1 //===-- DecodedThread.cpp -------------------------------------------------===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 9 #include "DecodedThread.h" 10 #include "TraceCursorIntelPT.h" 11 #include <intel-pt.h> 12 #include <memory> 13 #include <optional> 14 15 using namespace lldb; 16 using namespace lldb_private; 17 using namespace lldb_private::trace_intel_pt; 18 using namespace llvm; 19 20 char IntelPTError::ID; 21 22 IntelPTError::IntelPTError(int libipt_error_code, lldb::addr_t address) 23 : m_libipt_error_code(libipt_error_code), m_address(address) { 24 assert(libipt_error_code < 0); 25 } 26 27 void IntelPTError::log(llvm::raw_ostream &OS) const { 28 OS << pt_errstr(pt_errcode(m_libipt_error_code)); 29 if (m_address != LLDB_INVALID_ADDRESS && m_address > 0) 30 OS << formatv(": {0:x+16}", m_address); 31 } 32 33 bool DecodedThread::TSCRange::InRange(uint64_t item_index) const { 34 return item_index >= first_item_index && 35 item_index < first_item_index + items_count; 36 } 37 38 bool DecodedThread::NanosecondsRange::InRange(uint64_t item_index) const { 39 return item_index >= first_item_index && 40 item_index < first_item_index + items_count; 41 } 42 43 double DecodedThread::NanosecondsRange::GetInterpolatedTime( 44 uint64_t item_index, uint64_t begin_of_time_nanos, 45 const LinuxPerfZeroTscConversion &tsc_conversion) const { 46 uint64_t items_since_last_tsc = item_index - first_item_index; 47 48 auto interpolate = [&](uint64_t next_range_start_ns) { 49 if (next_range_start_ns == nanos) { 50 // If the resolution of the conversion formula is bad enough to consider 51 // these two timestamps as equal, then we just increase the next one by 1 52 // for correction 53 next_range_start_ns++; 54 } 55 long double item_duration = 56 static_cast<long double>(items_count) / (next_range_start_ns - nanos); 57 return (nanos - begin_of_time_nanos) + items_since_last_tsc * item_duration; 58 }; 59 60 if (!next_range) { 61 // If this is the last TSC range, so we have to extrapolate. In this case, 62 // we assume that each instruction took one TSC, which is what an 63 // instruction would take if no parallelism is achieved and the frequency 64 // multiplier is 1. 65 return interpolate(tsc_conversion.ToNanos(tsc + items_count)); 66 } 67 if (items_count < (next_range->tsc - tsc)) { 68 // If the numbers of items in this range is less than the total TSC duration 69 // of this range, i.e. each instruction taking longer than 1 TSC, then we 70 // can assume that something else happened between these TSCs (e.g. a 71 // context switch, change to kernel, decoding errors, etc). In this case, we 72 // also assume that each instruction took 1 TSC. A proper way to improve 73 // this would be to analize the next events in the trace looking for context 74 // switches or trace disablement events, but for now, as we only want an 75 // approximation, we keep it simple. We are also guaranteed that the time in 76 // nanos of the next range is different to the current one, just because of 77 // the definition of a NanosecondsRange. 78 return interpolate( 79 std::min(tsc_conversion.ToNanos(tsc + items_count), next_range->nanos)); 80 } 81 82 // In this case, each item took less than 1 TSC, so some parallelism was 83 // achieved, which is an indication that we didn't suffered of any kind of 84 // interruption. 85 return interpolate(next_range->nanos); 86 } 87 88 uint64_t DecodedThread::GetItemsCount() const { return m_item_kinds.size(); } 89 90 lldb::addr_t 91 DecodedThread::GetInstructionLoadAddress(uint64_t item_index) const { 92 return m_item_data[item_index].load_address; 93 } 94 95 lldb::addr_t 96 DecodedThread::GetSyncPointOffsetByIndex(uint64_t item_index) const { 97 return m_psb_offsets.find(item_index)->second; 98 } 99 100 ThreadSP DecodedThread::GetThread() { return m_thread_sp; } 101 102 DecodedThread::TraceItemStorage & 103 DecodedThread::CreateNewTraceItem(lldb::TraceItemKind kind) { 104 m_item_kinds.push_back(kind); 105 m_item_data.emplace_back(); 106 if (m_last_tsc) 107 (*m_last_tsc)->second.items_count++; 108 if (m_last_nanoseconds) 109 (*m_last_nanoseconds)->second.items_count++; 110 return m_item_data.back(); 111 } 112 113 void DecodedThread::NotifySyncPoint(lldb::addr_t psb_offset) { 114 m_psb_offsets.try_emplace(GetItemsCount(), psb_offset); 115 AppendEvent(lldb::eTraceEventSyncPoint); 116 } 117 118 void DecodedThread::NotifyTsc(TSC tsc) { 119 if (m_last_tsc && (*m_last_tsc)->second.tsc == tsc) 120 return; 121 if (m_last_tsc) 122 assert(tsc >= (*m_last_tsc)->second.tsc && 123 "We can't have decreasing times"); 124 125 m_last_tsc = 126 m_tscs.emplace(GetItemsCount(), TSCRange{tsc, 0, GetItemsCount()}).first; 127 128 if (m_tsc_conversion) { 129 uint64_t nanos = m_tsc_conversion->ToNanos(tsc); 130 if (!m_last_nanoseconds || (*m_last_nanoseconds)->second.nanos != nanos) { 131 m_last_nanoseconds = 132 m_nanoseconds 133 .emplace(GetItemsCount(), NanosecondsRange{nanos, tsc, nullptr, 0, 134 GetItemsCount()}) 135 .first; 136 if (*m_last_nanoseconds != m_nanoseconds.begin()) { 137 auto prev_range = prev(*m_last_nanoseconds); 138 prev_range->second.next_range = &(*m_last_nanoseconds)->second; 139 } 140 } 141 } 142 AppendEvent(lldb::eTraceEventHWClockTick); 143 } 144 145 void DecodedThread::NotifyCPU(lldb::cpu_id_t cpu_id) { 146 if (!m_last_cpu || *m_last_cpu != cpu_id) { 147 m_cpus.emplace(GetItemsCount(), cpu_id); 148 m_last_cpu = cpu_id; 149 AppendEvent(lldb::eTraceEventCPUChanged); 150 } 151 } 152 153 lldb::cpu_id_t DecodedThread::GetCPUByIndex(uint64_t item_index) const { 154 auto it = m_cpus.upper_bound(item_index); 155 return it == m_cpus.begin() ? LLDB_INVALID_CPU_ID : prev(it)->second; 156 } 157 158 std::optional<DecodedThread::TSCRange> 159 DecodedThread::GetTSCRangeByIndex(uint64_t item_index) const { 160 auto next_it = m_tscs.upper_bound(item_index); 161 if (next_it == m_tscs.begin()) 162 return std::nullopt; 163 return prev(next_it)->second; 164 } 165 166 std::optional<DecodedThread::NanosecondsRange> 167 DecodedThread::GetNanosecondsRangeByIndex(uint64_t item_index) { 168 auto next_it = m_nanoseconds.upper_bound(item_index); 169 if (next_it == m_nanoseconds.begin()) 170 return std::nullopt; 171 return prev(next_it)->second; 172 } 173 174 uint64_t DecodedThread::GetTotalInstructionCount() const { 175 return m_insn_count; 176 } 177 178 void DecodedThread::AppendEvent(lldb::TraceEvent event) { 179 CreateNewTraceItem(lldb::eTraceItemKindEvent).event = event; 180 m_events_stats.RecordEvent(event); 181 } 182 183 void DecodedThread::AppendInstruction(const pt_insn &insn) { 184 CreateNewTraceItem(lldb::eTraceItemKindInstruction).load_address = insn.ip; 185 m_insn_count++; 186 } 187 188 void DecodedThread::AppendError(const IntelPTError &error) { 189 CreateNewTraceItem(lldb::eTraceItemKindError).error = 190 ConstString(error.message()).AsCString(); 191 m_error_stats.RecordError(/*fatal=*/false); 192 } 193 194 void DecodedThread::AppendCustomError(StringRef err, bool fatal) { 195 CreateNewTraceItem(lldb::eTraceItemKindError).error = 196 ConstString(err).AsCString(); 197 m_error_stats.RecordError(fatal); 198 } 199 200 lldb::TraceEvent DecodedThread::GetEventByIndex(int item_index) const { 201 return m_item_data[item_index].event; 202 } 203 204 const DecodedThread::EventsStats &DecodedThread::GetEventsStats() const { 205 return m_events_stats; 206 } 207 208 void DecodedThread::EventsStats::RecordEvent(lldb::TraceEvent event) { 209 events_counts[event]++; 210 total_count++; 211 } 212 213 uint64_t DecodedThread::ErrorStats::GetTotalCount() const { 214 uint64_t total = 0; 215 for (const auto &[kind, count] : libipt_errors) 216 total += count; 217 218 return total + other_errors + fatal_errors; 219 } 220 221 void DecodedThread::ErrorStats::RecordError(bool fatal) { 222 if (fatal) 223 fatal_errors++; 224 else 225 other_errors++; 226 } 227 228 void DecodedThread::ErrorStats::RecordError(int libipt_error_code) { 229 libipt_errors[pt_errstr(pt_errcode(libipt_error_code))]++; 230 } 231 232 const DecodedThread::ErrorStats &DecodedThread::GetErrorStats() const { 233 return m_error_stats; 234 } 235 236 lldb::TraceItemKind 237 DecodedThread::GetItemKindByIndex(uint64_t item_index) const { 238 return static_cast<lldb::TraceItemKind>(m_item_kinds[item_index]); 239 } 240 241 const char *DecodedThread::GetErrorByIndex(uint64_t item_index) const { 242 return m_item_data[item_index].error; 243 } 244 245 DecodedThread::DecodedThread( 246 ThreadSP thread_sp, 247 const std::optional<LinuxPerfZeroTscConversion> &tsc_conversion) 248 : m_thread_sp(thread_sp), m_tsc_conversion(tsc_conversion) {} 249 250 size_t DecodedThread::CalculateApproximateMemoryUsage() const { 251 return sizeof(TraceItemStorage) * m_item_data.size() + 252 sizeof(uint8_t) * m_item_kinds.size() + 253 (sizeof(uint64_t) + sizeof(TSC)) * m_tscs.size() + 254 (sizeof(uint64_t) + sizeof(uint64_t)) * m_nanoseconds.size() + 255 (sizeof(uint64_t) + sizeof(lldb::cpu_id_t)) * m_cpus.size(); 256 } 257