src/nb/analytics/memory_tracker_impl.cc - cobalt - Git at Google

 /*
  * Copyright 2016 Google Inc. All Rights Reserved.
  *
  * 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 "starboard/client_porting/poem/string_leaks_poem.h"

 #include "nb/analytics/memory_tracker_impl.h"

 #include <algorithm>
 #include <cstring>
 #include <functional>
 #include <iomanip>
 #include <iterator>
 #include <sstream>

 #include "nb/concurrent_map.h"
 #include "starboard/atomic.h"
 #include "starboard/common/flat_map.h"
 #include "starboard/log.h"
 #include "starboard/time.h"

 namespace nb {
 namespace analytics {
 namespace {

 // This class allows std containers to bypass memory reporting.
 template <typename T>
 class RawAllocator : public std::allocator<T> {
 public:
   typedef typename std::allocator<T>::pointer pointer;
   typedef typename std::allocator<T>::const_pointer const_pointer;
   typedef typename std::allocator<T>::reference reference;
   typedef typename std::allocator<T>::const_reference const_reference;
   typedef typename std::allocator<T>::size_type size_type;
   typedef typename std::allocator<T>::value_type value_type;
   typedef typename std::allocator<T>::difference_type difference_type;

   RawAllocator() {}

   // Constructor used for rebinding
   template <typename U>
   RawAllocator(const RawAllocator<U>& x) {}

   pointer allocate(size_type n,
     std::allocator<void>::const_pointer hint = NULL) {
     void* ptr = SbMemoryAllocateNoReport(n * sizeof(value_type));
     return static_cast<pointer>(ptr);
   }

   void deallocate(pointer p, size_type n) { SbMemoryDeallocateNoReport(p); }
   template <typename U>
   struct rebind {
     typedef RawAllocator<U> other;
   };
 };
 }  // namespace.

 // ThreadLocalBool_NoReport class guarantees that any memory allocated will NOT
 // go through any memory reporting mechanism. Otherwise certain platforms will
 // encounter a stack overflow condition as execution re-enters the allocation
 // function.
 class MemoryTrackerImpl::ThreadLocalBool_NoReport {
  public:
   void Set(bool val) {
     if (val) {
       thread_map_.Set(SbThreadGetId(), val);
     } else {
       // Rather than set to false, remove the element.
       thread_map_.Remove(SbThreadGetId());
     }
   }

   bool Get() {
     ThreadMap::EntryHandle entry;
     bool has_key = thread_map_.Get(SbThreadGetId(), &entry);
     if (!has_key) {
       return false;
     }
     return entry.Value();

   }

  private:
   // Create a concurrent map that supports fast deletion of elements
   // (no memory release).
   //
   using PairType = std::vector<std::pair<SbThreadId, bool>>::value_type;
   // This vector bypasses reporting allocators.
   using VectorPair = std::vector<PairType, RawAllocator<PairType>>;
   // The InnerMap is backed by the vector. The FlatMap transforms the vector
   // into a map interface.
   using InnerMap = starboard::FlatMap<SbThreadId, bool,
                                       std::less<SbThreadId>,
                                       VectorPair>;
   // Concurrent map uses distributed locking to achieve a highly concurrent
   // unsorted map.
   using ThreadMap = ConcurrentMap<SbThreadId,
                                   bool,
                                   std::hash<SbThreadId>,
                                   InnerMap>;

   ThreadMap thread_map_;
 };

 SbMemoryReporter* MemoryTrackerImpl::GetMemoryReporter() {
   return &sb_memory_tracker_;
 }

 NbMemoryScopeReporter* MemoryTrackerImpl::GetMemoryScopeReporter() {
   return &nb_memory_scope_reporter_;
 }

 int64_t MemoryTrackerImpl::GetTotalAllocationBytes() {
   return total_bytes_allocated_.load();
 }

 AllocationGroup* MemoryTrackerImpl::GetAllocationGroup(const char* name) {
   DisableMemoryTrackingInScope no_tracking(this);
   AllocationGroup* alloc_group = alloc_group_map_.Ensure(name);
   return alloc_group;
 }

 void MemoryTrackerImpl::PushAllocationGroupByName(const char* group_name) {
   AllocationGroup* group = GetAllocationGroup(group_name);
   PushAllocationGroup(group);
 }

 void MemoryTrackerImpl::PushAllocationGroup(AllocationGroup* alloc_group) {
   if (alloc_group == NULL) {
     alloc_group = alloc_group_map_.GetDefaultUnaccounted();
   }
   DisableMemoryTrackingInScope no_tracking(this);
   allocation_group_stack_tls_.GetOrCreate()->Push(alloc_group);
 }

 AllocationGroup* MemoryTrackerImpl::PeekAllocationGroup() {
   DisableMemoryTrackingInScope no_tracking(this);
   AllocationGroup* out =
       allocation_group_stack_tls_.GetOrCreate()->Peek();
   if (out == NULL) {
     out = alloc_group_map_.GetDefaultUnaccounted();
   }
   return out;
 }

 void MemoryTrackerImpl::PopAllocationGroup() {
   DisableMemoryTrackingInScope no_tracking(this);
   AllocationGroupStack* alloc_tls = allocation_group_stack_tls_.GetOrCreate();
   alloc_tls->Pop();
   AllocationGroup* group = alloc_tls->Peek();
   // We don't allow null, so if this is encountered then push the
   // "default unaccounted" alloc group.
   if (group == NULL) {
     alloc_tls->Push(alloc_group_map_.GetDefaultUnaccounted());
   }
 }

 void MemoryTrackerImpl::GetAllocationGroups(
     std::vector<const AllocationGroup*>* output) {
   DisableMemoryTrackingInScope no_allocation_tracking(this);
   output->reserve(100);
   alloc_group_map_.GetAll(output);
 }

 void MemoryTrackerImpl::GetAllocationGroups(
     std::map<std::string, const AllocationGroup*>* output) {
   output->clear();
   DisableMemoryTrackingInScope no_tracking(this);
   std::vector<const AllocationGroup*> tmp;
   GetAllocationGroups(&tmp);
   for (size_t i = 0; i < tmp.size(); ++i) {
     output->insert(std::make_pair(tmp[i]->name(), tmp[i]));
   }
 }

 void MemoryTrackerImpl::Accept(AllocationVisitor* visitor) {
   DisableMemoryTrackingInScope no_mem_allocation_reporting(this);
   DisableDeletionInScope no_mem_deletion_reporting(this);
   atomic_allocation_map_.Accept(visitor);
 }

 void MemoryTrackerImpl::Clear() {
   // Prevent clearing of the tree from triggering a re-entrant
   // memory deallocation.
   atomic_allocation_map_.Clear();
   total_bytes_allocated_.store(0);
 }

 void MemoryTrackerImpl::Debug_PushAllocationGroupBreakPointByName(
     const char* group_name) {
   DisableMemoryTrackingInScope no_tracking(this);
   SB_DCHECK(group_name != NULL);
   AllocationGroup* group = alloc_group_map_.Ensure(group_name);
   Debug_PushAllocationGroupBreakPoint(group);
 }

 void MemoryTrackerImpl::Debug_PushAllocationGroupBreakPoint(
     AllocationGroup* alloc_group) {
   DisableMemoryTrackingInScope no_tracking(this);
   allocation_group_stack_tls_.GetOrCreate()->Push_DebugBreak(alloc_group);
 }

 void MemoryTrackerImpl::Debug_PopAllocationGroupBreakPoint() {
   DisableMemoryTrackingInScope no_tracking(this);
   allocation_group_stack_tls_.GetOrCreate()->Pop_DebugBreak();
 }

 void MemoryTrackerImpl::OnMalloc(void* context,
                                  const void* memory,
                                  size_t size) {
   MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
   t->AddMemoryTracking(memory, size);
 }

 void MemoryTrackerImpl::OnDealloc(void* context, const void* memory) {
   MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
   t->RemoveMemoryTracking(memory);
 }

 void MemoryTrackerImpl::OnMapMem(void* context,
                                  const void* memory,
                                  size_t size) {
   // We might do something more interesting with MapMemory calls later.
   OnMalloc(context, memory, size);
 }

 void MemoryTrackerImpl::OnUnMapMem(void* context,
                                    const void* memory,
                                    size_t size) {
   // We might do something more interesting with UnMapMemory calls later.
   OnDealloc(context, memory);
 }

 void MemoryTrackerImpl::OnPushAllocationGroup(
     void* context,
     NbMemoryScopeInfo* memory_scope_info) {
   MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
   void** cached_handle = &(memory_scope_info->cached_handle_);
   const bool allows_caching = memory_scope_info->allows_caching_;
   const char* group_name = memory_scope_info->memory_scope_name_;

   AllocationGroup* group = NULL;
   if (allows_caching && *cached_handle != NULL) {
     group = static_cast<AllocationGroup*>(*cached_handle);
   } else {
     group = t->GetAllocationGroup(group_name);
     if (allows_caching) {
       // Flush all pending writes so that the the pointee is well formed
       // by the time the pointer becomes visible to other threads.
       SbAtomicMemoryBarrier();
       *cached_handle = static_cast<void*>(group);
     }
   }

   DisableMemoryTrackingInScope no_memory_tracking_in_scope(t);
   t->PushAllocationGroup(group);
   CallStack* callstack = t->callstack_tls_.GetOrCreate();
   callstack->push_back(memory_scope_info);
 }

 void MemoryTrackerImpl::OnPopAllocationGroup(void* context) {
   MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
   t->PopAllocationGroup();
   CallStack* callstack = t->callstack_tls_.GetOrCreate();
   // Callstack can be empty when the memory tracker binds to the callback
   // system while the program is in the middle of the execution.
   if (!callstack->empty()) {
     callstack->pop_back();
   }
 }

 void MemoryTrackerImpl::Initialize(
     SbMemoryReporter* sb_memory_reporter,
     NbMemoryScopeReporter* memory_scope_reporter) {
   SbMemoryReporter mem_reporter = {
       MemoryTrackerImpl::OnMalloc, MemoryTrackerImpl::OnDealloc,
       MemoryTrackerImpl::OnMapMem, MemoryTrackerImpl::OnUnMapMem,
       this};

   NbMemoryScopeReporter mem_scope_reporter = {
       MemoryTrackerImpl::OnPushAllocationGroup,
       MemoryTrackerImpl::OnPopAllocationGroup,
       this,
   };

   *sb_memory_reporter = mem_reporter;
   *memory_scope_reporter = mem_scope_reporter;
 }

 void MemoryTrackerImpl::SetThreadFilter(SbThreadId tid) {
   thread_filter_id_ = tid;
 }

 bool MemoryTrackerImpl::IsCurrentThreadAllowedToReport() const {
   if (thread_filter_id_ == kSbThreadInvalidId) {
     return true;
   }
   return SbThreadGetId() == thread_filter_id_;
 }

 void MemoryTrackerImpl::SetMemoryTrackerDebugCallback(
     MemoryTrackerDebugCallback* cb) {
   debug_callback_.swap(cb);
 }

 MemoryTrackerImpl::DisableDeletionInScope::DisableDeletionInScope(
     MemoryTrackerImpl* owner)
     : owner_(owner) {
   prev_state_ = owner->MemoryDeletionEnabled();
   owner_->SetMemoryDeletionEnabled(false);
 }

 MemoryTrackerImpl::DisableDeletionInScope::~DisableDeletionInScope() {
   owner_->SetMemoryDeletionEnabled(prev_state_);
 }

 MemoryTrackerImpl::MemoryTrackerImpl()
     : thread_filter_id_(kSbThreadInvalidId), debug_callback_(nullptr) {
   memory_deletion_enabled_tls_.reset(new ThreadLocalBool_NoReport);
   memory_tracking_disabled_tls_.reset(new ThreadLocalBool_NoReport);
   total_bytes_allocated_.store(0);
   global_hooks_installed_ = false;
   Initialize(&sb_memory_tracker_, &nb_memory_scope_reporter_);
   // Push the default region so that stats can be accounted for.
   PushAllocationGroup(alloc_group_map_.GetDefaultUnaccounted());
 }

 MemoryTrackerImpl::~MemoryTrackerImpl() {
   // If we are currently hooked into allocation tracking...
   if (global_hooks_installed_) {
     RemoveGlobalTrackingHooks();
     // For performance reasons no locking is used on the tracker.
     // Therefore give enough time for other threads to exit this tracker
     // before fully destroying this object.
     SbThreadSleep(250 * kSbTimeMillisecond);  // 250 millisecond wait.
   }
 }

 bool MemoryTrackerImpl::AddMemoryTracking(const void* memory, size_t size) {
   // Vars are stored to assist in debugging.
   const bool thread_allowed_to_report = IsCurrentThreadAllowedToReport();
   const bool valid_memory_request = (memory != NULL) && (size != 0);
   const bool mem_track_enabled = IsMemoryTrackingEnabled();

   const bool tracking_enabled =
       mem_track_enabled && valid_memory_request && thread_allowed_to_report;

   if (!tracking_enabled) {
     return false;
   }

   // End all memory tracking in subsequent data structures.
   DisableMemoryTrackingInScope no_memory_tracking(this);
   AllocationGroupStack* alloc_stack =
       allocation_group_stack_tls_.GetOrCreate();
   AllocationGroup* group = alloc_stack->Peek();
   if (!group) {
     group = alloc_group_map_.GetDefaultUnaccounted();
   }

 #ifndef NDEBUG
   // This section of the code is designed to allow a developer to break
   // execution whenever the debug allocation stack is in scope, so that the
   // allocations can be stepped through. This is a THREAD LOCAL operation.
   // Example:
   //   Debug_PushAllocationGroupBreakPointByName("Javascript");
   //  ...now set a break point below at "static int i = 0"
   if (group && (group == alloc_stack->Peek_DebugBreak()) &&
       alloc_stack->Peek_DebugBreak()) {
     static int i = 0;  // This static is here to allow an
     ++i;               // easy breakpoint in the debugger
   }
 #endif

   AllocationRecord alloc_record(size, group);
   bool added = atomic_allocation_map_.Add(memory, alloc_record);
   if (added) {
     AddAllocationBytes(size);
     group->AddAllocation(size);
     ConcurrentPtr<MemoryTrackerDebugCallback>::Access access_ptr =
         debug_callback_.access_ptr(SbThreadId());

     // If access_ptr is valid then it is guaranteed to be alive for the
     // duration of the scope.
     if (access_ptr) {
       const CallStack& callstack = *(callstack_tls_.GetOrCreate());
       DisableDeletionInScope disable_deletion_tracking(this);
       access_ptr->OnMemoryAllocation(memory, alloc_record, callstack);
     }
   } else {
     // Handles the case where the memory hasn't been properly been reported
     // released. This is less serious than you would think because the memory
     // allocator in the system will recycle the memory and it will come back.
     AllocationRecord unexpected_alloc;
     atomic_allocation_map_.Get(memory, &unexpected_alloc);
     AllocationGroup* prev_group = unexpected_alloc.allocation_group;

     std::string prev_group_name;
     if (prev_group) {
       prev_group_name = unexpected_alloc.allocation_group->name();
     } else {
       prev_group_name = "none";
     }

     if (!added) {
       std::stringstream ss;
       ss << "\nUnexpected condition, previous allocation was not removed:\n"
          << "\tprevious alloc group: " << prev_group_name << "\n"
          << "\tnew alloc group: " << group->name() << "\n"
          << "\tprevious size: " << unexpected_alloc.size << "\n"
          << "\tnew size: " << size << "\n";

       SbLogRaw(ss.str().c_str());
     }
   }
   return added;
 }

 size_t MemoryTrackerImpl::RemoveMemoryTracking(const void* memory) {
   const bool do_remove = memory && MemoryDeletionEnabled();
   if (!do_remove) {
     return 0;
   }

   AllocationRecord alloc_record;
   bool removed = false;

   ConcurrentPtr<MemoryTrackerDebugCallback>::Access access_ptr =
       debug_callback_.access_ptr(SbThreadId());

   if (access_ptr) {
     if (atomic_allocation_map_.Get(memory, &alloc_record)) {
       DisableMemoryTrackingInScope no_memory_tracking(this);
       const CallStack& callstack = (*callstack_tls_.GetOrCreate());
       access_ptr->OnMemoryDeallocation(memory, alloc_record, callstack);
     }
   }

   // Prevent a map::erase() from causing an endless stack overflow by
   // disabling memory deletion for the very limited scope.
   {
     DisableDeletionInScope no_memory_deletion(this);
     removed = atomic_allocation_map_.Remove(memory, &alloc_record);
   }

   if (!removed) {
     return 0;
   } else {
     const int64_t alloc_size = (static_cast<int64_t>(alloc_record.size));
     AllocationGroup* group = alloc_record.allocation_group;
     if (group) {
       group->AddAllocation(-alloc_size);
     }
     AddAllocationBytes(-alloc_size);
     return alloc_record.size;
   }
 }

 bool MemoryTrackerImpl::GetMemoryTracking(const void* memory,
                                           AllocationRecord* record) const {
   const bool exists = atomic_allocation_map_.Get(memory, record);
   return exists;
 }

 void MemoryTrackerImpl::SetMemoryTrackingEnabled(bool on) {
   memory_tracking_disabled_tls_->Set(!on);
 }

 bool MemoryTrackerImpl::IsMemoryTrackingEnabled() const {
   const bool enabled = !memory_tracking_disabled_tls_->Get();
   return enabled;
 }

 void MemoryTrackerImpl::AddAllocationBytes(int64_t val) {
   total_bytes_allocated_.fetch_add(val);
 }

 bool MemoryTrackerImpl::MemoryDeletionEnabled() const {
   return !memory_deletion_enabled_tls_->Get();
 }

 void MemoryTrackerImpl::SetMemoryDeletionEnabled(bool on) {
   memory_deletion_enabled_tls_->Set(!on);
 }

 MemoryTrackerImpl::DisableMemoryTrackingInScope::DisableMemoryTrackingInScope(
     MemoryTrackerImpl* t)
     : owner_(t) {
   prev_value_ = owner_->IsMemoryTrackingEnabled();
   owner_->SetMemoryTrackingEnabled(false);
 }

 MemoryTrackerImpl::DisableMemoryTrackingInScope::
     ~DisableMemoryTrackingInScope() {
   owner_->SetMemoryTrackingEnabled(prev_value_);
 }

 }  // namespace analytics
 }  // namespace nb
	/*
	* Copyright 2016 Google Inc. All Rights Reserved.
	*
	* 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 "starboard/client_porting/poem/string_leaks_poem.h"

	#include "nb/analytics/memory_tracker_impl.h"

	#include <algorithm>
	#include <cstring>
	#include <functional>
	#include <iomanip>
	#include <iterator>
	#include <sstream>

	#include "nb/concurrent_map.h"
	#include "starboard/atomic.h"
	#include "starboard/common/flat_map.h"
	#include "starboard/log.h"
	#include "starboard/time.h"

	namespace nb {
	namespace analytics {
	namespace {

	// This class allows std containers to bypass memory reporting.
	template <typename T>
	class RawAllocator : public std::allocator<T> {
	public:
	typedef typename std::allocator<T>::pointer pointer;
	typedef typename std::allocator<T>::const_pointer const_pointer;
	typedef typename std::allocator<T>::reference reference;
	typedef typename std::allocator<T>::const_reference const_reference;
	typedef typename std::allocator<T>::size_type size_type;
	typedef typename std::allocator<T>::value_type value_type;
	typedef typename std::allocator<T>::difference_type difference_type;

	RawAllocator() {}

	// Constructor used for rebinding
	template <typename U>
	RawAllocator(const RawAllocator<U>& x) {}

	pointer allocate(size_type n,
	std::allocator<void>::const_pointer hint = NULL) {
	void* ptr = SbMemoryAllocateNoReport(n * sizeof(value_type));
	return static_cast<pointer>(ptr);
	}

	void deallocate(pointer p, size_type n) { SbMemoryDeallocateNoReport(p); }
	template <typename U>
	struct rebind {
	typedef RawAllocator<U> other;
	};
	};
	} // namespace.

	// ThreadLocalBool_NoReport class guarantees that any memory allocated will NOT
	// go through any memory reporting mechanism. Otherwise certain platforms will
	// encounter a stack overflow condition as execution re-enters the allocation
	// function.
	class MemoryTrackerImpl::ThreadLocalBool_NoReport {
	public:
	void Set(bool val) {
	if (val) {
	thread_map_.Set(SbThreadGetId(), val);
	} else {
	// Rather than set to false, remove the element.
	thread_map_.Remove(SbThreadGetId());
	}
	}

	bool Get() {
	ThreadMap::EntryHandle entry;
	bool has_key = thread_map_.Get(SbThreadGetId(), &entry);
	if (!has_key) {
	return false;
	}
	return entry.Value();

	}

	private:
	// Create a concurrent map that supports fast deletion of elements
	// (no memory release).
	//
	using PairType = std::vector<std::pair<SbThreadId, bool>>::value_type;
	// This vector bypasses reporting allocators.
	using VectorPair = std::vector<PairType, RawAllocator<PairType>>;
	// The InnerMap is backed by the vector. The FlatMap transforms the vector
	// into a map interface.
	using InnerMap = starboard::FlatMap<SbThreadId, bool,
	std::less<SbThreadId>,
	VectorPair>;
	// Concurrent map uses distributed locking to achieve a highly concurrent
	// unsorted map.
	using ThreadMap = ConcurrentMap<SbThreadId,
	bool,
	std::hash<SbThreadId>,
	InnerMap>;

	ThreadMap thread_map_;
	};

	SbMemoryReporter* MemoryTrackerImpl::GetMemoryReporter() {
	return &sb_memory_tracker_;
	}

	NbMemoryScopeReporter* MemoryTrackerImpl::GetMemoryScopeReporter() {
	return &nb_memory_scope_reporter_;
	}

	int64_t MemoryTrackerImpl::GetTotalAllocationBytes() {
	return total_bytes_allocated_.load();
	}

	AllocationGroup* MemoryTrackerImpl::GetAllocationGroup(const char* name) {
	DisableMemoryTrackingInScope no_tracking(this);
	AllocationGroup* alloc_group = alloc_group_map_.Ensure(name);
	return alloc_group;
	}

	void MemoryTrackerImpl::PushAllocationGroupByName(const char* group_name) {
	AllocationGroup* group = GetAllocationGroup(group_name);
	PushAllocationGroup(group);
	}

	void MemoryTrackerImpl::PushAllocationGroup(AllocationGroup* alloc_group) {
	if (alloc_group == NULL) {
	alloc_group = alloc_group_map_.GetDefaultUnaccounted();
	}
	DisableMemoryTrackingInScope no_tracking(this);
	allocation_group_stack_tls_.GetOrCreate()->Push(alloc_group);
	}

	AllocationGroup* MemoryTrackerImpl::PeekAllocationGroup() {
	DisableMemoryTrackingInScope no_tracking(this);
	AllocationGroup* out =
	allocation_group_stack_tls_.GetOrCreate()->Peek();
	if (out == NULL) {
	out = alloc_group_map_.GetDefaultUnaccounted();
	}
	return out;
	}

	void MemoryTrackerImpl::PopAllocationGroup() {
	DisableMemoryTrackingInScope no_tracking(this);
	AllocationGroupStack* alloc_tls = allocation_group_stack_tls_.GetOrCreate();
	alloc_tls->Pop();
	AllocationGroup* group = alloc_tls->Peek();
	// We don't allow null, so if this is encountered then push the
	// "default unaccounted" alloc group.
	if (group == NULL) {
	alloc_tls->Push(alloc_group_map_.GetDefaultUnaccounted());
	}
	}

	void MemoryTrackerImpl::GetAllocationGroups(
	std::vector<const AllocationGroup> output) {
	DisableMemoryTrackingInScope no_allocation_tracking(this);
	output->reserve(100);
	alloc_group_map_.GetAll(output);
	}

	void MemoryTrackerImpl::GetAllocationGroups(
	std::map<std::string, const AllocationGroup> output) {
	output->clear();
	DisableMemoryTrackingInScope no_tracking(this);
	std::vector<const AllocationGroup*> tmp;
	GetAllocationGroups(&tmp);
	for (size_t i = 0; i < tmp.size(); ++i) {
	output->insert(std::make_pair(tmp[i]->name(), tmp[i]));
	}
	}

	void MemoryTrackerImpl::Accept(AllocationVisitor* visitor) {
	DisableMemoryTrackingInScope no_mem_allocation_reporting(this);
	DisableDeletionInScope no_mem_deletion_reporting(this);
	atomic_allocation_map_.Accept(visitor);
	}

	void MemoryTrackerImpl::Clear() {
	// Prevent clearing of the tree from triggering a re-entrant
	// memory deallocation.
	atomic_allocation_map_.Clear();
	total_bytes_allocated_.store(0);
	}

	void MemoryTrackerImpl::Debug_PushAllocationGroupBreakPointByName(
	const char* group_name) {
	DisableMemoryTrackingInScope no_tracking(this);
	SB_DCHECK(group_name != NULL);
	AllocationGroup* group = alloc_group_map_.Ensure(group_name);
	Debug_PushAllocationGroupBreakPoint(group);
	}

	void MemoryTrackerImpl::Debug_PushAllocationGroupBreakPoint(
	AllocationGroup* alloc_group) {
	DisableMemoryTrackingInScope no_tracking(this);
	allocation_group_stack_tls_.GetOrCreate()->Push_DebugBreak(alloc_group);
	}

	void MemoryTrackerImpl::Debug_PopAllocationGroupBreakPoint() {
	DisableMemoryTrackingInScope no_tracking(this);
	allocation_group_stack_tls_.GetOrCreate()->Pop_DebugBreak();
	}

	void MemoryTrackerImpl::OnMalloc(void* context,
	const void* memory,
	size_t size) {
	MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
	t->AddMemoryTracking(memory, size);
	}

	void MemoryTrackerImpl::OnDealloc(void* context, const void* memory) {
	MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
	t->RemoveMemoryTracking(memory);
	}

	void MemoryTrackerImpl::OnMapMem(void* context,
	const void* memory,
	size_t size) {
	// We might do something more interesting with MapMemory calls later.
	OnMalloc(context, memory, size);
	}

	void MemoryTrackerImpl::OnUnMapMem(void* context,
	const void* memory,
	size_t size) {
	// We might do something more interesting with UnMapMemory calls later.
	OnDealloc(context, memory);
	}

	void MemoryTrackerImpl::OnPushAllocationGroup(
	void* context,
	NbMemoryScopeInfo* memory_scope_info) {
	MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
	void** cached_handle = &(memory_scope_info->cached_handle_);
	const bool allows_caching = memory_scope_info->allows_caching_;
	const char* group_name = memory_scope_info->memory_scope_name_;

	AllocationGroup* group = NULL;
	if (allows_caching && *cached_handle != NULL) {
	group = static_cast<AllocationGroup>(cached_handle);
	} else {
	group = t->GetAllocationGroup(group_name);
	if (allows_caching) {
	// Flush all pending writes so that the the pointee is well formed
	// by the time the pointer becomes visible to other threads.
	SbAtomicMemoryBarrier();
	cached_handle = static_cast<void>(group);
	}
	}

	DisableMemoryTrackingInScope no_memory_tracking_in_scope(t);
	t->PushAllocationGroup(group);
	CallStack* callstack = t->callstack_tls_.GetOrCreate();
	callstack->push_back(memory_scope_info);
	}

	void MemoryTrackerImpl::OnPopAllocationGroup(void* context) {
	MemoryTrackerImpl* t = static_cast<MemoryTrackerImpl*>(context);
	t->PopAllocationGroup();
	CallStack* callstack = t->callstack_tls_.GetOrCreate();
	// Callstack can be empty when the memory tracker binds to the callback
	// system while the program is in the middle of the execution.
	if (!callstack->empty()) {
	callstack->pop_back();
	}
	}

	void MemoryTrackerImpl::Initialize(
	SbMemoryReporter* sb_memory_reporter,
	NbMemoryScopeReporter* memory_scope_reporter) {
	SbMemoryReporter mem_reporter = {
	MemoryTrackerImpl::OnMalloc, MemoryTrackerImpl::OnDealloc,
	MemoryTrackerImpl::OnMapMem, MemoryTrackerImpl::OnUnMapMem,
	this};

	NbMemoryScopeReporter mem_scope_reporter = {
	MemoryTrackerImpl::OnPushAllocationGroup,
	MemoryTrackerImpl::OnPopAllocationGroup,
	this,
	};

	*sb_memory_reporter = mem_reporter;
	*memory_scope_reporter = mem_scope_reporter;
	}

	void MemoryTrackerImpl::SetThreadFilter(SbThreadId tid) {
	thread_filter_id_ = tid;
	}

	bool MemoryTrackerImpl::IsCurrentThreadAllowedToReport() const {
	if (thread_filter_id_ == kSbThreadInvalidId) {
	return true;
	}
	return SbThreadGetId() == thread_filter_id_;
	}

	void MemoryTrackerImpl::SetMemoryTrackerDebugCallback(
	MemoryTrackerDebugCallback* cb) {
	debug_callback_.swap(cb);
	}

	MemoryTrackerImpl::DisableDeletionInScope::DisableDeletionInScope(
	MemoryTrackerImpl* owner)
	: owner_(owner) {
	prev_state_ = owner->MemoryDeletionEnabled();
	owner_->SetMemoryDeletionEnabled(false);
	}

	MemoryTrackerImpl::DisableDeletionInScope::~DisableDeletionInScope() {
	owner_->SetMemoryDeletionEnabled(prev_state_);
	}

	MemoryTrackerImpl::MemoryTrackerImpl()
	: thread_filter_id_(kSbThreadInvalidId), debug_callback_(nullptr) {
	memory_deletion_enabled_tls_.reset(new ThreadLocalBool_NoReport);
	memory_tracking_disabled_tls_.reset(new ThreadLocalBool_NoReport);
	total_bytes_allocated_.store(0);
	global_hooks_installed_ = false;
	Initialize(&sb_memory_tracker_, &nb_memory_scope_reporter_);
	// Push the default region so that stats can be accounted for.
	PushAllocationGroup(alloc_group_map_.GetDefaultUnaccounted());
	}

	MemoryTrackerImpl::~MemoryTrackerImpl() {
	// If we are currently hooked into allocation tracking...
	if (global_hooks_installed_) {
	RemoveGlobalTrackingHooks();
	// For performance reasons no locking is used on the tracker.
	// Therefore give enough time for other threads to exit this tracker
	// before fully destroying this object.
	SbThreadSleep(250 * kSbTimeMillisecond); // 250 millisecond wait.
	}
	}

	bool MemoryTrackerImpl::AddMemoryTracking(const void* memory, size_t size) {
	// Vars are stored to assist in debugging.
	const bool thread_allowed_to_report = IsCurrentThreadAllowedToReport();
	const bool valid_memory_request = (memory != NULL) && (size != 0);
	const bool mem_track_enabled = IsMemoryTrackingEnabled();

	const bool tracking_enabled =
	mem_track_enabled && valid_memory_request && thread_allowed_to_report;

	if (!tracking_enabled) {
	return false;
	}

	// End all memory tracking in subsequent data structures.
	DisableMemoryTrackingInScope no_memory_tracking(this);
	AllocationGroupStack* alloc_stack =
	allocation_group_stack_tls_.GetOrCreate();
	AllocationGroup* group = alloc_stack->Peek();
	if (!group) {
	group = alloc_group_map_.GetDefaultUnaccounted();
	}

	#ifndef NDEBUG
	// This section of the code is designed to allow a developer to break
	// execution whenever the debug allocation stack is in scope, so that the
	// allocations can be stepped through. This is a THREAD LOCAL operation.
	// Example:
	// Debug_PushAllocationGroupBreakPointByName("Javascript");
	// ...now set a break point below at "static int i = 0"
	if (group && (group == alloc_stack->Peek_DebugBreak()) &&
	alloc_stack->Peek_DebugBreak()) {
	static int i = 0; // This static is here to allow an
	++i; // easy breakpoint in the debugger
	}
	#endif

	AllocationRecord alloc_record(size, group);
	bool added = atomic_allocation_map_.Add(memory, alloc_record);
	if (added) {
	AddAllocationBytes(size);
	group->AddAllocation(size);
	ConcurrentPtr<MemoryTrackerDebugCallback>::Access access_ptr =
	debug_callback_.access_ptr(SbThreadId());

	// If access_ptr is valid then it is guaranteed to be alive for the
	// duration of the scope.
	if (access_ptr) {
	const CallStack& callstack = *(callstack_tls_.GetOrCreate());
	DisableDeletionInScope disable_deletion_tracking(this);
	access_ptr->OnMemoryAllocation(memory, alloc_record, callstack);
	}
	} else {
	// Handles the case where the memory hasn't been properly been reported
	// released. This is less serious than you would think because the memory
	// allocator in the system will recycle the memory and it will come back.
	AllocationRecord unexpected_alloc;
	atomic_allocation_map_.Get(memory, &unexpected_alloc);
	AllocationGroup* prev_group = unexpected_alloc.allocation_group;

	std::string prev_group_name;
	if (prev_group) {
	prev_group_name = unexpected_alloc.allocation_group->name();
	} else {
	prev_group_name = "none";
	}

	if (!added) {
	std::stringstream ss;
	ss << "\nUnexpected condition, previous allocation was not removed:\n"
	<< "\tprevious alloc group: " << prev_group_name << "\n"
	<< "\tnew alloc group: " << group->name() << "\n"
	<< "\tprevious size: " << unexpected_alloc.size << "\n"
	<< "\tnew size: " << size << "\n";

	SbLogRaw(ss.str().c_str());
	}
	}
	return added;
	}

	size_t MemoryTrackerImpl::RemoveMemoryTracking(const void* memory) {
	const bool do_remove = memory && MemoryDeletionEnabled();
	if (!do_remove) {
	return 0;
	}

	AllocationRecord alloc_record;
	bool removed = false;

	ConcurrentPtr<MemoryTrackerDebugCallback>::Access access_ptr =
	debug_callback_.access_ptr(SbThreadId());

	if (access_ptr) {
	if (atomic_allocation_map_.Get(memory, &alloc_record)) {
	DisableMemoryTrackingInScope no_memory_tracking(this);
	const CallStack& callstack = (*callstack_tls_.GetOrCreate());
	access_ptr->OnMemoryDeallocation(memory, alloc_record, callstack);
	}
	}

	// Prevent a map::erase() from causing an endless stack overflow by
	// disabling memory deletion for the very limited scope.
	{
	DisableDeletionInScope no_memory_deletion(this);
	removed = atomic_allocation_map_.Remove(memory, &alloc_record);
	}

	if (!removed) {
	return 0;
	} else {
	const int64_t alloc_size = (static_cast<int64_t>(alloc_record.size));
	AllocationGroup* group = alloc_record.allocation_group;
	if (group) {
	group->AddAllocation(-alloc_size);
	}
	AddAllocationBytes(-alloc_size);
	return alloc_record.size;
	}
	}

	bool MemoryTrackerImpl::GetMemoryTracking(const void* memory,
	AllocationRecord* record) const {
	const bool exists = atomic_allocation_map_.Get(memory, record);
	return exists;
	}

	void MemoryTrackerImpl::SetMemoryTrackingEnabled(bool on) {
	memory_tracking_disabled_tls_->Set(!on);
	}

	bool MemoryTrackerImpl::IsMemoryTrackingEnabled() const {
	const bool enabled = !memory_tracking_disabled_tls_->Get();
	return enabled;
	}

	void MemoryTrackerImpl::AddAllocationBytes(int64_t val) {
	total_bytes_allocated_.fetch_add(val);
	}

	bool MemoryTrackerImpl::MemoryDeletionEnabled() const {
	return !memory_deletion_enabled_tls_->Get();
	}

	void MemoryTrackerImpl::SetMemoryDeletionEnabled(bool on) {
	memory_deletion_enabled_tls_->Set(!on);
	}

	MemoryTrackerImpl::DisableMemoryTrackingInScope::DisableMemoryTrackingInScope(
	MemoryTrackerImpl* t)
	: owner_(t) {
	prev_value_ = owner_->IsMemoryTrackingEnabled();
	owner_->SetMemoryTrackingEnabled(false);
	}

	MemoryTrackerImpl::DisableMemoryTrackingInScope::
	~DisableMemoryTrackingInScope() {
	owner_->SetMemoryTrackingEnabled(prev_value_);
	}

	} // namespace analytics
	} // namespace nb