本文主要对android4.4 ril的telephony与modem的命令交互流程进行分析,当然本文不是重点介绍telephony。
telephony涉及具体业务逻辑内容比较多,包括sim、dail、sms、network等等,以后会针对这些内容学习分析。
ril在android体系中的位置:
(a) 应用层发起访问modem的请求
(b) rild进程
(a) 应用层发起访问modem的请求
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java中的类ril,提供了一系
列的接口给上层应用调用,以访问modem。当然这些接口并不是直接给app使用,而是由framework中sim、dail、
sms、network等相关服务调用。
如: 以查询sim卡状态geticccardstatus()为例,该api为uicccontroller模块所调用:
完整的sim卡请求log:
10-11 12:21:43.630 d/rilj ( 1833): [3653]> get_sim_status
10-11 12:21:43.630 d/rilc ( 1286): [0005]> get_sim_status
10-11 12:21:43.630 d/rilc ( 1286): onrequest: get_sim_status
10-11 12:21:43.630 d/atc ( 1286): at> at+cpin?
10-11 12:21:43.640 d/atc ( 1286): at< +cpin: ready
10-11 12:21:43.640 d/atc ( 1286): at< ok
10-11 12:21:43.640 d/rilc ( 1286): [0005]< get_sim_status {[app_type=1,app_state=5,perso_substate=2,aid_ptr=(null),app_label_ptr=(null),pin1_replaced=0,pin1=0,pin2=0],}
10-11 12:21:43.640 d/rilj ( 1833): [3653]< get_sim_status icccardstate {cardstate_present,pinstate_unknown,num_apps=1,gsm_id=0{apptype_sim,appstate_ready},cdma_id=8,ims_id=8}
发起请求:
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
我要评论@override
public void
geticccardstatus(message result) {
//note: this ril request has not been renamed to icc,
// but this request is also valid for sim and ruim
rilrequest rr = rilrequest.obtain(ril_request_get_sim_status, result); /* 获取一个rilrequest */
if (rilj_logd) riljlog(rr.serialstring() + "> " + requesttostring(rr.mrequest)); /* 参考log:[3653]> get_sim_status */
send(rr); /* 发送请求 */
}
rilrequest.obtain是从内存池获取一个rilrequest实例,并初始化:
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
class rilrequest {
static final string log_tag = "rilrequest";
... ...
static rilrequest obtain(int request, message result) {
rilrequest rr = null;
synchronized(spoolsync) { /* 从内存池中取出一个rilrequest对象*/
if (spool != null) {
rr = spool;
spool = rr.mnext;
rr.mnext = null;
spoolsize--;
}
}
if (rr == null) { /* 如果内存池中没有,则实例化一个 */
rr = new rilrequest();
}
rr.mserial = snextserial.getandincrement(); /* 获取串号,并且+1 */
rr.mrequest = request; /* 对应ril_request_*请求 */
rr.mresult = result;
rr.mparcel = parcel.obtain(); /* 初始化一个parcel,用于封包以发送给底层rild */
if (result != null && result.gettarget() == null) {
throw new nullpointerexception("message target must not be null");
}
// first elements in any ril parcel
rr.mparcel.writeint(request); /* 每个ril parcel最开始也最基本的两个元素 */
rr.mparcel.writeint(rr.mserial);
return rr; /* 返回这个从内存池中获取的实例 */
}
... ...
string
serialstring() {
//cheesy way to do %04d
stringbuilder sb = new stringbuilder(8); /* 创建一个stringbuilder实例用于操作字符串 */
string sn;
long adjustedserial = (((long)mserial) - integer.min_value)%10000;
sn = long.tostring(adjustedserial); /* 把数值转换成字符串 */
//sb.append("j[");
sb.append('[');
for (int i = 0, s = sn.length() ; i < 4 - s; i++) {
sb.append('0');
}
sb.append(sn);
sb.append(']');
return sb.tostring(); /* 转换出来的字符串格式: [xxxx] */
}
... ...
}
send(rr)发送请求到服务端:
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
private void
send(rilrequest rr) {
message msg;
... ...
msg = msender.obtainmessage(event_send, rr); /* 发送event_send时间,时间参数为rilrequest */
acquirewakelock(); /* 获取wakelock,禁止进入休眠 */
msg.sendtotarget(); /* message从handler类获取,从而可以直接向该handler对象发送消息。target就是创建message的handler */
}
实际上telephony无法直接与modem通讯,由于每个厂商的modem都不一样,modem存在于系统中的方式
也不一样,如:有的cpu芯片厂商的modem是以一个cp核的方式集成在基带上(高通、展讯等),有的cpu芯
片(exynos 4412等)需要通过串口/usb外接modem模块,如:bc72 lte模块等。
send(rr)向rild发送请求,这里涉及一个进程间通信问题,而且java侧与c++侧的进程通讯,当然这里并没
有用android开发的朋友都熟悉的bind,而是socket。
telephony/java侧ril命令交互的处理,暂且称为rilj。
rilj作为socket的客户端,rild(rild进程)作为服务端,后面会分析rild进程。
socket客户端的创建:
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
public ril(context context, int preferrednetworktype, int cdmasubscription) {
... ...
msenderthread = new handlerthread("rilsender"); /* 创建rilsender线程 */
msenderthread.start();
looper looper = msenderthread.getlooper();
msender = new rilsender(looper);
connectivitymanager cm = (connectivitymanager)context.getsystemservice(
context.connectivity_service);
if (cm.isnetworksupported(connectivitymanager.type_mobile) == false) {
riljlog("not starting rilreceiver: wifi-only");
} else {
riljlog("starting rilreceiver");
mreceiver = new rilreceiver();
mreceiverthread = new thread(mreceiver, "rilreceiver"); /* 创建rilreceiver线程 */
mreceiverthread.start();
... ...
}
... ...
}
class rilreceiver implements runnable {
byte[] buffer;
rilreceiver() { /* 构造时,分配一个数组 */
buffer = new byte[ril_max_command_bytes];
}
@override
public void
run() { /* 循环读取从rild返回或主动上报的数据 */
int retrycount = 0;
try {for (;;) {
localsocket s = null;
localsocketaddress l;
try {
s = new localsocket(); /* 创建一个socket客户端 */
l = new localsocketaddress(socket_name_ril,
localsocketaddress.namespace.reserved);
s.connect(l); /* 连接服务器 */
}
... ...
}
... ...
try {
inputstream is = msocket.getinputstream(); /* 循环读取socket的数据 */
for (;;) {
parcel p;
length = readrilmessage(is, buffer); /* 解析socket数据 */
if (length < 0) {
// end-of-stream reached
break;
}
p = parcel.obtain(); /* 获取一个parcel */
p.unmarshall(buffer, 0, length); /* 读取出来的就是之前序列化的byte数组,所以要进行一个反序列化操作 */
p.setdataposition(0); /* 从buffer转换到parcel之后,需要将指针手动指向到最初的位置 */
//rlog.v(rilj_log_tag, "read packet: " + length + " bytes");
processresponse(p);
p.recycle(); /* 数据处理完后,需要回收parcel的内存 */
}
}
... ...
}
rilreceiver线程创建socket客户端,连接服务端,然后进入等待服务端的processresponse消息处理循环,rilj
接收到rild回复的response返回ril请求的发起者,以geticccardstatus(message result)为例,processresponse(p)
会把drild的response返回给uicccontroller
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
private static int readrilmessage(inputstream is, byte[] buffer)
throws ioexception {
int countread;
int offset;
int remaining;
int messagelength;
// first, read in the length of the message
offset = 0;
remaining = 4;
do {
countread = is.read(buffer, offset, remaining); /* 读出消息的4字节长度 */
if (countread < 0 ) {
rlog.e(rilj_log_tag, "hit eos reading message length");
return -1;
}
offset += countread;
remaining -= countread;
} while (remaining > 0);
messagelength = ((buffer[0] & 0xff) << 24) /* 获取长度 */
| ((buffer[1] & 0xff) << 16)
| ((buffer[2] & 0xff) << 8)
| (buffer[3] & 0xff);
// then, re-use the buffer and read in the message itself
offset = 0;
remaining = messagelength;
do {
countread = is.read(buffer, offset, remaining); /* 读取剩余的数据 */
if (countread < 0 ) {
rlog.e(rilj_log_tag, "hit eos reading message. messagelength=" + messagelength
+ " remaining=" + remaining);
return -1;
}
offset += countread;
remaining -= countread;
} while (remaining > 0);
return messagelength;
}
private void
processresponse (parcel p) {
int type;
type = p.readint(); /* 从rild返回的数据第一个字节,表示请求的返回类型:response_unsolicited/response_solicited */
if (type == response_unsolicited) {
processunsolicited (p); /* 主动上报 */
} else if (type == response_solicited) {
rilrequest rr = processsolicited (p); /* 普通请求对应的同步上报 */
if (rr != null) {
rr.release(); /* 释放对应的rilrequest内存和wakelock */
decrementwakelock();
}
}
}
rild的response一般有两种,一种是rilj普通请求,rild对rilj请求的response (response_solicited),另一种是rild主动上报的
response (response_unsolicited), processresponse (parcel p)分别对这两种情况的response进行处理。
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
private rilrequest
processsolicited (parcel p) {
int serial, error;
boolean found = false;
serial = p.readint(); /* 串号,也就是token */
error = p.readint(); /* 错误码 */
rilrequest rr;
rr = findandremoverequestfromlist(serial); /* 根据taken取出对应的rilrequest */
... ...
*/
case ril_request_get_sim_status: ret = responseicccardstatus(p); break;
... ...
if (rr.mresult != null) {
asyncresult.formessage(rr.mresult, ret, null); /* 把rr.mresult存到asyncresult.userobj,并把rr.mresult.obj转换为asyncresult */
rr.mresult.sendtotarget(); /* msg发送到对应的target(handler) */
}
... ...
}
private object
responseicccardstatus(parcel p) {
icccardapplicationstatus appstatus;
... ...
appstatus = new icccardapplicationstatus();
... ...
return cardstatus;
}
回到刚才send(rr),send(rr)并不是直接发送到socket服务端rild,而是通过一个message发送到rilsender线程,
在handlemessage中,把请求发到socket服务端rild。
frameworks/opt/telephony/src/java/com/android/internal/telephony/ril.java
class rilsender extends handler implements runnable { /* 继承handler,实现runnable */
public rilsender(looper looper) {
super(looper);
}
... ...
//***** handler implementation
@override public void
handlemessage(message msg) { /* 继承handler的handlemessage */
rilrequest rr = (rilrequest)(msg.obj); /* maessage中携带的rilrequest对象 */
rilrequest req = null;
switch (msg.what) {
case event_send: /* 发送ril请求事件 */
try {
localsocket s;
s = msocket; /* rilreceiver中创建的用于与rild通讯的socket */
... ...
synchronized (mrequestlist) { /* 多线程保护操作mrequestlist */
mrequestlist.append(rr.mserial, rr); /* 把接受到的rilrequest和对应的串号,存到mrequestlist数据 */
}
byte[] data;
data = rr.mparcel.marshall(); /* 把parcel中的数据转换为byte数据 */
rr.mparcel.recycle(); /* parcel的内存回收 */
rr.mparcel = null;
... ...
// parcel length in big endian
datalength[0] = datalength[1] = 0; /* ril请求包的大小为4个字节 */
datalength[2] = (byte)((data.length >> 8) & 0xff);
datalength[3] = (byte)((data.length) & 0xff);
//rlog.v(rilj_log_tag, "writing packet: " + data.length + " bytes");
s.getoutputstream().write(datalength); /* 把包大小和包数据发送出去 */
s.getoutputstream().write(data);
} catch (ioexception ex) {
rlog.e(rilj_log_tag, "ioexception", ex);
req = findandremoverequestfromlist(rr.mserial); /* 如果出现异常,则把串号对应的rilrequest从mrequestlist中删除 */
// make sure this request has not already been handled,
// eg, if rilreceiver cleared the list.
if (req != null) {
rr.onerror(radio_not_available, null);
rr.release();
decrementwakelock();
}
}
... ...
}
}
}
(b) rild进程
rild作为一个独立的进程,telephony与modem之间的通讯通道。抽象出一些接口以适配不同的modem厂商,无需关心具体的
硬件操作,或者以哪种形式存存在于系统(modem作为cp集成于cpu或cpu通过串口/usb连接,如: bc72 lte模块)。因为这些接口
由厂商去实现具体的硬件操作细节,这些接口都在libreference-ril中,在android中使用bc72 lte模块,只要移植
libreference-ril就行。
1. rild的启动
rild有init进程直接启动,启动后就监听rilj客户端,等待rilj连接请求。
device/samsung/smdk4x12/conf/init.smdk4x12.rc
service ril-daemon /system/bin/rild -l /system/lib/libreference-ril.so
class main
socket rild stream 660 root radio
socket rild-debug stream 660 radio system
user root
hardware/ril/rild/rild.c为rild进程入口:
hardware/ril/rild/rild.c
int main(int argc, char **argv)
{
... ...
dlhandle = dlopen(rillibpath, rtld_now); /* 打开/system/lib/libreference-ril.so */
if (dlhandle == null) {
rloge("dlopen failed: %s", dlerror());
exit(-1);
}
ril_starteventloop(); /* 创建eventloop线程, 在ril_event_loop()中监听多路io的事件,如主动唤醒事件(pipe)、rilj的请求等 */
/* 获取/system/lib/libreference-ril.so中ril_init函数指针 */
rilinit = (const ril_radiofunctions *(*)(const struct ril_env *, int, char **))dlsym(dlhandle, "ril_init");
if (rilinit == null) {
rloge("ril_init not defined or exported in %s\n", rillibpath);
exit(-1);
}
if (haslibargs) {
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, "");
argc = make_argv(args, rilargv);
}
// make sure there's a reasonable argv[0]
rilargv[0] = argv[0];
funcs = rilinit(&s_rilenv, argc, rilargv); /* 初始化vender ril */
ril_register(funcs); /* 注册ril */
... ...
}
hardware/ril/libril/ril.cpp
extern "c" void
ril_starteventloop(void) {
... ...
ret = pthread_create(&s_tid_dispatch, &attr, eventloop, null); /* 创建eventloop线程 */
... ...
}
static void *
eventloop(void *param) {
int ret;
int filedes[2];
ril_event_init(); /* 初始化事件链表,timer_list,pending_list, watch_table */
pthread_mutex_lock(&s_startupmutex);
s_started = 1;
pthread_cond_broadcast(&s_startupcond);
pthread_mutex_unlock(&s_startupmutex);
ret = pipe(filedes); /* 创建一个pipe,用于每次添加一个新事件时,唤醒selet()返回,更新fd_set使select监听新的事件 */
if (ret < 0) {
rloge("error in pipe() errno:%d", errno);
return null;
}
s_fdwakeupread = filedes[0]; /* filedes[0]用于读pipe, filedes[1]用于写pipe */
s_fdwakeupwrite = filedes[1];
fcntl(s_fdwakeupread, f_setfl, o_nonblock); /* 以非阻塞的方式读pipe */
ril_event_set (&s_wakeupfd_event, s_fdwakeupread, true, /* 读pipe描述符绑定到s_wakeupfd_event事件,指定回调processwakeupcallback */
processwakeupcallback, null);
rileventaddwakeup (&s_wakeupfd_event); /* 添加s_wakeupfd_event事件到watch_table,更新readfds集合,使select监听该事件,并触发该事件 */
// only returns on error
ril_event_loop(); /* 进入多路io事件监听循环 */
rloge ("error in event_loop_base errno:%d", errno);
// kill self to restart on error
kill(0, sigkill);
return null;
}
main函数主要启动eventloop线程,在ril_event_loop()中监听多路io的事件,如主动唤醒事件(pipe)、rilj的请求等,
注册vendor ril接口(libreference-ril)
注意这里pipe的主要作用是唤醒select返回,因为每次动态的添加一个事件,都要更新readfds集合,方便select监听
集合中新的io。
rileventaddwakeup()添加新事件后,都会触发select返回
hardware/ril/libril/ril.cpp
static void rileventaddwakeup(struct ril_event *ev) {
ril_event_add(ev); /* 添加事件 */
triggerevloop(); /* 触发事件, 每添加一个事件,都通过写pipe唤醒select,以更新多路io集合,使能够监听该事件 */
}
hardware/ril/libril/ril_event.cpp
void ril_event_add(struct ril_event * ev)
{
dlog("~~~~ +ril_event_add ~~~~");
mutex_acquire();
for (int i = 0; i < max_fd_events; i++) {
if (watch_table[i] == null) {
watch_table[i] = ev; /* 将新事件添加到watch_table */
ev->index = i;
dlog("~~~~ added at %d ~~~~", i);
dump_event(ev);
fd_set(ev->fd, &readfds); /* 更新readfds集合 */
if (ev->fd >= nfds) nfds = ev->fd+1; /* 更新nfds */
dlog("~~~~ nfds = %d ~~~~", nfds);
break;
}
}
mutex_release();
dlog("~~~~ -ril_event_add ~~~~");
}
hardware/ril/libril/ril.cpp
static void triggerevloop() {
int ret;
if (!pthread_equal(pthread_self(), s_tid_dispatch)) {
/* trigger event loop to wakeup. no reason to do this,
* if we're in the event loop thread */
do {
ret = write (s_fdwakeupwrite, " ", 1); /* 向pipe写入一个" ",以唤醒select */
} while (ret < 0 && errno == eintr);
}
}
在ril_event_loop()接收到事件或socket客户端rilj发过来的请求后,firepending()根据事件请求,调用相应的处理函数
hardware/ril/libril/ril_event.cpp
void ril_event_loop()
{
int n;
fd_set rfds;
struct timeval tv;
struct timeval * ptv;
for (;;) {
// make local copy of read fd_set
memcpy(&rfds, &readfds, sizeof(fd_set));
if (-1 == calcnexttimeout(&tv)) { /* 计算timer_list链表中每个事件对应的超时时间 */
// no pending timers; block indefinitely
dlog("~~~~ no timers; blocking indefinitely ~~~~");
ptv = null;
} else {
dlog("~~~~ blocking for %ds + %dus ~~~~", (int)tv.tv_sec, (int)tv.tv_usec);
ptv = &tv;
}
printreadies(&rfds);
n = select(nfds, &rfds, null, null, ptv); /* 等待readfds集合中的事件唤醒 */
printreadies(&rfds);
dlog("~~~~ %d events fired ~~~~", n);
if (n < 0) {
if (errno == eintr) continue;
rloge("ril_event: select error (%d)", errno);
// bail?
return;
}
// check for timeouts
processtimeouts(); /* 检查timer_list链表中是否有事件已经超时 */
// check for read-ready
processreadreadies(&rfds, n); /* 从watch_table中取出监听到的事件, 并添加到pending_list链表 */
// fire away
firepending(); /* 从pending_list依次取出事件,并执行该事件的回调 */
}
}
static void processtimeouts()
{
dlog("~~~~ +processtimeouts ~~~~");
mutex_acquire();
struct timeval now;
struct ril_event * tev = timer_list.next;
struct ril_event * next;
getnow(&now);
// walk list, see if now >= ev->timeout for any events
/* 检查timer_list链表中是否有事件已经超时 */
dlog("~~~~ looking for timers <= %ds + %dus ~~~~", (int)now.tv_sec, (int)now.tv_usec);
while ((tev != &timer_list) && (timercmp(&now, &tev->timeout, >))) {
// timer expired
dlog("~~~~ firing timer ~~~~");
next = tev->next;
removefromlist(tev); /* 将该超时移出链表 */
addtolist(tev, &pending_list); /* 并且将该超时添加到pending链表 */
tev = next; /* 指针指向下一个超时 */
}
mutex_release();
dlog("~~~~ -processtimeouts ~~~~");
}
static void processreadreadies(fd_set * rfds, int n)
{
dlog("~~~~ +processreadreadies (%d) ~~~~", n);
mutex_acquire();
for (int i = 0; (i < max_fd_events) && (n > 0); i++) {
struct ril_event * rev = watch_table[i];
if (rev != null && fd_isset(rev->fd, rfds)) { /* 从watch_table中取出监听到的事件 */
addtolist(rev, &pending_list); /* 并把该事件加入pending_list链表 */
if (rev->persist == false) { /* 如果该事件不需要处理,则移出removewatch */
removewatch(rev, i);
}
n--;
}
}
mutex_release();
dlog("~~~~ -processreadreadies (%d) ~~~~", n);
}
static void firepending()
{
dlog("~~~~ +firepending ~~~~");
struct ril_event * ev = pending_list.next;
while (ev != &pending_list) { /* 从pending_list依次取出事件 */
struct ril_event * next = ev->next;
removefromlist(ev);
ev->func(ev->fd, 0, ev->param); /* 并执行该事件的回调 */
ev = next;
}
dlog("~~~~ -firepending ~~~~");
}
上面分析了ril_starteventloop()的事件流程,简单总结就是根据事件调用该事件的处理函数。
到这里还没说到怎样创建socket服务端的,回到mian(),funcs = rilinit(&s_rilenv, argc, rilargv);
初始化了libreference-ril,ril_register(funcs);注册了厂商须实现的相关接口,创建socket服务端的,
并监听客户端连接,一旦连接,则开始等待读取客户端发过来的请求。
hardware/ril/libril/ril.cpp
extern "c" void
ril_register (const ril_radiofunctions *callbacks) {
... ...
s_fdlisten = android_get_control_socket(socket_name_ril); /* 创建socket服务端,用于与rilj通信 */
if (s_fdlisten < 0) {
rloge("failed to get socket '" socket_name_ril "'");
exit(-1);
}
ret = listen(s_fdlisten, 4); /* 监听rilj */
if (ret < 0) {
rloge("failed to listen on control socket '%d': %s",
s_fdlisten, strerror(errno));
exit(-1);
}
/* note: non-persistent so we can accept only one connection at a time */
ril_event_set (&s_listen_event, s_fdlisten, false, /* 设置一个监听事件s_listen_event,一旦与rilj建立连 */
listencallback, null); /* 则进入listencallback,等待读取rilj发送数据 */
rileventaddwakeup (&s_listen_event); /* 添加s_listen_event到watch_table, 唤醒select */
... ...
}
static void listencallback (int fd, short flags, void *param) {
... ...
s_fdcommand = accept(s_fdlisten, (sockaddr *) &peeraddr, &socklen); /* 接受rilj客户端的连接 */
... ...
err = getsockopt(s_fdcommand, sol_socket, so_peercred, &creds, &szcreds);
ret = fcntl(s_fdcommand, f_setfl, o_nonblock); /* 非阻塞方式读写socket */
if (ret < 0) {
rloge ("error setting o_nonblock errno:%d", errno);
}
rlogi("libril: new connection");
p_rs = record_stream_new(s_fdcommand, max_command_bytes); /* 创建一个stream用于缓存读socket的数据 */
ril_event_set (&s_commands_event, s_fdcommand, 1, /* 设置s_commands_event,processcommandscallback循环读取socket的数据 */
processcommandscallback, p_rs);
rileventaddwakeup (&s_commands_event); /* 添加s_commands_event事件,唤醒select */
onnewcommandconnect(); /* 通知rilj已建立连接 */
}
static void processcommandscallback(int fd, short flags, void *param) {
... ...
for (;;) {
/* loop until eagain/eintr, end of stream, or other error */
ret = record_stream_get_next(p_rs, &p_record, &recordlen); /* 循环从数据流中读取socket数据 */
if (ret == 0 && p_record == null) {
/* end-of-stream */
break;
} else if (ret < 0) {
break;
} else if (ret == 0) { /* && p_record != null */
processcommandbuffer(p_record, recordlen); /* 对接受到的数据进行组包,下发给vender ril,即libreference-ril.so */
}
}
}
processcommandbuffer(p_record, recordlen)对接收到的数据进行组包,下发给vender ril,即libreference-ril.so,
然后就脱离了rild的控制了,libreference-ril.so主要是厂商对rild控制modem接口的实现。
hardware/ril/libril/ril.cpp
static int
processcommandbuffer(void *buffer, size_t buflen) {
... ...
p.setdata((uint8_t *) buffer, buflen); /* 把接受到的数据填装到parcel */
// status checked at end
status = p.readint32(&request); /* 解析request */
status = p.readint32 (&token); /* 解析token,rilj中的serial */
... ...
pri = (requestinfo *)calloc(1, sizeof(requestinfo)); /* 分配一个requestinfo,用于发送请求给vendor ril */
pri->token = token; /* 设置token */
pri->pci = &(s_commands[request]); /* 设置请求 */
ret = pthread_mutex_lock(&s_pendingrequestsmutex);
assert (ret == 0);
pri->p_next = s_pendingrequests; /* 添加到s_pendingrequests请求链表中 */
s_pendingrequests = pri;
ret = pthread_mutex_unlock(&s_pendingrequestsmutex);
assert (ret == 0);
/* slastdispatchedtoken = token; */
pri->pci->dispatchfunction(p, pri); /* 执行事件回调,到这里开始进入vender ril了 */
return 0;
}
我们仍然以获取sim卡状态为例,pri->pci->dispatchfunction(p, pri)对应调用了dispatchvoid()
hardware/ril/libril/ril.cpp
static void
dispatchvoid (parcel& p, requestinfo *pri) {
clearprintbuf;
printrequest(pri->token, pri->pci->requestnumber);
s_callbacks.onrequest(pri->pci->requestnumber, null, 0, pri);
}
s_callbacks.onrequest(pri->pci->requestnumber, null, 0, pri); 调用的就是libreference-ril.c中的onrequest()函数。
以上分析了rild对rilj下发的请求处理流程,下面接着分析rild返回response给rilj的流程。分两种情况,一种对请求的响应,
另一种是主动上报。
libreference-ril对请求处理完毕后,调用ril_onrequestcomplete回复rilj该请求的处理结果。
hardware/ril/libril/ril.cpp
ril_onrequestcomplete(ril_token t, ril_errno e, void *response, size_t responselen) {
... ...
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);
... ...
}
... ...
sendresponse(p);
... ...
}
static int
sendresponse (parcel &p) {
printresponse;
return sendresponseraw(p.data(), p.datasize());
}
static int
sendresponseraw (const void *data, size_t datasize) {
... ...
ret = blockingwrite(fd, (void *)&header, sizeof(header)); /* 先写4字节数据长度 */
if (ret < 0) {
pthread_mutex_unlock(&s_writemutex);
return ret;
}
ret = blockingwrite(fd, data, datasize); /* 再写数据 */
... ...
}
最终是通过sendresponseraw()直接通过写socket回复rilj。对于主动上报的处理是类似的,也是通过sendresponseraw()
上报给rilj。可以参考ril_onunsolicitedresponse()函数。
到此,rilj与rild之间的通信流程已经分析完,后续分析libreference-ril。libreference-ril中先关接口的实现方式,每个modem厂商都不一样。
bc72是通过串口/usb发送at的方式控制,实现通话、短信、上网等功能。
谢谢!
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