row.Function << "\"\n"; }); } using namespace llvm::xray; namespace llvm { template <> struct format_provider { static void format(const llvm::xray::RecordTypes &T, raw_ostream &Stream, StringRef Style) { switch(T) { case RecordTypes::ENTER: Stream << "enter"; break; case RecordTypes::ENTER_ARG: Stream << "enter-arg"; break; case RecordTypes::EXIT: Stream << "exit"; break; case RecordTypes::TAIL_EXIT: Stream << "tail-exit"; break; } } }; } // namespace llvm static CommandRegistration Unused(&Account, []() -> Error { InstrumentationMap Map; if (!AccountInstrMap.empty()) { auto InstrumentationMapOrError = loadInstrumentationMap(AccountInstrMap); if (!InstrumentationMapOrError) return joinErrors(make_error( Twine("Cannot open instrumentation map '") + AccountInstrMap + "'", std::make_error_code(std::errc::invalid_argument)), InstrumentationMapOrError.takeError()); Map = std::move(*InstrumentationMapOrError); } std::error_code EC; raw_fd_ostream OS(AccountOutput, EC, sys::fs::OpenFlags::F_Text); if (EC) return make_error( Twine("Cannot open file '") + AccountOutput + "' for writing.", EC); const auto &FunctionAddresses = Map.getFunctionAddresses(); symbolize::LLVMSymbolizer::Options Opts( symbolize::FunctionNameKind::LinkageName, true, true, false, ""); symbolize::LLVMSymbolizer Symbolizer(Opts); llvm::xray::FuncIdConversionHelper FuncIdHelper(AccountInstrMap, Symbolizer, FunctionAddresses); xray::LatencyAccountant FCA(FuncIdHelper, AccountDeduceSiblingCalls); auto TraceOrErr = loadTraceFile(AccountInput); if (!TraceOrErr) return joinErrors( make_error( Twine("Failed loading input file '") + AccountInput + "'", std::make_error_code(std::errc::executable_format_error)), TraceOrErr.takeError()); auto &T = *TraceOrErr; for (const auto &Record : T) { if (FCA.accountRecord(Record)) continue; errs() << "Error processing record: " << llvm::formatv( R"({{type: {0}; cpu: {1}; record-type: {2}; function-id: {3}; tsc: {4}; thread-id: {5}; process-id: {6}}})", Record.RecordType, Record.CPU, Record.Type, Record.FuncId, Record.TSC, Record.TId, Record.PId) << '\n'; for (const auto &ThreadStack : FCA.getPerThreadFunctionStack()) { errs() << "Thread ID: " << ThreadStack.first << "\n"; if (ThreadStack.second.empty()) { errs() << " (empty stack)\n"; continue; } auto Level = ThreadStack.second.size(); for (const auto &Entry : llvm::reverse(ThreadStack.second)) errs() << " #" << Level-- << "\t" << FuncIdHelper.SymbolOrNumber(Entry.first) << '\n'; } if (!AccountKeepGoing) return make_error( Twine("Failed accounting function calls in file '") + AccountInput + "'.", std::make_error_code(std::errc::executable_format_error)); } switch (AccountOutputFormat) { case AccountOutputFormats::TEXT: FCA.exportStatsAsText(OS, T.getFileHeader()); break; case AccountOutputFormats::CSV: FCA.exportStatsAsCSV(OS, T.getFileHeader()); break; } return Error::success(); });