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cobalt / cobalt / 0c2b1d4428f8ae16220e86a16bebd07ff691a412 / . / base / metrics / persistent_memory_allocator.h
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// Copyright (c) 2015 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef BASE_METRICS_PERSISTENT_MEMORY_ALLOCATOR_H_
#define BASE_METRICS_PERSISTENT_MEMORY_ALLOCATOR_H_
#include <atomic>
#include <memory>
#include <type_traits>
#include "base/atomicops.h"
#include "base/base_export.h"
#include "base/files/file_path.h"
#include "base/gtest_prod_util.h"
#include "base/macros.h"
#include "base/strings/string_piece.h"
#include "starboard/types.h"
namespace base {
class HistogramBase;
class MemoryMappedFile;
class SharedMemory;
// Simple allocator for pieces of a memory block that may be persistent
// to some storage or shared across multiple processes. This class resides
// under base/metrics because it was written for that purpose. It is,
// however, fully general-purpose and can be freely moved to base/memory
// if other uses are found.
//
// This class provides for thread-secure (i.e. safe against other threads
// or processes that may be compromised and thus have malicious intent)
// allocation of memory within a designated block and also a mechanism by
// which other threads can learn of these allocations.
//
// There is (currently) no way to release an allocated block of data because
// doing so would risk invalidating pointers held by other processes and
// greatly complicate the allocation algorithm.
//
// Construction of this object can accept new, clean (i.e. zeroed) memory
// or previously initialized memory. In the first case, construction must
// be allowed to complete before letting other allocators attach to the same
// segment. In other words, don't share the segment until at least one
// allocator has been attached to it.
//
// Note that memory not in active use is not accessed so it is possible to
// use virtual memory, including memory-mapped files, as backing storage with
// the OS "pinning" new (zeroed) physical RAM pages only as they are needed.
//
// OBJECTS: Although the allocator can be used in a "malloc" sense, fetching
// character arrays and manipulating that memory manually, the better way is
// generally to use the "object" methods to create and manage allocations. In
// this way the sizing, type-checking, and construction are all automatic. For
// this to work, however, every type of stored object must define two public
// "constexpr" values, kPersistentTypeId and kExpectedInstanceSize, as such:
//
// struct MyPersistentObjectType {
// // SHA1(MyPersistentObjectType): Increment this if structure changes!
// static constexpr uint32_t kPersistentTypeId = 0x3E15F6DE + 1;
//
// // Expected size for 32/64-bit check. Update this if structure changes!
// static constexpr size_t kExpectedInstanceSize = 20;
//
// ...
// };
//
// kPersistentTypeId: This value is an arbitrary identifier that allows the
// identification of these objects in the allocator, including the ability
// to find them via iteration. The number is arbitrary but using the first
// four bytes of the SHA1 hash of the type name means that there shouldn't
// be any conflicts with other types that may also be stored in the memory.
// The fully qualified name (e.g. base::debug::MyPersistentObjectType) could
// be used to generate the hash if the type name seems common. Use a command
// like this to get the hash: echo -n "MyPersistentObjectType" | sha1sum
// If the structure layout changes, ALWAYS increment this number so that
// newer versions of the code don't try to interpret persistent data written
// by older versions with a different layout.
//
// kExpectedInstanceSize: This value is the hard-coded number that matches
// what sizeof(T) would return. By providing it explicitly, the allocator can
// verify that the structure is compatible between both 32-bit and 64-bit
// versions of the code.
//
// Using New manages the memory and then calls the default constructor for the
// object. Given that objects are persistent, no destructor is ever called
// automatically though a caller can explicitly call Delete to destruct it and
// change the type to something indicating it is no longer in use.
//
// Though persistent memory segments are transferrable between programs built
// for different natural word widths, they CANNOT be exchanged between CPUs
// of different endianess. Attempts to do so will simply see the existing data
// as corrupt and refuse to access any of it.
class BASE_EXPORT PersistentMemoryAllocator {
public:
typedef uint32_t Reference;
// These states are used to indicate the overall condition of the memory
// segment irrespective of what is stored within it. Because the data is
// often persistent and thus needs to be readable by different versions of
// a program, these values are fixed and can never change.
enum MemoryState : uint8_t {
// Persistent memory starts all zeros and so shows "uninitialized".
MEMORY_UNINITIALIZED = 0,
// The header has been written and the memory is ready for use.
MEMORY_INITIALIZED = 1,
// The data should be considered deleted. This would be set when the
// allocator is being cleaned up. If file-backed, the file is likely
// to be deleted but since deletion can fail for a variety of reasons,
// having this extra status means a future reader can realize what
// should have happened.
MEMORY_DELETED = 2,
// Outside code can create states starting with this number; these too
// must also never change between code versions.
MEMORY_USER_DEFINED = 100,
};
// Iterator for going through all iterable memory records in an allocator.
// Like the allocator itself, iterators are lock-free and thread-secure.
// That means that multiple threads can share an iterator and the same
// reference will not be returned twice.
//
// The order of the items returned by an iterator matches the order in which
// MakeIterable() was called on them. Once an allocation is made iterable,
// it is always such so the only possible difference between successive
// iterations is for more to be added to the end.
//
// Iteration, in general, is tolerant of corrupted memory. It will return
// what it can and stop only when corruption forces it to. Bad corruption
// could cause the same object to be returned many times but it will
// eventually quit.
class BASE_EXPORT Iterator {
public:
// Constructs an iterator on a given |allocator|, starting at the beginning.
// The allocator must live beyond the lifetime of the iterator. This class
// has read-only access to the allocator (hence "const") but the returned
// references can be used on a read/write version, too.
explicit Iterator(const PersistentMemoryAllocator* allocator);
// As above but resuming from the |starting_after| reference. The first call
// to GetNext() will return the next object found after that reference. The
// reference must be to an "iterable" object; references to non-iterable
// objects (those that never had MakeIterable() called for them) will cause
// a run-time error.
Iterator(const PersistentMemoryAllocator* allocator,
Reference starting_after);
// Resets the iterator back to the beginning.
void Reset();
// Resets the iterator, resuming from the |starting_after| reference.
void Reset(Reference starting_after);
// Returns the previously retrieved reference, or kReferenceNull if none.
// If constructor or reset with a starting_after location, this will return
// that value.
Reference GetLast();
// Gets the next iterable, storing that type in |type_return|. The actual
// return value is a reference to the allocation inside the allocator or
// zero if there are no more. GetNext() may still be called again at a
// later time to retrieve any new allocations that have been added.
Reference GetNext(uint32_t* type_return);
// Similar to above but gets the next iterable of a specific |type_match|.
// This should not be mixed with calls to GetNext() because any allocations
// skipped here due to a type mis-match will never be returned by later
// calls to GetNext() meaning it's possible to completely miss entries.
Reference GetNextOfType(uint32_t type_match);
// As above but works using object type.
template <typename T>
Reference GetNextOfType() {
return GetNextOfType(T::kPersistentTypeId);
}
// As above but works using objects and returns null if not found.
template <typename T>
const T* GetNextOfObject() {
return GetAsObject<T>(GetNextOfType<T>());
}
// Converts references to objects. This is a convenience method so that
// users of the iterator don't need to also have their own pointer to the
// allocator over which the iterator runs in order to retrieve objects.
// Because the iterator is not read/write, only "const" objects can be
// fetched. Non-const objects can be fetched using the reference on a
// non-const (external) pointer to the same allocator (or use const_cast
// to remove the qualifier).
template <typename T>
const T* GetAsObject(Reference ref) const {
return allocator_->GetAsObject<T>(ref);
}
// Similar to GetAsObject() but converts references to arrays of things.
template <typename T>
const T* GetAsArray(Reference ref, uint32_t type_id, size_t count) const {
return allocator_->GetAsArray<T>(ref, type_id, count);
}
// Convert a generic pointer back into a reference. A null reference will
// be returned if |memory| is not inside the persistent segment or does not
// point to an object of the specified |type_id|.
Reference GetAsReference(const void* memory, uint32_t type_id) const {
return allocator_->GetAsReference(memory, type_id);
}
// As above but convert an object back into a reference.
template <typename T>
Reference GetAsReference(const T* obj) const {
return allocator_->GetAsReference(obj);
}
private:
// Weak-pointer to memory allocator being iterated over.
const PersistentMemoryAllocator* allocator_;
// The last record that was returned.
std::atomic<Reference> last_record_;
// The number of records found; used for detecting loops.
std::atomic<uint32_t> record_count_;
DISALLOW_COPY_AND_ASSIGN(Iterator);
};
// Returned information about the internal state of the heap.
struct MemoryInfo {
size_t total;
size_t free;
};
enum : Reference {
// A common "null" reference value.
kReferenceNull = 0,
};
enum : uint32_t {
// A value that will match any type when doing lookups.
kTypeIdAny = 0x00000000,
// A value indicating that the type is in transition. Work is being done
// on the contents to prepare it for a new type to come.
kTypeIdTransitioning = 0xFFFFFFFF,
};
enum : size_t {
kSizeAny = 1 // Constant indicating that any array size is acceptable.
};
// This is the standard file extension (suitable for being passed to the
// AddExtension() method of base::FilePath) for dumps of persistent memory.
static const base::FilePath::CharType kFileExtension[];
// The allocator operates on any arbitrary block of memory. Creation and
// persisting or sharing of that block with another process is the
// responsibility of the caller. The allocator needs to know only the
// block's |base| address, the total |size| of the block, and any internal
// |page| size (zero if not paged) across which allocations should not span.
// The |id| is an arbitrary value the caller can use to identify a
// particular memory segment. It will only be loaded during the initial
// creation of the segment and can be checked by the caller for consistency.
// The |name|, if provided, is used to distinguish histograms for this
// allocator. Only the primary owner of the segment should define this value;
// other processes can learn it from the shared state. If the underlying
// memory is |readonly| then no changes will be made to it. The resulting
// object should be stored as a "const" pointer.
//
// PersistentMemoryAllocator does NOT take ownership of the memory block.
// The caller must manage it and ensure it stays available throughout the
// lifetime of this object.
//
// Memory segments for sharing must have had an allocator attached to them
// before actually being shared. If the memory segment was just created, it
// should be zeroed before being passed here. If it was an existing segment,
// the values here will be compared to copies stored in the shared segment
// as a guard against corruption.
//
// Make sure that the memory segment is acceptable (see IsMemoryAcceptable()
// method below) before construction if the definition of the segment can
// vary in any way at run-time. Invalid memory segments will cause a crash.
PersistentMemoryAllocator(void* base, size_t size, size_t page_size,
uint64_t id, base::StringPiece name,
bool readonly);
virtual ~PersistentMemoryAllocator();
// Check if memory segment is acceptable for creation of an Allocator. This
// doesn't do any analysis of the data and so doesn't guarantee that the
// contents are valid, just that the paramaters won't cause the program to
// abort. The IsCorrupt() method will report detection of data problems
// found during construction and general operation.
static bool IsMemoryAcceptable(const void* data, size_t size,
size_t page_size, bool readonly);
// Get the internal identifier for this persistent memory segment.
uint64_t Id() const;
// Get the internal name of this allocator (possibly an empty string).
const char* Name() const;
// Is this segment open only for read?
bool IsReadonly() const { return readonly_; }
// Manage the saved state of the memory.
void SetMemoryState(uint8_t memory_state);
uint8_t GetMemoryState() const;
// Create internal histograms for tracking memory use and allocation sizes
// for allocator of |name| (which can simply be the result of Name()). This
// is done seperately from construction for situations such as when the
// histograms will be backed by memory provided by this very allocator.
//
// IMPORTANT: Callers must update tools/metrics/histograms/histograms.xml
// with the following histograms:
// UMA.PersistentAllocator.name.Errors
// UMA.PersistentAllocator.name.UsedPct
void CreateTrackingHistograms(base::StringPiece name);
// Flushes the persistent memory to any backing store. This typically does
// nothing but is used by the FilePersistentMemoryAllocator to inform the
// OS that all the data should be sent to the disk immediately. This is
// useful in the rare case where something has just been stored that needs
// to survive a hard shutdown of the machine like from a power failure.
// The |sync| parameter indicates if this call should block until the flush
// is complete but is only advisory and may or may not have an effect
// depending on the capabilities of the OS. Synchronous flushes are allowed
// only from theads that are allowed to do I/O but since |sync| is only
// advisory, all flushes should be done on IO-capable threads.
void Flush(bool sync);
// Direct access to underlying memory segment. If the segment is shared
// across threads or processes, reading data through these values does
// not guarantee consistency. Use with care. Do not write.
const void* data() const { return const_cast<const char*>(mem_base_); }
size_t length() const { return mem_size_; }
size_t size() const { return mem_size_; }
size_t used() const;
// Get an object referenced by a |ref|. For safety reasons, the |type_id|
// code and size-of(|T|) are compared to ensure the reference is valid
// and cannot return an object outside of the memory segment. A |type_id| of
// kTypeIdAny (zero) will match any though the size is still checked. NULL is
// returned if any problem is detected, such as corrupted storage or incorrect
// parameters. Callers MUST check that the returned value is not-null EVERY
// TIME before accessing it or risk crashing! Once dereferenced, the pointer
// is safe to reuse forever.
//
// It is essential that the object be of a fixed size. All fields must be of
// a defined type that does not change based on the compiler or the CPU
// natural word size. Acceptable are char, float, double, and (u)intXX_t.
// Unacceptable are int, bool, and wchar_t which are implementation defined
// with regards to their size.
//
// Alignment must also be consistent. A uint64_t after a uint32_t will pad
// differently between 32 and 64 bit architectures. Either put the bigger
// elements first, group smaller elements into blocks the size of larger
// elements, or manually insert padding fields as appropriate for the
// largest architecture, including at the end.
//
// To protected against mistakes, all objects must have the attribute
// |kExpectedInstanceSize| (static constexpr size_t) that is a hard-coded
// numerical value -- NNN, not sizeof(T) -- that can be tested. If the
// instance size is not fixed, at least one build will fail.
//
// If the size of a structure changes, the type-ID used to recognize it
// should also change so later versions of the code don't try to read
// incompatible structures from earlier versions.
//
// NOTE: Though this method will guarantee that an object of the specified
// type can be accessed without going outside the bounds of the memory
// segment, it makes no guarantees of the validity of the data within the
// object itself. If it is expected that the contents of the segment could
// be compromised with malicious intent, the object must be hardened as well.
//
// Though the persistent data may be "volatile" if it is shared with
// other processes, such is not necessarily the case. The internal
// "volatile" designation is discarded so as to not propagate the viral
// nature of that keyword to the caller. It can add it back, if necessary,
// based on knowledge of how the allocator is being used.
template <typename T>
T* GetAsObject(Reference ref) {
static_assert(std::is_standard_layout<T>::value, "only standard objects");
static_assert(!std::is_array<T>::value, "use GetAsArray<>()");
static_assert(T::kExpectedInstanceSize == sizeof(T), "inconsistent size");
return const_cast<T*>(reinterpret_cast<volatile T*>(
GetBlockData(ref, T::kPersistentTypeId, sizeof(T))));
}
template <typename T>
const T* GetAsObject(Reference ref) const {
static_assert(std::is_standard_layout<T>::value, "only standard objects");
static_assert(!std::is_array<T>::value, "use GetAsArray<>()");
static_assert(T::kExpectedInstanceSize == sizeof(T), "inconsistent size");
return const_cast<const T*>(reinterpret_cast<const volatile T*>(
GetBlockData(ref, T::kPersistentTypeId, sizeof(T))));
}
// Like GetAsObject but get an array of simple, fixed-size types.
//
// Use a |count| of the required number of array elements, or kSizeAny.
// GetAllocSize() can be used to calculate the upper bound but isn't reliable
// because padding can make space for extra elements that were not written.
//
// Remember that an array of char is a string but may not be NUL terminated.
//
// There are no compile-time or run-time checks to ensure 32/64-bit size
// compatibilty when using these accessors. Only use fixed-size types such
// as char, float, double, or (u)intXX_t.
template <typename T>
T* GetAsArray(Reference ref, uint32_t type_id, size_t count) {
static_assert(std::is_fundamental<T>::value, "use GetAsObject<>()");
return const_cast<T*>(reinterpret_cast<volatile T*>(
GetBlockData(ref, type_id, count * sizeof(T))));
}
template <typename T>
const T* GetAsArray(Reference ref, uint32_t type_id, size_t count) const {
static_assert(std::is_fundamental<T>::value, "use GetAsObject<>()");
return const_cast<const char*>(reinterpret_cast<const volatile T*>(
GetBlockData(ref, type_id, count * sizeof(T))));
}
// Get the corresponding reference for an object held in persistent memory.
// If the |memory| is not valid or the type does not match, a kReferenceNull
// result will be returned.
Reference GetAsReference(const void* memory, uint32_t type_id) const;
// Get the number of bytes allocated to a block. This is useful when storing
// arrays in order to validate the ending boundary. The returned value will
// include any padding added to achieve the required alignment and so could
// be larger than given in the original Allocate() request.
size_t GetAllocSize(Reference ref) const;
// Access the internal "type" of an object. This generally isn't necessary
// but can be used to "clear" the type and so effectively mark it as deleted
// even though the memory stays valid and allocated. Changing the type is
// an atomic compare/exchange and so requires knowing the existing value.
// It will return false if the existing type is not what is expected.
//
// Changing the type doesn't mean the data is compatible with the new type.
// Passing true for |clear| will zero the memory after the type has been
// changed away from |from_type_id| but before it becomes |to_type_id| meaning
// that it is done in a manner that is thread-safe. Memory is guaranteed to
// be zeroed atomically by machine-word in a monotonically increasing order.
//
// It will likely be necessary to reconstruct the type before it can be used.
// Changing the type WILL NOT invalidate existing pointers to the data, either
// in this process or others, so changing the data structure could have
// unpredicatable results. USE WITH CARE!
uint32_t GetType(Reference ref) const;
bool ChangeType(Reference ref,
uint32_t to_type_id,
uint32_t from_type_id,
bool clear);
// Allocated objects can be added to an internal list that can then be
// iterated over by other processes. If an allocated object can be found
// another way, such as by having its reference within a different object
// that will be made iterable, then this call is not necessary. This always
// succeeds unless corruption is detected; check IsCorrupted() to find out.
// Once an object is made iterable, its position in iteration can never
// change; new iterable objects will always be added after it in the series.
// Changing the type does not alter its "iterable" status.
void MakeIterable(Reference ref);
// Get the information about the amount of free space in the allocator. The
// amount of free space should be treated as approximate due to extras from
// alignment and metadata. Concurrent allocations from other threads will
// also make the true amount less than what is reported.
void GetMemoryInfo(MemoryInfo* meminfo) const;
// If there is some indication that the memory has become corrupted,
// calling this will attempt to prevent further damage by indicating to
// all processes that something is not as expected.
void SetCorrupt() const;
// This can be called to determine if corruption has been detected in the
// segment, possibly my a malicious actor. Once detected, future allocations
// will fail and iteration may not locate all objects.
bool IsCorrupt() const;
// Flag set if an allocation has failed because the memory segment was full.
bool IsFull() const;
// Update those "tracking" histograms which do not get updates during regular
// operation, such as how much memory is currently used. This should be
// called before such information is to be displayed or uploaded.
void UpdateTrackingHistograms();
// While the above works much like malloc & free, these next methods provide
// an "object" interface similar to new and delete.
// Reserve space in the memory segment of the desired |size| and |type_id|.
// A return value of zero indicates the allocation failed, otherwise the
// returned reference can be used by any process to get a real pointer via
// the GetAsObject() or GetAsArray calls. The actual allocated size may be
// larger and will always be a multiple of 8 bytes (64 bits).
Reference Allocate(size_t size, uint32_t type_id);
// Allocate and construct an object in persistent memory. The type must have
// both (size_t) kExpectedInstanceSize and (uint32_t) kPersistentTypeId
// static constexpr fields that are used to ensure compatibility between
// software versions. An optional size parameter can be specified to force
// the allocation to be bigger than the size of the object; this is useful
// when the last field is actually variable length.
template <typename T>
T* New(size_t size) {
if (size < sizeof(T))
size = sizeof(T);
Reference ref = Allocate(size, T::kPersistentTypeId);
void* mem =
const_cast<void*>(GetBlockData(ref, T::kPersistentTypeId, size));
if (!mem)
return nullptr;
DCHECK_EQ(0U, reinterpret_cast<uintptr_t>(mem) & (alignof(T) - 1));
return new (mem) T();
}
template <typename T>
T* New() {
return New<T>(sizeof(T));
}
// Similar to New, above, but construct the object out of an existing memory
// block and of an expected type. If |clear| is true, memory will be zeroed
// before construction. Though this is not standard object behavior, it
// is present to match with new allocations that always come from zeroed
// memory. Anything previously present simply ceases to exist; no destructor
// is called for it so explicitly Delete() the old object first if need be.
// Calling this will not invalidate existing pointers to the object, either
// in this process or others, so changing the object could have unpredictable
// results. USE WITH CARE!
template <typename T>
T* New(Reference ref, uint32_t from_type_id, bool clear) {
DCHECK_LE(sizeof(T), GetAllocSize(ref)) << "alloc not big enough for obj";
// Make sure the memory is appropriate. This won't be used until after
// the type is changed but checking first avoids the possibility of having
// to change the type back.
void* mem = const_cast<void*>(GetBlockData(ref, 0, sizeof(T)));
if (!mem)
return nullptr;
// Ensure the allocator's internal alignment is sufficient for this object.
// This protects against coding errors in the allocator.
DCHECK_EQ(0U, reinterpret_cast<uintptr_t>(mem) & (alignof(T) - 1));
// Change the type, clearing the memory if so desired. The new type is
// "transitioning" so that there is no race condition with the construction
// of the object should another thread be simultaneously iterating over
// data. This will "acquire" the memory so no changes get reordered before
// it.
if (!ChangeType(ref, kTypeIdTransitioning, from_type_id, clear))
return nullptr;
// Construct an object of the desired type on this memory, just as if
// New() had been called to create it.
T* obj = new (mem) T();
// Finally change the type to the desired one. This will "release" all of
// the changes above and so provide a consistent view to other threads.
bool success =
ChangeType(ref, T::kPersistentTypeId, kTypeIdTransitioning, false);
DCHECK(success);
return obj;
}
// Deletes an object by destructing it and then changing the type to a
// different value (default 0).
template <typename T>
void Delete(T* obj, uint32_t new_type) {
// Get the reference for the object.
Reference ref = GetAsReference<T>(obj);
// First change the type to "transitioning" so there is no race condition
// where another thread could find the object through iteration while it
// is been destructed. This will "acquire" the memory so no changes get
// reordered before it. It will fail if |ref| is invalid.
if (!ChangeType(ref, kTypeIdTransitioning, T::kPersistentTypeId, false))
return;
// Destruct the object.
obj->~T();
// Finally change the type to the desired value. This will "release" all
// the changes above.
bool success = ChangeType(ref, new_type, kTypeIdTransitioning, false);
DCHECK(success);
}
template <typename T>
void Delete(T* obj) {
Delete<T>(obj, 0);
}
// As above but works with objects allocated from persistent memory.
template <typename T>
Reference GetAsReference(const T* obj) const {
return GetAsReference(obj, T::kPersistentTypeId);
}
// As above but works with an object allocated from persistent memory.
template <typename T>
void MakeIterable(const T* obj) {
MakeIterable(GetAsReference<T>(obj));
}
protected:
enum MemoryType {
MEM_EXTERNAL,
MEM_MALLOC,
MEM_VIRTUAL,
MEM_SHARED,
MEM_FILE,
};
struct Memory {
Memory(void* b, MemoryType t) : base(b), type(t) {}
void* base;
MemoryType type;
};
// Constructs the allocator. Everything is the same as the public allocator
// except |memory| which is a structure with additional information besides
// the base address.
PersistentMemoryAllocator(Memory memory, size_t size, size_t page_size,
uint64_t id, base::StringPiece name,
bool readonly);
// Implementation of Flush that accepts how much to flush.
virtual void FlushPartial(size_t length, bool sync);
volatile char* const mem_base_; // Memory base. (char so sizeof guaranteed 1)
const MemoryType mem_type_; // Type of memory allocation.
const uint32_t mem_size_; // Size of entire memory segment.
const uint32_t mem_page_; // Page size allocations shouldn't cross.
const size_t vm_page_size_; // The page size used by the OS.
private:
struct SharedMetadata;
struct BlockHeader;
static const uint32_t kAllocAlignment;
static const Reference kReferenceQueue;
// The shared metadata is always located at the top of the memory segment.
// These convenience functions eliminate constant casting of the base
// pointer within the code.
const SharedMetadata* shared_meta() const {
return reinterpret_cast<const SharedMetadata*>(
const_cast<const char*>(mem_base_));
}
SharedMetadata* shared_meta() {
return reinterpret_cast<SharedMetadata*>(const_cast<char*>(mem_base_));
}
// Actual method for doing the allocation.
Reference AllocateImpl(size_t size, uint32_t type_id);
// Get the block header associated with a specific reference.
const volatile BlockHeader* GetBlock(Reference ref, uint32_t type_id,
uint32_t size, bool queue_ok,
bool free_ok) const;
volatile BlockHeader* GetBlock(Reference ref, uint32_t type_id, uint32_t size,
bool queue_ok, bool free_ok) {
return const_cast<volatile BlockHeader*>(
const_cast<const PersistentMemoryAllocator*>(this)->GetBlock(
ref, type_id, size, queue_ok, free_ok));
}
// Get the actual data within a block associated with a specific reference.
const volatile void* GetBlockData(Reference ref, uint32_t type_id,
uint32_t size) const;
volatile void* GetBlockData(Reference ref, uint32_t type_id,
uint32_t size) {
return const_cast<volatile void*>(
const_cast<const PersistentMemoryAllocator*>(this)->GetBlockData(
ref, type_id, size));
}
// Record an error in the internal histogram.
void RecordError(int error) const;
const bool readonly_; // Indicates access to read-only memory.
mutable std::atomic<bool> corrupt_; // Local version of "corrupted" flag.
HistogramBase* allocs_histogram_; // Histogram recording allocs.
HistogramBase* used_histogram_; // Histogram recording used space.
HistogramBase* errors_histogram_; // Histogram recording errors.
friend class PersistentMemoryAllocatorTest;
FRIEND_TEST_ALL_PREFIXES(PersistentMemoryAllocatorTest, AllocateAndIterate);
DISALLOW_COPY_AND_ASSIGN(PersistentMemoryAllocator);
};
// This allocator uses a local memory block it allocates from the general
// heap. It is generally used when some kind of "death rattle" handler will
// save the contents to persistent storage during process shutdown. It is
// also useful for testing.
class BASE_EXPORT LocalPersistentMemoryAllocator
: public PersistentMemoryAllocator {
public:
LocalPersistentMemoryAllocator(size_t size, uint64_t id,
base::StringPiece name);
~LocalPersistentMemoryAllocator() override;
private:
// Allocates a block of local memory of the specified |size|, ensuring that
// the memory will not be physically allocated until accessed and will read
// as zero when that happens.
static Memory AllocateLocalMemory(size_t size);
// Deallocates a block of local |memory| of the specified |size|.
static void DeallocateLocalMemory(void* memory, size_t size, MemoryType type);
DISALLOW_COPY_AND_ASSIGN(LocalPersistentMemoryAllocator);
};
#if !defined(STARBOARD)
// This allocator takes a shared-memory object and performs allocation from
// it. The memory must be previously mapped via Map() or MapAt(). The allocator
// takes ownership of the memory object.
class BASE_EXPORT SharedPersistentMemoryAllocator
: public PersistentMemoryAllocator {
public:
SharedPersistentMemoryAllocator(std::unique_ptr<SharedMemory> memory,
uint64_t id,
base::StringPiece name,
bool read_only);
~SharedPersistentMemoryAllocator() override;
SharedMemory* shared_memory() { return shared_memory_.get(); }
// Ensure that the memory isn't so invalid that it would crash when passing it
// to the allocator. This doesn't guarantee the data is valid, just that it
// won't cause the program to abort. The existing IsCorrupt() call will handle
// the rest.
static bool IsSharedMemoryAcceptable(const SharedMemory& memory);
private:
std::unique_ptr<SharedMemory> shared_memory_;
DISALLOW_COPY_AND_ASSIGN(SharedPersistentMemoryAllocator);
};
#endif // !defined(STARBOARD)
// NACL doesn't support any kind of file access in build.
#if !defined(OS_NACL) && !defined(STARBOARD)
// This allocator takes a memory-mapped file object and performs allocation
// from it. The allocator takes ownership of the file object.
class BASE_EXPORT FilePersistentMemoryAllocator
: public PersistentMemoryAllocator {
public:
// A |max_size| of zero will use the length of the file as the maximum
// size. The |file| object must have been already created with sufficient
// permissions (read, read/write, or read/write/extend).
FilePersistentMemoryAllocator(std::unique_ptr<MemoryMappedFile> file,
size_t max_size,
uint64_t id,
base::StringPiece name,
bool read_only);
~FilePersistentMemoryAllocator() override;
// Ensure that the file isn't so invalid that it would crash when passing it
// to the allocator. This doesn't guarantee the file is valid, just that it
// won't cause the program to abort. The existing IsCorrupt() call will handle
// the rest.
static bool IsFileAcceptable(const MemoryMappedFile& file, bool read_only);
// Load all or a portion of the file into memory for fast access. This can
// be used to force the disk access to be done on a background thread and
// then have the data available to be read on the main thread with a greatly
// reduced risk of blocking due to I/O. The risk isn't eliminated completely
// because the system could always release the memory when under pressure
// but this can happen to any block of memory (i.e. swapped out).
void Cache();
protected:
// PersistentMemoryAllocator:
void FlushPartial(size_t length, bool sync) override;
private:
std::unique_ptr<MemoryMappedFile> mapped_file_;
DISALLOW_COPY_AND_ASSIGN(FilePersistentMemoryAllocator);
};
#endif // !defined(OS_NACL)
// An allocation that is defined but not executed until required at a later
// time. This allows for potential users of an allocation to be decoupled
// from the logic that defines it. In addition, there can be multiple users
// of the same allocation or any region thereof that are guaranteed to always
// use the same space. It's okay to copy/move these objects.
//
// This is a top-level class instead of an inner class of the PMA so that it
// can be forward-declared in other header files without the need to include
// the full contents of this file.
class BASE_EXPORT DelayedPersistentAllocation {
public:
using Reference = PersistentMemoryAllocator::Reference;
// Creates a delayed allocation using the specified |allocator|. When
// needed, the memory will be allocated using the specified |type| and
// |size|. If |offset| is given, the returned pointer will be at that
// offset into the segment; this allows combining allocations into a
// single persistent segment to reduce overhead and means an "all or
// nothing" request. Note that |size| is always the total memory size
// and |offset| is just indicating the start of a block within it. If
// |make_iterable| was true, the allocation will made iterable when it
// is created; already existing allocations are not changed.
//
// Once allocated, a reference to the segment will be stored at |ref|.
// This shared location must be initialized to zero (0); it is checked
// with every Get() request to see if the allocation has already been
// done. If reading |ref| outside of this object, be sure to do an
// "acquire" load. Don't write to it -- leave that to this object.
//
// For convenience, methods taking both Atomic32 and std::atomic<Reference>
// are defined.
DelayedPersistentAllocation(PersistentMemoryAllocator* allocator,
subtle::Atomic32* ref,
uint32_t type,
size_t size,
bool make_iterable);
DelayedPersistentAllocation(PersistentMemoryAllocator* allocator,
subtle::Atomic32* ref,
uint32_t type,
size_t size,
size_t offset,
bool make_iterable);
DelayedPersistentAllocation(PersistentMemoryAllocator* allocator,
std::atomic<Reference>* ref,
uint32_t type,
size_t size,
bool make_iterable);
DelayedPersistentAllocation(PersistentMemoryAllocator* allocator,
std::atomic<Reference>* ref,
uint32_t type,
size_t size,
size_t offset,
bool make_iterable);
~DelayedPersistentAllocation();
// Gets a pointer to the defined allocation. This will realize the request
// and update the reference provided during construction. The memory will
// be zeroed the first time it is returned, after that it is shared with
// all other Get() requests and so shows any changes made to it elsewhere.
//
// If the allocation fails for any reason, null will be returned. This works
// even on "const" objects because the allocation is already defined, just
// delayed.
void* Get() const;
// Gets the internal reference value. If this returns a non-zero value then
// a subsequent call to Get() will do nothing but convert that reference into
// a memory location -- useful for accessing an existing allocation without
// creating one unnecessarily.
Reference reference() const {
return reference_->load(std::memory_order_relaxed);
}
private:
// The underlying object that does the actual allocation of memory. Its
// lifetime must exceed that of all DelayedPersistentAllocation objects
// that use it.
PersistentMemoryAllocator* const allocator_;
// The desired type and size of the allocated segment plus the offset
// within it for the defined request.
const uint32_t type_;
const uint32_t size_;
const uint32_t offset_;
// Flag indicating if allocation should be made iterable when done.
const bool make_iterable_;
// The location at which a reference to the allocated segment is to be
// stored once the allocation is complete. If multiple delayed allocations
// share the same pointer then an allocation on one will amount to an
// allocation for all.
volatile std::atomic<Reference>* const reference_;
// No DISALLOW_COPY_AND_ASSIGN as it's okay to copy/move these objects.
};
} // namespace base
#endif // BASE_METRICS_PERSISTENT_MEMORY_ALLOCATOR_H_