Move away from using recursive mapping for page tables.
Having the HHDM-based mapping allows us to more easily map data into non-resident processes.
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c6921b5459
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f6609983d2
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@ -39,121 +39,134 @@ uint64_t ShiftForEntryIndexing(uint64_t addr, uint64_t offset) {
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addr &= ~0xFFFF0000'00000000;
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addr >>= offset;
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addr <<= 3;
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return addr;
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return addr & 0xFF8;
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}
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uint64_t* Pml4Entry(uint64_t addr) {
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return reinterpret_cast<uint64_t*>(PML_RECURSE |
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uint64_t* Pml4Entry(uint64_t cr3, uint64_t addr) {
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cr3 += boot::GetHigherHalfDirectMap();
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return reinterpret_cast<uint64_t*>(cr3 |
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ShiftForEntryIndexing(addr, PML_OFFSET));
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}
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uint64_t* PageDirectoryPointerEntry(uint64_t addr) {
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return reinterpret_cast<uint64_t*>(PDP_RECURSE |
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uint64_t* PageDirectoryPointerEntry(uint64_t pdp_phys, uint64_t addr) {
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pdp_phys += boot::GetHigherHalfDirectMap();
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pdp_phys &= ~0xFFF;
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return reinterpret_cast<uint64_t*>(pdp_phys |
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ShiftForEntryIndexing(addr, PDP_OFFSET));
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}
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uint64_t* PageDirectoryEntry(uint64_t addr) {
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return reinterpret_cast<uint64_t*>(PD_RECURSE |
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uint64_t* PageDirectoryEntry(uint64_t pd_phys, uint64_t addr) {
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pd_phys += boot::GetHigherHalfDirectMap();
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pd_phys &= ~0xFFF;
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return reinterpret_cast<uint64_t*>(pd_phys |
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ShiftForEntryIndexing(addr, PD_OFFSET));
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}
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uint64_t* PageTableEntry(uint64_t addr) {
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return reinterpret_cast<uint64_t*>(PT_RECURSE |
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uint64_t* PageTableEntry(uint64_t pt_phys, uint64_t addr) {
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pt_phys += boot::GetHigherHalfDirectMap();
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pt_phys &= ~0xFFF;
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return reinterpret_cast<uint64_t*>(pt_phys |
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ShiftForEntryIndexing(addr, PT_OFFSET));
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}
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bool PageDirectoryPointerLoaded(uint64_t addr) {
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return *Pml4Entry(addr) & PRESENT_BIT;
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}
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bool PageDirectoryLoaded(uint64_t addr) {
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return PageDirectoryPointerLoaded(addr) &&
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(*PageDirectoryPointerEntry(addr) & PRESENT_BIT);
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}
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bool PageTableLoaded(uint64_t addr) {
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return PageDirectoryLoaded(addr) && (*PageDirectoryEntry(addr) & PRESENT_BIT);
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}
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void MapPage(uint64_t virt, uint64_t phys) {
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if (PageLoaded(virt)) {
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panic("Allocating Over Existing Page: %m", virt);
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bool IsPageResident(uint64_t cr3, uint64_t virt) {
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uint64_t* pml4_entry = Pml4Entry(cr3, virt);
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if (!(*pml4_entry & PRESENT_BIT)) {
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return false;
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}
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uint64_t* pdp_entry = PageDirectoryPointerEntry(*pml4_entry, virt);
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if (!(*pdp_entry & PRESENT_BIT)) {
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return false;
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}
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uint64_t* pd_entry = PageDirectoryEntry(*pdp_entry, virt);
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if (!(*pd_entry & PRESENT_BIT)) {
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return false;
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}
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uint64_t* pt_entry = PageTableEntry(*pd_entry, virt);
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if (!(*pt_entry & PRESENT_BIT)) {
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return false;
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}
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return true;
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}
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void MapPage(uint64_t cr3, uint64_t virt) {
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uint64_t access_bits = PRESENT_BIT | READ_WRITE_BIT;
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uint64_t higher_half = 0xffff8000'00000000;
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if ((virt & higher_half) != higher_half) {
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access_bits |= USER_MODE_BIT;
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}
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if (!PageDirectoryPointerLoaded(virt)) {
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uint64_t* pml4_entry = Pml4Entry(cr3, virt);
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if (!(*pml4_entry & PRESENT_BIT)) {
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uint64_t page = phys_mem::AllocatePage();
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*Pml4Entry(virt) = page | access_bits;
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ZeroOutPage(PageDirectoryPointerEntry(virt));
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*pml4_entry = page | access_bits;
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ZeroOutPage(PageDirectoryPointerEntry(*pml4_entry, virt));
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}
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if (!PageDirectoryLoaded(virt)) {
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uint64_t* pdp_entry = PageDirectoryPointerEntry(*pml4_entry, virt);
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if (!(*pdp_entry & PRESENT_BIT)) {
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uint64_t page = phys_mem::AllocatePage();
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*PageDirectoryPointerEntry(virt) = page | access_bits;
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ZeroOutPage(PageDirectoryEntry(virt));
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*pdp_entry = page | access_bits;
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ZeroOutPage(PageDirectoryEntry(*pdp_entry, virt));
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}
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if (!PageTableLoaded(virt)) {
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uint64_t* pd_entry = PageDirectoryEntry(*pdp_entry, virt);
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if (!(*pd_entry & PRESENT_BIT)) {
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uint64_t page = phys_mem::AllocatePage();
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*PageDirectoryEntry(virt) = page | access_bits;
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ZeroOutPage(PageTableEntry(virt));
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*(pd_entry) = page | access_bits;
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ZeroOutPage(PageTableEntry(*pd_entry, virt));
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}
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*PageTableEntry(virt) = PageAlign(phys) | access_bits;
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ZeroOutPage(reinterpret_cast<uint64_t*>(virt));
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uint64_t* pt_entry = PageTableEntry(*pd_entry, virt);
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if (!(*pt_entry & PRESENT_BIT)) {
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uint64_t phys = phys_mem::AllocatePage();
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*pt_entry = PageAlign(phys) | access_bits;
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ZeroOutPage(reinterpret_cast<uint64_t*>(boot::GetHigherHalfDirectMap() +
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PageAlign(phys)));
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} else {
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panic("Page already allocated.");
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}
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}
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uint64_t Pml4Index(uint64_t addr) { return (addr >> PML_OFFSET) & 0x1FF; }
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} // namespace
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void InitPaging() {
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uint64_t CurrCr3() {
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uint64_t pml4_addr = 0;
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asm volatile("mov %%cr3, %0;" : "=r"(pml4_addr));
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uint64_t* pml4_virtual =
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reinterpret_cast<uint64_t*>(boot::GetHigherHalfDirectMap() + pml4_addr);
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uint64_t recursive_entry = pml4_addr | PRESENT_BIT | READ_WRITE_BIT;
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pml4_virtual[0x1FE] = recursive_entry;
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return pml4_addr;
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}
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} // namespace
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void InitializePml4(uint64_t pml4_physical_addr) {
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uint64_t* pml4_virtual = reinterpret_cast<uint64_t*>(
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boot::GetHigherHalfDirectMap() + pml4_physical_addr);
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// Map the recursive entry.
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uint64_t recursive_entry = pml4_physical_addr | PRESENT_BIT | READ_WRITE_BIT;
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pml4_virtual[0x1FE] = recursive_entry;
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uint64_t curr_cr3 = CurrCr3();
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// Map the kernel entry.
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// This should contain the heap at 0xFFFFFFFF'40000000
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uint64_t kernel_addr = 0xFFFFFFFF'80000000;
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pml4_virtual[Pml4Index(kernel_addr)] = *Pml4Entry(kernel_addr);
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pml4_virtual[Pml4Index(kernel_addr)] = *Pml4Entry(curr_cr3, kernel_addr);
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// Map the HHDM.
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// This is necessary to access values off of the kernel stack.
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uint64_t hhdm = boot::GetHigherHalfDirectMap();
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pml4_virtual[Pml4Index(hhdm)] = *Pml4Entry(hhdm);
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pml4_virtual[Pml4Index(hhdm)] = *Pml4Entry(curr_cr3, hhdm);
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}
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void AllocatePage(uint64_t addr) {
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uint64_t physical_page = phys_mem::AllocatePage();
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MapPage(addr, physical_page);
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void AllocatePageIfNecessary(uint64_t addr, uint64_t cr3) {
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if (cr3 == 0) {
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cr3 = CurrCr3();
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}
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if (IsPageResident(cr3, addr)) {
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return;
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}
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MapPage(cr3, addr);
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}
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void EnsureResident(uint64_t addr, uint64_t size) {
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uint64_t max = addr + size;
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addr = PageAlign(addr);
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while (addr < max) {
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if (!PageLoaded(addr)) {
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AllocatePage(addr);
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}
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AllocatePageIfNecessary(addr);
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addr += 0x1000;
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}
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}
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bool PageLoaded(uint64_t addr) {
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return PageTableLoaded(addr) && (*PageTableEntry(addr) & PRESENT_BIT);
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}
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@ -2,10 +2,7 @@
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#include <stdint.h>
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void InitPaging();
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void InitializePml4(uint64_t pml4_physical_addr);
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void AllocatePage(uint64_t addr);
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void AllocatePageIfNecessary(uint64_t addr, uint64_t cr3 = 0);
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void EnsureResident(uint64_t addr, uint64_t size);
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bool PageLoaded(uint64_t addr);
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@ -17,9 +17,6 @@ extern "C" void zion() {
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InitGdt();
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InitIdt();
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dbgln("[boot] Init Paging.");
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InitPaging();
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dbgln("[boot] Init Physical Memory Manager.");
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phys_mem::InitBootstrapPageAllocation();
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KernelHeap heap(0xFFFFFFFF'40000000, 0xFFFFFFFF'80000000);
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