CoolPotOS/kernel/page.c
2024-04-11 22:53:15 +08:00

192 lines
6.2 KiB
C

#include "../include/memory.h"
#include "../include/graphics.h"
#include "../include/io.h"
#include "../include/task.h"
page_directory_t *kernel_directory = 0; // 内核用页目录
page_directory_t *current_directory = 0; // 当前页目录
uint32_t *frames;
uint32_t nframes;
extern struct task_struct *current;
extern uint32_t placement_address;
extern void *program_break, *program_break_end;
static void set_frame(uint32_t frame_addr) {
uint32_t frame = frame_addr / 0x1000;
uint32_t idx = INDEX_FROM_BIT(frame);
uint32_t off = OFFSET_FROM_BIT(frame);
frames[idx] |= (0x1 << off);
}
static void clear_frame(uint32_t frame_addr) {
uint32_t frame = frame_addr / 0x1000;
uint32_t idx = INDEX_FROM_BIT(frame);
uint32_t off = OFFSET_FROM_BIT(frame);
frames[idx] &= ~(0x1 << off);
}
static uint32_t test_frame(uint32_t frame_addr) {
uint32_t frame = frame_addr / 0x1000;
uint32_t idx = INDEX_FROM_BIT(frame);
uint32_t off = OFFSET_FROM_BIT(frame);
return (frames[idx] & (0x1 << off));
}
uint32_t first_frame() {
for (int i = 0; i < INDEX_FROM_BIT(nframes); i++) {
if (frames[i] != 0xffffffff) {
for (int j = 0; j < 32; j++) {
uint32_t toTest = 0x1 << j;
if (!(frames[i] & toTest)) {
return i * 4 * 8 + j;
}
}
}
}
return (uint32_t) -1;
}
void alloc_frame(page_t *page, int is_kernel, int is_writable) {
if (page->frame) return;
else {
uint32_t idx = first_frame();
if (idx == (uint32_t) -1) {
printf("FRAMES_FREE_ERROR: Cannot free frames!\n");
asm("cli");
for (;;)io_hlt();
}
set_frame(idx * 0x1000);
page->present = 1; // 现在这个页存在了
page->rw = is_writable ? 1 : 0; // 是否可写由is_writable决定
page->user = is_kernel ? 0 : 1; // 是否为用户态由is_kernel决定
page->frame = idx;
}
}
void free_frame(page_t *page) {
uint32_t frame = page->frame;
if (!frame) return;
else {
clear_frame(frame);
page->frame = 0x0;
}
}
void switch_page_directory(page_directory_t *dir) {
current_directory = dir;
asm volatile("mov %0, %%cr3" : : "r"(&dir->tablesPhysical));
uint32_t cr0;
asm volatile("mov %%cr0, %0" : "=r"(cr0));
cr0 |= 0x80000000;
asm volatile("mov %0, %%cr0" : : "r"(cr0));
}
page_t *get_page(uint32_t address, int make, page_directory_t *dir) {
address /= 0x1000;
uint32_t table_idx = address / 1024;
if (dir->tables[table_idx]) return &dir->tables[table_idx]->pages[address % 1024];
else if (make) {
uint32_t tmp;
dir->tables[table_idx] = (page_table_t *) kmalloc_ap(sizeof(page_table_t), &tmp);
memset(dir->tables[table_idx], 0, 0x1000);
dir->tablesPhysical[table_idx] = tmp | 0x7;
return &dir->tables[table_idx]->pages[address % 1024];
} else return 0;
}
void page_fault(registers_t *regs) {
asm("cli");
uint32_t faulting_address;
asm volatile("mov %%cr2, %0" : "=r" (faulting_address)); //
int present = !(regs->err_code & 0x1); // 页不存在
int rw = regs->err_code & 0x2; // 只读页被写入
int us = regs->err_code & 0x4; // 用户态写入内核页
int reserved = regs->err_code & 0x8; // 写入CPU保留位
int id = regs->err_code & 0x10; // 由取指引起
printf("[ERROR]: Page fault |");
if (present) {
printf("Type: present;\n\taddress: %x ", faulting_address);
if(current->pid == 0){
printf(" ======= Kernel Error ======= ");
while (1) io_hlt();
} else{
current->state = TASK_ZOMBIE;
printf("Taskkill process PID:%d Name:%s",current->pid,current->name);
}
}
else if (rw) {
printf("Type: read-only;\n\taddress: %x", faulting_address);
if(current->pid == 0){
printf(" ======= Kernel Error ======= ");
while (1) io_hlt();
} else{
current->state = TASK_ZOMBIE;
printf("Taskkill process PID:%d Name:%s",current->pid,current->name);
}
}
else if (us) {
printf("Type: user-mode;\n\taddres: %x", faulting_address);
if(current->pid == 0){
printf(" ======= Kernel Error ======= ");
while (1) io_hlt();
} else{
current->state = TASK_ZOMBIE;
printf("Taskkill process PID:%d Name:%s",current->pid,current->name);
}
}
else if (reserved) {
printf("Type: reserved;\n\taddress: %x", faulting_address);
if(current->pid == 0){
printf(" ======= Kernel Error ======= ");
while (1) io_hlt();
} else{
current->state = TASK_ZOMBIE;
printf("Taskkill process PID:%d Name:%s",current->pid,current->name);
}
}
else if (id) {
printf("Type: decode address;\n\taddress: %x", faulting_address);
if(current->pid == 0){
printf(" ======= Kernel Error ======= ");
while (1) io_hlt();
} else{
current->state = TASK_ZOMBIE;
printf("Taskkill process PID:%d Name:%s",current->pid,current->name);
}
}
}
void init_page() {
uint32_t mem_end_page = 0xFFFFFFFF; // 4GB Page
nframes = mem_end_page / 0x1000;
frames = (uint32_t *) kmalloc(INDEX_FROM_BIT(nframes));
memset(frames, 0, INDEX_FROM_BIT(nframes));
kernel_directory = (page_directory_t *) kmalloc_a(sizeof(page_directory_t)); //kmalloc: 无分页情况自动在内核后方分配 | 有分页从内核堆分配
memset(kernel_directory, 0, sizeof(page_directory_t));
current_directory = kernel_directory;
int i = 0;
while (i < placement_address) {
// 内核部分对ring3而言可读不可写 | 无偏移页表映射
alloc_frame(get_page(i, 1, kernel_directory), 0, 0);
i += 0x1000;
}
for (int i = KHEAP_START; i < KHEAP_START + KHEAP_INITIAL_SIZE; i++) {
alloc_frame(get_page(i, 1, kernel_directory), 0, 0);
}
register_interrupt_handler(14, page_fault);
switch_page_directory(kernel_directory);
program_break = (void *) KHEAP_START;
program_break_end = (void *) (KHEAP_START + KHEAP_INITIAL_SIZE);
}