base/debug/allocation_trace.h - platform/external/cronet - Git at Google

 // Copyright 2023 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_DEBUG_ALLOCATION_TRACE_H_
 #define BASE_DEBUG_ALLOCATION_TRACE_H_

 #include <algorithm>
 #include <array>
 #include <atomic>
 #include <cstdint>

 #include "base/allocator/dispatcher/subsystem.h"
 #include "base/base_export.h"
 #include "base/bits.h"
 #include "base/compiler_specific.h"
 #include "base/debug/debugging_buildflags.h"
 #include "base/debug/stack_trace.h"
 #include "base/memory/raw_ptr_exclusion.h"
 #include "build/build_config.h"

 namespace base::debug::tracer {

 // Number of traces that can be stored. This number must be a power of two to
 // allow for fast computation of modulo.
 constexpr size_t kMaximumNumberOfMemoryOperationTraces = (1 << 15);
 // Number of frames stored for each operation. Probably the lower frames
 // represent the memory allocation system. Hence, we store more frames to
 // increase chances of having a meaningful trace of the path that caused the
 // allocation or free.
 constexpr size_t kStackTraceSize = 16;

 // The type of an operation stored in the recorder.
 enum class OperationType {
   // The state of an operation record before calling any of the initialization
   // functions.
   kNone = 0,
   // The record represents an allocation operation.
   kAllocation,
   // The record represents a free operation.
   kFree,
 };

 using StackTraceContainer = std::array<const void*, kStackTraceSize>;

 // The record for a single operation. A record can represent any type of
 // operation, allocation or free, but not at the same time.
 //
 // A record protects itself from concurrent initializations. If a thread B calls
 // any of the Initialize*-functions while another thread A is currently
 // initializing, B's invocations shall immediately return |false| without
 // interfering with thread A.
 class BASE_EXPORT OperationRecord {
  public:
   constexpr OperationRecord() = default;

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

   // Is the record currently being taken?
   bool IsRecording() const;

   OperationType GetOperationType() const;
   // The address allocated or freed.
   const void* GetAddress() const;
   // Number of allocated bytes. Returns 0 for free operations.
   size_t GetSize() const;
   // The stacktrace as taken by the Initialize*-functions.
   const StackTraceContainer& GetStackTrace() const;

   // Initialize the record with data for another operation. Data from any
   // previous operation will be silently overwritten. These functions are
   // declared ALWAYS_INLINE to minimize pollution of the recorded stack trace.
   //
   // Both functions return false in case no record was taken, i.e. if another
   // thread is capturing.
   ALWAYS_INLINE bool InitializeFree(const void* freed_address) {
     return InitializeOperationRecord(freed_address, 0, OperationType::kFree);
   }

   ALWAYS_INLINE bool InitializeAllocation(const void* allocated_address,
                                           size_t allocated_size) {
     return InitializeOperationRecord(allocated_address, allocated_size,
                                      OperationType::kAllocation);
   }

  private:
   // Initialize a record with the given data. Return true if the record was
   // initialized successfully, false if no record was taken, i.e. if another
   // thread is capturing.
   ALWAYS_INLINE bool InitializeOperationRecord(const void* address,
                                                size_t size,
                                                OperationType operation_type);
   ALWAYS_INLINE void StoreStackTrace();

   // The stack trace taken in one of the Initialize* functions.
   StackTraceContainer stack_trace_ = {};
   // The number of allocated bytes.
   size_t size_ = 0;
   // The address that was allocated or freed.
   // We use a raw C++ pointer instead of base::raw_ptr for performance
   // reasons.
   // - In the recorder we only store pointers, we never allocate or free on
   //   our own.
   // - Storing is the hot path. base::raw_ptr::operator== may perform sanity
   //   checks which do not make sense in our case (otherwise the allocated
   //   address would have been quirky)
   RAW_PTR_EXCLUSION const void* address_ = nullptr;
   // The type of the operation that was performed. In the course of making a
   // record, this value is reset to |OperationType::kNone| and later set to
   // the operation type specific value, so if the process crashes whilst writing
   // the record, it's marked as empty. To prevent the compiler from optimizing
   // away the initial reset, this value is marked as volatile.
   volatile OperationType operation_type_ = OperationType::kNone;
   // Is the record currently being taken from another thread? Used to prevent
   // concurrent writes to the same record.
   //
   // The value is mutable since pre C++20 there is no const getter in
   // atomic_flag. All ways to get the value involve setting it.
   // TODO(https://crbug.com/1284275): Remove mutable and make IsRecording() use
   // atomic_flag::test();
   mutable std::atomic_flag is_recording_ = ATOMIC_FLAG_INIT;
 };

 ALWAYS_INLINE bool OperationRecord::InitializeOperationRecord(
     const void* address,
     size_t size,
     OperationType operation_type) {
   if (is_recording_.test_and_set(std::memory_order_acquire)) {
     return false;
   }

   operation_type_ = operation_type;
   StoreStackTrace();
   address_ = address;
   size_ = size;

   is_recording_.clear(std::memory_order_release);

   return true;
 }

 ALWAYS_INLINE void OperationRecord::StoreStackTrace() {
   stack_trace_.fill(nullptr);

 #if BUILDFLAG(CAN_UNWIND_WITH_FRAME_POINTERS)
   // Currently we limit ourselves to use TraceStackFramePointers. We know that
   // TraceStackFramePointers has an acceptable performance impact on Android.
   base::debug::TraceStackFramePointers(&stack_trace_[0], stack_trace_.size(),
                                        0);
 #elif BUILDFLAG(IS_LINUX)
   // Use base::debug::CollectStackTrace as an alternative for tests on Linux. We
   // still have a check in /base/debug/debug.gni to prevent that
   // AllocationStackTraceRecorder is enabled accidentally on Linux.
   base::debug::CollectStackTrace(&stack_trace_[0], stack_trace_.size());
 #else
 #error "No supported stack tracer found."
 #endif
 }

 struct BASE_EXPORT AllocationTraceRecorderStatistics {
 #if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
   AllocationTraceRecorderStatistics(size_t total_number_of_allocations,
                                     size_t total_number_of_collisions);
 #else
   AllocationTraceRecorderStatistics(size_t total_number_of_allocations);
 #endif

   // The total number of allocations that have been recorded.
   size_t total_number_of_allocations;
 #if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
   // The total number of collisions that have been encountered. A collision
   // happens when two threads concurrently try to record using the same slot.
   size_t total_number_of_collisions;
 #endif
 };

 // The recorder which holds entries for past memory operations.
 //
 // The memory image of the recorder will be copied into the crash-handler.
 // Therefore, it must not hold any references to external data which are vital
 // for proper functioning.
 //
 // It is important that the recorder itself does not allocate to prevent
 // recursive calls and save as much runtime overhead as possible.
 //
 // Therefore, records are stored in a preallocated buffer with a compile time
 // constant maximum size, see |kMaximumNumberOfMemoryOperationTraces|. Once all
 // records have been used, old records will be overwritten (fifo-style).
 //
 // The recorder works in an multithreaded environment without external locking.
 // Concurrent writes are prevented by two means:
 //  1 - We atomically increment and calculate the effective index of the record
 //  to be written.
 //  2 - If this entry is still being used (the recording thread didn't finish
 //  yet), we go back to step 1
 // Currently we do not enforce separate cache lines for each entry, which means
 // false sharing can occur. On the other hand, with 64 byte cachelines a clean
 // separation would introduce some 3*64 - sizeof(OperationRecord) = 40 bytes of
 // padding per entry.
 //
 // Note: As a process might be terminated for whatever reason while stack
 // traces are being written, the recorded data may contain some garbage.
 //
 // TODO(https://crbug.com/1419908): Evaluate the impact of the shared cache
 // lines between entries.
 class BASE_EXPORT AllocationTraceRecorder {
  public:
   constexpr AllocationTraceRecorder() = default;

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

   // The allocation event observer interface. See the dispatcher for further
   // details. The functions are marked NO_INLINE. All other functions called but
   // the one taking the call stack are marked ALWAYS_INLINE. This way we ensure
   // the number of frames recorded from these functions is fixed.

   // Handle all allocation events.
   NOINLINE void OnAllocation(
       const void* allocated_address,
       size_t allocated_size,
       base::allocator::dispatcher::AllocationSubsystem subsystem,
       const char* type);

   // Handle all free events.
   NOINLINE void OnFree(const void* freed_address);

   // Access functions to retrieve the current content of the recorder.
   // Note: Since the recorder is usually updated upon each allocation or free,
   // it is important to prevent updates if you want to read the entries at any
   // point.

   // Get the current number of entries stored in the recorder. When the
   // recorder has reached its maximum capacity, it always returns
   // |GetMaximumNumberOfTraces()|.
   size_t size() const;

   // Access the record of an operation by index. Oldest operation is always
   // accessible at index 0, latest operation at |size()-1|.
   // Note: Since a process might have crashed while a trace is being written,
   // especially the last records might be corrupted.
   const OperationRecord& operator[](size_t idx) const;

   constexpr size_t GetMaximumNumberOfTraces() const {
     return kMaximumNumberOfMemoryOperationTraces;
   }

   AllocationTraceRecorderStatistics GetRecorderStatistics() const;

  private:
   ALWAYS_INLINE size_t GetNextIndex();

   ALWAYS_INLINE static constexpr size_t WrapIdxIfNeeded(size_t idx);

   // The actual container.
   std::array<OperationRecord, kMaximumNumberOfMemoryOperationTraces>
       alloc_trace_buffer_ = {};
   // The total number of records that have been taken so far. Note that this
   // might be greater than |kMaximumNumberOfMemoryOperationTraces| since we
   // overwrite oldest items.
   std::atomic<size_t> total_number_of_records_ = 0;
 #if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
   std::atomic<size_t> total_number_of_collisions_ = 0;
 #endif
 };

 ALWAYS_INLINE constexpr size_t AllocationTraceRecorder::WrapIdxIfNeeded(
     size_t idx) {
   // Wrapping around counter, e.g. for BUFFER_SIZE = 256, the counter will
   // wrap around when reaching 256. To enable the compiler to emit more
   // optimized code we assert |kMaximumNumberOfMemoryOperationTraces| is a power
   // of two .
   static_assert(
       base::bits::IsPowerOfTwo(kMaximumNumberOfMemoryOperationTraces),
       "kMaximumNumberOfMemoryOperationTraces should be a power of 2 to "
       "allow for fast modulo operation.");

   return idx % kMaximumNumberOfMemoryOperationTraces;
 }

 ALWAYS_INLINE size_t AllocationTraceRecorder::GetNextIndex() {
   const auto raw_idx =
       total_number_of_records_.fetch_add(1, std::memory_order_relaxed);
   return WrapIdxIfNeeded(raw_idx);
 }

 }  // namespace base::debug::tracer

 #endif  // BASE_DEBUG_ALLOCATION_TRACE_H_
	// Copyright 2023 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_DEBUG_ALLOCATION_TRACE_H_
	#define BASE_DEBUG_ALLOCATION_TRACE_H_

	#include <algorithm>
	#include <array>
	#include <atomic>
	#include <cstdint>

	#include "base/allocator/dispatcher/subsystem.h"
	#include "base/base_export.h"
	#include "base/bits.h"
	#include "base/compiler_specific.h"
	#include "base/debug/debugging_buildflags.h"
	#include "base/debug/stack_trace.h"
	#include "base/memory/raw_ptr_exclusion.h"
	#include "build/build_config.h"

	namespace base::debug::tracer {

	// Number of traces that can be stored. This number must be a power of two to
	// allow for fast computation of modulo.
	constexpr size_t kMaximumNumberOfMemoryOperationTraces = (1 << 15);
	// Number of frames stored for each operation. Probably the lower frames
	// represent the memory allocation system. Hence, we store more frames to
	// increase chances of having a meaningful trace of the path that caused the
	// allocation or free.
	constexpr size_t kStackTraceSize = 16;

	// The type of an operation stored in the recorder.
	enum class OperationType {
	// The state of an operation record before calling any of the initialization
	// functions.
	kNone = 0,
	// The record represents an allocation operation.
	kAllocation,
	// The record represents a free operation.
	kFree,
	};

	using StackTraceContainer = std::array<const void*, kStackTraceSize>;

	// The record for a single operation. A record can represent any type of
	// operation, allocation or free, but not at the same time.
	//
	// A record protects itself from concurrent initializations. If a thread B calls
	// any of the Initialize*-functions while another thread A is currently
	// initializing, B's invocations shall immediately return \|false\| without
	// interfering with thread A.
	class BASE_EXPORT OperationRecord {
	public:
	constexpr OperationRecord() = default;

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

	// Is the record currently being taken?
	bool IsRecording() const;

	OperationType GetOperationType() const;
	// The address allocated or freed.
	const void* GetAddress() const;
	// Number of allocated bytes. Returns 0 for free operations.
	size_t GetSize() const;
	// The stacktrace as taken by the Initialize*-functions.
	const StackTraceContainer& GetStackTrace() const;

	// Initialize the record with data for another operation. Data from any
	// previous operation will be silently overwritten. These functions are
	// declared ALWAYS_INLINE to minimize pollution of the recorded stack trace.
	//
	// Both functions return false in case no record was taken, i.e. if another
	// thread is capturing.
	ALWAYS_INLINE bool InitializeFree(const void* freed_address) {
	return InitializeOperationRecord(freed_address, 0, OperationType::kFree);
	}

	ALWAYS_INLINE bool InitializeAllocation(const void* allocated_address,
	size_t allocated_size) {
	return InitializeOperationRecord(allocated_address, allocated_size,
	OperationType::kAllocation);
	}

	private:
	// Initialize a record with the given data. Return true if the record was
	// initialized successfully, false if no record was taken, i.e. if another
	// thread is capturing.
	ALWAYS_INLINE bool InitializeOperationRecord(const void* address,
	size_t size,
	OperationType operation_type);
	ALWAYS_INLINE void StoreStackTrace();

	// The stack trace taken in one of the Initialize* functions.
	StackTraceContainer stack_trace_ = {};
	// The number of allocated bytes.
	size_t size_ = 0;
	// The address that was allocated or freed.
	// We use a raw C++ pointer instead of base::raw_ptr for performance
	// reasons.
	// - In the recorder we only store pointers, we never allocate or free on
	// our own.
	// - Storing is the hot path. base::raw_ptr::operator== may perform sanity
	// checks which do not make sense in our case (otherwise the allocated
	// address would have been quirky)
	RAW_PTR_EXCLUSION const void* address_ = nullptr;
	// The type of the operation that was performed. In the course of making a
	// record, this value is reset to \|OperationType::kNone\| and later set to
	// the operation type specific value, so if the process crashes whilst writing
	// the record, it's marked as empty. To prevent the compiler from optimizing
	// away the initial reset, this value is marked as volatile.
	volatile OperationType operation_type_ = OperationType::kNone;
	// Is the record currently being taken from another thread? Used to prevent
	// concurrent writes to the same record.
	//
	// The value is mutable since pre C++20 there is no const getter in
	// atomic_flag. All ways to get the value involve setting it.
	// TODO(https://crbug.com/1284275): Remove mutable and make IsRecording() use
	// atomic_flag::test();
	mutable std::atomic_flag is_recording_ = ATOMIC_FLAG_INIT;
	};

	ALWAYS_INLINE bool OperationRecord::InitializeOperationRecord(
	const void* address,
	size_t size,
	OperationType operation_type) {
	if (is_recording_.test_and_set(std::memory_order_acquire)) {
	return false;
	}

	operation_type_ = operation_type;
	StoreStackTrace();
	address_ = address;
	size_ = size;

	is_recording_.clear(std::memory_order_release);

	return true;
	}

	ALWAYS_INLINE void OperationRecord::StoreStackTrace() {
	stack_trace_.fill(nullptr);

	#if BUILDFLAG(CAN_UNWIND_WITH_FRAME_POINTERS)
	// Currently we limit ourselves to use TraceStackFramePointers. We know that
	// TraceStackFramePointers has an acceptable performance impact on Android.
	base::debug::TraceStackFramePointers(&stack_trace_[0], stack_trace_.size(),
	0);
	#elif BUILDFLAG(IS_LINUX)
	// Use base::debug::CollectStackTrace as an alternative for tests on Linux. We
	// still have a check in /base/debug/debug.gni to prevent that
	// AllocationStackTraceRecorder is enabled accidentally on Linux.
	base::debug::CollectStackTrace(&stack_trace_[0], stack_trace_.size());
	#else
	#error "No supported stack tracer found."
	#endif
	}

	struct BASE_EXPORT AllocationTraceRecorderStatistics {
	#if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
	AllocationTraceRecorderStatistics(size_t total_number_of_allocations,
	size_t total_number_of_collisions);
	#else
	AllocationTraceRecorderStatistics(size_t total_number_of_allocations);
	#endif

	// The total number of allocations that have been recorded.
	size_t total_number_of_allocations;
	#if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
	// The total number of collisions that have been encountered. A collision
	// happens when two threads concurrently try to record using the same slot.
	size_t total_number_of_collisions;
	#endif
	};

	// The recorder which holds entries for past memory operations.
	//
	// The memory image of the recorder will be copied into the crash-handler.
	// Therefore, it must not hold any references to external data which are vital
	// for proper functioning.
	//
	// It is important that the recorder itself does not allocate to prevent
	// recursive calls and save as much runtime overhead as possible.
	//
	// Therefore, records are stored in a preallocated buffer with a compile time
	// constant maximum size, see \|kMaximumNumberOfMemoryOperationTraces\|. Once all
	// records have been used, old records will be overwritten (fifo-style).
	//
	// The recorder works in an multithreaded environment without external locking.
	// Concurrent writes are prevented by two means:
	// 1 - We atomically increment and calculate the effective index of the record
	// to be written.
	// 2 - If this entry is still being used (the recording thread didn't finish
	// yet), we go back to step 1
	// Currently we do not enforce separate cache lines for each entry, which means
	// false sharing can occur. On the other hand, with 64 byte cachelines a clean
	// separation would introduce some 3*64 - sizeof(OperationRecord) = 40 bytes of
	// padding per entry.
	//
	// Note: As a process might be terminated for whatever reason while stack
	// traces are being written, the recorded data may contain some garbage.
	//
	// TODO(https://crbug.com/1419908): Evaluate the impact of the shared cache
	// lines between entries.
	class BASE_EXPORT AllocationTraceRecorder {
	public:
	constexpr AllocationTraceRecorder() = default;

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

	// The allocation event observer interface. See the dispatcher for further
	// details. The functions are marked NO_INLINE. All other functions called but
	// the one taking the call stack are marked ALWAYS_INLINE. This way we ensure
	// the number of frames recorded from these functions is fixed.

	// Handle all allocation events.
	NOINLINE void OnAllocation(
	const void* allocated_address,
	size_t allocated_size,
	base::allocator::dispatcher::AllocationSubsystem subsystem,
	const char* type);

	// Handle all free events.
	NOINLINE void OnFree(const void* freed_address);

	// Access functions to retrieve the current content of the recorder.
	// Note: Since the recorder is usually updated upon each allocation or free,
	// it is important to prevent updates if you want to read the entries at any
	// point.

	// Get the current number of entries stored in the recorder. When the
	// recorder has reached its maximum capacity, it always returns
	// \|GetMaximumNumberOfTraces()\|.
	size_t size() const;

	// Access the record of an operation by index. Oldest operation is always
	// accessible at index 0, latest operation at \|size()-1\|.
	// Note: Since a process might have crashed while a trace is being written,
	// especially the last records might be corrupted.
	const OperationRecord& operator[](size_t idx) const;

	constexpr size_t GetMaximumNumberOfTraces() const {
	return kMaximumNumberOfMemoryOperationTraces;
	}

	AllocationTraceRecorderStatistics GetRecorderStatistics() const;

	private:
	ALWAYS_INLINE size_t GetNextIndex();

	ALWAYS_INLINE static constexpr size_t WrapIdxIfNeeded(size_t idx);

	// The actual container.
	std::array<OperationRecord, kMaximumNumberOfMemoryOperationTraces>
	alloc_trace_buffer_ = {};
	// The total number of records that have been taken so far. Note that this
	// might be greater than \|kMaximumNumberOfMemoryOperationTraces\| since we
	// overwrite oldest items.
	std::atomic<size_t> total_number_of_records_ = 0;
	#if BUILDFLAG(ENABLE_ALLOCATION_TRACE_RECORDER_FULL_REPORTING)
	std::atomic<size_t> total_number_of_collisions_ = 0;
	#endif
	};

	ALWAYS_INLINE constexpr size_t AllocationTraceRecorder::WrapIdxIfNeeded(
	size_t idx) {
	// Wrapping around counter, e.g. for BUFFER_SIZE = 256, the counter will
	// wrap around when reaching 256. To enable the compiler to emit more
	// optimized code we assert \|kMaximumNumberOfMemoryOperationTraces\| is a power
	// of two .
	static_assert(
	base::bits::IsPowerOfTwo(kMaximumNumberOfMemoryOperationTraces),
	"kMaximumNumberOfMemoryOperationTraces should be a power of 2 to "
	"allow for fast modulo operation.");

	return idx % kMaximumNumberOfMemoryOperationTraces;
	}

	ALWAYS_INLINE size_t AllocationTraceRecorder::GetNextIndex() {
	const auto raw_idx =
	total_number_of_records_.fetch_add(1, std::memory_order_relaxed);
	return WrapIdxIfNeeded(raw_idx);
	}

	} // namespace base::debug::tracer

	#endif // BASE_DEBUG_ALLOCATION_TRACE_H_