Atmosphere/libraries/libmesosphere/source/kern_k_page_table_base.cpp

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/*
* Copyright (c) Atmosphère-NX
*
* 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 <mesosphere.hpp>
#include <mesosphere/kern_select_page_table.hpp>
namespace ams::kern {
namespace {
class KScopedLightLockPair {
NON_COPYABLE(KScopedLightLockPair);
NON_MOVEABLE(KScopedLightLockPair);
private:
KLightLock *m_lower;
KLightLock *m_upper;
public:
ALWAYS_INLINE KScopedLightLockPair(KLightLock &lhs, KLightLock &rhs) {
/* Ensure our locks are in a consistent order. */
if (std::addressof(lhs) <= std::addressof(rhs)) {
m_lower = std::addressof(lhs);
m_upper = std::addressof(rhs);
} else {
m_lower = std::addressof(rhs);
m_upper = std::addressof(lhs);
}
/* Acquire both locks. */
m_lower->Lock();
if (m_lower != m_upper) {
m_upper->Lock();
}
}
~KScopedLightLockPair() {
/* Unlock the upper lock. */
if (m_upper != nullptr && m_upper != m_lower) {
m_upper->Unlock();
}
/* Unlock the lower lock. */
if (m_lower != nullptr) {
m_lower->Unlock();
}
}
public:
/* Utility. */
ALWAYS_INLINE void TryUnlockHalf(KLightLock &lock) {
/* Only allow unlocking if the lock is half the pair. */
if (m_lower != m_upper) {
/* We want to be sure the lock is one we own. */
if (m_lower == std::addressof(lock)) {
lock.Unlock();
m_lower = nullptr;
} else if (m_upper == std::addressof(lock)) {
lock.Unlock();
m_upper = nullptr;
}
}
}
};
}
void KPageTableBase::MemoryRange::Open() {
/* If the range contains heap pages, open them. */
if (this->IsHeap()) {
Kernel::GetMemoryManager().Open(this->GetAddress(), this->GetSize() / PageSize);
}
}
void KPageTableBase::MemoryRange::Close() {
/* If the range contains heap pages, close them. */
if (this->IsHeap()) {
Kernel::GetMemoryManager().Close(this->GetAddress(), this->GetSize() / PageSize);
}
}
Result KPageTableBase::InitializeForKernel(bool is_64_bit, void *table, KVirtualAddress start, KVirtualAddress end) {
/* Initialize our members. */
m_address_space_width = (is_64_bit) ? BITSIZEOF(u64) : BITSIZEOF(u32);
m_address_space_start = KProcessAddress(GetInteger(start));
m_address_space_end = KProcessAddress(GetInteger(end));
m_is_kernel = true;
m_enable_aslr = true;
m_enable_device_address_space_merge = false;
for (auto i = 0; i < RegionType_Count; ++i) {
m_region_starts[i] = 0;
m_region_ends[i] = 0;
}
m_current_heap_end = 0;
m_alias_code_region_start = 0;
m_alias_code_region_end = 0;
m_code_region_start = 0;
m_code_region_end = 0;
m_max_heap_size = 0;
m_mapped_physical_memory_size = 0;
m_mapped_unsafe_physical_memory = 0;
m_mapped_insecure_memory = 0;
m_mapped_ipc_server_memory = 0;
m_alias_region_extra_size = 0;
m_memory_block_slab_manager = Kernel::GetSystemSystemResource().GetMemoryBlockSlabManagerPointer();
m_block_info_manager = Kernel::GetSystemSystemResource().GetBlockInfoManagerPointer();
m_resource_limit = std::addressof(Kernel::GetSystemResourceLimit());
m_allocate_option = KMemoryManager::EncodeOption(KMemoryManager::Pool_System, KMemoryManager::Direction_FromFront);
m_heap_fill_value = MemoryFillValue_Zero;
m_ipc_fill_value = MemoryFillValue_Zero;
m_stack_fill_value = MemoryFillValue_Zero;
m_cached_physical_linear_region = nullptr;
m_cached_physical_heap_region = nullptr;
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/* Initialize our implementation. */
m_impl.InitializeForKernel(table, start, end);
/* Initialize our memory block manager. */
R_RETURN(m_memory_block_manager.Initialize(m_address_space_start, m_address_space_end, m_memory_block_slab_manager));
}
Result KPageTableBase::InitializeForProcess(ams::svc::CreateProcessFlag flags, bool from_back, KMemoryManager::Pool pool, void *table, KProcessAddress start, KProcessAddress end, KProcessAddress code_address, size_t code_size, KSystemResource *system_resource, KResourceLimit *resource_limit) {
/* Validate the region. */
MESOSPHERE_ABORT_UNLESS(start <= code_address);
MESOSPHERE_ABORT_UNLESS(code_address < code_address + code_size);
MESOSPHERE_ABORT_UNLESS(code_address + code_size - 1 <= end - 1);
/* Define helpers. */
auto GetSpaceStart = [&](KAddressSpaceInfo::Type type) ALWAYS_INLINE_LAMBDA {
return KAddressSpaceInfo::GetAddressSpaceStart(m_address_space_width, type);
};
auto GetSpaceSize = [&](KAddressSpaceInfo::Type type) ALWAYS_INLINE_LAMBDA {
return KAddressSpaceInfo::GetAddressSpaceSize(m_address_space_width, type);
};
/* Default to zero alias region extra size. */
m_alias_region_extra_size = 0;
/* Set our width and heap/alias sizes. */
m_address_space_width = GetAddressSpaceWidth(flags);
size_t alias_region_size = GetSpaceSize(KAddressSpaceInfo::Type_Alias);
size_t heap_region_size = GetSpaceSize(KAddressSpaceInfo::Type_Heap);
/* Adjust heap/alias size if we don't have an alias region. */
if ((flags & ams::svc::CreateProcessFlag_AddressSpaceMask) == ams::svc::CreateProcessFlag_AddressSpace32BitWithoutAlias) {
heap_region_size += alias_region_size;
alias_region_size = 0;
}
/* Set code regions and determine remaining sizes. */
KProcessAddress process_code_start;
KProcessAddress process_code_end;
size_t stack_region_size;
size_t kernel_map_region_size;
KProcessAddress before_process_code_start, after_process_code_start;
size_t before_process_code_size, after_process_code_size;
if (m_address_space_width == 39) {
stack_region_size = GetSpaceSize(KAddressSpaceInfo::Type_Stack);
kernel_map_region_size = GetSpaceSize(KAddressSpaceInfo::Type_MapSmall);
m_code_region_start = GetSpaceStart(KAddressSpaceInfo::Type_Map39Bit);
m_code_region_end = m_code_region_start + GetSpaceSize(KAddressSpaceInfo::Type_Map39Bit);
m_alias_code_region_start = m_code_region_start;
m_alias_code_region_end = m_code_region_end;
process_code_start = util::AlignDown(GetInteger(code_address), RegionAlignment);
process_code_end = util::AlignUp(GetInteger(code_address) + code_size, RegionAlignment);
before_process_code_start = m_code_region_start;
before_process_code_size = process_code_start - before_process_code_start;
after_process_code_start = process_code_end;
after_process_code_size = m_code_region_end - process_code_end;
/* If we have a 39-bit address space and should, enable extra size to the alias region. */
if (flags & ams::svc::CreateProcessFlag_EnableAliasRegionExtraSize) {
/* Extra size is 1/8th of the address space. */
m_alias_region_extra_size = (static_cast<size_t>(1) << m_address_space_width) / 8;
alias_region_size += m_alias_region_extra_size;
}
} else {
stack_region_size = 0;
kernel_map_region_size = 0;
m_code_region_start = GetSpaceStart(KAddressSpaceInfo::Type_MapSmall);
m_code_region_end = m_code_region_start + GetSpaceSize(KAddressSpaceInfo::Type_MapSmall);
m_alias_code_region_start = m_code_region_start;
m_alias_code_region_end = GetSpaceStart(KAddressSpaceInfo::Type_MapLarge) + GetSpaceSize(KAddressSpaceInfo::Type_MapLarge);
m_region_starts[RegionType_Stack] = m_code_region_start;
m_region_ends[RegionType_Stack] = m_code_region_end;
m_region_starts[RegionType_KernelMap] = m_code_region_start;
m_region_ends[RegionType_KernelMap] = m_code_region_end;
process_code_start = m_code_region_start;
process_code_end = m_code_region_end;
before_process_code_start = m_code_region_start;
before_process_code_size = 0;
after_process_code_start = GetSpaceStart(KAddressSpaceInfo::Type_MapLarge);
after_process_code_size = GetSpaceSize(KAddressSpaceInfo::Type_MapLarge);
}
/* Set other basic fields. */
m_enable_aslr = (flags & ams::svc::CreateProcessFlag_EnableAslr) != 0;
m_enable_device_address_space_merge = (flags & ams::svc::CreateProcessFlag_DisableDeviceAddressSpaceMerge) == 0;
m_address_space_start = start;
m_address_space_end = end;
m_is_kernel = false;
m_memory_block_slab_manager = system_resource->GetMemoryBlockSlabManagerPointer();
m_block_info_manager = system_resource->GetBlockInfoManagerPointer();
m_resource_limit = resource_limit;
/* Set up our undetermined regions. */
{
/* Declare helper structure for layout process. */
struct RegionLayoutInfo {
size_t size;
RegionType type;
s32 alloc_index; /* 0 for before process code, 1 for after process code */
};
/* Create region layout info array, and add regions to it. */
RegionLayoutInfo region_layouts[RegionType_Count] = {};
size_t num_regions = 0;
if (kernel_map_region_size > 0) { region_layouts[num_regions++] = { .size = kernel_map_region_size, .type = RegionType_KernelMap, .alloc_index = 0, }; }
if (stack_region_size > 0) { region_layouts[num_regions++] = { .size = stack_region_size, .type = RegionType_Stack, .alloc_index = 0, }; }
region_layouts[num_regions++] = { .size = alias_region_size, .type = RegionType_Alias, .alloc_index = 0, };
region_layouts[num_regions++] = { .size = heap_region_size, .type = RegionType_Heap, .alloc_index = 0, };
/* Selection-sort the regions by size largest-to-smallest. */
for (size_t i = 0; i < num_regions - 1; ++i) {
for (size_t j = i + 1; j < num_regions; ++j) {
if (region_layouts[i].size < region_layouts[j].size) {
std::swap(region_layouts[i], region_layouts[j]);
}
}
}
/* Layout the regions. */
constexpr auto AllocIndexCount = 2;
KProcessAddress alloc_starts[AllocIndexCount] = { before_process_code_start, after_process_code_start };
size_t alloc_sizes[AllocIndexCount] = { before_process_code_size, after_process_code_size };
size_t alloc_counts[AllocIndexCount] = {};
for (size_t i = 0; i < num_regions; ++i) {
/* Get reference to the current region. */
auto &cur_region = region_layouts[i];
/* Determine where the current region should go. */
cur_region.alloc_index = alloc_sizes[1] >= alloc_sizes[0] ? 1 : 0;
++alloc_counts[cur_region.alloc_index];
/* Check that the current region can fit. */
R_UNLESS(alloc_sizes[cur_region.alloc_index] >= cur_region.size, svc::ResultOutOfMemory());
/* Update our remaining size tracking. */
alloc_sizes[cur_region.alloc_index] -= cur_region.size;
}
/* Selection sort the regions to coalesce them by alloc index. */
for (size_t i = 0; i < num_regions - 1; ++i) {
for (size_t j = i + 1; j < num_regions; ++j) {
if (region_layouts[i].alloc_index > region_layouts[j].alloc_index) {
std::swap(region_layouts[i], region_layouts[j]);
}
}
}
/* Layout the regions for each alloc index. */
for (auto cur_alloc_index = 0; cur_alloc_index < AllocIndexCount; ++cur_alloc_index) {
/* If there are no regions to place, continue. */
const size_t cur_alloc_count = alloc_counts[cur_alloc_index];
if (cur_alloc_count == 0) {
continue;
}
/* Determine the starting region index for the current alloc index. */
size_t cur_region_index = 0;
for (size_t i = 0; i < num_regions; ++i) {
if (region_layouts[i].alloc_index == cur_alloc_index) {
cur_region_index = i;
break;
}
}
/* If aslr is enabled, randomize the current region order. Otherwise, sort by type. */
if (m_enable_aslr) {
for (size_t i = 0; i < cur_alloc_count - 1; ++i) {
std::swap(region_layouts[i], region_layouts[KSystemControl::GenerateRandomRange(i, cur_alloc_count - 1)]);
}
} else {
for (size_t i = 0; i < cur_alloc_count - 1; ++i) {
for (size_t j = i + 1; j < cur_alloc_count; ++j) {
if (region_layouts[cur_region_index + i].type > region_layouts[cur_region_index + j].type) {
std::swap(region_layouts[cur_region_index + i], region_layouts[cur_region_index + j]);
}
}
}
}
/* Determine aslr offsets for the current space. */
size_t aslr_offsets[RegionType_Count] = {};
if (m_enable_aslr) {
/* Generate the aslr offsets. */
for (size_t i = 0; i < cur_alloc_count; ++i) {
aslr_offsets[i] = KSystemControl::GenerateRandomRange(0, alloc_sizes[cur_alloc_index] / RegionAlignment) * RegionAlignment;
}
/* Sort the aslr offsets. */
for (size_t i = 0; i < cur_alloc_count - 1; ++i) {
for (size_t j = i + 1; j < cur_alloc_count; ++j) {
if (aslr_offsets[i] > aslr_offsets[j]) {
std::swap(aslr_offsets[i], aslr_offsets[j]);
}
}
}
}
/* Calculate final region positions. */
KProcessAddress prev_region_end = alloc_starts[cur_alloc_index];
size_t prev_aslr_offset = 0;
for (size_t i = 0; i < cur_alloc_count; ++i) {
/* Get the current region. */
auto &cur_region = region_layouts[cur_region_index + i];
/* Set the current region start/end. */
m_region_starts[cur_region.type] = (aslr_offsets[i] - prev_aslr_offset) + GetInteger(prev_region_end);
m_region_ends[cur_region.type] = m_region_starts[cur_region.type] + cur_region.size;
/* Update tracking variables. */
prev_region_end = m_region_ends[cur_region.type];
prev_aslr_offset = aslr_offsets[i];
}
}
/* Declare helpers to check that regions are inside our address space. */
const KProcessAddress process_code_last = process_code_end - 1;
auto IsInAddressSpace = [&](KProcessAddress addr) ALWAYS_INLINE_LAMBDA { return m_address_space_start <= addr && addr <= m_address_space_end; };
/* Ensure that the KernelMap region is valid. */
for (size_t k = 0; k < num_regions; ++k) {
if (const auto &kmap_region = region_layouts[k]; kmap_region.type == RegionType_KernelMap) {
/* If there's no kmap region, we have nothing to check. */
if (kmap_region.size == 0) {
break;
}
/* Check that the kmap region is within our address space. */
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_starts[RegionType_KernelMap]));
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_ends[RegionType_KernelMap]));
/* Check for overlap with process code. */
const KProcessAddress kmap_start = m_region_starts[RegionType_KernelMap];
const KProcessAddress kmap_last = m_region_ends[RegionType_KernelMap] - 1;
MESOSPHERE_ABORT_UNLESS(kernel_map_region_size == 0 || kmap_last < process_code_start || process_code_last < kmap_start);
/* Check for overlap with stack. */
for (size_t s = 0; s < num_regions; ++s) {
if (const auto &stack_region = region_layouts[s]; stack_region.type == RegionType_Stack) {
if (stack_region.size != 0) {
const KProcessAddress stack_start = m_region_starts[RegionType_Stack];
const KProcessAddress stack_last = m_region_ends[RegionType_Stack] - 1;
MESOSPHERE_ABORT_UNLESS((kernel_map_region_size == 0 && stack_region_size == 0) || kmap_last < stack_start || stack_last < kmap_start);
}
break;
}
}
/* Check for overlap with alias. */
for (size_t a = 0; a < num_regions; ++a) {
if (const auto &alias_region = region_layouts[a]; alias_region.type == RegionType_Alias) {
if (alias_region.size != 0) {
const KProcessAddress alias_start = m_region_starts[RegionType_Alias];
const KProcessAddress alias_last = m_region_ends[RegionType_Alias] - 1;
MESOSPHERE_ABORT_UNLESS(kmap_last < alias_start || alias_last < kmap_start);
}
break;
}
}
/* Check for overlap with heap. */
for (size_t h = 0; h < num_regions; ++h) {
if (const auto &heap_region = region_layouts[h]; heap_region.type == RegionType_Heap) {
if (heap_region.size != 0) {
const KProcessAddress heap_start = m_region_starts[RegionType_Heap];
const KProcessAddress heap_last = m_region_ends[RegionType_Heap] - 1;
MESOSPHERE_ABORT_UNLESS(kmap_last < heap_start || heap_last < kmap_start);
}
break;
}
}
}
}
/* Check that the Stack region is valid. */
for (size_t s = 0; s < num_regions; ++s) {
if (const auto &stack_region = region_layouts[s]; stack_region.type == RegionType_Stack) {
/* If there's no stack region, we have nothing to check. */
if (stack_region.size == 0) {
break;
}
/* Check that the stack region is within our address space. */
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_starts[RegionType_Stack]));
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_ends[RegionType_Stack]));
/* Check for overlap with process code. */
const KProcessAddress stack_start = m_region_starts[RegionType_Stack];
const KProcessAddress stack_last = m_region_ends[RegionType_Stack] - 1;
MESOSPHERE_ABORT_UNLESS(stack_region_size == 0 || stack_last < process_code_start || process_code_last < stack_start);
/* Check for overlap with alias. */
for (size_t a = 0; a < num_regions; ++a) {
if (const auto &alias_region = region_layouts[a]; alias_region.type == RegionType_Alias) {
if (alias_region.size != 0) {
const KProcessAddress alias_start = m_region_starts[RegionType_Alias];
const KProcessAddress alias_last = m_region_ends[RegionType_Alias] - 1;
MESOSPHERE_ABORT_UNLESS(stack_last < alias_start || alias_last < stack_start);
}
break;
}
}
/* Check for overlap with heap. */
for (size_t h = 0; h < num_regions; ++h) {
if (const auto &heap_region = region_layouts[h]; heap_region.type == RegionType_Heap) {
if (heap_region.size != 0) {
const KProcessAddress heap_start = m_region_starts[RegionType_Heap];
const KProcessAddress heap_last = m_region_ends[RegionType_Heap] - 1;
MESOSPHERE_ABORT_UNLESS(stack_last < heap_start || heap_last < stack_start);
}
break;
}
}
}
}
/* Check that the Alias region is valid. */
for (size_t a = 0; a < num_regions; ++a) {
if (const auto &alias_region = region_layouts[a]; alias_region.type == RegionType_Alias) {
/* If there's no alias region, we have nothing to check. */
if (alias_region.size == 0) {
break;
}
/* Check that the alias region is within our address space. */
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_starts[RegionType_Alias]));
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_ends[RegionType_Alias]));
/* Check for overlap with process code. */
const KProcessAddress alias_start = m_region_starts[RegionType_Alias];
const KProcessAddress alias_last = m_region_ends[RegionType_Alias] - 1;
MESOSPHERE_ABORT_UNLESS(alias_last < process_code_start || process_code_last < alias_start);
/* Check for overlap with heap. */
for (size_t h = 0; h < num_regions; ++h) {
if (const auto &heap_region = region_layouts[h]; heap_region.type == RegionType_Heap) {
if (heap_region.size != 0) {
const KProcessAddress heap_start = m_region_starts[RegionType_Heap];
const KProcessAddress heap_last = m_region_ends[RegionType_Heap] - 1;
MESOSPHERE_ABORT_UNLESS(alias_last < heap_start || heap_last < alias_start);
}
break;
}
}
}
}
/* Check that the Heap region is valid. */
for (size_t h = 0; h < num_regions; ++h) {
if (const auto &heap_region = region_layouts[h]; heap_region.type == RegionType_Heap) {
/* If there's no heap region, we have nothing to check. */
if (heap_region.size == 0) {
break;
}
/* Check that the heap region is within our address space. */
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_starts[RegionType_Heap]));
MESOSPHERE_ABORT_UNLESS(IsInAddressSpace(m_region_ends[RegionType_Heap]));
/* Check for overlap with process code. */
const KProcessAddress heap_start = m_region_starts[RegionType_Heap];
const KProcessAddress heap_last = m_region_ends[RegionType_Heap] - 1;
MESOSPHERE_ABORT_UNLESS(heap_last < process_code_start || process_code_last < heap_start);
}
}
}
/* Set heap and fill members. */
m_current_heap_end = m_region_starts[RegionType_Heap];
m_max_heap_size = 0;
m_mapped_physical_memory_size = 0;
m_mapped_unsafe_physical_memory = 0;
m_mapped_insecure_memory = 0;
m_mapped_ipc_server_memory = 0;
const bool fill_memory = KTargetSystem::IsDebugMemoryFillEnabled();
m_heap_fill_value = fill_memory ? MemoryFillValue_Heap : MemoryFillValue_Zero;
m_ipc_fill_value = fill_memory ? MemoryFillValue_Ipc : MemoryFillValue_Zero;
m_stack_fill_value = fill_memory ? MemoryFillValue_Stack : MemoryFillValue_Zero;
/* Set allocation option. */
m_allocate_option = KMemoryManager::EncodeOption(pool, from_back ? KMemoryManager::Direction_FromBack : KMemoryManager::Direction_FromFront);
/* Initialize our implementation. */
m_impl.InitializeForProcess(table, GetInteger(start), GetInteger(end));
/* Initialize our memory block manager. */
R_RETURN(m_memory_block_manager.Initialize(m_address_space_start, m_address_space_end, m_memory_block_slab_manager));
}
void KPageTableBase::Finalize() {
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/* Finalize memory blocks. */
m_memory_block_manager.Finalize(m_memory_block_slab_manager);
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/* Free any unsafe mapped memory. */
if (m_mapped_unsafe_physical_memory) {
Kernel::GetUnsafeMemory().Release(m_mapped_unsafe_physical_memory);
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}
/* Release any insecure mapped memory. */
if (m_mapped_insecure_memory) {
if (auto * const insecure_resource_limit = KSystemControl::GetInsecureMemoryResourceLimit(); insecure_resource_limit != nullptr) {
insecure_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, m_mapped_insecure_memory);
}
}
/* Release any ipc server memory. */
if (m_mapped_ipc_server_memory) {
m_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, m_mapped_ipc_server_memory);
}
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/* Invalidate the entire instruction cache. */
cpu::InvalidateEntireInstructionCache();
}
KProcessAddress KPageTableBase::GetRegionAddress(ams::svc::MemoryState state) const {
switch (state) {
case ams::svc::MemoryState_Free:
case ams::svc::MemoryState_Kernel:
return m_address_space_start;
case ams::svc::MemoryState_Normal:
return m_region_starts[RegionType_Heap];
case ams::svc::MemoryState_Ipc:
case ams::svc::MemoryState_NonSecureIpc:
case ams::svc::MemoryState_NonDeviceIpc:
return m_region_starts[RegionType_Alias];
case ams::svc::MemoryState_Stack:
return m_region_starts[RegionType_Stack];
case ams::svc::MemoryState_Static:
case ams::svc::MemoryState_ThreadLocal:
return m_region_starts[RegionType_KernelMap];
case ams::svc::MemoryState_Io:
case ams::svc::MemoryState_Shared:
case ams::svc::MemoryState_AliasCode:
case ams::svc::MemoryState_AliasCodeData:
case ams::svc::MemoryState_Transfered:
case ams::svc::MemoryState_SharedTransfered:
case ams::svc::MemoryState_SharedCode:
case ams::svc::MemoryState_GeneratedCode:
case ams::svc::MemoryState_CodeOut:
case ams::svc::MemoryState_Coverage:
case ams::svc::MemoryState_Insecure:
return m_alias_code_region_start;
case ams::svc::MemoryState_Code:
case ams::svc::MemoryState_CodeData:
return m_code_region_start;
MESOSPHERE_UNREACHABLE_DEFAULT_CASE();
}
}
size_t KPageTableBase::GetRegionSize(ams::svc::MemoryState state) const {
switch (state) {
case ams::svc::MemoryState_Free:
case ams::svc::MemoryState_Kernel:
return m_address_space_end - m_address_space_start;
case ams::svc::MemoryState_Normal:
return m_region_ends[RegionType_Heap] - m_region_starts[RegionType_Heap];
case ams::svc::MemoryState_Ipc:
case ams::svc::MemoryState_NonSecureIpc:
case ams::svc::MemoryState_NonDeviceIpc:
return m_region_ends[RegionType_Alias] - m_region_starts[RegionType_Alias];
case ams::svc::MemoryState_Stack:
return m_region_ends[RegionType_Stack] - m_region_starts[RegionType_Stack];
case ams::svc::MemoryState_Static:
case ams::svc::MemoryState_ThreadLocal:
return m_region_ends[RegionType_KernelMap] - m_region_starts[RegionType_KernelMap];
case ams::svc::MemoryState_Io:
case ams::svc::MemoryState_Shared:
case ams::svc::MemoryState_AliasCode:
case ams::svc::MemoryState_AliasCodeData:
case ams::svc::MemoryState_Transfered:
case ams::svc::MemoryState_SharedTransfered:
case ams::svc::MemoryState_SharedCode:
case ams::svc::MemoryState_GeneratedCode:
case ams::svc::MemoryState_CodeOut:
case ams::svc::MemoryState_Coverage:
case ams::svc::MemoryState_Insecure:
return m_alias_code_region_end - m_alias_code_region_start;
case ams::svc::MemoryState_Code:
case ams::svc::MemoryState_CodeData:
return m_code_region_end - m_code_region_start;
MESOSPHERE_UNREACHABLE_DEFAULT_CASE();
}
}
bool KPageTableBase::CanContain(KProcessAddress addr, size_t size, ams::svc::MemoryState state) const {
const KProcessAddress end = addr + size;
const KProcessAddress last = end - 1;
const KProcessAddress region_start = this->GetRegionAddress(state);
const size_t region_size = this->GetRegionSize(state);
const bool is_in_region = region_start <= addr && addr < end && last <= region_start + region_size - 1;
const bool is_in_heap = !(end <= m_region_starts[RegionType_Heap] || m_region_ends[RegionType_Heap] <= addr || m_region_starts[RegionType_Heap] == m_region_ends[RegionType_Heap]);
const bool is_in_alias = !(end <= m_region_starts[RegionType_Alias] || m_region_ends[RegionType_Alias] <= addr || m_region_starts[RegionType_Alias] == m_region_ends[RegionType_Alias]);
switch (state) {
case ams::svc::MemoryState_Free:
case ams::svc::MemoryState_Kernel:
return is_in_region;
case ams::svc::MemoryState_Io:
case ams::svc::MemoryState_Static:
case ams::svc::MemoryState_Code:
case ams::svc::MemoryState_CodeData:
case ams::svc::MemoryState_Shared:
case ams::svc::MemoryState_AliasCode:
case ams::svc::MemoryState_AliasCodeData:
case ams::svc::MemoryState_Stack:
case ams::svc::MemoryState_ThreadLocal:
case ams::svc::MemoryState_Transfered:
case ams::svc::MemoryState_SharedTransfered:
case ams::svc::MemoryState_SharedCode:
case ams::svc::MemoryState_GeneratedCode:
case ams::svc::MemoryState_CodeOut:
case ams::svc::MemoryState_Coverage:
case ams::svc::MemoryState_Insecure:
return is_in_region && !is_in_heap && !is_in_alias;
case ams::svc::MemoryState_Normal:
MESOSPHERE_ASSERT(is_in_heap);
return is_in_region && !is_in_alias;
case ams::svc::MemoryState_Ipc:
case ams::svc::MemoryState_NonSecureIpc:
case ams::svc::MemoryState_NonDeviceIpc:
MESOSPHERE_ASSERT(is_in_alias);
return is_in_region && !is_in_heap;
default:
return false;
}
}
Result KPageTableBase::CheckMemoryState(const KMemoryInfo &info, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr) const {
/* Validate the states match expectation. */
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R_UNLESS((info.m_state & state_mask) == state, svc::ResultInvalidCurrentMemory());
R_UNLESS((info.m_permission & perm_mask) == perm, svc::ResultInvalidCurrentMemory());
R_UNLESS((info.m_attribute & attr_mask) == attr, svc::ResultInvalidCurrentMemory());
R_SUCCEED();
}
Result KPageTableBase::CheckMemoryStateContiguous(size_t *out_blocks_needed, KProcessAddress addr, size_t size, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr) const {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Get information about the first block. */
const KProcessAddress last_addr = addr + size - 1;
KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(addr);
KMemoryInfo info = it->GetMemoryInfo();
/* If the start address isn't aligned, we need a block. */
const size_t blocks_for_start_align = (util::AlignDown(GetInteger(addr), PageSize) != info.GetAddress()) ? 1 : 0;
while (true) {
/* Validate against the provided masks. */
R_TRY(this->CheckMemoryState(info, state_mask, state, perm_mask, perm, attr_mask, attr));
/* Break once we're done. */
if (last_addr <= info.GetLastAddress()) {
break;
}
/* Advance our iterator. */
it++;
MESOSPHERE_ASSERT(it != m_memory_block_manager.cend());
info = it->GetMemoryInfo();
}
/* If the end address isn't aligned, we need a block. */
const size_t blocks_for_end_align = (util::AlignUp(GetInteger(addr) + size, PageSize) != info.GetEndAddress()) ? 1 : 0;
if (out_blocks_needed != nullptr) {
*out_blocks_needed = blocks_for_start_align + blocks_for_end_align;
}
R_SUCCEED();
}
Result KPageTableBase::CheckMemoryState(KMemoryState *out_state, KMemoryPermission *out_perm, KMemoryAttribute *out_attr, size_t *out_blocks_needed, KMemoryBlockManager::const_iterator it, KProcessAddress last_addr, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr, u32 ignore_attr) const {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Get information about the first block. */
KMemoryInfo info = it->GetMemoryInfo();
/* Validate all blocks in the range have correct state. */
const KMemoryState first_state = info.m_state;
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const KMemoryPermission first_perm = info.m_permission;
const KMemoryAttribute first_attr = info.m_attribute;
while (true) {
/* Validate the current block. */
R_UNLESS(info.m_state == first_state, svc::ResultInvalidCurrentMemory());
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R_UNLESS(info.m_permission == first_perm, svc::ResultInvalidCurrentMemory());
R_UNLESS((info.m_attribute | ignore_attr) == (first_attr | ignore_attr), svc::ResultInvalidCurrentMemory());
/* Validate against the provided masks. */
R_TRY(this->CheckMemoryState(info, state_mask, state, perm_mask, perm, attr_mask, attr));
/* Break once we're done. */
if (last_addr <= info.GetLastAddress()) {
break;
}
/* Advance our iterator. */
it++;
MESOSPHERE_ASSERT(it != m_memory_block_manager.cend());
info = it->GetMemoryInfo();
}
/* Write output state. */
if (out_state != nullptr) {
*out_state = first_state;
}
if (out_perm != nullptr) {
*out_perm = first_perm;
}
if (out_attr != nullptr) {
*out_attr = static_cast<KMemoryAttribute>(first_attr & ~ignore_attr);
}
/* If the end address isn't aligned, we need a block. */
if (out_blocks_needed != nullptr) {
const size_t blocks_for_end_align = (util::AlignDown(GetInteger(last_addr), PageSize) + PageSize != info.GetEndAddress()) ? 1 : 0;
*out_blocks_needed = blocks_for_end_align;
}
R_SUCCEED();
}
Result KPageTableBase::CheckMemoryState(KMemoryState *out_state, KMemoryPermission *out_perm, KMemoryAttribute *out_attr, size_t *out_blocks_needed, KProcessAddress addr, size_t size, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr, u32 ignore_attr) const {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Check memory state. */
const KProcessAddress last_addr = addr + size - 1;
KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(addr);
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R_TRY(this->CheckMemoryState(out_state, out_perm, out_attr, out_blocks_needed, it, last_addr, state_mask, state, perm_mask, perm, attr_mask, attr, ignore_attr));
/* If the start address isn't aligned, we need a block. */
if (out_blocks_needed != nullptr && util::AlignDown(GetInteger(addr), PageSize) != it->GetAddress()) {
++(*out_blocks_needed);
}
R_SUCCEED();
}
Result KPageTableBase::LockMemoryAndOpen(KPageGroup *out_pg, KPhysicalAddress *out_paddr, KProcessAddress addr, size_t size, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr, KMemoryPermission new_perm, u32 lock_attr) {
/* Validate basic preconditions. */
MESOSPHERE_ASSERT((lock_attr & attr) == 0);
MESOSPHERE_ASSERT((lock_attr & (KMemoryAttribute_IpcLocked | KMemoryAttribute_DeviceShared)) == 0);
/* Validate the lock request. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(addr, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check that the output page group is empty, if it exists. */
if (out_pg) {
MESOSPHERE_ASSERT(out_pg->GetNumPages() == 0);
}
/* Check the state. */
KMemoryState old_state;
KMemoryPermission old_perm;
KMemoryAttribute old_attr;
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), std::addressof(old_attr), std::addressof(num_allocator_blocks), addr, size, state_mask | KMemoryState_FlagReferenceCounted, state | KMemoryState_FlagReferenceCounted, perm_mask, perm, attr_mask, attr));
/* Get the physical address, if we're supposed to. */
if (out_paddr != nullptr) {
MESOSPHERE_ABORT_UNLESS(this->GetPhysicalAddressLocked(out_paddr, addr));
}
/* Make the page group, if we're supposed to. */
if (out_pg != nullptr) {
R_TRY(this->MakePageGroup(*out_pg, addr, num_pages));
}
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Decide on new perm and attr. */
new_perm = (new_perm != KMemoryPermission_None) ? new_perm : old_perm;
KMemoryAttribute new_attr = static_cast<KMemoryAttribute>(old_attr | lock_attr);
/* Update permission, if we need to. */
if (new_perm != old_perm) {
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
const KPageProperties properties = { new_perm, false, (old_attr & KMemoryAttribute_Uncached) != 0, DisableMergeAttribute_DisableHeadBodyTail };
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
}
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, old_state, new_perm, new_attr, KMemoryBlockDisableMergeAttribute_Locked, KMemoryBlockDisableMergeAttribute_None);
/* If we have an output group, open. */
if (out_pg) {
out_pg->Open();
}
R_SUCCEED();
}
Result KPageTableBase::UnlockMemory(KProcessAddress addr, size_t size, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr, KMemoryPermission new_perm, u32 lock_attr, const KPageGroup *pg) {
/* Validate basic preconditions. */
MESOSPHERE_ASSERT((attr_mask & lock_attr) == lock_attr);
MESOSPHERE_ASSERT((attr & lock_attr) == lock_attr);
/* Validate the unlock request. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(addr, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the state. */
KMemoryState old_state;
KMemoryPermission old_perm;
KMemoryAttribute old_attr;
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), std::addressof(old_attr), std::addressof(num_allocator_blocks), addr, size, state_mask | KMemoryState_FlagReferenceCounted, state | KMemoryState_FlagReferenceCounted, perm_mask, perm, attr_mask, attr));
/* Check the page group. */
if (pg != nullptr) {
R_UNLESS(this->IsValidPageGroup(*pg, addr, num_pages), svc::ResultInvalidMemoryRegion());
}
/* Decide on new perm and attr. */
new_perm = (new_perm != KMemoryPermission_None) ? new_perm : old_perm;
KMemoryAttribute new_attr = static_cast<KMemoryAttribute>(old_attr & ~lock_attr);
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Update permission, if we need to. */
if (new_perm != old_perm) {
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
const KPageProperties properties = { new_perm, false, (old_attr & KMemoryAttribute_Uncached) != 0, DisableMergeAttribute_EnableAndMergeHeadBodyTail };
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
}
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, old_state, new_perm, new_attr, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Locked);
R_SUCCEED();
}
Result KPageTableBase::QueryInfoImpl(KMemoryInfo *out_info, ams::svc::PageInfo *out_page, KProcessAddress address) const {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
MESOSPHERE_ASSERT(out_info != nullptr);
MESOSPHERE_ASSERT(out_page != nullptr);
const KMemoryBlock *block = m_memory_block_manager.FindBlock(address);
R_UNLESS(block != nullptr, svc::ResultInvalidCurrentMemory());
*out_info = block->GetMemoryInfo();
out_page->flags = 0;
R_SUCCEED();
}
Result KPageTableBase::QueryMappingImpl(KProcessAddress *out, KPhysicalAddress address, size_t size, ams::svc::MemoryState state) const {
MESOSPHERE_ASSERT(!this->IsLockedByCurrentThread());
MESOSPHERE_ASSERT(out != nullptr);
const KProcessAddress region_start = this->GetRegionAddress(state);
const size_t region_size = this->GetRegionSize(state);
/* Check that the address/size are potentially valid. */
R_UNLESS((address < address + size), svc::ResultNotFound());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry cur_entry = { .phys_addr = Null<KPhysicalAddress>, .block_size = 0, .sw_reserved_bits = 0, .attr = 0 };
bool cur_valid = false;
TraversalEntry next_entry;
bool next_valid;
size_t tot_size = 0;
next_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), region_start);
next_entry.block_size = (next_entry.block_size - (GetInteger(region_start) & (next_entry.block_size - 1)));
/* Iterate, looking for entry. */
while (true) {
if ((!next_valid && !cur_valid) || (next_valid && cur_valid && next_entry.phys_addr == cur_entry.phys_addr + cur_entry.block_size)) {
cur_entry.block_size += next_entry.block_size;
} else {
if (cur_valid && cur_entry.phys_addr <= address && address + size <= cur_entry.phys_addr + cur_entry.block_size) {
/* Check if this region is valid. */
const KProcessAddress mapped_address = (region_start + tot_size) + (address - cur_entry.phys_addr);
if (R_SUCCEEDED(this->CheckMemoryState(mapped_address, size, KMemoryState_Mask, static_cast<KMemoryState>(util::ToUnderlying(state)), KMemoryPermission_UserRead, KMemoryPermission_UserRead, KMemoryAttribute_None, KMemoryAttribute_None))) {
/* It is! */
*out = mapped_address;
R_SUCCEED();
}
}
/* Update tracking variables. */
tot_size += cur_entry.block_size;
cur_entry = next_entry;
cur_valid = next_valid;
}
if (cur_entry.block_size + tot_size >= region_size) {
break;
}
next_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
}
/* Check the last entry. */
R_UNLESS(cur_valid, svc::ResultNotFound());
R_UNLESS(cur_entry.phys_addr <= address, svc::ResultNotFound());
R_UNLESS(address + size <= cur_entry.phys_addr + cur_entry.block_size, svc::ResultNotFound());
/* Check if the last region is valid. */
const KProcessAddress mapped_address = (region_start + tot_size) + (address - cur_entry.phys_addr);
R_TRY_CATCH(this->CheckMemoryState(mapped_address, size, KMemoryState_All, state, KMemoryPermission_UserRead, KMemoryPermission_UserRead, KMemoryAttribute_None, KMemoryAttribute_None)) {
R_CONVERT_ALL(svc::ResultNotFound());
} R_END_TRY_CATCH;
/* We found the region. */
*out = mapped_address;
R_SUCCEED();
}
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Result KPageTableBase::MapMemory(KProcessAddress dst_address, KProcessAddress src_address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Validate that the source address's state is valid. */
KMemoryState src_state;
size_t num_src_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(src_state), nullptr, nullptr, std::addressof(num_src_allocator_blocks), src_address, size, KMemoryState_FlagCanAlias, KMemoryState_FlagCanAlias, KMemoryPermission_All, KMemoryPermission_UserReadWrite, KMemoryAttribute_All, KMemoryAttribute_None));
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/* Validate that the dst address's state is valid. */
size_t num_dst_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_dst_allocator_blocks), dst_address, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
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/* Create an update allocator for the source. */
Result src_allocator_result;
KMemoryBlockManagerUpdateAllocator src_allocator(std::addressof(src_allocator_result), m_memory_block_slab_manager, num_src_allocator_blocks);
R_TRY(src_allocator_result);
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/* Create an update allocator for the destination. */
Result dst_allocator_result;
KMemoryBlockManagerUpdateAllocator dst_allocator(std::addressof(dst_allocator_result), m_memory_block_slab_manager, num_dst_allocator_blocks);
R_TRY(dst_allocator_result);
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/* Map the memory. */
{
/* Determine the number of pages being operated on. */
const size_t num_pages = size / PageSize;
/* Create page groups for the memory being unmapped. */
KPageGroup pg(m_block_info_manager);
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/* Create the page group representing the source. */
R_TRY(this->MakePageGroup(pg, src_address, num_pages));
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Reprotect the source as kernel-read/not mapped. */
const KMemoryPermission new_src_perm = static_cast<KMemoryPermission>(KMemoryPermission_KernelRead | KMemoryPermission_NotMapped);
const KMemoryAttribute new_src_attr = KMemoryAttribute_Locked;
const KPageProperties src_properties = { new_src_perm, false, false, DisableMergeAttribute_DisableHeadBodyTail };
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R_TRY(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, src_properties, OperationType_ChangePermissions, false));
/* Ensure that we unprotect the source pages on failure. */
ON_RESULT_FAILURE {
const KPageProperties unprotect_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_EnableHeadBodyTail };
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MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, unprotect_properties, OperationType_ChangePermissions, true));
};
/* Map the alias pages. */
const KPageProperties dst_map_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_DisableHead };
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R_TRY(this->MapPageGroupImpl(updater.GetPageList(), dst_address, pg, dst_map_properties, false));
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(src_allocator), src_address, num_pages, src_state, new_src_perm, new_src_attr, KMemoryBlockDisableMergeAttribute_Locked, KMemoryBlockDisableMergeAttribute_None);
m_memory_block_manager.Update(std::addressof(dst_allocator), dst_address, num_pages, KMemoryState_Stack, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
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}
R_SUCCEED();
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}
Result KPageTableBase::UnmapMemory(KProcessAddress dst_address, KProcessAddress src_address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Validate that the source address's state is valid. */
KMemoryState src_state;
size_t num_src_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(src_state), nullptr, nullptr, std::addressof(num_src_allocator_blocks), src_address, size, KMemoryState_FlagCanAlias, KMemoryState_FlagCanAlias, KMemoryPermission_All, KMemoryPermission_NotMapped | KMemoryPermission_KernelRead, KMemoryAttribute_All, KMemoryAttribute_Locked));
/* Validate that the dst address's state is valid. */
KMemoryPermission dst_perm;
size_t num_dst_allocator_blocks;
R_TRY(this->CheckMemoryState(nullptr, std::addressof(dst_perm), nullptr, std::addressof(num_dst_allocator_blocks), dst_address, size, KMemoryState_All, KMemoryState_Stack, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
/* Create an update allocator for the source. */
Result src_allocator_result;
KMemoryBlockManagerUpdateAllocator src_allocator(std::addressof(src_allocator_result), m_memory_block_slab_manager, num_src_allocator_blocks);
R_TRY(src_allocator_result);
/* Create an update allocator for the destination. */
Result dst_allocator_result;
KMemoryBlockManagerUpdateAllocator dst_allocator(std::addressof(dst_allocator_result), m_memory_block_slab_manager, num_dst_allocator_blocks);
R_TRY(dst_allocator_result);
/* Unmap the memory. */
{
/* Determine the number of pages being operated on. */
const size_t num_pages = size / PageSize;
/* Create page groups for the memory being unmapped. */
KPageGroup pg(m_block_info_manager);
/* Create the page group representing the destination. */
R_TRY(this->MakePageGroup(pg, dst_address, num_pages));
/* Ensure the page group is the valid for the source. */
R_UNLESS(this->IsValidPageGroup(pg, src_address, num_pages), svc::ResultInvalidMemoryRegion());
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the aliased copy of the pages. */
const KPageProperties dst_unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), dst_address, num_pages, Null<KPhysicalAddress>, false, dst_unmap_properties, OperationType_Unmap, false));
/* Ensure that we re-map the aliased pages on failure. */
ON_RESULT_FAILURE {
this->RemapPageGroup(updater.GetPageList(), dst_address, size, pg);
};
/* Try to set the permissions for the source pages back to what they should be. */
const KPageProperties src_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_EnableAndMergeHeadBodyTail };
R_TRY(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, src_properties, OperationType_ChangePermissions, false));
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(src_allocator), src_address, num_pages, src_state, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Locked);
m_memory_block_manager.Update(std::addressof(dst_allocator), dst_address, num_pages, KMemoryState_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
}
R_SUCCEED();
}
Result KPageTableBase::MapCodeMemory(KProcessAddress dst_address, KProcessAddress src_address, size_t size) {
/* Validate the mapping request. */
R_UNLESS(this->CanContain(dst_address, size, KMemoryState_AliasCode), svc::ResultInvalidMemoryRegion());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Verify that the source memory is normal heap. */
KMemoryState src_state;
KMemoryPermission src_perm;
size_t num_src_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(src_state), std::addressof(src_perm), nullptr, std::addressof(num_src_allocator_blocks), src_address, size, KMemoryState_All, KMemoryState_Normal, KMemoryPermission_All, KMemoryPermission_UserReadWrite, KMemoryAttribute_All, KMemoryAttribute_None));
/* Verify that the destination memory is unmapped. */
size_t num_dst_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_dst_allocator_blocks), dst_address, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator for the source. */
Result src_allocator_result;
KMemoryBlockManagerUpdateAllocator src_allocator(std::addressof(src_allocator_result), m_memory_block_slab_manager, num_src_allocator_blocks);
R_TRY(src_allocator_result);
/* Create an update allocator for the destination. */
Result dst_allocator_result;
KMemoryBlockManagerUpdateAllocator dst_allocator(std::addressof(dst_allocator_result), m_memory_block_slab_manager, num_dst_allocator_blocks);
R_TRY(dst_allocator_result);
/* Map the code memory. */
{
/* Determine the number of pages being operated on. */
const size_t num_pages = size / PageSize;
/* Create page groups for the memory being unmapped. */
KPageGroup pg(m_block_info_manager);
/* Create the page group representing the source. */
R_TRY(this->MakePageGroup(pg, src_address, num_pages));
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Reprotect the source as kernel-read/not mapped. */
const KMemoryPermission new_perm = static_cast<KMemoryPermission>(KMemoryPermission_KernelRead | KMemoryPermission_NotMapped);
const KPageProperties src_properties = { new_perm, false, false, DisableMergeAttribute_DisableHeadBodyTail };
R_TRY(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, src_properties, OperationType_ChangePermissions, false));
/* Ensure that we unprotect the source pages on failure. */
ON_RESULT_FAILURE {
const KPageProperties unprotect_properties = { src_perm, false, false, DisableMergeAttribute_EnableHeadBodyTail };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, unprotect_properties, OperationType_ChangePermissions, true));
};
/* Map the alias pages. */
const KPageProperties dst_properties = { new_perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->MapPageGroupImpl(updater.GetPageList(), dst_address, pg, dst_properties, false));
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(src_allocator), src_address, num_pages, src_state, new_perm, KMemoryAttribute_Locked, KMemoryBlockDisableMergeAttribute_Locked, KMemoryBlockDisableMergeAttribute_None);
m_memory_block_manager.Update(std::addressof(dst_allocator), dst_address, num_pages, KMemoryState_AliasCode, new_perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
}
R_SUCCEED();
}
Result KPageTableBase::UnmapCodeMemory(KProcessAddress dst_address, KProcessAddress src_address, size_t size) {
/* Validate the mapping request. */
R_UNLESS(this->CanContain(dst_address, size, KMemoryState_AliasCode), svc::ResultInvalidMemoryRegion());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Verify that the source memory is locked normal heap. */
size_t num_src_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_src_allocator_blocks), src_address, size, KMemoryState_All, KMemoryState_Normal, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_Locked));
/* Verify that the destination memory is aliasable code. */
size_t num_dst_allocator_blocks;
R_TRY(this->CheckMemoryStateContiguous(std::addressof(num_dst_allocator_blocks), dst_address, size, KMemoryState_FlagCanCodeAlias, KMemoryState_FlagCanCodeAlias, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All & ~KMemoryAttribute_PermissionLocked, KMemoryAttribute_None));
/* Determine whether any pages being unmapped are code. */
bool any_code_pages = false;
{
KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(dst_address);
while (true) {
/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* Check if the memory has code flag. */
if ((info.GetState() & KMemoryState_FlagCode) != 0) {
any_code_pages = true;
break;
}
/* Check if we're done. */
if (dst_address + size - 1 <= info.GetLastAddress()) {
break;
}
/* Advance. */
++it;
}
}
/* Ensure that we maintain the instruction cache. */
bool reprotected_pages = false;
ON_SCOPE_EXIT {
if (reprotected_pages && any_code_pages) {
cpu::InvalidateEntireInstructionCache();
}
};
/* Unmap. */
{
/* Determine the number of pages being operated on. */
const size_t num_pages = size / PageSize;
/* Create page groups for the memory being unmapped. */
KPageGroup pg(m_block_info_manager);
/* Create the page group representing the destination. */
R_TRY(this->MakePageGroup(pg, dst_address, num_pages));
/* Verify that the page group contains the same pages as the source. */
R_UNLESS(this->IsValidPageGroup(pg, src_address, num_pages), svc::ResultInvalidMemoryRegion());
/* Create an update allocator for the source. */
Result src_allocator_result;
KMemoryBlockManagerUpdateAllocator src_allocator(std::addressof(src_allocator_result), m_memory_block_slab_manager, num_src_allocator_blocks);
R_TRY(src_allocator_result);
/* Create an update allocator for the destination. */
Result dst_allocator_result;
KMemoryBlockManagerUpdateAllocator dst_allocator(std::addressof(dst_allocator_result), m_memory_block_slab_manager, num_dst_allocator_blocks);
R_TRY(dst_allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the aliased copy of the pages. */
const KPageProperties dst_unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), dst_address, num_pages, Null<KPhysicalAddress>, false, dst_unmap_properties, OperationType_Unmap, false));
/* Ensure that we re-map the aliased pages on failure. */
ON_RESULT_FAILURE {
this->RemapPageGroup(updater.GetPageList(), dst_address, size, pg);
};
/* Try to set the permissions for the source pages back to what they should be. */
const KPageProperties src_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_EnableAndMergeHeadBodyTail };
R_TRY(this->Operate(updater.GetPageList(), src_address, num_pages, Null<KPhysicalAddress>, false, src_properties, OperationType_ChangePermissions, false));
/* Apply the memory block updates. */
m_memory_block_manager.Update(std::addressof(dst_allocator), dst_address, num_pages, KMemoryState_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
m_memory_block_manager.Update(std::addressof(src_allocator), src_address, num_pages, KMemoryState_Normal, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Locked);
/* Note that we reprotected pages. */
reprotected_pages = true;
}
R_SUCCEED();
}
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Result KPageTableBase::MapInsecurePhysicalMemory(KProcessAddress address, size_t size) {
/* Get the insecure memory resource limit and pool. */
auto * const insecure_resource_limit = KSystemControl::GetInsecureMemoryResourceLimit();
const auto insecure_pool = static_cast<KMemoryManager::Pool>(KSystemControl::GetInsecureMemoryPool());
/* Reserve the insecure memory. */
/* NOTE: ResultOutOfMemory is returned here instead of the usual LimitReached. */
KScopedResourceReservation memory_reservation(insecure_resource_limit, ams::svc::LimitableResource_PhysicalMemoryMax, size);
R_UNLESS(memory_reservation.Succeeded(), svc::ResultOutOfMemory());
/* Allocate pages for the insecure memory. */
KPageGroup pg(m_block_info_manager);
R_TRY(Kernel::GetMemoryManager().AllocateAndOpen(std::addressof(pg), size / PageSize, 1, KMemoryManager::EncodeOption(insecure_pool, KMemoryManager::Direction_FromFront)));
/* Close the opened pages when we're done with them. */
/* If the mapping succeeds, each page will gain an extra reference, otherwise they will be freed automatically. */
ON_SCOPE_EXIT { pg.Close(); };
/* Clear all the newly allocated pages. */
for (const auto &it : pg) {
std::memset(GetVoidPointer(GetHeapVirtualAddress(it.GetAddress())), m_heap_fill_value, it.GetSize());
}
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Validate that the address's state is valid. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Map the pages. */
const size_t num_pages = size / PageSize;
const KPageProperties map_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(updater.GetPageList(), address, num_pages, pg, map_properties, OperationType_MapGroup, false));
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Insecure, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* Update our mapped insecure size. */
m_mapped_insecure_memory += size;
/* Commit the memory reservation. */
memory_reservation.Commit();
/* We succeeded. */
R_SUCCEED();
}
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Result KPageTableBase::UnmapInsecurePhysicalMemory(KProcessAddress address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, KMemoryState_Insecure, KMemoryPermission_All, KMemoryPermission_UserReadWrite, KMemoryAttribute_All, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the memory. */
const size_t num_pages = size / PageSize;
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), address, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
/* Update our mapped insecure size. */
m_mapped_insecure_memory -= size;
/* Release the insecure memory from the insecure limit. */
if (auto * const insecure_resource_limit = KSystemControl::GetInsecureMemoryResourceLimit(); insecure_resource_limit != nullptr) {
insecure_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, size);
}
R_SUCCEED();
}
KProcessAddress KPageTableBase::FindFreeArea(KProcessAddress region_start, size_t region_num_pages, size_t num_pages, size_t alignment, size_t offset, size_t guard_pages) const {
KProcessAddress address = Null<KProcessAddress>;
if (num_pages <= region_num_pages) {
if (this->IsAslrEnabled()) {
/* Try to directly find a free area up to 8 times. */
for (size_t i = 0; i < 8; i++) {
const size_t random_offset = KSystemControl::GenerateRandomRange(0, (region_num_pages - num_pages - guard_pages) * PageSize / alignment) * alignment;
const KProcessAddress candidate = util::AlignDown(GetInteger(region_start + random_offset), alignment) + offset;
KMemoryInfo info;
ams::svc::PageInfo page_info;
MESOSPHERE_R_ABORT_UNLESS(this->QueryInfoImpl(std::addressof(info), std::addressof(page_info), candidate));
if (info.m_state != KMemoryState_Free) { continue; }
if (!(region_start <= candidate)) { continue; }
if (!(info.GetAddress() + guard_pages * PageSize <= GetInteger(candidate))) { continue; }
if (!(candidate + (num_pages + guard_pages) * PageSize - 1 <= info.GetLastAddress())) { continue; }
if (!(candidate + (num_pages + guard_pages) * PageSize - 1 <= region_start + region_num_pages * PageSize - 1)) { continue; }
address = candidate;
break;
}
/* Fall back to finding the first free area with a random offset. */
if (address == Null<KProcessAddress>) {
/* NOTE: Nintendo does not account for guard pages here. */
/* This may theoretically cause an offset to be chosen that cannot be mapped. */
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/* We will account for guard pages. */
const size_t offset_pages = KSystemControl::GenerateRandomRange(0, region_num_pages - num_pages - guard_pages);
address = m_memory_block_manager.FindFreeArea(region_start + offset_pages * PageSize, region_num_pages - offset_pages, num_pages, alignment, offset, guard_pages);
}
}
/* Find the first free area. */
if (address == Null<KProcessAddress>) {
address = m_memory_block_manager.FindFreeArea(region_start, region_num_pages, num_pages, alignment, offset, guard_pages);
}
}
return address;
}
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size_t KPageTableBase::GetSize(KMemoryState state) const {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Iterate, counting blocks with the desired state. */
size_t total_size = 0;
for (KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(m_address_space_start); it != m_memory_block_manager.end(); ++it) {
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/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
if (info.GetState() == state) {
total_size += info.GetSize();
}
}
return total_size;
}
size_t KPageTableBase::GetCodeSize() const {
return this->GetSize(KMemoryState_Code);
}
size_t KPageTableBase::GetCodeDataSize() const {
return this->GetSize(KMemoryState_CodeData);
}
size_t KPageTableBase::GetAliasCodeSize() const {
return this->GetSize(KMemoryState_AliasCode);
}
size_t KPageTableBase::GetAliasCodeDataSize() const {
return this->GetSize(KMemoryState_AliasCodeData);
}
Result KPageTableBase::AllocateAndMapPagesImpl(PageLinkedList *page_list, KProcessAddress address, size_t num_pages, const KPageProperties &properties) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Create a page group to hold the pages we allocate. */
KPageGroup pg(m_block_info_manager);
/* Allocate the pages. */
R_TRY(Kernel::GetMemoryManager().AllocateAndOpen(std::addressof(pg), num_pages, 1, m_allocate_option));
/* Ensure that the page group is closed when we're done working with it. */
ON_SCOPE_EXIT { pg.Close(); };
/* Clear all pages. */
for (const auto &it : pg) {
std::memset(GetVoidPointer(GetHeapVirtualAddress(it.GetAddress())), m_heap_fill_value, it.GetSize());
}
/* Map the pages. */
R_RETURN(this->Operate(page_list, address, num_pages, pg, properties, OperationType_MapGroup, false));
}
Result KPageTableBase::MapPageGroupImpl(PageLinkedList *page_list, KProcessAddress address, const KPageGroup &pg, const KPageProperties properties, bool reuse_ll) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Note the current address, so that we can iterate. */
const KProcessAddress start_address = address;
KProcessAddress cur_address = address;
/* Ensure that we clean up on failure. */
ON_RESULT_FAILURE {
MESOSPHERE_ABORT_UNLESS(!reuse_ll);
if (cur_address != start_address) {
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(page_list, start_address, (cur_address - start_address) / PageSize, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, true));
}
};
/* Iterate, mapping all pages in the group. */
for (const auto &block : pg) {
/* Map and advance. */
const KPageProperties cur_properties = (cur_address == start_address) ? properties : KPageProperties{ properties.perm, properties.io, properties.uncached, DisableMergeAttribute_None };
R_TRY(this->Operate(page_list, cur_address, block.GetNumPages(), block.GetAddress(), true, cur_properties, OperationType_Map, reuse_ll));
cur_address += block.GetSize();
}
/* We succeeded! */
R_SUCCEED();
}
void KPageTableBase::RemapPageGroup(PageLinkedList *page_list, KProcessAddress address, size_t size, const KPageGroup &pg) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Note the current address, so that we can iterate. */
const KProcessAddress start_address = address;
const KProcessAddress last_address = start_address + size - 1;
const KProcessAddress end_address = last_address + 1;
/* Iterate over the memory. */
auto pg_it = pg.begin();
MESOSPHERE_ABORT_UNLESS(pg_it != pg.end());
KPhysicalAddress pg_phys_addr = pg_it->GetAddress();
size_t pg_pages = pg_it->GetNumPages();
auto it = m_memory_block_manager.FindIterator(start_address);
while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* Determine the range to map. */
KProcessAddress map_address = std::max(info.GetAddress(), GetInteger(start_address));
const KProcessAddress map_end_address = std::min(info.GetEndAddress(), GetInteger(end_address));
MESOSPHERE_ABORT_UNLESS(map_end_address != map_address);
/* Determine if we should disable head merge. */
const bool disable_head_merge = info.GetAddress() >= GetInteger(start_address) && (info.GetDisableMergeAttribute() & KMemoryBlockDisableMergeAttribute_Normal) != 0;
const KPageProperties map_properties = { info.GetPermission(), false, false, disable_head_merge ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
/* While we have pages to map, map them. */
size_t map_pages = (map_end_address - map_address) / PageSize;
while (map_pages > 0) {
/* Check if we're at the end of the physical block. */
if (pg_pages == 0) {
/* Ensure there are more pages to map. */
MESOSPHERE_ABORT_UNLESS(pg_it != pg.end());
/* Advance our physical block. */
++pg_it;
pg_phys_addr = pg_it->GetAddress();
pg_pages = pg_it->GetNumPages();
}
/* Map whatever we can. */
const size_t cur_pages = std::min(pg_pages, map_pages);
MESOSPHERE_R_ABORT_UNLESS(this->Operate(page_list, map_address, map_pages, pg_phys_addr, true, map_properties, OperationType_Map, true));
/* Advance. */
map_address += cur_pages * PageSize;
map_pages -= cur_pages;
pg_phys_addr += cur_pages * PageSize;
pg_pages -= cur_pages;
}
/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
break;
}
/* Advance. */
++it;
}
/* Check that we re-mapped precisely the page group. */
MESOSPHERE_ABORT_UNLESS((++pg_it) == pg.end());
}
Result KPageTableBase::MakePageGroup(KPageGroup &pg, KProcessAddress addr, size_t num_pages) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
const size_t size = num_pages * PageSize;
/* We're making a new group, not adding to an existing one. */
R_UNLESS(pg.empty(), svc::ResultInvalidCurrentMemory());
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
R_UNLESS(impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), addr), svc::ResultInvalidCurrentMemory());
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
/* Iterate, adding to group as we go. */
while (tot_size < size) {
R_UNLESS(impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context)), svc::ResultInvalidCurrentMemory());
if (next_entry.phys_addr != (cur_addr + cur_size)) {
const size_t cur_pages = cur_size / PageSize;
R_UNLESS(IsHeapPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
R_TRY(pg.AddBlock(cur_addr, cur_pages));
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we add the right amount for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* add the last block. */
const size_t cur_pages = cur_size / PageSize;
R_UNLESS(IsHeapPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
R_TRY(pg.AddBlock(cur_addr, cur_pages));
R_SUCCEED();
}
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bool KPageTableBase::IsValidPageGroup(const KPageGroup &pg, KProcessAddress addr, size_t num_pages) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
const size_t size = num_pages * PageSize;
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/* Empty groups are necessarily invalid. */
if (pg.empty()) {
return false;
}
auto &impl = this->GetImpl();
/* We're going to validate that the group we'd expect is the group we see. */
auto cur_it = pg.begin();
KPhysicalAddress cur_block_address = cur_it->GetAddress();
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size_t cur_block_pages = cur_it->GetNumPages();
auto UpdateCurrentIterator = [&]() ALWAYS_INLINE_LAMBDA {
if (cur_block_pages == 0) {
if ((++cur_it) == pg.end()) {
return false;
}
cur_block_address = cur_it->GetAddress();
cur_block_pages = cur_it->GetNumPages();
}
return true;
};
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
if (!impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), addr)) {
return false;
}
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
/* Iterate, comparing expected to actual. */
while (tot_size < size) {
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if (!impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context))) {
return false;
}
if (next_entry.phys_addr != (cur_addr + cur_size)) {
const size_t cur_pages = cur_size / PageSize;
if (!IsHeapPhysicalAddress(cur_addr)) {
return false;
}
if (!UpdateCurrentIterator()) {
return false;
}
if (cur_block_address != cur_addr || cur_block_pages < cur_pages) {
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return false;
}
cur_block_address += cur_size;
cur_block_pages -= cur_pages;
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we compare the right amount for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
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}
if (!IsHeapPhysicalAddress(cur_addr)) {
return false;
}
if (!UpdateCurrentIterator()) {
return false;
}
return cur_block_address == cur_addr && cur_block_pages == (cur_size / PageSize);
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}
Result KPageTableBase::GetContiguousMemoryRangeWithState(MemoryRange *out, KProcessAddress address, size_t size, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
auto &impl = this->GetImpl();
/* Begin a traversal. */
TraversalContext context;
TraversalEntry cur_entry = { .phys_addr = Null<KPhysicalAddress>, .block_size = 0, .sw_reserved_bits = 0, .attr = 0 };
R_UNLESS(impl.BeginTraversal(std::addressof(cur_entry), std::addressof(context), address), svc::ResultInvalidCurrentMemory());
/* Traverse until we have enough size or we aren't contiguous any more. */
const KPhysicalAddress phys_address = cur_entry.phys_addr;
const u8 entry_attr = cur_entry.attr;
size_t contig_size;
for (contig_size = cur_entry.block_size - (GetInteger(phys_address) & (cur_entry.block_size - 1)); contig_size < size; contig_size += cur_entry.block_size) {
if (!impl.ContinueTraversal(std::addressof(cur_entry), std::addressof(context))) {
break;
}
if (cur_entry.phys_addr != phys_address + contig_size) {
break;
}
if (cur_entry.attr != entry_attr) {
break;
}
}
/* Take the minimum size for our region. */
size = std::min(size, contig_size);
/* Check that the memory is contiguous (modulo the reference count bit). */
const u32 test_state_mask = state_mask | KMemoryState_FlagReferenceCounted;
const bool is_heap = R_SUCCEEDED(this->CheckMemoryStateContiguous(address, size, test_state_mask, state | KMemoryState_FlagReferenceCounted, perm_mask, perm, attr_mask, attr));
if (!is_heap) {
R_TRY(this->CheckMemoryStateContiguous(address, size, test_state_mask, state, perm_mask, perm, attr_mask, attr));
}
/* The memory is contiguous, so set the output range. */
out->Set(phys_address, size, is_heap, attr);
R_SUCCEED();
}
Result KPageTableBase::SetMemoryPermission(KProcessAddress addr, size_t size, ams::svc::MemoryPermission svc_perm) {
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const size_t num_pages = size / PageSize;
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Verify we can change the memory permission. */
KMemoryState old_state;
KMemoryPermission old_perm;
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), nullptr, std::addressof(num_allocator_blocks), addr, size, KMemoryState_FlagCanReprotect, KMemoryState_FlagCanReprotect, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
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/* Determine new perm. */
const KMemoryPermission new_perm = ConvertToKMemoryPermission(svc_perm);
R_SUCCEED_IF(old_perm == new_perm);
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { new_perm, false, false, DisableMergeAttribute_None };
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R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, old_state, new_perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_None);
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R_SUCCEED();
}
Result KPageTableBase::SetProcessMemoryPermission(KProcessAddress addr, size_t size, ams::svc::MemoryPermission svc_perm) {
const size_t num_pages = size / PageSize;
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Verify we can change the memory permission. */
KMemoryState old_state;
KMemoryPermission old_perm;
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), nullptr, std::addressof(num_allocator_blocks), addr, size, KMemoryState_FlagCode, KMemoryState_FlagCode, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
/* Make a new page group for the region. */
KPageGroup pg(m_block_info_manager);
/* Determine new perm/state. */
const KMemoryPermission new_perm = ConvertToKMemoryPermission(svc_perm);
KMemoryState new_state = old_state;
const bool is_w = (new_perm & KMemoryPermission_UserWrite) == KMemoryPermission_UserWrite;
const bool is_x = (new_perm & KMemoryPermission_UserExecute) == KMemoryPermission_UserExecute;
const bool was_x = (old_perm & KMemoryPermission_UserExecute) == KMemoryPermission_UserExecute;
MESOSPHERE_ASSERT(!(is_w && is_x));
if (is_w) {
switch (old_state) {
case KMemoryState_Code: new_state = KMemoryState_CodeData; break;
case KMemoryState_AliasCode: new_state = KMemoryState_AliasCodeData; break;
MESOSPHERE_UNREACHABLE_DEFAULT_CASE();
}
}
/* Create a page group, if we're setting execute permissions. */
if (is_x) {
R_TRY(this->MakePageGroup(pg, GetInteger(addr), num_pages));
}
/* Succeed if there's nothing to do. */
R_SUCCEED_IF(old_perm == new_perm && old_state == new_state);
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { new_perm, false, false, DisableMergeAttribute_None };
const auto operation = was_x ? OperationType_ChangePermissionsAndRefreshAndFlush : OperationType_ChangePermissions;
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, Null<KPhysicalAddress>, false, properties, operation, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, new_state, new_perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_None);
/* Ensure cache coherency, if we're setting pages as executable. */
if (is_x) {
for (const auto &block : pg) {
cpu::StoreDataCache(GetVoidPointer(GetHeapVirtualAddress(block.GetAddress())), block.GetSize());
}
cpu::InvalidateEntireInstructionCache();
}
R_SUCCEED();
}
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Result KPageTableBase::SetMemoryAttribute(KProcessAddress addr, size_t size, u32 mask, u32 attr) {
const size_t num_pages = size / PageSize;
MESOSPHERE_ASSERT((mask | KMemoryAttribute_SetMask) == KMemoryAttribute_SetMask);
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Verify we can change the memory attribute. */
KMemoryState old_state;
KMemoryPermission old_perm;
KMemoryAttribute old_attr;
size_t num_allocator_blocks;
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constexpr u32 AttributeTestMask = ~(KMemoryAttribute_SetMask | KMemoryAttribute_DeviceShared);
const u32 state_test_mask = ((mask & KMemoryAttribute_Uncached) ? static_cast<u32>(KMemoryState_FlagCanChangeAttribute) : 0) | ((mask & KMemoryAttribute_PermissionLocked) ? static_cast<u32>(KMemoryState_FlagCanPermissionLock) : 0);
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), std::addressof(old_attr), std::addressof(num_allocator_blocks),
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addr, size,
state_test_mask, state_test_mask,
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KMemoryPermission_None, KMemoryPermission_None,
AttributeTestMask, KMemoryAttribute_None, ~AttributeTestMask));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* If we need to, perform a change attribute operation. */
if ((mask & KMemoryAttribute_Uncached) != 0) {
/* Determine the new attribute. */
const KMemoryAttribute new_attr = static_cast<KMemoryAttribute>(((old_attr & ~mask) | (attr & mask)));
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/* Perform operation. */
const KPageProperties properties = { old_perm, false, (new_attr & KMemoryAttribute_Uncached) != 0, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissionsAndRefreshAndFlush, false));
}
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/* Update the blocks. */
m_memory_block_manager.UpdateAttribute(std::addressof(allocator), addr, num_pages, mask, attr);
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R_SUCCEED();
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}
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Result KPageTableBase::SetHeapSize(KProcessAddress *out, size_t size) {
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/* Lock the physical memory mutex. */
KScopedLightLock map_phys_mem_lk(m_map_physical_memory_lock);
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/* Try to perform a reduction in heap, instead of an extension. */
KProcessAddress cur_address;
size_t allocation_size;
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Validate that setting heap size is possible at all. */
R_UNLESS(!m_is_kernel, svc::ResultOutOfMemory());
R_UNLESS(size <= static_cast<size_t>(m_region_ends[RegionType_Heap] - m_region_starts[RegionType_Heap]), svc::ResultOutOfMemory());
R_UNLESS(size <= m_max_heap_size, svc::ResultOutOfMemory());
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if (size < static_cast<size_t>(m_current_heap_end - m_region_starts[RegionType_Heap])) {
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/* The size being requested is less than the current size, so we need to free the end of the heap. */
/* Validate memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks),
m_region_starts[RegionType_Heap] + size, (m_current_heap_end - m_region_starts[RegionType_Heap]) - size,
KMemoryState_All, KMemoryState_Normal,
KMemoryPermission_All, KMemoryPermission_UserReadWrite,
KMemoryAttribute_All, KMemoryAttribute_None));
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/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the end of the heap. */
const size_t num_pages = ((m_current_heap_end - m_region_starts[RegionType_Heap]) - size) / PageSize;
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), m_region_starts[RegionType_Heap] + size, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
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/* Release the memory from the resource limit. */
m_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, num_pages * PageSize);
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/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), m_region_starts[RegionType_Heap] + size, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, size == 0 ? KMemoryBlockDisableMergeAttribute_Normal : KMemoryBlockDisableMergeAttribute_None);
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/* Update the current heap end. */
m_current_heap_end = m_region_starts[RegionType_Heap] + size;
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/* Set the output. */
*out = m_region_starts[RegionType_Heap];
R_SUCCEED();
} else if (size == static_cast<size_t>(m_current_heap_end - m_region_starts[RegionType_Heap])) {
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/* The size requested is exactly the current size. */
*out = m_region_starts[RegionType_Heap];
R_SUCCEED();
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} else {
/* We have to allocate memory. Determine how much to allocate and where while the table is locked. */
cur_address = m_current_heap_end;
allocation_size = size - (m_current_heap_end - m_region_starts[RegionType_Heap]);
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}
}
/* Reserve memory for the heap extension. */
KScopedResourceReservation memory_reservation(m_resource_limit, ams::svc::LimitableResource_PhysicalMemoryMax, allocation_size);
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R_UNLESS(memory_reservation.Succeeded(), svc::ResultLimitReached());
/* Allocate pages for the heap extension. */
KPageGroup pg(m_block_info_manager);
R_TRY(Kernel::GetMemoryManager().AllocateAndOpen(std::addressof(pg), allocation_size / PageSize, 1, m_allocate_option));
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/* Close the opened pages when we're done with them. */
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/* If the mapping succeeds, each page will gain an extra reference, otherwise they will be freed automatically. */
ON_SCOPE_EXIT { pg.Close(); };
/* Clear all the newly allocated pages. */
for (const auto &it : pg) {
std::memset(GetVoidPointer(GetHeapVirtualAddress(it.GetAddress())), m_heap_fill_value, it.GetSize());
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}
/* Map the pages. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Ensure that the heap hasn't changed since we began executing. */
MESOSPHERE_ABORT_UNLESS(cur_address == m_current_heap_end);
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), m_current_heap_end, allocation_size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
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/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Map the pages. */
const size_t num_pages = allocation_size / PageSize;
const KPageProperties map_properties = { KMemoryPermission_UserReadWrite, false, false, (m_current_heap_end == m_region_starts[RegionType_Heap]) ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), m_current_heap_end, num_pages, pg, map_properties, OperationType_MapGroup, false));
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/* We succeeded, so commit our memory reservation. */
memory_reservation.Commit();
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), m_current_heap_end, num_pages, KMemoryState_Normal, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, m_region_starts[RegionType_Heap] == m_current_heap_end ? KMemoryBlockDisableMergeAttribute_Normal : KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_None);
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/* Update the current heap end. */
m_current_heap_end = m_region_starts[RegionType_Heap] + size;
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/* Set the output. */
*out = m_region_starts[RegionType_Heap];
R_SUCCEED();
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}
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}
Result KPageTableBase::SetMaxHeapSize(size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Only process page tables are allowed to set heap size. */
MESOSPHERE_ASSERT(!this->IsKernel());
m_max_heap_size = size;
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R_SUCCEED();
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}
Result KPageTableBase::QueryInfo(KMemoryInfo *out_info, ams::svc::PageInfo *out_page_info, KProcessAddress addr) const {
/* If the address is invalid, create a fake block. */
if (!this->Contains(addr, 1)) {
*out_info = {
.m_address = GetInteger(m_address_space_end),
.m_size = 0 - GetInteger(m_address_space_end),
.m_state = static_cast<KMemoryState>(ams::svc::MemoryState_Inaccessible),
.m_device_disable_merge_left_count = 0,
.m_device_disable_merge_right_count = 0,
.m_ipc_lock_count = 0,
.m_device_use_count = 0,
.m_ipc_disable_merge_count = 0,
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.m_permission = KMemoryPermission_None,
.m_attribute = KMemoryAttribute_None,
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.m_original_permission = KMemoryPermission_None,
.m_disable_merge_attribute = KMemoryBlockDisableMergeAttribute_None,
};
out_page_info->flags = 0;
R_SUCCEED();
}
/* Otherwise, lock the table and query. */
KScopedLightLock lk(m_general_lock);
R_RETURN(this->QueryInfoImpl(out_info, out_page_info, addr));
}
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Result KPageTableBase::QueryPhysicalAddress(ams::svc::PhysicalMemoryInfo *out, KProcessAddress address) const {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Align the address down to page size. */
address = util::AlignDown(GetInteger(address), PageSize);
/* Verify that we can query the address. */
KMemoryInfo info;
ams::svc::PageInfo page_info;
R_TRY(this->QueryInfoImpl(std::addressof(info), std::addressof(page_info), address));
/* Check the memory state. */
R_TRY(this->CheckMemoryState(info, KMemoryState_FlagCanQueryPhysical, KMemoryState_FlagCanQueryPhysical, KMemoryPermission_UserReadExecute, KMemoryPermission_UserRead, KMemoryAttribute_None, KMemoryAttribute_None));
/* Prepare to traverse. */
KPhysicalAddress phys_addr;
size_t phys_size;
KProcessAddress virt_addr = info.GetAddress();
KProcessAddress end_addr = info.GetEndAddress();
/* Perform traversal. */
{
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = m_impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), virt_addr);
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R_UNLESS(traverse_valid, svc::ResultInvalidCurrentMemory());
/* Set tracking variables. */
phys_addr = next_entry.phys_addr;
phys_size = next_entry.block_size - (GetInteger(phys_addr) & (next_entry.block_size - 1));
/* Iterate. */
while (true) {
/* Continue the traversal. */
traverse_valid = m_impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
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if (!traverse_valid) {
break;
}
if (next_entry.phys_addr != (phys_addr + phys_size)) {
/* Check if we're done. */
if (virt_addr <= address && address <= virt_addr + phys_size - 1) {
break;
}
/* Advance. */
phys_addr = next_entry.phys_addr;
virt_addr += next_entry.block_size;
phys_size = next_entry.block_size - (GetInteger(phys_addr) & (next_entry.block_size - 1));
} else {
phys_size += next_entry.block_size;
}
/* Check if we're done. */
if (end_addr < virt_addr + phys_size) {
break;
}
}
MESOSPHERE_ASSERT(virt_addr <= address && address <= virt_addr + phys_size - 1);
/* Ensure we use the right size. */
if (end_addr < virt_addr + phys_size) {
phys_size = end_addr - virt_addr;
}
}
/* Set the output. */
out->physical_address = GetInteger(phys_addr);
out->virtual_address = GetInteger(virt_addr);
out->size = phys_size;
R_SUCCEED();
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}
Result KPageTableBase::MapIoImpl(KProcessAddress *out, PageLinkedList *page_list, KPhysicalAddress phys_addr, size_t size, KMemoryState state, KMemoryPermission perm) {
/* Check pre-conditions. */
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
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MESOSPHERE_ASSERT(util::IsAligned(GetInteger(phys_addr), PageSize));
MESOSPHERE_ASSERT(util::IsAligned(size, PageSize));
MESOSPHERE_ASSERT(size > 0);
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R_UNLESS(phys_addr < phys_addr + size, svc::ResultInvalidAddress());
const size_t num_pages = size / PageSize;
const KPhysicalAddress last = phys_addr + size - 1;
/* Get region extents. */
const KProcessAddress region_start = m_region_starts[RegionType_KernelMap];
const size_t region_size = m_region_ends[RegionType_KernelMap] - m_region_starts[RegionType_KernelMap];
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const size_t region_num_pages = region_size / PageSize;
MESOSPHERE_ASSERT(this->CanContain(region_start, region_size, state));
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/* Locate the memory region. */
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const KMemoryRegion *region = KMemoryLayout::Find(phys_addr);
R_UNLESS(region != nullptr, svc::ResultInvalidAddress());
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MESOSPHERE_ASSERT(region->Contains(GetInteger(phys_addr)));
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/* Ensure that the region is mappable. */
const bool is_rw = perm == KMemoryPermission_UserReadWrite;
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while (true) {
/* Check that the region exists. */
R_UNLESS(region != nullptr, svc::ResultInvalidAddress());
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/* Check the region attributes. */
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R_UNLESS(!region->IsDerivedFrom(KMemoryRegionType_Dram), svc::ResultInvalidAddress());
R_UNLESS(!region->HasTypeAttribute(KMemoryRegionAttr_UserReadOnly) || !is_rw, svc::ResultInvalidAddress());
R_UNLESS(!region->HasTypeAttribute(KMemoryRegionAttr_NoUserMap), svc::ResultInvalidAddress());
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/* Check if we're done. */
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if (GetInteger(last) <= region->GetLastAddress()) {
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break;
}
/* Advance. */
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region = region->GetNext();
};
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/* Select an address to map at. */
KProcessAddress addr = Null<KProcessAddress>;
for (s32 block_type = KPageTable::GetMaxBlockType(); block_type >= 0; block_type--) {
const size_t alignment = KPageTable::GetBlockSize(static_cast<KPageTable::BlockType>(block_type));
const KPhysicalAddress aligned_phys = util::AlignUp(GetInteger(phys_addr), alignment) + alignment - 1;
if (aligned_phys <= phys_addr) {
continue;
}
const KPhysicalAddress last_aligned_paddr = util::AlignDown(GetInteger(last) + 1, alignment) - 1;
if (!(last_aligned_paddr <= last && aligned_phys <= last_aligned_paddr)) {
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continue;
}
addr = this->FindFreeArea(region_start, region_num_pages, num_pages, alignment, 0, this->GetNumGuardPages());
if (addr != Null<KProcessAddress>) {
break;
}
}
R_UNLESS(addr != Null<KProcessAddress>, svc::ResultOutOfMemory());
/* Check that we can map IO here. */
MESOSPHERE_ASSERT(this->CanContain(addr, size, state));
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MESOSPHERE_R_ASSERT(this->CheckMemoryState(addr, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Perform mapping operation. */
const KPageProperties properties = { perm, state == KMemoryState_IoRegister, false, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(page_list, addr, num_pages, phys_addr, true, properties, OperationType_Map, false));
/* Set the output address. */
*out = addr;
R_SUCCEED();
}
Result KPageTableBase::MapIo(KPhysicalAddress phys_addr, size_t size, KMemoryPermission perm) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Map the io memory. */
KProcessAddress addr;
R_TRY(this->MapIoImpl(std::addressof(addr), updater.GetPageList(), phys_addr, size, KMemoryState_IoRegister, perm));
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/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, size / PageSize, KMemoryState_IoRegister, perm, KMemoryAttribute_Locked, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
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/* We successfully mapped the pages. */
R_SUCCEED();
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}
Result KPageTableBase::MapIoRegion(KProcessAddress dst_address, KPhysicalAddress phys_addr, size_t size, ams::svc::MemoryMapping mapping, ams::svc::MemoryPermission svc_perm) {
const size_t num_pages = size / PageSize;
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Validate the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), dst_address, size, KMemoryState_All, KMemoryState_None, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KMemoryPermission perm = ConvertToKMemoryPermission(svc_perm);
const KPageProperties properties = { perm, mapping == ams::svc::MemoryMapping_IoRegister, mapping == ams::svc::MemoryMapping_Uncached, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(updater.GetPageList(), dst_address, num_pages, phys_addr, true, properties, OperationType_Map, false));
/* Update the blocks. */
const auto state = mapping == ams::svc::MemoryMapping_Memory ? KMemoryState_IoMemory : KMemoryState_IoRegister;
m_memory_block_manager.Update(std::addressof(allocator), dst_address, num_pages, state, perm, KMemoryAttribute_Locked, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* We successfully mapped the pages. */
R_SUCCEED();
}
Result KPageTableBase::UnmapIoRegion(KProcessAddress dst_address, KPhysicalAddress phys_addr, size_t size, ams::svc::MemoryMapping mapping) {
const size_t num_pages = size / PageSize;
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Validate the memory state. */
KMemoryState old_state;
KMemoryPermission old_perm;
KMemoryAttribute old_attr;
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(old_state), std::addressof(old_perm), std::addressof(old_attr), std::addressof(num_allocator_blocks),
dst_address, size,
KMemoryState_All, mapping == ams::svc::MemoryMapping_Memory ? KMemoryState_IoMemory : KMemoryState_IoRegister,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_All, KMemoryAttribute_Locked));
/* Validate that the region being unmapped corresponds to the physical range described. */
{
/* Get the impl. */
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
MESOSPHERE_ABORT_UNLESS(impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), dst_address));
/* Check that the physical region matches. */
R_UNLESS(next_entry.phys_addr == phys_addr, svc::ResultInvalidMemoryRegion());
/* Iterate. */
for (size_t checked_size = next_entry.block_size - (GetInteger(phys_addr) & (next_entry.block_size - 1)); checked_size < size; checked_size += next_entry.block_size) {
/* Continue the traversal. */
MESOSPHERE_ABORT_UNLESS(impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context)));
/* Check that the physical region matches. */
R_UNLESS(next_entry.phys_addr == phys_addr + checked_size, svc::ResultInvalidMemoryRegion());
}
}
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* If the region being unmapped is Memory, synchronize. */
if (mapping == ams::svc::MemoryMapping_Memory) {
/* Change the region to be uncached. */
const KPageProperties properties = { old_perm, false, true, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), dst_address, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissionsAndRefresh, false));
/* Temporarily unlock ourselves, so that other operations can occur while we flush the region. */
m_general_lock.Unlock();
ON_SCOPE_EXIT { m_general_lock.Lock(); };
/* Flush the region. */
MESOSPHERE_R_ABORT_UNLESS(cpu::FlushDataCache(GetVoidPointer(dst_address), size));
}
/* Perform the unmap. */
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), dst_address, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), dst_address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
R_SUCCEED();
}
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Result KPageTableBase::MapStatic(KPhysicalAddress phys_addr, size_t size, KMemoryPermission perm) {
MESOSPHERE_ASSERT(util::IsAligned(GetInteger(phys_addr), PageSize));
MESOSPHERE_ASSERT(util::IsAligned(size, PageSize));
MESOSPHERE_ASSERT(size > 0);
R_UNLESS(phys_addr < phys_addr + size, svc::ResultInvalidAddress());
const size_t num_pages = size / PageSize;
const KPhysicalAddress last = phys_addr + size - 1;
/* Get region extents. */
const KProcessAddress region_start = this->GetRegionAddress(KMemoryState_Static);
const size_t region_size = this->GetRegionSize(KMemoryState_Static);
const size_t region_num_pages = region_size / PageSize;
/* Locate the memory region. */
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const KMemoryRegion *region = KMemoryLayout::Find(phys_addr);
R_UNLESS(region != nullptr, svc::ResultInvalidAddress());
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MESOSPHERE_ASSERT(region->Contains(GetInteger(phys_addr)));
R_UNLESS(GetInteger(last) <= region->GetLastAddress(), svc::ResultInvalidAddress());
/* Check the region attributes. */
const bool is_rw = perm == KMemoryPermission_UserReadWrite;
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R_UNLESS( region->IsDerivedFrom(KMemoryRegionType_Dram), svc::ResultInvalidAddress());
R_UNLESS(!region->HasTypeAttribute(KMemoryRegionAttr_NoUserMap), svc::ResultInvalidAddress());
R_UNLESS(!region->HasTypeAttribute(KMemoryRegionAttr_UserReadOnly) || !is_rw, svc::ResultInvalidAddress());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Select an address to map at. */
KProcessAddress addr = Null<KProcessAddress>;
for (s32 block_type = KPageTable::GetMaxBlockType(); block_type >= 0; block_type--) {
const size_t alignment = KPageTable::GetBlockSize(static_cast<KPageTable::BlockType>(block_type));
const KPhysicalAddress aligned_phys = util::AlignUp(GetInteger(phys_addr), alignment) + alignment - 1;
if (aligned_phys <= phys_addr) {
continue;
}
const KPhysicalAddress last_aligned_paddr = util::AlignDown(GetInteger(last) + 1, alignment) - 1;
if (!(last_aligned_paddr <= last && aligned_phys <= last_aligned_paddr)) {
continue;
}
addr = this->FindFreeArea(region_start, region_num_pages, num_pages, alignment, 0, this->GetNumGuardPages());
if (addr != Null<KProcessAddress>) {
break;
}
}
R_UNLESS(addr != Null<KProcessAddress>, svc::ResultOutOfMemory());
/* Check that we can map static here. */
MESOSPHERE_ASSERT(this->CanContain(addr, size, KMemoryState_Static));
MESOSPHERE_R_ASSERT(this->CheckMemoryState(addr, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, phys_addr, true, properties, OperationType_Map, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, KMemoryState_Static, perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* We successfully mapped the pages. */
R_SUCCEED();
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}
Result KPageTableBase::MapRegion(KMemoryRegionType region_type, KMemoryPermission perm) {
/* Get the memory region. */
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const KMemoryRegion *region = KMemoryLayout::GetPhysicalMemoryRegionTree().FindFirstDerived(region_type);
R_UNLESS(region != nullptr, svc::ResultOutOfRange());
/* Check that the region is valid. */
MESOSPHERE_ABORT_UNLESS(region->GetEndAddress() != 0);
/* Map the region. */
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R_TRY_CATCH(this->MapStatic(region->GetAddress(), region->GetSize(), perm)) {
R_CONVERT(svc::ResultInvalidAddress, svc::ResultOutOfRange())
} R_END_TRY_CATCH;
R_SUCCEED();
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}
Result KPageTableBase::MapPages(KProcessAddress *out_addr, size_t num_pages, size_t alignment, KPhysicalAddress phys_addr, bool is_pa_valid, KProcessAddress region_start, size_t region_num_pages, KMemoryState state, KMemoryPermission perm) {
MESOSPHERE_ASSERT(util::IsAligned(alignment, PageSize) && alignment >= PageSize);
/* Ensure this is a valid map request. */
R_UNLESS(this->CanContain(region_start, region_num_pages * PageSize, state), svc::ResultInvalidCurrentMemory());
R_UNLESS(num_pages < region_num_pages, svc::ResultOutOfMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Find a random address to map at. */
KProcessAddress addr = this->FindFreeArea(region_start, region_num_pages, num_pages, alignment, 0, this->GetNumGuardPages());
R_UNLESS(addr != Null<KProcessAddress>, svc::ResultOutOfMemory());
MESOSPHERE_ASSERT(util::IsAligned(GetInteger(addr), alignment));
MESOSPHERE_ASSERT(this->CanContain(addr, num_pages * PageSize, state));
MESOSPHERE_R_ASSERT(this->CheckMemoryState(addr, num_pages * PageSize, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { perm, false, false, DisableMergeAttribute_DisableHead };
if (is_pa_valid) {
R_TRY(this->Operate(updater.GetPageList(), addr, num_pages, phys_addr, true, properties, OperationType_Map, false));
} else {
R_TRY(this->AllocateAndMapPagesImpl(updater.GetPageList(), addr, num_pages, properties));
}
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, state, perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* We successfully mapped the pages. */
*out_addr = addr;
R_SUCCEED();
}
Result KPageTableBase::MapPages(KProcessAddress address, size_t num_pages, KMemoryState state, KMemoryPermission perm) {
/* Check that the map is in range. */
const size_t size = num_pages * PageSize;
R_UNLESS(this->CanContain(address, size, state), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Map the pages. */
const KPageProperties properties = { perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->AllocateAndMapPagesImpl(updater.GetPageList(), address, num_pages, properties));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, state, perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
R_SUCCEED();
}
Result KPageTableBase::UnmapPages(KProcessAddress address, size_t num_pages, KMemoryState state) {
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/* Check that the unmap is in range. */
const size_t size = num_pages * PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, state, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
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/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform the unmap. */
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
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R_TRY(this->Operate(updater.GetPageList(), address, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
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R_SUCCEED();
}
Result KPageTableBase::MapPageGroup(KProcessAddress *out_addr, const KPageGroup &pg, KProcessAddress region_start, size_t region_num_pages, KMemoryState state, KMemoryPermission perm) {
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MESOSPHERE_ASSERT(!this->IsLockedByCurrentThread());
/* Ensure this is a valid map request. */
const size_t num_pages = pg.GetNumPages();
R_UNLESS(this->CanContain(region_start, region_num_pages * PageSize, state), svc::ResultInvalidCurrentMemory());
R_UNLESS(num_pages < region_num_pages, svc::ResultOutOfMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Find a random address to map at. */
KProcessAddress addr = this->FindFreeArea(region_start, region_num_pages, num_pages, PageSize, 0, this->GetNumGuardPages());
R_UNLESS(addr != Null<KProcessAddress>, svc::ResultOutOfMemory());
MESOSPHERE_ASSERT(this->CanContain(addr, num_pages * PageSize, state));
MESOSPHERE_R_ASSERT(this->CheckMemoryState(addr, num_pages * PageSize, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->MapPageGroupImpl(updater.GetPageList(), addr, pg, properties, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, state, perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* We successfully mapped the pages. */
*out_addr = addr;
R_SUCCEED();
}
Result KPageTableBase::MapPageGroup(KProcessAddress addr, const KPageGroup &pg, KMemoryState state, KMemoryPermission perm) {
MESOSPHERE_ASSERT(!this->IsLockedByCurrentThread());
/* Ensure this is a valid map request. */
const size_t num_pages = pg.GetNumPages();
const size_t size = num_pages * PageSize;
R_UNLESS(this->CanContain(addr, size, state), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check if state allows us to map. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), addr, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform mapping operation. */
const KPageProperties properties = { perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->MapPageGroupImpl(updater.GetPageList(), addr, pg, properties, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), addr, num_pages, state, perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* We successfully mapped the pages. */
R_SUCCEED();
}
Result KPageTableBase::UnmapPageGroup(KProcessAddress address, const KPageGroup &pg, KMemoryState state) {
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MESOSPHERE_ASSERT(!this->IsLockedByCurrentThread());
/* Ensure this is a valid unmap request. */
const size_t num_pages = pg.GetNumPages();
const size_t size = num_pages * PageSize;
R_UNLESS(this->CanContain(address, size, state), svc::ResultInvalidCurrentMemory());
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/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Check if state allows us to unmap. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, state, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
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/* Check that the page group is valid. */
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R_UNLESS(this->IsValidPageGroup(pg, address, num_pages), svc::ResultInvalidCurrentMemory());
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/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Perform unmapping operation. */
const KPageProperties properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
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R_TRY(this->Operate(updater.GetPageList(), address, num_pages, Null<KPhysicalAddress>, false, properties, OperationType_Unmap, false));
/* Update the blocks. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
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R_SUCCEED();
}
Result KPageTableBase::MakeAndOpenPageGroup(KPageGroup *out, KProcessAddress address, size_t num_pages, u32 state_mask, u32 state, u32 perm_mask, u32 perm, u32 attr_mask, u32 attr) {
/* Ensure that the page group isn't null. */
MESOSPHERE_ASSERT(out != nullptr);
/* Make sure that the region we're mapping is valid for the table. */
const size_t size = num_pages * PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check if state allows us to create the group. */
R_TRY(this->CheckMemoryState(address, size, state_mask | KMemoryState_FlagReferenceCounted, state | KMemoryState_FlagReferenceCounted, perm_mask, perm, attr_mask, attr));
/* Create a new page group for the region. */
R_TRY(this->MakePageGroup(*out, address, num_pages));
/* Open a new reference to the pages in the group. */
out->Open();
R_SUCCEED();
}
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Result KPageTableBase::InvalidateProcessDataCache(KProcessAddress address, size_t size) {
/* Check that the region is in range. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Check the memory state. */
R_TRY(this->CheckMemoryStateContiguous(address, size, KMemoryState_FlagReferenceCounted, KMemoryState_FlagReferenceCounted, KMemoryPermission_UserReadWrite, KMemoryPermission_UserReadWrite, KMemoryAttribute_Uncached, KMemoryAttribute_None));
/* Get the impl. */
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), address);
R_UNLESS(traverse_valid, svc::ResultInvalidCurrentMemory());
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
R_UNLESS(traverse_valid, svc::ResultInvalidCurrentMemory());
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Check that the pages are linearly mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Invalidate the block. */
if (cur_size > 0) {
/* NOTE: Nintendo does not check the result of invalidation. */
cpu::InvalidateDataCache(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), cur_size);
}
/* Advance. */
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Check that the last block is linearly mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Invalidate the last block. */
if (cur_size > 0) {
/* NOTE: Nintendo does not check the result of invalidation. */
cpu::InvalidateDataCache(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), cur_size);
}
R_SUCCEED();
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}
Result KPageTableBase::InvalidateCurrentProcessDataCache(KProcessAddress address, size_t size) {
/* Check pre-condition: this is being called on the current process. */
MESOSPHERE_ASSERT(this == std::addressof(GetCurrentProcess().GetPageTable().GetBasePageTable()));
/* Check that the region is in range. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
R_TRY(this->CheckMemoryStateContiguous(address, size, KMemoryState_FlagReferenceCounted, KMemoryState_FlagReferenceCounted, KMemoryPermission_UserReadWrite, KMemoryPermission_UserReadWrite, KMemoryAttribute_Uncached, KMemoryAttribute_None));
/* Invalidate the data cache. */
R_RETURN(cpu::InvalidateDataCache(GetVoidPointer(address), size));
}
Result KPageTableBase::ReadDebugMemory(void *buffer, KProcessAddress address, size_t size) {
/* Lightly validate the region is in range. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Require that the memory either be user readable or debuggable. */
const bool can_read = R_SUCCEEDED(this->CheckMemoryStateContiguous(address, size, KMemoryState_None, KMemoryState_None, KMemoryPermission_UserRead, KMemoryPermission_UserRead, KMemoryAttribute_None, KMemoryAttribute_None));
if (!can_read) {
const bool can_debug = R_SUCCEEDED(this->CheckMemoryStateContiguous(address, size, KMemoryState_FlagCanDebug, KMemoryState_FlagCanDebug, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
R_UNLESS(can_debug, svc::ResultInvalidCurrentMemory());
}
/* Get the impl. */
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), address);
R_UNLESS(traverse_valid, svc::ResultInvalidCurrentMemory());
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy as much aligned data as we can. */
if (cur_size >= sizeof(u32)) {
const size_t copy_size = util::AlignDown(cur_size, sizeof(u32));
const void * copy_src = GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr));
cpu::FlushDataCache(copy_src, copy_size);
R_UNLESS(UserspaceAccess::CopyMemoryToUserAligned32Bit(buffer, copy_src, copy_size), svc::ResultInvalidPointer());
buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(buffer) + copy_size);
cur_addr += copy_size;
cur_size -= copy_size;
}
/* Copy remaining data. */
if (cur_size > 0) {
const void * copy_src = GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr));
cpu::FlushDataCache(copy_src, cur_size);
R_UNLESS(UserspaceAccess::CopyMemoryToUser(buffer, copy_src, cur_size), svc::ResultInvalidPointer());
}
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(buffer) + cur_size);
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
R_SUCCEED();
}
Result KPageTableBase::WriteDebugMemory(KProcessAddress address, const void *buffer, size_t size) {
/* Lightly validate the region is in range. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Require that the memory either be user writable or debuggable. */
const bool can_read = R_SUCCEEDED(this->CheckMemoryStateContiguous(address, size, KMemoryState_None, KMemoryState_None, KMemoryPermission_UserReadWrite, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryAttribute_None));
if (!can_read) {
const bool can_debug = R_SUCCEEDED(this->CheckMemoryStateContiguous(address, size, KMemoryState_FlagCanDebug, KMemoryState_FlagCanDebug, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
R_UNLESS(can_debug, svc::ResultInvalidCurrentMemory());
}
/* Get the impl. */
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), address);
R_UNLESS(traverse_valid, svc::ResultInvalidCurrentMemory());
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy as much aligned data as we can. */
if (cur_size >= sizeof(u32)) {
const size_t copy_size = util::AlignDown(cur_size, sizeof(u32));
R_UNLESS(UserspaceAccess::CopyMemoryFromUserAligned32Bit(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), buffer, copy_size), svc::ResultInvalidCurrentMemory());
cpu::StoreDataCache(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), copy_size);
buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(buffer) + copy_size);
cur_addr += copy_size;
cur_size -= copy_size;
}
/* Copy remaining data. */
if (cur_size > 0) {
R_UNLESS(UserspaceAccess::CopyMemoryFromUser(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), buffer, cur_size), svc::ResultInvalidCurrentMemory());
cpu::StoreDataCache(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), cur_size);
}
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
buffer = reinterpret_cast<void *>(reinterpret_cast<uintptr_t>(buffer) + cur_size);
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
/* Invalidate the entire instruction cache, as this svc allows modifying executable pages. */
cpu::InvalidateEntireInstructionCache();
R_SUCCEED();
}
Result KPageTableBase::ReadIoMemoryImpl(void *buffer, KPhysicalAddress phys_addr, size_t size, KMemoryState state) {
/* Check pre-conditions. */
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Determine the mapping extents. */
const KPhysicalAddress map_start = util::AlignDown(GetInteger(phys_addr), PageSize);
const KPhysicalAddress map_end = util::AlignUp(GetInteger(phys_addr) + size, PageSize);
const size_t map_size = map_end - map_start;
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Temporarily map the io memory. */
KProcessAddress io_addr;
R_TRY(this->MapIoImpl(std::addressof(io_addr), updater.GetPageList(), map_start, map_size, state, KMemoryPermission_UserRead));
/* Ensure we unmap the io memory when we're done with it. */
ON_SCOPE_EXIT {
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), io_addr, map_size / PageSize, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, true));
};
/* Read the memory. */
const KProcessAddress read_addr = io_addr + (GetInteger(phys_addr) & (PageSize - 1));
switch ((GetInteger(read_addr) | size) & 3) {
case 0:
{
R_UNLESS(UserspaceAccess::ReadIoMemory32Bit(buffer, GetVoidPointer(read_addr), size), svc::ResultInvalidPointer());
}
break;
case 2:
{
R_UNLESS(UserspaceAccess::ReadIoMemory16Bit(buffer, GetVoidPointer(read_addr), size), svc::ResultInvalidPointer());
}
break;
default:
{
R_UNLESS(UserspaceAccess::ReadIoMemory8Bit(buffer, GetVoidPointer(read_addr), size), svc::ResultInvalidPointer());
}
break;
}
R_SUCCEED();
}
Result KPageTableBase::WriteIoMemoryImpl(KPhysicalAddress phys_addr, const void *buffer, size_t size, KMemoryState state) {
/* Check pre-conditions. */
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
/* Determine the mapping extents. */
const KPhysicalAddress map_start = util::AlignDown(GetInteger(phys_addr), PageSize);
const KPhysicalAddress map_end = util::AlignUp(GetInteger(phys_addr) + size, PageSize);
const size_t map_size = map_end - map_start;
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Temporarily map the io memory. */
KProcessAddress io_addr;
R_TRY(this->MapIoImpl(std::addressof(io_addr), updater.GetPageList(), map_start, map_size, state, KMemoryPermission_UserReadWrite));
/* Ensure we unmap the io memory when we're done with it. */
ON_SCOPE_EXIT {
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), io_addr, map_size / PageSize, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, true));
};
/* Read the memory. */
const KProcessAddress write_addr = io_addr + (GetInteger(phys_addr) & (PageSize - 1));
switch ((GetInteger(write_addr) | size) & 3) {
case 0:
{
R_UNLESS(UserspaceAccess::WriteIoMemory32Bit(GetVoidPointer(write_addr), buffer, size), svc::ResultInvalidPointer());
}
break;
case 2:
{
R_UNLESS(UserspaceAccess::WriteIoMemory16Bit(GetVoidPointer(write_addr), buffer, size), svc::ResultInvalidPointer());
}
break;
default:
{
R_UNLESS(UserspaceAccess::WriteIoMemory8Bit(GetVoidPointer(write_addr), buffer, size), svc::ResultInvalidPointer());
}
break;
}
R_SUCCEED();
}
Result KPageTableBase::ReadDebugIoMemory(void *buffer, KProcessAddress address, size_t size, KMemoryState state) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* We need to lock both this table, and the current process's table, so set up some aliases. */
KPageTableBase &src_page_table = *this;
KPageTableBase &dst_page_table = GetCurrentProcess().GetPageTable().GetBasePageTable();
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
/* Check that the desired range is readable io memory. */
R_TRY(this->CheckMemoryStateContiguous(address, size, KMemoryState_All, state, KMemoryPermission_UserRead, KMemoryPermission_UserRead, KMemoryAttribute_None, KMemoryAttribute_None));
/* Read the memory. */
u8 *dst = static_cast<u8 *>(buffer);
const KProcessAddress last_address = address + size - 1;
while (address <= last_address) {
/* Get the current physical address. */
KPhysicalAddress phys_addr;
MESOSPHERE_ABORT_UNLESS(src_page_table.GetPhysicalAddressLocked(std::addressof(phys_addr), address));
/* Determine the current read size. */
const size_t cur_size = std::min<size_t>(last_address - address + 1, PageSize - (GetInteger(address) & (PageSize - 1)));
/* Read. */
R_TRY(dst_page_table.ReadIoMemoryImpl(dst, phys_addr, cur_size, state));
/* Advance. */
address += cur_size;
dst += cur_size;
}
R_SUCCEED();
}
Result KPageTableBase::WriteDebugIoMemory(KProcessAddress address, const void *buffer, size_t size, KMemoryState state) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* We need to lock both this table, and the current process's table, so set up some aliases. */
KPageTableBase &src_page_table = *this;
KPageTableBase &dst_page_table = GetCurrentProcess().GetPageTable().GetBasePageTable();
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
/* Check that the desired range is writable io memory. */
R_TRY(this->CheckMemoryStateContiguous(address, size, KMemoryState_All, state, KMemoryPermission_UserReadWrite, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryAttribute_None));
/* Read the memory. */
const u8 *src = static_cast<const u8 *>(buffer);
const KProcessAddress last_address = address + size - 1;
while (address <= last_address) {
/* Get the current physical address. */
KPhysicalAddress phys_addr;
MESOSPHERE_ABORT_UNLESS(src_page_table.GetPhysicalAddressLocked(std::addressof(phys_addr), address));
/* Determine the current read size. */
const size_t cur_size = std::min<size_t>(last_address - address + 1, PageSize - (GetInteger(address) & (PageSize - 1)));
/* Read. */
R_TRY(dst_page_table.WriteIoMemoryImpl(phys_addr, src, cur_size, state));
/* Advance. */
address += cur_size;
src += cur_size;
}
R_SUCCEED();
}
Result KPageTableBase::LockForMapDeviceAddressSpace(bool *out_is_io, KProcessAddress address, size_t size, KMemoryPermission perm, bool is_aligned, bool check_heap) {
/* Lightly validate the range before doing anything else. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
const u32 test_state = (is_aligned ? KMemoryState_FlagCanAlignedDeviceMap : KMemoryState_FlagCanDeviceMap) | (check_heap ? KMemoryState_FlagReferenceCounted : KMemoryState_None);
size_t num_allocator_blocks;
KMemoryState old_state;
R_TRY(this->CheckMemoryState(std::addressof(old_state), nullptr, nullptr, std::addressof(num_allocator_blocks), address, size, test_state, test_state, perm, perm, KMemoryAttribute_IpcLocked | KMemoryAttribute_Locked, KMemoryAttribute_None, KMemoryAttribute_DeviceShared));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Update the memory blocks. */
m_memory_block_manager.UpdateLock(std::addressof(allocator), address, num_pages, &KMemoryBlock::ShareToDevice, KMemoryPermission_None);
/* Set whether the locked memory was io. */
*out_is_io = static_cast<ams::svc::MemoryState>(old_state & KMemoryState_Mask) == ams::svc::MemoryState_Io;
R_SUCCEED();
}
Result KPageTableBase::LockForUnmapDeviceAddressSpace(KProcessAddress address, size_t size, bool check_heap) {
/* Lightly validate the range before doing anything else. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
const u32 test_state = KMemoryState_FlagCanDeviceMap | (check_heap ? KMemoryState_FlagReferenceCounted : KMemoryState_None);
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryStateContiguous(std::addressof(num_allocator_blocks),
address, size,
test_state, test_state,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked, KMemoryAttribute_DeviceShared));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Update the memory blocks. */
const KMemoryBlockManager::MemoryBlockLockFunction lock_func = m_enable_device_address_space_merge ? &KMemoryBlock::UpdateDeviceDisableMergeStateForShare : &KMemoryBlock::UpdateDeviceDisableMergeStateForShareRight;
m_memory_block_manager.UpdateLock(std::addressof(allocator), address, num_pages, lock_func, KMemoryPermission_None);
R_SUCCEED();
}
Result KPageTableBase::UnlockForDeviceAddressSpace(KProcessAddress address, size_t size) {
/* Lightly validate the range before doing anything else. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryStateContiguous(std::addressof(num_allocator_blocks),
address, size,
KMemoryState_FlagCanDeviceMap, KMemoryState_FlagCanDeviceMap,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked, KMemoryAttribute_DeviceShared));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Update the memory blocks. */
m_memory_block_manager.UpdateLock(std::addressof(allocator), address, num_pages, &KMemoryBlock::UnshareToDevice, KMemoryPermission_None);
R_SUCCEED();
}
Result KPageTableBase::UnlockForDeviceAddressSpacePartialMap(KProcessAddress address, size_t size) {
/* Lightly validate the range before doing anything else. */
const size_t num_pages = size / PageSize;
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check memory state. */
size_t allocator_num_blocks = 0;
R_TRY(this->CheckMemoryStateContiguous(std::addressof(allocator_num_blocks),
address, size,
KMemoryState_FlagCanDeviceMap, KMemoryState_FlagCanDeviceMap,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked, KMemoryAttribute_DeviceShared));
/* Create an update allocator for the region. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, allocator_num_blocks);
R_TRY(allocator_result);
/* Update the memory blocks. */
m_memory_block_manager.UpdateLock(std::addressof(allocator), address, num_pages, m_enable_device_address_space_merge ? &KMemoryBlock::UpdateDeviceDisableMergeStateForUnshare : &KMemoryBlock::UpdateDeviceDisableMergeStateForUnshareRight, KMemoryPermission_None);
R_SUCCEED();
}
Result KPageTableBase::OpenMemoryRangeForMapDeviceAddressSpace(KPageTableBase::MemoryRange *out, KProcessAddress address, size_t size, KMemoryPermission perm, bool is_aligned) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Get the range. */
const u32 test_state = (is_aligned ? KMemoryState_FlagCanAlignedDeviceMap : KMemoryState_FlagCanDeviceMap);
R_TRY(this->GetContiguousMemoryRangeWithState(out,
address, size,
test_state, test_state,
perm, perm,
KMemoryAttribute_IpcLocked | KMemoryAttribute_Locked, KMemoryAttribute_None));
/* We got the range, so open it. */
out->Open();
R_SUCCEED();
}
Result KPageTableBase::OpenMemoryRangeForUnmapDeviceAddressSpace(MemoryRange *out, KProcessAddress address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Get the range. */
R_TRY(this->GetContiguousMemoryRangeWithState(out,
address, size,
KMemoryState_FlagCanDeviceMap, KMemoryState_FlagCanDeviceMap,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked, KMemoryAttribute_DeviceShared));
/* We got the range, so open it. */
out->Open();
R_SUCCEED();
}
Result KPageTableBase::LockForIpcUserBuffer(KPhysicalAddress *out, KProcessAddress address, size_t size) {
R_RETURN(this->LockMemoryAndOpen(nullptr, out, address, size,
KMemoryState_FlagCanIpcUserBuffer, KMemoryState_FlagCanIpcUserBuffer,
KMemoryPermission_All, KMemoryPermission_UserReadWrite,
KMemoryAttribute_All, KMemoryAttribute_None,
static_cast<KMemoryPermission>(KMemoryPermission_NotMapped | KMemoryPermission_KernelReadWrite),
KMemoryAttribute_Locked));
}
Result KPageTableBase::UnlockForIpcUserBuffer(KProcessAddress address, size_t size) {
R_RETURN(this->UnlockMemory(address, size,
KMemoryState_FlagCanIpcUserBuffer, KMemoryState_FlagCanIpcUserBuffer,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_All, KMemoryAttribute_Locked,
KMemoryPermission_UserReadWrite,
KMemoryAttribute_Locked, nullptr));
}
Result KPageTableBase::LockForTransferMemory(KPageGroup *out, KProcessAddress address, size_t size, KMemoryPermission perm) {
R_RETURN(this->LockMemoryAndOpen(out, nullptr, address, size,
KMemoryState_FlagCanTransfer, KMemoryState_FlagCanTransfer,
KMemoryPermission_All, KMemoryPermission_UserReadWrite,
KMemoryAttribute_All, KMemoryAttribute_None,
perm,
KMemoryAttribute_Locked));
}
Result KPageTableBase::UnlockForTransferMemory(KProcessAddress address, size_t size, const KPageGroup &pg) {
R_RETURN(this->UnlockMemory(address, size,
KMemoryState_FlagCanTransfer, KMemoryState_FlagCanTransfer,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_All, KMemoryAttribute_Locked,
KMemoryPermission_UserReadWrite,
KMemoryAttribute_Locked, std::addressof(pg)));
}
2020-07-29 00:09:07 +02:00
Result KPageTableBase::LockForCodeMemory(KPageGroup *out, KProcessAddress address, size_t size) {
R_RETURN(this->LockMemoryAndOpen(out, nullptr, address, size,
KMemoryState_FlagCanCodeMemory, KMemoryState_FlagCanCodeMemory,
KMemoryPermission_All, KMemoryPermission_UserReadWrite,
KMemoryAttribute_All, KMemoryAttribute_None,
static_cast<KMemoryPermission>(KMemoryPermission_NotMapped | KMemoryPermission_KernelReadWrite),
KMemoryAttribute_Locked));
}
Result KPageTableBase::UnlockForCodeMemory(KProcessAddress address, size_t size, const KPageGroup &pg) {
R_RETURN(this->UnlockMemory(address, size,
KMemoryState_FlagCanCodeMemory, KMemoryState_FlagCanCodeMemory,
KMemoryPermission_None, KMemoryPermission_None,
KMemoryAttribute_All, KMemoryAttribute_Locked,
KMemoryPermission_UserReadWrite,
KMemoryAttribute_Locked, std::addressof(pg)));
}
Result KPageTableBase::OpenMemoryRangeForProcessCacheOperation(MemoryRange *out, KProcessAddress address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Get the range. */
R_TRY(this->GetContiguousMemoryRangeWithState(out,
address, size,
KMemoryState_FlagReferenceCounted, KMemoryState_FlagReferenceCounted,
KMemoryPermission_UserRead, KMemoryPermission_UserRead,
KMemoryAttribute_Uncached, KMemoryAttribute_None));
/* We got the range, so open it. */
out->Open();
R_SUCCEED();
}
2020-07-10 10:15:14 +02:00
Result KPageTableBase::CopyMemoryFromLinearToUser(KProcessAddress dst_addr, size_t size, KProcessAddress src_addr, u32 src_state_mask, u32 src_state, KMemoryPermission src_test_perm, u32 src_attr_mask, u32 src_attr) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(src_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check memory state. */
R_TRY(this->CheckMemoryStateContiguous(src_addr, size, src_state_mask, src_state, src_test_perm, src_test_perm, src_attr_mask | KMemoryAttribute_Uncached, src_attr));
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), src_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy as much aligned data as we can. */
if (cur_size >= sizeof(u32)) {
const size_t copy_size = util::AlignDown(cur_size, sizeof(u32));
R_UNLESS(UserspaceAccess::CopyMemoryToUserAligned32Bit(GetVoidPointer(dst_addr), GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), copy_size), svc::ResultInvalidCurrentMemory());
dst_addr += copy_size;
cur_addr += copy_size;
cur_size -= copy_size;
}
/* Copy remaining data. */
if (cur_size > 0) {
R_UNLESS(UserspaceAccess::CopyMemoryToUser(GetVoidPointer(dst_addr), GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), cur_size), svc::ResultInvalidCurrentMemory());
}
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
dst_addr += cur_size;
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
}
R_SUCCEED();
2020-07-10 10:15:14 +02:00
}
Result KPageTableBase::CopyMemoryFromLinearToKernel(KProcessAddress dst_addr, size_t size, KProcessAddress src_addr, u32 src_state_mask, u32 src_state, KMemoryPermission src_test_perm, u32 src_attr_mask, u32 src_attr) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(src_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check memory state. */
R_TRY(this->CheckMemoryStateContiguous(src_addr, size, src_state_mask, src_state, src_test_perm, src_test_perm, src_attr_mask | KMemoryAttribute_Uncached, src_attr));
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), src_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy the data. */
std::memcpy(GetVoidPointer(dst_addr), GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), cur_size);
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
dst_addr += cur_size;
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
}
R_SUCCEED();
2020-07-10 10:15:14 +02:00
}
Result KPageTableBase::CopyMemoryFromUserToLinear(KProcessAddress dst_addr, size_t size, u32 dst_state_mask, u32 dst_state, KMemoryPermission dst_test_perm, u32 dst_attr_mask, u32 dst_attr, KProcessAddress src_addr) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(dst_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check memory state. */
R_TRY(this->CheckMemoryStateContiguous(dst_addr, size, dst_state_mask, dst_state, dst_test_perm, dst_test_perm, dst_attr_mask | KMemoryAttribute_Uncached, dst_attr));
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), dst_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy as much aligned data as we can. */
if (cur_size >= sizeof(u32)) {
const size_t copy_size = util::AlignDown(cur_size, sizeof(u32));
R_UNLESS(UserspaceAccess::CopyMemoryFromUserAligned32Bit(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), GetVoidPointer(src_addr), copy_size), svc::ResultInvalidCurrentMemory());
src_addr += copy_size;
cur_addr += copy_size;
cur_size -= copy_size;
}
/* Copy remaining data. */
if (cur_size > 0) {
R_UNLESS(UserspaceAccess::CopyMemoryFromUser(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), GetVoidPointer(src_addr), cur_size), svc::ResultInvalidCurrentMemory());
}
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
src_addr += cur_size;
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
}
R_SUCCEED();
2020-07-10 10:15:14 +02:00
}
Result KPageTableBase::CopyMemoryFromKernelToLinear(KProcessAddress dst_addr, size_t size, u32 dst_state_mask, u32 dst_state, KMemoryPermission dst_test_perm, u32 dst_attr_mask, u32 dst_attr, KProcessAddress src_addr) {
/* Lightly validate the range before doing anything else. */
R_UNLESS(this->Contains(dst_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check memory state. */
R_TRY(this->CheckMemoryStateContiguous(dst_addr, size, dst_state_mask, dst_state, dst_test_perm, dst_test_perm, dst_attr_mask | KMemoryAttribute_Uncached, dst_attr));
auto &impl = this->GetImpl();
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), dst_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_addr = next_entry.phys_addr;
size_t cur_size = next_entry.block_size - (GetInteger(cur_addr) & (next_entry.block_size - 1));
size_t tot_size = cur_size;
Minor header fixes to reduce parsing issues with Clang (#1700) * Work around Clang's incomplete C++20 support for omitting typename * vapours: fix Clang error about missing return in constexpr function * stratosphere: fix call to non-constexpr strlen in constexpr function strlen being constexpr is a non-compliant GCC extension; Clang explicitly rejects it: https://reviews.llvm.org/D23692 * stratosphere: add a bunch of missing override specifiers * stratosphere: work around Clang consteval bug Minimal example: https://godbolt.org/z/MoM64v93M The issue seems to be that Clang does not consider f(x) to be a constant expression if x comes from a template argument that isn't a non-type auto template argument (???) We can work around this by relaxing GetMessageHeaderForCheck (by using constexpr instead of consteval). This produces no functional changes because the result of GetMessageHeaderForCheck() is assigned to a constexpr variable, so the result is guaranteed to be computed at compile-time. * stratosphere: fix missing require clauses in definitions GCC not requiring the require clauses to be repeated for member definitions is actually a compiler bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=96830 Clang rejects declarations with missing require clauses. * Fix ALWAYS_INLINE_LAMBDA and parameter list relative order While GCC doesn't seem to care about the position of the always_inline attribute relative to the parameter list, Clang is very picky and requires the attribute to appear after the parameter list (and before a trailing return type) * stratosphere: fix static constexpr member variable with incomplete type GCC accepts this for some reason (because of the lambda?) but Clang correctly rejects this.
2021-11-07 02:19:34 +01:00
auto PerformCopy = [&]() ALWAYS_INLINE_LAMBDA -> Result {
/* Ensure the address is linear mapped. */
R_UNLESS(IsLinearMappedPhysicalAddress(cur_addr), svc::ResultInvalidCurrentMemory());
/* Copy the data. */
std::memcpy(GetVoidPointer(GetLinearMappedVirtualAddress(cur_addr)), GetVoidPointer(src_addr), cur_size);
R_SUCCEED();
};
/* Iterate. */
while (tot_size < size) {
/* Continue the traversal. */
traverse_valid = impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
if (next_entry.phys_addr != (cur_addr + cur_size)) {
/* Perform copy. */
R_TRY(PerformCopy());
/* Advance. */
src_addr += cur_size;
cur_addr = next_entry.phys_addr;
cur_size = next_entry.block_size;
} else {
cur_size += next_entry.block_size;
}
tot_size += next_entry.block_size;
}
/* Ensure we use the right size for the last block. */
if (tot_size > size) {
cur_size -= (tot_size - size);
}
/* Perform copy for the last block. */
R_TRY(PerformCopy());
}
R_SUCCEED();
2020-07-10 10:15:14 +02:00
}
Result KPageTableBase::CopyMemoryFromHeapToHeap(KPageTableBase &dst_page_table, KProcessAddress dst_addr, size_t size, u32 dst_state_mask, u32 dst_state, KMemoryPermission dst_test_perm, u32 dst_attr_mask, u32 dst_attr, KProcessAddress src_addr, u32 src_state_mask, u32 src_state, KMemoryPermission src_test_perm, u32 src_attr_mask, u32 src_attr) {
/* For convenience, alias this. */
KPageTableBase &src_page_table = *this;
/* Lightly validate the ranges before doing anything else. */
R_UNLESS(src_page_table.Contains(src_addr, size), svc::ResultInvalidCurrentMemory());
R_UNLESS(dst_page_table.Contains(dst_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
/* Check memory state. */
R_TRY(src_page_table.CheckMemoryStateContiguous(src_addr, size, src_state_mask, src_state, src_test_perm, src_test_perm, src_attr_mask | KMemoryAttribute_Uncached, src_attr));
R_TRY(dst_page_table.CheckMemoryStateContiguous(dst_addr, size, dst_state_mask, dst_state, dst_test_perm, dst_test_perm, dst_attr_mask | KMemoryAttribute_Uncached, dst_attr));
/* Get implementations. */
auto &src_impl = src_page_table.GetImpl();
auto &dst_impl = dst_page_table.GetImpl();
/* Prepare for traversal. */
TraversalContext src_context;
TraversalContext dst_context;
TraversalEntry src_next_entry;
TraversalEntry dst_next_entry;
bool traverse_valid;
/* Begin traversal. */
traverse_valid = src_impl.BeginTraversal(std::addressof(src_next_entry), std::addressof(src_context), src_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
traverse_valid = dst_impl.BeginTraversal(std::addressof(dst_next_entry), std::addressof(dst_context), dst_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_src_block_addr = src_next_entry.phys_addr;
KPhysicalAddress cur_dst_block_addr = dst_next_entry.phys_addr;
size_t cur_src_size = src_next_entry.block_size - (GetInteger(cur_src_block_addr) & (src_next_entry.block_size - 1));
size_t cur_dst_size = dst_next_entry.block_size - (GetInteger(cur_dst_block_addr) & (dst_next_entry.block_size - 1));
/* Adjust the initial block sizes. */
src_next_entry.block_size = cur_src_size;
dst_next_entry.block_size = cur_dst_size;
/* Before we get any crazier, succeed if there's nothing to do. */
R_SUCCEED_IF(size == 0);
/* We're going to manage dual traversal via an offset against the total size. */
KPhysicalAddress cur_src_addr = cur_src_block_addr;
KPhysicalAddress cur_dst_addr = cur_dst_block_addr;
size_t cur_min_size = std::min<size_t>(cur_src_size, cur_dst_size);
/* Iterate. */
size_t ofs = 0;
while (ofs < size) {
/* Determine how much we can copy this iteration. */
const size_t cur_copy_size = std::min<size_t>(cur_min_size, size - ofs);
/* If we need to advance the traversals, do so. */
bool updated_src = false, updated_dst = false, skip_copy = false;
if (ofs + cur_copy_size != size) {
if (cur_src_addr + cur_min_size == cur_src_block_addr + cur_src_size) {
/* Continue the src traversal. */
traverse_valid = src_impl.ContinueTraversal(std::addressof(src_next_entry), std::addressof(src_context));
MESOSPHERE_ASSERT(traverse_valid);
/* Update source. */
updated_src = cur_src_addr + cur_min_size != GetInteger(src_next_entry.phys_addr);
}
if (cur_dst_addr + cur_min_size == dst_next_entry.phys_addr + dst_next_entry.block_size) {
/* Continue the dst traversal. */
traverse_valid = dst_impl.ContinueTraversal(std::addressof(dst_next_entry), std::addressof(dst_context));
MESOSPHERE_ASSERT(traverse_valid);
/* Update destination. */
updated_dst = cur_dst_addr + cur_min_size != GetInteger(dst_next_entry.phys_addr);
}
/* If we didn't update either of source/destination, skip the copy this iteration. */
if (!updated_src && !updated_dst) {
skip_copy = true;
/* Update the source block address. */
cur_src_block_addr = src_next_entry.phys_addr;
}
}
/* Do the copy, unless we're skipping it. */
if (!skip_copy) {
/* We need both ends of the copy to be heap blocks. */
R_UNLESS(IsHeapPhysicalAddress(cur_src_addr), svc::ResultInvalidCurrentMemory());
R_UNLESS(IsHeapPhysicalAddress(cur_dst_addr), svc::ResultInvalidCurrentMemory());
/* Copy the data. */
std::memcpy(GetVoidPointer(GetHeapVirtualAddress(cur_dst_addr)), GetVoidPointer(GetHeapVirtualAddress(cur_src_addr)), cur_copy_size);
/* Update. */
cur_src_block_addr = src_next_entry.phys_addr;
cur_src_addr = updated_src ? cur_src_block_addr : cur_src_addr + cur_copy_size;
cur_dst_block_addr = dst_next_entry.phys_addr;
cur_dst_addr = updated_dst ? cur_dst_block_addr : cur_dst_addr + cur_copy_size;
/* Advance offset. */
ofs += cur_copy_size;
}
/* Update min size. */
cur_src_size = src_next_entry.block_size;
cur_dst_size = dst_next_entry.block_size;
cur_min_size = std::min<size_t>(cur_src_block_addr - cur_src_addr + cur_src_size, cur_dst_block_addr - cur_dst_addr + cur_dst_size);
}
}
R_SUCCEED();
2020-07-10 10:15:14 +02:00
}
Result KPageTableBase::CopyMemoryFromHeapToHeapWithoutCheckDestination(KPageTableBase &dst_page_table, KProcessAddress dst_addr, size_t size, u32 dst_state_mask, u32 dst_state, KMemoryPermission dst_test_perm, u32 dst_attr_mask, u32 dst_attr, KProcessAddress src_addr, u32 src_state_mask, u32 src_state, KMemoryPermission src_test_perm, u32 src_attr_mask, u32 src_attr) {
/* For convenience, alias this. */
KPageTableBase &src_page_table = *this;
/* Lightly validate the ranges before doing anything else. */
R_UNLESS(src_page_table.Contains(src_addr, size), svc::ResultInvalidCurrentMemory());
R_UNLESS(dst_page_table.Contains(dst_addr, size), svc::ResultInvalidCurrentMemory());
/* Copy the memory. */
{
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
2020-08-17 23:20:24 +02:00
/* Check memory state for source. */
R_TRY(src_page_table.CheckMemoryStateContiguous(src_addr, size, src_state_mask, src_state, src_test_perm, src_test_perm, src_attr_mask | KMemoryAttribute_Uncached, src_attr));
2020-08-17 23:20:24 +02:00
/* Destination state is intentionally unchecked. */
MESOSPHERE_UNUSED(dst_state_mask, dst_state, dst_test_perm, dst_attr_mask, dst_attr);
/* Get implementations. */
auto &src_impl = src_page_table.GetImpl();
auto &dst_impl = dst_page_table.GetImpl();
/* Prepare for traversal. */
TraversalContext src_context;
TraversalContext dst_context;
TraversalEntry src_next_entry;
TraversalEntry dst_next_entry;
bool traverse_valid;
/* Begin traversal. */
traverse_valid = src_impl.BeginTraversal(std::addressof(src_next_entry), std::addressof(src_context), src_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
traverse_valid = dst_impl.BeginTraversal(std::addressof(dst_next_entry), std::addressof(dst_context), dst_addr);
MESOSPHERE_ABORT_UNLESS(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_src_block_addr = src_next_entry.phys_addr;
KPhysicalAddress cur_dst_block_addr = dst_next_entry.phys_addr;
size_t cur_src_size = src_next_entry.block_size - (GetInteger(cur_src_block_addr) & (src_next_entry.block_size - 1));
size_t cur_dst_size = dst_next_entry.block_size - (GetInteger(cur_dst_block_addr) & (dst_next_entry.block_size - 1));
/* Adjust the initial block sizes. */
src_next_entry.block_size = cur_src_size;
dst_next_entry.block_size = cur_dst_size;
/* Before we get any crazier, succeed if there's nothing to do. */
R_SUCCEED_IF(size == 0);
/* We're going to manage dual traversal via an offset against the total size. */
KPhysicalAddress cur_src_addr = cur_src_block_addr;
KPhysicalAddress cur_dst_addr = cur_dst_block_addr;
size_t cur_min_size = std::min<size_t>(cur_src_size, cur_dst_size);
/* Iterate. */
size_t ofs = 0;
while (ofs < size) {
/* Determine how much we can copy this iteration. */
const size_t cur_copy_size = std::min<size_t>(cur_min_size, size - ofs);
/* If we need to advance the traversals, do so. */
bool updated_src = false, updated_dst = false, skip_copy = false;
if (ofs + cur_copy_size != size) {
if (cur_src_addr + cur_min_size == cur_src_block_addr + cur_src_size) {
/* Continue the src traversal. */
traverse_valid = src_impl.ContinueTraversal(std::addressof(src_next_entry), std::addressof(src_context));
MESOSPHERE_ASSERT(traverse_valid);
/* Update source. */
updated_src = cur_src_addr + cur_min_size != GetInteger(src_next_entry.phys_addr);
}
if (cur_dst_addr + cur_min_size == dst_next_entry.phys_addr + dst_next_entry.block_size) {
/* Continue the dst traversal. */
traverse_valid = dst_impl.ContinueTraversal(std::addressof(dst_next_entry), std::addressof(dst_context));
MESOSPHERE_ASSERT(traverse_valid);
/* Update destination. */
updated_dst = cur_dst_addr + cur_min_size != GetInteger(dst_next_entry.phys_addr);
}
/* If we didn't update either of source/destination, skip the copy this iteration. */
if (!updated_src && !updated_dst) {
skip_copy = true;
/* Update the source block address. */
cur_src_block_addr = src_next_entry.phys_addr;
}
}
/* Do the copy, unless we're skipping it. */
if (!skip_copy) {
/* We need both ends of the copy to be heap blocks. */
R_UNLESS(IsHeapPhysicalAddress(cur_src_addr), svc::ResultInvalidCurrentMemory());
R_UNLESS(IsHeapPhysicalAddress(cur_dst_addr), svc::ResultInvalidCurrentMemory());
/* Copy the data. */
std::memcpy(GetVoidPointer(GetHeapVirtualAddress(cur_dst_addr)), GetVoidPointer(GetHeapVirtualAddress(cur_src_addr)), cur_copy_size);
/* Update. */
cur_src_block_addr = src_next_entry.phys_addr;
cur_src_addr = updated_src ? cur_src_block_addr : cur_src_addr + cur_copy_size;
cur_dst_block_addr = dst_next_entry.phys_addr;
cur_dst_addr = updated_dst ? cur_dst_block_addr : cur_dst_addr + cur_copy_size;
/* Advance offset. */
ofs += cur_copy_size;
}
/* Update min size. */
cur_src_size = src_next_entry.block_size;
cur_dst_size = dst_next_entry.block_size;
cur_min_size = std::min<size_t>(cur_src_block_addr - cur_src_addr + cur_src_size, cur_dst_block_addr - cur_dst_addr + cur_dst_size);
}
}
R_SUCCEED();
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}
#pragma GCC push_options
#pragma GCC optimize ("-O3")
Result KPageTableBase::SetupForIpcClient(PageLinkedList *page_list, size_t *out_blocks_needed, KProcessAddress address, size_t size, KMemoryPermission test_perm, KMemoryState dst_state) {
/* Validate pre-conditions. */
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
MESOSPHERE_ASSERT(test_perm == KMemoryPermission_UserReadWrite || test_perm == KMemoryPermission_UserRead);
/* Check that the address is in range. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Get the source permission. */
const auto src_perm = static_cast<KMemoryPermission>((test_perm == KMemoryPermission_UserReadWrite) ? (KMemoryPermission_KernelReadWrite | KMemoryPermission_NotMapped) : KMemoryPermission_UserRead);
/* Get aligned extents. */
const KProcessAddress aligned_src_start = util::AlignDown(GetInteger(address), PageSize);
const KProcessAddress aligned_src_end = util::AlignUp(GetInteger(address) + size, PageSize);
const KProcessAddress mapping_src_start = util::AlignUp(GetInteger(address), PageSize);
const KProcessAddress mapping_src_end = util::AlignDown(GetInteger(address) + size, PageSize);
const auto aligned_src_last = GetInteger(aligned_src_end) - 1;
const auto mapping_src_last = GetInteger(mapping_src_end) - 1;
/* Get the test state and attribute mask. */
u32 test_state;
u32 test_attr_mask;
switch (dst_state) {
case KMemoryState_Ipc:
test_state = KMemoryState_FlagCanUseIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked;
break;
case KMemoryState_NonSecureIpc:
test_state = KMemoryState_FlagCanUseNonSecureIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_Locked;
break;
case KMemoryState_NonDeviceIpc:
test_state = KMemoryState_FlagCanUseNonDeviceIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_Locked;
break;
default:
R_THROW(svc::ResultInvalidCombination());
}
/* Ensure that on failure, we roll back appropriately. */
size_t mapped_size = 0;
ON_RESULT_FAILURE {
if (mapped_size > 0) {
this->CleanupForIpcClientOnServerSetupFailure(page_list, mapping_src_start, mapped_size, src_perm);
}
};
size_t blocks_needed = 0;
/* Iterate, mapping as needed. */
KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(aligned_src_start);
while (true) {
const KMemoryInfo info = it->GetMemoryInfo();
/* Validate the current block. */
R_TRY(this->CheckMemoryState(info, test_state, test_state, test_perm, test_perm, test_attr_mask, KMemoryAttribute_None));
if (mapping_src_start < mapping_src_end && GetInteger(mapping_src_start) < info.GetEndAddress() && info.GetAddress() < GetInteger(mapping_src_end)) {
const auto cur_start = info.GetAddress() >= GetInteger(mapping_src_start) ? info.GetAddress() : GetInteger(mapping_src_start);
const auto cur_end = mapping_src_last >= info.GetLastAddress() ? info.GetEndAddress() : GetInteger(mapping_src_end);
const size_t cur_size = cur_end - cur_start;
if (info.GetAddress() < GetInteger(mapping_src_start)) {
++blocks_needed;
}
if (mapping_src_last < info.GetLastAddress()) {
++blocks_needed;
}
/* Set the permissions on the block, if we need to. */
if ((info.GetPermission() & KMemoryPermission_IpcLockChangeMask) != src_perm) {
const DisableMergeAttribute head_body_attr = (GetInteger(mapping_src_start) >= info.GetAddress()) ? DisableMergeAttribute_DisableHeadAndBody : DisableMergeAttribute_None;
const DisableMergeAttribute tail_attr = (cur_end == GetInteger(mapping_src_end)) ? DisableMergeAttribute_DisableTail : DisableMergeAttribute_None;
const KPageProperties properties = { src_perm, false, false, static_cast<DisableMergeAttribute>(head_body_attr | tail_attr) };
R_TRY(this->Operate(page_list, cur_start, cur_size / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
}
/* Note that we mapped this part. */
mapped_size += cur_size;
}
/* If the block is at the end, we're done. */
if (aligned_src_last <= info.GetLastAddress()) {
break;
}
/* Advance. */
++it;
MESOSPHERE_ABORT_UNLESS(it != m_memory_block_manager.end());
}
if (out_blocks_needed != nullptr) {
MESOSPHERE_ASSERT(blocks_needed <= KMemoryBlockManagerUpdateAllocator::MaxBlocks);
*out_blocks_needed = blocks_needed;
}
R_SUCCEED();
}
Result KPageTableBase::SetupForIpcServer(KProcessAddress *out_addr, size_t size, KProcessAddress src_addr, KMemoryPermission test_perm, KMemoryState dst_state, KPageTableBase &src_page_table, bool send) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
MESOSPHERE_ASSERT(src_page_table.IsLockedByCurrentThread());
/* Check that we can theoretically map. */
const KProcessAddress region_start = m_region_starts[RegionType_Alias];
const size_t region_size = m_region_ends[RegionType_Alias] - m_region_starts[RegionType_Alias];
R_UNLESS(size < region_size, svc::ResultOutOfAddressSpace());
/* Get aligned source extents. */
const KProcessAddress src_start = src_addr;
const KProcessAddress src_end = src_addr + size;
const KProcessAddress aligned_src_start = util::AlignDown(GetInteger(src_start), PageSize);
const KProcessAddress aligned_src_end = util::AlignUp(GetInteger(src_start) + size, PageSize);
const KProcessAddress mapping_src_start = util::AlignUp(GetInteger(src_start), PageSize);
const KProcessAddress mapping_src_end = util::AlignDown(GetInteger(src_start) + size, PageSize);
const size_t aligned_src_size = aligned_src_end - aligned_src_start;
const size_t mapping_src_size = (mapping_src_start < mapping_src_end) ? (mapping_src_end - mapping_src_start) : 0;
/* Select a random address to map at. */
KProcessAddress dst_addr = Null<KProcessAddress>;
for (s32 block_type = KPageTable::GetMaxBlockType(); block_type >= 0; block_type--) {
const size_t alignment = KPageTable::GetBlockSize(static_cast<KPageTable::BlockType>(block_type));
const size_t offset = GetInteger(aligned_src_start) & (alignment - 1);
dst_addr = this->FindFreeArea(region_start, region_size / PageSize, aligned_src_size / PageSize, alignment, offset, this->GetNumGuardPages());
if (dst_addr != Null<KProcessAddress>) {
break;
}
}
R_UNLESS(dst_addr != Null<KProcessAddress>, svc::ResultOutOfAddressSpace());
/* Check that we can perform the operation we're about to perform. */
MESOSPHERE_ASSERT(this->CanContain(dst_addr, aligned_src_size, dst_state));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Reserve space for any partial pages we allocate. */
const size_t unmapped_size = aligned_src_size - mapping_src_size;
KScopedResourceReservation memory_reservation(m_resource_limit, ams::svc::LimitableResource_PhysicalMemoryMax, unmapped_size);
R_UNLESS(memory_reservation.Succeeded(), svc::ResultLimitReached());
/* Ensure that we manage page references correctly. */
KPhysicalAddress start_partial_page = Null<KPhysicalAddress>;
KPhysicalAddress end_partial_page = Null<KPhysicalAddress>;
KProcessAddress cur_mapped_addr = dst_addr;
/* If the partial pages are mapped, an extra reference will have been opened. Otherwise, they'll free on scope exit. */
ON_SCOPE_EXIT {
if (start_partial_page != Null<KPhysicalAddress>) {
Kernel::GetMemoryManager().Close(start_partial_page, 1);
}
if (end_partial_page != Null<KPhysicalAddress>) {
Kernel::GetMemoryManager().Close(end_partial_page, 1);
}
};
ON_RESULT_FAILURE {
if (cur_mapped_addr != dst_addr) {
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), dst_addr, (cur_mapped_addr - dst_addr) / PageSize, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, true));
}
};
/* Allocate the start page as needed. */
if (aligned_src_start < mapping_src_start) {
start_partial_page = Kernel::GetMemoryManager().AllocateAndOpenContinuous(1, 1, m_allocate_option);
R_UNLESS(start_partial_page != Null<KPhysicalAddress>, svc::ResultOutOfMemory());
}
/* Allocate the end page as needed. */
if (mapping_src_end < aligned_src_end && (aligned_src_start < mapping_src_end || aligned_src_start == mapping_src_start)) {
end_partial_page = Kernel::GetMemoryManager().AllocateAndOpenContinuous(1, 1, m_allocate_option);
R_UNLESS(end_partial_page != Null<KPhysicalAddress>, svc::ResultOutOfMemory());
}
/* Get the implementation. */
auto &src_impl = src_page_table.GetImpl();
/* Get the fill value for partial pages. */
const auto fill_val = m_ipc_fill_value;
/* Begin traversal. */
TraversalContext context;
TraversalEntry next_entry;
bool traverse_valid = src_impl.BeginTraversal(std::addressof(next_entry), std::addressof(context), aligned_src_start);
MESOSPHERE_ASSERT(traverse_valid);
MESOSPHERE_UNUSED(traverse_valid);
/* Prepare tracking variables. */
KPhysicalAddress cur_block_addr = next_entry.phys_addr;
size_t cur_block_size = next_entry.block_size - (GetInteger(cur_block_addr) & (next_entry.block_size - 1));
size_t tot_block_size = cur_block_size;
/* Map the start page, if we have one. */
if (start_partial_page != Null<KPhysicalAddress>) {
/* Ensure the page holds correct data. */
const KVirtualAddress start_partial_virt = GetHeapVirtualAddress(start_partial_page);
if (send) {
const size_t partial_offset = src_start - aligned_src_start;
size_t copy_size, clear_size;
if (src_end < mapping_src_start) {
copy_size = size;
clear_size = mapping_src_start - src_end;
} else {
copy_size = mapping_src_start - src_start;
clear_size = 0;
}
std::memset(GetVoidPointer(start_partial_virt), fill_val, partial_offset);
std::memcpy(GetVoidPointer(start_partial_virt + partial_offset), GetVoidPointer(GetHeapVirtualAddress(cur_block_addr) + partial_offset), copy_size);
if (clear_size > 0) {
std::memset(GetVoidPointer(start_partial_virt + partial_offset + copy_size), fill_val, clear_size);
}
} else {
std::memset(GetVoidPointer(start_partial_virt), fill_val, PageSize);
}
/* Map the page. */
const KPageProperties start_map_properties = { test_perm, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(updater.GetPageList(), cur_mapped_addr, 1, start_partial_page, true, start_map_properties, OperationType_Map, false));
/* Update tracking extents. */
cur_mapped_addr += PageSize;
cur_block_addr += PageSize;
cur_block_size -= PageSize;
/* If the block's size was one page, we may need to continue traversal. */
if (cur_block_size == 0 && aligned_src_size > PageSize) {
traverse_valid = src_impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
cur_block_addr = next_entry.phys_addr;
cur_block_size = next_entry.block_size;
tot_block_size += next_entry.block_size;
}
}
/* Map the remaining pages. */
while (aligned_src_start + tot_block_size < mapping_src_end) {
/* Continue the traversal. */
traverse_valid = src_impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
/* Process the block. */
if (next_entry.phys_addr != cur_block_addr + cur_block_size) {
/* Map the block we've been processing so far. */
const KPageProperties map_properties = { test_perm, false, false, (cur_mapped_addr == dst_addr) ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), cur_mapped_addr, cur_block_size / PageSize, cur_block_addr, true, map_properties, OperationType_Map, false));
/* Update tracking extents. */
cur_mapped_addr += cur_block_size;
cur_block_addr = next_entry.phys_addr;
cur_block_size = next_entry.block_size;
} else {
cur_block_size += next_entry.block_size;
}
tot_block_size += next_entry.block_size;
}
/* Handle the last direct-mapped page. */
if (const KProcessAddress mapped_block_end = aligned_src_start + tot_block_size - cur_block_size; mapped_block_end < mapping_src_end) {
const size_t last_block_size = mapping_src_end - mapped_block_end;
/* Map the last block. */
const KPageProperties map_properties = { test_perm, false, false, (cur_mapped_addr == dst_addr) ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), cur_mapped_addr, last_block_size / PageSize, cur_block_addr, true, map_properties, OperationType_Map, false));
/* Update tracking extents. */
cur_mapped_addr += last_block_size;
cur_block_addr += last_block_size;
if (mapped_block_end + cur_block_size < aligned_src_end && cur_block_size == last_block_size) {
traverse_valid = src_impl.ContinueTraversal(std::addressof(next_entry), std::addressof(context));
MESOSPHERE_ASSERT(traverse_valid);
cur_block_addr = next_entry.phys_addr;
}
}
/* Map the end page, if we have one. */
if (end_partial_page != Null<KPhysicalAddress>) {
/* Ensure the page holds correct data. */
const KVirtualAddress end_partial_virt = GetHeapVirtualAddress(end_partial_page);
if (send) {
const size_t copy_size = src_end - mapping_src_end;
std::memcpy(GetVoidPointer(end_partial_virt), GetVoidPointer(GetHeapVirtualAddress(cur_block_addr)), copy_size);
std::memset(GetVoidPointer(end_partial_virt + copy_size), fill_val, PageSize - copy_size);
} else {
std::memset(GetVoidPointer(end_partial_virt), fill_val, PageSize);
}
/* Map the page. */
const KPageProperties map_properties = { test_perm, false, false, (cur_mapped_addr == dst_addr) ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), cur_mapped_addr, 1, end_partial_page, true, map_properties, OperationType_Map, false));
}
/* Update memory blocks to reflect our changes */
m_memory_block_manager.Update(std::addressof(allocator), dst_addr, aligned_src_size / PageSize, dst_state, test_perm, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* Set the output address. */
2020-07-13 03:53:45 +02:00
*out_addr = dst_addr + (src_start - aligned_src_start);
/* We succeeded. */
memory_reservation.Commit();
R_SUCCEED();
}
Result KPageTableBase::SetupForIpc(KProcessAddress *out_dst_addr, size_t size, KProcessAddress src_addr, KPageTableBase &src_page_table, KMemoryPermission test_perm, KMemoryState dst_state, bool send) {
/* For convenience, alias this. */
KPageTableBase &dst_page_table = *this;
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(std::addressof(src_page_table));
/* Perform client setup. */
size_t num_allocator_blocks;
R_TRY(src_page_table.SetupForIpcClient(updater.GetPageList(), std::addressof(num_allocator_blocks), src_addr, size, test_perm, dst_state));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), src_page_table.m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* Get the mapped extents. */
const KProcessAddress src_map_start = util::AlignUp(GetInteger(src_addr), PageSize);
const KProcessAddress src_map_end = util::AlignDown(GetInteger(src_addr) + size, PageSize);
const size_t src_map_size = src_map_end - src_map_start;
/* Ensure that we clean up appropriately if we fail after this. */
const auto src_perm = static_cast<KMemoryPermission>((test_perm == KMemoryPermission_UserReadWrite) ? (KMemoryPermission_KernelReadWrite | KMemoryPermission_NotMapped) : KMemoryPermission_UserRead);
ON_RESULT_FAILURE {
if (src_map_end > src_map_start) {
src_page_table.CleanupForIpcClientOnServerSetupFailure(updater.GetPageList(), src_map_start, src_map_size, src_perm);
}
};
/* Perform server setup. */
R_TRY(dst_page_table.SetupForIpcServer(out_dst_addr, size, src_addr, test_perm, dst_state, src_page_table, send));
/* If anything was mapped, ipc-lock the pages. */
if (src_map_start < src_map_end) {
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/* Get the source permission. */
src_page_table.m_memory_block_manager.UpdateLock(std::addressof(allocator), src_map_start, (src_map_end - src_map_start) / PageSize, &KMemoryBlock::LockForIpc, src_perm);
}
R_SUCCEED();
}
Result KPageTableBase::CleanupForIpcServer(KProcessAddress address, size_t size, KMemoryState dst_state) {
/* Validate the address. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Validate the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, dst_state, KMemoryPermission_UserRead, KMemoryPermission_UserRead, KMemoryAttribute_All, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Get aligned extents. */
const KProcessAddress aligned_start = util::AlignDown(GetInteger(address), PageSize);
const KProcessAddress aligned_end = util::AlignUp(GetInteger(address) + size, PageSize);
const size_t aligned_size = aligned_end - aligned_start;
const size_t aligned_num_pages = aligned_size / PageSize;
/* Unmap the pages. */
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), aligned_start, aligned_num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Update memory blocks. */
m_memory_block_manager.Update(std::addressof(allocator), aligned_start, aligned_num_pages, KMemoryState_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
/* Release from the resource limit as relevant. */
const KProcessAddress mapping_start = util::AlignUp(GetInteger(address), PageSize);
const KProcessAddress mapping_end = util::AlignDown(GetInteger(address) + size, PageSize);
const size_t mapping_size = (mapping_start < mapping_end) ? mapping_end - mapping_start : 0;
m_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, aligned_size - mapping_size);
R_SUCCEED();
}
Result KPageTableBase::CleanupForIpcClient(KProcessAddress address, size_t size, KMemoryState dst_state) {
/* Validate the address. */
R_UNLESS(this->Contains(address, size), svc::ResultInvalidCurrentMemory());
/* Get aligned source extents. */
const KProcessAddress mapping_start = util::AlignUp(GetInteger(address), PageSize);
const KProcessAddress mapping_end = util::AlignDown(GetInteger(address) + size, PageSize);
const KProcessAddress mapping_last = mapping_end - 1;
const size_t mapping_size = (mapping_start < mapping_end) ? (mapping_end - mapping_start) : 0;
/* If nothing was mapped, we're actually done immediately. */
R_SUCCEED_IF(mapping_size == 0);
/* Get the test state and attribute mask. */
u32 test_state;
u32 test_attr_mask;
switch (dst_state) {
case KMemoryState_Ipc:
test_state = KMemoryState_FlagCanUseIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_DeviceShared | KMemoryAttribute_Locked;
break;
case KMemoryState_NonSecureIpc:
test_state = KMemoryState_FlagCanUseNonSecureIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_Locked;
break;
case KMemoryState_NonDeviceIpc:
test_state = KMemoryState_FlagCanUseNonDeviceIpc;
test_attr_mask = KMemoryAttribute_Uncached | KMemoryAttribute_Locked;
break;
default:
R_THROW(svc::ResultInvalidCombination());
}
/* Lock the table. */
/* NOTE: Nintendo does this *after* creating the updater below, but this does not follow convention elsewhere in KPageTableBase. */
KScopedLightLock lk(m_general_lock);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Ensure that on failure, we roll back appropriately. */
size_t mapped_size = 0;
ON_RESULT_FAILURE {
if (mapped_size > 0) {
/* Determine where the mapping ends. */
const auto mapped_end = GetInteger(mapping_start) + mapped_size;
const auto mapped_last = mapped_end - 1;
/* Get current and next iterators. */
KMemoryBlockManager::const_iterator start_it = m_memory_block_manager.FindIterator(mapping_start);
KMemoryBlockManager::const_iterator next_it = start_it;
++next_it;
/* Get the current block info. */
KMemoryInfo cur_info = start_it->GetMemoryInfo();
/* Create tracking variables. */
KProcessAddress cur_address = cur_info.GetAddress();
size_t cur_size = cur_info.GetSize();
bool cur_perm_eq = cur_info.GetPermission() == cur_info.GetOriginalPermission();
bool cur_needs_set_perm = !cur_perm_eq && cur_info.GetIpcLockCount() == 1;
bool first = cur_info.GetIpcDisableMergeCount() == 1 && (cur_info.GetDisableMergeAttribute() & KMemoryBlockDisableMergeAttribute_Locked) == 0;
while ((GetInteger(cur_address) + cur_size - 1) < mapped_last) {
/* Check that we have a next block. */
MESOSPHERE_ABORT_UNLESS(next_it != m_memory_block_manager.end());
/* Get the next info. */
const KMemoryInfo next_info = next_it->GetMemoryInfo();
/* Check if we can consolidate the next block's permission set with the current one. */
const bool next_perm_eq = next_info.GetPermission() == next_info.GetOriginalPermission();
const bool next_needs_set_perm = !next_perm_eq && next_info.GetIpcLockCount() == 1;
if (cur_perm_eq == next_perm_eq && cur_needs_set_perm == next_needs_set_perm && cur_info.GetOriginalPermission() == next_info.GetOriginalPermission()) {
/* We can consolidate the reprotection for the current and next block into a single call. */
cur_size += next_info.GetSize();
} else {
/* We have to operate on the current block. */
if ((cur_needs_set_perm || first) && !cur_perm_eq) {
const KPageProperties properties = { cur_info.GetPermission(), false, false, first ? DisableMergeAttribute_EnableAndMergeHeadBodyTail : DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), cur_address, cur_size / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, true));
}
/* Advance. */
cur_address = next_info.GetAddress();
cur_size = next_info.GetSize();
first = false;
}
/* Advance. */
cur_info = next_info;
cur_perm_eq = next_perm_eq;
cur_needs_set_perm = next_needs_set_perm;
++next_it;
}
/* Process the last block. */
if ((first || cur_needs_set_perm) && !cur_perm_eq) {
const KPageProperties properties = { cur_info.GetPermission(), false, false, first ? DisableMergeAttribute_EnableAndMergeHeadBodyTail : DisableMergeAttribute_None };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), cur_address, cur_size / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, true));
}
}
};
/* Iterate, reprotecting as needed. */
{
/* Get current and next iterators. */
KMemoryBlockManager::const_iterator start_it = m_memory_block_manager.FindIterator(mapping_start);
KMemoryBlockManager::const_iterator next_it = start_it;
++next_it;
/* Validate the current block. */
KMemoryInfo cur_info = start_it->GetMemoryInfo();
MESOSPHERE_R_ABORT_UNLESS(this->CheckMemoryState(cur_info, test_state, test_state, KMemoryPermission_None, KMemoryPermission_None, test_attr_mask | KMemoryAttribute_IpcLocked, KMemoryAttribute_IpcLocked));
/* Create tracking variables. */
KProcessAddress cur_address = cur_info.GetAddress();
size_t cur_size = cur_info.GetSize();
bool cur_perm_eq = cur_info.GetPermission() == cur_info.GetOriginalPermission();
bool cur_needs_set_perm = !cur_perm_eq && cur_info.GetIpcLockCount() == 1;
bool first = cur_info.GetIpcDisableMergeCount() == 1 && (cur_info.GetDisableMergeAttribute() & KMemoryBlockDisableMergeAttribute_Locked) == 0;
while ((cur_address + cur_size - 1) < mapping_last) {
/* Check that we have a next block. */
MESOSPHERE_ABORT_UNLESS(next_it != m_memory_block_manager.end());
/* Get the next info. */
const KMemoryInfo next_info = next_it->GetMemoryInfo();
/* Validate the next block. */
MESOSPHERE_R_ABORT_UNLESS(this->CheckMemoryState(next_info, test_state, test_state, KMemoryPermission_None, KMemoryPermission_None, test_attr_mask | KMemoryAttribute_IpcLocked, KMemoryAttribute_IpcLocked));
/* Check if we can consolidate the next block's permission set with the current one. */
const bool next_perm_eq = next_info.GetPermission() == next_info.GetOriginalPermission();
const bool next_needs_set_perm = !next_perm_eq && next_info.GetIpcLockCount() == 1;
if (cur_perm_eq == next_perm_eq && cur_needs_set_perm == next_needs_set_perm && cur_info.GetOriginalPermission() == next_info.GetOriginalPermission()) {
/* We can consolidate the reprotection for the current and next block into a single call. */
cur_size += next_info.GetSize();
} else {
/* We have to operate on the current block. */
if ((cur_needs_set_perm || first) && !cur_perm_eq) {
const KPageProperties properties = { cur_needs_set_perm ? cur_info.GetOriginalPermission() : cur_info.GetPermission(), false, false, first ? DisableMergeAttribute_EnableHeadAndBody : DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), cur_address, cur_size / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
}
/* Mark that we mapped the block. */
mapped_size += cur_size;
/* Advance. */
cur_address = next_info.GetAddress();
cur_size = next_info.GetSize();
first = false;
}
/* Advance. */
cur_info = next_info;
cur_perm_eq = next_perm_eq;
cur_needs_set_perm = next_needs_set_perm;
++next_it;
}
/* Process the last block. */
const auto lock_count = cur_info.GetIpcLockCount() + (next_it != m_memory_block_manager.end() ? (next_it->GetIpcDisableMergeCount() - next_it->GetIpcLockCount()) : 0);
if ((first || cur_needs_set_perm || (lock_count == 1)) && !cur_perm_eq) {
const DisableMergeAttribute head_body_attr = first ? DisableMergeAttribute_EnableHeadAndBody : DisableMergeAttribute_None;
const DisableMergeAttribute tail_attr = lock_count == 1 ? DisableMergeAttribute_EnableTail : DisableMergeAttribute_None;
const KPageProperties properties = { cur_needs_set_perm ? cur_info.GetOriginalPermission() : cur_info.GetPermission(), false, false, static_cast<DisableMergeAttribute>(head_body_attr | tail_attr) };
R_TRY(this->Operate(updater.GetPageList(), cur_address, cur_size / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, false));
}
}
/* Create an update allocator. */
/* NOTE: Guaranteed zero blocks needed here. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, 0);
R_TRY(allocator_result);
/* Unlock the pages. */
m_memory_block_manager.UpdateLock(std::addressof(allocator), mapping_start, mapping_size / PageSize, &KMemoryBlock::UnlockForIpc, KMemoryPermission_None);
R_SUCCEED();
}
void KPageTableBase::CleanupForIpcClientOnServerSetupFailure(PageLinkedList *page_list, KProcessAddress address, size_t size, KMemoryPermission prot_perm) {
MESOSPHERE_ASSERT(this->IsLockedByCurrentThread());
MESOSPHERE_ASSERT(util::IsAligned(GetInteger(address), PageSize));
MESOSPHERE_ASSERT(util::IsAligned(size, PageSize));
/* Get the mapped extents. */
const KProcessAddress src_map_start = address;
const KProcessAddress src_map_end = address + size;
const KProcessAddress src_map_last = src_map_end - 1;
/* This function is only invoked when there's something to do. */
MESOSPHERE_ASSERT(src_map_end > src_map_start);
/* Iterate over blocks, fixing permissions. */
KMemoryBlockManager::const_iterator it = m_memory_block_manager.FindIterator(address);
while (true) {
const KMemoryInfo info = it->GetMemoryInfo();
const auto cur_start = info.GetAddress() >= GetInteger(src_map_start) ? info.GetAddress() : GetInteger(src_map_start);
const auto cur_end = src_map_last <= info.GetLastAddress() ? src_map_end : info.GetEndAddress();
/* If we can, fix the protections on the block. */
if ((info.GetIpcLockCount() == 0 && (info.GetPermission() & KMemoryPermission_IpcLockChangeMask) != prot_perm) ||
(info.GetIpcLockCount() != 0 && (info.GetOriginalPermission() & KMemoryPermission_IpcLockChangeMask) != prot_perm))
{
/* Check if we actually need to fix the protections on the block. */
if (cur_end == src_map_end || info.GetAddress() <= GetInteger(src_map_start) || (info.GetPermission() & KMemoryPermission_IpcLockChangeMask) != prot_perm) {
const bool start_nc = (info.GetAddress() == GetInteger(src_map_start)) ? ((info.GetDisableMergeAttribute() & (KMemoryBlockDisableMergeAttribute_Locked | KMemoryBlockDisableMergeAttribute_IpcLeft)) == 0) : info.GetAddress() <= GetInteger(src_map_start);
const DisableMergeAttribute head_body_attr = start_nc ? DisableMergeAttribute_EnableHeadAndBody : DisableMergeAttribute_None;
DisableMergeAttribute tail_attr;
if (cur_end == src_map_end && info.GetEndAddress() == src_map_end) {
auto next_it = it;
++next_it;
const auto lock_count = info.GetIpcLockCount() + (next_it != m_memory_block_manager.end() ? (next_it->GetIpcDisableMergeCount() - next_it->GetIpcLockCount()) : 0);
tail_attr = lock_count == 0 ? DisableMergeAttribute_EnableTail : DisableMergeAttribute_None;
} else {
tail_attr = DisableMergeAttribute_None;
}
const KPageProperties properties = { info.GetPermission(), false, false, static_cast<DisableMergeAttribute>(head_body_attr | tail_attr) };
MESOSPHERE_R_ABORT_UNLESS(this->Operate(page_list, cur_start, (cur_end - cur_start) / PageSize, Null<KPhysicalAddress>, false, properties, OperationType_ChangePermissions, true));
}
}
/* If we're past the end of the region, we're done. */
if (src_map_last <= info.GetLastAddress()) {
break;
}
/* Advance. */
++it;
MESOSPHERE_ABORT_UNLESS(it != m_memory_block_manager.end());
}
}
#pragma GCC pop_options
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Result KPageTableBase::MapPhysicalMemory(KProcessAddress address, size_t size) {
/* Lock the physical memory lock. */
KScopedLightLock phys_lk(m_map_physical_memory_lock);
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/* Calculate the last address for convenience. */
const KProcessAddress last_address = address + size - 1;
/* Define iteration variables. */
KProcessAddress cur_address;
size_t mapped_size;
/* The entire mapping process can be retried. */
while (true) {
/* Check if the memory is already mapped. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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/* Iterate over the memory. */
cur_address = address;
mapped_size = 0;
auto it = m_memory_block_manager.FindIterator(cur_address);
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while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
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/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
if (info.GetState() != KMemoryState_Free) {
mapped_size += (last_address + 1 - cur_address);
}
break;
}
/* Track the memory if it's mapped. */
if (info.GetState() != KMemoryState_Free) {
mapped_size += KProcessAddress(info.GetEndAddress()) - cur_address;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
/* If the size mapped is the size requested, we've nothing to do. */
R_SUCCEED_IF(size == mapped_size);
}
/* Allocate and map the memory. */
{
/* Reserve the memory from the process resource limit. */
KScopedResourceReservation memory_reservation(m_resource_limit, ams::svc::LimitableResource_PhysicalMemoryMax, size - mapped_size);
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R_UNLESS(memory_reservation.Succeeded(), svc::ResultLimitReached());
/* Allocate pages for the new memory. */
KPageGroup pg(m_block_info_manager);
R_TRY(Kernel::GetMemoryManager().AllocateForProcess(std::addressof(pg), (size - mapped_size) / PageSize, m_allocate_option, GetCurrentProcess().GetId(), m_heap_fill_value));
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/* If we fail in the next bit (or retry), we need to cleanup the pages. */
auto pg_guard = SCOPE_GUARD {
pg.OpenFirst();
pg.Close();
};
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/* Map the memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
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size_t num_allocator_blocks = 0;
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/* Verify that nobody has mapped memory since we first checked. */
{
/* Iterate over the memory. */
size_t checked_mapped_size = 0;
cur_address = address;
auto it = m_memory_block_manager.FindIterator(cur_address);
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while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
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/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
const bool is_free = info.GetState() == KMemoryState_Free;
if (is_free) {
if (info.GetAddress() < GetInteger(address)) {
++num_allocator_blocks;
}
if (last_address < info.GetLastAddress()) {
++num_allocator_blocks;
}
}
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/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
if (!is_free) {
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checked_mapped_size += (last_address + 1 - cur_address);
}
break;
}
/* Track the memory if it's mapped. */
if (!is_free) {
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checked_mapped_size += KProcessAddress(info.GetEndAddress()) - cur_address;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
/* If the size now isn't what it was before, somebody mapped or unmapped concurrently. */
/* If this happened, retry. */
if (mapped_size != checked_mapped_size) {
continue;
}
}
/* Create an update allocator. */
MESOSPHERE_ASSERT(num_allocator_blocks <= KMemoryBlockManagerUpdateAllocator::MaxBlocks);
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
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/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Prepare to iterate over the memory. */
auto pg_it = pg.begin();
KPhysicalAddress pg_phys_addr = pg_it->GetAddress();
size_t pg_pages = pg_it->GetNumPages();
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/* Reset the current tracking address, and make sure we clean up on failure. */
pg_guard.Cancel();
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cur_address = address;
ON_RESULT_FAILURE {
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if (cur_address > address) {
const KProcessAddress last_unmap_address = cur_address - 1;
/* Iterate, unmapping the pages. */
cur_address = address;
auto it = m_memory_block_manager.FindIterator(cur_address);
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while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
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/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* If the memory state is free, we mapped it and need to unmap it. */
if (info.GetState() == KMemoryState_Free) {
/* Determine the range to unmap. */
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
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const size_t cur_pages = std::min(KProcessAddress(info.GetEndAddress()) - cur_address, last_unmap_address + 1 - cur_address) / PageSize;
/* Unmap. */
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), cur_address, cur_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, true));
}
/* Check if we're done. */
if (last_unmap_address <= info.GetLastAddress()) {
break;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
}
/* Release any remaining unmapped memory. */
Kernel::GetMemoryManager().OpenFirst(pg_phys_addr, pg_pages);
Kernel::GetMemoryManager().Close(pg_phys_addr, pg_pages);
for (++pg_it; pg_it != pg.end(); ++pg_it) {
Kernel::GetMemoryManager().OpenFirst(pg_it->GetAddress(), pg_it->GetNumPages());
Kernel::GetMemoryManager().Close(pg_it->GetAddress(), pg_it->GetNumPages());
}
};
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auto it = m_memory_block_manager.FindIterator(cur_address);
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while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
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/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* If it's unmapped, we need to map it. */
if (info.GetState() == KMemoryState_Free) {
/* Determine the range to map. */
const KPageProperties map_properties = { KMemoryPermission_UserReadWrite, false, false, cur_address == this->GetAliasRegionStart() ? DisableMergeAttribute_DisableHead : DisableMergeAttribute_None };
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size_t map_pages = std::min(KProcessAddress(info.GetEndAddress()) - cur_address, last_address + 1 - cur_address) / PageSize;
/* While we have pages to map, map them. */
{
/* Create a page group for the current mapping range. */
KPageGroup cur_pg(m_block_info_manager);
{
ON_RESULT_FAILURE {
cur_pg.OpenFirst();
cur_pg.Close();
};
size_t remain_pages = map_pages;
while (remain_pages > 0) {
/* Check if we're at the end of the physical block. */
if (pg_pages == 0) {
/* Ensure there are more pages to map. */
MESOSPHERE_ASSERT(pg_it != pg.end());
/* Advance our physical block. */
++pg_it;
pg_phys_addr = pg_it->GetAddress();
pg_pages = pg_it->GetNumPages();
}
/* Add whatever we can to the current block. */
const size_t cur_pages = std::min(pg_pages, remain_pages);
R_TRY(cur_pg.AddBlock(pg_phys_addr + ((pg_pages - cur_pages) * PageSize), cur_pages));
/* Advance. */
remain_pages -= cur_pages;
pg_pages -= cur_pages;
}
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}
/* Map the pages. */
R_TRY(this->Operate(updater.GetPageList(), cur_address, map_pages, cur_pg, map_properties, OperationType_MapFirstGroup, false));
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}
}
/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
break;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
/* We succeeded, so commit the memory reservation. */
memory_reservation.Commit();
/* Increase our tracked mapped size. */
m_mapped_physical_memory_size += (size - mapped_size);
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/* Update the relevant memory blocks. */
m_memory_block_manager.UpdateIfMatch(std::addressof(allocator), address, size / PageSize,
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KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None,
KMemoryState_Normal, KMemoryPermission_UserReadWrite, KMemoryAttribute_None,
address == this->GetAliasRegionStart() ? KMemoryBlockDisableMergeAttribute_Normal : KMemoryBlockDisableMergeAttribute_None,
KMemoryBlockDisableMergeAttribute_None);
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R_SUCCEED();
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}
}
}
}
Result KPageTableBase::UnmapPhysicalMemory(KProcessAddress address, size_t size) {
/* Lock the physical memory lock. */
KScopedLightLock phys_lk(m_map_physical_memory_lock);
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Calculate the last address for convenience. */
const KProcessAddress last_address = address + size - 1;
/* Define iteration variables. */
KProcessAddress map_start_address = Null<KProcessAddress>;
KProcessAddress map_last_address = Null<KProcessAddress>;
KProcessAddress cur_address;
size_t mapped_size;
size_t num_allocator_blocks = 0;
/* Check if the memory is mapped. */
{
/* Iterate over the memory. */
cur_address = address;
mapped_size = 0;
auto it = m_memory_block_manager.FindIterator(cur_address);
while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* Verify the memory's state. */
const bool is_normal = info.GetState() == KMemoryState_Normal && info.GetAttribute() == 0;
const bool is_free = info.GetState() == KMemoryState_Free;
R_UNLESS(is_normal || is_free, svc::ResultInvalidCurrentMemory());
if (is_normal) {
R_UNLESS(info.GetAttribute() == KMemoryAttribute_None, svc::ResultInvalidCurrentMemory());
if (map_start_address == Null<KProcessAddress>) {
map_start_address = cur_address;
}
map_last_address = (last_address >= info.GetLastAddress()) ? info.GetLastAddress() : last_address;
if (info.GetAddress() < GetInteger(address)) {
++num_allocator_blocks;
}
if (last_address < info.GetLastAddress()) {
++num_allocator_blocks;
}
mapped_size += (map_last_address + 1 - cur_address);
}
/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
break;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
/* If there's nothing mapped, we've nothing to do. */
R_SUCCEED_IF(mapped_size == 0);
}
/* Create an update allocator. */
MESOSPHERE_ASSERT(num_allocator_blocks <= KMemoryBlockManagerUpdateAllocator::MaxBlocks);
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Separate the mapping. */
const KPageProperties sep_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), map_start_address, (map_last_address + 1 - map_start_address) / PageSize, Null<KPhysicalAddress>, false, sep_properties, OperationType_Separate, false));
/* Reset the current tracking address, and make sure we clean up on failure. */
cur_address = address;
/* Iterate over the memory, unmapping as we go. */
auto it = m_memory_block_manager.FindIterator(cur_address);
const auto clear_merge_attr = (it->GetState() == KMemoryState_Normal && it->GetAddress() == this->GetAliasRegionStart() && it->GetAddress() == address) ? KMemoryBlockDisableMergeAttribute_Normal : KMemoryBlockDisableMergeAttribute_None;
while (true) {
/* Check that the iterator is valid. */
MESOSPHERE_ASSERT(it != m_memory_block_manager.end());
/* Get the memory info. */
const KMemoryInfo info = it->GetMemoryInfo();
/* If the memory state is normal, we need to unmap it. */
if (info.GetState() == KMemoryState_Normal) {
/* Determine the range to unmap. */
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
const size_t cur_pages = std::min(KProcessAddress(info.GetEndAddress()) - cur_address, last_address + 1 - cur_address) / PageSize;
/* Unmap. */
MESOSPHERE_R_ABORT_UNLESS(this->Operate(updater.GetPageList(), cur_address, cur_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
}
/* Check if we're done. */
if (last_address <= info.GetLastAddress()) {
break;
}
/* Advance. */
cur_address = info.GetEndAddress();
++it;
}
/* Release the memory resource. */
m_mapped_physical_memory_size -= mapped_size;
m_resource_limit->Release(ams::svc::LimitableResource_PhysicalMemoryMax, mapped_size);
/* Update memory blocks. */
m_memory_block_manager.Update(std::addressof(allocator), address, size / PageSize, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, clear_merge_attr);
/* We succeeded. */
R_SUCCEED();
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}
Result KPageTableBase::MapPhysicalMemoryUnsafe(KProcessAddress address, size_t size) {
/* Try to reserve the unsafe memory. */
R_UNLESS(Kernel::GetUnsafeMemory().TryReserve(size), svc::ResultLimitReached());
/* Ensure we release our reservation on failure. */
ON_RESULT_FAILURE { Kernel::GetUnsafeMemory().Release(size); };
/* Create a page group for the new memory. */
KPageGroup pg(m_block_info_manager);
/* Allocate the new memory. */
const size_t num_pages = size / PageSize;
R_TRY(Kernel::GetMemoryManager().AllocateAndOpen(std::addressof(pg), num_pages, 1, KMemoryManager::EncodeOption(KMemoryManager::Pool_Unsafe, KMemoryManager::Direction_FromFront)));
/* Close the page group when we're done with it. */
ON_SCOPE_EXIT { pg.Close(); };
/* Clear the new memory. */
for (const auto &block : pg) {
std::memset(GetVoidPointer(GetHeapVirtualAddress(block.GetAddress())), m_heap_fill_value, block.GetSize());
}
/* Map the new memory. */
{
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, KMemoryState_Free, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_None, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Map the pages. */
const KPageProperties map_properties = { KMemoryPermission_UserReadWrite, false, false, DisableMergeAttribute_DisableHead };
R_TRY(this->Operate(updater.GetPageList(), address, num_pages, pg, map_properties, OperationType_MapGroup, false));
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Normal, KMemoryPermission_UserReadWrite, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_Normal, KMemoryBlockDisableMergeAttribute_None);
/* Update our mapped unsafe size. */
m_mapped_unsafe_physical_memory += size;
/* We succeeded. */
R_SUCCEED();
}
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}
Result KPageTableBase::UnmapPhysicalMemoryUnsafe(KProcessAddress address, size_t size) {
/* Lock the table. */
KScopedLightLock lk(m_general_lock);
/* Check whether we can unmap this much unsafe physical memory. */
R_UNLESS(size <= m_mapped_unsafe_physical_memory, svc::ResultInvalidCurrentMemory());
/* Check the memory state. */
size_t num_allocator_blocks;
R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size, KMemoryState_All, KMemoryState_Normal, KMemoryPermission_All, KMemoryPermission_UserReadWrite, KMemoryAttribute_All, KMemoryAttribute_None));
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the memory. */
const size_t num_pages = size / PageSize;
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), address, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
/* Release the unsafe memory from the limit. */
Kernel::GetUnsafeMemory().Release(size);
/* Update our mapped unsafe size. */
m_mapped_unsafe_physical_memory -= size;
R_SUCCEED();
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}
Result KPageTableBase::UnmapProcessMemory(KProcessAddress dst_address, size_t size, KPageTableBase &src_page_table, KProcessAddress src_address) {
/* We need to lock both this table, and the current process's table, so set up an alias. */
KPageTableBase &dst_page_table = *this;
/* Acquire the table locks. */
KScopedLightLockPair lk(src_page_table.m_general_lock, dst_page_table.m_general_lock);
/* Check that the memory is mapped in the destination process. */
size_t num_allocator_blocks;
R_TRY(dst_page_table.CheckMemoryState(std::addressof(num_allocator_blocks), dst_address, size, KMemoryState_All, KMemoryState_SharedCode, KMemoryPermission_UserReadWrite, KMemoryPermission_UserReadWrite, KMemoryAttribute_All, KMemoryAttribute_None));
/* Check that the memory is mapped in the source process. */
R_TRY(src_page_table.CheckMemoryState(src_address, size, KMemoryState_FlagCanMapProcess, KMemoryState_FlagCanMapProcess, KMemoryPermission_None, KMemoryPermission_None, KMemoryAttribute_All, KMemoryAttribute_None));
/* Validate that the memory ranges are compatible. */
{
/* Define a helper type. */
struct ContiguousRangeInfo {
public:
KPageTableBase &m_pt;
TraversalContext m_context;
TraversalEntry m_entry;
KPhysicalAddress m_phys_addr;
size_t m_cur_size;
size_t m_remaining_size;
public:
ContiguousRangeInfo(KPageTableBase &pt, KProcessAddress address, size_t size) : m_pt(pt), m_remaining_size(size) {
/* Begin a traversal. */
MESOSPHERE_ABORT_UNLESS(m_pt.GetImpl().BeginTraversal(std::addressof(m_entry), std::addressof(m_context), address));
/* Setup tracking fields. */
m_phys_addr = m_entry.phys_addr;
m_cur_size = std::min<size_t>(m_remaining_size, m_entry.block_size - (GetInteger(m_phys_addr) & (m_entry.block_size - 1)));
/* Consume the whole contiguous block. */
this->DetermineContiguousBlockExtents();
}
void ContinueTraversal() {
/* Update our remaining size. */
m_remaining_size = m_remaining_size - m_cur_size;
/* Update our tracking fields. */
if (m_remaining_size > 0) {
m_phys_addr = m_entry.phys_addr;
m_cur_size = std::min<size_t>(m_remaining_size, m_entry.block_size);
/* Consume the whole contiguous block. */
this->DetermineContiguousBlockExtents();
}
}
private:
void DetermineContiguousBlockExtents() {
/* Continue traversing until we're not contiguous, or we have enough. */
while (m_cur_size < m_remaining_size) {
MESOSPHERE_ABORT_UNLESS(m_pt.GetImpl().ContinueTraversal(std::addressof(m_entry), std::addressof(m_context)));
/* If we're not contiguous, we're done. */
if (m_entry.phys_addr != m_phys_addr + m_cur_size) {
break;
}
/* Update our current size. */
m_cur_size = std::min(m_remaining_size, m_cur_size + m_entry.block_size);
}
}
};
/* Create ranges for both tables. */
ContiguousRangeInfo src_range(src_page_table, src_address, size);
ContiguousRangeInfo dst_range(dst_page_table, dst_address, size);
/* Validate the ranges. */
while (src_range.m_remaining_size > 0 && dst_range.m_remaining_size > 0) {
R_UNLESS(src_range.m_phys_addr == dst_range.m_phys_addr, svc::ResultInvalidMemoryRegion());
R_UNLESS(src_range.m_cur_size == dst_range.m_cur_size, svc::ResultInvalidMemoryRegion());
src_range.ContinueTraversal();
dst_range.ContinueTraversal();
}
}
/* We no longer need to hold our lock on the source page table. */
lk.TryUnlockHalf(src_page_table.m_general_lock);
/* Create an update allocator. */
Result allocator_result;
KMemoryBlockManagerUpdateAllocator allocator(std::addressof(allocator_result), m_memory_block_slab_manager, num_allocator_blocks);
R_TRY(allocator_result);
/* We're going to perform an update, so create a helper. */
KScopedPageTableUpdater updater(this);
/* Unmap the memory. */
const size_t num_pages = size / PageSize;
const KPageProperties unmap_properties = { KMemoryPermission_None, false, false, DisableMergeAttribute_None };
R_TRY(this->Operate(updater.GetPageList(), dst_address, num_pages, Null<KPhysicalAddress>, false, unmap_properties, OperationType_Unmap, false));
/* Apply the memory block update. */
m_memory_block_manager.Update(std::addressof(allocator), dst_address, num_pages, KMemoryState_Free, KMemoryPermission_None, KMemoryAttribute_None, KMemoryBlockDisableMergeAttribute_None, KMemoryBlockDisableMergeAttribute_Normal);
R_SUCCEED();
}
}