Kernel: MMU::get() is now MMU::kernel

MMU is can now be locked with RecursiveSpinLock.

Scheduler now has get_current_tid() that works before the Scheduler
is initialized. This allows RecursiveSpinLock usage early on.
This commit is contained in:
Bananymous 2023-05-28 16:18:18 +03:00
parent a2ee543fa1
commit 869de7283f
11 changed files with 100 additions and 63 deletions

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@ -1,38 +1,41 @@
#include <BAN/Errors.h> #include <BAN/Errors.h>
#include <kernel/Arch.h>
#include <kernel/LockGuard.h>
#include <kernel/Memory/kmalloc.h> #include <kernel/Memory/kmalloc.h>
#include <kernel/Memory/MMU.h> #include <kernel/Memory/MMU.h>
#define FLAGS_MASK (PAGE_SIZE - 1) #define FLAGS_MASK (PAGE_SIZE - 1)
#define PAGE_MASK (~FLAGS_MASK) #define PAGE_MASK (~FLAGS_MASK)
#define CLEANUP_STRUCTURE(s) \ #define CLEANUP_STRUCTURE(s) \
for (uint64_t i = 0; i < 512; i++) \ do { \
if (s[i] & Flags::Present) \ for (uint64_t i = 0; i < 512; i++) \
return; \ if ((s)[i] & Flags::Present) \
kfree(s) return; \
kfree(s); \
} while (false)
extern uint8_t g_kernel_end[]; extern uint8_t g_kernel_end[];
namespace Kernel namespace Kernel
{ {
static MMU* s_instance = nullptr; static MMU* s_kernel = nullptr;
static MMU* s_current = nullptr; static MMU* s_current = nullptr;
void MMU::initialize() void MMU::initialize()
{ {
ASSERT(s_instance == nullptr); ASSERT(s_kernel == nullptr);
s_instance = new MMU(); s_kernel = new MMU();
ASSERT(s_instance); ASSERT(s_kernel);
s_instance->initialize_kernel(); s_kernel->initialize_kernel();
s_instance->load(); s_kernel->load();
} }
MMU& MMU::get() MMU& MMU::kernel()
{ {
ASSERT(s_instance); ASSERT(s_kernel);
return *s_instance; return *s_kernel;
} }
MMU& MMU::current() MMU& MMU::current()
@ -61,13 +64,15 @@ namespace Kernel
MMU::MMU() MMU::MMU()
{ {
if (s_instance == nullptr) if (s_kernel == nullptr)
return; return;
// Here we copy the s_instances paging structs since they are // Here we copy the s_kernel paging structs since they are
// global for every process // global for every process
uint64_t* global_pml4 = s_instance->m_highest_paging_struct; LockGuard _(s_kernel->m_lock);
uint64_t* global_pml4 = s_kernel->m_highest_paging_struct;
uint64_t* pml4 = allocate_page_aligned_page(); uint64_t* pml4 = allocate_page_aligned_page();
for (uint32_t pml4e = 0; pml4e < 512; pml4e++) for (uint32_t pml4e = 0; pml4e < 512; pml4e++)
@ -136,6 +141,10 @@ namespace Kernel
void MMU::load() void MMU::load()
{ {
uintptr_t rsp;
read_rsp(rsp);
ASSERT(!is_page_free(rsp & PAGE_MASK));
asm volatile("movq %0, %%cr3" :: "r"(m_highest_paging_struct)); asm volatile("movq %0, %%cr3" :: "r"(m_highest_paging_struct));
s_current = this; s_current = this;
} }
@ -148,41 +157,39 @@ namespace Kernel
void MMU::identity_map_range(paddr_t address, size_t size, flags_t flags) void MMU::identity_map_range(paddr_t address, size_t size, flags_t flags)
{ {
paddr_t s_page = address & PAGE_MASK; LockGuard _(m_lock);
paddr_t e_page = (address + size - 1) & PAGE_MASK;
for (paddr_t page = s_page; page <= e_page; page += PAGE_SIZE) paddr_t s_page = address / PAGE_SIZE;
identity_map_page(page, flags); paddr_t e_page = (address + size - 1) / PAGE_SIZE;
for (paddr_t page = s_page; page <= e_page; page++)
identity_map_page(page * PAGE_SIZE, flags);
} }
void MMU::unmap_page(vaddr_t address) void MMU::unmap_page(vaddr_t address)
{ {
LockGuard _(m_lock);
ASSERT((address >> 48) == 0); ASSERT((address >> 48) == 0);
address &= PAGE_MASK; address &= PAGE_MASK;
if (is_page_free(address))
{
dwarnln("unmapping unmapped page {8H}", address);
return;
}
uint64_t pml4e = (address >> 39) & 0x1FF; uint64_t pml4e = (address >> 39) & 0x1FF;
uint64_t pdpte = (address >> 30) & 0x1FF; uint64_t pdpte = (address >> 30) & 0x1FF;
uint64_t pde = (address >> 21) & 0x1FF; uint64_t pde = (address >> 21) & 0x1FF;
uint64_t pte = (address >> 12) & 0x1FF; uint64_t pte = (address >> 12) & 0x1FF;
uint64_t* pml4 = m_highest_paging_struct; uint64_t* pml4 = m_highest_paging_struct;
if (!(pml4[pml4e] & Flags::Present))
return;
uint64_t* pdpt = (uint64_t*)(pml4[pml4e] & PAGE_MASK); uint64_t* pdpt = (uint64_t*)(pml4[pml4e] & PAGE_MASK);
if (!(pdpt[pdpte] & Flags::Present)) uint64_t* pd = (uint64_t*)(pdpt[pdpte] & PAGE_MASK);
return; uint64_t* pt = (uint64_t*)(pd[pde] & PAGE_MASK);
uint64_t* pd = (uint64_t*)(pdpt[pdpte] & PAGE_MASK);
if (!(pd[pde] & Flags::Present))
return;
uint64_t* pt = (uint64_t*)(pd[pde] & PAGE_MASK);
if (!(pt[pte] & Flags::Present))
return;
pt[pte] = 0; pt[pte] = 0;
CLEANUP_STRUCTURE(pt); CLEANUP_STRUCTURE(pt);
pd[pde] = 0; pd[pde] = 0;
CLEANUP_STRUCTURE(pd); CLEANUP_STRUCTURE(pd);
@ -193,14 +200,18 @@ namespace Kernel
void MMU::unmap_range(vaddr_t address, size_t size) void MMU::unmap_range(vaddr_t address, size_t size)
{ {
vaddr_t s_page = address & PAGE_MASK; LockGuard _(m_lock);
vaddr_t e_page = (address + size - 1) & PAGE_MASK;
for (vaddr_t page = s_page; page <= e_page; page += PAGE_SIZE) vaddr_t s_page = address / PAGE_SIZE;
unmap_page(page); vaddr_t e_page = (address + size - 1) / PAGE_SIZE;
for (vaddr_t page = s_page; page <= e_page; page++)
unmap_page(page * PAGE_SIZE);
} }
void MMU::map_page_at(paddr_t paddr, vaddr_t vaddr, flags_t flags) void MMU::map_page_at(paddr_t paddr, vaddr_t vaddr, flags_t flags)
{ {
LockGuard _(m_lock);
ASSERT((paddr >> 48) == 0); ASSERT((paddr >> 48) == 0);
ASSERT((vaddr >> 48) == 0); ASSERT((vaddr >> 48) == 0);
@ -245,6 +256,8 @@ namespace Kernel
uint64_t MMU::get_page_data(vaddr_t address) const uint64_t MMU::get_page_data(vaddr_t address) const
{ {
LockGuard _(m_lock);
ASSERT((address >> 48) == 0); ASSERT((address >> 48) == 0);
ASSERT(address % PAGE_SIZE == 0); ASSERT(address % PAGE_SIZE == 0);
@ -284,6 +297,8 @@ namespace Kernel
vaddr_t MMU::get_free_page() const vaddr_t MMU::get_free_page() const
{ {
LockGuard _(m_lock);
// Try to find free page that can be mapped without // Try to find free page that can be mapped without
// allocations (page table with unused entries) // allocations (page table with unused entries)
vaddr_t* pml4 = m_highest_paging_struct; vaddr_t* pml4 = m_highest_paging_struct;
@ -332,6 +347,8 @@ namespace Kernel
vaddr_t MMU::get_free_contiguous_pages(size_t page_count) const vaddr_t MMU::get_free_contiguous_pages(size_t page_count) const
{ {
LockGuard _(m_lock);
for (vaddr_t address = PAGE_SIZE; !(address >> 48); address += PAGE_SIZE) for (vaddr_t address = PAGE_SIZE; !(address >> 48); address += PAGE_SIZE)
{ {
bool valid { true }; bool valid { true };
@ -339,7 +356,7 @@ namespace Kernel
{ {
if (get_page_flags(address + page * PAGE_SIZE) & Flags::Present) if (get_page_flags(address + page * PAGE_SIZE) & Flags::Present)
{ {
address += page; address += page * PAGE_SIZE;
valid = false; valid = false;
break; break;
} }
@ -359,8 +376,10 @@ namespace Kernel
bool MMU::is_range_free(vaddr_t start, size_t size) const bool MMU::is_range_free(vaddr_t start, size_t size) const
{ {
LockGuard _(m_lock);
vaddr_t first_page = start / PAGE_SIZE; vaddr_t first_page = start / PAGE_SIZE;
vaddr_t last_page = BAN::Math::div_round_up<vaddr_t>(start + size, PAGE_SIZE); vaddr_t last_page = (start + size - 1) / PAGE_SIZE;
for (vaddr_t page = first_page; page <= last_page; page++) for (vaddr_t page = first_page; page <= last_page; page++)
if (!is_page_free(page * PAGE_SIZE)) if (!is_page_free(page * PAGE_SIZE))
return false; return false;

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@ -1,6 +1,7 @@
#pragma once #pragma once
#include <kernel/Memory/Heap.h> #include <kernel/Memory/Types.h>
#include <kernel/SpinLock.h>
namespace Kernel namespace Kernel
{ {
@ -18,7 +19,7 @@ namespace Kernel
public: public:
static void initialize(); static void initialize();
static MMU& get(); static MMU& kernel();
static MMU& current(); static MMU& current();
@ -44,12 +45,16 @@ namespace Kernel
void load(); void load();
void lock() const { m_lock.lock(); }
void unlock() const { m_lock.unlock(); }
private: private:
uint64_t get_page_data(vaddr_t) const; uint64_t get_page_data(vaddr_t) const;
void initialize_kernel(); void initialize_kernel();
private: private:
uint64_t* m_highest_paging_struct; uint64_t* m_highest_paging_struct { nullptr };
mutable RecursiveSpinLock m_lock;
}; };
} }

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@ -68,7 +68,7 @@ namespace Kernel
static Process& current() { return Thread::current().process(); } static Process& current() { return Thread::current().process(); }
MMU& mmu() { return m_mmu ? *m_mmu : MMU::get(); } MMU& mmu() { return m_mmu ? *m_mmu : MMU::kernel(); }
private: private:
Process(pid_t); Process(pid_t);

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@ -26,6 +26,7 @@ namespace Kernel
void unblock_threads(Semaphore*); void unblock_threads(Semaphore*);
Thread& current_thread(); Thread& current_thread();
static pid_t current_tid();
private: private:
Scheduler() = default; Scheduler() = default;

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@ -49,6 +49,8 @@ namespace Kernel
uintptr_t interrupt_stack_size() const { return m_interrupt_stack_size; } uintptr_t interrupt_stack_size() const { return m_interrupt_stack_size; }
static Thread& current() ; static Thread& current() ;
static pid_t current_tid();
Process& process(); Process& process();
bool has_process() const { return m_process; } bool has_process() const { return m_process; }

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@ -105,8 +105,8 @@ namespace Kernel
if (rsdp->revision >= 2) if (rsdp->revision >= 2)
{ {
const XSDT* xsdt = (const XSDT*)rsdp->xsdt_address; const XSDT* xsdt = (const XSDT*)rsdp->xsdt_address;
MMU::get().identity_map_page((uintptr_t)xsdt, MMU::Flags::Present); MMU::kernel().identity_map_page((uintptr_t)xsdt, MMU::Flags::Present);
BAN::ScopeGuard _([xsdt] { MMU::get().unmap_page((uintptr_t)xsdt); }); BAN::ScopeGuard _([xsdt] { MMU::kernel().unmap_page((uintptr_t)xsdt); });
if (memcmp(xsdt->signature, "XSDT", 4) != 0) if (memcmp(xsdt->signature, "XSDT", 4) != 0)
return BAN::Error::from_error_code(ErrorCode::ACPI_RootInvalid); return BAN::Error::from_error_code(ErrorCode::ACPI_RootInvalid);
@ -120,8 +120,8 @@ namespace Kernel
else else
{ {
const RSDT* rsdt = (const RSDT*)(uintptr_t)rsdp->rsdt_address; const RSDT* rsdt = (const RSDT*)(uintptr_t)rsdp->rsdt_address;
MMU::get().identity_map_page((uintptr_t)rsdt, MMU::Flags::Present); MMU::kernel().identity_map_page((uintptr_t)rsdt, MMU::Flags::Present);
BAN::ScopeGuard _([rsdt] { MMU::get().unmap_page((uintptr_t)rsdt); }); BAN::ScopeGuard _([rsdt] { MMU::kernel().unmap_page((uintptr_t)rsdt); });
if (memcmp(rsdt->signature, "RSDT", 4) != 0) if (memcmp(rsdt->signature, "RSDT", 4) != 0)
return BAN::Error::from_error_code(ErrorCode::ACPI_RootInvalid); return BAN::Error::from_error_code(ErrorCode::ACPI_RootInvalid);
@ -133,13 +133,13 @@ namespace Kernel
m_entry_count = (rsdt->length - sizeof(SDTHeader)) / 4; m_entry_count = (rsdt->length - sizeof(SDTHeader)) / 4;
} }
MMU::get().identity_map_range(m_header_table, m_entry_count * m_entry_size, MMU::Flags::Present); MMU::kernel().identity_map_range(m_header_table, m_entry_count * m_entry_size, MMU::Flags::Present);
for (uint32_t i = 0; i < m_entry_count; i++) for (uint32_t i = 0; i < m_entry_count; i++)
{ {
auto* header = get_header_from_index(i); auto* header = get_header_from_index(i);
MMU::get().identity_map_page((uintptr_t)header, MMU::Flags::Present); MMU::kernel().identity_map_page((uintptr_t)header, MMU::Flags::Present);
MMU::get().identity_map_range((uintptr_t)header, header->length, MMU::Flags::Present); MMU::kernel().identity_map_range((uintptr_t)header, header->length, MMU::Flags::Present);
} }
return {}; return {};

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@ -146,10 +146,10 @@ APIC* APIC::create()
return nullptr; return nullptr;
} }
MMU::get().identity_map_page(apic->m_local_apic, MMU::Flags::ReadWrite | MMU::Flags::Present); MMU::kernel().identity_map_page(apic->m_local_apic, MMU::Flags::ReadWrite | MMU::Flags::Present);
for (auto& io_apic : apic->m_io_apics) for (auto& io_apic : apic->m_io_apics)
{ {
MMU::get().identity_map_page(io_apic.address, MMU::Flags::ReadWrite | MMU::Flags::Present); MMU::kernel().identity_map_page(io_apic.address, MMU::Flags::ReadWrite | MMU::Flags::Present);
io_apic.max_redirs = io_apic.read(IOAPIC_MAX_REDIRS); io_apic.max_redirs = io_apic.read(IOAPIC_MAX_REDIRS);
} }

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@ -130,7 +130,7 @@ namespace Kernel
ASSERT(m_general_allocator == nullptr); ASSERT(m_general_allocator == nullptr);
if (m_mmu) if (m_mmu)
{ {
MMU::get().load(); MMU::kernel().load();
delete m_mmu; delete m_mmu;
} }
for (auto paddr : m_allocated_pages) for (auto paddr : m_allocated_pages)

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@ -52,16 +52,24 @@ namespace Kernel
return m_current_thread ? *m_current_thread->thread : *m_idle_thread; return m_current_thread ? *m_current_thread->thread : *m_idle_thread;
} }
pid_t Scheduler::current_tid()
{
if (s_instance == nullptr)
return 0;
return Scheduler::get().current_thread().tid();
}
void Scheduler::reschedule() void Scheduler::reschedule()
{ {
VERIFY_CLI(); VERIFY_CLI();
ASSERT(InterruptController::get().is_in_service(PIT_IRQ)); ASSERT(InterruptController::get().is_in_service(PIT_IRQ));
InterruptController::get().eoi(PIT_IRQ); InterruptController::get().eoi(PIT_IRQ);
if (PIT::ms_since_boot() <= m_last_reschedule) if (PIT::ms_since_boot() <= m_last_reschedule)
return; return;
m_last_reschedule = PIT::ms_since_boot(); m_last_reschedule = PIT::ms_since_boot();
wake_threads(); wake_threads();
if (save_current_thread()) if (save_current_thread())
@ -174,7 +182,7 @@ namespace Kernel
GDT::set_tss_stack(current.interrupt_stack_base() + current.interrupt_stack_size()); GDT::set_tss_stack(current.interrupt_stack_base() + current.interrupt_stack_size());
} }
else else
MMU::get().load(); MMU::kernel().load();
switch (current.state()) switch (current.state())
{ {

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@ -1,5 +1,5 @@
#include <kernel/Scheduler.h>
#include <kernel/SpinLock.h> #include <kernel/SpinLock.h>
#include <kernel/Thread.h>
namespace Kernel namespace Kernel
{ {
@ -25,7 +25,7 @@ namespace Kernel
void RecursiveSpinLock::lock() void RecursiveSpinLock::lock()
{ {
// FIXME: is this thread safe? // FIXME: is this thread safe?
if (m_locker == Thread::current().tid()) if (m_locker == Scheduler::current_tid())
{ {
m_lock_depth++; m_lock_depth++;
} }
@ -33,13 +33,15 @@ namespace Kernel
{ {
m_lock.lock(); m_lock.lock();
ASSERT(m_locker == 0); ASSERT(m_locker == 0);
m_locker = Thread::current().tid(); m_locker = Scheduler::current_tid();
m_lock_depth = 1; m_lock_depth = 1;
} }
} }
void RecursiveSpinLock::unlock() void RecursiveSpinLock::unlock()
{ {
ASSERT(m_lock_depth > 0);
m_lock_depth--; m_lock_depth--;
if (m_lock_depth == 0) if (m_lock_depth == 0)
{ {

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@ -36,7 +36,7 @@ VesaTerminalDriver* VesaTerminalDriver::create()
return nullptr; return nullptr;
} }
MMU::get().identity_map_range(framebuffer.addr, framebuffer.pitch * framebuffer.height, MMU::Flags::UserSupervisor | MMU::Flags::ReadWrite | MMU::Flags::Present); MMU::kernel().identity_map_range(framebuffer.addr, framebuffer.pitch * framebuffer.height, MMU::Flags::UserSupervisor | MMU::Flags::ReadWrite | MMU::Flags::Present);
auto* driver = new VesaTerminalDriver( auto* driver = new VesaTerminalDriver(
framebuffer.width, framebuffer.width,
@ -53,7 +53,7 @@ VesaTerminalDriver* VesaTerminalDriver::create()
VesaTerminalDriver::~VesaTerminalDriver() VesaTerminalDriver::~VesaTerminalDriver()
{ {
MMU::get().unmap_range(m_address, m_pitch * m_height); MMU::kernel().unmap_range(m_address, m_pitch * m_height);
} }
void VesaTerminalDriver::set_pixel(uint32_t offset, Color color) void VesaTerminalDriver::set_pixel(uint32_t offset, Color color)