转载linux内核笔记之进程地址空间
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进程的地址空间由允许进程使用的全部线性地址组成,在32位系统中为0~3GB,每个进程看到的线性地址集合是不同的。
内核通过线性区的资源(数据结构)来表示线性地址区间,线性区是由起始线性地址,长度和一些访问权限来描述的。线性区的大小为页框的整数倍,起始地址为4096的整数倍。
下图展示了x86 Linux 进程的地址空间组织结构:
- 正文段 .text ,这是CPU执行的机器指令部分。通常正文段是共享的,而且是只读的,以防止程序修改其自身的指令。
- 数据段 .data。数据段包含了程序中需要明确赋初值的变量。
- 非初始化数据段 bss。bss 起始于 IBM 704汇编语言中的 Block Storage Start 指令的首字母缩写,并且沿用至今。
线性区描述符
进程地址空间中的堆、栈等,就是一个线性区,线性区的结构类型为 struct vm_area_struct
:
299structvm_area_struct {
300/* The first cache line has the info for VMA tree walking. */
301
302unsignedlongvm_start;/* Our start address within vm_mm. */
303unsignedlongvm_end;/* The first byte after our end address
304 within vm_mm. */
305
306/* linked list of VM areas per task, sorted by address */
307structvm_area_struct *vm_next, *vm_prev;
308
309structrb_node vm_rb;
310
311/*
312 * Largest free memory gap in bytes to the left of this VMA.
313 * Either between this VMA and vma->vm_prev, or between one of the
314 * VMAs below us in the VMA rbtree and its ->vm_prev. This helps
315 * get_unmapped_area find a free area of the right size.
316 */
317unsignedlongrb_subtree_gap;
318
319/* Second cache line starts here. */
320
321structmm_struct *vm_mm;/* The address space we belong to. */
322pgprot_tvm_page_prot;/* Access permissions of this VMA. */
323unsignedlongvm_flags;/* Flags, see mm.h. */
324
325/*
326 * For areas with an address space and backing store,
327 * linkage into the address_space->i_mmap interval tree.
328 */
329struct{
330structrb_node rb;
331unsignedlongrb_subtree_last;
332} shared;
333
334/*
335 * A file‘s MAP_PRIVATE vma can be in both i_mmap tree and anon_vma
336 * list, after a COW of one of the file pages. A MAP_SHARED vma
337 * can only be in the i_mmap tree. An anonymous MAP_PRIVATE, stack
338 * or brk vma (with NULL file) can only be in an anon_vma list.
339 */
340structlist_head anon_vma_chain;/* Serialized by mmap_sem &
341 * page_table_lock */
342structanon_vma *anon_vma;/* Serialized by page_table_lock */
343
344/* Function pointers to deal with this struct. */
345conststructvm_operations_struct *vm_ops;
346
347/* Information about our backing store: */
348unsignedlongvm_pgoff;/* Offset (within vm_file) in PAGE_SIZE
349 units */
350structfile * vm_file;/* File we map to (can be NULL). */
351void* vm_private_data;/* was vm_pte (shared mem) */
352
353#ifndefCONFIG_MMU
354structvm_region *vm_region;/* NOMMU mapping region */
355#endif
356#ifdefCONFIG_NUMA
357structmempolicy *vm_policy;/* NUMA policy for the VMA */
358#endif
359structvm_userfaultfd_ctx vm_userfaultfd_ctx;
360};
vm_start
:线性区的起始地址vm_end
:线性区的结束地址vm_rb
:作为红黑树中的一个节点使用vm_mm
:指向所在的内存描述符vm_page_prot
:线性区中页框的访问权限vm_flags
:线性区的标志vm_next, vm_prev
:分别指向线性区链表中的下一个和上一个线性区描述符- … …
内存描述符
内存描述符中包含了与进程地址空间有关的所有信息,结构类型为 struct mm_struct
:
395structmm_struct {
396structvm_area_struct *mmap;/* list of VMAs */
397structrb_root mm_rb;
398u32 vmacache_seqnum;/* per-thread vmacache */
399#ifdefCONFIG_MMU
400unsignedlong(*get_unmapped_area)(structfile *filp,
401unsignedlongaddr,unsignedlonglen,
402unsignedlongpgoff,unsignedlongflags);
403#endif
404unsignedlongmmap_base;/* base of mmap area */
405unsignedlongmmap_legacy_base;/* base of mmap area in bottom-up allocations */
406unsignedlongtask_size;/* size of task vm space */
407unsignedlonghighest_vm_end;/* highest vma end address */
408pgd_t* pgd;
409atomic_tmm_users;/* How many users with user space? */
410atomic_tmm_count;/* How many references to "struct mm_struct" (users count as 1) */
411atomic_long_tnr_ptes;/* PTE page table pages */
412#ifCONFIG_PGTABLE_LEVELS > 2
413atomic_long_tnr_pmds;/* PMD page table pages */
414#endif
415intmap_count;/* number of VMAs */
416
417spinlock_tpage_table_lock;/* Protects page tables and some counters */
418structrw_semaphore mmap_sem;
419
420structlist_head mmlist;/* List of maybe swapped mm‘s. These are globally strung
421 * together off init_mm.mmlist, and are protected
422 * by mmlist_lock
423 */
424
425
426unsignedlonghiwater_rss;/* High-watermark of RSS usage */
427unsignedlonghiwater_vm;/* High-water virtual memory usage */
428
429unsignedlongtotal_vm;/* Total pages mapped */
430unsignedlonglocked_vm;/* Pages that have PG_mlocked set */
431unsignedlongpinned_vm;/* Refcount permanently increased */
432unsignedlongdata_vm;/* VM_WRITE & ~VM_SHARED & ~VM_STACK */
433unsignedlongexec_vm;/* VM_EXEC & ~VM_WRITE & ~VM_STACK */
434unsignedlongstack_vm;/* VM_STACK */
435unsignedlongdef_flags;
436unsignedlongstart_code, end_code, start_data, end_data;
437unsignedlongstart_brk, brk, start_stack;
438unsignedlongarg_start, arg_end, env_start, env_end;
439
440unsignedlongsaved_auxv[AT_VECTOR_SIZE];/* for /proc/PID/auxv */
441
442/*
443 * Special counters, in some configurations protected by the
444 * page_table_lock, in other configurations by being atomic.
445 */
446structmm_rss_stat rss_stat;
447
448structlinux_binfmt *binfmt;
449
450cpumask_var_tcpu_vm_mask_var;
451
452/* Architecture-specific MM context */
453mm_context_tcontext;
454
455unsignedlongflags;/* Must use atomic bitops to access the bits */
456
457structcore_state *core_state;/* coredumping support */
458#ifdefCONFIG_AIO
459spinlock_tioctx_lock;
460structkioctx_table__rcu *ioctx_table;
461#endif
462#ifdefCONFIG_MEMCG
463/*
464 * "owner" points to a task that is regarded as the canonical
465 * user/owner of this mm. All of the following must be true in
466 * order for it to be changed:
467 *
468 * current == mm->owner
469 * current->mm != mm
470 * new_owner->mm == mm
471 * new_owner->alloc_lock is held
472 */
473structtask_struct__rcu *owner;
474#endif
475
476/* store ref to file /proc/<pid>/exe symlink points to */
477structfile__rcu *exe_file;
478#ifdefCONFIG_MMU_NOTIFIER
479structmmu_notifier_mm *mmu_notifier_mm;
480#endif
481#ifdefined(CONFIG_TRANSPARENT_HUGEPAGE) && !USE_SPLIT_PMD_PTLOCKS
482pgtable_tpmd_huge_pte;/* protected by page_table_lock */
483#endif
484#ifdefCONFIG_CPUMASK_OFFSTACK
485structcpumask cpumask_allocation;
486#endif
487#ifdefCONFIG_NUMA_BALANCING
488/*
489 * numa_next_scan is the next time that the PTEs will be marked
490 * pte_numa. NUMA hinting faults will gather statistics and migrate
491 * pages to new nodes if necessary.
492 */
493unsignedlongnuma_next_scan;
494
495/* Restart point for scanning and setting pte_numa */
496unsignedlongnuma_scan_offset;
497
498/* numa_scan_seq prevents two threads setting pte_numa */
499intnuma_scan_seq;
500#endif
501#ifdefined(CONFIG_NUMA_BALANCING) || defined(CONFIG_COMPACTION)
502/*
503 * An operation with batched TLB flushing is going on. Anything that
504 * can move process memory needs to flush the TLB when moving a
505 * PROT_NONE or PROT_NUMA mapped page.
506 */
507booltlb_flush_pending;
508#endif
509structuprobes_state uprobes_state;
510#ifdefCONFIG_X86_INTEL_MPX
511/* address of the bounds directory */
512void__user *bd_addr;
513#endif
514#ifdefCONFIG_HUGETLB_PAGE
515atomic_long_thugetlb_usage;
516#endif
517#ifdefCONFIG_MMU
518structwork_struct async_put_work;
519#endif
520};
mmap
:线性区描述符链表中的头元素mm_rb
:线性区描述符所在红黑树的根get_unmapped_area
:在进程地址空间中搜索有效线性地址区间的方法mmap_base
:标识第一个分配的匿名线性区或文件内存映射的线性地址task_size
:进程地址空间的大小highest_vm_end
:能使用的最高线性地址pgd
:指向页全局目录mm_users
:次使用计数器mm_count
:主使用计数器nr_ptes
:页表项数量map_count
:线性区数量mmlist
:链接内存描述符链表中的相邻描述符- … …
线性区相关
进程所拥有的所有线性区通过一个简单地链表链接在一起,链表中的线性区按内存地址升序排列。内核通过进程的内存描述符的 mmap
字段找到线性区链表的第一个线性区。
内核频繁执行的一个操作就是查找包含指定线性地址的的线性区,虽然可以通过遍历链表来查找,但是当线性区数量很庞大时,例如面向对象的数据库,此时的效率会变得非常低效。
Linux2.6把内存描述符存放在红黑树的数据结构中,当插入或删除一个线性区描述符时,内核通过红黑树搜索前后元素,并用搜索结果快速更新链表而不用扫描链表。一般来说,红黑树用来确定含有指定地址的线性区,而链表通常在扫描整个线性区集合的时候使用。
内存描述符相关
进程、内存描述符、线性区描述符、线性地址之间的关系如下:
所有内存描述符存放在一个双向链表中,每个描述符中的 mmlist
字段存放链表中相邻元素的地址。链表的第一个元素是 init_mm
的 mmlist
字段, init_mm
是初始化阶段进程0所使用的内存描述符。
mm_users
字段存放共享 mm_struct
数据结构的轻量级进程(线程)的个数, mm_count
字段是内存描述符的主使用器, mm_users
的所有使用者在 mm_count
中只占有一个单位,也就是说多个线程只使得 mm_count
的值增加了1。假如一个内核线程使用了该内存描述符,则 mm_count
的值增加1。
对于内核线程来说,因为仅运行在内核态,所以永远不会访问低于 TASK_SIZE
(3GB)的地址。每个进程的描述符中包含了两种内存描述符指针: mm
和 active_mm
。对于普通进程,两者都指向进程的内存描述符,而内核线程的 active_mm
指向进程的内存描述符, mm
为null。(PS:内核线程使用的全局页表存放在主内存描述符的pgd字段中)
总结
本文简单地描述了进程地址空间中的一些主要数据结构以及之间的联系,关于源码以及更多细节内容在日后整理。
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