Improving comments on panics generated by CActive::SetActive. Patch slightly altered based on comments by John Imhofe.
// Copyright (c) 1997-2009 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\device\t_modem1.cpp
// Test program for PC Card Serial Port Driver - Requires Dacom GoldCard Modem.
//
//
#include <e32std.h>
#include <e32std_private.h>
#include <e32test.h>
#include <e32cons.h>
#include <e32svr.h>
#include <e32hal.h>
#include <e32uid.h>
#include <d32comm.h>
#include <hal.h>
class RComm : public RBusDevComm
{
public:
TInt WriteS(const TDesC8& aDes);
};
const TInt KBlockSize=256;
// Block size Line rate
const TInt KBlocksShort=4; // 4*256=1K - <1200
const TInt KBlocksMedium=12; // 12*256=3K - <4800
const TInt KBlocksLong=64; // 64*256=16K - <28800
const TInt KBlocksVeryLong=128; // 128*256=32K - 28800
enum TLineRate {EV21_300,EBell103_300,EV22_1200,EBell212_1200,EV22bis_2400,
EV32_4800,EV32_9600,EV32bis_14400,EV34_28800,ELineRateEnd};
const TInt KMaxLineRates=ELineRateEnd;
const TInt KStandardRxBufferSize=0x400;
#if !defined (__WINS__)
#define PDD_NAME _L("EUARTn")
#define LDD_NAME _L("ECOMM")
#else
#define PDD_NAME _L("ECDRV.PDD")
#define LDD_NAME _L("ECOMM.LDD")
#endif
LOCAL_D RTest test(_L("T_MODEM1"));
LOCAL_D TInt LineModeData[KMaxLineRates]={0,64,1,69,2,9,9,10,11};
LOCAL_D TInt LineRateData[KMaxLineRates]={300,300,1200,1200,2400,4800,9600,14400,28800};
LOCAL_D TInt LineConnectData[KMaxLineRates]={1200,1200,1200,1200,2400,4800,9600,14400,28800};
LOCAL_D RComm *theSerialPort;
TInt RComm::WriteS(const TDesC8& aDes)
//
// Syncronous write
//
{
TRequestStatus s;
Write(s,aDes,aDes.Length());
User::WaitForRequest(s);
return(s.Int());
}
LOCAL_C TPtrC BaudRateInText(TBps aRate)
//
// Convert into Baudrate text
//
{
switch (aRate)
{
case EBps50: return(_L("50")); break;
case EBps75: return(_L("75")); break;
case EBps110: return(_L("110")); break;
case EBps134: return(_L("134")); break;
case EBps150: return(_L("150")); break;
case EBps300: return(_L("300")); break;
case EBps600: return(_L("600")); break;
case EBps1200: return(_L("1200")); break;
case EBps1800: return(_L("1800")); break;
case EBps2000: return(_L("2000")); break;
case EBps2400: return(_L("2400")); break;
case EBps3600: return(_L("3600")); break;
case EBps4800: return(_L("4800")); break;
case EBps7200: return(_L("7200")); break;
case EBps9600: return(_L("9600")); break;
case EBps19200: return(_L("19200")); break;
case EBps38400: return(_L("38400")); break;
case EBps57600: return(_L("57600")); break;
case EBps115200: return(_L("115000")); break;
default: return(_L("Unknown")); break;
}
}
LOCAL_C TInt TranslateCrLf(TDes8 &aDes)
//
// Search for CR/LF characters in a string and replace them with
// '\r' '\n' format. Also replaces unprintable characters with "?"
//
{
TText8 buf[KBlockSize];
TText8 *pS=(TText8*)aDes.Ptr();
TText8 *pSE=pS+aDes.Size();
TText8 *pT=&buf[0];
TText8 *pTMax=pT+(KBlockSize-1);
for (;pS<pSE;pS++,pT++)
{
if (pT>=pTMax)
return(KErrTooBig);
if (*pS=='\xD'||*pS=='\xA')
{
*pT++='\\';
*pT=(*pS=='\xD')?'r':'n';
}
else if (((TChar)*pS).IsPrint())
*pT=*pS;
else
*pT='\?';
}
*pT=0;
if ((pT-&buf[0])>aDes.MaxLength())
return(KErrTooBig);
aDes.Copy(&buf[0]);
return(KErrNone);
}
/* ???
LOCAL_C void PrintBuf(TDes8 &aBuf)
//
// Print the contents of a buffer
//
{
TInt len=aBuf.Length();
for (TInt i=0;i<=len/8;i++)
{
test.Printf(_L("%4d: "),i*8);
for (TInt j=0;j<8;j++)
{
if ((i*8)+j>=len)
break;
TInt v=aBuf[(i*8)+j];
test.Printf(_L("%02x "),v);
}
test.Printf(_L("\n\r"));
}
}
*/
LOCAL_C void testLoopBack(TLineRate aLineRate,TBps aBaudRate)
//
// Perform an analogue loopback test at the specified linerate
//
{
TInt err;
TBuf<64> b;
TPtrC bd=BaudRateInText(aBaudRate);
b.Format(_L("Loopback test(%S)"),&bd);
test.Start(b);
TBuf8<KBlockSize> txBuf;
theSerialPort->ResetBuffers();
txBuf.Format(_L8("AT&F+MS=%d,0,%d,%d\\N0&K3&D2M0\r"),LineModeData[aLineRate],LineRateData[aLineRate],LineRateData[aLineRate]);
test(theSerialPort->WriteS(txBuf)==KErrNone);
TBuf8<KBlockSize> rxBuf;
User::After(2000000); // 2Secs
err=theSerialPort->QueryReceiveBuffer();
test(err>0);
rxBuf.SetLength(err);
TRequestStatus rxStat;
theSerialPort->ReadOneOrMore(rxStat,rxBuf);
User::WaitForRequest(rxStat);
// test.Printf(_L(" Rx(%d):"),rxStat); // ???
test(rxStat==KErrNone);
txBuf.Append(_L("\r\nOK\r\n"));
err=rxBuf.Compare(txBuf);
// test(TranslateCrLf(rxBuf)==KErrNone); // ???
// test.Printf(_L(" %S\r\n"),&rxBuf); // ???
test(err==0);
test.Next(_L("Get loopback"));
txBuf.Format(_L8("AT&T1\r"));
test(theSerialPort->WriteS(txBuf)==KErrNone);
User::After(5000000); // 5Secs
err=theSerialPort->QueryReceiveBuffer();
test(err>0);
rxBuf.SetLength(err);
theSerialPort->ReadOneOrMore(rxStat,rxBuf);
User::WaitForRequest(rxStat);
test.Printf(_L(" Rx(%d):"),rxStat);
test(rxStat==KErrNone);
txBuf.AppendFormat(_L8("\r\nCONNECT %d\r\n"),LineConnectData[aLineRate]);
err=rxBuf.Compare(txBuf);
test(TranslateCrLf(rxBuf)==KErrNone);
test.Printf(_L(" %S\r\n"),&rxBuf); // Print what we got back (without CR/LF etc).
// Sometimes get extra character as modem goes on-line so just look for command echo + connect
test(err>=0);
User::After(2000000); // 2Secs
TInt totalBlocksToTransfer;
if (aBaudRate<EBps1200||aLineRate<EV22_1200)
totalBlocksToTransfer=KBlocksShort;
else if (aBaudRate<EBps4800||aLineRate<EV32_4800)
totalBlocksToTransfer=KBlocksMedium;
else if (aLineRate<EV34_28800)
totalBlocksToTransfer=KBlocksLong;
else
totalBlocksToTransfer=KBlocksVeryLong;
b.Format(_L("Transfering data(%dK)"),(totalBlocksToTransfer*KBlockSize)/1024);
test.Next(b);
TInt loopBackFail=KErrGeneral;
TRequestStatus txStat;
txBuf.SetLength(KBlockSize);
TInt i;
for (i=0;i<KBlockSize;i++)
txBuf[i]=(TUint8)i;
theSerialPort->Write(txStat,txBuf,KBlockSize);
TInt txBlks=(totalBlocksToTransfer-1);
rxBuf.Fill(0,KBlockSize);
theSerialPort->Read(rxStat,rxBuf,KBlockSize);
TInt rxBlks=0;
TRequestStatus tStat;
RTimer tim;
test(tim.CreateLocal()==KErrNone);
tim.After(tStat,40000000); // 40Secs
test.Printf(_L(">"));
FOREVER
{
User::WaitForAnyRequest();
if (tStat!=KRequestPending)
{
// test.Printf(_L("t")); // Timed out
theSerialPort->ReadCancel(); // Cancel serial read
User::WaitForRequest(rxStat);
if (txBlks>0)
{
theSerialPort->WriteCancel(); // Cancel serial write
User::WaitForRequest(txStat);
}
loopBackFail=KErrTimedOut; // Test failed
break;
}
else if (rxStat!=KRequestPending)
{
// test.Printf(_L("r")); // Serial rx request complete
if (rxStat!=0)
{
loopBackFail=rxStat.Int(); // Test failed
goto endSerial;
}
for (i=0;i<KBlockSize;i++)
{
if (rxBuf[i]!=i)
{
loopBackFail=KErrCorrupt; // Test failed
rxBuf[KBlockSize-1]=0;
// PrintBuf(rxBuf); // ???
// goto endSerial; // !!!Ignore compare fails for now!!!
}
}
test.Printf(_L("<"));
if (++rxBlks<totalBlocksToTransfer)
{
rxBuf.Fill(0,KBlockSize);
theSerialPort->Read(rxStat,rxBuf,KBlockSize);
}
else
{
loopBackFail=KErrNone;
endSerial:
tim.Cancel(); // Cancel timer request.
User::WaitForRequest(tStat);
if (txBlks>0)
{
theSerialPort->WriteCancel(); // Cancel serial write
User::WaitForRequest(txStat);
}
break;
}
}
else if (txStat!=KRequestPending)
{
// test.Printf(_L("s")); // Serial tx request complete
if (txBlks>0)
{
theSerialPort->Write(txStat,txBuf,KBlockSize);
test.Printf(_L(">"));
txBlks--;
}
}
else
{
// test.Printf(_L("?")); // Stray signal - cancel everything
theSerialPort->ReadCancel(); // Cancel serial read
User::WaitForRequest(rxStat);
tim.Cancel(); // Cancel timer request.
User::WaitForRequest(tStat);
if (txBlks>0)
{
theSerialPort->WriteCancel(); // Cancel serial write
User::WaitForRequest(txStat);
}
loopBackFail=KErrDied;
break;
}
}
test.Printf(_L(" (%d)\r\n"),loopBackFail);
// !!! At this point RTS may or may not be asserted following the write cancel. The
// following seems necessary to make sure RTS is asserted so any remaining Rx data
// can be received.and thrown away
User::After(2000000);
theSerialPort->ResetBuffers();
User::After(1000000); // Wait 1Secs for any remaining Rx data
tim.Close();
test.Next(_L("Disconnect"));
theSerialPort->ResetBuffers(); // Through away any remaining Rx data.
txBuf.Format(_L8("+++"));
test(theSerialPort->WriteS(txBuf)==KErrNone);
User::After(2000000); // 2Secs
err=theSerialPort->QueryReceiveBuffer();
test(err>0);
rxBuf.SetLength(err);
theSerialPort->ReadOneOrMore(rxStat,rxBuf);
User::WaitForRequest(rxStat);
test(rxStat==KErrNone);
txBuf.Append(_L("\r\nOK\r\n"));
err=rxBuf.Compare(txBuf);
// test(TranslateCrLf(rxBuf)==KErrNone); // ???
// test.Printf(_L(" %S\r\n"),&rxBuf); // ???
test(err==0);
txBuf.Format(_L8("ATH0\r"));
test(theSerialPort->WriteS(txBuf)==KErrNone);
User::After(4000000); // 4Secs
err=theSerialPort->QueryReceiveBuffer();
test(err>0);
rxBuf.SetLength(err);
theSerialPort->ReadOneOrMore(rxStat,rxBuf);
User::WaitForRequest(rxStat);
test(rxStat==KErrNone);
txBuf.Append(_L("\r\nOK\r\n"));
err=rxBuf.Compare(txBuf);
// test(TranslateCrLf(rxBuf)==KErrNone); // ???
// test.Printf(_L(" %S\r\n"),&rxBuf); // ???
test(err==0);
test.Next(_L("Check result"));
test(loopBackFail==KErrNone || loopBackFail==KErrCorrupt); // !!!Ignore compare fails for now!!!
// test(loopBackFail==KErrNone);
test.End();
}
LOCAL_C void testAllLineRates(TBps aRate)
//
// Perform loopback test at the specified baudrate in as many line modes that
// are supported at this baudrate
//
{
test.Start(_L("Setting baudrate"));
TCommConfig cBuf;
TCommConfigV01 &c=cBuf();
theSerialPort->Config(cBuf);
c.iRate=aRate;
c.iDataBits=EData8;
c.iStopBits=EStop1;
c.iParity=EParityNone;
c.iHandshake=KConfigObeyCTS;
// c.iHandshake=0;
test(theSerialPort->SetConfig(cBuf)==KErrNone);
if (aRate>=EBps38400)
{
test.Next(_L("Testing at V.34-28800"));
testLoopBack(EV34_28800,aRate);
}
if (aRate>=EBps19200)
{
test.Next(_L("Testing at V.32bis-14400"));
testLoopBack(EV32bis_14400,aRate);
}
if (aRate>=EBps9600)
{
test.Next(_L("Testing at V.32-9600"));
testLoopBack(EV32_9600,aRate);
}
// if (aRate>=EBps4800)
// {
// test.Next(_L("Testing at V.32-4800"));
// testLoopBack(EV32_4800,aRate);
// }
if (aRate>=EBps2400)
{
test.Next(_L("Testing at V.22bis-2400"));
testLoopBack(EV22bis_2400,aRate);
}
// if (aRate>=EBps1200)
// {
// test.Next(_L("Testing at Bell212-1200"));
// testLoopBack(EBell212_1200,aRate);
// }
// if (aRate>=EBps1200)
// {
// test.Next(_L("Testing at V.22-1200"));
// testLoopBack(EV22_1200,aRate);
// }
// test.Next(_L("Testing at Bell103-300"));
// testLoopBack(EBell103_300,aRate);
test.Next(_L("Testing at V.21-300"));
testLoopBack(EV21_300,aRate);
test.End();
}
GLDEF_C TInt E32Main()
{
// test.SetLogged(EFalse); // Turn off serial port debugging!
TInt r;
test.Title();
test.Start(_L("PC Card Modem Test Program"));
RProcess proc;
TBuf <0x100> cmd;
proc.CommandLine(cmd);
// First parameter (if present) sets the serial port number
TInt port=0;
if ((cmd.Length()>0) && (cmd[0]>='1' && cmd[0]<='4'))
port=(TInt)(cmd[0]-'0');
// 2nd parameter (if present) sets the start speed
// (4=115K,3=57600,2=38400,1=19200,0=9600)
TInt startSpeed=4;
if ((cmd.Length()>3) && (cmd[2]>='0' && cmd[2]<='4'))
startSpeed=(TInt)(cmd[2]-'0');
test.Next(_L("Load Device Drivers"));
TBuf<10> pddName=PDD_NAME;
#if !defined (__WINS__)
pddName[5]=(TText)('1'+port);
TInt muid=0;
if (HAL::Get(HAL::EMachineUid, muid)==KErrNone)
{
// Brutus uses EUART4 for both COM3 and COM4
if (muid==HAL::EMachineUid_Brutus && port==4)
pddName[5]=(TText)'4';
}
#endif
r=User::LoadPhysicalDevice(pddName);
test(r==KErrNone||r==KErrAlreadyExists);
r=User::LoadLogicalDevice(LDD_NAME);
test(r==KErrNone||r==KErrAlreadyExists);
test.Next(_L("Open serial port"));
theSerialPort=new RComm;
test(theSerialPort!=NULL);
r=theSerialPort->Open(port);
test(r==KErrNone);
// TCommCaps capsBuf;
// TCommCapsV01& caps=capsBuf();
// theSerialPort->Caps(capsBuf);
// Check that the driver powering sequence has completed successfully by
// issueing a few simple driver control functions.
test.Next(_L("Modem power tests"));
test(theSerialPort->SetReceiveBufferLength(KStandardRxBufferSize)==KErrNone);
r=theSerialPort->ReceiveBufferLength();
// test.Printf(_L("(%d)"),r); // ???
test(r==KStandardRxBufferSize);
r=(TInt)theSerialPort->Signals();
// test.Printf(_L("(%d)"),r); // ???
test(r>=0);
RTimer timer;
TRequestStatus rs;
test(timer.CreateLocal()==KErrNone);
TTime tim;
tim.HomeTime();
tim+=TTimeIntervalSeconds(8);
timer.At(rs,tim);
UserHal::SwitchOff();
User::WaitForRequest(rs);
test(rs.Int()==KErrNone);
r=theSerialPort->ReceiveBufferLength();
// test.Printf(_L("(%d)"),r); // ???
test(r==KStandardRxBufferSize);
r=(TInt)theSerialPort->Signals();
// test.Printf(_L("(%d)"),r); // ???
test(r>=0);
User::After(2000000); // 2Secs !!!
if (startSpeed>=4)
{
test.Next(_L("Testing at 115K"));
testAllLineRates(EBps115200);
}
if (startSpeed>=3)
{
test.Next(_L("Testing at 57600"));
testAllLineRates(EBps57600);
}
if (startSpeed>=2)
{
test.Next(_L("Testing at 38400"));
testAllLineRates(EBps38400);
}
if (startSpeed>=1)
{
test.Next(_L("Testing at 19200"));
testAllLineRates(EBps19200);
}
test.Next(_L("Testing at 9600"));
testAllLineRates(EBps9600);
test.Next(_L("Close serial port"));
theSerialPort->Close();
delete theSerialPort;
test.End();
return(KErrNone);
}