third_party/perfetto/src/profiling/memory/unwinding.cc - cobalt - Git at Google

 /*
  * Copyright (C) 2018 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "src/profiling/memory/unwinding.h"

 #include <sys/types.h>
 #include <unistd.h>

 #include <unwindstack/MachineArm.h>
 #include <unwindstack/MachineArm64.h>
 #include <unwindstack/MachineMips.h>
 #include <unwindstack/MachineMips64.h>
 #include <unwindstack/MachineRiscv64.h>
 #include <unwindstack/MachineX86.h>
 #include <unwindstack/MachineX86_64.h>
 #include <unwindstack/Maps.h>
 #include <unwindstack/Memory.h>
 #include <unwindstack/Regs.h>
 #include <unwindstack/RegsArm.h>
 #include <unwindstack/RegsArm64.h>
 #include <unwindstack/RegsMips.h>
 #include <unwindstack/RegsMips64.h>
 #include <unwindstack/RegsRiscv64.h>
 #include <unwindstack/RegsX86.h>
 #include <unwindstack/RegsX86_64.h>
 #include <unwindstack/Unwinder.h>
 #include <unwindstack/UserArm.h>
 #include <unwindstack/UserArm64.h>
 #include <unwindstack/UserMips.h>
 #include <unwindstack/UserMips64.h>
 #include <unwindstack/UserRiscv64.h>
 #include <unwindstack/UserX86.h>
 #include <unwindstack/UserX86_64.h>

 #include <procinfo/process_map.h>

 #include "perfetto/base/logging.h"
 #include "perfetto/base/task_runner.h"
 #include "perfetto/ext/base/file_utils.h"
 #include "perfetto/ext/base/scoped_file.h"
 #include "perfetto/ext/base/string_utils.h"
 #include "perfetto/ext/base/thread_task_runner.h"

 #include "src/profiling/memory/unwound_messages.h"
 #include "src/profiling/memory/wire_protocol.h"

 namespace perfetto {
 namespace profiling {
 namespace {

 constexpr base::TimeMillis kMapsReparseInterval{500};
 constexpr uint32_t kRetryDelayMs = 100;

 constexpr size_t kMaxFrames = 500;

 // We assume average ~300us per unwind. If we handle up to 1000 unwinds, this
 // makes sure other tasks get to be run at least every 300ms if the unwinding
 // saturates this thread.
 constexpr size_t kUnwindBatchSize = 1000;
 constexpr size_t kRecordBatchSize = 1024;
 constexpr size_t kMaxAllocRecordArenaSize = 2 * kRecordBatchSize;

 #pragma GCC diagnostic push
 // We do not care about deterministic destructor order.
 #pragma GCC diagnostic ignored "-Wglobal-constructors"
 #pragma GCC diagnostic ignored "-Wexit-time-destructors"
 static std::vector<std::string> kSkipMaps{"heapprofd_client.so",
                                           "heapprofd_client_api.so"};
 #pragma GCC diagnostic pop

 size_t GetRegsSize(unwindstack::Regs* regs) {
   if (regs->Is32Bit())
     return sizeof(uint32_t) * regs->total_regs();
   return sizeof(uint64_t) * regs->total_regs();
 }

 void ReadFromRawData(unwindstack::Regs* regs, void* raw_data) {
   memcpy(regs->RawData(), raw_data, GetRegsSize(regs));
 }

 }  // namespace

 std::unique_ptr<unwindstack::Regs> CreateRegsFromRawData(
     unwindstack::ArchEnum arch,
     void* raw_data) {
   std::unique_ptr<unwindstack::Regs> ret;
   switch (arch) {
     case unwindstack::ARCH_X86:
       ret.reset(new unwindstack::RegsX86());
       break;
     case unwindstack::ARCH_X86_64:
       ret.reset(new unwindstack::RegsX86_64());
       break;
     case unwindstack::ARCH_ARM:
       ret.reset(new unwindstack::RegsArm());
       break;
     case unwindstack::ARCH_ARM64:
       ret.reset(new unwindstack::RegsArm64());
       break;
     case unwindstack::ARCH_MIPS:
       ret.reset(new unwindstack::RegsMips());
       break;
     case unwindstack::ARCH_MIPS64:
       ret.reset(new unwindstack::RegsMips64());
       break;
     case unwindstack::ARCH_RISCV64:
       ret.reset(new unwindstack::RegsRiscv64());
       break;
     case unwindstack::ARCH_UNKNOWN:
       break;
   }
   if (ret)
     ReadFromRawData(ret.get(), raw_data);
   return ret;
 }

 bool DoUnwind(WireMessage* msg, UnwindingMetadata* metadata, AllocRecord* out) {
   AllocMetadata* alloc_metadata = msg->alloc_header;
   std::unique_ptr<unwindstack::Regs> regs(CreateRegsFromRawData(
       alloc_metadata->arch, alloc_metadata->register_data));
   if (regs == nullptr) {
     PERFETTO_DLOG("Unable to construct unwindstack::Regs");
     unwindstack::FrameData frame_data{};
     frame_data.function_name = "ERROR READING REGISTERS";

     out->frames.clear();
     out->build_ids.clear();
     out->frames.emplace_back(std::move(frame_data));
     out->build_ids.emplace_back("");
     out->error = true;
     return false;
   }
   uint8_t* stack = reinterpret_cast<uint8_t*>(msg->payload);
   std::shared_ptr<unwindstack::Memory> mems =
       std::make_shared<StackOverlayMemory>(metadata->fd_mem,
                                            alloc_metadata->stack_pointer, stack,
                                            msg->payload_size);

   unwindstack::Unwinder unwinder(kMaxFrames, &metadata->fd_maps, regs.get(),
                                  mems);
 #if PERFETTO_BUILDFLAG(PERFETTO_ANDROID_BUILD)
   unwinder.SetJitDebug(metadata->GetJitDebug(regs->Arch()));
   unwinder.SetDexFiles(metadata->GetDexFiles(regs->Arch()));
 #endif
   // Suppress incorrect "variable may be uninitialized" error for if condition
   // after this loop. error_code = LastErrorCode gets run at least once.
   unwindstack::ErrorCode error_code = unwindstack::ERROR_NONE;
   for (int attempt = 0; attempt < 2; ++attempt) {
     if (attempt > 0) {
       if (metadata->last_maps_reparse_time + kMapsReparseInterval >
           base::GetWallTimeMs()) {
         PERFETTO_DLOG("Skipping reparse due to rate limit.");
         break;
       }
       PERFETTO_DLOG("Reparsing maps");
       metadata->ReparseMaps();
       metadata->last_maps_reparse_time = base::GetWallTimeMs();
       // Regs got invalidated by libuwindstack's speculative jump.
       // Reset.
       ReadFromRawData(regs.get(), alloc_metadata->register_data);
       out->reparsed_map = true;
 #if PERFETTO_BUILDFLAG(PERFETTO_ANDROID_BUILD)
       unwinder.SetJitDebug(metadata->GetJitDebug(regs->Arch()));
       unwinder.SetDexFiles(metadata->GetDexFiles(regs->Arch()));
 #endif
     }
     out->frames.swap(unwinder.frames());  // Provide the unwinder buffer to use.
     unwinder.Unwind(&kSkipMaps, /*map_suffixes_to_ignore=*/nullptr);
     out->frames.swap(unwinder.frames());  // Take the buffer back.
     error_code = unwinder.LastErrorCode();
     if (error_code != unwindstack::ERROR_INVALID_MAP &&
         (unwinder.warnings() & unwindstack::WARNING_DEX_PC_NOT_IN_MAP) == 0) {
       break;
     }
   }
   out->build_ids.resize(out->frames.size());
   for (size_t i = 0; i < out->frames.size(); ++i) {
     out->build_ids[i] = metadata->GetBuildId(out->frames[i]);
   }

   if (error_code != unwindstack::ERROR_NONE) {
     PERFETTO_DLOG("Unwinding error %" PRIu8, error_code);
     unwindstack::FrameData frame_data{};
     frame_data.function_name =
         "ERROR " + StringifyLibUnwindstackError(error_code);

     out->frames.emplace_back(std::move(frame_data));
     out->build_ids.emplace_back("");
     out->error = true;
   }
   return true;
 }

 UnwindingWorker::~UnwindingWorker() {
   if (thread_task_runner_.get() == nullptr) {
     return;
   }
   std::mutex mutex;
   std::condition_variable cv;

   std::unique_lock<std::mutex> lock(mutex);
   bool done = false;
   thread_task_runner_.PostTask([&mutex, &cv, &done, this] {
     for (auto& it : client_data_) {
       auto& client_data = it.second;
       client_data.sock->Shutdown(false);
     }
     client_data_.clear();

     std::lock_guard<std::mutex> inner_lock(mutex);
     done = true;
     cv.notify_one();
   });
   cv.wait(lock, [&done] { return done; });
 }

 void UnwindingWorker::OnDisconnect(base::UnixSocket* self) {
   pid_t peer_pid = self->peer_pid_linux();
   auto it = client_data_.find(peer_pid);
   if (it == client_data_.end()) {
     PERFETTO_DFATAL_OR_ELOG("Disconnected unexpected socket.");
     return;
   }

   ClientData& client_data = it->second;
   SharedRingBuffer& shmem = client_data.shmem;
   client_data.drain_bytes = shmem.read_avail();

   if (client_data.drain_bytes != 0) {
     DrainJob(peer_pid);
   } else {
     FinishDisconnect(it);
   }
 }

 void UnwindingWorker::RemoveClientData(
     std::map<pid_t, ClientData>::iterator client_data_iterator) {
   client_data_.erase(client_data_iterator);
   if (client_data_.empty()) {
     // We got rid of the last client. Flush and destruct AllocRecords in
     // arena. Disable the arena (will not accept returning borrowed records)
     // in case there are pending AllocRecords on the main thread.
     alloc_record_arena_.Disable();
   }
 }

 void UnwindingWorker::FinishDisconnect(
     std::map<pid_t, ClientData>::iterator client_data_iterator) {
   pid_t peer_pid = client_data_iterator->first;
   ClientData& client_data = client_data_iterator->second;
   SharedRingBuffer& shmem = client_data.shmem;

   if (!client_data.free_records.empty()) {
     delegate_->PostFreeRecord(this, std::move(client_data.free_records));
   }

   SharedRingBuffer::Stats stats = {};
   {
     auto lock = shmem.AcquireLock(ScopedSpinlock::Mode::Try);
     if (lock.locked())
       stats = shmem.GetStats(lock);
     else
       PERFETTO_ELOG("Failed to log shmem to get stats.");
   }
   DataSourceInstanceID ds_id = client_data.data_source_instance_id;

   RemoveClientData(client_data_iterator);
   delegate_->PostSocketDisconnected(this, ds_id, peer_pid, stats);
 }

 void UnwindingWorker::OnDataAvailable(base::UnixSocket* self) {
   // Drain buffer to clear the notification.
   char recv_buf[kUnwindBatchSize];
   self->Receive(recv_buf, sizeof(recv_buf));
   BatchUnwindJob(self->peer_pid_linux());
 }

 UnwindingWorker::ReadAndUnwindBatchResult UnwindingWorker::ReadAndUnwindBatch(
     ClientData* client_data) {
   SharedRingBuffer& shmem = client_data->shmem;
   SharedRingBuffer::Buffer buf;
   ReadAndUnwindBatchResult res;

   size_t i;
   for (i = 0; i < kUnwindBatchSize; ++i) {
     uint64_t reparses_before = client_data->metadata.reparses;
     buf = shmem.BeginRead();
     if (!buf)
       break;
     HandleBuffer(this, &alloc_record_arena_, buf, client_data,
                  client_data->sock->peer_pid_linux(), delegate_);
     res.bytes_read += shmem.EndRead(std::move(buf));
     // Reparsing takes time, so process the rest in a new batch to avoid timing
     // out.
     if (reparses_before < client_data->metadata.reparses) {
       res.status = ReadAndUnwindBatchResult::Status::kHasMore;
       return res;
     }
   }

   if (i == kUnwindBatchSize) {
     res.status = ReadAndUnwindBatchResult::Status::kHasMore;
   } else if (i > 0) {
     res.status = ReadAndUnwindBatchResult::Status::kReadSome;
   } else {
     res.status = ReadAndUnwindBatchResult::Status::kReadNone;
   }
   return res;
 }

 void UnwindingWorker::BatchUnwindJob(pid_t peer_pid) {
   auto it = client_data_.find(peer_pid);
   if (it == client_data_.end()) {
     // This can happen if the client disconnected before the buffer was fully
     // handled.
     PERFETTO_DLOG("Unexpected data.");
     return;
   }
   ClientData& client_data = it->second;
   if (client_data.drain_bytes != 0) {
     // This process disconnected and we're reading out the remainder of its
     // buffered data in a dedicated recurring task (DrainJob), so this task has
     // nothing to do.
     return;
   }

   bool job_reposted = false;
   bool reader_paused = false;
   switch (ReadAndUnwindBatch(&client_data).status) {
     case ReadAndUnwindBatchResult::Status::kHasMore:
       thread_task_runner_.get()->PostTask(
           [this, peer_pid] { BatchUnwindJob(peer_pid); });
       job_reposted = true;
       break;
     case ReadAndUnwindBatchResult::Status::kReadSome:
       thread_task_runner_.get()->PostDelayedTask(
           [this, peer_pid] { BatchUnwindJob(peer_pid); }, kRetryDelayMs);
       job_reposted = true;
       break;
     case ReadAndUnwindBatchResult::Status::kReadNone:
       client_data.shmem.SetReaderPaused();
       reader_paused = true;
       break;
   }

   // We need to either repost the job, or set the reader paused bit. By
   // setting that bit, we inform the client that we want to be notified when
   // new data is written to the shared memory buffer.
   // If we do neither of these things, we will not read from the shared memory
   // buffer again.
   PERFETTO_CHECK(job_reposted || reader_paused);
 }

 void UnwindingWorker::DrainJob(pid_t peer_pid) {
   auto it = client_data_.find(peer_pid);
   if (it == client_data_.end()) {
     return;
   }
   ClientData& client_data = it->second;
   auto res = ReadAndUnwindBatch(&client_data);
   switch (res.status) {
     case ReadAndUnwindBatchResult::Status::kHasMore:
       if (res.bytes_read < client_data.drain_bytes) {
         client_data.drain_bytes -= res.bytes_read;
         thread_task_runner_.get()->PostTask(
             [this, peer_pid] { DrainJob(peer_pid); });
         return;
       }
       // ReadAndUnwindBatch read more than client_data.drain_bytes.
       break;
     case ReadAndUnwindBatchResult::Status::kReadSome:
       // ReadAndUnwindBatch read all the available data (for now) in the shared
       // memory buffer.
     case ReadAndUnwindBatchResult::Status::kReadNone:
       // There was no data in the shared memory buffer.
       break;
   }
   // No further drain task has been scheduled. Drain is finished. Finish the
   // disconnect operation as well.

   FinishDisconnect(it);
 }

 // static
 void UnwindingWorker::HandleBuffer(UnwindingWorker* self,
                                    AllocRecordArena* alloc_record_arena,
                                    const SharedRingBuffer::Buffer& buf,
                                    ClientData* client_data,
                                    pid_t peer_pid,
                                    Delegate* delegate) {
   UnwindingMetadata* unwinding_metadata = &client_data->metadata;
   DataSourceInstanceID data_source_instance_id =
       client_data->data_source_instance_id;
   WireMessage msg;
   // TODO(fmayer): standardise on char* or uint8_t*.
   // char* has stronger guarantees regarding aliasing.
   // see https://timsong-cpp.github.io/cppwp/n3337/basic.lval#10.8
   if (!ReceiveWireMessage(reinterpret_cast<char*>(buf.data), buf.size, &msg)) {
     PERFETTO_DFATAL_OR_ELOG("Failed to receive wire message.");
     return;
   }

   if (msg.record_type == RecordType::Malloc) {
     std::unique_ptr<AllocRecord> rec = alloc_record_arena->BorrowAllocRecord();
     rec->alloc_metadata = *msg.alloc_header;
     rec->pid = peer_pid;
     rec->data_source_instance_id = data_source_instance_id;
     auto start_time_us = base::GetWallTimeNs() / 1000;
     if (!client_data->stream_allocations)
       DoUnwind(&msg, unwinding_metadata, rec.get());
     rec->unwinding_time_us = static_cast<uint64_t>(
         ((base::GetWallTimeNs() / 1000) - start_time_us).count());
     delegate->PostAllocRecord(self, std::move(rec));
   } else if (msg.record_type == RecordType::Free) {
     FreeRecord rec;
     rec.pid = peer_pid;
     rec.data_source_instance_id = data_source_instance_id;
     // We need to copy this, so we can return the memory to the shmem buffer.
     memcpy(&rec.entry, msg.free_header, sizeof(*msg.free_header));
     client_data->free_records.emplace_back(std::move(rec));
     if (client_data->free_records.size() == kRecordBatchSize) {
       delegate->PostFreeRecord(self, std::move(client_data->free_records));
       client_data->free_records.clear();
       client_data->free_records.reserve(kRecordBatchSize);
     }
   } else if (msg.record_type == RecordType::HeapName) {
     HeapNameRecord rec;
     rec.pid = peer_pid;
     rec.data_source_instance_id = data_source_instance_id;
     memcpy(&rec.entry, msg.heap_name_header, sizeof(*msg.heap_name_header));
     rec.entry.heap_name[sizeof(rec.entry.heap_name) - 1] = '\0';
     delegate->PostHeapNameRecord(self, std::move(rec));
   } else {
     PERFETTO_DFATAL_OR_ELOG("Invalid record type.");
   }
 }

 void UnwindingWorker::PostHandoffSocket(HandoffData handoff_data) {
   // Even with C++14, this cannot be moved, as std::function has to be
   // copyable, which HandoffData is not.
   HandoffData* raw_data = new HandoffData(std::move(handoff_data));
   // We do not need to use a WeakPtr here because the task runner will not
   // outlive its UnwindingWorker.
   thread_task_runner_.get()->PostTask([this, raw_data] {
     HandoffData data = std::move(*raw_data);
     delete raw_data;
     HandleHandoffSocket(std::move(data));
   });
 }

 void UnwindingWorker::HandleHandoffSocket(HandoffData handoff_data) {
   auto sock = base::UnixSocket::AdoptConnected(
       handoff_data.sock.ReleaseFd(), this, this->thread_task_runner_.get(),
       base::SockFamily::kUnix, base::SockType::kStream);
   pid_t peer_pid = sock->peer_pid_linux();

   UnwindingMetadata metadata(std::move(handoff_data.maps_fd),
                              std::move(handoff_data.mem_fd));
   ClientData client_data{
       handoff_data.data_source_instance_id,
       std::move(sock),
       std::move(metadata),
       std::move(handoff_data.shmem),
       std::move(handoff_data.client_config),
       handoff_data.stream_allocations,
       /*drain_bytes=*/0,
       /*free_records=*/{},
   };
   client_data.free_records.reserve(kRecordBatchSize);
   client_data.shmem.SetReaderPaused();
   client_data_.emplace(peer_pid, std::move(client_data));
   alloc_record_arena_.Enable();
 }

 void UnwindingWorker::HandleDrainFree(DataSourceInstanceID ds_id, pid_t pid) {
   auto it = client_data_.find(pid);
   if (it != client_data_.end()) {
     ClientData& client_data = it->second;

     if (!client_data.free_records.empty()) {
       delegate_->PostFreeRecord(this, std::move(client_data.free_records));
       client_data.free_records.clear();
       client_data.free_records.reserve(kRecordBatchSize);
     }
   }
   delegate_->PostDrainDone(this, ds_id);
 }

 void UnwindingWorker::PostDisconnectSocket(pid_t pid) {
   // We do not need to use a WeakPtr here because the task runner will not
   // outlive its UnwindingWorker.
   thread_task_runner_.get()->PostTask(
       [this, pid] { HandleDisconnectSocket(pid); });
 }

 void UnwindingWorker::PostPurgeProcess(pid_t pid) {
   // We do not need to use a WeakPtr here because the task runner will not
   // outlive its UnwindingWorker.
   thread_task_runner_.get()->PostTask([this, pid] {
     auto it = client_data_.find(pid);
     if (it == client_data_.end()) {
       return;
     }
     RemoveClientData(it);
   });
 }

 void UnwindingWorker::PostDrainFree(DataSourceInstanceID ds_id, pid_t pid) {
   // We do not need to use a WeakPtr here because the task runner will not
   // outlive its UnwindingWorker.
   thread_task_runner_.get()->PostTask(
       [this, ds_id, pid] { HandleDrainFree(ds_id, pid); });
 }

 void UnwindingWorker::HandleDisconnectSocket(pid_t pid) {
   auto it = client_data_.find(pid);
   if (it == client_data_.end()) {
     // This is expected if the client voluntarily disconnects before the
     // profiling session ended. In that case, there is a race between the main
     // thread learning about the disconnect and it calling back here.
     return;
   }
   ClientData& client_data = it->second;
   // Shutdown and call OnDisconnect handler.
   client_data.shmem.SetShuttingDown();
   client_data.sock->Shutdown(/* notify= */ true);
 }

 std::unique_ptr<AllocRecord> AllocRecordArena::BorrowAllocRecord() {
   std::lock_guard<std::mutex> l(*alloc_records_mutex_);
   if (!alloc_records_.empty()) {
     std::unique_ptr<AllocRecord> result = std::move(alloc_records_.back());
     alloc_records_.pop_back();
     return result;
   }
   return std::unique_ptr<AllocRecord>(new AllocRecord());
 }

 void AllocRecordArena::ReturnAllocRecord(std::unique_ptr<AllocRecord> record) {
   std::lock_guard<std::mutex> l(*alloc_records_mutex_);
   if (enabled_ && record && alloc_records_.size() < kMaxAllocRecordArenaSize)
     alloc_records_.emplace_back(std::move(record));
 }

 void AllocRecordArena::Disable() {
   std::lock_guard<std::mutex> l(*alloc_records_mutex_);
   alloc_records_.clear();
   enabled_ = false;
 }

 void AllocRecordArena::Enable() {
   std::lock_guard<std::mutex> l(*alloc_records_mutex_);
   enabled_ = true;
 }

 UnwindingWorker::Delegate::~Delegate() = default;

 }  // namespace profiling
 }  // namespace perfetto
	/*
	* Copyright (C) 2018 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "src/profiling/memory/unwinding.h"

	#include <sys/types.h>
	#include <unistd.h>

	#include <unwindstack/MachineArm.h>
	#include <unwindstack/MachineArm64.h>
	#include <unwindstack/MachineMips.h>
	#include <unwindstack/MachineMips64.h>
	#include <unwindstack/MachineRiscv64.h>
	#include <unwindstack/MachineX86.h>
	#include <unwindstack/MachineX86_64.h>
	#include <unwindstack/Maps.h>
	#include <unwindstack/Memory.h>
	#include <unwindstack/Regs.h>
	#include <unwindstack/RegsArm.h>
	#include <unwindstack/RegsArm64.h>
	#include <unwindstack/RegsMips.h>
	#include <unwindstack/RegsMips64.h>
	#include <unwindstack/RegsRiscv64.h>
	#include <unwindstack/RegsX86.h>
	#include <unwindstack/RegsX86_64.h>
	#include <unwindstack/Unwinder.h>
	#include <unwindstack/UserArm.h>
	#include <unwindstack/UserArm64.h>
	#include <unwindstack/UserMips.h>
	#include <unwindstack/UserMips64.h>
	#include <unwindstack/UserRiscv64.h>
	#include <unwindstack/UserX86.h>
	#include <unwindstack/UserX86_64.h>

	#include <procinfo/process_map.h>

	#include "perfetto/base/logging.h"
	#include "perfetto/base/task_runner.h"
	#include "perfetto/ext/base/file_utils.h"
	#include "perfetto/ext/base/scoped_file.h"
	#include "perfetto/ext/base/string_utils.h"
	#include "perfetto/ext/base/thread_task_runner.h"

	#include "src/profiling/memory/unwound_messages.h"
	#include "src/profiling/memory/wire_protocol.h"

	namespace perfetto {
	namespace profiling {
	namespace {

	constexpr base::TimeMillis kMapsReparseInterval{500};
	constexpr uint32_t kRetryDelayMs = 100;

	constexpr size_t kMaxFrames = 500;

	// We assume average ~300us per unwind. If we handle up to 1000 unwinds, this
	// makes sure other tasks get to be run at least every 300ms if the unwinding
	// saturates this thread.
	constexpr size_t kUnwindBatchSize = 1000;
	constexpr size_t kRecordBatchSize = 1024;
	constexpr size_t kMaxAllocRecordArenaSize = 2 * kRecordBatchSize;

	#pragma GCC diagnostic push
	// We do not care about deterministic destructor order.
	#pragma GCC diagnostic ignored "-Wglobal-constructors"
	#pragma GCC diagnostic ignored "-Wexit-time-destructors"
	static std::vector<std::string> kSkipMaps{"heapprofd_client.so",
	"heapprofd_client_api.so"};
	#pragma GCC diagnostic pop

	size_t GetRegsSize(unwindstack::Regs* regs) {
	if (regs->Is32Bit())
	return sizeof(uint32_t) * regs->total_regs();
	return sizeof(uint64_t) * regs->total_regs();
	}

	void ReadFromRawData(unwindstack::Regs* regs, void* raw_data) {
	memcpy(regs->RawData(), raw_data, GetRegsSize(regs));
	}

	} // namespace

	std::unique_ptr<unwindstack::Regs> CreateRegsFromRawData(
	unwindstack::ArchEnum arch,
	void* raw_data) {
	std::unique_ptr<unwindstack::Regs> ret;
	switch (arch) {
	case unwindstack::ARCH_X86:
	ret.reset(new unwindstack::RegsX86());
	break;
	case unwindstack::ARCH_X86_64:
	ret.reset(new unwindstack::RegsX86_64());
	break;
	case unwindstack::ARCH_ARM:
	ret.reset(new unwindstack::RegsArm());
	break;
	case unwindstack::ARCH_ARM64:
	ret.reset(new unwindstack::RegsArm64());
	break;
	case unwindstack::ARCH_MIPS:
	ret.reset(new unwindstack::RegsMips());
	break;
	case unwindstack::ARCH_MIPS64:
	ret.reset(new unwindstack::RegsMips64());
	break;
	case unwindstack::ARCH_RISCV64:
	ret.reset(new unwindstack::RegsRiscv64());
	break;
	case unwindstack::ARCH_UNKNOWN:
	break;
	}
	if (ret)
	ReadFromRawData(ret.get(), raw_data);
	return ret;
	}

	bool DoUnwind(WireMessage* msg, UnwindingMetadata* metadata, AllocRecord* out) {
	AllocMetadata* alloc_metadata = msg->alloc_header;
	std::unique_ptr<unwindstack::Regs> regs(CreateRegsFromRawData(
	alloc_metadata->arch, alloc_metadata->register_data));
	if (regs == nullptr) {
	PERFETTO_DLOG("Unable to construct unwindstack::Regs");
	unwindstack::FrameData frame_data{};
	frame_data.function_name = "ERROR READING REGISTERS";

	out->frames.clear();
	out->build_ids.clear();
	out->frames.emplace_back(std::move(frame_data));
	out->build_ids.emplace_back("");
	out->error = true;
	return false;
	}
	uint8_t* stack = reinterpret_cast<uint8_t*>(msg->payload);
	std::shared_ptr<unwindstack::Memory> mems =
	std::make_shared<StackOverlayMemory>(metadata->fd_mem,
	alloc_metadata->stack_pointer, stack,
	msg->payload_size);

	unwindstack::Unwinder unwinder(kMaxFrames, &metadata->fd_maps, regs.get(),
	mems);
	#if PERFETTO_BUILDFLAG(PERFETTO_ANDROID_BUILD)
	unwinder.SetJitDebug(metadata->GetJitDebug(regs->Arch()));
	unwinder.SetDexFiles(metadata->GetDexFiles(regs->Arch()));
	#endif
	// Suppress incorrect "variable may be uninitialized" error for if condition
	// after this loop. error_code = LastErrorCode gets run at least once.
	unwindstack::ErrorCode error_code = unwindstack::ERROR_NONE;
	for (int attempt = 0; attempt < 2; ++attempt) {
	if (attempt > 0) {
	if (metadata->last_maps_reparse_time + kMapsReparseInterval >
	base::GetWallTimeMs()) {
	PERFETTO_DLOG("Skipping reparse due to rate limit.");
	break;
	}
	PERFETTO_DLOG("Reparsing maps");
	metadata->ReparseMaps();
	metadata->last_maps_reparse_time = base::GetWallTimeMs();
	// Regs got invalidated by libuwindstack's speculative jump.
	// Reset.
	ReadFromRawData(regs.get(), alloc_metadata->register_data);
	out->reparsed_map = true;
	#if PERFETTO_BUILDFLAG(PERFETTO_ANDROID_BUILD)
	unwinder.SetJitDebug(metadata->GetJitDebug(regs->Arch()));
	unwinder.SetDexFiles(metadata->GetDexFiles(regs->Arch()));
	#endif
	}
	out->frames.swap(unwinder.frames()); // Provide the unwinder buffer to use.
	unwinder.Unwind(&kSkipMaps, /map_suffixes_to_ignore=/nullptr);
	out->frames.swap(unwinder.frames()); // Take the buffer back.
	error_code = unwinder.LastErrorCode();
	if (error_code != unwindstack::ERROR_INVALID_MAP &&
	(unwinder.warnings() & unwindstack::WARNING_DEX_PC_NOT_IN_MAP) == 0) {
	break;
	}
	}
	out->build_ids.resize(out->frames.size());
	for (size_t i = 0; i < out->frames.size(); ++i) {
	out->build_ids[i] = metadata->GetBuildId(out->frames[i]);
	}

	if (error_code != unwindstack::ERROR_NONE) {
	PERFETTO_DLOG("Unwinding error %" PRIu8, error_code);
	unwindstack::FrameData frame_data{};
	frame_data.function_name =
	"ERROR " + StringifyLibUnwindstackError(error_code);

	out->frames.emplace_back(std::move(frame_data));
	out->build_ids.emplace_back("");
	out->error = true;
	}
	return true;
	}

	UnwindingWorker::~UnwindingWorker() {
	if (thread_task_runner_.get() == nullptr) {
	return;
	}
	std::mutex mutex;
	std::condition_variable cv;

	std::unique_lock<std::mutex> lock(mutex);
	bool done = false;
	thread_task_runner_.PostTask([&mutex, &cv, &done, this] {
	for (auto& it : client_data_) {
	auto& client_data = it.second;
	client_data.sock->Shutdown(false);
	}
	client_data_.clear();

	std::lock_guard<std::mutex> inner_lock(mutex);
	done = true;
	cv.notify_one();
	});
	cv.wait(lock, [&done] { return done; });
	}

	void UnwindingWorker::OnDisconnect(base::UnixSocket* self) {
	pid_t peer_pid = self->peer_pid_linux();
	auto it = client_data_.find(peer_pid);
	if (it == client_data_.end()) {
	PERFETTO_DFATAL_OR_ELOG("Disconnected unexpected socket.");
	return;
	}

	ClientData& client_data = it->second;
	SharedRingBuffer& shmem = client_data.shmem;
	client_data.drain_bytes = shmem.read_avail();

	if (client_data.drain_bytes != 0) {
	DrainJob(peer_pid);
	} else {
	FinishDisconnect(it);
	}
	}

	void UnwindingWorker::RemoveClientData(
	std::map<pid_t, ClientData>::iterator client_data_iterator) {
	client_data_.erase(client_data_iterator);
	if (client_data_.empty()) {
	// We got rid of the last client. Flush and destruct AllocRecords in
	// arena. Disable the arena (will not accept returning borrowed records)
	// in case there are pending AllocRecords on the main thread.
	alloc_record_arena_.Disable();
	}
	}

	void UnwindingWorker::FinishDisconnect(
	std::map<pid_t, ClientData>::iterator client_data_iterator) {
	pid_t peer_pid = client_data_iterator->first;
	ClientData& client_data = client_data_iterator->second;
	SharedRingBuffer& shmem = client_data.shmem;

	if (!client_data.free_records.empty()) {
	delegate_->PostFreeRecord(this, std::move(client_data.free_records));
	}

	SharedRingBuffer::Stats stats = {};
	{
	auto lock = shmem.AcquireLock(ScopedSpinlock::Mode::Try);
	if (lock.locked())
	stats = shmem.GetStats(lock);
	else
	PERFETTO_ELOG("Failed to log shmem to get stats.");
	}
	DataSourceInstanceID ds_id = client_data.data_source_instance_id;

	RemoveClientData(client_data_iterator);
	delegate_->PostSocketDisconnected(this, ds_id, peer_pid, stats);
	}

	void UnwindingWorker::OnDataAvailable(base::UnixSocket* self) {
	// Drain buffer to clear the notification.
	char recv_buf[kUnwindBatchSize];
	self->Receive(recv_buf, sizeof(recv_buf));
	BatchUnwindJob(self->peer_pid_linux());
	}

	UnwindingWorker::ReadAndUnwindBatchResult UnwindingWorker::ReadAndUnwindBatch(
	ClientData* client_data) {
	SharedRingBuffer& shmem = client_data->shmem;
	SharedRingBuffer::Buffer buf;
	ReadAndUnwindBatchResult res;

	size_t i;
	for (i = 0; i < kUnwindBatchSize; ++i) {
	uint64_t reparses_before = client_data->metadata.reparses;
	buf = shmem.BeginRead();
	if (!buf)
	break;
	HandleBuffer(this, &alloc_record_arena_, buf, client_data,
	client_data->sock->peer_pid_linux(), delegate_);
	res.bytes_read += shmem.EndRead(std::move(buf));
	// Reparsing takes time, so process the rest in a new batch to avoid timing
	// out.
	if (reparses_before < client_data->metadata.reparses) {
	res.status = ReadAndUnwindBatchResult::Status::kHasMore;
	return res;
	}
	}

	if (i == kUnwindBatchSize) {
	res.status = ReadAndUnwindBatchResult::Status::kHasMore;
	} else if (i > 0) {
	res.status = ReadAndUnwindBatchResult::Status::kReadSome;
	} else {
	res.status = ReadAndUnwindBatchResult::Status::kReadNone;
	}
	return res;
	}

	void UnwindingWorker::BatchUnwindJob(pid_t peer_pid) {
	auto it = client_data_.find(peer_pid);
	if (it == client_data_.end()) {
	// This can happen if the client disconnected before the buffer was fully
	// handled.
	PERFETTO_DLOG("Unexpected data.");
	return;
	}
	ClientData& client_data = it->second;
	if (client_data.drain_bytes != 0) {
	// This process disconnected and we're reading out the remainder of its
	// buffered data in a dedicated recurring task (DrainJob), so this task has
	// nothing to do.
	return;
	}

	bool job_reposted = false;
	bool reader_paused = false;
	switch (ReadAndUnwindBatch(&client_data).status) {
	case ReadAndUnwindBatchResult::Status::kHasMore:
	thread_task_runner_.get()->PostTask(
	[this, peer_pid] { BatchUnwindJob(peer_pid); });
	job_reposted = true;
	break;
	case ReadAndUnwindBatchResult::Status::kReadSome:
	thread_task_runner_.get()->PostDelayedTask(
	[this, peer_pid] { BatchUnwindJob(peer_pid); }, kRetryDelayMs);
	job_reposted = true;
	break;
	case ReadAndUnwindBatchResult::Status::kReadNone:
	client_data.shmem.SetReaderPaused();
	reader_paused = true;
	break;
	}

	// We need to either repost the job, or set the reader paused bit. By
	// setting that bit, we inform the client that we want to be notified when
	// new data is written to the shared memory buffer.
	// If we do neither of these things, we will not read from the shared memory
	// buffer again.
	PERFETTO_CHECK(job_reposted \|\| reader_paused);
	}

	void UnwindingWorker::DrainJob(pid_t peer_pid) {
	auto it = client_data_.find(peer_pid);
	if (it == client_data_.end()) {
	return;
	}
	ClientData& client_data = it->second;
	auto res = ReadAndUnwindBatch(&client_data);
	switch (res.status) {
	case ReadAndUnwindBatchResult::Status::kHasMore:
	if (res.bytes_read < client_data.drain_bytes) {
	client_data.drain_bytes -= res.bytes_read;
	thread_task_runner_.get()->PostTask(
	[this, peer_pid] { DrainJob(peer_pid); });
	return;
	}
	// ReadAndUnwindBatch read more than client_data.drain_bytes.
	break;
	case ReadAndUnwindBatchResult::Status::kReadSome:
	// ReadAndUnwindBatch read all the available data (for now) in the shared
	// memory buffer.
	case ReadAndUnwindBatchResult::Status::kReadNone:
	// There was no data in the shared memory buffer.
	break;
	}
	// No further drain task has been scheduled. Drain is finished. Finish the
	// disconnect operation as well.

	FinishDisconnect(it);
	}

	// static
	void UnwindingWorker::HandleBuffer(UnwindingWorker* self,
	AllocRecordArena* alloc_record_arena,
	const SharedRingBuffer::Buffer& buf,
	ClientData* client_data,
	pid_t peer_pid,
	Delegate* delegate) {
	UnwindingMetadata* unwinding_metadata = &client_data->metadata;
	DataSourceInstanceID data_source_instance_id =
	client_data->data_source_instance_id;
	WireMessage msg;
	// TODO(fmayer): standardise on char* or uint8_t*.
	// char* has stronger guarantees regarding aliasing.
	// see https://timsong-cpp.github.io/cppwp/n3337/basic.lval#10.8
	if (!ReceiveWireMessage(reinterpret_cast<char*>(buf.data), buf.size, &msg)) {
	PERFETTO_DFATAL_OR_ELOG("Failed to receive wire message.");
	return;
	}

	if (msg.record_type == RecordType::Malloc) {
	std::unique_ptr<AllocRecord> rec = alloc_record_arena->BorrowAllocRecord();
	rec->alloc_metadata = *msg.alloc_header;
	rec->pid = peer_pid;
	rec->data_source_instance_id = data_source_instance_id;
	auto start_time_us = base::GetWallTimeNs() / 1000;
	if (!client_data->stream_allocations)
	DoUnwind(&msg, unwinding_metadata, rec.get());
	rec->unwinding_time_us = static_cast<uint64_t>(
	((base::GetWallTimeNs() / 1000) - start_time_us).count());
	delegate->PostAllocRecord(self, std::move(rec));
	} else if (msg.record_type == RecordType::Free) {
	FreeRecord rec;
	rec.pid = peer_pid;
	rec.data_source_instance_id = data_source_instance_id;
	// We need to copy this, so we can return the memory to the shmem buffer.
	memcpy(&rec.entry, msg.free_header, sizeof(*msg.free_header));
	client_data->free_records.emplace_back(std::move(rec));
	if (client_data->free_records.size() == kRecordBatchSize) {
	delegate->PostFreeRecord(self, std::move(client_data->free_records));
	client_data->free_records.clear();
	client_data->free_records.reserve(kRecordBatchSize);
	}
	} else if (msg.record_type == RecordType::HeapName) {
	HeapNameRecord rec;
	rec.pid = peer_pid;
	rec.data_source_instance_id = data_source_instance_id;
	memcpy(&rec.entry, msg.heap_name_header, sizeof(*msg.heap_name_header));
	rec.entry.heap_name[sizeof(rec.entry.heap_name) - 1] = '\0';
	delegate->PostHeapNameRecord(self, std::move(rec));
	} else {
	PERFETTO_DFATAL_OR_ELOG("Invalid record type.");
	}
	}

	void UnwindingWorker::PostHandoffSocket(HandoffData handoff_data) {
	// Even with C++14, this cannot be moved, as std::function has to be
	// copyable, which HandoffData is not.
	HandoffData* raw_data = new HandoffData(std::move(handoff_data));
	// We do not need to use a WeakPtr here because the task runner will not
	// outlive its UnwindingWorker.
	thread_task_runner_.get()->PostTask([this, raw_data] {
	HandoffData data = std::move(*raw_data);
	delete raw_data;
	HandleHandoffSocket(std::move(data));
	});
	}

	void UnwindingWorker::HandleHandoffSocket(HandoffData handoff_data) {
	auto sock = base::UnixSocket::AdoptConnected(
	handoff_data.sock.ReleaseFd(), this, this->thread_task_runner_.get(),
	base::SockFamily::kUnix, base::SockType::kStream);
	pid_t peer_pid = sock->peer_pid_linux();

	UnwindingMetadata metadata(std::move(handoff_data.maps_fd),
	std::move(handoff_data.mem_fd));
	ClientData client_data{
	handoff_data.data_source_instance_id,
	std::move(sock),
	std::move(metadata),
	std::move(handoff_data.shmem),
	std::move(handoff_data.client_config),
	handoff_data.stream_allocations,
	/drain_bytes=/0,
	/free_records=/{},
	};
	client_data.free_records.reserve(kRecordBatchSize);
	client_data.shmem.SetReaderPaused();
	client_data_.emplace(peer_pid, std::move(client_data));
	alloc_record_arena_.Enable();
	}

	void UnwindingWorker::HandleDrainFree(DataSourceInstanceID ds_id, pid_t pid) {
	auto it = client_data_.find(pid);
	if (it != client_data_.end()) {
	ClientData& client_data = it->second;

	if (!client_data.free_records.empty()) {
	delegate_->PostFreeRecord(this, std::move(client_data.free_records));
	client_data.free_records.clear();
	client_data.free_records.reserve(kRecordBatchSize);
	}
	}
	delegate_->PostDrainDone(this, ds_id);
	}

	void UnwindingWorker::PostDisconnectSocket(pid_t pid) {
	// We do not need to use a WeakPtr here because the task runner will not
	// outlive its UnwindingWorker.
	thread_task_runner_.get()->PostTask(
	[this, pid] { HandleDisconnectSocket(pid); });
	}

	void UnwindingWorker::PostPurgeProcess(pid_t pid) {
	// We do not need to use a WeakPtr here because the task runner will not
	// outlive its UnwindingWorker.
	thread_task_runner_.get()->PostTask([this, pid] {
	auto it = client_data_.find(pid);
	if (it == client_data_.end()) {
	return;
	}
	RemoveClientData(it);
	});
	}

	void UnwindingWorker::PostDrainFree(DataSourceInstanceID ds_id, pid_t pid) {
	// We do not need to use a WeakPtr here because the task runner will not
	// outlive its UnwindingWorker.
	thread_task_runner_.get()->PostTask(
	[this, ds_id, pid] { HandleDrainFree(ds_id, pid); });
	}

	void UnwindingWorker::HandleDisconnectSocket(pid_t pid) {
	auto it = client_data_.find(pid);
	if (it == client_data_.end()) {
	// This is expected if the client voluntarily disconnects before the
	// profiling session ended. In that case, there is a race between the main
	// thread learning about the disconnect and it calling back here.
	return;
	}
	ClientData& client_data = it->second;
	// Shutdown and call OnDisconnect handler.
	client_data.shmem.SetShuttingDown();
	client_data.sock->Shutdown(/* notify= */ true);
	}

	std::unique_ptr<AllocRecord> AllocRecordArena::BorrowAllocRecord() {
	std::lock_guard<std::mutex> l(*alloc_records_mutex_);
	if (!alloc_records_.empty()) {
	std::unique_ptr<AllocRecord> result = std::move(alloc_records_.back());
	alloc_records_.pop_back();
	return result;
	}
	return std::unique_ptr<AllocRecord>(new AllocRecord());
	}

	void AllocRecordArena::ReturnAllocRecord(std::unique_ptr<AllocRecord> record) {
	std::lock_guard<std::mutex> l(*alloc_records_mutex_);
	if (enabled_ && record && alloc_records_.size() < kMaxAllocRecordArenaSize)
	alloc_records_.emplace_back(std::move(record));
	}

	void AllocRecordArena::Disable() {
	std::lock_guard<std::mutex> l(*alloc_records_mutex_);
	alloc_records_.clear();
	enabled_ = false;
	}

	void AllocRecordArena::Enable() {
	std::lock_guard<std::mutex> l(*alloc_records_mutex_);
	enabled_ = true;
	}

	UnwindingWorker::Delegate::~Delegate() = default;

	} // namespace profiling
	} // namespace perfetto