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ladybird/Kernel/VM/MemoryManager.h
Andreas Kling 082ed6f417 Kernel: Simplify VMObject locking & page fault handlers 
This patch greatly simplifies VMObject locking by doing two things:

1. Giving VMObject an IntrusiveList of all its mapping Region objects.
2. Removing VMObject::m_paging_lock in favor of VMObject::m_lock

Before (1), VMObject::for_each_region() was forced to acquire the
global MM lock (since it worked by walking MemoryManager's list of
all regions and checking for regions that pointed to itself.)

With each VMObject having its own list of Regions, VMObject's own
m_lock is all we need.

Before (2), page fault handlers used a separate mutex for preventing
overlapping work. This design required multiple temporary unlocks
and was generally extremely hard to reason about.

Instead, page fault handlers now use VMObject's own m_lock as well.
2021-07-23 03:24:44 +02:00

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/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/Concepts.h>
#include <AK/HashTable.h>
#include <AK/NonnullOwnPtrVector.h>
#include <AK/NonnullRefPtrVector.h>
#include <AK/String.h>
#include <Kernel/Arch/x86/PageFault.h>
#include <Kernel/Arch/x86/TrapFrame.h>
#include <Kernel/Forward.h>
#include <Kernel/SpinLock.h>
#include <Kernel/VM/AllocationStrategy.h>
#include <Kernel/VM/PhysicalPage.h>
#include <Kernel/VM/PhysicalRegion.h>
#include <Kernel/VM/Region.h>
#include <Kernel/VM/VMObject.h>
namespace Kernel {
constexpr bool page_round_up_would_wrap(FlatPtr x)
{
return x > (explode_byte(0xFF) & ~0xFFF);
}
constexpr FlatPtr page_round_up(FlatPtr x)
{
FlatPtr rounded = (((FlatPtr)(x)) + PAGE_SIZE - 1) & (~(PAGE_SIZE - 1));
// Rounding up >0xfffff000 wraps back to 0. That's never what we want.
VERIFY(x == 0 || rounded != 0);
return rounded;
}
constexpr FlatPtr page_round_down(FlatPtr x)
{
return ((FlatPtr)(x)) & ~(PAGE_SIZE - 1);
}
inline FlatPtr low_physical_to_virtual(FlatPtr physical)
{
return physical + kernel_base;
}
inline FlatPtr virtual_to_low_physical(FlatPtr virtual_)
{
return virtual_ - kernel_base;
}
enum class UsedMemoryRangeType {
LowMemory = 0,
Prekernel,
Kernel,
BootModule,
PhysicalPages,
};
static constexpr StringView UserMemoryRangeTypeNames[] {
"Low memory",
"Prekernel",
"Kernel",
"Boot module",
"Physical Pages"
};
struct UsedMemoryRange {
UsedMemoryRangeType type {};
PhysicalAddress start;
PhysicalAddress end;
};
struct ContiguousReservedMemoryRange {
PhysicalAddress start;
PhysicalSize length {};
};
enum class PhysicalMemoryRangeType {
Usable = 0,
Reserved,
ACPI_Reclaimable,
ACPI_NVS,
BadMemory,
Unknown,
};
struct PhysicalMemoryRange {
PhysicalMemoryRangeType type { PhysicalMemoryRangeType::Unknown };
PhysicalAddress start;
PhysicalSize length {};
};
#define MM Kernel::MemoryManager::the()
struct MemoryManagerData {
SpinLock<u8> m_quickmap_in_use;
u32 m_quickmap_prev_flags;
PhysicalAddress m_last_quickmap_pd;
PhysicalAddress m_last_quickmap_pt;
};
extern RecursiveSpinLock s_mm_lock;
class MemoryManager {
AK_MAKE_ETERNAL
friend class PageDirectory;
friend class AnonymousVMObject;
friend class Region;
friend class VMObject;
public:
static MemoryManager& the();
static bool is_initialized();
static void initialize(u32 cpu);
static inline MemoryManagerData& get_data()
{
return Processor::current().get_mm_data();
}
PageFaultResponse handle_page_fault(PageFault const&);
void set_page_writable_direct(VirtualAddress, bool);
void protect_readonly_after_init_memory();
void unmap_text_after_init();
void unmap_ksyms_after_init();
static void enter_process_paging_scope(Process&);
static void enter_space(Space&);
bool validate_user_stack_no_lock(Space&, VirtualAddress) const;
bool validate_user_stack(Space&, VirtualAddress) const;
enum class ShouldZeroFill {
No,
Yes
};
bool commit_user_physical_pages(size_t);
void uncommit_user_physical_pages(size_t);
NonnullRefPtr<PhysicalPage> allocate_committed_user_physical_page(ShouldZeroFill = ShouldZeroFill::Yes);
RefPtr<PhysicalPage> allocate_user_physical_page(ShouldZeroFill = ShouldZeroFill::Yes, bool* did_purge = nullptr);
RefPtr<PhysicalPage> allocate_supervisor_physical_page();
NonnullRefPtrVector<PhysicalPage> allocate_contiguous_supervisor_physical_pages(size_t size);
void deallocate_physical_page(PhysicalAddress);
OwnPtr<Region> allocate_contiguous_kernel_region(size_t, StringView name, Region::Access access, Region::Cacheable = Region::Cacheable::Yes);
OwnPtr<Region> allocate_kernel_region(size_t, StringView name, Region::Access access, AllocationStrategy strategy = AllocationStrategy::Reserve, Region::Cacheable = Region::Cacheable::Yes);
OwnPtr<Region> allocate_kernel_region(PhysicalAddress, size_t, StringView name, Region::Access access, Region::Cacheable = Region::Cacheable::Yes);
OwnPtr<Region> allocate_kernel_region_identity(PhysicalAddress, size_t, StringView name, Region::Access access, Region::Cacheable = Region::Cacheable::Yes);
OwnPtr<Region> allocate_kernel_region_with_vmobject(VMObject&, size_t, StringView name, Region::Access access, Region::Cacheable = Region::Cacheable::Yes);
OwnPtr<Region> allocate_kernel_region_with_vmobject(Range const&, VMObject&, StringView name, Region::Access access, Region::Cacheable = Region::Cacheable::Yes);
struct SystemMemoryInfo {
PhysicalSize user_physical_pages { 0 };
PhysicalSize user_physical_pages_used { 0 };
PhysicalSize user_physical_pages_committed { 0 };
PhysicalSize user_physical_pages_uncommitted { 0 };
PhysicalSize super_physical_pages { 0 };
PhysicalSize super_physical_pages_used { 0 };
};
SystemMemoryInfo get_system_memory_info()
{
ScopedSpinLock lock(s_mm_lock);
return m_system_memory_info;
}
template<IteratorFunction<VMObject&> Callback>
static void for_each_vmobject(Callback callback)
{
ScopedSpinLock locker(s_mm_lock);
for (auto& vmobject : MM.m_vmobjects) {
if (callback(vmobject) == IterationDecision::Break)
break;
}
}
template<VoidFunction<VMObject&> Callback>
static void for_each_vmobject(Callback callback)
{
for (auto& vmobject : MM.m_vmobjects)
callback(vmobject);
}
static Region* find_user_region_from_vaddr(Space&, VirtualAddress);
static Region* find_user_region_from_vaddr_no_lock(Space&, VirtualAddress);
static void validate_syscall_preconditions(Space&, RegisterState const&);
void dump_kernel_regions();
PhysicalPage& shared_zero_page() { return *m_shared_zero_page; }
PhysicalPage& lazy_committed_page() { return *m_lazy_committed_page; }
PageDirectory& kernel_page_directory() { return *m_kernel_page_directory; }
Vector<UsedMemoryRange> const& used_memory_ranges() { return m_used_memory_ranges; }
bool is_allowed_to_mmap_to_userspace(PhysicalAddress, Range const&) const;
PhysicalPageEntry& get_physical_page_entry(PhysicalAddress);
PhysicalAddress get_physical_address(PhysicalPage const&);
private:
MemoryManager();
~MemoryManager();
void initialize_physical_pages();
void register_reserved_ranges();
void register_vmobject(VMObject&);
void unregister_vmobject(VMObject&);
void register_region(Region&);
void unregister_region(Region&);
void protect_kernel_image();
void parse_memory_map();
static void flush_tlb_local(VirtualAddress, size_t page_count = 1);
static void flush_tlb(PageDirectory const*, VirtualAddress, size_t page_count = 1);
static Region* kernel_region_from_vaddr(VirtualAddress);
static Region* find_region_from_vaddr(VirtualAddress);
RefPtr<PhysicalPage> find_free_user_physical_page(bool);
ALWAYS_INLINE u8* quickmap_page(PhysicalPage& page)
{
return quickmap_page(page.paddr());
}
u8* quickmap_page(PhysicalAddress const&);
void unquickmap_page();
PageDirectoryEntry* quickmap_pd(PageDirectory&, size_t pdpt_index);
PageTableEntry* quickmap_pt(PhysicalAddress);
PageTableEntry* pte(PageDirectory&, VirtualAddress);
PageTableEntry* ensure_pte(PageDirectory&, VirtualAddress);
void release_pte(PageDirectory&, VirtualAddress, bool);
RefPtr<PageDirectory> m_kernel_page_directory;
RefPtr<PhysicalPage> m_shared_zero_page;
RefPtr<PhysicalPage> m_lazy_committed_page;
SystemMemoryInfo m_system_memory_info;
NonnullOwnPtrVector<PhysicalRegion> m_user_physical_regions;
NonnullOwnPtrVector<PhysicalRegion> m_super_physical_regions;
OwnPtr<PhysicalRegion> m_physical_pages_region;
PhysicalPageEntry* m_physical_page_entries { nullptr };
size_t m_physical_page_entries_count { 0 };
Region::ListInMemoryManager m_user_regions;
Region::ListInMemoryManager m_kernel_regions;
Vector<UsedMemoryRange> m_used_memory_ranges;
Vector<PhysicalMemoryRange> m_physical_memory_ranges;
Vector<ContiguousReservedMemoryRange> m_reserved_memory_ranges;
VMObject::List m_vmobjects;
};
inline bool is_user_address(VirtualAddress vaddr)
{
return vaddr.get() < USER_RANGE_CEILING;
}
inline bool is_user_range(VirtualAddress vaddr, size_t size)
{
if (vaddr.offset(size) < vaddr)
return false;
return is_user_address(vaddr) && is_user_address(vaddr.offset(size));
}
inline bool is_user_range(Range const& range)
{
return is_user_range(range.base(), range.size());
}
inline bool PhysicalPage::is_shared_zero_page() const
{
return this == &MM.shared_zero_page();
}
inline bool PhysicalPage::is_lazy_committed_page() const
{
return this == &MM.lazy_committed_page();
}
}
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