src/perf_data_handler.cc - platform/external/perf_data_converter - Git at Google

 /*
  * Copyright (c) 2016, Google Inc.
  * All rights reserved.
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include <cstring>
 #include <iomanip>
 #include <memory>
 #include <sstream>
 #include <unordered_map>
 #include <vector>

 #include "int_compat.h"
 #include "intervalmap.h"
 #include "path_matching.h"
 #include "perf_data_handler.h"
 #include "string_compat.h"
 #include "quipper/perf_reader.h"

 using quipper::PerfDataProto;
 using quipper::PerfDataProto_MMapEvent;
 using quipper::PerfDataProto_CommEvent;

 namespace perftools {
 namespace {

 // Normalizer processes a PerfDataProto and maintains tables to the
 // current metadata for each process.  It drives callbacks to
 // PerfDataHandler with samples in a fully normalized form.
 class Normalizer {
  public:
   Normalizer(const PerfDataProto& perf_proto, PerfDataHandler* handler)
       : perf_proto_(perf_proto), handler_(handler) {
     for (const auto& build_id : perf_proto_.build_ids()) {
       const string& bytes = build_id.build_id_hash();
       std::stringstream hex;
       for (size_t i = 0; i < bytes.size(); ++i) {
         // The char must be turned into an int to be used by stringstream;
         // however, if the byte's value -8 it should be turned to 0x00f8 as an
         // int, not 0xfff8. This cast solves this problem.
         const auto& byte = static_cast<unsigned char>(bytes[i]);
         hex << std::hex << std::setfill('0') << std::setw(2)
             << static_cast<int>(byte);
       }
       if (build_id.filename() != "") {
         filename_to_build_id_[build_id.filename()] = hex.str();
       } else {
         std::stringstream filename;
         filename << std::hex << build_id.filename_md5_prefix();
         filename_to_build_id_[filename.str().c_str()] = hex.str();
       }
     }

     uint64 current_event_index = 0;
     for (const auto& attr : perf_proto_.file_attrs()) {
       for (uint64 id : attr.ids()) {
         id_to_event_index_[id] = current_event_index;
       }
       current_event_index++;
     }
   }

   Normalizer(const Normalizer&) = delete;
   Normalizer& operator=(const Normalizer&) = delete;

   ~Normalizer() {}

   // Convert to a protobuf using quipper and then aggregate the results.
   void Normalize();

  private:
   // Using a 32-bit type for the PID values as the max PID value on 64-bit
   // systems is 2^22, see http://man7.org/linux/man-pages/man5/proc.5.html.
   typedef std::unordered_map<uint32, PerfDataHandler::Mapping*> PidToMMapMap;
   typedef std::unordered_map<uint32, const PerfDataProto_CommEvent*>
       PidToCommMap;

   typedef IntervalMap<const PerfDataHandler::Mapping*> MMapIntervalMap;

   // Copy the parent's mmaps/comm if they exist.  Otherwise, items
   // will be lazily populated.
   void UpdateMapsWithMMapEvent(const quipper::PerfDataProto_MMapEvent* mmap);

   void UpdateMapsWithForkEvent(const quipper::PerfDataProto_ForkEvent& fork);
   void LogStats();

   // Normalize the sample_event in event_proto and call handler_->Sample
   void InvokeHandleSample(const quipper::PerfDataProto::PerfEvent& perf_event);

   // Find the MMAP event which has ip in its address range from pid.  If no
   // mapping is found, returns nullptr.
   const PerfDataHandler::Mapping* TryLookupInPid(uint32 pid, uint64 ip) const;

   // Find the mapping for a given ip given a pid context (in user or kernel
   // mappings); returns nullptr if none can be found.
   const PerfDataHandler::Mapping* GetMappingFromPidAndIP(uint32 pid,
                                                          uint64 ip) const;

   // Find the main MMAP event for this pid.  If no mapping is found,
   // nullptr is returned.
   const PerfDataHandler::Mapping* GetMainMMapFromPid(uint32 pid) const;

   // For profiles with a single event, perf doesn't bother sending the
   // id.  So, if there is only one event, the event index must be 0.
   // Returns the event index corresponding to the id for this sample, or
   // -1 for an error.
   int64 GetEventIndexForSample(
       const quipper::PerfDataProto_SampleEvent& sample) const;

   const quipper::PerfDataProto& perf_proto_;
   PerfDataHandler* handler_;  // unowned.

   // Mapping we have allocated.
   std::vector<std::unique_ptr<PerfDataHandler::Mapping>> owned_mappings_;
   std::vector<std::unique_ptr<quipper::PerfDataProto_MMapEvent>>
       owned_quipper_mappings_;

   // The event for a given sample is determined by the id.
   // Map each id to an index in the event_profiles_ vector.
   std::unordered_map<uint64, uint64> id_to_event_index_;

   // pid_to_comm_event maps a pid to the corresponding comm event.
   PidToCommMap pid_to_comm_event_;

   // pid_to_mmaps maps a pid to all mmap events that correspond to that pid.
   std::unordered_map<uint32, std::unique_ptr<MMapIntervalMap>> pid_to_mmaps_;

   // pid_to_executable_mmap maps a pid to mmap that most likely contains the
   // filename of the main executable for that pid.
   PidToMMapMap pid_to_executable_mmap_;

   // map filenames to build-ids.
   std::unordered_map<string, string> filename_to_build_id_;

   struct {
     int64 samples = 0;
     int64 missing_main_mmap = 0;
     int64 missing_sample_mmap = 0;

     int64 callchain_ips = 0;
     int64 missing_callchain_mmap = 0;

     int64 branch_stack_ips = 0;
     int64 missing_branch_stack_mmap = 0;

     int64 no_event_errors = 0;
   } stat_;
 };

 void Normalizer::UpdateMapsWithForkEvent(
     const quipper::PerfDataProto_ForkEvent& fork) {
   if (fork.pid() == fork.ppid()) {
     // Don't care about threads.
     return;
   }
   const auto& it = pid_to_mmaps_.find(fork.ppid());
   if (it != pid_to_mmaps_.end()) {
     pid_to_mmaps_[fork.pid()] = std::unique_ptr<MMapIntervalMap>(
         new MMapIntervalMap(*it->second.get()));
   }
   auto comm_it = pid_to_comm_event_.find(fork.ppid());
   if (comm_it != pid_to_comm_event_.end()) {
     pid_to_comm_event_[fork.pid()] = comm_it->second;
   }
   auto exec_mmap_it = pid_to_executable_mmap_.find(fork.ppid());
   if (exec_mmap_it != pid_to_executable_mmap_.end()) {
     pid_to_executable_mmap_[fork.pid()] = exec_mmap_it->second;
   }
 }

 inline bool HasPrefixString(const string& haystack, const char* needle) {
   const size_t needle_len = strlen(needle);
   const size_t haystack_len = haystack.length();
   return haystack_len >= needle_len &&
          haystack.compare(0, needle_len, needle) == 0;
 }

 inline bool HasSuffixString(const string& haystack, const char* needle) {
   const size_t needle_len = strlen(needle);
   const size_t haystack_len = haystack.length();
   return haystack_len >= needle_len &&
          haystack.compare(haystack_len - needle_len, needle_len, needle) == 0;
 }

 void Normalizer::Normalize() {
   for (const auto& event_proto : perf_proto_.events()) {
     if (event_proto.has_mmap_event()) {
       UpdateMapsWithMMapEvent(&event_proto.mmap_event());
     } else if (event_proto.has_comm_event()) {
       if (event_proto.comm_event().pid() == event_proto.comm_event().tid()) {
         // pid==tid happens on exec()
         pid_to_executable_mmap_.erase(event_proto.comm_event().pid());
         pid_to_comm_event_[event_proto.comm_event().pid()] =
             &event_proto.comm_event();
       }
       PerfDataHandler::CommContext comm_context;
       comm_context.comm = &event_proto.comm_event();
       handler_->Comm(comm_context);
     } else if (event_proto.has_fork_event()) {
       UpdateMapsWithForkEvent(event_proto.fork_event());
     } else if (event_proto.has_lost_event()) {
       stat_.samples += event_proto.lost_event().lost();
       stat_.missing_main_mmap += event_proto.lost_event().lost();
       stat_.missing_sample_mmap += event_proto.lost_event().lost();
       quipper::PerfDataProto::SampleEvent sample;
       quipper::PerfDataProto::EventHeader header;
       sample.set_id(event_proto.lost_event().id());
       sample.set_pid(event_proto.lost_event().sample_info().pid());
       sample.set_tid(event_proto.lost_event().sample_info().tid());
       PerfDataHandler::SampleContext context(header, sample);
       context.file_attrs_index = GetEventIndexForSample(sample);
       if (context.file_attrs_index == -1) {
         ++stat_.no_event_errors;
         continue;
       }
       for (uint64 i = 0; i < event_proto.lost_event().lost(); ++i) {
         handler_->Sample(context);
       }
     } else if (event_proto.has_sample_event()) {
       InvokeHandleSample(event_proto);
     }
   }

   LogStats();
 }

 void Normalizer::InvokeHandleSample(
     const quipper::PerfDataProto::PerfEvent& event_proto) {
   if (!event_proto.has_sample_event()) {
     std::cerr << "Expected sample event." << std::endl;
     abort();
   }
   const auto& sample = event_proto.sample_event();
   PerfDataHandler::SampleContext context(event_proto.header(),
                                          event_proto.sample_event());
   context.file_attrs_index = GetEventIndexForSample(context.sample);
   if (context.file_attrs_index == -1) {
     ++stat_.no_event_errors;
     return;
   }
   ++stat_.samples;

   uint32 pid = sample.pid();

   context.sample_mapping = GetMappingFromPidAndIP(pid, sample.ip());
   stat_.missing_sample_mmap += context.sample_mapping == nullptr;

   context.main_mapping = GetMainMMapFromPid(pid);
   std::unique_ptr<PerfDataHandler::Mapping> fake;
   // Kernel samples might take some extra work.
   if (context.main_mapping == nullptr &&
       (event_proto.header().misc() & PERF_RECORD_MISC_CPUMODE_MASK) ==
           PERF_RECORD_MISC_KERNEL) {
     auto comm_it = pid_to_comm_event_.find(pid);
     auto kernel_it = pid_to_executable_mmap_.find(-1);
     if (comm_it != pid_to_comm_event_.end()) {
       const string* build_id = nullptr;
       if (kernel_it != pid_to_executable_mmap_.end()) {
         build_id = kernel_it->second->build_id;
       }
       fake.reset(new PerfDataHandler::Mapping(&comm_it->second->comm(),
                                               build_id, 0, 1, 0, 0));
       context.main_mapping = fake.get();
     } else if (pid == 0 && kernel_it != pid_to_executable_mmap_.end()) {
       context.main_mapping = kernel_it->second;
     }
   }

   stat_.missing_main_mmap += context.main_mapping == nullptr;

   // Normalize the callchain.
   context.callchain.resize(sample.callchain_size());
   for (int i = 0; i < sample.callchain_size(); ++i) {
     ++stat_.callchain_ips;
     context.callchain[i].ip = sample.callchain(i);
     context.callchain[i].mapping =
         GetMappingFromPidAndIP(pid, sample.callchain(i));
     stat_.missing_callchain_mmap += context.callchain[i].mapping == nullptr;
   }

   // Normalize the branch_stack.
   context.branch_stack.resize(sample.branch_stack_size());
   for (int i = 0; i < sample.branch_stack_size(); ++i) {
     stat_.branch_stack_ips += 2;
     auto bse = sample.branch_stack(i);
     // from
     context.branch_stack[i].from.ip = bse.from_ip();
     context.branch_stack[i].from.mapping =
         GetMappingFromPidAndIP(pid, bse.from_ip());
     stat_.missing_branch_stack_mmap +=
         context.branch_stack[i].from.mapping == nullptr;
     // to
     context.branch_stack[i].to.ip = bse.to_ip();
     context.branch_stack[i].to.mapping =
         GetMappingFromPidAndIP(pid, bse.to_ip());
     stat_.missing_branch_stack_mmap +=
         context.branch_stack[i].to.mapping == nullptr;
     // mispredicted
     context.branch_stack[i].mispredicted = bse.mispredicted();
   }

   handler_->Sample(context);
 }

 static void CheckStat(int64 num, int64 denom, const string& desc) {
   const int max_missing_pct = 1;
   if (denom > 0 && num * 100 / denom > max_missing_pct) {
     LOG(ERROR) << "stat: " << desc << " " << num << "/" << denom;
   }
 }

 void Normalizer::LogStats() {
   CheckStat(stat_.missing_main_mmap, stat_.samples, "missing_main_mmap");
   CheckStat(stat_.missing_sample_mmap, stat_.samples, "missing_sample_mmap");
   CheckStat(stat_.missing_callchain_mmap, stat_.callchain_ips,
             "missing_callchain_mmap");
   CheckStat(stat_.missing_branch_stack_mmap, stat_.branch_stack_ips,
             "missing_branch_stack_mmap");
   CheckStat(stat_.no_event_errors, 1, "unknown event id");
 }

 static bool IsVirtualMapping(const string& map_name) {
   return HasPrefixString(map_name, "//") ||
          (HasPrefixString(map_name, "[") && HasSuffixString(map_name, "]"));
 }

 void Normalizer::UpdateMapsWithMMapEvent(
     const quipper::PerfDataProto_MMapEvent* mmap) {
   if (mmap->len() == 0) {
     LOG(WARNING) << "bogus mapping: " << mmap->filename();
     return;
   }
   uint32 pid = mmap->pid();
   MMapIntervalMap* interval_map = nullptr;
   const auto& it = pid_to_mmaps_.find(pid);
   if (it == pid_to_mmaps_.end()) {
     interval_map = new MMapIntervalMap;
     pid_to_mmaps_[pid] = std::unique_ptr<MMapIntervalMap>(interval_map);
   } else {
     interval_map = it->second.get();
   }
   std::unordered_map<string, string>::const_iterator build_id_it;
   if (mmap->filename() != "") {
     build_id_it = filename_to_build_id_.find(mmap->filename());
   } else {
     std::stringstream filename;
     filename << std::hex << mmap->filename_md5_prefix();
     build_id_it = filename_to_build_id_.find(filename.str());
   }

   const string* build_id = build_id_it == filename_to_build_id_.end()
                                ? nullptr
                                : &build_id_it->second;
   PerfDataHandler::Mapping* mapping = new PerfDataHandler::Mapping(
       &mmap->filename(), build_id, mmap->start(), mmap->start() + mmap->len(),
       mmap->pgoff(), mmap->filename_md5_prefix());
   owned_mappings_.emplace_back(mapping);
   if (mapping->file_offset > (static_cast<uint64>(1) << 63) &&
       mapping->limit > (static_cast<uint64>(1) << 63)) {
     // kernel is funky and basically swaps start and offset.  Arrange
     // them such that we can reasonably symbolize them later.
     uint64 old_start = mapping->start;
     // file_offset here actually refers to the address of the _stext
     // kernel symbol, so we need to align it.
     mapping->start = mapping->file_offset - mapping->file_offset % 4096;
     mapping->file_offset = old_start;
   }

   interval_map->Set(mapping->start, mapping->limit, mapping);
   // Pass the final mapping through to the subclass also.
   PerfDataHandler::MMapContext mmap_context;
   mmap_context.pid = pid;
   mmap_context.mapping = mapping;
   handler_->MMap(mmap_context);

   // Main executables are usually loaded at 0x8048000 or 0x400000.
   // If we ever see an MMAP starting at one of those locations, that should be
   // our guess.
   // This is true even if the old MMAP started at one of the locations, because
   // the pid may have been recycled since then (so newer is better).
   if (mapping->start == 0x8048000 || mapping->start == 0x400000) {
     pid_to_executable_mmap_[pid] = mapping;
     return;
   }
   // Figure out whether this MMAP is the main executable.
   // If there have been no previous MMAPs for this pid, then this MMAP is our
   // best guess.
   auto old_mapping_it = pid_to_executable_mmap_.find(pid);
   PerfDataHandler::Mapping* old_mapping =
       old_mapping_it == pid_to_executable_mmap_.end() ? nullptr
                                                       : old_mapping_it->second;

   if (old_mapping != nullptr && old_mapping->start == 0x400000 &&
       (old_mapping->filename == nullptr || *old_mapping->filename == "") &&
       mapping->start - mapping->file_offset == 0x400000) {
     // Hugepages remap the main binary, but the original mapping loses
     // its name, so we have this hack.
     old_mapping->filename = &mmap->filename();
   }

   static const char kKernelPrefix[] = "[kernel.kallsyms]";

   if (old_mapping == nullptr && !HasSuffixString(mmap->filename(), ".ko") &&
       !HasSuffixString(mmap->filename(), ".so") &&
       !IsDeletedSharedObject(mmap->filename()) &&
       !IsVersionedSharedObject(mmap->filename()) &&
       !IsVirtualMapping(mmap->filename()) &&
       !HasPrefixString(mmap->filename(), kKernelPrefix)) {
     if (!HasPrefixString(mmap->filename(), "/usr/bin") &&
         !HasPrefixString(mmap->filename(), "/usr/sbin") &&
         !HasSuffixString(mmap->filename(), "/sel_ldr")) {
       LOG(INFO) << "guessing main for pid: " << pid << " " << mmap->filename();
     }
     pid_to_executable_mmap_[pid] = mapping;
     return;
   }

   if (pid == std::numeric_limits<uint32>::max() &&
       HasPrefixString(mmap->filename(), kKernelPrefix)) {
     pid_to_executable_mmap_[pid] = mapping;
   }
 }

 const PerfDataHandler::Mapping* Normalizer::TryLookupInPid(uint32 pid,
                                                            uint64 ip) const {
   const auto& it = pid_to_mmaps_.find(pid);
   if (it == pid_to_mmaps_.end()) {
     VLOG(2) << "No mmaps for pid " << pid;
     return nullptr;
   }
   MMapIntervalMap* mmaps = it->second.get();

   const PerfDataHandler::Mapping* mapping = nullptr;
   mmaps->Lookup(ip, &mapping);
   return mapping;
 }

 // Find the mapping for ip in the context of pid.  We might be looking
 // at a kernel IP, however (which can show up in any pid, and are
 // stored in our map as pid = -1), so check there if the lookup fails
 // in our process.
 const PerfDataHandler::Mapping* Normalizer::GetMappingFromPidAndIP(
     uint32 pid, uint64 ip) const {
   if (ip >= PERF_CONTEXT_MAX) {
     // These aren't real IPs, they're context hints.  Drop them.
     return nullptr;
   }
   // One could try to decide if this is a kernel or user sample
   // directly.  ahh@ thinks there's a heuristic that should work on
   // x86 (basically without any error): all kernel samples should have
   // 16 high bits set, all user samples should have high 16 bits
   // cleared.  But that's not portable, and on any arch (...hopefully)
   // the user/kernel mappings should be disjoint anyway, so just check
   // both, starting with user.  We could also use PERF_CONTEXT_KERNEL
   // and friends (see for instance how perf handles this:
   // https://goto.google.com/udgor) to know whether to check user or
   // kernel, but this seems more robust.
   const PerfDataHandler::Mapping* mapping = TryLookupInPid(pid, ip);
   if (mapping == nullptr) {
     // Might be a kernel sample.
     mapping = TryLookupInPid(-1, ip);
   }
   if (mapping == nullptr) {
     VLOG(2) << "no sample mmap found for pid " << pid << " and ip " << ip;
     return nullptr;
   }
   if (ip < mapping->start || ip >= mapping->limit) {
     std::cerr << "IP is not in mapping." << std::endl
               << "IP: " << ip << std::endl
               << "Start: " << mapping->start << std::endl
               << "Limit: " << mapping->limit << std::endl;
     abort();
   }
   return mapping;
 }

 const PerfDataHandler::Mapping* Normalizer::GetMainMMapFromPid(
     uint32 pid) const {
   auto mapping_it = pid_to_executable_mmap_.find(pid);
   if (mapping_it != pid_to_executable_mmap_.end()) {
     return mapping_it->second;
   }

   VLOG(2) << "No argv0 name found for sample with pid: " << pid;
   return nullptr;
 }

 int64 Normalizer::GetEventIndexForSample(
     const quipper::PerfDataProto_SampleEvent& sample) const {
   if (perf_proto_.file_attrs().size() == 1) {
     return 0;
   }

   if (!sample.has_id()) {
     LOG(ERROR) << "Perf sample did not have id";
     return -1;
   }

   auto it = id_to_event_index_.find(sample.id());
   if (it == id_to_event_index_.end()) {
     LOG(ERROR) << "Incorrect event id: " << sample.id();
     return -1;
   }
   return it->second;
 }
 }  // namespace

 // Finds needle in haystack starting at cursor. It then returns the index
 // directly after needle or string::npos if needle was not found.
 size_t FindAfter(const string& haystack, const string& needle, size_t cursor) {
   auto next_cursor = haystack.find(needle, cursor);
   if (next_cursor != string::npos) {
     next_cursor += needle.size();
   }
   return next_cursor;
 }

 bool IsDeletedSharedObject(const string& path) {
   size_t cursor = 1;
   while ((cursor = FindAfter(path, ".so", cursor)) != string::npos) {
     const auto ch = path.at(cursor);
     if (ch == '.' || ch == '_' || ch == ' ') {
       return path.find("(deleted)", cursor) != string::npos;
     }
   }
   return false;
 }

 bool IsVersionedSharedObject(const string& path) {
   return path.find(".so.", 1) != string::npos;
 }

 PerfDataHandler::PerfDataHandler() {}

 void PerfDataHandler::Process(const quipper::PerfDataProto& perf_proto,
                               PerfDataHandler* handler) {
   Normalizer Normalizer(perf_proto, handler);
   return Normalizer.Normalize();
 }

 }  // namespace perftools
	/*
	* Copyright (c) 2016, Google Inc.
	* All rights reserved.
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include <cstring>
	#include <iomanip>
	#include <memory>
	#include <sstream>
	#include <unordered_map>
	#include <vector>

	#include "int_compat.h"
	#include "intervalmap.h"
	#include "path_matching.h"
	#include "perf_data_handler.h"
	#include "string_compat.h"
	#include "quipper/perf_reader.h"

	using quipper::PerfDataProto;
	using quipper::PerfDataProto_MMapEvent;
	using quipper::PerfDataProto_CommEvent;

	namespace perftools {
	namespace {

	// Normalizer processes a PerfDataProto and maintains tables to the
	// current metadata for each process. It drives callbacks to
	// PerfDataHandler with samples in a fully normalized form.
	class Normalizer {
	public:
	Normalizer(const PerfDataProto& perf_proto, PerfDataHandler* handler)
	: perf_proto_(perf_proto), handler_(handler) {
	for (const auto& build_id : perf_proto_.build_ids()) {
	const string& bytes = build_id.build_id_hash();
	std::stringstream hex;
	for (size_t i = 0; i < bytes.size(); ++i) {
	// The char must be turned into an int to be used by stringstream;
	// however, if the byte's value -8 it should be turned to 0x00f8 as an
	// int, not 0xfff8. This cast solves this problem.
	const auto& byte = static_cast<unsigned char>(bytes[i]);
	hex << std::hex << std::setfill('0') << std::setw(2)
	<< static_cast<int>(byte);
	}
	if (build_id.filename() != "") {
	filename_to_build_id_[build_id.filename()] = hex.str();
	} else {
	std::stringstream filename;
	filename << std::hex << build_id.filename_md5_prefix();
	filename_to_build_id_[filename.str().c_str()] = hex.str();
	}
	}

	uint64 current_event_index = 0;
	for (const auto& attr : perf_proto_.file_attrs()) {
	for (uint64 id : attr.ids()) {
	id_to_event_index_[id] = current_event_index;
	}
	current_event_index++;
	}
	}

	Normalizer(const Normalizer&) = delete;
	Normalizer& operator=(const Normalizer&) = delete;

	~Normalizer() {}

	// Convert to a protobuf using quipper and then aggregate the results.
	void Normalize();

	private:
	// Using a 32-bit type for the PID values as the max PID value on 64-bit
	// systems is 2^22, see http://man7.org/linux/man-pages/man5/proc.5.html.
	typedef std::unordered_map<uint32, PerfDataHandler::Mapping*> PidToMMapMap;
	typedef std::unordered_map<uint32, const PerfDataProto_CommEvent*>
	PidToCommMap;

	typedef IntervalMap<const PerfDataHandler::Mapping*> MMapIntervalMap;

	// Copy the parent's mmaps/comm if they exist. Otherwise, items
	// will be lazily populated.
	void UpdateMapsWithMMapEvent(const quipper::PerfDataProto_MMapEvent* mmap);

	void UpdateMapsWithForkEvent(const quipper::PerfDataProto_ForkEvent& fork);
	void LogStats();

	// Normalize the sample_event in event_proto and call handler_->Sample
	void InvokeHandleSample(const quipper::PerfDataProto::PerfEvent& perf_event);

	// Find the MMAP event which has ip in its address range from pid. If no
	// mapping is found, returns nullptr.
	const PerfDataHandler::Mapping* TryLookupInPid(uint32 pid, uint64 ip) const;

	// Find the mapping for a given ip given a pid context (in user or kernel
	// mappings); returns nullptr if none can be found.
	const PerfDataHandler::Mapping* GetMappingFromPidAndIP(uint32 pid,
	uint64 ip) const;

	// Find the main MMAP event for this pid. If no mapping is found,
	// nullptr is returned.
	const PerfDataHandler::Mapping* GetMainMMapFromPid(uint32 pid) const;

	// For profiles with a single event, perf doesn't bother sending the
	// id. So, if there is only one event, the event index must be 0.
	// Returns the event index corresponding to the id for this sample, or
	// -1 for an error.
	int64 GetEventIndexForSample(
	const quipper::PerfDataProto_SampleEvent& sample) const;

	const quipper::PerfDataProto& perf_proto_;
	PerfDataHandler* handler_; // unowned.

	// Mapping we have allocated.
	std::vector<std::unique_ptr<PerfDataHandler::Mapping>> owned_mappings_;
	std::vector<std::unique_ptr<quipper::PerfDataProto_MMapEvent>>
	owned_quipper_mappings_;

	// The event for a given sample is determined by the id.
	// Map each id to an index in the event_profiles_ vector.
	std::unordered_map<uint64, uint64> id_to_event_index_;

	// pid_to_comm_event maps a pid to the corresponding comm event.
	PidToCommMap pid_to_comm_event_;

	// pid_to_mmaps maps a pid to all mmap events that correspond to that pid.
	std::unordered_map<uint32, std::unique_ptr<MMapIntervalMap>> pid_to_mmaps_;

	// pid_to_executable_mmap maps a pid to mmap that most likely contains the
	// filename of the main executable for that pid.
	PidToMMapMap pid_to_executable_mmap_;

	// map filenames to build-ids.
	std::unordered_map<string, string> filename_to_build_id_;

	struct {
	int64 samples = 0;
	int64 missing_main_mmap = 0;
	int64 missing_sample_mmap = 0;

	int64 callchain_ips = 0;
	int64 missing_callchain_mmap = 0;

	int64 branch_stack_ips = 0;
	int64 missing_branch_stack_mmap = 0;

	int64 no_event_errors = 0;
	} stat_;
	};

	void Normalizer::UpdateMapsWithForkEvent(
	const quipper::PerfDataProto_ForkEvent& fork) {
	if (fork.pid() == fork.ppid()) {
	// Don't care about threads.
	return;
	}
	const auto& it = pid_to_mmaps_.find(fork.ppid());
	if (it != pid_to_mmaps_.end()) {
	pid_to_mmaps_[fork.pid()] = std::unique_ptr<MMapIntervalMap>(
	new MMapIntervalMap(*it->second.get()));
	}
	auto comm_it = pid_to_comm_event_.find(fork.ppid());
	if (comm_it != pid_to_comm_event_.end()) {
	pid_to_comm_event_[fork.pid()] = comm_it->second;
	}
	auto exec_mmap_it = pid_to_executable_mmap_.find(fork.ppid());
	if (exec_mmap_it != pid_to_executable_mmap_.end()) {
	pid_to_executable_mmap_[fork.pid()] = exec_mmap_it->second;
	}
	}

	inline bool HasPrefixString(const string& haystack, const char* needle) {
	const size_t needle_len = strlen(needle);
	const size_t haystack_len = haystack.length();
	return haystack_len >= needle_len &&
	haystack.compare(0, needle_len, needle) == 0;
	}

	inline bool HasSuffixString(const string& haystack, const char* needle) {
	const size_t needle_len = strlen(needle);
	const size_t haystack_len = haystack.length();
	return haystack_len >= needle_len &&
	haystack.compare(haystack_len - needle_len, needle_len, needle) == 0;
	}

	void Normalizer::Normalize() {
	for (const auto& event_proto : perf_proto_.events()) {
	if (event_proto.has_mmap_event()) {
	UpdateMapsWithMMapEvent(&event_proto.mmap_event());
	} else if (event_proto.has_comm_event()) {
	if (event_proto.comm_event().pid() == event_proto.comm_event().tid()) {
	// pid==tid happens on exec()
	pid_to_executable_mmap_.erase(event_proto.comm_event().pid());
	pid_to_comm_event_[event_proto.comm_event().pid()] =
	&event_proto.comm_event();
	}
	PerfDataHandler::CommContext comm_context;
	comm_context.comm = &event_proto.comm_event();
	handler_->Comm(comm_context);
	} else if (event_proto.has_fork_event()) {
	UpdateMapsWithForkEvent(event_proto.fork_event());
	} else if (event_proto.has_lost_event()) {
	stat_.samples += event_proto.lost_event().lost();
	stat_.missing_main_mmap += event_proto.lost_event().lost();
	stat_.missing_sample_mmap += event_proto.lost_event().lost();
	quipper::PerfDataProto::SampleEvent sample;
	quipper::PerfDataProto::EventHeader header;
	sample.set_id(event_proto.lost_event().id());
	sample.set_pid(event_proto.lost_event().sample_info().pid());
	sample.set_tid(event_proto.lost_event().sample_info().tid());
	PerfDataHandler::SampleContext context(header, sample);
	context.file_attrs_index = GetEventIndexForSample(sample);
	if (context.file_attrs_index == -1) {
	++stat_.no_event_errors;
	continue;
	}
	for (uint64 i = 0; i < event_proto.lost_event().lost(); ++i) {
	handler_->Sample(context);
	}
	} else if (event_proto.has_sample_event()) {
	InvokeHandleSample(event_proto);
	}
	}

	LogStats();
	}

	void Normalizer::InvokeHandleSample(
	const quipper::PerfDataProto::PerfEvent& event_proto) {
	if (!event_proto.has_sample_event()) {
	std::cerr << "Expected sample event." << std::endl;
	abort();
	}
	const auto& sample = event_proto.sample_event();
	PerfDataHandler::SampleContext context(event_proto.header(),
	event_proto.sample_event());
	context.file_attrs_index = GetEventIndexForSample(context.sample);
	if (context.file_attrs_index == -1) {
	++stat_.no_event_errors;
	return;
	}
	++stat_.samples;

	uint32 pid = sample.pid();

	context.sample_mapping = GetMappingFromPidAndIP(pid, sample.ip());
	stat_.missing_sample_mmap += context.sample_mapping == nullptr;

	context.main_mapping = GetMainMMapFromPid(pid);
	std::unique_ptr<PerfDataHandler::Mapping> fake;
	// Kernel samples might take some extra work.
	if (context.main_mapping == nullptr &&
	(event_proto.header().misc() & PERF_RECORD_MISC_CPUMODE_MASK) ==
	PERF_RECORD_MISC_KERNEL) {
	auto comm_it = pid_to_comm_event_.find(pid);
	auto kernel_it = pid_to_executable_mmap_.find(-1);
	if (comm_it != pid_to_comm_event_.end()) {
	const string* build_id = nullptr;
	if (kernel_it != pid_to_executable_mmap_.end()) {
	build_id = kernel_it->second->build_id;
	}
	fake.reset(new PerfDataHandler::Mapping(&comm_it->second->comm(),
	build_id, 0, 1, 0, 0));
	context.main_mapping = fake.get();
	} else if (pid == 0 && kernel_it != pid_to_executable_mmap_.end()) {
	context.main_mapping = kernel_it->second;
	}
	}

	stat_.missing_main_mmap += context.main_mapping == nullptr;

	// Normalize the callchain.
	context.callchain.resize(sample.callchain_size());
	for (int i = 0; i < sample.callchain_size(); ++i) {
	++stat_.callchain_ips;
	context.callchain[i].ip = sample.callchain(i);
	context.callchain[i].mapping =
	GetMappingFromPidAndIP(pid, sample.callchain(i));
	stat_.missing_callchain_mmap += context.callchain[i].mapping == nullptr;
	}

	// Normalize the branch_stack.
	context.branch_stack.resize(sample.branch_stack_size());
	for (int i = 0; i < sample.branch_stack_size(); ++i) {
	stat_.branch_stack_ips += 2;
	auto bse = sample.branch_stack(i);
	// from
	context.branch_stack[i].from.ip = bse.from_ip();
	context.branch_stack[i].from.mapping =
	GetMappingFromPidAndIP(pid, bse.from_ip());
	stat_.missing_branch_stack_mmap +=
	context.branch_stack[i].from.mapping == nullptr;
	// to
	context.branch_stack[i].to.ip = bse.to_ip();
	context.branch_stack[i].to.mapping =
	GetMappingFromPidAndIP(pid, bse.to_ip());
	stat_.missing_branch_stack_mmap +=
	context.branch_stack[i].to.mapping == nullptr;
	// mispredicted
	context.branch_stack[i].mispredicted = bse.mispredicted();
	}

	handler_->Sample(context);
	}

	static void CheckStat(int64 num, int64 denom, const string& desc) {
	const int max_missing_pct = 1;
	if (denom > 0 && num * 100 / denom > max_missing_pct) {
	LOG(ERROR) << "stat: " << desc << " " << num << "/" << denom;
	}
	}

	void Normalizer::LogStats() {
	CheckStat(stat_.missing_main_mmap, stat_.samples, "missing_main_mmap");
	CheckStat(stat_.missing_sample_mmap, stat_.samples, "missing_sample_mmap");
	CheckStat(stat_.missing_callchain_mmap, stat_.callchain_ips,
	"missing_callchain_mmap");
	CheckStat(stat_.missing_branch_stack_mmap, stat_.branch_stack_ips,
	"missing_branch_stack_mmap");
	CheckStat(stat_.no_event_errors, 1, "unknown event id");
	}

	static bool IsVirtualMapping(const string& map_name) {
	return HasPrefixString(map_name, "//") \|\|
	(HasPrefixString(map_name, "[") && HasSuffixString(map_name, "]"));
	}

	void Normalizer::UpdateMapsWithMMapEvent(
	const quipper::PerfDataProto_MMapEvent* mmap) {
	if (mmap->len() == 0) {
	LOG(WARNING) << "bogus mapping: " << mmap->filename();
	return;
	}
	uint32 pid = mmap->pid();
	MMapIntervalMap* interval_map = nullptr;
	const auto& it = pid_to_mmaps_.find(pid);
	if (it == pid_to_mmaps_.end()) {
	interval_map = new MMapIntervalMap;
	pid_to_mmaps_[pid] = std::unique_ptr<MMapIntervalMap>(interval_map);
	} else {
	interval_map = it->second.get();
	}
	std::unordered_map<string, string>::const_iterator build_id_it;
	if (mmap->filename() != "") {
	build_id_it = filename_to_build_id_.find(mmap->filename());
	} else {
	std::stringstream filename;
	filename << std::hex << mmap->filename_md5_prefix();
	build_id_it = filename_to_build_id_.find(filename.str());
	}

	const string* build_id = build_id_it == filename_to_build_id_.end()
	? nullptr
	: &build_id_it->second;
	PerfDataHandler::Mapping* mapping = new PerfDataHandler::Mapping(
	&mmap->filename(), build_id, mmap->start(), mmap->start() + mmap->len(),
	mmap->pgoff(), mmap->filename_md5_prefix());
	owned_mappings_.emplace_back(mapping);
	if (mapping->file_offset > (static_cast<uint64>(1) << 63) &&
	mapping->limit > (static_cast<uint64>(1) << 63)) {
	// kernel is funky and basically swaps start and offset. Arrange
	// them such that we can reasonably symbolize them later.
	uint64 old_start = mapping->start;
	// file_offset here actually refers to the address of the _stext
	// kernel symbol, so we need to align it.
	mapping->start = mapping->file_offset - mapping->file_offset % 4096;
	mapping->file_offset = old_start;
	}

	interval_map->Set(mapping->start, mapping->limit, mapping);
	// Pass the final mapping through to the subclass also.
	PerfDataHandler::MMapContext mmap_context;
	mmap_context.pid = pid;
	mmap_context.mapping = mapping;
	handler_->MMap(mmap_context);

	// Main executables are usually loaded at 0x8048000 or 0x400000.
	// If we ever see an MMAP starting at one of those locations, that should be
	// our guess.
	// This is true even if the old MMAP started at one of the locations, because
	// the pid may have been recycled since then (so newer is better).
	if (mapping->start == 0x8048000 \|\| mapping->start == 0x400000) {
	pid_to_executable_mmap_[pid] = mapping;
	return;
	}
	// Figure out whether this MMAP is the main executable.
	// If there have been no previous MMAPs for this pid, then this MMAP is our
	// best guess.
	auto old_mapping_it = pid_to_executable_mmap_.find(pid);
	PerfDataHandler::Mapping* old_mapping =
	old_mapping_it == pid_to_executable_mmap_.end() ? nullptr
	: old_mapping_it->second;

	if (old_mapping != nullptr && old_mapping->start == 0x400000 &&
	(old_mapping->filename == nullptr \|\| *old_mapping->filename == "") &&
	mapping->start - mapping->file_offset == 0x400000) {
	// Hugepages remap the main binary, but the original mapping loses
	// its name, so we have this hack.
	old_mapping->filename = &mmap->filename();
	}

	static const char kKernelPrefix[] = "[kernel.kallsyms]";

	if (old_mapping == nullptr && !HasSuffixString(mmap->filename(), ".ko") &&
	!HasSuffixString(mmap->filename(), ".so") &&
	!IsDeletedSharedObject(mmap->filename()) &&
	!IsVersionedSharedObject(mmap->filename()) &&
	!IsVirtualMapping(mmap->filename()) &&
	!HasPrefixString(mmap->filename(), kKernelPrefix)) {
	if (!HasPrefixString(mmap->filename(), "/usr/bin") &&
	!HasPrefixString(mmap->filename(), "/usr/sbin") &&
	!HasSuffixString(mmap->filename(), "/sel_ldr")) {
	LOG(INFO) << "guessing main for pid: " << pid << " " << mmap->filename();
	}
	pid_to_executable_mmap_[pid] = mapping;
	return;
	}

	if (pid == std::numeric_limits<uint32>::max() &&
	HasPrefixString(mmap->filename(), kKernelPrefix)) {
	pid_to_executable_mmap_[pid] = mapping;
	}
	}

	const PerfDataHandler::Mapping* Normalizer::TryLookupInPid(uint32 pid,
	uint64 ip) const {
	const auto& it = pid_to_mmaps_.find(pid);
	if (it == pid_to_mmaps_.end()) {
	VLOG(2) << "No mmaps for pid " << pid;
	return nullptr;
	}
	MMapIntervalMap* mmaps = it->second.get();

	const PerfDataHandler::Mapping* mapping = nullptr;
	mmaps->Lookup(ip, &mapping);
	return mapping;
	}

	// Find the mapping for ip in the context of pid. We might be looking
	// at a kernel IP, however (which can show up in any pid, and are
	// stored in our map as pid = -1), so check there if the lookup fails
	// in our process.
	const PerfDataHandler::Mapping* Normalizer::GetMappingFromPidAndIP(
	uint32 pid, uint64 ip) const {
	if (ip >= PERF_CONTEXT_MAX) {
	// These aren't real IPs, they're context hints. Drop them.
	return nullptr;
	}
	// One could try to decide if this is a kernel or user sample
	// directly. ahh@ thinks there's a heuristic that should work on
	// x86 (basically without any error): all kernel samples should have
	// 16 high bits set, all user samples should have high 16 bits
	// cleared. But that's not portable, and on any arch (...hopefully)
	// the user/kernel mappings should be disjoint anyway, so just check
	// both, starting with user. We could also use PERF_CONTEXT_KERNEL
	// and friends (see for instance how perf handles this:
	// https://goto.google.com/udgor) to know whether to check user or
	// kernel, but this seems more robust.
	const PerfDataHandler::Mapping* mapping = TryLookupInPid(pid, ip);
	if (mapping == nullptr) {
	// Might be a kernel sample.
	mapping = TryLookupInPid(-1, ip);
	}
	if (mapping == nullptr) {
	VLOG(2) << "no sample mmap found for pid " << pid << " and ip " << ip;
	return nullptr;
	}
	if (ip < mapping->start \|\| ip >= mapping->limit) {
	std::cerr << "IP is not in mapping." << std::endl
	<< "IP: " << ip << std::endl
	<< "Start: " << mapping->start << std::endl
	<< "Limit: " << mapping->limit << std::endl;
	abort();
	}
	return mapping;
	}

	const PerfDataHandler::Mapping* Normalizer::GetMainMMapFromPid(
	uint32 pid) const {
	auto mapping_it = pid_to_executable_mmap_.find(pid);
	if (mapping_it != pid_to_executable_mmap_.end()) {
	return mapping_it->second;
	}

	VLOG(2) << "No argv0 name found for sample with pid: " << pid;
	return nullptr;
	}

	int64 Normalizer::GetEventIndexForSample(
	const quipper::PerfDataProto_SampleEvent& sample) const {
	if (perf_proto_.file_attrs().size() == 1) {
	return 0;
	}

	if (!sample.has_id()) {
	LOG(ERROR) << "Perf sample did not have id";
	return -1;
	}

	auto it = id_to_event_index_.find(sample.id());
	if (it == id_to_event_index_.end()) {
	LOG(ERROR) << "Incorrect event id: " << sample.id();
	return -1;
	}
	return it->second;
	}
	} // namespace

	// Finds needle in haystack starting at cursor. It then returns the index
	// directly after needle or string::npos if needle was not found.
	size_t FindAfter(const string& haystack, const string& needle, size_t cursor) {
	auto next_cursor = haystack.find(needle, cursor);
	if (next_cursor != string::npos) {
	next_cursor += needle.size();
	}
	return next_cursor;
	}

	bool IsDeletedSharedObject(const string& path) {
	size_t cursor = 1;
	while ((cursor = FindAfter(path, ".so", cursor)) != string::npos) {
	const auto ch = path.at(cursor);
	if (ch == '.' \|\| ch == '_' \|\| ch == ' ') {
	return path.find("(deleted)", cursor) != string::npos;
	}
	}
	return false;
	}

	bool IsVersionedSharedObject(const string& path) {
	return path.find(".so.", 1) != string::npos;
	}

	PerfDataHandler::PerfDataHandler() {}

	void PerfDataHandler::Process(const quipper::PerfDataProto& perf_proto,
	PerfDataHandler* handler) {
	Normalizer Normalizer(perf_proto, handler);
	return Normalizer.Normalize();
	}

	} // namespace perftools