// Copyright (c) 2008-2009 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\system\t_atomic_common.cpp
//
//
#ifdef __KERNEL_MODE__
#include <kernel/kernel.h>
#else
#define __E32TEST_EXTENSION__
#include <e32test.h>
extern RTest test;
#define __INCLUDE_FUNC_NAMES__
#endif
#define __INCLUDE_ATOMIC_FUNCTIONS__
#define __INCLUDE_CONTROL_FUNCTIONS__
#define __INCLUDE_FUNCTION_ATTRIBUTES__
#include "t_atomic.h"
#define DEBUGPRINTVAR(x) \
{ \
const TUint8* p = (const TUint8*)&(x); \
DEBUGPRINT("Line %d: " #x "=%02x %02x %02x %02x %02x %02x %02x %02x", __LINE__, p[0], p[1], p[2], p[3], p[4], p[5], p[6], p[7]); \
}
extern "C" {
// Simulated versions of atomic functions without the atomicity
#define __LOAD(T) return *(T*)a
#define __STORE(T) *(T*)a=v; return v
#define __SWP(T) T oldv=*(T*)a; *(T*)a=v; return oldv
#define __CAS(T) if (*(T*)a==*q) {*(T*)a=v; return 1;} *q=*(T*)a; return 0
#define __ADD(T) T oldv=*(T*)a; *(T*)a=(T)(oldv+v); return oldv
#define __AND(T) T oldv=*(T*)a; *(T*)a=(T)(oldv&v); return oldv
#define __IOR(T) T oldv=*(T*)a; *(T*)a=(T)(oldv|v); return oldv
#define __XOR(T) T oldv=*(T*)a; *(T*)a=(T)(oldv^v); return oldv
#define __AXO(T) T oldv=*(T*)a; *(T*)a=(T)((oldv&u)^v); return oldv
#define __TA(T) T oldv=*(T*)a; *(T*)a=(T)(oldv+((oldv>=t)?u:v)); return oldv
TUint8 __nonatomic_load8(const volatile TAny* a)
{
__LOAD(TUint8);
}
TUint8 __nonatomic_store8(volatile TAny* a, TUint8 v)
{
__STORE(TUint8);
}
TUint8 __nonatomic_swp8(volatile TAny* a, TUint8 v)
{
__SWP(TUint8);
}
TBool __nonatomic_cas8(volatile TAny* a, TUint8* q, TUint8 v)
{
__CAS(TUint8);
}
TUint8 __nonatomic_add8(volatile TAny* a, TUint8 v)
{
__ADD(TUint8);
}
TUint8 __nonatomic_and8(volatile TAny* a, TUint8 v)
{
__AND(TUint8);
}
TUint8 __nonatomic_ior8(volatile TAny* a, TUint8 v)
{
__IOR(TUint8);
}
TUint8 __nonatomic_xor8(volatile TAny* a, TUint8 v)
{
__XOR(TUint8);
}
TUint8 __nonatomic_axo8(volatile TAny* a, TUint8 u, TUint8 v)
{
__AXO(TUint8);
}
TUint8 __nonatomic_tau8(volatile TAny* a, TUint8 t, TUint8 u, TUint8 v)
{
__TA(TUint8);
}
TInt8 __nonatomic_tas8(volatile TAny* a, TInt8 t, TInt8 u, TInt8 v)
{
__TA(TInt8);
}
TUint16 __nonatomic_load16(const volatile TAny* a)
{
__LOAD(TUint16);
}
TUint16 __nonatomic_store16(volatile TAny* a, TUint16 v)
{
__STORE(TUint16);
}
TUint16 __nonatomic_swp16(volatile TAny* a, TUint16 v)
{
__SWP(TUint16);
}
TBool __nonatomic_cas16(volatile TAny* a, TUint16* q, TUint16 v)
{
__CAS(TUint16);
}
TUint16 __nonatomic_add16(volatile TAny* a, TUint16 v)
{
__ADD(TUint16);
}
TUint16 __nonatomic_and16(volatile TAny* a, TUint16 v)
{
__AND(TUint16);
}
TUint16 __nonatomic_ior16(volatile TAny* a, TUint16 v)
{
__IOR(TUint16);
}
TUint16 __nonatomic_xor16(volatile TAny* a, TUint16 v)
{
__XOR(TUint16);
}
TUint16 __nonatomic_axo16(volatile TAny* a, TUint16 u, TUint16 v)
{
__AXO(TUint16);
}
TUint16 __nonatomic_tau16(volatile TAny* a, TUint16 t, TUint16 u, TUint16 v)
{
__TA(TUint16);
}
TInt16 __nonatomic_tas16(volatile TAny* a, TInt16 t, TInt16 u, TInt16 v)
{
__TA(TInt16);
}
TUint32 __nonatomic_load32(const volatile TAny* a)
{
__LOAD(TUint32);
}
TUint32 __nonatomic_store32(volatile TAny* a, TUint32 v)
{
__STORE(TUint32);
}
TUint32 __nonatomic_swp32(volatile TAny* a, TUint32 v)
{
__SWP(TUint32);
}
TBool __nonatomic_cas32(volatile TAny* a, TUint32* q, TUint32 v)
{
__CAS(TUint32);
}
TUint32 __nonatomic_add32(volatile TAny* a, TUint32 v)
{
__ADD(TUint32);
}
TUint32 __nonatomic_and32(volatile TAny* a, TUint32 v)
{
__AND(TUint32);
}
TUint32 __nonatomic_ior32(volatile TAny* a, TUint32 v)
{
__IOR(TUint32);
}
TUint32 __nonatomic_xor32(volatile TAny* a, TUint32 v)
{
__XOR(TUint32);
}
TUint32 __nonatomic_axo32(volatile TAny* a, TUint32 u, TUint32 v)
{
__AXO(TUint32);
}
TUint32 __nonatomic_tau32(volatile TAny* a, TUint32 t, TUint32 u, TUint32 v)
{
__TA(TUint32);
}
TInt32 __nonatomic_tas32(volatile TAny* a, TInt32 t, TInt32 u, TInt32 v)
{
__TA(TInt32);
}
TUint64 __nonatomic_load64(const volatile TAny* a)
{
__LOAD(TUint64);
}
TUint64 __nonatomic_store64(volatile TAny* a, TUint64 v)
{
__STORE(TUint64);
}
TUint64 __nonatomic_swp64(volatile TAny* a, TUint64 v)
{
__SWP(TUint64);
}
TBool __nonatomic_cas64(volatile TAny* a, TUint64* q, TUint64 v)
{
__CAS(TUint64);
}
TUint64 __nonatomic_add64(volatile TAny* a, TUint64 v)
{
__ADD(TUint64);
}
TUint64 __nonatomic_and64(volatile TAny* a, TUint64 v)
{
__AND(TUint64);
}
TUint64 __nonatomic_ior64(volatile TAny* a, TUint64 v)
{
__IOR(TUint64);
}
TUint64 __nonatomic_xor64(volatile TAny* a, TUint64 v)
{
__XOR(TUint64);
}
TUint64 __nonatomic_axo64(volatile TAny* a, TUint64 u, TUint64 v)
{
__AXO(TUint64);
}
TUint64 __nonatomic_tau64(volatile TAny* a, TUint64 t, TUint64 u, TUint64 v)
{
__TA(TUint64);
}
TInt64 __nonatomic_tas64(volatile TAny* a, TInt64 t, TInt64 u, TInt64 v)
{
__TA(TInt64);
}
} // extern "C"
#define DEBUGPRINTxyrc() \
DEBUGPRINTVAR(x); \
DEBUGPRINTVAR(y); \
DEBUGPRINTVAR(r); \
DEBUGPRINTVAR(c)
template<class T> TInt DoLoadTest(TInt aIndex, TAny* aPtr, T aInitialValue)
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("DoLoadTest %d %08x", aIndex, aPtr);
#endif
typename TLoadFn<T>::F atomic = (typename TLoadFn<T>::F)AtomicFuncPtr[aIndex];
typename TLoadFn<T>::F control = (typename TLoadFn<T>::F)ControlFuncPtr[aIndex];
T& x = *(T*)aPtr;
x = aInitialValue;
T y = aInitialValue;
T r = atomic(&x);
T c = control(&y);
if (r!=c || x!=y)
{
DEBUGPRINTxyrc();
return __LINE__;
}
return 0;
}
template<class T> TInt DoRmw1Test(TInt aIndex, TAny* aPtr, T aInitialValue, T a1)
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("DoRmw1Test %d %08x", aIndex, aPtr);
#endif
typename TRmw1Fn<T>::F atomic = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aIndex];
typename TRmw1Fn<T>::F control = (typename TRmw1Fn<T>::F)ControlFuncPtr[aIndex];
T& x = *(T*)aPtr;
x = aInitialValue;
T y = aInitialValue;
T r = atomic(&x,a1);
T c = control(&y,a1);
if (r!=c || x!=y)
{
DEBUGPRINTxyrc();
return __LINE__;
}
return 0;
}
template<class T> TInt DoRmw2Test(TInt aIndex, TAny* aPtr, T aInitialValue, T a1, T a2)
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("DoRmw2Test %d %08x", aIndex, aPtr);
#endif
typename TRmw2Fn<T>::F atomic = (typename TRmw2Fn<T>::F)AtomicFuncPtr[aIndex];
typename TRmw2Fn<T>::F control = (typename TRmw2Fn<T>::F)ControlFuncPtr[aIndex];
T& x = *(T*)aPtr;
x = aInitialValue;
T y = aInitialValue;
T r = atomic(&x,a1,a2);
T c = control(&y,a1,a2);
if (r!=c || x!=y)
{
DEBUGPRINTxyrc();
return __LINE__;
}
return 0;
}
template<class T> TInt DoRmw3Test(TInt aIndex, TAny* aPtr, T aInitialValue, T a1, T a2, T a3)
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("DoRmw3Test %d %08x", aIndex, aPtr);
#endif
typename TRmw3Fn<T>::F atomic = (typename TRmw3Fn<T>::F)AtomicFuncPtr[aIndex];
typename TRmw3Fn<T>::F control = (typename TRmw3Fn<T>::F)ControlFuncPtr[aIndex];
T& x = *(T*)aPtr;
x = aInitialValue;
T y = aInitialValue;
T r = atomic(&x,a1,a2,a3);
T c = control(&y,a1,a2,a3);
if (r!=c || x!=y)
{
DEBUGPRINTxyrc();
return __LINE__;
}
return 0;
}
template<class T> TInt DoCasTest(TInt aIndex, TAny* aPtr, T aInitialValue, T aExpectedValue, T aFinalValue)
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("DoCasTest %d %08x", aIndex, aPtr);
#endif
typename TCasFn<T>::F atomic = (typename TCasFn<T>::F)AtomicFuncPtr[aIndex];
typename TCasFn<T>::F control = (typename TCasFn<T>::F)ControlFuncPtr[aIndex];
T& x = *(T*)aPtr;
x = aInitialValue;
T ex = aExpectedValue;
T y = aInitialValue;
T ey = aExpectedValue;
TBool r = atomic(&x,&ex,aFinalValue);
TBool c = control(&y,&ey,aFinalValue);
TInt line = 0;
if (r && !c)
line = __LINE__;
else if (!r && c)
line = __LINE__;
else if (x!=y)
line = __LINE__;
else if (ex!=ey)
line = __LINE__;
else if (r && x!=aFinalValue)
line = __LINE__;
else if (!r && ex!=aInitialValue)
line = __LINE__;
if (line)
{
DEBUGPRINT("r=%d",r);
DEBUGPRINTVAR(x);
DEBUGPRINTVAR(ex);
DEBUGPRINT("c=%d",c);
DEBUGPRINTVAR(y);
DEBUGPRINTVAR(ey);
}
return line;
}
TEnclosed::TEnclosed(TInt aSize)
{
iOffset = -1;
iSize = aSize;
iData = (TUint64*)((T_UintPtr(i_Data) + 7) &~ 7); // align up to next 8 byte boundary
iBackup = iData + 8;
}
TAny* TEnclosed::Ptr()
{
return ((TUint8*)iData + iOffset);
}
TInt TEnclosed::Next()
{
const TInt KLimit[8] = {8, 16, 0, 32, 0, 0, 0, 32};
if (iOffset<0)
iOffset = 0;
else
{
TInt r = Verify();
if (r!=0)
return r;
iOffset += iSize;
}
if (iOffset >= KLimit[iSize-1])
return KErrEof;
Init();
return KErrNone;
}
void TEnclosed::Init()
{
TUint32 x = iOffset+1;
x |= (x<<8);
x |= (x<<16);
TUint32* d = (TUint32*)iData;
TUint32* b = (TUint32*)iBackup;
TInt i;
for (i=0; i<16; ++i)
{
*d++ = x;
*b++ = x;
x = 69069*x + 41;
}
}
TInt TEnclosed::Verify()
{
TUint8* d = (TUint8*)iData;
const TUint8* b = (const TUint8*)iBackup;
TInt i;
for (i=0; i<iSize; ++i)
d[iOffset+i] = b[iOffset+i];
if (memcompare(b,64,d,64))
{
DEBUGPRINT("FAIL! iOffset=%02x, sizeof(T)=%1d", iOffset, iSize);
for (i=0; i<64; ++i)
{
if (d[i]!=b[i])
{
DEBUGPRINT("d[%02x]=%02x b[%02x]=%02x", i, d[i], i, b[i]);
}
}
return __LINE__;
}
return 0;
}
TInt TDGBase::Execute()
{
PFV af0 = AtomicFuncPtr[iIndex];
PFV cf0 = ControlFuncPtr[iIndex];
if (!af0 || !cf0)
return __LINE__;
TUint attr = FuncAttr[iIndex];
TInt type = ATTR_TO_TYPE(attr);
TInt size = ATTR_TO_SIZE(attr);
TInt func = ATTR_TO_FUNC(attr);
if (type==EFuncTypeInvalid)
return __LINE__;
#ifdef __EXTRA_DEBUG__
TInt ord = ATTR_TO_ORD(attr);
DEBUGPRINT("A=%08x T=%d O=%d S=%d F=%d", attr, type, ord, size, func);
#endif
TEnclosed enc(size);
TInt res = 0;
while ( (res = enc.Next()) == KErrNone )
{
#ifdef __EXTRA_DEBUG__
DEBUGPRINT("Offset %02x", enc.Offset());
#endif
TAny* ptr = enc.Ptr();
switch (type)
{
case EFuncTypeLoad:
{
switch (size)
{
case 1: res = DoLoadTest<TUint8>(iIndex, ptr, (TUint8)i0); break;
case 2: res = DoLoadTest<TUint16>(iIndex, ptr, (TUint16)i0); break;
case 4: res = DoLoadTest<TUint32>(iIndex, ptr, (TUint32)i0); break;
case 8: res = DoLoadTest<TUint64>(iIndex, ptr, i0); break;
default: res = __LINE__; break;
}
break;
}
case EFuncTypeRmw1:
{
switch (size)
{
case 1: res = DoRmw1Test<TUint8>(iIndex, ptr, (TUint8)i0, (TUint8)i1); break;
case 2: res = DoRmw1Test<TUint16>(iIndex, ptr, (TUint16)i0, (TUint16)i1); break;
case 4: res = DoRmw1Test<TUint32>(iIndex, ptr, (TUint32)i0, (TUint32)i1); break;
case 8: res = DoRmw1Test<TUint64>(iIndex, ptr, i0, i1); break;
default: res = __LINE__; break;
}
break;
}
case EFuncTypeRmw2:
{
switch (size)
{
case 1: res = DoRmw2Test<TUint8>(iIndex, ptr, (TUint8)i0, (TUint8)i1, (TUint8)i2); break;
case 2: res = DoRmw2Test<TUint16>(iIndex, ptr, (TUint16)i0, (TUint16)i1, (TUint16)i2); break;
case 4: res = DoRmw2Test<TUint32>(iIndex, ptr, (TUint32)i0, (TUint32)i1, (TUint32)i2); break;
case 8: res = DoRmw2Test<TUint64>(iIndex, ptr, i0, i1, i2); break;
default: res = __LINE__; break;
}
break;
}
case EFuncTypeRmw3:
{
if (func==EAtomicFuncTAU)
{
switch (size)
{
case 1: res = DoRmw3Test<TUint8>(iIndex, ptr, (TUint8)i0, (TUint8)i1, (TUint8)i2, (TUint8)i3); break;
case 2: res = DoRmw3Test<TUint16>(iIndex, ptr, (TUint16)i0, (TUint16)i1, (TUint16)i2, (TUint16)i3); break;
case 4: res = DoRmw3Test<TUint32>(iIndex, ptr, (TUint32)i0, (TUint32)i1, (TUint32)i2, (TUint32)i3); break;
case 8: res = DoRmw3Test<TUint64>(iIndex, ptr, i0, i1, i2, i3); break;
default: res = __LINE__; break;
}
}
else if (func==EAtomicFuncTAS)
{
switch (size)
{
case 1: res = DoRmw3Test<TInt8>(iIndex, ptr, (TInt8)i0, (TInt8)i1, (TInt8)i2, (TInt8)i3); break;
case 2: res = DoRmw3Test<TInt16>(iIndex, ptr, (TInt16)i0, (TInt16)i1, (TInt16)i2, (TInt16)i3); break;
case 4: res = DoRmw3Test<TInt32>(iIndex, ptr, (TInt32)i0, (TInt32)i1, (TInt32)i2, (TInt32)i3); break;
case 8: res = DoRmw3Test<TInt64>(iIndex, ptr, i0, i1, i2, i3); break;
default: res = __LINE__; break;
}
}
else
res = __LINE__;
break;
}
case EFuncTypeCas:
{
switch (size)
{
case 1: res = DoCasTest<TUint8>(iIndex, ptr, (TUint8)i0, (TUint8)i1, (TUint8)i2); break;
case 2: res = DoCasTest<TUint16>(iIndex, ptr, (TUint16)i0, (TUint16)i1, (TUint16)i2); break;
case 4: res = DoCasTest<TUint32>(iIndex, ptr, (TUint32)i0, (TUint32)i1, (TUint32)i2); break;
case 8: res = DoCasTest<TUint64>(iIndex, ptr, i0, i1, i2); break;
default: res = __LINE__; break;
}
break;
}
default:
res = __LINE__;
break;
}
if (res)
return res;
}
if (res == KErrEof)
res = 0;
return res;
}
#ifndef __KERNEL_MODE__
void TDGBase::Dump(const char* aTitle)
{
TPtrC8 fname8((const TText8*)FuncName[iIndex]);
TBuf<64> fname;
fname.Copy(fname8);
DEBUGPRINT(aTitle);
DEBUGPRINT("iIndex=%d (%S)", iIndex, &fname);
DEBUGPRINT("i0 = %08x %08x", I64HIGH(i0), I64LOW(i0));
DEBUGPRINT("i1 = %08x %08x", I64HIGH(i1), I64LOW(i1));
DEBUGPRINT("i2 = %08x %08x", I64HIGH(i2), I64LOW(i2));
DEBUGPRINT("i3 = %08x %08x", I64HIGH(i3), I64LOW(i3));
}
#endif
template<class T> TInt DoSwap(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw1Fn<T>::F atomic = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aA.iIndex];
T newv = (T)aA.i0;
T orig = atomic(aPtr, newv);
T xr = (T)(newv ^ orig);
aT->iXor ^= xr;
T diff = (T)(newv - orig);
aT->iDiff += diff;
return 0;
}
template<class T> TInt DoAdd(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw1Fn<T>::F atomic = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aA.iIndex];
T arg = (T)aA.i0;
T orig = atomic(aPtr, arg);
T xr = (T)((arg+orig) ^ orig);
aT->iXor ^= xr;
aT->iDiff += arg;
return 0;
}
template<class T> TInt DoXor(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw1Fn<T>::F atomic = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aA.iIndex];
T arg = (T)aA.i0;
T orig = atomic(aPtr, arg);
T diff = (T)((arg^orig) - orig);
aT->iDiff += diff;
aT->iXor ^= arg;
return 0;
}
template<class T> TInt DoAndOr(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw1Fn<T>::F atomic_and = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aA.iIndex];
typename TRmw1Fn<T>::F atomic_or = (typename TRmw1Fn<T>::F)AtomicFuncPtr[aA.iIndex+4];
T aarg = (T)aA.i0;
T oarg = (T)aA.i1;
T aorig = atomic_and(aPtr, aarg);
T oorig = atomic_or(aPtr, oarg);
T adiff = (T)((aorig & aarg) - aorig);
T odiff = (T)((oorig | oarg) - oorig);
aT->iDiff += adiff + odiff;
T axor = (T)((aorig & aarg) ^ aorig);
T oxor = (T)((oorig | oarg) ^ oorig);
aT->iXor ^= axor ^ oxor;
return 0;
}
template<class T> TInt DoAxo(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw2Fn<T>::F atomic = (typename TRmw2Fn<T>::F)AtomicFuncPtr[aA.iIndex];
T aarg = (T)aA.i0;
T xarg = (T)aA.i1;
T orig = atomic(aPtr, aarg, xarg);
T newv = (T)((orig & aarg) ^ xarg);
aT->iDiff += (newv - orig);
aT->iXor ^= (newv ^ orig);
return 0;
}
template<class T> TInt DoThAdd(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TRmw3Fn<T>::F atomic = (typename TRmw3Fn<T>::F)AtomicFuncPtr[aA.iIndex];
T thr = (T)aA.i0;
T arg1 = (T)aA.i1;
T arg2 = (T)aA.i2;
T orig = atomic(aPtr, thr, arg1, arg2);
T newv = (T)((orig >= thr) ? (orig + arg1) : (orig + arg2));
aT->iDiff += (orig >= thr) ? arg1 : arg2;
aT->iXor ^= (newv ^ orig);
return 0;
}
template<class T> TInt DoCas(TAny* aPtr, TPerThread* aT, TAtomicAction& aA, T*)
{
typename TCasFn<T>::F atomic = (typename TCasFn<T>::F)AtomicFuncPtr[aA.iIndex];
T orig = *(const volatile T*)aPtr;
T newv;
TBool done = FALSE;
TUint32 fails = 0xffffffffu;
do {
++fails;
newv = Transform<T>::F(orig);
done = atomic(aPtr, &orig, newv);
} while(!done);
aT->iFailCount += fails;
++aT->iDiff;
aT->iXor ^= (newv ^ orig);
return 0;
}
volatile TUint Dummy;
extern "C" TInt DoAtomicAction(TAny* aPtr, TPerThread* aT, TAtomicAction& aA)
{
TUint x = TUint(aT)*0x9E3779B9u;
x = (x>>8)&15;
while(x--)
++Dummy;
TInt r = KErrNotSupported;
TUint attr = FuncAttr[aA.iIndex];
TUint func = ATTR_TO_FUNC(attr);
TUint size = ATTR_TO_SIZE(attr);
switch (size)
{
case 1:
{
TUint8 xx;
TUint8* dummy = &xx;
TInt8 yy;
TInt8* sdummy = &yy;
switch (func)
{
case EAtomicFuncSWP: r=DoSwap<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncADD: r=DoAdd<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAND: r=DoAndOr<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncXOR: r=DoXor<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAXO: r=DoAxo<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAU: r=DoThAdd<TUint8>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAS: r=DoThAdd<TInt8>(aPtr, aT, aA, sdummy); break;
case EAtomicFuncCAS: r=DoCas<TUint8>(aPtr, aT, aA, dummy); break;
default: break;
}
break;
}
case 2:
{
TUint16 xx;
TUint16* dummy = &xx;
TInt16 yy;
TInt16* sdummy = &yy;
switch (func)
{
case EAtomicFuncSWP: r=DoSwap<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncADD: r=DoAdd<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAND: r=DoAndOr<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncXOR: r=DoXor<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAXO: r=DoAxo<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAU: r=DoThAdd<TUint16>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAS: r=DoThAdd<TInt16>(aPtr, aT, aA, sdummy); break;
case EAtomicFuncCAS: r=DoCas<TUint16>(aPtr, aT, aA, dummy); break;
default: break;
}
break;
}
case 4:
{
TUint32 xx;
TUint32* dummy = &xx;
TInt32 yy;
TInt32* sdummy = &yy;
switch (func)
{
case EAtomicFuncSWP: r=DoSwap<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncADD: r=DoAdd<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAND: r=DoAndOr<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncXOR: r=DoXor<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAXO: r=DoAxo<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAU: r=DoThAdd<TUint32>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAS: r=DoThAdd<TInt32>(aPtr, aT, aA, sdummy); break;
case EAtomicFuncCAS: r=DoCas<TUint32>(aPtr, aT, aA, dummy); break;
default: break;
}
break;
}
case 8:
{
TUint64A xx;
TUint64* dummy = &xx;
TInt64A yy;
TInt64* sdummy = &yy;
switch (func)
{
case EAtomicFuncSWP: r=DoSwap<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncADD: r=DoAdd<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAND: r=DoAndOr<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncXOR: r=DoXor<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncAXO: r=DoAxo<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAU: r=DoThAdd<TUint64>(aPtr, aT, aA, dummy); break;
case EAtomicFuncTAS: r=DoThAdd<TInt64>(aPtr, aT, aA, sdummy); break;
case EAtomicFuncCAS: r=DoCas<TUint64>(aPtr, aT, aA, dummy); break;
default: break;
}
break;
}
default:
break;
}
++aT->iCount;
return r;
}