380 lines
12 KiB
C
380 lines
12 KiB
C
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#include <kernel/chroma.h>
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#include <lainlib/lainlib.h>
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/************************
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*** Team Kitty, 2020 ***
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*** Chroma ***
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***********************/
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/****************************************
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* W O R K I N P R O G R E S S *
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****************************************
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*
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* This file contains functions for virtual memory management.
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*
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* Virtual Memory Management is still a work in progress.
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* The functions here are hold-offs from old versions of the software implemented here, as well as from the EFI version of Chroma, called Sync.
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*
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* There, these functions worked, but here, under BIOS, it's a lot more difficult.
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* It will take some time to get these functions working.
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*
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* The general plan, being that the BOOTBOOT loader has given us static addresses for all of our doodads,
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* is to keep the core kernel where it is (FFFFFFFFFFE00000) and load in modules and libraries around it.
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*
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* We start in the higher half, so we'll dedicate the lower half (7FFFFFFFFFFF and below) to userspace.
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*
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* That means we have about 3 terabytes of RAM for the kernel.
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* This will be identity mapped, always.
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*
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* Handily, since most modern processors ignore the highest 2 bytes of a virtual address, and the kernel
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* is mapped to 0x80000000000 and above, we can use the nomenclature:
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* * 0x00007FFFFFFFFFFF and below is user space.
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* * 0xFFFF800000000000 and above is kernel space.
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* The processor will ignore the first 4 chars, and this provides a great deal of readability for the
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* future of the kernel.
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*
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* We'll have a kernel heap mapped into this kernel space, as well as a kernel stack (for task switching and error tracing).
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* These will be 1GB each.
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* We may have to increase this in the future, once Helix is fully integrated.
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* Helix will take a lot of memory, as it is a fully featured 3D engine. We may have to implement things like
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* texture streaming and mipmapping. Minimising RAM usage is NOT a priority for me, but it would be nice
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* to have a minimum requirement above 32GB.
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*
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* // TODO: Expand Kernel Heap
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*
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*
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* //TODO: there are lots of calls to AllocateFrame here, those need to be separated out into AllocateZeroFrame if necessary.
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*
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*
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*/
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extern size_t _kernel_text_start;
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extern size_t _kernel_rodata_start;
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extern size_t _kernel_data_start;
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//__attribute__((aligned(4096))) static size_t Pagetable[512] = {0};
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#define LAST_ENTRY 0xFF8
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#define SET_ADDRESS(a,b) ((*(size_t*) (a)) = (size_t) b)
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/*
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* It turns out it's useful to have macros for the standard
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* data size units.
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*
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* Who would've thoguht?
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*/
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#define KiB 1 * 1024
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#define MiB 1 * 1024 * KiB
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#define PAGE_PRESENT 1
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#define PAGE_RW 2
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#define PAGE_USER 4
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#define PAGE_GLOBAL 8
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#define USERWRITEABLE_FLAGS(a) ((a & 0xFFFFFF00) + 0x83)
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// The AbstractAllocator control struct
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static allocator_t Allocator = NULL;
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// The AbstractAllocator Ticketlock.
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static ticketlock_t AllocatorLock = {0};
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// Entries to help allocate the Kernel Stack
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static list_entry_t StackFreeList;
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static ticketlock_t StackLock = {0};
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static void* StackPointer = (void*) KERNEL_STACK_REGION;
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// A temporary itoa function for better debugging..
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const char* IntToAscii(int In) {
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char* OutputBuffer = " ";
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size_t Temp, i = 0, j = 0;
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do {
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Temp = In % 10;
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OutputBuffer[i++] = (Temp < 10) ? (Temp + '0') : (Temp + 'a' - 10);
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} while (In /= 10);
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OutputBuffer[i--] = 0;
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for(j = 0; j < i; j++, i--) {
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Temp = OutputBuffer[j];
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OutputBuffer[j] = OutputBuffer[i];
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OutputBuffer[i] = Temp;
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}
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return OutputBuffer;
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}
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void InitPaging() {
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StackFreeList = (list_entry_t) { &StackFreeList, &StackFreeList };
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size_t Size = AlignUpwards(AllocatorSize(), PAGE_SIZE);
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Allocator = PhysAllocateZeroMem(Size);
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Allocator = CreateAllocatorWithPool(Allocator, Size);
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SerialPrintf("[ Mem] Everything preallocated for paging.\n");
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KernelAddressSpace = (address_space_t) {
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.Lock = {0},
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.PML4 = PhysAllocateZeroMem(PAGE_SIZE)
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};
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size_t* Pagetable = KernelAddressSpace.PML4;
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//SerialPrintf("[ Mem] About to identity map the higher half.\n");
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// Identity map the higher half
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for(int i = 256; i < 512; i++) {
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Pagetable[i] = (size_t)PhysAllocateZeroMem(PAGE_SIZE);
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Pagetable[i] = (size_t)(((char*)Pagetable[i]) - DIRECT_REGION);
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Pagetable[i] |= (PAGE_PRESENT | PAGE_RW);
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//SerialPrintf("%d", i - 256);
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}
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SerialPrintf("[ Mem] Identity mapping higher half complete.\n");
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MMapEnt* TopEntry = (MMapEnt*)(((&bootldr) + bootldr.size) - sizeof(MMapEnt));
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size_t LargestAddress = TopEntry->ptr + TopEntry->size;
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SerialPrintf("[ Mem] About to map lower memory into the Direct Region.\n");
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for(size_t Address = 0; Address < AlignUpwards(LargestAddress, PAGE_SIZE); Address += PAGE_SIZE) {
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MapVirtualMemory(&KernelAddressSpace, (size_t*)(((char*)Address) + DIRECT_REGION), Address, MAP_WRITE);
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}
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SerialPrintf("[ Mem] Lower half mapping complete.\n");
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SerialPrintf("[ Mem] Mapping kernel into new memory map.\r\n");
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//TODO: Disallow execution of rodata and data, and bootldr/environment
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for(void* Address = CAST(void*, KERNEL_REGION);
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Address < CAST(void*, KERNEL_REGION + 0x2000); // Lower half of Kernel
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Address = CAST(void*, CAST(char*, Address) + PAGE_SIZE)) {
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MapVirtualMemory(&KernelAddressSpace, Address, (CAST(size_t, Address) - KERNEL_REGION) + KERNEL_PHYSICAL, MAP_EXEC);
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}
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for(void* Address = CAST(void*, KERNEL_REGION + 0x2000);
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Address < CAST(void*, KERNEL_REGION + 0x12000); // Higher half of kernel
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Address = CAST(void*, CAST(char*, Address) + PAGE_SIZE)) {
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MapVirtualMemory(&KernelAddressSpace, Address, (CAST(size_t, Address) - KERNEL_REGION) + KERNEL_PHYSICAL_2, MAP_EXEC);
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}
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for(void* Address = CAST(void*, FB_REGION);
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Address < CAST(void*, 0x200000); // TODO: Turn this into a calculation with bootldr.fb_size
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Address = CAST(void*, CAST(char*, Address) + PAGE_SIZE)) {
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MapVirtualMemory(&KernelAddressSpace, Address, (CAST(size_t, Address) - FB_REGION) + FB_PHYSICAL, MAP_WRITE);
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}
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SerialPrintf("[ Mem] Kernel mapped into pagetables. New PML4 at 0x%p\r\n", KernelAddressSpace.PML4);
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//ASSERT(Allocator != NULL);
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}
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static size_t GetCachingAttribute(pagecache_t Cache) {
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switch (Cache) {
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case CACHE_WRITE_BACK: return 0;
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case CACHE_WRITE_THROUGH: return 1 << 2;
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case CACHE_NONE: return 1 << 3;
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case CACHE_WRITE_COMBINING: return 1 << 6;
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}
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return 1 << 3;
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}
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static bool ExpandAllocator(size_t NewSize) {
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size_t AllocSize = AlignUpwards(AllocatorPoolOverhead() + sizeof(size_t) * 5 + NewSize, PAGE_SIZE);
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void* Pool = PhysAllocateMem(AllocSize);
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return AddPoolToAllocator(Allocator, Pool, AllocSize) != NULL;
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}
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static void GetPageFromTables(address_space_t* AddressSpace, size_t VirtualAddress, size_t** Page) {
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//ASSERT(Page != NULL);
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//ASSERT(AddressSpace != NULL);
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size_t* Pagetable = AddressSpace->PML4;
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for(int Level = 4; Level > 1; Level--) {
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size_t* Entry = &Pagetable[(VirtualAddress >> (12u + 9u * (Level - 1))) & 0x1FFU];
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ASSERT(*Entry & PAGE_PRESENT, "Page not present during retrieval");
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Pagetable = (size_t*)((char*)(*Entry & 0x7ffffffffffff000ull) + DIRECT_REGION);
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}
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ASSERT(Pagetable[(VirtualAddress >> 12U) & 0x1FFU] & PAGE_PRESENT, "PDPE not present during retrieval");
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*Page = &Pagetable[(VirtualAddress >> 12U) & 0x1FFU];
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}
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void SetAddressSpace(address_space_t* AddressSpace) {
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//ASSERT(AddressSpace != NULL);
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if((size_t)((char*)ReadControlRegister(3) + DIRECT_REGION) != (size_t) &AddressSpace->PML4) {
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WriteControlRegister(3, CAST(size_t, &AddressSpace->PML4));
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}
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}
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void MapVirtualMemory(address_space_t* AddressSpace, void* VirtualAddress, size_t PhysicalAddress, mapflags_t Flag) {
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//bool MapGlobally = false;
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size_t Virtual = (size_t)VirtualAddress;
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//ASSERT(AddressSpace != NULL);
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TicketAttemptLock(&AddressSpace->Lock);
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size_t Flags = PAGE_PRESENT;
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if(Flag & MAP_WRITE)
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Flags |= MAP_WRITE;
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if(Virtual < USER_REGION)
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Flags |= PAGE_USER;
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//TODO: Global mapping
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size_t* Pagetable = AddressSpace->PML4;
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for(int Level = 4; Level > 1; Level--) {
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size_t* Entry = &Pagetable[(Virtual >> (12u + 9u * (Level - 1))) & 0x1FFu];
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if(!(*Entry & PAGE_PRESENT)) {
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directptr_t Pointer = PhysAllocateZeroMem(PAGE_SIZE);
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*Entry = (size_t)(((char*)Pointer) + DIRECT_REGION);
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}
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*Entry |= Flags;
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Pagetable = (size_t*)(((char*)(*Entry & 0x7ffffffffffff000ull) + DIRECT_REGION));
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}
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size_t* Entry = &Pagetable[(Virtual >> 12u) & 0x1FFu];
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*Entry = Flags | PhysicalAddress;
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if(AddressSpace != NULL) {
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TicketUnlock(&AddressSpace->Lock);
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}
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}
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void UnmapVirtualMemory(address_space_t* AddressSpace, void* VirtualAddress){
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//ASSERT(AddressSpace != NULL);
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TicketAttemptLock(&AddressSpace->Lock);
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size_t* Entry;
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GetPageFromTables(AddressSpace, (size_t)VirtualAddress, &Entry);
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*Entry = 0;
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InvalidatePage((size_t)VirtualAddress);
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if(AddressSpace != NULL) {
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TicketUnlock(&AddressSpace->Lock);
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}
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}
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void CacheVirtualMemory(address_space_t* AddressSpace, void* VirtualAddress, pagecache_t Cache) {
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//ASSERT(AddressSpace != NULL);
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TicketAttemptLock(&AddressSpace->Lock);
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size_t* Entry;
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GetPageFromTables(AddressSpace, (size_t)VirtualAddress, &Entry);
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*Entry &= ~((1 << 6) | (1 << 2) | (1 << 3));
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*Entry |= GetCachingAttribute(Cache);
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InvalidatePage((size_t)VirtualAddress);
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if(AddressSpace != NULL) {
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TicketUnlock(&AddressSpace->Lock);
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}
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}
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void* AllocateMemory(size_t Bits) {
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TicketAttemptLock(&AllocatorLock);
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void* Result = AllocatorMalloc(Allocator, Bits);
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if(Result == NULL) {
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if(!ExpandAllocator(Bits)) {
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TicketUnlock(&AllocatorLock);
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return 0ULL;
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}
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Result = AllocatorMalloc(Allocator, Bits);
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}
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if(Result != NULL) {
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memset(Result, 0, Bits);
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}
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TicketUnlock(&AllocatorLock);
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return Result;
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}
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void* ReallocateMemory(void* Address, size_t NewSize) {
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TicketAttemptLock(&AllocatorLock);
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void* Result = AllocatorRealloc(Allocator, Address, NewSize);
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if(Result == NULL) {
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if(!ExpandAllocator(NewSize)) {
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TicketUnlock(&AllocatorLock);
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return 0ULL;
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}
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Result = AllocatorRealloc(Allocator, Address, NewSize);
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}
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TicketUnlock(&AllocatorLock);
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return Result;
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}
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void FreeMemory(void* Address) {
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TicketAttemptLock(&AllocatorLock);
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AllocatorFree(Allocator, Address);
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TicketUnlock(&AllocatorLock);
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}
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void* AllocateKernelStack() {
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void* StackAddress = NULL;
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size_t StackSize = PAGE_SIZE * 4;
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TicketAttemptLock(&StackLock);
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if(ListIsEmpty(&StackFreeList)) {
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StackAddress = StackPointer;
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StackPointer = (void*)(((char*)StackPointer) + (4*KiB) + StackSize);
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for(size_t i = 0; i < (StackSize / PAGE_SIZE); i++) {
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directptr_t NewStack;
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NewStack = PhysAllocateZeroMem(PAGE_SIZE);
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MapVirtualMemory(&KernelAddressSpace, (void*)((size_t)StackAddress + i * PAGE_SIZE), (size_t)((char*)NewStack) - DIRECT_REGION, MAP_WRITE);
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}
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} else {
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list_entry_t* StackEntry = StackFreeList.Next;
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ListRemove(StackEntry);
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memset(StackEntry, 0, StackSize);
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StackAddress = (void*)StackEntry;
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}
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TicketUnlock(&StackLock);
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StackAddress = (void*)((size_t)StackAddress + StackSize);
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StackAddress = (void*)((size_t)StackAddress - sizeof(size_t) * 2);
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return StackAddress;
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}
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void FreeKernelStack(void* StackAddress) {
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TicketAttemptLock(&StackLock);
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list_entry_t* ListEntry = (list_entry_t*)(((size_t)(StackAddress) + (sizeof(size_t) * 2)) - (PAGE_SIZE * 4));
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ListAdd(&StackFreeList, ListEntry);
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TicketUnlock(&StackLock);
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}
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