diff -r 000000000000 -r bde4ae8d615e os/kernelhwsrv/kerneltest/e32test/misc/t_ipccpy.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/os/kernelhwsrv/kerneltest/e32test/misc/t_ipccpy.cpp Fri Jun 15 03:10:57 2012 +0200 @@ -0,0 +1,724 @@ +// Copyright (c) 1998-2009 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\misc\t_ipccpy.cpp +// Overview: +// Test and benchmark IPC reading, writing, copying. +// API Information: +// RBusLogicalChannel, DLogicalChannel. +// Details: +// - Load the specified logical device driver, open a channel to it, allocate +// a cell of specified size from the current thread's heap, get Kernel HAL +// memory model information. +// - Make a synchronous Kernel Executive type request to the logical channel +// to write specified data to the buffer, read the data and calculate the +// time taken for writing and reading the data. Benchmark the time required +// to for 1000 64K user->kernel and kernel->user copies. +// - Create a chunk, get a pointer to the base of the chunk's reserved region, +// create a server thread, establish a session with the server, signal +// completion of the client's request when message is received, read, +// write specified bits and check it is as expected. +// Platforms/Drives/Compatibility: +// All. +// Assumptions/Requirement/Pre-requisites: +// Failures and causes: +// Base Port information: +// +// + +#include +#include "d_ipccpy.h" +#include "u32std.h" +#include +#include "../mmu/mmudetect.h" +#include + +RTest test(_L("T_IPCCPY")); +TUint8* Buffer; +TUint8* Disc; +RIpcCpy Ipccpy; +TUint32 MainId; +TUint8 Bss[4096]; +TUint8* Kern; +TUint8* RamDrive; +TUint8* Nonexistent; +TUint8* Unaligned=Bss+1; +TInt CloseTime; +TLinAddr HwChunkAddr[RIpcCpy::ENumHwChunkTypes]; +TPtr8 UserDes(Buffer+96,96,96); + +void SetupAddresses() + { + Kern=KernData(); + TUint32 mm_attr=MemModelAttributes(); + TUint32 mm_type=mm_attr & EMemModelTypeMask; + switch (mm_type) + { + case EMemModelTypeDirect: + RamDrive=(TUint8*)0; // not used anyway + Nonexistent=(TUint8*)0xa8000000; + break; + case EMemModelTypeMoving: + RamDrive=(TUint8*)0x40000000; + Nonexistent=(TUint8*)0x60f00000; + break; + case EMemModelTypeMultiple: + RamDrive=(TUint8*)0xa0000000; + Nonexistent=(TUint8*)0xfe000000; + break; + case EMemModelTypeFlexible: + RamDrive=(TUint8*)0; + Nonexistent=(TUint8*)0x8ff00000; + break; + case EMemModelTypeEmul: + RamDrive=(TUint8*)0; // not used anyway + Nonexistent=(TUint8*)0xf0000000; + break; + default: + test(0); + break; + } + new (&UserDes) TPtr8(Buffer+96,96,96); + Ipccpy.HardwareChunks(HwChunkAddr,UserDes); + test.Printf(_L("Buffer=%08x\n"),Buffer); + test.Printf(_L("Bss=%08x\n"),Bss); + test.Printf(_L("Kern=%08x\n"),Kern); + test.Printf(_L("RamDrive=%08x\n"),RamDrive); + test.Printf(_L("Nonexistent=%08x\n"),Nonexistent); + test.Printf(_L("Unaligned=%08x\n"),Unaligned); + test.Printf(_L("HwChunkSupRw=%08x\n"),HwChunkAddr[RIpcCpy::EHwChunkSupRw]); + test.Printf(_L("HwChunkUserRw=%08x\n"),HwChunkAddr[RIpcCpy::EHwChunkUserRw]); + test.Printf(_L("HwChunkUserRo=%08x\n"),HwChunkAddr[RIpcCpy::EHwChunkUserRo]); + } + +_LIT(KLitKernExec,"KERN-EXEC"); + +void TestEq(TInt a, TInt b, TInt l); +void Test(TBool c, TInt l); + +#define TESTEQ(a,b) TestEq((a),(b),__LINE__) +#define TEST(c) Test((c),__LINE__) + +void TestEq(TInt a, TInt b, TInt l) + { + if (a!=b) + { + if (TUint32(RThread().Id())==MainId) + { + test.Printf(_L("Line %d a=%d, b=%d\n"),l,a,b); + test(0); + } + else + User::Panic(_L("TESTEQ"),l); + } + } + +void Test(TBool c, TInt l) + { + if (!c) + { + if (TUint32(RThread().Id())==MainId) + { + test.Printf(_L("Line %d FAIL\n"),l); + test(0); + } + else + User::Panic(_L("TEST"),l); + } + } + +struct SIpcTestInfo + { + const TAny* iLocal; + const TAny* iRemote; + TInt iOffset; + TInt iMode; // bit 0 = 1 for 16 bit, bit 1 = 1 for write + }; + +class RLocalSession : public RSessionBase + { +public: + TInt Connect(RServer2 aSrv,TRequestStatus* aStat) + {return CreateSession(aSrv,TVersion(),-1,EIpcSession_Unsharable,0,aStat);} + void Test(const TAny* aRemote) + {Send(0,TIpcArgs((const TDesC8*)aRemote,(const TDesC16*)aRemote,(TDes8*)aRemote,(TDes16*)aRemote));} + void Wait() + {SendReceive(1);} + }; + +RServer2 IpcServer; + +TInt IpcTestFn(TAny* aInfo) + { + SIpcTestInfo& i=*(SIpcTestInfo*)aInfo; + + if (IpcServer.Handle()) + IpcServer.Close(); + + TESTEQ(IpcServer.CreateGlobal(KNullDesC),KErrNone); + RLocalSession sess; + TRequestStatus stat; + TESTEQ(sess.Connect(IpcServer,&stat),KErrNone); + RMessage2 m; + IpcServer.Receive(m); + m.Complete(KErrNone); // connect + User::WaitForRequest(stat); // connection message report + sess.Test(i.iRemote); + IpcServer.Receive(m); + + TInt r=KMinTInt; + switch (i.iMode) + { + case 0: + { // read 8 bit + TDesC8* pR=(TDesC8*)i.iRemote; + TDes8* pL=(TDes8*)i.iLocal; + r=m.Read(0,*pL,i.iOffset); + if (r==KErrNone) + { + TESTEQ(pL->Length(),pR->Length()-i.iOffset); + TEST(*pL==pR->Mid(i.iOffset)); + } + break; + } + case 1: + { // read 16 bit + TDesC16* pR=(TDesC16*)i.iRemote; + TDes16* pL=(TDes16*)i.iLocal; + r=m.Read(1,*pL,i.iOffset); + if (r==KErrNone) + { + TESTEQ(pL->Length(),pR->Length()-i.iOffset); + TEST(*pL==pR->Mid(i.iOffset)); + } + break; + } + case 2: + { // write 8 bit + TDes8* pR=(TDes8*)i.iRemote; + TDesC8* pL=(TDesC8*)i.iLocal; + r=m.Write(2,*pL,i.iOffset); + if (r==KErrNone) + { + TESTEQ(pR->Length(),pL->Length()+i.iOffset); + TEST(*pL==pR->Mid(i.iOffset)); + } + break; + } + case 3: + { // write 16 bit + TDes16* pR=(TDes16*)i.iRemote; + TDesC16* pL=(TDesC16*)i.iLocal; + r=m.Write(3,*pL,i.iOffset); + if (r==KErrNone) + { + TESTEQ(pR->Length(),pL->Length()+i.iOffset); + TEST(*pL==pR->Mid(i.iOffset)); + } + break; + } + default: + User::Panic(_L("MODE"),i.iMode); + } + m.Complete(0); + sess.Close(); + IpcServer.Close(); + + return r; + } + +void _DoIpcTest(const TAny* aLocal, const TAny* aRemote, TInt aOffset, TInt aMode, const TDesC* aPanicCat, TInt aResult, TInt aLine) + { + test.Printf(_L("Line %d\n"),aLine); + SIpcTestInfo info; + info.iLocal=aLocal; + info.iRemote=aRemote; + info.iOffset=aOffset; + info.iMode=aMode; + if (!aPanicCat) + { + // do test in this thread + TInt r=IpcTestFn(&info); + TESTEQ(r,aResult); + return; + } + TBool jit=User::JustInTime(); + RThread t; + TInt r=t.Create(KNullDesC(),IpcTestFn,0x2000,NULL,&info); + test(r==KErrNone); + TRequestStatus s; + t.Logon(s); + User::SetJustInTime(EFalse); + t.Resume(); + User::WaitForRequest(s); + User::SetJustInTime(jit); + test(t.ExitType()==EExitPanic); + test(t.ExitCategory()==*aPanicCat); + TESTEQ(t.ExitReason(),aResult); + t.Close(); + } + +void DoIpcTest(const TUint8* aLocal, const TUint8* aRemote, TInt aLength, TInt aMode, const TDesC* aPanicCat, TInt aResult, TInt aLine) + { + TPtr8 local((TUint8*)aLocal,aLength,aLength); + TPtr8 remote((TUint8*)aRemote,aLength,aLength); + _DoIpcTest(&local,&remote,0,aMode,aPanicCat,aResult,aLine); + } + +void DoIpcTest(const TUint8* aLocal, const TDesC8& aRemote, TInt aLength, TInt aMode, const TDesC* aPanicCat, TInt aResult, TInt aLine) + { + TPtr8 local((TUint8*)aLocal,aLength,aLength); + _DoIpcTest(&local,&aRemote,0,aMode,aPanicCat,aResult,aLine); + } + +void TestIpcCopyErrors() + { + RChunk c; + TInt r=c.CreateDisconnectedLocal(0,0,0x500000); + test(r==KErrNone); + r=c.Commit(0,0x1000); + test(r==KErrNone); + r=c.Commit(0x2000,0x1000); + test(r==KErrNone); + r=c.Commit(0x3ff000,0x1000); + test(r==KErrNone); + Disc=c.Base(); + test.Printf(_L("Disc=%08x\n"),Disc); + DoIpcTest(Buffer,(const TUint8*)&TestEq,100,0,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,(const TUint8*)&TestEq,100,2,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest((const TUint8*)&TestEq,Buffer,100,2,NULL,KErrNone,__LINE__); + DoIpcTest((const TUint8*)&TestEq,Buffer,100,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,Nonexistent,100,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(Buffer,Nonexistent,100,2,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(Nonexistent,Buffer,100,2,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Nonexistent,Buffer,100,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,Unaligned,100,0,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,Unaligned,100,2,NULL,KErrNone,__LINE__); + DoIpcTest(Unaligned,Buffer,100,2,NULL,KErrNone,__LINE__); + DoIpcTest(Unaligned,Buffer,100,0,NULL,KErrNone,__LINE__); + + DoIpcTest(Disc+4001,Buffer,95,0,NULL,KErrNone,__LINE__); + if (HaveVirtMem()) + DoIpcTest(Disc+4001,Buffer,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,Disc+4001,95,0,NULL,KErrNone,__LINE__); + if (HaveVirtMem()) + DoIpcTest(Buffer,Disc+4001,96,0,NULL,KErrBadDescriptor,__LINE__); + + TPtr8* pdes; + if (HaveVirtMem()) + { + // test descriptor stored stradling chunk end... + pdes = (TPtr8*)(Disc+0x3ffff4); + memcpy(pdes,&UserDes,12); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrNone,__LINE__); + pdes = (TPtr8*)(Disc+0x3ffff8); + memcpy(pdes,&UserDes,8); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrBadDescriptor,__LINE__); + pdes = (TPtr8*)(Disc+0x3ffffc); + memcpy(pdes,&UserDes,4); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrBadDescriptor,__LINE__); + r=c.Commit(0x400000,0x1000); + test(r==KErrNone); + pdes = (TPtr8*)(Disc+0x3ffff4); + memcpy(pdes,&UserDes,12); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrNone,__LINE__); + pdes = (TPtr8*)(Disc+0x3ffff8); + memcpy(pdes,&UserDes,12); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrNone,__LINE__); + pdes = (TPtr8*)(Disc+0x3ffffc); + memcpy(pdes,&UserDes,12); + DoIpcTest(Buffer,*pdes,pdes->Size(),0,NULL,KErrNone,__LINE__); + } + + if (HaveMultAddr()) + { + if(RamDrive) + { + DoIpcTest(Disc+0x100000,Buffer,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,Disc+0x100000,96,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(RamDrive,Buffer,4,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,RamDrive,4,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(RamDrive,Buffer,4,2,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,RamDrive,4,2,NULL,KErrBadDescriptor,__LINE__); + } + + // if memory alising happens during IPC then the memory at 'Disc' would be aliased + // at KIPCAliasAddress and so would not be protected by MMU permission checks. + // However, the kernel should still prevent this, to avoid degrading process + // protection for memory in other parts of the alias region. +#ifdef __CPU_X86 + const TUint8* KIPCAliasAddress; + if((MemModelAttributes()&EMemModelTypeMask) == EMemModelTypeFlexible) + KIPCAliasAddress = (TUint8*)0x7e000000; + else + KIPCAliasAddress = (TUint8*)0xc0400000; +#else + const TUint8* KIPCAliasAddress = (TUint8*)0x00200000; +#endif + DoIpcTest(KIPCAliasAddress,Disc,4,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Disc,KIPCAliasAddress,4,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(KIPCAliasAddress,Disc,4,2,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Disc,KIPCAliasAddress,4,2,NULL,KErrBadDescriptor,__LINE__); + } + + if (HaveIPCKernProt()) + { + DoIpcTest(Kern,Buffer,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,Kern,96,0,NULL,KErrBadDescriptor,__LINE__); + TUint8* addrRW = (TUint8*)HwChunkAddr[RIpcCpy::EHwChunkSupRw]; + if(addrRW) + { + DoIpcTest(Buffer,*(TDes8*)addrRW,96,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(Buffer,*(TDes8*)addrRW,96,2,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(addrRW+96,Buffer,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,addrRW,96,0,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(addrRW+96,Buffer,96,2,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,addrRW,96,2,NULL,KErrBadDescriptor,__LINE__); + } + } + + if((MemModelAttributes()&EMemModelTypeMask) == EMemModelTypeMultiple + || (MemModelAttributes()&EMemModelTypeMask) == EMemModelTypeFlexible + ) + { + // On multiple memory model, test IPC to Hardware Chunks. + // IPC to hardware chunks not supported on Moving Memory + TUint8* addrRW = (TUint8*)HwChunkAddr[RIpcCpy::EHwChunkUserRw]; + if(addrRW) + { + DoIpcTest(Buffer,*(TDes8*)addrRW,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,*(TDes8*)addrRW,96,2,NULL,KErrNone,__LINE__); + DoIpcTest(addrRW+96,Buffer,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,addrRW,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(addrRW+96,Buffer,96,2,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,addrRW,96,2,NULL,KErrNone,__LINE__); + DoIpcTest(addrRW+96,addrRW,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(addrRW+96,addrRW,96,2,NULL,KErrNone,__LINE__); + } + TUint8* addrRO = (TUint8*)HwChunkAddr[RIpcCpy::EHwChunkUserRo]; + if(addrRO && HaveWriteProt()) + { + DoIpcTest(Buffer,*(TDes8*)addrRO,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,*(TDes8*)addrRO,96,2,&KLitKernExec,EBadIpcDescriptor,__LINE__); + DoIpcTest(addrRO+96,Buffer,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(Buffer,addrRO,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(addrRO+96,Buffer,96,2,NULL,KErrNone,__LINE__); + DoIpcTest(Buffer,addrRO,96,2,NULL,KErrBadDescriptor,__LINE__); + DoIpcTest(addrRW+96,addrRO,96,0,NULL,KErrNone,__LINE__); + DoIpcTest(addrRW+96,addrRW,96,2,NULL,KErrNone,__LINE__); + DoIpcTest(addrRO+96,addrRO,96,0,&KLitKernExec,ECausedException,__LINE__); + DoIpcTest(addrRO+96,addrRW,96,2,NULL,KErrNone,__LINE__); + } + } + + c.Close(); + } + +RMessage2 Msg1, Msg2; + +TInt SendAndExit(TAny* aPtr) + { + RLocalSession sess; + TInt r=sess.Connect(IpcServer,NULL); + if (r!=KErrNone) + return r; + sess.Test(aPtr); + sess.Wait(); + sess.Close(); + User::AfterHighRes(1000*CloseTime); + Msg1.Complete(0); // complete my own message! - this removes message reference to thread + return 0; + } + +void TestIpcAsyncClose() + { + + // Create a 16MB chunk + const TInt desSize = 8*1024*1024; + RChunk chunk; + test(chunk.CreateLocal(2 * desSize, 2 * desSize) == KErrNone); + test(chunk.Adjust(2 * desSize) == KErrNone); + + TUint8* bigBuf=chunk.Base(); + test(bigBuf!=NULL); + TUint8* bigBuf2=chunk.Base() + desSize; + test(bigBuf2!=NULL); + TPtr8 bigBufPtr(bigBuf, desSize, desSize); + TPtr8 bigBufPtr2(bigBuf2, 0, desSize); + + if (IpcServer.Handle()) + IpcServer.Close(); + TESTEQ(IpcServer.CreateGlobal(KNullDesC),KErrNone); + + RThread t; + TInt r=t.Create(KNullDesC,SendAndExit,0x1000,NULL,&bigBufPtr); + test(r==KErrNone); + TFullName fn(t.FullName()); + TRequestStatus s; + t.Logon(s); + t.SetPriority(EPriorityMuchMore); + t.Resume(); + + IpcServer.Receive(Msg1); // connect + Msg1.Complete(KErrNone); + IpcServer.Receive(Msg1); // test message + IpcServer.Receive(Msg2); // wait/synch message + TUint32 initial = User::NTickCount(); + r=Msg1.Read(2,bigBufPtr2,0); // arg2 is writable 8 bit descriptor + TUint32 final = User::NTickCount(); + TUint32 elapsed = final - initial; + if (elapsed<3) + test.Printf(_L("*** WARNING! The big IPC only took %dms, which means the next test might fail! \n"),elapsed); + else + test.Printf(_L("Big IPC took %dms\n"),elapsed); + CloseTime = (TInt)(elapsed>>2); + Msg2.Complete(0); + IpcServer.Receive(Msg2); // disconnect + TUint32 disconnect = User::NTickCount(); + + // We expect this IPC read to fail part way through + r=Msg1.Read(2,bigBufPtr2,0); // arg2 is writable 8 bit descriptor + test.Printf(_L("counters: initial=%d final=%d disconnect=%d current=%d\n"),initial,final,disconnect,User::NTickCount()); + test.Printf(_L("2nd Big IPC returned %d\n"),r); + test(r==KErrDied); + test(Msg1.IsNull()); + Msg2.Complete(0); // complete session closure as well + User::WaitForRequest(s); + test(s==KErrNone); + CLOSE_AND_WAIT(t); + test(t.Open(fn)==KErrNotFound); + IpcServer.Close(); + + // t already closed +// User::Free(bigBuf); +// User::Free(bigBuf2); + chunk.Close(); + } + +void BenchmarkTest() + { + TAny* bigbuf = User::Alloc(65536); + test(bigbuf != NULL); + TInt i; + TUint32 initial, final; + initial = User::NTickCount(); + for (i=0; i<1000; ++i) + Ipccpy.BigWrite(bigbuf, 0); + final = User::NTickCount(); + TUint32 wcal = final - initial; + initial = User::NTickCount(); + for (i=0; i<1000; ++i) + Ipccpy.BigWrite(bigbuf, 65536); + final = User::NTickCount(); + TUint32 write = final - initial; + test.Printf(_L("64K user->kernel copy takes %d us\n"), write - wcal); + initial = User::NTickCount(); + for (i=0; i<1000; ++i) + Ipccpy.BigRead(bigbuf, 0); + final = User::NTickCount(); + TUint32 rcal = final - initial; + initial = User::NTickCount(); + for (i=0; i<1000; ++i) + Ipccpy.BigRead(bigbuf, 65536); + final = User::NTickCount(); + TUint32 read = final - initial; + test.Printf(_L("64K kernel->user copy takes %d us\n"), read - rcal); + User::Free(bigbuf); +// User::After(10*1000*1000); + } + + +RMessage2 IpcMesage; +const TInt KTestChunkSize = 1024*1024; +const TInt KReadSize = 4096; + +TInt IpcMultipleAliasesThread(TAny* aBuffer) + { + TBuf8 data; + TAny** dataStart = (TAny**)data.Ptr(); + TAny** dataEnd = (TAny**)(data.Ptr()+KReadSize-sizeof(TAny*)); + for(;;) + { + TInt offset; + for(offset=0; offset>2)&3; + TInt length=(x>>4)+1; + TInt err=-1; + TInt i; + for (i=0; i=0) + { + test.Printf(_L("Sequence number %03x\nSrcOffset %d, DestOffset %d, Length %d\n"),x,src_offset,dest_offset,length); + test.Printf(_L("First error at %d"),err); + for (i=0; i<272; i+=16) + { + TInt j; + test.Printf(_L("%03x:"),i); + for (j=0; j<16; ++j) + { + test.Printf(_L(" %02x"),Buffer[i+j]); + } + } + test(0); + } + if (x==4095) + break; + } + Ipccpy.Close(); + test.End(); + return KErrNone; + }