在讲这个之前,我们先来点大家都知道的东西,当我们感觉线程一直卡在某个地方,想知道卡在哪里,首先想到的是进行线程dump,而常用的命令是jstack ,我们就可以看到如下线程栈了
2014-06-18 12:56:14 Full thread dump Java HotSpot(TM) 64-Bit Server VM (24.51-b03 mixed mode): "Attach Listener" daemon prio=5 tid=0x00007fb0c6800800 nid=0x440b waiting on condition [0x0000000000000000] java.lang.Thread.State: RUNNABLE "Service Thread" daemon prio=5 tid=0x00007fb0c584d800 nid=0x5303 runnable [0x0000000000000000] java.lang.Thread.State: RUNNABLE "C2 CompilerThread1" daemon prio=5 tid=0x00007fb0c482e000 nid=0x5103 waiting on condition [0x0000000000000000] java.lang.Thread.State: RUNNABLE "C2 CompilerThread0" daemon prio=5 tid=0x00007fb0c482c800 nid=0x4f03 waiting on condition [0x0000000000000000] java.lang.Thread.State: RUNNABLE "Signal Dispatcher" daemon prio=5 tid=0x00007fb0c4815800 nid=0x4d03 runnable [0x0000000000000000] java.lang.Thread.State: RUNNABLE "Finalizer" daemon prio=5 tid=0x00007fb0c4813800 nid=0x3903 in Object.wait() [0x00000001187d2000] java.lang.Thread.State: WAITING (on object monitor) at java.lang.Object.wait(Native Method) - waiting on <0x00000007aaa85568> (a java.lang.ref.ReferenceQueue$Lock) at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:135) - locked <0x00000007aaa85568> (a java.lang.ref.ReferenceQueue$Lock) at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:151) at java.lang.ref.Finalizer$FinalizerThread.run(Finalizer.java:189) "Reference Handler" daemon prio=5 tid=0x00007fb0c4800000 nid=0x3703 in Object.wait() [0x00000001186cf000] java.lang.Thread.State: WAITING (on object monitor) at java.lang.Object.wait(Native Method) - waiting on <0x00000007aaa850f0> (a java.lang.ref.Reference$Lock) at java.lang.Object.wait(Object.java:503) at java.lang.ref.Reference$ReferenceHandler.run(Reference.java:133) - locked <0x00000007aaa850f0> (a java.lang.ref.Reference$Lock) "main" prio=5 tid=0x00007fb0c5800800 nid=0x1903 waiting on condition [0x0000000107962000] java.lang.Thread.State: TIMED_WAITING (sleeping) at java.lang.Thread.sleep(Native Method) at Test.main(Test.java:5) "VM Thread" prio=5 tid=0x00007fb0c583d800 nid=0x3503 runnable "GC task thread#0 (ParallelGC)" prio=5 tid=0x00007fb0c401e000 nid=0x2503 runnable "GC task thread#1 (ParallelGC)" prio=5 tid=0x00007fb0c401e800 nid=0x2703 runnable "GC task thread#2 (ParallelGC)" prio=5 tid=0x00007fb0c401f800 nid=0x2903 runnable "GC task thread#3 (ParallelGC)" prio=5 tid=0x00007fb0c4020000 nid=0x2b03 runnable "GC task thread#4 (ParallelGC)" prio=5 tid=0x00007fb0c4020800 nid=0x2d03 runnable "GC task thread#5 (ParallelGC)" prio=5 tid=0x00007fb0c4021000 nid=0x2f03 runnable "GC task thread#6 (ParallelGC)" prio=5 tid=0x00007fb0c4022000 nid=0x3103 runnable "GC task thread#7 (ParallelGC)" prio=5 tid=0x00007fb0c4022800 nid=0x3303 runnable "VM Periodic Task Thread" prio=5 tid=0x00007fb0c5845000 nid=0x5503 waiting on condition
大家是否注意过上面圈起来的两个线程,”Attach Listener”和“Signal Dispatcher”,这两个线程是我们这次要讲的Attach机制的关键,先偷偷告诉各位,其实Attach Listener这个线程在jvm起来的时候可能并没有的,后面会细说。
那Attach机制是什么?说简单点就是jvm提供一种jvm进程间通信的能力,能让一个进程传命令给另外一个进程,并让它执行内部的一些操作,比如说我们为了让另外一个jvm进程把线程dump出来,那么我们跑了一个jstack的进程,然后传了个pid的参数,告诉它要哪个进程进行线程dump,既然是两个进程,那肯定涉及到进程间通信,以及传输协议的定义,比如要执行什么操作,传了什么参数等
总结起来说,比如内存dump,线程dump,类信息统计(比如加载的类及大小以及实例个数等),动态加载agent(使用过btrace的应该不陌生),动态设置vm flag(但是并不是所有的flag都可以设置的,因为有些flag是在jvm启动过程中使用的,是一次性的),打印vm flag,获取系统属性等,这些对应的源码(AttachListener.cpp)如下
static AttachOperationFunctionInfo funcs[] = { { "agentProperties", get_agent_properties }, { "datadump", data_dump }, { "dumpheap", dump_heap }, { "load", JvmtiExport::load_agent_library }, { "properties", get_system_properties }, { "threaddump", thread_dump }, { "inspectheap", heap_inspection }, { "setflag", set_flag }, { "printflag", print_flag }, { "jcmd", jcmd }, { NULL, NULL } };
后面是命令对应的处理函数。
前面也提到了,jvm在启动过程中可能并没有启动Attach Listener这个线程,可以通过jvm参数来启动,代码 (Threads::create_vm)如下:
if (!DisableAttachMechanism) { if (StartAttachListener || AttachListener::init_at_startup()) { AttachListener::init(); } } bool AttachListener::init_at_startup() { if (ReduceSignalUsage) { return true; } else { return false; } }
其中DisableAttachMechanism,StartAttachListener ,ReduceSignalUsage均默认是false(globals.hpp)
product(bool, DisableAttachMechanism, false, \ "Disable mechanism that allows tools to Attach to this VM”) product(bool, StartAttachListener, false, \ "Always start Attach Listener at VM startup") product(bool, ReduceSignalUsage, false, \ "Reduce the use of OS signals in Java and/or the VM”)
因此AttachListener::init()并不会被执行,而Attach Listener线程正是在此方法里创建的
// Starts the Attach Listener thread void AttachListener::init() { EXCEPTION_MARK; klassOop k = SystemDictionary::resolve_or_fail(vmSymbols::java_lang_Thread(), true, CHECK); instanceKlassHandle klass (THREAD, k); instanceHandle thread_oop = klass->allocate_instance_handle(CHECK); const char thread_name[] = "Attach Listener"; Handle string = java_lang_String::create_from_str(thread_name, CHECK); // Initialize thread_oop to put it into the system threadGroup Handle thread_group (THREAD, Universe::system_thread_group()); JavaValue result(T_VOID); JavaCalls::call_special(&result, thread_oop, klass, vmSymbols::object_initializer_name(), vmSymbols::threadgroup_string_void_signature(), thread_group, string, CHECK); KlassHandle group(THREAD, SystemDictionary::ThreadGroup_klass()); JavaCalls::call_special(&result, thread_group, group, vmSymbols::add_method_name(), vmSymbols::thread_void_signature(), thread_oop, // ARG 1 CHECK); { MutexLocker mu(Threads_lock); JavaThread* listener_thread = new JavaThread(&Attach_listener_thread_entry); // Check that thread and osthread were created if (listener_thread == NULL || listener_thread->osthread() == NULL) { vm_exit_during_initialization("java.lang.OutOfMemoryError", "unable to create new native thread"); } java_lang_Thread::set_thread(thread_oop(), listener_thread); java_lang_Thread::set_daemon(thread_oop()); listener_thread->set_threadObj(thread_oop()); Threads::add(listener_thread); Thread::start(listener_thread); } }
既然在启动的时候不会创建这个线程,那么我们在上面看到的那个线程是怎么创建的呢,这个就要关注另外一个线程“Signal Dispatcher”了,顾名思义是处理信号的,这个线程是在jvm启动的时候就会创建的,具体代码就不说了。
下面以jstack的实现来说明触发Attach这一机制进行的过程,jstack命令的实现其实是一个叫做JStack.java的类,查看jstack代码后会走到下面的方法里
private static void runThreadDump(String pid, String args[]) throws Exception { VirtualMachine vm = null; try { vm = VirtualMachine.Attach(pid); } catch (Exception x) { String msg = x.getMessage(); if (msg != null) { System.err.println(pid + ": " + msg); } else { x.printStackTrace(); } if ((x instanceof AttachNotSupportedException) && (loadSAClass() != null)) { System.err.println("The -F option can be used when the target " + "process is not responding"); } System.exit(1); } // Cast to HotSpotVirtualMachine as this is implementation specific // method. InputStream in = ((HotSpotVirtualMachine)vm).remoteDataDump((Object[])args); // read to EOF and just print output byte b[] = new byte[256]; int n; do { n = in.read(b); if (n > 0) { String s = new String(b, 0, n, "UTF-8"); System.out.print(s); } } while (n > 0); in.close(); vm.detach(); }
请注意VirtualMachine.Attach(pid);这行代码,触发Attach pid的关键,如果是在linux下会走到下面的构造函数
LinuxVirtualMachine(AttachProvider provider, String vmid) throws AttachNotSupportedException, IOException { super(provider, vmid); // This provider only understands pids int pid; try { pid = Integer.parseInt(vmid); } catch (NumberFormatException x) { throw new AttachNotSupportedException("Invalid process identifier"); } // Find the socket file. If not found then we attempt to start the // Attach mechanism in the target VM by sending it a QUIT signal. // Then we attempt to find the socket file again. path = findSocketFile(pid); if (path == null) { File f = createAttachFile(pid); try { // On LinuxThreads each thread is a process and we don't have the // pid of the VMThread which has SIGQUIT unblocked. To workaround // this we get the pid of the "manager thread" that is created // by the first call to pthread_create. This is parent of all // threads (except the initial thread). if (isLinuxThreads) { int mpid; try { mpid = getLinuxThreadsManager(pid); } catch (IOException x) { throw new AttachNotSupportedException(x.getMessage()); } assert(mpid >= 1); sendQuitToChildrenOf(mpid); } else { sendQuitTo(pid); } // give the target VM time to start the Attach mechanism int i = 0; long delay = 200; int retries = (int)(AttachTimeout() / delay); do { try { Thread.sleep(delay); } catch (InterruptedException x) { } path = findSocketFile(pid); i++; } while (i <= retries && path == null); if (path == null) { throw new AttachNotSupportedException( "Unable to open socket file: target process not responding " + "or HotSpot VM not loaded"); } } finally { f.delete(); } } // Check that the file owner/permission to avoid Attaching to // bogus process checkPermissions(path); // Check that we can connect to the process // - this ensures we throw the permission denied error now rather than // later when we attempt to enqueue a command. int s = socket(); try { connect(s, path); } finally { close(s); } }
这里要解释下代码了,首先看到调用了createAttachFile方法在目标进程的cwd目录下创建了一个文件/proc//cwd/.Attach_pid,这个在后面的信号处理过程中会取出来做判断(为了安全),另外我们知道在linux下线程是用进程实现的,在jvm启动过程中会创建很多线程,比如我们上面的信号线程,也就是会看到很多的pid(应该是LWP),那么如何找到这个信号处理线程呢,从上面实现来看是找到我们传进去的pid的父进程,然后给它的所有子进程都发送一个SIGQUIT信号,而jvm里除了信号线程,其他线程都设置了对此信号的屏蔽,因此收不到该信号,于是该信号就传给了“Signal Dispatcher”,在传完之后作轮询等待看目标进程是否创建了某个文件,AttachTimeout默认超时时间是5000ms,可通过设置系统变量sun.tools.Attach.AttachTimeout来指定,下面是Signal Dispatcher线程的entry实现
static void signal_thread_entry(JavaThread* thread, TRAPS) { os::set_priority(thread, NearMaxPriority); while (true) { int sig; { // FIXME : Currently we have not decieded what should be the status // for this java thread blocked here. Once we decide about // that we should fix this. sig = os::signal_wait(); } if (sig == os::sigexitnum_pd()) { // Terminate the signal thread return; } switch (sig) { case SIGBREAK: { // Check if the signal is a trigger to start the Attach Listener - in that // case don't print stack traces. if (!DisableAttachMechanism && AttachListener::is_init_trigger()) { continue; } // Print stack traces // Any SIGBREAK operations added here should make sure to flush // the output stream (e.g. tty->flush()) after output. See 4803766. // Each module also prints an extra carriage return after its output. VM_PrintThreads op; VMThread::execute(&op); VM_PrintJNI jni_op; VMThread::execute(&jni_op); VM_FindDeadlocks op1(tty); VMThread::execute(&op1); Universe::print_heap_at_SIGBREAK(); if (PrintClassHistogram) { VM_GC_HeapInspection op1(gclog_or_tty, true /* force full GC before heap inspection */, true /* need_prologue */); VMThread::execute(&op1); } if (JvmtiExport::should_post_data_dump()) { JvmtiExport::post_data_dump(); } break; } …. } } } }
当信号是SIGBREAK(在jvm里做了#define,其实就是SIGQUIT)的时候,就会触发 AttachListener::is_init_trigger()的执行,
bool AttachListener::is_init_trigger() { if (init_at_startup() || is_initialized()) { return false; // initialized at startup or already initialized } char fn[PATH_MAX+1]; sprintf(fn, ".Attach_pid%d", os::current_process_id()); int ret; struct stat64 st; RESTARTABLE(::stat64(fn, &st), ret); if (ret == -1) { snprintf(fn, sizeof(fn), "%s/.Attach_pid%d", os::get_temp_directory(), os::current_process_id()); RESTARTABLE(::stat64(fn, &st), ret); } if (ret == 0) { // simple check to avoid starting the Attach mechanism when // a bogus user creates the file if (st.st_uid == geteuid()) { init(); return true; } } return false; }
一开始会判断当前进程目录下是否有个.Attach_pid文件(前面提到了),如果没有就会在/tmp下创建一个/tmp/.Attach_pid,当那个文件的uid和自己的uid是一致的情况下(为了安全)再调用init方法
// Starts the Attach Listener thread void AttachListener::init() { EXCEPTION_MARK; klassOop k = SystemDictionary::resolve_or_fail(vmSymbols::java_lang_Thread(), true, CHECK); instanceKlassHandle klass (THREAD, k); instanceHandle thread_oop = klass->allocate_instance_handle(CHECK); const char thread_name[] = "Attach Listener"; Handle string = java_lang_String::create_from_str(thread_name, CHECK); // Initialize thread_oop to put it into the system threadGroup Handle thread_group (THREAD, Universe::system_thread_group()); JavaValue result(T_VOID); JavaCalls::call_special(&result, thread_oop, klass, vmSymbols::object_initializer_name(), vmSymbols::threadgroup_string_void_signature(), thread_group, string, CHECK); KlassHandle group(THREAD, SystemDictionary::ThreadGroup_klass()); JavaCalls::call_special(&result, thread_group, group, vmSymbols::add_method_name(), vmSymbols::thread_void_signature(), thread_oop, // ARG 1 CHECK); { MutexLocker mu(Threads_lock); JavaThread* listener_thread = new JavaThread(&Attach_listener_thread_entry); // Check that thread and osthread were created if (listener_thread == NULL || listener_thread->osthread() == NULL) { vm_exit_during_initialization("java.lang.OutOfMemoryError", "unable to create new native thread"); } java_lang_Thread::set_thread(thread_oop(), listener_thread); java_lang_Thread::set_daemon(thread_oop()); listener_thread->set_threadObj(thread_oop()); Threads::add(listener_thread); Thread::start(listener_thread); } }
此时水落石出了,看到创建了一个线程,并且取名为Attach Listener。再看看其子类LinuxAttachListener的init方法
int LinuxAttachListener::init() { char path[UNIX_PATH_MAX]; // socket file char initial_path[UNIX_PATH_MAX]; // socket file during setup int listener; // listener socket (file descriptor) // register function to cleanup ::atexit(listener_cleanup); int n = snprintf(path, UNIX_PATH_MAX, "%s/.java_pid%d", os::get_temp_directory(), os::current_process_id()); if (n < (int)UNIX_PATH_MAX) { n = snprintf(initial_path, UNIX_PATH_MAX, "%s.tmp", path); } if (n >= (int)UNIX_PATH_MAX) { return -1; } // create the listener socket listener = ::socket(PF_UNIX, SOCK_STREAM, 0); if (listener == -1) { return -1; } // bind socket struct sockaddr_un addr; addr.sun_family = AF_UNIX; strcpy(addr.sun_path, initial_path); ::unlink(initial_path); int res = ::bind(listener, (struct sockaddr*)&addr, sizeof(addr)); if (res == -1) { RESTARTABLE(::close(listener), res); return -1; } // put in listen mode, set permissions, and rename into place res = ::listen(listener, 5); if (res == 0) { RESTARTABLE(::chmod(initial_path, S_IREAD|S_IWRITE), res); if (res == 0) { res = ::rename(initial_path, path); } } if (res == -1) { RESTARTABLE(::close(listener), res); ::unlink(initial_path); return -1; } set_path(path); set_listener(listener); return 0; }
看到其创建了一个监听套接字,并创建了一个文件/tmp/.java_pid,这个文件就是客户端之前一直在轮询等待的文件,随着这个文件的生成,意味着Attach的过程圆满结束了。
看看它的entry实现Attach_listener_thread_entry
static void Attach_listener_thread_entry(JavaThread* thread, TRAPS) { os::set_priority(thread, NearMaxPriority); thread->record_stack_base_and_size(); if (AttachListener::pd_init() != 0) { return; } AttachListener::set_initialized(); for (;;) { AttachOperation* op = AttachListener::dequeue(); if (op == NULL) { return; // dequeue failed or shutdown } ResourceMark rm; bufferedStream st; jint res = JNI_OK; // handle special detachall operation if (strcmp(op->name(), AttachOperation::detachall_operation_name()) == 0) { AttachListener::detachall(); } else { // find the function to dispatch too AttachOperationFunctionInfo* info = NULL; for (int i=0; funcs[i].name != NULL; i++) { const char* name = funcs[i].name; assert(strlen(name) <= AttachOperation::name_length_max, "operation <= name_length_max"); if (strcmp(op->name(), name) == 0) { info = &(funcs[i]); break; } } // check for platform dependent Attach operation if (info == NULL) { info = AttachListener::pd_find_operation(op->name()); } if (info != NULL) { // dispatch to the function that implements this operation res = (info->func)(op, &st); } else { st.print("Operation %s not recognized!", op->name()); res = JNI_ERR; } } // operation complete - send result and output to client op->complete(res, &st); } }
从代码来看就是从队列里不断取AttachOperation,然后找到请求命令对应的方法进行执行,比如我们一开始说的jstack命令,找到 { “threaddump”, thread_dump }的映射关系,然后执行thread_dump方法
再来看看其要调用的AttachListener::dequeue(),
AttachOperation* AttachListener::dequeue() { JavaThread* thread = JavaThread::current(); ThreadBlockInVM tbivm(thread); thread->set_suspend_equivalent(); // cleared by handle_special_suspend_equivalent_condition() or // java_suspend_self() via check_and_wait_while_suspended() AttachOperation* op = LinuxAttachListener::dequeue(); // were we externally suspended while we were waiting? thread->check_and_wait_while_suspended(); return op; }
最终调用的是LinuxAttachListener::dequeue(),
LinuxAttachOperation* LinuxAttachListener::dequeue() { for (;;) { int s; // wait for client to connect struct sockaddr addr; socklen_t len = sizeof(addr); RESTARTABLE(::accept(listener(), &addr, &len), s); if (s == -1) { return NULL; // log a warning? } // get the credentials of the peer and check the effective uid/guid // - check with jeff on this. struct ucred cred_info; socklen_t optlen = sizeof(cred_info); if (::getsockopt(s, SOL_SOCKET, SO_PEERCRED, (void*)&cred_info, &optlen) == -1) { int res; RESTARTABLE(::close(s), res); continue; } uid_t euid = geteuid(); gid_t egid = getegid(); if (cred_info.uid != euid || cred_info.gid != egid) { int res; RESTARTABLE(::close(s), res); continue; } // peer credential look okay so we read the request LinuxAttachOperation* op = read_request(s); if (op == NULL) { int res; RESTARTABLE(::close(s), res); continue; } else { return op; } } }
我们看到如果没有请求的话,会一直accept在那里,当来了请求,然后就会创建一个套接字,并读取数据,构建出LinuxAttachOperation返回并执行。
整个过程就这样了,从Attach线程创建到接收请求,处理请求。