2023年8月6日 星期日

Linux Kernel(22.1)- My Socket Domain and Protocol


本章主要參考Add a new protocol to Linux Kernel寫一個自創新的socket protocol family小範例, 主要要填寫“struct proto” (/include/net/sock.h) 與“struct net_proto_family” (/include/linux/net.h)相關的operation,再分別用proto_register(struct proto *)與sock_register(struct net_proto_famil*)去跟系統註冊, 並將struct proto_ops分配給socket, 讓對應的system call都能找到對應的operation去執行

首先要先呼叫“proto_register()”跟系統註冊protocol handler.
struct my_sock {
  /* struct sock must be the first member of my_sock */
  struct sock sk;
  int channel;
};

static struct proto my_proto = {
  .name = "MYSOCK",
  .owner = THIS_MODULE,
  .obj_size = sizeof(struct my_sock),
};

static int __init myproto_init(void)
{
  int ret = -1;

  ret = proto_register(&my_proto, 0);
  if (ret) {
    mypr_err("Failed to register myprotocol\n");
    return ret;
  }
  ...
}

這個註冊動作只是把自訂的proto加入proto_list中, 我跳過這個註冊也不影響該範例, 有空再來研究細節吧, 註冊成功後可以在/proc/net/protocols中看見.
/ # cat /proc/net/protocols | grep MY
/ # insmod /lib/modules/5.15.0/extra/socket_demo.ko
socket_demo: loading out-of-tree module taints kernel.
NET: Registered PF_MCTP protocol family
myproto_init(#182)myprotocol module loaded
/ # cat /proc/net/protocols | grep MY
MYSOCK     504      0      -1   NI       0   no   socket_demo  n  n  n  n  n  n  n  n  n  n  n  n  n  n  n  n  n  n  n

接著要註冊socket layer的handler, 是透過sock_register()註冊到net_families[NPROTO=AF_MAX]中, 當user space呼叫socket()時, 就會透過sock_rgister()所掛載的create()創建對應的socket.
socket() /* userspace */
|-> SYSCALL_DEFINE3(socket, int, family, int, type, int, protocol) /* kernel */
  |-> __sys_socket(family, type, protocol);
    |-> __sock_create(family, type, protocol, &sock);
      |-> __sock_create(current->nsproxy->net_ns, family, type, protocol, res, 0);
        |-> pf = rcu_dereference(net_families[family]);
        |-> err = pf->create(net, sock, protocol, kern);
  |->sock_map_fd(sock, flags & (O_CLOEXEC | O_NONBLOCK));

相對應的"sock_register()"代碼
#define PF_MYPROTO 45         // (AF_MAX - 1), 隨意給個我沒用的PROTO
#define AF_MYPROTO PF_MYPROTO

#define mypr_info(fmt, ...)  pr_info("%s(#%d)"fmt, __func__, __LINE__, ##__VA_ARGS__);
#define mypr_err(fmt, ...)  pr_err("%s(#%d)"fmt, __func__, __LINE__, ##__VA_ARGS__);

/* for user space */
struct sockaddr_my {
  int channel;
};

static const struct proto_ops my_proto_ops = {
  .family = PF_MYPROTO,
  .owner = THIS_MODULE,
  .bind = my_bind,
  .listen = my_listen,
  .accept = my_accept,
  .connect = my_connect,
  .release = my_release,
  .sendmsg = my_sendmsg,
  .recvmsg = my_recvmsg,
};

static int myproto_create(struct net *net, struct socket *sock, int protocol, int kern)
{
  struct sock *sk;
  struct my_sock *my_sock;
  // 這裡的alloc會把my_proto帶入, 這樣在alloc時, 就可以alloc "struct my_sock"大小的記憶體
  // struct my_sock的struct sock sk;可以用kernel的sk相關函數操作, 自定義部分再轉型成"my_sock"去操作
  sk = sk_alloc(net, PF_MYPROTO, GFP_KERNEL, &my_proto, kern);
  if (!sk) {
    mypr_err("sk_alloc failed\n");
    return -ENOMEM;
  }
  // 將socket operation掛上來, 屆時對應的system call就會呼叫到對應的socket operation
  sock->ops = &my_proto_ops;
  // struct sock *sk 剛alloc, 透過sock_init_data()做一下init, 並將sock與sk做關聯
  // sk->sk_socket = sock;
  sock_init_data(sock, sk);
  // sk已經透過sock_init_data()處理好後, 再轉型成my_sock做自定義操作
  my_sock = (struct my_sock *) sk;
  my_sock->channel = 999; // 範例而已, 沒特別意思
  mypr_info("default channel:%d\n", my_sock->channel);

  return 0;
}

static struct net_proto_family myproto_family = {
  .family = PF_MYPROTO,
  .create = myproto_create,
  .owner = THIS_MODULE,
};

static int __init myproto_init(void)
{
  ret = sock_register(&myproto_family);
  if (ret) {
    mypr_err("Failed to register myprotocol family\n");
    proto_unregister(&my_proto);
    return ret;
  }

  mypr_err("myprotocol module loaded\n");
  return 0;
}

下面舉幾個socket operation從user到kernel的socket operation的路徑
bind() /* userspace */
|-> SYSCALL_DEFINE3(bind, int, fd, struct sockaddr __user *, umyaddr, int, addrlen) // kernel space
  |-> _sys_bind(fd, umyaddr, addrlen);
    |-> sock = sockfd_lookup_light(fd, &err, &fput_needed);
    |-> sock->ops->bind(sock,(struct sockaddr *)&address, addrlen);
    
listen() // userspace
|-> SYSCALL_DEFINE2(listen, int, fd, int, backlog) // kernel space
  |-> __sys_listen(fd, backlog);
    |-> sock = sockfd_lookup_light(fd, &err, &fput_needed);
    |-> sock->ops->listen(sock,(struct sockaddr *)&address, addrlen);  
從上面的範例不難理解, 大概就是在system call(__sys_xx())時直接呼叫對應的socket operation, 但是, 用過user space的都知道, 也可以透過read()/write()呼叫對應的sendmsg()與recvmsg(), 主要是在__sys_socket()時, 透過sock_map_fd()將file operation掛上去, 其中的read()/write()就是對應到sendmsg()/recvmsg().
int sock_map_fd(struct socket *sock, int flags)
|-> sock_alloc_file(sock, flags, NULL);
  |-> alloc_file_pseudo(&socket_file_ops);
    |-> file = alloc_file(&path, flags, fops);
      |-> file->f_op = fop;
      
static const struct file_operations socket_file_ops = {
  .read_iter =    sock_read_iter,
  .write_iter =   sock_write_iter,
};

sock_read_iter(struct kiocb *iocb, struct iov_iter *to)
|-> sock_recvmsg(sock, &msg, msg.msg_flags);

sock_write_iter(struct kiocb *iocb, struct iov_iter *from)
|-> res = sock_sendmsg(sock, &msg);

這篇只有簡單的介紹一下相關的API, 所以底下的socket operation都只是簡單的印出訊息, sendmsg()則是將user資料印出, 而recvmsg()則是固定回傳"My test", 如果不支援的socket operation可以使用sock_no_xxx即可.
/* Bind socket to specified sockaddr. */
static int my_bind(struct socket *sock, struct sockaddr *saddr, int len)
{
  DECLARE_SOCKADDR(struct sockaddr_my *, addr, saddr);
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  mypr_info("sock->channel %d\n", my_sock->channel);
  if (len < sizeof(*addr)) {
    mypr_err("len of addr is small\n");
    return -EINVAL;
  }
  my_sock->channel = addr->channel;
  return 0;
}

static int my_listen(struct socket *sock, int len)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return sock_no_listen(sock, len);
}

static int my_accept(struct socket *sock, struct socket *newsock, int flags, bool kern)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return sock_no_accept(sock, newsock, flags, kern);
}

static int my_release(struct socket *sock)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return 0;
}

static int my_connect(struct socket *sock, struct sockaddr *saddr, int len, int flags)
{
  DECLARE_SOCKADDR(struct sockaddr_my *, addr, saddr);
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;

  if (len < sizeof(*addr)) {
    return -EINVAL;
  }
  return 0;
}

static int my_recvmsg(struct socket *sock, struct msghdr *msg, size_t len, int flags)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  struct sk_buff *skb;
  int err;
  size_t copied;
  unsigned char buf[] = "My test";
  memcpy_to_msg(msg, buf, sizeof(buf));

  return sizeof(buf);
}

static int my_sendmsg(struct socket *sock, struct msghdr *msg, size_t len)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  int err;
  unsigned *buf;
  mypr_info("len:%d, channel:%d\n", len, my_sock->channel);

  buf = kmalloc(len + 1, GFP_KERNEL);
  if (!buf) {
    return -ENOMEM;
  }
  // Safely copy data from user space to kernel space
  memset(buf, 0, len + 1);
  err = memcpy_from_msg(buf, msg, len);
  mypr_info("data: err:%d, msg:%s\n", err, (char *) buf);
  kfree(buf);

  return len;
}

完整的Module code
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/socket.h>
#include <linux/net.h>
#include <linux/sockios.h>
#include <linux/netdevice.h>
#include <linux/errno.h>
#include <linux/proc_fs.h>
#include <linux/file.h>
#include <linux/fs.h>
#include <net/protocol.h>

#define PF_MYPROTO 45		// (AF_MAX - 1)
#define AF_MYPROTO PF_MYPROTO

#define mypr_info(fmt, ...)  pr_info("%s(#%d)"fmt, __func__, __LINE__, ##__VA_ARGS__);
#define mypr_err(fmt, ...)  pr_err("%s(#%d)"fmt, __func__, __LINE__, ##__VA_ARGS__);

#include <net/sock.h>
struct my_sock {
  /* struct sock must be the first member of my_sock */
  struct sock sk;
  int channel;
};

static inline struct my_sock *my_sock_sk(struct sock *sk)
{
  return container_of(sk, struct my_sock, sk);
}

/* for user space */
struct sockaddr_my {
  int channel;
};

static struct proto my_proto = {
  .name = "MYSOCK",
  .owner = THIS_MODULE,
  .obj_size = sizeof(struct my_sock),
};

/* Bind socket to specified sockaddr. */
static int my_bind(struct socket *sock, struct sockaddr *saddr, int len)
{
  DECLARE_SOCKADDR(struct sockaddr_my *, addr, saddr);
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  mypr_info("sock->channel %d\n", my_sock->channel);
  if (len < sizeof(*addr)) {
    mypr_err("len of addr is small\n");
    return -EINVAL;
  }
  my_sock->channel = addr->channel;
  return 0;
}

static int my_listen(struct socket *sock, int len)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return sock_no_listen(sock, len);
}

static int my_accept(struct socket *sock, struct socket *newsock, int flags, bool kern)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return sock_no_accept(sock, newsock, flags, kern);
}

static int my_release(struct socket *sock)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  mypr_info("sock->channel %d\n", my_sock->channel);
  return 0;
}

static int my_connect(struct socket *sock, struct sockaddr *saddr, int len, int flags)
{
  DECLARE_SOCKADDR(struct sockaddr_my *, addr, saddr);
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;

  if (len < sizeof(*addr)) {
    return -EINVAL;
  }
  return 0;
}

static int my_recvmsg(struct socket *sock, struct msghdr *msg, size_t len, int flags)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  struct sk_buff *skb;
  int err;
  size_t copied;
  unsigned char buf[] = "My test";
  memcpy_to_msg(msg, buf, sizeof(buf));

  return sizeof(buf);
}

static int my_sendmsg(struct socket *sock, struct msghdr *msg, size_t len)
{
  struct my_sock *my_sock = my_sock_sk(sock->sk);
  struct sock *sk = sock->sk;
  int err;
  unsigned *buf;
  mypr_info("len:%d, channel:%d\n", len, my_sock->channel);

  buf = kmalloc(len + 1, GFP_KERNEL);
  if (!buf) {
    return -ENOMEM;
  }
  // Safely copy data from user space to kernel space
  memset(buf, 0, len + 1);
  err = memcpy_from_msg(buf, msg, len);
  mypr_info("data: err:%d, msg:%s\n", err, (char *) buf);
  kfree(buf);

  return len;
}

static const struct proto_ops my_proto_ops = {
  .family = PF_MYPROTO,
  .owner = THIS_MODULE,
  .bind = my_bind,
  .listen = my_listen,
  .accept = my_accept,
  .connect = my_connect,
  .release = my_release,
  .sendmsg = my_sendmsg,
  .recvmsg = my_recvmsg,
};

static int myproto_create(struct net *net, struct socket *sock, int protocol, int kern)
{
  struct sock *sk;
  struct my_sock *my_sock;
  sk = sk_alloc(net, PF_MYPROTO, GFP_KERNEL, &my_proto, kern);
  if (!sk) {
    mypr_err("sk_alloc failed\n");
    return -ENOMEM;
  }
  sock->ops = &my_proto_ops;
  sock_init_data(sock, sk);
  my_sock = (struct my_sock *) sk;
  my_sock->channel = 999;
  mypr_info("default channel:%d\n", my_sock->channel);

  return 0;
}

static struct net_proto_family myproto_family = {
  .family = PF_MYPROTO,
  .create = myproto_create,
  .owner = THIS_MODULE,
};

static int __init myproto_init(void)
{
  int ret = -1;

  ret = proto_register(&my_proto, 0);
  if (ret) {
    mypr_err("Failed to register myprotocol\n");
    return ret;
  }

  ret = sock_register(&myproto_family);
  if (ret) {
    mypr_err("Failed to register myprotocol family\n");
    proto_unregister(&my_proto);
    return ret;
  }

  mypr_err("myprotocol module loaded\n");
  return 0;
}

static void __exit myproto_exit(void)
{
  sock_unregister(PF_MYPROTO);
  proto_unregister(&my_proto);
  mypr_info("myprotocol module unloaded\n");
}

module_init(myproto_init);
module_exit(myproto_exit);

MODULE_LICENSE("GPL");

完整的User code
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <arpa/inet.h>

#define AF_MYPROTO 45
#define PF_MYPROTO AF_MYPROTO

struct sockaddr_my {
  int channel;
};

int main(int argc, char *argv[]) {
    int sfd, new_socket, ret;
    struct sockaddr_my saddr;
    char buf[128];

    // Create a socket
    printf("%s(#%d): socket\n", __FUNCTION__, __LINE__);
    sfd = socket(AF_MYPROTO, SOCK_STREAM, 0);
    if (sfd == -1) {
        perror("Socket creation failed");
        exit(EXIT_FAILURE);
    }

    // Set up the server address structure
    saddr.channel = 123;

    printf("%s(#%d): bind\n", __FUNCTION__, __LINE__);
    // Bind the socket to the specified port
    if (bind(sfd, (struct sockaddr *)&saddr, sizeof(saddr)) == -1) {
        perror("Bind failed");
    }

    printf("%s(#%d): listen\n", __FUNCTION__, __LINE__);
    // Listen for incoming connections
    if (listen(sfd, 1) == -1) {
        perror("Listen failed");
    }

    ret = write(sfd, argv[1], strlen(argv[1]));
    if (ret < 0) {
        perror("write");
	exit(0);
    }
    printf("write: %d\n", ret);

    memset(buf, 0, sizeof(buf));
    ret = read(sfd, buf, sizeof(buf));
    printf("read: %d/%s\n", ret, buf);

    // Close the server socket
    close(sfd);

    return 0;
}

執行結果
/ # insmod /lib/modules/5.15.0/extra/socket_demo.ko
socket_demo: loading out-of-tree module taints kernel.
NET: Registered PF_MCTP protocol family
myproto_init(#178)myprotocol module loaded
/ # /my_sock abc
main(#23): socket
myproto_create(#150)default channel:999
main(#33): bind
my_bind(#49)sock->channel 999
main(#39): listen
my_listen(#61)sock->channel 123
Listen failed: Operation not supported
my_sendmsg(#110)len:3, channel:123
my_sendmsg(#119)data: err:0, msg:abc
write: 3
read: 8/My test
my_release(#75)sock->channel 123


    參考資料:
  • Add a new protocol to Linux Kernel, https://linuxwarrior.wordpress.com/2008/12/02/add-a-new-protocol-to-linux-kernel/
  • https://lishiwen4.github.io/network/socket-interface-and-network-protocol
  • https://www.cnblogs.com/hellokitty2/p/10188376.html
  • https://liuhangbin.netlify.app/post/linux-socket/
  • https://hackmd.io/@rickywu0421/linux_networking_1




2023年8月4日 星期五

Linux Kernel(21.1)- ID Allocation


如同ID Allocation的Overview提到的, kernel提供了對應的一些API, 用以產生與維護identifiers (IDs), 舉凡file descriptor, process IDs, device instance number等等. IDR主要多了ID與pointer的對用能力, 而IDA就是單純的分配ID, 本章透過簡單的程式碼讓大家能瞭解與使用IDA.

首先, 該範例是個簡易的kernel module, 透過DEFINE_IDA(my_ida)宣告一個my_ida變數, 這是我們, 並透過read file operation去取得一個新的ID(ida_simple_get), 在write file operation中透過寫入特定ID移除該ID(ida_simple_remove), 最後在移除kernel module時, 使用ida_destroy(struct ida * ida)把所有的IDA resource都釋放, 不然會造成memory leak.
#include <linux/init.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/idr.h>
#include <linux/moduleparam.h>
#include <linux/fs.h>
#include <linux/proc_fs.h>
#include <linux/seq_file.h>
#include <linux/uaccess.h> // Required for copy_from_user

MODULE_LICENSE("GPL");
MODULE_AUTHOR("Brook");
MODULE_DESCRIPTION("Kernel module to demo IDA");
MODULE_VERSION("0.1");

static DEFINE_IDA(my_ida);

static ssize_t ida_demo_read(struct file *file, char *buf, size_t count, loff_t *ppos)
{
    int id, len;
    char tmp_buf[10];

    id = ida_simple_get(&my_ida, 0, 0, GFP_KERNEL);
    if (id >= 0) {
        printk(KERN_INFO "IDR Demo: Successfully allocated ID: %d\n", id);
    } else {
        printk(KERN_ERR "IDR Demo: Failed to allocate ID\n");
        return -ENOMEM;
    }

    len = snprintf(tmp_buf, sizeof(tmp_buf), "%d", id);
    if (len < 0) {
        return -EINVAL;
    }

    if (copy_to_user(buf, tmp_buf, len)) {
        return -EFAULT;
    }

    return 0;
}

static ssize_t
ida_demo_write(struct file *file, const char __user *buf, size_t count, loff_t *ppos)
{
    char tmp_buf[20];
    int id;

    if (count >= sizeof(tmp_buf))
        return -EINVAL;

    if (copy_from_user(tmp_buf, buf, count))
        return -EFAULT;

    tmp_buf[count] = '\0';
    // Convert the input string to an integer
    if (kstrtoint(tmp_buf, 10, &id)) {
        printk(KERN_ERR "invalid ID: %s\n", tmp_buf);
        return -EINVAL;
    }

    printk(KERN_INFO "remove ID %d\n", id);
    ida_simple_remove(&my_ida, id);

    return count;
}

// Define a file operation structure for IDA access
static struct file_operations ida_fops = {
    .open = simple_open,
    .read = ida_demo_read,
    .write = ida_demo_write,
    .llseek = default_llseek,
};

static int __init ida_demo_init(void)
{
    struct proc_dir_entry *proc_entry;

    printk(KERN_INFO "IDR Demo: Initializing module\n");

    // Create a file entry to invoke 'ida'
    proc_entry = proc_create("ida", S_IRUGO, NULL, &ida_fops);
    if (!proc_entry) {
        printk(KERN_ERR "Failed to create sysfs entry for 'ida'\n");
        return -ENOMEM;
    }
    return 0;
}

static void __exit ida_demo_exit(void)
{
    printk(KERN_INFO "IDR Demo: Exiting module\n");
    ida_destroy(&my_ida);
}

module_init(ida_demo_init);
module_exit(ida_demo_exit);


簡易的Makefile
KDIR ?= /build/brook/Projects/qemu/linux/
# Modules which are included in the kernel are installed in the
# directory:
#       /lib/modules/$(KERNELRELEASE)/kernel/
# And external modules are installed in:
#       /lib/modules/$(KERNELRELEASE)/extra/
#
# INSTALL_MOD_PATH
# A prefix can be added to the
#       installation path using the variable INSTALL_MOD_PATH:
#
#       $ make INSTALL_MOD_PATH=/frodo modules_install
#       => Install dir: /frodo/lib/modules/$(KERNELRELEASE)/kernel/
export INSTALL_MOD_PATH=/build/brook/Projects/qemu/initrd-arm
obj-m := ida_demo.o
ida_demo-y := ida_main.o

modules modules_install clean:
 $(MAKE) -C $(KDIR) M=$$PWD $@


這是在QEMU下執行的結果, 會先產生ID 0/1/2, 然後移除1, 接著再產生的ID就會把1生出來, 再來就是3了, 所以透過IDA, 可以幫user管理ID(唯一的編號)
/ # uname -a
Linux (none) 5.4.0+ #6 SMP Tue Jan 3 08:39:24 CST 2023 armv7l GNU/Linux
/ # insmod /lib/modules/5.4.0+/extra/ida_demo.ko
ida_demo: loading out-of-tree module taints kernel.
IDR Demo: Initializing module
/ # cat /proc/ida
IDR Demo: Successfully allocated ID: 0
/ # cat /proc/ida
IDR Demo: Successfully allocated ID: 1
/ # cat /proc/ida
IDR Demo: Successfully allocated ID: 2
/ # echo 1 > /proc/ida
remove ID 1
/ # cat /proc/ida
IDR Demo: Successfully allocated ID: 1
/ # cat /proc/ida
IDR Demo: Successfully allocated ID: 3



  • https://www.kernel.org/doc/html/v5.4/core-api/idr.html, ID Allocation




2023年1月1日 星期日

Table Of Content for tag "Linux - kernel"


Linux Kernel(1)- Linux Module簡介
Linux Modules(1.1)module parameters

Linux Kernel(2)- register char device
Linux Kernel(2.1)- MAJRO NUMBER RESERVED FOR DYNAMIC ASSIGNMENT

Linux Kernel(3)- procfs
Linux Kernel(3.1)- procfs之vector方式寫入
Linux Kernel(3.2)- procfs之symlink與mkdir

Linux Kernel(4)- seq_file
Linux Kernel(4.1)- seq_file之範例(fp/proc/devices.c)
Linux Kernel(4.2)- seq_file之single page

Linux Kernel(5)- ioctl

Linux Kernel(6)- miscdev

Linux Kernel(7)- timing
Linux Kernel(7.1)- timer
Linux Modules(7.2)- tasklet
Linux Modules(7.3)- work queue

Linux Kernel(8)- Notification
Linux Kernel(8.1)- Notifier機制剖析

Linux Kernel(9)- Kthread

Linux Kernel(10)- MTD/Memory Technology Device
Linux Kernel(10.1)- drivers/mtd/devices/mtdram.c
Linux Kernel(10.2)- mtd partitions
Linux Kernel(10.3)- Command line partition table parsing
Linux Kernel(10.3.1)- Command line partition table parsing for Kernel 4.19

Linux Kernel(11)- sysfs and device node
Linux Kernel(11.1)- sysfs and hotplug
Linux Kernel(11.2)- mdev.conf

Linux Kernel(12)- netfilter
Linux Kernel(12.1)- netfilter機制之初探

Linux Kernel(13)- syscall

Linux Kernel(14)- Kernel Synchronization
Linux Modules(14.1)- Read Copy Update

Linux Kernel(15)- Platform Devices
Linux Kernel(15.1)- platform_driver_register()之如何调用driver.probe()
Linux Kernel(15.2)- platform_device_register()之如何调用driver.probe()
Linux Kernel(15.3)- The Linux usage model for device tree data

Linux Kernel(16.1)- Network Device Driver, simple snull

Linux Kernel(17)- Device Tree
Linux Kernel(17.1)- Basic Device Tree syntax
Linux Kernel(17.2)- Common Device Tree API

Linux Kernel(18)- Virtual File System
Linux Kernel(18.1)- My First Filesystem
Linux Kernel(18.2)- SysCall mount

Linux Kernel(19)- General Purpose Input/Output
Linux Kernel(19.1)- /sys/class/gpio usage

Linux Kernel(20)- Input device
Linux Kernel(20.1)- Input device user program
Linux Kernel(20.2)- uinput module
Linux Kernel(20.3)- Creating an input device driver

Linux Kernel(21)- ID Allocation
Linux Kernel(21.1)- ID Allocation
Linux Kernel(21.2)- radix tree API
Linux Kernel(21.3)- radix tree implementation

Linux Kernel(22)- Linux Socket
Linux Kernel(22.1)- My Socket Domain and Protocol

Linux Kernel(23)- SKB


Linux Kernel(24)- Multimedia Card
Linux Kernel(24.1)- fdisk Multimedia Card

Linux Kernel(25)- USB(Universal Serial Bus)
Linux Kernel(25.1)- Gadget Configfs




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