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deferred_heap.h
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deferred_heap.h
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///////////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2016 Herb Sutter. All rights reserved.
//
// This code is licensed under the MIT License (MIT).
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
//
///////////////////////////////////////////////////////////////////////////////
#ifndef GCPP_DEFERRED_HEAP
#define GCPP_DEFERRED_HEAP
#include "gpage.h"
#include <vector>
#include <list>
#include <utility>
#include <unordered_set>
#include <algorithm>
#include <type_traits>
#include <memory>
namespace gcpp {
template<class T> class deferred_ptr;
// Copy and remove elements that satisfy pred from [first, last) into out.
template<class BidirectionalIterator, class OutputIterator, class Predicate>
std::pair<BidirectionalIterator, OutputIterator>
unstable_remove_copy_if(BidirectionalIterator first, BidirectionalIterator last,
OutputIterator out, Predicate pred)
{
for (;;) {
first = std::find_if(first, last, pred);
if (first == last) {
break;
}
// *first satisfies pred. Move it out of the sequence...
*out++ = std::move(*first);
// ...and replace with the last element of the sequence.
if (first == --last) {
break;
}
*first = std::move(*last);
}
return {first, out};
}
// destructor contains a pointer and type-correct-but-erased dtor call.
// (Happily, a noncapturing lambda decays to a function pointer, which
// will make these both easy to construct and cheap to store without
// resorting to the usual type-erasure machinery.)
//
class destructors {
struct destructor {
const void* p;
void(*destroy)(const void*);
};
std::vector<destructor> dtors;
public:
// Store the destructor, if it's not trivial
//
template<class T>
void store(gsl::span<T> p) {
Expects(p.size() > 0
&& "no object to register for destruction");
if (!std::is_trivially_destructible<T>::value) {
// For now we'll just store individual dtors even for arrays.
// Future: To represent destructors for arrays more compactly,
// have an array_destructor type as well with a count and size,
// and when storing a new destructor check if it's immediately
// after the end of an existing array destructor and if so just
// ++count, similarly when removing a destructor from the end,
// or break apart an array_destructor when removing a
// destructor from the middle
for (auto& t : p) {
dtors.push_back({
std::addressof(t), // address
[](const void* x) { static_cast<const T*>(x)->~T(); }
}); // dtor to invoke
}
}
}
// Inquire whether there is a destructor registered for p
//
template<class T>
bool is_stored(gsl::not_null<T*> p) const noexcept {
return std::is_trivially_destructible<T>::value
|| std::any_of(dtors.begin(), dtors.end(),
[=](auto x) { return x.p == p.get(); });
}
// Run all the destructors and clear the list
//
void run_all() {
for (auto& d : dtors) {
d.destroy(d.p); // call object's destructor
}
dtors.clear();
}
// Run all the destructors for objects in [begin,end)
//
bool run(gsl::span<byte> range) {
if (range.size() == 0)
return false;
// for reentrancy safety, we'll take a local copy of destructors to be run
//
// move any destructors for objects in this range to a local list...
//
struct cleanup_t {
std::vector<destructor> to_destroy;
// ensure the locally saved destructors are run even if an exception is thrown
~cleanup_t() {
for (auto& d : to_destroy) {
// =====================================================================
// === BEGIN REENTRANCY-SAFE: ensure no in-progress use of private state
d.destroy(d.p); // call object's destructor
// === END REENTRANCY-SAFE: reload any stored copies of private state
// =====================================================================
}
}
} cleanup;
auto const lo = &*range.begin(), hi = lo + range.size();
auto it = unstable_remove_copy_if(
dtors.begin(), dtors.end(), std::back_inserter(cleanup.to_destroy),
[=](destructor const& dtor) { return lo <= dtor.p && dtor.p < hi; }).first;
dtors.erase(it, dtors.end());
return !cleanup.to_destroy.empty();
}
void debug_print() const;
};
//----------------------------------------------------------------------------
//
// The deferred heap produces deferred_ptr<T>s via make<T>.
//
//----------------------------------------------------------------------------
class deferred_heap {
class deferred_ptr_void;
friend class deferred_ptr_void;
template<class T> friend class deferred_ptr;
template<class T> friend class deferred_allocator;
// Disable copy and move
deferred_heap(deferred_heap&) = delete;
void operator=(deferred_heap&) = delete;
// Add/remove a deferred_ptr in the tracking list.
// Invoked when constructing and destroying a deferred_ptr.
void enregister(const deferred_ptr_void& p);
void deregister(const deferred_ptr_void& p);
//------------------------------------------------------------------------
//
// deferred_ptr_void is the generic pointer type we use and track
// internally. The user uses deferred_ptr<T>, the type-casting wrapper.
//
// There are two main states:
//
// - unattached, myheap == nullptr
// this pointer is not yet attached to a heap, and p must be null
//
// - attached, myheap != nullptr
// this pointer is attached to myheap and must not be repointed to a
// different heap (assignment from a pointer into a different heap is
// not allowed)
//
// The pointer becomes attached when it is first constructed or assigned with
// a non-null page pointer (incl. when copied from an attached pointer). The
// pointer becomes unattached when the heap it was attached to is destroyed.
//
class deferred_ptr_void {
// There are other ways to implement this, including to make deferred_ptr
// be the same size as an ordinary pointer and trivially copyable; one
// alternative implementation checked in earlier did that.
//
// For right now, I think it's easier to present the key ideas initially
// with fewer distractions by just keeping a back pointer to the heap.
// The two reasons are to enable debug checks to prevent cross-assignment
// from multiple heaps, and to know where to deregister. Other ways to
// do the same include having statically tagged heaps, such as having
// deferred_heap<MyHeapTag> give deferred_ptr<T, MyHeapTag>s and
// just statically prevent cross-assignment and statically identify the
// heaps, which lets you have trivially copyable deferred_ptrs and no
// run-time overhead for deferred_ptr space and assignment. I felt that
// explaining static heap tagging would be a distraction in the initial
// presentation from the central concepts that are actually important.
deferred_heap* myheap;
void* p;
friend deferred_heap;
protected:
void set(void* p_) noexcept { p = p_; }
deferred_ptr_void(deferred_heap* heap = nullptr, void* p_ = nullptr)
: myheap{ heap }
, p{ p_ }
{
// Allow null pointers, we'll set the page on the first assignment
Expects((p == nullptr || myheap != nullptr) && "heap cannot be null for a non-null pointer");
if (myheap != nullptr) {
myheap->enregister(*this);
}
}
~deferred_ptr_void() {
if (myheap != nullptr) {
myheap->deregister(*this);
}
}
deferred_ptr_void(const deferred_ptr_void& that)
: deferred_ptr_void(that.myheap, that.p)
{ }
deferred_ptr_void& operator=(const deferred_ptr_void& that) noexcept {
// Allow assignment from an unattached null pointer
if (that.myheap == nullptr) {
Expects(that.p == nullptr && "unattached deferred_ptr must be null");
reset(); // just to keep the nulling logic in one place
}
// Otherwise, we must be unattached or pointing into the same heap
else {
Expects((myheap == nullptr || myheap == that.myheap)
&& "cannot assign deferred_ptrs into different deferred_heaps");
p = that.p;
if (myheap == nullptr) {
that.myheap->enregister(*this); // perform lazy attach
myheap = that.myheap;
}
}
return *this;
}
// detach is called from ~deferred_heap() when the heap is destroyed
// before this pointer is destroyed
//
void detach() noexcept {
p = nullptr;
myheap = nullptr;
}
public:
deferred_heap* get_heap() const noexcept { return myheap; }
void* get() const noexcept { return p; }
void reset() noexcept { p = nullptr; /* leave myheap alone so we can assign again */ }
};
// For non-roots (deferred_ptrs that are in the deferred heap), we'll additionally
// store an int that we'll use for terminating marking within the deferred heap.
// The level is the distance from some root -- not necessarily the smallest
// distance from a root, just along whatever path we took during marking.
//
struct nonroot {
const deferred_ptr_void* p;
std::size_t level = 0;
nonroot(const deferred_ptr_void* p_) noexcept : p{ p_ } { }
};
struct dhpage {
gpage page;
bitflags live_starts; // for tracing
std::vector<nonroot> deferred_ptrs; // known deferred_ptrs in this page
deferred_heap* myheap;
// Construct a page tuned to hold Hint objects, big enough for
// at least 1 + phi ~= 2.62 of these requests (but at least 8K),
// and a tracking min_alloc chunk sizeof(request) (but at least 4 bytes).
// Note: Hint used only to deduce total size and tracking granularity.
// Future: Don't allocate objects on pages with chunk sizes > 2 * object size
//
template<class Hint>
dhpage(const Hint* /*--*/, size_t n, deferred_heap* heap)
: page{ std::max<size_t>(sizeof(Hint) * n * 3, 8192 /*good general default*/),
std::max<size_t>(sizeof(Hint), 4) }
, live_starts{ page.locations(), false }
, myheap{ heap }
{ }
};
//------------------------------------------------------------------------
// Data: Storage and tracking information
//
std::list<dhpage> pages;
std::unordered_set<const deferred_ptr_void*> roots; // outside deferred heap
destructors dtors;
bool is_destroying = false;
bool collect_before_expand = false; // Future: pull this into an options struct
public:
//------------------------------------------------------------------------
//
// Construct and destroy
//
deferred_heap() = default;
~deferred_heap();
//------------------------------------------------------------------------
//
// make: Allocate one object of type T initialized with args
//
// If allocation fails, the returned pointer will be null
//
template<class T, class ...Args>
deferred_ptr<T> make(Args&&... args) {
auto p = allocate<T>();
if (p != nullptr) {
construct<T>(p.get(), std::forward<Args>(args)...);
}
return p;
}
//------------------------------------------------------------------------
//
// make_array: Allocate n default-constructed objects of type T
//
// If allocation fails, the returned pointer will be null
//
template<class T>
deferred_ptr<T> make_array(std::size_t n) {
auto p = allocate<T>(n);
if (p != nullptr) {
construct_array<T>(p.get(), n);
}
return p;
}
private:
//------------------------------------------------------------------------
//
// Core allocator functions: allocate, construct, destroy
// (not deallocate, which is done at collection time)
//
// There are private, for use via deferred_allocator only
// Helper: Return the dhpage on which this object exists.
// If the object is not in our storage, returns null.
//
template<class T>
dhpage* find_dhpage_of(T* p) noexcept;
struct find_dhpage_info_ret {
dhpage* page = nullptr;
gpage::contains_info_ret info;
};
template<class T>
find_dhpage_info_ret find_dhpage_info(T* p) noexcept;
template<class T>
std::pair<dhpage*, byte*> allocate_from_existing_pages(int n);
template<class T>
deferred_ptr<T> allocate(int n = 1);
template<class T, class ...Args>
void construct(gsl::not_null<T*> p, Args&& ...args);
template<class T>
void construct_array(gsl::not_null<T*> p, int n);
template<class T>
void destroy(gsl::not_null<T*> p) noexcept;
bool destroy_objects(gsl::span<byte> range);
//------------------------------------------------------------------------
//
// collect, et al.: Sweep the deferred heap
//
void mark(const deferred_ptr_void& p, std::size_t level) noexcept;
public:
void collect();
auto get_collect_before_expand() {
return collect_before_expand;
}
void set_collect_before_expand(bool enable = false) {
collect_before_expand = enable;
}
void debug_print() const;
};
//------------------------------------------------------------------------
//
// deferred_ptr<T> is the typed pointer type for callers to use.
//
//------------------------------------------------------------------------
//
template<class T>
class deferred_ptr : public deferred_heap::deferred_ptr_void {
deferred_ptr(deferred_heap* heap, T* p)
: deferred_ptr_void{ heap, p }
{ }
friend deferred_heap;
template<class U>
friend class deferred_ptr;
public:
// iterator traits
using value_type = T;
using pointer = deferred_ptr<value_type>;
using reference = std::add_lvalue_reference_t<T>;
using difference_type = ptrdiff_t;
using iterator_category = std::random_access_iterator_tag;
// Default and null construction. (Note we do not use a defaulted
// T* parameter, so that the T* overload can be private and the
// nullptr overload can be public.)
//
deferred_ptr() = default;
// Construction and assignment from null. Note: The null constructor
// is not defined as a combination default constructor in the usual
// way (that is, as constructor from T* with a default null argument)
// because general construction from T* is private.
//
deferred_ptr(std::nullptr_t) : deferred_ptr{} { }
deferred_ptr& operator=(std::nullptr_t) noexcept {
reset();
return *this;
}
// Copying.
//
deferred_ptr(const deferred_ptr& that)
: deferred_ptr_void(that)
{ }
deferred_ptr& operator=(const deferred_ptr& that) noexcept = default; // trivial copy assignment
// Copying with conversions (base -> derived, non-const -> const).
//
template<class U, class = typename std::enable_if<std::is_convertible<U*, T*>::value, void>::type>
deferred_ptr(const deferred_ptr<U>& that)
: deferred_ptr_void(that)
{ }
template<class U, class = typename std::enable_if<std::is_convertible<U*, T*>::value, void>::type>
deferred_ptr& operator=(const deferred_ptr<U>& that) noexcept {
deferred_ptr_void::operator=(that);
return *this;
}
// Aliasing conversion: Type-safely forming a pointer to data member of T of type U.
// Thanks to Casey Carter and Jon Caves for helping get this incantation right.
//
template<class U> struct id { using type = U; }; // this is just to turn off
template<class U> using id_t = typename id<U>::type; // type deduction for TT and ...
template<class U, class TT = T> // .. TT itself is a workaround for that we can't just
deferred_ptr<U> ptr_to(U id_t<TT>::*pU) { // write T:: here because <<C++ arcana>>
Expects(get_heap() && get() && "can't ptr_to on an unattached or null pointer");
return{ get_heap(), &(get()->*pU) };
}
// Accessors.
//
T* get() const noexcept {
return (T*)deferred_ptr_void::get();
}
explicit operator bool() const { return deferred_ptr_void::get() != nullptr; }
std::add_lvalue_reference_t<T> operator*() const noexcept {
// This contract is currently disabled because MSVC's std::vector
// implementation relies on being able to innocuously dereference
// any pointer (even null) briefly just to take the pointee's
// address again, to un-fancy "fancy" pointers like this one
// (The next VS "15" Preview has a fix & we can re-enable this.)
//Expects(get() && "attempt to dereference null");
return *get();
}
T* operator->() const noexcept {
Expects(get() && "attempt to dereference null");
return get();
}
template<class U>
static deferred_ptr<U> pointer_to(U& u) {
return deferred_ptr<U>(&u);
}
int compare3(const deferred_ptr& that) const { return get() < that.get() ? -1 : get() == that.get() ? 0 : 1; };
GCPP_TOTALLY_ORDERED_COMPARISON(deferred_ptr); // maybe someday this will be default
// Checked pointer arithmetic
//
// Future: This is checked in debug mode, but it might be better to split off
// arithmetic into a separate array_deferred_ptr or deferred_span or suchlike
// type. For now it's on deferred_ptr itself because when you instantiate
// vector<T, deferred_allocator<T>> you need a pointer type that works as a
// random-access iterator, and if we split this into an array_deferred_ptr type
// we'll also need to make deferred_allocator use that instead... that can wait.
//
deferred_ptr& operator+=(int offset) noexcept {
#ifndef NDEBUG
Expects(get() != nullptr
&& "bad deferred_ptr arithmetic: can't perform arithmetic on a null pointer");
auto this_info = get_heap()->find_dhpage_info(get());
Expects(this_info.page != nullptr
&& "corrupt non-null deferred_ptr, not pointing into deferred heap");
Expects(this_info.info.found > gpage::in_range_unallocated
&& "corrupt non-null deferred_ptr, pointing to unallocated memory");
auto temp = get() + offset;
auto temp_info = get_heap()->find_dhpage_info(temp);
Expects(this_info.page == temp_info.page
&& "bad deferred_ptr arithmetic: attempt to leave dhpage");
Expects(
// if this points to the start of an allocation, it's always legal
// to form a pointer to the following element (just don't deref it)
// which covers one-past-the-end of single-element allocations
( (
this_info.info.found == gpage::in_range_allocated_start
&& (offset == -1 || offset == 0 || offset == 1)
)
// otherwise this and temp must point into the same allocation
// which is covered for arrays by the extra byte we allocated
|| (
this_info.info.start_location == temp_info.info.start_location
&& temp_info.info.found > gpage::in_range_unallocated)
)
&& "bad deferred_ptr arithmetic: attempt to go outside the allocation");
#endif
set(get() + offset);
return *this;
}
deferred_ptr& operator-=(int offset) noexcept {
return operator+=(-offset);
}
deferred_ptr& operator++() noexcept {
return operator+=(1);
}
deferred_ptr& operator++(int) noexcept {
return operator+=(1);
}
deferred_ptr& operator--() noexcept {
return operator+=(-1);
}
deferred_ptr operator+(int offset) const noexcept {
auto ret = *this;
ret += offset;
return ret;
}
deferred_ptr operator-(int offset) const noexcept {
return *this + -offset;
}
std::add_lvalue_reference_t<T> operator[](size_t offset) noexcept {
#ifndef NDEBUG
// In debug mode, perform the arithmetic checks by creating a temporary deferred_ptr
auto tmp = *this;
tmp += offset;
return *tmp;
#else
// In release mode, don't enregister/deregister a temnporary deferred_ptr
return *(get() + offset);
#endif
}
ptrdiff_t operator-(const deferred_ptr& that) const noexcept {
#ifndef NDEBUG
// Note that this intentionally permits subtracting two null pointers
if (get() == that.get()) {
return 0;
}
Expects(get() != nullptr && that.get() != nullptr
&& "bad deferred_ptr arithmetic: can't subtract pointers when one is null");
auto this_info = get_heap()->find_dhpage_info(get());
auto that_info = get_heap()->find_dhpage_info(that.get());
Expects(this_info.page != nullptr
&& that_info.page != nullptr
&& "corrupt non-null deferred_ptr, not pointing into deferred heap");
Expects(that_info.info.found > gpage::in_range_unallocated
&& "corrupt non-null deferred_ptr, pointing to unallocated space");
Expects(that_info.page == this_info.page
&& "bad deferred_ptr arithmetic: attempt to leave dhpage");
Expects(
// If that points to the start of an allocation, it's always legal
// to form a pointer to the following element (just don't deref it)
// which covers one-past-the-end of single-element allocations
//
// Future: We could eliminate this first test by adding an extra byte
// to every allocation, then we'd be type-safe too (this being the
// only way to form a deferred_ptr<T> to something not allocated as a T)
((
that_info.info.found == gpage::in_range_allocated_start
&& (get() == that.get()+1)
)
// Otherwise this and temp must point into the same allocation
// which is covered for arrays by the extra byte we allocated
|| (
that_info.info.start_location == this_info.info.start_location
&& this_info.info.found > gpage::in_range_unallocated)
)
&& "bad deferred_ptr arithmetic: attempt to go outside the allocation");
#endif
return get() - that.get();
}
};
// Specialize void just to get rid of the void& return from operator*
template<>
class deferred_ptr<void> : public deferred_heap::deferred_ptr_void {
deferred_ptr(deferred_heap* page, void* p)
: deferred_ptr_void(page, p)
{ }
friend deferred_heap;
public:
// Default and null construction. (Note we do not use a defaulted
// T* parameter, so that the T* overload can be private and the
// nullptr overload can be public.)
//
deferred_ptr() : deferred_ptr_void(nullptr) { }
// Construction and assignment from null. Note: The null constructor
// is not defined as a combination default constructor in the usual
// way (that is, as constructor from T* with a default null argument)
// because general construction from T* is private.
//
deferred_ptr(std::nullptr_t) : deferred_ptr{} { }
deferred_ptr& operator=(std::nullptr_t) noexcept {
reset();
return *this;
}
// Copying.
//
deferred_ptr(const deferred_ptr& that)
: deferred_ptr_void(that)
{ }
deferred_ptr& operator=(const deferred_ptr& that) noexcept
{
deferred_ptr_void::operator=(that);
return *this;
}
// Copying with conversions (base -> derived, non-const -> const).
//
template<class U>
deferred_ptr(const deferred_ptr<U>& that)
: deferred_ptr_void(that)
{ }
template<class U>
deferred_ptr& operator=(const deferred_ptr<U>& that) noexcept {
deferred_ptr_void::operator=(that);
return *this;
}
// Accessors.
//
void* get() const noexcept {
return deferred_ptr_void::get();
}
void* operator->() const noexcept {
Expects(get() && "attempt to dereference null");
return get();
}
};
//----------------------------------------------------------------------------
//
// deferred_heap function implementations
//
//----------------------------------------------------------------------------
//
inline
deferred_heap::~deferred_heap()
{
// Note: setting this flag lets us skip worrying about reentrancy;
// a destructor may not allocate a new object (which would try to
// enregister and therefore change our data structures)
is_destroying = true;
// when destroying the arena, detach all pointers and run all destructors
//
for (auto& p : roots) {
const_cast<deferred_ptr_void*>(p)->detach();
}
for (auto& pg : pages) {
for (auto& p : pg.deferred_ptrs) {
const_cast<deferred_ptr_void*>(p.p)->detach();
}
}
// this calls user code (the dtors), but no reentrancy care is
// necessary per note above
dtors.run_all();
}
// Add this deferred_ptr to the tracking list. Invoked when constructing a deferred_ptr.
//
inline
void deferred_heap::enregister(const deferred_ptr_void& p) {
// append it to the back of the appropriate list
Expects(!is_destroying
&& "cannot allocate new objects on a deferred_heap that is being destroyed");
auto pg = find_dhpage_of(&p);
if (pg != nullptr)
{
pg->deferred_ptrs.push_back(&p);
}
else
{
roots.insert(&p);
}
}
// Remove this deferred_ptr from tracking. Invoked when destroying a deferred_ptr.
//
inline
void deferred_heap::deregister(const deferred_ptr_void& p) {
// no need to actually deregister if we're tearing down this deferred_heap
if (is_destroying)
return;
// find its entry, starting from the back because it's more
// likely to be there (newer objects tend to have shorter
// lifetimes... all local deferred_ptrs fall into this category,
// and especially temporary deferred_ptrs)
//
auto erased_count = roots.erase(&p);
Expects(erased_count < 2 && "duplicate registration");
if (erased_count > 0)
return;
for (auto& pg : pages) {
auto j = find_if(pg.deferred_ptrs.rbegin(), pg.deferred_ptrs.rend(),
[&p](auto x) { return x.p == &p; });
if (j != pg.deferred_ptrs.rend()) {
*j = pg.deferred_ptrs.back();
pg.deferred_ptrs.pop_back();
return;
}
}
Expects(!"attempt to deregister an unregistered deferred_ptr");
}
// Return the dhpage on which this object exists.
// If the object is not in our storage, returns null.
//
template<class T>
deferred_heap::dhpage* deferred_heap::find_dhpage_of(T* p) noexcept {
if (p != nullptr) {
for (auto& pg : pages) {
if (pg.page.contains((byte*)p))
return &pg;
}
}
return nullptr;
}
template<class T>
deferred_heap::find_dhpage_info_ret deferred_heap::find_dhpage_info(T* p) noexcept {
find_dhpage_info_ret ret;
for (auto& pg : pages) {
auto info = pg.page.contains_info((byte*)p);
if (info.found != gpage::not_in_range) {
ret.page = &pg;
ret.info = info;
}
}
return ret;
}
template<class T>
std::pair<deferred_heap::dhpage*, byte*>
deferred_heap::allocate_from_existing_pages(int n) {
for (auto& pg : pages) {
auto p = pg.page.allocate<T>(n);
if (p != nullptr)
return{ &pg, p };
}
return{ nullptr, nullptr };
}
template<class T>
deferred_ptr<T> deferred_heap::allocate(int n)
{
Expects(n > 0 && "cannot request an empty allocation");
// get raw memory from the backing storage...
auto p = allocate_from_existing_pages<T>(n);
// ... performing a collection if necessary ...
if (p.second == nullptr && collect_before_expand) {
collect();
p = allocate_from_existing_pages<T>(n);
}
// ... allocating another page if necessary
if (p.second == nullptr) {
// pass along the type hint for size/alignment
pages.emplace_back((T*)nullptr, n, this);
p.first = &pages.back(); // Future: just use emplace_back's return value, in a C++17 STL
p = { p.first, p.first->page.template allocate<T>(n) };
}
Expects(p.second != nullptr && "failed to allocate but didn't throw an exception");
return{ this, reinterpret_cast<T*>(p.second) };
}
template<class T, class ...Args>
void deferred_heap::construct(gsl::not_null<T*> p, Args&& ...args)
{
// if there are objects with deferred destructors in this
// region, run those first and remove them
destroy_objects({ (byte*)p.get(), sizeof(T) });
// construct the object...
// =====================================================================
// === BEGIN REENTRANCY-SAFE: ensure no in-progress use of private state
::new (static_cast<void*>(p.get())) T{ std::forward<Args>(args)... };
// === END REENTRANCY-SAFE: reload any stored copies of private state
// =====================================================================
// ... and store the destructor
dtors.store(gsl::span<T>(p, 1));
}
template<class T>
void deferred_heap::construct_array(gsl::not_null<T*> p, int n)
{
Expects(n > 0 && "cannot request an empty array");
// if there are objects with deferred destructors in this
// region, run those first and remove them
destroy_objects({ (byte*)p.get(), gsl::narrow_cast<int>(sizeof(T)) * n });
// construct all the objects...
for (auto i = 0; i < n; ++i) {
// =====================================================================
// === BEGIN REENTRANCY-SAFE: ensure no in-progress use of private state
try {
::new (static_cast<void*>(p.get() + i)) T{};
} catch(...) {
while (i-- > 0) {
(p.get() + i)->~T();
}
throw;
}
// === END REENTRANCY-SAFE: reload any stored copies of private state
// =====================================================================
}
// ... and store the destructor
dtors.store(gsl::span<T>(p, n));
}
template<class T>
void deferred_heap::destroy(gsl::not_null<T*> p) noexcept
{
Expects(dtors.is_stored(p)
&& "attempt to destroy an object whose destructor is not registered");
}
inline
bool deferred_heap::destroy_objects(gsl::span<byte> range) {
return dtors.run(range);
}
//------------------------------------------------------------------------
//
// collect, et al.: Sweep the deferred heap
//
inline
void deferred_heap::mark(const deferred_ptr_void& p, std::size_t level) noexcept
{
// if it isn't null ...
if (p.get() == nullptr)
return;
// ... find which page it points into ...
for (auto& pg : pages) {
auto where = pg.page.contains_info((byte*)p.get());
Expects(where.found != gpage::in_range_unallocated
&& "must not point to unallocated memory");
if (where.found != gpage::not_in_range) {
// ... and mark the chunk as live ...
pg.live_starts.set(where.start_location, true);
// ... and mark any deferred_ptrs in the allocation as reachable
for (auto& dp : pg.deferred_ptrs) {
auto dp_where = pg.page.contains_info((byte*)dp.p);
Expects((dp_where.found == gpage::in_range_allocated_middle
|| dp_where.found == gpage::in_range_allocated_start)
&& "points to unallocated memory");
if (dp_where.start_location == where.start_location
&& dp.level == 0) {
dp.level = level; // 'level' steps from a root
}
}
break;
}
}
}
inline
void deferred_heap::collect()
{
// 1. reset all the mark bits and in-arena deferred_ptr levels
//
for (auto& pg : pages) {
pg.live_starts.set_all(false);
for (auto& dp : pg.deferred_ptrs) {
dp.level = 0;
}
}
// 2. mark all roots + the in-arena deferred_ptrs reachable from them
//
std::size_t level = 1;
for (auto& p : roots) {
mark(*p, level); // mark this deferred_ptr root
}
bool done = false;
while (!done) {
done = true; // we're done unless we find another to mark
++level;
for (auto& pg : pages) {
for (auto& dp : pg.deferred_ptrs) {
if (dp.level == level - 1) {
done = false;
mark(*(dp.p), level); // mark this reachable in-arena deferred_ptr
}
}
}
}
// We have now marked every allocation to save, so now
// go through and clean up all the unreachable objects