Android 电话系统框架介绍

目录

1.简介

1.1模块组成

1.2系统框架图

1.3代码结构图

2.RILD框架设计

3.RILD源码分析

3.1RILD进程入口函数分析

3.2启动事件循环处理eventLoop工作线程

3.2.1添加事件

3.2.2触发事件

3.2.3处理事件

3.2.4超时事件查询

3.2.5可读事件查询

3.2.6事件处理

3.3RIL_Env定义

3.4RIL_RadioFunctions定义

1.onRequest

2.currentState

3.onSupports

4.onCancel

5.getVersion

3.5注册RIL_Env接口

3.6RIL_Init的主要任务:

3.6.1.打开AT模块

3.6.2.添加定时事件RIL_requestTimedCallback

3.6.3.readLoop工作线程

3.6.4.注册RIL_RadioFunctions接口

3.7.客户端连接处理

3.8.客户端通信处理

4.电话拨打流程


1.简介

在android系统中rild运行在AP上,AP上的应用通过rild发送AT指令给BP,BP接收到信息后又通过rild传送给AP。AP与BP之间有两种通信方式:

  1. Solicited Response:Ap向Bp发送请求,Bp给Ap发送回复,该类型的AT指令及其回调函数以数组的形式存放在Ril_commands.h文件中:{数组中的索引号,请求回调函数,响应回调函数}
  2. unSolicited Response:Bp主动给Ap发送事件,该类型的AT指令及其回调函数以数组的形式存放在ril_unsol_commands.h文件中:{数组中的索引号,响应回调函数,类型}

不同手机厂商使用的AT命令不完全相同,为了保密,AP与BP之间通过各厂商自己的相关动态库来通信。

Android 电话系统框架介绍_第1张图片

1.1模块组成

RIL模块由rild守护进程、libril.so、librefrence.so三部分组成:

1.rild模块被编译为一个可执行文件,实现一个main函数作为整个ril模块的入口点。在初始化时使用dlopen打开librefrence_ril.so,从中取出并执行RIL_Init函数,得到RIL_RadioFunctions指针,通过RIL_register()函数注册到libril.so库中,其源码结构如下:

2.libril.so是共享库,主要负责同上层的通信工作,接收ril的请求,并传递给librefrence_ril.so,同时将librefrence_ril.so返回的消息送给调用进程,源码结构如下所示:

 Android 电话系统框架介绍_第2张图片

3.librefrence_ril.so是由各手机厂商自己实现,在rild进程运行中通过dlopen方式加载,主要负责跟modem硬件通信,转换来自libril.so的请求为AT命令,同时监听Modem的反馈信息给libril.so

Android 电话系统框架介绍_第3张图片

Android的电话系统主要分为三个部分,java层的各种电话相关应用,java层的Phone Service,主要为上层提供API,同时与native进行通信,可以看做为电话系统的客户端,native层的电话服务进程RILD,负责为上层提供各种电话功能服务,直接与modem进行交互:

Android 电话系统框架介绍_第4张图片

1.2系统框架图

Android电话系统设计框架图:

Android 电话系统框架介绍_第5张图片

由于Android 开发者使用的Modem 是不一样的,各种指令格式,初始化序列都可能不一样,所以为了消除这些差别,Android 设计者将ril 做了一个抽象,使用一个虚拟电话的概念,不同modem相关的AT指令或者通信协议编译成相应的动态链接库.so文件,Rild 是具体的AT 指令合成者和应答解析者。

1.3代码结构图

Android电话系统代码结构图:

Android 电话系统框架介绍_第6张图片

2.RILD框架设计

在android的电话系统中,在native层实现了电话服务的服务端,由RILD服务与modem的交互,在java层实现电话的客户端,本文主要介绍电话系统的服务端RILD进程,以下是RILD的设计框架图:

Android 电话系统框架介绍_第7张图片

3.RILD源码分析

在kernel启动完成后,将启动第一个应用进程Init进程,在android之Init进程启动过程源码分析一文中对init进程的启动流程进行了详细的介绍。init进程在启动过程中将读取init.rc文件来启动一些重量级的native服务,rild进程就是通过配置在init.rc中来启动的。

service ril-daemon /system/bin/rild  
    class main  
    socket rild stream 660 root radio  
    socket rild-debug stream 660 radio system  
    user root  
    group radio cache inet misc audio sdcard_rw log  

3.1RILD进程入口函数分析

接下来给出的是RILD进程启动的时序图:

Android 电话系统框架介绍_第8张图片

hardware\ril\rild\rild.c

int main(int argc, char **argv)  
{  
    const char * rilLibPath = NULL;  
    char **rilArgv;  
    void *dlHandle;  
    const RIL_RadioFunctions *(*rilInit)(const struct RIL_Env *, int, char **);  
    const RIL_RadioFunctions *funcs;  
    char libPath[PROPERTY_VALUE_MAX];  
    unsigned char hasLibArgs = 0;  
    int i;  
  umask(S_IRGRP | S_IWGRP | S_IXGRP | S_IROTH | S_IWOTH | S_IXOTH);  
  //rild启动无参数  
    for (i = 1; i < argc ;) {  
        if (0 == strcmp(argv[i], "-l") && (argc - i > 1)) {  
            rilLibPath = argv[i + 1];  
            i += 2;  
        } else if (0 == strcmp(argv[i], "--")) {  
            i++;  
            hasLibArgs = 1;  
            break;  
        } else {  
            usage(argv[0]);  
        }  
    }  
  if (rilLibPath == NULL) {  
      //通过Android属性系统读取属性"rild.libpath"的值,即lib库的存放路径  
        if ( 0 == property_get(LIB_PATH_PROPERTY, libPath, NULL)) {  
            goto done;  
        } else {  
            rilLibPath = libPath;  
        }  
  }  
##################################################################################  
                            判断是否为模拟器  
##################################################################################  
#if 1  
    {  
        static char*  arg_overrides[3];  
        static char   arg_device[32];  
        int           done = 0;  
#define  REFERENCE_RIL_PATH  "/system/lib/libreference-ril.so"  
        /* first, read /proc/cmdline into memory */  
        char          buffer[1024], *p, *q;  
        int           len;  
        int           fd = open("/proc/cmdline",O_RDONLY);  
        if (fd < 0) {  
            LOGD("could not open /proc/cmdline:%s", strerror(errno));  
            goto OpenLib;  
        }  
        //读取/proc/cmdline文件中的内容  
        do {  
            len = read(fd,buffer,sizeof(buffer)); }  
        while (len == -1 && errno == EINTR);  
        if (len < 0) {  
            LOGD("could not read /proc/cmdline:%s", strerror(errno));  
            close(fd);  
            goto OpenLib;  
        }  
        close(fd);  
        //判断是否为模拟器,对于真机,此处条件为false  
        if (strstr(buffer, "android.qemud=") != NULL)  
        {  
            int  tries = 5;  
#define  QEMUD_SOCKET_NAME    "qemud"  
            while (1) {  
                int  fd;  
                sleep(1);  
                fd = socket_local_client(QEMUD_SOCKET_NAME,  
                            ANDROID_SOCKET_NAMESPACE_RESERVED,  
                            SOCK_STREAM );  
                if (fd >= 0) {  
                    close(fd);  
                    snprintf( arg_device, sizeof(arg_device), "%s/%s",  
                                ANDROID_SOCKET_DIR, QEMUD_SOCKET_NAME );  
                    arg_overrides[1] = "-s";  
                    arg_overrides[2] = arg_device;  
                    done = 1;  
                    break;  
                }  
                LOGD("could not connect to %s socket: %s",QEMUD_SOCKET_NAME, strerror(errno));  
                if (--tries == 0)  
                    break;  
            }  
            if (!done) {  
                LOGE("could not connect to %s socket (giving up): %s",  
                    QEMUD_SOCKET_NAME, strerror(errno));  
                while(1)  
                    sleep(0x00ffffff);  
            }  
        }  
  
        /* otherwise, try to see if we passed a device name from the kernel */  
        if (!done) do { //true  
#define  KERNEL_OPTION  "android.ril="  
#define  DEV_PREFIX     "/dev/"  
            //判断/proc/cmdline中的内容是否包含"android.ril="  
            p = strstr( buffer, KERNEL_OPTION );  
            if (p == NULL)  
                break;  
            p += sizeof(KERNEL_OPTION)-1;  
            q  = strpbrk( p, " \t\n\r" );  
            if (q != NULL)  
                *q = 0;  
            snprintf( arg_device, sizeof(arg_device), DEV_PREFIX "%s", p );  
            arg_device[sizeof(arg_device)-1] = 0;  
            arg_overrides[1] = "-d";  
            arg_overrides[2] = arg_device;  
            done = 1;  
        } while (0);  
          
        if (done) { //false  
            argv = arg_overrides;  
            argc = 3;  
            i    = 1;  
            hasLibArgs = 1;  
            rilLibPath = REFERENCE_RIL_PATH;  
            LOGD("overriding with %s %s", arg_overrides[1], arg_overrides[2]);  
        }  
    }  
OpenLib:  
#endif  
##################################################################################  
                            动态库装载  
##################################################################################  
  
  switchUser();//设置Rild进程的组用户为radio  
  //加载厂商自定义的库  
    ①dlHandle = dlopen(rilLibPath, RTLD_NOW);  
    if (dlHandle == NULL) {  
        fprintf(stderr, "dlopen failed: %s\n", dlerror());  
        exit(-1);  
  }  
  //创建客户端事件监听线程  
  ②RIL_startEventLoop();  
  //通过dlsym定位到RIL_Init函数的地址,并且强制转换为RIL_RadioFunctions的函数指针  
    ③rilInit = (const RIL_RadioFunctions *(*)(const struct RIL_Env *, int, char **))dlsym(dlHandle, "RIL_Init");  
    if (rilInit == NULL) {  
        fprintf(stderr, "RIL_Init not defined or exported in %s\n", rilLibPath);  
        exit(-1);  
    }  
    if (hasLibArgs) { //false  
        rilArgv = argv + i - 1;  
        argc = argc -i + 1;  
    } else {  
        static char * newArgv[MAX_LIB_ARGS];  
        static char args[PROPERTY_VALUE_MAX];  
        rilArgv = newArgv;  
        property_get(LIB_ARGS_PROPERTY, args, "");//通过属性系统读取"rild.libargs"属性值  
        argc = make_argv(args, rilArgv);  
    }  
    // Make sure there's a reasonable argv[0]  
  rilArgv[0] = argv[0];  
  //调用RIL_Init函数来初始化rild,传入参数s_rilEnv,返回RIL_RadioFunctions地址  
  ④funcs = rilInit(&s_rilEnv, argc, rilArgv);  
  //注册客户端事件处理接口RIL_RadioFunctions,并创建socket监听事件  
    ⑤RIL_register(funcs);  
done:  
    while(1) {  
        // sleep(UINT32_MAX) seems to return immediately on bionic  
        sleep(0x00ffffff);  
    }  
}  

在main函数中主要完成以下工作:

1.解析命令行参数,通过判断是否为模拟器采取不同的方式来读取libreference-ril.so库的存放路径;

2.使用dlopen手动装载libreference-ril.so库;

3.启动事件循环处理;

4.从libreference-ril.so库中取得RIL_Init函数地址,并使用该函数将libril.so库中的RIL_Env接口注册到libreference-ril.so库,同时将libreference-ril.so库中的RIL_RadioFunctions接口注册到到libril.so库中,建立起libril.so库与libreference-ril.so库通信桥梁;

3.2启动事件循环处理eventLoop工作线程

建立多路I/O驱动机制的消息队列,用来接收上层发出的命令以及往Modem发送AT指令的工作,时整个RIL系统的核心部分。创建一个事件分发线程s_tid_dispatch,线程执行体为eventLoop。

hardware\ril\libril\Ril.cpp 

extern "C" void RIL_startEventLoop(void) {  
    int ret;  
    pthread_attr_t attr;  
    /* spin up eventLoop thread and wait for it to get started */  
    s_started = 0;  
    pthread_mutex_lock(&s_startupMutex);  
    pthread_attr_init (&attr);  
  pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);  
  //创建一个工作线程eventLoop  
  ret = pthread_create(&s_tid_dispatch, &attr, eventLoop, NULL);  
  //确保函数返回前eventLoop线程启动运行  
    while (s_started == 0) {  
        pthread_cond_wait(&s_startupCond, &s_startupMutex);  
    }  
    pthread_mutex_unlock(&s_startupMutex);  
    if (ret < 0) {  
        LOGE("Failed to create dispatch thread errno:%d", errno);  
        return;  
    }  
} 

eventLoop执行时序图:

Android 电话系统框架介绍_第9张图片

static void * eventLoop(void *param) {  
    int ret;  
    int filedes[2];  
    ril_event_init(); //初始化请求队列  
    pthread_mutex_lock(&s_startupMutex);  
    s_started = 1; //eventLoop线程运行标志位  
    pthread_cond_broadcast(&s_startupCond);  
  pthread_mutex_unlock(&s_startupMutex);  
  //创建匿名管道  
    ret = pipe(filedes);  
    if (ret < 0) {  
        LOGE("Error in pipe() errno:%d", errno);  
        return NULL;  
  }  
  //s_fdWakeupRead为管道读端  
  s_fdWakeupRead = filedes[0];  
  //s_fdWakeupWrite为管道写端  
  s_fdWakeupWrite = filedes[1];  
  //设置管道读端为O_NONBLOCK非阻塞  
  fcntl(s_fdWakeupRead, F_SETFL, O_NONBLOCK);  
  //初始化s_wakeupfd_event结构体的内容,句柄为s_fdWakeupRead,回调函数为   processWakeupCallback  
    ril_event_set (&s_wakeupfd_event, s_fdWakeupRead, true,processWakeupCallback, NULL);  
    ①rilEventAddWakeup (&s_wakeupfd_event);  
    // Only returns on error  
    ②ril_event_loop();  
    LOGE ("error in event_loop_base errno:%d", errno);  
    return NULL;  
}

在rild中定义了event的概念,Rild支持两种类型的事件:

1. 定时事件:根据事件的执行时间来启动执行,通过ril_timer_add添加到time_list队列中

2. Wakeup事件:这些事件的句柄fd将加入的select IO多路复用的句柄池readFDs中,当对应的fd可读时将触发这些事件。对于处于listen端的socket,fd可读表示有个客户端连接,此时需要调用accept接受连接。

事件定义如下:

struct ril_event {  
    struct ril_event *next;  
    struct ril_event *prev;  
    int fd;  //文件句柄  
    int index; //该事件在监控表中的索引   
    bool persist; //如果是保持的,则不从watch_list 中删除  
    struct timeval timeout; //任务执行时间  
    ril_event_cb func; //回调事件处理函数  
    void *param; //回调时参数  
};  

在Rild进程中的几个重要事件有

static struct ril_event s_commands_event;  
ril_event_set (&s_commands_event, s_fdCommand, 1,processCommandsCallback, p_rs)  
  
static struct ril_event s_wakeupfd_event;  
ril_event_set (&s_wakeupfd_event, s_fdWakeupRead, true,processWakeupCallback, NULL)  
  
static struct ril_event s_listen_event;  
ril_event_set (&s_listen_event, s_fdListen, false,listenCallback, NULL)  
  
static struct ril_event s_wake_timeout_event;  
ril_timer_add(&(p_info->event), &myRelativeTime);
static struct ril_event s_debug_event;  
ril_event_set (&s_debug_event, s_fdDebug, true,debugCallback, NULL)  

在RILD中定义了三个事件队列,用于处理不同的事件:

/事件监控队列

static struct ril_event * watch_table[MAX_FD_EVENTS];

//定时事件队列

static struct ril_event timer_list;

//处理事件队列

static struct ril_event pending_list; //待处理事件队列,事件已经触发,需要所回调处理的事件

Android 电话系统框架介绍_第10张图片

3.2.1添加事件

1.添加Wakeup 事件

static void rilEventAddWakeup(struct ril_event *ev) {  
    ril_event_add(ev); //向监控表watch_table添加一个s_wakeupfd_event事件  
    triggerEvLoop(); //向管道s_fdWakeupWrite中写入之来触发事件循环  
}  
void ril_event_add(struct ril_event * ev)  
{  
    dlog("~~~~ +ril_event_add ~~~~");  
    MUTEX_ACQUIRE();  
    for (int i = 0; i < MAX_FD_EVENTS; i++) { //遍历监控表watch_table  
        if (watch_table[i] == NULL) { //从监控表中查找空闲的索引,然后把该任务加入到监控表中  
            watch_table[i] = ev; //向监控表中添加事件  
            ev->index = i; //事件的索引设置为在监控表中的索引  
            dlog("~~~~ added at %d ~~~~", i);  
            dump_event(ev);  
            FD_SET(ev->fd, &readFds); //将添加的事件对应的句柄添加到句柄池readFds中  
            if (ev->fd >= nfds) nfds = ev->fd+1; //修改句柄最大值  
            dlog("~~~~ nfds = %d ~~~~", nfds);  
            break;  
        }  
    }  
    MUTEX_RELEASE();  
    dlog("~~~~ -ril_event_add ~~~~");  
} 

2.添加定时事件

void ril_timer_add(struct ril_event * ev, struct timeval * tv)  
{  
    dlog("~~~~ +ril_timer_add ~~~~");  
    MUTEX_ACQUIRE();  
    struct ril_event * list;  
    if (tv != NULL) {  
        list = timer_list.next;  
        ev->fd = -1; // make sure fd is invalid  
        struct timeval now;  
        getNow(&now);  
        timeradd(&now, tv, &ev->timeout);  
        // keep list sorted  
        while (timercmp(&list->timeout, &ev->timeout, < ) && (list != &timer_list)) {  
            list = list->next;  
        }  
        // list now points to the first event older than ev  
        addToList(ev, list);  
    }  
    MUTEX_RELEASE();  
    dlog("~~~~ -ril_timer_add ~~~~");  
}  

3.2.2触发事件

static void triggerEvLoop() {  
    int ret;  
  if (!pthread_equal(pthread_self(), s_tid_dispatch)) { //如果当前线程ID不等于事件分发线程eventLoop的线程ID  
      do {  
            ret = write (s_fdWakeupWrite, " ", 1); //向管道写端写入值1来触发eventLoop事件循环  
         } while (ret < 0 && errno == EINTR);  
    }  
}  

3.2.3处理事件

void ril_event_loop()  
{  
    int n;  
    fd_set rfds;  
    struct timeval tv;  
    struct timeval * ptv;  
    for (;;) {  
        memcpy(&rfds, &readFds, sizeof(fd_set));  
        if (-1 == calcNextTimeout(&tv)) {  
            dlog("~~~~ no timers; blocking indefinitely ~~~~");  
            ptv = NULL;  
        } else {  
            dlog("~~~~ blocking for %ds + %dus ~~~~", (int)tv.tv_sec, (int)tv.tv_usec);  
            ptv = &tv;  
        }  
        //使用select 函数等待在FDS 上,只要FDS 中记录的设备有数据到来,select 就会设置相应的标志位并返回。readFDS 记录了所有的事件相关设备句柄。readFDS 中句柄是在在AddEvent 加入的。  
        printReadies(&rfds);  
        n = select(nfds, &rfds, NULL, NULL, ptv);   
        printReadies(&rfds);  
        dlog("~~~~ %d events fired ~~~~", n);  
        if (n < 0) {  
            if (errno == EINTR) continue;  
            LOGE("ril_event: select error (%d)", errno);  
            return;  
        }  
        processTimeouts(); //从timer_list中查询执行时间已到的事件,并添加到pending_list中  
        processReadReadies(&rfds, n); //从watch_table中查询数据可读的事件,并添加到pending_list中去处理,如果该事件不是持久事件,则同时从watch_table中删除  
        //遍历pending_list,调用事件处理回调函数处理所有事件  
        firePending();  
    }  
}  

在eventLoop工作线程中,循环处理到来的事件及定时结束事件,整个处理流程如下图所示:

Android 电话系统框架介绍_第11张图片

首先通过Linux中的select多路I/O复用对句柄池中的所有句柄进行监控,当有事件到来时select返回,否则阻塞。当select返回时,表示有事件的到来,通过调用processTimeouts函数来处理超时事件,处理方式是遍历time_list链表以查询超时事件,并将超时事件移入到pending_list链表中,接着调用processReadReadies函数来处理触发的事件,处理方式为遍历watch_table列表以查询触发的事件,并将触发的事件移入到pending_list链表中,如果该事件不是持久事件,还需要从watch_table列表中移除,当查询完两种待处理的事件并放入到pending_list链表中后,调用firePending函数对待处理的事件进行集中处理,处理方式为遍历链表,调用每一个事件的回调函数。

3.2.4超时事件查询

static void processTimeouts()  
{  
    dlog("~~~~ +processTimeouts ~~~~");  
    MUTEX_ACQUIRE();  
    struct timeval now;  
    struct ril_event * tev = timer_list.next;  
    struct ril_event * next;  
    getNow(&now); //获取当前时间  
  dlog("~~~~ Looking for timers <= %ds + %dus ~~~~", (int)now.tv_sec, (int)now.tv_usec);  
  //如果当前时间大于事件的超时时间,则将该事件从timer_list中移除,添加到pending_list  
    while ((tev != &timer_list) && (timercmp(&now, &tev->timeout, >))) {  
        dlog("~~~~ firing timer ~~~~");  
        next = tev->next;  
        removeFromList(tev); //从timer_list中移除事件  
        addToList(tev, &pending_list); //将事件添加到pending_list  
        tev = next;  
    }  
    MUTEX_RELEASE();  
    dlog("~~~~ -processTimeouts ~~~~");  
} 

3.2.5可读事件查询

static void processReadReadies(fd_set * rfds, int n)  
{  
    dlog("~~~~ +processReadReadies (%d) ~~~~", n);  
  MUTEX_ACQUIRE();   
  //遍历watch_table数组,根据select返回的句柄n查找对应的事件  
    for (int i = 0; (i < MAX_FD_EVENTS) && (n > 0); i++) {  
        struct ril_event * rev = watch_table[i]; //得到相应的事件  
        if (rev != NULL && FD_ISSET(rev->fd, rfds)) {  
            addToList(rev, &pending_list); //将该事件添加到pending_list中  
            if (rev->persist == false) { //如果该事件不是持久事件还要从watch_table中移除  
                removeWatch(rev, i);  
            }  
            n--;  
        }  
    }  
    MUTEX_RELEASE();  
    dlog("~~~~ -processReadReadies (%d) ~~~~", n);  
} 

3.2.6事件处理

static void firePending()  
{  
    dlog("~~~~ +firePending ~~~~");  
    struct ril_event * ev = pending_list.next;  
    while (ev != &pending_list) { //遍历pending_list链表,处理链表中的所有事件  
        struct ril_event * next = ev->next;  
        removeFromList(ev); //将处理完的事件从pending_list中移除  
        ev->func(ev->fd, 0, ev->param); //调用事件处理的回调函数  
        ev = next;  
    }  
    dlog("~~~~ -firePending ~~~~");  
}  

3.3RIL_Env定义

hardware\ril\include\telephony\ril.h

struct RIL_Env {  
    //动态库完成请求后通知处理结果的接口  
  void (*OnRequestComplete)(RIL_Token t, RIL_Errno e,void *response, size_t responselen);  
    //动态库unSolicited Response通知接口  
  void (*OnUnsolicitedResponse)(int unsolResponse, const void *data,size_t datalen);  
    //向Rild提交一个超时任务的接口  
    void (*RequestTimedCallback) (RIL_TimedCallback callback,void *param, const struct timeval *relativeTime);  
};

hardware\ril\rild\rild.c

s_rilEnv变量定义:

static struct RIL_Env s_rilEnv = {  
    RIL_onRequestComplete,  
    RIL_onUnsolicitedResponse,  
    RIL_requestTimedCallback  
};  

在hardware\ril\libril\ril.cpp中实现了RIL_Env的各个接口函数

1.RIL_onRequestComplete

extern "C" void RIL_onRequestComplete(RIL_Token t, RIL_Errno e, void *response, size_t responselen) {  
    RequestInfo *pRI;  
    int ret;  
    size_t errorOffset;  
    pRI = (RequestInfo *)t;  
    if (!checkAndDequeueRequestInfo(pRI)) {  
        LOGE ("RIL_onRequestComplete: invalid RIL_Token");  
        return;  
    }  
    if (pRI->local > 0) {  
        // Locally issued command...void only!  
        // response does not go back up the command socket  
        LOGD("C[locl]< %s", requestToString(pRI->pCI->requestNumber));  
        goto done;  
    }  
    appendPrintBuf("[%04d]< %s",pRI->token, requestToString(pRI->pCI->requestNumber));  
    if (pRI->cancelled == 0) {  
        Parcel p;  
        p.writeInt32 (RESPONSE_SOLICITED);  
        p.writeInt32 (pRI->token);  
        errorOffset = p.dataPosition();  
        p.writeInt32 (e);  
        if (response != NULL) {  
            // there is a response payload, no matter success or not.  
            ret = pRI->pCI->responseFunction(p, response, responselen);  
            /* if an error occurred, rewind and mark it */  
            if (ret != 0) {  
                p.setDataPosition(errorOffset);  
                p.writeInt32 (ret);  
            }  
        }  
        if (e != RIL_E_SUCCESS) {  
            appendPrintBuf("%s fails by %s", printBuf, failCauseToString(e));  
        }  
        if (s_fdCommand < 0) {  
            LOGD ("RIL onRequestComplete: Command channel closed");  
        }  
        sendResponse(p);  
    }  
done:  
    free(pRI);  
}  

通过调用responseXXX将底层响应传给客户进程

2.RIL_onUnsolicitedResponse

extern "C" void RIL_onUnsolicitedResponse(int unsolResponse, void *data,  
                                size_t datalen)  
{  
    int unsolResponseIndex;  
    int ret;  
    int64_t timeReceived = 0;  
    bool shouldScheduleTimeout = false;  
    if (s_registerCalled == 0) {  
        // Ignore RIL_onUnsolicitedResponse before RIL_register  
        LOGW("RIL_onUnsolicitedResponse called before RIL_register");  
        return;  
    }  
    unsolResponseIndex = unsolResponse - RIL_UNSOL_RESPONSE_BASE;  
    if ((unsolResponseIndex < 0)  
        || (unsolResponseIndex >= (int32_t)NUM_ELEMS(s_unsolResponses))) {  
        LOGE("unsupported unsolicited response code %d", unsolResponse);  
        return;  
    }  
    // Grab a wake lock if needed for this reponse,  
    // as we exit we'll either release it immediately  
    // or set a timer to release it later.  
    switch (s_unsolResponses[unsolResponseIndex].wakeType) {  
        case WAKE_PARTIAL:  
            grabPartialWakeLock();  
            shouldScheduleTimeout = true;  
        break;  
        case DONT_WAKE:  
        default:  
            // No wake lock is grabed so don't set timeout  
            shouldScheduleTimeout = false;  
            break;  
    }  
    // Mark the time this was received, doing this  
    // after grabing the wakelock incase getting  
    // the elapsedRealTime might cause us to goto  
    // sleep.  
    if (unsolResponse == RIL_UNSOL_NITZ_TIME_RECEIVED) {  
        timeReceived = elapsedRealtime();  
    }  
    appendPrintBuf("[UNSL]< %s", requestToString(unsolResponse));  
    Parcel p;  
    p.writeInt32 (RESPONSE_UNSOLICITED);  
    p.writeInt32 (unsolResponse);  
    ret = s_unsolResponses[unsolResponseIndex].responseFunction(p, data, datalen);  
    if (ret != 0) {  
        // Problem with the response. Don't continue;  
        goto error_exit;  
    }  
    // some things get more payload  
    switch(unsolResponse) {  
        case RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED:  
            p.writeInt32(s_callbacks.onStateRequest());  
            appendPrintBuf("%s {%s}", printBuf,  
                radioStateToString(s_callbacks.onStateRequest()));  
        break;  
        case RIL_UNSOL_NITZ_TIME_RECEIVED:  
            // Store the time that this was received so the  
            // handler of this message can account for  
            // the time it takes to arrive and process. In  
            // particular the system has been known to sleep  
            // before this message can be processed.  
            p.writeInt64(timeReceived);  
        break;  
    }  
    ret = sendResponse(p);  
    if (ret != 0 && unsolResponse == RIL_UNSOL_NITZ_TIME_RECEIVED) {  
        // Unfortunately, NITZ time is not poll/update like everything  
        // else in the system. So, if the upstream client isn't connected,  
        // keep a copy of the last NITZ response (with receive time noted  
        // above) around so we can deliver it when it is connected  
        if (s_lastNITZTimeData != NULL) {  
            free (s_lastNITZTimeData);  
            s_lastNITZTimeData = NULL;  
        }  
        s_lastNITZTimeData = malloc(p.dataSize());  
        s_lastNITZTimeDataSize = p.dataSize();  
        memcpy(s_lastNITZTimeData, p.data(), p.dataSize());  
    }  
    // For now, we automatically go back to sleep after TIMEVAL_WAKE_TIMEOUT  
    // FIXME The java code should handshake here to release wake lock  
    if (shouldScheduleTimeout) {  
        // Cancel the previous request  
        if (s_last_wake_timeout_info != NULL) {  
            s_last_wake_timeout_info->userParam = (void *)1;  
        }  
        s_last_wake_timeout_info= internalRequestTimedCallback(wakeTimeoutCallback, NULL,  
                                            &TIMEVAL_WAKE_TIMEOUT);  
    }  
    return;  
error_exit:  
    if (shouldScheduleTimeout) {  
        releaseWakeLock();  
    }  
}  

这个函数处理modem从网络端接收到的各种事件,如网络信号变化,拨入的电话,收到短信等。然后传给客户进程。

3.RIL_requestTimedCallback

extern "C" void RIL_requestTimedCallback (RIL_TimedCallback callback, void *param,  
                                const struct timeval *relativeTime) {  
    internalRequestTimedCallback (callback, param, relativeTime);  
}  
static UserCallbackInfo *internalRequestTimedCallback (RIL_TimedCallback callback, void *param,  
                                const struct timeval *relativeTime)  
{  
    struct timeval myRelativeTime;  
    UserCallbackInfo *p_info;  
    p_info = (UserCallbackInfo *) malloc (sizeof(UserCallbackInfo));  
    p_info->p_callback = callback;  
    p_info->userParam = param;  
    if (relativeTime == NULL) {  
        /* treat null parameter as a 0 relative time */  
        memset (&myRelativeTime, 0, sizeof(myRelativeTime));  
    } else {  
        /* FIXME I think event_add's tv param is really const anyway */  
        memcpy (&myRelativeTime, relativeTime, sizeof(myRelativeTime));  
    }  
    ril_event_set(&(p_info->event), -1, false, userTimerCallback, p_info);  
    ril_timer_add(&(p_info->event), &myRelativeTime);  
    triggerEvLoop();  
    return p_info;  
}  

3.4RIL_RadioFunctions定义

客户端向Rild发送请求的接口,由各手机厂商实现。

hardware\ril\include\telephony\Ril.h 

typedef struct {  
    int version; //Rild版本  
    RIL_RequestFunc onRequest; //AP请求接口  
    RIL_RadioStateRequest onStateRequest;//BP状态查询  
    RIL_Supports supports;  
    RIL_Cancel onCancel;  
    RIL_GetVersion getVersion;//动态库版本  
} RIL_RadioFunctions;  
static const RIL_RadioFunctions s_callbacks = {  
    RIL_VERSION,  
    onRequest,  
    currentState,  
    onSupports,  
    onCancel,  
    getVersion  
};  

在hardware\ril\reference-ril\reference-ril.c中实现了RIL_RadioFunctions的各个接口函数

1.onRequest

static void onRequest (int request, void *data, size_t datalen, RIL_Token t)  
{  
    ATResponse *p_response;  
    int err;  
    LOGD("onRequest: %s", requestToString(request));  
    /* Ignore all requests except RIL_REQUEST_GET_SIM_STATUS 
     * when RADIO_STATE_UNAVAILABLE. 
     */  
    if (sState == RADIO_STATE_UNAVAILABLE  
        && request != RIL_REQUEST_GET_SIM_STATUS  
    ) {  
        RIL_onRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0);  
        return;  
    }  
    /* Ignore all non-power requests when RADIO_STATE_OFF 
     * (except RIL_REQUEST_GET_SIM_STATUS) 
     */  
    if (sState == RADIO_STATE_OFF&& !(request == RIL_REQUEST_RADIO_POWER  
            || request == RIL_REQUEST_GET_SIM_STATUS)  
    ) {  
        RIL_onRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0);  
        return;  
    }  
    switch (request) {  
        case RIL_REQUEST_GET_SIM_STATUS: {  
            RIL_CardStatus *p_card_status;  
            char *p_buffer;  
            int buffer_size;  
            int result = getCardStatus(&p_card_status);  
            if (result == RIL_E_SUCCESS) {  
                p_buffer = (char *)p_card_status;  
                buffer_size = sizeof(*p_card_status);  
            } else {  
                p_buffer = NULL;  
                buffer_size = 0;  
            }  
            RIL_onRequestComplete(t, result, p_buffer, buffer_size);  
            freeCardStatus(p_card_status);  
            break;  
        }  
        case RIL_REQUEST_GET_CURRENT_CALLS:  
            requestGetCurrentCalls(data, datalen, t);  
            break;  
        case RIL_REQUEST_DIAL:  
            requestDial(data, datalen, t);  
            break;  
        case RIL_REQUEST_HANGUP:  
            requestHangup(data, datalen, t);  
            break;  
        case RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND:  
            // 3GPP 22.030 6.5.5  
            // "Releases all held calls or sets User Determined User Busy  
            //  (UDUB) for a waiting call."  
            at_send_command("AT+CHLD=0", NULL);  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND:  
            // 3GPP 22.030 6.5.5  
            // "Releases all active calls (if any exist) and accepts  
            //  the other (held or waiting) call."  
            at_send_command("AT+CHLD=1", NULL);  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE:  
            // 3GPP 22.030 6.5.5  
            // "Places all active calls (if any exist) on hold and accepts  
            //  the other (held or waiting) call."  
            at_send_command("AT+CHLD=2", NULL);  
  
#ifdef WORKAROUND_ERRONEOUS_ANSWER  
            s_expectAnswer = 1;  
#endif /* WORKAROUND_ERRONEOUS_ANSWER */  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_ANSWER:  
            at_send_command("ATA", NULL);  
#ifdef WORKAROUND_ERRONEOUS_ANSWER  
            s_expectAnswer = 1;  
#endif /* WORKAROUND_ERRONEOUS_ANSWER */  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_CONFERENCE:  
            // 3GPP 22.030 6.5.5  
            // "Adds a held call to the conversation"  
            at_send_command("AT+CHLD=3", NULL);  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_UDUB:  
            /* user determined user busy */  
            /* sometimes used: ATH */  
            at_send_command("ATH", NULL);  
            /* success or failure is ignored by the upper layer here. 
               it will call GET_CURRENT_CALLS and determine success that way */  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        case RIL_REQUEST_SEPARATE_CONNECTION:  
            {  
                char  cmd[12];  
                int   party = ((int*)data)[0];  
                // Make sure that party is in a valid range.  
                // (Note: The Telephony middle layer imposes a range of 1 to 7.  
                // It's sufficient for us to just make sure it's single digit.)  
                if (party > 0 && party < 10) {  
                    sprintf(cmd, "AT+CHLD=2%d", party);  
                    at_send_command(cmd, NULL);  
                    RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
                } else {  
                    RIL_onRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0);  
                }  
            }  
            break;  
        case RIL_REQUEST_SIGNAL_STRENGTH:  
            requestSignalStrength(data, datalen, t);  
            break;  
        case RIL_REQUEST_REGISTRATION_STATE:  
        case RIL_REQUEST_GPRS_REGISTRATION_STATE:  
            requestRegistrationState(request, data, datalen, t);  
            break;  
        case RIL_REQUEST_OPERATOR:  
            requestOperator(data, datalen, t);  
            break;  
        case RIL_REQUEST_RADIO_POWER:  
            requestRadioPower(data, datalen, t);  
            break;  
        case RIL_REQUEST_DTMF: {  
            char c = ((char *)data)[0];  
            char *cmd;  
            asprintf(&cmd, "AT+VTS=%c", (int)c);  
            at_send_command(cmd, NULL);  
            free(cmd);  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            break;  
        }  
        case RIL_REQUEST_SEND_SMS:  
            requestSendSMS(data, datalen, t);  
            break;  
        case RIL_REQUEST_SETUP_DATA_CALL:  
            requestSetupDataCall(data, datalen, t);  
            break;  
        case RIL_REQUEST_SMS_ACKNOWLEDGE:  
            requestSMSAcknowledge(data, datalen, t);  
            break;  
        case RIL_REQUEST_GET_IMSI:  
            p_response = NULL;  
            err = at_send_command_numeric("AT+CIMI", &p_response);  
            if (err < 0 || p_response->success == 0) {  
                RIL_onRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0);  
            } else {  
                RIL_onRequestComplete(t, RIL_E_SUCCESS,  
                    p_response->p_intermediates->line, sizeof(char *));  
            }  
            at_response_free(p_response);  
            break;  
        case RIL_REQUEST_GET_IMEI:  
            p_response = NULL;  
            err = at_send_command_numeric("AT+CGSN", &p_response);  
  
            if (err < 0 || p_response->success == 0) {  
                RIL_onRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0);  
            } else {  
                RIL_onRequestComplete(t, RIL_E_SUCCESS,  
                    p_response->p_intermediates->line, sizeof(char *));  
            }  
            at_response_free(p_response);  
            break;  
        case RIL_REQUEST_SIM_IO:  
            requestSIM_IO(data,datalen,t);  
            break;  
        case RIL_REQUEST_SEND_USSD:  
            requestSendUSSD(data, datalen, t);  
            break;  
        case RIL_REQUEST_CANCEL_USSD:  
            p_response = NULL;  
            err = at_send_command_numeric("AT+CUSD=2", &p_response);  
            if (err < 0 || p_response->success == 0) {  
                RIL_onRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0);  
            } else {  
                RIL_onRequestComplete(t, RIL_E_SUCCESS,  
                    p_response->p_intermediates->line, sizeof(char *));  
            }  
            at_response_free(p_response);  
            break;  
        case RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC:  
            at_send_command("AT+COPS=0", NULL);  
            break;  
        case RIL_REQUEST_DATA_CALL_LIST:  
            requestDataCallList(data, datalen, t);  
            break;  
        case RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE:  
            requestQueryNetworkSelectionMode(data, datalen, t);  
            break;  
        case RIL_REQUEST_OEM_HOOK_RAW:  
            // echo back data  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, data, datalen);  
            break;  
        case RIL_REQUEST_OEM_HOOK_STRINGS: {  
            int i;  
            const char ** cur;  
            LOGD("got OEM_HOOK_STRINGS: 0x%8p %lu", data, (long)datalen);  
            for (i = (datalen / sizeof (char *)), cur = (const char **)data ;  
                    i > 0 ; cur++, i --) {  
                LOGD("> '%s'", *cur);  
            }  
            // echo back strings  
            RIL_onRequestComplete(t, RIL_E_SUCCESS, data, datalen);  
            break;  
        }  
        case RIL_REQUEST_WRITE_SMS_TO_SIM:  
            requestWriteSmsToSim(data, datalen, t);  
            break;  
        case RIL_REQUEST_DELETE_SMS_ON_SIM: {  
            char * cmd;  
            p_response = NULL;  
            asprintf(&cmd, "AT+CMGD=%d", ((int *)data)[0]);  
            err = at_send_command(cmd, &p_response);  
            free(cmd);  
            if (err < 0 || p_response->success == 0) {  
                RIL_onRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0);  
            } else {  
                RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
            }  
            at_response_free(p_response);  
            break;  
        }  
        case RIL_REQUEST_ENTER_SIM_PIN:  
        case RIL_REQUEST_ENTER_SIM_PUK:  
        case RIL_REQUEST_ENTER_SIM_PIN2:  
        case RIL_REQUEST_ENTER_SIM_PUK2:  
        case RIL_REQUEST_CHANGE_SIM_PIN:  
        case RIL_REQUEST_CHANGE_SIM_PIN2:  
            requestEnterSimPin(data, datalen, t);  
            break;  
        case RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION:  
            requestSmsBroadcastActivation(0,data, datalen, t);  
            break;  
        case RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG:  
             LOGD("onRequest RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG");  
            requestSetSmsBroadcastConfig(0,data, datalen, t);  
            break;  
        case RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG:  
            requestGetSmsBroadcastConfig(0,data, datalen, t);  
            break;  
        default:  
            RIL_onRequestComplete(t, RIL_E_REQUEST_NOT_SUPPORTED, NULL, 0);  
            break;  
    }  
}  

对每一个RIL_REQUEST_XXX请求转化成相应的ATcommand,发送给modem,然后睡眠等待,当收到ATcommand的最终响应后,线程被唤醒,将响应传给客户端进程。

2.currentState

static RIL_RadioState currentState()  
{  
    return sState;  
} 

3.onSupports

static int onSupports (int requestCode)  
{  
    //@@@ todo  
    return 1;  
}  

4.onCancel

static void onCancel (RIL_Token t)  
{  
    //@@@todo  
}  

5.getVersion

static const char * getVersion(void)  
{  
    return "android reference-ril 1.0";  
}  

3.5注册RIL_Env接口

Android 电话系统框架介绍_第12张图片

由于各手机厂商的AT指令差异,因此与modem交互层需要各手机厂商实现,以动态库的形式提供。作为介于modem与上层的中间层,即要与底层交互也要与上层通信,因此就需要定义一个接口来衔接RILD与动态库,RIL_Env和RIL_RadioFunctions接口就是libril.so与librefrence.so通信的桥梁。是Rild架构中用于隔离通用代码和厂商代码的接口,RIL_Env由通用代码实现,而RIL_RadioFunctions则是由厂商代码实现。

 

3.6RIL_Init的主要任务:

1. 向librefrence.so注册libril.so提供的接口RIL_Env;

2. 创建一个mainLoop工作线程,用于初始化AT模块,并监控AT模块的状态,一旦AT被关闭,则重新打开并初始化AT;

3. 当AT被打开后,mainLoop工作线程将向Rild提交一个定时事件,并触发eventLoop来完成对modem的初始化;

4. 创建一个readLoop工作线程,用于从AT串口中读取数据;

5.返回librefrence.so提供的接口RIL_RadioFunctions;

hardware\ril\reference-ril\reference-ril.c

const RIL_RadioFunctions *RIL_Init(const struct RIL_Env *env, int argc, char **argv)  
{  
    int ret;  
    int fd = -1;  
    int opt;  
    pthread_attr_t attr;  
  s_rilenv = env; //将ril.cpp中定义的RIL_Env注册到reference-ril.c中的s_rilenv  
    while ( -1 != (opt = getopt(argc, argv, "p:d:s:"))) {  
        switch (opt) {  
            case 'p':  
                s_port = atoi(optarg);  
                if (s_port == 0) {  
                    usage(argv[0]);  
                    return NULL;  
                }  
                LOGI("Opening loopback port %d\n", s_port);  
            break;  
            case 'd':  
                s_device_path = optarg;  
                LOGI("Opening tty device %s\n", s_device_path);  
            break;  
            case 's':  
                s_device_path   = optarg;  
                s_device_socket = 1;  
                LOGI("Opening socket %s\n", s_device_path);  
            break;  
            default:  
                usage(argv[0]);  
                return NULL;  
        }  
    }  
    if (s_port < 0 && s_device_path == NULL) {  
        usage(argv[0]);  
        return NULL;  
    }  
    pthread_attr_init (&attr);  
  pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);  
  //创建一个mainLoop线程  
  ret = pthread_create(&s_tid_mainloop, &attr, mainLoop, NULL);  
  //将reference-ril.c中定义的RIL_RadioFunctions返回并注册到ril.cpp中的s_callbacks  
    return &s_callbacks;  
}  

mainLoop工作线程是用来初始化并监控AT模块的,一旦AT模块被关闭,就自动打开。

static void * mainLoop(void *param)  
{  
    int fd;  
    int ret;  
  AT_DUMP("== ", "entering mainLoop()", -1 );  
  //为AT模块设置回调函数  
    at_set_on_reader_closed(onATReaderClosed);  
    at_set_on_timeout(onATTimeout);  
    for (;;) {  
        fd = -1;  
        while  (fd < 0) { //获得串口AT模块的设备文件描述符  
            if (s_port > 0) {  
                fd = socket_loopback_client(s_port, SOCK_STREAM);  
            } else if (s_device_socket) {  
                if (!strcmp(s_device_path, "/dev/socket/qemud")) {  
                    /* Qemu-specific control socket */  
                    fd = socket_local_client( "qemud",  
                 ANDROID_SOCKET_NAMESPACE_RESERVED,SOCK_STREAM );  
                    if (fd >= 0 ) {  
                        char  answer[2];  
                        if ( write(fd, "gsm", 3) != 3 ||read(fd, answer, 2) != 2 ||  
                             memcmp(answer, "OK", 2) != 0)  
                        {  
                            close(fd);  
                            fd = -1;  
                        }  
                   }  
                }  
                else  
                    fd = socket_local_client( s_device_path,    ANDROID_SOCKET_NAMESPACE_FILESYSTEM,SOCK_STREAM );  
            } else if (s_device_path != NULL) {  
                fd = open (s_device_path, O_RDWR);  
                if ( fd >= 0 && !memcmp( s_device_path, "/dev/ttyS", 9 ) ) {  
                    /* disable echo on serial ports */  
                    struct termios  ios;  
                    tcgetattr( fd, &ios );  
                    ios.c_lflag = 0;  /* disable ECHO, ICANON, etc... */  
                    tcsetattr( fd, TCSANOW, &ios );  
                }  
            }  
            if (fd < 0) {  
                perror ("opening AT interface. retrying...");  
                sleep(10);  
            }  
        }  
        s_closed = 0;  
        //打开AT模块,创建AT读取线程s_tid_reader,fd为modem设备文件句柄  
        ret = at_open(fd, onUnsolicited);  
        if (ret < 0) {  
            LOGE ("AT error %d on at_open\n", ret);  
            return 0;  
        }  
        //向Rild提交超时任务  
        RIL_requestTimedCallback(initializeCallback, NULL, &TIMEVAL_0);  
        sleep(1);  
        //如果AT模块被关闭,则waitForClose返回,重新打开AT,如果AT已打开,则阻塞  
        waitForClose();  
        LOGI("Re-opening after close");  
    }  
}  

3.6.1.打开AT模块

通过at_open打开文件描述符为fd的AT串口设备,并注册回调函数ATUnsolHandler 

int at_open(int fd, ATUnsolHandler h)  
{  
    int ret;  
    pthread_t tid;  
    pthread_attr_t attr;  
    s_fd = fd;  
    s_unsolHandler = h;  
    s_readerClosed = 0;  
    s_responsePrefix = NULL;  
    s_smsPDU = NULL;  
    sp_response = NULL;  
    /* Android power control ioctl */  
#ifdef HAVE_ANDROID_OS  
#ifdef OMAP_CSMI_POWER_CONTROL  
    ret = ioctl(fd, OMAP_CSMI_TTY_ENABLE_ACK);  
    if(ret == 0) {  
        int ack_count;  
        int read_count;  
        int old_flags;  
        char sync_buf[256];  
        old_flags = fcntl(fd, F_GETFL, 0);  
        fcntl(fd, F_SETFL, old_flags | O_NONBLOCK);  
        do {  
            ioctl(fd, OMAP_CSMI_TTY_READ_UNACKED, &ack_count);  
            read_count = 0;  
            do {  
                ret = read(fd, sync_buf, sizeof(sync_buf));  
                if(ret > 0)  
                    read_count += ret;  
            } while(ret > 0 || (ret < 0 && errno == EINTR));  
            ioctl(fd, OMAP_CSMI_TTY_ACK, &ack_count);  
         } while(ack_count > 0 || read_count > 0);  
        fcntl(fd, F_SETFL, old_flags);  
        s_readCount = 0;  
        s_ackPowerIoctl = 1;  
    }  
    else  
        s_ackPowerIoctl = 0;  
#else // OMAP_CSMI_POWER_CONTROL  
        s_ackPowerIoctl = 0;  
#endif // OMAP_CSMI_POWER_CONTROL  
#endif /*HAVE_ANDROID_OS*/  
    pthread_attr_init (&attr);  
  pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);  
  //创建readerLoop工作线程,该线程用于从串口读取数据  
    ret = pthread_create(&s_tid_reader, &attr, readerLoop, &attr);  
    if (ret < 0) {  
        perror ("pthread_create");  
        return -1;  
    }  
    return 0;  
}  

3.6.2.添加定时事件RIL_requestTimedCallback

RIL_requestTimedCallback(initializeCallback, NULL, &TIMEVAL_0);  
  
#define RIL_requestTimedCallback(a,b,c) s_rilenv->RequestTimedCallback(a,b,c)  

向定时事件队列中添加一个定时事件,该事件的处理函数为initializeCallback,用于发送一些AT指令来初始化BP的modem。

3.6.3.readLoop工作线程

Read loop 解析从Modem 发过来的回应。如果遇到URC 则通过handleUnsolicited 上报的RIL_JAVA。如果是命令的应答,则通过handleFinalResponse 通知send_at_command 有应答结果。

Android 电话系统框架介绍_第13张图片

static void *readerLoop(void *arg)  
{  
    for (;;) {  
        const char * line;  
        line = readline();  
        if (line == NULL) {  
            break;  
        }  
        if(isSMSUnsolicited(line)) { //判断是否是SMS 通知  
            char *line1;  
            const char *line2;  
            line1 = strdup(line);  
            line2 = readline();  
            if (line2 == NULL) {  
                break;  
            }  
            if (s_unsolHandler != NULL) {  
                s_unsolHandler (line1, line2); //回调通知SMS  
            }  
            free(line1);  
        } else {  
            processLine(line); //处理接收到的数据,根据line中的指令调用不同的回调函数  
        }  
#ifdef HAVE_ANDROID_OS  
        if (s_ackPowerIoctl > 0) {  
            /* acknowledge that bytes have been read and processed */  
            ioctl(s_fd, OMAP_CSMI_TTY_ACK, &s_readCount);  
            s_readCount = 0;  
        }  
#endif /*HAVE_ANDROID_OS*/  
    }  
    onReaderClosed();  
    return NULL;  
}  

3.6.4.注册RIL_RadioFunctions接口

hardware\ril\libril\ril.cpp

extern "C" void RIL_register (const RIL_RadioFunctions *callbacks) {  
    int ret;  
  int flags;  
  //版本验证  
    if (callbacks == NULL || ((callbacks->version != RIL_VERSION)&& (callbacks->version < 2))) {   
        return;  
    }  
    if (callbacks->version < RIL_VERSION) {  
        LOGE ("RIL_register: upgrade RIL to version %d current version=%d",  
              RIL_VERSION, callbacks->version);  
    }  
    if (s_registerCalled > 0) {  
        LOGE("RIL_register has been called more than once. "Subsequent call ignored");  
        return;  
  }  
    //将reference-ril.c中定义的RIL_RadioFunctions注册到ril.cpp中  
    memcpy(&s_callbacks, callbacks, sizeof (RIL_RadioFunctions));  
    s_registerCalled = 1;  
    for (int i = 0; i < (int)NUM_ELEMS(s_commands); i++) {  
        assert(i == s_commands[i].requestNumber); //序号验证  
    }  
    for (int i = 0; i < (int)NUM_ELEMS(s_unsolResponses); i++) {  
        assert(i + RIL_UNSOL_RESPONSE_BASE== s_unsolResponses[i].requestNumber);  
    }  
    // old standalone impl wants it here.  
    if (s_started == 0) {  
        RIL_startEventLoop();  
    }  
  // 得到名为rild的socket句柄  
  s_fdListen = android_get_control_socket(SOCKET_NAME_RIL);  
    if (s_fdListen < 0) {  
        LOGE("Failed to get socket '" SOCKET_NAME_RIL "'");  
        exit(-1);  
  }  
  // 监听该socket  
    ret = listen(s_fdListen, 4);  
    if (ret < 0) {  
        LOGE("Failed to listen on control socket '%d': %s",s_fdListen, strerror(errno));  
        exit(-1);  
    }  
    /* 设置s_listen_event事件,一旦有客户端连接,即s_fdListen可读就会导致eventLoop工作线程中的select返回,因为该事件不是持久的,因此调用为listenCallback处理完后,将从watch_table移除该事件,所以Rild只支持一个客户端连接*/  
  ril_event_set (&s_listen_event, s_fdListen, false,listenCallback, NULL);  
    /* 添加s_listen_event事件,并触发eventLoop工作线程 */  
    rilEventAddWakeup (&s_listen_event);  
#if 1  
    // 得到调试socket的句柄rild-debug  
    s_fdDebug = android_get_control_socket(SOCKET_NAME_RIL_DEBUG);  
    if (s_fdDebug < 0) {  
        LOGE("Failed to get socket '" SOCKET_NAME_RIL_DEBUG "' errno:%d", errno);  
        exit(-1);  
  }  
  //监听该socket  
    ret = listen(s_fdDebug, 4);  
    if (ret < 0) {  
        LOGE("Failed to listen on ril debug socket '%d': %s",s_fdDebug, strerror(errno));  
        exit(-1);  
  }  
    /* 设置s_debug_event事件 */  
    ril_event_set (&s_debug_event, s_fdDebug, true,debugCallback, NULL);  
    /* 添加s_debug_event事件,并触发eventLoop工作线程  */  
    rilEventAddWakeup (&s_debug_event);  
#endif  
}  

打开监听端口,接收来自客户端进程的命令请求,当与客户进程连接建立时调用listenCallback函数,创建单独线程监视并处理所有事件源。

3.7.客户端连接处理

s_listen_event事件用于处理上层客户端的socket连接,当得到socket连接请求时,eventLoop工作线程里的select返回并自动调用listenCallback回调函数进行处理:

static void listenCallback (int fd, short flags, void *param) {  
    int ret;  
    int err;  
    int is_phone_socket;  
    RecordStream *p_rs;  
    commthread_data_t *user_data = NULL;  
    user_data =(commthread_data_t *)malloc(sizeof(commthread_data_t));  
    struct sockaddr_un peeraddr;  
    socklen_t socklen = sizeof (peeraddr);  
    struct ucred creds;  
    socklen_t szCreds = sizeof(creds);  
    struct passwd *pwd = NULL;  
    assert (s_fdCommand < 0);  
  assert (fd == s_fdListen);  
  //接收一个客户端的连接,并将该socket连接保存在变量s_fdCommand中  
    s_fdCommand = accept(s_fdListen, (sockaddr *) &peeraddr, &socklen);  
    if (s_fdCommand < 0 ) {  
        LOGE("Error on accept() errno:%d", errno);  
        /* start listening for new connections again */  
        rilEventAddWakeup(&s_listen_event);  
          return;  
    }  
    /* 对客户端权限判断,判断是否是进程组ID为radio的进程发起的连接*/  
    errno = 0;  
    is_phone_socket = 0;  
    err = getsockopt(s_fdCommand, SOL_SOCKET, SO_PEERCRED, &creds, &szCreds);  
    if (err == 0 && szCreds > 0) {  
        errno = 0;  
        pwd = getpwuid(creds.uid);  
        if (pwd != NULL) {  
            if (strcmp(pwd->pw_name, PHONE_PROCESS) == 0) {  
                is_phone_socket = 1;  
            } else {  
                LOGE("RILD can't accept socket from process %s", pwd->pw_name);  
            }  
        } else {  
            LOGE("Error on getpwuid() errno: %d", errno);  
        }  
    } else {  
        LOGD("Error on getsockopt() errno: %d", errno);  
    }  
      
    if ( !is_phone_socket ) {  
      LOGE("RILD must accept socket from %s", PHONE_PROCESS);  
      close(s_fdCommand);  
      s_fdCommand = -1;  
      onCommandsSocketClosed();  
      /* start listening for new connections again */  
      rilEventAddWakeup(&s_listen_event);  
      return;  
    }  
#if 0  
    if(s_dualSimMode) {  
        if(s_sim_num == 0) {  
            property_get(SIM_POWER_PROPERTY, prop, "0");  
            if(!strcmp(prop, "0")) {  
                property_set(SIM_POWER_PROPERTY, "1");  
                s_callbacks.powerSIM(NULL);  
            }  
        } else if(s_sim_num == 1) {  
            property_get(SIM_POWER_PROPERTY1, prop, "0");  
            if(!strcmp(prop, "0")) {  
                property_set(SIM_POWER_PROPERTY1, "1");  
                s_callbacks.powerSIM(NULL);  
            }  
        }  
    } else {  
        property_get(SIM_POWER_PROPERTY, prop, "0");  
        if(!strcmp(prop, "0")) {  
            property_set(SIM_POWER_PROPERTY, "1");  
            s_callbacks.powerSIM(NULL);  
        }  
    }  
#endif  
    //p_rs为RecordStream类型,它内部会分配一个缓冲区来存储客户端发送过来的数据  
  p_rs = record_stream_new(s_fdCommand, MAX_COMMAND_BYTES);  
  //添加一个针对接收到的客户端连接的处理事件,从而在eventLoop工作线程中处理该客户端的各种请求  
    ril_event_set (&s_commands_event, s_fdCommand, 1,processCommandsCallback, p_rs);  
    rilEventAddWakeup (&s_commands_event);  
    onNewCommandConnect();  
}  

3.8.客户端通信处理

在listenCallback中首先接收客户端的连接请求,并验证客户端的权限,同时将该客户端以事件的形式添加到eventLoop工作线程中进行监控,当该客户端有数据请求时,eventLoop工作线程从select中返回,并自动调用processCommandsCallback回调函数:

static void processCommandsCallback(int fd, short flags, void *param) {  
    RecordStream *p_rs;  
    void *p_record;  
    size_t recordlen;  
    int ret;  
    assert(fd == s_fdCommand);  
    p_rs = (RecordStream *)param;  
  for (;;) { //循环处理客户端发送过来的AT命令  
      //读取一条AT命令  
        ret = record_stream_get_next(p_rs, &p_record, &recordlen);  
        if (ret == 0 && p_record == NULL) {  
            break;  
        } else if (ret < 0) {  
            break;  
        } else if (ret == 0) { /* && p_record != NULL */  
            //处理客户端发送过来的AT命令  
            processCommandBuffer(p_record, recordlen);  
        }  
    }  
    if (ret == 0 || !(errno == EAGAIN || errno == EINTR)) {  
        if (ret != 0) {  
            LOGE("error on reading command socket errno:%d\n", errno);  
        } else {  
            LOGW("EOS.  Closing command socket.");  
        }  
        close(s_fdCommand);  
        s_fdCommand = -1;  
        ril_event_del(&s_commands_event);  
        record_stream_free(p_rs);  
        rilEventAddWakeup(&s_listen_event);  
        onCommandsSocketClosed();  
    }  
}  

通过processCommandBuffer函数来处理每一条AT命令:

static int processCommandBuffer(void *buffer, size_t buflen) {  
    Parcel p;  
    status_t status;  
    int32_t request;  
    int32_t token;  
    RequestInfo *pRI;  
    int ret;  
    p.setData((uint8_t *) buffer, buflen);  
    // status checked at end  
    status = p.readInt32(&request);  
    status = p.readInt32 (&token);  
    if (status != NO_ERROR) {  
        LOGE("invalid request block");  
        return 0;  
    }  
    if (request < 1 || request >= (int32_t)NUM_ELEMS(s_commands)) {  
        LOGE("unsupported request code %d token %d", request, token);  
        return 0;  
    }  
    pRI = (RequestInfo *)calloc(1, sizeof(RequestInfo));  
    pRI->token = token; //AT命令标号  
    pRI->pCI = &(s_commands[request]); //根据request找到s_commands命令数组中的指定AT命令  
    ret = pthread_mutex_lock(&s_pendingRequestsMutex);  
    assert (ret == 0);  
    pRI->p_next = s_pendingRequests;  
    s_pendingRequests = pRI;  
    ret = pthread_mutex_unlock(&s_pendingRequestsMutex);  
  assert (ret == 0);  
  //调用指定AT命令的dispatch函数,根据接收来自客户进程的命令和参数,调用onRequest进行处理。  
    pRI->pCI->dispatchFunction(p, pRI);  
    return 0;  
}  

打电话的AT命令:{RIL_REQUEST_DIAL, dispatchDial, responseVoid},

发短信的AT命令:{RIL_REQUEST_SEND_SMS, dispatchStrings, responseSMS},

4.电话拨打流程

Android 电话系统框架介绍_第14张图片

static void dispatchDial (Parcel &p, RequestInfo *pRI) {  
  RIL_Dial dial; //RIL_Dial存储了打电话的所有信息  
    RIL_UUS_Info uusInfo;   
    int32_t sizeOfDial;  
    int32_t t;  
    .................. //初始化dial变量    
  s_callbacks.onRequest(pRI->pCI->requestNumber, &dial, sizeOfDial, pRI);  
  .................  
    return;  
}  

s_callbacks.onRequest其实就是调用RIL_RadioFunctions中的onRequest函数,该函数在前面已介绍过了。

static void onRequest (int request, void *data, size_t datalen, RIL_Token t)  
{  
    switch (request) {  
        case RIL_REQUEST_DIAL:  
            requestDial(data, datalen, t);  
            break;  
    }  
}
static void requestDial(void *data, size_t datalen, RIL_Token t)  
{  
    RIL_Dial *p_dial;  
    char *cmd;  
    const char *clir;  
    int ret;  
    p_dial = (RIL_Dial *)data;  
    switch (p_dial->clir) {  
        case 1: clir = "I"; break;  /*invocation*/  
        case 2: clir = "i"; break;  /*suppression*/  
        default:  
        case 0: clir = ""; break;   /*subscription default*/  
  }  
  //向串口发送AT指令  
    ret = at_send_command(cmd, NULL);  
  free(cmd);  
  //通知请求结果  
    RIL_onRequestComplete(t, RIL_E_SUCCESS, NULL, 0);  
}  

向AT发送完拨号指令后,通过RIL_onRequestComplete返回处理结果,RIL_onRequestComplete实际上是RIL_Env中的OnRequestComplete函数,在前面我们也介绍过了

extern "C" void RIL_onRequestComplete(RIL_Token t, RIL_Errno e, void *response, size_t responselen) {  
    RequestInfo *pRI;  
    int ret;  
    size_t errorOffset;  
  pRI = (RequestInfo *)t;  
  //该请求已经处理,需要从请求队列中移除该请求  
    if (!checkAndDequeueRequestInfo(pRI)) {  
        LOGE ("RIL_onRequestComplete: invalid RIL_Token");  
        return;  
    }  
    if (pRI->local > 0) {  
        ...........  
        sendResponse(p);  
    }  
done:  
    free(pRI);  
}  
static int sendResponse (Parcel &p) {  
    return sendResponseRaw(p.data(), p.dataSize()); //将结果发送给JAVA RIL客户端  
}  
static int sendResponseRaw (const void *data, size_t dataSize) {  
    int fd = s_fdCommand;  
    int ret;  
    uint32_t header;  
    if (s_fdCommand < 0) {  
        return -1;  
    }  
    if (dataSize > MAX_COMMAND_BYTES) {  
        return -1;  
    }  
    pthread_mutex_lock(&s_writeMutex);  
    header = htonl(dataSize);  
    ret = blockingWrite(fd, (void *)&header, sizeof(header));  
    if (ret < 0) {  
        pthread_mutex_unlock(&s_writeMutex);  
        return ret;  
    }  
    ret = blockingWrite(fd, data, dataSize);  
    if (ret < 0) {  
        pthread_mutex_unlock(&s_writeMutex);  
        return ret;  
    }  
    pthread_mutex_unlock(&s_writeMutex);  
    return 0;  
} 

拨打电话的时序图如下:

Android 电话系统框架介绍_第15张图片

Rild通过onRequest向动态库提交一个请求,然后返回,动态库处理完请求后,处理结果通过回调接口通知客户端

你可能感兴趣的:(Android进阶,android)