tdesktop/Telegram/SourceFiles/base/runtime_composer.h

280 lines
7.6 KiB
C++

/*
This file is part of Telegram Desktop,
the official desktop application for the Telegram messaging service.
For license and copyright information please follow this link:
https://github.com/telegramdesktop/tdesktop/blob/master/LEGAL
*/
#pragma once
template <typename Base>
class RuntimeComposer;
class RuntimeComposerBase;
typedef void(*RuntimeComponentConstruct)(void *location, RuntimeComposerBase *composer);
typedef void(*RuntimeComponentDestruct)(void *location);
typedef void(*RuntimeComponentMove)(void *location, void *waslocation);
struct RuntimeComponentWrapStruct {
// Don't init any fields, because it is only created in
// global scope, so it will be filled by zeros from the start.
RuntimeComponentWrapStruct() = default;
RuntimeComponentWrapStruct(std::size_t size, std::size_t align, RuntimeComponentConstruct construct, RuntimeComponentDestruct destruct, RuntimeComponentMove move)
: Size(size)
, Align(align)
, Construct(construct)
, Destruct(destruct)
, Move(move) {
}
std::size_t Size;
std::size_t Align;
RuntimeComponentConstruct Construct;
RuntimeComponentDestruct Destruct;
RuntimeComponentMove Move;
};
template <int Value, int Denominator>
struct CeilDivideMinimumOne {
static constexpr int Result = ((Value / Denominator) + ((!Value || (Value % Denominator)) ? 1 : 0));
};
extern RuntimeComponentWrapStruct RuntimeComponentWraps[64];
extern QAtomicInt RuntimeComponentIndexLast;
template <typename Type, typename Base>
struct RuntimeComponent {
using RuntimeComponentBase = Base;
RuntimeComponent() {
// While there is no std::aligned_alloc().
static_assert(alignof(Type) <= alignof(std::max_align_t), "Components should align to std::max_align_t!");
}
RuntimeComponent(const RuntimeComponent &other) = delete;
RuntimeComponent &operator=(const RuntimeComponent &other) = delete;
RuntimeComponent(RuntimeComponent &&other) = delete;
RuntimeComponent &operator=(RuntimeComponent &&other) = default;
static int Index() {
static QAtomicInt MyIndex(0);
if (auto index = MyIndex.loadAcquire()) {
return index - 1;
}
while (true) {
auto last = RuntimeComponentIndexLast.loadAcquire();
if (RuntimeComponentIndexLast.testAndSetOrdered(last, last + 1)) {
Assert(last < 64);
if (MyIndex.testAndSetOrdered(0, last + 1)) {
RuntimeComponentWraps[last] = RuntimeComponentWrapStruct(
sizeof(Type),
alignof(Type),
Type::RuntimeComponentConstruct,
Type::RuntimeComponentDestruct,
Type::RuntimeComponentMove);
}
break;
}
}
return MyIndex.loadAcquire() - 1;
}
static uint64 Bit() {
return (1ULL << Index());
}
protected:
static void RuntimeComponentConstruct(void *location, RuntimeComposerBase *composer) {
new (location) Type();
}
static void RuntimeComponentDestruct(void *location) {
((Type*)location)->~Type();
}
static void RuntimeComponentMove(void *location, void *waslocation) {
*(Type*)location = std::move(*(Type*)waslocation);
}
};
class RuntimeComposerMetadata {
public:
RuntimeComposerMetadata(uint64 mask) : _mask(mask) {
for (int i = 0; i != 64; ++i) {
auto componentBit = (1ULL << i);
if (_mask & componentBit) {
auto componentSize = RuntimeComponentWraps[i].Size;
if (componentSize) {
auto componentAlign = RuntimeComponentWraps[i].Align;
if (auto badAlign = (size % componentAlign)) {
size += (componentAlign - badAlign);
}
offsets[i] = size;
size += componentSize;
accumulate_max(align, componentAlign);
}
} else if (_mask < componentBit) {
last = i;
break;
}
}
}
// Meta pointer in the start.
std::size_t size = sizeof(const RuntimeComposerMetadata*);
std::size_t align = alignof(const RuntimeComposerMetadata*);
std::size_t offsets[64] = { 0 };
int last = 64;
bool equals(uint64 mask) const {
return _mask == mask;
}
uint64 maskadd(uint64 mask) const {
return _mask | mask;
}
uint64 maskremove(uint64 mask) const {
return _mask & (~mask);
}
private:
uint64 _mask;
};
const RuntimeComposerMetadata *GetRuntimeComposerMetadata(uint64 mask);
class RuntimeComposerBase {
public:
RuntimeComposerBase(uint64 mask = 0) : _data(zerodata()) {
if (mask) {
auto meta = GetRuntimeComposerMetadata(mask);
auto data = operator new(meta->size);
Assert(data != nullptr);
_data = data;
_meta() = meta;
for (int i = 0; i < meta->last; ++i) {
auto offset = meta->offsets[i];
if (offset >= sizeof(_meta())) {
try {
auto constructAt = _dataptrunsafe(offset);
auto space = RuntimeComponentWraps[i].Size;
auto alignedAt = constructAt;
std::align(RuntimeComponentWraps[i].Align, space, alignedAt, space);
Assert(alignedAt == constructAt);
RuntimeComponentWraps[i].Construct(constructAt, this);
} catch (...) {
while (i > 0) {
--i;
offset = meta->offsets[--i];
if (offset >= sizeof(_meta())) {
RuntimeComponentWraps[i].Destruct(_dataptrunsafe(offset));
}
}
throw;
}
}
}
}
}
RuntimeComposerBase(const RuntimeComposerBase &other) = delete;
RuntimeComposerBase &operator=(const RuntimeComposerBase &other) = delete;
~RuntimeComposerBase() {
if (_data != zerodata()) {
auto meta = _meta();
for (int i = 0; i < meta->last; ++i) {
auto offset = meta->offsets[i];
if (offset >= sizeof(_meta())) {
RuntimeComponentWraps[i].Destruct(_dataptrunsafe(offset));
}
}
operator delete(_data);
}
}
protected:
bool UpdateComponents(uint64 mask = 0) {
if (_meta()->equals(mask)) {
return false;
}
RuntimeComposerBase result(mask);
result.swap(*this);
if (_data != zerodata() && result._data != zerodata()) {
const auto meta = _meta();
const auto wasmeta = result._meta();
for (auto i = 0; i != meta->last; ++i) {
const auto offset = meta->offsets[i];
const auto wasoffset = wasmeta->offsets[i];
if (offset >= sizeof(_meta())
&& wasoffset >= sizeof(_meta())) {
RuntimeComponentWraps[i].Move(
_dataptrunsafe(offset),
result._dataptrunsafe(wasoffset));
}
}
}
return true;
}
bool AddComponents(uint64 mask = 0) {
return UpdateComponents(_meta()->maskadd(mask));
}
bool RemoveComponents(uint64 mask = 0) {
return UpdateComponents(_meta()->maskremove(mask));
}
private:
template <typename Base>
friend class RuntimeComposer;
static const RuntimeComposerMetadata *ZeroRuntimeComposerMetadata;
static void *zerodata() {
return &ZeroRuntimeComposerMetadata;
}
void *_dataptrunsafe(int skip) const {
return (char*)_data + skip;
}
void *_dataptr(int skip) const {
return (skip >= sizeof(_meta())) ? _dataptrunsafe(skip) : nullptr;
}
const RuntimeComposerMetadata *&_meta() const {
return *static_cast<const RuntimeComposerMetadata**>(_data);
}
void *_data = nullptr;
void swap(RuntimeComposerBase &other) {
std::swap(_data, other._data);
}
};
template <typename Base>
class RuntimeComposer : public RuntimeComposerBase {
public:
using RuntimeComposerBase::RuntimeComposerBase;
template <
typename Type,
typename = std::enable_if_t<std::is_same_v<
typename Type::RuntimeComponentBase,
Base>>>
bool Has() const {
return (_meta()->offsets[Type::Index()] >= sizeof(_meta()));
}
template <
typename Type,
typename = std::enable_if_t<std::is_same_v<
typename Type::RuntimeComponentBase,
Base>>>
Type *Get() {
return static_cast<Type*>(_dataptr(_meta()->offsets[Type::Index()]));
}
template <
typename Type,
typename = std::enable_if_t<std::is_same_v<
typename Type::RuntimeComponentBase,
Base>>>
const Type *Get() const {
return static_cast<const Type*>(_dataptr(_meta()->offsets[Type::Index()]));
}
};