Trying to figure out how to implement my WINC like compatibility layer. Going the emulation way is probably not so smart. We should not use the kernel but rather hook native functions in the Exec calls.
// 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:
// @internalComponent
//
//
#include <e32std.h>
#include <e32std_private.h>
#include <u32std.h> // unicode builds
#include <e32base.h>
#include <e32base_private.h>
#include <e32Test.h> // RTest headder
#include "testcaseroot.h"
#include "b2bwatchers.h"
#include "testcase1233.h"
#include <e32debug.h>
#define LOG_INTO_STEP(a) test.Printf(_L("\nInto Step [%S]\n\n"), &a);
/* **************************************************************************************
* the name below is used to add a pointer to our construction method to a pointer MAP in
* the class factory
*/
_LIT(KTestCaseId,"PBASE-USB_OTGDI-1233");
const TTestCaseFactoryReceipt<CTestCase1233> CTestCase1233::iFactoryReceipt(KTestCaseId);
CTestCase1233* CTestCase1233::NewL(TBool aHost)
{
LOG_FUNC
CTestCase1233* self = new (ELeave) CTestCase1233(aHost);
CleanupStack::PushL(self);
self->ConstructL();
CleanupStack::Pop(self);
return self;
}
CTestCase1233::CTestCase1233(TBool aHost)
: CTestCaseB2BRoot(KTestCaseId, aHost, iStatus)
{
LOG_FUNC
}
/**
ConstructL
*/
void CTestCase1233::ConstructL()
{
LOG_FUNC
iTestVID = 0x0E22; // Symbian
iTestPID = 0xF000 + 1233; // Test 1233
BaseConstructL();
}
CTestCase1233::~CTestCase1233()
{
LOG_FUNC
iCollector.DestroyObservers();
Cancel();
}
void CTestCase1233::ExecuteTestCaseL()
{
LOG_FUNC
iCaseStep = EPreconditions;
CActiveScheduler::Add(this);
SelfComplete();
}
void CTestCase1233::DoCancel()
{
LOG_FUNC
// cancel our timer
iTimer.Cancel();
}
void CTestCase1233::RunStepL()
{
LOG_FUNC
// Obtain the completion code for this CActive obj.
TInt completionCode(iStatus.Int());
TBuf<MAX_DSTRLEN> aDescription;
switch(iCaseStep)
{
/*==================================================*/
/* Fixed 'pre' steps */
/*==================================================*/
case EPreconditions:
{
LOG_INTO_STEP(_L("EPreconditions"))
iCaseStep = ELoadLdd;
StepB2BPreconditions();
break;
}
case ELoadLdd:
{
LOG_INTO_STEP(_L("ELoadLdd"))
// Note we use here the hex equivalent of #1233 for the PID
if (!StepLoadClient(0xF4D1/*use default settings for SRP/HNP support*/))
{
return TestFailed(KErrAbort, _L("Client Load Failure"));
}
// load OTG ldd and init.
if (!StepLoadLDD())
{
return TestFailed(KErrAbort, _L("OTG Load Failure"));
}
if(otgActivateFdfActor()!=KErrNone)
{
return TestFailed(KErrAbort, _L("Couldn't load FDF Actor"));
}
// test that the right cable is in
CheckRoleConnections();
// subscribe to OTG states,events and messages now that it has loaded OK
TRAPD(result, iCollector.CreateObserversL(*this));
if (KErrNone != result)
{
return(TestFailed(KErrNoMemory, _L("Unable to create observers")));
}
// Allow enough time for 8 enumerations, say a second each, plus two of the
// tests require 15 seconds of SOF traffic
const TInt KTestCase1233Timeout = 45000;
iCollector.AddStepTimeout(KTestCase1233Timeout);
iCollector.ClearAllEvents();
iCaseStep = ERaiseVBus;
SelfComplete();
break;
}
/*==================================================*/
/* Steps for this test case only */
/*==================================================*/
case ELoopToNextPID:
{
LOG_INTO_STEP(_L("ELoopToNextPID"));
if (KTestCaseWatchdogTO == iStatus.Int())
{
iCollector.DestroyObservers();
return TestFailed(KErrAbort, _L("Timeout"));
}
if ( iTestVID == 0x0E22 )
{
iTestVID = 0x1A0A; // OPT and test devices
iTestPID = 0x0100; // One *before* the first HS test ID
}
iTestPID++;
if ( iTestPID > 0x0108 )
{
test.Printf(_L("All VID/PID pairs done\n"));
iCaseStep = EUnloadLdd;
}
else
{
if(gTestRoleMaster)
{
// B
test.Printf(_L("Setting VID/PID of 0x%04x/0x%04x\n"),iTestVID,iTestPID);
if (!StepChangeVidPid(iTestVID,iTestPID))
{
return TestFailed(KErrAbort, _L("VID/PID Change Failure"));
}
}
else
{
// A
test.Printf(_L("Expecting VID/PID of 0x%04x/0x%04x\n"),iTestVID,iTestPID);
}
iCollector.ClearAllEvents();
iCaseStep = ERaiseVBus;
}
SelfComplete();
break;
}
case ERaiseVBus:
{
LOG_INTO_STEP(_L("ERaiseVBus"));
if (KTestCaseWatchdogTO == iStatus.Int())
{
iCollector.DestroyObservers();
return TestFailed(KErrAbort, _L("Timeout"));
}
if (gTestRoleMaster)
{
// B device
iCollector.AddRequiredNotification(EWatcherEvent, RUsbOtgDriver::EEventVbusRaised);
iCollector.AddRequiredNotification(EWatcherState, RUsbOtgDriver::EStateBPeripheral);
iCollector.AddRequiredNotification(EWatcherPeripheralState, EUsbcDeviceStateDefault);
iCollector.AddRequiredNotification(EWatcherPeripheralState, EUsbcDeviceStateAddress);
iCollector.AddRequiredNotification(EWatcherEvent, RUsbOtgDriver::EEventHnpEnabled);
iCollector.AddRequiredNotification(EWatcherPeripheralState, EUsbcDeviceStateConfigured);
}
else
{
// A device
test.Printf(_L("Raising VBUS for VID/PID = 0x%04x/0x%04x\n"),iTestVID,iTestPID);
if ( otgBusRequest() != KErrNone )
{
return TestFailed(KErrAbort, _L("Raise Vbus - RUsbOtgDriver::BusRequest() FAILED!"));
}
iCollector.AddRequiredNotification(EWatcherEvent, RUsbOtgDriver::EEventVbusRaised);
iCollector.AddRequiredNotification(EWatcherAConnectionIdle, RUsbOtgDriver::EConnectionBusy);
iCollector.AddRequiredNotification(EWatcherState, RUsbOtgDriver::EStateAHost);
}
iCaseStep = EVBusRaised;
SetActive();
break;
}
case EVBusRaised:
{
LOG_INTO_STEP(_L("EVBusRaised"));
if (KTestCaseWatchdogTO == iStatus.Int())
{
return TestFailed(KErrAbort, _L("Timeout"));
}
if ( otgVbusPresent() )
{
test.Printf(_L("...VBUS is UP\n"));
iCaseStep = EDropVBus;
}
else
{
test.Printf(_L("...VBUS is DOWN\n"));
return TestFailed(KErrAbort, _L("Vbus did not rise - FAILED!"));
}
if (gTestRoleMaster)
{
// B device
SelfComplete();
}
else
{
// A device
// The default device (0x0E22/0xB4D1) is passed to the FDF, which will (eventually)
// suspend and enter connection idle state.
// The HS test devices (0x1A0A) will not be presented to FDF, so there will be no
// trailing connection idle to find.
if ( iTestVID == 0x0E22 )
{
iCollector.AddRequiredNotification(EWatcherAConnectionIdle, RUsbOtgDriver::EConnectionIdle);
SetActive();
}
else
{
SelfComplete();
}
}
break;
}
case EDropVBus:
{
LOG_INTO_STEP(_L("EDropVBus"));
if (KTestCaseWatchdogTO == iStatus.Int())
{
iCollector.DestroyObservers();
return TestFailed(KErrAbort, _L("Timeout"));
}
if ( gTestRoleMaster)
{
// B device
iCollector.AddRequiredNotification(EWatcherEvent, RUsbOtgDriver::EEventVbusDropped);
}
else
{
// A device
otgBusDrop();
iCollector.AddRequiredNotification(EWatcherEvent, RUsbOtgDriver::EEventVbusDropped);
}
iCaseStep = EVBusDropped;
SetActive();
break;
}
case EVBusDropped:
{
LOG_INTO_STEP(_L("EVBusDropped"));
if (KTestCaseWatchdogTO == iStatus.Int())
{
return TestFailed(KErrAbort, _L("Timeout"));
}
if ( otgVbusPresent() )
{
test.Printf(_L("...VBUS is UP\n"));
return TestFailed(KErrAbort, _L("Vbus did not rise - FAILED!"));
}
else
{
test.Printf(_L("...VBUS is DOWN\n"));
iCaseStep = ELoopToNextPID;
}
SelfComplete();
break;
}
/*==================================================*/
/* Fixed 'post' steps */
/*==================================================*/
case EUnloadLdd:
{
LOG_INTO_STEP(_L("EUnloadLdd"))
otgDeactivateFdfActor();
iCollector.DestroyObservers();
if (EFalse == StepUnloadLDD()){
return TestFailed(KErrAbort,_L("unload Ldd failure"));
}
if (!StepUnloadClient()){
return TestFailed(KErrAbort,_L("Client Unload Failure"));
}
iCaseStep = ELastStep;
SelfComplete();
break;
}
case ELastStep:
{
LOG_INTO_STEP(_L("ELastStep"))
TestPassed();
RequestCharacter();
break;
}
default:
{
LOG_INTO_STEP(_L("DEFAULT! (unknown test step)"));
Cancel();
RequestCharacter();
return (TestFailed(KErrCorrupt, _L("<Error> unknown test step")));
}
}
}