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#include <cstdint>
#include <generic/mm/pmm.hpp>
#include <generic/mm/heap.hpp>
#include <generic/mm/paging.hpp>
#include <etc/bootloaderinfo.hpp>
#include <etc/logging.hpp>
#include <limine.h>
#include <etc/etc.hpp>
#include <etc/libc.hpp>
static void init();
std::uint64_t kernel_cr3;
alwaysmapped_t* alwmap = 0;
uint64_t* __paging_next_level(std::uint64_t* table,std::uint16_t idx,std::uint64_t flags,std::uint32_t id) {
if(!(table[idx] & PTE_PRESENT))
table[idx] = memory::pmm::_physical::allocid(4096,id) | flags;
return (uint64_t*)Other::toVirt(table[idx] & PTE_MASK_VALUE);
}
uint64_t* __paging_next_level_noalloc(std::uint64_t* table,std::uint16_t idx,std::uint64_t flags,std::uint32_t id) {
if(!(table[idx] & PTE_PRESENT))
return 0;
return (uint64_t*)Other::toVirt(table[idx] & PTE_MASK_VALUE);
}
void memory::paging::map(std::uint64_t cr3,std::uint64_t phys,std::uint64_t virt,std::uint64_t flags) {
std::uint64_t align_phys = ALIGNDOWN(phys,4096);
std::uint64_t align_virt = ALIGNDOWN(virt,4096);
std::uint64_t* cr30 = (std::uint64_t*)Other::toVirt(cr3);
std::uint64_t new_flags = PTE_PRESENT | PTE_RW;
if(PTE_INDEX(align_virt,39) < 256)
new_flags |= PTE_USER;
uint64_t* pml3 = __paging_next_level(cr30,PTE_INDEX(align_virt,39),new_flags,0);
uint64_t* pml2 = __paging_next_level(pml3,PTE_INDEX(align_virt,30),new_flags,0);
uint64_t* pml = __paging_next_level(pml2,PTE_INDEX(align_virt,21),new_flags,0);
pml[PTE_INDEX(align_virt,12)] = align_phys | flags;
}
void memory::paging::mapid(std::uint64_t cr3,std::uint64_t phys,std::uint64_t virt,std::uint64_t flags,std::uint32_t id) {
std::uint64_t align_phys = ALIGNDOWN(phys,4096);
std::uint64_t align_virt = ALIGNDOWN(virt,4096);
std::uint64_t* cr30 = (std::uint64_t*)Other::toVirt(cr3);
std::uint64_t new_flags = PTE_PRESENT | PTE_RW;
if(PTE_INDEX(align_virt,39) < 256)
new_flags |= PTE_USER;
uint64_t* pml3 = __paging_next_level(cr30,PTE_INDEX(align_virt,39),new_flags,id);
uint64_t* pml2 = __paging_next_level(pml3,PTE_INDEX(align_virt,30),new_flags,id);
uint64_t* pml = __paging_next_level(pml2,PTE_INDEX(align_virt,21),new_flags,id);
pml[PTE_INDEX(align_virt,12)] = align_phys | flags;
}
void memory::paging::change(std::uint64_t cr3, std::uint64_t virt, std::uint64_t flags) {
std::uint64_t align_virt = ALIGNDOWN(virt,4096);
std::uint64_t* cr30 = (std::uint64_t*)Other::toVirt(cr3);
std::uint64_t new_flags = PTE_PRESENT | PTE_RW;
if(PTE_INDEX(align_virt,39) < 256)
new_flags |= PTE_USER;
uint64_t* pml3 = __paging_next_level(cr30,PTE_INDEX(align_virt,39),new_flags,0);//1
uint64_t* pml2 = __paging_next_level(pml3,PTE_INDEX(align_virt,30),new_flags,0); // 2
uint64_t* pml = __paging_next_level(pml2,PTE_INDEX(align_virt,21),new_flags,0); // 3
pml[PTE_INDEX(align_virt,12)] = (pml[PTE_INDEX(align_virt,12)] & PTE_MASK_VALUE) | flags;
}
std::int64_t __memory_paging_getphys(std::uint64_t cr3, std::uint64_t virt) {
std::uint64_t align_virt = ALIGNDOWN(virt,4096);
std::uint64_t* cr30 = (std::uint64_t*)Other::toVirt(cr3);
if(cr30[PTE_INDEX(virt,39)] & PTE_PRESENT) {
std::uint64_t* pml3 = __paging_next_level_noalloc(cr30,PTE_INDEX(align_virt,39),0,0);//1
if(pml3[PTE_INDEX(virt,30)] & PTE_PRESENT) {
std::uint64_t* pml2 = __paging_next_level_noalloc(pml3,PTE_INDEX(align_virt,30),0,0); // 2
if(pml2[PTE_INDEX(virt,21)] & PTE_PRESENT) {
uint64_t* pml = __paging_next_level_noalloc(pml2,PTE_INDEX(align_virt,21),0,0); // 3
if(pml[PTE_INDEX(align_virt,12)] & PTE_PRESENT) {
return pml[PTE_INDEX(virt,12)] & PTE_MASK_VALUE;
} else {
return -1;
}
} else {
return -1;
}
} else {
return -1;
}
} else {
return -1;
}
}
void memory::paging::destroyrange(std::uint64_t cr3, std::uint64_t virt, std::uint64_t len) {
for(std::uint64_t i = 0;i < len; i += 4096) {
std::int64_t phys = __memory_paging_getphys(cr3,virt + i);
if(phys != -1 && phys != 0) {
memory::pmm::_physical::free((std::uint64_t)phys);
map(cr3,0,virt + i,0);
}
}
}
void memory::paging::duplicaterangeifexists(std::uint64_t src_cr3, std::uint64_t dest_cr3, std::uint64_t virt, std::uint64_t len, std::uint64_t flags) {
zerorange(dest_cr3,virt,len);
for(std::uint64_t i = 0;i < len; i += 4096) {
std::int64_t phys = __memory_paging_getphys(src_cr3,virt + i);
if(phys != -1) {
std::uint64_t new_phys = memory::pmm::_physical::alloc(4096);
memcpy(Other::toVirt(new_phys),Other::toVirt(phys),4096);
map(dest_cr3,new_phys,virt + i,flags);
}
}
}
void memory::paging::changerange(std::uint64_t cr3, std::uint64_t virt, std::uint64_t len , std::uint64_t flags) {
for(std::uint64_t i = 0;i < len; i += 4096) {
change(cr3,virt + i, flags);
}
}
void memory::paging::maprange(std::uint64_t cr3,std::uint64_t phys,std::uint64_t virt,std::uint64_t len,std::uint64_t flags) {
for(std::uint64_t i = 0; i < len; i += 4096) {
map(cr3,phys + i,virt + i,flags);
}
}
void* memory::paging::maprangeret(std::uint64_t phys,std::uint64_t len,std::uint64_t flags) {
std::uint64_t virt = (std::uint64_t)Other::toVirt(phys);
for(std::uint64_t i = 0; i < len; i += 4096) {
map(kernel_cr3,phys + i,virt + i,flags);
}
return (void*)Other::toVirt(phys);
}
void memory::paging::zerorange(std::uint64_t cr3,std::uint64_t virt,std::uint64_t len) {
for(std::uint64_t i = 0; i < len; i += 4096) {
map(cr3,0,virt + i,0);
}
}
void memory::paging::maprangeid(std::uint64_t cr3,std::uint64_t phys,std::uint64_t virt,std::uint64_t len,std::uint64_t flags, std::uint32_t id) {
for(std::uint64_t i = 0; i < len; i += 4096) {
mapid(cr3,phys + i,virt + i,flags,id);
}
}
void memory::paging::mapentry(std::uint64_t cr3,std::uint8_t type,std::uint64_t add_flags) {
limine_memmap_response* mmap = BootloaderInfo::AccessMemoryMap();
limine_memmap_entry* current = mmap->entries[0];
for(int i = 0;i < mmap->entry_count;i++) {
current = mmap->entries[i];
if(current->type == type)
maprange(cr3,current->base,(std::uint64_t)Other::toVirt(current->base),current->length,PTE_PRESENT | PTE_RW | add_flags);
}
}
void* memory::paging::kernelmap(std::uint64_t cr3,std::uint64_t phys) {
map(kernel_cr3,phys,(std::uint64_t)Other::toVirt(phys),PTE_PRESENT | PTE_RW);
return Other::toVirt(phys);
}
void __paging_map_kernel(std::uint64_t cr3,std::uint32_t id) {
extern std::uint64_t kernel_start;
extern std::uint64_t kernel_end;
limine_executable_address_response* ker = BootloaderInfo::AccessKernel();
for(std::uint64_t i = ALIGNDOWN((std::uint64_t)&kernel_start,4096);i < ALIGNUP((std::uint64_t)&kernel_end,4096);i += 4096) {
memory::paging::mapid(cr3,i - ker->virtual_base + ker->physical_base,i,PTE_PRESENT | PTE_RW,0);
}
}
void memory::paging::mapkernel(std::uint64_t cr3,std::uint32_t id) {
__paging_map_kernel(cr3,id);
}
void memory::paging::enablekernel() {
asm volatile("mov %0, %%cr3" : : "r"(kernel_cr3) : "memory");
}
void memory::paging::enablepaging(std::uint64_t cr3) {
asm volatile("mov %0, %%cr3" : : "r"(cr3) : "memory");
}
std::uint64_t memory::paging::kernelget() {
return kernel_cr3;
}
void __map_range_id(std::uint64_t cr3,std::uint64_t phys,std::uint64_t virt,std::uint64_t len,std::uint64_t flags,std::uint32_t id) {
for(std::uint64_t i = 0; i < len; i += 4096) {
memory::paging::map(cr3,phys + i,virt + i,flags);
}
}
void memory::paging::alwaysmappedadd(std::uint64_t phys, std::uint64_t len) {
alwaysmapped_t* alw = new alwaysmapped_t;
alw->next = alwmap;
alw->phys = phys;
alw->len = len;
alwmap = alw;
}
void memory::paging::alwaysmappedmap(std::uint64_t cr3,std::uint32_t id) {
alwaysmapped_t* current = alwmap;
while(current) {
__map_range_id(cr3,current->phys,(std::uint64_t)Other::toVirt(current->phys),current->len,PTE_RW | PTE_PRESENT,id);
current = current->next;
}
}
void __paging_destroy_table(std::uint64_t phys_table, int level) {
std::uint64_t* table = (std::uint64_t*)Other::toVirt(phys_table);
if(level != 3) {
if(level == 0) {
for(int i = 0; i < 256; i++) {
if(table[i] & PTE_PRESENT) {
__paging_destroy_table(table[i] & PTE_MASK_VALUE,level + 1);
}
}
} else {
for(int i = 0;i < 512; i++) {
if(table[i] & PTE_PRESENT) {
__paging_destroy_table(table[i] & PTE_MASK_VALUE,level + 1);
}
}
}
}
if(level != 0)
memory::pmm::_physical::free(phys_table);
}
void memory::paging::destroy(std::uint64_t cr3) {
if(cr3 == kernel_cr3)
return;
__paging_destroy_table(cr3,0);
}
void memory::paging::init() {
kernel_cr3 = memory::pmm::_physical::alloc(4096);
mapentry(kernel_cr3,LIMINE_MEMMAP_USABLE,0);
mapentry(kernel_cr3,LIMINE_MEMMAP_FRAMEBUFFER,PTE_WC);
mapentry(kernel_cr3,LIMINE_MEMMAP_BOOTLOADER_RECLAIMABLE,0);
mapentry(kernel_cr3,LIMINE_MEMMAP_EXECUTABLE_AND_MODULES,0);
mapkernel(kernel_cr3,0);
enablekernel();
}
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