问题描述
在我的应用程序中,我使用JNA来使用用C编写的本机代码,在回调中我从本机应用程序获得通知。
在回调中,我得到一个指针和一些其他要处理的数据。在JNA回调代码中,我必须再次使用该指针来调用其他本机库代码,并且必须传递该指针。之后,我必须从该回调返回。
如果我不从回调调用中间本机库方法(传递指针),它工作得很好,但如果我添加这个调用,我的应用程序会间歇性地崩溃(主要是在处理了数百个回调请求之后,有时它也成功地运行了数千个回调)。
在本机代码中为其设置挂钩的NotificationHook类对象是一个静态变量,因为应用程序将只有一个挂钩。和本地库逐一调用。
public interface INotificationHook extends Callback {
public int NotificationHook(TRANX htrans, NOTIFICATION.ByReference notification);
}
public class NotificationHook implements INotificationHook {
@Override
public int NotificationHook(final TRANX tranx, final NOTIFICATION.ByReference notification) {
System.out.println("Enter Java Callback");
// notification contains actual data to process
library.SendSrvcResponse(tranx); // if I put this method call, application crashes intermittently
System.out.println("Exit Java Callback");
return 0;
}
}
Tranx本地结构:
typedef struct tagTRANX { int unused; } *TRANX;
TRANX.java
import com.sun.jna.Pointer;
import com.sun.jna.Structure;
import com.sun.jna.Structure.FieldOrder;
@FieldOrder({"unused"})
public class TRANX extends Structure {
public static class ByReference extends TRANX implements Structure.ByReference {
}
public static class ByValue extends TRANX implements Structure.ByValue {
}
public int unused = 0;
public TRANX () {
super();
}
public TRANX(final int unused) {
super();
this.unused = unused;
}
public TRANX(final Pointer peer) {
super(peer);
}
}
JNA中的库定义(Java):
int SendSrvcResponse(TRANX tranx);
该指针实际上是一个结构指针,我尝试创建一个结构并将该指针替换为该指针,即使在这种情况下应用程序也会崩溃。
当我添加很少的进出日志时,观察结果如下:
printf("Enter to JNA from c library for callback");
hs = (*piHook->hookProc) (
tranx, notification);
printf("Callback completed from JNA and returned to c library");
中间调用c库:
SendSrvcResponse(TRANX tranx) {
printf("Enter to send response in c library");
// do some operation
printf("Enter to send response in c library");
}
每次成功执行时,这是我从控制台(集合JNA和C库)的打印日志中获得的信息:
从c库进入JNA//C库调用JNA回调 输入Java回调//Java回调调用Enter发送 c库中的响应//调用本机库中的方法发送 在c库中回车以发送响应//本机库中的方法在发送响应后退出 退出Java回调//Java 回调完成其操作 JNA回调完成后返回到c库//,将流程返回到c库 代码 在应用程序崩溃的情况下,打印日志中缺少最后一条语句。只有JNA将方法流返回给C,但C不会接收它。其中通知是指针。
崩溃日志:
#
# A fatal error has been detected by the Java Runtime Environment:
#
# SIGSEGV (0xb) at pc=0x0000ffff6c78f610, pid=6396, tid=0x0000ffff6d9f0ac8
#
# JRE version: OpenJDK Runtime Environment (8.0_272-b10) (build 1.8.0_272-b10)
# Java VM: OpenJDK 64-Bit Server VM (25.272-b10 mixed mode linux-aarch64 compressed oops)
# Derivative: IcedTea 3.17.0
# Distribution: Custom build (Fri Dec 11 01:04:16 UTC 2020)
# Problematic frame:
# C [jna791751318727750086.tmp+0xa610] Java_com_sun_jna_Native_setByte+0x50
#
# Core dump written. Default location: **************
#
# If you would like to submit a bug report, please include
# instructions on how to reproduce the bug and visit:
# https://icedtea.classpath.org/bugzilla
# The crash happened outside the Java Virtual Machine in native code.
# See problematic frame for where to report the bug.
#
--------------- T H R E A D ---------------
Current thread (0x0000ffff6c7b7000): JavaThread "Thread-5356" [_thread_in_native, id=6642, stack(0x0000ffff6d9d0000,0x0000ffff6d9f0ac8)]
siginfo: si_signo: 11 (SIGSEGV), si_code: 1 (SEGV_MAPERR), si_addr: 0x0000ffff6c2ec018
Registers:
R0=0x0000000000000000
R1=0x0000000000000000
R2=0x0000ffff6c2ec018
R3=0x0000000000000000
R4=0x0000000000000000
R5=0x0000000000000000
R6=0x0000ffff66b49458
R7=0x0000ffff66b49458
R8=0x0000ffff6c78f5c0
R9=0x0000ffff6c7b72c8
R10=0x0000000020002230
R11=0x00000000f212dde8
R12=0x0000ffff691637f0
R13=0x0000000020002230
R14=0x00000000f212e4e0
R15=0x00000000f213acd0
R16=0x00000001006c7770
R17=0x0000000000000000
R18=0x0000000000000001
R19=0x0000ffff6c7aa250
R20=0x0000000000000000
R21=0x00000000f212e2b0
R22=0x0000000100781ed8
R23=0x00000000f212fd60
R24=0x00000000f213a868
R25=0x00000001000016d0
R26=0x00000000f213a880
R27=0x0000000000000000
R28=0x0000ffff6c7b7000
R29=0x0000ffff6d9efcd0
R30=0x0000ffff78fea394
Top of Stack: (sp=0x0000ffff6d9efcd0)
0x0000ffff6d9efcd0: 0000ffff6d9efd60 0000ffff78fea394
0x0000ffff6d9efce0: 00000000200f03db 0000000000000000
0x0000ffff6d9efcf0: 0000ffff6c2ec018 0000000000000000
0x0000ffff6d9efd00: 0000ffff6c7b7250 00aebfc8f212dfd8
0x0000ffff6d9efd10: 00000000f212dde8 00000000f21343b0
0x0000ffff6d9efd20: 00000000f21342f0 00000000f2134350
0x0000ffff6d9efd30: 00000000f2134368 00000000f2134380
0x0000ffff6d9efd40: 00000000f2134320 00000000f2134398
0x0000ffff6d9efd50: 00000000fca7ebc8 0000ffff77adb000
0x0000ffff6d9efd60: 0000ffff6d9f0220 0000ffff7988acb4
0x0000ffff6d9efd70: 00000000f21343c8 00000000f213a978
0x0000ffff6d9efd80: 0000ffff6d9f0220 0000ffff79952fbc
0x0000ffff6d9efd90: 00000000f213aa28 00000000f213aa68
0x0000ffff6d9efda0: 0000000000000000 00000000f213aae8
0x0000ffff6d9efdb0: 0000ffff6d9efdd0 0000ffff80d78678
0x0000ffff6d9efdc0: 0000000000000000 00000001000115f0
0x0000ffff6d9efdd0: 00000000fc391290 00000000f212e4e0
0x0000ffff6d9efde0: 00000000f212dfd8 00000000fc3a3960
0x0000ffff6d9efdf0: 00000000200eada6 0000000000000000
0x0000ffff6d9efe00: 00000000f21342e0 0000ffff6c7b7000
0x0000ffff6d9efe10: 00000000fc43c670 00000000d024ce28
0x0000ffff6d9efe20: 0000ffff6d9f0220 0000ffff799275fc
0x0000ffff6d9efe30: 00000000f212e4e0 00000000f212fb00
0x0000ffff6d9efe40: 00000000d0d14760 00000000d0d14760
0x0000ffff6d9efe50: 00000000f2131bc0 f212f75000000000
0x0000ffff6d9efe60: 0000ffff6d9f0220 0000ffff78eccdd8
0x0000ffff6d9efe70: 00000000f2131c20 00000000f212e398
0x0000ffff6d9efe80: 0000ffff6d9f0220 0000ffff79463d2c
0x0000ffff6d9efe90: 200f03db00000000 0000000100781ed8
0x0000ffff6d9efea0: 00000000f213acb0 00000000f21342e0
0x0000ffff6d9efeb0: 00000000f212e398 0000000000000000
0x0000ffff6d9efec0: 00000000f212e4e0 0000000000000000
Instructions: (pc=0x0000ffff6c78f610)
0x0000ffff6c78f5f0: e1 ff 00 91 1f 00 01 eb a3 02 00 54 e2 0f 42 a9
0x0000ffff6c78f600: c0 00 00 f0 00 40 09 91 e1 ff 40 39 00 20 42 b9
0x0000ffff6c78f610: 41 68 23 38 e0 00 00 34 e0 1b 40 f9 22 00 00 b0
0x0000ffff6c78f620: 21 00 00 b0 42 80 30 91 21 e0 30 91 45 e5 ff 97
Register to memory mapping:
R0=0x0000000000000000
R1=0x0000000000000000
R2=0x0000ffff6c2ec018
R3=0x0000000000000000
R4=0x0000000000000000
R5=0x0000000000000000
R6=0x0000ffff66b49458
R7=0x0000ffff66b49458
R8=0x0000ffff6c78f5c0
R9=0x0000ffff6c7b72c8
R10=0x0000000020002230
R11=0x00000000f212dde8
R12=0x0000ffff691637f0
R13=0x0000000020002230
R14=0x00000000f212e4e0
R15=0x00000000f213acd0
R16=0x00000001006c7770
R17=0x0000000000000000
R18=0x0000000000000001
R19=0x0000ffff6c7aa250
R20=0x0000000000000000
R21=0x00000000f212e2b0
R22=0x0000000100781ed8
R23=0x00000000f212fd60
R24=0x00000000f213a868
R25=0x00000001000016d0
R26=0x00000000f213a880
R27=0x0000000000000000
R28=0x0000ffff6c7b7000
R29=0x0000ffff6d9efcd0
R30=0x0000ffff78fea394
Stack: [0x0000ffff6d9d0000,0x0000ffff6d9f0ac8], sp=0x0000ffff6d9efcd0, free space=127k
Native frames: (J=compiled Java code, j=interpreted, Vv=VM code, C=native code)
C [jna791751318727750086.tmp+0xa610] Java_com_sun_jna_Native_setByte+0x50
J 5174 com.sun.jna.Native.setByte(Lcom/sun/jna/Pointer;JJB)V (0 bytes) @ 0x0000ffff78fea394 [0x0000ffff78fea300+0x94]
V [libjvm.so+0x40f678]
C 0x00000000f212e4e0
Java frames: (J=compiled Java code, j=interpreted, Vv=VM code)
J 5174 com.sun.jna.Native.setByte(Lcom/sun/jna/Pointer;JJB)V (0 bytes) @ 0x0000ffff78fea398 [0x0000ffff78fea300+0x98]
J 9695 C2 com.sun.jna.Pointer.setByte(JB)V (11 bytes) @ 0x0000ffff7988acb4 [0x0000ffff7988ac80+0x34]
J 9266 C2 com.sun.jna.Pointer.setValue(JLjava/lang/Object;Ljava/lang/Class;)V (607 bytes) @ 0x0000ffff79952fbc [0x0000ffff79951ec0+0x10fc]
J 9230 C2 com.sun.jna.Structure.writeField(Lcom/sun/jna/Structure$StructField;)V (427 bytes) @ 0x0000ffff799275fc [0x0000ffff79927500+0xfc]
J 9423 C2 com.sun.jna.Structure.write()V (126 bytes) @ 0x0000ffff79463d2c [0x0000ffff79463840+0x4ec]
J 9434 C2 com.sun.jna.Structure.autoWrite()V (45 bytes) @ 0x0000ffff7904e274 [0x0000ffff7904e240+0x34]
J 9905 C1 com.sun.jna.CallbackReference$DefaultCallbackProxy.invokeCallback([Ljava/lang/Object;)Ljava/lang/Object; (238 bytes) @ 0x0000ffff78ee17c4 [0x0000ffff78ede580+0x3244]
J 9904 C1 com.sun.jna.CallbackReference$DefaultCallbackProxy.callback([Ljava/lang/Object;)Ljava/lang/Object; (22 bytes) @ 0x0000ffff78fa18b0 [0x0000ffff78fa1800+0xb0]
v ~StubRoutines::call_stub
我尝试过的内容:
在JNA回调输入中用指针替换Tranx。 在Java回调方法的最后一行对结构调用clear()。
在JNA中注释完整的处理回调代码,只保留对SendSrvcResponse方法的调用并返回回调。
所有这些都会导致崩溃,没有一个是有帮助的。
一个奇怪的观察是,当在本机C代码中实现此回调时,应用程序不会中断。只有在与JNA集成时才会中断。
有人能帮我了解一下这一事件的可能原因吗?或者我怎样才能进一步调查它?
推荐答案
根据您提供的代码,问题与这里的其他回调相关问题相同:由于JAVA的垃圾回收,您正在丢失TRANX的本机分配。
JNAStructure由两部分组成:(指向数据的)指针和数据本身。您尚未为TRANX提供本机typlef来确认您的JNA映射,但实例化的对象将有一个内部指针引用,指向4字节的内存分配(int unused)。
您只显示回调代码,其中TRANX已经是一个参数,这意味着您已经将其实例化以传递给回调。
如果您使用new TRANX()或new TRANX(int unused)自己分配它,则JNA已
Structure的本机内存作为垃圾收集过程的一部分被自动释放。这是回调的常见问题,因为您通常不控制回调返回的时间,因此会出现以下顺序:
在Java中创建对象(分配TRANX结构在内部跟踪指针所指向的本机4字节)
将TRANX对象传递给回调
传递对象后,Java立即不再需要自己的对象;它是不可访问的,因此有资格进行垃圾回收
发生GC时,本机4字节作为进程的一部分被释放
回调中的TRANX对象在内部仍有指针,但它现在指向不再分配的内存,从而导致SIGSEGV(或无效内存访问错误,或由另一个线程分配内存时出现奇怪症状,或其他未定义的行为)。
该问题的解决方案是跟踪与TRANX关联的内存。
TRANX对象的引用,以防止它无法到达。
这通常需要在您确定回调将被处理之后访问TRANX结构
在JDK9+中,ReachabilityFence可用于此。
在JDK8中,您应该以某种方式操作类(例如,从类中读取值,或对其调用toString等)。
如果您使用本机分配并使用从本机API返回的peer值创建指针,则读取API以确定何时释放该内存。