// Copyright (c) 2007-2009 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:
// @file PBASE-T_USBDI-0487.cpp
// @internalComponent
//
//
#include "PBASE-T_USBDI-0487.h"
#include "testpolicy.h"
#include "modelleddevices.h"
namespace NUnitTesting_USBDI
{
_LIT8(KDataPayload1,"12345678911111112");
// _LIT8(KDataPayload2,"12345opqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz"); unused
// _LIT8(KDataPayload3,"abcdefghijklmnopqrstuvwxyzopqrstuvwxyzabcdefghijklmnopqrstuvwxyz12345"); unused
const TInt KInterruptTransferId1 = 0x01;
const TInt KInterruptTransferId2 = 0x02;
const TInt KInterruptTransferId3 = 0x03;
_LIT(KTestCaseId,"PBASE-T_USBDI-0487");
const TFunctorTestCase<CUT_PBASE_T_USBDI_0487,TBool> CUT_PBASE_T_USBDI_0487::iFunctor(KTestCaseId);
CUT_PBASE_T_USBDI_0487* CUT_PBASE_T_USBDI_0487::NewL(TBool aHostRole)
{
CUT_PBASE_T_USBDI_0487* self = new (ELeave) CUT_PBASE_T_USBDI_0487(aHostRole);
CleanupStack::PushL(self);
self->ConstructL();
CleanupStack::Pop(self);
return self;
}
CUT_PBASE_T_USBDI_0487::CUT_PBASE_T_USBDI_0487(TBool aHostRole)
: CBaseTestCase(KTestCaseId,aHostRole),
iCaseStep(EInProgress)
{
}
void CUT_PBASE_T_USBDI_0487::ConstructL()
{
iTestDevice = new RUsbDeviceA(this);
BaseConstructL();
}
CUT_PBASE_T_USBDI_0487::~CUT_PBASE_T_USBDI_0487()
{
LOG_FUNC
Cancel();
delete iTransferIn;
delete iTransferIn2;
delete iTransferIn3;
// Close pipe(s) before interface(s)
iInPipe.Close();
// Close interfaces
iUsbInterface1.Close();
iUsbInterface0.Close();
delete iControlEp0;
delete iActorFDF;
if(!IsHost() && iTestDevice)
{
iTestDevice->Close();
}
delete iTestDevice;
}
void CUT_PBASE_T_USBDI_0487::ExecuteHostTestCaseL()
{
LOG_FUNC
iActorFDF = CActorFDF::NewL(*this);
iControlEp0 = new (ELeave) CEp0Transfer(iUsbInterface0);
iActorFDF->Monitor();
TimeoutIn(30);
}
void CUT_PBASE_T_USBDI_0487::HostDoCancel()
{
LOG_FUNC
// Cancel the timeout timer
CancelTimeout();
}
void CUT_PBASE_T_USBDI_0487::ExecuteDeviceTestCaseL()
{
LOG_FUNC
iTestDevice->OpenL(TestCaseId());
iTestDevice->SubscribeToReports(iStatus);
SetActive();
iTestDevice->SoftwareConnect();
}
void CUT_PBASE_T_USBDI_0487::DeviceDoCancel()
{
LOG_FUNC
// Cancel the device
iTestDevice->CancelSubscriptionToReports();
}
void CUT_PBASE_T_USBDI_0487::DeviceStateChangeL(RUsbDevice::TDeviceState aPreviousState,RUsbDevice::TDeviceState aNewState,
TInt aCompletionCode)
{
LOG_FUNC
}
void CUT_PBASE_T_USBDI_0487::DeviceInsertedL(TUint aDeviceHandle)
{
LOG_FUNC
Cancel();
TInt err(KErrNone);
// Validate that device is as expected
CUsbTestDevice& testDevice = iActorFDF->DeviceL(aDeviceHandle);
if(testDevice.SerialNumber().Compare(TestCaseId()) != 0)
{
// Incorrect device for this test case
RDebug::Printf("<Warning %d> Incorrect device serial number (%S) connected for this test case (%S)",
KErrNotFound,&testDevice.SerialNumber(),&TestCaseId());
// Start the connection timeout again
CancelTimeout();
iTimer.After(iStatus,30000000);
SetActive();
return;
}
TUint32 token0,token1;
err = testDevice.Device().GetTokenForInterface(0,token0);
if(err != KErrNone)
{
RDebug::Printf("<Error %d> Token for interface 0 could not be retrieved",err);
return TestFailed(err);
}
err = iUsbInterface0.Open(token0); // Default interface setting 0
if(err != KErrNone)
{
RDebug::Printf("<Error %d> Unable to open interface 0 using token %d",err,token0);
return TestFailed(err);
}
err = testDevice.Device().GetTokenForInterface(1,token1);
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Token for interface 1 could not be retrieved"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
err = iUsbInterface1.Open(token1); // Default interface setting 0
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Unable to open interface 1 using token %d"),err,token1);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
// Select alternate interface setting 1
err = iUsbInterface1.SelectAlternateInterface(1);
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Selecting alternate interface setting 1 on interface 1"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
iControlEp0->SendRequest(request,this);
return;
}
// Open a pipe for endpoint (Int in)
TInt endpointAddress;
err = GetEndpointAddress(iUsbInterface1,1,KTransferTypeInterrupt,KEpDirectionIn,endpointAddress);
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> unable to get endpoint address for interrupt in endpoint"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
iControlEp0->SendRequest(request,this);
return;
}
err = iUsbInterface1.OpenPipeForEndpoint(iInPipe,endpointAddress,EFalse);
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Unable to open pipe for endpoint 1"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
RDebug::Printf("Opened pipe to endpoint address %08x for interrupt transfer to host",endpointAddress);
// create an interrupt transfer
iTransferIn = new (ELeave) CInterruptTransfer(iInPipe,iUsbInterface1,256,*this,KInterruptTransferId1);
iTransferIn->RegisterTransferDescriptor();
// create a 2nd interrupt transfer
iTransferIn2 = new (ELeave) CInterruptTransfer(iInPipe,iUsbInterface1,256,*this,KInterruptTransferId2);
iTransferIn2->RegisterTransferDescriptor();
// create a 3rd interrupt transfer
iTransferIn3 = new (ELeave) CInterruptTransfer(iInPipe,iUsbInterface1,256,*this,KInterruptTransferId3);
iTransferIn3->RegisterTransferDescriptor();
// Initialise the descriptors for transfer
RDebug::Printf("Initialising the transfer descriptors");
err = iUsbInterface1.InitialiseTransferDescriptors();
if(err != KErrNone)
{
RDebug::Printf("<Error %d> Unable to initialise transfer descriptors",err);
return;
}
// que interrupt transfer
err = iTransferIn->TransferInL(KDataPayload1().Length());
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Unable to queue an interrupt transfer"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
// que interrupt transfer
err = iTransferIn2->TransferInL(KDataPayload1().Length());
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Unable to queue an interrupt transfer"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
// Que a 3rd interrupt transfer
err = iTransferIn3->TransferInL(KDataPayload1().Length());
if(err != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Unable to queue an interrupt transfer"),err);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(err,msg);
return iControlEp0->SendRequest(request,this);
}
// Timeout the interrupt transfer in 7 seconds
TimeoutIn(7);
// Instruct the client device to write the following data through the valid endpoint
TEndpointWriteRequest request(1,1,KDataPayload1);
iControlEp0->SendRequest(request,this);
}
void CUT_PBASE_T_USBDI_0487::Ep0TransferCompleteL(TInt aCompletionCode)
{
LOG_FUNC
RDebug::Printf("Ep0TransferCompleteL with aCompletionCode = %d"),aCompletionCode;
if(aCompletionCode != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Transfer to control endpoint 0 was not successful"),aCompletionCode);
RDebug::Print(msg);
}
if(iCaseStep == EPassed)
{
if(aCompletionCode == KErrNone)
{
return TestPassed();
}
// else error
iCaseStep = EFailed;
}
if(iCaseStep == EFailed)
{
return TestFailed(KErrCompletion);
}
}
void CUT_PBASE_T_USBDI_0487::TransferCompleteL(TInt aTransferId,TInt aCompletionCode)
{
LOG_FUNC
Cancel();
RDebug::Printf("Transfer %d completed with %d",aTransferId,aCompletionCode);
if(aCompletionCode != KErrNone)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Transfer %d did not complete successfully"),aCompletionCode,aTransferId);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(aCompletionCode,msg);
return iControlEp0->SendRequest(request,this);
}
if(aTransferId == KInterruptTransferId1)
{
TPtrC8 data(iTransferIn->DataPolled());
RDebug::Printf("data.Length 1()= %d", data.Length());
TBuf<256> msg;
for(int i = 0 ; i < data.Length(); i++)
{
msg.AppendFormat(_L("%02x"),data[i]);
}
RDebug::Print(msg);
// Compare the data to what is expected
if(data.Compare(KDataPayload1) != 0)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Interrupt data received does not match data sent"),KErrCompletion);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(KErrCompletion,msg);
return iControlEp0->SendRequest(request,this);
}
User::After(3000000);
// Comparison is a match, continue
TEndpointWriteRequest request(1,1,KDataPayload1);
return iControlEp0->SendRequest(request,this);
}
else if(aTransferId == KInterruptTransferId2)
{
TPtrC8 data(iTransferIn2->DataPolled());
RDebug::Printf("data.Length 2()= %d", data.Length());
TBuf<256> msg;
for(int i = 0 ; i < data.Length(); i++)
{
msg.AppendFormat(_L("%02x"),data[i]);
}
RDebug::Print(msg);
// Compare the data to what is expected
if(data.Compare(KDataPayload1) != 0)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Interrupt data received does not match data sent"),KErrCompletion);
RDebug::Print(msg);
//TODO if test fails! Test fail code below WAS commented out
iCaseStep = EFailed;
TTestCaseFailed request(KErrCompletion,msg);
return iControlEp0->SendRequest(request,this);
}
// Comparison is a match, continue
TEndpointWriteRequest request(1,1,KDataPayload1);
return iControlEp0->SendRequest(request,this);
}
else if(aTransferId == KInterruptTransferId3)
{
TPtrC8 data(iTransferIn3->DataPolled());
// Compare the data to what is expected
if(data.Compare(KDataPayload1) != 0)
{
TBuf<256> msg;
msg.Format(_L("<Error %d> Interrupt data received does not match data sent"),KErrCompletion);
RDebug::Print(msg);
iCaseStep = EFailed;
TTestCaseFailed request(KErrCompletion,msg);
return iControlEp0->SendRequest(request,this);
}
// Comparison is a match, test passed
iCaseStep = EPassed;
TTestCasePassed request;
return iControlEp0->SendRequest(request,this);
}
else
{
RDebug::Printf("<Error> Unknown transfer identity");
TestFailed(KErrUnknown);
}
}
void CUT_PBASE_T_USBDI_0487::DeviceRemovedL(TUint aDeviceHandle)
{
LOG_FUNC
// The test device should not be removed until the test case has passed
// so this test case has not completed, and state this event as an error
TestFailed(KErrDisconnected);
}
void CUT_PBASE_T_USBDI_0487::BusErrorL(TInt aError)
{
LOG_FUNC
// This test case handles no failiures on the bus
TestFailed(KErrCompletion);
}
void CUT_PBASE_T_USBDI_0487::HostRunL()
{
LOG_FUNC
// Obtain the completion code
TInt completionCode(iStatus.Int());
if(completionCode == KErrNone)
{
// Action timeout
RDebug::Printf("<Error> Action timeout");
TestFailed(KErrTimedOut);
}
else
{
RDebug::Printf("<Error %d> Timeout timer could not complete",completionCode);
TestFailed(completionCode);
}
}
void CUT_PBASE_T_USBDI_0487::DeviceRunL()
{
LOG_FUNC
// Disconnect the device
iTestDevice->SoftwareDisconnect();
// Complete the test case request
TestPolicy().SignalTestComplete(iStatus.Int());
}
}