阅读 Linux 内核源码——共享内存

介绍

我看的是linux-4.2.3的源码。参考了《边干边学——Linux内核指导》(鬼畜的书名)第16章内容,他们用的是2.6.15的内核源码。

现在linux中可以使用共享内存的方式有两种

  1. POSIX的shm_open()/dev/shm/下打开一个文件,用mmap()映射到进程自己的内存地址

  2. System V的shmget()得到一个共享内存对象的id,用shmat()映射到进程自己的内存地址

POSIX的实现是基于tmpfs的,函数都写在libc里,没什么好说的,主要还是看System V的实现方式。在System V中共享内存属于IPC子系统。所谓ipc,就是InterProcess Communication即进程间通信的意思,System V比前面的Unix增加了3中进程间通信的方式,共享内存、消息队列、信号量,统称IPC。主要代码在以下文件中

  • ipc/shm.c

  • include/linux/shm.h

  • ipc/util.c

  • ipc/util.h

  • include/linux/ipc.h

同一块共享内存在内核中至少有3个标识符

  1. IPC对象id(IPC对象是保存IPC信息的数据结构)

  2. 进程虚拟内存中文件的inode,即每个进程中的共享内存也是以文件的方式存在的,但并不是显式的。可以通过某个vm_area_struct->vm_file->f_dentry->d_inode->i_ino表示

  3. IPC对象的key。如果在shmget()中传入同一个key可以获取到同一块共享内存。但由于key是用户指定的,可能重复,而且也很少程序写之前会约定一个key,所以这种方法不是很常用。通常System V这种共享内存的方式是用于有父子关系的进程的。或者用ftok()函数用路径名来生成一个key。

首先看一下在内核中表示一块共享内存的数据结构,在include/linux/shm.h
/* */是内核源码的注释,// 是我的注释

struct shmid_kernel /* private to the kernel */
{    
    struct kern_ipc_perm    shm_perm; // 权限,这个结构体中还有一些重要的内容,后面会提到
    struct file        *shm_file;        // 表示这块共享内存的内核文件,文件内容即共享内存的内容
    unsigned long        shm_nattch;   // 连接到这块共享内存的进程数
    unsigned long        shm_segsz;    // 大小,字节为单位
    time_t            shm_atim;         // 最后一次连接时间
    time_t            shm_dtim;         // 最后一次断开时间
    time_t            shm_ctim;         // 最后一次更改信息的时间
    pid_t            shm_cprid;        // 创建者进程id
    pid_t            shm_lprid;        // 最后操作者进程id
    struct user_struct    *mlock_user;

    /* The task created the shm object.  NULL if the task is dead. */
    struct task_struct    *shm_creator;
    struct list_head    shm_clist;    /* list by creator */
};

再看一下struct shmid_kernel中存储权限信息的shm_perm,在include/linux/ipc.h

/* used by in-kernel data structures */
struct kern_ipc_perm
{
    spinlock_t    lock;
    bool        deleted;
    int        id;           // IPC对象id
    key_t        key;      // IPC对象键值,即创建共享内存时用户指定的
    kuid_t        uid;      // IPC对象拥有者id
    kgid_t        gid;      // 组id
    kuid_t        cuid;     // 创建者id
    kgid_t        cgid;
    umode_t        mode; 
    unsigned long    seq;
    void        *security;
};

为啥有这样一个struct呢?因为这些权限、id、key是IPC对象都有的属性,所以比如表示semaphore的结构struct semid_kernel中也有一个这样的struct kern_ipc_perm。然后在传递IPC对象的时候,传的也是struct kern_ipc_perm的指针,再用container_of这样的宏获得外面的struct,这样就能用同一个函数操作3种IPC对象,达到较好的代码重用。

接下来我们看一下共享内存相关函数。首先它们都是系统调用,对应的用户API在libc里面,参数是相同的,只是libc中的API做了一些调用系统调用需要的日常工作(保护现场、恢复现场之类的),所以就直接看这个系统调用了。

声明在include/linux/syscalls.h

asmlinkage long sys_shmat(int shmid, char __user *shmaddr, int shmflg);
asmlinkage long sys_shmget(key_t key, size_t size, int flag);
asmlinkage long sys_shmdt(char __user *shmaddr);
asmlinkage long sys_shmctl(int shmid, int cmd, struct shmid_ds __user *buf);

定义在ipc/shm.c

shmget

SYSCALL_DEFINE3(shmget, key_t, key, size_t, size, int, shmflg)
{
    struct ipc_namespace *ns;
    static const struct ipc_ops shm_ops = {
        .getnew = newseg,
        .associate = shm_security,
        .more_checks = shm_more_checks,
    };
    struct ipc_params shm_params;

    ns = current->nsproxy->ipc_ns;

    shm_params.key = key;
    shm_params.flg = shmflg;
    shm_params.u.size = size;

    return ipcget(ns, &shm_ids(ns), &shm_ops, &shm_params);
}

首先看到这个函数定义可能会很奇怪,不过这个SYSCALL_DEFINE3的宏展开来最后形式肯定和.h文件中声明的一样,即还是long sys_shmget(key_t key, size_t size, int flag)这个宏是为了修一个bug,纯粹黑科技,这里不提它。

然后这里实际调用的函数是ipcget()。为了统一一个ipc的接口也是煞费苦心,共享内存、信号量、消息队列三种对象创建的时候都会调用这个函数,但其实创建的逻辑并不在这里。而在shm_ops中的三个函数里。

namespace

顺便提一下其中的current->nsproxy->ipc_ns。这个的类型是struct ipc_namespace。它是啥呢?我们知道,共享内存这些进程间通信的数据结构是全局的,但有时候需要把他们隔离开,即某一组进程并不知道另外的进程的共享内存,它们只希望在组内共用这些东西,这样就不会与其他进程冲突。于是就煞费苦心在内核中加了一个namespace。只要在clone()函数中加入CLONE_NEWIPC标志就能创建一个新的IPC namespace。

那么这个IPC namespace和我们的共享内存的数据结构有什么关系呢,可以看一下结构体

struct ipc_ids {
    int in_use;
    unsigned short seq;
    struct rw_semaphore rwsem;
    struct idr ipcs_idr;
    int next_id;
};

struct ipc_namespace {
    atomic_t    count;
    struct ipc_ids    ids[3];
    ...
};

比较重要的是其中的ids,它存的是所用IPC对象的id,其中共享内存都存在ids[2]中。而在ids[2]中真正负责管理数据的是ipcs_idr,它也是内核中一个煞费苦心弄出来的id管理机制,一个id可以对应任意唯一确定的对象。把它理解成一个数组就好。它们之间的关系大概如下图所示。

                                                        [0] struct kern_ipc_perm <==> struct shmid_kernel
struct ipc_namespace => struct ipc_ids => struct idr => [1] struct kern_ipc_perm <==> struct shmid_kernel
                                                        [2] struct kern_ipc_perm <==> struct shmid_kernel

回到shmget

好的,我们回头来看看shmget()究竟干了啥,首先看一下ipcget()

int ipcget(struct ipc_namespace *ns, struct ipc_ids *ids,
            const struct ipc_ops *ops, struct ipc_params *params)
{
    if (params->key == IPC_PRIVATE)
        return ipcget_new(ns, ids, ops, params);
    else
        return ipcget_public(ns, ids, ops, params);
}

如果传进来的参数是IPC_PRIVATE(这个宏的值是0)的话,无论是什么mode,都会创建一块新的共享内存。如果非0,则会去已有的共享内存中找有没有这个key的,有就返回,没有就新建。

首先看一下新建的函数newseg()

static int newseg(struct ipc_namespace *ns, struct ipc_params *params)
{
    key_t key = params->key;
    int shmflg = params->flg;
    size_t size = params->u.size;
    int error;
    struct shmid_kernel *shp;
    size_t numpages = (size + PAGE_SIZE - 1) >> PAGE_SHIFT;
    struct file *file;
    char name[13];
    int id;
    vm_flags_t acctflag = 0;

    if (size < SHMMIN || size > ns->shm_ctlmax)
        return -EINVAL;

    if (numpages << PAGE_SHIFT < size)
        return -ENOSPC;

    if (ns->shm_tot + numpages < ns->shm_tot ||
            ns->shm_tot + numpages > ns->shm_ctlall)
        return -ENOSPC;

    shp = ipc_rcu_alloc(sizeof(*shp));
    if (!shp)
        return -ENOMEM;

    shp->shm_perm.key = key;
    shp->shm_perm.mode = (shmflg & S_IRWXUGO);
    shp->mlock_user = NULL;

    shp->shm_perm.security = NULL;
    error = security_shm_alloc(shp);
    if (error) {
        ipc_rcu_putref(shp, ipc_rcu_free);
        return error;
    }

    sprintf(name, "SYSV%08x", key);
    if (shmflg & SHM_HUGETLB) {
        struct hstate *hs;
        size_t hugesize;

        hs = hstate_sizelog((shmflg >> SHM_HUGE_SHIFT) & SHM_HUGE_MASK);
        if (!hs) {
            error = -EINVAL;
            goto no_file;
        }
        hugesize = ALIGN(size, huge_page_size(hs));

        /* hugetlb_file_setup applies strict accounting */
        if (shmflg & SHM_NORESERVE)
            acctflag = VM_NORESERVE;
        file = hugetlb_file_setup(name, hugesize, acctflag,
                  &shp->mlock_user, HUGETLB_SHMFS_INODE,
                (shmflg >> SHM_HUGE_SHIFT) & SHM_HUGE_MASK);
    } else {
        /*
         * Do not allow no accounting for OVERCOMMIT_NEVER, even
         * if it's asked for.
         */
        if  ((shmflg & SHM_NORESERVE) &&
                sysctl_overcommit_memory != OVERCOMMIT_NEVER)
            acctflag = VM_NORESERVE;
        file = shmem_kernel_file_setup(name, size, acctflag);
    }
    error = PTR_ERR(file);
    if (IS_ERR(file))
        goto no_file;

    id = ipc_addid(&shm_ids(ns), &shp->shm_perm, ns->shm_ctlmni);
    if (id < 0) {
        error = id;
        goto no_id;
    }

    shp->shm_cprid = task_tgid_vnr(current);
    shp->shm_lprid = 0;
    shp->shm_atim = shp->shm_dtim = 0;
    shp->shm_ctim = get_seconds();
    shp->shm_segsz = size;
    shp->shm_nattch = 0;
    shp->shm_file = file;
    shp->shm_creator = current;
    list_add(&shp->shm_clist, ¤t->sysvshm.shm_clist);

    /*
     * shmid gets reported as "inode#" in /proc/pid/maps.
     * proc-ps tools use this. Changing this will break them.
     */
    file_inode(file)->i_ino = shp->shm_perm.id;

    ns->shm_tot += numpages;
    error = shp->shm_perm.id;

    ipc_unlock_object(&shp->shm_perm);
    rcu_read_unlock();
    return error;

no_id:
    if (is_file_hugepages(file) && shp->mlock_user)
        user_shm_unlock(size, shp->mlock_user);
    fput(file);
no_file:
    ipc_rcu_putref(shp, shm_rcu_free);
    return error;
}

这个函数首先几个if检查size是不是合法的参数,并且检查有没有足够的pages。然后调用ipc_rcu_alloc()函数给共享内存数据结构shp分配空间。然后把一些参数写到shp的shm_perm成员中。然后sprintf下面那个大的if-else是为表示共享内存内容的file分配空间。再然后ipc_addid()是一个比较重要的函数,它把刚才新建的这个共享内存的数据结构的指针加入到namespace的ids里,即可以想象成加入到数组里,并获得一个可以找到它的id。这里的id并不完全是数组的下标,因为要避免重复,所以这里有一个简单的机制来保证生成的id几乎是unique的,即ids里面有个seq变量,每次新加入共享内存对象时都会加1,而真正的id是这样生成的SEQ_MULTIPLIER * seq + id。然后初始化一些成员,再把这个数据结构的指针加到当前进程的一个list里。这个函数的工作就基本完成了。

接下来我们再看一下如果创建时传入一个已有的key,即ipcget_public()的逻辑

static int ipcget_public(struct ipc_namespace *ns, struct ipc_ids *ids,
        const struct ipc_ops *ops, struct ipc_params *params)
{
    struct kern_ipc_perm *ipcp;
    int flg = params->flg;
    int err;

    /*
     * Take the lock as a writer since we are potentially going to add
     * a new entry + read locks are not "upgradable"
     */
    down_write(&ids->rwsem);
    ipcp = ipc_findkey(ids, params->key);
    if (ipcp == NULL) {
        /* key not used */
        if (!(flg & IPC_CREAT))
            err = -ENOENT;
        else
            err = ops->getnew(ns, params);
    } else {
        /* ipc object has been locked by ipc_findkey() */

        if (flg & IPC_CREAT && flg & IPC_EXCL)
            err = -EEXIST;
        else {
            err = 0;
            if (ops->more_checks)
                err = ops->more_checks(ipcp, params);
            if (!err)
                /*
                 * ipc_check_perms returns the IPC id on
                 * success
                 */
                err = ipc_check_perms(ns, ipcp, ops, params);
        }
        ipc_unlock(ipcp);
    }
    up_write(&ids->rwsem);

    return err;
}

逻辑非常简单,先去找有没有这个key。没有的话还是创建一个新的,注意ops->getnew()对应的就是刚才的newseg()函数。如果找到了就判断一下权限有没有问题,没有问题就直接返回IPC id。

可以再看下ipc_findkey()这个函数

static struct kern_ipc_perm *ipc_findkey(struct ipc_ids *ids, key_t key)
{
    struct kern_ipc_perm *ipc;
    int next_id;
    int total;

    for (total = 0, next_id = 0; total < ids->in_use; next_id++) {
        ipc = idr_find(&ids->ipcs_idr, next_id);

        if (ipc == NULL)
            continue;

        if (ipc->key != key) {
            total++;
            continue;
        }

        rcu_read_lock();
        ipc_lock_object(ipc);
        return ipc;
    }

    return NULL;
}

逻辑也很简单,注意到ids->ipcs_idr就是之前提到的Interger ID Managenent机制,里面存的就是shmid和对象一一对应的关系。然后这里可以看到ids->in_use表示的是共享内存的个数,由于中间的有些可能删掉了,所以total在找到一个不为空的共享内存的时候才++。然后我们也可以看到,这里对重复的key并没有做任何处理。所以我们在编程的时候也应该避免直接约定用某一个数字当key。

shmat

接下来我们看一下shmat(),它的逻辑全在do_shmat()中,所以我们直接看这个函数。

long do_shmat(int shmid, char __user *shmaddr, int shmflg, ulong *raddr,
          unsigned long shmlba)
{
    struct shmid_kernel *shp;
    unsigned long addr;
    unsigned long size;
    struct file *file;
    int    err;
    unsigned long flags;
    unsigned long prot;
    int acc_mode;
    struct ipc_namespace *ns;
    struct shm_file_data *sfd;
    struct path path;
    fmode_t f_mode;
    unsigned long populate = 0;

    err = -EINVAL;
    if (shmid < 0)
        goto out;
    else if ((addr = (ulong)shmaddr)) {
        if (addr & (shmlba - 1)) {
            if (shmflg & SHM_RND)
                addr &= ~(shmlba - 1);       /* round down */
            else
#ifndef __ARCH_FORCE_SHMLBA
                if (addr & ~PAGE_MASK)
#endif
                    goto out;
        }
        flags = MAP_SHARED | MAP_FIXED;
    } else {
        if ((shmflg & SHM_REMAP))
            goto out;

        flags = MAP_SHARED;
    }

    if (shmflg & SHM_RDONLY) {
        prot = PROT_READ;
        acc_mode = S_IRUGO;
        f_mode = FMODE_READ;
    } else {
        prot = PROT_READ | PROT_WRITE;
        acc_mode = S_IRUGO | S_IWUGO;
        f_mode = FMODE_READ | FMODE_WRITE;
    }
    if (shmflg & SHM_EXEC) {
        prot |= PROT_EXEC;
        acc_mode |= S_IXUGO;
    }

    /*
     * We cannot rely on the fs check since SYSV IPC does have an
     * additional creator id...
     */
    ns = current->nsproxy->ipc_ns;
    rcu_read_lock();
    shp = shm_obtain_object_check(ns, shmid);
    if (IS_ERR(shp)) {
        err = PTR_ERR(shp);
        goto out_unlock;
    }

    err = -EACCES;
    if (ipcperms(ns, &shp->shm_perm, acc_mode))
        goto out_unlock;

    err = security_shm_shmat(shp, shmaddr, shmflg);
    if (err)
        goto out_unlock;

    ipc_lock_object(&shp->shm_perm);

    /* check if shm_destroy() is tearing down shp */
    if (!ipc_valid_object(&shp->shm_perm)) {
        ipc_unlock_object(&shp->shm_perm);
        err = -EIDRM;
        goto out_unlock;
    }

    path = shp->shm_file->f_path;
    path_get(&path);
    shp->shm_nattch++;
    size = i_size_read(d_inode(path.dentry));
    ipc_unlock_object(&shp->shm_perm);
    rcu_read_unlock();

    err = -ENOMEM;
    sfd = kzalloc(sizeof(*sfd), GFP_KERNEL);
    if (!sfd) {
        path_put(&path);
        goto out_nattch;
    }

    file = alloc_file(&path, f_mode,
              is_file_hugepages(shp->shm_file) ?
                &shm_file_operations_huge :
                &shm_file_operations);
    err = PTR_ERR(file);
    if (IS_ERR(file)) {
        kfree(sfd);
        path_put(&path);
        goto out_nattch;
    }

    file->private_data = sfd;
    file->f_mapping = shp->shm_file->f_mapping;
    sfd->id = shp->shm_perm.id;
    sfd->ns = get_ipc_ns(ns);
    sfd->file = shp->shm_file;
    sfd->vm_ops = NULL;

    err = security_mmap_file(file, prot, flags);
    if (err)
        goto out_fput;

    down_write(¤t->mm->mmap_sem);
    if (addr && !(shmflg & SHM_REMAP)) {
        err = -EINVAL;
        if (addr + size < addr)
            goto invalid;

        if (find_vma_intersection(current->mm, addr, addr + size))
            goto invalid;
    }

    addr = do_mmap_pgoff(file, addr, size, prot, flags, 0, &populate);
    *raddr = addr;
    err = 0;
    if (IS_ERR_VALUE(addr))
        err = (long)addr;
invalid:
    up_write(¤t->mm->mmap_sem);
    if (populate)
        mm_populate(addr, populate);

out_fput:
    fput(file);

out_nattch:
    down_write(&shm_ids(ns).rwsem);
    shp = shm_lock(ns, shmid);
    shp->shm_nattch--;
    if (shm_may_destroy(ns, shp))
        shm_destroy(ns, shp);
    else
        shm_unlock(shp);
    up_write(&shm_ids(ns).rwsem);
    return err;

out_unlock:
    rcu_read_unlock();
out:
    return err;
}

首先检查shmaddr的合法性并进行对齐,即调整为shmlba的整数倍。如果传入addr是0,前面检查部分只会加上一个MAP_SHARED标志,因为后面的mmap会自动为其分配地址。然后从那一段两行的注释开始,函数通过shmid尝试获取共享内存对象,并进行权限检查。然后修改shp中的一些数据,比如连接进程数加一。然后是通过alloc_file()创建真正的要做mmap的file。在mmap之前还要对地址空间进行检查,检查是否和别的地址重叠,是否够用。实际的映射工作就在do_mmap_pgoff()函数中做了。

shmdt

SYSCALL_DEFINE1(shmdt, char __user *, shmaddr)
{
    struct mm_struct *mm = current->mm;
    struct vm_area_struct *vma;
    unsigned long addr = (unsigned long)shmaddr;
    int retval = -EINVAL;
#ifdef CONFIG_MMU
    loff_t size = 0;
    struct file *file;
    struct vm_area_struct *next;
#endif

    if (addr & ~PAGE_MASK)
        return retval;

    down_write(&mm->mmap_sem);

    /*
     * This function tries to be smart and unmap shm segments that
     * were modified by partial mlock or munmap calls:
     * - It first determines the size of the shm segment that should be
     *   unmapped: It searches for a vma that is backed by shm and that
     *   started at address shmaddr. It records it's size and then unmaps
     *   it.
     * - Then it unmaps all shm vmas that started at shmaddr and that
     *   are within the initially determined size and that are from the
     *   same shm segment from which we determined the size.
     * Errors from do_munmap are ignored: the function only fails if
     * it's called with invalid parameters or if it's called to unmap
     * a part of a vma. Both calls in this function are for full vmas,
     * the parameters are directly copied from the vma itself and always
     * valid - therefore do_munmap cannot fail. (famous last words?)
     */
    /*
     * If it had been mremap()'d, the starting address would not
     * match the usual checks anyway. So assume all vma's are
     * above the starting address given.
     */
    vma = find_vma(mm, addr);

#ifdef CONFIG_MMU
    while (vma) {
        next = vma->vm_next;

        /*
         * Check if the starting address would match, i.e. it's
         * a fragment created by mprotect() and/or munmap(), or it
         * otherwise it starts at this address with no hassles.
         */
        if ((vma->vm_ops == &shm_vm_ops) &&
            (vma->vm_start - addr)/PAGE_SIZE == vma->vm_pgoff) {

            /*
             * Record the file of the shm segment being
             * unmapped.  With mremap(), someone could place
             * page from another segment but with equal offsets
             * in the range we are unmapping.
             */
            file = vma->vm_file;
            size = i_size_read(file_inode(vma->vm_file));
            do_munmap(mm, vma->vm_start, vma->vm_end - vma->vm_start);
            /*
             * We discovered the size of the shm segment, so
             * break out of here and fall through to the next
             * loop that uses the size information to stop
             * searching for matching vma's.
             */
            retval = 0;
            vma = next;
            break;
        }
        vma = next;
    }

    /*
     * We need look no further than the maximum address a fragment
     * could possibly have landed at. Also cast things to loff_t to
     * prevent overflows and make comparisons vs. equal-width types.
     */
    size = PAGE_ALIGN(size);
    while (vma && (loff_t)(vma->vm_end - addr) <= size) {
        next = vma->vm_next;

        /* finding a matching vma now does not alter retval */
        if ((vma->vm_ops == &shm_vm_ops) &&
            ((vma->vm_start - addr)/PAGE_SIZE == vma->vm_pgoff) &&
            (vma->vm_file == file))
            do_munmap(mm, vma->vm_start, vma->vm_end - vma->vm_start);
        vma = next;
    }

#else /* CONFIG_MMU */
    /* under NOMMU conditions, the exact address to be destroyed must be
     * given */
    if (vma && vma->vm_start == addr && vma->vm_ops == &shm_vm_ops) {
        do_munmap(mm, vma->vm_start, vma->vm_end - vma->vm_start);
        retval = 0;
    }

#endif

    up_write(&mm->mmap_sem);
    return retval;
}

接下来是shmdt(),这个函数非常简单,找到传入的shmaddr对应的虚拟内存数据结构vma,检查它的地址是不是正确的,然后调用do_munmap()函数断开对共享内存的连接。注意此操作并不会销毁共享内存,即使没有进程连接到它也不会,只有手动调用shmctl(id, IPC_RMID, NULL)才能销毁。

shmctl()总体就是一个switch语句,大多数做的是读取信息的或者设置标志位的工作,这里不赘述。

你可能感兴趣的:(阅读 Linux 内核源码——共享内存)