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Atmosphere/libraries/libstratosphere/source/fssystem/fssystem_pooled_buffer.cpp

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/*
* Copyright (c) Atmosphère-NX
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*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stratosphere.hpp>
namespace ams::fssystem {
namespace {
class AdditionalDeviceAddressEntry {
private:
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os::SdkMutex m_mutex;
bool m_is_registered;
uintptr_t m_address;
size_t m_size;
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public:
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constexpr AdditionalDeviceAddressEntry() : m_mutex(), m_is_registered(), m_address(), m_size() { /* ... */ }
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void Register(uintptr_t addr, size_t sz) {
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std::scoped_lock lk(m_mutex);
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AMS_ASSERT(!m_is_registered);
if (!m_is_registered) {
m_is_registered = true;
m_address = addr;
m_size = sz;
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}
}
void Unregister(uintptr_t addr) {
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std::scoped_lock lk(m_mutex);
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if (m_is_registered && m_address == addr) {
m_is_registered = false;
m_address = 0;
m_size = 0;
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}
}
bool Includes(const void *ptr) {
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std::scoped_lock lk(m_mutex);
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if (m_is_registered) {
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const uintptr_t addr = reinterpret_cast<uintptr_t>(ptr);
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return m_address <= addr && addr < m_address + m_size;
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} else {
return false;
}
}
};
constexpr auto RetryWait = TimeSpan::FromMilliSeconds(10);
constexpr size_t HeapBlockSize = BufferPoolAlignment;
static_assert(HeapBlockSize == 4_KB);
/* A heap block is 4KB. An order is a power of two. */
/* This gives blocks of the order 32KB, 512KB, 4MB. */
constexpr s32 HeapOrderTrim = 3;
constexpr s32 HeapOrderMax = 7;
constexpr s32 HeapOrderMaxForLarge = HeapOrderMax + 3;
constexpr size_t HeapAllocatableSizeTrim = HeapBlockSize * (static_cast<size_t>(1) << HeapOrderTrim);
constexpr size_t HeapAllocatableSizeMax = HeapBlockSize * (static_cast<size_t>(1) << HeapOrderMax);
constexpr size_t HeapAllocatableSizeMaxForLarge = HeapBlockSize * (static_cast<size_t>(1) << HeapOrderMaxForLarge);
constinit os::SdkMutex g_heap_mutex;
constinit FileSystemBuddyHeap g_heap;
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constinit std::atomic<size_t> g_retry_count;
constinit std::atomic<size_t> g_reduce_allocation_count;
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constinit void *g_heap_buffer;
constinit size_t g_heap_size;
constinit size_t g_heap_free_size_peak;
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constinit AdditionalDeviceAddressEntry g_additional_device_address_entry;
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}
size_t PooledBuffer::GetAllocatableSizeMaxCore(bool large) {
return large ? HeapAllocatableSizeMaxForLarge : HeapAllocatableSizeMax;
}
void PooledBuffer::AllocateCore(size_t ideal_size, size_t required_size, bool large) {
/* Ensure preconditions. */
AMS_ASSERT(g_heap_buffer != nullptr);
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AMS_ASSERT(m_buffer == nullptr);
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AMS_ASSERT(g_heap.GetBlockSize() == HeapBlockSize);
/* Check that we can allocate this size. */
AMS_ASSERT(required_size <= GetAllocatableSizeMaxCore(large));
const size_t target_size = std::min(std::max(ideal_size, required_size), GetAllocatableSizeMaxCore(large));
/* Loop until we allocate. */
while (true) {
/* Lock the heap and try to allocate. */
{
std::scoped_lock lk(g_heap_mutex);
/* Determine how much we can allocate, and don't allocate more than half the heap. */
size_t allocatable_size = g_heap.GetAllocatableSizeMax();
if (allocatable_size > HeapBlockSize) {
allocatable_size >>= 1;
}
/* Check if this allocation is acceptable. */
if (allocatable_size >= required_size) {
/* Get the order. */
const auto order = g_heap.GetOrderFromBytes(std::min(target_size, allocatable_size));
/* Allocate and get the size. */
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m_buffer = reinterpret_cast<char *>(g_heap.AllocateByOrder(order));
m_size = g_heap.GetBytesFromOrder(order);
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}
}
/* Check if we allocated. */
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if (m_buffer != nullptr) {
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/* If we need to trim the end, do so. */
if (this->GetSize() >= target_size + HeapAllocatableSizeTrim) {
this->Shrink(util::AlignUp(target_size, HeapAllocatableSizeTrim));
}
AMS_ASSERT(this->GetSize() >= required_size);
/* If we reduced, note so. */
if (this->GetSize() < std::min(target_size, HeapAllocatableSizeMax)) {
g_reduce_allocation_count++;
}
break;
} else {
/* Sleep. */
os::SleepThread(RetryWait);
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g_retry_count++;
}
}
/* Update metrics. */
{
std::scoped_lock lk(g_heap_mutex);
const size_t free_size = g_heap.GetTotalFreeSize();
if (free_size < g_heap_free_size_peak) {
g_heap_free_size_peak = free_size;
}
}
}
void PooledBuffer::Shrink(size_t ideal_size) {
AMS_ASSERT(ideal_size <= GetAllocatableSizeMaxCore(true));
/* Check if we actually need to shrink. */
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if (m_size > ideal_size) {
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/* If we do, we need to have a buffer allocated from the heap. */
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AMS_ASSERT(m_buffer != nullptr);
AMS_ASSERT(g_heap.GetBlockSize() == HeapBlockSize);
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const size_t new_size = util::AlignUp(ideal_size, HeapBlockSize);
/* Repeatedly free the tail of our buffer until we're done. */
{
std::scoped_lock lk(g_heap_mutex);
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while (new_size < m_size) {
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/* Determine the size and order to free. */
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const size_t tail_align = util::LeastSignificantOneBit(m_size);
const size_t free_size = std::min(util::FloorPowerOfTwo(m_size - new_size), tail_align);
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const s32 free_order = g_heap.GetOrderFromBytes(free_size);
/* Ensure we determined size correctly. */
AMS_ASSERT(util::IsAligned(free_size, HeapBlockSize));
AMS_ASSERT(free_size == g_heap.GetBytesFromOrder(free_order));
/* Actually free the memory. */
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g_heap.Free(m_buffer + m_size - free_size, free_order);
m_size -= free_size;
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}
}
/* Shrinking to zero means that we have no buffer. */
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if (m_size == 0) {
m_buffer = nullptr;
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}
}
}
Result InitializeBufferPool(char *buffer, size_t size) {
AMS_ASSERT(g_heap_buffer == nullptr);
AMS_ASSERT(buffer != nullptr);
AMS_ASSERT(util::IsAligned(reinterpret_cast<uintptr_t>(buffer), BufferPoolAlignment));
/* Initialize the heap. */
R_TRY(g_heap.Initialize(reinterpret_cast<uintptr_t>(buffer), size, HeapBlockSize, HeapOrderMaxForLarge + 1));
/* Initialize metrics. */
g_heap_buffer = buffer;
g_heap_size = size;
g_heap_free_size_peak = size;
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R_SUCCEED();
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}
Result InitializeBufferPool(char *buffer, size_t size, char *work, size_t work_size) {
AMS_ASSERT(g_heap_buffer == nullptr);
AMS_ASSERT(buffer != nullptr);
AMS_ASSERT(util::IsAligned(reinterpret_cast<uintptr_t>(buffer), BufferPoolAlignment));
AMS_ASSERT(work_size >= BufferPoolWorkSize);
/* Initialize the heap. */
R_TRY(g_heap.Initialize(reinterpret_cast<uintptr_t>(buffer), size, HeapBlockSize, HeapOrderMaxForLarge + 1, work, work_size));
/* Initialize metrics. */
g_heap_buffer = buffer;
g_heap_size = size;
g_heap_free_size_peak = size;
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R_SUCCEED();
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}
bool IsPooledBuffer(const void *buffer) {
AMS_ASSERT(buffer != nullptr);
return g_heap_buffer <= buffer && buffer < reinterpret_cast<char *>(g_heap_buffer) + g_heap_size;
}
size_t GetPooledBufferRetriedCount() {
return g_retry_count;
}
size_t GetPooledBufferReduceAllocationCount() {
return g_reduce_allocation_count;
}
size_t GetPooledBufferFreeSizePeak() {
return g_heap_free_size_peak;
}
void ClearPooledBufferPeak() {
std::scoped_lock lk(g_heap_mutex);
g_heap_free_size_peak = g_heap.GetTotalFreeSize();
g_retry_count = 0;
g_reduce_allocation_count = 0;
}
void RegisterAdditionalDeviceAddress(uintptr_t address, size_t size) {
g_additional_device_address_entry.Register(address, size);
}
void UnregisterAdditionalDeviceAddress(uintptr_t address) {
g_additional_device_address_entry.Unregister(address);
}
bool IsAdditionalDeviceAddress(const void *ptr) {
return g_additional_device_address_entry.Includes(ptr);
}
}