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chromium / aosp / platform / external / libchrome / refs/heads/factory-gru-8557.B / . / base / metrics / persistent_memory_allocator.cc
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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.
#include "base/metrics/persistent_memory_allocator.h"
#include <assert.h>
#include <algorithm>
#include "base/files/memory_mapped_file.h"
#include "base/logging.h"
#include "base/memory/shared_memory.h"
#include "base/metrics/histogram_macros.h"
namespace {
// Required range of memory segment sizes. It has to fit in an unsigned 32-bit
// number and should be a power of 2 in order to accomodate almost any page
// size.
const uint32_t kSegmentMinSize = 1 << 10; // 1 KiB
const uint32_t kSegmentMaxSize = 1 << 30; // 1 GiB
// A constant (random) value placed in the shared metadata to identify
// an already initialized memory segment.
const uint32_t kGlobalCookie = 0x408305DC;
// The current version of the metadata. If updates are made that change
// the metadata, the version number can be queried to operate in a backward-
// compatible manner until the memory segment is completely re-initalized.
const uint32_t kGlobalVersion = 1;
// Constant values placed in the block headers to indicate its state.
const uint32_t kBlockCookieFree = 0;
const uint32_t kBlockCookieQueue = 1;
const uint32_t kBlockCookieWasted = (uint32_t)-1;
const uint32_t kBlockCookieAllocated = 0xC8799269;
// TODO(bcwhite): When acceptable, consider moving flags to std::atomic<char>
// types rather than combined bitfield.
// Flags stored in the flags_ field of the SharedMetaData structure below.
enum : int {
kFlagCorrupt = 1 << 0,
kFlagFull = 1 << 1
};
bool CheckFlag(const volatile std::atomic<uint32_t>* flags, int flag) {
uint32_t loaded_flags = flags->load(std::memory_order_relaxed);
return (loaded_flags & flag) != 0;
}
void SetFlag(volatile std::atomic<uint32_t>* flags, int flag) {
uint32_t loaded_flags = flags->load(std::memory_order_relaxed);
for (;;) {
uint32_t new_flags = (loaded_flags & ~flag) | flag;
// In the failue case, actual "flags" value stored in loaded_flags.
if (flags->compare_exchange_weak(loaded_flags, new_flags))
break;
}
}
} // namespace
namespace base {
// All allocations and data-structures must be aligned to this byte boundary.
// Alignment as large as the physical bus between CPU and RAM is _required_
// for some architectures, is simply more efficient on other CPUs, and
// generally a Good Idea(tm) for all platforms as it reduces/eliminates the
// chance that a type will span cache lines. Alignment mustn't be less
// than 8 to ensure proper alignment for all types. The rest is a balance
// between reducing spans across multiple cache lines and wasted space spent
// padding out allocations. An alignment of 16 would ensure that the block
// header structure always sits in a single cache line. An average of about
// 1/2 this value will be wasted with every allocation.
const uint32_t PersistentMemoryAllocator::kAllocAlignment = 8;
// The block-header is placed at the top of every allocation within the
// segment to describe the data that follows it.
struct PersistentMemoryAllocator::BlockHeader {
uint32_t size; // Number of bytes in this block, including header.
uint32_t cookie; // Constant value indicating completed allocation.
uint32_t type_id; // A number provided by caller indicating data type.
std::atomic<uint32_t> next; // Pointer to the next block when iterating.
};
// The shared metadata exists once at the top of the memory segment to
// describe the state of the allocator to all processes.
struct PersistentMemoryAllocator::SharedMetadata {
uint32_t cookie; // Some value that indicates complete initialization.
uint32_t size; // Total size of memory segment.
uint32_t page_size; // Paging size within memory segment.
uint32_t version; // Version code so upgrades don't break.
uint64_t id; // Arbitrary ID number given by creator.
uint32_t name; // Reference to stored name string.
// Above is read-only after first construction. Below may be changed and
// so must be marked "volatile" to provide correct inter-process behavior.
// Bitfield of information flags. Access to this should be done through
// the CheckFlag() and SetFlag() methods defined above.
volatile std::atomic<uint32_t> flags;
// Offset/reference to first free space in segment.
volatile std::atomic<uint32_t> freeptr;
// The "iterable" queue is an M&S Queue as described here, append-only:
// https://www.research.ibm.com/people/m/michael/podc-1996.pdf
volatile std::atomic<uint32_t> tailptr; // Last block of iteration queue.
volatile BlockHeader queue; // Empty block for linked-list head/tail.
};
// The "queue" block header is used to detect "last node" so that zero/null
// can be used to indicate that it hasn't been added at all. It is part of
// the SharedMetadata structure which itself is always located at offset zero.
const PersistentMemoryAllocator::Reference
PersistentMemoryAllocator::kReferenceQueue =
offsetof(SharedMetadata, queue);
const base::FilePath::CharType PersistentMemoryAllocator::kFileExtension[] =
FILE_PATH_LITERAL(".pma");
PersistentMemoryAllocator::Iterator::Iterator(
const PersistentMemoryAllocator* allocator)
: allocator_(allocator), last_record_(kReferenceQueue), record_count_(0) {}
PersistentMemoryAllocator::Iterator::Iterator(
const PersistentMemoryAllocator* allocator,
Reference starting_after)
: allocator_(allocator), last_record_(starting_after), record_count_(0) {
// Ensure that the starting point is a valid, iterable block (meaning it can
// be read and has a non-zero "next" pointer).
const volatile BlockHeader* block =
allocator_->GetBlock(starting_after, 0, 0, false, false);
if (!block || block->next.load(std::memory_order_relaxed) == 0) {
NOTREACHED();
last_record_.store(kReferenceQueue, std::memory_order_release);
}
}
PersistentMemoryAllocator::Reference
PersistentMemoryAllocator::Iterator::GetNext(uint32_t* type_return) {
// Make a copy of the existing count of found-records, acquiring all changes
// made to the allocator, notably "freeptr" (see comment in loop for why
// the load of that value cannot be moved above here) that occurred during
// any previous runs of this method, including those by parallel threads
// that interrupted it. It pairs with the Release at the end of this method.
//
// Otherwise, if the compiler were to arrange the two loads such that
// "count" was fetched _after_ "freeptr" then it would be possible for
// this thread to be interrupted between them and other threads perform
// multiple allocations, make-iterables, and iterations (with the included
// increment of |record_count_|) culminating in the check at the bottom
// mistakenly determining that a loop exists. Isn't this stuff fun?
uint32_t count = record_count_.load(std::memory_order_acquire);
Reference last = last_record_.load(std::memory_order_acquire);
Reference next;
while (true) {
const volatile BlockHeader* block =
allocator_->GetBlock(last, 0, 0, true, false);
if (!block) // Invalid iterator state.
return kReferenceNull;
// The compiler and CPU can freely reorder all memory accesses on which
// there are no dependencies. It could, for example, move the load of
// "freeptr" to above this point because there are no explicit dependencies
// between it and "next". If it did, however, then another block could
// be queued after that but before the following load meaning there is
// one more queued block than the future "detect loop by having more
// blocks that could fit before freeptr" will allow.
//
// By "acquiring" the "next" value here, it's synchronized to the enqueue
// of the node which in turn is synchronized to the allocation (which sets
// freeptr). Thus, the scenario above cannot happen.
next = block->next.load(std::memory_order_acquire);
if (next == kReferenceQueue) // No next allocation in queue.
return kReferenceNull;
block = allocator_->GetBlock(next, 0, 0, false, false);
if (!block) { // Memory is corrupt.
allocator_->SetCorrupt();
return kReferenceNull;
}
// Update the "last_record" pointer to be the reference being returned.
// If it fails then another thread has already iterated past it so loop
// again. Failing will also load the existing value into "last" so there
// is no need to do another such load when the while-loop restarts. A
// "strong" compare-exchange is used because failing unnecessarily would
// mean repeating some fairly costly validations above.
if (last_record_.compare_exchange_strong(last, next)) {
*type_return = block->type_id;
break;
}
}
// Memory corruption could cause a loop in the list. Such must be detected
// so as to not cause an infinite loop in the caller. This is done by simply
// making sure it doesn't iterate more times than the absolute maximum
// number of allocations that could have been made. Callers are likely
// to loop multiple times before it is detected but at least it stops.
const uint32_t freeptr = std::min(
allocator_->shared_meta()->freeptr.load(std::memory_order_relaxed),
allocator_->mem_size_);
const uint32_t max_records =
freeptr / (sizeof(BlockHeader) + kAllocAlignment);
if (count > max_records) {
allocator_->SetCorrupt();
return kReferenceNull;
}
// Increment the count and release the changes made above. It pairs with
// the Acquire at the top of this method. Note that this operation is not
// strictly synchonized with fetching of the object to return, which would
// have to be done inside the loop and is somewhat complicated to achieve.
// It does not matter if it falls behind temporarily so long as it never
// gets ahead.
record_count_.fetch_add(1, std::memory_order_release);
return next;
}
PersistentMemoryAllocator::Reference
PersistentMemoryAllocator::Iterator::GetNextOfType(uint32_t type_match) {
Reference ref;
uint32_t type_found;
while ((ref = GetNext(&type_found)) != 0) {
if (type_found == type_match)
return ref;
}
return kReferenceNull;
}
// static
bool PersistentMemoryAllocator::IsMemoryAcceptable(const void* base,
size_t size,
size_t page_size,
bool readonly) {
return ((base && reinterpret_cast<uintptr_t>(base) % kAllocAlignment == 0) &&
(size >= sizeof(SharedMetadata) && size <= kSegmentMaxSize) &&
(size >= kSegmentMinSize || readonly) &&
(size % kAllocAlignment == 0 || readonly) &&
(page_size == 0 || size % page_size == 0 || readonly));
}
PersistentMemoryAllocator::PersistentMemoryAllocator(
void* base,
size_t size,
size_t page_size,
uint64_t id,
base::StringPiece name,
bool readonly)
: mem_base_(static_cast<char*>(base)),
mem_size_(static_cast<uint32_t>(size)),
mem_page_(static_cast<uint32_t>((page_size ? page_size : size))),
readonly_(readonly),
corrupt_(0),
allocs_histogram_(nullptr),
used_histogram_(nullptr) {
static_assert(sizeof(BlockHeader) % kAllocAlignment == 0,
"BlockHeader is not a multiple of kAllocAlignment");
static_assert(sizeof(SharedMetadata) % kAllocAlignment == 0,
"SharedMetadata is not a multiple of kAllocAlignment");
static_assert(kReferenceQueue % kAllocAlignment == 0,
"\"queue\" is not aligned properly; must be at end of struct");
// Ensure that memory segment is of acceptable size.
CHECK(IsMemoryAcceptable(base, size, page_size, readonly));
// These atomics operate inter-process and so must be lock-free. The local
// casts are to make sure it can be evaluated at compile time to a constant.
CHECK(((SharedMetadata*)0)->freeptr.is_lock_free());
CHECK(((SharedMetadata*)0)->flags.is_lock_free());
CHECK(((BlockHeader*)0)->next.is_lock_free());
CHECK(corrupt_.is_lock_free());
if (shared_meta()->cookie != kGlobalCookie) {
if (readonly) {
SetCorrupt();
return;
}
// This block is only executed when a completely new memory segment is
// being initialized. It's unshared and single-threaded...
volatile BlockHeader* const first_block =
reinterpret_cast<volatile BlockHeader*>(mem_base_ +
sizeof(SharedMetadata));
if (shared_meta()->cookie != 0 ||
shared_meta()->size != 0 ||
shared_meta()->version != 0 ||
shared_meta()->freeptr.load(std::memory_order_relaxed) != 0 ||
shared_meta()->flags.load(std::memory_order_relaxed) != 0 ||
shared_meta()->id != 0 ||
shared_meta()->name != 0 ||
shared_meta()->tailptr != 0 ||
shared_meta()->queue.cookie != 0 ||
shared_meta()->queue.next.load(std::memory_order_relaxed) != 0 ||
first_block->size != 0 ||
first_block->cookie != 0 ||
first_block->type_id != 0 ||
first_block->next != 0) {
// ...or something malicious has been playing with the metadata.
NOTREACHED();
SetCorrupt();
}
// This is still safe to do even if corruption has been detected.
shared_meta()->cookie = kGlobalCookie;
shared_meta()->size = mem_size_;
shared_meta()->page_size = mem_page_;
shared_meta()->version = kGlobalVersion;
shared_meta()->id = id;
shared_meta()->freeptr.store(sizeof(SharedMetadata),
std::memory_order_release);
// Set up the queue of iterable allocations.
shared_meta()->queue.size = sizeof(BlockHeader);
shared_meta()->queue.cookie = kBlockCookieQueue;
shared_meta()->queue.next.store(kReferenceQueue, std::memory_order_release);
shared_meta()->tailptr.store(kReferenceQueue, std::memory_order_release);
// Allocate space for the name so other processes can learn it.
if (!name.empty()) {
const size_t name_length = name.length() + 1;
shared_meta()->name = Allocate(name_length, 0);
char* name_cstr = GetAsObject<char>(shared_meta()->name, 0);
if (name_cstr)
memcpy(name_cstr, name.data(), name.length());
}
} else {
if (shared_meta()->size == 0 ||
shared_meta()->version == 0 ||
shared_meta()->freeptr.load(std::memory_order_relaxed) == 0 ||
shared_meta()->tailptr == 0 ||
shared_meta()->queue.cookie == 0 ||
shared_meta()->queue.next.load(std::memory_order_relaxed) == 0) {
SetCorrupt();
}
if (!readonly) {
// The allocator is attaching to a previously initialized segment of
// memory. Make sure the embedded data matches what has been passed.
if (shared_meta()->size != mem_size_ ||
shared_meta()->page_size != mem_page_) {
NOTREACHED();
SetCorrupt();
}
}
}
}
PersistentMemoryAllocator::~PersistentMemoryAllocator() {
// It's strictly forbidden to do any memory access here in case there is
// some issue with the underlying memory segment. The "Local" allocator
// makes use of this to allow deletion of the segment on the heap from
// within its destructor.
}
uint64_t PersistentMemoryAllocator::Id() const {
return shared_meta()->id;
}
const char* PersistentMemoryAllocator::Name() const {
Reference name_ref = shared_meta()->name;
const char* name_cstr = GetAsObject<char>(name_ref, 0);
if (!name_cstr)
return "";
size_t name_length = GetAllocSize(name_ref);
if (name_cstr[name_length - 1] != '\0') {
NOTREACHED();
SetCorrupt();
return "";
}
return name_cstr;
}
void PersistentMemoryAllocator::CreateTrackingHistograms(
base::StringPiece name) {
if (name.empty() || readonly_)
return;
std::string name_string = name.as_string();
DCHECK(!used_histogram_);
used_histogram_ = LinearHistogram::FactoryGet(
"UMA.PersistentAllocator." + name_string + ".UsedPct", 1, 101, 21,
HistogramBase::kUmaTargetedHistogramFlag);
DCHECK(!allocs_histogram_);
allocs_histogram_ = Histogram::FactoryGet(
"UMA.PersistentAllocator." + name_string + ".Allocs", 1, 10000, 50,
HistogramBase::kUmaTargetedHistogramFlag);
}
size_t PersistentMemoryAllocator::used() const {
return std::min(shared_meta()->freeptr.load(std::memory_order_relaxed),
mem_size_);
}
size_t PersistentMemoryAllocator::GetAllocSize(Reference ref) const {
const volatile BlockHeader* const block = GetBlock(ref, 0, 0, false, false);
if (!block)
return 0;
uint32_t size = block->size;
// Header was verified by GetBlock() but a malicious actor could change
// the value between there and here. Check it again.
if (size <= sizeof(BlockHeader) || ref + size > mem_size_) {
SetCorrupt();
return 0;
}
return size - sizeof(BlockHeader);
}
uint32_t PersistentMemoryAllocator::GetType(Reference ref) const {
const volatile BlockHeader* const block = GetBlock(ref, 0, 0, false, false);
if (!block)
return 0;
return block->type_id;
}
void PersistentMemoryAllocator::SetType(Reference ref, uint32_t type_id) {
DCHECK(!readonly_);
volatile BlockHeader* const block = GetBlock(ref, 0, 0, false, false);
if (!block)
return;
block->type_id = type_id;
}
PersistentMemoryAllocator::Reference PersistentMemoryAllocator::Allocate(
size_t req_size,
uint32_t type_id) {
Reference ref = AllocateImpl(req_size, type_id);
if (ref) {
// Success: Record this allocation in usage stats (if active).
if (allocs_histogram_)
allocs_histogram_->Add(static_cast<HistogramBase::Sample>(req_size));
} else {
// Failure: Record an allocation of zero for tracking.
if (allocs_histogram_)
allocs_histogram_->Add(0);
}
return ref;
}
PersistentMemoryAllocator::Reference PersistentMemoryAllocator::AllocateImpl(
size_t req_size,
uint32_t type_id) {
DCHECK(!readonly_);
// Validate req_size to ensure it won't overflow when used as 32-bit value.
if (req_size > kSegmentMaxSize - sizeof(BlockHeader)) {
NOTREACHED();
return kReferenceNull;
}
// Round up the requested size, plus header, to the next allocation alignment.
uint32_t size = static_cast<uint32_t>(req_size + sizeof(BlockHeader));
size = (size + (kAllocAlignment - 1)) & ~(kAllocAlignment - 1);
if (size <= sizeof(BlockHeader) || size > mem_page_) {
NOTREACHED();
return kReferenceNull;
}
// Get the current start of unallocated memory. Other threads may
// update this at any time and cause us to retry these operations.
// This value should be treated as "const" to avoid confusion through
// the code below but recognize that any failed compare-exchange operation
// involving it will cause it to be loaded with a more recent value. The
// code should either exit or restart the loop in that case.
/* const */ uint32_t freeptr =
shared_meta()->freeptr.load(std::memory_order_acquire);
// Allocation is lockless so we do all our caculation and then, if saving
// indicates a change has occurred since we started, scrap everything and
// start over.
for (;;) {
if (IsCorrupt())
return kReferenceNull;
if (freeptr + size > mem_size_) {
SetFlag(&shared_meta()->flags, kFlagFull);
return kReferenceNull;
}
// Get pointer to the "free" block. If something has been allocated since
// the load of freeptr above, it is still safe as nothing will be written
// to that location until after the compare-exchange below.
volatile BlockHeader* const block = GetBlock(freeptr, 0, 0, false, true);
if (!block) {
SetCorrupt();
return kReferenceNull;
}
// An allocation cannot cross page boundaries. If it would, create a
// "wasted" block and begin again at the top of the next page. This
// area could just be left empty but we fill in the block header just
// for completeness sake.
const uint32_t page_free = mem_page_ - freeptr % mem_page_;
if (size > page_free) {
if (page_free <= sizeof(BlockHeader)) {
SetCorrupt();
return kReferenceNull;
}
const uint32_t new_freeptr = freeptr + page_free;
if (shared_meta()->freeptr.compare_exchange_strong(freeptr,
new_freeptr)) {
block->size = page_free;
block->cookie = kBlockCookieWasted;
}
continue;
}
// Don't leave a slice at the end of a page too small for anything. This
// can result in an allocation up to two alignment-sizes greater than the
// minimum required by requested-size + header + alignment.
if (page_free - size < sizeof(BlockHeader) + kAllocAlignment)
size = page_free;
const uint32_t new_freeptr = freeptr + size;
if (new_freeptr > mem_size_) {
SetCorrupt();
return kReferenceNull;
}
// Save our work. Try again if another thread has completed an allocation
// while we were processing. A "weak" exchange would be permissable here
// because the code will just loop and try again but the above processing
// is significant so make the extra effort of a "strong" exchange.
if (!shared_meta()->freeptr.compare_exchange_strong(freeptr, new_freeptr))
continue;
// Given that all memory was zeroed before ever being given to an instance
// of this class and given that we only allocate in a monotomic fashion
// going forward, it must be that the newly allocated block is completely
// full of zeros. If we find anything in the block header that is NOT a
// zero then something must have previously run amuck through memory,
// writing beyond the allocated space and into unallocated space.
if (block->size != 0 ||
block->cookie != kBlockCookieFree ||
block->type_id != 0 ||
block->next.load(std::memory_order_relaxed) != 0) {
SetCorrupt();
return kReferenceNull;
}
block->size = size;
block->cookie = kBlockCookieAllocated;
block->type_id = type_id;
return freeptr;
}
}
void PersistentMemoryAllocator::GetMemoryInfo(MemoryInfo* meminfo) const {
uint32_t remaining = std::max(
mem_size_ - shared_meta()->freeptr.load(std::memory_order_relaxed),
(uint32_t)sizeof(BlockHeader));
meminfo->total = mem_size_;
meminfo->free = IsCorrupt() ? 0 : remaining - sizeof(BlockHeader);
}
void PersistentMemoryAllocator::MakeIterable(Reference ref) {
DCHECK(!readonly_);
if (IsCorrupt())
return;
volatile BlockHeader* block = GetBlock(ref, 0, 0, false, false);
if (!block) // invalid reference
return;
if (block->next.load(std::memory_order_acquire) != 0) // Already iterable.
return;
block->next.store(kReferenceQueue, std::memory_order_release); // New tail.
// Try to add this block to the tail of the queue. May take multiple tries.
// If so, tail will be automatically updated with a more recent value during
// compare-exchange operations.
uint32_t tail = shared_meta()->tailptr.load(std::memory_order_acquire);
for (;;) {
// Acquire the current tail-pointer released by previous call to this
// method and validate it.
block = GetBlock(tail, 0, 0, true, false);
if (!block) {
SetCorrupt();
return;
}
// Try to insert the block at the tail of the queue. The tail node always
// has an existing value of kReferenceQueue; if that is somehow not the
// existing value then another thread has acted in the meantime. A "strong"
// exchange is necessary so the "else" block does not get executed when
// that is not actually the case (which can happen with a "weak" exchange).
uint32_t next = kReferenceQueue; // Will get replaced with existing value.
if (block->next.compare_exchange_strong(next, ref,
std::memory_order_acq_rel,
std::memory_order_acquire)) {
// Update the tail pointer to the new offset. If the "else" clause did
// not exist, then this could be a simple Release_Store to set the new
// value but because it does, it's possible that other threads could add
// one or more nodes at the tail before reaching this point. We don't
// have to check the return value because it either operates correctly
// or the exact same operation has already been done (by the "else"
// clause) on some other thread.
shared_meta()->tailptr.compare_exchange_strong(tail, ref,
std::memory_order_release,
std::memory_order_relaxed);
return;
} else {
// In the unlikely case that a thread crashed or was killed between the
// update of "next" and the update of "tailptr", it is necessary to
// perform the operation that would have been done. There's no explicit
// check for crash/kill which means that this operation may also happen
// even when the other thread is in perfect working order which is what
// necessitates the CompareAndSwap above.
shared_meta()->tailptr.compare_exchange_strong(tail, next,
std::memory_order_acq_rel,
std::memory_order_acquire);
}
}
}
// The "corrupted" state is held both locally and globally (shared). The
// shared flag can't be trusted since a malicious actor could overwrite it.
// Because corruption can be detected during read-only operations such as
// iteration, this method may be called by other "const" methods. In this
// case, it's safe to discard the constness and modify the local flag and
// maybe even the shared flag if the underlying data isn't actually read-only.
void PersistentMemoryAllocator::SetCorrupt() const {
LOG(ERROR) << "Corruption detected in shared-memory segment.";
const_cast<std::atomic<bool>*>(&corrupt_)->store(true,
std::memory_order_relaxed);
if (!readonly_) {
SetFlag(const_cast<volatile std::atomic<uint32_t>*>(&shared_meta()->flags),
kFlagCorrupt);
}
}
bool PersistentMemoryAllocator::IsCorrupt() const {
if (corrupt_.load(std::memory_order_relaxed) ||
CheckFlag(&shared_meta()->flags, kFlagCorrupt)) {
SetCorrupt(); // Make sure all indicators are set.
return true;
}
return false;
}
bool PersistentMemoryAllocator::IsFull() const {
return CheckFlag(&shared_meta()->flags, kFlagFull);
}
// Dereference a block |ref| and ensure that it's valid for the desired
// |type_id| and |size|. |special| indicates that we may try to access block
// headers not available to callers but still accessed by this module. By
// having internal dereferences go through this same function, the allocator
// is hardened against corruption.
const volatile PersistentMemoryAllocator::BlockHeader*
PersistentMemoryAllocator::GetBlock(Reference ref, uint32_t type_id,
uint32_t size, bool queue_ok,
bool free_ok) const {
// Validation of parameters.
if (ref % kAllocAlignment != 0)
return nullptr;
if (ref < (queue_ok ? kReferenceQueue : sizeof(SharedMetadata)))
return nullptr;
size += sizeof(BlockHeader);
if (ref + size > mem_size_)
return nullptr;
// Validation of referenced block-header.
if (!free_ok) {
uint32_t freeptr = std::min(
shared_meta()->freeptr.load(std::memory_order_relaxed), mem_size_);
if (ref + size > freeptr)
return nullptr;
const volatile BlockHeader* const block =
reinterpret_cast<volatile BlockHeader*>(mem_base_ + ref);
if (block->size < size)
return nullptr;
if (ref + block->size > freeptr)
return nullptr;
if (ref != kReferenceQueue && block->cookie != kBlockCookieAllocated)
return nullptr;
if (type_id != 0 && block->type_id != type_id)
return nullptr;
}
// Return pointer to block data.
return reinterpret_cast<const volatile BlockHeader*>(mem_base_ + ref);
}
const volatile void* PersistentMemoryAllocator::GetBlockData(
Reference ref,
uint32_t type_id,
uint32_t size) const {
DCHECK(size > 0);
const volatile BlockHeader* block =
GetBlock(ref, type_id, size, false, false);
if (!block)
return nullptr;
return reinterpret_cast<const volatile char*>(block) + sizeof(BlockHeader);
}
void PersistentMemoryAllocator::UpdateTrackingHistograms() {
DCHECK(!readonly_);
if (used_histogram_) {
MemoryInfo meminfo;
GetMemoryInfo(&meminfo);
HistogramBase::Sample used_percent = static_cast<HistogramBase::Sample>(
((meminfo.total - meminfo.free) * 100ULL / meminfo.total));
used_histogram_->Add(used_percent);
}
}
//----- LocalPersistentMemoryAllocator -----------------------------------------
LocalPersistentMemoryAllocator::LocalPersistentMemoryAllocator(
size_t size,
uint64_t id,
base::StringPiece name)
: PersistentMemoryAllocator(memset(new char[size], 0, size),
size, 0, id, name, false) {}
LocalPersistentMemoryAllocator::~LocalPersistentMemoryAllocator() {
delete [] mem_base_;
}
//----- SharedPersistentMemoryAllocator ----------------------------------------
SharedPersistentMemoryAllocator::SharedPersistentMemoryAllocator(
std::unique_ptr<SharedMemory> memory,
uint64_t id,
base::StringPiece name,
bool read_only)
: PersistentMemoryAllocator(static_cast<uint8_t*>(memory->memory()),
memory->mapped_size(),
0,
id,
name,
read_only),
shared_memory_(std::move(memory)) {}
SharedPersistentMemoryAllocator::~SharedPersistentMemoryAllocator() {}
// static
bool SharedPersistentMemoryAllocator::IsSharedMemoryAcceptable(
const SharedMemory& memory) {
return IsMemoryAcceptable(memory.memory(), memory.mapped_size(), 0, true);
}
//----- FilePersistentMemoryAllocator ------------------------------------------
FilePersistentMemoryAllocator::FilePersistentMemoryAllocator(
std::unique_ptr<MemoryMappedFile> file,
uint64_t id,
base::StringPiece name)
: PersistentMemoryAllocator(const_cast<uint8_t*>(file->data()),
file->length(),
0,
id,
name,
true),
mapped_file_(std::move(file)) {}
FilePersistentMemoryAllocator::~FilePersistentMemoryAllocator() {}
// static
bool FilePersistentMemoryAllocator::IsFileAcceptable(
const MemoryMappedFile& file) {
return IsMemoryAcceptable(file.data(), file.length(), 0, true);
}
} // namespace base