path: root/src/arch/amd64/paging.c

#include <panic.h>
#include <cpuid.h>
#include <stdint.h>
#include <lib.h>
#include <memory.h>

#define MEMORY_INTERNAL
#include <memory/physalloc.h>
#include <memory/virtalloc.h>

#include "paging.h"
#include "bindings.h"

// PAGE MAP LEVEL 4 ENTRY
struct pml4e {
	uint64_t flags              : 6;
	uint64_t                    : 6;
	uint64_t address            : 40;
	uint64_t                    : 11;
	uint64_t execute_disable    : 1;
};

// PAGE DIRECTORY POINTER TABLE ENTRY
struct pdpte {
	uint64_t flags              : 6;
	uint64_t                    : 1;
	uint64_t page_size          : 1;
	uint64_t                    : 4;
	uint64_t address            : 40;
	uint64_t                    : 11;
	uint64_t execute_disable    : 1;
};

// PAGE DIRECTORY ENTRY
struct pde {
	uint64_t flags              : 6;
	uint64_t                    : 1;
	uint64_t page_size          : 1;
	uint64_t                    : 4;
	uint64_t address            : 40;
	uint64_t                    : 11;
	uint64_t execute_disable    : 1;
};

// PAGE TABLE ENTRY
struct pte {
	uint64_t flags              : 9;
	uint64_t                    : 3;
	uint64_t address            : 40;
	uint64_t                    : 7;
	uint64_t protection_key     : 4;
	uint64_t execute_disable    : 1;
};

// bss segment, can write to
extern struct pml4e kernel_pml4[512];
extern struct pdpte kernel_pdpt_0[512];
extern struct pde kernel_pd_0[512];
extern struct pte bootstrap_pt[512];
extern struct pte paging_pt[512]; // paging_pt should NEVER be outside of this file, NEVER i say

// paged address to read page tables
// the structures are not gurenteed to be ident mapped
// map them here with map_<type>(phys_addr) before useing structures
void                *addr_mapped = (void *) (uintptr_t) 0x204000;
static struct pml4e *pml4_mapped = (void *) (uintptr_t) 0x200000;
static struct pdpte *pdpt_mapped = (void *) (uintptr_t) 0x201000;
static struct pde   *pd_mapped   = (void *) (uintptr_t) 0x202000;
static struct pte   *pt_mapped   = (void *) (uintptr_t) 0x203000;

static inline void invlpg(void *addr) {
	__asm volatile("invlpg (%0)" ::"r" (addr) : "memory");
}

static void load_addr(void *phys_addr) {
	static struct pte *pt = &paging_pt[4];
	pt->address = (uint64_t)phys_addr >> 12;
	pt->flags = F_PRESENT | F_WRITEABLE;
	invlpg(addr_mapped);
}

static void load_pml4(void *phys) {
	static struct pte *pt = &paging_pt[0];
	if ((uint64_t)phys >> 12 == pt->address)
		return;
	pt->address = (uint64_t)phys >> 12;
	pt->flags = F_PRESENT | F_WRITEABLE;
	invlpg(pml4_mapped);
}

static void load_pdpt(void *phys) {
	static struct pte *pt = &paging_pt[1];
	if ((uint64_t)phys >> 12 == pt->address)
		return;
	pt->address = (uint64_t)phys >> 12;
	pt->flags = F_PRESENT | F_WRITEABLE;
	invlpg(pdpt_mapped);
}

static void load_pd(void *phys) {
	static struct pte *pt = &paging_pt[2];
	if ((uint64_t)phys >> 12 == pt->address)
		return;
	pt->address = (uint64_t)phys >> 12;
	pt->flags = F_PRESENT | F_WRITEABLE;
	invlpg(pdpt_mapped);
}

static void load_pt(void *phys) {
	static struct pte *pt = &paging_pt[3];
	if ((uint64_t)phys >> 12 == pt->address)
		return;
	pt->address = (uint64_t)phys >> 12;
	pt->flags = F_PRESENT | F_WRITEABLE;
	invlpg(pt_mapped);
}

#define PAG_SUCCESS      0
#define PAG_CANNOT_ALLOC 1
#define PAG_NOT_PRESENT  2

static int select_pdpt(
		void *virt,
		unsigned int flags,
		struct pml4e *root,
		struct pdpte **res,
		bool create
) {
	load_pml4(root);
	uint64_t offset = (uint64_t)virt >> 39;
	struct pml4e *pml4e = &pml4_mapped[offset];
	if (!(pml4e->flags & F_PRESENT)) {
		if (!create) {
			return PAG_NOT_PRESENT;
		}
		void *new_page = alloc_phys_page();
		if (new_page == NULL) {
			return PAG_CANNOT_ALLOC;
		}
		load_addr(new_page);
		memset(addr_mapped, 0, PAGE_SIZE);
		pml4e->address = ((uint64_t)new_page) >> 12;
		pml4e->flags = F_PRESENT;
	}
	if (flags)
		pml4e->flags = F_PRESENT | flags;
	*res = (struct pdpte *)(uintptr_t)(pml4e->address << 12);
	return PAG_SUCCESS;
}

static int select_pd(
		void *virt,
		unsigned int flags,
		struct pdpte *pdpt,
		struct pde **res,
		bool create
) {
	load_pdpt(pdpt);
	uint64_t offset = ((uint64_t)virt >> 30) & 0x1ff;
	struct pdpte *pdpte = &pdpt_mapped[offset];
	if (!(pdpte->flags & F_PRESENT)) {
		if (!create) {
			return PAG_NOT_PRESENT;
		}
		void *new_page = alloc_phys_page();
		if (new_page == NULL) {
			return PAG_CANNOT_ALLOC;
		}
		load_addr(new_page);
		memset(addr_mapped, 0, PAGE_SIZE);
		pdpte->address = ((uint64_t)new_page) >> 12;
		pdpte->flags = F_PRESENT;
	}
	if (flags)
		pdpte->flags = F_PRESENT | flags;
	*res = (struct pde *)(uintptr_t)(pdpte->address << 12);
	return PAG_SUCCESS;
}

static int select_pt(
		void *virt,
		unsigned int flags,
		struct pde *pd,
		struct pte **res,
		bool create
) {
	load_pd(pd);
	uint64_t offset = ((uint64_t)virt >> 21) & 0x1ff;
	struct pde *pde = &pd_mapped[offset];
	if (!(pde->flags & F_PRESENT)) {
		if (!create) {
			return PAG_NOT_PRESENT;
		}
		void *new_page = alloc_phys_page();
		if (new_page == NULL) {
			return PAG_CANNOT_ALLOC;
		}
		load_addr(new_page);
		memset(addr_mapped, 0, PAGE_SIZE);
		pde->address = ((uint64_t)new_page) >> 12;
		pde->flags = F_PRESENT;
	}
	if (flags)
		pde->flags = F_PRESENT | flags;
	*res = (struct pte *)(uintptr_t)(pde->address << 12);
	return PAG_SUCCESS;
}

static void select_page(
		void *virt,
		struct pte *pt,
		struct pte **res
) {
	load_pt(pt);
	uint64_t offset = ((uint64_t)virt >> 12) & 0x1ff;
	struct pte *page = &pt_mapped[offset];
	*res = page;
	return;
}

static inline void try_unmap_pml4(void) {
	for (int i = 0; i < 512; i++) {
		if (pml4_mapped[i].flags & F_PRESENT)
			return;
	}
	for (int i = 0; i < 512; i++) {
		if (pml4_mapped[i].address) {
			void *addr = (void *)(uintptr_t)(pml4_mapped[i].address << 12);
			free_phys_page(addr);
		}
	}
}

static inline void try_unmap_pdpt(void) {
	for (int i = 0; i < 512; i++) {
		if (pdpt_mapped[i].flags & F_PRESENT)
			return;
	}
	for (int i = 0; i < 512; i++) {
		if (pdpt_mapped[i].address) {
			void *addr = (void *)(uintptr_t)(pdpt_mapped[i].address << 12);
			free_phys_page(addr);
		}
	}
	try_unmap_pml4();
}

static inline void try_unmap_pd(void) {
	for (int i = 0; i < 512; i++) {
		if (pd_mapped[i].flags & F_PRESENT)
			return;
	}
	for (int i = 0; i < 512; i++) {
		if (pd_mapped[i].address) {
			void *addr = (void *)(uintptr_t)(pd_mapped[i].address << 12);
			free_phys_page(addr);
		}
	}
	try_unmap_pdpt();
}

static inline void try_unmap_pt(void) {
	for (int i = 0; i < 512; i++) {
		if (pt_mapped[i].flags & F_PRESENT)
			return;
	}
	for (int i = 0; i < 512; i++) {
		if (pt_mapped[i].address) {
			void *addr = (void *)(uintptr_t)(pt_mapped[i].address << 12);
			free_phys_page(addr);
		}
	}
	try_unmap_pd();
}

static void unmap_page(
		struct pml4e *root,
		void *virt
) {
	struct pdpte *pdpt;
	struct pde   *pd;
	struct pte   *pt;
	struct pte   *page;

	unsigned int df = 0;

	if (select_pdpt(virt, df, root, &pdpt, false))
		return;

	if (select_pd(virt, df, pdpt, &pd, false))
		return;

	if (select_pt(virt, df, pd, &pt, false))
		return;

	select_page(virt, pt, &page);

	page->address = 0;
	page->flags = 0;

	try_unmap_pt();

	invlpg(virt);

	return;
}

static void unmap_pages(
		struct pml4e *root,
		void *virt_start,
		long page_count
) {
	uint64_t pml4_o = -1,
			 pdpt_o = -1,
			 pd_o   = -1;

	uint64_t pml4_n,
			 pdpt_n,
			 pd_n;

	struct pdpte *pdpt = NULL;
	struct pde   *pd   = NULL;
	struct pte   *pt   = NULL;
	struct pte   *page = NULL;

	unsigned int df = 0;

	void *virt;

	for (long i = 0; i < page_count; i++) {

		virt = (char *)virt_start + (i * PAGE_SIZE);

		pml4_n = (uint64_t)  virt >> 39;
		pdpt_n = ((uint64_t) virt >> 30) & 0x1ff;
		pd_n   = ((uint64_t) virt >> 21) & 0x1ff;

		if (pdpt == NULL || pml4_o != pml4_n) {
			if (select_pdpt(virt, df, root, &pdpt, false))
				continue;
			pml4_o = pml4_n;
		}

		if (pd == NULL || pdpt_o != pdpt_n) {
			if (select_pd(virt, df, pdpt, &pd, false))
				continue;
			pdpt_o = pdpt_n;
		}

		if (pt == NULL || pd_o != pd_n) {
			if (pt) {
				try_unmap_pt();
			}
			if (select_pt(virt, df, pd, &pt, false))
				continue;
			pd_o = pd_n;
		}

		select_page(virt, pt, &page);

		page->address = 0;
		page->flags = 0;

	}

	if (pt != NULL)
		try_unmap_pt();

	return;
}

static int map_page(
		struct pml4e *root,
		void *virt,
		void *phys,
		unsigned int flags
) {
	struct pdpte *pdpt;
	struct pde   *pd;
	struct pte   *pt;
	struct pte   *page;

	unsigned int df = F_WRITEABLE;

	if (select_pdpt(virt, df, root, &pdpt, true))
		return 1;

	if (select_pd(virt, df, pdpt, &pd, true))
		return 1;

	if (select_pt(virt, df, pd, &pt, true))
		return 1;

	select_page(virt, pt, &page);

	page->address = (uint64_t)phys >> 12;
	page->flags = F_PRESENT | flags;
	invlpg(virt);

	return 0;
}

static int map_pages(
		struct pml4e *root,
		void *virt_start,
		void *phys_start,
		unsigned int flags,
		long page_count
) {
	uint64_t pml4_o = -1,
			 pdpt_o = -1,
			 pd_o   = -1;

	uint64_t pml4_n,
			 pdpt_n,
			 pd_n;

	struct pdpte *pdpt = NULL;
	struct pde   *pd   = NULL;
	struct pte   *pt   = NULL;
	struct pte   *page = NULL;

	void *virt, *phys;

	unsigned int df = F_WRITEABLE;

	long i;
	for (i = 0; i < page_count; i++) {

		virt = (char *)virt_start + (i * PAGE_SIZE);
		phys = (char *)phys_start + (i * PAGE_SIZE);

		pml4_n = (uint64_t)  virt >> 39;
		pdpt_n = ((uint64_t) virt >> 30) & 0x1ff;
		pd_n   = ((uint64_t) virt >> 21) & 0x1ff;

		if (pdpt == NULL || pml4_o != pml4_n) {
			if (select_pdpt(virt, df, root, &pdpt, true))
				goto failed;
			pml4_o = pml4_n;
		}

		if (pd == NULL || pdpt_o != pdpt_n) {
			if (select_pd(virt, df, pdpt, &pd, true))
				goto failed;
			pdpt_o = pdpt_n;
		}

		if (pt == NULL || pd_o != pd_n) {
			if (select_pt(virt, df, pd, &pt, true))
				goto failed;
			pd_o = pd_n;
		}

		select_page(virt, pt, &page);

		page->address = (uint64_t)phys >> 12;
		page->flags = F_PRESENT | flags;
		invlpg(virt);

	}

	return 0;

failed:

	unmap_pages(root, virt, i);

	return 1;
}

void paging_init(void) {
	kernel_pml4[0].flags = F_PRESENT | F_WRITEABLE;
	kernel_pml4[0].address = (uint64_t)(&kernel_pdpt_0) >> 12;

	kernel_pdpt_0[0].flags = F_PRESENT | F_WRITEABLE;
	kernel_pdpt_0[0].address = (uint64_t)(&kernel_pd_0) >> 12;

	kernel_pd_0[1].flags = F_PRESENT | F_WRITEABLE;
	kernel_pd_0[1].address = (uint64_t)(&paging_pt) >> 12;
	kernel_pd_0[2].flags = F_PRESENT | F_WRITEABLE;
	kernel_pd_0[2].address = (uint64_t)(&bootstrap_pt) >> 12;

	memset(&paging_pt, 0, 4096);
	memset(&bootstrap_pt, 0, 4096);
}

static inline void *page_align(void *addr) {
	uintptr_t a = (uintptr_t) addr;
	a += PAGE_SIZE - 1;
	a /= PAGE_SIZE;
	a *= PAGE_SIZE;
	return (void *) a;
}

void *mmap(void *addr, size_t len) {
	len += (long)addr % PAGE_SIZE;
	long pages = (len + PAGE_SIZE - 1) / PAGE_SIZE;
	void *virt = virtaddr_alloc(pages);
	if (virt == NULL) {
		return NULL;
	}
	void *phys = page_align(addr);
	if (map_pages(
			kernel_pml4,
			virt,
			phys,
			F_WRITEABLE,
			pages
	)) {
		virtaddr_free(virt);
		return NULL;
	}
	return virt;
}

void unmap(void *addr) {
	long pages = virtaddr_free(addr);
	if (pages < 1)
		return;
	unmap_pages(kernel_pml4, addr, pages);
}

void *alloc_pages(int count) {
	void *virt = virtaddr_alloc(count);
	if (virt == NULL)
		return NULL;
	void *phys = alloc_phys_pages(count);
	if (phys == NULL) {
		virtaddr_free(virt);
		return NULL;
	}
	if (map_pages(
			kernel_pml4,
			virt,
			phys,
			F_WRITEABLE,
			count
	)) {
		virtaddr_free(virt);
		return NULL;
	}
	return virt;
}

void free_page(void *virt) {
	(void) virt;
	panic("free_page is not yet implemented");
}

void free_pages(void *virt) {
	long pages = virtaddr_free(virt);
	if (pages < 1)
		return;
	unmap_pages(kernel_pml4, virt, pages);
}

void memory_lock(void) {
	cli();
}

void memory_unlock(void) {
	sti();
}

int kmap_page(void *virt_addr, void *phys_addr, unsigned int flags) {
	return map_page(kernel_pml4, virt_addr, phys_addr, flags);
}

int kunmap_page(void *virt_addr) {
	unmap_page(kernel_pml4, virt_addr);
	return 0;
}