#include "mm.h"
#include "slab.h"
#include "../common/printk.h"
#include "../common/kprint.h"
#include "../driver/multiboot2/multiboot2.h"
#include <process/process.h>
ul Total_Memory = 0;
ul total_2M_pages = 0;
static ul root_page_table_phys_addr = 0; // 内核层根页表的物理地址
void mm_init()
{
kinfo("Initializing memory management unit...");
// 设置内核程序不同部分的起止地址
memory_management_struct.kernel_code_start = (ul)&_text;
memory_management_struct.kernel_code_end = (ul)&_etext;
memory_management_struct.kernel_data_end = (ul)&_edata;
memory_management_struct.rodata_end = (ul)&_erodata;
memory_management_struct.start_brk = (ul)&_end;
struct multiboot_mmap_entry_t mb2_mem_info[512];
int count;
multiboot2_iter(multiboot2_get_memory, mb2_mem_info, &count);
for (int i = 0; i < count; ++i)
{
//可用的内存
if (mb2_mem_info->type == 1)
Total_Memory += mb2_mem_info->len;
// 保存信息到mms
memory_management_struct.e820[i].BaseAddr = mb2_mem_info[i].addr;
memory_management_struct.e820[i].Length = mb2_mem_info[i].len;
memory_management_struct.e820[i].type = mb2_mem_info[i].type;
memory_management_struct.len_e820 = i;
// 脏数据
if (mb2_mem_info[i].type > 4 || mb2_mem_info[i].len == 0 || mb2_mem_info[i].type < 1)
break;
}
printk("[ INFO ] Total amounts of RAM : %ld bytes\n", Total_Memory);
// 计算有效内存页数
for (int i = 0; i < memory_management_struct.len_e820; ++i)
{
if (memory_management_struct.e820[i].type != 1)
continue;
// 将内存段的起始物理地址按照2M进行对齐
ul addr_start = PAGE_2M_ALIGN(memory_management_struct.e820[i].BaseAddr);
// 将内存段的终止物理地址的低2M区域清空,以实现对齐
ul addr_end = ((memory_management_struct.e820[i].BaseAddr + memory_management_struct.e820[i].Length) & PAGE_2M_MASK);
// 内存段不可用
if (addr_end <= addr_start)
continue;
total_2M_pages += ((addr_end - addr_start) >> PAGE_2M_SHIFT);
}
kinfo("Total amounts of 2M pages : %ld.", total_2M_pages);
// 物理地址空间的最大地址(包含了物理内存、内存空洞、ROM等)
ul max_addr = memory_management_struct.e820[memory_management_struct.len_e820].BaseAddr + memory_management_struct.e820[memory_management_struct.len_e820].Length;
// 初始化mms的bitmap
// bmp的指针指向截止位置的4k对齐的上边界(防止修改了别的数据)
memory_management_struct.bmp = (unsigned long *)((memory_management_struct.start_brk + PAGE_4K_SIZE - 1) & PAGE_4K_MASK);
memory_management_struct.bits_size = max_addr >> PAGE_2M_SHIFT; // 物理地址空间的最大页面数
memory_management_struct.bmp_len = (((unsigned long)(max_addr >> PAGE_2M_SHIFT) + sizeof(unsigned long) * 8 - 1) / 8) & (~(sizeof(unsigned long) - 1)); // bmp由多少个unsigned long变量组成
// 初始化bitmap, 先将整个bmp空间全部置位。稍后再将可用物理内存页复位。
memset(memory_management_struct.bmp, 0xff, memory_management_struct.bmp_len);
// 初始化内存页结构
// 将页结构映射于bmp之后
memory_management_struct.pages_struct = (struct Page *)(((unsigned long)memory_management_struct.bmp + memory_management_struct.bmp_len + PAGE_4K_SIZE - 1) & PAGE_4K_MASK);
memory_management_struct.count_pages = max_addr >> PAGE_2M_SHIFT;
memory_management_struct.pages_struct_len = ((max_addr >> PAGE_2M_SHIFT) * sizeof(struct Page) + sizeof(long) - 1) & (~(sizeof(long) - 1));
// 将pages_struct全部清空,以备后续初始化
memset(memory_management_struct.pages_struct, 0x00, memory_management_struct.pages_struct_len); // init pages memory
// 初始化内存区域
memory_management_struct.zones_struct = (struct Zone *)(((ul)memory_management_struct.pages_struct + memory_management_struct.pages_struct_len + PAGE_4K_SIZE - 1) & PAGE_4K_MASK);
// 由于暂时无法计算zone结构体的数量,因此先将其设为0
memory_management_struct.count_zones = 0;
// zones-struct 成员变量暂时按照5个来计算
memory_management_struct.zones_struct_len = (5 * sizeof(struct Zone) + sizeof(ul) - 1) & (~(sizeof(ul) - 1));
memset(memory_management_struct.zones_struct, 0x00, memory_management_struct.zones_struct_len);
// ==== 遍历e820数组,完成成员变量初始化工作 ===
for (int i = 0; i < memory_management_struct.len_e820; ++i)
{
if (memory_management_struct.e820[i].type != 1) // 不是操作系统可以使用的物理内存
continue;
ul addr_start = PAGE_2M_ALIGN(memory_management_struct.e820[i].BaseAddr);
ul addr_end = (memory_management_struct.e820[i].BaseAddr + memory_management_struct.e820[i].Length) & PAGE_2M_MASK;
if (addr_end <= addr_start)
continue;
// zone init
struct Zone *z = memory_management_struct.zones_struct + memory_management_struct.count_zones;
++memory_management_struct.count_zones;
z->zone_addr_start = addr_start;
z->zone_addr_end = addr_end;
z->zone_length = addr_end - addr_start;
z->count_pages_using = 0;
z->count_pages_free = (addr_end - addr_start) >> PAGE_2M_SHIFT;
z->total_pages_link = 0;
z->attr = 0;
z->gmd_struct = &memory_management_struct;
z->count_pages = (addr_end - addr_start) >> PAGE_2M_SHIFT;
z->pages_group = (struct Page *)(memory_management_struct.pages_struct + (addr_start >> PAGE_2M_SHIFT));
// 初始化页
struct Page *p = z->pages_group;
for (int j = 0; j < z->count_pages; ++j, ++p)
{
p->zone = z;
p->addr_phys = addr_start + PAGE_2M_SIZE * j;
p->attr = 0;
p->ref_counts = 0;
p->age = 0;
// 将bmp中对应的位 复位
*(memory_management_struct.bmp + ((p->addr_phys >> PAGE_2M_SHIFT) >> 6)) ^= (1UL << ((p->addr_phys >> PAGE_2M_SHIFT) % 64));
}
}
// 初始化0~2MB的物理页
// 由于这个区间的内存由多个内存段组成,因此不会被以上代码初始化,需要我们手动配置page[0]。
memory_management_struct.pages_struct->zone = memory_management_struct.zones_struct;
memory_management_struct.pages_struct->addr_phys = 0UL;
set_page_attr(memory_management_struct.pages_struct, PAGE_PGT_MAPPED | PAGE_KERNEL_INIT | PAGE_KERNEL);
memory_management_struct.pages_struct->ref_counts = 1;
memory_management_struct.pages_struct->age = 0;
// 将第0页的标志位给置上
//*(memory_management_struct.bmp) |= 1UL;
// 计算zone结构体的总长度(按照64位对齐)
memory_management_struct.zones_struct_len = (memory_management_struct.count_zones * sizeof(struct Zone) + sizeof(ul) - 1) & (~(sizeof(ul) - 1));
ZONE_DMA_INDEX = 0;
ZONE_NORMAL_INDEX = 0;
ZONE_UNMAPPED_INDEX = 0;
for (int i = 0; i < memory_management_struct.count_zones; ++i)
{
struct Zone *z = memory_management_struct.zones_struct + i;
// printk_color(ORANGE, BLACK, "zone_addr_start:%#18lx, zone_addr_end:%#18lx, zone_length:%#18lx, pages_group:%#18lx, count_pages:%#18lx\n",
// z->zone_addr_start, z->zone_addr_end, z->zone_length, z->pages_group, z->count_pages);
// 1GB以上的内存空间不做映射
if (z->zone_addr_start >= 0x100000000 && (!ZONE_UNMAPPED_INDEX))
ZONE_UNMAPPED_INDEX = i;
}
// kdebug("ZONE_DMA_INDEX=%d\tZONE_NORMAL_INDEX=%d\tZONE_UNMAPPED_INDEX=%d", ZONE_DMA_INDEX, ZONE_NORMAL_INDEX, ZONE_UNMAPPED_INDEX);
// 设置内存页管理结构的地址,预留了一段空间,防止内存越界。
memory_management_struct.end_of_struct = (ul)((ul)memory_management_struct.zones_struct + memory_management_struct.zones_struct_len + sizeof(long) * 32) & (~(sizeof(long) - 1));
// printk_color(ORANGE, BLACK, "code_start:%#18lx, code_end:%#18lx, data_end:%#18lx, kernel_end:%#18lx, end_of_struct:%#18lx\n",
// memory_management_struct.kernel_code_start, memory_management_struct.kernel_code_end, memory_management_struct.kernel_data_end, memory_management_struct.kernel_end, memory_management_struct.end_of_struct);
// 初始化内存管理单元结构所占的物理页的结构体
ul mms_max_page = (virt_2_phys(memory_management_struct.end_of_struct) >> PAGE_2M_SHIFT); // 内存管理单元所占据的序号最大的物理页
// kdebug("mms_max_page=%ld", mms_max_page);
struct Page *tmp_page = NULL;
ul page_num;
// 第0个page已经在上方配置
for (ul j = 1; j <= mms_max_page; ++j)
{
tmp_page = memory_management_struct.pages_struct + j;
page_init(tmp_page, PAGE_PGT_MAPPED | PAGE_KERNEL | PAGE_KERNEL_INIT);
page_num = tmp_page->addr_phys >> PAGE_2M_SHIFT;
*(memory_management_struct.bmp + (page_num >> 6)) |= (1UL << (page_num % 64));
++tmp_page->zone->count_pages_using;
--tmp_page->zone->count_pages_free;
}
global_CR3 = get_CR3();
// root_page_table_phys_addr = global_CR3;
// kdebug("global_CR3\t:%#018lx", global_CR3);
// kdebug("*global_CR3\t:%#018lx", *phys_2_virt(global_CR3) & (~0xff));
// kdebug("**global_CR3\t:%#018lx", *phys_2_virt(*phys_2_virt(global_CR3) & (~0xff)) & (~0xff));
// kdebug("1.memory_management_struct.bmp:%#018lx\tzone->count_pages_using:%d\tzone_struct->count_pages_free:%d", *memory_management_struct.bmp, memory_management_struct.zones_struct->count_pages_using, memory_management_struct.zones_struct->count_pages_free);
// kinfo("Cleaning page table remapping at 0x0000");
kinfo("Memory management unit initialize complete!");
flush_tlb();
// 初始化slab内存池
slab_init();
page_table_init();
init_frame_buffer();
}
/**
* @brief 初始化内存页
*
* @param page 内存页结构体
* @param flags 标志位
* 本函数只负责初始化内存页,允许对同一页面进行多次初始化
* 而维护计数器及置位bmp标志位的功能,应当在分配页面的时候手动完成
* @return unsigned long
*/
unsigned long page_init(struct Page *page, ul flags)
{
page->attr |= flags;
// 若页面的引用计数为0或是共享页,增加引用计数
if ((!page->ref_counts) || (page->attr & PAGE_SHARED))
{
++page->ref_counts;
++page->zone->total_pages_link;
}
return 0;
}
/**
* @brief 从已初始化的页结构中搜索符合申请条件的、连续num个struct page
*
* @param zone_select 选择内存区域, 可选项:dma, mapped in pgt(normal), unmapped in pgt
* @param num 需要申请的连续内存页的数量 num<64
* @param flags 将页面属性设置成flag
* @return struct Page*
*/
struct Page *alloc_pages(unsigned int zone_select, int num, ul flags)
{
ul zone_start = 0, zone_end = 0;
if (num >= 64 && num <= 0)
{
kerror("alloc_pages(): num is invalid.");
return NULL;
}
ul attr = flags;
switch (zone_select)
{
case ZONE_DMA:
// DMA区域
zone_start = 0;
zone_end = ZONE_DMA_INDEX;
attr |= PAGE_PGT_MAPPED;
break;
case ZONE_NORMAL:
zone_start = ZONE_DMA_INDEX;
zone_end = ZONE_NORMAL_INDEX;
attr |= PAGE_PGT_MAPPED;
break;
case ZONE_UNMAPPED_IN_PGT:
zone_start = ZONE_NORMAL_INDEX;
zone_end = ZONE_UNMAPPED_INDEX;
attr = 0;
break;
default:
kerror("In alloc_pages: param: zone_select incorrect.");
// 返回空
return NULL;
break;
}
for (int i = zone_start; i <= zone_end; ++i)
{
if ((memory_management_struct.zones_struct + i)->count_pages_free < num)
continue;
struct Zone *z = memory_management_struct.zones_struct + i;
// 区域对应的起止页号
ul page_start = (z->zone_addr_start >> PAGE_2M_SHIFT);
ul page_end = (z->zone_addr_end >> PAGE_2M_SHIFT);
ul tmp = 64 - page_start % 64;
for (ul j = page_start; j < page_end; j += ((j % 64) ? tmp : 64))
{
// 按照bmp中的每一个元素进行查找
// 先将p定位到bmp的起始元素
ul *p = memory_management_struct.bmp + (j >> 6);
ul shift = j % 64;
ul tmp_num = ((1UL << num) - 1);
for (ul k = shift; k < 64; ++k)
{
// 寻找连续num个空页
if (!((k ? ((*p >> k) | (*(p + 1) << (64 - k))) : *p) & tmp_num))
{
ul start_page_num = j + k - shift; // 计算得到要开始获取的内存页的页号
for (ul l = 0; l < num; ++l)
{
struct Page *x = memory_management_struct.pages_struct + start_page_num + l;
// 分配页面,手动配置属性及计数器
// 置位bmp
*(memory_management_struct.bmp + ((x->addr_phys >> PAGE_2M_SHIFT) >> 6)) |= (1UL << (x->addr_phys >> PAGE_2M_SHIFT) % 64);
++z->count_pages_using;
--z->count_pages_free;
x->attr = attr;
}
// 成功分配了页面,返回第一个页面的指针
// printk("start page num=%d\n",start_page_num);
return (struct Page *)(memory_management_struct.pages_struct + start_page_num);
}
}
}
}
return NULL;
}
/**
* @brief 清除页面的引用计数, 计数为0时清空除页表已映射以外的所有属性
*
* @param p 物理页结构体
* @return unsigned long
*/
unsigned long page_clean(struct Page *p)
{
--p->ref_counts;
--p->zone->total_pages_link;
// 若引用计数为空,则清空除PAGE_PGT_MAPPED以外的所有属性
if (!p->ref_counts)
{
p->attr &= PAGE_PGT_MAPPED;
}
return 0;
}
/**
* @brief Get the page's attr
*
* @param page 内存页结构体
* @return ul 属性
*/
ul get_page_attr(struct Page *page)
{
if (page == NULL)
{
kBUG("get_page_attr(): page == NULL");
return EPAGE_NULL;
}
else
return page->attr;
}
/**
* @brief Set the page's attr
*
* @param page 内存页结构体
* @param flags 属性
* @return ul 错误码
*/
ul set_page_attr(struct Page *page, ul flags)
{
if (page == NULL)
{
kBUG("get_page_attr(): page == NULL");
return EPAGE_NULL;
}
else
{
page->attr = flags;
return 0;
}
}
/**
* @brief 释放连续number个内存页
*
* @param page 第一个要被释放的页面的结构体
* @param number 要释放的内存页数量 number<64
*/
void free_pages(struct Page *page, int number)
{
if (page == NULL)
{
kerror("free_pages() page is invalid.");
return;
}
if (number >= 64 || number <= 0)
{
kerror("free_pages(): number %d is invalid.", number);
return;
}
ul page_num;
for (int i = 0; i < number; ++i, ++page)
{
page_num = page->addr_phys >> PAGE_2M_SHIFT;
// 复位bmp
*(memory_management_struct.bmp + (page_num >> 6)) &= ~(1UL << (page_num % 64));
// 更新计数器
--page->zone->count_pages_using;
++page->zone->count_pages_free;
page->attr = 0;
}
return;
}
/**
* @brief 重新初始化页表的函数
* 将0~4GB的物理页映射到线性地址空间
*/
void page_table_init()
{
kinfo("Re-Initializing page table...");
global_CR3 = get_CR3();
/*
// 由于CR3寄存器的[11..0]位是PCID标志位,因此将低12位置0后,就是PML4页表的基地址
ul *pml4_addr = (ul *)((ul)phys_2_virt((ul)global_CR3 & (~0xfffUL)));
kdebug("PML4 addr=%#018lx *pml4=%#018lx", pml4_addr, *pml4_addr);
ul *pdpt_addr = phys_2_virt(*pml4_addr & (~0xfffUL));
kdebug("pdpt addr=%#018lx *pdpt=%#018lx", pdpt_addr, *pdpt_addr);
ul *pd_addr = phys_2_virt(*pdpt_addr & (~0xfffUL));
kdebug("pd addr=%#018lx *pd=%#018lx", pd_addr, *pd_addr);
*/
ul *tmp_addr;
for (int i = 0; i < memory_management_struct.count_zones; ++i)
{
struct Zone *z = memory_management_struct.zones_struct + i;
struct Page *p = z->pages_group;
if (i == ZONE_UNMAPPED_INDEX)
break;
for (int j = 0; j < z->count_pages; ++j)
{
mm_map_phys_addr((ul)phys_2_virt(p->addr_phys), p->addr_phys, PAGE_2M_SIZE, PAGE_KERNEL_PAGE);
/*
// 计算出PML4页表中的页表项的地址
tmp_addr = (ul *)((ul)pml4_addr + ((((ul)phys_2_virt(p->addr_phys)) >> PAGE_GDT_SHIFT) & 0x1ff) * 8);
// 说明该页还没有分配pdpt页表,使用kmalloc分配一个
if (*tmp_addr = 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
set_pml4t(tmp_addr, mk_pml4t(virt_2_phys(virt_addr), PAGE_KERNEL_PGT));
}
// 计算出pdpt页表的页表项的地址
tmp_addr = (ul *)((ul)(phys_2_virt(*tmp_addr & (~0xfffUL))) + ((((ul)phys_2_virt(p->addr_phys)) >> PAGE_1G_SHIFT) & 0x1ff) * 8);
// 说明该页还没有分配pd页表,使用kmalloc分配一个
if (*tmp_addr = 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
set_pdpt(tmp_addr, mk_pdpt(virt_2_phys(virt_addr), PAGE_KERNEL_DIR));
}
// 计算出pd页表的页表项的地址
tmp_addr = (ul *)((ul)(phys_2_virt(*tmp_addr & (~0xfffUL))) + ((((ul)phys_2_virt(p->addr_phys)) >> PAGE_2M_SHIFT) & 0x1ff) * 8);
// 填入pd页表的页表项,映射2MB物理页
set_pdt(tmp_addr, mk_pdt(virt_2_phys(p->addr_phys), PAGE_KERNEL_PAGE));
*/
// 测试
if (j % 50 == 0)
kdebug("pd_addr=%#018lx, *pd_addr=%#018lx", tmp_addr, *tmp_addr);
}
}
flush_tlb();
kinfo("Page table Initialized.");
}
/**
* @brief VBE帧缓存区的地址重新映射
* 将帧缓存区映射到地址0xffff800003000000处
*/
void init_frame_buffer()
{
kinfo("Re-mapping VBE frame buffer...");
global_CR3 = get_CR3();
ul fb_virt_addr = SPECIAL_MEMOEY_MAPPING_VIRT_ADDR_BASE + FRAME_BUFFER_MAPPING_OFFSET;
ul fb_phys_addr = get_VBE_FB_phys_addr();
// 计算帧缓冲区的线性地址对应的pml4页表项的地址
ul *tmp = phys_2_virt((ul *)((ul)global_CR3 & (~0xfffUL)) + ((fb_virt_addr >> PAGE_GDT_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pml4t(tmp, mk_pml4t(virt_2_phys(virt_addr), PAGE_KERNEL_PGT));
}
tmp = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + ((fb_virt_addr >> PAGE_1G_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pdpt(tmp, mk_pdpt(virt_2_phys(virt_addr), PAGE_KERNEL_DIR));
}
ul vbe_fb_length = get_VBE_FB_length();
ul *tmp1;
// 初始化2M物理页
for (ul i = 0; i < (vbe_fb_length << 2); i += PAGE_2M_SIZE)
{
// 计算当前2M物理页对应的pdt的页表项的物理地址
tmp1 = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + (((ul)(fb_virt_addr + i) >> PAGE_2M_SHIFT) & 0x1ff));
// 页面写穿,禁止缓存
set_pdt(tmp1, mk_pdt((ul)fb_phys_addr + i, PAGE_KERNEL_PAGE | PAGE_PWT | PAGE_PCD));
}
set_pos_VBE_FB_addr((uint *)fb_virt_addr);
flush_tlb();
kinfo("VBE frame buffer successfully Re-mapped!");
}
/**
* @brief 将物理地址映射到页表的函数
*
* @param virt_addr_start 要映射到的虚拟地址的起始位置
* @param phys_addr_start 物理地址的起始位置
* @param length 要映射的区域的长度(字节)
*/
void mm_map_phys_addr(ul virt_addr_start, ul phys_addr_start, ul length, ul flags)
{
global_CR3 = get_CR3();
// 计算线性地址对应的pml4页表项的地址
ul *tmp = phys_2_virt((ul *)((ul)global_CR3 & (~0xfffUL)) + ((virt_addr_start >> PAGE_GDT_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pml4t(tmp, mk_pml4t(virt_2_phys(virt_addr), PAGE_KERNEL_PGT));
}
tmp = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + ((virt_addr_start >> PAGE_1G_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pdpt(tmp, mk_pdpt(virt_2_phys(virt_addr), PAGE_KERNEL_DIR));
}
ul *tmp1;
// 初始化2M物理页
for (ul i = 0; i < (length); i += PAGE_2M_SIZE)
{
// 计算当前2M物理页对应的pdt的页表项的物理地址
tmp1 = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + (((ul)(virt_addr_start + i) >> PAGE_2M_SHIFT) & 0x1ff));
// 页面写穿,禁止缓存
set_pdt(tmp1, mk_pdt((ul)phys_addr_start + i, flags));
}
flush_tlb();
}
void mm_map_phys_addr_user(ul virt_addr_start, ul phys_addr_start, ul length, ul flags)
{
global_CR3 = get_CR3();
// 计算线性地址对应的pml4页表项的地址
ul *tmp = phys_2_virt((ul *)((ul)global_CR3 & (~0xfffUL)) + ((virt_addr_start >> PAGE_GDT_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pml4t(tmp, mk_pml4t(virt_2_phys(virt_addr), PAGE_USER_PGT));
}
else
kdebug("*tmp != 0!!! \t tmp = %#018lx\t *tmp = %#018lx", tmp, *tmp);
tmp = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + ((virt_addr_start >> PAGE_1G_SHIFT) & 0x1ff));
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pdpt(tmp, mk_pdpt(virt_2_phys(virt_addr), PAGE_USER_DIR));
}
else
kdebug("*tmp != 0!!! \t tmp = %#018lx\t *tmp = %#018lx", tmp, *tmp);
ul *tmp1;
// 初始化2M物理页
for (ul i = 0; i < (length); i += PAGE_2M_SIZE)
{
// 计算当前2M物理页对应的pdt的页表项的物理地址
tmp1 = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + (((ul)(virt_addr_start + i) >> PAGE_2M_SHIFT) & 0x1ff));
// 页面写穿,禁止缓存
set_pdt(tmp1, mk_pdt((ul)phys_addr_start + i, flags | PAGE_USER_PAGE));
}
flush_tlb();
}
/**
* @brief 将将物理地址填写到进程的页表的函数
*
* @param proc_page_table_addr 页表的基地址
* @param is_phys 页表的基地址是否为物理地址
* @param virt_addr_start 要映射到的虚拟地址的起始位置
* @param phys_addr_start 物理地址的起始位置
* @param length 要映射的区域的长度(字节)
* @param user 用户态是否可访问
*/
void mm_map_proc_page_table(ul proc_page_table_addr, bool is_phys, ul virt_addr_start, ul phys_addr_start, ul length, ul flags, bool user)
{
// kdebug("proc_page_table_addr=%#018lx", proc_page_table_addr);
// 计算线性地址对应的pml4页表项的地址
ul *tmp;
if (is_phys)
tmp = phys_2_virt((ul *)((ul)proc_page_table_addr & (~0xfffUL)) + ((virt_addr_start >> PAGE_GDT_SHIFT) & 0x1ff));
else
tmp = (ul *)((ul)proc_page_table_addr & (~0xfffUL)) + ((virt_addr_start >> PAGE_GDT_SHIFT) & 0x1ff);
// kdebug("tmp = %#018lx", tmp);
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pml4t(tmp, mk_pml4t(virt_2_phys(virt_addr), (user ? PAGE_USER_PGT : PAGE_KERNEL_PGT)));
}
// kdebug("*tmp = %#018lx", *tmp);
if (is_phys)
tmp = phys_2_virt((ul *)(*tmp & (~0xfffUL)) + ((virt_addr_start >> PAGE_1G_SHIFT) & 0x1ff));
else
tmp = (ul *)(*tmp & (~0xfffUL)) + ((virt_addr_start >> PAGE_1G_SHIFT) & 0x1ff);
if (*tmp == 0)
{
ul *virt_addr = kmalloc(PAGE_4K_SIZE, 0);
memset(virt_addr, 0, PAGE_4K_SIZE);
set_pdpt(tmp, mk_pdpt(virt_2_phys(virt_addr), (user ? PAGE_USER_DIR : PAGE_KERNEL_DIR)));
}
ul *tmp1;
// 初始化2M物理页
for (ul i = 0; i < (length); i += PAGE_2M_SIZE)
{
// 计算当前2M物理页对应的pdt的页表项的物理地址
if (is_phys)
tmp1 = phys_2_virt(((ul *)(*tmp & (~0xfffUL)) + (((ul)(virt_addr_start + i) >> PAGE_2M_SHIFT) & 0x1ff)));
else
tmp1 = ((ul *)(*tmp & (~0xfffUL)) + (((ul)(virt_addr_start + i) >> PAGE_2M_SHIFT) & 0x1ff));
// 页面写穿,禁止缓存
set_pdt(tmp1, mk_pdt((ul)phys_addr_start + i, flags | (user ? PAGE_USER_PAGE : PAGE_KERNEL_PAGE)));
}
flush_tlb();
}
/**
* @brief 调整堆区域的大小(暂时只能增加堆区域)
*
* @todo 缩小堆区域
* @param old_brk_end_addr 原本的堆内存区域的结束地址
* @param offset 新的地址相对于原地址的偏移量
* @return uint64_t
*/
uint64_t mm_do_brk(uint64_t old_brk_end_addr, int64_t offset)
{
// 暂不支持缩小堆内存
if (offset < 0)
return old_brk_end_addr;
uint64_t end_addr = old_brk_end_addr + offset;
for (uint64_t i = old_brk_end_addr; i < end_addr; i += PAGE_2M_SIZE)
{
kdebug("map [%d]", i);
mm_map_proc_page_table((uint64_t)current_pcb->mm->pgd, true, i, alloc_pages(ZONE_NORMAL, 1, PAGE_PGT_MAPPED)->addr_phys, PAGE_2M_SIZE, PAGE_USER_PAGE, true);
}
current_pcb->mm->brk_end = end_addr;
return end_addr;
}