// Copyright (c) 1995-2010 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "Eclipse Public License v1.0"
// which accompanies this distribution, and is available
// at the URL "http://www.eclipse.org/legal/epl-v10.html".
//
// Initial Contributors:
// Nokia Corporation - initial contribution.
//
// Contributors:
//
// Description:
// e32test\thread\t_thread.cpp
// Overview:
// Tests the RThread class
// API Information:
// RThread, RUndertaker
// Details:
// - Create a thread, verify its priority, change the priority and verify results.
// - Verify naming and renaming threads works as expected.
// - Test logging on, resuming and closing a thread. Verify results are as expected.
// - Test creating threads with a variety of invalid parameters. Verify results.
// - Test the RUndertaker methods: create some threads, logon to the undertaker,
// verify results upon killing a thread and setting the thread handle.
// - Check kernel allocation when creating threads and undertakers. Verify the
// heap has not been corrupted.
// - Run a thread multiple times, panic within the thread, panic external to the
// thread and exit a thread in a variety of ways. Verify results are as expected.
// - Create a semaphore and some threads, verify the threads can wait on and signal
// the semaphore.
// - Test unclosed but completed threads.
// - Suspend and resume some threads in a variety of ways, verify results are as
// expected.
// - Test thread duplication.
// - Test opening a thread using an full name, perform various tests by finding,
// killing, closing, recreating etc. Verify the results are as expected.
// - Test creating a thread using a duplicate name then reuse the thread with a
// valid name. Verify results are as expected.
// - Verify that a panicked thread releases an existing mutex.
// - Test thread ID: attempt to open a nonexistent thread by ID, verify different
// threads have different IDs, verify open by ID works as expected.
// - Test RThread::StackInfo(), print results and verify results are as expected.
// Platforms/Drives/Compatibility:
// All.
// Assumptions/Requirement/Pre-requisites:
// Failures and causes:
// Base Port information:
//
//
#define __E32TEST_EXTENSION__
#include <e32test.h>
#include <e32panic.h>
#include <e32svr.h>
#include <u32hal.h>
#include <e32atomics.h>
#include <e32def.h>
#include <e32def_private.h>
#include "../misc/prbs.h"
const TInt KNumThreads=20;
const TInt KExitPanicNum=999;
const TInt KHeapSize=0x200;
const TInt KThreadReturnValue=9999;
const TInt KTerminationReason=1234;
const TInt KKillReason=4321;
enum TInstruction {ENormal,EInstrPanic,EWait};
const TInt KWaitTime=800000;
class TReadInfo
{
public:
TDesC* tdesc;
TPtrC* tptrc;
TDes* tdes;
TPtr* tptr;
HBufC* hbufc;
TBufC<0x20>* tbufc;
TBuf<0x20>* tbuf;
TPtr* tptrdes;
TAny* anAddress;
};
LOCAL_D RTest test(_L("T_THREAD"));
LOCAL_D RTest rtest(_L("Read thread tests"));
LOCAL_D RTest wtest(_L("Write thread tests"));
#define rtest(x) rtest(x,__LINE__)
#define wtest(x) wtest(x,__LINE__)
LOCAL_C TInt LoopyThread(TAny*)
{
FOREVER
User::AfterHighRes(1000);
}
LOCAL_D void testUndertaker(TOwnerType anOwnerType)
//
// Test RThreadWatcher
//
{
RThread thread1;
TInt r;
test.Start(_L("Test the RUndertaker class"));
test.Next(_L("Create a thread"));
// if (anOwnerType==EOwnerThread)
// User::SetDebugMask(0x8000867c);
r=thread1.Create(_L("Loopy1"),LoopyThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)NULL,anOwnerType);
test(r==KErrNone);
thread1.Resume();
TRequestStatus stat1;
TInt threadHandle1;
RThread w1;
RUndertaker u1;
test.Next(_L("Create an RUndertaker"));
r=u1.Create();
test(r==KErrNone);
test.Next(_L("Logon to RUndertaker"));
r=u1.Logon(stat1,threadHandle1);
test(r==KErrNone);
test.Next(_L("Logon again & check we're rejected"));
r=u1.Logon(stat1,threadHandle1);
test(r==KErrInUse);
test.Next(_L("Cancel logon to RUndertaker"));
r=u1.LogonCancel();
test(r==KErrNone);
test(stat1==KErrCancel);
test.Next(_L("Logon to RUndertaker again"));
u1.Logon(stat1,threadHandle1);
test.Next(_L("Create another thread"));
RThread thread2;
r=thread2.Create(_L("Loopy2"),LoopyThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)NULL,anOwnerType);
test(r==KErrNone);
thread2.Resume();
TRequestStatus stat2;
TInt threadHandle2;
RThread w2;
RUndertaker u2;
test.Next(_L("Create another RUndertaker"));
r=u2.Create();
test(r==KErrNone);
test.Next(_L("Logon to RUndertaker"));
r=u2.Logon(stat2,threadHandle2);
test(r==KErrNone);
test.Next(_L("Create yet another thread"));
RThread thread3;
r=thread3.Create(_L("Loopy3"),LoopyThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)NULL,anOwnerType);
test(r==KErrNone);
thread3.Resume();
test.Next(_L("Kill the first thread & check the undertakers"));
thread1.Kill(0x489);
thread1.Close();
User::WaitForRequest(stat1);
User::WaitForRequest(stat2);
test(stat1==KErrDied);
test(stat2==KErrDied);
RThread keep1;
RThread keep2;
test.Next(_L("Set the RThread handles"));
keep1.SetHandle(threadHandle1);
keep2.SetHandle(threadHandle2);
test.Next(_L("Test the exit reasons"));
test(keep1.ExitReason()==0x489);
test(keep2.ExitReason()==0x489);
// test.Printf(_L("Thread name %S\n"),&(w1.Name()));
test.Next(_L("Logon again with both watchers"));
r=u1.Logon(stat1,threadHandle1);
test(r==KErrNone);
r=u2.Logon(stat2,threadHandle2);
test(r==KErrNone);
test.Next(_L("Kill the 3rd thread & check the undertakers"));
thread3.Kill(0x999);
thread3.Close();
User::WaitForRequest(stat1);
User::WaitForRequest(stat2);
test(stat1==KErrDied);
test(stat2==KErrDied);
test.Next(_L("Set the RThread handles"));
w1.SetHandle(threadHandle1);
w2.SetHandle(threadHandle2);
test.Next(_L("Test the exit reasons"));
test(w1.ExitReason()==0x999);
test(w2.ExitReason()==0x999);
// test.Printf(_L("Thread name %S\n"),&(w1.Name()));
w1.Close();
CLOSE_AND_WAIT(w2);
test.Next(_L("Logon again with both undertakers"));
r=u1.Logon(stat1,threadHandle1);
test(r==KErrNone);
r=u2.Logon(stat2,threadHandle2);
test(r==KErrNone);
test.Next(_L("Kill the 2nd thread & check the undertakers"));
thread2.Kill(0x707);
thread2.Close();
User::WaitForRequest(stat1);
User::WaitForRequest(stat2);
test(stat1==KErrDied);
test(stat2==KErrDied);
test.Next(_L("Set the RThread handles"));
w1.SetHandle(threadHandle1);
w2.SetHandle(threadHandle2);
test.Next(_L("Test the exit reasons"));
test(w1.ExitReason()==0x707);
test(w2.ExitReason()==0x707);
// test.Printf(_L("Thread name %S\n"),&(w1.Name()));
test.Next(_L("Check kernel allocation"));
test.Next(_L("Please wait while I create & close masses of threads"));
RThread t[KNumThreads];
TInt j;
for (j=0; j<KNumThreads; j++)
{
TBuf<0x10> name;
name.Format(_L("LoopyThread%d"),j);
test(t[j].Create(name, LoopyThread, KDefaultStackSize, KHeapSize, KHeapSize, (TAny*)NULL,anOwnerType)==KErrNone);
}
for (j=0; j<KNumThreads-1; j++)
{
t[j].Kill(666);
CLOSE_AND_WAIT(t[j]);
}
test.Next(_L("Please wait while I close & create some undertakers"));
u1.Close();
u2.Close();
r=u1.Create();
test(r==KErrNone);
r=u2.Create();
test(r==KErrNone);
test.Next(_L("Mark kernel heap"));
__KHEAP_MARK;
test.Next(_L("Create thread"));
RThread threadx;
r=threadx.Create(_L("Loopyx"),LoopyThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)NULL,anOwnerType);
test(r==KErrNone);
test.Next(_L("Resume thread"));
threadx.Resume();
test.Next(_L("Create undertaker"));
TRequestStatus statx;
TInt threadHandlex;
RUndertaker ux;
r=ux.Create();
test(r==KErrNone);
test.Next(_L("Logon to undertaker"));
r=ux.Logon(statx,threadHandlex);
test(r==KErrNone);
test.Next(_L("Kill thread"));
threadx.Kill(0x666);
threadx.Close();
User::WaitForRequest(statx);
test(statx==KErrDied);
test.Next(_L("Close thread"));
RThread wx;
wx.SetHandle(threadHandlex);
CLOSE_AND_WAIT(wx);
test.Next(_L("Close undertaker"));
ux.Close();
test.Next(_L("Check kernel heap"));
__KHEAP_MARKEND;
w1.Close();
CLOSE_AND_WAIT(w2);
keep1.Close();
CLOSE_AND_WAIT(keep2);
t[KNumThreads-1].Kill(666);
CLOSE_AND_WAIT(t[KNumThreads-1]);
test.Next(_L("Close RUndertakers"));
u1.Close();
u2.Close();
test.End();
}
volatile TInt IFLAG;
TInt InstructionThread(TAny* anInstruction)
{
__e32_atomic_store_ord32(&IFLAG, 1);
RThread::Rendezvous(KErrNone);
TInstruction what=(TInstruction)(TInt)anInstruction;
if (what==EInstrPanic)
User::Panic(_L("Hello"), KExitPanicNum);
if (what==ENormal)
return(KThreadReturnValue);
User::After(500000);
return(KErrNone);
}
TInt StartInstructionThread(RThread& aT, const TDesC& aName, TInt aInstruction, RAllocator* aAllocator, TOwnerType aOwnerType, TRequestStatus* aL, TRequestStatus* aR)
{
TInt r;
if (aAllocator == NULL)
{
r = aT.Create(aName, &InstructionThread, KDefaultStackSize, KHeapSize, KHeapSize, (TAny*)aInstruction, aOwnerType);
}
else
{
r = aT.Create(aName, &InstructionThread, KDefaultStackSize, aAllocator, (TAny*)aInstruction, aOwnerType);
}
if (r!=KErrNone)
return r;
if (aL)
{
aT.Logon(*aL);
TInt s = aL->Int();
test_Equal(s, KRequestPending);
}
if (aR)
{
aT.Rendezvous(*aR);
TInt s = aR->Int();
test_Equal(s, KRequestPending);
aT.Resume();
User::WaitForRequest(*aR);
s = aR->Int();
test_KErrNone(s);
}
return r;
}
LOCAL_D TInt test4Thread(TAny *aSem)
//
// Wait to be released on the semaphore.
// Then release the semaphore.
//
{
RSemaphore& sem=(*(RSemaphore*)aSem);
sem.Wait();
sem.Signal();
return(KErrNone);
}
TInt BadPriority(TAny* aThread)
{
((RThread*)aThread)->SetPriority(EPriorityNull);
return KErrNone;
}
_LIT(KLitRomString,"RomStringRomStringRomStringRomStringRomStringRomStringRomString");
LOCAL_C TInt BadFullNameThread(TAny* aPar)
{
RThread thread;
switch ((TInt)aPar)
{
case 0:
{
HBufC* hBuf = HBufC::New(5);//Size 5 is not sufficient. thread.FullName should panic.
test(NULL != hBuf);
RBuf rBuf(hBuf);
thread.FullName(rBuf);
rBuf.Close();
}
return(KErrNone);
case 1:
{
TPtr ptr((TText*)(KLitRomString.iBuf), KLitRomString.iTypeLength);
// Passing descriptor whose data is in ROM. This may behave in different ways
// on differrent platforms. Here, we just check that Kernel is safe.
thread.FullName(ptr);
}
return(KErrNone);
}
return(KErrArgument);
}
LOCAL_D void test1()
//
// Test 1
//
{
__UHEAP_MARK;
RThread thread;
TRequestStatus stat;
TInt r;
test.Start(_L("Close without create"));
thread.Close();
test.Next(_L("Create ENormal"));
r = StartInstructionThread(thread, _L("Thread"), ENormal, NULL, EOwnerProcess, 0, 0);
test_KErrNone(r);
test.Next(_L("Test priorities"));
test(thread.Priority()==EPriorityNormal);
thread.SetPriority(EPriorityRealTime); // WINS will commute this to EPriorityMuchMore
#if defined(__EPOC32__)
test(thread.Priority()==EPriorityRealTime);
#endif
thread.SetPriority(EPriorityMuchMore);
test(thread.Priority()==EPriorityMuchMore);
// thread.SetPriority(EPriorityNull);
RThread badThread;
r = badThread.Create(_L("Bad Priority"),BadPriority,KDefaultStackSize,KHeapSize,KHeapSize,&thread);
test(r==KErrNone);
badThread.Logon(stat);
test(stat==KRequestPending);
badThread.Resume();
User::WaitForRequest(stat);
test(stat==EBadPriority);
test(badThread.ExitCategory()==_L("KERN-EXEC"));
test(badThread.ExitReason()==EBadPriority);
test(badThread.ExitType()==EExitPanic);
CLOSE_AND_WAIT(badThread);
test(thread.Priority()==EPriorityMuchMore);
#if defined(__EPOC32__)
test.Next(_L("Test setting process priority from thread"));
test(thread.ProcessPriority()==EPriorityForeground);
thread.SetProcessPriority(EPriorityHigh);
test(thread.ProcessPriority()==EPriorityHigh);
test(RProcess().Priority()==EPriorityHigh);
thread.SetProcessPriority(EPriorityForeground);
test(thread.ProcessPriority()==EPriorityForeground);
test(RProcess().Priority()==EPriorityForeground);
#endif
TBuf<0x100> name;
test.Next(_L("Test thread name"));
test(thread.Name()==_L("Thread"));
test.Next(_L("Get owning process name"));
RProcess p;
test(thread.Process(p)==KErrNone);
name=p.Name();
name.Append(_L("::"));
name.Append(thread.Name());
test.Next(_L("Test fullname - via TFullName RHandleBase::FullName"));
test(thread.FullName().CompareF(name)==0);
test.Next(_L("Test fullname - via void RHandleBase::FullName(TDes& aName)"));
HBufC* hBuf = HBufC::New(100);
test(NULL != hBuf);
TPtr ptr = hBuf->Des();
thread.FullName(ptr);
test(ptr.CompareF(name)==0);
RBuf rBuf(hBuf);
thread.FullName(rBuf);
test(rBuf.CompareF(name)==0);
rBuf.Close();
test.Next(_L("Test void RHandleBase::FullName(TDes& aName) when aName is too short"));
TInt aaa=badThread.Create(_L("BadFullNameThread1"),BadFullNameThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)0);
test(aaa==KErrNone);
badThread.Logon(stat);
test(badThread.ExitType()==EExitPending);
badThread.Resume();
User::WaitForRequest(stat);
test(badThread.ExitCategory()==_L("KERN-EXEC"));
test(badThread.ExitReason()==EKUDesSetLengthOverflow);
test(badThread.ExitType()==EExitPanic);
CLOSE_AND_WAIT(badThread);
test.Next(_L("Test void RHandleBase::FullName(TDes& aName) where aName has data in ROM "));
aaa=badThread.Create(_L("BadFullNameThread2"),BadFullNameThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)1);
test(aaa==KErrNone);
badThread.Logon(stat);
test(badThread.ExitType()==EExitPending);
badThread.Resume();
User::WaitForRequest(stat);
test.Printf(_L("BadFullNameThread2 exited with ExitReason=%d and ExitType=%d\n"),badThread.ExitReason(),badThread.ExitType());
CLOSE_AND_WAIT(badThread);
test.Next(_L("Rename current thread"));
test(User::RenameThread(_L("renamed"))==KErrNone);
name=p.Name();
name.Append(_L("::"));
RThread me;
name.Append(me.Name());
test(me.Name()==_L("renamed"));
test(me.FullName().CompareF(name)==0);
test.Next(_L("Test running exit types"));
test(thread.ExitType()==EExitPending);
test(thread.ExitReason()==0);
// no getters for iUserHeap and iFrame
test(thread.ExitCategory()==KNullDesC);
test.Next(_L("Test logging on"));
thread.Logon(stat);
RThread t;
test(t.RequestCount()==0);
test(stat==KRequestPending);
r=thread.LogonCancel(stat); // this generates a signal
test(r==KErrNone);
test(stat==KErrNone);
test(t.RequestCount()==1); // the request count is 1 due to the signal generated by LogonCancel
test(thread.RequestCount()==0);
test.Next(_L("Resuming thread"));
thread.Resume();
test.Next(_L("Absorb cancel"));
User::WaitForRequest(stat);
test.Next(_L("Test LogonCancel on dead thread is ok"));
r=thread.LogonCancel(stat);
test(r==KErrGeneral);
test.Next(_L("Close thread"));
CLOSE_AND_WAIT(thread);
test.Next(_L("Close again"));
thread.Close();
thread.Close();
thread.Close();
thread.Close();
__UHEAP_MARKEND;
test.End();
}
LOCAL_D void test2(TOwnerType anOwnerType)
//
// Test 2
//
{
__UHEAP_MARK;
RThread thread;
TRequestStatus stat;
TRequestStatus rstat;
TInt r;
test.Start(_L("Run thread 10 times"));
for (TInt xx=0;xx<10;xx++)
{
test.Printf(_L("\r%02d"),xx);
r = StartInstructionThread(thread, _L("Thread1"), ENormal, NULL, anOwnerType, &stat, 0);
test_KErrNone(r);
thread.Resume();
User::WaitForRequest(stat);
CLOSE_AND_WAIT(thread);
}
test.Printf(_L("\n"));
test.Next(_L("Panic within thread"));
r = StartInstructionThread(thread, _L("Thread2"), EInstrPanic, NULL, anOwnerType, &stat, 0);
test_KErrNone(r);
test(thread.ExitType()==EExitPending);
thread.Resume();
User::WaitForRequest(stat);
test(thread.ExitCategory()==_L("Hello"));
test(thread.ExitReason()==KExitPanicNum);
test(thread.ExitType()==EExitPanic);
CLOSE_AND_WAIT(thread);
test.Next(_L("Panic external to thread"));
TInt ijk;
TUint seed[2] = { 0xadf85458, 0 };
TUint maxcount = 0;
RHeap* temporaryHeap = User::ChunkHeap(NULL, KHeapSize*8192, KHeapSize*8192);
test(temporaryHeap != NULL);
for (ijk=0; ijk<8192; ++ijk)
{
if (!(ijk&255))
test.Printf(_L("%d\n"), ijk);
//
// For this test we need to use a temporary heap created in advance as we
// will be panicking the thread at any point during its creation and since
// the heap would have been allocated by the user side thread, it is
// possible that if we let it allocate its own heap, the kernel may not
// be able to close it in the temporary states of creation or when
// TLocalThreadData::DllSetTls() grabs a temporary handle on the heap.
// In those cases RTest::CloseHandleAndWaitForDestruction() would timeout
// and the test would fail.
//
// In addition, if we shared the creating thread's heap allocations may
// be left behind and cause the heap mark test to fail on this thread.
//
r = StartInstructionThread(thread, _L("Thread3"), EWait, temporaryHeap, anOwnerType, &stat, 0);
test_KErrNone(r);
__e32_atomic_store_ord32(&IFLAG, 0);
thread.Resume();
thread.SetPriority(EPriorityMore);
if (maxcount==0)
{
while (__e32_atomic_load_acq32(&IFLAG)==0 && --maxcount!=0)
{
}
maxcount = 0u - maxcount;
test.Printf(_L("maxcount=%u\n"), maxcount);
}
else
{
TUint random = Random(seed);
random %= maxcount;
++random;
while (__e32_atomic_load_acq32(&IFLAG)==0 && --random!=0)
{
}
}
thread.Panic(_L("panic"), 123);
User::WaitForRequest(stat);
test(thread.ExitCategory()==_L("panic"));
test(thread.ExitReason()==123);
test(thread.ExitType()==EExitPanic);
r = RTest::CloseHandleAndWaitForDestruction(thread);
test_KErrNone(r);
}
temporaryHeap->Close();
test.Next(_L("Internal exit"));
r = StartInstructionThread(thread, _L("Thread4"), ENormal, NULL, anOwnerType, &stat, 0);
test_KErrNone(r);
test(thread.ExitType()==EExitPending);
thread.Resume();
User::WaitForRequest(stat);
test(thread.ExitCategory()==_L("Kill"));
test(thread.ExitReason()==KThreadReturnValue);
test(thread.ExitType()==EExitKill);
CLOSE_AND_WAIT(thread);
test.Next(_L("External terminate"));
r = StartInstructionThread(thread, _L("Thread5"), EWait, NULL, anOwnerType, &stat, &rstat);
test_KErrNone(r);
test.Next(_L("Terminate"));
thread.Terminate(KTerminationReason);
test.Next(_L("Wait"));
User::WaitForRequest(stat);
test(thread.ExitCategory()==_L("Terminate"));
test(thread.ExitReason()==KTerminationReason);
test(thread.ExitType()==EExitTerminate);
test.Next(_L("Close"));
CLOSE_AND_WAIT(thread);
test.Next(_L("External kill"));
r = StartInstructionThread(thread, _L("Thread6"), EWait, NULL, anOwnerType, &stat, &rstat);
test_KErrNone(r);
thread.Suspend();
thread.Resume();
thread.Kill(KKillReason);
User::WaitForRequest(stat);
test(thread.ExitCategory()==_L("Kill"));
test(thread.ExitReason()==KKillReason);
test(thread.ExitType()==EExitKill);
test.Next(_L("Kill again"));
thread.Kill(KErrNone);
thread.Kill(KErrNone);
thread.Kill(KErrNone);
CLOSE_AND_WAIT(thread);
test.End();
__UHEAP_MARKEND;
}
LOCAL_D void test3()
//
// Test 3.
//
{
test.Start(_L("Read across thread"));
TReadInfo info;
TPtrC des1=_L("tdesc");
info.tdesc=(&des1);
TPtrC ptr1=_L("tptrc");
info.tptrc=&ptr1;
TBuf<0x20> tdes(_L("tdes"));
info.tdes=&tdes;
TBuf<0x20> tptrbuf(_L("tptr"));
TPtr tptr((TText*)tptrbuf.Ptr(),tptrbuf.Length(),tptrbuf.MaxLength());
info.tptr=&tptr;
TBuf<0x20> hbufc(_L("hbufc"));
HBufC *pH=hbufc.Alloc();
test(pH!=NULL);
info.hbufc=pH;
TBufC<0x20> tbufc(_L("tbufc"));
info.tbufc=&tbufc;
TBuf<0x20> tbuf(_L("tbuf"));
info.tbuf=&tbuf;
TBufC<0x20> tptrdes(_L("tptrdes"));
TPtr des=tptrdes.Des();
info.tptrdes=&des;
TBuf<0x10> b(_L("Hello"));
info.anAddress=(&b);
info.anAddress= info.anAddress; //prevents warning (var set but never used)
delete pH;
test.End();
}
LOCAL_D void test4()
//
// Test 4.
//
{
test.Start(_L("Create sempahore"));
RSemaphore sem;
TInt r=sem.CreateLocal(0);
test(r==KErrNone);
//
test.Next(_L("Create thread 1"));
RThread t;
r=t.Create(_L("Thread1"),test4Thread,KDefaultStackSize,KHeapSize,KHeapSize,&sem);
test(r==KErrNone);
t.Resume();
t.Close();
//
test.Next(_L("Create thread 2"));
r=t.Create(_L("Thread2"),test4Thread,KDefaultStackSize,KHeapSize,KHeapSize,&sem);
test(r==KErrNone);
t.Resume();
t.Close();
//
test.Next(_L("Create thread 3"));
r=t.Create(_L("Thread3"),test4Thread,KDefaultStackSize,KHeapSize,KHeapSize,&sem);
test(r==KErrNone);
t.Resume();
t.Close();
//
test.Next(_L("Release threads"));
sem.Signal(3);
//
test.Next(_L("Wait 1"));
sem.Wait();
//
test.Next(_L("Wait 2"));
sem.Wait();
//
test.Next(_L("Wait 2"));
sem.Wait();
sem.Close();
//
test.End();
}
TInt MinimalThread(TAny*)
//
// Minimal thread, used in test 5
//
{
return(KErrNone);
}
LOCAL_D void test5()
//
// Test 5 - tests unclosed but completed threads
//
{
test.Start(_L("Start thread"));
RThread thread1;
test(thread1.Create(_L("Test Thread1"),MinimalThread,KDefaultStackSize,KHeapSize,KHeapSize,NULL)==KErrNone);
TRequestStatus stat1;
thread1.Logon(stat1);
thread1.Resume();
User::WaitForRequest(stat1);
test(thread1.ExitType()==EExitKill);
// 'missing' thread1.Close();
test.Next(_L("Start another thread"));
RThread thread2;
test(thread2.Create(_L("Test Thread2"),MinimalThread,KDefaultStackSize,KHeapSize,KHeapSize,NULL)==KErrNone);
TRequestStatus stat2;
thread2.Logon(stat2);
thread2.Resume();
User::WaitForRequest(stat2); //Goes wrong here in build 48
test(thread2.ExitType()==EExitKill);
test.Next(_L("Close both threads"));
CLOSE_AND_WAIT(thread2);
CLOSE_AND_WAIT(thread1);
test.End();
}
LOCAL_D TInt test6Thread(TAny *anArg)
//
//
//
{
((RSemaphore*)anArg)->Wait();
RThread t;
RThread dup;
dup.Duplicate(t);
dup.Panic(_L("Test"),0);
return KErrNone;
}
void test6()
//
// Test thread duplication
//
{
test.Start(_L("Create thread"));
RSemaphore sem;
TInt r=sem.CreateLocal(0);
test(r==KErrNone);
RThread t;
t.Create(_L("test6thread"),test6Thread,KDefaultStackSize,KHeapSize,KHeapSize,&sem);
test.Next(_L("Resume thread"));
TRequestStatus stat;
t.Logon(stat);
t.Resume();
sem.Signal();
User::WaitForRequest(stat);
test.Next(_L("Close thread"));
t.Close();
sem.Close();
test.End();
}
RSemaphore gsem;
enum TThreadProgress { EBeforeStart, EStarted, EWaiting, EDoneWaiting, EFinished };
TThreadProgress progress=EBeforeStart;
LOCAL_D TInt test7thread(TAny * /*anArg*/)
//
//
//
{
progress=EStarted;
progress=EWaiting;
gsem.Wait();
progress=EDoneWaiting;
gsem.Wait();
progress=EFinished;
return KErrNone;
}
void test7()
//
// Suspend/ Resume tests
//
{
TInt r=gsem.CreateLocal(0);
test(r==KErrNone);
test.Start(_L("Create thread"));
RThread t;
r=t.Create(_L("test7thread"), test7thread, KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
TRequestStatus stat;
t.Logon(stat);
test.Next(_L("Resume thread"));
t.Resume();
User::After(KWaitTime); // wait a bit;
test.Next(_L("Make thread wait on a semaphore"));
test(progress==EWaiting);
test.Next(_L("Suspend waiting thread"));
t.Suspend();
test.Next(_L("Signal the semaphore"));
gsem.Signal();
User::After(KWaitTime);
test.Next(_L("Test thread still suspended"));
test(progress==EWaiting);
test.Next(_L("resume thread"));
t.Resume();
test.Next(_L("Test the thread no longer waiting on the semaphore"));
User::After(KWaitTime);
test(progress==EDoneWaiting);
test.Next(_L("Wait for thread to finish"));
gsem.Signal();
User::WaitForRequest(stat);
test(stat==KErrNone);
test(progress==EFinished);
CLOSE_AND_WAIT(t);
RThread tt;
progress=EBeforeStart;
test.Next(_L("Create Thread"));
r=tt.Create(_L("test7thread"), test7thread, KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
tt.Logon(stat);
test.Next(_L("Suspend thread without starting it"));
tt.Suspend();
tt.Suspend();
test.Next(_L("Resume and test suspend/resume balance"));
tt.Resume();
tt.Resume();
User::After(KWaitTime);
test(progress==EBeforeStart);
tt.Resume();
test.Next(_L("test thread is suspended on semaphore"));
User::After(KWaitTime);
test(progress==EWaiting);
test.Next(_L("suspend thread"));
tt.Suspend();
tt.Suspend();
test.Next(_L("resume thread"));
tt.Resume();
tt.Resume();
test.Next(_L("test thread still suspended on semaphore"));
User::After(KWaitTime);
test(progress==EWaiting);
test.Next(_L("Suspend, Suspend, Signal semaphore, Suspend"));
tt.Suspend();
tt.Suspend();
gsem.Signal();
tt.Suspend();
test.Next(_L("test thread still suspended on semaphore"));
User::After(KWaitTime);
test(progress==EWaiting);
test.Next(_L("Resume thread, checking suspend/resume balance"));
tt.Resume();
User::After(KWaitTime);
test(progress==EWaiting);
tt.Resume();
User::After(KWaitTime);
test(progress==EWaiting);
tt.Resume();
User::After(KWaitTime);
test(progress==EDoneWaiting);
test.Next(_L("Resume an executing thread"));
tt.Resume();
tt.Resume();
// test.Next(_L("Suspend and check balance"));
// tt.Suspend();
// tt.Suspend();
test.Next(_L("Wait for thread to finish"));
gsem.Signal();
User::After(KWaitTime);
test(progress==EFinished);
User::WaitForRequest(stat);
CLOSE_AND_WAIT(tt);
//
test.Next(_L("Create Thread"));
r=tt.Create(_L("test7thread"), test7thread, KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
tt.Logon(stat);
test.Next(_L("Resume"));
tt.Resume();
test.Next(_L("Hang thread on semaphore"));
User::After(KWaitTime);
test(progress==EWaiting);
test.Next(_L("Suspend then Resume thread"));
tt.Suspend();
tt.Suspend();
tt.Resume();
User::After(KWaitTime);
test(progress==EWaiting);
tt.Resume();
test.Next(_L("Check still hanging on semaphore"));
User::After(KWaitTime);
test(progress==EWaiting);
test.Next(_L("Signal Semaphore"));
gsem.Signal();
test.Next(_L("Test thread executing again"));
User::After(KWaitTime);
test(progress==EDoneWaiting);
test.Next(_L("Hang thread on another semaphore, and suspend"));
tt.Suspend();
test.Next(_L("Signal semaphore, and suspend again"));
gsem.Signal();
User::After(KWaitTime);
test(progress==EDoneWaiting);
tt.Suspend();
test.Next(_L("Resume the thread"));
tt.Resume();
User::After(KWaitTime);
test(progress==EDoneWaiting);
tt.Resume();
test.Next(_L("Wait for thread to finish"));
User::After(KWaitTime);
test(progress==EFinished);
User::WaitForRequest(stat);
CLOSE_AND_WAIT(tt);
test.End();
}
#if 0
RSemaphore Sem;
LOCAL_D TInt test8thread(TAny* aPtr)
//
//
//
{
typedef TBuf<0x20> TTestBuf;
typedef volatile TTestBuf* TTestBufPtr;
volatile TTestBufPtr& pB=*(volatile TTestBufPtr*)aPtr;
if ((TUint)pB != 0xc90fdaa2)
return KErrGeneral;
Sem.Wait();
TDesC* pD=(TDesC*)pB;
test(*pD==_L("Everything's just hunky-dory"));
delete (TTestBufPtr*)pB;
__UHEAP_MARKEND;
return KErrNone;
}
#endif
void test8()
//
// Get Heap
//
{
// !!! RThread::SetInitialParameter no longer exists
/*
typedef TBuf<0x20> TTestBuf;
TTestBuf* buf=(TTestBuf*)0xc90fdaa2;
test.Start(_L("Create thread"));
RThread thread;
TInt r=thread.Create(_L("test8thread"),test8thread,KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
r=Sem.CreateLocal(0);
test(r==KErrNone);
test.Next(_L("Set parameter"));
r=thread.SetInitialParameter(&buf);
test(r==KErrNone);
TRequestStatus stat;
thread.Logon(stat);
thread.SetPriority(EPriorityMore);
test.Next(_L("Resume thread"));
thread.Resume();
test.Next(_L("Set initial parameter NULL"));
r=thread.SetInitialParameter(NULL);
test(thread.ExitType()==EExitPending);
test.Next(_L("Get heap"));
RHeap* heap;
heap=thread.Heap();
test.Next(_L("Alloc inside heap"));
__RHEAP_MARK(heap);
buf=(TTestBuf*)heap->Alloc(sizeof(TTestBuf));
test(buf!=NULL);
new(buf) TTestBuf;
*buf=(_L("Everything's just hunky-dory"));
Sem.Signal();
User::WaitForRequest(stat);
test(stat==KErrNone);
test(thread.ExitType()==EExitKill);
test(thread.ExitReason()==KErrNone);
test.Next(_L("Close"));
thread.Close();
Sem.Close();
test.End();
*/
}
TInt Thread(TAny* /*aAny*/)
{
RTest test(_L("Any old thread"));
test.Next(_L("Find remote thread"));
// find the main thread
TFullName name;
name=RProcess().Name();
name.Append(_L("::*"));
TFindThread ft;
ft.Find(name);
TInt r=ft.Next(name);
test(r==KErrNone);
RThread t;
t.Open(ft);
t.Close();
return KErrNone;
}
void test9()
{
test.Start(_L("Test create a NULL TPtr"));
TPtr p(NULL, 10, 10);
test.Next(_L("Create and run remote thread"));
RThread t;
TInt r;
r=t.Create(_L("Any Old Thread"), Thread, 0x2000, 0x2000, 0x2000, (TAny *)&p);
test(KErrNone==r);
TRequestStatus stat;
t.Logon(stat);
t.Resume();
test.Next(_L("Wait for thread to complete"));
User::WaitForRequest(stat);
test(stat==KErrNone);
test(t.ExitCategory()==_L("Kill"));
test(t.ExitReason()==KErrNone);
test(t.ExitType()==EExitKill);
CLOSE_AND_WAIT(t);
test.End();
}
TInt FoghornLeghorn(TAny* aMutex)
//
// Thread function
//
{
((RSemaphore*)aMutex)->Wait();
RThread thread;
TInt r=thread.Create(_L("I say * boy"),FoghornLeghorn,KDefaultStackSize,NULL,aMutex);
test(r==KErrBadName);
return KErrNone;
}
void testOpen()
{
test.Start(_L("Create Foghorn Leghorn"));
RSemaphore fogMut;
fogMut.CreateLocal(0);
RThread foghorn;
TInt r=foghorn.Create(_L("Foghorn Leghorn"),FoghornLeghorn,KDefaultStackSize,KHeapSize,KHeapSize,&fogMut);
test(r==KErrNone);
test.Next(_L("Logon"));
TRequestStatus stat;
foghorn.Logon(stat);
test(stat==KRequestPending);
test.Next(_L("Resume Foghorn Leghorn"));
foghorn.Resume();
test.Next(_L("Get full name"));
TFindThread find(_L("*Foghorn Leghorn"));
TFullName name;
r=find.Next(name);
test(r==KErrNone);
test.Next(_L("Open another handle using full name"));
RThread leghorn;
r=leghorn.Open(name);
test(r==KErrNone);
test.Next(_L("Kill using second handle"));
leghorn.Kill(34523);
User::WaitForRequest(stat);
test(stat==34523);
test.Next(_L("Close handles"));
foghorn.Close();
CLOSE_AND_WAIT(leghorn);
test.Next(_L("Again! - Create Foghorn Leghorn"));
r=foghorn.Create(_L("Foghorn Leghorn"),FoghornLeghorn,KDefaultStackSize,KHeapSize,KHeapSize,&fogMut);
test(r==KErrNone);
test.Next(_L("Logon"));
foghorn.Logon(stat);
test(stat==KRequestPending);
test.Next(_L("Resume Foghorn Leghorn"));
foghorn.Resume();
test.Next(_L("Get full name"));
find.Find(_L("*Foghorn Leghorn"));
r=find.Next(name);
test(r==KErrNone);
test.Next(_L("Open another handle using full name"));
r=leghorn.Open(name);
test(r==KErrNone);
test.Next(_L("Kill using second handle"));
leghorn.Kill(67857);
User::WaitForRequest(stat);
test(stat==67857);
test.Next(_L("Close handles"));
foghorn.Close();
CLOSE_AND_WAIT(leghorn);
test.Next(_L("Create Foghorn Leghorn"));
r=foghorn.Create(_L("Foghorn Leghorn"),FoghornLeghorn,KDefaultStackSize,KHeapSize,KHeapSize,&fogMut);
test(r==KErrNone);
test.Next(_L("Logon"));
foghorn.Logon(stat);
test(stat==KRequestPending);
test.Next(_L("Resume Foghorn Leghorn"));
foghorn.Resume();
test.Next(_L("Now close it"));
foghorn.Close();
test.Next(_L("Get full name"));
find.Find(_L("*Foghorn Leghorn"));
r=find.Next(name);
test(r==KErrNone);
test.Next(_L("Open using full name"));
r=leghorn.Open(name);
test(r==KErrNone);
test.Next(_L("Kill"));
leghorn.Kill(67857);
User::WaitForRequest(stat);
test(stat==67857);
test.Next(_L("Close"));
CLOSE_AND_WAIT(leghorn);
test.Next(_L("Start and get it to try to start a new thread"));
r=foghorn.Create(_L("Foghorn Leghorn"),FoghornLeghorn,KDefaultStackSize,KHeapSize,KHeapSize,&fogMut);
test(r==KErrNone);
foghorn.Logon(stat);
test(stat==KRequestPending);
foghorn.Resume();
fogMut.Signal();
User::WaitForRequest(stat);
test(stat==KErrNone);
test(foghorn.ExitCategory()==_L("Kill"));
test(foghorn.ExitReason()==KErrNone);
test(foghorn.ExitType()==EExitKill);
test.Next(_L("Close"));
CLOSE_AND_WAIT(foghorn);
fogMut.Close();
test.End();
}
TInt Bunny(TAny*)
//
// Thread function
//
{
FOREVER
;
}
void testReuse()
{
test.Start(_L("Create thread with duplicate name"));
RThread thread;
TFullName name=thread.Name();
TInt r=thread.Create(name,Bunny,KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrAlreadyExists);
// thread.Resume(); handle will be invalid since create failed
test.Next(_L("Create with a good name"));
r=thread.Create(_L("Bugs Bunny"),Bunny,KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
TRequestStatus stat;
thread.Logon(stat);
test.Next(_L("Resume"));
thread.Resume();
test.Next(_L("Kill"));
thread.Kill(15);
User::WaitForRequest(stat);
test(stat==15);
CLOSE_AND_WAIT(thread);
test.End();
}
TInt HongKongPhooey(TAny * /*aAny*/)
{
RMutex m;
m.OpenGlobal(_L("Test Mutex"));
m.Wait();
User::Panic(_L("Hello"),900);
return KErrNone;
}
void testReleaseMutex()
//
// Bug HA-187
//
{
TInt r;
test.Start(_L("Create a global Mutex"));
RMutex m;
r=m.CreateGlobal(_L("Test Mutex"));
test.Next(_L("Create a thread"));
RThread number1SuperGuy;
r=number1SuperGuy.Create(_L("Hong Kong Phooey"), HongKongPhooey, KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
TRequestStatus s;
number1SuperGuy.Logon(s);
test.Next(_L("Resume Thread"));
number1SuperGuy.Resume();
test.Next(_L("Wait on Mutex and Panic"));
User::WaitForRequest(s);
test(number1SuperGuy.ExitType()==EExitPanic);
test(number1SuperGuy.ExitCategory()==_L("Hello"));
test(number1SuperGuy.ExitReason()==900);
User::After(100000); // wait a bit for everything to be cleaned up
m.Wait();
test.Next(_L("Close everything"));
m.Close();
CLOSE_AND_WAIT(number1SuperGuy);
test.End();
}
void testId()
{
test.Start(_L("Try to open nonexistant thread by ID"));
RThread thread;
TInt r=thread.Open(*(TThreadId*)&KMaxTUint);
test(r==KErrNotFound);
test.Next(_L("Get thread ID"));
r=thread.Create(_L("Buster Bunny"),Bunny,KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
TThreadId id=thread.Id();
TThreadId id2=thread.Id();
test(id==id2);
RThread thread2;
r=thread2.Create(_L("Babs Bunny"),Bunny,KDefaultStackSize,KHeapSize,KHeapSize,NULL);
test(r==KErrNone);
id2=thread2.Id();
test(id!=id2);
test(*(TUint*)&id+1==*(TUint*)&id2);
test.Next(_L("Open by ID"));
TRequestStatus stat;
thread.Logon(stat);
thread.Kill(54624);
User::WaitForRequest(stat);
test(stat==54624);
thread.Close();
r=thread.Open(id2);
test(r==KErrNone);
test(thread.Name()==_L("Babs Bunny"));
test(thread.FullName()==thread2.FullName());
thread2.Close();
id=thread.Id();
test(id==id2);
thread.Logon(stat);
thread.Kill(88863);
User::WaitForRequest(stat);
test(stat==88863);
CLOSE_AND_WAIT(thread);
test.End();
}
struct SCreateInfo
{
TInt iStackSize;
TInt iMinHeapSize;
TInt iMaxHeapSize;
};
TInt BadCreation(TAny* aCreateInfo)
{
SCreateInfo& info=*((SCreateInfo*)aCreateInfo);
RThread thread;
thread.Create(_L("Won't work"),Bunny,info.iStackSize,info.iMinHeapSize,info.iMaxHeapSize,NULL);
return KErrNone;
}
void testCreate()
{
test.Start(_L("Negative stack size"));
RThread thread;
TRequestStatus stat;
TInt r;
{
SCreateInfo info={-1,0x1000,0x1000};
r=thread.Create(_L("Test Create"),BadCreation,KDefaultStackSize,KHeapSize,KHeapSize,&info);
test(KErrNone==r);
thread.Logon(stat);
thread.Resume();
User::WaitForRequest(stat);
test(stat==EThrdStackSizeNegative);
test(thread.ExitType()==EExitPanic);
test(thread.ExitReason()==EThrdStackSizeNegative);
test(thread.ExitCategory()==_L("USER"));
CLOSE_AND_WAIT(thread);
}
//
test.Next(_L("Negative heap min size"));
{
SCreateInfo info={0x1000,-1,0x1000};
r=thread.Create(_L("Test Create"),BadCreation,KDefaultStackSize,KHeapSize,KHeapSize,&info);
test(KErrNone==r);
thread.Logon(stat);
thread.Resume();
User::WaitForRequest(stat);
test(stat==EThrdHeapMinTooSmall);
test(thread.ExitType()==EExitPanic);
test(thread.ExitReason()==EThrdHeapMinTooSmall);
test(thread.ExitCategory()==_L("USER"));
CLOSE_AND_WAIT(thread);
}
test.Next(_L("Negative heap max size"));
{
SCreateInfo info={0x1000,0x1000,-1};
r=thread.Create(_L("Test Create"),BadCreation,KDefaultStackSize,KHeapSize,KHeapSize,&info);
test(KErrNone==r);
thread.Logon(stat);
thread.Resume();
User::WaitForRequest(stat);
test(stat==EThrdHeapMaxLessThanMin);
test(thread.ExitType()==EExitPanic);
test(thread.ExitReason()==EThrdHeapMaxLessThanMin);
test(thread.ExitCategory()==_L("USER"));
CLOSE_AND_WAIT(thread);
}
test.Next(_L("heap max size < heap min size"));
{
SCreateInfo info={0x1000,0x2001,0x1000};
r=thread.Create(_L("Test Create"),BadCreation,KDefaultStackSize,KHeapSize,KHeapSize,&info);
test(KErrNone==r);
thread.Logon(stat);
thread.Resume();
User::WaitForRequest(stat);
test(stat==EThrdHeapMaxLessThanMin);
test(thread.ExitType()==EExitPanic);
test(thread.ExitReason()==EThrdHeapMaxLessThanMin);
test(thread.ExitCategory()==_L("USER"));
CLOSE_AND_WAIT(thread);
}
test.Next(_L("Little min heap size"));
{
SCreateInfo info={0x1000,KMinHeapSize-1,0x1000};
r=thread.Create(_L("Test Create"),BadCreation,KDefaultStackSize,KHeapSize,KHeapSize,&info);
test(KErrNone==r);
thread.Logon(stat);
thread.Resume();
User::WaitForRequest(stat);
test(stat==EThrdHeapMinTooSmall);
test(thread.ExitType()==EExitPanic);
test(thread.ExitReason()==EThrdHeapMinTooSmall);
test(thread.ExitCategory()==_L("USER"));
CLOSE_AND_WAIT(thread);
}
test.End();
}
TInt StackInfoThread(TAny*)
{
TInt a;
RThread::Rendezvous((TInt)&a); // Complete rendezvous using address of 'a' which is on the stack
return 0;
}
void testThreadStackInfo()
{
// Check the info about the current thread's stack
RThread thread;
TThreadStackInfo info;
TInt r = thread.StackInfo(info);
test(r==KErrNone);
TLinAddr a = (TLinAddr)&info;
test.Printf(_L("address on stack=%x iBase=%x iLimit=%x iExpandLimit=%x"),a,info.iBase,info.iLimit,info.iExpandLimit);
test(a<=info.iBase);
test(a>=info.iLimit);
test(info.iExpandLimit<=info.iLimit);
// Create another thread
r=thread.Create(_L("StackInfoThread"),StackInfoThread,KDefaultStackSize,KHeapSize,KHeapSize,(TAny*)NULL);
test(r==KErrNone);
thread.SetPriority(EPriorityLess);
// Resume thread and wait for it to run
TRequestStatus stat;
thread.Rendezvous(stat);
thread.Resume();
User::WaitForRequest(stat);
// Test getting stack info of another thread
r = thread.StackInfo(info);
test(r==KErrNone);
a = stat.Int(); // a = an address on the threads stack
test.Printf(_L("address on stack=%x iBase=%x iLimit=%x iExpandLimit=%x"),a,info.iBase,info.iLimit,info.iExpandLimit);
test(a<=info.iBase);
test(a>=info.iLimit);
test(info.iExpandLimit<=info.iLimit);
// Let thread run to end
thread.Logon(stat);
User::WaitForRequest(stat);
test(stat.Int()==0);
}
GLDEF_C TInt E32Main()
//
// Main
//
{
// don't want just in time debugging as we trap panics
TBool justInTime=User::JustInTime();
User::SetJustInTime(EFalse);
test.Title();
__UHEAP_MARK;
TFullName name;
name=RThread().Name();
test.Start(_L("Test threads"));
test.Next(_L("Test 1"));
test1();
test.Next(_L("Test create"));
testCreate();
test.Next(_L("Test RUndertaker"));
testUndertaker(EOwnerProcess);
test.Next(_L("Test2"));
test2(EOwnerProcess);
User::SetJustInTime(justInTime);
test.Next(_L("Test3"));
test3();
test.Next(_L("Test4"));
test4();
test.Next(_L("Completed but unclosed thread"));
User::SetJustInTime(EFalse);
test5();
User::SetJustInTime(justInTime);
test.Next(_L("Suspend/Resume"));
test7();
test.Next(_L("Testing thread duplication"));
User::SetJustInTime(EFalse);
test6();
User::SetJustInTime(justInTime);
test.Next(_L("Get thread's heap"));
test8();
test.Next(_L("Test read NULL remotely (HA-178)"));
test9();
test.Next(_L("Test Open(aFullName)"));
testOpen();
test.Next(_L("Test Reuse after a failed create"));
testReuse();
test.Next(_L("Test thread releases Mutex (HA-178)"));
User::SetJustInTime(EFalse);
testReleaseMutex();
User::SetJustInTime(justInTime);
test.Next(_L("Test Thread ID"));
testId();
test.Next(_L("Test RThread::StackInfo"));
testThreadStackInfo();
test.End();
__UHEAP_MARKEND;
return(KErrNone);
}