目录
2.1页表建立函数__create_page_tables.6
2.1.1pgtbl x25,x26,
x24分析... 7
2.1.3create_pgd_entry/create_block_map宏解释...8
3.1TLB打开之前,内存物理内存大小如何通知OS内核?...12
3.3ARMv8三级页表情况下,全部把页表放到内存中是放不下的(1G大小),是不是部分放到硬盘中?...16
1 ARMv8存储管理
1.1 Aarch64 Linux中的内存布局
ARMv8架构可以支持48位虚拟地址,并配置成4级页表(4K页),或者3级页表(64K页)。而本Linux系统只使用39位虚拟地址(512G内核,512G用户),配置成3级页表(4K页)或者2级页表(64K页)
用户空间的地址63:39位都置零,内核空间地址63:39都置一,虚拟地址的第63位可以用来选择TTBRx。swapper_pg_dir只包含内核全局映射,用户的pgd包含用户(非全局)映射。swapper_pg_dir地址在TTBR1中,不会写入TTBR0中。
AArch64Linux内存布局:
Start End Size Use
--------------------------------------------------------------------------------------------------
0000000000000000 0000007fffffffff 512GB user
ffffff8000000000 ffffffbbfffcffff ~240GB vmalloc
ffffffbbfffd0000 ffffffbcfffdffff 64KB [guardpage]
ffffffbbfffe0000 ffffffbcfffeffff 64KB PCII/O space
ffffffbbffff0000 ffffffbcffffffff 64KB [guard page]
ffffffbc00000000 ffffffbdffffffff 8GB vmemmap
ffffffbe00000000 ffffffbffbffffff ~8GB [guard,future vmmemap]
ffffffbffc000000 ffffffbfffffffff 64MB modules
ffffffc000000000 ffffffffffffffff 256GB memory
1.2 AArch64的虚拟地址格式
1.2.1 4K页时的虚拟地址
1.2.2 64K页时的虚拟地址
2 head.S页表建立过程分析
2.1 页表建立函数__create_page_tables
该函数用于在内核启动时,为FDT(设备树)、内核镜像创建启动所必须的页表。等内核正常运行后,还需运行create_mapping为所有的物理内存创建页表,这将覆盖__create_page_tables所创建的页表。
内核开始运行时创建页表源文件:arm64/kernel/head.Sline345
/*
* Setup the initial page tables. We only setup the barest amount which is
* required to get the kernel running. The following sections are required:
* -identity mapping to enable the MMU (low address, TTBR0)
* -first few MB of the kernel linear mapping to jump to once the MMU has
* been enabled, including the FDT blob (TTBR1)
*/
__create_page_tables:
pgtbl x25, x26,x24 //idmap_pg_dir and swapper_pg_dir addresses
/*
* 清空新建的两个页表TTBR0,TTBR1
*/
mov x0,x25
add x6,x26, #SWAPPER_DIR_SIZE
1: stp xzr,xzr, [x0], #16
stp xzr,xzr, [x0], #16
stp xzr,xzr, [x0], #16
stp xzr,xzr, [x0], #16
cmp x0,x6
b.lo 1b
ldr x7,=MM_MMUFLAGS
/*
* Create the identity mapping.
*/
add x0, x25,#PAGE_SIZE // sectiontable address
adr x3, __turn_mmu_on // virtual/physical address
create_pgd_entry x25, x0, x3, x5, x6 //展开见1.1.3
create_block_map x0, x7, x3, x5, x5, idmap=1
/*
* Map the kernel image (starting withPHYS_OFFSET).
*/
add x0,x26, #PAGE_SIZE //section table address
mov x5,#PAGE_OFFSET
create_pgd_entry x26, x0, x5, x3, x6
ldr x6,=KERNEL_END - 1
mov x3,x24 // physoffset
create_block_map x0, x7, x3, x5, x6
/*
* Map the FDT blob (maximum 2MB; must bewithin 512MB of
* PHYS_OFFSET).
*/
mov x3,x21 // FDTphys address
and x3,x3, #~((1 << 21) - 1) // 2MBaligned
mov x6,#PAGE_OFFSET
sub x5,x3, x24 //subtract PHYS_OFFSET
tst x5,#~((1 << 29) - 1) //within 512MB?
csel x21,xzr, x21, ne // zero the FDTpointer
b.ne 1f
add x5,x5, x6 // __va(FDTblob)
add x6,x5, #1 << 21 // 2MB forthe FDT blob
sub x6,x6, #1 //inclusive range
create_block_map x0, x7, x3, x5, x6
1:
ret
ENDPROC(__create_page_tables)
2.1.1 pgtbl x25, x26, x24分析
pgtbl是个宏,定义如下:
arm64/kernel/head.S line55
.macro pgtbl,ttb0, ttb1, phys
add \ttb1,\phys, #TEXT_OFFSET - SWAPPER_DIR_SIZE
sub \ttb0,\ttb1, #IDMAP_DIR_SIZE
.endm
pgtbl x25,x26, x24 //展开后如下
add x26,x24, #TEXT_OFFSET -SWAPPER_DIR_SIZE
sub x25,x26,#IDMAP_DIR_SIZE
其中各变量定义如下:
#defineSWAPPER_DIR_SIZE (3 * PAGE_SIZE)
#defineIDMAP_DIR_SIZE (2 *PAGE_SIZE)
说明:
1、关于TTBR0、TTBR1的介绍见ARM ARM 手册的Page B4-1708
2、x25中存TTBR0(TTBR0 holds the base address of translation table 0)的地址;
3、X26存TTBR1(TTBR1 holds the base address of translation table 1)地址;
4、X24 存PHYS_OFFSET,/* PHYS_OFFSET- the physical address of the start of memory. */
#definePHYS_OFFSET ({ memstart_addr; })
5、TEXT_OFFSET是Bootloader启动时传进来的参数,是内核Image加载时相对于RAM起始地址的偏移量
6、PAGE_OFFSEST:the virtual address of the start of the kernel image.
图1 pgtbl宏分析
2.1.2 MM_MMUFLAGS解释
在文件arm64/kernel/head.S line71:
/*
* Initial memory map attributes.
*/
#ifndefCONFIG_SMP
#definePTE_FLAGS PTE_TYPE_PAGE | PTE_AF
#definePMD_FLAGS PMD_TYPE_SECT | PMD_SECT_AF
#else
#definePTE_FLAGS PTE_TYPE_PAGE | PTE_AF |PTE_SHARED
#definePMD_FLAGS PMD_TYPE_SECT | PMD_SECT_AF| PMD_SECT_S
#endif
#ifdefCONFIG_ARM64_64K_PAGES
#defineMM_MMUFLAGS PTE_ATTRINDX(MT_NORMAL) |PTE_FLAGS
#defineIO_MMUFLAGS PTE_ATTRINDX(MT_DEVICE_nGnRE)| PTE_XN | PTE_FLAGS
#else
#defineMM_MMUFLAGS PMD_ATTRINDX(MT_NORMAL) |PMD_FLAGS
#defineIO_MMUFLAGS PMD_ATTRINDX(MT_DEVICE_nGnRE)| PMD_SECT_XN | PMD_FLAGS
#endif
根据以上宏定义能明确,MM_MMUFLAGS就是根据你编译内核时选定的页大小(64K or 4K),设置MMU。
2.1.3 create_pgd_entry/create_block_map宏解释
1、create_pgd_entry
/*
* Macro to populate the PGD for thecorresponding block entry in the next
* level (tbl) for the given virtual address.
*
* Preserves: pgd,tbl, virt
* Corrupts: tmp1,tmp2
*/
.macro create_pgd_entry,pgd, tbl, virt, tmp1, tmp2
lsr \tmp1,\virt, #PGDIR_SHIFT
and \tmp1,\tmp1, #PTRS_PER_PGD - 1 // PGD index
orr \tmp2,\tbl, #3 // PGD entrytable type
str \tmp2,[\pgd, \tmp1, lsl #3]
.endm
根据以上定义,create_pgd_entry x25, x0, x3, x5, x6展开后如下:
lsr x5, x3,# PGDIR_SHIFT //X3中存放的是__turn_mmu_on的地址,右移PGDIR_SHIFT(30)位
and x5, x5, #PTRS_PER_PGD – 1//将<38:30>置位
orr x6, x0, #3 //x0存放PGD entry(即下级页表地址),低三位用于表项的有效位
str x6, [ x25, x5, lsl #3] //将entry存放到TTBR0(x25)中偏移为x5左移3位(乘8,因为entry为8byte)的位置处。
为了便于理解,如下图所示:
图2 4K页面时48位虚拟地址组成
注意:上图中虚拟地址对应的表格名称是:
PGD:全局描述符表
PUD:折合到PGD中,Linux中不使用
PMD:页表中间描述符表
PTE:页表
Linux内核只使用了39位虚拟地址
图3 64位页表项格式
图4
同理,create_pgd_entry x26, x0, x5, x3, x6展开后如下:
lsr x3, x5,#PGDIR_SHIFT //X5中存放的是PAGE_OFFSET= 0xffffffc000000000,右移PGDIR_SHIFT位存入X3
and x3, x3,#PTRS_PER_PGD – 1//将<38:30>置位
orr x6, x0, #3 //x0存放TTBR1指向的页的下一页,低三位用于表项的有效位,存入x6
str x6, [ x26, x3,lsl #3] //将entry存放到TTBR0(x25)中偏移为x5左移3位的位置处
以上内容就是,填写TTBR1指向的页表中偏移为x3*8(因为一个entry是8byte)的页表项,内容为x6(即图4中x0所指的位置)
2、create_block_map
/*
* Macro to populate block entries in the pagetable for the start..end
* virtual range (inclusive).
*
* Preserves: tbl,flags
* Corrupts: phys,start, end, pstate
*/
.macro create_block_map,tbl, flags, phys, start, end, idmap=0
lsr \phys,\phys, #BLOCK_SHIFT
.if \idmap
and \start,\phys, #PTRS_PER_PTE - 1 // table index
.else
lsr \start,\start, #BLOCK_SHIFT
and \start,\start, #PTRS_PER_PTE - 1 // table index
.endif
orr \phys,\flags, \phys, lsl #BLOCK_SHIFT //table entry
.ifnc \start,\end
lsr \end,\end, #BLOCK_SHIFT
and \end,\end, #PTRS_PER_PTE - 1 // tableend index
.endif
9999: str \phys,[\tbl, \start, lsl #3] // storethe entry
.ifnc \start,\end //ifnc:如果string1!=string2
add \start,\start, #1 // next entry
add \phys,\phys, #BLOCK_SIZE // next block
cmp \start,\end
b.ls 9999b
.endif
.endm
根据以上宏定义,create_block_map x0, x7, x3,x5, x5, idmap=1,翻译后如下:
lsr x3, x3, # BLOCK_SHIFT
and x5, x3 # PTRS_PER_PTE – 1
orr x3, x7, x3, lsl # BLOCK_SHIFT
9999:
str x3, [x0, x5, lsl #3]
同理,create_block_map x0, x7, x3, x5,x6展开后如下:
lsr x3,x3, #BLOCK_SHIFT
lsr x5,x5, #BLOCK_SHIFT
and x5,x5, #PTRS_PER_PTE - 1 // table index
orr x3,x7, x3, lsl #BLOCK_SHIFT // tableentry
lsr x6,x6, #BLOCK_SHIFT
and x6,x6, #PTRS_PER_PTE - 1 // table endindex
9999: str x3,[x0, x5, lsl #3] // store the entry
add x5,x5, #1 // next entry
add x3,x3, #BLOCK_SIZE // next block
cmp x5, x6
b.ls 9999b
create_block_mapx0, x7, x3, x5, x6宏的作用就是创建内核镜像所有的映射关系
3 问题解答
3.1 TLB打开之前,内存物理内存大小如何通知OS内核?
Bootloader通过设备树(devicetree.dts文件)将物理内存起始地址及大小传给Linux 内核。物理内存的大小需要在bootloader即dts文件中写明。dts文件中内存声明如下:
memory {
device_type= "memory";
reg= <0x00000000 0x80000000>;
};
Reg字段:<地址 大小>
以上声明一段内存:从地址0x开始,大小为2G
3.2 PGD及PTE的填写过程
内核初始化时,会调用map_mem对所有内存建立页表,进行映射,函数执行流程是:
start_kernel()àsetup_arch()àpaging_init()àmap_mem()àcreate_mapping()
下面我们从map_mem()函数开始分析。
3.2.1 map_mem()
arm64/mm/mmu.cline254
staticvoid __init map_mem(void)
{
struct memblock_region *reg;
// 按照内存块进行映射,映射所有内存bank
for_each_memblock(memory, reg) {
phys_addr_t start = reg->base;
phys_addr_t end = start +reg->size;
if (start >= end) //如果end不大于start 则退出
break;
create_mapping(start,__phys_to_virt(start), end - start);//创建映射
}
}
3.2.2 create_mapping()
arm64/mm/mmu.cline 230
/*
* Create the page directory entries and anynecessary page tables for the
* mapping specified by 'md'.
*/
staticvoid __init create_mapping(phys_addr_t phys, unsigned long virt,
phys_addr_t size)
{
unsigned long addr, length, end, next;
pgd_t *pgd;
if (virt < VMALLOC_START) { //对虚拟地址进行检查
pr_warning("BUG: not creatingmapping for 0x%016llx at 0x%016lx - outside kernel range\n",
phys, virt);
return;
}
addr = virt & PAGE_MASK; // PAGE_MASK=(~(PAGE_SIZE-1)),将虚拟地址的低位偏移掩掉
//计算需要映射的内存长度,对齐到下一页的边界
length= PAGE_ALIGN(size + (virt & ~PAGE_MASK));
//一级数组中addr对应的段在init_mm->pgd的下标,即在内核的pgd中获得一个entry
pgd = pgd_offset_k(addr);
end = addr + length; //计算需要映射的结束地址
do {
next = pgd_addr_end(addr, end);//获得下一段开始地址
//申请并初始化一个段
//段码,虚拟地址,结束地址,物理地址,内存类型
alloc_init_pud(pgd,addr, next, phys);
phys += next - addr;//物理地址累加
} while (pgd++, addr = next, addr != end);
}
3.2.3 alloc_init_pud()
arm64/mm/mmu.cline213
staticvoid __init alloc_init_pud(pgd_t *pgd, unsigned long addr,
unsigned long end, unsigned long phys)
{
//由于Linux内核不使用pud,所以pud折如pgd,这里的pud=pgd
pud_t *pud = pud_offset(pgd, addr);
unsigned long next;
do {
next = pud_addr_end(addr, end);
alloc_init_pmd(pud, addr, next, phys);
phys += next - addr;
} while (pud++, addr = next, addr != end);
}
3.2.4 alloc_init_pmd()
arm64/mm/mmu.cline 187
staticvoid __init alloc_init_pmd(pud_t *pud, unsigned long addr,
unsigned long end, phys_addr_t phys)
{
pmd_t *pmd;
unsigned long next;
/*
*Check for initial section mappings in the pgd/pud and remove them.
*/
if (pud_none(*pud) || pud_bad(*pud)) {
pmd = early_alloc(PTRS_PER_PMD *sizeof(pmd_t));
pud_populate(&init_mm, pud,pmd);
}
pmd = pmd_offset(pud, addr);
do {
next = pmd_addr_end(addr, end);
/* try section mapping first */
//addr,end, phys都是段对齐,则直接进行段映射(大部分情况下应该是满足条件),否则需要进一步填写PTE。
//段大小在不同页大小情况下不同,在3级页表时,2M;在2级页表时,512M
if (((addr | next | phys) &~SECTION_MASK) == 0)
//将物理地址及一些段属性存放到pmd中
set_pmd(pmd, __pmd(phys |prot_sect_kernel));
else
alloc_init_pte(pmd, addr, next,__phys_to_pfn(phys));
phys += next - addr;
} while (pmd++, addr = next, addr != end);
}
3.2.5 set_pmd()
arm64/include/asmline 195
staticinline void set_pmd(pmd_t *pmdp, pmd_t pmd)
{
*pmdp = pmd;
dsb();//同步数据进RAM(由于有cache机制,所以数据操作的时候是先保存在cache中的,这里是强制将数据从cache中刷进RAM中)
}
3.2.6 alloc_init_pte()
arm64/mm/mmu.cline 169
staticvoid __init alloc_init_pte(pmd_t *pmd, unsigned long addr,
unsigned long end, unsigned long pfn)
{
pte_t *pte;
if (pmd_none(*pmd)) {
pte = early_alloc(PTRS_PER_PTE *sizeof(pte_t));
__pmd_populate(pmd, __pa(pte),PMD_TYPE_TABLE);
}
BUG_ON(pmd_bad(*pmd));
pte = pte_offset_kernel(pmd, addr);
do {
set_pte(pte,pfn_pte(pfn, PAGE_KERNEL_EXEC));
pfn++;
} while (pte++, addr += PAGE_SIZE, addr !=end);
}
3.2.7 set_pte()
arm64/include/asm/pgtable.hline 150
staticinline void set_pte(pte_t *ptep, pte_t pte)
{
*ptep = pte;
}
3.3 ARMv8三级页表情况下,全部把页表放到内存中是放不下的(1G大小),是不是部分放到硬盘中?
答:ARMv8 OS是根据内存大小建立页表的,例如当物理内存只有1G时,1G=230=218 *4K(页大小),即需要218个PTE,每个页表512个PTE,所以需要29个PT表,共需要29*4K=2M大小的页表(事实上还需要计算PGD和PMD,各4K)。
所以1G内存空间,需要2M大小页表;
2G——4M
100G——200M
512G——1G页表
相对内存大小来说,页表大小还是很小的。
注意:如果是64位机器,就不存在高端内存一说,因为地址空间很大很大,属于内核的空间也不止1G,在aarch64 linux中内核空间是512G,内核完全可以直接管理所有内存。