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https://github.com/Atmosphere-NX/Atmosphere.git
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96f95b9f95
* result: try out some experimental shenanigans * result: sketch out some more shenanigans * result: see what it looks like to convert kernel to use result conds instead of guards * make rest of kernel use experimental new macro-ing
511 lines
22 KiB
C++
511 lines
22 KiB
C++
/*
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* Copyright (c) Atmosphère-NX
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms and conditions of the GNU General Public License,
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* version 2, as published by the Free Software Foundation.
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*
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* This program is distributed in the hope it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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* more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <mesosphere.hpp>
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namespace ams::kern {
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namespace {
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constexpr KMemoryManager::Pool GetPoolFromMemoryRegionType(u32 type) {
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if ((type | KMemoryRegionType_DramApplicationPool) == type) {
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return KMemoryManager::Pool_Application;
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} else if ((type | KMemoryRegionType_DramAppletPool) == type) {
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return KMemoryManager::Pool_Applet;
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} else if ((type | KMemoryRegionType_DramSystemPool) == type) {
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return KMemoryManager::Pool_System;
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} else if ((type | KMemoryRegionType_DramSystemNonSecurePool) == type) {
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return KMemoryManager::Pool_SystemNonSecure;
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} else {
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MESOSPHERE_PANIC("InvalidMemoryRegionType for conversion to Pool");
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}
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}
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}
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void KMemoryManager::Initialize(KVirtualAddress management_region, size_t management_region_size) {
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/* Clear the management region to zero. */
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const KVirtualAddress management_region_end = management_region + management_region_size;
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std::memset(GetVoidPointer(management_region), 0, management_region_size);
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/* Reset our manager count. */
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m_num_managers = 0;
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/* Traverse the virtual memory layout tree, initializing each manager as appropriate. */
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while (m_num_managers != MaxManagerCount) {
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/* Locate the region that should initialize the current manager. */
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KPhysicalAddress region_address = Null<KPhysicalAddress>;
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size_t region_size = 0;
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Pool region_pool = Pool_Count;
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for (const auto &it : KMemoryLayout::GetPhysicalMemoryRegionTree()) {
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/* We only care about regions that we need to create managers for. */
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if (!it.IsDerivedFrom(KMemoryRegionType_DramUserPool)) {
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continue;
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}
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/* We want to initialize the managers in order. */
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if (it.GetAttributes() != m_num_managers) {
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continue;
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}
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const KPhysicalAddress cur_start = it.GetAddress();
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const KPhysicalAddress cur_end = it.GetEndAddress();
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/* Validate the region. */
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MESOSPHERE_ABORT_UNLESS(cur_end != Null<KPhysicalAddress>);
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MESOSPHERE_ASSERT(cur_start != Null<KPhysicalAddress>);
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MESOSPHERE_ASSERT(it.GetSize() > 0);
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/* Update the region's extents. */
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if (region_address == Null<KPhysicalAddress>) {
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region_address = cur_start;
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region_size = it.GetSize();
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region_pool = GetPoolFromMemoryRegionType(it.GetType());
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} else {
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MESOSPHERE_ASSERT(cur_start == region_address + region_size);
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/* Update the size. */
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region_size = cur_end - region_address;
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MESOSPHERE_ABORT_UNLESS(GetPoolFromMemoryRegionType(it.GetType()) == region_pool);
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}
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}
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/* If we didn't find a region, we're done. */
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if (region_size == 0) {
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break;
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}
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/* Initialize a new manager for the region. */
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Impl *manager = std::addressof(m_managers[m_num_managers++]);
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MESOSPHERE_ABORT_UNLESS(m_num_managers <= util::size(m_managers));
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const size_t cur_size = manager->Initialize(region_address, region_size, management_region, management_region_end, region_pool);
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management_region += cur_size;
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MESOSPHERE_ABORT_UNLESS(management_region <= management_region_end);
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/* Insert the manager into the pool list. */
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if (m_pool_managers_tail[region_pool] == nullptr) {
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m_pool_managers_head[region_pool] = manager;
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} else {
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m_pool_managers_tail[region_pool]->SetNext(manager);
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manager->SetPrev(m_pool_managers_tail[region_pool]);
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}
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m_pool_managers_tail[region_pool] = manager;
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}
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/* Free each region to its corresponding heap. */
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size_t reserved_sizes[MaxManagerCount] = {};
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const KPhysicalAddress ini_start = GetInitialProcessBinaryPhysicalAddress();
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const KPhysicalAddress ini_end = ini_start + InitialProcessBinarySizeMax;
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const KPhysicalAddress ini_last = ini_end - 1;
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for (const auto &it : KMemoryLayout::GetPhysicalMemoryRegionTree()) {
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if (it.IsDerivedFrom(KMemoryRegionType_DramUserPool)) {
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/* Get the manager for the region. */
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auto &manager = m_managers[it.GetAttributes()];
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const KPhysicalAddress cur_start = it.GetAddress();
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const KPhysicalAddress cur_last = it.GetLastAddress();
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const KPhysicalAddress cur_end = it.GetEndAddress();
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if (cur_start <= ini_start && ini_last <= cur_last) {
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/* Free memory before the ini to the heap. */
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if (cur_start != ini_start) {
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manager.Free(cur_start, (ini_start - cur_start) / PageSize);
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}
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/* Open/reserve the ini memory. */
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manager.OpenFirst(ini_start, InitialProcessBinarySizeMax / PageSize);
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reserved_sizes[it.GetAttributes()] += InitialProcessBinarySizeMax;
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/* Free memory after the ini to the heap. */
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if (ini_last != cur_last) {
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MESOSPHERE_ABORT_UNLESS(cur_end != Null<KPhysicalAddress>);
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manager.Free(ini_end, cur_end - ini_end);
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}
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} else {
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/* Ensure there's no partial overlap with the ini image. */
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if (cur_start <= ini_last) {
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MESOSPHERE_ABORT_UNLESS(cur_last < ini_start);
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} else {
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/* Otherwise, check the region for general validity. */
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MESOSPHERE_ABORT_UNLESS(cur_end != Null<KPhysicalAddress>);
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}
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/* Free the memory to the heap. */
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manager.Free(cur_start, it.GetSize() / PageSize);
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}
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}
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}
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/* Update the used size for all managers. */
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for (size_t i = 0; i < m_num_managers; ++i) {
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m_managers[i].SetInitialUsedHeapSize(reserved_sizes[i]);
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}
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}
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Result KMemoryManager::InitializeOptimizedMemory(u64 process_id, Pool pool) {
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/* Lock the pool. */
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KScopedLightLock lk(m_pool_locks[pool]);
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/* Check that we don't already have an optimized process. */
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R_UNLESS(!m_has_optimized_process[pool], svc::ResultBusy());
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/* Set the optimized process id. */
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m_optimized_process_ids[pool] = process_id;
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m_has_optimized_process[pool] = true;
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/* Clear the management area for the optimized process. */
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for (auto *manager = this->GetFirstManager(pool, Direction_FromFront); manager != nullptr; manager = this->GetNextManager(manager, Direction_FromFront)) {
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manager->InitializeOptimizedMemory();
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}
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R_SUCCEED();
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}
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void KMemoryManager::FinalizeOptimizedMemory(u64 process_id, Pool pool) {
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/* Lock the pool. */
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KScopedLightLock lk(m_pool_locks[pool]);
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/* If the process was optimized, clear it. */
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if (m_has_optimized_process[pool] && m_optimized_process_ids[pool] == process_id) {
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m_has_optimized_process[pool] = false;
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}
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}
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KPhysicalAddress KMemoryManager::AllocateAndOpenContinuous(size_t num_pages, size_t align_pages, u32 option) {
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/* Early return if we're allocating no pages. */
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if (num_pages == 0) {
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return Null<KPhysicalAddress>;
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}
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/* Lock the pool that we're allocating from. */
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const auto [pool, dir] = DecodeOption(option);
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KScopedLightLock lk(m_pool_locks[pool]);
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/* Choose a heap based on our page size request. */
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const s32 heap_index = KPageHeap::GetAlignedBlockIndex(num_pages, align_pages);
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/* Loop, trying to iterate from each block. */
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Impl *chosen_manager = nullptr;
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KPhysicalAddress allocated_block = Null<KPhysicalAddress>;
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for (chosen_manager = this->GetFirstManager(pool, dir); chosen_manager != nullptr; chosen_manager = this->GetNextManager(chosen_manager, dir)) {
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allocated_block = chosen_manager->AllocateBlock(heap_index, true);
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if (allocated_block != Null<KPhysicalAddress>) {
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break;
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}
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}
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/* If we failed to allocate, quit now. */
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if (allocated_block == Null<KPhysicalAddress>) {
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return Null<KPhysicalAddress>;
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}
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/* If we allocated more than we need, free some. */
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const size_t allocated_pages = KPageHeap::GetBlockNumPages(heap_index);
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if (allocated_pages > num_pages) {
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chosen_manager->Free(allocated_block + num_pages * PageSize, allocated_pages - num_pages);
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}
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/* Maintain the optimized memory bitmap, if we should. */
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if (m_has_optimized_process[pool]) {
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chosen_manager->TrackUnoptimizedAllocation(allocated_block, num_pages);
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}
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/* Open the first reference to the pages. */
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chosen_manager->OpenFirst(allocated_block, num_pages);
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return allocated_block;
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}
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Result KMemoryManager::AllocatePageGroupImpl(KPageGroup *out, size_t num_pages, Pool pool, Direction dir, bool unoptimized, bool random) {
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/* Choose a heap based on our page size request. */
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const s32 heap_index = KPageHeap::GetBlockIndex(num_pages);
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R_UNLESS(0 <= heap_index, svc::ResultOutOfMemory());
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/* Ensure that we don't leave anything un-freed. */
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ON_RESULT_FAILURE {
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for (const auto &it : *out) {
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auto &manager = this->GetManager(it.GetAddress());
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const size_t num_pages = std::min(it.GetNumPages(), (manager.GetEndAddress() - it.GetAddress()) / PageSize);
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manager.Free(it.GetAddress(), num_pages);
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}
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out->Finalize();
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};
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/* Keep allocating until we've allocated all our pages. */
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for (s32 index = heap_index; index >= 0 && num_pages > 0; index--) {
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const size_t pages_per_alloc = KPageHeap::GetBlockNumPages(index);
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for (Impl *cur_manager = this->GetFirstManager(pool, dir); cur_manager != nullptr; cur_manager = this->GetNextManager(cur_manager, dir)) {
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while (num_pages >= pages_per_alloc) {
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/* Allocate a block. */
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KPhysicalAddress allocated_block = cur_manager->AllocateBlock(index, random);
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if (allocated_block == Null<KPhysicalAddress>) {
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break;
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}
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/* Ensure we don't leak the block if we fail. */
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ON_RESULT_FAILURE { cur_manager->Free(allocated_block, pages_per_alloc); };
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/* Add the block to our group. */
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R_TRY(out->AddBlock(allocated_block, pages_per_alloc));
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/* Maintain the optimized memory bitmap, if we should. */
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if (unoptimized) {
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cur_manager->TrackUnoptimizedAllocation(allocated_block, pages_per_alloc);
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}
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num_pages -= pages_per_alloc;
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}
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}
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}
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/* Only succeed if we allocated as many pages as we wanted. */
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R_UNLESS(num_pages == 0, svc::ResultOutOfMemory());
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/* We succeeded! */
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R_SUCCEED();
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}
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Result KMemoryManager::AllocateAndOpen(KPageGroup *out, size_t num_pages, u32 option) {
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MESOSPHERE_ASSERT(out != nullptr);
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MESOSPHERE_ASSERT(out->GetNumPages() == 0);
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/* Early return if we're allocating no pages. */
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R_SUCCEED_IF(num_pages == 0);
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/* Lock the pool that we're allocating from. */
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const auto [pool, dir] = DecodeOption(option);
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KScopedLightLock lk(m_pool_locks[pool]);
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/* Allocate the page group. */
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R_TRY(this->AllocatePageGroupImpl(out, num_pages, pool, dir, m_has_optimized_process[pool], true));
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/* Open the first reference to the pages. */
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for (const auto &block : *out) {
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KPhysicalAddress cur_address = block.GetAddress();
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size_t remaining_pages = block.GetNumPages();
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while (remaining_pages > 0) {
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/* Get the manager for the current address. */
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auto &manager = this->GetManager(cur_address);
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/* Process part or all of the block. */
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const size_t cur_pages = std::min(remaining_pages, manager.GetPageOffsetToEnd(cur_address));
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manager.OpenFirst(cur_address, cur_pages);
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/* Advance. */
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cur_address += cur_pages * PageSize;
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remaining_pages -= cur_pages;
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}
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}
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R_SUCCEED();
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}
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Result KMemoryManager::AllocateAndOpenForProcess(KPageGroup *out, size_t num_pages, u32 option, u64 process_id, u8 fill_pattern) {
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MESOSPHERE_ASSERT(out != nullptr);
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MESOSPHERE_ASSERT(out->GetNumPages() == 0);
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/* Decode the option. */
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const auto [pool, dir] = DecodeOption(option);
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/* Allocate the memory. */
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bool optimized;
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{
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/* Lock the pool that we're allocating from. */
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KScopedLightLock lk(m_pool_locks[pool]);
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/* Check if we have an optimized process. */
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const bool has_optimized = m_has_optimized_process[pool];
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const bool is_optimized = m_optimized_process_ids[pool] == process_id;
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/* Allocate the page group. */
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R_TRY(this->AllocatePageGroupImpl(out, num_pages, pool, dir, has_optimized && !is_optimized, false));
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/* Set whether we should optimize. */
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optimized = has_optimized && is_optimized;
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/* Open the first reference to the pages. */
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for (const auto &block : *out) {
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KPhysicalAddress cur_address = block.GetAddress();
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size_t remaining_pages = block.GetNumPages();
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while (remaining_pages > 0) {
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/* Get the manager for the current address. */
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auto &manager = this->GetManager(cur_address);
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/* Process part or all of the block. */
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const size_t cur_pages = std::min(remaining_pages, manager.GetPageOffsetToEnd(cur_address));
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manager.OpenFirst(cur_address, cur_pages);
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/* Advance. */
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cur_address += cur_pages * PageSize;
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remaining_pages -= cur_pages;
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}
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}
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}
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/* Perform optimized memory tracking, if we should. */
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if (optimized) {
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/* Iterate over the allocated blocks. */
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for (const auto &block : *out) {
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/* Get the block extents. */
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const KPhysicalAddress block_address = block.GetAddress();
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const size_t block_pages = block.GetNumPages();
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/* If it has no pages, we don't need to do anything. */
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if (block_pages == 0) {
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continue;
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}
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/* Fill all the pages that we need to fill. */
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bool any_new = false;
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{
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KPhysicalAddress cur_address = block_address;
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size_t remaining_pages = block_pages;
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while (remaining_pages > 0) {
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/* Get the manager for the current address. */
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auto &manager = this->GetManager(cur_address);
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/* Process part or all of the block. */
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const size_t cur_pages = std::min(remaining_pages, manager.GetPageOffsetToEnd(cur_address));
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any_new = manager.ProcessOptimizedAllocation(cur_address, cur_pages, fill_pattern);
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/* Advance. */
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cur_address += cur_pages * PageSize;
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remaining_pages -= cur_pages;
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}
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}
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/* If there are new pages, update tracking for the allocation. */
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if (any_new) {
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/* Update tracking for the allocation. */
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KPhysicalAddress cur_address = block_address;
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size_t remaining_pages = block_pages;
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while (remaining_pages > 0) {
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/* Get the manager for the current address. */
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auto &manager = this->GetManager(cur_address);
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/* Lock the pool for the manager. */
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KScopedLightLock lk(m_pool_locks[manager.GetPool()]);
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/* Track some or all of the current pages. */
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const size_t cur_pages = std::min(remaining_pages, manager.GetPageOffsetToEnd(cur_address));
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manager.TrackOptimizedAllocation(cur_address, cur_pages);
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/* Advance. */
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cur_address += cur_pages * PageSize;
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remaining_pages -= cur_pages;
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}
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}
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}
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} else {
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/* Set all the allocated memory. */
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for (const auto &block : *out) {
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std::memset(GetVoidPointer(KMemoryLayout::GetLinearVirtualAddress(block.GetAddress())), fill_pattern, block.GetSize());
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}
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}
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R_SUCCEED();
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}
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size_t KMemoryManager::Impl::Initialize(KPhysicalAddress address, size_t size, KVirtualAddress management, KVirtualAddress management_end, Pool p) {
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/* Calculate management sizes. */
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const size_t ref_count_size = (size / PageSize) * sizeof(u16);
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const size_t optimize_map_size = CalculateOptimizedProcessOverheadSize(size);
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const size_t manager_size = util::AlignUp(optimize_map_size + ref_count_size, PageSize);
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const size_t page_heap_size = KPageHeap::CalculateManagementOverheadSize(size);
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const size_t total_management_size = manager_size + page_heap_size;
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MESOSPHERE_ABORT_UNLESS(manager_size <= total_management_size);
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MESOSPHERE_ABORT_UNLESS(management + total_management_size <= management_end);
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MESOSPHERE_ABORT_UNLESS(util::IsAligned(total_management_size, PageSize));
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/* Setup region. */
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m_pool = p;
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m_management_region = management;
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m_page_reference_counts = GetPointer<RefCount>(management + optimize_map_size);
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MESOSPHERE_ABORT_UNLESS(util::IsAligned(GetInteger(m_management_region), PageSize));
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/* Initialize the manager's KPageHeap. */
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m_heap.Initialize(address, size, management + manager_size, page_heap_size);
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return total_management_size;
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}
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void KMemoryManager::Impl::TrackUnoptimizedAllocation(KPhysicalAddress block, size_t num_pages) {
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/* Get the range we're tracking. */
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size_t offset = this->GetPageOffset(block);
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const size_t last = offset + num_pages - 1;
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/* Track. */
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u64 *optimize_map = GetPointer<u64>(m_management_region);
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while (offset <= last) {
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/* Mark the page as not being optimized-allocated. */
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optimize_map[offset / BITSIZEOF(u64)] &= ~(u64(1) << (offset % BITSIZEOF(u64)));
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|
offset++;
|
|
}
|
|
}
|
|
|
|
void KMemoryManager::Impl::TrackOptimizedAllocation(KPhysicalAddress block, size_t num_pages) {
|
|
/* Get the range we're tracking. */
|
|
size_t offset = this->GetPageOffset(block);
|
|
const size_t last = offset + num_pages - 1;
|
|
|
|
/* Track. */
|
|
u64 *optimize_map = GetPointer<u64>(m_management_region);
|
|
while (offset <= last) {
|
|
/* Mark the page as being optimized-allocated. */
|
|
optimize_map[offset / BITSIZEOF(u64)] |= (u64(1) << (offset % BITSIZEOF(u64)));
|
|
|
|
offset++;
|
|
}
|
|
}
|
|
|
|
bool KMemoryManager::Impl::ProcessOptimizedAllocation(KPhysicalAddress block, size_t num_pages, u8 fill_pattern) {
|
|
/* We want to return whether any pages were newly allocated. */
|
|
bool any_new = false;
|
|
|
|
/* Get the range we're processing. */
|
|
size_t offset = this->GetPageOffset(block);
|
|
const size_t last = offset + num_pages - 1;
|
|
|
|
/* Process. */
|
|
u64 *optimize_map = GetPointer<u64>(m_management_region);
|
|
while (offset <= last) {
|
|
/* Check if the page has been optimized-allocated before. */
|
|
if ((optimize_map[offset / BITSIZEOF(u64)] & (u64(1) << (offset % BITSIZEOF(u64)))) == 0) {
|
|
/* If not, it's new. */
|
|
any_new = true;
|
|
|
|
/* Fill the page. */
|
|
std::memset(GetVoidPointer(KMemoryLayout::GetLinearVirtualAddress(m_heap.GetAddress()) + offset * PageSize), fill_pattern, PageSize);
|
|
}
|
|
|
|
offset++;
|
|
}
|
|
|
|
/* Return the number of pages we processed. */
|
|
return any_new;
|
|
}
|
|
|
|
size_t KMemoryManager::Impl::CalculateManagementOverheadSize(size_t region_size) {
|
|
const size_t ref_count_size = (region_size / PageSize) * sizeof(u16);
|
|
const size_t optimize_map_size = (util::AlignUp((region_size / PageSize), BITSIZEOF(u64)) / BITSIZEOF(u64)) * sizeof(u64);
|
|
const size_t manager_meta_size = util::AlignUp(optimize_map_size + ref_count_size, PageSize);
|
|
const size_t page_heap_size = KPageHeap::CalculateManagementOverheadSize(region_size);
|
|
return manager_meta_size + page_heap_size;
|
|
}
|
|
|
|
}
|