We need a way to pass flags to rombuilds in Raptor via extension flm interfaces, so that the CPP pass
of the rom input files can be informed what toolchain we are building with and conditionally
include or exclude files depending on whether the toolchain could build them.
// Copyright (c) 1995-2009 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:
// e32\euser\epoc\up_utl.cpp
//
//
#include <u32exec.h>
#include "up_std.h"
#include <e32svr.h>
#include <e32uid.h>
#ifdef __EPOC32__
#include <e32rom.h>
#endif
#include <e32atomics.h>
//#define __DEBUG_IMAGE__ 1
#if defined(__DEBUG_IMAGE__) && defined (__EPOC32__)
extern RDebug debug;
#define __IF_DEBUG(t) {debug.t;}
#else
#define __IF_DEBUG(t)
#endif
/**
Atomically (i.e. in a manner which is safe against concurrent access by other
threads) increments a TInt value by 1.
As an example of its use, the function is used in the implementation of
critical sections.
@param aValue A reference to an integer whose value is to be incremented.
On return contains the incremented value.
@return The value of aValue before it is incremented.
@see User::LockedDec
@see RCrticalSection
*/
EXPORT_C TInt User::LockedInc(TInt& aValue)
{
return (TInt)__e32_atomic_add_ord32(&aValue, 1);
}
/**
Atomically (i.e. in a manner which is safe against concurrent access by other
threads) decrements a TInt value by 1.
As an example of its use, the function is used in the implementation of
critical sections.
@param aValue A reference to an integer whose value is to be decremented.
On return contains the decremented value.
@return The value of aValue before it is decremented.
@see User::LockedInc
@see RCrticalSection
*/
EXPORT_C TInt User::LockedDec(TInt& aValue)
{
return (TInt)__e32_atomic_add_ord32(&aValue, 0xFFFFFFFF);
}
EXPORT_C TInt User::SafeInc(TInt& aValue)
/**
Atomically increments the specified value by 1, if the value is > 0.
@param aValue The value to be incremented; on return the incremented value.
@return The original value of aValue
*/
{
return __e32_atomic_tas_ord32(&aValue, 1, 1, 0);
}
EXPORT_C TInt User::SafeDec(TInt &aValue)
/**
Atomically decrements the specified value by 1, if the value is > 0.
@param aValue The value to be decremented; on return the decremented value.
@return The original value of aValue
*/
{
return __e32_atomic_tas_ord32(&aValue, 1, -1, 0);
}
EXPORT_C void UserSvr::WsRegisterThread()
//
// Register the window server thread.
//
{
Exec::WsRegisterThread();
}
EXPORT_C void UserSvr::FsRegisterThread()
//
// Register the file server thread.
//
{
Exec::FsRegisterThread();
}
EXPORT_C void UserSvr::RegisterTrustedChunk(TInt aHandle)
/**
Registers file server's chunk intended for DMA transfer.
@internalComponent
@released
*/
{
Exec::RegisterTrustedChunk(aHandle);
}
EXPORT_C TInt UserHeap::SetupThreadHeap(TBool, SStdEpocThreadCreateInfo& aInfo)
/**
@internalComponent
*/
{
TInt r = KErrNone;
if (!aInfo.iAllocator && aInfo.iHeapInitialSize>0)
{
// new heap required
RHeap* pH = NULL;
r = CreateThreadHeap(aInfo, pH);
}
else if (aInfo.iAllocator)
{
// sharing a heap
RAllocator* pA = aInfo.iAllocator;
pA->Open();
User::SwitchAllocator(pA);
}
return r;
}
EXPORT_C void User::HandleException(TAny* aInfo)
/**
Enables the current thread to handle an exception.
The function is called by the kernel.
@param aInfo A pointer to a TExcType type containing the exception information.
@see TExcType
*/
{
const TUint32* p = (const TUint32*)aInfo;
TUint32 excType = p[0];
TExceptionHandler f = Exec::ExceptionHandler(KCurrentThreadHandle);
TRAPD(r, (*f)(TExcType(excType)) );
Exec::ThreadSetFlags(KCurrentThreadHandle,KThreadFlagLastChance,0);
if (r!=KErrNone)
User::Leave(r);
}
#ifdef __EPOC32__
EXPORT_C TInt User::IsRomAddress(TBool &aBool, TAny *aPtr)
/**
Tests whether the specified address is in the ROM.
@param aBool True, if the address at aPtr is within the ROM; false,
otherwise.
@param aPtr The address to be tested.
@return Always KErrNone.
*/
{
TUint a = (TUint)aPtr;
TUint main_start = UserSvr::RomHeaderAddress();
TUint main_end = main_start + ((TRomHeader*)main_start)->iUncompressedSize;
aBool = (a>=main_start && a<main_end);
if (aBool)
return KErrNone; // address is in main ROM
TUint rda = UserSvr::RomRootDirectoryAddress();
// We assume here, the primary rom starts a multiple of 4k.
if (rda > main_end)
{
// ASSUMPTIONS HERE
// 1. root directory is past the end of the main ROM so there must be an extension ROM
// 2. the ROM file system in the extension ROM is at the beginning of the ROM (similar to the
// main ROM)
// 3. the extension ROM is mapped starting at a megabyte boundary
// Thus the address of the extension ROM header may be obtained by rounding the root directory
// address down to the next megabyte boundary.
TUint ext_start = rda &~ 0x000fffffu;
TUint ext_base = ((TExtensionRomHeader*)ext_start)->iRomBase;
TUint ext_end = ext_start + ((TExtensionRomHeader*)ext_start)->iUncompressedSize;
aBool = (ext_base==ext_start && a>=ext_start && a<ext_end);
} return KErrNone;
}
#endif
#ifdef __MARM__
EXPORT_C void E32Loader::GetV7StubAddresses(TLinAddr& aExe, TLinAddr& aDll)
{
// Only need V7 support on ARM platforms
aExe = (TLinAddr)&E32Loader::V7ExeEntryStub;
aDll = (TLinAddr)&E32Loader::V7DllEntryStub;
}
#endif
#ifdef __MARM__
// Only need V7 support on ARM platforms
_LIT(KEka1EntryStubName, "eka1_entry_stub.dll");
extern "C" TLinAddr GetEka1ExeEntryPoint()
{
TLinAddr a = 0;
RLibrary l;
TInt r = l.Load(KEka1EntryStubName, KNullDesC, TUidType(KDynamicLibraryUid, KEka1EntryStubUid));
if (r == KErrNone)
r = l.Duplicate(RThread(), EOwnerProcess);
if (r == KErrNone)
{
a = (TLinAddr)l.Lookup(1);
if (!a)
r = KErrNotSupported;
}
if (r != KErrNone)
RThread().Kill(r);
Exec::SetReentryPoint(a);
return a;
}
#endif